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/*
* Copyright (C) 2008 Apple Inc. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#include "JIT.h"
#if ENABLE(JIT)
#include "CodeBlock.h"
#include "JITInlineMethods.h"
#include "JITStubCall.h"
#include "JSArray.h"
#include "JSFunction.h"
#include "Interpreter.h"
#include "ResultType.h"
#include "SamplingTool.h"
#ifndef NDEBUG
#include <stdio.h>
#endif
using namespace std;
namespace JSC {
#if USE(JSVALUE32_64)
void JIT::compileOpCallInitializeCallFrame()
{
// regT0 holds callee, regT1 holds argCount
store32(regT1, Address(callFrameRegister, RegisterFile::ArgumentCount * static_cast<int>(sizeof(Register))));
loadPtr(Address(regT0, OBJECT_OFFSETOF(JSFunction, m_data) + OBJECT_OFFSETOF(ScopeChain, m_node)), regT1); // scopeChain
emitStore(static_cast<unsigned>(RegisterFile::OptionalCalleeArguments), JSValue());
storePtr(regT0, Address(callFrameRegister, RegisterFile::Callee * static_cast<int>(sizeof(Register)))); // callee
storePtr(regT1, Address(callFrameRegister, RegisterFile::ScopeChain * static_cast<int>(sizeof(Register)))); // scopeChain
}
void JIT::compileOpCallSetupArgs(Instruction* instruction)
{
int argCount = instruction[3].u.operand;
int registerOffset = instruction[4].u.operand;
emitPutJITStubArg(regT1, regT0, 0);
emitPutJITStubArgConstant(registerOffset, 1);
emitPutJITStubArgConstant(argCount, 2);
}
void JIT::compileOpConstructSetupArgs(Instruction* instruction)
{
int argCount = instruction[3].u.operand;
int registerOffset = instruction[4].u.operand;
int proto = instruction[5].u.operand;
int thisRegister = instruction[6].u.operand;
emitPutJITStubArg(regT1, regT0, 0);
emitPutJITStubArgConstant(registerOffset, 1);
emitPutJITStubArgConstant(argCount, 2);
emitPutJITStubArgFromVirtualRegister(proto, 3, regT2, regT3);
emitPutJITStubArgConstant(thisRegister, 4);
}
void JIT::compileOpCallVarargsSetupArgs(Instruction*)
{
emitPutJITStubArg(regT1, regT0, 0);
emitPutJITStubArg(regT3, 1); // registerOffset
emitPutJITStubArg(regT2, 2); // argCount
}
void JIT::compileOpCallVarargs(Instruction* instruction)
{
int dst = instruction[1].u.operand;
int callee = instruction[2].u.operand;
int argCountRegister = instruction[3].u.operand;
int registerOffset = instruction[4].u.operand;
emitLoad(callee, regT1, regT0);
emitLoadPayload(argCountRegister, regT2); // argCount
addPtr(Imm32(registerOffset), regT2, regT3); // registerOffset
compileOpCallVarargsSetupArgs(instruction);
emitJumpSlowCaseIfNotJSCell(callee, regT1);
addSlowCase(branchPtr(NotEqual, Address(regT0), ImmPtr(m_globalData->jsFunctionVPtr)));
// Speculatively roll the callframe, assuming argCount will match the arity.
mul32(Imm32(sizeof(Register)), regT3, regT3);
addPtr(callFrameRegister, regT3);
storePtr(callFrameRegister, Address(regT3, RegisterFile::CallerFrame * static_cast<int>(sizeof(Register))));
move(regT3, callFrameRegister);
move(regT2, regT1); // argCount
emitNakedCall(m_globalData->jitStubs.ctiVirtualCall());
emitStore(dst, regT1, regT0);
sampleCodeBlock(m_codeBlock);
}
void JIT::compileOpCallVarargsSlowCase(Instruction* instruction, Vector<SlowCaseEntry>::iterator& iter)
{
int dst = instruction[1].u.operand;
int callee = instruction[2].u.operand;
linkSlowCaseIfNotJSCell(iter, callee);
linkSlowCase(iter);
JITStubCall stubCall(this, cti_op_call_NotJSFunction);
stubCall.call(dst); // In the interpreter, the callee puts the return value in dst.
