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// Copyright 2012 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/ia32/codegen-ia32.h"

#if V8_TARGET_ARCH_IA32

#include "src/codegen.h"
#include "src/heap/heap.h"
#include "src/macro-assembler.h"

namespace v8 {
namespace internal {


// -------------------------------------------------------------------------
// Platform-specific RuntimeCallHelper functions.

void StubRuntimeCallHelper::BeforeCall(MacroAssembler* masm) const {
  masm->EnterFrame(StackFrame::INTERNAL);
  DCHECK(!masm->has_frame());
  masm->set_has_frame(true);
}


void StubRuntimeCallHelper::AfterCall(MacroAssembler* masm) const {
  masm->LeaveFrame(StackFrame::INTERNAL);
  DCHECK(masm->has_frame());
  masm->set_has_frame(false);
}


#define __ masm.


UnaryMathFunctionWithIsolate CreateSqrtFunction(Isolate* isolate) {
  size_t actual_size;
  // Allocate buffer in executable space.
  byte* buffer =
      static_cast<byte*>(base::OS::Allocate(1 * KB, &actual_size, true));
  if (buffer == nullptr) return nullptr;
  MacroAssembler masm(isolate, buffer, static_cast<int>(actual_size),
                      CodeObjectRequired::kNo);
  // esp[1 * kPointerSize]: raw double input
  // esp[0 * kPointerSize]: return address
  // Move double input into registers.
  {
    __ movsd(xmm0, Operand(esp, 1 * kPointerSize));
    __ sqrtsd(xmm0, xmm0);
    __ movsd(Operand(esp, 1 * kPointerSize), xmm0);
    // Load result into floating point register as return value.
    __ fld_d(Operand(esp, 1 * kPointerSize));
    __ Ret();
  }

  CodeDesc desc;
  masm.GetCode(&desc);
  DCHECK(!RelocInfo::RequiresRelocation(desc));

  Assembler::FlushICache(isolate, buffer, actual_size);
  base::OS::ProtectCode(buffer, actual_size);
  return FUNCTION_CAST<UnaryMathFunctionWithIsolate>(buffer);
}


// Helper functions for CreateMemMoveFunction.
#undef __
#define __ ACCESS_MASM(masm)

enum Direction { FORWARD, BACKWARD };
enum Alignment { MOVE_ALIGNED, MOVE_UNALIGNED };

// Expects registers:
// esi - source, aligned if alignment == ALIGNED
// edi - destination, always aligned
// ecx - count (copy size in bytes)
// edx - loop count (number of 64 byte chunks)
void MemMoveEmitMainLoop(MacroAssembler* masm,
                         Label* move_last_15,
                         Direction direction,
                         Alignment alignment) {
  Register src = esi;
  Register dst = edi;
  Register count = ecx;
  Register loop_count = edx;
  Label loop, move_last_31, move_last_63;
  __ cmp(loop_count, 0);
  __ j(equal, &move_last_63);
  __ bind(&loop);
  // Main loop. Copy in 64 byte chunks.
  if (direction == BACKWARD) __ sub(src, Immediate(0x40));
  __ movdq(alignment == MOVE_ALIGNED, xmm0, Operand(src, 0x00));
  __ movdq(alignment == MOVE_ALIGNED, xmm1, Operand(src, 0x10));
  __ movdq(alignment == MOVE_ALIGNED, xmm2, Operand(src, 0x20));
  __ movdq(alignment == MOVE_ALIGNED, xmm3, Operand(src, 0x30));
  if (direction == FORWARD) __ add(src, Immediate(0x40));
  if (direction == BACKWARD) __ sub(dst, Immediate(0x40));
  __ movdqa(Operand(dst, 0x00), xmm0);
  __ movdqa(Operand(dst, 0x10), xmm1);
  __ movdqa(Operand(dst, 0x20), xmm2);
  __ movdqa(Operand(dst, 0x30), xmm3);
  if (direction == FORWARD) __ add(dst, Immediate(0x40));
  __ dec(loop_count);
  __ j(not_zero, &loop);
  // At most 63 bytes left to copy.
  __ bind(&move_last_63);
  __ test(count, Immediate(0x20));
  __ j(zero, &move_last_31);
  if (direction == BACKWARD) __ sub(src, Immediate(0x20));
  __ movdq(alignment == MOVE_ALIGNED, xmm0, Operand(src, 0x00));
  __ movdq(alignment == MOVE_ALIGNED, xmm1, Operand(src, 0x10));
  if (direction == FORWARD) __ add(src, Immediate(0x20));
  if (direction == BACKWARD) __ sub(dst, Immediate(0x20));
  __ movdqa(Operand(dst, 0x00), xmm0);
  __ movdqa(Operand(dst, 0x10), xmm1);
  if (direction == FORWARD) __ add(dst, Immediate(0x20));
  // At most 31 bytes left to copy.
  __ bind(&move_last_31);
  __ test(count, Immediate(0x10));
  __ j(zero, move_last_15);
  if (direction == BACKWARD) __ sub(src, Immediate(0x10));
  __ movdq(alignment == MOVE_ALIGNED, xmm0, Operand(src, 0));
  if (direction == FORWARD) __ add(src, Immediate(0x10));
  if (direction == BACKWARD) __ sub(dst, Immediate(0x10));
  __ movdqa(Operand(dst, 0), xmm0);
  if (direction == FORWARD) __ add(dst, Immediate(0x10));
}


