/* -*- 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 "jit/MIRGraph.h" #include "jit/CompileInfo.h" #include "jit/InlineScriptTree.h" #include "jit/IonOptimizationLevels.h" #include "jit/JitSpewer.h" #include "jit/MIR.h" #include "jit/MIRGenerator.h" using namespace js; using namespace js::jit; MIRGenerator::MIRGenerator(CompileRealm* realm, const JitCompileOptions& options, TempAllocator* alloc, MIRGraph* graph, const CompileInfo* info, const OptimizationInfo* optimizationInfo) : realm(realm), runtime(realm ? realm->runtime() : nullptr), outerInfo_(info), optimizationInfo_(optimizationInfo), alloc_(alloc), graph_(graph), offThreadStatus_(Ok()), cancelBuild_(false), wasmMaxStackArgBytes_(0), needsOverrecursedCheck_(false), needsStaticStackAlignment_(false), instrumentedProfiling_(false), instrumentedProfilingIsCached_(false), stringsCanBeInNursery_(realm ? realm->zone()->canNurseryAllocateStrings() : false), bigIntsCanBeInNursery_(realm ? realm->zone()->canNurseryAllocateBigInts() : false), minWasmHeapLength_(0), options(options), gs_(alloc) {} bool MIRGenerator::licmEnabled() const { return optimizationInfo().licmEnabled() && !disableLICM_ && !outerInfo().hadLICMInvalidation(); } mozilla::GenericErrorResult MIRGenerator::abort(AbortReason r) { if (JitSpewEnabled(JitSpew_IonAbort)) { switch (r) { case AbortReason::Alloc: JitSpew(JitSpew_IonAbort, "AbortReason::Alloc"); break; case AbortReason::Disable: JitSpew(JitSpew_IonAbort, "AbortReason::Disable"); break; case AbortReason::Error: JitSpew(JitSpew_IonAbort, "AbortReason::Error"); break; case AbortReason::NoAbort: MOZ_CRASH("Abort with AbortReason::NoAbort"); break; } } return Err(std::move(r)); } mozilla::GenericErrorResult MIRGenerator::abortFmt( AbortReason r, const char* message, va_list ap) { JitSpewVA(JitSpew_IonAbort, message, ap); return Err(std::move(r)); } mozilla::GenericErrorResult MIRGenerator::abort( AbortReason r, const char* message, ...) { va_list ap; va_start(ap, message); auto forward = abortFmt(r, message, ap); va_end(ap); return forward; } void MIRGraph::addBlock(MBasicBlock* block) { MOZ_ASSERT(block); block->setId(blockIdGen_++); blocks_.pushBack(block); numBlocks_++; } void MIRGraph::insertBlockAfter(MBasicBlock* at, MBasicBlock* block) { block->setId(blockIdGen_++); blocks_.insertAfter(at, block); numBlocks_++; } void MIRGraph::insertBlockBefore(MBasicBlock* at, MBasicBlock* block) { block->setId(blockIdGen_++); blocks_.insertBefore(at, block); numBlocks_++; } void MIRGraph::removeBlock(MBasicBlock* block) { // Remove a block from the graph. It will also cleanup the block. if (block == osrBlock_) { osrBlock_ = nullptr; } if (returnAccumulator_) { size_t i = 0; while (i < returnAccumulator_->length()) { if ((*returnAccumulator_)[i] == block) { returnAccumulator_->erase(returnAccumulator_->begin() + i); } else { i++; } } } block->clear(); block->markAsDead(); if (block->isInList()) { blocks_.remove(block); numBlocks_--; } } void MIRGraph::unmarkBlocks() { for (MBasicBlockIterator i(blocks_.begin()); i != blocks_.end(); i++) { i->unmark(); } } MBasicBlock* MBasicBlock::New(MIRGraph& graph, size_t stackDepth, const CompileInfo& info, MBasicBlock* maybePred, BytecodeSite* site, Kind kind) { MOZ_ASSERT(site->pc() != nullptr); MBasicBlock* block = new (graph.alloc()) MBasicBlock(graph, info, site, kind); if (!block->init()) { return nullptr; } if (!block->inherit(graph.alloc(), stackDepth, maybePred, 0)) { return nullptr; } return block; } MBasicBlock* MBasicBlock::NewPopN(MIRGraph& graph, const CompileInfo& info, MBasicBlock* pred, BytecodeSite* site, Kind kind, uint32_t popped) { MOZ_ASSERT(site->pc() != nullptr); MBasicBlock* block = new (graph.alloc()) MBasicBlock(graph, info, site, kind); if (!block->init()) { return nullptr; } if (!block->inherit(graph.alloc(), pred->stackDepth(), pred, popped)) { return nullptr; } return block; } MBasicBlock* MBasicBlock::NewPendingLoopHeader(MIRGraph& graph, const CompileInfo& info, MBasicBlock* pred, BytecodeSite* site) { MOZ_ASSERT(site->pc() != nullptr); MBasicBlock* block = new (graph.alloc()) MBasicBlock(graph, info, site, PENDING_LOOP_HEADER); if (!block->init()) { return nullptr; } if (!block->inherit(graph.alloc(), pred->stackDepth(), pred, 0)) { return nullptr; } return block; } MBasicBlock* MBasicBlock::NewSplitEdge(MIRGraph& graph, MBasicBlock* pred, size_t predEdgeIdx, MBasicBlock* succ) { MBasicBlock* split = nullptr; if (!succ->pc()) { // The predecessor does not have a PC, this is a Wasm compilation. split = MBasicBlock::New(graph, succ->info(), pred, SPLIT_EDGE); if (!split) { return