Source/JavaScriptCore/dfg/DFGJITCompiler.cpp - WebKit - Git at Google

 /*
  * Copyright (C) 2011, 2013-2015 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 "DFGJITCompiler.h"

 #if ENABLE(DFG_JIT)

 #include "ArityCheckFailReturnThunks.h"
 #include "CodeBlock.h"
 #include "DFGFailedFinalizer.h"
 #include "DFGInlineCacheWrapperInlines.h"
 #include "DFGJITCode.h"
 #include "DFGJITFinalizer.h"
 #include "DFGOSRExitCompiler.h"
 #include "DFGOperations.h"
 #include "DFGRegisterBank.h"
 #include "DFGSlowPathGenerator.h"
 #include "DFGSpeculativeJIT.h"
 #include "DFGThunks.h"
 #include "JSCJSValueInlines.h"
 #include "LinkBuffer.h"
 #include "MaxFrameExtentForSlowPathCall.h"
 #include "JSCInlines.h"
 #include "VM.h"

 namespace JSC { namespace DFG {

 JITCompiler::JITCompiler(Graph& dfg)
     : CCallHelpers(&dfg.m_vm, dfg.m_codeBlock)
     , m_graph(dfg)
     , m_jitCode(adoptRef(new JITCode()))
     , m_blockHeads(dfg.numBlocks())
 {
     if (shouldShowDisassembly() || m_graph.m_vm.m_perBytecodeProfiler)
         m_disassembler = std::make_unique<Disassembler>(dfg);
 }

 JITCompiler::~JITCompiler()
 {
 }

 void JITCompiler::linkOSRExits()
 {
     ASSERT(m_jitCode->osrExit.size() == m_exitCompilationInfo.size());
     if (m_graph.compilation()) {
         for (unsigned i = 0; i < m_jitCode->osrExit.size(); ++i) {
             OSRExitCompilationInfo& info = m_exitCompilationInfo[i];
             Vector<Label> labels;
             if (!info.m_failureJumps.empty()) {
                 for (unsigned j = 0; j < info.m_failureJumps.jumps().size(); ++j)
                     labels.append(info.m_failureJumps.jumps()[j].label());
             } else
                 labels.append(info.m_replacementSource);
             m_exitSiteLabels.append(labels);
         }
     }

     for (unsigned i = 0; i < m_jitCode->osrExit.size(); ++i) {
         OSRExit& exit = m_jitCode->osrExit[i];
         OSRExitCompilationInfo& info = m_exitCompilationInfo[i];
         JumpList& failureJumps = info.m_failureJumps;
         if (!failureJumps.empty())
             failureJumps.link(this);
         else
             info.m_replacementDestination = label();
         jitAssertHasValidCallFrame();
         store32(TrustedImm32(i), &vm()->osrExitIndex);
         exit.setPatchableCodeOffset(patchableJump());
     }
 }

 void JITCompiler::compileEntry()
 {
     // This code currently matches the old JIT. In the function header we need to
     // save return address and call frame via the prologue and perform a fast stack check.
     // FIXME: https://bugs.webkit.org/show_bug.cgi?id=56292
     // We'll need to convert the remaining cti_ style calls (specifically the stack
     // check) which will be dependent on stack layout. (We'd need to account for this in
     // both normal return code and when jumping to an exception handler).
     emitFunctionPrologue();
     emitPutImmediateToCallFrameHeader(m_codeBlock, JSStack::CodeBlock);
     jitAssertTagsInPlace();
 }

 void JITCompiler::compileBody()
 {
     // We generate the speculative code path, followed by OSR exit code to return
     // to the old JIT code if speculations fail.

     bool compiledSpeculative = m_speculative->compile();
     ASSERT_UNUSED(compiledSpeculative, compiledSpeculative);
 }

 void JITCompiler::compileExceptionHandlers()
 {
     if (!m_exceptionChecksWithCallFrameRollback.empty()) {
         m_exceptionChecksWithCallFrameRollback.link(this);

         // lookupExceptionHandlerFromCallerFrame is passed two arguments, the VM and the exec (the CallFrame*).
         move(TrustedImmPtr(vm()), GPRInfo::argumentGPR0);
         move(GPRInfo::callFrameRegister, GPRInfo::argumentGPR1);
         addPtr(TrustedImm32(m_graph.stackPointerOffset() * sizeof(Register)), GPRInfo::callFrameRegister, stackPointerRegister);

 #if CPU(X86)
         // FIXME: should use the call abstraction, but this is currently in the SpeculativeJIT layer!
         poke(GPRInfo::argumentGPR0);
         poke(GPRInfo::argumentGPR1, 1);
 #endif
         m_calls.append(CallLinkRecord(call(), lookupExceptionHandlerFromCallerFrame));

         jumpToExceptionHandler();
     }

     if (!m_exceptionChecks.empty()) {
         m_exceptionChecks.link(this);

         // lookupExceptionHandler is passed two arguments, the VM and the exec (the CallFrame*).
         move(TrustedImmPtr(vm()), GPRInfo::argumentGPR0);
         move(GPRInfo::callFrameRegister, GPRInfo::argumentGPR1);

 #if CPU(X86)
         // FIXME: should use the call abstraction, but this is currently in the SpeculativeJIT layer!
         poke(GPRInfo::argumentGPR0);
         poke(GPRInfo::argumentGPR1, 1);
 #endif
         m_calls.append(CallLinkRecord(call(), lookupExceptionHandler));

         jumpToExceptionHandler();
     }
 }

 void JITCompiler::link(LinkBuffer& linkBuffer)
 {
     // Link the code, populate data in CodeBlock data structures.
     m_jitCode->common.frameRegisterCount = m_graph.frameRegisterCount();
     m_jitCode->common.requiredRegisterCountForExit = m_graph.requiredRegisterCountForExit();

     if (!m_graph.m_plan.inlineCallFrames->isEmpty())
         m_jitCode->common.inlineCallFrames = m_graph.m_plan.inlineCallFrames;

