From 2aa4a82499d4becd2284cdb482213d541b8804dd Mon Sep 17 00:00:00 2001 From: Daniel Baumann Date: Sun, 28 Apr 2024 16:29:10 +0200 Subject: Adding upstream version 86.0.1. Signed-off-by: Daniel Baumann --- js/public/Conversions.h | 590 ++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 590 insertions(+) create mode 100644 js/public/Conversions.h (limited to 'js/public/Conversions.h') diff --git a/js/public/Conversions.h b/js/public/Conversions.h new file mode 100644 index 0000000000..6c0ca7601e --- /dev/null +++ b/js/public/Conversions.h @@ -0,0 +1,590 @@ +/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- + * vim: set ts=8 sts=2 et sw=2 tw=80: + * This Source Code Form is subject to the terms of the Mozilla Public + * License, v. 2.0. If a copy of the MPL was not distributed with this + * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ + +/* ECMAScript conversion operations. */ + +#ifndef js_Conversions_h +#define js_Conversions_h + +#include "mozilla/Casting.h" +#include "mozilla/Compiler.h" +#include "mozilla/FloatingPoint.h" +#include "mozilla/MathAlgorithms.h" +#include "mozilla/WrappingOperations.h" + +#include +#include // size_t +#include // {u,}int{8,16,32,64}_t +#include + +#include "jspubtd.h" +#include "jstypes.h" // JS_PUBLIC_API + +#include "js/RootingAPI.h" +#include "js/Value.h" + +namespace js { + +/* DO NOT CALL THIS. Use JS::ToBoolean. */ +extern JS_PUBLIC_API bool ToBooleanSlow(JS::HandleValue v); + +/* DO NOT CALL THIS. Use JS::ToNumber. */ +extern JS_PUBLIC_API bool ToNumberSlow(JSContext* cx, JS::HandleValue v, + double* dp); + +/* DO NOT CALL THIS. Use JS::ToInt8. */ +extern JS_PUBLIC_API bool ToInt8Slow(JSContext* cx, JS::HandleValue v, + int8_t* out); + +/* DO NOT CALL THIS. Use JS::ToUint8. */ +extern JS_PUBLIC_API bool ToUint8Slow(JSContext* cx, JS::HandleValue v, + uint8_t* out); + +/* DO NOT CALL THIS. Use JS::ToInt16. */ +extern JS_PUBLIC_API bool ToInt16Slow(JSContext* cx, JS::HandleValue v, + int16_t* out); + +/* DO NOT CALL THIS. Use JS::ToInt32. */ +extern JS_PUBLIC_API bool ToInt32Slow(JSContext* cx, JS::HandleValue v, + int32_t* out); + +/* DO NOT CALL THIS. Use JS::ToUint32. */ +extern JS_PUBLIC_API bool ToUint32Slow(JSContext* cx, JS::HandleValue v, + uint32_t* out); + +/* DO NOT CALL THIS. Use JS::ToUint16. */ +extern JS_PUBLIC_API bool ToUint16Slow(JSContext* cx, JS::HandleValue v, + uint16_t* out); + +/* DO NOT CALL THIS. Use JS::ToInt64. */ +extern JS_PUBLIC_API bool ToInt64Slow(JSContext* cx, JS::HandleValue v, + int64_t* out); + +/* DO NOT CALL THIS. Use JS::ToUint64. */ +extern JS_PUBLIC_API bool ToUint64Slow(JSContext* cx, JS::HandleValue v, + uint64_t* out); + +/* DO NOT CALL THIS. Use JS::ToString. */ +extern JS_PUBLIC_API JSString* ToStringSlow(JSContext* cx, JS::HandleValue v); + +/* DO NOT CALL THIS. Use JS::ToObject. */ +extern JS_PUBLIC_API JSObject* ToObjectSlow(JSContext* cx, JS::HandleValue v, + bool reportScanStack); + +} // namespace js + +namespace JS { + +namespace detail { + +#ifdef JS_DEBUG +/** + * Assert that we're not doing GC on cx, that we're in a request as + * needed, and that the compartments for cx and v are correct. + * Also check that GC would be safe at this point. + */ +extern JS_PUBLIC_API void AssertArgumentsAreSane(JSContext* cx, HandleValue v); +#else +inline void AssertArgumentsAreSane(JSContext* cx, HandleValue v) {} +#endif /* JS_DEBUG */ + +} // namespace detail + +/** + * ES6 draft 20141224, 7.1.1, second algorithm. + * + * Most users shouldn't call this -- use JS::ToBoolean, ToNumber, or ToString + * instead. This will typically only be called from custom convert hooks that + * wish to fall back to the ES6 default conversion behavior shared by most + * objects in JS, codified as OrdinaryToPrimitive. + */ +extern JS_PUBLIC_API bool OrdinaryToPrimitive(JSContext* cx, HandleObject obj, + JSType type, + MutableHandleValue