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webkit / WebKit / 473b92ed852160eab7c2365a49eda22bbbc97909 / . / PerformanceTests / JetStream2 / RexBench / OfflineAssembler / LowLevelInterpreter.js
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/*
* DO NOT EDIT THIS FILE, it is autogenerated.
*/
"use strict";
(function() {
let source = `# Copyright (C) 2011-2017 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. AND ITS CONTRIBUTORS \`\`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 ITS 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.
# Crash course on the language that this is written in (which I just call
# "assembly" even though it's more than that):
#
# - Mostly gas-style operand ordering. The last operand tends to be the
# destination. So "a := b" is written as "mov b, a". But unlike gas,
# comparisons are in-order, so "if (a < b)" is written as
# "bilt a, b, ...".
#
# - "b" = byte, "h" = 16-bit word, "i" = 32-bit word, "p" = pointer.
# For 32-bit, "i" and "p" are interchangeable except when an op supports one
# but not the other.
#
# - In general, valid operands for macro invocations and instructions are
# registers (eg "t0"), addresses (eg "4[t0]"), base-index addresses
# (eg "7[t0, t1, 2]"), absolute addresses (eg "0xa0000000[]"), or labels
# (eg "_foo" or ".foo"). Macro invocations can also take anonymous
# macros as operands. Instructions cannot take anonymous macros.
#
# - Labels must have names that begin with either "_" or ".". A "." label
# is local and gets renamed before code gen to minimize namespace
# pollution. A "_" label is an extern symbol (i.e. ".globl"). The "_"
# may or may not be removed during code gen depending on whether the asm
# conventions for C name mangling on the target platform mandate a "_"
# prefix.
#
# - A "macro" is a lambda expression, which may be either anonymous or
# named. But this has caveats. "macro" can take zero or more arguments,
# which may be macros or any valid operands, but it can only return
# code. But you can do Turing-complete things via continuation passing
# style: "macro foo (a, b) b(a, a) end foo(foo, foo)". Actually, don't do
# that, since you'll just crash the assembler.
#
# - An "if" is a conditional on settings. Any identifier supplied in the
# predicate of an "if" is assumed to be a #define that is available
# during code gen. So you can't use "if" for computation in a macro, but
# you can use it to select different pieces of code for different
# platforms.
#
# - Arguments to macros follow lexical scoping rather than dynamic scoping.
# Const's also follow lexical scoping and may override (hide) arguments
# or other consts. All variables (arguments and constants) can be bound
# to operands. Additionally, arguments (but not constants) can be bound
# to macros.
# The following general-purpose registers are available:
#
# - cfr and sp hold the call frame and (native) stack pointer respectively.
# They are callee-save registers, and guaranteed to be distinct from all other
# registers on all architectures.
#
# - lr is defined on non-X86 architectures (ARM64, ARMv7, ARM,
# ARMv7_TRADITIONAL, MIPS and CLOOP) and holds the return PC
#
# - pc holds the (native) program counter on 32-bits ARM architectures (ARM,
# ARMv7, ARMv7_TRADITIONAL)
#
# - t0, t1, t2, t3, t4 and optionally t5 are temporary registers that can get trashed on
# calls, and are pairwise distinct registers. t4 holds the JS program counter, so use
# with caution in opcodes (actually, don't use it in opcodes at all, except as PC).
#
# - r0 and r1 are the platform's customary return registers, and thus are
# two distinct registers
#
# - a0, a1, a2 and a3 are the platform's customary argument registers, and
# thus are pairwise distinct registers. Be mindful that:
# + On X86, there are no argument registers. a0 and a1 are edx and
# ecx following the fastcall convention, but you should still use the stack
# to pass your arguments. The cCall2 and cCall4 macros do this for you.
# + On X86_64_WIN, you should allocate space on the stack for the arguments,
# and the return convention is weird for > 8 bytes types. The only place we
# use > 8 bytes return values is on a cCall, and cCall2 and cCall4 handle
# this for you.
#
# - The only registers guaranteed to be caller-saved are r0, r1, a0, a1 and a2, and
# you should be mindful of that in functions that are called directly from C.
# If you need more registers, you should push and pop them like a good
# assembly citizen, because any other register will be callee-saved on X86.
#
# You can additionally assume:
#
# - a3, t2, t3, t4 and t5 are never return registers; t0, t1, a0, a1 and a2
# can be return registers.
#
# - t4 and t5 are never argument registers, t3 can only be a3, t1 can only be
# a1; but t0 and t2 can be either a0 or a2.
#
# - On 64 bits, there are callee-save registers named csr0, csr1, ... csrN.
# The last three csr registers are used used to store the PC base and
# two special tag values. Don't use them for anything else.
#
# Additional platform-specific details (you shouldn't rely on this remaining
# true):
#
# - For consistency with the baseline JIT, t0 is always r0 (and t1 is always
# r1 on 32 bits platforms). You should use the r version when you need return
# registers, and the t version otherwise: code using t0 (or t1) should still
# work if swapped with e.g. t3, while code using r0 (or r1) should not. There
# *may* be legacy code relying on this.
#
# - On all platforms other than X86, t0 can only be a0 and t2 can only be a2.
#
# - On all platforms other than X86 and X86_64, a2 is not a return register.
# a2 is r0 on X86 (because we have so few registers) and r1 on X86_64 (because
# the ABI enforces it).
#
# The following floating-point registers are available:
#
# - ft0-ft5 are temporary floating-point registers that get trashed on calls,
# and are pairwise distinct.
#
# - fa0 and fa1 are the platform's customary floating-point argument
# registers, and are both distinct. On 64-bits platforms, fa2 and fa3 are
# additional floating-point argument registers.
#
# - fr is the platform's customary floating-point return register
#
# You can assume that ft1-ft5 or fa1-fa3 are never fr, and that ftX is never
# faY if X != Y.
# First come the common protocols that both interpreters use. Note that each
# of these must have an ASSERT() in LLIntData.cpp
# Work-around for the fact that the toolchain's awareness of armv7k / armv7s
# results in a separate slab in the fat binary, yet the offlineasm doesn't know
# to expect it.
if ARMv7k
end
if ARMv7s
end
# These declarations must match interpreter/JSStack.h.
const PtrSize = constexpr (sizeof(void*))
if JSVALUE64
const CallFrameHeaderSlots = 5
else
const CallFrameHeaderSlots = 4
const CallFrameAlignSlots = 1
end
const SlotSize = 8
const JSEnvironmentRecord_variables = (sizeof JSEnvironmentRecord + SlotSize - 1) & ~(SlotSize - 1)
const DirectArguments_storage = (sizeof DirectArguments + SlotSize - 1) & ~(SlotSize - 1)
