/* * Copyright (C) 1999-2000 Harri Porten (porten@kde.org) * Copyright (C) 2002-2020 Apple Inc. All rights reserved. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public License * along with this library; see the file COPYING.LIB. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, * Boston, MA 02110-1301, USA. * */ #pragma once #include "CallFrame.h" #include "ExceptionHelpers.h" #include "JSBigInt.h" #include "JSCJSValueInlines.h" namespace JSC { #define InvalidPrototypeChain (std::numeric_limits::max()) NEVER_INLINE JSValue jsAddSlowCase(JSGlobalObject*, JSValue, JSValue); JSString* jsTypeStringForValueWithConcurrency(VM&, JSGlobalObject*, JSValue, Concurrency); size_t normalizePrototypeChain(JSGlobalObject*, JSCell*, bool& sawPolyProto); template ALWAYS_INLINE TriState jsTypeofIsObjectWithConcurrency(JSGlobalObject* globalObject, JSValue value) { VM& vm = globalObject->vm(); if (!value.isObject()) return triState(value.isNull()); JSObject* object = asObject(value); if (object->structure(vm)->masqueradesAsUndefined(globalObject)) return TriState::False; return invert(object->isCallableWithConcurrency(vm)); } template ALWAYS_INLINE TriState jsTypeofIsFunctionWithConcurrency(JSGlobalObject* globalObject, JSValue value) { VM& vm = globalObject->vm(); if (!value.isObject()) return TriState::False; JSObject* object = asObject(value); if (object->structure(vm)->masqueradesAsUndefined(globalObject)) return TriState::False; return object->isCallableWithConcurrency(vm); } inline JSString* jsTypeStringForValue(JSGlobalObject* globalObject, JSValue value) { return jsTypeStringForValueWithConcurrency(getVM(globalObject), globalObject, value, Concurrency::MainThread); } ALWAYS_INLINE bool jsTypeofIsObject(JSGlobalObject* globalObject, JSValue value) { auto result = jsTypeofIsObjectWithConcurrency(globalObject, value); ASSERT(result != TriState::Indeterminate); return result == TriState::True; } ALWAYS_INLINE bool jsTypeofIsFunction(JSGlobalObject* globalObject, JSValue value) { auto result = jsTypeofIsFunctionWithConcurrency(globalObject, value); ASSERT(result != TriState::Indeterminate); return result == TriState::True; } ALWAYS_INLINE JSString* jsString(JSGlobalObject* globalObject, const String& u1, JSString* s2) { VM& vm = getVM(globalObject); auto scope = DECLARE_THROW_SCOPE(vm); unsigned length1 = u1.length(); if (!length1) return s2; unsigned length2 = s2->length(); if (!length2) return jsString(vm, u1); static_assert(JSString::MaxLength == std::numeric_limits::max(), ""); if (sumOverflows(length1, length2)) { throwOutOfMemoryError(globalObject, scope); return nullptr; } // (1) Cost of making JSString : sizeof(JSString) (for new string) + sizeof(StringImpl header) + length1 + length2 // (2) Cost of making JSRopeString: sizeof(JSString) (for u1) + sizeof(JSRopeString) // We do not account u1 cost in (2) since u1 may be shared StringImpl, and it may not introduce additional cost. // We conservatively consider the cost of u1. Currently, we are not considering about is8Bit() case because 16-bit // strings are relatively rare. But we can do that if we need to consider it. if (s2->isRope() || (StringImpl::headerSize() + length1 + length2) >= sizeof(JSRopeString)) return JSRopeString::create(vm, jsString(vm, u1), s2); ASSERT(!s2->isRope()); const String& u2 = s2->value(globalObject); scope.assertNoException(); String newString = tryMakeString(u1, u2); if (!newString) { throwOutOfMemoryError(globalObject, scope); return nullptr; } return JSString::create(vm, newString.releaseImpl().releaseNonNull()); } ALWAYS_INLINE JSString* jsString(JSGlobalObject* globalObject, JSString* s1, const String& u2) { VM& vm = getVM(globalObject); auto scope = DECLARE_THROW_SCOPE(vm); unsigned length1 = s1->length(); if (!length1) return jsString(vm, u2); unsigned length2 = u2.length(); if (!length2) return s1; static_assert(JSString::MaxLength == std::numeric_limits::max(), ""); if (sumOverflows(length1, length2)) { throwOutOfMemoryError(globalObject, scope); return nullptr; } // (1) Cost of making JSString : sizeof(JSString) (for new string) + sizeof(StringImpl header) + length1 + length2 // (2) Cost of making JSRopeString: sizeof(JSString) (for u2) + sizeof(JSRopeString) if (s1->isRope() || (StringImpl::headerSize() + length1 + length2) >= sizeof(JSRopeString)) return JSRopeString::create(vm, s1, jsString(vm, u2)); ASSERT(!s1->isRope()); const String& u1 = s1->value(globalObject); scope.assertNoException(); String newString = tryMakeString(u1, u2); if (!newString) { throwOutOfMemoryError(globalObject, scope); return nullptr; } return JSString::create(vm, newString.releaseImpl().releaseNonNull()); } ALWAYS_INLINE JSString* jsString(JSGlobalObject* globalObject, JSString* s1, JSString* s2) { VM& vm = getVM(globalObject); auto scope = DECLARE_THROW_SCOPE(vm); unsigned length1 = s1->length(); if (!length1) return s2; unsigned length2 = s2->length(); if (!length2) return s1; static_assert(JSString::MaxLength == std::numeric_limits::max(), ""); if (sumOverflows(length1, length2)) { throwOutOfMemoryError(globalObject, scope); return nullptr; } return JSRopeString::create(vm, s1, s2); } ALWAYS_INLINE JSString* jsString(JSGlobalObject* globalObject, JSString* s1, JSString* s2, JSString* s3) { VM& vm = getVM(globalObject); auto scope = DECLARE_THROW_SCOPE(vm); unsigned length1 = s1->length(); if (!length1) RELEASE_AND_RETURN(scope, jsString(globalObject, s2, s3)); unsigned length2 = s2->length(); if (!length2) RELEASE_AND_RETURN(scope, jsString(globalObject, s1, s3)); unsigned length3 = s3->length(); if (!length3) RELEASE_AND_RETURN(scope, jsString(globalObject, s1, s2)); static_assert(JSString::MaxLength == std::numeric_limits::max(), ""); if (sumOverflows(length1, length2, length3)) { throwOutOfMemoryError(globalObject, scope); return nullptr; } return JSRopeString::create(vm, s1, s2, s3); } ALWAYS_INLINE JSString* jsString(JSGlobalObject* globalObject, const String& u1, const String& u2) { VM& vm = getVM(globalObject); auto scope = DECLARE_THROW_SCOPE(vm); unsigned length1 = u1.length(); if (!length1) return jsString(vm, u2); unsigned length2 = u2.length(); if (!length2) return jsString(vm, u1); static_assert(JSString::MaxLength == std::numeric_limits::max(), ""); if (sumOverflows(length1, length2)) { throwOutOfMemoryError(globalObject, scope); return nullptr; } // (1) Cost of making JSString : sizeof(JSString) (for new string) + sizeof(StringImpl header) + length1 + length2 // (2) Cost of making JSRopeString: sizeof(JSString) (for u1) + sizeof(JSString) (for u2) + sizeof(JSRopeString) if ((StringImpl::headerSize() + length1 + length2) >= (sizeof(JSRopeString) + sizeof(JSString))) return JSRopeString::create(vm, jsString(vm, u1), jsString(vm, u2)); String newString = tryMakeString(u1, u2); if (!newString) { throwOutOfMemoryError(globalObject, scope); return nullptr; } return JSString::create(vm, newString.releaseImpl().releaseNonNull()); } ALWAYS_INLINE JSString* jsString(JSGlobalObject* globalObject, const String& u1, const String& u2, const String& u3) { VM& vm = getVM(globalObject); auto scope = DECLARE_THROW_SCOPE(vm); unsigned length1 = u1.length(); unsigned length2 = u2.length(); unsigned length3 = u3.length(); ASSERT(length1 <= JSString::MaxLength); ASSERT(length2 <= JSString::MaxLength); ASSERT(length3 <= JSString::MaxLength); if (!length1) RELEASE_AND_RETURN(scope, jsString(globalObject, u2, u3)); if (!length2) RELEASE_AND_RETURN(scope, jsString(globalObject, u1, u3)); if (!length3) RELEASE_AND_RETURN(scope, jsString(globalObject, u1, u2)); static_assert(JSString::MaxLength == std::numeric_limits::max(), ""); if (sumOverflows(length1, length2, length3)) { throwOutOfMemoryError(globalObject, scope); return nullptr; } // (1) Cost