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ladybird/Userland/Libraries/LibJS/Runtime/Value.cpp
Linus Groh 5db38d7ba1 LibJS: Replace standalone js_bigint() with BigInt::create() 
Three standalone Cell creation functions remain in the JS namespace:

- js_bigint()
- js_string()
- js_symbol()

All of them are leftovers from early iterations when LibJS still took
inspiration from JSC, which itself has jsString(). Nowadays, we pretty
much exclusively use static create() functions to construct types
allocated on the JS heap, and there's no reason to not do the same for
these.
Also change the return type from BigInt* to NonnullGCPtr<BigInt> while
we're here.

This is patch 1/3, replacement of js_string() and js_symbol() follow.
2022-12-07 16:43:06 +00:00

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/*
* Copyright (c) 2020, Andreas Kling <kling@serenityos.org>
* Copyright (c) 2020-2022, Linus Groh <linusg@serenityos.org>
* Copyright (c) 2022, David Tuin <davidot@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/AllOf.h>
#include <AK/Assertions.h>
#include <AK/CharacterTypes.h>
#include <AK/DeprecatedString.h>
#include <AK/FloatingPointStringConversions.h>
#include <AK/StringBuilder.h>
#include <AK/StringFloatingPointConversions.h>
#include <AK/Utf8View.h>
#include <LibCrypto/BigInt/SignedBigInteger.h>
#include <LibCrypto/NumberTheory/ModularFunctions.h>
#include <LibJS/Runtime/AbstractOperations.h>
#include <LibJS/Runtime/Accessor.h>
#include <LibJS/Runtime/Array.h>
#include <LibJS/Runtime/BigInt.h>
#include <LibJS/Runtime/BigIntObject.h>
#include <LibJS/Runtime/BooleanObject.h>
#include <LibJS/Runtime/BoundFunction.h>
#include <LibJS/Runtime/Completion.h>
#include <LibJS/Runtime/Error.h>
#include <LibJS/Runtime/FunctionObject.h>
#include <LibJS/Runtime/GlobalObject.h>
#include <LibJS/Runtime/NativeFunction.h>
#include <LibJS/Runtime/NumberObject.h>
#include <LibJS/Runtime/Object.h>
#include <LibJS/Runtime/PrimitiveString.h>
#include <LibJS/Runtime/ProxyObject.h>
#include <LibJS/Runtime/RegExpObject.h>
#include <LibJS/Runtime/StringObject.h>
#include <LibJS/Runtime/StringPrototype.h>
#include <LibJS/Runtime/SymbolObject.h>
#include <LibJS/Runtime/VM.h>
#include <LibJS/Runtime/Value.h>
#include <math.h>
namespace JS {
static inline bool same_type_for_equality(Value const& lhs, Value const& rhs)
{
// If the top two bytes are identical then either:
// both are NaN boxed Values with the same type
// or they are doubles which happen to have the same top bytes.
if ((lhs.encoded() & TAG_EXTRACTION) == (rhs.encoded() & TAG_EXTRACTION))
return true;
if (lhs.is_number() && rhs.is_number())
return true;
// One of the Values is not a number and they do not have the same tag
return false;
}
static const Crypto::SignedBigInteger BIGINT_ZERO { 0 };
ALWAYS_INLINE bool both_number(Value const& lhs, Value const& rhs)
{
return lhs.is_number() && rhs.is_number();
}
ALWAYS_INLINE bool both_bigint(Value const& lhs, Value const& rhs)
{
return lhs.is_bigint() && rhs.is_bigint();
}
// 6.1.6.1.20 Number::toString ( x ), https://tc39.es/ecma262/#sec-numeric-types-number-tostring
// Implementation for radix = 10
DeprecatedString number_to_string(double d, NumberToStringMode mode)
{
auto convert_to_decimal_digits_array = [](auto x, auto& digits, auto& length) {
for (; x; x /= 10)
digits[length++] = x % 10 | '0';
for (i32 i = 0; 2 * i + 1 < length; ++i)
swap(digits[i], digits[length - i - 1]);
};
// 1. If x is NaN, return "NaN".
if (isnan(d))
return "NaN";
// 2. If x is +0𝔽 or -0𝔽, return "0".
if (d == +0.0 || d == -0.0)
return "0";
// 4. If x is +∞𝔽, return "Infinity".
if (isinf(d)) {
if (d > 0)
return "Infinity";
else
return "-Infinity";
}
StringBuilder builder;
// 5. Let n, k, and s be integers such that k ≥ 1, radix ^ (k - 1) ≤ s < radix ^ k,
// 𝔽(s × radix ^ (n - k)) is x, and k is as small as possible. Note that k is the number of
// digits in the representation of s using radix radix, that s is not divisible by radix, and
// that the least significant digit of s is not necessarily uniquely determined by these criteria.
//
// Note: guarantees provided by convert_floating_point_to_decimal_exponential_form satisfy
// requirements of NOTE 2.
auto [sign, mantissa, exponent] = convert_floating_point_to_decimal_exponential_form(d);
i32 k = 0;
AK::Array<char, 20> mantissa_digits;
convert_to_decimal_digits_array(mantissa, mantissa_digits, k);
i32 n = exponent + k; // s = mantissa
// 3. If x < -0𝔽, return the string-concatenation of "-" and Number::toString(-x, radix).
if (sign)
builder.append('-');
// Non-standard: Intl needs number-to-string conversions for extremely large numbers without any
// exponential formatting, as it will handle such formatting itself in a locale-aware way.
bool force_no_exponent = mode == NumberToStringMode::WithoutExponent;
// 6. If radix ≠ 10 or n is in the inclusive interval from -5 to 21, then
if ((n >= -5 && n <= 21) || force_no_exponent) {
// a. If n ≥ k, then
if (n >= k) {
// i. Return the string-concatenation of:
// the code units of the k digits of the representation of s using radix radix
builder.append(mantissa_digits.data(), k);
// n - k occurrences of the code unit 0x0030 (DIGIT ZERO)
builder.append_repeated('0', n - k);
// b. Else if n > 0, then
} else if (n > 0) {
// i. Return the string-concatenation of:
// the code units of the most significant n digits of the representation of s using radix radix
builder.append(mantissa_digits.data(), n);
// the code unit 0x002E (FULL STOP)
builder.append('.');
// the code units of the remaining k - n digits of the representation of s using radix radix
builder.append(mantissa_digits.data() + n, k - n);
// c. Else,
} else {
// i. Assert: n ≤ 0.
VERIFY(n <= 0);
// ii. Return the string-concatenation of:
// the code unit 0x0030 (DIGIT ZERO)
builder.append('0');
// the code unit 0x002E (FULL STOP)
builder.append('.');
// -n occurrences of the code unit 0x0030 (DIGIT ZERO)
builder.append_repeated('0', -n);
// the code units of the k digits of the representation of s using radix radix
builder.append(mantissa_digits.data(), k);
}
return builder.to_deprecated_string();
}
// 7. NOTE: In this case, the input will be represented using scientific E notation, such as 1.2e+3.
// 9. If n < 0, then
// a. Let exponentSign be the code unit 0x002D (HYPHEN-MINUS).
// 10. Else,
// a. Let exponentSign be the code unit 0x002B (PLUS SIGN).
