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cobalt / cobalt / 4fe09471d0134f1d49ad5034a1c8867d6f9f4551 / . / src / third_party / mozjs / js / src / jit / mips / Trampoline-mips.cpp
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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
* vim: set ts=8 sts=4 et sw=4 tw=99:
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "jscompartment.h"
#include "jit/Bailouts.h"
#include "jit/IonCompartment.h"
#include "jit/IonLinker.h"
#include "jit/IonFrames.h"
#include "jit/IonLinker.h"
#include "jit/IonSpewer.h"
#include "jit/Bailouts.h"
#include "jit/mips/Bailouts-mips.h"
#include "jit/mips/BaselineHelpers-mips.h"
#ifdef JS_ION_PERF
# include "jit/PerfSpewer.h"
#endif
#include "jit/VMFunctions.h"
#include "jit/mips/Bailouts-mips.h"
using namespace js;
using namespace js::jit;
static_assert(sizeof(uintptr_t) == sizeof(uint32_t), "Not 64-bit clean.");
struct EnterJITRegs
{
double f30;
double f28;
double f26;
double f24;
double f22;
double f20;
// empty slot for alignment
uintptr_t align;
// non-volatile registers.
uintptr_t ra;
uintptr_t s7;
uintptr_t s6;
uintptr_t s5;
uintptr_t s4;
uintptr_t s3;
uintptr_t s2;
uintptr_t s1;
uintptr_t s0;
};
struct EnterJITArgs
{
// First 4 argumet placeholders
void *jitcode; // <- sp points here when function is entered.
int maxArgc;
Value *maxArgv;
StackFrame* fp;
// Arguments on stack
CalleeToken calleeToken;
JSObject *scopeChain;
size_t numStackValues;
Value *vp;
};
static void
GenerateReturn(MacroAssembler &masm, int returnCode)
{
MOZ_ASSERT(masm.framePushed() == sizeof(EnterJITRegs));
// Restore non-volatile registers
masm.loadPtr(Address(StackPointer, offsetof(EnterJITRegs, s0)), s0);
masm.loadPtr(Address(StackPointer, offsetof(EnterJITRegs, s1)), s1);
masm.loadPtr(Address(StackPointer, offsetof(EnterJITRegs, s2)), s2);
masm.loadPtr(Address(StackPointer, offsetof(EnterJITRegs, s3)), s3);
masm.loadPtr(Address(StackPointer, offsetof(EnterJITRegs, s4)), s4);
masm.loadPtr(Address(StackPointer, offsetof(EnterJITRegs, s5)), s5);
masm.loadPtr(Address(StackPointer, offsetof(EnterJITRegs, s6)), s6);
masm.loadPtr(Address(StackPointer, offsetof(EnterJITRegs, s7)), s7);
masm.loadPtr(Address(StackPointer, offsetof(EnterJITRegs, ra)), ra);
// Restore non-volatile floating point registers
masm.loadDouble(Address(StackPointer, offsetof(EnterJITRegs, f20)), f20);
masm.loadDouble(Address(StackPointer, offsetof(EnterJITRegs, f22)), f22);
masm.loadDouble(Address(StackPointer, offsetof(EnterJITRegs, f24)), f24);
masm.loadDouble(Address(StackPointer, offsetof(EnterJITRegs, f26)), f26);
masm.loadDouble(Address(StackPointer, offsetof(EnterJITRegs, f28)), f28);
masm.loadDouble(Address(StackPointer, offsetof(EnterJITRegs, f30)), f30);
masm.freeStack(sizeof(EnterJITRegs));
masm.branch(ra);
}
static void
GeneratePrologue(MacroAssembler &masm)
{
// Save non-volatile registers. These must be saved by the trampoline,
// rather than the JIT'd code, because they are scanned by the conservative
// scanner.
