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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_MIR_h
#define jit_MIR_h
// This file declares everything needed to build actual MIR instructions: the
// actual opcodes and instructions themselves, the instruction interface, and
// use chains.
#include "jscntxt.h"
#include "jslibmath.h"
#include "jsinfer.h"
#include "jsinferinlines.h"
#include "jstypedarrayinlines.h"
#include "TypePolicy.h"
#include "IonAllocPolicy.h"
#include "InlineList.h"
#include "MOpcodes.h"
#include "FixedArityList.h"
#include "IonMacroAssembler.h"
#include "Bailouts.h"
#include "FixedList.h"
#include "CompilerRoot.h"
namespace js {
namespace jit {
class BaselineInspector;
class ValueNumberData;
class Range;
static const inline
MIRType MIRTypeFromValue(const js::Value &vp)
{
if (vp.isDouble())
return MIRType_Double;
return MIRTypeFromValueType(vp.extractNonDoubleType());
}
#define MIR_FLAG_LIST(_) \
_(InWorklist) \
_(EmittedAtUses) \
_(LoopInvariant) \
_(Commutative) \
_(Movable) /* Allow LICM and GVN to move this instruction */ \
_(Lowered) /* (Debug only) has a virtual register */ \
_(Guard) /* Not removable if uses == 0 */ \
_(Folded) /* Has constant folded uses not reflected in SSA */ \
\
/* The instruction has been marked dead for lazy removal from resume
* points.
*/ \
_(Unused) \
_(DOMFunction) /* Contains or uses a common DOM method function */ \
\
/* Marks if an instruction has fewer uses than the original code.
* E.g. UCE can remove code.
* Every instruction where an use is/was removed from an instruction and
* as a result the number of operands doesn't equal the original code
* need to get marked as UseRemoved. This is important for truncation
* analysis to know, since if all original uses are still present,
* it can ignore resumepoints.
* Currently this is done for every pass after IonBuilder and before
* Truncate Doubles. So every time removeUse is called, UseRemoved needs
* to get set.
*/ \
_(UseRemoved)
class MDefinition;
class MInstruction;
class MBasicBlock;
class MNode;
class MUse;
class MIRGraph;
class MResumePoint;
// Represents a use of a node.
class MUse : public TempObject, public InlineListNode<MUse>
{
friend class MDefinition;
MDefinition *producer_; // MDefinition that is being used.
MNode *consumer_; // The node that is using this operand.
uint32_t index_; // The index of this operand in its consumer.
MUse(MDefinition *producer, MNode *consumer, uint32_t index)
: producer_(producer),
consumer_(consumer),
index_(index)
{ }
public:
// Default constructor for use in vectors.
MUse()
: producer_(NULL), consumer_(NULL), index_(0)
{ }
static inline MUse *New(MDefinition *producer, MNode *consumer, uint32_t index) {
return new MUse(producer, consumer, index);
}
// Set data inside the MUse.
void set(MDefinition *producer, MNode *consumer, uint32_t index) {
producer_ = producer;
consumer_ = consumer;
index_ = index;
}
MDefinition *producer() const {
JS_ASSERT(producer_ != NULL);
return producer_;
}
bool hasProducer() const {
return producer_ != NULL;
}
MNode *consumer() const {
JS_ASSERT(consumer_ != NULL);
return consumer_;
}
uint32_t index() const {
return index_;
}
};
typedef InlineList<MUse>::iterator MUseIterator;
// A node is an entry in the MIR graph. It has two kinds:
// MInstruction: an instruction which appears in the IR stream.
// MResumePoint: a list of instructions that correspond to the state of the
// interpreter stack.
//
// Nodes can hold references to MDefinitions. Each MDefinition has a list of
// nodes holding such a reference (its use chain).
class MNode : public TempObject
{
friend class MDefinition;
protected:
MBasicBlock *block_; // Containing basic block.
public:
enum Kind {
Definition,
ResumePoint
};
MNode()
: block_(NULL)
{ }
MNode(MBasicBlock *block)
: block_(block)
{ }
virtual Kind kind() const = 0;
// Returns the definition at a given operand.
virtual MDefinition *getOperand(size_t index) const = 0;
virtual size_t numOperands() const = 0;
bool isDefinition() const {
return kind() == Definition;
}
bool isResumePoint() const {
return kind() == ResumePoint;
}
MBasicBlock *block() const {
return block_;
}
// Instructions needing to hook into type analysis should return a
// TypePolicy.
virtual TypePolicy *typePolicy() {
return NULL;
}
// Replaces an already-set operand during iteration over a use chain.
MUseIterator replaceOperand(MUseIterator use, MDefinition *ins);
// Replaces an already-set operand, updating use information.
void replaceOperand(size_t index, MDefinition *ins);
// Resets the operand to an uninitialized state, breaking the link
// with the previous operand's producer.
void discardOperand(size_t index);
inline MDefinition *toDefinition();
inline MResumePoint *toResumePoint();
protected:
// Sets an unset operand, updating use information.
virtual void setOperand(size_t index, MDefinition *operand) = 0;
// Gets the MUse corresponding to given operand.
virtual MUse *getUseFor(size_t index) = 0;
};
class AliasSet {
private:
uint32_t flags_;
public:
enum Flag {
None_ = 0,
ObjectFields = 1 << 0, // shape, class, slots, length etc.
Element = 1 << 1, // A member of obj->elements.
DynamicSlot = 1 << 2, // A member of obj->slots.
FixedSlot = 1 << 3, // A member of obj->fixedSlots().
TypedArrayElement = 1 << 4, // A typed array element.
DOMProperty = 1 << 5, // A DOM property
TypedArrayLength = 1 << 6,// A typed array's length
Last = TypedArrayLength,
Any = Last | (Last - 1),
NumCategories = 7,
// Indicates load or store.
Store_ = 1 << 31
};
AliasSet(uint32_t flags)
: flags_(flags)
{
JS_STATIC_ASSERT((1 << NumCategories) - 1 == Any);
}
public:
inline bool isNone() const {
return flags_ == None_;
}
uint32_t flags() const {
return flags_ & Any;
}
inline bool isStore() const {
return !!(flags_ & Store_);
}
inline bool isLoad() const {
return !isStore() && !isNone();
}
inline AliasSet operator |(const AliasSet &other) const {
return AliasSet(flags_ | other.flags_);
}
inline AliasSet operator &(const AliasSet &other) const {
return AliasSet(flags_ & other.flags_);
}
static AliasSet None() {
return AliasSet(None_);
}
static AliasSet Load(uint32_t flags) {
JS_ASSERT(flags && !(flags & Store_));
return AliasSet(flags);
}
static AliasSet Store(uint32_t flags) {
JS_ASSERT(flags && !(flags & Store_));
return AliasSet(flags | Store_);
}
};
// An MDefinition is an SSA name.
class MDefinition : public MNode
{
friend class MBasicBlock;
friend class Loop;
public:
enum Opcode {
# define DEFINE_OPCODES(op) Op_##op,
MIR_OPCODE_LIST(DEFINE_OPCODES)
# undef DEFINE_OPCODES
Op_Invalid
};
private:
InlineList<MUse> uses_; // Use chain.
uint32_t id_; // Instruction ID, which after block re-ordering
// is sorted within a basic block.
ValueNumberData *valueNumber_; // The instruction's value number (see GVN for details in use)
Range *range_; // Any computed range for this def.
MIRType resultType_; // Representation of result type.
types::StackTypeSet *resultTypeSet_; // Optional refinement of the result type.
uint32_t flags_; // Bit flags.
union {
MDefinition *dependency_; // Implicit dependency (store, call, etc.) of this instruction.
// Used by alias analysis, GVN and LICM.
uint32_t virtualRegister_; // Used by lowering to map definitions to virtual registers.
};
// Track bailouts by storing the current pc in MIR instruction. Also used
// for profiling and keeping track of what the last known pc was.
jsbytecode *trackedPc_;
private:
enum Flag {
None = 0,
# define DEFINE_FLAG(flag) flag,
MIR_FLAG_LIST(DEFINE_FLAG)
# undef DEFINE_FLAG
Total
};
void setBlock(MBasicBlock *block) {
block_ = block;
}
bool hasFlags(uint32_t flags) const {
return (flags_ & flags) == flags;
}
void removeFlags(uint32_t flags) {
flags_ &= ~flags;
}
void setFlags(uint32_t flags) {
flags_ |= flags;
}
virtual bool neverHoist() const { return false; }
public:
MDefinition()
: id_(0),
valueNumber_(NULL),
range_(NULL),
resultType_(MIRType_None),
resultTypeSet_(NULL),
flags_(0),
dependency_(NULL),
trackedPc_(NULL)
{ }
virtual Opcode op() const = 0;
virtual const char *opName() const = 0;
void printName(FILE *fp);
static void PrintOpcodeName(FILE *fp, Opcode op);
virtual void printOpcode(FILE *fp);
void setTrackedPc(jsbytecode *pc) {
trackedPc_ = pc;
}
jsbytecode *trackedPc() {
return trackedPc_;
}
Range *range() const {
return range_;
}
void setRange(Range *range) {
range_ = range;
}
virtual HashNumber valueHash() const;
virtual bool congruentTo(MDefinition* const &ins) const {
return false;
}
bool congruentIfOperandsEqual(MDefinition * const &ins) const;
virtual MDefinition *foldsTo(bool useValueNumbers);
virtual void analyzeEdgeCasesForward();
virtual void analyzeEdgeCasesBackward();
virtual bool truncate();
virtual bool isOperandTruncated(size_t index) const;
bool earlyAbortCheck();
// Compute an absolute or symbolic range for the value of this node.
// Ranges are only computed for definitions whose type is int32.
virtual void computeRange() {
}
MNode::Kind kind() const {
return MNode::Definition;
}
uint32_t id() const {
JS_ASSERT(block_);
return id_;
}
void setId(uint32_t id) {
id_ = id;
}
uint32_t valueNumber() const;
void setValueNumber(uint32_t vn);
ValueNumberData *valueNumberData() {
return valueNumber_;
}
void clearValueNumberData() {
valueNumber_ = NULL;
}
void setValueNumberData(ValueNumberData *vn) {
JS_ASSERT(valueNumber_ == NULL);
valueNumber_ = vn;
}
#define FLAG_ACCESSOR(flag) \
bool is##flag() const {\
return hasFlags(1 << flag);\
}\
void set##flag() {\
JS_ASSERT(!hasFlags(1 << flag));\
setFlags(1 << flag);\
}\
void setNot##flag() {\
JS_ASSERT(hasFlags(1 << flag));\
removeFlags(1 << flag);\
}\
void set##flag##Unchecked() {\
setFlags(1 << flag);\
}
MIR_FLAG_LIST(FLAG_ACCESSOR)
#undef FLAG_ACCESSOR
MIRType type() const {
return resultType_;
}
types::StackTypeSet *resultTypeSet() const {
return resultTypeSet_;
}
bool emptyResultTypeSet() const;
bool mightBeType(MIRType type) const {
JS_ASSERT(type != MIRType_Value);
if (type == this->type())
return true;
if (MIRType_Value != this->type())
return false;
return !resultTypeSet() || resultTypeSet()->mightBeType(ValueTypeFromMIRType(type));
}
// Returns the beginning of this definition's use chain.
MUseIterator usesBegin() const {
return uses_.begin();
}
// Returns the end of this definition's use chain.
MUseIterator usesEnd() const {
return uses_.end();
}
bool canEmitAtUses() const {
return !isEmittedAtUses();
}
// Removes a use at the given position
MUseIterator removeUse(MUseIterator use);
void removeUse(MUse *use) {
uses_.remove(use);
}
// Number of uses of this instruction.
size_t useCount() const;
// Number of uses of this instruction.
// (only counting MDefinitions, ignoring MResumePoints)
size_t defUseCount() const;
bool hasUses() const {
return !uses_.empty();
}
virtual bool isControlInstruction() const {
return false;
}
void addUse(MUse *use) {
uses_.pushFront(use);
}
void replaceAllUsesWith(MDefinition *dom);
// Mark this instruction as having replaced all uses of ins, as during GVN,
// returning false if the replacement should not be performed. For use when
// GVN eliminates instructions which are not equivalent to one another.
virtual bool updateForReplacement(MDefinition *ins) {
return true;
}
// Same thing, but for folding
virtual bool updateForFolding(MDefinition *ins) {
return true;
}
void setVirtualRegister(uint32_t vreg) {
virtualRegister_ = vreg;
#ifdef DEBUG
setLoweredUnchecked();
#endif
}
uint32_t virtualRegister() const {
JS_ASSERT(isLowered());
return virtualRegister_;
}
public:
// Opcode testing and casts.
# define OPCODE_CASTS(opcode) \
bool is##opcode() const { \
return op() == Op_##opcode; \
} \
inline M##opcode *to##opcode();
MIR_OPCODE_LIST(OPCODE_CASTS)
# undef OPCODE_CASTS
inline MInstruction *toInstruction();
bool isInstruction() const {
return !isPhi();
}
void setResultType(MIRType type) {
resultType_ = type;
}
void setResultTypeSet(types::StackTypeSet *types) {
resultTypeSet_ = types;
}
MDefinition *dependency() const {
return dependency_;
}
void setDependency(MDefinition *dependency) {
dependency_ = dependency;
}
virtual AliasSet getAliasSet() const {
// Instructions are effectful by default.
return AliasSet::Store(AliasSet::Any);
}
bool isEffectful() const {
return getAliasSet().isStore();
}
virtual bool mightAlias(MDefinition *store) {
// Return whether this load may depend on the specified store, given
// that the alias sets intersect. This may be refined to exclude
// possible aliasing in cases where alias set flags are too imprecise.
JS_ASSERT(!isEffectful() && store->isEffectful());
JS_ASSERT(getAliasSet().flags() & store->getAliasSet().flags());
return true;
}
};
// An MUseDefIterator walks over uses in a definition, skipping any use that is
// not a definition. Items from the use list must not be deleted during
// iteration.
class MUseDefIterator
{
MDefinition *def_;
MUseIterator current_;
MUseIterator search(MUseIterator start) {
MUseIterator i(start);
for (; i != def_->usesEnd(); i++) {
if (i->consumer()->isDefinition())
return i;
}
return def_->usesEnd();
}
public:
MUseDefIterator(MDefinition *def)
: def_(def),
current_(search(def->usesBegin()))
{ }
operator bool() const {
return current_ != def_->usesEnd();
}
MUseDefIterator operator ++(int) {
MUseDefIterator old(*this);
if (current_ != def_->usesEnd())
current_++;
current_ = search(current_);
return old;
}
MUse *use() const {
return *current_;
}
MDefinition *def() const {
return current_->consumer()->toDefinition();
}
size_t index() const {
return current_->index();
}
};
// An instruction is an SSA name that is inserted into a basic block's IR
// stream.
class MInstruction
: public MDefinition,
public InlineListNode<MInstruction>
{
MResumePoint *resumePoint_;
public:
MInstruction()
: resumePoint_(NULL)
{ }
virtual bool accept(MInstructionVisitor *visitor) = 0;
void setResumePoint(MResumePoint *resumePoint) {
JS_ASSERT(!resumePoint_);
resumePoint_ = resumePoint;
}
MResumePoint *resumePoint() const {
return resumePoint_;
}
};
#define INSTRUCTION_HEADER(opcode) \
Opcode op() const { \
return MDefinition::Op_##opcode; \
} \
const char *opName() const { \
return #opcode; \
} \
bool accept(MInstructionVisitor *visitor) { \
return visitor->visit##opcode(this); \
}
template <size_t Arity>
class MAryInstruction : public MInstruction
{
protected:
FixedArityList<MUse, Arity> operands_;
void setOperand(size_t index, MDefinition *operand) {
operands_[index].set(operand, this, index);
operand->addUse(&operands_[index]);
}
MUse *getUseFor(size_t index) {
return &operands_[index];
}
public:
MDefinition *getOperand(size_t index) const {
return operands_[index].producer();
}
size_t numOperands() const {
return Arity;
}
};
class MNullaryInstruction : public MAryInstruction<0>
{ };
class MUnaryInstruction : public MAryInstruction<1>
{
protected:
MUnaryInstruction(MDefinition *ins)
{
setOperand(0, ins);
}
};
// Generates an LSnapshot without further effect.
class MStart : public MNullaryInstruction
{
public:
enum StartType {
StartType_Default,
StartType_Osr
};
private:
StartType startType_;
private:
MStart(StartType startType)
: startType_(startType)
{ }
public:
INSTRUCTION_HEADER(Start)
static MStart *New(StartType startType) {
return new MStart(startType);
}
StartType startType() {
return startType_;
}
};
// Instruction marking on entrypoint for on-stack replacement.
// OSR may occur at loop headers (at JSOP_TRACE).
// There is at most one MOsrEntry per MIRGraph.
class MOsrEntry : public MNullaryInstruction
{
protected:
MOsrEntry() {
setResultType(MIRType_Pointer);
}
public:
INSTRUCTION_HEADER(OsrEntry)
static MOsrEntry *New() {
return new MOsrEntry;
}
};
// No-op instruction. This cannot be moved or eliminated, and is intended for
// anchoring resume points at arbitrary points in a block.
class MNop : public MNullaryInstruction
{
protected:
MNop() {
}
public:
INSTRUCTION_HEADER(Nop)
static MNop *New() {
return new MNop();
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// A constant js::Value.
class MConstant : public MNullaryInstruction
{
Value value_;
protected:
MConstant(const Value &v);
public:
INSTRUCTION_HEADER(Constant)
static MConstant *New(const Value &v);
const js::Value &value() const {
return value_;
}
const js::Value *vp() const {
return &value_;
}
void printOpcode(FILE *fp);
HashNumber valueHash() const;
bool congruentTo(MDefinition * const &ins) const;
AliasSet getAliasSet() const {
return AliasSet::None();
}
void computeRange();
bool truncate();
};
class MParameter : public MNullaryInstruction
{
int32_t index_;
public:
static const int32_t THIS_SLOT = -1;
MParameter(int32_t index, types::StackTypeSet *types)
: index_(index)
{
setResultType(MIRType_Value);
setResultTypeSet(types);
}
public:
INSTRUCTION_HEADER(Parameter)
static MParameter *New(int32_t index, types::StackTypeSet *types);
int32_t index() const {
return index_;
}
void printOpcode(FILE *fp);
HashNumber valueHash() const;
bool congruentTo(MDefinition * const &ins) const;
};
class MCallee : public MNullaryInstruction
{
public:
MCallee()
{
setResultType(MIRType_Object);
setMovable();
}
public:
INSTRUCTION_HEADER(Callee)
bool congruentTo(MDefinition * const &ins) const {
return congruentIfOperandsEqual(ins);
}
static MCallee *New() {
return new MCallee();
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MControlInstruction : public MInstruction
{
public:
MControlInstruction()
{ }
virtual size_t numSuccessors() const = 0;
virtual MBasicBlock *getSuccessor(size_t i) const = 0;
virtual void replaceSuccessor(size_t i, MBasicBlock *successor) = 0;
bool isControlInstruction() const {
return true;
}
};
class MTableSwitch
: public MControlInstruction
{
// The successors of the tableswitch
// - First successor = the default case
// - Successor 2 and higher = the cases sorted on case index.
Vector<MBasicBlock*, 0, IonAllocPolicy> successors_;
// Contains the blocks/cases that still need to get build
Vector<MBasicBlock*, 0, IonAllocPolicy> blocks_;
MUse operand_;
int32_t low_;
int32_t high_;
MTableSwitch(MDefinition *ins,
int32_t low, int32_t high)
: successors_(),
blocks_(),
low_(low),
high_(high)
{
setOperand(0, ins);
}
protected:
void setOperand(size_t index, MDefinition *operand) {
JS_ASSERT(index == 0);
operand_.set(operand, this, index);
operand->addUse(&operand_);
}
MUse *getUseFor(size_t index) {
JS_ASSERT(index == 0);
return &operand_;
}
public:
INSTRUCTION_HEADER(TableSwitch)
static MTableSwitch *New(MDefinition *ins, int32_t low, int32_t high);
size_t numSuccessors() const {
return successors_.length();
}
MBasicBlock *getSuccessor(size_t i) const {
JS_ASSERT(i < numSuccessors());
return successors_[i];
}
void replaceSuccessor(size_t i, MBasicBlock *successor) {
JS_ASSERT(i < numSuccessors());
successors_[i] = successor;
}
MBasicBlock** blocks() {
return &blocks_[0];
}
size_t numBlocks() const {
return blocks_.length();
}
int32_t low() const {
return low_;
}
int32_t high() const {
return high_;
}
MBasicBlock *getDefault() const {
return getSuccessor(0);
}
MBasicBlock *getCase(size_t i) const {
return getSuccessor(i+1);
}
size_t numCases() const {
return high() - low() + 1;
}
void addDefault(MBasicBlock *block) {
JS_ASSERT(successors_.length() == 0);
successors_.append(block);
}
void addCase(MBasicBlock *block) {
JS_ASSERT(successors_.length() < (size_t)(high_ - low_ + 2));
JS_ASSERT(successors_.length() != 0);
successors_.append(block);
}
MBasicBlock *getBlock(size_t i) const {
JS_ASSERT(i < numBlocks());
return blocks_[i];
}
void addBlock(MBasicBlock *block) {
blocks_.append(block);
}
MDefinition *getOperand(size_t index) const {
JS_ASSERT(index == 0);
return operand_.producer();
}
size_t numOperands() const {
return 1;
}
};
template <size_t Arity, size_t Successors>
class MAryControlInstruction : public MControlInstruction
{
FixedArityList<MUse, Arity> operands_;
FixedArityList<MBasicBlock *, Successors> successors_;
protected:
void setOperand(size_t index, MDefinition *operand) {
operands_[index].set(operand, this, index);
operand->addUse(&operands_[index]);
}
void setSuccessor(size_t index, MBasicBlock *successor) {
successors_[index] = successor;
}
MUse *getUseFor(size_t index) {
return &operands_[index];
}
public:
MDefinition *getOperand(size_t index) const {
return operands_[index].producer();
}
size_t numOperands() const {
return Arity;
}
size_t numSuccessors() const {
return Successors;
}
MBasicBlock *getSuccessor(size_t i) const {
return successors_[i];
}
void replaceSuccessor(size_t i, MBasicBlock *succ) {
successors_[i] = succ;
}
};
// Jump to the start of another basic block.
class MGoto : public MAryControlInstruction<0, 1>
{
MGoto(MBasicBlock *target) {
setSuccessor(0, target);
}
public:
INSTRUCTION_HEADER(Goto)
static MGoto *New(MBasicBlock *target);
MBasicBlock *target() {
return getSuccessor(0);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
enum BranchDirection {
FALSE_BRANCH,
TRUE_BRANCH
};
static inline BranchDirection
NegateBranchDirection(BranchDirection dir)
{
return (dir == FALSE_BRANCH) ? TRUE_BRANCH : FALSE_BRANCH;
}
// Tests if the input instruction evaluates to true or false, and jumps to the
// start of a corresponding basic block.
class MTest
: public MAryControlInstruction<1, 2>,
public TestPolicy
{
bool operandMightEmulateUndefined_;
MTest(MDefinition *ins, MBasicBlock *if_true, MBasicBlock *if_false)
: operandMightEmulateUndefined_(true)
{
setOperand(0, ins);
setSuccessor(0, if_true);
setSuccessor(1, if_false);
}
public:
INSTRUCTION_HEADER(Test)
static MTest *New(MDefinition *ins,
MBasicBlock *ifTrue, MBasicBlock *ifFalse);
MBasicBlock *ifTrue() const {
return getSuccessor(0);
}
MBasicBlock *ifFalse() const {
return getSuccessor(1);
}
MBasicBlock *branchSuccessor(BranchDirection dir) const {
return (dir == TRUE_BRANCH) ? ifTrue() : ifFalse();
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
void infer(JSContext *cx);
MDefinition *foldsTo(bool useValueNumbers);
void markOperandCantEmulateUndefined() {
operandMightEmulateUndefined_ = false;
}
bool operandMightEmulateUndefined() const {
return operandMightEmulateUndefined_;
}
};
// Returns from this function to the previous caller.
class MReturn
: public MAryControlInstruction<1, 0>,
public BoxInputsPolicy
{
MReturn(MDefinition *ins) {
setOperand(0, ins);
}
public:
INSTRUCTION_HEADER(Return)
static MReturn *New(MDefinition *ins) {
return new MReturn(ins);
}
MDefinition *input() const {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MThrow
: public MAryControlInstruction<1, 0>,
public BoxInputsPolicy
{
MThrow(MDefinition *ins) {
setOperand(0, ins);
}
public:
INSTRUCTION_HEADER(Throw)
static MThrow *New(MDefinition *ins) {
return new MThrow(ins);
}
TypePolicy *typePolicy() {
return this;
}
virtual AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MNewParallelArray : public MNullaryInstruction
{
CompilerRootObject templateObject_;
MNewParallelArray(JSObject *templateObject)
: templateObject_(templateObject)
{
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(NewParallelArray);
static MNewParallelArray *New(JSObject *templateObject) {
return new MNewParallelArray(templateObject);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
JSObject *templateObject() const {
return templateObject_;
}
};
// Fabricate a type set containing only the type of the specified object.
types::StackTypeSet *
MakeSingletonTypeSet(JSObject *obj);
void
MergeTypes(MIRType *ptype, types::StackTypeSet **ptypeSet,
MIRType newType, types::StackTypeSet *newTypeSet);
class MNewArray : public MNullaryInstruction
{
public:
enum AllocatingBehaviour {
NewArray_Allocating,
NewArray_Unallocating
};
private:
// Number of space to allocate for the array.
uint32_t count_;
// Template for the created object.
