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/*
* Copyright (C) 2008-2018 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"
#if ENABLE(JIT)
#include "JIT.h"
#include "BytecodeGraph.h"
#include "CodeBlock.h"
#include "CodeBlockWithJITType.h"
#include "DFGCapabilities.h"
#include "InterpreterInlines.h"
#include "JITInlines.h"
#include "JITOperations.h"
#include "JSArray.h"
#include "JSCInlines.h"
#include "JSFunction.h"
#include "LinkBuffer.h"
#include "MaxFrameExtentForSlowPathCall.h"
#include "ModuleProgramCodeBlock.h"
#include "PCToCodeOriginMap.h"
#include "ProfilerDatabase.h"
#include "ProgramCodeBlock.h"
#include "ResultType.h"
#include "SlowPathCall.h"
#include "StackAlignment.h"
#include "ThunkGenerators.h"
#include "TypeProfilerLog.h"
#include <wtf/CryptographicallyRandomNumber.h>
#include <wtf/GraphNodeWorklist.h>
#include <wtf/SimpleStats.h>
using namespace std;
namespace JSC {
namespace JITInternal {
static constexpr const bool verbose = false;
}
Seconds totalBaselineCompileTime;
Seconds totalDFGCompileTime;
Seconds totalFTLCompileTime;
Seconds totalFTLDFGCompileTime;
Seconds totalFTLB3CompileTime;
void ctiPatchCallByReturnAddress(ReturnAddressPtr returnAddress, FunctionPtr<CFunctionPtrTag> newCalleeFunction)
{
MacroAssembler::repatchCall(
CodeLocationCall<NoPtrTag>(MacroAssemblerCodePtr<NoPtrTag>(returnAddress)),
newCalleeFunction.retagged<OperationPtrTag>());
}
JIT::JIT(VM* vm, CodeBlock* codeBlock, unsigned loopOSREntryBytecodeOffset)
: JSInterfaceJIT(vm, codeBlock)
, m_interpreter(vm->interpreter)
, m_labels(codeBlock ? codeBlock->numberOfInstructions() : 0)
, m_bytecodeOffset(std::numeric_limits<unsigned>::max())
, m_getByIdIndex(UINT_MAX)
, m_getByIdWithThisIndex(UINT_MAX)
, m_putByIdIndex(UINT_MAX)
, m_byValInstructionIndex(UINT_MAX)
, m_callLinkInfoIndex(UINT_MAX)
, m_pcToCodeOriginMapBuilder(*vm)
, m_canBeOptimized(false)
, m_shouldEmitProfiling(false)
, m_shouldUseIndexMasking(Options::enableSpectreMitigations())
, m_loopOSREntryBytecodeOffset(loopOSREntryBytecodeOffset)
{
}
JIT::~JIT()
{
}
#if ENABLE(DFG_JIT)
void JIT::emitEnterOptimizationCheck()
{
if (!canBeOptimized())
return;
JumpList skipOptimize;
skipOptimize.append(branchAdd32(Signed, TrustedImm32(Options::executionCounterIncrementForEntry()), AbsoluteAddress(m_codeBlock->addressOfJITExecuteCounter())));
ASSERT(!m_bytecodeOffset);
copyCalleeSavesFromFrameOrRegisterToEntryFrameCalleeSavesBuffer(vm()->topEntryFrame);
callOperation(operationOptimize, m_bytecodeOffset);
skipOptimize.append(branchTestPtr(Zero, returnValueGPR));
jump(returnValueGPR, GPRInfo::callFrameRegister);
skipOptimize.link(this);
}
#endif
void JIT::emitNotifyWrite(WatchpointSet* set)
{
if (!set || set->state() == IsInvalidated) {
addSlowCase(Jump());
return;
}
addSlowCase(branch8(NotEqual, AbsoluteAddress(set->addressOfState()), TrustedImm32(IsInvalidated)));
}
void JIT::emitNotifyWrite(GPRReg pointerToSet)
{
addSlowCase(branch8(NotEqual, Address(pointerToSet, WatchpointSet::offsetOfState()), TrustedImm32(IsInvalidated)));
}
void JIT::assertStackPointerOffset()
{
if (ASSERT_DISABLED)
return;
addPtr(TrustedImm32(stackPointerOffsetFor(m_codeBlock) * sizeof(Register)), callFrameRegister, regT0);
Jump ok = branchPtr(Equal, regT0, stackPointerRegister);
breakpoint();
ok.link(this);
}
#define NEXT_OPCODE(name) \
m_bytecodeOffset += OPCODE_LENGTH(name); \
break;
#define DEFINE_SLOW_OP(name) \
case op_##name: { \
if (m_bytecodeOffset >= startBytecodeOffset) { \
JITSlowPathCall slowPathCall(this, currentInstruction, slow_path_##name); \
slowPathCall.call(); \
} \
NEXT_OPCODE(op_##name); \
}
#define DEFINE_OP(name) \
case name: { \
if (m_bytecodeOffset >= startBytecodeOffset) { \
emit_##name(currentInstruction); \
} \
NEXT_OPCODE(name); \
}
#define DEFINE_SLOWCASE_OP(name) \
case name: { \
emitSlow_##name(currentInstruction, iter); \
NEXT_OPCODE(name); \
}
#define DEFINE_SLOWCASE_SLOW_OP(name) \
case op_##name: { \
emitSlowCaseCall(currentInstruction, iter, slow_path_##name); \
NEXT_OPCODE(op_##name); \
}
void JIT::emitSlowCaseCall(Instruction* currentInstruction, Vector<SlowCaseEntry>::iterator& iter, SlowPathFunction stub)
{
linkAllSlowCases(iter);
JITSlowPathCall slowPathCall(this, currentInstruction, stub);
slowPathCall.call();
}
void JIT::privateCompileMainPass()
{
if (JITInternal::verbose)
dataLog("Compiling ", *m_codeBlock, "\n");
jitAssertTagsInPlace();
jitAssertArgumentCountSane();
Instruction* instructionsBegin = m_codeBlock->instructions().begin();
unsigned instructionCount = m_instructions.size();
m_callLinkInfoIndex = 0;
VM& vm = *m_codeBlock->vm();
unsigned startBytecodeOffset = 0;
if (m_loopOSREntryBytecodeOffset && (m_codeBlock->inherits<ProgramCodeBlock>(vm) || m_codeBlock->inherits<ModuleProgramCodeBlock>(vm))) {
// We can only do this optimization because we execute ProgramCodeBlock's exactly once.