const StackAlignment = 16
const StackAlignmentSlots = 2
const StackAlignmentMask = StackAlignment - 1
const CallerFrameAndPCSize = 2 * PtrSize
const CallerFrame = 0
const ReturnPC = CallerFrame + PtrSize
const CodeBlock = ReturnPC + PtrSize
const Callee = CodeBlock + SlotSize
const ArgumentCount = Callee + SlotSize
const ThisArgumentOffset = ArgumentCount + SlotSize
const FirstArgumentOffset = ThisArgumentOffset + SlotSize
const CallFrameHeaderSize = ThisArgumentOffset
# Some value representation constants.
if JSVALUE64
const TagBitTypeOther = 0x2
const TagBitBool = 0x4
const TagBitUndefined = 0x8
const ValueEmpty = 0x0
const ValueFalse = TagBitTypeOther | TagBitBool
const ValueTrue = TagBitTypeOther | TagBitBool | 1
const ValueUndefined = TagBitTypeOther | TagBitUndefined
const ValueNull = TagBitTypeOther
const TagTypeNumber = 0xffff000000000000
const TagMask = TagTypeNumber | TagBitTypeOther
else
const Int32Tag = -1
const BooleanTag = -2
const NullTag = -3
const UndefinedTag = -4
const CellTag = -5
const EmptyValueTag = -6
const DeletedValueTag = -7
const LowestTag = DeletedValueTag
end
# PutByIdFlags data
const PutByIdPrimaryTypeMask = constexpr PutByIdPrimaryTypeMask
const PutByIdPrimaryTypeSecondary = constexpr PutByIdPrimaryTypeSecondary
const PutByIdPrimaryTypeObjectWithStructure = constexpr PutByIdPrimaryTypeObjectWithStructure
const PutByIdPrimaryTypeObjectWithStructureOrOther = constexpr PutByIdPrimaryTypeObjectWithStructureOrOther
const PutByIdSecondaryTypeMask = constexpr PutByIdSecondaryTypeMask
const PutByIdSecondaryTypeBottom = constexpr PutByIdSecondaryTypeBottom
const PutByIdSecondaryTypeBoolean = constexpr PutByIdSecondaryTypeBoolean
const PutByIdSecondaryTypeOther = constexpr PutByIdSecondaryTypeOther
const PutByIdSecondaryTypeInt32 = constexpr PutByIdSecondaryTypeInt32
const PutByIdSecondaryTypeNumber = constexpr PutByIdSecondaryTypeNumber
const PutByIdSecondaryTypeString = constexpr PutByIdSecondaryTypeString
const PutByIdSecondaryTypeSymbol = constexpr PutByIdSecondaryTypeSymbol
const PutByIdSecondaryTypeObject = constexpr PutByIdSecondaryTypeObject
const PutByIdSecondaryTypeObjectOrOther = constexpr PutByIdSecondaryTypeObjectOrOther
const PutByIdSecondaryTypeTop = constexpr PutByIdSecondaryTypeTop
const CallOpCodeSize = 9
if X86_64 or ARM64 or C_LOOP
const maxFrameExtentForSlowPathCall = 0
elsif ARM or ARMv7_TRADITIONAL or ARMv7
const maxFrameExtentForSlowPathCall = 24
elsif X86 or X86_WIN
const maxFrameExtentForSlowPathCall = 40
elsif MIPS
const maxFrameExtentForSlowPathCall = 40
elsif X86_64_WIN
const maxFrameExtentForSlowPathCall = 64
end
if X86_64 or X86_64_WIN or ARM64
const CalleeSaveSpaceAsVirtualRegisters = 3
else
const CalleeSaveSpaceAsVirtualRegisters = 0
end
const CalleeSaveSpaceStackAligned = (CalleeSaveSpaceAsVirtualRegisters * SlotSize + StackAlignment - 1) & ~StackAlignmentMask
# Watchpoint states
const ClearWatchpoint = constexpr ClearWatchpoint
const IsWatched = constexpr IsWatched
const IsInvalidated = constexpr IsInvalidated
# ShadowChicken data
const ShadowChickenTailMarker = constexpr ShadowChicken::Packet::tailMarkerValue
# ArithProfile data
const ArithProfileInt = 0x100000
const ArithProfileIntInt = 0x120000
const ArithProfileNumber = 0x200000
const ArithProfileNumberInt = 0x220000
const ArithProfileNumberNumber = 0x240000
const ArithProfileIntNumber = 0x140000
# Some register conventions.
if JSVALUE64
# - Use a pair of registers to represent the PC: one register for the
# base of the bytecodes, and one register for the index.
# - The PC base (or PB for short) must be stored in a callee-save register.
# - C calls are still given the Instruction* rather than the PC index.
# This requires an add before the call, and a sub after.
const PC = t4 # When changing this, make sure LLIntPC is up to date in LLIntPCRanges.h
if ARM64
const PB = csr7
const tagTypeNumber = csr8
const tagMask = csr9
elsif X86_64
const PB = csr2
const tagTypeNumber = csr3
const tagMask = csr4
elsif X86_64_WIN
const PB = csr4
const tagTypeNumber = csr5
const tagMask = csr6
elsif C_LOOP
const PB = csr0
const tagTypeNumber = csr1
const tagMask = csr2
end
macro loadisFromInstruction(offset, dest)
loadis offset * 8[PB, PC, 8], dest
end
macro loadpFromInstruction(offset, dest)
loadp offset * 8[PB, PC, 8], dest
end
macro storeisToInstruction(value, offset)
storei value, offset * 8[PB, PC, 8]
end
macro storepToInstruction(value, offset)
storep value, offset * 8[PB, PC, 8]
end
else
const PC = t4 # When changing this, make sure LLIntPC is up to date in LLIntPCRanges.h
macro loadisFromInstruction(offset, dest)
loadis offset * 4[PC], dest
end
macro loadpFromInstruction(offset, dest)
loadp offset * 4[PC], dest
end
macro storeisToInstruction(value, offset)
storei value, offset * 4[PC]
