src/arm64/deoptimizer-arm64.cc - fp2-dev/platform/external/v8 - Gitiles

 // Copyright 2013 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "src/arm64/frames-arm64.h"
 #include "src/codegen.h"
 #include "src/deoptimizer.h"
 #include "src/full-codegen/full-codegen.h"
 #include "src/register-configuration.h"
 #include "src/safepoint-table.h"


 namespace v8 {
 namespace internal {


 int Deoptimizer::patch_size() {
   // Size of the code used to patch lazy bailout points.
   // Patching is done by Deoptimizer::DeoptimizeFunction.
   return 4 * kInstructionSize;
 }


 void Deoptimizer::EnsureRelocSpaceForLazyDeoptimization(Handle<Code> code) {
   // Empty because there is no need for relocation information for the code
   // patching in Deoptimizer::PatchCodeForDeoptimization below.
 }


 void Deoptimizer::PatchCodeForDeoptimization(Isolate* isolate, Code* code) {
   // Invalidate the relocation information, as it will become invalid by the
   // code patching below, and is not needed any more.
   code->InvalidateRelocation();

   // TODO(jkummerow): if (FLAG_zap_code_space), make the code object's
   // entry sequence unusable (see other architectures).

   DeoptimizationInputData* deopt_data =
       DeoptimizationInputData::cast(code->deoptimization_data());
   Address code_start_address = code->instruction_start();
 #ifdef DEBUG
   Address prev_call_address = NULL;
 #endif
   // For each LLazyBailout instruction insert a call to the corresponding
   // deoptimization entry.
   for (int i = 0; i < deopt_data->DeoptCount(); i++) {
     if (deopt_data->Pc(i)->value() == -1) continue;

     Address call_address = code_start_address + deopt_data->Pc(i)->value();
     Address deopt_entry = GetDeoptimizationEntry(isolate, i, LAZY);

     PatchingAssembler patcher(isolate, call_address,
                               patch_size() / kInstructionSize);
     patcher.ldr_pcrel(ip0, (2 * kInstructionSize) >> kLoadLiteralScaleLog2);
     patcher.blr(ip0);
     patcher.dc64(reinterpret_cast<intptr_t>(deopt_entry));

     DCHECK((prev_call_address == NULL) ||
            (call_address >= prev_call_address + patch_size()));
     DCHECK(call_address + patch_size() <= code->instruction_end());
 #ifdef DEBUG
     prev_call_address = call_address;
 #endif
   }
 }


 void Deoptimizer::SetPlatformCompiledStubRegisters(
     FrameDescription* output_frame, CodeStubDescriptor* descriptor) {
   ApiFunction function(descriptor->deoptimization_handler());
   ExternalReference xref(&function, ExternalReference::BUILTIN_CALL, isolate_);
   intptr_t handler = reinterpret_cast<intptr_t>(xref.address());
   int params = descriptor->GetHandlerParameterCount();
   output_frame->SetRegister(x0.code(), params);
   output_frame->SetRegister(x1.code(), handler);
 }


 void Deoptimizer::CopyDoubleRegisters(FrameDescription* output_frame) {
   for (int i = 0; i < DoubleRegister::kMaxNumRegisters; ++i) {
     double double_value = input_->GetDoubleRegister(i);
     output_frame->SetDoubleRegister(i, double_value);
   }
 }


 #define __ masm()->

 void Deoptimizer::TableEntryGenerator::Generate() {
   GeneratePrologue();

   // TODO(all): This code needs to be revisited. We probably only need to save
   // caller-saved registers here. Callee-saved registers can be stored directly
   // in the input frame.