of making JSString : sizeof(JSString) (for new string) + sizeof(StringImpl header) + length1 + length2 + length3 // (2) Cost of making JSRopeString: sizeof(JSString) (for u1) + sizeof(JSString) (for u2) + sizeof(JSString) (for u3) + sizeof(JSRopeString) if ((StringImpl::headerSize() + length1 + length2 + length3) >= (sizeof(JSRopeString) + sizeof(JSString) * 2)) return JSRopeString::create(vm, jsString(vm, u1), jsString(vm, u2), jsString(vm, u3)); String newString = tryMakeString(u1, u2, u3); if (!newString) { throwOutOfMemoryError(globalObject, scope); return nullptr; } return JSString::create(vm, newString.releaseImpl().releaseNonNull()); } ALWAYS_INLINE JSValue jsStringFromRegisterArray(JSGlobalObject* globalObject, Register* strings, unsigned count) { VM& vm = getVM(globalObject); auto scope = DECLARE_THROW_SCOPE(vm); JSRopeString::RopeBuilder ropeBuilder(vm); for (unsigned i = 0; i < count; ++i) { JSValue v = strings[-static_cast(i)].jsValue(); JSString* string = v.toString(globalObject); RETURN_IF_EXCEPTION(scope, { }); if (!ropeBuilder.append(string)) return throwOutOfMemoryError(globalObject, scope); } return ropeBuilder.release(); } ALWAYS_INLINE JSBigInt::ComparisonResult compareBigInt(JSValue left, JSValue right) { ASSERT(left.isBigInt()); ASSERT(right.isBigInt()); #if USE(BIGINT32) if (left.isBigInt32()) { if (right.isBigInt32()) return JSBigInt::compare(left.bigInt32AsInt32(), right.bigInt32AsInt32()); ASSERT(right.isHeapBigInt()); return JSBigInt::compare(left.bigInt32AsInt32(), right.asHeapBigInt()); } if (right.isBigInt32()) { ASSERT(left.isHeapBigInt()); return JSBigInt::compare(left.asHeapBigInt(), right.bigInt32AsInt32()); } #endif return JSBigInt::compare(left.asHeapBigInt(), right.asHeapBigInt()); } ALWAYS_INLINE JSBigInt::ComparisonResult compareBigIntToOtherPrimitive(JSGlobalObject* globalObject, JSBigInt* v1, JSValue primValue) { VM& vm = globalObject->vm(); auto scope = DECLARE_THROW_SCOPE(vm); ASSERT(primValue.isPrimitive()); ASSERT(!primValue.isBigInt()); if (primValue.isString()) { String string = asString(primValue)->value(globalObject); RETURN_IF_EXCEPTION(scope, JSBigInt::ComparisonResult::Undefined); JSValue bigIntValue = JSBigInt::stringToBigInt(globalObject, string); RETURN_IF_EXCEPTION(scope, JSBigInt::ComparisonResult::Undefined); if (!bigIntValue) return JSBigInt::ComparisonResult::Undefined; if (bigIntValue.isHeapBigInt()) return JSBigInt::compare(v1, bigIntValue.asHeapBigInt()); ASSERT(bigIntValue.isBigInt32()); #if USE(BIGINT32) // FIXME: use something less hacky, e.g. some kind of JSBigInt::compareToInt32 return JSBigInt::compareToDouble(v1, static_cast(bigIntValue.bigInt32AsInt32())); #endif } double numberValue = primValue.toNumber(globalObject); RETURN_IF_EXCEPTION(scope, JSBigInt::ComparisonResult::Undefined); return JSBigInt::compareToDouble(v1, numberValue); } ALWAYS_INLINE JSBigInt::ComparisonResult compareBigInt32ToOtherPrimitive(JSGlobalObject* globalObject, int32_t v1, JSValue primValue) { VM& vm = globalObject->vm(); auto scope = DECLARE_THROW_SCOPE(vm); ASSERT(primValue.isPrimitive()); ASSERT(!primValue.isBigInt()); auto compare = [&] (auto v1, auto v2) { static_assert(std::is_same_v); if (v1 == v2) return JSBigInt::ComparisonResult::Equal; if (v1 < v2) return JSBigInt::ComparisonResult::LessThan; return JSBigInt::ComparisonResult::GreaterThan; }; if (primValue.isString()) { String string = asString(primValue)->value(globalObject); RETURN_IF_EXCEPTION(scope, JSBigInt::ComparisonResult::Undefined); JSValue bigIntValue = JSBigInt::stringToBigInt(globalObject, string); RETURN_IF_EXCEPTION(scope, JSBigInt::ComparisonResult::Undefined); if (!bigIntValue) return JSBigInt::ComparisonResult::Undefined; if (bigIntValue.isHeapBigInt()) return JSBigInt::compare(v1, bigIntValue.asHeapBigInt()); ASSERT(bigIntValue.isBigInt32()); #if USE(BIGINT32) return