char exponent_sign = n < 0 ? '-' : '+';
AK::Array<char, 5> exponent_digits;
i32 exponent_length = 0;
convert_to_decimal_digits_array(abs(n - 1), exponent_digits, exponent_length);
// 11. If k is 1, then
if (k == 1) {
// a. Return the string-concatenation of:
// the code unit of the single digit of s
builder.append(mantissa_digits[0]);
// the code unit 0x0065 (LATIN SMALL LETTER E)
builder.append('e');
// exponentSign
builder.append(exponent_sign);
// the code units of the decimal representation of abs(n - 1)
builder.append(exponent_digits.data(), exponent_length);
return builder.to_deprecated_string();
}
// 12. Return the string-concatenation of:
// the code unit of the most significant digit of the decimal representation of s
builder.append(mantissa_digits[0]);
// the code unit 0x002E (FULL STOP)
builder.append('.');
// the code units of the remaining k - 1 digits of the decimal representation of s
builder.append(mantissa_digits.data() + 1, k - 1);
// the code unit 0x0065 (LATIN SMALL LETTER E)
builder.append('e');
// exponentSign
builder.append(exponent_sign);
// the code units of the decimal representation of abs(n - 1)
builder.append(exponent_digits.data(), exponent_length);
return builder.to_deprecated_string();
}
// 7.2.2 IsArray ( argument ), https://tc39.es/ecma262/#sec-isarray
ThrowCompletionOr<bool> Value::is_array(VM& vm) const
{
if (!is_object())
return false;
auto& object = as_object();
if (is<Array>(object))
return true;
if (is<ProxyObject>(object)) {
auto& proxy = static_cast<ProxyObject const&>(object);
if (proxy.is_revoked())
return vm.throw_completion<TypeError>(ErrorType::ProxyRevoked);
return Value(&proxy.target()).is_array(vm);
}
return false;
}
Array& Value::as_array()
{
VERIFY(is_object() && is<Array>(as_object()));
return static_cast<Array&>(as_object());
}
// 7.2.3 IsCallable ( argument ), https://tc39.es/ecma262/#sec-iscallable
bool Value::is_function() const
{
return is_object() && as_object().is_function();
}
FunctionObject& Value::as_function()
{
VERIFY(is_function());
return static_cast<FunctionObject&>(as_object());
}
FunctionObject const& Value::as_function() const
{
VERIFY(is_function());
return static_cast<FunctionObject const&>(as_object());
}
// 7.2.4 IsConstructor ( argument ), https://tc39.es/ecma262/#sec-isconstructor
bool Value::is_constructor() const
{
// 1. If Type(argument) is not Object, return false.
if (!is_function())
return false;
// 2. If argument has a [[Construct]] internal method, return true.
if (as_function().has_constructor())
return true;
// 3. Return false.
return false;
}
// 7.2.8 IsRegExp ( argument ), https://tc39.es/ecma262/#sec-isregexp
ThrowCompletionOr<bool> Value::is_regexp(VM& vm) const
{
if (!is_object())
return false;
auto matcher = TRY(as_object().get(*vm.well_known_symbol_match()));
if (!matcher.is_undefined())
return matcher.to_boolean();
return is<RegExpObject>(as_object());
}
// 13.5.3 The typeof Operator, https://tc39.es/ecma262/#sec-typeof-operator
DeprecatedString Value::typeof() const
{
if (is_number())
return "number";
switch (m_value.tag) {
case UNDEFINED_TAG:
return "undefined";
case NULL_TAG:
return "object";
case STRING_TAG:
return "string";
case OBJECT_TAG:
// B.3.7.3 Changes to the typeof Operator, https://tc39.es/ecma262/#sec-IsHTMLDDA-internal-slot-typeof
if (as_object().is_htmldda())
return "undefined";
if (is_function())
return "function";
return "object";
case BOOLEAN_TAG:
return "boolean";
case SYMBOL_TAG:
return "symbol";
case BIGINT_TAG:
return "bigint";
default:
VERIFY_NOT_REACHED();
}
}
DeprecatedString Value::to_string_without_side_effects() const
{
if (is_double())
return number_to_string(m_value.as_double);
switch (m_value.tag) {
case UNDEFINED_TAG:
return "undefined";
case NULL_TAG:
return "null";
case BOOLEAN_TAG:
return as_bool() ? "true" : "false";
case INT32_TAG:
return DeprecatedString::number(as_i32());
case STRING_TAG:
return as_string().deprecated_string();
case SYMBOL_TAG:
return as_symbol().to_deprecated_string();
case BIGINT_TAG:
return as_bigint().to_deprecated_string();
case OBJECT_TAG:
return DeprecatedString::formatted("[object {}]", as_object().class_name());
case ACCESSOR_TAG:
return "<accessor>";
default:
VERIFY_NOT_REACHED();
}
}
ThrowCompletionOr<PrimitiveString*> Value::to_primitive_string(VM& vm)
{
if (is_string())
return &as_string();
auto string = TRY(to_string(vm));
return js_string(vm, string);
}
// 7.1.17 ToString ( argument ), https://tc39.es/ecma262/#sec-tostring
ThrowCompletionOr<DeprecatedString> Value::to_string(VM& vm) const
{
if (is_double())
return number_to_string(m_value.as_double);
switch (m_value.tag) {
case UNDEFINED_TAG:
return "undefined"sv;
case NULL_TAG:
return "null"sv;
case BOOLEAN_TAG:
return as_bool() ? "true"sv : "false"sv;
case INT32_TAG:
return DeprecatedString::number(as_i32());
case STRING_TAG:
return as_string().deprecated_string();
case SYMBOL_TAG:
return vm.throw_completion<TypeError>(ErrorType::Convert, "symbol", "string");
case BIGINT_TAG:
return as_bigint().big_integer().to_base(10);
case OBJECT_TAG: {
auto primitive_value = TRY(to_primitive(vm, PreferredType::String));
return primitive_value.to_string(vm);
}
default:
VERIFY_NOT_REACHED();
}
}
ThrowCompletionOr<Utf16String> Value::to_utf16_string(VM& vm) const
{
if (is_string())
return as_string().utf16_string();
auto utf8_string = TRY(to_string(vm));
return Utf16String(utf8_string);
}
// 7.1.2 ToBoolean ( argument ), https://tc39.es/ecma262/#sec-toboolean
bool Value::to_boolean() const
{
if (is_double()) {
if (is_nan())
return false;
return m_value.as_double != 0;
}
switch (m_value.tag) {
case UNDEFINED_TAG:
case NULL_TAG:
return false;
case BOOLEAN_TAG:
return as_bool();
case INT32_TAG:
return as_i32() != 0;
case STRING_TAG:
return !as_string().is_empty();
case SYMBOL_TAG:
return true;
case BIGINT_TAG:
return as_bigint().big_integer() != BIGINT_ZERO;
case OBJECT_TAG:
// B.3.7.1 Changes to ToBoolean, https://tc39.es/ecma262/#sec-IsHTMLDDA-internal-slot-to-boolean
if (as_object().is_htmldda())
return false;
return true;
default:
VERIFY_NOT_REACHED();
}
}
// 7.1.1 ToPrimitive ( input [ , preferredType ] ), https://tc39.es/ecma262/#sec-toprimitive
ThrowCompletionOr<Value> Value::to_primitive(VM& vm, PreferredType preferred_type) const
{
auto get_hint_for_preferred_type = [&]() -> DeprecatedString {
switch (preferred_type) {
case PreferredType::Default:
return "default";
case PreferredType::String:
return "string";
case PreferredType::Number:
return "number";
default:
VERIFY_NOT_REACHED();
}
};
if (is_object()) {
auto to_primitive_method = TRY(get_method(vm, *vm.well_known_symbol_to_primitive()));
if (to_primitive_method) {
auto hint = get_hint_for_preferred_type();
auto result = TRY(call(vm, *to_primitive_method, *this, js_string(vm, hint)));
if (!result.is_object())
return result;
return vm.throw_completion<TypeError>(ErrorType::ToPrimitiveReturnedObject, to_string_without_side_effects(), hint);
}
if (preferred_type == PreferredType::Default)
preferred_type = PreferredType::Number;
return as_object().ordinary_to_primitive(preferred_type);
}
return *this;
}
// 7.1.18 ToObject ( argument ), https://tc39.es/ecma262/#sec-toobject
ThrowCompletionOr<Object*> Value::to_object(VM& vm) const
{
auto& realm = *vm.current_realm();
VERIFY(!is_empty());
if (is_number())
return NumberObject::create(realm, as_double());
switch (m_value.tag) {
case UNDEFINED_TAG:
case NULL_TAG:
return vm.throw_completion<TypeError>(ErrorType::ToObjectNullOrUndefined);
case BOOLEAN_TAG:
return BooleanObject::create(realm, as_bool());
case STRING_TAG:
return StringObject::create(realm, const_cast<JS::PrimitiveString&>(as_string()), *realm.intrinsics().string_prototype());
case SYMBOL_TAG:
return SymbolObject::create(realm, const_cast<JS::Symbol&>(as_symbol()));
case BIGINT_TAG:
return BigIntObject::create(realm, const_cast<JS::BigInt&>(as_bigint()));
case OBJECT_TAG:
return &const_cast<Object&>(as_object());
default:
VERIFY_NOT_REACHED();
}
}
// 7.1.3 ToNumeric ( value ), https://tc39.es/ecma262/#sec-tonumeric
FLATTEN ThrowCompletionOr<Value> Value::to_numeric(VM& vm) const
{
auto primitive = TRY(to_primitive(vm, Value::PreferredType::Number));
if (primitive.is_bigint())
return primitive;
return primitive.to_number(vm);
}
constexpr bool is_ascii_number(u32 code_point)
{
return is_ascii_digit(code_point) || code_point == '.' || (code_point == 'e' || code_point == 'E') || code_point == '+' || code_point == '-';
}
struct NumberParseResult {
StringView literal;
u8 base;
};
static Optional<NumberParseResult> parse_number_text(StringView text)
{
NumberParseResult result {};
auto check_prefix = [&](auto lower_prefix, auto upper_prefix) {
if (text.length() <= 2)
return false;
if (!text.starts_with(lower_prefix) && !text.starts_with(upper_prefix))
return false;
return true;
};
// https://tc39.es/ecma262/#sec-tonumber-applied-to-the-string-type
if (check_prefix("0b"sv, "0B"sv)) {
if (!all_of(text.substring_view(2), is_ascii_binary_digit))
return {};
result.literal = text.substring_view(2);
result.base = 2;
} else if (check_prefix("0o"sv, "0O"sv)) {
if (!all_of(text.substring_view(2), is_ascii_octal_digit))
return {};
result.literal = text.substring_view(2);
result.base = 8;
} else if (check_prefix("0x"sv, "0X"sv)) {
if (!all_of(text.substring_view(2), is_ascii_hex_digit))
return {};
result.literal = text.substring_view(2);
result.base = 16;
} else {
if (!all_of(text, is_ascii_number))
return {};
result.literal = text;
result.base = 10;
}
return result;
}
// 7.1.4.1.1 StringToNumber ( str ), https://tc39.es/ecma262/#sec-stringtonumber
Optional<Value> string_to_number(StringView string)
{
// 1. Let text be StringToCodePoints(str).
