From 6bf0a5cb5034a7e684dcc3500e841785237ce2dd Mon Sep 17 00:00:00 2001 From: Daniel Baumann Date: Sun, 7 Apr 2024 19:32:43 +0200 Subject: Adding upstream version 1:115.7.0. Signed-off-by: Daniel Baumann --- js/src/wasm/WasmInstance.cpp | 2759 ++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 2759 insertions(+) create mode 100644 js/src/wasm/WasmInstance.cpp (limited to 'js/src/wasm/WasmInstance.cpp') diff --git a/js/src/wasm/WasmInstance.cpp b/js/src/wasm/WasmInstance.cpp new file mode 100644 index 0000000000..557ed4e988 --- /dev/null +++ b/js/src/wasm/WasmInstance.cpp @@ -0,0 +1,2759 @@ +/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- + * vim: set ts=8 sts=2 et sw=2 tw=80: + * + * Copyright 2016 Mozilla Foundation + * + * Licensed under the Apache License, Version 2.0 (the "License"); + * you may not use this file except in compliance with the License. + * You may obtain a copy of the License at + * + * http://www.apache.org/licenses/LICENSE-2.0 + * + * Unless required by applicable law or agreed to in writing, software + * distributed under the License is distributed on an "AS IS" BASIS, + * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. + * See the License for the specific language governing permissions and + * limitations under the License. + */ + +#include "wasm/WasmInstance-inl.h" + +#include "mozilla/CheckedInt.h" +#include "mozilla/DebugOnly.h" + +#include +#include + +#include "jsmath.h" + +#include "gc/Marking.h" +#include "jit/AtomicOperations.h" +#include "jit/Disassemble.h" +#include "jit/JitCommon.h" +#include "jit/JitRuntime.h" +#include "jit/Registers.h" +#include "js/ForOfIterator.h" +#include "js/friend/ErrorMessages.h" // js::GetErrorMessage, JSMSG_* +#include "js/Stack.h" // JS::NativeStackLimitMin +#include "util/StringBuffer.h" +#include "util/Text.h" +#include "vm/ArrayBufferObject.h" +#include "vm/BigIntType.h" +#include "vm/Compartment.h" +#include "vm/ErrorObject.h" +#include "vm/Interpreter.h" +#include "vm/Iteration.h" +#include "vm/JitActivation.h" +#include "vm/PlainObject.h" // js::PlainObject +#include "wasm/WasmBuiltins.h" +#include "wasm/WasmCode.h" +#include "wasm/WasmDebug.h" +#include "wasm/WasmDebugFrame.h" +#include "wasm/WasmGcObject.h" +#include "wasm/WasmJS.h" +#include "wasm/WasmMemory.h" +#include "wasm/WasmModule.h" +#include "wasm/WasmStubs.h" +#include "wasm/WasmTypeDef.h" +#include "wasm/WasmValType.h" +#include "wasm/WasmValue.h" + +#include "gc/StoreBuffer-inl.h" +#include "vm/ArrayBufferObject-inl.h" +#include "vm/JSObject-inl.h" + +using namespace js; +using namespace js::jit; +using namespace js::wasm; + +using mozilla::BitwiseCast; +using mozilla::CheckedUint32; +using mozilla::DebugOnly; + +// Instance must be aligned at least as much as any of the integer, float, +// or SIMD values that we'd like to store in it. +static_assert(alignof(Instance) >= + std::max(sizeof(Registers::RegisterContent), + sizeof(FloatRegisters::RegisterContent))); + +// The globalArea must be aligned at least as much as an instance. This is +// guaranteed to be sufficient for all data types we care about, including +// SIMD values. See the above assertion. +static_assert(Instance::offsetOfData() % alignof(Instance) == 0); + +// We want the memory base to be the first field, and accessible with no +// offset. This incidentally is also an assertion that there is no superclass +// with fields. +static_assert(Instance::offsetOfMemoryBase() == 0); + +// We want instance fields that are commonly accessed by the JIT to have +// compact encodings. A limit of less than 128 bytes is chosen to fit within +// the signed 8-bit mod r/m x86 encoding. +static_assert(Instance::offsetOfLastCommonJitField() < 128); + +////////////////////////////////////////////////////////////////////////////// +// +// Functions and invocation. + +TypeDefInstanceData* Instance::typeDefInstanceData(uint32_t typeIndex) const { + TypeDefInstanceData* instanceData = + (TypeDefInstanceData*)(data() + metadata().typeDefsOffsetStart); + return &instanceData[typeIndex]; +} + +const void* Instance::addressOfGlobalCell(const GlobalDesc& global) const { + const void* cell = data() + global.offset(); + // Indirect globals store a pointer to their cell in the instance global + // data. Dereference it to find the real cell. + if (global.isIndirect()) { + cell = *(const void**)cell; + } + return cell; +} + +FuncImportInstanceData& Instance::funcImportInstanceData(const FuncImport& fi) { + return *(FuncImportInstanceData*)(data() + fi.instanceOffset()); +} + +TableInstanceData& Instance::tableInstanceData(uint32_t tableIndex) const { + TableInstanceData* instanceData = + (TableInstanceData*)(data() + metadata().tablesOffsetStart); + return instanceData[tableIndex]; +} + +TagInstanceData& Instance::tagInstanceData(uint32_t tagIndex) const { + TagInstanceData* instanceData = + (TagInstanceData*)(data() + metadata().tagsOffsetStart); + return instanceData[tagIndex]; +} + +static bool UnpackResults(JSContext* cx, const ValTypeVector& resultTypes, + const Maybe stackResultsArea, uint64_t* argv, + MutableHandleValue rval) { + if (!stackResultsArea) { + MOZ_ASSERT(resultTypes.length() <= 1); + // Result is either one scalar value to unpack to a wasm value, or + // an ignored value for a zero-valued function. + if (resultTypes.length() == 1) { + return ToWebAssemblyValue(cx, rval, resultTypes[0], argv, true); + } + return true; + } + + MOZ_ASSERT(stackResultsArea.isSome()); + Rooted array(cx); + if (!IterableToArray(cx, rval, &array)) { + return false; + } + + if (resultTypes.length() != array->length()) { + UniqueChars expected(JS_smprintf("%zu", resultTypes.length())); + UniqueChars got(JS_smprintf("%u", array->length())); + + JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr, + JSMSG_WASM_WRONG_NUMBER_OF_VALUES, expected.get(), + got.get()); + return false; + } + + DebugOnly previousOffset = ~(uint64_t)0; + + ABIResultIter iter(ResultType::Vector(resultTypes)); + // The values are converted in the order they are pushed on the + // abstract WebAssembly stack; switch to iterate in push order. + while (!iter.done()) { + iter.next(); + } + DebugOnly seenRegisterResult = false; + for (iter.switchToPrev(); !iter.done(); iter.prev()) { + const ABIResult& result = iter.cur(); + MOZ_ASSERT(!seenRegisterResult); + // Use rval as a scratch area to hold the extracted result. + rval.set(array->getDenseElement(iter.index())); + if (result.inRegister()) { + // Currently, if a function type has results, there can be only + // one register result. If there is only one result, it is + // returned as a scalar and not an iterable, so we don't get here. + // If there are multiple results, we extract the register result + // and set `argv[0]` set to the extracted result, to be returned by + // register in the stub. The register result follows any stack + // results, so this preserves conversion order. + if (!ToWebAssemblyValue(cx, rval, result.type(), argv, true)) { + return false; + } + seenRegisterResult = true; + continue; + } + uint32_t result_size = result.size(); + MOZ_ASSERT(result_size == 4 || result_size == 8); +#ifdef DEBUG + if (previousOffset == ~(uint64_t)0) { + previousOffset = (uint64_t)result.stackOffset(); + } else { + MOZ_ASSERT(previousOffset - (uint64_t)result_size == + (uint64_t)result.stackOffset()); + previousOffset -= (uint64_t)result_size; + } +#endif + char* loc = stackResultsArea.value() + result.stackOffset(); + if (!ToWebAssemblyValue(cx, rval, result.type(), loc, result_size == 8)) { + return false; + } + } + + return true; +} + +bool Instance::callImport(JSContext* cx, uint32_t funcImportIndex, + unsigned argc, uint64_t* argv) { + AssertRealmUnchanged aru(cx); + + Tier tier = code().bestTier(); + + const FuncImport& fi = metadata(tier).funcImports[funcImportIndex]; + const FuncType& funcType = metadata().getFuncImportType(fi); + + ArgTypeVector argTypes(funcType); + InvokeArgs args(cx); + if (!args.init(cx, argTypes.lengthWithoutStackResults())) { + return false; + } + + if (funcType.hasUnexposableArgOrRet()) { + JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr, + JSMSG_WASM_BAD_VAL_TYPE); + return false; + } + + MOZ_ASSERT(argTypes.lengthWithStackResults() == argc); + Maybe stackResultPointer; + size_t lastBoxIndexPlusOne = 0; + { + JS::AutoAssertNoGC nogc; + for (size_t i = 0; i < argc; i++) { + const void* rawArgLoc = &argv[i]; + if (argTypes.isSyntheticStackResultPointerArg(i)) { + stackResultPointer = Some(*(char**)rawArgLoc); + continue; + } + size_t naturalIndex = argTypes.naturalIndex(i); + ValType type = funcType.args()[naturalIndex]; + // Avoid boxes creation not to trigger GC. + if (ToJSValueMayGC(type)) { + lastBoxIndexPlusOne = i + 1; + continue; + } + MutableHandleValue argValue = args[naturalIndex]; + if (!ToJSValue(cx, rawArgLoc, type, argValue)) { + return false; + } + } + } + + // Visit arguments that need to perform allocation in a second loop + // after the rest of arguments are converted. + for (size_t i = 0; i < lastBoxIndexPlusOne; i++) { + if (argTypes.isSyntheticStackResultPointerArg(i)) { + continue; + } + const void* rawArgLoc = &argv[i]; + size_t naturalIndex = argTypes.naturalIndex(i); + ValType type = funcType.args()[naturalIndex]; + if (!ToJSValueMayGC(type)) { + continue; + } + MOZ_ASSERT(!type.isRefRepr()); + // The conversions are safe here because source values are not references + // and will not be moved. + MutableHandleValue argValue = args[naturalIndex]; + if (!ToJSValue(cx, rawArgLoc, type, argValue)) { + return false; + } + } + + FuncImportInstanceData& import = funcImportInstanceData(fi); + Rooted importCallable(cx, import.callable); + MOZ_ASSERT(cx->realm() == importCallable->nonCCWRealm()); + + RootedValue fval(cx, ObjectValue(*importCallable)); + RootedValue thisv(cx, UndefinedValue()); + RootedValue rval(cx); + if (!Call(cx, fval, thisv, args, &rval)) { + return false; + } + + if (!UnpackResults(cx, funcType.results(), stackResultPointer, argv, &rval)) { + return false; + } + + if (!JitOptions.enableWasmJitExit) { + return true; + } + + // The import may already have become optimized. + for (auto t : code().tiers()) { + void* jitExitCode = codeBase(t) + fi.jitExitCodeOffset(); + if (import.code == jitExitCode) { + return true; + } + } + + void* jitExitCode = codeBase(tier) + fi.jitExitCodeOffset(); + + if (!importCallable->is()) { + return true; + } + + // Test if the function is JIT compiled. + if (!importCallable->as().hasBytecode()) { + return true; + } + + JSScript* script = importCallable->as().nonLazyScript(); + if (!script->hasJitScript()) { + return true; + } + + // Skip if the function does not have a signature that allows for a JIT exit. + if (!funcType.canHaveJitExit()) { + return true; + } + + // Let's optimize it! + + import.code = jitExitCode; + return true; +} + +/* static */ int32_t /* 0 to signal trap; 1 to signal OK */ +Instance::callImport_general(Instance* instance, int32_t funcImportIndex, + int32_t argc, uint64_t* argv) { + JSContext* cx = instance->cx(); + return instance->callImport(cx, funcImportIndex, argc, argv); +} + +////////////////////////////////////////////////////////////////////////////// +// +// Atomic operations and shared memory. + +template +static int32_t PerformWait(Instance* instance, PtrT byteOffset, ValT value, + int64_t timeout_ns) { + JSContext* cx = instance->cx(); + + if (!instance->memory()->isShared()) { + ReportTrapError(cx, JSMSG_WASM_NONSHARED_WAIT); + return -1; + } + + if (byteOffset & (sizeof(ValT) - 1)) { + ReportTrapError(cx, JSMSG_WASM_UNALIGNED_ACCESS); + return -1; + } + + if (byteOffset + sizeof(ValT) > instance->memory()->volatileMemoryLength()) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return -1; + } + + mozilla::Maybe timeout; + if (timeout_ns >= 0) { + timeout = mozilla::Some( + mozilla::TimeDuration::FromMicroseconds(double(timeout_ns) / 1000)); + } + + MOZ_ASSERT(byteOffset <= SIZE_MAX, "Bounds check is broken"); + switch (atomics_wait_impl(cx, instance->sharedMemoryBuffer(), + size_t(byteOffset), value, timeout)) { + case FutexThread::WaitResult::OK: + return 0; + case FutexThread::WaitResult::NotEqual: + return 1; + case FutexThread::WaitResult::TimedOut: + return 2; + case FutexThread::WaitResult::Error: + return -1; + default: + MOZ_CRASH(); + } +} + +/* static */ int32_t Instance::wait_i32_m32(Instance* instance, + uint32_t byteOffset, int32_t value, + int64_t timeout_ns) { + MOZ_ASSERT(SASigWaitI32M32.failureMode == FailureMode::FailOnNegI32); + return PerformWait(instance, byteOffset, value, timeout_ns); +} + +/* static */ int32_t Instance::wait_i32_m64(Instance* instance, + uint64_t byteOffset, int32_t value, + int64_t timeout_ns) { + MOZ_ASSERT(SASigWaitI32M64.failureMode == FailureMode::FailOnNegI32); + return PerformWait(instance, byteOffset, value, timeout_ns); +} + +/* static */ int32_t Instance::wait_i64_m32(Instance* instance, + uint32_t byteOffset, int64_t value, + int64_t timeout_ns) { + MOZ_ASSERT(SASigWaitI64M32.failureMode == FailureMode::FailOnNegI32); + return PerformWait(instance, byteOffset, value, timeout_ns); +} + +/* static */ int32_t Instance::wait_i64_m64(Instance* instance, + uint64_t byteOffset, int64_t value, + int64_t timeout_ns) { + MOZ_ASSERT(SASigWaitI64M64.failureMode == FailureMode::FailOnNegI32); + return PerformWait(instance, byteOffset, value, timeout_ns); +} + +template +static int32_t PerformWake(Instance* instance, PtrT byteOffset, int32_t count) { + JSContext* cx = instance->cx(); + + // The alignment guard is not in the wasm spec as of 2017-11-02, but is + // considered likely to appear, as 4-byte alignment is required for WAKE by + // the spec's validation algorithm. + + if (byteOffset & 3) { + ReportTrapError(cx, JSMSG_WASM_UNALIGNED_ACCESS); + return -1; + } + + if (byteOffset >= instance->memory()->volatileMemoryLength()) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return -1; + } + + if (!instance->memory()->isShared()) { + return 0; + } + + MOZ_ASSERT(byteOffset <= SIZE_MAX, "Bounds check is broken"); + int64_t woken = atomics_notify_impl(instance->sharedMemoryBuffer(), + size_t(byteOffset), int64_t(count)); + + if (woken > INT32_MAX) { + ReportTrapError(cx, JSMSG_WASM_WAKE_OVERFLOW); + return -1; + } + + return int32_t(woken); +} + +/* static */ int32_t Instance::wake_m32(Instance* instance, uint32_t byteOffset, + int32_t count) { + MOZ_ASSERT(SASigWakeM32.failureMode == FailureMode::FailOnNegI32); + return PerformWake(instance, byteOffset, count); +} + +/* static */ int32_t Instance::wake_m64(Instance* instance, uint64_t byteOffset, + int32_t count) { + MOZ_ASSERT(SASigWakeM32.failureMode == FailureMode::FailOnNegI32); + return PerformWake(instance, byteOffset, count); +} + +////////////////////////////////////////////////////////////////////////////// +// +// Bulk memory operations. + +/* static */ uint32_t Instance::memoryGrow_m32(Instance* instance, + uint32_t delta) { + MOZ_ASSERT(SASigMemoryGrowM32.failureMode == FailureMode::Infallible); + MOZ_ASSERT(!instance->isAsmJS()); + + JSContext* cx = instance->cx(); + Rooted memory(cx, instance->memory_); + + // It is safe to cast to uint32_t, as all limits have been checked inside + // grow() and will not have been exceeded for a 32-bit memory. + uint32_t ret = uint32_t(WasmMemoryObject::grow(memory, uint64_t(delta), cx)); + + // If there has been a moving grow, this Instance should have been notified. + MOZ_RELEASE_ASSERT(instance->memoryBase_ == + instance->memory_->buffer().dataPointerEither()); + + return ret; +} + +/* static */ uint64_t Instance::memoryGrow_m64(Instance* instance, + uint64_t delta) { + MOZ_ASSERT(SASigMemoryGrowM64.failureMode == FailureMode::Infallible); + MOZ_ASSERT(!instance->isAsmJS()); + + JSContext* cx = instance->cx(); + Rooted memory(cx, instance->memory_); + + uint64_t ret = WasmMemoryObject::grow(memory, delta, cx); + + // If there has been a moving grow, this Instance should have been notified. + MOZ_RELEASE_ASSERT(instance->memoryBase_ == + instance->memory_->buffer().dataPointerEither()); + + return ret; +} + +/* static */ uint32_t Instance::memorySize_m32(Instance* instance) { + MOZ_ASSERT(SASigMemorySizeM32.failureMode == FailureMode::Infallible); + + // This invariant must hold when running Wasm code. Assert it here so we can + // write tests for cross-realm calls. + DebugOnly cx = instance->cx(); + MOZ_ASSERT(cx->realm() == instance->realm()); + + Pages pages = instance->memory()->volatilePages(); +#ifdef JS_64BIT + // Ensure that the memory size is no more than 4GiB. + MOZ_ASSERT(pages <= Pages(MaxMemory32LimitField)); +#endif + return uint32_t(pages.value()); +} + +/* static */ uint64_t Instance::memorySize_m64(Instance* instance) { + MOZ_ASSERT(SASigMemorySizeM64.failureMode == FailureMode::Infallible); + + // This invariant must hold when running Wasm code. Assert it here so we can + // write tests for cross-realm calls. + DebugOnly cx = instance->cx(); + MOZ_ASSERT(cx->realm() == instance->realm()); + + Pages pages = instance->memory()->volatilePages(); +#ifdef JS_64BIT + MOZ_ASSERT(pages <= Pages(MaxMemory64LimitField)); +#endif + return pages.value(); +} + +template +inline int32_t WasmMemoryCopy(JSContext* cx, T memBase, size_t memLen, + I dstByteOffset, I srcByteOffset, I len, + F memMove) { + if (!MemoryBoundsCheck(dstByteOffset, len, memLen) || + !MemoryBoundsCheck(srcByteOffset, len, memLen)) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return -1; + } + + memMove(memBase + uintptr_t(dstByteOffset), + memBase + uintptr_t(srcByteOffset), size_t(len)); + return 0; +} + +template +inline int32_t MemoryCopy(JSContext* cx, I dstByteOffset, I srcByteOffset, + I len, uint8_t* memBase) { + const WasmArrayRawBuffer* rawBuf = WasmArrayRawBuffer::fromDataPtr(memBase); + size_t memLen = rawBuf->byteLength(); + return WasmMemoryCopy(cx, memBase, memLen, dstByteOffset, srcByteOffset, len, + memmove); +} + +template +inline int32_t MemoryCopyShared(JSContext* cx, I dstByteOffset, I srcByteOffset, + I len, uint8_t* memBase) { + using RacyMemMove = + void (*)(SharedMem, SharedMem, size_t); + + const WasmSharedArrayRawBuffer* rawBuf = + WasmSharedArrayRawBuffer::fromDataPtr(memBase); + size_t memLen = rawBuf->volatileByteLength(); + + return WasmMemoryCopy, RacyMemMove>( + cx, SharedMem::shared(memBase), memLen, dstByteOffset, + srcByteOffset, len, AtomicOperations::memmoveSafeWhenRacy); +} + +/* static */ int32_t Instance::memCopy_m32(Instance* instance, + uint32_t dstByteOffset, + uint32_t srcByteOffset, uint32_t len, + uint8_t* memBase) { + MOZ_ASSERT(SASigMemCopyM32.failureMode == FailureMode::FailOnNegI32); + JSContext* cx = instance->cx(); + return MemoryCopy(cx, dstByteOffset, srcByteOffset, len, memBase); +} + +/* static */ int32_t Instance::memCopyShared_m32(Instance* instance, + uint32_t dstByteOffset, + uint32_t srcByteOffset, + uint32_t len, + uint8_t* memBase) { + MOZ_ASSERT(SASigMemCopySharedM32.failureMode == FailureMode::FailOnNegI32); + JSContext* cx = instance->cx(); + return MemoryCopyShared(cx, dstByteOffset, srcByteOffset, len, memBase); +} + +/* static */ int32_t Instance::memCopy_m64(Instance* instance, + uint64_t dstByteOffset, + uint64_t srcByteOffset, uint64_t len, + uint8_t* memBase) { + MOZ_ASSERT(SASigMemCopyM64.failureMode == FailureMode::FailOnNegI32); + JSContext* cx = instance->cx(); + return MemoryCopy(cx, dstByteOffset, srcByteOffset, len, memBase); +} + +/* static */ int32_t Instance::memCopyShared_m64(Instance* instance, + uint64_t dstByteOffset, + uint64_t srcByteOffset, + uint64_t len, + uint8_t* memBase) { + MOZ_ASSERT(SASigMemCopySharedM64.failureMode == FailureMode::FailOnNegI32); + JSContext* cx = instance->cx(); + return MemoryCopyShared(cx, dstByteOffset, srcByteOffset, len, memBase); +} + +template +inline int32_t WasmMemoryFill(JSContext* cx, T memBase, size_t memLen, + I byteOffset, uint32_t value, I len, F memSet) { + if (!MemoryBoundsCheck(byteOffset, len, memLen)) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return -1; + } + + // The required write direction is upward, but that is not currently + // observable as there are no fences nor any read/write protect operation. + memSet(memBase + uintptr_t(byteOffset), int(value), size_t(len)); + return 0; +} + +template +inline int32_t MemoryFill(JSContext* cx, I byteOffset, uint32_t value, I len, + uint8_t* memBase) { + const WasmArrayRawBuffer* rawBuf = WasmArrayRawBuffer::fromDataPtr(memBase); + size_t memLen = rawBuf->byteLength(); + return WasmMemoryFill(cx, memBase, memLen, byteOffset, value, len, memset); +} + +template +inline int32_t MemoryFillShared(JSContext* cx, I byteOffset, uint32_t value, + I len, uint8_t* memBase) { + const WasmSharedArrayRawBuffer* rawBuf = + WasmSharedArrayRawBuffer::fromDataPtr(memBase); + size_t memLen = rawBuf->volatileByteLength(); + return WasmMemoryFill(cx, SharedMem::shared(memBase), memLen, + byteOffset, value, len, + AtomicOperations::memsetSafeWhenRacy); +} + +/* static */ int32_t Instance::memFill_m32(Instance* instance, + uint32_t byteOffset, uint32_t value, + uint32_t len, uint8_t* memBase) { + MOZ_ASSERT(SASigMemFillM32.failureMode == FailureMode::FailOnNegI32); + JSContext* cx = instance->cx(); + return MemoryFill(cx, byteOffset, value, len, memBase); +} + +/* static */ int32_t Instance::memFillShared_m32(Instance* instance, + uint32_t byteOffset, + uint32_t value, uint32_t len, + uint8_t* memBase) { + MOZ_ASSERT(SASigMemFillSharedM32.failureMode == FailureMode::FailOnNegI32); + JSContext* cx = instance->cx(); + return MemoryFillShared(cx, byteOffset, value, len, memBase); +} + +/* static */ int32_t Instance::memFill_m64(Instance* instance, + uint64_t byteOffset, uint32_t value, + uint64_t len, uint8_t* memBase) { + MOZ_ASSERT(SASigMemFillM64.failureMode == FailureMode::FailOnNegI32); + JSContext* cx = instance->cx(); + return MemoryFill(cx, byteOffset, value, len, memBase); +} + +/* static */ int32_t Instance::memFillShared_m64(Instance* instance, + uint64_t byteOffset, + uint32_t value, uint64_t len, + uint8_t* memBase) { + MOZ_ASSERT(SASigMemFillSharedM64.failureMode == FailureMode::FailOnNegI32); + JSContext* cx = instance->cx(); + return MemoryFillShared(cx, byteOffset, value, len, memBase); +} + +static bool BoundsCheckInit(uint32_t dstOffset, uint32_t srcOffset, + uint32_t len, size_t memLen, uint32_t segLen) { + uint64_t dstOffsetLimit = uint64_t(dstOffset) + uint64_t(len); + uint64_t srcOffsetLimit = uint64_t(srcOffset) + uint64_t(len); + + return dstOffsetLimit > memLen || srcOffsetLimit > segLen; +} + +static bool BoundsCheckInit(uint64_t dstOffset, uint32_t srcOffset, + uint32_t len, size_t memLen, uint32_t segLen) { + uint64_t dstOffsetLimit = dstOffset + uint64_t(len); + uint64_t srcOffsetLimit = uint64_t(srcOffset) + uint64_t(len); + + return dstOffsetLimit < dstOffset || dstOffsetLimit > memLen || + srcOffsetLimit > segLen; +} + +template +static int32_t MemoryInit(JSContext* cx, Instance* instance, I dstOffset, + uint32_t srcOffset, uint32_t len, + const DataSegment* maybeSeg) { + if (!maybeSeg) { + if (len == 0 && srcOffset == 0) { + return 0; + } + + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return -1; + } + + const DataSegment& seg = *maybeSeg; + MOZ_RELEASE_ASSERT(!seg.active()); + + const uint32_t segLen = seg.bytes.length(); + + WasmMemoryObject* mem = instance->memory(); + const size_t memLen = mem->volatileMemoryLength(); + + // We are proposing to copy + // + // seg.bytes.begin()[ srcOffset .. srcOffset + len - 1 ] + // to + // memoryBase[ dstOffset .. dstOffset + len - 1 ] + + if (BoundsCheckInit(dstOffset, srcOffset, len, memLen, segLen)) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return -1; + } + + // The required read/write direction is upward, but that is not currently + // observable as there are no fences nor any read/write protect operation. + SharedMem dataPtr = mem->buffer().dataPointerEither(); + if (mem->isShared()) { + AtomicOperations::memcpySafeWhenRacy( + dataPtr + uintptr_t(dstOffset), (uint8_t*)seg.bytes.begin() + srcOffset, + len); + } else { + uint8_t* rawBuf = dataPtr.unwrap(/*Unshared*/); + memcpy(rawBuf + uintptr_t(dstOffset), + (const char*)seg.bytes.begin() + srcOffset, len); + } + return 0; +} + +/* static */ int32_t Instance::memInit_m32(Instance* instance, + uint32_t dstOffset, + uint32_t srcOffset, uint32_t len, + uint32_t segIndex) { + MOZ_ASSERT(SASigMemInitM32.failureMode == FailureMode::FailOnNegI32); + MOZ_RELEASE_ASSERT(size_t(segIndex) < instance->passiveDataSegments_.length(), + "ensured by validation"); + + JSContext* cx = instance->cx(); + return MemoryInit(cx, instance, dstOffset, srcOffset, len, + instance->passiveDataSegments_[segIndex]); +} + +/* static */ int32_t Instance::memInit_m64(Instance* instance, + uint64_t dstOffset, + uint32_t srcOffset, uint32_t len, + uint32_t segIndex) { + MOZ_ASSERT(SASigMemInitM64.failureMode == FailureMode::FailOnNegI32); + MOZ_RELEASE_ASSERT(size_t(segIndex) < instance->passiveDataSegments_.length(), + "ensured by validation"); + + JSContext* cx = instance->cx(); + return MemoryInit(cx, instance, dstOffset, srcOffset, len, + instance->passiveDataSegments_[segIndex]); +} + +////////////////////////////////////////////////////////////////////////////// +// +// Bulk table operations. + +/* static */ int32_t Instance::tableCopy(Instance* instance, uint32_t dstOffset, + uint32_t srcOffset, uint32_t len, + uint32_t dstTableIndex, + uint32_t srcTableIndex) { + MOZ_ASSERT(SASigTableCopy.failureMode == FailureMode::FailOnNegI32); + + JSContext* cx = instance->cx(); + const SharedTable& srcTable = instance->tables()[srcTableIndex]; + uint32_t srcTableLen = srcTable->length(); + + const SharedTable& dstTable = instance->tables()[dstTableIndex]; + uint32_t dstTableLen = dstTable->length(); + + // Bounds check and deal with arithmetic overflow. + uint64_t dstOffsetLimit = uint64_t(dstOffset) + len; + uint64_t srcOffsetLimit = uint64_t(srcOffset) + len; + + if (dstOffsetLimit > dstTableLen || srcOffsetLimit > srcTableLen) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return -1; + } + + bool isOOM = false; + + if (&srcTable == &dstTable && dstOffset > srcOffset) { + for (uint32_t i = len; i > 0; i--) { + if (!dstTable->copy(cx, *srcTable, dstOffset + (i - 1), + srcOffset + (i - 1))) { + isOOM = true; + break; + } + } + } else if (&srcTable == &dstTable && dstOffset == srcOffset) { + // No-op + } else { + for (uint32_t i = 0; i < len; i++) { + if (!dstTable->copy(cx, *srcTable, dstOffset + i, srcOffset + i)) { + isOOM = true; + break; + } + } + } + + if (isOOM) { + return -1; + } + return 0; +} + +bool Instance::initElems(uint32_t tableIndex, const ElemSegment& seg, + uint32_t dstOffset, uint32_t srcOffset, uint32_t len) { + Table& table = *tables_[tableIndex]; + MOZ_ASSERT(dstOffset <= table.length()); + MOZ_ASSERT(len <= table.length() - dstOffset); + + Tier tier = code().bestTier(); + const MetadataTier& metadataTier = metadata(tier); + const FuncImportVector& funcImports = metadataTier.funcImports; + const CodeRangeVector& codeRanges = metadataTier.codeRanges; + const Uint32Vector& funcToCodeRange = metadataTier.funcToCodeRange; + const Uint32Vector& elemFuncIndices = seg.elemFuncIndices; + MOZ_ASSERT(srcOffset <= elemFuncIndices.length()); + MOZ_ASSERT(len <= elemFuncIndices.length() - srcOffset); + + uint8_t* codeBaseTier = codeBase(tier); + for (uint32_t i = 0; i < len; i++) { + uint32_t funcIndex = elemFuncIndices[srcOffset + i]; + if (funcIndex == NullFuncIndex) { + table.setNull(dstOffset + i); + } else if (!table.isFunction()) { + // Note, fnref must be rooted if we do anything more than just store it. + void* fnref = Instance::refFunc(this, funcIndex); + if (fnref == AnyRef::invalid().forCompiledCode()) { + return false; // OOM, which has already been reported. + } + table.fillAnyRef(dstOffset + i, 1, AnyRef::fromCompiledCode(fnref)); + } else { + if (funcIndex < metadataTier.funcImports.length()) { + FuncImportInstanceData& import = + funcImportInstanceData(funcImports[funcIndex]); + MOZ_ASSERT(import.callable->isCallable()); + if (import.callable->is()) { + JSFunction* fun = &import.callable->as(); + if (IsWasmExportedFunction(fun)) { + // This element is a wasm function imported from another + // instance. To preserve the === function identity required by + // the JS embedding spec, we must set the element to the + // imported function's underlying CodeRange.funcCheckedCallEntry and + // Instance so that future Table.get()s produce the same + // function object as was imported. + WasmInstanceObject* calleeInstanceObj = + ExportedFunctionToInstanceObject(fun); + Instance& calleeInstance = calleeInstanceObj->instance(); + Tier calleeTier = calleeInstance.code().bestTier(); + const CodeRange& calleeCodeRange = + calleeInstanceObj->getExportedFunctionCodeRange(fun, + calleeTier); + void* code = calleeInstance.codeBase(calleeTier) + + calleeCodeRange.funcCheckedCallEntry(); + table.setFuncRef(dstOffset + i, code, &calleeInstance); + continue; + } + } + } + void* code = + codeBaseTier + + codeRanges[funcToCodeRange[funcIndex]].funcCheckedCallEntry(); + table.setFuncRef(dstOffset + i, code, this); + } + } + return true; +} + +/* static */ int32_t Instance::tableInit(Instance* instance, uint32_t dstOffset, + uint32_t srcOffset, uint32_t len, + uint32_t segIndex, + uint32_t tableIndex) { + MOZ_ASSERT(SASigTableInit.failureMode == FailureMode::FailOnNegI32); + + MOZ_RELEASE_ASSERT(size_t(segIndex) < instance->passiveElemSegments_.length(), + "ensured by validation"); + + JSContext* cx = instance->cx(); + if (!instance->passiveElemSegments_[segIndex]) { + if (len == 0 && srcOffset == 0) { + return 0; + } + + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return -1; + } + + const ElemSegment& seg = *instance->passiveElemSegments_[segIndex]; + MOZ_RELEASE_ASSERT(!seg.active()); + const uint32_t segLen = seg.length(); + + const Table& table = *instance->tables()[tableIndex]; + const uint32_t tableLen = table.length(); + + // We are proposing to copy + // + // seg[ srcOffset .. srcOffset + len - 1 ] + // to + // tableBase[ dstOffset .. dstOffset + len - 1 ] + + // Bounds check and deal with arithmetic overflow. + uint64_t dstOffsetLimit = uint64_t(dstOffset) + uint64_t(len); + uint64_t srcOffsetLimit = uint64_t(srcOffset) + uint64_t(len); + + if (dstOffsetLimit > tableLen || srcOffsetLimit > segLen) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return -1; + } + + if (!instance->initElems(tableIndex, seg, dstOffset, srcOffset, len)) { + return -1; // OOM, which has already been reported. + } + + return 0; +} + +/* static */ int32_t Instance::tableFill(Instance* instance, uint32_t start, + void* value, uint32_t len, + uint32_t tableIndex) { + MOZ_ASSERT(SASigTableFill.failureMode == FailureMode::FailOnNegI32); + + JSContext* cx = instance->cx(); + Table& table = *instance->tables()[tableIndex]; + + // Bounds check and deal with arithmetic overflow. + uint64_t offsetLimit = uint64_t(start) + uint64_t(len); + + if (offsetLimit > table.length()) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return -1; + } + + switch (table.repr()) { + case TableRepr::Ref: + table.fillAnyRef(start, len, AnyRef::fromCompiledCode(value)); + break; + case TableRepr::Func: + MOZ_RELEASE_ASSERT(!table.isAsmJS()); + table.fillFuncRef(start, len, FuncRef::fromCompiledCode(value), cx); + break; + } + + return 0; +} + +template +static bool WasmDiscardCheck(Instance* instance, I byteOffset, I byteLen, + size_t memLen, bool shared) { + JSContext* cx = instance->cx(); + + if (byteOffset % wasm::PageSize != 0 || byteLen % wasm::PageSize != 0) { + ReportTrapError(cx, JSMSG_WASM_UNALIGNED_ACCESS); + return false; + } + + if (!MemoryBoundsCheck(byteOffset, byteLen, memLen)) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return false; + } + + return true; +} + +template +static int32_t MemDiscardNotShared(Instance* instance, I byteOffset, I byteLen, + uint8_t* memBase) { + WasmArrayRawBuffer* rawBuf = WasmArrayRawBuffer::fromDataPtr(memBase); + size_t memLen = rawBuf->byteLength(); + + if (!WasmDiscardCheck(instance, byteOffset, byteLen, memLen, false)) { + return -1; + } + rawBuf->discard(byteOffset, byteLen); + + return 0; +} + +template +static int32_t MemDiscardShared(Instance* instance, I byteOffset, I byteLen, + uint8_t* memBase) { + WasmSharedArrayRawBuffer* rawBuf = + WasmSharedArrayRawBuffer::fromDataPtr(memBase); + size_t memLen = rawBuf->volatileByteLength(); + + if (!WasmDiscardCheck(instance, byteOffset, byteLen, memLen, true)) { + return -1; + } + rawBuf->discard(byteOffset, byteLen); + + return 0; +} + +/* static */ int32_t Instance::memDiscard_m32(Instance* instance, + uint32_t byteOffset, + uint32_t byteLen, + uint8_t* memBase) { + return MemDiscardNotShared(instance, byteOffset, byteLen, memBase); +} + +/* static */ int32_t Instance::memDiscard_m64(Instance* instance, + uint64_t byteOffset, + uint64_t byteLen, + uint8_t* memBase) { + return MemDiscardNotShared(instance, byteOffset, byteLen, memBase); +} + +/* static */ int32_t Instance::memDiscardShared_m32(Instance* instance, + uint32_t byteOffset, + uint32_t byteLen, + uint8_t* memBase) { + return MemDiscardShared(instance, byteOffset, byteLen, memBase); +} + +/* static */ int32_t Instance::memDiscardShared_m64(Instance* instance, + uint64_t byteOffset, + uint64_t byteLen, + uint8_t* memBase) { + return MemDiscardShared(instance, byteOffset, byteLen, memBase); +} + +/* static */ void* Instance::tableGet(Instance* instance, uint32_t index, + uint32_t tableIndex) { + MOZ_ASSERT(SASigTableGet.failureMode == FailureMode::FailOnInvalidRef); + + JSContext* cx = instance->cx(); + const Table& table = *instance->tables()[tableIndex]; + if (index >= table.length()) { + ReportTrapError(cx, JSMSG_WASM_TABLE_OUT_OF_BOUNDS); + return AnyRef::invalid().forCompiledCode(); + } + + switch (table.repr()) { + case TableRepr::Ref: + return table.getAnyRef(index).forCompiledCode(); + case TableRepr::Func: { + MOZ_RELEASE_ASSERT(!table.isAsmJS()); + RootedFunction fun(cx); + if (!table.getFuncRef(cx, index, &fun)) { + return AnyRef::invalid().forCompiledCode(); + } + return FuncRef::fromJSFunction(fun).forCompiledCode(); + } + } + MOZ_CRASH("Should not