path: root/deps/v8/src/compiler/arm64/instruction-selector-arm64.cc

// Copyright 2014 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/compiler/instruction-selector-impl.h"
#include "src/compiler/node-matchers.h"

namespace v8 {
namespace internal {
namespace compiler {

enum ImmediateMode {
  kArithmeticImm,  // 12 bit unsigned immediate shifted left 0 or 12 bits
  kShift32Imm,     // 0 - 31
  kShift64Imm,     // 0 - 63
  kLogical32Imm,
  kLogical64Imm,
  kLoadStoreImm8,   // signed 8 bit or 12 bit unsigned scaled by access size
  kLoadStoreImm16,
  kLoadStoreImm32,
  kLoadStoreImm64,
  kNoImmediate
};


// Adds Arm64-specific methods for generating operands.
class Arm64OperandGenerator FINAL : public OperandGenerator {
 public:
  explicit Arm64OperandGenerator(InstructionSelector* selector)
      : OperandGenerator(selector) {}

  InstructionOperand* UseOperand(Node* node, ImmediateMode mode) {
    if (CanBeImmediate(node, mode)) {
      return UseImmediate(node);
    }
    return UseRegister(node);
  }

  bool CanBeImmediate(Node* node, ImmediateMode mode) {
    int64_t value;
    if (node->opcode() == IrOpcode::kInt32Constant)
      value = OpParameter<int32_t>(node);
    else if (node->opcode() == IrOpcode::kInt64Constant)
      value = OpParameter<int64_t>(node);
    else
      return false;
    unsigned ignored;
    switch (mode) {
      case kLogical32Imm:
        // TODO(dcarney): some unencodable values can be handled by
        // switching instructions.
        return Assembler::IsImmLogical(static_cast<uint64_t>(value), 32,
                                       &ignored, &ignored, &ignored);
      case kLogical64Imm:
        return Assembler::IsImmLogical(static_cast<uint64_t>(value), 64,
                                       &ignored, &ignored, &ignored);
      case kArithmeticImm:
        // TODO(dcarney): -values can be handled by instruction swapping
        return Assembler::IsImmAddSub(value);
      case kShift32Imm:
        return 0 <= value && value < 32;
      case kShift64Imm:
        return 0 <= value && value < 64;
      case kLoadStoreImm8:
        return IsLoadStoreImmediate(value, LSByte);
      case kLoadStoreImm16:
        return IsLoadStoreImmediate(value, LSHalfword);
      case kLoadStoreImm32:
        return IsLoadStoreImmediate(value, LSWord);
      case kLoadStoreImm64:
        return IsLoadStoreImmediate(value, LSDoubleWord);
      case kNoImmediate:
        return false;
    }
    return false;
  }

 private:
  bool IsLoadStoreImmediate(int64_t value, LSDataSize size) {
    return Assembler::IsImmLSScaled(value, size) ||
           Assembler::IsImmLSUnscaled(value);
  }
};


static void VisitRRR(InstructionSelector* selector, ArchOpcode opcode,
                     Node* node) {
  Arm64OperandGenerator g(selector);
  selector->Emit(opcode, g.DefineAsRegister(node),
                 g.UseRegister(node->InputAt(0)),
                 g.UseRegister(node->InputAt(1)));
}


static void VisitRRRFloat64(InstructionSelector* selector, ArchOpcode opcode,
                            Node* node) {
  Arm64OperandGenerator g(selector);
  selector->Emit(opcode, g.DefineAsRegister(node),
                 g.UseRegister(node->InputAt(0)),
                 g.UseRegister(node->InputAt(1)));
}


static void VisitRRO(InstructionSelector* selector, ArchOpcode opcode,
                     Node* node, ImmediateMode operand_mode) {
  Arm64OperandGenerator g(selector);
  selector->Emit(opcode, g.DefineAsRegister(node),
                 g.UseRegister(node->InputAt(0)),
                 g.UseOperand(node->InputAt(1), operand_mode));
}