void MemMoveEmitPopAndReturn(MacroAssembler* masm) {
  __ pop(esi);
  __ pop(edi);
  __ ret(0);
}


#undef __
#define __ masm.


class LabelConverter {
 public:
  explicit LabelConverter(byte* buffer) : buffer_(buffer) {}
  int32_t address(Label* l) const {
    return reinterpret_cast<int32_t>(buffer_) + l->pos();
  }
 private:
  byte* buffer_;
};


MemMoveFunction CreateMemMoveFunction(Isolate* isolate) {
  size_t actual_size;
  // Allocate buffer in executable space.
  byte* buffer =
      static_cast<byte*>(base::OS::Allocate(1 * KB, &actual_size, true));
  if (buffer == nullptr) return nullptr;
  MacroAssembler masm(isolate, buffer, static_cast<int>(actual_size),
                      CodeObjectRequired::kNo);
  LabelConverter conv(buffer);

  // Generated code is put into a fixed, unmovable buffer, and not into
  // the V8 heap. We can't, and don't, refer to any relocatable addresses
  // (e.g. the JavaScript nan-object).

  // 32-bit C declaration function calls pass arguments on stack.

  // Stack layout:
  // esp[12]: Third argument, size.
  // esp[8]: Second argument, source pointer.
  // esp[4]: First argument, destination pointer.
  // esp[0]: return address

  const int kDestinationOffset = 1 * kPointerSize;
  const int kSourceOffset = 2 * kPointerSize;
  const int kSizeOffset = 3 * kPointerSize;

  // When copying up to this many bytes, use special "small" handlers.
  const size_t kSmallCopySize = 8;
  // When copying up to this many bytes, use special "medium" handlers.
  const size_t kMediumCopySize = 63;
  // When non-overlapping region of src and dst is less than this,
  // use a more careful implementation (slightly slower).
  const size_t kMinMoveDistance = 16;
  // Note that these values are dictated by the implementation below,
  // do not just change them and hope things will work!

  int stack_offset = 0;  // Update if we change the stack height.

  Label backward, backward_much_overlap;
  Label forward_much_overlap, small_size, medium_size, pop_and_return;
  __ push(edi);
  __ push(esi);
  stack_offset += 2 * kPointerSize;
  Register dst = edi;
  Register src = esi;
  Register count = ecx;
  Register loop_count = edx;
  __ mov(dst, Operand(esp, stack_offset + kDestinationOffset));
  __ mov(src, Operand(esp, stack_offset + kSourceOffset));
  __ mov(count, Operand(esp, stack_offset + kSizeOffset));

  __ cmp(dst, src);
  __ j(equal, &pop_and_return);

  __ prefetch(Operand(src, 0), 1);
  __ cmp(count, kSmallCopySize);
  __ j(below_equal, &small_size);
  __ cmp(count, kMediumCopySize);
  __ j(below_equal, &medium_size);
  __ cmp(dst, src);
  __ j(above, &backward);

  {
    // |dst| is a lower address than |src|. Copy front-to-back.
    Label unaligned_source, move_last_15, skip_last_move;
    __ mov(eax, src);
    __ sub(eax, dst);
    __ cmp(eax, kMinMoveDistance);
    __ j(below, &forward_much_overlap);
    // Copy first 16 bytes.
    __ movdqu(xmm0, Operand(src, 0));
    __ movdqu(Operand(dst, 0), xmm0);
    // Determine distance to alignment: 16 - (dst & 0xF).
    __ mov(edx, dst);
    __ and_(edx, 0xF);
    __ neg(edx);
    __ add(edx, Immediate(16));
    __ add(dst, edx);
    __ add(src, edx);
    __ sub(count, edx);
    // dst is now aligned. Main copy loop.
    __ mov(loop_count, count);
    __ shr(loop_count, 6);
    // Check if src is also aligned.
    __ test(src, Immediate(0xF));
    __ j(not_zero, &unaligned_source);
    // Copy loop for aligned source and destination.
    MemMoveEmitMainLoop(&masm, &move_last_15, FORWARD, MOVE_ALIGNED);
    // At most 15 bytes to copy. Copy 16 bytes at end of string.
    __ bind(&move_last_15);
    __ and_(count, 0xF);
    __ j(zero, &skip_last_move, Label::kNear);
    __ movdqu(xmm0, Operand(src, count, times_1, -0x10));
    __ movdqu(Operand(dst, count, times_1, -0x10), xmm0);
    __ bind(&skip_last_move);
    MemMoveEmitPopAndReturn(&masm);