 #if USE(JSVALUE32_64)
     m_jitCode->common.doubleConstants = WTF::move(m_graph.m_doubleConstants);
 #endif

     m_graph.registerFrozenValues();

     BitVector usedJumpTables;
     for (Bag<SwitchData>::iterator iter = m_graph.m_switchData.begin(); !!iter; ++iter) {
         SwitchData& data = **iter;
         if (!data.didUseJumpTable)
             continue;

         if (data.kind == SwitchString)
             continue;

         RELEASE_ASSERT(data.kind == SwitchImm || data.kind == SwitchChar);

         usedJumpTables.set(data.switchTableIndex);
         SimpleJumpTable& table = m_codeBlock->switchJumpTable(data.switchTableIndex);
         table.ctiDefault = linkBuffer.locationOf(m_blockHeads[data.fallThrough.block->index]);
         table.ctiOffsets.grow(table.branchOffsets.size());
         for (unsigned j = table.ctiOffsets.size(); j--;)
             table.ctiOffsets[j] = table.ctiDefault;
         for (unsigned j = data.cases.size(); j--;) {
             SwitchCase& myCase = data.cases[j];
             table.ctiOffsets[myCase.value.switchLookupValue(data.kind) - table.min] =
                 linkBuffer.locationOf(m_blockHeads[myCase.target.block->index]);
         }
     }

     for (unsigned i = m_codeBlock->numberOfSwitchJumpTables(); i--;) {
         if (usedJumpTables.get(i))
             continue;

         m_codeBlock->switchJumpTable(i).clear();
     }

     // NOTE: we cannot clear string switch tables because (1) we're running concurrently
     // and we cannot deref StringImpl's and (2) it would be weird to deref those
     // StringImpl's since we refer to them.
     for (Bag<SwitchData>::iterator switchDataIter = m_graph.m_switchData.begin(); !!switchDataIter; ++switchDataIter) {
         SwitchData& data = **switchDataIter;
         if (!data.didUseJumpTable)
             continue;

         if (data.kind != SwitchString)
             continue;

         StringJumpTable& table = m_codeBlock->stringSwitchJumpTable(data.switchTableIndex);
         table.ctiDefault = linkBuffer.locationOf(m_blockHeads[data.fallThrough.block->index]);
         StringJumpTable::StringOffsetTable::iterator iter;
         StringJumpTable::StringOffsetTable::iterator end = table.offsetTable.end();
         for (iter = table.offsetTable.begin(); iter != end; ++iter)
             iter->value.ctiOffset = table.ctiDefault;
         for (unsigned j = data.cases.size(); j--;) {
             SwitchCase& myCase = data.cases[j];
             iter = table.offsetTable.find(myCase.value.stringImpl());
             RELEASE_ASSERT(iter != end);
             iter->value.ctiOffset = linkBuffer.locationOf(m_blockHeads[myCase.target.block->index]);
         }
     }

     // Link all calls out from the JIT code to their respective functions.
     for (unsigned i = 0; i < m_calls.size(); ++i)
         linkBuffer.link(m_calls[i].m_call, m_calls[i].m_function);

     for (unsigned i = m_getByIds.size(); i--;)
         m_getByIds[i].finalize(linkBuffer);
     for (unsigned i = m_putByIds.size(); i--;)
         m_putByIds[i].finalize(linkBuffer);

     for (unsigned i = 0; i < m_ins.size(); ++i) {
         StructureStubInfo& info = *m_ins[i].m_stubInfo;
         CodeLocationCall callReturnLocation = linkBuffer.locationOf(m_ins[i].m_slowPathGenerator->call());
         info.patch.deltaCallToDone = differenceBetweenCodePtr(callReturnLocation, linkBuffer.locationOf(m_ins[i].m_done));
         info.patch.deltaCallToJump = differenceBetweenCodePtr(callReturnLocation, linkBuffer.locationOf(m_ins[i].m_jump));
         info.callReturnLocation = callReturnLocation;
         info.patch.deltaCallToSlowCase = differenceBetweenCodePtr(callReturnLocation, linkBuffer.locationOf(m_ins[i].m_slowPathGenerator->label()));
     }

     for (unsigned i = 0; i < m_jsCalls.size(); ++i) {
         JSCallRecord& record = m_jsCalls[i];
         CallLinkInfo& info = *record.m_info;
         linkBuffer.link(record.m_slowCall, FunctionPtr(m_vm->getCTIStub(linkCallThunkGenerator).code().executableAddress()));
         info.setCallLocations(linkBuffer.locationOfNearCall(record.m_slowCall),
             linkBuffer.locationOf(record.m_targetToCheck),
             linkBuffer.locationOfNearCall(record.m_fastCall));
     }

     MacroAssemblerCodeRef osrExitThunk = vm()->getCTIStub(osrExitGenerationThunkGenerator);
     CodeLocationLabel target = CodeLocationLabel(osrExitThunk.code());
     for (unsigned i = 0; i < m_jitCode->osrExit.size(); ++i) {
         OSRExit& exit = m_jitCode->osrExit[i];
         OSRExitCompilationInfo& info = m_exitCompilationInfo[i];
         linkBuffer.link(exit.getPatchableCodeOffsetAsJump(), target);
         exit.correctJump(linkBuffer);
         if (info.m_replacementSource.isSet()) {
             m_jitCode->common.jumpReplacements.append(JumpReplacement(
                 linkBuffer.locationOf(info.m_replacementSource),
                 linkBuffer.locationOf(info.m_replacementDestination)));
         }
     }

     if (m_graph.compilation()) {
         ASSERT(m_exitSiteLabels.size() == m_jitCode->osrExit.size());
         for (unsigned i = 0; i < m_exitSiteLabels.size(); ++i) {
             Vector<Label>& labels = m_exitSiteLabels[i];
             Vector<const void*> addresses;
             for (unsigned j = 0; j < labels.size(); ++j)
                 addresses.append(linkBuffer.locationOf(labels[j]).executableAddress());
             m_graph.compilation()->addOSRExitSite(addresses);
         }
     } else
         ASSERT(!m_exitSiteLabels.size());

     m_jitCode->common.compilation = m_graph.compilation();