compare(v1, bigIntValue.bigInt32AsInt32()); #endif } // Note that 0n <=> -0.0 is handling -0.0 as +0. double numberValue = primValue.toNumber(globalObject); RETURN_IF_EXCEPTION(scope, JSBigInt::ComparisonResult::Undefined); if (std::isnan(numberValue)) return JSBigInt::ComparisonResult::Undefined; return compare(static_cast(v1), numberValue); } ALWAYS_INLINE bool bigIntCompareResult(JSBigInt::ComparisonResult comparisonResult, JSBigInt::ComparisonMode comparisonMode) { if (comparisonMode == JSBigInt::ComparisonMode::LessThan) return comparisonResult == JSBigInt::ComparisonResult::LessThan; ASSERT(comparisonMode == JSBigInt::ComparisonMode::LessThanOrEqual); return comparisonResult == JSBigInt::ComparisonResult::LessThan || comparisonResult == JSBigInt::ComparisonResult::Equal; } ALWAYS_INLINE bool bigIntCompare(JSGlobalObject* globalObject, JSValue v1, JSValue v2, JSBigInt::ComparisonMode comparisonMode) { ASSERT(v1.isBigInt() || v2.isBigInt()); ASSERT(v1.isPrimitive() && v2.isPrimitive()); VM& vm = globalObject->vm(); auto scope = DECLARE_THROW_SCOPE(vm); if (v1.isBigInt() && v2.isBigInt()) return bigIntCompareResult(compareBigInt(v1, v2), comparisonMode); #if USE(BIGINT32) if (v1.isBigInt32()) { ASSERT(!v2.isBigInt()); auto comparisonResult = compareBigInt32ToOtherPrimitive(globalObject, v1.bigInt32AsInt32(), v2); RETURN_IF_EXCEPTION(scope, false); return bigIntCompareResult(comparisonResult, comparisonMode); } if (v2.isBigInt32()) { ASSERT(!v1.isBigInt()); auto comparisonResult = compareBigInt32ToOtherPrimitive(globalObject, v2.bigInt32AsInt32(), v1); RETURN_IF_EXCEPTION(scope, false); return bigIntCompareResult(invertBigIntCompareResult(comparisonResult), comparisonMode); } ASSERT(!v1.isBigInt32() && !v2.isBigInt32()); #endif if (v1.isHeapBigInt()) { ASSERT(!v2.isBigInt()); auto comparisonResult = compareBigIntToOtherPrimitive(globalObject, v1.asHeapBigInt(), v2); RETURN_IF_EXCEPTION(scope, false); return bigIntCompareResult(comparisonResult, comparisonMode); } // Here we check inverted because BigInt is the v2 ASSERT(!v1.isBigInt()); ASSERT(v2.isHeapBigInt()); auto comparisonResult = compareBigIntToOtherPrimitive(globalObject, v2.asHeapBigInt(), v1); RETURN_IF_EXCEPTION(scope, false); return bigIntCompareResult(invertBigIntCompareResult(comparisonResult), comparisonMode); } ALWAYS_INLINE bool toPrimitiveNumeric(JSGlobalObject* globalObject, JSValue v, JSValue& p, double& n) { VM& vm = globalObject->vm(); auto scope = DECLARE_THROW_SCOPE(vm); p = v.toPrimitive(globalObject, PreferNumber); RETURN_IF_EXCEPTION(scope, false); if (p.isBigInt()) return true; n = p.toNumber(globalObject); RETURN_IF_EXCEPTION(scope, false); return !p.isString(); } // See ES5 11.8.1/11.8.2/11.8.5 for definition of leftFirst, this value ensures correct // evaluation ordering for argument conversions for '<' and '>'. For '<' pass the value // true, for leftFirst, for '>' pass the value false (and reverse operand order). template ALWAYS_INLINE bool jsLess(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { VM& vm = globalObject->vm(); auto scope = DECLARE_THROW_SCOPE(vm); if (v1.isInt32() && v2.isInt32()) return v1.asInt32() < v2.asInt32(); if (v1.isNumber() && v2.isNumber()) return v1.asNumber() < v2.asNumber(); if (isJSString(v1) && isJSString(v2)) { String s1 = asString(v1)->value(globalObject); RETURN_IF_EXCEPTION(scope, false); String s2 = asString(v2)->value(globalObject); RETURN_IF_EXCEPTION(scope, false); return codePointCompareLessThan(s1, s2); } double n1; double n2; JSValue p1; JSValue p2; bool wasNotString1; bool wasNotString2; if (leftFirst) { wasNotString1 = toPrimitiveNumeric(globalObject, v1, p1, n1); RETURN_IF_EXCEPTION(scope, false); wasNotString2 = toPrimitiveNumeric(globalObject, v2, p2, n2); } else { wasNotString2 = toPrimitiveNumeric(globalObject, v2, p2, n2); RETURN_IF_EXCEPTION(scope, false); wasNotString1 = toPrimitiveNumeric(globalObject, v1, p1, n1); } RETURN_IF_EXCEPTION(scope, false); if (wasNotString1 || wasNotString2) { if (p1.isBigInt() || p2.isBigInt()) RELEASE_AND_RETURN(scope, bigIntCompare(globalObject, p1, p2, JSBigInt::ComparisonMode::LessThan)); return n1 < n2; } return codePointCompareLessThan(asString(p1)->value(globalObject), asString(p2)->value(globalObject)); } // See ES5 11.8.3/11.8.4/11.8.5 for definition of leftFirst, this value ensures correct // evaluation ordering for argument conversions for '<=' and '=>'. For '<=' pass the // value true, for leftFirst, for '=>' pass the value false (and reverse operand order). template ALWAYS_INLINE bool jsLessEq(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { VM& vm = globalObject->vm(); auto scope = DECLARE_THROW_SCOPE(vm); if (v1.isInt32() && v2.isInt32()) return v1.asInt32() <= v2.asInt32(); if (v1.isNumber() && v2.isNumber()) return v1.asNumber() <= v2.asNumber(); if (isJSString(v1) && isJSString(v2)) { String s1 = asString(v1)->value(globalObject); RETURN_IF_EXCEPTION(scope, false); String s2 = asString(v2)->value(globalObject); RETURN_IF_EXCEPTION(scope, false); return !codePointCompareLessThan(s2, s1); } double n1; double n2; JSValue p1; JSValue p2; bool wasNotString1; bool wasNotString2; if (leftFirst) { wasNotString1 = toPrimitiveNumeric(globalObject, v1, p1, n1); RETURN_IF_EXCEPTION(scope, false); wasNotString2 = toPrimitiveNumeric(globalObject, v2, p2, n2); } else { wasNotString2 = toPrimitiveNumeric(globalObject, v2, p2, n2); RETURN_IF_EXCEPTION(scope, false); wasNotString1 = toPrimitiveNumeric(globalObject, v1, p1, n1); } RETURN_IF_EXCEPTION(scope, false); if (wasNotString1 || wasNotString2) { if (p1.isBigInt() || p2.isBigInt()) RELEASE_AND_RETURN(scope, bigIntCompare(globalObject, p1, p2, JSBigInt::ComparisonMode::LessThanOrEqual)); return n1 <= n2; } return !codePointCompareLessThan(asString(p2)->value(globalObject), asString(p1)->value(globalObject)); } // Fast-path choices here are based on frequency data from SunSpider: // Add case: // --------------------------- // 5626160 Add case: 3 3 (of these, 3637690 are for immediate values) // 247412 Add case: 5 5 // 20900 Add case: 5 6 // 13962 Add case: 5 3 // 4000 Add case: 3 5 ALWAYS_INLINE JSValue jsAddNonNumber(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { VM& vm = globalObject->vm(); auto scope = DECLARE_THROW_SCOPE(vm); ASSERT(!v1.isNumber() || !v2.isNumber()); if (LIKELY(v1.isString() && !v2.isObject())) { if (v2.isString()) RELEASE_AND_RETURN(scope, jsString(globalObject, asString(v1), asString(v2))); String s2 = v2.toWTFString(globalObject); RETURN_IF_EXCEPTION(scope, { }); RELEASE_AND_RETURN(scope, jsString(globalObject, asString(v1), s2)); } // All other cases are pretty uncommon RELEASE_AND_RETURN(scope, jsAddSlowCase(globalObject, v1, v2)); } ALWAYS_INLINE JSValue jsAdd(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { if (v1.isNumber() && v2.isNumber()) return jsNumber(v1.asNumber() + v2.asNumber()); return jsAddNonNumber(globalObject, v1, v2); } template ALWAYS_INLINE JSValue arithmeticBinaryOp(JSGlobalObject* globalObject, JSValue v1, JSValue v2, DoubleOperation&& doubleOp, BigIntOp&& bigIntOp, const char* errorMessage) { VM& vm = globalObject->vm(); auto scope = DECLARE_THROW_SCOPE(vm); JSValue leftNumeric = v1.toNumeric(globalObject); RETURN_IF_EXCEPTION(scope, { }); JSValue rightNumeric = v2.toNumeric(globalObject); RETURN_IF_EXCEPTION(scope, { }); if (leftNumeric.isNumber() && rightNumeric.isNumber()) return jsNumber(doubleOp(leftNumeric.asNumber(), rightNumeric.asNumber())); #if USE(BIGINT32) if (leftNumeric.isBigInt32()) { if (rightNumeric.isBigInt32()) RELEASE_AND_RETURN(scope, bigIntOp(globalObject, leftNumeric.bigInt32AsInt32(), rightNumeric.bigInt32AsInt32())); if (rightNumeric.isHeapBigInt()) RELEASE_AND_RETURN(scope, bigIntOp(globalObject, leftNumeric.bigInt32AsInt32(), rightNumeric.asHeapBigInt())); } else