gecko-dev/ef/Compiler/PrimitiveGraph/Primitives.h

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/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*-
*
* The contents of this file are subject to the Netscape Public
* License Version 1.1 (the "License"); you may not use this file
* except in compliance with the License. You may obtain a copy of
* the License at http://www.mozilla.org/NPL/
*
* Software distributed under the License is distributed on an "AS
* IS" basis, WITHOUT WARRANTY OF ANY KIND, either express or
* implied. See the License for the specific language governing
* rights and limitations under the License.
*
* The Original Code is mozilla.org code.
*
* The Initial Developer of the Original Code is Netscape
* Communications Corporation. Portions created by Netscape are
* Copyright (C) 1998 Netscape Communications Corporation. All
* Rights Reserved.
*
* Contributor(s):
*/
#ifndef PRIMITIVES_H
#define PRIMITIVES_H
#include "Value.h"
#include "DoublyLinkedList.h"
#include "VirtualRegister.h"
#include "LogModule.h"
#include "Attributes.h"
enum PrimitiveFormat
{
pfNone,
pfPhi, // Phi node
pfConst, // Constant
pfDebug, // Debug or Break
pfControl, // If condition node or switch index node
pfCatch, // Catch exception producer
pfProj, // Projection
pfArg, // Argument
pfResult, // Result
pfUnaryGeneric, // General one-argument operations
pfBinaryGeneric, // General two-argument operations
pfLd, // Ld
pfSt, // St
pfMonitor, // MEnter and MExit
pfSync, // Sync
pfSysCall, // SysCall
pfCall // Call
};
const uint nPrimitiveFormats = pfCall + 1;
enum PrimitiveCategory
{
pcNone,
pcPhi, // Phi node
pcConst, // Constant
pcDebug, // Debug or Break
pcIfCond, // If condition node
pcSwitch, // Switch index node
pcCatch, // Catch exception producer
pcProj, // Projection
pcArg, // Argument
pcResult, // Result
pcGeneric, // Two-argument integer arithmetic and logical
pcDivMod, // Div and Mod
pcShift, // Shifts
pcExt, // Ext
pcFGeneric, // Floating-point arithmetic
pcConv, // Conv
pcFConv, // FConv
pcCmp, // Cmp
pcFCmp, // FCmp
pcCond, // Cond
pcCond3, // Cond3
pcCheck1, // ChkNull
pcCheck2, // ChkCast, Limit, and LimCast
pcLd, // Ld
pcSt, // St
pcMonitor, // MEnter and MExit
pcSync, // Sync
pcSysCall, // SysCall
pcCall // Call
};
const uint nPrimitiveCategories = pcCall + 1;
extern const PrimitiveFormat categoryFormats[nPrimitiveCategories];
#include "PrimitiveOperations.h"
#ifdef DEBUG_LOG
int print(LogModuleObject &f, PrimitiveFormat pf);
int print(LogModuleObject &f, PrimitiveCategory pc);
int print(LogModuleObject &f, PrimitiveOperation pk);
#endif
// ----------------------------------------------------------------------------
class DataNode;
class ControlNode;
class ControlEdge;
class Instruction;
class VariableOrConstant
{
private:
static const DataNode constSources[nValueKinds];
protected: // (In DEBUG versions both variables below are nil if not explicitly set.)
const DataNode *source; // The referenced DataNode or (if pointing to a constant) Source
DataNode *node; // The node to which this DataConsumer belongs (used in DataConsumer only)
union {
DoublyLinkedNode links; // Links to other consumers of a non-constant value (used in DataConsumer only)
Value value; // Constant
};
public:
#ifdef DEBUG
VariableOrConstant() {source = 0;}
#endif
bool operator==(const VariableOrConstant &poc2) const;
bool operator!=(const VariableOrConstant &poc2) const {return !(*this == poc2);}
bool isImmediate() const {return false;}
bool hasKind(ValueKind kind) const;
ValueKind getKind() const;
inline bool isConstant() const;
inline bool isVariable() const;
DataNode &getVariable() const;
inline const Value &getConstant() const;
inline Value &getConstant();
bool isAlwaysNonzero() const;
Type *getDynamicType() const;
void setConstant(Int32 v);
void setConstant(Int64 v);
void setConstant(Flt32 v);
void setConstant(Flt64 v);
void setConstant(addr v);
void setConstant(Condition v);
void setConstant(Memory v);
void setConstant(ValueKind kind, const Value &v);
void setVariable(DataNode &producer);
};
// A DataConsumer is like a VariableOrConstant except that it belongs to some (consumer) DataNode.
