/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*-
* vim: set ts=8 sts=2 et sw=2 tw=80:
*
* Copyright 2016 Mozilla Foundation
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
// This is an INTERNAL header for Wasm baseline compiler: inline methods in the
// compiler for basic code generation.
#ifndef wasm_wasm_baseline_codegen_inl_h
#define wasm_wasm_baseline_codegen_inl_h
// The templates for register management must be defined by the time we use the
// templated emitters, below.
#include "wasm/WasmBCRegMgmt-inl.h"
namespace js {
namespace wasm {
//////////////////////////////////////////////////////////////////////////////
//
// Register-to-register moves.
void BaseCompiler::moveI32(RegI32 src, RegI32 dest) {
if (src != dest) {
masm.move32(src, dest);
}
}
void BaseCompiler::moveI64(RegI64 src, RegI64 dest) {
if (src != dest) {
masm.move64(src, dest);
}
}
void BaseCompiler::moveRef(RegRef src, RegRef dest) {
if (src != dest) {
masm.movePtr(src, dest);
}
}
void BaseCompiler::movePtr(RegPtr src, RegPtr dest) {
if (src != dest) {
masm.movePtr(src, dest);
}
}
void BaseCompiler::moveF64(RegF64 src, RegF64 dest) {
if (src != dest) {
masm.moveDouble(src, dest);
}
}
void BaseCompiler::moveF32(RegF32 src, RegF32 dest) {
if (src != dest) {
masm.moveFloat32(src, dest);
}
}
#ifdef ENABLE_WASM_SIMD
void BaseCompiler::moveV128(RegV128 src, RegV128 dest) {
if (src != dest) {
masm.moveSimd128(src, dest);
}
}
#endif
template <>
inline void BaseCompiler::move<RegI32>(RegI32 src, RegI32 dest) {
moveI32(src, dest);
}
template <>
inline void BaseCompiler::move<RegI64>(RegI64 src, RegI64 dest) {
moveI64(src, dest);
}
template <>
inline void BaseCompiler::move<RegF32>(RegF32 src, RegF32 dest) {
moveF32(src, dest);
}
template <>
inline void BaseCompiler::move<RegF64>(RegF64 src, RegF64 dest) {
moveF64(src, dest);
}
template <>
inline void BaseCompiler::move<RegRef>(RegRef src, RegRef dest) {
moveRef(src, dest);
}
template <>
inline void BaseCompiler::move<RegPtr>(RegPtr src, RegPtr dest) {
movePtr(src, dest);
}
#ifdef ENABLE_WASM_SIMD
template <>
inline void BaseCompiler::move<RegV128>(RegV128 src, RegV128 dest) {
moveV128(src, dest);
}
#endif
//////////////////////////////////////////////////////////////////////////////
//
// Constant loads.
void BaseCompiler::moveImm32(int32_t v, RegI32 dest) {
masm.move32(Imm32(v), dest);
}
void BaseCompiler::moveImm64(int64_t v, RegI64 dest) {
masm.move64(Imm64(v), dest);
}
void BaseCompiler::moveImmRef(intptr_t v, RegRef dest) {
masm.movePtr(ImmWord(v), dest);
}
//////////////////////////////////////////////////////////////////////////////
//
// Calls.