if (leftNumeric.isHeapBigInt()) { if (rightNumeric.isBigInt32()) RELEASE_AND_RETURN(scope, bigIntOp(globalObject, leftNumeric.asHeapBigInt(), rightNumeric.bigInt32AsInt32())); else if (rightNumeric.isHeapBigInt()) RELEASE_AND_RETURN(scope, bigIntOp(globalObject, leftNumeric.asHeapBigInt(), rightNumeric.asHeapBigInt())); } #else if (leftNumeric.isHeapBigInt() && rightNumeric.isHeapBigInt()) RELEASE_AND_RETURN(scope, bigIntOp(globalObject, leftNumeric.asHeapBigInt(), rightNumeric.asHeapBigInt())); #endif return throwTypeError(globalObject, scope, errorMessage); } ALWAYS_INLINE JSValue jsSub(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { auto doubleOp = [] (double left, double right) -> double { return left - right; }; auto bigIntOp = [] (JSGlobalObject* globalObject, auto left, auto right) { return JSBigInt::sub(globalObject, left, right); }; return arithmeticBinaryOp(globalObject, v1, v2, doubleOp, bigIntOp, "Invalid mix of BigInt and other type in subtraction."_s); } ALWAYS_INLINE JSValue jsMul(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { auto doubleOp = [] (double left, double right) -> double { return left * right; }; auto bigIntOp = [] (JSGlobalObject* globalObject, auto left, auto right) { return JSBigInt::multiply(globalObject, left, right); }; return arithmeticBinaryOp(globalObject, v1, v2, doubleOp, bigIntOp, "Invalid mix of BigInt and other type in multiplication."_s); } ALWAYS_INLINE JSValue jsDiv(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { auto doubleOp = [] (double left, double right) -> double { return left / right; }; auto bigIntOp = [] (JSGlobalObject* globalObject, auto left, auto right) { return JSBigInt::divide(globalObject, left, right); }; return arithmeticBinaryOp(globalObject, v1, v2, doubleOp, bigIntOp, "Invalid mix of BigInt and other type in division."_s); } ALWAYS_INLINE JSValue jsRemainder(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { auto doubleOp = [] (double left, double right) -> double { return Math::fmodDouble(left, right); }; auto bigIntOp = [] (JSGlobalObject* globalObject, auto left, auto right) { return JSBigInt::remainder(globalObject, left, right); }; return arithmeticBinaryOp(globalObject, v1, v2, doubleOp, bigIntOp, "Invalid mix of BigInt and other type in remainder."_s); } ALWAYS_INLINE JSValue jsPow(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { auto doubleOp = [] (double left, double right) -> double { return operationMathPow(left, right); }; auto bigIntOp = [] (JSGlobalObject* globalObject, auto left, auto right) { return JSBigInt::exponentiate(globalObject, left, right); }; return arithmeticBinaryOp(globalObject, v1, v2, doubleOp, bigIntOp, "Invalid mix of BigInt and other type in exponentiation."_s); } ALWAYS_INLINE JSValue jsInc(JSGlobalObject* globalObject, JSValue v) { VM& vm = globalObject->vm(); auto scope = DECLARE_THROW_SCOPE(vm); auto operandNumeric = v.toNumeric(globalObject); RETURN_IF_EXCEPTION(scope, { }); if (operandNumeric.isNumber()) return jsNumber(operandNumeric.asNumber() + 1); #if USE(BIGINT32) if (operandNumeric.isBigInt32()) RELEASE_AND_RETURN(scope, JSBigInt::inc(globalObject, operandNumeric.bigInt32AsInt32())); #endif ASSERT(operandNumeric.isHeapBigInt()); RELEASE_AND_RETURN(scope, JSBigInt::inc(globalObject, operandNumeric.asHeapBigInt())); } ALWAYS_INLINE JSValue jsDec(JSGlobalObject* globalObject, JSValue v) { VM& vm = globalObject->vm(); auto scope = DECLARE_THROW_SCOPE(vm); auto operandNumeric = v.toNumeric(globalObject); RETURN_IF_EXCEPTION(scope, { }); if (operandNumeric.isNumber()) return jsNumber(operandNumeric.asNumber() - 1); #if USE(BIGINT32) if (operandNumeric.isBigInt32()) RELEASE_AND_RETURN(scope, JSBigInt::dec(globalObject, operandNumeric.bigInt32AsInt32())); #endif