// Shared routine for multiple binary operations.
template <typename Matcher>
static void VisitBinop(InstructionSelector* selector, Node* node,
                       InstructionCode opcode, ImmediateMode operand_mode,
                       FlagsContinuation* cont) {
  Arm64OperandGenerator g(selector);
  Matcher m(node);
  InstructionOperand* inputs[4];
  size_t input_count = 0;
  InstructionOperand* outputs[2];
  size_t output_count = 0;

  inputs[input_count++] = g.UseRegister(m.left().node());
  inputs[input_count++] = g.UseOperand(m.right().node(), operand_mode);

  if (cont->IsBranch()) {
    inputs[input_count++] = g.Label(cont->true_block());
    inputs[input_count++] = g.Label(cont->false_block());
  }

  outputs[output_count++] = g.DefineAsRegister(node);
  if (cont->IsSet()) {
    outputs[output_count++] = g.DefineAsRegister(cont->result());
  }

  DCHECK_NE(0, input_count);
  DCHECK_NE(0, output_count);
  DCHECK_GE(arraysize(inputs), input_count);
  DCHECK_GE(arraysize(outputs), output_count);

  Instruction* instr = selector->Emit(cont->Encode(opcode), output_count,
                                      outputs, input_count, inputs);
  if (cont->IsBranch()) instr->MarkAsControl();
}


// Shared routine for multiple binary operations.
template <typename Matcher>
static void VisitBinop(InstructionSelector* selector, Node* node,
                       ArchOpcode opcode, ImmediateMode operand_mode) {
  FlagsContinuation cont;
  VisitBinop<Matcher>(selector, node, opcode, operand_mode, &cont);
}


void InstructionSelector::VisitLoad(Node* node) {
  MachineType rep = RepresentationOf(OpParameter<LoadRepresentation>(node));
  MachineType typ = TypeOf(OpParameter<LoadRepresentation>(node));
  Arm64OperandGenerator g(this);
  Node* base = node->InputAt(0);
  Node* index = node->InputAt(1);
  ArchOpcode opcode;
  ImmediateMode immediate_mode = kNoImmediate;
  switch (rep) {
    case kRepFloat32:
      opcode = kArm64LdrS;
      immediate_mode = kLoadStoreImm32;
      break;
    case kRepFloat64:
      opcode = kArm64LdrD;
      immediate_mode = kLoadStoreImm64;
      break;
    case kRepBit:  // Fall through.
    case kRepWord8:
      opcode = typ == kTypeInt32 ? kArm64Ldrsb : kArm64Ldrb;
      immediate_mode = kLoadStoreImm8;
      break;
    case kRepWord16:
      opcode = typ == kTypeInt32 ? kArm64Ldrsh : kArm64Ldrh;
      immediate_mode = kLoadStoreImm16;
      break;
    case kRepWord32:
      opcode = kArm64LdrW;
      immediate_mode = kLoadStoreImm32;
      break;
    case kRepTagged:  // Fall through.
    case kRepWord64:
      opcode = kArm64Ldr;
      immediate_mode = kLoadStoreImm64;
      break;
    default:
      UNREACHABLE();
      return;
  }
  if (g.CanBeImmediate(index, immediate_mode)) {
    Emit(opcode | AddressingModeField::encode(kMode_MRI),
         g.DefineAsRegister(node), g.UseRegister(base), g.UseImmediate(index));
  } else {
    Emit(opcode | AddressingModeField::encode(kMode_MRR),
         g.DefineAsRegister(node), g.UseRegister(base), g.UseRegister(index));
  }
}


void InstructionSelector::VisitStore(Node* node) {
  Arm64OperandGenerator g(this);
  Node* base = node->InputAt(0);
  Node* index = node->InputAt(1);
  Node* value = node->InputAt(2);

