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|
/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
* 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 "jit/arm64/Assembler-arm64.h"
#include "mozilla/DebugOnly.h"
#include "mozilla/MathAlgorithms.h"
#include "jscompartment.h"
#include "jsutil.h"
#include "gc/Marking.h"
#include "jit/arm64/Architecture-arm64.h"
#include "jit/arm64/MacroAssembler-arm64.h"
#include "jit/ExecutableAllocator.h"
#include "jit/JitCompartment.h"
#include "gc/StoreBuffer-inl.h"
using namespace js;
using namespace js::jit;
using mozilla::CountLeadingZeroes32;
using mozilla::DebugOnly;
// Note this is used for inter-wasm calls and may pass arguments and results
// in floating point registers even if the system ABI does not.
ABIArg
ABIArgGenerator::next(MIRType type)
{
switch (type) {
case MIRType::Int32:
case MIRType::Pointer:
if (intRegIndex_ == NumIntArgRegs) {
current_ = ABIArg(stackOffset_);
stackOffset_ += sizeof(uintptr_t);
break;
}
current_ = ABIArg(Register::FromCode(intRegIndex_));
intRegIndex_++;
break;
case MIRType::Float32:
case MIRType::Double:
if (floatRegIndex_ == NumFloatArgRegs) {
current_ = ABIArg(stackOffset_);
stackOffset_ += sizeof(double);
break;
}
current_ = ABIArg(FloatRegister(floatRegIndex_,
type == MIRType::Double ? FloatRegisters::Double
: FloatRegisters::Single));
floatRegIndex_++;
break;
default:
MOZ_CRASH("Unexpected argument type");
}
return current_;
}
namespace js {
namespace jit {
void
Assembler::finish()
{
armbuffer_.flushPool();
// The extended jump table is part of the code buffer.
ExtendedJumpTable_ = emitExtendedJumpTable();
Assembler::FinalizeCode();
// The jump relocation table starts with a fixed-width integer pointing
// to the start of the extended jump table.
// Space for this integer is allocated by Assembler::addJumpRelocation()
// before writing the first entry.
// Don't touch memory if we saw an OOM error.
if (jumpRelocations_.length() && !oom()) {
MOZ_ASSERT(jumpRelocations_.length() >= sizeof(uint32_t));
*(uint32_t*)jumpRelocations_.buffer() = ExtendedJumpTable_.getOffset();
}
}
BufferOffset
Assembler::emitExtendedJumpTable()
{
if (!pendingJumps_.length() || oom())
return BufferOffset();
armbuffer_.flushPool();
armbuffer_.align(SizeOfJumpTableEntry);
BufferOffset tableOffset = armbuffer_.nextOffset();
for (size_t i = 0; i < pendingJumps_.length(); i++) {
// Each JumpTableEntry is of the form:
// LDR ip0 [PC, 8]
// BR ip0
// [Patchable 8-byte constant low bits]
// [Patchable 8-byte constant high bits]
DebugOnly<size_t> preOffset = size_t(armbuffer_.nextOffset().getOffset());
ldr(vixl::ip0, ptrdiff_t(8 / vixl::kInstructionSize));
br(vixl::ip0);
DebugOnly<size_t> prePointer = size_t(armbuffer_.nextOffset().getOffset());
MOZ_ASSERT_IF(!oom(), prePointer - preOffset == OffsetOfJumpTableEntryPointer);
brk(0x0);
brk(0x0);
DebugOnly<size_t> postOffset = size_t(armbuffer_.nextOffset().getOffset());
MOZ_ASSERT_IF(!oom(), postOffset - preOffset == SizeOfJumpTableEntry);
}
if (oom())
return BufferOffset();
return tableOffset;
}
void
Assembler::executableCopy(uint8_t* buffer)
{
// Copy the code and all constant pools into the output buffer.
armbuffer_.executableCopy(buffer);
// Patch any relative jumps that target code outside the buffer.
// The extended jump table may be used for distant jumps.
for (size_t i = 0; i < pendingJumps_.length(); i++) {
RelativePatch& rp = pendingJumps_[i];
if (!rp.target) {
// The patch target is nullptr for jumps that have been linked to
// a label within the same code block, but may be repatched later
// to jump to a different code block.
continue;
}
Instruction* target = (Instruction*)rp.target;
Instruction* branch = (Instruction*)(buffer + rp.offset.getOffset());
JumpTableEntry* extendedJumpTable =
reinterpret_cast<JumpTableEntry*>(buffer + ExtendedJumpTable_.getOffset());
if (branch->BranchType() != vixl::UnknownBranchType) {
if (branch->IsTargetReachable(target)) {
branch->SetImmPCOffsetTarget(target);
} else {
JumpTableEntry* entry = &extendedJumpTable[i];
branch->SetImmPCOffsetTarget(entry->getLdr());
entry->data = target;
}
} else {
// Currently a two-instruction call, it should be possible to optimize this
// into a single instruction call + nop in some instances, but this will work.