   // Save all allocatable floating point registers.
   CPURegList saved_fp_registers(
       CPURegister::kFPRegister, kDRegSizeInBits,
       RegisterConfiguration::Crankshaft()->allocatable_double_codes_mask());
   __ PushCPURegList(saved_fp_registers);

   // We save all the registers expcept jssp, sp and lr.
   CPURegList saved_registers(CPURegister::kRegister, kXRegSizeInBits, 0, 27);
   saved_registers.Combine(fp);
   __ PushCPURegList(saved_registers);

   __ Mov(x3, Operand(ExternalReference(Isolate::kCEntryFPAddress, isolate())));
   __ Str(fp, MemOperand(x3));

   const int kSavedRegistersAreaSize =
       (saved_registers.Count() * kXRegSize) +
       (saved_fp_registers.Count() * kDRegSize);

   // Floating point registers are saved on the stack above core registers.
   const int kFPRegistersOffset = saved_registers.Count() * kXRegSize;

   // Get the bailout id from the stack.
   Register bailout_id = x2;
   __ Peek(bailout_id, kSavedRegistersAreaSize);

   Register code_object = x3;
   Register fp_to_sp = x4;
   // Get the address of the location in the code object. This is the return
   // address for lazy deoptimization.
   __ Mov(code_object, lr);
   // Compute the fp-to-sp delta, and correct one word for bailout id.
   __ Add(fp_to_sp, __ StackPointer(),
          kSavedRegistersAreaSize + (1 * kPointerSize));
   __ Sub(fp_to_sp, fp, fp_to_sp);

   // Allocate a new deoptimizer object.
   __ Mov(x0, 0);
   Label context_check;
   __ Ldr(x1, MemOperand(fp, CommonFrameConstants::kContextOrFrameTypeOffset));
   __ JumpIfSmi(x1, &context_check);
   __ Ldr(x0, MemOperand(fp, JavaScriptFrameConstants::kFunctionOffset));
   __ bind(&context_check);
   __ Mov(x1, type());
   // Following arguments are already loaded:
   //  - x2: bailout id
   //  - x3: code object address
   //  - x4: fp-to-sp delta
   __ Mov(x5, ExternalReference::isolate_address(isolate()));

   {
     // Call Deoptimizer::New().
     AllowExternalCallThatCantCauseGC scope(masm());
     __ CallCFunction(ExternalReference::new_deoptimizer_function(isolate()), 6);
   }

   // Preserve "deoptimizer" object in register x0.
   Register deoptimizer = x0;

   // Get the input frame descriptor pointer.
   __ Ldr(x1, MemOperand(deoptimizer, Deoptimizer::input_offset()));

   // Copy core registers into the input frame.
   CPURegList copy_to_input = saved_registers;
   for (int i = 0; i < saved_registers.Count(); i++) {
     __ Peek(x2, i * kPointerSize);
     CPURegister current_reg = copy_to_input.PopLowestIndex();
     int offset = (current_reg.code() * kPointerSize) +
         FrameDescription::registers_offset();
     __ Str(x2, MemOperand(x1, offset));
   }

   // Copy FP registers to the input frame.
   CPURegList copy_fp_to_input = saved_fp_registers;
   for (int i = 0; i < saved_fp_registers.Count(); i++) {
     int src_offset = kFPRegistersOffset + (i * kDoubleSize);
     __ Peek(x2, src_offset);
     CPURegister reg = copy_fp_to_input.PopLowestIndex();
     int dst_offset = FrameDescription::double_registers_offset() +
                      (reg.code() * kDoubleSize);
     __ Str(x2, MemOperand(x1, dst_offset));
   }

   // Remove the bailout id and the saved registers from the stack.
   __ Drop(1 + (kSavedRegistersAreaSize / kXRegSize));

   // Compute a pointer to the unwinding limit in register x2; that is
   // the first stack slot not part of the input frame.
   Register unwind_limit = x2;
   __ Ldr(unwind_limit, MemOperand(x1, FrameDescription::frame_size_offset()));
   __ Add(unwind_limit, unwind_limit, __ StackPointer());

   // Unwind the stack down to - but not including - the unwinding
   // limit and copy the contents of the activation frame to the input
   // frame description.
   __ Add(x3, x1, FrameDescription::frame_content_offset());
   Label pop_loop;
   Label pop_loop_header;
   __ B(&pop_loop_header);
   __ Bind(&pop_loop);
   __ Pop(x4);
   __ Str(x4, MemOperand(x3, kPointerSize, PostIndex));
   __ Bind(&pop_loop_header);
   __ Cmp(unwind_limit, __ StackPointer());
   __ B(ne, &pop_loop);

   // Compute the output frame in the deoptimizer.
   __ Push(x0);  // Preserve deoptimizer object across call.