  StoreRepresentation store_rep = OpParameter<StoreRepresentation>(node);
  MachineType rep = RepresentationOf(store_rep.machine_type());
  if (store_rep.write_barrier_kind() == kFullWriteBarrier) {
    DCHECK(rep == kRepTagged);
    // TODO(dcarney): refactor RecordWrite function to take temp registers
    //                and pass them here instead of using fixed regs
    // TODO(dcarney): handle immediate indices.
    InstructionOperand* temps[] = {g.TempRegister(x11), g.TempRegister(x12)};
    Emit(kArm64StoreWriteBarrier, NULL, g.UseFixed(base, x10),
         g.UseFixed(index, x11), g.UseFixed(value, x12), arraysize(temps),
         temps);
    return;
  }
  DCHECK_EQ(kNoWriteBarrier, store_rep.write_barrier_kind());
  ArchOpcode opcode;
  ImmediateMode immediate_mode = kNoImmediate;
  switch (rep) {
    case kRepFloat32:
      opcode = kArm64StrS;
      immediate_mode = kLoadStoreImm32;
      break;
    case kRepFloat64:
      opcode = kArm64StrD;
      immediate_mode = kLoadStoreImm64;
      break;
    case kRepBit:  // Fall through.
    case kRepWord8:
      opcode = kArm64Strb;
      immediate_mode = kLoadStoreImm8;
      break;
    case kRepWord16:
      opcode = kArm64Strh;
      immediate_mode = kLoadStoreImm16;
      break;
    case kRepWord32:
      opcode = kArm64StrW;
      immediate_mode = kLoadStoreImm32;
      break;
    case kRepTagged:  // Fall through.
    case kRepWord64:
      opcode = kArm64Str;
      immediate_mode = kLoadStoreImm64;
      break;
    default:
      UNREACHABLE();
      return;
  }
  if (g.CanBeImmediate(index, immediate_mode)) {
    Emit(opcode | AddressingModeField::encode(kMode_MRI), NULL,
         g.UseRegister(base), g.UseImmediate(index), g.UseRegister(value));
  } else {
    Emit(opcode | AddressingModeField::encode(kMode_MRR), NULL,
         g.UseRegister(base), g.UseRegister(index), g.UseRegister(value));
  }
}


template <typename Matcher>
static void VisitLogical(InstructionSelector* selector, Node* node, Matcher* m,
                         ArchOpcode opcode, bool left_can_cover,
                         bool right_can_cover, ImmediateMode imm_mode) {
  Arm64OperandGenerator g(selector);

  // Map instruction to equivalent operation with inverted right input.
  ArchOpcode inv_opcode = opcode;
  switch (opcode) {
    case kArm64And32:
      inv_opcode = kArm64Bic32;
      break;
    case kArm64And:
      inv_opcode = kArm64Bic;
      break;
    case kArm64Or32:
      inv_opcode = kArm64Orn32;
      break;
    case kArm64Or:
      inv_opcode = kArm64Orn;
      break;
    case kArm64Eor32:
      inv_opcode = kArm64Eon32;
      break;
    case kArm64Eor:
      inv_opcode = kArm64Eon;
      break;
    default:
      UNREACHABLE();
  }

  // Select Logical(y, ~x) for Logical(Xor(x, -1), y).
  if ((m->left().IsWord32Xor() || m->left().IsWord64Xor()) && left_can_cover) {
    Matcher mleft(m->left().node());
    if (mleft.right().Is(-1)) {
      // TODO(all): support shifted operand on right.
      selector->Emit(inv_opcode, g.DefineAsRegister(node),
                     g.UseRegister(m->right().node()),
                     g.UseRegister(mleft.left().node()));
      return;
    }
  }

  // Select Logical(x, ~y) for Logical(x, Xor(y, -1)).
  if ((m->right().IsWord32Xor() || m->right().IsWord64Xor()) &&
      right_can_cover) {
    Matcher mright(m->right().node());
    if (mright.right().Is(-1)) {
      // TODO(all): support shifted operand on right.
      selector->Emit(inv_opcode, g.DefineAsRegister(node),
                     g.UseRegister(m->left().node()),
                     g.UseRegister(mright.left().node()));
      return;
    }
  }

  if (m->IsWord32Xor() && m->right().Is(-1)) {
    selector->Emit(kArm64Not32, g.DefineAsRegister(node),
                   g.UseRegister(m->left().node()));
  } else if (m->IsWord64Xor() && m->right().Is(-1)) {
    selector->Emit(kArm64Not, g.DefineAsRegister(node),
                   g.UseRegister(m->left().node()));
  } else {
    VisitBinop<Matcher>(selector, node, opcode, imm_mode);
  }
}


