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1a6a6231cc040c8ee372156530796aff80830ac0
xahaud/src/TransactionEngine.cpp
Arthur Britto 1a6a6231cc Add path expansion to transaction engine.
2012-08-03 14:57:52 -07:00

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//
// XXX Should make sure all fields and are recognized on a transactions.
// XXX Make sure fee is claimed for failed transactions.
// XXX Might uses an unordered set for vector.
//
#include "TransactionEngine.h"
#include <boost/foreach.hpp>
#include <boost/format.hpp>
#include <queue>
#include "../json/writer.h"
#include "Config.h"
#include "Log.h"
#include "TransactionFormats.h"
#include "utils.h"
// Small for testing, should likely be 32 or 64.
#define DIR_NODE_MAX 2
#define RIPPLE_PATHS_MAX 3
#define QUALITY_ONE 100000000 // 10e9
#define CURRENCY_ONE uint160(1) // Used as a place holder
#define ACCOUNT_ONE uint160(1) // Used as a place holder
// static STAmount saOne(CURRENCY_ONE, 1, 0);
bool transResultInfo(TransactionEngineResult terCode, std::string& strToken, std::string& strHuman)
{
static struct {
TransactionEngineResult terCode;
const char* cpToken;
const char* cpHuman;
} transResultInfoA[] = {
{ tenBAD_ADD_AUTH, "tenBAD_ADD_AUTH", "Not authorized to add account." },
{ tenBAD_AMOUNT, "tenBAD_AMOUNT", "Can only send positive amounts." },
{ tenBAD_CLAIM_ID, "tenBAD_CLAIM_ID", "Malformed." },
{ tenBAD_EXPIRATION, "tenBAD_EXPIRATION", "Malformed." },
{ tenBAD_GEN_AUTH, "tenBAD_GEN_AUTH", "Not authorized to claim generator." },
{ tenBAD_ISSUER, "tenBAD_ISSUER", "Malformed." },
{ tenBAD_OFFER, "tenBAD_OFFER", "Malformed." },
{ tenBAD_PATH, "tenBAD_PATH", "Malformed: path." },
{ tenBAD_PATH_COUNT, "tenBAD_PATH_COUNT", "Malformed: too many paths." },
{ tenBAD_PUBLISH, "tenBAD_PUBLISH", "Malformed: bad publish." },
{ tenBAD_RIPPLE, "tenBAD_RIPPLE", "Ledger prevents ripple from succeeding." },
{ tenBAD_SET_ID, "tenBAD_SET_ID", "Malformed." },
{ tenCLAIMED, "tenCLAIMED", "Can not claim a previously claimed account." },
{ tenCREATED, "tenCREATED", "Can't add an already created account." },
{ tenCREATEXNS, "tenCREATEXNS", "Can not specify non XNS for Create." },
{ tenDST_IS_SRC, "tenDST_IS_SRC", "Destination may not be source." },
{ tenDST_NEEDED, "tenDST_NEEDED", "Destination not specified." },
{ tenEXPIRED, "tenEXPIRED", "Won't add an expired offer." },
{ tenEXPLICITXNS, "tenEXPLICITXNS", "XNS is used by default, don't specify it." },
{ tenFAILED, "tenFAILED", "Something broke horribly" },
{ tenGEN_IN_USE, "tenGEN_IN_USE", "Generator already in use." },
{ tenINSUF_FEE_P, "tenINSUF_FEE_P", "fee totally insufficient" },
{ tenINVALID, "tenINVALID", "The transaction is ill-formed" },
{ tenMSG_SET, "tenMSG_SET", "Can't change a message key." },
{ tenREDUNDANT, "tenREDUNDANT", "Sends same currency to self." },
{ tenRIPPLE_EMPTY, "tenRIPPLE_EMPTY", "PathSet with no paths." },
{ tenUNKNOWN, "tenUNKNOWN", "The transactions requires logic not implemented yet" },
{ terALREADY, "terALREADY", "The exact transaction was already in this ledger" },
{ terBAD_AUTH, "terBAD_AUTH", "Transaction's public key is not authorized." },
{ terBAD_AUTH_MASTER, "terBAD_AUTH_MASTER", "Auth for unclaimed account needs correct master key." },
{ terBAD_LEDGER, "terBAD_LEDGER", "Ledger in unexpected state." },
{ terBAD_RIPPLE, "terBAD_RIPPLE", "No ripple path can be satisfied." },
{ terBAD_SEQ, "terBAD_SEQ", "This sequence number should be zero for prepaid transactions." },
{ terCREATED, "terCREATED", "Can not create a previously created account." },
{ terDIR_FULL, "terDIR_FULL", "Can not add entry to full dir." },
{ terFUNDS_SPENT, "terFUNDS_SPENT", "Can't set password, password set funds already spent." },
{ terINSUF_FEE_B, "terINSUF_FEE_B", "Account balance can't pay fee" },
{ terINSUF_FEE_T, "terINSUF_FEE_T", "fee insufficient now (account doesn't exist, network load)" },
{ terNODE_NOT_FOUND, "terNODE_NOT_FOUND", "Can not delete a directory node." },
{ terNODE_NOT_MENTIONED, "terNODE_NOT_MENTIONED", "Could not remove node from a directory." },
{ terNODE_NO_ROOT, "terNODE_NO_ROOT", "Directory doesn't exist." },
{ terNO_ACCOUNT, "terNO_ACCOUNT", "The source account does not exist" },
{ terNO_DST, "terNO_DST", "The destination does not exist" },
{ terNO_LINE_NO_ZERO, "terNO_LINE_NO_ZERO", "Can't zero non-existant line, destination might make it." },
{ terNO_PATH, "terNO_PATH", "No path existed or met transaction/balance requirements" },
{ terOFFER_NOT_FOUND, "terOFFER_NOT_FOUND", "Can not cancel offer." },
{ terOVER_LIMIT, "terOVER_LIMIT", "Over limit." },
{ terPAST_LEDGER, "terPAST_LEDGER", "The transaction expired and can't be applied" },
{ terPAST_SEQ, "terPAST_SEQ", "This sequence number has already past" },
{ terPATH_EMPTY, "terPATH_EMPTY", "Path could not send partial amount." },
{ terPATH_PARTIAL, "terPATH_PARTIAL", "Path could not send full amount." },
{ terPRE_SEQ, "terPRE_SEQ", "Missing/inapplicable prior transaction" },
{ terSET_MISSING_DST, "terSET_MISSING_DST", "Can't set password, destination missing." },
{ terSUCCESS, "terSUCCESS", "The transaction was applied" },
{ terUNCLAIMED, "terUNCLAIMED", "Can not use an unclaimed account." },
{ terUNFUNDED, "terUNFUNDED", "Source account had insufficient balance for transaction." },
};
int iIndex = NUMBER(transResultInfoA);
while (iIndex-- && transResultInfoA[iIndex].terCode != terCode)
;
if (iIndex >= 0)
{
strToken = transResultInfoA[iIndex].cpToken;
strHuman = transResultInfoA[iIndex].cpHuman;
}
return iIndex >= 0;
}
STAmount TransactionEngine::rippleBalance(const uint160& uToAccountID, const uint160& uFromAccountID, const uint160& uCurrencyID)
{
STAmount saBalance;
SLE::pointer sleRippleState = entryCache(ltRIPPLE_STATE, Ledger::getRippleStateIndex(uToAccountID, uFromAccountID, uCurrencyID));
assert(sleRippleState);
if (sleRippleState)
{
saBalance = sleRippleState->getIValueFieldAmount(sfBalance);
if (uToAccountID < uFromAccountID)
saBalance.negate();
}
return saBalance;
}
STAmount TransactionEngine::rippleLimit(const uint160& uToAccountID, const uint160& uFromAccountID, const uint160& uCurrencyID)
{
STAmount saLimit;
SLE::pointer sleRippleState = entryCache(ltRIPPLE_STATE, Ledger::getRippleStateIndex(uToAccountID, uFromAccountID, uCurrencyID));
assert(sleRippleState);
if (sleRippleState)
{
saLimit = sleRippleState->getIValueFieldAmount(uToAccountID < uFromAccountID ? sfLowLimit : sfHighLimit);
}
return saLimit;
}
uint32 TransactionEngine::rippleTransfer(const uint160& uIssuerID)
{
SLE::pointer sleAccount = entryCache(ltACCOUNT_ROOT, Ledger::getAccountRootIndex(uIssuerID));
return sleAccount->getIFieldPresent(sfTransferRate)
? sleAccount->getIFieldU32(sfTransferRate)
: QUALITY_ONE;
}
// XXX Might not need this, might store in nodes on calc reverse.
uint32 TransactionEngine::rippleQualityIn(const uint160& uToAccountID, const uint160& uFromAccountID, const uint160& uCurrencyID)
{
uint32 uQualityIn;
SLE::pointer sleRippleState = entryCache(ltRIPPLE_STATE, Ledger::getRippleStateIndex(uToAccountID, uFromAccountID, uCurrencyID));
if (sleRippleState)
{
uQualityIn = sleRippleState->getIFieldU32(uToAccountID < uFromAccountID ? sfLowQualityIn : sfHighQualityIn);
}
else
{
assert(false);
uQualityIn = QUALITY_ONE;
}
return uQualityIn;
}
uint32 TransactionEngine::rippleQualityOut(const uint160& uToAccountID, const uint160& uFromAccountID, const uint160& uCurrencyID)
{
uint32 uQualityOut;
SLE::pointer sleRippleState = entryCache(ltRIPPLE_STATE, Ledger::getRippleStateIndex(uToAccountID, uFromAccountID, uCurrencyID));
if (sleRippleState)
{
uQualityOut = sleRippleState->getIFieldU32(uToAccountID < uFromAccountID ? sfLowQualityOut : sfHighQualityOut);
}
else
{
assert(false);
uQualityOut = QUALITY_ONE;
}
return uQualityOut;
}
// Return how much of uIssuerID's uCurrencyID IOUs that uAccountID holds. May be negative.
// <-- IOU's uAccountID has of uIssuerID
STAmount TransactionEngine::rippleHolds(const uint160& uAccountID, const uint160& uCurrencyID, const uint160& uIssuerID)
{
STAmount saBalance;
SLE::pointer sleRippleState = entryCache(ltRIPPLE_STATE, Ledger::getRippleStateIndex(uAccountID, uIssuerID, uCurrencyID));
if (sleRippleState)
{
saBalance = sleRippleState->getIValueFieldAmount(sfBalance);
if (uAccountID < uIssuerID)
saBalance.negate(); // Put balance in low terms.
}
return saBalance;
}
// <-- saAmount: amount of uCurrencyID held by uAccountID. May be negative.
STAmount TransactionEngine::accountHolds(const uint160& uAccountID, const uint160& uCurrencyID, const uint160& uIssuerID)
{
STAmount saAmount;
if (uCurrencyID.isZero())
{
SLE::pointer sleAccount = entryCache(ltACCOUNT_ROOT, Ledger::getAccountRootIndex(uAccountID));
saAmount = sleAccount->getIValueFieldAmount(sfBalance);
Log(lsINFO) << "accountHolds: stamps: " << saAmount.getText();
}
else
{
saAmount = rippleHolds(uAccountID, uCurrencyID, uIssuerID);
Log(lsINFO) << "accountHolds: "
<< saAmount.getFullText()
<< " : "
<< STAmount::createHumanCurrency(uCurrencyID)
<< "/"
<< NewcoinAddress::createHumanAccountID(uIssuerID);
}
return saAmount;
}
// Returns the funds available for uAccountID for a currency/issuer.
// Use when you need a default for rippling uAccountID's currency.
// --> saDefault/currency/issuer
// <-- saFunds: Funds available. May be negative.
// If the issuer is the same as uAccountID, result is Default.
STAmount TransactionEngine::accountFunds(const uint160& uAccountID, const STAmount& saDefault)
{
STAmount saFunds;
Log(lsINFO) << "accountFunds: uAccountID="
<< NewcoinAddress::createHumanAccountID(uAccountID);
Log(lsINFO) << "accountFunds: saDefault.isNative()=" << saDefault.isNative();
Log(lsINFO) << "accountFunds: saDefault.getIssuer()="
<< NewcoinAddress::createHumanAccountID(saDefault.getIssuer());
if (!saDefault.isNative() && saDefault.getIssuer() == uAccountID)
{
saFunds = saDefault;
Log(lsINFO) << "accountFunds: offer funds: ripple self-funded: " << saFunds.getText();
}
else
{
saFunds = accountHolds(uAccountID, saDefault.getCurrency(), saDefault.getIssuer());
Log(lsINFO) << "accountFunds: offer funds: uAccountID ="
<< NewcoinAddress::createHumanAccountID(uAccountID)
<< " : "
<< saFunds.getText()
<< "/"
<< saDefault.getHumanCurrency()
<< "/"
<< NewcoinAddress::createHumanAccountID(saDefault.getIssuer());
}
return saFunds;
}
// Calculate transit fee.
STAmount TransactionEngine::rippleTransit(const uint160& uSenderID, const uint160& uReceiverID, const uint160& uIssuerID, const STAmount& saAmount)
{
STAmount saTransitFee;
if (uSenderID != uIssuerID && uReceiverID != uIssuerID)
{
uint32 uTransitRate = rippleTransfer(uIssuerID);
if (QUALITY_ONE != uTransitRate)
{
STAmount saTransitRate(CURRENCY_ONE, uTransitRate, -9);
saTransitFee = STAmount::multiply(saAmount, saTransitRate, saAmount.getCurrency());
}
}
return saTransitFee;
}
// Direct send w/o fees: redeeming IOUs and/or sending own IOUs.
void TransactionEngine::rippleCredit(const uint160& uSenderID, const uint160& uReceiverID, const STAmount& saAmount)
{
uint160 uIssuerID = saAmount.getIssuer();
assert(uSenderID == uIssuerID || uReceiverID == uIssuerID);
bool bFlipped = uSenderID > uReceiverID;
uint256 uIndex = Ledger::getRippleStateIndex(uSenderID, uReceiverID, saAmount.getCurrency());
SLE::pointer sleRippleState = entryCache(ltRIPPLE_STATE, uIndex);
if (!sleRippleState)
{
Log(lsINFO) << "rippleCredit: Creating ripple line: " << uIndex.ToString();
STAmount saBalance = saAmount;
sleRippleState = entryCreate(ltRIPPLE_STATE, uIndex);
if (!bFlipped)
saBalance.negate();
sleRippleState->setIFieldAmount(sfBalance, saBalance);
sleRippleState->setIFieldAccount(bFlipped ? sfHighID : sfLowID, uSenderID);
sleRippleState->setIFieldAccount(bFlipped ? sfLowID : sfHighID, uReceiverID);
}
else
{
STAmount saBalance = sleRippleState->getIValueFieldAmount(sfBalance);
if (!bFlipped)
saBalance.negate(); // Put balance in low terms.
saBalance += saAmount;
if (!bFlipped)
saBalance.negate();
sleRippleState->setIFieldAmount(sfBalance, saBalance);
entryModify(sleRippleState);
}
}
// Send regardless of limits.