end
end
if X86_64_WIN
const extraTempReg = t0
else
const extraTempReg = t5
end
# Constants for reasoning about value representation.
if BIG_ENDIAN
const TagOffset = 0
const PayloadOffset = 4
else
const TagOffset = 4
const PayloadOffset = 0
end
# Constant for reasoning about butterflies.
const IsArray = constexpr IsArray
const IndexingShapeMask = constexpr IndexingShapeMask
const NoIndexingShape = constexpr NoIndexingShape
const Int32Shape = constexpr Int32Shape
const DoubleShape = constexpr DoubleShape
const ContiguousShape = constexpr ContiguousShape
const ArrayStorageShape = constexpr ArrayStorageShape
const SlowPutArrayStorageShape = constexpr SlowPutArrayStorageShape
# Type constants.
const StringType = constexpr StringType
const SymbolType = constexpr SymbolType
const ObjectType = constexpr ObjectType
const FinalObjectType = constexpr FinalObjectType
const JSFunctionType = constexpr JSFunctionType
const ArrayType = constexpr ArrayType
const DerivedArrayType = constexpr DerivedArrayType
const ProxyObjectType = constexpr ProxyObjectType
# The typed array types need to be numbered in a particular order because of the manually written
# switch statement in get_by_val and put_by_val.
const Int8ArrayType = constexpr Int8ArrayType
const Int16ArrayType = constexpr Int16ArrayType
const Int32ArrayType = constexpr Int32ArrayType
const Uint8ArrayType = constexpr Uint8ArrayType
const Uint8ClampedArrayType = constexpr Uint8ClampedArrayType
const Uint16ArrayType = constexpr Uint16ArrayType
const Uint32ArrayType = constexpr Uint32ArrayType
const Float32ArrayType = constexpr Float32ArrayType
const Float64ArrayType = constexpr Float64ArrayType
const FirstArrayType = Int8ArrayType
const LastArrayType = Float64ArrayType
# Type flags constants.
const MasqueradesAsUndefined = constexpr MasqueradesAsUndefined
const ImplementsDefaultHasInstance = constexpr ImplementsDefaultHasInstance
# Bytecode operand constants.
const FirstConstantRegisterIndex = constexpr FirstConstantRegisterIndex
# Code type constants.
const GlobalCode = constexpr GlobalCode
const EvalCode = constexpr EvalCode
const FunctionCode = constexpr FunctionCode
const ModuleCode = constexpr ModuleCode
# The interpreter steals the tag word of the argument count.
const LLIntReturnPC = ArgumentCount + TagOffset
# String flags.
const HashFlags8BitBuffer = 8
# Copied from PropertyOffset.h
const firstOutOfLineOffset = 100
# ResolveType
const GlobalProperty = constexpr GlobalProperty
const GlobalVar = constexpr GlobalVar
const GlobalLexicalVar = constexpr GlobalLexicalVar
const ClosureVar = constexpr ClosureVar
const LocalClosureVar = constexpr LocalClosureVar
const ModuleVar = constexpr ModuleVar
const GlobalPropertyWithVarInjectionChecks = constexpr GlobalPropertyWithVarInjectionChecks
const GlobalVarWithVarInjectionChecks = constexpr GlobalVarWithVarInjectionChecks
const GlobalLexicalVarWithVarInjectionChecks = constexpr GlobalLexicalVarWithVarInjectionChecks
const ClosureVarWithVarInjectionChecks = constexpr ClosureVarWithVarInjectionChecks
const ResolveTypeMask = constexpr GetPutInfo::typeBits
const InitializationModeMask = constexpr GetPutInfo::initializationBits
const InitializationModeShift = constexpr GetPutInfo::initializationShift
const NotInitialization = constexpr InitializationMode::NotInitialization
const MarkedBlockSize = constexpr MarkedBlock::blockSize
const MarkedBlockMask = ~(MarkedBlockSize - 1)
const BlackThreshold = constexpr blackThreshold
# Allocation constants
if JSVALUE64
const JSFinalObjectSizeClassIndex = 1
else
const JSFinalObjectSizeClassIndex = 3
end
# This must match wtf/Vector.h
const VectorBufferOffset = 0
if JSVALUE64
const VectorSizeOffset = 12
else
const VectorSizeOffset = 8
end
# Some common utilities.
macro crash()
if C_LOOP
cloopCrash
else
call _llint_crash
end
end
macro assert(assertion)
if ASSERT_ENABLED
assertion(.ok)
crash()
.ok:
end
end
# The probe macro can be used to insert some debugging code without perturbing scalar
# registers. Presently, the probe macro only preserves scalar registers. Hence, the
# C probe callback function should not trash floating point registers.
#
# The macro you pass to probe() can pass whatever registers you like to your probe
# callback function. However, you need to be mindful of which of the registers are
# also used as argument registers, and ensure that you don't trash the register value
# before storing it in the probe callback argument register that you desire.
#
# Here's an example of how it's used:
#
# probe(
# macro()
# move cfr, a0 # pass the ExecState* as arg0.
# move t0, a1 # pass the value of register t0 as arg1.
# call _cProbeCallbackFunction # to do whatever you want.
# end
# )
#
if X86_64
macro probe(action)
# save all the registers that the LLInt may use.
push a0, a1
push a2, a3
push t0, t1
push t2, t3
push t4, t5
action()
# restore all the registers we saved previously.
pop t5, t4
pop t3, t2
pop t1, t0
pop a3, a2
pop a1, a0
end
end
macro checkStackPointerAlignment(tempReg, location)
if ARM64 or C_LOOP
# ARM64 will check for us!
# C_LOOP does not need the alignment, and can use a little perf
# improvement from avoiding useless work.
else
if ARM or ARMv7 or ARMv7_TRADITIONAL
# ARM can't do logical ops with the sp as a source
move sp, tempReg
andp StackAlignmentMask, tempReg
else
andp sp, StackAlignmentMask, tempReg
end
btpz tempReg, .stackPointerOkay
move location, tempReg
break
.stackPointerOkay:
end
end
if C_LOOP or ARM64 or X86_64 or X86_64_WIN
const CalleeSaveRegisterCount = 0
elsif ARM or ARMv7_TRADITIONAL or ARMv7
const CalleeSaveRegisterCount = 7
elsif MIPS
const CalleeSaveRegisterCount = 1
elsif X86 or X86_WIN
const CalleeSaveRegisterCount = 3
end
const CalleeRegisterSaveSize = CalleeSaveRegisterCount * PtrSize
# VMEntryTotalFrameSize includes the space for struct VMEntryRecord and the
# callee save registers rounded up to keep the stack aligned
const VMEntryTotalFrameSize = (CalleeRegisterSaveSize + sizeof VMEntryRecord + StackAlignment - 1) & ~StackAlignmentMask
macro pushCalleeSaves()
if C_LOOP or ARM64 or X86_64 or X86_64_WIN
elsif ARM or ARMv7_TRADITIONAL
emit "push {r4-r10}"
elsif ARMv7
emit "push {r4-r6, r8-r11}"
elsif MIPS
emit "addiu $sp, $sp, -4"
emit "sw $s4, 0($sp)"
# save $gp to $s4 so that we can restore it after a function call
emit "move $s4, $gp"
elsif X86
emit "push %esi"
emit "push %edi"
emit "push %ebx"
elsif X86_WIN
emit "push esi"
emit "push edi"
emit "push ebx"
end
end
macro popCalleeSaves()
if C_LOOP or ARM64 or X86_64 or X86_64_WIN
elsif ARM or ARMv7_TRADITIONAL
emit "pop {r4-r10}"
elsif ARMv7
emit "pop {r4-r6, r8-r11}"
elsif MIPS
emit "lw $s4, 0($sp)"
emit "addiu $sp, $sp, 4"
elsif X86
emit "pop %ebx"
emit "pop %edi"
emit "pop %esi"
elsif X86_WIN
emit "pop ebx"
emit "pop edi"
emit "pop esi"
end
end
macro preserveCallerPCAndCFR()
if C_LOOP or ARM or ARMv7 or ARMv7_TRADITIONAL or MIPS
push lr
push cfr
elsif X86 or X86_WIN or X86_64 or X86_64_WIN
push cfr
elsif ARM64
push cfr, lr
else
error
end
move sp, cfr
end
macro restoreCallerPCAndCFR()
move cfr, sp
if C_LOOP or ARM or ARMv7 or ARMv7_TRADITIONAL or MIPS
pop cfr
pop lr
elsif X86 or X86_WIN or X86_64 or X86_64_WIN
pop cfr
elsif ARM64
pop lr, cfr
end
end
macro preserveCalleeSavesUsedByLLInt()
subp CalleeSaveSpaceStackAligned, sp
if C_LOOP
elsif ARM or ARMv7_TRADITIONAL
