v8/src/wasm/wasm-interpreter.cc

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// Copyright 2016 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include <atomic>
#include <type_traits>
#include "src/wasm/wasm-interpreter.h"
#include "src/base/overflowing-math.h"
#include "src/codegen/assembler-inl.h"
#include "src/compiler/wasm-compiler.h"
#include "src/numbers/conversions.h"
#include "src/objects/objects-inl.h"
#include "src/utils/boxed-float.h"
#include "src/utils/identity-map.h"
#include "src/utils/utils.h"
#include "src/wasm/decoder.h"
#include "src/wasm/function-body-decoder-impl.h"
#include "src/wasm/function-body-decoder.h"
#include "src/wasm/memory-tracing.h"
#include "src/wasm/module-compiler.h"
#include "src/wasm/wasm-arguments.h"
#include "src/wasm/wasm-engine.h"
#include "src/wasm/wasm-external-refs.h"
#include "src/wasm/wasm-limits.h"
#include "src/wasm/wasm-module.h"
#include "src/wasm/wasm-objects-inl.h"
#include "src/wasm/wasm-opcodes.h"
#include "src/zone/accounting-allocator.h"
#include "src/zone/zone-containers.h"
namespace v8 {
namespace internal {
namespace wasm {
using base::ReadLittleEndianValue;
using base::ReadUnalignedValue;
using base::WriteLittleEndianValue;
using base::WriteUnalignedValue;
#define TRACE(...) \
do { \
if (FLAG_trace_wasm_interpreter) PrintF(__VA_ARGS__); \
} while (false)
#if V8_TARGET_BIG_ENDIAN
#define LANE(i, type) ((sizeof(type.val) / sizeof(type.val[0])) - (i)-1)
#else
#define LANE(i, type) (i)
#endif
#define FOREACH_SIMPLE_BINOP(V) \
V(I32Add, uint32_t, +) \
V(I32Sub, uint32_t, -) \
V(I32Mul, uint32_t, *) \
V(I32And, uint32_t, &) \
V(I32Ior, uint32_t, |) \
V(I32Xor, uint32_t, ^) \
V(I32Eq, uint32_t, ==) \
V(I32Ne, uint32_t, !=) \
V(I32LtU, uint32_t, <) \
V(I32LeU, uint32_t, <=) \
V(I32GtU, uint32_t, >) \
V(I32GeU, uint32_t, >=) \
V(I32LtS, int32_t, <) \
V(I32LeS, int32_t, <=) \
V(I32GtS, int32_t, >) \
V(I32GeS, int32_t, >=) \
V(I64Add, uint64_t, +) \
V(I64Sub, uint64_t, -) \
V(I64Mul, uint64_t, *) \
V(I64And, uint64_t, &) \
V(I64Ior, uint64_t, |) \
V(I64Xor, uint64_t, ^) \
V(I64Eq, uint64_t, ==) \
V(I64Ne, uint64_t, !=) \
V(I64LtU, uint64_t, <) \
V(I64LeU, uint64_t, <=) \
V(I64GtU, uint64_t, >) \
V(I64GeU, uint64_t, >=) \
V(I64LtS, int64_t, <) \
V(I64LeS, int64_t, <=) \
V(I64GtS, int64_t, >) \
V(I64GeS, int64_t, >=) \
V(F32Add, float, +) \
V(F32Sub, float, -) \
V(F32Eq, float, ==) \
V(F32Ne, float, !=) \
V(F32Lt, float, <) \
V(F32Le, float, <=) \
V(F32Gt, float, >) \
V(F32Ge, float, >=) \
V(F64Add, double, +) \
V(F64Sub, double, -) \
V(F64Eq, double, ==) \
V(F64Ne, double, !=) \
V(F64Lt, double, <) \
V(F64Le, double, <=) \
V(F64Gt, double, >) \
V(F64Ge, double, >=) \
V(F32Mul, float, *) \
V(F64Mul, double, *) \
V(F32Div, float, /) \
V(F64Div, double, /)
#define FOREACH_OTHER_BINOP(V) \
V(I32DivS, int32_t) \
V(I32DivU, uint32_t) \
V(I32RemS, int32_t) \
V(I32RemU, uint32_t) \
V(I32Shl, uint32_t) \
V(I32ShrU, uint32_t) \
V(I32ShrS, int32_t) \
V(I64DivS, int64_t) \
V(I64DivU, uint64_t) \
V(I64RemS, int64_t) \
V(I64RemU, uint64_t) \
V(I64Shl, uint64_t) \
V(I64ShrU, uint64_t) \
V(I64ShrS, int64_t) \
V(I32Ror, int32_t) \
V(I32Rol, int32_t) \
V(I64Ror, int64_t) \
V(I64Rol, int64_t) \
V(F32Min, float) \
V(F32Max, float) \
V(F64Min, double) \
V(F64Max, double) \
V(I32AsmjsDivS, int32_t) \
V(I32AsmjsDivU, uint32_t) \
V(I32AsmjsRemS, int32_t) \
V(I32AsmjsRemU, uint32_t) \
V(F32CopySign, Float32) \
V(F64CopySign, Float64)
#define FOREACH_I32CONV_FLOATOP(V) \
V(I32SConvertF32, int32_t, float) \
V(I32SConvertF64, int32_t, double) \
V(I32UConvertF32, uint32_t, float) \
V(I32UConvertF64, uint32_t, double)
#define FOREACH_OTHER_UNOP(V) \
V(I32Clz, uint32_t) \
V(I32Ctz, uint32_t) \
V(I32Popcnt, uint32_t) \
V(I32Eqz, uint32_t) \
V(I64Clz, uint64_t) \
V(I64Ctz, uint64_t) \
V(I64Popcnt, uint64_t) \
V(I64Eqz, uint64_t) \
V(F32Abs, Float32) \
V(F32Neg, Float32) \
V(F32Ceil, float) \
V(F32Floor, float) \
V(F32Trunc, float) \
V(F32NearestInt, float) \
V(F64Abs, Float64) \
V(F64Neg, Float64) \
V(F64Ceil, double) \
V(F64Floor, double) \
V(F64Trunc, double) \
V(F64NearestInt, double) \
V(I32ConvertI64, int64_t) \
V(I64SConvertF32, float) \
V(I64SConvertF64, double) \
V(I64UConvertF32, float) \
V(I64UConvertF64, double) \
V(I64SConvertI32, int32_t) \
V(I64UConvertI32, uint32_t) \
V(F32SConvertI32, int32_t) \
V(F32UConvertI32, uint32_t) \
V(F32SConvertI64, int64_t) \
V(F32UConvertI64, uint64_t) \
V(F32ConvertF64, double) \
V(F32ReinterpretI32, int32_t) \
V(F64SConvertI32, int32_t) \
V(F64UConvertI32, uint32_t) \
V(F64SConvertI64, int64_t) \
V(F64UConvertI64, uint64_t) \
V(F64ConvertF32, float) \
V(F64ReinterpretI64, int64_t) \
V(I32AsmjsSConvertF32, float) \
V(I32AsmjsUConvertF32, float) \
V(I32AsmjsSConvertF64, double) \
V(I32AsmjsUConvertF64, double) \
V(F32Sqrt, float) \
V(F64Sqrt, double)
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namespace {
constexpr uint32_t kFloat32SignBitMask = uint32_t{1} << 31;
constexpr uint64_t kFloat64SignBitMask = uint64_t{1} << 63;
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inline int32_t ExecuteI32DivS(int32_t a, int32_t b, TrapReason* trap) {
if (b == 0) {
*trap = kTrapDivByZero;
return 0;
}
if (b == -1 && a == std::numeric_limits<int32_t>::min()) {
*trap = kTrapDivUnrepresentable;
return 0;
}
return a / b;
}
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inline uint32_t ExecuteI32DivU(uint32_t a, uint32_t b, TrapReason* trap) {
if (b == 0) {
*trap = kTrapDivByZero;
return 0;
}
return a / b;
}
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inline int32_t ExecuteI32RemS(int32_t a, int32_t b, TrapReason* trap) {
if (b == 0) {
*trap = kTrapRemByZero;
return 0;
}
if (b == -1) return 0;
return a % b;
}
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inline uint32_t ExecuteI32RemU(uint32_t a, uint32_t b, TrapReason* trap) {
if (b == 0) {
*trap = kTrapRemByZero;
return 0;
}
return a % b;
}
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inline uint32_t ExecuteI32Shl(uint32_t a, uint32_t b, TrapReason* trap) {
return a << (b & 0x1F);
}
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inline uint32_t ExecuteI32ShrU(uint32_t a, uint32_t b, TrapReason* trap) {
return a >> (b & 0x1F);
}
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inline int32_t ExecuteI32ShrS(int32_t a, int32_t b, TrapReason* trap) {
return a >> (b & 0x1F);
}
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inline int64_t ExecuteI64DivS(int64_t a, int64_t b, TrapReason* trap) {
if (b == 0) {
*trap = kTrapDivByZero;
return 0;
}
if (b == -1 && a == std::numeric_limits<int64_t>::min()) {
*trap = kTrapDivUnrepresentable;
return 0;
}
return a / b;
}
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inline uint64_t ExecuteI64DivU(uint64_t a, uint64_t b, TrapReason* trap) {
if (b == 0) {
*trap = kTrapDivByZero;
return 0;
}
return a / b;
}
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inline int64_t ExecuteI64RemS(int64_t a, int64_t b, TrapReason* trap) {
if (b == 0) {
*trap = kTrapRemByZero;
return 0;
}
if (b == -1) return 0;
return a % b;
}
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inline uint64_t ExecuteI64RemU(uint64_t a, uint64_t b, TrapReason* trap) {
if (b == 0) {
*trap = kTrapRemByZero;
return 0;
}
return a % b;
}
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inline uint64_t ExecuteI64Shl(uint64_t a, uint64_t b, TrapReason* trap) {
return a << (b & 0x3F);
}
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inline uint64_t ExecuteI64ShrU(uint64_t a, uint64_t b, TrapReason* trap) {
return a >> (b & 0x3F);
}
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inline int64_t ExecuteI64ShrS(int64_t a, int64_t b, TrapReason* trap) {
return a >> (b & 0x3F);
}
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inline uint32_t ExecuteI32Ror(uint32_t a, uint32_t b, TrapReason* trap) {
return (a >> (b & 0x1F)) | (a << ((32 - b) & 0x1F));
}
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inline uint32_t ExecuteI32Rol(uint32_t a, uint32_t b, TrapReason* trap) {
return (a << (b & 0x1F)) | (a >> ((32 - b) & 0x1F));
}
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inline uint64_t ExecuteI64Ror(uint64_t a, uint64_t b, TrapReason* trap) {
return (a >> (b & 0x3F)) | (a << ((64 - b) & 0x3F));
}
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inline uint64_t ExecuteI64Rol(uint64_t a, uint64_t b, TrapReason* trap) {
return (a << (b & 0x3F)) | (a >> ((64 - b) & 0x3F));
}
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inline float ExecuteF32Min(float a, float b, TrapReason* trap) {
return JSMin(a, b);
}
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inline float ExecuteF32Max(float a, float b, TrapReason* trap) {
return JSMax(a, b);
}
inline Float32 ExecuteF32CopySign(Float32 a, Float32 b, TrapReason* trap) {
return Float32::FromBits((a.get_bits() & ~kFloat32SignBitMask) |
(b.get_bits() & kFloat32SignBitMask));
}
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inline double ExecuteF64Min(double a, double b, TrapReason* trap) {
return JSMin(a, b);
}
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inline double ExecuteF64Max(double a, double b, TrapReason* trap) {
return JSMax(a, b);
}
inline Float64 ExecuteF64CopySign(Float64 a, Float64 b, TrapReason* trap) {
return Float64::FromBits((a.get_bits() & ~kFloat64SignBitMask) |
(b.get_bits() & kFloat64SignBitMask));
}
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inline int32_t ExecuteI32AsmjsDivS(int32_t a, int32_t b, TrapReason* trap) {
if (b == 0) return 0;
if (b == -1 && a == std::numeric_limits<int32_t>::min()) {
return std::numeric_limits<int32_t>::min();
}
return a / b;
}
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inline uint32_t ExecuteI32AsmjsDivU(uint32_t a, uint32_t b, TrapReason* trap) {
if (b == 0) return 0;
return a / b;
}
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inline int32_t ExecuteI32AsmjsRemS(int32_t a, int32_t b, TrapReason* trap) {
if (b == 0) return 0;
if (b == -1) return 0;
return a % b;
}
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inline uint32_t ExecuteI32AsmjsRemU(uint32_t a, uint32_t b, TrapReason* trap) {
if (b == 0) return 0;
return a % b;
}
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inline int32_t ExecuteI32AsmjsSConvertF32(float a, TrapReason* trap) {
return DoubleToInt32(a);
}
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inline uint32_t ExecuteI32AsmjsUConvertF32(float a, TrapReason* trap) {
return DoubleToUint32(a);
}
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inline int32_t ExecuteI32AsmjsSConvertF64(double a, TrapReason* trap) {
return DoubleToInt32(a);
}
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inline uint32_t ExecuteI32AsmjsUConvertF64(double a, TrapReason* trap) {
return DoubleToUint32(a);
}
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int32_t ExecuteI32Clz(uint32_t val, TrapReason* trap) {
Reland "[bits] Consolidate Count{Leading,Trailing}Zeros" This is a reland of 7d231e576a6ffd651041094ba10bc5b39777528c, fixed to avoid instantiating CountLeadingZeros for bits==0. Original change's description: > [bits] Consolidate Count{Leading,Trailing}Zeros > > Instead of having one method for 32 bit integers and one for 64 bit, > plus a templatized version to choose from those two, just implement one > version which handles unsigned integers of any size. Also, make them > constexpr. > The Count{Leading,Trailing}Zeros{32,64} methods are kept for now in > order to keep the amount of code changes small. Also, sometimes it > improves readability by stating exactly the size of the argument, > especially for leading zeros (where zero-extending would add more > leading zeros). > > CountLeadingZeros now uses a binary search inspired implementation > as proposed in Hacker's Delight. It's more than 20% faster on x64 if > the builtins are disabled. > CountTrailingZeros falls back to CountPopulation instead of counting in > a naive loop. This is ~50% faster. > > R=mstarzinger@chromium.org > > Change-Id: I1d8bf1d7295b930724163248150444bd17fbb34e > Reviewed-on: https://chromium-review.googlesource.com/741231 > Reviewed-by: Michael Starzinger <mstarzinger@chromium.org> > Commit-Queue: Clemens Hammacher <clemensh@chromium.org> > Cr-Commit-Position: refs/heads/master@{#49106} Change-Id: Icdff2510ec66d1c96a1912cef29d77d8550994ee Reviewed-on: https://chromium-review.googlesource.com/753903 Reviewed-by: Michael Starzinger <mstarzinger@chromium.org> Commit-Queue: Clemens Hammacher <clemensh@chromium.org> Cr-Commit-Position: refs/heads/master@{#49138}
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return base::bits::CountLeadingZeros(val);
}
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uint32_t ExecuteI32Ctz(uint32_t val, TrapReason* trap) {
Reland "[bits] Consolidate Count{Leading,Trailing}Zeros" This is a reland of 7d231e576a6ffd651041094ba10bc5b39777528c, fixed to avoid instantiating CountLeadingZeros for bits==0. Original change's description: > [bits] Consolidate Count{Leading,Trailing}Zeros > > Instead of having one method for 32 bit integers and one for 64 bit, > plus a templatized version to choose from those two, just implement one > version which handles unsigned integers of any size. Also, make them > constexpr. > The Count{Leading,Trailing}Zeros{32,64} methods are kept for now in > order to keep the amount of code changes small. Also, sometimes it > improves readability by stating exactly the size of the argument, > especially for leading zeros (where zero-extending would add more > leading zeros). > > CountLeadingZeros now uses a binary search inspired implementation > as proposed in Hacker's Delight. It's more than 20% faster on x64 if > the builtins are disabled. > CountTrailingZeros falls back to CountPopulation instead of counting in > a naive loop. This is ~50% faster. > > R=mstarzinger@chromium.org > > Change-Id: I1d8bf1d7295b930724163248150444bd17fbb34e > Reviewed-on: https://chromium-review.googlesource.com/741231 > Reviewed-by: Michael Starzinger <mstarzinger@chromium.org> > Commit-Queue: Clemens Hammacher <clemensh@chromium.org> > Cr-Commit-Position: refs/heads/master@{#49106} Change-Id: Icdff2510ec66d1c96a1912cef29d77d8550994ee Reviewed-on: https://chromium-review.googlesource.com/753903 Reviewed-by: Michael Starzinger <mstarzinger@chromium.org> Commit-Queue: Clemens Hammacher <clemensh@chromium.org> Cr-Commit-Position: refs/heads/master@{#49138}
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return base::bits::CountTrailingZeros(val);
}
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uint32_t ExecuteI32Popcnt(uint32_t val, TrapReason* trap) {
return base::bits::CountPopulation(val);
}
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inline uint32_t ExecuteI32Eqz(uint32_t val, TrapReason* trap) {
return val == 0 ? 1 : 0;
}
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int64_t ExecuteI64Clz(uint64_t val, TrapReason* trap) {
Reland "[bits] Consolidate Count{Leading,Trailing}Zeros" This is a reland of 7d231e576a6ffd651041094ba10bc5b39777528c, fixed to avoid instantiating CountLeadingZeros for bits==0. Original change's description: > [bits] Consolidate Count{Leading,Trailing}Zeros > > Instead of having one method for 32 bit integers and one for 64 bit, > plus a templatized version to choose from those two, just implement one > version which handles unsigned integers of any size. Also, make them > constexpr. > The Count{Leading,Trailing}Zeros{32,64} methods are kept for now in > order to keep the amount of code changes small. Also, sometimes it > improves readability by stating exactly the size of the argument, > especially for leading zeros (where zero-extending would add more > leading zeros). > > CountLeadingZeros now uses a binary search inspired implementation > as proposed in Hacker's Delight. It's more than 20% faster on x64 if > the builtins are disabled. > CountTrailingZeros falls back to CountPopulation instead of counting in > a naive loop. This is ~50% faster. > > R=mstarzinger@chromium.org > > Change-Id: I1d8bf1d7295b930724163248150444bd17fbb34e > Reviewed-on: https://chromium-review.googlesource.com/741231 > Reviewed-by: Michael Starzinger <mstarzinger@chromium.org> > Commit-Queue: Clemens Hammacher <clemensh@chromium.org> > Cr-Commit-Position: refs/heads/master@{#49106} Change-Id: Icdff2510ec66d1c96a1912cef29d77d8550994ee Reviewed-on: https://chromium-review.googlesource.com/753903 Reviewed-by: Michael Starzinger <mstarzinger@chromium.org> Commit-Queue: Clemens Hammacher <clemensh@chromium.org> Cr-Commit-Position: refs/heads/master@{#49138}
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return base::bits::CountLeadingZeros(val);
}
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inline uint64_t ExecuteI64Ctz(uint64_t val, TrapReason* trap) {
Reland "[bits] Consolidate Count{Leading,Trailing}Zeros" This is a reland of 7d231e576a6ffd651041094ba10bc5b39777528c, fixed to avoid instantiating CountLeadingZeros for bits==0. Original change's description: > [bits] Consolidate Count{Leading,Trailing}Zeros > > Instead of having one method for 32 bit integers and one for 64 bit, > plus a templatized version to choose from those two, just implement one > version which handles unsigned integers of any size. Also, make them > constexpr. > The Count{Leading,Trailing}Zeros{32,64} methods are kept for now in > order to keep the amount of code changes small. Also, sometimes it > improves readability by stating exactly the size of the argument, > especially for leading zeros (where zero-extending would add more > leading zeros). > > CountLeadingZeros now uses a binary search inspired implementation > as proposed in Hacker's Delight. It's more than 20% faster on x64 if > the builtins are disabled. > CountTrailingZeros falls back to CountPopulation instead of counting in > a naive loop. This is ~50% faster. > > R=mstarzinger@chromium.org > > Change-Id: I1d8bf1d7295b930724163248150444bd17fbb34e > Reviewed-on: https://chromium-review.googlesource.com/741231 > Reviewed-by: Michael Starzinger <mstarzinger@chromium.org> > Commit-Queue: Clemens Hammacher <clemensh@chromium.org> > Cr-Commit-Position: refs/heads/master@{#49106} Change-Id: Icdff2510ec66d1c96a1912cef29d77d8550994ee Reviewed-on: https://chromium-review.googlesource.com/753903 Reviewed-by: Michael Starzinger <mstarzinger@chromium.org> Commit-Queue: Clemens Hammacher <clemensh@chromium.org> Cr-Commit-Position: refs/heads/master@{#49138}
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return base::bits::CountTrailingZeros(val);
}
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inline int64_t ExecuteI64Popcnt(uint64_t val, TrapReason* trap) {
return base::bits::CountPopulation(val);
}
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inline int32_t ExecuteI64Eqz(uint64_t val, TrapReason* trap) {
return val == 0 ? 1 : 0;
}
inline Float32 ExecuteF32Abs(Float32 a, TrapReason* trap) {
return Float32::FromBits(a.get_bits() & ~kFloat32SignBitMask);
}
inline Float32 ExecuteF32Neg(Float32 a, TrapReason* trap) {
return Float32::FromBits(a.get_bits() ^ kFloat32SignBitMask);
}
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inline float ExecuteF32Ceil(float a, TrapReason* trap) { return ceilf(a); }
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inline float ExecuteF32Floor(float a, TrapReason* trap) { return floorf(a); }
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inline float ExecuteF32Trunc(float a, TrapReason* trap) { return truncf(a); }
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inline float ExecuteF32NearestInt(float a, TrapReason* trap) {
return nearbyintf(a);
}
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inline float ExecuteF32Sqrt(float a, TrapReason* trap) {
float result = sqrtf(a);
return result;
}
inline Float64 ExecuteF64Abs(Float64 a, TrapReason* trap) {
return Float64::FromBits(a.get_bits() & ~kFloat64SignBitMask);
}
inline Float64 ExecuteF64Neg(Float64 a, TrapReason* trap) {
return Float64::FromBits(a.get_bits() ^ kFloat64SignBitMask);
}
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inline double ExecuteF64Ceil(double a, TrapReason* trap) { return ceil(a); }
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inline double ExecuteF64Floor(double a, TrapReason* trap) { return floor(a); }
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inline double ExecuteF64Trunc(double a, TrapReason* trap) { return trunc(a); }
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inline double ExecuteF64NearestInt(double a, TrapReason* trap) {
return nearbyint(a);
}
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inline double ExecuteF64Sqrt(double a, TrapReason* trap) { return sqrt(a); }
template <typename int_type, typename float_type>
int_type ExecuteConvert(float_type a, TrapReason* trap) {
if (is_inbounds<int_type>(a)) {
return static_cast<int_type>(a);
}
*trap = kTrapFloatUnrepresentable;
return 0;
}
template <typename int_type, typename float_type>
int_type ExecuteConvertSaturate(float_type a) {
TrapReason base_trap = kTrapCount;
int32_t val = ExecuteConvert<int_type>(a, &base_trap);
if (base_trap == kTrapCount) {
return val;
}
return std::isnan(a) ? 0
: (a < static_cast<float_type>(0.0)
? std::numeric_limits<int_type>::min()
: std::numeric_limits<int_type>::max());
}
template <typename dst_type, typename src_type, void (*fn)(Address)>
inline dst_type CallExternalIntToFloatFunction(src_type input) {
uint8_t data[std::max(sizeof(dst_type), sizeof(src_type))];
Address data_addr = reinterpret_cast<Address>(data);
WriteUnalignedValue<src_type>(data_addr, input);
fn(data_addr);
return ReadUnalignedValue<dst_type>(data_addr);
}
template <typename dst_type, typename src_type, int32_t (*fn)(Address)>
inline dst_type CallExternalFloatToIntFunction(src_type input,
TrapReason* trap) {
uint8_t data[std::max(sizeof(dst_type), sizeof(src_type))];
Address data_addr = reinterpret_cast<Address>(data);
WriteUnalignedValue<src_type>(data_addr, input);
if (!fn(data_addr)) *trap = kTrapFloatUnrepresentable;
return ReadUnalignedValue<dst_type>(data_addr);
}
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inline uint32_t ExecuteI32ConvertI64(int64_t a, TrapReason* trap) {
return static_cast<uint32_t>(a & 0xFFFFFFFF);
}
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int64_t ExecuteI64SConvertF32(float a, TrapReason* trap) {
return CallExternalFloatToIntFunction<int64_t, float,
float32_to_int64_wrapper>(a, trap);
}
int64_t ExecuteI64SConvertSatF32(float a) {
TrapReason base_trap = kTrapCount;
int64_t val = ExecuteI64SConvertF32(a, &base_trap);
if (base_trap == kTrapCount) {
return val;
}
return std::isnan(a) ? 0
: (a < 0.0 ? std::numeric_limits<int64_t>::min()
: std::numeric_limits<int64_t>::max());
}
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int64_t ExecuteI64SConvertF64(double a, TrapReason* trap) {
return CallExternalFloatToIntFunction<int64_t, double,
float64_to_int64_wrapper>(a, trap);
}
int64_t ExecuteI64SConvertSatF64(double a) {
TrapReason base_trap = kTrapCount;
int64_t val = ExecuteI64SConvertF64(a, &base_trap);
if (base_trap == kTrapCount) {
return val;
}
return std::isnan(a) ? 0
: (a < 0.0 ? std::numeric_limits<int64_t>::min()
: std::numeric_limits<int64_t>::max());
}
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uint64_t ExecuteI64UConvertF32(float a, TrapReason* trap) {
return CallExternalFloatToIntFunction<uint64_t, float,
float32_to_uint64_wrapper>(a, trap);
}
uint64_t ExecuteI64UConvertSatF32(float a) {
TrapReason base_trap = kTrapCount;
uint64_t val = ExecuteI64UConvertF32(a, &base_trap);
if (base_trap == kTrapCount) {
return val;
}
return std::isnan(a) ? 0
: (a < 0.0 ? std::numeric_limits<uint64_t>::min()
: std::numeric_limits<uint64_t>::max());
}
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uint64_t ExecuteI64UConvertF64(double a, TrapReason* trap) {
return CallExternalFloatToIntFunction<uint64_t, double,
float64_to_uint64_wrapper>(a, trap);
}
uint64_t ExecuteI64UConvertSatF64(double a) {
TrapReason base_trap = kTrapCount;
int64_t val = ExecuteI64UConvertF64(a, &base_trap);
if (base_trap == kTrapCount) {
return val;
}
return std::isnan(a) ? 0
: (a < 0.0 ? std::numeric_limits<uint64_t>::min()
: std::numeric_limits<uint64_t>::max());
}
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inline int64_t ExecuteI64SConvertI32(int32_t a, TrapReason* trap) {
return static_cast<int64_t>(a);
}
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inline int64_t ExecuteI64UConvertI32(uint32_t a, TrapReason* trap) {
return static_cast<uint64_t>(a);
}
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inline float ExecuteF32SConvertI32(int32_t a, TrapReason* trap) {
return static_cast<float>(a);
}
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inline float ExecuteF32UConvertI32(uint32_t a, TrapReason* trap) {
return static_cast<float>(a);
}
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inline float ExecuteF32SConvertI64(int64_t a, TrapReason* trap) {
return static_cast<float>(a);
}
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inline float ExecuteF32UConvertI64(uint64_t a, TrapReason* trap) {
return CallExternalIntToFloatFunction<float, uint64_t,
uint64_to_float32_wrapper>(a);
}
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inline float ExecuteF32ConvertF64(double a, TrapReason* trap) {
return DoubleToFloat32(a);
}
inline Float32 ExecuteF32ReinterpretI32(int32_t a, TrapReason* trap) {
return Float32::FromBits(a);
}
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inline double ExecuteF64SConvertI32(int32_t a, TrapReason* trap) {
return static_cast<double>(a);
}
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inline double ExecuteF64UConvertI32(uint32_t a, TrapReason* trap) {
return static_cast<double>(a);
}
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inline double ExecuteF64SConvertI64(int64_t a, TrapReason* trap) {
return static_cast<double>(a);
}
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inline double ExecuteF64UConvertI64(uint64_t a, TrapReason* trap) {
return CallExternalIntToFloatFunction<double, uint64_t,
uint64_to_float64_wrapper>(a);
}
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inline double ExecuteF64ConvertF32(float a, TrapReason* trap) {
return static_cast<double>(a);
}
inline Float64 ExecuteF64ReinterpretI64(int64_t a, TrapReason* trap) {
return Float64::FromBits(a);
}
inline int32_t ExecuteI32ReinterpretF32(WasmValue a) {
return a.to_f32_boxed().get_bits();
}
inline int64_t ExecuteI64ReinterpretF64(WasmValue a) {
return a.to_f64_boxed().get_bits();
}
constexpr int32_t kCatchInArity = 1;
} // namespace
class SideTable;
// Code and metadata needed to execute a function.