// --> saAmount: Amount/currency/issuer for receiver to get.
// <-- saActual: Amount actually sent. Sender pay's fees.
STAmount TransactionEngine::rippleSend(const uint160& uSenderID, const uint160& uReceiverID, const STAmount& saAmount)
{
STAmount saActual;
uint160 uIssuerID = saAmount.getIssuer();
if (uSenderID == uIssuerID || uReceiverID == uIssuerID)
{
// Direct send: redeeming IOUs and/or sending own IOUs.
rippleCredit(uSenderID, uReceiverID, saAmount);
saActual = saAmount;
}
else
{
// Sending 3rd party IOUs: transit.
STAmount saTransitFee = rippleTransit(uSenderID, uReceiverID, uIssuerID, saAmount);
saActual = saTransitFee.isZero() ? saAmount : saAmount+saTransitFee;
saActual.setIssuer(uIssuerID); // XXX Make sure this done in + above.
rippleCredit(uIssuerID, uReceiverID, saAmount);
rippleCredit(uSenderID, uIssuerID, saActual);
}
return saActual;
}
STAmount TransactionEngine::accountSend(const uint160& uSenderID, const uint160& uReceiverID, const STAmount& saAmount)
{
STAmount saActualCost;
if (saAmount.isNative())
{
SLE::pointer sleSender = entryCache(ltACCOUNT_ROOT, Ledger::getAccountRootIndex(uSenderID));
SLE::pointer sleReceiver = entryCache(ltACCOUNT_ROOT, Ledger::getAccountRootIndex(uReceiverID));
Log(lsINFO) << str(boost::format("accountSend> %s (%s) -> %s (%s) : %s")
% NewcoinAddress::createHumanAccountID(uSenderID)
% (sleSender->getIValueFieldAmount(sfBalance)).getFullText()
% NewcoinAddress::createHumanAccountID(uReceiverID)
% (sleReceiver->getIValueFieldAmount(sfBalance)).getFullText()
% saAmount.getFullText());
sleSender->setIFieldAmount(sfBalance, sleSender->getIValueFieldAmount(sfBalance) - saAmount);
sleReceiver->setIFieldAmount(sfBalance, sleReceiver->getIValueFieldAmount(sfBalance) + saAmount);
Log(lsINFO) << str(boost::format("accountSend< %s (%s) -> %s (%s) : %s")
% NewcoinAddress::createHumanAccountID(uSenderID)
% (sleSender->getIValueFieldAmount(sfBalance)).getFullText()
% NewcoinAddress::createHumanAccountID(uReceiverID)
% (sleReceiver->getIValueFieldAmount(sfBalance)).getFullText()
% saAmount.getFullText());
entryModify(sleSender);
entryModify(sleReceiver);
saActualCost = saAmount;
}
else
{
saActualCost = rippleSend(uSenderID, uReceiverID, saAmount);
}
return saActualCost;
}
TransactionEngineResult TransactionEngine::offerDelete(const SLE::pointer& sleOffer, const uint256& uOfferIndex, const uint160& uOwnerID)
{
uint64 uOwnerNode = sleOffer->getIFieldU64(sfOwnerNode);
TransactionEngineResult terResult = dirDelete(false, uOwnerNode, Ledger::getOwnerDirIndex(uOwnerID), uOfferIndex);
if (terSUCCESS == terResult)
{
uint256 uDirectory = sleOffer->getIFieldH256(sfBookDirectory);
uint64 uBookNode = sleOffer->getIFieldU64(sfBookNode);
terResult = dirDelete(false, uBookNode, uDirectory, uOfferIndex);
}
entryDelete(sleOffer);
return terResult;
}
// <-- uNodeDir: For deletion, present to make dirDelete efficient.
// --> uRootIndex: The index of the base of the directory. Nodes are based off of this.
// --> uLedgerIndex: Value to add to directory.
// We only append. This allow for things that watch append only structure to just monitor from the last node on ward.
// Within a node with no deletions order of elements is sequential. Otherwise, order of elements is random.
TransactionEngineResult TransactionEngine::dirAdd(
uint64& uNodeDir,
const uint256& uRootIndex,
const uint256& uLedgerIndex)
{
SLE::pointer sleNode;
STVector256 svIndexes;
SLE::pointer sleRoot = entryCache(ltDIR_NODE, uRootIndex);
if (!sleRoot)
{
// No root, make it.
sleRoot = entryCreate(ltDIR_NODE, uRootIndex);
sleNode = sleRoot;
uNodeDir = 0;
}
else
{
uNodeDir = sleRoot->getIFieldU64(sfIndexPrevious); // Get index to last directory node.
if (uNodeDir)
{
// Try adding to last node.
sleNode = entryCache(ltDIR_NODE, Ledger::getDirNodeIndex(uRootIndex, uNodeDir));
assert(sleNode);
}
else
{
// Try adding to root. Didn't have a previous set to the last node.
sleNode = sleRoot;
}
svIndexes = sleNode->getIFieldV256(sfIndexes);
if (DIR_NODE_MAX != svIndexes.peekValue().size())
{
// Add to current node.
entryModify(sleNode);
}
// Add to new node.
else if (!++uNodeDir)
{
return terDIR_FULL;
}
else
{
// Have old last point to new node, if it was not root.
if (uNodeDir == 1)
{
// Previous node is root node.
sleRoot->setIFieldU64(sfIndexNext, uNodeDir);
}
else
{
// Previous node is not root node.
SLE::pointer slePrevious = entryCache(ltDIR_NODE, Ledger::getDirNodeIndex(uRootIndex, uNodeDir-1));
slePrevious->setIFieldU64(sfIndexNext, uNodeDir);
entryModify(slePrevious);
sleNode->setIFieldU64(sfIndexPrevious, uNodeDir-1);
}
// Have root point to new node.
sleRoot->setIFieldU64(sfIndexPrevious, uNodeDir);
entryModify(sleRoot);
// Create the new node.
sleNode = entryCreate(ltDIR_NODE, Ledger::getDirNodeIndex(uRootIndex, uNodeDir));
svIndexes = STVector256();
}
}
svIndexes.peekValue().push_back(uLedgerIndex); // Append entry.
sleNode->setIFieldV256(sfIndexes, svIndexes); // Save entry.
Log(lsINFO) << "dirAdd: creating: root: " << uRootIndex.ToString();
Log(lsINFO) << "dirAdd: appending: Entry: " << uLedgerIndex.ToString();
Log(lsINFO) << "dirAdd: appending: Node: " << strHex(uNodeDir);
// Log(lsINFO) << "dirAdd: appending: PREV: " << svIndexes.peekValue()[0].ToString();
return terSUCCESS;
}
// --> bKeepRoot: True, if we never completely clean up, after we overflow the root node.
// --> uNodeDir: Node containing entry.
// --> uRootIndex: The index of the base of the directory. Nodes are based off of this.
// --> uLedgerIndex: Value to add to directory.
// Ledger must be in a state for this to work.
TransactionEngineResult TransactionEngine::dirDelete(
bool bKeepRoot,
const uint64& uNodeDir,
const uint256& uRootIndex,
const uint256& uLedgerIndex)
{
uint64 uNodeCur = uNodeDir;
SLE::pointer sleNode = entryCache(ltDIR_NODE, uNodeCur ? Ledger::getDirNodeIndex(uRootIndex, uNodeCur) : uRootIndex);
assert(sleNode);
if (!sleNode)
{
Log(lsWARNING) << "dirDelete: no such node";
return terBAD_LEDGER;
}
STVector256 svIndexes = sleNode->getIFieldV256(sfIndexes);
std::vector<uint256>& vuiIndexes = svIndexes.peekValue();
std::vector<uint256>::iterator it;
it = std::find(vuiIndexes.begin(), vuiIndexes.end(), uLedgerIndex);
assert(vuiIndexes.end() != it);
if (vuiIndexes.end() == it)
{
assert(false);
Log(lsWARNING) << "dirDelete: no such entry";
return terBAD_LEDGER;
}
// Remove the element.
if (vuiIndexes.size() > 1)
*it = vuiIndexes[vuiIndexes.size()-1];
vuiIndexes.resize(vuiIndexes.size()-1);
sleNode->setIFieldV256(sfIndexes, svIndexes);
entryModify(sleNode);
if (vuiIndexes.empty())
{
// May be able to delete nodes.
uint64 uNodePrevious = sleNode->getIFieldU64(sfIndexPrevious);
uint64 uNodeNext = sleNode->getIFieldU64(sfIndexNext);
if (!uNodeCur)
{
// Just emptied root node.
if (!uNodePrevious)
{
// Never overflowed the root node. Delete it.
entryDelete(sleNode);
}
// Root overflowed.
else if (bKeepRoot)
{
// If root overflowed and not allowed to delete overflowed root node.
nothing();
}
else if (uNodePrevious != uNodeNext)
{
// Have more than 2 nodes. Can't delete root node.
nothing();
}
else
{
// Have only a root node and a last node.
SLE::pointer sleLast = entryCache(ltDIR_NODE, Ledger::getDirNodeIndex(uRootIndex, uNodeNext));
assert(sleLast);
if (sleLast->getIFieldV256(sfIndexes).peekValue().empty())
{
// Both nodes are empty.
entryDelete(sleNode); // Delete root.
entryDelete(sleLast); // Delete last.
}
else
{
// Have an entry, can't delete root node.
nothing();
}
}
}
// Just emptied a non-root node.
else if (uNodeNext)
{
// Not root and not last node. Can delete node.
SLE::pointer slePrevious = entryCache(ltDIR_NODE, uNodePrevious ? Ledger::getDirNodeIndex(uRootIndex, uNodePrevious) : uRootIndex);
assert(slePrevious);
SLE::pointer sleNext = entryCache(ltDIR_NODE, uNodeNext ? Ledger::getDirNodeIndex(uRootIndex, uNodeNext) : uRootIndex);
assert(slePrevious);
assert(sleNext);
if (!slePrevious)
{
Log(lsWARNING) << "dirDelete: previous node is missing";
return terBAD_LEDGER;
}
if (!sleNext)
{
Log(lsWARNING) << "dirDelete: next node is missing";
return terBAD_LEDGER;
}
// Fix previous to point to its new next.
slePrevious->setIFieldU64(sfIndexNext, uNodeNext);
entryModify(slePrevious);
// Fix next to point to its new previous.
sleNext->setIFieldU64(sfIndexPrevious, uNodePrevious);
entryModify(sleNext);
}
// Last node.
else if (bKeepRoot || uNodePrevious)
{
// Not allowed to delete last node as root was overflowed.
// Or, have pervious entries preventing complete delete.
nothing();
}
else
{
// Last and only node besides the root.
SLE::pointer sleRoot = entryCache(ltDIR_NODE, uRootIndex);
assert(sleRoot);
if (sleRoot->getIFieldV256(sfIndexes).peekValue().empty())
{
// Both nodes are empty.
entryDelete(sleRoot); // Delete root.
entryDelete(sleNode); // Delete last.
}
else
{
// Root has an entry, can't delete.
nothing();
}
}
}
return terSUCCESS;
}
// <-- true, if had a next entry.
bool TransactionEngine::dirFirst(
const uint256& uRootIndex, // --> Root of directory.
SLE::pointer& sleNode, // <-> current node
unsigned int& uDirEntry, // <-- next entry
uint256& uEntryIndex) // <-- The entry, if available. Otherwise, zero.
{
sleNode = entryCache(ltDIR_NODE, uRootIndex);
uDirEntry = 0;
assert(sleNode); // We never probe for directories.
return TransactionEngine::dirNext(uRootIndex, sleNode, uDirEntry, uEntryIndex);
}
// <-- true, if had a next entry.
bool TransactionEngine::dirNext(
const uint256& uRootIndex, // --> Root of directory
SLE::pointer& sleNode, // <-> current node
unsigned int& uDirEntry, // <-> next entry
uint256& uEntryIndex) // <-- The entry, if available. Otherwise, zero.
{
STVector256 svIndexes = sleNode->getIFieldV256(sfIndexes);
std::vector<uint256>& vuiIndexes = svIndexes.peekValue();
if (uDirEntry == vuiIndexes.size())
{
uint64 uNodeNext = sleNode->getIFieldU64(sfIndexNext);
if (!uNodeNext)
{
uEntryIndex.zero();
return false;
}
else
{
sleNode = entryCache(ltDIR_NODE, Ledger::getDirNodeIndex(uRootIndex, uNodeNext));
uDirEntry = 0;
return dirNext(uRootIndex, sleNode, uDirEntry, uEntryIndex);
}
}
uEntryIndex = vuiIndexes[uDirEntry++];
return true;
}
// Set the authorized public key for an account. May also set the generator map.
TransactionEngineResult TransactionEngine::setAuthorized(const SerializedTransaction& txn, bool bMustSetGenerator)
{
//
// Verify that submitter knows the private key for the generator.
// Otherwise, people could deny access to generators.
//
std::vector<unsigned char> vucCipher = txn.getITFieldVL(sfGenerator);
std::vector<unsigned char> vucPubKey = txn.getITFieldVL(sfPubKey);
std::vector<unsigned char> vucSignature = txn.getITFieldVL(sfSignature);
NewcoinAddress naAccountPublic = NewcoinAddress::createAccountPublic(vucPubKey);
if (!naAccountPublic.accountPublicVerify(Serializer::getSHA512Half(vucCipher), vucSignature))
{
Log(lsWARNING) << "createGenerator: bad signature unauthorized generator claim";
return tenBAD_GEN_AUTH;
}
// Create generator.
uint160 hGeneratorID = naAccountPublic.getAccountID();
SLE::pointer sleGen = entryCache(ltGENERATOR_MAP, Ledger::getGeneratorIndex(hGeneratorID));
if (!sleGen)
{
// Create the generator.
Log(lsTRACE) << "createGenerator: creating generator";
sleGen = entryCreate(ltGENERATOR_MAP, Ledger::getGeneratorIndex(hGeneratorID));
sleGen->setIFieldVL(sfGenerator, vucCipher);
}
else if (bMustSetGenerator)
{
// Doing a claim. Must set generator.
// Generator is already in use. Regular passphrases limited to one wallet.
