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chromium / external / v8 / master / . / src / compiler / mips / instruction-selector-mips.cc
blob: 4862e986046f16bae1a7893d9bdb37adfef76349 [file] [log] [blame]
// 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/base/bits.h"
#include "src/compiler/instruction-selector-impl.h"
#include "src/compiler/node-matchers.h"
namespace v8 {
namespace internal {
namespace compiler {
#define TRACE_UNIMPL() \
PrintF("UNIMPLEMENTED instr_sel: %s at line %d\n", __FUNCTION__, __LINE__)
#define TRACE() PrintF("instr_sel: %s at line %d\n", __FUNCTION__, __LINE__)
// Adds Mips-specific methods for generating InstructionOperands.
class MipsOperandGenerator FINAL : public OperandGenerator {
public:
explicit MipsOperandGenerator(InstructionSelector* selector)
: OperandGenerator(selector) {}
InstructionOperand* UseOperand(Node* node, InstructionCode opcode) {
if (CanBeImmediate(node, opcode)) {
return UseImmediate(node);
}
return UseRegister(node);
}
bool CanBeImmediate(Node* node, InstructionCode opcode) {
Int32Matcher m(node);
if (!m.HasValue()) return false;
int32_t value = m.Value();
switch (ArchOpcodeField::decode(opcode)) {
case kMipsShl:
case kMipsSar:
case kMipsShr:
return is_uint5(value);
case kMipsXor:
return is_uint16(value);
case kMipsLdc1:
case kMipsSdc1:
return is_int16(value + kIntSize);
default:
return is_int16(value);
}
}
private:
bool ImmediateFitsAddrMode1Instruction(int32_t imm) const {
TRACE_UNIMPL();
return false;
}
};
static void VisitRRR(InstructionSelector* selector, ArchOpcode opcode,
Node* node) {
MipsOperandGenerator 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) {
MipsOperandGenerator g(selector);
selector->Emit(opcode, g.DefineAsRegister(node),
g.UseRegister(node->InputAt(0)),
g.UseOperand(node->InputAt(1), opcode));
}
static void VisitBinop(InstructionSelector* selector, Node* node,
InstructionCode opcode, FlagsContinuation* cont) {
MipsOperandGenerator g(selector);
Int32BinopMatcher 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(), opcode);
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();
}
static void VisitBinop(InstructionSelector* selector, Node* node,
InstructionCode opcode) {
FlagsContinuation cont;
VisitBinop(selector, node, opcode, &cont);
}
void InstructionSelector::VisitLoad(Node* node) {
MachineType rep = RepresentationOf(OpParameter<LoadRepresentation>(node));
MachineType typ = TypeOf(OpParameter<LoadRepresentation>(node));
MipsOperandGenerator g(this);
Node* base = node->InputAt(0);
Node* index = node->InputAt(1);
ArchOpcode opcode;
switch (rep) {
case kRepFloat32:
opcode = kMipsLwc1;
break;
case kRepFloat64:
opcode = kMipsLdc1;
break;
case kRepBit: // Fall through.
case kRepWord8:
opcode = typ == kTypeUint32 ? kMipsLbu : kMipsLb;
break;
case kRepWord16:
opcode = typ == kTypeUint32 ? kMipsLhu : kMipsLh;
break;
case kRepTagged: // Fall through.
case kRepWord32:
opcode = kMipsLw;
break;
default:
UNREACHABLE();
return;
}
if (g.CanBeImmediate(index, opcode)) {
Emit(opcode | AddressingModeField::encode(kMode_MRI),
g.DefineAsRegister(node), g.UseRegister(base), g.UseImmediate(index));
} else {
InstructionOperand* addr_reg = g.TempRegister();
Emit(kMipsAdd | AddressingModeField::encode(kMode_None), addr_reg,
g.UseRegister(index), g.UseRegister(base));
// Emit desired load opcode, using temp addr_reg.