ASSERT(operandNumeric.isHeapBigInt()); RELEASE_AND_RETURN(scope, JSBigInt::dec(globalObject, operandNumeric.asHeapBigInt())); } ALWAYS_INLINE JSValue jsBitwiseNot(JSGlobalObject* globalObject, JSValue v) { VM& vm = globalObject->vm(); auto scope = DECLARE_THROW_SCOPE(vm); auto operandNumeric = v.toBigIntOrInt32(globalObject); RETURN_IF_EXCEPTION(scope, { }); if (operandNumeric.isInt32()) return jsNumber(~operandNumeric.asInt32()); #if USE(BIGINT32) if (operandNumeric.isBigInt32()) RELEASE_AND_RETURN(scope, JSBigInt::bitwiseNot(globalObject, operandNumeric.bigInt32AsInt32())); #endif ASSERT(operandNumeric.isHeapBigInt()); RELEASE_AND_RETURN(scope, JSBigInt::bitwiseNot(globalObject, operandNumeric.asHeapBigInt())); } template ALWAYS_INLINE JSValue shift(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { VM& vm = globalObject->vm(); auto scope = DECLARE_THROW_SCOPE(vm); auto leftNumeric = v1.toBigIntOrInt32(globalObject); RETURN_IF_EXCEPTION(scope, { }); auto rightNumeric = v2.toBigIntOrInt32(globalObject); RETURN_IF_EXCEPTION(scope, { }); if (leftNumeric.isInt32() && rightNumeric.isInt32()) { int32_t leftInt32 = leftNumeric.asInt32(); int32_t rightInt32 = rightNumeric.asInt32() & 31; int32_t result = isLeft ? (leftInt32 << rightInt32) : (leftInt32 >> rightInt32); return jsNumber(result); } #if USE(BIGINT32) if (leftNumeric.isBigInt32()) { if (rightNumeric.isBigInt32()) { if (isLeft) RELEASE_AND_RETURN(scope, JSBigInt::leftShift(globalObject, leftNumeric.bigInt32AsInt32(), rightNumeric.bigInt32AsInt32())); RELEASE_AND_RETURN(scope, JSBigInt::signedRightShift(globalObject, leftNumeric.bigInt32AsInt32(), rightNumeric.bigInt32AsInt32())); } if (rightNumeric.isHeapBigInt()) { if (isLeft) RELEASE_AND_RETURN(scope, JSBigInt::leftShift(globalObject, leftNumeric.bigInt32AsInt32(), rightNumeric.asHeapBigInt())); RELEASE_AND_RETURN(scope, JSBigInt::signedRightShift(globalObject, leftNumeric.bigInt32AsInt32(), rightNumeric.asHeapBigInt())); } } else if (leftNumeric.isHeapBigInt()) { if (rightNumeric.isBigInt32()) { if (isLeft) RELEASE_AND_RETURN(scope, JSBigInt::leftShift(globalObject, leftNumeric.asHeapBigInt(), rightNumeric.bigInt32AsInt32())); RELEASE_AND_RETURN(scope, JSBigInt::signedRightShift(globalObject, leftNumeric.asHeapBigInt(), rightNumeric.bigInt32AsInt32())); } else if (rightNumeric.isHeapBigInt()) { if (isLeft) RELEASE_AND_RETURN(scope, JSBigInt::leftShift(globalObject, leftNumeric.asHeapBigInt(), rightNumeric.asHeapBigInt())); RELEASE_AND_RETURN(scope, JSBigInt::signedRightShift(globalObject, leftNumeric.asHeapBigInt(), rightNumeric.asHeapBigInt())); } } #else if (leftNumeric.isHeapBigInt() && rightNumeric.isHeapBigInt()) { if (isLeft) RELEASE_AND_RETURN(scope, JSBigInt::leftShift(globalObject, leftNumeric.asHeapBigInt(), rightNumeric.asHeapBigInt())); RELEASE_AND_RETURN(scope, JSBigInt::signedRightShift(globalObject, leftNumeric.asHeapBigInt(), rightNumeric.asHeapBigInt())); } #endif auto errorMessage = isLeft ? "Invalid mix of BigInt and other type in left shift operation." : "Invalid mix of BigInt and other type in signed right shift operation."; return throwTypeError(globalObject, scope, errorMessage); } ALWAYS_INLINE JSValue jsLShift(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { constexpr bool isLeft = true; return shift(globalObject, v1, v2); } ALWAYS_INLINE JSValue jsRShift(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { constexpr bool isLeft = false; return shift(globalObject, v1, v2); } ALWAYS_INLINE JSValue jsURShift(JSGlobalObject* globalObject, JSValue left, JSValue right) { VM& vm = globalObject->vm(); auto scope = DECLARE_THROW_SCOPE(vm); Optional leftUint32 = left.toUInt32AfterToNumeric(globalObject); RETURN_IF_EXCEPTION(scope, { }); Optional rightUint32 = right.toUInt32AfterToNumeric(globalObject); RETURN_IF_EXCEPTION(scope, { }); if (UNLIKELY(!leftUint32 || !rightUint32)) { throwTypeError(globalObject, scope, "BigInt