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24 Commits

Author SHA1 Message Date
Olek
6a6fed5dce More hostfunctions (#5451)
* Bug fixes:
- Fix bugs found during schedule table tests
- Add more tests
- Add parameters passing for runEscrowWasm function

* Add new host-functions
 fix wamr logging
 add runtime passing through HF
 fix runEscrowWasm interface

* Improve logs

* Fix logging bug

* Set 4k limit for update_data HF

* allHF wasm module fixes
2025-05-30 19:01:27 -04:00
Mayukha Vadari
1f8aece8cd feat: add a GasUsed parameter to the metadata (#5456) 2025-05-29 16:36:55 -04:00
Mayukha Vadari
6c6f8cd4f9 Merge remote-tracking branch 'upstream/develop' into develop3 2025-05-29 13:05:11 -04:00
Mayukha Vadari
fb1311e013 uncomment???? 2025-05-28 14:00:50 -04:00
Mayukha Vadari
ce31acf030 debug comments 2025-05-28 13:48:38 -04:00
Mayukha Vadari
31ad5ac63b Merge remote-tracking branch 'upstream/ripple/smart-escrow' into develop3 2025-05-27 18:29:41 -04:00
Mayukha Vadari
1ede0bdec4 fix: fix fixtures (#5445) 2025-05-23 17:37:14 -04:00
Mayukha Vadari
aef32ead2c better WASM logging to match rippled (#5395)
* basic logging

* pass in Journal

* log level based on journal level

* clean up

* attempt at adding WAMR logging properly

* improve logline

* maybe_unused

* fix

* fix

* fix segfault

* add test
2025-05-23 10:31:02 -04:00
Mayukha Vadari
5b43ec7f73 refactor: switch function name from ready to finish (#5430) 2025-05-20 16:12:19 -04:00
Olek
1e9ff88a00 Fix CI build issues
* Mac build fix
* Windows build fix
* Windows instruction counter fix
2025-05-08 12:39:37 -04:00
Mayukha Vadari
bb9bb5f5c5 Merge branch 'ripple/smart-escrow' into develop2 2025-05-01 18:44:06 -04:00
Mayukha Vadari
c533abd8b6 Update size and compute cap defaults (#5417) 2025-05-01 18:41:51 -04:00
Olek
bb9bc764bc Switch to WAMR (#5416)
* Switch to WAMR
2025-05-01 18:02:06 -04:00
Mayukha Vadari
b4b53a6cb7 Merge branch 'ripple/smart-escrow' into develop2 2025-04-29 15:25:54 -04:00
Mayukha Vadari
9c0204906c fix reference fee tests 2025-04-29 15:25:00 -04:00
Mayukha Vadari
4670b373c1 try to fix tests 2025-04-29 14:10:27 -04:00
Mayukha Vadari
f03b5883bd More host functions (#5411)
* getNFT

* escrow keylet

* account keylet

* credential keylet

* oracle keylet

* hook everything in

* fix stuff
2025-04-29 12:39:12 -04:00
Mayukha Vadari
f8b2fe4dd5 fix imports 2025-04-28 17:43:15 -04:00
Mayukha Vadari
be4a0c9c2b Merge remote-tracking branch 'upstream/ripple/smart-escrow' into develop2 2025-04-28 17:14:28 -04:00
Mayukha Vadari
f37d52d8e9 Set up fees for WASM processing (#5393)
* set up fields

* throw error if allowance is too high

* votable gas price

* fix comments

* hook everything together

* make test less flaky (hopefully)

* fix other tests

* fix some tests

* fix tests

* clean up

* add more tests

* uncomment other tests

* respond to comments

* fix build

* respond to comments
2025-04-24 08:47:13 -04:00
Mayukha Vadari
177cdaf550 Connect votable gas limit into VM (#5360)
* [WIP] add gas limit

* [WIP] host function escrow tests

* finish test

* uncomment out tests
2025-03-25 10:55:33 -04:00
pwang200
1573a443b7 smart escrow devnet 1 host functions (#5353)
* devnet 1 host functions

* clang-format

* fix build issues
2025-03-24 17:07:17 -04:00
Mayukha Vadari
911c0466c0 Merge develop into ripple/smart-escrow (#5357)
* Set version to 2.4.0

* refactor: Remove unused and add missing includes (#5293)

The codebase is filled with includes that are unused, and which thus can be removed. At the same time, the files often do not include all headers that contain the definitions used in those files. This change uses clang-format and clang-tidy to clean up the includes, with minor manual intervention to ensure the code compiles on all platforms.

* refactor: Calculate numFeatures automatically (#5324)

Requiring manual updates of numFeatures is an annoying manual process that is easily forgotten, and leads to frequent merge conflicts. This change takes advantage of the `XRPL_FEATURE` and `XRPL_FIX` macros, and adds a new `XRPL_RETIRE` macro to automatically set `numFeatures`.

* refactor: Improve ordering of headers with clang-format (#5343)

Removes all manual header groupings from source and header files by leveraging clang-format options.

* Rename "deadlock" to "stall" in `LoadManager` (#5341)

What the LoadManager class does is stall detection, which is not the same as deadlock detection. In the condition of severe CPU starvation, LoadManager will currently intentionally crash rippled reporting `LogicError: Deadlock detected`. This error message is misleading as the condition being detected is not a deadlock. This change fixes and refactors the code in response.

* Adds hub.xrpl-commons.org as a new Bootstrap Cluster (#5263)

* fix: Error message for ledger_entry rpc (#5344)

Changes the error to `malformedAddress` for `permissioned_domain` in the `ledger_entry` rpc, when the account is not a string. This change makes it more clear to a user what is wrong with their request.

* fix: Handle invalid marker parameter in grpc call (#5317)

The `end_marker` is used to limit the range of ledger entries to fetch. If `end_marker` is less than `marker`, a crash can occur. This change adds an additional check.

* fix: trust line RPC no ripple flag (#5345)

The Trustline RPC `no_ripple` flag gets set depending on `lsfDefaultRipple` flag, which is not a flag of a trustline but of the account root. The `lsfDefaultRipple` flag does not provide any insight if this particular trust line has `lsfLowNoRipple` or `lsfHighNoRipple` flag set, so it should not be used here at all. This change simplifies the logic.

* refactor: Updates Conan dependencies: RocksDB (#5335)

Updates RocksDB to version 9.7.3, the latest version supported in Conan 1.x. A patch for 9.7.4 that fixes a memory leak is included.

* fix: Remove null pointer deref, just do abort (#5338)

This change removes the existing undefined behavior from `LogicError`, so we can be certain that there will be always a stacktrace.

De-referencing a null pointer is an old trick to generate `SIGSEGV`, which would typically also create a stacktrace. However it is also an undefined behaviour and compilers can do something else. A more robust way to create a stacktrace while crashing the program is to use `std::abort`, which we have also used in this location for a long time. If we combine the two, we might not get the expected behaviour - namely, the nullpointer deref followed by `std::abort`, as handled in certain compiler versions may not immediately cause a crash. We have observed stacktrace being wiped instead, and thread put in indeterminate state, then stacktrace created without any useful information.

* chore: Add PR number to payload (#5310)

This PR adds one more payload field to the libXRPL compatibility check workflow - the PR number itself.

* chore: Update link to ripple-binary-codec (#5355)

The link to ripple-binary-codec's definitions.json appears to be outdated. The updated link is also documented here: https://xrpl.org/docs/references/protocol/binary-format#definitions-file

* Prevent consensus from getting stuck in the establish phase (#5277)

- Detects if the consensus process is "stalled". If it is, then we can declare a 
  consensus and end successfully even if we do not have 80% agreement on
  our proposal.
  - "Stalled" is defined as:
    - We have a close time consensus
    - Each disputed transaction is individually stalled:
      - It has been in the final "stuck" 95% requirement for at least 2
        (avMIN_ROUNDS) "inner rounds" of phaseEstablish,
      - and either all of the other trusted proposers or this validator, if proposing,
        have had the same vote(s) for at least 4 (avSTALLED_ROUNDS) "inner
        rounds", and at least 80% of the validators (including this one, if
        appropriate) agree about the vote (whether yes or no).
- If we have been in the establish phase for more than 10x the previous
  consensus establish phase's time, then consensus is considered "expired",
  and we will leave the round, which sends a partial validation (indicating
  that the node is moving on without validating). Two restrictions avoid
  prematurely exiting, or having an extended exit in extreme situations.
  - The 10x time is clamped to be within a range of 15s
    (ledgerMAX_CONSENSUS) to 120s (ledgerABANDON_CONSENSUS).
  - If consensus has not had an opportunity to walk through all avalanche
    states (defined as not going through 8 "inner rounds" of phaseEstablish),
    then ConsensusState::Expired is treated as ConsensusState::No.
- When enough nodes leave the round, any remaining nodes will see they've
  fallen behind, and move on, too, generally before hitting the timeout. Any
  validations or partial validations sent during this time will help the
  consensus process bring the nodes back together.

---------

Co-authored-by: Michael Legleux <mlegleux@ripple.com>
Co-authored-by: Bart <bthomee@users.noreply.github.com>
Co-authored-by: Ed Hennis <ed@ripple.com>
Co-authored-by: Bronek Kozicki <brok@incorrekt.com>
Co-authored-by: Darius Tumas <Tokeiito@users.noreply.github.com>
Co-authored-by: Sergey Kuznetsov <skuznetsov@ripple.com>
Co-authored-by: cyan317 <120398799+cindyyan317@users.noreply.github.com>
Co-authored-by: Vlad <129996061+vvysokikh1@users.noreply.github.com>
Co-authored-by: Alex Kremer <akremer@ripple.com>
2025-03-20 16:47:14 -04:00
Mayukha Vadari
b6a95f9970 PoC Smart Escrows (#5340)
* wasmedge in unittest

* add WashVM.h and cpp

* accountID comparison (vector<u8>) working

* json decode tx and ledger object with two buffers working

* wasm return a buffer working

* add a failure test case to P2P3

* host function return ledger sqn

* instruction gas and host function gas

* basics

* add scaffold

* add amendment check

* working PoC

* get test working

* fix clang-format

* prototype #2

* p2p3

* [WIP] P4

* P5

* add calculateBaseFee

* add FinishFunction preflight checks (+ tests)

* additional reserve for sfFinishFunction

* higher fees for EscrowFinish

* rename amendment to SmartEscrow

* make fee voting changes, add basic tests

* clean up

* clean up

* clean up

* more cleanup

* add subscribe tests

* add more tests

* undo formatting

* undo formatting

* remove bad comment

* more debugging statements

* fix clang-format

* fix rebase issues

* fix more rebase issues

* more rebase fixes

* add source code for wasm

* respond to comments

* add const

---------

Co-authored-by: Peng Wang <pwang200@gmail.com>
2025-03-20 14:08:06 -04:00
2650 changed files with 299155 additions and 394203 deletions

View File

@@ -1,20 +1,4 @@
---
BreakBeforeBraces: Custom
BraceWrapping:
AfterClass: true
AfterControlStatement: true
AfterEnum: false
AfterFunction: true
AfterNamespace: false
AfterObjCDeclaration: true
AfterStruct: true
AfterUnion: true
BeforeCatch: true
BeforeElse: true
IndentBraces: false
KeepEmptyLinesAtTheStartOfBlocks: false
MaxEmptyLinesToKeep: 1
---
Language: Cpp
AccessModifierOffset: -4
AlignAfterOpenBracket: AlwaysBreak
@@ -34,10 +18,23 @@ AlwaysBreakBeforeMultilineStrings: true
AlwaysBreakTemplateDeclarations: true
BinPackArguments: false
BinPackParameters: false
BraceWrapping:
AfterClass: true
AfterControlStatement: true
AfterEnum: false
AfterFunction: true
AfterNamespace: false
AfterObjCDeclaration: true
AfterStruct: true
AfterUnion: true
BeforeCatch: true
BeforeElse: true
IndentBraces: false
BreakBeforeBinaryOperators: false
BreakBeforeBraces: Custom
BreakBeforeTernaryOperators: true
BreakConstructorInitializersBeforeComma: true
ColumnLimit: 100
ColumnLimit: 80
CommentPragmas: "^ IWYU pragma:"
ConstructorInitializerAllOnOneLineOrOnePerLine: true
ConstructorInitializerIndentWidth: 4
@@ -50,26 +47,27 @@ ForEachMacros: [Q_FOREACH, BOOST_FOREACH]
IncludeBlocks: Regroup
IncludeCategories:
- Regex: "^<(test)/"
Priority: 1
Priority: 0
- Regex: "^<(xrpld)/"
Priority: 2
Priority: 1
- Regex: "^<(xrpl)/"
Priority: 3
Priority: 2
- Regex: "^<(boost)/"
Priority: 4
Priority: 3
- Regex: "^.*/"
Priority: 5
Priority: 4
- Regex: '^.*\.h'
Priority: 6
Priority: 5
- Regex: ".*"
Priority: 7
Priority: 6
IncludeIsMainRegex: "$"
MainIncludeChar: AngleBracket
IndentCaseLabels: true
IndentFunctionDeclarationAfterType: false
IndentRequiresClause: true
IndentWidth: 4
IndentWrappedFunctionNames: false
KeepEmptyLinesAtTheStartOfBlocks: false
MaxEmptyLinesToKeep: 1
NamespaceIndentation: None
ObjCSpaceAfterProperty: false
ObjCSpaceBeforeProtocolList: false
@@ -97,8 +95,3 @@ Standard: Cpp11
TabWidth: 8
UseTab: Never
QualifierAlignment: Right
---
Language: Proto
BasedOnStyle: Google
ColumnLimit: 0
IndentWidth: 2

View File

@@ -1,166 +0,0 @@
---
Checks: "-*,
bugprone-*,
-bugprone-easily-swappable-parameters,
-bugprone-exception-escape,
-bugprone-implicit-widening-of-multiplication-result,
-bugprone-narrowing-conversions,
-bugprone-throwing-static-initialization,
cppcoreguidelines-*,
-cppcoreguidelines-avoid-c-arrays,
-cppcoreguidelines-avoid-capturing-lambda-coroutines,
-cppcoreguidelines-avoid-const-or-ref-data-members,
-cppcoreguidelines-avoid-do-while,
-cppcoreguidelines-avoid-goto,
-cppcoreguidelines-avoid-magic-numbers,
-cppcoreguidelines-avoid-non-const-global-variables,
-cppcoreguidelines-avoid-reference-coroutine-parameters,
-cppcoreguidelines-c-copy-assignment-signature,
-cppcoreguidelines-explicit-virtual-functions,
-cppcoreguidelines-interfaces-global-init,
-cppcoreguidelines-macro-to-enum,
-cppcoreguidelines-macro-usage,
-cppcoreguidelines-missing-std-forward,
-cppcoreguidelines-narrowing-conversions,
-cppcoreguidelines-no-malloc,
-cppcoreguidelines-noexcept-destructor,
-cppcoreguidelines-noexcept-move-operations,
-cppcoreguidelines-noexcept-swap,
-cppcoreguidelines-non-private-member-variables-in-classes,
-cppcoreguidelines-owning-memory,
-cppcoreguidelines-prefer-member-initializer,
-cppcoreguidelines-pro-bounds-array-to-pointer-decay,
-cppcoreguidelines-pro-bounds-avoid-unchecked-container-access,
-cppcoreguidelines-pro-bounds-constant-array-index,
-cppcoreguidelines-pro-bounds-pointer-arithmetic,
-cppcoreguidelines-pro-type-const-cast,
-cppcoreguidelines-pro-type-cstyle-cast,
-cppcoreguidelines-pro-type-reinterpret-cast,
-cppcoreguidelines-pro-type-union-access,
-cppcoreguidelines-pro-type-vararg,
-cppcoreguidelines-slicing,
-cppcoreguidelines-special-member-functions,
llvm-namespace-comment,
misc-*,
-misc-anonymous-namespace-in-header,
-misc-confusable-identifiers,
-misc-coroutine-hostile-raii,
-misc-misleading-bidirectional,
-misc-misleading-identifier,
-misc-multiple-inheritance,
-misc-new-delete-overloads,
-misc-no-recursion,
-misc-non-copyable-objects,
-misc-non-private-member-variables-in-classes,
-misc-override-with-different-visibility,
-misc-predictable-rand,
-misc-unconventional-assign-operator,
-misc-uniqueptr-reset-release,
-misc-unused-parameters,
-misc-use-anonymous-namespace,
-misc-use-internal-linkage,
modernize-*,
-modernize-avoid-c-arrays,
-modernize-avoid-c-style-cast,
-modernize-return-braced-init-list,
-modernize-use-integer-sign-comparison,
-modernize-use-trailing-return-type,
performance-*,
-performance-avoid-endl,
-performance-enum-size,
-performance-inefficient-algorithm,
-performance-inefficient-string-concatenation,
-performance-no-int-to-ptr,
-performance-noexcept-destructor,
-performance-noexcept-move-constructor,
-performance-noexcept-swap,
-performance-type-promotion-in-math-fn,
-performance-unnecessary-copy-initialization,
-performance-unnecessary-value-param,
readability-*,
-readability-avoid-const-params-in-decls,
-readability-avoid-unconditional-preprocessor-if,
-readability-container-data-pointer,
-readability-delete-null-pointer,
-readability-function-cognitive-complexity,
-readability-function-size,
-readability-identifier-length,
-readability-inconsistent-declaration-parameter-name,
-readability-isolate-declaration,
-readability-magic-numbers,
-readability-misplaced-array-index,
-readability-named-parameter,
-readability-operators-representation,
-readability-qualified-auto,
-readability-redundant-access-specifiers,
-readability-redundant-control-flow,
-readability-redundant-function-ptr-dereference,
-readability-redundant-preprocessor,
-readability-redundant-smartptr-get,
-readability-redundant-string-cstr,
-readability-simplify-subscript-expr,
-readability-static-accessed-through-instance,
-readability-string-compare,
-readability-uniqueptr-delete-release,
-readability-uppercase-literal-suffix,
-readability-use-anyofallof,
-readability-use-concise-preprocessor-directives
"
# ---
# bugprone-narrowing-conversions, # This will break a lot of code but we should enable it in the future because it can eliminate a lot of bugs
# misc-override-with-different-visibility, # Will be addressed in a future PR, but for now it generates too many warnings
# readability-inconsistent-declaration-parameter-name, # In this codebase this check will break a lot of arg names
# readability-static-accessed-through-instance, # this check is probably unnecessary. It makes the code less readable
# ---
CheckOptions:
bugprone-unsafe-functions.ReportMoreUnsafeFunctions: true
bugprone-unused-return-value.CheckedReturnTypes: ::std::error_code;::std::error_condition;::std::errc
misc-include-cleaner.IgnoreHeaders: ".*/(detail|impl)/.*;.*fwd\\.h(pp)?;time.h;stdlib.h;sqlite3.h;netinet/in\\.h;sys/resource\\.h;sys/sysinfo\\.h;linux/sysinfo\\.h;__chrono/.*;bits/.*;_abort\\.h;boost/.*;openssl/obj_mac\\.h"
readability-braces-around-statements.ShortStatementLines: 2
readability-identifier-naming.MacroDefinitionCase: UPPER_CASE
readability-identifier-naming.ClassCase: CamelCase
readability-identifier-naming.StructCase: CamelCase
readability-identifier-naming.UnionCase: CamelCase
readability-identifier-naming.EnumCase: CamelCase
readability-identifier-naming.EnumConstantCase: CamelCase
readability-identifier-naming.ScopedEnumConstantCase: CamelCase
readability-identifier-naming.GlobalConstantCase: CamelCase
readability-identifier-naming.GlobalConstantPrefix: "k"
readability-identifier-naming.GlobalVariableCase: CamelCase
readability-identifier-naming.GlobalVariablePrefix: "g"
readability-identifier-naming.ConstexprFunctionCase: camelBack
readability-identifier-naming.ConstexprMethodCase: camelBack
readability-identifier-naming.ClassMethodCase: camelBack
readability-identifier-naming.ClassMemberCase: camelBack
readability-identifier-naming.ClassConstantCase: CamelCase
readability-identifier-naming.ClassConstantPrefix: "k"
readability-identifier-naming.StaticConstantCase: CamelCase
readability-identifier-naming.StaticConstantPrefix: "k"
readability-identifier-naming.StaticVariableCase: camelBack
readability-identifier-naming.ConstexprVariableCase: camelBack
readability-identifier-naming.LocalConstantCase: camelBack
readability-identifier-naming.LocalVariableCase: camelBack
readability-identifier-naming.TemplateParameterCase: CamelCase
readability-identifier-naming.ParameterCase: camelBack
readability-identifier-naming.FunctionCase: camelBack
readability-identifier-naming.MemberCase: camelBack
readability-identifier-naming.PrivateMemberCase: camelBack
readability-identifier-naming.PrivateMemberSuffix: _
readability-identifier-naming.ProtectedMemberCase: camelBack
readability-identifier-naming.ProtectedMemberSuffix: _
readability-identifier-naming.PublicMemberCase: camelBack
readability-identifier-naming.PublicMemberSuffix: ""
readability-identifier-naming.GlobalFunctionIgnoredRegexp: "^(to_string|hash_append|tuple_hash)$"
HeaderFilterRegex: '^.*/(tests?|xrpl|xrpld)/.*\.(h|hpp|ipp)$'
ExcludeHeaderFilterRegex: '^.*/protocol_autogen/.*\.(h|hpp)$'
WarningsAsErrors: "*"

View File

@@ -27,17 +27,11 @@ github_checks:
parsers:
cobertura:
partials_as_hits: true
handle_missing_conditions: true
handle_missing_conditions : true
slack_app: false
ignore:
- "src/test/"
- "src/tests/"
- "include/xrpl/beast/test/"
- "include/xrpl/beast/unit_test/"
# Telemetry modules — conditionally compiled behind XRPL_ENABLE_TELEMETRY,
# which is not enabled in coverage builds.
- "src/xrpld/telemetry/"
- "src/libxrpl/beast/insight/OTelCollector.cpp"
- "include/xrpl/beast/insight/OTelCollector.h"

View File

@@ -1,381 +0,0 @@
ignorePaths:
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- src/libxrpl/crypto
- CMakeUserPresets.json
- Doxyfile
- docs/**/*.puml
- cmake/**
- LICENSE.md
- .clang-tidy
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allowCompoundWords: true # TODO (#6334)
ignoreRandomStrings: true
minWordLength: 5
dictionaries:
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- en_US
- en_GB
ignoreRegExpList:
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- /\bC[A-Z0-9]{15}/g # CTIDs
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- /\b(XRPL|BEAST)_[A-Z_0-9]+_H+/g # include guards
- /::[a-z:_]+/g # things from other namespaces
- /\blib[a-z]+/g # libraries
- /\b[0-9]{4}-[0-9]{2}-[0-9]{2}[,:][A-Za-zÀ-ÖØ-öø-ÿ.\s]+/g # copyright dates
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- /[\['"`]-[DWw][a-zA-Z0-9_-]+['"`\]]/g # compile flags
- ABCDEFGHIJKLMNOPQRSTUVWXYZ
- ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz
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- /'[^']*'/g # single-quoted strings
- /`[^`]*`/g # backtick strings
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- synched->synced
- synch->sync
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- mathbunnyru
- mcmodel
- MEMORYSTATUSEX
- Merkle
- Metafuncton
- misprediction
- missingok
- MPTAMM
- mptbalance
- MPTDEX
- mptflags
- mptid
- mptissuance
- mptissuanceid
- mptissue
- mptoken
- mptokenid
- mptokenissuance
- mptokens
- mpts
- mtgox
- multisig
- multisign
- multisigned
- Nakamoto
- nftid
- nftoffer
- nftoken
- nftokenid
- nftokenpages
- nftokens
- nftpage
- nikb
- nixfmt
- nixos
- nixpkgs
- NETOP
- NOLINT
- NOLINTNEXTLINE
- nonxrp
- noreplace
- noripple
- nostd
- nostdinc
- notifempty
- nudb
- nullptr
- nunl
- Nyffenegger
- onlatest
- ostr
- otelc
- pargs
- partitioner
- paychan
- paychans
- Pedersen
- permdex
- perminute
- permissioned
- pgrep
- pkill
- pimpl
- pointee
- populator
- pratik
- preauth
- preauthorization
- preauthorize
- preauthorizes
- preclaim
- preun
- protobuf
- protos
- ptrs
- pushd
- pyenv
- pyparsing
- qalloc
- qbsprofile
- queuable
- Raphson
- rcflags
- reparent
- replayer
- reqps
- rerandomize
- rerandomization
- rerandomized
- rerandomizes
- rerere
- retriable
- RIPD
- ripdtop
- rippleci
- rippled
- ripplerpc
- rippletest
- RLUSD
- rngfill
- rocksdb
- Rohrs
- roundings
- sahyadri
- Satoshi
- scons
- Schnorr
- secp
- sendq
- seqit
- sf
- SFIELD
- sfields
- shamap
- shamapitem
- shfmt
- shlibs
- sidechain
- SIGGOOD
- sle
- sles
- soci
- socidb
- SRPMS
- sslws
- statsd
- STATSDCOLLECTOR
- stissue
- stnum
- stobj
- stobject
- stpath
- stpathset
- sttx
- stvar
- stvector
- stxchainattestations
- summands
- superpeer
- superpeers
- takergets
- takerpays
- ters
- TMEndpointv2
- traceql
- trixie
- tx
- txid
- txids
- txjson
- txn
- txns
- txqueue
- txs
- ubsan
- UBSAN
- ufdio
- umant
- unacquired
- unambiguity
- unauthorizes
- unauthorizing
- unergonomic
- unfetched
- unfindable
- unflatten
- unfund
- unimpair
- unroutable
- unscalable
- unserviced
- unshareable
- unshares
- unsquelch
- unsquelched
- unsquelching
- unvalidated
- unveto
- unvetoed
- upvotes
- USDB
- variadics
- venv
- vfalco
- vinnie
- wasmi
- wextra
- wptr
- writeme
- wsrch
- wthread
- xbridge
- xchain
- ximinez
- XMACRO
- xrpkuwait
- xrpl
- xrpld
- xrplf
- xxhash
- xxhasher
- xychart
- zpages
- ripplex
- mseconds

View File

@@ -1,107 +0,0 @@
# Custom CMake command definitions for gersemi formatting.
# These stubs teach gersemi the signatures of project-specific commands
# so it can format their invocations correctly.
function(git_branch branch_val)
endfunction()
function(isolate_headers target A B scope)
endfunction()
function(create_symbolic_link target link)
endfunction()
macro(exclude_from_default target_)
endmacro()
macro(exclude_if_included target_)
endmacro()
function(target_protobuf_sources target prefix)
set(options APPEND_PATH DESCRIPTORS)
set(oneValueArgs
LANGUAGE
OUT_VAR
EXPORT_MACRO
TARGET
PROTOC_OUT_DIR
PLUGIN
PLUGIN_OPTIONS
PROTOC_EXE
)
set(multiValueArgs
PROTOS
IMPORT_DIRS
GENERATE_EXTENSIONS
PROTOC_OPTIONS
DEPENDENCIES
)
cmake_parse_arguments(
THIS_FUNCTION_PREFIX
"${options}"
"${oneValueArgs}"
"${multiValueArgs}"
${ARGN}
)
endfunction()
function(add_module parent name)
endfunction()
function(verify_target_headers target headers_dir)
endfunction()
function(_verify_add_headers target dir)
endfunction()
function(setup_protocol_autogen)
endfunction()
function(target_link_modules parent scope)
endfunction()
function(setup_target_for_coverage_gcovr)
set(options NONE)
set(oneValueArgs BASE_DIRECTORY NAME FORMAT)
set(multiValueArgs EXCLUDE EXECUTABLE EXECUTABLE_ARGS DEPENDENCIES)
cmake_parse_arguments(
THIS_FUNCTION_PREFIX
"${options}"
"${oneValueArgs}"
"${multiValueArgs}"
${ARGN}
)
endfunction()
function(add_code_coverage_to_target name scope)
endfunction()
function(verbose_find_path variable name)
set(options
NO_CACHE
REQUIRED
OPTIONAL
NO_DEFAULT_PATH
NO_PACKAGE_ROOT_PATH
NO_CMAKE_PATH
NO_CMAKE_ENVIRONMENT_PATH
NO_SYSTEM_ENVIRONMENT_PATH
NO_CMAKE_SYSTEM_PATH
NO_CMAKE_INSTALL_PREFIX
CMAKE_FIND_ROOT_PATH_BOTH
ONLY_CMAKE_FIND_ROOT_PATH
NO_CMAKE_FIND_ROOT_PATH
)
set(oneValueArgs REGISTRY_VIEW VALIDATOR DOC)
set(multiValueArgs NAMES HINTS PATHS PATH_SUFFIXES)
cmake_parse_arguments(
THIS_FUNCTION_PREFIX
"${options}"
"${oneValueArgs}"
"${multiValueArgs}"
${ARGN}
)
endfunction()
function(patch_nix_binary target)
endfunction()

View File

@@ -1 +0,0 @@
definitions: [.gersemi]

View File

@@ -1,81 +1,13 @@
# This feature requires Git >= 2.24
# To use it by default in git blame:
# git config blame.ignoreRevsFile .git-blame-ignore-revs
# This file is sorted in reverse chronological order, with the most recent commits at the top.
# The commits listed here are ignored by git blame, which is useful for formatting-only commits that would otherwise obscure the history of changes to a file.
# refactor: Enable clang-tidy `readability-identifier-naming` check (#6571)
8995564ed6b9e453e144bb663303072a3c1ba305
# refactor: Enable remaining clang-tidy `cppcoreguidelines` checks (#6538)
72f4cb097f626b08b02fc3efcb4aa11cb2e7adb8
# refactor: Rename system name from 'ripple' to 'xrpld' (#6347)
ffea3977f0b771fe8e43a8f74e4d393d63a7afd8
# refactor: Update transaction folder structure (#6483)
5865bd017f777491b4a956f9210be0c4161f5442
# chore: Use gersemi instead of ancient cmake-format (#6486)
0c74270b055133a57a497b5c9fc5a75f7647b1f4
# chore: Apply clang-format width 100 (#6387)
2c1fad102353e11293e3edde1c043224e7d3e983
# chore: Set clang-format width to 100 in config file (#6387)
25cca465538a56cce501477f9e5e2c1c7ea2d84c
# chore: Set cmake-format width to 100 (#6386)
469ce9f291a4480c38d4ee3baca5136b2f053cd0
# refactor: Modularize app/tx (#6228)
0976b2b68b64972af8e6e7c497900b5bce9fe22f
# chore: Update clang-format to 21.1.8 (#6352)
958d8f375453d80bb1aa4c293b5102c045a3e4b4
# refactor: Replace include guards by '#pragma once' (#6322)
34ef577604782ca8d6e1c17df8bd7470990a52ff
# chore: Format all cmake files without comments (#6294)
fe9c8d568fcf6ac21483024e01f58962dd5c8260
# chore: Add cmake-format pre-commit hook (#6279)
a0e09187b9370805d027c611a7e9ff5a0125282a
# chore: Set ColumnLimit to 120 in clang-format (#6288)
5f638f55536def0d88b970d1018a465a238e55f4
# refactor: Fix typos in comments, configure cspell (#6164)
3c9f5b62525cb1d6ca1153eeb10433db7d7379fd
# refactor: Rename `rippled.cfg` to `xrpld.cfg` (#6098)
3d1b3a49b3601a0a7037fa0b19d5df7b5e0e2fc1
# refactor: Rename `ripple` namespace to `xrpl` (#5982)
1eb0fdac6543706b4b9ddca57fd4102928a1f871
# refactor: Rename `rippled` binary to `xrpld` (#5983)
9eb84a561ef8bb066d89f098bd9b4ac71baed67c
# refactor: Replaces secp256k1 source by Conan package (#6089)
813bc4d9491b078bb950f8255f93b02f71320478
# refactor: Remove unnecessary copyright notices already covered by LICENSE.md (#5929)
1d42c4f6de6bf01d1286fc7459b17a37a5189e88
# refactor: Rename `RIPPLE_` and `RIPPLED_` definitions to `XRPL_` (#5821)
ada83564d894829424b0f4d922b0e737e07abbf7
# refactor: Modularize shamap and nodestore (#5668)
8eb233c2ea8ad5a159be73b77f0f5e1496d547ac
# refactor: Modularise ledger (#5493)
dc8b37a52448b005153c13a7f046ad494128cf94
# chore: Update clang-format and prettier with pre-commit (#5709)
c14ce956adeabe476ad73c18d73103f347c9c613
# chore: Fix file formatting (#5718)
896b8c3b54a22b0497cb0d1ce95e1095f9a227ce
# chore: Reverts formatting changes to external files, adds formatting changes to proto files (#5711)
b13370ac0d207217354f1fc1c29aef87769fb8a1
# chore: Run prettier on all files (#5657)
97f0747e103f13e26e45b731731059b32f7679ac
# Reformat code with clang-format-18
552377c76f55b403a1c876df873a23d780fcc81c
# Recompute loops (#4997)
d028005aa6319338b0adae1aebf8abe113162960
# Rewrite includes (#4997)
1d23148e6dd53957fcb6205c07a5c6cd7b64d50c
# Rearrange sources (#4997)
e416ee72ca26fa0c09d2aee1b68bdfb2b7046eed
# Move CMake directory (#4997)
2e902dee53aab2a8f27f32971047bb81e022f94f
# Rewrite includes
0eebe6a5f4246fced516d52b83ec4e7f47373edd
# Format formerly .hpp files
760f16f56835663d9286bd29294d074de26a7ba6
# Rename .hpp to .h
241b9ddde9e11beb7480600fd5ed90e1ef109b21
# Consolidate external libraries
e2384885f5f630c8f0ffe4bf21a169b433a16858
# Format first-party source according to .clang-format
50760c693510894ca368e90369b0cc2dabfd07f3
e2384885f5f630c8f0ffe4bf21a169b433a16858
241b9ddde9e11beb7480600fd5ed90e1ef109b21
760f16f56835663d9286bd29294d074de26a7ba6
0eebe6a5f4246fced516d52b83ec4e7f47373edd
2189cc950c0cebb89e4e2fa3b2d8817205bf7cef
b9d007813378ad0ff45660dc07285b823c7e9855
fe9a5365b8a52d4acc42eb27369247e6f238a4f9
9a93577314e6a8d4b4a8368cc9d2b15a5d8303e8
552377c76f55b403a1c876df873a23d780fcc81c

5
.gitattributes vendored
View File

@@ -1,6 +1,9 @@
# Set default behaviour, in case users don't have core.autocrlf set.
#* text=auto
# cspell: disable
# These annoying files
rippled.1 binary
LICENSE binary
# Visual Studio
*.sln text eol=crlf

8
.github/CODEOWNERS vendored Normal file
View File

@@ -0,0 +1,8 @@
# Allow anyone to review any change by default.
*
# Require the rpc-reviewers team to review changes to the rpc code.
include/xrpl/protocol/ @xrplf/rpc-reviewers
src/libxrpl/protocol/ @xrplf/rpc-reviewers
src/xrpld/rpc/ @xrplf/rpc-reviewers
src/xrpld/app/misc/ @xrplf/rpc-reviewers

View File

@@ -1,36 +1,31 @@
---
name: Bug Report
about: Create a report to help us improve xrpld
title: "[Title with short description] (Version: [xrpld version])"
labels: ""
assignees: ""
---
about: Create a report to help us improve rippled
title: "[Title with short description] (Version: [rippled version])"
labels: ''
assignees: ''
---
<!-- Please search existing issues to avoid creating duplicates.-->
## Issue Description
<!--Provide a summary for your issue/bug.-->
## Steps to Reproduce
<!--List in detail the exact steps to reproduce the unexpected behavior of the software.-->
## Expected Result
<!--Explain in detail what behavior you expected to happen.-->
## Actual Result
<!--Explain in detail what behavior actually happened.-->
## Environment
<!--Please describe your environment setup (such as Ubuntu 18.04 with Boost 1.70).-->
<!-- If you are using a formal release, please use the version returned by './xrpld --version' as the version number-->
<!-- If you are using a formal release, please use the version returned by './rippled --version' as the version number-->
<!-- If you are working off of develop, please add the git hash via 'git rev-parse HEAD'-->
## Supporting Files
<!--If you have supporting files such as a log, feel free to post a link here using Github Gist.-->
<!--Consider adding configuration files with private information removed via Github Gist. -->

View File

@@ -1,25 +1,21 @@
---
name: Feature Request
about: Suggest a new feature for the xrpld project
title: "[Title with short description] (Version: [xrpld version])"
about: Suggest a new feature for the rippled project
title: "[Title with short description] (Version: [rippled version])"
labels: Feature Request
assignees: ""
---
assignees: ''
---
<!-- Please search existing issues to avoid creating duplicates.-->
## Summary
<!-- Provide a summary to the feature request-->
## Motivation
<!-- Why do we need this feature?-->
## Solution
<!-- What is the solution?-->
## Paths Not Taken
<!-- What other alternatives have been considered?-->

View File

@@ -1,47 +0,0 @@
name: Build Conan dependencies
description: "Install Conan dependencies, optionally forcing a rebuild of all dependencies."
# Note that actions do not support 'type' and all inputs are strings, see
# https://docs.github.com/en/actions/reference/workflows-and-actions/metadata-syntax#inputs.
inputs:
build_type:
description: 'The build type to use ("Debug", "Release").'
required: true
build_nproc:
description: "The number of processors to use for building."
required: true
force_build:
description: 'Force building of all dependencies ("true", "false").'
required: false
default: "false"
log_verbosity:
description: "The logging verbosity."
required: false
default: "verbose"
sanitizers:
description: "The sanitizers to enable."
required: false
default: ""
runs:
using: composite
steps:
- name: Install Conan dependencies
shell: bash
env:
BUILD_NPROC: ${{ inputs.build_nproc }}
BUILD_OPTION: ${{ inputs.force_build == 'true' && '*' || 'missing' }}
BUILD_TYPE: ${{ inputs.build_type }}
LOG_VERBOSITY: ${{ inputs.log_verbosity }}
SANITIZERS: ${{ inputs.sanitizers }}
run: |
conan install \
--profile:all ci \
--build="${BUILD_OPTION}" \
--options:host='&:tests=True' \
--options:host='&:xrpld=True' \
--settings:all build_type="${BUILD_TYPE}" \
--conf:all tools.build:jobs=${BUILD_NPROC} \
--conf:all tools.build:verbosity="${LOG_VERBOSITY}" \
--conf:all tools.compilation:verbosity="${LOG_VERBOSITY}" \
.

34
.github/actions/build/action.yml vendored Normal file
View File

@@ -0,0 +1,34 @@
name: build
inputs:
generator:
default: null
configuration:
required: true
cmake-args:
default: null
cmake-target:
default: all
# An implicit input is the environment variable `build_dir`.
runs:
using: composite
steps:
- name: configure
shell: bash
run: |
cd ${build_dir}
cmake \
${{ inputs.generator && format('-G "{0}"', inputs.generator) || '' }} \
-DCMAKE_TOOLCHAIN_FILE:FILEPATH=build/generators/conan_toolchain.cmake \
-DCMAKE_BUILD_TYPE=${{ inputs.configuration }} \
-Dtests=TRUE \
-Dxrpld=TRUE \
${{ inputs.cmake-args }} \
..
- name: build
shell: bash
run: |
cmake \
--build ${build_dir} \
--config ${{ inputs.configuration }} \
--parallel ${NUM_PROCESSORS:-$(nproc)} \
--target ${{ inputs.cmake-target }}

58
.github/actions/dependencies/action.yml vendored Normal file
View File

@@ -0,0 +1,58 @@
name: dependencies
inputs:
configuration:
required: true
# An implicit input is the environment variable `build_dir`.
runs:
using: composite
steps:
- name: unlock Conan
shell: bash
run: conan remove --locks
- name: export custom recipes
shell: bash
run: |
conan config set general.revisions_enabled=1
conan export external/snappy snappy/1.1.10@
conan export external/rocksdb rocksdb/9.7.3@
conan export external/soci soci/4.0.3@
conan export external/nudb nudb/2.0.8@
conan export -k external/wamr wamr/2.2.0@
- name: add Ripple Conan remote
shell: bash
run: |
conan remote list
conan remote remove ripple || true
# Do not quote the URL. An empty string will be accepted (with
# a non-fatal warning), but a missing argument will not.
conan remote add ripple ${{ env.CONAN_URL }} --insert 0
- name: try to authenticate to Ripple Conan remote
id: remote
shell: bash
run: |
# `conan user` implicitly uses the environment variables
# CONAN_LOGIN_USERNAME_<REMOTE> and CONAN_PASSWORD_<REMOTE>.
# https://docs.conan.io/1/reference/commands/misc/user.html#using-environment-variables
# https://docs.conan.io/1/reference/env_vars.html#conan-login-username-conan-login-username-remote-name
# https://docs.conan.io/1/reference/env_vars.html#conan-password-conan-password-remote-name
echo outcome=$(conan user --remote ripple --password >&2 \
&& echo success || echo failure) | tee ${GITHUB_OUTPUT}
- name: list missing binaries
id: binaries
shell: bash
# Print the list of dependencies that would need to be built locally.
# A non-empty list means we have "failed" to cache binaries remotely.
run: |
echo missing=$(conan info . --build missing --settings build_type=${{ inputs.configuration }} --json 2>/dev/null | grep '^\[') | tee ${GITHUB_OUTPUT}
- name: install dependencies
shell: bash
run: |
mkdir ${build_dir}
cd ${build_dir}
conan install \
--output-folder . \
--build missing \
--options tests=True \
--options xrpld=True \
--settings build_type=${{ inputs.configuration }} \
..

View File

@@ -1,44 +0,0 @@
name: Generate build version number
description: "Generate build version number."
outputs:
version:
description: "The generated build version number."
value: ${{ steps.version.outputs.version }}
runs:
using: composite
steps:
# When a tag is pushed, the version is used as-is.
- name: Generate version for tag event
if: ${{ startsWith(github.ref, 'refs/tags/') }}
shell: bash
env:
VERSION: ${{ github.ref_name }}
run: echo "VERSION=${VERSION}" >>"${GITHUB_ENV}"
# When a tag is not pushed, then the version (e.g. 1.2.3-b0) is extracted
# from the BuildInfo.cpp file and the shortened commit hash appended to it.
# We use a plus sign instead of a hyphen because Conan recipe versions do
# not support two hyphens.
- name: Generate version for non-tag event
if: ${{ !startsWith(github.ref, 'refs/tags/') }}
shell: bash
run: |
echo 'Extracting version from BuildInfo.cpp.'
VERSION="$(cat src/libxrpl/protocol/BuildInfo.cpp | grep "versionString =" | awk -F '"' '{print $2}')"
if [[ -z "${VERSION}" ]]; then
echo 'Unable to extract version from BuildInfo.cpp.'
exit 1
fi
echo 'Appending shortened commit hash to version.'
SHA='${{ github.sha }}'
VERSION="${VERSION}+${SHA:0:7}"
echo "VERSION=${VERSION}" >>"${GITHUB_ENV}"
- name: Output version
id: version
shell: bash
run: echo "version=${VERSION}" >>"${GITHUB_OUTPUT}"

View File

@@ -1,34 +0,0 @@
name: Set compiler environment
description: "Set CC and CXX environment variables for the given compiler."
inputs:
compiler:
description: 'The compiler to use ("gcc" or "clang").'
required: true
runs:
using: composite
steps:
- name: Set CC and CXX for gcc
if: ${{ inputs.compiler == 'gcc' }}
shell: bash
run: |
echo "CC=gcc" >>"${GITHUB_ENV}"
echo "CXX=g++" >>"${GITHUB_ENV}"
- name: Set CC and CXX for clang
if: ${{ inputs.compiler == 'clang' }}
shell: bash
run: |
echo "CC=clang" >>"${GITHUB_ENV}"
echo "CXX=clang++" >>"${GITHUB_ENV}"
- name: Fail on unknown compiler
if: ${{ inputs.compiler != 'gcc' && inputs.compiler != 'clang' }}
shell: bash
env:
COMPILER: ${{ inputs.compiler }}
run: |
echo "Unknown compiler: $COMPILER" >&2
exit 1

View File

@@ -1,49 +0,0 @@
name: Setup Conan
description: "Set up Conan configuration, profile, and remote."
inputs:
remote_name:
description: "The name of the Conan remote to use."
required: false
default: xrplf
remote_url:
description: "The URL of the Conan endpoint to use."
required: false
default: https://conan.xrplf.org/repository/conan/
runs:
using: composite
steps:
- name: Apply custom configuration to global.conf
shell: bash
run: |
cat conan/global.conf ${{ runner.os == 'Linux' && '>>' || '>' }} $(conan config home)/global.conf
- name: Show global configuration
shell: bash
run: |
conan config show '*'
- name: Install profiles
shell: bash
run: |
conan config install conan/profiles/ -tf $(conan config home)/profiles/
- name: Show CI profile
shell: bash
run: |
conan profile show --profile ci
- name: Add a remote
shell: bash
env:
REMOTE_NAME: ${{ inputs.remote_name }}
REMOTE_URL: ${{ inputs.remote_url }}
run: |
conan remote add --index 0 --force "${REMOTE_NAME}" "${REMOTE_URL}"
- name: List remotes
shell: bash
run: |
conan remote list

View File

@@ -1,17 +0,0 @@
version: 2
updates:
- package-ecosystem: github-actions
directories:
- /
- .github/actions/build-deps/
- .github/actions/generate-version/
- .github/actions/set-compiler-env/
- .github/actions/setup-conan/
schedule:
interval: weekly
day: monday
time: "04:00"
timezone: Etc/GMT
commit-message:
prefix: "ci: [DEPENDABOT] "
target-branch: develop

View File

@@ -29,6 +29,22 @@ If a refactor, how is this better than the previous implementation?
If there is a spec or design document for this feature, please link it here.
-->
### Type of Change
<!--
Please check [x] relevant options, delete irrelevant ones.
-->
- [ ] Bug fix (non-breaking change which fixes an issue)
- [ ] New feature (non-breaking change which adds functionality)
- [ ] Breaking change (fix or feature that would cause existing functionality to not work as expected)
- [ ] Refactor (non-breaking change that only restructures code)
- [ ] Performance (increase or change in throughput and/or latency)
- [ ] Tests (you added tests for code that already exists, or your new feature included in this PR)
- [ ] Documentation update
- [ ] Chore (no impact to binary, e.g. `.gitignore`, formatting, dropping support for older tooling)
- [ ] Release
### API Impact
<!--

View File

@@ -1,85 +0,0 @@
#!/usr/bin/env python3
"""
Checks that a pull request description has been customized from the
pull_request_template.md. Exits with code 1 if the description is empty
or identical to the template (ignoring HTML comments and whitespace).
Usage:
python check-pr-description.py --template-file TEMPLATE --pr-body-file BODY
"""
import argparse
import re
import sys
from pathlib import Path
def normalize(text: str) -> str:
"""Strip HTML comments, trim lines, and remove blank lines."""
# Remove HTML comments (possibly multi-line)
text = re.sub(r"<!--.*?-->", "", text, flags=re.DOTALL)
# Strip each line and drop empties
lines = [line.strip() for line in text.splitlines()]
lines = [line for line in lines if line]
return "\n".join(lines)
def main() -> int:
parser = argparse.ArgumentParser(
description="Check that a PR description differs from the template."
)
parser.add_argument(
"--template-file",
type=Path,
required=True,
help="Path to the pull request template file.",
)
parser.add_argument(
"--pr-body-file",
type=Path,
required=True,
help="Path to a file containing the PR body text.",
)
args = parser.parse_args()
template_path: Path = args.template_file
pr_body_path: Path = args.pr_body_file
if not template_path.is_file():
print(f"::error::Template file {template_path} not found")
return 1
if not pr_body_path.is_file():
print(f"::error::PR body file {pr_body_path} not found")
return 1
template = template_path.read_text(encoding="utf-8")
pr_body = pr_body_path.read_text(encoding="utf-8")
# Check if the PR body is empty or whitespace-only
if not pr_body.strip():
print(
"::error::PR description is empty. "
"Please fill in the pull request template."
)
return 1
norm_template = normalize(template)
norm_pr_body = normalize(pr_body)
if norm_pr_body == norm_template:
print(
"::error::PR description (ignoring HTML comments) is identical"
" to the template. Please fill in the details of your change."
f"\n\nVisible template content:\n---\n{norm_template}\n---"
f"\n\nVisible PR description content:\n---\n{norm_pr_body}\n---"
)
return 1
print("PR description has been customized from the template.")
return 0
if __name__ == "__main__":
sys.exit(main())

View File

@@ -1,403 +0,0 @@
#!/usr/bin/env python3
"""
Format embedded shell snippets using the shfmt hook configured in
.pre-commit-config.yaml.
Two shapes are recognised:
* YAML workflow/action files: literal block-scalar runs (`run: |`) and
single-line runs (`run: some command`). A single-line run is upgraded to
a `run: |` block scalar if shfmt's output spans multiple lines.
* Markdown files: ``` ```bash ``` fenced code blocks.
Any block that shfmt cannot parse is skipped with a warning on stderr, so
the file is left untouched and surrounding blocks still get formatted.
For each occurrence the body is dedented, written to a temp .sh file,
formatted via `pre-commit run shfmt --files <temp>` (falling back to
`prek`), then re-indented and written back in place.
When invoked without arguments, every .yml/.yaml under .github/ plus every
.md file in the repo is scanned. When invoked with file arguments (the
pre-commit case), only those files are processed.
"""
from __future__ import annotations
import re
import shutil
import subprocess
import sys
import tempfile
from dataclasses import dataclass
from pathlib import Path
from typing import Union
REPO = Path(__file__).resolve().parents[2]
_HOOK_RUNNER = next((cmd for cmd in ("pre-commit", "prek") if shutil.which(cmd)), None)
if _HOOK_RUNNER is None:
sys.exit("error: neither `pre-commit` nor `prek` found on PATH")
RUN_BLOCK_RE = re.compile(r"^(?P<prefix>[ \t]*(?:- )?)run:[ \t]*\|[+-]?[ \t]*$")
RUN_INLINE_RE = re.compile(
r"^(?P<prefix>[ \t]*(?:- )?)run:[ \t]+" r"(?P<value>(?!\|[+-]?[ \t]*$)\S.*?)[ \t]*$"
)
MD_BASH_OPEN_RE = re.compile(r"^(?P<indent>[ ]{0,3})`{3}bash[ \t]*$")
MD_FENCE_CLOSE_RE = re.compile(r"^[ ]{0,3}`{3,}[ \t]*$")
@dataclass(frozen=True)
class BlockRun:
"""A `run: |` block scalar; `body_start:body_end` slices into `lines`."""
body_start: int
body_end: int
body_indent: int
@dataclass(frozen=True)
class InlineRun:
"""A single-line `run: value` at `line_idx`."""
line_idx: int
prefix: str
value: str
@dataclass(frozen=True)
class MdBashBlock:
"""A markdown ``` ```bash ``` fenced code block.
`body_start:body_end` slices into the file's lines; `open_line_idx`
points at the opening fence line.
"""
open_line_idx: int
body_start: int
body_end: int
body_indent: int
RunItem = Union[BlockRun, InlineRun]
def _scan_block_body(
lines: list[str], body_start: int, run_col: int
) -> tuple[int | None, int]:
"""Locate the body of a `run: |` block scalar starting at `body_start`.
Returns `(body_indent, scan_end)`. `scan_end` is the line index where the
outer scanner should resume. `body_indent` is `None` when no body is
present (the scalar is empty, or the next non-blank line has indent
`<= run_col`).
"""
body_indent: int | None = None
scan_end = len(lines)
for idx in range(body_start, len(lines)):
line = lines[idx]
if line.strip() == "":
continue
indent = len(line) - len(line.lstrip(" "))
if body_indent is None:
if indent > run_col:
body_indent = indent
else:
scan_end = idx
break
elif indent < body_indent:
scan_end = idx
break
if body_indent is not None:
while scan_end > body_start and lines[scan_end - 1].strip() == "":
scan_end -= 1
if scan_end <= body_start:
body_indent = None
return body_indent, scan_end
def find_run_blocks(lines: list[str]) -> list[RunItem]:
"""Return run items in document order."""
items: list[RunItem] = []
line_idx = 0
while line_idx < len(lines):
line = lines[line_idx]
if block_match := RUN_BLOCK_RE.match(line):
run_col = len(block_match.group("prefix"))
body_start = line_idx + 1
body_indent, scan_end = _scan_block_body(lines, body_start, run_col)
if body_indent is not None:
items.append(
BlockRun(
body_start=body_start,
body_end=scan_end,
body_indent=body_indent,
)
)
line_idx = scan_end
continue
if inline_match := RUN_INLINE_RE.match(line):
items.append(
InlineRun(
line_idx=line_idx,
prefix=inline_match.group("prefix"),
value=inline_match.group("value"),
)
)
line_idx += 1
return items
def find_md_bash_blocks(lines: list[str]) -> list[MdBashBlock]:
"""Return ``` ```bash ``` fenced code blocks in document order."""
blocks: list[MdBashBlock] = []
line_idx = 0
while line_idx < len(lines):
open_match = MD_BASH_OPEN_RE.match(lines[line_idx])
if not open_match:
line_idx += 1
continue
body_start = line_idx + 1
close_idx = next(
(
j
for j in range(body_start, len(lines))
if MD_FENCE_CLOSE_RE.match(lines[j])
),
None,
)
if close_idx is None:
line_idx = body_start
continue
body = lines[body_start:close_idx]
non_blank = [b for b in body if b.strip()]
body_indent = (
min(len(b) - len(b.lstrip(" ")) for b in non_blank)
if non_blank
else len(open_match.group("indent"))
)
blocks.append(
MdBashBlock(
open_line_idx=line_idx,
body_start=body_start,
body_end=close_idx,
body_indent=body_indent,
)
)
line_idx = close_idx + 1
return blocks
def dedent(lines: list[str], n: int) -> list[str]:
pad = " " * n
return [
(
""
if line.strip() == ""
else (line[n:] if line.startswith(pad) else line.lstrip(" "))
)
for line in lines
]
def reindent(lines: list[str], n: int) -> list[str]:
pad = " " * n
return [pad + line if line else "" for line in lines]
_SHFMT_ERR_RE = re.compile(r"\.sh:\d+:\d+:\s")
_GHA_EXPR_RE = re.compile(r"\$\{\{.*?\}\}", re.DOTALL)
_GHA_PLACEHOLDER_RE = re.compile(r"__GHA_EXPR_(\d+)__")
def _encode_gha_exprs(text: str) -> tuple[str, list[str]]:
"""Replace `${{ ... }}` expressions with bash-safe placeholder identifiers."""
exprs: list[str] = []
def repl(match: re.Match[str]) -> str:
exprs.append(match.group(0))
return f"__GHA_EXPR_{len(exprs) - 1}__"
return _GHA_EXPR_RE.sub(repl, text), exprs
def _decode_gha_exprs(text: str, exprs: list[str]) -> str:
"""Restore `${{ ... }}` expressions from placeholder identifiers."""
return _GHA_PLACEHOLDER_RE.sub(lambda m: exprs[int(m.group(1))], text)
def shfmt_via_hook(tmp_path: Path) -> tuple[bool, str]:
# `${{ ... }}` is not valid shell, so swap it for a placeholder identifier
# that shfmt can parse, then restore it after formatting.
encoded, exprs = _encode_gha_exprs(tmp_path.read_text())
if exprs:
tmp_path.write_text(encoded)
res = subprocess.run(
[_HOOK_RUNNER, "run", "shfmt", "--files", str(tmp_path)],
cwd=REPO,
capture_output=True,
text=True,
)
output = res.stdout + res.stderr
# shfmt emits parse errors as "<path>:<line>:<col>: <message>".
parse_err = bool(_SHFMT_ERR_RE.search(output))
# A non-zero exit that is neither a parse error nor pre-commit's "I had
# to modify files" signal means the hook itself failed to run (missing
# binary, install failure, bad config, ...). Surface that loudly rather
# than silently treating it as a no-op.
if (
res.returncode != 0
and not parse_err
and "files were modified by this hook" not in output
):
sys.exit(
f"error: `{_HOOK_RUNNER} run shfmt` failed with exit {res.returncode}:\n{output}"
)
if exprs and not parse_err:
tmp_path.write_text(_decode_gha_exprs(tmp_path.read_text(), exprs))
return not parse_err, output
def _skip(path: Path, where: int, kind: str, output: str) -> None:
print(
f" shfmt could not parse {kind} at {path}:{where + 1} — skipped",
file=sys.stderr,
)
print(f" {output.strip()}", file=sys.stderr)
def process_yaml_file(path: Path, tmp_path: Path) -> int:
text = path.read_text()
had_nl = text.endswith("\n")
lines = text.split("\n")
if had_nl:
lines = lines[:-1]
items = find_run_blocks(lines)
if not items:
return 0
changed = 0
# Process in reverse so earlier indices remain valid as we splice.
for item in reversed(items):
if isinstance(item, BlockRun):
body = lines[item.body_start : item.body_end]
tmp_path.write_text("\n".join(dedent(body, item.body_indent)) + "\n")
ok, output = shfmt_via_hook(tmp_path)
if not ok:
_skip(path, item.body_start, "block", output)
continue
formatted = tmp_path.read_text().rstrip("\n")
new_body = reindent(formatted.split("\n"), item.body_indent)
if new_body != body:
lines[item.body_start : item.body_end] = new_body
changed += 1
else:
tmp_path.write_text(item.value + "\n")
ok, output = shfmt_via_hook(tmp_path)
if not ok:
_skip(path, item.line_idx, "inline run", output)
continue
formatted = tmp_path.read_text().rstrip("\n")
if formatted == item.value:
continue
formatted_lines = formatted.split("\n")
if len(formatted_lines) == 1:
lines[item.line_idx] = f"{item.prefix}run: {formatted}"
else:
body_indent = len(item.prefix) + 2
lines[item.line_idx : item.line_idx + 1] = [
f"{item.prefix}run: |",
*reindent(formatted_lines, body_indent),
]
changed += 1
new_text = "\n".join(lines) + ("\n" if had_nl else "")
if new_text != text:
path.write_text(new_text)
return changed
def process_md_file(path: Path, tmp_path: Path) -> int:
text = path.read_text()
had_nl = text.endswith("\n")
lines = text.split("\n")
if had_nl:
lines = lines[:-1]
blocks = find_md_bash_blocks(lines)
if not blocks:
return 0
changed = 0
for block in reversed(blocks):
body = lines[block.body_start : block.body_end]
tmp_path.write_text("\n".join(dedent(body, block.body_indent)) + "\n")
ok, output = shfmt_via_hook(tmp_path)
if not ok:
_skip(path, block.open_line_idx, "```bash block", output)
continue
formatted = tmp_path.read_text().rstrip("\n")
formatted_lines = formatted.split("\n") if formatted else []
new_body = reindent(formatted_lines, block.body_indent)
if new_body != body:
lines[block.body_start : block.body_end] = new_body
changed += 1
new_text = "\n".join(lines) + ("\n" if had_nl else "")
if new_text != text:
path.write_text(new_text)
return changed
def process_file(path: Path, tmp_path: Path) -> int:
if path.suffix in (".yml", ".yaml"):
return process_yaml_file(path, tmp_path)
if path.suffix == ".md":
return process_md_file(path, tmp_path)
return 0
def gather_files(argv: list[str]) -> list[Path]:
"""Return YAML workflow/action files and markdown files that we should
process — either the paths in `argv` or, when `argv` is empty, every
such file in the repo (skipping `external/`)."""
if argv:
candidates: list[Path] = [
(REPO / a).resolve() if not Path(a).is_absolute() else Path(a) for a in argv
]
else:
gh = REPO / ".github"
candidates = [
*gh.rglob("*.yml"),
*gh.rglob("*.yaml"),
*(
p
for p in REPO.rglob("*.md")
if "external" not in p.relative_to(REPO).parts
),
]
return sorted(
p
for p in candidates
if p.exists()
and (
(p.suffix in (".yml", ".yaml") and ".github" in p.parts)
or p.suffix == ".md"
)
)
def main(argv: list[str]) -> int:
files = gather_files(argv)
if not files:
return 0
with tempfile.TemporaryDirectory(prefix="format-inline-bash-") as tmpdir:
tmp_path = Path(tmpdir) / "shfmt.sh"
total = 0
for f in files:
n = process_file(f, tmp_path)
if n:
print(f"{f.relative_to(REPO)}: reformatted {n} block(s)")
total += n
return 1 if total else 0
if __name__ == "__main__":
sys.exit(main(sys.argv[1:]))

View File

@@ -1,134 +0,0 @@
# Levelization
Levelization is the term used to describe efforts to prevent xrpld from
having or creating cyclic dependencies.
xrpld code is organized into directories under `src/xrpld`, `src/libxrpl` (and
`src/test`) representing modules. The modules are intended to be
organized into "tiers" or "levels" such that a module from one level can
only include code from lower levels. Additionally, a module
in one level should never include code in an `impl` or `detail` folder of any level
other than its own.
The codebase is split into two main areas:
- **libxrpl** (`src/libxrpl`, `include/xrpl`): Reusable library modules with public interfaces
- **xrpld** (`src/xrpld`): Application-specific implementation code
Unfortunately, over time, enforcement of levelization has been
inconsistent, so the current state of the code doesn't necessarily
reflect these rules. Whenever possible, developers should refactor any
levelization violations they find (by moving files or individual
classes). At the very least, don't make things worse.
The table below summarizes the _desired_ division of modules, based on the current
state of the xrpld code. The levels are numbered from
the bottom up with the lower level, lower numbered, more independent
modules listed first, and the higher level, higher numbered modules with
more dependencies listed later.
**tl;dr:** The modules listed first are more independent than the modules
listed later.
## libxrpl Modules (Reusable Libraries)
| Level / Tier | Module(s) |
| ------------ | ----------------------------------- |
| 01 | xrpl/beast |
| 02 | xrpl/basics |
| 03 | xrpl/json xrpl/crypto |
| 04 | xrpl/protocol |
| 05 | xrpl/core xrpl/resource xrpl/server |
| 06 | xrpl/ledger xrpl/nodestore xrpl/net |
| 07 | xrpl/shamap |
## xrpld Modules (Application Implementation)
| Level / Tier | Module(s) |
| ------------ | -------------------------------- |
| 05 | xrpld/conditions xrpld/consensus |
| 06 | xrpld/core xrpld/peerfinder |
| 07 | xrpld/shamap xrpld/overlay |
| 08 | xrpld/app |
| 09 | xrpld/rpc |
| 10 | xrpld/perflog |
## Test Modules
| Level / Tier | Module(s) |
| ------------ | -------------------------------------------------------------------------------------------------------- |
| 11 | test/jtx test/beast test/csf |
| 12 | test/unit_test |
| 13 | test/crypto test/conditions test/json test/resource test/shamap test/peerfinder test/basics test/overlay |
| 14 | test |
| 15 | test/net test/protocol test/ledger test/consensus test/core test/server test/nodestore |
| 16 | test/rpc test/app |
(Note that `test` levelization is _much_ less important and _much_ less
strictly enforced than `xrpl`/`xrpld` levelization, other than the requirement
that `test` code should _never_ be included in `xrpl` or `xrpld` code.)
## Validation
The [levelization](generate.py) script takes no parameters,
reads no environment variables, and can be run from any directory,
as long as it is in the expected location in the xrpld repo.
It can be run at any time from within a checked out repo, and will
do an analysis of all the `#include`s in
the xrpld source. The only caveat is that it runs much slower
under Windows than in Linux. It hasn't yet been tested under MacOS.
It generates many files of [results](results):
- `rawincludes.txt`: The raw dump of the `#includes`
- `paths.txt`: A second dump grouping the source module
to the destination module, de-duped, and with frequency counts.
- `includes/`: A directory where each file represents a module and
contains a list of modules and counts that the module _includes_.
- `included_by/`: Similar to `includes/`, but the other way around. Each
file represents a module and contains a list of modules and counts
that _include_ the module.
- [`loops.txt`](results/loops.txt): A list of direct loops detected
between modules as they actually exist, as opposed to how they are
desired as described above. In a perfect repo, this file will be
empty.
This file is committed to the repo, and is used by the [levelization
Github workflow](../../workflows/reusable-check-levelization.yml) to validate
that nothing changed.
- [`ordering.txt`](results/ordering.txt): A list showing relationships
between modules where there are no loops as they actually exist, as
opposed to how they are desired as described above.
This file is committed to the repo, and is used by the [levelization
Github workflow](../../workflows/reusable-check-levelization.yml) to validate
that nothing changed.
- [`levelization.yml`](../../workflows/reusable-check-levelization.yml)
Github Actions workflow to test that levelization loops haven't
changed. Unfortunately, if changes are detected, it can't tell if
they are improvements or not, so if you have resolved any issues or
done anything else to improve levelization, run `generate.py`,
and commit the updated results.
The `loops.txt` and `ordering.txt` files relate the modules
using comparison signs, which indicate the number of times each
module is included in the other.
- `A > B` means that A should probably be at a higher level than B,
because B is included in A significantly more than A is included in B.
These results can be included in both `loops.txt` and `ordering.txt`.
Because `ordering.txt`only includes relationships where B is not
included in A at all, it will only include these types of results.
- `A ~= B` means that A and B are included in each other a different
number of times, but the values are so close that the script can't
definitively say that one should be above the other. These results
will only be included in `loops.txt`.
- `A == B` means that A and B include each other the same number of
times, so the script has no clue which should be higher. These results
will only be included in `loops.txt`.
The committed files hide the detailed values intentionally, to
prevent false alarms and merging issues, and because it's easy to
get those details locally.
1. Run `generate.py`
2. Grep the modules in `paths.txt`.
- For example, if a cycle is found `A ~= B`, simply `grep -w
A .github/scripts/levelization/results/paths.txt | grep -w B`

View File

@@ -1,335 +0,0 @@
#!/usr/bin/env python3
"""
Usage: generate.py
This script takes no parameters, and can be called from any directory in the file system.
"""
import os
import re
import subprocess
import sys
from collections import defaultdict
from pathlib import Path
from typing import Dict, List, Tuple, Set, Optional
# Compile regex patterns once at module level
INCLUDE_PATTERN = re.compile(r"^\s*#include.*/.*\.h")
INCLUDE_PATH_PATTERN = re.compile(r'[<"]([^>"]+)[>"]')
def dictionary_sort_key(s: str) -> str:
"""
Create a sort key that mimics 'sort -d' (dictionary order).
Dictionary order only considers blanks and alphanumeric characters.
This means punctuation like '.' is ignored during sorting.
"""
# Keep only alphanumeric characters and spaces
return "".join(c for c in s if c.isalnum() or c.isspace())
def get_level(file_path: str) -> str:
"""
Extract the level from a file path (second and third directory components).
Equivalent to bash: cut -d/ -f 2,3
Examples:
src/xrpld/app/main.cpp -> xrpld.app
src/libxrpl/protocol/STObject.cpp -> libxrpl.protocol
include/xrpl/basics/base_uint.h -> xrpl.basics
"""
parts = file_path.split("/")
# Get fields 2 and 3 (indices 1 and 2 in 0-based indexing)
if len(parts) >= 3:
level = f"{parts[1]}/{parts[2]}"
elif len(parts) >= 2:
level = f"{parts[1]}/toplevel"
else:
level = file_path
# If the "level" indicates a file, cut off the filename
if "." in level.split("/")[-1]: # Avoid Path object creation
# Use the "toplevel" label as a workaround for `sort`
# inconsistencies between different utility versions
level = level.rsplit("/", 1)[0] + "/toplevel"
return level.replace("/", ".")
def extract_include_level(include_line: str) -> Optional[str]:
"""
Extract the include path from an #include directive.
Gets the first two directory components from the include path.
Equivalent to bash: cut -d/ -f 1,2
Examples:
#include <xrpl/basics/base_uint.h> -> xrpl.basics
#include "xrpld/app/main/Application.h" -> xrpld.app
"""
# Remove everything before the quote or angle bracket
match = INCLUDE_PATH_PATTERN.search(include_line)
if not match:
return None
include_path = match.group(1)
parts = include_path.split("/")
# Get first two fields (indices 0 and 1)
if len(parts) >= 2:
include_level = f"{parts[0]}/{parts[1]}"
else:
include_level = include_path
# If the "includelevel" indicates a file, cut off the filename
if "." in include_level.split("/")[-1]: # Avoid Path object creation
include_level = include_level.rsplit("/", 1)[0] + "/toplevel"
return include_level.replace("/", ".")
def find_repository_directories(
start_path: Path, depth_limit: int = 10
) -> Tuple[Path, List[Path]]:
"""
Find the repository root by looking for src or include folders.
Walks up the directory tree from the start path.
"""
current = start_path.resolve()
# Walk up the directory tree
for _ in range(depth_limit): # Limit search depth to prevent infinite loops
src_path = current / "src"
include_path = current / "include"
# Check if this directory has src or include folders
has_src = src_path.exists()
has_include = include_path.exists()
if has_src or has_include:
return current, [src_path, include_path]
# Move up one level
parent = current.parent
if parent == current: # Reached filesystem root
break
current = parent
# If we couldn't find it, raise an error
raise RuntimeError(
"Could not find repository root. "
"Expected to find a directory containing 'src' and/or 'include' folders."
)
def main():
# Change to the script's directory
script_dir = Path(__file__).parent.resolve()
os.chdir(script_dir)
# Clean up and create results directory.
results_dir = script_dir / "results"
if results_dir.exists():
import shutil
shutil.rmtree(results_dir)
results_dir.mkdir()
# Find the repository root by searching for src and include directories.
try:
repo_root, scan_dirs = find_repository_directories(script_dir)
print(f"Found repository root: {repo_root}")
print(f"Scanning directories:")
for scan_dir in scan_dirs:
print(f" - {scan_dir.relative_to(repo_root)}")
except RuntimeError as e:
print(f"Error: {e}", file=sys.stderr)
sys.exit(1)
print("\nScanning for raw includes...")
# Find all #include directives
raw_includes: List[Tuple[str, str]] = []
rawincludes_file = results_dir / "rawincludes.txt"
# Write to file as we go to avoid storing everything in memory.
with open(rawincludes_file, "w", buffering=8192) as raw_f:
for dir_path in scan_dirs:
print(f" Scanning {dir_path.relative_to(repo_root)}...")
for file_path in dir_path.rglob("*"):
if not file_path.is_file():
continue
try:
rel_path_str = str(file_path.relative_to(repo_root))
# Read file with a large buffer for performance.
with open(
file_path,
"r",
encoding="utf-8",
errors="ignore",
buffering=8192,
) as f:
for line in f:
# Quick check before regex
if "#include" not in line or "boost" in line:
continue
if INCLUDE_PATTERN.match(line):
line_stripped = line.strip()
entry = f"{rel_path_str}:{line_stripped}\n"
print(entry, end="")
raw_f.write(entry)
raw_includes.append((rel_path_str, line_stripped))
except Exception as e:
print(f"Error reading {file_path}: {e}", file=sys.stderr)
# Build levelization paths and count directly (no need to sort first).
print("Build levelization paths")
path_counts: Dict[Tuple[str, str], int] = defaultdict(int)
for file_path, include_line in raw_includes:
include_level = extract_include_level(include_line)
if not include_level:
continue
level = get_level(file_path)
if level != include_level:
path_counts[(level, include_level)] += 1
# Sort and deduplicate paths (using dictionary order like bash 'sort -d').
print("Sort and deduplicate paths")
paths_file = results_dir / "paths.txt"
with open(paths_file, "w") as f:
# Sort using dictionary order: only alphanumeric and spaces matter
sorted_items = sorted(
path_counts.items(),
key=lambda x: (dictionary_sort_key(x[0][0]), dictionary_sort_key(x[0][1])),
)
for (level, include_level), count in sorted_items:
line = f"{count:7} {level} {include_level}\n"
print(line.rstrip())
f.write(line)
# Split into flat-file database
print("Split into flat-file database")
includes_dir = results_dir / "includes"
included_by_dir = results_dir / "included_by"
includes_dir.mkdir()
included_by_dir.mkdir()
# Batch writes by grouping data first to avoid repeated file opens.
includes_data: Dict[str, List[Tuple[str, int]]] = defaultdict(list)
included_by_data: Dict[str, List[Tuple[str, int]]] = defaultdict(list)
# Process in sorted order to match bash script behaviour (dictionary order).
sorted_items = sorted(
path_counts.items(),
key=lambda x: (dictionary_sort_key(x[0][0]), dictionary_sort_key(x[0][1])),
)
for (level, include_level), count in sorted_items:
includes_data[level].append((include_level, count))
included_by_data[include_level].append((level, count))
# Write all includes files in sorted order (dictionary order).
for level in sorted(includes_data.keys(), key=dictionary_sort_key):
entries = includes_data[level]
with open(includes_dir / level, "w") as f:
for include_level, count in entries:
line = f"{include_level} {count}\n"
print(line.rstrip())
f.write(line)
# Write all included_by files in sorted order (dictionary order).
for include_level in sorted(included_by_data.keys(), key=dictionary_sort_key):
entries = included_by_data[include_level]
with open(included_by_dir / include_level, "w") as f:
for level, count in entries:
line = f"{level} {count}\n"
print(line.rstrip())
f.write(line)
# Search for loops
print("Search for loops")
loops_file = results_dir / "loops.txt"
ordering_file = results_dir / "ordering.txt"
loops_found: Set[Tuple[str, str]] = set()
# Pre-load all include files into memory to avoid repeated I/O.
# This is the biggest optimisation - we were reading files repeatedly in nested loops.
# Use list of tuples to preserve file order.
includes_cache: Dict[str, List[Tuple[str, int]]] = {}
includes_lookup: Dict[str, Dict[str, int]] = {} # For fast lookup
# Note: bash script uses 'for source in *' which uses standard glob sorting,
# NOT dictionary order. So we use standard sorted() here, not dictionary_sort_key.
for include_file in sorted(includes_dir.iterdir(), key=lambda p: p.name):
if not include_file.is_file():
continue
includes_cache[include_file.name] = []
includes_lookup[include_file.name] = {}
with open(include_file, "r") as f:
for line in f:
parts = line.strip().split()
if len(parts) >= 2:
include_name = parts[0]
include_count = int(parts[1])
includes_cache[include_file.name].append(
(include_name, include_count)
)
includes_lookup[include_file.name][include_name] = include_count
with open(loops_file, "w", buffering=8192) as loops_f, open(
ordering_file, "w", buffering=8192
) as ordering_f:
# Use standard sorting to match bash glob expansion 'for source in *'.
for source in sorted(includes_cache.keys()):
source_includes = includes_cache[source]
for include, include_freq in source_includes:
# Check if include file exists and references source
if include not in includes_lookup:
continue
source_freq = includes_lookup[include].get(source)
if source_freq is not None:
# Found a loop
loop_key = tuple(sorted([source, include]))
if loop_key in loops_found:
continue
loops_found.add(loop_key)
loops_f.write(f"Loop: {source} {include}\n")
# If the counts are close, indicate that the two modules are
# on the same level, though they shouldn't be.
diff = include_freq - source_freq
if diff > 3:
loops_f.write(f" {source} > {include}\n\n")
elif diff < -3:
loops_f.write(f" {include} > {source}\n\n")
elif source_freq == include_freq:
loops_f.write(f" {include} == {source}\n\n")
else:
loops_f.write(f" {include} ~= {source}\n\n")
else:
ordering_f.write(f"{source} > {include}\n")
# Print results
print("\nOrdering:")
with open(ordering_file, "r") as f:
print(f.read(), end="")
print("\nLoops:")
with open(loops_file, "r") as f:
print(f.read(), end="")
if __name__ == "__main__":
main()

View File

@@ -1,21 +0,0 @@
Loop: xrpl.telemetry xrpld.rpc
xrpld.rpc > xrpl.telemetry
Loop: xrpld.app xrpld.overlay
xrpld.app > xrpld.overlay
Loop: xrpld.app xrpld.peerfinder
xrpld.peerfinder ~= xrpld.app
Loop: xrpld.app xrpld.rpc
xrpld.rpc > xrpld.app
Loop: xrpld.app xrpld.shamap
xrpld.shamap > xrpld.app
Loop: xrpld.overlay xrpld.rpc
xrpld.rpc ~= xrpld.overlay
Loop: xrpld.overlay xrpld.telemetry
xrpld.telemetry ~= xrpld.overlay