// Also, if the DataConsumer is a variable, it is linked into the source (producer) DataNode's
// doubly-linked list of consumers.
// If the DataConsumer currently contains a variable, do not change its source (for example by
// using either setConstant or setVariable). Instead, call either clearVariable or destroy
// first and then call setConstant or setVariable, thus making sure that the DataNodes' lists
// of consumers are kept consistent. In DEBUG versions asserts will enforce this rule.
class DataConsumer: public VariableOrConstant
{
#ifdef DEBUG
public:
DataConsumer() {node = 0;}
private:
DataConsumer(const DataConsumer &); // Copying forbidden
void operator=(const DataConsumer &); // Copying forbidden
#endif
public:
void operator=(const VariableOrConstant &p);
void move(DataConsumer &src);
void destroy();
DataNode &getNode() const {assert(node); return *node;}
void setNode(DataNode &n) {node = &n;}
#ifdef DEBUG
void setConstant(Int32 v);
void setConstant(Int64 v);
void setConstant(Flt32 v);
void setConstant(Flt64 v);
void setConstant(addr v);
void setConstant(Condition v);
void setConstant(Memory v);
void setConstant(ValueKind kind, const Value &v);
#endif
void setVariable(DataNode &producer);
inline void clearVariable();
void clear() {if (isVariable()) clearVariable();}
// DoublyLinkedNode administration
static DataConsumer &linkOwner(DoublyLinkedNode &l) {return *(DataConsumer *)((char *)&l - offsetof(DataConsumer, links));}
DoublyLinkedNode &getLinks() {return links;}
#ifdef DEBUG_LOG
int printRef(LogModuleObject &f) const;
#endif
};
inline bool isIfCond(PrimitiveOperation op) {return op >= poIfLt && op <= poIfUGe;}
inline bool isCond2(PrimitiveOperation op) {return op >= poLt_I && op <= poUGe_I;}
inline bool isCond3(PrimitiveOperation op) {return op >= poCatL_I && op <= poCatCG_I;}
inline Condition2 ifCondToCondition2(PrimitiveOperation op) {assert(isIfCond(op)); return (Condition2)(op - poIfLt + condLt);}
inline Condition2 cond2ToCondition2(PrimitiveOperation op) {assert(isCond2(op)); return (Condition2)(op - poLt_I + condLt);}
inline Condition3 cond3ToCondition3(PrimitiveOperation op) {assert(isCond3(op)); return (Condition3)(op - poCatL_I);}
inline PrimitiveOperation condition2ToIfCond(Condition2 cond2) {return (PrimitiveOperation)(cond2 - condLt + poIfLt);}
inline PrimitiveOperation condition2ToCond2(Condition2 cond2) {return (PrimitiveOperation)(cond2 - condLt + poLt_I);}
inline PrimitiveOperation condition3ToCond3(Condition3 cond3) {return (PrimitiveOperation)(cond3 + poCatL_I);}
DataNode *partialComputeComparison(Condition2 cond2, VariableOrConstant c, bool &result);
// ----------------------------------------------------------------------------
extern Uint16 gCurLineNumber; // debug get line number info
class DataNode
{
ValueKind kind ENUM_8; // Kind of the constant or the data node's outgoing data edge
bool constant BOOL_8; // True if this value is a constant (held inside the DataConsumer)
enum DataNodeFlag
{
dnIsReal, // This primitive can be created (as opposed to, say, poNone, which cannot)
dnCanRaiseException, // This primitive can raise an exception
dnIsRoot // This primitive feeds a control node, so it should't be deleted just because its data
}; // output is dead.
struct Template
{
PrimitiveOperation operation ENUM_16; // Minor kind of primitive
PrimitiveCategory category ENUM_8; // Major kind of primitive
ValueKind kind ENUM_8; // Kind of the constant or the data node's outgoing data edge
Uint16 flags; // DataNodeFlags
};
static const Template templates[nPrimitiveOperations];
#ifdef DEBUG
public:
enum Origin {aoVariable, aoConstant, aoEither};
struct InputConstraint
{
ValueKind kind ENUM_8; // Kinds of an input. vkVoid means "any kind".
Origin origin ENUM_8; // Can the input be a variable, a constant, or either?
};
private:
struct InputConstraintPattern
{
const InputConstraint *inputConstraints;// Constraints on the inputs.