nullptr; } // Insert the split edge block in-between. split->end(MGoto::New(graph.alloc(), succ)); } else { // The predecessor has a PC, this is a Warp compilation. MResumePoint* succEntry = succ->entryResumePoint(); BytecodeSite* site = new (graph.alloc()) BytecodeSite(succ->trackedTree(), succEntry->pc()); split = new (graph.alloc()) MBasicBlock(graph, succ->info(), site, SPLIT_EDGE); if (!split->init()) { return nullptr; } // A split edge is used to simplify the graph to avoid having a // predecessor with multiple successors as well as a successor with // multiple predecessors. As instructions can be moved in this // split-edge block, we need to give this block a resume point. To do // so, we copy the entry resume points of the successor and filter the // phis to keep inputs from the current edge. // Propagate the caller resume point from the inherited block. split->callerResumePoint_ = succ->callerResumePoint(); // Split-edge are created after the interpreter stack emulation. Thus, // there is no need for creating slots. split->stackPosition_ = succEntry->stackDepth(); // Create a resume point using our initial stack position. MResumePoint* splitEntry = new (graph.alloc()) MResumePoint(split, succEntry->pc(), ResumeMode::ResumeAt); if (!splitEntry->init(graph.alloc())) { return nullptr; } split->entryResumePoint_ = splitEntry; // Insert the split edge block in-between. split->end(MGoto::New(graph.alloc(), succ)); // The target entry resume point might have phi operands, keep the // operands of the phi coming from our edge. size_t succEdgeIdx = succ->indexForPredecessor(pred); for (size_t i = 0, e = splitEntry->numOperands(); i < e; i++) { MDefinition* def = succEntry->getOperand(i); // This early in the pipeline, we have no recover instructions in // any entry resume point. if (def->block() == succ) { if (def->isPhi()) { def = def->toPhi()->getOperand(succEdgeIdx); } else { // The phi-operand may already have been optimized out. MOZ_ASSERT(def->isConstant()); MOZ_ASSERT(def->type() == MIRType::MagicOptimizedOut); def = split->optimizedOutConstant(graph.alloc()); } } splitEntry->initOperand(i, def); } // This is done in the New variant for wasm, so we cannot keep this // line below, where the rest of the graph is modified. if (!split->predecessors_.append(pred)) { return nullptr; } } split->setLoopDepth(succ->loopDepth()); graph.insertBlockAfter(pred, split); pred->replaceSuccessor(predEdgeIdx, split); succ->replacePredecessor(pred, split); return split; } void MBasicBlock::moveToNewBlock(MInstruction* ins, MBasicBlock* dst) { MOZ_ASSERT(ins->block() == this); MOZ_ASSERT(!dst->hasLastIns()); instructions_.remove(ins); ins->setInstructionBlock(dst, dst->trackedSite()); if (MResumePoint* rp = ins->resumePoint()) { removeResumePoint(rp); dst->addResumePoint(rp); rp->setBlock(dst); } dst->instructions_.pushBack(ins); } void MBasicBlock::moveOuterResumePointTo(MBasicBlock* dest) { if (MResumePoint* outer = outerResumePoint()) { removeResumePoint(outer); outerResumePoint_ = nullptr; dest->setOuterResumePoint(outer); dest->addResumePoint(outer); outer->setBlock(dest); } } bool MBasicBlock::wrapInstructionInFastpath(MInstruction* ins, MInstruction* fastpath, MInstruction* condition) { MOZ_ASSERT(ins->block() == this); MOZ_ASSERT(!ins->isControlInstruction()); MInstructionIterator rest(begin(ins)); rest++; MResumePoint* resumeBeforeIns = activeResumePoint(ins); MResumePoint* resumeAfterIns = activeResumePoint(*rest); // Create the join block. MBasicBlock* join = MBasicBlock::NewInternal(graph_, this, resumeAfterIns); if (!join) { return false; } // Update the successors of the current block. for (uint32_t i = 0; i < numSuccessors(); i++) { getSuccessor(i)->replacePredecessor(this, join); } if (successorWithPhis()) { join->setSuccessorWithPhis(successorWithPhis(), positionInPhiSuccessor()); clearSuccessorWithPhis(); } // Copy all instructions after |ins| into the join block. while (rest != end()) { MInstruction* ins = *rest++; moveToNewBlock(ins, join); } MOZ_ASSERT(!hasLastIns()); MOZ_ASSERT(join->hasLastIns()); graph_.insertBlockAfter(this, join); // Create the fast path block. MBasicBlock* fastpathBlock = MBasicBlock::NewInternal(graph_, this, resumeBeforeIns); if (!fastpathBlock) { return false; } graph_.insertBlockAfter(this, fastpathBlock); fastpathBlock->add(fastpath); fastpathBlock->end(MGoto::New(graph_.alloc(), join)); // Create the slowpath block. MBasicBlock* slowpathBlock = MBasicBlock::NewInternal(graph_, this, resumeBeforeIns); if (!slowpathBlock) { return