   {
     // Call Deoptimizer::ComputeOutputFrames().
     AllowExternalCallThatCantCauseGC scope(masm());
     __ CallCFunction(
         ExternalReference::compute_output_frames_function(isolate()), 1);
   }
   __ Pop(x4);  // Restore deoptimizer object (class Deoptimizer).

   __ Ldr(__ StackPointer(),
          MemOperand(x4, Deoptimizer::caller_frame_top_offset()));

   // Replace the current (input) frame with the output frames.
   Label outer_push_loop, inner_push_loop,
       outer_loop_header, inner_loop_header;
   __ Ldrsw(x1, MemOperand(x4, Deoptimizer::output_count_offset()));
   __ Ldr(x0, MemOperand(x4, Deoptimizer::output_offset()));
   __ Add(x1, x0, Operand(x1, LSL, kPointerSizeLog2));
   __ B(&outer_loop_header);

   __ Bind(&outer_push_loop);
   Register current_frame = x2;
   __ Ldr(current_frame, MemOperand(x0, 0));
   __ Ldr(x3, MemOperand(current_frame, FrameDescription::frame_size_offset()));
   __ B(&inner_loop_header);

   __ Bind(&inner_push_loop);
   __ Sub(x3, x3, kPointerSize);
   __ Add(x6, current_frame, x3);
   __ Ldr(x7, MemOperand(x6, FrameDescription::frame_content_offset()));
   __ Push(x7);
   __ Bind(&inner_loop_header);
   __ Cbnz(x3, &inner_push_loop);

   __ Add(x0, x0, kPointerSize);
   __ Bind(&outer_loop_header);
   __ Cmp(x0, x1);
   __ B(lt, &outer_push_loop);

   __ Ldr(x1, MemOperand(x4, Deoptimizer::input_offset()));
   DCHECK(!saved_fp_registers.IncludesAliasOf(crankshaft_fp_scratch) &&
          !saved_fp_registers.IncludesAliasOf(fp_zero) &&
          !saved_fp_registers.IncludesAliasOf(fp_scratch));
   while (!saved_fp_registers.IsEmpty()) {
     const CPURegister reg = saved_fp_registers.PopLowestIndex();
     int src_offset = FrameDescription::double_registers_offset() +
                      (reg.code() * kDoubleSize);
     __ Ldr(reg, MemOperand(x1, src_offset));
   }

   // Push state from the last output frame.
   __ Ldr(x6, MemOperand(current_frame, FrameDescription::state_offset()));
   __ Push(x6);

   // TODO(all): ARM copies a lot (if not all) of the last output frame onto the
   // stack, then pops it all into registers. Here, we try to load it directly
   // into the relevant registers. Is this correct? If so, we should improve the
   // ARM code.

   // TODO(all): This code needs to be revisited, We probably don't need to
   // restore all the registers as fullcodegen does not keep live values in
   // registers (note that at least fp must be restored though).

   // Restore registers from the last output frame.
   // Note that lr is not in the list of saved_registers and will be restored
   // later. We can use it to hold the address of last output frame while
   // reloading the other registers.
   DCHECK(!saved_registers.IncludesAliasOf(lr));
   Register last_output_frame = lr;
   __ Mov(last_output_frame, current_frame);

   // We don't need to restore x7 as it will be clobbered later to hold the
   // continuation address.
   Register continuation = x7;
   saved_registers.Remove(continuation);

   while (!saved_registers.IsEmpty()) {
     // TODO(all): Look for opportunities to optimize this by using ldp.
     CPURegister current_reg = saved_registers.PopLowestIndex();
     int offset = (current_reg.code() * kPointerSize) +
         FrameDescription::registers_offset();
     __ Ldr(current_reg, MemOperand(last_output_frame, offset));
   }