    // Copy loop for unaligned source and aligned destination.
    __ bind(&unaligned_source);
    MemMoveEmitMainLoop(&masm, &move_last_15, FORWARD, MOVE_UNALIGNED);
    __ jmp(&move_last_15);

    // Less than kMinMoveDistance offset between dst and src.
    Label loop_until_aligned, last_15_much_overlap;
    __ bind(&loop_until_aligned);
    __ mov_b(eax, Operand(src, 0));
    __ inc(src);
    __ mov_b(Operand(dst, 0), eax);
    __ inc(dst);
    __ dec(count);
    __ bind(&forward_much_overlap);  // Entry point into this block.
    __ test(dst, Immediate(0xF));
    __ j(not_zero, &loop_until_aligned);
    // dst is now aligned, src can't be. Main copy loop.
    __ mov(loop_count, count);
    __ shr(loop_count, 6);
    MemMoveEmitMainLoop(&masm, &last_15_much_overlap,
                        FORWARD, MOVE_UNALIGNED);
    __ bind(&last_15_much_overlap);
    __ and_(count, 0xF);
    __ j(zero, &pop_and_return);
    __ cmp(count, kSmallCopySize);
    __ j(below_equal, &small_size);
    __ jmp(&medium_size);
  }

  {
    // |dst| is a higher address than |src|. Copy backwards.
    Label unaligned_source, move_first_15, skip_last_move;
    __ bind(&backward);
    // |dst| and |src| always point to the end of what's left to copy.
    __ add(dst, count);
    __ add(src, count);
    __ mov(eax, dst);
    __ sub(eax, src);
    __ cmp(eax, kMinMoveDistance);
    __ j(below, &backward_much_overlap);
    // Copy last 16 bytes.
    __ movdqu(xmm0, Operand(src, -0x10));
    __ movdqu(Operand(dst, -0x10), xmm0);
    // Find distance to alignment: dst & 0xF
    __ mov(edx, dst);
    __ and_(edx, 0xF);
    __ sub(dst, edx);
    __ sub(src, edx);
    __ sub(count, edx);
    // dst is now aligned. Main copy loop.
    __ mov(loop_count, count);
    __ shr(loop_count, 6);
    // Check if src is also aligned.
    __ test(src, Immediate(0xF));
    __ j(not_zero, &unaligned_source);
    // Copy loop for aligned source and destination.
    MemMoveEmitMainLoop(&masm, &move_first_15, BACKWARD, MOVE_ALIGNED);
    // At most 15 bytes to copy. Copy 16 bytes at beginning of string.
    __ bind(&move_first_15);
    __ and_(count, 0xF);
    __ j(zero, &skip_last_move, Label::kNear);
    __ sub(src, count);
    __ sub(dst, count);
    __ movdqu(xmm0, Operand(src, 0));
    __ movdqu(Operand(dst, 0), xmm0);
    __ bind(&skip_last_move);
    MemMoveEmitPopAndReturn(&masm);

    // Copy loop for unaligned source and aligned destination.
    __ bind(&unaligned_source);
    MemMoveEmitMainLoop(&masm, &move_first_15, BACKWARD, MOVE_UNALIGNED);
    __ jmp(&move_first_15);

    // Less than kMinMoveDistance offset between dst and src.
    Label loop_until_aligned, first_15_much_overlap;
    __ bind(&loop_until_aligned);
    __ dec(src);
    __ dec(dst);
    __ mov_b(eax, Operand(src, 0));
    __ mov_b(Operand(dst, 0), eax);
    __ dec(count);
    __ bind(&backward_much_overlap);  // Entry point into this block.
    __ test(dst, Immediate(0xF));
    __ j(not_zero, &loop_until_aligned);
    // dst is now aligned, src can't be. Main copy loop.
    __ mov(loop_count, count);
    __ shr(loop_count, 6);
    MemMoveEmitMainLoop(&masm, &first_15_much_overlap,
                        BACKWARD, MOVE_UNALIGNED);
    __ bind(&first_15_much_overlap);
    __ and_(count, 0xF);
    __ j(zero, &pop_and_return);
    // Small/medium handlers expect dst/src to point to the beginning.
    __ sub(dst, count);
    __ sub(src, count);
    __ cmp(count, kSmallCopySize);
    __ j(below_equal, &small_size);
    __ jmp(&medium_size);
  }
  {
    // Special handlers for 9 <= copy_size < 64. No assumptions about
    // alignment or move distance, so all reads must be unaligned and
    // must happen before any writes.
    Label medium_handlers, f9_16, f17_32, f33_48, f49_63;

