/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*- * vim: set ts=8 sts=4 et sw=4 tw=99: * 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/RegisterAllocator.h" using namespace js; using namespace js::jit; bool AllocationIntegrityState::record() { // Ignore repeated record() calls. if (!instructions.empty()) return true; if (!instructions.appendN(InstructionInfo(), graph.numInstructions())) return false; if (!virtualRegisters.appendN((LDefinition*)nullptr, graph.numVirtualRegisters())) return false; if (!blocks.reserve(graph.numBlocks())) return false; for (size_t i = 0; i < graph.numBlocks(); i++) { blocks.infallibleAppend(BlockInfo()); LBlock* block = graph.getBlock(i); MOZ_ASSERT(block->mir()->id() == i); BlockInfo& blockInfo = blocks[i]; if (!blockInfo.phis.reserve(block->numPhis())) return false; for (size_t j = 0; j < block->numPhis(); j++) { blockInfo.phis.infallibleAppend(InstructionInfo()); InstructionInfo& info = blockInfo.phis[j]; LPhi* phi = block->getPhi(j); MOZ_ASSERT(phi->numDefs() == 1); uint32_t vreg = phi->getDef(0)->virtualRegister(); virtualRegisters[vreg] = phi->getDef(0); if (!info.outputs.append(*phi->getDef(0))) return false; for (size_t k = 0, kend = phi->numOperands(); k < kend; k++) { if (!info.inputs.append(*phi->getOperand(k))) return false; } } for (LInstructionIterator iter = block->begin(); iter != block->end(); iter++) { LInstruction* ins = *iter; InstructionInfo& info = instructions[ins->id()]; for (size_t k = 0; k < ins->numTemps(); k++) { if (!ins->getTemp(k)->isBogusTemp()) { uint32_t vreg = ins->getTemp(k)->virtualRegister(); virtualRegisters[vreg] = ins->getTemp(k); } if (!info.temps.append(*ins->getTemp(k))) return false; } for (size_t k = 0; k < ins->numDefs(); k++) { if (!ins->getDef(k)->isBogusTemp()) { uint32_t vreg = ins->getDef(k)->virtualRegister(); virtualRegisters[vreg] = ins->getDef(k); } if (!info.outputs.append(*ins->getDef(k))) return false; } for (LInstruction::InputIterator alloc(*ins); alloc.more(); alloc.next()) { if (!info.inputs.append(**alloc)) return false; } } } return seen.init(); } bool AllocationIntegrityState::check(bool populateSafepoints) { MOZ_ASSERT(!instructions.empty()); #ifdef JS_JITSPEW if (JitSpewEnabled(JitSpew_RegAlloc)) dump(); #endif #ifdef DEBUG for (size_t blockIndex = 0; blockIndex < graph.numBlocks(); blockIndex++) { LBlock* block = graph.getBlock(blockIndex); // Check that all instruction inputs and outputs have been assigned an allocation. for (LInstructionIterator iter = block->begin(); iter != block->end(); iter++) { LInstruction* ins = *iter; for (LInstruction::InputIterator alloc(*ins); alloc.more(); alloc.next()) MOZ_ASSERT(!alloc->isUse()); for (size_t i = 0; i < ins->numDefs(); i++) { LDefinition* def = ins->getDef(i); MOZ_ASSERT(!def->output()->isUse()); LDefinition oldDef = instructions[ins->id()].outputs[i]; MOZ_ASSERT_IF(oldDef.policy() == LDefinition::MUST_REUSE_INPUT, *def->output() == *ins->getOperand(oldDef.getReusedInput())); } for (size_t i = 0; i < ins->numTemps(); i++) { LDefinition* temp = ins->getTemp(i); MOZ_ASSERT_IF(!temp->isBogusTemp(), temp->output()->isRegister()); LDefinition oldTemp = instructions[ins->id()].temps[i]; MOZ_ASSERT_IF(oldTemp.policy() == LDefinition::MUST_REUSE_INPUT, *temp->output() == *ins->getOperand(oldTemp.getReusedInput())); } } } #endif // Check that the register assignment and move groups preserve the original // semantics of the virtual registers. Each virtual register has a single // write (owing to the SSA representation), but the allocation may move the // written value around between registers and memory locations along // different paths through the script. // // For each use of an allocation, follow the physical value which is read // backward through the script, along all paths to the value's virtual // register's definition. for (size_t blockIndex = 0; blockIndex < graph.numBlocks(); blockIndex++) { LBlock* block = graph.getBlock(blockIndex); for (LInstructionIterator iter = block->begin(); iter != block->end(); iter++) { LInstruction* ins = *iter; const InstructionInfo& info = instructions[ins->id()]; LSafepoint* safepoint = ins->safepoint(); if (safepoint) { for (size_t i = 0; i < ins->numTemps(); i++) { if (ins->getTemp(i)->isBogusTemp()) continue; uint32_t vreg = info.temps[i].virtualRegister(); LAllocation* alloc = ins->getTemp(i)->output(); if (!checkSafepointAllocation(ins, vreg, *alloc, populateSafepoints)) return false; } MOZ_ASSERT_IF(ins->isCall() && !populateSafepoints, safepoint->liveRegs().emptyFloat() && safepoint->liveRegs().emptyGeneral()); } size_t inputIndex = 0; for (LInstruction::InputIterator alloc(*ins); alloc.more(); alloc.next()) { LAllocation oldInput = info.inputs[inputIndex++]; if (!oldInput.isUse()) continue; uint32_t vreg = oldInput.toUse()->virtualRegister(); if (safepoint && !oldInput.toUse()->usedAtStart()) { if (!checkSafepointAllocation(ins, vreg, **alloc, populateSafepoints)) return false; } // Start checking at the previous instruction, in case this // instruction reuses its input register for an output. LInstructionReverseIterator riter = block->rbegin(ins); riter++; if (!checkIntegrity(block, *riter, vreg, **alloc, populateSafepoints)) return false; while (!worklist.empty()) { IntegrityItem item = worklist.popCopy(); if (!checkIntegrity(item.block, *item.block->rbegin(), item.vreg, item.alloc, populateSafepoints)) { return false; } } } } } return true; } bool AllocationIntegrityState::checkIntegrity(LBlock* block, LInstruction* ins, uint32_t vreg, LAllocation alloc, bool populateSafepoints) { for (LInstructionReverseIterator iter(block->rbegin(ins)); iter != block->rend(); iter++) { ins = *iter; // Follow values through assignments in move groups. All assignments in // a move group are considered to happen simultaneously, so stop after // the first matching move is found. if (ins->isMoveGroup()) { LMoveGroup* group = ins->toMoveGroup(); for (int i = group->numMoves() - 1; i >= 0; i--) { if (group->getMove(i).to() == alloc) { alloc = group->getMove(i).from(); break; } } } const InstructionInfo& info = instructions[ins->id()]; // Make sure the physical location being tracked is not clobbered by // another instruction, and that if the originating vreg definition is // found that it is writing to the tracked location. for (size_t i = 0; i < ins->numDefs(); i++) { LDefinition* def = ins->getDef(i); if (def->isBogusTemp()) continue; if (info.outputs[i].virtualRegister() == vreg) { MOZ_ASSERT(*def->output() == alloc); // Found the original definition, done scanning. return true; } else { MOZ_ASSERT(*def->output() != alloc); } } for (size_t i = 0; i < ins->numTemps(); i++) { LDefinition* temp = ins->getTemp(i); if (!temp->isBogusTemp()) MOZ_ASSERT(*temp->output() != alloc); } if (ins->safepoint()) { if (!checkSafepointAllocation(ins, vreg, alloc, populateSafepoints)) return false; } } // Phis are effectless, but change the vreg we are tracking. Check if there // is one