   __ Ldr(continuation, MemOperand(last_output_frame,
                                   FrameDescription::continuation_offset()));
   __ Ldr(lr, MemOperand(last_output_frame, FrameDescription::pc_offset()));
   __ InitializeRootRegister();
   __ Br(continuation);
 }


 // Size of an entry of the second level deopt table.
 // This is the code size generated by GeneratePrologue for one entry.
 const int Deoptimizer::table_entry_size_ = 2 * kInstructionSize;


 void Deoptimizer::TableEntryGenerator::GeneratePrologue() {
   UseScratchRegisterScope temps(masm());
   Register entry_id = temps.AcquireX();

   // Create a sequence of deoptimization entries.
   // Note that registers are still live when jumping to an entry.
   Label done;
   {
     InstructionAccurateScope scope(masm());

     // The number of entry will never exceed kMaxNumberOfEntries.
     // As long as kMaxNumberOfEntries is a valid 16 bits immediate you can use
     // a movz instruction to load the entry id.
     DCHECK(is_uint16(Deoptimizer::kMaxNumberOfEntries));

     for (int i = 0; i < count(); i++) {
       int start = masm()->pc_offset();
       USE(start);
       __ movz(entry_id, i);
       __ b(&done);
       DCHECK(masm()->pc_offset() - start == table_entry_size_);
     }
   }
   __ Bind(&done);
   __ Push(entry_id);
 }


 void FrameDescription::SetCallerPc(unsigned offset, intptr_t value) {
   SetFrameSlot(offset, value);
 }


 void FrameDescription::SetCallerFp(unsigned offset, intptr_t value) {
   SetFrameSlot(offset, value);
 }


 void FrameDescription::SetCallerConstantPool(unsigned offset, intptr_t value) {
   // No embedded constant pool support.
   UNREACHABLE();
 }


 #undef __

 }  // namespace internal
 }  // namespace v8
	// Copyright 2013 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "src/arm64/frames-arm64.h"
	#include "src/codegen.h"
	#include "src/deoptimizer.h"
	#include "src/full-codegen/full-codegen.h"
	#include "src/register-configuration.h"
	#include "src/safepoint-table.h"


	namespace v8 {
	namespace internal {


	int Deoptimizer::patch_size() {
	// Size of the code used to patch lazy bailout points.
	// Patching is done by Deoptimizer::DeoptimizeFunction.
	return 4 * kInstructionSize;
	}


	void Deoptimizer::EnsureRelocSpaceForLazyDeoptimization(Handle<Code> code) {
	// Empty because there is no need for relocation information for the code
	// patching in Deoptimizer::PatchCodeForDeoptimization below.
	}


	void Deoptimizer::PatchCodeForDeoptimization(Isolate* isolate, Code* code) {
	// Invalidate the relocation information, as it will become invalid by the
	// code patching below, and is not needed any more.
	code->InvalidateRelocation();

	// TODO(jkummerow): if (FLAG_zap_code_space), make the code object's
	// entry sequence unusable (see other architectures).

	DeoptimizationInputData* deopt_data =
	DeoptimizationInputData::cast(code->deoptimization_data());
	Address code_start_address = code->instruction_start();
	#ifdef DEBUG
	Address prev_call_address = NULL;
	#endif
	// For each LLazyBailout instruction insert a call to the corresponding
	// deoptimization entry.
	for (int i = 0; i < deopt_data->DeoptCount(); i++) {
	if (deopt_data->Pc(i)->value() == -1) continue;

	Address call_address = code_start_address + deopt_data->Pc(i)->value();
	Address deopt_entry = GetDeoptimizationEntry(isolate, i, LAZY);

	PatchingAssembler patcher(isolate, call_address,
	patch_size() / kInstructionSize);
	patcher.ldr_pcrel(ip0, (2 * kInstructionSize) >> kLoadLiteralScaleLog2);
	patcher.blr(ip0);
	patcher.dc64(reinterpret_cast<intptr_t>(deopt_entry));

