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|
/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
*
* Copyright 2015 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/WasmGenerator.h"
#include "mozilla/CheckedInt.h"
#include "mozilla/EnumeratedRange.h"
#include <algorithm>
#include "wasm/WasmBaselineCompile.h"
#include "wasm/WasmIonCompile.h"
#include "wasm/WasmStubs.h"
#include "jit/MacroAssembler-inl.h"
using namespace js;
using namespace js::jit;
using namespace js::wasm;
using mozilla::CheckedInt;
using mozilla::MakeEnumeratedRange;
// ****************************************************************************
// ModuleGenerator
static const unsigned GENERATOR_LIFO_DEFAULT_CHUNK_SIZE = 4 * 1024;
static const unsigned COMPILATION_LIFO_DEFAULT_CHUNK_SIZE = 64 * 1024;
static const uint32_t BAD_CODE_RANGE = UINT32_MAX;
ModuleGenerator::ModuleGenerator(ImportVector&& imports)
: alwaysBaseline_(false),
imports_(Move(imports)),
numSigs_(0),
numTables_(0),
lifo_(GENERATOR_LIFO_DEFAULT_CHUNK_SIZE),
masmAlloc_(&lifo_),
masm_(MacroAssembler::WasmToken(), masmAlloc_),
lastPatchedCallsite_(0),
startOfUnpatchedCallsites_(0),
parallel_(false),
outstanding_(0),
activeFuncDef_(nullptr),
startedFuncDefs_(false),
finishedFuncDefs_(false),
numFinishedFuncDefs_(0)
{
MOZ_ASSERT(IsCompilingWasm());
}
ModuleGenerator::~ModuleGenerator()
{
if (parallel_) {
// Wait for any outstanding jobs to fail or complete.
if (outstanding_) {
AutoLockHelperThreadState lock;
while (true) {
IonCompileTaskPtrVector& worklist = HelperThreadState().wasmWorklist(lock);
MOZ_ASSERT(outstanding_ >= worklist.length());
outstanding_ -= worklist.length();
worklist.clear();
IonCompileTaskPtrVector& finished = HelperThreadState().wasmFinishedList(lock);
MOZ_ASSERT(outstanding_ >= finished.length());
outstanding_ -= finished.length();
finished.clear();
uint32_t numFailed = HelperThreadState().harvestFailedWasmJobs(lock);
MOZ_ASSERT(outstanding_ >= numFailed);
outstanding_ -= numFailed;
if (!outstanding_)
break;
HelperThreadState().wait(lock, GlobalHelperThreadState::CONSUMER);
}
}
MOZ_ASSERT(HelperThreadState().wasmCompilationInProgress);
HelperThreadState().wasmCompilationInProgress = false;
} else {
MOZ_ASSERT(!outstanding_);
}
}
bool
ModuleGenerator::init(UniqueModuleGeneratorData shared, const CompileArgs& args,
Metadata* maybeAsmJSMetadata)
{
shared_ = Move(shared);
alwaysBaseline_ = args.alwaysBaseline;
if (!exportedFuncs_.init())
return false;
if (!funcToCodeRange_.appendN(BAD_CODE_RANGE, shared_->funcSigs.length()))
return false;
linkData_.globalDataLength = AlignBytes(InitialGlobalDataBytes, sizeof(void*));;
// asm.js passes in an AsmJSMetadata subclass to use instead.
if (maybeAsmJSMetadata) {
metadata_ = maybeAsmJSMetadata;
MOZ_ASSERT(isAsmJS());
} else {
metadata_ = js_new<Metadata>();
if (!metadata_)
return false;
MOZ_ASSERT(!isAsmJS());
}
if (args.scriptedCaller.filename) {
metadata_->filename = DuplicateString(args.scriptedCaller.filename.get());
if (!metadata_->filename)
return false;
}
if (!assumptions_.clone(args.assumptions))
return false;
// For asm.js, the Vectors in ModuleGeneratorData are max-sized reservations
// and will be initialized in a linear order via init* functions as the
// module is generated. For wasm, the Vectors are correctly-sized and
// already initialized.
