/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- * vim: set ts=8 sts=2 et sw=2 tw=80: * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "frontend/BytecodeSection.h" #include "mozilla/Assertions.h" // MOZ_ASSERT #include "frontend/AbstractScopePtr.h" // ScopeIndex #include "frontend/CompilationStencil.h" // CompilationStencil #include "frontend/FrontendContext.h" // FrontendContext #include "frontend/SharedContext.h" // FunctionBox #include "vm/BytecodeUtil.h" // INDEX_LIMIT, StackUses, StackDefs #include "vm/GlobalObject.h" #include "vm/JSContext.h" // JSContext #include "vm/RegExpObject.h" // RegexpObject #include "vm/Scope.h" // GlobalScope using namespace js; using namespace js::frontend; bool GCThingList::append(FunctionBox* funbox, GCThingIndex* index) { // Append the function to the vector and return the index in *index. *index = GCThingIndex(vector.length()); if (!vector.emplaceBack(funbox->index())) { return false; } return true; } AbstractScopePtr GCThingList::getScope(size_t index) const { const TaggedScriptThingIndex& elem = vector[index]; if (elem.isEmptyGlobalScope()) { // The empty enclosing scope should be stored by // CompilationInput::initForSelfHostingGlobal. return AbstractScopePtr::compilationEnclosingScope(compilationState); } return AbstractScopePtr(compilationState, elem.toScope()); } mozilla::Maybe GCThingList::getScopeIndex(size_t index) const { const TaggedScriptThingIndex& elem = vector[index]; if (elem.isEmptyGlobalScope()) { return mozilla::Nothing(); } return mozilla::Some(vector[index].toScope()); } TaggedParserAtomIndex GCThingList::getAtom(size_t index) const { const TaggedScriptThingIndex& elem = vector[index]; return elem.toAtom(); } bool js::frontend::EmitScriptThingsVector( JSContext* cx, const CompilationAtomCache& atomCache, const CompilationStencil& stencil, CompilationGCOutput& gcOutput, mozilla::Span things, mozilla::Span output) { MOZ_ASSERT(things.size() <= INDEX_LIMIT); MOZ_ASSERT(things.size() == output.size()); for (uint32_t i = 0; i < things.size(); i++) { const auto& thing = things[i]; switch (thing.tag()) { case TaggedScriptThingIndex::Kind::ParserAtomIndex: case TaggedScriptThingIndex::Kind::WellKnown: { JSString* str = atomCache.getExistingStringAt(cx, thing.toAtom()); MOZ_ASSERT(str); output[i] = JS::GCCellPtr(str); break; } case TaggedScriptThingIndex::Kind::Null: output[i] = JS::GCCellPtr(nullptr); break; case TaggedScriptThingIndex::Kind::BigInt: { const BigIntStencil& data = stencil.bigIntData[thing.toBigInt()]; BigInt* bi = data.createBigInt(cx); if (!bi) { return false; } output[i] = JS::GCCellPtr(bi); break; } case TaggedScriptThingIndex::Kind::ObjLiteral: { const ObjLiteralStencil& data = stencil.objLiteralData[thing.toObjLiteral()]; JS::GCCellPtr ptr = data.create(cx, atomCache); if (!ptr) { return false; } output[i] = ptr; break; } case TaggedScriptThingIndex::Kind::RegExp: { RegExpStencil& data = stencil.regExpData[thing.toRegExp()]; RegExpObject* regexp = data.createRegExp(cx, atomCache); if (!regexp) { return false; } output[i] = JS::GCCellPtr(regexp); break; } case TaggedScriptThingIndex::Kind::Scope: output[i] = JS::GCCellPtr(gcOutput.getScope(thing.toScope())); break; case TaggedScriptThingIndex::Kind::Function: output[i] = JS::GCCellPtr(gcOutput.getFunction(thing.toFunction())); break; case TaggedScriptThingIndex::Kind::EmptyGlobalScope: { Scope* scope = &cx->global()->emptyGlobalScope(); output[i] = JS::GCCellPtr(scope); break; } } } return true; } bool CGTryNoteList::append(TryNoteKind kind, uint32_t stackDepth, BytecodeOffset start, BytecodeOffset end) { MOZ_ASSERT(start <= end); // Offsets are given relative to sections, but we only expect main-section // to have TryNotes. In finish() we will fixup base offset. TryNote note(uint32_t(kind), stackDepth, start.toUint32(), (end - start).toUint32()); return list.append(note); } bool CGScopeNoteList::append(GCThingIndex scopeIndex, BytecodeOffset offset, uint32_t parent) { ScopeNote note; note.index = scopeIndex; note.start = offset.toUint32(); note.length = 0; note.parent = parent; return list.append(note); } void CGScopeNoteList::recordEnd(uint32_t index, BytecodeOffset offset) { recordEndImpl(index, offset.toUint32()); } void CGScopeNoteList::recordEndFunctionBodyVar(uint32_t index) { recordEndImpl(index, UINT32_MAX); } void CGScopeNoteList::recordEndImpl(uint32_t index, uint32_t offset) { MOZ_ASSERT(index < length()); MOZ_ASSERT(list[index].length == 0); MOZ_ASSERT(offset >= list[index].start); list[index].length = offset - list[index].start; } BytecodeSection::BytecodeSection(FrontendContext* fc, uint32_t lineNum, uint32_t column) : code_(fc), notes_(fc), lastNoteOffset_(0), tryNoteList_(fc), scopeNoteList_(fc), resumeOffsetList_(fc), currentLine_(lineNum), lastColumn_(column) {} void BytecodeSection::updateDepth(BytecodeOffset target) { jsbytecode* pc = code(target); int nuses = StackUses(pc); int ndefs = StackDefs(pc); stackDepth_ -= nuses; MOZ_ASSERT(stackDepth_ >= 0); stackDepth_ += ndefs; if (uint32_t(stackDepth_) > maxStackDepth_) { maxStackDepth_ = stackDepth_; } } PerScriptData::PerScriptData(FrontendContext* fc, frontend::CompilationState& compilationState) : gcThingList_(fc, compilationState), atomIndices_(fc->nameCollectionPool()) {} bool PerScriptData::init(FrontendContext* fc) { return atomIndices_.acquire(fc); }