map(m_bytecodeIndex + OPCODE_LENGTH(op_call_varargs), dst, regT1, regT0);
sampleCodeBlock(m_codeBlock);
}
void JIT::emit_op_ret(Instruction* currentInstruction)
{
unsigned dst = currentInstruction[1].u.operand;
// We could JIT generate the deref, only calling out to C when the refcount hits zero.
if (m_codeBlock->needsFullScopeChain())
JITStubCall(this, cti_op_ret_scopeChain).call();
emitLoad(dst, regT1, regT0);
emitGetFromCallFrameHeaderPtr(RegisterFile::ReturnPC, regT2);
emitGetFromCallFrameHeaderPtr(RegisterFile::CallerFrame, callFrameRegister);
restoreReturnAddressBeforeReturn(regT2);
ret();
}
void JIT::emit_op_construct_verify(Instruction* currentInstruction)
{
unsigned dst = currentInstruction[1].u.operand;
emitLoad(dst, regT1, regT0);
addSlowCase(branch32(NotEqual, regT1, Imm32(JSValue::CellTag)));
loadPtr(Address(regT0, OBJECT_OFFSETOF(JSCell, m_structure)), regT2);
addSlowCase(branch32(NotEqual, Address(regT2, OBJECT_OFFSETOF(Structure, m_typeInfo) + OBJECT_OFFSETOF(TypeInfo, m_type)), Imm32(ObjectType)));
}
void JIT::emitSlow_op_construct_verify(Instruction* currentInstruction, Vector<SlowCaseEntry>::iterator& iter)
{
unsigned dst = currentInstruction[1].u.operand;
unsigned src = currentInstruction[2].u.operand;
linkSlowCase(iter);
linkSlowCase(iter);
emitLoad(src, regT1, regT0);
emitStore(dst, regT1, regT0);
}
void JIT::emitSlow_op_call(Instruction* currentInstruction, Vector<SlowCaseEntry>::iterator& iter)
{
compileOpCallSlowCase(currentInstruction, iter, m_callLinkInfoIndex++, op_call);
}
void JIT::emitSlow_op_call_eval(Instruction* currentInstruction, Vector<SlowCaseEntry>::iterator& iter)
{
compileOpCallSlowCase(currentInstruction, iter, m_callLinkInfoIndex++, op_call_eval);
}
void JIT::emitSlow_op_call_varargs(Instruction* currentInstruction, Vector<SlowCaseEntry>::iterator& iter)
{
compileOpCallVarargsSlowCase(currentInstruction, iter);
}
void JIT::emitSlow_op_construct(Instruction* currentInstruction, Vector<SlowCaseEntry>::iterator& iter)
{
compileOpCallSlowCase(currentInstruction, iter, m_callLinkInfoIndex++, op_construct);
}
void JIT::emit_op_call(Instruction* currentInstruction)
{
compileOpCall(op_call, currentInstruction, m_callLinkInfoIndex++);
}
void JIT::emit_op_call_eval(Instruction* currentInstruction)
{
compileOpCall(op_call_eval, currentInstruction, m_callLinkInfoIndex++);
}
void JIT::emit_op_load_varargs(Instruction* currentInstruction)
{
int argCountDst = currentInstruction[1].u.operand;
int argsOffset = currentInstruction[2].u.operand;
JITStubCall stubCall(this, cti_op_load_varargs);
stubCall.addArgument(Imm32(argsOffset));
stubCall.call();
// Stores a naked int32 in the register file.