if (!isAsmJS()) {
numSigs_ = shared_->sigs.length();
numTables_ = shared_->tables.length();
for (size_t i = 0; i < shared_->funcImportGlobalDataOffsets.length(); i++) {
shared_->funcImportGlobalDataOffsets[i] = linkData_.globalDataLength;
linkData_.globalDataLength += sizeof(FuncImportTls);
if (!addFuncImport(*shared_->funcSigs[i], shared_->funcImportGlobalDataOffsets[i]))
return false;
}
for (const Import& import : imports_) {
if (import.kind == DefinitionKind::Table) {
MOZ_ASSERT(shared_->tables.length() == 1);
shared_->tables[0].external = true;
break;
}
}
for (TableDesc& table : shared_->tables) {
if (!allocateGlobalBytes(sizeof(TableTls), sizeof(void*), &table.globalDataOffset))
return false;
}
for (uint32_t i = 0; i < numSigs_; i++) {
SigWithId& sig = shared_->sigs[i];
if (SigIdDesc::isGlobal(sig)) {
uint32_t globalDataOffset;
if (!allocateGlobalBytes(sizeof(void*), sizeof(void*), &globalDataOffset))
return false;
sig.id = SigIdDesc::global(sig, globalDataOffset);
Sig copy;
if (!copy.clone(sig))
return false;
if (!metadata_->sigIds.emplaceBack(Move(copy), sig.id))
return false;
} else {
sig.id = SigIdDesc::immediate(sig);
}
}
for (GlobalDesc& global : shared_->globals) {
if (global.isConstant())
continue;
if (!allocateGlobal(&global))
return false;
}
} else {
MOZ_ASSERT(shared_->sigs.length() == MaxSigs);
MOZ_ASSERT(shared_->tables.length() == MaxTables);
MOZ_ASSERT(shared_->asmJSSigToTableIndex.length() == MaxSigs);
}
return true;
}
bool
ModuleGenerator::finishOutstandingTask()
{
MOZ_ASSERT(parallel_);
IonCompileTask* task = nullptr;
{
AutoLockHelperThreadState lock;
while (true) {
MOZ_ASSERT(outstanding_ > 0);
if (HelperThreadState().wasmFailed(lock))
return false;
if (!HelperThreadState().wasmFinishedList(lock).empty()) {
outstanding_--;
task = HelperThreadState().wasmFinishedList(lock).popCopy();
break;
}
HelperThreadState().wait(lock, GlobalHelperThreadState::CONSUMER);
}
}
return finishTask(task);
}
bool
ModuleGenerator::funcIsCompiled(uint32_t funcIndex) const
{
return funcToCodeRange_[funcIndex] != BAD_CODE_RANGE;
}
const CodeRange&
ModuleGenerator::funcCodeRange(uint32_t funcIndex) const
{
MOZ_ASSERT(funcIsCompiled(funcIndex));
const CodeRange& cr = metadata_->codeRanges[funcToCodeRange_[funcIndex]];
MOZ_ASSERT(cr.isFunction());
return cr;
}
static uint32_t
JumpRange()
{
return Min(JitOptions.jumpThreshold, JumpImmediateRange);
}
typedef HashMap<uint32_t, uint32_t, DefaultHasher<uint32_t>, SystemAllocPolicy> OffsetMap;
bool
ModuleGenerator::patchCallSites(TrapExitOffsetArray* maybeTrapExits)
{
MacroAssembler::AutoPrepareForPatching patching(masm_);
masm_.haltingAlign(CodeAlignment);
// Create far jumps for calls that have relative offsets that may otherwise
// go out of range. Far jumps are created for two cases: direct calls
// between function definitions and calls to trap exits by trap out-of-line
// paths. Far jump code is shared when possible to reduce bloat. This method
// is called both between function bodies (at a frequency determined by the
// ISA's jump range) and once at the very end of a module's codegen after
// all possible calls/traps have been emitted.
OffsetMap existingCallFarJumps;
if (!existingCallFarJumps.init())
return false;
EnumeratedArray<Trap, Trap::Limit, Maybe<uint32_t>> existingTrapFarJumps;
for (; lastPatchedCallsite_ < masm_.callSites().length(); lastPatchedCallsite_++) {
const CallSiteAndTarget& cs = masm_.callSites()[lastPatchedCallsite_];
uint32_t callerOffset = cs.returnAddressOffset();
MOZ_RELEASE_ASSERT(callerOffset < INT32_MAX);
switch (cs.kind()) {
case CallSiteDesc::Dynamic:
case CallSiteDesc::Symbolic:
break;
case CallSiteDesc::Func: {
if (funcIsCompiled(cs.funcIndex())) {
uint32_t calleeOffset = funcCodeRange(cs.funcIndex()).funcNonProfilingEntry();
MOZ_RELEASE_ASSERT(calleeOffset < INT32_MAX);
if (uint32_t(abs(int32_t(calleeOffset) - int32_t(callerOffset))) < JumpRange()) {
masm_.patchCall(callerOffset, calleeOffset);
break;
}
}
OffsetMap::AddPtr p = existingCallFarJumps.lookupForAdd(cs.funcIndex());
if (!p) {
Offsets offsets;
offsets.begin = masm_.currentOffset();
uint32_t jumpOffset = masm_.farJumpWithPatch().offset();
offsets.end = masm_.currentOffset();
if (masm_.oom())
return false;
if (!metadata_->codeRanges.emplaceBack(CodeRange::FarJumpIsland, offsets))
return false;
if (!existingCallFarJumps.add(p, cs.funcIndex(), offsets.begin))
return false;
// Record calls' far jumps in metadata since they must be
// repatched at runtime when profiling mode is toggled.