masm.reserveStack(sizeof(EnterJITRegs));
masm.storePtr(s0, Address(StackPointer, offsetof(EnterJITRegs, s0)));
masm.storePtr(s1, Address(StackPointer, offsetof(EnterJITRegs, s1)));
masm.storePtr(s2, Address(StackPointer, offsetof(EnterJITRegs, s2)));
masm.storePtr(s3, Address(StackPointer, offsetof(EnterJITRegs, s3)));
masm.storePtr(s4, Address(StackPointer, offsetof(EnterJITRegs, s4)));
masm.storePtr(s5, Address(StackPointer, offsetof(EnterJITRegs, s5)));
masm.storePtr(s6, Address(StackPointer, offsetof(EnterJITRegs, s6)));
masm.storePtr(s7, Address(StackPointer, offsetof(EnterJITRegs, s7)));
masm.storePtr(ra, Address(StackPointer, offsetof(EnterJITRegs, ra)));
masm.as_sd(f20, StackPointer, offsetof(EnterJITRegs, f20));
masm.as_sd(f22, StackPointer, offsetof(EnterJITRegs, f22));
masm.as_sd(f24, StackPointer, offsetof(EnterJITRegs, f24));
masm.as_sd(f26, StackPointer, offsetof(EnterJITRegs, f26));
masm.as_sd(f28, StackPointer, offsetof(EnterJITRegs, f28));
masm.as_sd(f30, StackPointer, offsetof(EnterJITRegs, f30));
}
/*
* This method generates a trampoline for a c++ function with the following
* signature:
* void enter(void *code, int argc, Value *argv, InterpreterFrame *fp,
* CalleeToken calleeToken, JSObject *scopeChain, Value *vp)
* ...using standard EABI calling convention
*/
IonCode *
IonRuntime::generateEnterJIT(JSContext *cx, EnterJitType type)
{
const Register reg_code = a0;
const Register reg_argc = a1;
const Register reg_argv = a2;
const Register reg_frame = a3;
MOZ_ASSERT(OsrFrameReg == reg_frame);
MacroAssembler masm(cx);
GeneratePrologue(masm);
const Address slotToken(sp, sizeof(EnterJITRegs) + offsetof(EnterJITArgs, calleeToken));
const Address slotVp(sp, sizeof(EnterJITRegs) + offsetof(EnterJITArgs, vp));
// Save stack pointer into s4
masm.movePtr(StackPointer, s4);
// Load calleeToken into s2.
masm.loadPtr(slotToken, s2);
// Save stack pointer as baseline frame.
if (type == EnterJitBaseline)
masm.movePtr(StackPointer, BaselineFrameReg);
// Load the number of actual arguments into s3.
masm.loadPtr(slotVp, s3);
masm.unboxInt32(Address(s3, 0), s3);
/***************************************************************
Loop over argv vector, push arguments onto stack in reverse order
***************************************************************/
masm.as_sll(s0, reg_argc, 3); // s0 = argc * 8
masm.addPtr(reg_argv, s0); // s0 = argv + argc * 8
// Loop over arguments, copying them from an unknown buffer onto the Ion
// stack so they can be accessed from JIT'ed code.
Label header, footer;
// If there aren't any arguments, don't do anything
masm.ma_b(s0, reg_argv, &footer, Assembler::BelowOrEqual, ShortJump);
{
masm.bind(&header);
masm.subPtr(Imm32(2 * sizeof(uintptr_t)), s0);
masm.subPtr(Imm32(2 * sizeof(uintptr_t)), StackPointer);
ValueOperand value = ValueOperand(s6, s7);
masm.loadValue(Address(s0, 0), value);
masm.storeValue(value, Address(StackPointer, 0));
masm.ma_b(s0, reg_argv, &header, Assembler::Above, ShortJump);
}
masm.bind(&footer);
masm.subPtr(Imm32(2 * sizeof(uintptr_t)), StackPointer);
masm.storePtr(s3, Address(StackPointer, sizeof(uintptr_t))); // actual arguments
masm.storePtr(s2, Address(StackPointer, 0)); // callee token
masm.subPtr(StackPointer, s4);
masm.makeFrameDescriptor(s4, IonFrame_Entry);
masm.push(s4); // descriptor
CodeLabel returnLabel;
if (type == EnterJitBaseline) {
// Handle OSR.
GeneralRegisterSet regs(GeneralRegisterSet::All());
regs.take(JSReturnOperand);
regs.take(OsrFrameReg);
regs.take(BaselineFrameReg);
regs.take(reg_code);
const Address slotNumStackValues(BaselineFrameReg, sizeof(EnterJITRegs) +
offsetof(EnterJITArgs, numStackValues));
const Address slotScopeChain(BaselineFrameReg, sizeof(EnterJITRegs) +
offsetof(EnterJITArgs, scopeChain));
Label notOsr;
masm.ma_b(OsrFrameReg, OsrFrameReg, &notOsr, Assembler::Zero, ShortJump);
Register scratch = regs.takeAny();
Register numStackValues = regs.takeAny();
masm.load32(slotNumStackValues, numStackValues);
// Push return address, previous frame pointer.
masm.subPtr(Imm32(2 * sizeof(uintptr_t)), StackPointer);
masm.ma_li(scratch, returnLabel.dest());
masm.storePtr(scratch, Address(StackPointer, sizeof(uintptr_t)));
masm.storePtr(BaselineFrameReg, Address(StackPointer, 0));
// Reserve frame.
