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ladybird/Userland/Libraries/LibJS/Runtime/Intl/MathematicalValue.cpp
Linus Groh f9705eb2f4 LibJS: Replace GlobalObject with VM in Intl AOs [Part 1/19] 
Instead of passing a GlobalObject everywhere, we will simply pass a VM,
from which we can get everything we need: common names, the current
realm, symbols, arguments, the heap, and a few other things.

In some places we already don't actually need a global object and just
do it for consistency - no more `auto& vm = global_object.vm();`!

This will eventually automatically fix the "wrong realm" issue we have
in some places where we (incorrectly) use the global object from the
allocating object, e.g. in call() / construct() implementations. When
only ever a VM is passed around, this issue can't happen :^)

I've decided to split this change into a series of patches that should
keep each commit down do a somewhat manageable size.
2022-08-23 13:58:30 +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::create_from(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::create_from(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::create_from(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::create_from(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::create_from(10);
auto result = Crypto::SignedBigInteger::create_from(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::create_from(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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