store32(returnValueRegister, Address(callFrameRegister, argCountDst * sizeof(Register)));
}
void JIT::emit_op_call_varargs(Instruction* currentInstruction)
{
compileOpCallVarargs(currentInstruction);
}
void JIT::emit_op_construct(Instruction* currentInstruction)
{
compileOpCall(op_construct, currentInstruction, m_callLinkInfoIndex++);
}
#if !ENABLE(JIT_OPTIMIZE_CALL)
/* ------------------------------ BEGIN: !ENABLE(JIT_OPTIMIZE_CALL) ------------------------------ */
void JIT::compileOpCall(OpcodeID opcodeID, Instruction* instruction, unsigned)
{
int dst = instruction[1].u.operand;
int callee = instruction[2].u.operand;
int argCount = instruction[3].u.operand;
int registerOffset = instruction[4].u.operand;
Jump wasEval;
if (opcodeID == op_call_eval) {
JITStubCall stubCall(this, cti_op_call_eval);
stubCall.addArgument(callee);
stubCall.addArgument(JIT::Imm32(registerOffset));
stubCall.addArgument(JIT::Imm32(argCount));
stubCall.call();
wasEval = branch32(NotEqual, regT1, Imm32(JSValue::EmptyValueTag));
}
emitLoad(callee, regT1, regT0);
if (opcodeID == op_call)
compileOpCallSetupArgs(instruction);
else if (opcodeID == op_construct)
compileOpConstructSetupArgs(instruction);
emitJumpSlowCaseIfNotJSCell(callee, regT1);
addSlowCase(branchPtr(NotEqual, Address(regT0), ImmPtr(m_globalData->jsFunctionVPtr)));
// First, in the case of a construct, allocate the new object.
if (opcodeID == op_construct) {
JITStubCall(this, cti_op_construct_JSConstruct).call(registerOffset - RegisterFile::CallFrameHeaderSize - argCount);
emitLoad(callee, regT1, regT0);
}
// Speculatively roll the callframe, assuming argCount will match the arity.
storePtr(callFrameRegister, Address(callFrameRegister, (RegisterFile::CallerFrame + registerOffset) * static_cast<int>(sizeof(Register))));
addPtr(Imm32(registerOffset * static_cast<int>(sizeof(Register))), callFrameRegister);
move(Imm32(argCount), regT1);
emitNakedCall(m_globalData->jitStubs.ctiVirtualCall());
if (opcodeID == op_call_eval)
wasEval.link(this);
emitStore(dst, regT1, regT0);
sampleCodeBlock(m_codeBlock);
}
void JIT::compileOpCallSlowCase(Instruction* instruction, Vector<SlowCaseEntry>::iterator& iter, unsigned, OpcodeID opcodeID)
{
int dst = instruction[1].u.operand;
int callee = instruction[2].u.operand;
linkSlowCaseIfNotJSCell(iter, callee);
linkSlowCase(iter);
JITStubCall stubCall(this, opcodeID == op_construct ? cti_op_construct_NotJSConstruct : cti_op_call_NotJSFunction);
stubCall.call(dst); // In the interpreter, the callee puts the return value in dst.
sampleCodeBlock(m_codeBlock);
}
#else // !ENABLE(JIT_OPTIMIZE_CALL)
/* ------------------------------ BEGIN: ENABLE(JIT_OPTIMIZE_CALL) ------------------------------ */
void JIT::compileOpCall(OpcodeID opcodeID, Instruction* instruction, unsigned callLinkInfoIndex)
{
int dst = instruction[1].u.operand;
int callee = instruction[2].u.operand;
int argCount = instruction[3].u.operand;
int registerOffset = instruction[4].u.operand;
Jump wasEval;
if (opcodeID == op_call_eval) {
JITStubCall stubCall(this, cti_op_call_eval);
stubCall.addArgument(callee);
stubCall.addArgument(JIT::Imm32(registerOffset));
stubCall.addArgument(JIT::Imm32(argCount));
stubCall.call();
wasEval = branch32(NotEqual, regT1, Imm32(JSValue::EmptyValueTag));
}
emitLoad(callee, regT1, regT0);
DataLabelPtr addressOfLinkedFunctionCheck;
Jump jumpToSlow = branchPtrWithPatch(NotEqual, regT0, addressOfLinkedFunctionCheck, ImmPtr(0));
addSlowCase(jumpToSlow);
ASSERT(differenceBetween(addressOfLinkedFunctionCheck, jumpToSlow) == patchOffsetOpCallCompareToJump);
m_callStructureStubCompilationInfo[callLinkInfoIndex].hotPathBegin = addressOfLinkedFunctionCheck;
addSlowCase(branch32(NotEqual, regT1, Imm32(JSValue::CellTag)));
// The following is the fast case, only used whan a callee can be linked.