 }

 void JITCompiler::compile()
 {
     SamplingRegion samplingRegion("DFG Backend");

     setStartOfCode();
     compileEntry();
     m_speculative = std::make_unique<SpeculativeJIT>(*this);

     // Plant a check that sufficient space is available in the JSStack.
     addPtr(TrustedImm32(virtualRegisterForLocal(m_graph.requiredRegisterCountForExecutionAndExit() - 1).offset() * sizeof(Register)), GPRInfo::callFrameRegister, GPRInfo::regT1);
     Jump stackOverflow = branchPtr(Above, AbsoluteAddress(m_vm->addressOfStackLimit()), GPRInfo::regT1);

     addPtr(TrustedImm32(m_graph.stackPointerOffset() * sizeof(Register)), GPRInfo::callFrameRegister, stackPointerRegister);
     checkStackPointerAlignment();
     compileBody();
     setEndOfMainPath();

     // === Footer code generation ===
     //
     // Generate the stack overflow handling; if the stack check in the entry head fails,
     // we need to call out to a helper function to throw the StackOverflowError.
     stackOverflow.link(this);

     emitStoreCodeOrigin(CodeOrigin(0));

     if (maxFrameExtentForSlowPathCall)
         addPtr(TrustedImm32(-maxFrameExtentForSlowPathCall), stackPointerRegister);

     m_speculative->callOperationWithCallFrameRollbackOnException(operationThrowStackOverflowError, m_codeBlock);

     // Generate slow path code.
     m_speculative->runSlowPathGenerators();

     compileExceptionHandlers();
     linkOSRExits();

     // Create OSR entry trampolines if necessary.
     m_speculative->createOSREntries();
     setEndOfCode();

     auto linkBuffer = std::make_unique<LinkBuffer>(*m_vm, *this, m_codeBlock, JITCompilationCanFail);
     if (linkBuffer->didFailToAllocate()) {
         m_graph.m_plan.finalizer = std::make_unique<FailedFinalizer>(m_graph.m_plan);
         return;
     }

     link(*linkBuffer);
     m_speculative->linkOSREntries(*linkBuffer);

     m_jitCode->shrinkToFit();
     codeBlock()->shrinkToFit(CodeBlock::LateShrink);

     disassemble(*linkBuffer);

     m_graph.m_plan.finalizer = std::make_unique<JITFinalizer>(
         m_graph.m_plan, m_jitCode.release(), WTF::move(linkBuffer));
 }

 void JITCompiler::compileFunction()
 {
     SamplingRegion samplingRegion("DFG Backend");

     setStartOfCode();
     compileEntry();

     // === Function header code generation ===
     // This is the main entry point, without performing an arity check.
     // If we needed to perform an arity check we will already have moved the return address,
     // so enter after this.
     Label fromArityCheck(this);
     // Plant a check that sufficient space is available in the JSStack.
     addPtr(TrustedImm32(virtualRegisterForLocal(m_graph.requiredRegisterCountForExecutionAndExit() - 1).offset() * sizeof(Register)), GPRInfo::callFrameRegister, GPRInfo::regT1);
     Jump stackOverflow = branchPtr(Above, AbsoluteAddress(m_vm->addressOfStackLimit()), GPRInfo::regT1);

     // Move the stack pointer down to accommodate locals
     addPtr(TrustedImm32(m_graph.stackPointerOffset() * sizeof(Register)), GPRInfo::callFrameRegister, stackPointerRegister);
     checkStackPointerAlignment();

     // === Function body code generation ===
     m_speculative = std::make_unique<SpeculativeJIT>(*this);
     compileBody();
     setEndOfMainPath();

     // === Function footer code generation ===
     //
     // Generate code to perform the stack overflow handling (if the stack check in
     // the function header fails), and generate the entry point with arity check.
     //
     // Generate the stack overflow handling; if the stack check in the function head fails,
     // we need to call out to a helper function to throw the StackOverflowError.
     stackOverflow.link(this);

     emitStoreCodeOrigin(CodeOrigin(0));

     if (maxFrameExtentForSlowPathCall)
         addPtr(TrustedImm32(-maxFrameExtentForSlowPathCall), stackPointerRegister);

     m_speculative->callOperationWithCallFrameRollbackOnException(operationThrowStackOverflowError, m_codeBlock);

