commit/024c56d15b51da60007e618b151c02cfee4c9f0a/Units_8h_source.html

//------------------------------------------------------------------------------

/*

    This file is part of rippled: https://github.com/ripple/rippled

    Copyright (c) 2019 Ripple Labs Inc.


    Permission to use, copy, modify, and/or distribute this software for any

    purpose  with  or without fee is hereby granted, provided that the above

    copyright notice and this permission notice appear in all copies.


    THE  SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES

    WITH  REGARD  TO  THIS  SOFTWARE  INCLUDING  ALL  IMPLIED  WARRANTIES  OF

    MERCHANTABILITY  AND  FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR

    ANY  SPECIAL ,  DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES

    WHATSOEVER  RESULTING  FROM  LOSS  OF USE, DATA OR PROFITS, WHETHER IN AN

    ACTION  OF  CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF

    OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.

*/


#ifndef PROTOCOL_UNITS_H_INCLUDED

#define PROTOCOL_UNITS_H_INCLUDED


#include <xrpl/basics/safe_cast.h>

#include <xrpl/beast/utility/Zero.h>

#include <xrpl/beast/utility/instrumentation.h>

#include <xrpl/json/json_value.h>


#include <boost/multiprecision/cpp_int.hpp>

#include <boost/operators.hpp>


#include <iosfwd>

#include <limits>

#include <optional>


namespace ripple {


namespace unit {


struct dropTag;

struct feelevelTag;

struct unitlessTag;


class BipsTag;

class TenthBipsTag;


// These names don't have to be too descriptive, because we're in the "unit"

// namespace.


template <class T>

concept Valid = std::is_class_v<T> && std::is_object_v<typename T::unit_type> &&

    std::is_object_v<typename T::value_type>;


template <class T>

concept Usable = Valid<T> &&

    (std::is_same_v<typename T::unit_type, feelevelTag> ||

     std::is_same_v<typename T::unit_type, unitlessTag> ||

     std::is_same_v<typename T::unit_type, dropTag> ||

     std::is_same_v<typename T::unit_type, BipsTag> ||

     std::is_same_v<typename T::unit_type, TenthBipsTag>);


template <class Other, class VU>

concept Compatible = Valid<VU> && std::is_arithmetic_v<Other> &&

    std::is_arithmetic_v<typename VU::value_type> &&

    std::is_convertible_v<Other, typename VU::value_type>;


template <class T>

concept Integral = std::is_integral_v<T>;


template <class VU>

concept IntegralValue = Integral<typename VU::value_type>;


template <class VU1, class VU2>

concept CastableValue = IntegralValue<VU1> && IntegralValue<VU2> &&

    std::is_same_v<typename VU1::unit_type, typename VU2::unit_type>;


template <class UnitTag, class T>


class ValueUnit : private boost::totally_ordered<ValueUnit<UnitTag, T>>,

                  private boost::additive<ValueUnit<UnitTag, T>>,

                  private boost::equality_comparable<ValueUnit<UnitTag, T>, T>,

                  private boost::dividable<ValueUnit<UnitTag, T>, T>,

                  private boost::modable<ValueUnit<UnitTag, T>, T>,

                  private boost::unit_steppable<ValueUnit<UnitTag, T>>

{

public:

    using unit_type = UnitTag;

    using value_type = T;


private:

    value_type value_;


public:

    ValueUnit() = default;

    constexpr ValueUnit(ValueUnit const& other) = default;

    constexpr ValueUnit&

    operator=(ValueUnit const& other) = default;


    constexpr explicit ValueUnit(beast::Zero) : value_(0)

    {

    }


    constexpr ValueUnit&


    operator=(beast::Zero)

    {

        value_ = 0;

        return *this;

    }


    constexpr explicit ValueUnit(value_type value) : value_(value)

    {

    }


    constexpr ValueUnit&


    operator=(value_type value)

    {

        value_ = value;

        return *this;

    }


    template <Compatible<ValueUnit> Other>


    constexpr ValueUnit(ValueUnit<unit_type, Other> const& value)

        requires SafeToCast<Other, value_type>

        : ValueUnit(safe_cast<value_type>(value.value()))

    {

    }


    constexpr ValueUnit


    operator+(value_type const& rhs) const

    {

        return ValueUnit{value_ + rhs};

    }


    friend constexpr ValueUnit


    operator+(value_type lhs, ValueUnit const& rhs)

    {

        // addition is commutative

        return rhs + lhs;

    }


    constexpr ValueUnit


    operator-(value_type const& rhs) const

    {

        return ValueUnit{value_ - rhs};