elsif ARMv7
elsif ARM64
emit "stp x27, x28, [x29, #-16]"
emit "stp xzr, x26, [x29, #-32]"
elsif MIPS
elsif X86
elsif X86_WIN
elsif X86_64
storep csr4, -8[cfr]
storep csr3, -16[cfr]
storep csr2, -24[cfr]
elsif X86_64_WIN
storep csr6, -8[cfr]
storep csr5, -16[cfr]
storep csr4, -24[cfr]
end
end
macro restoreCalleeSavesUsedByLLInt()
if C_LOOP
elsif ARM or ARMv7_TRADITIONAL
elsif ARMv7
elsif ARM64
emit "ldp xzr, x26, [x29, #-32]"
emit "ldp x27, x28, [x29, #-16]"
elsif MIPS
elsif X86
elsif X86_WIN
elsif X86_64
loadp -24[cfr], csr2
loadp -16[cfr], csr3
loadp -8[cfr], csr4
elsif X86_64_WIN
loadp -24[cfr], csr4
loadp -16[cfr], csr5
loadp -8[cfr], csr6
end
end
macro copyCalleeSavesToVMEntryFrameCalleeSavesBuffer(vm, temp)
if ARM64 or X86_64 or X86_64_WIN
loadp VM::topVMEntryFrame[vm], temp
vmEntryRecord(temp, temp)
leap VMEntryRecord::calleeSaveRegistersBuffer[temp], temp
if ARM64
storep csr0, [temp]
storep csr1, 8[temp]
storep csr2, 16[temp]
storep csr3, 24[temp]
storep csr4, 32[temp]
storep csr5, 40[temp]
storep csr6, 48[temp]
storep csr7, 56[temp]
storep csr8, 64[temp]
storep csr9, 72[temp]
stored csfr0, 80[temp]
stored csfr1, 88[temp]
stored csfr2, 96[temp]
stored csfr3, 104[temp]
stored csfr4, 112[temp]
stored csfr5, 120[temp]
stored csfr6, 128[temp]
stored csfr7, 136[temp]
elsif X86_64
storep csr0, [temp]
storep csr1, 8[temp]
storep csr2, 16[temp]
storep csr3, 24[temp]
storep csr4, 32[temp]
elsif X86_64_WIN
storep csr0, [temp]
storep csr1, 8[temp]
storep csr2, 16[temp]
storep csr3, 24[temp]
storep csr4, 32[temp]
storep csr5, 40[temp]
storep csr6, 48[temp]
end
end
end
macro restoreCalleeSavesFromVMEntryFrameCalleeSavesBuffer(vm, temp)
if ARM64 or X86_64 or X86_64_WIN
loadp VM::topVMEntryFrame[vm], temp
vmEntryRecord(temp, temp)
leap VMEntryRecord::calleeSaveRegistersBuffer[temp], temp
if ARM64
loadp [temp], csr0
loadp 8[temp], csr1
loadp 16[temp], csr2
loadp 24[temp], csr3
loadp 32[temp], csr4
loadp 40[temp], csr5
loadp 48[temp], csr6
loadp 56[temp], csr7
loadp 64[temp], csr8
loadp 72[temp], csr9
loadd 80[temp], csfr0
loadd 88[temp], csfr1
loadd 96[temp], csfr2
loadd 104[temp], csfr3
loadd 112[temp], csfr4
loadd 120[temp], csfr5
loadd 128[temp], csfr6
loadd 136[temp], csfr7
elsif X86_64
loadp [temp], csr0
loadp 8[temp], csr1
loadp 16[temp], csr2
loadp 24[temp], csr3
loadp 32[temp], csr4
elsif X86_64_WIN
loadp [temp], csr0
loadp 8[temp], csr1
loadp 16[temp], csr2
loadp 24[temp], csr3
loadp 32[temp], csr4
loadp 40[temp], csr5
loadp 48[temp], csr6
end
end
end
macro preserveReturnAddressAfterCall(destinationRegister)
if C_LOOP or ARM or ARMv7 or ARMv7_TRADITIONAL or ARM64 or MIPS
# In C_LOOP case, we're only preserving the bytecode vPC.
move lr, destinationRegister
elsif X86 or X86_WIN or X86_64 or X86_64_WIN
pop destinationRegister
else
error
end
end
macro functionPrologue()
if X86 or X86_WIN or X86_64 or X86_64_WIN
push cfr
elsif ARM64
push cfr, lr
elsif C_LOOP or ARM or ARMv7 or ARMv7_TRADITIONAL or MIPS
push lr
push cfr
end
move sp, cfr
end
macro functionEpilogue()
if X86 or X86_WIN or X86_64 or X86_64_WIN
pop cfr
elsif ARM64
pop lr, cfr
elsif C_LOOP or ARM or ARMv7 or ARMv7_TRADITIONAL or MIPS
pop cfr
pop lr
end
end
macro vmEntryRecord(entryFramePointer, resultReg)
subp entryFramePointer, VMEntryTotalFrameSize, resultReg
end
macro getFrameRegisterSizeForCodeBlock(codeBlock, size)
loadi CodeBlock::m_numCalleeLocals[codeBlock], size
lshiftp 3, size
addp maxFrameExtentForSlowPathCall, size
end
macro restoreStackPointerAfterCall()
loadp CodeBlock[cfr], t2
getFrameRegisterSizeForCodeBlock(t2, t2)
if ARMv7
subp cfr, t2, t2
move t2, sp
else
subp cfr, t2, sp
end
end
macro traceExecution()
if COLLECT_STATS
callSlowPath(_llint_count_opcode)
end
if EXECUTION_TRACING
callSlowPath(_llint_trace)
end
end
macro traceSlowPathExecution()
if COLLECT_STATS
callSlowPath(_llint_count_opcode_slow_path)
end
end
macro callOpcodeSlowPath(slowPath)
traceSlowPathExecution()
callSlowPath(slowPath)
end
macro callTargetFunction(callee)
if C_LOOP
cloopCallJSFunction callee
else
call callee
end
restoreStackPointerAfterCall()
dispatchAfterCall()
end
macro prepareForRegularCall(callee, temp1, temp2, temp3)
addp CallerFrameAndPCSize, sp
end
# sp points to the new frame
macro prepareForTailCall(callee, temp1, temp2, temp3)
restoreCalleeSavesUsedByLLInt()
loadi PayloadOffset + ArgumentCount[cfr], temp2
loadp CodeBlock[cfr], temp1
loadp CodeBlock::m_numParameters[temp1], temp1
bilteq temp1, temp2, .noArityFixup
move temp1, temp2
.noArityFixup:
# We assume < 2^28 arguments
muli SlotSize, temp2
addi StackAlignment - 1 + CallFrameHeaderSize, temp2
andi ~StackAlignmentMask, temp2
move cfr, temp1
addp temp2, temp1
loadi PayloadOffset + ArgumentCount[sp], temp2
# We assume < 2^28 arguments
muli SlotSize, temp2
addi StackAlignment - 1 + CallFrameHeaderSize, temp2
andi ~StackAlignmentMask, temp2
if ARM or ARMv7_TRADITIONAL or ARMv7 or ARM64 or C_LOOP or MIPS
addp 2 * PtrSize, sp
subi 2 * PtrSize, temp2
loadp PtrSize[cfr], lr
else
addp PtrSize, sp
subi PtrSize, temp2
loadp PtrSize[cfr], temp3
storep temp3, [sp]
end
subp temp2, temp1
loadp [cfr], cfr
.copyLoop:
subi PtrSize, temp2
loadp [sp, temp2, 1], temp3
storep temp3, [temp1, temp2, 1]
btinz temp2, .copyLoop
move temp1, sp
jmp callee
end
macro slowPathForCall(slowPath, prepareCall)
traceSlowPathExecution()
callCallSlowPath(
slowPath,
# Those are r0 and r1
macro (callee, calleeFramePtr)
btpz calleeFramePtr, .dontUpdateSP
move calleeFramePtr, sp
prepareCall(callee, t2, t3, t4)
.dontUpdateSP:
callTargetFunction(callee)
end)
end
macro arrayProfile(cellAndIndexingType, profile, scratch)
const cell = cellAndIndexingType
const indexingType = cellAndIndexingType
loadi JSCell::m_structureID[cell], scratch
storei scratch, ArrayProfile::m_lastSeenStructureID[profile]
loadb JSCell::m_indexingTypeAndMisc[cell], indexingType
end
macro skipIfIsRememberedOrInEden(cell, slowPath)
memfence
bba JSCell::m_cellState[cell], BlackThreshold, .done
slowPath()
.done:
end
macro notifyWrite(set, slow)
bbneq WatchpointSet::m_state[set], IsInvalidated, slow
end
macro checkSwitchToJIT(increment, action)
loadp CodeBlock[cfr], t0
baddis increment, CodeBlock::m_llintExecuteCounter + BaselineExecutionCounter::m_counter[t0], .continue
action()
.continue:
end
macro checkSwitchToJITForEpilogue()
checkSwitchToJIT(
10,
macro ()
callOpcodeSlowPath(_llint_replace)
end)
end
macro assertNotConstant(index)
assert(macro (ok) bilt index, FirstConstantRegisterIndex, ok end)
end
macro functionForCallCodeBlockGetter(targetRegister)
if JSVALUE64
loadp Callee[cfr], targetRegister
else
loadp Callee + PayloadOffset[cfr], targetRegister
end
loadp JSFunction::m_executable[targetRegister], targetRegister
loadp FunctionExecutable::m_codeBlockForCall[targetRegister], targetRegister
end
macro functionForConstructCodeBlockGetter(targetRegister)
if JSVALUE64
loadp Callee[cfr], targetRegister
else
loadp Callee + PayloadOffset[cfr], targetRegister
end
loadp JSFunction::m_executable[targetRegister], targetRegister
loadp FunctionExecutable::m_codeBlockForConstruct[targetRegister], targetRegister
end
macro notFunctionCodeBlockGetter(targetRegister)
loadp CodeBlock[cfr], targetRegister
end
macro functionCodeBlockSetter(sourceRegister)
storep sourceRegister, CodeBlock[cfr]
end
macro notFunctionCodeBlockSetter(sourceRegister)