    __ bind(&f9_16);
    __ movsd(xmm0, Operand(src, 0));
    __ movsd(xmm1, Operand(src, count, times_1, -8));
    __ movsd(Operand(dst, 0), xmm0);
    __ movsd(Operand(dst, count, times_1, -8), xmm1);
    MemMoveEmitPopAndReturn(&masm);

    __ bind(&f17_32);
    __ movdqu(xmm0, Operand(src, 0));
    __ movdqu(xmm1, Operand(src, count, times_1, -0x10));
    __ movdqu(Operand(dst, 0x00), xmm0);
    __ movdqu(Operand(dst, count, times_1, -0x10), xmm1);
    MemMoveEmitPopAndReturn(&masm);

    __ bind(&f33_48);
    __ movdqu(xmm0, Operand(src, 0x00));
    __ movdqu(xmm1, Operand(src, 0x10));
    __ movdqu(xmm2, Operand(src, count, times_1, -0x10));
    __ movdqu(Operand(dst, 0x00), xmm0);
    __ movdqu(Operand(dst, 0x10), xmm1);
    __ movdqu(Operand(dst, count, times_1, -0x10), xmm2);
    MemMoveEmitPopAndReturn(&masm);

    __ bind(&f49_63);
    __ movdqu(xmm0, Operand(src, 0x00));
    __ movdqu(xmm1, Operand(src, 0x10));
    __ movdqu(xmm2, Operand(src, 0x20));
    __ movdqu(xmm3, Operand(src, count, times_1, -0x10));
    __ movdqu(Operand(dst, 0x00), xmm0);
    __ movdqu(Operand(dst, 0x10), xmm1);
    __ movdqu(Operand(dst, 0x20), xmm2);
    __ movdqu(Operand(dst, count, times_1, -0x10), xmm3);
    MemMoveEmitPopAndReturn(&masm);

    __ bind(&medium_handlers);
    __ dd(conv.address(&f9_16));
    __ dd(conv.address(&f17_32));
    __ dd(conv.address(&f33_48));
    __ dd(conv.address(&f49_63));

    __ bind(&medium_size);  // Entry point into this block.
    __ mov(eax, count);
    __ dec(eax);
    __ shr(eax, 4);
    if (FLAG_debug_code) {
      Label ok;
      __ cmp(eax, 3);
      __ j(below_equal, &ok);
      __ int3();
      __ bind(&ok);
    }
    __ mov(eax, Operand(eax, times_4, conv.address(&medium_handlers)));
    __ jmp(eax);
  }
  {
    // Specialized copiers for copy_size <= 8 bytes.
    Label small_handlers, f0, f1, f2, f3, f4, f5_8;
    __ bind(&f0);
    MemMoveEmitPopAndReturn(&masm);

    __ bind(&f1);
    __ mov_b(eax, Operand(src, 0));
    __ mov_b(Operand(dst, 0), eax);
    MemMoveEmitPopAndReturn(&masm);

    __ bind(&f2);
    __ mov_w(eax, Operand(src, 0));
    __ mov_w(Operand(dst, 0), eax);
    MemMoveEmitPopAndReturn(&masm);

    __ bind(&f3);
    __ mov_w(eax, Operand(src, 0));
    __ mov_b(edx, Operand(src, 2));
    __ mov_w(Operand(dst, 0), eax);
    __ mov_b(Operand(dst, 2), edx);
    MemMoveEmitPopAndReturn(&masm);

    __ bind(&f4);
    __ mov(eax, Operand(src, 0));
    __ mov(Operand(dst, 0), eax);
    MemMoveEmitPopAndReturn(&masm);

    __ bind(&f5_8);
    __ mov(eax, Operand(src, 0));
    __ mov(edx, Operand(src, count, times_1, -4));
    __ mov(Operand(dst, 0), eax);
    __ mov(Operand(dst, count, times_1, -4), edx);
    MemMoveEmitPopAndReturn(&masm);

    __ bind(&small_handlers);
    __ dd(conv.address(&f0));
    __ dd(conv.address(&f1));
    __ dd(conv.address(&f2));
    __ dd(conv.address(&f3));
    __ dd(conv.address(&f4));
    __ dd(conv.address(&f5_8));
    __ dd(conv.address(&f5_8));
    __ dd(conv.address(&f5_8));
    __ dd(conv.address(&f5_8));