// This optimization would be invalid otherwise. When the LLInt determines it wants to
// do OSR entry into the baseline JIT in a loop, it will pass in the bytecode offset it
// was executing at when it kicked off our compilation. We only need to compile code for
// anything reachable from that bytecode offset.
// We only bother building the bytecode graph if it could save time and executable
// memory. We pick an arbitrary offset where we deem this is profitable.
if (m_loopOSREntryBytecodeOffset >= 200) {
// As a simplification, we don't find all bytecode ranges that are unreachable.
// Instead, we just find the minimum bytecode offset that is reachable, and
// compile code from that bytecode offset onwards.
BytecodeGraph graph(m_codeBlock, m_instructions);
BytecodeBasicBlock* block = graph.findBasicBlockForBytecodeOffset(m_loopOSREntryBytecodeOffset);
RELEASE_ASSERT(block);
GraphNodeWorklist<BytecodeBasicBlock*> worklist;
startBytecodeOffset = UINT_MAX;
worklist.push(block);
while (BytecodeBasicBlock* block = worklist.pop()) {
startBytecodeOffset = std::min(startBytecodeOffset, block->leaderOffset());
worklist.pushAll(block->successors());
}
}
}
for (m_bytecodeOffset = 0; m_bytecodeOffset < instructionCount; ) {
if (m_bytecodeOffset == startBytecodeOffset && startBytecodeOffset > 0) {
// We've proven all bytecode instructions up until here are unreachable.
// Let's ensure that by crashing if it's ever hit.
breakpoint();
}
if (m_disassembler)
m_disassembler->setForBytecodeMainPath(m_bytecodeOffset, label());
Instruction* currentInstruction = instructionsBegin + m_bytecodeOffset;
ASSERT_WITH_MESSAGE(Interpreter::isOpcode(currentInstruction->u.opcode), "privateCompileMainPass gone bad @ %d", m_bytecodeOffset);
m_pcToCodeOriginMapBuilder.appendItem(label(), CodeOrigin(m_bytecodeOffset));
#if ENABLE(OPCODE_SAMPLING)
if (m_bytecodeOffset > 0) // Avoid the overhead of sampling op_enter twice.
sampleInstruction(currentInstruction);
#endif
m_labels[m_bytecodeOffset] = label();
if (JITInternal::verbose)
dataLogF("Old JIT emitting code for bc#%u at offset 0x%lx.\n", m_bytecodeOffset, (long)debugOffset());
OpcodeID opcodeID = Interpreter::getOpcodeID(currentInstruction->u.opcode);
if (UNLIKELY(m_compilation)) {
add64(
TrustedImm32(1),
AbsoluteAddress(m_compilation->executionCounterFor(Profiler::OriginStack(Profiler::Origin(
m_compilation->bytecodes(), m_bytecodeOffset)))->address()));
}
if (Options::eagerlyUpdateTopCallFrame())
updateTopCallFrame();
unsigned bytecodeOffset = m_bytecodeOffset;
switch (opcodeID) {
DEFINE_SLOW_OP(in)
DEFINE_SLOW_OP(less)
DEFINE_SLOW_OP(lesseq)
DEFINE_SLOW_OP(greater)
DEFINE_SLOW_OP(greatereq)
DEFINE_SLOW_OP(is_function)
DEFINE_SLOW_OP(is_object_or_null)
DEFINE_SLOW_OP(typeof)
DEFINE_SLOW_OP(strcat)
DEFINE_SLOW_OP(push_with_scope)
DEFINE_SLOW_OP(create_lexical_environment)
DEFINE_SLOW_OP(get_by_val_with_this)
DEFINE_SLOW_OP(put_by_id_with_this)
DEFINE_SLOW_OP(put_by_val_with_this)
DEFINE_SLOW_OP(resolve_scope_for_hoisting_func_decl_in_eval)
DEFINE_SLOW_OP(define_data_property)
DEFINE_SLOW_OP(define_accessor_property)
DEFINE_SLOW_OP(unreachable)
DEFINE_SLOW_OP(throw_static_error)
DEFINE_SLOW_OP(new_array_with_spread)
DEFINE_SLOW_OP(new_array_buffer)
DEFINE_SLOW_OP(spread)
DEFINE_SLOW_OP(get_enumerable_length)
DEFINE_SLOW_OP(has_generic_property)
DEFINE_SLOW_OP(get_property_enumerator)
DEFINE_SLOW_OP(to_index_string)
DEFINE_SLOW_OP(create_direct_arguments)
DEFINE_SLOW_OP(create_scoped_arguments)
DEFINE_SLOW_OP(create_cloned_arguments)
DEFINE_SLOW_OP(create_rest)
DEFINE_SLOW_OP(pow)
DEFINE_OP(op_add)
DEFINE_OP(op_bitand)
DEFINE_OP(op_bitor)