vp); + +/* ES6 draft 20141224, 7.1.2. */ +MOZ_ALWAYS_INLINE bool ToBoolean(HandleValue v) { + if (v.isBoolean()) { + return v.toBoolean(); + } + if (v.isInt32()) { + return v.toInt32() != 0; + } + if (v.isNullOrUndefined()) { + return false; + } + if (v.isDouble()) { + double d = v.toDouble(); + return !mozilla::IsNaN(d) && d != 0; + } + if (v.isSymbol()) { + return true; + } + + /* The slow path handles strings, BigInts and objects. */ + return js::ToBooleanSlow(v); +} + +/* ES6 draft 20141224, 7.1.3. */ +MOZ_ALWAYS_INLINE bool ToNumber(JSContext* cx, HandleValue v, double* out) { + detail::AssertArgumentsAreSane(cx, v); + + if (v.isNumber()) { + *out = v.toNumber(); + return true; + } + return js::ToNumberSlow(cx, v, out); +} + +// ES2020 draft rev 6b05bc56ba4e3c7a2b9922c4282d9eb844426d9b +// 7.1.5 ToInteger ( argument ) +// +// Specialized for double values. +inline double ToInteger(double d) { + if (d == 0) { + return 0; + } + + if (!mozilla::IsFinite(d)) { + if (mozilla::IsNaN(d)) { + return 0; + } + return d; + } + + return std::trunc(d) + (+0.0); // Add zero to convert -0 to +0. +} + +/* ES6 draft 20141224, 7.1.5. */ +MOZ_ALWAYS_INLINE bool ToInt32(JSContext* cx, JS::HandleValue v, int32_t* out) { + detail::AssertArgumentsAreSane(cx, v); + + if (v.isInt32()) { + *out = v.toInt32(); + return true; + } + return js::ToInt32Slow(cx, v, out); +} + +/* ES6 draft 20141224, 7.1.6. */ +MOZ_ALWAYS_INLINE bool ToUint32(JSContext* cx, HandleValue v, uint32_t* out) { + detail::AssertArgumentsAreSane(cx, v); + + if (v.isInt32()) { + *out = uint32_t(v.toInt32()); + return true; + } + return js::ToUint32Slow(cx, v, out); +} + +/* ES6 draft 20141224, 7.1.7. */ +MOZ_ALWAYS_INLINE bool ToInt16(JSContext* cx, JS::HandleValue v, int16_t* out) { + detail::AssertArgumentsAreSane(cx, v); + + if (v.isInt32()) { + *out = int16_t(v.toInt32()); + return true; + } + return js::ToInt16Slow(cx, v, out); +} + +/* ES6 draft 20141224, 7.1.8. */ +MOZ_ALWAYS_INLINE bool ToUint16(JSContext* cx, HandleValue v, uint16_t* out) { + detail::AssertArgumentsAreSane(cx, v); + + if (v.isInt32()) { + *out = uint16_t(v.toInt32()); + return true; + } + return js::ToUint16Slow(cx, v, out); +} + +/* ES6 draft 20141224, 7.1.9 */ +MOZ_ALWAYS_INLINE bool ToInt8(JSContext* cx, JS::HandleValue v, int8_t* out) { + detail::AssertArgumentsAreSane(cx, v); + + if (v.isInt32()) { + *out = int8_t(v.toInt32()); + return true; + } + return js::ToInt8Slow(cx, v, out); +} + +/* ES6 ECMA-262, 7.1.10 */ +MOZ_ALWAYS_INLINE bool ToUint8(JSContext* cx, JS::HandleValue v, uint8_t* out) { + detail::AssertArgumentsAreSane(cx, v); + + if (v.isInt32()) { + *out = uint8_t(v.toInt32()); + return true; + } + return js::ToUint8Slow(cx, v, out); +} + +/* + * Non-standard, with behavior similar to that of ToInt32, except in its + * producing an int64_t. + */ +MOZ_ALWAYS_INLINE bool ToInt64(JSContext* cx, HandleValue v, int64_t* out) { + detail::AssertArgumentsAreSane(cx, v); + + if (v.isInt32()) { + *out = int64_t(v.toInt32()); + return true; + } + return js::ToInt64Slow(cx, v, out); +} + +/* + * Non-standard, with behavior similar to that of ToUint32, except in its + * producing a uint64_t. + */ +MOZ_ALWAYS_INLINE bool ToUint64(JSContext* cx, HandleValue v, uint64_t* out) { + detail::AssertArgumentsAreSane(cx, v); + + if (v.isInt32()) { + *out = uint64_t(v.toInt32()); + return true; + } + return js::ToUint64Slow(cx, v, out); +} + +/* ES6 draft 20141224, 7.1.12. */ +MOZ_ALWAYS_INLINE JSString* ToString(JSContext* cx, HandleValue v) { + detail::AssertArgumentsAreSane(cx, v); + + if (v.isString()) { + return v.toString(); + } + return js::ToStringSlow(cx, v); +} + +/* ES6 draft 20141224, 7.1.13. */ +inline JSObject* ToObject(JSContext* cx, HandleValue v) { + detail::AssertArgumentsAreSane(cx, v); + + if (v.isObject()) { + return &v.toObject(); + } + return