/*
* Copyright (C) 2008, 2009 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"
// This probably does not belong here; adding here for now as a quick Windows build fix.
#if ENABLE(ASSEMBLER) && CPU(X86) && !OS(MAC_OS_X)
#include "MacroAssembler.h"
JSC::MacroAssemblerX86Common::SSE2CheckState JSC::MacroAssemblerX86Common::s_sse2CheckState = NotCheckedSSE2;
#endif
#if ENABLE(JIT)
#include "CodeBlock.h"
#include "Interpreter.h"
#include "JITInlineMethods.h"
#include "JITStubCall.h"
#include "JSArray.h"
#include "JSFunction.h"
#include "LinkBuffer.h"
#include "RepatchBuffer.h"
#include "ResultType.h"
#include "SamplingTool.h"
#ifndef NDEBUG
#include <stdio.h>
#endif
using namespace std;
namespace JSC {
void ctiPatchNearCallByReturnAddress(CodeBlock* codeblock, ReturnAddressPtr returnAddress, MacroAssemblerCodePtr newCalleeFunction)
{
RepatchBuffer repatchBuffer(codeblock);
repatchBuffer.relinkNearCallerToTrampoline(returnAddress, newCalleeFunction);
}
void ctiPatchCallByReturnAddress(CodeBlock* codeblock, ReturnAddressPtr returnAddress, MacroAssemblerCodePtr newCalleeFunction)
{
RepatchBuffer repatchBuffer(codeblock);
repatchBuffer.relinkCallerToTrampoline(returnAddress, newCalleeFunction);
}
void ctiPatchCallByReturnAddress(CodeBlock* codeblock, ReturnAddressPtr returnAddress, FunctionPtr newCalleeFunction)
{
RepatchBuffer repatchBuffer(codeblock);
repatchBuffer.relinkCallerToFunction(returnAddress, newCalleeFunction);
}
JIT::JIT(JSGlobalData* globalData, CodeBlock* codeBlock)
: m_interpreter(globalData->interpreter)
, m_globalData(globalData)
, m_codeBlock(codeBlock)
, m_labels(codeBlock ? codeBlock->instructions().size() : 0)
, m_propertyAccessCompilationInfo(codeBlock ? codeBlock->numberOfStructureStubInfos() : 0)
, m_callStructureStubCompilationInfo(codeBlock ? codeBlock->numberOfCallLinkInfos() : 0)
, m_bytecodeIndex((unsigned)-1)
#if USE(JSVALUE32_64)
, m_jumpTargetIndex(0)
, m_mappedBytecodeIndex((unsigned)-1)
, m_mappedVirtualRegisterIndex((unsigned)-1)
, m_mappedTag((RegisterID)-1)
, m_mappedPayload((RegisterID)-1)
#else
, m_lastResultBytecodeRegister(std::numeric_limits<int>::max())
, m_jumpTargetsPosition(0)
#endif
{
}
#if USE(JSVALUE32_64)
void JIT::emitTimeoutCheck()
{
Jump skipTimeout = branchSub32(NonZero, Imm32(1), timeoutCheckRegister);
JITStubCall stubCall(this, cti_timeout_check);
stubCall.addArgument(regT1, regT0); // save last result registers.
stubCall.call(timeoutCheckRegister);
stubCall.getArgument(0, regT1, regT0); // reload last result registers.