Emit(opcode | AddressingModeField::encode(kMode_MRI),
g.DefineAsRegister(node), addr_reg, g.TempImmediate(0));
}
}
void InstructionSelector::VisitStore(Node* node) {
MipsOperandGenerator 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(t1), g.TempRegister(t2)};
Emit(kMipsStoreWriteBarrier, NULL, g.UseFixed(base, t0),
g.UseFixed(index, t1), g.UseFixed(value, t2), arraysize(temps), temps);
return;
}
DCHECK_EQ(kNoWriteBarrier, store_rep.write_barrier_kind());
ArchOpcode opcode;
switch (rep) {
case kRepFloat32:
opcode = kMipsSwc1;
break;
case kRepFloat64:
opcode = kMipsSdc1;
break;
case kRepBit: // Fall through.
case kRepWord8:
opcode = kMipsSb;
break;
case kRepWord16:
opcode = kMipsSh;
break;
case kRepTagged: // Fall through.
case kRepWord32:
opcode = kMipsSw;
break;
default:
UNREACHABLE();
return;
}
if (g.CanBeImmediate(index, opcode)) {
Emit(opcode | AddressingModeField::encode(kMode_MRI), NULL,
g.UseRegister(base), g.UseImmediate(index), g.UseRegister(value));
} else {
InstructionOperand* addr_reg = g.TempRegister();
Emit(kMipsAdd | AddressingModeField::encode(kMode_None), addr_reg,
g.UseRegister(index), g.UseRegister(base));
// Emit desired store opcode, using temp addr_reg.
Emit(opcode | AddressingModeField::encode(kMode_MRI), NULL, addr_reg,
g.TempImmediate(0), g.UseRegister(value));
}
}
void InstructionSelector::VisitWord32And(Node* node) {
VisitBinop(this, node, kMipsAnd);
}
void InstructionSelector::VisitWord32Or(Node* node) {
VisitBinop(this, node, kMipsOr);
}
void InstructionSelector::VisitWord32Xor(Node* node) {
VisitBinop(this, node, kMipsXor);
}
void InstructionSelector::VisitWord32Shl(Node* node) {
VisitRRO(this, kMipsShl, node);
}
void InstructionSelector::VisitWord32Shr(Node* node) {
VisitRRO(this, kMipsShr, node);
}
void InstructionSelector::VisitWord32Sar(Node* node) {
VisitRRO(this, kMipsSar, node);
}
void InstructionSelector::VisitWord32Ror(Node* node) {
VisitRRO(this, kMipsRor, node);
}
void InstructionSelector::VisitInt32Add(Node* node) {
MipsOperandGenerator g(this);
// TODO(plind): Consider multiply & add optimization from arm port.
VisitBinop(this, node, kMipsAdd);
}
void InstructionSelector::VisitInt32Sub(Node* node) {
VisitBinop(this, node, kMipsSub);
}
void InstructionSelector::VisitInt32Mul(Node* node) {
MipsOperandGenerator g(this);
Int32BinopMatcher m(node);
if (m.right().HasValue() && m.right().Value() > 0) {
int32_t value = m.right().Value();
if (base::bits::IsPowerOfTwo32(value)) {
Emit(kMipsShl | AddressingModeField::encode(kMode_None),
g.DefineAsRegister(node), g.UseRegister(m.left().node()),
g.TempImmediate(WhichPowerOf2(value)));
return;
}
if (base::bits::IsPowerOfTwo32(value - 1)) {
InstructionOperand* temp = g.TempRegister();
Emit(kMipsShl | AddressingModeField::encode(kMode_None), temp,
g.UseRegister(m.left().node()),
g.TempImmediate(WhichPowerOf2(value - 1)));
Emit(kMipsAdd | AddressingModeField::encode(kMode_None),
g.DefineAsRegister(node), g.UseRegister(m.left().node()), temp);
return;
}
if (base::bits::IsPowerOfTwo32(value + 1)) {
InstructionOperand* temp = g.TempRegister();
Emit(kMipsShl | AddressingModeField::encode(kMode_None), temp,
g.UseRegister(m.left().node()),
g.TempImmediate(WhichPowerOf2(value + 1)));
Emit(kMipsSub | AddressingModeField::encode(kMode_None),
g.DefineAsRegister(node), temp, g.UseRegister(m.left().node()));
return;
}
}
Emit(kMipsMul, g.DefineAsRegister(node), g.UseRegister(m.left().node()),
g.UseRegister(m.right().node()));
}
void InstructionSelector::VisitInt32MulHigh(Node* node) {
MipsOperandGenerator g(this);
Emit(kMipsMulHigh, g.DefineAsRegister(node), g.UseRegister(node->InputAt(0)),
g.UseRegister(node->InputAt(1)));