if (!metadata_->callThunks.emplaceBack(jumpOffset, cs.funcIndex()))
return false;
}
masm_.patchCall(callerOffset, p->value());
break;
}
case CallSiteDesc::TrapExit: {
if (maybeTrapExits) {
uint32_t calleeOffset = (*maybeTrapExits)[cs.trap()].begin;
MOZ_RELEASE_ASSERT(calleeOffset < INT32_MAX);
if (uint32_t(abs(int32_t(calleeOffset) - int32_t(callerOffset))) < JumpRange()) {
masm_.patchCall(callerOffset, calleeOffset);
break;
}
}
if (!existingTrapFarJumps[cs.trap()]) {
Offsets offsets;
offsets.begin = masm_.currentOffset();
masm_.append(TrapFarJump(cs.trap(), masm_.farJumpWithPatch()));
offsets.end = masm_.currentOffset();
if (masm_.oom())
return false;
if (!metadata_->codeRanges.emplaceBack(CodeRange::FarJumpIsland, offsets))
return false;
existingTrapFarJumps[cs.trap()] = Some(offsets.begin);
}
masm_.patchCall(callerOffset, *existingTrapFarJumps[cs.trap()]);
break;
}
}
}
return true;
}
bool
ModuleGenerator::patchFarJumps(const TrapExitOffsetArray& trapExits)
{
MacroAssembler::AutoPrepareForPatching patching(masm_);
for (CallThunk& callThunk : metadata_->callThunks) {
uint32_t funcIndex = callThunk.u.funcIndex;
callThunk.u.codeRangeIndex = funcToCodeRange_[funcIndex];
CodeOffset farJump(callThunk.offset);
masm_.patchFarJump(farJump, funcCodeRange(funcIndex).funcNonProfilingEntry());
}
for (const TrapFarJump& farJump : masm_.trapFarJumps())
masm_.patchFarJump(farJump.jump, trapExits[farJump.trap].begin);
return true;
}
bool
ModuleGenerator::finishTask(IonCompileTask* task)
{
const FuncBytes& func = task->func();
FuncCompileResults& results = task->results();
masm_.haltingAlign(CodeAlignment);
// Before merging in the new function's code, if calls in a prior function
// body might go out of range, insert far jumps to extend the range.
if ((masm_.size() - startOfUnpatchedCallsites_) + results.masm().size() > JumpRange()) {
startOfUnpatchedCallsites_ = masm_.size();
if (!patchCallSites())
return false;
}
// Offset the recorded FuncOffsets by the offset of the function in the
// whole module's code segment.
uint32_t offsetInWhole = masm_.size();
results.offsets().offsetBy(offsetInWhole);
// Add the CodeRange for this function.
uint32_t funcCodeRangeIndex = metadata_->codeRanges.length();
if (!metadata_->codeRanges.emplaceBack(func.index(), func.lineOrBytecode(), results.offsets()))
return false;
MOZ_ASSERT(!funcIsCompiled(func.index()));
funcToCodeRange_[func.index()] = funcCodeRangeIndex;
// Merge the compiled results into the whole-module masm.
mozilla::DebugOnly<size_t> sizeBefore = masm_.size();
if (!masm_.asmMergeWith(results.masm()))
return false;
MOZ_ASSERT(masm_.size() == offsetInWhole + results.masm().size());
freeTasks_.infallibleAppend(task);
return true;
}
bool
ModuleGenerator::finishFuncExports()
{
// In addition to all the functions that were explicitly exported, any
// element of an exported table is also exported.
for (ElemSegment& elems : elemSegments_) {
if (shared_->tables[elems.tableIndex].external) {
for (uint32_t funcIndex : elems.elemFuncIndices) {
if (!exportedFuncs_.put(funcIndex))
return false;
}
}
}
// ModuleGenerator::exportedFuncs_ is an unordered HashSet. The
// FuncExportVector stored in Metadata needs to be stored sorted by
// function index to allow O(log(n)) lookup at runtime.
Uint32Vector sorted;
if (!sorted.reserve(exportedFuncs_.count()))
return false;
for (Uint32Set::Range r = exportedFuncs_.all(); !r.empty(); r.popFront())
sorted.infallibleAppend(r.front());
std::sort(sorted.begin(), sorted.end());
MOZ_ASSERT(metadata_->funcExports.empty());
if (!metadata_->funcExports.reserve(sorted.length()))
return false;
for (uint32_t funcIndex : sorted) {
Sig sig;
if (!sig.clone(funcSig(funcIndex)))
return false;
uint32_t codeRangeIndex = funcToCodeRange_[funcIndex];
metadata_->funcExports.infallibleEmplaceBack(Move(sig), funcIndex, codeRangeIndex);
}
return true;
}
typedef Vector<Offsets, 0, SystemAllocPolicy> OffsetVector;
typedef Vector<ProfilingOffsets, 0, SystemAllocPolicy> ProfilingOffsetVector;
bool
ModuleGenerator::finishCodegen()
{
masm_.haltingAlign(CodeAlignment);
uint32_t offsetInWhole = masm_.size();
uint32_t numFuncExports = metadata_->funcExports.length();
MOZ_ASSERT(numFuncExports == exportedFuncs_.count());
// Generate stubs in a separate MacroAssembler since, otherwise, for modules
// larger than the JumpImmediateRange, even local uses of Label will fail
// due to the large absolute offsets temporarily stored by Label::bind().