skipTimeout.link(this);
}
#else
void JIT::emitTimeoutCheck()
{
Jump skipTimeout = branchSub32(NonZero, Imm32(1), timeoutCheckRegister);
JITStubCall(this, cti_timeout_check).call(timeoutCheckRegister);
skipTimeout.link(this);
killLastResultRegister();
}
#endif
#define NEXT_OPCODE(name) \
m_bytecodeIndex += OPCODE_LENGTH(name); \
break;
#if USE(JSVALUE32_64)
#define DEFINE_BINARY_OP(name) \
case name: { \
JITStubCall stubCall(this, cti_##name); \
stubCall.addArgument(currentInstruction[2].u.operand); \
stubCall.addArgument(currentInstruction[3].u.operand); \
stubCall.call(currentInstruction[1].u.operand); \
NEXT_OPCODE(name); \
}
#define DEFINE_UNARY_OP(name) \
case name: { \
JITStubCall stubCall(this, cti_##name); \
stubCall.addArgument(currentInstruction[2].u.operand); \
stubCall.call(currentInstruction[1].u.operand); \
NEXT_OPCODE(name); \
}
#else // USE(JSVALUE32_64)
#define DEFINE_BINARY_OP(name) \
case name: { \
JITStubCall stubCall(this, cti_##name); \
stubCall.addArgument(currentInstruction[2].u.operand, regT2); \
stubCall.addArgument(currentInstruction[3].u.operand, regT2); \
stubCall.call(currentInstruction[1].u.operand); \
NEXT_OPCODE(name); \
}
#define DEFINE_UNARY_OP(name) \
case name: { \
JITStubCall stubCall(this, cti_##name); \
stubCall.addArgument(currentInstruction[2].u.operand, regT2); \
stubCall.call(currentInstruction[1].u.operand); \
NEXT_OPCODE(name); \
}
#endif // USE(JSVALUE32_64)
#define DEFINE_OP(name) \
case name: { \
emit_##name(currentInstruction); \
NEXT_OPCODE(name); \
}
#define DEFINE_SLOWCASE_OP(name) \
case name: { \
emitSlow_##name(currentInstruction, iter); \
NEXT_OPCODE(name); \
}
void JIT::privateCompileMainPass()
{
Instruction* instructionsBegin = m_codeBlock->instructions().begin();
unsigned instructionCount = m_codeBlock->instructions().size();
m_propertyAccessInstructionIndex = 0;
m_globalResolveInfoIndex = 0;
m_callLinkInfoIndex = 0;
for (m_bytecodeIndex = 0; m_bytecodeIndex < instructionCount; ) {
Instruction* currentInstruction = instructionsBegin + m_bytecodeIndex;
ASSERT_WITH_MESSAGE(m_interpreter->isOpcode(currentInstruction->u.opcode), "privateCompileMainPass gone bad @ %d", m_bytecodeIndex);
#if ENABLE(OPCODE_SAMPLING)
if (m_bytecodeIndex > 0) // Avoid the overhead of sampling op_enter twice.
sampleInstruction(currentInstruction);
#endif
#if !USE(JSVALUE32_64)
if (m_labels[m_bytecodeIndex].isUsed())
killLastResultRegister();
#endif
m_labels[m_bytecodeIndex] = label();
switch (m_interpreter->getOpcodeID(currentInstruction->u.opcode)) {
DEFINE_BINARY_OP(op_del_by_val)
#if USE(JSVALUE32)
DEFINE_BINARY_OP(op_div)
#endif
DEFINE_BINARY_OP(op_in)
DEFINE_BINARY_OP(op_less)
DEFINE_BINARY_OP(op_lesseq)
DEFINE_BINARY_OP(op_urshift)
DEFINE_UNARY_OP(op_is_boolean)
DEFINE_UNARY_OP(op_is_function)
DEFINE_UNARY_OP(op_is_number)
DEFINE_UNARY_OP(op_is_object)
DEFINE_UNARY_OP(op_is_string)
DEFINE_UNARY_OP(op_is_undefined)
#if !USE(JSVALUE32_64)
DEFINE_UNARY_OP(op_negate)
#endif