}
void InstructionSelector::VisitUint32MulHigh(Node* node) {
MipsOperandGenerator g(this);
Emit(kMipsMulHighU, g.DefineAsRegister(node), g.UseRegister(node->InputAt(0)),
g.UseRegister(node->InputAt(1)));
}
void InstructionSelector::VisitInt32Div(Node* node) {
MipsOperandGenerator g(this);
Int32BinopMatcher m(node);
Emit(kMipsDiv, g.DefineAsRegister(node), g.UseRegister(m.left().node()),
g.UseRegister(m.right().node()));
}
void InstructionSelector::VisitUint32Div(Node* node) {
MipsOperandGenerator g(this);
Int32BinopMatcher m(node);
Emit(kMipsDivU, g.DefineAsRegister(node), g.UseRegister(m.left().node()),
g.UseRegister(m.right().node()));
}
void InstructionSelector::VisitInt32Mod(Node* node) {
MipsOperandGenerator g(this);
Int32BinopMatcher m(node);
Emit(kMipsMod, g.DefineAsRegister(node), g.UseRegister(m.left().node()),
g.UseRegister(m.right().node()));
}
void InstructionSelector::VisitUint32Mod(Node* node) {
MipsOperandGenerator g(this);
Int32BinopMatcher m(node);
Emit(kMipsModU, g.DefineAsRegister(node), g.UseRegister(m.left().node()),
g.UseRegister(m.right().node()));
}
void InstructionSelector::VisitChangeFloat32ToFloat64(Node* node) {
MipsOperandGenerator g(this);
Emit(kMipsCvtDS, g.DefineAsRegister(node), g.UseRegister(node->InputAt(0)));
}
void InstructionSelector::VisitChangeInt32ToFloat64(Node* node) {
MipsOperandGenerator g(this);
Emit(kMipsCvtDW, g.DefineAsRegister(node), g.UseRegister(node->InputAt(0)));
}
void InstructionSelector::VisitChangeUint32ToFloat64(Node* node) {
MipsOperandGenerator g(this);
Emit(kMipsCvtDUw, g.DefineAsRegister(node), g.UseRegister(node->InputAt(0)));
}
void InstructionSelector::VisitChangeFloat64ToInt32(Node* node) {
MipsOperandGenerator g(this);
Emit(kMipsTruncWD, g.DefineAsRegister(node), g.UseRegister(node->InputAt(0)));
}
void InstructionSelector::VisitChangeFloat64ToUint32(Node* node) {
MipsOperandGenerator g(this);
Emit(kMipsTruncUwD, g.DefineAsRegister(node),
g.UseRegister(node->InputAt(0)));
}
void InstructionSelector::VisitTruncateFloat64ToFloat32(Node* node) {
MipsOperandGenerator g(this);
Emit(kMipsCvtSD, g.DefineAsRegister(node), g.UseRegister(node->InputAt(0)));
}
void InstructionSelector::VisitFloat64Add(Node* node) {
VisitRRR(this, kMipsAddD, node);
}
void InstructionSelector::VisitFloat64Sub(Node* node) {
VisitRRR(this, kMipsSubD, node);
}
void InstructionSelector::VisitFloat64Mul(Node* node) {
VisitRRR(this, kMipsMulD, node);
}
void InstructionSelector::VisitFloat64Div(Node* node) {
VisitRRR(this, kMipsDivD, node);
}
void InstructionSelector::VisitFloat64Mod(Node* node) {
MipsOperandGenerator g(this);
Emit(kMipsModD, g.DefineAsFixed(node, f0), g.UseFixed(node->InputAt(0), f12),
g.UseFixed(node->InputAt(1), f14))->MarkAsCall();
}
void InstructionSelector::VisitFloat64Sqrt(Node* node) {
MipsOperandGenerator g(this);
Emit(kMipsSqrtD, g.DefineAsRegister(node), g.UseRegister(node->InputAt(0)));
}
void InstructionSelector::VisitFloat64Floor(Node* node) { UNREACHABLE(); }
void InstructionSelector::VisitFloat64Ceil(Node* node) { UNREACHABLE(); }
void InstructionSelector::VisitFloat64RoundTruncate(Node* node) {
UNREACHABLE();
}
void InstructionSelector::VisitFloat64RoundTiesAway(Node* node) {
UNREACHABLE();
}
void InstructionSelector::VisitCall(Node* node) {
MipsOperandGenerator g(this);
CallDescriptor* descriptor = OpParameter<CallDescriptor*>(node);
FrameStateDescriptor* frame_state_descriptor = NULL;
if (descriptor->NeedsFrameState()) {
frame_state_descriptor =
GetFrameStateDescriptor(node->InputAt(descriptor->InputCount()));
}
CallBuffer buffer(zone(), descriptor, frame_state_descriptor);
// Compute InstructionOperands for inputs and outputs.