# Nothing to do!
end
# Do the bare minimum required to execute code. Sets up the PC, leave the CodeBlock*
# in t1. May also trigger prologue entry OSR.
macro prologue(codeBlockGetter, codeBlockSetter, osrSlowPath, traceSlowPath)
# Set up the call frame and check if we should OSR.
preserveCallerPCAndCFR()
if EXECUTION_TRACING
subp maxFrameExtentForSlowPathCall, sp
callSlowPath(traceSlowPath)
addp maxFrameExtentForSlowPathCall, sp
end
codeBlockGetter(t1)
if not C_LOOP
baddis 5, CodeBlock::m_llintExecuteCounter + BaselineExecutionCounter::m_counter[t1], .continue
if JSVALUE64
move cfr, a0
move PC, a1
cCall2(osrSlowPath)
else
# We are after the function prologue, but before we have set up sp from the CodeBlock.
# Temporarily align stack pointer for this call.
subp 8, sp
move cfr, a0
move PC, a1
cCall2(osrSlowPath)
addp 8, sp
end
btpz r0, .recover
move cfr, sp # restore the previous sp
# pop the callerFrame since we will jump to a function that wants to save it
if ARM64
pop lr, cfr
elsif ARM or ARMv7 or ARMv7_TRADITIONAL or MIPS
pop cfr
pop lr
else
pop cfr
end
jmp r0
.recover:
codeBlockGetter(t1)
.continue:
end
codeBlockSetter(t1)
preserveCalleeSavesUsedByLLInt()
# Set up the PC.
if JSVALUE64
loadp CodeBlock::m_instructions[t1], PB
move 0, PC
else
loadp CodeBlock::m_instructions[t1], PC
end
# Get new sp in t0 and check stack height.
getFrameRegisterSizeForCodeBlock(t1, t0)
subp cfr, t0, t0
bpa t0, cfr, .needStackCheck
loadp CodeBlock::m_vm[t1], t2
if C_LOOP
bpbeq VM::m_cloopStackLimit[t2], t0, .stackHeightOK
else
bpbeq VM::m_softStackLimit[t2], t0, .stackHeightOK
end
.needStackCheck:
# Stack height check failed - need to call a slow_path.
# Set up temporary stack pointer for call including callee saves
subp maxFrameExtentForSlowPathCall, sp
callSlowPath(_llint_stack_check)
bpeq r1, 0, .stackHeightOKGetCodeBlock
move r1, cfr
dispatch(0) # Go to exception handler in PC
.stackHeightOKGetCodeBlock:
# Stack check slow path returned that the stack was ok.
# Since they were clobbered, need to get CodeBlock and new sp
codeBlockGetter(t1)
getFrameRegisterSizeForCodeBlock(t1, t0)
subp cfr, t0, t0
.stackHeightOK:
move t0, sp
if JSVALUE64
move TagTypeNumber, tagTypeNumber
addp TagBitTypeOther, tagTypeNumber, tagMask
end
end
# Expects that CodeBlock is in t1, which is what prologue() leaves behind.
# Must call dispatch(0) after calling this.
macro functionInitialization(profileArgSkip)
# Profile the arguments. Unfortunately, we have no choice but to do this. This
# code is pretty horrendous because of the difference in ordering between
# arguments and value profiles, the desire to have a simple loop-down-to-zero
# loop, and the desire to use only three registers so as to preserve the PC and
# the code block. It is likely that this code should be rewritten in a more
# optimal way for architectures that have more than five registers available
# for arbitrary use in the interpreter.
loadi CodeBlock::m_numParameters[t1], t0
addp -profileArgSkip, t0 # Use addi because that's what has the peephole
assert(macro (ok) bpgteq t0, 0, ok end)
btpz t0, .argumentProfileDone
loadp CodeBlock::m_argumentValueProfiles + VectorBufferOffset[t1], t3
mulp sizeof ValueProfile, t0, t2 # Aaaaahhhh! Need strength reduction!
lshiftp 3, t0
addp t2, t3
.argumentProfileLoop:
if JSVALUE64
loadq ThisArgumentOffset - 8 + profileArgSkip * 8[cfr, t0], t2
subp sizeof ValueProfile, t3
storeq t2, profileArgSkip * sizeof ValueProfile + ValueProfile::m_buckets[t3]
else
loadi ThisArgumentOffset + TagOffset - 8 + profileArgSkip * 8[cfr, t0], t2
subp sizeof ValueProfile, t3
storei t2, profileArgSkip * sizeof ValueProfile + ValueProfile::m_buckets + TagOffset[t3]
loadi ThisArgumentOffset + PayloadOffset - 8 + profileArgSkip * 8[cfr, t0], t2
storei t2, profileArgSkip * sizeof ValueProfile + ValueProfile::m_buckets + PayloadOffset[t3]
end
baddpnz -8, t0, .argumentProfileLoop
.argumentProfileDone:
end
macro doReturn()
restoreCalleeSavesUsedByLLInt()
restoreCallerPCAndCFR()
ret
end
# stub to call into JavaScript or Native functions
# EncodedJSValue vmEntryToJavaScript(void* code, VM* vm, ProtoCallFrame* protoFrame)
# EncodedJSValue vmEntryToNativeFunction(void* code, VM* vm, ProtoCallFrame* protoFrame)
if C_LOOP
_llint_vm_entry_to_javascript:
else
global _vmEntryToJavaScript
_vmEntryToJavaScript:
end
doVMEntry(makeJavaScriptCall)
if C_LOOP
_llint_vm_entry_to_native:
else
global _vmEntryToNative
_vmEntryToNative:
end
doVMEntry(makeHostFunctionCall)
if not C_LOOP
# void sanitizeStackForVMImpl(VM* vm)
global _sanitizeStackForVMImpl
_sanitizeStackForVMImpl:
# We need three non-aliased caller-save registers. We are guaranteed
# this for a0, a1 and a2 on all architectures.
if X86 or X86_WIN
loadp 4[sp], a0
end
const vm = a0
const address = a1
const zeroValue = a2
loadp VM::m_lastStackTop[vm], address
bpbeq sp, address, .zeroFillDone
move 0, zeroValue
.zeroFillLoop:
storep zeroValue, [address]
addp PtrSize, address
bpa sp, address, .zeroFillLoop
.zeroFillDone:
move sp, address
storep address, VM::m_lastStackTop[vm]
ret
# VMEntryRecord* vmEntryRecord(const VMEntryFrame* entryFrame)
global _vmEntryRecord
_vmEntryRecord:
if X86 or X86_WIN
loadp 4[sp], a0
end
vmEntryRecord(a0, r0)
ret
end
if C_LOOP
# Dummy entry point the C Loop uses to initialize.
_llint_entry:
crash()
else
macro initPCRelative(pcBase)
if X86_64 or X86_64_WIN or X86 or X86_WIN
call _relativePCBase
_relativePCBase:
pop pcBase
elsif ARM64
elsif ARMv7
_relativePCBase:
move pc, pcBase
subp 3, pcBase # Need to back up the PC and set the Thumb2 bit
elsif ARM or ARMv7_TRADITIONAL
_relativePCBase:
move pc, pcBase
subp 8, pcBase
elsif MIPS
la _relativePCBase, pcBase
setcallreg pcBase # needed to set $t9 to the right value for the .cpload created by the label.
_relativePCBase:
end
end
# The PC base is in t1, as this is what _llint_entry leaves behind through
# initPCRelative(t1)
macro setEntryAddress(index, label)
if X86_64 or X86_64_WIN
leap (label - _relativePCBase)[t1], t3
move index, t4
storep t3, [a0, t4, 8]
elsif X86 or X86_WIN
leap (label - _relativePCBase)[t1], t3
move index, t4
storep t3, [a0, t4, 4]
elsif ARM64
pcrtoaddr label, t1
move index, t4
storep t1, [a0, t4, 8]
elsif ARM or ARMv7 or ARMv7_TRADITIONAL
mvlbl (label - _relativePCBase), t4
addp t4, t1, t4
move index, t3
storep t4, [a0, t3, 4]
elsif MIPS
la label, t4
la _relativePCBase, t3
subp t3, t4
addp t4, t1, t4
move index, t3
storep t4, [a0, t3, 4]
end
end
global _llint_entry
# Entry point for the llint to initialize.
_llint_entry:
functionPrologue()
pushCalleeSaves()
if X86 or X86_WIN
loadp 20[sp], a0
end
initPCRelative(t1)
# Include generated bytecode initialization file.
include InitBytecodes
popCalleeSaves()
functionEpilogue()
ret
end
_llint_program_prologue:
prologue(notFunctionCodeBlockGetter, notFunctionCodeBlockSetter, _llint_entry_osr, _llint_trace_prologue)
dispatch(0)
_llint_module_program_prologue:
prologue(notFunctionCodeBlockGetter, notFunctionCodeBlockSetter, _llint_entry_osr, _llint_trace_prologue)
dispatch(0)
_llint_eval_prologue:
prologue(notFunctionCodeBlockGetter, notFunctionCodeBlockSetter, _llint_entry_osr, _llint_trace_prologue)
dispatch(0)
_llint_function_for_call_prologue:
prologue(functionForCallCodeBlockGetter, functionCodeBlockSetter, _llint_entry_osr_function_for_call, _llint_trace_prologue_function_for_call)
functionInitialization(0)
dispatch(0)
_llint_function_for_construct_prologue:
prologue(functionForConstructCodeBlockGetter, functionCodeBlockSetter, _llint_entry_osr_function_for_construct, _llint_trace_prologue_function_for_construct)
functionInitialization(1)
dispatch(0)
_llint_function_for_call_arity_check:
prologue(functionForCallCodeBlockGetter, functionCodeBlockSetter, _llint_entry_osr_function_for_call_arityCheck, _llint_trace_arityCheck_for_call)
functionArityCheck(.functionForCallBegin, _slow_path_call_arityCheck)
.functionForCallBegin:
functionInitialization(0)
dispatch(0)
_llint_function_for_construct_arity_check:
prologue(functionForConstructCodeBlockGetter, functionCodeBlockSetter, _llint_entry_osr_function_for_construct_arityCheck, _llint_trace_arityCheck_for_construct)
functionArityCheck(.functionForConstructBegin, _slow_path_construct_arityCheck)
.functionForConstructBegin:
functionInitialization(1)
dispatch(0)