js::ToObjectSlow(cx, v, false); +} + +/** + * Convert a double value to UnsignedInteger (an unsigned integral type) using + * ECMAScript-style semantics (that is, in like manner to how ECMAScript's + * ToInt32 converts to int32_t). + * + * If d is infinite or NaN, return 0. + * Otherwise compute d2 = sign(d) * floor(abs(d)), and return the + * UnsignedInteger value congruent to d2 % 2**(bit width of UnsignedInteger). + * + * The algorithm below is inspired by that found in + * + * but has been generalized to all integer widths. + */ +template +inline UnsignedInteger ToUnsignedInteger(double d) { + static_assert(std::is_unsigned_v, + "UnsignedInteger must be an unsigned type"); + + uint64_t bits = mozilla::BitwiseCast(d); + unsigned DoubleExponentShift = mozilla::FloatingPoint::kExponentShift; + + // Extract the exponent component. (Be careful here! It's not technically + // the exponent in NaN, infinities, and subnormals.) + int_fast16_t exp = + int_fast16_t((bits & mozilla::FloatingPoint::kExponentBits) >> + DoubleExponentShift) - + int_fast16_t(mozilla::FloatingPoint::kExponentBias); + + // If the exponent's less than zero, abs(d) < 1, so the result is 0. (This + // also handles subnormals.) + if (exp < 0) { + return 0; + } + + uint_fast16_t exponent = mozilla::AssertedCast(exp); + + // If the exponent is greater than or equal to the bits of precision of a + // double plus UnsignedInteger's width, the number is either infinite, NaN, + // or too large to have lower-order bits in the congruent value. (Example: + // 2**84 is exactly representable as a double. The next exact double is + // 2**84 + 2**32. Thus if UnsignedInteger is uint32_t, an exponent >= 84 + // implies floor(abs(d)) == 0 mod 2**32.) Return 0 in all these cases. + constexpr size_t ResultWidth = CHAR_BIT * sizeof(UnsignedInteger); + if (exponent >= DoubleExponentShift + ResultWidth) { + return 0; + } + + // The significand contains the bits that will determine the final result. + // Shift those bits left or right, according to the exponent, to their + // locations in the unsigned binary representation of floor(abs(d)). + static_assert(sizeof(UnsignedInteger) <= sizeof(uint64_t), + "left-shifting below would lose upper bits"); + UnsignedInteger result = + (exponent > DoubleExponentShift) + ? UnsignedInteger(bits << (exponent - DoubleExponentShift)) + : UnsignedInteger(bits >> (DoubleExponentShift - exponent)); + + // Two further complications remain. First, |result| may contain bogus + // sign/exponent bits. Second, IEEE-754 numbers' significands (excluding + // subnormals, but we already handled those) have an implicit leading 1 + // which may affect the final result. + // + // It may appear that there's complexity here depending on how ResultWidth + // and DoubleExponentShift relate, but it turns out there's not. + // + // Assume ResultWidth < DoubleExponentShift: + // Only right-shifts leave bogus bits in |result|. For this to happen, + // we must right-shift by > |DoubleExponentShift - ResultWidth|, implying + // |exponent < ResultWidth|. + // The implicit leading bit only matters if it appears in the final + // result -- if |2**exponent mod 2**ResultWidth != 0|. This implies + // |exponent < ResultWidth|. + // Otherwise assume ResultWidth >= DoubleExponentShift: + // Any left-shift less than |ResultWidth - DoubleExponentShift| leaves + // bogus bits in |result|. This implies |exponent < ResultWidth|. Any + // right-shift less than |ResultWidth| does too, which implies + // |DoubleExponentShift - ResultWidth < exponent|. By assumption, then, + // |exponent| is negative, but we excluded that above. So bogus bits + // need only |exponent < ResultWidth|. + // The implicit leading bit matters identically to the other case, so + // again, |exponent < ResultWidth|. + if (exponent < ResultWidth) { + const auto implicitOne = + static_cast(UnsignedInteger{1} << exponent); + result &= implicitOne - 1; // remove bogus bits + result += implicitOne; // add the implicit bit + } + + // Compute the congruent value in the signed range. + return (bits & mozilla::FloatingPoint::kSignBit) ? ~result + 1 + : result; +} + +template +inline SignedInteger ToSignedInteger(double d) { + static_assert(std::is_signed_v, + "SignedInteger must be a signed type"); + + using UnsignedInteger = std::make_unsigned_t; + UnsignedInteger u = ToUnsignedInteger(d); + + return mozilla::WrapToSigned(u); +} + +// clang crashes compiling this when targeting arm: +// https://llvm.org/bugs/show_bug.cgi?id=22974 +#if defined(__arm__) && MOZ_IS_GCC + +template <> +inline int32_t ToSignedInteger(double d) { + int32_t i; + uint32_t tmp0; + uint32_t tmp1; + uint32_t tmp2; + asm( + // We use a pure integer solution here. In the 'softfp' ABI, the argument + // will start in r0 and r1, and VFP can't do all of the necessary ECMA + // conversions by itself so some integer code will be required anyway. A + // hybrid solution is faster on A9, but this pure integer solution is + // notably faster for A8. + + // %0 is the result register, and may alias either of the %[QR]1 + // registers. + // %Q4 holds the lower part of the mantissa. + // %R4 holds the sign, exponent, and the upper part of the mantissa. + // %1, %2 and %3 are used as temporary values. + + // Extract the exponent. + " mov %1, %R4, LSR #20\n" + " bic %1, %1, #(1 << 11)\n" // Clear the sign. + + // Set the implicit top bit of the mantissa. This clobbers a bit of the + // exponent, but we have already extracted that. + " orr %R4, %R4, #(1 << 20)\n" + + // Special Cases + // We should return zero in the following special cases: + // - Exponent is 0x000 - 1023: +/-0 or subnormal. + // - Exponent is 0x7ff - 1023: +/-INFINITY or NaN + // - This case is implicitly handled by the standard code path + // anyway, as shifting the mantissa up by the exponent will + // result in '0'. + // + // The result is composed of the mantissa, prepended with '1' and + // bit-shifted left by the (decoded) exponent. Note that because the + // r1[20] is the bit with value '1', r1 is effectively already shifted + // (left) by 20 bits, and r0 is already shifted by 52 bits. + + // Adjust the exponent to remove the encoding offset. If the decoded + // exponent is negative, quickly bail out with '0' as such values round to + // zero anyway. This also catches +/-0 and subnormals. + " sub %1, %1, #0xff\n" + " subs %1, %1, #0x300\n" + " bmi 8f\n" + + // %1 = (decoded) exponent >= 0 + // %R4 = upper mantissa and sign + + // ---- Lower Mantissa ---- + " subs %3, %1, #52\n" // Calculate exp-52 + " bmi 1f\n" + + // Shift r0 left by exp-52. + // Ensure that we don't overflow ARM's 8-bit shift operand range. + // We need to handle anything up to an 11-bit value here as we know that + // 52 <= exp <= 1024 (0x400). Any shift beyond 31 bits results in zero + // anyway, so as long as we don't touch the bottom 5 bits, we can use + // a logical OR to push long shifts into the 32 <= (exp&0xff) <= 255 + // range. + " bic %2, %3, #0xff\n" + " orr %3, %3, %2, LSR #3\n" + // We can now perform a straight shift, avoiding the need for any + // conditional instructions or extra branches. + " mov %Q4, %Q4, LSL %3\n" + " b 2f\n" + "1:\n" // Shift r0 right by 52-exp. + // We know that 0 <= exp < 52, and we can shift up to 255 bits so + // 52-exp will always be a valid shift and we can sk%3 the range + // check for this case. + " rsb %3, %1, #52\n" + " mov %Q4, %Q4, LSR %3\n" + + // %1 = (decoded) exponent + // %R4 = upper mantissa and sign + // %Q4 = partially-converted integer + + "2:\n" + // ---- Upper Mantissa ---- + // This is much the same as the lower mantissa, with a few different + // boundary checks and some masking to hide the exponent & sign bit in the + // upper word. + // Note that the upper