Uint8 nInputConstraints; // Number of inputs (repeat input counts here as one input)
bool repeat BOOL_8; // If true, the last input can be repeated zero or more times
};
static const InputConstraintPattern inputConstraintPatterns[nPrimitiveOperations];
#endif
PrimitiveOperation operation ENUM_16; // Minor kind of primitive
PrimitiveCategory category ENUM_8; // Major kind of primitive
bool alwaysNonzero BOOL_8; // If true, the value of this DataNode is known to always be nonzero
Uint16 flags; // DataNodeFlags
DoublyLinkedList<DataConsumer> consumers; // List of consumers of data produced by this DataNode
protected:
ControlNode *container; // The ControlNode that contains this DataNode or nil if none
DataConsumer *inputsBegin; // Array of incoming data flow edges
DataConsumer *inputsEnd; // Last element + 1
Uint16 lineNumber; // Java source line number
public:
Uint32 producerNumber; // Serial number assigned and used by the register allocator and pretty-printer
IntervalMapping *mapping; // The localVariable
// corresponding to the
// mapping
private:
struct _annotation
{
VirtualRegisterPtr lowVReg;
VirtualRegisterPtr highVReg;
Instruction *insn;
} annotation;
#ifdef DEBUG
// make sure we do not incorrectly use annotations
enum AnnotationKind {anNone, anInsn, anVr};
AnnotationKind annotationKind;
#endif
protected:
explicit DataNode(PrimitiveOperation op);
void destroy();
public:
DataNode(ValueKind kind) : kind(kind), constant(true) {};
virtual ~DataNode() {};
// Use these instead of expressions like "getFormat() == pfLd" because the latter doesn't do
// type checking -- the compiler will happily let you make errors like "getFormat() == pcLd".
inline bool isConstant() const {return constant;}
inline bool isVariable() const {return !constant;}
bool hasKind(ValueKind k) const {return k == kind;}
bool hasFormat(PrimitiveFormat f) const {return f == categoryFormats[category];}
bool hasCategory(PrimitiveCategory c) const {return c == category;}
bool hasOperation(PrimitiveOperation op) const {return op == operation;}
ValueKind getKind() const {return kind;}
PrimitiveFormat getFormat() const {return categoryFormats[category];}
PrimitiveCategory getCategory() const {return category;}
PrimitiveOperation getOperation() const {return operation;}
void setOperation(PrimitiveOperation op);
// Flag queries
bool isReal() const {return flags>>dnIsReal & 1;}
bool canRaiseException() const {return flags>>dnCanRaiseException & 1;}
bool isRoot() const {return flags>>dnIsRoot & 1;}
bool producesVariable() const {return !isVoidKind(kind);}
bool isAlwaysNonzero() const {return alwaysNonzero;}
void setAlwaysNonzero(bool nz) {alwaysNonzero = nz;}
bool hasConsumers() const {return !consumers.empty();}
const DoublyLinkedList<DataConsumer> &getConsumers() const {return consumers;}
void addConsumer(DataConsumer &consumer) {consumers.addLast(consumer);}
ControlNode *getContainer() const {return container;}
void setContainer(ControlNode *c) {assert(!container); container = c;} // For use by ControlNode only.
// see also changeContainer in PhiNode and Primitive.