DEFINE_OP(op_bitxor)
DEFINE_OP(op_call)
DEFINE_OP(op_tail_call)
DEFINE_OP(op_call_eval)
DEFINE_OP(op_call_varargs)
DEFINE_OP(op_tail_call_varargs)
DEFINE_OP(op_tail_call_forward_arguments)
DEFINE_OP(op_construct_varargs)
DEFINE_OP(op_catch)
DEFINE_OP(op_construct)
DEFINE_OP(op_create_this)
DEFINE_OP(op_to_this)
DEFINE_OP(op_get_argument)
DEFINE_OP(op_argument_count)
DEFINE_OP(op_get_rest_length)
DEFINE_OP(op_check_tdz)
DEFINE_OP(op_identity_with_profile)
DEFINE_OP(op_debug)
DEFINE_OP(op_del_by_id)
DEFINE_OP(op_del_by_val)
DEFINE_OP(op_div)
DEFINE_OP(op_end)
DEFINE_OP(op_enter)
DEFINE_OP(op_get_scope)
DEFINE_OP(op_eq)
DEFINE_OP(op_eq_null)
DEFINE_OP(op_below)
DEFINE_OP(op_beloweq)
DEFINE_OP(op_try_get_by_id)
case op_get_array_length:
case op_get_by_id_proto_load:
case op_get_by_id_unset:
DEFINE_OP(op_get_by_id)
DEFINE_OP(op_get_by_id_with_this)
DEFINE_OP(op_get_by_id_direct)
DEFINE_OP(op_get_by_val)
DEFINE_OP(op_overrides_has_instance)
DEFINE_OP(op_instanceof)
DEFINE_OP(op_instanceof_custom)
DEFINE_OP(op_is_empty)
DEFINE_OP(op_is_undefined)
DEFINE_OP(op_is_boolean)
DEFINE_OP(op_is_number)
DEFINE_OP(op_is_object)
DEFINE_OP(op_is_cell_with_type)
DEFINE_OP(op_jeq_null)
DEFINE_OP(op_jfalse)
DEFINE_OP(op_jmp)
DEFINE_OP(op_jneq_null)
DEFINE_OP(op_jneq_ptr)
DEFINE_OP(op_jless)
DEFINE_OP(op_jlesseq)
DEFINE_OP(op_jgreater)
DEFINE_OP(op_jgreatereq)
DEFINE_OP(op_jnless)
DEFINE_OP(op_jnlesseq)
DEFINE_OP(op_jngreater)
DEFINE_OP(op_jngreatereq)
DEFINE_OP(op_jeq)
DEFINE_OP(op_jneq)
DEFINE_OP(op_jstricteq)
DEFINE_OP(op_jnstricteq)
DEFINE_OP(op_jbelow)
DEFINE_OP(op_jbeloweq)
DEFINE_OP(op_jtrue)
DEFINE_OP(op_loop_hint)
DEFINE_OP(op_check_traps)
DEFINE_OP(op_nop)
DEFINE_OP(op_super_sampler_begin)
DEFINE_OP(op_super_sampler_end)
DEFINE_OP(op_lshift)
DEFINE_OP(op_mod)
DEFINE_OP(op_mov)
DEFINE_OP(op_mul)
DEFINE_OP(op_negate)
DEFINE_OP(op_neq)
DEFINE_OP(op_neq_null)
DEFINE_OP(op_new_array)
DEFINE_OP(op_new_array_with_size)
DEFINE_OP(op_new_func)
DEFINE_OP(op_new_func_exp)
DEFINE_OP(op_new_generator_func)
DEFINE_OP(op_new_generator_func_exp)
DEFINE_OP(op_new_async_func)
DEFINE_OP(op_new_async_func_exp)
DEFINE_OP(op_new_async_generator_func)
DEFINE_OP(op_new_async_generator_func_exp)
DEFINE_OP(op_new_object)
DEFINE_OP(op_new_regexp)
DEFINE_OP(op_not)
DEFINE_OP(op_nstricteq)
DEFINE_OP(op_dec)
DEFINE_OP(op_inc)
DEFINE_OP(op_profile_type)
DEFINE_OP(op_profile_control_flow)
DEFINE_OP(op_get_parent_scope)
DEFINE_OP(op_put_by_id)
case op_put_by_val_direct:
DEFINE_OP(op_put_by_val)
DEFINE_OP(op_put_getter_by_id)
DEFINE_OP(op_put_setter_by_id)
DEFINE_OP(op_put_getter_setter_by_id)
DEFINE_OP(op_put_getter_by_val)
DEFINE_OP(op_put_setter_by_val)
DEFINE_OP(op_ret)
DEFINE_OP(op_rshift)
DEFINE_OP(op_unsigned)
DEFINE_OP(op_urshift)
DEFINE_OP(op_set_function_name)
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_throw)
DEFINE_OP(op_to_number)
DEFINE_OP(op_to_string)
DEFINE_OP(op_to_object)
DEFINE_OP(op_to_primitive)
DEFINE_OP(op_resolve_scope)
DEFINE_OP(op_get_from_scope)
DEFINE_OP(op_put_to_scope)
DEFINE_OP(op_get_from_arguments)
DEFINE_OP(op_put_to_arguments)
DEFINE_OP(op_has_structure_property)
DEFINE_OP(op_has_indexed_property)
DEFINE_OP(op_get_direct_pname)
DEFINE_OP(op_enumerator_structure_pname)
DEFINE_OP(op_enumerator_generic_pname)
DEFINE_OP(op_log_shadow_chicken_prologue)
DEFINE_OP(op_log_shadow_chicken_tail)
default:
RELEASE_ASSERT_NOT_REACHED();
}
if (JITInternal::verbose)
dataLog("At ", bytecodeOffset, ": ", m_slowCases.size(), "\n");
}
RELEASE_ASSERT(m_callLinkInfoIndex == m_callCompilationInfo.size());
#ifndef NDEBUG
// Reset this, in order to guard its use with ASSERTs.