Register framePtr = BaselineFrameReg;
masm.subPtr(Imm32(BaselineFrame::Size()), StackPointer);
masm.movePtr(StackPointer, framePtr);
// Reserve space for locals and stack values.
masm.ma_sll(scratch, numStackValues, Imm32(3));
masm.subPtr(scratch, StackPointer);
// Enter exit frame.
masm.addPtr(Imm32(BaselineFrame::Size() + BaselineFrame::FramePointerOffset), scratch);
masm.makeFrameDescriptor(scratch, IonFrame_BaselineJS);
// Push frame descriptor and fake return address.
masm.reserveStack(2 * sizeof(uintptr_t));
masm.storePtr(scratch, Address(StackPointer, sizeof(uintptr_t))); // Frame descriptor
masm.storePtr(zero, Address(StackPointer, 0)); // fake return address
masm.enterFakeExitFrame();
masm.reserveStack(2 * sizeof(uintptr_t));
masm.storePtr(framePtr, Address(StackPointer, sizeof(uintptr_t))); // BaselineFrame
masm.storePtr(reg_code, Address(StackPointer, 0)); // jitcode
masm.setupUnalignedABICall(3, scratch);
masm.passABIArg(BaselineFrameReg); // BaselineFrame
masm.passABIArg(OsrFrameReg); // InterpreterFrame
masm.passABIArg(numStackValues);
masm.callWithABI(JS_FUNC_TO_DATA_PTR(void *, jit::InitBaselineFrameForOsr));
Register jitcode = regs.takeAny();
masm.loadPtr(Address(StackPointer, 0), jitcode);
masm.loadPtr(Address(StackPointer, sizeof(uintptr_t)), framePtr);
masm.freeStack(2 * sizeof(uintptr_t));
MOZ_ASSERT(jitcode != ReturnReg);
Label error;
masm.freeStack(IonExitFrameLayout::SizeWithFooter());
masm.addPtr(Imm32(BaselineFrame::Size()), framePtr);
masm.branchIfFalseBool(ReturnReg, &error);
masm.jump(jitcode);
// OOM: load error value, discard return address and previous frame
// pointer and return.
masm.bind(&error);
masm.movePtr(framePtr, StackPointer);
masm.addPtr(Imm32(2 * sizeof(uintptr_t)), StackPointer);
masm.moveValue(MagicValue(JS_ION_ERROR), JSReturnOperand);
masm.ma_li(scratch, returnLabel.dest());
masm.jump(scratch);
masm.bind(&notOsr);
// Load the scope chain in R1.
MOZ_ASSERT(R1.scratchReg() != reg_code);
masm.loadPtr(slotScopeChain, R1.scratchReg());
}
// Call the function with pushing return address to stack.
masm.ma_callIonHalfPush(reg_code);
if (type == EnterJitBaseline) {
// Baseline OSR will return here.
masm.bind(returnLabel.src());
if (!masm.addCodeLabel(returnLabel))
return nullptr;
}
// Pop arguments off the stack.
// s0 <- 8*argc (size of all arguments we pushed on the stack)
masm.pop(s0);
masm.rshiftPtr(Imm32(4), s0);
masm.addPtr(s0, StackPointer);
// Store the returned value into the slotVp
masm.loadPtr(slotVp, s1);
masm.storeValue(JSReturnOperand, Address(s1, 0));
// Restore non-volatile registers and return.
GenerateReturn(masm, ShortJump);
Linker linker(masm);
AutoFlushCache afc("GenerateEnterJIT");
#ifdef JS_ION_PERF
writePerfSpewerIonCodeProfile(code, "EnterJIT");
#endif
return linker.newCode(cx, JSC::OTHER_CODE);
}
IonCode *
IonRuntime::generateInvalidator(JSContext *cx)
{
MacroAssembler masm(cx);
// NOTE: Members ionScript_ and osiPointReturnAddress_ of
// InvalidationBailoutStack are already on the stack.
static const uint32_t STACK_DATA_SIZE = sizeof(InvalidationBailoutStack) -
2 * sizeof(uintptr_t);
// Stack has to be alligned here. If not, we will have to fix it.
masm.checkStackAlignment();
// Make room for data on stack.
masm.subPtr(Imm32(STACK_DATA_SIZE), StackPointer);
// Save general purpose registers
for (uint32_t i = 0; i < Registers::Total; i++) {
Address address = Address(StackPointer, InvalidationBailoutStack::offsetOfRegs() +
i * sizeof(uintptr_t));
masm.storePtr(Register::FromCode(i), address);
}
// Save floating point registers
// We can use as_sd because stack is alligned.
for (uint32_t i = 0; i < FloatRegisters::Total; i++) {
if (i % 2 == 0) {
masm.as_sd(FloatRegister::FromCode(i), StackPointer,
InvalidationBailoutStack::offsetOfFpRegs() + (i/2) * sizeof(double));
}
}
// Pass pointer to InvalidationBailoutStack structure.
masm.movePtr(StackPointer, a0);
// Reserve place for return value and BailoutInfo pointer
masm.subPtr(Imm32(2 * sizeof(uintptr_t)), StackPointer);
// Pass pointer to return value.