    __ bind(&small_size);  // Entry point into this block.
    if (FLAG_debug_code) {
      Label ok;
      __ cmp(count, 8);
      __ j(below_equal, &ok);
      __ int3();
      __ bind(&ok);
    }
    __ mov(eax, Operand(count, times_4, conv.address(&small_handlers)));
    __ jmp(eax);
  }

  __ bind(&pop_and_return);
  MemMoveEmitPopAndReturn(&masm);

  CodeDesc desc;
  masm.GetCode(&desc);
  DCHECK(!RelocInfo::RequiresRelocation(desc));
  Assembler::FlushICache(isolate, buffer, actual_size);
  base::OS::ProtectCode(buffer, actual_size);
  // TODO(jkummerow): It would be nice to register this code creation event
  // with the PROFILE / GDBJIT system.
  return FUNCTION_CAST<MemMoveFunction>(buffer);
}


#undef __

// -------------------------------------------------------------------------
// Code generators

#define __ ACCESS_MASM(masm)


void ElementsTransitionGenerator::GenerateMapChangeElementsTransition(
    MacroAssembler* masm,
    Register receiver,
    Register key,
    Register value,
    Register target_map,
    AllocationSiteMode mode,
    Label* allocation_memento_found) {
  Register scratch = edi;
  DCHECK(!AreAliased(receiver, key, value, target_map, scratch));

  if (mode == TRACK_ALLOCATION_SITE) {
    DCHECK(allocation_memento_found != NULL);
    __ JumpIfJSArrayHasAllocationMemento(
        receiver, scratch, allocation_memento_found);
  }

  // Set transitioned map.
  __ mov(FieldOperand(receiver, HeapObject::kMapOffset), target_map);
  __ RecordWriteField(receiver,
                      HeapObject::kMapOffset,
                      target_map,
                      scratch,
                      kDontSaveFPRegs,
                      EMIT_REMEMBERED_SET,
                      OMIT_SMI_CHECK);
}


void ElementsTransitionGenerator::GenerateSmiToDouble(
    MacroAssembler* masm,
    Register receiver,
    Register key,
    Register value,
    Register target_map,
    AllocationSiteMode mode,
    Label* fail) {
  // Return address is on the stack.
  DCHECK(receiver.is(edx));
  DCHECK(key.is(ecx));
  DCHECK(value.is(eax));
  DCHECK(target_map.is(ebx));

  Label loop, entry, convert_hole, gc_required, only_change_map;

  if (mode == TRACK_ALLOCATION_SITE) {
    __ JumpIfJSArrayHasAllocationMemento(edx, edi, fail);
  }

  // Check for empty arrays, which only require a map transition and no changes
  // to the backing store.
  __ mov(edi, FieldOperand(edx, JSObject::kElementsOffset));
  __ cmp(edi, Immediate(masm->isolate()->factory()->empty_fixed_array()));
  __ j(equal, &only_change_map);

  __ push(eax);
  __ push(ebx);
  __ push(esi);

  __ mov(edi, FieldOperand(edi, FixedArray::kLengthOffset));

  // Allocate new FixedDoubleArray.
  // edx: receiver
  // edi: length of source FixedArray (smi-tagged)
  AllocationFlags flags = static_cast<AllocationFlags>(DOUBLE_ALIGNMENT);
  __ Allocate(FixedDoubleArray::kHeaderSize, times_8, edi,
              REGISTER_VALUE_IS_SMI, eax, ebx, no_reg, &gc_required, flags);

  // eax: destination FixedDoubleArray
  // edi: number of elements
  // edx: receiver
  __ mov(FieldOperand(eax, HeapObject::kMapOffset),
         Immediate(masm->isolate()->factory()->fixed_double_array_map()));
  __ mov(FieldOperand(eax, FixedDoubleArray::kLengthOffset), edi);
  __ mov(esi, FieldOperand(edx, JSObject::kElementsOffset));
  // Replace receiver's backing store with newly created FixedDoubleArray.
  __ mov(FieldOperand(edx, JSObject::kElementsOffset), eax);
  __ mov(ebx, eax);
  __ RecordWriteField(edx,
                      JSObject::kElementsOffset,
                      ebx,
                      edi,
                      kDontSaveFPRegs,
                      EMIT_REMEMBERED_SET,
                      OMIT_SMI_CHECK);

  __ mov(edi, FieldOperand(esi, FixedArray::kLengthOffset));

  // Prepare for conversion loop.
  ExternalReference canonical_the_hole_nan_reference =
      ExternalReference::address_of_the_hole_nan();
  XMMRegister the_hole_nan = xmm1;
  __ movsd(the_hole_nan,
           Operand::StaticVariable(canonical_the_hole_nan_reference));
  __ jmp(&entry);

  // Call into runtime if GC is required.
  __ bind(&gc_required);