	DCHECK((prev_call_address == NULL) \|\|
	(call_address >= prev_call_address + patch_size()));
	DCHECK(call_address + patch_size() <= code->instruction_end());
	#ifdef DEBUG
	prev_call_address = call_address;
	#endif
	}
	}


	void Deoptimizer::SetPlatformCompiledStubRegisters(
	FrameDescription* output_frame, CodeStubDescriptor* descriptor) {
	ApiFunction function(descriptor->deoptimization_handler());
	ExternalReference xref(&function, ExternalReference::BUILTIN_CALL, isolate_);
	intptr_t handler = reinterpret_cast<intptr_t>(xref.address());
	int params = descriptor->GetHandlerParameterCount();
	output_frame->SetRegister(x0.code(), params);
	output_frame->SetRegister(x1.code(), handler);
	}


	void Deoptimizer::CopyDoubleRegisters(FrameDescription* output_frame) {
	for (int i = 0; i < DoubleRegister::kMaxNumRegisters; ++i) {
	double double_value = input_->GetDoubleRegister(i);
	output_frame->SetDoubleRegister(i, double_value);
	}
	}



	#define __ masm()->

	void Deoptimizer::TableEntryGenerator::Generate() {
	GeneratePrologue();

	// TODO(all): This code needs to be revisited. We probably only need to save
	// caller-saved registers here. Callee-saved registers can be stored directly
	// in the input frame.

	// Save all allocatable floating point registers.
	CPURegList saved_fp_registers(
	CPURegister::kFPRegister, kDRegSizeInBits,
	RegisterConfiguration::Crankshaft()->allocatable_double_codes_mask());
	__ PushCPURegList(saved_fp_registers);

	// We save all the registers expcept jssp, sp and lr.
	CPURegList saved_registers(CPURegister::kRegister, kXRegSizeInBits, 0, 27);
	saved_registers.Combine(fp);
	__ PushCPURegList(saved_registers);

	__ Mov(x3, Operand(ExternalReference(Isolate::kCEntryFPAddress, isolate())));
	__ Str(fp, MemOperand(x3));

	const int kSavedRegistersAreaSize =
	(saved_registers.Count() * kXRegSize) +
	(saved_fp_registers.Count() * kDRegSize);

	// Floating point registers are saved on the stack above core registers.
	const int kFPRegistersOffset = saved_registers.Count() * kXRegSize;

	// Get the bailout id from the stack.
	Register bailout_id = x2;
	__ Peek(bailout_id, kSavedRegistersAreaSize);

	Register code_object = x3;
	Register fp_to_sp = x4;
	// Get the address of the location in the code object. This is the return
	// address for lazy deoptimization.
	__ Mov(code_object, lr);
	// Compute the fp-to-sp delta, and correct one word for bailout id.
	__ Add(fp_to_sp, __ StackPointer(),
	kSavedRegistersAreaSize + (1 * kPointerSize));
	__ Sub(fp_to_sp, fp, fp_to_sp);

	// Allocate a new deoptimizer object.
	__ Mov(x0, 0);
	Label context_check;
	__ Ldr(x1, MemOperand(fp, CommonFrameConstants::kContextOrFrameTypeOffset));
	__ JumpIfSmi(x1, &context_check);
	__ Ldr(x0, MemOperand(fp, JavaScriptFrameConstants::kFunctionOffset));
	__ bind(&context_check);
	__ Mov(x1, type());
	// Following arguments are already loaded:
	// - x2: bailout id
	// - x3: code object address
	// - x4: fp-to-sp delta
	__ Mov(x5, ExternalReference::isolate_address(isolate()));

	{
	// Call Deoptimizer::New().
	AllowExternalCallThatCantCauseGC scope(masm());
	__ CallCFunction(ExternalReference::new_deoptimizer_function(isolate()), 6);
	}