struct InterpreterCode {
const WasmFunction* function; // wasm function
BodyLocalDecls locals; // local declarations
const byte* start; // start of code
const byte* end; // end of code
SideTable* side_table; // precomputed side table for control flow
const byte* at(pc_t pc) { return start + pc; }
};
// A helper class to compute the control transfers for each bytecode offset.
// Control transfers allow Br, BrIf, BrTable, If, Else, and End bytecodes to
// be directly executed without the need to dynamically track blocks.
class SideTable : public ZoneObject {
public:
ControlTransferMap map_;
int32_t max_stack_height_ = 0;
SideTable(Zone* zone, const WasmModule* module, InterpreterCode* code)
: map_(zone) {
// Create a zone for all temporary objects.
Zone control_transfer_zone(zone->allocator(), ZONE_NAME);
// Represents a control flow label.
class CLabel : public ZoneObject {
explicit CLabel(Zone* zone, int32_t target_stack_height, uint32_t arity)
: target_stack_height(target_stack_height),
arity(arity),
refs(zone) {}
public:
struct Ref {
const byte* from_pc;
const int32_t stack_height;
};
const byte* target = nullptr;
int32_t target_stack_height;
// Arity when branching to this label.
const uint32_t arity;
ZoneVector<Ref> refs;
static CLabel* New(Zone* zone, int32_t stack_height, uint32_t arity) {
return new (zone) CLabel(zone, stack_height, arity);
}
// Bind this label to the given PC.
void Bind(const byte* pc) {
DCHECK_NULL(target);
target = pc;
}
// Reference this label from the given location.
void Ref(const byte* from_pc, int32_t stack_height) {
// Target being bound before a reference means this is a loop.
DCHECK_IMPLIES(target, *target == kExprLoop);
refs.push_back({from_pc, stack_height});
}
void Finish(ControlTransferMap* map, const byte* start) {
DCHECK_NOT_NULL(target);
for (auto ref : refs) {
size_t offset = static_cast<size_t>(ref.from_pc - start);
auto pcdiff = static_cast<pcdiff_t>(target - ref.from_pc);
DCHECK_GE(ref.stack_height, target_stack_height);
spdiff_t spdiff =
static_cast<spdiff_t>(ref.stack_height - target_stack_height);
TRACE("control transfer @%zu: Δpc %d, stack %u->%u = -%u\n", offset,
pcdiff, ref.stack_height, target_stack_height, spdiff);
ControlTransferEntry& entry = (*map)[offset];
entry.pc_diff = pcdiff;
entry.sp_diff = spdiff;
entry.target_arity = arity;
}
}
};
// An entry in the control stack.
struct Control {
const byte* pc;
CLabel* end_label;
CLabel* else_label;
// Arity (number of values on the stack) when exiting this control
// structure via |end|.
uint32_t exit_arity;
// Track whether this block was already left, i.e. all further
// instructions are unreachable.
bool unreachable = false;
Control(const byte* pc, CLabel* end_label, CLabel* else_label,
uint32_t exit_arity)
: pc(pc),
end_label(end_label),
else_label(else_label),
exit_arity(exit_arity) {}
Control(const byte* pc, CLabel* end_label, uint32_t exit_arity)
: Control(pc, end_label, nullptr, exit_arity) {}
void Finish(ControlTransferMap* map, const byte* start) {
end_label->Finish(map, start);
if (else_label) else_label->Finish(map, start);
}
};
// Compute the ControlTransfer map.
// This algorithm maintains a stack of control constructs similar to the
// AST decoder. The {control_stack} allows matching {br,br_if,br_table}
// bytecodes with their target, as well as determining whether the current
// bytecodes are within the true or false block of an else.
ZoneVector<Control> control_stack(&control_transfer_zone);
// It also maintains a stack of all nested {try} blocks to resolve local
// handler targets for potentially throwing operations. These exceptional
// control transfers are treated just like other branches in the resulting
// map. This stack contains indices into the above control stack.
ZoneVector<size_t> exception_stack(zone);
int32_t stack_height = 0;
uint32_t func_arity =
static_cast<uint32_t>(code->function->sig->return_count());
CLabel* func_label =
CLabel::New(&control_transfer_zone, stack_height, func_arity);
control_stack.emplace_back(code->start, func_label, func_arity);
auto control_parent = [&]() -> Control& {
DCHECK_LE(2, control_stack.size());
return control_stack[control_stack.size() - 2];
};
auto copy_unreachable = [&] {
control_stack.back().unreachable = control_parent().unreachable;
};
for (BytecodeIterator i(code->start, code->end, &code->locals);
i.has_next(); i.next()) {
WasmOpcode opcode = i.current();
int32_t exceptional_stack_height = 0;
if (WasmOpcodes::IsPrefixOpcode(opcode)) opcode = i.prefixed_opcode();
bool unreachable = control_stack.back().unreachable;
if (unreachable) {
TRACE("@%u: %s (is unreachable)\n", i.pc_offset(),
WasmOpcodes::OpcodeName(opcode));
} else {
auto stack_effect =
StackEffect(module, code->function->sig, i.pc(), i.end());
TRACE("@%u: %s (sp %d - %d + %d)\n", i.pc_offset(),
WasmOpcodes::OpcodeName(opcode), stack_height, stack_effect.first,
stack_effect.second);
DCHECK_GE(stack_height, stack_effect.first);
DCHECK_GE(kMaxUInt32, static_cast<uint64_t>(stack_height) -
stack_effect.first + stack_effect.second);
exceptional_stack_height = stack_height - stack_effect.first;
stack_height = stack_height - stack_effect.first + stack_effect.second;
if (stack_height > max_stack_height_) max_stack_height_ = stack_height;
}
if (!exception_stack.empty() && WasmOpcodes::IsThrowingOpcode(opcode)) {
// Record exceptional control flow from potentially throwing opcodes to
// the local handler if one is present. The stack height at the throw
// point is assumed to have popped all operands and not pushed any yet.
DCHECK_GE(control_stack.size() - 1, exception_stack.back());
const Control* c = &control_stack[exception_stack.back()];
if (!unreachable) c->else_label->Ref(i.pc(), exceptional_stack_height);
if (exceptional_stack_height + kCatchInArity > max_stack_height_) {
max_stack_height_ = exceptional_stack_height + kCatchInArity;
}
TRACE("handler @%u: %s -> try @%u\n", i.pc_offset(),
WasmOpcodes::OpcodeName(opcode),
static_cast<uint32_t>(c->pc - code->start));
}
switch (opcode) {
case kExprBlock:
case kExprLoop: {
bool is_loop = opcode == kExprLoop;
BlockTypeImmediate<Decoder::kNoValidate> imm(WasmFeatures::All(), &i,
i.pc());
if (imm.type == kWasmBottom) {
imm.sig = module->signature(imm.sig_index);
}
TRACE("control @%u: %s, arity %d->%d\n", i.pc_offset(),
is_loop ? "Loop" : "Block", imm.in_arity(), imm.out_arity());
CLabel* label =
CLabel::New(&control_transfer_zone, stack_height - imm.in_arity(),
is_loop ? imm.in_arity() : imm.out_arity());
control_stack.emplace_back(i.pc(), label, imm.out_arity());
copy_unreachable();
if (is_loop) label->Bind(i.pc());
break;
}
case kExprIf: {
BlockTypeImmediate<Decoder::kNoValidate> imm(WasmFeatures::All(), &i,
i.pc());
if (imm.type == kWasmBottom) {
imm.sig = module->signature(imm.sig_index);
}
TRACE("control @%u: If, arity %d->%d\n", i.pc_offset(),
imm.in_arity(), imm.out_arity());
CLabel* end_label =
CLabel::New(&control_transfer_zone, stack_height - imm.in_arity(),
imm.out_arity());
CLabel* else_label =
CLabel::New(&control_transfer_zone, stack_height, 0);
control_stack.emplace_back(i.pc(), end_label, else_label,
imm.out_arity());
copy_unreachable();
if (!unreachable) else_label->Ref(i.pc(), stack_height);
break;
}
case kExprElse: {
Control* c = &control_stack.back();
copy_unreachable();
TRACE("control @%u: Else\n", i.pc_offset());
if (!control_parent().unreachable) {
c->end_label->Ref(i.pc(), stack_height);
}
DCHECK_NOT_NULL(c->else_label);
c->else_label->Bind(i.pc() + 1);
c->else_label->Finish(&map_, code->start);
stack_height = c->else_label->target_stack_height;
c->else_label = nullptr;
DCHECK_IMPLIES(!unreachable,
stack_height >= c->end_label->target_stack_height);
break;
}
case kExprTry: {
BlockTypeImmediate<Decoder::kNoValidate> imm(WasmFeatures::All(), &i,
i.pc());
if (imm.type == kWasmBottom) {
imm.sig = module->signature(imm.sig_index);
}
TRACE("control @%u: Try, arity %d->%d\n", i.pc_offset(),
imm.in_arity(), imm.out_arity());
CLabel* end_label = CLabel::New(&control_transfer_zone, stack_height,
imm.out_arity());
CLabel* catch_label =
CLabel::New(&control_transfer_zone, stack_height, kCatchInArity);
control_stack.emplace_back(i.pc(), end_label, catch_label,
imm.out_arity());
exception_stack.push_back(control_stack.size() - 1);
copy_unreachable();
break;
}
case kExprCatch: {
DCHECK_EQ(control_stack.size() - 1, exception_stack.back());
Control* c = &control_stack.back();
exception_stack.pop_back();
copy_unreachable();
TRACE("control @%u: Catch\n", i.pc_offset());
if (!control_parent().unreachable) {
c->end_label->Ref(i.pc(), stack_height);
}
DCHECK_NOT_NULL(c->else_label);
c->else_label->Bind(i.pc() + 1);
c->else_label->Finish(&map_, code->start);
c->else_label = nullptr;
DCHECK_IMPLIES(!unreachable,
stack_height >= c->end_label->target_stack_height);
stack_height = c->end_label->target_stack_height + kCatchInArity;
break;
}
case kExprBrOnExn: {
BranchOnExceptionImmediate<Decoder::kNoValidate> imm(&i, i.pc());
uint32_t depth = imm.depth.depth; // Extracted for convenience.
imm.index.exception = &module->exceptions[imm.index.index];
DCHECK_EQ(0, imm.index.exception->sig->return_count());
size_t params = imm.index.exception->sig->parameter_count();
// Taken branches pop the exception and push the encoded values.
int32_t height = stack_height - 1 + static_cast<int32_t>(params);
TRACE("control @%u: BrOnExn[depth=%u]\n", i.pc_offset(), depth);
Control* c = &control_stack[control_stack.size() - depth - 1];
if (!unreachable) c->end_label->Ref(i.pc(), height);
break;
}
case kExprEnd: {
Control* c = &control_stack.back();
TRACE("control @%u: End\n", i.pc_offset());
// Only loops have bound labels.
DCHECK_IMPLIES(c->end_label->target, *c->pc == kExprLoop);
if (!c->end_label->target) {
if (c->else_label) c->else_label->Bind(i.pc());
c->end_label->Bind(i.pc() + 1);
}
c->Finish(&map_, code->start);
DCHECK_IMPLIES(!unreachable,
stack_height >= c->end_label->target_stack_height);
stack_height = c->end_label->target_stack_height + c->exit_arity;
control_stack.pop_back();
break;
}
case kExprBr: {
BranchDepthImmediate<Decoder::kNoValidate> imm(&i, i.pc());
TRACE("control @%u: Br[depth=%u]\n", i.pc_offset(), imm.depth);
Control* c = &control_stack[control_stack.size() - imm.depth - 1];
if (!unreachable) c->end_label->Ref(i.pc(), stack_height);
break;
}
case kExprBrIf: {
BranchDepthImmediate<Decoder::kNoValidate> imm(&i, i.pc());
TRACE("control @%u: BrIf[depth=%u]\n", i.pc_offset(), imm.depth);
Control* c = &control_stack[control_stack.size() - imm.depth - 1];
if (!unreachable) c->end_label->Ref(i.pc(), stack_height);
break;
}
case kExprBrTable: {
BranchTableImmediate<Decoder::kNoValidate> imm(&i, i.pc());
BranchTableIterator<Decoder::kNoValidate> iterator(&i, imm);
TRACE("control @%u: BrTable[count=%u]\n", i.pc_offset(),
imm.table_count);
if (!unreachable) {
while (iterator.has_next()) {
uint32_t j = iterator.cur_index();
uint32_t target = iterator.next();
Control* c = &control_stack[control_stack.size() - target - 1];
c->end_label->Ref(i.pc() + j, stack_height);
}
}
break;
}
default:
break;
}
if (WasmOpcodes::IsUnconditionalJump(opcode)) {
control_stack.back().unreachable = true;
}
}
DCHECK_EQ(0, control_stack.size());
DCHECK_EQ(func_arity, stack_height);
}
bool HasEntryAt(pc_t from) {
auto result = map_.find(from);
return result != map_.end();
}
ControlTransferEntry& Lookup(pc_t from) {
auto result = map_.find(from);
DCHECK(result != map_.end());
return result->second;
}
};
// The main storage for interpreter code. It maps {WasmFunction} to the
// metadata needed to execute each function.
class CodeMap {
Zone* zone_;
const WasmModule* module_;
ZoneVector<InterpreterCode> interpreter_code_;
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public:
CodeMap(const WasmModule* module, const uint8_t* module_start, Zone* zone)
Reland "[wasm] Don't store global handles in the interpreter" This is a reland of 5648aad553e09144197fbb40cf9314d057bd52ba. Previous compile error should be fixed by disabling strict aliasing assumptions on gyp: https://chromium-review.googlesource.com/c/571806 Original change's description: > [wasm] Don't store global handles in the interpreter > > Storing global handles in the interpreter is dangerous, because the > global handles are strong roots into the heap. The interpreter itself is > referenced from the heap via a Managed. Hence the interpreter keeps the > instance alive, while the instance keeps the Managed alive. So the GC > will never collect them. > > This CL refactors this to only store the handle to the instance object > while executing in the interpreter, and clearing it when returning. > It also removes the cache of import wrappers, as it should not be > performance critical, but keeps lots of objects alive. If it turns out > to be performance critical, we will have to reintroduce such a cache > stored in the WasmDebugInfo object. > > R=titzer@chromium.org > CC=ahaas@chromium.org > > Bug: chromium:610330 > Change-Id: I54b489dadc16685887c0c1a98da6fd0df5ad7cbb > Reviewed-on: https://chromium-review.googlesource.com/567058 > Reviewed-by: Ben Titzer <titzer@chromium.org> > Commit-Queue: Clemens Hammacher <clemensh@chromium.org> > Cr-Commit-Position: refs/heads/master@{#46629} TBR=titzer@chromium.org Bug: chromium:610330 Change-Id: Ic7836b1b1a044a89f2138f0c76f92acd3a1b2f2b Reviewed-on: https://chromium-review.googlesource.com/570578 Commit-Queue: Clemens Hammacher <clemensh@chromium.org> Reviewed-by: Clemens Hammacher <clemensh@chromium.org> Cr-Commit-Position: refs/heads/master@{#46679}
2017-07-14 13:58:25 +00:00
: zone_(zone), module_(module), interpreter_code_(zone) {
if (module == nullptr) return;
interpreter_code_.reserve(module->functions.size());
for (const WasmFunction& function : module->functions) {
if (function.imported) {
DCHECK(!function.code.is_set());
AddFunction(&function, nullptr, nullptr);
} else {
AddFunction(&function, module_start + function.code.offset(),
module_start + function.code.end_offset());
}
}
}
2017-03-23 09:46:16 +00:00
const WasmModule* module() const { return module_; }
Revert "Revert "[wasm] JIT using WasmCodeManager"" This reverts commit b301203e5aec9c8ff32f93aa31f8d764311e6e6e. Reason for revert: Fixed issues on arm. Original change's description: > Revert "[wasm] JIT using WasmCodeManager" > > This reverts commit d4c8393c1cc9cf3e2b19daabc3a161ff18d596cb. > > Reason for revert: Breaks ARM hardware: > https://build.chromium.org/p/client.v8.ports/builders/V8%20Arm%20-%20debug/builds/5268 > > Original change's description: > > [wasm] JIT using WasmCodeManager > > > > This is the first step towards wasm code sharing. This CL moves wasm > > code generation outside the JavaScript GC heap using the previously - > > introduced WasmCodeManager (all this, behind the --wasm-jit-to-native > > flag). > > > > See design document: go/wasm-on-native-heap-stage-1 > > > > This CL doesn't change other wasm architectural invariants. We still > > have per-Isolate wasm code generation, and per-wasm module instance > > code specialization. > > > > Bug:v8:6876 > > > > Cq-Include-Trybots: master.tryserver.chromium.linux:linux_chromium_rel_ng > > Change-Id: I1e08cecad75f93fb081545c31228a4568be276d3 > > Reviewed-on: https://chromium-review.googlesource.com/674086 > > Reviewed-by: Ben Titzer <titzer@chromium.org> > > Reviewed-by: Eric Holk <eholk@chromium.org> > > Cr-Commit-Position: refs/heads/master@{#49689} > > TBR=bradnelson@chromium.org,titzer@chromium.org,mtrofin@chromium.org,eholk@chromium.org > > Change-Id: I89af1ea5decd841bc12cd2ceaf74d32bc4433885 > No-Presubmit: true > No-Tree-Checks: true > No-Try: true > Bug: v8:6876 > Cq-Include-Trybots: master.tryserver.chromium.linux:linux_chromium_rel_ng > Reviewed-on: https://chromium-review.googlesource.com/794690 > Reviewed-by: Michael Achenbach <machenbach@chromium.org> > Commit-Queue: Michael Achenbach <machenbach@chromium.org> > Cr-Commit-Position: refs/heads/master@{#49691} TBR=bradnelson@chromium.org,machenbach@chromium.org,titzer@chromium.org,mtrofin@chromium.org,eholk@chromium.org Change-Id: I1b07638d1bb2ba0664305b4b2dcfc1342dc8444f No-Presubmit: true No-Tree-Checks: true No-Try: true Bug: v8:6876 Cq-Include-Trybots: master.tryserver.chromium.linux:linux_chromium_rel_ng Reviewed-on: https://chromium-review.googlesource.com/794434 Commit-Queue: Mircea Trofin <mtrofin@chromium.org> Reviewed-by: Mircea Trofin <mtrofin@chromium.org> Cr-Commit-Position: refs/heads/master@{#49692}
2017-11-28 22:25:36 +00:00
InterpreterCode* GetCode(const WasmFunction* function) {
InterpreterCode* code = GetCode(function->func_index);
DCHECK_EQ(function, code->function);
return code;
}
InterpreterCode* GetCode(uint32_t function_index) {
DCHECK_LT(function_index, interpreter_code_.size());
return Preprocess(&interpreter_code_[function_index]);
}
InterpreterCode* Preprocess(InterpreterCode* code) {
DCHECK_EQ(code->function->imported, code->start == nullptr);
if (!code->side_table && code->start) {
// Compute the control targets map and the local declarations.
code->side_table = new (zone_) SideTable(zone_, module_, code);
}
return code;
}
void AddFunction(const WasmFunction* function, const byte* code_start,
const byte* code_end) {
InterpreterCode code = {function, BodyLocalDecls(zone_), code_start,
code_end, nullptr};
DCHECK_EQ(interpreter_code_.size(), function->func_index);
interpreter_code_.push_back(code);
}
void SetFunctionCode(const WasmFunction* function, const byte* start,
const byte* end) {
DCHECK_LT(function->func_index, interpreter_code_.size());
InterpreterCode* code = &interpreter_code_[function->func_index];
DCHECK_EQ(function, code->function);
code->start = const_cast<byte*>(start);
code->end = const_cast<byte*>(end);
code->side_table = nullptr;
Preprocess(code);
}
2017-03-23 09:46:16 +00:00
};
namespace {
struct CallResult {
enum Type {
// The function should be executed inside this interpreter.