     // The fast entry point into a function does not check the correct number of arguments
     // have been passed to the call (we only use the fast entry point where we can statically
     // determine the correct number of arguments have been passed, or have already checked).
     // In cases where an arity check is necessary, we enter here.
     // FIXME: change this from a cti call to a DFG style operation (normal C calling conventions).
     m_arityCheck = label();
     compileEntry();

     load32(AssemblyHelpers::payloadFor((VirtualRegister)JSStack::ArgumentCount), GPRInfo::regT1);
     branch32(AboveOrEqual, GPRInfo::regT1, TrustedImm32(m_codeBlock->numParameters())).linkTo(fromArityCheck, this);
     emitStoreCodeOrigin(CodeOrigin(0));
     if (maxFrameExtentForSlowPathCall)
         addPtr(TrustedImm32(-maxFrameExtentForSlowPathCall), stackPointerRegister);
     m_speculative->callOperationWithCallFrameRollbackOnException(m_codeBlock->m_isConstructor ? operationConstructArityCheck : operationCallArityCheck, GPRInfo::regT0);
     if (maxFrameExtentForSlowPathCall)
         addPtr(TrustedImm32(maxFrameExtentForSlowPathCall), stackPointerRegister);
     branchTest32(Zero, GPRInfo::regT0).linkTo(fromArityCheck, this);
     emitStoreCodeOrigin(CodeOrigin(0));
     GPRReg thunkReg;
 #if USE(JSVALUE64)
     thunkReg = GPRInfo::regT7;
 #else
     thunkReg = GPRInfo::regT5;
 #endif
     CodeLocationLabel* arityThunkLabels =
         m_vm->arityCheckFailReturnThunks->returnPCsFor(*m_vm, m_codeBlock->numParameters());
     move(TrustedImmPtr(arityThunkLabels), thunkReg);
     loadPtr(BaseIndex(thunkReg, GPRInfo::regT0, timesPtr()), thunkReg);
     m_callArityFixup = call();
     jump(fromArityCheck);

     // Generate slow path code.
     m_speculative->runSlowPathGenerators();

     compileExceptionHandlers();
     linkOSRExits();

     // Create OSR entry trampolines if necessary.
     m_speculative->createOSREntries();
     setEndOfCode();

     // === Link ===
     auto linkBuffer = std::make_unique<LinkBuffer>(*m_vm, *this, m_codeBlock, JITCompilationCanFail);
     if (linkBuffer->didFailToAllocate()) {
         m_graph.m_plan.finalizer = std::make_unique<FailedFinalizer>(m_graph.m_plan);
         return;
     }
     link(*linkBuffer);
     m_speculative->linkOSREntries(*linkBuffer);

     m_jitCode->shrinkToFit();
     codeBlock()->shrinkToFit(CodeBlock::LateShrink);

     linkBuffer->link(m_callArityFixup, FunctionPtr((m_vm->getCTIStub(arityFixupGenerator)).code().executableAddress()));

     disassemble(*linkBuffer);

     MacroAssemblerCodePtr withArityCheck = linkBuffer->locationOf(m_arityCheck);

     m_graph.m_plan.finalizer = std::make_unique<JITFinalizer>(
         m_graph.m_plan, m_jitCode.release(), WTF::move(linkBuffer), withArityCheck);
 }

 void JITCompiler::disassemble(LinkBuffer& linkBuffer)
 {
     if (shouldShowDisassembly()) {
         m_disassembler->dump(linkBuffer);
         linkBuffer.didAlreadyDisassemble();
     }

     if (m_graph.m_plan.compilation)
         m_disassembler->reportToProfiler(m_graph.m_plan.compilation.get(), linkBuffer);
 }

 #if USE(JSVALUE32_64)
 void* JITCompiler::addressOfDoubleConstant(Node* node)
 {
     double value = node->asNumber();
     int64_t valueBits = bitwise_cast<int64_t>(value);
     auto it = m_graph.m_doubleConstantsMap.find(valueBits);
     if (it != m_graph.m_doubleConstantsMap.end())
         return it->second;

     if (!m_graph.m_doubleConstants)
         m_graph.m_doubleConstants = std::make_unique<Bag<double>>();

     double* addressInConstantPool = m_graph.m_doubleConstants->add();
     *addressInConstantPool = value;
     m_graph.m_doubleConstantsMap[valueBits] = addressInConstantPool;
     return addressInConstantPool;
 }
 #endif

 void JITCompiler::noticeOSREntry(BasicBlock& basicBlock, JITCompiler::Label blockHead, LinkBuffer& linkBuffer)
 {
     // OSR entry is not allowed into blocks deemed unreachable by control flow analysis.
     if (!basicBlock.intersectionOfCFAHasVisited)
         return;

     OSREntryData* entry = m_jitCode->appendOSREntryData(basicBlock.bytecodeBegin, linkBuffer.offsetOf(blockHead));

     entry->m_expectedValues = basicBlock.intersectionOfPastValuesAtHead;

     // Fix the expected values: in our protocol, a dead variable will have an expected
     // value of (None, []). But the old JIT may stash some values there. So we really
     // need (Top, TOP).
     for (size_t argument = 0; argument < basicBlock.variablesAtHead.numberOfArguments(); ++argument) {
         Node* node = basicBlock.variablesAtHead.argument(argument);
         if (!node || !node->shouldGenerate())
             entry->m_expectedValues.argument(argument).makeHeapTop();
     }
     for (size_t local = 0; local < basicBlock.variablesAtHead.numberOfLocals(); ++local) {
         Node* node = basicBlock.variablesAtHead.local(local);
         if (!node || !node->shouldGenerate())
             entry->m_expectedValues.local(local).makeHeapTop();
         else {
             VariableAccessData* variable = node->variableAccessData();
             entry->m_machineStackUsed.set(variable->machineLocal().toLocal());

             switch (variable->flushFormat()) {
             case FlushedDouble:
                 entry->m_localsForcedDouble.set(local);
                 break;
             case FlushedInt52:
                 entry->m_localsForcedMachineInt.set(local);
                 break;
             default:
                 break;
             }

             if (variable->local() != variable->machineLocal()) {
                 entry->m_reshufflings.append(
                     OSREntryReshuffling(
                         variable->local().offset(), variable->machineLocal().offset()));
             }
         }
     }

     entry->m_reshufflings.shrinkToFit();
 }

 } } // namespace JSC::DFG

 #endif // ENABLE(DFG_JIT)
	/*
	* Copyright (C) 2011, 2013-2015 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 "DFGJITCompiler.h"