// In the case of OpConstruct, call out to a cti_ function to create the new object.
if (opcodeID == op_construct) {
int proto = instruction[5].u.operand;
int thisRegister = instruction[6].u.operand;
JITStubCall stubCall(this, cti_op_construct_JSConstruct);
stubCall.addArgument(regT1, regT0);
stubCall.addArgument(Imm32(0)); // FIXME: Remove this unused JITStub argument.
stubCall.addArgument(Imm32(0)); // FIXME: Remove this unused JITStub argument.
stubCall.addArgument(proto);
stubCall.call(thisRegister);
emitLoad(callee, regT1, regT0);
}
// Fast version of stack frame initialization, directly relative to edi.
// Note that this omits to set up RegisterFile::CodeBlock, which is set in the callee
emitStore(registerOffset + RegisterFile::OptionalCalleeArguments, JSValue());
emitStore(registerOffset + RegisterFile::Callee, regT1, regT0);
loadPtr(Address(regT0, OBJECT_OFFSETOF(JSFunction, m_data) + OBJECT_OFFSETOF(ScopeChain, m_node)), regT1); // newScopeChain
store32(Imm32(argCount), Address(callFrameRegister, (registerOffset + RegisterFile::ArgumentCount) * static_cast<int>(sizeof(Register))));
storePtr(callFrameRegister, Address(callFrameRegister, (registerOffset + RegisterFile::CallerFrame) * static_cast<int>(sizeof(Register))));
storePtr(regT1, Address(callFrameRegister, (registerOffset + RegisterFile::ScopeChain) * static_cast<int>(sizeof(Register))));
addPtr(Imm32(registerOffset * sizeof(Register)), callFrameRegister);
// Call to the callee
m_callStructureStubCompilationInfo[callLinkInfoIndex].hotPathOther = emitNakedCall();
if (opcodeID == op_call_eval)
wasEval.link(this);
// Put the return value in dst. In the interpreter, op_ret does this.
emitStore(dst, regT1, regT0);
map(m_bytecodeIndex + opcodeLengths[opcodeID], dst, regT1, regT0);
sampleCodeBlock(m_codeBlock);
}
void JIT::compileOpCallSlowCase(Instruction* instruction, Vector<SlowCaseEntry>::iterator& iter, unsigned callLinkInfoIndex, OpcodeID opcodeID)
{
int dst = instruction[1].u.operand;
int callee = instruction[2].u.operand;
int argCount = instruction[3].u.operand;
int registerOffset = instruction[4].u.operand;
linkSlowCase(iter);
linkSlowCase(iter);
// The arguments have been set up on the hot path for op_call_eval
if (opcodeID == op_call)
compileOpCallSetupArgs(instruction);
else if (opcodeID == op_construct)
compileOpConstructSetupArgs(instruction);
// Fast check for JS function.