}
}
}
BufferOffset
Assembler::immPool(ARMRegister dest, uint8_t* value, vixl::LoadLiteralOp op, ARMBuffer::PoolEntry* pe)
{
uint32_t inst = op | Rt(dest);
const size_t numInst = 1;
const unsigned sizeOfPoolEntryInBytes = 4;
const unsigned numPoolEntries = sizeof(value) / sizeOfPoolEntryInBytes;
return allocEntry(numInst, numPoolEntries, (uint8_t*)&inst, value, pe);
}
BufferOffset
Assembler::immPool64(ARMRegister dest, uint64_t value, ARMBuffer::PoolEntry* pe)
{
return immPool(dest, (uint8_t*)&value, vixl::LDR_x_lit, pe);
}
BufferOffset
Assembler::immPool64Branch(RepatchLabel* label, ARMBuffer::PoolEntry* pe, Condition c)
{
MOZ_CRASH("immPool64Branch");
}
BufferOffset
Assembler::fImmPool(ARMFPRegister dest, uint8_t* value, vixl::LoadLiteralOp op)
{
uint32_t inst = op | Rt(dest);
const size_t numInst = 1;
const unsigned sizeOfPoolEntryInBits = 32;
const unsigned numPoolEntries = dest.size() / sizeOfPoolEntryInBits;
return allocEntry(numInst, numPoolEntries, (uint8_t*)&inst, value);
}
BufferOffset
Assembler::fImmPool64(ARMFPRegister dest, double value)
{
return fImmPool(dest, (uint8_t*)&value, vixl::LDR_d_lit);
}
BufferOffset
Assembler::fImmPool32(ARMFPRegister dest, float value)
{
return fImmPool(dest, (uint8_t*)&value, vixl::LDR_s_lit);
}
void
Assembler::bind(Label* label, BufferOffset targetOffset)
{
// Nothing has seen the label yet: just mark the location.
// If we've run out of memory, don't attempt to modify the buffer which may
// not be there. Just mark the label as bound to the (possibly bogus)
// targetOffset.
if (!label->used() || oom()) {
label->bind(targetOffset.getOffset());
return;
}
// Get the most recent instruction that used the label, as stored in the label.
// This instruction is the head of an implicit linked list of label uses.
BufferOffset branchOffset(label);
while (branchOffset.assigned()) {
// Before overwriting the offset in this instruction, get the offset of
// the next link in the implicit branch list.
BufferOffset nextOffset = NextLink(branchOffset);
// Linking against the actual (Instruction*) would be invalid,
// since that Instruction could be anywhere in memory.
// Instead, just link against the correct relative offset, assuming
// no constant pools, which will be taken into consideration
// during finalization.
ptrdiff_t relativeByteOffset = targetOffset.getOffset() - branchOffset.getOffset();
Instruction* link = getInstructionAt(branchOffset);
// This branch may still be registered for callbacks. Stop tracking it.
vixl::ImmBranchType branchType = link->BranchType();
vixl::ImmBranchRangeType branchRange = Instruction::ImmBranchTypeToRange(branchType);
if (branchRange < vixl::NumShortBranchRangeTypes) {
BufferOffset deadline(branchOffset.getOffset() +
Instruction::ImmBranchMaxForwardOffset(branchRange));
armbuffer_.unregisterBranchDeadline(branchRange, deadline);
}
// Is link able to reach the label?
if (link->IsPCRelAddressing() || link->IsTargetReachable(link + relativeByteOffset)) {
// Write a new relative offset into the instruction.
link->SetImmPCOffsetTarget(link + relativeByteOffset);
} else {
// This is a short-range branch, and it can't reach the label directly.
// Verify that it branches to a veneer: an unconditional branch.
MOZ_ASSERT(getInstructionAt(nextOffset)->BranchType() == vixl::UncondBranchType);
}
branchOffset = nextOffset;
}
// Bind the label, so that future uses may encode the offset immediately.
label->bind(targetOffset.getOffset());
}
void
Assembler::bind(RepatchLabel* label)
{
// Nothing has seen the label yet: just mark the location.