OffsetVector entries;
ProfilingOffsetVector interpExits;
ProfilingOffsetVector jitExits;
TrapExitOffsetArray trapExits;
Offsets outOfBoundsExit;
Offsets unalignedAccessExit;
Offsets interruptExit;
Offsets throwStub;
{
TempAllocator alloc(&lifo_);
MacroAssembler masm(MacroAssembler::WasmToken(), alloc);
Label throwLabel;
if (!entries.resize(numFuncExports))
return false;
for (uint32_t i = 0; i < numFuncExports; i++)
entries[i] = GenerateEntry(masm, metadata_->funcExports[i]);
if (!interpExits.resize(numFuncImports()))
return false;
if (!jitExits.resize(numFuncImports()))
return false;
for (uint32_t i = 0; i < numFuncImports(); i++) {
interpExits[i] = GenerateImportInterpExit(masm, metadata_->funcImports[i], i, &throwLabel);
jitExits[i] = GenerateImportJitExit(masm, metadata_->funcImports[i], &throwLabel);
}
for (Trap trap : MakeEnumeratedRange(Trap::Limit))
trapExits[trap] = GenerateTrapExit(masm, trap, &throwLabel);
outOfBoundsExit = GenerateOutOfBoundsExit(masm, &throwLabel);
unalignedAccessExit = GenerateUnalignedExit(masm, &throwLabel);
interruptExit = GenerateInterruptExit(masm, &throwLabel);
throwStub = GenerateThrowStub(masm, &throwLabel);
if (masm.oom() || !masm_.asmMergeWith(masm))
return false;
}
// Adjust each of the resulting Offsets (to account for being merged into
// masm_) and then create code ranges for all the stubs.
for (uint32_t i = 0; i < numFuncExports; i++) {
entries[i].offsetBy(offsetInWhole);
metadata_->funcExports[i].initEntryOffset(entries[i].begin);
if (!metadata_->codeRanges.emplaceBack(CodeRange::Entry, entries[i]))
return false;
}
for (uint32_t i = 0; i < numFuncImports(); i++) {
interpExits[i].offsetBy(offsetInWhole);
metadata_->funcImports[i].initInterpExitOffset(interpExits[i].begin);
if (!metadata_->codeRanges.emplaceBack(CodeRange::ImportInterpExit, interpExits[i]))
return false;
jitExits[i].offsetBy(offsetInWhole);
metadata_->funcImports[i].initJitExitOffset(jitExits[i].begin);
if (!metadata_->codeRanges.emplaceBack(CodeRange::ImportJitExit, jitExits[i]))
return false;
}
for (Trap trap : MakeEnumeratedRange(Trap::Limit)) {
trapExits[trap].offsetBy(offsetInWhole);
if (!metadata_->codeRanges.emplaceBack(CodeRange::TrapExit, trapExits[trap]))
return false;
}
outOfBoundsExit.offsetBy(offsetInWhole);
if (!metadata_->codeRanges.emplaceBack(CodeRange::Inline, outOfBoundsExit))
return false;
unalignedAccessExit.offsetBy(offsetInWhole);
if (!metadata_->codeRanges.emplaceBack(CodeRange::Inline, unalignedAccessExit))
return false;
interruptExit.offsetBy(offsetInWhole);
if (!metadata_->codeRanges.emplaceBack(CodeRange::Inline, interruptExit))
return false;
throwStub.offsetBy(offsetInWhole);
if (!metadata_->codeRanges.emplaceBack(CodeRange::Inline, throwStub))
return false;
// Fill in LinkData with the offsets of these stubs.
linkData_.outOfBoundsOffset = outOfBoundsExit.begin;
linkData_.interruptOffset = interruptExit.begin;
// Now that all other code has been emitted, patch all remaining callsites
// then far jumps. Patching callsites can generate far jumps so there is an
// ordering dependency.
if (!patchCallSites(&trapExits))
return false;
if (!patchFarJumps(trapExits))
return false;
// Code-generation is complete!
masm_.finish();
return !masm_.oom();
}
bool
ModuleGenerator::finishLinkData(Bytes& code)
{
// Inflate the global bytes up to page size so that the total bytes are a
// page size (as required by the allocator functions).
linkData_.globalDataLength = AlignBytes(linkData_.globalDataLength, gc::SystemPageSize());
// Add links to absolute addresses identified symbolically.
for (size_t i = 0; i < masm_.numSymbolicAccesses(); i++) {
SymbolicAccess src = masm_.symbolicAccess(i);
if (!linkData_.symbolicLinks[src.target].append(src.patchAt.offset()))
return false;
}
// Relative link metadata: absolute addresses that refer to another point within
// the asm.js module.