INTERNAL,
// For indirect calls: Table or function does not exist.
INVALID_FUNC,
// For indirect calls: Signature does not match expected signature.
SIGNATURE_MISMATCH
};
Type type;
// If type is INTERNAL, this field holds the function to call internally.
InterpreterCode* interpreter_code;
CallResult(Type type) : type(type) { // NOLINT
DCHECK_NE(INTERNAL, type);
}
CallResult(Type type, InterpreterCode* code)
: type(type), interpreter_code(code) {
DCHECK_EQ(INTERNAL, type);
}
};
// Like a static_cast from src to dst, but specialized for boxed floats.
template <typename dst, typename src>
struct converter {
dst operator()(src val) const { return static_cast<dst>(val); }
};
template <>
struct converter<Float64, uint64_t> {
Float64 operator()(uint64_t val) const { return Float64::FromBits(val); }
};
template <>
struct converter<Float32, uint32_t> {
Float32 operator()(uint32_t val) const { return Float32::FromBits(val); }
};
template <>
struct converter<uint64_t, Float64> {
uint64_t operator()(Float64 val) const { return val.get_bits(); }
};
template <>
struct converter<uint32_t, Float32> {
uint32_t operator()(Float32 val) const { return val.get_bits(); }
};
template <typename T>
V8_INLINE bool has_nondeterminism(T val) {
static_assert(!std::is_floating_point<T>::value, "missing specialization");
return false;
}
template <>
V8_INLINE bool has_nondeterminism<float>(float val) {
return std::isnan(val);
}
template <>
V8_INLINE bool has_nondeterminism<double>(double val) {
return std::isnan(val);
}
} // namespace
// Responsible for executing code directly.
class ThreadImpl {
struct Activation {
uint32_t fp;
sp_t sp;
Activation(uint32_t fp, sp_t sp) : fp(fp), sp(sp) {}
};
public:
// The {ReferenceStackScope} sets up the reference stack in the interpreter.
// The handle to the reference stack has to be re-initialized everytime we
// call into the interpreter because there is no HandleScope that could
// contain that handle. A global handle is not an option because it can lead
// to a memory leak if a reference to the {WasmInstanceObject} is put onto the
// reference stack and thereby transitively keeps the interpreter alive.
class ReferenceStackScope {
public:
explicit ReferenceStackScope(ThreadImpl* impl) : impl_(impl) {
// The reference stack is already initialized, we don't have to do
// anything.
if (!impl_->reference_stack_cell_.is_null()) return;
impl_->reference_stack_cell_ = handle(
impl_->instance_object_->debug_info().interpreter_reference_stack(),
impl_->isolate_);
// We initialized the reference stack, so we also have to reset it later.
do_reset_stack_ = true;
}
~ReferenceStackScope() {
if (do_reset_stack_) {
impl_->reference_stack_cell_ = Handle<Cell>();
}
}
private:
ThreadImpl* impl_;
bool do_reset_stack_ = false;
};
ThreadImpl(Zone* zone, CodeMap* codemap,
Handle<WasmInstanceObject> instance_object)
: codemap_(codemap),
isolate_(instance_object->GetIsolate()),
instance_object_(instance_object),
frames_(zone),
activations_(zone) {}
//==========================================================================
// Implementation of public interface for WasmInterpreter::Thread.
//==========================================================================
WasmInterpreter::State state() { return state_; }
void InitFrame(const WasmFunction* function, WasmValue* args) {
DCHECK_EQ(current_activation().fp, frames_.size());
InterpreterCode* code = codemap()->GetCode(function);
size_t num_params = function->sig->parameter_count();
EnsureStackSpace(num_params);
Push(args, num_params);
PushFrame(code);
}
WasmInterpreter::State Run(int num_steps = -1) {
DCHECK(state_ == WasmInterpreter::STOPPED ||
state_ == WasmInterpreter::PAUSED);
DCHECK(num_steps == -1 || num_steps > 0);
if (num_steps == -1) {
TRACE(" => Run()\n");
} else if (num_steps == 1) {
TRACE(" => Step()\n");
} else {
TRACE(" => Run(%d)\n", num_steps);
}
state_ = WasmInterpreter::RUNNING;
Execute(frames_.back().code, frames_.back().pc, num_steps);
// If state_ is STOPPED, the current activation must be fully unwound.
DCHECK_IMPLIES(state_ == WasmInterpreter::STOPPED,
current_activation().fp == frames_.size());
return state_;
}
void Pause() { UNIMPLEMENTED(); }
void Reset() {
TRACE("----- RESET -----\n");
ResetStack(0);
frames_.clear();
state_ = WasmInterpreter::STOPPED;
trap_reason_ = kTrapCount;
possible_nondeterminism_ = false;
}
int GetFrameCount() {
DCHECK_GE(kMaxInt, frames_.size());
return static_cast<int>(frames_.size());
}
WasmValue GetReturnValue(uint32_t index) {
if (state_ == WasmInterpreter::TRAPPED) return WasmValue(0xDEADBEEF);
DCHECK_EQ(WasmInterpreter::FINISHED, state_);
Activation act = current_activation();
// Current activation must be finished.
DCHECK_EQ(act.fp, frames_.size());
return GetStackValue(act.sp + index);
}
WasmValue GetStackValue(sp_t index) {
DCHECK_GT(StackHeight(), index);
return stack_[index].ExtractValue(this, index);
}
void SetStackValue(sp_t index, WasmValue value) {
DCHECK_GT(StackHeight(), index);
stack_[index] = StackValue(value, this, index);
}
TrapReason GetTrapReason() { return trap_reason_; }
bool PossibleNondeterminism() { return possible_nondeterminism_; }
uint64_t NumInterpretedCalls() { return num_interpreted_calls_; }
Handle<Cell> reference_stack_cell() const { return reference_stack_cell_; }
uint32_t NumActivations() {
return static_cast<uint32_t>(activations_.size());
}
uint32_t StartActivation() {
TRACE("----- START ACTIVATION %zu -----\n", activations_.size());
// If you use activations, use them consistently:
DCHECK_IMPLIES(activations_.empty(), frames_.empty());
DCHECK_IMPLIES(activations_.empty(), StackHeight() == 0);
uint32_t activation_id = static_cast<uint32_t>(activations_.size());
activations_.emplace_back(static_cast<uint32_t>(frames_.size()),
StackHeight());
state_ = WasmInterpreter::STOPPED;
return activation_id;
}
void FinishActivation(uint32_t id) {
TRACE("----- FINISH ACTIVATION %zu -----\n", activations_.size() - 1);
DCHECK_LT(0, activations_.size());
DCHECK_EQ(activations_.size() - 1, id);
// Stack height must match the start of this activation (otherwise unwind
// first).
DCHECK_EQ(activations_.back().fp, frames_.size());
DCHECK_LE(activations_.back().sp, StackHeight());
ResetStack(activations_.back().sp);
activations_.pop_back();
}
uint32_t ActivationFrameBase(uint32_t id) {
DCHECK_GT(activations_.size(), id);
return activations_[id].fp;
}
WasmInterpreter::Thread::ExceptionHandlingResult RaiseException(
Isolate* isolate, Handle<Object> exception) {
DCHECK_EQ(WasmInterpreter::TRAPPED, state_);
isolate->Throw(*exception); // Will check that none is pending.
if (HandleException(isolate) == WasmInterpreter::Thread::UNWOUND) {
DCHECK_EQ(WasmInterpreter::STOPPED, state_);
return WasmInterpreter::Thread::UNWOUND;
}
state_ = WasmInterpreter::PAUSED;
return WasmInterpreter::Thread::HANDLED;
}
private:
// Handle a thrown exception. Returns whether the exception was handled inside
// the current activation. Unwinds the interpreted stack accordingly.
WasmInterpreter::Thread::ExceptionHandlingResult HandleException(
Isolate* isolate) {
DCHECK(isolate->has_pending_exception());
bool catchable =
isolate->is_catchable_by_wasm(isolate->pending_exception());
DCHECK_LT(0, activations_.size());
Activation& act = activations_.back();
while (frames_.size() > act.fp) {
Frame& frame = frames_.back();
InterpreterCode* code = frame.code;
if (catchable && code->side_table->HasEntryAt(frame.pc)) {
TRACE("----- HANDLE -----\n");
Push(WasmValue(handle(isolate->pending_exception(), isolate)));
isolate->clear_pending_exception();
frame.pc += JumpToHandlerDelta(code, frame.pc);
TRACE(" => handler #%zu (#%u @%zu)\n", frames_.size() - 1,
code->function->func_index, frame.pc);
return WasmInterpreter::Thread::HANDLED;
}
TRACE(" => drop frame #%zu (#%u @%zu)\n", frames_.size() - 1,
code->function->func_index, frame.pc);
ResetStack(frame.sp);
frames_.pop_back();
}
TRACE("----- UNWIND -----\n");
DCHECK_EQ(act.fp, frames_.size());
DCHECK_EQ(act.sp, StackHeight());
state_ = WasmInterpreter::STOPPED;
return WasmInterpreter::Thread::UNWOUND;
}
// Entries on the stack of functions being evaluated.
struct Frame {
InterpreterCode* code;
pc_t pc;
sp_t sp;
// Limit of parameters.
sp_t plimit() { return sp + code->function->sig->parameter_count(); }
// Limit of locals.
sp_t llimit() { return plimit() + code->locals.type_list.size(); }
};
// Safety wrapper for values on the operand stack represented as {WasmValue}.
// Most values are stored directly on the stack, only reference values are
// kept in a separate on-heap reference stack to make the GC trace them.
// TODO(wasm): Optimize simple stack operations (like "get_local",
// "set_local", and "tee_local") so that they don't require a handle scope.
// TODO(wasm): Consider optimizing activations that use no reference
// values to avoid allocating the reference stack entirely.
class StackValue {
public:
StackValue() = default; // Only needed for resizing the stack.
StackValue(WasmValue v, ThreadImpl* thread, sp_t index) : value_(v) {
if (IsReferenceValue()) {
value_ = WasmValue(Handle<Object>::null());
int ref_index = static_cast<int>(index);
thread->reference_stack().set(ref_index, *v.to_anyref());
}
}
WasmValue ExtractValue(ThreadImpl* thread, sp_t index) {
if (!IsReferenceValue()) return value_;
DCHECK(value_.to_anyref().is_null());
int ref_index = static_cast<int>(index);
Isolate* isolate = thread->isolate_;
Handle<Object> ref(thread->reference_stack().get(ref_index), isolate);
DCHECK(!ref->IsTheHole(isolate));
return WasmValue(ref);
}
bool IsReferenceValue() const { return value_.type() == kWasmAnyRef; }
void ClearValue(ThreadImpl* thread, sp_t index) {
if (!IsReferenceValue()) return;
int ref_index = static_cast<int>(index);
Isolate* isolate = thread->isolate_;
thread->reference_stack().set_the_hole(isolate, ref_index);
}
static void ClearValues(ThreadImpl* thread, sp_t index, int count) {
int ref_index = static_cast<int>(index);
thread->reference_stack().FillWithHoles(ref_index, ref_index + count);
}
static bool IsClearedValue(ThreadImpl* thread, sp_t index) {
int ref_index = static_cast<int>(index);
Isolate* isolate = thread->isolate_;
return thread->reference_stack().is_the_hole(isolate, ref_index);
}
private:
WasmValue value_;
};
friend class ReferenceStackScope;
CodeMap* codemap_;
Isolate* isolate_;
Handle<WasmInstanceObject> instance_object_;
std::unique_ptr<StackValue[]> stack_;
StackValue* stack_limit_ = nullptr; // End of allocated stack space.
StackValue* sp_ = nullptr; // Current stack pointer.
// The reference stack is pointed to by a {Cell} to be able to replace the
// underlying {FixedArray} when growing the stack. This avoids having to
// recreate or update the global handle keeping this object alive.
Handle<Cell> reference_stack_cell_; // References are on an on-heap stack.
ZoneVector<Frame> frames_;
WasmInterpreter::State state_ = WasmInterpreter::STOPPED;
TrapReason trap_reason_ = kTrapCount;
bool possible_nondeterminism_ = false;
uint64_t num_interpreted_calls_ = 0;
// Store the stack height of each activation (for unwind and frame
// inspection).
ZoneVector<Activation> activations_;
CodeMap* codemap() const { return codemap_; }
const WasmModule* module() const { return codemap_->module(); }
FixedArray reference_stack() const {
return FixedArray::cast(reference_stack_cell_->value());
}
void DoTrap(TrapReason trap, pc_t pc) {
TRACE("TRAP: %s\n", WasmOpcodes::TrapReasonMessage(trap));
state_ = WasmInterpreter::TRAPPED;
trap_reason_ = trap;
CommitPc(pc);
}
// Check if there is room for a function's activation.
void EnsureStackSpaceForCall(InterpreterCode* code) {
EnsureStackSpace(code->side_table->max_stack_height_ +
code->locals.type_list.size());
DCHECK_GE(StackHeight(), code->function->sig->parameter_count());
}
// Push a frame with arguments already on the stack.
void PushFrame(InterpreterCode* code) {
DCHECK_NOT_NULL(code);
DCHECK_NOT_NULL(code->side_table);
EnsureStackSpaceForCall(code);
++num_interpreted_calls_;
size_t arity = code->function->sig->parameter_count();
// The parameters will overlap the arguments already on the stack.
DCHECK_GE(StackHeight(), arity);
frames_.push_back({code, 0, StackHeight() - arity});
frames_.back().pc = InitLocals(code);
TRACE(" => PushFrame #%zu (#%u @%zu)\n", frames_.size() - 1,
code->function->func_index, frames_.back().pc);
}
pc_t InitLocals(InterpreterCode* code) {
for (ValueType p : code->locals.type_list) {
WasmValue val;
switch (p.kind()) {
#define CASE_TYPE(valuetype, ctype) \
case ValueType::valuetype: \
val = WasmValue(ctype{}); \
break;
FOREACH_WASMVALUE_CTYPES(CASE_TYPE)
#undef CASE_TYPE
case ValueType::kAnyRef:
case ValueType::kFuncRef:
case ValueType::kNullRef:
case ValueType::kExnRef:
case ValueType::kRef:
case ValueType::kOptRef:
case ValueType::kEqRef: {
val = WasmValue(isolate_->factory()->null_value());
break;
}
case ValueType::kStmt:
case ValueType::kBottom:
case ValueType::kI8:
case ValueType::kI16:
UNREACHABLE();
break;
}
Push(val);
}
return code->locals.encoded_size;
}
void CommitPc(pc_t pc) {
DCHECK(!frames_.empty());
frames_.back().pc = pc;
}
void ReloadFromFrameOnException(Decoder* decoder, InterpreterCode** code,
pc_t* pc, pc_t* limit) {
Frame* top = &frames_.back();
*code = top->code;
*pc = top->pc;
*limit = top->code->end - top->code->start;
decoder->Reset(top->code->start, top->code->end);
}
int LookupTargetDelta(InterpreterCode* code, pc_t pc) {
return static_cast<int>(code->side_table->Lookup(pc).pc_diff);
}
int JumpToHandlerDelta(InterpreterCode* code, pc_t pc) {
ControlTransferEntry& control_transfer_entry = code->side_table->Lookup(pc);
DoStackTransfer(control_transfer_entry.sp_diff + kCatchInArity,
control_transfer_entry.target_arity);
return control_transfer_entry.pc_diff;
}
int DoBreak(InterpreterCode* code, pc_t pc, size_t depth) {
ControlTransferEntry& control_transfer_entry = code->side_table->Lookup(pc);
DoStackTransfer(control_transfer_entry.sp_diff,
control_transfer_entry.target_arity);
return control_transfer_entry.pc_diff;
}
pc_t ReturnPc(Decoder* decoder, InterpreterCode* code, pc_t pc) {
switch (code->start[pc]) {
case kExprCallFunction: {
CallFunctionImmediate<Decoder::kNoValidate> imm(decoder, code->at(pc));
return pc + 1 + imm.length;
}
case kExprCallIndirect: {
CallIndirectImmediate<Decoder::kNoValidate> imm(WasmFeatures::All(),
decoder, code->at(pc));
return pc + 1 + imm.length;
}
default:
UNREACHABLE();
}
}
bool DoReturn(Decoder* decoder, InterpreterCode** code, pc_t* pc, pc_t* limit,
size_t arity) {
2016-12-01 08:52:31 +00:00
DCHECK_GT(frames_.size(), 0);
spdiff_t sp_diff = static_cast<spdiff_t>(StackHeight() - frames_.back().sp);
frames_.pop_back();
if (frames_.size() == current_activation().fp) {
// A return from the last frame terminates the execution.
state_ = WasmInterpreter::FINISHED;
DoStackTransfer(sp_diff, arity);
TRACE(" => finish\n");
return false;
} else {
// Return to caller frame.
Frame* top = &frames_.back();
*code = top->code;
decoder->Reset((*code)->start, (*code)->end);
*pc = ReturnPc(decoder, *code, top->pc);
*limit = top->code->end - top->code->start;
TRACE(" => Return to #%zu (#%u @%zu)\n", frames_.size() - 1,
(*code)->function->func_index, *pc);
DoStackTransfer(sp_diff, arity);
return true;
}
}
// Returns true if the call was successful, false if the stack check failed
// and the current activation was fully unwound.
bool DoCall(Decoder* decoder, InterpreterCode* target, pc_t* pc,
pc_t* limit) V8_WARN_UNUSED_RESULT {
frames_.back().pc = *pc;
PushFrame(target);
if (!DoStackCheck()) return false;
*pc = frames_.back().pc;
*limit = target->end - target->start;
decoder->Reset(target->start, target->end);
return true;
}
// Returns true if the tail call was successful, false if the stack check
// failed.
bool DoReturnCall(Decoder* decoder, InterpreterCode* target, pc_t* pc,
pc_t* limit) V8_WARN_UNUSED_RESULT {
DCHECK_NOT_NULL(target);
DCHECK_NOT_NULL(target->side_table);
EnsureStackSpaceForCall(target);
++num_interpreted_calls_;
Frame* top = &frames_.back();
// Drop everything except current parameters.
spdiff_t sp_diff = static_cast<spdiff_t>(StackHeight() - top->sp);
size_t arity = target->function->sig->parameter_count();
DoStackTransfer(sp_diff, arity);
*limit = target->end - target->start;
decoder->Reset(target->start, target->end);
// Rebuild current frame to look like a call to callee.
top->code = target;
top->pc = 0;
top->sp = StackHeight() - arity;
top->pc = InitLocals(target);
*pc = top->pc;
TRACE(" => ReturnCall #%zu (#%u @%zu)\n", frames_.size() - 1,
target->function->func_index, top->pc);
return true;
}
// Copies {arity} values on the top of the stack down the stack while also
// dropping {sp_diff} many stack values in total from the stack.
void DoStackTransfer(spdiff_t sp_diff, size_t arity) {
// before: |---------------| pop_count | arity |
// ^ 0 ^ dest ^ src ^ StackHeight()
// ^----< sp_diff >----^
//
// after: |---------------| arity |
// ^ 0 ^ StackHeight()
sp_t stack_height = StackHeight();
sp_t dest = stack_height - sp_diff;
sp_t src = stack_height - arity;
DCHECK_LE(dest, stack_height);
DCHECK_LE(dest, src);
if (arity && (dest != src)) {
StackValue* stack = stack_.get();
memmove(stack + dest, stack + src, arity * sizeof(StackValue));
// Also move elements on the reference stack accordingly.
reference_stack().MoveElements(
isolate_, static_cast<int>(dest), static_cast<int>(src),
static_cast<int>(arity), UPDATE_WRITE_BARRIER);
}
ResetStack(dest + arity);
}
inline Address EffectiveAddress(uint32_t index) {
// Compute the effective address of the access, making sure to condition
// the index even in the in-bounds case.
return reinterpret_cast<Address>(instance_object_->memory_start()) +
(index & instance_object_->memory_mask());
}
template <typename mtype>
inline Address BoundsCheckMem(uint32_t offset, uint32_t index) {
uint32_t effective_index = offset + index;
if (effective_index < index) {
return kNullAddress; // wraparound => oob
}
if (!base::IsInBounds(effective_index, sizeof(mtype),
instance_object_->memory_size())) {
return kNullAddress; // oob
}
return EffectiveAddress(effective_index);
}
inline bool BoundsCheckMemRange(uint32_t index, uint32_t* size,
Address* out_address) {
bool ok = base::ClampToBounds(
index, size, static_cast<uint32_t>(instance_object_->memory_size()));
*out_address = EffectiveAddress(index);
return ok;
}
template <typename ctype, typename mtype>
bool ExecuteLoad(Decoder* decoder, InterpreterCode* code, pc_t pc,
int* const len, MachineRepresentation rep,
int prefix_len = 0) {
// Some opcodes have a prefix byte, and MemoryAccessImmediate assumes that
// the memarg is 1 byte from pc. We don't increment pc at the caller,
// because we want to keep pc to the start of the operation to keep trap
// reporting and tracing accurate, otherwise those will report at the middle
// of an opcode.
MemoryAccessImmediate<Decoder::kNoValidate> imm(
decoder, code->at(pc + prefix_len), sizeof(ctype));
uint32_t index = Pop().to<uint32_t>();
Address addr = BoundsCheckMem<mtype>(imm.offset, index);
if (!addr) {
DoTrap(kTrapMemOutOfBounds, pc);
return false;
}
WasmValue result(
converter<ctype, mtype>{}(ReadLittleEndianValue<mtype>(addr)));
Push(result);
*len += imm.length;
if (FLAG_trace_wasm_memory) {
MemoryTracingInfo info(imm.offset + index, false, rep);
TraceMemoryOperation(ExecutionTier::kInterpreter, &info,
code->function->func_index, static_cast<int>(pc),
instance_object_->memory_start());
}
return true;
}
template <typename ctype, typename mtype>
bool ExecuteStore(Decoder* decoder, InterpreterCode* code, pc_t pc,
int* const len, MachineRepresentation rep,
int prefix_len = 0) {
// Some opcodes have a prefix byte, and MemoryAccessImmediate assumes that
// the memarg is 1 byte from pc. We don't increment pc at the caller,
// because we want to keep pc to the start of the operation to keep trap
// reporting and tracing accurate, otherwise those will report at the middle
// of an opcode.