m_bytecodeOffset = std::numeric_limits<unsigned>::max();
#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].toBytecodeOffset], this);
m_jmpTable.clear();
}
void JIT::privateCompileSlowCases()
{
Instruction* instructionsBegin = m_codeBlock->instructions().begin();
m_getByIdIndex = 0;
m_getByIdWithThisIndex = 0;
m_putByIdIndex = 0;
m_byValInstructionIndex = 0;
m_callLinkInfoIndex = 0;
// Use this to assert that slow-path code associates new profiling sites with existing
// ValueProfiles rather than creating new ones. This ensures that for a given instruction
// (say, get_by_id) we get combined statistics for both the fast-path executions of that
// instructions and the slow-path executions. Furthermore, if the slow-path code created
// new ValueProfiles then the ValueProfiles would no longer be sorted by bytecode offset,
// which would break the invariant necessary to use CodeBlock::valueProfileForBytecodeOffset().
unsigned numberOfValueProfiles = m_codeBlock->numberOfValueProfiles();
for (Vector<SlowCaseEntry>::iterator iter = m_slowCases.begin(); iter != m_slowCases.end();) {
m_bytecodeOffset = iter->to;
m_pcToCodeOriginMapBuilder.appendItem(label(), CodeOrigin(m_bytecodeOffset));
unsigned firstTo = m_bytecodeOffset;
Instruction* currentInstruction = instructionsBegin + m_bytecodeOffset;
RareCaseProfile* rareCaseProfile = 0;
if (shouldEmitProfiling())
rareCaseProfile = m_codeBlock->addRareCaseProfile(m_bytecodeOffset);
if (JITInternal::verbose)
dataLogF("Old JIT emitting slow code for bc#%u at offset 0x%lx.\n", m_bytecodeOffset, (long)debugOffset());
if (m_disassembler)
m_disassembler->setForBytecodeSlowPath(m_bytecodeOffset, label());
switch (Interpreter::getOpcodeID(currentInstruction->u.opcode)) {
DEFINE_SLOWCASE_OP(op_add)
DEFINE_SLOWCASE_OP(op_call)
DEFINE_SLOWCASE_OP(op_tail_call)
DEFINE_SLOWCASE_OP(op_call_eval)
DEFINE_SLOWCASE_OP(op_call_varargs)
DEFINE_SLOWCASE_OP(op_tail_call_varargs)
DEFINE_SLOWCASE_OP(op_tail_call_forward_arguments)
DEFINE_SLOWCASE_OP(op_construct_varargs)
DEFINE_SLOWCASE_OP(op_construct)
DEFINE_SLOWCASE_OP(op_eq)
DEFINE_SLOWCASE_OP(op_try_get_by_id)
case op_get_array_length:
case op_get_by_id_proto_load:
case op_get_by_id_unset:
DEFINE_SLOWCASE_OP(op_get_by_id)
DEFINE_SLOWCASE_OP(op_get_by_id_with_this)
DEFINE_SLOWCASE_OP(op_get_by_id_direct)
DEFINE_SLOWCASE_OP(op_get_by_val)
DEFINE_SLOWCASE_OP(op_instanceof)
DEFINE_SLOWCASE_OP(op_instanceof_custom)
DEFINE_SLOWCASE_OP(op_jless)
DEFINE_SLOWCASE_OP(op_jlesseq)
DEFINE_SLOWCASE_OP(op_jgreater)
DEFINE_SLOWCASE_OP(op_jgreatereq)
DEFINE_SLOWCASE_OP(op_jnless)
DEFINE_SLOWCASE_OP(op_jnlesseq)
DEFINE_SLOWCASE_OP(op_jngreater)
DEFINE_SLOWCASE_OP(op_jngreatereq)
DEFINE_SLOWCASE_OP(op_jeq)
DEFINE_SLOWCASE_OP(op_jneq)
DEFINE_SLOWCASE_OP(op_jstricteq)
DEFINE_SLOWCASE_OP(op_jnstricteq)
DEFINE_SLOWCASE_OP(op_loop_hint)
DEFINE_SLOWCASE_OP(op_check_traps)
DEFINE_SLOWCASE_OP(op_mod)
DEFINE_SLOWCASE_OP(op_mul)
DEFINE_SLOWCASE_OP(op_negate)
