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/* -*- 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/. */
#ifndef jit_shared_Lowering_shared_h
#define jit_shared_Lowering_shared_h
// This file declares the structures that are used for attaching LIR to a
// MIRGraph.
#include "jit/LIR.h"
#include "jit/MIRGenerator.h"
namespace js {
namespace jit {
class MIRGenerator;
class MIRGraph;
class MDefinition;
class MInstruction;
class LOsiPoint;
class LIRGeneratorShared : public MDefinitionVisitor
{
protected:
MIRGenerator* gen;
MIRGraph& graph;
LIRGraph& lirGraph_;
LBlock* current;
MResumePoint* lastResumePoint_;
LRecoverInfo* cachedRecoverInfo_;
LOsiPoint* osiPoint_;
public:
LIRGeneratorShared(MIRGenerator* gen, MIRGraph& graph, LIRGraph& lirGraph)
: gen(gen),
graph(graph),
lirGraph_(lirGraph),
lastResumePoint_(nullptr),
cachedRecoverInfo_(nullptr),
osiPoint_(nullptr)
{ }
MIRGenerator* mir() {
return gen;
}
protected:
static void ReorderCommutative(MDefinition** lhsp, MDefinition** rhsp, MInstruction* ins);
static bool ShouldReorderCommutative(MDefinition* lhs, MDefinition* rhs, MInstruction* ins);
// A backend can decide that an instruction should be emitted at its uses,
// rather than at its definition. To communicate this, set the
// instruction's virtual register set to 0. When using the instruction,
// its virtual register is temporarily reassigned. To know to clear it
// after constructing the use information, the worklist bit is temporarily
// unset.
//
// The backend can use the worklist bit to determine whether or not a
// definition should be created.
inline void emitAtUses(MInstruction* mir);
// The lowest-level calls to use, those that do not wrap another call to
// use(), must prefix grabbing virtual register IDs by these calls.
inline void ensureDefined(MDefinition* mir);
// These all create a use of a virtual register, with an optional
// allocation policy.
//
// Some of these use functions have atStart variants.
// - non-atStart variants will tell the register allocator that the input
// allocation must be different from any Temp or Definition also needed for
// this LInstruction.
// - atStart variants relax that restriction and allow the input to be in
// the same register as any Temp or output Definition used by the
// LInstruction. Note that it doesn't *imply* this will actually happen,
// but gives a hint to the register allocator that it can do it.
//
// TL;DR: Use non-atStart variants only if you need the input value after
// writing to any temp or definitions, during code generation of this
// LInstruction. Otherwise, use atStart variants, which will lower register
// pressure.
inline LUse use(MDefinition* mir, LUse policy);
inline LUse use(MDefinition* mir);
inline LUse useAtStart(MDefinition* mir);
inline LUse useRegister(MDefinition* mir);
inline LUse useRegisterAtStart(MDefinition* mir);
inline LUse useFixed(MDefinition* mir, Register reg);
inline LUse useFixed(MDefinition* mir, FloatRegister reg);
inline LUse useFixed(MDefinition* mir, AnyRegister reg);
inline LUse useFixedAtStart(MDefinition* mir, Register reg);
inline LUse useFixedAtStart(MDefinition* mir, AnyRegister reg);
inline LAllocation useOrConstant(MDefinition* mir);
inline LAllocation useOrConstantAtStart(MDefinition* mir);
// "Any" is architecture dependent, and will include registers and stack
// slots on X86, and only registers on ARM.
inline LAllocation useAny(MDefinition* mir);
inline LAllocation useAnyOrConstant(MDefinition* mir);
// "Storable" is architecture dependend, and will include registers and
// constants on X86 and only registers on ARM. This is a generic "things
// we can expect to write into memory in 1 instruction".
inline LAllocation useStorable(MDefinition* mir);
inline LAllocation useStorableAtStart(MDefinition* mir);
inline LAllocation useKeepalive(MDefinition* mir);
inline LAllocation useKeepaliveOrConstant(MDefinition* mir);
inline LAllocation useRegisterOrConstant(MDefinition* mir);
inline LAllocation useRegisterOrConstantAtStart(MDefinition* mir);
inline LAllocation useRegisterOrZeroAtStart(MDefinition* mir);
inline LAllocation useRegisterOrNonDoubleConstant(MDefinition* mir);
inline LUse useRegisterForTypedLoad(MDefinition* mir, MIRType type);
#ifdef JS_NUNBOX32
inline LUse useType(MDefinition* mir, LUse::Policy policy);
inline LUse usePayload(MDefinition* mir, LUse::Policy policy);
inline LUse usePayloadAtStart(MDefinition* mir, LUse::Policy policy);
inline LUse usePayloadInRegisterAtStart(MDefinition* mir);
// Adds a box input to an instruction, setting operand |n| to the type and
// |n+1| to the payload. Does not modify the operands, instead expecting a
// policy to already be set.