View File

@@ -1,346 +0,0 @@
libxrpl.basics > xrpl.basics
libxrpl.conditions > xrpl.basics
libxrpl.conditions > xrpl.conditions
libxrpl.config > xrpl.basics
libxrpl.config > xrpl.config
libxrpl.core > xrpl.basics
libxrpl.core > xrpl.core
libxrpl.core > xrpl.json
libxrpl.crypto > xrpl.basics
libxrpl.json > xrpl.basics
libxrpl.json > xrpl.json
libxrpl.ledger > xrpl.basics
libxrpl.ledger > xrpl.json
libxrpl.ledger > xrpl.ledger
libxrpl.ledger > xrpl.nodestore
libxrpl.ledger > xrpl.protocol
libxrpl.ledger > xrpl.shamap
libxrpl.net > xrpl.basics
libxrpl.net > xrpl.net
libxrpl.nodestore > xrpl.basics
libxrpl.nodestore > xrpl.config
libxrpl.nodestore > xrpl.json
libxrpl.nodestore > xrpl.nodestore
libxrpl.nodestore > xrpl.protocol
libxrpl.protocol > xrpl.basics
libxrpl.protocol > xrpl.json
libxrpl.protocol > xrpl.protocol
libxrpl.rdb > xrpl.basics
libxrpl.rdb > xrpl.config
libxrpl.rdb > xrpl.core
libxrpl.rdb > xrpl.rdb
libxrpl.resource > xrpl.basics
libxrpl.resource > xrpl.json
libxrpl.resource > xrpl.protocol
libxrpl.resource > xrpl.resource
libxrpl.server > xrpl.basics
libxrpl.server > xrpl.config
libxrpl.server > xrpl.core
libxrpl.server > xrpl.json
libxrpl.server > xrpl.protocol
libxrpl.server > xrpl.rdb
libxrpl.server > xrpl.resource
libxrpl.server > xrpl.server
libxrpl.shamap > xrpl.basics
libxrpl.shamap > xrpl.nodestore
libxrpl.shamap > xrpl.protocol
libxrpl.shamap > xrpl.shamap
libxrpl.telemetry > xrpl.basics
libxrpl.telemetry > xrpl.config
libxrpl.telemetry > xrpl.protocol
libxrpl.telemetry > xrpl.telemetry
libxrpl.tx > xrpl.basics
libxrpl.tx > xrpl.conditions
libxrpl.tx > xrpl.core
libxrpl.tx > xrpl.json
libxrpl.tx > xrpl.ledger
libxrpl.tx > xrpl.protocol
libxrpl.tx > xrpl.server
libxrpl.tx > xrpl.telemetry
libxrpl.tx > xrpl.tx
test.app > test.jtx
test.app > test.unit_test
test.app > xrpl.basics
test.app > xrpl.config
test.app > xrpl.core
test.app > xrpld.app
test.app > xrpld.consensus
test.app > xrpld.core
test.app > xrpld.overlay
test.app > xrpld.rpc
test.app > xrpl.json
test.app > xrpl.ledger
test.app > xrpl.nodestore
test.app > xrpl.protocol
test.app > xrpl.resource
test.app > xrpl.server
test.app > xrpl.shamap
test.app > xrpl.tx
test.basics > test.jtx
test.basics > test.unit_test
test.basics > xrpl.basics
test.basics > xrpl.core
test.basics > xrpld.rpc
test.basics > xrpl.json
test.basics > xrpl.protocol
test.beast > xrpl.basics
test.conditions > xrpl.basics
test.conditions > xrpl.conditions
test.consensus > test.csf
test.consensus > test.jtx
test.consensus > test.unit_test
test.consensus > xrpl.basics
test.consensus > xrpld.app
test.consensus > xrpld.consensus
test.consensus > xrpl.ledger
test.consensus > xrpl.protocol
test.consensus > xrpl.shamap
test.consensus > xrpl.tx
test.core > test.jtx
test.core > test.unit_test
test.core > xrpl.basics
test.core > xrpl.config
test.core > xrpl.core
test.core > xrpld.core
test.core > xrpl.json
test.core > xrpl.protocol
test.core > xrpl.rdb
test.core > xrpl.server
test.csf > xrpl.basics
test.csf > xrpld.consensus
test.csf > xrpl.json
test.csf > xrpl.ledger
test.csf > xrpl.telemetry
test.json > test.jtx
test.json > xrpl.json
test.jtx > test.unit_test
test.jtx > xrpl.basics
test.jtx > xrpl.config
test.jtx > xrpl.core
test.jtx > xrpld.app
test.jtx > xrpld.core
test.jtx > xrpld.rpc
test.jtx > xrpl.json
test.jtx > xrpl.ledger
test.jtx > xrpl.net
test.jtx > xrpl.protocol
test.jtx > xrpl.resource
test.jtx > xrpl.server
test.jtx > xrpl.tx
test.ledger > test.jtx
test.ledger > xrpl.basics
test.ledger > xrpl.core
test.ledger > xrpld.app
test.ledger > xrpld.core
test.ledger > xrpl.json
test.ledger > xrpl.ledger
test.ledger > xrpl.protocol
test.nodestore > test.jtx
test.nodestore > test.unit_test
test.nodestore > xrpl.basics
test.nodestore > xrpl.config
test.nodestore > xrpld.core
test.nodestore > xrpl.nodestore
test.nodestore > xrpl.protocol
test.nodestore > xrpl.rdb
test.overlay > test.jtx
test.overlay > test.unit_test
test.overlay > xrpl.basics
test.overlay > xrpl.config
test.overlay > xrpld.app
test.overlay > xrpld.core
test.overlay > xrpld.overlay
test.overlay > xrpld.peerfinder
test.overlay > xrpl.json
test.overlay > xrpl.nodestore
test.overlay > xrpl.protocol
test.overlay > xrpl.resource
test.overlay > xrpl.server
test.overlay > xrpl.shamap
test.peerfinder > test.beast
test.peerfinder > test.unit_test
test.peerfinder > xrpl.basics
test.peerfinder > xrpld.core
test.peerfinder > xrpld.peerfinder
test.peerfinder > xrpl.protocol
test.protocol > test.jtx
test.protocol > test.unit_test
test.protocol > xrpl.basics
test.protocol > xrpl.json
test.protocol > xrpl.protocol
test.resource > test.unit_test
test.resource > xrpl.basics
test.resource > xrpl.resource
test.rpc > test.jtx
test.rpc > xrpl.basics
test.rpc > xrpl.config
test.rpc > xrpl.core
test.rpc > xrpld.app
test.rpc > xrpld.core
test.rpc > xrpld.overlay
test.rpc > xrpld.rpc
test.rpc > xrpl.json
test.rpc > xrpl.ledger
test.rpc > xrpl.protocol
test.rpc > xrpl.resource
test.rpc > xrpl.server
test.rpc > xrpl.tx
test.server > test.jtx
test.server > test.unit_test
test.server > xrpl.basics
test.server > xrpl.config
test.server > xrpld.app
test.server > xrpld.core
test.server > xrpl.json
test.server > xrpl.protocol
test.server > xrpl.server
test.shamap > test.unit_test
test.shamap > xrpl.basics
test.shamap > xrpl.config
test.shamap > xrpl.nodestore
test.shamap > xrpl.protocol
test.shamap > xrpl.shamap
test.unit_test > xrpl.basics
test.unit_test > xrpl.protocol
tests.libxrpl > xrpl.basics
tests.libxrpl > xrpl.config
tests.libxrpl > xrpl.core
tests.libxrpl > xrpld.telemetry
tests.libxrpl > xrpl.json
tests.libxrpl > xrpl.ledger
tests.libxrpl > xrpl.net
tests.libxrpl > xrpl.nodestore
tests.libxrpl > xrpl.protocol
tests.libxrpl > xrpl.protocol_autogen
tests.libxrpl > xrpl.server
tests.libxrpl > xrpl.shamap
tests.libxrpl > xrpl.telemetry
tests.libxrpl > xrpl.tx
xrpl.conditions > xrpl.basics
xrpl.conditions > xrpl.protocol
xrpl.config > xrpl.basics
xrpl.core > xrpl.basics
xrpl.core > xrpl.json
xrpl.core > xrpl.protocol
xrpl.json > xrpl.basics
xrpl.ledger > xrpl.basics
xrpl.ledger > xrpl.json
xrpl.ledger > xrpl.nodestore
xrpl.ledger > xrpl.protocol
xrpl.ledger > xrpl.shamap
xrpl.net > xrpl.basics
xrpl.nodestore > xrpl.basics
xrpl.nodestore > xrpl.config
xrpl.nodestore > xrpl.json
xrpl.nodestore > xrpl.protocol
xrpl.protocol > xrpl.basics
xrpl.protocol > xrpl.json
xrpl.protocol_autogen > xrpl.json
xrpl.protocol_autogen > xrpl.protocol
xrpl.rdb > xrpl.basics
xrpl.rdb > xrpl.core
xrpl.rdb > xrpl.protocol
xrpl.resource > xrpl.basics
xrpl.resource > xrpl.json
xrpl.resource > xrpl.protocol
xrpl.server > xrpl.basics
xrpl.server > xrpl.core
xrpl.server > xrpl.json
xrpl.server > xrpl.protocol
xrpl.server > xrpl.rdb
xrpl.server > xrpl.resource
xrpl.shamap > xrpl.basics
xrpl.shamap > xrpl.nodestore
xrpl.shamap > xrpl.protocol
xrpl.telemetry > xrpl.config
xrpl.tx > xrpl.basics
xrpl.tx > xrpl.core
xrpl.tx > xrpl.ledger
xrpl.tx > xrpl.protocol
xrpl.tx > xrpl.telemetry
xrpld.app > test.unit_test
xrpld.app > xrpl.basics
xrpld.app > xrpl.config
xrpld.app > xrpl.core
xrpld.app > xrpld.consensus
xrpld.app > xrpld.core
xrpld.app > xrpld.telemetry
xrpld.app > xrpl.json
xrpld.app > xrpl.ledger
xrpld.app > xrpl.net
xrpld.app > xrpl.nodestore
xrpld.app > xrpl.protocol
xrpld.app > xrpl.rdb
xrpld.app > xrpl.resource
xrpld.app > xrpl.server
xrpld.app > xrpl.shamap
xrpld.app > xrpl.telemetry
xrpld.app > xrpl.tx
xrpld.consensus > xrpl.basics
xrpld.consensus > xrpl.json
xrpld.consensus > xrpl.ledger
xrpld.consensus > xrpl.protocol
xrpld.consensus > xrpl.telemetry
xrpld.core > xrpl.basics
xrpld.core > xrpl.config
xrpld.core > xrpl.core
xrpld.core > xrpl.net
xrpld.core > xrpl.protocol
xrpld.core > xrpl.rdb
xrpld.overlay > xrpl.basics
xrpld.overlay > xrpl.config
xrpld.overlay > xrpl.core
xrpld.overlay > xrpld.consensus
xrpld.overlay > xrpld.core
xrpld.overlay > xrpld.peerfinder
xrpld.overlay > xrpl.json
xrpld.overlay > xrpl.ledger
xrpld.overlay > xrpl.protocol
xrpld.overlay > xrpl.resource
xrpld.overlay > xrpl.server
xrpld.overlay > xrpl.shamap
xrpld.overlay > xrpl.telemetry
xrpld.overlay > xrpl.tx
xrpld.peerfinder > xrpl.basics
xrpld.peerfinder > xrpl.config
xrpld.peerfinder > xrpld.core
xrpld.peerfinder > xrpl.protocol
xrpld.peerfinder > xrpl.rdb
xrpld.perflog > xrpl.basics
xrpld.perflog > xrpl.config
xrpld.perflog > xrpl.core
xrpld.perflog > xrpld.app
xrpld.perflog > xrpld.rpc
xrpld.perflog > xrpld.telemetry
xrpld.perflog > xrpl.json
xrpld.perflog > xrpl.nodestore
xrpld.perflog > xrpl.protocol
xrpld.rpc > xrpl.basics
xrpld.rpc > xrpl.config
xrpld.rpc > xrpl.core
xrpld.rpc > xrpld.core
xrpld.rpc > xrpl.json
xrpld.rpc > xrpl.ledger
xrpld.rpc > xrpl.net
xrpld.rpc > xrpl.nodestore
xrpld.rpc > xrpl.protocol
xrpld.rpc > xrpl.rdb
xrpld.rpc > xrpl.resource
xrpld.rpc > xrpl.server
xrpld.rpc > xrpl.shamap
xrpld.rpc > xrpl.tx
xrpld.shamap > xrpl.basics
xrpld.shamap > xrpld.core
xrpld.shamap > xrpl.nodestore
xrpld.shamap > xrpl.protocol
xrpld.shamap > xrpl.shamap
xrpld.telemetry > xrpl.basics
xrpld.telemetry > xrpl.core
xrpld.telemetry > xrpld.consensus
xrpld.telemetry > xrpld.core
xrpld.telemetry > xrpl.json
xrpld.telemetry > xrpl.nodestore
xrpld.telemetry > xrpl.protocol
xrpld.telemetry > xrpl.rdb
xrpld.telemetry > xrpl.server
xrpld.telemetry > xrpl.telemetry

View File

@@ -1,70 +0,0 @@
# OTel naming-consistency check
`check_otel_naming.py` enforces the OpenTelemetry span-attribute naming
convention documented in
[CONTRIBUTING.md](../../../CONTRIBUTING.md#telemetry-span-attribute-naming)
across every layer of the telemetry pipeline. The `*SpanNames.h` constants are
the single source of truth (L1); every other layer must agree with them.
## Running locally
```
python .github/scripts/otel-naming/check_otel_naming.py
```
It takes no arguments, can be run from any directory inside the repo, and uses
only the Python standard library (no `pip install`, matching the levelization
check). A non-zero exit code means a violation was found; the output lists each
violation as `RULE | location | token | expected`.
## What it checks
The valid key set is **derived dynamically from the OTel code** — there is no
hardcoded allowlist:
- **L1 keys** come from the `namespace attr { ... }` blocks of every
`*SpanNames.h`, resolving the `makeStr("x")` / `join(seg::a, seg::b)` DSL
(cross-file, so `join(seg::rpc, ...)` resolves `seg::rpc` from the base
`SpanNames.h`). Each constant is resolved against **its own** header, so two
headers that define a same-named constant (e.g. a base `attr::ledgerHash` and
a domain `attr::ledgerHash`) each contribute their real wire key — a later
header cannot clobber an earlier one's value in a flat table.
- **Legitimate dotted keys** = ONLY the keys the code actually sets as resource
attributes, i.e. the entries inside `Telemetry.cpp`'s `Resource::Create({...})`
call: the `semconv::service::*` keys (`service.*`) plus any `attr::<name>`
constants passed there (`xrpl.network.*`). A dotted key that is _declared_ in a
header but never set as a resource attr is a span attribute in resource
clothing — a Rule-A violation, even if it lives in the base `SpanNames.h`.
### Rules (each fails the build, when its inputs are present)
| Rule | Check |
| ---- | ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- |
| A | No stray dotted span-attribute key (only the derived resource keys may be dotted). |
| G | Attribute keys are `lower_snake_case` (`^[a-z][a-z0-9_]*$` per dot-segment) — no camelCase, UPPERCASE, or spaces. |
| F | No string literals as attribute keys or span-name arguments in `setAttribute`/`addEvent`/`span`/`childSpan`. Attribute _values_ are exempt (runtime data); `*SpanNames.h` definitions and test files are exempt. |
| B | Every collector `spanmetrics.dimensions` name exists in the L1 key set. |
| C | Every Tempo span-filter tag exists in the L1 key set. |
| D | Every dashboard label resolves to an L1 span attribute, a native-metric label (L6, emitted by MetricsRegistry), or a Prometheus/Grafana builtin. TraceQL scope prefixes (`span.`/`resource.`/…) are stripped before the L1 lookup. |
| E | No dotted `xrpl.<domain>.<field>` attribute key in the runbook (only the L1 resource attrs `xrpl.network.*` may be dotted). Span names, filenames, OTel-standard keys, and metric labels are not flagged. |
Rule F runs **unconditionally** (it is a purely syntactic check on the
call-sites and needs no `*SpanNames.h`), so a code path that calls
`SpanGuard::span`/`setAttribute` directly without ever defining a header is
still caught.
### Warnings (printed, never fail the build)
| Rule | Check |
| ---- | ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------ |
| H | A namespace-qualified constant (e.g. `foo::bar::myKey`) used at a telemetry call-site is not defined in any `*SpanNames.h`. The constant should live in the proper header; defining it in-place bypasses rules A/G/F. Warns rather than fails — the argument may be a legitimately dynamic value, and the header may live on a later branch. Bare locals and `std::` names are not warned. |
## Presence-gated
Every rule runs **only when the source files it needs are present** in the tree
and is otherwise skipped (printed as `SKIP: <rule> — <reason>`), never failed.
This keeps the check correct no matter how telemetry work is split across PRs —
a stacked chain, one large PR, or independent per-stage PRs where (for example)
the collector config lands before the dashboards. The collector/Tempo/dashboard/
runbook layers are introduced in later phases; on a branch without them, only
the L1-intrinsic rules (A, G, F) run.

View File

@@ -1,885 +0,0 @@
#!/usr/bin/env python3
"""
Usage: check_otel_naming.py
This script takes no parameters and can be called from any directory inside the
repository (it locates the repo root via `git rev-parse`).
Enforces the OpenTelemetry span-attribute naming convention documented in
CONTRIBUTING.md ("Telemetry span attribute naming") across every layer of the
telemetry pipeline. The `*SpanNames.h` constants are the single source of truth
(L1); every other layer must agree with them.
Design principles
-----------------
1. No hardcoded allowlist. The set of valid attribute keys — including which
dotted keys are legitimate resource attributes — is derived dynamically by
parsing the repository's own OTel code:
* `*SpanNames.h` `namespace attr { ... }` blocks (the underscore/bare keys
and the `join(seg::..., ...)` dotted resource compositions), and
* the keys the code passes to `Resource::Create({ ... })` in Telemetry.cpp
(the standard `semconv::service::*` keys -> service.name/version/...).
2. Presence-gated enforcement. Every rule runs ONLY when the source files it
needs are present in the tree, and is otherwise skipped (never failed). This
keeps the check correct no matter how work is split across PRs: a stacked
chain, one large PR, or independent per-stage PRs where (for example) the
collector config lands in a different PR than the dashboards. The check never
assumes a file from another phase/PR exists.
Layers
------
L1 code : src/**/*SpanNames.h, include/**/*SpanNames.h (ground truth)
L1 resource : src/libxrpl/telemetry/Telemetry.cpp (dotted allowlist)
L1 callsites : setAttribute/addEvent/span/childSpan in src/**, include/**
L2 collector : docker/telemetry/otel-collector-config.yaml (spanmetrics dims)
L3 tempo : docker/telemetry/tempo.yaml (span filter tags)
L4 dashboards: docker/telemetry/grafana/dashboards/*.json (PromQL labels)
L5 runbook : docs/telemetry-runbook.md (attr tables)
L6 metrics : MetricsRegistry.cpp instrument labels (native-metric
label keys, a valid dashboard-label source besides L1)
Rules (each FAILS the build, when its inputs are present)
---------------------------------------------------------
A No stray dotted span-attribute key. A dotted `<a>.<b>` used as a span
attribute that is not in the derived resource-key set is a violation.
G Attribute keys must be lower_snake_case (^[a-z][a-z0-9_]*$ per segment).
Flags camelCase, UPPERCASE, spaces, and other stray characters.
F No string literals as attribute keys or span-name arguments. The
setAttribute/addEvent key and the span/childSpan prefix/name args must
reference a *SpanNames.h constant, never a "literal". Attribute VALUES are
exempt (runtime data). Definitions inside *SpanNames.h are exempt, and
test files are exempt (they pass arbitrary literals to exercise the API).
B Every collector spanmetrics dimension exists in the L1 key set.
C Every tempo span-filter tag exists in the L1 key set.
D Every dashboard label resolves to an L1 span attribute, an L6
native-metric label, or a builtin. TraceQL `span.`/`resource.` scope
prefixes are stripped before the L1 lookup.
E No dotted `xrpl.<domain>.<field>` attribute key in the runbook (only the
L1 resource attrs xrpl.network.* may be dotted). Span names, filenames,
OTel-standard keys, and metric labels are not flagged.
Warnings (printed, but do NOT fail the build)
----------------------------------------------
H A constant referenced at a telemetry call-site is not defined in any
*SpanNames.h. Span constants should live in the corresponding
*SpanNames.h (single source of truth); defining one in-place bypasses the
naming rules. A warning (not a failure) because the argument may instead
be a legitimately dynamic local (e.g. a computed span-name leaf).
Exit code is non-zero if any present-and-enforced rule finds a violation.
Warnings never change the exit code.
"""
import re
import subprocess
import sys
from pathlib import Path
from typing import Dict, List, Optional, Set, Tuple
# ---------------------------------------------------------------------------
# Repo location
# ---------------------------------------------------------------------------
def repo_root() -> Path:
"""Return the repository root, so the script works from any CWD.
Exits with a readable message (not a traceback) if git is unavailable or the
CWD is outside a repository."""
try:
out = subprocess.run(
["git", "rev-parse", "--show-toplevel"],
capture_output=True,
text=True,
check=True,
)
except (subprocess.CalledProcessError, FileNotFoundError):
print(
"error: check_otel_naming.py must be run inside the git repository.",
file=sys.stderr,
)
sys.exit(2)
return Path(out.stdout.strip())
def read_source(path: Path) -> str:
"""Read a file as UTF-8, tolerating stray non-UTF-8 bytes rather than
crashing the whole check on one bad byte."""
return path.read_text(encoding="utf-8", errors="ignore")
# ---------------------------------------------------------------------------
# Regexes (compiled once)
# ---------------------------------------------------------------------------
# A segment/string constant definition: `inline constexpr auto NAME = <expr>;`
CONST_DEF = re.compile(r"inline\s+constexpr\s+auto\s+(\w+)\s*=\s*(.+?);", re.DOTALL)
MAKESTR = re.compile(r'makeStr\(\s*"([^"]*)"\s*\)')
# A `namespace <name> {` opener, to track which namespace a constant lives in.
NS_OPEN = re.compile(r"namespace\s+([\w:]+)\s*\{")
# A `using ::a::b::field;` re-export inside an attr block; captures the leaf.
USING_DECL = re.compile(r"using\s+(?:::)?[\w:]*::(\w+)\s*;")
# Telemetry call-sites whose string arguments must be constants, not literals.
# Require a receiver so we match real SpanGuard calls, not std::span / a math
# `span(...)` / a bare method declaration:
# - `SpanGuard::span(` / `SpanGuard::childSpan(` (static factory)
# - `<obj>.span(` / `<obj>->setAttribute(` etc. (member call)
# `span`/`childSpan` additionally require the `SpanGuard`/`.`/`->` receiver;
# `setAttribute`/`addEvent` only ever exist on a guard, so a `.`/`->` suffices.
CALLSITE = re.compile(
r"(?:SpanGuard::|\.|->)\s*(setAttribute|addEvent|span|childSpan)\s*\("
)
# A C++ string literal (used to flag literals inside call-site argument lists).
STRING_LITERAL = re.compile(r'"((?:[^"\\]|\\.)*)"')
# A C++ line comment (`//` ... end of line) and a block comment (`/* ... */`).
LINE_COMMENT = re.compile(r"//[^\n]*")
BLOCK_COMMENT = re.compile(r"/\*.*?\*/", re.DOTALL)
# A TraceQL scope prefix on a label (`span.`, `resource.`, `event.`, etc.).
# Dashboards reference span attributes in TraceQL as `span.<attr>`; the bare
# attribute is what must exist in L1, so strip the scope before validating.
TRACEQL_SCOPE = re.compile(r"^(?:span|resource|event|link|instrumentation_scope)\.")
# An OTel metric label key as emitted in C++: `Add(.., {{"label", ...}})` /
# `{{"label", value}}` instrument calls in MetricsRegistry.
METRIC_LABEL = re.compile(r'\{\{\s*"([a-z_][a-z0-9_]*)"\s*,')
def strip_comments(text: str) -> str:
"""Remove C/C++ `//` line comments and `/* ... */` block comments.
Used only for L1 attribute-key extraction so that a commented-out or
illustrative `makeStr("...")` inside a `namespace attr` block does not leak
into the authoritative key set. Rule F deliberately does NOT strip comments
— it must still see `@code` doc-comment examples so their call-site
arguments are held to the constant-only convention.
String literals are not specially handled; a `//` or `/*` appearing inside a
string is vanishingly rare in the *SpanNames.h headers and would at worst
drop a constant from L1 (a conservative direction).
"""
text = BLOCK_COMMENT.sub("", text)
text = LINE_COMMENT.sub("", text)
return text
# ---------------------------------------------------------------------------
# L1: parse *SpanNames.h into the authoritative key set
# ---------------------------------------------------------------------------
def find_spanname_headers(root: Path) -> List[Path]:
return sorted(
p
for p in list((root / "src").rglob("*SpanNames.h"))
+ list((root / "include").rglob("*SpanNames.h"))
if p.is_file()
)
def resolve_constants(
text: str, symbols: Optional[Dict[str, str]] = None
) -> Dict[str, str]:
"""Resolve `inline constexpr auto NAME = <makeStr/join expr>` to strings.
Supports the small constexpr DSL used by SpanNames.h:
makeStr("x") -> "x"
join(a, b) -> resolve(a) + "." + resolve(b)
seg::xrpl / attr::foo -> looked up in the symbol table
The optional `symbols` argument seeds (and is updated in place with) the
table, so a global pass over ALL *SpanNames.h headers can resolve
cross-file references such as `join(seg::rpc, ...)` where `seg::rpc` is
defined in the base SpanNames.h. Keys are stored by their bare name
(last `::` component), so `seg::rpc` and `rpc` both resolve.
"""
if symbols is None:
symbols = {}
def resolve_expr(expr: str) -> Optional[str]:
expr = expr.strip()
m = MAKESTR.fullmatch(expr)
if m:
return m.group(1)
if expr.startswith("join(") and expr.endswith(")"):
args = split_top_level_args(expr[len("join(") : -1])
parts = [resolve_expr(a) for a in args]
if any(p is None for p in parts):
return None
return ".".join(p for p in parts if p is not None)
# Bare or qualified symbol reference, e.g. `seg::xrpl` or `networkId`.
key = expr.split("::")[-1]
return symbols.get(key, symbols.get(expr))
# Iterate definitions in source order so earlier symbols are available.
for m in CONST_DEF.finditer(text):
name, expr = m.group(1), m.group(2)
val = resolve_expr(expr)
if val is not None:
symbols[name] = val
return symbols
def build_global_symbols(headers: List[Path]) -> Dict[str, str]:
"""Resolve constants across ALL headers so cross-file `seg::`/`join`
references (e.g. `join(seg::rpc, ...)` in RpcSpanNames.h, where `seg::rpc`
lives in the base SpanNames.h) resolve. Base SpanNames.h is processed
first so its `seg::` segments seed the table."""
symbols: Dict[str, str] = {}
ordered = sorted(headers, key=lambda p: (p.name != "SpanNames.h", str(p)))
# Two passes: the first seeds segments, the second resolves dependents.
# Comments are stripped so a commented-out constant cannot seed the table.
for _ in range(2):
for h in ordered:
resolve_constants(strip_comments(read_source(h)), symbols)
return symbols
def split_top_level_args(s: str) -> List[str]:
"""Split a comma-separated arg list, respecting nested parentheses and
ignoring parens/commas that appear inside a "string literal" (so a value
like `setAttribute(k, ",")` does not get mis-split)."""
args, depth, cur = [], 0, ""
in_str = False
escaped = False
for ch in s:
if in_str:
cur += ch
if escaped:
escaped = False
elif ch == "\\":
escaped = True
elif ch == '"':
in_str = False
continue
if ch == '"':
in_str = True
cur += ch
elif ch == "(":
depth += 1
cur += ch
elif ch == ")":
depth -= 1
cur += ch
elif ch == "," and depth == 0:
args.append(cur)
cur = ""
else:
cur += ch
if cur.strip():
args.append(cur)
return args
def attr_namespace_spans(text: str) -> List[str]:
"""Return the source text of each `namespace attr { ... }` block in `text`.
Brace-matched over the whole (comment-stripped) text, so a definition that
wraps across several physical lines is contained in one span. Nested braces
inside the block are balanced correctly."""
spans: List[str] = []
for opener in NS_OPEN.finditer(text):
if opener.group(1).split("::")[-1] != "attr":
continue
# Walk from the opening brace, balancing nesting to the matching close.
i = opener.end() # one char past the namespace's `{`
depth = 1
start = i
while i < len(text) and depth > 0:
c = text[i]
if c == "{":
depth += 1
elif c == "}":
depth -= 1
i += 1
spans.append(text[start : i - 1])
return spans
def attr_keys_from_header(path: Path, symbols: Dict[str, str]) -> Set[str]:
"""Return the set of attribute-key strings declared in a header's
`namespace attr { ... }` block(s). `symbols` is the global cross-file
table, used ONLY to seed `seg::`/segment references for `join(...)`
resolution — never to look up an attr constant's value.
A constant DEFINED in this header is resolved against this header's OWN
text, so two headers that each define a same-named constant (e.g. the base
`attr::ledgerHash = xrpl.ledger.hash` and consensus
`attr::ledgerHash = ledger_hash`) each report their real wire key. The
global table is keyed by bare name and would otherwise let a later header
clobber an earlier one, erasing the real key from L1 (a Rule-A blind spot).
A `using`-re-export, by contrast, imports a constant defined elsewhere, so
it is resolved against the global table.
Comments are stripped first (a commented constant must not enter L1), and
each attr block is brace-matched over the whole text so multi-line
`inline constexpr auto NAME = join(\\n ...);` definitions are captured."""
text = strip_comments(read_source(path))
# Local table: the global segments/symbols seed cross-file `join` parts,
# then this header's own definitions overwrite any same-named global entry
# so a locally-defined attr resolves to ITS value, not another header's.
local = dict(symbols)
resolve_constants(text, local)
keys: Set[str] = set()
for block in attr_namespace_spans(text):
for md in CONST_DEF.finditer(block):
# Resolve a locally-defined constant against the LOCAL table; this
# captures makeStr("x") and join(seg::y, ...) with the header's own
# value, immune to cross-header bare-name collisions.
val = local.get(md.group(1))
if val is not None:
keys.add(val)
# `using ::ns::attr::field;` re-exports a constant defined in ANOTHER
# header (e.g. PeerSpanNames imports the base ledgerHash). Resolve the
# imported name against the global table.
for um in USING_DECL.finditer(block):
val = symbols.get(um.group(1))
if val is not None:
keys.add(val)
return keys
# ---------------------------------------------------------------------------
# Reporting
# ---------------------------------------------------------------------------
class Report:
def __init__(self) -> None:
self.violations: List[Tuple[str, str, str, str]] = []
self.warnings: List[Tuple[str, str, str, str]] = []
self.skips: List[str] = []
self.checked: List[str] = []
def violation(self, rule: str, loc: str, token: str, expected: str) -> None:
self.violations.append((rule, loc, token, expected))
def warning(self, rule: str, loc: str, token: str, note: str) -> None:
"""A non-fatal finding: printed, but does not fail the build. Used where
the script cannot be certain a finding is wrong (e.g. a constant used at
a call-site that is not defined in any *SpanNames.h — it might be a
misplaced constant, or a legitimately dynamic value)."""
self.warnings.append((rule, loc, token, note))
def skip(self, rule: str, reason: str) -> None:
self.skips.append(f"SKIP: {rule}{reason}")
def ok(self, msg: str) -> None:
self.checked.append(f"OK: {msg}")
def render_and_exit(self) -> None:
for line in self.skips:
print(line)
for line in self.checked:
print(line)
if self.warnings:
print("\nNaming-convention warnings (non-fatal):\n")
print(f" {'RULE':<5} {'LOCATION':<48} {'TOKEN':<28} NOTE")
print(f" {'-' * 5} {'-' * 48} {'-' * 28} {'-' * 30}")
for rule, loc, token, note in self.warnings:
print(f" {rule:<5} {loc:<48} {token:<28} {note}")
if self.violations:
print("\nNaming-convention violations:\n")
print(f" {'RULE':<5} {'LOCATION':<48} {'TOKEN':<28} EXPECTED")
print(f" {'-' * 5} {'-' * 48} {'-' * 28} {'-' * 30}")
for rule, loc, token, expected in self.violations:
print(f" {rule:<5} {loc:<48} {token:<28} {expected}")
print(
"\nSee CONTRIBUTING.md -> 'Telemetry span attribute naming'. "
"The *SpanNames.h constants are the single source of truth."
)
sys.exit(1)
print("\nAll present telemetry naming layers are consistent.")
sys.exit(0)
def main() -> None:
root = repo_root()
report = Report()
# --- Build the L1 ground-truth key set (presence-gated) ----------------
headers = find_spanname_headers(root)
l1_keys: Set[str] = set()
if headers:
symbols = build_global_symbols(headers)
# Map each key to the header(s) that declare it, so Rule A can tell a
# legitimate resource attr (declared in the base SpanNames.h) from a
# stray dotted key declared in a domain header.
keys_by_header: Dict[Path, Set[str]] = {}
for h in headers:
hk = attr_keys_from_header(h, symbols)
keys_by_header[h] = hk
l1_keys |= hk
report.ok(
f"L1: {len(l1_keys)} attribute keys from {len(headers)} "
f"*SpanNames.h header(s)"
)
else:
report.skip("L1", "no *SpanNames.h present (not a naming-relevant tree)")
keys_by_header = {}
# --- Derive the legitimate dotted (resource) keys dynamically ----------
# ONLY the keys actually passed to Resource::Create() in Telemetry.cpp
# (semconv service.* + the attr:: constants set there, e.g. xrpl.network.*).
# A dotted key declared in a header but NOT set as a resource attr is a
# Rule-A violation, not an allowlist entry.
resource_symbols = symbols if headers else {}
dotted_allow = derive_dotted_resource_keys(root, resource_symbols, report)
# --- Rule A: no stray dotted span-attribute keys -----------------------
if l1_keys:
run_rule_a(keys_by_header, dotted_allow, report)
# --- Rule G: keys must be lower_snake_case -----------------------------
if l1_keys:
run_rule_g(keys_by_header, report)
# --- Rule F (+ Rule H): scan telemetry call-sites ----------------------
# Runs UNCONDITIONALLY: Rule F is a purely syntactic check (is this argument
# a literal?) and does not need the L1 key set, so a code path that uses
# SpanGuard::span/setAttribute directly without ever defining a *SpanNames.h
# is still caught. Rule H (warning) additionally flags constant references
# not defined in any *SpanNames.h.
header_symbols = spanname_symbol_names(headers)
run_rule_f(root, report, header_symbols)
# --- Cross-layer rules B/C/D/E (each presence-gated) -------------------
# L6 native-metric labels: span attributes are not the only valid dashboard
# labels — the MetricsRegistry emits OTel metrics whose label keys are an
# additional source of truth. Derive them dynamically (same principle as L1)
# so dashboards may reference them without tripping Rule D.
metric_labels = metric_label_names(root)
run_rule_b_collector(root, l1_keys, report)
run_rule_c_tempo(root, l1_keys, report)
run_rule_d_dashboards(root, l1_keys, metric_labels, report)
run_rule_e_runbook(root, l1_keys, report)
report.render_and_exit()
def resource_create_block(text: str) -> str:
"""Return the text inside the first `Resource::Create({ ... })` argument
list, brace-matched so nested `{key, value}` initializers are contained.
Empty string if the call is absent."""
m = re.search(r"Resource::Create\(\s*\{", text)
if not m:
return ""
i = m.end() # one char past the opening `{`
depth, start = 1, i
while i < len(text) and depth > 0:
c = text[i]
if c == "{":
depth += 1
elif c == "}":
depth -= 1
i += 1
return text[start : i - 1]
def derive_dotted_resource_keys(
root: Path, symbols: Dict[str, str], report: Report
) -> Set[str]:
"""Legitimate dotted keys = ONLY the keys the code actually sets as RESOURCE
attributes, i.e. the entries inside Telemetry.cpp's `Resource::Create({...})`
call: the standard semconv keys (`service.*`) plus any `attr::<name>`
constants passed there (resolved to their wire key via the global symbol
table, e.g. `attr::networkId` -> `xrpl.network.id`).
A dotted key DECLARED in a `*SpanNames.h` header but NOT passed to
Resource::Create() is a span attribute wearing the resource form — a Rule-A
violation, never allowlisted. Deriving the allowlist from the actual
resource call (not from "any dotted key in the base header") is what lets
Rule A catch a stray dotted span attr such as `xrpl.ledger.hash`."""
allow: Set[str] = set()
tele = root / "src" / "libxrpl" / "telemetry" / "Telemetry.cpp"
if not tele.is_file():
report.skip("resource-derive", "Telemetry.cpp not present")
return allow
block = resource_create_block(read_source(tele))
# semconv::<group>::k<CamelKey> -> the dotted OTel-standard key. The
# CamelKey already embeds the group, e.g. service::kServiceInstanceId
# -> service.instance.id. Split the CamelCase name into dotted lowercase
# segments; if it does not lead with the group, prepend the group.
for m in re.finditer(r"semconv::(\w+)::k(\w+)", block):
group, camel = m.group(1), m.group(2)
segments = camel_to_dotsegments(camel)
if segments and segments[0] == group:
allow.add(".".join(segments))
else:
allow.add(group + "." + ".".join(segments))
# attr::<name> constants set as resource attrs (e.g. networkId/networkType);
# resolve each to its wire key and allowlist only the dotted ones.
for m in re.finditer(r"attr::(\w+)", block):
val = symbols.get(m.group(1))
if val is not None and "." in val:
allow.add(val)
report.ok(f"resource dotted-key allowlist derived: {sorted(allow)}")
return allow
def camel_to_dotsegments(s: str) -> List[str]:
"""Split a CamelCase identifier into lowercase dot-segment parts, e.g.
`ServiceInstanceId` -> ['service', 'instance', 'id']."""
return [w.lower() for w in re.findall(r"[A-Z][a-z0-9]*", s)]
def run_rule_a(
keys_by_header: Dict[Path, Set[str]], dotted_allow: Set[str], report: Report
) -> None:
"""Any dotted attribute key that is not an allowed resource key is a
violation, reported against the header that declares it."""
found = False
for h in sorted(keys_by_header):
for key in sorted(keys_by_header[h]):
if "." in key and key not in dotted_allow:
found = True
report.violation("A", h.name, key, "underscore form, not dotted")
if not found:
report.ok("A: no stray dotted span-attribute keys")
# A lower_snake_case identifier segment: starts lowercase, then lowercase /
# digits / underscores. No uppercase, no spaces, no camelCase.
SNAKE_SEGMENT = re.compile(r"^[a-z][a-z0-9_]*$")
def run_rule_g(keys_by_header: Dict[Path, Set[str]], report: Report) -> None:
"""Every attribute key must be lower_snake_case. Bare/underscore keys must
match ^[a-z][a-z0-9_]*$; dotted resource keys must be lowercase
dot-separated segments (each segment lower_snake_case). Flags camelCase,
UPPERCASE, spaces, and other stray characters."""
found = False
for h in sorted(keys_by_header):
for key in sorted(keys_by_header[h]):
segments = key.split(".")
if all(SNAKE_SEGMENT.match(seg) for seg in segments):
continue
found = True
report.violation("G", h.name, key, "must be lower_snake_case")
if not found:
report.ok("G: all attribute keys are lower_snake_case")
# Which argument positions of each call must be a constant (0-based). The
# attribute VALUE position is intentionally absent: values are runtime data
# (command names, hashes, counts), not naming-convention surface.
# setAttribute(key, value) -> check arg 0 (key); value (arg 1) exempt
# addEvent(name[, attrs]) -> check arg 0 (event name)
# span(category, prefix, name) -> check args 1,2 (prefix + span-name leaf)
# childSpan(name[, parentCtx]) -> check arg 0 (span-name leaf)
CONSTANT_ARG_POSITIONS: Dict[str, Set[int]] = {
"setAttribute": {0},
"addEvent": {0},
"span": {1, 2},
"childSpan": {0},
}
def is_test_path(path: Path) -> bool:
"""True if the path is test code. Tests legitimately pass arbitrary literal
keys/names to exercise the API mechanics, so Rule F does not apply to them.
Matches a `test`/`tests` directory anywhere in the path (e.g. src/test/,
src/tests/, .../detail/tests/)."""
return any(part in ("test", "tests") for part in path.parts)
# A constant reference passed at a call-site, e.g. `rpc_span::attr::command`
# or a bare `myKey`. We capture the leaf identifier (after the last `::`).
IDENTIFIER_ARG = re.compile(r"^[\s&*]*([A-Za-z_][\w:]*)\s*$")
def spanname_symbol_names(headers: List[Path]) -> Set[str]:
"""Every `inline constexpr auto NAME = ...;` symbol defined across the
*SpanNames.h headers, by bare name. Used by Rule H to tell whether a
constant referenced at a call-site actually lives in a SpanNames header."""
names: Set[str] = set()
for h in headers:
for m in CONST_DEF.finditer(strip_comments(read_source(h))):
names.add(m.group(1))
return names
def run_rule_f(root: Path, report: Report, header_symbols: Set[str]) -> None:
"""Walk every telemetry call-site (non-test, non-*SpanNames.h) and check the
constant-only argument positions of setAttribute/addEvent/span/childSpan:
Rule F (FAIL): a string literal in a key / span-name position. Attribute
VALUES are exempt (runtime data).
Rule H (WARN): a constant reference whose name is not defined in any
*SpanNames.h. The constant should live in the corresponding
*SpanNames.h (single source of truth); defining it in-place bypasses
the naming rules. Warn rather than fail — the argument may instead be a
legitimately dynamic local (e.g. a computed span-name leaf)."""
found_f = False
sources = [
p
for base in ("src", "include")
for ext in ("*.h", "*.cpp")
for p in (root / base).rglob(ext)
if p.is_file()
]
for path in sorted(sources):
if path.name.endswith("SpanNames.h") or is_test_path(path):
continue
text = read_source(path)
rel = path.relative_to(root)
for call, arglist, lineno in iter_calls(text):
positions = CONSTANT_ARG_POSITIONS.get(call, set())
args = split_top_level_args(arglist)
for idx in positions:
if idx >= len(args):
continue
arg = args[idx]
lit = STRING_LITERAL.search(arg)
if lit:
found_f = True
report.violation(
"F",
f"{rel}:{lineno}",
f'{call} arg{idx} "{lit.group(1)}"',
"use a *SpanNames.h constant",
)
continue
# Not a literal: Rule H warns when a NAMESPACE-QUALIFIED constant
# reference (e.g. `consensus::span::accept`) is not defined in
# any *SpanNames.h — i.e. the constant was defined in-place
# instead of in the proper header. We only consider qualified
# refs (containing `::`): a bare lowercase identifier is almost
# always a legitimately dynamic local (a computed span-name leaf
# or attribute value), not a misplaced constant, so warning on it
# would be noise. Standard-library types (std::...) are skipped.
ident = IDENTIFIER_ARG.match(arg)
if not (ident and header_symbols):
continue
ref = ident.group(1)
if "::" not in ref or ref.startswith("std::"):
continue
leaf = ref.split("::")[-1]
if leaf not in header_symbols:
report.warning(
"H",
f"{rel}:{lineno}",
f"{call} arg{idx} {ref}",
"not defined in any *SpanNames.h",
)
if not found_f:
report.ok("F: no string-literal keys/names at telemetry call-sites")
def iter_calls(text: str):
"""Yield (call_name, raw_arglist, lineno) for each setAttribute/addEvent/
span/childSpan invocation, spanning multiple physical lines if needed."""
for m in CALLSITE.finditer(text):
name = m.group(1)
# Walk from the opening paren, balancing nesting to find the close.
# Parens inside a "string literal" are ignored so a value such as
# `setAttribute(k, ")")` does not close the call early.
i = m.end() # one char past the '('
depth = 1
in_str = False
escaped = False
while i < len(text) and depth > 0:
c = text[i]
if in_str:
if escaped:
escaped = False
elif c == "\\":
escaped = True
elif c == '"':
in_str = False
elif c == '"':
in_str = True
elif c == "(":
depth += 1
elif c == ")":
depth -= 1
i += 1
arglist = text[m.end() : i - 1]
lineno = text.count("\n", 0, m.start()) + 1
yield name, arglist, lineno
def run_rule_b_collector(root: Path, l1_keys: Set[str], report: Report) -> None:
path = root / "docker" / "telemetry" / "otel-collector-config.yaml"
if not path.is_file():
report.skip("B", "collector config not present")
return
text = read_source(path)
if "spanmetrics" not in text:
report.skip("B", "no spanmetrics block in collector config")
return
dims = extract_spanmetrics_dimensions(text)
if not l1_keys:
report.skip("B", "no L1 key set to validate against")
return
miss = [d for d in dims if d not in l1_keys]
for d in miss:
report.violation("B", str(path.relative_to(root)), d, "must exist in L1")
if not miss:
report.ok(f"B: {len(dims)} collector dimension(s) all in L1")
def extract_spanmetrics_dimensions(text: str) -> List[str]:
dims: List[str] = []
in_dims = False
for line in text.splitlines():
if re.search(r"\bdimensions\s*:", line):
in_dims = True
continue
if in_dims:
m = re.search(r"-\s*name\s*:\s*([A-Za-z0-9_.]+)", line)
if m:
dims.append(m.group(1))
elif line.strip() and not line.lstrip().startswith("-") and ":" in line:
in_dims = False
return dims
def run_rule_c_tempo(root: Path, l1_keys: Set[str], report: Report) -> None:
# The trace-search filter tags live in the Grafana Tempo DATASOURCE
# provisioning file (search.filters[].{tag,scope}); the Tempo server
# tempo.yaml has no such tags. Prefer the datasource file; fall back to the
# server file so the rule still does something if the layout changes.
candidates = [
root / "docker/telemetry/grafana/provisioning/datasources/tempo.yaml",
root / "docker/telemetry/tempo.yaml",
]
path = next((p for p in candidates if p.is_file()), None)
if path is None:
report.skip("C", "tempo datasource provisioning not present")
return
if not l1_keys:
report.skip("C", "no L1 key set to validate against")
return
# Pair each filter's `tag:` with its `scope:` (a few lines below it) and
# validate only span-scope tags — resource/intrinsic tags (service.*, name,
# status, duration) are not span attributes. Strip a TraceQL span. prefix.
lines = read_source(path).splitlines()
span_tags: List[str] = []
for i, line in enumerate(lines):
m = re.search(r"^\s*tag:\s*(\S+)", line)
if not m:
continue
scope = next(
(
sm.group(1)
for j in range(i, min(i + 4, len(lines)))
for sm in [re.search(r"scope:\s*(\S+)", lines[j])]
if sm
),
"",
)
if scope == "span":
span_tags.append(TRACEQL_SCOPE.sub("", m.group(1)))
if not span_tags:
report.skip("C", "no span-scope filter tags in tempo datasource")
return
miss = [t for t in span_tags if t not in l1_keys]
for t in sorted(set(miss)):
report.violation("C", str(path.relative_to(root)), t, "must exist in L1")
if not miss:
report.ok(f"C: {len(span_tags)} tempo span-filter tag(s) all in L1")
def metric_label_names(root: Path) -> Set[str]:
"""L6: OTel native-metric label keys emitted by the telemetry code, e.g.
`counter->Add(1, {{"job_type", value}})` in MetricsRegistry.cpp. These are
a valid source of dashboard labels distinct from span attributes (L1)."""
labels: Set[str] = set()
for base in ("src", "include"):
for p in (root / base).rglob("*.cpp"):
if not p.is_file():
continue
text = read_source(p)
if "MetricsRegistry" not in p.name and "metric" not in text.lower():
continue
labels |= set(METRIC_LABEL.findall(text))
return labels
def run_rule_d_dashboards(
root: Path, l1_keys: Set[str], metric_labels: Set[str], report: Report
) -> None:
dash_dir = root / "docker" / "telemetry" / "grafana" / "dashboards"
files = sorted(dash_dir.glob("*.json")) if dash_dir.is_dir() else []
if not files:
report.skip("D", "no dashboard JSON present")
return
if not l1_keys:
report.skip("D", "no L1 key set to validate against")
return
builtins = {
"__name__", # Prometheus reserved label for the metric name itself
"le",
"exported_instance",
"span_name",
"status_code",
"service_name",
"service_version",
"service_instance_id",
"job",
"instance",
}
# A dashboard label is valid if it is a span attribute (L1), a native-metric
# label (L6), or a Prometheus/Grafana builtin.
valid = l1_keys | metric_labels | builtins
found = False
for f in files:
try:
text = read_source(f)
except OSError:
continue
# PromQL `sum by (a, b)` and `{label="..."}` references.
labels: Set[str] = set()
for m in re.finditer(r"by\s*\(([^)]*)\)", text):
labels |= {x.strip() for x in m.group(1).split(",") if x.strip()}
for m in re.finditer(r"\b([a-z_][a-z0-9_.]*)\s*[=!]~?\s*\"", text):
labels.add(m.group(1))
for lbl in sorted(labels):
# Strip a TraceQL scope prefix (span./resource./...) — the bare
# attribute is what must resolve against L1.
bare = TRACEQL_SCOPE.sub("", lbl)
if bare in valid:
continue
found = True
report.violation(
"D",
str(f.relative_to(root)),
lbl,
"must exist in L1, a metric label, or be a builtin",
)
if not found:
report.ok(f"D: dashboard PromQL labels all resolve ({len(files)} file(s))")
def run_rule_e_runbook(root: Path, l1_keys: Set[str], report: Report) -> None:
path = root / "docs" / "telemetry-runbook.md"
if not path.is_file():
report.skip("E", "runbook not present")
return
if not l1_keys:
report.skip("E", "no L1 key set to validate against")
return
text = read_source(path)
found = False
# Only the dotted `xrpl.<domain>.<field>` attribute form is a violation. The
# `xrpl.`-with-trailing-dot anchor is the discriminator: it matches the old
# dotted attribute convention being migrated away from, while everything
# else legitimately dotted in the runbook does NOT match it —
# * span names (`consensus.round`, `tx.process`) no `xrpl.` prefix
# * filenames (`xrpld.cfg`, `RCLConsensus.cpp`) `xrpld.`/`.cpp`, not `xrpl.`
# * OTel-standard (`service.name`, `http.method`) no `xrpl.` prefix
# * metric labels (`xrpl_rpc_command`) underscore, no dot
# Legitimate dotted resource attrs (`xrpl.network.id`/`.type`) are in L1 and
# are skipped. A dotted `xrpl.` token absent from L1 is a genuine doc/code
# mismatch (e.g. `xrpl.tx.hash` where the code emits `tx_hash`).
for m in re.finditer(r"`(xrpl\.[a-z][a-z0-9_.]*)`", text):
token = m.group(1)
if token in l1_keys: # legitimate dotted resource attr (xrpl.network.*)
continue
found = True
report.violation(
"E", str(path.relative_to(root)), token, "underscore, not dotted"
)
if not found:
report.ok("E: runbook attribute references consistent with L1")
if __name__ == "__main__":
main()

View File

@@ -1,864 +0,0 @@
#!/usr/bin/env python3
"""Unit tests for check_otel_naming.py.
Stdlib-only (unittest), matching the dependency-free policy of the check itself.
Run from anywhere:
python .github/scripts/otel-naming/test_check_otel_naming.py
Each rule is exercised in isolation against a synthetic tree / synthetic L1 key
set, covering positive (must flag), negative (must not flag), and boundary
cases. Rule E (runbook dotted-attribute detection) has the densest coverage
because its discriminator — the `xrpl.<domain>.` prefix vs span names,
filenames, OTel-standard keys, and metric labels — is the subtlest.
"""
import contextlib
import importlib.util
import io
import shutil
import tempfile
import unittest
from pathlib import Path
# Load the check module by path (it is not an importable package).
_spec = importlib.util.spec_from_file_location(
"check_otel_naming", str(Path(__file__).with_name("check_otel_naming.py"))
)
chk = importlib.util.module_from_spec(_spec)
_spec.loader.exec_module(chk)
# A controlled L1 set used across tests: the two legitimate dotted resource
# attrs plus a handful of underscore span-attribute keys.
L1 = {
"xrpl.network.id",
"xrpl.network.type",
"tx_hash",
"peer_id",
"consensus_mode",
"command",
"rpc_status",
"ledger_seq",
}
def _run_rule_e(runbook_text: str):
"""Run Rule E against a synthetic runbook; return the flagged tokens."""
d = Path(tempfile.mkdtemp())
try:
(d / "docs").mkdir()
(d / "docs" / "telemetry-runbook.md").write_text(runbook_text)
report = chk.Report()
chk.run_rule_e_runbook(d, set(L1), report)
return sorted(v[2] for v in report.violations)
finally:
shutil.rmtree(d)
class RuleERunbook(unittest.TestCase):
"""Rule E: only dotted `xrpl.<domain>.<field>` attribute keys are flagged."""
# ----- positive: genuine dotted attribute-key violations -----
def test_single_dotted_attr(self):
self.assertEqual(_run_rule_e("`xrpl.tx.hash`"), ["xrpl.tx.hash"])
def test_multiple_dotted_attrs(self):
self.assertEqual(
_run_rule_e("`xrpl.tx.hash` and `xrpl.consensus.mode`"),
["xrpl.consensus.mode", "xrpl.tx.hash"],
)
def test_deep_dotted_three_segments(self):
self.assertEqual(
_run_rule_e("`xrpl.consensus.ledger.seq`"), ["xrpl.consensus.ledger.seq"]
)
def test_dotted_attr_with_underscore_field(self):
self.assertEqual(
_run_rule_e("`xrpl.consensus.round_id`"), ["xrpl.consensus.round_id"]
)
def test_repeated_token_reported_each_occurrence(self):
self.assertEqual(
_run_rule_e("`xrpl.tx.hash` ... `xrpl.tx.hash`"),
["xrpl.tx.hash", "xrpl.tx.hash"],
)
def test_resource_attr_not_in_l1_is_flagged(self):
self.assertEqual(
_run_rule_e("`xrpl.network.unknown`"), ["xrpl.network.unknown"]
)
# ----- negative: legitimately-dotted tokens that must NOT be flagged -----
def test_span_name_single(self):
self.assertEqual(_run_rule_e("`consensus.round`"), [])
def test_span_name_multi_segment(self):
self.assertEqual(
_run_rule_e("`consensus.phase.open` `rpc.command.server_info`"), []
)
def test_filename_cfg(self):
self.assertEqual(_run_rule_e("`xrpld.cfg`"), [])
def test_filename_cpp(self):
self.assertEqual(_run_rule_e("`RCLConsensus.cpp`"), [])
def test_otel_standard_service_name(self):
self.assertEqual(_run_rule_e("`service.name`"), [])
def test_otel_standard_http_method(self):
self.assertEqual(_run_rule_e("`http.method`"), [])
def test_metric_label_underscore(self):
self.assertEqual(_run_rule_e("`xrpl_rpc_command`"), [])
def test_bare_underscore_attrs(self):
self.assertEqual(_run_rule_e("`tx_hash` `consensus_mode`"), [])
def test_legit_dotted_resource_attrs_in_l1(self):
self.assertEqual(_run_rule_e("`xrpl.network.id` `xrpl.network.type`"), [])
def test_prose_word(self):
self.assertEqual(_run_rule_e("the `command` attribute"), [])
def test_plain_prose_no_backticks(self):
self.assertEqual(_run_rule_e("xrpl.tx.hash without backticks is prose"), [])
# ----- boundary -----
def test_empty_runbook(self):
self.assertEqual(_run_rule_e(""), [])
def test_lookalike_prefix_xrpld(self):
# `xrpld.` is NOT `xrpl.` — must not match.
self.assertEqual(_run_rule_e("`xrpld.foo`"), [])
def test_lookalike_prefix_underscore(self):
# `xrpl_rpc.command` starts with `xrpl_`, not `xrpl.`.
self.assertEqual(_run_rule_e("`xrpl_rpc.command`"), [])
def test_uppercase_segment_not_matched(self):
# The pattern requires a lowercase char after `xrpl.`; uppercase keys are
# caught by Rule G at the L1 layer, not by the runbook text scan.
self.assertEqual(_run_rule_e("`xrpl.TX.hash`"), [])
def test_token_touching_table_pipes(self):
self.assertEqual(_run_rule_e("| `xrpl.tx.hash` | desc |"), ["xrpl.tx.hash"])
def test_mixed_line_only_xrpl_dotted_flagged(self):
self.assertEqual(
_run_rule_e("`consensus.round` uses `xrpl.tx.hash` and `service.name`"),
["xrpl.tx.hash"],
)
def test_skips_when_runbook_absent(self):
d = Path(tempfile.mkdtemp())
try:
report = chk.Report()
chk.run_rule_e_runbook(d, set(L1), report)
self.assertEqual(report.violations, [])
self.assertTrue(any("SKIP: E" in s for s in report.skips))
finally:
shutil.rmtree(d)
def test_skips_when_l1_empty(self):
d = Path(tempfile.mkdtemp())
try:
(d / "docs").mkdir()
(d / "docs" / "telemetry-runbook.md").write_text("`xrpl.tx.hash`")
report = chk.Report()
chk.run_rule_e_runbook(d, set(), report)
self.assertEqual(report.violations, [])
self.assertTrue(any("SKIP: E" in s for s in report.skips))
finally:
shutil.rmtree(d)
class DslParser(unittest.TestCase):
"""The makeStr/join/seg:: constexpr DSL resolver — the foundation of the
L1 key set. Covers flat, nested, cross-file, alias, and multi-line forms."""
def test_flat_join(self):
syms = chk.resolve_constants(
'inline constexpr auto a = makeStr("xrpl");\n'
'inline constexpr auto b = makeStr("network");\n'
"inline constexpr auto c = join(a, b);\n"
)
self.assertEqual(syms["c"], "xrpl.network")
def test_nested_join_three_segments(self):
syms = chk.resolve_constants(
'inline constexpr auto xrpl = makeStr("xrpl");\n'
'inline constexpr auto network = makeStr("network");\n'
"inline constexpr auto networkId = "
'join(join(xrpl, network), makeStr("id"));\n'
)
self.assertEqual(syms["networkId"], "xrpl.network.id")
def test_qualified_seg_reference(self):
# `seg::rpc` resolves by its bare leaf `rpc`.
syms = chk.resolve_constants('inline constexpr auto rpc = makeStr("rpc");\n')
syms2 = chk.resolve_constants(
'inline constexpr auto command = join(seg::rpc, makeStr("command"));\n',
syms,
)
self.assertEqual(syms2["command"], "rpc.command")
def test_alias_reference(self):
syms = chk.resolve_constants('inline constexpr auto rpc = makeStr("rpc");\n')
chk.resolve_constants("inline constexpr auto alias = seg::rpc;\n", syms)
self.assertEqual(syms["alias"], "rpc")
def test_unresolvable_expr_omitted(self):
syms = chk.resolve_constants("inline constexpr auto x = join(unknown, y);\n")
self.assertNotIn("x", syms)
def test_split_top_level_args_respects_nesting(self):
self.assertEqual(
chk.split_top_level_args("join(seg::a, b), c"),
["join(seg::a, b)", " c"],
)
def test_split_top_level_args_ignores_comma_in_string(self):
self.assertEqual(
chk.split_top_level_args('key, ","'),
["key", ' ","'],
)
def test_strip_comments_removes_line_and_block(self):
self.assertEqual(
chk.strip_comments("a // line\nb /* blk */ c").split(),
["a", "b", "c"],
)
def _write(path: Path, text: str) -> None:
path.parent.mkdir(parents=True, exist_ok=True)
path.write_text(text)
def _header(ns_attr_body: str, prefix_seg: str = "") -> str:
"""A minimal *SpanNames.h body: optional seg defs + a namespace attr block."""
return (
"#pragma once\n"
+ prefix_seg
+ "namespace xrpl::telemetry::demo::span {\n"
+ "namespace attr {\n"
+ ns_attr_body
+ "} // namespace attr\n"
+ "}\n"
)
class AttrKeyExtraction(unittest.TestCase):
"""attr_keys_from_header: comment-stripping + multi-line + using re-export."""
def _l1(self, header_text):
d = Path(tempfile.mkdtemp())
try:
h = d / "src" / "DemoSpanNames.h"
_write(h, header_text)
syms = chk.build_global_symbols([h])
return chk.attr_keys_from_header(h, syms)
finally:
shutil.rmtree(d)
def test_single_line_makestr(self):
keys = self._l1(_header('inline constexpr auto k = makeStr("tx_hash");\n'))
self.assertIn("tx_hash", keys)
def test_multiline_constexpr_captured(self):
keys = self._l1(
_header("inline constexpr auto k =\n" ' makeStr("round_time_ms");\n')
)
self.assertIn("round_time_ms", keys)
def test_commented_makestr_not_leaked(self):
keys = self._l1(
_header(
'inline constexpr auto k = makeStr("good");\n'
'// inline constexpr auto bad = makeStr("old.dotted");\n'
)
)
self.assertIn("good", keys)
self.assertNotIn("old.dotted", keys)
def test_block_commented_makestr_not_leaked(self):
keys = self._l1(
_header(
'inline constexpr auto k = makeStr("good");\n'
'/* makeStr("blockbad") */\n'
)
)
self.assertNotIn("blockbad", keys)
class CamelToDotSegments(unittest.TestCase):
"""semconv CamelCase -> dotted OTel-standard key derivation."""
def test_service_instance_id(self):
self.assertEqual(
chk.camel_to_dotsegments("ServiceInstanceId"),
["service", "instance", "id"],
)
def test_service_name(self):
self.assertEqual(chk.camel_to_dotsegments("ServiceName"), ["service", "name"])
def test_derive_keys_from_telemetry_cpp(self):
d = Path(tempfile.mkdtemp())
try:
tele = d / "src" / "libxrpl" / "telemetry" / "Telemetry.cpp"
_write(
tele,
"resource::Resource::Create({\n"
" {semconv::service::kServiceName, x},\n"
" {semconv::service::kServiceInstanceId, y},\n"
"});\n",
)
report = chk.Report()
allow = chk.derive_dotted_resource_keys(d, {}, report)
self.assertIn("service.name", allow)
self.assertIn("service.instance.id", allow)
finally:
shutil.rmtree(d)
class SymbolCollision(unittest.TestCase):
"""attr_keys_from_header must resolve a constant against ITS OWN header, so
two headers defining a same-named constant each report their real wire key.
Regression for the flat-symbol-table collision that let a later header
clobber an earlier one and erased a dotted key from L1 (a Rule-A blind
spot)."""
def _build(self, files):
d = Path(tempfile.mkdtemp())
paths = {}
for rel, text in files.items():
p = d / rel
_write(p, text)
paths[rel] = p
return d, paths
def test_same_named_const_not_clobbered_across_headers(self):
base = (
"#pragma once\n"
"namespace xrpl::telemetry {\n"
'namespace seg { inline constexpr auto xrpl = makeStr("xrpl");\n'
'inline constexpr auto ledger = makeStr("ledger"); }\n'
"namespace attr {\n"
"inline constexpr auto ledgerHash = "
'join(join(seg::xrpl, seg::ledger), makeStr("hash"));\n'
"}\n}\n"
)
cons = (
"#pragma once\n"
"namespace xrpl::telemetry::consensus::span {\n"
"namespace attr { inline constexpr auto ledgerHash = "
'makeStr("ledger_hash"); }\n}\n'
)
d, paths = self._build(
{
"include/xrpl/telemetry/SpanNames.h": base,
"src/xrpld/consensus/ConsensusSpanNames.h": cons,
}
)
try:
headers = chk.find_spanname_headers(d)
syms = chk.build_global_symbols(headers)
by_name = {p.name: chk.attr_keys_from_header(p, syms) for p in headers}
# The base header keeps its dotted key; consensus keeps the bare one.
self.assertIn("xrpl.ledger.hash", by_name["SpanNames.h"])
self.assertEqual(by_name["ConsensusSpanNames.h"], {"ledger_hash"})
finally:
shutil.rmtree(d)
def test_using_reexport_still_resolves_globally(self):
# A `using`-re-export imports a constant defined elsewhere; it must
# resolve against the global table, not the local header.
base = (
"#pragma once\n"
"namespace xrpl::telemetry {\n"
"namespace attr { inline constexpr auto txHash = "
'makeStr("tx_hash"); }\n}\n'
)
dom = (
"#pragma once\n"
"namespace xrpl::telemetry::tx::span {\n"
"namespace attr { using ::xrpl::telemetry::attr::txHash; }\n}\n"
)
d, paths = self._build(
{
"include/xrpl/telemetry/SpanNames.h": base,
"src/xrpld/app/misc/TxSpanNames.h": dom,
}
)
try:
headers = chk.find_spanname_headers(d)
syms = chk.build_global_symbols(headers)
keys = chk.attr_keys_from_header(
paths["src/xrpld/app/misc/TxSpanNames.h"], syms
)
self.assertEqual(keys, {"tx_hash"})
finally:
shutil.rmtree(d)
class ResourceAllowlistScope(unittest.TestCase):
"""derive_dotted_resource_keys must allowlist ONLY the dotted keys actually
passed to Resource::Create() — not every dotted key in the base header. A
dotted attr declared in a header but not set as a resource attr is a Rule-A
violation."""
def _derive(self, tele_text, span_text):
d = Path(tempfile.mkdtemp())
try:
_write(d / "src" / "libxrpl" / "telemetry" / "Telemetry.cpp", tele_text)
_write(d / "include" / "xrpl" / "telemetry" / "SpanNames.h", span_text)
headers = chk.find_spanname_headers(d)
syms = chk.build_global_symbols(headers)
allow = chk.derive_dotted_resource_keys(d, syms, chk.Report())
return allow, syms, headers, d
except Exception:
shutil.rmtree(d)
raise
def test_dotted_span_attr_not_allowlisted_and_flagged(self):
span = (
"#pragma once\n"
"namespace xrpl::telemetry {\n"
'namespace seg { inline constexpr auto xrpl = makeStr("xrpl");\n'
'inline constexpr auto ledger = makeStr("ledger");\n'
'inline constexpr auto network = makeStr("network"); }\n'
"namespace attr {\n"
"inline constexpr auto networkId = "
'join(join(seg::xrpl, seg::network), makeStr("id"));\n'
"inline constexpr auto ledgerHash = "
'join(join(seg::xrpl, seg::ledger), makeStr("hash"));\n'
"}\n}\n"
)
tele = (
"auto r = resource::Resource::Create({\n"
" {semconv::service::kServiceName, x},\n"
" {std::string(attr::networkId), n},\n"
"});\n"
)
allow, syms, headers, d = self._derive(tele, span)
try:
# networkId IS a resource attr; ledgerHash is NOT, despite living in
# the base header.
self.assertIn("xrpl.network.id", allow)
self.assertNotIn("xrpl.ledger.hash", allow)
kbh = {h: chk.attr_keys_from_header(h, syms) for h in headers}
report = chk.Report()
chk.run_rule_a(kbh, allow, report)
self.assertEqual([v[2] for v in report.violations], ["xrpl.ledger.hash"])
finally:
shutil.rmtree(d)
def test_resource_block_brace_matched(self):
# A nested {key,value} initializer must not truncate the block scan.
tele = (
"auto r = resource::Resource::Create({\n"
" {semconv::service::kServiceName, x},\n"
" {std::string(attr::networkType), t},\n"
"});\n"
)
span = (
"#pragma once\n"
"namespace xrpl::telemetry {\n"
'namespace seg { inline constexpr auto xrpl = makeStr("xrpl");\n'
'inline constexpr auto network = makeStr("network"); }\n'
"namespace attr { inline constexpr auto networkType = "
'join(join(seg::xrpl, seg::network), makeStr("type")); }\n}\n'
)
allow, _syms, _headers, d = self._derive(tele, span)
try:
self.assertIn("xrpl.network.type", allow)
self.assertIn("service.name", allow)
finally:
shutil.rmtree(d)
def _run_rule_a(keys_by_header, allow):
report = chk.Report()
chk.run_rule_a(keys_by_header, allow, report)
return sorted(v[2] for v in report.violations)
class RuleADotted(unittest.TestCase):
def test_dotted_attr_not_in_allow_flagged(self):
kbh = {Path("src/RpcSpanNames.h"): {"xrpl.tx.hash", "command"}}
self.assertEqual(_run_rule_a(kbh, {"xrpl.network.id"}), ["xrpl.tx.hash"])
def test_resource_attr_in_allow_passes(self):
kbh = {Path("src/SpanNames.h"): {"xrpl.network.id"}}
self.assertEqual(_run_rule_a(kbh, {"xrpl.network.id"}), [])
def test_bare_key_never_flagged(self):
kbh = {Path("src/TxSpanNames.h"): {"tx_hash", "command"}}
self.assertEqual(_run_rule_a(kbh, set()), [])
def _run_rule_g(keys_by_header):
report = chk.Report()
chk.run_rule_g(keys_by_header, report)
return sorted(v[2] for v in report.violations)
class RuleGSnakeCase(unittest.TestCase):
def test_camelcase_flagged(self):
self.assertEqual(_run_rule_g({Path("h"): {"txHash"}}), ["txHash"])
def test_uppercase_flagged(self):
self.assertEqual(_run_rule_g({Path("h"): {"TX_HASH"}}), ["TX_HASH"])
def test_space_flagged(self):
self.assertEqual(_run_rule_g({Path("h"): {"bad key"}}), ["bad key"])
def test_snake_case_passes(self):
self.assertEqual(_run_rule_g({Path("h"): {"tx_hash", "rpc_status"}}), [])
def test_dotted_resource_segments_pass(self):
self.assertEqual(_run_rule_g({Path("h"): {"xrpl.network.id"}}), [])
def test_dotted_with_bad_segment_flagged(self):
self.assertEqual(
_run_rule_g({Path("h"): {"xrpl.Network.id"}}), ["xrpl.Network.id"]
)
class RuleFAndH(unittest.TestCase):
"""run_rule_f: literal keys/span-names flagged; values & tests exempt.
Rule H: qualified constant not in any header warns (non-fatal)."""
def _run(self, rel_path, source, header_symbols=frozenset()):
d = Path(tempfile.mkdtemp())
try:
_write(d / rel_path, source)
report = chk.Report()
chk.run_rule_f(d, report, set(header_symbols))
return (
sorted(v[2] for v in report.violations),
sorted(w[2] for w in report.warnings),
)
finally:
shutil.rmtree(d)
def test_literal_key_flagged(self):
v, _ = self._run("src/Foo.cpp", 'g.setAttribute("lit_key", v);\n')
self.assertEqual(v, ['setAttribute arg0 "lit_key"'])
def test_literal_value_exempt(self):
v, _ = self._run("src/Foo.cpp", 'g.setAttribute(attr::command, "submit");\n')
self.assertEqual(v, [])
def test_span_name_args_flagged(self):
v, _ = self._run("src/Foo.cpp", 'SpanGuard::span(cat, "rpc", "command");\n')
self.assertEqual(v, ['span arg1 "rpc"', 'span arg2 "command"'])
def test_test_path_exempt(self):
v, _ = self._run("src/test/Foo.cpp", 'g.setAttribute("lit_key", v);\n')
self.assertEqual(v, [])
def test_spannames_header_exempt(self):
v, _ = self._run("src/DemoSpanNames.h", 'g.setAttribute("lit_key", v);\n')
self.assertEqual(v, [])
def test_bare_span_call_not_matched(self):
# No SpanGuard/./-> receiver -> not a telemetry call-site.
v, _ = self._run("src/Foo.cpp", 'auto s = span("not", "telemetry");\n')
self.assertEqual(v, [])
def test_multiline_call_reports_first_line(self):
v, _ = self._run("src/Foo.cpp", 'g.setAttribute(\n "k",\n v);\n')
self.assertEqual(v, ['setAttribute arg0 "k"'])
def test_paren_in_string_value_does_not_break_parsing(self):
# The ")" inside the value must not end the call early; key still seen.
v, _ = self._run("src/Foo.cpp", 'g.setAttribute("k", ")");\n')
self.assertEqual(v, ['setAttribute arg0 "k"'])
def test_rule_h_qualified_constant_warns(self):
v, w = self._run(
"src/Foo.cpp",
"g.setAttribute(consensus::span::accept, v);\n",
header_symbols={"command"},
)
self.assertEqual(v, [])
self.assertEqual(w, ["setAttribute arg0 consensus::span::accept"])
def test_rule_h_known_constant_no_warning(self):
_, w = self._run(
"src/Foo.cpp",
"g.setAttribute(rpc_span::attr::command, v);\n",
header_symbols={"command"},
)
self.assertEqual(w, [])
def test_rule_h_bare_local_no_warning(self):
_, w = self._run(
"src/Foo.cpp", "g.setAttribute(myLeaf, v);\n", header_symbols={"command"}
)
self.assertEqual(w, [])
class RuleBCollector(unittest.TestCase):
def _run(self, yaml_text, l1):
d = Path(tempfile.mkdtemp())
try:
_write(d / "docker" / "telemetry" / "otel-collector-config.yaml", yaml_text)
report = chk.Report()
chk.run_rule_b_collector(d, set(l1), report)
return sorted(v[2] for v in report.violations), report.skips
finally:
shutil.rmtree(d)
def test_dimension_not_in_l1_flagged(self):
y = "spanmetrics:\n dimensions:\n - name: bogus_dim\n - name: command\n"
v, _ = self._run(y, {"command"})
self.assertEqual(v, ["bogus_dim"])
def test_all_dimensions_in_l1_pass(self):
y = "spanmetrics:\n dimensions:\n - name: command\n - name: rpc_status\n"
v, _ = self._run(y, {"command", "rpc_status"})
self.assertEqual(v, [])
def test_skip_when_no_spanmetrics_block(self):
v, skips = self._run("receivers:\n otlp:\n", {"command"})
self.assertEqual(v, [])
self.assertTrue(any("SKIP: B" in s for s in skips))
class RuleCTempo(unittest.TestCase):
"""Rule C reads the Grafana Tempo DATASOURCE file's search.filters and
validates only span-scope tags against L1."""
DS = "docker/telemetry/grafana/provisioning/datasources/tempo.yaml"
def _run(self, yaml_text, l1):
d = Path(tempfile.mkdtemp())
try:
_write(d / self.DS, yaml_text)
report = chk.Report()
chk.run_rule_c_tempo(d, set(l1), report)
return sorted(v[2] for v in report.violations), report.skips
finally:
shutil.rmtree(d)
def _filter(self, fid, tag, scope):
return (
f" - id: {fid}\n"
f" tag: {tag}\n"
f' operator: "="\n'
f" scope: {scope}\n"
f" type: static\n"
)
def test_span_tag_not_in_l1_flagged(self):
y = "search:\n filters:\n" + self._filter("f1", "bogus_tag", "span")
v, _ = self._run(y, {"command"})
self.assertEqual(v, ["bogus_tag"])
def test_span_tags_in_l1_pass(self):
y = (
"search:\n filters:\n"
+ self._filter("f1", "command", "span")
+ self._filter("f2", "tx_hash", "span")
)
v, _ = self._run(y, {"command", "tx_hash"})
self.assertEqual(v, [])
def test_resource_and_intrinsic_tags_ignored(self):
# service.* (resource) and name/status/duration (intrinsic) are not
# span attributes — they must not be validated against L1.
y = (
"search:\n filters:\n"
+ self._filter("f1", "service.instance.id", "resource")
+ self._filter("f2", "name", "intrinsic")
+ self._filter("f3", "duration", "intrinsic")
)
v, skips = self._run(y, {"command"})
self.assertEqual(v, [])
self.assertTrue(any("SKIP: C" in s for s in skips))
def test_skip_when_datasource_absent(self):
d = Path(tempfile.mkdtemp())
try:
report = chk.Report()
chk.run_rule_c_tempo(d, {"command"}, report)
self.assertEqual(report.violations, [])
self.assertTrue(any("SKIP: C" in s for s in report.skips))
finally:
shutil.rmtree(d)
class RuleDDashboards(unittest.TestCase):
def _run(self, json_text, l1, metric_labels=frozenset()):
d = Path(tempfile.mkdtemp())
try:
_write(
d / "docker" / "telemetry" / "grafana" / "dashboards" / "x.json",
json_text,
)
report = chk.Report()
chk.run_rule_d_dashboards(d, set(l1), set(metric_labels), report)
return sorted(v[2] for v in report.violations)
finally:
shutil.rmtree(d)
def test_unknown_promql_label_flagged(self):
self.assertEqual(
self._run('"expr": "sum by (bogus_label) (x)"', {"command"}),
["bogus_label"],
)
def test_builtin_labels_not_flagged(self):
self.assertEqual(
self._run('"expr": "sum by (le, span_name, exported_instance) (x)"', set()),
[],
)
def test_prometheus_name_label_not_flagged(self):
# `__name__` is the Prometheus reserved metric-name label; the renamed
# system-*.json dashboards use `sum by (le, __name__)`.
self.assertEqual(
self._run('"expr": "sum by (le, __name__) (rate(x[5m]))"', set()),
[],
)
def test_l1_label_passes(self):
self.assertEqual(self._run('"q": "{command=\\"x\\"}"', {"command"}), [])
def test_traceql_span_prefix_stripped(self):
# `span.establish_count` must validate against the bare L1 key.
self.assertEqual(
self._run(
'"expr": "count_over_time(x) by (span.establish_count)"',
{"establish_count"},
),
[],
)
def test_traceql_resource_prefix_stripped(self):
self.assertEqual(self._run('"q": "{resource.service_name=\\"x\\"}"', set()), [])
def test_native_metric_label_passes(self):
# `job_type` / `reason` are emitted by MetricsRegistry, not span attrs.
self.assertEqual(
self._run(
'"expr": "sum by (job_type, reason) (x)"',
{"command"},
metric_labels={"job_type", "reason"},
),
[],
)
def test_unknown_label_still_flagged_with_metric_labels(self):
# A label that is neither L1, metric label, nor builtin still fails.
self.assertEqual(
self._run(
'"expr": "sum by (bogus) (x)"',
{"command"},
metric_labels={"job_type"},
),
["bogus"],
)
def test_span_prefixed_unknown_still_flagged(self):
# `span.not_a_key` whose bare form is unknown is still a violation.
self.assertEqual(
self._run('"expr": "x by (span.not_a_key)"', {"command"}),
["span.not_a_key"],
)
class MetricLabelExtraction(unittest.TestCase):
"""L6: native-metric label keys parsed from C++ instrument calls."""
def test_extracts_add_label(self):
d = Path(tempfile.mkdtemp())
try:
_write(
d / "src" / "xrpld" / "telemetry" / "MetricsRegistry.cpp",
'counter->Add(1, {{"job_type", std::string(jobType)}});\n'
'c2->Add(1, {{"reason", std::string(r)}});\n',
)
self.assertEqual(chk.metric_label_names(d), {"job_type", "reason"})
finally:
shutil.rmtree(d)
def test_no_metrics_file_empty(self):
d = Path(tempfile.mkdtemp())
try:
(d / "src").mkdir()
self.assertEqual(chk.metric_label_names(d), set())
finally:
shutil.rmtree(d)
class ReportExitContract(unittest.TestCase):
@staticmethod
def _exit_code(report):
"""Call render_and_exit (which prints + raises SystemExit), swallowing
its stdout, and return the exit code."""
with contextlib.redirect_stdout(io.StringIO()):
try:
report.render_and_exit()
except SystemExit as e:
return e.code
return None # pragma: no cover - render_and_exit always exits
def test_violation_exits_nonzero(self):
r = chk.Report()
r.violation("A", "f", "tok", "exp")
self.assertEqual(self._exit_code(r), 1)
def test_clean_exits_zero(self):
r = chk.Report()
r.ok("all good")
self.assertEqual(self._exit_code(r), 0)
def test_warning_only_exits_zero(self):
r = chk.Report()
r.warning("H", "f", "tok", "note")
self.assertEqual(self._exit_code(r), 0)
class RuleEReportTuple(unittest.TestCase):
"""Assert Rule E records the full (rule, expected) tuple, not just token."""
def test_violation_tuple_fields(self):
d = Path(tempfile.mkdtemp())
try:
(d / "docs").mkdir()
(d / "docs" / "telemetry-runbook.md").write_text("`xrpl.tx.hash`")
report = chk.Report()
chk.run_rule_e_runbook(d, {"xrpl.network.id"}, report)
self.assertEqual(len(report.violations), 1)
rule, _loc, token, expected = report.violations[0]
self.assertEqual(rule, "E")
self.assertEqual(token, "xrpl.tx.hash")
self.assertEqual(expected, "underscore, not dotted")
finally:
shutil.rmtree(d)
def test_clean_runbook_records_ok(self):
d = Path(tempfile.mkdtemp())
try:
(d / "docs").mkdir()
(d / "docs" / "telemetry-runbook.md").write_text(
"`tx_hash` `consensus.round`"
)
report = chk.Report()
chk.run_rule_e_runbook(d, {"tx_hash"}, report)
self.assertEqual(report.violations, [])
self.assertTrue(any("E:" in c for c in report.checked))
finally:
shutil.rmtree(d)
if __name__ == "__main__":
unittest.main(verbosity=2)

View File

@@ -1,50 +0,0 @@
## Renaming ripple(d) to xrpl(d)
In the initial phases of development of the XRPL, the open source codebase was
called "rippled" and it remains with that name even today. Today, over 1000
nodes run the application, and code contributions have been submitted by
developers located around the world. The XRPL community is larger than ever.
In light of the decentralized and diversified nature of XRPL, we will rename any
references to `ripple` and `rippled` to `xrpl` and `xrpld`, when appropriate.
See [here](https://xls.xrpl.org/xls/XLS-0095-rename-rippled-to-xrpld.html) for
more information.
### Scripts
To facilitate this transition, there will be multiple scripts that developers
can run on their own PRs and forks to minimize conflicts. Each script should be
run from the repository root.
1. `.github/scripts/rename/definitions.sh`: This script will rename all
definitions, such as include guards, from `RIPPLE_XXX` and `RIPPLED_XXX` to
`XRPL_XXX`.
2. `.github/scripts/rename/copyright.sh`: This script will remove superfluous
copyright notices.
3. `.github/scripts/rename/cmake.sh`: This script will rename all CMake files
from `RippleXXX.cmake` or `RippledXXX.cmake` to `XrplXXX.cmake`, and any
references to `ripple` and `rippled` (with or without capital letters) to
`xrpl` and `xrpld`, respectively. The name of the binary will remain as-is,
and will only be renamed to `xrpld` by a later script.
4. `.github/scripts/rename/binary.sh`: This script will rename the binary from
`rippled` to `xrpld`, and reverses the symlink so that `rippled` points to
the `xrpld` binary.
5. `.github/scripts/rename/namespace.sh`: This script will rename the C++
namespaces from `ripple` to `xrpl`.
6. `.github/scripts/rename/config.sh`: This script will rename the config from
`rippled.cfg` to `xrpld.cfg`, and updating the code accordingly. The old
filename will still be accepted.
7. `.github/scripts/rename/docs.sh`: This script will rename any lingering
references of `ripple(d)` to `xrpl(d)` in code, comments, and documentation.
You can run all these scripts from the repository root as follows:
```shell
./.github/scripts/rename/definitions.sh .
./.github/scripts/rename/copyright.sh .
./.github/scripts/rename/cmake.sh .
./.github/scripts/rename/binary.sh .
./.github/scripts/rename/namespace.sh .
./.github/scripts/rename/config.sh .
./.github/scripts/rename/docs.sh .
```

View File

@@ -1,55 +0,0 @@
#!/bin/bash
# Exit the script as soon as an error occurs.
set -e
# On MacOS, ensure that GNU sed is installed and available as `gsed`.
SED_COMMAND=sed
if [[ "${OSTYPE}" == 'darwin'* ]]; then
if ! command -v gsed &>/dev/null; then
echo "Error: gsed is not installed. Please install it using 'brew install gnu-sed'."
exit 1
fi
SED_COMMAND=gsed
fi
# This script changes the binary name from `rippled` to `xrpld`, and reverses
# the symlink that currently points from `xrpld` to `rippled` so that it points
# from `rippled` to `xrpld` instead.
# Usage: .github/scripts/rename/binary.sh <repository directory>
if [ "$#" -ne 1 ]; then
echo "Usage: $0 <repository directory>"
exit 1
fi
DIRECTORY=$1
echo "Processing directory: ${DIRECTORY}"
if [ ! -d "${DIRECTORY}" ]; then
echo "Error: Directory '${DIRECTORY}' does not exist."
exit 1
fi
pushd "${DIRECTORY}"
# Remove the binary name override added by the cmake.sh script.
${SED_COMMAND} -z -i -E 's@\s+# For the time being.+"rippled"\)@@' cmake/XrplCore.cmake
# Reverse the symlink.
${SED_COMMAND} -i -E 's@create_symbolic_link\(rippled@create_symbolic_link(xrpld@' cmake/XrplInstall.cmake
${SED_COMMAND} -i -E 's@/xrpld\$\{suffix\}@/rippled${suffix}@' cmake/XrplInstall.cmake
# Rename references to the binary.
${SED_COMMAND} -i -E 's@rippled@xrpld@g' BUILD.md
${SED_COMMAND} -i -E 's@rippled@xrpld@g' CONTRIBUTING.md
${SED_COMMAND} -i -E 's@rippled@xrpld@g' .github/ISSUE_TEMPLATE/bug_report.md
# Restore and/or fix certain renames. The pre-commit hook will update the
# formatting upon saving/committing.
${SED_COMMAND} -i -E 's@ripple/xrpld@XRPLF/rippled@g' BUILD.md
${SED_COMMAND} -i -E 's@XRPLF/xrpld@XRPLF/rippled@g' BUILD.md
${SED_COMMAND} -i -E 's@xrpld \(`xrpld`\)@xrpld@g' BUILD.md
${SED_COMMAND} -i -E 's@XRPLF/xrpld@XRPLF/rippled@g' CONTRIBUTING.md
${SED_COMMAND} -i -E 's@XRPLF/xrpld@XRPLF/rippled@g' docs/build/install.md
popd
echo "Processing complete."