MemoryAccessImmediate<Decoder::kNoValidate> imm(
decoder, code->at(pc + prefix_len), sizeof(ctype));
ctype val = Pop().to<ctype>();
uint32_t index = Pop().to<uint32_t>();
Address addr = BoundsCheckMem<mtype>(imm.offset, index);
if (!addr) {
DoTrap(kTrapMemOutOfBounds, pc);
return false;
}
WriteLittleEndianValue<mtype>(addr, converter<mtype, ctype>{}(val));
*len += imm.length;
if (FLAG_trace_wasm_memory) {
MemoryTracingInfo info(imm.offset + index, true, rep);
TraceMemoryOperation(ExecutionTier::kInterpreter, &info,
code->function->func_index, static_cast<int>(pc),
instance_object_->memory_start());
}
return true;
}
template <typename type, typename op_type>
bool ExtractAtomicOpParams(Decoder* decoder, InterpreterCode* code,
Address* address, pc_t pc, int* const len,
type* val = nullptr, type* val2 = nullptr) {
MemoryAccessImmediate<Decoder::kNoValidate> imm(decoder, code->at(pc + 1),
sizeof(type));
if (val2) *val2 = static_cast<type>(Pop().to<op_type>());
if (val) *val = static_cast<type>(Pop().to<op_type>());
uint32_t index = Pop().to<uint32_t>();
*address = BoundsCheckMem<type>(imm.offset, index);
if (!*address) {
DoTrap(kTrapMemOutOfBounds, pc);
return false;
}
if (!IsAligned(*address, sizeof(type))) {
DoTrap(kTrapUnalignedAccess, pc);
return false;
}
*len += imm.length;
return true;
}
template <typename type>
bool ExtractAtomicWaitNotifyParams(Decoder* decoder, InterpreterCode* code,
pc_t pc, int* const len,
uint32_t* buffer_offset, type* val,
Reland "[wasm] Refactor AtomicWait implementation" Stack parameters in the StubCallDescriptor were set to the wrong type. I changed it now so that for stack parameters that are specified in the CallInterfaceDescriptor, type specified type is used. All other parameters are assumed to be tagged, as it has been until now. Original change's description: > [wasm] Refactor AtomicWait implementation > > The existing implementation included aspects that are not > straight-forward to implement in Liftoff and seemed inefficient: > * Convert the timeout in WebAssembly code from I64 to F64, just to > convert it back in the runtime. > * On 32-bit platforms this conversion needs an additional C-call. > * Split the I64 expected value from I64 into two I32 values in the > wasm-compiler. > * Ideally the int64-lowering takes care of 32-bit specific handling. > > With this CL the timeout and the expected value are passed as I64 to > the runtime (a builtin moves the I64 into a bigint for that). The > int64-lowering takes care of 32-bit platforms. There are special > builtins for 32-bit platforms, but they are written such that ideally > also the int64-lowering could create them. Bug: v8:10108 Change-Id: Ib87b543666708457c0d686208a86e46cdca3f9a2 Reviewed-on: https://chromium-review.googlesource.com/c/v8/v8/+/2080362 Reviewed-by: Jakob Kummerow <jkummerow@chromium.org> Reviewed-by: Tobias Tebbi <tebbi@chromium.org> Commit-Queue: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#66533}
2020-02-28 13:59:12 +00:00
int64_t* timeout = nullptr) {
MemoryAccessImmediate<Decoder::kValidate> imm(decoder, code->at(pc + 1),
sizeof(type));
if (timeout) {
Reland "[wasm] Refactor AtomicWait implementation" Stack parameters in the StubCallDescriptor were set to the wrong type. I changed it now so that for stack parameters that are specified in the CallInterfaceDescriptor, type specified type is used. All other parameters are assumed to be tagged, as it has been until now. Original change's description: > [wasm] Refactor AtomicWait implementation > > The existing implementation included aspects that are not > straight-forward to implement in Liftoff and seemed inefficient: > * Convert the timeout in WebAssembly code from I64 to F64, just to > convert it back in the runtime. > * On 32-bit platforms this conversion needs an additional C-call. > * Split the I64 expected value from I64 into two I32 values in the > wasm-compiler. > * Ideally the int64-lowering takes care of 32-bit specific handling. > > With this CL the timeout and the expected value are passed as I64 to > the runtime (a builtin moves the I64 into a bigint for that). The > int64-lowering takes care of 32-bit platforms. There are special > builtins for 32-bit platforms, but they are written such that ideally > also the int64-lowering could create them. Bug: v8:10108 Change-Id: Ib87b543666708457c0d686208a86e46cdca3f9a2 Reviewed-on: https://chromium-review.googlesource.com/c/v8/v8/+/2080362 Reviewed-by: Jakob Kummerow <jkummerow@chromium.org> Reviewed-by: Tobias Tebbi <tebbi@chromium.org> Commit-Queue: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#66533}
2020-02-28 13:59:12 +00:00
*timeout = Pop().to<int64_t>();
}
*val = Pop().to<type>();
auto index = Pop().to<uint32_t>();
// Check bounds.
Address address = BoundsCheckMem<uint32_t>(imm.offset, index);
*buffer_offset = index + imm.offset;
if (!address) {
DoTrap(kTrapMemOutOfBounds, pc);
return false;
}
// Check alignment.
const uint32_t align_mask = sizeof(type) - 1;
if ((*buffer_offset & align_mask) != 0) {
DoTrap(kTrapUnalignedAccess, pc);
return false;
}
*len += imm.length;
return true;
}
bool ExecuteNumericOp(WasmOpcode opcode, Decoder* decoder,
InterpreterCode* code, pc_t pc, int* const len) {
switch (opcode) {
case kExprI32SConvertSatF32:
Push(WasmValue(ExecuteConvertSaturate<int32_t>(Pop().to<float>())));
return true;
case kExprI32UConvertSatF32:
Push(WasmValue(ExecuteConvertSaturate<uint32_t>(Pop().to<float>())));
return true;
case kExprI32SConvertSatF64:
Push(WasmValue(ExecuteConvertSaturate<int32_t>(Pop().to<double>())));
return true;
case kExprI32UConvertSatF64:
Push(WasmValue(ExecuteConvertSaturate<uint32_t>(Pop().to<double>())));
return true;
case kExprI64SConvertSatF32:
Push(WasmValue(ExecuteI64SConvertSatF32(Pop().to<float>())));
return true;
case kExprI64UConvertSatF32:
Push(WasmValue(ExecuteI64UConvertSatF32(Pop().to<float>())));
return true;
case kExprI64SConvertSatF64:
Push(WasmValue(ExecuteI64SConvertSatF64(Pop().to<double>())));
return true;
case kExprI64UConvertSatF64:
Push(WasmValue(ExecuteI64UConvertSatF64(Pop().to<double>())));
return true;
case kExprMemoryInit: {
MemoryInitImmediate<Decoder::kNoValidate> imm(decoder, code->at(pc));
// The data segment index must be in bounds since it is required by
// validation.
DCHECK_LT(imm.data_segment_index, module()->num_declared_data_segments);
*len += imm.length;
auto size = Pop().to<uint32_t>();
auto src = Pop().to<uint32_t>();
auto dst = Pop().to<uint32_t>();
Address dst_addr;
auto src_max =
instance_object_->data_segment_sizes()[imm.data_segment_index];
if (!BoundsCheckMemRange(dst, &size, &dst_addr) ||
!base::IsInBounds(src, size, src_max)) {
DoTrap(kTrapMemOutOfBounds, pc);
return false;
}
Address src_addr =
instance_object_->data_segment_starts()[imm.data_segment_index] +
src;
std::memmove(reinterpret_cast<void*>(dst_addr),
reinterpret_cast<void*>(src_addr), size);
return true;
}
case kExprDataDrop: {
DataDropImmediate<Decoder::kNoValidate> imm(decoder, code->at(pc));
// The data segment index must be in bounds since it is required by
// validation.
DCHECK_LT(imm.index, module()->num_declared_data_segments);
*len += imm.length;
instance_object_->data_segment_sizes()[imm.index] = 0;
return true;
}
case kExprMemoryCopy: {
MemoryCopyImmediate<Decoder::kNoValidate> imm(decoder, code->at(pc));
*len += imm.length;
auto size = Pop().to<uint32_t>();
auto src = Pop().to<uint32_t>();
auto dst = Pop().to<uint32_t>();
Address dst_addr;
Address src_addr;
if (!BoundsCheckMemRange(dst, &size, &dst_addr) ||
!BoundsCheckMemRange(src, &size, &src_addr)) {
DoTrap(kTrapMemOutOfBounds, pc);
return false;
}
std::memmove(reinterpret_cast<void*>(dst_addr),
reinterpret_cast<void*>(src_addr), size);
return true;
}
case kExprMemoryFill: {
MemoryIndexImmediate<Decoder::kNoValidate> imm(decoder,
code->at(pc + 1));
*len += imm.length;
auto size = Pop().to<uint32_t>();
auto value = Pop().to<uint32_t>();
auto dst = Pop().to<uint32_t>();
Address dst_addr;
bool ok = BoundsCheckMemRange(dst, &size, &dst_addr);
if (!ok) {
DoTrap(kTrapMemOutOfBounds, pc);
return false;
}
std::memset(reinterpret_cast<void*>(dst_addr), value, size);
return true;
}
case kExprTableInit: {
TableInitImmediate<Decoder::kNoValidate> imm(decoder, code->at(pc));
*len += imm.length;
auto size = Pop().to<uint32_t>();
auto src = Pop().to<uint32_t>();
auto dst = Pop().to<uint32_t>();
HandleScope scope(isolate_); // Avoid leaking handles.
bool ok = WasmInstanceObject::InitTableEntries(
instance_object_->GetIsolate(), instance_object_, imm.table.index,
imm.elem_segment_index, dst, src, size);
if (!ok) DoTrap(kTrapTableOutOfBounds, pc);
return ok;
}
case kExprElemDrop: {
ElemDropImmediate<Decoder::kNoValidate> imm(decoder, code->at(pc));
*len += imm.length;
instance_object_->dropped_elem_segments()[imm.index] = 1;
return true;
}
case kExprTableCopy: {
TableCopyImmediate<Decoder::kNoValidate> imm(decoder, code->at(pc));
auto size = Pop().to<uint32_t>();
auto src = Pop().to<uint32_t>();
auto dst = Pop().to<uint32_t>();
HandleScope handle_scope(isolate_); // Avoid leaking handles.
bool ok = WasmInstanceObject::CopyTableEntries(
isolate_, instance_object_, imm.table_dst.index,
imm.table_src.index, dst, src, size);
if (!ok) DoTrap(kTrapTableOutOfBounds, pc);
*len += imm.length;
return ok;
}
case kExprTableGrow: {
TableIndexImmediate<Decoder::kNoValidate> imm(decoder,
code->at(pc + 1));
HandleScope handle_scope(isolate_);
auto table = handle(
WasmTableObject::cast(instance_object_->tables().get(imm.index)),
isolate_);
auto delta = Pop().to<uint32_t>();
auto value = Pop().to_anyref();
int32_t result = WasmTableObject::Grow(isolate_, table, delta, value);
Push(WasmValue(result));
*len += imm.length;
return true;
}
case kExprTableSize: {
TableIndexImmediate<Decoder::kNoValidate> imm(decoder,
code->at(pc + 1));
HandleScope handle_scope(isolate_);
auto table = handle(
WasmTableObject::cast(instance_object_->tables().get(imm.index)),
isolate_);
uint32_t table_size = table->current_length();
Push(WasmValue(table_size));
*len += imm.length;
return true;
}
case kExprTableFill: {
TableIndexImmediate<Decoder::kNoValidate> imm(decoder,
code->at(pc + 1));
HandleScope handle_scope(isolate_);
auto count = Pop().to<uint32_t>();
auto value = Pop().to_anyref();
auto start = Pop().to<uint32_t>();
auto table = handle(
WasmTableObject::cast(instance_object_->tables().get(imm.index)),
isolate_);
uint32_t table_size = table->current_length();
if (start > table_size) {
DoTrap(kTrapTableOutOfBounds, pc);
return false;
}
// Even when table.fill goes out-of-bounds, as many entries as possible
// are put into the table. Only afterwards we trap.
uint32_t fill_count = std::min(count, table_size - start);
if (fill_count < count) {
DoTrap(kTrapTableOutOfBounds, pc);
return false;
}
WasmTableObject::Fill(isolate_, table, start, value, fill_count);
*len += imm.length;
return true;
}
default:
FATAL(
"Unknown or unimplemented opcode #%d:%s", code->start[pc],
WasmOpcodes::OpcodeName(static_cast<WasmOpcode>(code->start[pc])));
UNREACHABLE();
}
return false;
}
template <typename type, typename op_type, typename func>
op_type ExecuteAtomicBinopBE(type val, Address addr, func op) {
type old_val;
type new_val;
old_val = ReadUnalignedValue<type>(addr);
do {
new_val =
ByteReverse(static_cast<type>(op(ByteReverse<type>(old_val), val)));
} while (!(std::atomic_compare_exchange_strong(
reinterpret_cast<std::atomic<type>*>(addr), &old_val, new_val)));
return static_cast<op_type>(ByteReverse<type>(old_val));
}
template <typename type>
type AdjustByteOrder(type param) {
#if V8_TARGET_BIG_ENDIAN
return ByteReverse(param);
#else
return param;
#endif
}
bool ExecuteAtomicOp(WasmOpcode opcode, Decoder* decoder,
InterpreterCode* code, pc_t pc, int* const len) {
#if V8_TARGET_BIG_ENDIAN
constexpr bool kBigEndian = true;
#else
constexpr bool kBigEndian = false;
#endif
WasmValue result;
switch (opcode) {
#define ATOMIC_BINOP_CASE(name, type, op_type, operation, op) \
case kExpr##name: { \
type val; \
Address addr; \
op_type result; \
if (!ExtractAtomicOpParams<type, op_type>(decoder, code, &addr, pc, len, \
&val)) { \
return false; \
} \
static_assert(sizeof(std::atomic<type>) == sizeof(type), \
"Size mismatch for types std::atomic<" #type \
">, and " #type); \
if (kBigEndian) { \
auto oplambda = [](type a, type b) { return a op b; }; \
result = ExecuteAtomicBinopBE<type, op_type>(val, addr, oplambda); \
} else { \
result = static_cast<op_type>( \
std::operation(reinterpret_cast<std::atomic<type>*>(addr), val)); \
} \
Push(WasmValue(result)); \
break; \
}
ATOMIC_BINOP_CASE(I32AtomicAdd, uint32_t, uint32_t, atomic_fetch_add, +);
ATOMIC_BINOP_CASE(I32AtomicAdd8U, uint8_t, uint32_t, atomic_fetch_add, +);
ATOMIC_BINOP_CASE(I32AtomicAdd16U, uint16_t, uint32_t, atomic_fetch_add,
+);
ATOMIC_BINOP_CASE(I32AtomicSub, uint32_t, uint32_t, atomic_fetch_sub, -);
ATOMIC_BINOP_CASE(I32AtomicSub8U, uint8_t, uint32_t, atomic_fetch_sub, -);
ATOMIC_BINOP_CASE(I32AtomicSub16U, uint16_t, uint32_t, atomic_fetch_sub,
-);
ATOMIC_BINOP_CASE(I32AtomicAnd, uint32_t, uint32_t, atomic_fetch_and, &);
ATOMIC_BINOP_CASE(I32AtomicAnd8U, uint8_t, uint32_t, atomic_fetch_and, &);
ATOMIC_BINOP_CASE(I32AtomicAnd16U, uint16_t, uint32_t,
atomic_fetch_and, &);
ATOMIC_BINOP_CASE(I32AtomicOr, uint32_t, uint32_t, atomic_fetch_or, |);
ATOMIC_BINOP_CASE(I32AtomicOr8U, uint8_t, uint32_t, atomic_fetch_or, |);
ATOMIC_BINOP_CASE(I32AtomicOr16U, uint16_t, uint32_t, atomic_fetch_or, |);
ATOMIC_BINOP_CASE(I32AtomicXor, uint32_t, uint32_t, atomic_fetch_xor, ^);
ATOMIC_BINOP_CASE(I32AtomicXor8U, uint8_t, uint32_t, atomic_fetch_xor, ^);
ATOMIC_BINOP_CASE(I32AtomicXor16U, uint16_t, uint32_t, atomic_fetch_xor,
^);
ATOMIC_BINOP_CASE(I32AtomicExchange, uint32_t, uint32_t, atomic_exchange,
=);
ATOMIC_BINOP_CASE(I32AtomicExchange8U, uint8_t, uint32_t, atomic_exchange,
=);
ATOMIC_BINOP_CASE(I32AtomicExchange16U, uint16_t, uint32_t,
atomic_exchange, =);
ATOMIC_BINOP_CASE(I64AtomicAdd, uint64_t, uint64_t, atomic_fetch_add, +);
ATOMIC_BINOP_CASE(I64AtomicAdd8U, uint8_t, uint64_t, atomic_fetch_add, +);
ATOMIC_BINOP_CASE(I64AtomicAdd16U, uint16_t, uint64_t, atomic_fetch_add,
+);
ATOMIC_BINOP_CASE(I64AtomicAdd32U, uint32_t, uint64_t, atomic_fetch_add,
+);
ATOMIC_BINOP_CASE(I64AtomicSub, uint64_t, uint64_t, atomic_fetch_sub, -);
ATOMIC_BINOP_CASE(I64AtomicSub8U, uint8_t, uint64_t, atomic_fetch_sub, -);
ATOMIC_BINOP_CASE(I64AtomicSub16U, uint16_t, uint64_t, atomic_fetch_sub,
-);
ATOMIC_BINOP_CASE(I64AtomicSub32U, uint32_t, uint64_t, atomic_fetch_sub,
-);
ATOMIC_BINOP_CASE(I64AtomicAnd, uint64_t, uint64_t, atomic_fetch_and, &);
ATOMIC_BINOP_CASE(I64AtomicAnd8U, uint8_t, uint64_t, atomic_fetch_and, &);
ATOMIC_BINOP_CASE(I64AtomicAnd16U, uint16_t, uint64_t,
atomic_fetch_and, &);
ATOMIC_BINOP_CASE(I64AtomicAnd32U, uint32_t, uint64_t,
atomic_fetch_and, &);
ATOMIC_BINOP_CASE(I64AtomicOr, uint64_t, uint64_t, atomic_fetch_or, |);
ATOMIC_BINOP_CASE(I64AtomicOr8U, uint8_t, uint64_t, atomic_fetch_or, |);
ATOMIC_BINOP_CASE(I64AtomicOr16U, uint16_t, uint64_t, atomic_fetch_or, |);
ATOMIC_BINOP_CASE(I64AtomicOr32U, uint32_t, uint64_t, atomic_fetch_or, |);
ATOMIC_BINOP_CASE(I64AtomicXor, uint64_t, uint64_t, atomic_fetch_xor, ^);
ATOMIC_BINOP_CASE(I64AtomicXor8U, uint8_t, uint64_t, atomic_fetch_xor, ^);
ATOMIC_BINOP_CASE(I64AtomicXor16U, uint16_t, uint64_t, atomic_fetch_xor,
^);
ATOMIC_BINOP_CASE(I64AtomicXor32U, uint32_t, uint64_t, atomic_fetch_xor,
^);
ATOMIC_BINOP_CASE(I64AtomicExchange, uint64_t, uint64_t, atomic_exchange,
=);
ATOMIC_BINOP_CASE(I64AtomicExchange8U, uint8_t, uint64_t, atomic_exchange,
=);
ATOMIC_BINOP_CASE(I64AtomicExchange16U, uint16_t, uint64_t,
atomic_exchange, =);
ATOMIC_BINOP_CASE(I64AtomicExchange32U, uint32_t, uint64_t,
atomic_exchange, =);
#undef ATOMIC_BINOP_CASE
#define ATOMIC_COMPARE_EXCHANGE_CASE(name, type, op_type) \
case kExpr##name: { \
type old_val; \
type new_val; \
Address addr; \
if (!ExtractAtomicOpParams<type, op_type>(decoder, code, &addr, pc, len, \
&old_val, &new_val)) { \
return false; \
} \
static_assert(sizeof(std::atomic<type>) == sizeof(type), \
"Size mismatch for types std::atomic<" #type \
">, and " #type); \
old_val = AdjustByteOrder<type>(old_val); \
new_val = AdjustByteOrder<type>(new_val); \
std::atomic_compare_exchange_strong( \
reinterpret_cast<std::atomic<type>*>(addr), &old_val, new_val); \
Push(WasmValue(static_cast<op_type>(AdjustByteOrder<type>(old_val)))); \
break; \
}
ATOMIC_COMPARE_EXCHANGE_CASE(I32AtomicCompareExchange, uint32_t,
uint32_t);
ATOMIC_COMPARE_EXCHANGE_CASE(I32AtomicCompareExchange8U, uint8_t,
uint32_t);
ATOMIC_COMPARE_EXCHANGE_CASE(I32AtomicCompareExchange16U, uint16_t,
uint32_t);
ATOMIC_COMPARE_EXCHANGE_CASE(I64AtomicCompareExchange, uint64_t,
uint64_t);
ATOMIC_COMPARE_EXCHANGE_CASE(I64AtomicCompareExchange8U, uint8_t,
uint64_t);
ATOMIC_COMPARE_EXCHANGE_CASE(I64AtomicCompareExchange16U, uint16_t,
uint64_t);
ATOMIC_COMPARE_EXCHANGE_CASE(I64AtomicCompareExchange32U, uint32_t,
uint64_t);
#undef ATOMIC_COMPARE_EXCHANGE_CASE
#define ATOMIC_LOAD_CASE(name, type, op_type, operation) \
case kExpr##name: { \
Address addr; \
if (!ExtractAtomicOpParams<type, op_type>(decoder, code, &addr, pc, \
len)) { \
return false; \
} \
static_assert(sizeof(std::atomic<type>) == sizeof(type), \
"Size mismatch for types std::atomic<" #type \
">, and " #type); \
result = WasmValue(static_cast<op_type>(AdjustByteOrder<type>( \