masm.ma_addu(a1, StackPointer, Imm32(sizeof(uintptr_t)));
// Pass pointer to BailoutInfo
masm.movePtr(StackPointer, a2);
masm.setupAlignedABICall(3);
masm.passABIArg(a0);
masm.passABIArg(a1);
masm.passABIArg(a2);
masm.callWithABI(JS_FUNC_TO_DATA_PTR(void *, InvalidationBailout));
masm.loadPtr(Address(StackPointer, 0), a2);
masm.loadPtr(Address(StackPointer, sizeof(uintptr_t)), a1);
// Remove the return address, the IonScript, the register state
// (InvaliationBailoutStack) and the space that was allocated for the
// return value.
masm.addPtr(Imm32(sizeof(InvalidationBailoutStack) + 2 * sizeof(uintptr_t)), StackPointer);
// remove the space that this frame was using before the bailout
// (computed by InvalidationBailout)
masm.addPtr(a1, StackPointer);
// Jump to shared bailout tail. The BailoutInfo pointer has to be in r2.
IonCode* bailoutTail = cx->runtime()->ionRuntime()->getBailoutTail();
masm.branch(bailoutTail);
Linker linker(masm);
AutoFlushCache afc("Invalidator");
IonCode* code = linker.newCode(cx, JSC::OTHER_CODE);
IonSpew(IonSpew_Invalidate, " invalidation thunk created at %p", (void *) code->raw());
return code;
}
IonCode *
IonRuntime::generateArgumentsRectifier(JSContext *cx, ExecutionMode mode, void **returnAddrOut)
{
MacroAssembler masm(cx);
// ArgumentsRectifierReg contains the |nargs| pushed onto the current
// frame. Including |this|, there are (|nargs| + 1) arguments to copy.
MOZ_ASSERT(ArgumentsRectifierReg == s3);
Register numActArgsReg = t6;
Register calleeTokenReg = t7;
Register numArgsReg = t5;
// Copy number of actual arguments into numActArgsReg
masm.loadPtr(Address(StackPointer, IonRectifierFrameLayout::offsetOfNumActualArgs()),
numActArgsReg);
// Load the number of |undefined|s to push into t1.
masm.loadPtr(Address(StackPointer, IonRectifierFrameLayout::offsetOfCalleeToken()),
calleeTokenReg);
masm.load16ZeroExtend(
Address(
calleeTokenReg,
offsetof(JSFunction, nargs)
), numArgsReg
);
masm.ma_subu(t1, numArgsReg, s3);
masm.moveValue(UndefinedValue(), ValueOperand(t3, t4));
masm.movePtr(StackPointer, t2); // Save %sp.
// Push undefined.
{
Label undefLoopTop;
masm.bind(&undefLoopTop);
masm.subPtr(Imm32(sizeof(Value)), StackPointer);
masm.storeValue(ValueOperand(t3, t4), Address(StackPointer, 0));
masm.sub32(Imm32(1), t1);
masm.ma_b(t1, t1, &undefLoopTop, Assembler::NonZero, ShortJump);
}
// Get the topmost argument.
masm.ma_sll(t0, s3, Imm32(3)); // t0 <- nargs * 8
masm.addPtr(t0, t2); // t2 <- t2(saved sp) + nargs * 8
masm.addPtr(Imm32(sizeof(IonRectifierFrameLayout)), t2);
// Push arguments, |nargs| + 1 times (to include |this|).
{
Label copyLoopTop, initialSkip;
masm.ma_b(&initialSkip, ShortJump);
masm.bind(&copyLoopTop);
masm.subPtr(Imm32(sizeof(Value)), t2);
masm.sub32(Imm32(1), s3);
masm.bind(&initialSkip);
MOZ_ASSERT(sizeof(Value) == 2 * sizeof(uint32_t));
// Read argument and push to stack.
masm.subPtr(Imm32(sizeof(Value)), StackPointer);
masm.load32(Address(t2, NUNBOX32_TYPE_OFFSET), t0);
masm.store32(t0, Address(StackPointer, NUNBOX32_TYPE_OFFSET));
masm.load32(Address(t2, NUNBOX32_PAYLOAD_OFFSET), t0);
masm.store32(t0, Address(StackPointer, NUNBOX32_PAYLOAD_OFFSET));
masm.ma_b(s3, s3, &copyLoopTop, Assembler::NonZero, ShortJump);
}
// translate the framesize from values into bytes
masm.ma_addu(t0, numArgsReg, Imm32(1));
masm.lshiftPtr(Imm32(3), t0);
// Construct sizeDescriptor.
masm.makeFrameDescriptor(t0, IonFrame_Rectifier);
// Construct IonJSFrameLayout.
masm.subPtr(Imm32(3 * sizeof(uintptr_t)), StackPointer);
// Push actual arguments.
masm.storePtr(numActArgsReg, Address(StackPointer, 2 * sizeof(uintptr_t)));
// Push callee token.
masm.storePtr(calleeTokenReg, Address(StackPointer, sizeof(uintptr_t)));
// Push frame descriptor.
masm.storePtr(t0, Address(StackPointer, 0));
// Call the target function.