DEFINE_SLOWCASE_OP(op_neq)
DEFINE_SLOWCASE_OP(op_new_object)
DEFINE_SLOWCASE_OP(op_put_by_id)
case op_put_by_val_direct:
DEFINE_SLOWCASE_OP(op_put_by_val)
DEFINE_SLOWCASE_OP(op_sub)
DEFINE_SLOWCASE_OP(op_has_indexed_property)
DEFINE_SLOWCASE_OP(op_get_from_scope)
DEFINE_SLOWCASE_OP(op_put_to_scope)
DEFINE_SLOWCASE_SLOW_OP(unsigned)
DEFINE_SLOWCASE_SLOW_OP(inc)
DEFINE_SLOWCASE_SLOW_OP(dec)
DEFINE_SLOWCASE_SLOW_OP(bitand)
DEFINE_SLOWCASE_SLOW_OP(bitor)
DEFINE_SLOWCASE_SLOW_OP(bitxor)
DEFINE_SLOWCASE_SLOW_OP(lshift)
DEFINE_SLOWCASE_SLOW_OP(rshift)
DEFINE_SLOWCASE_SLOW_OP(urshift)
DEFINE_SLOWCASE_SLOW_OP(div)
DEFINE_SLOWCASE_SLOW_OP(create_this)
DEFINE_SLOWCASE_SLOW_OP(to_this)
DEFINE_SLOWCASE_SLOW_OP(to_primitive)
DEFINE_SLOWCASE_SLOW_OP(to_number)
DEFINE_SLOWCASE_SLOW_OP(to_string)
DEFINE_SLOWCASE_SLOW_OP(to_object)
DEFINE_SLOWCASE_SLOW_OP(not)
DEFINE_SLOWCASE_SLOW_OP(stricteq)
DEFINE_SLOWCASE_SLOW_OP(nstricteq)
DEFINE_SLOWCASE_SLOW_OP(get_direct_pname)
DEFINE_SLOWCASE_SLOW_OP(has_structure_property)
DEFINE_SLOWCASE_SLOW_OP(resolve_scope)
DEFINE_SLOWCASE_SLOW_OP(check_tdz)
default:
RELEASE_ASSERT_NOT_REACHED();
}
if (JITInternal::verbose)
dataLog("At ", firstTo, " slow: ", iter - m_slowCases.begin(), "\n");
RELEASE_ASSERT_WITH_MESSAGE(iter == m_slowCases.end() || firstTo != iter->to, "Not enough jumps linked in slow case codegen.");
RELEASE_ASSERT_WITH_MESSAGE(firstTo == (iter - 1)->to, "Too many jumps linked in slow case codegen.");
if (shouldEmitProfiling())
add32(TrustedImm32(1), AbsoluteAddress(&rareCaseProfile->m_counter));
emitJumpSlowToHot(jump(), 0);
}
RELEASE_ASSERT(m_getByIdIndex == m_getByIds.size());
RELEASE_ASSERT(m_getByIdWithThisIndex == m_getByIdsWithThis.size());
RELEASE_ASSERT(m_putByIdIndex == m_putByIds.size());
RELEASE_ASSERT(m_callLinkInfoIndex == m_callCompilationInfo.size());
RELEASE_ASSERT(numberOfValueProfiles == m_codeBlock->numberOfValueProfiles());
#ifndef NDEBUG
// Reset this, in order to guard its use with ASSERTs.
m_bytecodeOffset = std::numeric_limits<unsigned>::max();
#endif
}
void JIT::compileWithoutLinking(JITCompilationEffort effort)
{
MonotonicTime before { };
if (UNLIKELY(computeCompileTimes()))
before = MonotonicTime::now();
{
ConcurrentJSLocker locker(m_codeBlock->m_lock);
m_instructions = m_codeBlock->instructions().clone();
}
DFG::CapabilityLevel level = m_codeBlock->capabilityLevel();
switch (level) {
case DFG::CannotCompile:
m_canBeOptimized = false;
m_canBeOptimizedOrInlined = false;
m_shouldEmitProfiling = false;
break;
case DFG::CanCompile:
case DFG::CanCompileAndInline:
m_canBeOptimized = true;
m_canBeOptimizedOrInlined = true;
m_shouldEmitProfiling = true;
break;
default:
RELEASE_ASSERT_NOT_REACHED();
break;
}
switch (m_codeBlock->codeType()) {
case GlobalCode:
case ModuleCode:
case EvalCode:
m_codeBlock->m_shouldAlwaysBeInlined = false;
break;
case FunctionCode:
// We could have already set it to false because we detected an uninlineable call.
// Don't override that observation.