// If we've run out of memory, don't attempt to modify the buffer which may
// not be there. Just mark the label as bound to nextOffset().
if (!label->used() || oom()) {
label->bind(nextOffset().getOffset());
return;
}
int branchOffset = label->offset();
Instruction* inst = getInstructionAt(BufferOffset(branchOffset));
inst->SetImmPCOffsetTarget(inst + nextOffset().getOffset() - branchOffset);
}
void
Assembler::trace(JSTracer* trc)
{
for (size_t i = 0; i < pendingJumps_.length(); i++) {
RelativePatch& rp = pendingJumps_[i];
if (rp.kind == Relocation::JITCODE) {
JitCode* code = JitCode::FromExecutable((uint8_t*)rp.target);
TraceManuallyBarrieredEdge(trc, &code, "masmrel32");
MOZ_ASSERT(code == JitCode::FromExecutable((uint8_t*)rp.target));
}
}
// TODO: Trace.
#if 0
if (tmpDataRelocations_.length())
::TraceDataRelocations(trc, &armbuffer_, &tmpDataRelocations_);
#endif
}
void
Assembler::addJumpRelocation(BufferOffset src, Relocation::Kind reloc)
{
// Only JITCODE relocations are patchable at runtime.
MOZ_ASSERT(reloc == Relocation::JITCODE);
// The jump relocation table starts with a fixed-width integer pointing
// to the start of the extended jump table. But, we don't know the
// actual extended jump table offset yet, so write a 0 which we'll
// patch later in Assembler::finish().
if (!jumpRelocations_.length())
jumpRelocations_.writeFixedUint32_t(0);
// Each entry in the table is an (offset, extendedTableIndex) pair.
jumpRelocations_.writeUnsigned(src.getOffset());
jumpRelocations_.writeUnsigned(pendingJumps_.length());
}
void
Assembler::addPendingJump(BufferOffset src, ImmPtr target, Relocation::Kind reloc)
{
MOZ_ASSERT(target.value != nullptr);
if (reloc == Relocation::JITCODE)
addJumpRelocation(src, reloc);
// This jump is not patchable at runtime. Extended jump table entry requirements
// cannot be known until finalization, so to be safe, give each jump and entry.
// This also causes GC tracing of the target.
enoughMemory_ &= pendingJumps_.append(RelativePatch(src, target.value, reloc));
}
size_t
Assembler::addPatchableJump(BufferOffset src, Relocation::Kind reloc)
{
MOZ_CRASH("TODO: This is currently unused (and untested)");
if (reloc == Relocation::JITCODE)
addJumpRelocation(src, reloc);
size_t extendedTableIndex = pendingJumps_.length();
enoughMemory_ &= pendingJumps_.append(RelativePatch(src, nullptr, reloc));
return extendedTableIndex;
}
void
PatchJump(CodeLocationJump& jump_, CodeLocationLabel label, ReprotectCode reprotect)
{
MOZ_CRASH("PatchJump");
}
void
Assembler::PatchDataWithValueCheck(CodeLocationLabel label, PatchedImmPtr newValue,
PatchedImmPtr expected)
{
Instruction* i = (Instruction*)label.raw();
void** pValue = i->LiteralAddress<void**>();
MOZ_ASSERT(*pValue == expected.value);
*pValue = newValue.value;
}
void
Assembler::PatchDataWithValueCheck(CodeLocationLabel label, ImmPtr newValue, ImmPtr expected)
{
PatchDataWithValueCheck(label, PatchedImmPtr(newValue.value), PatchedImmPtr(expected.value));
}
void
Assembler::ToggleToJmp(CodeLocationLabel inst_)
{
Instruction* i = (Instruction*)inst_.raw();
MOZ_ASSERT(i->IsAddSubImmediate());
// Refer to instruction layout in ToggleToCmp().
int imm19 = (int)i->Bits(23, 5);
MOZ_ASSERT(vixl::is_int19(imm19));
b(i, imm19, Always);
}
void
Assembler::ToggleToCmp(CodeLocationLabel inst_)
{
Instruction* i = (Instruction*)inst_.raw();
MOZ_ASSERT(i->IsCondB());
int imm19 = i->ImmCondBranch();
// bit 23 is reserved, and the simulator throws an assertion when this happens
// It'll be messy to decode, but we can steal bit 30 or bit 31.
MOZ_ASSERT(vixl::is_int18(imm19));
// 31 - 64-bit if set, 32-bit if unset. (OK!)
// 30 - sub if set, add if unset. (OK!)
// 29 - SetFlagsBit. Must be set.
// 22:23 - ShiftAddSub. (OK!)
// 10:21 - ImmAddSub. (OK!)
// 5:9 - First source register (Rn). (OK!)
// 0:4 - Destination Register. Must be xzr.