Uint32 nInputs() const {return inputsEnd - inputsBegin;}
DataConsumer *getInputsBegin() const {return inputsBegin;}
DataConsumer *getInputsEnd() const {return inputsEnd;}
DataConsumer &nthInput(Uint32 n) const {assert(n < nInputs()); return inputsBegin[n];}
bool nthInputIsConstant(Uint32 n) const {return nthInput(n).isConstant();}
DataNode &nthInputVariable(Uint32 n) const;
bool isSignedCompare() const;
Value &nthInputConstant(Uint32 n) const {return nthInput(n).getConstant();}
Uint16 getLineNumber() const {return lineNumber;}
void setLineNumber(Uint16 lineNumber) {DataNode::lineNumber = lineNumber;}
inline void annotate(Instruction& insn);
inline void annotate(VirtualRegister& vReg, VRClass cl);
inline void annotateLow(VirtualRegister& vReg, VRClass cl);
inline void annotateHigh(VirtualRegister& vReg, VRClass cl);
inline void annotate(VirtualRegister& lowVReg, VirtualRegister& highVReg, VRClass cl);
inline VirtualRegister* getVirtualRegisterAnnotation();
inline VirtualRegister* getLowVirtualRegisterAnnotation();
inline VirtualRegister* getHighVirtualRegisterAnnotation();
inline VirtualRegisterPtr& getVirtualRegisterPtrAnnotation();
inline VirtualRegisterPtr& getLowVirtualRegisterPtrAnnotation();
inline VirtualRegisterPtr& getHighVirtualRegisterPtrAnnotation();
inline Instruction* getInstructionAnnotation();
Uint32 assignProducerNumbers(Uint32 base);
virtual void setInstructionRoot(Instruction* /*inInstructionRoot*/) {}
virtual Instruction* getInstructionRoot() {return NULL;}
#ifdef DEBUG
virtual void validate(); // perform self-consistency checks
InputConstraintPattern getInputConstraintPattern() { return inputConstraintPatterns[getOperation()]; }
bool mark BOOL_8; // marks this primitive as having been seen during an ordered search
#endif
#ifdef DEBUG_LOG
protected:
virtual void printOutgoing(LogModuleObject &f) const;
virtual void printIncoming(LogModuleObject &f) const;
public:
int printRef(LogModuleObject &f) const;
void printPretty(LogModuleObject &f, int margin) const;
#endif
#if 1
// HACK! These are temporary stubs and will go away soon.
DataNode *getOutgoingEdgesBegin() {return this;}
DataNode *getOutgoingEdgesEnd() {return this + producesVariable();}
#endif
};
class PhiNode: public DataNode, public DoublyLinkedEntry<PhiNode> // Links to other PhiNodes in the same ControlNode
{
DataConsumer *inputsLimit; // Pointer past last entry allocated in the inputsBegin array
// (may include extra slop after inputsEnd)
public:
PhiNode(Uint32 nExpectedInputs, ValueKind kind, Pool &pool);
void destroy();
static PhiNode &cast(DataNode &node)
{assert(node.getFormat() == pfPhi); return *static_cast<PhiNode *>(&node);}
void clearContainer() {assert(container); remove(); container = 0;}
void changeContainer(ControlNode *c) {assert(container); remove(); container = c;} // For use by ControlNode only.
void addInput(DataNode &producer, Pool &pool);
void removeSomeInputs(Function2<bool, DataConsumer &, ControlEdge &> &f);
};
class Primitive: public DataNode, public DoublyLinkedEntry<Primitive> // Links to other Primitives in the same ControlNode
{
protected:
Instruction *instructionRoot; // Instructions which creates this primitive if no outputs
Uint16 burgState; // BURG state given to this node
Uint16 lineNumber; // corresponds to src line#
Uint32 bytecodeIndex; // Bytecode Index
Uint16 debugLineNumber; // contains value >= lineNumber of all children (during InstructionScheduling)
public:
explicit Primitive(PrimitiveOperation op, Uint32 bci);
void destroy();
static Primitive &cast(DataNode &node)
{assert(node.getFormat() >= pfConst); return *static_cast<Primitive *>(&node);}
void clearContainer() {assert(container); remove(); container = 0;}
void changeContainer(ControlNode *c) {assert(container); remove(); container = c;} // For use by ControlNode only.