Log(lsWARNING) << "createGenerator: generator already in use";
return tenGEN_IN_USE;
}
// Set the public key needed to use the account.
uint160 uAuthKeyID = bMustSetGenerator
? hGeneratorID // Claim
: txn.getITFieldAccount(sfAuthorizedKey); // PasswordSet
mTxnAccount->setIFieldAccount(sfAuthorizedKey, uAuthKeyID);
return terSUCCESS;
}
SLE::pointer TransactionEngine::entryCache(LedgerEntryType letType, const uint256& uIndex)
{
SLE::pointer sleEntry;
if (!uIndex.isZero())
{
LedgerEntryAction action;
sleEntry = mNodes.getEntry(uIndex, action);
if (!sleEntry)
{
sleEntry = mLedger->getSLE(uIndex);
if (sleEntry)
{
mNodes.entryCache(sleEntry);
mOrigNodes.entryCache(sleEntry); // So the metadata code can compare to the original
}
}
else if(action == taaDELETE)
assert(false);
}
return sleEntry;
}
SLE::pointer TransactionEngine::entryCreate(LedgerEntryType letType, const uint256& uIndex)
{
assert(!uIndex.isZero());
SLE::pointer sleNew = boost::make_shared<SerializedLedgerEntry>(letType);
sleNew->setIndex(uIndex);
mNodes.entryCreate(sleNew);
return sleNew;
}
void TransactionEngine::entryDelete(SLE::pointer sleEntry, bool unfunded)
{
mNodes.entryDelete(sleEntry, unfunded);
}
void TransactionEngine::entryModify(SLE::pointer sleEntry)
{
mNodes.entryModify(sleEntry);
}
void TransactionEngine::txnWrite()
{
// Write back the account states and add the transaction to the ledger
for (boost::unordered_map<uint256, LedgerEntrySetEntry>::iterator it = mNodes.begin(), end = mNodes.end();
it != end; ++it)
{
const SLE::pointer& sleEntry = it->second.mEntry;
switch (it->second.mAction)
{
case taaNONE:
assert(false);
break;
case taaCACHED:
break;
case taaCREATE:
{
Log(lsINFO) << "applyTransaction: taaCREATE: " << sleEntry->getText();
if (mLedger->writeBack(lepCREATE, sleEntry) & lepERROR)
assert(false);
}
break;
case taaMODIFY:
{
Log(lsINFO) << "applyTransaction: taaMODIFY: " << sleEntry->getText();
if (mLedger->writeBack(lepNONE, sleEntry) & lepERROR)
assert(false);
}
break;
case taaDELETE:
{
Log(lsINFO) << "applyTransaction: taaDELETE: " << sleEntry->getText();
if (!mLedger->peekAccountStateMap()->delItem(it->first))
assert(false);
}
break;
}
}
}
// This is for when a transaction fails from the issuer's point of view and the current changes need to be cleared so other
// actions can be applied to the ledger.
void TransactionEngine::entryReset()
{
mNodes.setTo(mOrigNodes);
}
TransactionEngineResult TransactionEngine::applyTransaction(const SerializedTransaction& txn,
TransactionEngineParams params)
{
Log(lsTRACE) << "applyTransaction>";
assert(mLedger);
mLedgerParentCloseTime = mLedger->getParentCloseTimeNC();
mNodes.init(txn.getTransactionID(), mLedger->getLedgerSeq());
#ifdef DEBUG
if (1)
{
Serializer ser;
txn.add(ser);
SerializerIterator sit(ser);
SerializedTransaction s2(sit);
if (!s2.isEquivalent(txn))
{
Log(lsFATAL) << "Transaction serdes mismatch";
Json::StyledStreamWriter ssw;
ssw.write(Log(lsINFO).ref(), txn.getJson(0));
ssw.write(Log(lsFATAL).ref(), s2.getJson(0));
assert(false);
}
}
#endif
TransactionEngineResult terResult = terSUCCESS;
uint256 txID = txn.getTransactionID();
if (!txID)
{
Log(lsWARNING) << "applyTransaction: invalid transaction id";
terResult = tenINVALID;
}
//
// Verify transaction is signed properly.
//
// Extract signing key
// Transactions contain a signing key. This allows us to trivially verify a transaction has at least been properly signed
// without going to disk. Each transaction also notes a source account id. This is used to verify that the signing key is
// associated with the account.
// XXX This could be a lot cleaner to prevent unnecessary copying.
NewcoinAddress naSigningPubKey;
if (terSUCCESS == terResult)
naSigningPubKey = NewcoinAddress::createAccountPublic(txn.peekSigningPubKey());
// Consistency: really signed.
if ((terSUCCESS == terResult) && ((params & tepNO_CHECK_SIGN) == 0) && !txn.checkSign(naSigningPubKey))
{
Log(lsWARNING) << "applyTransaction: Invalid transaction: bad signature";
terResult = tenINVALID;
}
STAmount saCost = theConfig.FEE_DEFAULT;
// Customize behavoir based on transaction type.
if (terSUCCESS == terResult)
{
switch (txn.getTxnType())
{
case ttCLAIM:
case ttPASSWORD_SET:
saCost = 0;
break;
case ttPAYMENT:
if (txn.getFlags() & tfCreateAccount)
{
saCost = theConfig.FEE_ACCOUNT_CREATE;
}
break;
case ttNICKNAME_SET:
{
SLE::pointer sleNickname = entryCache(ltNICKNAME, txn.getITFieldH256(sfNickname));
if (!sleNickname)
saCost = theConfig.FEE_NICKNAME_CREATE;
}
break;
case ttACCOUNT_SET:
case ttCREDIT_SET:
case ttINVOICE:
case ttOFFER_CREATE:
case ttOFFER_CANCEL:
case ttPASSWORD_FUND:
case ttWALLET_ADD:
nothing();
break;
case ttINVALID:
Log(lsWARNING) << "applyTransaction: Invalid transaction: ttINVALID transaction type";
terResult = tenINVALID;
break;
default:
Log(lsWARNING) << "applyTransaction: Invalid transaction: unknown transaction type";
terResult = tenUNKNOWN;
break;
}
}
STAmount saPaid = txn.getTransactionFee();
if (terSUCCESS == terResult && (params & tepNO_CHECK_FEE) == tepNONE)
{
if (!saCost.isZero())
{
if (saPaid < saCost)
{
Log(lsINFO) << "applyTransaction: insufficient fee";
terResult = tenINSUF_FEE_P;
}
}
else
{
if (!saPaid.isZero())
{
// Transaction is malformed.
Log(lsWARNING) << "applyTransaction: fee not allowed";
terResult = tenINSUF_FEE_P;
}
}
}
// Get source account ID.
mTxnAccountID = txn.getSourceAccount().getAccountID();
if (terSUCCESS == terResult && !mTxnAccountID)
{
Log(lsWARNING) << "applyTransaction: bad source id";
terResult = tenINVALID;
}
if (terSUCCESS != terResult)
return terResult;
boost::recursive_mutex::scoped_lock sl(mLedger->mLock);
mTxnAccount = entryCache(ltACCOUNT_ROOT, Ledger::getAccountRootIndex(mTxnAccountID));
// Find source account
// If are only forwarding, due to resource limitations, we might verifying only some transactions, this would be probablistic.
STAmount saSrcBalance;
uint32 t_seq = txn.getSequence();
bool bHaveAuthKey = false;
if (!mTxnAccount)
{
Log(lsTRACE) << str(boost::format("applyTransaction: Delay transaction: source account does not exist: %s") %
txn.getSourceAccount().humanAccountID());
terResult = terNO_ACCOUNT;
}
else
{
saSrcBalance = mTxnAccount->getIValueFieldAmount(sfBalance);
bHaveAuthKey = mTxnAccount->getIFieldPresent(sfAuthorizedKey);
}
// Check if account claimed.
if (terSUCCESS == terResult)
{
switch (txn.getTxnType())
{
case ttCLAIM:
if (bHaveAuthKey)
{
Log(lsWARNING) << "applyTransaction: Account already claimed.";
terResult = tenCLAIMED;
}
break;
default:
nothing();
break;
}
}
// Consistency: Check signature
if (terSUCCESS == terResult)
{
switch (txn.getTxnType())
{
case ttCLAIM:
// Transaction's signing public key must be for the source account.
// To prove the master private key made this transaction.
if (naSigningPubKey.getAccountID() != mTxnAccountID)
{
// Signing Pub Key must be for Source Account ID.
Log(lsWARNING) << "sourceAccountID: " << naSigningPubKey.humanAccountID();
Log(lsWARNING) << "txn accountID: " << txn.getSourceAccount().humanAccountID();
terResult = tenBAD_CLAIM_ID;
}
break;
case ttPASSWORD_SET:
// Transaction's signing public key must be for the source account.
// To prove the master private key made this transaction.
if (naSigningPubKey.getAccountID() != mTxnAccountID)
{
// Signing Pub Key must be for Source Account ID.
Log(lsWARNING) << "sourceAccountID: " << naSigningPubKey.humanAccountID();
Log(lsWARNING) << "txn accountID: " << txn.getSourceAccount().humanAccountID();
terResult = tenBAD_SET_ID;
}
break;
default:
// Verify the transaction's signing public key is the key authorized for signing.
if (bHaveAuthKey && naSigningPubKey.getAccountID() == mTxnAccount->getIValueFieldAccount(sfAuthorizedKey).getAccountID())
{
// Authorized to continue.
nothing();
}
else if (naSigningPubKey.getAccountID() == mTxnAccountID)
{
// Authorized to continue.
nothing();
}
else if (bHaveAuthKey)
{
Log(lsINFO) << "applyTransaction: Delay: Not authorized to use account.";
terResult = terBAD_AUTH;
}
else
{
Log(lsINFO) << "applyTransaction: Invalid: Not authorized to use account.";
terResult = terBAD_AUTH_MASTER;
}
break;
}
}
// Deduct the fee, so it's not available during the transaction.
// Will only write the account back, if the transaction succeeds.
if (terSUCCESS != terResult || saCost.isZero())
{
nothing();
}
else if (saSrcBalance < saPaid)
{
Log(lsINFO)
<< str(boost::format("applyTransaction: Delay: insufficent balance: balance=%s paid=%s")
% saSrcBalance.getText()
% saPaid.getText());
terResult = terINSUF_FEE_B;
}
else
{
mTxnAccount->setIFieldAmount(sfBalance, saSrcBalance - saPaid);
}
// Validate sequence
if (terSUCCESS != terResult)
{
nothing();
}
else if (!saCost.isZero())
{
uint32 a_seq = mTxnAccount->getIFieldU32(sfSequence);
Log(lsTRACE) << "Aseq=" << a_seq << ", Tseq=" << t_seq;
if (t_seq != a_seq)
{
if (a_seq < t_seq)
{
Log(lsINFO) << "applyTransaction: future sequence number";
terResult = terPRE_SEQ;
}
else if (mLedger->hasTransaction(txID))
{
Log(lsWARNING) << "applyTransaction: duplicate sequence number";
terResult = terALREADY;
}
else
{
Log(lsWARNING) << "applyTransaction: past sequence number";
terResult = terPAST_SEQ;
}
}
else
{
mTxnAccount->setIFieldU32(sfSequence, t_seq + 1);
}
}
else
{
Log(lsINFO) << "applyTransaction: Zero cost transaction";
if (t_seq)
{
Log(lsINFO) << "applyTransaction: bad sequence for pre-paid transaction";
terResult = terPAST_SEQ;
}
}
if (terSUCCESS == terResult)
{
entryModify(mTxnAccount);
mOrigNodes = mNodes.duplicate();
switch (txn.getTxnType())
{
case ttACCOUNT_SET:
terResult = doAccountSet(txn);
break;
case ttCLAIM:
terResult = doClaim(txn);
break;
case ttCREDIT_SET:
terResult = doCreditSet(txn);
break;
case ttINVALID:
Log(lsINFO) << "applyTransaction: invalid type";
terResult = tenINVALID;
break;
case ttINVOICE:
terResult = doInvoice(txn);
break;
case ttOFFER_CREATE:
terResult = doOfferCreate(txn);
break;
case ttOFFER_CANCEL:
terResult = doOfferCancel(txn);
break;
case ttNICKNAME_SET:
terResult = doNicknameSet(txn);
break;
case ttPASSWORD_FUND:
terResult = doPasswordFund(txn);
break;
case ttPASSWORD_SET:
terResult = doPasswordSet(txn);
break;
case ttPAYMENT:
terResult = doPayment(txn);
break;
case ttWALLET_ADD:
terResult = doWalletAdd(txn);
break;
default:
terResult = tenUNKNOWN;
break;
}
}
std::string strToken;
std::string strHuman;
transResultInfo(terResult, strToken, strHuman);
Log(lsINFO) << "applyTransaction: terResult=" << strToken << " : " << terResult << " : " << strHuman;
if (terSUCCESS == terResult)
{
txnWrite();
Serializer s;
txn.add(s);
// XXX add failed status too
// XXX do fees as need.