CompilerRootObject templateObject_;
// Allocate space at initialization or not
AllocatingBehaviour allocating_;
public:
INSTRUCTION_HEADER(NewArray)
MNewArray(uint32_t count, JSObject *templateObject, AllocatingBehaviour allocating)
: count_(count),
templateObject_(templateObject),
allocating_(allocating)
{
setResultType(MIRType_Object);
setResultTypeSet(MakeSingletonTypeSet(templateObject));
}
uint32_t count() const {
return count_;
}
JSObject *templateObject() const {
return templateObject_;
}
bool isAllocating() const {
return allocating_ == NewArray_Allocating;
}
// Returns true if the code generator should call through to the
// VM rather than the fast path.
bool shouldUseVM() const;
// NewArray is marked as non-effectful because all our allocations are
// either lazy when we are using "new Array(length)" or bounded by the
// script or the stack size when we are using "new Array(...)" or "[...]"
// notations. So we might have to allocate the array twice if we bail
// during the computation of the first element of the square braket
// notation.
virtual AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MNewObject : public MNullaryInstruction
{
CompilerRootObject templateObject_;
bool templateObjectIsClassPrototype_;
MNewObject(JSObject *templateObject, bool templateObjectIsClassPrototype)
: templateObject_(templateObject),
templateObjectIsClassPrototype_(templateObjectIsClassPrototype)
{
JS_ASSERT_IF(templateObjectIsClassPrototype, !shouldUseVM());
setResultType(MIRType_Object);
setResultTypeSet(MakeSingletonTypeSet(templateObject));
}
public:
INSTRUCTION_HEADER(NewObject)
static MNewObject *New(JSObject *templateObject, bool templateObjectIsClassPrototype) {
return new MNewObject(templateObject, templateObjectIsClassPrototype);
}
// Returns true if the code generator should call through to the
// VM rather than the fast path.
bool shouldUseVM() const;
bool templateObjectIsClassPrototype() const {
return templateObjectIsClassPrototype_;
}
JSObject *templateObject() const {
return templateObject_;
}
};
// Could be allocating either a new array or a new object.
class MParNew : public MUnaryInstruction
{
CompilerRootObject templateObject_;
public:
INSTRUCTION_HEADER(ParNew);
MParNew(MDefinition *parSlice,
JSObject *templateObject)
: MUnaryInstruction(parSlice),
templateObject_(templateObject)
{
setResultType(MIRType_Object);
}
MDefinition *parSlice() const {
return getOperand(0);
}
JSObject *templateObject() const {
return templateObject_;
}
};
// Could be allocating either a new array or a new object.
class MParBailout : public MAryControlInstruction<0, 0>
{
public:
INSTRUCTION_HEADER(ParBailout);
MParBailout()
: MAryControlInstruction<0, 0>()
{
setResultType(MIRType_Undefined);
setGuard();
}
};
// Slow path for adding a property to an object without a known base.
class MInitProp
: public MAryInstruction<2>,
public MixPolicy<ObjectPolicy<0>, BoxPolicy<1> >
{
public:
CompilerRootPropertyName name_;
protected:
MInitProp(MDefinition *obj, HandlePropertyName name, MDefinition *value)
: name_(name)
{
setOperand(0, obj);
setOperand(1, value);
setResultType(MIRType_None);
}
public:
INSTRUCTION_HEADER(InitProp)
static MInitProp *New(MDefinition *obj, HandlePropertyName name, MDefinition *value) {
return new MInitProp(obj, name, value);
}
MDefinition *getObject() const {
return getOperand(0);
}
MDefinition *getValue() const {
return getOperand(1);
}
PropertyName *propertyName() const {
return name_;
}
TypePolicy *typePolicy() {
return this;
}
};
class MInitElem
: public MAryInstruction<3>,
public Mix3Policy<ObjectPolicy<0>, BoxPolicy<1>, BoxPolicy<2> >
{
MInitElem(MDefinition *obj, MDefinition *id, MDefinition *value)
{
setOperand(0, obj);
setOperand(1, id);
setOperand(2, value);
setResultType(MIRType_None);
}
public:
INSTRUCTION_HEADER(InitElem)
static MInitElem *New(MDefinition *obj, MDefinition *id, MDefinition *value) {
return new MInitElem(obj, id, value);
}
MDefinition *getObject() const {
return getOperand(0);
}
MDefinition *getId() const {
return getOperand(1);
}
MDefinition *getValue() const {
return getOperand(2);
}
TypePolicy *typePolicy() {
return this;
}
};
// Designates the start of call frame construction.
// Generates code to adjust the stack pointer for the argument vector.
// Argc is inferred by checking the use chain during lowering.
class MPrepareCall : public MNullaryInstruction
{
public:
INSTRUCTION_HEADER(PrepareCall)
MPrepareCall()
{ }
// Get the vector size for the upcoming call by looking at the call.
uint32_t argc() const;
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MVariadicInstruction : public MInstruction
{
FixedList<MUse> operands_;
protected:
bool init(size_t length) {
return operands_.init(length);
}
public:
// Will assert if called before initialization.
MDefinition *getOperand(size_t index) const {
return operands_[index].producer();
}
size_t numOperands() const {
return operands_.length();
}
void setOperand(size_t index, MDefinition *operand) {
operands_[index].set(operand, this, index);
operand->addUse(&operands_[index]);
}
MUse *getUseFor(size_t index) {
return &operands_[index];
}
};
class MCall
: public MVariadicInstruction,
public CallPolicy
{
private:
// An MCall uses the MPrepareCall, MDefinition for the function, and
// MPassArg instructions. They are stored in the same list.
static const size_t PrepareCallOperandIndex = 0;
static const size_t FunctionOperandIndex = 1;
static const size_t NumNonArgumentOperands = 2;
protected:
// True if the call is for JSOP_NEW.
bool construct_;
// Monomorphic cache of single target from TI, or NULL.
CompilerRootFunction target_;
// Holds a target's Script alive.
CompilerRootScript targetScript_;
// Original value of argc from the bytecode.
uint32_t numActualArgs_;
bool needsArgCheck_;
MCall(JSFunction *target, uint32_t numActualArgs, bool construct)
: construct_(construct),
target_(target),
targetScript_(NULL),
numActualArgs_(numActualArgs),
needsArgCheck_(true)
{
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(Call)
static MCall *New(JSFunction *target, size_t maxArgc, size_t numActualArgs, bool construct);
void initPrepareCall(MDefinition *start) {
JS_ASSERT(start->isPrepareCall());
return setOperand(PrepareCallOperandIndex, start);
}
void initFunction(MDefinition *func) {
JS_ASSERT(!func->isPassArg());
return setOperand(FunctionOperandIndex, func);
}
bool needsArgCheck() const {
return needsArgCheck_;
}
void disableArgCheck() {
needsArgCheck_ = false;
}
MPrepareCall *getPrepareCall() {
return getOperand(PrepareCallOperandIndex)->toPrepareCall();
}
MDefinition *getFunction() const {
return getOperand(FunctionOperandIndex);
}
void replaceFunction(MInstruction *newfunc) {
replaceOperand(FunctionOperandIndex, newfunc);
}
void addArg(size_t argnum, MPassArg *arg);
MDefinition *getArg(uint32_t index) const {
return getOperand(NumNonArgumentOperands + index);
}
void rootTargetScript(JSFunction *target) {
targetScript_.setRoot(target->nonLazyScript());
}
bool hasRootedScript() {
return targetScript_ != NULL;
}
// For TI-informed monomorphic callsites.
JSFunction *getSingleTarget() const {
return target_;
}
bool isConstructing() const {
return construct_;
}
// The number of stack arguments is the max between the number of formal
// arguments and the number of actual arguments. The number of stack
// argument includes the |undefined| padding added in case of underflow.
// Includes |this|.
uint32_t numStackArgs() const {
return numOperands() - NumNonArgumentOperands;
}
// Does not include |this|.
uint32_t numActualArgs() const {
return numActualArgs_;
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
return AliasSet::Store(AliasSet::Any);
}
};
// fun.apply(self, arguments)
class MApplyArgs
: public MAryInstruction<3>,
public MixPolicy<ObjectPolicy<0>, MixPolicy<IntPolicy<1>, BoxPolicy<2> > >
{
protected:
// Monomorphic cache of single target from TI, or NULL.
CompilerRootFunction target_;
MApplyArgs(JSFunction *target, MDefinition *fun, MDefinition *argc, MDefinition *self)
: target_(target)
{
setOperand(0, fun);
setOperand(1, argc);
setOperand(2, self);
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(ApplyArgs)
static MApplyArgs *New(JSFunction *target, MDefinition *fun, MDefinition *argc,
MDefinition *self);
MDefinition *getFunction() const {
return getOperand(0);
}
// For TI-informed monomorphic callsites.
JSFunction *getSingleTarget() const {
return target_;
}
MDefinition *getArgc() const {
return getOperand(1);
}
MDefinition *getThis() const {
return getOperand(2);
}
TypePolicy *typePolicy() {
return this;
}
};
class MGetDynamicName
: public MAryInstruction<2>,
public MixPolicy<ObjectPolicy<0>, StringPolicy<1> >
{
protected:
MGetDynamicName(MDefinition *scopeChain, MDefinition *name)
{
setOperand(0, scopeChain);
setOperand(1, name);
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(GetDynamicName)
static MGetDynamicName *
New(MDefinition *scopeChain, MDefinition *name) {
return new MGetDynamicName(scopeChain, name);
}
MDefinition *getScopeChain() const {
return getOperand(0);
}
MDefinition *getName() const {
return getOperand(1);
}
TypePolicy *typePolicy() {
return this;
}
};
// Bailout if the input string contains 'arguments'
class MFilterArguments
: public MAryInstruction<1>,
public StringPolicy<0>
{
protected:
MFilterArguments(MDefinition *string)
{
setOperand(0, string);
setGuard();
setResultType(MIRType_None);
}
public:
INSTRUCTION_HEADER(FilterArguments)
static MFilterArguments *
New(MDefinition *string) {
return new MFilterArguments(string);
}
MDefinition *getString() const {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
};
class MCallDirectEval
: public MAryInstruction<3>,
public MixPolicy<ObjectPolicy<0>, MixPolicy<StringPolicy<1>, BoxPolicy<2> > >
{
protected:
MCallDirectEval(MDefinition *scopeChain, MDefinition *string, MDefinition *thisValue,
jsbytecode *pc)
: pc_(pc)
{
setOperand(0, scopeChain);
setOperand(1, string);
setOperand(2, thisValue);
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(CallDirectEval)
static MCallDirectEval *
New(MDefinition *scopeChain, MDefinition *string, MDefinition *thisValue,
jsbytecode *pc) {
return new MCallDirectEval(scopeChain, string, thisValue, pc);
}
MDefinition *getScopeChain() const {
return getOperand(0);
}
MDefinition *getString() const {
return getOperand(1);
}
MDefinition *getThisValue() const {
return getOperand(2);
}
jsbytecode *pc() const {
return pc_;
}
TypePolicy *typePolicy() {
return this;
}
private:
jsbytecode *pc_;
};
class MBinaryInstruction : public MAryInstruction<2>
{
protected:
MBinaryInstruction(MDefinition *left, MDefinition *right)
{
setOperand(0, left);
setOperand(1, right);
}
public:
MDefinition *lhs() const {
return getOperand(0);
}
MDefinition *rhs() const {
return getOperand(1);
}
protected:
HashNumber valueHash() const
{
MDefinition *lhs = getOperand(0);
MDefinition *rhs = getOperand(1);
return op() ^ lhs->valueNumber() ^ rhs->valueNumber();
}
void swapOperands() {
MDefinition *temp = getOperand(0);
replaceOperand(0, getOperand(1));
replaceOperand(1, temp);
}
bool congruentTo(MDefinition *const &ins) const
{
if (op() != ins->op())
return false;
if (type() != ins->type())
return false;
if (isEffectful() || ins->isEffectful())
return false;
MDefinition *left = getOperand(0);
MDefinition *right = getOperand(1);
MDefinition *tmp;
if (isCommutative() && left->valueNumber() > right->valueNumber()) {
tmp = right;
right = left;
left = tmp;
}
MDefinition *insLeft = ins->getOperand(0);
MDefinition *insRight = ins->getOperand(1);
if (isCommutative() && insLeft->valueNumber() > insRight->valueNumber()) {
tmp = insRight;
insRight = insLeft;
insLeft = tmp;
}
return (left->valueNumber() == insLeft->valueNumber()) &&
(right->valueNumber() == insRight->valueNumber());
}
};
class MTernaryInstruction : public MAryInstruction<3>
{
protected:
MTernaryInstruction(MDefinition *first, MDefinition *second, MDefinition *third)
{
setOperand(0, first);
setOperand(1, second);
setOperand(2, third);
}
protected:
HashNumber valueHash() const
{
MDefinition *first = getOperand(0);
MDefinition *second = getOperand(1);
MDefinition *third = getOperand(2);
return op() ^ first->valueNumber() ^ second->valueNumber() ^ third->valueNumber();
}
bool congruentTo(MDefinition *const &ins) const
{
if (op() != ins->op())
return false;
if (type() != ins->type())
return false;
if (isEffectful() || ins->isEffectful())
return false;
MDefinition *first = getOperand(0);
MDefinition *second = getOperand(1);
MDefinition *third = getOperand(2);
MDefinition *insFirst = ins->getOperand(0);
MDefinition *insSecond = ins->getOperand(1);
MDefinition *insThird = ins->getOperand(2);
return first->valueNumber() == insFirst->valueNumber() &&
second->valueNumber() == insSecond->valueNumber() &&
third->valueNumber() == insThird->valueNumber();
}
};
class MQuaternaryInstruction : public MAryInstruction<4>
{
protected:
MQuaternaryInstruction(MDefinition *first, MDefinition *second,
MDefinition *third, MDefinition *fourth)
{
setOperand(0, first);
setOperand(1, second);
setOperand(2, third);
setOperand(3, fourth);
}
protected:
HashNumber valueHash() const
{
MDefinition *first = getOperand(0);
MDefinition *second = getOperand(1);
MDefinition *third = getOperand(2);
MDefinition *fourth = getOperand(3);
return op() ^ first->valueNumber() ^ second->valueNumber() ^
third->valueNumber() ^ fourth->valueNumber();
}
bool congruentTo(MDefinition *const &ins) const
{
if (op() != ins->op())
return false;
if (type() != ins->type())
return false;
if (isEffectful() || ins->isEffectful())
return false;
MDefinition *first = getOperand(0);
MDefinition *second = getOperand(1);
MDefinition *third = getOperand(2);
MDefinition *fourth = getOperand(3);
MDefinition *insFirst = ins->getOperand(0);
MDefinition *insSecond = ins->getOperand(1);
MDefinition *insThird = ins->getOperand(2);
MDefinition *insFourth = ins->getOperand(3);
return first->valueNumber() == insFirst->valueNumber() &&
second->valueNumber() == insSecond->valueNumber() &&
third->valueNumber() == insThird->valueNumber() &&
fourth->valueNumber() == insFourth->valueNumber();
}
};
class MCompare
: public MBinaryInstruction,
public ComparePolicy
{
public:
enum CompareType {
// Anything compared to Undefined
Compare_Undefined,
// Anything compared to Null
Compare_Null,
// Undefined compared to Boolean
// Null compared to Boolean
// Double compared to Boolean
// String compared to Boolean
// Object compared to Boolean
// Value compared to Boolean
Compare_Boolean,
// Int32 compared to Int32
// Boolean compared to Boolean
Compare_Int32,
// Int32 compared as unsigneds
Compare_UInt32,
// Double compared to Double
Compare_Double,
Compare_DoubleMaybeCoerceLHS,
Compare_DoubleMaybeCoerceRHS,
// String compared to String
Compare_String,
// Undefined compared to String
// Null compared to String
// Boolean compared to String
// Int32 compared to String
// Double compared to String
// Object compared to String
// Value compared to String
Compare_StrictString,
// Object compared to Object
Compare_Object,
// Compare 2 values bitwise
Compare_Value,
// All other possible compares
Compare_Unknown
};
private:
CompareType compareType_;
JSOp jsop_;
bool operandMightEmulateUndefined_;
MCompare(MDefinition *left, MDefinition *right, JSOp jsop)
: MBinaryInstruction(left, right),
compareType_(Compare_Unknown),
jsop_(jsop),
operandMightEmulateUndefined_(true)
{
setResultType(MIRType_Boolean);
setMovable();
}
public:
INSTRUCTION_HEADER(Compare)
static MCompare *New(MDefinition *left, MDefinition *right, JSOp op);
static MCompare *NewAsmJS(MDefinition *left, MDefinition *right, JSOp op, CompareType compareType);
bool tryFold(bool *result);
bool evaluateConstantOperands(bool *result);
MDefinition *foldsTo(bool useValueNumbers);
void infer(JSContext *cx, BaselineInspector *inspector, jsbytecode *pc);
CompareType compareType() const {
return compareType_;
}
bool isDoubleComparison() const {
return compareType() == Compare_Double ||
compareType() == Compare_DoubleMaybeCoerceLHS ||
compareType() == Compare_DoubleMaybeCoerceRHS;
}
void setCompareType(CompareType type) {
compareType_ = type;
}
MIRType inputType();
JSOp jsop() const {
return jsop_;
}
TypePolicy *typePolicy() {
return this;
}
void markNoOperandEmulatesUndefined() {
operandMightEmulateUndefined_ = false;
}
bool operandMightEmulateUndefined() const {
return operandMightEmulateUndefined_;
}
AliasSet getAliasSet() const {
// Strict equality is never effectful.
if (jsop_ == JSOP_STRICTEQ || jsop_ == JSOP_STRICTNE)
return AliasSet::None();
if (compareType_ == Compare_Unknown)
return AliasSet::Store(AliasSet::Any);
JS_ASSERT(compareType_ <= Compare_Value);
return AliasSet::None();
}
protected:
bool congruentTo(MDefinition *const &ins) const {
if (!MBinaryInstruction::congruentTo(ins))
return false;
return compareType() == ins->toCompare()->compareType() &&
jsop() == ins->toCompare()->jsop();
}
};
// Takes a typed value and returns an untyped value.
class MBox : public MUnaryInstruction
{
MBox(MDefinition *ins)
: MUnaryInstruction(ins)
{
setResultType(MIRType_Value);
if (ins->resultTypeSet()) {
setResultTypeSet(ins->resultTypeSet());
} else if (ins->type() != MIRType_Value) {
types::Type ntype = ins->type() == MIRType_Object
? types::Type::AnyObjectType()
: types::Type::PrimitiveType(ValueTypeFromMIRType(ins->type()));
setResultTypeSet(GetIonContext()->temp->lifoAlloc()->new_<types::StackTypeSet>(ntype));
}
setMovable();
}
public:
INSTRUCTION_HEADER(Box)
static MBox *New(MDefinition *ins)
{
// Cannot box a box.
JS_ASSERT(ins->type() != MIRType_Value);
return new MBox(ins);
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// Note: the op may have been inverted during lowering (to put constants in a
// position where they can be immediates), so it is important to use the
// lir->jsop() instead of the mir->jsop() when it is present.
static inline Assembler::Condition
JSOpToCondition(MCompare::CompareType compareType, JSOp op)
{
bool isSigned = (compareType != MCompare::Compare_UInt32);
return JSOpToCondition(op, isSigned);
}
// Takes a typed value and checks if it is a certain type. If so, the payload
// is unpacked and returned as that type. Otherwise, it is considered a
// deoptimization.
class MUnbox : public MUnaryInstruction, public BoxInputsPolicy
{
public:
enum Mode {
Fallible, // Check the type, and deoptimize if unexpected.
Infallible, // Type guard is not necessary.
TypeBarrier, // Guard on the type, and act like a TypeBarrier on failure.
TypeGuard // Guard on the type, and deoptimize otherwise.
};
private:
Mode mode_;
MUnbox(MDefinition *ins, MIRType type, Mode mode)
: MUnaryInstruction(ins),
mode_(mode)
{
JS_ASSERT(ins->type() == MIRType_Value);
JS_ASSERT(type == MIRType_Boolean ||
type == MIRType_Int32 ||
type == MIRType_Double ||
type == MIRType_String ||
type == MIRType_Object);
setResultType(type);
setResultTypeSet(ins->resultTypeSet());
setMovable();
if (mode_ == TypeBarrier || mode_ == TypeGuard)
setGuard();
if (mode_ == TypeGuard)
mode_ = Fallible;
}
public:
INSTRUCTION_HEADER(Unbox)
static MUnbox *New(MDefinition *ins, MIRType type, Mode mode)
{
return new MUnbox(ins, type, mode);
}
TypePolicy *typePolicy() {
return this;
}
Mode mode() const {
return mode_;
}
MDefinition *input() const {
return getOperand(0);
}
BailoutKind bailoutKind() const {
// If infallible, no bailout should be generated.