View File

@@ -1,88 +0,0 @@
#!/bin/bash
# Exit the script as soon as an error occurs.
set -e
# On MacOS, ensure that GNU sed and head are installed and available as `gsed`
# and `ghead`, respectively.
SED_COMMAND=sed
HEAD_COMMAND=head
if [[ "${OSTYPE}" == 'darwin'* ]]; then
if ! command -v gsed &>/dev/null; then
echo "Error: gsed is not installed. Please install it using 'brew install gnu-sed'."
exit 1
fi
SED_COMMAND=gsed
if ! command -v ghead &>/dev/null; then
echo "Error: ghead is not installed. Please install it using 'brew install coreutils'."
exit 1
fi
HEAD_COMMAND=ghead
fi
# This script renames CMake files from `RippleXXX.cmake` or `RippledXXX.cmake`
# to `XrplXXX.cmake`, and any references to `ripple` and `rippled` (with or
# without capital letters) to `xrpl` and `xrpld`, respectively. The name of the
# binary will remain as-is, and will only be renamed to `xrpld` in a different
# script, but the proto file will be renamed.
# Usage: .github/scripts/rename/cmake.sh <repository directory>
if [ "$#" -ne 1 ]; then
echo "Usage: $0 <repository directory>"
exit 1
fi
DIRECTORY=$1
echo "Processing directory: ${DIRECTORY}"
if [ ! -d "${DIRECTORY}" ]; then
echo "Error: Directory '${DIRECTORY}' does not exist."
exit 1
fi
pushd "${DIRECTORY}"
# Rename the files.
find cmake -type f -name 'Rippled*.cmake' -exec bash -c 'mv "${1}" "${1/Rippled/Xrpl}"' - {} \;
find cmake -type f -name 'Ripple*.cmake' -exec bash -c 'mv "${1}" "${1/Ripple/Xrpl}"' - {} \;
if [ -e include/xrpl/proto/ripple.proto ]; then
mv include/xrpl/proto/ripple.proto include/xrpl/proto/xrpl.proto
fi
# Rename inside the files.
find cmake -type f -name '*.cmake' | while read -r FILE; do
echo "Processing file: ${FILE}"
${SED_COMMAND} -i 's/Rippled/Xrpld/g' "${FILE}"
${SED_COMMAND} -i 's/Ripple/Xrpl/g' "${FILE}"
${SED_COMMAND} -i 's/rippled/xrpld/g' "${FILE}"
${SED_COMMAND} -i 's/ripple/xrpl/g' "${FILE}"
done
${SED_COMMAND} -i -E 's/Rippled?/Xrpl/g' CMakeLists.txt
${SED_COMMAND} -i 's/ripple/xrpl/g' CMakeLists.txt
${SED_COMMAND} -i 's/ripple.pb.h/xrpl.pb.h/' include/xrpl/protocol/messages.h
${SED_COMMAND} -i 's/ripple.pb.h/xrpl.pb.h/' BUILD.md
${SED_COMMAND} -i 's/ripple.pb.h/xrpl.pb.h/' BUILD.md
# Restore the name of the validator keys repository.
${SED_COMMAND} -i 's@xrpl/validator-keys-tool@ripple/validator-keys-tool@' cmake/XrplValidatorKeys.cmake
# Ensure the name of the binary and config remain 'rippled' for now.
${SED_COMMAND} -i -E 's/xrpld(-example)?\.cfg/rippled\1.cfg/g' cmake/XrplInstall.cmake
if grep -q '"xrpld"' cmake/XrplCore.cmake; then
# The script has been rerun, so just restore the name of the binary.
${SED_COMMAND} -i 's/"xrpld"/"rippled"/' cmake/XrplCore.cmake
elif ! grep -q '"rippled"' cmake/XrplCore.cmake; then
${HEAD_COMMAND} -n -1 cmake/XrplCore.cmake >cmake.tmp
echo ' # For the time being, we will keep the name of the binary as it was.' >>cmake.tmp
echo ' set_target_properties(xrpld PROPERTIES OUTPUT_NAME "rippled")' >>cmake.tmp
tail -1 cmake/XrplCore.cmake >>cmake.tmp
mv cmake.tmp cmake/XrplCore.cmake
fi
# Restore the symlink from 'xrpld' to 'rippled'.
${SED_COMMAND} -i -E 's@create_symbolic_link\(xrpld@create_symbolic_link(rippled@' cmake/XrplInstall.cmake
# Remove the symlink that previously pointed from 'ripple' to 'xrpl' but now is
# no longer needed.
${SED_COMMAND} -z -i -E 's@install\(CODE.+CMAKE_INSTALL_INCLUDEDIR}/xrpl\)\n"\)\n+@@' cmake/XrplInstall.cmake
popd
echo "Renaming complete."

View File

@@ -1,71 +0,0 @@
#!/bin/bash
# Exit the script as soon as an error occurs.
set -e
# On MacOS, ensure that GNU sed is installed and available as `gsed`.
SED_COMMAND=sed
if [[ "${OSTYPE}" == 'darwin'* ]]; then
if ! command -v gsed &>/dev/null; then
echo "Error: gsed is not installed. Please install it using 'brew install gnu-sed'."
exit 1
fi
SED_COMMAND=gsed
fi
# This script renames the config from `rippled.cfg` to `xrpld.cfg`, and updates
# the code accordingly. The old filename will still be accepted.
# Usage: .github/scripts/rename/config.sh <repository directory>
if [ "$#" -ne 1 ]; then
echo "Usage: $0 <repository directory>"
exit 1
fi
DIRECTORY=$1
echo "Processing directory: ${DIRECTORY}"
if [ ! -d "${DIRECTORY}" ]; then
echo "Error: Directory '${DIRECTORY}' does not exist."
exit 1
fi
pushd "${DIRECTORY}"
# Add the xrpld.cfg to the .gitignore.
if ! grep -q 'xrpld.cfg' .gitignore; then
${SED_COMMAND} -i '/rippled.cfg/a\
/xrpld.cfg' .gitignore
fi
# Rename the files.
if [ -e rippled.cfg ]; then
mv rippled.cfg xrpld.cfg
fi
if [ -e cfg/rippled-example.cfg ]; then
mv cfg/rippled-example.cfg cfg/xrpld-example.cfg
fi
# Rename inside the files.
DIRECTORIES=("cfg" "cmake" "include" "src")
for DIRECTORY in "${DIRECTORIES[@]}"; do
echo "Processing directory: ${DIRECTORY}"
find "${DIRECTORY}" -type f \( -name "*.h" -o -name "*.hpp" -o -name "*.ipp" -o -name "*.cpp" -o -name "*.cmake" -o -name "*.txt" -o -name "*.cfg" -o -name "*.md" \) | while read -r FILE; do
echo "Processing file: ${FILE}"
${SED_COMMAND} -i -E 's/rippled(-example)?[ .]cfg/xrpld\1.cfg/g' "${FILE}"
${SED_COMMAND} -i 's/rippleConfig/xrpldConfig/g' "${FILE}"
done
done
${SED_COMMAND} -i 's/rippled/xrpld/g' cfg/xrpld-example.cfg
${SED_COMMAND} -i 's/rippled/xrpld/g' src/test/core/Config_test.cpp
${SED_COMMAND} -i 's/ripplevalidators/xrplvalidators/g' src/test/core/Config_test.cpp # cspell: disable-line
${SED_COMMAND} -i 's@ripple/@xrpld/@g' src/test/core/Config_test.cpp
${SED_COMMAND} -i 's/Rippled/File/g' src/test/core/Config_test.cpp
# Restore the old config file name in the code that maintains support for now.
${SED_COMMAND} -i 's/kConfigLegacyName = "xrpld.cfg"/kConfigLegacyName = "rippled.cfg"/g' src/xrpld/core/detail/Config.cpp
# Restore an URL.
${SED_COMMAND} -i 's/connect-your-xrpld-to-the-xrp-test-net.html/connect-your-rippled-to-the-xrp-test-net.html/g' cfg/xrpld-example.cfg
popd
echo "Renaming complete."

View File

@@ -1,103 +0,0 @@
#!/bin/bash
# Exit the script as soon as an error occurs.
set -e
# On MacOS, ensure that GNU sed is installed and available as `gsed`.
SED_COMMAND=sed
if [[ "${OSTYPE}" == 'darwin'* ]]; then
if ! command -v gsed &>/dev/null; then
echo "Error: gsed is not installed. Please install it using 'brew install gnu-sed'."
exit 1
fi
SED_COMMAND=gsed
fi
# This script removes superfluous copyright notices in source and header files
# in this project. Specifically, it removes all notices referencing Ripple,
# XRPLF, and certain individual contributors upon mutual agreement, so the one
# in the LICENSE.md file applies throughout. Copyright notices referencing
# external contributions, e.g. from Bitcoin, remain as-is.
# Usage: .github/scripts/rename/copyright.sh <repository directory>
if [ "$#" -ne 1 ]; then
echo "Usage: $0 <repository directory>"
exit 1
fi
DIRECTORY=$1
echo "Processing directory: ${DIRECTORY}"
if [ ! -d "${DIRECTORY}" ]; then
echo "Error: Directory '${DIRECTORY}' does not exist."
exit 1
fi
pushd "${DIRECTORY}"
# Prevent sed and echo from removing newlines and tabs in string literals by
# temporarily replacing them with placeholders. This only affects one file.
PLACEHOLDER_NEWLINE="__NEWLINE__"
PLACEHOLDER_TAB="__TAB__"
${SED_COMMAND} -i -E "s@\\\n@${PLACEHOLDER_NEWLINE}@g" src/test/rpc/ValidatorInfo_test.cpp
${SED_COMMAND} -i -E "s@\\\t@${PLACEHOLDER_TAB}@g" src/test/rpc/ValidatorInfo_test.cpp
# Process the include/ and src/ directories.
DIRECTORIES=("include" "src")
for DIRECTORY in "${DIRECTORIES[@]}"; do
echo "Processing directory: ${DIRECTORY}"
find "${DIRECTORY}" -type f \( -name "*.h" -o -name "*.hpp" -o -name "*.ipp" -o -name "*.cpp" -o -name "*.macro" \) | while read -r FILE; do
echo "Processing file: ${FILE}"
# Handle the cases where the copyright notice is enclosed in /* ... */
# and usually surrounded by //---- and //======.
${SED_COMMAND} -z -i -E 's@^//-------+\n+@@' "${FILE}"
${SED_COMMAND} -z -i -E 's@^.*Copyright.+(Ripple|Bougalis|Falco|Hinnant|Null|Ritchford|XRPLF).+PERFORMANCE OF THIS SOFTWARE\.\n\*/\n+@@' "${FILE}" # cspell: ignore Bougalis Falco Hinnant Ritchford
${SED_COMMAND} -z -i -E 's@^//=======+\n+@@' "${FILE}"
# Handle the cases where the copyright notice is commented out with //.
${SED_COMMAND} -z -i -E 's@^//\n// Copyright.+Falco \(vinnie dot falco at gmail dot com\)\n//\n+@@' "${FILE}" # cspell: ignore Vinnie Falco
done
done
# Restore copyright notices that were removed from specific files, without
# restoring the verbiage that is already present in LICENSE.md. Ensure that if
# the script is run multiple times, duplicate notices are not added.
if ! grep -q 'Raw Material Software' include/xrpl/beast/core/CurrentThreadName.h; then
echo -e "// Portions of this file are from JUCE (http://www.juce.com).\n// Copyright (c) 2013 - Raw Material Software Ltd.\n// Please visit http://www.juce.com\n\n$(cat include/xrpl/beast/core/CurrentThreadName.h)" >include/xrpl/beast/core/CurrentThreadName.h
fi
if ! grep -q 'Dev Null' src/test/app/NetworkID_test.cpp; then
echo -e "// Copyright (c) 2020 Dev Null Productions\n\n$(cat src/test/app/NetworkID_test.cpp)" >src/test/app/NetworkID_test.cpp
fi
if ! grep -q 'Dev Null' src/test/app/tx/apply_test.cpp; then
echo -e "// Copyright (c) 2020 Dev Null Productions\n\n$(cat src/test/app/tx/apply_test.cpp)" >src/test/app/tx/apply_test.cpp
fi
if ! grep -q 'Dev Null' src/test/rpc/ManifestRPC_test.cpp; then
echo -e "// Copyright (c) 2020 Dev Null Productions\n\n$(cat src/test/rpc/ManifestRPC_test.cpp)" >src/test/rpc/ManifestRPC_test.cpp
fi
if ! grep -q 'Dev Null' src/test/rpc/ValidatorInfo_test.cpp; then
echo -e "// Copyright (c) 2020 Dev Null Productions\n\n$(cat src/test/rpc/ValidatorInfo_test.cpp)" >src/test/rpc/ValidatorInfo_test.cpp
fi
if ! grep -q 'Dev Null' src/xrpld/rpc/handlers/server_info/Manifest.cpp; then
echo -e "// Copyright (c) 2019 Dev Null Productions\n\n$(cat src/xrpld/rpc/handlers/server_info/Manifest.cpp)" >src/xrpld/rpc/handlers/server_info/Manifest.cpp
fi
if ! grep -q 'Dev Null' src/xrpld/rpc/handlers/admin/status/ValidatorInfo.cpp; then
echo -e "// Copyright (c) 2019 Dev Null Productions\n\n$(cat src/xrpld/rpc/handlers/admin/status/ValidatorInfo.cpp)" >src/xrpld/rpc/handlers/admin/status/ValidatorInfo.cpp
fi
if ! grep -q 'Bougalis' include/xrpl/basics/SlabAllocator.h; then
echo -e "// Copyright (c) 2022, Nikolaos D. Bougalis <nikb@bougalis.net>\n\n$(cat include/xrpl/basics/SlabAllocator.h)" >include/xrpl/basics/SlabAllocator.h # cspell: ignore Nikolaos Bougalis nikb
fi
if ! grep -q 'Bougalis' include/xrpl/basics/spinlock.h; then
echo -e "// Copyright (c) 2022, Nikolaos D. Bougalis <nikb@bougalis.net>\n\n$(cat include/xrpl/basics/spinlock.h)" >include/xrpl/basics/spinlock.h # cspell: ignore Nikolaos Bougalis nikb
fi
if ! grep -q 'Bougalis' include/xrpl/basics/tagged_integer.h; then
echo -e "// Copyright (c) 2014, Nikolaos D. Bougalis <nikb@bougalis.net>\n\n$(cat include/xrpl/basics/tagged_integer.h)" >include/xrpl/basics/tagged_integer.h # cspell: ignore Nikolaos Bougalis nikb
fi
if ! grep -q 'Ritchford' include/xrpl/beast/utility/Zero.h; then
echo -e "// Copyright (c) 2014, Tom Ritchford <tom@swirly.com>\n\n$(cat include/xrpl/beast/utility/Zero.h)" >include/xrpl/beast/utility/Zero.h # cspell: ignore Ritchford
fi
# Restore newlines and tabs in string literals in the affected file.
${SED_COMMAND} -i -E "s@${PLACEHOLDER_NEWLINE}@\\\n@g" src/test/rpc/ValidatorInfo_test.cpp
${SED_COMMAND} -i -E "s@${PLACEHOLDER_TAB}@\\\t@g" src/test/rpc/ValidatorInfo_test.cpp
popd
echo "Removal complete."

View File

@@ -1,42 +0,0 @@
#!/bin/bash
# Exit the script as soon as an error occurs.
set -e
# On MacOS, ensure that GNU sed is installed and available as `gsed`.
SED_COMMAND=sed
if [[ "${OSTYPE}" == 'darwin'* ]]; then
if ! command -v gsed &>/dev/null; then
echo "Error: gsed is not installed. Please install it using 'brew install gnu-sed'."
exit 1
fi
SED_COMMAND=gsed
fi
# This script renames definitions, such as include guards, in this project.
# Specifically, it renames "RIPPLED_XXX" and "RIPPLE_XXX" to "XRPL_XXX" by
# scanning all cmake, header, and source files in the specified directory and
# its subdirectories.
# Usage: .github/scripts/rename/definitions.sh <repository directory>
if [ "$#" -ne 1 ]; then
echo "Usage: $0 <repository directory>"
exit 1
fi
DIRECTORY=$1
echo "Processing directory: ${DIRECTORY}"
if [ ! -d "${DIRECTORY}" ]; then
echo "Error: Directory '${DIRECTORY}' does not exist."
exit 1
fi
find "${DIRECTORY}" -type f \( -name "*.h" -o -name "*.hpp" -o -name "*.ipp" -o -name "*.cpp" \) | while read -r FILE; do
echo "Processing file: ${FILE}"
${SED_COMMAND} -i -E 's@#(define|endif|if|ifdef|ifndef)(.*)(RIPPLED_|RIPPLE_)([A-Z0-9_]+)@#\1\2XRPL_\4@g' "${FILE}"
done
find "${DIRECTORY}" -type f \( -name "*.cmake" -o -name "*.txt" \) | while read -r FILE; do
echo "Processing file: ${FILE}"
${SED_COMMAND} -i -E 's@(RIPPLED_|RIPPLE_)([A-Z0-9_]+)@XRPL_\2@g' "${FILE}"
done
echo "Renaming complete."

View File

@@ -1,96 +0,0 @@
#!/bin/bash
# Exit the script as soon as an error occurs.
set -e
# On MacOS, ensure that GNU sed is installed and available as `gsed`.
SED_COMMAND=sed
if [[ "${OSTYPE}" == 'darwin'* ]]; then
if ! command -v gsed &>/dev/null; then
echo "Error: gsed is not installed. Please install it using 'brew install gnu-sed'."
exit 1
fi
SED_COMMAND=gsed
fi
# This script renames all remaining references to `ripple` and `rippled` to
# `xrpl` and `xrpld`, respectively, in code, comments, and documentation.
# Usage: .github/scripts/rename/docs.sh <repository directory>
if [ "$#" -ne 1 ]; then
echo "Usage: $0 <repository directory>"
exit 1
fi
DIRECTORY=$1
echo "Processing directory: ${DIRECTORY}"
if [ ! -d "${DIRECTORY}" ]; then
echo "Error: Directory '${DIRECTORY}' does not exist."
exit 1
fi
pushd "${DIRECTORY}"
find . -type f \( -name "*.h" -o -name "*.hpp" -o -name "*.ipp" -o -name "*.cpp" -o -name "*.txt" -o -name "*.cfg" -o -name "*.md" -o -name "*.proto" \) -not -path "./.github/scripts/*" | while read -r FILE; do
echo "Processing file: ${FILE}"
${SED_COMMAND} -i 's/rippleLockEscrowMPT/lockEscrowMPT/g' "${FILE}"
${SED_COMMAND} -i 's/rippleUnlockEscrowMPT/unlockEscrowMPT/g' "${FILE}"
${SED_COMMAND} -i 's/rippleCredit/directSendNoFee/g' "${FILE}"
${SED_COMMAND} -i 's/rippleSend/directSendNoLimit/g' "${FILE}"
${SED_COMMAND} -i -E 's@([^/+-])rippled@\1xrpld@g' "${FILE}"
${SED_COMMAND} -i -E 's@([^/+-])Rippled@\1Xrpld@g' "${FILE}"
${SED_COMMAND} -i -E 's/^rippled/xrpld/g' "${FILE}"
${SED_COMMAND} -i -E 's/^Rippled/Xrpld/g' "${FILE}"
# cspell: disable
${SED_COMMAND} -i -E 's/(r|R)ipple (a|A)ddress/XRPL address/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (a|A)ccount/XRPL account/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (a|A)lgorithm/XRPL algorithm/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (c|C)lient/XRPL client/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (c|C)luster/XRPL cluster/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (c|C)onsensus/XRPL consensus/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (d|D)efault/XRPL default/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (e|E)poch/XRPL epoch/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (f|F)eature/XRPL feature/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (n|N)etwork/XRPL network/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (p|P)ayment/XRPL payment/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (p|P)rotocol/XRPL protocol/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (r|R)epository/XRPL repository/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple RPC/XRPL RPC/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (s|S)erialization/XRPL serialization/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (s|S)erver/XRPL server/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (s|S)pecific/XRPL specific/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple Source/XRPL Source/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (t|T)imestamp/XRPL timestamp/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple uses the consensus/XRPL uses the consensus/g' "${FILE}"
${SED_COMMAND} -i -E 's/(r|R)ipple (v|V)alidator/XRPL validator/g' "${FILE}"
# cspell: enable
${SED_COMMAND} -i 's/RippleLib/XrplLib/g' "${FILE}"
${SED_COMMAND} -i 's/ripple-lib/XrplLib/g' "${FILE}"
${SED_COMMAND} -i 's@opt/ripple/@opt/xrpld/@g' "${FILE}"
${SED_COMMAND} -i 's@src/ripple/@src/xrpld/@g' "${FILE}"
${SED_COMMAND} -i 's@ripple/app/@xrpld/app/@g' "${FILE}"
${SED_COMMAND} -i 's@github.com/ripple/rippled@github.com/XRPLF/rippled@g' "${FILE}"
${SED_COMMAND} -i 's/\ba xrpl/an xrpl/g' "${FILE}"
${SED_COMMAND} -i 's/\ba XRPL/an XRPL/g' "${FILE}"
done
${SED_COMMAND} -i 's/ripple_libs/xrpl_libs/' BUILD.md
${SED_COMMAND} -i 's/Ripple integrators/XRPL developers/' README.md
${SED_COMMAND} -i 's/sanitizer-configuration-for-rippled/sanitizer-configuration-for-xrpld/' docs/build/sanitizers.md
${SED_COMMAND} -i 's/rippled/xrpld/g' .github/scripts/levelization/README.md
${SED_COMMAND} -i 's/rippled/xrpld/g' .github/scripts/strategy-matrix/generate.py
${SED_COMMAND} -i 's@/rippled@/xrpld@g' docs/build/install.md
${SED_COMMAND} -i 's@github.com/XRPLF/xrpld@github.com/XRPLF/rippled@g' docs/build/install.md
${SED_COMMAND} -i 's/rippled/xrpld/g' docs/Doxyfile
${SED_COMMAND} -i 's/ripple_basics/basics/' include/xrpl/basics/CountedObject.h
${SED_COMMAND} -i 's/<ripple/<xrpl/' include/xrpl/protocol/AccountID.h
${SED_COMMAND} -i 's/Ripple:/the XRPL:/g' include/xrpl/protocol/SecretKey.h
${SED_COMMAND} -i 's/Ripple:/the XRPL:/g' include/xrpl/protocol/Seed.h
${SED_COMMAND} -i 's/ripple/xrpl/g' src/test/README.md
${SED_COMMAND} -i 's/www.ripple.com/www.xrpl.org/g' src/test/protocol/Seed_test.cpp
# Restore specific changes.
${SED_COMMAND} -i 's@b5efcc/src/xrpld@b5efcc/src/ripple@' include/xrpl/protocol/README.md
${SED_COMMAND} -i 's/dbPrefix_ = "xrpldb"/dbPrefix_ = "rippledb"/' src/xrpld/app/misc/SHAMapStoreImp.h # cspell: disable-line
${SED_COMMAND} -i 's/kConfigLegacyName = "xrpld.cfg"/kConfigLegacyName = "rippled.cfg"/' src/xrpld/core/detail/Config.cpp
popd
echo "Renaming complete."

View File

@@ -1,30 +0,0 @@
#!/bin/bash
# Exit the script as soon as an error occurs.
set -e
# This script checks whether there are no new include guards introduced by a new
# PR, as header files should use "#pragma once" instead. The script assumes any
# include guards will use "XRPL_" as prefix.
# Usage: .github/scripts/rename/include.sh <repository directory>
if [ "$#" -ne 1 ]; then
echo "Usage: $0 <repository directory>"
exit 1
fi
DIRECTORY=$1
echo "Processing directory: ${DIRECTORY}"
if [ ! -d "${DIRECTORY}" ]; then
echo "Error: Directory '${DIRECTORY}' does not exist."
exit 1
fi
find "${DIRECTORY}" -type f \( -name "*.h" -o -name "*.hpp" -o -name "*.ipp" \) | while read -r FILE; do
echo "Processing file: ${FILE}"
if grep -q "#ifndef XRPL_" "${FILE}"; then
echo "Please replace all include guards by #pragma once."
exit 1
fi
done
echo "Checking complete."

View File

@@ -1,59 +0,0 @@
#!/bin/bash
# Exit the script as soon as an error occurs.
set -e
# On MacOS, ensure that GNU sed is installed and available as `gsed`.
SED_COMMAND=sed
if [[ "${OSTYPE}" == 'darwin'* ]]; then
if ! command -v gsed &>/dev/null; then
echo "Error: gsed is not installed. Please install it using 'brew install gnu-sed'."
exit 1
fi
SED_COMMAND=gsed
fi
# This script renames the `ripple` namespace to `xrpl` in this project.
# Specifically, it renames all occurrences of `namespace ripple` and `ripple::`
# to `namespace xrpl` and `xrpl::`, respectively, by scanning all header and
# source files in the specified directory and its subdirectories, as well as any
# occurrences in the documentation. It also renames them in the test suites.
# Usage: .github/scripts/rename/namespace.sh <repository directory>
if [ "$#" -ne 1 ]; then
echo "Usage: $0 <repository directory>"
exit 1
fi
DIRECTORY=$1
echo "Processing directory: ${DIRECTORY}"
if [ ! -d "${DIRECTORY}" ]; then
echo "Error: Directory '${DIRECTORY}' does not exist."
exit 1
fi
pushd "${DIRECTORY}"
DIRECTORIES=("include" "src" "tests")
for DIRECTORY in "${DIRECTORIES[@]}"; do
echo "Processing directory: ${DIRECTORY}"
find "${DIRECTORY}" -type f \( -name "*.h" -o -name "*.hpp" -o -name "*.ipp" -o -name "*.cpp" -o -name "*.macro" \) | while read -r FILE; do
echo "Processing file: ${FILE}"
${SED_COMMAND} -i 's/namespace ripple/namespace xrpl/g' "${FILE}"
${SED_COMMAND} -i 's/ripple::/xrpl::/g' "${FILE}"
${SED_COMMAND} -i 's/"ripple:/"xrpl::/g' "${FILE}"
${SED_COMMAND} -i -E 's/(BEAST_DEFINE_TESTSUITE.+)ripple(.+)/\1xrpl\2/g' "${FILE}"
done
done
# Special case for NuDBFactory that has ripple twice in the test suite name.
${SED_COMMAND} -i -E 's/(BEAST_DEFINE_TESTSUITE.+)ripple(.+)/\1xrpl\2/g' src/test/nodestore/NuDBFactory_test.cpp
DIRECTORY=$1
find "${DIRECTORY}" -type f -name "*.md" | while read -r FILE; do
echo "Processing file: ${FILE}"
${SED_COMMAND} -i 's/ripple::/xrpl::/g' "${FILE}"
done
popd
echo "Renaming complete."

View File

@@ -1,322 +0,0 @@
#!/usr/bin/env python3
import argparse
import dataclasses
import itertools
import json
from pathlib import Path
THIS_DIR = Path(__file__).parent.resolve()
_BASE_CMAKE_ARGS = ["-Dtests=ON", "-Dwerr=ON", "-Dxrpld=ON", "-Dwextra=ON"]
# Maps sanitizer names (as used in cmake) to short config-name suffixes.
_SANITIZER_SUFFIX: dict[str, str] = {
"address": "asan",
"undefinedbehavior": "ubsan",
"thread": "tsan",
}
def get_cmake_args(build_type: str, extra_args: str) -> str:
"""Get the full list of CMake arguments for a config."""
args = _BASE_CMAKE_ARGS.copy()
if extra_args:
args.extend(extra_args.split())
return " ".join(args)
def runs_on_event(exclude_event_types: list[str], event: str | None) -> bool:
"""Whether a config should run for the current event.
'exclude_event_types' is a list of GitHub event names (e.g.
["pull_request"]) on which the config should NOT run; an empty list means
the config runs on every event. When no event is given (event is None), no
filtering is applied.
"""
if event is None:
return True
return event not in exclude_event_types
# ---------------------------------------------------------------------------
# Input types — shapes of the JSON config files
# ---------------------------------------------------------------------------
@dataclasses.dataclass
class LinuxConfig:
"""One entry in linux.json's 'configs' or 'package_configs' arrays."""
compiler: list[str]
build_type: list[str]
arch: list[str]
sanitizers: list[str] = dataclasses.field(default_factory=list)
suffix: str = ""
extra_cmake_args: str = ""
image: str = "" # only used by package_configs entries
# List of GitHub event names (e.g. "pull_request") on which this config
# should NOT run. Empty means it runs on every event.
exclude_event_types: list[str] = dataclasses.field(default_factory=list)
@dataclasses.dataclass
class LinuxFile:
"""Shape of linux.json."""
image_tag: str
configs: dict[str, list[LinuxConfig]] # distro → configs
package_configs: dict[str, list[LinuxConfig]] # distro → packaging configs
@classmethod
def load(cls, path: Path) -> "LinuxFile":
data = json.loads(path.read_text())
def parse(section: dict) -> dict[str, list[LinuxConfig]]:
return {
distro: [LinuxConfig(**c) for c in cfgs]
for distro, cfgs in section.items()
}
return cls(
image_tag=data["image_tag"],
configs=parse(data["configs"]),
package_configs=parse(data.get("package_configs", {})),
)
@dataclasses.dataclass
class PlatformConfig:
"""One entry in macos.json's or windows.json's 'configs' array."""
build_type: list[str]
build_only: bool = False # if true, skip tests (e.g. macos/Windows Debug)
extra_cmake_args: str = ""
# List of GitHub event names (e.g. "pull_request") on which this config
# should NOT run. Empty means it runs on every event.
exclude_event_types: list[str] = dataclasses.field(default_factory=list)
def __post_init__(self) -> None:
if isinstance(self.build_type, str):
self.build_type = [self.build_type]
@dataclasses.dataclass
class PlatformFile:
"""Shape of macos.json and windows.json."""
platform: str # e.g. "macos/arm64" or "windows/amd64"
runner: list[str] # GitHub Actions runner labels
configs: list[PlatformConfig]
@classmethod
def load(cls, path: Path) -> "PlatformFile":
data = json.loads(path.read_text())
return cls(
platform=data["platform"],
runner=data["runner"],
configs=[PlatformConfig(**c) for c in data["configs"]],
)
# ---------------------------------------------------------------------------
# Output types — shapes of the generated GitHub Actions matrix entries
# ---------------------------------------------------------------------------
@dataclasses.dataclass
class Architecture:
platform: str
runner: list[str]
@dataclasses.dataclass
class MatrixEntry:
"""One entry in the generated build/test strategy matrix."""
config_name: str
cmake_args: str
cmake_target: str
build_only: bool
build_type: str
architecture: Architecture
sanitizers: str
image: str = "" # container image; empty for macOS/Windows (runs natively)
compiler: str = "" # compiler name ("gcc" or "clang"); empty for macOS/Windows
@dataclasses.dataclass
class PackagingEntry:
"""One entry in the generated packaging strategy matrix."""
artifact_name: str
image: str
distro: str # e.g. "debian" or "rhel"; drives package-format-specific steps
# ---------------------------------------------------------------------------
# Matrix expansion
# ---------------------------------------------------------------------------
_ARCHS: dict[str, Architecture] = {
"amd64": Architecture(
platform="linux/amd64", runner=["self-hosted", "Linux", "X64", "heavy"]
),
"arm64": Architecture(
platform="linux/arm64",
runner=["self-hosted", "Linux", "ARM64", "heavy-arm64"],
),
}
def expand_linux_matrix(
linux: LinuxFile, event: str | None = None
) -> list[MatrixEntry]:
"""Expand a LinuxFile into a flat list of matrix entries.
Each config entry is expanded over the cross-product of its
compiler, build_type, sanitizers, and architecture lists. Configs that
exclude the current event are skipped.
"""
entries: list[MatrixEntry] = []
for distro, configs in linux.configs.items():
for cfg in configs:
if not runs_on_event(cfg.exclude_event_types, event):
continue
# An empty sanitizers list means "one entry with no sanitizer".
effective_sanitizers = cfg.sanitizers or [""]
effective_archs = {arch: _ARCHS[arch] for arch in cfg.arch}
for compiler, build_type, sanitizer, (arch, arch_info) in itertools.product(
cfg.compiler,
cfg.build_type,
effective_sanitizers,
effective_archs.items(),
):
name = f"{distro}-{compiler}-{build_type.lower()}-{arch}"
suffix_parts = [
s for s in [cfg.suffix, _SANITIZER_SUFFIX.get(sanitizer, "")] if s
]
if suffix_parts:
name += "-" + "-".join(suffix_parts)
entries.append(
MatrixEntry(
config_name=name,
image=f"ghcr.io/xrplf/xrpld/nix-{distro}:{linux.image_tag}",
cmake_args=get_cmake_args(build_type, cfg.extra_cmake_args),
cmake_target="all",
build_only=False,
build_type=build_type,
architecture=arch_info,
sanitizers=sanitizer,
compiler=compiler,
)
)
return entries
def expand_linux_packaging(linux: LinuxFile) -> list[PackagingEntry]:
"""Generate the packaging matrix from a LinuxFile's package_configs section.
Packaging uses vanilla distro images (debian:bookworm, ubi9, …) instead of
the nix-based build images, because deb/rpm tooling (debhelper, rpm-build)
is taken from the distro's archive rather than from nixpkgs. Each config
entry carries its own 'image'.
"""
entries = []
for distro, configs in linux.package_configs.items():
for cfg in configs:
for compiler, build_type in itertools.product(cfg.compiler, cfg.build_type):
entries.append(
PackagingEntry(
artifact_name=f"xrpld-{distro}-{compiler}-{build_type.lower()}-amd64",
image=cfg.image,
distro=distro,
)
)
return entries
def expand_platform_matrix(
pf: PlatformFile, event: str | None = None
) -> list[MatrixEntry]:
"""Expand a PlatformFile (macOS or Windows) into matrix entries.
Configs that exclude the current event are skipped.
"""
platform_name, arch = pf.platform.split("/")
is_windows = platform_name == "windows"
entries: list[MatrixEntry] = []
for cfg in pf.configs:
if not runs_on_event(cfg.exclude_event_types, event):
continue
for build_type in cfg.build_type:
entries.append(
MatrixEntry(
config_name=f"{platform_name}-{arch}-{build_type.lower()}",
cmake_args=get_cmake_args(build_type, cfg.extra_cmake_args),
cmake_target="install" if is_windows else "all",
build_only=cfg.build_only,
build_type=build_type,
architecture=Architecture(platform=pf.platform, runner=pf.runner),
sanitizers="",
)
)
return entries
# ---------------------------------------------------------------------------
# Entry point
# ---------------------------------------------------------------------------
if __name__ == "__main__":
parser = argparse.ArgumentParser(
description="Generate a CI strategy matrix for all platforms or a specific one."
)
parser.add_argument(
"-c",
"--config",
help="Platform to generate for ('linux', 'macos', or 'windows'). Defaults to all platforms.",
choices=["linux", "macos", "windows"],
default=None,
)
parser.add_argument(
"-p",
"--packaging",
help="Emit the Linux packaging matrix instead of the build/test matrix.",
action="store_true",
)
parser.add_argument(
"-e",
"--event",
help="The GitHub event name that triggered the workflow (e.g. 'push', "
"'pull_request'). Configs are filtered by their 'event_type'. If "
"omitted, no filtering is applied.",
default=None,
)
args = parser.parse_args()
matrix: list[MatrixEntry] | list[PackagingEntry] = []
if args.packaging:
matrix = expand_linux_packaging(LinuxFile.load(THIS_DIR / "linux.json"))
else:
if args.config in ("linux", None):
matrix += expand_linux_matrix(
LinuxFile.load(THIS_DIR / "linux.json"), args.event
)
if args.config in ("macos", None):
matrix += expand_platform_matrix(
PlatformFile.load(THIS_DIR / "macos.json"), args.event
)
if args.config in ("windows", None):
matrix += expand_platform_matrix(
PlatformFile.load(THIS_DIR / "windows.json"), args.event
)
print(f"matrix={json.dumps({'include': [dataclasses.asdict(e) for e in matrix]})}")

View File

@@ -1,84 +0,0 @@
{
"image_tag": "sha-e29b523",
"configs": {
"ubuntu": [
{
"compiler": ["gcc", "clang"],
"build_type": ["Debug", "Release"],
"arch": ["amd64", "arm64"]
},
{
"compiler": ["gcc", "clang"],
"build_type": ["Debug", "Release"],
"arch": ["amd64"],
"sanitizers": ["address", "undefinedbehavior"]
},
{
"compiler": ["gcc"],
"build_type": ["Debug"],
"arch": ["amd64"],
"suffix": "coverage",
"extra_cmake_args": "-DUNIT_TEST_REFERENCE_FEE=500 -Dcoverage=ON -Dcoverage_format=xml -DCODE_COVERAGE_VERBOSE=ON -DCMAKE_C_FLAGS=-O0 -DCMAKE_CXX_FLAGS=-O0"
},
{
"compiler": ["clang"],
"build_type": ["Debug"],
"arch": ["amd64"],
"suffix": "voidstar",
"extra_cmake_args": "-Dvoidstar=ON"
},
{
"compiler": ["clang"],
"build_type": ["Release"],
"arch": ["amd64"],
"suffix": "reffee",
"extra_cmake_args": "-DUNIT_TEST_REFERENCE_FEE=1000"
},
{
"compiler": ["gcc"],
"build_type": ["Debug"],
"arch": ["amd64"],
"suffix": "unity",
"extra_cmake_args": "-Dunity=ON",
"exclude_event_types": ["pull_request"]
}
],
"debian": [
{
"compiler": ["gcc"],
"build_type": ["Release"],
"arch": ["amd64"]
}
],
"rhel": [
{
"compiler": ["gcc"],
"build_type": ["Release"],
"arch": ["amd64"]
}
]
},
"package_configs": {
"debian": [
{
"compiler": ["gcc"],
"build_type": ["Release"],
"arch": ["amd64"],
"image": "ghcr.io/xrplf/xrpld/packaging-debian:sha-577d745"
}
],
"rhel": [
{
"compiler": ["gcc"],
"build_type": ["Release"],
"arch": ["amd64"],
"image": "ghcr.io/xrplf/xrpld/packaging-rhel:sha-577d745"
}
]
}
}

View File

@@ -1,16 +0,0 @@
{
"platform": "macos/arm64",
"runner": ["self-hosted", "macOS", "ARM64", "macos-26-apple-clang-21"],
"configs": [
{
"build_type": "Release",
"extra_cmake_args": "-DCMAKE_POLICY_VERSION_MINIMUM=3.5"
},
{
"build_type": "Debug",
"extra_cmake_args": "-DCMAKE_POLICY_VERSION_MINIMUM=3.5",
"build_only": true,
"exclude_event_types": ["pull_request"]
}
]
}

View File

@@ -1,12 +0,0 @@
{
"platform": "windows/amd64",
"runner": ["self-hosted", "Windows", "dev-box-windows-2026"],
"configs": [
{ "build_type": "Release" },
{
"build_type": "Debug",
"build_only": true,
"exclude_event_types": ["pull_request"]
}
]
}

View File

@@ -1,62 +0,0 @@
name: Build Nix Docker images
on:
push:
branches:
- develop
paths:
- ".github/workflows/build-nix-images.yml"
- "flake.nix"
- "flake.lock"
- "nix/**"
- "!nix/docker/README.md"
- "!nix/devshell.nix"
- "bin/check-tools.sh"
- "bin/install-sanitizer-libs.sh"
pull_request:
paths:
- ".github/workflows/build-nix-images.yml"
- "flake.nix"
- "flake.lock"
- "nix/**"
- "!nix/docker/README.md"
- "!nix/devshell.nix"
- "bin/check-tools.sh"
- "bin/install-sanitizer-libs.sh"
workflow_dispatch:
concurrency:
# Read `on-trigger.yml` for the rationale behind this concurrency group name.
group: ${{ github.workflow }}-${{ github.event_name == 'push' && github.ref == 'refs/heads/develop' && github.sha || github.ref }}
cancel-in-progress: true
defaults:
run:
shell: bash
jobs:
build-merge:
name: Build and push nix-${{ matrix.distro.name }}
permissions:
contents: read
packages: write
strategy:
fail-fast: false
matrix:
# The base images are the oldest supported version of each distro
# that we want to build images for.
distro:
- name: nixos
base_image: nixos/nix:latest
- name: ubuntu
base_image: ubuntu:20.04
- name: debian
base_image: debian:bookworm
- name: rhel
base_image: registry.access.redhat.com/ubi9/ubi:latest
uses: XRPLF/actions/.github/workflows/build-multiarch-image.yml@ee03d31bcc4501d7599dc1b1ecd7a34af582ad1c
with:
image_name: xrpld/nix-${{ matrix.distro.name }}
dockerfile: nix/docker/Dockerfile
base_image: ${{ matrix.distro.base_image }}
push: ${{ github.event_name == 'push' }}

View File

@@ -1,46 +0,0 @@
name: Build packaging Docker images
on:
push:
branches:
- develop
paths:
- ".github/workflows/build-packaging-images.yml"
- "package/Dockerfile"
- "package/install-packaging-tools.sh"
pull_request:
paths:
- ".github/workflows/build-packaging-images.yml"
- "package/Dockerfile"
- "package/install-packaging-tools.sh"
workflow_dispatch:
concurrency:
# Read `on-trigger.yml` for the rationale behind this concurrency group name.
group: ${{ github.workflow }}-${{ github.event_name == 'push' && github.ref == 'refs/heads/develop' && github.sha || github.ref }}
cancel-in-progress: true
defaults:
run:
shell: bash
jobs:
build-merge:
name: Build and push packaging-${{ matrix.distro.name }}
permissions:
contents: read
packages: write
strategy:
fail-fast: false
matrix:
distro:
- name: debian
base_image: debian:bookworm
- name: rhel
base_image: registry.access.redhat.com/ubi9/ubi:latest
uses: XRPLF/actions/.github/workflows/build-multiarch-image.yml@ee03d31bcc4501d7599dc1b1ecd7a34af582ad1c
with:
image_name: xrpld/packaging-${{ matrix.distro.name }}
dockerfile: package/Dockerfile
base_image: ${{ matrix.distro.base_image }}
push: ${{ github.event_name == 'push' }}

View File

@@ -1,13 +0,0 @@
name: Check PR commits
on:
pull_request_target:
# The action needs to have write permissions to post comments on the PR.
permissions:
contents: read
pull-requests: write
jobs:
check_commits:
uses: XRPLF/actions/.github/workflows/check-pr-commits.yml@e2c7f400d1e85ae65dad552fd425169fbacca4a3

View File

@@ -1,39 +0,0 @@
name: Check PR description
on:
merge_group:
types:
- checks_requested
pull_request:
types:
- opened
- edited
- reopened
- synchronize
- ready_for_review
branches:
- develop
- "release-*"
- "release/*"
- "staging/*"
jobs:
check_description:
if: ${{ github.event.pull_request.draft != true }}
runs-on: ubuntu-latest
steps:
- name: Checkout repository
uses: actions/checkout@9c091bb21b7c1c1d1991bb908d89e4e9dddfe3e0 # v7.0.0
- name: Write PR body to file
env:
PR_BODY: ${{ github.event.pull_request.body }}
if: ${{ github.event_name == 'pull_request' }}
run: printenv PR_BODY >pr_body.md
- name: Check PR description differs from template
if: ${{ github.event_name == 'pull_request' }}
run: |
python .github/scripts/check-pr-description.py \
--template-file .github/pull_request_template.md \
--pr-body-file pr_body.md

View File

@@ -1,23 +0,0 @@
name: Check PR title
on:
merge_group:
types:
- checks_requested
pull_request:
types:
- opened
- edited
- reopened
- synchronize
- ready_for_review
branches:
- develop
- "release-*"
- "release/*"
- "staging/*"
jobs:
check_title:
if: ${{ github.event.pull_request.draft != true }}
uses: XRPLF/actions/.github/workflows/check-pr-title.yml@cba1f0891650baf1a9c88624dc2d72573be2eb81

63
.github/workflows/clang-format.yml vendored Normal file
View File

@@ -0,0 +1,63 @@
name: clang-format
on:
push:
pull_request:
types: [opened, reopened, synchronize, ready_for_review]
jobs:
check:
if: ${{ github.event_name == 'push' || github.event.pull_request.draft != true || contains(github.event.pull_request.labels.*.name, 'DraftRunCI') }}
runs-on: ubuntu-24.04
env:
CLANG_VERSION: 18
steps:
- uses: actions/checkout@v4
- name: Install clang-format
run: |
codename=$( lsb_release --codename --short )
sudo tee /etc/apt/sources.list.d/llvm.list >/dev/null <<EOF
deb http://apt.llvm.org/${codename}/ llvm-toolchain-${codename}-${CLANG_VERSION} main
deb-src http://apt.llvm.org/${codename}/ llvm-toolchain-${codename}-${CLANG_VERSION} main
EOF
wget -O - https://apt.llvm.org/llvm-snapshot.gpg.key | sudo apt-key add
sudo apt-get update
sudo apt-get install clang-format-${CLANG_VERSION}
- name: Format first-party sources
run: find include src tests -type f \( -name '*.cpp' -o -name '*.hpp' -o -name '*.h' -o -name '*.ipp' \) -exec clang-format-${CLANG_VERSION} -i {} +
- name: Check for differences
id: assert
run: |
set -o pipefail
git diff --exit-code | tee "clang-format.patch"
- name: Upload patch
if: failure() && steps.assert.outcome == 'failure'
uses: actions/upload-artifact@v4
continue-on-error: true
with:
name: clang-format.patch
if-no-files-found: ignore
path: clang-format.patch
- name: What happened?
if: failure() && steps.assert.outcome == 'failure'
env:
PREAMBLE: |
If you are reading this, you are looking at a failed Github Actions
job. That means you pushed one or more files that did not conform
to the formatting specified in .clang-format. That may be because
you neglected to run 'git clang-format' or 'clang-format' before
committing, or that your version of clang-format has an
incompatibility with the one on this
machine, which is:
SUGGESTION: |
To fix it, you can do one of two things:
1. Download and apply the patch generated as an artifact of this
job to your repo, commit, and push.
2. Run 'git-clang-format --extensions cpp,h,hpp,ipp develop'
in your repo, commit, and push.
run: |
echo "${PREAMBLE}"
clang-format-${CLANG_VERSION} --version
echo "${SUGGESTION}"
exit 1

View File

@@ -1,25 +0,0 @@
name: Label PRs with merge conflicts
on:
# So that PRs touching the same files as the push are updated.
push:
# So that the `dirtyLabel` is removed if conflicts are resolved.
# We recommend `pull_request_target` so that github secrets are available.
# In `pull_request` we wouldn't be able to change labels of fork PRs.
pull_request_target:
types: [synchronize]
permissions:
pull-requests: write
jobs:
main:
runs-on: ubuntu-latest
steps:
- name: Check if PRs are dirty
uses: eps1lon/actions-label-merge-conflict@0273be72a0bbd58fcd71d0d6c02c209b50d1e5e1 # v3.1.0
with:
dirtyLabel: "PR: has conflicts"
repoToken: "${{ secrets.GITHUB_TOKEN }}"
commentOnDirty: "This PR has conflicts, please resolve them in order for the PR to be reviewed."
commentOnClean: "All conflicts have been resolved. Assigned reviewers can now start or resume their review."

37
.github/workflows/doxygen.yml vendored Normal file
View File

@@ -0,0 +1,37 @@
name: Build and publish Doxygen documentation
# To test this workflow, push your changes to your fork's `develop` branch.
on:
push:
branches:
- develop
- doxygen
concurrency:
group: ${{ github.workflow }}-${{ github.ref }}
cancel-in-progress: true
jobs:
documentation:
runs-on: ubuntu-latest
permissions:
contents: write
container: ghcr.io/xrplf/rippled-build-ubuntu:aaf5e3e
steps:
- name: checkout
uses: actions/checkout@v4
- name: check environment
run: |
echo ${PATH} | tr ':' '\n'
cmake --version
doxygen --version
env | sort
- name: build
run: |
mkdir build
cd build
cmake -Donly_docs=TRUE ..
cmake --build . --target docs --parallel $(nproc)
- name: publish
uses: peaceiris/actions-gh-pages@v3
with:
github_token: ${{ secrets.GITHUB_TOKEN }}
publish_dir: build/docs/html

53
.github/workflows/levelization.yml vendored Normal file
View File

@@ -0,0 +1,53 @@
name: levelization
on:
push:
pull_request:
types: [opened, reopened, synchronize, ready_for_review]
jobs:
check:
if: ${{ github.event_name == 'push' || github.event.pull_request.draft != true || contains(github.event.pull_request.labels.*.name, 'DraftRunCI') }}
runs-on: ubuntu-latest
env:
CLANG_VERSION: 10
steps:
- uses: actions/checkout@v4
- name: Check levelization
run: Builds/levelization/levelization.sh
- name: Check for differences
id: assert
run: |
set -o pipefail
git diff --exit-code | tee "levelization.patch"
- name: Upload patch
if: failure() && steps.assert.outcome == 'failure'
uses: actions/upload-artifact@v4
continue-on-error: true
with:
name: levelization.patch
if-no-files-found: ignore
path: levelization.patch
- name: What happened?
if: failure() && steps.assert.outcome == 'failure'
env:
MESSAGE: |
If you are reading this, you are looking at a failed Github
Actions job. That means you changed the dependency relationships
between the modules in rippled. That may be an improvement or a
regression. This check doesn't judge.
A rule of thumb, though, is that if your changes caused
something to be removed from loops.txt, that's probably an
improvement. If something was added, it's probably a regression.
To fix it, you can do one of two things:
1. Download and apply the patch generated as an artifact of this
job to your repo, commit, and push.
2. Run './Builds/levelization/levelization.sh' in your repo,
commit, and push.
See Builds/levelization/README.md for more info.
run: |
echo "${MESSAGE}"
exit 1

91
.github/workflows/libxrpl.yml vendored Normal file
View File

@@ -0,0 +1,91 @@
name: Check libXRPL compatibility with Clio
env:
CONAN_URL: http://18.143.149.228:8081/artifactory/api/conan/conan-non-prod
CONAN_LOGIN_USERNAME_RIPPLE: ${{ secrets.CONAN_USERNAME }}
CONAN_PASSWORD_RIPPLE: ${{ secrets.CONAN_TOKEN }}
on:
pull_request:
paths:
- 'src/libxrpl/protocol/BuildInfo.cpp'
- '.github/workflows/libxrpl.yml'
types: [opened, reopened, synchronize, ready_for_review]
concurrency:
group: ${{ github.workflow }}-${{ github.ref }}
cancel-in-progress: true
jobs:
publish:
if: ${{ github.event_name == 'push' || github.event.pull_request.draft != true || contains(github.event.pull_request.labels.*.name, 'DraftRunCI') }}
name: Publish libXRPL
outputs:
outcome: ${{ steps.upload.outputs.outcome }}
version: ${{ steps.version.outputs.version }}
channel: ${{ steps.channel.outputs.channel }}
runs-on: [self-hosted, heavy]
container: ghcr.io/xrplf/rippled-build-ubuntu:aaf5e3e
steps:
- name: Wait for essential checks to succeed
uses: lewagon/wait-on-check-action@v1.3.4
with:
ref: ${{ github.event.pull_request.head.sha || github.sha }}
running-workflow-name: wait-for-check-regexp
check-regexp: '(dependencies|test).*linux.*' # Ignore windows and mac tests but make sure linux passes
repo-token: ${{ secrets.GITHUB_TOKEN }}
wait-interval: 10
- name: Checkout
uses: actions/checkout@v4
- name: Generate channel
id: channel
shell: bash
run: |
echo channel="clio/pr_${{ github.event.pull_request.number }}" | tee ${GITHUB_OUTPUT}
- name: Export new package
shell: bash
run: |
conan export . ${{ steps.channel.outputs.channel }}
- name: Add Ripple Conan remote
shell: bash
run: |
conan remote list
conan remote remove ripple || true
# Do not quote the URL. An empty string will be accepted (with a non-fatal warning), but a missing argument will not.
conan remote add ripple ${{ env.CONAN_URL }} --insert 0
- name: Parse new version
id: version
shell: bash
run: |
echo version="$(cat src/libxrpl/protocol/BuildInfo.cpp | grep "versionString =" \
| awk -F '"' '{print $2}')" | tee ${GITHUB_OUTPUT}
- name: Try to authenticate to Ripple Conan remote
id: remote
shell: bash
run: |
# `conan user` implicitly uses the environment variables CONAN_LOGIN_USERNAME_<REMOTE> and CONAN_PASSWORD_<REMOTE>.
# https://docs.conan.io/1/reference/commands/misc/user.html#using-environment-variables
# https://docs.conan.io/1/reference/env_vars.html#conan-login-username-conan-login-username-remote-name
# https://docs.conan.io/1/reference/env_vars.html#conan-password-conan-password-remote-name
echo outcome=$(conan user --remote ripple --password >&2 \
&& echo success || echo failure) | tee ${GITHUB_OUTPUT}
- name: Upload new package
id: upload
if: (steps.remote.outputs.outcome == 'success')
shell: bash
run: |
echo "conan upload version ${{ steps.version.outputs.version }} on channel ${{ steps.channel.outputs.channel }}"
echo outcome=$(conan upload xrpl/${{ steps.version.outputs.version }}@${{ steps.channel.outputs.channel }} --remote ripple --confirm >&2 \
&& echo success || echo failure) | tee ${GITHUB_OUTPUT}
notify_clio:
name: Notify Clio
runs-on: ubuntu-latest
needs: publish
env:
GH_TOKEN: ${{ secrets.CLIO_NOTIFY_TOKEN }}
steps:
- name: Notify Clio about new version
if: (needs.publish.outputs.outcome == 'success')
shell: bash
run: |
gh api --method POST -H "Accept: application/vnd.github+json" -H "X-GitHub-Api-Version: 2022-11-28" \
/repos/xrplf/clio/dispatches -f "event_type=check_libxrpl" \
-F "client_payload[version]=${{ needs.publish.outputs.version }}@${{ needs.publish.outputs.channel }}" \
-F "client_payload[pr]=${{ github.event.pull_request.number }}"

99
.github/workflows/macos.yml vendored Normal file
View File

@@ -0,0 +1,99 @@
name: macos
on:
pull_request:
types: [opened, reopened, synchronize, ready_for_review]
push:
# If the branches list is ever changed, be sure to change it on all
# build/test jobs (nix, macos, windows, instrumentation)
branches:
# Always build the package branches
- develop
- release
- master
# Branches that opt-in to running
- 'ci/**'
concurrency:
group: ${{ github.workflow }}-${{ github.ref }}
cancel-in-progress: true
jobs:
test:
if: ${{ github.event_name == 'push' || github.event.pull_request.draft != true || contains(github.event.pull_request.labels.*.name, 'DraftRunCI') }}
strategy:
matrix:
platform:
- macos
generator:
- Ninja
configuration:
- Release
runs-on: [self-hosted, macOS]
env:
# The `build` action requires these variables.
build_dir: .build
NUM_PROCESSORS: 12
steps:
- name: checkout
uses: actions/checkout@v4
- name: install Conan
run: |
brew install conan@1
echo '/opt/homebrew/opt/conan@1/bin' >> $GITHUB_PATH
- name: install Ninja
if: matrix.generator == 'Ninja'
run: brew install ninja
- name: install python
run: |
if which python > /dev/null 2>&1; then
echo "Python executable exists"
else
brew install python@3.13
ln -s /opt/homebrew/bin/python3 /opt/homebrew/bin/python
fi
- name: install cmake
run: |
if which cmake > /dev/null 2>&1; then
echo "cmake executable exists"
else
brew install cmake
fi
- name: install nproc
run: |
brew install coreutils
- name: check environment
run: |
env | sort
echo ${PATH} | tr ':' '\n'
python --version
conan --version
cmake --version
nproc --version
echo -n "nproc returns: "
nproc
system_profiler SPHardwareDataType
sysctl -n hw.logicalcpu
clang --version
- name: configure Conan
run : |
conan profile new default --detect || true
conan profile update settings.compiler.cppstd=20 default
- name: build dependencies
uses: ./.github/actions/dependencies
env:
CONAN_URL: http://18.143.149.228:8081/artifactory/api/conan/conan-non-prod
CONAN_LOGIN_USERNAME_RIPPLE: ${{ secrets.CONAN_USERNAME }}
CONAN_PASSWORD_RIPPLE: ${{ secrets.CONAN_TOKEN }}
with:
configuration: ${{ matrix.configuration }}
- name: build
uses: ./.github/actions/build
with:
generator: ${{ matrix.generator }}
configuration: ${{ matrix.configuration }}
cmake-args: "-Dassert=TRUE -Dwerr=TRUE ${{ matrix.cmake-args }}"
- name: test
run: |
n=$(nproc)
echo "Using $n test jobs"
${build_dir}/rippled --unittest --unittest-jobs $n

60
.github/workflows/missing-commits.yml vendored Normal file
View File

@@ -0,0 +1,60 @@
name: missing-commits
on:
push:
branches:
# Only check that the branches are up to date when updating the
# relevant branches.
- develop
- release
jobs:
up_to_date:
runs-on: ubuntu-24.04
steps:
- uses: actions/checkout@v4
with:
fetch-depth: 0
- name: Check for missing commits
id: commits
env:
SUGGESTION: |
If you are reading this, then the commits indicated above are
missing from "develop" and/or "release". Do a reverse-merge
as soon as possible. See CONTRIBUTING.md for instructions.
run: |
set -o pipefail
# Branches ordered by how "canonical" they are. Every commit in
# one branch should be in all the branches behind it
order=( master release develop )
branches=()
for branch in "${order[@]}"
do
# Check that the branches exist so that this job will work on
# forked repos, which don't necessarily have master and
# release branches.
if git ls-remote --exit-code --heads origin \
refs/heads/${branch} > /dev/null
then
branches+=( origin/${branch} )
fi
done
prior=()
for branch in "${branches[@]}"
do
if [[ ${#prior[@]} -ne 0 ]]
then
echo "Checking ${prior[@]} for commits missing from ${branch}"
git log --oneline --no-merges "${prior[@]}" \
^$branch | tee -a "missing-commits.txt"
echo
fi
prior+=( "${branch}" )
done
if [[ $( cat missing-commits.txt | wc -l ) -ne 0 ]]
then
echo "${SUGGESTION}"
exit 1
fi

444
.github/workflows/nix.yml vendored Normal file
View File

@@ -0,0 +1,444 @@
name: nix
on:
pull_request:
types: [opened, reopened, synchronize, ready_for_review]
push:
# If the branches list is ever changed, be sure to change it on all
# build/test jobs (nix, macos, windows)
branches:
# Always build the package branches
- develop
- release
- master
# Branches that opt-in to running
- "ci/**"
concurrency:
group: ${{ github.workflow }}-${{ github.ref }}
cancel-in-progress: true
# This workflow has multiple job matrixes.
# They can be considered phases because most of the matrices ("test",
# "coverage", "conan", ) depend on the first ("dependencies").
#
# The first phase has a job in the matrix for each combination of
# variables that affects dependency ABI:
# platform, compiler, and configuration.
# It creates a GitHub artifact holding the Conan profile,
# and builds and caches binaries for all the dependencies.
# If an Artifactory remote is configured, they are cached there.
# If not, they are added to the GitHub artifact.
# GitHub's "cache" action has a size limit (10 GB) that is too small
# to hold the binaries if they are built locally.
# We must use the "{upload,download}-artifact" actions instead.
#
# The remaining phases have a job in the matrix for each test
# configuration. They install dependency binaries from the cache,
# whichever was used, and build and test rippled.
#
# "instrumentation" is independent, but is included here because it also
# builds on linux in the same "on:" conditions.
jobs:
dependencies:
if: ${{ github.event_name == 'push' || github.event.pull_request.draft != true || contains(github.event.pull_request.labels.*.name, 'DraftRunCI') }}
strategy:
fail-fast: false
matrix:
platform:
- linux
compiler:
- gcc
- clang
configuration:
- Debug
- Release
include:
- compiler: gcc
profile:
version: 11
cc: /usr/bin/gcc
cxx: /usr/bin/g++
- compiler: clang
profile:
version: 14
cc: /usr/bin/clang-14
cxx: /usr/bin/clang++-14
runs-on: [self-hosted, heavy]
container: ghcr.io/xrplf/rippled-build-ubuntu:aaf5e3e
env:
build_dir: .build
steps:
- name: upgrade conan
run: |
pip install --upgrade "conan<2"
- name: checkout
uses: actions/checkout@v4
- name: check environment
run: |
echo ${PATH} | tr ':' '\n'
lsb_release -a || true
${{ matrix.profile.cc }} --version
conan --version
cmake --version
env | sort
- name: configure Conan
run: |
conan profile new default --detect
conan profile update settings.compiler.cppstd=20 default
conan profile update settings.compiler=${{ matrix.compiler }} default
conan profile update settings.compiler.version=${{ matrix.profile.version }} default
conan profile update settings.compiler.libcxx=libstdc++11 default
conan profile update env.CC=${{ matrix.profile.cc }} default
conan profile update env.CXX=${{ matrix.profile.cxx }} default
conan profile update conf.tools.build:compiler_executables='{"c": "${{ matrix.profile.cc }}", "cpp": "${{ matrix.profile.cxx }}"}' default
- name: archive profile
# Create this archive before dependencies are added to the local cache.
run: tar -czf conan.tar -C ~/.conan .
- name: build dependencies
uses: ./.github/actions/dependencies
env:
CONAN_URL: http://18.143.149.228:8081/artifactory/api/conan/conan-non-prod
CONAN_LOGIN_USERNAME_RIPPLE: ${{ secrets.CONAN_USERNAME }}
CONAN_PASSWORD_RIPPLE: ${{ secrets.CONAN_TOKEN }}
with:
configuration: ${{ matrix.configuration }}
- name: upload archive
uses: actions/upload-artifact@v4
with:
name: ${{ matrix.platform }}-${{ matrix.compiler }}-${{ matrix.configuration }}
path: conan.tar
if-no-files-found: error
test:
strategy:
fail-fast: false
matrix:
platform:
- linux
compiler:
- gcc
- clang
configuration:
- Debug
- Release
cmake-args:
-
- "-Dunity=ON"
needs: dependencies
runs-on: [self-hosted, heavy]
container: ghcr.io/xrplf/rippled-build-ubuntu:aaf5e3e
env:
build_dir: .build
steps:
- name: upgrade conan
run: |
pip install --upgrade "conan<2"
- name: download cache
uses: actions/download-artifact@v4
with:
name: ${{ matrix.platform }}-${{ matrix.compiler }}-${{ matrix.configuration }}
- name: extract cache
run: |
mkdir -p ~/.conan
tar -xzf conan.tar -C ~/.conan
- name: check environment
run: |
env | sort
echo ${PATH} | tr ':' '\n'
conan --version
cmake --version
- name: checkout
uses: actions/checkout@v4
- name: dependencies
uses: ./.github/actions/dependencies
env:
CONAN_URL: http://18.143.149.228:8081/artifactory/api/conan/conan-non-prod
with:
configuration: ${{ matrix.configuration }}
- name: build
uses: ./.github/actions/build
with:
generator: Ninja
configuration: ${{ matrix.configuration }}
cmake-args: "-Dassert=TRUE -Dwerr=TRUE ${{ matrix.cmake-args }}"
- name: test
run: |
${build_dir}/rippled --unittest --unittest-jobs $(nproc)
reference-fee-test:
strategy:
fail-fast: false
matrix:
platform:
- linux
compiler:
- gcc
configuration:
- Debug
cmake-args:
- "-DUNIT_TEST_REFERENCE_FEE=200"
- "-DUNIT_TEST_REFERENCE_FEE=1000"
needs: dependencies
runs-on: [self-hosted, heavy]
container: ghcr.io/xrplf/rippled-build-ubuntu:aaf5e3e
env:
build_dir: .build
steps:
- name: upgrade conan
run: |
pip install --upgrade "conan<2"
- name: download cache
uses: actions/download-artifact@v4
with:
name: ${{ matrix.platform }}-${{ matrix.compiler }}-${{ matrix.configuration }}
- name: extract cache
run: |
mkdir -p ~/.conan
tar -xzf conan.tar -C ~/.conan
- name: check environment
run: |
env | sort
echo ${PATH} | tr ':' '\n'
conan --version
cmake --version
- name: checkout
uses: actions/checkout@v4
- name: dependencies
uses: ./.github/actions/dependencies
env:
CONAN_URL: http://18.143.149.228:8081/artifactory/api/conan/conan-non-prod
with:
configuration: ${{ matrix.configuration }}
- name: build
uses: ./.github/actions/build
with:
generator: Ninja
configuration: ${{ matrix.configuration }}
cmake-args: "-Dassert=TRUE -Dwerr=TRUE ${{ matrix.cmake-args }}"
- name: test
run: |
${build_dir}/rippled --unittest --unittest-jobs $(nproc)
coverage:
strategy:
fail-fast: false
matrix:
platform:
- linux
compiler:
- gcc
configuration:
- Debug
needs: dependencies
runs-on: [self-hosted, heavy]
container: ghcr.io/xrplf/rippled-build-ubuntu:aaf5e3e
env:
build_dir: .build
steps:
- name: upgrade conan
run: |
pip install --upgrade "conan<2"
- name: download cache
uses: actions/download-artifact@v4
with:
name: ${{ matrix.platform }}-${{ matrix.compiler }}-${{ matrix.configuration }}
- name: extract cache
run: |
mkdir -p ~/.conan
tar -xzf conan.tar -C ~/.conan
- name: install gcovr
run: pip install "gcovr>=7,<9"
- name: check environment
run: |
echo ${PATH} | tr ':' '\n'
conan --version
cmake --version
gcovr --version
env | sort
ls ~/.conan
- name: checkout
uses: actions/checkout@v4
- name: dependencies
uses: ./.github/actions/dependencies
env:
CONAN_URL: http://18.143.149.228:8081/artifactory/api/conan/conan-non-prod
with:
configuration: ${{ matrix.configuration }}
- name: build
uses: ./.github/actions/build
with:
generator: Ninja
configuration: ${{ matrix.configuration }}
cmake-args: >-
-Dassert=TRUE
-Dwerr=TRUE
-Dcoverage=ON
-Dcoverage_format=xml
-DCODE_COVERAGE_VERBOSE=ON
-DCMAKE_CXX_FLAGS="-O0"
-DCMAKE_C_FLAGS="-O0"
cmake-target: coverage
- name: move coverage report
shell: bash
run: |
mv "${build_dir}/coverage.xml" ./
- name: archive coverage report
uses: actions/upload-artifact@v4
with:
name: coverage.xml
path: coverage.xml
retention-days: 30
- name: upload coverage report
uses: wandalen/wretry.action@v1.4.10
with:
action: codecov/codecov-action@v4.5.0
with: |
files: coverage.xml
fail_ci_if_error: true
disable_search: true
verbose: true
plugin: noop
token: ${{ secrets.CODECOV_TOKEN }}
attempt_limit: 5
attempt_delay: 210000 # in milliseconds
conan:
needs: dependencies
runs-on: [self-hosted, heavy]
container: ghcr.io/xrplf/rippled-build-ubuntu:aaf5e3e
env:
build_dir: .build
configuration: Release
steps:
- name: upgrade conan
run: |
pip install --upgrade "conan<2"
- name: download cache
uses: actions/download-artifact@v4
with:
name: linux-gcc-${{ env.configuration }}
- name: extract cache
run: |
mkdir -p ~/.conan
tar -xzf conan.tar -C ~/.conan
- name: check environment
run: |
env | sort
echo ${PATH} | tr ':' '\n'
conan --version
cmake --version
- name: checkout
uses: actions/checkout@v4
- name: dependencies
uses: ./.github/actions/dependencies
env:
CONAN_URL: http://18.143.149.228:8081/artifactory/api/conan/conan-non-prod
with:
configuration: ${{ env.configuration }}
- name: export
run: |
version=$(conan inspect --raw version .)
reference="xrpl/${version}@local/test"
conan remove -f ${reference} || true
conan export . local/test
echo "reference=${reference}" >> "${GITHUB_ENV}"
- name: build
run: |
cd tests/conan
mkdir ${build_dir}
cd ${build_dir}
conan install .. --output-folder . \
--require-override ${reference} --build missing
cmake .. \
-DCMAKE_TOOLCHAIN_FILE:FILEPATH=./build/${configuration}/generators/conan_toolchain.cmake \
-DCMAKE_BUILD_TYPE=${configuration}
cmake --build .
./example | grep '^[[:digit:]]\+\.[[:digit:]]\+\.[[:digit:]]\+'
# NOTE we are not using dependencies built above because it lags with
# compiler versions. Instrumentation requires clang version 16 or
# later
instrumentation-build:
if: ${{ github.event_name == 'push' || github.event.pull_request.draft != true || contains(github.event.pull_request.labels.*.name, 'DraftRunCI') }}
env:
CLANG_RELEASE: 16
strategy:
fail-fast: false
runs-on: [self-hosted, heavy]
container: debian:bookworm
steps:
- name: install prerequisites
env:
DEBIAN_FRONTEND: noninteractive
run: |
apt-get update
apt-get install --yes --no-install-recommends \
clang-${CLANG_RELEASE} clang++-${CLANG_RELEASE} \
python3-pip python-is-python3 make cmake git wget
apt-get clean
update-alternatives --install \
/usr/bin/clang clang /usr/bin/clang-${CLANG_RELEASE} 100 \
--slave /usr/bin/clang++ clang++ /usr/bin/clang++-${CLANG_RELEASE}
update-alternatives --auto clang
pip install --no-cache --break-system-packages "conan<2"
- name: checkout
uses: actions/checkout@v4
- name: prepare environment
run: |
mkdir ${GITHUB_WORKSPACE}/.build
echo "SOURCE_DIR=$GITHUB_WORKSPACE" >> $GITHUB_ENV
echo "BUILD_DIR=$GITHUB_WORKSPACE/.build" >> $GITHUB_ENV
echo "CC=/usr/bin/clang" >> $GITHUB_ENV
echo "CXX=/usr/bin/clang++" >> $GITHUB_ENV
- name: configure Conan
run: |
conan profile new --detect default
conan profile update settings.compiler=clang default
conan profile update settings.compiler.version=${CLANG_RELEASE} default
conan profile update settings.compiler.libcxx=libstdc++11 default
conan profile update settings.compiler.cppstd=20 default
conan profile update options.rocksdb=False default
conan profile update \
'conf.tools.build:compiler_executables={"c": "/usr/bin/clang", "cpp": "/usr/bin/clang++"}' default
conan profile update 'env.CXXFLAGS="-DBOOST_ASIO_DISABLE_CONCEPTS"' default
conan profile update 'conf.tools.build:cxxflags+=["-DBOOST_ASIO_DISABLE_CONCEPTS"]' default
conan export external/snappy snappy/1.1.10@
conan export external/soci soci/4.0.3@
conan export -k external/wamr wamr/2.2.0@
- name: build dependencies
run: |
cd ${BUILD_DIR}
conan install ${SOURCE_DIR} \
--output-folder ${BUILD_DIR} \
--install-folder ${BUILD_DIR} \
--build missing \
--settings build_type=Debug
- name: build with instrumentation
run: |
cd ${BUILD_DIR}
cmake -S ${SOURCE_DIR} -B ${BUILD_DIR} \
-Dvoidstar=ON \
-Dtests=ON \
-Dxrpld=ON \
-DCMAKE_BUILD_TYPE=Debug \
-DSECP256K1_BUILD_BENCHMARK=OFF \
-DSECP256K1_BUILD_TESTS=OFF \
-DSECP256K1_BUILD_EXHAUSTIVE_TESTS=OFF \
-DCMAKE_TOOLCHAIN_FILE=${BUILD_DIR}/build/generators/conan_toolchain.cmake
cmake --build . --parallel $(nproc)
- name: verify instrumentation enabled
run: |
cd ${BUILD_DIR}
./rippled --version | grep libvoidstar
- name: run unit tests
run: |
cd ${BUILD_DIR}
./rippled -u --unittest-jobs $(( $(nproc)/4 ))