happen"); +} + +/* static */ uint32_t Instance::tableGrow(Instance* instance, void* initValue, + uint32_t delta, uint32_t tableIndex) { + MOZ_ASSERT(SASigTableGrow.failureMode == FailureMode::Infallible); + + JSContext* cx = instance->cx(); + RootedAnyRef ref(cx, AnyRef::fromCompiledCode(initValue)); + Table& table = *instance->tables()[tableIndex]; + + uint32_t oldSize = table.grow(delta); + + if (oldSize != uint32_t(-1) && initValue != nullptr) { + table.fillUninitialized(oldSize, delta, ref, cx); + } + +#ifdef DEBUG + if (!table.elemType().isNullable()) { + table.assertRangeNotNull(oldSize, delta); + } +#endif // DEBUG + return oldSize; +} + +/* static */ int32_t Instance::tableSet(Instance* instance, uint32_t index, + void* value, uint32_t tableIndex) { + MOZ_ASSERT(SASigTableSet.failureMode == FailureMode::FailOnNegI32); + + JSContext* cx = instance->cx(); + Table& table = *instance->tables()[tableIndex]; + + if (index >= table.length()) { + ReportTrapError(cx, JSMSG_WASM_TABLE_OUT_OF_BOUNDS); + return -1; + } + + switch (table.repr()) { + case TableRepr::Ref: + table.fillAnyRef(index, 1, AnyRef::fromCompiledCode(value)); + break; + case TableRepr::Func: + MOZ_RELEASE_ASSERT(!table.isAsmJS()); + table.fillFuncRef(index, 1, FuncRef::fromCompiledCode(value), cx); + break; + } + + return 0; +} + +/* static */ uint32_t Instance::tableSize(Instance* instance, + uint32_t tableIndex) { + MOZ_ASSERT(SASigTableSize.failureMode == FailureMode::Infallible); + Table& table = *instance->tables()[tableIndex]; + return table.length(); +} + +/* static */ void* Instance::refFunc(Instance* instance, uint32_t funcIndex) { + MOZ_ASSERT(SASigRefFunc.failureMode == FailureMode::FailOnInvalidRef); + JSContext* cx = instance->cx(); + + Tier tier = instance->code().bestTier(); + const MetadataTier& metadataTier = instance->metadata(tier); + const FuncImportVector& funcImports = metadataTier.funcImports; + + // If this is an import, we need to recover the original function to maintain + // reference equality between a re-exported function and 'ref.func'. The + // identity of the imported function object is stable across tiers, which is + // what we want. + // + // Use the imported function only if it is an exported function, otherwise + // fall through to get a (possibly new) exported function. + if (funcIndex < funcImports.length()) { + FuncImportInstanceData& import = + instance->funcImportInstanceData(funcImports[funcIndex]); + if (import.callable->is()) { + JSFunction* fun = &import.callable->as(); + if (IsWasmExportedFunction(fun)) { + return FuncRef::fromJSFunction(fun).forCompiledCode(); + } + } + } + + RootedFunction fun(cx); + Rooted instanceObj(cx, instance->object()); + if (!WasmInstanceObject::getExportedFunction(cx, instanceObj, funcIndex, + &fun)) { + // Validation ensures that we always have a valid funcIndex, so we must + // have OOM'ed + ReportOutOfMemory(cx); + return AnyRef::invalid().forCompiledCode(); + } + + return FuncRef::fromJSFunction(fun).forCompiledCode(); +} + +////////////////////////////////////////////////////////////////////////////// +// +// Segment management. + +/* static */ int32_t Instance::elemDrop(Instance* instance, uint32_t segIndex) { + MOZ_ASSERT(SASigElemDrop.failureMode == FailureMode::FailOnNegI32); + + MOZ_RELEASE_ASSERT(size_t(segIndex) < instance->passiveElemSegments_.length(), + "ensured by validation"); + + if (!instance->passiveElemSegments_[segIndex]) { + return 0; + } + + SharedElemSegment& segRefPtr = instance->passiveElemSegments_[segIndex]; + MOZ_RELEASE_ASSERT(!segRefPtr->active()); + + // Drop this instance's reference to the ElemSegment so it can be released. + segRefPtr = nullptr; + return 0; +} + +/* static */ int32_t Instance::dataDrop(Instance* instance, uint32_t segIndex) { + MOZ_ASSERT(SASigDataDrop.failureMode == FailureMode::FailOnNegI32); + + MOZ_RELEASE_ASSERT(size_t(segIndex) < instance->passiveDataSegments_.length(), + "ensured by validation"); + + if (!instance->passiveDataSegments_[segIndex]) { + return 0; + } + + SharedDataSegment& segRefPtr = instance->passiveDataSegments_[segIndex]; + MOZ_RELEASE_ASSERT(!segRefPtr->active()); + + // Drop this instance's reference to the DataSegment so it can be released. + segRefPtr = nullptr; + return 0; +} + +////////////////////////////////////////////////////////////////////////////// +// +// Object support. + +/* static */ void Instance::postBarrier(Instance* instance, + gc::Cell** location) { + MOZ_ASSERT(SASigPostBarrier.failureMode == FailureMode::Infallible); + MOZ_ASSERT(location); + instance->storeBuffer_->putCell(reinterpret_cast(location)); +} + +/* static */ void Instance::postBarrierPrecise(Instance* instance, + JSObject** location, + JSObject* prev) { + MOZ_ASSERT(SASigPostBarrierPrecise.failureMode == FailureMode::Infallible); + postBarrierPreciseWithOffset(instance, location, /*offset=*/0, prev); +} + +/* static */ void Instance::postBarrierPreciseWithOffset(Instance* instance, + JSObject** base, + uint32_t offset, + JSObject* prev) { + MOZ_ASSERT(SASigPostBarrierPreciseWithOffset.failureMode == + FailureMode::Infallible); + MOZ_ASSERT(base); + JSObject** location = (JSObject**)(uintptr_t(base) + size_t(offset)); + JSObject* next = *location; + JSObject::postWriteBarrier(location, prev, next); +} + +////////////////////////////////////////////////////////////////////////////// +// +// GC and exception handling support. + +/* static */ void* Instance::structNew(Instance* instance, + TypeDefInstanceData* typeDefData) { + MOZ_ASSERT(SASigStructNew.failureMode == FailureMode::FailOnNullPtr); + JSContext* cx = instance->cx(); + // The new struct will be allocated in an initial heap as determined by + // pretenuring logic as set up in `Instance::init`. + return WasmStructObject::createStruct( + cx, typeDefData, typeDefData->allocSite.initialHeap()); +} + +/* static */ void* Instance::structNewUninit(Instance* instance, + TypeDefInstanceData* typeDefData) { + MOZ_ASSERT(SASigStructNew.failureMode == FailureMode::FailOnNullPtr); + JSContext* cx = instance->cx(); + // The new struct will be allocated in an initial heap as determined by + // pretenuring logic as set up in `Instance::init`. + return WasmStructObject::createStruct( + cx, typeDefData, typeDefData->allocSite.initialHeap()); +} + +/* static */ void* Instance::arrayNew(Instance* instance, uint32_t numElements, + TypeDefInstanceData* typeDefData) { + MOZ_ASSERT(SASigArrayNew.failureMode == FailureMode::FailOnNullPtr); + JSContext* cx = instance->cx(); + // The new array will be allocated in an initial heap as determined by + // pretenuring logic as set up in `Instance::init`. + return WasmArrayObject::createArray( + cx, typeDefData, typeDefData->allocSite.initialHeap(), numElements); +} + +/* static */ void* Instance::arrayNewUninit(Instance* instance, + uint32_t numElements, + TypeDefInstanceData* typeDefData) { + MOZ_ASSERT(SASigArrayNew.failureMode == FailureMode::FailOnNullPtr); + JSContext* cx = instance->cx(); + // The new array will be allocated in an initial heap as determined by + // pretenuring logic as set up in `Instance::init`. + return WasmArrayObject::createArray( + cx, typeDefData, typeDefData->allocSite.initialHeap(), numElements); +} + +// Creates an array (WasmArrayObject) containing `numElements` of type +// described by `typeDef`. Initialises it with data copied from the data +// segment whose index is `segIndex`, starting at byte offset `segByteOffset` +// in the segment. Traps if the segment doesn't hold enough bytes to fill the +// array. +/* static */ void* Instance::arrayNewData(Instance* instance, + uint32_t segByteOffset, + uint32_t numElements, + TypeDefInstanceData* typeDefData, + uint32_t segIndex) { + MOZ_ASSERT(SASigArrayNewData.failureMode == FailureMode::FailOnNullPtr); + JSContext* cx = instance->cx(); + + // Check that the data segment is valid for use. + MOZ_RELEASE_ASSERT(size_t(segIndex) < instance->passiveDataSegments_.length(), + "ensured by validation"); + const DataSegment* seg = instance->passiveDataSegments_[segIndex]; + + // `seg` will be nullptr if the segment has already been 'data.drop'ed + // (either implicitly in the case of 'active' segments during instantiation, + // or explicitly by the data.drop instruction.) In that case we can + // continue only if there's no need to copy any data out of it. + if (!seg && (numElements != 0 || segByteOffset != 0)) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return nullptr; + } + // At this point, if `seg` is null then `numElements` and `segByteOffset` + // are both zero. + + const TypeDef* typeDef = typeDefData->typeDef; + Rooted arrayObj( + cx, + WasmArrayObject::createArray( + cx, typeDefData, typeDefData->allocSite.initialHeap(), numElements)); + if (!arrayObj) { + // WasmArrayObject::createArray will have reported OOM. + return nullptr; + } + MOZ_RELEASE_ASSERT(arrayObj->is()); + + if (!seg) { + // A zero-length array was requested and has been created, so we're done. + return arrayObj; + } + + // Compute the number of bytes to copy, ensuring it's below 2^32. + CheckedUint32 numBytesToCopy = + CheckedUint32(numElements) * + CheckedUint32(typeDef->arrayType().elementType_.size()); + if (!numBytesToCopy.isValid()) { + // Because the request implies that 2^32 or more bytes are to be copied. + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return nullptr; + } + + // Range-check the copy. The obvious thing to do is to compute the offset + // of the last byte to copy, but that would cause underflow in the + // zero-length-and-zero-offset case. Instead, compute that value plus one; + // in other words the offset of the first byte *not* to copy. + CheckedUint32 lastByteOffsetPlus1 = + CheckedUint32(segByteOffset) + numBytesToCopy; + + CheckedUint32 numBytesAvailable(seg->bytes.length()); + if (!lastByteOffsetPlus1.isValid() || !numBytesAvailable.isValid() || + lastByteOffsetPlus1.value() > numBytesAvailable.value()) { + // Because the last byte to copy doesn't exist inside `seg->bytes`. + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return nullptr; + } + + // Because `numBytesToCopy` is an in-range `CheckedUint32`, the cast to + // `size_t` is safe even on a 32-bit target. + memcpy(arrayObj->data_, &seg->bytes[segByteOffset], + size_t(numBytesToCopy.value())); + + return arrayObj; +} + +// This is almost identical to ::arrayNewData, apart from the final part that +// actually copies the data. It creates an array (WasmArrayObject) +// containing `numElements` of type described by `typeDef`. Initialises it +// with data copied from the element segment whose index is `segIndex`, +// starting at element number `segElemIndex` in the segment. Traps if the +// segment doesn't hold enough elements to fill the array. +/* static */ void* Instance::arrayNewElem(Instance* instance, + uint32_t segElemIndex, + uint32_t numElements, + TypeDefInstanceData* typeDefData, + uint32_t segIndex) { + MOZ_ASSERT(SASigArrayNewElem.failureMode == FailureMode::FailOnNullPtr); + JSContext* cx = instance->cx(); + + // Check that the element segment is valid for use. + MOZ_RELEASE_ASSERT(size_t(segIndex) < instance->passiveElemSegments_.length(), + "ensured by validation"); + const ElemSegment* seg = instance->passiveElemSegments_[segIndex]; + + // As with ::arrayNewData, if `seg` is nullptr then we can only safely copy + // zero elements from it. + if (!seg && (numElements != 0 || segElemIndex != 0)) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return nullptr; + } + // At this point, if `seg` is null then `numElements` and `segElemIndex` + // are both zero. + + const TypeDef* typeDef = typeDefData->typeDef; + + // The element segment is an array of uint32_t indicating function indices, + // which we'll have to dereference (to produce real function pointers) + // before parking them in the array. Hence each array element must be a + // machine word. + MOZ_RELEASE_ASSERT(typeDef->arrayType().elementType_.size() == sizeof(void*)); + + Rooted arrayObj( + cx, + WasmArrayObject::createArray( + cx, typeDefData, typeDefData->allocSite.initialHeap(), numElements)); + if (!arrayObj) { + // WasmArrayObject::createArray will have reported OOM. + return nullptr; + } + MOZ_RELEASE_ASSERT(arrayObj->is()); + + if (!seg) { + // A zero-length array was requested and has been created, so we're done. + return arrayObj; + } + + // Range-check the copy. As in ::arrayNewData, compute the index of the + // last element to copy, plus one. + CheckedUint32 lastIndexPlus1 = + CheckedUint32(segElemIndex) + CheckedUint32(numElements); + + CheckedUint32 numElemsAvailable(seg->elemFuncIndices.length()); + if (!lastIndexPlus1.isValid() || !numElemsAvailable.isValid() || + lastIndexPlus1.value() > numElemsAvailable.value()) { + // Because the last element to copy doesn't exist inside + // `seg->elemFuncIndices`. + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return nullptr; + } + + // Do the initialisation, converting function indices into code pointers as + // we go. + void** dst = (void**)arrayObj->data_; + const uint32_t* src = &seg->elemFuncIndices[segElemIndex]; + for (uint32_t i = 0; i < numElements; i++) { + uint32_t funcIndex = src[i]; + FieldType elemType = typeDef->arrayType().elementType_; + MOZ_RELEASE_ASSERT(elemType.isRefType()); + RootedVal value(cx, elemType.refType()); + if (funcIndex == NullFuncIndex) { + // value remains null + } else { + void* funcRef = Instance::refFunc(instance, funcIndex); + if (funcRef == AnyRef::invalid().forCompiledCode()) { + return nullptr; // OOM, which has already been reported. + } + value = Val(elemType.refType(), FuncRef::fromCompiledCode(funcRef)); + } + value.get().writeToHeapLocation(&dst[i]); + } + + return arrayObj; +} + +/* static */ int32_t Instance::arrayCopy(Instance* instance, void* dstArray, + uint32_t dstIndex, void* srcArray, + uint32_t srcIndex, + uint32_t numElements, + uint32_t elementSize) { + MOZ_ASSERT(SASigArrayCopy.failureMode == FailureMode::FailOnNegI32); + JSContext* cx = instance->cx(); + + // At the entry point, `elementSize` may be negative to indicate + // reftyped-ness of array elements. That is done in order to avoid having + // to pass yet another (boolean) parameter here. + + // "traps if either array is null" + if (!srcArray || !dstArray) { + ReportTrapError(cx, JSMSG_WASM_DEREF_NULL); + return -1; + } + + bool elemsAreRefTyped = false; + if (int32_t(elementSize) < 0) { + elemsAreRefTyped = true; + elementSize = uint32_t(-int32_t(elementSize)); + } + MOZ_ASSERT(elementSize >= 1 && elementSize <= 16); + + // Get hold of the two arrays. + Rooted dstArrayObj(cx, + static_cast(dstArray)); + MOZ_RELEASE_ASSERT(dstArrayObj->is()); + + Rooted srcArrayObj(cx, + static_cast(srcArray)); + MOZ_RELEASE_ASSERT(srcArrayObj->is()); + + // If WasmArrayObject::numElements() is changed to return 64 bits, the + // following checking logic will be incorrect. + STATIC_ASSERT_WASMARRAYELEMENTS_NUMELEMENTS_IS_U32; + + // "traps if destination + length > len(array1)" + uint64_t dstNumElements = uint64_t(dstArrayObj->numElements_); + if (uint64_t(dstIndex) + uint64_t(numElements) > dstNumElements) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return -1; + } + + // "traps if source + length > len(array2)" + uint64_t srcNumElements = uint64_t(srcArrayObj->numElements_); + if (uint64_t(srcIndex) + uint64_t(numElements) > srcNumElements) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return -1; + } + + // trap if we're asked to copy 2^32 or more bytes on a 32-bit target. + uint64_t numBytesToCopy = uint64_t(numElements) * uint64_t(elementSize); +#ifndef JS_64BIT + if (numBytesToCopy > uint64_t(UINT32_MAX)) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return -1; + } +#endif + // We're now assured that `numBytesToCopy` can be cast to `size_t` without + // overflow. + + // Actually do the copy, taking care to handle cases where the src and dst + // areas overlap. + uint8_t* srcBase = srcArrayObj->data_; + uint8_t* dstBase = dstArrayObj->data_; + srcBase += size_t(srcIndex) * size_t(elementSize); + dstBase += size_t(dstIndex) * size_t(elementSize); + + if (numBytesToCopy == 0 || srcBase == dstBase) { + // Early exit if there's no work to do. + return 0; + } + + if (!elemsAreRefTyped) { + // Hand off to memmove, which is presumably highly optimized. + memmove(dstBase, srcBase, size_t(numBytesToCopy)); + return 0; + } + + // We're copying refs; doing that needs suitable GC barrier-ing. + uint8_t* nextSrc; + uint8_t* nextDst; + intptr_t step; + if (dstBase < srcBase) { + // Moving data backwards in the address space; so iterate forwards through + // the array. + step = intptr_t(elementSize); + nextSrc = srcBase; + nextDst = dstBase; + } else { + // Moving data forwards; so iterate backwards. + step = -intptr_t(elementSize); + nextSrc = srcBase + size_t(numBytesToCopy) - size_t(elementSize); + nextDst = dstBase + size_t(numBytesToCopy) - size_t(elementSize); + } + // We don't know the type of the elems, only that they are refs. No matter, + // we can simply make up a type. + RefType aRefType = RefType::eq(); + // Do the iteration + for (size_t i = 0; i < size_t(numElements); i++) { + // Copy `elementSize` bytes from `nextSrc` to `nextDst`. + RootedVal value(cx, aRefType); + value.get().readFromHeapLocation(nextSrc); + value.get().writeToHeapLocation(nextDst); + nextSrc += step; + nextDst += step; + } + + return 0; +} + +/* static */ void* Instance::exceptionNew(Instance* instance, JSObject* tag) { + MOZ_ASSERT(SASigExceptionNew.failureMode == FailureMode::FailOnNullPtr); + JSContext* cx = instance->cx(); + Rooted tagObj(cx, &tag->as()); + RootedObject proto(cx, &cx->global()->getPrototype(JSProto_WasmException)); + RootedObject stack(cx, nullptr); + return AnyRef::fromJSObject( + WasmExceptionObject::create(cx, tagObj, stack, proto)) + .forCompiledCode(); +} + +/* static */ int32_t Instance::throwException(Instance* instance, + JSObject* exn) { + MOZ_ASSERT(SASigThrowException.failureMode == FailureMode::FailOnNegI32); + + JSContext* cx = instance->cx(); + RootedValue exnVal(cx, UnboxAnyRef(AnyRef::fromJSObject(exn))); + cx->setPendingException(exnVal, nullptr); + + // By always returning -1, we trigger a wasmTrap(Trap::ThrowReported), + // and use that to trigger the stack walking for this exception. + return -1; +} + +/* static */ int32_t Instance::intrI8VecMul(Instance* instance, uint32_t dest, + uint32_t src1, uint32_t src2, + uint32_t len, uint8_t* memBase) { + MOZ_ASSERT(SASigIntrI8VecMul.failureMode == FailureMode::FailOnNegI32); + + JSContext* cx = instance->cx(); + const WasmArrayRawBuffer* rawBuf = WasmArrayRawBuffer::fromDataPtr(memBase); + size_t memLen = rawBuf->byteLength(); + + // Bounds check and deal with arithmetic overflow. + uint64_t destLimit = uint64_t(dest) + uint64_t(len); + uint64_t src1Limit = uint64_t(src1) + uint64_t(len); + uint64_t src2Limit = uint64_t(src2) + uint64_t(len); + if (destLimit > memLen || src1Limit > memLen || src2Limit > memLen) { + ReportTrapError(cx, JSMSG_WASM_OUT_OF_BOUNDS); + return -1; + } + + // Basic dot product + uint8_t* destPtr = &memBase[dest]; + uint8_t* src1Ptr = &memBase[src1]; + uint8_t* src2Ptr = &memBase[src2]; + while (len > 0) { + *destPtr = (*src1Ptr) * (*src2Ptr); + + destPtr++; + src1Ptr++; + src2Ptr++; + len--; + } + + return 0; +} + +////////////////////////////////////////////////////////////////////////////// +// +// Instance creation and related. + +Instance::Instance(JSContext* cx, Handle object, + const SharedCode& code, Handle memory, + SharedTableVector&& tables, UniqueDebugState maybeDebug) + : realm_(cx->realm()), + jsJitArgsRectifier_( + cx->runtime()->jitRuntime()->getArgumentsRectifier().value), + jsJitExceptionHandler_( + cx->runtime()->jitRuntime()->getExceptionTail().value), + preBarrierCode_( + cx->runtime()->jitRuntime()->preBarrier(MIRType::Object).value), + storeBuffer_(&cx->runtime()->gc.storeBuffer()), + object_(object), + code_(std::move(code)), + memory_(memory), + tables_(std::move(tables)), + maybeDebug_(std::move(maybeDebug)), + debugFilter_(nullptr), + maxInitializedGlobalsIndexPlus1_(0) {} + +Instance* Instance::create(JSContext* cx, Handle object, + const SharedCode& code, uint32_t instanceDataLength, + Handle memory, + SharedTableVector&& tables, + UniqueDebugState maybeDebug) { + void* base = js_calloc(alignof(Instance) + offsetof(Instance, data_) + + instanceDataLength); + if (!base) { + ReportOutOfMemory(cx); + return nullptr; + } + void* aligned = (void*)AlignBytes(uintptr_t(base), alignof(Instance)); + + auto* instance = new (aligned) Instance( + cx, object, code, memory, std::move(tables), std::move(maybeDebug)); + instance->allocatedBase_ = base; + return instance; +} + +void Instance::destroy(Instance* instance) { + instance->~Instance(); + js_free(instance->allocatedBase_); +} + +bool Instance::init(JSContext* cx, const JSObjectVector& funcImports, + const ValVector& globalImportValues, + const WasmGlobalObjectVector& globalObjs, + const WasmTagObjectVector& tagObjs, + const DataSegmentVector& dataSegments, + const ElemSegmentVector& elemSegments) { + MOZ_ASSERT(!!maybeDebug_ == metadata().debugEnabled); + +#ifdef DEBUG + for (auto t : code_->tiers()) { + MOZ_ASSERT(funcImports.length() == metadata(t).funcImports.length()); + } +#endif + MOZ_ASSERT(tables_.length() == metadata().tables.length()); + + memoryBase_ = + memory_ ? memory_->buffer().dataPointerEither().unwrap() : nullptr; + size_t limit = memory_ ? memory_->boundsCheckLimit() : 0; +#if !defined(JS_64BIT) + // We assume that the limit is a 32-bit quantity + MOZ_ASSERT(limit <= UINT32_MAX); +#endif + boundsCheckLimit_ = limit; + cx_ = cx; + valueBoxClass_ = &WasmValueBox::class_; + resetInterrupt(cx); + jumpTable_ = code_->tieringJumpTable(); + debugFilter_ = nullptr; + addressOfNeedsIncrementalBarrier_ = + cx->compartment()->zone()->addressOfNeedsIncrementalBarrier(); + + // Initialize function imports in the instance data + Tier callerTier = code_->bestTier(); + for (size_t i = 0; i < metadata(callerTier).funcImports.length(); i++) { + JSObject* f = funcImports[i]; + MOZ_ASSERT(f->isCallable()); + const FuncImport& fi = metadata(callerTier).funcImports[i]; + const FuncType& funcType = metadata().getFuncImportType(fi); + FuncImportInstanceData& import = funcImportInstanceData(fi); + import.callable = f; + if (f->is()) { + JSFunction* fun = &f->as(); + if (!isAsmJS() && IsWasmExportedFunction(fun)) { + WasmInstanceObject* calleeInstanceObj = + ExportedFunctionToInstanceObject(fun); + Instance& calleeInstance = calleeInstanceObj->instance(); + Tier calleeTier = calleeInstance.code().bestTier(); + const CodeRange& codeRange = + calleeInstanceObj->getExportedFunctionCodeRange( + &f->as(), calleeTier); + import.instance = &calleeInstance; + import.realm = fun->realm(); + import.code = calleeInstance.codeBase(calleeTier) + + codeRange.funcUncheckedCallEntry(); + } else if (void* thunk = MaybeGetBuiltinThunk(fun, funcType)) { + import.instance = this; + import.realm = fun->realm(); + import.code = thunk; + } else { + import.instance = this; + import.realm = fun->realm(); + import.code = codeBase(callerTier) + fi.interpExitCodeOffset(); + } + } else { + import.instance = this; + import.realm = f->nonCCWRealm(); + import.code = codeBase(callerTier) + fi.interpExitCodeOffset(); + } + } + + // Initialize tables in the instance data + for (size_t i = 0; i < tables_.length(); i++) { + const TableDesc& td = metadata().tables[i]; + TableInstanceData& table = tableInstanceData(i); + table.length = tables_[i]->length(); + table.elements = tables_[i]->instanceElements(); + // Non-imported tables, with init_expr, has to be initialized with + // the evaluated value. + if (!td.isImported && td.initExpr) { + Rooted instanceObj(cx, object()); + RootedVal val(cx); + if (!td.initExpr->evaluate(cx, instanceObj, &val)) { + return false; + } + RootedAnyRef ref(cx, val.get().ref()); + tables_[i]->fillUninitialized(0, tables_[i]->length(), ref, cx); + } + } + +#ifdef DEBUG + // All (linked) tables with non-nullable types must be initialized. + for (size_t i = 0; i < tables_.length(); i++) { + const TableDesc& td = metadata().tables[i]; + if (!td.elemType.isNullable()) { + tables_[i]->assertRangeNotNull(0, tables_[i]->length()); + } + } +#endif // DEBUG + + // Initialize tags in the instance data + for (size_t i = 0; i < metadata().tags.length(); i++) { + MOZ_ASSERT(tagObjs[i] != nullptr); + tagInstanceData(i).object = tagObjs[i]; + } + pendingException_ = nullptr; + pendingExceptionTag_ = nullptr; + + // Add debug filtering table. + if (metadata().debugEnabled) { + size_t numFuncs = metadata().debugNumFuncs(); + size_t numWords = std::max((numFuncs + 31) / 32, 1); + debugFilter_ = (uint32_t*)js_calloc(numWords, sizeof(uint32_t)); + if (!debugFilter_) { + return false; + } + } + + // Add observer if our memory base may grow + if (memory_ && memory_->movingGrowable() && + !memory_->addMovingGrowObserver(cx, object_)) { + return false; + } + + // Add observers if our tables may grow + for (const SharedTable& table : tables_) { + if (table->movingGrowable() && !table->addMovingGrowObserver(cx, object_)) { + return false; + } + } + + // Initialize type definitions in the instance data. + const SharedTypeContext& types = metadata().types; + Zone* zone = realm()->zone(); + for (uint32_t typeIndex = 0; typeIndex < types->length(); typeIndex++) { + const TypeDef& typeDef = types->type(typeIndex); + TypeDefInstanceData* typeDefData = typeDefInstanceData(typeIndex); + + // Set default field values. + new (typeDefData) TypeDefInstanceData(); + + // Store the runtime type for this type index + typeDefData->typeDef = &typeDef; + typeDefData->superTypeVector = typeDef.superTypeVector(); + + if (typeDef.kind() == TypeDefKind::Struct || + typeDef.kind() == TypeDefKind::Array) { + // Compute the parameters that allocation will use. First, the class + // and alloc kind for the type definition. + const JSClass* clasp; + gc::AllocKind allocKind; + + if (typeDef.kind() == TypeDefKind::Struct) { + clasp = WasmStructObject::classForTypeDef(&typeDef); + allocKind = WasmStructObject::allocKindForTypeDef(&typeDef); + } else { + clasp = &WasmArrayObject::class_; + allocKind = WasmArrayObject::allocKind(); + } + + // Move the alloc kind to background if possible + if (CanChangeToBackgroundAllocKind(allocKind, clasp)) { + allocKind = ForegroundToBackgroundAllocKind(allocKind); + } + + // Find the shape using the class and recursion group + typeDefData->shape = + WasmGCShape::getShape(cx, clasp, cx->realm(), TaggedProto(), + &typeDef.recGroup(), ObjectFlags()); + if (!typeDefData->shape) { + return false; + } + + typeDefData->clasp = clasp; + typeDefData->allocKind = allocKind; + + // Initialize the allocation site for pre-tenuring. + typeDefData->allocSite.initWasm(zone); + } else if (typeDef.kind() == TypeDefKind::Func) { + // Nothing to do; the default values are OK. + } else { + MOZ_ASSERT(typeDef.kind() == TypeDefKind::None); + MOZ_CRASH(); + } + } + + // Initialize globals in the instance data. + // + // This must be performed after we have initialized runtime types as a global + // initializer may reference them. + // + // We increment `maxInitializedGlobalsIndexPlus1_` every iteration of the + // loop, as we call out to `InitExpr::evaluate` which may call + // `constantGlobalGet` which uses this value to assert we're never accessing + // uninitialized globals. + maxInitializedGlobalsIndexPlus1_ = 0; + for (size_t i = 0; i < metadata().globals.length(); + i++, maxInitializedGlobalsIndexPlus1_ = i) { + const GlobalDesc& global = metadata().globals[i]; + + // Constants are baked into the code, never stored in the global area. + if (global.isConstant()) { + continue; + } + + uint8_t* globalAddr = data() + global.offset(); + switch (global.kind()) { + case GlobalKind::Import: { + size_t imported = global.importIndex(); + if (global.isIndirect()) { + *(void**)globalAddr = + (void*)&globalObjs[imported]->val().get().cell(); + } else { + globalImportValues[imported].writeToHeapLocation(globalAddr); + } + break; + } + case GlobalKind::Variable: { + RootedVal val(cx); + const InitExpr& init = global.initExpr(); + Rooted instanceObj(cx, object()); + if (!init.evaluate(cx, instanceObj, &val)) { + return false; + } + + if (global.isIndirect()) { + // Initialize the cell + wasm::GCPtrVal& cell = globalObjs[i]->val(); + cell = val.get(); + // Link to the cell + void* address = (void*)&cell.get().cell(); + *(void**)globalAddr = address; + } else { + val.get().writeToHeapLocation(globalAddr); + } + break; + } + case GlobalKind::Constant: { + MOZ_CRASH("skipped at the top"); + } + } + } + + // All globals were initialized + MOZ_ASSERT(maxInitializedGlobalsIndexPlus1_ == metadata().globals.length()); + + // Take references to the passive data segments + if (!passiveDataSegments_.resize(dataSegments.length())) { + return false; + } + for (size_t i = 0; i < dataSegments.length(); i++) { + if (!dataSegments[i]->active()) { + passiveDataSegments_[i] = dataSegments[i]; + } + } + + // Take references to the passive element segments + if (!passiveElemSegments_.resize(elemSegments.length())) { + return false; + } + for (size_t i = 0; i < elemSegments.length(); i++) { + if (elemSegments[i]->kind == ElemSegment::Kind::Passive) { + passiveElemSegments_[i] = elemSegments[i]; + } + } + + return true; +} + +Instance::~Instance() { + realm_->wasm.unregisterInstance(*this); + + if (debugFilter_) { + js_free(debugFilter_); + } + + // Any pending exceptions should have been consumed. + MOZ_ASSERT(!pendingException_); +} + +void Instance::setInterrupt() { + interrupt_ = true; + stackLimit_ = JS::NativeStackLimitMin; +} + +bool Instance::isInterrupted() const { + return interrupt_ || stackLimit_ == JS::NativeStackLimitMin; +} + +void Instance::resetInterrupt(JSContext* cx) { + interrupt_ = false; + stackLimit_ = cx->stackLimitForJitCode(JS::StackForUntrustedScript); +} + +bool Instance::debugFilter(uint32_t funcIndex) const { + return (debugFilter_[funcIndex / 32] >> funcIndex % 32) & 1; +} + +void Instance::setDebugFilter(uint32_t funcIndex, bool value) { + if (value) { + debugFilter_[funcIndex / 32] |= (1 << funcIndex % 32); + } else { + debugFilter_[funcIndex / 32] &= ~(1 << funcIndex % 32); + } +} + +size_t Instance::memoryMappedSize() const { + return memory_->buffer().wasmMappedSize(); +} + +bool Instance::memoryAccessInGuardRegion(const uint8_t* addr, + unsigned numBytes) const { + MOZ_ASSERT(numBytes > 0); + + if (!metadata().usesMemory()) { + return false; + } + + uint8_t* base = memoryBase().unwrap(/* comparison */); + if (addr < base) { + return false; + } + + size_t lastByteOffset = addr - base + (numBytes - 1); + return lastByteOffset >= memory()->volatileMemoryLength() && + lastByteOffset < memoryMappedSize(); +} + +void Instance::tracePrivate(JSTracer* trc) { + // This method is only called from WasmInstanceObject so the only reason why + // TraceEdge is called is so that the pointer can be updated during a moving + // GC. + MOZ_ASSERT_IF(trc->isMarkingTracer(), gc::IsMarked(trc->runtime(), object_)); + TraceEdge(trc, &object_, "wasm instance object"); + + // OK to just do one tier here; though the tiers have different funcImports + // tables, they share the instance object. + for (const FuncImport& fi : metadata(code().stableTier()).funcImports) { + TraceNullableEdge(trc, &funcImportInstanceData(fi).callable, "wasm import"); + } + + for (const SharedTable& table : tables_) { + table->trace(trc); + } + + for (const GlobalDesc& global : code().metadata().globals) { + // Indirect reference globals get traced by the owning WebAssembly.Global. + if (!global.type().isRefRepr() || global.isConstant() || + global.isIndirect()) { + continue; + } + GCPtr* obj = (GCPtr*)(data() + global.offset()); + TraceNullableEdge(trc, obj, "wasm reference-typed global"); + } + + for (uint32_t tagIndex = 0; tagIndex < code().metadata().tags.length(); + tagIndex++) { + TraceNullableEdge(trc, &tagInstanceData(tagIndex).object, "wasm tag"); + } + + const SharedTypeContext& types = metadata().types; + for (uint32_t typeIndex = 0; typeIndex < types->length(); typeIndex++) { + TypeDefInstanceData* typeDefData = typeDefInstanceData(typeIndex); + TraceNullableEdge(trc, &typeDefData->shape, "wasm shape"); + } + + TraceNullableEdge(trc, &memory_, "wasm buffer"); + TraceNullableEdge(trc, &pendingException_, "wasm pending exception value"); + TraceNullableEdge(trc, &pendingExceptionTag_, "wasm pending exception tag"); + + if (maybeDebug_) { + maybeDebug_->trace(trc); + } +} + +void js::wasm::TraceInstanceEdge(JSTracer* trc, Instance* instance, + const char* name) { + if (IsTracerKind(trc, JS::TracerKind::Moving)) { + // Compacting GC: The Instance does not move so there is nothing to do here. + // Reading the object from the instance below would be a data race during + // multi-threaded updates. Compacting GC does not rely on graph traversal + // to find all edges that need to be updated. + return; + } + + // Instance fields are traced by the owning WasmInstanceObject's trace + // hook. Tracing this ensures they are traced once. + JSObject* object = instance->objectUnbarriered(); + TraceManuallyBarrieredEdge(trc, &object, name); +} + +uintptr_t Instance::traceFrame(JSTracer* trc, const wasm::WasmFrameIter& wfi, + uint8_t* nextPC, + uintptr_t highestByteVisitedInPrevFrame) { + const StackMap* map = code().lookupStackMap(nextPC); + if (!map) { + return 0; + } + + Frame* frame = wfi.frame(); + + // |frame| points somewhere in the middle of the area described by |map|. + // We have to calculate |scanStart|, the lowest address that is described by + // |map|, by consulting |map->frameOffsetFromTop|. + + const size_t numMappedBytes = map->header.numMappedWords * sizeof(void*); + const uintptr_t scanStart = uintptr_t(frame) + + (map->header.frameOffsetFromTop * sizeof(void*)) - + numMappedBytes; + MOZ_ASSERT(0 == scanStart % sizeof(void*)); + + // Do what we can to assert that, for consecutive wasm frames, their stack + // maps also abut exactly. This is a useful sanity check on the sizing of + // stackmaps. + // + // In debug builds, the stackmap construction machinery goes to considerable + // efforts to ensure that the