DEFINE_UNARY_OP(op_typeof)
DEFINE_OP(op_add)
DEFINE_OP(op_bitand)
DEFINE_OP(op_bitnot)
DEFINE_OP(op_bitor)
DEFINE_OP(op_bitxor)
DEFINE_OP(op_call)
DEFINE_OP(op_call_eval)
DEFINE_OP(op_call_varargs)
DEFINE_OP(op_catch)
DEFINE_OP(op_construct)
DEFINE_OP(op_construct_verify)
DEFINE_OP(op_convert_this)
DEFINE_OP(op_init_arguments)
DEFINE_OP(op_create_arguments)
DEFINE_OP(op_debug)
DEFINE_OP(op_del_by_id)
#if !USE(JSVALUE32)
DEFINE_OP(op_div)
#endif
DEFINE_OP(op_end)
DEFINE_OP(op_enter)
DEFINE_OP(op_enter_with_activation)
DEFINE_OP(op_eq)
DEFINE_OP(op_eq_null)
DEFINE_OP(op_get_by_id)
DEFINE_OP(op_get_by_val)
DEFINE_OP(op_get_by_pname)
DEFINE_OP(op_get_global_var)
DEFINE_OP(op_get_pnames)
DEFINE_OP(op_get_scoped_var)
DEFINE_OP(op_instanceof)
DEFINE_OP(op_jeq_null)
DEFINE_OP(op_jfalse)
DEFINE_OP(op_jmp)
DEFINE_OP(op_jmp_scopes)
DEFINE_OP(op_jneq_null)
DEFINE_OP(op_jneq_ptr)
DEFINE_OP(op_jnless)
DEFINE_OP(op_jless)
DEFINE_OP(op_jnlesseq)
DEFINE_OP(op_jsr)
DEFINE_OP(op_jtrue)
DEFINE_OP(op_load_varargs)
DEFINE_OP(op_loop)
DEFINE_OP(op_loop_if_less)
DEFINE_OP(op_loop_if_lesseq)
DEFINE_OP(op_loop_if_true)
DEFINE_OP(op_loop_if_false)
DEFINE_OP(op_lshift)
DEFINE_OP(op_method_check)
DEFINE_OP(op_mod)
DEFINE_OP(op_mov)
DEFINE_OP(op_mul)
#if USE(JSVALUE32_64)
DEFINE_OP(op_negate)
#endif
DEFINE_OP(op_neq)
DEFINE_OP(op_neq_null)
DEFINE_OP(op_new_array)
DEFINE_OP(op_new_error)
DEFINE_OP(op_new_func)
DEFINE_OP(op_new_func_exp)
DEFINE_OP(op_new_object)
DEFINE_OP(op_new_regexp)
DEFINE_OP(op_next_pname)
DEFINE_OP(op_not)
DEFINE_OP(op_nstricteq)
DEFINE_OP(op_pop_scope)
DEFINE_OP(op_post_dec)
DEFINE_OP(op_post_inc)
DEFINE_OP(op_pre_dec)
DEFINE_OP(op_pre_inc)
DEFINE_OP(op_profile_did_call)
DEFINE_OP(op_profile_will_call)
DEFINE_OP(op_push_new_scope)
DEFINE_OP(op_push_scope)
DEFINE_OP(op_put_by_id)
DEFINE_OP(op_put_by_index)
DEFINE_OP(op_put_by_val)
DEFINE_OP(op_put_getter)
DEFINE_OP(op_put_global_var)
DEFINE_OP(op_put_scoped_var)
DEFINE_OP(op_put_setter)
DEFINE_OP(op_resolve)
DEFINE_OP(op_resolve_base)
DEFINE_OP(op_resolve_global)
DEFINE_OP(op_resolve_skip)
DEFINE_OP(op_resolve_with_base)
DEFINE_OP(op_ret)
DEFINE_OP(op_rshift)
DEFINE_OP(op_sret)
DEFINE_OP(op_strcat)
DEFINE_OP(op_stricteq)
DEFINE_OP(op_sub)
DEFINE_OP(op_switch_char)
DEFINE_OP(op_switch_imm)
DEFINE_OP(op_switch_string)
DEFINE_OP(op_tear_off_activation)
DEFINE_OP(op_tear_off_arguments)
DEFINE_OP(op_throw)
DEFINE_OP(op_to_jsnumber)
DEFINE_OP(op_to_primitive)
case op_get_array_length:
case op_get_by_id_chain:
case op_get_by_id_generic:
case op_get_by_id_proto:
case op_get_by_id_proto_list:
case op_get_by_id_self:
case op_get_by_id_self_list:
case op_get_string_length:
case op_put_by_id_generic:
case op_put_by_id_replace:
case op_put_by_id_transition:
ASSERT_NOT_REACHED();
}
}
ASSERT(m_propertyAccessInstructionIndex == m_codeBlock->numberOfStructureStubInfos());
ASSERT(m_callLinkInfoIndex == m_codeBlock->numberOfCallLinkInfos());
#ifndef NDEBUG
// Reset this, in order to guard its use with ASSERTs.