Uint16 getBurgState() const { return burgState;}
Uint16* getBurgStatePtr() { return &burgState; }
Uint16 setBurgState(Uint16 newState) {burgState = newState; return newState;}
Uint16 getLineNumber() {return lineNumber;}
Uint16 setLineNumber(Uint16 newLineNumber) {lineNumber = newLineNumber; return lineNumber;}
Uint16 getDebugLineNumber() {return debugLineNumber;}
Uint16 setDebugLineNumber(Uint16 newDebugLineNumber) {debugLineNumber = newDebugLineNumber; return debugLineNumber;}
Uint32 getBytecodeIndex() {return bytecodeIndex;}
void setBytecodeIndex(Uint32 bci) {bytecodeIndex = bci;};
void setInstructionRoot(Instruction* inInstructionRoot) {instructionRoot = inInstructionRoot;}
Instruction* getInstructionRoot() {return instructionRoot;}
};
// --- PRIVATE ----------------------------------------------------------------
// A primitive that has no incoming edges
class Primitive0: public Primitive
{
protected:
explicit Primitive0(PrimitiveOperation op, Uint32 bci);
};
// A primitive that has one incoming edge
class Primitive1: public Primitive
{
protected:
DataConsumer input; // Incoming data edge
explicit Primitive1(PrimitiveOperation op, Uint32 bci);
public:
DataConsumer &getInput() {return input;}
};
// A primitive that has two incoming edges
class Primitive2: public Primitive
{
protected:
DataConsumer inputs[2]; // Incoming data edges
explicit Primitive2(PrimitiveOperation op, Uint32 bci);
public:
DataConsumer *getInputs() {return inputs;}
};
// --- PUBLIC -----------------------------------------------------------------
// Lone constants
class PrimConst: public Primitive0
{
public:
const Value value;
PrimConst(ValueKind vk, const Value &value, Uint32 bci);
static PrimConst &cast(DataNode &node)
{assert(node.hasFormat(pfConst)); return *static_cast<PrimConst *>(&node);}
#ifdef DEBUG
void validate(); // perform self-consistency checks
#endif
#ifdef DEBUG_LOG
protected:
virtual void printIncoming(LogModuleObject &f) const;
#endif
};
enum TupleComponent
{
tcMemory = 0, // Outgoing memory edge
tcValue = 1, // Value returned from a volatile load
tcFirstResult = 1, // Component number of first result from a call or system call; subsequent results, if any,
// have TupleComponent numbers starting from 2.
tcMAX = 0x80000000 // (dummy value to force TupleComponent to be 32 bits wide)
};
// Projections of tuple values into their components
class PrimProj: public Primitive1
{
public:
const TupleComponent component; // Number that indicates which component we're getting from the tuple
PrimProj(PrimitiveOperation op, TupleComponent component,
bool alwaysNonzero, Uint32 bci);
PrimProj(ValueKind vk, TupleComponent component, bool alwaysNonzero,
Uint32 bci);
static PrimProj &cast(DataNode &node)
{assert(node.hasFormat(pfProj)); return *static_cast<PrimProj *>(&node);}
#ifdef DEBUG_LOG
protected:
virtual void printIncoming(LogModuleObject &f) const;
#endif
};
// Incoming function arguments
class PrimArg: public Primitive0
{
public:
PrimArg();
void initOutgoingEdge(ValueKind vk, bool alwaysNonzero);
static PrimArg &cast(DataNode &node)
{assert(node.hasFormat(pfArg)); return *static_cast<PrimArg *>(&node);}
#ifdef DEBUG_LOG
protected:
virtual void printIncoming(LogModuleObject &f) const;
#endif
};
// Outgoing function results
class PrimResult: public Primitive1
{
public:
explicit PrimResult(Uint32 bci, ValueKind vk = vkMemory);
void setResultKind(ValueKind vk);
static PrimResult &cast(DataNode &node)
{assert(node.hasFormat(pfResult)); return *static_cast<PrimResult *>(&node);}
#ifdef DEBUG_LOG
protected:
virtual void printOutgoing(LogModuleObject &f) const;
#endif
};
// Anchor primitives for linking if and switch inputs to their control nodes;
class PrimControl: public Primitive1
{
public:
explicit PrimControl(PrimitiveOperation op, Uint32 bci);
static PrimControl &cast(DataNode &node)
{assert(node.hasFormat(pfControl)); return *static_cast<PrimControl *>(&node);}
};
// Caught exceptions
class PrimCatch: public Primitive0
{
public:
PrimCatch(Uint32 bci);
static PrimCatch &cast(DataNode &node)
{assert(node.hasFormat(pfCatch)); return *static_cast<PrimCatch *>(&node);}
};
// Unary arithmetic and logical primitives
class PrimUnaryGeneric: public Primitive1
{
public:
explicit PrimUnaryGeneric(PrimitiveOperation op, Uint32 bci,
bool alwaysNonzero = false);
static PrimUnaryGeneric &cast(DataNode &node)
{assert(node.hasFormat(pfUnaryGeneric)); return *static_cast<PrimUnaryGeneric *>(&node);}
};
// Binary arithmetic and logical primitives, including Div and Mod
class PrimBinaryGeneric: public Primitive2
{
public:
explicit PrimBinaryGeneric(PrimitiveOperation op, Uint32 bci,
bool alwaysNonzero = false);
