// [AsmJit] // Machine Code Generation for C++. // // [License] // Zlib - See LICENSE.md file in the package. #define ASMJIT_EXPORTS #include "../core/build.h" #if defined(ASMJIT_BUILD_X86) && !defined(ASMJIT_NO_COMPILER) #include "../core/cpuinfo.h" #include "../core/support.h" #include "../core/type.h" #include "../x86/x86assembler.h" #include "../x86/x86compiler.h" #include "../x86/x86instapi_p.h" #include "../x86/x86instdb_p.h" #include "../x86/x86internal_p.h" #include "../x86/x86rapass_p.h" ASMJIT_BEGIN_SUB_NAMESPACE(x86) // ============================================================================ // [asmjit::x86::X86RAPass - Helpers] // ============================================================================ static ASMJIT_INLINE uint64_t raImmMaskFromSize(uint32_t size) noexcept { ASMJIT_ASSERT(size > 0 && size < 256); static const uint64_t masks[] = { 0x00000000000000FFu, // 1 0x000000000000FFFFu, // 2 0x00000000FFFFFFFFu, // 4 0xFFFFFFFFFFFFFFFFu, // 8 0x0000000000000000u, // 16 0x0000000000000000u, // 32 0x0000000000000000u, // 64 0x0000000000000000u, // 128 0x0000000000000000u // 256 }; return masks[Support::ctz(size)]; } static ASMJIT_INLINE uint32_t raUseOutFlagsFromRWFlags(uint32_t rwFlags) noexcept { static const uint32_t map[] = { 0, RATiedReg::kRead | RATiedReg::kUse, // kRead RATiedReg::kWrite | RATiedReg::kOut, // kWrite RATiedReg::kRW | RATiedReg::kUse, // kRW 0, RATiedReg::kRead | RATiedReg::kUse | RATiedReg::kUseRM, // kRead | kRegMem RATiedReg::kWrite | RATiedReg::kOut | RATiedReg::kOutRM, // kWrite | kRegMem RATiedReg::kRW | RATiedReg::kUse | RATiedReg::kUseRM // kRW | kRegMem }; return map[rwFlags & (OpRWInfo::kRW | OpRWInfo::kRegMem)]; } static ASMJIT_INLINE uint32_t raRegRwFlags(uint32_t flags) noexcept { return raUseOutFlagsFromRWFlags(flags); } static ASMJIT_INLINE uint32_t raMemBaseRwFlags(uint32_t flags) noexcept { constexpr uint32_t shift = Support::constCtz(OpRWInfo::kMemBaseRW); return raUseOutFlagsFromRWFlags((flags >> shift) & OpRWInfo::kRW); } static ASMJIT_INLINE uint32_t raMemIndexRwFlags(uint32_t flags) noexcept { constexpr uint32_t shift = Support::constCtz(OpRWInfo::kMemIndexRW); return raUseOutFlagsFromRWFlags((flags >> shift) & OpRWInfo::kRW); } // ============================================================================ // [asmjit::x86::X86RACFGBuilder] // ============================================================================ class X86RACFGBuilder : public RACFGBuilder { public: uint32_t _archId; bool _is64Bit; bool _avxEnabled; inline X86RACFGBuilder(X86RAPass* pass) noexcept : RACFGBuilder(pass), _archId(pass->cc()->archId()), _is64Bit(pass->gpSize() == 8), _avxEnabled(pass->_avxEnabled) {} inline Compiler* cc() const noexcept { return static_cast(_cc); } inline uint32_t choose(uint32_t sseInst, uint32_t avxInst) const noexcept { return _avxEnabled ? avxInst : sseInst; } Error onInst(InstNode* inst, uint32_t& controlType, RAInstBuilder& ib) noexcept; Error onBeforeCall(FuncCallNode* call) noexcept; Error onCall(FuncCallNode* call, RAInstBuilder& ib) noexcept; Error moveImmToRegArg(FuncCallNode* call, const FuncValue& arg, const Imm& imm_, BaseReg* out) noexcept; Error moveImmToStackArg(FuncCallNode* call, const