void InstructionSelector::VisitWord32And(Node* node) {
  Int32BinopMatcher m(node);
  VisitLogical<Int32BinopMatcher>(
      this, node, &m, kArm64And32, CanCover(node, m.left().node()),
      CanCover(node, m.right().node()), kLogical32Imm);
}


void InstructionSelector::VisitWord64And(Node* node) {
  Int64BinopMatcher m(node);
  VisitLogical<Int64BinopMatcher>(
      this, node, &m, kArm64And, CanCover(node, m.left().node()),
      CanCover(node, m.right().node()), kLogical64Imm);
}


void InstructionSelector::VisitWord32Or(Node* node) {
  Int32BinopMatcher m(node);
  VisitLogical<Int32BinopMatcher>(
      this, node, &m, kArm64Or32, CanCover(node, m.left().node()),
      CanCover(node, m.right().node()), kLogical32Imm);
}


void InstructionSelector::VisitWord64Or(Node* node) {
  Int64BinopMatcher m(node);
  VisitLogical<Int64BinopMatcher>(
      this, node, &m, kArm64Or, CanCover(node, m.left().node()),
      CanCover(node, m.right().node()), kLogical64Imm);
}


void InstructionSelector::VisitWord32Xor(Node* node) {
  Int32BinopMatcher m(node);
  VisitLogical<Int32BinopMatcher>(
      this, node, &m, kArm64Eor32, CanCover(node, m.left().node()),
      CanCover(node, m.right().node()), kLogical32Imm);
}


void InstructionSelector::VisitWord64Xor(Node* node) {
  Int64BinopMatcher m(node);
  VisitLogical<Int64BinopMatcher>(
      this, node, &m, kArm64Eor, CanCover(node, m.left().node()),
      CanCover(node, m.right().node()), kLogical64Imm);
}


void InstructionSelector::VisitWord32Shl(Node* node) {
  VisitRRO(this, kArm64Shl32, node, kShift32Imm);
}


void InstructionSelector::VisitWord64Shl(Node* node) {
  VisitRRO(this, kArm64Shl, node, kShift64Imm);
}


void InstructionSelector::VisitWord32Shr(Node* node) {
  VisitRRO(this, kArm64Shr32, node, kShift32Imm);
}


void InstructionSelector::VisitWord64Shr(Node* node) {
  VisitRRO(this, kArm64Shr, node, kShift64Imm);
}


void InstructionSelector::VisitWord32Sar(Node* node) {
  VisitRRO(this, kArm64Sar32, node, kShift32Imm);
}


void InstructionSelector::VisitWord64Sar(Node* node) {
  VisitRRO(this, kArm64Sar, node, kShift64Imm);
}


void InstructionSelector::VisitWord32Ror(Node* node) {
  VisitRRO(this, kArm64Ror32, node, kShift32Imm);
}


void InstructionSelector::VisitWord64Ror(Node* node) {
  VisitRRO(this, kArm64Ror, node, kShift64Imm);
}


void InstructionSelector::VisitInt32Add(Node* node) {
  Arm64OperandGenerator g(this);
  Int32BinopMatcher m(node);
  // Select Madd(x, y, z) for Add(Mul(x, y), z).
  if (m.left().IsInt32Mul() && CanCover(node, m.left().node())) {
    Int32BinopMatcher mleft(m.left().node());
    Emit(kArm64Madd32, g.DefineAsRegister(node),
         g.UseRegister(mleft.left().node()),
         g.UseRegister(mleft.right().node()), g.UseRegister(m.right().node()));
    return;
  }
  // Select Madd(x, y, z) for Add(x, Mul(x, y)).
  if (m.right().IsInt32Mul() && CanCover(node, m.right().node())) {
    Int32BinopMatcher mright(m.right().node());
    Emit(kArm64Madd32, g.DefineAsRegister(node),
         g.UseRegister(mright.left().node()),
         g.UseRegister(mright.right().node()), g.UseRegister(m.left().node()));
    return;
  }
  VisitBinop<Int32BinopMatcher>(this, node, kArm64Add32, kArithmeticImm);
}