	#if ENABLE(DFG_JIT)

	#include "ArityCheckFailReturnThunks.h"
	#include "CodeBlock.h"
	#include "DFGFailedFinalizer.h"
	#include "DFGInlineCacheWrapperInlines.h"
	#include "DFGJITCode.h"
	#include "DFGJITFinalizer.h"
	#include "DFGOSRExitCompiler.h"
	#include "DFGOperations.h"
	#include "DFGRegisterBank.h"
	#include "DFGSlowPathGenerator.h"
	#include "DFGSpeculativeJIT.h"
	#include "DFGThunks.h"
	#include "JSCJSValueInlines.h"
	#include "LinkBuffer.h"
	#include "MaxFrameExtentForSlowPathCall.h"
	#include "JSCInlines.h"
	#include "VM.h"

	namespace JSC { namespace DFG {

	JITCompiler::JITCompiler(Graph& dfg)
	: CCallHelpers(&dfg.m_vm, dfg.m_codeBlock)
	, m_graph(dfg)
	, m_jitCode(adoptRef(new JITCode()))
	, m_blockHeads(dfg.numBlocks())
	{
	if (shouldShowDisassembly() \|\| m_graph.m_vm.m_perBytecodeProfiler)
	m_disassembler = std::make_unique<Disassembler>(dfg);
	}

	JITCompiler::~JITCompiler()
	{
	}

	void JITCompiler::linkOSRExits()
	{
	ASSERT(m_jitCode->osrExit.size() == m_exitCompilationInfo.size());
	if (m_graph.compilation()) {
	for (unsigned i = 0; i < m_jitCode->osrExit.size(); ++i) {
	OSRExitCompilationInfo& info = m_exitCompilationInfo[i];
	Vector<Label> labels;
	if (!info.m_failureJumps.empty()) {
	for (unsigned j = 0; j < info.m_failureJumps.jumps().size(); ++j)
	labels.append(info.m_failureJumps.jumps()[j].label());
	} else
	labels.append(info.m_replacementSource);
	m_exitSiteLabels.append(labels);
	}
	}

	for (unsigned i = 0; i < m_jitCode->osrExit.size(); ++i) {
	OSRExit& exit = m_jitCode->osrExit[i];
	OSRExitCompilationInfo& info = m_exitCompilationInfo[i];
	JumpList& failureJumps = info.m_failureJumps;
	if (!failureJumps.empty())
	failureJumps.link(this);
	else
	info.m_replacementDestination = label();
	jitAssertHasValidCallFrame();
	store32(TrustedImm32(i), &vm()->osrExitIndex);
	exit.setPatchableCodeOffset(patchableJump());
	}
	}

	void JITCompiler::compileEntry()
	{
	// This code currently matches the old JIT. In the function header we need to
	// save return address and call frame via the prologue and perform a fast stack check.
	// FIXME: https://bugs.webkit.org/show_bug.cgi?id=56292
	// We'll need to convert the remaining cti_ style calls (specifically the stack
	// check) which will be dependent on stack layout. (We'd need to account for this in
	// both normal return code and when jumping to an exception handler).
	emitFunctionPrologue();
	emitPutImmediateToCallFrameHeader(m_codeBlock, JSStack::CodeBlock);
	jitAssertTagsInPlace();
	}

	void JITCompiler::compileBody()
	{
	// We generate the speculative code path, followed by OSR exit code to return
	// to the old JIT code if speculations fail.

	bool compiledSpeculative = m_speculative->compile();
	ASSERT_UNUSED(compiledSpeculative, compiledSpeculative);
	}

	void JITCompiler::compileExceptionHandlers()
	{
	if (!m_exceptionChecksWithCallFrameRollback.empty()) {
	m_exceptionChecksWithCallFrameRollback.link(this);

	// lookupExceptionHandlerFromCallerFrame is passed two arguments, the VM and the exec (the CallFrame*).
	move(TrustedImmPtr(vm()), GPRInfo::argumentGPR0);
	move(GPRInfo::callFrameRegister, GPRInfo::argumentGPR1);
	addPtr(TrustedImm32(m_graph.stackPointerOffset() * sizeof(Register)), GPRInfo::callFrameRegister, stackPointerRegister);

	#if CPU(X86)
	// FIXME: should use the call abstraction, but this is currently in the SpeculativeJIT layer!
	poke(GPRInfo::argumentGPR0);
	poke(GPRInfo::argumentGPR1, 1);
	#endif
	m_calls.append(CallLinkRecord(call(), lookupExceptionHandlerFromCallerFrame));

	jumpToExceptionHandler();
	}

	if (!m_exceptionChecks.empty()) {
	m_exceptionChecks.link(this);

	// lookupExceptionHandler is passed two arguments, the VM and the exec (the CallFrame*).
	move(TrustedImmPtr(vm()), GPRInfo::argumentGPR0);
	move(GPRInfo::callFrameRegister, GPRInfo::argumentGPR1);

	#if CPU(X86)
	// FIXME: should use the call abstraction, but this is currently in the SpeculativeJIT layer!
	poke(GPRInfo::argumentGPR0);
	poke(GPRInfo::argumentGPR1, 1);
	#endif
	m_calls.append(CallLinkRecord(call(), lookupExceptionHandler));

	jumpToExceptionHandler();
	}
	}

	void JITCompiler::link(LinkBuffer& linkBuffer)
	{
	// Link the code, populate data in CodeBlock data structures.
	m_jitCode->common.frameRegisterCount = m_graph.frameRegisterCount();
	m_jitCode->common.requiredRegisterCountForExit = m_graph.requiredRegisterCountForExit();

	if (!m_graph.m_plan.inlineCallFrames->isEmpty())
	m_jitCode->common.inlineCallFrames = m_graph.m_plan.inlineCallFrames;