View File

@@ -1,196 +0,0 @@
# This workflow runs all workflows to check, build and test the project on
# various Linux flavors, as well as on MacOS and Windows, on every push to a
# user branch. However, it will not run if the pull request is a draft unless it
# has the 'DraftRunCI' label. For commits to PRs that target a release branch,
# it also uploads the libxrpl recipe to the Conan remote.
name: PR
on:
merge_group:
types:
- checks_requested
pull_request:
types:
- opened
- reopened
- synchronize
- ready_for_review
concurrency:
group: ${{ github.workflow }}-${{ github.ref }}
cancel-in-progress: true
defaults:
run:
shell: bash
jobs:
# This job determines whether the rest of the workflow should run. It runs
# when the PR is not a draft (which should also cover merge-group) or
# has the 'DraftRunCI' label.
should-run:
if: ${{ !github.event.pull_request.draft || contains(github.event.pull_request.labels.*.name, 'DraftRunCI') }}
runs-on: ubuntu-latest
steps:
- name: Checkout repository
uses: actions/checkout@9c091bb21b7c1c1d1991bb908d89e4e9dddfe3e0 # v7.0.0
- name: Determine changed files
# This step checks whether any files have changed that should
# cause the next jobs to run. We do it this way rather than
# using `paths` in the `on:` section, because all required
# checks must pass, even for changes that do not modify anything
# that affects those checks. We would therefore like to make the
# checks required only if the job runs, but GitHub does not
# support that directly. By always executing the workflow on new
# commits and by using the changed-files action below, we ensure
# that Github considers any skipped jobs to have passed, and in
# turn the required checks as well.
id: changes
uses: tj-actions/changed-files@9426d40962ed5378910ee2e21d5f8c6fcbf2dd96 # v47.0.6
with:
files: |
# These paths are unique to `on-pr.yml`.
.github/scripts/levelization/**
.github/scripts/otel-naming/**
.github/scripts/rename/**
.github/workflows/reusable-check-levelization.yml
.github/workflows/reusable-check-otel-naming.yml
.github/workflows/reusable-check-rename.yml
.github/workflows/on-pr.yml
# Keep the paths below in sync with those in `on-trigger.yml`.
.github/actions/build-deps/**
.github/actions/generate-version/**
.github/actions/setup-conan/**
.github/scripts/strategy-matrix/**
.github/workflows/reusable-build-test-config.yml
.github/workflows/reusable-build-test.yml
.github/workflows/reusable-clang-tidy.yml
.github/workflows/reusable-package.yml
.github/workflows/reusable-strategy-matrix.yml
.github/workflows/reusable-test.yml
.github/workflows/reusable-upload-recipe.yml
.clang-tidy
.codecov.yml
bin/check-tools.sh
cfg/**
cmake/**
conan/**
external/**
include/**
src/**
tests/**
CMakeLists.txt
conanfile.py
conan.lock
LICENSE.md
package/**
README.md
- name: Check whether to run
# This step determines whether the rest of the workflow should
# run. The rest of the workflow will run if this job runs AND at
# least one of:
# * Any of the files checked in the `changes` step were modified
# * The PR is NOT a draft and is labeled "Ready to merge"
# * The workflow is running from the merge queue
id: go
env:
FILES: ${{ steps.changes.outputs.any_changed }}
DRAFT: ${{ github.event.pull_request.draft }}
READY: ${{ contains(github.event.pull_request.labels.*.name, 'Ready to merge') }}
MERGE: ${{ github.event_name == 'merge_group' }}
run: |
echo "go=${{ (env.DRAFT != 'true' && env.READY == 'true') || env.FILES == 'true' || env.MERGE == 'true' }}" >>"${GITHUB_OUTPUT}"
cat "${GITHUB_OUTPUT}"
outputs:
go: ${{ steps.go.outputs.go == 'true' }}
check-levelization:
needs: should-run
if: ${{ needs.should-run.outputs.go == 'true' }}
uses: ./.github/workflows/reusable-check-levelization.yml
check-otel-naming:
needs: should-run
if: ${{ needs.should-run.outputs.go == 'true' }}
uses: ./.github/workflows/reusable-check-otel-naming.yml
check-rename:
needs: should-run
if: ${{ needs.should-run.outputs.go == 'true' }}
uses: ./.github/workflows/reusable-check-rename.yml
clang-tidy:
needs: should-run
if: ${{ needs.should-run.outputs.go == 'true' }}
uses: ./.github/workflows/reusable-clang-tidy.yml
permissions:
issues: write
contents: read
with:
create_issue_on_failure: false
build-test:
needs: should-run
if: ${{ needs.should-run.outputs.go == 'true' }}
uses: ./.github/workflows/reusable-build-test.yml
strategy:
fail-fast: false
matrix:
os: [linux, macos, windows]
with:
# Enable ccache only for events targeting the XRPLF repository, since
# other accounts will not have access to our remote cache storage.
ccache_enabled: ${{ github.repository_owner == 'XRPLF' }}
os: ${{ matrix.os }}
secrets:
CODECOV_TOKEN: ${{ secrets.CODECOV_TOKEN }}
package:
needs: [should-run, build-test]
if: ${{ needs.should-run.outputs.go == 'true' }}
uses: ./.github/workflows/reusable-package.yml
upload-recipe:
needs:
- should-run
- build-test
# Only run when committing to a PR that targets a release branch.
if: ${{ github.repository == 'XRPLF/rippled' && needs.should-run.outputs.go == 'true' && github.event_name == 'pull_request' && startsWith(github.event.pull_request.base.ref, 'release') }}
uses: ./.github/workflows/reusable-upload-recipe.yml
secrets:
remote_username: ${{ secrets.NEXUS_REMOTE_USERNAME }}
remote_password: ${{ secrets.NEXUS_REMOTE_PASSWORD }}
notify-clio:
needs: upload-recipe
runs-on: ubuntu-latest
steps:
# Notify the Clio repository about the newly proposed release version, so
# it can be checked for compatibility before the release is actually made.
- name: Notify Clio
env:
GH_TOKEN: ${{ secrets.CLIO_NOTIFY_TOKEN }}
PR_URL: ${{ github.event.pull_request.html_url }}
run: |
gh api --method POST -H "Accept: application/vnd.github+json" -H "X-GitHub-Api-Version: 2022-11-28" \
/repos/xrplf/clio/dispatches -f "event_type=check_libxrpl" \
-F "client_payload[ref]=${{ needs.upload-recipe.outputs.recipe_ref }}" \
-F "client_payload[pr_url]=${PR_URL}"
passed:
if: failure() || cancelled()
needs:
- check-levelization
- check-otel-naming
- check-rename
- clang-tidy
- build-test
- package
- upload-recipe
- notify-clio
runs-on: ubuntu-latest
steps:
- name: Fail
run: exit 1

View File

@@ -1,42 +0,0 @@
# This workflow uploads the libxrpl recipe to the Conan remote and builds
# release packages when a versioned tag is pushed.
name: Tag
on:
push:
tags:
- "[0-9]+.[0-9]+.[0-9]*"
concurrency:
group: ${{ github.workflow }}-${{ github.ref }}
cancel-in-progress: true
defaults:
run:
shell: bash
jobs:
upload-recipe:
if: ${{ github.repository == 'XRPLF/rippled' }}
uses: ./.github/workflows/reusable-upload-recipe.yml
secrets:
remote_username: ${{ secrets.NEXUS_REMOTE_USERNAME }}
remote_password: ${{ secrets.NEXUS_REMOTE_PASSWORD }}
build-test:
if: ${{ github.repository == 'XRPLF/rippled' }}
uses: ./.github/workflows/reusable-build-test.yml
strategy:
fail-fast: true
matrix:
os: [linux]
with:
ccache_enabled: false
os: ${{ matrix.os }}
secrets:
CODECOV_TOKEN: ${{ secrets.CODECOV_TOKEN }}
package:
if: ${{ github.repository == 'XRPLF/rippled' }}
needs: build-test
uses: ./.github/workflows/reusable-package.yml

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@@ -1,105 +0,0 @@
# This workflow runs all workflows to build and test the code on various Linux
# flavors, as well as on MacOS and Windows, on a scheduled basis, on merge into
# the 'develop' or 'release*' branches, or when requested manually. Upon pushes
# to the develop branch it also uploads the libxrpl recipe to the Conan remote.
name: Trigger
on:
push:
branches:
- "develop"
- "release*"
paths:
# These paths are unique to `on-trigger.yml`.
- ".github/workflows/on-trigger.yml"
# Keep the paths below in sync with those in `on-pr.yml`.
- ".github/actions/build-deps/**"
- ".github/actions/generate-version/**"
- ".github/actions/setup-conan/**"
- ".github/scripts/strategy-matrix/**"
- ".github/workflows/reusable-build-test-config.yml"
- ".github/workflows/reusable-build-test.yml"
- ".github/workflows/reusable-clang-tidy.yml"
- ".github/workflows/reusable-package.yml"
- ".github/workflows/reusable-strategy-matrix.yml"
- ".github/workflows/reusable-test.yml"
- ".github/workflows/reusable-upload-recipe.yml"
- ".clang-tidy"
- ".codecov.yml"
- "bin/check-tools.sh"
- "cfg/**"
- "cmake/**"
- "conan/**"
- "external/**"
- "include/**"
- "src/**"
- "tests/**"
- "CMakeLists.txt"
- "conanfile.py"
- "conan.lock"
- "LICENSE.md"
- "package/**"
- "README.md"
# Run at 06:32 UTC on every day of the week from Monday through Friday. This
# will force all dependencies to be rebuilt, which is useful to verify that
# all dependencies can be built successfully. Only the dependencies that
# are actually missing from the remote will be uploaded.
schedule:
- cron: "32 6 * * 1-5"
# Run when manually triggered via the GitHub UI or API.
workflow_dispatch:
concurrency:
# When a PR is merged into the develop branch it will be assigned a unique
# group identifier, so execution will continue even if another PR is merged
# while it is still running. In all other cases the group identifier is shared
# per branch, so that any in-progress runs are cancelled when a new commit is
# pushed.
group: ${{ github.workflow }}-${{ github.event_name == 'push' && github.ref == 'refs/heads/develop' && github.sha || github.ref }}
cancel-in-progress: true
defaults:
run:
shell: bash
jobs:
clang-tidy:
uses: ./.github/workflows/reusable-clang-tidy.yml
permissions:
issues: write
contents: read
with:
create_issue_on_failure: ${{ github.event_name == 'schedule' }}
build-test:
uses: ./.github/workflows/reusable-build-test.yml
strategy:
fail-fast: ${{ github.event_name == 'merge_group' }}
matrix:
os: [linux, macos, windows]
with:
# Enable ccache only for events targeting the XRPLF repository, since
# other accounts will not have access to our remote cache storage.
# However, we do not enable ccache for events targeting a release branch,
# to protect against the rare case that the output produced by ccache is
# not identical to a regular compilation.
ccache_enabled: ${{ github.repository_owner == 'XRPLF' && !startsWith(github.ref, 'refs/heads/release') }}
os: ${{ matrix.os }}
secrets:
CODECOV_TOKEN: ${{ secrets.CODECOV_TOKEN }}
upload-recipe:
needs: build-test
# Only run when pushing to the develop branch.
if: ${{ github.repository == 'XRPLF/rippled' && github.event_name == 'push' && github.ref == 'refs/heads/develop' }}
uses: ./.github/workflows/reusable-upload-recipe.yml
secrets:
remote_username: ${{ secrets.NEXUS_REMOTE_USERNAME }}
remote_password: ${{ secrets.NEXUS_REMOTE_PASSWORD }}
package:
needs: build-test
uses: ./.github/workflows/reusable-package.yml

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@@ -1,20 +0,0 @@
name: Run pre-commit hooks
on:
merge_group:
types:
- checks_requested
pull_request:
push:
branches:
- "develop"
- "release*"
workflow_dispatch:
jobs:
# Call the workflow in the XRPLF/actions repo that runs the pre-commit hooks.
run-hooks:
uses: XRPLF/actions/.github/workflows/pre-commit.yml@1bde119a1ab71305ba5d3716e7a82cea1c7bdede
with:
runs_on: ubuntu-latest
container: '{ "image": "ghcr.io/xrplf/ci/tools-rippled-pre-commit:sha-41ec7c1" }'

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@@ -1,94 +0,0 @@
# This workflow builds the documentation for the repository, and publishes it to
# GitHub Pages when changes are merged into the default branch.
name: Build and publish documentation
on:
push:
branches:
- "develop"
paths:
- ".github/workflows/publish-docs.yml"
- "*.md"
- "**/*.md"
- "docs/**"
- "include/**"
- "src/libxrpl/**"
- "src/xrpld/**"
pull_request:
paths:
- ".github/workflows/publish-docs.yml"
- "*.md"
- "**/*.md"
- "docs/**"
- "include/**"
- "src/libxrpl/**"
- "src/xrpld/**"
concurrency:
group: ${{ github.workflow }}-${{ github.ref }}
cancel-in-progress: true
defaults:
run:
shell: bash
env:
BUILD_DIR: build
# ubuntu-latest has only 2 CPUs for private repositories
# https://docs.github.com/en/actions/reference/runners/github-hosted-runners#standard-github-hosted-runners-for--private-repositories
NPROC_SUBTRACT: ${{ github.event.repository.visibility == 'public' && '2' || '1' }}
jobs:
build:
runs-on: ubuntu-latest
container: ghcr.io/xrplf/xrpld/nix-ubuntu:sha-e29b523
steps:
- name: Checkout repository
uses: actions/checkout@9c091bb21b7c1c1d1991bb908d89e4e9dddfe3e0 # v7.0.0
- name: Prepare runner
uses: XRPLF/actions/prepare-runner@64ec3cf3b152b4444638f470bbd6df7a7a30c81c
with:
enable_ccache: false
- name: Get number of processors
uses: XRPLF/actions/get-nproc@cf0433aa74563aead044a1e395610c96d65a37cf
id: nproc
with:
subtract: ${{ env.NPROC_SUBTRACT }}
- name: Print build environment
uses: XRPLF/actions/print-build-env@59dec886e4afb05a1724443af08baccbc045b574
- name: Check Doxygen version
run: doxygen --version
- name: Build documentation
env:
BUILD_NPROC: ${{ steps.nproc.outputs.nproc }}
run: |
mkdir -p "${BUILD_DIR}"
cd "${BUILD_DIR}"
cmake -Donly_docs=ON ..
cmake --build . --target docs --parallel ${BUILD_NPROC}
- name: Create documentation artifact
if: ${{ github.event.repository.visibility == 'public' && github.event_name == 'push' }}
uses: actions/upload-pages-artifact@fc324d3547104276b827a68afc52ff2a11cc49c9 # v5.0.0
with:
path: ${{ env.BUILD_DIR }}/docs/html
deploy:
if: ${{ github.repository == 'XRPLF/rippled' && github.event_name == 'push' }}
needs: build
runs-on: ubuntu-latest
permissions:
pages: write
id-token: write
environment:
name: github-pages
url: ${{ steps.deploy.outputs.page_url }}
steps:
- name: Deploy to GitHub Pages
id: deploy
uses: actions/deploy-pages@cd2ce8fcbc39b97be8ca5fce6e763baed58fa128 # v5.0.0

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@@ -1,378 +0,0 @@
name: Build and test configuration
on:
workflow_call:
inputs:
build_only:
description: 'Whether to only build or to build and test the code ("true", "false").'
required: true
type: boolean
build_type:
description: 'The build type to use ("Debug", "Release").'
required: true
type: string
ccache_enabled:
description: "Whether to enable ccache."
required: false
type: boolean
default: false
cmake_args:
description: "Additional arguments to pass to CMake."
required: false
type: string
default: ""
cmake_target:
description: "The CMake target to build."
required: true
type: string
runs_on:
description: Runner to run the job on as a JSON string
required: true
type: string
image:
description: "The image to run in (leave empty to run natively)"
required: true
type: string
config_name:
description: "The configuration string (used for naming artifacts and such)."
required: true
type: string
nproc_subtract:
description: "The number of processors to subtract when calculating parallelism."
required: false
type: number
default: 2
sanitizers:
description: "The sanitizers to enable."
required: false
type: string
default: ""
compiler:
description: 'The compiler to use ("gcc" or "clang"). Leave empty for macOS/Windows (uses system default).'
required: false
type: string
default: ""
secrets:
CODECOV_TOKEN:
description: "The Codecov token to use for uploading coverage reports."
required: true
defaults:
run:
shell: bash
env:
# Conan installs the generators in the build/generators directory, see the
# layout() method in conanfile.py. We then run CMake from the build directory.
BUILD_DIR: build
jobs:
build-and-test:
name: ${{ inputs.config_name }}
runs-on: ${{ fromJSON(inputs.runs_on) }}
container: ${{ inputs.image != '' && inputs.image || null }}
timeout-minutes: ${{ inputs.sanitizers != '' && 360 || 180 }}
env:
# Use a namespace to keep the objects separate for each configuration.
CCACHE_NAMESPACE: ${{ inputs.config_name }}
# Ccache supports both Redis and HTTP endpoints.
# * For Redis, use the following format: redis://ip:port, see
# https://github.com/ccache/ccache/wiki/Redis-storage. Note that TLS is
# not directly supported by ccache, and requires use of a proxy.
# * For HTTP use the following format: http://ip:port/cache when using
# nginx as backend or http://ip:port|layout=bazel when using Bazel
# Remote Cache, see https://github.com/ccache/ccache/wiki/HTTP-storage.
# Note that HTTPS is not directly supported by ccache.
CCACHE_REMOTE_ONLY: true
CCACHE_REMOTE_STORAGE: http://cache.dev.ripplex.io:8080|layout=bazel
# Ignore the creation and modification timestamps on files, since the
# header files are copied into separate directories by CMake, which will
# otherwise result in cache misses.
CCACHE_SLOPPINESS: include_file_ctime,include_file_mtime
# Determine if coverage and voidstar should be enabled.
COVERAGE_ENABLED: ${{ contains(inputs.cmake_args, '-Dcoverage=ON') }}
VOIDSTAR_ENABLED: ${{ contains(inputs.cmake_args, '-Dvoidstar=ON') }}
SANITIZERS_ENABLED: ${{ inputs.sanitizers != '' }}
steps:
- name: Cleanup workspace (macOS and Windows)
if: ${{ runner.os == 'macOS' || runner.os == 'Windows' }}
uses: XRPLF/actions/cleanup-workspace@c7d9ce5ebb03c752a354889ecd870cadfc2b1cd4
- name: Checkout repository
uses: actions/checkout@9c091bb21b7c1c1d1991bb908d89e4e9dddfe3e0 # v7.0.0
- name: Prepare runner
uses: XRPLF/actions/prepare-runner@64ec3cf3b152b4444638f470bbd6df7a7a30c81c
with:
enable_ccache: ${{ inputs.ccache_enabled }}
- name: Set ccache log file
if: ${{ inputs.ccache_enabled && runner.debug == '1' }}
run: echo "CCACHE_LOGFILE=${{ runner.temp }}/ccache.log" >>"${GITHUB_ENV}"
- name: Check tools
env:
CHECK_TOOLS_SKIP_CLONE: "1"
run: ./bin/check-tools.sh
- name: Print build environment
uses: XRPLF/actions/print-build-env@59dec886e4afb05a1724443af08baccbc045b574
- name: Get number of processors
uses: XRPLF/actions/get-nproc@cf0433aa74563aead044a1e395610c96d65a37cf
id: nproc
with:
subtract: ${{ inputs.nproc_subtract }}
- name: Set compiler environment (Linux)
if: ${{ runner.os == 'Linux' }}
uses: ./.github/actions/set-compiler-env
with:
compiler: ${{ inputs.compiler }}
- name: Setup Conan
env:
SANITIZERS: ${{ inputs.sanitizers }}
uses: ./.github/actions/setup-conan
- name: Build dependencies
uses: ./.github/actions/build-deps
with:
build_nproc: ${{ steps.nproc.outputs.nproc }}
build_type: ${{ inputs.build_type }}
# Set the verbosity to "quiet" for Windows to avoid an excessive
# amount of logs. For other OSes, the "verbose" logs are more useful.
log_verbosity: ${{ runner.os == 'Windows' && 'quiet' || 'verbose' }}
sanitizers: ${{ inputs.sanitizers }}
- name: Configure CMake
working-directory: ${{ env.BUILD_DIR }}
env:
BUILD_TYPE: ${{ inputs.build_type }}
CMAKE_ARGS: ${{ inputs.cmake_args }}
run: |
cmake \
-G '${{ runner.os == 'Windows' && 'Visual Studio 18 2026' || 'Ninja' }}' \
-DCMAKE_TOOLCHAIN_FILE:FILEPATH=build/generators/conan_toolchain.cmake \
-DCMAKE_BUILD_TYPE="${BUILD_TYPE}" \
${CMAKE_ARGS} \
..
# Export the sanitizer options before any instrumented binary runs. The
# protocol code-gen and build steps below invoke instrumented dependency
# tools (protoc, grpc), so setting UBSAN_OPTIONS here lets the UBSan
# suppression list silence their diagnostics too, not just at test time.
# GITHUB_WORKSPACE (not the github.workspace context) is used so the path
# resolves correctly inside the container job.
- name: Set sanitizer options
if: ${{ !inputs.build_only && env.SANITIZERS_ENABLED == 'true' }}
env:
CONFIG_NAME: ${{ inputs.config_name }}
run: |
SUPP="${GITHUB_WORKSPACE}/sanitizers/suppressions"
ASAN_OPTS="include=${SUPP}/runtime-asan-options.txt:suppressions=${SUPP}/asan.supp"
if [[ "${CONFIG_NAME}" == *gcc* ]]; then
ASAN_OPTS="${ASAN_OPTS}:alloc_dealloc_mismatch=0"
fi
echo "ASAN_OPTIONS=${ASAN_OPTS}" >>${GITHUB_ENV}
echo "TSAN_OPTIONS=include=${SUPP}/runtime-tsan-options.txt:suppressions=${SUPP}/tsan.supp" >>${GITHUB_ENV}
echo "UBSAN_OPTIONS=include=${SUPP}/runtime-ubsan-options.txt:suppressions=${SUPP}/ubsan.supp" >>${GITHUB_ENV}
echo "LSAN_OPTIONS=include=${SUPP}/runtime-lsan-options.txt:suppressions=${SUPP}/lsan.supp" >>${GITHUB_ENV}
- name: Check protocol autogen files are up-to-date
working-directory: ${{ env.BUILD_DIR }}
env:
MESSAGE: |
The generated protocol wrapper classes are out of date.
This typically happens when the macro files or generator scripts
have changed but the generated files were not regenerated.
To fix this:
1. Run: cmake --build . --target setup_code_gen
2. Run: cmake --build . --target code_gen
3. Commit and push the regenerated files
run: |
set -e
cmake --build . --target setup_code_gen
cmake --build . --target code_gen
DIFF=$(git -C .. status --porcelain -- include/xrpl/protocol_autogen src/tests/libxrpl/protocol_autogen)
if [ -n "${DIFF}" ]; then
echo "::error::Generated protocol files are out of date"
git -C .. diff -- include/xrpl/protocol_autogen src/tests/libxrpl/protocol_autogen
echo "${MESSAGE}"
exit 1
fi
- name: Build the binary
working-directory: ${{ env.BUILD_DIR }}
env:
BUILD_NPROC: ${{ steps.nproc.outputs.nproc }}
BUILD_TYPE: ${{ inputs.build_type }}
CMAKE_TARGET: ${{ inputs.cmake_target }}
run: |
cmake \
--build . \
--config "${BUILD_TYPE}" \
--parallel "${BUILD_NPROC}" \
--target "${CMAKE_TARGET}"
- name: Show ccache statistics
if: ${{ inputs.ccache_enabled }}
run: |
ccache --show-stats -vv
if [ '${{ runner.debug }}' = '1' ]; then
cat "${CCACHE_LOGFILE}"
curl ${CCACHE_REMOTE_STORAGE%|*}/status || true
fi
- name: Upload the binary (Linux)
if: ${{ github.event.repository.visibility == 'public' && runner.os == 'Linux' }}
uses: actions/upload-artifact@043fb46d1a93c77aae656e7c1c64a875d1fc6a0a # v7.0.1
with:
name: xrpld-${{ inputs.config_name }}
path: ${{ env.BUILD_DIR }}/xrpld
retention-days: 3
if-no-files-found: error
- name: Upload the test binary (Linux)
if: ${{ github.event.repository.visibility == 'public' && runner.os == 'Linux' }}
uses: actions/upload-artifact@043fb46d1a93c77aae656e7c1c64a875d1fc6a0a # v7.0.1
with:
name: xrpl_tests-${{ inputs.config_name }}
path: ${{ env.BUILD_DIR }}/xrpl_tests
retention-days: 3
if-no-files-found: error
- name: Export server definitions
if: ${{ runner.os != 'Windows' && !inputs.build_only && env.VOIDSTAR_ENABLED != 'true' }}
working-directory: ${{ env.BUILD_DIR }}
run: |
set -o pipefail
./xrpld --definitions | python3 -m json.tool >server_definitions.json
- name: Upload server definitions
if: ${{ github.event.repository.visibility == 'public' && inputs.config_name == 'debian-gcc-release-amd64' }}
uses: actions/upload-artifact@043fb46d1a93c77aae656e7c1c64a875d1fc6a0a # v7.0.1
with:
name: server-definitions
path: ${{ env.BUILD_DIR }}/server_definitions.json
retention-days: 3
if-no-files-found: error
- name: Check linking (Linux)
if: ${{ runner.os == 'Linux' && env.SANITIZERS_ENABLED == 'false' }}
working-directory: ${{ env.BUILD_DIR }}
run: |
ldd ./xrpld
if [ "$(ldd ./xrpld | grep -E '(libstdc\+\+|libgcc)' | wc -l)" -eq 0 ]; then
echo 'The binary is statically linked.'
else
echo 'The binary is dynamically linked.'
exit 1
fi
- name: Verify presence of instrumentation (Linux)
if: ${{ runner.os == 'Linux' && env.VOIDSTAR_ENABLED == 'true' }}
working-directory: ${{ env.BUILD_DIR }}
run: |
./xrpld --version | grep libvoidstar
- name: Run the separate tests
if: ${{ !inputs.build_only }}
working-directory: ${{ runner.os == 'Windows' && format('{0}/{1}', env.BUILD_DIR, inputs.build_type) || env.BUILD_DIR }}
run: ./xrpl_tests
- name: Run the embedded tests
if: ${{ !inputs.build_only }}
working-directory: ${{ runner.os == 'Windows' && format('{0}/{1}', env.BUILD_DIR, inputs.build_type) || env.BUILD_DIR }}
env:
BUILD_NPROC: ${{ steps.nproc.outputs.nproc }}
run: |
set -o pipefail
# Coverage builds are slower due to instrumentation; use fewer parallel jobs to avoid flakiness
[ "$COVERAGE_ENABLED" = "true" ] && BUILD_NPROC=$((BUILD_NPROC - 2))
# The resolver/preload workaround is only correct for the ASan build:
# a regular build doesn't hit the __dn_expand interceptor bug, and must
# NOT have libasan injected. So only preload when xrpld is ASan-built.
#
# libresolv hosts getaddrinfo's resolver helpers (dn_expand, res_*). Under ASan
# these are intercepted via dlsym(RTLD_NEXT, ...), which yields a NULL pointer
# and crashes DNS resolution if libresolv isn't loaded. Linking it guarantees
# the symbols are present; it's a harmless no-op on glibc >= 2.34 (merged into
# libc) and is what the compiler driver already does for sanitizer builds.
# https://github.com/llvm/llvm-project/issues/59007
# https://github.com/google/sanitizers/issues/1592
if ldd ./xrpld | grep -q libasan; then
PRELOAD="$(gcc -print-file-name=libasan.so):/usr/lib/x86_64-linux-gnu/libresolv.so.2"
else
PRELOAD=""
fi
LD_PRELOAD="$PRELOAD" ./xrpld --unittest --unittest-jobs "${BUILD_NPROC}" 2>&1 | tee unittest.log
- name: Show test failure summary
if: ${{ failure() && !inputs.build_only }}
env:
WORKING_DIR: ${{ runner.os == 'Windows' && format('{0}\{1}', env.BUILD_DIR, inputs.build_type) || env.BUILD_DIR }}
run: |
if [ ! -d "${WORKING_DIR}" ]; then
echo "Working directory '${WORKING_DIR}' does not exist."
exit 0
fi
cd "${WORKING_DIR}"
if [ ! -f unittest.log ]; then
echo "unittest.log not found; embedded tests may not have run."
exit 0
fi
if ! grep -E "failed" unittest.log; then
echo "Log present but no failure lines found in unittest.log."
fi
- name: Debug failure (Linux)
if: ${{ failure() && runner.os == 'Linux' && !inputs.build_only }}
run: |
echo "IPv4 local port range:"
cat /proc/sys/net/ipv4/ip_local_port_range
echo "Netstat:"
netstat -an
- name: Prepare coverage report
if: ${{ !inputs.build_only && env.COVERAGE_ENABLED == 'true' }}
working-directory: ${{ env.BUILD_DIR }}
env:
BUILD_NPROC: ${{ steps.nproc.outputs.nproc }}
BUILD_TYPE: ${{ inputs.build_type }}
run: |
cmake \
--build . \
--config "${BUILD_TYPE}" \
--parallel "${BUILD_NPROC}" \
--target coverage
- name: Upload coverage report
if: ${{ github.repository == 'XRPLF/rippled' && !inputs.build_only && env.COVERAGE_ENABLED == 'true' }}
uses: codecov/codecov-action@fb8b3582c8e4def4969c97caa2f19720cb33a72f # v7.0.0
with:
disable_search: true
disable_telem: true
fail_ci_if_error: true
files: ${{ env.BUILD_DIR }}/coverage.xml
plugins: noop
token: ${{ secrets.CODECOV_TOKEN }}
verbose: true

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@@ -1,54 +0,0 @@
# This workflow builds and tests the binary for various configurations.
name: Build and test
# This workflow can only be triggered by other workflows. Note that the
# workflow_call event does not support the 'choice' input type, see
# https://docs.github.com/en/actions/reference/workflows-and-actions/workflow-syntax#onworkflow_callinputsinput_idtype,
# so we use 'string' instead.
on:
workflow_call:
inputs:
ccache_enabled:
description: "Whether to enable ccache."
required: false
type: boolean
default: false
os:
description: 'The operating system to use for the build ("linux", "macos", "windows").'
required: true
type: string
secrets:
CODECOV_TOKEN:
description: "The Codecov token to use for uploading coverage reports."
required: true
jobs:
# Generate the strategy matrix to be used by the following job.
generate-matrix:
uses: ./.github/workflows/reusable-strategy-matrix.yml
with:
os: ${{ inputs.os }}
# Build and test the binary for each configuration.
build-test-config:
needs:
- generate-matrix
uses: ./.github/workflows/reusable-build-test-config.yml
strategy:
fail-fast: ${{ github.event_name == 'merge_group' }}
matrix: ${{ fromJson(needs.generate-matrix.outputs.matrix) }}
with:
build_only: ${{ matrix.build_only }}
build_type: ${{ matrix.build_type }}
ccache_enabled: ${{ inputs.ccache_enabled }}
cmake_args: ${{ matrix.cmake_args }}
cmake_target: ${{ matrix.cmake_target }}
runs_on: ${{ toJSON(matrix.architecture.runner) }}
image: ${{ matrix.image || '' }}
config_name: ${{ matrix.config_name }}
sanitizers: ${{ matrix.sanitizers }}
compiler: ${{ matrix.compiler || '' }}
secrets:
CODECOV_TOKEN: ${{ secrets.CODECOV_TOKEN }}

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@@ -1,46 +0,0 @@
# This workflow checks if the dependencies between the modules are correctly
# indexed.
name: Check levelization
# This workflow can only be triggered by other workflows.
on: workflow_call
concurrency:
group: ${{ github.workflow }}-${{ github.ref }}-levelization
cancel-in-progress: true
defaults:
run:
shell: bash
jobs:
levelization:
runs-on: ubuntu-latest
steps:
- name: Checkout repository
uses: actions/checkout@9c091bb21b7c1c1d1991bb908d89e4e9dddfe3e0 # v7.0.0
- name: Check levelization
run: python .github/scripts/levelization/generate.py
- name: Check for differences
env:
MESSAGE: |
The dependency relationships between the modules in xrpld have
changed, which may be an improvement or a regression.
A rule of thumb is that if your changes caused something to be
removed from loops.txt, it's probably an improvement, while if
something was added, it's probably a regression.
Run '.github/scripts/levelization/generate.py' in your repo, commit
and push the changes. See .github/scripts/levelization/README.md for
more info.
run: |
DIFF=$(git status --porcelain)
if [ -n "${DIFF}" ]; then
# Print the differences to give the contributor a hint about what to
# expect when running levelization on their own machine.
git diff
echo "${MESSAGE}"
exit 1
fi

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@@ -1,28 +0,0 @@
# This workflow checks that OpenTelemetry span-attribute names stay consistent
# across the code (*SpanNames.h), collector, Tempo, dashboards, and docs.
# See .github/scripts/otel-naming/check_otel_naming.py and the
# "Telemetry span attribute naming" section in CONTRIBUTING.md.
name: Check OTel naming
# This workflow can only be triggered by other workflows.
on: workflow_call
concurrency:
group: ${{ github.workflow }}-${{ github.ref }}-otel-naming
cancel-in-progress: true
defaults:
run:
shell: bash
jobs:
otel-naming:
runs-on: ubuntu-latest
steps:
- name: Checkout repository
uses: actions/checkout@df4cb1c069e1874edd31b4311f1884172cec0e10 # v6.0.3
- name: Check OTel naming
# The script is stdlib-only and reads only files already in the tree;
# it enforces each rule only when the layer it needs is present, so it
# works whether telemetry changes land in one PR or several.
run: python .github/scripts/otel-naming/check_otel_naming.py

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@@ -1,56 +0,0 @@
# This workflow checks if the codebase is properly renamed, see more info in
# .github/scripts/rename/README.md.
name: Check rename
# This workflow can only be triggered by other workflows.
on: workflow_call
concurrency:
group: ${{ github.workflow }}-${{ github.ref }}-rename
cancel-in-progress: true
defaults:
run:
shell: bash
jobs:
rename:
runs-on: ubuntu-latest
steps:
- name: Checkout repository
uses: actions/checkout@9c091bb21b7c1c1d1991bb908d89e4e9dddfe3e0 # v7.0.0
- name: Check definitions
run: .github/scripts/rename/definitions.sh .
- name: Check copyright notices
run: .github/scripts/rename/copyright.sh .
- name: Check CMake configs
run: .github/scripts/rename/cmake.sh .
- name: Check binary name
run: .github/scripts/rename/binary.sh .
- name: Check namespaces
run: .github/scripts/rename/namespace.sh .
- name: Check config name
run: .github/scripts/rename/config.sh .
- name: Check include guards
run: .github/scripts/rename/include.sh .
- name: Check documentation
run: .github/scripts/rename/docs.sh .
- name: Check for differences
env:
MESSAGE: |
One or more files contain changes that do not adhere to new naming
conventions.
Run the scripts in '.github/scripts/rename/' in your repo, commit
and push the changes. See .github/scripts/rename/README.md for
more info.
run: |
DIFF=$(git status --porcelain)
if [ -n "${DIFF}" ]; then
# Print the differences to give the contributor a hint about what to
# expect when running the renaming scripts on their own machine.
git diff
echo "${MESSAGE}"
exit 1
fi

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@@ -1,194 +0,0 @@
name: Run clang-tidy on files
on:
workflow_call:
inputs:
create_issue_on_failure:
description: "Whether to create an issue if the check failed"
type: boolean
default: false
defaults:
run:
shell: bash
env:
BUILD_DIR: build
BUILD_TYPE: Debug # Debug so that ASSERTS and such participate in clang-tidy check
OUTPUT_FILE: /tmp/clang-tidy-output.txt
FILTERED_OUTPUT_FILE: /tmp/clang-tidy-filtered-output.txt
DIFF_FILE: /tmp/clang-tidy-git-diff.txt
ISSUE_FILE: /tmp/clang-tidy-issue.md
COMPILER: clang
jobs:
determine-files:
permissions:
contents: read
uses: XRPLF/actions/.github/workflows/determine-tidy-files.yml@d041ac9f1fa9f07a4ba335eb4c1c82233fb3fef6
run-clang-tidy:
name: Run clang tidy
needs: [determine-files]
if: ${{ needs.determine-files.outputs.cpp_changed_files != '' || needs.determine-files.outputs.need_full_run == 'true' }}
runs-on: ["self-hosted", "Linux", "X64", "heavy"]
container: "ghcr.io/xrplf/xrpld/nix-debian:sha-e29b523"
permissions:
contents: read
issues: write
steps:
- name: Checkout repository
uses: actions/checkout@9c091bb21b7c1c1d1991bb908d89e4e9dddfe3e0 # v7.0.0
- name: Prepare runner
uses: XRPLF/actions/prepare-runner@64ec3cf3b152b4444638f470bbd6df7a7a30c81c
with:
enable_ccache: false
- name: Print build environment
uses: XRPLF/actions/print-build-env@59dec886e4afb05a1724443af08baccbc045b574
- name: Get number of processors
uses: XRPLF/actions/get-nproc@cf0433aa74563aead044a1e395610c96d65a37cf
id: nproc
- name: Set compiler environment
uses: ./.github/actions/set-compiler-env
with:
compiler: ${{ env.COMPILER }}
- name: Setup Conan
uses: ./.github/actions/setup-conan
- name: Build dependencies
uses: ./.github/actions/build-deps
with:
build_nproc: ${{ steps.nproc.outputs.nproc }}
build_type: ${{ env.BUILD_TYPE }}
log_verbosity: verbose
- name: Configure CMake
working-directory: ${{ env.BUILD_DIR }}
run: |
cmake \
-G 'Ninja' \
-DCMAKE_TOOLCHAIN_FILE:FILEPATH=build/generators/conan_toolchain.cmake \
-DCMAKE_BUILD_TYPE="${BUILD_TYPE}" \
-Dtests=ON \
-Dwerr=ON \
-Dxrpld=ON \
-Dverify_headers=ON \
..
# clang-tidy needs headers generated from proto files
- name: Build libxrpl.libpb
working-directory: ${{ env.BUILD_DIR }}
run: |
ninja -j ${{ steps.nproc.outputs.nproc }} xrpl.libpb
- name: Run clang tidy
id: run_clang_tidy
continue-on-error: true
env:
TARGETS: ${{ needs.determine-files.outputs.need_full_run != 'true' && needs.determine-files.outputs.cpp_changed_files || 'include src tests' }}
run: |
set -o pipefail
run-clang-tidy -j ${{ steps.nproc.outputs.nproc }} -p "${BUILD_DIR}" -quiet -fix -allow-no-checks ${TARGETS} 2>&1 | tee "${OUTPUT_FILE}"
- name: Print filtered clang-tidy errors
if: ${{ steps.run_clang_tidy.outcome != 'success' }}
run: |
bin/filter-clang-tidy.py "${OUTPUT_FILE}"
- name: Upload clang-tidy output
if: ${{ github.event.repository.visibility == 'public' && steps.run_clang_tidy.outcome != 'success' }}
uses: actions/upload-artifact@043fb46d1a93c77aae656e7c1c64a875d1fc6a0a # v7.0.1
with:
path: ${{ env.OUTPUT_FILE }}
archive: false
retention-days: 30
- name: Check for changes
id: files_changed
continue-on-error: true
run: |
git diff --exit-code
- name: Fix style
if: ${{ steps.files_changed.outcome != 'success' }}
run: |
pre-commit run --all-files || true
- name: Generate git diff
if: ${{ steps.files_changed.outcome != 'success' }}
run: |
git diff | tee "${DIFF_FILE}"
- name: Upload clang-tidy diff output
if: ${{ github.event.repository.visibility == 'public' && steps.files_changed.outcome != 'success' }}
uses: actions/upload-artifact@043fb46d1a93c77aae656e7c1c64a875d1fc6a0a # v7.0.1
with:
path: ${{ env.DIFF_FILE }}
archive: false
retention-days: 30
- name: Write issue header
if: ${{ steps.run_clang_tidy.outcome != 'success' }}
run: |
cat >"${ISSUE_FILE}" <<EOF
## Clang-tidy Check Failed
### Clang-tidy Output:
\`\`\`
EOF
- name: Append filtered clang-tidy output to issue body
if: ${{ steps.run_clang_tidy.outcome != 'success' }}
run: |
if [ -f "${OUTPUT_FILE}" ]; then
# Filter to the unique errors with their source context.
bin/filter-clang-tidy.py "${OUTPUT_FILE}" >"${FILTERED_OUTPUT_FILE}" || true
# If filtered output is empty, use original (might be a different error format)
if [ ! -s "${FILTERED_OUTPUT_FILE}" ]; then
cp "${OUTPUT_FILE}" "${FILTERED_OUTPUT_FILE}"
fi
# Truncate if too large
head -c 60000 "${FILTERED_OUTPUT_FILE}" >>"${ISSUE_FILE}"
if [ "$(wc -c <"${FILTERED_OUTPUT_FILE}")" -gt 60000 ]; then
echo "" >>"${ISSUE_FILE}"
echo "... (output truncated, see artifacts for full output)" >>"${ISSUE_FILE}"
fi
rm "${FILTERED_OUTPUT_FILE}"
else
echo "No output file found" >>"${ISSUE_FILE}"
fi
- name: Append issue footer
if: ${{ steps.run_clang_tidy.outcome != 'success' }}
run: |
cat >>"${ISSUE_FILE}" <<EOF
\`\`\`
---
*This issue was automatically created by the clang-tidy workflow.*
EOF
- name: Create issue
if: ${{ steps.run_clang_tidy.outcome != 'success' && inputs.create_issue_on_failure }}
uses: XRPLF/actions/create-issue@2b8bc36af85b88bca0dd7bfac2e2dc05f94ad712
with:
title: "Clang-tidy check failed"
body_file: ${{ env.ISSUE_FILE }}
labels: "Bug,Clang-tidy"
assignees: "godexsoft,mathbunnyru"
- name: Fail if clang-tidy found issues
if: ${{ steps.run_clang_tidy.outcome != 'success' }}
run: |
echo "Clang-tidy check failed!"
exit 1

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@@ -1,81 +0,0 @@
# Build Linux packages (DEB and RPM) from pre-built binary artifacts.
# Discovers which configurations to package from linux.json (configs in
# "package_configs") and fans out one job per distro. Only linux/amd64 is
# supported; the runner is hardcoded in the job below.
name: Package
on:
workflow_call:
inputs:
pkg_release:
description: "Package release number. Increment when repackaging the same executable."
required: false
type: string
default: "1"
defaults:
run:
shell: bash
env:
BUILD_DIR: build
jobs:
generate-matrix:
runs-on: ubuntu-latest
outputs:
matrix: ${{ steps.generate.outputs.matrix }}
steps:
- name: Checkout repository
uses: actions/checkout@9c091bb21b7c1c1d1991bb908d89e4e9dddfe3e0 # v7.0.0
- name: Set up Python
uses: actions/setup-python@ece7cb06caefa5fff74198d8649806c4678c61a1 # v6.3.0
with:
python-version: "3.13"
- name: Generate packaging matrix
id: generate
working-directory: .github/scripts/strategy-matrix
run: ./generate.py --packaging >>"${GITHUB_OUTPUT}"
package:
needs: [generate-matrix]
if: ${{ github.event.repository.visibility == 'public' }}
strategy:
fail-fast: false
matrix: ${{ fromJson(needs.generate-matrix.outputs.matrix) }}
name: "${{ matrix.artifact_name }}"
permissions:
contents: read
runs-on: ["self-hosted", "Linux", "X64", "heavy"]
container: ${{ matrix.image }}
timeout-minutes: 30
steps:
- name: Checkout repository
uses: actions/checkout@9c091bb21b7c1c1d1991bb908d89e4e9dddfe3e0 # v7.0.0
- name: Download pre-built binary
uses: actions/download-artifact@3e5f45b2cfb9172054b4087a40e8e0b5a5461e7c # v8.0.1
with:
name: ${{ matrix.artifact_name }}
path: ${{ env.BUILD_DIR }}
- name: Make binary executable
run: chmod +x "${BUILD_DIR}/xrpld"
- name: Build package
env:
PKG_RELEASE: ${{ inputs.pkg_release }}
run: ./package/build_pkg.sh
- name: Upload package artifact
uses: actions/upload-artifact@043fb46d1a93c77aae656e7c1c64a875d1fc6a0a # v7.0.1
with:
name: ${{ matrix.artifact_name }}-pkg
path: |
${{ env.BUILD_DIR }}/debbuild/*.deb
${{ env.BUILD_DIR }}/debbuild/*.ddeb
${{ env.BUILD_DIR }}/rpmbuild/RPMS/**/*.rpm
if-no-files-found: error

View File

@@ -1,39 +0,0 @@
name: Generate strategy matrix
on:
workflow_call:
inputs:
os:
description: 'The operating system to use for the build ("linux", "macos", "windows", or empty for all).'
required: false
type: string
outputs:
matrix:
description: "The generated strategy matrix."
value: ${{ jobs.generate-matrix.outputs.matrix }}
defaults:
run:
shell: bash
jobs:
generate-matrix:
runs-on: ubuntu-latest
outputs:
matrix: ${{ steps.generate.outputs.matrix }}
steps:
- name: Checkout repository
uses: actions/checkout@9c091bb21b7c1c1d1991bb908d89e4e9dddfe3e0 # v7.0.0
- name: Set up Python
uses: actions/setup-python@ece7cb06caefa5fff74198d8649806c4678c61a1 # v6.3.0
with:
python-version: "3.13"
- name: Generate strategy matrix
working-directory: .github/scripts/strategy-matrix
id: generate
env:
GENERATE_CONFIG: ${{ inputs.os != '' && format('--config={0}', inputs.os) || '' }}
GENERATE_EVENT: ${{ github.event_name }}
run: ./generate.py ${GENERATE_CONFIG} --event="${GENERATE_EVENT}" >>"${GITHUB_OUTPUT}"

View File

@@ -1,95 +0,0 @@
# This workflow exports the built libxrpl package to the Conan remote.
name: Upload Conan recipe
# This workflow can only be triggered by other workflows.
on:
workflow_call:
inputs:
remote_name:
description: "The name of the Conan remote to use."
required: false
type: string
default: xrplf
remote_url:
description: "The URL of the Conan endpoint to use."
required: false
type: string
default: https://conan.xrplf.org/repository/conan/
secrets:
remote_username:
description: "The username for logging into the Conan remote."
required: true
remote_password:
description: "The password for logging into the Conan remote."
required: true
outputs:
recipe_ref:
description: "The Conan recipe reference ('name/version') that was uploaded."
value: ${{ jobs.upload.outputs.ref }}
concurrency:
group: ${{ github.workflow }}-${{ github.ref }}-upload-recipe
cancel-in-progress: true
defaults:
run:
shell: bash
jobs:
upload:
runs-on: ubuntu-latest
container: ghcr.io/xrplf/xrpld/nix-ubuntu:sha-e29b523
env:
REMOTE_NAME: ${{ inputs.remote_name }}
CONAN_LOGIN_USERNAME_XRPLF: ${{ secrets.remote_username }}
CONAN_PASSWORD_XRPLF: ${{ secrets.remote_password }}
steps:
- name: Checkout repository
uses: actions/checkout@9c091bb21b7c1c1d1991bb908d89e4e9dddfe3e0 # v7.0.0
- name: Generate build version number
id: version
uses: ./.github/actions/generate-version
- name: Set up Conan
uses: ./.github/actions/setup-conan
with:
remote_name: ${{ inputs.remote_name }}
remote_url: ${{ inputs.remote_url }}
- name: Log into Conan remote
run: conan remote login "${REMOTE_NAME}" "${CONAN_LOGIN_USERNAME_XRPLF}" --password "${CONAN_PASSWORD_XRPLF}"
- name: Upload Conan recipe (version)
run: |
conan export . --version=${{ steps.version.outputs.version }}
conan upload --confirm --check --remote="${REMOTE_NAME}" xrpl/${{ steps.version.outputs.version }}
# When this workflow is triggered by a push event, it will always be when merging into the
# 'develop' branch, see on-trigger.yml.
- name: Upload Conan recipe (develop)
if: ${{ github.event_name == 'push' }}
run: |
conan export . --version=develop
conan upload --confirm --check --remote="${REMOTE_NAME}" xrpl/develop
# When this workflow is triggered by a pull request event, it will always be when merging into
# one of the 'release' branches, see on-pr.yml.
- name: Upload Conan recipe (rc)
if: ${{ github.event_name == 'pull_request' }}
run: |
conan export . --version=rc
conan upload --confirm --check --remote="${REMOTE_NAME}" xrpl/rc
# When this workflow is triggered by a push event, it will always be when tagging a final
# release, see on-tag.yml.
- name: Upload Conan recipe (release)
if: ${{ startsWith(github.ref, 'refs/tags/') }}
run: |
conan export . --version=release
conan upload --confirm --check --remote="${REMOTE_NAME}" xrpl/release
outputs:
ref: xrpl/${{ steps.version.outputs.version }}

View File

@@ -1,310 +0,0 @@
# Telemetry Validation CI Workflow
#
# Builds rippled with telemetry enabled, runs the multi-node workload
# harness, validates all telemetry data, and runs performance benchmarks.
#
# This is a separate workflow from the main CI. It runs:
# - On manual dispatch (workflow_dispatch)
# - On pushes to telemetry-related branches
#
# The workflow is intentionally heavyweight (builds rippled, starts Docker
# services, runs a multi-node cluster) — it validates the full telemetry
# stack end-to-end rather than individual unit tests.
#
# Architecture: two jobs to leverage cached dependencies:
# 1. build-xrpld — runs on a self-hosted runner inside the same container
# image the main CI uses (debian-bookworm-gcc-13). This ensures Conan
# packages are fetched from the XRPLF remote instead of built from
# source, and ccache hits the remote cache.
# 2. validate-telemetry — runs on ubuntu-latest (which has Docker) to
# launch the telemetry stack (OTel collector, Prometheus, Tempo, etc.)
# and validate the full pipeline end-to-end.
name: Telemetry Validation
on:
workflow_dispatch:
inputs:
rpc_rate:
description: "RPC load rate (requests per second)"
required: false
default: "50"
rpc_duration:
description: "RPC load duration (seconds)"
required: false
default: "120"
tx_tps:
description: "Transaction submit rate (TPS)"
required: false
default: "5"
tx_duration:
description: "Transaction submit duration (seconds)"
required: false
default: "120"
run_benchmark:
description: "Run performance benchmarks"
required: false
type: boolean
default: false
push:
branches:
- "pratik/otel-phase*"
- "feature/otel-*"
- "feature/telemetry-*"
paths:
- ".github/workflows/telemetry-validation.yml"
- "docker/telemetry/**"
- "include/xrpl/basics/Telemetry*.h"
- "src/xrpld/app/misc/Telemetry*"
concurrency:
group: telemetry-validation-${{ github.ref }}
cancel-in-progress: true
defaults:
run:
shell: bash
env:
BUILD_DIR: build
jobs:
# ── Job 1: Build xrpld in the same container the main CI uses ──────
# This ensures Conan binary packages are fetched from the XRPLF remote
# (matching package IDs) and ccache hits the remote compilation cache.
build-xrpld:
name: Build xrpld
runs-on: [self-hosted, Linux, X64, heavy]
container: ghcr.io/xrplf/ci/debian-bookworm:gcc-13-sha-ab4d1f0
timeout-minutes: 60
env:
CCACHE_NAMESPACE: telemetry-validation
CCACHE_REMOTE_ONLY: true
CCACHE_REMOTE_STORAGE: http://cache.dev.ripplex.io:8080|layout=bazel
CCACHE_SLOPPINESS: include_file_ctime,include_file_mtime
steps:
- name: Checkout repository
uses: actions/checkout@de0fac2e4500dabe0009e67214ff5f5447ce83dd # v6.0.2
- name: Prepare runner
uses: XRPLF/actions/prepare-runner@90f11ee655d1687824fb8793db770477d52afbab
with:
enable_ccache: ${{ github.repository_owner == 'XRPLF' }}
- name: Print build environment
uses: XRPLF/actions/print-build-env@59dec886e4afb05a1724443af08baccbc045b574
- name: Get number of processors
uses: XRPLF/actions/get-nproc@cf0433aa74563aead044a1e395610c96d65a37cf
id: nproc
with:
subtract: 2
- name: Setup Conan
uses: ./.github/actions/setup-conan
- name: Build dependencies
uses: ./.github/actions/build-deps
with:
build_nproc: ${{ steps.nproc.outputs.nproc }}
build_type: Release
log_verbosity: verbose
- name: Configure CMake
working-directory: ${{ env.BUILD_DIR }}
run: |
cmake \
-G Ninja \
-DCMAKE_TOOLCHAIN_FILE:FILEPATH=build/generators/conan_toolchain.cmake \
-DCMAKE_BUILD_TYPE=Release \
..
- name: Build xrpld
working-directory: ${{ env.BUILD_DIR }}
env:
BUILD_NPROC: ${{ steps.nproc.outputs.nproc }}
run: |
cmake \
--build . \
--config Release \
--parallel "${BUILD_NPROC}" \
--target xrpld
- name: Show ccache statistics
if: ${{ github.repository_owner == 'XRPLF' }}
run: ccache --show-stats -vv
- name: Upload xrpld binary
uses: actions/upload-artifact@043fb46d1a93c77aae656e7c1c64a875d1fc6a0a # v7.0.1
with:
name: xrpld-telemetry
path: ${{ env.BUILD_DIR }}/xrpld
retention-days: 1
if-no-files-found: error
# ── Job 2: Run telemetry validation on ubuntu-latest (has Docker) ──
validate-telemetry:
name: Telemetry Stack Validation
needs: build-xrpld
runs-on: ubuntu-latest
timeout-minutes: 30
steps:
- name: Checkout repository
uses: actions/checkout@de0fac2e4500dabe0009e67214ff5f5447ce83dd # v6.0.2
- name: Install Python dependencies
run: pip3 install -r docker/telemetry/workload/requirements.txt
- name: Download xrpld binary
uses: actions/download-artifact@95815c38cf2ff2164869cbab79da8d1f422bc89e # v4.2.1
with:
name: xrpld-telemetry
path: ${{ env.BUILD_DIR }}
- name: Make binaries and scripts executable
run: |
chmod +x ${{ env.BUILD_DIR }}/xrpld
chmod +x docker/telemetry/workload/*.sh
- name: Run full telemetry validation
id: validation
env:
RPC_RATE: ${{ github.event.inputs.rpc_rate || '50' }}
RPC_DURATION: ${{ github.event.inputs.rpc_duration || '120' }}
TX_TPS: ${{ github.event.inputs.tx_tps || '5' }}
TX_DURATION: ${{ github.event.inputs.tx_duration || '120' }}
RUN_BENCHMARK: ${{ github.event.inputs.run_benchmark }}
run: |
ARGS="--xrpld ${{ env.BUILD_DIR }}/xrpld --skip-loki"
ARGS="$ARGS --rpc-rate $RPC_RATE"
ARGS="$ARGS --rpc-duration $RPC_DURATION"
ARGS="$ARGS --tx-tps $TX_TPS"
ARGS="$ARGS --tx-duration $TX_DURATION"
if [ "$RUN_BENCHMARK" = "true" ]; then
ARGS="$ARGS --with-benchmark"
fi
docker/telemetry/workload/run-full-validation.sh $ARGS
# continue-on-error allows subsequent steps (artifact upload,
# summary printing) to run even if validation fails. The final
# "Check validation result" step re-checks steps.validation.outcome
# (the pre-continue-on-error result) and fails the job properly.
continue-on-error: true
- name: Upload validation reports
if: always()
uses: actions/upload-artifact@043fb46d1a93c77aae656e7c1c64a875d1fc6a0a # v7.0.1
with:
name: telemetry-validation-reports
path: /tmp/xrpld-validation/reports/
retention-days: 30
- name: Upload node logs
if: failure()
uses: actions/upload-artifact@043fb46d1a93c77aae656e7c1c64a875d1fc6a0a # v7.0.1
with:
name: xrpld-node-logs
path: /tmp/xrpld-validation/node*/debug.log
retention-days: 7
- name: Print validation summary
if: always()
run: |
REPORT="/tmp/xrpld-validation/reports/validation-report.json"
if [ -f "$REPORT" ]; then
echo "## Telemetry Validation Results" >>"$GITHUB_STEP_SUMMARY"
echo "" >>"$GITHUB_STEP_SUMMARY"
TOTAL=$(jq '.summary.total' "$REPORT")
PASSED=$(jq '.summary.passed' "$REPORT")
FAILED=$(jq '.summary.failed' "$REPORT")
echo "| Metric | Value |" >>"$GITHUB_STEP_SUMMARY"
echo "|--------|-------|" >>"$GITHUB_STEP_SUMMARY"
echo "| Total Checks | $TOTAL |" >>"$GITHUB_STEP_SUMMARY"
echo "| Passed | $PASSED |" >>"$GITHUB_STEP_SUMMARY"
echo "| Failed | $FAILED |" >>"$GITHUB_STEP_SUMMARY"
echo "" >>"$GITHUB_STEP_SUMMARY"
if [ "$FAILED" -gt 0 ]; then
echo "### Failed Checks" >>"$GITHUB_STEP_SUMMARY"
echo "" >>"$GITHUB_STEP_SUMMARY"
jq -r '.checks[] | select(.passed == false) | "- **\(.name)**: \(.message)"' "$REPORT" >>"$GITHUB_STEP_SUMMARY"
fi
fi
# Publishes captured OTel timings + regression report to the Step Summary.
# When the committed baseline is a placeholder, emits a fenced JSON block
# that can be copy-pasted directly into baselines/baseline-timings.json.
# When the baseline is populated, summarises the top regressions so the
# PR author sees the failure reason without downloading artifacts.
- name: Print regression summary
if: always()
run: |
set -euo pipefail
TIMINGS="/tmp/xrpld-validation/reports/timings.json"
REGRESSION="/tmp/xrpld-validation/reports/regression-report.json"
BASELINE="docker/telemetry/workload/baselines/baseline-timings.json"
if [ ! -f "$TIMINGS" ]; then
echo "## Regression Gate: no timings captured" >>"$GITHUB_STEP_SUMMARY"
echo "::warning::capture_timings.py did not produce timings.json — regression gate was not evaluated."
exit 0
fi
if [ ! -f "$BASELINE" ]; then
echo "## Regression Gate: baseline file missing" >>"$GITHUB_STEP_SUMMARY"
echo "::error::baselines/baseline-timings.json not found in checkout"
exit 1
fi
# NOTE: do NOT use `jq -e` here. With -e, jq exits non-zero when the
# filter's result is boolean false — which is the normal case for a
# populated (non-placeholder) baseline — and that would be
# misreported as a parse failure. Plain `jq -r` exits 0 on any valid
# JSON, so a real non-zero exit genuinely means malformed JSON.
IS_PLACEHOLDER=$(jq -r '.placeholder == true or (.metrics | length == 0)' "$BASELINE") || {
echo "::error::Failed to parse baseline JSON"
exit 1
}
echo "## OTel Timings Regression Gate" >>"$GITHUB_STEP_SUMMARY"
echo "" >>"$GITHUB_STEP_SUMMARY"
if [ "$IS_PLACEHOLDER" = "true" ]; then
echo "### Paste into \`baselines/baseline-timings.json\`" >>"$GITHUB_STEP_SUMMARY"
echo "" >>"$GITHUB_STEP_SUMMARY"
echo "The committed baseline is a placeholder. Open a PR replacing" \
"its contents with the JSON block below to activate the" \
"regression gate." >>"$GITHUB_STEP_SUMMARY"
echo "" >>"$GITHUB_STEP_SUMMARY"
echo '```json' >>"$GITHUB_STEP_SUMMARY"
cat "$TIMINGS" >>"$GITHUB_STEP_SUMMARY"
echo '```' >>"$GITHUB_STEP_SUMMARY"
elif [ -f "$REGRESSION" ]; then
REGR_COUNT=$(jq -e '.summary.regressions' "$REGRESSION") || REGR_COUNT=0
IMPR_COUNT=$(jq -e '.summary.improvements' "$REGRESSION") || IMPR_COUNT=0
TOTAL=$(jq -e '.summary.total' "$REGRESSION") || TOTAL=0
echo "| Stat | Count |" >>"$GITHUB_STEP_SUMMARY"
echo "|------|-------|" >>"$GITHUB_STEP_SUMMARY"
echo "| Metrics compared | $TOTAL |" >>"$GITHUB_STEP_SUMMARY"
echo "| Regressions | $REGR_COUNT |" >>"$GITHUB_STEP_SUMMARY"
echo "| Improvements | $IMPR_COUNT |" >>"$GITHUB_STEP_SUMMARY"
echo "" >>"$GITHUB_STEP_SUMMARY"
if [ "$REGR_COUNT" -gt 0 ]; then
echo "### Regressions" >>"$GITHUB_STEP_SUMMARY"
echo "" >>"$GITHUB_STEP_SUMMARY"
echo "| Metric | Baseline | Current | Δ | % | Unit |" >>"$GITHUB_STEP_SUMMARY"
echo "|--------|---------:|--------:|--:|--:|------|" >>"$GITHUB_STEP_SUMMARY"
jq -r '.metrics[] | select(.regressed) | "| \(.key) | \(.baseline) | \(.current) | \(.delta) | \(.pct_change)% | \(.unit) |"' \
"$REGRESSION" >>"$GITHUB_STEP_SUMMARY"
fi
fi
- name: Cleanup
if: always()
run: |
docker/telemetry/workload/run-full-validation.sh --cleanup 2>/dev/null || true
- name: Check validation result
if: steps.validation.outcome == 'failure'
run: |
echo "Telemetry validation failed. Check the uploaded reports for details."
exit 1

View File

@@ -1,119 +0,0 @@
name: Upload Conan Dependencies
on:
schedule:
- cron: "0 3 * * 2-6"
workflow_dispatch:
inputs:
force_source_build:
description: "Force source build of all dependencies"
required: false
default: false
type: boolean
force_upload:
description: "Force upload of all dependencies"
required: false
default: false
type: boolean
pull_request:
branches: [develop]
paths:
# This allows testing changes to the upload workflow in a PR
- .github/workflows/upload-conan-deps.yml
push:
branches: [develop]
paths:
- .github/workflows/upload-conan-deps.yml
- .github/workflows/reusable-strategy-matrix.yml
- .github/actions/build-deps/action.yml
- .github/actions/setup-conan/action.yml
- ".github/scripts/strategy-matrix/**"
- conanfile.py
- conan.lock
- conan/profiles/**
env:
CONAN_REMOTE_NAME: xrplf
CONAN_REMOTE_URL: https://conan.xrplf.org/repository/conan/
NPROC_SUBTRACT: 2
concurrency:
group: ${{ github.workflow }}-${{ github.ref }}
cancel-in-progress: true
defaults:
run:
shell: bash
jobs:
# Generate the strategy matrix to be used by the following job.
generate-matrix:
uses: ./.github/workflows/reusable-strategy-matrix.yml
# Build and upload the dependencies for each configuration.
run-upload-conan-deps:
needs:
- generate-matrix
strategy:
fail-fast: false
matrix: ${{ fromJson(needs.generate-matrix.outputs.matrix) }}
runs-on: ${{ matrix.architecture.runner }}
container: ${{ matrix.image || null }}
steps:
- name: Cleanup workspace (macOS and Windows)
if: ${{ runner.os == 'macOS' || runner.os == 'Windows' }}
uses: XRPLF/actions/cleanup-workspace@c7d9ce5ebb03c752a354889ecd870cadfc2b1cd4
- name: Checkout repository
uses: actions/checkout@9c091bb21b7c1c1d1991bb908d89e4e9dddfe3e0 # v7.0.0
- name: Prepare runner
uses: XRPLF/actions/prepare-runner@64ec3cf3b152b4444638f470bbd6df7a7a30c81c
with:
enable_ccache: false
- name: Print build environment
uses: XRPLF/actions/print-build-env@59dec886e4afb05a1724443af08baccbc045b574
- name: Get number of processors
uses: XRPLF/actions/get-nproc@cf0433aa74563aead044a1e395610c96d65a37cf
id: nproc
with:
subtract: ${{ env.NPROC_SUBTRACT }}
- name: Set compiler environment (Linux)
if: ${{ runner.os == 'Linux' }}
uses: ./.github/actions/set-compiler-env
with:
compiler: ${{ matrix.compiler }}
- name: Setup Conan
env:
SANITIZERS: ${{ matrix.sanitizers }}
uses: ./.github/actions/setup-conan
with:
remote_name: ${{ env.CONAN_REMOTE_NAME }}
remote_url: ${{ env.CONAN_REMOTE_URL }}
- name: Build dependencies
uses: ./.github/actions/build-deps
with:
build_nproc: ${{ steps.nproc.outputs.nproc }}
build_type: ${{ matrix.build_type }}
force_build: ${{ github.event_name == 'schedule' || github.event.inputs.force_source_build == 'true' }}
# Set the verbosity to "quiet" for Windows to avoid an excessive
# amount of logs. For other OSes, the "verbose" logs are more useful.
log_verbosity: ${{ runner.os == 'Windows' && 'quiet' || 'verbose' }}
sanitizers: ${{ matrix.sanitizers }}
- name: Log into Conan remote
if: ${{ github.repository == 'XRPLF/rippled' && (github.event_name == 'push' || github.event_name == 'workflow_dispatch') }}
run: conan remote login "${CONAN_REMOTE_NAME}" "${{ secrets.NEXUS_REMOTE_USERNAME }}" --password "${{ secrets.NEXUS_REMOTE_PASSWORD }}"
- name: Upload Conan packages
if: ${{ github.repository == 'XRPLF/rippled' && (github.event_name == 'push' || github.event_name == 'workflow_dispatch') }}
env:
FORCE_OPTION: ${{ github.event.inputs.force_upload == 'true' && '--force' || '' }}
CONAN_LOGIN_USERNAME_XRPLF: ${{ secrets.NEXUS_REMOTE_USERNAME }}
CONAN_PASSWORD_XRPLF: ${{ secrets.NEXUS_REMOTE_PASSWORD }}
run: conan upload "*" --remote="${CONAN_REMOTE_NAME}" --confirm ${FORCE_OPTION}

99
.github/workflows/windows.yml vendored Normal file
View File

@@ -0,0 +1,99 @@
name: windows
on:
pull_request:
types: [opened, reopened, synchronize, ready_for_review]
push:
# If the branches list is ever changed, be sure to change it on all
# build/test jobs (nix, macos, windows, instrumentation)
branches:
# Always build the package branches
- develop
- release
- master
# Branches that opt-in to running
- 'ci/**'
# https://docs.github.com/en/actions/using-jobs/using-concurrency
concurrency:
group: ${{ github.workflow }}-${{ github.ref }}
cancel-in-progress: true
jobs:
test:
if: ${{ github.event_name == 'push' || github.event.pull_request.draft != true || contains(github.event.pull_request.labels.*.name, 'DraftRunCI') }}
strategy:
fail-fast: false
matrix:
version:
- generator: Visual Studio 17 2022
runs-on: windows-2022
configuration:
- type: Release
tests: true
- type: Debug
# Skip running unit tests on debug builds, because they
# take an unreasonable amount of time
tests: false
runtime: d
runs-on: ${{ matrix.version.runs-on }}
env:
build_dir: .build
steps:
- name: checkout
uses: actions/checkout@v4
- name: choose Python
uses: actions/setup-python@v5
with:
python-version: 3.9
- name: learn Python cache directory
id: pip-cache
shell: bash
run: |
python -m pip install --upgrade pip
echo "dir=$(pip cache dir)" | tee ${GITHUB_OUTPUT}
- name: restore Python cache directory
uses: actions/cache@v4
with:
path: ${{ steps.pip-cache.outputs.dir }}
key: ${{ runner.os }}-${{ hashFiles('.github/workflows/windows.yml') }}
- name: install Conan
run: pip install wheel 'conan<2'
- name: check environment
run: |
dir env:
$env:PATH -split ';'
python --version
conan --version
cmake --version
- name: configure Conan
shell: bash
run: |
conan profile new default --detect
conan profile update settings.compiler.cppstd=20 default
conan profile update \
settings.compiler.runtime=MT${{ matrix.configuration.runtime }} \
default
- name: build dependencies
uses: ./.github/actions/dependencies
env:
CONAN_URL: http://18.143.149.228:8081/artifactory/api/conan/conan-non-prod
CONAN_LOGIN_USERNAME_RIPPLE: ${{ secrets.CONAN_USERNAME }}
CONAN_PASSWORD_RIPPLE: ${{ secrets.CONAN_TOKEN }}
with:
configuration: ${{ matrix.configuration.type }}
- name: build
uses: ./.github/actions/build
with:
generator: '${{ matrix.version.generator }}'
configuration: ${{ matrix.configuration.type }}
# Hard code for now. Move to the matrix if varied options are needed
cmake-args: '-Dassert=TRUE -Dwerr=TRUE -Dreporting=OFF -Dunity=ON'
cmake-target: install
- name: test
shell: bash
if: ${{ matrix.configuration.tests }}
run: |
${build_dir}/${{ matrix.configuration.type }}/rippled --unittest \
--unittest-jobs $(nproc)

134
.gitignore vendored
View File

@@ -1,52 +1,70 @@
# .gitignore
# cspell: disable
# Macintosh Desktop Services Store files.
bin/boostbook_catalog.xml
bin/config.log
bin/project-cache.jam
# Ignore vim swap files.
*.swp
# Ignore SCons support files.
.sconsign.dblite
# Ignore python compiled files.
*.pyc
# Ignore Macintosh Desktop Services Store files.
.DS_Store
# Build, intermediate, and temporary artifacts.
# Ignore backup/temps
*~
*.o
*.pdb
*.swp
/.clangd
Debug/
Release/
/.build/
/.venv/
/build/
/db/
/out.txt
/Testing/
/tmp/
CMakeSettings.json
CMakeUserPresets.json
# Coverage files.
# Ignore object files.
*.o
.nih_c
tags
TAGS
GTAGS
GRTAGS
GPATH
bin/rippled
Debug/*.*
Release/*.*
# Ignore coverage files.
*.gcno
*.gcda
*.gcov
# Profiling data.
gmon.out
# Levelization checking
Builds/levelization/results/rawincludes.txt
Builds/levelization/results/paths.txt
Builds/levelization/results/includes/
Builds/levelization/results/includedby/
# Levelization data.
.github/scripts/levelization/results/*
!.github/scripts/levelization/results/loops.txt
!.github/scripts/levelization/results/ordering.txt
# Ignore tmp directory.
tmp
# Customized configs.
/rippled.cfg
/xrpld.cfg
/validators.txt
# Ignore database directory.
db/
db/*.db
db/*.db-*
# Locally patched Conan recipes
external/conan-center-index/
# Ignore debug logs
debug_log.txt
# Local conan directory
.conan
# Ignore customized configs
rippled.cfg
validators.txt
# XCode IDE.
# Doxygen generated documentation output
HtmlDocumentation
docs/html_doc
# Xcode user-specific project settings
# Xcode
.DS_Store
/build/
*.pbxuser
!default.pbxuser
*.mode1v3
@@ -59,32 +77,38 @@ xcuserdata
profile
*.moved-aside
DerivedData
.idea/
*.hmap
# JetBrains IDE.
/.idea/
# Intel Parallel Studio 2013 XE
My Amplifier XE Results - RippleD
# Microsoft Visual Studio IDE.
/.vs/
/.vscode/
# Compiler intermediate output
/out.txt
# zed IDE.
/.zed/
# Build Log
rippled-build.log
# AI tools.
/.agent
/.agents
/.augment
/.claude
/CLAUDE.md
# Profiling data
gmon.out
# Python
__pycache__
Builds/VisualStudio2015/*.db
Builds/VisualStudio2015/*.user
Builds/VisualStudio2015/*.opendb
Builds/VisualStudio2015/*.sdf
# Direnv's directory
/.direnv
# MSVC
*.pdb
.vs/
CMakeSettings.json
compile_commands.json
.clangd
packages
pkg_out
pkg
CMakeUserPresets.json
bld.rippled/
.vscode
# clangd cache
/.cache
docker/telemetry/workload/__pycache__/
.claude/
# Suggested in-tree build directory
/.build/

View File

@@ -1,131 +1,6 @@
# To run pre-commit hooks, first install pre-commit:
# - `pip install pre-commit==${PRE_COMMIT_VERSION}`
#
# Then, run the following command to install the git hook scripts:
# - `pre-commit install`
# You can run all configured hooks against all files with:
# - `pre-commit run --all-files`
# To manually run a specific hook, use:
# - `pre-commit run <hook_id> --all-files`
# To run the hooks against only the staged files, use:
# - `pre-commit run`
# .pre-commit-config.yaml
repos:
- repo: https://github.com/pre-commit/pre-commit-hooks
rev: 3e8a8703264a2f4a69428a0aa4dcb512790b2c8c # frozen: v6.0.0
hooks:
- id: check-added-large-files
args: [--maxkb=400, --enforce-all]
- id: check-executables-have-shebangs
- id: trailing-whitespace
- id: end-of-file-fixer
- id: check-merge-conflict
args: [--assume-in-merge]
- repo: local
hooks:
- id: clang-tidy
name: "clang-tidy (enable with: TIDY=1)"
entry: ./bin/pre-commit/clang_tidy_check.py
language: python
types_or: [c++, c]
# .ipp fragments are included by their owning header rather than compiled
# as standalone translation units, so they have no compile_commands.json
# entry to lint (verify_headers checks them transitively).
exclude: '^include/xrpl/protocol_autogen|\.ipp$'
- id: fix-include-style
name: fix include style
entry: ./bin/pre-commit/fix_include_style.py
language: python
types_or: [c++, c]
exclude: ^include/xrpl/protocol_autogen/(transactions|ledger_entries)/
- id: fix-pragma-once
name: fix missing '#pragma once' declarations in header files
language: python
entry: ./bin/pre-commit/fix_pragma_once.py
files: \.(h|hpp)$
- repo: https://github.com/pre-commit/mirrors-clang-format
rev: dd18dad857d6133e90bbe478f4f2f22ec0030269 # frozen: v22.1.5
hooks:
- id: clang-format
args: [--style=file]
types_or: [c++, c, proto]
exclude: ^include/xrpl/protocol_autogen/(transactions|ledger_entries)/
- repo: https://github.com/BlankSpruce/gersemi-pre-commit
rev: e98930bdc210d3387007f9252d8c1694ea7e410f # frozen: 0.27.7
hooks:
- id: gersemi
- repo: https://github.com/rbubley/mirrors-prettier
rev: 39e2973981e6d2f9b6c543b0086a2d2393abdc89 # frozen: v3.9.4
hooks:
- id: prettier
args: [--end-of-line=auto]
- repo: https://github.com/psf/black-pre-commit-mirror
rev: 4160603246a6b365d4a2af661c6d71b0a0f50478 # frozen: 26.5.1
hooks:
- id: black
- repo: https://github.com/scop/pre-commit-shfmt
rev: 05c1426671b9237fb5e1444dd63aa5731bec0dfb # frozen: v3.13.1-1
hooks:
- id: shfmt
args: [--write, --indent=4, --case-indent=true]
- repo: local
hooks:
- id: format-inline-bash-workflows
name: "format `run:` blocks in workflows/actions"
entry: ./.github/scripts/format-inline-bash.py
language: python
files: ^\.github/(workflows|actions)/.*\.ya?ml$
- id: format-inline-bash-markdown
name: "format ```bash blocks in markdown"
entry: ./.github/scripts/format-inline-bash.py
language: python
files: \.md$
- repo: https://github.com/streetsidesoftware/cspell-cli
rev: ea11f9efc0bec520073405bc30552da887ba71bc # frozen: v10.0.1
hooks:
- id: cspell
name: check changed files spelling
exclude: |
(?x)^(
\.cspell\.config\.yaml|
include/xrpl/protocol_autogen/(transactions|ledger_entries)/.*
)$
- id: cspell
name: check commit message spelling
args:
- --no-must-find-files
- --no-progress
- --no-summary
stages: [commit-msg]
- repo: local
hooks:
- id: nix-fmt
name: Format Nix files
entry: |
bash -c '
if command -v nix &> /dev/null || [ "$GITHUB_ACTIONS" = "true" ]; then
nix --extra-experimental-features "nix-command flakes" fmt "$@"
else
echo "Skipping nix-fmt: nix not installed and not in GitHub Actions"
exit 0
fi
' --
language: system
types:
- nix
pass_filenames: true
exclude: |
(?x)^(
external/.*|
.github/scripts/levelization/results/.*\.txt|
src/tests/libxrpl/protocol_autogen/(transactions|ledger_entries)/.*
)$
- repo: https://github.com/pre-commit/mirrors-clang-format
rev: v18.1.3
hooks:
- id: clang-format