which produced this vreg. We need to follow back through the phi // inputs as it is not guaranteed the register allocator filled in physical // allocations for the inputs and outputs of the phis. for (size_t i = 0; i < block->numPhis(); i++) { const InstructionInfo& info = blocks[block->mir()->id()].phis[i]; LPhi* phi = block->getPhi(i); if (info.outputs[0].virtualRegister() == vreg) { for (size_t j = 0, jend = phi->numOperands(); j < jend; j++) { uint32_t newvreg = info.inputs[j].toUse()->virtualRegister(); LBlock* predecessor = block->mir()->getPredecessor(j)->lir(); if (!addPredecessor(predecessor, newvreg, alloc)) return false; } return true; } } // No phi which defined the vreg we are tracking, follow back through all // predecessors with the existing vreg. for (size_t i = 0, iend = block->mir()->numPredecessors(); i < iend; i++) { LBlock* predecessor = block->mir()->getPredecessor(i)->lir(); if (!addPredecessor(predecessor, vreg, alloc)) return false; } return true; } bool AllocationIntegrityState::checkSafepointAllocation(LInstruction* ins, uint32_t vreg, LAllocation alloc, bool populateSafepoints) { LSafepoint* safepoint = ins->safepoint(); MOZ_ASSERT(safepoint); if (ins->isCall() && alloc.isRegister()) return true; if (alloc.isRegister()) { AnyRegister reg = alloc.toRegister(); if (populateSafepoints) safepoint->addLiveRegister(reg); MOZ_ASSERT(safepoint->liveRegs().has(reg)); } // The |this| argument slot is implicitly included in all safepoints. if (alloc.isArgument() && alloc.toArgument()->index() < THIS_FRAME_ARGSLOT + sizeof(Value)) return true; LDefinition::Type type = virtualRegisters[vreg] ? virtualRegisters[vreg]->type() : LDefinition::GENERAL; switch (type) { case LDefinition::OBJECT: if (populateSafepoints) { JitSpew(JitSpew_RegAlloc, "Safepoint object v%u i%u %s", vreg, ins->id(), alloc.toString().get()); if (!safepoint->addGcPointer(alloc)) return false; } MOZ_ASSERT(safepoint->hasGcPointer(alloc)); break; case LDefinition::SLOTS: if (populateSafepoints) { JitSpew(JitSpew_RegAlloc, "Safepoint slots v%u i%u %s", vreg, ins->id(), alloc.toString().get()); if (!safepoint->addSlotsOrElementsPointer(alloc)) return false; } MOZ_ASSERT(safepoint->hasSlotsOrElementsPointer(alloc)); break; #ifdef JS_NUNBOX32 // Do not assert that safepoint information for nunbox types is complete, // as if a vreg for a value's components are copied in multiple places // then the safepoint information may not reflect all copies. All copies // of payloads must be reflected, however, for generational GC. case LDefinition::TYPE: if (populateSafepoints) { JitSpew(JitSpew_RegAlloc, "Safepoint type v%u i%u %s", vreg, ins->id(), alloc.toString().get()); if (!safepoint->addNunboxType(vreg, alloc)) return false; } break; case LDefinition::PAYLOAD: if (populateSafepoints) { JitSpew(JitSpew_RegAlloc, "Safepoint payload v%u i%u %s", vreg, ins->id(), alloc.toString().get()); if (!safepoint->addNunboxPayload(vreg, alloc)) return false; } MOZ_ASSERT(safepoint->hasNunboxPayload(alloc)); break; #else case LDefinition::BOX: if (populateSafepoints) { JitSpew(JitSpew_RegAlloc, "Safepoint boxed value v%u i%u %s", vreg, ins->id(), alloc.toString().get()); if (!safepoint->addBoxedValue(alloc)) return false; } MOZ_ASSERT(safepoint->hasBoxedValue(alloc)); break; #endif default: break; } return true; } bool AllocationIntegrityState::addPredecessor(LBlock* block, uint32_t vreg, LAllocation alloc) { // There is no need to reanalyze if we have already seen this