mantissa is pre-shifted by 20 in %R4, but we shift + // it left more to remove the sign and exponent so it is effectively + // pre-shifted by 31 bits. + " subs %3, %1, #31\n" // Calculate exp-31 + " mov %1, %R4, LSL #11\n" // Re-use %1 as a temporary register. + " bmi 3f\n" + + // Shift %R4 left by exp-31. + // Avoid overflowing the 8-bit shift range, as before. + " bic %2, %3, #0xff\n" + " orr %3, %3, %2, LSR #3\n" + // Perform the shift. + " mov %2, %1, LSL %3\n" + " b 4f\n" + "3:\n" // Shift r1 right by 31-exp. + // We know that 0 <= exp < 31, and we can shift up to 255 bits so + // 31-exp will always be a valid shift and we can skip the range + // check for this case. + " rsb %3, %3, #0\n" // Calculate 31-exp from -(exp-31) + " mov %2, %1, LSR %3\n" // Thumb-2 can't do "LSR %3" in "orr". + + // %Q4 = partially-converted integer (lower) + // %R4 = upper mantissa and sign + // %2 = partially-converted integer (upper) + + "4:\n" + // Combine the converted parts. + " orr %Q4, %Q4, %2\n" + // Negate the result if we have to, and move it to %0 in the process. To + // avoid conditionals, we can do this by inverting on %R4[31], then adding + // %R4[31]>>31. + " eor %Q4, %Q4, %R4, ASR #31\n" + " add %0, %Q4, %R4, LSR #31\n" + " b 9f\n" + "8:\n" + // +/-INFINITY, +/-0, subnormals, NaNs, and anything else out-of-range + // that will result in a conversion of '0'. + " mov %0, #0\n" + "9:\n" + : "=r"(i), "=&r"(tmp0), "=&r"(tmp1), "=&r"(tmp2), "=&r"(d) + : "4"(d) + : "cc"); + return i; +} + +#endif // defined (__arm__) && MOZ_IS_GCC + +namespace detail { + +template > +struct ToSignedOrUnsignedInteger; + +template +struct ToSignedOrUnsignedInteger { + static IntegerType compute(double d) { + return ToUnsignedInteger(d); + } +}; + +template +struct ToSignedOrUnsignedInteger { + static IntegerType compute(double d) { + return ToSignedInteger(d); + } +}; + +} // namespace detail + +template +inline IntegerType ToSignedOrUnsignedInteger(double d) { + return detail::ToSignedOrUnsignedInteger::compute(d); +} + +/* WEBIDL 4.2.4 */ +inline int8_t ToInt8(double d) { return ToSignedInteger(d); } + +/* ECMA-262 7.1.10 ToUInt8() specialized for doubles. */ +inline int8_t ToUint8(double d) { return ToUnsignedInteger(d); } + +/* WEBIDL 4.2.6 */ +inline int16_t ToInt16(double d) { return ToSignedInteger(d); } + +inline uint16_t ToUint16(double d) { return ToUnsignedInteger(d); } + +/* ES5 9.5 ToInt32 (specialized for doubles). */ +inline int32_t ToInt32(double d) { return ToSignedInteger(d); } + +/* ES5 9.6 (specialized for doubles). */ +inline uint32_t ToUint32(double d) { return ToUnsignedInteger(d); } + +/* WEBIDL 4.2.10 */ +inline int64_t ToInt64(double d) { return ToSignedInteger(d); } + +/* WEBIDL 4.2.11 */ +inline uint64_t ToUint64(double d) { return ToUnsignedInteger(d); } + +/** + * An amount of space large enough to store the null-terminated result of + * |ToString| on any Number. + * + * The + * |NumberToString| algorithm is specified in terms of results, not an + * algorithm. It is extremely unclear from the algorithm's definition what its + * longest output can be. |-(2**-19 - 2**-72)| requires 25 + 1 characters and + * is believed to be at least *very close* to the upper bound, so we round that + * *very generously* upward to a 64-bit pointer-size boundary (to be extra + * cautious) and assume that's adequate. + * + * If you can supply better reasoning for a tighter bound, file a bug to improve + * this! + */ +static constexpr size_t MaximumNumberToStringLength = 31 + 1; + +/** + * Store in |out| the null-terminated, base-10 result of |ToString| applied to + * |d| per . + * (This will produce "NaN", "-Infinity", or "Infinity" for non-finite |d|.) + */ +extern JS_PUBLIC_API void NumberToString( + double d, char (&out)[MaximumNumberToStringLength]); + +} // namespace JS + +#endif /* js_Conversions_h */ -- cgit v1.2.3