Jump callLinkFailNotObject = branch32(NotEqual, regT1, Imm32(JSValue::CellTag));
Jump callLinkFailNotJSFunction = branchPtr(NotEqual, Address(regT0), ImmPtr(m_globalData->jsFunctionVPtr));
// First, in the case of a construct, allocate the new object.
if (opcodeID == op_construct) {
JITStubCall(this, cti_op_construct_JSConstruct).call(registerOffset - RegisterFile::CallFrameHeaderSize - argCount);
emitLoad(callee, regT1, regT0);
}
// Speculatively roll the callframe, assuming argCount will match the arity.
storePtr(callFrameRegister, Address(callFrameRegister, (RegisterFile::CallerFrame + registerOffset) * static_cast<int>(sizeof(Register))));
addPtr(Imm32(registerOffset * static_cast<int>(sizeof(Register))), callFrameRegister);
move(Imm32(argCount), regT1);
m_callStructureStubCompilationInfo[callLinkInfoIndex].callReturnLocation = emitNakedCall(m_globalData->jitStubs.ctiVirtualCallLink());
// Put the return value in dst.
emitStore(dst, regT1, regT0);;
sampleCodeBlock(m_codeBlock);
// If not, we need an extra case in the if below!
ASSERT(OPCODE_LENGTH(op_call) == OPCODE_LENGTH(op_call_eval));
// Done! - return back to the hot path.
if (opcodeID == op_construct)
emitJumpSlowToHot(jump(), OPCODE_LENGTH(op_construct));
else
emitJumpSlowToHot(jump(), OPCODE_LENGTH(op_call));
// This handles host functions
callLinkFailNotObject.link(this);
callLinkFailNotJSFunction.link(this);
JITStubCall(this, opcodeID == op_construct ? cti_op_construct_NotJSConstruct : cti_op_call_NotJSFunction).call();
emitStore(dst, regT1, regT0);;
sampleCodeBlock(m_codeBlock);
}
/* ------------------------------ END: !ENABLE / ENABLE(JIT_OPTIMIZE_CALL) ------------------------------ */
#endif // !ENABLE(JIT_OPTIMIZE_CALL)
#else // USE(JSVALUE32_64)
void JIT::compileOpCallInitializeCallFrame()
{
store32(regT1, Address(callFrameRegister, RegisterFile::ArgumentCount * static_cast<int>(sizeof(Register))));
loadPtr(Address(regT0, OBJECT_OFFSETOF(JSFunction, m_data) + OBJECT_OFFSETOF(ScopeChain, m_node)), regT1); // newScopeChain
storePtr(ImmPtr(JSValue::encode(JSValue())), Address(callFrameRegister, RegisterFile::OptionalCalleeArguments * static_cast<int>(sizeof(Register))));
storePtr(regT0, Address(callFrameRegister, RegisterFile::Callee * static_cast<int>(sizeof(Register))));
storePtr(regT1, Address(callFrameRegister, RegisterFile::ScopeChain * static_cast<int>(sizeof(Register))));
}
void JIT::compileOpCallSetupArgs(Instruction* instruction)
{
int argCount = instruction[3].u.operand;
int registerOffset = instruction[4].u.operand;
// ecx holds func
emitPutJITStubArg(regT0, 0);
emitPutJITStubArgConstant(argCount, 2);
emitPutJITStubArgConstant(registerOffset, 1);
}
void JIT::compileOpCallVarargsSetupArgs(Instruction* instruction)
{
int registerOffset = instruction[4].u.operand;
// ecx holds func
emitPutJITStubArg(regT0, 0);
emitPutJITStubArg(regT1, 2);
addPtr(Imm32(registerOffset), regT1, regT2);
emitPutJITStubArg(regT2, 1);
}
void JIT::compileOpConstructSetupArgs(Instruction* instruction)
{
int argCount = instruction[3].u.operand;
int registerOffset = instruction[4].u.operand;
int proto = instruction[5].u.operand;
int thisRegister = instruction[6].u.operand;
// ecx holds func
emitPutJITStubArg(regT0, 0);
emitPutJITStubArgConstant(registerOffset, 1);
emitPutJITStubArgConstant(argCount, 2);
emitPutJITStubArgFromVirtualRegister(proto, 3, regT2);
emitPutJITStubArgConstant(thisRegister, 4);
}
void JIT::compileOpCallVarargs(Instruction* instruction)
{
int dst = instruction[1].u.operand;
int callee = instruction[2].u.operand;
int argCountRegister = instruction[3].u.operand;
emitGetVirtualRegister(argCountRegister, regT1);
emitGetVirtualRegister(callee, regT0);
compileOpCallVarargsSetupArgs(instruction);
// Check for JSFunctions.