FuncValue& arg, const Imm& imm_) noexcept; Error moveRegToStackArg(FuncCallNode* call, const FuncValue& arg, const BaseReg& reg) noexcept; Error onBeforeRet(FuncRetNode* funcRet) noexcept; Error onRet(FuncRetNode* funcRet, RAInstBuilder& ib) noexcept; }; // ============================================================================ // [asmjit::x86::X86RACFGBuilder - OnInst] // ============================================================================ Error X86RACFGBuilder::onInst(InstNode* inst, uint32_t& controlType, RAInstBuilder& ib) noexcept { InstRWInfo rwInfo; uint32_t instId = inst->id(); if (Inst::isDefinedId(instId)) { uint32_t opCount = inst->opCount(); const Operand* opArray = inst->operands(); ASMJIT_PROPAGATE(InstInternal::queryRWInfo(_archId, inst->baseInst(), opArray, opCount, rwInfo)); const InstDB::InstInfo& instInfo = InstDB::infoById(instId); bool hasGpbHiConstraint = false; uint32_t singleRegOps = 0; if (opCount) { for (uint32_t i = 0; i < opCount; i++) { const Operand& op = opArray[i]; const OpRWInfo& opRwInfo = rwInfo.operand(i); if (op.isReg()) { // Register Operand // ---------------- const Reg& reg = op.as(); uint32_t flags = raRegRwFlags(opRwInfo.opFlags()); uint32_t allowedRegs = 0xFFFFFFFFu; // X86-specific constraints related to LO|HI general purpose registers. // This is only required when the register is part of the encoding. If // the register is fixed we won't restrict anything as it doesn't restrict // encoding of other registers. if (reg.isGpb() && !(opRwInfo.opFlags() & OpRWInfo::kRegPhysId)) { flags |= RATiedReg::kX86Gpb; if (!_is64Bit) { // Restrict to first four - AL|AH|BL|BH|CL|CH|DL|DH. In 32-bit mode // it's not possible to access SIL|DIL, etc, so this is just enough. allowedRegs = 0x0Fu; } else { // If we encountered GPB-HI register the situation is much more // complicated than in 32-bit mode. We need to patch all registers // to not use ID higher than 7 and all GPB-LO registers to not use // index higher than 3. Instead of doing the patching here we just // set a flag and will do it later, to not complicate this loop. if (reg.isGpbHi()) { hasGpbHiConstraint = true; allowedRegs = 0x0Fu; } } } uint32_t vIndex = Operand::virtIdToIndex(reg.id()); if (vIndex < Operand::kVirtIdCount) { RAWorkReg* workReg; ASMJIT_PROPAGATE(_pass->virtIndexAsWorkReg(vIndex, &workReg)); // Use RW instead of Write in case that not the whole register is // overwritten. This is important for liveness as we cannot kill a // register that will be used. For example `mov al, 0xFF` is not a // write-only operation if user allocated the whole `rax` register. if ((flags & RATiedReg::kRW) == RATiedReg::kWrite) { if (workReg->regByteMask() & ~(opRwInfo.writeByteMask() | opRwInfo.extendByteMask())) { // Not write-only operation. flags = (flags & ~RATiedReg::kOut) | (RATiedReg::kRead | RATiedReg::kUse); } } // Do not use RegMem flag if changing Reg to Mem requires additional // CPU feature that may not be enabled. if (rwInfo.rmFeature() && (flags & (RATiedReg::kUseRM | RATiedReg::kOutRM))) { flags &= ~(RATiedReg::kUseRM | RATiedReg::kOutRM); } uint32_t group = workReg->group(); uint32_t allocable = _pass->_availableRegs[group] & allowedRegs; uint32_t