inline void fillBoxUses(LInstruction* lir, size_t n, MDefinition* mir);
#endif
// These create temporary register requests.
inline LDefinition temp(LDefinition::Type type = LDefinition::GENERAL,
LDefinition::Policy policy = LDefinition::REGISTER);
inline LInt64Definition tempInt64(LDefinition::Policy policy = LDefinition::REGISTER);
inline LDefinition tempFloat32();
inline LDefinition tempDouble();
inline LDefinition tempCopy(MDefinition* input, uint32_t reusedInput);
// Note that the fixed register has a GENERAL type.
inline LDefinition tempFixed(Register reg);
template <size_t Ops, size_t Temps>
inline void defineFixed(LInstructionHelper<1, Ops, Temps>* lir, MDefinition* mir,
const LAllocation& output);
template <size_t Ops, size_t Temps>
inline void defineBox(LInstructionHelper<BOX_PIECES, Ops, Temps>* lir, MDefinition* mir,
LDefinition::Policy policy = LDefinition::REGISTER);
template <size_t Ops, size_t Temps>
inline void defineInt64(LInstructionHelper<INT64_PIECES, Ops, Temps>* lir, MDefinition* mir,
LDefinition::Policy policy = LDefinition::REGISTER);
template <size_t Ops, size_t Temps>
inline void defineInt64Fixed(LInstructionHelper<INT64_PIECES, Ops, Temps>* lir, MDefinition* mir,
const LInt64Allocation& output);
template <size_t Ops, size_t Temps>
inline void defineSinCos(LInstructionHelper<2, Ops, Temps> *lir, MDefinition *mir,
LDefinition::Policy policy = LDefinition::REGISTER);
inline void defineSharedStubReturn(LInstruction* lir, MDefinition* mir);
inline void defineReturn(LInstruction* lir, MDefinition* mir);
template <size_t X>
inline void define(details::LInstructionFixedDefsTempsHelper<1, X>* lir, MDefinition* mir,
LDefinition::Policy policy = LDefinition::REGISTER);
template <size_t X>
inline void define(details::LInstructionFixedDefsTempsHelper<1, X>* lir, MDefinition* mir,
const LDefinition& def);
template <size_t Ops, size_t Temps>
inline void defineReuseInput(LInstructionHelper<1, Ops, Temps>* lir, MDefinition* mir,
uint32_t operand);
template <size_t Ops, size_t Temps>
inline void defineInt64ReuseInput(LInstructionHelper<INT64_PIECES, Ops, Temps>* lir,
MDefinition* mir, uint32_t operand);
// Returns a box allocation for a Value-typed instruction.
inline LBoxAllocation useBox(MDefinition* mir, LUse::Policy policy = LUse::REGISTER,
bool useAtStart = false);
// Returns a box allocation. The use is either typed, a Value, or
// a constant (if useConstant is true).
inline LBoxAllocation useBoxOrTypedOrConstant(MDefinition* mir, bool useConstant);
// Returns an int64 allocation for an Int64-typed instruction.
inline LInt64Allocation useInt64(MDefinition* mir, LUse::Policy policy, bool useAtStart);
inline LInt64Allocation useInt64(MDefinition* mir, bool useAtStart = false);
inline LInt64Allocation useInt64AtStart(MDefinition* mir);
inline LInt64Allocation useInt64OrConstant(MDefinition* mir, bool useAtStart = false);
inline LInt64Allocation useInt64Register(MDefinition* mir, bool useAtStart = false);
inline LInt64Allocation useInt64RegisterOrConstant(MDefinition* mir, bool useAtStart = false);
inline LInt64Allocation useInt64Fixed(MDefinition* mir, Register64 regs, bool useAtStart = false);
LInt64Allocation useInt64RegisterAtStart(MDefinition* mir) {
return useInt64Register(mir, /* useAtStart = */ true);
}
LInt64Allocation useInt64RegisterOrConstantAtStart(MDefinition* mir) {
return useInt64RegisterOrConstant(mir, /* useAtStart = */ true);
}
LInt64Allocation useInt64OrConstantAtStart(MDefinition* mir) {
return useInt64OrConstant(mir, /* useAtStart = */ true);
}
// Rather than defining a new virtual register, sets |ins| to have the same
// virtual register as |as|.