	// Preserve "deoptimizer" object in register x0.
	Register deoptimizer = x0;

	// Get the input frame descriptor pointer.
	__ Ldr(x1, MemOperand(deoptimizer, Deoptimizer::input_offset()));

	// Copy core registers into the input frame.
	CPURegList copy_to_input = saved_registers;
	for (int i = 0; i < saved_registers.Count(); i++) {
	__ Peek(x2, i * kPointerSize);
	CPURegister current_reg = copy_to_input.PopLowestIndex();
	int offset = (current_reg.code() * kPointerSize) +
	FrameDescription::registers_offset();
	__ Str(x2, MemOperand(x1, offset));
	}

	// Copy FP registers to the input frame.
	CPURegList copy_fp_to_input = saved_fp_registers;
	for (int i = 0; i < saved_fp_registers.Count(); i++) {
	int src_offset = kFPRegistersOffset + (i * kDoubleSize);
	__ Peek(x2, src_offset);
	CPURegister reg = copy_fp_to_input.PopLowestIndex();
	int dst_offset = FrameDescription::double_registers_offset() +
	(reg.code() * kDoubleSize);
	__ Str(x2, MemOperand(x1, dst_offset));
	}

	// Remove the bailout id and the saved registers from the stack.
	__ Drop(1 + (kSavedRegistersAreaSize / kXRegSize));

	// Compute a pointer to the unwinding limit in register x2; that is
	// the first stack slot not part of the input frame.
	Register unwind_limit = x2;
	__ Ldr(unwind_limit, MemOperand(x1, FrameDescription::frame_size_offset()));
	__ Add(unwind_limit, unwind_limit, __ StackPointer());

	// Unwind the stack down to - but not including - the unwinding
	// limit and copy the contents of the activation frame to the input
	// frame description.
	__ Add(x3, x1, FrameDescription::frame_content_offset());
	Label pop_loop;
	Label pop_loop_header;
	__ B(&pop_loop_header);
	__ Bind(&pop_loop);
	__ Pop(x4);
	__ Str(x4, MemOperand(x3, kPointerSize, PostIndex));
	__ Bind(&pop_loop_header);
	__ Cmp(unwind_limit, __ StackPointer());
	__ B(ne, &pop_loop);

	// Compute the output frame in the deoptimizer.
	__ Push(x0); // Preserve deoptimizer object across call.

	{
	// Call Deoptimizer::ComputeOutputFrames().
	AllowExternalCallThatCantCauseGC scope(masm());
	__ CallCFunction(
	ExternalReference::compute_output_frames_function(isolate()), 1);
	}
	__ Pop(x4); // Restore deoptimizer object (class Deoptimizer).

	__ Ldr(__ StackPointer(),
	MemOperand(x4, Deoptimizer::caller_frame_top_offset()));

	// Replace the current (input) frame with the output frames.
	Label outer_push_loop, inner_push_loop,
	outer_loop_header, inner_loop_header;
	__ Ldrsw(x1, MemOperand(x4, Deoptimizer::output_count_offset()));
	__ Ldr(x0, MemOperand(x4, Deoptimizer::output_offset()));
	__ Add(x1, x0, Operand(x1, LSL, kPointerSizeLog2));
	__ B(&outer_loop_header);

	__ Bind(&outer_push_loop);
	Register current_frame = x2;
	__ Ldr(current_frame, MemOperand(x0, 0));
	__ Ldr(x3, MemOperand(current_frame, FrameDescription::frame_size_offset()));
	__ B(&inner_loop_header);

	__ Bind(&inner_push_loop);
	__ Sub(x3, x3, kPointerSize);
	__ Add(x6, current_frame, x3);
	__ Ldr(x7, MemOperand(x6, FrameDescription::frame_content_offset()));
	__ Push(x7);
	__ Bind(&inner_loop_header);
	__ Cbnz(x3, &inner_push_loop);