false; } graph_.insertBlockAfter(fastpathBlock, slowpathBlock); moveToNewBlock(ins, slowpathBlock); slowpathBlock->end(MGoto::New(graph_.alloc(), join)); // Connect current block to fastpath and slowpath. add(condition); end(MTest::New(graph_.alloc(), condition, fastpathBlock, slowpathBlock)); // Update predecessors. if (!fastpathBlock->addPredecessorWithoutPhis(this) || !slowpathBlock->addPredecessorWithoutPhis(this) || !join->addPredecessorWithoutPhis(fastpathBlock) || !join->addPredecessorWithoutPhis(slowpathBlock)) { return false; } if (ins->hasUses()) { // Insert phi. MPhi* phi = MPhi::New(graph_.alloc()); if (!phi->reserveLength(2)) { return false; } phi->addInput(fastpath); fastpathBlock->setSuccessorWithPhis(join, 0); phi->addInput(ins); slowpathBlock->setSuccessorWithPhis(join, 1); join->addPhi(phi); for (MUseIterator i(ins->usesBegin()), e(ins->usesEnd()); i != e;) { MUse* use = *i++; if (use->consumer() != phi && use->consumer() != ins->resumePoint()) { use->replaceProducer(phi); } } } moveOuterResumePointTo(join); return true; } MBasicBlock* MBasicBlock::NewInternal(MIRGraph& graph, MBasicBlock* orig, MResumePoint* resumePoint) { jsbytecode* pc = IsResumeAfter(resumePoint->mode()) ? GetNextPc(resumePoint->pc()) : resumePoint->pc(); BytecodeSite* site = new (graph.alloc()) BytecodeSite(orig->trackedTree(), pc); MBasicBlock* block = new (graph.alloc()) MBasicBlock(graph, orig->info(), site, INTERNAL); if (!block->init()) { return nullptr; } // Propagate the caller resume point from the original block. block->callerResumePoint_ = orig->callerResumePoint(); // Copy the resume point. block->stackPosition_ = resumePoint->stackDepth(); MResumePoint* entryResumePoint = new (graph.alloc()) MResumePoint(block, pc, ResumeMode::ResumeAt); if (!entryResumePoint->init(graph.alloc())) { return nullptr; } for (size_t i = 0; i < resumePoint->stackDepth(); i++) { entryResumePoint->initOperand(i, resumePoint->getOperand(i)); } block->entryResumePoint_ = entryResumePoint; block->setLoopDepth(orig->loopDepth()); return block; } MBasicBlock* MBasicBlock::New(MIRGraph& graph, const CompileInfo& info, MBasicBlock* pred, Kind kind) { BytecodeSite* site = new (graph.alloc()) BytecodeSite(); MBasicBlock* block = new (graph.alloc()) MBasicBlock(graph, info, site, kind); if (!block->init()) { return nullptr; } if (pred) { block->stackPosition_ = pred->stackPosition_; if (block->kind_ == PENDING_LOOP_HEADER) { size_t nphis = block->stackPosition_; size_t nfree = graph.phiFreeListLength(); TempAllocator& alloc = graph.alloc(); MPhi* phis = nullptr; if (nphis > nfree) { phis = alloc.allocateArray(nphis - nfree); if (!phis) { return nullptr; } } // Note: Phis are inserted in the same order as the slots. for (size_t i = 0; i < nphis; i++) { MDefinition* predSlot = pred->getSlot(i); MOZ_ASSERT(predSlot->type() != MIRType::Value); MPhi* phi; if (i < nfree) { phi = graph.takePhiFromFreeList(); } else { phi = phis + (i - nfree); } new (phi) MPhi(alloc, predSlot->type()); phi->addInlineInput(predSlot); // Add append Phis in the block. block->addPhi(phi); block->setSlot(i, phi); } } else { if (!block->ensureHasSlots(0)) { return nullptr; } block->copySlots(pred); } if (!block->predecessors_.append(pred)) { return nullptr; } } return block; } // Create an empty and unreachable block which jumps to |header|. Used // when the normal entry into a loop is removed (but the loop is still // reachable due to OSR) to preserve the invariant that every loop // header has two predecessors, which is needed for building the // dominator tree. The new block is inserted immediately before the // header, which preserves the graph ordering (post-order/RPO). These // blocks will all be removed before lowering. MBasicBlock* MBasicBlock::NewFakeLoopPredecessor(MIRGraph& graph, MBasicBlock* header) { MOZ_ASSERT(graph.osrBlock()); MBasicBlock* backedge = header->backedge(); MBasicBlock* fake = MBasicBlock::New(graph, header->info(), nullptr, MBasicBlock::FAKE_LOOP_PRED); if (!fake) { return nullptr; } graph.insertBlockBefore(header, fake); fake->setUnreachable(); // Create fake defs to use as inputs for any phis in |header|. for (MPhiIterator iter(header->phisBegin()), end(header->phisEnd()); iter != end; ++iter) { if (!graph.alloc().ensureBallast()) { return nullptr; } MPhi* phi = *iter; auto* fakeDef = MUnreachableResult::New(graph.alloc(), phi->type()); fake->add(fakeDef); if (!phi->addInputSlow(fakeDef)) { return nullptr; } } fake->end(MGoto::New(graph.alloc(), header)); if (!header->addPredecessorWithoutPhis(fake)) { return nullptr; } // The backedge is always the last predecessor, but we have added a // new pred. Restore |backedge| as |header|'s loop backedge. header->clearLoopHeader(); header->setLoopHeader(backedge); return fake; } void MIRGraph::removeFakeLoopPredecessors() { MOZ_ASSERT(osrBlock()); size_t id = 0; for (ReversePostorderIterator it = rpoBegin(); it != rpoEnd();) { MBasicBlock* block = *it++; if (block->isFakeLoopPred()) { MOZ_ASSERT(block->unreachable()); MBasicBlock* succ = block->getSingleSuccessor(); succ->removePredecessor(block); removeBlock(block); } else { block->setId(id++); } } #ifdef DEBUG canBuildDominators_ = false; #endif } MBasicBlock::MBasicBlock(MIRGraph& graph, const CompileInfo& info, BytecodeSite* site, Kind kind) : graph_(graph), info_(info), predecessors_(graph.alloc()), stackPosition_(info_.firstStackSlot()), id_(0), domIndex_(0), numDominated_(0), lir_(nullptr), callerResumePoint_(nullptr), entryResumePoint_(nullptr), outerResumePoint_(nullptr), successorWithPhis_(nullptr), positionInPhiSuccessor_(0), loopDepth_(0), kind_(kind), mark_(false), immediatelyDominated_(graph.alloc()), immediateDominator_(nullptr), trackedSite_(site), lineno_(0u), columnIndex_(0u) { MOZ_ASSERT(trackedSite_, "trackedSite_ is non-nullptr"); } bool MBasicBlock::init() { return slots_.init(graph_.alloc(), info_.nslots()); } bool MBasicBlock::increaseSlots(size_t num) { return slots_.growBy(graph_.alloc(), num); } bool MBasicBlock::ensureHasSlots(size_t num) { size_t depth = stackDepth() + num; if (depth > nslots()) { if (!increaseSlots(depth - nslots())) { return false; } } return true; } void MBasicBlock::copySlots(MBasicBlock* from) { MOZ_ASSERT(stackPosition_ <= from->stackPosition_); MOZ_ASSERT(stackPosition_ <= nslots()); MDefinition** thisSlots = slots_.begin(); MDefinition** fromSlots = from->slots_.begin(); for (size_t i = 0, e = stackPosition_; i < e; ++i) { thisSlots[i] = fromSlots[i]; } } bool MBasicBlock::inherit(TempAllocator& alloc, size_t stackDepth, MBasicBlock* maybePred, uint32_t popped) { MOZ_ASSERT_IF(maybePred, maybePred->stackDepth() == stackDepth); MOZ_ASSERT(stackDepth >= popped); stackDepth -= popped; stackPosition_ = stackDepth; if (maybePred && kind_ != PENDING_LOOP_HEADER) { copySlots(maybePred); } MOZ_ASSERT(info_.nslots() >= stackPosition_); MOZ_ASSERT(!entryResumePoint_); // Propagate the caller resume point from the inherited block. callerResumePoint_ = maybePred ? maybePred->callerResumePoint() : nullptr; // Create a resume point using our initial stack state. entryResumePoint_ = new (alloc) MResumePoint(this, pc(), ResumeMode::ResumeAt); if (!entryResumePoint_->init(alloc)) { return false; } if (maybePred) { if (!predecessors_.append(maybePred)) { return false; } if (kind_ == PENDING_LOOP_HEADER) { for (size_t i = 0; i < stackDepth; i++) { MPhi* phi = MPhi::New(alloc.fallible()); if (!phi) { return false; } phi->addInlineInput(maybePred->getSlot(i)); addPhi(phi); setSlot(i, phi); entryResumePoint()->initOperand(i, phi); } } else { for (size_t i = 0; i < stackDepth; i++) { entryResumePoint()->initOperand(i, getSlot(i)); } } } else { /* * Don't leave the operands uninitialized for the caller, as it may not * initialize them later on. */ for (size_t i = 0; i < stackDepth; i++) { entryResumePoint()->clearOperand(i); } } return true; } void MBasicBlock::inheritSlots(MBasicBlock* parent) { stackPosition_ = parent->stackPosition_; copySlots(parent); } bool MBasicBlock::initEntrySlots(TempAllocator& alloc) { // Remove the previous resume point. discardResumePoint(entryResumePoint_); // Create a resume point using our initial stack state. entryResumePoint_ = MResumePoint::New(alloc, this, pc(), ResumeMode::ResumeAt); if (!entryResumePoint_) { return false; } return true; } MDefinition* MBasicBlock::environmentChain() { return getSlot(info().environmentChainSlot()); } MDefinition* MBasicBlock::argumentsObject() { return getSlot(info().argsObjSlot()); } void MBasicBlock::setEnvironmentChain(MDefinition* scopeObj) { setSlot(info().environmentChainSlot(), scopeObj); } void MBasicBlock::setArgumentsObject(MDefinition* argsObj) { setSlot(info().argsObjSlot(), argsObj); } void MBasicBlock::pick(int32_t depth) { // pick takes a value and moves it to the top. // pick(-2): // A B C D E // A B D C E [ swapAt(-2) ] // A B D E C [ swapAt(-1) ] for (; depth < 0; depth++) { swapAt(depth); } } void MBasicBlock::unpick(int32_t depth) { // unpick takes the value on top of the stack and moves it under the depth-th // element; // unpick(-2): // A B C D E // A B C E D [ swapAt(-1) ] // A B E C D [ swapAt(-2) ] for (int32_t n = -1; n >= depth; n--) { swapAt(n); } } void MBasicBlock::swapAt(int32_t depth) { uint32_t lhsDepth = stackPosition_ + depth - 1; uint32_t rhsDepth = stackPosition_ + depth; MDefinition* temp = slots_[lhsDepth]; slots_[lhsDepth] = slots_[rhsDepth]; slots_[rhsDepth] = temp; } void MBasicBlock::discardLastIns() { discard(lastIns()); } MConstant* MBasicBlock::optimizedOutConstant(TempAllocator& alloc) { // If the first instruction is a MConstant(MagicValue(JS_OPTIMIZED_OUT)) // then reuse it. MInstruction* ins = *begin(); if (ins->type() == MIRType::MagicOptimizedOut) { return ins->toConstant(); } MConstant* constant = MConstant::New(alloc, MagicValue(JS_OPTIMIZED_OUT)); insertBefore(ins, constant); return constant; } void MBasicBlock::moveBefore(MInstruction* at, MInstruction* ins) { // Remove |ins| from the current block. MOZ_ASSERT(ins->block() == this); instructions_.remove(ins); // Insert into new block, which may be distinct. // Uses and operands are untouched. ins->setInstructionBlock(at->block(), at->trackedSite()); at->block()->instructions_.insertBefore(at, ins); } MInstruction* MBasicBlock::safeInsertTop(MDefinition* ins, IgnoreTop ignore) { MOZ_ASSERT(graph().osrBlock() != this, "We are not supposed to add any instruction in OSR blocks."); // Beta nodes and interrupt checks are required to be located at the // beginnings of basic blocks, so we must insert new instructions after any // such instructions. MInstructionIterator insertIter = !ins || ins->isPhi() ? begin() : begin(ins->toInstruction()); while (insertIter->isBeta() || insertIter->isInterruptCheck() || insertIter->isConstant() || insertIter->isParameter() || (!(ignore & IgnoreRecover) && insertIter->isRecoveredOnBailout())) { insertIter++; } return *insertIter; } void MBasicBlock::discardResumePoint( MResumePoint* rp, ReferencesType refType /* = RefType_Default */) { if (refType & RefType_DiscardOperands) { rp->releaseUses(); } rp->setDiscarded(); removeResumePoint(rp); } void MBasicBlock::removeResumePoint(MResumePoint* rp) { #ifdef DEBUG MResumePointIterator iter = resumePointsBegin(); while (*iter != rp) { // We should reach it before reaching the end. MOZ_ASSERT(iter != resumePointsEnd()); iter++; } resumePoints_.removeAt(iter); #endif } void MBasicBlock::prepareForDiscard( MInstruction* ins, ReferencesType refType /* = RefType_Default */) { // Only remove instructions from the same basic block. This is needed for // correctly removing the resume point if any. MOZ_ASSERT(ins->block() == this); MResumePoint* rp = ins->resumePoint(); if ((refType & RefType_DiscardResumePoint) && rp) { discardResumePoint(rp, refType); } // We need to assert that instructions have no uses after removing the their // resume points operands as they could be captured by their own resume // point. MOZ_ASSERT_IF(refType & RefType_AssertNoUses, !ins->hasUses()); const uint32_t InstructionOperands = RefType_DiscardOperands | RefType_DiscardInstruction; if ((refType & InstructionOperands) == InstructionOperands) { for (size_t i = 0, e = ins->numOperands(); i < e; i++) { ins->releaseOperand(i); } } ins->setDiscarded(); } void MBasicBlock::discard(MInstruction* ins) { prepareForDiscard(ins); instructions_.remove(ins); } void MBasicBlock::discardIgnoreOperands(MInstruction* ins) { #ifdef DEBUG for (size_t i = 0, e = ins->numOperands(); i < e; i++) { MOZ_ASSERT(!ins->hasOperand(i)); } #endif prepareForDiscard(ins, RefType_IgnoreOperands); instructions_.remove(ins); } void MBasicBlock::discardAllInstructions() { MInstructionIterator iter = begin(); discardAllInstructionsStartingAt(iter); } void MBasicBlock::discardAllInstructionsStartingAt(MInstructionIterator iter) { while (iter != end()) { // Discard operands and resume point operands and flag the instruction // as discarded. Also we do not assert that we have no uses as blocks // might be removed in reverse post order. MInstruction* ins = *iter++; prepareForDiscard(ins, RefType_DefaultNoAssert); instructions_.remove(ins); } } void MBasicBlock::discardAllPhis() { for (MPhiIterator iter = phisBegin(); iter != phisEnd(); iter++) { iter->removeAllOperands(); } for (MBasicBlock** pred = predecessors_.begin(); pred != predecessors_.end(); pred++) { (*pred)->clearSuccessorWithPhis(); } phis_.clear(); } void MBasicBlock::discardAllResumePoints(bool discardEntry) { if (outerResumePoint_) { clearOuterResumePoint(); } if (discardEntry && entryResumePoint_) { clearEntryResumePoint(); } #ifdef DEBUG if (!entryResumePoint()) { MOZ_ASSERT(resumePointsEmpty()); } else { MResumePointIterator iter(resumePointsBegin()); MOZ_ASSERT(iter != resumePointsEnd()); iter++; MOZ_ASSERT(iter == resumePointsEnd()); } #endif } void