static PrimBinaryGeneric &cast(DataNode &node)
{assert(node.hasFormat(pfBinaryGeneric)); return *static_cast<PrimBinaryGeneric *>(&node);}
};
// Memory read primitives
class PrimLoad: public Primitive2
{
protected:
bool hasOutgoingMemory; // True if this is a volatile load
public:
PrimLoad(PrimitiveOperation op, bool hasOutgoingMemory, Uint32 bci);
static PrimLoad &cast(DataNode &node)
{assert(node.hasFormat(pfLd)); return *static_cast<PrimLoad *>(&node);}
DataConsumer &getIncomingMemory() {return inputs[0];}
DataConsumer &getAddress() {return inputs[1];}
};
// Memory write primitives
class PrimStore: public Primitive
{
protected:
DataConsumer inputs[3]; // Incoming data edges (memory, address, and data)
public:
explicit PrimStore(PrimitiveOperation op, Uint32 bci);
static PrimStore &cast(DataNode &node)
{assert(node.hasFormat(pfSt)); return *static_cast<PrimStore *>(&node);}
DataConsumer &getIncomingMemory() {return inputs[0];}
DataConsumer &getAddress() {return inputs[1];}
DataConsumer &getData() {return inputs[2];}
};
// Monitor access primitives
class PrimMonitor: public Primitive2
{
Uint32 slot; // Index of stack slot for the saved subheader
public:
enum {unknownSlot = (Uint32)-1}; // Value to store in slot if not known yet
PrimMonitor(PrimitiveOperation op, Uint32 slot, Uint32 bci);
static PrimMonitor &cast(DataNode &node)
{assert(node.hasFormat(pfMonitor)); return *static_cast<PrimMonitor *>(&node);}
DataConsumer &getIncomingMemory() {return inputs[0];}
DataConsumer &getMonitor() {return inputs[1];}
Uint32 getSlot() const {assert(slot != unknownSlot); return slot;}
};
// Memory synchronization point primitives
class PrimSync: public Primitive0
{
public:
PrimSync(Uint32 bci);
static PrimSync &cast(DataNode &node)
{assert(node.hasFormat(pfSync)); return *static_cast<PrimSync *>(&node);}
};
struct SysCall;
// System call primitives
class PrimSysCall: public Primitive
{
public:
const SysCall &sysCall; // The type of system call represented here
PrimSysCall(const SysCall &sysCall, Pool &pool, Uint32 bci);
static PrimSysCall &cast(DataNode &node)
{assert(node.hasFormat(pfSysCall)); return *static_cast<PrimSysCall *>(&node);}
#ifdef DEBUG_LOG
protected:
virtual void printIncoming(LogModuleObject &f) const;
#endif
};
// Function call primitives
class PrimCall: public Primitive
{
public:
const uint nArguments; // Number of arguments in this call (does not include the function or memory edges)
const uint nResults; // Number of results in this call (does not include the outgoing memory edge)
const Method *const method; // The Method being called or nil if not known
PrimCall(PrimitiveOperation op, const Method *method, uint nArguments,
uint nResults, Pool &pool, Uint32 bci);
static PrimCall &cast(DataNode &node)
{assert(node.hasFormat(pfCall)); return *static_cast<PrimCall *>(&node);}
DataConsumer &getIncomingMemory() {return inputsBegin[0];}
DataConsumer &getFunction() {return inputsBegin[1];}
DataConsumer *getArguments() {return inputsBegin + 2;}
#ifdef DEBUG_LOG
protected:
virtual void printIncoming(LogModuleObject &f) const;
#endif
};
// --- INLINES ----------------------------------------------------------------
inline bool VariableOrConstant::hasKind(ValueKind kind) const {assert(source); return source->hasKind(kind);}
inline ValueKind VariableOrConstant::getKind() const {assert(source); return source->getKind();}
inline bool VariableOrConstant::isConstant() const {assert(source); return source->isConstant();}
inline bool VariableOrConstant::isVariable() const {assert(source); return source->isVariable();}
inline const Value &VariableOrConstant::getConstant() const {assert(source && source->isConstant()); return value;}
inline Value &VariableOrConstant::getConstant() {assert(source && source->isConstant()); return value;}
inline void VariableOrConstant::setConstant(Int32 v) {source = constSources + vkInt; value.i = v;}
inline void VariableOrConstant::setConstant(Int64 v) {source = constSources + vkLong; value.l = v;}
inline void VariableOrConstant::setConstant(Flt32 v) {source = constSources + vkFloat; value.f = v;}
inline void VariableOrConstant::setConstant(Flt64 v) {source = constSources + vkDouble; value.d = v;}
inline void VariableOrConstant::setConstant(addr v) {source = constSources + vkAddr; value.a = v;}
inline void VariableOrConstant::setConstant(Condition v) {source = constSources + vkCond; value.c = v;}
inline void VariableOrConstant::setConstant(Memory v) {source = constSources + vkMemory; value.m = v;}
inline void VariableOrConstant::setConstant(ValueKind kind, const Value &v) {source = constSources + kind; value = v;}
//
// Return the producer linked to this VariableOrConstant or DataConsumer.