stackmaps for consecutive frames abut exactly. + // This is so as to ensure there are no areas of stack inadvertently ignored + // by a stackmap, nor covered by two stackmaps. Hence any failure of this + // assertion is serious and should be investigated. +#ifndef JS_CODEGEN_ARM64 + MOZ_ASSERT_IF(highestByteVisitedInPrevFrame != 0, + highestByteVisitedInPrevFrame + 1 == scanStart); +#endif + + uintptr_t* stackWords = (uintptr_t*)scanStart; + + // If we have some exit stub words, this means the map also covers an area + // created by a exit stub, and so the highest word of that should be a + // constant created by (code created by) GenerateTrapExit. + MOZ_ASSERT_IF( + map->header.numExitStubWords > 0, + stackWords[map->header.numExitStubWords - 1 - + TrapExitDummyValueOffsetFromTop] == TrapExitDummyValue); + + // And actually hand them off to the GC. + for (uint32_t i = 0; i < map->header.numMappedWords; i++) { + if (map->getBit(i) == 0) { + continue; + } + + // TODO/AnyRef-boxing: With boxed immediates and strings, the value may + // not be a traceable JSObject*. + ASSERT_ANYREF_IS_JSOBJECT; + + // This assertion seems at least moderately effective in detecting + // discrepancies or misalignments between the map and reality. + MOZ_ASSERT(js::gc::IsCellPointerValidOrNull((const void*)stackWords[i])); + + if (stackWords[i]) { + TraceRoot(trc, (JSObject**)&stackWords[i], + "Instance::traceWasmFrame: normal word"); + } + } + + // Finally, deal with any GC-managed fields in the DebugFrame, if it is + // present and those fields may be live. + if (map->header.hasDebugFrameWithLiveRefs) { + DebugFrame* debugFrame = DebugFrame::from(frame); + char* debugFrameP = (char*)debugFrame; + + // TODO/AnyRef-boxing: With boxed immediates and strings, the value may + // not be a traceable JSObject*. + ASSERT_ANYREF_IS_JSOBJECT; + + for (size_t i = 0; i < MaxRegisterResults; i++) { + if (debugFrame->hasSpilledRegisterRefResult(i)) { + char* resultRefP = debugFrameP + DebugFrame::offsetOfRegisterResult(i); + TraceNullableRoot( + trc, (JSObject**)resultRefP, + "Instance::traceWasmFrame: DebugFrame::resultResults_"); + } + } + + if (debugFrame->hasCachedReturnJSValue()) { + char* cachedReturnJSValueP = + debugFrameP + DebugFrame::offsetOfCachedReturnJSValue(); + TraceRoot(trc, (js::Value*)cachedReturnJSValueP, + "Instance::traceWasmFrame: DebugFrame::cachedReturnJSValue_"); + } + } + + return scanStart + numMappedBytes - 1; +} + +WasmMemoryObject* Instance::memory() const { return memory_; } + +SharedMem Instance::memoryBase() const { + MOZ_ASSERT(metadata().usesMemory()); + MOZ_ASSERT(memoryBase_ == memory_->buffer().dataPointerEither()); + return memory_->buffer().dataPointerEither(); +} + +SharedArrayRawBuffer* Instance::sharedMemoryBuffer() const { + MOZ_ASSERT(memory_->isShared()); + return memory_->sharedArrayRawBuffer(); +} + +WasmInstanceObject* Instance::objectUnbarriered() const { + return object_.unbarrieredGet(); +} + +WasmInstanceObject* Instance::object() const { return object_; } + +static bool EnsureEntryStubs(const Instance& instance, uint32_t funcIndex, + const FuncExport** funcExport, + void** interpEntry) { + Tier tier = instance.code().bestTier(); + + size_t funcExportIndex; + *funcExport = + &instance.metadata(tier).lookupFuncExport(funcIndex, &funcExportIndex); + + const FuncExport& fe = **funcExport; + if (fe.hasEagerStubs()) { + *interpEntry = instance.codeBase(tier) + fe.eagerInterpEntryOffset(); + return true; + } + + MOZ_ASSERT(!instance.isAsmJS(), "only wasm can lazily export functions"); + + // If the best tier is Ion, life is simple: background compilation has + // already completed and has been committed, so there's no risk of race + // conditions here. + // + // If the best tier is Baseline, there could be a background compilation + // happening at the same time. The background compilation will lock the + // first tier lazy stubs first to stop new baseline stubs from being + // generated, then the second tier stubs to generate them. + // + // - either we take the tier1 lazy stub lock before the background + // compilation gets it, then we generate the lazy stub for tier1. When the + // background thread gets the tier1 lazy stub lock, it will see it has a + // lazy stub and will recompile it for tier2. + // - or we don't take the lock here first. Background compilation won't + // find a lazy stub for this function, thus won't generate it. So we'll do + // it ourselves after taking the tier2 lock. + // + // Also see doc block for stubs in WasmJS.cpp. + + auto stubs = instance.code(tier).lazyStubs().writeLock(); + *interpEntry = stubs->lookupInterpEntry(fe.funcIndex()); + if (*interpEntry) { + return true; + } + + // The best tier might have changed after we've taken the lock. + Tier prevTier = tier; + tier = instance.code().bestTier(); + const Metadata& metadata = instance.metadata(); + const CodeTier& codeTier = instance.code(tier); + if (tier == prevTier) { + if (!stubs->createOneEntryStub(funcExportIndex, metadata, codeTier)) { + return false; + } + + *interpEntry = stubs->lookupInterpEntry(fe.funcIndex()); + MOZ_ASSERT(*interpEntry); + return true; + } + + MOZ_RELEASE_ASSERT(prevTier == Tier::Baseline && tier == Tier::Optimized); + auto stubs2 = instance.code(tier).lazyStubs().writeLock(); + + // If it didn't have a stub in the first tier, background compilation + // shouldn't have made one in the second tier. + MOZ_ASSERT(!stubs2->hasEntryStub(fe.funcIndex())); + + if (!stubs2->createOneEntryStub(funcExportIndex, metadata, codeTier)) { + return false; + } + + *interpEntry = stubs2->lookupInterpEntry(fe.funcIndex()); + MOZ_ASSERT(*interpEntry); + return true; +} + +static bool GetInterpEntryAndEnsureStubs(JSContext* cx, Instance& instance, + uint32_t funcIndex, CallArgs args, + void** interpEntry, + const FuncType** funcType) { + const FuncExport* funcExport; + if (!EnsureEntryStubs(instance, funcIndex, &funcExport, interpEntry)) { + return false; + } + + *funcType = &instance.metadata().getFuncExportType(*funcExport); + +#ifdef DEBUG + // EnsureEntryStubs() has ensured proper jit-entry stubs have been created and + // installed in funcIndex's JumpTable entry, so check against the presence of + // the provisional lazy stub. See also + // WasmInstanceObject::getExportedFunction(). + if (!funcExport->hasEagerStubs() && (*funcType)->canHaveJitEntry()) { + if (!EnsureBuiltinThunksInitialized()) { + return false; + } + JSFunction& callee = args.callee().as(); + void* provisionalLazyJitEntryStub = ProvisionalLazyJitEntryStub(); + MOZ_ASSERT(provisionalLazyJitEntryStub); + MOZ_ASSERT(callee.isWasmWithJitEntry()); + MOZ_ASSERT(*callee.wasmJitEntry() != provisionalLazyJitEntryStub); + } +#endif + return true; +} + +bool wasm::ResultsToJSValue(JSContext* cx, ResultType type, + void* registerResultLoc, + Maybe stackResultsLoc, + MutableHandleValue rval, CoercionLevel level) { + if (type.empty()) { + // No results: set to undefined, and we're done. + rval.setUndefined(); + return true; + } + + // If we added support for multiple register results, we'd need to establish a + // convention for how to store them to memory in registerResultLoc. For now + // we can punt. + static_assert(MaxRegisterResults == 1); + + // Stack results written to stackResultsLoc; register result written + // to registerResultLoc. + + // First, convert the register return value, and prepare to iterate in + // push order. Note that if the register result is a reference type, + // it may be unrooted, so ToJSValue_anyref must not GC in that case. + ABIResultIter iter(type); + DebugOnly usedRegisterResult = false; + for (; !iter.done(); iter.next()) { + if (iter.cur().inRegister()) { + MOZ_ASSERT(!usedRegisterResult); + if (!ToJSValue(cx, registerResultLoc, iter.cur().type(), + rval, level)) { + return false; + } + usedRegisterResult = true; + } + } + MOZ_ASSERT(usedRegisterResult); + + MOZ_ASSERT((stackResultsLoc.isSome()) == (iter.count() > 1)); + if (!stackResultsLoc) { + // A single result: we're done. + return true; + } + + // Otherwise, collect results in an array, in push order. + Rooted array(cx, NewDenseEmptyArray(cx)); + if (!array) { + return false; + } + RootedValue tmp(cx); + for (iter.switchToPrev(); !iter.done(); iter.prev()) { + const ABIResult& result = iter.cur(); + if (result.onStack()) { + char* loc = stackResultsLoc.value() + result.stackOffset(); + if (!ToJSValue(cx, loc, result.type(), &tmp, level)) { + return false; + } + if (!NewbornArrayPush(cx, array, tmp)) { + return false; + } + } else { + if (!NewbornArrayPush(cx, array, rval)) { + return false; + } + } + } + rval.set(ObjectValue(*array)); + return true; +} + +class MOZ_RAII ReturnToJSResultCollector { + class MOZ_RAII StackResultsRooter : public JS::CustomAutoRooter { + ReturnToJSResultCollector& collector_; + + public: + StackResultsRooter(JSContext* cx, ReturnToJSResultCollector& collector) + : JS::CustomAutoRooter(cx), collector_(collector) {} + + void trace(JSTracer* trc) final { + for (ABIResultIter iter(collector_.type_); !iter.done(); iter.next()) { + const ABIResult& result = iter.cur(); + if (result.onStack() && result.type().isRefRepr()) { + char* loc = collector_.stackResultsArea_.get() + result.stackOffset(); + JSObject** refLoc = reinterpret_cast(loc); + TraceNullableRoot(trc, refLoc, "StackResultsRooter::trace"); + } + } + } + }; + friend class StackResultsRooter; + + ResultType type_; + UniquePtr stackResultsArea_; + Maybe rooter_; + + public: + explicit ReturnToJSResultCollector(const ResultType& type) : type_(type){}; + bool init(JSContext* cx) { + bool needRooter = false; + ABIResultIter iter(type_); + for (; !iter.done(); iter.next()) { + const ABIResult& result = iter.cur(); + if (result.onStack() && result.type().isRefRepr()) { + needRooter = true; + } + } + uint32_t areaBytes = iter.stackBytesConsumedSoFar(); + MOZ_ASSERT_IF(needRooter, areaBytes > 0); + if (areaBytes > 0) { + // It is necessary to zero storage for ref results, and it doesn't + // hurt to do so for other POD results. + stackResultsArea_ = cx->make_zeroed_pod_array(areaBytes); + if (!stackResultsArea_) { + return false; + } + if (needRooter) { + rooter_.emplace(cx, *this); + } + } + return true; + } + + void* stackResultsArea() { + MOZ_ASSERT(stackResultsArea_); + return stackResultsArea_.get(); + } + + bool collect(JSContext* cx, void* registerResultLoc, MutableHandleValue rval, + CoercionLevel level) { + Maybe stackResultsLoc = + stackResultsArea_ ? Some(stackResultsArea_.get()) : Nothing(); + return ResultsToJSValue(cx, type_, registerResultLoc, stackResultsLoc, rval, + level); + } +}; + +bool Instance::callExport(JSContext* cx, uint32_t funcIndex, CallArgs args, + CoercionLevel level) { + if (memory_) { + // If there has been a moving grow, this Instance should have been notified. + MOZ_RELEASE_ASSERT(memory_->buffer().dataPointerEither() == memoryBase()); + } + + void* interpEntry; + const FuncType* funcType; + if (!GetInterpEntryAndEnsureStubs(cx, *this, funcIndex, args, &interpEntry, + &funcType)) { + return false; + } + + // Lossless coercions can handle unexposable arguments or returns. This is + // only available in testing code. + if (level != CoercionLevel::Lossless && funcType->hasUnexposableArgOrRet()) { + JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr, + JSMSG_WASM_BAD_VAL_TYPE); + return false; + } + + ArgTypeVector argTypes(*funcType); + ResultType