InitializeCallBuffer(node, &buffer, true, false);
// TODO(dcarney): might be possible to use claim/poke instead
// Push any stack arguments.
for (NodeVectorRIter input = buffer.pushed_nodes.rbegin();
input != buffer.pushed_nodes.rend(); input++) {
// TODO(plind): inefficient for MIPS, use MultiPush here.
// - Also need to align the stack. See arm64.
// - Maybe combine with arg slot stuff in DirectCEntry stub.
Emit(kMipsPush, NULL, g.UseRegister(*input));
}
// 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.
InstructionOperand** first_output =
buffer.outputs.size() > 0 ? &buffer.outputs.front() : NULL;
Instruction* call_instr =
Emit(opcode, buffer.outputs.size(), first_output,
buffer.instruction_args.size(), &buffer.instruction_args.front());
call_instr->MarkAsCall();
}
namespace {
// Shared routine for multiple compare operations.
static void VisitCompare(InstructionSelector* selector, InstructionCode opcode,
InstructionOperand* left, InstructionOperand* right,
FlagsContinuation* cont) {
MipsOperandGenerator 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());
// TODO(plind): Revisit and test this path.
selector->Emit(opcode, g.DefineAsRegister(cont->result()), left, right);
}
}
// Shared routine for multiple float compare operations.
void VisitFloat64Compare(InstructionSelector* selector, Node* node,
FlagsContinuation* cont) {
MipsOperandGenerator g(selector);
Node* left = node->InputAt(0);
Node* right = node->InputAt(1);
VisitCompare(selector, kMipsCmpD, g.UseRegister(left), g.UseRegister(right),
cont);
}
// Shared routine for multiple word compare operations.
void VisitWordCompare(InstructionSelector* selector, Node* node,
InstructionCode opcode, FlagsContinuation* cont,
bool commutative) {
MipsOperandGenerator 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, opcode)) {
VisitCompare(selector, opcode, g.UseRegister(left), g.UseImmediate(right),
cont);
} else if (g.CanBeImmediate(left, opcode)) {
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 VisitWordCompare(InstructionSelector* selector, Node* node,
FlagsContinuation* cont) {
VisitWordCompare(selector, node, kMipsCmp, cont, false);
}
} // namespace
// Shared routine for word comparisons against zero.
void VisitWordCompareZero(InstructionSelector* selector, Node* user,
Node* value, FlagsContinuation* cont) {
while (selector->CanCover(user, value)) {
switch (value->opcode()) {
case IrOpcode::kWord32Equal: {
// Combine with comparisons against 0 by simply inverting the
// continuation.
Int32BinopMatcher m(value);
if (m.right().Is(0)) {
user = value;
value = m.left().node();
cont->Negate();
continue;
}
cont->OverwriteAndNegateIfEqual(kEqual);
return VisitWordCompare(selector, value, cont);
}
case IrOpcode::kInt32LessThan:
cont->OverwriteAndNegateIfEqual(kSignedLessThan);
return VisitWordCompare(selector, value, cont);
case IrOpcode::kInt32LessThanOrEqual:
cont->OverwriteAndNegateIfEqual(kSignedLessThanOrEqual);
return VisitWordCompare(selector, value, cont);
case IrOpcode::kUint32LessThan:
cont->OverwriteAndNegateIfEqual(kUnsignedLessThan);
return VisitWordCompare(selector, value, cont);
case IrOpcode::kUint32LessThanOrEqual:
cont->OverwriteAndNegateIfEqual(kUnsignedLessThanOrEqual);
return VisitWordCompare(selector, value, cont);
case IrOpcode::kFloat64Equal:
cont->OverwriteAndNegateIfEqual(kUnorderedEqual);
return VisitFloat64Compare(selector, value, cont);
case IrOpcode::kFloat64LessThan:
cont->OverwriteAndNegateIfEqual(kUnorderedLessThan);
return VisitFloat64Compare(selector, value, cont);
case IrOpcode::kFloat64LessThanOrEqual:
cont->OverwriteAndNegateIfEqual(kUnorderedLessThanOrEqual);
return VisitFloat64Compare(selector, value, cont);
case IrOpcode::kProjection:
// Check if this is the overflow output projection of an
// <Operation>WithOverflow node.
if (OpParameter<size_t>(value) == 1u) {
// We cannot combine the <Operation>WithOverflow with this branch
// unless the 0th projection (the use of the actual value of the
// <Operation> is either NULL, which means there's no use of the
// actual value, or was already defined, which means it is scheduled
// *AFTER* this branch).