useId = BaseReg::kIdBad; uint32_t outId = BaseReg::kIdBad; uint32_t useRewriteMask = 0; uint32_t outRewriteMask = 0; if (flags & RATiedReg::kUse) { useRewriteMask = Support::bitMask(inst->getRewriteIndex(®._baseId)); if (opRwInfo.opFlags() & OpRWInfo::kRegPhysId) { useId = opRwInfo.physId(); flags |= RATiedReg::kUseFixed; } } else { outRewriteMask = Support::bitMask(inst->getRewriteIndex(®._baseId)); if (opRwInfo.opFlags() & OpRWInfo::kRegPhysId) { outId = opRwInfo.physId(); flags |= RATiedReg::kOutFixed; } } ASMJIT_PROPAGATE(ib.add(workReg, flags, allocable, useId, useRewriteMask, outId, outRewriteMask, opRwInfo.rmSize())); if (singleRegOps == i) singleRegOps++; } } else if (op.isMem()) { // Memory Operand // -------------- const Mem& mem = op.as(); ib.addForbiddenFlags(RATiedReg::kUseRM | RATiedReg::kOutRM); if (mem.isRegHome()) { RAWorkReg* workReg; ASMJIT_PROPAGATE(_pass->virtIndexAsWorkReg(Operand::virtIdToIndex(mem.baseId()), &workReg)); _pass->getOrCreateStackSlot(workReg); } else if (mem.hasBaseReg()) { uint32_t vIndex = Operand::virtIdToIndex(mem.baseId()); if (vIndex < Operand::kVirtIdCount) { RAWorkReg* workReg; ASMJIT_PROPAGATE(_pass->virtIndexAsWorkReg(vIndex, &workReg)); uint32_t flags = raMemBaseRwFlags(opRwInfo.opFlags()); uint32_t group = workReg->group(); uint32_t allocable = _pass->_availableRegs[group]; uint32_t useId = BaseReg::kIdBad; uint32_t outId = BaseReg::kIdBad; uint32_t useRewriteMask = 0; uint32_t outRewriteMask = 0; if (flags & RATiedReg::kUse) { useRewriteMask = Support::bitMask(inst->getRewriteIndex(&mem._baseId)); if (opRwInfo.opFlags() & OpRWInfo::kMemPhysId) { useId = opRwInfo.physId(); flags |= RATiedReg::kUseFixed; } } else { outRewriteMask = Support::bitMask(inst->getRewriteIndex(&mem._baseId)); if (opRwInfo.opFlags() & OpRWInfo::kMemPhysId) { outId = opRwInfo.physId(); flags |= RATiedReg::kOutFixed; } } ASMJIT_PROPAGATE(ib.add(workReg, flags, allocable, useId, useRewriteMask, outId, outRewriteMask)); } } if (mem.hasIndexReg()) { uint32_t vIndex = Operand::virtIdToIndex(mem.indexId()); if (vIndex < Operand::kVirtIdCount) { RAWorkReg* workReg; ASMJIT_PROPAGATE(_pass->virtIndexAsWorkReg(vIndex, &workReg)); uint32_t flags = raMemIndexRwFlags(opRwInfo.opFlags()); uint32_t group = workReg->group(); uint32_t allocable = _pass->_availableRegs[group]; // Index registers have never fixed id on X86/x64. const uint32_t useId = BaseReg::kIdBad; const uint32_t outId = BaseReg::kIdBad; uint32_t useRewriteMask = 0; uint32_t outRewriteMask = 0; if (flags & RATiedReg::kUse) useRewriteMask = Support::bitMask(inst->getRewriteIndex(&mem._mem.indexId)); else outRewriteMask = Support::bitMask(inst->getRewriteIndex(&mem._mem.indexId)); ASMJIT_PROPAGATE(ib.add(workReg, RATiedReg::kUse | RATiedReg::kRead, allocable, useId, useRewriteMask, outId, outRewriteMask)); } } } } } // Handle extra operand (either REP {cx|ecx|rcx} or AVX-512 {k} selector). if (inst->hasExtraReg()) { uint32_t vIndex = Operand::virtIdToIndex(inst->extraReg().id()); if (vIndex < Operand::kVirtIdCount) { RAWorkReg* workReg; ASMJIT_PROPAGATE(_pass->virtIndexAsWorkReg(vIndex, &workReg)); uint32_t group = workReg->group(); uint32_t rewriteMask = Support::bitMask(inst->getRewriteIndex(&inst->extraReg()._id)); if (group == Gp::kGroupKReg) { // AVX-512 mask selector {k} register - read-only, allocable to any register except {k0}. uint32_t allocableRegs= _pass->_availableRegs[group] & ~Support::bitMask(0); ASMJIT_PROPAGATE(ib.add(workReg, RATiedReg::kUse | RATiedReg::kRead, allocableRegs, BaseReg::kIdBad, rewriteMask, BaseReg::kIdBad, 0)); singleRegOps = 0; } else { // REP {cx|ecx|rcx} register - read & write, allocable to {cx|ecx|rcx} only. ASMJIT_PROPAGATE(ib.add(workReg, RATiedReg::kUse | RATiedReg::kRW, 0, Gp::kIdCx, rewriteMask, Gp::kIdBad, 0)); } } else { uint32_t group = inst->extraReg().group(); if (group == Gp::kGroupKReg && inst->extraReg().id() != 0) singleRegOps = 0; } } // Handle X86 constraints. if (hasGpbHiConstraint) { for (uint32_t i = 0; i < ib.tiedRegCount(); i++) { RATiedReg* tiedReg = ib[i]; tiedReg->_allocableRegs &= tiedReg->hasFlag(RATiedReg::kX86Gpb) ? 0x0Fu : 0xFFu; } } if (ib.tiedRegCount() == 1) { // Handle special cases of some instructions where all operands share the same // register. In such case the single operand becomes read-only or write-only. uint32_t singleRegCase = InstDB::kSingleRegNone; if (singleRegOps == opCount) { singleRegCase = instInfo.singleRegCase(); } else if (opCount == 2 && inst->opType(1).isImm()) { // Handle some tricks used by X86 asm. const BaseReg& reg = inst->opType(0).as(); const Imm& imm = inst->opType(1).as(); const RAWorkReg* workReg = _pass->workRegById(ib[0]->workId()); uint32_t workRegSize = workReg->info().size(); switch (inst->id()) { case Inst::kIdOr: { // Sets the value of the destination register to -1, previous content unused. if (reg.size() >= 4 || reg.size() >= workRegSize) { if (imm.i64() == -1 || imm.u64() == raImmMaskFromSize(reg.size())) singleRegCase = InstDB::kSingleRegWO; } ASMJIT_FALLTHROUGH; } case Inst::kIdAdd: case Inst::kIdAnd: case Inst::kIdRol: case Inst::kIdRor: case Inst::kIdSar: case Inst::kIdShl: case Inst::kIdShr: case Inst::kIdSub: case Inst::kIdXor: { // Updates [E|R]FLAGS without changing the content. if (reg.size() != 4 || reg.size() >= workRegSize) { if (imm.u64() == 0) singleRegCase = InstDB::kSingleRegRO; } break; } } } switch (singleRegCase) { case InstDB::kSingleRegNone: break; case InstDB::kSingleRegRO: ib[0]->makeReadOnly(); break; case InstDB::kSingleRegWO: ib[0]->makeWriteOnly(); break; } } controlType = instInfo.controlType(); } return kErrorOk; } // ============================================================================ // [asmjit::x86::X86RACFGBuilder - OnCall] // ============================================================================ Error X86RACFGBuilder::onBeforeCall(FuncCallNode* call) noexcept { uint32_t argCount = call->argCount(); uint32_t retCount = call->retCount(); const FuncDetail& fd = call->detail(); cc()->_setCursor(call->prev()); for (uint32_t argIndex = 0; argIndex < argCount; argIndex++) { for (uint32_t argHi = 0; argHi <= kFuncArgHi; argHi += kFuncArgHi) { if (!fd.hasArg(argIndex + argHi)) continue; const FuncValue& arg = fd.arg(argIndex + argHi); const Operand& op = call->arg(argIndex + argHi); if (op.isNone()) continue; if (op.isReg()) { const Reg& reg = op.as(); RAWorkReg* workReg; ASMJIT_PROPAGATE(_pass->virtIndexAsWorkReg(Operand::virtIdToIndex(reg.id()), &workReg)); if (arg.isReg()) { uint32_t regGroup = workReg->group(); uint32_t argGroup = Reg::groupOf(arg.regType()); if (regGroup != argGroup) { // TODO: ASMJIT_ASSERT(false); } } else { ASMJIT_PROPAGATE(moveRegToStackArg(call, arg, op.as())); } } else if (op.isImm()) { if (arg.isReg()) { BaseReg reg; ASMJIT_PROPAGATE(moveImmToRegArg(call, arg, op.as(), ®)); call->_args[argIndex + argHi] = reg; } else { ASMJIT_PROPAGATE(moveImmToStackArg(call, arg, op.as())); } } } } cc()->_setCursor(call); if (fd.hasFlag(CallConv::kFlagCalleePopsStack)) ASMJIT_PROPAGATE(cc()->sub(cc()->zsp(), fd.argStackSize())); for (uint32_t retIndex = 0; retIndex < retCount; retIndex++) { const FuncValue& ret = fd.ret(retIndex); const Operand& op = call->ret(retIndex); if (op.isReg()) { const Reg& reg = op.as(); RAWorkReg* workReg; ASMJIT_PROPAGATE(_pass->virtIndexAsWorkReg(Operand::virtIdToIndex(reg.id()), &workReg)); if (ret.isReg()) { if (ret.regType() == Reg::kTypeSt) { if (workReg->group() != Reg::kGroupVec) return DebugUtils::errored(kErrorInvalidAssignment); Reg dst = Reg(workReg->signature(), workReg->virtId()); Mem mem; uint32_t typeId = Type::baseOf(workReg->typeId()); if (ret.hasTypeId()) typeId = ret.typeId(); switch (typeId) { case Type::kIdF32: ASMJIT_PROPAGATE(_pass->useTemporaryMem(mem, 4, 4)); mem.setSize(4); ASMJIT_PROPAGATE(cc()->fstp(mem)); ASMJIT_PROPAGATE(cc()->emit(choose(Inst::kIdMovss, Inst::kIdVmovss), dst.as(), mem)); break; case Type::kIdF64: ASMJIT_PROPAGATE(_pass->useTemporaryMem(mem, 8, 4)); mem.setSize(8); ASMJIT_PROPAGATE(cc()->fstp(mem)); ASMJIT_PROPAGATE(cc()->emit(choose(Inst::kIdMovsd, Inst::kIdVmovsd), dst.as(), mem)); break; default: return DebugUtils::errored(kErrorInvalidAssignment); } } else { uint32_t regGroup = workReg->group(); uint32_t retGroup = Reg::groupOf(ret.regType()); if (regGroup != retGroup) { // TODO: ASMJIT_ASSERT(false); } } } } } // This block has function call(s). _curBlock->addFlags(RABlock::kFlagHasFuncCalls); _pass->func()->frame().addAttributes(FuncFrame::kAttrHasFuncCalls); _pass->func()->frame().updateCallStackSize(fd.argStackSize()); return kErrorOk; } Error X86RACFGBuilder::onCall(FuncCallNode* call, RAInstBuilder& ib) noexcept { uint32_t argCount = call->argCount(); uint32_t retCount = call->retCount(); const FuncDetail& fd = call->detail(); for (uint32_t argIndex = 0; argIndex < argCount; argIndex++) { for (uint32_t argHi = 0; argHi <= kFuncArgHi; argHi += kFuncArgHi) { if (!fd.hasArg(argIndex + argHi)) continue; const FuncValue& arg = fd.arg(argIndex + argHi); const Operand& op = call->arg(argIndex + argHi); if (op.isNone()) continue; if (op.isReg()) { const Reg& reg = op.as(); RAWorkReg* workReg; ASMJIT_PROPAGATE(_pass->virtIndexAsWorkReg(Operand::virtIdToIndex(reg.id()), &workReg)); if (arg.isReg()) { uint32_t regGroup = workReg->group(); uint32_t argGroup = Reg::groupOf(arg.regType()); if (regGroup == argGroup) { ASMJIT_PROPAGATE(ib.addCallArg(workReg, arg.regId())); } } } } } for (uint32_t retIndex = 0; retIndex < retCount; retIndex++) { const FuncValue& ret = fd.ret(retIndex); const Operand& op = call->ret(retIndex); // Not