m_codeBlock->m_shouldAlwaysBeInlined &= canInline(level) && DFG::mightInlineFunction(m_codeBlock);
break;
}
if (UNLIKELY(Options::dumpDisassembly() || (m_vm->m_perBytecodeProfiler && Options::disassembleBaselineForProfiler())))
m_disassembler = std::make_unique<JITDisassembler>(m_codeBlock);
if (UNLIKELY(m_vm->m_perBytecodeProfiler)) {
m_compilation = adoptRef(
new Profiler::Compilation(
m_vm->m_perBytecodeProfiler->ensureBytecodesFor(m_codeBlock),
Profiler::Baseline));
m_compilation->addProfiledBytecodes(*m_vm->m_perBytecodeProfiler, m_codeBlock);
}
m_pcToCodeOriginMapBuilder.appendItem(label(), CodeOrigin(0, nullptr));
Label entryLabel(this);
if (m_disassembler)
m_disassembler->setStartOfCode(entryLabel);
// Just add a little bit of randomness to the codegen
if (random() & 1)
nop();
emitFunctionPrologue();
emitPutToCallFrameHeader(m_codeBlock, CallFrameSlot::codeBlock);
Label beginLabel(this);
sampleCodeBlock(m_codeBlock);
#if ENABLE(OPCODE_SAMPLING)
sampleInstruction(m_codeBlock->instructions().begin());
#endif
if (m_codeBlock->codeType() == FunctionCode) {
ASSERT(m_bytecodeOffset == std::numeric_limits<unsigned>::max());
if (shouldEmitProfiling()) {
for (int argument = 0; argument < m_codeBlock->numParameters(); ++argument) {
// If this is a constructor, then we want to put in a dummy profiling site (to
// keep things consistent) but we don't actually want to record the dummy value.
if (m_codeBlock->m_isConstructor && !argument)
continue;
int offset = CallFrame::argumentOffsetIncludingThis(argument) * static_cast<int>(sizeof(Register));
#if USE(JSVALUE64)
load64(Address(callFrameRegister, offset), regT0);
#elif USE(JSVALUE32_64)
load32(Address(callFrameRegister, offset + OBJECT_OFFSETOF(JSValue, u.asBits.payload)), regT0);
load32(Address(callFrameRegister, offset + OBJECT_OFFSETOF(JSValue, u.asBits.tag)), regT1);
#endif
emitValueProfilingSite(m_codeBlock->valueProfileForArgument(argument));
}
}
}
int frameTopOffset = stackPointerOffsetFor(m_codeBlock) * sizeof(Register);
unsigned maxFrameSize = -frameTopOffset;
addPtr(TrustedImm32(frameTopOffset), callFrameRegister, regT1);
JumpList stackOverflow;
if (UNLIKELY(maxFrameSize > Options::reservedZoneSize()))
stackOverflow.append(branchPtr(Above, regT1, callFrameRegister));
stackOverflow.append(branchPtr(Above, AbsoluteAddress(m_vm->addressOfSoftStackLimit()), regT1));
move(regT1, stackPointerRegister);
checkStackPointerAlignment();
if (Options::zeroStackFrame())
clearStackFrame(callFrameRegister, stackPointerRegister, regT0, maxFrameSize);
emitSaveCalleeSaves();
emitMaterializeTagCheckRegisters();
RELEASE_ASSERT(!JITCode::isJIT(m_codeBlock->jitType()));
privateCompileMainPass();
privateCompileLinkPass();
privateCompileSlowCases();
if (m_disassembler)
m_disassembler->setEndOfSlowPath(label());
m_pcToCodeOriginMapBuilder.appendItem(label(), PCToCodeOriginMapBuilder::defaultCodeOrigin());
stackOverflow.link(this);
m_bytecodeOffset = 0;
if (maxFrameExtentForSlowPathCall)
addPtr(TrustedImm32(-maxFrameExtentForSlowPathCall), stackPointerRegister);
callOperationWithCallFrameRollbackOnException(operationThrowStackOverflowError, m_codeBlock);
if (m_codeBlock->codeType() == FunctionCode) {
m_arityCheck = label();
store8(TrustedImm32(0), &m_codeBlock->m_shouldAlwaysBeInlined);
emitFunctionPrologue();
emitPutToCallFrameHeader(m_codeBlock, CallFrameSlot::codeBlock);
load32(payloadFor(CallFrameSlot::argumentCount), regT1);
branch32(AboveOrEqual, regT1, TrustedImm32(m_codeBlock->m_numParameters)).linkTo(beginLabel, this);
m_bytecodeOffset = 0;
if (maxFrameExtentForSlowPathCall)
addPtr(TrustedImm32(-maxFrameExtentForSlowPathCall), stackPointerRegister);
callOperationWithCallFrameRollbackOnException(m_codeBlock->m_isConstructor ? operationConstructArityCheck : operationCallArityCheck);
if (maxFrameExtentForSlowPathCall)
addPtr(TrustedImm32(maxFrameExtentForSlowPathCall), stackPointerRegister);
branchTest32(Zero, returnValueGPR).linkTo(beginLabel, this);
move(returnValueGPR, GPRInfo::argumentGPR0);
emitNakedCall(m_vm->getCTIStub(arityFixupGenerator).retaggedCode<NoPtrTag>());
#if !ASSERT_DISABLED
m_bytecodeOffset = std::numeric_limits<unsigned>::max(); // Reset this, in order to guard its use with ASSERTs.
#endif
jump(beginLabel);
} else
m_arityCheck = entryLabel; // Not a function.