m_bytecodeIndex = (unsigned)-1;
#endif
}
void JIT::privateCompileLinkPass()
{
unsigned jmpTableCount = m_jmpTable.size();
for (unsigned i = 0; i < jmpTableCount; ++i)
m_jmpTable[i].from.linkTo(m_labels[m_jmpTable[i].toBytecodeIndex], this);
m_jmpTable.clear();
}
void JIT::privateCompileSlowCases()
{
Instruction* instructionsBegin = m_codeBlock->instructions().begin();
m_propertyAccessInstructionIndex = 0;
#if USE(JSVALUE32_64)
m_globalResolveInfoIndex = 0;
#endif
m_callLinkInfoIndex = 0;
for (Vector<SlowCaseEntry>::iterator iter = m_slowCases.begin(); iter != m_slowCases.end();) {
#if !USE(JSVALUE32_64)
killLastResultRegister();
#endif
m_bytecodeIndex = iter->to;
#ifndef NDEBUG
unsigned firstTo = m_bytecodeIndex;
#endif
Instruction* currentInstruction = instructionsBegin + m_bytecodeIndex;
switch (m_interpreter->getOpcodeID(currentInstruction->u.opcode)) {
DEFINE_SLOWCASE_OP(op_add)
DEFINE_SLOWCASE_OP(op_bitand)
DEFINE_SLOWCASE_OP(op_bitnot)
DEFINE_SLOWCASE_OP(op_bitor)
DEFINE_SLOWCASE_OP(op_bitxor)
DEFINE_SLOWCASE_OP(op_call)
DEFINE_SLOWCASE_OP(op_call_eval)
DEFINE_SLOWCASE_OP(op_call_varargs)
DEFINE_SLOWCASE_OP(op_construct)
DEFINE_SLOWCASE_OP(op_construct_verify)
DEFINE_SLOWCASE_OP(op_convert_this)
#if !USE(JSVALUE32)
DEFINE_SLOWCASE_OP(op_div)
#endif
DEFINE_SLOWCASE_OP(op_eq)
DEFINE_SLOWCASE_OP(op_get_by_id)
DEFINE_SLOWCASE_OP(op_get_by_val)
DEFINE_SLOWCASE_OP(op_get_by_pname)
DEFINE_SLOWCASE_OP(op_instanceof)
DEFINE_SLOWCASE_OP(op_jfalse)
DEFINE_SLOWCASE_OP(op_jnless)
DEFINE_SLOWCASE_OP(op_jless)
DEFINE_SLOWCASE_OP(op_jnlesseq)
DEFINE_SLOWCASE_OP(op_jtrue)
DEFINE_SLOWCASE_OP(op_loop_if_less)
DEFINE_SLOWCASE_OP(op_loop_if_lesseq)
DEFINE_SLOWCASE_OP(op_loop_if_true)
DEFINE_SLOWCASE_OP(op_loop_if_false)
DEFINE_SLOWCASE_OP(op_lshift)
DEFINE_SLOWCASE_OP(op_method_check)
DEFINE_SLOWCASE_OP(op_mod)
DEFINE_SLOWCASE_OP(op_mul)
#if USE(JSVALUE32_64)
DEFINE_SLOWCASE_OP(op_negate)
#endif
DEFINE_SLOWCASE_OP(op_neq)
DEFINE_SLOWCASE_OP(op_not)
DEFINE_SLOWCASE_OP(op_nstricteq)
DEFINE_SLOWCASE_OP(op_post_dec)
DEFINE_SLOWCASE_OP(op_post_inc)
DEFINE_SLOWCASE_OP(op_pre_dec)
DEFINE_SLOWCASE_OP(op_pre_inc)