std::operation(reinterpret_cast<std::atomic<type>*>(addr))))); \
Push(result); \
break; \
}
ATOMIC_LOAD_CASE(I32AtomicLoad, uint32_t, uint32_t, atomic_load);
ATOMIC_LOAD_CASE(I32AtomicLoad8U, uint8_t, uint32_t, atomic_load);
ATOMIC_LOAD_CASE(I32AtomicLoad16U, uint16_t, uint32_t, atomic_load);
ATOMIC_LOAD_CASE(I64AtomicLoad, uint64_t, uint64_t, atomic_load);
ATOMIC_LOAD_CASE(I64AtomicLoad8U, uint8_t, uint64_t, atomic_load);
ATOMIC_LOAD_CASE(I64AtomicLoad16U, uint16_t, uint64_t, atomic_load);
ATOMIC_LOAD_CASE(I64AtomicLoad32U, uint32_t, uint64_t, atomic_load);
#undef ATOMIC_LOAD_CASE
#define ATOMIC_STORE_CASE(name, type, op_type, operation) \
case kExpr##name: { \
type val; \
Address addr; \
if (!ExtractAtomicOpParams<type, op_type>(decoder, code, &addr, pc, len, \
&val)) { \
return false; \
} \
static_assert(sizeof(std::atomic<type>) == sizeof(type), \
"Size mismatch for types std::atomic<" #type \
">, and " #type); \
std::operation(reinterpret_cast<std::atomic<type>*>(addr), \
AdjustByteOrder<type>(val)); \
break; \
}
ATOMIC_STORE_CASE(I32AtomicStore, uint32_t, uint32_t, atomic_store);
ATOMIC_STORE_CASE(I32AtomicStore8U, uint8_t, uint32_t, atomic_store);
ATOMIC_STORE_CASE(I32AtomicStore16U, uint16_t, uint32_t, atomic_store);
ATOMIC_STORE_CASE(I64AtomicStore, uint64_t, uint64_t, atomic_store);
ATOMIC_STORE_CASE(I64AtomicStore8U, uint8_t, uint64_t, atomic_store);
ATOMIC_STORE_CASE(I64AtomicStore16U, uint16_t, uint64_t, atomic_store);
ATOMIC_STORE_CASE(I64AtomicStore32U, uint32_t, uint64_t, atomic_store);
#undef ATOMIC_STORE_CASE
case kExprAtomicFence:
std::atomic_thread_fence(std::memory_order_seq_cst);
*len += 1;
break;
case kExprI32AtomicWait: {
int32_t val;
Reland "[wasm] Refactor AtomicWait implementation" Stack parameters in the StubCallDescriptor were set to the wrong type. I changed it now so that for stack parameters that are specified in the CallInterfaceDescriptor, type specified type is used. All other parameters are assumed to be tagged, as it has been until now. Original change's description: > [wasm] Refactor AtomicWait implementation > > The existing implementation included aspects that are not > straight-forward to implement in Liftoff and seemed inefficient: > * Convert the timeout in WebAssembly code from I64 to F64, just to > convert it back in the runtime. > * On 32-bit platforms this conversion needs an additional C-call. > * Split the I64 expected value from I64 into two I32 values in the > wasm-compiler. > * Ideally the int64-lowering takes care of 32-bit specific handling. > > With this CL the timeout and the expected value are passed as I64 to > the runtime (a builtin moves the I64 into a bigint for that). The > int64-lowering takes care of 32-bit platforms. There are special > builtins for 32-bit platforms, but they are written such that ideally > also the int64-lowering could create them. Bug: v8:10108 Change-Id: Ib87b543666708457c0d686208a86e46cdca3f9a2 Reviewed-on: https://chromium-review.googlesource.com/c/v8/v8/+/2080362 Reviewed-by: Jakob Kummerow <jkummerow@chromium.org> Reviewed-by: Tobias Tebbi <tebbi@chromium.org> Commit-Queue: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#66533}
2020-02-28 13:59:12 +00:00
int64_t timeout;
uint32_t buffer_offset;
if (!ExtractAtomicWaitNotifyParams<int32_t>(
decoder, code, pc, len, &buffer_offset, &val, &timeout)) {
return false;
}
HandleScope handle_scope(isolate_);
Handle<JSArrayBuffer> array_buffer(
instance_object_->memory_object().array_buffer(), isolate_);
Reland "[wasm] Refactor AtomicWait implementation" Stack parameters in the StubCallDescriptor were set to the wrong type. I changed it now so that for stack parameters that are specified in the CallInterfaceDescriptor, type specified type is used. All other parameters are assumed to be tagged, as it has been until now. Original change's description: > [wasm] Refactor AtomicWait implementation > > The existing implementation included aspects that are not > straight-forward to implement in Liftoff and seemed inefficient: > * Convert the timeout in WebAssembly code from I64 to F64, just to > convert it back in the runtime. > * On 32-bit platforms this conversion needs an additional C-call. > * Split the I64 expected value from I64 into two I32 values in the > wasm-compiler. > * Ideally the int64-lowering takes care of 32-bit specific handling. > > With this CL the timeout and the expected value are passed as I64 to > the runtime (a builtin moves the I64 into a bigint for that). The > int64-lowering takes care of 32-bit platforms. There are special > builtins for 32-bit platforms, but they are written such that ideally > also the int64-lowering could create them. Bug: v8:10108 Change-Id: Ib87b543666708457c0d686208a86e46cdca3f9a2 Reviewed-on: https://chromium-review.googlesource.com/c/v8/v8/+/2080362 Reviewed-by: Jakob Kummerow <jkummerow@chromium.org> Reviewed-by: Tobias Tebbi <tebbi@chromium.org> Commit-Queue: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#66533}
2020-02-28 13:59:12 +00:00
auto result = FutexEmulation::WaitWasm32(isolate_, array_buffer,
buffer_offset, val, timeout);
Push(WasmValue(result.ToSmi().value()));
break;
}
case kExprI64AtomicWait: {
int64_t val;
Reland "[wasm] Refactor AtomicWait implementation" Stack parameters in the StubCallDescriptor were set to the wrong type. I changed it now so that for stack parameters that are specified in the CallInterfaceDescriptor, type specified type is used. All other parameters are assumed to be tagged, as it has been until now. Original change's description: > [wasm] Refactor AtomicWait implementation > > The existing implementation included aspects that are not > straight-forward to implement in Liftoff and seemed inefficient: > * Convert the timeout in WebAssembly code from I64 to F64, just to > convert it back in the runtime. > * On 32-bit platforms this conversion needs an additional C-call. > * Split the I64 expected value from I64 into two I32 values in the > wasm-compiler. > * Ideally the int64-lowering takes care of 32-bit specific handling. > > With this CL the timeout and the expected value are passed as I64 to > the runtime (a builtin moves the I64 into a bigint for that). The > int64-lowering takes care of 32-bit platforms. There are special > builtins for 32-bit platforms, but they are written such that ideally > also the int64-lowering could create them. Bug: v8:10108 Change-Id: Ib87b543666708457c0d686208a86e46cdca3f9a2 Reviewed-on: https://chromium-review.googlesource.com/c/v8/v8/+/2080362 Reviewed-by: Jakob Kummerow <jkummerow@chromium.org> Reviewed-by: Tobias Tebbi <tebbi@chromium.org> Commit-Queue: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#66533}
2020-02-28 13:59:12 +00:00
int64_t timeout;
uint32_t buffer_offset;
if (!ExtractAtomicWaitNotifyParams<int64_t>(
decoder, code, pc, len, &buffer_offset, &val, &timeout)) {
return false;
}
HandleScope handle_scope(isolate_);
Handle<JSArrayBuffer> array_buffer(
instance_object_->memory_object().array_buffer(), isolate_);
Reland "[wasm] Refactor AtomicWait implementation" Stack parameters in the StubCallDescriptor were set to the wrong type. I changed it now so that for stack parameters that are specified in the CallInterfaceDescriptor, type specified type is used. All other parameters are assumed to be tagged, as it has been until now. Original change's description: > [wasm] Refactor AtomicWait implementation > > The existing implementation included aspects that are not > straight-forward to implement in Liftoff and seemed inefficient: > * Convert the timeout in WebAssembly code from I64 to F64, just to > convert it back in the runtime. > * On 32-bit platforms this conversion needs an additional C-call. > * Split the I64 expected value from I64 into two I32 values in the > wasm-compiler. > * Ideally the int64-lowering takes care of 32-bit specific handling. > > With this CL the timeout and the expected value are passed as I64 to > the runtime (a builtin moves the I64 into a bigint for that). The > int64-lowering takes care of 32-bit platforms. There are special > builtins for 32-bit platforms, but they are written such that ideally > also the int64-lowering could create them. Bug: v8:10108 Change-Id: Ib87b543666708457c0d686208a86e46cdca3f9a2 Reviewed-on: https://chromium-review.googlesource.com/c/v8/v8/+/2080362 Reviewed-by: Jakob Kummerow <jkummerow@chromium.org> Reviewed-by: Tobias Tebbi <tebbi@chromium.org> Commit-Queue: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#66533}
2020-02-28 13:59:12 +00:00
auto result = FutexEmulation::WaitWasm64(isolate_, array_buffer,
buffer_offset, val, timeout);
Push(WasmValue(result.ToSmi().value()));
break;
}
case kExprAtomicNotify: {
int32_t val;
uint32_t buffer_offset;
if (!ExtractAtomicWaitNotifyParams<int32_t>(decoder, code, pc, len,
&buffer_offset, &val)) {
return false;
}
HandleScope handle_scope(isolate_);
Handle<JSArrayBuffer> array_buffer(
instance_object_->memory_object().array_buffer(), isolate_);
auto result = FutexEmulation::Wake(array_buffer, buffer_offset, val);
Push(WasmValue(result.ToSmi().value()));
break;
}
default:
UNREACHABLE();
return false;
}
return true;
}
bool ExecuteSimdOp(WasmOpcode opcode, Decoder* decoder, InterpreterCode* code,
pc_t pc, int* const len, uint32_t opcode_length) {
switch (opcode) {
#define SPLAT_CASE(format, sType, valType, num) \
case kExpr##format##Splat: { \
WasmValue val = Pop(); \
valType v = val.to<valType>(); \
sType s; \
for (int i = 0; i < num; i++) s.val[i] = v; \
Push(WasmValue(Simd128(s))); \
return true; \
}
SPLAT_CASE(F64x2, float2, double, 2)
SPLAT_CASE(F32x4, float4, float, 4)
SPLAT_CASE(I64x2, int2, int64_t, 2)
SPLAT_CASE(I32x4, int4, int32_t, 4)
SPLAT_CASE(I16x8, int8, int32_t, 8)
SPLAT_CASE(I8x16, int16, int32_t, 16)
#undef SPLAT_CASE
#define EXTRACT_LANE_CASE(format, name) \
case kExpr##format##ExtractLane: { \
SimdLaneImmediate<Decoder::kNoValidate> imm(decoder, code->at(pc), \
opcode_length); \
*len += 1; \
WasmValue val = Pop(); \
Simd128 s = val.to_s128(); \
auto ss = s.to_##name(); \
Push(WasmValue(ss.val[LANE(imm.lane, ss)])); \
return true; \
}
EXTRACT_LANE_CASE(F64x2, f64x2)
EXTRACT_LANE_CASE(F32x4, f32x4)
EXTRACT_LANE_CASE(I64x2, i64x2)
EXTRACT_LANE_CASE(I32x4, i32x4)
#undef EXTRACT_LANE_CASE
// Unsigned extracts require a bit more care. The underlying array in
// Simd128 is signed (see wasm-value.h), so when casted to uint32_t it
// will be signed extended, e.g. int8_t -> int32_t -> uint32_t. So for
// unsigned extracts, we will cast it int8_t -> uint8_t -> uint32_t. We
// add the DCHECK to ensure that if the array type changes, we know to
// change this function.
#define EXTRACT_LANE_EXTEND_CASE(format, name, sign, extended_type) \
case kExpr##format##ExtractLane##sign: { \
SimdLaneImmediate<Decoder::kNoValidate> imm(decoder, code->at(pc), \
opcode_length); \
*len += 1; \
WasmValue val = Pop(); \
Simd128 s = val.to_s128(); \
auto ss = s.to_##name(); \
auto res = ss.val[LANE(imm.lane, ss)]; \
DCHECK(std::is_signed<decltype(res)>::value); \
if (std::is_unsigned<extended_type>::value) { \
using unsigned_type = std::make_unsigned<decltype(res)>::type; \
Push(WasmValue( \
static_cast<extended_type>(static_cast<unsigned_type>(res)))); \
} else { \
Push(WasmValue(static_cast<extended_type>(res))); \
} \
return true; \
}
EXTRACT_LANE_EXTEND_CASE(I16x8, i16x8, S, int32_t)
EXTRACT_LANE_EXTEND_CASE(I16x8, i16x8, U, uint32_t)
EXTRACT_LANE_EXTEND_CASE(I8x16, i8x16, S, int32_t)
EXTRACT_LANE_EXTEND_CASE(I8x16, i8x16, U, uint32_t)
#undef EXTRACT_LANE_EXTEND_CASE
#define BINOP_CASE(op, name, stype, count, expr) \
case kExpr##op: { \
WasmValue v2 = Pop(); \
WasmValue v1 = Pop(); \
stype s1 = v1.to_s128().to_##name(); \
stype s2 = v2.to_s128().to_##name(); \
stype res; \
for (size_t i = 0; i < count; ++i) { \
auto a = s1.val[LANE(i, s1)]; \
auto b = s2.val[LANE(i, s1)]; \
auto result = expr; \
possible_nondeterminism_ |= has_nondeterminism(result); \
res.val[LANE(i, s1)] = expr; \
} \
Push(WasmValue(Simd128(res))); \
return true; \
}
BINOP_CASE(F64x2Add, f64x2, float2, 2, a + b)
BINOP_CASE(F64x2Sub, f64x2, float2, 2, a - b)
BINOP_CASE(F64x2Mul, f64x2, float2, 2, a * b)
BINOP_CASE(F64x2Div, f64x2, float2, 2, base::Divide(a, b))
BINOP_CASE(F64x2Min, f64x2, float2, 2, JSMin(a, b))
BINOP_CASE(F64x2Max, f64x2, float2, 2, JSMax(a, b))
BINOP_CASE(F64x2Pmin, f64x2, float2, 2, std::min(a, b))
BINOP_CASE(F64x2Pmax, f64x2, float2, 2, std::max(a, b))
BINOP_CASE(F32x4Add, f32x4, float4, 4, a + b)
BINOP_CASE(F32x4Sub, f32x4, float4, 4, a - b)
BINOP_CASE(F32x4Mul, f32x4, float4, 4, a * b)
BINOP_CASE(F32x4Div, f32x4, float4, 4, a / b)
BINOP_CASE(F32x4Min, f32x4, float4, 4, JSMin(a, b))
BINOP_CASE(F32x4Max, f32x4, float4, 4, JSMax(a, b))
BINOP_CASE(F32x4Pmin, f32x4, float4, 4, std::min(a, b))
BINOP_CASE(F32x4Pmax, f32x4, float4, 4, std::max(a, b))
BINOP_CASE(I64x2Add, i64x2, int2, 2, base::AddWithWraparound(a, b))
BINOP_CASE(I64x2Sub, i64x2, int2, 2, base::SubWithWraparound(a, b))
BINOP_CASE(I64x2Mul, i64x2, int2, 2, base::MulWithWraparound(a, b))
BINOP_CASE(I64x2MinS, i64x2, int2, 2, a < b ? a : b)
BINOP_CASE(I64x2MinU, i64x2, int2, 2,
static_cast<uint64_t>(a) < static_cast<uint64_t>(b) ? a : b)
BINOP_CASE(I64x2MaxS, i64x2, int2, 2, a > b ? a : b)
BINOP_CASE(I64x2MaxU, i64x2, int2, 2,
static_cast<uint64_t>(a) > static_cast<uint64_t>(b) ? a : b)
BINOP_CASE(I32x4Add, i32x4, int4, 4, base::AddWithWraparound(a, b))
BINOP_CASE(I32x4Sub, i32x4, int4, 4, base::SubWithWraparound(a, b))
BINOP_CASE(I32x4Mul, i32x4, int4, 4, base::MulWithWraparound(a, b))
BINOP_CASE(I32x4MinS, i32x4, int4, 4, a < b ? a : b)
BINOP_CASE(I32x4MinU, i32x4, int4, 4,
static_cast<uint32_t>(a) < static_cast<uint32_t>(b) ? a : b)
BINOP_CASE(I32x4MaxS, i32x4, int4, 4, a > b ? a : b)
BINOP_CASE(I32x4MaxU, i32x4, int4, 4,
static_cast<uint32_t>(a) > static_cast<uint32_t>(b) ? a : b)
BINOP_CASE(S128And, i32x4, int4, 4, a & b)
BINOP_CASE(S128Or, i32x4, int4, 4, a | b)
BINOP_CASE(S128Xor, i32x4, int4, 4, a ^ b)
BINOP_CASE(S128AndNot, i32x4, int4, 4, a & ~b)
BINOP_CASE(I16x8Add, i16x8, int8, 8, base::AddWithWraparound(a, b))
BINOP_CASE(I16x8Sub, i16x8, int8, 8, base::SubWithWraparound(a, b))
BINOP_CASE(I16x8Mul, i16x8, int8, 8, base::MulWithWraparound(a, b))
BINOP_CASE(I16x8MinS, i16x8, int8, 8, a < b ? a : b)
BINOP_CASE(I16x8MinU, i16x8, int8, 8,
static_cast<uint16_t>(a) < static_cast<uint16_t>(b) ? a : b)
BINOP_CASE(I16x8MaxS, i16x8, int8, 8, a > b ? a : b)
BINOP_CASE(I16x8MaxU, i16x8, int8, 8,
static_cast<uint16_t>(a) > static_cast<uint16_t>(b) ? a : b)
BINOP_CASE(I16x8AddSaturateS, i16x8, int8, 8, SaturateAdd<int16_t>(a, b))
BINOP_CASE(I16x8AddSaturateU, i16x8, int8, 8, SaturateAdd<uint16_t>(a, b))
BINOP_CASE(I16x8SubSaturateS, i16x8, int8, 8, SaturateSub<int16_t>(a, b))
BINOP_CASE(I16x8SubSaturateU, i16x8, int8, 8, SaturateSub<uint16_t>(a, b))
BINOP_CASE(I16x8RoundingAverageU, i16x8, int8, 8,
base::RoundingAverageUnsigned<uint16_t>(a, b))
BINOP_CASE(I8x16Add, i8x16, int16, 16, base::AddWithWraparound(a, b))
BINOP_CASE(I8x16Sub, i8x16, int16, 16, base::SubWithWraparound(a, b))
BINOP_CASE(I8x16Mul, i8x16, int16, 16, base::MulWithWraparound(a, b))
BINOP_CASE(I8x16MinS, i8x16, int16, 16, a < b ? a : b)
BINOP_CASE(I8x16MinU, i8x16, int16, 16,
static_cast<uint8_t>(a) < static_cast<uint8_t>(b) ? a : b)
BINOP_CASE(I8x16MaxS, i8x16, int16, 16, a > b ? a : b)
BINOP_CASE(I8x16MaxU, i8x16, int16, 16,
static_cast<uint8_t>(a) > static_cast<uint8_t>(b) ? a : b)
BINOP_CASE(I8x16AddSaturateS, i8x16, int16, 16, SaturateAdd<int8_t>(a, b))
BINOP_CASE(I8x16AddSaturateU, i8x16, int16, 16,
SaturateAdd<uint8_t>(a, b))
BINOP_CASE(I8x16SubSaturateS, i8x16, int16, 16, SaturateSub<int8_t>(a, b))
BINOP_CASE(I8x16SubSaturateU, i8x16, int16, 16,
SaturateSub<uint8_t>(a, b))
BINOP_CASE(I8x16RoundingAverageU, i8x16, int16, 16,
base::RoundingAverageUnsigned<uint8_t>(a, b))
#undef BINOP_CASE
#define UNOP_CASE(op, name, stype, count, expr) \
case kExpr##op: { \
WasmValue v = Pop(); \
stype s = v.to_s128().to_##name(); \
stype res; \
for (size_t i = 0; i < count; ++i) { \
auto a = s.val[i]; \
auto result = expr; \
possible_nondeterminism_ |= has_nondeterminism(result); \
res.val[i] = result; \
} \
Push(WasmValue(Simd128(res))); \
return true; \
}
UNOP_CASE(F64x2Abs, f64x2, float2, 2, std::abs(a))
UNOP_CASE(F64x2Neg, f64x2, float2, 2, -a)
UNOP_CASE(F64x2Sqrt, f64x2, float2, 2, std::sqrt(a))
UNOP_CASE(F32x4Abs, f32x4, float4, 4, std::abs(a))
UNOP_CASE(F32x4Neg, f32x4, float4, 4, -a)
UNOP_CASE(F32x4Sqrt, f32x4, float4, 4, std::sqrt(a))
UNOP_CASE(F32x4RecipApprox, f32x4, float4, 4, base::Recip(a))
UNOP_CASE(F32x4RecipSqrtApprox, f32x4, float4, 4, base::RecipSqrt(a))
UNOP_CASE(F32x4Ceil, f32x4, float4, 4, ceilf(a))
UNOP_CASE(F32x4Floor, f32x4, float4, 4, floorf(a))
UNOP_CASE(F32x4Trunc, f32x4, float4, 4, truncf(a))
UNOP_CASE(F32x4NearestInt, f32x4, float4, 4, nearbyintf(a))
UNOP_CASE(I64x2Neg, i64x2, int2, 2, base::NegateWithWraparound(a))
UNOP_CASE(I32x4Neg, i32x4, int4, 4, base::NegateWithWraparound(a))
UNOP_CASE(I32x4Abs, i32x4, int4, 4, std::abs(a))
UNOP_CASE(S128Not, i32x4, int4, 4, ~a)
UNOP_CASE(I16x8Neg, i16x8, int8, 8, base::NegateWithWraparound(a))
UNOP_CASE(I16x8Abs, i16x8, int8, 8, std::abs(a))
UNOP_CASE(I8x16Neg, i8x16, int16, 16, base::NegateWithWraparound(a))
UNOP_CASE(I8x16Abs, i8x16, int16, 16, std::abs(a))
#undef UNOP_CASE
// Cast to double in call to signbit is due to MSCV issue, see
// https://github.com/microsoft/STL/issues/519.