handled here... if (ret.regType() == Reg::kTypeSt) continue; if (op.isReg()) { const Reg& reg = op.as(); RAWorkReg* workReg; ASMJIT_PROPAGATE(_pass->virtIndexAsWorkReg(Operand::virtIdToIndex(reg.id()), &workReg)); if (ret.isReg()) { uint32_t regGroup = workReg->group(); uint32_t retGroup = Reg::groupOf(ret.regType()); if (regGroup == retGroup) { ASMJIT_PROPAGATE(ib.addCallRet(workReg, ret.regId())); } } else { return DebugUtils::errored(kErrorInvalidAssignment); } } } // Setup clobbered registers. ib._clobbered[0] = Support::lsbMask(_pass->_physRegCount[0]) & ~fd.preservedRegs(0); ib._clobbered[1] = Support::lsbMask(_pass->_physRegCount[1]) & ~fd.preservedRegs(1); ib._clobbered[2] = Support::lsbMask(_pass->_physRegCount[2]) & ~fd.preservedRegs(2); ib._clobbered[3] = Support::lsbMask(_pass->_physRegCount[3]) & ~fd.preservedRegs(3); return kErrorOk; } // ============================================================================ // [asmjit::x86::X86RACFGBuilder - MoveImmToRegArg] // ============================================================================ Error X86RACFGBuilder::moveImmToRegArg(FuncCallNode* call, const FuncValue& arg, const Imm& imm_, BaseReg* out) noexcept { ASMJIT_UNUSED(call); ASMJIT_ASSERT(arg.isReg()); Imm imm(imm_); uint32_t rTypeId = Type::kIdU32; switch (arg.typeId()) { case Type::kIdI8: imm.signExtend8Bits(); goto MovU32; case Type::kIdU8: imm.zeroExtend8Bits(); goto MovU32; case Type::kIdI16: imm.signExtend16Bits(); goto MovU32; case Type::kIdU16: imm.zeroExtend16Bits(); goto MovU32; case Type::kIdI32: case Type::kIdU32: MovU32: imm.zeroExtend32Bits(); break; case Type::kIdI64: case Type::kIdU64: // Moving to GPD automatically zero extends in 64-bit mode. if (imm.isUInt32()) { imm.zeroExtend32Bits(); break; } rTypeId = Type::kIdU64; break; default: return DebugUtils::errored(kErrorInvalidState); } ASMJIT_PROPAGATE(cc()->_newReg(*out, rTypeId, nullptr)); cc()->virtRegById(out->id())->setWeight(RAPass::kCallArgWeight); return cc()->mov(out->as(), imm); } // ============================================================================ // [asmjit::x86::X86RACFGBuilder - MoveImmToStackArg] // ============================================================================ Error X86RACFGBuilder::moveImmToStackArg(FuncCallNode* call, const FuncValue& arg, const Imm& imm_) noexcept { ASMJIT_UNUSED(call); ASMJIT_ASSERT(arg.isStack()); Mem mem = ptr(_pass->_sp.as(), arg.stackOffset()); Imm imm[2]; mem.setSize(4); imm[0] = imm_; uint32_t nMovs = 0; // One stack entry has the same size as the native register size. That means // that if we want to move a 32-bit integer on the stack in 64-bit mode, we // need to extend it to a 64-bit integer first. In 32-bit mode, pushing a // 64-bit on stack is done in two steps by pushing low and high parts // separately. switch (arg.typeId()) { case Type::kIdI8: imm[0].signExtend8Bits(); goto MovU32; case Type::kIdU8: imm[0].zeroExtend8Bits(); goto MovU32; case Type::kIdI16: imm[0].signExtend16Bits(); goto MovU32; case Type::kIdU16: imm[0].zeroExtend16Bits(); goto MovU32; case Type::kIdI32: case Type::kIdU32: case Type::kIdF32: MovU32: imm[0].zeroExtend32Bits(); nMovs = 1; break; case Type::kIdI64: case