JS_ASSERT(fallible());
return mode() == Fallible
? Bailout_Normal
: Bailout_TypeBarrier;
}
bool fallible() const {
return mode() != Infallible;
}
bool congruentTo(MDefinition *const &ins) const {
if (!ins->isUnbox() || ins->toUnbox()->mode() != mode())
return false;
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
void printOpcode(FILE *fp);
};
class MGuardObject : public MUnaryInstruction, public SingleObjectPolicy
{
MGuardObject(MDefinition *ins)
: MUnaryInstruction(ins)
{
setGuard();
setMovable();
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(GuardObject)
static MGuardObject *New(MDefinition *ins) {
return new MGuardObject(ins);
}
MDefinition *input() const {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MGuardString
: public MUnaryInstruction,
public StringPolicy<0>
{
MGuardString(MDefinition *ins)
: MUnaryInstruction(ins)
{
setGuard();
setMovable();
setResultType(MIRType_String);
}
public:
INSTRUCTION_HEADER(GuardString)
static MGuardString *New(MDefinition *ins) {
return new MGuardString(ins);
}
MDefinition *input() const {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// Caller-side allocation of |this| for |new|:
// Given a templateobject, construct |this| for JSOP_NEW
class MCreateThisWithTemplate
: public MNullaryInstruction
{
// Template for |this|, provided by TI
CompilerRootObject templateObject_;
MCreateThisWithTemplate(JSObject *templateObject)
: templateObject_(templateObject)
{
setResultType(MIRType_Object);
setResultTypeSet(MakeSingletonTypeSet(templateObject));
}
public:
INSTRUCTION_HEADER(CreateThisWithTemplate);
static MCreateThisWithTemplate *New(JSObject *templateObject)
{
return new MCreateThisWithTemplate(templateObject);
}
JSObject *getTemplateObject() const {
return templateObject_;
}
// Although creation of |this| modifies global state, it is safely repeatable.
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// Caller-side allocation of |this| for |new|:
// Given a prototype operand, construct |this| for JSOP_NEW.
class MCreateThisWithProto
: public MBinaryInstruction,
public MixPolicy<ObjectPolicy<0>, ObjectPolicy<1> >
{
MCreateThisWithProto(MDefinition *callee, MDefinition *prototype)
: MBinaryInstruction(callee, prototype)
{
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(CreateThisWithProto)
static MCreateThisWithProto *New(MDefinition *callee, MDefinition *prototype)
{
return new MCreateThisWithProto(callee, prototype);
}
MDefinition *getCallee() const {
return getOperand(0);
}
MDefinition *getPrototype() const {
return getOperand(1);
}
// Although creation of |this| modifies global state, it is safely repeatable.
AliasSet getAliasSet() const {
return AliasSet::None();
}
TypePolicy *typePolicy() {
return this;
}
};
// Caller-side allocation of |this| for |new|:
// Constructs |this| when possible, else MagicValue(JS_IS_CONSTRUCTING).
class MCreateThis
: public MUnaryInstruction,
public ObjectPolicy<0>
{
MCreateThis(MDefinition *callee)
: MUnaryInstruction(callee)
{
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(CreateThis)
static MCreateThis *New(MDefinition *callee)
{
return new MCreateThis(callee);
}
MDefinition *getCallee() const {
return getOperand(0);
}
// Although creation of |this| modifies global state, it is safely repeatable.
AliasSet getAliasSet() const {
return AliasSet::None();
}
TypePolicy *typePolicy() {
return this;
}
};
// Eager initialization of arguments object.
class MCreateArgumentsObject
: public MUnaryInstruction,
public ObjectPolicy<0>
{
MCreateArgumentsObject(MDefinition *callObj)
: MUnaryInstruction(callObj)
{
setResultType(MIRType_Object);
setGuard();
}
public:
INSTRUCTION_HEADER(CreateArgumentsObject)
static MCreateArgumentsObject *New(MDefinition *callObj) {
return new MCreateArgumentsObject(callObj);
}
MDefinition *getCallObject() const {
return getOperand(0);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
TypePolicy *typePolicy() {
return this;
}
};
class MGetArgumentsObjectArg
: public MUnaryInstruction,
public ObjectPolicy<0>
{
size_t argno_;
MGetArgumentsObjectArg(MDefinition *argsObject, size_t argno)
: MUnaryInstruction(argsObject),
argno_(argno)
{
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(GetArgumentsObjectArg)
static MGetArgumentsObjectArg *New(MDefinition *argsObj, size_t argno)
{
return new MGetArgumentsObjectArg(argsObj, argno);
}
MDefinition *getArgsObject() const {
return getOperand(0);
}
size_t argno() const {
return argno_;
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::Any);
}
TypePolicy *typePolicy() {
return this;
}
};
class MSetArgumentsObjectArg
: public MBinaryInstruction,
public MixPolicy<ObjectPolicy<0>, BoxPolicy<1> >
{
size_t argno_;
MSetArgumentsObjectArg(MDefinition *argsObj, size_t argno, MDefinition *value)
: MBinaryInstruction(argsObj, value),
argno_(argno)
{
}
public:
INSTRUCTION_HEADER(SetArgumentsObjectArg)
static MSetArgumentsObjectArg *New(MDefinition *argsObj, size_t argno, MDefinition *value)
{
return new MSetArgumentsObjectArg(argsObj, argno, value);
}
MDefinition *getArgsObject() const {
return getOperand(0);
}
size_t argno() const {
return argno_;
}
MDefinition *getValue() const {
return getOperand(1);
}
AliasSet getAliasSet() const {
return AliasSet::Store(AliasSet::Any);
}
TypePolicy *typePolicy() {
return this;
}
};
class MRunOncePrologue
: public MNullaryInstruction
{
protected:
MRunOncePrologue()
{
setGuard();
}
public:
INSTRUCTION_HEADER(RunOncePrologue)
static MRunOncePrologue *New() {
return new MRunOncePrologue();
}
};
// Given a MIRType_Value A and a MIRType_Object B:
// If the Value may be safely unboxed to an Object, return Object(A).
// Otherwise, return B.
// Used to implement return behavior for inlined constructors.
class MReturnFromCtor
: public MAryInstruction<2>,
public MixPolicy<BoxPolicy<0>, ObjectPolicy<1> >
{
MReturnFromCtor(MDefinition *value, MDefinition *object) {
setOperand(0, value);
setOperand(1, object);
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(ReturnFromCtor)
static MReturnFromCtor *New(MDefinition *value, MDefinition *object)
{
return new MReturnFromCtor(value, object);
}
MDefinition *getValue() const {
return getOperand(0);
}
MDefinition *getObject() const {
return getOperand(1);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
TypePolicy *typePolicy() {
return this;
}
};
// Passes an MDefinition to an MCall. Must occur between an MPrepareCall and
// MCall. Boxes the input and stores it to the correct location on stack.
//
// Arguments are *not* simply pushed onto a call stack: they are evaluated
// left-to-right, but stored in the arg vector in C-style, right-to-left.
class MPassArg : public MUnaryInstruction
{
int32_t argnum_;
private:
MPassArg(MDefinition *def)
: MUnaryInstruction(def), argnum_(-1)
{
setResultType(def->type());
setResultTypeSet(def->resultTypeSet());
}
public:
INSTRUCTION_HEADER(PassArg)
static MPassArg *New(MDefinition *def)
{
return new MPassArg(def);
}
MDefinition *getArgument() const {
return getOperand(0);
}
// Set by the MCall.
void setArgnum(uint32_t argnum) {
argnum_ = argnum;
}
uint32_t getArgnum() const {
JS_ASSERT(argnum_ >= 0);
return (uint32_t)argnum_;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
void printOpcode(FILE *fp);
};
// Converts a primitive (either typed or untyped) to a double. If the input is
// not primitive at runtime, a bailout occurs.
class MToDouble
: public MUnaryInstruction,
public ToDoublePolicy
{
public:
// Types of values which can be converted.
enum ConversionKind {
NonStringPrimitives,
NonNullNonStringPrimitives,
NumbersOnly
};
private:
ConversionKind conversion_;
MToDouble(MDefinition *def, ConversionKind conversion = NonStringPrimitives)
: MUnaryInstruction(def), conversion_(conversion)
{
setResultType(MIRType_Double);
setMovable();
}
public:
INSTRUCTION_HEADER(ToDouble)
static MToDouble *New(MDefinition *def, ConversionKind conversion = NonStringPrimitives) {
return new MToDouble(def, conversion);
}
static MToDouble *NewAsmJS(MDefinition *def) {
return new MToDouble(def);
}
ConversionKind conversion() const {
return conversion_;
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *foldsTo(bool useValueNumbers);
MDefinition *input() const {
return getOperand(0);
}
bool congruentTo(MDefinition *const &ins) const {
if (!ins->isToDouble() || ins->toToDouble()->conversion() != conversion())
return false;
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
void computeRange();
bool truncate();
bool isOperandTruncated(size_t index) const;
};
// Converts a uint32 to a double (coming from asm.js).
class MAsmJSUnsignedToDouble
: public MUnaryInstruction
{
MAsmJSUnsignedToDouble(MDefinition *def)
: MUnaryInstruction(def)
{
setResultType(MIRType_Double);
setMovable();
}
public:
INSTRUCTION_HEADER(AsmJSUnsignedToDouble);
static MAsmJSUnsignedToDouble *NewAsmJS(MDefinition *def) {
return new MAsmJSUnsignedToDouble(def);
}
MDefinition *foldsTo(bool useValueNumbers);
MDefinition *input() const {
return getOperand(0);
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// Converts a primitive (either typed or untyped) to an int32. If the input is
// not primitive at runtime, a bailout occurs. If the input cannot be converted
// to an int32 without loss (i.e. "5.5" or undefined) then a bailout occurs.
class MToInt32 : public MUnaryInstruction
{
bool canBeNegativeZero_;
MToInt32(MDefinition *def)
: MUnaryInstruction(def),
canBeNegativeZero_(true)
{
setResultType(MIRType_Int32);
setMovable();
}
public:
INSTRUCTION_HEADER(ToInt32)
static MToInt32 *New(MDefinition *def)
{
return new MToInt32(def);
}
MDefinition *input() const {
return getOperand(0);
}
MDefinition *foldsTo(bool useValueNumbers);
// this only has backwards information flow.
void analyzeEdgeCasesBackward();
bool canBeNegativeZero() {
return canBeNegativeZero_;
}
void setCanBeNegativeZero(bool negativeZero) {
canBeNegativeZero_ = negativeZero;
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
void computeRange();
};
// Converts a value or typed input to a truncated int32, for use with bitwise
// operations. This is an infallible ValueToECMAInt32.
class MTruncateToInt32 : public MUnaryInstruction
{
MTruncateToInt32(MDefinition *def)
: MUnaryInstruction(def)
{
setResultType(MIRType_Int32);
setMovable();
}
public:
INSTRUCTION_HEADER(TruncateToInt32)
static MTruncateToInt32 *New(MDefinition *def) {
return new MTruncateToInt32(def);
}
static MTruncateToInt32 *NewAsmJS(MDefinition *def) {
return new MTruncateToInt32(def);
}
MDefinition *input() const {
return getOperand(0);
}
MDefinition *foldsTo(bool useValueNumbers);
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
void computeRange();
bool isOperandTruncated(size_t index) const;
};
// Converts any type to a string
class MToString : public MUnaryInstruction
{
MToString(MDefinition *def)
: MUnaryInstruction(def)
{
setResultType(MIRType_String);
setMovable();
}
public:
INSTRUCTION_HEADER(ToString)
static MToString *New(MDefinition *def)
{
return new MToString(def);
}
MDefinition *input() const {
return getOperand(0);
}
MDefinition *foldsTo(bool useValueNumbers);
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
JS_ASSERT(input()->type() < MIRType_Object);
return AliasSet::None();
}
};
class MBitNot
: public MUnaryInstruction,
public BitwisePolicy
{
protected:
MBitNot(MDefinition *input)
: MUnaryInstruction(input)
{
setResultType(MIRType_Int32);
setMovable();
}
public:
INSTRUCTION_HEADER(BitNot)
static MBitNot *New(MDefinition *input);
static MBitNot *NewAsmJS(MDefinition *input);
TypePolicy *typePolicy() {
return this;
}
MDefinition *foldsTo(bool useValueNumbers);
void infer();
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
if (specialization_ == MIRType_None)
return AliasSet::Store(AliasSet::Any);
return AliasSet::None();
}
};
class MTypeOf
: public MUnaryInstruction,
public BoxInputsPolicy
{
MIRType inputType_;
MTypeOf(MDefinition *def, MIRType inputType)
: MUnaryInstruction(def), inputType_(inputType)
{
setResultType(MIRType_String);
setMovable();
}
public:
INSTRUCTION_HEADER(TypeOf)
static MTypeOf *New(MDefinition *def, MIRType inputType) {
return new MTypeOf(def, inputType);
}
TypePolicy *typePolicy() {
return this;
}
MIRType inputType() const {
return inputType_;
}
MDefinition *input() const {
return getOperand(0);
}
MDefinition *foldsTo(bool useValueNumbers);
AliasSet getAliasSet() const {
if (inputType_ <= MIRType_String)
return AliasSet::None();
// For objects, typeof may invoke an effectful typeof hook.
return AliasSet::Store(AliasSet::Any);
}
};
class MToId
: public MBinaryInstruction,
public BoxInputsPolicy
{
MToId(MDefinition *object, MDefinition *index)
: MBinaryInstruction(object, index)
{
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(ToId)
static MToId *New(MDefinition *object, MDefinition *index) {
return new MToId(object, index);
}
TypePolicy *typePolicy() {
return this;
}
};
class MBinaryBitwiseInstruction
: public MBinaryInstruction,
public BitwisePolicy
{
protected:
MBinaryBitwiseInstruction(MDefinition *left, MDefinition *right)
: MBinaryInstruction(left, right)
{
setResultType(MIRType_Int32);
setMovable();
}
void specializeForAsmJS();
public:
TypePolicy *typePolicy() {
return this;
}
MDefinition *foldsTo(bool useValueNumbers);
MDefinition *foldUnnecessaryBitop();
virtual MDefinition *foldIfZero(size_t operand) = 0;
virtual MDefinition *foldIfNegOne(size_t operand) = 0;
virtual MDefinition *foldIfEqual() = 0;
virtual void infer(BaselineInspector *inspector, jsbytecode *pc);
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
if (specialization_ >= MIRType_Object)
return AliasSet::Store(AliasSet::Any);
return AliasSet::None();
}
bool isOperandTruncated(size_t index) const;
};
class MBitAnd : public MBinaryBitwiseInstruction
{
MBitAnd(MDefinition *left, MDefinition *right)
: MBinaryBitwiseInstruction(left, right)
{ }
public:
INSTRUCTION_HEADER(BitAnd)
static MBitAnd *New(MDefinition *left, MDefinition *right);
static MBitAnd *NewAsmJS(MDefinition *left, MDefinition *right);
MDefinition *foldIfZero(size_t operand) {
return getOperand(operand); // 0 & x => 0;
}
MDefinition *foldIfNegOne(size_t operand) {
return getOperand(1 - operand); // x & -1 => x
}
MDefinition *foldIfEqual() {
return getOperand(0); // x & x => x;
}
void computeRange();
};
class MBitOr : public MBinaryBitwiseInstruction
{
MBitOr(MDefinition *left, MDefinition *right)
: MBinaryBitwiseInstruction(left, right)
{ }
public:
INSTRUCTION_HEADER(BitOr)
static MBitOr *New(MDefinition *left, MDefinition *right);
static MBitOr *NewAsmJS(MDefinition *left, MDefinition *right);
MDefinition *foldIfZero(size_t operand) {
return getOperand(1 - operand); // 0 | x => x, so if ith is 0, return (1-i)th
}
MDefinition *foldIfNegOne(size_t operand) {
return getOperand(operand); // x | -1 => -1
}
MDefinition *foldIfEqual() {
return getOperand(0); // x | x => x
}
};
class MBitXor : public MBinaryBitwiseInstruction
{
MBitXor(MDefinition *left, MDefinition *right)
: MBinaryBitwiseInstruction(left, right)
{ }
public:
INSTRUCTION_HEADER(BitXor)
static MBitXor *New(MDefinition *left, MDefinition *right);
static MBitXor *NewAsmJS(MDefinition *left, MDefinition *right);
MDefinition *foldIfZero(size_t operand) {
return getOperand(1 - operand); // 0 ^ x => x
}
MDefinition *foldIfNegOne(size_t operand) {
return this;
}
MDefinition *foldIfEqual() {
return this;
}
};
class MShiftInstruction
: public MBinaryBitwiseInstruction
{
protected:
MShiftInstruction(MDefinition *left, MDefinition *right)
: MBinaryBitwiseInstruction(left, right)
{ }
public:
MDefinition *foldIfNegOne(size_t operand) {
return this;
}
MDefinition *foldIfEqual() {
return this;
}
virtual void infer(BaselineInspector *inspector, jsbytecode *pc);
};
class MLsh : public MShiftInstruction
{
MLsh(MDefinition *left, MDefinition *right)
: MShiftInstruction(left, right)
{ }
public:
INSTRUCTION_HEADER(Lsh)
static MLsh *New(MDefinition *left, MDefinition *right);
static MLsh *NewAsmJS(MDefinition *left, MDefinition *right);
MDefinition *foldIfZero(size_t operand) {
// 0 << x => 0
// x << 0 => x
return getOperand(0);
}
void computeRange();
};
class MRsh : public MShiftInstruction
{
MRsh(MDefinition *left, MDefinition *right)
: MShiftInstruction(left, right)
{ }
public:
INSTRUCTION_HEADER(Rsh)
static MRsh *New(MDefinition *left, MDefinition *right);
static MRsh *NewAsmJS(MDefinition *left, MDefinition *right);
MDefinition *foldIfZero(size_t operand) {
// 0 >> x => 0
// x >> 0 => x
return getOperand(0);
}
void computeRange();
};
class MUrsh : public MShiftInstruction
{
bool canOverflow_;
MUrsh(MDefinition *left, MDefinition *right)
: MShiftInstruction(left, right),
canOverflow_(true)
{ }
public:
INSTRUCTION_HEADER(Ursh)
static MUrsh *New(MDefinition *left, MDefinition *right);
static MUrsh *NewAsmJS(MDefinition *left, MDefinition *right);
MDefinition *foldIfZero(size_t operand) {
// 0 >>> x => 0
if (operand == 0)
return getOperand(0);
return this;
}
void infer(BaselineInspector *inspector, jsbytecode *pc);
bool canOverflow() {
// solution is only negative when lhs < 0 and rhs & 0x1f == 0
MDefinition *lhs = getOperand(0);
MDefinition *rhs = getOperand(1);
if (lhs->isConstant()) {
Value lhsv = lhs->toConstant()->value();
if (lhsv.isInt32() && lhsv.toInt32() >= 0)
return false;
}
if (rhs->isConstant()) {
Value rhsv = rhs->toConstant()->value();
if (rhsv.isInt32() && rhsv.toInt32() % 32 != 0)
return false;
}
return canOverflow_;
}
bool fallible() {
return canOverflow();
}
};
class MBinaryArithInstruction
: public MBinaryInstruction,
public ArithPolicy
{
// Implicit truncate flag is set by the truncate backward range analysis
// optimization phase, and by asm.js pre-processing. It is used in
// NeedNegativeZeroCheck to check if the result of a multiplication needs to
// produce -0 double value, and for avoiding overflow checks.
// This optimization happens when the multiplication cannot be truncated
// even if all uses are truncating its result, such as when the range
// analysis detect a precision loss in the multiplication.
bool implicitTruncate_;
void inferFallback(BaselineInspector *inspector, jsbytecode *pc);
public:
MBinaryArithInstruction(MDefinition *left, MDefinition *right)
: MBinaryInstruction(left, right),
implicitTruncate_(false)
{
setMovable();
}
TypePolicy *typePolicy() {
return this;
}
MIRType specialization() const {
return specialization_;
}
MDefinition *foldsTo(bool useValueNumbers);
virtual double getIdentity() = 0;
void infer(BaselineInspector *inspector,
jsbytecode *pc, bool overflowed);
void setInt32() {
specialization_ = MIRType_Int32;
setResultType(MIRType_Int32);
}
bool congruentTo(MDefinition *const &ins) const {
return MBinaryInstruction::congruentTo(ins);
}
AliasSet getAliasSet() const {
if (specialization_ >= MIRType_Object)
return AliasSet::Store(AliasSet::Any);
return AliasSet::None();
}
bool isTruncated() const {
return implicitTruncate_;
}
void setTruncated(bool truncate) {
implicitTruncate_ = truncate;
}
};
class MMinMax
: public MBinaryInstruction,
public ArithPolicy
{
bool isMax_;
MMinMax(MDefinition *left, MDefinition *right, MIRType type, bool isMax)
: MBinaryInstruction(left, right),
isMax_(isMax)
{
JS_ASSERT(type == MIRType_Double || type == MIRType_Int32);
setResultType(type);
setMovable();
specialization_ = type;
}
public:
INSTRUCTION_HEADER(MinMax)
static MMinMax *New(MDefinition *left, MDefinition *right, MIRType type, bool isMax) {
return new MMinMax(left, right, type, isMax);
}
bool isMax() const {
return isMax_;
}
MIRType specialization() const {
return specialization_;
}
TypePolicy *typePolicy() {
return this;
}
bool congruentTo(MDefinition *const &ins) const {
if (!ins->isMinMax())
return false;
if (isMax() != ins->toMinMax()->isMax())
return false;
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MAbs
: public MUnaryInstruction,
public ArithPolicy
{
bool implicitTruncate_;
MAbs(MDefinition *num, MIRType type)
: MUnaryInstruction(num),
implicitTruncate_(false)
{
JS_ASSERT(type == MIRType_Double || type == MIRType_Int32);
setResultType(type);
setMovable();
specialization_ = type;
}
public:
INSTRUCTION_HEADER(Abs)
static MAbs *New(MDefinition *num, MIRType type) {
return new MAbs(num, type);
}
static MAbs *NewAsmJS(MDefinition *num, MIRType type) {
MAbs *ins = new MAbs(num, type);
ins->implicitTruncate_ = true;
return ins;
}
MDefinition *num() const {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
bool fallible() const;
AliasSet getAliasSet() const {
return AliasSet::None();
}
void computeRange();
};
// Inline implementation of Math.sqrt().
class MSqrt
: public MUnaryInstruction,
public DoublePolicy<0>
{
MSqrt(MDefinition *num)
: MUnaryInstruction(num)
{
setResultType(MIRType_Double);
setMovable();
}
public:
INSTRUCTION_HEADER(Sqrt)
static MSqrt *New(MDefinition *num) {
return new MSqrt(num);
}
static MSqrt *NewAsmJS(MDefinition *num, MIRType type) {
JS_ASSERT(type == MIRType_Double);
return new MSqrt(num);
}
MDefinition *num() const {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// Inline implementation of atan2 (arctangent of y/x).
class MAtan2
: public MBinaryInstruction,
public MixPolicy<DoublePolicy<0>, DoublePolicy<1> >
{
MAtan2(MDefinition *y, MDefinition *x)
: MBinaryInstruction(y, x)
{
setResultType(MIRType_Double);
setMovable();
}
public:
INSTRUCTION_HEADER(Atan2)
static MAtan2 *New(MDefinition *y, MDefinition *x) {
return new MAtan2(y, x);
}
MDefinition *y() const {
return getOperand(0);
}
MDefinition *x() const {
return getOperand(1);
}
TypePolicy *typePolicy() {
return this;
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// Inline implementation of Math.pow().
class MPow
: public MBinaryInstruction,
public PowPolicy
{
MPow(MDefinition *input, MDefinition *power, MIRType powerType)
: MBinaryInstruction(input, power),
PowPolicy(powerType)
{
setResultType(MIRType_Double);
setMovable();
}
public:
INSTRUCTION_HEADER(Pow)
static MPow *New(MDefinition *input, MDefinition *power, MIRType powerType) {
return new MPow(input, power, powerType);
}
MDefinition *input() const {
return lhs();
}
MDefinition *power() const {
return rhs();
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// Inline implementation of Math.pow(x, 0.5), which subtly differs from Math.sqrt(x).
class MPowHalf
: public MUnaryInstruction,
public DoublePolicy<0>
{
MPowHalf(MDefinition *input)
: MUnaryInstruction(input)
{
setResultType(MIRType_Double);
setMovable();
}
public:
INSTRUCTION_HEADER(PowHalf)
static MPowHalf *New(MDefinition *input) {
return new MPowHalf(input);
}
MDefinition *input() const {
return getOperand(0);
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// Inline implementation of Math.random().
class MRandom : public MNullaryInstruction
{
MRandom()
{
setResultType(MIRType_Double);
}
public:
INSTRUCTION_HEADER(Random)
static MRandom *New() {
return new MRandom;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MMathFunction
: public MUnaryInstruction,
public DoublePolicy<0>
{
public:
enum Function {
Log,
Sin,
Cos,
Exp,
Tan,
ACos,
ASin,
ATan
};
private:
Function function_;
MathCache *cache_;
MMathFunction(MDefinition *input, Function function, MathCache *cache)
: MUnaryInstruction(input), function_(function), cache_(cache)
{
setResultType(MIRType_Double);
setMovable();
}
public:
INSTRUCTION_HEADER(MathFunction)
static MMathFunction *New(MDefinition *input, Function function, MathCache *cache) {
return new MMathFunction(input, function, cache);
}
Function function() const {
return function_;
}
MathCache *cache() const {
return cache_;
}
MDefinition *input() const {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
bool congruentTo(MDefinition *const &ins) const {
if (!ins->isMathFunction())
return false;
if (ins->toMathFunction()->function() != function())
return false;
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MAdd : public MBinaryArithInstruction
{
// Is this instruction really an int at heart?