	#if USE(JSVALUE32_64)
	m_jitCode->common.doubleConstants = WTF::move(m_graph.m_doubleConstants);
	#endif

	m_graph.registerFrozenValues();

	BitVector usedJumpTables;
	for (Bag<SwitchData>::iterator iter = m_graph.m_switchData.begin(); !!iter; ++iter) {
	SwitchData& data = **iter;
	if (!data.didUseJumpTable)
	continue;

	if (data.kind == SwitchString)
	continue;

	RELEASE_ASSERT(data.kind == SwitchImm \|\| data.kind == SwitchChar);

	usedJumpTables.set(data.switchTableIndex);
	SimpleJumpTable& table = m_codeBlock->switchJumpTable(data.switchTableIndex);
	table.ctiDefault = linkBuffer.locationOf(m_blockHeads[data.fallThrough.block->index]);
	table.ctiOffsets.grow(table.branchOffsets.size());
	for (unsigned j = table.ctiOffsets.size(); j--;)
	table.ctiOffsets[j] = table.ctiDefault;
	for (unsigned j = data.cases.size(); j--;) {
	SwitchCase& myCase = data.cases[j];
	table.ctiOffsets[myCase.value.switchLookupValue(data.kind) - table.min] =
	linkBuffer.locationOf(m_blockHeads[myCase.target.block->index]);
	}
	}

	for (unsigned i = m_codeBlock->numberOfSwitchJumpTables(); i--;) {
	if (usedJumpTables.get(i))
	continue;

	m_codeBlock->switchJumpTable(i).clear();
	}

	// NOTE: we cannot clear string switch tables because (1) we're running concurrently
	// and we cannot deref StringImpl's and (2) it would be weird to deref those
	// StringImpl's since we refer to them.
	for (Bag<SwitchData>::iterator switchDataIter = m_graph.m_switchData.begin(); !!switchDataIter; ++switchDataIter) {
	SwitchData& data = **switchDataIter;
	if (!data.didUseJumpTable)
	continue;

	if (data.kind != SwitchString)
	continue;

	StringJumpTable& table = m_codeBlock->stringSwitchJumpTable(data.switchTableIndex);
	table.ctiDefault = linkBuffer.locationOf(m_blockHeads[data.fallThrough.block->index]);
	StringJumpTable::StringOffsetTable::iterator iter;
	StringJumpTable::StringOffsetTable::iterator end = table.offsetTable.end();
	for (iter = table.offsetTable.begin(); iter != end; ++iter)
	iter->value.ctiOffset = table.ctiDefault;
	for (unsigned j = data.cases.size(); j--;) {
	SwitchCase& myCase = data.cases[j];
	iter = table.offsetTable.find(myCase.value.stringImpl());
	RELEASE_ASSERT(iter != end);
	iter->value.ctiOffset = linkBuffer.locationOf(m_blockHeads[myCase.target.block->index]);
	}
	}

	// Link all calls out from the JIT code to their respective functions.
	for (unsigned i = 0; i < m_calls.size(); ++i)
	linkBuffer.link(m_calls[i].m_call, m_calls[i].m_function);

	for (unsigned i = m_getByIds.size(); i--;)
	m_getByIds[i].finalize(linkBuffer);
	for (unsigned i = m_putByIds.size(); i--;)
	m_putByIds[i].finalize(linkBuffer);

	for (unsigned i = 0; i < m_ins.size(); ++i) {
	StructureStubInfo& info = *m_ins[i].m_stubInfo;
	CodeLocationCall callReturnLocation = linkBuffer.locationOf(m_ins[i].m_slowPathGenerator->call());
	info.patch.deltaCallToDone = differenceBetweenCodePtr(callReturnLocation, linkBuffer.locationOf(m_ins[i].m_done));
	info.patch.deltaCallToJump = differenceBetweenCodePtr(callReturnLocation, linkBuffer.locationOf(m_ins[i].m_jump));
	info.callReturnLocation = callReturnLocation;
	info.patch.deltaCallToSlowCase = differenceBetweenCodePtr(callReturnLocation, linkBuffer.locationOf(m_ins[i].m_slowPathGenerator->label()));
	}

	for (unsigned i = 0; i < m_jsCalls.size(); ++i) {
	JSCallRecord& record = m_jsCalls[i];
	CallLinkInfo& info = *record.m_info;
	linkBuffer.link(record.m_slowCall, FunctionPtr(m_vm->getCTIStub(linkCallThunkGenerator).code().executableAddress()));
	info.setCallLocations(linkBuffer.locationOfNearCall(record.m_slowCall),
	linkBuffer.locationOf(record.m_targetToCheck),
	linkBuffer.locationOfNearCall(record.m_fastCall));
	}

	MacroAssemblerCodeRef osrExitThunk = vm()->getCTIStub(osrExitGenerationThunkGenerator);
	CodeLocationLabel target = CodeLocationLabel(osrExitThunk.code());
	for (unsigned i = 0; i < m_jitCode->osrExit.size(); ++i) {
	OSRExit& exit = m_jitCode->osrExit[i];
	OSRExitCompilationInfo& info = m_exitCompilationInfo[i];
	linkBuffer.link(exit.getPatchableCodeOffsetAsJump(), target);
	exit.correctJump(linkBuffer);
	if (info.m_replacementSource.isSet()) {
	m_jitCode->common.jumpReplacements.append(JumpReplacement(
	linkBuffer.locationOf(info.m_replacementSource),
	linkBuffer.locationOf(info.m_replacementDestination)));
	}
	}

	if (m_graph.compilation()) {
	ASSERT(m_exitSiteLabels.size() == m_jitCode->osrExit.size());
	for (unsigned i = 0; i < m_exitSiteLabels.size(); ++i) {
	Vector<Label>& labels = m_exitSiteLabels[i];
	Vector<const void*> addresses;
	for (unsigned j = 0; j < labels.size(); ++j)
	addresses.append(linkBuffer.locationOf(labels[j]).executableAddress());
	m_graph.compilation()->addOSRExitSite(addresses);
	}
	} else
	ASSERT(!m_exitSiteLabels.size());

	m_jitCode->common.compilation = m_graph.compilation();