does not support >>> operator"_s); return { }; } return jsNumber(static_cast(leftUint32.value() >> (rightUint32.value() & 31))); } template ALWAYS_INLINE JSValue bitwiseBinaryOp(JSGlobalObject* globalObject, JSValue v1, JSValue v2, Int32Operation&& int32Op, BigIntOp&& bigIntOp, const char* errorMessage) { VM& vm = globalObject->vm(); auto scope = DECLARE_THROW_SCOPE(vm); auto leftNumeric = v1.toBigIntOrInt32(globalObject); RETURN_IF_EXCEPTION(scope, { }); auto rightNumeric = v2.toBigIntOrInt32(globalObject); RETURN_IF_EXCEPTION(scope, { }); if (leftNumeric.isInt32() && rightNumeric.isInt32()) return jsNumber(int32Op(leftNumeric.asInt32(), rightNumeric.asInt32())); #if USE(BIGINT32) if (leftNumeric.isBigInt32()) { if (rightNumeric.isBigInt32()) RELEASE_AND_RETURN(scope, bigIntOp(globalObject, leftNumeric.bigInt32AsInt32(), rightNumeric.bigInt32AsInt32())); if (rightNumeric.isHeapBigInt()) RELEASE_AND_RETURN(scope, bigIntOp(globalObject, leftNumeric.bigInt32AsInt32(), rightNumeric.asHeapBigInt())); } else if (leftNumeric.isHeapBigInt()) { if (rightNumeric.isBigInt32()) RELEASE_AND_RETURN(scope, bigIntOp(globalObject, leftNumeric.asHeapBigInt(), rightNumeric.bigInt32AsInt32())); else if (rightNumeric.isHeapBigInt()) RELEASE_AND_RETURN(scope, bigIntOp(globalObject, leftNumeric.asHeapBigInt(), rightNumeric.asHeapBigInt())); } #else if (leftNumeric.isHeapBigInt() && rightNumeric.isHeapBigInt()) RELEASE_AND_RETURN(scope, bigIntOp(globalObject, leftNumeric.asHeapBigInt(), rightNumeric.asHeapBigInt())); #endif return throwTypeError(globalObject, scope, errorMessage); } ALWAYS_INLINE JSValue jsBitwiseAnd(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { auto int32Op = [] (int32_t left, int32_t right) -> int32_t { return left & right; }; auto bigIntOp = [] (JSGlobalObject* globalObject, auto left, auto right) { return JSBigInt::bitwiseAnd(globalObject, left, right); }; // FIXME: currently, for pairs of BigInt32, we unbox them, do the "and" and re-box them. // We could do it directly on the JSValue. return bitwiseBinaryOp(globalObject, v1, v2, int32Op, bigIntOp, "Invalid mix of BigInt and other type in bitwise 'and' operation."_s); } ALWAYS_INLINE JSValue jsBitwiseOr(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { auto int32Op = [] (int32_t left, int32_t right) -> int32_t { return left | right; }; // FIXME: currently, for pairs of BigInt32, we unbox them, do the "or" and re-box them. // We could do it directly on the JSValue. auto bigIntOp = [] (JSGlobalObject* globalObject, auto left, auto right) { return JSBigInt::bitwiseOr(globalObject, left, right); }; return bitwiseBinaryOp(globalObject, v1, v2, int32Op, bigIntOp, "Invalid mix of BigInt and other type in bitwise 'or' operation."_s); } ALWAYS_INLINE JSValue jsBitwiseXor(JSGlobalObject* globalObject, JSValue v1, JSValue v2) { auto int32Op = [] (int32_t left, int32_t right) -> int32_t { return left ^ right; }; // FIXME: currently, for pairs of BigInt32, we unbox them, do the "xor" and re-box them. // We could do it directly on the JSValue, and just remember to do an or with 0x12 at the end to restore the tag auto bigIntOp = [] (JSGlobalObject* globalObject, auto left, auto right) { return JSBigInt::bitwiseXor(globalObject, left, right); }; return bitwiseBinaryOp(globalObject, v1, v2, int32Op, bigIntOp, "Invalid mix of BigInt and other type in bitwise 'xor' operation."_s); } ALWAYS_INLINE EncodedJSValue getByValWithIndex(JSGlobalObject* globalObject, JSCell* base, uint32_t index) { if (base->isObject()) { JSObject* object = asObject(base); if (object->canGetIndexQuickly(index)) return JSValue::encode(object->getIndexQuickly(index)); } if (isJSString(base) && asString(base)->canGetIndex(index)) return JSValue::encode(asString(base)->getIndex(globalObject, index)); return JSValue::encode(JSValue(base).get(globalObject, index)); } } // namespace JSC