void InstructionSelector::VisitInt64Add(Node* node) {
  Arm64OperandGenerator g(this);
  Int64BinopMatcher m(node);
  // Select Madd(x, y, z) for Add(Mul(x, y), z).
  if (m.left().IsInt64Mul() && CanCover(node, m.left().node())) {
    Int64BinopMatcher mleft(m.left().node());
    Emit(kArm64Madd, g.DefineAsRegister(node),
         g.UseRegister(mleft.left().node()),
         g.UseRegister(mleft.right().node()), g.UseRegister(m.right().node()));
    return;
  }
  // Select Madd(x, y, z) for Add(x, Mul(x, y)).
  if (m.right().IsInt64Mul() && CanCover(node, m.right().node())) {
    Int64BinopMatcher mright(m.right().node());
    Emit(kArm64Madd, g.DefineAsRegister(node),
         g.UseRegister(mright.left().node()),
         g.UseRegister(mright.right().node()), g.UseRegister(m.left().node()));
    return;
  }
  VisitBinop<Int64BinopMatcher>(this, node, kArm64Add, kArithmeticImm);
}


void InstructionSelector::VisitInt32Sub(Node* node) {
  Arm64OperandGenerator g(this);
  Int32BinopMatcher m(node);

  // Select Msub(a, x, y) for Sub(a, Mul(x, y)).
  if (m.right().IsInt32Mul() && CanCover(node, m.right().node())) {
    Int32BinopMatcher mright(m.right().node());
    Emit(kArm64Msub32, g.DefineAsRegister(node),
         g.UseRegister(mright.left().node()),
         g.UseRegister(mright.right().node()), g.UseRegister(m.left().node()));
    return;
  }

  if (m.left().Is(0)) {
    Emit(kArm64Neg32, g.DefineAsRegister(node),
         g.UseRegister(m.right().node()));
  } else {
    VisitBinop<Int32BinopMatcher>(this, node, kArm64Sub32, kArithmeticImm);
  }
}


void InstructionSelector::VisitInt64Sub(Node* node) {
  Arm64OperandGenerator g(this);
  Int64BinopMatcher m(node);

  // Select Msub(a, x, y) for Sub(a, Mul(x, y)).
  if (m.right().IsInt64Mul() && CanCover(node, m.right().node())) {
    Int64BinopMatcher mright(m.right().node());
    Emit(kArm64Msub, g.DefineAsRegister(node),
         g.UseRegister(mright.left().node()),
         g.UseRegister(mright.right().node()), g.UseRegister(m.left().node()));
    return;
  }

  if (m.left().Is(0)) {
    Emit(kArm64Neg, g.DefineAsRegister(node), g.UseRegister(m.right().node()));
  } else {
    VisitBinop<Int64BinopMatcher>(this, node, kArm64Sub, kArithmeticImm);
  }
}


void InstructionSelector::VisitInt32Mul(Node* node) {
  Arm64OperandGenerator g(this);
  Int32BinopMatcher m(node);

  if (m.left().IsInt32Sub() && CanCover(node, m.left().node())) {
    Int32BinopMatcher mleft(m.left().node());

    // Select Mneg(x, y) for Mul(Sub(0, x), y).
    if (mleft.left().Is(0)) {
      Emit(kArm64Mneg32, g.DefineAsRegister(node),
           g.UseRegister(mleft.right().node()),
           g.UseRegister(m.right().node()));
      return;
    }
  }

  if (m.right().IsInt32Sub() && CanCover(node, m.right().node())) {
    Int32BinopMatcher mright(m.right().node());

    // Select Mneg(x, y) for Mul(x, Sub(0, y)).
    if (mright.left().Is(0)) {
      Emit(kArm64Mneg32, g.DefineAsRegister(node),
           g.UseRegister(m.left().node()),
           g.UseRegister(mright.right().node()));
      return;
    }
  }