DeprecatedString text = Utf8View(string).trim(whitespace_characters, AK::TrimMode::Both).as_string();
// 2. Let literal be ParseText(text, StringNumericLiteral).
if (text.is_empty())
return Value(0);
if (text == "Infinity" || text == "+Infinity")
return js_infinity();
if (text == "-Infinity")
return js_negative_infinity();
auto result = parse_number_text(text);
// 3. If literal is a List of errors, return NaN.
if (!result.has_value())
return js_nan();
// 4. Return StringNumericValue of literal.
if (result->base != 10) {
auto bigint = Crypto::UnsignedBigInteger::from_base(result->base, result->literal);
return Value(bigint.to_double());
}
auto maybe_double = text.to_double(AK::TrimWhitespace::No);
if (!maybe_double.has_value())
return js_nan();
return Value(*maybe_double);
}
// 7.1.4 ToNumber ( argument ), https://tc39.es/ecma262/#sec-tonumber
ThrowCompletionOr<Value> Value::to_number(VM& vm) const
{
VERIFY(!is_empty());
if (is_number())
return *this;
switch (m_value.tag) {
case UNDEFINED_TAG:
return js_nan();
case NULL_TAG:
return Value(0);
case BOOLEAN_TAG:
return Value(as_bool() ? 1 : 0);
case STRING_TAG:
return string_to_number(as_string().deprecated_string().view());
case SYMBOL_TAG:
return vm.throw_completion<TypeError>(ErrorType::Convert, "symbol", "number");
case BIGINT_TAG:
return vm.throw_completion<TypeError>(ErrorType::Convert, "BigInt", "number");
case OBJECT_TAG: {
auto primitive = TRY(to_primitive(vm, PreferredType::Number));
return primitive.to_number(vm);
}
default:
VERIFY_NOT_REACHED();
}
}
static Optional<BigInt*> string_to_bigint(VM& vm, StringView string);
// 7.1.13 ToBigInt ( argument ), https://tc39.es/ecma262/#sec-tobigint
ThrowCompletionOr<BigInt*> Value::to_bigint(VM& vm) const
{
auto primitive = TRY(to_primitive(vm, PreferredType::Number));
VERIFY(!primitive.is_empty());
if (primitive.is_number())
return vm.throw_completion<TypeError>(ErrorType::Convert, "number", "BigInt");
switch (primitive.m_value.tag) {
case UNDEFINED_TAG:
return vm.throw_completion<TypeError>(ErrorType::Convert, "undefined", "BigInt");
case NULL_TAG:
return vm.throw_completion<TypeError>(ErrorType::Convert, "null", "BigInt");
case BOOLEAN_TAG: {
auto value = primitive.as_bool() ? 1 : 0;
return BigInt::create(vm, Crypto::SignedBigInteger { value }).ptr();
}
case BIGINT_TAG:
return &primitive.as_bigint();
case STRING_TAG: {
// 1. Let n be ! StringToBigInt(prim).
auto bigint = string_to_bigint(vm, primitive.as_string().deprecated_string());
// 2. If n is undefined, throw a SyntaxError exception.
if (!bigint.has_value())
return vm.throw_completion<SyntaxError>(ErrorType::BigIntInvalidValue, primitive);
// 3. Return n.
return bigint.release_value();
}
case SYMBOL_TAG:
return vm.throw_completion<TypeError>(ErrorType::Convert, "symbol", "BigInt");
default:
VERIFY_NOT_REACHED();
}
}
struct BigIntParseResult {
StringView literal;
u8 base { 10 };
bool is_negative { false };
};
static Optional<BigIntParseResult> parse_bigint_text(StringView text)
{
BigIntParseResult result {};
auto parse_for_prefixed_base = [&](auto lower_prefix, auto upper_prefix, auto validator) {
if (text.length() <= 2)
return false;
if (!text.starts_with(lower_prefix) && !text.starts_with(upper_prefix))
return false;
return all_of(text.substring_view(2), validator);
};
if (parse_for_prefixed_base("0b"sv, "0B"sv, is_ascii_binary_digit)) {
result.literal = text.substring_view(2);
result.base = 2;
} else if (parse_for_prefixed_base("0o"sv, "0O"sv, is_ascii_octal_digit)) {
result.literal = text.substring_view(2);
result.base = 8;
} else if (parse_for_prefixed_base("0x"sv, "0X"sv, is_ascii_hex_digit)) {
result.literal = text.substring_view(2);
result.base = 16;
} else {
if (text.starts_with('-')) {
text = text.substring_view(1);
result.is_negative = true;
} else if (text.starts_with('+')) {
text = text.substring_view(1);
}
if (!all_of(text, is_ascii_digit))
return {};
result.literal = text;
result.base = 10;
}
return result;
}
// 7.1.14 StringToBigInt ( str ), https://tc39.es/ecma262/#sec-stringtobigint
static Optional<BigInt*> string_to_bigint(VM& vm, StringView string)
{
// 1. Let text be StringToCodePoints(str).
auto text = Utf8View(string).trim(whitespace_characters, AK::TrimMode::Both).as_string();
// 2. Let literal be ParseText(text, StringIntegerLiteral).
auto result = parse_bigint_text(text);
// 3. If literal is a List of errors, return undefined.
if (!result.has_value())
return {};
// 4. Let mv be the MV of literal.
// 5. Assert: mv is an integer.
auto bigint = Crypto::SignedBigInteger::from_base(result->base, result->literal);
if (result->is_negative && (bigint != BIGINT_ZERO))
bigint.negate();
// 6. Return (mv).