resultType(ResultType::Vector(funcType->results())); + ReturnToJSResultCollector results(resultType); + if (!results.init(cx)) { + return false; + } + + // The calling convention for an external call into wasm is to pass an + // array of 16-byte values where each value contains either a coerced int32 + // (in the low word), or a double value (in the low dword) value, with the + // coercions specified by the wasm signature. The external entry point + // unpacks this array into the system-ABI-specified registers and stack + // memory and then calls into the internal entry point. The return value is + // stored in the first element of the array (which, therefore, must have + // length >= 1). + Vector exportArgs(cx); + if (!exportArgs.resize( + std::max(1, argTypes.lengthWithStackResults()))) { + return false; + } + + ASSERT_ANYREF_IS_JSOBJECT; + Rooted> refs(cx); + + DebugCodegen(DebugChannel::Function, "wasm-function[%d] arguments [", + funcIndex); + RootedValue v(cx); + for (size_t i = 0; i < argTypes.lengthWithStackResults(); ++i) { + void* rawArgLoc = &exportArgs[i]; + if (argTypes.isSyntheticStackResultPointerArg(i)) { + *reinterpret_cast(rawArgLoc) = results.stackResultsArea(); + continue; + } + size_t naturalIdx = argTypes.naturalIndex(i); + v = naturalIdx < args.length() ? args[naturalIdx] : UndefinedValue(); + ValType type = funcType->arg(naturalIdx); + if (!ToWebAssemblyValue(cx, v, type, rawArgLoc, true, + level)) { + return false; + } + if (type.isRefRepr()) { + void* ptr = *reinterpret_cast(rawArgLoc); + // Store in rooted array until no more GC is possible. + RootedAnyRef ref(cx, AnyRef::fromCompiledCode(ptr)); + ASSERT_ANYREF_IS_JSOBJECT; + if (!refs.emplaceBack(ref.get().asJSObject())) { + return false; + } + DebugCodegen(DebugChannel::Function, "/(#%d)", int(refs.length() - 1)); + } + } + + // Copy over reference values from the rooted array, if any. + if (refs.length() > 0) { + DebugCodegen(DebugChannel::Function, "; "); + size_t nextRef = 0; + for (size_t i = 0; i < argTypes.lengthWithStackResults(); ++i) { + if (argTypes.isSyntheticStackResultPointerArg(i)) { + continue; + } + size_t naturalIdx = argTypes.naturalIndex(i); + ValType type = funcType->arg(naturalIdx); + if (type.isRefRepr()) { + void** rawArgLoc = (void**)&exportArgs[i]; + *rawArgLoc = refs[nextRef++]; + DebugCodegen(DebugChannel::Function, " ref(#%d) := %p ", + int(nextRef - 1), *rawArgLoc); + } + } + refs.clear(); + } + + DebugCodegen(DebugChannel::Function, "]\n"); + + // Ensure pending exception is cleared before and after (below) call. + MOZ_ASSERT(!pendingException_); + + { + JitActivation activation(cx); + + // Call the per-exported-function trampoline created by GenerateEntry. + auto funcPtr = JS_DATA_TO_FUNC_PTR(ExportFuncPtr, interpEntry); + if (!CALL_GENERATED_2(funcPtr, exportArgs.begin(), this)) { + return false; + } + } + + MOZ_ASSERT(!pendingException_); + + if (isAsmJS() && args.isConstructing()) { + // By spec, when a JS function is called as a constructor and this + // function returns a primary type, which is the case for all asm.js + // exported functions, the returned value is discarded and an empty + // object is returned instead. + PlainObject* obj = NewPlainObject(cx); + if (!obj) { + return false; + } + args.rval().set(ObjectValue(*obj)); + return true; + } + + // Note that we're not rooting the register result, if any; we depend + // on ResultsCollector::collect to root the value on our behalf, + // before causing any GC. + void* registerResultLoc = &exportArgs[0]; + DebugCodegen(DebugChannel::Function, "wasm-function[%d]; results [", + funcIndex); + if (!results.collect(cx, registerResultLoc, args.rval(), level)) { + return false; + } + DebugCodegen(DebugChannel::Function, "]\n"); + + return true; +} + +static JSObject* GetExceptionTag(JSObject* exn) { + return exn->is() ? &exn->as().tag() + : nullptr; +} + +void Instance::setPendingException(HandleAnyRef exn) { + pendingException_ = exn.get().asJSObject(); + pendingExceptionTag_ = GetExceptionTag(exn.get().asJSObject()); +} + +void Instance::constantGlobalGet(uint32_t globalIndex, + MutableHandleVal result) { + MOZ_RELEASE_ASSERT(globalIndex < maxInitializedGlobalsIndexPlus1_); + const GlobalDesc& global = metadata().globals[globalIndex]; + + // Constant globals are baked into the code and never stored in global data. + if (global.isConstant()) { + // We can just re-evaluate the global initializer to get the value. + result.set(Val(global.constantValue())); + return; + } + + // Otherwise, we need to load the initialized value from its cell. + const void* cell = addressOfGlobalCell(global); + result.address()->initFromHeapLocation(global.type(), cell); +} + +bool Instance::constantRefFunc(uint32_t funcIndex, + MutableHandleFuncRef result) { + void* fnref = Instance::refFunc(this, funcIndex); + if (fnref == AnyRef::invalid().forCompiledCode()) { + return false; // OOM, which has already been reported. + } + result.set(FuncRef::fromCompiledCode(fnref)); + return true; +} + +WasmStructObject* Instance::constantStructNewDefault(JSContext* cx, + uint32_t typeIndex) { + TypeDefInstanceData* typeDefData = typeDefInstanceData(typeIndex); + // We assume that constant structs will have a long lifetime and hence + // allocate them directly in the tenured heap. + return WasmStructObject::createStruct(cx, typeDefData, gc::Heap::Tenured); +} + +WasmArrayObject* Instance::constantArrayNewDefault(JSContext* cx, + uint32_t typeIndex, + uint32_t numElements) { + TypeDefInstanceData* typeDefData = typeDefInstanceData(typeIndex); + // We assume that constant arrays will have a long lifetime and hence + // allocate them directly in the tenured heap. + return WasmArrayObject::createArray(cx, typeDefData, gc::Heap::Tenured, + numElements); +} + +JSAtom* Instance::getFuncDisplayAtom(JSContext* cx, uint32_t funcIndex) const { + // The "display name" of a function is primarily shown in Error.stack which + // also includes location, so use getFuncNameBeforeLocation. + UTF8Bytes name; + if (!metadata().getFuncNameBeforeLocation(funcIndex, &name)) { + return nullptr; + } + + return AtomizeUTF8Chars(cx, name.begin(), name.length()); +} + +void Instance::ensureProfilingLabels(bool profilingEnabled) const { + return code_->ensureProfilingLabels(profilingEnabled); +} + +void Instance::onMovingGrowMemory() { + MOZ_ASSERT(!isAsmJS()); + MOZ_ASSERT(!memory_->isShared()); + + ArrayBufferObject& buffer = memory_->buffer().as(); + memoryBase_ = buffer.dataPointer(); + size_t limit = memory_->boundsCheckLimit(); +#if !defined(JS_64BIT) + // We assume that the limit is a 32-bit quantity + MOZ_ASSERT(limit <= UINT32_MAX); +#endif + boundsCheckLimit_ = limit; +} + +void Instance::onMovingGrowTable(const Table* theTable) { + MOZ_ASSERT(!isAsmJS()); + + // `theTable` has grown and we must update cached data for it. Importantly, + // we can have cached those data in more than one location: we'll have + // cached them once for each time the table was imported into this instance. + // + // When an instance is registered as an observer of a table it is only + // registered once, regardless of how many times the table was imported. + // Thus when a table is grown, onMovingGrowTable() is only invoked once for + // the table. + // + // Ergo we must go through the entire list of tables in the instance here + // and check for the table in all the cached-data slots; we can't exit after + // the first hit. + + for (uint32_t i = 0; i < tables_.length(); i++) { + if (tables_[i] == theTable) { + TableInstanceData& table = tableInstanceData(i); + table.length = tables_[i]->length(); + table.elements = tables_[i]->instanceElements(); + } + } +} + +JSString* Instance::createDisplayURL(JSContext* cx) { + // In the best case, we simply have a URL, from a streaming compilation of a + // fetched Response. + + if (metadata().filenameIsURL) { + const char* filename = metadata().filename.get(); + return NewStringCopyUTF8N(cx, JS::UTF8Chars(filename, strlen(filename))); + } + + // Otherwise, build wasm module URL from following parts: + // - "wasm:" as protocol; + // - URI encoded filename from metadata (if can be encoded), plus ":"; + // - 64-bit hash of the module bytes (as hex dump). + + JSStringBuilder result(cx); + if (!result.append("wasm:")) { + return nullptr; + } + + if (const char* filename = metadata().filename.get()) { + // EncodeURI returns false due to invalid chars or OOM -- fail only + // during OOM. + JSString* filenamePrefix = EncodeURI(cx, filename, strlen(filename)); + if (!filenamePrefix) { + if (cx->isThrowingOutOfMemory()) { + return nullptr; + } + + MOZ_ASSERT(!cx->isThrowingOverRecursed()); + cx->clearPendingException(); + return nullptr; + } + + if (!result.append(filenamePrefix)) { + return nullptr; + } + } + + if (metadata().debugEnabled) { + if (!result.append(":")) { + return nullptr; + } + + const ModuleHash& hash = metadata().debugHash; + for (unsigned char byte : hash) { + unsigned char digit1 = byte / 16, digit2 = byte % 16; + if (!result.append( + (char)(digit1 < 10 ? digit1 + '0' : digit1 + 'a' - 10))) { + return nullptr; + } + if (!result.append( + (char)(digit2 < 10 ? digit2 + '0' : digit2 + 'a' - 10))) { + return nullptr; + } + } + } + + return result.finishString(); +} + +WasmBreakpointSite* Instance::getOrCreateBreakpointSite(JSContext* cx, + uint32_t offset) { + MOZ_ASSERT(debugEnabled()); + return debug().getOrCreateBreakpointSite(cx, this, offset); +} + +void Instance::destroyBreakpointSite(JS::GCContext* gcx, uint32_t offset) { + MOZ_ASSERT(debugEnabled()); + return debug().destroyBreakpointSite(gcx, this, offset); +} + +void Instance::disassembleExport(JSContext* cx, uint32_t funcIndex, Tier tier, + PrintCallback printString) const { + const MetadataTier& metadataTier = metadata(tier); + const FuncExport& funcExport = metadataTier.lookupFuncExport(funcIndex); + const CodeRange& range = metadataTier.codeRange(funcExport); + const CodeTier& codeTier = code(tier); + const ModuleSegment& segment = codeTier.segment(); + + MOZ_ASSERT(range.begin() < segment.length()); + MOZ_ASSERT(range.end() < segment.length()); + + uint8_t* functionCode = segment.base() + range.begin(); + jit::Disassemble(functionCode, range.end() - range.begin(), printString); +} + +void Instance::addSizeOfMisc(MallocSizeOf mallocSizeOf, + Metadata::SeenSet* seenMetadata, + Code::SeenSet* seenCode, + Table::SeenSet* seenTables, size_t* code, + size_t* data) const { + *data += mallocSizeOf(this); + for (const SharedTable& table : tables_) { + *data += table->sizeOfIncludingThisIfNotSeen(mallocSizeOf, seenTables); + } + + if (maybeDebug_) { + maybeDebug_->addSizeOfMisc(mallocSizeOf, seenMetadata, seenCode, code, + data); + } + + code_->addSizeOfMiscIfNotSeen(mallocSizeOf, seenMetadata, seenCode, code, + data); +} + +////////////////////////////////////////////////////////////////////////////// +// +// Reporting of errors that are traps. + +void wasm::ReportTrapError(JSContext* cx, unsigned errorNumber) { + JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr, errorNumber); + + if (cx->isThrowingOutOfMemory()) { + return; + } + + // Mark the exception as thrown from a trap to prevent if from being handled + // by wasm exception handlers. + RootedValue exn(cx); + if (!cx->getPendingException(&exn)) { + return; + } + + MOZ_ASSERT(exn.isObject() && exn.toObject().is()); + exn.toObject().as().setFromWasmTrap(); +} -- cgit v1.2.3