#define BITMASK_CASE(op, name, stype, count) \
case kExpr##op: { \
WasmValue v = Pop(); \
stype s = v.to_s128().to_##name(); \
int32_t res = 0; \
for (size_t i = 0; i < count; ++i) { \
bool sign = std::signbit(static_cast<double>(s.val[LANE(i, s)])); \
res |= (sign << i); \
} \
Push(WasmValue(res)); \
return true; \
}
BITMASK_CASE(I8x16BitMask, i8x16, int16, 16)
BITMASK_CASE(I16x8BitMask, i16x8, int8, 8)
BITMASK_CASE(I32x4BitMask, i32x4, int4, 4)
#undef BITMASK_CASE
#define CMPOP_CASE(op, name, stype, out_stype, count, expr) \
case kExpr##op: { \
WasmValue v2 = Pop(); \
WasmValue v1 = Pop(); \
stype s1 = v1.to_s128().to_##name(); \
stype s2 = v2.to_s128().to_##name(); \
out_stype res; \
for (size_t i = 0; i < count; ++i) { \
auto a = s1.val[i]; \
auto b = s2.val[i]; \
auto result = expr; \
possible_nondeterminism_ |= has_nondeterminism(result); \
res.val[i] = result ? -1 : 0; \
} \
Push(WasmValue(Simd128(res))); \
return true; \
}
CMPOP_CASE(F64x2Eq, f64x2, float2, int2, 2, a == b)
CMPOP_CASE(F64x2Ne, f64x2, float2, int2, 2, a != b)
CMPOP_CASE(F64x2Gt, f64x2, float2, int2, 2, a > b)
CMPOP_CASE(F64x2Ge, f64x2, float2, int2, 2, a >= b)
CMPOP_CASE(F64x2Lt, f64x2, float2, int2, 2, a < b)
CMPOP_CASE(F64x2Le, f64x2, float2, int2, 2, a <= b)
CMPOP_CASE(F32x4Eq, f32x4, float4, int4, 4, a == b)
CMPOP_CASE(F32x4Ne, f32x4, float4, int4, 4, a != b)
CMPOP_CASE(F32x4Gt, f32x4, float4, int4, 4, a > b)
CMPOP_CASE(F32x4Ge, f32x4, float4, int4, 4, a >= b)
CMPOP_CASE(F32x4Lt, f32x4, float4, int4, 4, a < b)
CMPOP_CASE(F32x4Le, f32x4, float4, int4, 4, a <= b)
CMPOP_CASE(I64x2Eq, i64x2, int2, int2, 2, a == b)
CMPOP_CASE(I64x2Ne, i64x2, int2, int2, 2, a != b)
CMPOP_CASE(I64x2GtS, i64x2, int2, int2, 2, a > b)
CMPOP_CASE(I64x2GeS, i64x2, int2, int2, 2, a >= b)
CMPOP_CASE(I64x2LtS, i64x2, int2, int2, 2, a < b)
CMPOP_CASE(I64x2LeS, i64x2, int2, int2, 2, a <= b)
CMPOP_CASE(I64x2GtU, i64x2, int2, int2, 2,
static_cast<uint64_t>(a) > static_cast<uint64_t>(b))
CMPOP_CASE(I64x2GeU, i64x2, int2, int2, 2,
static_cast<uint64_t>(a) >= static_cast<uint64_t>(b))
CMPOP_CASE(I64x2LtU, i64x2, int2, int2, 2,
static_cast<uint64_t>(a) < static_cast<uint64_t>(b))
CMPOP_CASE(I64x2LeU, i64x2, int2, int2, 2,
static_cast<uint64_t>(a) <= static_cast<uint64_t>(b))
CMPOP_CASE(I32x4Eq, i32x4, int4, int4, 4, a == b)
CMPOP_CASE(I32x4Ne, i32x4, int4, int4, 4, a != b)
CMPOP_CASE(I32x4GtS, i32x4, int4, int4, 4, a > b)
CMPOP_CASE(I32x4GeS, i32x4, int4, int4, 4, a >= b)
CMPOP_CASE(I32x4LtS, i32x4, int4, int4, 4, a < b)
CMPOP_CASE(I32x4LeS, i32x4, int4, int4, 4, a <= b)
CMPOP_CASE(I32x4GtU, i32x4, int4, int4, 4,
static_cast<uint32_t>(a) > static_cast<uint32_t>(b))
CMPOP_CASE(I32x4GeU, i32x4, int4, int4, 4,
static_cast<uint32_t>(a) >= static_cast<uint32_t>(b))
CMPOP_CASE(I32x4LtU, i32x4, int4, int4, 4,
static_cast<uint32_t>(a) < static_cast<uint32_t>(b))
CMPOP_CASE(I32x4LeU, i32x4, int4, int4, 4,
static_cast<uint32_t>(a) <= static_cast<uint32_t>(b))
CMPOP_CASE(I16x8Eq, i16x8, int8, int8, 8, a == b)
CMPOP_CASE(I16x8Ne, i16x8, int8, int8, 8, a != b)
CMPOP_CASE(I16x8GtS, i16x8, int8, int8, 8, a > b)
CMPOP_CASE(I16x8GeS, i16x8, int8, int8, 8, a >= b)
CMPOP_CASE(I16x8LtS, i16x8, int8, int8, 8, a < b)
CMPOP_CASE(I16x8LeS, i16x8, int8, int8, 8, a <= b)
CMPOP_CASE(I16x8GtU, i16x8, int8, int8, 8,
static_cast<uint16_t>(a) > static_cast<uint16_t>(b))
CMPOP_CASE(I16x8GeU, i16x8, int8, int8, 8,
static_cast<uint16_t>(a) >= static_cast<uint16_t>(b))
CMPOP_CASE(I16x8LtU, i16x8, int8, int8, 8,
static_cast<uint16_t>(a) < static_cast<uint16_t>(b))
CMPOP_CASE(I16x8LeU, i16x8, int8, int8, 8,
static_cast<uint16_t>(a) <= static_cast<uint16_t>(b))
CMPOP_CASE(I8x16Eq, i8x16, int16, int16, 16, a == b)
CMPOP_CASE(I8x16Ne, i8x16, int16, int16, 16, a != b)
CMPOP_CASE(I8x16GtS, i8x16, int16, int16, 16, a > b)
CMPOP_CASE(I8x16GeS, i8x16, int16, int16, 16, a >= b)
CMPOP_CASE(I8x16LtS, i8x16, int16, int16, 16, a < b)
CMPOP_CASE(I8x16LeS, i8x16, int16, int16, 16, a <= b)
CMPOP_CASE(I8x16GtU, i8x16, int16, int16, 16,
static_cast<uint8_t>(a) > static_cast<uint8_t>(b))
CMPOP_CASE(I8x16GeU, i8x16, int16, int16, 16,
static_cast<uint8_t>(a) >= static_cast<uint8_t>(b))
CMPOP_CASE(I8x16LtU, i8x16, int16, int16, 16,
static_cast<uint8_t>(a) < static_cast<uint8_t>(b))
CMPOP_CASE(I8x16LeU, i8x16, int16, int16, 16,
static_cast<uint8_t>(a) <= static_cast<uint8_t>(b))
#undef CMPOP_CASE
#define REPLACE_LANE_CASE(format, name, stype, ctype) \
case kExpr##format##ReplaceLane: { \
SimdLaneImmediate<Decoder::kNoValidate> imm(decoder, code->at(pc), \
opcode_length); \
*len += 1; \
WasmValue new_val = Pop(); \
WasmValue simd_val = Pop(); \
stype s = simd_val.to_s128().to_##name(); \
s.val[LANE(imm.lane, s)] = new_val.to<ctype>(); \
Push(WasmValue(Simd128(s))); \
return true; \
}
REPLACE_LANE_CASE(F64x2, f64x2, float2, double)
REPLACE_LANE_CASE(F32x4, f32x4, float4, float)
REPLACE_LANE_CASE(I64x2, i64x2, int2, int64_t)
REPLACE_LANE_CASE(I32x4, i32x4, int4, int32_t)
REPLACE_LANE_CASE(I16x8, i16x8, int8, int32_t)
REPLACE_LANE_CASE(I8x16, i8x16, int16, int32_t)
#undef REPLACE_LANE_CASE
case kExprS128LoadMem:
return ExecuteLoad<Simd128, Simd128>(decoder, code, pc, len,
MachineRepresentation::kSimd128,
/*prefix_len=*/opcode_length);
case kExprS128StoreMem:
return ExecuteStore<Simd128, Simd128>(decoder, code, pc, len,
MachineRepresentation::kSimd128,
/*prefix_len=*/opcode_length);
#define SHIFT_CASE(op, name, stype, count, expr) \
case kExpr##op: { \
uint32_t shift = Pop().to<uint32_t>(); \
WasmValue v = Pop(); \
stype s = v.to_s128().to_##name(); \
stype res; \
for (size_t i = 0; i < count; ++i) { \
auto a = s.val[i]; \
res.val[i] = expr; \
} \
Push(WasmValue(Simd128(res))); \
return true; \
}
SHIFT_CASE(I64x2Shl, i64x2, int2, 2,
static_cast<uint64_t>(a) << (shift % 64))
SHIFT_CASE(I64x2ShrS, i64x2, int2, 2, a >> (shift % 64))
SHIFT_CASE(I64x2ShrU, i64x2, int2, 2,
static_cast<uint64_t>(a) >> (shift % 64))
SHIFT_CASE(I32x4Shl, i32x4, int4, 4,
static_cast<uint32_t>(a) << (shift % 32))
SHIFT_CASE(I32x4ShrS, i32x4, int4, 4, a >> (shift % 32))
SHIFT_CASE(I32x4ShrU, i32x4, int4, 4,
static_cast<uint32_t>(a) >> (shift % 32))
SHIFT_CASE(I16x8Shl, i16x8, int8, 8,
static_cast<uint16_t>(a) << (shift % 16))
SHIFT_CASE(I16x8ShrS, i16x8, int8, 8, a >> (shift % 16))
SHIFT_CASE(I16x8ShrU, i16x8, int8, 8,
static_cast<uint16_t>(a) >> (shift % 16))
SHIFT_CASE(I8x16Shl, i8x16, int16, 16,
static_cast<uint8_t>(a) << (shift % 8))
SHIFT_CASE(I8x16ShrS, i8x16, int16, 16, a >> (shift % 8))
SHIFT_CASE(I8x16ShrU, i8x16, int16, 16,
static_cast<uint8_t>(a) >> (shift % 8))
#undef SHIFT_CASE
#define CONVERT_CASE(op, src_type, name, dst_type, count, start_index, ctype, \
expr) \
case kExpr##op: { \
WasmValue v = Pop(); \
src_type s = v.to_s128().to_##name(); \
dst_type res; \
for (size_t i = 0; i < count; ++i) { \
ctype a = s.val[LANE(start_index + i, s)]; \
auto result = expr; \
possible_nondeterminism_ |= has_nondeterminism(result); \
res.val[LANE(i, res)] = expr; \
} \
Push(WasmValue(Simd128(res))); \
return true; \
}
CONVERT_CASE(F32x4SConvertI32x4, int4, i32x4, float4, 4, 0, int32_t,
static_cast<float>(a))
CONVERT_CASE(F32x4UConvertI32x4, int4, i32x4, float4, 4, 0, uint32_t,
static_cast<float>(a))
CONVERT_CASE(I32x4SConvertF32x4, float4, f32x4, int4, 4, 0, double,
std::isnan(a) ? 0
: a<kMinInt ? kMinInt : a> kMaxInt
? kMaxInt
: static_cast<int32_t>(a))
CONVERT_CASE(I32x4UConvertF32x4, float4, f32x4, int4, 4, 0, double,
std::isnan(a)
? 0
: a<0 ? 0 : a> kMaxUInt32 ? kMaxUInt32
: static_cast<uint32_t>(a))
CONVERT_CASE(I32x4SConvertI16x8High, int8, i16x8, int4, 4, 4, int16_t,
a)
CONVERT_CASE(I32x4UConvertI16x8High, int8, i16x8, int4, 4, 4, uint16_t,
a)
CONVERT_CASE(I32x4SConvertI16x8Low, int8, i16x8, int4, 4, 0, int16_t, a)
CONVERT_CASE(I32x4UConvertI16x8Low, int8, i16x8, int4, 4, 0, uint16_t,
a)
CONVERT_CASE(I16x8SConvertI8x16High, int16, i8x16, int8, 8, 8, int8_t,
a)
CONVERT_CASE(I16x8UConvertI8x16High, int16, i8x16, int8, 8, 8, uint8_t,
a)
CONVERT_CASE(I16x8SConvertI8x16Low, int16, i8x16, int8, 8, 0, int8_t, a)
CONVERT_CASE(I16x8UConvertI8x16Low, int16, i8x16, int8, 8, 0, uint8_t,
a)
#undef CONVERT_CASE
#define PACK_CASE(op, src_type, name, dst_type, count, ctype, dst_ctype) \
case kExpr##op: { \
WasmValue v2 = Pop(); \
WasmValue v1 = Pop(); \
src_type s1 = v1.to_s128().to_##name(); \
src_type s2 = v2.to_s128().to_##name(); \
dst_type res; \
int64_t min = std::numeric_limits<ctype>::min(); \
int64_t max = std::numeric_limits<ctype>::max(); \
for (size_t i = 0; i < count; ++i) { \
int64_t v = i < count / 2 ? s1.val[LANE(i, s1)] \
: s2.val[LANE(i - count / 2, s2)]; \
res.val[LANE(i, res)] = \
static_cast<dst_ctype>(std::max(min, std::min(max, v))); \
} \
Push(WasmValue(Simd128(res))); \
return true; \
}
PACK_CASE(I16x8SConvertI32x4, int4, i32x4, int8, 8, int16_t, int16_t)
PACK_CASE(I16x8UConvertI32x4, int4, i32x4, int8, 8, uint16_t, int16_t)
PACK_CASE(I8x16SConvertI16x8, int8, i16x8, int16, 16, int8_t, int8_t)
PACK_CASE(I8x16UConvertI16x8, int8, i16x8, int16, 16, uint8_t, int8_t)
#undef PACK_CASE
case kExprS128Select: {
int4 bool_val = Pop().to_s128().to_i32x4();
int4 v2 = Pop().to_s128().to_i32x4();
int4 v1 = Pop().to_s128().to_i32x4();
int4 res;
for (size_t i = 0; i < 4; ++i) {
res.val[i] = v2.val[i] ^ ((v1.val[i] ^ v2.val[i]) & bool_val.val[i]);
}
Push(WasmValue(Simd128(res)));
return true;
}
#define ADD_HORIZ_CASE(op, name, stype, count) \
case kExpr##op: { \
WasmValue v2 = Pop(); \
WasmValue v1 = Pop(); \
stype s1 = v1.to_s128().to_##name(); \
stype s2 = v2.to_s128().to_##name(); \
stype res; \
for (size_t i = 0; i < count / 2; ++i) { \
auto result1 = s1.val[LANE(i * 2, s1)] + s1.val[LANE(i * 2 + 1, s1)]; \
possible_nondeterminism_ |= has_nondeterminism(result1); \
res.val[LANE(i, s1)] = result1; \
auto result2 = s2.val[LANE(i * 2, s1)] + s2.val[LANE(i * 2 + 1, s1)]; \
possible_nondeterminism_ |= has_nondeterminism(result2); \
res.val[LANE(i + count / 2, s1)] = result2; \
} \
Push(WasmValue(Simd128(res))); \
return true; \
}
ADD_HORIZ_CASE(I32x4AddHoriz, i32x4, int4, 4)
ADD_HORIZ_CASE(F32x4AddHoriz, f32x4, float4, 4)
ADD_HORIZ_CASE(I16x8AddHoriz, i16x8, int8, 8)
#undef ADD_HORIZ_CASE
case kExprS8x16Swizzle: {
int16 v2 = Pop().to_s128().to_i8x16();
int16 v1 = Pop().to_s128().to_i8x16();
int16 res;
for (size_t i = 0; i < kSimd128Size; ++i) {
int lane = v2.val[LANE(i, v1)];
res.val[LANE(i, v1)] =
lane < kSimd128Size && lane >= 0 ? v1.val[LANE(lane, v1)] : 0;
}
Push(WasmValue(Simd128(res)));
return true;
}
case kExprS8x16Shuffle: {
Simd8x16ShuffleImmediate<Decoder::kNoValidate> imm(
decoder, code->at(pc), opcode_length);
*len += 16;
int16 v2 = Pop().to_s128().to_i8x16();
int16 v1 = Pop().to_s128().to_i8x16();
int16 res;
for (size_t i = 0; i < kSimd128Size; ++i) {
int lane = imm.shuffle[i];
res.val[LANE(i, v1)] = lane < kSimd128Size
? v1.val[LANE(lane, v1)]
: v2.val[LANE(lane - kSimd128Size, v1)];
}
Push(WasmValue(Simd128(res)));
return true;
}
case kExprV64x2AnyTrue:
case kExprV32x4AnyTrue:
case kExprV16x8AnyTrue:
case kExprV8x16AnyTrue: {
int4 s = Pop().to_s128().to_i32x4();
bool res = s.val[0] | s.val[1] | s.val[2] | s.val[3];
Push(WasmValue((res)));
return true;
}
#define REDUCTION_CASE(op, name, stype, count, operation) \
case kExpr##op: { \
stype s = Pop().to_s128().to_##name(); \
bool res = true; \
for (size_t i = 0; i < count; ++i) { \
res = res & static_cast<bool>(s.val[i]); \
} \
Push(WasmValue(res)); \
return true; \
}
REDUCTION_CASE(V64x2AllTrue, i64x2, int2, 2, &)
REDUCTION_CASE(V32x4AllTrue, i32x4, int4, 4, &)
REDUCTION_CASE(V16x8AllTrue, i16x8, int8, 8, &)
REDUCTION_CASE(V8x16AllTrue, i8x16, int16, 16, &)
#undef REDUCTION_CASE
#define QFM_CASE(op, name, stype, count, operation) \
case kExpr##op: { \
stype c = Pop().to_s128().to_##name(); \
stype b = Pop().to_s128().to_##name(); \
stype a = Pop().to_s128().to_##name(); \
stype res; \
for (size_t i = 0; i < count; i++) { \
res.val[i] = a.val[i] operation(b.val[i] * c.val[i]); \
} \
Push(WasmValue(Simd128(res))); \
return true; \
}
QFM_CASE(F32x4Qfma, f32x4, float4, 4, +)
QFM_CASE(F32x4Qfms, f32x4, float4, 4, -)
QFM_CASE(F64x2Qfma, f64x2, float2, 2, +)
QFM_CASE(F64x2Qfms, f64x2, float2, 2, -)
#undef QFM_CASE
case kExprS8x16LoadSplat: {
return DoSimdLoadSplat<int16, int32_t, int8_t>(
decoder, code, pc, len, MachineRepresentation::kWord8);
}
case kExprS16x8LoadSplat: {
return DoSimdLoadSplat<int8, int32_t, int16_t>(
decoder, code, pc, len, MachineRepresentation::kWord16);
}
case kExprS32x4LoadSplat: {
return DoSimdLoadSplat<int4, int32_t, int32_t>(
decoder, code, pc, len, MachineRepresentation::kWord32);
}
case kExprS64x2LoadSplat: {
return DoSimdLoadSplat<int2, int64_t, int64_t>(
decoder, code, pc, len, MachineRepresentation::kWord64);
}
case kExprI16x8Load8x8S: {
return DoSimdLoadExtend<int8, int16_t, int8_t>(
decoder, code, pc, len, MachineRepresentation::kWord64);
}
case kExprI16x8Load8x8U: {
return DoSimdLoadExtend<int8, uint16_t, uint8_t>(
decoder, code, pc, len, MachineRepresentation::kWord64);
}
case kExprI32x4Load16x4S: {
return DoSimdLoadExtend<int4, int32_t, int16_t>(
decoder, code, pc, len, MachineRepresentation::kWord64);
}
case kExprI32x4Load16x4U: {
return DoSimdLoadExtend<int4, uint32_t, uint16_t>(
decoder, code, pc, len, MachineRepresentation::kWord64);
}
case kExprI64x2Load32x2S: {
return DoSimdLoadExtend<int2, int64_t, int32_t>(
decoder, code, pc, len, MachineRepresentation::kWord64);
}
case kExprI64x2Load32x2U: {
return DoSimdLoadExtend<int2, uint64_t, uint32_t>(
decoder, code, pc, len, MachineRepresentation::kWord64);
}
default:
return false;
}
}
template <typename s_type, typename result_type, typename load_type>
bool DoSimdLoadSplat(Decoder* decoder, InterpreterCode* code, pc_t pc,
int* const len, MachineRepresentation rep) {
// len is the number of bytes the make up this op, including prefix byte, so
// the prefix_len for ExecuteLoad is len, minus the prefix byte itself.
// Think of prefix_len as: number of extra bytes that make up this op.
if (!ExecuteLoad<result_type, load_type>(decoder, code, pc, len, rep,
/*prefix_len=*/*len - 1)) {
return false;
}
result_type v = Pop().to<result_type>();
s_type s;
for (size_t i = 0; i < arraysize(s.val); i++) s.val[LANE(i, s)] = v;
Push(WasmValue(Simd128(s)));
return true;
}
template <typename s_type, typename wide_type, typename narrow_type>
bool DoSimdLoadExtend(Decoder* decoder, InterpreterCode* code, pc_t pc,
int* const len, MachineRepresentation rep) {
static_assert(sizeof(wide_type) == sizeof(narrow_type) * 2,
"size mismatch for wide and narrow types");
if (!ExecuteLoad<uint64_t, uint64_t>(decoder, code, pc, len, rep,
/*prefix_len=*/*len - 1)) {
return false;
}
constexpr int lanes = kSimd128Size / sizeof(wide_type);
uint64_t v = Pop().to_u64();
s_type s;
for (int i = 0; i < lanes; i++) {
uint8_t shift = i * (sizeof(narrow_type) * 8);
narrow_type el = static_cast<narrow_type>(v >> shift);
s.val[LANE(i, s)] = static_cast<wide_type>(el);
}
Push(WasmValue(Simd128(s)));
return true;
}
// Check if our control stack (frames_) exceeds the limit. Trigger stack
// overflow if it does, and unwinding the current frame.
// Returns true if execution can continue, false if the current activation was
// fully unwound.
// Do call this function immediately *after* pushing a new frame. The pc of
// the top frame will be reset to 0 if the stack check fails.
bool DoStackCheck() V8_WARN_UNUSED_RESULT {
// The goal of this stack check is not to prevent actual stack overflows,
// but to simulate stack overflows during the execution of compiled code.
// That is why this function uses FLAG_stack_size, even though the value
// stack actually lies in zone memory.
const size_t stack_size_limit = FLAG_stack_size * KB;
// Sum up the value stack size and the control stack size.
const size_t current_stack_size = (sp_ - stack_.get()) * sizeof(*sp_) +
frames_.size() * sizeof(frames_[0]);
if (V8_LIKELY(current_stack_size <= stack_size_limit)) {
return true;
}
// The pc of the top frame is initialized to the first instruction. We reset
// it to 0 here such that we report the same position as in compiled code.
frames_.back().pc = 0;
isolate_->StackOverflow();
return HandleException(isolate_) == WasmInterpreter::Thread::HANDLED;
}
void EncodeI32ExceptionValue(Handle<FixedArray> encoded_values,
uint32_t* encoded_index, uint32_t value) {
encoded_values->set((*encoded_index)++, Smi::FromInt(value >> 16));
encoded_values->set((*encoded_index)++, Smi::FromInt(value & 0xffff));
}
void EncodeI64ExceptionValue(Handle<FixedArray> encoded_values,
uint32_t* encoded_index, uint64_t value) {
EncodeI32ExceptionValue(encoded_values, encoded_index,
static_cast<uint32_t>(value >> 32));
EncodeI32ExceptionValue(encoded_values, encoded_index,
static_cast<uint32_t>(value));
}
// Allocate, initialize and throw a new exception. The exception values are
// being popped off the operand stack. Returns true if the exception is being
// handled locally by the interpreter, false otherwise (interpreter exits).
bool DoThrowException(const WasmException* exception,
uint32_t index) V8_WARN_UNUSED_RESULT {
HandleScope handle_scope(isolate_); // Avoid leaking handles.
Handle<WasmExceptionTag> exception_tag(
WasmExceptionTag::cast(instance_object_->exceptions_table().get(index)),
isolate_);
uint32_t encoded_size = WasmExceptionPackage::GetEncodedSize(exception);
Handle<WasmExceptionPackage> exception_object =
WasmExceptionPackage::New(isolate_, exception_tag, encoded_size);
Handle<FixedArray> encoded_values = Handle<FixedArray>::cast(
WasmExceptionPackage::GetExceptionValues(isolate_, exception_object));
// Encode the exception values on the operand stack into the exception
// package allocated above. This encoding has to be in sync with other
// backends so that exceptions can be passed between them.
const WasmExceptionSig* sig = exception->sig;
uint32_t encoded_index = 0;
sp_t base_index = StackHeight() - sig->parameter_count();
for (size_t i = 0; i < sig->parameter_count(); ++i) {
WasmValue value = GetStackValue(base_index + i);
switch (sig->GetParam(i).kind()) {
case ValueType::kI32: {
uint32_t u32 = value.to_u32();
EncodeI32ExceptionValue(encoded_values, &encoded_index, u32);
break;
}
case ValueType::kF32: {
uint32_t f32 = value.to_f32_boxed().get_bits();
EncodeI32ExceptionValue(encoded_values, &encoded_index, f32);
break;
}
case ValueType::kI64: {
uint64_t u64 = value.to_u64();
EncodeI64ExceptionValue(encoded_values, &encoded_index, u64);
break;
}
case ValueType::kF64: {
uint64_t f64 = value.to_f64_boxed().get_bits();
EncodeI64ExceptionValue(encoded_values, &encoded_index, f64);
break;
}
case ValueType::kS128: {
int4 s128 = value.to_s128().to_i32x4();
EncodeI32ExceptionValue(encoded_values, &encoded_index, s128.val[0]);
EncodeI32ExceptionValue(encoded_values, &encoded_index, s128.val[1]);
EncodeI32ExceptionValue(encoded_values, &encoded_index, s128.val[2]);
EncodeI32ExceptionValue(encoded_values, &encoded_index, s128.val[3]);
break;
}
case ValueType::kAnyRef:
case ValueType::kFuncRef:
case ValueType::kNullRef:
case ValueType::kExnRef: {
Handle<Object> anyref = value.to_anyref();
DCHECK_IMPLIES(sig->GetParam(i) == kWasmNullRef, anyref->IsNull());
encoded_values->set(encoded_index++, *anyref);
break;
}
case ValueType::kRef:
case ValueType::kOptRef:
case ValueType::kEqRef:
// TODO(7748): Implement these.