    }


    friend constexpr ValueUnit


    operator-(value_type lhs, ValueUnit const& rhs)

    {

        // subtraction is NOT commutative, but (lhs + (-rhs)) is addition, which

        // is

        return -rhs + lhs;

    }


    constexpr ValueUnit


    operator*(value_type const& rhs) const

    {

        return ValueUnit{value_ * rhs};

    }


    friend constexpr ValueUnit


    operator*(value_type lhs, ValueUnit const& rhs)

    {

        // multiplication is commutative

        return rhs * lhs;

    }


    constexpr value_type


    operator/(ValueUnit const& rhs) const

    {

        return value_ / rhs.value_;

    }


    ValueUnit&


    operator+=(ValueUnit const& other)

    {

        value_ += other.value();

        return *this;

    }


    ValueUnit&


    operator-=(ValueUnit const& other)

    {

        value_ -= other.value();

        return *this;

    }


    ValueUnit&


    operator++()

    {

        ++value_;

        return *this;

    }


    ValueUnit&


    operator--()

    {

        --value_;

        return *this;

    }


    ValueUnit&


    operator*=(value_type const& rhs)

    {

        value_ *= rhs;

        return *this;

    }


    ValueUnit&


    operator/=(value_type const& rhs)

    {

        value_ /= rhs;

        return *this;

    }


    template <Integral transparent = value_type>

    ValueUnit&


    operator%=(value_type const& rhs)

    {

        value_ %= rhs;

        return *this;

    }


    ValueUnit


    operator-() const

    {

        static_assert(

            std::is_signed_v<T>, "- operator illegal on unsigned value types");

        return ValueUnit{-value_};

    }


    constexpr bool


    operator==(ValueUnit const& other) const

    {

        return value_ == other.value_;

    }


    template <Compatible<ValueUnit> Other>

    constexpr bool


    operator==(ValueUnit<unit_type, Other> const& other) const

    {

        return value_ == other.value();

    }


    constexpr bool


    operator==(value_type other) const

    {

        return value_ == other;

    }


    template <Compatible<ValueUnit> Other>

    constexpr bool


    operator!=(ValueUnit<unit_type, Other> const& other) const

    {

        return !operator==(other);

    }


    constexpr bool

    operator<(ValueUnit const& other) const

    {

        return value_ < other.value_;

    }


    explicit constexpr


    operator bool() const noexcept

    {

        return value_ != 0;

    }


    constexpr int


    signum() const noexcept

    {

        return (value_ < 0) ? -1 : (value_ ? 1 : 0);

    }


    // TODO: Move this to a new class, maybe with the old "TaggedFee" name

    constexpr value_type


    fee() const

    {

        return value_;

    }


    template <class Other>

    constexpr double


    decimalFromReference(ValueUnit<unit_type, Other> reference) const

    {

        return static_cast<double>(value_) / reference.value();

    }


    // `Usable` is checked to ensure that only values with

    // known valid type tags can be converted to JSON. At the time

    // of implementation, that includes all known tags, but more may

    // be added in the future.

    Json::Value


    jsonClipped() const

        requires Usable<ValueUnit>

    {

        if constexpr (std::is_integral_v<value_type>)

        {

            using jsontype = std::conditional_t<

                std::is_signed_v<value_type>,

                Json::Int,

                Json::UInt>;


            constexpr auto min = std::numeric_limits<jsontype>::min();

            constexpr auto max = std::numeric_limits<jsontype>::max();


            if (value_ < min)

                return min;

            if (value_ > max)

                return max;

            return static_cast<jsontype>(value_);

        }

        else

        {

            return value_;

        }

    }


    constexpr value_type


    value() const

    {

        return value_;

    }


    friend std::istream&


    operator>>(std::istream& s, ValueUnit& val)

    {

        s >> val.value_;

        return s;

    }


};


// Output Values as just their numeric value.

template <class Char, class Traits, class UnitTag, class T>

std::basic_ostream<Char, Traits>&

operator<<(std::basic_ostream<Char, Traits>& os, ValueUnit<UnitTag, T> const& q)

{

    return os << q.value();

}


template <class UnitTag, class T>

std::string


to_string(ValueUnit<UnitTag, T> const& amount)

{

    return std::to_string(amount.value());