if (!mLedger->addTransaction(txID, s))
assert(false);
if ((params & tepUPDATE_TOTAL) != tepNONE)
mLedger->destroyCoins(saPaid.getNValue());
}
mTxnAccount = SLE::pointer();
mNodes.clear();
mOrigNodes.clear();
mUnfunded.clear();
return terResult;
}
TransactionEngineResult TransactionEngine::doAccountSet(const SerializedTransaction& txn)
{
Log(lsINFO) << "doAccountSet>";
//
// EmailHash
//
if (txn.getITFieldPresent(sfEmailHash))
{
uint128 uHash = txn.getITFieldH128(sfEmailHash);
if (uHash.isZero())
{
Log(lsINFO) << "doAccountSet: unset email hash";
mTxnAccount->makeIFieldAbsent(sfEmailHash);
}
else
{
Log(lsINFO) << "doAccountSet: set email hash";
mTxnAccount->setIFieldH128(sfEmailHash, uHash);
}
}
//
// WalletLocator
//
if (txn.getITFieldPresent(sfWalletLocator))
{
uint256 uHash = txn.getITFieldH256(sfWalletLocator);
if (uHash.isZero())
{
Log(lsINFO) << "doAccountSet: unset wallet locator";
mTxnAccount->makeIFieldAbsent(sfEmailHash);
}
else
{
Log(lsINFO) << "doAccountSet: set wallet locator";
mTxnAccount->setIFieldH256(sfWalletLocator, uHash);
}
}
//
// MessageKey
//
if (!txn.getITFieldPresent(sfMessageKey))
{
nothing();
}
else if (mTxnAccount->getIFieldPresent(sfMessageKey))
{
Log(lsINFO) << "doAccountSet: can not change message key";
return tenMSG_SET;
}
else
{
Log(lsINFO) << "doAccountSet: set message key";
mTxnAccount->setIFieldVL(sfMessageKey, txn.getITFieldVL(sfMessageKey));
}
//
// Domain
//
if (txn.getITFieldPresent(sfDomain))
{
std::vector<unsigned char> vucDomain = txn.getITFieldVL(sfDomain);
if (vucDomain.empty())
{
Log(lsINFO) << "doAccountSet: unset domain";
mTxnAccount->makeIFieldAbsent(sfDomain);
}
else
{
Log(lsINFO) << "doAccountSet: set domain";
mTxnAccount->setIFieldVL(sfDomain, vucDomain);
}
}
//
// TransferRate
//
if (txn.getITFieldPresent(sfTransferRate))
{
uint32 uRate = txn.getITFieldU32(sfTransferRate);
if (!uRate)
{
Log(lsINFO) << "doAccountSet: unset transfer rate";
mTxnAccount->makeIFieldAbsent(sfTransferRate);
}
else
{
Log(lsINFO) << "doAccountSet: set transfer rate";
mTxnAccount->setIFieldU32(sfTransferRate, uRate);
}
}
//
// PublishHash && PublishSize
//
bool bPublishHash = txn.getITFieldPresent(sfPublishHash);
bool bPublishSize = txn.getITFieldPresent(sfPublishSize);
if (bPublishHash ^ bPublishSize)
{
Log(lsINFO) << "doAccountSet: bad publish";
return tenBAD_PUBLISH;
}
else if (bPublishHash && bPublishSize)
{
uint256 uHash = txn.getITFieldH256(sfPublishHash);
uint32 uSize = txn.getITFieldU32(sfPublishSize);
if (uHash.isZero())
{
Log(lsINFO) << "doAccountSet: unset publish";
mTxnAccount->makeIFieldAbsent(sfPublishHash);
mTxnAccount->makeIFieldAbsent(sfPublishSize);
}
else
{
Log(lsINFO) << "doAccountSet: set publish";
mTxnAccount->setIFieldH256(sfPublishHash, uHash);
mTxnAccount->setIFieldU32(sfPublishSize, uSize);
}
}
Log(lsINFO) << "doAccountSet<";
return terSUCCESS;
}
TransactionEngineResult TransactionEngine::doClaim(const SerializedTransaction& txn)
{
Log(lsINFO) << "doClaim>";
TransactionEngineResult terResult = setAuthorized(txn, true);
Log(lsINFO) << "doClaim<";
return terResult;
}
TransactionEngineResult TransactionEngine::doCreditSet(const SerializedTransaction& txn)
{
TransactionEngineResult terResult = terSUCCESS;
Log(lsINFO) << "doCreditSet>";
// Check if destination makes sense.
uint160 uDstAccountID = txn.getITFieldAccount(sfDestination);
if (!uDstAccountID)
{
Log(lsINFO) << "doCreditSet: Invalid transaction: Destination account not specifed.";
return tenDST_NEEDED;
}
else if (mTxnAccountID == uDstAccountID)
{
Log(lsINFO) << "doCreditSet: Invalid transaction: Can not extend credit to self.";
return tenDST_IS_SRC;
}
SLE::pointer sleDst = entryCache(ltACCOUNT_ROOT, Ledger::getAccountRootIndex(uDstAccountID));
if (!sleDst)
{
Log(lsINFO) << "doCreditSet: Delay transaction: Destination account does not exist.";
return terNO_DST;
}
bool bFlipped = mTxnAccountID > uDstAccountID;
uint32 uFlags = bFlipped ? lsfLowIndexed : lsfHighIndexed;
bool bLimitAmount = txn.getITFieldPresent(sfLimitAmount);
STAmount saLimitAmount = bLimitAmount ? txn.getITFieldAmount(sfLimitAmount) : STAmount();
bool bQualityIn = txn.getITFieldPresent(sfQualityIn);
uint32 uQualityIn = bQualityIn ? txn.getITFieldU32(sfQualityIn) : 0;
bool bQualityOut = txn.getITFieldPresent(sfQualityOut);
uint32 uQualityOut = bQualityIn ? txn.getITFieldU32(sfQualityOut) : 0;
uint160 uCurrencyID = saLimitAmount.getCurrency();
STAmount saBalance(uCurrencyID);
bool bAddIndex = false;
bool bDelIndex = false;
SLE::pointer sleRippleState = entryCache(ltRIPPLE_STATE, Ledger::getRippleStateIndex(mTxnAccountID, uDstAccountID, uCurrencyID));
if (sleRippleState)
{
// A line exists in one or more directions.
#if 0
if (saLimitAmount.isZero())
{
// Zeroing line.
uint160 uLowID = sleRippleState->getIValueFieldAccount(sfLowID).getAccountID();
uint160 uHighID = sleRippleState->getIValueFieldAccount(sfHighID).getAccountID();
bool bLow = uLowID == uSrcAccountID;
bool bHigh = uLowID == uDstAccountID;
bool bBalanceZero = sleRippleState->getIValueFieldAmount(sfBalance).isZero();
STAmount saDstLimit = sleRippleState->getIValueFieldAmount(bSendLow ? sfLowLimit : sfHighLimit);
bool bDstLimitZero = saDstLimit.isZero();
assert(bLow || bHigh);
if (bBalanceZero && bDstLimitZero)
{
// Zero balance and eliminating last limit.
bDelIndex = true;
terResult = dirDelete(false, uSrcRef, Ledger::getRippleDirIndex(mTxnAccountID), sleRippleState->getIndex());
}
}
#endif
if (!bDelIndex)
{
if (bLimitAmount)
sleRippleState->setIFieldAmount(bFlipped ? sfHighLimit: sfLowLimit , saLimitAmount);
if (!bQualityIn)
{
nothing();
}
else if (uQualityIn)
{
sleRippleState->setIFieldU32(bFlipped ? sfLowQualityIn : sfHighQualityIn, uQualityIn);
}
else
{
sleRippleState->makeIFieldAbsent(bFlipped ? sfLowQualityIn : sfHighQualityIn);
}
if (!bQualityOut)
{
nothing();
}
else if (uQualityOut)
{
sleRippleState->setIFieldU32(bFlipped ? sfLowQualityOut : sfHighQualityOut, uQualityOut);
}
else
{
sleRippleState->makeIFieldAbsent(bFlipped ? sfLowQualityOut : sfHighQualityOut);
}
bAddIndex = !(sleRippleState->getFlags() & uFlags);
if (bAddIndex)
sleRippleState->setFlag(uFlags);
entryModify(sleRippleState);
}
Log(lsINFO) << "doCreditSet: Modifying ripple line: bAddIndex=" << bAddIndex << " bDelIndex=" << bDelIndex;
}
// Line does not exist.
else if (saLimitAmount.isZero())
{
Log(lsINFO) << "doCreditSet: Redundant: Setting non-existant ripple line to 0.";
return terNO_LINE_NO_ZERO;
}
else
{
// Create a new ripple line.
STAmount saZero(uCurrencyID);
bAddIndex = true;
sleRippleState = entryCreate(ltRIPPLE_STATE, Ledger::getRippleStateIndex(mTxnAccountID, uDstAccountID, uCurrencyID));
Log(lsINFO) << "doCreditSet: Creating ripple line: " << sleRippleState->getIndex().ToString();
sleRippleState->setFlag(uFlags);
sleRippleState->setIFieldAmount(sfBalance, saZero); // Zero balance in currency.
sleRippleState->setIFieldAmount(bFlipped ? sfHighLimit : sfLowLimit, saLimitAmount);
sleRippleState->setIFieldAmount(bFlipped ? sfLowLimit : sfHighLimit, saZero);
sleRippleState->setIFieldAccount(bFlipped ? sfHighID : sfLowID, mTxnAccountID);
sleRippleState->setIFieldAccount(bFlipped ? sfLowID : sfHighID, uDstAccountID);
if (uQualityIn)
sleRippleState->setIFieldU32(bFlipped ? sfLowQualityIn : sfHighQualityIn, uQualityIn);
if (uQualityOut)
sleRippleState->setIFieldU32(bFlipped ? sfLowQualityOut : sfHighQualityOut, uQualityOut);
}
if (bAddIndex)
{
uint64 uSrcRef; // Ignored, ripple_state dirs never delete.
// XXX Make dirAdd more flexiable to take vector.
terResult = dirAdd(uSrcRef, Ledger::getRippleDirIndex(mTxnAccountID), sleRippleState->getIndex());
}
Log(lsINFO) << "doCreditSet<";
return terResult;
}
TransactionEngineResult TransactionEngine::doNicknameSet(const SerializedTransaction& txn)
{
std::cerr << "doNicknameSet>" << std::endl;
uint256 uNickname = txn.getITFieldH256(sfNickname);
bool bMinOffer = txn.getITFieldPresent(sfMinimumOffer);
STAmount saMinOffer = bMinOffer ? txn.getITFieldAmount(sfAmount) : STAmount();
SLE::pointer sleNickname = entryCache(ltNICKNAME, uNickname);
if (sleNickname)
{
// Edit old entry.
sleNickname->setIFieldAccount(sfAccount, mTxnAccountID);
if (bMinOffer && !saMinOffer.isZero())
{
sleNickname->setIFieldAmount(sfMinimumOffer, saMinOffer);
}
else
{
sleNickname->makeIFieldAbsent(sfMinimumOffer);
}
entryModify(sleNickname);
}
else
{
// Make a new entry.
// XXX Need to include authorization limiting for first year.
sleNickname = entryCreate(ltNICKNAME, Ledger::getNicknameIndex(uNickname));
std::cerr << "doNicknameSet: Creating nickname node: " << sleNickname->getIndex().ToString() << std::endl;
sleNickname->setIFieldAccount(sfAccount, mTxnAccountID);
if (bMinOffer && !saMinOffer.isZero())
sleNickname->setIFieldAmount(sfMinimumOffer, saMinOffer);
}
std::cerr << "doNicknameSet<" << std::endl;
return terSUCCESS;
}
TransactionEngineResult TransactionEngine::doPasswordFund(const SerializedTransaction& txn)
{
std::cerr << "doPasswordFund>" << std::endl;
uint160 uDstAccountID = txn.getITFieldAccount(sfDestination);
SLE::pointer sleDst = mTxnAccountID == uDstAccountID
? mTxnAccount
: entryCache(ltACCOUNT_ROOT, Ledger::getAccountRootIndex(uDstAccountID));
if (!sleDst)
{
// Destination account does not exist.
std::cerr << "doPasswordFund: Delay transaction: Destination account does not exist." << std::endl;
return terSET_MISSING_DST;
}
if (sleDst->getFlags() & lsfPasswordSpent)
{
sleDst->clearFlag(lsfPasswordSpent);
std::cerr << "doPasswordFund: Clearing spent." << sleDst->getFlags() << std::endl;
if (mTxnAccountID != uDstAccountID) {
std::cerr << "doPasswordFund: Destination modified." << std::endl;
entryModify(sleDst);
}
}
std::cerr << "doPasswordFund<" << std::endl;
return terSUCCESS;
}
TransactionEngineResult TransactionEngine::doPasswordSet(const SerializedTransaction& txn)
{
std::cerr << "doPasswordSet>" << std::endl;
if (mTxnAccount->getFlags() & lsfPasswordSpent)
{
std::cerr << "doPasswordSet: Delay transaction: Funds already spent." << std::endl;
return terFUNDS_SPENT;
}
mTxnAccount->setFlag(lsfPasswordSpent);
TransactionEngineResult terResult = setAuthorized(txn, false);
std::cerr << "doPasswordSet<" << std::endl;
return terResult;
}
#ifdef WORK_IN_PROGRESS
// XXX Need to adjust for fees.
// Find offers to satisfy pnDst.
// - Does not adjust any balances as there is at least a forward pass to come.
// --> pnDst.saWanted: currency and amount wanted
// --> pnSrc.saIOURedeem.mCurrency: use this before saIOUIssue, limit to use.
// --> pnSrc.saIOUIssue.mCurrency: use this after saIOURedeem, limit to use.
// <-- pnDst.saReceive
// <-- pnDst.saIOUForgive
// <-- pnDst.saIOUAccept
// <-- terResult : terSUCCESS = no error and if !bAllowPartial complelely satisfied wanted.
// <-> usOffersDeleteAlways:
// <-> usOffersDeleteOnSuccess:
TransactionEngineResult calcOfferFill(paymentNode& pnSrc, paymentNode& pnDst, bool bAllowPartial)
{
TransactionEngineResult terResult;
if (pnDst.saWanted.isNative())
{
// Transfer stamps.
STAmount saSrcFunds = pnSrc.saAccount->accountHolds(pnSrc.saAccount, uint160(0), uint160(0));
if (saSrcFunds && (bAllowPartial || saSrcFunds > pnDst.saWanted))
{
pnSrc.saSend = min(saSrcFunds, pnDst.saWanted);
pnDst.saReceive = pnSrc.saSend;
}
else
{
terResult = terINSUF_PATH;
}
}
else
{
// Ripple funds.
{
prv->saSend = min(prv->account->saBalance(), cur->saWanted);
// Redeem to limit.
terResult = calcOfferFill(
accountHolds(pnSrc.saAccount, pnDst.saWanted.getCurrency(), pnDst.saWanted.getIssuer()),
pnSrc.saIOURedeem,
pnDst.saIOUForgive,
bAllowPartial);
if (terSUCCESS == terResult)
{
// Issue to wanted.
terResult = calcOfferFill(
pnDst.saWanted, // As much as wanted is available, limited by credit limit.
pnSrc.saIOUIssue,
pnDst.saIOUAccept,
bAllowPartial);
}
if (terSUCCESS == terResult && !bAllowPartial)
{
STAmount saTotal = pnDst.saIOUForgive + pnSrc.saIOUAccept;
if (saTotal != saWanted)
terResult = terINSUF_PATH;
}
}
return terResult;
}
// Get the next offer limited by funding.
// - Stop when becomes unfunded.
void TransactionEngine::calcOfferBridgeNext(
const uint256& uBookRoot, // --> Which order book to look in.
const uint256& uBookEnd, // --> Limit of how far to look.
uint256& uBookDirIndex, // <-> Current directory. <-- 0 = no offer available.
uint64& uBookDirNode, // <-> Which node. 0 = first.
unsigned int& uBookDirEntry, // <-> Entry in node. 0 = first.
STAmount& saOfferIn, // <-- How much to pay in, fee inclusive, to get saOfferOut out.
STAmount& saOfferOut // <-- How much offer pays out.