UNIMPLEMENTED();
case ValueType::kI8:
case ValueType::kI16:
case ValueType::kStmt:
case ValueType::kBottom:
UNREACHABLE();
}
}
DCHECK_EQ(encoded_size, encoded_index);
Drop(static_cast<int>(sig->parameter_count()));
// Now that the exception is ready, set it as pending.
isolate_->Throw(*exception_object);
return HandleException(isolate_) == WasmInterpreter::Thread::HANDLED;
}
// Throw a given existing exception. Returns true if the exception is being
// handled locally by the interpreter, false otherwise (interpreter exits).
bool DoRethrowException(WasmValue exception) {
isolate_->ReThrow(*exception.to_anyref());
return HandleException(isolate_) == WasmInterpreter::Thread::HANDLED;
}
// Determines whether the given exception has a tag matching the expected tag
// for the given index within the exception table of the current instance.
bool MatchingExceptionTag(Handle<Object> exception_object, uint32_t index) {
if (!exception_object->IsWasmExceptionPackage(isolate_)) return false;
Handle<Object> caught_tag = WasmExceptionPackage::GetExceptionTag(
isolate_, Handle<WasmExceptionPackage>::cast(exception_object));
Handle<Object> expected_tag =
handle(instance_object_->exceptions_table().get(index), isolate_);
DCHECK(expected_tag->IsWasmExceptionTag());
return expected_tag.is_identical_to(caught_tag);
}
void DecodeI32ExceptionValue(Handle<FixedArray> encoded_values,
uint32_t* encoded_index, uint32_t* value) {
uint32_t msb = Smi::cast(encoded_values->get((*encoded_index)++)).value();
uint32_t lsb = Smi::cast(encoded_values->get((*encoded_index)++)).value();
*value = (msb << 16) | (lsb & 0xffff);
}
void DecodeI64ExceptionValue(Handle<FixedArray> encoded_values,
uint32_t* encoded_index, uint64_t* value) {
uint32_t lsb = 0, msb = 0;
DecodeI32ExceptionValue(encoded_values, encoded_index, &msb);
DecodeI32ExceptionValue(encoded_values, encoded_index, &lsb);
*value = (static_cast<uint64_t>(msb) << 32) | static_cast<uint64_t>(lsb);
}
// Unpack the values encoded in the given exception. The exception values are
// pushed onto the operand stack. Callers must perform a tag check to ensure
// the encoded values match the expected signature of the exception.
void DoUnpackException(const WasmException* exception,
Handle<Object> exception_object) {
Handle<FixedArray> encoded_values =
Handle<FixedArray>::cast(WasmExceptionPackage::GetExceptionValues(
isolate_, Handle<WasmExceptionPackage>::cast(exception_object)));
// Decode the exception values from the given exception package and push
// them onto the operand stack. This encoding has to be in sync with other
// backends so that exceptions can be passed between them.
const WasmExceptionSig* sig = exception->sig;
uint32_t encoded_index = 0;
for (size_t i = 0; i < sig->parameter_count(); ++i) {
WasmValue value;
switch (sig->GetParam(i).kind()) {
case ValueType::kI32: {
uint32_t u32 = 0;
DecodeI32ExceptionValue(encoded_values, &encoded_index, &u32);
value = WasmValue(u32);
break;
}
case ValueType::kF32: {
uint32_t f32_bits = 0;
DecodeI32ExceptionValue(encoded_values, &encoded_index, &f32_bits);
value = WasmValue(Float32::FromBits(f32_bits));
break;
}
case ValueType::kI64: {
uint64_t u64 = 0;
DecodeI64ExceptionValue(encoded_values, &encoded_index, &u64);
value = WasmValue(u64);
break;
}
case ValueType::kF64: {
uint64_t f64_bits = 0;
DecodeI64ExceptionValue(encoded_values, &encoded_index, &f64_bits);
value = WasmValue(Float64::FromBits(f64_bits));
break;
}
case ValueType::kS128: {
int4 s128 = {0, 0, 0, 0};
uint32_t* vals = reinterpret_cast<uint32_t*>(s128.val);
DecodeI32ExceptionValue(encoded_values, &encoded_index, &vals[0]);
DecodeI32ExceptionValue(encoded_values, &encoded_index, &vals[1]);
DecodeI32ExceptionValue(encoded_values, &encoded_index, &vals[2]);
DecodeI32ExceptionValue(encoded_values, &encoded_index, &vals[3]);
value = WasmValue(Simd128(s128));
break;
}
case ValueType::kAnyRef:
case ValueType::kFuncRef:
case ValueType::kNullRef:
case ValueType::kExnRef: {
Handle<Object> anyref(encoded_values->get(encoded_index++), isolate_);
DCHECK_IMPLIES(sig->GetParam(i) == kWasmNullRef, anyref->IsNull());
value = WasmValue(anyref);
break;
}
case ValueType::kRef:
case ValueType::kOptRef:
case ValueType::kEqRef:
// TODO(7748): Implement these.
UNIMPLEMENTED();
case ValueType::kI8:
case ValueType::kI16:
case ValueType::kStmt:
case ValueType::kBottom:
UNREACHABLE();
}
Push(value);
}
DCHECK_EQ(WasmExceptionPackage::GetEncodedSize(exception), encoded_index);
}
void Execute(InterpreterCode* code, pc_t pc, int max) {
DCHECK_NOT_NULL(code->side_table);
DCHECK(!frames_.empty());
// There must be enough space on the stack to hold the arguments, locals,
// and the value stack.
DCHECK_LE(code->function->sig->parameter_count() +
code->locals.type_list.size() +
code->side_table->max_stack_height_,
stack_limit_ - stack_.get() - frames_.back().sp);
// Seal the surrounding {HandleScope} to ensure that all cases within the
// interpreter switch below which deal with handles open their own scope.
// This avoids leaking / accumulating handles in the surrounding scope.
SealHandleScope shs(isolate_);
Decoder decoder(code->start, code->end);
pc_t limit = code->end - code->start;
while (true) {
DCHECK_GT(limit, pc);
DCHECK_NOT_NULL(code->start);
int len = 1;
// We need to store this, because SIMD opcodes are LEB encoded, and later
// on when executing, we need to know where to read immediates from.
uint32_t simd_opcode_length = 0;
byte orig = code->start[pc];
WasmOpcode opcode = static_cast<WasmOpcode>(orig);
if (WasmOpcodes::IsPrefixOpcode(opcode)) {
opcode = decoder.read_prefixed_opcode<Decoder::kNoValidate>(
&code->start[pc], &simd_opcode_length);
len += simd_opcode_length;
}
// If max is 0, break. If max is positive (a limit is set), decrement it.
if (max >= 0 && WasmOpcodes::IsBreakable(opcode)) {
if (max == 0) break;
--max;
}
TRACE("@%-3zu: %-24s:", pc, WasmOpcodes::OpcodeName(opcode));
TraceValueStack();
TRACE("\n");
#ifdef DEBUG
// Compute the stack effect of this opcode, and verify later that the
// stack was modified accordingly.
std::pair<uint32_t, uint32_t> stack_effect =
StackEffect(codemap_->module(), frames_.back().code->function->sig,
code->start + pc, code->end);
sp_t expected_new_stack_height =
StackHeight() - stack_effect.first + stack_effect.second;
#endif
switch (orig) {
case kExprNop:
break;
case kExprBlock:
case kExprLoop:
case kExprTry: {
BlockTypeImmediate<Decoder::kNoValidate> imm(WasmFeatures::All(),
&decoder, code->at(pc));
len = 1 + imm.length;
break;
}
case kExprIf: {
BlockTypeImmediate<Decoder::kNoValidate> imm(WasmFeatures::All(),
&decoder, code->at(pc));
WasmValue cond = Pop();
bool is_true = cond.to<uint32_t>() != 0;
if (is_true) {
// fall through to the true block.
len = 1 + imm.length;
TRACE(" true => fallthrough\n");
} else {
len = LookupTargetDelta(code, pc);
TRACE(" false => @%zu\n", pc + len);
}
break;
}
case kExprElse:
case kExprCatch: {
len = LookupTargetDelta(code, pc);
TRACE(" end => @%zu\n", pc + len);
break;
}
case kExprThrow: {
ExceptionIndexImmediate<Decoder::kNoValidate> imm(&decoder,
code->at(pc));
CommitPc(pc); // Needed for local unwinding.
const WasmException* exception = &module()->exceptions[imm.index];
if (!DoThrowException(exception, imm.index)) return;
ReloadFromFrameOnException(&decoder, &code, &pc, &limit);
continue; // Do not bump pc.
}
case kExprRethrow: {
HandleScope handle_scope(isolate_); // Avoid leaking handles.
WasmValue ex = Pop();
if (ex.to_anyref()->IsNull()) return DoTrap(kTrapRethrowNullRef, pc);
CommitPc(pc); // Needed for local unwinding.
if (!DoRethrowException(ex)) return;
ReloadFromFrameOnException(&decoder, &code, &pc, &limit);
continue; // Do not bump pc.
}
case kExprBrOnExn: {
BranchOnExceptionImmediate<Decoder::kNoValidate> imm(&decoder,
code->at(pc));
HandleScope handle_scope(isolate_); // Avoid leaking handles.
WasmValue ex = Pop();
Handle<Object> exception = ex.to_anyref();
if (exception->IsNull()) return DoTrap(kTrapBrOnExnNullRef, pc);
if (MatchingExceptionTag(exception, imm.index.index)) {
imm.index.exception = &module()->exceptions[imm.index.index];
DoUnpackException(imm.index.exception, exception);
len = DoBreak(code, pc, imm.depth.depth);
TRACE(" match => @%zu\n", pc + len);
} else {
Push(ex); // Exception remains on stack.
TRACE(" false => fallthrough\n");
len = 1 + imm.length;
}
break;
}
case kExprSelectWithType: {
SelectTypeImmediate<Decoder::kNoValidate> imm(WasmFeatures::All(),
&decoder, code->at(pc));
len = 1 + imm.length;
V8_FALLTHROUGH;
}
case kExprSelect: {
HandleScope scope(isolate_); // Avoid leaking handles.
WasmValue cond = Pop();
WasmValue fval = Pop();
WasmValue tval = Pop();
Push(cond.to<int32_t>() != 0 ? tval : fval);
break;
}
case kExprBr: {
BranchDepthImmediate<Decoder::kNoValidate> imm(&decoder,
code->at(pc));
len = DoBreak(code, pc, imm.depth);
TRACE(" br => @%zu\n", pc + len);
break;
}
case kExprBrIf: {
BranchDepthImmediate<Decoder::kNoValidate> imm(&decoder,
code->at(pc));
WasmValue cond = Pop();
bool is_true = cond.to<uint32_t>() != 0;
if (is_true) {
len = DoBreak(code, pc, imm.depth);
TRACE(" br_if => @%zu\n", pc + len);
} else {
TRACE(" false => fallthrough\n");
len = 1 + imm.length;
}
break;
}
case kExprBrTable: {
BranchTableImmediate<Decoder::kNoValidate> imm(&decoder,
code->at(pc));
BranchTableIterator<Decoder::kNoValidate> iterator(&decoder, imm);
uint32_t key = Pop().to<uint32_t>();
uint32_t depth = 0;
if (key >= imm.table_count) key = imm.table_count;
for (uint32_t i = 0; i <= key; i++) {
DCHECK(iterator.has_next());
depth = iterator.next();
}
len = key + DoBreak(code, pc + key, static_cast<size_t>(depth));
TRACE(" br[%u] => @%zu\n", key, pc + key + len);
break;
}
case kExprReturn: {
size_t arity = code->function->sig->return_count();
if (!DoReturn(&decoder, &code, &pc, &limit, arity)) return;
continue; // Do not bump pc.
}
case kExprUnreachable: {
return DoTrap(kTrapUnreachable, pc);
}
case kExprEnd: {
break;
}
case kExprI32Const: {
ImmI32Immediate<Decoder::kNoValidate> imm(&decoder, code->at(pc));
Push(WasmValue(imm.value));
len = 1 + imm.length;
break;
}
case kExprI64Const: {
ImmI64Immediate<Decoder::kNoValidate> imm(&decoder, code->at(pc));
Push(WasmValue(imm.value));
len = 1 + imm.length;
break;
}
case kExprF32Const: {
ImmF32Immediate<Decoder::kNoValidate> imm(&decoder, code->at(pc));
Push(WasmValue(imm.value));
len = 1 + imm.length;
break;
}
case kExprF64Const: {
ImmF64Immediate<Decoder::kNoValidate> imm(&decoder, code->at(pc));
Push(WasmValue(imm.value));
len = 1 + imm.length;
break;
}
case kExprRefNull: {
Push(WasmValue(isolate_->factory()->null_value()));
break;
}
case kExprRefFunc: {
FunctionIndexImmediate<Decoder::kNoValidate> imm(&decoder,
code->at(pc));
HandleScope handle_scope(isolate_); // Avoid leaking handles.
Handle<WasmExternalFunction> function =
WasmInstanceObject::GetOrCreateWasmExternalFunction(
isolate_, instance_object_, imm.index);
Push(WasmValue(function));
len = 1 + imm.length;
break;
}
case kExprLocalGet: {
LocalIndexImmediate<Decoder::kNoValidate> imm(&decoder, code->at(pc));
HandleScope handle_scope(isolate_); // Avoid leaking handles.
Push(GetStackValue(frames_.back().sp + imm.index));
len = 1 + imm.length;
break;
}
case kExprLocalSet: {
LocalIndexImmediate<Decoder::kNoValidate> imm(&decoder, code->at(pc));
HandleScope handle_scope(isolate_); // Avoid leaking handles.
WasmValue val = Pop();
SetStackValue(frames_.back().sp + imm.index, val);
len = 1 + imm.length;
break;
}
case kExprLocalTee: {
LocalIndexImmediate<Decoder::kNoValidate> imm(&decoder, code->at(pc));
HandleScope handle_scope(isolate_); // Avoid leaking handles.
WasmValue val = Pop();
SetStackValue(frames_.back().sp + imm.index, val);
Push(val);
len = 1 + imm.length;
break;
}
case kExprDrop: {
Drop();
break;
}
case kExprCallFunction: {
CallFunctionImmediate<Decoder::kNoValidate> imm(&decoder,
code->at(pc));
InterpreterCode* target = codemap()->GetCode(imm.index);
CHECK(!target->function->imported);
2017-03-23 09:46:16 +00:00
// Execute an internal call.
if (!DoCall(&decoder, target, &pc, &limit)) return;
code = target;
continue; // Do not bump pc.
2017-03-23 09:46:16 +00:00
} break;
case kExprCallIndirect: {
CallIndirectImmediate<Decoder::kNoValidate> imm(
WasmFeatures::All(), &decoder, code->at(pc));
uint32_t entry_index = Pop().to<uint32_t>();
CommitPc(pc); // TODO(wasm): Be more disciplined about committing PC.
CallResult result =
CallIndirectFunction(imm.table_index, entry_index, imm.sig_index);
2017-03-23 09:46:16 +00:00
switch (result.type) {
case CallResult::INTERNAL:
2017-03-23 09:46:16 +00:00
// The import is a function of this instance. Call it directly.
if (!DoCall(&decoder, result.interpreter_code, &pc, &limit))
return;
2017-03-23 09:46:16 +00:00
code = result.interpreter_code;
continue; // Do not bump pc.
case CallResult::INVALID_FUNC:
2017-03-23 09:46:16 +00:00
return DoTrap(kTrapFuncInvalid, pc);
case CallResult::SIGNATURE_MISMATCH:
return DoTrap(kTrapFuncSigMismatch, pc);
}
2017-03-23 09:46:16 +00:00
} break;
case kExprReturnCall: {
CallFunctionImmediate<Decoder::kNoValidate> imm(&decoder,
code->at(pc));
InterpreterCode* target = codemap()->GetCode(imm.index);
CHECK(!target->function->imported);
// Enter internal found function.
if (!DoReturnCall(&decoder, target, &pc, &limit)) return;
code = target;
continue; // Do not bump pc.
} break;
case kExprReturnCallIndirect: {
CallIndirectImmediate<Decoder::kNoValidate> imm(
WasmFeatures::All(), &decoder, code->at(pc));
uint32_t entry_index = Pop().to<uint32_t>();
CommitPc(pc); // TODO(wasm): Be more disciplined about committing PC.
// TODO(wasm): Calling functions needs some refactoring to avoid
// multi-exit code like this.
CallResult result =
CallIndirectFunction(imm.table_index, entry_index, imm.sig_index);
switch (result.type) {
case CallResult::INTERNAL: {
InterpreterCode* target = result.interpreter_code;
DCHECK(!target->function->imported);
// The function belongs to this instance. Enter it directly.
if (!DoReturnCall(&decoder, target, &pc, &limit)) return;
code = result.interpreter_code;
continue; // Do not bump pc.
}
case CallResult::INVALID_FUNC:
return DoTrap(kTrapFuncInvalid, pc);
case CallResult::SIGNATURE_MISMATCH:
return DoTrap(kTrapFuncSigMismatch, pc);
}
} break;
case kExprGlobalGet: {
GlobalIndexImmediate<Decoder::kNoValidate> imm(&decoder,
code->at(pc));
HandleScope handle_scope(isolate_);
Push(WasmInstanceObject::GetGlobalValue(
instance_object_, module()->globals[imm.index]));
len = 1 + imm.length;
break;
}
case kExprGlobalSet: {
GlobalIndexImmediate<Decoder::kNoValidate> imm(&decoder,
code->at(pc));
auto& global = module()->globals[imm.index];
switch (global.type.kind()) {
#define CASE_TYPE(valuetype, ctype) \
case ValueType::valuetype: { \
uint8_t* ptr = \
WasmInstanceObject::GetGlobalStorage(instance_object_, global); \
WriteLittleEndianValue<ctype>(reinterpret_cast<Address>(ptr), \
Pop().to<ctype>()); \
break; \
}
FOREACH_WASMVALUE_CTYPES(CASE_TYPE)
#undef CASE_TYPE
case ValueType::kAnyRef:
case ValueType::kFuncRef:
case ValueType::kNullRef:
case ValueType::kExnRef:
case ValueType::kRef:
case ValueType::kOptRef:
case ValueType::kEqRef: {
// TODO(7748): Type checks or DCHECKs for ref types?
HandleScope handle_scope(isolate_); // Avoid leaking handles.
Handle<FixedArray> global_buffer; // The buffer of the global.
uint32_t global_index; // The index into the buffer.
std::tie(global_buffer, global_index) =
WasmInstanceObject::GetGlobalBufferAndIndex(instance_object_,
global);
Handle<Object> ref = Pop().to_anyref();
DCHECK_IMPLIES(global.type == kWasmNullRef, ref->IsNull());
global_buffer->set(global_index, *ref);
break;
}
case ValueType::kI8:
case ValueType::kI16:
case ValueType::kStmt:
case ValueType::kBottom:
UNREACHABLE();
}
len = 1 + imm.length;
break;
}
case kExprTableGet: {
TableIndexImmediate<Decoder::kNoValidate> imm(&decoder, code->at(pc));
HandleScope handle_scope(isolate_);
auto table = handle(
WasmTableObject::cast(instance_object_->tables().get(imm.index)),
isolate_);
uint32_t table_size = table->current_length();
uint32_t entry_index = Pop().to<uint32_t>();
if (entry_index >= table_size) {
return DoTrap(kTrapTableOutOfBounds, pc);
}
Handle<Object> value =
WasmTableObject::Get(isolate_, table, entry_index);
Push(WasmValue(value));
len = 1 + imm.length;
break;
}
case kExprTableSet: {
TableIndexImmediate<Decoder::kNoValidate> imm(&decoder, code->at(pc));
HandleScope handle_scope(isolate_);
auto table = handle(
WasmTableObject::cast(instance_object_->tables().get(imm.index)),
isolate_);
uint32_t table_size = table->current_length();
Handle<Object> value = Pop().to_anyref();
uint32_t entry_index = Pop().to<uint32_t>();
if (entry_index >= table_size) {
return DoTrap(kTrapTableOutOfBounds, pc);
}
WasmTableObject::Set(isolate_, table, entry_index, value);
len = 1 + imm.length;
break;
}
#define LOAD_CASE(name, ctype, mtype, rep) \
case kExpr##name: { \
if (!ExecuteLoad<ctype, mtype>(&decoder, code, pc, &len, \
MachineRepresentation::rep)) \
return; \
break; \
}
LOAD_CASE(I32LoadMem8S, int32_t, int8_t, kWord8);
LOAD_CASE(I32LoadMem8U, int32_t, uint8_t, kWord8);
LOAD_CASE(I32LoadMem16S, int32_t, int16_t, kWord16);
LOAD_CASE(I32LoadMem16U, int32_t, uint16_t, kWord16);
LOAD_CASE(I64LoadMem8S, int64_t, int8_t, kWord8);
LOAD_CASE(I64LoadMem8U, int64_t, uint8_t, kWord16);
LOAD_CASE(I64LoadMem16S, int64_t, int16_t, kWord16);
LOAD_CASE(I64LoadMem16U, int64_t, uint16_t, kWord16);
LOAD_CASE(I64LoadMem32S, int64_t, int32_t, kWord32);
LOAD_CASE(I64LoadMem32U, int64_t, uint32_t, kWord32);
LOAD_CASE(I32LoadMem, int32_t, int32_t, kWord32);
LOAD_CASE(I64LoadMem, int64_t, int64_t, kWord64);
LOAD_CASE(F32LoadMem, Float32, uint32_t, kFloat32);
LOAD_CASE(F64LoadMem, Float64, uint64_t, kFloat64);
#undef LOAD_CASE
#define STORE_CASE(name, ctype, mtype, rep) \
case kExpr##name: { \
if (!ExecuteStore<ctype, mtype>(&decoder, code, pc, &len, \
MachineRepresentation::rep)) \
return; \
break; \
}
STORE_CASE(I32StoreMem8, int32_t, int8_t, kWord8);
STORE_CASE(I32StoreMem16, int32_t, int16_t, kWord16);
STORE_CASE(I64StoreMem8, int64_t, int8_t, kWord8);
STORE_CASE(I64StoreMem16, int64_t, int16_t, kWord16);
STORE_CASE(I64StoreMem32, int64_t, int32_t, kWord32);
STORE_CASE(I32StoreMem, int32_t, int32_t, kWord32);
STORE_CASE(I64StoreMem, int64_t, int64_t, kWord64);
STORE_CASE(F32StoreMem, Float32, uint32_t, kFloat32);
STORE_CASE(F64StoreMem, Float64, uint64_t, kFloat64);
#undef STORE_CASE
#define ASMJS_LOAD_CASE(name, ctype, mtype, defval) \
case kExpr##name: { \
uint32_t index = Pop().to<uint32_t>(); \
ctype result; \
Address addr = BoundsCheckMem<mtype>(0, index); \
if (!addr) { \
result = defval; \
} else { \
/* TODO(titzer): alignment for asmjs load mem? */ \
result = static_cast<ctype>(*reinterpret_cast<mtype*>(addr)); \
} \
Push(WasmValue(result)); \
break; \
}
ASMJS_LOAD_CASE(I32AsmjsLoadMem8S, int32_t, int8_t, 0);
ASMJS_LOAD_CASE(I32AsmjsLoadMem8U, int32_t, uint8_t, 0);
ASMJS_LOAD_CASE(I32AsmjsLoadMem16S, int32_t, int16_t, 0);
ASMJS_LOAD_CASE(I32AsmjsLoadMem16U, int32_t, uint16_t, 0);
ASMJS_LOAD_CASE(I32AsmjsLoadMem, int32_t, int32_t, 0);
ASMJS_LOAD_CASE(F32AsmjsLoadMem, float, float,
std::numeric_limits<float>::quiet_NaN());
ASMJS_LOAD_CASE(F64AsmjsLoadMem, double, double,
std::numeric_limits<double>::quiet_NaN());
#undef ASMJS_LOAD_CASE
#define ASMJS_STORE_CASE(name, ctype, mtype) \
case kExpr##name: { \
WasmValue val = Pop(); \
uint32_t index = Pop().to<uint32_t>(); \
Address addr = BoundsCheckMem<mtype>(0, index); \
if (addr) { \
*(reinterpret_cast<mtype*>(addr)) = static_cast<mtype>(val.to<ctype>()); \
} \
Push(val); \
break; \
}
ASMJS_STORE_CASE(I32AsmjsStoreMem8, int32_t, int8_t);
ASMJS_STORE_CASE(I32AsmjsStoreMem16, int32_t, int16_t);
ASMJS_STORE_CASE(I32AsmjsStoreMem, int32_t, int32_t);
ASMJS_STORE_CASE(F32AsmjsStoreMem, float, float);
ASMJS_STORE_CASE(F64AsmjsStoreMem, double, double);
#undef ASMJS_STORE_CASE
case kExprMemoryGrow: {
MemoryIndexImmediate<Decoder::kNoValidate> imm(&decoder,
code->at(pc));
uint32_t delta_pages = Pop().to<uint32_t>();
HandleScope handle_scope(isolate_); // Avoid leaking handles.