DEFINE_SLOWCASE_OP(op_put_by_id)
DEFINE_SLOWCASE_OP(op_put_by_val)
#if USE(JSVALUE32_64)
DEFINE_SLOWCASE_OP(op_resolve_global)
#endif
DEFINE_SLOWCASE_OP(op_rshift)
DEFINE_SLOWCASE_OP(op_stricteq)
DEFINE_SLOWCASE_OP(op_sub)
DEFINE_SLOWCASE_OP(op_to_jsnumber)
DEFINE_SLOWCASE_OP(op_to_primitive)
default:
ASSERT_NOT_REACHED();
}
ASSERT_WITH_MESSAGE(iter == m_slowCases.end() || firstTo != iter->to,"Not enough jumps linked in slow case codegen.");
ASSERT_WITH_MESSAGE(firstTo == (iter - 1)->to, "Too many jumps linked in slow case codegen.");
emitJumpSlowToHot(jump(), 0);
}
#if ENABLE(JIT_OPTIMIZE_PROPERTY_ACCESS)
ASSERT(m_propertyAccessInstructionIndex == m_codeBlock->numberOfStructureStubInfos());
#endif
ASSERT(m_callLinkInfoIndex == m_codeBlock->numberOfCallLinkInfos());
#ifndef NDEBUG
// Reset this, in order to guard its use with ASSERTs.
m_bytecodeIndex = (unsigned)-1;
#endif
}
JITCode JIT::privateCompile()
{
sampleCodeBlock(m_codeBlock);
#if ENABLE(OPCODE_SAMPLING)
sampleInstruction(m_codeBlock->instructions().begin());
#endif
// Could use a pop_m, but would need to offset the following instruction if so.
preserveReturnAddressAfterCall(regT2);
emitPutToCallFrameHeader(regT2, RegisterFile::ReturnPC);
Jump slowRegisterFileCheck;
Label afterRegisterFileCheck;
if (m_codeBlock->codeType() == FunctionCode) {
// In the case of a fast linked call, we do not set this up in the caller.
emitPutImmediateToCallFrameHeader(m_codeBlock, RegisterFile::CodeBlock);
peek(regT0, OBJECT_OFFSETOF(JITStackFrame, registerFile) / sizeof (void*));
addPtr(Imm32(m_codeBlock->m_numCalleeRegisters * sizeof(Register)), callFrameRegister, regT1);
slowRegisterFileCheck = branchPtr(Above, regT1, Address(regT0, OBJECT_OFFSETOF(RegisterFile, m_end)));
afterRegisterFileCheck = label();
}
privateCompileMainPass();
privateCompileLinkPass();
privateCompileSlowCases();
if (m_codeBlock->codeType() == FunctionCode) {
slowRegisterFileCheck.link(this);
m_bytecodeIndex = 0;
JITStubCall(this, cti_register_file_check).call();
#ifndef NDEBUG
m_bytecodeIndex = (unsigned)-1; // Reset this, in order to guard its use with ASSERTs.