  // Restore registers before jumping into runtime.
  __ pop(esi);
  __ pop(ebx);
  __ pop(eax);
  __ jmp(fail);

  // Convert and copy elements
  // esi: source FixedArray
  __ bind(&loop);
  __ mov(ebx, FieldOperand(esi, edi, times_2, FixedArray::kHeaderSize));
  // ebx: current element from source
  // edi: index of current element
  __ JumpIfNotSmi(ebx, &convert_hole);

  // Normal smi, convert it to double and store.
  __ SmiUntag(ebx);
  __ Cvtsi2sd(xmm0, ebx);
  __ movsd(FieldOperand(eax, edi, times_4, FixedDoubleArray::kHeaderSize),
           xmm0);
  __ jmp(&entry);

  // Found hole, store hole_nan_as_double instead.
  __ bind(&convert_hole);

  if (FLAG_debug_code) {
    __ cmp(ebx, masm->isolate()->factory()->the_hole_value());
    __ Assert(equal, kObjectFoundInSmiOnlyArray);
  }

  __ movsd(FieldOperand(eax, edi, times_4, FixedDoubleArray::kHeaderSize),
           the_hole_nan);

  __ bind(&entry);
  __ sub(edi, Immediate(Smi::FromInt(1)));
  __ j(not_sign, &loop);

  // Restore registers.
  __ pop(esi);
  __ pop(ebx);
  __ pop(eax);

  __ bind(&only_change_map);
  // eax: value
  // ebx: target map
  // Set transitioned map.
  __ mov(FieldOperand(edx, HeapObject::kMapOffset), ebx);
  __ RecordWriteField(edx,
                      HeapObject::kMapOffset,
                      ebx,
                      edi,
                      kDontSaveFPRegs,
                      OMIT_REMEMBERED_SET,
                      OMIT_SMI_CHECK);
}


void ElementsTransitionGenerator::GenerateDoubleToObject(
    MacroAssembler* masm,
    Register receiver,
    Register key,
    Register value,
    Register target_map,
    AllocationSiteMode mode,
    Label* fail) {
  // Return address is on the stack.
  DCHECK(receiver.is(edx));
  DCHECK(key.is(ecx));
  DCHECK(value.is(eax));
  DCHECK(target_map.is(ebx));

  Label loop, entry, convert_hole, gc_required, only_change_map, success;

  if (mode == TRACK_ALLOCATION_SITE) {
    __ JumpIfJSArrayHasAllocationMemento(edx, edi, fail);
  }

  // Check for empty arrays, which only require a map transition and no changes
  // to the backing store.
  __ mov(edi, FieldOperand(edx, JSObject::kElementsOffset));
  __ cmp(edi, Immediate(masm->isolate()->factory()->empty_fixed_array()));
  __ j(equal, &only_change_map);

  __ push(esi);
  __ push(eax);
  __ push(edx);
  __ push(ebx);

  __ mov(ebx, FieldOperand(edi, FixedDoubleArray::kLengthOffset));

  // Allocate new FixedArray.
  // ebx: length of source FixedDoubleArray (smi-tagged)
  __ lea(edi, Operand(ebx, times_2, FixedArray::kHeaderSize));
  __ Allocate(edi, eax, esi, no_reg, &gc_required, NO_ALLOCATION_FLAGS);

  // eax: destination FixedArray
  // ebx: number of elements
  __ mov(FieldOperand(eax, HeapObject::kMapOffset),
         Immediate(masm->isolate()->factory()->fixed_array_map()));
  __ mov(FieldOperand(eax, FixedArray::kLengthOffset), ebx);
  __ mov(edi, FieldOperand(edx, JSObject::kElementsOffset));

  // Allocating heap numbers in the loop below can fail and cause a jump to
  // gc_required. We can't leave a partly initialized FixedArray behind,
  // so pessimistically fill it with holes now.
  Label initialization_loop, initialization_loop_entry;
  __ jmp(&initialization_loop_entry, Label::kNear);
  __ bind(&initialization_loop);
  __ mov(FieldOperand(eax, ebx, times_2, FixedArray::kHeaderSize),
         masm->isolate()->factory()->the_hole_value());
  __ bind(&initialization_loop_entry);
  __ sub(ebx, Immediate(Smi::FromInt(1)));
  __ j(not_sign, &initialization_loop);

  __ mov(ebx, FieldOperand(edi, FixedDoubleArray::kLengthOffset));
  __ jmp(&entry);

  // ebx: target map
  // edx: receiver
  // Set transitioned map.
  __ bind(&only_change_map);
  __ mov(FieldOperand(edx, HeapObject::kMapOffset), ebx);
  __ RecordWriteField(edx,
                      HeapObject::kMapOffset,
                      ebx,
                      edi,
                      kDontSaveFPRegs,
                      OMIT_REMEMBERED_SET,
                      OMIT_SMI_CHECK);
  __ jmp(&success);