)
{
saOfferIn = 0; // XXX currency & issuer
saOfferOut = 0; // XXX currency & issuer
bool bDone = false;
while (!bDone)
{
uint256 uOfferIndex;
// Get uOfferIndex.
dirNext(uBookRoot, uBookEnd, uBookDirIndex, uBookDirNode, uBookDirEntry, uOfferIndex);
SLE::pointer sleOffer = entryCache(ltOFFER, uOfferIndex);
uint160 uOfferOwnerID = sleOffer->getIValueFieldAccount(sfAccount).getAccountID();
STAmount saOfferPays = sleOffer->getIValueFieldAmount(sfTakerGets);
STAmount saOfferGets = sleOffer->getIValueFieldAmount(sfTakerPays);
if (sleOffer->getIFieldPresent(sfGetsIssuer))
saOfferPays.setIssuer(sleOffer->getIValueFieldAccount(sfGetsIssuer).getAccountID());
if (sleOffer->getIFieldPresent(sfPaysIssuer))
saOfferGets.setIssuer(sleOffer->getIValueFieldAccount(sfPaysIssuer).getAccountID());
if (sleOffer->getIFieldPresent(sfExpiration) && sleOffer->getIFieldU32(sfExpiration) <= mLedger->getParentCloseTimeNC())
{
// Offer is expired.
Log(lsINFO) << "calcOfferFirst: encountered expired offer";
}
else
{
STAmount saOfferFunds = accountFunds(uOfferOwnerID, saOfferPays);
// Outbound fees are paid by offer owner.
// XXX Calculate outbound fee rate.
if (saOfferPays.isNative())
{
// No additional fees for stamps.
nothing();
}
else if (saOfferPays.getIssuer() == uOfferOwnerID)
{
// Offerer is issue own IOUs.
// No fees at this exact point, XXX receiving node may charge a fee.
// XXX Make sure has a credit line with receiver, limit by credit line.
nothing();
// XXX Broken - could be issuing or redeeming or both.
}
else
{
// Offer must be redeeming IOUs.
// No additional
// XXX Broken
}
if (!saOfferFunds.isPositive())
{
// Offer is unfunded.
Log(lsINFO) << "calcOfferFirst: offer unfunded: delete";
}
else if (saOfferFunds >= saOfferPays)
{
// Offer fully funded.
// Account transfering funds in to offer always pays inbound fees.
//
saOfferIn = saOfferGets; // XXX Add in fees?
saOfferOut = saOfferPays;
bDone = true;
}
else
{
// Offer partially funded.
// saOfferIn/saOfferFunds = saOfferGets/saOfferPays
// XXX Round such that all saOffer funds are exhausted.
saOfferIn = (saOfferFunds*saOfferGets)/saOfferPays; // XXX Add in fees?
saOfferOut = saOfferFunds;
bDone = true;
}
}
if (!bDone)
{
// mUnfunded.insert(uOfferIndex);
}
}
while (bNext);
}
// If either currency is not stamps, then also calculates vs stamp bridge.
// --> saWanted: Limit of how much is wanted out.
// <-- saPay: How much to pay into the offer.
// <-- saGot: How much to the offer pays out. Never more than saWanted.
void TransactionEngine::calcNodeOfferReverse(
const uint160& uPayCurrency,
const uint160& uPayIssuerID,
const STAmount& saWanted, // Driver
STAmount& saPay,
STAmount& saGot
) const
{
TransactionEngineResult terResult = tenUNKNOWN;
bool bDirectNext = true; // True, if need to load.
uint256 uDirectQuality;
uint256 uDirectTip = Ledger::getBookBase(uGetsCurrency, uGetsIssuerID, uPaysCurrency, uPaysIssuerID);
uint256 uDirectEnd = Ledger::getQualityNext(uDirectTip);
bool bBridge = true; // True, if bridging active. False, missing an offer.
uint256 uBridgeQuality;
STAmount saBridgeIn; // Amount available.
STAmount saBridgeOut;
bool bInNext = true; // True, if need to load.
STAmount saInIn; // Amount available. Consumed in loop. Limited by offer funding.
STAmount saInOut;
uint256 uInTip; // Current entry.
uint256 uInEnd;
unsigned int uInEntry;
bool bOutNext = true;
STAmount saOutIn;
STAmount saOutOut;
uint256 uOutTip;
uint256 uOutEnd;
unsigned int uOutEntry;
saPay.zero();
saPay.setCurrency(uPayCurrency);
saPay.setIssuer(uPayIssuerID);
saNeed = saWanted;
if (!saWanted.isNative() && !uTakerCurrency.isZero())
{
// Bridging
uInTip = Ledger::getBookBase(uPayCurrency, uPayIssuerID, uint160(0), uint160(0));
uInEnd = Ledger::getQualityNext(uInTip);
uOutTip = Ledger::getBookBase(uint160(0), uint160(0), saWanted.getCurrency(), saWanted.getIssuer());
uOutEnd = Ledger::getQualityNext(uInTip);
}
while (tenUNKNOWN == terResult)
{
if (saNeed == saWanted)
{
// Got all.
saGot = saWanted;
terResult = terSUCCESS;
}
else
{
// Calculate next tips, if needed.
if (bDirectNext)
{
// Find next direct offer.
uDirectTip = mLedger->getNextLedgerIndex(uDirectTip, uDirectEnd);
if (!!uDirectTip)
{
sleDirectDir = entryCache(ltDIR_NODE, uDirectTip);
// XXX Need to calculate the real quality: including fees.
uDirectQuality = STAmount::getQualityNext(uDirectTip);
}
bDirectNext = false;
}
if (bBridge && (bInNext || bOutNext))
{
// Bridging and need to calculate next bridge rate.
// A bridge can consist of multiple offers. As offer's are consumed, the effective rate changes.
if (bInNext)
{
// sleInDir = entryCache(ltDIR_NODE, mLedger->getNextLedgerIndex(uInIndex, uInEnd));
// Get the next funded offer.
offerBridgeNext(uInIndex, uInEnd, uInEntry, saInIn, saInOut); // Get offer limited by funding.
bInNext = false;
}
if (bOutNext)
{
// sleOutDir = entryCache(ltDIR_NODE, mLedger->getNextLedgerIndex(uOutIndex, uOutEnd));
offerNext(uOutIndex, uOutEnd, uOutEntry, saOutIn, saOutOut);
bOutNext = false;
}
if (!uInIndex || !uOutIndex)
{
bBridge = false; // No more offers to bridge.
}
else
{
// Have bridge in and out entries.
// Calculate bridge rate. Out offer pay ripple fee. In offer fee is added to in cost.
saBridgeOut.zero();
if (saInOut < saOutIn)
{
// Limit by in.
// XXX Need to include fees in saBridgeIn.
saBridgeIn = saInIn; // All of in
// Limit bridge out: saInOut/saBridgeOut = saOutIn/saOutOut
// Round such that we would take all of in offer, otherwise would have leftovers.
saBridgeOut = (saInOut * saOutOut) / saOutIn;
}
else if (saInOut > saOutIn)
{
// Limit by out, if at all.
// XXX Need to include fees in saBridgeIn.
// Limit bridge in:saInIn/saInOuts = aBridgeIn/saOutIn
// Round such that would take all of out offer.
saBridgeIn = (saInIn * saOutIn) / saInOuts;
saBridgeOut = saOutOut; // All of out.
}
else
{
// Entries match,
// XXX Need to include fees in saBridgeIn.
saBridgeIn = saInIn; // All of in
saBridgeOut = saOutOut; // All of out.
}
uBridgeQuality = STAmount::getRate(saBridgeIn, saBridgeOut); // Inclusive of fees.
}
}
if (bBridge)
{
bUseBridge = !uDirectTip || (uBridgeQuality < uDirectQuality)
}
else if (!!uDirectTip)
{
bUseBridge = false
}
else
{
// No more offers. Declare success, even if none returned.
saGot = saWanted-saNeed;
terResult = terSUCCESS;
}
if (terSUCCESS != terResult)
{
STAmount& saAvailIn = bUseBridge ? saBridgeIn : saDirectIn;
STAmount& saAvailOut = bUseBridge ? saBridgeOut : saDirectOut;
if (saAvailOut > saNeed)
{
// Consume part of offer. Done.
saNeed = 0;
saPay += (saNeed*saAvailIn)/saAvailOut; // Round up, prefer to pay more.
}
else
{
// Consume entire offer.
saNeed -= saAvailOut;
saPay += saAvailIn;
if (bUseBridge)
{
// Consume bridge out.
if (saOutOut == saAvailOut)
{
// Consume all.
saOutOut = 0;
saOutIn = 0;
bOutNext = true;
}
else
{
// Consume portion of bridge out, must be consuming all of bridge in.
// saOutIn/saOutOut = saSpent/saAvailOut
// Round?
saOutIn -= (saOutIn*saAvailOut)/saOutOut;
saOutOut -= saAvailOut;
}
// Consume bridge in.
if (saOutIn == saAvailIn)
{
// Consume all.
saInOut = 0;
saInIn = 0;
bInNext = true;
}
else
{
// Consume portion of bridge in, must be consuming all of bridge out.
// saInIn/saInOut = saAvailIn/saPay
// Round?
saInOut -= (saInOut*saAvailIn)/saInIn;
saInIn -= saAvailIn;
}
}
else
{
bDirectNext = true;
}
}
}
}
}
}
#endif
// From the destination work towards the source calculating how much must be asked for.
// --> bAllowPartial: If false, fail if can't meet requirements.
// <-- bSuccess: true=success, false=insufficient funds / liqudity.
// <-> pnNodes:
// --> [end]saWanted.mAmount
// --> [all]saWanted.mCurrency
// --> [all]saAccount
// <-> [0]saWanted.mAmount : --> limit, <-- actual
// XXX Disallow looping.
// XXX With multiple path and due to offers, must consider consumed.
bool TransactionEngine::calcPathReverse(PathState::pointer pspCur)
{
TransactionEngineResult terResult = tenUNKNOWN;
unsigned int uLast = pspCur->vpnNodes.size() - 1;
unsigned int uIndex = pspCur->vpnNodes.size();
while (tenUNKNOWN == terResult && uIndex--)
{
// Calculate:
// (1) saPrvRedeem & saPrvIssue from saCurRevRedeem & saCurRevIssue.
// (2) saCurWanted by summing saRevRedeem & saRevIssue. <-- XXX might not need this as it can be infered.
// XXX We might not need to do 0.
paymentNode& prvPN = uIndex ? pspCur->vpnNodes[uIndex-1] : pspCur->vpnNodes[0];
paymentNode& curPN = pspCur->vpnNodes[uIndex];
paymentNode& nxtPN = uIndex == uLast ? pspCur->vpnNodes[uLast] : pspCur->vpnNodes[uIndex+1];
bool bAccount = !!(curPN.uFlags & STPathElement::typeAccount);
bool bRedeem = !!(curPN.uFlags & STPathElement::typeRedeem);
bool bIssue = !!(curPN.uFlags & STPathElement::typeIssue);
uint160& uPrvAccountID = prvPN.uAccountID;
uint160& uCurAccountID = curPN.uAccountID;
uint160& uNxtAccountID = nxtPN.uAccountID;
uint160& uCurrencyID = curPN.uCurrencyID;
if (uIndex == uLast)
{
// saCurWanted set by caller.
uint32 uQualityIn = rippleQualityIn(uCurAccountID, uPrvAccountID, uCurrencyID);
STAmount saPrvBalance = rippleBalance(uCurAccountID, uPrvAccountID, uCurrencyID);
STAmount saPrvLimit = rippleLimit(uCurAccountID, uPrvAccountID, uCurAccountID);
STAmount saPrvRedeemReq = saPrvBalance.isNative() ? -saPrvBalance : STAmount(uCurrencyID, 0);
STAmount& saPrvRedeemAct = prvPN.saRevRedeem; // What previous should redeem with cur.
STAmount& saPrvIssueAct = prvPN.saRevIssue;
STAmount saPrvIssueReq = saPrvBalance.isPositive() ? saPrvLimit - saPrvBalance : saPrvLimit;
STAmount saCurWantedReq = pspCur->saOutReq;
STAmount saCurWantedAct;
// Calculate redeem
if (bRedeem
&& saPrvRedeemReq) // Previous has IOUs to redeem.
{
// Redeem at 1:1
saCurWantedAct = MIN(saPrvRedeemReq, saCurWantedReq);
saPrvRedeemAct = saCurWantedAct;
}
// Calculate issuing.
if (bIssue
&& saCurWantedReq != saCurWantedAct // Need more.
&& saPrvIssueReq) // Will accept IOUs.
{
// Rate: quality in : 1.0
calcNodeRipple(uQualityIn, QUALITY_ONE, saPrvIssueReq, saCurWantedReq, saPrvIssueAct, saCurWantedAct);
}
if (!saCurWantedAct)
{
// Must have processed something.
terResult = tenBAD_AMOUNT;
}
}
else if (!bAccount)
{
// Offer node.
// Ripple or transfering from previous node through this offer to next node.
// Current node has a credit line with next node.
// Next node will receive either its own IOUs or this nodes IOUs.
// We limit what this node sends by this nodes redeem and issue max.
// This allows path lists to be strictly redeem.
// XXX Make sure offer book was not previously mentioned.
#if 0
uint160 uPrvCurrency = curPN.uFlags & PF_WANTED_CURRENCY
? curPN->saWanted.getCurrency()
: saSendMax.getCurrency();
uint160 uPrvIssuer = curPN.uFlags & PF_WANTED_ISSUER
? curPN->saWanted.getIssuer()
: saSendMax.getIssuer();
calcNodeOfferReverse(
uTakerCurrency,
uTakerIssuer,
nxtPN->saWanted, // Driver.
uTakerPaid,
uTakerGot,
uOwnerPaid,
uOwnerGot,
);
if (uOwnerPaid.isZero())
{
terResult = terZERO; // Path contributes nothing.
}
else
{
// Update wanted.
// Save sent amount
}
#endif
}
// Ripple through account.
else if (!bIssue && !bRedeem)
{
// XXX This might be checked sooner.
terResult = tenBAD_PATH; // Must be able to redeem and issue.
}
else if (!uIndex)
{
// Done. No previous. We know what we would like to redeem and issue.
nothing();
}
else
{
// Rippling through this accounts balances.
// No currency change.
// Given saCurRedeem & saCurIssue figure out saPrvRedeem & saPrvIssue.
uint32 uQualityIn = rippleQualityIn(uCurAccountID, uPrvAccountID, uCurrencyID);
uint32 uQualityOut = rippleQualityOut(uCurAccountID, uNxtAccountID, uCurrencyID);
STAmount saPrvBalance = rippleBalance(uCurAccountID, uPrvAccountID, uCurrencyID);
STAmount saPrvLimit = rippleLimit(uCurAccountID, uPrvAccountID, uCurrencyID);
STAmount saPrvRedeemReq = saPrvBalance.isNegative() ? -saPrvBalance : STAmount(uCurrencyID, 0);
STAmount& saPrvRedeemAct = prvPN.saRevRedeem;
STAmount saPrvIssueReq = saPrvLimit - saPrvBalance;
STAmount& saPrvIssueAct = prvPN.saRevIssue;
const STAmount& saCurRedeemReq = curPN.saRevRedeem;
STAmount saCurRedeemAct;
const STAmount& saCurIssueReq = curPN.saRevIssue;
STAmount saCurIssueAct; // Track progess.