	}

	void JITCompiler::compile()
	{
	SamplingRegion samplingRegion("DFG Backend");

	setStartOfCode();
	compileEntry();
	m_speculative = std::make_unique<SpeculativeJIT>(*this);

	// Plant a check that sufficient space is available in the JSStack.
	addPtr(TrustedImm32(virtualRegisterForLocal(m_graph.requiredRegisterCountForExecutionAndExit() - 1).offset() * sizeof(Register)), GPRInfo::callFrameRegister, GPRInfo::regT1);
	Jump stackOverflow = branchPtr(Above, AbsoluteAddress(m_vm->addressOfStackLimit()), GPRInfo::regT1);

	addPtr(TrustedImm32(m_graph.stackPointerOffset() * sizeof(Register)), GPRInfo::callFrameRegister, stackPointerRegister);
	checkStackPointerAlignment();
	compileBody();
	setEndOfMainPath();

	// === Footer code generation ===
	//
	// Generate the stack overflow handling; if the stack check in the entry head fails,
	// we need to call out to a helper function to throw the StackOverflowError.
	stackOverflow.link(this);

	emitStoreCodeOrigin(CodeOrigin(0));

	if (maxFrameExtentForSlowPathCall)
	addPtr(TrustedImm32(-maxFrameExtentForSlowPathCall), stackPointerRegister);

	m_speculative->callOperationWithCallFrameRollbackOnException(operationThrowStackOverflowError, m_codeBlock);

	// Generate slow path code.
	m_speculative->runSlowPathGenerators();

	compileExceptionHandlers();
	linkOSRExits();

	// Create OSR entry trampolines if necessary.
	m_speculative->createOSREntries();
	setEndOfCode();

	auto linkBuffer = std::make_unique<LinkBuffer>(m_vm, this, m_codeBlock, JITCompilationCanFail);
	if (linkBuffer->didFailToAllocate()) {
	m_graph.m_plan.finalizer = std::make_unique<FailedFinalizer>(m_graph.m_plan);
	return;
	}

	link(*linkBuffer);
	m_speculative->linkOSREntries(*linkBuffer);

	m_jitCode->shrinkToFit();
	codeBlock()->shrinkToFit(CodeBlock::LateShrink);

	disassemble(*linkBuffer);

	m_graph.m_plan.finalizer = std::make_unique<JITFinalizer>(
	m_graph.m_plan, m_jitCode.release(), WTF::move(linkBuffer));
	}

	void JITCompiler::compileFunction()
	{
	SamplingRegion samplingRegion("DFG Backend");

	setStartOfCode();
	compileEntry();

	// === Function header code generation ===
	// This is the main entry point, without performing an arity check.
	// If we needed to perform an arity check we will already have moved the return address,
	// so enter after this.
	Label fromArityCheck(this);
	// Plant a check that sufficient space is available in the JSStack.
	addPtr(TrustedImm32(virtualRegisterForLocal(m_graph.requiredRegisterCountForExecutionAndExit() - 1).offset() * sizeof(Register)), GPRInfo::callFrameRegister, GPRInfo::regT1);
	Jump stackOverflow = branchPtr(Above, AbsoluteAddress(m_vm->addressOfStackLimit()), GPRInfo::regT1);

	// Move the stack pointer down to accommodate locals
	addPtr(TrustedImm32(m_graph.stackPointerOffset() * sizeof(Register)), GPRInfo::callFrameRegister, stackPointerRegister);
	checkStackPointerAlignment();

	// === Function body code generation ===
	m_speculative = std::make_unique<SpeculativeJIT>(*this);
	compileBody();
	setEndOfMainPath();

	// === Function footer code generation ===
	//
	// Generate code to perform the stack overflow handling (if the stack check in
	// the function header fails), and generate the entry point with arity check.
	//
	// Generate the stack overflow handling; if the stack check in the function head fails,
	// we need to call out to a helper function to throw the StackOverflowError.
	stackOverflow.link(this);

	emitStoreCodeOrigin(CodeOrigin(0));

	if (maxFrameExtentForSlowPathCall)
	addPtr(TrustedImm32(-maxFrameExtentForSlowPathCall), stackPointerRegister);

	m_speculative->callOperationWithCallFrameRollbackOnException(operationThrowStackOverflowError, m_codeBlock);