  VisitRRR(this, kArm64Mul32, node);
}


void InstructionSelector::VisitInt64Mul(Node* node) {
  Arm64OperandGenerator g(this);
  Int64BinopMatcher m(node);

  if (m.left().IsInt64Sub() && CanCover(node, m.left().node())) {
    Int64BinopMatcher mleft(m.left().node());

    // Select Mneg(x, y) for Mul(Sub(0, x), y).
    if (mleft.left().Is(0)) {
      Emit(kArm64Mneg, g.DefineAsRegister(node),
           g.UseRegister(mleft.right().node()),
           g.UseRegister(m.right().node()));
      return;
    }
  }

  if (m.right().IsInt64Sub() && CanCover(node, m.right().node())) {
    Int64BinopMatcher mright(m.right().node());

    // Select Mneg(x, y) for Mul(x, Sub(0, y)).
    if (mright.left().Is(0)) {
      Emit(kArm64Mneg, g.DefineAsRegister(node), g.UseRegister(m.left().node()),
           g.UseRegister(mright.right().node()));
      return;
    }
  }

  VisitRRR(this, kArm64Mul, node);
}


void InstructionSelector::VisitInt32Div(Node* node) {
  VisitRRR(this, kArm64Idiv32, node);
}


void InstructionSelector::VisitInt64Div(Node* node) {
  VisitRRR(this, kArm64Idiv, node);
}


void InstructionSelector::VisitInt32UDiv(Node* node) {
  VisitRRR(this, kArm64Udiv32, node);
}


void InstructionSelector::VisitInt64UDiv(Node* node) {
  VisitRRR(this, kArm64Udiv, node);
}


void InstructionSelector::VisitInt32Mod(Node* node) {
  VisitRRR(this, kArm64Imod32, node);
}


void InstructionSelector::VisitInt64Mod(Node* node) {
  VisitRRR(this, kArm64Imod, node);
}


void InstructionSelector::VisitInt32UMod(Node* node) {
  VisitRRR(this, kArm64Umod32, node);
}


void InstructionSelector::VisitInt64UMod(Node* node) {
  VisitRRR(this, kArm64Umod, node);
}


void InstructionSelector::VisitChangeFloat32ToFloat64(Node* node) {
  Arm64OperandGenerator g(this);
  Emit(kArm64Float32ToFloat64, g.DefineAsRegister(node),
       g.UseRegister(node->InputAt(0)));
}


void InstructionSelector::VisitChangeInt32ToFloat64(Node* node) {
  Arm64OperandGenerator g(this);
  Emit(kArm64Int32ToFloat64, g.DefineAsRegister(node),
       g.UseRegister(node->InputAt(0)));
}


void InstructionSelector::VisitChangeUint32ToFloat64(Node* node) {
  Arm64OperandGenerator g(this);
  Emit(kArm64Uint32ToFloat64, g.DefineAsRegister(node),
       g.UseRegister(node->InputAt(0)));
}


void InstructionSelector::VisitChangeFloat64ToInt32(Node* node) {
  Arm64OperandGenerator g(this);
  Emit(kArm64Float64ToInt32, g.DefineAsRegister(node),
       g.UseRegister(node->InputAt(0)));
}


void InstructionSelector::VisitChangeFloat64ToUint32(Node* node) {
  Arm64OperandGenerator g(this);
  Emit(kArm64Float64ToUint32, g.DefineAsRegister(node),
       g.UseRegister(node->InputAt(0)));
}


void InstructionSelector::VisitChangeInt32ToInt64(Node* node) {
  Arm64OperandGenerator g(this);
  Emit(kArm64Sxtw, g.DefineAsRegister(node), g.UseRegister(node->InputAt(0)));
}


void InstructionSelector::VisitChangeUint32ToUint64(Node* node) {
  Arm64OperandGenerator g(this);
  Emit(kArm64Mov32, g.DefineAsRegister(node), g.UseRegister(node->InputAt(0)));
}


void InstructionSelector::VisitTruncateFloat64ToFloat32(Node* node) {
  Arm64OperandGenerator g(this);
  Emit(kArm64Float64ToFloat32, g.DefineAsRegister(node),
       g.UseRegister(node->InputAt(0)));
}