// Previous redeem part 1: redeem -> redeem
if (bRedeem
&& saCurRedeemReq // Next wants us to redeem.
&& saPrvBalance.isNegative()) // Previous has IOUs to redeem.
{
// Rate : 1.0 : quality out
calcNodeRipple(QUALITY_ONE, uQualityOut, saPrvRedeemReq, saCurRedeemReq, saPrvRedeemAct, saCurRedeemAct);
}
// Previous redeem part 2: redeem -> issue.
if (bIssue
&& saCurRedeemReq != saCurRedeemAct // Can only if issue if more can not be redeemed.
&& saPrvBalance.isNegative() // Previous still has IOUs.
&& saCurIssueReq) // Need some issued.
{
// Rate : 1.0 : transfer_rate
calcNodeRipple(QUALITY_ONE, rippleTransfer(uCurAccountID), saPrvRedeemReq, saCurIssueReq, saPrvRedeemAct, saCurIssueAct);
}
// Previous issue part 1: issue -> redeem
if (bRedeem
&& saCurRedeemReq != saCurRedeemAct // Can only redeem if more to be redeemed.
&& !saPrvBalance.isNegative()) // Previous has no IOUs.
{
// Rate: quality in : quality out
calcNodeRipple(uQualityIn, uQualityOut, saPrvIssueReq, saCurRedeemReq, saPrvIssueAct, saCurRedeemAct);
}
// Previous issue part 2 : issue -> issue
if (bIssue
&& saCurRedeemReq != saCurRedeemAct // Can only if issue if more can not be redeemed.
&& !saPrvBalance.isNegative() // Previous has no IOUs.
&& saCurIssueReq != saCurIssueAct) // Need some issued.
{
// Rate: quality in : 1.0
calcNodeRipple(uQualityIn, QUALITY_ONE, saPrvIssueReq, saCurIssueReq, saPrvIssueAct, saCurIssueAct);
}
if (!saCurRedeemAct && !saCurIssueAct)
{
// Must want something.
terResult = tenBAD_AMOUNT;
}
}
}
return tenUNKNOWN == terResult;
}
// Cur is the driver and will be filled exactly.
// uQualityIn -> uQualityOut
// saPrvReq -> saCurReq
// sqPrvAct -> saCurAct
// This routine works backwards as it calculates previous wants based on previous credit limits and current wants.
// This routine works forwards as it calculates current deliver based on previous delivery limits and current wants.
void TransactionEngine::calcNodeRipple(
const uint32 uQualityIn,
const uint32 uQualityOut,
const STAmount& saPrvReq, // --> in limit including fees
const STAmount& saCurReq, // --> out limit (driver)
STAmount& saPrvAct, // <-> in limit including achieved
STAmount& saCurAct) // <-> out limit achieved.
{
STAmount saPrv = saPrvReq-saPrvAct;
STAmount saCur = saCurReq-saCurAct;
if (uQualityIn >= uQualityOut)
{
// No fee.
STAmount saTransfer = MIN(saPrv, saCur);
saPrvAct += saTransfer;
saCurAct += saTransfer;
}
else
{
// Fee.
STAmount saCurIn = STAmount::divide(STAmount::multiply(saCur, uQualityOut, CURRENCY_ONE), uQualityIn, CURRENCY_ONE);
if (saCurIn >= saPrv)
{
// All of cur. Some amount of prv.
saCurAct = saCurReq;
saPrvAct += saCurIn;
}
else
{
// A part of cur. All of prv. (cur as driver)
STAmount saCurOut = STAmount::divide(STAmount::multiply(saPrv, uQualityIn, CURRENCY_ONE), uQualityOut, CURRENCY_ONE);
saCurAct += saCurOut;
saPrvAct = saPrvReq;
}
}
}
// From the source work toward the destination calculate how much is transfered at each step and finally.
// <-> pnNodes:
// --> [0]saWanted.mAmount
// --> [all]saWanted.saSend
// --> [all]saWanted.IOURedeem
// --> [all]saWanted.IOUIssue
// --> [all]saAccount
void TransactionEngine::calcPathForward(PathState::pointer pspCur)
{
unsigned int uIndex = 0;
unsigned int uEnd = pspCur->vpnNodes.size();
unsigned int uLast = uEnd - 1;
while (uIndex != uEnd)
{
// Calculate (1) sending by fullfilling next wants and (2) setting current wants.
paymentNode& prvPN = uIndex ? pspCur->vpnNodes[uIndex-1] : pspCur->vpnNodes[0];
paymentNode& curPN = pspCur->vpnNodes[uIndex];
paymentNode& nxtPN = uIndex == uLast ? pspCur->vpnNodes[uLast] : pspCur->vpnNodes[uIndex+1];
// XXX Assume rippling.
if (!uIndex)
{
// First node, calculate amount to send.
STAmount& saCurRedeemReq = curPN.saRevRedeem;
STAmount& saCurRedeemAct = curPN.saFwdRedeem;
STAmount& saCurIssueReq = curPN.saRevIssue;
STAmount& saCurIssueAct = curPN.saFwdIssue;
STAmount& saCurSendMaxReq = pspCur->saInReq;
STAmount& saCurSendMaxAct = pspCur->saInAct;
if (saCurRedeemReq)
{
// Redeem requested.
saCurRedeemAct = MIN(saCurRedeemAct, saCurSendMaxReq);
saCurSendMaxAct = saCurRedeemAct;
}
if (saCurIssueReq && saCurSendMaxReq != saCurRedeemAct)
{
// Issue requested and not over budget.
saCurIssueAct = MIN(saCurSendMaxReq-saCurRedeemAct, saCurIssueReq);
// saCurSendMaxAct += saCurIssueReq; // Not needed.
}
}
else if (uIndex == uLast)
{
// Last node. Accept all funds. Calculate amount actually to credit.
uint32 uQualityIn = rippleQualityIn(curPN.uAccountID, prvPN.uAccountID, curPN.uCurrencyID);
STAmount& saPrvRedeemReq = prvPN.saFwdRedeem;
STAmount& saPrvIssueReq = prvPN.saFwdIssue;
STAmount saPrvIssueAct = uQualityIn >= QUALITY_ONE
? saPrvIssueReq // No fee.
: STAmount::multiply(saPrvIssueReq, uQualityIn, curPN.uCurrencyID); // Fee.
STAmount& saCurReceive = pspCur->saOutAct;
// Amount to credit.
saCurReceive = saPrvRedeemReq+saPrvIssueAct;
// Actually receive.
rippleCredit(curPN.uAccountID, prvPN.uAccountID, saCurReceive);
}
else
{
// Handle middle node.
// The previous nodes tells want it wants to push through to current.
// The current node know what it would push through next.
// Determine for the current node:
// - Output to next node minus fees.
// Perform balance adjustment with previous.
// All of previous output is consumed.
uint160& uCurrencyID = curPN.uCurrencyID;
uint160& uPrvAccountID = prvPN.uAccountID;
uint160& uCurAccountID = curPN.uAccountID;
uint160& uNxtAccountID = nxtPN.uAccountID;
STAmount& saPrvRedeemReq = prvPN.saFwdRedeem;
STAmount saPrvRedeemAct;
STAmount& saPrvIssueReq = prvPN.saFwdIssue;
STAmount saPrvIssueAct;
STAmount& saCurRedeemReq = curPN.saRevRedeem;
STAmount& saCurRedeemAct = curPN.saFwdRedeem;
STAmount& saCurIssueReq = curPN.saRevIssue;
STAmount& saCurIssueAct = curPN.saFwdIssue;
// Have funds in previous node to transfer.
uint32 uQualityIn = rippleQualityIn(uCurAccountID, uPrvAccountID, uCurrencyID);
uint32 uQualityOut = rippleQualityOut(uCurAccountID, uNxtAccountID, uCurrencyID);
// Previous redeem part 1: redeem -> redeem
if (saPrvRedeemReq != saPrvRedeemAct) // Previous wants to redeem. To next must be ok.
{
// Rate : 1.0 : quality out
calcNodeRipple(QUALITY_ONE, uQualityOut, saPrvRedeemReq, saCurRedeemReq, saPrvRedeemAct, saCurRedeemAct);
}
// Previous redeem part 2: redeem -> issue.
// wants to redeem and current would and can issue.
// If redeeming cur to next is done, this implies can issue.
if (saPrvRedeemReq != saPrvRedeemAct // Previous still wants to redeem.
&& saCurRedeemReq == saCurRedeemAct) // Current has more to redeem to next.
{
// Rate : 1.0 : transfer_rate
calcNodeRipple(QUALITY_ONE, rippleTransfer(uCurAccountID), saPrvRedeemReq, saCurIssueReq, saPrvRedeemAct, saCurIssueAct);
}
// Previous issue part 1: issue -> redeem
if (saPrvIssueReq != saPrvIssueAct // Previous wants to issue.
&& saCurRedeemReq == saCurRedeemAct) // Current has more to redeem to next.
{
// Rate: quality in : quality out
calcNodeRipple(uQualityIn, uQualityOut, saPrvIssueReq, saCurRedeemReq, saPrvIssueAct, saCurRedeemAct);
}
// Previous issue part 2 : issue -> issue
if (saPrvIssueReq != saPrvIssueAct) // Previous wants to issue. To next must be ok.
{
// Rate: quality in : 1.0
calcNodeRipple(uQualityIn, QUALITY_ONE, saPrvIssueReq, saCurIssueReq, saPrvIssueAct, saCurIssueAct);
}
// Adjust prv --> cur balance : take all inbound
// XXX Currency must be in amount.
rippleCredit(uCurAccountID, uPrvAccountID, saPrvRedeemReq + saPrvIssueReq);
}
}
}
bool PathState::less(const PathState::pointer& lhs, const PathState::pointer& rhs)
{
// Return true, iff lhs has less priority than rhs.
if (lhs->uQuality != rhs->uQuality)
return lhs->uQuality > rhs->uQuality; // Bigger is worse.
// Best quanity is second rank.
if (lhs->saOutAct != rhs->saOutAct)
return lhs->saOutAct < rhs->saOutAct; // Smaller is worse.
// Path index is third rank.
return lhs->mIndex > rhs->mIndex; // Bigger is worse.
}
// <-- bValid: true, if node is valid.
bool PathState::pushNode(int iType, uint160 uAccountID, uint160 uCurrencyID, uint160 uIssuerID)
{
paymentNode pnCur;
bool bFirst = vpnNodes.empty();
const paymentNode& pnPrv = bFirst ? paymentNode() : vpnNodes.back();
bool bAccount = !!(iType & STPathElement::typeAccount);
bool bCurrency = !!(iType & STPathElement::typeCurrency);
bool bIssuer = !!(iType & STPathElement::typeIssuer);
bool bRedeem = !!(iType & STPathElement::typeRedeem);
bool bIssue = !!(iType & STPathElement::typeIssue);
bool bValid = true;
pnCur.uFlags = iType;
if (iType & ~STPathElement::typeValidBits)
{
bValid = false;
}
else if (bAccount)
{
if (bRedeem || bIssue)
{
// Account link
pnCur.uAccountID = uAccountID;
pnCur.uCurrencyID = bCurrency ? uCurrencyID : pnPrv.uCurrencyID;
pnCur.uIssuerID = bIssuer ? uIssuerID : uAccountID;
// An intermediate node may be implied.
// An offer may be implied
if (uCurrencyID != pnPrv.uCurrencyID)
{
// Implied preceeding offer.
bValid = pushNode(
0,
ACCOUNT_ONE,
CURRENCY_ONE, // Inherit from previous
ACCOUNT_ONE); // Inherit from previous
}
else if (uIssuerID != pnPrv.uIssuerID)
{
// Implied preceeding account.
bValid = pushNode(
STPathElement::typeAccount
| STPathElement::typeRedeem
| STPathElement::typeIssue,
uIssuerID,
CURRENCY_ONE, // Inherit from previous
ACCOUNT_ONE); // Default same as account.
}
}
else
{
bValid = false;
}
}
else
{
// Offer link
if (bRedeem || bIssue)
{
bValid = false;
}
else
{
pnCur.uCurrencyID = bCurrency ? uCurrencyID : pnPrv.uCurrencyID;
pnCur.uIssuerID = bIssuer ? uIssuerID : uAccountID;
}
}
vpnNodes.push_back(pnCur);
return bValid;
}
PathState::PathState(
int iIndex,
const LedgerEntrySet& lesSource,
const STPath& spSourcePath,
uint160 uReceiverID,
uint160 uSenderID,
STAmount saSend,
STAmount saSendMax,
bool bPartialPayment
)
: mIndex(iIndex), uQuality(0), bDirty(true)
{
lesEntries = lesSource.duplicate();
saOutReq = saSend;
saInReq = saSendMax;
pushNode(STPathElement::typeAccount, uSenderID, saSendMax.getCurrency(), saSendMax.getIssuer());
BOOST_FOREACH(const STPathElement& speElement, spSourcePath)
{
pushNode(speElement.getNodeType(), speElement.getAccountID(), speElement.getCurrency(), speElement.getIssuerID());
}
pushNode(STPathElement::typeAccount, uReceiverID, saOutReq.getCurrency(), saOutReq.getIssuer());
}
// Calculate the next increment of a path.
void TransactionEngine::pathNext(PathState::pointer pspCur)
{
// The next state is what is available in preference order.
// This is calculated when referenced accounts changed.
if (calcPathReverse(pspCur))
{
calcPathForward(pspCur);
}
else
{
// Mark path as inactive.
pspCur->uQuality = 0;
pspCur->bDirty = false;
}
}
// Apply an increment of the path, then calculate the next increment.
void TransactionEngine::pathApply(PathState::pointer pspCur)
{
}
// XXX Need to audit for things like setting accountID not having memory.