MAdd(MDefinition *left, MDefinition *right)
: MBinaryArithInstruction(left, right)
{
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(Add)
static MAdd *New(MDefinition *left, MDefinition *right) {
return new MAdd(left, right);
}
static MAdd *NewAsmJS(MDefinition *left, MDefinition *right, MIRType type) {
MAdd *add = new MAdd(left, right);
add->specialization_ = type;
add->setResultType(type);
if (type == MIRType_Int32) {
add->setTruncated(true);
add->setCommutative();
}
return add;
}
void analyzeTruncateBackward();
double getIdentity() {
return 0;
}
bool fallible();
void computeRange();
bool truncate();
bool isOperandTruncated(size_t index) const;
};
class MSub : public MBinaryArithInstruction
{
MSub(MDefinition *left, MDefinition *right)
: MBinaryArithInstruction(left, right)
{
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(Sub)
static MSub *New(MDefinition *left, MDefinition *right) {
return new MSub(left, right);
}
static MSub *NewAsmJS(MDefinition *left, MDefinition *right, MIRType type) {
MSub *sub = new MSub(left, right);
sub->specialization_ = type;
sub->setResultType(type);
if (type == MIRType_Int32)
sub->setTruncated(true);
return sub;
}
double getIdentity() {
return 0;
}
bool fallible();
void computeRange();
bool truncate();
bool isOperandTruncated(size_t index) const;
};
class MMul : public MBinaryArithInstruction
{
public:
enum Mode {
Normal,
Integer
};
private:
// Annotation the result could be a negative zero
// and we need to guard this during execution.
bool canBeNegativeZero_;
Mode mode_;
MMul(MDefinition *left, MDefinition *right, MIRType type, Mode mode)
: MBinaryArithInstruction(left, right),
canBeNegativeZero_(true),
mode_(mode)
{
if (mode == Integer) {
// This implements the required behavior for Math.imul, which
// can never fail and always truncates its output to int32.
canBeNegativeZero_ = false;
setTruncated(true);
setCommutative();
}
JS_ASSERT_IF(mode != Integer, mode == Normal);
if (type != MIRType_Value)
specialization_ = type;
setResultType(type);
}
public:
INSTRUCTION_HEADER(Mul)
static MMul *New(MDefinition *left, MDefinition *right) {
return new MMul(left, right, MIRType_Value, MMul::Normal);
}
static MMul *New(MDefinition *left, MDefinition *right, MIRType type, Mode mode = Normal) {
return new MMul(left, right, type, mode);
}
MDefinition *foldsTo(bool useValueNumbers);
void analyzeEdgeCasesForward();
void analyzeEdgeCasesBackward();
double getIdentity() {
return 1;
}
bool canOverflow();
bool canBeNegativeZero() {
return canBeNegativeZero_;
}
void setCanBeNegativeZero(bool negativeZero) {
canBeNegativeZero_ = negativeZero;
}
bool updateForReplacement(MDefinition *ins);
bool fallible() {
return canBeNegativeZero_ || canOverflow();
}
void computeRange();
bool truncate();
bool isOperandTruncated(size_t index) const;
Mode mode() { return mode_; }
};
class MDiv : public MBinaryArithInstruction
{
bool canBeNegativeZero_;
bool canBeNegativeOverflow_;
bool canBeDivideByZero_;
MDiv(MDefinition *left, MDefinition *right, MIRType type)
: MBinaryArithInstruction(left, right),
canBeNegativeZero_(true),
canBeNegativeOverflow_(true),
canBeDivideByZero_(true)
{
if (type != MIRType_Value)
specialization_ = type;
setResultType(type);
}
public:
INSTRUCTION_HEADER(Div)
static MDiv *New(MDefinition *left, MDefinition *right) {
return new MDiv(left, right, MIRType_Value);
}
static MDiv *New(MDefinition *left, MDefinition *right, MIRType type) {
return new MDiv(left, right, type);
}
static MDiv *NewAsmJS(MDefinition *left, MDefinition *right, MIRType type) {
MDiv *div = new MDiv(left, right, type);
if (type == MIRType_Int32)
div->setTruncated(true);
return div;
}
MDefinition *foldsTo(bool useValueNumbers);
void analyzeEdgeCasesForward();
void analyzeEdgeCasesBackward();
double getIdentity() {
JS_NOT_REACHED("not used");
return 1;
}
bool canBeNegativeZero() {
return canBeNegativeZero_;
}
void setCanBeNegativeZero(bool negativeZero) {
canBeNegativeZero_ = negativeZero;
}
bool canBeNegativeOverflow() {
return canBeNegativeOverflow_;
}
bool canBeDivideByZero() {
return canBeDivideByZero_;
}
bool fallible();
bool truncate();
#if defined(JS_CPU_MIPS)
// isTruncatedDirectly_ defaults to false in SpiderMonkey 31.
bool isTruncatedIndirectly() const {
return false;
}
bool canTruncateInfinities() const {
return isTruncated();
}
bool canTruncateRemainder() const {
return isTruncated();
}
bool canTruncateOverflow() const {
return isTruncated() || isTruncatedIndirectly();
}
bool canTruncateNegativeZero() const {
return isTruncated() || isTruncatedIndirectly();
}
#endif
};
class MMod : public MBinaryArithInstruction
{
MMod(MDefinition *left, MDefinition *right, MIRType type)
: MBinaryArithInstruction(left, right)
{
if (type != MIRType_Value)
specialization_ = type;
setResultType(type);
}
public:
INSTRUCTION_HEADER(Mod)
static MMod *New(MDefinition *left, MDefinition *right) {
return new MMod(left, right, MIRType_Value);
}
static MMod *NewAsmJS(MDefinition *left, MDefinition *right, MIRType type) {
MMod *mod = new MMod(left, right, type);
if (type == MIRType_Int32)
mod->setTruncated(true);
return mod;
}
MDefinition *foldsTo(bool useValueNumbers);
double getIdentity() {
JS_NOT_REACHED("not used");
return 1;
}
bool fallible();
void computeRange();
bool truncate();
#if defined(JS_CPU_MIPS)
// Can be negativeDividend defaults to true in SpiderMonkey31 and is set
// to 0 in several areas that analyze the code. Since false seems to be
// more restrictive, we return that here. This seems to be ok so far,
// however we should be careful when this code is run.
bool canBeNegativeDividend() const {
JS_ASSERT(specialization_ == MIRType_Int32);
SB_LOG(WARNING) << "canBeNegativeDividend() returning false";
return false;
}
bool
canBeDivideByZero() const {
JS_ASSERT(specialization_ == MIRType_Int32);
return !rhs()->isConstant() || rhs()->toConstant()->value().toInt32() == 0;
}
// unsigned_ defaults to false in SpiderMonkey31.
bool isUnsigned() const {
return false;
}
#endif
};
class MConcat
: public MBinaryInstruction,
public BinaryStringPolicy
{
MConcat(MDefinition *left, MDefinition *right)
: MBinaryInstruction(left, right)
{
setMovable();
setResultType(MIRType_String);
}
public:
INSTRUCTION_HEADER(Concat)
static MConcat *New(MDefinition *left, MDefinition *right) {
return new MConcat(left, right);
}
TypePolicy *typePolicy() {
return this;
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MCharCodeAt
: public MBinaryInstruction,
public MixPolicy<StringPolicy<0>, IntPolicy<1> >
{
MCharCodeAt(MDefinition *str, MDefinition *index)
: MBinaryInstruction(str, index)
{
setMovable();
setResultType(MIRType_Int32);
}
public:
INSTRUCTION_HEADER(CharCodeAt)
static MCharCodeAt *New(MDefinition *str, MDefinition *index) {
return new MCharCodeAt(str, index);
}
TypePolicy *typePolicy() {
return this;
}
virtual AliasSet getAliasSet() const {
// Strings are immutable, so there is no implicit dependency.
return AliasSet::None();
}
void computeRange();
};
class MFromCharCode
: public MUnaryInstruction,
public IntPolicy<0>
{
MFromCharCode(MDefinition *code)
: MUnaryInstruction(code)
{
setMovable();
setResultType(MIRType_String);
}
public:
INSTRUCTION_HEADER(FromCharCode)
static MFromCharCode *New(MDefinition *code) {
return new MFromCharCode(code);
}
virtual AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MPhi : public MDefinition, public InlineForwardListNode<MPhi>
{
js::Vector<MUse, 2, IonAllocPolicy> inputs_;
uint32_t slot_;
bool hasBackedgeType_;
bool triedToSpecialize_;
bool isIterator_;
#if DEBUG
bool specialized_;
uint32_t capacity_;
#endif
MPhi(uint32_t slot)
: slot_(slot),
hasBackedgeType_(false),
triedToSpecialize_(false),
isIterator_(false)
#if DEBUG
, specialized_(false)
, capacity_(0)
#endif
{
setResultType(MIRType_Value);
}
protected:
MUse *getUseFor(size_t index) {
return &inputs_[index];
}
public:
INSTRUCTION_HEADER(Phi)
static MPhi *New(uint32_t slot);
void setOperand(size_t index, MDefinition *operand) {
// Note: after the initial IonBuilder pass, it is OK to change phi
// operands such that they do not include the type sets of their
// operands. This can arise during e.g. value numbering, where
// definitions producing the same value may have different type sets.
JS_ASSERT(index < numOperands());
inputs_[index].set(operand, this, index);
operand->addUse(&inputs_[index]);
}
void removeOperand(size_t index);
MDefinition *getOperand(size_t index) const {
return inputs_[index].producer();
}
size_t numOperands() const {
return inputs_.length();
}
uint32_t slot() const {
return slot_;
}
bool hasBackedgeType() const {
return hasBackedgeType_;
}
bool triedToSpecialize() const {
return triedToSpecialize_;
}
void specialize(MIRType type) {
triedToSpecialize_ = true;
setResultType(type);
}
void specializeType();
// Whether this phi's type already includes information for def.
bool typeIncludes(MDefinition *def);
// Add types for this phi which speculate about new inputs that may come in
// via a loop backedge.
void addBackedgeType(MIRType type, types::StackTypeSet *typeSet);
// Initializes the operands vector to the given capacity,
// permitting use of addInput() instead of addInputSlow().
bool reserveLength(size_t length);
// Use only if capacity has been reserved by reserveLength
void addInput(MDefinition *ins);
// Appends a new input to the input vector. May call realloc_().
// Prefer reserveLength() and addInput() instead, where possible.
bool addInputSlow(MDefinition *ins, bool *ptypeChange = NULL);
MDefinition *foldsTo(bool useValueNumbers);
bool congruentTo(MDefinition * const &ins) const;
bool isIterator() const {
return isIterator_;
}
void setIterator() {
isIterator_ = true;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
void computeRange();
MDefinition *operandIfRedundant() {
// If this phi is redundant (e.g., phi(a,a) or b=phi(a,this)),
// returns the operand that it will always be equal to (a, in
// those two cases).
MDefinition *first = getOperand(0);
for (size_t i = 1; i < numOperands(); i++) {
if (getOperand(i) != first && getOperand(i) != this)
return NULL;
}
return first;
}
};
// The goal of a Beta node is to split a def at a conditionally taken
// branch, so that uses dominated by it have a different name.
class MBeta : public MUnaryInstruction
{
private:
const Range *comparison_;
MDefinition *val_;
MBeta(MDefinition *val, const Range *comp)
: MUnaryInstruction(val),
comparison_(comp),
val_(val)
{
setResultType(val->type());
setResultTypeSet(val->resultTypeSet());
}
public:
INSTRUCTION_HEADER(Beta)
void printOpcode(FILE *fp);
static MBeta *New(MDefinition *val, const Range *comp)
{
return new MBeta(val, comp);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
void computeRange();
};
// MIR representation of a Value on the OSR StackFrame.
// The Value is indexed off of OsrFrameReg.
class MOsrValue : public MUnaryInstruction
{
private:
ptrdiff_t frameOffset_;
MOsrValue(MOsrEntry *entry, ptrdiff_t frameOffset)
: MUnaryInstruction(entry),
frameOffset_(frameOffset)
{
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(OsrValue)
static MOsrValue *New(MOsrEntry *entry, ptrdiff_t frameOffset) {
return new MOsrValue(entry, frameOffset);
}
ptrdiff_t frameOffset() const {
return frameOffset_;
}
MOsrEntry *entry() {
return getOperand(0)->toOsrEntry();
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// MIR representation of a JSObject scope chain pointer on the OSR StackFrame.
// The pointer is indexed off of OsrFrameReg.
class MOsrScopeChain : public MUnaryInstruction
{
private:
MOsrScopeChain(MOsrEntry *entry)
: MUnaryInstruction(entry)
{
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(OsrScopeChain)
static MOsrScopeChain *New(MOsrEntry *entry) {
return new MOsrScopeChain(entry);
}
MOsrEntry *entry() {
return getOperand(0)->toOsrEntry();
}
};
// Check the current frame for over-recursion past the global stack limit.
class MCheckOverRecursed : public MNullaryInstruction
{
public:
INSTRUCTION_HEADER(CheckOverRecursed)
};
// Check the current frame for over-recursion past the global stack limit.
// Uses the per-thread recursion limit.
class MParCheckOverRecursed : public MUnaryInstruction
{
public:
INSTRUCTION_HEADER(ParCheckOverRecursed);
MParCheckOverRecursed(MDefinition *parForkJoinSlice)
: MUnaryInstruction(parForkJoinSlice)
{
setResultType(MIRType_None);
setGuard();
setMovable();
}
MDefinition *parSlice() const {
return getOperand(0);
}
};
// Check for an interrupt (or rendezvous) in parallel mode.
class MParCheckInterrupt : public MUnaryInstruction
{
public:
INSTRUCTION_HEADER(ParCheckInterrupt);
MParCheckInterrupt(MDefinition *parForkJoinSlice)
: MUnaryInstruction(parForkJoinSlice)
{
setResultType(MIRType_None);
setGuard();
setMovable();
}
MDefinition *parSlice() const {
return getOperand(0);
}
};
// Check whether we need to fire the interrupt handler.
class MInterruptCheck : public MNullaryInstruction
{
MInterruptCheck() {
setGuard();
}
public:
INSTRUCTION_HEADER(InterruptCheck)
static MInterruptCheck *New() {
return new MInterruptCheck();
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// If not defined, set a global variable to |undefined|.
class MDefVar : public MUnaryInstruction
{
CompilerRootPropertyName name_; // Target name to be defined.
unsigned attrs_; // Attributes to be set.
private:
MDefVar(PropertyName *name, unsigned attrs, MDefinition *scopeChain)
: MUnaryInstruction(scopeChain),
name_(name),
attrs_(attrs)
{
}
public:
INSTRUCTION_HEADER(DefVar)
static MDefVar *New(PropertyName *name, unsigned attrs, MDefinition *scopeChain) {
return new MDefVar(name, attrs, scopeChain);
}
PropertyName *name() const {
return name_;
}
unsigned attrs() const {
return attrs_;
}
MDefinition *scopeChain() const {
return getOperand(0);
}
};
class MDefFun : public MUnaryInstruction
{
CompilerRootFunction fun_;
private:
MDefFun(HandleFunction fun, MDefinition *scopeChain)
: MUnaryInstruction(scopeChain),
fun_(fun)
{}
public:
INSTRUCTION_HEADER(DefFun)
static MDefFun *New(HandleFunction fun, MDefinition *scopeChain) {
return new MDefFun(fun, scopeChain);
}
JSFunction *fun() const {
return fun_;
}
MDefinition *scopeChain() const {
return getOperand(0);
}
};
class MRegExp : public MNullaryInstruction
{
CompilerRoot<RegExpObject *> source_;
CompilerRootObject prototype_;
MRegExp(RegExpObject *source, JSObject *prototype)
: source_(source),
prototype_(prototype)
{
setResultType(MIRType_Object);
JS_ASSERT(source->getProto() == prototype);
setResultTypeSet(MakeSingletonTypeSet(source));
}
public:
INSTRUCTION_HEADER(RegExp)
static MRegExp *New(RegExpObject *source, JSObject *prototype) {
return new MRegExp(source, prototype);
}
RegExpObject *source() const {
return source_;
}
JSObject *getRegExpPrototype() const {
return prototype_;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MRegExpTest
: public MBinaryInstruction,
public MixPolicy<ObjectPolicy<1>, StringPolicy<0> >
{
private:
MRegExpTest(MDefinition *regexp, MDefinition *string)
: MBinaryInstruction(string, regexp)
{
setResultType(MIRType_Boolean);
}
public:
INSTRUCTION_HEADER(RegExpTest)
static MRegExpTest *New(MDefinition *regexp, MDefinition *string) {
return new MRegExpTest(regexp, string);
}
MDefinition *string() const {
return getOperand(0);
}
MDefinition *regexp() const {
return getOperand(1);
}
TypePolicy *typePolicy() {
return this;
}
};
class MLambda
: public MUnaryInstruction,
public SingleObjectPolicy
{
CompilerRootFunction fun_;
MLambda(MDefinition *scopeChain, JSFunction *fun)
: MUnaryInstruction(scopeChain), fun_(fun)
{
setResultType(MIRType_Object);
if (!fun->hasSingletonType() && !types::UseNewTypeForClone(fun))
setResultTypeSet(MakeSingletonTypeSet(fun));
}
public:
INSTRUCTION_HEADER(Lambda)
static MLambda *New(MDefinition *scopeChain, JSFunction *fun) {
return new MLambda(scopeChain, fun);
}
MDefinition *scopeChain() const {
return getOperand(0);
}
JSFunction *fun() const {
return fun_;
}
TypePolicy *typePolicy() {
return this;
}
};
class MParLambda
: public MBinaryInstruction,
public SingleObjectPolicy
{
CompilerRootFunction fun_;
MParLambda(MDefinition *parSlice,
MDefinition *scopeChain, JSFunction *fun)
: MBinaryInstruction(parSlice, scopeChain), fun_(fun)
{
JS_ASSERT(!fun->hasSingletonType());
JS_ASSERT(!types::UseNewTypeForClone(fun));
setResultType(MIRType_Object);
setResultTypeSet(MakeSingletonTypeSet(fun));
}
public:
INSTRUCTION_HEADER(ParLambda);
static MParLambda *New(MDefinition *parSlice,
MDefinition *scopeChain, JSFunction *fun) {
return new MParLambda(parSlice, scopeChain, fun);
}
static MParLambda *New(MDefinition *parSlice,
MLambda *originalInstruction) {
return New(parSlice,
originalInstruction->scopeChain(),
originalInstruction->fun());
}
MDefinition *parSlice() const {
return getOperand(0);
}
MDefinition *scopeChain() const {
return getOperand(1);
}
JSFunction *fun() const {
return fun_;
}
};
// Determines the implicit |this| value for function calls.
class MImplicitThis
: public MUnaryInstruction,
public SingleObjectPolicy
{
MImplicitThis(MDefinition *callee)
: MUnaryInstruction(callee)
{
setResultType(MIRType_Value);
setMovable();
}
public:
INSTRUCTION_HEADER(ImplicitThis)
static MImplicitThis *New(MDefinition *callee) {
return new MImplicitThis(callee);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *callee() const {
return getOperand(0);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// Returns obj->slots.
class MSlots
: public MUnaryInstruction,
public SingleObjectPolicy
{
MSlots(MDefinition *object)
: MUnaryInstruction(object)
{
setResultType(MIRType_Slots);
setMovable();
}
public:
INSTRUCTION_HEADER(Slots)
static MSlots *New(MDefinition *object) {
return new MSlots(object);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *object() const {
return getOperand(0);
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::ObjectFields);
}
};
// Returns obj->elements.
class MElements
: public MUnaryInstruction,
public SingleObjectPolicy
{
MElements(MDefinition *object)
: MUnaryInstruction(object)
{
setResultType(MIRType_Elements);
setMovable();
}
public:
INSTRUCTION_HEADER(Elements)
static MElements *New(MDefinition *object) {
return new MElements(object);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *object() const {
return getOperand(0);
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::ObjectFields);
}
};
// A constant value for some object's array elements or typed array elements.
class MConstantElements : public MNullaryInstruction
{
void *value_;
protected:
MConstantElements(void *v)
: value_(v)
{
setResultType(MIRType_Elements);
setMovable();
}
public:
INSTRUCTION_HEADER(ConstantElements)
static MConstantElements *New(void *v) {
return new MConstantElements(v);
}
void *value() const {
return value_;
}
void printOpcode(FILE *fp);
HashNumber valueHash() const {
return (HashNumber)(size_t) value_;
}
bool congruentTo(MDefinition * const &ins) const {
return ins->isConstantElements() && ins->toConstantElements()->value() == value();
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// Passes through an object's elements, after ensuring it is entirely doubles.
class MConvertElementsToDoubles
: public MUnaryInstruction
{
MConvertElementsToDoubles(MDefinition *elements)
: MUnaryInstruction(elements)
{
setGuard();
setMovable();
setResultType(MIRType_Elements);
}
public:
INSTRUCTION_HEADER(ConvertElementsToDoubles)
static MConvertElementsToDoubles *New(MDefinition *elements) {
return new MConvertElementsToDoubles(elements);
}
MDefinition *elements() const {
return getOperand(0);
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
// This instruction can read and write to the elements' contents.