predecessor. // We share the seen allocations across analysis of each use, as there will // likely be common ground between different uses of the same vreg. IntegrityItem item; item.block = block; item.vreg = vreg; item.alloc = alloc; item.index = seen.count(); IntegrityItemSet::AddPtr p = seen.lookupForAdd(item); if (p) return true; if (!seen.add(p, item)) return false; return worklist.append(item); } void AllocationIntegrityState::dump() { #ifdef DEBUG fprintf(stderr, "Register Allocation Integrity State:\n"); for (size_t blockIndex = 0; blockIndex < graph.numBlocks(); blockIndex++) { LBlock* block = graph.getBlock(blockIndex); MBasicBlock* mir = block->mir(); fprintf(stderr, "\nBlock %lu", static_cast(blockIndex)); for (size_t i = 0; i < mir->numSuccessors(); i++) fprintf(stderr, " [successor %u]", mir->getSuccessor(i)->id()); fprintf(stderr, "\n"); for (size_t i = 0; i < block->numPhis(); i++) { const InstructionInfo& info = blocks[blockIndex].phis[i]; LPhi* phi = block->getPhi(i); CodePosition input(block->getPhi(0)->id(), CodePosition::INPUT); CodePosition output(block->getPhi(block->numPhis() - 1)->id(), CodePosition::OUTPUT); fprintf(stderr, "[%u,%u Phi] [def %s] ", input.bits(), output.bits(), phi->getDef(0)->toString().get()); for (size_t j = 0; j < phi->numOperands(); j++) fprintf(stderr, " [use %s]", info.inputs[j].toString().get()); fprintf(stderr, "\n"); } for (LInstructionIterator iter = block->begin(); iter != block->end(); iter++) { LInstruction* ins = *iter; const InstructionInfo& info = instructions[ins->id()]; CodePosition input(ins->id(), CodePosition::INPUT); CodePosition output(ins->id(), CodePosition::OUTPUT); fprintf(stderr, "["); if (input != CodePosition::MIN) fprintf(stderr, "%u,%u ", input.bits(), output.bits()); fprintf(stderr, "%s]", ins->opName()); if (ins->isMoveGroup()) { LMoveGroup* group = ins->toMoveGroup(); for (int i = group->numMoves() - 1; i >= 0; i--) { fprintf(stderr, " [%s -> %s]", group->getMove(i).from().toString().get(), group->getMove(i).to().toString().get()); } fprintf(stderr, "\n"); continue; } for (size_t i = 0; i < ins->numDefs(); i++) fprintf(stderr, " [def %s]", ins->getDef(i)->toString().get()); for (size_t i = 0; i < ins->numTemps(); i++) { LDefinition* temp = ins->getTemp(i); if (!temp->isBogusTemp()) fprintf(stderr, " [temp v%u %s]", info.temps[i].virtualRegister(), temp->toString().get()); } size_t index = 0; for (LInstruction::InputIterator alloc(*ins); alloc.more(); alloc.next()) { fprintf(stderr, " [use %s", info.inputs[index++].toString().get()); if (!alloc->isConstant()) fprintf(stderr, " %s", alloc->toString().get()); fprintf(stderr, "]"); } fprintf(stderr, "\n"); } } // Print discovered allocations at the ends of blocks, in the order they // were discovered. Vector seenOrdered; if (!seenOrdered.appendN(IntegrityItem(), seen.count())) { fprintf(stderr, "OOM while dumping allocations\n"); return; } for (IntegrityItemSet::Enum iter(seen); !iter.empty(); iter.popFront()) { IntegrityItem item = iter.front(); seenOrdered[item.index] = item; } if (!seenOrdered.empty()) { fprintf(stderr, "Intermediate Allocations:\n"); for (size_t i = 0; i < seenOrdered.length(); i++) { IntegrityItem item = seenOrdered[i]; fprintf(stderr, " block %u reg v%u alloc %s\n", item.block->mir()->id(), item.vreg, item.alloc.toString().get()); } } fprintf(stderr, "\n"); #endif } const CodePosition CodePosition::MAX(UINT_MAX); const CodePosition CodePosition::MIN(0); bool RegisterAllocator::init() { if (!insData.init(mir, graph.numInstructions())) return false; if (!entryPositions.reserve(graph.numBlocks()) || !exitPositions.reserve(graph.numBlocks())) return false; for (size_t i = 0; i < graph.numBlocks(); i++) { LBlock* block = graph.getBlock(i); for (LInstructionIterator ins = block->begin(); ins != block->end(); ins++) insData[ins->id()] = *ins; for (size_t j = 0; j < block->numPhis(); j++) { LPhi* phi = block->getPhi(j); insData[phi->id()] = phi; } CodePosition entry = block->numPhis() != 0 ? CodePosition(block->getPhi(0)->id(), CodePosition::INPUT) : inputOf(block->firstInstructionWithId()); CodePosition exit = outputOf(block->lastInstructionWithId()); MOZ_ASSERT(block->mir()->id() == i); entryPositions.infallibleAppend(entry); exitPositions.infallibleAppend(exit); } return true; } LMoveGroup* RegisterAllocator::getInputMoveGroup(LInstruction* ins) { MOZ_ASSERT(!ins->fixReuseMoves()); if (ins->inputMoves()) return ins->inputMoves(); LMoveGroup* moves = LMoveGroup::New(alloc()); ins->setInputMoves(moves); ins->block()->insertBefore(ins, moves); return moves; } LMoveGroup* RegisterAllocator::getFixReuseMoveGroup(LInstruction* ins) { if (ins->fixReuseMoves()) return ins->fixReuseMoves(); LMoveGroup* moves = LMoveGroup::New(alloc()); ins->setFixReuseMoves(moves); ins->block()->insertBefore(ins, moves); return moves; } LMoveGroup* RegisterAllocator::getMoveGroupAfter(LInstruction* ins) { if (ins->movesAfter()) return ins->movesAfter(); LMoveGroup* moves = LMoveGroup::New(alloc()); ins->setMovesAfter(moves); ins->block()->insertAfter(ins, moves); return moves; } void RegisterAllocator::dumpInstructions() { #ifdef JS_JITSPEW fprintf(stderr, "Instructions:\n"); for (size_t blockIndex = 0; blockIndex < graph.numBlocks(); blockIndex++) { LBlock* block = graph.getBlock(blockIndex); MBasicBlock* mir = block->mir(); fprintf(stderr, "\nBlock %lu", static_cast(blockIndex)); for (size_t i = 0; i < mir->numSuccessors(); i++) fprintf(stderr, " [successor %u]", mir->getSuccessor(i)->id()); fprintf(stderr, "\n"); for (size_t i = 0; i < block->numPhis(); i++) { LPhi* phi = block->getPhi(i); fprintf(stderr, "[%u,%u Phi] [def %s]", inputOf(phi).bits(), outputOf(phi).bits(), phi->getDef(0)->toString().get()); for (size_t j = 0; j < phi->numOperands(); j++) fprintf(stderr, " [use %s]", phi->getOperand(j)->toString().get()); fprintf(stderr, "\n"); } for (LInstructionIterator iter = block->begin(); iter != block->end(); iter++) { LInstruction* ins = *iter; fprintf(stderr, "["); if (ins->id() != 0) fprintf(stderr, "%u,%u ", inputOf(ins).bits(), outputOf(ins).bits()); fprintf(stderr, "%s]", ins->opName()); if (ins->isMoveGroup()) { LMoveGroup* group = ins->toMoveGroup(); for (int i = group->numMoves() - 1; i >= 0; i--) { // Use two printfs, as LAllocation::toString is not reentant. fprintf(stderr, " [%s", group->getMove(i).from().toString().get()); fprintf(stderr, " -> %s]", group->getMove(i).to().toString().get()); } fprintf(stderr, "\n"); continue; } for (size_t i = 0; i < ins->numDefs(); i++) fprintf(stderr, " [def %s]", ins->getDef(i)->toString().get()); for (size_t i = 0; i < ins->numTemps(); i++) { LDefinition* temp = ins->getTemp(i); if (!temp->isBogusTemp()) fprintf(stderr, " [temp %s]", temp->toString().get()); } for (LInstruction::InputIterator alloc(*ins); alloc.more(); alloc.next()) { if (!alloc->isBogus()) fprintf(stderr, " [use %s]", alloc->toString().get()); } fprintf(stderr, "\n"); } } fprintf(stderr, "\n"); #endif // JS_JITSPEW }