// CodeLabels are used for switch cases and loads from floating-point /
// SIMD values in the constant pool.
for (size_t i = 0; i < masm_.numCodeLabels(); i++) {
CodeLabel cl = masm_.codeLabel(i);
LinkData::InternalLink inLink(LinkData::InternalLink::CodeLabel);
inLink.patchAtOffset = masm_.labelToPatchOffset(*cl.patchAt());
inLink.targetOffset = cl.target()->offset();
if (!linkData_.internalLinks.append(inLink))
return false;
}
#if defined(JS_CODEGEN_X86)
// Global data accesses in x86 need to be patched with the absolute
// address of the global. Globals are allocated sequentially after the
// code section so we can just use an InternalLink.
for (GlobalAccess a : masm_.globalAccesses()) {
LinkData::InternalLink inLink(LinkData::InternalLink::RawPointer);
inLink.patchAtOffset = masm_.labelToPatchOffset(a.patchAt);
inLink.targetOffset = code.length() + a.globalDataOffset;
if (!linkData_.internalLinks.append(inLink))
return false;
}
#elif defined(JS_CODEGEN_X64)
// Global data accesses on x64 use rip-relative addressing and thus we can
// patch here, now that we know the final codeLength.
for (GlobalAccess a : masm_.globalAccesses()) {
void* from = code.begin() + a.patchAt.offset();
void* to = code.end() + a.globalDataOffset;
X86Encoding::SetRel32(from, to);
}
#else
// Global access is performed using the GlobalReg and requires no patching.
MOZ_ASSERT(masm_.globalAccesses().length() == 0);
#endif
return true;
}
bool
ModuleGenerator::addFuncImport(const Sig& sig, uint32_t globalDataOffset)
{
MOZ_ASSERT(!finishedFuncDefs_);
Sig copy;
if (!copy.clone(sig))
return false;
return metadata_->funcImports.emplaceBack(Move(copy), globalDataOffset);
}
bool
ModuleGenerator::allocateGlobalBytes(uint32_t bytes, uint32_t align, uint32_t* globalDataOffset)
{
CheckedInt<uint32_t> newGlobalDataLength(linkData_.globalDataLength);
newGlobalDataLength += ComputeByteAlignment(newGlobalDataLength.value(), align);
if (!newGlobalDataLength.isValid())
return false;
*globalDataOffset = newGlobalDataLength.value();
newGlobalDataLength += bytes;
if (!newGlobalDataLength.isValid())
return false;
linkData_.globalDataLength = newGlobalDataLength.value();
return true;
}
bool
ModuleGenerator::allocateGlobal(GlobalDesc* global)
{
MOZ_ASSERT(!startedFuncDefs_);
unsigned width = 0;
switch (global->type()) {
case ValType::I32:
case ValType::F32:
width = 4;
break;
case ValType::I64:
case ValType::F64:
width = 8;
break;
case ValType::I8x16:
case ValType::I16x8:
case ValType::I32x4:
case ValType::F32x4:
case ValType::B8x16:
case ValType::B16x8:
case ValType::B32x4:
width = 16;
break;
}
uint32_t offset;
if (!allocateGlobalBytes(width, width, &offset))
return false;
global->setOffset(offset);
return true;
}
bool
ModuleGenerator::addGlobal(ValType type, bool isConst, uint32_t* index)
{
MOZ_ASSERT(isAsmJS());
MOZ_ASSERT(!startedFuncDefs_);
*index = shared_->globals.length();
GlobalDesc global(type, !isConst, *index);
if (!allocateGlobal(&global))
return false;
return shared_->globals.append(global);
}
void
ModuleGenerator::initSig(uint32_t sigIndex, Sig&& sig)
{
MOZ_ASSERT(isAsmJS());
MOZ_ASSERT(sigIndex == numSigs_);
numSigs_++;
MOZ_ASSERT(shared_->sigs[sigIndex] == Sig());
shared_->sigs[sigIndex] = Move(sig);
}
const SigWithId&
ModuleGenerator::sig(uint32_t index) const
{
MOZ_ASSERT(index < numSigs_);
return shared_->sigs[index];
}
void
ModuleGenerator::initFuncSig(uint32_t funcIndex, uint32_t sigIndex)
{
MOZ_ASSERT(isAsmJS());
MOZ_ASSERT(!shared_->funcSigs[funcIndex]);
shared_->funcSigs[funcIndex] = &shared_->sigs[sigIndex];
}
void
ModuleGenerator::initMemoryUsage(MemoryUsage memoryUsage)
{
MOZ_ASSERT(isAsmJS());
MOZ_ASSERT(shared_->memoryUsage == MemoryUsage::None);
shared_->memoryUsage = memoryUsage;
}
void
ModuleGenerator::bumpMinMemoryLength(uint32_t newMinMemoryLength)
{
MOZ_ASSERT(isAsmJS());
MOZ_ASSERT(newMinMemoryLength >= shared_->minMemoryLength);
shared_->minMemoryLength = newMinMemoryLength;
}
bool
ModuleGenerator::initImport(uint32_t funcIndex, uint32_t sigIndex)
{
MOZ_ASSERT(isAsmJS());
MOZ_ASSERT(!shared_->funcSigs[funcIndex]);
shared_->funcSigs[funcIndex] = &shared_->sigs[sigIndex];
uint32_t globalDataOffset;
if (!allocateGlobalBytes(sizeof(FuncImportTls), sizeof(void*), &globalDataOffset))
return false;
MOZ_ASSERT(!shared_->funcImportGlobalDataOffsets[funcIndex]);
shared_->funcImportGlobalDataOffsets[funcIndex] = globalDataOffset;
MOZ_ASSERT(funcIndex == metadata_->funcImports.length());
return addFuncImport(sig(sigIndex), globalDataOffset);
}
uint32_t
ModuleGenerator::numFuncImports() const
{
// Until all functions have been validated, asm.js doesn't know the total
// number of imports.