// However, it is alright to hoist this from loops which explicitly
// read or write to the elements: such reads and writes will use double
// values and can be reordered freely wrt this conversion, except that
// definite double loads must follow the conversion. The latter
// property is ensured by chaining this instruction with the elements
// themselves, in the same manner as MBoundsCheck.
return AliasSet::None();
}
};
// Load a dense array's initialized length from an elements vector.
class MInitializedLength
: public MUnaryInstruction
{
MInitializedLength(MDefinition *elements)
: MUnaryInstruction(elements)
{
setResultType(MIRType_Int32);
setMovable();
}
public:
INSTRUCTION_HEADER(InitializedLength)
static MInitializedLength *New(MDefinition *elements) {
return new MInitializedLength(elements);
}
MDefinition *elements() const {
return getOperand(0);
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::ObjectFields);
}
};
// Set a dense array's initialized length to an elements vector.
class MSetInitializedLength
: public MAryInstruction<2>
{
MSetInitializedLength(MDefinition *elements, MDefinition *index)
{
setOperand(0, elements);
setOperand(1, index);
}
public:
INSTRUCTION_HEADER(SetInitializedLength)
static MSetInitializedLength *New(MDefinition *elements, MDefinition *index) {
return new MSetInitializedLength(elements, index);
}
MDefinition *elements() const {
return getOperand(0);
}
MDefinition *index() const {
return getOperand(1);
}
AliasSet getAliasSet() const {
return AliasSet::Store(AliasSet::ObjectFields);
}
};
// Load a dense array's initialized length from an elements vector.
class MArrayLength
: public MUnaryInstruction
{
public:
MArrayLength(MDefinition *elements)
: MUnaryInstruction(elements)
{
setResultType(MIRType_Int32);
setMovable();
}
INSTRUCTION_HEADER(ArrayLength)
MDefinition *elements() const {
return getOperand(0);
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::ObjectFields);
}
};
// Read the length of a typed array.
class MTypedArrayLength
: public MUnaryInstruction,
public SingleObjectPolicy
{
MTypedArrayLength(MDefinition *obj)
: MUnaryInstruction(obj)
{
setResultType(MIRType_Int32);
setMovable();
}
public:
INSTRUCTION_HEADER(TypedArrayLength)
static MTypedArrayLength *New(MDefinition *obj) {
return new MTypedArrayLength(obj);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *object() const {
return getOperand(0);
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::TypedArrayLength);
}
};
// Load a typed array's elements vector.
class MTypedArrayElements
: public MUnaryInstruction,
public SingleObjectPolicy
{
MTypedArrayElements(MDefinition *object)
: MUnaryInstruction(object)
{
setResultType(MIRType_Elements);
setMovable();
}
public:
INSTRUCTION_HEADER(TypedArrayElements)
static MTypedArrayElements *New(MDefinition *object) {
return new MTypedArrayElements(object);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *object() const {
return getOperand(0);
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::ObjectFields);
}
};
// Perform !-operation
class MNot
: public MUnaryInstruction,
public TestPolicy
{
bool operandMightEmulateUndefined_;
public:
MNot(MDefinition *input)
: MUnaryInstruction(input),
operandMightEmulateUndefined_(true)
{
setResultType(MIRType_Boolean);
setMovable();
}
static MNot *New(MDefinition *elements) {
return new MNot(elements);
}
static MNot *NewAsmJS(MDefinition *elements) {
MNot *ins = new MNot(elements);
ins->setResultType(MIRType_Int32);
return ins;
}
INSTRUCTION_HEADER(Not);
void infer(JSContext *cx);
MDefinition *foldsTo(bool useValueNumbers);
void markOperandCantEmulateUndefined() {
operandMightEmulateUndefined_ = false;
}
bool operandMightEmulateUndefined() const {
return operandMightEmulateUndefined_;
}
MDefinition *operand() const {
return getOperand(0);
}
virtual AliasSet getAliasSet() const {
return AliasSet::None();
}
TypePolicy *typePolicy() {
return this;
}
};
// Bailout if index + minimum < 0 or index + maximum >= length. The length used
// in a bounds check must not be negative, or the wrong result may be computed
// (unsigned comparisons may be used).
class MBoundsCheck
: public MBinaryInstruction
{
// Range over which to perform the bounds check, may be modified by GVN.
int32_t minimum_;
int32_t maximum_;
MBoundsCheck(MDefinition *index, MDefinition *length)
: MBinaryInstruction(index, length), minimum_(0), maximum_(0)
{
setGuard();
setMovable();
JS_ASSERT(index->type() == MIRType_Int32);
JS_ASSERT(length->type() == MIRType_Int32);
// Returns the checked index.
setResultType(MIRType_Int32);
}
public:
INSTRUCTION_HEADER(BoundsCheck)
static MBoundsCheck *New(MDefinition *index, MDefinition *length) {
return new MBoundsCheck(index, length);
}
MDefinition *index() const {
return getOperand(0);
}
MDefinition *length() const {
return getOperand(1);
}
int32_t minimum() const {
return minimum_;
}
void setMinimum(int32_t n) {
minimum_ = n;
}
int32_t maximum() const {
return maximum_;
}
void setMaximum(int32_t n) {
maximum_ = n;
}
bool congruentTo(MDefinition * const &ins) const {
if (!ins->isBoundsCheck())
return false;
MBoundsCheck *other = ins->toBoundsCheck();
if (minimum() != other->minimum() || maximum() != other->maximum())
return false;
return congruentIfOperandsEqual(other);
}
virtual AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// Bailout if index < minimum.
class MBoundsCheckLower
: public MUnaryInstruction
{
int32_t minimum_;
MBoundsCheckLower(MDefinition *index)
: MUnaryInstruction(index), minimum_(0)
{
setGuard();
setMovable();
JS_ASSERT(index->type() == MIRType_Int32);
}
public:
INSTRUCTION_HEADER(BoundsCheckLower)
static MBoundsCheckLower *New(MDefinition *index) {
return new MBoundsCheckLower(index);
}
MDefinition *index() const {
return getOperand(0);
}
int32_t minimum() const {
return minimum_;
}
void setMinimum(int32_t n) {
minimum_ = n;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
bool fallible();
};
// Load a value from a dense array's element vector and does a hole check if the
// array is not known to be packed.
class MLoadElement
: public MBinaryInstruction,
public SingleObjectPolicy
{
bool needsHoleCheck_;
bool loadDoubles_;
MLoadElement(MDefinition *elements, MDefinition *index, bool needsHoleCheck, bool loadDoubles)
: MBinaryInstruction(elements, index),
needsHoleCheck_(needsHoleCheck),
loadDoubles_(loadDoubles)
{
setResultType(MIRType_Value);
setMovable();
JS_ASSERT(elements->type() == MIRType_Elements);
JS_ASSERT(index->type() == MIRType_Int32);
}
public:
INSTRUCTION_HEADER(LoadElement)
static MLoadElement *New(MDefinition *elements, MDefinition *index,
bool needsHoleCheck, bool loadDoubles) {
return new MLoadElement(elements, index, needsHoleCheck, loadDoubles);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *elements() const {
return getOperand(0);
}
MDefinition *index() const {
return getOperand(1);
}
bool needsHoleCheck() const {
return needsHoleCheck_;
}
bool loadDoubles() const {
return loadDoubles_;
}
bool fallible() const {
return needsHoleCheck();
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::Element);
}
};
// Load a value from a dense array's element vector. If the index is
// out-of-bounds, or the indexed slot has a hole, undefined is returned
// instead.
class MLoadElementHole
: public MTernaryInstruction,
public SingleObjectPolicy
{
bool needsHoleCheck_;
MLoadElementHole(MDefinition *elements, MDefinition *index, MDefinition *initLength, bool needsHoleCheck)
: MTernaryInstruction(elements, index, initLength),
needsHoleCheck_(needsHoleCheck)
{
setResultType(MIRType_Value);
setMovable();
JS_ASSERT(elements->type() == MIRType_Elements);
JS_ASSERT(index->type() == MIRType_Int32);
JS_ASSERT(initLength->type() == MIRType_Int32);
}
public:
INSTRUCTION_HEADER(LoadElementHole)
static MLoadElementHole *New(MDefinition *elements, MDefinition *index,
MDefinition *initLength, bool needsHoleCheck) {
return new MLoadElementHole(elements, index, initLength, needsHoleCheck);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *elements() const {
return getOperand(0);
}
MDefinition *index() const {
return getOperand(1);
}
MDefinition *initLength() const {
return getOperand(2);
}
bool needsNegativeIntCheck() const;
bool needsHoleCheck() const {
return needsHoleCheck_;
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::Element);
}
void collectRangeInfo();
};
class MStoreElementCommon
{
bool needsBarrier_;
MIRType elementType_;
bool racy_; // if true, exempted from normal data race req. during par. exec.
protected:
MStoreElementCommon()
: needsBarrier_(false),
elementType_(MIRType_Value),
racy_(false)
{ }
public:
MIRType elementType() const {
return elementType_;
}
void setElementType(MIRType elementType) {
JS_ASSERT(elementType != MIRType_None);
elementType_ = elementType;
}
bool needsBarrier() const {
return needsBarrier_;
}
void setNeedsBarrier() {
needsBarrier_ = true;
}
bool racy() const {
return racy_;
}
void setRacy() {
racy_ = true;
}
};
// Store a value to a dense array slots vector.
class MStoreElement
: public MAryInstruction<3>,
public MStoreElementCommon,
public SingleObjectPolicy
{
bool needsHoleCheck_;
MStoreElement(MDefinition *elements, MDefinition *index, MDefinition *value, bool needsHoleCheck) {
setOperand(0, elements);
setOperand(1, index);
setOperand(2, value);
needsHoleCheck_ = needsHoleCheck;
JS_ASSERT(elements->type() == MIRType_Elements);
JS_ASSERT(index->type() == MIRType_Int32);
}
public:
INSTRUCTION_HEADER(StoreElement)
static MStoreElement *New(MDefinition *elements, MDefinition *index, MDefinition *value,
bool needsHoleCheck) {
return new MStoreElement(elements, index, value, needsHoleCheck);
}
MDefinition *elements() const {
return getOperand(0);
}
MDefinition *index() const {
return getOperand(1);
}
MDefinition *value() const {
return getOperand(2);
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
return AliasSet::Store(AliasSet::Element);
}
bool needsHoleCheck() const {
return needsHoleCheck_;
}
bool fallible() const {
return needsHoleCheck();
}
};
// Like MStoreElement, but supports indexes >= initialized length. The downside
// is that we cannot hoist the elements vector and bounds check, since this
// instruction may update the (initialized) length and reallocate the elements
// vector.
class MStoreElementHole
: public MAryInstruction<4>,
public MStoreElementCommon,
public SingleObjectPolicy
{
MStoreElementHole(MDefinition *object, MDefinition *elements,
MDefinition *index, MDefinition *value) {
setOperand(0, object);
setOperand(1, elements);
setOperand(2, index);
setOperand(3, value);
JS_ASSERT(elements->type() == MIRType_Elements);
JS_ASSERT(index->type() == MIRType_Int32);
}
public:
INSTRUCTION_HEADER(StoreElementHole)
static MStoreElementHole *New(MDefinition *object, MDefinition *elements,
MDefinition *index, MDefinition *value) {
return new MStoreElementHole(object, elements, index, value);
}
MDefinition *object() const {
return getOperand(0);
}
MDefinition *elements() const {
return getOperand(1);
}
MDefinition *index() const {
return getOperand(2);
}
MDefinition *value() const {
return getOperand(3);
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
// StoreElementHole can update the initialized length, the array length
// or reallocate obj->elements.
return AliasSet::Store(AliasSet::Element | AliasSet::ObjectFields);
}
};
// Array.prototype.pop or Array.prototype.shift on a dense array.
class MArrayPopShift
: public MUnaryInstruction,
public SingleObjectPolicy
{
public:
enum Mode {
Pop,
Shift
};
private:
Mode mode_;
bool needsHoleCheck_;
bool maybeUndefined_;
MArrayPopShift(MDefinition *object, Mode mode, bool needsHoleCheck, bool maybeUndefined)
: MUnaryInstruction(object), mode_(mode), needsHoleCheck_(needsHoleCheck),
maybeUndefined_(maybeUndefined)
{ }
public:
INSTRUCTION_HEADER(ArrayPopShift)
static MArrayPopShift *New(MDefinition *object, Mode mode, bool needsHoleCheck,
bool maybeUndefined) {
return new MArrayPopShift(object, mode, needsHoleCheck, maybeUndefined);
}
MDefinition *object() const {
return getOperand(0);
}
bool needsHoleCheck() const {
return needsHoleCheck_;
}
bool maybeUndefined() const {
return maybeUndefined_;
}
bool mode() const {
return mode_;
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
return AliasSet::Store(AliasSet::Element | AliasSet::ObjectFields);
}
};
// Array.prototype.push on a dense array. Returns the new array length.
class MArrayPush
: public MBinaryInstruction,
public SingleObjectPolicy
{
MArrayPush(MDefinition *object, MDefinition *value)
: MBinaryInstruction(object, value)
{
setResultType(MIRType_Int32);
}
public:
INSTRUCTION_HEADER(ArrayPush)
static MArrayPush *New(MDefinition *object, MDefinition *value) {
return new MArrayPush(object, value);
}
MDefinition *object() const {
return getOperand(0);
}
MDefinition *value() const {
return getOperand(1);
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
return AliasSet::Store(AliasSet::Element | AliasSet::ObjectFields);
}
};
// Array.prototype.concat on two dense arrays.
class MArrayConcat
: public MBinaryInstruction,
public MixPolicy<ObjectPolicy<0>, ObjectPolicy<1> >
{
CompilerRootObject templateObj_;
MArrayConcat(MDefinition *lhs, MDefinition *rhs, HandleObject templateObj)
: MBinaryInstruction(lhs, rhs),
templateObj_(templateObj)
{
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(ArrayConcat)
static MArrayConcat *New(MDefinition *lhs, MDefinition *rhs, HandleObject templateObj) {
return new MArrayConcat(lhs, rhs, templateObj);
}
JSObject *templateObj() const {
return templateObj_;
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
return AliasSet::Store(AliasSet::Element | AliasSet::ObjectFields);
}
};
class MLoadTypedArrayElement
: public MBinaryInstruction
{
int arrayType_;
MLoadTypedArrayElement(MDefinition *elements, MDefinition *index, int arrayType)
: MBinaryInstruction(elements, index), arrayType_(arrayType)
{
setResultType(MIRType_Value);
setMovable();
JS_ASSERT(elements->type() == MIRType_Elements);
JS_ASSERT(index->type() == MIRType_Int32);
JS_ASSERT(arrayType >= 0 && arrayType < TypedArray::TYPE_MAX);
}
public:
INSTRUCTION_HEADER(LoadTypedArrayElement)
static MLoadTypedArrayElement *New(MDefinition *elements, MDefinition *index, int arrayType) {
return new MLoadTypedArrayElement(elements, index, arrayType);
}
int arrayType() const {
return arrayType_;
}
bool fallible() const {
// Bailout if the result does not fit in an int32.
return arrayType_ == TypedArray::TYPE_UINT32 && type() == MIRType_Int32;
}
MDefinition *elements() const {
return getOperand(0);
}
MDefinition *index() const {
return getOperand(1);
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::TypedArrayElement);
}
};
// Load a value from a typed array. Out-of-bounds accesses are handled using
// a VM call.
class MLoadTypedArrayElementHole
: public MBinaryInstruction,
public SingleObjectPolicy
{
int arrayType_;
bool allowDouble_;
MLoadTypedArrayElementHole(MDefinition *object, MDefinition *index, int arrayType, bool allowDouble)
: MBinaryInstruction(object, index), arrayType_(arrayType), allowDouble_(allowDouble)
{
setResultType(MIRType_Value);
setMovable();
JS_ASSERT(index->type() == MIRType_Int32);
JS_ASSERT(arrayType >= 0 && arrayType < TypedArray::TYPE_MAX);
}
public:
INSTRUCTION_HEADER(LoadTypedArrayElementHole)
static MLoadTypedArrayElementHole *New(MDefinition *object, MDefinition *index, int arrayType, bool allowDouble) {
return new MLoadTypedArrayElementHole(object, index, arrayType, allowDouble);
}
int arrayType() const {
return arrayType_;
}
bool allowDouble() const {
return allowDouble_;
}
bool fallible() const {
return arrayType_ == TypedArray::TYPE_UINT32 && !allowDouble_;
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *object() const {
return getOperand(0);
}
MDefinition *index() const {
return getOperand(1);
}
AliasSet getAliasSet() const {
// Out-of-bounds accesses are handled using a VM call, this may
// invoke getters on the prototype chain.
return AliasSet::Store(AliasSet::Any);
}
};
// Load a value fallibly or infallibly from a statically known typed array.
class MLoadTypedArrayElementStatic : public MUnaryInstruction
{
MLoadTypedArrayElementStatic(JSObject *typedArray, MDefinition *ptr)
: MUnaryInstruction(ptr), typedArray_(typedArray), fallible_(true)
{
int type = TypedArray::type(typedArray_);
if (type == TypedArray::TYPE_FLOAT32 || type == TypedArray::TYPE_FLOAT64)
setResultType(MIRType_Double);
else
setResultType(MIRType_Int32);
}
CompilerRootObject typedArray_;
bool fallible_;
public:
INSTRUCTION_HEADER(LoadTypedArrayElementStatic);
static MLoadTypedArrayElementStatic *New(JSObject *typedArray, MDefinition *ptr) {
return new MLoadTypedArrayElementStatic(typedArray, ptr);
}
ArrayBufferView::ViewType viewType() const { return JS_GetArrayBufferViewType(typedArray_); }
void *base() const;
size_t length() const;
MDefinition *ptr() const { return getOperand(0); }
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::TypedArrayElement);
}
bool fallible() const {
return fallible_;
}
void setInfallible() {
fallible_ = false;
}
void computeRange();
bool truncate();
};
class MStoreTypedArrayElement
: public MTernaryInstruction,
public StoreTypedArrayPolicy
{
int arrayType_;
// See note in MStoreElementCommon.
bool racy_;
MStoreTypedArrayElement(MDefinition *elements, MDefinition *index, MDefinition *value,
int arrayType)
: MTernaryInstruction(elements, index, value), arrayType_(arrayType), racy_(false)
{
setMovable();
JS_ASSERT(elements->type() == MIRType_Elements);
JS_ASSERT(index->type() == MIRType_Int32);
JS_ASSERT(arrayType >= 0 && arrayType < TypedArray::TYPE_MAX);
}
public:
INSTRUCTION_HEADER(StoreTypedArrayElement)
static MStoreTypedArrayElement *New(MDefinition *elements, MDefinition *index, MDefinition *value,
int arrayType) {
return new MStoreTypedArrayElement(elements, index, value, arrayType);
}
int arrayType() const {
return arrayType_;
}
bool isByteArray() const {
return (arrayType_ == TypedArray::TYPE_INT8 ||
arrayType_ == TypedArray::TYPE_UINT8 ||
arrayType_ == TypedArray::TYPE_UINT8_CLAMPED);
}
bool isFloatArray() const {
return (arrayType_ == TypedArray::TYPE_FLOAT32 ||
arrayType_ == TypedArray::TYPE_FLOAT64);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *elements() const {
return getOperand(0);
}
MDefinition *index() const {
return getOperand(1);
}
MDefinition *value() const {
return getOperand(2);
}
AliasSet getAliasSet() const {
return AliasSet::Store(AliasSet::TypedArrayElement);
}
bool racy() const {
return racy_;
}
void setRacy() {
racy_ = true;
}
};
class MStoreTypedArrayElementHole
: public MAryInstruction<4>,
public StoreTypedArrayHolePolicy
{
int arrayType_;
MStoreTypedArrayElementHole(MDefinition *elements, MDefinition *length, MDefinition *index,
MDefinition *value, int arrayType)
: MAryInstruction<4>(), arrayType_(arrayType)
{
setOperand(0, elements);
setOperand(1, length);
setOperand(2, index);
setOperand(3, value);
setMovable();
JS_ASSERT(elements->type() == MIRType_Elements);
JS_ASSERT(length->type() == MIRType_Int32);
JS_ASSERT(index->type() == MIRType_Int32);
JS_ASSERT(arrayType >= 0 && arrayType < TypedArray::TYPE_MAX);
}
public:
INSTRUCTION_HEADER(StoreTypedArrayElementHole)
static MStoreTypedArrayElementHole *New(MDefinition *elements, MDefinition *length,
MDefinition *index, MDefinition *value, int arrayType)
{
return new MStoreTypedArrayElementHole(elements, length, index, value, arrayType);
}
int arrayType() const {
return arrayType_;
}
bool isByteArray() const {
return (arrayType_ == TypedArray::TYPE_INT8 ||
arrayType_ == TypedArray::TYPE_UINT8 ||
arrayType_ == TypedArray::TYPE_UINT8_CLAMPED);
}
bool isFloatArray() const {
return (arrayType_ == TypedArray::TYPE_FLOAT32 ||
arrayType_ == TypedArray::TYPE_FLOAT64);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *elements() const {
return getOperand(0);
}
MDefinition *length() const {
return getOperand(1);
}
MDefinition *index() const {
return getOperand(2);
}
MDefinition *value() const {
return getOperand(3);
}
AliasSet getAliasSet() const {
return AliasSet::Store(AliasSet::TypedArrayElement);
}
};
// Store a value infallibly to a statically known typed array.
class MStoreTypedArrayElementStatic :
public MBinaryInstruction
, public StoreTypedArrayElementStaticPolicy
{
MStoreTypedArrayElementStatic(JSObject *typedArray, MDefinition *ptr, MDefinition *v)
: MBinaryInstruction(ptr, v), typedArray_(typedArray)
{}
CompilerRootObject typedArray_;
public:
INSTRUCTION_HEADER(StoreTypedArrayElementStatic);
static MStoreTypedArrayElementStatic *New(JSObject *typedArray, MDefinition *ptr, MDefinition *v) {
return new MStoreTypedArrayElementStatic(typedArray, ptr, v);
}
TypePolicy *typePolicy() {
return this;
}
ArrayBufferView::ViewType viewType() const { return JS_GetArrayBufferViewType(typedArray_); }
void *base() const;
size_t length() const;
MDefinition *ptr() const { return getOperand(0); }
MDefinition *value() const { return getOperand(1); }
AliasSet getAliasSet() const {
return AliasSet::Store(AliasSet::TypedArrayElement);
}
};
// Compute an "effective address", i.e., a compound computation of the form:
// base + index * scale + displacement
class MEffectiveAddress : public MBinaryInstruction
{
MEffectiveAddress(MDefinition *base, MDefinition *index, Scale scale, int32_t displacement)
: MBinaryInstruction(base, index), scale_(scale), displacement_(displacement)
{
JS_ASSERT(base->type() == MIRType_Int32);
JS_ASSERT(index->type() == MIRType_Int32);
setMovable();
setResultType(MIRType_Int32);
}
Scale scale_;
int32_t displacement_;
public:
INSTRUCTION_HEADER(EffectiveAddress);
static MEffectiveAddress *New(MDefinition *base, MDefinition *index, Scale s, int32_t d) {
return new MEffectiveAddress(base, index, s, d);
}
MDefinition *base() const {
return lhs();
}
MDefinition *index() const {
return rhs();
}
Scale scale() const {
return scale_;
}
int32_t displacement() const {
return displacement_;
}
};
// Clamp input to range [0, 255] for Uint8ClampedArray.