emitJumpSlowCaseIfNotJSCell(regT0);
addSlowCase(branchPtr(NotEqual, Address(regT0), ImmPtr(m_globalData->jsFunctionVPtr)));
// Speculatively roll the callframe, assuming argCount will match the arity.
mul32(Imm32(sizeof(Register)), regT2, regT2);
intptr_t offset = (intptr_t)sizeof(Register) * (intptr_t)RegisterFile::CallerFrame;
addPtr(Imm32((int32_t)offset), regT2, regT3);
addPtr(callFrameRegister, regT3);
storePtr(callFrameRegister, regT3);
addPtr(regT2, callFrameRegister);
emitNakedCall(m_globalData->jitStubs.ctiVirtualCall());
// Put the return value in dst. In the interpreter, op_ret does this.
emitPutVirtualRegister(dst);
sampleCodeBlock(m_codeBlock);
}
void JIT::compileOpCallVarargsSlowCase(Instruction* instruction, Vector<SlowCaseEntry>::iterator& iter)
{
int dst = instruction[1].u.operand;
linkSlowCase(iter);
linkSlowCase(iter);
JITStubCall stubCall(this, cti_op_call_NotJSFunction);
stubCall.call(dst); // In the interpreter, the callee puts the return value in dst.
sampleCodeBlock(m_codeBlock);
}
#if !ENABLE(JIT_OPTIMIZE_CALL)
/* ------------------------------ BEGIN: !ENABLE(JIT_OPTIMIZE_CALL) ------------------------------ */
void JIT::compileOpCall(OpcodeID opcodeID, Instruction* instruction, unsigned)
{
int dst = instruction[1].u.operand;
int callee = instruction[2].u.operand;
int argCount = instruction[3].u.operand;
int registerOffset = instruction[4].u.operand;
// Handle eval
Jump wasEval;
if (opcodeID == op_call_eval) {
JITStubCall stubCall(this, cti_op_call_eval);
stubCall.addArgument(callee, regT0);
stubCall.addArgument(JIT::Imm32(registerOffset));
stubCall.addArgument(JIT::Imm32(argCount));
stubCall.call();
wasEval = branchPtr(NotEqual, regT0, ImmPtr(JSValue::encode(JSValue())));
}
emitGetVirtualRegister(callee, regT0);
// The arguments have been set up on the hot path for op_call_eval
if (opcodeID == op_call)
compileOpCallSetupArgs(instruction);
else if (opcodeID == op_construct)
compileOpConstructSetupArgs(instruction);
// Check for JSFunctions.
emitJumpSlowCaseIfNotJSCell(regT0);
addSlowCase(branchPtr(NotEqual, Address(regT0), ImmPtr(m_globalData->jsFunctionVPtr)));
// First, in the case of a construct, allocate the new object.
if (opcodeID == op_construct) {
JITStubCall(this, cti_op_construct_JSConstruct).call(registerOffset - RegisterFile::CallFrameHeaderSize - argCount);
emitGetVirtualRegister(callee, regT0);
}
// Speculatively roll the callframe, assuming argCount will match the arity.