RegI32 BaseCompiler::captureReturnedI32() {
RegI32 r = RegI32(ReturnReg);
MOZ_ASSERT(isAvailableI32(r));
needI32(r);
#if defined(JS_64BIT)
masm.widenInt32(r);
#endif
return r;
}
RegI64 BaseCompiler::captureReturnedI64() {
RegI64 r = RegI64(ReturnReg64);
MOZ_ASSERT(isAvailableI64(r));
needI64(r);
return r;
}
RegF32 BaseCompiler::captureReturnedF32(
const FunctionCall& call) {
RegF32 r = RegF32(ReturnFloat32Reg);
MOZ_ASSERT(isAvailableF32(r));
needF32(r);
#if defined(JS_CODEGEN_ARM)
if (call.usesSystemAbi && !call.hardFP) {
masm.ma_vxfer(ReturnReg, r);
}
#endif
return r;
}
RegF64 BaseCompiler::captureReturnedF64(
const FunctionCall& call) {
RegF64 r = RegF64(ReturnDoubleReg);
MOZ_ASSERT(isAvailableF64(r));
needF64(r);
#if defined(JS_CODEGEN_ARM)
if (call.usesSystemAbi && !call.hardFP) {
masm.ma_vxfer(ReturnReg64.low, ReturnReg64.high, r);
}
#endif
return r;
}
#ifdef ENABLE_WASM_SIMD
RegV128 BaseCompiler::captureReturnedV128(
const FunctionCall& call) {
RegV128 r = RegV128(ReturnSimd128Reg);
MOZ_ASSERT(isAvailableV128(r));
needV128(r);
return r;
}
#endif
RegRef BaseCompiler::captureReturnedRef() {
RegRef r = RegRef(ReturnReg);
MOZ_ASSERT(isAvailableRef(r));
needRef(r);
return r;
}
//////////////////////////////////////////////////////////////////////////////
//
// Miscellaneous.
void BaseCompiler::trap(Trap t)
const { masm.wasmTrap(t, trapSiteDesc()); }
void BaseCompiler::cmp64Set(Assembler::Condition cond, RegI64 lhs, RegI64 rhs,
RegI32 dest) {
#if defined(JS_PUNBOX64)
masm.cmpPtrSet(cond, lhs.reg, rhs.reg, dest);
#else
// TODO / OPTIMIZE (Bug 1316822): This is pretty branchy, we should be
// able to do better.
Label done, condTrue;
masm.branch64(cond, lhs, rhs, &condTrue);
moveImm32(0, dest);
masm.jump(&done);
masm.bind(&condTrue);
moveImm32(1, dest);
masm.bind(&done);
#endif
}
[[nodiscard]]
bool BaseCompiler::supportsRoundInstruction(RoundingMode mode) {
return Assembler::HasRoundInstruction(mode);
}
void BaseCompiler::roundF32(RoundingMode roundingMode, RegF32 f0) {
masm.nearbyIntFloat32(roundingMode, f0, f0);
}
void BaseCompiler::roundF64(RoundingMode roundingMode, RegF64 f0) {
masm.nearbyIntDouble(roundingMode, f0, f0);
}
void BaseCompiler::branchTo(Assembler::DoubleCondition c, RegF64 lhs,
RegF64 rhs, Label* l) {
masm.branchDouble(c, lhs, rhs, l);
}
void BaseCompiler::branchTo(Assembler::DoubleCondition c, RegF32 lhs,
RegF32 rhs, Label* l) {
masm.branchFloat(c, lhs, rhs, l);
}
void BaseCompiler::branchTo(Assembler::Condition c, RegI32 lhs, RegI32 rhs,
Label* l) {
masm.branch32(c, lhs, rhs, l);
}
void BaseCompiler::branchTo(Assembler::Condition c, RegI32 lhs, Imm32 rhs,
Label* l) {
masm.branch32(c, lhs, rhs, l);
}
void BaseCompiler::branchTo(Assembler::Condition c, RegI64 lhs, RegI64 rhs,
Label* l) {
masm.branch64(c, lhs, rhs, l);
}
void BaseCompiler::branchTo(Assembler::Condition c, RegI64 lhs, Imm64 rhs,
Label* l) {
masm.branch64(c, lhs, rhs, l);
}
void BaseCompiler::branchTo(Assembler::Condition c, RegRef lhs, ImmWord rhs,
Label* l) {
masm.branchPtr(c, lhs, rhs, l);
}
//////////////////////////////////////////////////////////////////////////////
//
// Templated emitters
template <>
inline BaseCompiler& BaseCompiler::selectCompiler<BaseCompiler>() {
return *
this;
}
template <>
inline MacroAssembler& BaseCompiler::selectCompiler<MacroAssembler>() {
return masm;
}
template <
typename SourceType,
typename DestType>
void BaseCompiler::emitUnop(
void (*op)(MacroAssembler& masm, SourceType rs,
DestType rd)) {
SourceType rs = pop<SourceType>();
DestType rd = need<DestType>();
op(masm, rs, rd);
free(rs);
push(rd);
}
// Specialize narrowing reuse. Consumers may assume that rs.reg==rd on 64-bit
// platforms, or rs.low==rd on 32-bit platforms.