class MClampToUint8
: public MUnaryInstruction,
public ClampPolicy
{
MClampToUint8(MDefinition *input)
: MUnaryInstruction(input)
{
setResultType(MIRType_Int32);
setMovable();
}
public:
INSTRUCTION_HEADER(ClampToUint8)
static MClampToUint8 *New(MDefinition *input) {
return new MClampToUint8(input);
}
MDefinition *foldsTo(bool useValueNumbers);
MDefinition *input() const {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
void computeRange();
};
class MLoadFixedSlot
: public MUnaryInstruction,
public SingleObjectPolicy
{
size_t slot_;
protected:
MLoadFixedSlot(MDefinition *obj, size_t slot)
: MUnaryInstruction(obj), slot_(slot)
{
setResultType(MIRType_Value);
setMovable();
}
public:
INSTRUCTION_HEADER(LoadFixedSlot)
static MLoadFixedSlot *New(MDefinition *obj, size_t slot) {
return new MLoadFixedSlot(obj, slot);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *object() const {
return getOperand(0);
}
size_t slot() const {
return slot_;
}
bool congruentTo(MDefinition * const &ins) const {
if (!ins->isLoadFixedSlot())
return false;
if (slot() != ins->toLoadFixedSlot()->slot())
return false;
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::FixedSlot);
}
bool mightAlias(MDefinition *store);
};
class MStoreFixedSlot
: public MBinaryInstruction,
public SingleObjectPolicy
{
bool needsBarrier_;
size_t slot_;
MStoreFixedSlot(MDefinition *obj, MDefinition *rval, size_t slot, bool barrier)
: MBinaryInstruction(obj, rval),
needsBarrier_(barrier),
slot_(slot)
{ }
public:
INSTRUCTION_HEADER(StoreFixedSlot)
static MStoreFixedSlot *New(MDefinition *obj, size_t slot, MDefinition *rval) {
return new MStoreFixedSlot(obj, rval, slot, false);
}
static MStoreFixedSlot *NewBarriered(MDefinition *obj, size_t slot, MDefinition *rval) {
return new MStoreFixedSlot(obj, rval, slot, true);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *object() const {
return getOperand(0);
}
MDefinition *value() const {
return getOperand(1);
}
size_t slot() const {
return slot_;
}
AliasSet getAliasSet() const {
return AliasSet::Store(AliasSet::FixedSlot);
}
bool needsBarrier() const {
return needsBarrier_;
}
void setNeedsBarrier() {
needsBarrier_ = true;
}
};
class InlinePropertyTable : public TempObject
{
struct Entry : public TempObject {
CompilerRoot<types::TypeObject *> typeObj;
CompilerRootFunction func;
Entry(types::TypeObject *typeObj, JSFunction *func)
: typeObj(typeObj), func(func)
{ }
};
jsbytecode *pc_;
MResumePoint *priorResumePoint_;
Vector<Entry *, 4, IonAllocPolicy> entries_;
public:
InlinePropertyTable(jsbytecode *pc)
: pc_(pc), priorResumePoint_(NULL), entries_()
{ }
void setPriorResumePoint(MResumePoint *resumePoint) {
JS_ASSERT(priorResumePoint_ == NULL);
priorResumePoint_ = resumePoint;
}
MResumePoint *priorResumePoint() const {
return priorResumePoint_;
}
jsbytecode *pc() const {
return pc_;
}
bool addEntry(types::TypeObject *typeObj, JSFunction *func) {
return entries_.append(new Entry(typeObj, func));
}
size_t numEntries() const {
return entries_.length();
}
types::TypeObject *getTypeObject(size_t i) const {
JS_ASSERT(i < numEntries());
return entries_[i]->typeObj;
}
JSFunction *getFunction(size_t i) const {
JS_ASSERT(i < numEntries());
return entries_[i]->func;
}
bool hasFunction(JSFunction *func) const;
types::StackTypeSet *buildTypeSetForFunction(JSFunction *func) const;
// Remove targets that vetoed inlining from the InlinePropertyTable.
void trimTo(AutoObjectVector &targets, Vector<bool> &choiceSet);
// Ensure that the InlinePropertyTable's domain is a subset of |targets|.
void trimToAndMaybePatchTargets(AutoObjectVector &targets, AutoObjectVector &originals);
};
class MGetPropertyCache
: public MUnaryInstruction,
public SingleObjectPolicy
{
CompilerRootPropertyName name_;
bool idempotent_;
bool allowGetters_;
InlinePropertyTable *inlinePropertyTable_;
MGetPropertyCache(MDefinition *obj, HandlePropertyName name)
: MUnaryInstruction(obj),
name_(name),
idempotent_(false),
allowGetters_(false),
inlinePropertyTable_(NULL)
{
setResultType(MIRType_Value);
// The cache will invalidate if there are objects with e.g. lookup or
// resolve hooks on the proto chain. setGuard ensures this check is not
// eliminated.
setGuard();
}
public:
INSTRUCTION_HEADER(GetPropertyCache)
static MGetPropertyCache *New(MDefinition *obj, HandlePropertyName name) {
return new MGetPropertyCache(obj, name);
}
InlinePropertyTable *initInlinePropertyTable(jsbytecode *pc) {
JS_ASSERT(inlinePropertyTable_ == NULL);
inlinePropertyTable_ = new InlinePropertyTable(pc);
return inlinePropertyTable_;
}
void clearInlinePropertyTable() {
inlinePropertyTable_ = NULL;
}
InlinePropertyTable *propTable() const {
return inlinePropertyTable_;
}
MDefinition *object() const {
return getOperand(0);
}
PropertyName *name() const {
return name_;
}
bool idempotent() const {
return idempotent_;
}
void setIdempotent() {
idempotent_ = true;
setMovable();
}
bool allowGetters() const {
return allowGetters_;
}
void setAllowGetters() {
allowGetters_ = true;
}
TypePolicy *typePolicy() { return this; }
bool congruentTo(MDefinition * const &ins) const {
if (!idempotent_)
return false;
if (!ins->isGetPropertyCache())
return false;
if (name() != ins->toGetPropertyCache()->name())
return false;
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
if (idempotent_) {
return AliasSet::Load(AliasSet::ObjectFields |
AliasSet::FixedSlot |
AliasSet::DynamicSlot);
}
return AliasSet::Store(AliasSet::Any);
}
};
// Emit code to load a value from an object's slots if its shape matches
// one of the shapes observed by the baseline IC, else bails out.
class MGetPropertyPolymorphic
: public MUnaryInstruction,
public SingleObjectPolicy
{
struct Entry {
// The shape to guard against.
Shape *objShape;
// The property to laod.
Shape *shape;
};
Vector<Entry, 4, IonAllocPolicy> shapes_;
CompilerRootPropertyName name_;
MGetPropertyPolymorphic(MDefinition *obj, HandlePropertyName name)
: MUnaryInstruction(obj),
name_(name)
{
setMovable();
setResultType(MIRType_Value);
}
PropertyName *name() const {
return name_;
}
public:
INSTRUCTION_HEADER(GetPropertyPolymorphic)
static MGetPropertyPolymorphic *New(MDefinition *obj, HandlePropertyName name) {
return new MGetPropertyPolymorphic(obj, name);
}
bool congruentTo(MDefinition *const &ins) const {
if (!ins->isGetPropertyPolymorphic())
return false;
if (name() != ins->toGetPropertyPolymorphic()->name())
return false;
return congruentIfOperandsEqual(ins);
}
TypePolicy *typePolicy() {
return this;
}
bool addShape(Shape *objShape, Shape *shape) {
Entry entry;
entry.objShape = objShape;
entry.shape = shape;
return shapes_.append(entry);
}
size_t numShapes() const {
return shapes_.length();
}
Shape *objShape(size_t i) const {
return shapes_[i].objShape;
}
Shape *shape(size_t i) const {
return shapes_[i].shape;
}
MDefinition *obj() const {
return getOperand(0);
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::ObjectFields | AliasSet::FixedSlot | AliasSet::DynamicSlot);
}
bool mightAlias(MDefinition *store);
};
// Emit code to store a value to an object's slots if its shape matches
// one of the shapes observed by the baseline IC, else bails out.
class MSetPropertyPolymorphic
: public MBinaryInstruction,
public SingleObjectPolicy
{
struct Entry {
// The shape to guard against.
Shape *objShape;
// The property to laod.
Shape *shape;
};
Vector<Entry, 4, IonAllocPolicy> shapes_;
bool needsBarrier_;
MSetPropertyPolymorphic(MDefinition *obj, MDefinition *value)
: MBinaryInstruction(obj, value),
needsBarrier_(false)
{
}
public:
INSTRUCTION_HEADER(SetPropertyPolymorphic)
static MSetPropertyPolymorphic *New(MDefinition *obj, MDefinition *value) {
return new MSetPropertyPolymorphic(obj, value);
}
TypePolicy *typePolicy() {
return this;
}
bool addShape(Shape *objShape, Shape *shape) {
Entry entry;
entry.objShape = objShape;
entry.shape = shape;
return shapes_.append(entry);
}
size_t numShapes() const {
return shapes_.length();
}
Shape *objShape(size_t i) const {
return shapes_[i].objShape;
}
Shape *shape(size_t i) const {
return shapes_[i].shape;
}
MDefinition *obj() const {
return getOperand(0);
}
MDefinition *value() const {
return getOperand(1);
}
bool needsBarrier() const {
return needsBarrier_;
}
void setNeedsBarrier() {
needsBarrier_ = true;
}
AliasSet getAliasSet() const {
return AliasSet::Store(AliasSet::ObjectFields | AliasSet::FixedSlot | AliasSet::DynamicSlot);
}
};
class MDispatchInstruction
: public MControlInstruction,
public SingleObjectPolicy
{
// Map from JSFunction* -> MBasicBlock.
struct Entry {
JSFunction *func;
MBasicBlock *block;
Entry(JSFunction *func, MBasicBlock *block)
: func(func), block(block)
{ }
};
Vector<Entry, 4, IonAllocPolicy> map_;
// An optional fallback path that uses MCall.
MBasicBlock *fallback_;
MUse operand_;
public:
MDispatchInstruction(MDefinition *input)
: map_(), fallback_(NULL)
{
setOperand(0, input);
}
protected:
void setOperand(size_t index, MDefinition *operand) {
JS_ASSERT(index == 0);
operand_.set(operand, this, 0);
operand->addUse(&operand_);
}
MUse *getUseFor(size_t index) {
JS_ASSERT(index == 0);
return &operand_;
}
MDefinition *getOperand(size_t index) const {
JS_ASSERT(index == 0);
return operand_.producer();
}
size_t numOperands() const {
return 1;
}
public:
void setSuccessor(size_t i, MBasicBlock *successor) {
JS_ASSERT(i < numSuccessors());
if (i == map_.length())
fallback_ = successor;
else
map_[i].block = successor;
}
size_t numSuccessors() const {
return map_.length() + (fallback_ ? 1 : 0);
}
void replaceSuccessor(size_t i, MBasicBlock *successor) {
setSuccessor(i, successor);
}
MBasicBlock *getSuccessor(size_t i) const {
JS_ASSERT(i < numSuccessors());
if (i == map_.length())
return fallback_;
return map_[i].block;
}
public:
void addCase(JSFunction *func, MBasicBlock *block) {
map_.append(Entry(func, block));
}
uint32_t numCases() const {
return map_.length();
}
JSFunction *getCase(uint32_t i) const {
return map_[i].func;
}
MBasicBlock *getCaseBlock(uint32_t i) const {
return map_[i].block;
}
bool hasFallback() const {
return bool(fallback_);
}
void addFallback(MBasicBlock *block) {
JS_ASSERT(!hasFallback());
fallback_ = block;
}
MBasicBlock *getFallback() const {
JS_ASSERT(hasFallback());
return fallback_;
}
public:
MDefinition *input() const {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
};
// Polymorphic dispatch for inlining, keyed off incoming TypeObject.
class MTypeObjectDispatch : public MDispatchInstruction
{
// Map TypeObject (of CallProp's Target Object) -> JSFunction (yielded by the CallProp).
InlinePropertyTable *inlinePropertyTable_;
MTypeObjectDispatch(MDefinition *input, InlinePropertyTable *table)
: MDispatchInstruction(input),
inlinePropertyTable_(table)
{ }
public:
INSTRUCTION_HEADER(TypeObjectDispatch)
static MTypeObjectDispatch *New(MDefinition *ins, InlinePropertyTable *table) {
return new MTypeObjectDispatch(ins, table);
}
InlinePropertyTable *propTable() const {
return inlinePropertyTable_;
}
};
// Polymorphic dispatch for inlining, keyed off incoming JSFunction*.
class MFunctionDispatch : public MDispatchInstruction
{
MFunctionDispatch(MDefinition *input)
: MDispatchInstruction(input)
{ }
public:
INSTRUCTION_HEADER(FunctionDispatch)
static MFunctionDispatch *New(MDefinition *ins) {
return new MFunctionDispatch(ins);
}
};
// Represents a polymorphic dispatch to one or more functions.
class MPolyInlineDispatch : public MControlInstruction, public SingleObjectPolicy
{
// A table to map JSFunctions to the blocks that execute them.
struct Entry {
MConstant *funcConst;
MBasicBlock *block;
Entry(MConstant *funcConst, MBasicBlock *block)
: funcConst(funcConst), block(block) {}
};
Vector<Entry, 4, IonAllocPolicy> dispatchTable_;
MUse operand_;
InlinePropertyTable *inlinePropertyTable_;
MBasicBlock *fallbackPrepBlock_;
MBasicBlock *fallbackMidBlock_;
MBasicBlock *fallbackEndBlock_;
MPolyInlineDispatch(MDefinition *ins)
: dispatchTable_(),
inlinePropertyTable_(NULL),
fallbackPrepBlock_(NULL),
fallbackMidBlock_(NULL),
fallbackEndBlock_(NULL)
{
setOperand(0, ins);
}
MPolyInlineDispatch(MDefinition *ins, InlinePropertyTable *inlinePropertyTable,
MBasicBlock *fallbackPrepBlock,
MBasicBlock *fallbackMidBlock,
MBasicBlock *fallbackEndBlock)
: dispatchTable_(),
inlinePropertyTable_(inlinePropertyTable),
fallbackPrepBlock_(fallbackPrepBlock),
fallbackMidBlock_(fallbackMidBlock),
fallbackEndBlock_(fallbackEndBlock)
{
setOperand(0, ins);
}
protected:
virtual void setOperand(size_t index, MDefinition *operand) {
JS_ASSERT(index == 0);
operand_.set(operand, this, index);
operand->addUse(&operand_);
}
MUse *getUseFor(size_t index) {
JS_ASSERT(index == 0);
return &operand_;
}
void setSuccessor(size_t i, MBasicBlock *successor) {
JS_ASSERT(i < numSuccessors());
if (inlinePropertyTable_ && (i == numSuccessors() - 1))
fallbackPrepBlock_ = successor;
else
dispatchTable_[i].block = successor;
}
public:
INSTRUCTION_HEADER(PolyInlineDispatch)
virtual MDefinition *getOperand(size_t index) const {
JS_ASSERT(index == 0);
return operand_.producer();
}
virtual size_t numOperands() const {
return 1;
}
virtual size_t numSuccessors() const {
return dispatchTable_.length() + (inlinePropertyTable_ ? 1 : 0);
}
virtual void replaceSuccessor(size_t i, MBasicBlock *successor) {
setSuccessor(i, successor);
}
MBasicBlock *getSuccessor(size_t i) const {
JS_ASSERT(i < numSuccessors());
if (inlinePropertyTable_ && (i == numSuccessors() - 1))
return fallbackPrepBlock_;
else
return dispatchTable_[i].block;
}
static MPolyInlineDispatch *New(MDefinition *ins) {
return new MPolyInlineDispatch(ins);
}
static MPolyInlineDispatch *New(MDefinition *ins, InlinePropertyTable *inlinePropTable,
MBasicBlock *fallbackPrepBlock,
MBasicBlock *fallbackMidBlock,
MBasicBlock *fallbackEndBlock)
{
return new MPolyInlineDispatch(ins, inlinePropTable,
fallbackPrepBlock,
fallbackMidBlock,
fallbackEndBlock);
}
size_t numCallees() const {
return dispatchTable_.length();
}
void addCallee(MConstant *funcConst, MBasicBlock *block) {
dispatchTable_.append(Entry(funcConst, block));
}
MConstant *getFunctionConstant(size_t i) const {
JS_ASSERT(i < numCallees());
return dispatchTable_[i].funcConst;
}
JSFunction *getFunction(size_t i) const {
return &getFunctionConstant(i)->value().toObject().as<JSFunction>();
}
MBasicBlock *getFunctionBlock(size_t i) const {
JS_ASSERT(i < numCallees());
return dispatchTable_[i].block;
}
MBasicBlock *getFunctionBlock(JSFunction *func) const {
for (size_t i = 0; i < numCallees(); i++) {
if (getFunction(i) == func)
return getFunctionBlock(i);
}
JS_NOT_REACHED("Bad function lookup!");
}
InlinePropertyTable *propTable() const {
return inlinePropertyTable_;
}
MBasicBlock *fallbackPrepBlock() const {
JS_ASSERT(inlinePropertyTable_ != NULL);
return fallbackPrepBlock_;
}
MBasicBlock *fallbackMidBlock() const {
JS_ASSERT(inlinePropertyTable_ != NULL);
return fallbackMidBlock_;
}
MBasicBlock *fallbackEndBlock() const {
JS_ASSERT(inlinePropertyTable_ != NULL);
return fallbackEndBlock_;
}
MDefinition *input() const {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
};
class MGetElementCache
: public MBinaryInstruction
{
MixPolicy<ObjectPolicy<0>, BoxPolicy<1> > PolicyV;
MixPolicy<ObjectPolicy<0>, IntPolicy<1> > PolicyT;
// See the comment in IonBuilder::jsop_getelem.
bool monitoredResult_;
MGetElementCache(MDefinition *obj, MDefinition *value, bool monitoredResult)
: MBinaryInstruction(obj, value), monitoredResult_(monitoredResult)
{
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(GetElementCache)
static MGetElementCache *New(MDefinition *obj, MDefinition *value, bool monitoredResult) {
return new MGetElementCache(obj, value, monitoredResult);
}
MDefinition *object() const {
return getOperand(0);
}
MDefinition *index() const {
return getOperand(1);
}
bool monitoredResult() const {
return monitoredResult_;
}
TypePolicy *typePolicy() {
if (type() == MIRType_Value)
return &PolicyV;
return &PolicyT;
}
};
class MBindNameCache
: public MUnaryInstruction,
public SingleObjectPolicy
{
CompilerRootPropertyName name_;
CompilerRootScript script_;
jsbytecode *pc_;
MBindNameCache(MDefinition *scopeChain, PropertyName *name, JSScript *script, jsbytecode *pc)
: MUnaryInstruction(scopeChain), name_(name), script_(script), pc_(pc)
{
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(BindNameCache)
static MBindNameCache *New(MDefinition *scopeChain, PropertyName *name, JSScript *script,
jsbytecode *pc) {
return new MBindNameCache(scopeChain, name, script, pc);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *scopeChain() const {
return getOperand(0);
}
PropertyName *name() const {
return name_;
}
JSScript *script() const {
return script_;
}
jsbytecode *pc() const {
return pc_;
}
};
// Guard on an object's shape.
class MGuardShape
: public MUnaryInstruction,
public SingleObjectPolicy
{
CompilerRootShape shape_;
BailoutKind bailoutKind_;
MGuardShape(MDefinition *obj, Shape *shape, BailoutKind bailoutKind)
: MUnaryInstruction(obj),
shape_(shape),
bailoutKind_(bailoutKind)
{
setGuard();
setMovable();
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(GuardShape)
static MGuardShape *New(MDefinition *obj, Shape *shape, BailoutKind bailoutKind) {
return new MGuardShape(obj, shape, bailoutKind);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *obj() const {
return getOperand(0);
}
const Shape *shape() const {
return shape_;
}
BailoutKind bailoutKind() const {
return bailoutKind_;
}
bool congruentTo(MDefinition * const &ins) const {
if (!ins->isGuardShape())
return false;
if (shape() != ins->toGuardShape()->shape())
return false;
if (bailoutKind() != ins->toGuardShape()->bailoutKind())
return false;
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::ObjectFields);
}
};
// Guard on an object's type, inclusively or exclusively.
class MGuardObjectType
: public MUnaryInstruction,
public SingleObjectPolicy
{
CompilerRoot<types::TypeObject *> typeObject_;
bool bailOnEquality_;
MGuardObjectType(MDefinition *obj, types::TypeObject *typeObject, bool bailOnEquality)
: MUnaryInstruction(obj),
typeObject_(typeObject),
bailOnEquality_(bailOnEquality)
{
setGuard();
setMovable();
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(GuardObjectType)
static MGuardObjectType *New(MDefinition *obj, types::TypeObject *typeObject,
bool bailOnEquality) {
return new MGuardObjectType(obj, typeObject, bailOnEquality);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *obj() const {
return getOperand(0);
}
const types::TypeObject *typeObject() const {
return typeObject_;
}
bool bailOnEquality() const {
return bailOnEquality_;
}
bool congruentTo(MDefinition * const &ins) const {
if (!ins->isGuardObjectType())
return false;
if (typeObject() != ins->toGuardObjectType()->typeObject())
return false;
if (bailOnEquality() != ins->toGuardObjectType()->bailOnEquality())
return false;
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::ObjectFields);
}
};
// Guard on an object's class.
class MGuardClass
: public MUnaryInstruction,
public SingleObjectPolicy
{
const Class *class_;
MGuardClass(MDefinition *obj, const Class *clasp)
: MUnaryInstruction(obj),
class_(clasp)
{
setGuard();
setMovable();
}
public:
INSTRUCTION_HEADER(GuardClass)
static MGuardClass *New(MDefinition *obj, const Class *clasp) {
return new MGuardClass(obj, clasp);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *obj() const {
return getOperand(0);
}
const Class *getClass() const {
return class_;
}
bool congruentTo(MDefinition * const &ins) const {
if (!ins->isGuardClass())
return false;
if (getClass() != ins->toGuardClass()->getClass())
return false;
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::ObjectFields);
}
};
// Load from vp[slot] (slots that are not inline in an object).
class MLoadSlot
: public MUnaryInstruction,
public SingleObjectPolicy
{
uint32_t slot_;
MLoadSlot(MDefinition *slots, uint32_t slot)
: MUnaryInstruction(slots),
slot_(slot)
{
setResultType(MIRType_Value);
setMovable();
JS_ASSERT(slots->type() == MIRType_Slots);
}
public:
INSTRUCTION_HEADER(LoadSlot)
static MLoadSlot *New(MDefinition *slots, uint32_t slot) {
return new MLoadSlot(slots, slot);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *slots() const {
return getOperand(0);
}
uint32_t slot() const {
return slot_;
}
bool congruentTo(MDefinition * const &ins) const {
if (!ins->isLoadSlot())
return false;
if (slot() != ins->toLoadSlot()->slot())
return false;
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
JS_ASSERT(slots()->type() == MIRType_Slots);
return AliasSet::Load(AliasSet::DynamicSlot);
}
bool mightAlias(MDefinition *store);
};
// Inline call to access a function's environment (scope chain).
class MFunctionEnvironment
: public MUnaryInstruction,
public SingleObjectPolicy
{
public:
MFunctionEnvironment(MDefinition *function)
: MUnaryInstruction(function)
{
setResultType(MIRType_Object);
setMovable();
}
INSTRUCTION_HEADER(FunctionEnvironment)
static MFunctionEnvironment *New(MDefinition *function) {
return new MFunctionEnvironment(function);
}
MDefinition *function() const {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
// A function's environment is fixed.