// Note that this code assumes the function is JITted.
masm.loadPtr(Address(calleeTokenReg, JSFunction::offsetOfNativeOrScript()), t1);
masm.loadBaselineOrIonRaw(t1, t1, mode, nullptr);
masm.ma_callIonHalfPush(t1);
uint32_t returnOffset = masm.currentOffset();
// arg1
// ...
// argN
// num actual args
// callee token
// sizeDescriptor <- sp now
// return address
// Remove the rectifier frame.
// t0 <- descriptor with FrameType.
masm.loadPtr(Address(StackPointer, 0), t0);
masm.rshiftPtr(Imm32(FRAMESIZE_SHIFT), t0); // t0 <- descriptor.
// Discard descriptor, calleeToken and number of actual arguments.
masm.addPtr(Imm32(3 * sizeof(uintptr_t)), StackPointer);
// arg1
// ...
// argN <- sp now; t0 <- frame descriptor
// num actual args
// callee token
// sizeDescriptor
// return address
// Discard pushed arguments.
masm.addPtr(t0, StackPointer);
masm.ret();
Linker linker(masm);
AutoFlushCache afc("ArgumentsRectifier");
IonCode *code = linker.newCode(cx, JSC::OTHER_CODE);
CodeOffsetLabel returnLabel(returnOffset);
returnLabel.fixup(&masm);
if (returnAddrOut)
*returnAddrOut = (void *) (code->raw() + returnLabel.offset());
#ifdef JS_ION_PERF
writePerfSpewerIonCodeProfile(code, "ArgumentsRectifier");
#endif
return code;
}
/* There are two different stack layouts when doing bailout. They are
* represented via class BailoutStack.
*
* - First case is when bailout is done trough bailout table. In this case
* table offset is stored in $ra (look at IonRuntime::generateBailoutTable())
* and thunk code should save it on stack. In this case frameClassId_ cannot
* be NO_FRAME_SIZE_CLASS_ID. Members snapshotOffset_ and padding_ are not on
* the stack.
*
* - Other case is when bailout is done via out of line code (lazy bailout).
* In this case frame size is stored in $ra (look at
* CodeGeneratorMIPS::generateOutOfLineCode()) and thunk code should save it
* on stack. Other difference is that members snapshotOffset_ and padding_ are
* pushed to the stack by CodeGeneratorMIPS::visitOutOfLineBailout(). Field
* frameClassId_ is forced to be NO_FRAME_SIZE_CLASS_ID
* (See: IonRuntime::generateBailoutHandler).
*/
static void
GenerateBailoutThunk(JSContext *cx, MacroAssembler &masm, uint32_t frameClass)
{
// NOTE: Members snapshotOffset_ and padding_ of BailoutStack
// are not stored in this function.
static const uint32_t bailoutDataSize = sizeof(BailoutStack) - 2 * sizeof(uintptr_t);
static const uint32_t bailoutInfoOutParamSize = 2 * sizeof(uintptr_t);
// Make sure that alignment is proper.
masm.checkStackAlignment();
// Make room for data.
masm.subPtr(Imm32(bailoutDataSize), StackPointer);
// Save general purpose registers.
for (uint32_t i = 0; i < Registers::Total; i++) {
uint32_t off = BailoutStack::offsetOfRegs() + i * sizeof(uintptr_t);
masm.storePtr(Register::FromCode(i), Address(StackPointer, off));
}
// Save floating point registers
// We can use as_sd because stack is alligned.
for (uintptr_t i = 0; i < FloatRegisters::Total; i++) {
if (i % 2 == 0) {
masm.as_sd(FloatRegister::FromCode(i), StackPointer,
BailoutStack::offsetOfFpRegs() + (i/2) * sizeof(double));
}
}
// Store the frameSize_ or tableOffset_ stored in ra
// See: IonRuntime::generateBailoutTable()
// See: CodeGeneratorMIPS::generateOutOfLineCode()
masm.storePtr(ra, Address(StackPointer, BailoutStack::offsetOfFrameSize()));
// Put frame class to stack
masm.storePtr(ImmWord(frameClass), Address(StackPointer, BailoutStack::offsetOfFrameClass()));
// Put pointer to BailoutStack as first argument to the Bailout()
masm.movePtr(StackPointer, a0);
// Put pointer to BailoutInfo
masm.subPtr(Imm32(bailoutInfoOutParamSize), StackPointer);
masm.storePtr(ImmWord((void*)NULL), Address(StackPointer, 0));
masm.movePtr(StackPointer, a1);
masm.setupAlignedABICall(2);
masm.passABIArg(a0);
masm.passABIArg(a1);
masm.callWithABI(JS_FUNC_TO_DATA_PTR(void *, Bailout));
// Get BailoutInfo pointer
masm.loadPtr(Address(StackPointer, 0), a2);
// Remove both the bailout frame and the topmost Ion frame's stack.
