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ladybird/Userland/Libraries/LibJS/Runtime/Intl/MathematicalValue.cpp
davidot 791855deab LibCrypto+LibJS: Remove the create_from methods from BigInteger 
Instead we just use a specific constructor. With this set of
constructors using curly braces for constructing is highly recommended.
As then it will not do too many implicit conversions which could lead to
unexpected loss of data or calling the much slower double constructor.

Also to ensure we don't feed (Un)SignedBigInteger infinities we throw
RangeError earlier for Durations.
2022-08-26 19:18:26 +01:00

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/*
* Copyright (c) 2022, Tim Flynn <trflynn89@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <LibJS/Runtime/AbstractOperations.h>
#include <LibJS/Runtime/GlobalObject.h>
#include <LibJS/Runtime/Intl/MathematicalValue.h>
#include <math.h>
namespace JS::Intl {
bool MathematicalValue::is_number() const
{
return m_value.has<double>();
}
double MathematicalValue::as_number() const
{
VERIFY(is_number());
return m_value.get<double>();
}
bool MathematicalValue::is_bigint() const
{
return m_value.has<Crypto::SignedBigInteger>();
}
Crypto::SignedBigInteger const& MathematicalValue::as_bigint() const
{
VERIFY(is_bigint());
return m_value.get<Crypto::SignedBigInteger>();
}
bool MathematicalValue::is_mathematical_value() const
{
return is_number() || is_bigint();
}
bool MathematicalValue::is_positive_infinity() const
{
if (is_mathematical_value())
return false;
return m_value.get<Symbol>() == Symbol::PositiveInfinity;
}
bool MathematicalValue::is_negative_infinity() const
{
if (is_mathematical_value())
return false;
return m_value.get<Symbol>() == Symbol::NegativeInfinity;
}
bool MathematicalValue::is_negative_zero() const
{
if (is_mathematical_value())
return false;
return m_value.get<Symbol>() == Symbol::NegativeZero;
}
bool MathematicalValue::is_nan() const
{
if (is_mathematical_value())
return false;
return m_value.get<Symbol>() == Symbol::NotANumber;
}
void MathematicalValue::negate()
{
m_value.visit(
[](double& value) {
VERIFY(value != 0.0);
value *= -1.0;
},
[](Crypto::SignedBigInteger& value) { value.negate(); },
[](auto) { VERIFY_NOT_REACHED(); });
}
MathematicalValue MathematicalValue::plus(Checked<i32> addition) const
{
return m_value.visit(
[&](double value) {
return MathematicalValue { value + addition.value() };
},
[&](Crypto::SignedBigInteger const& value) {
return MathematicalValue { value.plus(Crypto::SignedBigInteger { addition.value() }) };
},
[](auto) -> MathematicalValue { VERIFY_NOT_REACHED(); });
}
MathematicalValue MathematicalValue::plus(MathematicalValue const& addition) const
{
return m_value.visit(
[&](double value) {
return MathematicalValue { value + addition.as_number() };
},
[&](Crypto::SignedBigInteger const& value) {
return MathematicalValue { value.plus(addition.as_bigint()) };
},
[](auto) -> MathematicalValue { VERIFY_NOT_REACHED(); });
}
MathematicalValue MathematicalValue::minus(Checked<i32> subtraction) const
{
return m_value.visit(
[&](double value) {
return MathematicalValue { value - subtraction.value() };
},
[&](Crypto::SignedBigInteger const& value) {
return MathematicalValue { value.minus(Crypto::SignedBigInteger { subtraction.value() }) };
},
[](auto) -> MathematicalValue { VERIFY_NOT_REACHED(); });
}
MathematicalValue MathematicalValue::minus(MathematicalValue const& subtraction) const
{
return m_value.visit(
[&](double value) {
return MathematicalValue { value - subtraction.as_number() };
},
[&](Crypto::SignedBigInteger const& value) {
return MathematicalValue { value.minus(subtraction.as_bigint()) };
},
[](auto) -> MathematicalValue { VERIFY_NOT_REACHED(); });
}
MathematicalValue MathematicalValue::multiplied_by(Checked<i32> multiplier) const
{
return m_value.visit(
[&](double value) {
return MathematicalValue { value * multiplier.value() };
},
[&](Crypto::SignedBigInteger const& value) {
return MathematicalValue { value.multiplied_by(Crypto::SignedBigInteger { multiplier.value() }) };
},
[](auto) -> MathematicalValue { VERIFY_NOT_REACHED(); });
}
MathematicalValue MathematicalValue::multiplied_by(MathematicalValue const& multiplier) const
{
return m_value.visit(
[&](double value) {
return MathematicalValue { value * multiplier.as_number() };
},
[&](Crypto::SignedBigInteger const& value) {
return MathematicalValue { value.multiplied_by(multiplier.as_bigint()) };
},
[](auto) -> MathematicalValue { VERIFY_NOT_REACHED(); });
}
MathematicalValue MathematicalValue::divided_by(Checked<i32> divisor) const
{
return m_value.visit(
[&](double value) {
return MathematicalValue { value / divisor.value() };
},
[&](Crypto::SignedBigInteger const& value) {
return MathematicalValue { value.divided_by(Crypto::SignedBigInteger { divisor.value() }).quotient };
},
[](auto) -> MathematicalValue { VERIFY_NOT_REACHED(); });
}
MathematicalValue MathematicalValue::divided_by(MathematicalValue const& divisor) const