void InstructionSelector::VisitTruncateInt64ToInt32(Node* node) {
  Arm64OperandGenerator g(this);
  Emit(kArm64Mov32, g.DefineAsRegister(node), g.UseRegister(node->InputAt(0)));
}


void InstructionSelector::VisitFloat64Add(Node* node) {
  VisitRRRFloat64(this, kArm64Float64Add, node);
}


void InstructionSelector::VisitFloat64Sub(Node* node) {
  VisitRRRFloat64(this, kArm64Float64Sub, node);
}


void InstructionSelector::VisitFloat64Mul(Node* node) {
  VisitRRRFloat64(this, kArm64Float64Mul, node);
}


void InstructionSelector::VisitFloat64Div(Node* node) {
  VisitRRRFloat64(this, kArm64Float64Div, node);
}


void InstructionSelector::VisitFloat64Mod(Node* node) {
  Arm64OperandGenerator g(this);
  Emit(kArm64Float64Mod, g.DefineAsFixed(node, d0),
       g.UseFixed(node->InputAt(0), d0),
       g.UseFixed(node->InputAt(1), d1))->MarkAsCall();
}


void InstructionSelector::VisitFloat64Sqrt(Node* node) {
  Arm64OperandGenerator g(this);
  Emit(kArm64Float64Sqrt, g.DefineAsRegister(node),
       g.UseRegister(node->InputAt(0)));
}


void InstructionSelector::VisitInt32AddWithOverflow(Node* node,
                                                    FlagsContinuation* cont) {
  VisitBinop<Int32BinopMatcher>(this, node, kArm64Add32, kArithmeticImm, cont);
}


void InstructionSelector::VisitInt32SubWithOverflow(Node* node,
                                                    FlagsContinuation* cont) {
  VisitBinop<Int32BinopMatcher>(this, node, kArm64Sub32, kArithmeticImm, cont);
}


// Shared routine for multiple compare operations.
static void VisitCompare(InstructionSelector* selector, InstructionCode opcode,
                         InstructionOperand* left, InstructionOperand* right,
                         FlagsContinuation* cont) {
  Arm64OperandGenerator g(selector);
  opcode = cont->Encode(opcode);
  if (cont->IsBranch()) {
    selector->Emit(opcode, NULL, left, right, g.Label(cont->true_block()),
                   g.Label(cont->false_block()))->MarkAsControl();
  } else {
    DCHECK(cont->IsSet());
    selector->Emit(opcode, g.DefineAsRegister(cont->result()), left, right);
  }
}


// Shared routine for multiple word compare operations.
static void VisitWordCompare(InstructionSelector* selector, Node* node,
                             InstructionCode opcode, FlagsContinuation* cont,
                             bool commutative) {
  Arm64OperandGenerator g(selector);
  Node* left = node->InputAt(0);
  Node* right = node->InputAt(1);

  // Match immediates on left or right side of comparison.
  if (g.CanBeImmediate(right, kArithmeticImm)) {
    VisitCompare(selector, opcode, g.UseRegister(left), g.UseImmediate(right),
                 cont);
  } else if (g.CanBeImmediate(left, kArithmeticImm)) {
    if (!commutative) cont->Commute();
    VisitCompare(selector, opcode, g.UseRegister(right), g.UseImmediate(left),
                 cont);
  } else {
    VisitCompare(selector, opcode, g.UseRegister(left), g.UseRegister(right),
                 cont);
  }
}


void InstructionSelector::VisitWord32Test(Node* node, FlagsContinuation* cont) {
  switch (node->opcode()) {
    case IrOpcode::kInt32Add:
      return VisitWordCompare(this, node, kArm64Cmn32, cont, true);
    case IrOpcode::kInt32Sub:
      return VisitWordCompare(this, node, kArm64Cmp32, cont, false);
    case IrOpcode::kWord32And:
      return VisitWordCompare(this, node, kArm64Tst32, cont, true);
    default:
      break;
  }