if (frameClass == NO_FRAME_SIZE_CLASS_ID) {
// Load frameSize from stack
masm.loadPtr(Address(StackPointer,
bailoutInfoOutParamSize + BailoutStack::offsetOfFrameSize()), a1);
// Remove complete BailoutStack class and data after it
masm.addPtr(Imm32(sizeof(BailoutStack) + bailoutInfoOutParamSize), StackPointer);
// Remove frame size srom stack
masm.addPtr(a1, StackPointer);
} else {
uint32_t frameSize = FrameSizeClass::FromClass(frameClass).frameSize();
// Remove the data this fuction added and frame size.
masm.addPtr(Imm32(bailoutDataSize + bailoutInfoOutParamSize + frameSize), StackPointer);
}
// Jump to shared bailout tail. The BailoutInfo pointer has to be in a2.
IonCode* bailoutTail = cx->runtime()->ionRuntime()->getBailoutTail();
masm.branch(bailoutTail);
}
IonCode *
IonRuntime::generateBailoutTable(JSContext *cx, uint32_t frameClass)
{
MacroAssembler masm(cx);
Label bailout;
for (size_t i = 0; i < BAILOUT_TABLE_SIZE; i++) {
// Calculate offset to the end of table
int32_t offset = (BAILOUT_TABLE_SIZE - i) * BAILOUT_TABLE_ENTRY_SIZE;
// We use the 'ra' as table offset later in GenerateBailoutThunk
masm.as_bal(BOffImm16(offset));
masm.nop();
}
masm.bind(&bailout);
GenerateBailoutThunk(cx, masm, frameClass);
Linker linker(masm);
AutoFlushCache afc("BailoutTable");
IonCode *code = linker.newCode(cx, JSC::OTHER_CODE);
#ifdef JS_ION_PERF
writePerfSpewerIonCodeProfile(code, "BailoutTable");
#endif
return code;
}
IonCode *
IonRuntime::generateBailoutHandler(JSContext *cx)
{
MacroAssembler masm(cx);
GenerateBailoutThunk(cx, masm, NO_FRAME_SIZE_CLASS_ID);
Linker linker(masm);
AutoFlushCache afc("BailoutHandler");
IonCode *code = linker.newCode(cx, JSC::OTHER_CODE);
#ifdef JS_ION_PERF
writePerfSpewerIonCodeProfile(code, "BailoutHandler");
#endif
return code;
}
IonCode *
IonRuntime::generateVMWrapper(JSContext *cx, const VMFunction &f)
{
typedef MoveResolver::MoveOperand MoveOperand;
MOZ_ASSERT(functionWrappers_);
MOZ_ASSERT(functionWrappers_->initialized());
VMWrapperMap::AddPtr p = functionWrappers_->lookupForAdd(&f);
if (p) {
return p->value;
}
MacroAssembler masm(cx);
GeneralRegisterSet regs = GeneralRegisterSet(Register::Codes::WrapperMask);
static_assert((Register::Codes::VolatileMask & ~Register::Codes::WrapperMask) == 0,
"Wrapper register set should be a superset of Volatile register set.");
// The context is the first argument; a0 is the first argument register.
Register cxreg = a0;
regs.take(cxreg);
// We're aligned to an exit frame, so link it up.
masm.enterExitFrameAndLoadContext(&f, cxreg, regs.getAny(), f.executionMode);
// Save the base of the argument set stored on the stack.
Register argsBase = InvalidReg;
if (f.explicitArgs) {
argsBase = t1; // Use temporary register.
regs.take(argsBase);
masm.ma_addu(argsBase, StackPointer, Imm32(IonExitFrameLayout::SizeWithFooter()));
}
// Reserve space for the outparameter.
Register outReg = InvalidReg;
switch (f.outParam) {
case Type_Value:
outReg = t0; // Use temporary register.
regs.take(outReg);
// Value outparam has to be 8 byte aligned because the called
// function can use sdc1 or ldc1 instructions to access it.
masm.reserveStack((StackAlignment - sizeof(uintptr_t)) + sizeof(Value));
masm.alignPointerUp(StackPointer, outReg, StackAlignment);
break;
case Type_Handle:
outReg = t0;
regs.take(outReg);
if (f.outParamRootType == VMFunction::RootValue) {
// Value outparam has to be 8 byte aligned because the called
// function can use sdc1 or ldc1 instructions to access it.