return BigInt::create(vm, move(bigint));
}
// 7.1.15 ToBigInt64 ( argument ), https://tc39.es/ecma262/#sec-tobigint64
ThrowCompletionOr<i64> Value::to_bigint_int64(VM& vm) const
{
auto* bigint = TRY(to_bigint(vm));
return static_cast<i64>(bigint->big_integer().to_u64());
}
// 7.1.16 ToBigUint64 ( argument ), https://tc39.es/ecma262/#sec-tobiguint64
ThrowCompletionOr<u64> Value::to_bigint_uint64(VM& vm) const
{
auto* bigint = TRY(to_bigint(vm));
return bigint->big_integer().to_u64();
}
ThrowCompletionOr<double> Value::to_double(VM& vm) const
{
return TRY(to_number(vm)).as_double();
}
// 7.1.19 ToPropertyKey ( argument ), https://tc39.es/ecma262/#sec-topropertykey
ThrowCompletionOr<PropertyKey> Value::to_property_key(VM& vm) const
{
if (is_int32() && as_i32() >= 0)
return PropertyKey { as_i32() };
auto key = TRY(to_primitive(vm, PreferredType::String));
if (key.is_symbol())
return &key.as_symbol();
return TRY(key.to_string(vm));
}
ThrowCompletionOr<i32> Value::to_i32_slow_case(VM& vm) const
{
VERIFY(!is_int32());
double value = TRY(to_number(vm)).as_double();
if (!isfinite(value) || value == 0)
return 0;
auto abs = fabs(value);
auto int_val = floor(abs);
if (signbit(value))
int_val = -int_val;
auto remainder = fmod(int_val, 4294967296.0);
auto int32bit = remainder >= 0.0 ? remainder : remainder + 4294967296.0; // The notation “x modulo y” computes a value k of the same sign as y
if (int32bit >= 2147483648.0)
int32bit -= 4294967296.0;
return static_cast<i32>(int32bit);
}
ThrowCompletionOr<i32> Value::to_i32(VM& vm) const
{
if (is_int32())
return as_i32();
return to_i32_slow_case(vm);
}
// 7.1.7 ToUint32 ( argument ), https://tc39.es/ecma262/#sec-touint32
ThrowCompletionOr<u32> Value::to_u32(VM& vm) const
{
double value = TRY(to_number(vm)).as_double();
if (!isfinite(value) || value == 0)
return 0;
auto int_val = floor(fabs(value));
if (signbit(value))
int_val = -int_val;
auto int32bit = fmod(int_val, NumericLimits<u32>::max() + 1.0);
// Cast to i64 here to ensure that the double --> u32 cast doesn't invoke undefined behavior
// Otherwise, negative numbers cause a UBSAN warning.
return static_cast<u32>(static_cast<i64>(int32bit));
}
// 7.1.8 ToInt16 ( argument ), https://tc39.es/ecma262/#sec-toint16
ThrowCompletionOr<i16> Value::to_i16(VM& vm) const
{
double value = TRY(to_number(vm)).as_double();
if (!isfinite(value) || value == 0)
return 0;
auto abs = fabs(value);
auto int_val = floor(abs);
if (signbit(value))
int_val = -int_val;
auto remainder = fmod(int_val, 65536.0);
auto int16bit = remainder >= 0.0 ? remainder : remainder + 65536.0; // The notation “x modulo y” computes a value k of the same sign as y
if (int16bit >= 32768.0)
int16bit -= 65536.0;
return static_cast<i16>(int16bit);
}
// 7.1.9 ToUint16 ( argument ), https://tc39.es/ecma262/#sec-touint16
ThrowCompletionOr<u16> Value::to_u16(VM& vm) const
{
double value = TRY(to_number(vm)).as_double();
if (!isfinite(value) || value == 0)
return 0;
auto int_val = floor(fabs(value));
if (signbit(value))
int_val = -int_val;
auto int16bit = fmod(int_val, NumericLimits<u16>::max() + 1.0);
if (int16bit < 0)
int16bit += NumericLimits<u16>::max() + 1.0;
return static_cast<u16>(int16bit);
}
// 7.1.10 ToInt8 ( argument ), https://tc39.es/ecma262/#sec-toint8
ThrowCompletionOr<i8> Value::to_i8(VM& vm) const
{
double value = TRY(to_number(vm)).as_double();
if (!isfinite(value) || value == 0)
return 0;
auto abs = fabs(value);
auto int_val = floor(abs);
if (signbit(value))
int_val = -int_val;
auto remainder = fmod(int_val, 256.0);
auto int8bit = remainder >= 0.0 ? remainder : remainder + 256.0; // The notation “x modulo y” computes a value k of the same sign as y
if (int8bit >= 128.0)
int8bit -= 256.0;
return static_cast<i8>(int8bit);
}
// 7.1.11 ToUint8 ( argument ), https://tc39.es/ecma262/#sec-touint8
ThrowCompletionOr<u8> Value::to_u8(VM& vm) const
{
double value = TRY(to_number(vm)).as_double();
if (!isfinite(value) || value == 0)
return 0;
auto int_val = floor(fabs(value));
if (signbit(value))
int_val = -int_val;
auto int8bit = fmod(int_val, NumericLimits<u8>::max() + 1.0);
if (int8bit < 0)
int8bit += NumericLimits<u8>::max() + 1.0;
return static_cast<u8>(int8bit);
}
// 7.1.12 ToUint8Clamp ( argument ), https://tc39.es/ecma262/#sec-touint8clamp
ThrowCompletionOr<u8> Value::to_u8_clamp(VM& vm) const
{
auto number = TRY(to_number(vm));
if (number.is_nan())
return 0;
double value = number.as_double();
if (value <= 0.0)
return 0;
if (value >= 255.0)
return 255;
auto int_val = floor(value);
if (int_val + 0.5 < value)
return static_cast<u8>(int_val + 1.0);
if (value < int_val + 0.5)
return static_cast<u8>(int_val);
if (fmod(int_val, 2.0) == 1.0)
return static_cast<u8>(int_val + 1.0);
return static_cast<u8>(int_val);
}
// 7.1.20 ToLength ( argument ), https://tc39.es/ecma262/#sec-tolength
ThrowCompletionOr<size_t> Value::to_length(VM& vm) const
{
auto len = TRY(to_integer_or_infinity(vm));
if (len <= 0)
return 0;
// FIXME: The spec says that this function's output range is 0 - 2^53-1. But we don't want to overflow the size_t.
constexpr double length_limit = sizeof(void*) == 4 ? NumericLimits<size_t>::max() : MAX_ARRAY_LIKE_INDEX;
return min(len, length_limit);
}
// 7.1.22 ToIndex ( argument ), https://tc39.es/ecma262/#sec-toindex
ThrowCompletionOr<size_t> Value::to_index(VM& vm) const
{
if (is_undefined())
return 0;
auto integer_index = TRY(to_integer_or_infinity(vm));
if (integer_index < 0)
return vm.throw_completion<RangeError>(ErrorType::InvalidIndex);
auto index = MUST(Value(integer_index).to_length(vm));
if (integer_index != index)
return vm.throw_completion<RangeError>(ErrorType::InvalidIndex);
return index;
}
// 7.1.5 ToIntegerOrInfinity ( argument ), https://tc39.es/ecma262/#sec-tointegerorinfinity
ThrowCompletionOr<double> Value::to_integer_or_infinity(VM& vm) const
{
auto number = TRY(to_number(vm));
if (number.is_nan() || number.as_double() == 0)
return 0;
if (number.is_infinity())
return number.as_double();
auto integer = floor(fabs(number.as_double()));
if (number.as_double() < 0 && integer != 0)
integer = -integer;
return integer;
}
// Standalone variant using plain doubles for cases where we already got numbers and know the AO won't throw.
double to_integer_or_infinity(double number)
{
// 1. Let number be ? ToNumber(argument).
// 2. If number is NaN, +0𝔽, or -0𝔽, return 0.
if (isnan(number) || number == 0)
return 0;
// 3. If number is +∞𝔽, return +∞.
if (__builtin_isinf_sign(number) > 0)
return static_cast<double>(INFINITY);
// 4. If number is -∞𝔽, return -∞.
if (__builtin_isinf_sign(number) < 0)
return static_cast<double>(-INFINITY);
// 5. Let integer be floor(abs((number))).
auto integer = floor(fabs(number));
// 6. If number < -0𝔽, set integer to -integer.
if (number < 0 && integer != 0)
integer = -integer;
// 7. Return integer.
return integer;
}
// 7.3.3 GetV ( V, P ), https://tc39.es/ecma262/#sec-getv
ThrowCompletionOr<Value> Value::get(VM& vm, PropertyKey const& property_key) const
{
// 1. Assert: IsPropertyKey(P) is true.
VERIFY(property_key.is_valid());
// 2. Let O be ? ToObject(V).
auto* object = TRY(to_object(vm));
// 3. Return ? O.[[Get]](P, V).
return TRY(object->internal_get(property_key, *this));
}
// 7.3.11 GetMethod ( V, P ), https://tc39.es/ecma262/#sec-getmethod
ThrowCompletionOr<FunctionObject*> Value::get_method(VM& vm, PropertyKey const& property_key) const
{
// 1. Assert: IsPropertyKey(P) is true.