  Arm64OperandGenerator g(this);
  VisitCompare(this, kArm64Tst32, g.UseRegister(node), g.UseRegister(node),
               cont);
}


void InstructionSelector::VisitWord64Test(Node* node, FlagsContinuation* cont) {
  switch (node->opcode()) {
    case IrOpcode::kWord64And:
      return VisitWordCompare(this, node, kArm64Tst, cont, true);
    default:
      break;
  }

  Arm64OperandGenerator g(this);
  VisitCompare(this, kArm64Tst, g.UseRegister(node), g.UseRegister(node), cont);
}


void InstructionSelector::VisitWord32Compare(Node* node,
                                             FlagsContinuation* cont) {
  VisitWordCompare(this, node, kArm64Cmp32, cont, false);
}


void InstructionSelector::VisitWord64Compare(Node* node,
                                             FlagsContinuation* cont) {
  VisitWordCompare(this, node, kArm64Cmp, cont, false);
}


void InstructionSelector::VisitFloat64Compare(Node* node,
                                              FlagsContinuation* cont) {
  Arm64OperandGenerator g(this);
  Node* left = node->InputAt(0);
  Node* right = node->InputAt(1);
  VisitCompare(this, kArm64Float64Cmp, g.UseRegister(left),
               g.UseRegister(right), cont);
}


void InstructionSelector::VisitCall(Node* call, BasicBlock* continuation,
                                    BasicBlock* deoptimization) {
  Arm64OperandGenerator g(this);
  CallDescriptor* descriptor = OpParameter<CallDescriptor*>(call);

  FrameStateDescriptor* frame_state_descriptor = NULL;
  if (descriptor->NeedsFrameState()) {
    frame_state_descriptor =
        GetFrameStateDescriptor(call->InputAt(descriptor->InputCount()));
  }

  CallBuffer buffer(zone(), descriptor, frame_state_descriptor);

  // Compute InstructionOperands for inputs and outputs.
  // TODO(turbofan): on ARM64 it's probably better to use the code object in a
  // register if there are multiple uses of it. Improve constant pool and the
  // heuristics in the register allocator for where to emit constants.
  InitializeCallBuffer(call, &buffer, true, false);

  // Push the arguments to the stack.
  bool pushed_count_uneven = buffer.pushed_nodes.size() & 1;
  int aligned_push_count = buffer.pushed_nodes.size();
  // TODO(dcarney): claim and poke probably take small immediates,
  //                loop here or whatever.
  // Bump the stack pointer(s).
  if (aligned_push_count > 0) {
    // TODO(dcarney): it would be better to bump the csp here only
    //                and emit paired stores with increment for non c frames.
    Emit(kArm64Claim | MiscField::encode(aligned_push_count), NULL);
  }
  // Move arguments to the stack.
  {
    int slot = buffer.pushed_nodes.size() - 1;
    // Emit the uneven pushes.
    if (pushed_count_uneven) {
      Node* input = buffer.pushed_nodes[slot];
      Emit(kArm64Poke | MiscField::encode(slot), NULL, g.UseRegister(input));
      slot--;
    }
    // Now all pushes can be done in pairs.
    for (; slot >= 0; slot -= 2) {
      Emit(kArm64PokePair | MiscField::encode(slot), NULL,
           g.UseRegister(buffer.pushed_nodes[slot]),
           g.UseRegister(buffer.pushed_nodes[slot - 1]));
    }
  }

  // Select the appropriate opcode based on the call type.
  InstructionCode opcode;
  switch (descriptor->kind()) {
    case CallDescriptor::kCallCodeObject: {
      opcode = kArchCallCodeObject;
      break;
    }
    case CallDescriptor::kCallJSFunction:
      opcode = kArchCallJSFunction;
      break;
    default:
      UNREACHABLE();
      return;
  }
  opcode |= MiscField::encode(descriptor->flags());

  // Emit the call instruction.
  Instruction* call_instr =
      Emit(opcode, buffer.outputs.size(), &buffer.outputs.front(),
           buffer.instruction_args.size(), &buffer.instruction_args.front());

  call_instr->MarkAsCall();
  if (deoptimization != NULL) {
    DCHECK(continuation != NULL);
    call_instr->MarkAsControl();
  }
}

}  // namespace compiler
}  // namespace internal
}  // namespace v8