  // Call into runtime if GC is required.
  __ bind(&gc_required);
  __ pop(ebx);
  __ pop(edx);
  __ pop(eax);
  __ pop(esi);
  __ jmp(fail);

  // Box doubles into heap numbers.
  // edi: source FixedDoubleArray
  // eax: destination FixedArray
  __ bind(&loop);
  // ebx: index of current element (smi-tagged)
  uint32_t offset = FixedDoubleArray::kHeaderSize + sizeof(kHoleNanLower32);
  __ cmp(FieldOperand(edi, ebx, times_4, offset), Immediate(kHoleNanUpper32));
  __ j(equal, &convert_hole);

  // Non-hole double, copy value into a heap number.
  __ AllocateHeapNumber(edx, esi, no_reg, &gc_required);
  // edx: new heap number
  __ movsd(xmm0,
           FieldOperand(edi, ebx, times_4, FixedDoubleArray::kHeaderSize));
  __ movsd(FieldOperand(edx, HeapNumber::kValueOffset), xmm0);
  __ mov(FieldOperand(eax, ebx, times_2, FixedArray::kHeaderSize), edx);
  __ mov(esi, ebx);
  __ RecordWriteArray(eax,
                      edx,
                      esi,
                      kDontSaveFPRegs,
                      EMIT_REMEMBERED_SET,
                      OMIT_SMI_CHECK);
  __ jmp(&entry, Label::kNear);

  // Replace the-hole NaN with the-hole pointer.
  __ bind(&convert_hole);
  __ mov(FieldOperand(eax, ebx, times_2, FixedArray::kHeaderSize),
         masm->isolate()->factory()->the_hole_value());

  __ bind(&entry);
  __ sub(ebx, Immediate(Smi::FromInt(1)));
  __ j(not_sign, &loop);

  __ pop(ebx);
  __ pop(edx);
  // ebx: target map
  // edx: receiver
  // Set transitioned map.
  __ mov(FieldOperand(edx, HeapObject::kMapOffset), ebx);
  __ RecordWriteField(edx,
                      HeapObject::kMapOffset,
                      ebx,
                      edi,
                      kDontSaveFPRegs,
                      OMIT_REMEMBERED_SET,
                      OMIT_SMI_CHECK);
  // Replace receiver's backing store with newly created and filled FixedArray.
  __ mov(FieldOperand(edx, JSObject::kElementsOffset), eax);
  __ RecordWriteField(edx,
                      JSObject::kElementsOffset,
                      eax,
                      edi,
                      kDontSaveFPRegs,
                      EMIT_REMEMBERED_SET,
                      OMIT_SMI_CHECK);

  // Restore registers.
  __ pop(eax);
  __ pop(esi);

  __ bind(&success);
}


void StringCharLoadGenerator::Generate(MacroAssembler* masm,
                                       Factory* factory,
                                       Register string,
                                       Register index,
                                       Register result,
                                       Label* call_runtime) {
  // Fetch the instance type of the receiver into result register.
  __ mov(result, FieldOperand(string, HeapObject::kMapOffset));
  __ movzx_b(result, FieldOperand(result, Map::kInstanceTypeOffset));

  // We need special handling for indirect strings.
  Label check_sequential;
  __ test(result, Immediate(kIsIndirectStringMask));
  __ j(zero, &check_sequential, Label::kNear);

  // Dispatch on the indirect string shape: slice or cons.
  Label cons_string;
  __ test(result, Immediate(kSlicedNotConsMask));
  __ j(zero, &cons_string, Label::kNear);

  // Handle slices.
  Label indirect_string_loaded;
  __ mov(result, FieldOperand(string, SlicedString::kOffsetOffset));
  __ SmiUntag(result);
  __ add(index, result);
  __ mov(string, FieldOperand(string, SlicedString::kParentOffset));
  __ jmp(&indirect_string_loaded, Label::kNear);

  // Handle cons strings.
  // Check whether the right hand side is the empty string (i.e. if
  // this is really a flat string in a cons string). If that is not
  // the case we would rather go to the runtime system now to flatten
  // the string.
  __ bind(&cons_string);
  __ cmp(FieldOperand(string, ConsString::kSecondOffset),
         Immediate(factory->empty_string()));
  __ j(not_equal, call_runtime);
  __ mov(string, FieldOperand(string, ConsString::kFirstOffset));

  __ bind(&indirect_string_loaded);
  __ mov(result, FieldOperand(string, HeapObject::kMapOffset));
  __ movzx_b(result, FieldOperand(result, Map::kInstanceTypeOffset));