//
inline DataNode &VariableOrConstant::getVariable() const
{
assert(source && source->isVariable());
return *const_cast<DataNode *>(source);
}
//
// If known, return the actual type of the object produced by this VariableOrConstant.
// If not known, return nil.
// The returned type is the most specific type of the object, not a conservative statically
// computed bound.
// Currently this method works only on VariableOrConstants of kind vkAddr.
//
inline Type *VariableOrConstant::getDynamicType() const
{
assert(hasKind(vkAddr));
// For now, don't infer types of non-constants.
return isConstant() ? objectAddressType(value.a) : 0;
}
//
// Set this VariableOrConstant to represent the given producer.
//
inline void VariableOrConstant::setVariable(DataNode &producer)
{
source = &producer;
links.init();
}
// ----------------------------------------------------------------------------
#ifdef DEBUG
inline void DataConsumer::setConstant(Int32 v) {assert(!(source && source->isVariable())); VariableOrConstant::setConstant(v);}
inline void DataConsumer::setConstant(Int64 v) {assert(!(source && source->isVariable())); VariableOrConstant::setConstant(v);}
inline void DataConsumer::setConstant(Flt32 v) {assert(!(source && source->isVariable())); VariableOrConstant::setConstant(v);}
inline void DataConsumer::setConstant(Flt64 v) {assert(!(source && source->isVariable())); VariableOrConstant::setConstant(v);}
inline void DataConsumer::setConstant(addr v) {assert(!(source && source->isVariable())); VariableOrConstant::setConstant(v);}
inline void DataConsumer::setConstant(Condition v) {assert(!(source && source->isVariable())); VariableOrConstant::setConstant(v);}
inline void DataConsumer::setConstant(Memory v) {assert(!(source && source->isVariable())); VariableOrConstant::setConstant(v);}
inline void DataConsumer::setConstant(ValueKind kind, const Value &v) {assert(!(source && source->isVariable())); VariableOrConstant::setConstant(kind, v);}
#endif
inline void DataConsumer::clearVariable() {assert(source && source->isVariable()); links.remove(); DEBUG_ONLY(source = 0);}
//
// Destroy this DataConsumer, which must have been initialized. This DataConsumer
// is unlinked from any linked lists to which it belonged and left uninitialized.
//
inline void DataConsumer::destroy()
{
if (isVariable())
links.remove();
#ifdef DEBUG
source = 0;
node = 0;
#endif
}
//
// Link the DataConsumer located to the given, non-constant source.
//
inline void DataConsumer::setVariable(DataNode &producer)
{
assert(!(source && source->isVariable()));
VariableOrConstant::setVariable(producer);
producer.addConsumer(*this);
}
// ----------------------------------------------------------------------------
//
// Initialize this DataNode, which will contain a primitive or phi node with
// the given operation.
//
inline DataNode::DataNode(PrimitiveOperation op)
{
const Template &t = templates[op];
kind = t.kind;
constant = false;
operation = t.operation;
category = t.category;
alwaysNonzero = false;
flags = t.flags;
container = 0;
mapping = 0;
assert(isReal());
#ifdef DEBUG
producerNumber = (Uint32)-1;
annotationKind = anNone;
#endif
annotation.insn = NULL;
lineNumber = gCurLineNumber++;
}
//
// Change the operation of a DataNode to the given operation.
// A DataNode's operation can only be changed within the same category.
//
inline void DataNode::setOperation(PrimitiveOperation op)
{
const Template &t = templates[op];
assert(hasCategory(t.category));
kind = t.kind;
operation = t.operation;
alwaysNonzero = false;
flags = t.flags;
}
//
// Return the nth input, which must be a variable.