masm.reserveStack((StackAlignment - sizeof(uintptr_t)) + sizeof(Value));
masm.alignPointerUp(StackPointer, outReg, StackAlignment);
masm.storeValue(UndefinedValue(), Address(outReg, 0));
}
else {
masm.PushEmptyRooted(f.outParamRootType);
masm.movePtr(StackPointer, outReg);
}
break;
case Type_Bool:
case Type_Int32:
MOZ_ASSERT(sizeof(uintptr_t) == sizeof(uint32_t));
case Type_Pointer:
outReg = t0;
regs.take(outReg);
masm.reserveStack(sizeof(uintptr_t));
masm.movePtr(StackPointer, outReg);
break;
default:
MOZ_ASSERT(f.outParam == Type_Void);
break;
}
masm.setupUnalignedABICall(f.argc(), regs.getAny());
masm.passABIArg(cxreg);
size_t argDisp = 0;
// Copy any arguments.
for (uint32_t explicitArg = 0; explicitArg < f.explicitArgs; explicitArg++) {
MoveOperand from;
switch (f.argProperties(explicitArg)) {
case VMFunction::WordByValue:
masm.passABIArg(MoveOperand(argsBase, argDisp));
argDisp += sizeof(uint32_t);
break;
case VMFunction::DoubleByValue:
// Values should be passed by reference, not by value, so we
// assert that the argument is a double-precision float.
MOZ_ASSERT(f.argPassedInFloatReg(explicitArg));
masm.passABIArg(MoveOperand(argsBase, argDisp, MoveOperand::FLOAT));
argDisp += sizeof(double);
break;
case VMFunction::WordByRef:
masm.passABIArg(MoveOperand(argsBase, argDisp, MoveOperand::EFFECTIVE));
argDisp += sizeof(uint32_t);
break;
case VMFunction::DoubleByRef:
masm.passABIArg(MoveOperand(argsBase, argDisp, MoveOperand::EFFECTIVE));
argDisp += sizeof(double);
break;
}
}
// Copy the implicit outparam, if any.
if (outReg != InvalidReg)
masm.passABIArg(outReg);
masm.callWithABI(f.wrapped);
// Test for failure.
Label failureLabel;
switch (f.failType()) {
case Type_Object:
masm.branchTestPtr(Assembler::Zero, v0, v0, &failureLabel);
break;
case Type_Bool:
// Called functions return bools, which are 0/false and non-zero/true
masm.branchIfFalseBool(v0, &failureLabel);
break;
case Type_ParallelResult:
// TODO: Remove these comments and warning after proxy object issue is
// fixed.
// Type_ParallelResult was removed in SpiderMonkey31, so we should be
// careful when this is run.
// In ARM, it is:
// masm.branch32(Assembler::NotEqual, r0, Imm32(TP_SUCCESS), &failure); - arm
// In x86, it is:
// masm.branchPtr(Assembler::NotEqual, eax, Imm32(TP_SUCCESS), &failure); - x86
SB_LOG(WARNING) << "masm.branchPtr(Assembler::NotEqual, v0, Imm32(TP_SUCCESS), &failureLabel)";
masm.branchPtr(Assembler::NotEqual, v0, Imm32(TP_SUCCESS), &failureLabel);
break;
default:
JS_NOT_REACHED("unknown failure kind");
}
// Load the outparam and free any allocated stack.
switch (f.outParam) {
case Type_Handle:
if (f.outParamRootType == VMFunction::RootValue) {
masm.alignPointerUp(StackPointer, SecondScratchReg, StackAlignment);
masm.loadValue(Address(SecondScratchReg, 0), JSReturnOperand);
masm.freeStack((StackAlignment - sizeof(uintptr_t)) + sizeof(Value));
}
else {
masm.popRooted(f.outParamRootType, ReturnReg, JSReturnOperand);
}
break;
case Type_Value:
masm.alignPointerUp(StackPointer, SecondScratchReg, StackAlignment);
masm.loadValue(Address(SecondScratchReg, 0), JSReturnOperand);
masm.freeStack((StackAlignment - sizeof(uintptr_t)) + sizeof(Value));
break;
case Type_Int32:
MOZ_ASSERT(sizeof(uintptr_t) == sizeof(uint32_t));
case Type_Pointer:
masm.load32(Address(StackPointer, 0), ReturnReg);
masm.freeStack(sizeof(uintptr_t));
break;
case Type_Bool:
masm.load8ZeroExtend(Address(StackPointer, 0), ReturnReg);
masm.freeStack(sizeof(uintptr_t));
break;
default:
MOZ_ASSERT(f.outParam == Type_Void);
break;
}
masm.leaveExitFrame();
masm.retn(Imm32(sizeof(IonExitFrameLayout) +
f.explicitStackSlots() * sizeof(uintptr_t) +
f.extraValuesToPop * sizeof(Value)));
masm.bind(&failureLabel);
masm.handleFailure(f.executionMode);
Linker linker(masm);
AutoFlushCache afc("VMWrapper");
IonCode *wrapper = linker.newCode(cx, JSC::OTHER_CODE);
if (!wrapper)
return NULL;
// linker.newCode may trigger a GC and sweep functionWrappers_ so we have
// to use relookupOrAdd instead of add.