VERIFY(property_key.is_valid());
// 2. Let func be ? GetV(V, P).
auto function = TRY(get(vm, property_key));
// 3. If func is either undefined or null, return undefined.
if (function.is_nullish())
return nullptr;
// 4. If IsCallable(func) is false, throw a TypeError exception.
if (!function.is_function())
return vm.throw_completion<TypeError>(ErrorType::NotAFunction, function.to_string_without_side_effects());
// 5. Return func.
return &function.as_function();
}
// 13.10 Relational Operators, https://tc39.es/ecma262/#sec-relational-operators
ThrowCompletionOr<Value> greater_than(VM& vm, Value lhs, Value rhs)
{
if (lhs.is_int32() && rhs.is_int32())
return lhs.as_i32() > rhs.as_i32();
TriState relation = TRY(is_less_than(vm, lhs, rhs, false));
if (relation == TriState::Unknown)
return Value(false);
return Value(relation == TriState::True);
}
// 13.10 Relational Operators, https://tc39.es/ecma262/#sec-relational-operators
ThrowCompletionOr<Value> greater_than_equals(VM& vm, Value lhs, Value rhs)
{
if (lhs.is_int32() && rhs.is_int32())
return lhs.as_i32() >= rhs.as_i32();
TriState relation = TRY(is_less_than(vm, lhs, rhs, true));
if (relation == TriState::Unknown || relation == TriState::True)
return Value(false);
return Value(true);
}
// 13.10 Relational Operators, https://tc39.es/ecma262/#sec-relational-operators
ThrowCompletionOr<Value> less_than(VM& vm, Value lhs, Value rhs)
{
if (lhs.is_int32() && rhs.is_int32())
return lhs.as_i32() < rhs.as_i32();
TriState relation = TRY(is_less_than(vm, lhs, rhs, true));
if (relation == TriState::Unknown)
return Value(false);
return Value(relation == TriState::True);
}
// 13.10 Relational Operators, https://tc39.es/ecma262/#sec-relational-operators
ThrowCompletionOr<Value> less_than_equals(VM& vm, Value lhs, Value rhs)
{
if (lhs.is_int32() && rhs.is_int32())
return lhs.as_i32() <= rhs.as_i32();
TriState relation = TRY(is_less_than(vm, lhs, rhs, false));
if (relation == TriState::Unknown || relation == TriState::True)
return Value(false);
return Value(true);
}
// 13.12 Binary Bitwise Operators, https://tc39.es/ecma262/#sec-binary-bitwise-operators
ThrowCompletionOr<Value> bitwise_and(VM& vm, Value lhs, Value rhs)
{
auto lhs_numeric = TRY(lhs.to_numeric(vm));
auto rhs_numeric = TRY(rhs.to_numeric(vm));
if (both_number(lhs_numeric, rhs_numeric)) {
if (!lhs_numeric.is_finite_number() || !rhs_numeric.is_finite_number())
return Value(0);
return Value(TRY(lhs_numeric.to_i32(vm)) & TRY(rhs_numeric.to_i32(vm)));
}
if (both_bigint(lhs_numeric, rhs_numeric))
return BigInt::create(vm, lhs_numeric.as_bigint().big_integer().bitwise_and(rhs_numeric.as_bigint().big_integer()));
return vm.throw_completion<TypeError>(ErrorType::BigIntBadOperatorOtherType, "bitwise AND");
}
// 13.12 Binary Bitwise Operators, https://tc39.es/ecma262/#sec-binary-bitwise-operators
ThrowCompletionOr<Value> bitwise_or(VM& vm, Value lhs, Value rhs)
{
auto lhs_numeric = TRY(lhs.to_numeric(vm));
auto rhs_numeric = TRY(rhs.to_numeric(vm));
if (both_number(lhs_numeric, rhs_numeric)) {
if (!lhs_numeric.is_finite_number() && !rhs_numeric.is_finite_number())
return Value(0);
if (!lhs_numeric.is_finite_number())
return rhs_numeric;
if (!rhs_numeric.is_finite_number())
return lhs_numeric;
return Value(TRY(lhs_numeric.to_i32(vm)) | TRY(rhs_numeric.to_i32(vm)));
}
if (both_bigint(lhs_numeric, rhs_numeric))
return BigInt::create(vm, lhs_numeric.as_bigint().big_integer().bitwise_or(rhs_numeric.as_bigint().big_integer()));
return vm.throw_completion<TypeError>(ErrorType::BigIntBadOperatorOtherType, "bitwise OR");
}
// 13.12 Binary Bitwise Operators, https://tc39.es/ecma262/#sec-binary-bitwise-operators
ThrowCompletionOr<Value> bitwise_xor(VM& vm, Value lhs, Value rhs)
{
auto lhs_numeric = TRY(lhs.to_numeric(vm));
auto rhs_numeric = TRY(rhs.to_numeric(vm));
if (both_number(lhs_numeric, rhs_numeric)) {
if (!lhs_numeric.is_finite_number() && !rhs_numeric.is_finite_number())
return Value(0);
if (!lhs_numeric.is_finite_number())
return rhs_numeric;
if (!rhs_numeric.is_finite_number())
return lhs_numeric;
return Value(TRY(lhs_numeric.to_i32(vm)) ^ TRY(rhs_numeric.to_i32(vm)));
}
if (both_bigint(lhs_numeric, rhs_numeric))
return BigInt::create(vm, lhs_numeric.as_bigint().big_integer().bitwise_xor(rhs_numeric.as_bigint().big_integer()));
return vm.throw_completion<TypeError>(ErrorType::BigIntBadOperatorOtherType, "bitwise XOR");
}
// 13.5.6 Bitwise NOT Operator ( ~ ), https://tc39.es/ecma262/#sec-bitwise-not-operator
ThrowCompletionOr<Value> bitwise_not(VM& vm, Value lhs)
{
auto lhs_numeric = TRY(lhs.to_numeric(vm));
if (lhs_numeric.is_number())
return Value(~TRY(lhs_numeric.to_i32(vm)));
return BigInt::create(vm, lhs_numeric.as_bigint().big_integer().bitwise_not());
}
// 13.5.4 Unary + Operator, https://tc39.es/ecma262/#sec-unary-plus-operator
ThrowCompletionOr<Value> unary_plus(VM& vm, Value lhs)
{
return TRY(lhs.to_number(vm));
}
// 13.5.5 Unary - Operator, https://tc39.es/ecma262/#sec-unary-minus-operator
ThrowCompletionOr<Value> unary_minus(VM& vm, Value lhs)
{
auto lhs_numeric = TRY(lhs.to_numeric(vm));
if (lhs_numeric.is_number()) {
if (lhs_numeric.is_nan())
return js_nan();
return Value(-lhs_numeric.as_double());
}
if (lhs_numeric.as_bigint().big_integer() == BIGINT_ZERO)
return BigInt::create(vm, BIGINT_ZERO);
auto big_integer_negated = lhs_numeric.as_bigint().big_integer();
big_integer_negated.negate();
return BigInt::create(vm, big_integer_negated);
}
// 13.9.1 The Left Shift Operator ( << ), https://tc39.es/ecma262/#sec-left-shift-operator
ThrowCompletionOr<Value> left_shift(VM& vm, Value lhs, Value rhs)
{
auto lhs_numeric = TRY(lhs.to_numeric(vm));
auto rhs_numeric = TRY(rhs.to_numeric(vm));
if (both_number(lhs_numeric, rhs_numeric)) {
if (!lhs_numeric.is_finite_number())
return Value(0);
if (!rhs_numeric.is_finite_number())
return lhs_numeric;
// Ok, so this performs toNumber() again but that "can't" throw
auto lhs_i32 = MUST(lhs_numeric.to_i32(vm));
auto rhs_u32 = MUST(rhs_numeric.to_u32(vm)) % 32;
return Value(lhs_i32 << rhs_u32);
}
if (both_bigint(lhs_numeric, rhs_numeric)) {
// 6.1.6.2.9 BigInt::leftShift ( x, y ), https://tc39.es/ecma262/#sec-numeric-types-bigint-leftShift
auto multiplier_divisor = Crypto::SignedBigInteger { Crypto::NumberTheory::Power(Crypto::UnsignedBigInteger(2), rhs_numeric.as_bigint().big_integer().unsigned_value()) };
// 1. If y < 0, then
if (rhs_numeric.as_bigint().big_integer().is_negative()) {
// a. Return the BigInt value that represents (x) / 2^-y, rounding down to the nearest integer, including for negative numbers.