// From the above, there is a safe 19-bit contiguous region from 5:23.
Emit(i, vixl::ThirtyTwoBits | vixl::AddSubImmediateFixed | vixl::SUB | Flags(vixl::SetFlags) |
Rd(vixl::xzr) | (imm19 << vixl::Rn_offset));
}
void
Assembler::ToggleCall(CodeLocationLabel inst_, bool enabled)
{
const Instruction* first = reinterpret_cast<Instruction*>(inst_.raw());
Instruction* load;
Instruction* call;
// There might be a constant pool at the very first instruction.
first = first->skipPool();
// Skip the stack pointer restore instruction.
if (first->IsStackPtrSync())
first = first->InstructionAtOffset(vixl::kInstructionSize)->skipPool();
load = const_cast<Instruction*>(first);
// The call instruction follows the load, but there may be an injected
// constant pool.
call = const_cast<Instruction*>(load->InstructionAtOffset(vixl::kInstructionSize)->skipPool());
if (call->IsBLR() == enabled)
return;
if (call->IsBLR()) {
// If the second instruction is blr(), then wehave:
// ldr x17, [pc, offset]
// blr x17
MOZ_ASSERT(load->IsLDR());
// We want to transform this to:
// adr xzr, [pc, offset]
// nop
int32_t offset = load->ImmLLiteral();
adr(load, xzr, int32_t(offset));
nop(call);
} else {
// We have:
// adr xzr, [pc, offset] (or ldr x17, [pc, offset])
// nop
MOZ_ASSERT(load->IsADR() || load->IsLDR());
MOZ_ASSERT(call->IsNOP());
// Transform this to:
// ldr x17, [pc, offset]
// blr x17
int32_t offset = (int)load->ImmPCRawOffset();
MOZ_ASSERT(vixl::is_int19(offset));
ldr(load, ScratchReg2_64, int32_t(offset));
blr(call, ScratchReg2_64);
}
}
class RelocationIterator
{
CompactBufferReader reader_;
uint32_t tableStart_;
uint32_t offset_;
uint32_t extOffset_;
public:
explicit RelocationIterator(CompactBufferReader& reader)
: reader_(reader)
{
// The first uint32_t stores the extended table offset.
tableStart_ = reader_.readFixedUint32_t();
}
bool read() {
if (!reader_.more())
return false;
offset_ = reader_.readUnsigned();
extOffset_ = reader_.readUnsigned();
return true;
}
uint32_t offset() const {
return offset_;
}
uint32_t extendedOffset() const {
return extOffset_;
}
};
static JitCode*
CodeFromJump(JitCode* code, uint8_t* jump)
{
const Instruction* inst = (const Instruction*)jump;
uint8_t* target;
// We're expecting a call created by MacroAssembler::call(JitCode*).
// It looks like:
//
// ldr scratch, [pc, offset]
// blr scratch
//
// If the call has been toggled by ToggleCall(), it looks like:
//
// adr xzr, [pc, offset]
// nop
//
// There might be a constant pool at the very first instruction.
// See also ToggleCall().
inst = inst->skipPool();
// Skip the stack pointer restore instruction.
if (inst->IsStackPtrSync())
inst = inst->InstructionAtOffset(vixl::kInstructionSize)->skipPool();
if (inst->BranchType() != vixl::UnknownBranchType) {
// This is an immediate branch.
target = (uint8_t*)inst->ImmPCOffsetTarget();
} else if (inst->IsLDR()) {
// This is an ldr+blr call that is enabled. See ToggleCall().
mozilla::DebugOnly<const Instruction*> nextInst =
inst->InstructionAtOffset(vixl::kInstructionSize)->skipPool();
MOZ_ASSERT(nextInst->IsNOP() || nextInst->IsBLR());
target = (uint8_t*)inst->Literal64();
} else if (inst->IsADR()) {
// This is a disabled call: adr+nop. See ToggleCall().
mozilla::DebugOnly<const Instruction*> nextInst =
inst->InstructionAtOffset(vixl::kInstructionSize)->skipPool();
MOZ_ASSERT(nextInst->IsNOP());
ptrdiff_t offset = inst->ImmPCRawOffset() << vixl::kLiteralEntrySizeLog2;
// This is what Literal64 would do with the corresponding ldr.
memcpy(&target, inst + offset, sizeof(target));
} else {
MOZ_CRASH("Unrecognized jump instruction.");
}
// If the jump is within the code buffer, it uses the extended jump table.