#endif
jump(afterRegisterFileCheck);
}
ASSERT(m_jmpTable.isEmpty());
LinkBuffer patchBuffer(this, m_globalData->executableAllocator.poolForSize(m_assembler.size()));
// Translate vPC offsets into addresses in JIT generated code, for switch tables.
for (unsigned i = 0; i < m_switches.size(); ++i) {
SwitchRecord record = m_switches[i];
unsigned bytecodeIndex = record.bytecodeIndex;
if (record.type != SwitchRecord::String) {
ASSERT(record.type == SwitchRecord::Immediate || record.type == SwitchRecord::Character);
ASSERT(record.jumpTable.simpleJumpTable->branchOffsets.size() == record.jumpTable.simpleJumpTable->ctiOffsets.size());
record.jumpTable.simpleJumpTable->ctiDefault = patchBuffer.locationOf(m_labels[bytecodeIndex + record.defaultOffset]);
for (unsigned j = 0; j < record.jumpTable.simpleJumpTable->branchOffsets.size(); ++j) {
unsigned offset = record.jumpTable.simpleJumpTable->branchOffsets[j];
record.jumpTable.simpleJumpTable->ctiOffsets[j] = offset ? patchBuffer.locationOf(m_labels[bytecodeIndex + offset]) : record.jumpTable.simpleJumpTable->ctiDefault;
}
} else {
ASSERT(record.type == SwitchRecord::String);
record.jumpTable.stringJumpTable->ctiDefault = patchBuffer.locationOf(m_labels[bytecodeIndex + record.defaultOffset]);
StringJumpTable::StringOffsetTable::iterator end = record.jumpTable.stringJumpTable->offsetTable.end();
for (StringJumpTable::StringOffsetTable::iterator it = record.jumpTable.stringJumpTable->offsetTable.begin(); it != end; ++it) {
unsigned offset = it->second.branchOffset;
it->second.ctiOffset = offset ? patchBuffer.locationOf(m_labels[bytecodeIndex + offset]) : record.jumpTable.stringJumpTable->ctiDefault;
}
}
}
for (size_t i = 0; i < m_codeBlock->numberOfExceptionHandlers(); ++i) {
HandlerInfo& handler = m_codeBlock->exceptionHandler(i);
handler.nativeCode = patchBuffer.locationOf(m_labels[handler.target]);
}
for (Vector<CallRecord>::iterator iter = m_calls.begin(); iter != m_calls.end(); ++iter) {
if (iter->to)
patchBuffer.link(iter->from, FunctionPtr(iter->to));
}
if (m_codeBlock->hasExceptionInfo()) {
m_codeBlock->callReturnIndexVector().reserveCapacity(m_calls.size());
for (Vector<CallRecord>::iterator iter = m_calls.begin(); iter != m_calls.end(); ++iter)
m_codeBlock->callReturnIndexVector().append(CallReturnOffsetToBytecodeIndex(patchBuffer.returnAddressOffset(iter->from), iter->bytecodeIndex));
}
// Link absolute addresses for jsr
for (Vector<JSRInfo>::iterator iter = m_jsrSites.begin(); iter != m_jsrSites.end(); ++iter)
patchBuffer.patch(iter->storeLocation, patchBuffer.locationOf(iter->target).executableAddress());
#if ENABLE(JIT_OPTIMIZE_PROPERTY_ACCESS)
for (unsigned i = 0; i < m_codeBlock->numberOfStructureStubInfos(); ++i) {
StructureStubInfo& info = m_codeBlock->structureStubInfo(i);
info.callReturnLocation = patchBuffer.locationOf(m_propertyAccessCompilationInfo[i].callReturnLocation);
info.hotPathBegin = patchBuffer.locationOf(m_propertyAccessCompilationInfo[i].hotPathBegin);
}
#endif
#if ENABLE(JIT_OPTIMIZE_CALL)
for (unsigned i = 0; i < m_codeBlock->numberOfCallLinkInfos(); ++i) {
CallLinkInfo& info = m_codeBlock->callLinkInfo(i);