template <>
inline void BaseCompiler::emitUnop(
void (*op)(MacroAssembler& masm, RegI64 rs,
RegI32 rd)) {
RegI64 rs = pop<RegI64>();
RegI32 rd = fromI64(rs);
op(masm, rs, rd);
freeI64Except(rs, rd);
push(rd);
}
template <
typename CompilerType,
typename RegType>
void BaseCompiler::emitUnop(
void (*op)(CompilerType& compiler, RegType rsd)) {
RegType rsd = pop<RegType>();
op(selectCompiler<CompilerType>(), rsd);
push(rsd);
}
template <
typename RegType,
typename TempType>
void BaseCompiler::emitUnop(
void (*op)(BaseCompiler& bc, RegType rsd,
TempType rt),
TempType (*getSpecializedTemp)(BaseCompiler& bc)) {
RegType rsd = pop<RegType>();
TempType temp = getSpecializedTemp(*
this);
op(*
this, rsd, temp);
maybeFree(temp);
push(rsd);
}
template <
typename SourceType,
typename DestType,
typename TempType>
void BaseCompiler::emitUnop(
void (*op)(MacroAssembler& masm, SourceType rs,
DestType rd, TempType temp)) {
SourceType rs = pop<SourceType>();
DestType rd = need<DestType>();
TempType temp = need<TempType>();
op(masm, rs, rd, temp);
free(rs);
free(temp);
push(rd);
}
template <
typename SourceType,
typename DestType,
typename ImmType>
void BaseCompiler::emitUnop(ImmType immediate,
void (*op)(MacroAssembler&, ImmType, SourceType,
DestType)) {
SourceType rs = pop<SourceType>();
DestType rd = need<DestType>();
op(masm, immediate, rs, rd);
free(rs);
push(rd);
}
template <
typename CompilerType,
typename RhsType,
typename LhsDestType>
void BaseCompiler::emitBinop(
void (*op)(CompilerType& masm, RhsType src,
LhsDestType srcDest)) {
RhsType rs = pop<RhsType>();
LhsDestType rsd = pop<LhsDestType>();
op(selectCompiler<CompilerType>(), rs, rsd);
free(rs);
push(rsd);
}
template <
typename CompilerType,
typename ValType>
void BaseCompiler::emitTernary(
void (*op)(CompilerType&, ValType src0,
ValType src1, ValType srcDest)) {
ValType src2 = pop<ValType>();
ValType src1 = pop<ValType>();
ValType srcDest = pop<ValType>();
op(selectCompiler<CompilerType>(), src1, src2, srcDest);
free(src2);
free(src1);
push(srcDest);
}
template <
typename CompilerType,
typename ValType>
void BaseCompiler::emitTernary(
void (*op)(CompilerType&, ValType src0,
ValType src1, ValType srcDest,
ValType temp)) {
ValType src2 = pop<ValType>();
ValType src1 = pop<ValType>();
ValType srcDest = pop<ValType>();
ValType temp = need<ValType>();
op(selectCompiler<CompilerType>(), src1, src2, srcDest, temp);
free(temp);
free(src2);
free(src1);
push(srcDest);
}
template <
typename CompilerType,
typename ValType>
void BaseCompiler::emitTernaryResultLast(
void (*op)(CompilerType&, ValType src0,
ValType src1,
ValType srcDest)) {
ValType srcDest = pop<ValType>();
ValType src2 = pop<ValType>();
ValType src1 = pop<ValType>();
op(selectCompiler<CompilerType>(), src1, src2, srcDest);
free(src2);
free(src1);
push(srcDest);
}
template <
typename RhsDestType,
typename LhsType>
void BaseCompiler::emitBinop(
void (*op)(MacroAssembler& masm, RhsDestType src,
LhsType srcDest, RhsDestOp)) {
RhsDestType rsd = pop<RhsDestType>();
LhsType rs = pop<LhsType>();
op(masm, rsd, rs, RhsDestOp::
True);