MBasicBlock::clear() { discardAllInstructions(); discardAllResumePoints(); discardAllPhis(); } void MBasicBlock::insertBefore(MInstruction* at, MInstruction* ins) { MOZ_ASSERT(at->block() == this); ins->setInstructionBlock(this, at->trackedSite()); graph().allocDefinitionId(ins); instructions_.insertBefore(at, ins); } void MBasicBlock::insertAfter(MInstruction* at, MInstruction* ins) { MOZ_ASSERT(at->block() == this); ins->setInstructionBlock(this, at->trackedSite()); graph().allocDefinitionId(ins); instructions_.insertAfter(at, ins); } void MBasicBlock::insertAtEnd(MInstruction* ins) { if (hasLastIns()) { insertBefore(lastIns(), ins); } else { add(ins); } } void MBasicBlock::addPhi(MPhi* phi) { phis_.pushBack(phi); phi->setPhiBlock(this); graph().allocDefinitionId(phi); } void MBasicBlock::discardPhi(MPhi* phi) { MOZ_ASSERT(!phis_.empty()); phi->removeAllOperands(); phi->setDiscarded(); phis_.remove(phi); if (phis_.empty()) { for (MBasicBlock* pred : predecessors_) { pred->clearSuccessorWithPhis(); } } } MResumePoint* MBasicBlock::activeResumePoint(MInstruction* ins) { for (MInstructionReverseIterator iter = rbegin(ins); iter != rend(); iter++) { if (iter->resumePoint() && *iter != ins) { return iter->resumePoint(); } } // If none, take the entry resume point. return entryResumePoint(); } void MBasicBlock::flagOperandsOfPrunedBranches(MInstruction* ins) { MResumePoint* rp = activeResumePoint(ins); // The only blocks which do not have any entryResumePoint in Ion, are the // SplitEdge blocks. SplitEdge blocks only have a Goto instruction before // Range Analysis phase. In adjustInputs, we are manipulating instructions // which have a TypePolicy. So, as a Goto has no operand and no type // policy, the entry resume point should exist. MOZ_ASSERT(rp); // Flag all operands as being potentially used. while (rp) { for (size_t i = 0, end = rp->numOperands(); i < end; i++) { rp->getOperand(i)->setImplicitlyUsedUnchecked(); } rp = rp->caller(); } } bool MBasicBlock::addPredecessor(TempAllocator& alloc, MBasicBlock* pred) { return addPredecessorPopN(alloc, pred, 0); } bool MBasicBlock::addPredecessorPopN(TempAllocator& alloc, MBasicBlock* pred, uint32_t popped) { MOZ_ASSERT(pred); MOZ_ASSERT(predecessors_.length() > 0); // Predecessors must be finished, and at the correct stack depth. MOZ_ASSERT(pred->hasLastIns()); MOZ_ASSERT(pred->stackPosition_ == stackPosition_ + popped); for (uint32_t i = 0, e = stackPosition_; i < e; ++i) { MDefinition* mine = getSlot(i); MDefinition* other = pred->getSlot(i); if (mine != other) { MIRType phiType = mine->type(); if (phiType != other->type()) { phiType = MIRType::Value; } // If the current instruction is a phi, and it was created in this // basic block, then we have already placed this phi and should // instead append to its operands. if (mine->isPhi() && mine->block() == this) { MOZ_ASSERT(predecessors_.length()); MOZ_ASSERT(!mine->hasDefUses(), "should only change type of newly created phis"); mine->setResultType(phiType); if (!mine->toPhi()->addInputSlow(other)) { return false; } } else { // Otherwise, create a new phi node. MPhi* phi = MPhi::New(alloc.fallible(), phiType); if (!phi) { return false; } addPhi(phi); // Prime the phi for each predecessor, so input(x) comes from // predecessor(x). if (!phi->reserveLength(predecessors_.length() + 1)) { return false; } for (size_t j = 0, numPreds = predecessors_.length(); j < numPreds; ++j) { MOZ_ASSERT(predecessors_[j]->getSlot(i) == mine); phi->addInput(mine); } phi->addInput(other); setSlot(i, phi); if (entryResumePoint()) { entryResumePoint()->replaceOperand(i, phi); } } } } return predecessors_.append(pred); } bool MBasicBlock::addPredecessorSameInputsAs(MBasicBlock* pred, MBasicBlock* existingPred) { MOZ_ASSERT(pred); MOZ_ASSERT(predecessors_.length() > 0); // Predecessors must be finished, and at the correct stack depth. MOZ_ASSERT(pred->hasLastIns()); MOZ_ASSERT(!pred->successorWithPhis()); if (!phisEmpty()) { size_t existingPosition = indexForPredecessor(existingPred); for (MPhiIterator iter = phisBegin(); iter != phisEnd(); iter++) { if (!iter->addInputSlow(iter->getOperand(existingPosition))) { return false; } } } if (!predecessors_.append(pred)) { return false; } return true; } bool MBasicBlock::addPredecessorWithoutPhis(MBasicBlock* pred) { // Predecessors must be finished. MOZ_ASSERT(pred && pred->hasLastIns()); return predecessors_.append(pred); } bool MBasicBlock::addImmediatelyDominatedBlock(MBasicBlock* child) { return immediatelyDominated_.append(child); } void MBasicBlock::removeImmediatelyDominatedBlock(MBasicBlock* child) { for (size_t i = 