/* -*- 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/LICM.h" #include "jit/IonAnalysis.h" #include "jit/JitSpewer.h" #include "jit/MIRGenerator.h" #include "jit/MIRGraph.h" using namespace js; using namespace js::jit; // Test whether any instruction in the loop possiblyCalls(). static bool LoopContainsPossibleCall(MIRGraph& graph, MBasicBlock* header, MBasicBlock* backedge) { for (auto i(graph.rpoBegin(header)); ; ++i) { MOZ_ASSERT(i != graph.rpoEnd(), "Reached end of graph searching for blocks in loop"); MBasicBlock* block = *i; if (!block->isMarked()) continue; for (auto insIter(block->begin()), insEnd(block->end()); insIter != insEnd; ++insIter) { MInstruction* ins = *insIter; if (ins->possiblyCalls()) { #ifdef JS_JITSPEW JitSpew(JitSpew_LICM, " Possile call found at %s%u", ins->opName(), ins->id()); #endif return true; } } if (block == backedge) break; } return false; } // When a nested loop has no exits back into what would be its parent loop, // MarkLoopBlocks on the parent loop doesn't mark the blocks of the nested // loop, since they technically aren't part of the loop. However, AliasAnalysis // currently does consider such nested loops to be part of their parent // loops. Consequently, we can't use IsInLoop on dependency() values; we must // test whether a dependency() is *before* the loop, even if it is not // technically in the loop. static bool IsBeforeLoop(MDefinition* ins, MBasicBlock* header) { return ins->block()->id() < header->id(); } // Test whether the given instruction is inside the loop (and thus not // loop-invariant). static bool IsInLoop(MDefinition* ins) { return ins->block()->isMarked(); } // Test whether the given instruction is cheap and not worth hoisting unless // one of its users will be hoisted as well. static bool RequiresHoistedUse(const MDefinition* ins, bool hasCalls) { if (ins->isConstantElements()) return true; if (ins->isBox()) { MOZ_ASSERT(!ins->toBox()->input()->isBox(), "Box of a box could lead to unbounded recursion"); return true; } // Integer constants are usually cheap and aren't worth hoisting on their // own, in general. Floating-point constants typically are worth hoisting, // unless they'll end up being spilled (eg. due to a call). if (ins->isConstant() && (!IsFloatingPointType(ins->type()) || hasCalls)) return true; return false; } // Test whether the given instruction has any operands defined within the loop. static bool HasOperandInLoop(MInstruction* ins, bool hasCalls) { // An instruction is only loop invariant if it and all of its operands can // be safely hoisted into the loop preheader. for (size_t i = 0, e = ins->numOperands(); i != e; ++i) { MDefinition* op = ins->getOperand(i); if (!IsInLoop(op)) continue; if (RequiresHoistedUse(op, hasCalls)) { // Recursively test for loop invariance. Note that the recursion is // bounded because we require RequiresHoistedUse to be set at each // level. if (!HasOperandInLoop(op->toInstruction(), hasCalls)) continue; } return true; } return false; } // Test whether the given instruction is hoistable, ignoring memory // dependencies. static bool IsHoistableIgnoringDependency(MInstruction* ins, bool hasCalls) { return ins->isMovable() && !ins->isEffectful() && !ins->neverHoist() && !HasOperandInLoop(ins, hasCalls); } // Test whether the given instruction has a memory dependency inside the loop. static bool HasDependencyInLoop(MInstruction* ins, MBasicBlock* header) { // Don't hoist if this instruction depends on a store inside the loop. if (MInstruction* dep = ins->dependency()) return !IsBeforeLoop(dep, header); return false; } // Test whether the given instruction is hoistable. static bool IsHoistable(MInstruction* ins, MBasicBlock* header, bool hasCalls) { return IsHoistableIgnoringDependency(ins, hasCalls) && !HasDependencyInLoop(ins, header); } // In preparation for hoisting an instruction, hoist any of its operands