  // Distinguish sequential and external strings. Only these two string
  // representations can reach here (slices and flat cons strings have been
  // reduced to the underlying sequential or external string).
  Label seq_string;
  __ bind(&check_sequential);
  STATIC_ASSERT(kSeqStringTag == 0);
  __ test(result, Immediate(kStringRepresentationMask));
  __ j(zero, &seq_string, Label::kNear);

  // Handle external strings.
  Label one_byte_external, done;
  if (FLAG_debug_code) {
    // Assert that we do not have a cons or slice (indirect strings) here.
    // Sequential strings have already been ruled out.
    __ test(result, Immediate(kIsIndirectStringMask));
    __ Assert(zero, kExternalStringExpectedButNotFound);
  }
  // Rule out short external strings.
  STATIC_ASSERT(kShortExternalStringTag != 0);
  __ test_b(result, Immediate(kShortExternalStringMask));
  __ j(not_zero, call_runtime);
  // Check encoding.
  STATIC_ASSERT(kTwoByteStringTag == 0);
  __ test_b(result, Immediate(kStringEncodingMask));
  __ mov(result, FieldOperand(string, ExternalString::kResourceDataOffset));
  __ j(not_equal, &one_byte_external, Label::kNear);
  // Two-byte string.
  __ movzx_w(result, Operand(result, index, times_2, 0));
  __ jmp(&done, Label::kNear);
  __ bind(&one_byte_external);
  // One-byte string.
  __ movzx_b(result, Operand(result, index, times_1, 0));
  __ jmp(&done, Label::kNear);

  // Dispatch on the encoding: one-byte or two-byte.
  Label one_byte;
  __ bind(&seq_string);
  STATIC_ASSERT((kStringEncodingMask & kOneByteStringTag) != 0);
  STATIC_ASSERT((kStringEncodingMask & kTwoByteStringTag) == 0);
  __ test(result, Immediate(kStringEncodingMask));
  __ j(not_zero, &one_byte, Label::kNear);

  // Two-byte string.
  // Load the two-byte character code into the result register.
  __ movzx_w(result, FieldOperand(string,
                                  index,
                                  times_2,
                                  SeqTwoByteString::kHeaderSize));
  __ jmp(&done, Label::kNear);

  // One-byte string.
  // Load the byte into the result register.
  __ bind(&one_byte);
  __ movzx_b(result, FieldOperand(string,
                                  index,
                                  times_1,
                                  SeqOneByteString::kHeaderSize));
  __ bind(&done);
}

#undef __


CodeAgingHelper::CodeAgingHelper(Isolate* isolate) {
  USE(isolate);
  DCHECK(young_sequence_.length() == kNoCodeAgeSequenceLength);
  CodePatcher patcher(isolate, young_sequence_.start(),
                      young_sequence_.length());
  patcher.masm()->push(ebp);
  patcher.masm()->mov(ebp, esp);
  patcher.masm()->push(esi);
  patcher.masm()->push(edi);
}


#ifdef DEBUG
bool CodeAgingHelper::IsOld(byte* candidate) const {
  return *candidate == kCallOpcode;
}
#endif


bool Code::IsYoungSequence(Isolate* isolate, byte* sequence) {
  bool result = isolate->code_aging_helper()->IsYoung(sequence);
  DCHECK(result || isolate->code_aging_helper()->IsOld(sequence));
  return result;
}


void Code::GetCodeAgeAndParity(Isolate* isolate, byte* sequence, Age* age,
                               MarkingParity* parity) {
  if (IsYoungSequence(isolate, sequence)) {
    *age = kNoAgeCodeAge;
    *parity = NO_MARKING_PARITY;
  } else {
    sequence++;  // Skip the kCallOpcode byte
    Address target_address = sequence + *reinterpret_cast<int*>(sequence) +
        Assembler::kCallTargetAddressOffset;
    Code* stub = GetCodeFromTargetAddress(target_address);
    GetCodeAgeAndParity(stub, age, parity);
  }
}


void Code::PatchPlatformCodeAge(Isolate* isolate,
                                byte* sequence,
                                Code::Age age,
                                MarkingParity parity) {
  uint32_t young_length = isolate->code_aging_helper()->young_sequence_length();
  if (age == kNoAgeCodeAge) {
    isolate->code_aging_helper()->CopyYoungSequenceTo(sequence);
    Assembler::FlushICache(isolate, sequence, young_length);
  } else {
    Code* stub = GetCodeAgeStub(isolate, age, parity);
    CodePatcher patcher(isolate, sequence, young_length);
    patcher.masm()->call(stub->instruction_start(), RelocInfo::NONE32);
  }
}


}  // namespace internal
}  // namespace v8

#endif  // V8_TARGET_ARCH_IA32