ASSERT(m_jmpTable.isEmpty());
privateCompileExceptionHandlers();
if (m_disassembler)
m_disassembler->setEndOfCode(label());
m_pcToCodeOriginMapBuilder.appendItem(label(), PCToCodeOriginMapBuilder::defaultCodeOrigin());
m_linkBuffer = std::unique_ptr<LinkBuffer>(new LinkBuffer(*this, m_codeBlock, effort));
MonotonicTime after { };
if (UNLIKELY(computeCompileTimes())) {
after = MonotonicTime::now();
if (Options::reportTotalCompileTimes())
totalBaselineCompileTime += after - before;
}
if (UNLIKELY(reportCompileTimes())) {
CString codeBlockName = toCString(*m_codeBlock);
dataLog("Optimized ", codeBlockName, " with Baseline JIT into ", m_linkBuffer->size(), " bytes in ", (after - before).milliseconds(), " ms.\n");
}
}
CompilationResult JIT::link()
{
LinkBuffer& patchBuffer = *m_linkBuffer;
if (patchBuffer.didFailToAllocate())
return CompilationFailed;
// Translate vPC offsets into addresses in JIT generated code, for switch tables.
for (auto& record : m_switches) {
unsigned bytecodeOffset = record.bytecodeOffset;
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());
auto* simpleJumpTable = record.jumpTable.simpleJumpTable;
simpleJumpTable->ctiDefault = patchBuffer.locationOf<JSSwitchPtrTag>(m_labels[bytecodeOffset + record.defaultOffset]);
for (unsigned j = 0; j < record.jumpTable.simpleJumpTable->branchOffsets.size(); ++j) {
unsigned offset = record.jumpTable.simpleJumpTable->branchOffsets[j];
simpleJumpTable->ctiOffsets[j] = offset
? patchBuffer.locationOf<JSSwitchPtrTag>(m_labels[bytecodeOffset + offset])
: simpleJumpTable->ctiDefault;
}
} else {
ASSERT(record.type == SwitchRecord::String);
auto* stringJumpTable = record.jumpTable.stringJumpTable;
stringJumpTable->ctiDefault =
patchBuffer.locationOf<JSSwitchPtrTag>(m_labels[bytecodeOffset + record.defaultOffset]);
for (auto& location : stringJumpTable->offsetTable.values()) {
unsigned offset = location.branchOffset;
location.ctiOffset = offset
? patchBuffer.locationOf<JSSwitchPtrTag>(m_labels[bytecodeOffset + offset])
: stringJumpTable->ctiDefault;
}
}
}
for (size_t i = 0; i < m_codeBlock->numberOfExceptionHandlers(); ++i) {
HandlerInfo& handler = m_codeBlock->exceptionHandler(i);
// FIXME: <rdar://problem/39433318>.
handler.nativeCode = patchBuffer.locationOf<ExceptionHandlerPtrTag>(m_labels[handler.target]);
}
for (auto& record : m_calls) {
if (record.callee)
patchBuffer.link(record.from, record.callee);
}
for (unsigned i = m_getByIds.size(); i--;)
m_getByIds[i].finalize(patchBuffer);
for (unsigned i = m_getByIdsWithThis.size(); i--;)
m_getByIdsWithThis[i].finalize(patchBuffer);
for (unsigned i = m_putByIds.size(); i--;)
m_putByIds[i].finalize(patchBuffer);
if (m_byValCompilationInfo.size()) {
CodeLocationLabel<ExceptionHandlerPtrTag> exceptionHandler = patchBuffer.locationOf<ExceptionHandlerPtrTag>(m_exceptionHandler);
for (const auto& byValCompilationInfo : m_byValCompilationInfo) {
PatchableJump patchableNotIndexJump = byValCompilationInfo.notIndexJump;
auto notIndexJump = CodeLocationJump<JSInternalPtrTag>();
if (Jump(patchableNotIndexJump).isSet())
notIndexJump = CodeLocationJump<JSInternalPtrTag>(patchBuffer.locationOf<JSInternalPtrTag>(patchableNotIndexJump));
auto badTypeJump = CodeLocationJump<JSInternalPtrTag>(patchBuffer.locationOf<JSInternalPtrTag>(byValCompilationInfo.badTypeJump));
CodeLocationLabel<NoPtrTag> doneTarget = patchBuffer.locationOf<NoPtrTag>(byValCompilationInfo.doneTarget);
CodeLocationLabel<NoPtrTag> nextHotPathTarget = patchBuffer.locationOf<NoPtrTag>(byValCompilationInfo.nextHotPathTarget);
CodeLocationLabel<NoPtrTag> slowPathTarget = patchBuffer.locationOf<NoPtrTag>(byValCompilationInfo.slowPathTarget);
CodeLocationCall<NoPtrTag> returnAddress = patchBuffer.locationOf<NoPtrTag>(byValCompilationInfo.returnAddress);
*byValCompilationInfo.byValInfo = ByValInfo(
byValCompilationInfo.bytecodeIndex,
notIndexJump,
badTypeJump,
exceptionHandler,
byValCompilationInfo.arrayMode,
byValCompilationInfo.arrayProfile,
differenceBetweenCodePtr(badTypeJump, doneTarget),
differenceBetweenCodePtr(badTypeJump, nextHotPathTarget),
differenceBetweenCodePtr(returnAddress, slowPathTarget));
}
}
for (auto& compilationInfo : m_callCompilationInfo) {
CallLinkInfo& info = *compilationInfo.callLinkInfo;
info.setCallLocations(
CodeLocationLabel<JSInternalPtrTag>(patchBuffer.locationOfNearCall<JSInternalPtrTag>(compilationInfo.callReturnLocation)),
CodeLocationLabel<JSInternalPtrTag>(patchBuffer.locationOf<JSInternalPtrTag>(compilationInfo.hotPathBegin)),