//
inline DataNode &DataNode::nthInputVariable(Uint32 n) const
{
return nthInput(n).getVariable();
}
inline void DataNode::annotate(Instruction& insn)
{
annotation.insn = &insn;
DEBUG_ONLY(annotationKind = anInsn);
}
inline void DataNode::annotateLow(VirtualRegister& vReg, VRClass cl)
{
annotation.lowVReg.initialize(vReg, cl);
DEBUG_ONLY(annotationKind = anVr);
#ifdef DEBUG
vReg.isAnnotated = true;
if (vReg.isPreColored())
trespass("This is not a temporary register. It cannot be preColored. !!!");
#endif
}
inline void DataNode::annotateHigh(VirtualRegister& vReg, VRClass cl)
{
annotation.highVReg.initialize(vReg, cl);
DEBUG_ONLY(annotationKind = anVr);
#ifdef DEBUG
vReg.isAnnotated = true;
if (vReg.isPreColored())
trespass("This is not a temporary register. It cannot be preColored. !!!");
#endif
}
inline void DataNode::annotate(VirtualRegister& vReg, VRClass cl) {annotateLow(vReg, cl);}
inline void DataNode::annotate(VirtualRegister& lowVReg, VirtualRegister& highVReg, VRClass cl)
{
annotation.lowVReg.initialize(lowVReg, cl);
annotation.highVReg.initialize(highVReg, cl);
DEBUG_ONLY(annotationKind = anVr);
#ifdef DEBUG
lowVReg.isAnnotated = true;
highVReg.isAnnotated = true;
if (lowVReg.isPreColored() || highVReg.isPreColored())
trespass("This is not a temporary register. It cannot be preColored. !!!");
#endif
}
inline VirtualRegister* DataNode::getLowVirtualRegisterAnnotation()
{
assert(annotationKind == anNone || annotationKind == anVr);
VirtualRegisterPtr& vRegPtr = annotation.lowVReg;
if (vRegPtr.isInitialized())
return &vRegPtr.getVirtualRegister();
else
return 0;
}
inline VirtualRegister* DataNode::getVirtualRegisterAnnotation() {return getLowVirtualRegisterAnnotation();}
inline VirtualRegister* DataNode::getHighVirtualRegisterAnnotation()
{
assert(annotationKind == anNone || annotationKind == anVr);
VirtualRegisterPtr& vRegPtr = annotation.highVReg;
if (vRegPtr.isInitialized())
return &vRegPtr.getVirtualRegister();
else
return 0;
}
inline VirtualRegisterPtr& DataNode::getLowVirtualRegisterPtrAnnotation()
{
assert(annotationKind == anNone || annotationKind == anVr);
return annotation.lowVReg;
}
inline VirtualRegisterPtr& DataNode::getHighVirtualRegisterPtrAnnotation()
{
assert(annotationKind == anNone || annotationKind == anVr);
return annotation.highVReg;
}
inline VirtualRegisterPtr& DataNode::getVirtualRegisterPtrAnnotation() {return getLowVirtualRegisterPtrAnnotation();}
inline Instruction* DataNode::getInstructionAnnotation()
{
assert(annotationKind == anNone || annotationKind == anInsn);
return (annotation.insn);
}
// ----------------------------------------------------------------------------
//
// Initialize a primitive with the given operation.
// The caller then has to connect the inputs to other data flow nodes.
//
inline Primitive::Primitive(PrimitiveOperation op, Uint32 bci):
DataNode(op),
instructionRoot(0),
bytecodeIndex(bci),
debugLineNumber(0)
{}
//
// Initialize a no-input primitive with the given operation.
//
inline Primitive0::Primitive0(PrimitiveOperation op, Uint32 bci)
: Primitive(op, bci)
{
inputsBegin = 0;
inputsEnd = 0;
}
//
// Initialize a one-input primitive with the given operation.
// The caller then has to connect the input to another data flow node.
//
inline Primitive1::Primitive1(PrimitiveOperation op, Uint32 bci)
: Primitive(op, bci)
{
inputsBegin = &input;
inputsEnd = &input + 1;
input.setNode(*this);
}
//
// Initialize a two-input primitive with the given operation.
// The caller then has to connect the inputs to other data flow nodes.
//
inline Primitive2::Primitive2(PrimitiveOperation op, Uint32 bci)
: Primitive(op, bci)
{
inputsBegin = inputs;
inputsEnd = inputs + 2;
inputs[0].setNode(*this);
inputs[1].setNode(*this);
}
//
// Change the value kind of the PrimResult.
//
inline void PrimResult::setResultKind(ValueKind vk)
{
assert(isStorableKind(vk) || isMemoryKind(vk));
setOperation((PrimitiveOperation)(poResult_I + vk - vkInt));
}
#endif