MOZ_ASSERT_IF(isAsmJS(), finishedFuncDefs_);
return metadata_->funcImports.length();
}
uint32_t
ModuleGenerator::numFuncDefs() const
{
// asm.js overallocates the length of funcSigs and in general does not know
// the number of function definitions until it's done compiling.
MOZ_ASSERT(!isAsmJS());
return shared_->funcSigs.length() - numFuncImports();
}
uint32_t
ModuleGenerator::numFuncs() const
{
// asm.js pre-reserves a bunch of function index space which is
// incrementally filled in during function-body validation. Thus, there are
// a few possible interpretations of numFuncs() (total index space size vs.
// exact number of imports/definitions encountered so far) and to simplify
// things we simply only define this quantity for wasm.
MOZ_ASSERT(!isAsmJS());
return shared_->funcSigs.length();
}
const SigWithId&
ModuleGenerator::funcSig(uint32_t funcIndex) const
{
MOZ_ASSERT(shared_->funcSigs[funcIndex]);
return *shared_->funcSigs[funcIndex];
}
bool
ModuleGenerator::addFuncExport(UniqueChars fieldName, uint32_t funcIndex)
{
return exportedFuncs_.put(funcIndex) &&
exports_.emplaceBack(Move(fieldName), funcIndex, DefinitionKind::Function);
}
bool
ModuleGenerator::addTableExport(UniqueChars fieldName)
{
MOZ_ASSERT(!startedFuncDefs_);
MOZ_ASSERT(shared_->tables.length() == 1);
shared_->tables[0].external = true;
return exports_.emplaceBack(Move(fieldName), DefinitionKind::Table);
}
bool
ModuleGenerator::addMemoryExport(UniqueChars fieldName)
{
return exports_.emplaceBack(Move(fieldName), DefinitionKind::Memory);
}
bool
ModuleGenerator::addGlobalExport(UniqueChars fieldName, uint32_t globalIndex)
{
return exports_.emplaceBack(Move(fieldName), globalIndex, DefinitionKind::Global);
}
bool
ModuleGenerator::setStartFunction(uint32_t funcIndex)
{
metadata_->startFuncIndex.emplace(funcIndex);
return exportedFuncs_.put(funcIndex);
}
bool
ModuleGenerator::addElemSegment(InitExpr offset, Uint32Vector&& elemFuncIndices)
{
MOZ_ASSERT(!isAsmJS());
MOZ_ASSERT(!startedFuncDefs_);
MOZ_ASSERT(shared_->tables.length() == 1);
for (uint32_t funcIndex : elemFuncIndices) {
if (funcIndex < numFuncImports()) {
shared_->tables[0].external = true;
break;
}
}
return elemSegments_.emplaceBack(0, offset, Move(elemFuncIndices));
}
void
ModuleGenerator::setDataSegments(DataSegmentVector&& segments)
{
MOZ_ASSERT(dataSegments_.empty());
dataSegments_ = Move(segments);
}
bool
ModuleGenerator::startFuncDefs()
{
MOZ_ASSERT(!startedFuncDefs_);
MOZ_ASSERT(!finishedFuncDefs_);
// The wasmCompilationInProgress atomic ensures that there is only one
// parallel compilation in progress at a time. In the special case of
// asm.js, where the ModuleGenerator itself can be on a helper thread, this
// avoids the possibility of deadlock since at most 1 helper thread will be
// blocking on other helper threads and there are always >1 helper threads.
// With wasm, this restriction could be relaxed by moving the worklist state
// out of HelperThreadState since each independent compilation needs its own
// worklist pair. Alternatively, the deadlock could be avoided by having the
// ModuleGenerator thread make progress (on compile tasks) instead of
// blocking.