0;; ++i) { MOZ_ASSERT(i < immediatelyDominated_.length(), "Dominated block to remove not present"); if (immediatelyDominated_[i] == child) { immediatelyDominated_[i] = immediatelyDominated_.back(); immediatelyDominated_.popBack(); return; } } } bool MBasicBlock::setBackedge(MBasicBlock* pred) { // Predecessors must be finished, and at the correct stack depth. MOZ_ASSERT(hasLastIns()); MOZ_ASSERT(pred->hasLastIns()); MOZ_ASSERT(pred->stackDepth() == entryResumePoint()->stackDepth()); // We must be a pending loop header MOZ_ASSERT(kind_ == PENDING_LOOP_HEADER); // Add exit definitions to each corresponding phi at the entry. if (!inheritPhisFromBackedge(pred)) { return false; } // We are now a loop header proper kind_ = LOOP_HEADER; return predecessors_.append(pred); } bool MBasicBlock::setBackedgeWasm(MBasicBlock* pred, size_t paramCount) { // Predecessors must be finished, and at the correct stack depth. MOZ_ASSERT(hasLastIns()); MOZ_ASSERT(pred->hasLastIns()); MOZ_ASSERT(stackDepth() + paramCount == pred->stackDepth()); // We must be a pending loop header MOZ_ASSERT(kind_ == PENDING_LOOP_HEADER); // Add exit definitions to each corresponding phi at the entry. // Note: Phis are inserted in the same order as the slots. (see // MBasicBlock::New) size_t slot = 0; for (MPhiIterator phi = phisBegin(); phi != phisEnd(); phi++, slot++) { MPhi* entryDef = *phi; MDefinition* exitDef = pred->getSlot(slot); // Assert that we already placed phis for each slot. MOZ_ASSERT(entryDef->block() == this); // Assert that the phi already has the correct type. MOZ_ASSERT(entryDef->type() == exitDef->type()); MOZ_ASSERT(entryDef->type() != MIRType::Value); if (entryDef == exitDef) { // If the exit def is the same as the entry def, make a redundant // phi. Since loop headers have exactly two incoming edges, we // know that that's just the first input. // // Note that we eliminate later rather than now, to avoid any // weirdness around pending continue edges which might still hold // onto phis. exitDef = entryDef->getOperand(0); } // Phis always have room for 2 operands, so this can't fail. MOZ_ASSERT(phi->numOperands() == 1); entryDef->addInlineInput(exitDef); // Two cases here: phis that correspond to locals, and phis that correspond // to loop parameters. Only phis for locals go in slots. if (slot < stackDepth()) { setSlot(slot, entryDef); } } // We are now a loop header proper kind_ = LOOP_HEADER; return predecessors_.append(pred); } void MBasicBlock::clearLoopHeader() { MOZ_ASSERT(isLoopHeader()); kind_ = NORMAL; } void MBasicBlock::setLoopHeader(MBasicBlock* newBackedge) { MOZ_ASSERT(!isLoopHeader()); kind_ = LOOP_HEADER; size_t numPreds = numPredecessors(); MOZ_ASSERT(numPreds != 0); size_t lastIndex = numPreds - 1; size_t oldIndex = 0; for (;; ++oldIndex) { MOZ_ASSERT(oldIndex < numPreds); MBasicBlock* pred = getPredecessor(oldIndex); if (pred == newBackedge) { break; } } // Set the loop backedge to be the last element in predecessors_. std::swap(predecessors_[oldIndex], predecessors_[lastIndex]); // If we have phis, reorder their operands accordingly. if (!phisEmpty()) { getPredecessor(oldIndex)->setSuccessorWithPhis(this, oldIndex); getPredecessor(lastIndex)->setSuccessorWithPhis(this, lastIndex); for (MPhiIterator iter(phisBegin()), end(phisEnd()); iter != end; ++iter) { MPhi* phi = *iter; MDefinition* last = phi->getOperand(oldIndex); MDefinition* old = phi->getOperand(lastIndex); phi->replaceOperand(oldIndex, old); phi->replaceOperand(lastIndex, last); } } MOZ_ASSERT(newBackedge->loopHeaderOfBackedge() == this); MOZ_ASSERT(backedge() == newBackedge); } size_t MBasicBlock::getSuccessorIndex(MBasicBlock* block) const { MOZ_ASSERT(lastIns()); for (size_t i = 0; i < numSuccessors(); i++) { if (getSuccessor(i) == block) { return i; } } MOZ_CRASH("Invalid successor"); } size_t MBasicBlock::getPredecessorIndex(MBasicBlock* block) const { for (size_t i = 0, e = numPredecessors(); i < e; ++i) { if (getPredecessor(i) == block) { return i; } } MOZ_CRASH("Invalid predecessor"); } void MBasicBlock::replaceSuccessor(size_t pos, MBasicBlock* split) { MOZ_ASSERT(lastIns()); // Note, during split-critical-edges, successors-with-phis is not yet set. // During PAA, this case is handled before we enter. MOZ_ASSERT_IF(successorWithPhis_, successorWithPhis_ != getSuccessor(pos)); lastIns()->replaceSuccessor(pos, split); } void MBasicBlock::replacePredecessor(MBasicBlock* old, MBasicBlock* split) { for (size_t i = 0; i < numPredecessors(); i++) { if (getPredecessor(i) == old) { predecessors_[i] = split; #ifdef DEBUG // The same block should not appear twice in the