// NOTE: Since y is negative we can just do (x) / 2^|y|
auto const& big_integer = lhs_numeric.as_bigint().big_integer();
auto division_result = big_integer.divided_by(multiplier_divisor);
// For positive initial values and no remainder just return quotient
if (division_result.remainder.is_zero() || !big_integer.is_negative())
return BigInt::create(vm, division_result.quotient);
// For negative round "down" to the next negative number
return BigInt::create(vm, division_result.quotient.minus(Crypto::SignedBigInteger { 1 }));
}
// 2. Return the BigInt value that represents (x) × 2^y.
return Value(BigInt::create(vm, lhs_numeric.as_bigint().big_integer().multiplied_by(multiplier_divisor)));
}
return vm.throw_completion<TypeError>(ErrorType::BigIntBadOperatorOtherType, "left-shift");
}
// 13.9.2 The Signed Right Shift Operator ( >> ), https://tc39.es/ecma262/#sec-signed-right-shift-operator
ThrowCompletionOr<Value> right_shift(VM& vm, Value lhs, Value rhs)
{
auto lhs_numeric = TRY(lhs.to_numeric(vm));
auto rhs_numeric = TRY(rhs.to_numeric(vm));
if (both_number(lhs_numeric, rhs_numeric)) {
if (!lhs_numeric.is_finite_number())
return Value(0);
if (!rhs_numeric.is_finite_number())
return lhs_numeric;
auto lhs_i32 = MUST(lhs_numeric.to_i32(vm));
auto rhs_u32 = MUST(rhs_numeric.to_u32(vm)) % 32;
return Value(lhs_i32 >> rhs_u32);
}
if (both_bigint(lhs_numeric, rhs_numeric)) {
auto rhs_negated = rhs_numeric.as_bigint().big_integer();
rhs_negated.negate();
return left_shift(vm, lhs, BigInt::create(vm, rhs_negated));
}
return vm.throw_completion<TypeError>(ErrorType::BigIntBadOperatorOtherType, "right-shift");
}
// 13.9.3 The Unsigned Right Shift Operator ( >>> ), https://tc39.es/ecma262/#sec-unsigned-right-shift-operator
ThrowCompletionOr<Value> unsigned_right_shift(VM& vm, Value lhs, Value rhs)
{
auto lhs_numeric = TRY(lhs.to_numeric(vm));
auto rhs_numeric = TRY(rhs.to_numeric(vm));
if (both_number(lhs_numeric, rhs_numeric)) {
if (!lhs_numeric.is_finite_number())
return Value(0);
if (!rhs_numeric.is_finite_number())
return lhs_numeric;
// Ok, so this performs toNumber() again but that "can't" throw
auto lhs_u32 = MUST(lhs_numeric.to_u32(vm));
auto rhs_u32 = MUST(rhs_numeric.to_u32(vm)) % 32;
return Value(lhs_u32 >> rhs_u32);
}
return vm.throw_completion<TypeError>(ErrorType::BigIntBadOperator, "unsigned right-shift");
}
// 13.8.1 The Addition Operator ( + ), https://tc39.es/ecma262/#sec-addition-operator-plus
ThrowCompletionOr<Value> add(VM& vm, Value lhs, Value rhs)
{
if (both_number(lhs, rhs)) {
if (lhs.is_int32() && rhs.is_int32()) {
Checked<i32> result;
result = MUST(lhs.to_i32(vm));
result += MUST(rhs.to_i32(vm));
if (!result.has_overflow())
return Value(result.value());
}
return Value(lhs.as_double() + rhs.as_double());
}
auto lhs_primitive = TRY(lhs.to_primitive(vm));
auto rhs_primitive = TRY(rhs.to_primitive(vm));
if (lhs_primitive.is_string() || rhs_primitive.is_string()) {
auto lhs_string = TRY(lhs_primitive.to_primitive_string(vm));
auto rhs_string = TRY(rhs_primitive.to_primitive_string(vm));
return js_rope_string(vm, *lhs_string, *rhs_string);
}
auto lhs_numeric = TRY(lhs_primitive.to_numeric(vm));
auto rhs_numeric = TRY(rhs_primitive.to_numeric(vm));
if (both_number(lhs_numeric, rhs_numeric))
return Value(lhs_numeric.as_double() + rhs_numeric.as_double());
if (both_bigint(lhs_numeric, rhs_numeric))
return BigInt::create(vm, lhs_numeric.as_bigint().big_integer().plus(rhs_numeric.as_bigint().big_integer()));
return vm.throw_completion<TypeError>(ErrorType::BigIntBadOperatorOtherType, "addition");
}
// 13.8.2 The Subtraction Operator ( - ), https://tc39.es/ecma262/#sec-subtraction-operator-minus
ThrowCompletionOr<Value> sub(VM& vm, Value lhs, Value rhs)
{
auto lhs_numeric = TRY(lhs.to_numeric(vm));
auto rhs_numeric = TRY(rhs.to_numeric(vm));
if (both_number(lhs_numeric, rhs_numeric)) {
double lhsd = lhs_numeric.as_double();
double rhsd = rhs_numeric.as_double();
double interm = lhsd - rhsd;
return Value(interm);
}
if (both_bigint(lhs_numeric, rhs_numeric))
return BigInt::create(vm, lhs_numeric.as_bigint().big_integer().minus(rhs_numeric.as_bigint().big_integer()));
return vm.throw_completion<TypeError>(ErrorType::BigIntBadOperatorOtherType, "subtraction");
}
// 13.7 Multiplicative Operators, https://tc39.es/ecma262/#sec-multiplicative-operators
ThrowCompletionOr<Value> mul(VM& vm, Value lhs, Value rhs)
{
auto lhs_numeric = TRY(lhs.to_numeric(vm));
auto rhs_numeric = TRY(rhs.to_numeric(vm));
if (both_number(lhs_numeric, rhs_numeric))
return Value(lhs_numeric.as_double() * rhs_numeric.as_double());
if (both_bigint(lhs_numeric, rhs_numeric))
return BigInt::create(vm, lhs_numeric.as_bigint().big_integer().multiplied_by(rhs_numeric.as_bigint().big_integer()));
return vm.throw_completion<TypeError>(ErrorType::BigIntBadOperatorOtherType, "multiplication");
}
// 13.7 Multiplicative Operators, https://tc39.es/ecma262/#sec-multiplicative-operators
ThrowCompletionOr<Value> div(VM& vm, Value lhs, Value rhs)
{
auto lhs_numeric = TRY(lhs.to_numeric(vm));
auto rhs_numeric = TRY(rhs.to_numeric(vm));
if (both_number(lhs_numeric, rhs_numeric))
return Value(lhs_numeric.as_double() / rhs_numeric.as_double());
if (both_bigint(lhs_numeric, rhs_numeric)) {
if (rhs_numeric.as_bigint().big_integer() == BIGINT_ZERO)
return vm.throw_completion<RangeError>(ErrorType::DivisionByZero);
return BigInt::create(vm, lhs_numeric.as_bigint().big_integer().divided_by(rhs_numeric.as_bigint().big_integer()).quotient);
}
return vm.throw_completion<TypeError>(ErrorType::BigIntBadOperatorOtherType, "division");
}
// 13.7 Multiplicative Operators, https://tc39.es/ecma262/#sec-multiplicative-operators
ThrowCompletionOr<Value> mod(VM& vm, Value lhs, Value rhs)
{
auto lhs_numeric = TRY(lhs.to_numeric(vm));
auto rhs_numeric = TRY(rhs.to_numeric(vm));
if (both_number(lhs_numeric, rhs_numeric)) {
// 6.1.6.1.6 Number::remainder ( n, d ), https://tc39.es/ecma262/#sec-numeric-types-number-remainder
// The ECMA specification is describing the mathematical definition of modulus
// implemented by fmod.