# Value-representation-specific code.
if JSVALUE64
include LowLevelInterpreter64
else
include LowLevelInterpreter32_64
end
# Value-representation-agnostic code.
_llint_op_create_direct_arguments:
traceExecution()
callOpcodeSlowPath(_slow_path_create_direct_arguments)
dispatch(constexpr op_create_direct_arguments_length)
_llint_op_create_scoped_arguments:
traceExecution()
callOpcodeSlowPath(_slow_path_create_scoped_arguments)
dispatch(constexpr op_create_scoped_arguments_length)
_llint_op_create_cloned_arguments:
traceExecution()
callOpcodeSlowPath(_slow_path_create_cloned_arguments)
dispatch(constexpr op_create_cloned_arguments_length)
_llint_op_create_this:
traceExecution()
callOpcodeSlowPath(_slow_path_create_this)
dispatch(constexpr op_create_this_length)
_llint_op_new_object:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_new_object)
dispatch(constexpr op_new_object_length)
_llint_op_new_func:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_new_func)
dispatch(constexpr op_new_func_length)
_llint_op_new_generator_func:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_new_generator_func)
dispatch(constexpr op_new_generator_func_length)
_llint_op_new_async_func:
traceExecution()
callSlowPath(_llint_slow_path_new_async_func)
dispatch(constexpr op_new_async_func_length)
_llint_op_new_array:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_new_array)
dispatch(constexpr op_new_array_length)
_llint_op_new_array_with_spread:
traceExecution()
callOpcodeSlowPath(_slow_path_new_array_with_spread)
dispatch(constexpr op_new_array_with_spread_length)
_llint_op_spread:
traceExecution()
callOpcodeSlowPath(_slow_path_spread)
dispatch(constexpr op_spread_length)
_llint_op_new_array_with_size:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_new_array_with_size)
dispatch(constexpr op_new_array_with_size_length)
_llint_op_new_array_buffer:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_new_array_buffer)
dispatch(constexpr op_new_array_buffer_length)
_llint_op_new_regexp:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_new_regexp)
dispatch(constexpr op_new_regexp_length)
_llint_op_less:
traceExecution()
callOpcodeSlowPath(_slow_path_less)
dispatch(constexpr op_less_length)
_llint_op_lesseq:
traceExecution()
callOpcodeSlowPath(_slow_path_lesseq)
dispatch(constexpr op_lesseq_length)
_llint_op_greater:
traceExecution()
callOpcodeSlowPath(_slow_path_greater)
dispatch(constexpr op_greater_length)
_llint_op_greatereq:
traceExecution()
callOpcodeSlowPath(_slow_path_greatereq)
dispatch(constexpr op_greatereq_length)
_llint_op_mod:
traceExecution()
callOpcodeSlowPath(_slow_path_mod)
dispatch(constexpr op_mod_length)
_llint_op_pow:
traceExecution()
callOpcodeSlowPath(_slow_path_pow)
dispatch(constexpr op_pow_length)
_llint_op_typeof:
traceExecution()
callOpcodeSlowPath(_slow_path_typeof)
dispatch(constexpr op_typeof_length)
_llint_op_is_object_or_null:
traceExecution()
callOpcodeSlowPath(_slow_path_is_object_or_null)
dispatch(constexpr op_is_object_or_null_length)
_llint_op_is_function:
traceExecution()
callOpcodeSlowPath(_slow_path_is_function)
dispatch(constexpr op_is_function_length)
_llint_op_in:
traceExecution()
callOpcodeSlowPath(_slow_path_in)
dispatch(constexpr op_in_length)
_llint_op_try_get_by_id:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_try_get_by_id)
dispatch(constexpr op_try_get_by_id_length)
_llint_op_del_by_id:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_del_by_id)
dispatch(constexpr op_del_by_id_length)
_llint_op_del_by_val:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_del_by_val)
dispatch(constexpr op_del_by_val_length)
_llint_op_put_by_index:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_put_by_index)
dispatch(constexpr op_put_by_index_length)
_llint_op_put_getter_by_id:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_put_getter_by_id)
dispatch(constexpr op_put_getter_by_id_length)
_llint_op_put_setter_by_id:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_put_setter_by_id)
dispatch(constexpr op_put_setter_by_id_length)
_llint_op_put_getter_setter_by_id:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_put_getter_setter_by_id)
dispatch(constexpr op_put_getter_setter_by_id_length)
_llint_op_put_getter_by_val:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_put_getter_by_val)
dispatch(constexpr op_put_getter_by_val_length)
_llint_op_put_setter_by_val:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_put_setter_by_val)
dispatch(constexpr op_put_setter_by_val_length)
_llint_op_define_data_property:
traceExecution()
callOpcodeSlowPath(_slow_path_define_data_property)
dispatch(constexpr op_define_data_property_length)
_llint_op_define_accessor_property:
traceExecution()
callOpcodeSlowPath(_slow_path_define_accessor_property)
dispatch(constexpr op_define_accessor_property_length)
_llint_op_jtrue:
traceExecution()
jumpTrueOrFalse(
macro (value, target) btinz value, target end,
_llint_slow_path_jtrue)
_llint_op_jfalse:
traceExecution()
jumpTrueOrFalse(
macro (value, target) btiz value, target end,
_llint_slow_path_jfalse)
_llint_op_jless:
traceExecution()
compare(
macro (left, right, target) bilt left, right, target end,
macro (left, right, target) bdlt left, right, target end,
_llint_slow_path_jless)
_llint_op_jnless:
traceExecution()
compare(
macro (left, right, target) bigteq left, right, target end,
macro (left, right, target) bdgtequn left, right, target end,
_llint_slow_path_jnless)
_llint_op_jgreater:
traceExecution()
compare(
macro (left, right, target) bigt left, right, target end,
macro (left, right, target) bdgt left, right, target end,
_llint_slow_path_jgreater)
_llint_op_jngreater:
traceExecution()
compare(
macro (left, right, target) bilteq left, right, target end,
macro (left, right, target) bdltequn left, right, target end,
_llint_slow_path_jngreater)
_llint_op_jlesseq:
traceExecution()
compare(
macro (left, right, target) bilteq left, right, target end,
macro (left, right, target) bdlteq left, right, target end,
_llint_slow_path_jlesseq)
_llint_op_jnlesseq:
traceExecution()
compare(
macro (left, right, target) bigt left, right, target end,
macro (left, right, target) bdgtun left, right, target end,
_llint_slow_path_jnlesseq)
_llint_op_jgreatereq:
traceExecution()
compare(
macro (left, right, target) bigteq left, right, target end,
macro (left, right, target) bdgteq left, right, target end,
_llint_slow_path_jgreatereq)
_llint_op_jngreatereq:
traceExecution()
compare(
macro (left, right, target) bilt left, right, target end,
macro (left, right, target) bdltun left, right, target end,
_llint_slow_path_jngreatereq)
_llint_op_loop_hint:
traceExecution()
checkSwitchToJITForLoop()
dispatch(constexpr op_loop_hint_length)
_llint_op_check_traps:
traceExecution()
loadp CodeBlock[cfr], t1
loadp CodeBlock::m_vm[t1], t1
loadb VM::m_traps+VMTraps::m_needTrapHandling[t1], t0
btpnz t0, .handleTraps
.afterHandlingTraps:
dispatch(constexpr op_check_traps_length)
.handleTraps:
callTrapHandler(.throwHandler)
jmp .afterHandlingTraps
.throwHandler:
jmp _llint_throw_from_slow_path_trampoline
# Returns the packet pointer in t0.
macro acquireShadowChickenPacket(slow)
loadp CodeBlock[cfr], t1
loadp CodeBlock::m_vm[t1], t1
loadp VM::m_shadowChicken[t1], t2
loadp ShadowChicken::m_logCursor[t2], t0
bpaeq t0, ShadowChicken::m_logEnd[t2], slow
addp sizeof ShadowChicken::Packet, t0, t1
storep t1, ShadowChicken::m_logCursor[t2]
end
_llint_op_nop:
dispatch(constexpr op_nop_length)
_llint_op_switch_string:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_switch_string)
dispatch(0)
_llint_op_new_func_exp:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_new_func_exp)
dispatch(constexpr op_new_func_exp_length)
_llint_op_new_generator_func_exp:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_new_generator_func_exp)
dispatch(constexpr op_new_generator_func_exp_length)
_llint_op_new_async_func_exp:
traceExecution()
callSlowPath(_llint_slow_path_new_async_func_exp)
dispatch(constexpr op_new_async_func_exp_length)
_llint_op_set_function_name:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_set_function_name)
dispatch(constexpr op_set_function_name_length)
_llint_op_call:
traceExecution()
arrayProfileForCall()
doCall(_llint_slow_path_call, prepareForRegularCall)
_llint_op_tail_call:
traceExecution()
arrayProfileForCall()
checkSwitchToJITForEpilogue()
doCall(_llint_slow_path_call, prepareForTailCall)
_llint_op_construct:
traceExecution()
doCall(_llint_slow_path_construct, prepareForRegularCall)
macro doCallVarargs(frameSlowPath, slowPath, prepareCall)
callOpcodeSlowPath(frameSlowPath)
branchIfException(_llint_throw_from_slow_path_trampoline)
# calleeFrame in r1
if JSVALUE64
move r1, sp
else
# The calleeFrame is not stack aligned, move down by CallerFrameAndPCSize to align
if ARMv7
subp r1, CallerFrameAndPCSize, t2
move t2, sp
else
subp r1, CallerFrameAndPCSize, sp
end
end
slowPathForCall(slowPath, prepareCall)
end
_llint_op_call_varargs:
traceExecution()
doCallVarargs(_llint_slow_path_size_frame_for_varargs, _llint_slow_path_call_varargs, prepareForRegularCall)
_llint_op_tail_call_varargs:
traceExecution()
checkSwitchToJITForEpilogue()
# We lie and perform the tail call instead of preparing it since we can't
# prepare the frame for a call opcode
doCallVarargs(_llint_slow_path_size_frame_for_varargs, _llint_slow_path_call_varargs, prepareForTailCall)
_llint_op_tail_call_forward_arguments:
traceExecution()
checkSwitchToJITForEpilogue()
# We lie and perform the tail call instead of preparing it since we can't
# prepare the frame for a call opcode
doCallVarargs(_llint_slow_path_size_frame_for_forward_arguments, _llint_slow_path_tail_call_forward_arguments, prepareForTailCall)
_llint_op_construct_varargs:
traceExecution()
doCallVarargs(_llint_slow_path_size_frame_for_varargs, _llint_slow_path_construct_varargs, prepareForRegularCall)
_llint_op_call_eval:
traceExecution()