TransactionEngineResult TransactionEngine::doPayment(const SerializedTransaction& txn)
{
// Ripple if source or destination is non-native or if there are paths.
uint32 uTxFlags = txn.getFlags();
bool bCreate = !!(uTxFlags & tfCreateAccount);
bool bNoRippleDirect = !!(uTxFlags & tfNoRippleDirect);
bool bPartialPayment = !!(uTxFlags & tfPartialPayment);
bool bPaths = txn.getITFieldPresent(sfPaths);
bool bMax = txn.getITFieldPresent(sfSendMax);
uint160 uDstAccountID = txn.getITFieldAccount(sfDestination);
STAmount saDstAmount = txn.getITFieldAmount(sfAmount);
STAmount saMaxAmount = bMax ? txn.getITFieldAmount(sfSendMax) : saDstAmount;
uint160 uSrcCurrency = saMaxAmount.getCurrency();
uint160 uDstCurrency = saDstAmount.getCurrency();
if (!uDstAccountID)
{
Log(lsINFO) << "doPayment: Invalid transaction: Payment destination account not specifed.";
return tenDST_NEEDED;
}
else if (!saDstAmount.isPositive())
{
Log(lsINFO) << "doPayment: Invalid transaction: bad amount: " << saDstAmount.getHumanCurrency() << " " << saDstAmount.getText();
return tenBAD_AMOUNT;
}
else if (mTxnAccountID == uDstAccountID && uSrcCurrency == uDstCurrency && !bPaths)
{
Log(lsINFO) << boost::str(boost::format("doPayment: Invalid transaction: Redunant transaction: src=%s, dst=%s, src_cur=%s, dst_cur=%s")
% mTxnAccountID.ToString()
% uDstAccountID.ToString()
% uSrcCurrency.ToString()
% uDstCurrency.ToString());
return tenREDUNDANT;
}
SLE::pointer sleDst = entryCache(ltACCOUNT_ROOT, Ledger::getAccountRootIndex(uDstAccountID));
if (!sleDst)
{
// Destination account does not exist.
if (bCreate && !saDstAmount.isNative())
{
// This restriction could be relaxed.
Log(lsINFO) << "doPayment: Invalid transaction: Create account may only fund XNS.";
return tenCREATEXNS;
}
else if (!bCreate)
{
Log(lsINFO) << "doPayment: Delay transaction: Destination account does not exist.";
return terNO_DST;
}
// Create the account.
sleDst = entryCreate(ltACCOUNT_ROOT, Ledger::getAccountRootIndex(uDstAccountID));
sleDst->setIFieldAccount(sfAccount, uDstAccountID);
sleDst->setIFieldU32(sfSequence, 1);
}
// Destination exists.
else if (bCreate)
{
// Retryable: if account created this ledger, reordering might allow account to be made by this transaction.
Log(lsINFO) << "doPayment: Invalid transaction: Account already created.";
return terCREATED;
}
else
{
entryModify(sleDst);
}
bool bRipple = bPaths || bMax || !saDstAmount.isNative();
if (!bRipple)
{
// Direct XNS payment.
STAmount saSrcXNSBalance = mTxnAccount->getIValueFieldAmount(sfBalance);
if (saSrcXNSBalance < saDstAmount)
{
// Transaction might succeed, if applied in a different order.
Log(lsINFO) << "doPayment: Delay transaction: Insufficent funds.";
return terUNFUNDED;
}
mTxnAccount->setIFieldAmount(sfBalance, saSrcXNSBalance - saDstAmount);
sleDst->setIFieldAmount(sfBalance, sleDst->getIValueFieldAmount(sfBalance) + saDstAmount);
return terSUCCESS;
}
//
// Ripple payment
//
// XXX Disallow loops in ripple paths
// Try direct ripple first.
if (!bNoRippleDirect && mTxnAccountID != uDstAccountID && uSrcCurrency == uDstCurrency)
{
SLE::pointer sleRippleState = entryCache(ltRIPPLE_STATE, Ledger::getRippleStateIndex(mTxnAccountID, uDstAccountID, uDstCurrency));
if (sleRippleState)
{
// There is a direct credit-line of some direction.
// - We can always pay IOUs back.
// - We can issue IOUs to the limit.
uint160 uLowID = sleRippleState->getIValueFieldAccount(sfLowID).getAccountID();
uint160 uHighID = sleRippleState->getIValueFieldAccount(sfHighID).getAccountID();
bool bSendHigh = uLowID == mTxnAccountID && uHighID == uDstAccountID;
bool bSendLow = uLowID == uDstAccountID && uHighID == mTxnAccountID;
// Flag we need if we end up owing IOUs.
uint32 uFlags = bSendHigh ? lsfLowIndexed : lsfHighIndexed;
assert(bSendLow || bSendHigh);
STAmount saDstLimit = sleRippleState->getIValueFieldAmount(bSendLow ? sfLowLimit : sfHighLimit);
STAmount saDstBalance = sleRippleState->getIValueFieldAmount(sfBalance);
if (bSendHigh)
{
// Put balance in dst terms.
saDstBalance.negate();
}
saDstBalance += saDstAmount;
if (saDstBalance > saDstLimit)
{
// Would exceed credit limit.
// YYY Note: in the future could push out other credits to make payment fit.
Log(lsINFO) << "doPayment: Delay transaction: Over limit: proposed balance="
<< saDstBalance.getText()
<< " limit="
<< saDstLimit.getText();
return terOVER_LIMIT;
}
if (saDstBalance.isZero())
{
// XXX May be able to delete indexes for credit limits which are zero.
nothing();
}
else if (saDstBalance.isNegative())
{
// dst still has outstanding IOUs, sle already indexed.
nothing();
}
// src has outstanding IOUs, sle should be indexed.
else if (! (sleRippleState->getFlags() & uFlags))
{
// Need to add index.
TransactionEngineResult terResult = terSUCCESS;
uint64 uSrcRef; // Ignored, ripple_state dirs never delete.
terResult = dirAdd(
uSrcRef,
Ledger::getRippleDirIndex(mTxnAccountID), // The source ended up owing.
sleRippleState->getIndex()); // Adding current entry.
if (terSUCCESS != terResult)
return terResult;
sleRippleState->setFlag(uFlags); // Note now indexed.
}
if (bSendHigh)
{
// Put balance in low terms.
saDstBalance.negate();
}
sleRippleState->setIFieldAmount(sfBalance, saDstBalance);
entryModify(sleRippleState);
return terSUCCESS;
}
}
STPathSet spsPaths = txn.getITFieldPathSet(sfPaths);
if (!spsPaths.isEmpty())
{
Log(lsINFO) << "doPayment: Invalid transaction: No paths.";
return tenRIPPLE_EMPTY;
}
else if (spsPaths.getPathCount() > RIPPLE_PATHS_MAX)
{
return tenBAD_PATH_COUNT;
}
// Incrementally search paths.
std::vector<PathState::pointer> vpsPaths;
BOOST_FOREACH(const STPath& spPath, spsPaths)
{
vpsPaths.push_back(PathState::createPathState(
vpsPaths.size(),
mNodes,
spPath,
uDstAccountID,
mTxnAccountID,
saDstAmount,
saMaxAmount,
bPartialPayment
));
}
TransactionEngineResult terResult;
STAmount saPaid;
STAmount saWanted;
terResult = tenUNKNOWN;
while (tenUNKNOWN == terResult)
{
PathState::pointer pspBest;
// Find the best path.
BOOST_FOREACH(PathState::pointer pspCur, vpsPaths)
{
if (pspCur->bDirty)
{
pspCur->bDirty = false;
pspCur->lesEntries = mNodes.duplicate();
// XXX Compute increment
pathNext(pspCur);
}
if (!pspBest || (pspCur->uQuality && PathState::less(pspBest, pspCur)))
pspBest = pspCur;
}
if (!pspBest)
{
//
// Apply path.
//
// Install changes for path.
mNodes.swapWith(pspBest->lesEntries);
// Mark that path as dirty.
pspBest->bDirty = true;
// Mark as dirty any other path that intersected.
BOOST_FOREACH(PathState::pointer& pspOther, vpsPaths)
{
// Look for intersection of best and the others.
// - Will forget the intersection applied.
// - Anything left will not interfere with it.
// - Will remember the non-intersection non-applied for future consideration.
if (!pspOther->bDirty
&& pspOther->uQuality
&& LedgerEntrySet::intersect(pspBest->lesEntries, pspOther->lesEntries))
pspOther->bDirty = true;
}
// Figure out if done.
if (tenUNKNOWN == terResult && saPaid == saWanted)
{
terResult = terSUCCESS;
}
}
// Ran out of paths.
else if (!bPartialPayment)
{
// Partial payment not allowed.
terResult = terPATH_PARTIAL; // XXX No effect, except unfunded and charge fee.
}
else if (saPaid.isZero())
{
// Nothing claimed.
terResult = terPATH_EMPTY; // XXX No effect except unfundeds and charge fee.
// XXX
}
else
{
terResult = terSUCCESS;
}
}
Log(lsINFO) << "doPayment: Delay transaction: No ripple paths could be satisfied.";
return terBAD_RIPPLE;
}
TransactionEngineResult TransactionEngine::doWalletAdd(const SerializedTransaction& txn)
{
std::cerr << "WalletAdd>" << std::endl;
std::vector<unsigned char> vucPubKey = txn.getITFieldVL(sfPubKey);
std::vector<unsigned char> vucSignature = txn.getITFieldVL(sfSignature);
uint160 uAuthKeyID = txn.getITFieldAccount(sfAuthorizedKey);
NewcoinAddress naMasterPubKey = NewcoinAddress::createAccountPublic(vucPubKey);
uint160 uDstAccountID = naMasterPubKey.getAccountID();
if (!naMasterPubKey.accountPublicVerify(Serializer::getSHA512Half(uAuthKeyID.begin(), uAuthKeyID.size()), vucSignature))
{
std::cerr << "WalletAdd: unauthorized: bad signature " << std::endl;
return tenBAD_ADD_AUTH;
}
SLE::pointer sleDst = entryCache(ltACCOUNT_ROOT, Ledger::getAccountRootIndex(uDstAccountID));
if (sleDst)
{
std::cerr << "WalletAdd: account already created" << std::endl;
return tenCREATED;
}
STAmount saAmount = txn.getITFieldAmount(sfAmount);
STAmount saSrcBalance = mTxnAccount->getIValueFieldAmount(sfBalance);
if (saSrcBalance < saAmount)
{
std::cerr
<< str(boost::format("WalletAdd: Delay transaction: insufficent balance: balance=%s amount=%s")
% saSrcBalance.getText()
% saAmount.getText())
<< std::endl;
return terUNFUNDED;
}
// Deduct initial balance from source account.
mTxnAccount->setIFieldAmount(sfBalance, saSrcBalance-saAmount);
// Create the account.
sleDst = entryCreate(ltACCOUNT_ROOT, Ledger::getAccountRootIndex(uDstAccountID));
sleDst->setIFieldAccount(sfAccount, uDstAccountID);
sleDst->setIFieldU32(sfSequence, 1);
sleDst->setIFieldAmount(sfBalance, saAmount);
sleDst->setIFieldAccount(sfAuthorizedKey, uAuthKeyID);
std::cerr << "WalletAdd<" << std::endl;
return terSUCCESS;
}
TransactionEngineResult TransactionEngine::doInvoice(const SerializedTransaction& txn)
{
return tenUNKNOWN;
}
// Take as much as possible. Adjusts account balances. Charges fees on top to taker.
// --> uBookBase: The order book to take against.
// --> saTakerPays: What the taker offers (w/ issuer)
// --> saTakerGets: What the taker wanted (w/ issuer)
// <-- saTakerPaid: What taker paid not including fees. To reduce an offer.
// <-- saTakerGot: What taker got not including fees. To reduce an offer.
// <-- terResult: terSUCCESS or terNO_ACCOUNT
// Note: All SLE modifications must always occur even on failure.
// XXX: Fees should be paid by the source of the currency.
TransactionEngineResult TransactionEngine::takeOffers(
bool bPassive,
const uint256& uBookBase,
const uint160& uTakerAccountID,
const SLE::pointer& sleTakerAccount,
const STAmount& saTakerPays,
const STAmount& saTakerGets,
STAmount& saTakerPaid,
STAmount& saTakerGot)
{
assert(!saTakerPays.isZero() && !saTakerGets.isZero());
Log(lsINFO) << "takeOffers: against book: " << uBookBase.ToString();
uint256 uTipIndex = uBookBase;
uint256 uBookEnd = Ledger::getQualityNext(uBookBase);
uint64 uTakeQuality = STAmount::getRate(saTakerGets, saTakerPays);
uint160 uTakerPaysAccountID = saTakerPays.getIssuer();
uint160 uTakerPaysCurrency = saTakerPays.getCurrency();
uint160 uTakerGetsAccountID = saTakerGets.getIssuer();
uint160 uTakerGetsCurrency = saTakerGets.getCurrency();
TransactionEngineResult terResult = tenUNKNOWN;
saTakerPaid = 0;
saTakerGot = 0;
while (tenUNKNOWN == terResult)
{
SLE::pointer sleOfferDir;
uint64 uTipQuality;
// Figure out next offer to take, if needed.
if (saTakerGets != saTakerGot && saTakerPays != saTakerPaid)
{
// Taker has needs.
sleOfferDir = entryCache(ltDIR_NODE, mLedger->getNextLedgerIndex(uTipIndex, uBookEnd));
if (sleOfferDir)
{
Log(lsINFO) << "takeOffers: possible counter offer found";
uTipIndex = sleOfferDir->getIndex();
uTipQuality = Ledger::getQuality(uTipIndex);
}
else
{
Log(lsINFO) << "takeOffers: counter offer book is empty: "
<< uTipIndex.ToString()
<< " ... "
<< uBookEnd.ToString();
}
}
if (!sleOfferDir || uTakeQuality < uTipQuality || (bPassive && uTakeQuality == uTipQuality))
{
// Done.
Log(lsINFO) << "takeOffers: done";
terResult = terSUCCESS;
}
else
{
// Have an offer to consider.
Log(lsINFO) << "takeOffers: considering dir : " << sleOfferDir->getJson(0);
SLE::pointer sleBookNode;
unsigned int uBookEntry;
uint256 uOfferIndex;
dirFirst(uTipIndex, sleBookNode, uBookEntry, uOfferIndex);
SLE::pointer sleOffer = entryCache(ltOFFER, uOfferIndex);
Log(lsINFO) << "takeOffers: considering offer : " << sleOffer->getJson(0);
uint160 uOfferOwnerID = sleOffer->getIValueFieldAccount(sfAccount).getAccountID();
STAmount saOfferPays = sleOffer->getIValueFieldAmount(sfTakerGets);
STAmount saOfferGets = sleOffer->getIValueFieldAmount(sfTakerPays);
if (sleOffer->getIFieldPresent(sfGetsIssuer))
saOfferPays.setIssuer(sleOffer->getIValueFieldAccount(sfGetsIssuer).getAccountID());
if (sleOffer->getIFieldPresent(sfPaysIssuer))
saOfferGets.setIssuer(sleOffer->getIValueFieldAccount(sfPaysIssuer).getAccountID());
if (sleOffer->getIFieldPresent(sfExpiration) && sleOffer->getIFieldU32(sfExpiration) <= mLedger->getParentCloseTimeNC())
{
// Offer is expired. Delete it.