View File

@@ -1 +0,0 @@
external

View File

@@ -4,116 +4,92 @@ This changelog is intended to list all updates to the [public API methods](https
For info about how [API versioning](https://xrpl.org/request-formatting.html#api-versioning) works, including examples, please view the [XLS-22d spec](https://github.com/XRPLF/XRPL-Standards/discussions/54). For details about the implementation of API versioning, view the [implementation PR](https://github.com/XRPLF/rippled/pull/3155). API versioning ensures existing integrations and users continue to receive existing behavior, while those that request a higher API version will experience new behavior.
The API version controls the API behavior you see. This includes what properties you see in responses, what parameters you're permitted to send in requests, and so on. You specify the API version in each of your requests. When a breaking change is introduced to the `xrpld` API, a new version is released. To avoid breaking your code, you should set (or increase) your version when you're ready to upgrade.
The API version controls the API behavior you see. This includes what properties you see in responses, what parameters you're permitted to send in requests, and so on. You specify the API version in each of your requests. When a breaking change is introduced to the `rippled` API, a new version is released. To avoid breaking your code, you should set (or increase) your version when you're ready to upgrade.
The [commandline](https://xrpl.org/docs/references/http-websocket-apis/api-conventions/request-formatting/#commandline-format) always uses the latest API version. The command line is intended for ad-hoc usage by humans, not programs or automated scripts. The command line is not meant for use in production code.
For a log of breaking changes, see the **API Version [number]** headings. In general, breaking changes are associated with a particular API Version number. For non-breaking changes, scroll to the **XRP Ledger version [x.y.z]** headings. Non-breaking changes are associated with a particular XRP Ledger (`xrpld`) release.
## API Version 3 (Beta)
API version 3 is currently a beta API. It requires enabling `[beta_rpc_api]` in the xrpld configuration to use. See [API-VERSION-3.md](API-VERSION-3.md) for the full list of changes in API version 3.
For a log of breaking changes, see the **API Version [number]** headings. In general, breaking changes are associated with a particular API Version number. For non-breaking changes, scroll to the **XRP Ledger version [x.y.z]** headings. Non-breaking changes are associated with a particular XRP Ledger (`rippled`) release.
## API Version 2
API version 2 is available in `xrpld` version 2.0.0 and later. See [API-VERSION-2.md](API-VERSION-2.md) for the full list of changes in API version 2.
API version 2 is available in `rippled` version 2.0.0 and later. To use this API, clients specify `"api_version" : 2` in each request.
#### Removed methods
In API version 2, the following deprecated methods are no longer available: (https://github.com/XRPLF/rippled/pull/4759)
- `tx_history` - Instead, use other methods such as `account_tx` or `ledger` with the `transactions` field set to `true`.
- `ledger_header` - Instead, use the `ledger` method.
#### Modifications to JSON transaction element in V2
In API version 2, JSON elements for transaction output have been changed and made consistent for all methods which output transactions. (https://github.com/XRPLF/rippled/pull/4775)
This helps to unify the JSON serialization format of transactions. (https://github.com/XRPLF/clio/issues/722, https://github.com/XRPLF/rippled/issues/4727)
- JSON transaction element is named `tx_json`
- Binary transaction element is named `tx_blob`
- JSON transaction metadata element is named `meta`
- Binary transaction metadata element is named `meta_blob`
Additionally, these elements are now consistently available next to `tx_json` (i.e. sibling elements), where possible:
- `hash` - Transaction ID. This data was stored inside transaction output in API version 1, but in API version 2 is a sibling element.
- `ledger_index` - Ledger index (only set on validated ledgers)
- `ledger_hash` - Ledger hash (only set on closed or validated ledgers)
- `close_time_iso` - Ledger close time expressed in ISO 8601 time format (only set on validated ledgers)
- `validated` - Bool element set to `true` if the transaction is in a validated ledger, otherwise `false`
This change affects the following methods:
- `tx` - Transaction data moved into element `tx_json` (was inline inside `result`) or, if binary output was requested, moved from `tx` to `tx_blob`. Renamed binary transaction metadata element (if it was requested) from `meta` to `meta_blob`. Changed location of `hash` and added new elements
- `account_tx` - Renamed transaction element from `tx` to `tx_json`. Renamed binary transaction metadata element (if it was requested) from `meta` to `meta_blob`. Changed location of `hash` and added new elements
- `transaction_entry` - Renamed transaction metadata element from `metadata` to `meta`. Changed location of `hash` and added new elements
- `subscribe` - Renamed transaction element from `transaction` to `tx_json`. Changed location of `hash` and added new elements
- `sign`, `sign_for`, `submit` and `submit_multisigned` - Changed location of `hash` element.
#### Modification to `Payment` transaction JSON schema
When reading Payments, the `Amount` field should generally **not** be used. Instead, use [delivered_amount](https://xrpl.org/partial-payments.html#the-delivered_amount-field) to see the amount that the Payment delivered. To clarify its meaning, the `Amount` field is being renamed to `DeliverMax`. (https://github.com/XRPLF/rippled/pull/4733)
- In `Payment` transaction type, JSON RPC field `Amount` is renamed to `DeliverMax`. To enable smooth client transition, `Amount` is still handled, as described below: (https://github.com/XRPLF/rippled/pull/4733)
- On JSON RPC input (e.g. `submit_multisigned` etc. methods), `Amount` is recognized as an alias to `DeliverMax` for both API version 1 and version 2 clients.
- On JSON RPC input, submitting both `Amount` and `DeliverMax` fields is allowed _only_ if they are identical; otherwise such input is rejected with `rpcINVALID_PARAMS` error.
- On JSON RPC output (e.g. `subscribe`, `account_tx` etc. methods), `DeliverMax` is present in both API version 1 and version 2.
- On JSON RPC output, `Amount` is only present in API version 1 and _not_ in version 2.
#### Modifications to account_info response
- `signer_lists` is returned in the root of the response. (In API version 1, it was nested under `account_data`.) (https://github.com/XRPLF/rippled/pull/3770)
- When using an invalid `signer_lists` value, the API now returns an "invalidParams" error. (https://github.com/XRPLF/rippled/pull/4585)
- (`signer_lists` must be a boolean. In API version 1, strings were accepted and may return a normal response - i.e. as if `signer_lists` were `true`.)
#### Modifications to [account_tx](https://xrpl.org/account_tx.html#account_tx) response
- Using `ledger_index_min`, `ledger_index_max`, and `ledger_index` returns `invalidParams` because if you use `ledger_index_min` or `ledger_index_max`, then it does not make sense to also specify `ledger_index`. In API version 1, no error was returned. (https://github.com/XRPLF/rippled/pull/4571)
- The same applies for `ledger_index_min`, `ledger_index_max`, and `ledger_hash`. (https://github.com/XRPLF/rippled/issues/4545#issuecomment-1565065579)
- Using a `ledger_index_min` or `ledger_index_max` beyond the range of ledgers that the server has:
- returns `lgrIdxMalformed` in API version 2. Previously, in API version 1, no error was returned. (https://github.com/XRPLF/rippled/issues/4288)
- Attempting to use a non-boolean value (such as a string) for the `binary` or `forward` parameters returns `invalidParams` (`rpcINVALID_PARAMS`). Previously, in API version 1, no error was returned. (https://github.com/XRPLF/rippled/pull/4620)
#### Modifications to [noripple_check](https://xrpl.org/noripple_check.html#noripple_check) response
- Attempting to use a non-boolean value (such as a string) for the `transactions` parameter returns `invalidParams` (`rpcINVALID_PARAMS`). Previously, in API version 1, no error was returned. (https://github.com/XRPLF/rippled/pull/4620)
## API Version 1
This version is supported by all `xrpld` versions. For WebSocket and HTTP JSON-RPC requests, it is currently the default API version used when no `api_version` is specified.
This version is supported by all `rippled` versions. For WebSocket and HTTP JSON-RPC requests, it is currently the default API version used when no `api_version` is specified.
## Unreleased
The [commandline](https://xrpl.org/docs/references/http-websocket-apis/api-conventions/request-formatting/#commandline-format) always uses the latest API version. The command line is intended for ad-hoc usage by humans, not programs or automated scripts. The command line is not meant for use in production code.
This section contains changes targeting a future version.
### Inconsistency: server_info - network_id
### Additions
- `ledger_entry`, `account_objects`: The `Delegate` ledger entry now includes an optional `DestinationNode` field, which stores the index into the authorized account's owner directory. This field is present on entries created after bidirectional directory tracking was introduced and may appear in RPC responses for those entries. ([#6681](https://github.com/XRPLF/rippled/pull/6681))
- `server_definitions`: Added the following new sections to the response ([#6321](https://github.com/XRPLF/rippled/pull/6321)):
- `TRANSACTION_FORMATS`: Describes the fields and their optionality for each transaction type, including common fields shared across all transactions.
- `LEDGER_ENTRY_FORMATS`: Describes the fields and their optionality for each ledger entry type, including common fields shared across all ledger entries.
- `TRANSACTION_FLAGS`: Maps transaction type names to their supported flags and flag values.
- `LEDGER_ENTRY_FLAGS`: Maps ledger entry type names to their flags and flag values.
- `ACCOUNT_SET_FLAGS`: Maps AccountSet flag names (asf flags) to their numeric values.
### Bugfixes
- Peer Crawler: The `port` field in `overlay.active[]` now consistently returns an integer instead of a string for outbound peers. [#6318](https://github.com/XRPLF/rippled/pull/6318)
- `ping`: The `ip` field is no longer returned as an empty string for proxied connections without a forwarded-for header. It is now omitted, consistent with the behavior for identified connections. [#6730](https://github.com/XRPLF/rippled/pull/6730)
- gRPC `GetLedgerDiff`: Fixed error message that incorrectly said "base ledger not validated" when the desired ledger was not validated. [#6730](https://github.com/XRPLF/rippled/pull/6730)
- `account_channels`: The `destination_account` field now returns an error if the value is not a string. [#6529](https://github.com/XRPLF/rippled/pull/6529)
- `subscribe`: The `taker` field in the `books` array now returns an error if the value is not a string. [#6529](https://github.com/XRPLF/rippled/pull/6529)
- `account_info`: The `urlgravatar` field now uses HTTPS instead of HTTP. [#6529](https://github.com/XRPLF/rippled/pull/6529)
- `ledger`: The `full`, `accounts`, `transactions`, `expand`, `binary`, `owner_funds`, and `queue` fields now return an error if the value is not a boolean. [#6529](https://github.com/XRPLF/rippled/pull/6529)
- `ledger_data`: The `binary` field now returns an error if the value is not a boolean. [#6529](https://github.com/XRPLF/rippled/pull/6529)
- `submit`: The `fail_hard` field now returns an error if the value is not a boolean. [#6529](https://github.com/XRPLF/rippled/pull/6529)
- `subscribe`: The `taker` field in the `books` array now returns `actMalformed` instead of `badIssuer` if the value is not a valid account. [#6529](https://github.com/XRPLF/rippled/pull/6529)
- Fixed a bug in `Forwarded` HTTP header parsing where the extracted IP address could be incorrect when no comma or semicolon delimiter follows the address. This could cause the server to misidentify a client's IP address when operating behind a reverse proxy. [#6529](https://github.com/XRPLF/rippled/pull/6529)
## XRP Ledger server version 3.1.0
[Version 3.1.0](https://github.com/XRPLF/rippled/releases/tag/3.1.0) was released on Jan 27, 2026.
### Additions in 3.1.0
- `vault_info`: New RPC method to retrieve information about a specific vault (part of XLS-66 Lending Protocol). ([#6156](https://github.com/XRPLF/rippled/pull/6156))
## XRP Ledger server version 3.0.0
[Version 3.0.0](https://github.com/XRPLF/rippled/releases/tag/3.0.0) was released on Dec 9, 2025.
### Additions in 3.0.0
- `ledger_entry`: Supports all ledger entry types with dedicated parsers. ([#5237](https://github.com/XRPLF/rippled/pull/5237))
- `ledger_entry`: New error codes `entryNotFound` and `unexpectedLedgerType` for more specific error handling. ([#5237](https://github.com/XRPLF/rippled/pull/5237))
- `ledger_entry`: Improved error messages with more context (e.g., specifying which field is invalid or missing). ([#5237](https://github.com/XRPLF/rippled/pull/5237))
- `ledger_entry`: Assorted bug fixes in RPC processing. ([#5237](https://github.com/XRPLF/rippled/pull/5237))
- `simulate`: Supports additional metadata in the response. ([#5754](https://github.com/XRPLF/rippled/pull/5754))
## XRP Ledger server version 2.6.2
[Version 2.6.2](https://github.com/XRPLF/rippled/releases/tag/2.6.2) was released on Nov 19, 2025.
This release contains bug fixes only and no API changes.
## XRP Ledger server version 2.6.1
[Version 2.6.1](https://github.com/XRPLF/rippled/releases/tag/2.6.1) was released on Sep 30, 2025.
This release contains bug fixes only and no API changes.
## XRP Ledger server version 2.6.0
[Version 2.6.0](https://github.com/XRPLF/rippled/releases/tag/2.6.0) was released on Aug 27, 2025.
### Additions in 2.6.0
- `account_info`: Added `allowTrustLineLocking` flag in response. ([#5525](https://github.com/XRPLF/rippled/pull/5525))
- `ledger`: Removed the type filter from the RPC command. ([#4934](https://github.com/XRPLF/rippled/pull/4934))
- `subscribe` (`validations` stream): `network_id` is now included. ([#5579](https://github.com/XRPLF/rippled/pull/5579))
- `subscribe` (`transactions` stream): `nftoken_id`, `nftoken_ids`, and `offer_id` are now included in transaction metadata. ([#5230](https://github.com/XRPLF/rippled/pull/5230))
## XRP Ledger server version 2.5.1
[Version 2.5.1](https://github.com/XRPLF/rippled/releases/tag/2.5.1) was released on Sep 17, 2025.
This release contains bug fixes only and no API changes.
The `network_id` field was added in the `server_info` response in version 1.5.0 (2019), but it is not returned in [reporting mode](https://xrpl.org/rippled-server-modes.html#reporting-mode). However, use of reporting mode is now discouraged, in favor of using [Clio](https://github.com/XRPLF/clio) instead.
## XRP Ledger server version 2.5.0
[Version 2.5.0](https://github.com/XRPLF/rippled/releases/tag/2.5.0) was released on Jun 24, 2025.
As of 2025-04-04, version 2.5.0 is in development. You can use a pre-release version by building from source or [using the `nightly` package](https://xrpl.org/docs/infrastructure/installation/install-rippled-on-ubuntu).
### Additions and bugfixes in 2.5.0
- `tx`: Added `ctid` field to the response and improved error handling. ([#4738](https://github.com/XRPLF/rippled/pull/4738))
- `ledger_entry`: Improved error messages in `permissioned_domain`. ([#5344](https://github.com/XRPLF/rippled/pull/5344))
- `simulate`: Improved multi-sign usage. ([#5479](https://github.com/XRPLF/rippled/pull/5479))
- `channel_authorize`: If `signing_support` is not enabled in the config, the RPC is disabled. ([#5385](https://github.com/XRPLF/rippled/pull/5385))
- `subscribe` (admin): Removed webhook queue limit to prevent dropping notifications; reduced HTTP timeout from 10 minutes to 30 seconds. ([#5163](https://github.com/XRPLF/rippled/pull/5163))
- `ledger_data` (gRPC): Fixed crashing issue with some invalid markers. ([#5137](https://github.com/XRPLF/rippled/pull/5137))
- `account_lines`: Fixed error with `no_ripple` and `no_ripple_peer` sometimes showing up incorrectly. ([#5345](https://github.com/XRPLF/rippled/pull/5345))
- `account_tx`: Fixed issue with incorrect CTIDs. ([#5408](https://github.com/XRPLF/rippled/pull/5408))
- `channel_authorize`: If `signing_support` is not enabled in the config, the RPC is disabled.
## XRP Ledger server version 2.4.0
@@ -121,19 +97,11 @@ This release contains bug fixes only and no API changes.
### Additions and bugfixes in 2.4.0
- `simulate`: A new RPC that executes a [dry run of a transaction submission](https://github.com/XRPLF/XRPL-Standards/tree/master/XLS-0069d-simulate#2-rpc-simulate). ([#5069](https://github.com/XRPLF/rippled/pull/5069))
- Signing methods (`sign`, `sign_for`, `submit`): Autofill fees better, properly handle transactions without a base fee, and autofill the `NetworkID` field. ([#5069](https://github.com/XRPLF/rippled/pull/5069))
- `ledger_entry`: `state` is added as an alias for `ripple_state`. ([#5199](https://github.com/XRPLF/rippled/pull/5199))
- `ledger`, `ledger_data`, `account_objects`: Support filtering ledger entry types by their canonical names (case-insensitive). ([#5271](https://github.com/XRPLF/rippled/pull/5271))
- `validators`: Added new field `validator_list_threshold` in response. ([#5112](https://github.com/XRPLF/rippled/pull/5112))
- `server_info`: Added git commit hash info on admin connection. ([#5225](https://github.com/XRPLF/rippled/pull/5225))
- `server_definitions`: Changed larger `UInt` serialized types to `Hash`. ([#5231](https://github.com/XRPLF/rippled/pull/5231))
## XRP Ledger server version 2.3.1
[Version 2.3.1](https://github.com/XRPLF/rippled/releases/tag/2.3.1) was released on Jan 29, 2025.
This release contains bug fixes only and no API changes.
- `ledger_entry`: `state` is added an alias for `ripple_state`.
- `ledger_entry`: Enables case-insensitive filtering by canonical name in addition to case-sensitive filtering by RPC name.
- `validators`: Added new field `validator_list_threshold` in response.
- `simulate`: A new RPC that executes a [dry run of a transaction submission](https://github.com/XRPLF/XRPL-Standards/tree/master/XLS-0069d-simulate#2-rpc-simulate)
- Signing methods autofill fees better and properly handle transactions that don't have a base fee, and will also autofill the `NetworkID` field.
## XRP Ledger server version 2.3.0
@@ -141,30 +109,19 @@ This release contains bug fixes only and no API changes.
### Breaking changes in 2.3.0
- `book_changes`: If the requested ledger version is not available on this node, a `ledgerNotFound` error is returned and the node does not attempt to acquire the ledger from the p2p network (as with other non-admin RPCs). Admins can still attempt to retrieve old ledgers with the `ledger_request` RPC.
- `book_changes`: If the requested ledger version is not available on this node, a `ledgerNotFound` error is returned and the node does not attempt to acquire the ledger from the p2p network (as with other non-admin RPCs).
Admins can still attempt to retrieve old ledgers with the `ledger_request` RPC.
### Additions and bugfixes in 2.3.0
- `book_changes`: Returns a `validated` field in its response. ([#5096](https://github.com/XRPLF/rippled/pull/5096))
- `book_changes`: Accepts shortcut strings (`current`, `closed`, `validated`) for the `ledger_index` parameter. ([#5096](https://github.com/XRPLF/rippled/pull/5096))
- `server_definitions`: Include `index` in response. ([#5190](https://github.com/XRPLF/rippled/pull/5190))
- `account_nfts`: Fix issue where unassociated marker would return incorrect results. ([#5045](https://github.com/XRPLF/rippled/pull/5045))
- `account_objects`: Fix issue where invalid marker would not return an error. ([#5046](https://github.com/XRPLF/rippled/pull/5046))
- `account_objects`: Disallow filtering by ledger entry types that an account cannot hold. ([#5056](https://github.com/XRPLF/rippled/pull/5056))
- `tx`: Allow lowercase CTID. ([#5049](https://github.com/XRPLF/rippled/pull/5049))
- `feature`: Better error handling for invalid values of `feature`. ([#5063](https://github.com/XRPLF/rippled/pull/5063))
- `book_changes`: Returns a `validated` field in its response, which was missing in prior versions.
## XRP Ledger server version 2.2.0
[Version 2.2.0](https://github.com/XRPLF/rippled/releases/tag/2.2.0) was released on Jun 5, 2024. The following additions are non-breaking (because they are purely additive):
- `feature`: Add a non-admin mode for users. (It was previously only available to admin connections.) The method returns an updated list of amendments, including their names and other information. ([#4781](https://github.com/XRPLF/rippled/pull/4781))
## XRP Ledger server version 2.0.1
[Version 2.0.1](https://github.com/XRPLF/rippled/releases/tag/2.0.1) was released on Jan 29, 2024. The following additions are non-breaking:
- `path_find`: Fixes unbounded memory growth. ([#4822](https://github.com/XRPLF/rippled/pull/4822))
- The `feature` method now has a non-admin mode for users. (It was previously only available to admin connections.) The method returns an updated list of amendments, including their names and other information. ([#4781](https://github.com/XRPLF/rippled/pull/4781))
## XRP Ledger server version 2.0.0
@@ -172,18 +129,24 @@ This release contains bug fixes only and no API changes.
- `server_definitions`: A new RPC that generates a `definitions.json`-like output that can be used in XRPL libraries.
- In `Payment` transactions, `DeliverMax` has been added. This is a replacement for the `Amount` field, which should not be used. Typically, the `delivered_amount` (in transaction metadata) should be used. To ease the transition, `DeliverMax` is present regardless of API version, since adding a field is non-breaking.
- API version 2 has been moved from beta to supported, meaning that it is generally available (regardless of the `beta_rpc_api` setting). The full list of changes is in [API-VERSION-2.md](API-VERSION-2.md).
- API version 2 has been moved from beta to supported, meaning that it is generally available (regardless of the `beta_rpc_api` setting).
## XRP Ledger server version 2.2.0
The following is a non-breaking addition to the API.
- The `feature` method now has a non-admin mode for users. (It was previously only available to admin connections.) The method returns an updated list of amendments, including their names and other information. ([#4781](https://github.com/XRPLF/rippled/pull/4781))
## XRP Ledger server version 1.12.0
[Version 1.12.0](https://github.com/XRPLF/rippled/releases/tag/1.12.0) was released on Sep 6, 2023. The following additions are non-breaking (because they are purely additive):
[Version 1.12.0](https://github.com/XRPLF/rippled/releases/tag/1.12.0) was released on Sep 6, 2023. The following additions are non-breaking (because they are purely additive).
- `server_info`: Added `ports`, an array which advertises the RPC and WebSocket ports. This information is also included in the `/crawl` endpoint (which calls `server_info` internally). `grpc` and `peer` ports are also included. ([#4427](https://github.com/XRPLF/rippled/pull/4427))
- `server_info`: Added `ports`, an array which advertises the RPC and WebSocket ports. This information is also included in the `/crawl` endpoint (which calls `server_info` internally). `grpc` and `peer` ports are also included. (https://github.com/XRPLF/rippled/pull/4427)
- `ports` contains objects, each containing a `port` for the listening port (a number string), and a `protocol` array listing the supported protocols on that port.
- This allows crawlers to build a more detailed topology without needing to port-scan nodes.
- (For peers and other non-admin clients, the info about admin ports is excluded.)
- Clawback: The following additions are gated by the Clawback amendment (`featureClawback`). ([#4553](https://github.com/XRPLF/rippled/pull/4553))
- Adds an [AccountRoot flag](https://xrpl.org/accountroot.html#accountroot-flags) called `lsfAllowTrustLineClawback`. ([#4617](https://github.com/XRPLF/rippled/pull/4617))
- Clawback: The following additions are gated by the Clawback amendment (`featureClawback`). (https://github.com/XRPLF/rippled/pull/4553)
- Adds an [AccountRoot flag](https://xrpl.org/accountroot.html#accountroot-flags) called `lsfAllowTrustLineClawback` (https://github.com/XRPLF/rippled/pull/4617)
- Adds the corresponding `asfAllowTrustLineClawback` [AccountSet Flag](https://xrpl.org/accountset.html#accountset-flags) as well.
- Clawback is disabled by default, so if an issuer desires the ability to claw back funds, they must use an `AccountSet` transaction to set the AllowTrustLineClawback flag. They must do this before creating any trust lines, offers, escrows, payment channels, or checks.
- Adds the [Clawback transaction type](https://github.com/XRPLF/XRPL-Standards/blob/master/XLS-39d-clawback/README.md#331-clawback-transaction), containing these fields:
@@ -218,16 +181,16 @@ This release contains bug fixes only and no API changes.
### Breaking changes in 1.11
- Added the ability to mark amendments as obsolete. For the `feature` admin API, there is a new possible value for the `vetoed` field. ([#4291](https://github.com/XRPLF/rippled/pull/4291))
- Added the ability to mark amendments as obsolete. For the `feature` admin API, there is a new possible value for the `vetoed` field. (https://github.com/XRPLF/rippled/pull/4291)
- The value of `vetoed` can now be `true`, `false`, or `"Obsolete"`.
- Removed the acceptance of seeds or public keys in place of account addresses. ([#4404](https://github.com/XRPLF/rippled/pull/4404))
- Removed the acceptance of seeds or public keys in place of account addresses. (https://github.com/XRPLF/rippled/pull/4404)
- This simplifies the API and encourages better security practices (i.e. seeds should never be sent over the network).
- For the `ledger_data` method, when all entries are filtered out, the `state` field of the response is now an empty list (in other words, an empty array, `[]`). (Previously, it would return `null`.) While this is technically a breaking change, the new behavior is consistent with the documentation, so this is considered only a bug fix. ([#4398](https://github.com/XRPLF/rippled/pull/4398))
- For the `ledger_data` method, when all entries are filtered out, the `state` field of the response is now an empty list (in other words, an empty array, `[]`). (Previously, it would return `null`.) While this is technically a breaking change, the new behavior is consistent with the documentation, so this is considered only a bug fix. (https://github.com/XRPLF/rippled/pull/4398)
- If and when the `fixNFTokenRemint` amendment activates, there will be a new AccountRoot field, `FirstNFTSequence`. This field is set to the current account sequence when the account issues their first NFT. If an account has not issued any NFTs, then the field is not set. ([#4406](https://github.com/XRPLF/rippled/pull/4406))
- There is a new account deletion restriction: an account can only be deleted if `FirstNFTSequence` + `MintedNFTokens` + `256` is less than the current ledger sequence.
- This is potentially a breaking change if clients have logic for determining whether an account can be deleted.
- NetworkID
- For sidechains and networks with a network ID greater than 1024, there is a new [transaction common field](https://xrpl.org/transaction-common-fields.html), `NetworkID`. ([#4370](https://github.com/XRPLF/rippled/pull/4370))
- For sidechains and networks with a network ID greater than 1024, there is a new [transaction common field](https://xrpl.org/transaction-common-fields.html), `NetworkID`. (https://github.com/XRPLF/rippled/pull/4370)
- This field helps to prevent replay attacks and is now required for chains whose network ID is 1025 or higher.
- The field must be omitted for Mainnet, so there is no change for Mainnet users.
- There are three new local error codes:
@@ -237,10 +200,10 @@ This release contains bug fixes only and no API changes.
### Additions and bug fixes in 1.11
- Added `nftoken_id`, `nftoken_ids` and `offer_id` meta fields into NFT `tx` and `account_tx` responses. ([#4447](https://github.com/XRPLF/rippled/pull/4447))
- Added an `account_flags` object to the `account_info` method response. ([#4459](https://github.com/XRPLF/rippled/pull/4459))
- Added `NFTokenPages` to the `account_objects` RPC. ([#4352](https://github.com/XRPLF/rippled/pull/4352))
- Fixed: `marker` returned from the `account_lines` command would not work on subsequent commands. ([#4361](https://github.com/XRPLF/rippled/pull/4361))
- Added `nftoken_id`, `nftoken_ids` and `offer_id` meta fields into NFT `tx` and `account_tx` responses. (https://github.com/XRPLF/rippled/pull/4447)
- Added an `account_flags` object to the `account_info` method response. (https://github.com/XRPLF/rippled/pull/4459)
- Added `NFTokenPages` to the `account_objects` RPC. (https://github.com/XRPLF/rippled/pull/4352)
- Fixed: `marker` returned from the `account_lines` command would not work on subsequent commands. (https://github.com/XRPLF/rippled/pull/4361)
## XRP Ledger server version 1.10.0

View File

@@ -1,66 +0,0 @@
# API Version 2
API version 2 is available in `xrpld` version 2.0.0 and later. To use this API, clients specify `"api_version" : 2` in each request.
For info about how [API versioning](https://xrpl.org/request-formatting.html#api-versioning) works, including examples, please view the [XLS-22d spec](https://github.com/XRPLF/XRPL-Standards/discussions/54). For details about the implementation of API versioning, view the [implementation PR](https://github.com/XRPLF/rippled/pull/3155). API versioning ensures existing integrations and users continue to receive existing behavior, while those that request a higher API version will experience new behavior.
## Removed methods
In API version 2, the following deprecated methods are no longer available: ([#4759](https://github.com/XRPLF/rippled/pull/4759))
- `tx_history` - Instead, use other methods such as `account_tx` or `ledger` with the `transactions` field set to `true`.
- `ledger_header` - Instead, use the `ledger` method.
## Modifications to JSON transaction element in API version 2
In API version 2, JSON elements for transaction output have been changed and made consistent for all methods which output transactions. ([#4775](https://github.com/XRPLF/rippled/pull/4775))
This helps to unify the JSON serialization format of transactions. ([clio#722](https://github.com/XRPLF/clio/issues/722), [#4727](https://github.com/XRPLF/rippled/issues/4727))
- JSON transaction element is named `tx_json`
- Binary transaction element is named `tx_blob`
- JSON transaction metadata element is named `meta`
- Binary transaction metadata element is named `meta_blob`
Additionally, these elements are now consistently available next to `tx_json` (i.e. sibling elements), where possible:
- `hash` - Transaction ID. This data was stored inside transaction output in API version 1, but in API version 2 is a sibling element.
- `ledger_index` - Ledger index (only set on validated ledgers)
- `ledger_hash` - Ledger hash (only set on closed or validated ledgers)
- `close_time_iso` - Ledger close time expressed in ISO 8601 time format (only set on validated ledgers)
- `validated` - Bool element set to `true` if the transaction is in a validated ledger, otherwise `false`
This change affects the following methods:
- `tx` - Transaction data moved into element `tx_json` (was inline inside `result`) or, if binary output was requested, moved from `tx` to `tx_blob`. Renamed binary transaction metadata element (if it was requested) from `meta` to `meta_blob`. Changed location of `hash` and added new elements
- `account_tx` - Renamed transaction element from `tx` to `tx_json`. Renamed binary transaction metadata element (if it was requested) from `meta` to `meta_blob`. Changed location of `hash` and added new elements
- `transaction_entry` - Renamed transaction metadata element from `metadata` to `meta`. Changed location of `hash` and added new elements
- `subscribe` - Renamed transaction element from `transaction` to `tx_json`. Changed location of `hash` and added new elements
- `sign`, `sign_for`, `submit` and `submit_multisigned` - Changed location of `hash` element.
## Modifications to `Payment` transaction JSON schema
When reading Payments, the `Amount` field should generally **not** be used. Instead, use [delivered_amount](https://xrpl.org/partial-payments.html#the-delivered_amount-field) to see the amount that the Payment delivered. To clarify its meaning, the `Amount` field is being renamed to `DeliverMax`. ([#4733](https://github.com/XRPLF/rippled/pull/4733))
- In `Payment` transaction type, JSON RPC field `Amount` is renamed to `DeliverMax`. To enable smooth client transition, `Amount` is still handled, as described below: ([#4733](https://github.com/XRPLF/rippled/pull/4733))
- On JSON RPC input (e.g. `submit_multisigned` etc. methods), `Amount` is recognized as an alias to `DeliverMax` for both API version 1 and version 2 clients.
- On JSON RPC input, submitting both `Amount` and `DeliverMax` fields is allowed _only_ if they are identical; otherwise such input is rejected with `rpcINVALID_PARAMS` error.
- On JSON RPC output (e.g. `subscribe`, `account_tx` etc. methods), `DeliverMax` is present in both API version 1 and version 2.
- On JSON RPC output, `Amount` is only present in API version 1 and _not_ in version 2.
## Modifications to account_info response
- `signer_lists` is returned in the root of the response. (In API version 1, it was nested under `account_data`.) ([#3770](https://github.com/XRPLF/rippled/pull/3770))
- When using an invalid `signer_lists` value, the API now returns an "invalidParams" error. ([#4585](https://github.com/XRPLF/rippled/pull/4585))
- (`signer_lists` must be a boolean. In API version 1, strings were accepted and may return a normal response - i.e. as if `signer_lists` were `true`.)
## Modifications to [account_tx](https://xrpl.org/account_tx.html#account_tx) response
- Using `ledger_index_min`, `ledger_index_max`, and `ledger_index` returns `invalidParams` because if you use `ledger_index_min` or `ledger_index_max`, then it does not make sense to also specify `ledger_index`. In API version 1, no error was returned. ([#4571](https://github.com/XRPLF/rippled/pull/4571))
- The same applies for `ledger_index_min`, `ledger_index_max`, and `ledger_hash`. ([#4545](https://github.com/XRPLF/rippled/issues/4545#issuecomment-1565065579))
- Using a `ledger_index_min` or `ledger_index_max` beyond the range of ledgers that the server has:
- returns `lgrIdxMalformed` in API version 2. Previously, in API version 1, no error was returned. ([#4288](https://github.com/XRPLF/rippled/issues/4288))
- Attempting to use a non-boolean value (such as a string) for the `binary` or `forward` parameters returns `invalidParams` (`rpcINVALID_PARAMS`). Previously, in API version 1, no error was returned. ([#4620](https://github.com/XRPLF/rippled/pull/4620))
## Modifications to [noripple_check](https://xrpl.org/noripple_check.html#noripple_check) response
- Attempting to use a non-boolean value (such as a string) for the `transactions` parameter returns `invalidParams` (`rpcINVALID_PARAMS`). Previously, in API version 1, no error was returned. ([#4620](https://github.com/XRPLF/rippled/pull/4620))

View File

@@ -1,27 +0,0 @@
# API Version 3
API version 3 is currently a **beta API**. It requires enabling `[beta_rpc_api]` in the xrpld configuration to use. To use this API, clients specify `"api_version" : 3` in each request.
For info about how [API versioning](https://xrpl.org/request-formatting.html#api-versioning) works, including examples, please view the [XLS-22d spec](https://github.com/XRPLF/XRPL-Standards/discussions/54). For details about the implementation of API versioning, view the [implementation PR](https://github.com/XRPLF/rippled/pull/3155). API versioning ensures existing integrations and users continue to receive existing behavior, while those that request a higher API version will experience new behavior.
## Breaking Changes
### Modifications to `amm_info`
The order of error checks has been changed to provide more specific error messages. ([#4924](https://github.com/XRPLF/rippled/pull/4924))
- **Before (API v2)**: When sending an invalid account or asset to `amm_info` while other parameters are not set as expected, the method returns a generic `rpcINVALID_PARAMS` error.
- **After (API v3)**: The same scenario returns a more specific error: `rpcISSUE_MALFORMED` for malformed assets or `rpcACT_MALFORMED` for malformed accounts.
### Modifications to `ledger_entry`
Added support for string shortcuts to look up fixed-location ledger entries using the `"index"` parameter. ([#5644](https://github.com/XRPLF/rippled/pull/5644))
In API version 3, the following string values can be used with the `"index"` parameter:
- `"index": "amendments"` - Returns the `Amendments` ledger entry
- `"index": "fee"` - Returns the `FeeSettings` ledger entry
- `"index": "nunl"` - Returns the `NegativeUNL` ledger entry
- `"index": "hashes"` - Returns the "short" `LedgerHashes` ledger entry (recent ledger hashes)
These shortcuts are only available in API version 3 and later. In API versions 1 and 2, these string values would result in an error.

567
BUILD.md
View File

@@ -1,131 +1,219 @@
| :warning: **WARNING** :warning: |
| ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- |
| These instructions assume you have a C++ development environment ready with Git, Python, Conan, CMake, and a C++ compiler. For help setting one up on Linux, macOS, or Windows, [see this guide](./docs/build/environment.md).<br><br>These instructions also assume a basic familiarity with Conan and CMake. If you are unfamiliar with Conan, you can read our [crash course](./docs/build/conan.md) or the official [Getting Started][conan-getting-started] walkthrough. |
| :warning: **WARNING** :warning:
|---|
| These instructions assume you have a C++ development environment ready with Git, Python, Conan, CMake, and a C++ compiler. For help setting one up on Linux, macOS, or Windows, [see this guide](./docs/build/environment.md). |
> These instructions also assume a basic familiarity with Conan and CMake.
> If you are unfamiliar with Conan,
> you can read our [crash course](./docs/build/conan.md)
> or the official [Getting Started][3] walkthrough.
## Branches
For a stable release, choose the `master` branch or one of the [tagged
releases](https://github.com/ripple/rippled/releases).
```
git checkout master
```
For the latest release candidate, choose the `release` branch.
```
git checkout release
```
For the latest set of untested features, or to contribute, choose the `develop`
branch.
```
git checkout develop
```
## Minimum Requirements
See [System Requirements](https://xrpl.org/system-requirements.html).
Building xrpld generally requires Git, Python, Conan, CMake, and a C++
compiler.
Building rippled generally requires git, Python, Conan, CMake, and a C++ compiler. Some guidance on setting up such a [C++ development environment can be found here](./docs/build/environment.md).
- [Python](https://www.python.org/downloads/)
- [Conan](https://conan.io/downloads.html)
- [CMake](https://cmake.org/download/)
- [Python 3.7](https://www.python.org/downloads/)
- [Conan 1.60](https://conan.io/downloads.html)[^1]
- [CMake 3.16](https://cmake.org/download/)
You can verify that the required tools are installed and runnable with:
[^1]: It is possible to build with Conan 2.x,
but the instructions are significantly different,
which is why we are not recommending it yet.
Notably, the `conan profile update` command is removed in 2.x.
Profiles must be edited by hand.
```bash
./bin/check-tools.sh
```
`rippled` is written in the C++20 dialect and includes the `<concepts>` header.
The [minimum compiler versions][2] required are:
`xrpld` is written in the C++23 dialect. The [tested compiler versions][cpp23-support] are:
| Compiler | Version |
| ----------- | --------------- |
| GCC | 15.2 |
| Clang | 22 |
| Apple Clang | 21 |
| MSVC | 19.44[^windows] |
## Operating Systems
Please see the [environment setup guide](./docs/build/environment.md) for detailed instructions for all platforms.
| Compiler | Version |
|-------------|---------|
| GCC | 11 |
| Clang | 13 |
| Apple Clang | 13.1.6 |
| MSVC | 19.23 |
### Linux
The Ubuntu Linux distribution has received the highest level of quality
assurance, testing, and support. We also support Red Hat and use Debian
internally.
Our Linux CI tooling is distro-independent and uses a Nix-based environment, so it should be possible to build on other Linux distributions as well, although we have not tested them.
The Ubuntu operating system has received the highest level of
quality assurance, testing, and support.
### macOS
Here are [sample instructions for setting up a C++ development environment on Linux](./docs/build/environment.md#linux).
Many `xrpld` engineers use macOS for development.
### Mac
Many rippled engineers use macOS for development.
Here are [sample instructions for setting up a C++ development environment on macOS](./docs/build/environment.md#macos).
### Windows
Windows is used by some engineers for development only.
Windows is not recommended for production use at this time.
[^windows]: Windows is not recommended for production use.
- Additionally, 32-bit Windows development is not supported.
[Boost]: https://www.boost.org/
## Steps
### Branches
For the latest set of untested features, or to contribute, choose the `develop`
branch.
```bash
git checkout develop
```
For a release candidate, choose the relevant release branch, e.g.
`release/3.2.x`.
```bash
git checkout release/3.2.x
```
For a stable release, choose one of the [tagged
releases](https://github.com/XRPLF/rippled/releases).
### Set Up Conan
After you have a [C++ development environment](./docs/build/environment.md) ready with Git, Python,
Conan, CMake, and a C++ compiler, you may need to set up your Conan profile.
After you have a [C++ development environment](./docs/build/environment.md) ready with Git, Python, Conan, CMake, and a C++ compiler, you may need to set up your Conan profile.
These instructions assume a basic familiarity with Conan and CMake. If you are
unfamiliar with Conan, then please read [this crash course](./docs/build/conan.md) or the official
[Getting Started][conan-getting-started] walkthrough.
These instructions assume a basic familiarity with Conan and CMake.
#### Profiles
If you are unfamiliar with Conan, then please read [this crash course](./docs/build/conan.md) or the official [Getting Started][3] walkthrough.
We recommend that you install our Conan profiles:
You'll need at least one Conan profile:
```bash
conan config install conan/profiles/ -tf $(conan config home)/profiles/
```
```
conan profile new default --detect
```
You can check your Conan profile by running:
Update the compiler settings:
```bash
conan profile show
```
```
conan profile update settings.compiler.cppstd=20 default
```
If the default profile is not suitable for your environment, you can create a custom profile and pass it to Conan.
More information on customizing Conan can be found in the [Advanced Conan configuration](./docs/build/advanced_conan.md).
Configure Conan (1.x only) to use recipe revisions:
#### Add xrplf remote
```
conan config set general.revisions_enabled=1
```
Run the following command to add the `xrplf` remote, which hosts some of our dependencies:
**Linux** developers will commonly have a default Conan [profile][] that compiles
with GCC and links with libstdc++.
If you are linking with libstdc++ (see profile setting `compiler.libcxx`),
then you will need to choose the `libstdc++11` ABI:
```bash
conan remote add --index 0 --force xrplf https://conan.xrplf.org/repository/conan/
```
```
conan profile update settings.compiler.libcxx=libstdc++11 default
```
### Set Up Ccache
To speed up repeated compilations, we recommend that you install
[ccache](https://ccache.dev), a tool that wraps your compiler so that it can
cache build objects locally.
On Linux and macOS, `ccache` is included in the [Nix development shell](./docs/build/nix.md).
#### Windows
You can install it using Chocolatey, i.e. `choco install ccache`. If you already
have Ccache installed, then `choco upgrade ccache` will update it to the latest
version. However, if you see an error such as:
Ensure inter-operability between `boost::string_view` and `std::string_view` types:
```
terminate called after throwing an instance of 'std::bad_alloc'
what(): std::bad_alloc
C:\Program Files\Microsoft Visual Studio\2022\Community\MSBuild\Microsoft\VC\v170\Microsoft.CppCommon.targets(617,5): error MSB6006: "cl.exe" exited with code 3.
conan profile update 'conf.tools.build:cxxflags+=["-DBOOST_BEAST_USE_STD_STRING_VIEW"]' default
conan profile update 'env.CXXFLAGS="-DBOOST_BEAST_USE_STD_STRING_VIEW"' default
```
then please install a specific version of Ccache that we know works, via: `choco
install ccache --version 4.11.3 --allow-downgrade`.
If you have other flags in the `conf.tools.build` or `env.CXXFLAGS` sections, make sure to retain the existing flags and append the new ones. You can check them with:
```
conan profile show default
```
**Windows** developers may need to use the x64 native build tools.
An easy way to do that is to run the shortcut "x64 Native Tools Command
Prompt" for the version of Visual Studio that you have installed.
Windows developers must also build `rippled` and its dependencies for the x64
architecture:
```
conan profile update settings.arch=x86_64 default
```
### Multiple compilers
When `/usr/bin/g++` exists on a platform, it is the default cpp compiler. This
default works for some users.
However, if this compiler cannot build rippled or its dependencies, then you can
install another compiler and set Conan and CMake to use it.
Update the `conf.tools.build:compiler_executables` setting in order to set the correct variables (`CMAKE_<LANG>_COMPILER`) in the
generated CMake toolchain file.
For example, on Ubuntu 20, you may have gcc at `/usr/bin/gcc` and g++ at `/usr/bin/g++`; if that is the case, you can select those compilers with:
```
conan profile update 'conf.tools.build:compiler_executables={"c": "/usr/bin/gcc", "cpp": "/usr/bin/g++"}' default
```
Replace `/usr/bin/gcc` and `/usr/bin/g++` with paths to the desired compilers.
It should choose the compiler for dependencies as well,
but not all of them have a Conan recipe that respects this setting (yet).
For the rest, you can set these environment variables.
Replace `<path>` with paths to the desired compilers:
- `conan profile update env.CC=<path> default`
- `conan profile update env.CXX=<path> default`
Export our [Conan recipe for Snappy](./external/snappy).
It does not explicitly link the C++ standard library,
which allows you to statically link it with GCC, if you want.
```
# Conan 1.x
conan export external/snappy snappy/1.1.10@
# Conan 2.x
conan export --version 1.1.10 external/snappy
```
Export our [Conan recipe for RocksDB](./external/rocksdb).
It does not override paths to dependencies when building with Visual Studio.
```
# Conan 1.x
conan export external/rocksdb rocksdb/9.7.3@
# Conan 2.x
conan export --version 9.7.3 external/rocksdb
```
Export our [Conan recipe for SOCI](./external/soci).
It patches their CMake to correctly import its dependencies.
```
# Conan 1.x
conan export external/soci soci/4.0.3@
# Conan 2.x
conan export --version 4.0.3 external/soci
```
Export our [Conan recipe for NuDB](./external/nudb).
It fixes some source files to add missing `#include`s.
```
# Conan 1.x
conan export external/nudb nudb/2.0.8@
# Conan 2.x
conan export --version 2.0.8 external/nudb
```
Export our [Conan recipe for WAMR](./external/wamr).
It add metering and expose some internal structures.
```
# Conan 1.x
conan export external/wamr wamr/2.2.0@
# Conan 2.x
conan export --version 2.2.0 external/wamr
```
### Build and Test
@@ -147,105 +235,98 @@ install ccache --version 4.11.3 --allow-downgrade`.
2. Use conan to generate CMake files for every configuration you want to build:
```
conan install .. --output-folder . --build missing --settings build_type=Release
conan install .. --output-folder . --build missing --settings build_type=Debug
```
```
conan install .. --output-folder . --build missing --settings build_type=Release
conan install .. --output-folder . --build missing --settings build_type=Debug
```
To build Debug, in the next step, be sure to set `-DCMAKE_BUILD_TYPE=Debug`
To build Debug, in the next step, be sure to set `-DCMAKE_BUILD_TYPE=Debug`
For a single-configuration generator, e.g. `Unix Makefiles` or `Ninja`,
you only need to run this command once.
For a multi-configuration generator, e.g. `Visual Studio`, you may want to
run it more than once.
For a single-configuration generator, e.g. `Unix Makefiles` or `Ninja`,
you only need to run this command once.
For a multi-configuration generator, e.g. `Visual Studio`, you may want to
run it more than once.
Each of these commands should also have a different `build_type` setting.
A second command with the same `build_type` setting will overwrite the files
generated by the first. You can pass the build type on the command line with
`--settings build_type=$BUILD_TYPE` or in the profile itself,
under the section `[settings]` with the key `build_type`.
Each of these commands should also have a different `build_type` setting.
A second command with the same `build_type` setting will overwrite the files
generated by the first. You can pass the build type on the command line with
`--settings build_type=$BUILD_TYPE` or in the profile itself,
under the section `[settings]` with the key `build_type`.
If you are using a Microsoft Visual C++ compiler,
then you will need to ensure consistency between the `build_type` setting
and the `compiler.runtime` setting.
When `build_type` is `Release`, `compiler.runtime` should be `MT`.
When `build_type` is `Debug`, `compiler.runtime` should be `MTd`.
```
conan install .. --output-folder . --build missing --settings build_type=Release --settings compiler.runtime=MT
conan install .. --output-folder . --build missing --settings build_type=Debug --settings compiler.runtime=MTd
```
3. Configure CMake and pass the toolchain file generated by Conan, located at
`$OUTPUT_FOLDER/build/generators/conan_toolchain.cmake`.
Single-config generators:
Single-config generators:
Pass the CMake variable [`CMAKE_BUILD_TYPE`][build_type]
and make sure it matches the one of the `build_type` settings
you chose in the previous step.
Pass the CMake variable [`CMAKE_BUILD_TYPE`][build_type]
and make sure it matches the one of the `build_type` settings
you chose in the previous step.
For example, to build Debug, in the next command, replace "Release" with "Debug"
For example, to build Debug, in the next command, replace "Release" with "Debug"
```
cmake -DCMAKE_TOOLCHAIN_FILE:FILEPATH=build/generators/conan_toolchain.cmake -DCMAKE_BUILD_TYPE=Release -Dxrpld=ON -Dtests=ON ..
```
```
cmake -DCMAKE_TOOLCHAIN_FILE:FILEPATH=build/generators/conan_toolchain.cmake -DCMAKE_BUILD_TYPE=Release -Dxrpld=ON -Dtests=ON ..
```
Multi-config generators:
```
cmake -DCMAKE_TOOLCHAIN_FILE:FILEPATH=build/generators/conan_toolchain.cmake -Dxrpld=ON -Dtests=ON ..
```
Multi-config generators:
**Note:** You can pass build options for `xrpld` in this step.
```
cmake -DCMAKE_TOOLCHAIN_FILE:FILEPATH=build/generators/conan_toolchain.cmake -Dxrpld=ON -Dtests=ON ..
```
4. Build `xrpld`.
**Note:** You can pass build options for `rippled` in this step.
5. Build `rippled`.
For a single-configuration generator, it will build whatever configuration
you passed for `CMAKE_BUILD_TYPE`. For a multi-configuration generator, you
must pass the option `--config` to select the build configuration.
you passed for `CMAKE_BUILD_TYPE`. For a multi-configuration generator,
you must pass the option `--config` to select the build configuration.
Single-config generators:
```
cmake --build . --parallel N
cmake --build . -j $(nproc)
```
Multi-config generators:
```
cmake --build . --config Release --parallel N
cmake --build . --config Debug --parallel N
cmake --build . --config Release
cmake --build . --config Debug
```
Replace the `--parallel` parameter N with the desired number of parallel jobs. A common starting point is half of the number of available CPU
cores.
5. Test xrpld.
6. Test rippled.
Single-config generators:
```
./xrpld --unittest --unittest-jobs N
./rippled --unittest
```
Multi-config generators:
```
./Release/xrpld --unittest --unittest-jobs N
./Debug/xrpld --unittest --unittest-jobs N
./Release/rippled --unittest
./Debug/rippled --unittest
```
Replace the `--unittest-jobs` parameter N with the desired unit tests
concurrency. Recommended setting is half of the number of available CPU
cores.
The location of `rippled` in your build directory depends on your CMake
generator. Pass `--help` to see the rest of the command line options.
The location of `xrpld` binary in your build directory depends on your
CMake generator. Pass `--help` to see the rest of the command line options.
## Code generation
The protocol wrapper classes in `include/xrpl/protocol_autogen/` are generated
from macro definition files in `include/xrpl/protocol/detail/`. If you modify
the macro files (e.g. `transactions.macro`, `ledger_entries.macro`) or the
generation scripts/templates in `cmake/scripts/codegen/`, you need to regenerate the
files:
```
cmake --build . --target setup_code_gen # create venv and install dependencies (once)
cmake --build . --target code_gen # regenerate code
```
The regenerated files should be committed alongside your changes.
## Coverage report
@@ -263,20 +344,20 @@ Prerequisites for the coverage report:
A coverage report is created when the following steps are completed, in order:
1. `xrpld` binary built with instrumentation data, enabled by the `coverage`
1. `rippled` binary built with instrumentation data, enabled by the `coverage`
option mentioned above
2. completed one or more run of the unit tests, which populates coverage capture data
2. completed run of unit tests, which populates coverage capture data
3. completed run of the `gcovr` tool (which internally invokes either `gcov` or `llvm-cov`)
to assemble both instrumentation data and the coverage capture data into a coverage report
The last step of the above is automated into a single target `coverage`. The instrumented
`xrpld` binary can also be used for regular development or testing work, at
The above steps are automated into a single target `coverage`. The instrumented
`rippled` binary can also be used for regular development or testing work, at
the cost of extra disk space utilization and a small performance hit
(to store coverage capture data). Since `xrpld` binary is simply a dependency of the
coverage report target, it is possible to re-run the `coverage` target without
rebuilding the `xrpld` binary. Note, running of the unit tests before the `coverage`
target is left to the developer. Each such run will append to the coverage data
collected in the build directory.
(to store coverage capture). In case of a spurious failure of unit tests, it is
possible to re-run the `coverage` target without rebuilding the `rippled` binary
(since it is simply a dependency of the coverage report target). It is also possible
to select only specific tests for the purpose of the coverage report, by setting
the `coverage_test` variable in `cmake`
The default coverage report format is `html-details`, but the user
can override it to any of the formats listed in `Builds/CMake/CodeCoverage.cmake`
@@ -285,6 +366,11 @@ to generate more than one format at a time by setting the `coverage_extra_args`
variable in `cmake`. The specific command line used to run the `gcovr` tool will be
displayed if the `CODE_COVERAGE_VERBOSE` variable is set.
By default, the code coverage tool runs parallel unit tests with `--unittest-jobs`
set to the number of available CPU cores. This may cause spurious test
errors on Apple. Developers can override the number of unit test jobs with
the `coverage_test_parallelism` variable in `cmake`.
Example use with some cmake variables set:
```
@@ -297,99 +383,48 @@ cmake --build . --target coverage
After the `coverage` target is completed, the generated coverage report will be
stored inside the build directory, as either of:
- file named `coverage.`_extension_, with a suitable extension for the report format, or
- file named `coverage.`_extension_ , with a suitable extension for the report format, or
- directory named `coverage`, with the `index.html` and other files inside, for the `html-details` or `html-nested` report formats.
## Sanitizers
To build dependencies and xrpld with sanitizer instrumentation, set the
`SANITIZERS` environment variable when running `conan install` and use the `sanitizers` profile:
```bash
export SANITIZERS=address,undefinedbehavior
conan install .. --output-folder . --profile:all sanitizers --build missing --settings build_type=Debug
```
You can then build and test as usual, with the generated `xrpld` binary containing the sanitizer instrumentation. When you run it, it will report any sanitizer errors it detects in the console output.
See [Sanitizers docs](./docs/build/sanitizers.md) for more details.
## Options
| Option | Default Value | Description |
| ---------------- | ------------- | ----------------------------------------------------------------------------- |
| `assert` | OFF | Force enabling assertions. |
| `coverage` | OFF | Prepare the coverage report. |
| `tests` | OFF | Build tests. |
| `unity` | OFF | Configure a unity build. |
| `verify_headers` | ON | Make the `verify-headers` target available to compile each header on its own. |
| `xrpld` | OFF | Build the xrpld application, and not just the libxrpl library. |
| `werr` | OFF | Treat compilation warnings as errors |
| `wextra` | OFF | Enable additional compilation warnings |
| Option | Default Value | Description |
| --- | ---| ---|
| `assert` | OFF | Enable assertions.
| `coverage` | OFF | Prepare the coverage report. |
| `san` | N/A | Enable a sanitizer with Clang. Choices are `thread` and `address`. |
| `tests` | OFF | Build tests. |
| `unity` | ON | Configure a unity build. |
| `xrpld` | OFF | Build the xrpld (`rippled`) application, and not just the libxrpl library. |
[Unity builds][unity-build] may be faster for the first build (at the cost of much more
memory) since they concatenate sources into fewer translation units. Non-unity
builds may be faster for incremental builds, and can be helpful for detecting
`#include` omissions.
[Unity builds][5] may be faster for the first build
(at the cost of much more memory) since they concatenate sources into fewer
translation units. Non-unity builds may be faster for incremental builds,
and can be helpful for detecting `#include` omissions.
### Verifying headers
The regular build only compiles `.cpp` files, so a header is only ever checked
through whatever translation unit happens to include it. A header that forgets
an `#include` is not caught as long as every `.cpp` that uses it includes its
missing dependency first. The `verify_headers` option (ON by default) adds a
`verify-headers` target that compiles every header on its own, which fails if a
header is not self-contained:
```bash
cmake --build . --target verify-headers
```
The per-header objects are excluded from the `all` target, so a normal build
never compiles them; they are built only through `verify-headers`. The generated
translation units do appear in `compile_commands.json`, so clang-tidy (and
clangd and IDEs) can lint each header on its own. Pass `-Dverify_headers=OFF` to
omit them entirely.
## Troubleshooting
### Conan
After any updates or changes to dependencies, you may need to do the following:
1. Remove your build directory.
2. Remove individual libraries from the Conan cache, e.g.
```bash
conan remove 'grpc/*'
2. Remove the Conan cache:
```
**or**
Remove all libraries from Conan cache:
```bash
conan remove '*'
rm -rf ~/.conan/data
```
4. Re-run [conan install](#build-and-test).
3. Re-run [conan export](./docs/build/advanced_conan.md#patched-recipes) if needed.
4. [Regenerate lockfile](./docs/build/advanced_conan.md#conan-lockfile).
5. Re-run [conan install](#build-and-test).
#### ERROR: Package not resolved
### 'protobuf/port_def.inc' file not found
If you're seeing an error like `ERROR: Package 'snappy/1.1.10' not resolved: Unable to find 'snappy/1.1.10#968fef506ff261592ec30c574d4a7809%1756234314.246' in remotes.`,
please [add `xrplf` remote](#add-xrplf-remote) or re-run `conan export` for [patched recipes](./docs/build/advanced_conan.md#patched-recipes).
### `protobuf/port_def.inc` file not found
If `cmake --build .` results in an error due to a missing a protobuf file, then
you might have generated CMake files for a different `build_type` than the
`CMAKE_BUILD_TYPE` you passed to Conan.
If `cmake --build .` results in an error due to a missing a protobuf file, then you might have generated CMake files for a different `build_type` than the `CMAKE_BUILD_TYPE` you passed to conan.
```
/xrpld/.build/pb-xrpl.libpb/xrpl/proto/xrpl.pb.h:10:10: fatal error: 'google/protobuf/port_def.inc' file not found
/rippled/.build/pb-xrpl.libpb/xrpl/proto/ripple.pb.h:10:10: fatal error: 'google/protobuf/port_def.inc' file not found
10 | #include <google/protobuf/port_def.inc>
| ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
1 error generated.
@@ -400,9 +435,77 @@ For example, if you want to build Debug:
1. For conan install, pass `--settings build_type=Debug`
2. For cmake, pass `-DCMAKE_BUILD_TYPE=Debug`
[cpp23-support]: https://en.cppreference.com/w/cpp/compiler_support/23
[conan-getting-started]: https://docs.conan.io/en/latest/getting_started.html
[unity-build]: https://en.wikipedia.org/wiki/Unity_build
### no std::result_of
If your compiler version is recent enough to have removed `std::result_of` as
part of C++20, e.g. Apple Clang 15.0, then you might need to add a preprocessor
definition to your build.
```
conan profile update 'options.boost:extra_b2_flags="define=BOOST_ASIO_HAS_STD_INVOKE_RESULT"' default
conan profile update 'env.CFLAGS="-DBOOST_ASIO_HAS_STD_INVOKE_RESULT"' default
conan profile update 'env.CXXFLAGS="-DBOOST_ASIO_HAS_STD_INVOKE_RESULT"' default
conan profile update 'conf.tools.build:cflags+=["-DBOOST_ASIO_HAS_STD_INVOKE_RESULT"]' default
conan profile update 'conf.tools.build:cxxflags+=["-DBOOST_ASIO_HAS_STD_INVOKE_RESULT"]' default
```
### call to 'async_teardown' is ambiguous
If you are compiling with an early version of Clang 16, then you might hit
a [regression][6] when compiling C++20 that manifests as an [error in a Boost
header][7]. You can workaround it by adding this preprocessor definition:
```
conan profile update 'env.CXXFLAGS="-DBOOST_ASIO_DISABLE_CONCEPTS"' default
conan profile update 'conf.tools.build:cxxflags+=["-DBOOST_ASIO_DISABLE_CONCEPTS"]' default
```
### recompile with -fPIC
If you get a linker error suggesting that you recompile Boost with
position-independent code, such as:
```
/usr/bin/ld.gold: error: /home/username/.conan/data/boost/1.77.0/_/_/package/.../lib/libboost_container.a(alloc_lib.o):
requires unsupported dynamic reloc 11; recompile with -fPIC
```
Conan most likely downloaded a bad binary distribution of the dependency.
This seems to be a [bug][1] in Conan just for Boost 1.77.0 compiled with GCC
for Linux. The solution is to build the dependency locally by passing
`--build boost` when calling `conan install`.
```
conan install --build boost ...
```
## Add a Dependency
If you want to experiment with a new package, follow these steps:
1. Search for the package on [Conan Center](https://conan.io/center/).
2. Modify [`conanfile.py`](./conanfile.py):
- Add a version of the package to the `requires` property.
- Change any default options for the package by adding them to the
`default_options` property (with syntax `'$package:$option': $value`).
3. Modify [`CMakeLists.txt`](./CMakeLists.txt):
- Add a call to `find_package($package REQUIRED)`.
- Link a library from the package to the target `ripple_libs`
(search for the existing call to `target_link_libraries(ripple_libs INTERFACE ...)`).
4. Start coding! Don't forget to include whatever headers you need from the package.
[1]: https://github.com/conan-io/conan-center-index/issues/13168
[2]: https://en.cppreference.com/w/cpp/compiler_support/20
[3]: https://docs.conan.io/en/latest/getting_started.html
[5]: https://en.wikipedia.org/wiki/Unity_build
[6]: https://github.com/boostorg/beast/issues/2648
[7]: https://github.com/boostorg/beast/issues/2661
[gcovr]: https://gcovr.com/en/stable/getting-started.html
[python-pip]: https://packaging.python.org/en/latest/guides/installing-using-pip-and-virtual-environments/
[build_type]: https://cmake.org/cmake/help/latest/variable/CMAKE_BUILD_TYPE.html
[profile]: https://docs.conan.io/en/latest/reference/profiles.html

View File

@@ -0,0 +1,114 @@
# Levelization
Levelization is the term used to describe efforts to prevent rippled from
having or creating cyclic dependencies.
rippled code is organized into directories under `src/rippled` (and
`src/test`) representing modules. The modules are intended to be
organized into "tiers" or "levels" such that a module from one level can
only include code from lower levels. Additionally, a module
in one level should never include code in an `impl` folder of any level
other than it's own.
Unfortunately, over time, enforcement of levelization has been
inconsistent, so the current state of the code doesn't necessarily
reflect these rules. Whenever possible, developers should refactor any
levelization violations they find (by moving files or individual
classes). At the very least, don't make things worse.
The table below summarizes the _desired_ division of modules, based on the
state of the rippled code when it was created. The levels are numbered from
the bottom up with the lower level, lower numbered, more independent
modules listed first, and the higher level, higher numbered modules with
more dependencies listed later.
**tl;dr:** The modules listed first are more independent than the modules
listed later.
| Level / Tier | Module(s) |
|--------------|-----------------------------------------------|
| 01 | ripple/beast ripple/unity
| 02 | ripple/basics
| 03 | ripple/json ripple/crypto
| 04 | ripple/protocol
| 05 | ripple/core ripple/conditions ripple/consensus ripple/resource ripple/server
| 06 | ripple/peerfinder ripple/ledger ripple/nodestore ripple/net
| 07 | ripple/shamap ripple/overlay
| 08 | ripple/app
| 09 | ripple/rpc
| 10 | ripple/perflog
| 11 | test/jtx test/beast test/csf
| 12 | test/unit_test
| 13 | test/crypto test/conditions test/json test/resource test/shamap test/peerfinder test/basics test/overlay
| 14 | test
| 15 | test/net test/protocol test/ledger test/consensus test/core test/server test/nodestore
| 16 | test/rpc test/app
(Note that `test` levelization is *much* less important and *much* less
strictly enforced than `ripple` levelization, other than the requirement
that `test` code should *never* be included in `ripple` code.)
## Validation
The [levelization.sh](levelization.sh) script takes no parameters,
reads no environment variables, and can be run from any directory,
as long as it is in the expected location in the rippled repo.
It can be run at any time from within a checked out repo, and will
do an analysis of all the `#include`s in
the rippled source. The only caveat is that it runs much slower
under Windows than in Linux. It hasn't yet been tested under MacOS.
It generates many files of [results](results):
* `rawincludes.txt`: The raw dump of the `#includes`
* `paths.txt`: A second dump grouping the source module
to the destination module, deduped, and with frequency counts.
* `includes/`: A directory where each file represents a module and
contains a list of modules and counts that the module _includes_.
* `includedby/`: Similar to `includes/`, but the other way around. Each
file represents a module and contains a list of modules and counts
that _include_ the module.
* [`loops.txt`](results/loops.txt): A list of direct loops detected
between modules as they actually exist, as opposed to how they are
desired as described above. In a perfect repo, this file will be
empty.
This file is committed to the repo, and is used by the [levelization
Github workflow](../../.github/workflows/levelization.yml) to validate
that nothing changed.
* [`ordering.txt`](results/ordering.txt): A list showing relationships
between modules where there are no loops as they actually exist, as
opposed to how they are desired as described above.
This file is committed to the repo, and is used by the [levelization
Github workflow](../../.github/workflows/levelization.yml) to validate
that nothing changed.
* [`levelization.yml`](../../.github/workflows/levelization.yml)
Github Actions workflow to test that levelization loops haven't
changed. Unfortunately, if changes are detected, it can't tell if
they are improvements or not, so if you have resolved any issues or
done anything else to improve levelization, run `levelization.sh`,
and commit the updated results.
The `loops.txt` and `ordering.txt` files relate the modules
using comparison signs, which indicate the number of times each
module is included in the other.
* `A > B` means that A should probably be at a higher level than B,
because B is included in A significantly more than A is included in B.
These results can be included in both `loops.txt` and `ordering.txt`.
Because `ordering.txt`only includes relationships where B is not
included in A at all, it will only include these types of results.
* `A ~= B` means that A and B are included in each other a different
number of times, but the values are so close that the script can't
definitively say that one should be above the other. These results
will only be included in `loops.txt`.
* `A == B` means that A and B include each other the same number of
times, so the script has no clue which should be higher. These results
will only be included in `loops.txt`.
The committed files hide the detailed values intentionally, to
prevent false alarms and merging issues, and because it's easy to
get those details locally.
1. Run `levelization.sh`
2. Grep the modules in `paths.txt`.
* For example, if a cycle is found `A ~= B`, simply `grep -w
A Builds/levelization/results/paths.txt | grep -w B`

View File

@@ -0,0 +1,130 @@
#!/bin/bash
# Usage: levelization.sh
# This script takes no parameters, reads no environment variables,
# and can be run from any directory, as long as it is in the expected
# location in the repo.
pushd $( dirname $0 )
if [ -v PS1 ]
then
# if the shell is interactive, clean up any flotsam before analyzing
git clean -ix
fi
# Ensure all sorting is ASCII-order consistently across platforms.
export LANG=C
rm -rfv results
mkdir results
includes="$( pwd )/results/rawincludes.txt"
pushd ../..
echo Raw includes:
grep -r '^[ ]*#include.*/.*\.h' include src | \
grep -v boost | tee ${includes}
popd
pushd results
oldifs=${IFS}
IFS=:
mkdir includes
mkdir includedby
echo Build levelization paths
exec 3< ${includes} # open rawincludes.txt for input
while read -r -u 3 file include
do
level=$( echo ${file} | cut -d/ -f 2,3 )
# If the "level" indicates a file, cut off the filename
if [[ "${level##*.}" != "${level}" ]]
then
# Use the "toplevel" label as a workaround for `sort`
# inconsistencies between different utility versions
level="$( dirname ${level} )/toplevel"
fi
level=$( echo ${level} | tr '/' '.' )
includelevel=$( echo ${include} | sed 's/.*["<]//; s/[">].*//' | \
cut -d/ -f 1,2 )
if [[ "${includelevel##*.}" != "${includelevel}" ]]
then
# Use the "toplevel" label as a workaround for `sort`
# inconsistencies between different utility versions
includelevel="$( dirname ${includelevel} )/toplevel"
fi
includelevel=$( echo ${includelevel} | tr '/' '.' )
if [[ "$level" != "$includelevel" ]]
then
echo $level $includelevel | tee -a paths.txt
fi
done
echo Sort and dedup paths
sort -ds paths.txt | uniq -c | tee sortedpaths.txt
mv sortedpaths.txt paths.txt
exec 3>&- #close fd 3
IFS=${oldifs}
unset oldifs
echo Split into flat-file database
exec 4<paths.txt # open paths.txt for input
while read -r -u 4 count level include
do
echo ${include} ${count} | tee -a includes/${level}
echo ${level} ${count} | tee -a includedby/${include}
done
exec 4>&- #close fd 4
loops="$( pwd )/loops.txt"
ordering="$( pwd )/ordering.txt"
pushd includes
echo Search for loops
# Redirect stdout to a file
exec 4>&1
exec 1>"${loops}"
for source in *
do
if [[ -f "$source" ]]
then
exec 5<"${source}" # open for input
while read -r -u 5 include includefreq
do
if [[ -f $include ]]
then
if grep -q -w $source $include
then
if grep -q -w "Loop: $include $source" "${loops}"
then
continue
fi
sourcefreq=$( grep -w $source $include | cut -d\ -f2 )
echo "Loop: $source $include"
# If the counts are close, indicate that the two modules are
# on the same level, though they shouldn't be
if [[ $(( $includefreq - $sourcefreq )) -gt 3 ]]
then
echo -e " $source > $include\n"
elif [[ $(( $sourcefreq - $includefreq )) -gt 3 ]]
then
echo -e " $include > $source\n"
elif [[ $sourcefreq -eq $includefreq ]]
then
echo -e " $include == $source\n"
else
echo -e " $include ~= $source\n"
fi
else
echo "$source > $include" >> "${ordering}"
fi
fi
done
exec 5>&- #close fd 5
fi
done
exec 1>&4 #close fd 1
exec 4>&- #close fd 4
cat "${ordering}"
cat "${loops}"
popd
popd
popd

View File

@@ -0,0 +1,42 @@
Loop: test.jtx test.toplevel
test.toplevel > test.jtx
Loop: test.jtx test.unit_test
test.unit_test == test.jtx
Loop: xrpld.app xrpld.core
xrpld.app > xrpld.core
Loop: xrpld.app xrpld.ledger
xrpld.app > xrpld.ledger
Loop: xrpld.app xrpld.net
xrpld.app > xrpld.net
Loop: xrpld.app xrpld.overlay
xrpld.overlay > xrpld.app
Loop: xrpld.app xrpld.peerfinder
xrpld.peerfinder ~= xrpld.app
Loop: xrpld.app xrpld.rpc
xrpld.rpc > xrpld.app
Loop: xrpld.app xrpld.shamap
xrpld.app > xrpld.shamap
Loop: xrpld.core xrpld.net
xrpld.net > xrpld.core
Loop: xrpld.core xrpld.perflog
xrpld.perflog == xrpld.core
Loop: xrpld.net xrpld.rpc
xrpld.rpc ~= xrpld.net
Loop: xrpld.overlay xrpld.rpc
xrpld.rpc ~= xrpld.overlay
Loop: xrpld.perflog xrpld.rpc
xrpld.rpc ~= xrpld.perflog

View File

@@ -0,0 +1,196 @@
libxrpl.basics > xrpl.basics
libxrpl.crypto > xrpl.basics
libxrpl.json > xrpl.basics
libxrpl.json > xrpl.json
libxrpl.protocol > xrpl.basics
libxrpl.protocol > xrpl.json
libxrpl.protocol > xrpl.protocol
libxrpl.resource > xrpl.basics
libxrpl.resource > xrpl.json
libxrpl.resource > xrpl.resource
libxrpl.server > xrpl.basics
libxrpl.server > xrpl.json
libxrpl.server > xrpl.protocol
libxrpl.server > xrpl.server
test.app > test.jtx
test.app > test.rpc
test.app > test.toplevel
test.app > test.unit_test
test.app > xrpl.basics
test.app > xrpld.app
test.app > xrpld.core
test.app > xrpld.ledger
test.app > xrpld.nodestore
test.app > xrpld.overlay
test.app > xrpld.rpc
test.app > xrpl.json
test.app > xrpl.protocol
test.app > xrpl.resource
test.basics > test.jtx
test.basics > test.unit_test
test.basics > xrpl.basics
test.basics > xrpld.perflog
test.basics > xrpld.rpc
test.basics > xrpl.json
test.basics > xrpl.protocol
test.beast > xrpl.basics
test.conditions > xrpl.basics
test.conditions > xrpld.conditions
test.consensus > test.csf
test.consensus > test.toplevel
test.consensus > test.unit_test
test.consensus > xrpl.basics
test.consensus > xrpld.app
test.consensus > xrpld.consensus
test.consensus > xrpld.ledger
test.consensus > xrpl.json
test.core > test.jtx
test.core > test.toplevel
test.core > test.unit_test
test.core > xrpl.basics
test.core > xrpld.core
test.core > xrpld.perflog
test.core > xrpl.json
test.core > xrpl.server
test.csf > xrpl.basics
test.csf > xrpld.consensus
test.csf > xrpl.json
test.csf > xrpl.protocol
test.json > test.jtx
test.json > xrpl.json
test.jtx > xrpl.basics
test.jtx > xrpld.app
test.jtx > xrpld.core
test.jtx > xrpld.ledger
test.jtx > xrpld.net
test.jtx > xrpld.rpc
test.jtx > xrpl.json
test.jtx > xrpl.protocol
test.jtx > xrpl.resource
test.jtx > xrpl.server
test.ledger > test.jtx
test.ledger > test.toplevel
test.ledger > xrpl.basics
test.ledger > xrpld.app
test.ledger > xrpld.core
test.ledger > xrpld.ledger
test.ledger > xrpl.protocol
test.nodestore > test.jtx
test.nodestore > test.toplevel
test.nodestore > test.unit_test
test.nodestore > xrpl.basics
test.nodestore > xrpld.core
test.nodestore > xrpld.nodestore
test.nodestore > xrpld.unity
test.overlay > test.jtx
test.overlay > test.toplevel
test.overlay > test.unit_test
test.overlay > xrpl.basics
test.overlay > xrpld.app
test.overlay > xrpld.overlay
test.overlay > xrpld.peerfinder
test.overlay > xrpld.shamap
test.overlay > xrpl.protocol
test.peerfinder > test.beast
test.peerfinder > test.unit_test
test.peerfinder > xrpl.basics
test.peerfinder > xrpld.core
test.peerfinder > xrpld.peerfinder
test.peerfinder > xrpl.protocol
test.protocol > test.toplevel
test.protocol > xrpl.basics
test.protocol > xrpl.json
test.protocol > xrpl.protocol
test.resource > test.unit_test
test.resource > xrpl.basics
test.resource > xrpl.resource
test.rpc > test.jtx
test.rpc > test.toplevel
test.rpc > xrpl.basics
test.rpc > xrpld.app
test.rpc > xrpld.core
test.rpc > xrpld.net
test.rpc > xrpld.overlay
test.rpc > xrpld.rpc
test.rpc > xrpl.json
test.rpc > xrpl.protocol
test.rpc > xrpl.resource
test.server > test.jtx
test.server > test.toplevel
test.server > test.unit_test
test.server > xrpl.basics
test.server > xrpld.app
test.server > xrpld.core
test.server > xrpld.rpc
test.server > xrpl.json
test.server > xrpl.server
test.shamap > test.unit_test
test.shamap > xrpl.basics
test.shamap > xrpld.nodestore
test.shamap > xrpld.shamap
test.shamap > xrpl.protocol
test.toplevel > test.csf
test.toplevel > xrpl.json
test.unit_test > xrpl.basics
xrpl.json > xrpl.basics
xrpl.protocol > xrpl.basics
xrpl.protocol > xrpl.json
xrpl.resource > xrpl.basics
xrpl.resource > xrpl.json
xrpl.resource > xrpl.protocol
xrpl.server > xrpl.basics
xrpl.server > xrpl.json
xrpl.server > xrpl.protocol
xrpld.app > test.unit_test
xrpld.app > xrpl.basics
xrpld.app > xrpld.conditions
xrpld.app > xrpld.consensus
xrpld.app > xrpld.nodestore
xrpld.app > xrpld.perflog
xrpld.app > xrpl.json
xrpld.app > xrpl.protocol
xrpld.app > xrpl.resource
xrpld.conditions > xrpl.basics
xrpld.conditions > xrpl.protocol
xrpld.consensus > xrpl.basics
xrpld.consensus > xrpl.json
xrpld.consensus > xrpl.protocol
xrpld.core > xrpl.basics
xrpld.core > xrpl.json
xrpld.core > xrpl.protocol
xrpld.ledger > xrpl.basics
xrpld.ledger > xrpl.json
xrpld.ledger > xrpl.protocol
xrpld.net > xrpl.basics
xrpld.net > xrpl.json
xrpld.net > xrpl.protocol
xrpld.net > xrpl.resource
xrpld.nodestore > xrpl.basics
xrpld.nodestore > xrpld.core
xrpld.nodestore > xrpld.unity
xrpld.nodestore > xrpl.json
xrpld.nodestore > xrpl.protocol
xrpld.overlay > xrpl.basics
xrpld.overlay > xrpld.core
xrpld.overlay > xrpld.peerfinder
xrpld.overlay > xrpld.perflog
xrpld.overlay > xrpl.json
xrpld.overlay > xrpl.protocol
xrpld.overlay > xrpl.resource
xrpld.overlay > xrpl.server
xrpld.peerfinder > xrpl.basics
xrpld.peerfinder > xrpld.core
xrpld.peerfinder > xrpl.protocol
xrpld.perflog > xrpl.basics
xrpld.perflog > xrpl.json
xrpld.rpc > xrpl.basics
xrpld.rpc > xrpld.core
xrpld.rpc > xrpld.ledger
xrpld.rpc > xrpld.nodestore
xrpld.rpc > xrpl.json
xrpld.rpc > xrpl.protocol
xrpld.rpc > xrpl.resource
xrpld.rpc > xrpl.server
xrpld.shamap > xrpl.basics
xrpld.shamap > xrpld.nodestore
xrpld.shamap > xrpl.protocol

View File

@@ -1,159 +1,147 @@
cmake_minimum_required(VERSION 3.16)
if(POLICY CMP0074)
cmake_policy(SET CMP0074 NEW)
cmake_policy(SET CMP0074 NEW)
endif()
if(POLICY CMP0077)
cmake_policy(SET CMP0077 NEW)
cmake_policy(SET CMP0077 NEW)
endif()
# Fix "unrecognized escape" issues when passing CMAKE_MODULE_PATH on Windows.
if(DEFINED CMAKE_MODULE_PATH)
file(TO_CMAKE_PATH "${CMAKE_MODULE_PATH}" CMAKE_MODULE_PATH)
endif()
file(TO_CMAKE_PATH "${CMAKE_MODULE_PATH}" CMAKE_MODULE_PATH)
list(APPEND CMAKE_MODULE_PATH "${CMAKE_CURRENT_SOURCE_DIR}/cmake")
project(xrpl)
set(CMAKE_CXX_EXTENSIONS OFF)
set(CMAKE_CXX_STANDARD 23)
set(CMAKE_CXX_STANDARD 20)
set(CMAKE_CXX_STANDARD_REQUIRED ON)
set(CMAKE_EXPORT_COMPILE_COMMANDS ON)
include(CompilationEnv)
if(is_gcc)
if(CMAKE_CXX_COMPILER_ID MATCHES "GNU")
# GCC-specific fixes
add_compile_options(-Wno-unknown-pragmas -Wno-subobject-linkage)
# -Wno-subobject-linkage can be removed when we upgrade GCC version to at least 13.3
elseif(is_clang)
elseif(CMAKE_CXX_COMPILER_ID MATCHES "Clang")
# Clang-specific fixes
add_compile_options(-Wno-unknown-warning-option) # Ignore unknown warning options
elseif(is_msvc)
elseif(MSVC)
# MSVC-specific fixes
add_compile_options(/wd4068) # Ignore unknown pragmas
endif()
# Enable ccache to speed up builds.
include(Ccache)
# make GIT_COMMIT_HASH define available to all sources
find_package(Git)
if(Git_FOUND)
execute_process(COMMAND ${GIT_EXECUTABLE} --git-dir=${CMAKE_CURRENT_SOURCE_DIR}/.git rev-parse HEAD
OUTPUT_STRIP_TRAILING_WHITESPACE OUTPUT_VARIABLE gch)
if(gch)
set(GIT_COMMIT_HASH "${gch}")
message(STATUS gch: ${GIT_COMMIT_HASH})
add_definitions(-DGIT_COMMIT_HASH="${GIT_COMMIT_HASH}")
endif()
execute_process(COMMAND ${GIT_EXECUTABLE} --git-dir=${CMAKE_CURRENT_SOURCE_DIR}/.git rev-parse --abbrev-ref HEAD
OUTPUT_STRIP_TRAILING_WHITESPACE OUTPUT_VARIABLE gb)
if(gb)
set(GIT_BRANCH "${gb}")
message(STATUS gb: ${GIT_BRANCH})
add_definitions(-DGIT_BRANCH="${GIT_BRANCH}")
endif()
endif() #git
if(thread_safety_analysis)
add_compile_options(
-Wthread-safety
-D_LIBCPP_ENABLE_THREAD_SAFETY_ANNOTATIONS
-DXRPL_ENABLE_THREAD_SAFETY_ANNOTATIONS
)
add_compile_options("-stdlib=libc++")
add_link_options("-stdlib=libc++")
add_compile_options(-Wthread-safety -D_LIBCPP_ENABLE_THREAD_SAFETY_ANNOTATIONS -DRIPPLE_ENABLE_THREAD_SAFETY_ANNOTATIONS)
add_compile_options("-stdlib=libc++")
add_link_options("-stdlib=libc++")
endif()
include(CheckCXXCompilerFlag)
include(FetchContent)
include(ExternalProject)
include(CMakeFuncs) # must come *after* ExternalProject b/c it overrides one function in EP
if(target)
message(
FATAL_ERROR
"The target option has been removed - use native cmake options to control build"
)
endif()
include (CheckCXXCompilerFlag)
include (FetchContent)
include (ExternalProject)
include (CMakeFuncs) # must come *after* ExternalProject b/c it overrides one function in EP
if (target)
message (FATAL_ERROR "The target option has been removed - use native cmake options to control build")
endif ()
include(PatchNixBinary)
include(XrplSanity)
include(XrplVersion)
include(XrplSettings)
# this check has to remain in the top-level cmake because of the early return statement
if(packages_only)
if(NOT TARGET rpm)
message(
FATAL_ERROR
"packages_only requested, but targets were not created - is docker installed?"
)
endif()
return()
endif()
include(XrplCompiler)
include(XrplSanitizers)
include(XrplInterface)
include(RippledSanity)
include(RippledVersion)
include(RippledSettings)
# this check has to remain in the top-level cmake
# because of the early return statement
if (packages_only)
if (NOT TARGET rpm)
message (FATAL_ERROR "packages_only requested, but targets were not created - is docker installed?")
endif()
return ()
endif ()
include(RippledCompiler)
include(RippledInterface)
option(only_docs "Include only the docs target?" FALSE)
include(XrplDocs)
include(RippledDocs)
if(only_docs)
return()
return()
endif()
include(deps/Boost)
###
include(deps/Boost)
find_package(OpenSSL 1.1.1 REQUIRED)
set_target_properties(OpenSSL::SSL PROPERTIES
INTERFACE_COMPILE_DEFINITIONS OPENSSL_NO_SSL2
)
set(SECP256K1_INSTALL TRUE)
add_subdirectory(external/secp256k1)
add_library(secp256k1::secp256k1 ALIAS secp256k1)
add_subdirectory(external/ed25519-donna)
add_subdirectory(external/antithesis-sdk)
find_package(date REQUIRED)
find_package(ed25519 REQUIRED)
find_package(gRPC REQUIRED)
find_package(LibArchive REQUIRED)
find_package(lz4 REQUIRED)
find_package(mpt-crypto REQUIRED)
find_package(nudb REQUIRED)
find_package(OpenSSL REQUIRED)
find_package(secp256k1 REQUIRED)
# Target names with :: are not allowed in a generator expression.
# We need to pull the include directories and imported location properties
# from separate targets.
find_package(LibArchive REQUIRED)
find_package(SOCI REQUIRED)
find_package(SQLite3 REQUIRED)
find_package(xxHash REQUIRED)
target_link_libraries(
xrpl_libs
INTERFACE
ed25519::ed25519
lz4::lz4
mpt-crypto::mpt-crypto
OpenSSL::Crypto
OpenSSL::SSL
secp256k1::secp256k1
soci::soci
SQLite::SQLite3
)
option(rocksdb "Enable RocksDB" ON)
if(rocksdb)
find_package(RocksDB REQUIRED)
set_target_properties(
RocksDB::rocksdb
PROPERTIES INTERFACE_COMPILE_DEFINITIONS XRPL_ROCKSDB_AVAILABLE=1
)
target_link_libraries(xrpl_libs INTERFACE RocksDB::rocksdb)
find_package(RocksDB REQUIRED)
set_target_properties(RocksDB::rocksdb PROPERTIES
INTERFACE_COMPILE_DEFINITIONS RIPPLE_ROCKSDB_AVAILABLE=1
)
target_link_libraries(ripple_libs INTERFACE RocksDB::rocksdb)
endif()
# OpenTelemetry distributed tracing (optional).
# When ON, links against opentelemetry-cpp and defines XRPL_ENABLE_TELEMETRY
# so that SpanGuard factory methods produce real OTel spans.
# When OFF (default), all tracing code compiles to no-ops with zero overhead.
# Enable via: conan install -o telemetry=True, or cmake -Dtelemetry=ON.
option(telemetry "Enable OpenTelemetry tracing" ON)
if(telemetry)
find_package(opentelemetry-cpp CONFIG REQUIRED)
add_compile_definitions(XRPL_ENABLE_TELEMETRY)
message(STATUS "OpenTelemetry tracing enabled")
endif()
find_package(nudb REQUIRED)
find_package(date REQUIRED)
find_package(xxHash REQUIRED)
find_package(wamr REQUIRED)
target_link_libraries(ripple_libs INTERFACE
ed25519::ed25519
lz4::lz4
OpenSSL::Crypto
OpenSSL::SSL
secp256k1::secp256k1
soci::soci
SQLite::SQLite3
)
# Work around changes to Conan recipe for now.
if(TARGET nudb::core)
set(nudb nudb::core)
set(nudb nudb::core)
elseif(TARGET NuDB::nudb)
set(nudb NuDB::nudb)
set(nudb NuDB::nudb)
else()
message(FATAL_ERROR "unknown nudb target")
message(FATAL_ERROR "unknown nudb target")
endif()
target_link_libraries(xrpl_libs INTERFACE ${nudb})
target_link_libraries(ripple_libs INTERFACE ${nudb})
if(coverage)
include(XrplCov)
include(RippledCov)
endif()
include(XrplCore)
include(XrplProtocolAutogen)
include(XrplInstall)
include(XrplPackaging)
include(XrplValidatorKeys)
if(tests)
include(CTest)
add_subdirectory(src/tests/libxrpl)
endif()
set(PROJECT_EXPORT_SET RippleExports)
include(RippledCore)
include(RippledInstall)
include(RippledValidatorKeys)

File diff suppressed because it is too large Load Diff

View File

@@ -1,7 +1,7 @@
ISC License
ISC License
Copyright (c) 2011, Arthur Britto, David Schwartz, Jed McCaleb, Vinnie Falco, Bob Way, Eric Lombrozo, Nikolaos D. Bougalis, Howard Hinnant.
Copyright (c) 2012-present, the XRP Ledger developers.
Copyright (c) 2012-2020, the XRP Ledger developers.
Permission to use, copy, modify, and distribute this software for any
purpose with or without fee is hereby granted, provided that the above
@@ -14,3 +14,4 @@ ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.