free(rs);
push(rsd);
}
template <
typename RhsType,
typename LhsDestType,
typename TempType>
void BaseCompiler::emitBinop(
void (*op)(MacroAssembler& masm, RhsType rs,
LhsDestType rsd, TempType temp)) {
RhsType rs = pop<RhsType>();
LhsDestType rsd = pop<LhsDestType>();
TempType temp = need<TempType>();
op(masm, rs, rsd, temp);
free(rs);
free(temp);
push(rsd);
}
template <
typename RhsType,
typename LhsDestType,
typename TempType1,
typename TempType2>
void BaseCompiler::emitBinop(
void (*op)(MacroAssembler& masm, RhsType rs,
LhsDestType rsd, TempType1 temp1,
TempType2 temp2)) {
RhsType rs = pop<RhsType>();
LhsDestType rsd = pop<LhsDestType>();
TempType1 temp1 = need<TempType1>();
TempType2 temp2 = need<TempType2>();
op(masm, rs, rsd, temp1, temp2);
free(rs);
free(temp1);
free(temp2);
push(rsd);
}
template <
typename RhsType,
typename LhsDestType,
typename ImmType>
void BaseCompiler::emitBinop(ImmType immediate,
void (*op)(MacroAssembler&, ImmType, RhsType,
LhsDestType)) {
RhsType rs = pop<RhsType>();
LhsDestType rsd = pop<LhsDestType>();
op(masm, immediate, rs, rsd);
free(rs);
push(rsd);
}
template <
typename RhsType,
typename LhsDestType,
typename ImmType,
typename TempType1,
typename TempType2>
void BaseCompiler::emitBinop(ImmType immediate,
void (*op)(MacroAssembler&, ImmType, RhsType,
LhsDestType, TempType1 temp1,
TempType2 temp2)) {
RhsType rs = pop<RhsType>();
LhsDestType rsd = pop<LhsDestType>();
TempType1 temp1 = need<TempType1>();
TempType2 temp2 = need<TempType2>();
op(masm, immediate, rs, rsd, temp1, temp2);
free(rs);
free(temp1);
free(temp2);
push(rsd);
}
template <
typename CompilerType1,
typename CompilerType2,
typename RegType,
typename ImmType>
void BaseCompiler::emitBinop(
void (*op)(CompilerType1& compiler, RegType rs,
RegType rsd),
void (*opConst)(CompilerType2& compiler, ImmType c,
RegType rsd),
RegType (BaseCompiler::*rhsPopper)()) {
ImmType c;
if (popConst(&c)) {
RegType rsd = pop<RegType>();
opConst(selectCompiler<CompilerType2>(), c, rsd);
push(rsd);
}
else {
RegType rs = rhsPopper ? (this->*rhsPopper)() : pop<RegType>();
RegType rsd = pop<RegType>();
op(selectCompiler<CompilerType1>(), rs, rsd);
free(rs);
push(rsd);
}
}
template <
typename R>
bool BaseCompiler::emitInstanceCallOp(
const SymbolicAddressSignature& fn,
R reader) {
if (!reader()) {
return false;
}
if (deadCode_) {
return true;
}
return emitInstanceCall(fn);
}
template <
typename A1,
typename R>
bool BaseCompiler::emitInstanceCallOp(
const SymbolicAddressSignature& fn,
R reader) {
A1 arg = 0;
if (!reader(&arg)) {
return false;
}
if (deadCode_) {
return true;
}
push(arg);
return emitInstanceCall(fn);
}
template <
typename A1,
typename A2,
typename R>
bool BaseCompiler::emitInstanceCallOp(
const SymbolicAddressSignature& fn,
R reader) {
A1 arg1 = 0;
A2 arg2 = 0;
if (!reader(&arg1, &arg2)) {
return false;
}
if (deadCode_) {
return true;
}
// Note order of arguments must be the same as for the reader.
push(arg1);
push(arg2);
return emitInstanceCall(fn);
}
}
// namespace wasm
}
// namespace js
#endif // wasm_wasm_baseline_codegen_inl_h