predecessor list. for (size_t j = i; j < numPredecessors(); j++) { MOZ_ASSERT(predecessors_[j] != old); } #endif return; } } MOZ_CRASH("predecessor was not found"); } void MBasicBlock::clearDominatorInfo() { setImmediateDominator(nullptr); immediatelyDominated_.clear(); numDominated_ = 0; } void MBasicBlock::removePredecessorWithoutPhiOperands(MBasicBlock* pred, size_t predIndex) { // If we're removing the last backedge, this is no longer a loop. if (isLoopHeader() && hasUniqueBackedge() && backedge() == pred) { clearLoopHeader(); } // Adjust phis. Note that this can leave redundant phis behind. // Don't adjust successorWithPhis() if we haven't constructed this // information yet. if (pred->successorWithPhis()) { MOZ_ASSERT(pred->positionInPhiSuccessor() == predIndex); pred->clearSuccessorWithPhis(); for (size_t j = predIndex + 1; j < numPredecessors(); j++) { getPredecessor(j)->setSuccessorWithPhis(this, j - 1); } } // Remove from pred list. predecessors_.erase(predecessors_.begin() + predIndex); } void MBasicBlock::removePredecessor(MBasicBlock* pred) { size_t predIndex = getPredecessorIndex(pred); // Remove the phi operands. for (MPhiIterator iter(phisBegin()), end(phisEnd()); iter != end; ++iter) { iter->removeOperand(predIndex); } // Now we can call the underlying function, which expects that phi // operands have been removed. removePredecessorWithoutPhiOperands(pred, predIndex); } bool MBasicBlock::inheritPhisFromBackedge(MBasicBlock* backedge) { // We must be a pending loop header MOZ_ASSERT(kind_ == PENDING_LOOP_HEADER); size_t stackDepth = entryResumePoint()->stackDepth(); for (size_t slot = 0; slot < stackDepth; slot++) { // Get the value stack-slot of the back edge. MDefinition* exitDef = backedge->getSlot(slot); // Get the value of the loop header. MDefinition* loopDef = entryResumePoint()->getOperand(slot); if (loopDef->block() != this) { // If we are finishing a pending loop header, then we need to ensure // that all operands are phis. This is usualy the case, except for // object/arrays build with generators, in which case we share the // same allocations across all blocks. MOZ_ASSERT(loopDef->block()->id() < id()); MOZ_ASSERT(loopDef == exitDef); continue; } // Phis are allocated by NewPendingLoopHeader. MPhi* entryDef = loopDef->toPhi(); MOZ_ASSERT(entryDef->block() == this); if (entryDef == exitDef) { // If the exit def is the same as the entry def, make a redundant // phi. Since loop headers have exactly two incoming edges, we // know that that's just the first input. // // Note that we eliminate later rather than now, to avoid any // weirdness around pending continue edges which might still hold // onto phis. exitDef = entryDef->getOperand(0); } if (!entryDef->addInputSlow(exitDef)) { return false; } } return true; } MTest* MBasicBlock::immediateDominatorBranch(BranchDirection* pdirection) { *pdirection = FALSE_BRANCH; if (numPredecessors() != 1) { return nullptr; } MBasicBlock* dom = immediateDominator(); if (dom != getPredecessor(0)) { return nullptr; } // Look for a trailing MTest branching to this block. MInstruction* ins = dom->lastIns(); if (ins->isTest()) { MTest* test = ins->toTest(); MOZ_ASSERT(test->ifTrue() == this || test->ifFalse() == this); if (test->ifTrue() == this && test->ifFalse() == this) { return nullptr; } *pdirection = (test->ifTrue() == this) ? TRUE_BRANCH : FALSE_BRANCH; return test; } return nullptr; } void MBasicBlock::dumpStack(GenericPrinter& out) { #ifdef DEBUG out.printf(" %-3s %-16s %-6s %-10s\n", "#", "name", "copyOf", "first/next"); out.printf("-------------------------------------------\n"); for (uint32_t i = 0; i < stackPosition_; i++) { out.printf(" %-3u", i); out.printf(" %-16p\n", (void*)slots_[i]); } #endif } void MBasicBlock::dumpStack() { Fprinter out(stderr); dumpStack(out); out.finish(); } void MIRGraph::dump(GenericPrinter& out) { #ifdef JS_JITSPEW for (MBasicBlockIterator iter(begin()); iter != end(); iter++) { iter->dump(out); out.printf("\n"); } #endif } void MIRGraph::dump() { Fprinter out(stderr); dump(out); out.finish(); } void MBasicBlock::dump(GenericPrinter& out) { #ifdef JS_JITSPEW out.printf("block%u:%s%s%s\n", id(), isLoopHeader() ? " (loop header)" : "", unreachable() ? " (unreachable)" : "", isMarked() ? " (marked)" : ""); if (MResumePoint* resume = entryResumePoint()) { resume->dump(out); } for (MPhiIterator iter(phisBegin()); iter != phisEnd(); iter++) { iter->dump(out); } for (MInstructionIterator iter(begin()); iter != end(); iter++) { iter->dump(out); } #endif } void MBasicBlock::dump() { Fprinter out(stderr); dump(out); out.finish(); }