	__ Add(x0, x0, kPointerSize);
	__ Bind(&outer_loop_header);
	__ Cmp(x0, x1);
	__ B(lt, &outer_push_loop);

	__ Ldr(x1, MemOperand(x4, Deoptimizer::input_offset()));
	DCHECK(!saved_fp_registers.IncludesAliasOf(crankshaft_fp_scratch) &&
	!saved_fp_registers.IncludesAliasOf(fp_zero) &&
	!saved_fp_registers.IncludesAliasOf(fp_scratch));
	while (!saved_fp_registers.IsEmpty()) {
	const CPURegister reg = saved_fp_registers.PopLowestIndex();
	int src_offset = FrameDescription::double_registers_offset() +
	(reg.code() * kDoubleSize);
	__ Ldr(reg, MemOperand(x1, src_offset));
	}

	// Push state from the last output frame.
	__ Ldr(x6, MemOperand(current_frame, FrameDescription::state_offset()));
	__ Push(x6);

	// TODO(all): ARM copies a lot (if not all) of the last output frame onto the
	// stack, then pops it all into registers. Here, we try to load it directly
	// into the relevant registers. Is this correct? If so, we should improve the
	// ARM code.

	// TODO(all): This code needs to be revisited, We probably don't need to
	// restore all the registers as fullcodegen does not keep live values in
	// registers (note that at least fp must be restored though).

	// Restore registers from the last output frame.
	// Note that lr is not in the list of saved_registers and will be restored
	// later. We can use it to hold the address of last output frame while
	// reloading the other registers.
	DCHECK(!saved_registers.IncludesAliasOf(lr));
	Register last_output_frame = lr;
	__ Mov(last_output_frame, current_frame);

	// We don't need to restore x7 as it will be clobbered later to hold the
	// continuation address.
	Register continuation = x7;
	saved_registers.Remove(continuation);

	while (!saved_registers.IsEmpty()) {
	// TODO(all): Look for opportunities to optimize this by using ldp.
	CPURegister current_reg = saved_registers.PopLowestIndex();
	int offset = (current_reg.code() * kPointerSize) +
	FrameDescription::registers_offset();
	__ Ldr(current_reg, MemOperand(last_output_frame, offset));
	}

	__ Ldr(continuation, MemOperand(last_output_frame,
	FrameDescription::continuation_offset()));
	__ Ldr(lr, MemOperand(last_output_frame, FrameDescription::pc_offset()));
	__ InitializeRootRegister();
	__ Br(continuation);
	}


	// Size of an entry of the second level deopt table.
	// This is the code size generated by GeneratePrologue for one entry.
	const int Deoptimizer::table_entry_size_ = 2 * kInstructionSize;


	void Deoptimizer::TableEntryGenerator::GeneratePrologue() {
	UseScratchRegisterScope temps(masm());
	Register entry_id = temps.AcquireX();

	// Create a sequence of deoptimization entries.
	// Note that registers are still live when jumping to an entry.
	Label done;
	{
	InstructionAccurateScope scope(masm());

	// The number of entry will never exceed kMaxNumberOfEntries.
	// As long as kMaxNumberOfEntries is a valid 16 bits immediate you can use
	// a movz instruction to load the entry id.
	DCHECK(is_uint16(Deoptimizer::kMaxNumberOfEntries));

	for (int i = 0; i < count(); i++) {
	int start = masm()->pc_offset();
	USE(start);
	__ movz(entry_id, i);
	__ b(&done);
	DCHECK(masm()->pc_offset() - start == table_entry_size_);
	}
	}
	__ Bind(&done);
	__ Push(entry_id);
	}


	void FrameDescription::SetCallerPc(unsigned offset, intptr_t value) {
	SetFrameSlot(offset, value);
	}


	void FrameDescription::SetCallerFp(unsigned offset, intptr_t value) {
	SetFrameSlot(offset, value);
	}


	void FrameDescription::SetCallerConstantPool(unsigned offset, intptr_t value) {
	// No embedded constant pool support.
	UNREACHABLE();
	}


	#undef __

	} // namespace internal
	} // namespace v8