patchBuffer.locationOfNearCall<JSInternalPtrTag>(compilationInfo.hotPathOther));
}
JITCodeMap jitCodeMap;
for (unsigned bytecodeOffset = 0; bytecodeOffset < m_labels.size(); ++bytecodeOffset) {
if (m_labels[bytecodeOffset].isSet())
jitCodeMap.append(bytecodeOffset, patchBuffer.locationOf<JSEntryPtrTag>(m_labels[bytecodeOffset]));
}
jitCodeMap.finish();
m_codeBlock->setJITCodeMap(WTFMove(jitCodeMap));
MacroAssemblerCodePtr<JSEntryPtrTag> withArityCheck = patchBuffer.locationOf<JSEntryPtrTag>(m_arityCheck);
if (Options::dumpDisassembly()) {
m_disassembler->dump(patchBuffer);
patchBuffer.didAlreadyDisassemble();
}
if (UNLIKELY(m_compilation)) {
if (Options::disassembleBaselineForProfiler())
m_disassembler->reportToProfiler(m_compilation.get(), patchBuffer);
m_vm->m_perBytecodeProfiler->addCompilation(m_codeBlock, *m_compilation);
}
if (m_pcToCodeOriginMapBuilder.didBuildMapping())
m_codeBlock->setPCToCodeOriginMap(std::make_unique<PCToCodeOriginMap>(WTFMove(m_pcToCodeOriginMapBuilder), patchBuffer));
CodeRef<JSEntryPtrTag> result = FINALIZE_CODE(
patchBuffer, JSEntryPtrTag,
"Baseline JIT code for %s", toCString(CodeBlockWithJITType(m_codeBlock, JITCode::BaselineJIT)).data());
m_vm->machineCodeBytesPerBytecodeWordForBaselineJIT->add(
static_cast<double>(result.size()) /
static_cast<double>(m_instructions.size()));
m_codeBlock->shrinkToFit(CodeBlock::LateShrink);
m_codeBlock->setJITCode(
adoptRef(*new DirectJITCode(result, withArityCheck, JITCode::BaselineJIT)));
if (JITInternal::verbose)
dataLogF("JIT generated code for %p at [%p, %p).\n", m_codeBlock, result.executableMemory()->start(), result.executableMemory()->end());
return CompilationSuccessful;
}
CompilationResult JIT::privateCompile(JITCompilationEffort effort)
{
doMainThreadPreparationBeforeCompile();
compileWithoutLinking(effort);
return link();
}
void JIT::privateCompileExceptionHandlers()
{
if (!m_exceptionChecksWithCallFrameRollback.empty()) {
m_exceptionChecksWithCallFrameRollback.link(this);
copyCalleeSavesToEntryFrameCalleeSavesBuffer(vm()->topEntryFrame);
// lookupExceptionHandlerFromCallerFrame 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(CallRecord(call(OperationPtrTag), std::numeric_limits<unsigned>::max(), FunctionPtr<OperationPtrTag>(lookupExceptionHandlerFromCallerFrame)));
jumpToExceptionHandler(*vm());
}
if (!m_exceptionChecks.empty() || m_byValCompilationInfo.size()) {
m_exceptionHandler = label();
m_exceptionChecks.link(this);
copyCalleeSavesToEntryFrameCalleeSavesBuffer(vm()->topEntryFrame);
// 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(CallRecord(call(OperationPtrTag), std::numeric_limits<unsigned>::max(), FunctionPtr<OperationPtrTag>(lookupExceptionHandler)));
jumpToExceptionHandler(*vm());
}
}
void JIT::doMainThreadPreparationBeforeCompile()
{
// This ensures that we have the most up to date type information when performing typecheck optimizations for op_profile_type.
if (m_vm->typeProfiler())
m_vm->typeProfilerLog()->processLogEntries(ASCIILiteral("Preparing for JIT compilation."));
}
unsigned JIT::frameRegisterCountFor(CodeBlock* codeBlock)
{
ASSERT(static_cast<unsigned>(codeBlock->m_numCalleeLocals) == WTF::roundUpToMultipleOf(stackAlignmentRegisters(), static_cast<unsigned>(codeBlock->m_numCalleeLocals)));
return roundLocalRegisterCountForFramePointerOffset(codeBlock->m_numCalleeLocals + maxFrameExtentForSlowPathCallInRegisters);
}
int JIT::stackPointerOffsetFor(CodeBlock* codeBlock)
{
return virtualRegisterForLocal(frameRegisterCountFor(codeBlock) - 1).offset();
}
bool JIT::reportCompileTimes()
{
return Options::reportCompileTimes() || Options::reportBaselineCompileTimes();
}
bool JIT::computeCompileTimes()
{
return reportCompileTimes() || Options::reportTotalCompileTimes();
}
HashMap<CString, Seconds> JIT::compileTimeStats()
{
HashMap<CString, Seconds> result;
if (Options::reportTotalCompileTimes()) {
result.add("Total Compile Time", totalBaselineCompileTime + totalDFGCompileTime + totalFTLCompileTime);
result.add("Baseline Compile Time", totalBaselineCompileTime);
#if ENABLE(DFG_JIT)
result.add("DFG Compile Time", totalDFGCompileTime);
#if ENABLE(FTL_JIT)
result.add("FTL Compile Time", totalFTLCompileTime);
result.add("FTL (DFG) Compile Time", totalFTLDFGCompileTime);
result.add("FTL (B3) Compile Time", totalFTLB3CompileTime);
#endif // ENABLE(FTL_JIT)
#endif // ENABLE(DFG_JIT)
}
return result;
}
} // namespace JSC
#endif // ENABLE(JIT)