View File

@@ -1,565 +0,0 @@
# Distributed Tracing Fundamentals
> **Parent Document**: [OpenTelemetryPlan.md](./OpenTelemetryPlan.md)
> **Next**: [Architecture Analysis](./01-architecture-analysis.md)
---
## What is Distributed Tracing?
Distributed tracing is a method for tracking data objects as they flow through distributed systems. In a network like XRP Ledger, a single transaction touches multiple independent nodes—each with no shared memory or logging. Distributed tracing connects these dots.
**Without tracing:** You see isolated logs on each node with no way to correlate them.
**With tracing:** You see the complete journey of a transaction or an event across all nodes it touched.
---
## Actors and Actions at a Glance
### Actors
| Who (Plain English) | Technical Term |
| ---------------------------------------------- | --------------- |
| A single unit of work being tracked | Span |
| The complete journey of a request | Trace |
| Data that links spans across services | Trace Context |
| Code that creates spans and propagates context | Instrumentation |
| Service that receives and processes traces | Collector |
| Storage and visualization system | Backend (Tempo) |
| Decision logic for which traces to keep | Sampler |
### Actions
| What Happens (Plain English) | Technical Term |
| --------------------------------------- | ----------------------- |
| Start tracking a new operation | Create a Span |
| Connect a child operation to its parent | Set `parent_span_id` |
| Group all related operations together | Share a `trace_id` |
| Pass tracking data between services | Context Propagation |
| Decide whether to record a trace | Sampling (Head or Tail) |
| Send completed traces to storage | Export (OTLP) |
---
## Core Concepts
### 1. Trace
A **trace** represents the entire journey of a request through the system. It has a unique `trace_id` that stays constant across all nodes.
```
Trace ID: abc123
├── Node A: received transaction
├── Node B: relayed transaction
├── Node C: included in consensus
└── Node D: applied to ledger
```
### 2. Span
A **span** represents a single unit of work within a trace. Each span has:
| Attribute | Description | Example |
| ---------------- | -------------------------------- | -------------------------- |
| `trace_id` | Identifies the trace | `event123` |
| `span_id` | Unique identifier | `span456` |
| `parent_span_id` | Parent span (if any) | `p_span123` |
| `name` | Operation name | `rpc.submit` |
| `start_time` | When work began (local time) | `2024-01-15T10:30:00Z` |
| `end_time` | When work completed (local time) | `2024-01-15T10:30:00.050Z` |
| `attributes` | Key-value metadata | `tx_hash=ABC...` |
| `status` | OK, ERROR MSG | `OK` |
### 3. Trace Context
**Trace context** is the data that propagates between services to link spans together. It contains:
- `trace_id` - The trace this span belongs to
- `span_id` - The current span (becomes parent for child spans)
- `trace_flags` - Sampling decisions
---
## How Spans Form a Trace
Spans have parent-child relationships forming a tree structure:
```mermaid
flowchart TB
subgraph trace["Trace: abc123"]
A["tx.submit<br/>span_id: 001<br/>50ms"] --> B["tx.validate<br/>span_id: 002<br/>5ms"]
A --> C["tx.relay<br/>span_id: 003<br/>10ms"]
A --> D["tx.apply<br/>span_id: 004<br/>30ms"]
D --> E["ledger.update<br/>span_id: 005<br/>20ms"]
end
style A fill:#0d47a1,stroke:#082f6a,color:#ffffff
style B fill:#1b5e20,stroke:#0d3d14,color:#ffffff
style C fill:#1b5e20,stroke:#0d3d14,color:#ffffff
style D fill:#1b5e20,stroke:#0d3d14,color:#ffffff
style E fill:#bf360c,stroke:#8c2809,color:#ffffff
```
**Reading the diagram:**
- **tx.submit (blue, root)**: The top-level span representing the entire transaction submission; all other spans are its descendants.
- **tx.validate, tx.relay, tx.apply (green)**: Direct children of tx.submit, representing the three main stages -- validation, relay to peers, and application to the ledger.
- **ledger.update (red)**: A grandchild span nested under tx.apply, representing the actual ledger state mutation triggered by applying the transaction.
- **Arrows (parent to child)**: Each arrow indicates a parent-child span relationship where the parent's completion depends on the child finishing.
The same trace visualized as a **timeline (Gantt chart)**:
```
Time → 0ms 10ms 20ms 30ms 40ms 50ms
├───────────────────────────────────────────┤
tx.submit│▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓│
├─────┤
tx.valid │▓▓▓▓▓│
│ ├──────────┤
tx.relay │ │▓▓▓▓▓▓▓▓▓▓│
│ ├────────────────────────────┤
tx.apply │ │▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓│
│ ├──────────────────┤
ledger │ │▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓▓│
```
---
## Span Relationships
Spans don't always form simple parent-child trees. Distributed tracing defines several relationship types to capture different causal patterns:
### 1. Parent-Child (ChildOf)
The default relationship. The parent span **depends on** or **contains** the child span. The child runs within the scope of the parent.
```
tx.submit (parent)
├── tx.validate (child) ← parent waits for this
├── tx.relay (child) ← parent waits for this
└── tx.apply (child) ← parent waits for this
```
**When to use:** Synchronous calls, nested operations, any case where the parent's completion depends on the child.
### 2. Follows-From
A causal relationship where the first span **triggers** the second, but does **not wait** for it. The originator fires and moves on.
```
Time →
tx.receive [=======]
↓ triggers (follows-from)
tx.relay [===========] ← runs independently
```
**When to use:** Asynchronous jobs, queued work, fire-and-forget patterns. For example, a node receives a transaction and queues it for relay — the relay span _follows from_ the receive span but the receiver doesn't wait for relaying to complete.
> **OpenTracing** defined `FollowsFrom` as a first-class reference type alongside `ChildOf`.
> **OpenTelemetry** represents this using **Span Links** with descriptive attributes instead (see below).
### 3. Span Links (Cross-Trace and Non-Hierarchical)
Links connect spans that are **causally related but not in a parent-child hierarchy**. Unlike parent-child, links can cross trace boundaries.
```
Trace A Trace B
────── ──────
batch.schedule batch.execute
├─ item.enqueue (span X) ┌──► process.item
├─ item.enqueue (span Y) ───┤ (links to X, Y, Z)
├─ item.enqueue (span Z) └──►
```
**Use cases:**
| Pattern | Description |
| -------------------- | --------------------------------------------------------------------------- |
| **Batch processing** | A batch span links back to all individual spans that contributed to it |
| **Fan-in** | An aggregation span links to the multiple producer spans it merges |
| **Fan-out** | Multiple downstream spans link back to the single span that triggered them |
| **Async handoff** | A deferred job links back to the request that queued it (follows-from) |
| **Cross-trace** | Correlating spans across independent traces (e.g., retries, related events) |
**Link structure:** Each link carries the target span's context plus optional attributes:
```
Link {
trace_id: <target trace>
span_id: <target span>
attributes: { "link.description": "triggered by batch scheduler" }
}
```
### Relationship Summary
```mermaid
flowchart LR
subgraph parent_child["Parent-Child"]
direction TB
P["Parent"] --> C["Child"]
end
subgraph follows_from["Follows-From"]
direction TB
A["Span A"] -.->|triggers| B["Span B"]
end
subgraph links["Span Links"]
direction TB
X["Span X\n(Trace 1)"] -.-|link| Y["Span Y\n(Trace 2)"]
end
parent_child ~~~ follows_from ~~~ links
style P fill:#0d47a1,stroke:#082f6a,color:#ffffff
style C fill:#1b5e20,stroke:#0d3d14,color:#ffffff
style A fill:#0d47a1,stroke:#082f6a,color:#ffffff
style B fill:#bf360c,stroke:#8c2809,color:#ffffff
style X fill:#4a148c,stroke:#38006b,color:#ffffff
style Y fill:#4a148c,stroke:#38006b,color:#ffffff
```
| Relationship | Same Trace? | Dependency? | OTel Mechanism |
| ---------------- | ----------- | -------------------------- | ----------------- |
| **Parent-Child** | Yes | Parent depends on child | `parent_span_id` |
| **Follows-From** | Usually | Causal but no dependency | Link + attributes |
| **Span Link** | Either | Correlation, no dependency | Link + attributes |
---
## Trace ID Generation
A `trace_id` is a 128-bit (16-byte) identifier that groups all spans belonging to one logical operation. How it's generated determines how easily you can find and correlate traces later.
### General Approaches
#### 1. Random (W3C Default)
Generate a random 128-bit ID when a trace starts. Standard approach for most services.
```
trace_id = random_128_bits()
```
| Pros | Cons |
| --------------------------- | --------------------------------------------- |
| Simple, standard | No natural correlation to domain events |
| Guaranteed unique per trace | If propagation is lost, trace is broken |
| Works with all OTel tooling | "Find trace for TX abc" requires index lookup |
#### 2. Deterministic (Derived from Domain Data)
Compute the trace_id from a hash of a natural identifier. Every node independently derives the **same** trace_id for the same event.
```
trace_id = SHA-256(domain_identifier)[0:16] // truncate to 128 bits
```
| Pros | Cons |
| --------------------------------------------------- | ---------------------------------------------------------- |
| Propagation-resilient — same ID computed everywhere | Same event processed twice (retry) shares trace_id |
| Natural search — domain ID maps directly to trace | Non-standard (tooling assumes random) |
| No coordination needed between nodes | 256→128 bit truncation (collision risk negligible at ~2⁶⁴) |
#### 3. Hybrid (Deterministic Prefix + Random Suffix)
First 8 bytes derived from domain data, last 8 bytes random.
```
trace_id = SHA-256(domain_identifier)[0:8] || random_64_bits()
```
| Pros | Cons |
| ------------------------------------------- | ---------------------------------------- |
| Prefix search: "find all traces for TX abc" | Must propagate to maintain full trace_id |
| Unique per processing instance | More complex generation logic |
| Retries get distinct trace_ids | Partial correlation only (prefix match) |
### XRPL Workflow Analysis
XRPL has a unique advantage: its core workflows produce **globally unique 256-bit hashes** that are known on every node. This makes deterministic trace_id generation practical in ways most systems can't achieve.
#### Natural Identifiers by Workflow
| Workflow | Natural Identifier | Size | Known at Start? | Same on All Nodes? |
| ------------------- | --------------------------------- | ---------- | ----------------------------- | -------------------------------- |
| **Transaction** | Transaction hash (`tid_`) | 256-bit | Yes — computed before signing | Yes — hash of canonical tx data |
| **Consensus round** | Previous ledger hash + ledger seq | 256+32 bit | Yes — known when round opens | Yes — all validators agree |
| **Validation** | Ledger hash being validated | 256-bit | Yes — from consensus result | Yes — same closed ledger |
| **Ledger catch-up** | Target ledger hash | 256-bit | Yes — we know what to fetch | Yes — identifies ledger globally |
#### Where These Identifiers Live in Code
```
Transaction: STTx::getTransactionID() → uint256 tid_
TMTransaction::rawTransaction → recompute hash from bytes
Consensus: ConsensusProposal::prevLedger_ → uint256 (previous ledger hash)
ConsensusProposal::position_ → uint256 (TxSet hash)
LedgerHeader::seq → uint32_t (ledger sequence)
Validation: STValidation::getLedgerHash() → uint256
STValidation::getNodeID() → NodeID (160-bit)
Ledger fetch: InboundLedger constructor → uint256 hash, uint32_t seq
TMGetLedger::ledgerHash → bytes (uint256)
```
### Recommended Strategy: Workflow-Scoped Deterministic
Each workflow type derives its trace_id from its natural domain identifier:
```
Transaction trace: trace_id = SHA-256("tx" || tx_hash)[0:16]
Consensus trace: trace_id = SHA-256("cons" || prev_ledger_hash || ledger_seq)[0:16]
Ledger catch-up: trace_id = SHA-256("fetch" || target_ledger_hash)[0:16]
```
The string prefix (`"tx"`, `"cons"`, `"fetch"`) prevents collisions between workflows that might share underlying hashes.
**Why this works for XRPL:**
1. **Propagation-resilient** — Even if a P2P message drops trace context, every node independently computes the same trace_id from the same tx_hash or ledger_hash. Spans still correlate.
2. **Zero-cost search** — "Show me the trace for transaction ABC" becomes a direct lookup: compute `SHA-256("tx" || ABC)[0:16]` and query. No secondary index needed.
3. **Cross-workflow linking via Span Links** — A consensus trace links to individual transaction traces. A validation span links to the consensus trace. This connects the full picture without forcing everything into one giant trace.
### Cross-Workflow Correlation
Each workflow gets its own trace. Span Links tie them together:
```mermaid
flowchart TB
subgraph tx_trace["Transaction Trace"]
direction LR
Tn["trace_id = f(tx_hash)"]:::note --> T1["tx.receive"] --> T2["tx.validate"] --> T3["tx.relay"]
end
subgraph cons_trace["Consensus Trace"]
direction LR
Cn["trace_id = f(prev_ledger, seq)"]:::note --> C1["cons.open"] --> C2["cons.propose"] --> C3["cons.accept"]
end
subgraph val_trace["Validation"]
direction LR
Vn["spans within consensus trace"]:::note --> V1["val.create"] --> V2["val.broadcast"]
end
subgraph fetch_trace["Catch-Up Trace"]
direction LR
Fn["trace_id = f(ledger_hash)"]:::note --> F1["fetch.request"] --> F2["fetch.receive"] --> F3["fetch.apply"]
end
C1 -.-|"span link\n(tx traces)"| T3
C3 --> V1
F1 -.-|"span link\n(target ledger)"| C3
classDef note fill:none,stroke:#888,stroke-dasharray:5 5,color:#333,font-style:italic
style T1 fill:#0d47a1,stroke:#082f6a,color:#ffffff
style T2 fill:#0d47a1,stroke:#082f6a,color:#ffffff
style T3 fill:#0d47a1,stroke:#082f6a,color:#ffffff
style C1 fill:#1b5e20,stroke:#0d3d14,color:#ffffff
style C2 fill:#1b5e20,stroke:#0d3d14,color:#ffffff
style C3 fill:#1b5e20,stroke:#0d3d14,color:#ffffff
style V1 fill:#bf360c,stroke:#8c2809,color:#ffffff
style V2 fill:#bf360c,stroke:#8c2809,color:#ffffff
style F1 fill:#4a148c,stroke:#38006b,color:#ffffff
style F2 fill:#4a148c,stroke:#38006b,color:#ffffff
style F3 fill:#4a148c,stroke:#38006b,color:#ffffff
```
**Reading the diagram:**
- **Transaction Trace (blue)**: An independent trace whose `trace_id` is deterministically derived from the transaction hash. Contains receive, validate, and relay spans.
- **Consensus Trace (green)**: An independent trace whose `trace_id` is derived from the previous ledger hash and sequence number. Covers the open, propose, and accept phases.
- **Validation (red)**: Validation spans live within the consensus trace (not a separate trace). They are created after the accept phase completes.
- **Catch-Up Trace (purple)**: An independent trace for ledger acquisition, derived from the target ledger hash. Used when a node is behind and fetching missing ledgers.
- **Dotted arrows (span links)**: Cross-trace correlations. Consensus links to transaction traces it included; catch-up links to the consensus trace that produced the target ledger.
- **Solid arrow (C3 to V1)**: A parent-child relationship -- validation spans are direct children of the consensus accept span within the same trace.
**How a query flows:**
```
"Why was TX abc slow?"
1. Compute trace_id = SHA-256("tx" || abc)[0:16]
2. Find transaction trace → see it was included in consensus round N
3. Follow span link → consensus trace for round N
4. See which phase was slow (propose? accept?)
5. If a node was catching up, follow link → catch-up trace
```
### Trade-offs to Consider
| Concern | Mitigation |
| ----------------------------- | ----------------------------------------------------------------------------------------------------------------------------- |
| **Retries get same trace_id** | Add `attempt` attribute to root span; spans have unique span_ids and timestamps |
| **256→128 bit truncation** | Birthday-bound collision at ~2⁶⁴ operations — negligible for XRPL's throughput |
| **Non-standard generation** | OTel spec allows any 16-byte non-zero value; tooling works on the hex string |
| **Hash computation cost** | SHA-256 is ~0.3μs per call; XRPL already computes these hashes for other purposes |
| **Late-binding identifiers** | Ledger hash isn't known until after consensus — validation spans use ledger_seq as fallback, then link to the consensus trace |
---
## Distributed Traces Across Nodes
In distributed systems like xrpld, traces span **multiple independent nodes**. The trace context must be propagated in network messages:
```mermaid
sequenceDiagram
participant Client
participant NodeA as Node A
participant NodeB as Node B
participant NodeC as Node C
Client->>NodeA: Submit TX<br/>(no trace context)
Note over NodeA: Creates new trace<br/>trace_id: abc123<br/>span: tx.receive
NodeA->>NodeB: Relay TX<br/>(trace_id: abc123, parent: 001)
Note over NodeB: Creates child span<br/>span: tx.relay<br/>parent_span_id: 001
NodeA->>NodeC: Relay TX<br/>(trace_id: abc123, parent: 001)
Note over NodeC: Creates child span<br/>span: tx.relay<br/>parent_span_id: 001
Note over NodeA,NodeC: All spans share trace_id: abc123<br/>enabling correlation across nodes
```
**Reading the diagram:**
- **Client**: The external entity that submits a transaction. It does not carry trace context -- the trace originates at the first node.
- **Node A**: The entry point that creates a new trace (trace_id: abc123) and the root span `tx.receive`. It relays the transaction to peers with trace context attached.
- **Node B and Node C**: Peer nodes that receive the relayed transaction along with the propagated trace context. Each creates a child span under Node A's span, preserving the same `trace_id`.
- **Arrows with trace context**: The relay messages carry `trace_id` and `parent_span_id`, allowing each downstream node to link its spans back to the originating span on Node A.
---
## Context Propagation
For traces to work across nodes, **trace context must be propagated** in messages.
### What's in the Context (~26 bytes)
| Field | Size | Description |
| ------------- | -------- | ------------------------------------------------------- |
| `trace_id` | 16 bytes | Identifies the entire trace (constant across all nodes) |
| `span_id` | 8 bytes | The sender's current span (becomes parent on receiver) |
| `trace_flags` | 1 byte | Sampling decision (bit 0 = sampled; bits 1-7 reserved) |
| `trace_state` | variable | Optional vendor-specific data (typically omitted) |
### How span_id Changes at Each Hop
Only **one** `span_id` travels in the context - the sender's current span. Each node:
1. Extracts the received `span_id` and uses it as the `parent_span_id`
2. Creates a **new** `span_id` for its own span
3. Sends its own `span_id` as the parent when forwarding
```
Node A Node B Node C
────── ────── ──────
Span AAA Span BBB Span CCC
│ │ │
▼ ▼ ▼
Context out: Context out: Context out:
├─ trace_id: abc123 ├─ trace_id: abc123 ├─ trace_id: abc123
├─ span_id: AAA ──────────► ├─ span_id: BBB ──────────► ├─ span_id: CCC ──────►
└─ flags: 01 └─ flags: 01 └─ flags: 01
│ │
parent = AAA parent = BBB
```
The `trace_id` stays constant, but `span_id` **changes at every hop** to maintain the parent-child chain.
### Propagation Formats
There are two patterns:
### HTTP/RPC Headers (W3C Trace Context)
```
traceparent: 00-4bf92f3577b34da6a3ce929d0e0e4736-00f067aa0ba902b7-01
│ │ │ │
│ │ │ └── Flags (sampled)
│ │ └── Parent span ID (16 hex)
│ └── Trace ID (32 hex)
└── Version
```
### Protocol Buffers (xrpld P2P messages)
xrpld P2P messages such as `TMTransaction` carry the trace context in two added byte fields alongside the existing payload: `trace_parent` holds the W3C traceparent (`trace_id`, `span_id`, and `trace_flags`), and `trace_state` holds the optional W3C tracestate. Together they propagate the trace across the P2P boundary so a receiving node can attach its spans to the sender's span.
---
## Sampling
Not every trace needs to be recorded. **Sampling** reduces overhead:
### Head Sampling (at trace start)
```
Request arrives → Random N% chance → Record or skip entire trace
```
- ✅ Low overhead
- ❌ May miss interesting traces
> **xrpld note**: xrpld intentionally fixes head sampling at 100% (sample
> everything) and does not expose a configurable ratio. A per-node ratio
> would let different nodes make divergent keep/drop decisions for the same
> distributed trace, producing broken/partial traces. xrpld uses a
> `ParentBased` sampler so spans with a remote parent honor the upstream
> decision. Volume reduction is delegated to collector-side tail sampling.
### Tail Sampling (after trace completes)
```
Trace completes → Collector evaluates:
- Error? → KEEP
- Slow? → KEEP
- Normal? → Sample 10%
```
- ✅ Never loses important traces
- ❌ Higher memory usage at collector
---
## Key Benefits for xrpld
| Challenge | How Tracing Helps |
| ---------------------------------- | ---------------------------------------- |
| "Where is my transaction?" | Follow trace across all nodes it touched |
| "Why was consensus slow?" | See timing breakdown of each phase |
| "Which node is the bottleneck?" | Compare span durations across nodes |
| "What happened during the outage?" | Correlate errors across the network |
---
## Glossary
| Term | Definition |
| -------------------- | ------------------------------------------------------------------- |
| **Trace** | Complete journey of a request, identified by `trace_id` |
| **Span** | Single operation within a trace |
| **Parent-Child** | Span relationship where the parent depends on the child |
| **Follows-From** | Causal relationship where originator doesn't wait for the result |
| **Span Link** | Non-hierarchical connection between spans, possibly across traces |
| **Deterministic ID** | Trace ID derived from domain data (e.g., tx_hash) instead of random |
| **Context** | Data propagated between services (`trace_id`, `span_id`, flags) |
| **Instrumentation** | Code that creates spans and propagates context |
| **Collector** | Service that receives, processes, and exports traces |
| **Backend** | Storage/visualization system (Tempo) |
| **Head Sampling** | Sampling decision at trace start |
| **Tail Sampling** | Sampling decision after trace completes |
---
_Next: [Architecture Analysis](./01-architecture-analysis.md)_ | _Back to: [Overview](./OpenTelemetryPlan.md)_

View File

@@ -1,467 +0,0 @@
# Architecture Analysis
> **Parent Document**: [OpenTelemetryPlan.md](./OpenTelemetryPlan.md)
> **Related**: [Design Decisions](./02-design-decisions.md) | [Implementation Strategy](./03-implementation-strategy.md)
---
## 1.1 Current xrpld Architecture Overview
> **WS** = WebSocket | **UNL** = Unique Node List | **TxQ** = Transaction Queue | **StatsD** = Statistics Daemon
The xrpld node software consists of several interconnected components that need instrumentation for distributed tracing:
```mermaid
flowchart TB
subgraph xrpld["xrpld Node"]
subgraph services["Core Services"]
RPC["RPC Server<br/>(HTTP/WS/gRPC)"]
Overlay["Overlay<br/>(P2P Network)"]
Consensus["Consensus<br/>(RCLConsensus)"]
ValidatorList["ValidatorList<br/>(UNL Mgmt)"]
end
JobQueue["JobQueue<br/>(Thread Pool)"]
subgraph processing["Processing Layer"]
NetworkOPs["NetworkOPs<br/>(Tx Processing)"]
LedgerMaster["LedgerMaster<br/>(Ledger Mgmt)"]
NodeStore["NodeStore<br/>(Database)"]
InboundLedgers["InboundLedgers<br/>(Ledger Sync)"]
end
subgraph appservices["Application Services"]
PathFind["PathFinding<br/>(Payment Paths)"]
TxQ["TxQ<br/>(Fee Escalation)"]
LoadMgr["LoadManager<br/>(Fee/Load)"]
end
subgraph observability["Existing Observability"]
PerfLog["PerfLog<br/>(JSON)"]
Insight["Insight<br/>(StatsD)"]
Logging["Logging<br/>(Journal)"]
end
services --> JobQueue
JobQueue --> processing
JobQueue --> appservices
end
style xrpld fill:#424242,stroke:#212121,color:#ffffff
style services fill:#1565c0,stroke:#0d47a1,color:#ffffff
style processing fill:#2e7d32,stroke:#1b5e20,color:#ffffff
style appservices fill:#6a1b9a,stroke:#4a148c,color:#ffffff
style observability fill:#e65100,stroke:#bf360c,color:#ffffff
```
**Reading the diagram:**
- **Core Services (blue)**: The entry points into xrpld -- RPC Server handles client requests, Overlay manages peer-to-peer networking, Consensus drives agreement, and ValidatorList manages trusted validators.
- **JobQueue (center)**: The asynchronous thread pool that decouples Core Services from the Processing and Application layers. All work flows through it.
- **Processing Layer (green)**: Core business logic -- NetworkOPs processes transactions, LedgerMaster manages ledger state, NodeStore handles persistence, and InboundLedgers synchronizes missing data.
- **Application Services (purple)**: Higher-level features -- PathFinding computes payment routes, TxQ manages fee-based queuing, and LoadManager tracks server load.
- **Existing Observability (orange)**: The current monitoring stack (PerfLog, Insight, Journal logging) that OpenTelemetry will complement, not replace.
- **Arrows (Services to JobQueue to layers)**: Work originates at Core Services, is enqueued onto the JobQueue, and dispatched to Processing or Application layers for execution.
---
## 1.1.1 Actors and Actions
### Actors
| Who (Plain English) | Technical Term |
| ----------------------------------------- | -------------------------- |
| Network node running XRPL software | xrpld node |
| External client submitting requests | RPC Client |
| Network neighbor sharing data | Peer (PeerImp) |
| Request handler for client queries | RPC Server (ServerHandler) |
| Command executor for specific RPC methods | RPCHandler |
| Agreement process between nodes | Consensus (RCLConsensus) |
| Transaction processing coordinator | NetworkOPs |
| Background task scheduler | JobQueue |
| Ledger state manager | LedgerMaster |
| Payment route calculator | PathFinding (Pathfinder) |
| Transaction waiting room | TxQ (Transaction Queue) |
| Fee adjustment system | LoadManager |
| Trusted validator list manager | ValidatorList |
| Protocol upgrade tracker | AmendmentTable |
| Ledger state hash tree | SHAMap |
| Persistent key-value storage | NodeStore |
### Actions
| What Happens (Plain English) | Technical Term |
| ---------------------------------------------- | ---------------------- |
| Client sends a request to a node | `rpc.request` |
| Node executes a specific RPC command | `rpc.command.*` |
| Node receives a transaction from a peer | `tx.receive` |
| Node checks if a transaction is valid | `tx.validate` |
| Node forwards a transaction to neighbors | `tx.relay` |
| Nodes agree on which transactions to include | `consensus.round` |
| Consensus progresses through phases | `consensus.phase.*` |
| Node builds a new confirmed ledger | `ledger.build` |
| Node fetches missing ledger data from peers | `ledger.acquire` |
| Node computes payment routes | `pathfind.compute` |
| Node queues a transaction for later processing | `txq.enqueue` |
| Node increases fees due to high load | `fee.escalate` |
| Node fetches the latest trusted validator list | `validator.list.fetch` |
| Node votes on a protocol amendment | `amendment.vote` |
| Node synchronizes state tree data | `shamap.sync` |
---
## 1.2 Key Components for Instrumentation
> **TxQ** = Transaction Queue | **UNL** = Unique Node List
| Component | Location | Purpose | Trace Value |
| ------------------ | ------------------------------------------ | ------------------------ | -------------------------------- |
| **Overlay** | `src/xrpld/overlay/` | P2P communication | Message propagation timing |
| **PeerImp** | `src/xrpld/overlay/detail/PeerImp.cpp` | Individual peer handling | Per-peer latency |
| **RCLConsensus** | `src/xrpld/app/consensus/RCLConsensus.cpp` | Consensus algorithm | Round timing, phase analysis |
| **NetworkOPs** | `src/xrpld/app/misc/NetworkOPs.cpp` | Transaction processing | Tx lifecycle tracking |
| **ServerHandler** | `src/xrpld/rpc/detail/ServerHandler.cpp` | RPC entry point | Request latency |
| **RPCHandler** | `src/xrpld/rpc/detail/RPCHandler.cpp` | Command execution | Per-command timing |
| **JobQueue** | `src/xrpl/core/JobQueue.h` | Async task execution | Queue wait times |
| **PathFinding** | `src/xrpld/app/paths/` | Payment path computation | Path latency, cache hits |
| **TxQ** | `src/xrpld/app/misc/TxQ.cpp` | Transaction queue/fees | Queue depth, eviction rates |
| **LoadManager** | `src/xrpld/app/main/LoadManager.cpp` | Fee escalation/load | Fee levels, load factors |
| **InboundLedgers** | `src/xrpld/app/ledger/InboundLedgers.cpp` | Ledger acquisition | Sync time, peer reliability |
| **ValidatorList** | `src/xrpld/app/misc/ValidatorList.cpp` | UNL management | List freshness, fetch failures |
| **AmendmentTable** | `src/xrpld/app/misc/AmendmentTable.cpp` | Protocol amendments | Voting status, activation events |
| **SHAMap** | `src/xrpld/shamap/` | State hash tree | Sync speed, missing nodes |
---
## 1.3 Transaction Flow Diagram
Transaction flow spans multiple nodes in the network. Each node creates linked spans to form a distributed trace:
```mermaid
sequenceDiagram
participant Client
participant PeerA as Peer A (Receive)
participant PeerB as Peer B (Relay)
participant PeerC as Peer C (Validate)
Client->>PeerA: 1. Submit TX
rect rgb(230, 245, 255)
Note over PeerA: tx.receive SPAN START
PeerA->>PeerA: HashRouter Deduplication
PeerA->>PeerA: tx.validate (child span)
end
PeerA->>PeerB: 2. Relay TX (with trace ctx)
rect rgb(230, 245, 255)
Note over PeerB: tx.receive (linked span)
end
PeerB->>PeerC: 3. Relay TX
rect rgb(230, 245, 255)
Note over PeerC: tx.receive (linked span)
PeerC->>PeerC: tx.process
end
Note over Client,PeerC: DISTRIBUTED TRACE (same trace_id: abc123)
```
**Reading the diagram:**
- **Client**: The external entity that submits a transaction to Peer A. It has no trace context -- the trace starts at the first node.
- **Peer A (Receive)**: The entry node that creates the root span `tx.receive`, runs HashRouter deduplication to avoid processing duplicates, and creates a child `tx.validate` span.
- **Peer A to Peer B arrow**: The relay message carries trace context (trace_id + parent span_id), enabling Peer B to create a linked span under the same trace.
- **Peer B (Relay)**: Receives the transaction and trace context, creates a `tx.receive` span linked to Peer A's trace, then relays onward.
- **Peer C (Validate)**: Final hop in this example. Creates a linked `tx.receive` span and runs `tx.process` to fully process the transaction.
- **Blue rectangles**: Highlight the span boundaries on each node, showing where instrumentation creates and closes spans.
### Trace Structure
```
trace_id: abc123
├── span: tx.receive (Peer A)
│ ├── span: tx.validate
│ └── span: tx.relay
├── span: tx.receive (Peer B) [parent: Peer A]
│ └── span: tx.relay
└── span: tx.receive (Peer C) [parent: Peer B]
└── span: tx.process
```
---
## 1.4 Consensus Round Flow
Consensus rounds are multi-phase operations that benefit significantly from tracing:
```mermaid
flowchart TB
subgraph round["consensus.round (root span)"]
attrs["Attributes:<br/>ledger_seq = 12345678<br/>consensus_mode = proposing<br/>proposers = 35"]
subgraph open["consensus.phase.open"]
open_desc["Duration: ~3s<br/>Waiting for transactions"]
end
subgraph establish["consensus.phase.establish"]
est_attrs["proposals_received = 28<br/>disputes_resolved = 3"]
est_children["├── consensus.proposal.receive (×28)<br/>├── consensus.proposal.send (×1)<br/>└── consensus.dispute.resolve (×3)"]
end
subgraph accept["consensus.phase.accept"]
acc_attrs["transactions_applied = 150<br/>ledger_hash = DEF456..."]
acc_children["├── ledger.build<br/>└── ledger.validate"]
end
attrs --> open
open --> establish
establish --> accept
end
style round fill:#f57f17,stroke:#e65100,color:#ffffff
style open fill:#1565c0,stroke:#0d47a1,color:#ffffff
style establish fill:#2e7d32,stroke:#1b5e20,color:#ffffff
style accept fill:#c2185b,stroke:#880e4f,color:#ffffff
```
**Reading the diagram:**
- **consensus.round (orange, root span)**: The top-level span encompassing the entire consensus round, with attributes like ledger sequence, mode, and proposer count.
- **consensus.phase.open (blue)**: The first phase where the node waits (~3s) to collect incoming transactions before proposing.
- **consensus.phase.establish (green)**: The negotiation phase where validators exchange proposals, resolve disputes, and converge on a transaction set. Child spans track each proposal received/sent and each dispute resolved.
- **consensus.phase.accept (pink)**: The final phase where the agreed transaction set is applied, a new ledger is built, and the ledger is validated. Child spans cover `ledger.build` and `ledger.validate`.
- **Arrows (open to establish to accept)**: The sequential flow through the three consensus phases. Each phase must complete before the next begins.
---
## 1.5 RPC Request Flow
> **WS** = WebSocket
RPC requests support W3C Trace Context headers for distributed tracing across services:
```mermaid
flowchart TB
subgraph request["rpc.request (root span)"]
http["HTTP Request — POST /<br/>traceparent:<br/>00-abc123...-def456...-01"]
attrs["Attributes:<br/>http.method = POST<br/>net.peer.ip = 192.168.1.100<br/>command = submit"]
subgraph enqueue["jobqueue.enqueue"]
job_attr["job_type = jtCLIENT_RPC"]
end
subgraph command["rpc.command.submit"]
cmd_attrs["version = 2<br/>rpc_role = user"]
cmd_children["├── tx.deserialize<br/>├── tx.validate_local<br/>└── tx.submit_to_network"]
end
response["Response: 200 OK<br/>Duration: 45ms"]
http --> attrs
attrs --> enqueue
enqueue --> command
command --> response
end
style request fill:#2e7d32,stroke:#1b5e20,color:#ffffff
style enqueue fill:#1565c0,stroke:#0d47a1,color:#ffffff
style command fill:#e65100,stroke:#bf360c,color:#ffffff
```
**Reading the diagram:**
- **rpc.request (green, root span)**: The outermost span representing the full RPC request lifecycle, from HTTP receipt to response. Carries the W3C `traceparent` header for distributed tracing.
- **HTTP Request node**: Shows the incoming POST request with its `traceparent` header and extracted attributes (method, peer IP, command name).
- **jobqueue.enqueue (blue)**: The span covering the asynchronous handoff from the RPC thread to the JobQueue worker thread. The trace context is preserved across this async boundary.
- **rpc.command.submit (orange)**: The span for the actual command execution, with child spans for deserialization, local validation, and network submission.
- **Response node**: The final output with HTTP status and total duration, marking the end of the root span.
- **Arrows (top to bottom)**: The sequential processing pipeline -- receive request, extract attributes, enqueue job, execute command, return response.
---
## 1.6 Key Trace Points
> **TxQ** = Transaction Queue
The following table identifies priority instrumentation points across the codebase:
| Category | Span Name | File | Method | Priority |
| --------------- | ---------------------- | ---------------------- | ----------------------- | -------- |
| **Transaction** | `tx.receive` | `PeerImp.cpp` | `handleTransaction()` | High |
| **Transaction** | `tx.validate` | `NetworkOPs.cpp` | `processTransaction()` | High |
| **Transaction** | `tx.process` | `NetworkOPs.cpp` | `doTransactionSync()` | High |
| **Transaction** | `tx.relay` | `OverlayImpl.cpp` | `relay()` | Medium |
| **Consensus** | `consensus.round` | `RCLConsensus.cpp` | `startRound()` | High |
| **Consensus** | `consensus.phase.*` | `Consensus.h` | `timerEntry()` | High |
| **Consensus** | `consensus.proposal.*` | `RCLConsensus.cpp` | `peerProposal()` | Medium |
| **RPC** | `rpc.request` | `ServerHandler.cpp` | `onRequest()` | High |
| **RPC** | `rpc.command.*` | `RPCHandler.cpp` | `doCommand()` | High |
| **Peer** | `peer.connect` | `OverlayImpl.cpp` | `onHandoff()` | Low |
| **Peer** | `peer.message.*` | `PeerImp.cpp` | `onMessage()` | Low |
| **Ledger** | `ledger.acquire` | `InboundLedgers.cpp` | `acquire()` | Medium |
| **Ledger** | `ledger.build` | `RCLConsensus.cpp` | `buildLCL()` | High |
| **PathFinding** | `pathfind.request` | `PathRequest.cpp` | `doUpdate()` | High |
| **PathFinding** | `pathfind.compute` | `Pathfinder.cpp` | `findPaths()` | High |
| **TxQ** | `txq.enqueue` | `TxQ.cpp` | `apply()` | High |
| **TxQ** | `txq.apply` | `TxQ.cpp` | `processClosedLedger()` | High |
| **Fee** | `fee.escalate` | `LoadManager.cpp` | `raiseLocalFee()` | Medium |
| **Ledger** | `ledger.replay` | `LedgerReplayer.h` | `replay()` | Medium |
| **Ledger** | `ledger.delta` | `LedgerDeltaAcquire.h` | `processData()` | Medium |
| **Validator** | `validator.list.fetch` | `ValidatorList.cpp` | `verify()` | Medium |
| **Validator** | `validator.manifest` | `Manifest.cpp` | `applyManifest()` | Low |
| **Amendment** | `amendment.vote` | `AmendmentTable.cpp` | `doVoting()` | Low |
| **SHAMap** | `shamap.sync` | `SHAMap.cpp` | `fetchRoot()` | Medium |
---
## 1.7 Instrumentation Priority
> **TxQ** = Transaction Queue
```mermaid
quadrantChart
title Instrumentation Priority Matrix
x-axis Low Complexity --> High Complexity
y-axis Low Value --> High Value
quadrant-1 Implement First
quadrant-2 Plan Carefully
quadrant-3 Quick Wins
quadrant-4 Consider Later
RPC Tracing: [0.2, 0.92]
Transaction Tracing: [0.55, 0.88]
Consensus Tracing: [0.78, 0.82]
PathFinding: [0.38, 0.75]
TxQ and Fees: [0.25, 0.65]
Ledger Sync: [0.62, 0.58]
Peer Message Tracing: [0.35, 0.25]
JobQueue Tracing: [0.2, 0.48]
Validator Mgmt: [0.48, 0.42]
Amendment Tracking: [0.15, 0.32]
SHAMap Operations: [0.72, 0.45]
```
---
## 1.8 Observable Outcomes
> **TxQ** = Transaction Queue | **UNL** = Unique Node List
After implementing OpenTelemetry, operators and developers will gain visibility into the following:
### 1.8.1 What You Will See: Traces
| Trace Type | Description | Example Query in Grafana/Tempo |
| -------------------------- | ------------------------------------------------------------------------------------------- | ----------------------------------------------- |
| **Transaction Lifecycle** | Full journey from RPC submission through validation, relay, consensus, and ledger inclusion | `{service.name="xrpld" && tx_hash="ABC123..."}` |
| **Cross-Node Propagation** | Transaction path across multiple xrpld nodes with timing | `{relay_count > 0}` |
| **Consensus Rounds** | Complete round with all phases (open, establish, accept) | `{span.name=~"consensus.round.*"}` |
| **RPC Request Processing** | Individual command execution with timing breakdown | `{command="account_info"}` |
| **Ledger Acquisition** | Peer-to-peer ledger data requests and responses | `{span.name="ledger.acquire"}` |
| **PathFinding Latency** | Path computation time and cache effectiveness for payment RPCs | `{span.name="pathfind.compute"}` |
| **TxQ Behavior** | Queue depth, eviction patterns, fee escalation during congestion | `{span.name=~"txq.*"}` |
| **Ledger Sync** | Full acquisition timeline including delta and transaction fetches | `{span.name=~"ledger.acquire.*"}` |
| **Validator Health** | UNL fetch success, manifest updates, stale list detection | `{span.name=~"validator.*"}` |
### 1.8.2 What You Will See: Metrics (Derived from Traces)
| Metric | Description | Dashboard Panel |
| ----------------------------- | --------------------------------------- | --------------------------- |
| **RPC Latency (p50/p95/p99)** | Response time distribution per command | Heatmap by command |
| **Transaction Throughput** | Transactions processed per second | Time series graph |
| **Consensus Round Duration** | Time to complete consensus phases | Histogram |
| **Cross-Node Latency** | Time for transaction to reach N nodes | Line chart with percentiles |
| **Error Rate** | Failed transactions/RPC calls by type | Stacked bar chart |
| **PathFinding Latency** | Path computation time per currency pair | Heatmap by currency |
| **TxQ Depth** | Queued transactions over time | Time series with thresholds |
| **Fee Escalation Level** | Current fee multiplier | Gauge with alert thresholds |
| **Ledger Sync Duration** | Time to acquire missing ledgers | Histogram |
### 1.8.3 Concrete Dashboard Examples
**Transaction Trace View (Tempo):**
```
┌────────────────────────────────────────────────────────────────────────────────┐
│ Trace: abc123... (Transaction Submission) Duration: 847ms │
├────────────────────────────────────────────────────────────────────────────────┤
│ ├── rpc.request [ServerHandler] ████░░░░░░ 45ms │
│ │ └── rpc.command.submit [RPCHandler] ████░░░░░░ 42ms │
│ │ └── tx.receive [NetworkOPs] ███░░░░░░░ 35ms │
│ │ ├── tx.validate [TxQ] █░░░░░░░░░ 8ms │
│ │ └── tx.relay [Overlay] ██░░░░░░░░ 15ms │
│ │ ├── tx.receive [Node-B] █████░░░░░ 52ms │
│ │ │ └── tx.relay [Node-B] ██░░░░░░░░ 18ms │
│ │ └── tx.receive [Node-C] ██████░░░░ 65ms │
│ └── consensus.round [RCLConsensus] ████████░░ 720ms │
│ ├── consensus.phase.open ██░░░░░░░░ 180ms │
│ ├── consensus.phase.establish █████░░░░░ 480ms │
│ └── consensus.phase.accept █░░░░░░░░░ 60ms │
└────────────────────────────────────────────────────────────────────────────────┘
```
**RPC Performance Dashboard Panel:**
```
┌─────────────────────────────────────────────────────────────┐
│ RPC Command Latency (Last 1 Hour) │
├─────────────────────────────────────────────────────────────┤
│ Command │ p50 │ p95 │ p99 │ Errors │ Rate │
│──────────────────┼────────┼────────┼────────┼────────┼──────│
│ account_info │ 12ms │ 45ms │ 89ms │ 0.1% │ 150/s│
│ submit │ 35ms │ 120ms │ 250ms │ 2.3% │ 45/s│
│ ledger │ 8ms │ 25ms │ 55ms │ 0.0% │ 80/s│
│ tx │ 15ms │ 50ms │ 100ms │ 0.5% │ 60/s│
│ server_info │ 5ms │ 12ms │ 20ms │ 0.0% │ 200/s│
└─────────────────────────────────────────────────────────────┘
```
**Consensus Health Dashboard Panel:**
```mermaid
---
config:
xyChart:
width: 1200
height: 400
plotReservedSpacePercent: 50
chartOrientation: vertical
themeVariables:
xyChart:
plotColorPalette: "#3498db"
---
xychart-beta
title "Consensus Round Duration (Last 24 Hours)"
x-axis "Time of Day (Hours)" [0, 2, 4, 6, 8, 10, 12, 14, 16, 18, 20, 22, 24]
y-axis "Duration (seconds)" 1 --> 5
line [2.1, 2.4, 2.8, 3.2, 3.8, 4.3, 4.5, 5.0, 4.7, 4.0, 3.2, 2.6, 2.0]
```
### 1.8.4 Operator Actionable Insights
| Scenario | What You'll See | Action |
| ------------------------- | ---------------------------------------------------------------------------- | ------------------------------------------------ |
| **Slow RPC** | Span showing which phase is slow (parsing, execution, serialization) | Optimize specific code path |
| **Transaction Stuck** | Trace stops at validation; error attribute shows reason | Fix transaction parameters |
| **Consensus Delay** | Phase.establish taking too long; proposer attribute shows missing validators | Investigate network connectivity |
| **Memory Spike** | Large batch of spans correlating with memory increase | Tune batch_size or sampling |
| **Network Partition** | Traces missing cross-node links for specific peer | Check peer connectivity |
| **Path Computation Slow** | pathfind.compute span shows high latency; cache miss rate in attributes | Warm the RippleLineCache, check order book depth |
| **TxQ Full** | txq.enqueue spans show evictions; fee.escalate spans increasing | Monitor fee levels, alert operators |
| **Ledger Sync Stalled** | ledger.acquire spans timing out; peer reliability attributes show issues | Check peer connectivity, add trusted peers |
| **UNL Stale** | validator.list.fetch spans failing; last_update attribute aging | Verify validator site URLs, check DNS |
### 1.8.5 Developer Debugging Workflow
1. **Find Transaction**: Query by `tx_hash` to get full trace
2. **Identify Bottleneck**: Look at span durations to find slowest component
3. **Check Attributes**: Review `validity`, `rpc_status` for errors
4. **Correlate Logs**: Use `trace_id` to find related PerfLog entries
5. **Compare Nodes**: Filter by `service.instance.id` to compare behavior across nodes
---
_Next: [Design Decisions](./02-design-decisions.md)_ | _Back to: [Overview](./OpenTelemetryPlan.md)_

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@@ -1,686 +0,0 @@
# Design Decisions
> **Parent Document**: [OpenTelemetryPlan.md](./OpenTelemetryPlan.md)
> **Related**: [Architecture Analysis](./01-architecture-analysis.md)
---
## 2.1 OpenTelemetry Components
> **OTLP** = OpenTelemetry Protocol
### 2.1.1 SDK Selection
**Primary Choice**: OpenTelemetry C++ SDK (`opentelemetry-cpp`)
| Component | Purpose | Required |
| --------------------------------------- | ---------------------- | ------------------------- |
| `opentelemetry-cpp::api` | Tracing API headers | Yes |
| `opentelemetry-cpp::sdk` | SDK implementation | Yes |
| `opentelemetry-cpp::ext` | Extensions (exporters) | Yes |
| `opentelemetry-cpp::otlp_http_exporter` | OTLP/HTTP export | Yes (shipped in Phase 1b) |
| `opentelemetry-cpp::otlp_grpc_exporter` | OTLP/gRPC export | Future (not yet wired up) |
### 2.1.2 Instrumentation Strategy
**Manual Instrumentation** (recommended):
| Approach | Pros | Cons |
| ---------- | --------------------------------------------------------------- | ------------------------------------------------------- |
| **Manual** | Precise control, optimized placement, xrpld-specific attributes | More development effort |
| **Auto** | Less code, automatic coverage | Less control, potential overhead, limited customization |
---
## 2.2 Exporter Configuration
> **OTLP** = OpenTelemetry Protocol
```mermaid
flowchart TB
subgraph nodes["xrpld Nodes"]
node1["xrpld<br/>Node 1"]
node2["xrpld<br/>Node 2"]
node3["xrpld<br/>Node 3"]
end
collector["OpenTelemetry<br/>Collector<br/>(sidecar or standalone)"]
subgraph backends["Observability Backends"]
tempo["Tempo"]
elastic["Elastic<br/>APM"]
end
node1 -->|"OTLP/HTTP<br/>:4318"| collector
node2 -->|"OTLP/HTTP<br/>:4318"| collector
node3 -->|"OTLP/HTTP<br/>:4318"| collector
collector --> tempo
collector --> elastic
style nodes fill:#0d47a1,stroke:#082f6a,color:#ffffff
style backends fill:#1b5e20,stroke:#0d3d14,color:#ffffff
style collector fill:#bf360c,stroke:#8c2809,color:#ffffff
```
**Reading the diagram:**
- **xrpld Nodes (blue)**: The source of telemetry data. Each xrpld node exports spans via OTLP/HTTP on port 4318 (the only exporter shipped in Phase 1b).
- **OpenTelemetry Collector (red)**: The central aggregation point that receives spans from all nodes. Can run as a sidecar (per-node) or standalone (shared). Handles batching, filtering, and routing.
- **Observability Backends (green)**: The storage and visualization destinations. Tempo is the recommended backend for both development and production, and Elastic APM is an alternative. The Collector routes to one or more backends.
- **Arrows (nodes to collector to backends)**: The data pipeline -- spans flow from nodes to the Collector over HTTP, then the Collector fans out to the configured backends.
### 2.2.1 OTLP/HTTP (Shipped in Phase 1b)
OTLP/HTTP is the only exporter wired up in Phase 1b. It is configured via
`OtlpHttpExporterOptions` with the collector traces endpoint
(`http://localhost:4318/v1/traces` by default) and a JSON content type
(binary protobuf is also available).
### 2.2.2 OTLP/gRPC (Future Work — Planned Upgrade)
OTLP/gRPC is planned as a future upgrade from the HTTP exporter. The gRPC
transport offers lower per-span overhead and tighter back-pressure semantics
than HTTP/JSON, making it attractive for production deployments once the HTTP
path is validated in earlier phases.
Required to land this upgrade:
1. Add `opentelemetry-cpp::otlp_grpc_exporter` to the Conan recipe (the
dependency already exists but is not linked in Phase 1b builds).
2. Extend `TelemetryConfig.cpp` to parse an `exporter` key (`otlp_http`
default, `otlp_grpc` opt-in) and a gRPC endpoint override.
3. In `Telemetry::start()` branch on the parsed exporter type and construct
either `OtlpHttpExporterFactory::Create(httpOpts)` or
`OtlpGrpcExporterFactory::Create(grpcOpts)` accordingly.
4. Update the runbook and dashboards to document the alternate port and TLS
settings.
When wired up, the gRPC path will use `OtlpGrpcExporterOptions` configured with
the collector endpoint (host on port 4317), TLS credentials enabled, and a CA
certificate path.
Until that work lands, `OtlpGrpcExporterOptions` is **not** used by any code
path in Phase 1b through Phase 5.
---
## 2.3 Span Naming Conventions
> **TxQ** = Transaction Queue | **UNL** = Unique Node List | **WS** = WebSocket
### 2.3.1 Naming Schema
```
<component>.<operation>[.<sub-operation>]
```
**Examples**:
- `tx.receive` - Transaction received from peer
- `consensus.phase.establish` - Consensus establish phase
- `rpc.command.server_info` - server_info RPC command
### 2.3.2 Complete Span Catalog
| Span name | Description |
| ------------------------------ | --------------------------------------- |
| `tx.receive` | Transaction received from network |
| `tx.validate` | Transaction signature/format validation |
| `tx.process` | Full transaction processing |
| `tx.relay` | Transaction relay to peers |
| `tx.apply` | Apply transaction to ledger |
| `consensus.round` | Complete consensus round |
| `consensus.phase.open` | Open phase - collecting transactions |
| `consensus.phase.establish` | Establish phase - reaching agreement |
| `consensus.phase.accept` | Accept phase - applying consensus |
| `consensus.proposal.receive` | Receive peer proposal |
| `consensus.proposal.send` | Send our proposal |
| `consensus.validation.receive` | Receive peer validation |
| `consensus.validation.send` | Send our validation |
| `rpc.request` | HTTP/WebSocket request handling |
| `rpc.command.*` | Specific RPC command (dynamic) |
| `peer.connect` | Peer connection establishment |
| `peer.disconnect` | Peer disconnection |
| `peer.message.send` | Send protocol message |
| `peer.message.receive` | Receive protocol message |
| `ledger.acquire` | Ledger acquisition from network |
| `ledger.build` | Build new ledger |
| `ledger.validate` | Ledger validation |
| `ledger.close` | Close ledger |
| `ledger.replay` | Ledger replay executed |
| `ledger.delta` | Delta-based ledger acquired |
| `pathfind.request` | Path request initiated |
| `pathfind.compute` | Path computation executed |
| `txq.enqueue` | Transaction queued |
| `txq.apply` | Queued transaction applied |
| `fee.escalate` | Fee escalation triggered |
| `validator.list.fetch` | UNL list fetched |
| `validator.manifest` | Manifest update processed |
| `amendment.vote` | Amendment voting executed |
| `shamap.sync` | State tree synchronization |
| `job.enqueue` | Job added to queue |
| `job.execute` | Job execution |
### 2.3.3 Attribute Naming Conventions
Span **names** follow §2.3.1 (dotted `<component>.<operation>`). Span
**attribute keys** follow the rules below. The constants in the `*SpanNames.h`
headers are the single source of truth; the collector, Tempo, the Grafana
dashboards, and the runbook all consume these exact keys, so every layer must
agree with the code. A CI check enforces this end to end.
1. **Per-span unique attribute** → bare field name, allowed when the field is
recorded by a single span/workflow so the span name already supplies the
domain (e.g. `command`, `version`, `local` on `rpc.command`).
2. **Shared attribute (same concept on more than one span)** → ONE key, reused
verbatim on every span that records it; the span name tells the occurrences
apart, so no per-emitter prefix is added. Name it by the field's meaning: a
property of a domain object keeps that object's bare field name (`ledger_hash`,
`ledger_seq`, `tx_hash`, `peer_id`, `full_validation`); a field already
qualified by a sub-kind keeps that qualifier on every emitter (`proposal_trusted`
on both `consensus.proposal.receive` and `peer.proposal.receive`;
`validation_trusted` likewise). Defined once in the base `SpanNames.h`
`namespace attr` block and re-exported (`using`) by each domain header.
3. **Collision qualifier**`<domain>_<field>`, only when a bare name would
collide with a DIFFERENT concept in the shared spanmetrics label space or with
the OTel-reserved `status` key (e.g. `rpc_status`, `grpc_status`,
`consensus_phase`, `consensus_round`, `consensus_mode`). This disambiguates
distinct concepts that share a word; it is NOT used to tag the same concept
with its emitting workflow — that is rule 2 (one shared name).
4. **Resource attribute** → dotted `xrpl.<subsystem>.<field>`, reserved ONLY
for process/network identity set once at startup (`xrpl.network.id`,
`xrpl.network.type`). Span attributes are never dotted in the `xrpl.` form —
it blurs the resource/span scope boundary and parses awkwardly in TraceQL.
5. **Span names** use `<subsystem>[.<component>]` (dotted, per §2.3.1). Only
attribute _keys_ follow rules 14.
Standard OpenTelemetry semantic-convention keys keep their canonical dotted
form (e.g. `service.*` resource attributes, `http.*` span attributes); the
"no dotted form" rule applies to xrpl-custom keys only.
The same rules are recorded in `CONTRIBUTING.md` (the permanent home, since
`OpenTelemetryPlan/` is removed once the rollout completes). The attribute
examples in §2.4 below follow these rules.
---
## 2.4 Attribute Schema
> **TxQ** = Transaction Queue | **UNL** = Unique Node List | **OTLP** = OpenTelemetry Protocol
### 2.4.1 Resource Attributes (Set Once at Startup)
Resource attributes identify the process and are set once at startup. They use
the standard OpenTelemetry semantic conventions plus custom dotted `xrpl.*`
keys (the dotted form is reserved for resource scope per §2.3.3).
| Key | Type / value | Description |
| --------------------- | ------------------------------------------------------- | ------------------------------ |
| `service.name` | `"xrpld"` | Standard `SERVICE_NAME` |
| `service.version` | `BuildInfo::getVersionString()` | Standard `SERVICE_VERSION` |
| `service.instance.id` | node public key (base58) | Standard `SERVICE_INSTANCE_ID` |
| `xrpl.network.id` | network id (e.g. 0 for mainnet) | Network identifier |
| `xrpl.network.type` | `"mainnet"` \| `"testnet"` \| `"devnet"` \| `"unknown"` | Network kind |
| `xrpl.node.type` | `"validator"` \| `"stock"` \| `"reporting"` | Node role |
| `xrpl.node.cluster` | cluster name | Cluster name, if clustered |
### 2.4.2 Span Attributes by Category
> Span attribute keys use the underscore form from §2.3.3 (shared/qualified
> keys are `<domain>_<field>`; per-span unique keys are bare). The dotted form
> is reserved for the resource attributes in §2.4.1 above. This catalog lists
> the planned attribute set by category; the exact emitted key for each
> implemented span is defined by the `*SpanNames.h` constants, which are the
> single source of truth where the two differ.
#### Transaction Attributes
| Key | Type | Description |
| -------------- | ------ | ------------------------------------- |
| `tx_hash` | string | Transaction hash (hex) |
| `tx_type` | string | `"Payment"`, `"OfferCreate"`, etc. |
| `tx_account` | string | Source account (redacted in prod) |
| `tx_sequence` | int64 | Account sequence number |
| `tx_fee` | int64 | Fee in drops |
| `tx_result` | string | `"tesSUCCESS"`, `"tecPATH_DRY"`, etc. |
| `ledger_index` | int64 | Ledger containing transaction |
| `relay_count` | int64 | Peers the transaction was relayed to |
| `suppressed` | bool | `true` when HashRouter dropped a dup |
#### Consensus Attributes
| Key | Type | Description |
| -------------------- | ------- | ----------------------------------- |
| `consensus_round` | int64 | Round number |
| `consensus_phase` | string | `"open"`, `"establish"`, `"accept"` |
| `consensus_mode` | string | `"proposing"`, `"observing"`, etc. |
| `proposers` | int64 | Number of proposers |
| `prev_ledger_prefix` | string | Previous ledger hash prefix |
| `ledger_seq` | int64 | Ledger sequence |
| `tx_count` | int64 | Transactions in consensus set |
| `round_time_ms` | float64 | Round duration |
Establish-phase gap fill and cross-node correlation attributes (Phase 4a):
| Key | Type | Description |
| --------------------- | ------ | --------------------------------------------------------- |
| `consensus_round_id` | int64 | Consensus round number |
| `consensus_ledger_id` | string | `previousLedger.id()` — shared across nodes |
| `trace_strategy` | string | `"deterministic"` or `"attribute"` |
| `converge_percent` | int64 | Convergence % (0-100+) |
| `establish_count` | int64 | Number of establish iterations |
| `disputes_count` | int64 | Active disputed transactions |
| `agree_count` | int64 | Peers that agree (haveConsensus) |
| `disagree_count` | int64 | Peers that disagree |
| `threshold_percent` | int64 | Close-time consensus threshold (`avCT_CONSENSUS_PCT`=75%) |
| `consensus_result` | string | `"yes"`, `"no"`, `"moved_on"`, `"expired"` |
| `mode_old` | string | Previous consensus mode |
| `mode_new` | string | New consensus mode |
#### RPC Attributes
| Key | Type | Description |
| ------------- | ------- | ----------------------------------------------------------------------------- |
| `command` | string | Command name (per-span unique on `rpc.command`) |
| `version` | int64 | API version |
| `rpc_role` | string | `"admin"` or `"user"` (qualified — `role` is generic) |
| `params` | string | Sanitized parameters (optional) |
| `rpc_status` | string | Response status: `success` \| `error` (qualified — `status` is OTel-reserved) |
| `duration_ms` | float64 | Request duration in milliseconds |
#### Peer & Message Attributes
| Key | Type | Description |
| -------------------- | ------- | -------------------------- |
| `peer_id` | string | Peer public key (base58) |
| `peer_address` | string | IP:port |
| `peer_latency_ms` | float64 | Measured latency |
| `peer_cluster` | string | Cluster name if clustered |
| `message_type` | string | Protocol message type name |
| `message_size_bytes` | int64 | Message size |
| `message_compressed` | bool | Whether compressed |
#### Ledger & Job Attributes
| Key | Type | Description |
| ----------------- | ------- | --------------------- |
| `ledger_hash` | string | Ledger hash |
| `ledger_index` | int64 | Ledger sequence/index |
| `close_time` | int64 | Close time (epoch) |
| `ledger_tx_count` | int64 | Transaction count |
| `job_type` | string | Job type name |
| `job_queue_ms` | float64 | Time spent in queue |
| `job_worker` | int64 | Worker thread ID |
#### PathFinding Attributes
| Key | Type | Description |
| -------------------------- | ------ | ------------------------- |
| `pathfind_source_currency` | string | Source currency code |
| `pathfind_dest_currency` | string | Destination currency code |
| `pathfind_path_count` | int64 | Number of paths found |
| `pathfind_cache_hit` | bool | RippleLineCache hit |
#### TxQ Attributes
| Key | Type | Description |
| --------------------- | ------ | --------------------------- |
| `txq_queue_depth` | int64 | Current queue depth |
| `txq_fee_level` | int64 | Fee level of transaction |
| `txq_eviction_reason` | string | Why transaction was evicted |
#### Fee Attributes
| Key | Type | Description |
| ---------------------- | ----- | ------------------------- |
| `fee_load_factor` | int64 | Current load factor |
| `fee_escalation_level` | int64 | Fee escalation multiplier |
#### Validator Attributes
| Key | Type | Description |
| ------------------------ | ----- | ------------------------- |
| `validator_list_size` | int64 | UNL size |
| `validator_list_age_sec` | int64 | Seconds since last update |
#### Amendment Attributes
| Key | Type | Description |
| ------------------ | ------ | -------------------------------------- |
| `amendment_name` | string | Amendment name |
| `amendment_status` | string | `"enabled"`, `"vetoed"`, `"supported"` |
#### SHAMap Attributes
| Key | Type | Description |
| ---------------------- | ------- | --------------------------------------------- |
| `shamap_type` | string | `"transaction"`, `"state"`, `"account_state"` |
| `shamap_missing_nodes` | int64 | Number of missing nodes during sync |
| `shamap_duration_ms` | float64 | Sync duration |
### 2.4.3 Data Collection Summary
The following table summarizes what data is collected by category:
| Category | Attributes Collected | Purpose |
| --------------- | ---------------------------------------------------------------------------------------------------------------- | ---------------------------- |
| **Transaction** | `tx_hash`, `tx_type`, `tx_result`, `tx_fee`, `ledger_index` | Trace transaction lifecycle |
| **Consensus** | `consensus_round`, `consensus_phase`, `consensus_mode`, `proposers`, `round_time_ms` | Analyze consensus timing |
| **RPC** | `command`, `version`, `rpc_status`, `duration_ms` | Monitor RPC performance |
| **Peer** | `peer_id` (public key), `peer_latency_ms`, `message_type`, `message_size_bytes` | Network topology analysis |
| **Ledger** | `ledger_hash`, `ledger_index`, `close_time`, `ledger_tx_count` | Ledger progression tracking |
| **Job** | `job_type`, `job_queue_ms`, `job_worker` | JobQueue performance |
| **PathFinding** | `pathfind_fast`, `pathfind_search_level`, `pathfind_num_paths`, `pathfind_ledger_index`, `pathfind_num_requests` | Payment path analysis |
| **TxQ** | `txq_queue_depth`, `txq_fee_level`, `txq_eviction_reason` | Queue depth and fee tracking |
| **Fee** | `fee_load_factor`, `fee_escalation_level` | Fee escalation monitoring |
| **Validator** | `validator_list_size`, `validator_list_age_sec` | UNL health monitoring |
| **Amendment** | `amendment_name`, `amendment_status` | Protocol upgrade tracking |
| **SHAMap** | `shamap_type`, `shamap_missing_nodes`, `shamap_duration_ms` | State tree sync performance |
### 2.4.4 Privacy & Sensitive Data Policy
> **PII** = Personally Identifiable Information
OpenTelemetry instrumentation is designed to collect **operational metadata only**, never sensitive content.
#### Data NOT Collected
The following data is explicitly **excluded** from telemetry collection:
| Excluded Data | Reason |
| ----------------------- | ----------------------------------------- |
| **Private Keys** | Never exposed; not relevant to tracing |
| **Account Balances** | Financial data; privacy sensitive |
| **Transaction Amounts** | Financial data; privacy sensitive |
| **Raw TX Payloads** | May contain sensitive memo/data fields |
| **Personal Data** | No PII collected |
| **IP Addresses** | Configurable; excluded by default in prod |
#### Privacy Protection Mechanisms
| Mechanism | Description |
| ----------------------------- | ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------ |
| **Account Hashing** | Account addresses are hashed both SDK-side (`pathfind_source_account`, `pathfind_dest_account` — always hashed before emission) and again at the collector level, so raw addresses never reach storage |
| **Configurable Redaction** | Sensitive fields can be excluded via `[telemetry]` config section |
| **Collector Tail Sampling** | xrpld head sampling is fixed at 1.0 (every span emitted); the collector retains ~10% of non-error traces, reducing stored data exposure |
| **Sampling** | Only 10% of traces recorded by default, reducing data exposure |
| **Local Control** | Node operators have full control over what gets exported |
| **No Raw Payloads** | Transaction content is never recorded, only metadata (hash, type, result) |
| **Collector-Level Filtering** | Additional redaction/hashing can be configured at OTel Collector |
#### Account Address Hashing
Account addresses are **always** hashed before they reach the telemetry
backend — there is no opt-out flag and therefore no insecure-by-default
failure mode. Protection is applied in two independent layers:
1. **SDK-side** (this node): the path-finding RPC handlers call
`redactAccount()` (`xrpl::telemetry`, `Redaction.h`) before setting the
`pathfind_source_account` / `pathfind_dest_account` span attributes. The
helper emits the first 16 characters of `sha512Half(address)` as
lowercase hex — deterministic (spans for one account still correlate)
but non-reversible.
2. **Collector-side** (defense-in-depth): an `attributes/hash` processor in
the OpenTelemetry Collector re-hashes those same attributes, so any node
that emitted a raw value is still redacted before storage.
#### Collector-Level Data Protection
The OpenTelemetry Collector can be configured (via an `attributes` processor)
to hash or redact sensitive attributes before export — for example, hashing
`pathfind_source_account` / `pathfind_dest_account`, deleting `peer_address`
to drop IP addresses, and deleting `params` to redact request parameters.
#### Configuration Options for Privacy
In `xrpld.cfg`, operators control data collection granularity through the
`[telemetry]` section. Besides `enabled`, per-component toggles
(`trace_transactions`, `trace_consensus`, `trace_rpc`, `trace_peer` — the last
often disabled due to high volume) select which spans are emitted. Account
address hashing is not configurable: addresses are hashed unconditionally by
the SDK helper described above, with collector-level hashing as a second
layer.
> **Key Principle**: Telemetry collects **operational metadata** (timing, counts, hashes) — never **sensitive content** (keys, balances, amounts, raw payloads).
> **See also**: [Securing the OTel Pipeline](./secure-OTel.md) covers transport-level protection for telemetry leaving the node — mTLS to the collector and validation of incoming peer trace context. Privacy controls in this section keep sensitive data out of spans; the security doc keeps the spans themselves out of untrusted hands.
---
## 2.5 Context Propagation Design
> **WS** = WebSocket
### 2.5.0 Deterministic Trace ID Strategy
Both transaction and consensus tracing use **deterministic trace IDs** derived from
a globally known hash, so all nodes handling the same workflow independently produce
spans under the same `trace_id`. This is combined with protobuf `span_id` propagation
for parent-child relay ordering when available.
#### Transactions — `trace_id = txHash[0:16]`
Every node that handles a transaction knows its `txID` (the `uint256` transaction
hash). The first 16 bytes of this hash are used as the OTel `trace_id`:
```
uint256 txHash: A1B2C3D4 E5F6A7B8 C9D0E1F2 A3B4C5D6 E7F8A9B0 C1D2E3F4 A5B6C7D8 E9F0A1B2
|---------- trace_id (16 bytes) ---------| (remaining 16 bytes unused)
```
Each node generates a **random 8-byte `span_id`** so its span is unique within the
shared trace. When protobuf `TraceContext` is present in the incoming `TMTransaction`,
the sender's `span_id` is extracted and used as the parent — preserving the relay
chain as a parent-child tree. When absent (older peers, first hop from client), the
span appears as a root in the same trace — correlation is preserved, only the tree
structure degrades.
```
Node A (submitter) Node B (relay) Node C (relay)
trace_id: A1B2... trace_id: A1B2... trace_id: A1B2...
span_id: 1234 (random) span_id: 5678 (random) span_id: 9ABC (random)
parent: (none) parent: 1234 (proto) parent: 5678 (proto)
↑ ↑
protobuf propagation protobuf propagation
```
If protobuf propagation fails at Node B (old peer):
```
Node A Node B (old peer) Node C
trace_id: A1B2... trace_id: A1B2... trace_id: A1B2...
span_id: 1234 span_id: 5678 span_id: 9ABC
parent: (none) parent: (none) parent: 5678 (proto)
↑ no parent, but same trace_id — still grouped
```
#### Consensus — `trace_id = prevLedgerHash[0:16]`
All validators in the same consensus round share the same `previousLedger.id()`.
The first 16 bytes are used as trace_id. See [Phase 4a implementation status](./06-implementation-phases.md)
and `createDeterministicContext()` in `RCLConsensus.cpp` for the implementation.
Switchable via `consensus_trace_strategy` config:
`"deterministic"` (default) or `"attribute"` (random trace_id, correlation via attribute queries).
#### Why Not Random IDs with Propagation Only?
Random trace IDs require **unbroken context propagation** across every hop. In a
mixed-version network (common during upgrades), older peers silently drop the
`trace_context` protobuf field. The trace splits and downstream spans become
impossible to find. Deterministic IDs make correlation **propagation-resilient** — the trace
backend groups all spans for the same transaction/round regardless of whether
propagation succeeded.
#### Why Keep Protobuf Propagation?
Deterministic trace IDs alone provide correlation (all spans grouped) but not
**causality** (which node relayed to which). Protobuf `span_id` propagation adds
parent-child ordering that shows the exact relay path. The two mechanisms complement
each other:
| Mechanism | Provides | Fails when |
| ---------------------------- | --------------------------- | -------------------------------------- |
| Deterministic trace_id | Cross-node correlation | Never (hash is always known) |
| Protobuf span_id propagation | Parent-child relay ordering | Older peer drops `trace_context` field |
#### Implementation Reference
The utility function `createDeterministicTxContext(uint256 const& txHash)` follows
the same pattern as `createDeterministicContext(uint256 const& ledgerId)` in
`RCLConsensus.cpp`. See [Phase 3 Task 3.9](./Phase3_taskList.md) for the full spec.
### 2.5.1 Propagation Boundaries
```mermaid
flowchart TB
subgraph http["HTTP/WebSocket (RPC)"]
w3c["W3C Trace Context Headers:<br/>traceparent:<br/>00-trace_id-span_id-flags<br/>tracestate: xrpld=..."]
end
subgraph protobuf["Protocol Buffers (P2P)"]
proto["message TraceContext {<br/> bytes trace_id = 1; // 16 bytes<br/> bytes span_id = 2; // 8 bytes<br/> uint32 trace_flags = 3;<br/> string trace_state = 4;<br/>}"]
end
subgraph jobqueue["JobQueue (Internal Async)"]
job["Context captured at job creation,<br/>restored at execution<br/><br/>class Job {<br/> otel::context::Context<br/> traceContext_;<br/>};"]
end
style http fill:#0d47a1,stroke:#082f6a,color:#ffffff
style protobuf fill:#1b5e20,stroke:#0d3d14,color:#ffffff
style jobqueue fill:#bf360c,stroke:#8c2809,color:#ffffff
```
**Reading the diagram:**
- **HTTP/WebSocket - RPC (blue)**: For client-facing RPC requests, trace context is propagated using the W3C `traceparent` header. This is the standard approach and works with any OTel-compatible client.
- **Protocol Buffers - P2P (green)**: For peer-to-peer messages between xrpld nodes, trace context is embedded as a protobuf `TraceContext` message carrying trace_id, span_id, flags, and optional trace_state.
- **JobQueue - Internal Async (red)**: For asynchronous work within a single node, the OTel context is captured when a job is created and restored when the job executes on a worker thread. This bridges the async gap so spans remain linked.
---
## 2.6 Integration with Existing Observability
> **OTLP** = OpenTelemetry Protocol | **WS** = WebSocket
### 2.6.1 Existing Frameworks Comparison
xrpld already has two observability mechanisms. OpenTelemetry complements (not replaces) them:
| Aspect | PerfLog | Beast Insight (StatsD) | OpenTelemetry |
| --------------------- | ----------------------------- | ---------------------------- | ------------------------- |
| **Type** | Logging | Metrics | Distributed Tracing |
| **Data** | JSON log entries | Counters, gauges, histograms | Spans with context |
| **Scope** | Single node | Single node | **Cross-node** |
| **Output** | `perf.log` file | StatsD server | OTLP Collector |
| **Question answered** | "What happened on this node?" | "How many? How fast?" | "What was the journey?" |
| **Correlation** | By timestamp | By metric name | By `trace_id` |
| **Overhead** | Low (file I/O) | Low (UDP packets) | Low-Medium (configurable) |
### 2.6.2 What Each Framework Does Best
#### PerfLog
- **Purpose**: Detailed local event logging for RPC and job execution
- **Strengths**:
- Rich JSON output with timing data
- Already integrated in RPC handlers
- File-based, no external dependencies
- **Limitations**:
- Single-node only (no cross-node correlation)
- No parent-child relationships between events
- Manual log parsing required
A PerfLog entry is a JSON object with fields such as `time`, `method`,
`duration_us`, and `result`.
#### Beast Insight (StatsD)
- **Purpose**: Real-time metrics for monitoring dashboards
- **Strengths**:
- Aggregated metrics (counters, gauges, histograms)
- Low overhead (UDP, fire-and-forget)
- Good for alerting thresholds
- **Limitations**:
- No request-level detail
- No causal relationships
- Single-node perspective
In xrpld, Beast Insight is used through `increment` (counters), `gauge`
(point-in-time values), and `timing` (durations) calls.
#### OpenTelemetry (NEW)
- **Purpose**: Distributed request tracing across nodes
- **Strengths**:
- **Cross-node correlation** via `trace_id`
- Parent-child span relationships
- Rich attributes per span
- Industry standard (CNCF)
- **Limitations**:
- Requires collector infrastructure
- Higher complexity than logging
A span is created via `startSpan` (e.g. `"tx.relay"`), annotated with
attributes such as `tx_hash` and `peer_id`, and is automatically linked to its
parent through the active context.
### 2.6.3 When to Use Each
| Scenario | PerfLog | StatsD | OpenTelemetry |
| --------------------------------------- | ---------- | ------ | ------------- |
| "How many TXs per second?" | ❌ | ✅ | ✅ |
| "What's the p99 RPC latency?" | ❌ | ✅ | ✅ |
| "Why was this specific TX slow?" | ⚠️ partial | ❌ | ✅ |
| "Which node delayed consensus?" | ❌ | ❌ | ✅ |
| "What happened on node X at time T?" | ✅ | ❌ | ✅ |
| "Show me the TX journey across 5 nodes" | ❌ | ❌ | ✅ |
### 2.6.4 Coexistence Strategy
> **Note**: Phase 7 replaces the StatsD bridge with native OTel Metrics SDK export. The diagram below shows the Phase 6 intermediate state. See [Phase7_taskList.md](./Phase7_taskList.md) for the migration design where Beast Insight emits via OTLP instead of StatsD.
```mermaid
flowchart TB
subgraph xrpld["xrpld Process"]
perflog["PerfLog<br/>(JSON to file)"]
insight["Beast Insight<br/>(StatsD)"]
otel["OpenTelemetry<br/>(Tracing)"]
end
perflog --> perffile["perf.log"]
insight --> statsd["StatsD Server"]
otel --> collector["OTLP Collector"]
perffile --> grafana["Grafana<br/>(Unified UI)"]
statsd --> grafana
collector --> grafana
style xrpld fill:#212121,stroke:#0a0a0a,color:#ffffff
style grafana fill:#bf360c,stroke:#8c2809,color:#ffffff
```
**Reading the diagram:**
- **xrpld Process (dark gray)**: The single xrpld node running all three observability frameworks side by side. Each framework operates independently with no interference.
- **PerfLog to perf.log**: PerfLog writes JSON-formatted event logs to a local file. Grafana can ingest these via Loki or a file-based datasource.
- **Beast Insight to StatsD Server**: Insight sends aggregated metrics (counters, gauges) over UDP to a StatsD server. Grafana reads from StatsD-compatible backends like Graphite or Prometheus (via StatsD exporter).
- **OpenTelemetry to OTLP Collector**: OTel exports spans over OTLP/HTTP to a Collector, which then forwards to a trace backend (Tempo). (OTLP/gRPC is future work — §2.2.2.)
- **Grafana (red, unified UI)**: All three data streams converge in Grafana, enabling operators to correlate logs, metrics, and traces in a single dashboard.
**Phase 7 target state**: Beast Insight routes to `OTelCollector` (new `Collector` implementation) which exports via OTLP/HTTP to the same collector endpoint as traces. StatsD UDP path becomes a deprecated fallback (`[insight] server=statsd`). See [06-implementation-phases.md §6.8](./06-implementation-phases.md) and [Phase7_taskList.md](./Phase7_taskList.md) for details.
### 2.6.5 Correlation with PerfLog
Trace IDs can be correlated with existing PerfLog entries for comprehensive
debugging. The design is for `RPCHandler.cpp` to start an `rpc.command.<method>`
span alongside the existing PerfLog `rpcStart`/`rpcFinish`/`rpcError` calls,
extract the span's `trace_id` (when valid), and eventually stamp it onto the
PerfLog entry (a planned `setTraceId` hook) so logs and traces share a key. The
span status is set to OK on success or to error (recording the exception) on
failure.
---
_Previous: [Architecture Analysis](./01-architecture-analysis.md)_ | _Next: [Implementation Strategy](./03-implementation-strategy.md)_ | _Back to: [Overview](./OpenTelemetryPlan.md)_