{
return m_value.visit(
[&](double value) {
return MathematicalValue { value / divisor.as_number() };
},
[&](Crypto::SignedBigInteger const& value) {
return MathematicalValue { value.divided_by(divisor.as_bigint()).quotient };
},
[](auto) -> MathematicalValue { VERIFY_NOT_REACHED(); });
}
static Crypto::SignedBigInteger bigint_power(Checked<i32> exponent)
{
VERIFY(exponent >= 0);
static auto base = Crypto::SignedBigInteger { 10 };
auto result = Crypto::SignedBigInteger { 1 };
for (i32 i = 0; i < exponent; ++i)
result = result.multiplied_by(base);
return result;
}
MathematicalValue MathematicalValue::multiplied_by_power(Checked<i32> exponent) const
{
return m_value.visit(
[&](double value) {
return MathematicalValue { value * pow(10, exponent.value()) };
},
[&](Crypto::SignedBigInteger const& value) {
if (exponent < 0)
return MathematicalValue { value.divided_by(bigint_power(-exponent.value())).quotient };
return MathematicalValue { value.multiplied_by(bigint_power(exponent)) };
},
[](auto) -> MathematicalValue { VERIFY_NOT_REACHED(); });
}
MathematicalValue MathematicalValue::divided_by_power(Checked<i32> exponent) const
{
return m_value.visit(
[&](double value) {
if (exponent < 0)
return MathematicalValue { value * pow(10, -exponent.value()) };
return MathematicalValue { value / pow(10, exponent.value()) };
},
[&](Crypto::SignedBigInteger const& value) {
if (exponent < 0)
return MathematicalValue { value.multiplied_by(bigint_power(-exponent.value())) };
return MathematicalValue { value.divided_by(bigint_power(exponent)).quotient };
},
[](auto) -> MathematicalValue { VERIFY_NOT_REACHED(); });
}
bool MathematicalValue::modulo_is_zero(Checked<i32> mod) const
{
return m_value.visit(
[&](double value) {
auto result = MathematicalValue { modulo(value, mod.value()) };
return result.is_equal_to(MathematicalValue { 0.0 });
},
[&](Crypto::SignedBigInteger const& value) {
return modulo(value, Crypto::SignedBigInteger { mod.value() }).is_zero();
},
[](auto) -> bool { VERIFY_NOT_REACHED(); });
}
int MathematicalValue::logarithmic_floor() const
{
return m_value.visit(
[](double value) {
return static_cast<int>(floor(log10(value)));
},
[](Crypto::SignedBigInteger const& value) {
// FIXME: Can we do this without string conversion?
return static_cast<int>(value.to_base(10).length() - 1);
},
[](auto) -> int { VERIFY_NOT_REACHED(); });
}
bool MathematicalValue::is_equal_to(MathematicalValue const& other) const
{
return m_value.visit(
[&](double value) {
static constexpr double epsilon = 5e-14;
return fabs(value - other.as_number()) < epsilon;
},
[&](Crypto::SignedBigInteger const& value) {
return value == other.as_bigint();
},
[](auto) -> bool { VERIFY_NOT_REACHED(); });
}
bool MathematicalValue::is_less_than(MathematicalValue const& other) const
{
return m_value.visit(
[&](double value) {
if (is_equal_to(other))
return false;
return value < other.as_number();
},
[&](Crypto::SignedBigInteger const& value) {
return value < other.as_bigint();
},
[](auto) -> bool { VERIFY_NOT_REACHED(); });
}
bool MathematicalValue::is_negative() const
{
return m_value.visit(
[](double value) { return value < 0.0; },
[](Crypto::SignedBigInteger const& value) { return value.is_negative(); },
[](Symbol symbol) { return symbol == Symbol::NegativeInfinity; });
}
bool MathematicalValue::is_positive() const
{
return m_value.visit(
[](double value) { return value > 0.0; },
[](Crypto::SignedBigInteger const& value) { return !value.is_zero() && !value.is_negative(); },
[](Symbol symbol) { return symbol == Symbol::PositiveInfinity; });
}
bool MathematicalValue::is_zero() const
{
return m_value.visit(
[&](double value) { return value == 0.0; },
[](Crypto::SignedBigInteger const& value) { return value.is_zero(); },
[](auto) { return false; });
}
String MathematicalValue::to_string() const
{
return m_value.visit(
[](double value) { return Value(value).to_string_without_side_effects(); },
[](Crypto::SignedBigInteger const& value) { return value.to_base(10); },
[](auto) -> String { VERIFY_NOT_REACHED(); });
}
Value MathematicalValue::to_value(VM& vm) const
{
return m_value.visit(
[](double value) {
return Value(value);
},
[&](Crypto::SignedBigInteger const& value) {
return Value(js_bigint(vm, value));
},
[](auto symbol) {
switch (symbol) {
case Symbol::PositiveInfinity:
return js_infinity();
case Symbol::NegativeInfinity:
return js_negative_infinity();
case Symbol::NegativeZero:
return Value(-0.0);
case Symbol::NotANumber:
return js_nan();
}
VERIFY_NOT_REACHED();
});
}
MathematicalValue::ValueType MathematicalValue::value_from_number(double number)
{
Value value(number);
if (value.is_positive_infinity())
return Symbol::PositiveInfinity;
if (value.is_negative_infinity())
return Symbol::NegativeInfinity;
if (value.is_negative_zero())
return Symbol::NegativeZero;
if (value.is_nan())
return Symbol::NotANumber;
return number;
}
}
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