info.ownerCodeBlock = m_codeBlock;
info.callReturnLocation = patchBuffer.locationOfNearCall(m_callStructureStubCompilationInfo[i].callReturnLocation);
info.hotPathBegin = patchBuffer.locationOf(m_callStructureStubCompilationInfo[i].hotPathBegin);
info.hotPathOther = patchBuffer.locationOfNearCall(m_callStructureStubCompilationInfo[i].hotPathOther);
}
#endif
unsigned methodCallCount = m_methodCallCompilationInfo.size();
m_codeBlock->addMethodCallLinkInfos(methodCallCount);
for (unsigned i = 0; i < methodCallCount; ++i) {
MethodCallLinkInfo& info = m_codeBlock->methodCallLinkInfo(i);
info.structureLabel = patchBuffer.locationOf(m_methodCallCompilationInfo[i].structureToCompare);
info.callReturnLocation = m_codeBlock->structureStubInfo(m_methodCallCompilationInfo[i].propertyAccessIndex).callReturnLocation;
}
return patchBuffer.finalizeCode();
}
#if !USE(JSVALUE32_64)
void JIT::emitGetVariableObjectRegister(RegisterID variableObject, int index, RegisterID dst)
{
loadPtr(Address(variableObject, OBJECT_OFFSETOF(JSVariableObject, d)), dst);
loadPtr(Address(dst, OBJECT_OFFSETOF(JSVariableObject::JSVariableObjectData, registers)), dst);
loadPtr(Address(dst, index * sizeof(Register)), dst);
}
void JIT::emitPutVariableObjectRegister(RegisterID src, RegisterID variableObject, int index)
{
loadPtr(Address(variableObject, OBJECT_OFFSETOF(JSVariableObject, d)), variableObject);
loadPtr(Address(variableObject, OBJECT_OFFSETOF(JSVariableObject::JSVariableObjectData, registers)), variableObject);
storePtr(src, Address(variableObject, index * sizeof(Register)));
}
#endif
#if ENABLE(JIT_OPTIMIZE_CALL)
void JIT::unlinkCall(CallLinkInfo* callLinkInfo)
{
// When the JSFunction is deleted the pointer embedded in the instruction stream will no longer be valid
// (and, if a new JSFunction happened to be constructed at the same location, we could get a false positive
// match). Reset the check so it no longer matches.
RepatchBuffer repatchBuffer(callLinkInfo->ownerCodeBlock.get());
#if USE(JSVALUE32_64)
repatchBuffer.repatch(callLinkInfo->hotPathBegin, 0);
#else
repatchBuffer.repatch(callLinkInfo->hotPathBegin, JSValue::encode(JSValue()));
#endif
}
void JIT::linkCall(JSFunction* callee, CodeBlock* callerCodeBlock, CodeBlock* calleeCodeBlock, JITCode& code, CallLinkInfo* callLinkInfo, int callerArgCount, JSGlobalData* globalData)
{
RepatchBuffer repatchBuffer(callerCodeBlock);
// Currently we only link calls with the exact number of arguments.
// If this is a native call calleeCodeBlock is null so the number of parameters is unimportant
if (!calleeCodeBlock || (callerArgCount == calleeCodeBlock->m_numParameters)) {
ASSERT(!callLinkInfo->isLinked());
if (calleeCodeBlock)
calleeCodeBlock->addCaller(callLinkInfo);
repatchBuffer.repatch(callLinkInfo->hotPathBegin, callee);
repatchBuffer.relink(callLinkInfo->hotPathOther, code.addressForCall());
}
// patch the call so we do not continue to try to link.
repatchBuffer.relink(callLinkInfo->callReturnLocation, globalData->jitStubs.ctiVirtualCall());
}
#endif // ENABLE(JIT_OPTIMIZE_CALL)
} // namespace JSC
#endif // ENABLE(JIT)