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@@ -1,483 +0,0 @@
# Implementation Strategy
> **Parent Document**: [OpenTelemetryPlan.md](./OpenTelemetryPlan.md)
> **Related**: [Configuration Reference](./05-configuration-reference.md)
---
## 3.1 Directory Structure
The telemetry implementation follows xrpld's existing code organization pattern:
```
include/xrpl/
├── telemetry/
│ ├── Telemetry.h # Main telemetry interface (global singleton)
│ ├── TelemetryConfig.h # Configuration structures
│ ├── TraceContext.h # Context propagation utilities
│ ├── SpanGuard.h # RAII span management with factory methods + discard()
│ ├── DiscardFlag.h # Thread-local discard flag
│ └── SpanAttributes.h # Attribute helper functions
src/libxrpl/
├── telemetry/
│ ├── Telemetry.cpp # Implementation + FilteringSpanProcessor
│ ├── TelemetryConfig.cpp # Config parsing
│ ├── TraceContext.cpp # Context serialization
│ └── NullTelemetry.cpp # No-op implementation
```
---
## 3.2 Implementation Approach
<div align="center">
```mermaid
%%{init: {'flowchart': {'nodeSpacing': 20, 'rankSpacing': 30}}}%%
flowchart TB
subgraph phase1["Phase 1: Core"]
direction LR
sdk["SDK Integration"] ~~~ interface["Telemetry Interface"] ~~~ config["Configuration"]
end
subgraph phase2["Phase 2: RPC"]
direction LR
http["HTTP Context"] ~~~ rpc["RPC Handlers"]
end
subgraph phase3["Phase 3: P2P"]
direction LR
proto["Protobuf Context"] ~~~ tx["Transaction Relay"]
end
subgraph phase4["Phase 4: Consensus"]
direction LR
consensus["Consensus Rounds"] ~~~ proposals["Proposals"]
end
phase1 --> phase2 --> phase3 --> phase4
style phase1 fill:#1565c0,stroke:#0d47a1,color:#ffffff
style phase2 fill:#2e7d32,stroke:#1b5e20,color:#ffffff
style phase3 fill:#e65100,stroke:#bf360c,color:#ffffff
style phase4 fill:#c2185b,stroke:#880e4f,color:#ffffff
```
</div>
### Key Principles
1. **Minimal Intrusion**: Instrumentation should not alter existing control flow
2. **Zero-Cost When Disabled**: Use compile-time flags and no-op implementations
3. **Backward Compatibility**: Protocol Buffer extensions use high field numbers
4. **Graceful Degradation**: Tracing failures must not affect node operation
---
## 3.3 Performance Overhead Summary
> **OTLP** = OpenTelemetry Protocol
| Metric | Overhead | Notes |
| ------------- | ---------- | ------------------------------------------------ |
| CPU | 1-3% | Of per-transaction CPU cost (~200μs baseline) |
| Memory | ~10 MB | SDK statics + batch buffer + worker thread stack |
| Network | 10-50 KB/s | Compressed OTLP export to collector |
| Latency (p99) | <2% | With proper sampling configuration |
---
## 3.4 Detailed CPU Overhead Analysis
### 3.4.1 Per-Operation Costs
> **Note on hardware assumptions**: The costs below are based on the official OTel C++ SDK CI benchmarks
> (969 runs on GitHub Actions 2-core shared runners). On production server hardware (3+ GHz Xeon),
> expect costs at the **lower end** of each range (~30-50% improvement over CI hardware).
| Operation | Time (ns) | Frequency | Impact |
| --------------------- | --------- | ---------------------- | ---------- |
| Span creation | 500-1000 | Every traced operation | Low |
| Span end | 100-200 | Every traced operation | Low |
| SetAttribute (string) | 80-120 | 3-5 per span | Low |
| SetAttribute (int) | 40-60 | 2-3 per span | Negligible |
| AddEvent | 100-200 | 0-2 per span | Low |
| Context injection | 150-250 | Per outgoing message | Low |
| Context extraction | 100-180 | Per incoming message | Low |
| GetCurrent context | 10-20 | Thread-local access | Negligible |
**Source**: Span creation based on OTel C++ SDK `BM_SpanCreation` benchmark (AlwaysOnSampler +
SimpleSpanProcessor + InMemoryExporter), median ~1,000 ns on CI hardware. AddEvent includes
timestamp read + string copy + vector push + mutex acquisition. Context injection/extraction
confirmed by `BM_SpanCreationWithScope` benchmark delta (~160 ns).
### 3.4.2 Transaction Processing Overhead
<div align="center">
```mermaid
%%{init: {'pie': {'textPosition': 0.75}}}%%
pie showData
"tx.receive (1400ns)" : 1400
"tx.validate (1200ns)" : 1200
"tx.relay (1200ns)" : 1200
"Context inject (200ns)" : 200
```
**Transaction Tracing Overhead (~4.0μs total)**
</div>
**Overhead percentage**: 4.0 μs / 200 μs (avg tx processing) = **~2.0%**
> **Breakdown**: Each span (tx.receive, tx.validate, tx.relay) costs ~1,000 ns for creation plus
> ~200-400 ns for 3-5 attribute sets. Context injection is ~200 ns (confirmed by benchmarks).
> On production hardware, expect ~2.6 μs total (~1.3% overhead) due to faster span creation (~500-600 ns).
### 3.4.3 Consensus Round Overhead
| Operation | Count | Cost (ns) | Total |
| ---------------------- | ----- | --------- | ---------- |
| consensus.round span | 1 | ~1200 | ~1.2 μs |
| consensus.phase spans | 3 | ~1100 | ~3.3 μs |
| proposal.receive spans | ~20 | ~1100 | ~22 μs |
| proposal.send spans | ~3 | ~1100 | ~3.3 μs |
| Context operations | ~30 | ~200 | ~6 μs |
| **TOTAL** | | | **~36 μs** |
> **Why higher**: Each span costs ~1,000 ns creation + ~100-200 ns for 1-2 attributes, totaling ~1,100-1,200 ns.
> Context operations remain ~200 ns (confirmed by benchmarks). On production hardware, expect ~24 μs total.
**Overhead percentage**: 36 μs / 3s (typical round) = **~0.001%** (negligible)
### 3.4.4 RPC Request Overhead
| Operation | Cost (ns) |
| ---------------- | ------------ |
| rpc.request span | ~1200 |
| rpc.command span | ~1100 |
| Context extract | ~250 |
| Context inject | ~200 |
| **TOTAL** | **~2.75 μs** |
> **Why higher**: Each span costs ~1,000 ns creation + ~100-200 ns for attributes (command name,
> version, role). Context extract/inject costs are confirmed by OTel C++ benchmarks.
- Fast RPC (1ms): 2.75 μs / 1ms = **~0.275%**
- Slow RPC (100ms): 2.75 μs / 100ms = **~0.003%**
---
## 3.5 Memory Overhead Analysis
> **OTLP** = OpenTelemetry Protocol
### 3.5.1 Static Memory
| Component | Size | Allocated |
| ------------------------------------ | ----------- | ---------- |
| TracerProvider singleton | ~64 KB | At startup |
| BatchSpanProcessor (circular buffer) | ~16 KB | At startup |
| BatchSpanProcessor (worker thread) | ~8 MB | At startup |
| OTLP/HTTP exporter (client init) | ~64 KB | At startup |
| Propagator registry | ~8 KB | At startup |
| **Total static** | **~8.1 MB** | |
> **Why higher than earlier estimate**: The BatchSpanProcessor's circular buffer itself is only ~16 KB
> (2049 x 8-byte `AtomicUniquePtr` entries), but it spawns a dedicated worker thread whose default
> stack size on Linux is ~8 MB. The OTLP/HTTP exporter allocates a small client and TLS
> initialization buffer. The worker thread stack dominates the static footprint.
### 3.5.2 Dynamic Memory
| Component | Size per unit | Max units | Peak |
| -------------------- | -------------- | ---------- | --------------- |
| Active span | ~500-800 bytes | 1000 | ~500-800 KB |
| Queued span (export) | ~500 bytes | 2048 | ~1 MB |
| Attribute storage | ~80 bytes | 5 per span | Included |
| Context storage | ~64 bytes | Per thread | ~6.4 KB |
| **Total dynamic** | | | **~1.5-1.8 MB** |
> **Why active spans are larger**: An active `Span` object includes the wrapper (~88 bytes: shared_ptr,
> mutex, unique_ptr to Recordable) plus `SpanData` (~250 bytes: SpanContext, timestamps, name, status,
> empty containers) plus attribute storage (~200-500 bytes for 3-5 string attributes in a `std::map`).
> Source: `sdk/src/trace/span.h` and `sdk/include/opentelemetry/sdk/trace/span_data.h`.
> Queued spans release the wrapper, keeping only `SpanData` + attributes (~500 bytes).
### 3.5.3 Memory Growth Characteristics
```mermaid
---
config:
xyChart:
width: 700
height: 400
---
xychart-beta
title "Memory Usage vs Span Rate (bounded by queue limit)"
x-axis "Spans/second" [0, 200, 400, 600, 800, 1000]
y-axis "Memory (MB)" 0 --> 12
line [8.5, 9.2, 9.6, 9.9, 10.0, 10.0]
```
**Notes**:
- Memory increases with span rate but **plateaus at queue capacity** (default 2048 spans)
- Batch export prevents unbounded growth
- At queue limit, oldest spans are dropped (not blocked)
- Maximum memory is bounded: ~8.3 MB static (dominated by worker thread stack) + 2048 queued spans x ~500 bytes (~1 MB) + active spans (~0.8 MB) ≈ **~10 MB ceiling**
- The worker thread stack (~8 MB) is virtual memory; actual RSS depends on stack usage (typically much less)
> **Measured outcome**: A perf-iac comparison (telemetry compiled-in + enabled vs compiled-out,
> 9 nodes — validators and client-handlers — under sustained payment load) recorded **no measurable
> RSS increase over the telemetry-off baseline** (~15 GiB mean / ~1819 GiB peak on both sides),
> with no OOM, no swap, and no leak across the run. The ~10 MB ceiling above is therefore a
> provisioning safety margin (dominated by virtual thread-stack address space), not an expected
> resident-memory increase. Steady-state cost shows up as throughput (~34% at head sampling 1.0),
> not memory.
### 3.5.4 Performance Data Sources
The overhead estimates in Sections 3.3-3.5 are derived from the following sources:
| Source | What it covers | URL |
| ------------------------------------------------ | ----------------------------------------------------- | ------------------------------------------------------------------------------------------------------------------------------------------ |
| OTel C++ SDK CI benchmarks (969 runs) | Span creation, context activation, sampler overhead | [Benchmark Dashboard](https://open-telemetry.github.io/opentelemetry-cpp/benchmarks/) |
| `api/test/trace/span_benchmark.cc` | API-level span creation (~22 ns no-op) | [Source](https://github.com/open-telemetry/opentelemetry-cpp/blob/main/api/test/trace/span_benchmark.cc) |
| `sdk/test/trace/sampler_benchmark.cc` | SDK span creation with samplers (~1,000 ns AlwaysOn) | [Source](https://github.com/open-telemetry/opentelemetry-cpp/blob/main/sdk/test/trace/sampler_benchmark.cc) |
| `sdk/include/.../span_data.h` | SpanData memory layout (~250 bytes base) | [Source](https://github.com/open-telemetry/opentelemetry-cpp/blob/main/sdk/include/opentelemetry/sdk/trace/span_data.h) |
| `sdk/src/trace/span.h` | Span wrapper memory layout (~88 bytes) | [Source](https://github.com/open-telemetry/opentelemetry-cpp/blob/main/sdk/src/trace/span.h) |
| `sdk/include/.../batch_span_processor_options.h` | Default queue size (2048), batch size (512) | [Source](https://github.com/open-telemetry/opentelemetry-cpp/blob/main/sdk/include/opentelemetry/sdk/trace/batch_span_processor_options.h) |
| `sdk/include/.../circular_buffer.h` | CircularBuffer implementation (AtomicUniquePtr array) | [Source](https://github.com/open-telemetry/opentelemetry-cpp/blob/main/sdk/include/opentelemetry/sdk/common/circular_buffer.h) |
| OTLP proto definition | Serialized span size estimation | [Proto](https://github.com/open-telemetry/opentelemetry-proto/blob/main/opentelemetry/proto/trace/v1/trace.proto) |
---
## 3.6 Network Overhead Analysis
### 3.6.1 Export Bandwidth
> **Bytes per span**: Estimates use ~500 bytes/span (conservative upper bound). OTLP protobuf analysis
> shows a typical span with 3-5 string attributes serializes to ~200-300 bytes raw; with gzip
> compression (~60-70% of raw) and batching (amortized headers), ~350 bytes/span is more realistic.
> The table uses the conservative estimate for capacity planning.
| Sampling Rate | Spans/sec | Bandwidth | Notes |
| ------------- | --------- | --------- | ---------------- |
| 100% | ~500 | ~250 KB/s | Development only |
| 10% | ~50 | ~25 KB/s | Staging |
| 1% | ~5 | ~2.5 KB/s | Production |
| Error-only | ~1 | ~0.5 KB/s | Minimal overhead |
### 3.6.2 Trace Context Propagation
| Message Type | Context Size | Messages/sec | Overhead |
| ---------------------- | ------------ | ------------ | ----------- |
| TMTransaction | 25 bytes | ~100 | ~2.5 KB/s |
| TMProposeSet | 25 bytes | ~10 | ~250 B/s |
| TMValidation | 25 bytes | ~50 | ~1.25 KB/s |
| **Total P2P overhead** | | | **~4 KB/s** |
---
## 3.7 Optimization Strategies
### 3.7.1 Sampling Strategies
#### Tail Sampling
```mermaid
flowchart TD
trace["New Trace"]
trace --> errors{"Is Error?"}
errors -->|Yes| sample["SAMPLE"]
errors -->|No| consensus{"Is Consensus?"}
consensus -->|Yes| sample
consensus -->|No| slow{"Is Slow?"}
slow -->|Yes| sample
slow -->|No| prob{"Random < 10%?"}
prob -->|Yes| sample
prob -->|No| drop["DROP"]
style sample fill:#4caf50,stroke:#388e3c,color:#fff
style drop fill:#f44336,stroke:#c62828,color:#fff
```
### 3.7.2 Batch Tuning Recommendations
| Environment | Batch Size | Batch Delay | Max Queue |
| ------------------ | ---------- | ----------- | --------- |
| Low-latency | 128 | 1000ms | 512 |
| High-throughput | 1024 | 10000ms | 8192 |
| Memory-constrained | 256 | 2000ms | 512 |
### 3.7.3 Conditional Instrumentation
Instrumentation is gated on two levels. A compile-time feature flag (`XRPL_ENABLE_TELEMETRY`) reduces the trace macros to no-ops when telemetry is built out, so disabled builds carry zero cost. At runtime, per-component guards (e.g. `shouldTracePeer()`) skip span creation for components whose tracing is turned off, incurring no overhead beyond a single boolean check.
---
## 3.8 Links to Detailed Documentation
- **[Configuration Reference](./05-configuration-reference.md)**: Configuration options and collector setup
- **[Implementation Phases](./06-implementation-phases.md)**: Detailed timeline and milestones
---
## 3.9 Code Intrusiveness Assessment
> **TxQ** = Transaction Queue
This section provides a detailed assessment of how intrusive the OpenTelemetry integration is to the existing xrpld codebase.
### 3.9.1 Files Modified Summary
| Component | Files Modified | Architectural Impact |
| --------------------- | -------------- | -------------------- |
| **Core Telemetry** | 10 new files | None (new module) |
| **Application Init** | 2 files | Minimal |
| **RPC Layer** | 3 files | Minimal |
| **Transaction Relay** | 4 files | Low |
| **Consensus** | 3 files | Low-Medium |
| **Protocol Buffers** | 1 file | Low |
| **CMake/Build** | 3 files | Minimal |
| **PathFinding** | 2 | Minimal |
| **TxQ/Fee** | 2 | Minimal |
| **Validator/Amend** | 3 | Minimal |
| **Total** | **~33 files** | **Low** |
### 3.9.2 Detailed File Impact
```mermaid
pie title Code Changes by Component
"New Telemetry Module" : 800
"Transaction Relay" : 160
"Consensus" : 130
"RPC Layer" : 100
"PathFinding" : 80
"TxQ/Fee" : 60
"Validator/Amendment" : 40
"Application Init" : 35
"Protocol Buffers" : 25
"Build System" : 60
```
#### New Files (No Impact on Existing Code)
| File | Purpose |
| ------------------------------------------- | ------------------------- |
| `include/xrpl/telemetry/Telemetry.h` | Main interface |
| `include/xrpl/telemetry/TelemetryConfig.h` | Configuration structures |
| `include/xrpl/telemetry/TraceContext.h` | Context propagation |
| `include/xrpl/telemetry/SpanGuard.h` | RAII wrapper |
| `include/xrpl/telemetry/DiscardFlag.h` | Thread-local discard flag |
| `include/xrpl/telemetry/SpanAttributes.h` | Attribute helpers |
| `src/libxrpl/telemetry/Telemetry.cpp` | Implementation |
| `src/libxrpl/telemetry/TelemetryConfig.cpp` | Config parsing |
| `src/libxrpl/telemetry/TraceContext.cpp` | Context serialization |
| `src/libxrpl/telemetry/NullTelemetry.cpp` | No-op implementation |
#### Modified Files (Existing Xrpld Code)
| File | Risk Level |
| ------------------------------------------------- | ---------- |
| `src/xrpld/app/main/Application.cpp` | Low |
| `include/xrpl/core/ServiceRegistry.h` | Low |
| `src/xrpld/rpc/detail/ServerHandler.cpp` | Low |
| `src/xrpld/rpc/handlers/*.cpp` | Low |
| `src/xrpld/overlay/detail/PeerImp.cpp` | Medium |
| `src/xrpld/overlay/detail/OverlayImpl.cpp` | Medium |
| `src/xrpld/app/consensus/RCLConsensus.cpp` | Medium |
| `src/xrpld/app/consensus/RCLConsensusAdaptor.cpp` | Medium |
| `src/xrpld/core/JobQueue.cpp` | Low |
| `src/xrpld/app/paths/PathRequest.cpp` | Low |
| `src/xrpld/app/paths/Pathfinder.cpp` | Low |
| `src/xrpld/app/misc/TxQ.cpp` | Low |
| `src/xrpld/app/main/LoadManager.cpp` | Low |
| `src/xrpld/app/misc/ValidatorList.cpp` | Low |
| `src/xrpld/app/misc/AmendmentTable.cpp` | Low |
| `src/xrpld/app/misc/Manifest.cpp` | Low |
| `src/xrpld/shamap/SHAMap.cpp` | Low |
| `src/xrpld/overlay/detail/ripple.proto` | Low |
| `CMakeLists.txt` | Low |
| `cmake/FindOpenTelemetry.cmake` | None (new) |
### 3.9.3 Risk Assessment by Component
<div align="center">
**Do First** ↖ ↗ **Plan Carefully**
```mermaid
quadrantChart
title Code Intrusiveness Risk Matrix
x-axis Low Risk --> High Risk
y-axis Low Value --> High Value
RPC Tracing: [0.2, 0.55]
Transaction Relay: [0.55, 0.85]
Consensus Tracing: [0.75, 0.92]
Peer Message Tracing: [0.85, 0.35]
JobQueue Context: [0.3, 0.42]
Ledger Acquisition: [0.48, 0.65]
PathFinding: [0.38, 0.72]
TxQ and Fees: [0.25, 0.62]
Validator Mgmt: [0.15, 0.35]
```
**Optional** ↙ ↘ **Avoid**
</div>
#### Risk Level Definitions
| Risk Level | Definition | Mitigation |
| ---------- | ---------------------------------------------------------------- | ---------------------------------- |
| **Low** | Additive changes only; no modification to existing logic | Standard code review |
| **Medium** | Minor modifications to existing functions; clear boundaries | Comprehensive unit tests |
| **High** | Changes to core logic or data structures; potential side effects | Integration tests + staged rollout |
### 3.9.4 Architectural Impact Assessment
| Aspect | Impact | Justification |
| -------------------- | ------- | -------------------------------------------------------------------------------- |
| **Data Flow** | Minimal | Read-only instrumentation; no modification to consensus or transaction data flow |
| **Threading Model** | Minimal | Context propagation uses thread-local storage (standard OTel pattern) |
| **Memory Model** | Low | Bounded queues prevent unbounded growth; RAII ensures cleanup |
| **Network Protocol** | Low | Optional fields in protobuf (high field numbers); backward compatible |
| **Configuration** | None | New config section; existing configs unaffected |
| **Build System** | Low | Optional CMake flag; builds work without OpenTelemetry |
| **Dependencies** | Low | OpenTelemetry SDK is optional; null implementation when disabled |
### 3.9.5 Backward Compatibility
| Compatibility | Status | Notes |
| --------------- | ------- | ----------------------------------------------------- |
| **Config File** | ✅ Full | New `[telemetry]` section is optional |
| **Protocol** | ✅ Full | Optional protobuf fields with high field numbers |
| **Build** | ✅ Full | `XRPL_ENABLE_TELEMETRY=OFF` produces identical binary |
| **Runtime** | ✅ Full | `enabled=0` produces zero overhead |
| **API** | ✅ Full | No changes to public RPC or P2P APIs |
### 3.9.6 Rollback Strategy
If issues are discovered after deployment:
1. **Immediate**: Set `enabled=0` in config and restart (zero code change)
2. **Quick**: Rebuild with `XRPL_ENABLE_TELEMETRY=OFF`
3. **Complete**: Revert telemetry commits (clean separation makes this easy)
### 3.9.7 Code Change Examples
**Minimal RPC Instrumentation (Low Intrusiveness):** Instrumenting an RPC handler adds roughly 3-4 lines: one macro to start the span and one or two `setAttribute` calls (command name, status). The span ends automatically via RAII, so the existing control flow — process the request, send the result — is untouched.
**Consensus Instrumentation (Medium Intrusiveness):** Consensus is slightly more intrusive because child spans in later phase transitions need the round's context. Beyond the span-start and attribute macros, this requires storing the active context in a new member variable (`currentRoundContext_`) at round start. The existing round logic itself remains unchanged.
---
_Previous: [Design Decisions](./02-design-decisions.md)_ | _Next: [Configuration Reference](./05-configuration-reference.md)_ | _Back to: [Overview](./OpenTelemetryPlan.md)_

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@@ -1,275 +0,0 @@
# Configuration Reference
> **Parent Document**: [OpenTelemetryPlan.md](./OpenTelemetryPlan.md)
> **Related**: [Implementation Phases](./06-implementation-phases.md)
---
## 5.1 xrpld Configuration
> **OTLP** = OpenTelemetry Protocol | **TxQ** = Transaction Queue
### 5.1.1 Configuration File Section
The authoritative `[telemetry]` example lives in `cfg/xrpld-example.cfg`. Telemetry is disabled by default (`enabled=0`); enabling it turns on distributed tracing for transaction flow, consensus, and RPC calls, with traces exported to an OpenTelemetry Collector over OTLP. Head sampling is intentionally fixed at 1.0 (sample everything) and is not configurable — per-node head-sampling would produce broken/partial distributed traces, so volume reduction is delegated to the collector's tail sampling (see Section 7.4.2). The full option reference follows.
### 5.1.2 Configuration Options Summary
| Option | Type | Default | Description |
| -------------------------- | ------ | --------------------------------- | ---------------------------------------------------------------------------------------------------------- |
| `enabled` | bool | `false` | Enable/disable telemetry |
| `endpoint` | string | `http://localhost:4318/v1/traces` | OTLP/HTTP collector endpoint |
| `use_tls` | bool | `false` | Enable TLS for exporter connection |
| `tls_ca_cert` | string | `""` | Path to CA certificate file |
| `tls_client_cert` | string | `""` | Path to node's client certificate (PEM) for mutual TLS; requires `use_tls=1`; empty = one-way TLS |
| `tls_client_key` | string | `""` | Path to private key (PEM) for `tls_client_cert`; requires `use_tls=1`; required when the cert is set |
| `batch_size` | uint | `512` | Spans per export batch |
| `batch_delay_ms` | uint | `5000` | Max delay before sending batch (ms) |
| `max_queue_size` | uint | `2048` | Maximum queued spans |
| `trace_transactions` | bool | `true` | Enable transaction tracing |
| `trace_consensus` | bool | `true` | Enable consensus tracing |
| `trace_rpc` | bool | `true` | Enable RPC tracing |
| `trace_peer` | bool | `true` | Enable peer message tracing (high volume) |
| `trace_ledger` | bool | `true` | Enable ledger tracing |
| `tx_trace_strategy` | string | `"deterministic"` | TX trace ID strategy: `"deterministic"` (trace_id = txHash[0:16]) or `"attribute"` (random) |
| `consensus_trace_strategy` | string | `"deterministic"` | Consensus trace ID strategy: `"deterministic"` (trace_id = prevLedgerHash[0:16]) or `"attribute"` (random) |
| `service_name` | string | `"xrpld"` | Service name (`service.name`) for traces and metrics |
| `service_instance_id` | string | `<node_pubkey>` | Instance identifier |
**Planned (not yet implemented)**: the following options appear in the design
documents but are not parsed by `TelemetryConfig.cpp` in Phase 1b and later
phases. They will be added as the corresponding subsystems are instrumented:
| Option | Planned Phase | Purpose |
| -------------------------- | ------------- | ----------------------------------------------------------------------- |
| `exporter` | Future | Select between OTLP/HTTP and OTLP/gRPC |
| `trace_pathfind` | Phase 2 | Path computation tracing toggle |
| `trace_txq` | Phase 3 | Transaction queue tracing toggle |
| `trace_validator` | Future | Validator list / manifest update tracing |
| `trace_amendment` | Future | Amendment voting tracing |
| `consensus_trace_strategy` | Phase 4 | Trace ID strategy for consensus rounds (`deterministic` \| `attribute`) |
---
## 5.2 Configuration Parser
> **TxQ** = Transaction Queue
The parser `setupTelemetry()` in `src/libxrpl/telemetry/TelemetryConfig.cpp` reads the `[telemetry]` `Section` and populates a `Telemetry::Setup` struct, applying the defaults listed in Section 5.1.2 via `section.value_or(...)`. It derives `serviceInstanceId` from the node public key when not overridden, selects the exporter endpoint default by exporter type, and leaves the sampling ratio at its fixed 1.0 default (not read from config — see Section 7.4.2).
---
## 5.3 Application Integration
### 5.3.1 ApplicationImp Changes
> **Deferred identity**: The node public key (`nodeIdentity_`) is not
> available during `ApplicationImp`'s member initializer list — it is
> resolved later in `setup()`. The `Telemetry` object is therefore
> constructed with an empty `serviceInstanceId` and patched via
> `setServiceInstanceId()` once `setup()` has called `getNodeIdentity()`.
`ApplicationImp` (in `src/xrpld/app/main/Application.cpp`) owns a `std::unique_ptr<telemetry::Telemetry> telemetry_`. It is built in the member initializer list via `makeTelemetry(setupTelemetry(...))` with an empty `serviceInstanceId`, then patched in `setup()` by calling `setServiceInstanceId()` with the Base58 node public key (unless the user supplied a custom `service_instance_id`). `start()` and `run()` forward to `telemetry_->start()` / `telemetry_->stop()`, and `getTelemetry()` returns the owned instance.
### 5.3.2 ServiceRegistry Interface Addition
`include/xrpl/core/ServiceRegistry.h` gains a pure-virtual `telemetry::Telemetry& getTelemetry()` (with a forward declaration of `telemetry::Telemetry`), giving every component a uniform accessor for the tracing subsystem.
> **Note:** `Application` extends `ServiceRegistry`, so `getTelemetry()` is
> available on both. Components that hold a `ServiceRegistry&` (e.g.
> `NetworkOPsImp`) call `registry_.get().getTelemetry()`. Components that
> still hold an `Application&` (e.g. `ServerHandler`, `PeerImp`,
> `RCLConsensusAdaptor`) call `app_.getTelemetry()` directly.
---
## 5.4 CMake Integration
> **OTLP** = OpenTelemetry Protocol
### 5.4.1 Find OpenTelemetry Module
A `cmake/FindOpenTelemetry.cmake` module locates the OpenTelemetry C++ SDK. It first tries `find_package(opentelemetry-cpp CONFIG)`, aliasing the imported targets `OpenTelemetry::api`, `OpenTelemetry::sdk`, and `OpenTelemetry::otlp_grpc_exporter`, and falls back to `pkg-config` when no CMake config package is present.
### 5.4.2 CMakeLists.txt Changes
The top-level `CMakeLists.txt` adds an `XRPL_ENABLE_TELEMETRY` option (default `OFF`). When enabled, it runs `find_package(OpenTelemetry REQUIRED)`, defines the `XRPL_ENABLE_TELEMETRY` compile flag, and builds the `xrpl_telemetry` library from the real telemetry sources linked against the OpenTelemetry targets; when disabled, it builds the same target from a no-op `NullTelemetry.cpp` so call sites compile unchanged.
---
## 5.5 OpenTelemetry Collector Configuration
> **OTLP** = OpenTelemetry Protocol | **APM** = Application Performance Monitoring
> **Production hardening**: The configurations in this section are starting points. For production deployments where xrpld ships telemetry across a network to a centrally-hosted collector, see [Securing the OTel Pipeline](./secure-OTel.md) for the required mTLS receiver config, NetworkPolicy, and peer trace-context validation.
The authoritative collector config lives in the repo at `docker/telemetry/otel-collector-config.yaml` (with Tempo backend config in `docker/telemetry/tempo.yaml`). The sections below summarize the development and production shapes of that pipeline.
### 5.5.1 Development Configuration
The development collector enables an OTLP receiver on both gRPC (`0.0.0.0:4317`) and HTTP (`0.0.0.0:4318`), a single `batch` processor (1s timeout, batch size 100), and two exporters: a `logging` exporter for console debugging and `otlp/tempo` (insecure) for trace visualization. The single `traces` pipeline wires receiver → batch → both exporters.
### 5.5.2 Production Configuration
The production collector adds TLS on the OTLP gRPC receiver and a richer processor chain: a `memory_limiter` (OOM guard), `batch` (5s timeout, size 512), `tail_sampling`, and an `attributes` processor that hashes sensitive fields (e.g. `tx_account`) and stamps `deployment.environment`. Tail sampling keeps all `ERROR` traces, slow consensus rounds (>5s) and slow RPC requests (>1s), and probabilistically samples the remainder at 10%. Exporters target Grafana Tempo (TLS) and Elastic APM; `health_check` and `zpages` extensions are enabled for operability.
---
## 5.6 Docker Compose Development Environment
> **OTLP** = OpenTelemetry Protocol
The authoritative development stack lives in the repo at `docker/telemetry/docker-compose.yml`. It brings up four services on a shared `xrpld-telemetry` network: an `otel-collector` (otel/opentelemetry-collector-contrib) exposing OTLP gRPC `4317`, OTLP HTTP `4318`, and health check `13133`; `tempo` for trace storage/visualization; `grafana` with provisioned datasources and dashboards (anonymous admin enabled); and an optional `prometheus` for metric correlation.
---
## 5.7 Configuration Architecture
> **OTLP** = OpenTelemetry Protocol
```mermaid
flowchart TB
subgraph config["Configuration Sources"]
cfgFile["xrpld.cfg<br/>[telemetry] section"]
cmake["CMake<br/>XRPL_ENABLE_TELEMETRY"]
end
subgraph init["Initialization"]
parse["setupTelemetry()"]
factory["makeTelemetry()"]
end
subgraph runtime["Runtime Components"]
tracer["TracerProvider"]
exporter["OTLP Exporter"]
processor["BatchProcessor"]
end
subgraph collector["Collector Pipeline"]
recv["Receivers"]
proc["Processors"]
exp["Exporters"]
end
cfgFile --> parse
cmake -->|"compile flag"| parse
parse --> factory
factory --> tracer
tracer --> processor
processor --> exporter
exporter -->|"OTLP"| recv
recv --> proc
proc --> exp
style config fill:#e3f2fd,stroke:#1976d2
style runtime fill:#e8f5e9,stroke:#388e3c
style collector fill:#fff3e0,stroke:#ff9800
```
**Reading the diagram:**
- **Configuration Sources**: `xrpld.cfg` provides runtime settings (endpoint, per-component trace toggles) while the CMake flag controls whether telemetry is compiled in at all. Head sampling is fixed at 1.0 and is not a config option; volume reduction happens via tail sampling in the collector.
- **Initialization**: `setupTelemetry()` parses config values, then `makeTelemetry()` constructs the provider, processor, and exporter objects.
- **Runtime Components**: The `TracerProvider` creates spans, the `BatchProcessor` buffers them, and the `OTLP Exporter` serializes and sends them over the wire.
- **OTLP arrow to Collector**: Trace data leaves the xrpld process via OTLP/HTTP and enters the external Collector pipeline. (OTLP/gRPC is future work — see design decisions §2.2.2.)
- **Collector Pipeline**: `Receivers` ingest OTLP data, `Processors` apply sampling/filtering/enrichment, and `Exporters` forward traces to storage backends (Tempo, etc.).
---
## 5.8 Grafana Integration
> **APM** = Application Performance Monitoring
Step-by-step instructions for integrating xrpld traces with Grafana.
### 5.8.1 Data Source Configuration
#### Tempo (Recommended)
A Tempo datasource (`grafana/provisioning/datasources/tempo.yaml`, provisioned from `docker/telemetry/grafana/`) points at `http://tempo:3200` and enables `tracesToLogs` (linking to Loki on `service.name`/`tx_hash` and mapping `trace_id``traceID`), `serviceMap` against Prometheus, the node graph, and Loki search.
#### Elastic APM
Alternatively, an Elasticsearch datasource (`grafana/provisioning/datasources/elastic-apm.yaml`) of type `elasticsearch` points at `http://elasticsearch:9200` against the `apm-*` index, using `@timestamp` as the time field and mapping the log message/level fields.
### 5.8.2 Dashboard Provisioning
A dashboard provider (`grafana/provisioning/dashboards/dashboards.yaml`) loads the `xrpld` dashboard folder from disk (`/var/lib/grafana/dashboards/rippled`), polling for changes every 30s with deletion disabled.
### 5.8.3 Example Dashboard: RPC Performance
An example `xrpld RPC Performance` dashboard (uid `xrpld-rpc-performance`) sourced from Tempo via TraceQL provides four panels: RPC latency by command (heatmap), RPC error rate by command (timeseries), the top 10 slowest RPC commands by average duration (table), and a recent-traces table.
### 5.8.4 Example Dashboard: Transaction Tracing
An example `xrpld Transaction Tracing` dashboard (uid `xrpld-tx-tracing`) over Tempo provides three panels: transaction throughput (`tx.receive` rate, stat), cross-node relay count (average `span.relay_count` on `tx.relay`, timeseries), and a table of transaction validation errors (`tx.validate` with `status.code=error`).
### 5.8.5 TraceQL Query Examples
Common queries for xrpld traces:
```
# Find all traces for a specific transaction hash
{resource.service.name="xrpld" && span.tx_hash="ABC123..."}
# Find slow RPC commands (>100ms)
{resource.service.name="xrpld" && name=~"rpc.command.*"} | duration > 100ms
# Find consensus rounds taking >5 seconds
{resource.service.name="xrpld" && name="consensus.round"} | duration > 5s
# Find failed transactions with error details
{resource.service.name="xrpld" && name="tx.validate" && status.code=error}
# Find transactions relayed to many peers
{resource.service.name="xrpld" && name="tx.relay"} | span.relay_count > 10
# Compare latency across nodes
{resource.service.name="xrpld" && name="rpc.command.account_info"} | avg(duration) by (resource.service.instance.id)
```
### 5.8.6 Correlation with PerfLog
To correlate OpenTelemetry traces with existing PerfLog data:
**Step 1: Configure Loki to ingest PerfLog**
Configure a Promtail scrape job (`promtail-config.yaml`) that tails `/var/log/rippled/perf*.log`, parses each JSON line, and promotes `trace_id`, `ledger_seq`, and `tx_hash` to Loki labels.
**Step 2: Add trace_id to PerfLog entries**
Modify PerfLog so its JSON output includes a `trace_id` field whenever a valid span is active: fetch the current span from the OpenTelemetry runtime context, and if its context is valid, render the trace ID as a 32-character lowercase hex string into the log entry.
**Step 3: Configure Grafana trace-to-logs link**
In the Tempo datasource, set the `tracesToLogs` derived field to link to Loki on the `trace_id` and `tx_hash` tags, with `filterByTraceID: true`.
### 5.8.7 Correlation with Insight/OTel System Metrics
To correlate traces with Beast Insight system metrics:
**Step 1: Export Insight metrics to Prometheus**
Beast Insight metrics are exported natively via OTLP to the OTel Collector,
which exposes them on the Prometheus endpoint alongside spanmetrics. Configure
the `[insight]` section of `xrpld.cfg` with `server=otel`,
`endpoint=http://localhost:4318/v1/metrics`, and `prefix=xrpld`; no separate
StatsD exporter or Prometheus scrape job is needed when using `server=otel`.
**Step 2: Add exemplars to metrics**
The OpenTelemetry SDK automatically adds exemplars (trace IDs) to metrics when using the Prometheus exporter, linking metric spikes to specific traces.
**Step 3: Configure Grafana metric-to-trace link**
In the Prometheus datasource, set `exemplarTraceIdDestinations` to map the `trace_id` exemplar to the Tempo datasource.
**Step 4: Dashboard panel with exemplars**
Add a timeseries panel over Prometheus (e.g. `histogram_quantile(0.99, rate(xrpld_rpc_duration_seconds_bucket[5m]))`) with `exemplar: true` enabled.
This allows clicking on metric data points to jump directly to the related trace.
---
_Previous: [Implementation Strategy](./03-implementation-strategy.md)_ | _Next: [Implementation Phases](./06-implementation-phases.md)_ | _Back to: [Overview](./OpenTelemetryPlan.md)_

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# Observability Backend Recommendations
> **Parent Document**: [OpenTelemetryPlan.md](./OpenTelemetryPlan.md)
> **Related**: [Implementation Phases](./06-implementation-phases.md) | [Appendix](./08-appendix.md)
---
## 7.1 Development/Testing Backends
> **OTLP** = OpenTelemetry Protocol
| Backend | Pros | Cons | Use Case |
| ---------- | ----------------------------------- | ---------------------- | ------------------- |
| **Tempo** | Cost-effective, Grafana integration | Requires Grafana stack | Local dev, CI, Prod |
| **Zipkin** | Simple, lightweight | Basic features | Quick prototyping |
### Quick Start with Tempo
```bash
# Start Tempo with OTLP support
docker run -d --name tempo \
-p 3200:3200 \
-p 4317:4317 \
-p 4318:4318 \
grafana/tempo:2.6.1
```
---
## 7.2 Production Backends
> **APM** = Application Performance Monitoring
| Backend | Pros | Cons | Use Case |
| ----------------- | ----------------------------------------- | ---------------------- | --------------------------- |
| **Grafana Tempo** | Cost-effective, Grafana integration | Requires Grafana stack | Most production deployments |
| **Elastic APM** | Full observability stack, log correlation | Resource intensive | Existing Elastic users |
| **Honeycomb** | Excellent query, high cardinality | SaaS cost | Deep debugging needs |
| **Datadog APM** | Full platform, easy setup | SaaS cost | Enterprise with budget |
### Backend Selection Flowchart
```mermaid
flowchart TD
start[Select Backend] --> budget{Budget<br/>Constraints?}
budget -->|Yes| oss[Open Source]
budget -->|No| saas{Prefer<br/>SaaS?}
oss --> existing{Existing<br/>Stack?}
existing -->|Grafana| tempo[Grafana Tempo]
existing -->|Elastic| elastic[Elastic APM]
existing -->|None| tempo
saas -->|Yes| enterprise{Enterprise<br/>Support?}
saas -->|No| oss
enterprise -->|Yes| datadog[Datadog APM]
enterprise -->|No| honeycomb[Honeycomb]
tempo --> final[Configure Collector]
elastic --> final
honeycomb --> final
datadog --> final
style start fill:#0f172a,stroke:#020617,color:#fff
style budget fill:#334155,stroke:#1e293b,color:#fff
style oss fill:#1e293b,stroke:#0f172a,color:#fff
style existing fill:#334155,stroke:#1e293b,color:#fff
style saas fill:#334155,stroke:#1e293b,color:#fff
style enterprise fill:#334155,stroke:#1e293b,color:#fff
style final fill:#0f172a,stroke:#020617,color:#fff
style tempo fill:#1b5e20,stroke:#0d3d14,color:#fff
style elastic fill:#bf360c,stroke:#8c2809,color:#fff
style honeycomb fill:#0d47a1,stroke:#082f6a,color:#fff
style datadog fill:#4a148c,stroke:#2e0d57,color:#fff
```
**Reading the diagram:**
- **Budget Constraints? (Yes)**: Leads to open-source options. If you already run Grafana or Elastic, pick the matching backend; otherwise default to Grafana Tempo.
- **Budget Constraints? (No) → Prefer SaaS?**: If you want a managed service, choose between Datadog (enterprise support) and Honeycomb (developer-focused). If not, fall back to open-source.
- **Terminal nodes (Tempo / Elastic / Honeycomb / Datadog)**: Each represents a concrete backend choice, all of which feed into the same final step.
- **Configure Collector**: Regardless of backend, you always finish by configuring the OTel Collector to export to your chosen destination.
---
## 7.3 Recommended Production Architecture
> **OTLP** = OpenTelemetry Protocol | **APM** = Application Performance Monitoring | **HA** = High Availability
```mermaid
flowchart TB
subgraph validators["Validator Nodes"]
v1[xrpld<br/>Validator 1]
v2[xrpld<br/>Validator 2]
end
subgraph stock["Stock Nodes"]
s1[xrpld<br/>Stock 1]
s2[xrpld<br/>Stock 2]
end
subgraph collector["OTel Collector Cluster"]
c1[Collector<br/>DC1]
c2[Collector<br/>DC2]
end
subgraph backends["Storage Backends"]
tempo[(Grafana<br/>Tempo)]
elastic[(Elastic<br/>APM)]
archive[(S3/GCS<br/>Archive)]
end
subgraph ui["Visualization"]
grafana[Grafana<br/>Dashboards]
end
v1 -->|OTLP| c1
v2 -->|OTLP| c1
s1 -->|OTLP| c2
s2 -->|OTLP| c2
c1 --> tempo
c1 --> elastic
c2 --> tempo
c2 --> archive
tempo --> grafana
elastic --> grafana
%% Note: simplified single-collector-per-DC topology shown for clarity
style validators fill:#b71c1c,stroke:#7f1d1d,color:#ffffff
style stock fill:#0d47a1,stroke:#082f6a,color:#ffffff
style collector fill:#bf360c,stroke:#8c2809,color:#ffffff
style backends fill:#1b5e20,stroke:#0d3d14,color:#ffffff
style ui fill:#4a148c,stroke:#2e0d57,color:#ffffff
```
**Reading the diagram:**
- **Validator / Stock Nodes**: All xrpld nodes emit trace data via OTLP. Validators and stock nodes are grouped separately because they may reside in different network zones.
- **Collector Cluster (DC1, DC2)**: Regional collectors receive OTLP from nodes in their datacenter, apply processing (sampling, enrichment), and fan out to multiple backends. Enrichment includes deployment-tier tagging: each collector stamps `deployment.environment` and (as a fallback) `xrpl.network.type` so one Grafana stack can filter data from many collectors by tier.
- **Storage Backends**: Tempo and Elastic provide queryable trace storage; S3/GCS Archive provides long-term cold storage for compliance or post-incident analysis.
- **Grafana Dashboards**: The single visualization layer that queries both Tempo and Elastic, giving operators a unified view of all traces.
- **Data flow direction**: Nodes → Collectors → Storage → Grafana. Each arrow represents a network hop; minimizing collector-to-backend hops reduces latency.
> **Note**: Production deployments should use multiple collector instances behind a load balancer for high availability. The diagram shows a simplified single-collector topology for clarity.
---
## 7.4 Architecture Considerations
### 7.4.1 Collector Placement
| Strategy | Description | Pros | Cons |
| ------------- | -------------------- | ------------------------ | ----------------------- |
| **Sidecar** | Collector per node | Isolation, simple config | Resource overhead |
| **DaemonSet** | Collector per host | Shared resources | Complexity |
| **Gateway** | Central collector(s) | Centralized processing | Single point of failure |
**Recommendation**: Use **Gateway** pattern with regional collectors for xrpld networks:
- One collector cluster per datacenter/region
- Tail-based sampling at collector level
- Multiple export destinations for redundancy
### 7.4.2 Sampling Strategy
```mermaid
flowchart LR
subgraph head["Head Sampling (Node)"]
hs[Node-level head sampling<br/>fixed at 100%<br/>not configurable]
end
subgraph tail["Tail Sampling (Collector)"]
ts1[Keep all errors]
ts2[Keep slow >5s]
ts3[Keep 10% rest]
end
head --> tail
ts1 --> final[Final Traces]
ts2 --> final
ts3 --> final
style head fill:#0d47a1,stroke:#082f6a,color:#fff
style tail fill:#1b5e20,stroke:#0d3d14,color:#fff
style hs fill:#0d47a1,stroke:#082f6a,color:#fff
style ts1 fill:#1b5e20,stroke:#0d3d14,color:#fff
style ts2 fill:#1b5e20,stroke:#0d3d14,color:#fff
style ts3 fill:#1b5e20,stroke:#0d3d14,color:#fff
style final fill:#bf360c,stroke:#8c2809,color:#fff
```
**Reading the diagram:**
- **Head Sampling (Node)**: xrpld pins head sampling at 100% (sample everything) and does not expose a configurable ratio. This is intentional: a per-node ratio would let different nodes make divergent keep/drop decisions for the same distributed trace, producing broken/partial traces. xrpld uses a `ParentBased` sampler so spans inheriting a remote parent honor the upstream decision. Volume reduction is delegated to the collector's tail sampling.
- **Tail Sampling (Collector)**: The second filter -- the collector inspects completed traces and applies rules: keep all errors, keep anything slower than 5 seconds, and keep 10% of the remainder.
- **Arrow head → tail**: All head-sampled traces flow to the collector, where tail sampling further reduces volume while preserving the most valuable data.
- **Final Traces**: The output after both sampling stages; this is what gets stored and queried. The two-stage approach balances cost with debuggability.
### 7.4.3 Data Retention
| Environment | Hot Storage | Warm Storage | Cold Archive |
| ----------- | ----------- | ------------ | ------------ |
| Development | 24 hours | N/A | N/A |
| Staging | 7 days | N/A | N/A |
| Production | 7 days | 30 days | many years |
---
## 7.5 Integration Checklist
- [ ] Choose primary backend (Tempo recommended for cost/features)
- [ ] Deploy collector cluster with high availability
- [ ] Configure tail-based sampling for error/latency traces
- [ ] Set up Grafana dashboards for trace visualization
- [ ] Configure alerts for trace anomalies
- [ ] Establish data retention policies
- [ ] Test trace correlation with logs and metrics
---
## 7.6 Grafana Dashboard Examples
Pre-built dashboards for xrpld observability.
### 7.6.1 Consensus Health Dashboard
A Tempo-backed dashboard (uid `xrpld-consensus-health`) with four panels, all driven by TraceQL:
- **Consensus Round Duration** (timeseries, ms): average `consensus.round` span duration per node instance, with yellow/red thresholds at 4s/5s.
- **Phase Duration Breakdown** (barchart): average duration of `consensus.phase.*` spans grouped by span name.
- **Proposers per Round** (stat): average of the `span.proposers` attribute on `consensus.round` spans.
- **Recent Slow Rounds (>5s)** (table): `consensus.round` spans filtered to `duration > 5s`.
Each panel's TraceQL query is described inline in its bullet above.
### 7.6.2 Node Overview Dashboard
A Tempo-backed dashboard (uid `xrpld-node-overview`) with four panels:
- **Active Nodes** (stat): count of distinct `resource.service.instance.id` values seen for the `xrpld` service.
- **Total Transactions (1h)** (stat): count of `tx.receive` spans.
- **Error Rate** (gauge, percent): ratio of `status.code=error` spans to all spans, with yellow/red thresholds at 1%/5%.
- **Service Map** (nodeGraph): Tempo-generated service dependency graph.
### 7.6.3 Alert Rules
Grafana provisions three TraceQL-based alert rules (group `xrpld-tracing-alerts`, evaluated every 1m) against the Tempo datasource:
- **Consensus Round Slow** (warning, `for: 5m`): fires when average `consensus.round` duration exceeds 5s.
```
{resource.service.name="xrpld" && name="consensus.round"} | avg(duration) > 5s
```
- **RPC Error Rate Spike** (critical, `for: 2m`): fires when the error rate across `rpc.command.*` spans exceeds 5%. Error _rate_ is a ratio, so it must divide the error-span rate by the total-span rate — a single TraceQL `rate()` returns spans/second, not a percentage, and would fire on traffic volume alone. This uses span metrics emitted by the collector's `spanmetrics` connector (Prometheus datasource), not a TraceQL query:
```
sum(rate(traces_spanmetrics_calls_total{service_name="xrpld", span_name=~"rpc.command.*", status_code="STATUS_CODE_ERROR"}[5m]))
/
sum(rate(traces_spanmetrics_calls_total{service_name="xrpld", span_name=~"rpc.command.*"}[5m]))
> 0.05
```
- **Transaction Throughput Drop** (warning, `for: 10m`): fires when the `tx.receive` span rate falls below 10/s.
```
{resource.service.name="xrpld" && name="tx.receive"} | rate() < 10
```
> **Note**: The Consensus Round Slow and Transaction Throughput Drop rules use TraceQL aggregates (`avg(duration)`, `rate()`), which require Tempo 2.3+ with TraceQL metrics enabled. Verify aggregate query support in your Tempo version before provisioning. The RPC Error Rate Spike rule instead queries Prometheus span metrics (collector `spanmetrics` connector), so it needs that connector enabled in the collector pipeline.
---
## 7.7 PerfLog and Insight Correlation
> **OTLP** = OpenTelemetry Protocol
How to correlate OpenTelemetry traces with existing xrpld observability.
### 7.7.1 Correlation Architecture
```mermaid
flowchart TB
subgraph xrpld["xrpld Node"]
otel[OpenTelemetry<br/>Spans]
perflog[PerfLog<br/>JSON Logs]
insight[Beast Insight<br/>StatsD Metrics]
end
subgraph collectors["Data Collection"]
otelc[OTel Collector]
promtail[Promtail/Fluentd]
statsd[StatsD Exporter]
end
subgraph storage["Storage"]
tempo[(Tempo)]
loki[(Loki)]
prom[(Prometheus)]
end
subgraph grafana["Grafana"]
traces[Trace View]
logs[Log View]
metrics[Metrics View]
corr[Correlation<br/>Panel]
end
otel -->|OTLP| otelc --> tempo
perflog -->|JSON| promtail --> loki
insight -->|StatsD| statsd --> prom
tempo --> traces
loki --> logs
prom --> metrics
traces --> corr
logs --> corr
metrics --> corr
style xrpld fill:#0d47a1,stroke:#082f6a,color:#fff
style collectors fill:#bf360c,stroke:#8c2809,color:#fff
style storage fill:#1b5e20,stroke:#0d3d14,color:#fff
style grafana fill:#4a148c,stroke:#2e0d57,color:#fff
style otel fill:#0d47a1,stroke:#082f6a,color:#fff
style perflog fill:#0d47a1,stroke:#082f6a,color:#fff
style insight fill:#0d47a1,stroke:#082f6a,color:#fff
style otelc fill:#bf360c,stroke:#8c2809,color:#fff
style promtail fill:#bf360c,stroke:#8c2809,color:#fff
style statsd fill:#bf360c,stroke:#8c2809,color:#fff
style tempo fill:#1b5e20,stroke:#0d3d14,color:#fff
style loki fill:#1b5e20,stroke:#0d3d14,color:#fff
style prom fill:#1b5e20,stroke:#0d3d14,color:#fff
style traces fill:#4a148c,stroke:#2e0d57,color:#fff
style logs fill:#4a148c,stroke:#2e0d57,color:#fff
style metrics fill:#4a148c,stroke:#2e0d57,color:#fff
style corr fill:#4a148c,stroke:#2e0d57,color:#fff
```
**Reading the diagram:**
- **xrpld Node (three sources)**: A single node emits three independent data streams -- OpenTelemetry spans, PerfLog JSON logs, and Beast Insight StatsD metrics.
- **Data Collection layer**: Each stream has its own collector -- OTel Collector for spans, Promtail/Fluentd for logs, and a StatsD exporter for metrics. They operate independently.
- **Storage layer (Tempo, Loki, Prometheus)**: Each data type lands in a purpose-built store optimized for its query patterns (trace search, log grep, metric aggregation).
- **Grafana Correlation Panel**: The key integration point -- Grafana queries all three stores and links them via shared fields (`trace_id`, `tx_hash`, `ledger_seq`), enabling a single-pane debugging experience.
### 7.7.2 Correlation Fields
| Source | Field | Link To | Purpose |
| ----------- | ------------------- | ------------- | -------------------------- |
| **Trace** | `trace_id` | Logs | Find log entries for trace |
| **Trace** | `tx_hash` | Logs, Metrics | Find TX-related data |
| **Trace** | `ledger_seq` | Logs | Find ledger-related logs |
| **PerfLog** | `trace_id` (new) | Traces | Jump to trace from log |
| **PerfLog** | `ledger_seq` | Traces | Find consensus trace |
| **Insight** | `exemplar.trace_id` | Traces | Jump from metric spike |
### 7.7.3 Example: Debugging a Slow Transaction
**Step 1: Find the trace**
```
# In Grafana Explore with Tempo
{resource.service.name="xrpld" && span.tx_hash="ABC123..."}
```
**Step 2: Get the trace_id from the trace view**
```
Trace ID: 4bf92f3577b34da6a3ce929d0e0e4736
```
**Step 3: Find related PerfLog entries**
```
# In Grafana Explore with Loki
{job="xrpld"} |= "4bf92f3577b34da6a3ce929d0e0e4736"
```
**Step 4: Check Insight metrics for the time window**
```
# In Grafana with Prometheus
rate(xrpld_tx_applied_total[1m])
@ timestamp_from_trace
```
### 7.7.4 Unified Dashboard Example
A single dashboard (uid `xrpld-unified`) that ties traces, metrics, and logs together across the Tempo, Prometheus, and Loki datasources:
- **Transaction Latency (Traces)** (timeseries, Tempo): `histogram_over_time(duration)` of `tx.receive` spans.
- **Transaction Rate (Metrics)** (timeseries, Prometheus): `rate(xrpld_tx_received_total[5m])` per instance, with a data link that opens the matching `tx.receive` traces in Tempo.
- **Recent Logs** (logs, Loki): `{job="xrpld"} | json`.
- **Trace Search** (table, Tempo): all `xrpld` traces, with per-row data links on `traceID` that jump to the trace in Tempo and to the correlated logs in Loki (`{job="xrpld"} |= "<traceID>"`).
The cross-datasource data links are what make this a single-pane debugging view; the correlation fields they rely on are listed in section 7.7.2.
---
_Previous: [Implementation Phases](./06-implementation-phases.md)_ | _Next: [Appendix](./08-appendix.md)_ | _Back to: [Overview](./OpenTelemetryPlan.md)_

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@@ -1,262 +0,0 @@
# Appendix
> **Parent Document**: [OpenTelemetryPlan.md](./OpenTelemetryPlan.md)
> **Related**: [Observability Backends](./07-observability-backends.md)
---
## 8.1 Glossary
> **OTLP** = OpenTelemetry Protocol | **TxQ** = Transaction Queue
| Term | Definition |
| --------------------- | ---------------------------------------------------------- |
| **Span** | A unit of work with start/end time, name, and attributes |
| **Trace** | A collection of spans representing a complete request flow |
| **Trace ID** | 128-bit unique identifier for a trace |
| **Span ID** | 64-bit unique identifier for a span within a trace |
| **Context** | Carrier for trace/span IDs across boundaries |
| **Propagator** | Component that injects/extracts context |
| **Sampler** | Decides which traces to record |
| **Exporter** | Sends spans to backend |
| **Collector** | Receives, processes, and forwards telemetry |
| **OTLP** | OpenTelemetry Protocol (wire format) |
| **W3C Trace Context** | Standard HTTP headers for trace propagation |
| **Baggage** | Key-value pairs propagated across service boundaries |
| **Resource** | Entity producing telemetry (service, host, etc.) |
| **Instrumentation** | Code that creates telemetry data |
### xrpld-Specific Terms
| Term | Definition |
| ----------------- | ------------------------------------------------------------- |
| **Overlay** | P2P network layer managing peer connections |
| **Consensus** | XRP Ledger consensus algorithm (RCL) |
| **Proposal** | Validator's suggested transaction set for a ledger |
| **Validation** | Validator's signature on a closed ledger |
| **HashRouter** | Component for transaction deduplication |
| **JobQueue** | Thread pool for asynchronous task execution |
| **PerfLog** | Existing performance logging system in xrpld |
| **Beast Insight** | Existing metrics framework in xrpld |
| **PathFinding** | Payment path computation engine for cross-currency payments |
| **TxQ** | Transaction queue managing fee-based prioritization |
| **LoadManager** | Dynamic fee escalation based on network load |
| **SHAMap** | SHA-256 hash-based map (Merkle trie variant) for ledger state |
### Phase 911 Terms
| Term | Definition |
| --------------------------- | ------------------------------------------------------------------------- |
| **MetricsRegistry** | Centralized class for OTel async gauge registrations (Phase 9) |
| **ObservableGauge** | OTel Metrics SDK async instrument polled via callback at fixed intervals |
| **PeriodicMetricReader** | OTel SDK component that invokes gauge callbacks at configurable intervals |
| **CountedObject** | xrpld template that tracks live instance counts via atomic counters |
| **TxQ** | Transaction queue managing fee escalation and ordering |
| **Load Factor** | Combined multiplier affecting transaction cost (local, cluster, network) |
| **OTel Collector Receiver** | Custom Go plugin that polls xrpld RPC and emits OTel metrics (Phase 11) |
---
## 8.2 Span Hierarchy Visualization
> **TxQ** = Transaction Queue
```mermaid
flowchart TB
subgraph trace["Trace: Transaction Lifecycle"]
rpc["rpc.request<br/>(entry point)"]
validate["tx.validate"]
relay["tx.relay<br/>(parent span)"]
subgraph peers["Peer Spans"]
p1["peer.send<br/>Peer A"]
p2["peer.send<br/>Peer B"]
p3["peer.send<br/>Peer C"]
end
subgraph pathfinding["PathFinding Spans"]
pathfind["pathfind.request"]
pathcomp["pathfind.compute"]
end
consensus["consensus.round"]
apply["tx.apply"]
subgraph txqueue["TxQ Spans"]
txq["txq.enqueue"]
txqApply["txq.apply"]
end
feeCalc["fee.escalate"]
end
subgraph validators["Validator Spans"]
valFetch["validator.list.fetch"]
valManifest["validator.manifest"]
end
rpc --> validate
rpc --> pathfind
pathfind --> pathcomp
validate --> relay
relay --> p1
relay --> p2
relay --> p3
p1 -.->|"context propagation"| consensus
consensus --> apply
apply --> txq
txq --> txqApply
txq --> feeCalc
style trace fill:#0f172a,stroke:#020617,color:#fff
style peers fill:#1e3a8a,stroke:#172554,color:#fff
style pathfinding fill:#134e4a,stroke:#0f766e,color:#fff
style txqueue fill:#064e3b,stroke:#047857,color:#fff
style validators fill:#4c1d95,stroke:#6d28d9,color:#fff
style rpc fill:#1d4ed8,stroke:#1e40af,color:#fff
style validate fill:#047857,stroke:#064e3b,color:#fff
style relay fill:#047857,stroke:#064e3b,color:#fff
style p1 fill:#0e7490,stroke:#155e75,color:#fff
style p2 fill:#0e7490,stroke:#155e75,color:#fff
style p3 fill:#0e7490,stroke:#155e75,color:#fff
style consensus fill:#fef3c7,stroke:#fde68a,color:#1e293b
style apply fill:#047857,stroke:#064e3b,color:#fff
style pathfind fill:#0e7490,stroke:#155e75,color:#fff
style pathcomp fill:#0e7490,stroke:#155e75,color:#fff
style txq fill:#047857,stroke:#064e3b,color:#fff
style txqApply fill:#047857,stroke:#064e3b,color:#fff
style feeCalc fill:#047857,stroke:#064e3b,color:#fff
style valFetch fill:#6d28d9,stroke:#4c1d95,color:#fff
style valManifest fill:#6d28d9,stroke:#4c1d95,color:#fff
```
**Reading the diagram:**
- **rpc.request (blue, top)**: The entry point — every traced transaction starts as an RPC call; this root span is the parent of all downstream work.
- **tx.validate and pathfind.request (green/teal, first fork)**: The RPC request fans out into transaction validation and, for cross-currency payments, a PathFinding branch (`pathfind.request` -> `pathfind.compute`).
- **tx.relay -> Peer Spans (teal, middle)**: After validation, the transaction is relayed to peers A, B, and C in parallel; each `peer.send` is a sibling child span showing fan-out across the network.
- **context propagation (dashed arrow)**: The dotted line from `peer.send Peer A` to `consensus.round` represents the trace context crossing a node boundary — the receiving validator picks up the same `trace_id` and continues the trace.
- **consensus.round -> tx.apply -> TxQ Spans (green, lower)**: Once consensus accepts the transaction, it is applied to the ledger; the TxQ spans (`txq.enqueue`, `txq.apply`, `fee.escalate`) capture queue depth and fee escalation behavior.
- **Validator Spans (purple, detached)**: `validator.list.fetch` and `validator.manifest` are independent workflows for UNL management — they run on their own traces and are linked to consensus via Span Links, not parent-child relationships.
---
## 8.3 References
> **OTLP** = OpenTelemetry Protocol
### OpenTelemetry Resources
1. [OpenTelemetry C++ SDK](https://github.com/open-telemetry/opentelemetry-cpp)
2. [OpenTelemetry Specification](https://opentelemetry.io/docs/specs/otel/)
3. [OpenTelemetry Collector](https://opentelemetry.io/docs/collector/)
4. [OTLP Protocol Specification](https://opentelemetry.io/docs/specs/otlp/)
### Standards
5. [W3C Trace Context](https://www.w3.org/TR/trace-context/)
6. [W3C Baggage](https://www.w3.org/TR/baggage/)
7. [Protocol Buffers](https://protobuf.dev/)
### xrpld Resources
8. [xrpld Source Code](https://github.com/XRPLF/rippled)
9. [XRP Ledger Documentation](https://xrpl.org/docs/)
10. [xrpld Overlay README](https://github.com/XRPLF/rippled/blob/develop/src/xrpld/overlay/README.md)
11. [xrpld RPC README](https://github.com/XRPLF/rippled/blob/develop/src/xrpld/rpc/README.md)
12. [xrpld Consensus README](https://github.com/XRPLF/rippled/blob/develop/src/xrpld/app/consensus/README.md)
---
## 8.4 Version History
| Version | Date | Author | Changes |
| ------- | ---------- | ------ | -------------------------------------------------------------- |
| 1.0 | 2026-02-12 | - | Initial implementation plan |
| 1.1 | 2026-02-13 | - | Refactored into modular documents |
| 1.2 | 2026-03-09 | - | Added Phases 911 (future enhancement plans) |
| 1.3 | 2026-03-24 | - | Review fixes: accuracy corrections, cross-document consistency |
---
## 8.5 Document Index
### Plan Documents
| Document | Description |
| -------------------------------------------------------------------- | -------------------------------------------------- |
| [OpenTelemetryPlan.md](./OpenTelemetryPlan.md) | Master overview and executive summary |
| [00-tracing-fundamentals.md](./00-tracing-fundamentals.md) | Distributed tracing concepts and OTel primer |
| [01-architecture-analysis.md](./01-architecture-analysis.md) | xrpld architecture and trace points |
| [02-design-decisions.md](./02-design-decisions.md) | SDK selection, exporters, span conventions |
| [03-implementation-strategy.md](./03-implementation-strategy.md) | Directory structure, performance analysis |
| [05-configuration-reference.md](./05-configuration-reference.md) | xrpld config, CMake, Collector configs |
| [06-implementation-phases.md](./06-implementation-phases.md) | Timeline, tasks, risks, success metrics |
| [07-observability-backends.md](./07-observability-backends.md) | Backend selection and architecture |
| [08-appendix.md](./08-appendix.md) | Glossary, references, version history |
| [secure-OTel.md](./secure-OTel.md) | Threat model and hardening (mTLS, peer validation) |
| [09-data-collection-reference.md](./09-data-collection-reference.md) | Span/metric/dashboard inventory |
### Task Lists
| Document | Description |
| -------------------------------------------------------------------------- | --------------------------------------------------- |
| [Phase2_taskList.md](./Phase2_taskList.md) | RPC layer trace instrumentation |
| [Phase3_taskList.md](./Phase3_taskList.md) | Peer overlay & consensus tracing |
| [Phase4_taskList.md](./Phase4_taskList.md) | Transaction lifecycle tracing |
| [Phase5_taskList.md](./Phase5_taskList.md) | Ledger processing & advanced tracing |
| [Phase5_IntegrationTest_taskList.md](./Phase5_IntegrationTest_taskList.md) | Observability stack integration tests |
| [Phase7_taskList.md](./Phase7_taskList.md) | Native OTel metrics migration |
| [Phase8_taskList.md](./Phase8_taskList.md) | Log-trace correlation |
| [Phase9_taskList.md](./Phase9_taskList.md) | Internal metric instrumentation gap fill (future) |
| [Phase10_taskList.md](./Phase10_taskList.md) | Synthetic workload generation & validation (future) |
| [Phase11_taskList.md](./Phase11_taskList.md) | Third-party data collection pipelines (future) |
> **Note**: Phases 1 and 6 do not have separate task list files. Phase 1 tasks are documented in [06-implementation-phases.md §6.2](./06-implementation-phases.md). Phase 6 tasks are documented in [06-implementation-phases.md §6.7](./06-implementation-phases.md).
---
## 8.6 Phase 911 Cross-Reference Guide
This guide maps Phase 911 content to its location across the documentation.
### Phase 9: Internal Metric Instrumentation Gap Fill
| Content | Location |
| ------------------------------- | ------------------------------------------------------------------------ |
| Plan & architecture | [06-implementation-phases.md §6.8.2](./06-implementation-phases.md) |
| Task list (10 tasks) | [Phase9_taskList.md](./Phase9_taskList.md) |
| Future metric definitions (~50) | [09-data-collection-reference.md §5b](./09-data-collection-reference.md) |
| New class: `MetricsRegistry` | `src/xrpld/telemetry/MetricsRegistry.h/.cpp` (planned) |
| New dashboards | `fee-market`, `job-queue` (planned) |
**Metric categories**: NodeStore I/O, Cache Hit Rates, TxQ, PerfLog Per-RPC, PerfLog Per-Job, Counted Objects, Fee Escalation & Load Factors.
### Phase 10: Synthetic Workload Generation & Telemetry Validation
| Content | Location |
| -------------------- | ------------------------------------------------------------------------ |
| Plan & architecture | [06-implementation-phases.md §6.8.3](./06-implementation-phases.md) |
| Task list (7 tasks) | [Phase10_taskList.md](./Phase10_taskList.md) |
| Validation inventory | [09-data-collection-reference.md §5c](./09-data-collection-reference.md) |
| Test harness | `docker/telemetry/docker-compose.workload.yaml` (planned) |
| CI workflow | `.github/workflows/telemetry-validation.yml` (planned) |
**Validates**: 16 spans, 22 attributes, 300+ metrics, 10 dashboards, log-trace correlation.
### Phase 11: Third-Party Data Collection Pipelines
| Content | Location |
| --------------------------------- | ------------------------------------------------------------------------ |
| Plan & architecture | [06-implementation-phases.md §6.8.4](./06-implementation-phases.md) |
| Task list (11 tasks) | [Phase11_taskList.md](./Phase11_taskList.md) |
| External metric definitions (~30) | [09-data-collection-reference.md §5d](./09-data-collection-reference.md) |
| Custom OTel Collector receiver | `docker/telemetry/otel-rippled-receiver/` (planned) |
| Prometheus alerting rules (11) | [09-data-collection-reference.md §5d](./09-data-collection-reference.md) |
| New dashboards (4) | Validator Health, Network Topology, Fee Market (External), DEX & AMM |
**Consumer categories**: Exchanges, Payment Processors, DeFi/AMM, NFT Marketplaces, Analytics Providers, Wallets, Compliance, Academic Researchers, Institutional Custody, CBDC Bridge Operators.
---
_Previous: [Observability Backends](./07-observability-backends.md)_ | _Back to: [Overview](./OpenTelemetryPlan.md)_

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<!-- cspell:ignore ondemand otelcol -->
# Benchmarking OpenTelemetry Overhead
How to empirically measure the runtime cost of rippled's OpenTelemetry
instrumentation, using the `ripple/perf-iac` performance pipeline.
> **Tracking:** [RIPD-7155](https://ripplelabs.atlassian.net/browse/RIPD-7155)
> (under epic RIPD-5060).
---
## What is measured
A perf-iac **Performance Comparison** run builds and deploys two rippled
clusters on dedicated EC2, drives identical JMeter payment load at both, and
profiles both:
| Side | rippled build | runtime cfg | collector | profiling |
| ------------- | --------------------------------------------------------- | ------------------------------------------------ | -------------------------------------- | --------- |
| **on-demand** | telemetry compiled in (phase-10 default `telemetry=True`) | `[telemetry] enabled=1`, OTLP → `127.0.0.1:4318` | node-local sidecar (receive + discard) | on |
| **baseline** | telemetry compiled out (`telemetry=False`) | none | none | on |
**Overhead = the delta between the two sides** — the rippled-process eBPF
profile difference (CPU spent in span creation / attribute extraction on the
hot path) plus the JMeter TPS / latency delta. The OTel trace data itself is
discarded; only the _cost_ of producing it is measured.
### Why a local discard-collector
rippled's OTLP exporter runs on a background thread. If the endpoint is dead,
that thread burns CPU on failed-export retries — and because the exporter is
_inside_ the rippled process, that retry CPU lands in the rippled profile and
inflates the apparent overhead. A node-local collector that accepts and
discards (nop exporter) lets the export succeed instantly, keeping the profile
clean. It is CPU-capped (50%) and, being a separate process, is excluded from
the rippled-process profile regardless.
---
## Prerequisites (one-time)
Two branches carry the benchmark setup:
| Branch | Repo | Purpose |
| ----------------------------------- | ----------------- | ------------------------------------------------------------------------ |
| `pratik/otel-phase11-telemetry-off` | `XRPLF/rippled` | baseline binary — `conanfile.py` `default_options.telemetry = False` |
| `pratik/otel-benchmarking-test` | `ripple/perf-iac` | adds the per-side `telemetry` config key + `otel_collector` Ansible role |
Both must be pushed. The perf-iac branch is the one to **run the workflow
from** (see below) so the telemetry plumbing is present.
---
## Triggering a run (manual — recommended)
Run the comparison from the perf-iac branch via `gh`, or via the Actions UI
with **Use workflow from = `pratik/otel-benchmarking-test`**.
```bash
gh workflow run perf-internal.yml -R ripple/perf-iac \
--ref pratik/otel-benchmarking-test \
-f work-item=RIPD-7155 \
-f testname_base=otel_overhead_phase10 \
-f ondemand_performance_config='{"repo":"xrplf/rippled","ref":"pratik/otel-phase10-workload-validation","telemetry":"on","test_tpm":"60000","test_duration":"600","profiling":"true"}' \
-f baseline_performance_config='{"repo":"xrplf/rippled","ref":"pratik/otel-phase11-telemetry-off","telemetry":"off","profiling":"true"}'
```
| Field | Meaning |
| --------------- | --------------------------------------------------------------- |
| `--ref` | **must** be the perf-iac branch with the telemetry changes |
| `work-item` | real Jira key, ≤32 chars (names the dynamic env) |
| `telemetry` | per-side: `on` for on-demand, `off` for baseline — never merges |
| `test_tpm` | aggregate throughput per **minute** (`60000` ≈ 1000 TPS) |
| `test_duration` | seconds (`600` = 10 min) |
| `profiling` | `true` on **both** sides — this is the measurement |
Shared keys (`test_tpm`, `test_duration`) inherit baseline ← on-demand, so set
them once. Omitting `ssh-public-key` auto-destroys the env after the run.
### Reading results
- Report URL appears in the **Performance Testing** job log.
- Slack notice to `#ripplex-performance-rippled-ci`.
- Compare the two sides' rippled-process profiles + the TPS/latency table.
---
## Triggering from rippled CI (optional — needs a cross-org token)
It is possible to add a `workflow_dispatch` job in `XRPLF/rippled` that shells
out to dispatch the perf-iac run, so the benchmark can be kicked off from the
rippled repo. **This is not wired up yet** because of a cross-org auth
requirement, documented here so DevOps can decide.
### The blocker
- rippled lives in **`XRPLF`**; perf-iac lives in **`ripple`** (different orgs).
- A workflow's default `GITHUB_TOKEN` is scoped to its own repo and **cannot**
dispatch a workflow in another org.
- A **PAT or GitHub App token** with `actions: write` on `ripple/perf-iac`
must be stored as a secret (e.g. `PERF_IAC_DISPATCH_TOKEN`) in
`XRPLF/rippled`. Provisioning that token is an org-admin decision.
### Sketch (once the token exists)
A `.github/workflows/otel-benchmark-trigger.yml` in rippled, `workflow_dispatch`
with inputs for the two refs / TPM / duration, whose single step dispatches
perf-iac:
```text
steps:
- dispatch perf-internal.yml on ripple/perf-iac
using gh CLI (or actions/github-script) authenticated with
secrets.PERF_IAC_DISPATCH_TOKEN, passing the same -f inputs as the
manual command above.
```
Notes / caveats:
- This only _kicks off_ the perf-iac run; the actual provisioning, build,
load, and profiling still execute **in** perf-iac under its own OIDC role
and repo `vars` — so no rippled-side AWS access is needed, only the
dispatch token.
- Results still surface in the perf-iac Actions run + Slack, not in rippled CI.
If rippled-side visibility is wanted, the trigger job can poll the dispatched
run and echo its conclusion/report URL into the rippled job summary.
---
## Lessons learned
- **A parent-directory `.gitignore` (`tasks/`) silently excluded the Ansible
role's `tasks/main.yml`.** The role committed without its tasks file and ran
as a no-op — the collector never installed, leaving the OTLP endpoint dead.
Always verify what is _tracked_ (`git ls-files <role>/`) after committing a
new role, not just what exists locally; run `ansible-playbook --syntax-check`
on the pushed tree.
- **Matrix legs run `max-parallel: 1`** — on-demand and baseline run
sequentially on one dynamic env (good for comparability; doubles wall-clock).
- Validate the role mechanics locally (syntax-check, render templates); the
full integration (real AMI apt install, 5-node provisioning, load) only
exercises in the pipeline — so a short `test_duration` smoke run is the
cheapest way to shake out integration bugs before a long measurement run.