GlobalHelperThreadState& threads = HelperThreadState();
MOZ_ASSERT(threads.threadCount > 1);
uint32_t numTasks;
if (CanUseExtraThreads() && threads.wasmCompilationInProgress.compareExchange(false, true)) {
#ifdef DEBUG
{
AutoLockHelperThreadState lock;
MOZ_ASSERT(!HelperThreadState().wasmFailed(lock));
MOZ_ASSERT(HelperThreadState().wasmWorklist(lock).empty());
MOZ_ASSERT(HelperThreadState().wasmFinishedList(lock).empty());
}
#endif
parallel_ = true;
numTasks = 2 * threads.maxWasmCompilationThreads();
} else {
numTasks = 1;
}
if (!tasks_.initCapacity(numTasks))
return false;
for (size_t i = 0; i < numTasks; i++)
tasks_.infallibleEmplaceBack(*shared_, COMPILATION_LIFO_DEFAULT_CHUNK_SIZE);
if (!freeTasks_.reserve(numTasks))
return false;
for (size_t i = 0; i < numTasks; i++)
freeTasks_.infallibleAppend(&tasks_[i]);
startedFuncDefs_ = true;
MOZ_ASSERT(!finishedFuncDefs_);
return true;
}
bool
ModuleGenerator::startFuncDef(uint32_t lineOrBytecode, FunctionGenerator* fg)
{
MOZ_ASSERT(startedFuncDefs_);
MOZ_ASSERT(!activeFuncDef_);
MOZ_ASSERT(!finishedFuncDefs_);
if (freeTasks_.empty() && !finishOutstandingTask())
return false;
IonCompileTask* task = freeTasks_.popCopy();
task->reset(&fg->bytes_);
fg->bytes_.clear();
fg->lineOrBytecode_ = lineOrBytecode;
fg->m_ = this;
fg->task_ = task;
activeFuncDef_ = fg;
return true;
}
bool
ModuleGenerator::finishFuncDef(uint32_t funcIndex, FunctionGenerator* fg)
{
MOZ_ASSERT(activeFuncDef_ == fg);
auto func = js::MakeUnique<FuncBytes>(Move(fg->bytes_),
funcIndex,
funcSig(funcIndex),
fg->lineOrBytecode_,
Move(fg->callSiteLineNums_));
if (!func)
return false;
auto mode = alwaysBaseline_ && BaselineCanCompile(fg)
? IonCompileTask::CompileMode::Baseline
: IonCompileTask::CompileMode::Ion;
fg->task_->init(Move(func), mode);
if (parallel_) {
if (!StartOffThreadWasmCompile(fg->task_))
return false;
outstanding_++;
} else {
if (!CompileFunction(fg->task_))
return false;
if (!finishTask(fg->task_))
return false;
}
fg->m_ = nullptr;
fg->task_ = nullptr;
activeFuncDef_ = nullptr;
numFinishedFuncDefs_++;
return true;
}
bool
ModuleGenerator::finishFuncDefs()
{
MOZ_ASSERT(startedFuncDefs_);
MOZ_ASSERT(!activeFuncDef_);
MOZ_ASSERT(!finishedFuncDefs_);
while (outstanding_ > 0) {
if (!finishOutstandingTask())
return false;
}
linkData_.functionCodeLength = masm_.size();
finishedFuncDefs_ = true;
// Generate wrapper functions for every import. These wrappers turn imports
// into plain functions so they can be put into tables and re-exported.
// asm.js cannot do either and so no wrappers are generated.
if (!isAsmJS()) {
for (size_t funcIndex = 0; funcIndex < numFuncImports(); funcIndex++) {
const FuncImport& funcImport = metadata_->funcImports[funcIndex];
const SigWithId& sig = funcSig(funcIndex);
FuncOffsets offsets = GenerateImportFunction(masm_, funcImport, sig.id);
if (masm_.oom())
return false;
uint32_t codeRangeIndex = metadata_->codeRanges.length();
if (!metadata_->codeRanges.emplaceBack(funcIndex, /* bytecodeOffset = */ 0, offsets))
return false;
MOZ_ASSERT(!funcIsCompiled(funcIndex));
funcToCodeRange_[funcIndex] = codeRangeIndex;
}
}
// All function indices should have an associated code range at this point
// (except in asm.js, which doesn't have import wrapper functions).
#ifdef DEBUG
if (isAsmJS()) {
MOZ_ASSERT(numFuncImports() < AsmJSFirstDefFuncIndex);
for (uint32_t i = 0; i < AsmJSFirstDefFuncIndex; i++)
MOZ_ASSERT(funcToCodeRange_[i] == BAD_CODE_RANGE);
for (uint32_t i = AsmJSFirstDefFuncIndex; i < numFinishedFuncDefs_; i++)
MOZ_ASSERT(funcCodeRange(i).funcIndex() == i);
} else {
MOZ_ASSERT(numFinishedFuncDefs_ == numFuncDefs());
for (uint32_t i = 0; i < numFuncs(); i++)
MOZ_ASSERT(funcCodeRange(i).funcIndex() == i);
}
#endif
// Complete element segments with the code range index of every element, now
// that all functions have been compiled.