storePtr(callFrameRegister, Address(callFrameRegister, (RegisterFile::CallerFrame + registerOffset) * static_cast<int>(sizeof(Register))));
addPtr(Imm32(registerOffset * static_cast<int>(sizeof(Register))), callFrameRegister);
move(Imm32(argCount), regT1);
emitNakedCall(m_globalData->jitStubs.ctiVirtualCall());
if (opcodeID == op_call_eval)
wasEval.link(this);
// Put the return value in dst. In the interpreter, op_ret does this.
emitPutVirtualRegister(dst);
sampleCodeBlock(m_codeBlock);
}
void JIT::compileOpCallSlowCase(Instruction* instruction, Vector<SlowCaseEntry>::iterator& iter, unsigned, OpcodeID opcodeID)
{
int dst = instruction[1].u.operand;
linkSlowCase(iter);
linkSlowCase(iter);
JITStubCall stubCall(this, opcodeID == op_construct ? cti_op_construct_NotJSConstruct : cti_op_call_NotJSFunction);
stubCall.call(dst); // In the interpreter, the callee puts the return value in dst.
sampleCodeBlock(m_codeBlock);
}
#else // !ENABLE(JIT_OPTIMIZE_CALL)
/* ------------------------------ BEGIN: ENABLE(JIT_OPTIMIZE_CALL) ------------------------------ */
void JIT::compileOpCall(OpcodeID opcodeID, Instruction* instruction, unsigned callLinkInfoIndex)
{
int dst = instruction[1].u.operand;
int callee = instruction[2].u.operand;
int argCount = instruction[3].u.operand;
int registerOffset = instruction[4].u.operand;
// Handle eval
Jump wasEval;
if (opcodeID == op_call_eval) {
JITStubCall stubCall(this, cti_op_call_eval);
stubCall.addArgument(callee, regT0);
stubCall.addArgument(JIT::Imm32(registerOffset));
stubCall.addArgument(JIT::Imm32(argCount));
stubCall.call();
wasEval = branchPtr(NotEqual, regT0, ImmPtr(JSValue::encode(JSValue())));
}
// This plants a check for a cached JSFunction value, so we can plant a fast link to the callee.
// This deliberately leaves the callee in ecx, used when setting up the stack frame below
emitGetVirtualRegister(callee, regT0);
DataLabelPtr addressOfLinkedFunctionCheck;
BEGIN_UNINTERRUPTED_SEQUENCE(sequenceOpCall);
Jump jumpToSlow = branchPtrWithPatch(NotEqual, regT0, addressOfLinkedFunctionCheck, ImmPtr(JSValue::encode(JSValue())));
END_UNINTERRUPTED_SEQUENCE(sequenceOpCall);
addSlowCase(jumpToSlow);
ASSERT(differenceBetween(addressOfLinkedFunctionCheck, jumpToSlow) == patchOffsetOpCallCompareToJump);
m_callStructureStubCompilationInfo[callLinkInfoIndex].hotPathBegin = addressOfLinkedFunctionCheck;
// The following is the fast case, only used whan a callee can be linked.
// In the case of OpConstruct, call out to a cti_ function to create the new object.
if (opcodeID == op_construct) {
int proto = instruction[5].u.operand;
int thisRegister = instruction[6].u.operand;
emitPutJITStubArg(regT0, 0);
emitPutJITStubArgFromVirtualRegister(proto, 3, regT2);
JITStubCall stubCall(this, cti_op_construct_JSConstruct);
stubCall.call(thisRegister);
emitGetVirtualRegister(callee, regT0);
}
// Fast version of stack frame initialization, directly relative to edi.