auto n = lhs_numeric.as_double();
auto d = rhs_numeric.as_double();
return Value(fmod(n, d));
}
if (both_bigint(lhs_numeric, rhs_numeric)) {
if (rhs_numeric.as_bigint().big_integer() == BIGINT_ZERO)
return vm.throw_completion<RangeError>(ErrorType::DivisionByZero);
return BigInt::create(vm, lhs_numeric.as_bigint().big_integer().divided_by(rhs_numeric.as_bigint().big_integer()).remainder);
}
return vm.throw_completion<TypeError>(ErrorType::BigIntBadOperatorOtherType, "modulo");
}
static Value exp_double(Value base, Value exponent)
{
VERIFY(both_number(base, exponent));
if (exponent.is_nan())
return js_nan();
if (exponent.is_positive_zero() || exponent.is_negative_zero())
return Value(1);
if (base.is_nan())
return js_nan();
if (base.is_positive_infinity())
return exponent.as_double() > 0 ? js_infinity() : Value(0);
if (base.is_negative_infinity()) {
auto is_odd_integral_number = exponent.is_integral_number() && (static_cast<i32>(exponent.as_double()) % 2 != 0);
if (exponent.as_double() > 0)
return is_odd_integral_number ? js_negative_infinity() : js_infinity();
else
return is_odd_integral_number ? Value(-0.0) : Value(0);
}
if (base.is_positive_zero())
return exponent.as_double() > 0 ? Value(0) : js_infinity();
if (base.is_negative_zero()) {
auto is_odd_integral_number = exponent.is_integral_number() && (static_cast<i32>(exponent.as_double()) % 2 != 0);
if (exponent.as_double() > 0)
return is_odd_integral_number ? Value(-0.0) : Value(0);
else
return is_odd_integral_number ? js_negative_infinity() : js_infinity();
}
VERIFY(base.is_finite_number() && !base.is_positive_zero() && !base.is_negative_zero());
if (exponent.is_positive_infinity()) {
auto absolute_base = fabs(base.as_double());
if (absolute_base > 1)
return js_infinity();
else if (absolute_base == 1)
return js_nan();
else if (absolute_base < 1)
return Value(0);
}
if (exponent.is_negative_infinity()) {
auto absolute_base = fabs(base.as_double());
if (absolute_base > 1)
return Value(0);
else if (absolute_base == 1)
return js_nan();
else if (absolute_base < 1)
return js_infinity();
}
VERIFY(exponent.is_finite_number() && !exponent.is_positive_zero() && !exponent.is_negative_zero());
if (base.as_double() < 0 && !exponent.is_integral_number())
return js_nan();
return Value(::pow(base.as_double(), exponent.as_double()));
}
// 13.6 Exponentiation Operator, https://tc39.es/ecma262/#sec-exp-operator
ThrowCompletionOr<Value> exp(VM& vm, Value lhs, Value rhs)
{
auto lhs_numeric = TRY(lhs.to_numeric(vm));
auto rhs_numeric = TRY(rhs.to_numeric(vm));
if (both_number(lhs_numeric, rhs_numeric))
return exp_double(lhs_numeric, rhs_numeric);
if (both_bigint(lhs_numeric, rhs_numeric)) {
if (rhs_numeric.as_bigint().big_integer().is_negative())
return vm.throw_completion<RangeError>(ErrorType::NegativeExponent);
return BigInt::create(vm, Crypto::NumberTheory::Power(lhs_numeric.as_bigint().big_integer(), rhs_numeric.as_bigint().big_integer()));
}
return vm.throw_completion<TypeError>(ErrorType::BigIntBadOperatorOtherType, "exponentiation");
}
ThrowCompletionOr<Value> in(VM& vm, Value lhs, Value rhs)
{
if (!rhs.is_object())
return vm.throw_completion<TypeError>(ErrorType::InOperatorWithObject);
auto lhs_property_key = TRY(lhs.to_property_key(vm));
return Value(TRY(rhs.as_object().has_property(lhs_property_key)));
}
// 13.10.2 InstanceofOperator ( V, target ), https://tc39.es/ecma262/#sec-instanceofoperator
ThrowCompletionOr<Value> instance_of(VM& vm, Value lhs, Value rhs)
{
if (!rhs.is_object())
return vm.throw_completion<TypeError>(ErrorType::NotAnObject, rhs.to_string_without_side_effects());
auto has_instance_method = TRY(rhs.get_method(vm, *vm.well_known_symbol_has_instance()));
if (has_instance_method) {
auto has_instance_result = TRY(call(vm, *has_instance_method, rhs, lhs));
return Value(has_instance_result.to_boolean());
}
if (!rhs.is_function())
return vm.throw_completion<TypeError>(ErrorType::NotAFunction, rhs.to_string_without_side_effects());
return TRY(ordinary_has_instance(vm, lhs, rhs));
}
// 7.3.22 OrdinaryHasInstance ( C, O ), https://tc39.es/ecma262/#sec-ordinaryhasinstance
ThrowCompletionOr<Value> ordinary_has_instance(VM& vm, Value lhs, Value rhs)
{
if (!rhs.is_function())
return Value(false);
auto& rhs_function = rhs.as_function();
if (is<BoundFunction>(rhs_function)) {
auto& bound_target = static_cast<BoundFunction const&>(rhs_function);
return instance_of(vm, lhs, Value(&bound_target.bound_target_function()));
}
if (!lhs.is_object())
return Value(false);
Object* lhs_object = &lhs.as_object();
auto rhs_prototype = TRY(rhs_function.get(vm.names.prototype));
if (!rhs_prototype.is_object())
return vm.throw_completion<TypeError>(ErrorType::InstanceOfOperatorBadPrototype, rhs.to_string_without_side_effects());
while (true) {
lhs_object = TRY(lhs_object->internal_get_prototype_of());
if (!lhs_object)
return Value(false);
if (same_value(rhs_prototype, lhs_object))
return Value(true);
}
}
// 7.2.10 SameValue ( x, y ), https://tc39.es/ecma262/#sec-samevalue
bool same_value(Value lhs, Value rhs)
{
if (!same_type_for_equality(lhs, rhs))
return false;
if (lhs.is_number()) {
if (lhs.is_nan() && rhs.is_nan())
return true;
if (lhs.is_positive_zero() && rhs.is_negative_zero())
return false;
if (lhs.is_negative_zero() && rhs.is_positive_zero())
return false;
return lhs.as_double() == rhs.as_double();
}
if (lhs.is_bigint()) {
auto lhs_big_integer = lhs.as_bigint().big_integer();
auto rhs_big_integer = rhs.as_bigint().big_integer();
if (lhs_big_integer == BIGINT_ZERO && rhs_big_integer == BIGINT_ZERO && lhs_big_integer.is_negative() != rhs_big_integer.is_negative())
return false;
return lhs_big_integer == rhs_big_integer;
}
return same_value_non_numeric(lhs, rhs);
}
// 7.2.11 SameValueZero ( x, y ), https://tc39.es/ecma262/#sec-samevaluezero
bool same_value_zero(Value lhs, Value rhs)
{
if (!same_type_for_equality(lhs, rhs))
return false;
if (lhs.is_number()) {
if (lhs.is_nan() && rhs.is_nan())
return true;
return lhs.as_double() == rhs.as_double();
}
if (lhs.is_bigint())
return lhs.as_bigint().big_integer() == rhs.as_bigint().big_integer();
return same_value_non_numeric(lhs, rhs);
}
// 7.2.12 SameValueNonNumeric ( x, y ), https://tc39.es/ecma262/#sec-samevaluenonnumeric
bool same_value_non_numeric(Value lhs, Value rhs)
{
VERIFY(!lhs.is_number() && !lhs.is_bigint());
VERIFY(same_type_for_equality(lhs, rhs));
if (lhs.is_string())
return lhs.as_string().deprecated_string() == rhs.as_string().deprecated_string();
return lhs.m_value.encoded == rhs.m_value.encoded;
}
// 7.2.15 IsStrictlyEqual ( x, y ), https://tc39.es/ecma262/#sec-isstrictlyequal
bool is_strictly_equal(Value lhs, Value rhs)
{
if (!same_type_for_equality(lhs, rhs))
return false;
if (lhs.is_number()) {
if (lhs.is_nan() || rhs.is_nan())
return false;
if (lhs.as_double() == rhs.as_double())
return true;
return false;
}
if (lhs.is_bigint())
return lhs.as_bigint().big_integer() == rhs.as_bigint().big_integer();
return same_value_non_numeric(lhs, rhs);
}
// 7.2.14 IsLooselyEqual ( x, y ), https://tc39.es/ecma262/#sec-islooselyequal
ThrowCompletionOr<bool> is_loosely_equal(VM& vm, Value lhs, Value rhs)
{
// 1. If Type(x) is the same as Type(y), then
if (same_type_for_equality(lhs, rhs)) {
// a. Return IsStrictlyEqual(x, y).
return is_strictly_equal(lhs, rhs);
}
// 2. If x is null and y is undefined, return true.
// 3. If x is undefined and y is null, return true.
if (lhs.is_nullish() && rhs.is_nullish())
return true;
// 4. NOTE: This step is replaced in section B.3.6.2.