inline void redefine(MDefinition* ins, MDefinition* as);
// Redefine a sin/cos call to sincos.
inline void redefine(MDefinition* def, MDefinition* as, MMathFunction::Function func);
TempAllocator& alloc() const {
return graph.alloc();
}
uint32_t getVirtualRegister() {
uint32_t vreg = lirGraph_.getVirtualRegister();
// If we run out of virtual registers, mark code generation as having
// failed and return a dummy vreg. Include a + 1 here for NUNBOX32
// platforms that expect Value vregs to be adjacent.
if (vreg + 1 >= MAX_VIRTUAL_REGISTERS) {
gen->abort("max virtual registers");
return 1;
}
return vreg;
}
template <typename T> void annotate(T* ins);
template <typename T> void add(T* ins, MInstruction* mir = nullptr);
void lowerTypedPhiInput(MPhi* phi, uint32_t inputPosition, LBlock* block, size_t lirIndex);
void defineTypedPhi(MPhi* phi, size_t lirIndex);
LOsiPoint* popOsiPoint() {
LOsiPoint* tmp = osiPoint_;
osiPoint_ = nullptr;
return tmp;
}
LRecoverInfo* getRecoverInfo(MResumePoint* rp);
LSnapshot* buildSnapshot(LInstruction* ins, MResumePoint* rp, BailoutKind kind);
bool assignPostSnapshot(MInstruction* mir, LInstruction* ins);
// Marks this instruction as fallible, meaning that before it performs
// effects (if any), it may check pre-conditions and bailout if they do not
// hold. This function informs the register allocator that it will need to
// capture appropriate state.
void assignSnapshot(LInstruction* ins, BailoutKind kind);
// Marks this instruction as needing to call into either the VM or GC. This
// function may build a snapshot that captures the result of its own
// instruction, and as such, should generally be called after define*().
void assignSafepoint(LInstruction* ins, MInstruction* mir,
BailoutKind kind = Bailout_DuringVMCall);
public:
void lowerConstantDouble(double d, MInstruction* mir) {
define(new(alloc()) LDouble(wasm::RawF64(d)), mir);
}
void lowerConstantFloat32(float f, MInstruction* mir) {
define(new(alloc()) LFloat32(wasm::RawF32(f)), mir);
}
void visitConstant(MConstant* ins) override;
// Whether to generate typed reads for element accesses with hole checks.
static bool allowTypedElementHoleCheck() {
return false;
}
// Whether to generate typed array accesses on statically known objects.
static bool allowStaticTypedArrayAccesses() {
return false;
}
// Provide NYI default implementations of the SIMD visitor functions.
// Many targets don't implement SIMD at all, and we don't want to duplicate
// these stubs in the specific sub-classes.
// Some SIMD visitors are implemented in LIRGenerator in Lowering.cpp. These
// shared implementations are not included here.
void visitSimdInsertElement(MSimdInsertElement*) override { MOZ_CRASH("NYI"); }
void visitSimdExtractElement(MSimdExtractElement*) override { MOZ_CRASH("NYI"); }
void visitSimdBinaryArith(MSimdBinaryArith*) override { MOZ_CRASH("NYI"); }
void visitSimdSelect(MSimdSelect*) override { MOZ_CRASH("NYI"); }
void visitSimdSplat(MSimdSplat*) override { MOZ_CRASH("NYI"); }
void visitSimdValueX4(MSimdValueX4*) override { MOZ_CRASH("NYI"); }
void visitSimdBinarySaturating(MSimdBinarySaturating*) override { MOZ_CRASH("NYI"); }
void visitSimdSwizzle(MSimdSwizzle*) override { MOZ_CRASH("NYI"); }
void visitSimdShuffle(MSimdShuffle*) override { MOZ_CRASH("NYI"); }
void visitSimdGeneralShuffle(MSimdGeneralShuffle*) override { MOZ_CRASH("NYI"); }
};
} // namespace jit
} // namespace js
#endif /* jit_shared_Lowering_shared_h */
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