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// Loads the current js::ForkJoinSlice*.
// Only applicable in ParallelExecution.
class MParSlice
: public MNullaryInstruction
{
public:
MParSlice()
: MNullaryInstruction()
{
setResultType(MIRType_ForkJoinSlice);
}
INSTRUCTION_HEADER(ParSlice);
AliasSet getAliasSet() const {
// Indicate that this instruction reads nothing, stores nothing.
// (For all intents and purposes)
return AliasSet::None();
}
};
// Store to vp[slot] (slots that are not inline in an object).
class MStoreSlot
: public MBinaryInstruction,
public SingleObjectPolicy
{
uint32_t slot_;
MIRType slotType_;
bool needsBarrier_;
MStoreSlot(MDefinition *slots, uint32_t slot, MDefinition *value, bool barrier)
: MBinaryInstruction(slots, value),
slot_(slot),
slotType_(MIRType_Value),
needsBarrier_(barrier)
{
JS_ASSERT(slots->type() == MIRType_Slots);
}
public:
INSTRUCTION_HEADER(StoreSlot)
static MStoreSlot *New(MDefinition *slots, uint32_t slot, MDefinition *value) {
return new MStoreSlot(slots, slot, value, false);
}
static MStoreSlot *NewBarriered(MDefinition *slots, uint32_t slot, MDefinition *value) {
return new MStoreSlot(slots, slot, value, true);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *slots() const {
return getOperand(0);
}
MDefinition *value() const {
return getOperand(1);
}
uint32_t slot() const {
return slot_;
}
MIRType slotType() const {
return slotType_;
}
void setSlotType(MIRType slotType) {
JS_ASSERT(slotType != MIRType_None);
slotType_ = slotType;
}
bool needsBarrier() const {
return needsBarrier_;
}
void setNeedsBarrier() {
needsBarrier_ = true;
}
AliasSet getAliasSet() const {
return AliasSet::Store(AliasSet::DynamicSlot);
}
};
class MGetNameCache
: public MUnaryInstruction,
public SingleObjectPolicy
{
public:
enum AccessKind {
NAMETYPEOF,
NAME
};
private:
CompilerRootPropertyName name_;
AccessKind kind_;
MGetNameCache(MDefinition *obj, HandlePropertyName name, AccessKind kind)
: MUnaryInstruction(obj),
name_(name),
kind_(kind)
{
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(GetNameCache)
static MGetNameCache *New(MDefinition *obj, HandlePropertyName name, AccessKind kind) {
return new MGetNameCache(obj, name, kind);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *scopeObj() const {
return getOperand(0);
}
PropertyName *name() const {
return name_;
}
AccessKind accessKind() const {
return kind_;
}
};
class MCallGetIntrinsicValue : public MNullaryInstruction
{
CompilerRootPropertyName name_;
MCallGetIntrinsicValue(HandlePropertyName name)
: name_(name)
{
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(CallGetIntrinsicValue)
static MCallGetIntrinsicValue *New(HandlePropertyName name) {
return new MCallGetIntrinsicValue(name);
}
PropertyName *name() const {
return name_;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MCallsiteCloneCache
: public MUnaryInstruction,
public SingleObjectPolicy
{
jsbytecode *callPc_;
MCallsiteCloneCache(MDefinition *callee, jsbytecode *callPc)
: MUnaryInstruction(callee),
callPc_(callPc)
{
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(CallsiteCloneCache);
static MCallsiteCloneCache *New(MDefinition *callee, jsbytecode *callPc) {
return new MCallsiteCloneCache(callee, callPc);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *callee() const {
return getOperand(0);
}
jsbytecode *callPc() const {
return callPc_;
}
// Callsite cloning is idempotent.
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MSetPropertyInstruction : public MBinaryInstruction
{
CompilerRootPropertyName name_;
bool strict_;
bool needsBarrier_;
protected:
MSetPropertyInstruction(MDefinition *obj, MDefinition *value, HandlePropertyName name,
bool strict)
: MBinaryInstruction(obj, value),
name_(name), strict_(strict), needsBarrier_(true)
{}
public:
MDefinition *obj() const {
return getOperand(0);
}
MDefinition *value() const {
return getOperand(1);
}
PropertyName *name() const {
return name_;
}
bool strict() const {
return strict_;
}
bool needsBarrier() const {
return needsBarrier_;
}
void setNeedsBarrier() {
needsBarrier_ = true;
}
};
class MSetElementInstruction
: public MTernaryInstruction
{
protected:
MSetElementInstruction(MDefinition *object, MDefinition *index, MDefinition *value)
: MTernaryInstruction(object, index, value)
{
}
public:
MDefinition *object() const {
return getOperand(0);
}
MDefinition *index() const {
return getOperand(1);
}
MDefinition *value() const {
return getOperand(2);
}
};
class MDeleteProperty
: public MUnaryInstruction,
public BoxInputsPolicy
{
CompilerRootPropertyName name_;
protected:
MDeleteProperty(MDefinition *val, HandlePropertyName name)
: MUnaryInstruction(val),
name_(name)
{
setResultType(MIRType_Boolean);
}
public:
INSTRUCTION_HEADER(DeleteProperty)
static MDeleteProperty *New(MDefinition *obj, HandlePropertyName name) {
return new MDeleteProperty(obj, name);
}
MDefinition *value() const {
return getOperand(0);
}
PropertyName *name() const {
return name_;
}
virtual TypePolicy *typePolicy() {
return this;
}
};
// Note: This uses CallSetElementPolicy to always box its second input,
// ensuring we don't need two LIR instructions to lower this.
class MCallSetProperty
: public MSetPropertyInstruction,
public CallSetElementPolicy
{
MCallSetProperty(MDefinition *obj, MDefinition *value, HandlePropertyName name, bool strict)
: MSetPropertyInstruction(obj, value, name, strict)
{
}
public:
INSTRUCTION_HEADER(CallSetProperty)
static MCallSetProperty *New(MDefinition *obj, MDefinition *value, HandlePropertyName name, bool strict) {
return new MCallSetProperty(obj, value, name, strict);
}
TypePolicy *typePolicy() {
return this;
}
};
class MSetPropertyCache
: public MSetPropertyInstruction,
public SingleObjectPolicy
{
MSetPropertyCache(MDefinition *obj, MDefinition *value, HandlePropertyName name, bool strict)
: MSetPropertyInstruction(obj, value, name, strict)
{
}
public:
INSTRUCTION_HEADER(SetPropertyCache)
static MSetPropertyCache *New(MDefinition *obj, MDefinition *value, HandlePropertyName name, bool strict) {
return new MSetPropertyCache(obj, value, name, strict);
}
TypePolicy *typePolicy() {
return this;
}
};
class MSetElementCache
: public MSetElementInstruction,
public MixPolicy<ObjectPolicy<0>, BoxPolicy<1> >
{
bool strict_;
MSetElementCache(MDefinition *obj, MDefinition *index, MDefinition *value, bool strict)
: MSetElementInstruction(obj, index, value),
strict_(strict)
{
}
public:
INSTRUCTION_HEADER(SetElementCache);
static MSetElementCache *New(MDefinition *obj, MDefinition *index, MDefinition *value,
bool strict) {
return new MSetElementCache(obj, index, value, strict);
}
bool strict() const {
return strict_;
}
TypePolicy *typePolicy() {
return this;
}
};
class MCallGetProperty
: public MUnaryInstruction,
public BoxInputsPolicy
{
CompilerRootPropertyName name_;
bool idempotent_;
MCallGetProperty(MDefinition *value, HandlePropertyName name)
: MUnaryInstruction(value), name_(name),
idempotent_(false)
{
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(CallGetProperty)
static MCallGetProperty *New(MDefinition *value, HandlePropertyName name) {
return new MCallGetProperty(value, name);
}
MDefinition *value() const {
return getOperand(0);
}
PropertyName *name() const {
return name_;
}
TypePolicy *typePolicy() {
return this;
}
// Constructors need to perform a GetProp on the function prototype.
// Since getters cannot be set on the prototype, fetching is non-effectful.
// The operation may be safely repeated in case of bailout.
void setIdempotent() {
idempotent_ = true;
}
AliasSet getAliasSet() const {
if (!idempotent_)
return AliasSet::Store(AliasSet::Any);
return AliasSet::None();
}
};
// Inline call to handle lhs[rhs]. The first input is a Value so that this
// instruction can handle both objects and strings.
class MCallGetElement
: public MBinaryInstruction,
public BoxInputsPolicy
{
MCallGetElement(MDefinition *lhs, MDefinition *rhs)
: MBinaryInstruction(lhs, rhs)
{
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(CallGetElement)
static MCallGetElement *New(MDefinition *lhs, MDefinition *rhs) {
return new MCallGetElement(lhs, rhs);
}
TypePolicy *typePolicy() {
return this;
}
};
class MCallSetElement
: public MSetElementInstruction,
public CallSetElementPolicy
{
MCallSetElement(MDefinition *object, MDefinition *index, MDefinition *value)
: MSetElementInstruction(object, index, value)
{
}
public:
INSTRUCTION_HEADER(CallSetElement)
static MCallSetElement *New(MDefinition *object, MDefinition *index, MDefinition *value) {
return new MCallSetElement(object, index, value);
}
TypePolicy *typePolicy() {
return this;
}
};
class MCallInitElementArray
: public MAryInstruction<2>,
public MixPolicy<ObjectPolicy<0>, BoxPolicy<1> >
{
uint32_t index_;
MCallInitElementArray(MDefinition *obj, uint32_t index, MDefinition *val)
: index_(index)
{
setOperand(0, obj);
setOperand(1, val);
}
public:
INSTRUCTION_HEADER(CallInitElementArray)
static MCallInitElementArray *New(MDefinition *obj, uint32_t index, MDefinition *val)
{
return new MCallInitElementArray(obj, index, val);
}
MDefinition *object() const {
return getOperand(0);
}
uint32_t index() const {
return index_;
}
MDefinition *value() const {
return getOperand(1);
}
TypePolicy *typePolicy() {
return this;
}
};
class MSetDOMProperty
: public MAryInstruction<2>,
public MixPolicy<ObjectPolicy<0>, BoxPolicy<1> >
{
const JSJitSetterOp func_;
MSetDOMProperty(const JSJitSetterOp func, MDefinition *obj, MDefinition *val)
: func_(func)
{
setOperand(0, obj);
setOperand(1, val);
}
public:
INSTRUCTION_HEADER(SetDOMProperty)
static MSetDOMProperty *New(const JSJitSetterOp func, MDefinition *obj, MDefinition *val)
{
return new MSetDOMProperty(func, obj, val);
}
const JSJitSetterOp fun() {
return func_;
}
MDefinition *object() {
return getOperand(0);
}
MDefinition *value()
{
return getOperand(1);
}
TypePolicy *typePolicy() {
return this;
}
};
class MGetDOMProperty
: public MAryInstruction<2>,
public ObjectPolicy<0>
{
const JSJitInfo *info_;
MGetDOMProperty(const JSJitInfo *jitinfo, MDefinition *obj, MDefinition *guard)
: info_(jitinfo)
{
JS_ASSERT(jitinfo);
JS_ASSERT(jitinfo->type == JSJitInfo::Getter);
setOperand(0, obj);
// Pin the guard as an operand if we want to hoist later
setOperand(1, guard);
// We are movable iff the jitinfo says we can be.
if (jitinfo->isPure)
setMovable();
setResultType(MIRType_Value);
}
protected:
const JSJitInfo *info() const {
return info_;
}
public:
INSTRUCTION_HEADER(GetDOMProperty)
static MGetDOMProperty *New(const JSJitInfo *info, MDefinition *obj, MDefinition *guard)
{
return new MGetDOMProperty(info, obj, guard);
}
const JSJitGetterOp fun() {
return info_->getter;
}
bool isInfallible() const {
return info_->isInfallible;
}
bool isDomConstant() const {
return info_->isConstant;
}
bool isDomPure() const {
return info_->isPure;
}
MDefinition *object() {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
bool congruentTo(MDefinition *const &ins) const {
if (!isDomPure())
return false;
if (!ins->isGetDOMProperty())
return false;
// Checking the jitinfo is the same as checking the constant function
if (!(info() == ins->toGetDOMProperty()->info()))
return false;
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
// The whole point of constancy is that it's non-effectful and doesn't
// conflict with anything
if (isDomConstant())
return AliasSet::None();
// Pure DOM attributes can only alias things that alias the world or
// explicitly alias DOM properties.
if (isDomPure())
return AliasSet::Load(AliasSet::DOMProperty);
return AliasSet::Store(AliasSet::Any);
}
};
class MStringLength
: public MUnaryInstruction,
public StringPolicy<0>
{
MStringLength(MDefinition *string)
: MUnaryInstruction(string)
{
setResultType(MIRType_Int32);
setMovable();
}
public:
INSTRUCTION_HEADER(StringLength)
static MStringLength *New(MDefinition *string) {
return new MStringLength(string);
}
MDefinition *foldsTo(bool useValueNumbers);
TypePolicy *typePolicy() {
return this;
}
MDefinition *string() const {
return getOperand(0);
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
// The string |length| property is immutable, so there is no
// implicit dependency.
return AliasSet::None();
}
};
// Inlined version of Math.floor().
class MFloor
: public MUnaryInstruction,
public DoublePolicy<0>
{
public:
MFloor(MDefinition *num)
: MUnaryInstruction(num)
{
setResultType(MIRType_Int32);
setMovable();
}
INSTRUCTION_HEADER(Floor)
MDefinition *num() const {
return getOperand(0);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
TypePolicy *typePolicy() {
return this;
}
};
// Inlined version of Math.round().
class MRound
: public MUnaryInstruction,
public DoublePolicy<0>
{
public:
MRound(MDefinition *num)
: MUnaryInstruction(num)
{
setResultType(MIRType_Int32);
setMovable();
}
INSTRUCTION_HEADER(Round)
MDefinition *num() const {
return getOperand(0);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
TypePolicy *typePolicy() {
return this;
}
};
class MIteratorStart
: public MUnaryInstruction,
public SingleObjectPolicy
{
uint8_t flags_;
MIteratorStart(MDefinition *obj, uint8_t flags)
: MUnaryInstruction(obj), flags_(flags)
{
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(IteratorStart)
static MIteratorStart *New(MDefinition *obj, uint8_t flags) {
return new MIteratorStart(obj, flags);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *object() const {
return getOperand(0);
}
uint8_t flags() const {
return flags_;
}
};
class MIteratorNext
: public MUnaryInstruction,
public SingleObjectPolicy
{
MIteratorNext(MDefinition *iter)
: MUnaryInstruction(iter)
{
setResultType(MIRType_Value);
}
public:
INSTRUCTION_HEADER(IteratorNext)
static MIteratorNext *New(MDefinition *iter) {
return new MIteratorNext(iter);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *iterator() const {
return getOperand(0);
}
};
class MIteratorMore
: public MUnaryInstruction,
public SingleObjectPolicy
{
MIteratorMore(MDefinition *iter)
: MUnaryInstruction(iter)
{
setResultType(MIRType_Boolean);
}
public:
INSTRUCTION_HEADER(IteratorMore)
static MIteratorMore *New(MDefinition *iter) {
return new MIteratorMore(iter);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *iterator() const {
return getOperand(0);
}
};
class MIteratorEnd
: public MUnaryInstruction,
public SingleObjectPolicy
{
MIteratorEnd(MDefinition *iter)
: MUnaryInstruction(iter)
{ }
public:
INSTRUCTION_HEADER(IteratorEnd)
static MIteratorEnd *New(MDefinition *iter) {
return new MIteratorEnd(iter);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *iterator() const {
return getOperand(0);
}
};
// Implementation for 'in' operator.
class MIn
: public MBinaryInstruction,
public MixPolicy<BoxPolicy<0>, ObjectPolicy<1> >
{
public:
MIn(MDefinition *key, MDefinition *obj)
: MBinaryInstruction(key, obj)
{
setResultType(MIRType_Boolean);
}
INSTRUCTION_HEADER(In)
TypePolicy *typePolicy() {
return this;
}
};
// Test whether the index is in the array bounds or a hole.
class MInArray
: public MQuaternaryInstruction,
public ObjectPolicy<3>
{
bool needsHoleCheck_;
MInArray(MDefinition *elements, MDefinition *index,
MDefinition *initLength, MDefinition *object,
bool needsHoleCheck)
: MQuaternaryInstruction(elements, index, initLength, object),
needsHoleCheck_(needsHoleCheck)
{
setResultType(MIRType_Boolean);
setMovable();
JS_ASSERT(elements->type() == MIRType_Elements);
JS_ASSERT(index->type() == MIRType_Int32);
JS_ASSERT(initLength->type() == MIRType_Int32);
}
public:
INSTRUCTION_HEADER(InArray)
static MInArray *New(MDefinition *elements, MDefinition *index,
MDefinition *initLength, MDefinition *object,
bool needsHoleCheck)
{
return new MInArray(elements, index, initLength, object, needsHoleCheck);
}
MDefinition *elements() const {
return getOperand(0);
}
MDefinition *index() const {
return getOperand(1);
}
MDefinition *initLength() const {
return getOperand(2);
}
MDefinition *object() const {
return getOperand(3);
}
bool needsHoleCheck() const {
return needsHoleCheck_;
}
bool needsNegativeIntCheck() const;
AliasSet getAliasSet() const {
return AliasSet::Load(AliasSet::Element);
}
TypePolicy *typePolicy() {
return this;
}
};
// Implementation for instanceof operator with specific rhs.
class MInstanceOf
: public MUnaryInstruction,
public InstanceOfPolicy
{
CompilerRootObject protoObj_;
public:
MInstanceOf(MDefinition *obj, JSObject *proto)
: MUnaryInstruction(obj),
protoObj_(proto)
{
setResultType(MIRType_Boolean);
}
INSTRUCTION_HEADER(InstanceOf)
TypePolicy *typePolicy() {
return this;
}
JSObject *prototypeObject() {
return protoObj_;
}
};
// Implementation for instanceof operator with unknown rhs.
class MCallInstanceOf
: public MBinaryInstruction,
public MixPolicy<BoxPolicy<0>, ObjectPolicy<1> >
{
public:
MCallInstanceOf(MDefinition *obj, MDefinition *proto)
: MBinaryInstruction(obj, proto)
{
setResultType(MIRType_Boolean);
}
INSTRUCTION_HEADER(CallInstanceOf)
TypePolicy *typePolicy() {
return this;
}
};
class MArgumentsLength : public MNullaryInstruction
{
MArgumentsLength()
{
setResultType(MIRType_Int32);
setMovable();
}
public:
INSTRUCTION_HEADER(ArgumentsLength)
static MArgumentsLength *New() {
return new MArgumentsLength();
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
// Arguments |length| cannot be mutated by Ion Code.
return AliasSet::None();
}
};
// This MIR instruction is used to get an argument from the actual arguments.
class MGetArgument
: public MUnaryInstruction,
public IntPolicy<0>
{
MGetArgument(MDefinition *idx)
: MUnaryInstruction(idx)
{
setResultType(MIRType_Value);
setMovable();
}
public:
INSTRUCTION_HEADER(GetArgument)
static MGetArgument *New(MDefinition *idx) {
return new MGetArgument(idx);
}
MDefinition *index() const {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
bool congruentTo(MDefinition *const &ins) const {
return congruentIfOperandsEqual(ins);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MRestCommon
{
unsigned numFormals_;
CompilerRootObject templateObject_;
protected:
MRestCommon(unsigned numFormals, JSObject *templateObject)
: numFormals_(numFormals),
templateObject_(templateObject)
{ }
public:
unsigned numFormals() const {
return numFormals_;
}
JSObject *templateObject() const {
return templateObject_;
}
};
class MRest
: public MUnaryInstruction,
public MRestCommon,
public IntPolicy<0>
{
MRest(MDefinition *numActuals, unsigned numFormals, JSObject *templateObject)
: MUnaryInstruction(numActuals),
MRestCommon(numFormals, templateObject)
{
setResultType(MIRType_Object);
setResultTypeSet(MakeSingletonTypeSet(templateObject));
}
public:
INSTRUCTION_HEADER(Rest);
static MRest *New(MDefinition *numActuals, unsigned numFormals, JSObject *templateObject) {
return new MRest(numActuals, numFormals, templateObject);
}
MDefinition *numActuals() const {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MParRest
: public MBinaryInstruction,
public MRestCommon,
public IntPolicy<1>
{
MParRest(MDefinition *parSlice, MDefinition *numActuals, unsigned numFormals,
JSObject *templateObject)
: MBinaryInstruction(parSlice, numActuals),
MRestCommon(numFormals, templateObject)
{
setResultType(MIRType_Object);
setResultTypeSet(MakeSingletonTypeSet(templateObject));
}
public:
INSTRUCTION_HEADER(ParRest);
static MParRest *New(MDefinition *parSlice, MDefinition *numActuals, unsigned numFormals,
JSObject *templateObject) {
return new MParRest(parSlice, numActuals, numFormals, templateObject);
}
static MParRest *New(MDefinition *parSlice, MRest *rest) {
return new MParRest(parSlice, rest->numActuals(), rest->numFormals(), rest->templateObject());
}
MDefinition *parSlice() const {
return getOperand(0);
}
MDefinition *numActuals() const {
return getOperand(1);
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MParWriteGuard
: public MBinaryInstruction,
public ObjectPolicy<1>
{
MParWriteGuard(MDefinition *parThreadContext,
MDefinition *obj)
: MBinaryInstruction(parThreadContext, obj)
{
setResultType(MIRType_None);
setGuard();
setMovable();
}
public:
INSTRUCTION_HEADER(ParWriteGuard);
static MParWriteGuard *New(MDefinition *parThreadContext, MDefinition *obj) {
return new MParWriteGuard(parThreadContext, obj);
}
MDefinition *parSlice() const {
return getOperand(0);
}
MDefinition *object() const {
return getOperand(1);
}
BailoutKind bailoutKind() const {
return Bailout_Normal;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MParDump
: public MUnaryInstruction,
public BoxPolicy<0>
{
public:
INSTRUCTION_HEADER(ParDump);
MParDump(MDefinition *v)
: MUnaryInstruction(v)
{
setResultType(MIRType_None);
}
MDefinition *value() const {
return getOperand(0);
}
TypePolicy *typePolicy() {
return this;
}
};
// Given a value, guard that the value is in a particular TypeSet, then returns
// that value.
class MTypeBarrier
: public MUnaryInstruction,
public BoxInputsPolicy
{
BailoutKind bailoutKind_;
MTypeBarrier(MDefinition *def, types::StackTypeSet *types, BailoutKind bailoutKind)
: MUnaryInstruction(def)
{
JS_ASSERT(!types->unknown());
setResultType(MIRType_Value);
setResultTypeSet(types);
setGuard();
setMovable();
bailoutKind_ = bailoutKind;
}
public:
INSTRUCTION_HEADER(TypeBarrier)
static MTypeBarrier *New(MDefinition *def, types::StackTypeSet *types) {
BailoutKind bailoutKind = def->isEffectful()
? Bailout_TypeBarrier
: Bailout_Normal;
return new MTypeBarrier(def, types, bailoutKind);
}
static MTypeBarrier *New(MDefinition *def, types::StackTypeSet *types,
BailoutKind bailoutKind) {
return new MTypeBarrier(def, types, bailoutKind);
}
TypePolicy *typePolicy() {
return this;
}
bool congruentTo(MDefinition * const &def) const {
return false;
}
MDefinition *input() const {
return getOperand(0);
}
BailoutKind bailoutKind() const {
return bailoutKind_;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
virtual bool neverHoist() const {
return resultTypeSet()->empty();
}
};
// Like MTypeBarrier, guard that the value is in the given type set. This is
// used before property writes to ensure the value being written is represented
// in the property types for the object.