if (!functionWrappers_->relookupOrAdd(p, &f, wrapper))
return NULL;
#ifdef JS_ION_PERF
writePerfSpewerIonCodeProfile(wrapper, "VMWrapper");
#endif
return wrapper;
}
IonCode *
IonRuntime::generatePreBarrier(JSContext *cx, MIRType type)
{
MacroAssembler masm(cx);
RegisterSet save;
if (cx->runtime()->jitSupportsFloatingPoint) {
save = RegisterSet(GeneralRegisterSet(Registers::VolatileMask),
FloatRegisterSet(FloatRegisters::VolatileMask));
} else {
save = RegisterSet(GeneralRegisterSet(Registers::VolatileMask),
FloatRegisterSet());
}
masm.PushRegsInMask(save);
MOZ_ASSERT(PreBarrierReg == a1);
masm.movePtr(ImmWord(cx->runtime()), a0);
masm.setupUnalignedABICall(2, a2);
masm.passABIArg(a0);
masm.passABIArg(a1);
if (type == MIRType_Value) {
masm.callWithABI(JS_FUNC_TO_DATA_PTR(void *, MarkValueFromIon));
} else {
MOZ_ASSERT(type == MIRType_Shape);
masm.callWithABI(JS_FUNC_TO_DATA_PTR(void *, MarkShapeFromIon));
}
masm.PopRegsInMask(save);
masm.ret();
Linker linker(masm);
AutoFlushCache afc("PreBarrier");
IonCode *code = linker.newCode(cx, JSC::OTHER_CODE);
#ifdef JS_ION_PERF
writePerfSpewerIonCodeProfile(code, "PreBarrier");
#endif
return code;
}
typedef bool (*HandleDebugTrapFn)(JSContext *, BaselineFrame *, uint8_t *, JSBool *);
static const VMFunction HandleDebugTrapInfo = FunctionInfo<HandleDebugTrapFn>(HandleDebugTrap);
IonCode *
IonRuntime::generateDebugTrapHandler(JSContext *cx)
{
MacroAssembler masm(cx);
Register scratch1 = t0;
Register scratch2 = t1;
// Load BaselineFrame pointer in scratch1.
masm.movePtr(s5, scratch1);
masm.subPtr(Imm32(BaselineFrame::Size()), scratch1);
// Enter a stub frame and call the HandleDebugTrap VM function. Ensure
// the stub frame has a nullptr ICStub pointer, since this pointer is
// marked during GC.
masm.movePtr(ImmWord((void*)NULL), BaselineStubReg);
EmitEnterStubFrame(masm, scratch2);
IonCompartment* ion = cx->compartment()->ionCompartment();
IonCode* code = ion->getVMWrapper(HandleDebugTrapInfo);
if (!code)
return NULL;
masm.subPtr(Imm32(2 * sizeof(uintptr_t)), StackPointer);
masm.storePtr(ra, Address(StackPointer, sizeof(uintptr_t)));
masm.storePtr(scratch1, Address(StackPointer, 0));
EmitCallVM(code, masm);
EmitLeaveStubFrame(masm);
// If the stub returns |true|, we have to perform a forced return
// (return from the JS frame). If the stub returns |false|, just return
// from the trap stub so that execution continues at the current pc.
Label forcedReturn;
masm.branchTest32(Assembler::NonZero, ReturnReg, ReturnReg, &forcedReturn);
// ra was restored by EmitLeaveStubFrame
masm.branch(ra);
masm.bind(&forcedReturn);
masm.loadValue(Address(s5, BaselineFrame::reverseOffsetOfReturnValue()),
JSReturnOperand);
masm.movePtr(s5, StackPointer);
masm.pop(s5);
masm.ret();
Linker linker(masm);
AutoFlushCache afc("DebugTrapHandler");
IonCode *codeDbg = linker.newCode(cx, JSC::OTHER_CODE);
#ifdef JS_ION_PERF
writePerfSpewerIonCodeProfile(codeDbg, "DebugTrapHandler");
#endif
return codeDbg;
}
IonCode *
IonRuntime::generateExceptionTailStub(JSContext *cx)
{
MacroAssembler masm;
masm.handleFailureWithHandlerTail();
Linker linker(masm);
AutoFlushCache afc("ExceptionTailStub");
IonCode *code = linker.newCode(cx, JSC::OTHER_CODE);
#ifdef JS_ION_PERF
writePerfSpewerIonCodeProfile(code, "ExceptionTailStub");
#endif
return code;
}
IonCode *
IonRuntime::generateBailoutTailStub(JSContext *cx)
{
MacroAssembler masm;
masm.generateBailoutTail(a1, a2);
Linker linker(masm);
AutoFlushCache afc("BailoutTailStub");
IonCode *code = linker.newCode(cx, JSC::OTHER_CODE);
#ifdef JS_ION_PERF
writePerfSpewerIonCodeProfile(code, "BailoutTailStub");
#endif
return code;
}