if (target >= code->raw() && target < code->raw() + code->instructionsSize()) {
MOZ_ASSERT(target + Assembler::SizeOfJumpTableEntry <= code->raw() + code->instructionsSize());
uint8_t** patchablePtr = (uint8_t**)(target + Assembler::OffsetOfJumpTableEntryPointer);
target = *patchablePtr;
}
return JitCode::FromExecutable(target);
}
void
Assembler::TraceJumpRelocations(JSTracer* trc, JitCode* code, CompactBufferReader& reader)
{
RelocationIterator iter(reader);
while (iter.read()) {
JitCode* child = CodeFromJump(code, code->raw() + iter.offset());
TraceManuallyBarrieredEdge(trc, &child, "rel32");
MOZ_ASSERT(child == CodeFromJump(code, code->raw() + iter.offset()));
}
}
static void
TraceDataRelocations(JSTracer* trc, uint8_t* buffer, CompactBufferReader& reader)
{
while (reader.more()) {
size_t offset = reader.readUnsigned();
Instruction* load = (Instruction*)&buffer[offset];
// The only valid traceable operation is a 64-bit load to an ARMRegister.
// Refer to movePatchablePtr() for generation.
MOZ_ASSERT(load->Mask(vixl::LoadLiteralMask) == vixl::LDR_x_lit);
uintptr_t* literalAddr = load->LiteralAddress<uintptr_t*>();
uintptr_t literal = *literalAddr;
// All pointers on AArch64 will have the top bits cleared.
// If those bits are not cleared, this must be a Value.
if (literal >> JSVAL_TAG_SHIFT) {
Value v = Value::fromRawBits(literal);
TraceManuallyBarrieredEdge(trc, &v, "ion-masm-value");
if (*literalAddr != v.asRawBits()) {
// Only update the code if the value changed, because the code
// is not writable if we're not moving objects.
*literalAddr = v.asRawBits();
}
// TODO: When we can, flush caches here if a pointer was moved.
continue;
}
// No barriers needed since the pointers are constants.
TraceManuallyBarrieredGenericPointerEdge(trc, reinterpret_cast<gc::Cell**>(literalAddr),
"ion-masm-ptr");
// TODO: Flush caches at end?
}
}
void
Assembler::TraceDataRelocations(JSTracer* trc, JitCode* code, CompactBufferReader& reader)
{
::TraceDataRelocations(trc, code->raw(), reader);
}
void
Assembler::FixupNurseryObjects(JSContext* cx, JitCode* code, CompactBufferReader& reader,
const ObjectVector& nurseryObjects)
{
MOZ_ASSERT(!nurseryObjects.empty());
uint8_t* buffer = code->raw();
bool hasNurseryPointers = false;
while (reader.more()) {
size_t offset = reader.readUnsigned();
Instruction* ins = (Instruction*)&buffer[offset];
uintptr_t* literalAddr = ins->LiteralAddress<uintptr_t*>();
uintptr_t literal = *literalAddr;
if (literal >> JSVAL_TAG_SHIFT)
continue; // This is a Value.
if (!(literal & 0x1))
continue;
uint32_t index = literal >> 1;
JSObject* obj = nurseryObjects[index];
*literalAddr = uintptr_t(obj);
// Either all objects are still in the nursery, or all objects are tenured.
MOZ_ASSERT_IF(hasNurseryPointers, IsInsideNursery(obj));
if (!hasNurseryPointers && IsInsideNursery(obj))
hasNurseryPointers = true;
}
if (hasNurseryPointers)
cx->runtime()->gc.storeBuffer.putWholeCell(code);
}
void
Assembler::PatchInstructionImmediate(uint8_t* code, PatchedImmPtr imm)
{
MOZ_CRASH("PatchInstructionImmediate()");
}
void
Assembler::retarget(Label* label, Label* target)
{
if (label->used()) {
if (target->bound()) {
bind(label, BufferOffset(target));
} else if (target->used()) {
// The target is not bound but used. Prepend label's branch list
// onto target's.
BufferOffset labelBranchOffset(label);
// Find the head of the use chain for label.
BufferOffset next = NextLink(labelBranchOffset);
while (next.assigned()) {
labelBranchOffset = next;
next = NextLink(next);
}
// Then patch the head of label's use chain to the tail of target's
// use chain, prepending the entire use chain of target.
SetNextLink(labelBranchOffset, BufferOffset(target));
target->use(label->offset());
} else {
// The target is unbound and unused. We can just take the head of
// the list hanging off of label, and dump that into target.
DebugOnly<uint32_t> prev = target->use(label->offset());
MOZ_ASSERT((int32_t)prev == Label::INVALID_OFFSET);
}
}
label->reset();
}
} // namespace jit
} // namespace js
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