class MMonitorTypes : public MUnaryInstruction, public BoxInputsPolicy
{
const types::StackTypeSet *typeSet_;
MMonitorTypes(MDefinition *def, const types::StackTypeSet *types)
: MUnaryInstruction(def),
typeSet_(types)
{
setGuard();
JS_ASSERT(!types->unknown());
}
public:
INSTRUCTION_HEADER(MonitorTypes)
static MMonitorTypes *New(MDefinition *def, const types::StackTypeSet *types) {
return new MMonitorTypes(def, types);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *input() const {
return getOperand(0);
}
const types::StackTypeSet *typeSet() const {
return typeSet_;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// Given a value being written to another object, update the generational store
// buffer if the value is in the nursery and object is in the tenured heap.
class MPostWriteBarrier
: public MBinaryInstruction,
public ObjectPolicy<0>
{
MPostWriteBarrier(MDefinition *obj, MDefinition *value)
: MBinaryInstruction(obj, value)
{
setGuard();
}
public:
INSTRUCTION_HEADER(PostWriteBarrier)
static MPostWriteBarrier *New(MDefinition *obj, MDefinition *value) {
return new MPostWriteBarrier(obj, value);
}
TypePolicy *typePolicy() {
return this;
}
MDefinition *object() const {
return getOperand(0);
}
MDefinition *value() const {
return getOperand(1);
}
};
class MNewSlots : public MNullaryInstruction
{
unsigned nslots_;
MNewSlots(unsigned nslots)
: nslots_(nslots)
{
setResultType(MIRType_Slots);
}
public:
INSTRUCTION_HEADER(NewSlots)
static MNewSlots *New(unsigned nslots) {
return new MNewSlots(nslots);
}
unsigned nslots() const {
return nslots_;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MNewDeclEnvObject : public MNullaryInstruction
{
CompilerRootObject templateObj_;
MNewDeclEnvObject(HandleObject templateObj)
: MNullaryInstruction(),
templateObj_(templateObj)
{
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(NewDeclEnvObject);
static MNewDeclEnvObject *New(HandleObject templateObj) {
return new MNewDeclEnvObject(templateObj);
}
JSObject *templateObj() {
return templateObj_;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MNewCallObject : public MUnaryInstruction
{
CompilerRootObject templateObj_;
bool needsSingletonType_;
MNewCallObject(HandleObject templateObj, bool needsSingletonType, MDefinition *slots)
: MUnaryInstruction(slots),
templateObj_(templateObj),
needsSingletonType_(needsSingletonType)
{
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(NewCallObject)
static MNewCallObject *New(HandleObject templateObj, bool needsSingletonType, MDefinition *slots) {
return new MNewCallObject(templateObj, needsSingletonType, slots);
}
MDefinition *slots() {
return getOperand(0);
}
JSObject *templateObject() {
return templateObj_;
}
bool needsSingletonType() {
return needsSingletonType_;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MParNewCallObject : public MBinaryInstruction
{
CompilerRootObject templateObj_;
MParNewCallObject(MDefinition *parSlice,
JSObject *templateObj, MDefinition *slots)
: MBinaryInstruction(parSlice, slots),
templateObj_(templateObj)
{
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(ParNewCallObject);
static MParNewCallObject *New(MDefinition *parSlice,
JSObject *templateObj,
MDefinition *slots) {
return new MParNewCallObject(parSlice, templateObj, slots);
}
static MParNewCallObject *New(MDefinition *parSlice,
MNewCallObject *originalInstruction) {
return New(parSlice,
originalInstruction->templateObject(),
originalInstruction->slots());
}
MDefinition *parSlice() const {
return getOperand(0);
}
MDefinition *slots() const {
return getOperand(1);
}
JSObject *templateObj() const {
return templateObj_;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MNewStringObject :
public MUnaryInstruction,
public StringPolicy<0>
{
CompilerRootObject templateObj_;
MNewStringObject(MDefinition *input, HandleObject templateObj)
: MUnaryInstruction(input),
templateObj_(templateObj)
{
setResultType(MIRType_Object);
}
public:
INSTRUCTION_HEADER(NewStringObject)
static MNewStringObject *New(MDefinition *input, HandleObject templateObj) {
return new MNewStringObject(input, templateObj);
}
MDefinition *input() const {
return getOperand(0);
}
StringObject *templateObj() const;
TypePolicy *typePolicy() {
return this;
}
};
// Node that represents that a script has begun executing. This comes at the
// start of the function and is called once per function (including inline
// ones)
class MFunctionBoundary : public MNullaryInstruction
{
public:
enum Type {
Enter, // a function has begun executing and it is not inline
Exit, // any function has exited (inlined or normal)
Inline_Enter, // an inline function has begun executing
Inline_Exit // all instructions of an inline function are done, a
// return from the inline function could have occurred
// before this boundary
};
private:
JSScript *script_;
Type type_;
unsigned inlineLevel_;
MFunctionBoundary(JSScript *script, Type type, unsigned inlineLevel)
: script_(script), type_(type), inlineLevel_(inlineLevel)
{
JS_ASSERT_IF(type != Inline_Exit, script != NULL);
JS_ASSERT_IF(type == Inline_Enter, inlineLevel != 0);
setGuard();
}
public:
INSTRUCTION_HEADER(FunctionBoundary)
static MFunctionBoundary *New(JSScript *script, Type type,
unsigned inlineLevel = 0) {
return new MFunctionBoundary(script, type, inlineLevel);
}
JSScript *script() {
return script_;
}
Type type() {
return type_;
}
unsigned inlineLevel() {
return inlineLevel_;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
// This is an alias for MLoadFixedSlot.
class MEnclosingScope : public MLoadFixedSlot
{
MEnclosingScope(MDefinition *obj)
: MLoadFixedSlot(obj, ScopeObject::enclosingScopeSlot())
{
setResultType(MIRType_Object);
}
public:
static MEnclosingScope *New(MDefinition *obj) {
return new MEnclosingScope(obj);
}
AliasSet getAliasSet() const {
// ScopeObject reserved slots are immutable.
return AliasSet::None();
}
};
// Creates a dense array of the given length.
//
// Note: the template object should be an *empty* dense array!
class MParNewDenseArray : public MBinaryInstruction
{
CompilerRootObject templateObject_;
public:
INSTRUCTION_HEADER(ParNewDenseArray);
MParNewDenseArray(MDefinition *parSlice,
MDefinition *length,
JSObject *templateObject)
: MBinaryInstruction(parSlice, length),
templateObject_(templateObject)
{
setResultType(MIRType_Object);
}
MDefinition *parSlice() const {
return getOperand(0);
}
MDefinition *length() const {
return getOperand(1);
}
JSObject *templateObject() const {
return templateObject_;
}
};
// A resume point contains the information needed to reconstruct the interpreter
// state from a position in the JIT. See the big comment near resumeAfter() in
// IonBuilder.cpp.
class MResumePoint : public MNode, public InlineForwardListNode<MResumePoint>
{
public:
enum Mode {
ResumeAt, // Resume until before the current instruction
ResumeAfter, // Resume after the current instruction
Outer // State before inlining.
};
private:
friend class MBasicBlock;
FixedList<MUse> operands_;
uint32_t stackDepth_;
jsbytecode *pc_;
MResumePoint *caller_;
MInstruction *instruction_;
Mode mode_;
MResumePoint(MBasicBlock *block, jsbytecode *pc, MResumePoint *parent, Mode mode);
void inherit(MBasicBlock *state);
protected:
// Initializes operands_ to an empty array of a fixed length.
// The array may then be filled in by inherit().
bool init() {
return operands_.init(stackDepth_);
}
// Overwrites an operand without updating its Uses.
void setOperand(size_t index, MDefinition *operand) {
JS_ASSERT(index < stackDepth_);
operands_[index].set(operand, this, index);
operand->addUse(&operands_[index]);
}
void clearOperand(size_t index) {
JS_ASSERT(index < stackDepth_);
operands_[index].set(NULL, this, index);
}
MUse *getUseFor(size_t index) {
return &operands_[index];
}
public:
static MResumePoint *New(MBasicBlock *block, jsbytecode *pc, MResumePoint *parent, Mode mode);
MNode::Kind kind() const {
return MNode::ResumePoint;
}
size_t numOperands() const {
return stackDepth_;
}
MDefinition *getOperand(size_t index) const {
JS_ASSERT(index < stackDepth_);
return operands_[index].producer();
}
jsbytecode *pc() const {
return pc_;
}
uint32_t stackDepth() const {
return stackDepth_;
}
MResumePoint *caller() {
return caller_;
}
void setCaller(MResumePoint *caller) {
caller_ = caller;
}
uint32_t frameCount() const {
uint32_t count = 1;
for (MResumePoint *it = caller_; it; it = it->caller_)
count++;
return count;
}
MInstruction *instruction() {
return instruction_;
}
void setInstruction(MInstruction *ins) {
instruction_ = ins;
}
Mode mode() const {
return mode_;
}
void discardUses() {
for (size_t i = 0; i < stackDepth_; i++) {
if (operands_[i].hasProducer())
operands_[i].producer()->removeUse(&operands_[i]);
}
}
};
/*
* Facade for a chain of MResumePoints that cross frame boundaries (due to
* function inlining). Operands are ordered from oldest frame to newest.
*/
class FlattenedMResumePointIter
{
Vector<MResumePoint *, 8, SystemAllocPolicy> resumePoints;
MResumePoint *newest;
size_t numOperands_;
public:
explicit FlattenedMResumePointIter(MResumePoint *newest)
: newest(newest), numOperands_(0)
{}
bool init() {
MResumePoint *it = newest;
do {
if (!resumePoints.append(it))
return false;
it = it->caller();
} while (it);
Reverse(resumePoints.begin(), resumePoints.end());
return true;
}
MResumePoint **begin() {
return resumePoints.begin();
}
MResumePoint **end() {
return resumePoints.end();
}
size_t numOperands() const {
return numOperands_;
}
};
class MIsCallable
: public MUnaryInstruction,
public SingleObjectPolicy
{
MIsCallable(MDefinition *object)
: MUnaryInstruction(object)
{
setResultType(MIRType_Boolean);
setMovable();
}
public:
INSTRUCTION_HEADER(IsCallable);
static MIsCallable *New(MDefinition *obj) {
return new MIsCallable(obj);
}
MDefinition *object() const {
return getOperand(0);
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MHaveSameClass
: public MBinaryInstruction,
public MixPolicy<ObjectPolicy<0>, ObjectPolicy<1> >
{
MHaveSameClass(MDefinition *left, MDefinition *right)
: MBinaryInstruction(left, right)
{
setResultType(MIRType_Boolean);
setMovable();
}
public:
INSTRUCTION_HEADER(HaveSameClass);
static MHaveSameClass *New(MDefinition *left, MDefinition *right) {
return new MHaveSameClass(left, right);
}
TypePolicy *typePolicy() {
return this;
}
AliasSet getAliasSet() const {
return AliasSet::None();
}
};
class MAsmJSNeg : public MUnaryInstruction
{
MAsmJSNeg(MDefinition *op, MIRType type)
: MUnaryInstruction(op)
{
setResultType(type);
setMovable();
}
public:
INSTRUCTION_HEADER(AsmJSNeg);
static MAsmJSNeg *NewAsmJS(MDefinition *op, MIRType type) {
return new MAsmJSNeg(op, type);
}
MDefinition *input() const {
return getOperand(0);
}
};
class MAsmJSUDiv : public MBinaryInstruction
{
MAsmJSUDiv(MDefinition *left, MDefinition *right)
: MBinaryInstruction(left, right)
{
setResultType(MIRType_Int32);
setMovable();
}
public:
INSTRUCTION_HEADER(AsmJSUDiv);
static MAsmJSUDiv *New(MDefinition *left, MDefinition *right) {
return new MAsmJSUDiv(left, right);
}
};
class MAsmJSUMod : public MBinaryInstruction
{
MAsmJSUMod(MDefinition *left, MDefinition *right)
: MBinaryInstruction(left, right)
{
setResultType(MIRType_Int32);
setMovable();
}
public:
INSTRUCTION_HEADER(AsmJSUMod);
static MAsmJSUMod *New(MDefinition *left, MDefinition *right) {
return new MAsmJSUMod(left, right);
}
};
class MAsmJSLoadHeap : public MUnaryInstruction
{
MAsmJSLoadHeap(ArrayBufferView::ViewType vt, MDefinition *ptr)
: MUnaryInstruction(ptr), viewType_(vt)
{
if (vt == ArrayBufferView::TYPE_FLOAT32 || vt == ArrayBufferView::TYPE_FLOAT64)
setResultType(MIRType_Double);
else
setResultType(MIRType_Int32);
}
ArrayBufferView::ViewType viewType_;
public:
INSTRUCTION_HEADER(AsmJSLoadHeap);
static MAsmJSLoadHeap *New(ArrayBufferView::ViewType vt, MDefinition *ptr) {
return new MAsmJSLoadHeap(vt, ptr);
}
ArrayBufferView::ViewType viewType() const { return viewType_; }
MDefinition *ptr() const { return getOperand(0); }
};
class MAsmJSStoreHeap : public MBinaryInstruction
{
MAsmJSStoreHeap(ArrayBufferView::ViewType vt, MDefinition *ptr, MDefinition *v)
: MBinaryInstruction(ptr, v), viewType_(vt)
{}
ArrayBufferView::ViewType viewType_;
public:
INSTRUCTION_HEADER(AsmJSStoreHeap);
static MAsmJSStoreHeap *New(ArrayBufferView::ViewType vt, MDefinition *ptr, MDefinition *v) {
return new MAsmJSStoreHeap(vt, ptr, v);
}
ArrayBufferView::ViewType viewType() const { return viewType_; }
MDefinition *ptr() const { return getOperand(0); }
MDefinition *value() const { return getOperand(1); }
};
class MAsmJSLoadGlobalVar : public MNullaryInstruction
{
MAsmJSLoadGlobalVar(MIRType type, unsigned globalDataOffset)
: globalDataOffset_(globalDataOffset)
{
JS_ASSERT(type == MIRType_Int32 || type == MIRType_Double);
setResultType(type);
}
unsigned globalDataOffset_;
public:
INSTRUCTION_HEADER(AsmJSLoadGlobalVar);
static MAsmJSLoadGlobalVar *New(MIRType type, unsigned globalDataOffset) {
return new MAsmJSLoadGlobalVar(type, globalDataOffset);
}
unsigned globalDataOffset() const { return globalDataOffset_; }
};
class MAsmJSStoreGlobalVar : public MUnaryInstruction
{
MAsmJSStoreGlobalVar(unsigned globalDataOffset, MDefinition *v)
: MUnaryInstruction(v), globalDataOffset_(globalDataOffset)
{}
unsigned globalDataOffset_;
public:
INSTRUCTION_HEADER(AsmJSStoreGlobalVar);
static MAsmJSStoreGlobalVar *New(unsigned globalDataOffset, MDefinition *v) {
return new MAsmJSStoreGlobalVar(globalDataOffset, v);
}
unsigned globalDataOffset() const { return globalDataOffset_; }
MDefinition *value() const { return getOperand(0); }
};
class MAsmJSLoadFuncPtr : public MUnaryInstruction
{
MAsmJSLoadFuncPtr(unsigned globalDataOffset, MDefinition *index)
: MUnaryInstruction(index), globalDataOffset_(globalDataOffset)
{
setResultType(MIRType_Pointer);
}
unsigned globalDataOffset_;
public:
INSTRUCTION_HEADER(AsmJSLoadFuncPtr);
static MAsmJSLoadFuncPtr *New(unsigned globalDataOffset, MDefinition *index) {
return new MAsmJSLoadFuncPtr(globalDataOffset, index);
}
unsigned globalDataOffset() const { return globalDataOffset_; }
MDefinition *index() const { return getOperand(0); }
};
class MAsmJSLoadFFIFunc : public MNullaryInstruction
{
MAsmJSLoadFFIFunc(unsigned globalDataOffset)
: globalDataOffset_(globalDataOffset)
{
setResultType(MIRType_Pointer);
}
unsigned globalDataOffset_;
public:
INSTRUCTION_HEADER(AsmJSLoadFFIFunc);
static MAsmJSLoadFFIFunc *New(unsigned globalDataOffset) {
return new MAsmJSLoadFFIFunc(globalDataOffset);
}
unsigned globalDataOffset() const { return globalDataOffset_; }
};
class MAsmJSParameter : public MNullaryInstruction
{
ABIArg abi_;
MAsmJSParameter(ABIArg abi, MIRType mirType)
: abi_(abi)
{
setResultType(mirType);
}
public:
INSTRUCTION_HEADER(AsmJSParameter);
static MAsmJSParameter *New(ABIArg abi, MIRType mirType) {
return new MAsmJSParameter(abi, mirType);
}
ABIArg abi() const { return abi_; }
};
class MAsmJSReturn : public MAryControlInstruction<1, 0>
{
MAsmJSReturn(MDefinition *ins) {
setOperand(0, ins);
}
public:
INSTRUCTION_HEADER(AsmJSReturn);
static MAsmJSReturn *New(MDefinition *ins) {
return new MAsmJSReturn(ins);
}
};
class MAsmJSVoidReturn : public MAryControlInstruction<0, 0>
{
public:
INSTRUCTION_HEADER(AsmJSVoidReturn);
static MAsmJSVoidReturn *New() {
return new MAsmJSVoidReturn();
}
};
class MAsmJSPassStackArg : public MUnaryInstruction
{
MAsmJSPassStackArg(uint32_t spOffset, MDefinition *ins)
: MUnaryInstruction(ins),
spOffset_(spOffset)
{}
uint32_t spOffset_;
public:
INSTRUCTION_HEADER(AsmJSPassStackArg);
static MAsmJSPassStackArg *New(uint32_t spOffset, MDefinition *ins) {
return new MAsmJSPassStackArg(spOffset, ins);
}
uint32_t spOffset() const {
return spOffset_;
}
void incrementOffset(uint32_t inc) {
spOffset_ += inc;
}
MDefinition *arg() const {
return getOperand(0);
}
};
class MAsmJSCall : public MInstruction
{
public:
class Callee {
public:
enum Which { Internal, Dynamic, Builtin };
private:
Which which_;
union {
Label *internal_;
MDefinition *dynamic_;
const void *builtin_;
} u;
public:
Callee() {}
Callee(Label *callee) : which_(Internal) { u.internal_ = callee; }
Callee(MDefinition *callee) : which_(Dynamic) { u.dynamic_ = callee; }
Callee(const void *callee) : which_(Builtin) { u.builtin_ = callee; }
Which which() const { return which_; }
Label *internal() const { JS_ASSERT(which_ == Internal); return u.internal_; }
MDefinition *dynamic() const { JS_ASSERT(which_ == Dynamic); return u.dynamic_; }
const void *builtin() const { JS_ASSERT(which_ == Builtin); return u.builtin_; }
};
private:
struct Operand {
AnyRegister reg;
MUse use;
};
Callee callee_;
size_t numOperands_;
MUse *operands_;
size_t numArgs_;
AnyRegister *argRegs_;
size_t spIncrement_;
protected:
void setOperand(size_t index, MDefinition *operand) {
operands_[index].set(operand, this, index);
operand->addUse(&operands_[index]);
}
MUse *getUseFor(size_t index) {
return &operands_[index];
}
public:
INSTRUCTION_HEADER(AsmJSCall);
struct Arg {
AnyRegister reg;
MDefinition *def;
Arg(AnyRegister reg, MDefinition *def) : reg(reg), def(def) {}
};
typedef Vector<Arg, 8> Args;
static MAsmJSCall *New(Callee callee, const Args &args, MIRType resultType, size_t spIncrement);
size_t numOperands() const {
return numOperands_;
}
MDefinition *getOperand(size_t index) const {
JS_ASSERT(index < numOperands_);
return operands_[index].producer();
}
size_t numArgs() const {
return numArgs_;
}
AnyRegister registerForArg(size_t index) const {
JS_ASSERT(index < numArgs_);
return argRegs_[index];
}
Callee callee() const {
return callee_;
}
size_t dynamicCalleeOperandIndex() const {
JS_ASSERT(callee_.which() == Callee::Dynamic);
JS_ASSERT(numArgs_ == numOperands_ - 1);
return numArgs_;
}
size_t spIncrement() const {
return spIncrement_;
}
};
// The asm.js version doesn't use the bail mechanism: instead it throws and
// exception by jumping to the given label.
class MAsmJSCheckOverRecursed : public MNullaryInstruction
{
Label *onError_;
MAsmJSCheckOverRecursed(Label *onError) : onError_(onError) {}
public:
INSTRUCTION_HEADER(AsmJSCheckOverRecursed);
static MAsmJSCheckOverRecursed *New(Label *onError) { return new MAsmJSCheckOverRecursed(onError); }
Label *onError() const { return onError_; }
};
#undef INSTRUCTION_HEADER
// Implement opcode casts now that the compiler can see the inheritance.
#define OPCODE_CASTS(opcode) \
M##opcode *MDefinition::to##opcode() \
{ \
JS_ASSERT(is##opcode()); \
return static_cast<M##opcode *>(this); \
}
MIR_OPCODE_LIST(OPCODE_CASTS)
#undef OPCODE_CASTS
MDefinition *MNode::toDefinition()
{
JS_ASSERT(isDefinition());
return (MDefinition *)this;
}
MResumePoint *MNode::toResumePoint()
{
JS_ASSERT(isResumePoint());
return (MResumePoint *)this;
}
MInstruction *MDefinition::toInstruction()
{
JS_ASSERT(!isPhi());
return (MInstruction *)this;
}
typedef Vector<MDefinition *, 8, IonAllocPolicy> MDefinitionVector;
// Helper functions used to decide how to build MIR.
bool ElementAccessIsDenseNative(MDefinition *obj, MDefinition *id);
bool ElementAccessIsTypedArray(MDefinition *obj, MDefinition *id, int *arrayType);
bool ElementAccessIsPacked(JSContext *cx, MDefinition *obj);
bool ElementAccessHasExtraIndexedProperty(JSContext *cx, MDefinition *obj);
MIRType DenseNativeElementType(JSContext *cx, MDefinition *obj);
bool PropertyReadNeedsTypeBarrier(JSContext *cx, types::TypeObject *object, PropertyName *name,
types::StackTypeSet *observed, bool updateObserved = true);
bool PropertyReadNeedsTypeBarrier(JSContext *cx, MDefinition *obj, PropertyName *name,
types::StackTypeSet *observed);
bool PropertyReadIsIdempotent(JSContext *cx, MDefinition *obj, PropertyName *name);
void AddObjectsForPropertyRead(JSContext *cx, MDefinition *obj, PropertyName *name,
types::StackTypeSet *observed);
bool PropertyWriteNeedsTypeBarrier(JSContext *cx, MBasicBlock *current, MDefinition **pobj,
PropertyName *name, MDefinition **pvalue,
bool canModify = true);
} // namespace jit
} // namespace js
#endif /* jit_MIR_h */