}


template <class Source>

concept muldivSource = Valid<Source> &&

    std::is_convertible_v<typename Source::value_type, std::uint64_t>;


template <class Dest>

concept muldivDest = muldivSource<Dest> &&  // Dest is also a source

    std::is_convertible_v<std::uint64_t, typename Dest::value_type> &&

    sizeof(typename Dest::value_type) >= sizeof(std::uint64_t);


template <class Source2, class Source1>

concept muldivSources = muldivSource<Source1> && muldivSource<Source2> &&

    std::is_same_v<typename Source1::unit_type, typename Source2::unit_type>;


template <class Dest, class Source1, class Source2>

concept muldivable = muldivSources<Source1, Source2> && muldivDest<Dest>;

// Source and Dest can be the same by default


template <class Dest, class Source1, class Source2>

concept muldivCommutable = muldivable<Dest, Source1, Source2> &&

    !std::is_same_v<typename Source1::unit_type, typename Dest::unit_type>;


template <class T>

ValueUnit<unitlessTag, T>


scalar(T value)

{

    return ValueUnit<unitlessTag, T>{value};

}


template <class Source1, class Source2, unit::muldivable<Source1, Source2> Dest>

std::optional<Dest>


mulDivU(Source1 value, Dest mul, Source2 div)

{

    // values can never be negative in any context.

    if (value.value() < 0 || mul.value() < 0 || div.value() < 0)

    {

        // split the asserts so if one hits, the user can tell which

        // without a debugger.

        XRPL_ASSERT(

            value.value() >= 0, "ripple::unit::mulDivU : minimum value input");

        XRPL_ASSERT(

            mul.value() >= 0, "ripple::unit::mulDivU : minimum mul input");

        XRPL_ASSERT(

            div.value() > 0, "ripple::unit::mulDivU : minimum div input");

        return std::nullopt;

    }


    using desttype = typename Dest::value_type;

    constexpr auto max = std::numeric_limits<desttype>::max();


    // Shortcuts, since these happen a lot in the real world

    if (value == div)

        return mul;

    if (mul.value() == div.value())

    {

        if (value.value() > max)

            return std::nullopt;

        return Dest{static_cast<desttype>(value.value())};

    }


    using namespace boost::multiprecision;


    uint128_t product;

    product = multiply(

        product,

        static_cast<std::uint64_t>(value.value()),

        static_cast<std::uint64_t>(mul.value()));


    auto quotient = product / div.value();


    if (quotient > max)

        return std::nullopt;


    return Dest{static_cast<desttype>(quotient)};

}


}  // namespace unit


// Fee Levels

template <class T>

using FeeLevel = unit::ValueUnit<unit::feelevelTag, T>;

using FeeLevel64 = FeeLevel<std::uint64_t>;

using FeeLevelDouble = FeeLevel<double>;


// Basis points (Bips)

template <class T>

using Bips = unit::ValueUnit<unit::BipsTag, T>;

using Bips16 = Bips<std::uint16_t>;

using Bips32 = Bips<std::uint32_t>;

template <class T>

using TenthBips = unit::ValueUnit<unit::TenthBipsTag, T>;

using TenthBips16 = TenthBips<std::uint16_t>;

using TenthBips32 = TenthBips<std::uint32_t>;


template <class Source1, class Source2, unit::muldivable<Source1, Source2> Dest>

std::optional<Dest>


mulDiv(Source1 value, Dest mul, Source2 div)

{

    return unit::mulDivU(value, mul, div);

}


template <

    class Source1,

    class Source2,

    unit::muldivCommutable<Source1, Source2> Dest>

std::optional<Dest>


mulDiv(Dest value, Source1 mul, Source2 div)

{

    // Multiplication is commutative

    return unit::mulDivU(mul, value, div);

}


template <unit::muldivDest Dest>

std::optional<Dest>


mulDiv(std::uint64_t value, Dest mul, std::uint64_t div)

{

    // Give the scalars a non-tag so the

    // unit-handling version gets called.

    return unit::mulDivU(unit::scalar(value), mul, unit::scalar(div));

}


template <unit::muldivDest Dest>

std::optional<Dest>


mulDiv(Dest value, std::uint64_t mul, std::uint64_t div)

{

    // Multiplication is commutative

    return mulDiv(mul, value, div);

}


template <unit::muldivSource Source1, unit::muldivSources<Source1> Source2>

std::optional<std::uint64_t>


mulDiv(Source1 value, std::uint64_t mul, Source2 div)

{

    // Give the scalars a dimensionless unit so the

    // unit-handling version gets called.

    auto unitresult = unit::mulDivU(value, unit::scalar(mul), div);


    if (!unitresult)

        return std::nullopt;


    return unitresult->value();