// B.3.6.2 Changes to IsLooselyEqual, https://tc39.es/ecma262/#sec-IsHTMLDDA-internal-slot-aec
// 4. Perform the following steps:
// a. If Type(x) is Object and x has an [[IsHTMLDDA]] internal slot and y is either null or undefined, return true.
if (lhs.is_object() && lhs.as_object().is_htmldda() && rhs.is_nullish())
return true;
// b. If x is either null or undefined and Type(y) is Object and y has an [[IsHTMLDDA]] internal slot, return true.
if (lhs.is_nullish() && rhs.is_object() && rhs.as_object().is_htmldda())
return true;
// == End of B.3.6.2 ==
// 5. If Type(x) is Number and Type(y) is String, return ! IsLooselyEqual(x, ! ToNumber(y)).
if (lhs.is_number() && rhs.is_string())
return is_loosely_equal(vm, lhs, MUST(rhs.to_number(vm)));
// 6. If Type(x) is String and Type(y) is Number, return ! IsLooselyEqual(! ToNumber(x), y).
if (lhs.is_string() && rhs.is_number())
return is_loosely_equal(vm, MUST(lhs.to_number(vm)), rhs);
// 7. If Type(x) is BigInt and Type(y) is String, then
if (lhs.is_bigint() && rhs.is_string()) {
// a. Let n be StringToBigInt(y).
auto bigint = string_to_bigint(vm, rhs.as_string().deprecated_string());
// b. If n is undefined, return false.
if (!bigint.has_value())
return false;
// c. Return ! IsLooselyEqual(x, n).
return is_loosely_equal(vm, lhs, *bigint);
}
// 8. If Type(x) is String and Type(y) is BigInt, return ! IsLooselyEqual(y, x).
if (lhs.is_string() && rhs.is_bigint())
return is_loosely_equal(vm, rhs, lhs);
// 9. If Type(x) is Boolean, return ! IsLooselyEqual(! ToNumber(x), y).
if (lhs.is_boolean())
return is_loosely_equal(vm, MUST(lhs.to_number(vm)), rhs);
// 10. If Type(y) is Boolean, return ! IsLooselyEqual(x, ! ToNumber(y)).
if (rhs.is_boolean())
return is_loosely_equal(vm, lhs, MUST(rhs.to_number(vm)));
// 11. If Type(x) is either String, Number, BigInt, or Symbol and Type(y) is Object, return ! IsLooselyEqual(x, ? ToPrimitive(y)).
if ((lhs.is_string() || lhs.is_number() || lhs.is_bigint() || lhs.is_symbol()) && rhs.is_object()) {
auto rhs_primitive = TRY(rhs.to_primitive(vm));
return is_loosely_equal(vm, lhs, rhs_primitive);
}
// 12. If Type(x) is Object and Type(y) is either String, Number, BigInt, or Symbol, return ! IsLooselyEqual(? ToPrimitive(x), y).
if (lhs.is_object() && (rhs.is_string() || rhs.is_number() || rhs.is_bigint() || rhs.is_symbol())) {
auto lhs_primitive = TRY(lhs.to_primitive(vm));
return is_loosely_equal(vm, lhs_primitive, rhs);
}
// 13. If Type(x) is BigInt and Type(y) is Number, or if Type(x) is Number and Type(y) is BigInt, then
if ((lhs.is_bigint() && rhs.is_number()) || (lhs.is_number() && rhs.is_bigint())) {
// a. If x or y are any of NaN, +∞𝔽, or -∞𝔽, return false.
if (lhs.is_nan() || lhs.is_infinity() || rhs.is_nan() || rhs.is_infinity())
return false;
// b. If (x) = (y), return true; otherwise return false.
if ((lhs.is_number() && !lhs.is_integral_number()) || (rhs.is_number() && !rhs.is_integral_number()))
return false;
VERIFY(!lhs.is_nan() && !rhs.is_nan());
auto& number_side = lhs.is_number() ? lhs : rhs;
auto& bigint_side = lhs.is_number() ? rhs : lhs;
return bigint_side.as_bigint().big_integer().compare_to_double(number_side.as_double()) == Crypto::UnsignedBigInteger::CompareResult::DoubleEqualsBigInt;
}
// 14. Return false.
return false;
}
// 7.2.13 IsLessThan ( x, y, LeftFirst ), https://tc39.es/ecma262/#sec-islessthan
ThrowCompletionOr<TriState> is_less_than(VM& vm, Value lhs, Value rhs, bool left_first)
{
Value x_primitive;
Value y_primitive;
if (left_first) {
x_primitive = TRY(lhs.to_primitive(vm, Value::PreferredType::Number));
y_primitive = TRY(rhs.to_primitive(vm, Value::PreferredType::Number));
} else {
y_primitive = TRY(lhs.to_primitive(vm, Value::PreferredType::Number));
x_primitive = TRY(rhs.to_primitive(vm, Value::PreferredType::Number));
}
if (x_primitive.is_string() && y_primitive.is_string()) {
auto x_string = x_primitive.as_string().deprecated_string();
auto y_string = y_primitive.as_string().deprecated_string();
Utf8View x_code_points { x_string };
Utf8View y_code_points { y_string };
if (x_code_points.starts_with(y_code_points))
return TriState::False;
if (y_code_points.starts_with(x_code_points))
return TriState::True;
for (auto k = x_code_points.begin(), l = y_code_points.begin();
k != x_code_points.end() && l != y_code_points.end();
++k, ++l) {
if (*k != *l) {
if (*k < *l) {
return TriState::True;
} else {
return TriState::False;
}
}
}
VERIFY_NOT_REACHED();
}
if (x_primitive.is_bigint() && y_primitive.is_string()) {
auto y_bigint = string_to_bigint(vm, y_primitive.as_string().deprecated_string());
if (!y_bigint.has_value())
return TriState::Unknown;
if (x_primitive.as_bigint().big_integer() < (*y_bigint)->big_integer())
return TriState::True;
return TriState::False;
}
if (x_primitive.is_string() && y_primitive.is_bigint()) {
auto x_bigint = string_to_bigint(vm, x_primitive.as_string().deprecated_string());
if (!x_bigint.has_value())
return TriState::Unknown;
if ((*x_bigint)->big_integer() < y_primitive.as_bigint().big_integer())
return TriState::True;
return TriState::False;
}
auto x_numeric = TRY(x_primitive.to_numeric(vm));
auto y_numeric = TRY(y_primitive.to_numeric(vm));
if (x_numeric.is_nan() || y_numeric.is_nan())
return TriState::Unknown;
if (x_numeric.is_positive_infinity() || y_numeric.is_negative_infinity())
return TriState::False;
if (x_numeric.is_negative_infinity() || y_numeric.is_positive_infinity())
return TriState::True;
if (x_numeric.is_number() && y_numeric.is_number()) {
if (x_numeric.as_double() < y_numeric.as_double())
return TriState::True;
else
return TriState::False;
}
if (x_numeric.is_bigint() && y_numeric.is_bigint()) {
if (x_numeric.as_bigint().big_integer() < y_numeric.as_bigint().big_integer())
return TriState::True;
else
return TriState::False;
}
VERIFY((x_numeric.is_number() && y_numeric.is_bigint()) || (x_numeric.is_bigint() && y_numeric.is_number()));
bool x_lower_than_y;
VERIFY(!x_numeric.is_nan() && !y_numeric.is_nan());
if (x_numeric.is_number()) {
x_lower_than_y = y_numeric.as_bigint().big_integer().compare_to_double(x_numeric.as_double())
== Crypto::UnsignedBigInteger::CompareResult::DoubleLessThanBigInt;
} else {
x_lower_than_y = x_numeric.as_bigint().big_integer().compare_to_double(y_numeric.as_double())
== Crypto::UnsignedBigInteger::CompareResult::DoubleGreaterThanBigInt;
}
if (x_lower_than_y)
return TriState::True;
else
return TriState::False;
}
// 7.3.21 Invoke ( V, P [ , argumentsList ] ), https://tc39.es/ecma262/#sec-invoke
ThrowCompletionOr<Value> Value::invoke_internal(VM& vm, PropertyKey const& property_key, Optional<MarkedVector<Value>> arguments)
{
auto property = TRY(get(vm, property_key));
if (!property.is_function())
return vm.throw_completion<TypeError>(ErrorType::NotAFunction, property.to_string_without_side_effects());
return call(vm, property.as_function(), *this, move(arguments));
}
}
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