which // were too cheap to hoist on their own. static void MoveDeferredOperands(MInstruction* ins, MInstruction* hoistPoint, bool hasCalls) { // If any of our operands were waiting for a user to be hoisted, make a note // to hoist them. for (size_t i = 0, e = ins->numOperands(); i != e; ++i) { MDefinition* op = ins->getOperand(i); if (!IsInLoop(op)) continue; MOZ_ASSERT(RequiresHoistedUse(op, hasCalls), "Deferred loop-invariant operand is not cheap"); MInstruction* opIns = op->toInstruction(); // Recursively move the operands. Note that the recursion is bounded // because we require RequiresHoistedUse to be set at each level. MoveDeferredOperands(opIns, hoistPoint, hasCalls); #ifdef JS_JITSPEW JitSpew(JitSpew_LICM, " Hoisting %s%u (now that a user will be hoisted)", opIns->opName(), opIns->id()); #endif opIns->block()->moveBefore(hoistPoint, opIns); } } static void VisitLoopBlock(MBasicBlock* block, MBasicBlock* header, MInstruction* hoistPoint, bool hasCalls) { for (auto insIter(block->begin()), insEnd(block->end()); insIter != insEnd; ) { MInstruction* ins = *insIter++; if (!IsHoistable(ins, header, hasCalls)) { #ifdef JS_JITSPEW if (IsHoistableIgnoringDependency(ins, hasCalls)) { JitSpew(JitSpew_LICM, " %s%u isn't hoistable due to dependency on %s%u", ins->opName(), ins->id(), ins->dependency()->opName(), ins->dependency()->id()); } #endif continue; } // Don't hoist a cheap constant if it doesn't enable us to hoist one of // its uses. We want those instructions as close as possible to their // use, to minimize register pressure. if (RequiresHoistedUse(ins, hasCalls)) { #ifdef JS_JITSPEW JitSpew(JitSpew_LICM, " %s%u will be hoisted only if its users are", ins->opName(), ins->id()); #endif continue; } // Hoist operands which were too cheap to hoist on their own. MoveDeferredOperands(ins, hoistPoint, hasCalls); #ifdef JS_JITSPEW JitSpew(JitSpew_LICM, " Hoisting %s%u", ins->opName(), ins->id()); #endif // Move the instruction to the hoistPoint. block->moveBefore(hoistPoint, ins); } } static void VisitLoop(MIRGraph& graph, MBasicBlock* header) { MInstruction* hoistPoint = header->loopPredecessor()->lastIns(); #ifdef JS_JITSPEW JitSpew(JitSpew_LICM, " Visiting loop with header block%u, hoisting to %s%u", header->id(), hoistPoint->opName(), hoistPoint->id()); #endif MBasicBlock* backedge = header->backedge(); // This indicates whether the loop contains calls or other things which // clobber most or all floating-point registers. In such loops, // floating-point constants should not be hoisted unless it enables further // hoisting. bool hasCalls = LoopContainsPossibleCall(graph, header, backedge); for (auto i(graph.rpoBegin(header)); ; ++i) { MOZ_ASSERT(i != graph.rpoEnd(), "Reached end of graph searching for blocks in loop"); MBasicBlock* block = *i; if (!block->isMarked()) continue; VisitLoopBlock(block, header, hoistPoint, hasCalls); if (block == backedge) break; } } bool jit::LICM(MIRGenerator* mir, MIRGraph& graph) { JitSpew(JitSpew_LICM, "Beginning LICM pass"); // Iterate in RPO to visit outer loops before inner loops. We'd hoist the // same things either way, but outer first means we do a little less work. for (auto i(graph.rpoBegin()), e(graph.rpoEnd()); i != e; ++i) { MBasicBlock* header = *i; if (!header->isLoopHeader()) continue; bool canOsr; size_t numBlocks = MarkLoopBlocks(graph, header, &canOsr); if (numBlocks == 0) { JitSpew(JitSpew_LICM, " Loop with header block%u isn't actually a loop", header->id()); continue; } // Hoisting out of a loop that has an entry from the OSR block in // addition to its normal entry is tricky. In theory we could clone // the instruction and insert phis. if (!canOsr) VisitLoop(graph, header); else JitSpew(JitSpew_LICM, " Skipping loop with header block%u due to OSR", header->id()); UnmarkLoopBlocks(graph, header); if (mir->shouldCancel("LICM (main loop)")) return false; } return true; }