}


template <unit::muldivSource Source1, unit::muldivSources<Source1> Source2>

std::optional<std::uint64_t>


mulDiv(std::uint64_t value, Source1 mul, Source2 div)

{

    // Multiplication is commutative

    return mulDiv(mul, value, div);

}


template <unit::IntegralValue Dest, unit::CastableValue<Dest> Src>

constexpr Dest


safe_cast(Src s) noexcept

{

    // Dest may not have an explicit value constructor

    return Dest{safe_cast<typename Dest::value_type>(s.value())};

}


template <unit::IntegralValue Dest, unit::Integral Src>

constexpr Dest

safe_cast(Src s) noexcept

{

    // Dest may not have an explicit value constructor

    return Dest{safe_cast<typename Dest::value_type>(s)};

}


template <unit::IntegralValue Dest, unit::CastableValue<Dest> Src>

constexpr Dest


unsafe_cast(Src s) noexcept

{

    // Dest may not have an explicit value constructor

    return Dest{unsafe_cast<typename Dest::value_type>(s.value())};

}


template <unit::IntegralValue Dest, unit::Integral Src>

constexpr Dest


unsafe_cast(Src s) noexcept

{

    // Dest may not have an explicit value constructor

    return Dest{unsafe_cast<typename Dest::value_type>(s)};

}


}  // namespace ripple


#endif  // PROTOCOL_UNITS_H_INCLUDED


std::istream

std::basic_ostream

std::string

Json::Value
Represents a JSON value.
Definition json_value.h:149

ripple::unit::ValueUnit
Definition Units.h:97

ripple::unit::ValueUnit::fee
constexpr value_type fee() const
Returns the number of drops.
Definition Units.h:296

ripple::unit::ValueUnit::operator*
friend constexpr ValueUnit operator*(value_type lhs, ValueUnit const &rhs)
Definition Units.h:177

ripple::unit::ValueUnit::jsonClipped
Json::Value jsonClipped() const
Definition Units.h:313

ripple::unit::ValueUnit::decimalFromReference
constexpr double decimalFromReference(ValueUnit< unit_type, Other > reference) const
Definition Units.h:303

ripple::unit::ValueUnit::value_type
T value_type
Definition Units.h:100

ripple::unit::ValueUnit::operator>>
friend std::istream & operator>>(std::istream &s, ValueUnit &val)
Definition Units.h:349

ripple::unit::ValueUnit::operator=
constexpr ValueUnit & operator=(beast::Zero)
Definition Units.h:116

ripple::unit::ValueUnit::signum
constexpr int signum() const noexcept
Return the sign of the amount.
Definition Units.h:288

ripple::unit::ValueUnit::operator+
constexpr ValueUnit operator+(value_type const &rhs) const
Definition Units.h:144

ripple::unit::ValueUnit::operator!=
constexpr bool operator!=(ValueUnit< unit_type, Other > const &other) const
Definition Units.h:268

ripple::unit::ValueUnit::operator+=
ValueUnit & operator+=(ValueUnit const &other)
Definition Units.h:190

ripple::unit::ValueUnit::operator-=
ValueUnit & operator-=(ValueUnit const &other)
Definition Units.h:197

ripple::unit::ValueUnit::operator<
constexpr bool operator<(ValueUnit const &other) const
Definition Units.h:274

ripple::unit::ValueUnit::operator/
constexpr value_type operator/(ValueUnit const &rhs) const
Definition Units.h:184

ripple::unit::ValueUnit::operator%=
ValueUnit & operator%=(value_type const &rhs)
Definition Units.h:233

ripple::unit::ValueUnit::operator++
ValueUnit & operator++()
Definition Units.h:204

ripple::unit::ValueUnit::operator*=
ValueUnit & operator*=(value_type const &rhs)
Definition Units.h:218

ripple::unit::ValueUnit::operator=
constexpr ValueUnit & operator=(value_type value)
Definition Units.h:127

ripple::unit::ValueUnit::operator==
constexpr bool operator==(ValueUnit< unit_type, Other > const &other) const
Definition Units.h:255

ripple::unit::ValueUnit::ValueUnit
ValueUnit()=default

ripple::unit::ValueUnit::ValueUnit
constexpr ValueUnit(value_type value)
Definition Units.h:122

ripple::unit::ValueUnit::ValueUnit
constexpr ValueUnit(ValueUnit< unit_type, Other > const &value)
Instances with the same unit, and a type that is "safe" to convert to this one can be converted impli...
Definition Units.h:137