Handle<WasmMemoryObject> memory(instance_object_->memory_object(),
isolate_);
int32_t result =
WasmMemoryObject::Grow(isolate_, memory, delta_pages);
Push(WasmValue(result));
len = 1 + imm.length;
// Treat one grow_memory instruction like 1000 other instructions,
// because it is a really expensive operation.
if (max > 0) max = std::max(0, max - 1000);
break;
}
case kExprMemorySize: {
MemoryIndexImmediate<Decoder::kNoValidate> imm(&decoder,
code->at(pc));
Push(WasmValue(static_cast<uint32_t>(instance_object_->memory_size() /
kWasmPageSize)));
len = 1 + imm.length;
break;
}
// We need to treat kExprI32ReinterpretF32 and kExprI64ReinterpretF64
// specially to guarantee that the quiet bit of a NaN is preserved on
// ia32 by the reinterpret casts.
case kExprI32ReinterpretF32: {
WasmValue val = Pop();
Push(WasmValue(ExecuteI32ReinterpretF32(val)));
break;
}
case kExprI64ReinterpretF64: {
WasmValue val = Pop();
Push(WasmValue(ExecuteI64ReinterpretF64(val)));
break;
}
#define SIGN_EXTENSION_CASE(name, wtype, ntype) \
case kExpr##name: { \
ntype val = static_cast<ntype>(Pop().to<wtype>()); \
Push(WasmValue(static_cast<wtype>(val))); \
break; \
}
SIGN_EXTENSION_CASE(I32SExtendI8, int32_t, int8_t);
SIGN_EXTENSION_CASE(I32SExtendI16, int32_t, int16_t);
SIGN_EXTENSION_CASE(I64SExtendI8, int64_t, int8_t);
SIGN_EXTENSION_CASE(I64SExtendI16, int64_t, int16_t);
SIGN_EXTENSION_CASE(I64SExtendI32, int64_t, int32_t);
#undef SIGN_EXTENSION_CASE
case kExprRefIsNull: {
HandleScope handle_scope(isolate_); // Avoid leaking handles.
uint32_t result = Pop().to_anyref()->IsNull() ? 1 : 0;
Push(WasmValue(result));
break;
}
case kNumericPrefix: {
if (!ExecuteNumericOp(opcode, &decoder, code, pc, &len)) return;
break;
}
case kAtomicPrefix: {
if (!ExecuteAtomicOp(opcode, &decoder, code, pc, &len)) return;
break;
}
case kSimdPrefix: {
if (!ExecuteSimdOp(opcode, &decoder, code, pc, &len,
simd_opcode_length))
return;
break;
}
#define EXECUTE_SIMPLE_BINOP(name, ctype, op) \
case kExpr##name: { \
WasmValue rval = Pop(); \
WasmValue lval = Pop(); \
auto result = lval.to<ctype>() op rval.to<ctype>(); \
possible_nondeterminism_ |= has_nondeterminism(result); \
Push(WasmValue(result)); \
break; \
}
FOREACH_SIMPLE_BINOP(EXECUTE_SIMPLE_BINOP)
#undef EXECUTE_SIMPLE_BINOP
#define EXECUTE_OTHER_BINOP(name, ctype) \
case kExpr##name: { \
TrapReason trap = kTrapCount; \
ctype rval = Pop().to<ctype>(); \
ctype lval = Pop().to<ctype>(); \
auto result = Execute##name(lval, rval, &trap); \
possible_nondeterminism_ |= has_nondeterminism(result); \
if (trap != kTrapCount) return DoTrap(trap, pc); \
Push(WasmValue(result)); \
break; \
}
FOREACH_OTHER_BINOP(EXECUTE_OTHER_BINOP)
#undef EXECUTE_OTHER_BINOP
#define EXECUTE_UNOP(name, ctype, exec_fn) \
case kExpr##name: { \
TrapReason trap = kTrapCount; \
ctype val = Pop().to<ctype>(); \
auto result = exec_fn(val, &trap); \
possible_nondeterminism_ |= has_nondeterminism(result); \
if (trap != kTrapCount) return DoTrap(trap, pc); \
Push(WasmValue(result)); \
break; \
}
#define EXECUTE_OTHER_UNOP(name, ctype) EXECUTE_UNOP(name, ctype, Execute##name)
FOREACH_OTHER_UNOP(EXECUTE_OTHER_UNOP)
#undef EXECUTE_OTHER_UNOP
#define EXECUTE_I32CONV_FLOATOP(name, out_type, in_type) \
EXECUTE_UNOP(name, in_type, ExecuteConvert<out_type>)
FOREACH_I32CONV_FLOATOP(EXECUTE_I32CONV_FLOATOP)
#undef EXECUTE_I32CONV_FLOATOP
#undef EXECUTE_UNOP
default:
FATAL("Unknown or unimplemented opcode #%d:%s", code->start[pc],
WasmOpcodes::OpcodeName(
static_cast<WasmOpcode>(code->start[pc])));
UNREACHABLE();
}
#ifdef DEBUG
if (!WasmOpcodes::IsControlOpcode(opcode)) {
DCHECK_EQ(expected_new_stack_height, StackHeight());
}
#endif
pc += len;
if (pc == limit) {
// Fell off end of code; do an implicit return.
TRACE("@%-3zu: ImplicitReturn\n", pc);
size_t arity = code->function->sig->return_count();
DCHECK_EQ(StackHeight() - arity, frames_.back().llimit());
if (!DoReturn(&decoder, &code, &pc, &limit, arity)) return;
}
}
state_ = WasmInterpreter::PAUSED;
CommitPc(pc);
}
WasmValue Pop() {
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DCHECK_GT(frames_.size(), 0);
DCHECK_GT(StackHeight(), frames_.back().llimit()); // can't pop into locals
StackValue stack_value = *--sp_;
// Note that {StackHeight} depends on the current {sp} value, hence this
// operation is split into two statements to ensure proper evaluation order.
WasmValue val = stack_value.ExtractValue(this, StackHeight());
stack_value.ClearValue(this, StackHeight());
return val;
}
void Drop(int n = 1) {
DCHECK_GE(StackHeight(), n);
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DCHECK_GT(frames_.size(), 0);
// Check that we don't pop into locals.
DCHECK_GE(StackHeight() - n, frames_.back().llimit());
StackValue::ClearValues(this, StackHeight() - n, n);
sp_ -= n;
}
WasmValue PopArity(size_t arity) {
if (arity == 0) return WasmValue();
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CHECK_EQ(1, arity);
return Pop();
}
void Push(WasmValue val) {
DCHECK_NE(kWasmStmt, val.type());
DCHECK_LE(1, stack_limit_ - sp_);
DCHECK(StackValue::IsClearedValue(this, StackHeight()));
StackValue stack_value(val, this, StackHeight());
// Note that {StackHeight} depends on the current {sp} value, hence this
// operation is split into two statements to ensure proper evaluation order.
*sp_++ = stack_value;
}
void Push(WasmValue* vals, size_t arity) {
DCHECK_LE(arity, stack_limit_ - sp_);
for (WasmValue *val = vals, *end = vals + arity; val != end; ++val) {
DCHECK_NE(kWasmStmt, val->type());
Push(*val);
}
}
void ResetStack(sp_t new_height) {
DCHECK_LE(new_height, StackHeight()); // Only allowed to shrink.
int count = static_cast<int>(StackHeight() - new_height);
StackValue::ClearValues(this, new_height, count);
sp_ = stack_.get() + new_height;
}
void EnsureStackSpace(size_t size) {
if (V8_LIKELY(static_cast<size_t>(stack_limit_ - sp_) >= size)) return;
size_t old_size = stack_limit_ - stack_.get();
size_t requested_size =
base::bits::RoundUpToPowerOfTwo64((sp_ - stack_.get()) + size);
size_t new_size = Max(size_t{8}, Max(2 * old_size, requested_size));
std::unique_ptr<StackValue[]> new_stack(new StackValue[new_size]);
if (old_size > 0) {
memcpy(new_stack.get(), stack_.get(), old_size * sizeof(*sp_));
}
sp_ = new_stack.get() + (sp_ - stack_.get());
stack_ = std::move(new_stack);
stack_limit_ = stack_.get() + new_size;
// Also resize the reference stack to the same size.
int grow_by = static_cast<int>(new_size - old_size);
HandleScope handle_scope(isolate_); // Avoid leaking handles.
Handle<FixedArray> old_ref_stack(reference_stack(), isolate_);
Handle<FixedArray> new_ref_stack =
isolate_->factory()->CopyFixedArrayAndGrow(old_ref_stack, grow_by);
new_ref_stack->FillWithHoles(static_cast<int>(old_size),
static_cast<int>(new_size));
reference_stack_cell_->set_value(*new_ref_stack);
}
sp_t StackHeight() { return sp_ - stack_.get(); }
void TraceValueStack() {
#ifdef DEBUG
if (!FLAG_trace_wasm_interpreter) return;
HandleScope handle_scope(isolate_); // Avoid leaking handles.
Frame* top = frames_.size() > 0 ? &frames_.back() : nullptr;
sp_t sp = top ? top->sp : 0;
sp_t plimit = top ? top->plimit() : 0;
sp_t llimit = top ? top->llimit() : 0;
for (size_t i = sp; i < StackHeight(); ++i) {
if (i < plimit) {
PrintF(" p%zu:", i);
} else if (i < llimit) {
PrintF(" l%zu:", i);
} else {
PrintF(" s%zu:", i);
}
WasmValue val = GetStackValue(i);
switch (val.type().kind()) {
case ValueType::kI32:
PrintF("i32:%d", val.to<int32_t>());
break;
case ValueType::kI64:
PrintF("i64:%" PRId64 "", val.to<int64_t>());
break;
case ValueType::kF32:
PrintF("f32:%f", val.to<float>());
break;
case ValueType::kF64:
PrintF("f64:%lf", val.to<double>());
break;
case ValueType::kS128: {
// This defaults to tracing all S128 values as i32x4 values for now,
// when there is more state to know what type of values are on the
// stack, the right format should be printed here.
int4 s = val.to_s128().to_i32x4();
PrintF("i32x4:%d,%d,%d,%d", s.val[0], s.val[1], s.val[2], s.val[3]);
break;
}
case ValueType::kAnyRef: {
Handle<Object> ref = val.to_anyref();
if (ref->IsNull()) {
PrintF("ref:null");
} else {
PrintF("ref:0x%" V8PRIxPTR, ref->ptr());
}
break;
}
case ValueType::kStmt:
PrintF("void");
break;
case ValueType::kFuncRef:
case ValueType::kExnRef:
case ValueType::kNullRef:
case ValueType::kRef:
case ValueType::kOptRef:
case ValueType::kEqRef:
PrintF("(func|null|exn|opt|eq|)ref:unimplemented");
break;
case ValueType::kI8:
case ValueType::kI16:
case ValueType::kBottom:
UNREACHABLE();
break;
}
}
#endif // DEBUG
}
static WasmCode* GetTargetCode(Isolate* isolate, Address target) {
WasmCodeManager* code_manager = isolate->wasm_engine()->code_manager();
NativeModule* native_module = code_manager->LookupNativeModule(target);
WasmCode* code = native_module->Lookup(target);
if (code->kind() == WasmCode::kJumpTable) {
uint32_t func_index =
native_module->GetFunctionIndexFromJumpTableSlot(target);
if (!native_module->HasCode(func_index)) {
bool success = CompileLazy(isolate, native_module, func_index);
if (!success) {
DCHECK(isolate->has_pending_exception());
return nullptr;
}
}
return native_module->GetCode(func_index);
}
DCHECK_EQ(code->instruction_start(), target);
return code;
}
CallResult CallIndirectFunction(uint32_t table_index, uint32_t entry_index,
uint32_t sig_index) {
HandleScope handle_scope(isolate_); // Avoid leaking handles.
uint32_t expected_sig_id = module()->signature_ids[sig_index];
DCHECK_EQ(expected_sig_id,
module()->signature_map.Find(*module()->signature(sig_index)));
// Bounds check against table size.
if (entry_index >=
static_cast<uint32_t>(WasmInstanceObject::IndirectFunctionTableSize(
isolate_, instance_object_, table_index))) {
return {CallResult::INVALID_FUNC};
}
IndirectFunctionTableEntry entry(instance_object_, table_index,
entry_index);
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// Signature check.
if (entry.sig_id() != static_cast<int32_t>(expected_sig_id)) {
return {CallResult::SIGNATURE_MISMATCH};
2018-06-19 09:47:17 +00:00
}
Revert "[wasm] Introduce jump table" This reverts commit 733b7c8258872dbbb44222831694c5f6b69424ab. Reason for revert: breaks arm64 gc-stress: https://ci.chromium.org/buildbot/client.v8.ports/V8%20Linux%20-%20arm64%20-%20sim%20-%20gc%20stress/11659 Original change's description: > [wasm] Introduce jump table > > This introduces the concept of a jump table for WebAssembly, which is > used for every direct and indirect call to any WebAssembly function. > For lazy compilation, it will initially contain code to call the > WasmCompileLazy builtin, where it passes the function index to be > called. > For non-lazy-compilation, it will contain a jump to the actual code. > The jump table allows to easily redirect functions for lazy > compilation, tier-up, debugging and (in the future) code aging. After > this CL, we will not need to patch existing code any more for any of > these operations. > > R=​mstarzinger@chromium.org, titzer@chromium.org > > Bug: v8:7758 > Change-Id: I45f9983c2b06ae81bf5ce9847f4542fb48844a4f > Reviewed-on: https://chromium-review.googlesource.com/1097075 > Commit-Queue: Clemens Hammacher <clemensh@chromium.org> > Reviewed-by: Ben Titzer <titzer@chromium.org> > Cr-Commit-Position: refs/heads/master@{#53805} TBR=mstarzinger@chromium.org,titzer@chromium.org,clemensh@chromium.org,sreten.kovacevic@mips.com Change-Id: Iea358db2cf13656a65cf69a6d82cbbc10d3e7e1c No-Presubmit: true No-Tree-Checks: true No-Try: true Bug: v8:7758 Reviewed-on: https://chromium-review.googlesource.com/1105157 Reviewed-by: Clemens Hammacher <clemensh@chromium.org> Commit-Queue: Clemens Hammacher <clemensh@chromium.org> Cr-Commit-Position: refs/heads/master@{#53807}
2018-06-18 20:37:10 +00:00
Handle<Object> object_ref = handle(entry.object_ref(), isolate_);
WasmCode* code = GetTargetCode(isolate_, entry.target());
CHECK_NOT_NULL(code);
// Check that this is an internal call (within the same instance).
CHECK(object_ref->IsWasmInstanceObject() &&
instance_object_.is_identical_to(object_ref));
DCHECK_EQ(WasmCode::kFunction, code->kind());
return {CallResult::INTERNAL, codemap()->GetCode(code->index())};
}
inline Activation current_activation() {
return activations_.empty() ? Activation(0, 0) : activations_.back();
}
};
namespace {
// Converters between WasmInterpreter::Thread and WasmInterpreter::ThreadImpl.
// Thread* is the public interface, without knowledge of the object layout.
// This cast is potentially risky, but as long as we always cast it back before
// accessing any data, it should be fine. UBSan is not complaining.
WasmInterpreter::Thread* ToThread(ThreadImpl* impl) {
return reinterpret_cast<WasmInterpreter::Thread*>(impl);
}
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ThreadImpl* ToImpl(WasmInterpreter::Thread* thread) {
return reinterpret_cast<ThreadImpl*>(thread);
}
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} // namespace
//============================================================================
// Implementation of the pimpl idiom for WasmInterpreter::Thread.
// Instead of placing a pointer to the ThreadImpl inside of the Thread object,
// we just reinterpret_cast them. ThreadImpls are only allocated inside this
// translation unit anyway.
//============================================================================
WasmInterpreter::State WasmInterpreter::Thread::state() {
ThreadImpl* impl = ToImpl(this);
ThreadImpl::ReferenceStackScope stack_scope(impl);
return impl->state();
}
void WasmInterpreter::Thread::InitFrame(const WasmFunction* function,
WasmValue* args) {
ThreadImpl* impl = ToImpl(this);
ThreadImpl::ReferenceStackScope stack_scope(impl);
impl->InitFrame(function, args);
}
WasmInterpreter::State WasmInterpreter::Thread::Run(int num_steps) {
ThreadImpl* impl = ToImpl(this);
ThreadImpl::ReferenceStackScope stack_scope(impl);
return impl->Run(num_steps);
}
void WasmInterpreter::Thread::Pause() { return ToImpl(this)->Pause(); }
void WasmInterpreter::Thread::Reset() {
ThreadImpl* impl = ToImpl(this);
ThreadImpl::ReferenceStackScope stack_scope(impl);
return impl->Reset();
}
WasmInterpreter::Thread::ExceptionHandlingResult
WasmInterpreter::Thread::RaiseException(Isolate* isolate,
Handle<Object> exception) {
ThreadImpl* impl = ToImpl(this);
ThreadImpl::ReferenceStackScope stack_scope(impl);
return impl->RaiseException(isolate, exception);
}
int WasmInterpreter::Thread::GetFrameCount() {
return ToImpl(this)->GetFrameCount();
}
WasmValue WasmInterpreter::Thread::GetReturnValue(int index) {
ThreadImpl* impl = ToImpl(this);
ThreadImpl::ReferenceStackScope stack_scope(impl);
return impl->GetReturnValue(index);
}
TrapReason WasmInterpreter::Thread::GetTrapReason() {
return ToImpl(this)->GetTrapReason();
}
bool WasmInterpreter::Thread::PossibleNondeterminism() {
return ToImpl(this)->PossibleNondeterminism();
}
uint64_t WasmInterpreter::Thread::NumInterpretedCalls() {
return ToImpl(this)->NumInterpretedCalls();
}
uint32_t WasmInterpreter::Thread::NumActivations() {
return ToImpl(this)->NumActivations();
}
uint32_t WasmInterpreter::Thread::StartActivation() {
ThreadImpl* impl = ToImpl(this);
ThreadImpl::ReferenceStackScope stack_scope(impl);
return impl->StartActivation();
}
void WasmInterpreter::Thread::FinishActivation(uint32_t id) {
ThreadImpl* impl = ToImpl(this);
ThreadImpl::ReferenceStackScope stack_scope(impl);
impl->FinishActivation(id);
}
uint32_t WasmInterpreter::Thread::ActivationFrameBase(uint32_t id) {
ThreadImpl* impl = ToImpl(this);
ThreadImpl::ReferenceStackScope stack_scope(impl);
return impl->ActivationFrameBase(id);
}
//============================================================================
// The implementation details of the interpreter.
//============================================================================
class WasmInterpreterInternals {
public:
// Create a copy of the module bytes for the interpreter, since the passed
// pointer might be invalidated after constructing the interpreter.
const ZoneVector<uint8_t> module_bytes_;
CodeMap codemap_;
std::vector<ThreadImpl> threads_;
WasmInterpreterInternals(Zone* zone, const WasmModule* module,
const ModuleWireBytes& wire_bytes,
Handle<WasmInstanceObject> instance_object)
: module_bytes_(wire_bytes.start(), wire_bytes.end(), zone),
codemap_(module, module_bytes_.data(), zone) {
threads_.emplace_back(zone, &codemap_, instance_object);
}
};
namespace {
void NopFinalizer(const v8::WeakCallbackInfo<void>& data) {
Address* global_handle_location =
reinterpret_cast<Address*>(data.GetParameter());
GlobalHandles::Destroy(global_handle_location);
}
Handle<WasmInstanceObject> MakeWeak(
Isolate* isolate, Handle<WasmInstanceObject> instance_object) {
Handle<WasmInstanceObject> weak_instance =
isolate->global_handles()->Create<WasmInstanceObject>(*instance_object);
Address* global_handle_location = weak_instance.location();
GlobalHandles::MakeWeak(global_handle_location, global_handle_location,
&NopFinalizer, v8::WeakCallbackType::kParameter);
return weak_instance;
}
} // namespace
//============================================================================
// Implementation of the public interface of the interpreter.
//============================================================================
WasmInterpreter::WasmInterpreter(Isolate* isolate, const WasmModule* module,
const ModuleWireBytes& wire_bytes,
Handle<WasmInstanceObject> instance_object)
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: zone_(isolate->allocator(), ZONE_NAME),
internals_(new WasmInterpreterInternals(
&zone_, module, wire_bytes, MakeWeak(isolate, instance_object))) {}
// The destructor is here so we can forward declare {WasmInterpreterInternals}
// used in the {unique_ptr} in the header.
WasmInterpreter::~WasmInterpreter() {}
void WasmInterpreter::Run() { internals_->threads_[0].Run(); }
void WasmInterpreter::Pause() { internals_->threads_[0].Pause(); }
int WasmInterpreter::GetThreadCount() {
return 1; // only one thread for now.
}
WasmInterpreter::Thread* WasmInterpreter::GetThread(int id) {
CHECK_EQ(0, id); // only one thread for now.
return ToThread(&internals_->threads_[id]);
}
void WasmInterpreter::AddFunctionForTesting(const WasmFunction* function) {
internals_->codemap_.AddFunction(function, nullptr, nullptr);
}
void WasmInterpreter::SetFunctionCodeForTesting(const WasmFunction* function,
const byte* start,
const byte* end) {
internals_->codemap_.SetFunctionCode(function, start, end);
}
ControlTransferMap WasmInterpreter::ComputeControlTransfersForTesting(
Zone* zone, const WasmModule* module, const byte* start, const byte* end) {
// Create some dummy structures, to avoid special-casing the implementation
// just for testing.
FunctionSig sig(0, 0, nullptr);
WasmFunction function{&sig, // sig
0, // func_index
0, // sig_index
{0, 0}, // code
false, // imported
false, // exported
false}; // declared
InterpreterCode code{&function, BodyLocalDecls(zone), start, end, nullptr};
// Now compute and return the control transfers.
SideTable side_table(zone, module, &code);
return side_table.map_;
}
#undef TRACE
#undef LANE
#undef FOREACH_SIMPLE_BINOP
#undef FOREACH_OTHER_BINOP
#undef FOREACH_I32CONV_FLOATOP
#undef FOREACH_OTHER_UNOP
} // namespace wasm
} // namespace internal
} // namespace v8