// Note that this omits to set up RegisterFile::CodeBlock, which is set in the callee
storePtr(ImmPtr(JSValue::encode(JSValue())), Address(callFrameRegister, (registerOffset + RegisterFile::OptionalCalleeArguments) * static_cast<int>(sizeof(Register))));
storePtr(regT0, Address(callFrameRegister, (registerOffset + RegisterFile::Callee) * static_cast<int>(sizeof(Register))));
loadPtr(Address(regT0, OBJECT_OFFSETOF(JSFunction, m_data) + OBJECT_OFFSETOF(ScopeChain, m_node)), regT1); // newScopeChain
store32(Imm32(argCount), Address(callFrameRegister, (registerOffset + RegisterFile::ArgumentCount) * static_cast<int>(sizeof(Register))));
storePtr(callFrameRegister, Address(callFrameRegister, (registerOffset + RegisterFile::CallerFrame) * static_cast<int>(sizeof(Register))));
storePtr(regT1, Address(callFrameRegister, (registerOffset + RegisterFile::ScopeChain) * static_cast<int>(sizeof(Register))));
addPtr(Imm32(registerOffset * sizeof(Register)), callFrameRegister);
// Call to the callee
m_callStructureStubCompilationInfo[callLinkInfoIndex].hotPathOther = emitNakedCall();
if (opcodeID == op_call_eval)
wasEval.link(this);
// Put the return value in dst. In the interpreter, op_ret does this.
emitPutVirtualRegister(dst);
sampleCodeBlock(m_codeBlock);
}
void JIT::compileOpCallSlowCase(Instruction* instruction, Vector<SlowCaseEntry>::iterator& iter, unsigned callLinkInfoIndex, OpcodeID opcodeID)
{
int dst = instruction[1].u.operand;
int callee = instruction[2].u.operand;
int argCount = instruction[3].u.operand;
int registerOffset = instruction[4].u.operand;
linkSlowCase(iter);
// The arguments have been set up on the hot path for op_call_eval
if (opcodeID == op_call)
compileOpCallSetupArgs(instruction);
else if (opcodeID == op_construct)
compileOpConstructSetupArgs(instruction);
// Fast check for JS function.
Jump callLinkFailNotObject = emitJumpIfNotJSCell(regT0);
Jump callLinkFailNotJSFunction = branchPtr(NotEqual, Address(regT0), ImmPtr(m_globalData->jsFunctionVPtr));
// First, in the case of a construct, allocate the new object.
if (opcodeID == op_construct) {
JITStubCall(this, cti_op_construct_JSConstruct).call(registerOffset - RegisterFile::CallFrameHeaderSize - argCount);
emitGetVirtualRegister(callee, regT0);
}
// Speculatively roll the callframe, assuming argCount will match the arity.
storePtr(callFrameRegister, Address(callFrameRegister, (RegisterFile::CallerFrame + registerOffset) * static_cast<int>(sizeof(Register))));
addPtr(Imm32(registerOffset * static_cast<int>(sizeof(Register))), callFrameRegister);
move(Imm32(argCount), regT1);
move(regT0, regT2);
m_callStructureStubCompilationInfo[callLinkInfoIndex].callReturnLocation = emitNakedCall(m_globalData->jitStubs.ctiVirtualCallLink());
// Put the return value in dst.
emitPutVirtualRegister(dst);
sampleCodeBlock(m_codeBlock);
// If not, we need an extra case in the if below!
ASSERT(OPCODE_LENGTH(op_call) == OPCODE_LENGTH(op_call_eval));
// Done! - return back to the hot path.
if (opcodeID == op_construct)
emitJumpSlowToHot(jump(), OPCODE_LENGTH(op_construct));
else
emitJumpSlowToHot(jump(), OPCODE_LENGTH(op_call));
// This handles host functions
callLinkFailNotObject.link(this);
callLinkFailNotJSFunction.link(this);
JITStubCall(this, opcodeID == op_construct ? cti_op_construct_NotJSConstruct : cti_op_call_NotJSFunction).call();
emitPutVirtualRegister(dst);
sampleCodeBlock(m_codeBlock);
}
/* ------------------------------ END: !ENABLE / ENABLE(JIT_OPTIMIZE_CALL) ------------------------------ */
#endif // !ENABLE(JIT_OPTIMIZE_CALL)
#endif // USE(JSVALUE32_64)
} // namespace JSC
#endif // ENABLE(JIT)
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