ripple::unit::ValueUnit::operator=
constexpr ValueUnit & operator=(ValueUnit const &other)=default

ripple::unit::ValueUnit::operator*
constexpr ValueUnit operator*(value_type const &rhs) const
Definition Units.h:171

ripple::unit::ValueUnit::value_
value_type value_
Definition Units.h:103

ripple::unit::ValueUnit::operator==
constexpr bool operator==(value_type other) const
Definition Units.h:261

ripple::unit::ValueUnit::operator-
ValueUnit operator-() const
Definition Units.h:240

ripple::unit::ValueUnit::ValueUnit
constexpr ValueUnit(beast::Zero)
Definition Units.h:111

ripple::unit::ValueUnit::operator/=
ValueUnit & operator/=(value_type const &rhs)
Definition Units.h:225

ripple::unit::ValueUnit::ValueUnit
constexpr ValueUnit(ValueUnit const &other)=default

ripple::unit::ValueUnit::operator-
friend constexpr ValueUnit operator-(value_type lhs, ValueUnit const &rhs)
Definition Units.h:163

ripple::unit::ValueUnit::operator--
ValueUnit & operator--()
Definition Units.h:211

ripple::unit::ValueUnit::operator+
friend constexpr ValueUnit operator+(value_type lhs, ValueUnit const &rhs)
Definition Units.h:150

ripple::unit::ValueUnit::operator==
constexpr bool operator==(ValueUnit const &other) const
Definition Units.h:248

ripple::unit::ValueUnit::unit_type
UnitTag unit_type
Definition Units.h:99

ripple::unit::ValueUnit::value
constexpr value_type value() const
Returns the underlying value.
Definition Units.h:343

ripple::unit::ValueUnit::operator-
constexpr ValueUnit operator-(value_type const &rhs) const
Definition Units.h:157

ripple::SafeToCast
Definition safe_cast.h:32

ripple::unit::CastableValue
Definition Units.h:87

ripple::unit::Compatible
Definition Units.h:76

ripple::unit::IntegralValue
Definition Units.h:84

ripple::unit::Integral
Definition Units.h:81

ripple::unit::Usable
Usable is checked to ensure that only values with known valid type tags can be used (sometimes transp...
Definition Units.h:68

ripple::unit::Valid
Definition Units.h:57

ripple::unit::muldivCommutable
Definition Units.h:389

ripple::unit::muldivDest
Definition Units.h:376

ripple::unit::muldivSource
Definition Units.h:372

ripple::unit::muldivSources
Definition Units.h:381

ripple::unit::muldivable
Definition Units.h:385

std::conditional_t

std::uint64_t

iosfwd

std::is_same_v
T is_same_v

limits

std::numeric_limits::max
T max(T... args)

std::numeric_limits::min
T min(T... args)

Json::Int
int Int
Definition json_forwards.h:26

Json::UInt
unsigned int UInt
Definition json_forwards.h:27

ripple::unit::mulDivU
std::optional< Dest > mulDivU(Source1 value, Dest mul, Source2 div)
Definition Units.h:401

ripple::unit::scalar
ValueUnit< unitlessTag, T > scalar(T value)
Definition Units.h:394

ripple::unit::operator<<
std::basic_ostream< Char, Traits > & operator<<(std::basic_ostream< Char, Traits > &os, ValueUnit< UnitTag, T > const &q)
Definition Units.h:359

ripple::unit::to_string
std::string to_string(ValueUnit< UnitTag, T > const &amount)
Definition Units.h:366

ripple
Use hash_* containers for keys that do not need a cryptographically secure hashing algorithm.
Definition algorithm.h:25

ripple::safe_cast
constexpr std::enable_if_t< std::is_integral_v< Dest > &&std::is_integral_v< Src >, Dest > safe_cast(Src s) noexcept
Definition safe_cast.h:41

ripple::multiply
STAmount multiply(STAmount const &amount, Rate const &rate)
Definition Rate2.cpp:53

ripple::mulDiv
std::optional< std::uint64_t > mulDiv(std::uint64_t value, std::uint64_t mul, std::uint64_t div)
Return value*mul/div accurately.
Definition libxrpl/basics/mulDiv.cpp:32

ripple::unsafe_cast
constexpr std::enable_if_t< std::is_integral_v< Dest > &&std::is_integral_v< Src >, Dest > unsafe_cast(Src s) noexcept
Definition safe_cast.h:77

optional

beast::Zero
Zero allows classes to offer efficient comparisons to zero.
Definition Zero.h:43

std::to_string
T to_string(T... args)