# Eval is executed in one of two modes:
#
# 1) We find that we're really invoking eval() in which case the
# execution is perfomed entirely inside the slow_path, and it
# returns the PC of a function that just returns the return value
# that the eval returned.
#
# 2) We find that we're invoking something called eval() that is not
# the real eval. Then the slow_path returns the PC of the thing to
# call, and we call it.
#
# This allows us to handle two cases, which would require a total of
# up to four pieces of state that cannot be easily packed into two
# registers (C functions can return up to two registers, easily):
#
# - The call frame register. This may or may not have been modified
# by the slow_path, but the convention is that it returns it. It's not
# totally clear if that's necessary, since the cfr is callee save.
# But that's our style in this here interpreter so we stick with it.
#
# - A bit to say if the slow_path successfully executed the eval and has
# the return value, or did not execute the eval but has a PC for us
# to call.
#
# - Either:
# - The JS return value (two registers), or
#
# - The PC to call.
#
# It turns out to be easier to just always have this return the cfr
# and a PC to call, and that PC may be a dummy thunk that just
# returns the JS value that the eval returned.
slowPathForCall(_llint_slow_path_call_eval, prepareForRegularCall)
_llint_generic_return_point:
dispatchAfterCall()
_llint_op_strcat:
traceExecution()
callOpcodeSlowPath(_slow_path_strcat)
dispatch(constexpr op_strcat_length)
_llint_op_push_with_scope:
traceExecution()
callOpcodeSlowPath(_slow_path_push_with_scope)
dispatch(constexpr op_push_with_scope_length)
_llint_op_assert:
traceExecution()
callOpcodeSlowPath(_slow_path_assert)
dispatch(constexpr op_assert_length)
_llint_op_unreachable:
traceExecution()
callOpcodeSlowPath(_slow_path_unreachable)
dispatch(constexpr op_unreachable_length)
_llint_op_yield:
notSupported()
_llint_op_create_lexical_environment:
traceExecution()
callOpcodeSlowPath(_slow_path_create_lexical_environment)
dispatch(constexpr op_create_lexical_environment_length)
_llint_op_throw:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_throw)
dispatch(constexpr op_throw_length)
_llint_op_throw_static_error:
traceExecution()
callOpcodeSlowPath(_slow_path_throw_static_error)
dispatch(constexpr op_throw_static_error_length)
_llint_op_debug:
traceExecution()
loadp CodeBlock[cfr], t0
loadi CodeBlock::m_debuggerRequests[t0], t0
btiz t0, .opDebugDone
callOpcodeSlowPath(_llint_slow_path_debug)
.opDebugDone:
dispatch(constexpr op_debug_length)
_llint_native_call_trampoline:
nativeCallTrampoline(NativeExecutable::m_function)
_llint_native_construct_trampoline:
nativeCallTrampoline(NativeExecutable::m_constructor)
_llint_op_get_enumerable_length:
traceExecution()
callOpcodeSlowPath(_slow_path_get_enumerable_length)
dispatch(constexpr op_get_enumerable_length_length)
_llint_op_has_indexed_property:
traceExecution()
callOpcodeSlowPath(_slow_path_has_indexed_property)
dispatch(constexpr op_has_indexed_property_length)
_llint_op_has_structure_property:
traceExecution()
callOpcodeSlowPath(_slow_path_has_structure_property)
dispatch(constexpr op_has_structure_property_length)
_llint_op_has_generic_property:
traceExecution()
callOpcodeSlowPath(_slow_path_has_generic_property)
dispatch(constexpr op_has_generic_property_length)
_llint_op_get_direct_pname:
traceExecution()
callOpcodeSlowPath(_slow_path_get_direct_pname)
dispatch(constexpr op_get_direct_pname_length)
_llint_op_get_property_enumerator:
traceExecution()
callOpcodeSlowPath(_slow_path_get_property_enumerator)
dispatch(constexpr op_get_property_enumerator_length)
_llint_op_enumerator_structure_pname:
traceExecution()
callOpcodeSlowPath(_slow_path_next_structure_enumerator_pname)
dispatch(constexpr op_enumerator_structure_pname_length)
_llint_op_enumerator_generic_pname:
traceExecution()
callOpcodeSlowPath(_slow_path_next_generic_enumerator_pname)
dispatch(constexpr op_enumerator_generic_pname_length)
_llint_op_to_index_string:
traceExecution()
callOpcodeSlowPath(_slow_path_to_index_string)
dispatch(constexpr op_to_index_string_length)
_llint_op_create_rest:
traceExecution()
callOpcodeSlowPath(_slow_path_create_rest)
dispatch(constexpr op_create_rest_length)
_llint_op_instanceof:
traceExecution()
callOpcodeSlowPath(_llint_slow_path_instanceof)
dispatch(constexpr op_instanceof_length)
_llint_op_get_by_id_with_this:
traceExecution()
callOpcodeSlowPath(_slow_path_get_by_id_with_this)
dispatch(constexpr op_get_by_id_with_this_length)
_llint_op_get_by_val_with_this:
traceExecution()
callOpcodeSlowPath(_slow_path_get_by_val_with_this)
dispatch(constexpr op_get_by_val_with_this_length)
_llint_op_put_by_id_with_this:
traceExecution()
callOpcodeSlowPath(_slow_path_put_by_id_with_this)
dispatch(constexpr op_put_by_id_with_this_length)
_llint_op_put_by_val_with_this:
traceExecution()
callOpcodeSlowPath(_slow_path_put_by_val_with_this)
dispatch(constexpr op_put_by_val_with_this_length)
_llint_op_resolve_scope_for_hoisting_func_decl_in_eval:
traceExecution()
callOpcodeSlowPath(_slow_path_resolve_scope_for_hoisting_func_decl_in_eval)
dispatch(constexpr op_resolve_scope_for_hoisting_func_decl_in_eval_length)
# Lastly, make sure that we can link even though we don't support all opcodes.
# These opcodes should never arise when using LLInt or either JIT. We assert
# as much.
macro notSupported()
if ASSERT_ENABLED
crash()
else
# We should use whatever the smallest possible instruction is, just to
# ensure that there is a gap between instruction labels. If multiple
# smallest instructions exist, we should pick the one that is most
# likely result in execution being halted. Currently that is the break
# instruction on all architectures we're interested in. (Break is int3
# on Intel, which is 1 byte, and bkpt on ARMv7, which is 2 bytes.)
break
end
end
`;
new File("LowLevelInterpreter.asm", source);
})();