Log(lsINFO) << "takeOffers: encountered expired offer";
offerDelete(sleOffer, uOfferIndex, uOfferOwnerID);
mUnfunded.insert(uOfferIndex);
}
else if (uOfferOwnerID == uTakerAccountID)
{
// Would take own offer. Consider old offer unfunded.
Log(lsINFO) << "takeOffers: encountered taker's own old offer";
offerDelete(sleOffer, uOfferIndex, uOfferOwnerID);
}
else
{
// Get offer funds available.
Log(lsINFO) << "takeOffers: saOfferPays=" << saOfferPays.getFullText();
STAmount saOfferFunds = accountFunds(uOfferOwnerID, saOfferPays);
STAmount saTakerFunds = accountFunds(uTakerAccountID, saTakerPays);
SLE::pointer sleOfferAccount; // Owner of offer.
if (!saOfferFunds.isPositive())
{
// Offer is unfunded, possibly due to previous balance action.
Log(lsINFO) << "takeOffers: offer unfunded: delete";
offerDelete(sleOffer, uOfferIndex, uOfferOwnerID);
mUnfunded.insert(uOfferIndex);
}
else
{
STAmount saPay = saTakerPays - saTakerPaid;
if (saTakerFunds < saPay)
saPay = saTakerFunds;
STAmount saSubTakerPaid;
STAmount saSubTakerGot;
Log(lsINFO) << "takeOffers: applyOffer: saTakerPays: " << saTakerPays.getFullText();
Log(lsINFO) << "takeOffers: applyOffer: saTakerPaid: " << saTakerPaid.getFullText();
Log(lsINFO) << "takeOffers: applyOffer: saTakerFunds: " << saTakerFunds.getFullText();
Log(lsINFO) << "takeOffers: applyOffer: saOfferFunds: " << saOfferFunds.getFullText();
Log(lsINFO) << "takeOffers: applyOffer: saPay: " << saPay.getFullText();
Log(lsINFO) << "takeOffers: applyOffer: saOfferPays: " << saOfferPays.getFullText();
Log(lsINFO) << "takeOffers: applyOffer: saOfferGets: " << saOfferGets.getFullText();
Log(lsINFO) << "takeOffers: applyOffer: saTakerPays: " << saTakerPays.getFullText();
Log(lsINFO) << "takeOffers: applyOffer: saTakerGets: " << saTakerGets.getFullText();
bool bOfferDelete = STAmount::applyOffer(
saOfferFunds,
saPay, // Driver XXX need to account for fees.
saOfferPays,
saOfferGets,
saTakerPays,
saTakerGets,
saSubTakerPaid,
saSubTakerGot);
Log(lsINFO) << "takeOffers: applyOffer: saSubTakerPaid: " << saSubTakerPaid.getFullText();
Log(lsINFO) << "takeOffers: applyOffer: saSubTakerGot: " << saSubTakerGot.getFullText();
// Adjust offer
if (bOfferDelete)
{
// Offer now fully claimed or now unfunded.
Log(lsINFO) << "takeOffers: offer claimed: delete";
offerDelete(sleOffer, uOfferIndex, uOfferOwnerID);
}
else
{
Log(lsINFO) << "takeOffers: offer partial claim: modify";
// Offer owner will pay less. Subtract what taker just got.
sleOffer->setIFieldAmount(sfTakerGets, saOfferPays -= saSubTakerGot);
// Offer owner will get less. Subtract what owner just paid.
sleOffer->setIFieldAmount(sfTakerPays, saOfferGets -= saSubTakerPaid);
entryModify(sleOffer);
}
// Offer owner pays taker.
saSubTakerGot.setIssuer(uTakerGetsAccountID); // XXX Move this earlier?
accountSend(uOfferOwnerID, uTakerAccountID, saSubTakerGot);
saTakerGot += saSubTakerGot;
// Taker pays offer owner.
saSubTakerPaid.setIssuer(uTakerPaysAccountID);
accountSend(uTakerAccountID, uOfferOwnerID, saSubTakerPaid);
saTakerPaid += saSubTakerPaid;
}
}
}
}
return terResult;
}
TransactionEngineResult TransactionEngine::doOfferCreate(const SerializedTransaction& txn)
{
Log(lsWARNING) << "doOfferCreate> " << txn.getJson(0);
uint32 txFlags = txn.getFlags();
bool bPassive = !!(txFlags & tfPassive);
uint160 uPaysIssuerID = txn.getITFieldAccount(sfPaysIssuer);
uint160 uGetsIssuerID = txn.getITFieldAccount(sfGetsIssuer);
STAmount saTakerPays = txn.getITFieldAmount(sfTakerPays);
saTakerPays.setIssuer(uPaysIssuerID);
Log(lsWARNING) << "doOfferCreate: saTakerPays=" << saTakerPays.getFullText();
STAmount saTakerGets = txn.getITFieldAmount(sfTakerGets);
saTakerGets.setIssuer(uGetsIssuerID);
Log(lsWARNING) << "doOfferCreate: saTakerGets=" << saTakerGets.getFullText();
uint32 uExpiration = txn.getITFieldU32(sfExpiration);
bool bHaveExpiration = txn.getITFieldPresent(sfExpiration);
uint32 uSequence = txn.getSequence();
uint256 uLedgerIndex = Ledger::getOfferIndex(mTxnAccountID, uSequence);
SLE::pointer sleOffer = entryCreate(ltOFFER, uLedgerIndex);
Log(lsINFO) << "doOfferCreate: Creating offer node: " << uLedgerIndex.ToString() << " uSequence=" << uSequence;
uint160 uPaysCurrency = saTakerPays.getCurrency();
uint160 uGetsCurrency = saTakerGets.getCurrency();
uint64 uRate = STAmount::getRate(saTakerGets, saTakerPays);
TransactionEngineResult terResult = terSUCCESS;
uint256 uDirectory; // Delete hints.
uint64 uOwnerNode;
uint64 uBookNode;
if (bHaveExpiration && !uExpiration)
{
Log(lsWARNING) << "doOfferCreate: Malformed offer: bad expiration";
terResult = tenBAD_EXPIRATION;
}
else if (bHaveExpiration && mLedger->getParentCloseTimeNC() >= uExpiration)
{
Log(lsWARNING) << "doOfferCreate: Expired transaction: offer expired";
terResult = tenEXPIRED;
}
else if (saTakerPays.isNative() && saTakerGets.isNative())
{
Log(lsWARNING) << "doOfferCreate: Malformed offer: XNS for XNS";
terResult = tenBAD_OFFER;
}
else if (saTakerPays.isZero() || saTakerGets.isZero())
{
Log(lsWARNING) << "doOfferCreate: Malformed offer: bad amount";
terResult = tenBAD_OFFER;
}
else if (uPaysCurrency == uGetsCurrency && uPaysIssuerID == uGetsIssuerID)
{
Log(lsWARNING) << "doOfferCreate: Malformed offer: redundant offer";
terResult = tenREDUNDANT;
}
else if (saTakerPays.isNative() != uPaysIssuerID.isZero() || saTakerGets.isNative() != uGetsIssuerID.isZero())
{
Log(lsWARNING) << "doOfferCreate: Malformed offer: bad issuer";
terResult = tenBAD_ISSUER;
}
else if (!accountFunds(mTxnAccountID, saTakerGets).isPositive())
{
Log(lsWARNING) << "doOfferCreate: delay: offers must be funded";
terResult = terUNFUNDED;
}
if (terSUCCESS == terResult && !saTakerPays.isNative())
{
SLE::pointer sleTakerPays = entryCache(ltACCOUNT_ROOT, Ledger::getAccountRootIndex(uPaysIssuerID));
if (!sleTakerPays)
{
Log(lsWARNING) << "doOfferCreate: delay: can't receive IOUs from non-existant issuer: " << NewcoinAddress::createHumanAccountID(uPaysIssuerID);
terResult = terNO_ACCOUNT;
}
}
if (terSUCCESS == terResult)
{
STAmount saOfferPaid;
STAmount saOfferGot;
uint256 uTakeBookBase = Ledger::getBookBase(uGetsCurrency, uGetsIssuerID, uPaysCurrency, uPaysIssuerID);
Log(lsINFO) << str(boost::format("doOfferCreate: take against book: %s : %s/%s -> %s/%s")
% uTakeBookBase.ToString()
% saTakerGets.getHumanCurrency()
% NewcoinAddress::createHumanAccountID(saTakerGets.getIssuer())
% saTakerPays.getHumanCurrency()
% NewcoinAddress::createHumanAccountID(saTakerPays.getIssuer()));
// Take using the parameters of the offer.
terResult = takeOffers(
bPassive,
uTakeBookBase,
mTxnAccountID,
mTxnAccount,
saTakerGets,
saTakerPays,
saOfferPaid, // How much was spent.
saOfferGot // How much was got.
);
Log(lsWARNING) << "doOfferCreate: takeOffers=" << terResult;
Log(lsWARNING) << "doOfferCreate: takeOffers: saOfferPaid=" << saOfferPaid.getFullText();
Log(lsWARNING) << "doOfferCreate: takeOffers: saOfferGot=" << saOfferGot.getFullText();
Log(lsWARNING) << "doOfferCreate: takeOffers: saTakerPays=" << saTakerPays.getFullText();
Log(lsWARNING) << "doOfferCreate: takeOffers: saTakerGets=" << saTakerGets.getFullText();
if (terSUCCESS == terResult)
{
saTakerPays -= saOfferGot; // Reduce payin from takers by what offer just got.
saTakerGets -= saOfferPaid; // Reduce payout to takers by what srcAccount just paid.
}
}
Log(lsWARNING) << "doOfferCreate: takeOffers: saTakerPays=" << saTakerPays.getFullText();
Log(lsWARNING) << "doOfferCreate: takeOffers: saTakerGets=" << saTakerGets.getFullText();
Log(lsWARNING) << "doOfferCreate: takeOffers: saTakerGets=" << NewcoinAddress::createHumanAccountID(saTakerGets.getIssuer());
Log(lsWARNING) << "doOfferCreate: takeOffers: mTxnAccountID=" << NewcoinAddress::createHumanAccountID(mTxnAccountID);
Log(lsWARNING) << "doOfferCreate: takeOffers: funds=" << accountFunds(mTxnAccountID, saTakerGets).getFullText();
// Log(lsWARNING) << "doOfferCreate: takeOffers: uPaysIssuerID=" << NewcoinAddress::createHumanAccountID(uPaysIssuerID);
// Log(lsWARNING) << "doOfferCreate: takeOffers: uGetsIssuerID=" << NewcoinAddress::createHumanAccountID(uGetsIssuerID);
if (terSUCCESS == terResult
&& !saTakerPays.isZero() // Still wanting something.
&& !saTakerGets.isZero() // Still offering something.
&& accountFunds(mTxnAccountID, saTakerGets).isPositive()) // Still funded.
{
// We need to place the remainder of the offer into its order book.
// Add offer to owner's directory.
terResult = dirAdd(uOwnerNode, Ledger::getOwnerDirIndex(mTxnAccountID), uLedgerIndex);
if (terSUCCESS == terResult)
{
uint256 uBookBase = Ledger::getBookBase(uPaysCurrency, uPaysIssuerID, uGetsCurrency, uGetsIssuerID);
Log(lsINFO) << str(boost::format("doOfferCreate: adding to book: %s : %s/%s -> %s/%s")
% uBookBase.ToString()
% saTakerPays.getHumanCurrency()
% NewcoinAddress::createHumanAccountID(saTakerPays.getIssuer())
% saTakerGets.getHumanCurrency()
% NewcoinAddress::createHumanAccountID(saTakerGets.getIssuer()));
uDirectory = Ledger::getQualityIndex(uBookBase, uRate); // Use original rate.
// Add offer to order book.
terResult = dirAdd(uBookNode, uDirectory, uLedgerIndex);
}
if (terSUCCESS == terResult)
{
// Log(lsWARNING) << "doOfferCreate: uPaysIssuerID=" << NewcoinAddress::createHumanAccountID(uPaysIssuerID);
// Log(lsWARNING) << "doOfferCreate: uGetsIssuerID=" << NewcoinAddress::createHumanAccountID(uGetsIssuerID);
// Log(lsWARNING) << "doOfferCreate: saTakerPays.isNative()=" << saTakerPays.isNative();
// Log(lsWARNING) << "doOfferCreate: saTakerGets.isNative()=" << saTakerGets.isNative();
// Log(lsWARNING) << "doOfferCreate: uPaysCurrency=" << saTakerPays.getHumanCurrency();
// Log(lsWARNING) << "doOfferCreate: uGetsCurrency=" << saTakerGets.getHumanCurrency();
sleOffer->setIFieldAccount(sfAccount, mTxnAccountID);
sleOffer->setIFieldU32(sfSequence, uSequence);
sleOffer->setIFieldH256(sfBookDirectory, uDirectory);
sleOffer->setIFieldAmount(sfTakerPays, saTakerPays);
sleOffer->setIFieldAmount(sfTakerGets, saTakerGets);
sleOffer->setIFieldU64(sfOwnerNode, uOwnerNode);
sleOffer->setIFieldU64(sfBookNode, uBookNode);
if (!saTakerPays.isNative())
sleOffer->setIFieldAccount(sfPaysIssuer, uPaysIssuerID);
if (!saTakerGets.isNative())
sleOffer->setIFieldAccount(sfGetsIssuer, uGetsIssuerID);
if (uExpiration)
sleOffer->setIFieldU32(sfExpiration, uExpiration);
if (bPassive)
sleOffer->setFlag(lsfPassive);
}
}
return terResult;
}
TransactionEngineResult TransactionEngine::doOfferCancel(const SerializedTransaction& txn)
{
TransactionEngineResult terResult;
uint32 uSequence = txn.getITFieldU32(sfOfferSequence);
uint256 uOfferIndex = Ledger::getOfferIndex(mTxnAccountID, uSequence);
SLE::pointer sleOffer = entryCache(ltOFFER, uOfferIndex);
if (sleOffer)
{
Log(lsWARNING) << "doOfferCancel: uSequence=" << uSequence;
terResult = offerDelete(sleOffer, uOfferIndex, mTxnAccountID);
}
else
{
Log(lsWARNING) << "doOfferCancel: offer not found: "
<< NewcoinAddress::createHumanAccountID(mTxnAccountID)
<< " : " << uSequence
<< " : " << uOfferIndex.ToString();
terResult = terOFFER_NOT_FOUND;
}
return terResult;
}
TransactionEngineResult TransactionEngine::doTake(const SerializedTransaction& txn)
{
return tenUNKNOWN;
}
TransactionEngineResult TransactionEngine::doStore(const SerializedTransaction& txn)
{
return tenUNKNOWN;
}
TransactionEngineResult TransactionEngine::doDelete(const SerializedTransaction& txn)
{
return tenUNKNOWN;
}
// vim:ts=4
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