for (ElemSegment& elems : elemSegments_) {
Uint32Vector& codeRangeIndices = elems.elemCodeRangeIndices;
MOZ_ASSERT(codeRangeIndices.empty());
if (!codeRangeIndices.reserve(elems.elemFuncIndices.length()))
return false;
for (uint32_t funcIndex : elems.elemFuncIndices)
codeRangeIndices.infallibleAppend(funcToCodeRange_[funcIndex]);
}
return true;
}
void
ModuleGenerator::setFuncNames(NameInBytecodeVector&& funcNames)
{
MOZ_ASSERT(metadata_->funcNames.empty());
metadata_->funcNames = Move(funcNames);
}
bool
ModuleGenerator::initSigTableLength(uint32_t sigIndex, uint32_t length)
{
MOZ_ASSERT(isAsmJS());
MOZ_ASSERT(length != 0);
MOZ_ASSERT(length <= MaxTableElems);
MOZ_ASSERT(shared_->asmJSSigToTableIndex[sigIndex] == 0);
shared_->asmJSSigToTableIndex[sigIndex] = numTables_;
TableDesc& table = shared_->tables[numTables_++];
table.kind = TableKind::TypedFunction;
table.limits.initial = length;
table.limits.maximum = Some(length);
return allocateGlobalBytes(sizeof(TableTls), sizeof(void*), &table.globalDataOffset);
}
bool
ModuleGenerator::initSigTableElems(uint32_t sigIndex, Uint32Vector&& elemFuncIndices)
{
MOZ_ASSERT(isAsmJS());
MOZ_ASSERT(finishedFuncDefs_);
uint32_t tableIndex = shared_->asmJSSigToTableIndex[sigIndex];
MOZ_ASSERT(shared_->tables[tableIndex].limits.initial == elemFuncIndices.length());
Uint32Vector codeRangeIndices;
if (!codeRangeIndices.resize(elemFuncIndices.length()))
return false;
for (size_t i = 0; i < elemFuncIndices.length(); i++)
codeRangeIndices[i] = funcToCodeRange_[elemFuncIndices[i]];
InitExpr offset(Val(uint32_t(0)));
if (!elemSegments_.emplaceBack(tableIndex, offset, Move(elemFuncIndices)))
return false;
elemSegments_.back().elemCodeRangeIndices = Move(codeRangeIndices);
return true;
}
SharedModule
ModuleGenerator::finish(const ShareableBytes& bytecode)
{
MOZ_ASSERT(!activeFuncDef_);
MOZ_ASSERT(finishedFuncDefs_);
if (!finishFuncExports())
return nullptr;
if (!finishCodegen())
return nullptr;
// Round up the code size to page size since this is eventually required by
// the executable-code allocator and for setting memory protection.
uint32_t bytesNeeded = masm_.bytesNeeded();
uint32_t padding = ComputeByteAlignment(bytesNeeded, gc::SystemPageSize());
// Use initLengthUninitialized so there is no round-up allocation nor time
// wasted zeroing memory.
Bytes code;
if (!code.initLengthUninitialized(bytesNeeded + padding))
return nullptr;
// Delay flushing of the icache until CodeSegment::create since there is
// more patching to do before this code becomes executable.
{
AutoFlushICache afc("ModuleGenerator::finish", /* inhibit = */ true);
masm_.executableCopy(code.begin());
}
// Zero the padding, since we used resizeUninitialized above.
memset(code.begin() + bytesNeeded, 0, padding);
// Convert the CallSiteAndTargetVector (needed during generation) to a
// CallSiteVector (what is stored in the Module).
if (!metadata_->callSites.appendAll(masm_.callSites()))
return nullptr;
// The MacroAssembler has accumulated all the memory accesses during codegen.
metadata_->memoryAccesses = masm_.extractMemoryAccesses();
metadata_->memoryPatches = masm_.extractMemoryPatches();
metadata_->boundsChecks = masm_.extractBoundsChecks();
// Copy over data from the ModuleGeneratorData.
metadata_->memoryUsage = shared_->memoryUsage;
metadata_->minMemoryLength = shared_->minMemoryLength;
metadata_->maxMemoryLength = shared_->maxMemoryLength;
metadata_->tables = Move(shared_->tables);
metadata_->globals = Move(shared_->globals);
// These Vectors can get large and the excess capacity can be significant,
// so realloc them down to size.
metadata_->memoryAccesses.podResizeToFit();
metadata_->memoryPatches.podResizeToFit();
metadata_->boundsChecks.podResizeToFit();
metadata_->codeRanges.podResizeToFit();
metadata_->callSites.podResizeToFit();
metadata_->callThunks.podResizeToFit();
// For asm.js, the tables vector is over-allocated (to avoid resize during
// parallel copilation). Shrink it back down to fit.
if (isAsmJS() && !metadata_->tables.resize(numTables_))
return nullptr;
// Assert CodeRanges are sorted.
#ifdef DEBUG
uint32_t lastEnd = 0;
for (const CodeRange& codeRange : metadata_->codeRanges) {
MOZ_ASSERT(codeRange.begin() >= lastEnd);
lastEnd = codeRange.end();
}
#endif
if (!finishLinkData(code))
return nullptr;
return SharedModule(js_new<Module>(Move(assumptions_),
Move(code),
Move(linkData_),
Move(imports_),
Move(exports_),
Move(dataSegments_),
Move(elemSegments_),
*metadata_,
bytecode));
}
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