	// The fast entry point into a function does not check the correct number of arguments
	// have been passed to the call (we only use the fast entry point where we can statically
	// determine the correct number of arguments have been passed, or have already checked).
	// In cases where an arity check is necessary, we enter here.
	// FIXME: change this from a cti call to a DFG style operation (normal C calling conventions).
	m_arityCheck = label();
	compileEntry();

	load32(AssemblyHelpers::payloadFor((VirtualRegister)JSStack::ArgumentCount), GPRInfo::regT1);
	branch32(AboveOrEqual, GPRInfo::regT1, TrustedImm32(m_codeBlock->numParameters())).linkTo(fromArityCheck, this);
	emitStoreCodeOrigin(CodeOrigin(0));
	if (maxFrameExtentForSlowPathCall)
	addPtr(TrustedImm32(-maxFrameExtentForSlowPathCall), stackPointerRegister);
	m_speculative->callOperationWithCallFrameRollbackOnException(m_codeBlock->m_isConstructor ? operationConstructArityCheck : operationCallArityCheck, GPRInfo::regT0);
	if (maxFrameExtentForSlowPathCall)
	addPtr(TrustedImm32(maxFrameExtentForSlowPathCall), stackPointerRegister);
	branchTest32(Zero, GPRInfo::regT0).linkTo(fromArityCheck, this);
	emitStoreCodeOrigin(CodeOrigin(0));
	GPRReg thunkReg;
	#if USE(JSVALUE64)
	thunkReg = GPRInfo::regT7;
	#else
	thunkReg = GPRInfo::regT5;
	#endif
	CodeLocationLabel* arityThunkLabels =
	m_vm->arityCheckFailReturnThunks->returnPCsFor(*m_vm, m_codeBlock->numParameters());
	move(TrustedImmPtr(arityThunkLabels), thunkReg);
	loadPtr(BaseIndex(thunkReg, GPRInfo::regT0, timesPtr()), thunkReg);
	m_callArityFixup = call();
	jump(fromArityCheck);

	// Generate slow path code.
	m_speculative->runSlowPathGenerators();

	compileExceptionHandlers();
	linkOSRExits();

	// Create OSR entry trampolines if necessary.
	m_speculative->createOSREntries();
	setEndOfCode();

	// === Link ===
	auto linkBuffer = std::make_unique<LinkBuffer>(m_vm, this, m_codeBlock, JITCompilationCanFail);
	if (linkBuffer->didFailToAllocate()) {
	m_graph.m_plan.finalizer = std::make_unique<FailedFinalizer>(m_graph.m_plan);
	return;
	}
	link(*linkBuffer);
	m_speculative->linkOSREntries(*linkBuffer);

	m_jitCode->shrinkToFit();
	codeBlock()->shrinkToFit(CodeBlock::LateShrink);

	linkBuffer->link(m_callArityFixup, FunctionPtr((m_vm->getCTIStub(arityFixupGenerator)).code().executableAddress()));

	disassemble(*linkBuffer);

	MacroAssemblerCodePtr withArityCheck = linkBuffer->locationOf(m_arityCheck);

	m_graph.m_plan.finalizer = std::make_unique<JITFinalizer>(
	m_graph.m_plan, m_jitCode.release(), WTF::move(linkBuffer), withArityCheck);
	}

	void JITCompiler::disassemble(LinkBuffer& linkBuffer)
	{
	if (shouldShowDisassembly()) {
	m_disassembler->dump(linkBuffer);
	linkBuffer.didAlreadyDisassemble();
	}

	if (m_graph.m_plan.compilation)
	m_disassembler->reportToProfiler(m_graph.m_plan.compilation.get(), linkBuffer);
	}

	#if USE(JSVALUE32_64)
	void* JITCompiler::addressOfDoubleConstant(Node* node)
	{
	double value = node->asNumber();
	int64_t valueBits = bitwise_cast<int64_t>(value);
	auto it = m_graph.m_doubleConstantsMap.find(valueBits);
	if (it != m_graph.m_doubleConstantsMap.end())
	return it->second;

	if (!m_graph.m_doubleConstants)
	m_graph.m_doubleConstants = std::make_unique<Bag<double>>();

	double* addressInConstantPool = m_graph.m_doubleConstants->add();
	*addressInConstantPool = value;
	m_graph.m_doubleConstantsMap[valueBits] = addressInConstantPool;
	return addressInConstantPool;
	}
	#endif

	void JITCompiler::noticeOSREntry(BasicBlock& basicBlock, JITCompiler::Label blockHead, LinkBuffer& linkBuffer)
	{
	// OSR entry is not allowed into blocks deemed unreachable by control flow analysis.
	if (!basicBlock.intersectionOfCFAHasVisited)
	return;

	OSREntryData* entry = m_jitCode->appendOSREntryData(basicBlock.bytecodeBegin, linkBuffer.offsetOf(blockHead));

	entry->m_expectedValues = basicBlock.intersectionOfPastValuesAtHead;

	// Fix the expected values: in our protocol, a dead variable will have an expected
	// value of (None, []). But the old JIT may stash some values there. So we really
	// need (Top, TOP).
	for (size_t argument = 0; argument < basicBlock.variablesAtHead.numberOfArguments(); ++argument) {
	Node* node = basicBlock.variablesAtHead.argument(argument);
	if (!node \|\| !node->shouldGenerate())
	entry->m_expectedValues.argument(argument).makeHeapTop();
	}
	for (size_t local = 0; local < basicBlock.variablesAtHead.numberOfLocals(); ++local) {
	Node* node = basicBlock.variablesAtHead.local(local);
	if (!node \|\| !node->shouldGenerate())
	entry->m_expectedValues.local(local).makeHeapTop();
	else {
	VariableAccessData* variable = node->variableAccessData();
	entry->m_machineStackUsed.set(variable->machineLocal().toLocal());

	switch (variable->flushFormat()) {
	case FlushedDouble:
	entry->m_localsForcedDouble.set(local);
	break;
	case FlushedInt52:
	entry->m_localsForcedMachineInt.set(local);
	break;
	default:
	break;
	}

	if (variable->local() != variable->machineLocal()) {
	entry->m_reshufflings.append(
	OSREntryReshuffling(
	variable->local().offset(), variable->machineLocal().offset()));
	}
	}
	}

	entry->m_reshufflings.shrinkToFit();
	}

	} } // namespace JSC::DFG

	#endif // ENABLE(DFG_JIT)