Node* const node = value->InputAt(0);
Node* const result = node->FindProjection(0);
if (!result || selector->IsDefined(result)) {
switch (node->opcode()) {
case IrOpcode::kInt32AddWithOverflow:
cont->OverwriteAndNegateIfEqual(kOverflow);
return VisitBinop(selector, node, kMipsAddOvf, cont);
case IrOpcode::kInt32SubWithOverflow:
cont->OverwriteAndNegateIfEqual(kOverflow);
return VisitBinop(selector, node, kMipsSubOvf, cont);
default:
break;
}
}
}
break;
case IrOpcode::kWord32And:
return VisitWordCompare(selector, value, kMipsTst, cont, true);
default:
break;
}
break;
}
// Continuation could not be combined with a compare, emit compare against 0.
MipsOperandGenerator g(selector);
InstructionCode const opcode = cont->Encode(kMipsCmp);
InstructionOperand* const value_operand = g.UseRegister(value);
if (cont->IsBranch()) {
selector->Emit(opcode, nullptr, value_operand, g.TempImmediate(0),
g.Label(cont->true_block()),
g.Label(cont->false_block()))->MarkAsControl();
} else {
selector->Emit(opcode, g.DefineAsRegister(cont->result()), value_operand,
g.TempImmediate(0));
}
}
void InstructionSelector::VisitBranch(Node* branch, BasicBlock* tbranch,
BasicBlock* fbranch) {
FlagsContinuation cont(kNotEqual, tbranch, fbranch);
// If we can fall through to the true block, invert the branch.
if (IsNextInAssemblyOrder(tbranch)) {
cont.Negate();
cont.SwapBlocks();
}
VisitWordCompareZero(this, branch, branch->InputAt(0), &cont);
}
void InstructionSelector::VisitWord32Equal(Node* const node) {
FlagsContinuation cont(kEqual, node);
Int32BinopMatcher m(node);
if (m.right().Is(0)) {
return VisitWordCompareZero(this, m.node(), m.left().node(), &cont);
}
VisitWordCompare(this, node, &cont);
}
void InstructionSelector::VisitInt32LessThan(Node* node) {
FlagsContinuation cont(kSignedLessThan, node);
VisitWordCompare(this, node, &cont);
}
void InstructionSelector::VisitInt32LessThanOrEqual(Node* node) {
FlagsContinuation cont(kSignedLessThanOrEqual, node);
VisitWordCompare(this, node, &cont);
}
void InstructionSelector::VisitUint32LessThan(Node* node) {
FlagsContinuation cont(kUnsignedLessThan, node);
VisitWordCompare(this, node, &cont);
}
void InstructionSelector::VisitUint32LessThanOrEqual(Node* node) {
FlagsContinuation cont(kUnsignedLessThanOrEqual, node);
VisitWordCompare(this, node, &cont);
}
void InstructionSelector::VisitInt32AddWithOverflow(Node* node) {
if (Node* ovf = node->FindProjection(1)) {
FlagsContinuation cont(kOverflow, ovf);
return VisitBinop(this, node, kMipsAddOvf, &cont);
}
FlagsContinuation cont;
VisitBinop(this, node, kMipsAddOvf, &cont);
}
void InstructionSelector::VisitInt32SubWithOverflow(Node* node) {
if (Node* ovf = node->FindProjection(1)) {
FlagsContinuation cont(kOverflow, ovf);
return VisitBinop(this, node, kMipsSubOvf, &cont);
}
FlagsContinuation cont;
VisitBinop(this, node, kMipsSubOvf, &cont);
}
void InstructionSelector::VisitFloat64Equal(Node* node) {
FlagsContinuation cont(kUnorderedEqual, node);
VisitFloat64Compare(this, node, &cont);
}
void InstructionSelector::VisitFloat64LessThan(Node* node) {
FlagsContinuation cont(kUnorderedLessThan, node);
VisitFloat64Compare(this, node, &cont);
}
void InstructionSelector::VisitFloat64LessThanOrEqual(Node* node) {
FlagsContinuation cont(kUnorderedLessThanOrEqual, node);
VisitFloat64Compare(this, node, &cont);
}
// static
MachineOperatorBuilder::Flags
InstructionSelector::SupportedMachineOperatorFlags() {
return MachineOperatorBuilder::kNoFlags;
}
} // namespace compiler
} // namespace internal
} // namespace v8