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@@ -1,226 +0,0 @@
# [OpenTelemetry](00-tracing-fundamentals.md) Distributed Tracing Implementation Plan for xrpld
## Executive Summary
> **OTLP** = OpenTelemetry Protocol
This document provides a comprehensive implementation plan for integrating OpenTelemetry distributed tracing into the xrpld XRP Ledger node software. The plan addresses the unique challenges of a decentralized peer-to-peer system where trace context must propagate across network boundaries between independent nodes.
### Key Benefits
- **End-to-end transaction visibility**: Track transactions from submission through consensus to ledger inclusion
- **Consensus round analysis**: Understand timing and behavior of consensus phases across validators
- **RPC performance insights**: Identify slow handlers and optimize response times
- **Network topology understanding**: Visualize message propagation patterns between peers
- **Incident debugging**: Correlate events across distributed nodes during issues
### Estimated Performance Overhead
| Metric | Overhead | Notes |
| ------------- | ---------- | ------------------------------------------------ |
| CPU | 1-3% | Span creation and attribute setting |
| Memory | <10 MB | SDK statics + batch buffer + worker thread stack |
| Network | 10-50 KB/s | Compressed OTLP export to collector |
| Latency (p99) | <2% | With proper sampling configuration |
---
## Document Structure
This implementation plan is organized into modular documents for easier navigation:
<div align="center">
```mermaid
flowchart TB
overview["📋 OpenTelemetryPlan.md<br/>(This Document)"]
subgraph fundamentals["Fundamentals"]
fund["00-tracing-fundamentals.md"]
end
subgraph analysis["Analysis & Design"]
arch["01-architecture-analysis.md"]
design["02-design-decisions.md"]
end
subgraph impl["Implementation"]
strategy["03-implementation-strategy.md"]
config["05-configuration-reference.md"]
end
subgraph deploy["Deployment & Planning"]
phases["06-implementation-phases.md"]
backends["07-observability-backends.md"]
appendix["08-appendix.md"]
secure["secure-OTel.md"]
dataref["09-data-collection-reference.md"]
end
overview --> fundamentals
overview --> analysis
overview --> impl
overview --> deploy
fund --> arch
arch --> design
design --> strategy
strategy --> config
config --> phases
phases --> backends
backends --> appendix
backends --> secure
appendix --> dataref
style overview fill:#1b5e20,stroke:#0d3d14,color:#fff,stroke-width:2px
style fundamentals fill:#00695c,stroke:#004d40,color:#fff
style fund fill:#00695c,stroke:#004d40,color:#fff
style analysis fill:#0d47a1,stroke:#082f6a,color:#fff
style impl fill:#bf360c,stroke:#8c2809,color:#fff
style deploy fill:#4a148c,stroke:#2e0d57,color:#fff
style arch fill:#0d47a1,stroke:#082f6a,color:#fff
style design fill:#0d47a1,stroke:#082f6a,color:#fff
style strategy fill:#bf360c,stroke:#8c2809,color:#fff
style config fill:#bf360c,stroke:#8c2809,color:#fff
style phases fill:#4a148c,stroke:#2e0d57,color:#fff
style backends fill:#4a148c,stroke:#2e0d57,color:#fff
style appendix fill:#4a148c,stroke:#2e0d57,color:#fff
style secure fill:#4a148c,stroke:#2e0d57,color:#fff
style dataref fill:#4a148c,stroke:#2e0d57,color:#fff
```
</div>
---
## Table of Contents
| Section | Document | Description |
| ------- | -------------------------------------------------------------- | ---------------------------------------------------------------------- |
| **0** | [Tracing Fundamentals](./00-tracing-fundamentals.md) | Distributed tracing concepts, span relationships, context propagation |
| **1** | [Architecture Analysis](./01-architecture-analysis.md) | xrpld component analysis, trace points, instrumentation priorities |
| **2** | [Design Decisions](./02-design-decisions.md) | SDK selection, exporters, span naming, attributes, context propagation |
| **3** | [Implementation Strategy](./03-implementation-strategy.md) | Directory structure, key principles, performance optimization |
| **5** | [Configuration Reference](./05-configuration-reference.md) | xrpld config, CMake integration, Collector configurations |
| **6** | [Implementation Phases](./06-implementation-phases.md) | 5-phase timeline, tasks, risks, success metrics |
| **7** | [Observability Backends](./07-observability-backends.md) | Backend selection guide and production architecture |
| **8** | [Appendix](./08-appendix.md) | Glossary, references, version history |
| **9** | [Data Collection Reference](./09-data-collection-reference.md) | Complete inventory of spans, attributes, metrics, and dashboards |
| **Sec** | [Securing the OTel Pipeline](./secure-OTel.md) | Threat model and hardening (mTLS, peer trace-context validation) |
---
## 0. Tracing Fundamentals
This document introduces distributed tracing concepts for readers unfamiliar with the domain. It covers what traces and spans are, how parent-child and follows-from relationships model causality, how context propagates across service boundaries, and how sampling controls data volume. It also maps these concepts to xrpld-specific scenarios like transaction relay and consensus.
➡️ **[Read Tracing Fundamentals](./00-tracing-fundamentals.md)**
---
## 1. Architecture Analysis
> **WS** = WebSocket | **TxQ** = Transaction Queue
The xrpld node consists of several key components that require instrumentation for comprehensive distributed tracing. The main areas include the RPC server (HTTP/WebSocket), Overlay P2P network, Consensus mechanism (RCLConsensus), JobQueue for async task execution, PathFinding, Transaction Queue (TxQ), fee escalation (LoadManager), ledger acquisition, validator management, and existing observability infrastructure (PerfLog, Insight/StatsD, Journal logging).
Key trace points span across transaction submission via RPC, peer-to-peer message propagation, consensus round execution, ledger building, path computation, transaction queue behavior, fee escalation, and validator health. The implementation prioritizes high-value, low-risk components first: RPC handlers provide immediate value with minimal risk, while consensus tracing requires careful implementation to avoid timing impacts.
➡️ **[Read full Architecture Analysis](./01-architecture-analysis.md)**
---
## 2. Design Decisions
> **OTLP** = OpenTelemetry Protocol | **CNCF** = Cloud Native Computing Foundation
The OpenTelemetry C++ SDK is selected for its CNCF backing, active development, and native performance characteristics. Traces are exported via OTLP/HTTP to an OpenTelemetry Collector, which provides flexible routing and sampling. OTLP/gRPC is planned future work (see design decisions §2.2.2).
Span naming follows a hierarchical `<component>.<operation>` convention (e.g., `rpc.submit`, `tx.relay`, `consensus.round`). Context propagation uses W3C Trace Context headers for HTTP and embedded Protocol Buffer fields for P2P messages. The implementation coexists with existing PerfLog and Insight observability systems through correlation IDs.
**Data Collection & Privacy**: Telemetry collects only operational metadata (timing, counts, hashes) — never sensitive content (private keys, balances, amounts, raw payloads). Privacy protection includes account hashing, configurable redaction, sampling, and collector-level filtering. Node operators retain full control over telemetry configuration.
➡️ **[Read full Design Decisions](./02-design-decisions.md)**
---
## 3. Implementation Strategy
The telemetry code is organized under `include/xrpl/telemetry/` for headers and `src/libxrpl/telemetry/` for implementation. Key principles include RAII-based span management via `SpanGuard` (with `discard()` for dropping unwanted spans), a `FilteringSpanProcessor` that intercepts `OnEnd()` to prevent discarded spans from entering the export pipeline, conditional compilation with `XRPL_ENABLE_TELEMETRY`, and minimal runtime overhead through batch processing and efficient sampling.
Performance optimization strategies include head sampling fixed at 100% (intentionally not configurable, so trace keep/drop decisions stay coherent across nodes), tail-based sampling at the collector for errors and slow traces to reduce volume, batch export to reduce network overhead, and conditional instrumentation that compiles to no-ops when disabled.
➡️ **[Read full Implementation Strategy](./03-implementation-strategy.md)**
---
## 5. Configuration Reference
> **OTLP** = OpenTelemetry Protocol | **APM** = Application Performance Monitoring
Configuration is handled through the `[telemetry]` section in `xrpld.cfg` with options for enabling/disabling, exporter selection, endpoint configuration, and component-level filtering. Head sampling is fixed at 1.0 (not operator-configurable); volume reduction is done by tail sampling in the collector. CMake integration includes a `XRPL_ENABLE_TELEMETRY` option for compile-time control.
OpenTelemetry Collector configurations are provided for development and production (with tail-based sampling, Tempo, and Elastic APM). Docker Compose examples enable quick local development environment setup.
➡️ **[View full Configuration Reference](./05-configuration-reference.md)**
---
## 6. Implementation Phases
The implementation spans 13 weeks across 8 phases:
| Phase | Duration | Focus | Key Deliverables |
| ----- | ----------- | --------------------- | ----------------------------------------------------------- |
| 1 | Weeks 1-2 | Core Infrastructure | SDK integration, Telemetry interface, Configuration |
| 2 | Weeks 3-4 | RPC Tracing | HTTP context extraction, Handler instrumentation |
| 3 | Weeks 5-6 | Transaction Tracing | Protocol Buffer context, Relay propagation |
| 4 | Weeks 7-8 | Consensus Tracing | Round spans, Proposal/validation tracing |
| 5 | Week 9 | Documentation | Runbook, Dashboards, Training |
| 6 | Week 10 | StatsD Metrics Bridge | OTel Collector StatsD receiver, 3 Grafana dashboards |
| 7 | Weeks 11-12 | Native OTel Metrics | OTelCollector impl, OTLP metrics export, StatsD deprecation |
| 8 | Week 13 | Log-Trace Correlation | trace_id in logs, Loki ingestion, Tempo↔Loki linking |
**Total Effort**: 65.1 developer-days with 2 developers
➡️ **[View full Implementation Phases](./06-implementation-phases.md)**
---
## 7. Observability Backends
> **APM** = Application Performance Monitoring | **GCS** = Google Cloud Storage
Grafana Tempo is recommended for all environments due to its cost-effectiveness and Grafana integration, while Elastic APM is ideal for organizations with existing Elastic infrastructure.
The recommended production architecture uses a gateway collector pattern with regional collectors performing tail-based sampling, routing traces to multiple backends (Tempo for primary storage, Elastic for log correlation, S3/GCS for long-term archive).
➡️ **[View Observability Backend Recommendations](./07-observability-backends.md)**
---
## 8. Appendix
The appendix contains a glossary of OpenTelemetry and xrpld-specific terms, references to external documentation and specifications, version history for this implementation plan, and a complete document index.
➡️ **[View Appendix](./08-appendix.md)**
---
## 9. Data Collection Reference
A single-source-of-truth reference documenting every piece of telemetry data collected by xrpld. Covers all 16 OpenTelemetry spans with their 22 attributes, all StatsD metrics (gauges, counters, histograms, overlay traffic), SpanMetrics-derived Prometheus metrics, and all 10 Grafana dashboards. Includes Tempo search guides and Prometheus query examples.
➡️ **[View Data Collection Reference](./09-data-collection-reference.md)**
---
## Securing the OTel Pipeline
Threat model and hardening guidance for production deployments where xrpld nodes ship telemetry to a centrally-hosted collector across an untrusted network. Covers the two attack surfaces (collector ingress and peer trace-context spoofing) and the chosen defenses: mTLS as primary collector auth, NetworkPolicy as defense-in-depth, and source-side validation plus per-peer rate limiting for the `protocol::TraceContext` field on peer messages.
➡️ **[View Securing the OTel Pipeline](./secure-OTel.md)**
---
_This document provides a comprehensive implementation plan for integrating OpenTelemetry distributed tracing into the xrpld XRP Ledger node software. For detailed information on any section, follow the links to the corresponding sub-documents._

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# Phase 10: Synthetic Workload Generation & Telemetry Validation — Task List
> **Status**: Future Enhancement
>
> **Goal**: Build tools that generate realistic XRPL traffic to validate the full Phases 1-9 telemetry stack end-to-end — all spans, attributes, metrics, dashboards, and log-trace correlation — under controlled load.
>
> **Scope**: Python/shell test harness + multi-node docker-compose environment + automated validation scripts + performance benchmarks.
>
> **Branch**: `pratik/otel-phase10-workload-validation` (from `pratik/otel-phase9-metric-gap-fill`)
>
> **Depends on**: Phase 9 (internal metric gap fill) — validates the full metric surface
### Related Plan Documents
| Document | Relevance |
| -------------------------------------------------------------------- | --------------------------------------------------------------- |
| [06-implementation-phases.md](./06-implementation-phases.md) | Phase 10 plan: motivation, architecture, exit criteria (§6.8.3) |
| [09-data-collection-reference.md](./09-data-collection-reference.md) | Defines the full inventory of spans/metrics to validate |
| [Phase9_taskList.md](./Phase9_taskList.md) | Prerequisite — all internal metrics must be emitting |
### Why This Phase Exists
Before Phases 1-9 can be considered production-ready, we need proof that:
1. All required spans fire with correct attributes under real transaction workloads
2. All 255+ StatsD metrics + ~50 Phase 9 metrics appear in Prometheus with non-zero values
3. Log-trace correlation (Phase 8) produces clickable trace_id links in Loki
4. All 10 Grafana dashboards render meaningful data (no empty panels)
5. Performance overhead stays within bounds (< 3% CPU, < 5MB memory)
6. The telemetry stack survives sustained load without data loss or queue backpressure
---
## Task 10.1: Multi-Node Test Harness
**Objective**: Create a docker-compose environment with 3-5 validator nodes that produces real consensus rounds.
**What to do**:
- Create `docker/telemetry/docker-compose.workload.yaml`:
- 5 xrpld validator nodes with UNL configured for each other
- All telemetry enabled: `[telemetry] enabled=1`, `[insight] server=otel`
- Full OTel stack: Collector, Tempo, Prometheus, Loki, Grafana
- Shared network with service discovery
- Each node should:
- Generate validator keys at startup
- Configure all 5 nodes in its UNL
- Enable all trace categories including `trace_peer=1`
- Write logs to a file tailed by the OTel Collector filelog receiver
- Include a `Makefile` target: `make telemetry-workload-up` / `make telemetry-workload-down`
**Key files**:
- New: `docker/telemetry/docker-compose.workload.yaml`
- New: `docker/telemetry/workload/generate-validator-keys.sh`
- New: `docker/telemetry/workload/xrpld-validator.cfg.template`
---
## Task 10.2: RPC Load Generator
**Objective**: Configurable tool that fires all traced RPC commands at controlled rates.
**What to do**:
- Create `docker/telemetry/workload/rpc_load_generator.py`:
- Connects to one or more xrpld WebSocket endpoints
- Fires all RPC commands that have trace spans: `server_info`, `ledger`, `tx`, `account_info`, `account_lines`, `fee`, `submit`, etc.
- Configurable parameters: rate (RPS), duration, command distribution weights
- Injects `traceparent` HTTP headers to test W3C context propagation
- Logs progress and errors to stdout
- Command distribution should match realistic production ratios:
- 40% `server_info` / `fee` (health checks)
- 30% `account_info` / `account_lines` / `account_objects` (wallet queries)
- 15% `ledger` / `ledger_data` (explorer queries)
- 10% `tx` / `account_tx` (transaction lookups)
- 5% `book_offers` / `amm_info` (DEX queries)
**Key files**:
- New: `docker/telemetry/workload/rpc_load_generator.py`
- New: `docker/telemetry/workload/requirements.txt`
---
## Task 10.3: Transaction Submitter
**Objective**: Generate diverse transaction types to exercise `tx.*` and `ledger.*` spans.
**What to do**:
- Create `docker/telemetry/workload/tx_submitter.py`:
- Pre-funds test accounts from genesis account
- Submits a mix of transaction types:
- `Payment` (XRP and issued currencies) exercises `tx.process`, `tx.apply`
- `OfferCreate` / `OfferCancel` DEX activity
- `TrustSet` trust line creation for issued currencies
- `NFTokenMint` / `NFTokenCreateOffer` / `NFTokenAcceptOffer` NFT activity
- `EscrowCreate` / `EscrowFinish` escrow lifecycle
- `AMMCreate` / `AMMDeposit` / `AMMWithdraw` AMM pool operations (if amendment enabled)
- Configurable: TPS target, transaction mix weights, duration
- Monitors submission results and tracks success/failure rates
- The transaction mix ensures the telemetry captures the full range of ledger activity that third parties care about.
**Key files**:
- New: `docker/telemetry/workload/tx_submitter.py`
- New: `docker/telemetry/workload/test_accounts.json` (pre-generated keypairs)
---
## Task 10.4: Telemetry Validation Suite
**Objective**: Automated scripts that verify all expected telemetry data exists after a workload run.
**What to do**:
- Create `docker/telemetry/workload/validate_telemetry.py`:
**Span validation** (queries Tempo API):
- Assert all required span names appear in traces (conditional spans `grpc.*`,
`ledger.acquire`, `txq.*`, `consensus.mode_change` are marked `optional` and
skipped when not exercised by the workload)
- Assert each span has its required attributes (bare/underscore keys per the
2026-05-13 span-attr naming redesign; dotted `xrpl.*` reserved for resource attrs)
- Assert parent-child relationships are correct (`rpc.ws_message` `rpc.process` `rpc.command.*`)
- Assert span durations are reasonable (> 0, < 60s)
**Metric validation** (queries Prometheus API):
- Assert all SpanMetrics-derived metrics are non-zero: `traces_span_metrics_calls_total`, `traces_span_metrics_duration_milliseconds_bucket`
- Assert all StatsD metrics are non-zero: `xrpld_LedgerMaster_Validated_Ledger_Age`, `xrpld_Peer_Finder_Active_*`, etc.
- Assert all Phase 9 metrics are non-zero: `xrpld_nodestore_*`, `xrpld_cache_*`, `xrpld_txq_*`, `xrpld_rpc_method_*`, `xrpld_object_count`, `xrpld_load_factor*`
- Assert metric label cardinality is within bounds
**Log-trace correlation validation** (queries Loki API):
- Assert logs contain `trace_id=` and `span_id=` fields
- Pick a random trace_id from Tempo query Loki for matching logs assert results exist
- Assert Grafana derived field links are functional
**Dashboard validation**:
- For each of the 10 Grafana dashboards, query the dashboard API and assert no panels show "No data"
- Output: JSON report with pass/fail per check, suitable for CI.
**Key files**:
- New: `docker/telemetry/workload/validate_telemetry.py`
- New: `docker/telemetry/workload/expected_spans.json` (span inventory for validation)
- New: `docker/telemetry/workload/expected_metrics.json` (metric inventory for validation)
---
## Task 10.5: Performance Benchmark Suite
**Objective**: Measure CPU/memory/latency overhead of the telemetry stack.
**What to do**:
- Create `docker/telemetry/workload/benchmark.sh`:
- **Baseline run**: Start cluster with `[telemetry] enabled=0`, run transaction workload for 5 minutes, record metrics
- **Telemetry run**: Start cluster with full telemetry enabled, run identical workload, record metrics
- **Comparison**: Calculate deltas for:
- CPU usage (per-node average)
- Memory RSS (per-node peak)
- RPC p99 latency
- Transaction throughput (TPS)
- Consensus round time p95
- Ledger close time p95
- Output: Markdown table comparing baseline vs. telemetry, with pass/fail against targets:
- CPU overhead < 3%
- Memory overhead < 5MB
- RPC latency impact < 2ms p99
- Throughput impact < 5%
- Consensus impact < 1%
- Store results in `docker/telemetry/workload/benchmark-results/` for historical tracking.
**Key files**:
- New: `docker/telemetry/workload/benchmark.sh`
- New: `docker/telemetry/workload/collect_system_metrics.sh`
---
## Task 10.6: CI Integration
**Objective**: Wire the validation suite into CI for regression detection.
**What to do**:
- Create a CI workflow (GitHub Actions or equivalent) that:
1. Builds xrpld with `-DXRPL_ENABLE_TELEMETRY=ON`
2. Starts the multi-node workload harness
3. Runs the RPC load generator + transaction submitter for 2 minutes
4. Runs the validation suite
5. Runs the benchmark suite
6. Fails the build if any validation check fails or benchmark exceeds thresholds
7. Archives the validation report and benchmark results as artifacts
- This should be a separate workflow (not part of the main CI), triggered manually or on telemetry-related branch changes.
**Key files**:
- New: `.github/workflows/telemetry-validation.yml`
- New: `docker/telemetry/workload/run-full-validation.sh` (orchestrator script)
---
## Task 10.7: Documentation
**Objective**: Document the workload tools and validation process.
**What to do**:
- Create `docker/telemetry/workload/README.md`:
- Quick start guide for running workload harness
- Configuration options for load generator and tx submitter
- How to read validation reports
- How to run benchmarks and interpret results
- Update `docs/telemetry-runbook.md`:
- Add "Validating Telemetry Stack" section
- Add "Performance Benchmarking" section
- Update `OpenTelemetryPlan/09-data-collection-reference.md`:
- Add "Validation" section with expected metric/span counts
---
## Exit Criteria — Delivered in PR #6519
- [x] Multi-node validator cluster starts and reaches consensus
- [x] RPC load generator fires all traced RPC commands at configurable rates
- [x] Transaction submitter generates 6+ transaction types at configurable TPS
- [x] Validation suite confirms all required spans, attributes, and metrics
- [x] Log-trace correlation validated end-to-end (Loki Tempo)
- [x] Grafana dashboards render data (no empty panels)
- [x] Overhead benchmark (`benchmark.sh`) measures telemetry-off vs telemetry-on deltas
- [x] CI workflow runs validation on telemetry branch changes
- [x] Validation report output is CI-parseable (JSON with exit codes)
- [x] OTel-driven regression gate captures per-span/per-RPC/per-job timings from
Prometheus and compares against a committed baseline
## Follow-up Work (tracked in separate PRs)
- [ ] FU-2: Automate baseline persistence across CI runs (artifact uploaded
on merge to `develop`, downloaded on PR runs). Current mechanism
requires a manual baseline-refresh PR.
- [ ] FU-4: Replace the proxy measurements in `benchmark.sh` (wall-clock curl
p99, ledger-cadence-as-TPS, ledger-cadence-as-consensus-p95) with
PromQL quantile queries from the same pipeline the regression gate uses.
- [ ] FU-6: Grafana dashboard plotting historical baseline values keyed by
commit SHA, for triaging noisy regressions.

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# Phase 11: Third-Party Data Collection Pipelines — Task List
> **Status**: Future Enhancement
>
> **Goal**: Build a custom OTel Collector receiver that periodically polls xrpld's admin RPCs and exports structured metrics for external consumers — making all XRPL health, validator, peer, fee, and DEX data available as Prometheus/OTLP metrics without xrpld code changes.
>
> **Scope**: Go-based OTel Collector receiver plugin + Grafana dashboards + Prometheus alerting rules.
>
> **Branch**: `pratik/otel-phase11-third-party-collection` (from `pratik/otel-phase10-workload-validation`)
>
> **Depends on**: Phase 10 (validation harness for testing the new receiver)
### Related Plan Documents
| Document | Relevance |
| -------------------------------------------------------------------- | --------------------------------------------------------------- |
| [06-implementation-phases.md](./06-implementation-phases.md) | Phase 11 plan: motivation, architecture, exit criteria (§6.8.4) |
| [09-data-collection-reference.md](./09-data-collection-reference.md) | Defines full metric inventory including third-party metrics |
| [Phase10_taskList.md](./Phase10_taskList.md) | Prerequisite — validation harness for testing |
### Third-Party Consumer Gap Analysis
This phase addresses the cross-cutting gap identified during research: **xrpld has no native Prometheus/OTLP metrics export for data accessible only via RPC**. Every consumer (exchanges, payment processors, analytics providers, validators, researchers, compliance firms, custodians) must build custom JSON-RPC polling and conversion. This receiver centralizes that work.
| Consumer Category | Data Unlocked by This Phase |
| -------------------------- | ------------------------------------------------------------------ |
| **Exchanges** | Real-time fee estimates, TxQ capacity, server health scores |
| **Payment Processors** | Settlement latency percentiles, corridor health, path availability |
| **Analytics Providers** | Validator metrics, network topology, amendment voting status |
| **DeFi / AMM** | AMM pool TVL, DEX order book depth, trade volumes |
| **Validators / Operators** | Per-peer latency, version distribution, UNL health, alerting |
| **Compliance** | Transaction volume trends, network growth metrics |
| **Academic Researchers** | Consensus performance time-series, decentralization metrics |
| **CBDC / Tokenization** | Token supply tracking, trust line adoption, freeze status |
| **Institutional Custody** | Multi-sig status, escrow tracking, reserve calculations |
| **Wallet Providers** | Server health for node selection, fee prediction data |
---
## Task 11.1: OTel Collector Receiver Scaffold
**Objective**: Create the Go project structure for a custom OTel Collector receiver that polls xrpld JSON-RPC.
**What to do**:
- Create `docker/telemetry/otel-rippled-receiver/`:
- `receiver.go` — implements `receiver.Metrics` interface
- `config.go` — configuration struct (endpoint, poll interval, enabled RPCs)
- `factory.go` — receiver factory registration
- `go.mod` / `go.sum` — Go module with OTel Collector SDK dependency
- Configuration model:
```yaml
xrpld_receiver:
endpoint: "http://localhost:5005" # xrpld admin RPC
poll_interval: 30s # how often to poll
enabled_collectors:
- server_info
- get_counts
- fee
- peers
- validators
- feature
- server_state
amm_pools: [] # optional: AMM pool IDs to track
book_offers_pairs: [] # optional: currency pairs for DEX depth
```
- Build a custom OTel Collector binary that includes this receiver alongside the standard receivers.
**Key files**:
- New: `docker/telemetry/otel-rippled-receiver/receiver.go`
- New: `docker/telemetry/otel-rippled-receiver/config.go`
- New: `docker/telemetry/otel-rippled-receiver/factory.go`
- New: `docker/telemetry/otel-rippled-receiver/go.mod`
- New: `docker/telemetry/otel-rippled-receiver/Dockerfile`
---
## Task 11.2: server_info / server_state Collector
**Objective**: Poll `server_info` and `server_state` and export all fields as OTel metrics.
**What to do**:
- Implement `serverInfoCollector` that calls `server_info` (admin) and extracts:
**Node Health Gauges:**
- `xrpl_server_state` (enum → int: disconnected=0, connected=1, syncing=2, tracking=3, full=4, proposing=5)
- `xrpl_server_state_duration_seconds`
- `xrpl_uptime_seconds`
- `xrpl_io_latency_ms`
- `xrpl_amendment_blocked` (0 or 1)
- `xrpl_peers_count`
- `xrpl_peer_disconnects_total`
- `xrpl_peer_disconnects_resources_total`
- `xrpl_jq_trans_overflow_total`
**Consensus Gauges:**
- `xrpl_last_close_proposers`
- `xrpl_last_close_converge_time_seconds`
- `xrpl_validation_quorum`
**Ledger Gauges:**
- `xrpl_validated_ledger_seq`
- `xrpl_validated_ledger_age_seconds`
- `xrpl_validated_ledger_base_fee_drops`
- `xrpl_validated_ledger_reserve_base_drops`
- `xrpl_validated_ledger_reserve_inc_drops`
- `xrpl_close_time_offset_seconds` (0 when absent)
**Load Factor Gauges:**
- `xrpl_load_factor`
- `xrpl_load_factor_server`
- `xrpl_load_factor_fee_escalation`
- `xrpl_load_factor_fee_queue`
- `xrpl_load_factor_local`
- `xrpl_load_factor_net`
- `xrpl_load_factor_cluster`
**State Accounting Gauges** (per state: disconnected, connected, syncing, tracking, full):
- `xrpl_state_duration_seconds{state="<name>"}`
- `xrpl_state_transitions_total{state="<name>"}`
**Validator Info** (when node is a validator):
- `xrpl_validator_list_count`
- `xrpl_validator_list_expiration_seconds` (epoch)
- `xrpl_validator_list_active` (0 or 1)
**Key files**:
- New: `docker/telemetry/otel-rippled-receiver/collectors/server_info.go`
---
## Task 11.3: get_counts Collector
**Objective**: Poll `get_counts` and export internal object counts and NodeStore stats.
**What to do**:
- Implement `getCountsCollector`:
**Database Gauges:**
- `xrpl_db_size_kb{db="total"}`, `xrpl_db_size_kb{db="ledger"}`, `xrpl_db_size_kb{db="transaction"}`
**NodeStore Gauges:**
- `xrpl_nodestore_reads_total`, `xrpl_nodestore_reads_hit`, `xrpl_nodestore_writes_total`
- `xrpl_nodestore_read_bytes`, `xrpl_nodestore_written_bytes`
- `xrpl_nodestore_read_duration_us`, `xrpl_nodestore_write_load`
- `xrpl_nodestore_read_queue`, `xrpl_nodestore_read_threads_running`
**Cache Gauges:**
- `xrpl_cache_hit_rate{cache="SLE"}`, `xrpl_cache_hit_rate{cache="ledger"}`, `xrpl_cache_hit_rate{cache="accepted_ledger"}`
- `xrpl_cache_size{cache="treenode"}`, `xrpl_cache_size{cache="fullbelow"}`, `xrpl_cache_size{cache="accepted_ledger"}`
**Object Count Gauges:**
- `xrpl_object_count{type="<name>"}` for each counted object type (Transaction, Ledger, NodeObject, STTx, STLedgerEntry, InboundLedger, Pathfinder, etc.)
**Rates:**
- `xrpl_historical_fetch_per_minute`
- `xrpl_local_txs`
**Key files**:
- New: `docker/telemetry/otel-rippled-receiver/collectors/get_counts.go`
---
## Task 11.4: Peer Topology Collector
**Objective**: Poll `peers` and export per-peer and aggregate network metrics.
**What to do**:
- Implement `peersCollector`:
**Aggregate Gauges:**
- `xrpl_peers_inbound_count`
- `xrpl_peers_outbound_count`
- `xrpl_peers_cluster_count`
**Per-Peer Gauges** (with labels `peer_key` truncated to 8 chars for cardinality control):
- `xrpl_peer_latency_ms{peer="<key>", version="<ver>", inbound="<bool>"}`
- `xrpl_peer_uptime_seconds{peer="<key>"}`
- `xrpl_peer_load{peer="<key>"}`
**Distribution Gauges** (aggregated across all peers):
- `xrpl_peer_latency_p50_ms`, `xrpl_peer_latency_p95_ms`, `xrpl_peer_latency_p99_ms`
- `xrpl_peer_version_count{version="<semver>"}` — count of peers per software version
**Tracking Status:**
- `xrpl_peer_diverged_count` — peers with `track=diverged`
- `xrpl_peer_unknown_count` — peers with `track=unknown`
**Key files**:
- New: `docker/telemetry/otel-rippled-receiver/collectors/peers.go`
**Cardinality note**: Per-peer metrics use truncated keys. For large peer sets (50+), the aggregate distribution gauges are preferred over per-peer labels.
---
## Task 11.5: Validator & Amendment Collector
**Objective**: Poll `validators` and `feature` to export validator health and amendment voting status.
**What to do**:
- Implement `validatorCollector`:
**From `validators` RPC:**
- `xrpl_trusted_validators_count`
- `xrpl_validator_signing` (0 or 1 — whether local validator is signing)
**From `feature` RPC:**
- `xrpl_amendment_enabled_count` — total enabled amendments
- `xrpl_amendment_majority_count` — amendments with majority but not yet enabled
- `xrpl_amendment_vetoed_count` — locally vetoed amendments
- `xrpl_amendment_unsupported_majority` (0 or 1) — any unsupported amendment has majority (critical alert)
**Per-amendment with majority** (limited cardinality — only amendments with `majority` set):
- `xrpl_amendment_majority_time{name="<amendment>"}` — epoch time when majority was gained
- `xrpl_amendment_votes{name="<amendment>"}` — current vote count
- `xrpl_amendment_threshold{name="<amendment>"}` — votes needed
**Key files**:
- New: `docker/telemetry/otel-rippled-receiver/collectors/validators.go`
---
## Task 11.6: Fee & TxQ Collector
**Objective**: Poll `fee` RPC and export real-time fee market data.
**What to do**:
- Implement `feeCollector` that calls the public `fee` RPC:
**Fee Level Gauges:**
- `xrpl_fee_current_ledger_size` — transactions in current open ledger
- `xrpl_fee_expected_ledger_size` — expected transactions at close
- `xrpl_fee_max_queue_size` — maximum transaction queue size
- `xrpl_fee_open_ledger_fee_drops` — minimum fee for open ledger inclusion
- `xrpl_fee_median_fee_drops` — median fee level
- `xrpl_fee_minimum_fee_drops` — base reference fee
- `xrpl_fee_queue_size` — current queue depth
- This overlaps with Phase 9's internal TxQ metrics but provides an external-only collection path that doesn't require xrpld code changes.
**Key files**:
- New: `docker/telemetry/otel-rippled-receiver/collectors/fee.go`
---
## Task 11.7: DEX & AMM Collector (Optional)
**Objective**: Periodically poll configured AMM pools and order book pairs for DeFi metrics.
**What to do**:
- Implement `dexCollector` (enabled only when `amm_pools` or `book_offers_pairs` are configured):
**AMM Pool Gauges** (per configured pool):
- `xrpl_amm_reserve{pool="<id>", asset="<currency>"}` — pool reserve amount
- `xrpl_amm_lp_token_supply{pool="<id>"}` — outstanding LP tokens
- `xrpl_amm_trading_fee{pool="<id>"}` — pool trading fee (basis points)
- `xrpl_amm_tvl_drops{pool="<id>"}` — total value locked (XRP-denominated)
**Order Book Gauges** (per configured pair):
- `xrpl_orderbook_bid_depth{pair="<base>/<quote>"}` — total bid volume
- `xrpl_orderbook_ask_depth{pair="<base>/<quote>"}` — total ask volume
- `xrpl_orderbook_spread{pair="<base>/<quote>"}` — best bid-ask spread
- `xrpl_orderbook_offer_count{pair="<base>/<quote>", side="bid|ask"}` — number of offers
**Key files**:
- New: `docker/telemetry/otel-rippled-receiver/collectors/dex.go`
**Note**: This is optional because it requires explicit configuration of which pools/pairs to track. Default configuration tracks no DEX data.
---
## Task 11.8: Prometheus Alerting Rules
**Objective**: Create production-ready alerting rules for the metrics exported by this receiver.
**What to do**:
- Create `docker/telemetry/prometheus/rippled-alerts.yml`:
**Tier 1 — Critical (page immediately):**
```yaml
- alert: XRPLServerNotFull
expr: xrpl_server_state < 4
for: 15m
- alert: XRPLAmendmentBlocked
expr: xrpl_amendment_blocked == 1
for: 1m
- alert: XRPLNoPeers
expr: xrpl_peers_count == 0
for: 5m
- alert: XRPLLedgerStale
expr: xrpl_validated_ledger_age_seconds > 120
for: 2m
- alert: XRPLHighIOLatency
expr: xrpl_io_latency_ms > 100
for: 5m
- alert: XRPLUnsupportedAmendmentMajority
expr: xrpl_amendment_unsupported_majority == 1
for: 1m
```
**Tier 2 — Warning (investigate within hours):**
```yaml
- alert: XRPLLowPeerCount
expr: xrpl_peers_count < 10
for: 15m
- alert: XRPLHighLoadFactor
expr: xrpl_load_factor > 10
for: 10m
- alert: XRPLSlowConsensus
expr: xrpl_last_close_converge_time_seconds > 6
for: 5m
- alert: XRPLValidatorListExpiring
expr: (xrpl_validator_list_expiration_seconds - time()) < 86400
for: 1h
- alert: XRPLClockDrift
expr: xrpl_close_time_offset_seconds > 0
for: 5m
- alert: XRPLStateFlapping
expr: rate(xrpl_state_transitions_total{state="full"}[1h]) > 2
for: 30m
```
**Key files**:
- New: `docker/telemetry/prometheus/rippled-alerts.yml`
- Update: `docker/telemetry/prometheus/prometheus.yml` (add rule_files reference)
---
## Task 11.9: New Grafana Dashboards
**Objective**: Create 4 new dashboards for the data exported by the receiver.
**What to do**:
- **Validator Health** (`validator-health`):
- Server state timeline, state duration breakdown
- Proposer count trend, converge time trend, validation quorum
- Validator list expiration countdown
- Amendment voting status (majority/enabled/vetoed)
- **Network Topology** (`xrpld-network-topology`):
- Peer count (inbound/outbound/cluster), peer version distribution
- Peer latency distribution (p50/p95/p99), diverged peer count
- Geographic distribution (if enriched with GeoIP)
- Peer uptime distribution
- **Fee Market** (`xrpld-fee-market-external`):
- Current fee levels (open ledger, median, minimum), fee escalation timeline
- Queue depth vs. capacity, transactions per ledger
- Load factor breakdown (server/network/cluster/escalation)
- **DEX & AMM Overview** (`xrpld-dex-amm`) (only populated when DEX collectors are configured):
- AMM pool TVL, reserve ratios, LP token supply
- Order book depth per pair, spread trends
- Trading fee revenue estimates
**Key files**:
- New: `docker/telemetry/grafana/dashboards/rippled-validator-health.json`
- New: `docker/telemetry/grafana/dashboards/rippled-network-topology.json`
- New: `docker/telemetry/grafana/dashboards/rippled-fee-market-external.json`
- New: `docker/telemetry/grafana/dashboards/rippled-dex-amm.json`
---
## Task 11.10: Integration with Phase 10 Validation
**Objective**: Extend the Phase 10 validation suite to verify this receiver's metrics.
**What to do**:
- Update `docker/telemetry/workload/validate_telemetry.py`:
- Add assertions for all `xrpl_*` metrics produced by the receiver
- Verify metric labels have expected values
- Verify alerting rules fire correctly (inject a "bad" state and check alert)
- Update `docker/telemetry/docker-compose.workload.yaml`:
- Add the custom OTel Collector build with the xrpld receiver
- Configure the receiver to poll one of the test nodes
**Key files**:
- Update: `docker/telemetry/workload/validate_telemetry.py`
- Update: `docker/telemetry/docker-compose.workload.yaml`
- Update: `docker/telemetry/workload/expected_metrics.json`
---
## Task 11.11: Documentation
**Objective**: Document the receiver, its metrics, deployment, and alerting.
**What to do**:
- Create `docker/telemetry/otel-rippled-receiver/README.md`:
- Architecture overview (how the receiver fits into the OTel Collector)
- Configuration reference (all config options with defaults)
- Metric reference table (all exported metrics with types and labels)
- Deployment guide (building custom collector binary, docker-compose integration)
- Update `OpenTelemetryPlan/09-data-collection-reference.md`:
- Add "Third-Party Metrics (OTel Collector Receiver)" section
- Add new Grafana dashboard reference (4 dashboards)
- Add alerting rules reference
- Update `docs/telemetry-runbook.md`:
- Add "Third-Party Metrics Receiver" troubleshooting section
- Add alerting playbook (what to do for each Tier 1/Tier 2 alert)
---
## Task 11.12: Alert Rules for External Dashboard Parity Metrics
> **Source**: [External Dashboard Parity](./06-implementation-phases.md#appendix-external-dashboard-parity) — 18 alert rules ported from the community [xrpl-validator-dashboard](https://github.com/realgrapedrop/xrpl-validator-dashboard).
>
> **Upstream**: Phase 7 Tasks 7.9-7.16 (metrics), Phase 9 Tasks 9.11-9.13 (dashboards).
> **Downstream**: None — terminal task in the parity chain.
**Objective**: Add Grafana alerting rules for the Phase 7+ parity metrics (validation agreement, validator health, peer quality, state tracking, ledger economy). These complement Task 11.8's `xrpl_*` alerts by covering the `xrpld_*` internal metrics.
**Critical Group** (8 rules, eval interval 10s):
| Rule | Condition | For |
| ------------------- | ------------------------------------------------------------- | --- |
| Agreement Below 90% | `xrpld_validation_agreement{metric="agreement_pct_24h"} < 90` | 30s |
| Not Proposing | `xrpld_state_tracking{metric="state_value"} < 6` | 10s |
| Unhealthy State | `xrpld_state_tracking{metric="state_value"} < 4` | 10s |
| Amendment Blocked | `xrpld_validator_health{metric="amendment_blocked"} == 1` | 1m |
| UNL Expiring | `xrpld_validator_health{metric="unl_expiry_days"} < 14` | 1h |
| High IO Latency | `histogram_quantile(0.95, xrpld_ios_latency_bucket) > 50` | 1m |
| High Load Factor | `xrpld_load_factor_metrics{metric="load_factor"} > 1000` | 1m |
| Peer Count Critical | `xrpld_server_info{metric="peers"} < 5` | 1m |
**Network Group** (3 rules, eval interval 10s):
| Rule | Condition | For |
| ------------------------- | ----------------------------------------------------------------- | --- |
| Peer Drop >10% | `delta(xrpld_server_info{metric="peers"}[30s]) / ... * 100 < -10` | 30s |
| Peer Drop >30% | Same formula, threshold -30 | 30s |
| P90 Latency + Disconnects | `peer_latency_p90_ms > 500 AND rate(disconnects) > 0` | 2m |
**Performance Group** (7 rules, eval interval 10s):
| Rule | Condition | For |
| ------------------- | ------------------------------------------------------------ | --- |
| CPU High | Per-core CPU > 80% (requires node_exporter) | 2m |
| Memory Critical | Memory usage > 90% (requires node_exporter) | 1m |
| Disk Warning | Disk usage > 85% (requires node_exporter) | 2m |
| Job Queue Overflow | `rate(xrpld_jq_trans_overflow_total[5m]) > 0` | 1m |
| Upgrade Recommended | `xrpld_peer_quality{metric="peers_higher_version_pct"} > 60` | 1m |
| TX Rate Drop | Transaction rate dropped > 50% in 5m window | 5m |
| Stale Ledger | `xrpld_ledger_economy{metric="ledger_age_seconds"} > 30` | 1m |
**Notification channel templates**: Email/SMTP, Discord, Slack, PagerDuty.
**Key files**:
- New/extend: `docker/telemetry/grafana/alerting/alert-rules-parity.yaml`
- New: `docker/telemetry/grafana/alerting/contact-points.yaml` (template configs)
- New: `docker/telemetry/grafana/alerting/notification-policies.yaml`
**Exit Criteria**:
- [ ] All 18 rules evaluate without errors in Grafana alerting UI
- [ ] Critical rules fire within expected timeframe when conditions are met
- [ ] Notification channel templates are documented (not hard-coded to any service)
---
## Task 11.13: Dual-Datasource Architecture Documentation
> **Source**: [External Dashboard Parity](./06-implementation-phases.md#appendix-external-dashboard-parity)
**Objective**: Document the external dashboard's "fast path" pattern as a future optimization for real-time panels.
**Pattern**: A lightweight Prometheus scrape endpoint (separate from OTLP pipeline) that polls critical metrics every 2-5s, bypassing the 10s OTLP metric reader interval and Prometheus scrape interval.
**Use case**: Real-time state panels (server state, ledger age, peer count) where 10-15s latency is too slow for operational dashboards.
**Decision**: Document as a future option, not implement now. The current 10s interval is acceptable for v1. The external dashboard achieves 2-5s freshness by polling RPC directly, which is what the Phase 11 receiver already does. Adding a separate scrape endpoint to xrpld would only be needed if sub-second metric freshness is required from the internal metrics pipeline.
**What to document**:
- Architecture comparison: OTLP pipeline (10-15s) vs. direct scrape (2-5s) vs. push gateway
- When to consider: operator feedback indicating 10s is insufficient for alerting SLOs
- How to implement if needed: add `/metrics` HTTP endpoint to xrpld with Prometheus client library
- Trade-offs: additional port, additional dependency, duplication with OTLP metrics
**Key files**:
- Update: `OpenTelemetryPlan/09-data-collection-reference.md` (add "Future: Dual-Datasource Architecture" section)
- Update: `docs/telemetry-runbook.md` (add brief note in performance tuning section)
**Exit Criteria**:
- [ ] Architecture comparison documented with clear trade-offs
- [ ] Decision rationale recorded (why deferred, when to revisit)
---
## Exit Criteria
- [ ] Custom OTel Collector receiver builds and starts without errors
- [ ] All `xrpl_*` metrics from server_info, get_counts, peers, validators, fee appear in Prometheus
- [ ] Metrics update at configured poll interval (default 30s)
- [ ] 4 new Grafana dashboards operational with data
- [ ] Prometheus alerting rules fire correctly for simulated failure conditions
- [ ] DEX/AMM collector works when configured (optional — not required for base exit criteria)
- [ ] Phase 10 validation suite passes with receiver metrics included
- [ ] Receiver handles xrpld restart/unavailability gracefully (no crash, logs warning, retries)
- [ ] Documentation complete: receiver README, metric reference, alerting playbook
- [ ] Go receiver has unit tests with >80% coverage
- [ ] 18 Grafana alert rules for Phase 7+ parity metrics evaluate correctly (Task 11.12)
- [ ] Dual-datasource architecture documented with trade-offs (Task 11.13)

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@@ -1,240 +0,0 @@
# Phase 2: RPC Tracing Completion Task List
> **Goal**: Complete RPC tracing coverage with unit tests, Grafana search filters, PathFind instrumentation, and config hardening. Build on the Phase 1c SpanGuard factory foundation to achieve production-quality RPC observability.
>
> **Scope**: Unit tests for core telemetry, Grafana Tempo search filters, PathFind RPC tracing, config validation (`std::clamp`).
>
> **Branch**: `pratik/otel-phase2-rpc-tracing` (from `pratik/otel-phase1c-rpc-integration`)
### Related Plan Documents
| Document | Relevance |
| ------------------------------------------------------------ | ------------------------------------------------------------- |
| [04-code-samples.md](./04-code-samples.md) | TraceContextPropagator (§4.4.2), RPC instrumentation (§4.5.3) |
| [02-design-decisions.md](./02-design-decisions.md) | W3C Trace Context (§2.5), span attributes (§2.4.2) |
| [06-implementation-phases.md](./06-implementation-phases.md) | Phase 2 tasks (§6.3), definition of done (§6.11.2) |
---
## Task 2.1: W3C Trace Context HTTP Header Extraction
**Status**: DEFERRED → Phase 3
**Reason**: W3C context propagation (`traceparent`/`tracestate` headers) requires a consumer — in Phase 2, RPC spans are entirely local to the node. Phase 3 introduces cross-node transaction tracing via protobuf context propagation, which is the first use case for extracted trace context. Implementing it here without a consumer would be dead code.
**Implemented in**: `pratik/otel-phase3-tx-tracing``TraceContextPropagator.h/.cpp`
---
## Task 2.2: Per-Category Span Creation
**Status**: COMPLETE (superseded by Phase 1c design)
**Original plan**: Add `XRPL_TRACE_PEER` and `XRPL_TRACE_LEDGER` macros.
**Actual implementation**: Phase 1c replaced all tracing macros with the `SpanGuard::span(TraceCategory, prefix, name)` factory pattern. The `TraceCategory` enum (`Rpc`, `Transactions`, `Consensus`, `Peer`, `Ledger`) serves the same conditional-creation purpose without macros. No separate task needed — the factory already supports all categories.
---
## Task 2.3: Add shouldTraceLedger() to Telemetry Interface
**Objective**: The `Setup` struct has a `traceLedger` field but there's no corresponding virtual method. Add it for interface completeness.
**What to do**:
- Edit `include/xrpl/telemetry/Telemetry.h`:
- Add `virtual bool shouldTraceLedger() const = 0;`
- Update all implementations:
- `src/libxrpl/telemetry/Telemetry.cpp` (TelemetryImpl, NullTelemetryOtel)
- `src/libxrpl/telemetry/NullTelemetry.cpp` (NullTelemetry)
**Key modified files**:
- `include/xrpl/telemetry/Telemetry.h`
- `src/libxrpl/telemetry/Telemetry.cpp`
- `src/libxrpl/telemetry/NullTelemetry.cpp`
---
## Task 2.4: Unit Tests for Core Telemetry Infrastructure
**Status**: COMPLETE
**Objective**: Add unit tests for the core telemetry abstractions to validate correctness and catch regressions.
**Implemented**:
- `src/tests/libxrpl/telemetry/TelemetryConfig.cpp`:
- Test Setup defaults (all fields have correct initial values)
- Test `setupTelemetry` config parser (empty section, full section, edge cases)
- Test `samplingRatio` clamping (values outside 0.0-1.0)
- `src/tests/libxrpl/telemetry/SpanGuardFactory.cpp`:
- Test null guard methods are safe (setAttribute, setOk, setError, addEvent on null)
- Test category span returns null when telemetry disabled
- Test child/linked span null when no parent context
- Test move construction transfers ownership
- Test recordException safe on null guard
- Test discard() safe on null guard
- `src/tests/libxrpl/telemetry/main.cpp` — GTest runner
- `src/tests/libxrpl/CMakeLists.txt` — test target with optional OTel linking
---
## Task 2.5: Enhance RPC Span Attributes
**Status**: DEFERRED (low priority)
**Reason**: The high-value attributes (`command`, `version`, `role`, `status`) are already set by Phase 1c. The remaining HTTP transport-level attributes (`http.method`, `net.peer.ip`, `http.status_code`) provide limited additional insight since:
- `http.method` is always POST for JSON-RPC
- `net.peer.ip` is debug-level info available in logs
- `duration_ms` is redundant with span duration (OTel captures start/end time natively)
These can be added later if dashboard queries specifically need them. The node health attributes (Task 2.8) provide far more operational value and were prioritized instead.
---
## Task 2.6: Build Verification and Performance Baseline
**Objective**: Verify the build succeeds with and without telemetry, and establish a performance baseline.
**What to do**:
1. Build with `telemetry=ON` and verify no compilation errors
2. Build with `telemetry=OFF` and verify no regressions
3. Run existing unit tests to verify no breakage
4. Document any build issues in lessons.md
**Verification Checklist**:
- [ ] `conan install . --build=missing -o telemetry=True` succeeds
- [ ] `cmake --preset default -Dtelemetry=ON` configures correctly
- [ ] Build succeeds with telemetry ON
- [ ] Build succeeds with telemetry OFF
- [ ] Existing tests pass with telemetry ON
- [ ] Existing tests pass with telemetry OFF
---
## Task 2.8: RPC Span Attribute Enrichment — Node Health Context
**Status**: DROPPED.
Node health (`amendment_blocked`, `server_state`) is not part of the telemetry surface. Operators consume the same data via the existing `server_info` / `server_state` RPC commands, so duplicating it on traces adds storage and cardinality cost without new value. The OTel C++ SDK 1.18.0 also does not support runtime updates to the resource, ruling out resource-level emission of these dynamic-by-nature flags.
---
## Task 2.9: PathFind RPC Instrumentation
**Status**: COMPLETE
**Objective**: Trace the path_find and ripple_path_find RPC handlers to capture request latency and computation cost.
**Spans added**:
- `pathfind.request` — wraps `doPathFind()` and `doRipplePathFind()` RPC handlers
- `pathfind.compute` — wraps `PathRequest::doUpdate()` (`pathfind_fast` attr)
- `pathfind.update_all` — wraps `PathRequestManager::updateAll()` on ledger close (`pathfind_ledger_index`, `pathfind_num_requests` attrs; emitted only when active subscriptions exist)
- `pathfind.discover` — wraps the entire per-source-asset loop in `PathRequest::findPaths()` (`pathfind_search_level`, `pathfind_num_paths` attrs). One span per RPC call instead of N (one per source asset). Trade-off: per-asset breakdown is lost; storage and cardinality bounded.
**Attribute namespacing**: All pathfind attributes use the `pathfind_*` underscore form per the Phase 1c naming-spec rule 5.
**New file**: `src/xrpld/rpc/detail/PathFindSpanNames.h`
**Modified files**:
- `src/xrpld/rpc/handlers/orderbook/PathFind.cpp`
- `src/xrpld/rpc/handlers/orderbook/RipplePathFind.cpp`
- `src/xrpld/rpc/detail/PathRequest.cpp`
- `src/xrpld/rpc/detail/PathRequestManager.cpp`
- `src/xrpld/rpc/detail/Pathfinder.cpp`
---
## Task 2.10: RPC and PathFind Span Attribute Gap Fill
**Status**: COMPLETE
**Objective**: Wire up workflow-identifying attributes that enable filtering and grouping traces by request characteristics without drilling into child spans.
**Attributes added**:
| Span | Attribute | Type | Source |
| ------------------- | ---------------------------- | ------ | --------------------------------- |
| `rpc.http_request` | `request_payload_size` | int64 | `request.body().size()` |
| `rpc.process` | `is_batch` | bool | `method == "batch"` check |
| `rpc.process` | `batch_size` | int64 | `params.size()` (only when batch) |
| `rpc.ws_message` | `command` | string | `jv[command]` or `jv[method]` |
| `rpc.command.*` | `load_type` | string | `context.loadType.label()` |
| `pathfind.compute` | `pathfind_dest_currency` | string | `to_string(saDstAmount_.asset())` |
| `pathfind.discover` | `pathfind_num_source_assets` | int64 | `sourceAssets.size()` |
_Note: `pathfind_dest_amount` was removed — the destination amount is a financial value excluded by the privacy policy (design §2.4.4)._
**New attr keys**: `RpcSpanNames.h` (`isBatch`, `batchSize`, `loadType`), `PathFindSpanNames.h` (`destCurrency`, `numSourceAssets`).
**Modified files**:
- `src/xrpld/rpc/detail/RpcSpanNames.h`
- `src/xrpld/rpc/detail/PathFindSpanNames.h`
- `src/xrpld/rpc/detail/ServerHandler.cpp`
- `src/xrpld/rpc/detail/RPCHandler.cpp`
- `src/xrpld/rpc/detail/PathRequest.cpp`
---
## Summary
| Task | Description | Status | Notes |
| ---- | ------------------------------------------- | ------------------- | --------------------------------------------------------- |
| 2.1 | W3C Trace Context header extraction | Deferred → Phase 3 | No consumer in Phase 2; needs cross-node tracing |
| 2.2 | Per-category span creation | Complete (Phase 1c) | Superseded by TraceCategory enum + SpanGuard |
| 2.3 | Add shouldTraceLedger() interface method | Complete (Phase 1c) | Delivered in Phase 1c base branch |
| 2.4 | Unit tests for core telemetry | Complete | TelemetryConfig + SpanGuardFactory tests |
| 2.5 | Enhanced RPC span attributes (HTTP-level) | Deferred | Low value; span duration covers timing natively |
| 2.6 | Build verification and performance baseline | Complete | Verified in CI on Phase 1c |
| 2.7 | Grafana Tempo search filters | Complete | rpc-command, rpc-status, rpc-role filters |
| 2.8 | RPC span attribute enrichment (node health) | Dropped | Available via `server_info`/`server_state` RPC |
| 2.9 | PathFind RPC instrumentation | Complete | request, compute, update_all, discover |
| 2.10 | RPC/PathFind span attribute gap fill | Complete | Batch detection, payload size, load cost, pathfind params |
**Delivered in this branch**: Tasks 2.4, 2.7, 2.9, 2.10.
**Deferred with rationale**: Tasks 2.1 (→Phase 3), 2.5 (low priority).
**Dropped**: Task 2.8 (node health not duplicated on traces).
**Superseded**: Task 2.2 (Phase 1c SpanGuard factory covers this).
---
## Known Issues / Future Work
### Thread safety of TelemetryImpl::stop() vs startSpan()
`TelemetryImpl::stop()` resets `sdkProvider_` (a `std::shared_ptr`) without
synchronization. `getTracer()` reads the same member from RPC handler threads.
This is a data race if any thread calls `startSpan()` concurrently with `stop()`.
**Current mitigation**: `Application::stop()` shuts down `serverHandler_`,
`overlay_`, and `jobQueue_` before calling `telemetry_->stop()`, so no callers
remain. See comments in `Telemetry.cpp:stop()` and `Application.cpp`.
**TODO**: Add an `std::atomic<bool> stopped_` flag checked in `getTracer()` to
make this robust against future shutdown order changes.
### Macro incompatibility: XRPL_TRACE_SPAN vs XRPL_TRACE_SET_ATTR
`XRPL_TRACE_SPAN` and `XRPL_TRACE_SPAN_KIND` declare `_xrpl_guard_` as a bare
`SpanGuard`, but `XRPL_TRACE_SET_ATTR` and `XRPL_TRACE_EXCEPTION` call
`_xrpl_guard_.has_value()` which requires `std::optional<SpanGuard>`. Using
`XRPL_TRACE_SPAN` followed by `XRPL_TRACE_SET_ATTR` in the same scope would
fail to compile.
**Current mitigation**: No call site currently uses `XRPL_TRACE_SPAN` — all
production code uses the conditional macros (`XRPL_TRACE_RPC`, `XRPL_TRACE_TX`,
etc.) which correctly wrap the guard in `std::optional`.
**TODO**: Either make `XRPL_TRACE_SPAN`/`XRPL_TRACE_SPAN_KIND` also wrap in
`std::optional`, or document that `XRPL_TRACE_SET_ATTR` is only compatible with
the conditional macros.

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@@ -1,548 +0,0 @@
# Phase 3: Transaction Tracing Task List
> **Goal**: Trace the full transaction lifecycle from RPC submission through peer relay, including cross-node context propagation via Protocol Buffer extensions. This is the WALK phase that demonstrates true distributed tracing.
>
> **Scope**: Protocol Buffer `TraceContext` message, context serialization, PeerImp transaction instrumentation, NetworkOPs processing instrumentation, HashRouter visibility, and multi-node relay context propagation.
>
> **Branch**: `pratik/otel-phase3-tx-tracing` (from `pratik/otel-phase2-rpc-tracing`)
### Related Plan Documents
| Document | Relevance |
| ------------------------------------------------------------ | ------------------------------------------------------------------------------------------------ |
| [04-code-samples.md](./04-code-samples.md) | TraceContext protobuf (§4.4.1), PeerImp instrumentation (§4.5.1), context serialization (§4.4.2) |
| [01-architecture-analysis.md](./01-architecture-analysis.md) | Transaction flow (§1.3), key trace points (§1.6) |
| [06-implementation-phases.md](./06-implementation-phases.md) | Phase 3 tasks (§6.4), definition of done (§6.11.3) |
| [02-design-decisions.md](./02-design-decisions.md) | Context propagation design (§2.5), attribute schema (§2.4.3) |
---
## Task 3.1: Define TraceContext Protocol Buffer Message
**Objective**: Add trace context fields to the P2P protocol messages so trace IDs can propagate across nodes.
**What to do**:
- Edit `include/xrpl/proto/xrpl.proto` (or `src/xrpld/proto/ripple.proto`, wherever the proto is):
- Add `TraceContext` message definition:
```protobuf
message TraceContext {
bytes trace_id = 1; // 16-byte trace identifier
bytes span_id = 2; // 8-byte span identifier
uint32 trace_flags = 3; // bit 0 = sampled
string trace_state = 4; // W3C tracestate value
}
```
- Add `optional TraceContext trace_context = 1001;` to:
- `TMTransaction`
- `TMProposeSet` (for Phase 4 use)
- `TMValidation` (for Phase 4 use)
- Use high field numbers (1001+) to avoid conflicts with existing fields
- Regenerate protobuf C++ code
**Key modified files**:
- `include/xrpl/proto/xrpl.proto` (or equivalent)
**Reference**:
- [04-code-samples.md §4.4.1](./04-code-samples.md) — TraceContext message definition
- [02-design-decisions.md §2.5.2](./02-design-decisions.md) — Protocol buffer context propagation design
---
## Task 3.2: Implement Protobuf Context Serialization
**Objective**: Create utilities to serialize/deserialize OTel trace context to/from protobuf `TraceContext` messages.
**What to do**:
- Create `include/xrpl/telemetry/TraceContextPropagator.h` (extend from Phase 2 if exists, or add protobuf methods):
- Add protobuf-specific methods:
- `static Context extractFromProtobuf(protocol::TraceContext const& proto)` — reconstruct OTel context from protobuf fields
- `static void injectToProtobuf(Context const& ctx, protocol::TraceContext& proto)` — serialize current span context into protobuf fields
- Both methods guard behind `#ifdef XRPL_ENABLE_TELEMETRY`
- Create/extend `src/libxrpl/telemetry/TraceContextPropagator.cpp`:
- Implement extraction: read trace_id (16 bytes), span_id (8 bytes), trace_flags from protobuf, construct `SpanContext`, wrap in `Context`
- Implement injection: get current span from context, serialize its TraceId, SpanId, and TraceFlags into protobuf fields
**Key new/modified files**:
- `include/xrpl/telemetry/TraceContextPropagator.h`
- `src/libxrpl/telemetry/TraceContextPropagator.cpp`
**Reference**:
- [04-code-samples.md §4.4.2](./04-code-samples.md) — Full extract/inject implementation
---
## Task 3.3: Instrument PeerImp Transaction Handling
**Objective**: Add trace spans to the peer-level transaction receive and relay path.
**What to do**:
- Edit `src/xrpld/overlay/detail/PeerImp.cpp`:
- In `onMessage(TMTransaction)` / `handleTransaction()`:
- Extract parent trace context from incoming `TMTransaction::trace_context` field (if present)
- Create `tx.receive` span as child of extracted context (or new root if none)
- Set attributes: `tx_hash`, `peer_id`, `tx_status`
- On HashRouter suppression (duplicate): set `suppressed=true`, add `tx.duplicate` event
- Wrap validation call with child span `tx.validate`
- Wrap relay with `tx.relay` span
- When relaying to peers:
- Inject current trace context into outgoing `TMTransaction::trace_context`
- Set `relay_count` attribute
- Use `SpanGuard::span(TraceCategory::Transactions, "tx", "receive")` factory
(Phase 1c replaced macros with the SpanGuard factory pattern)
**Key modified files**:
- `src/xrpld/overlay/detail/PeerImp.cpp`
**Reference**:
- [04-code-samples.md §4.5.1](./04-code-samples.md) — Full PeerImp instrumentation example
- [01-architecture-analysis.md §1.3](./01-architecture-analysis.md) — Transaction flow diagram
- [01-architecture-analysis.md §1.6](./01-architecture-analysis.md) — tx.receive trace point
---
## Task 3.4: Instrument NetworkOPs Transaction Processing
**Objective**: Trace the transaction processing pipeline in NetworkOPs, covering both sync and async paths.
**What to do**:
- Edit `src/xrpld/app/misc/NetworkOPs.cpp`:
- In `processTransaction()`:
- Create `tx.process` span
- Set attributes: `tx_hash`, `tx_type`, `local` (whether from RPC or peer)
- Record whether sync or async path is taken
- In `doTransactionAsync()`:
- Capture parent context before queuing
- Create `tx.queue` span with queue depth attribute
- Add event when transaction is dequeued for processing
- In `doTransactionSync()`:
- Create `tx.process_sync` span
- Record result (applied, queued, rejected)
**Key modified files**:
- `src/xrpld/app/misc/NetworkOPs.cpp`
**Reference**:
- [01-architecture-analysis.md §1.6](./01-architecture-analysis.md) — tx.validate and tx.process trace points
- [02-design-decisions.md §2.4.3](./02-design-decisions.md) — Transaction attribute schema
---
## Task 3.5: Instrument HashRouter for Dedup Visibility
**Objective**: Make transaction deduplication visible in traces by recording HashRouter decisions as span attributes/events.
**What to do**:
- Edit `src/xrpld/overlay/detail/PeerImp.cpp` (in handleTransaction):
- After calling `HashRouter::shouldProcess()` or `addSuppressionPeer()`:
- Record `suppressed` attribute (true/false)
- Record `tx_flags` showing current HashRouter state (SAVED, TRUSTED, etc.)
- Add `tx.first_seen` or `tx.duplicate` event
- This is NOT a modification to HashRouter itself — just recording its decisions as span attributes in the existing PeerImp instrumentation from Task 3.3.
**Key modified files**:
- `src/xrpld/overlay/detail/PeerImp.cpp` (same changes as 3.3, logically grouped)
---
## Task 3.6: Context Propagation in Transaction Relay
**Status**: COMPLETE (transaction relay). Consensus proposal/validation
propagation is deferred to Phase 4 — see "Planned (Phase 4)" below.
**Objective**: Ensure trace context flows correctly when transactions are relayed between peers, creating linked spans across nodes.
**What was done**:
- **TX send side**: `NetworkOPs::apply()` now injects the tx.process span's trace
context into the outgoing `TMTransaction` protobuf before relay, using
`telemetry::injectSpanContext()`. The receiving node's `txReceiveSpan()` (already
wired in PeerImp) extracts the parent span_id and creates the tx.receive span
as a child of the sender's tx.process span.
- **Edge cases**: Missing trace context (older peers) degrades gracefully to
standalone spans. Invalid/corrupted context is treated as absent. Trace
flags are propagated and respected.
**New infrastructure**:
- `SpanGuard::getTraceBytes()` — extracts raw trace_id/span_id/trace_flags
from a span without exposing OTel types. Safe to call from any thread.
- `PropagationHelpers.h` — `injectSpanContext(SpanGuard&, proto)` bridge
between SpanGuard and protobuf TraceContext.
- `TraceContextPropagator.h` — `injectToProtobuf(ctx, proto)` for
same-thread injection via OTel RuntimeContext.
**Key modified files**:
- `src/xrpld/app/misc/NetworkOPs.cpp` — tx relay injection
- `include/xrpl/telemetry/SpanGuard.h` — `TraceBytes` struct, `getTraceBytes()`
- `src/libxrpl/telemetry/SpanGuard.cpp` — `getTraceBytes()` implementation
- `src/xrpld/telemetry/PropagationHelpers.h` — inject helpers (new file)
**Planned (Phase 4 — not in this PR)**:
The consensus proposal/validation propagation below is Phase 4 scope and is
not implemented on this branch. It is listed here only to record the intended
design.
- **Proposal send/receive**: `RCLConsensus::Adaptor::propose()` injects the
current thread's active span context into the `TMProposeSet` protobuf via
`telemetry::injectToProtobuf()`. PeerImp creates a
`consensus.proposal.receive` span that extracts the sender's trace context
as parent (via `ConsensusReceiveTracing.h`).
- **Validation send/receive**: `RCLConsensus::Adaptor::validate()` injects
the current thread's active span context into the `TMValidation` protobuf.
PeerImp creates a `consensus.validation.receive` span that extracts the
sender's trace context as parent.
- Planned files: `src/xrpld/app/consensus/RCLConsensus.cpp` (send injection),
`src/xrpld/overlay/detail/PeerImp.cpp` (receive spans),
`src/xrpld/telemetry/ConsensusReceiveTracing.h` (receive span helpers,
new file).
**Reference**:
- [02-design-decisions.md §2.5](./02-design-decisions.md) — Context propagation design
- [04-code-samples.md §4.5.1](./04-code-samples.md) — Relay context injection pattern
---
## Task 3.7: Build Verification and Testing
**Objective**: Verify all Phase 3 changes compile and work correctly.
**What to do**:
1. Build with `telemetry=ON` — verify no compilation errors
2. Build with `telemetry=OFF` — verify no regressions
3. Run existing unit tests
4. Verify protobuf regeneration produces correct C++ code
5. Document any issues encountered
**Verification Checklist**:
- [ ] Protobuf changes generate valid C++
- [ ] Build succeeds with telemetry ON
- [ ] Build succeeds with telemetry OFF
- [ ] Existing tests pass
- [ ] No undefined symbols from new telemetry calls
---
## Task 3.8: Transaction Span Peer Version Attribute
> **Source**: [External Dashboard Parity](./06-implementation-phases.md#appendix-external-dashboard-parity) — adds peer version context inspired by the community [xrpl-validator-dashboard](https://github.com/realgrapedrop/xrpl-validator-dashboard).
>
> **Upstream**: Phase 2 (RPC span infrastructure must exist).
> **Downstream**: Phase 10 (validation checks for this attribute).
**Objective**: Add the relaying peer's xrpld version to `tx.receive` spans so operators can correlate transaction issues with peer version mismatches during network upgrades.
**What to do**:
- Edit `src/xrpld/overlay/detail/PeerImp.cpp`:
- In the `tx.receive` span block (after existing `peer_id` setAttribute call):
- Add `peer_version` (string) — from `this->getVersion()`
- Only set if `getVersion()` returns a non-empty string (avoid empty-string attributes)
**New span attribute**:
| Attribute | Type | Source | Example |
| -------------- | ------ | -------------------- | --------------- |
| `peer_version` | string | `peer->getVersion()` | `"xrpld-2.4.0"` |
**Rationale**: Transaction relay is where version mismatches cause subtle serialization or validation bugs. Tracing "this tx came from a v2.3.0 peer" helps diagnose compatibility issues. The community dashboard tracks peer versions externally; this brings version awareness into the trace itself.
**Key modified files**:
- `src/xrpld/overlay/detail/PeerImp.cpp`
**Exit Criteria**:
- [ ] `tx.receive` spans carry `peer_version` attribute with a non-empty version string
- [ ] Attribute is omitted (not set to empty string) when `getVersion()` returns empty
- [ ] Attribute visible in Tempo trace detail view
---
## Task 3.9: Deterministic Transaction Trace ID
> **Upstream**: Task 3.2 (protobuf serialization), Task 3.3 (PeerImp span exists).
> **Downstream**: Phase 10 (workload validation can query by tx hash directly).
> **Pattern**: Mirrors the consensus deterministic trace ID in Phase 4a
> (`createDeterministicContext` in `RCLConsensus.cpp`), adapted for transactions.
**Objective**: Derive the trace_id for transaction spans deterministically from the
transaction hash so that all nodes handling the same transaction independently produce
spans under the same trace_id — regardless of whether protobuf context propagation
succeeds.
**Why**: The current approach creates spans with random trace_ids and relies entirely
on protobuf `TraceContext` propagation to link them. If any hop in the relay chain
drops the context (older peers, message corruption, mixed-version networks), the trace
splits and downstream spans become impossible to find. With deterministic trace_ids,
correlation is guaranteed because every node derives the same trace_id from the same
`txID`.
**Approach — deterministic trace_id + protobuf span_id propagation**:
1. Derive `trace_id = txHash[0:16]` (first 16 bytes of the 32-byte transaction hash).
2. Generate a random 8-byte `span_id` per node (each node's span is unique within
the shared trace).
3. Create the span under this deterministic context as parent.
4. **Additionally**, if protobuf `TraceContext` is present in the incoming
`TMTransaction` message, extract the sender's `span_id` and use it as the span's
parent — this preserves parent-child ordering in the trace tree.
5. If protobuf context is absent (older peer, first hop), the span still has the
correct deterministic `trace_id` — it appears as a sibling root in the same trace
rather than being lost.
This gives the best of both worlds: guaranteed cross-node correlation via deterministic
`trace_id`, plus parent-child relay ordering via protobuf `span_id` when available.
**What to do**:
- Create `createDeterministicTxContext(uint256 const& txHash)` utility function:
- Location: shared header or file-local in `PeerImp.cpp` and `NetworkOPs.cpp`
(or a shared telemetry utility if both need it).
- Pattern: identical to `createDeterministicContext(uint256 const& ledgerId)` in
`RCLConsensus.cpp` — take `txHash[0:16]` as trace_id, random span_id via
`default_prng()`, sampled flag set, `remote=false`.
- Guard behind `#ifdef XRPL_ENABLE_TELEMETRY`.
```cpp
opentelemetry::context::Context
createDeterministicTxContext(uint256 const& txHash)
{
namespace trace = opentelemetry::trace;
// First 16 bytes of the 32-byte tx hash as trace ID.
trace::TraceId traceId(
opentelemetry::nostd::span<uint8_t const, 16>(txHash.data(), 16));
// Random span_id so each node's span is unique within the trace.
uint8_t spanIdBytes[8];
auto const rval = default_prng()();
std::memcpy(spanIdBytes, &rval, sizeof(spanIdBytes));
trace::SpanId spanId(
opentelemetry::nostd::span<uint8_t const, 8>(spanIdBytes, 8));
trace::SpanContext syntheticCtx(
traceId, spanId, trace::TraceFlags(1), /* remote = */ false);
return opentelemetry::context::Context{}.SetValue(
trace::kSpanKey,
opentelemetry::nostd::shared_ptr<trace::Span>(
new trace::DefaultSpan(syntheticCtx)));
}
```
- Edit `src/xrpld/overlay/detail/PeerImp.cpp` — restructure `handleTransaction()`:
- **Move span creation after deserialization** (txID must be known first):
1. Deserialize `STTx` and get `txID` (existing code at line ~1382).
2. Create deterministic parent context: `auto detCtx = createDeterministicTxContext(txID)`.
3. If `m->has_trace_context()`: extract protobuf context via `extractFromProtobuf()`,
**combine** with deterministic trace_id — use the protobuf span_id as parent
to preserve relay ordering, but override trace_id with the deterministic one.
4. If no protobuf context: create span under `detCtx` directly.
5. Set all existing attributes (`hash`, `peerId`, `peerVersion`, `suppressed`, etc.).
- **Combining deterministic trace_id with protobuf parent span_id**:
When both are available, construct a synthetic `SpanContext` with:
- `trace_id` = `txHash[0:16]` (deterministic)
- `span_id` = extracted from protobuf (sender's span_id → becomes parent)
- `trace_flags` = from protobuf
- `remote` = true (came from another node)
```cpp
// Pseudo-code for the combined context:
auto detTraceId = trace::TraceId(txHash.data(), 16);
auto remoteSpanId = /* from extractFromProtobuf */;
auto remoteFlags = /* from extractFromProtobuf */;
trace::SpanContext combinedCtx(
detTraceId, remoteSpanId, remoteFlags, /* remote = */ true);
// Use as parent context for the new span.
```
- Edit `src/xrpld/app/misc/NetworkOPs.cpp` — update `processTransaction()`:
- `transaction->getID()` is already available at the top of the function.
- Create deterministic parent context from `txID`.
- Create `tx.process` span under this context.
- No protobuf context to extract here (NetworkOPs is intra-node), so
deterministic context alone is sufficient.
- Add `trace_strategy` attribute to spans:
- Add `inline constexpr auto traceStrategy = "trace_strategy";`
to `TxSpanNames.h`.
- Set on each tx span: `span.setAttribute(tx_span::attr::traceStrategy, "deterministic")`.
**Key new/modified files**:
- `src/xrpld/overlay/detail/PeerImp.cpp` — restructured span creation
- `src/xrpld/app/misc/NetworkOPs.cpp` — deterministic context for tx.process
- `src/xrpld/telemetry/TxSpanNames.h` — new `traceStrategy` attribute constant
- New or shared utility for `createDeterministicTxContext()` (location TBD: could be
a shared header like `include/xrpl/telemetry/DeterministicContext.h`, or file-local
if only used in two places)
**Interaction with existing tasks**:
- **Task 3.3 (PeerImp instrumentation)**: The span creation in `handleTransaction()`
must be restructured — the span currently starts before `txID` is known. This task
moves it after deserialization.
- **Task 3.6 (Relay context propagation)**: Protobuf injection at the relay site
remains the same — `injectToProtobuf()` serializes the current span's `span_id`.
The receiver extracts it and combines with the deterministic `trace_id`.
- **Phase 4a (Consensus deterministic trace ID)**: This task follows the same pattern.
Consider extracting a shared utility (e.g., `createDeterministicContext(uint256)`)
that both consensus and transaction tracing use.
**Exit Criteria**:
- [ ] `tx.receive` and `tx.process` spans have deterministic trace_id = `txHash[0:16]`
- [ ] All nodes handling the same transaction produce spans under the same trace_id
- [x] Protobuf `span_id` propagation still works when available (parent-child ordering)
- [ ] Missing protobuf context (old peer) degrades gracefully to sibling spans, not lost traces
- [ ] `trace_strategy` attribute set to `"deterministic"` on all tx spans
- [ ] Trace queryable by tx hash (truncate hash → trace_id → direct lookup in Tempo)
**Deliverables implemented (not in original plan)**:
- **`SpanGuard::txSpan()` factory method** (`include/xrpl/telemetry/SpanGuard.h`):
Two overloads for creating transaction spans with deterministic trace IDs:
- `txSpan(category, group, name, txHash)` — standalone span (deterministic
trace_id from `txHash[0:16]`, no parent span_id).
- `txSpan(category, group, name, txHash, parentCtx)` — child span (deterministic
trace_id combined with protobuf-extracted parent span_id for relay ordering).
- **`TxTracing.h` helper functions** (`src/xrpld/telemetry/TxTracing.h`):
File-local helpers that wrap `SpanGuard::txSpan()` for the two main PeerImp call
sites:
- `txReceiveSpan(txHash, parentCtx)` — creates `tx.receive` span with
deterministic trace_id and optional protobuf parent context.
- `txProcessSpan(txHash)` — creates `tx.process` span with deterministic
trace_id only (no protobuf parent, used intra-node).
- **Note**: `TxTracing.h` includes `xrpl.pb.h` unconditionally (outside
`#ifdef XRPL_ENABLE_TELEMETRY`) because `protocol::TMTransaction` appears in
the function signatures regardless of telemetry build mode.
---
## Task 3.10: TxQ Instrumentation
**Status**: COMPLETE
**Objective**: Trace the transaction queue lifecycle — enqueue decisions, direct apply, batch clear, ledger-close accept loop, per-tx apply, and cleanup.
**Spans added**:
- `txq.enqueue` — wraps `TxQ::apply()` with tx_hash attribute
- `txq.apply_direct` — wraps `TxQ::tryDirectApply()` fast-path
- `txq.batch_clear` — wraps `TxQ::tryClearAccountQueueUpThruTx()`
- `txq.accept` — wraps `TxQ::accept()` ledger-close dequeue with queue_size attr
- `txq.accept_tx` — per-tx span inside accept loop with tx_hash, ter_code,
retries_remaining attributes
- `txq.cleanup` — wraps `TxQ::processClosedLedger()` with ledger_seq attribute
**New file**: `src/xrpld/app/misc/detail/TxQSpanNames.h`
**Modified file**: `src/xrpld/app/misc/detail/TxQ.cpp`
---
## Task 3.11: TX and TxQ Span Attribute Gap Fill
**Status**: COMPLETE
**Objective**: Add workflow-identifying attributes to transaction spans so operators can filter by transaction type and see outcomes without off-chain correlation.
**Attributes added**:
| Span | Attribute | Type | Source |
| ----------------- | -------------------- | ------ | ------------------------------------------------------------------- |
| `tx.process` | `tx_type` | string | `TxFormats::getInstance().findByType(stx->getTxnType())->getName()` |
| `tx.process` | `fee` | int64 | `stx->getFieldAmount(sfFee).xrp().drops()` |
| `tx.process` | `sequence` | int64 | `stx->getSeqProxy().value()` |
| `tx.process` | `ter_result` | string | `transToken(e.result)` (set after batch application) |
| `tx.process` | `applied` | bool | `e.applied` (set after batch application) |
| `tx.receive` | `tx_type` | string | `TxFormats::getInstance().findByType(stx->getTxnType())->getName()` |
| `txq.enqueue` | `tx_type` | string | same pattern as above |
| `txq.enqueue` | `txq_status` | string | `queued` / `applied_direct` / `applied` / `rejected` |
| `txq.enqueue` | `fee_level_paid` | int64 | `getFeeLevelPaid(view, *tx).value()` |
| `txq.enqueue` | `required_fee_level` | int64 | `getRequiredFeeLevel(...).value()` |
| `txq.batch_clear` | `num_cleared` | int64 | queued txs cleared ahead of the applying tx |
| `txq.cleanup` | `expired_count` | int64 | entries dropped for passed `LastLedgerSequence` |
| `txq.accept_tx` | `txq_status` | string | `applied` / `failed` / `retried` |
| `txq.accept` | `ledger_changed` | bool | set at end of accept loop |
**New attr keys**: `TxSpanNames.h` (`txType`, `fee`, `sequence`, `terResult`, `applied`), `TxQSpanNames.h` (`txType`).
**Modified files**:
- `src/xrpld/telemetry/TxSpanNames.h`
- `src/xrpld/app/misc/detail/TxQSpanNames.h`
- `src/xrpld/app/misc/NetworkOPs.cpp`
- `src/xrpld/overlay/detail/PeerImp.cpp`
- `src/xrpld/app/misc/detail/TxQ.cpp`
---
## Summary
| Task | Description | New Files | Modified Files | Depends On |
| ---- | ----------------------------------- | --------- | -------------- | ---------- |
| 3.1 | TraceContext protobuf message | 0 | 1 | Phase 2 |
| 3.2 | Protobuf context serialization | 1-2 | 0 | 3.1 |
| 3.3 | PeerImp transaction instrumentation | 0 | 1 | 3.2 |
| 3.4 | NetworkOPs transaction processing | 0 | 1 | Phase 2 |
| 3.5 | HashRouter dedup visibility | 0 | 1 | 3.3 |
| 3.6 | Relay context propagation | 0 | 1-2 | 3.3, 3.5 |
| 3.7 | Build verification and testing | 0 | 0 | 3.1-3.6 |
| 3.8 | TX span peer version attribute | 0 | 1 | 3.3 |
| 3.9 | Deterministic transaction trace ID | 0-1 | 3 | 3.2, 3.3 |
| 3.10 | TxQ instrumentation (6 spans) | 1 | 1 | 3.4 |
| 3.11 | TX/TxQ span attribute gap fill | 0 | 5 | 3.3, 3.10 |
**Parallel work**: Tasks 3.1 and 3.4 can start in parallel. Task 3.2 depends on 3.1. Tasks 3.3 and 3.5 depend on 3.2. Task 3.6 depends on 3.3 and 3.5. Task 3.8 depends on 3.3 (span must exist). Task 3.9 depends on 3.2 and 3.3. Task 3.10 depends on 3.4 (tx.process span must exist).
**Exit Criteria** (from [06-implementation-phases.md §6.11.3](./06-implementation-phases.md)):
- [x] Transaction traces span across nodes
- [x] Trace context in Protocol Buffer messages
- [ ] HashRouter deduplication visible in traces
- [ ] <5% overhead on transaction throughput
- [x] Deterministic trace_id: same trace_id for same tx across all nodes
- [x] Protobuf span_id propagation preserves parent-child ordering when available
---
## Known Issues / Future Work
### Unused trace_state proto field
The `TraceContext.trace_state` field (field 4) in `xrpl.proto` is reserved for
W3C `tracestate` vendor-specific key-value pairs but is not read or written by
`TraceContextPropagator`. Wire it when cross-vendor trace propagation is needed.
No wire cost since proto `optional` fields are zero-cost when absent.

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