Type::kIdU64: case Type::kIdF64: case Type::kIdMmx32: case Type::kIdMmx64: if (_is64Bit && imm[0].isInt32()) { mem.setSize(8); nMovs = 1; break; } imm[1].setU32(imm[0].u32Hi()); imm[0].zeroExtend32Bits(); nMovs = 2; break; default: return DebugUtils::errored(kErrorInvalidState); } for (uint32_t i = 0; i < nMovs; i++) { ASMJIT_PROPAGATE(cc()->mov(mem, imm[i])); mem.addOffsetLo32(int32_t(mem.size())); } return kErrorOk; } // ============================================================================ // [asmjit::x86::X86RACFGBuilder - MoveRegToStackArg] // ============================================================================ Error X86RACFGBuilder::moveRegToStackArg(FuncCallNode* call, const FuncValue& arg, const BaseReg& reg) noexcept { ASMJIT_UNUSED(call); ASMJIT_ASSERT(arg.isStack()); Mem mem = ptr(_pass->_sp.as(), arg.stackOffset()); Reg r0, r1; VirtReg* vr = cc()->virtRegById(reg.id()); uint32_t gpSize = cc()->gpSize(); uint32_t instId = 0; uint32_t dstTypeId = arg.typeId(); uint32_t srcTypeId = vr->typeId(); switch (dstTypeId) { case Type::kIdI64: case Type::kIdU64: // Extend BYTE->QWORD (GP). if (Type::isGp8(srcTypeId)) { r1.setRegT(reg.id()); instId = (dstTypeId == Type::kIdI64 && srcTypeId == Type::kIdI8) ? Inst::kIdMovsx : Inst::kIdMovzx; goto ExtendMovGpXQ; } // Extend WORD->QWORD (GP). if (Type::isGp16(srcTypeId)) { r1.setRegT(reg.id()); instId = (dstTypeId == Type::kIdI64 && srcTypeId == Type::kIdI16) ? Inst::kIdMovsx : Inst::kIdMovzx; goto ExtendMovGpXQ; } // Extend DWORD->QWORD (GP). if (Type::isGp32(srcTypeId)) { r1.setRegT(reg.id()); instId = Inst::kIdMovsxd; if (dstTypeId == Type::kIdI64 && srcTypeId == Type::kIdI32) goto ExtendMovGpXQ; else goto ZeroExtendGpDQ; } // Move QWORD (GP). if (Type::isGp64(srcTypeId)) goto MovGpQ; if (Type::isMmx(srcTypeId)) goto MovMmQ; if (Type::isVec(srcTypeId)) goto MovXmmQ; break; case Type::kIdI32: case Type::kIdU32: case Type::kIdI16: case Type::kIdU16: // DWORD <- WORD (Zero|Sign Extend). if (Type::isGp16(srcTypeId)) { bool isDstSigned = dstTypeId == Type::kIdI16 || dstTypeId == Type::kIdI32; bool isSrcSigned = srcTypeId == Type::kIdI8 || srcTypeId == Type::kIdI16; r1.setRegT(reg.id()); instId = isDstSigned && isSrcSigned ? Inst::kIdMovsx : Inst::kIdMovzx; goto ExtendMovGpD; } // DWORD <- BYTE (Zero|Sign Extend). if (Type::isGp8(srcTypeId)) { bool isDstSigned = dstTypeId == Type::kIdI16 || dstTypeId == Type::kIdI32; bool isSrcSigned = srcTypeId == Type::kIdI8 || srcTypeId == Type::kIdI16; r1.setRegT(reg.id()); instId = isDstSigned && isSrcSigned ? Inst::kIdMovsx : Inst::kIdMovzx; goto ExtendMovGpD; } ASMJIT_FALLTHROUGH; case Type::kIdI8: case Type::kIdU8: if (Type::isInt(srcTypeId)) goto MovGpD; if (Type::isMmx(srcTypeId)) goto MovMmD; if (Type::isVec(srcTypeId)) goto MovXmmD; break; case Type::kIdMmx32: case Type::kIdMmx64: // Extend BYTE->QWORD (GP). if (Type::isGp8(srcTypeId)) { r1.setRegT(reg.id()); instId = Inst::kIdMovzx; goto ExtendMovGpXQ; } // Extend WORD->QWORD (GP). if (Type::isGp16(srcTypeId)) { r1.setRegT(reg.id()); instId = Inst::kIdMovzx; goto ExtendMovGpXQ; } if (Type::isGp32(srcTypeId)) goto ExtendMovGpDQ; if (Type::isGp64(srcTypeId)) goto MovGpQ; if (Type::isMmx(srcTypeId)) goto MovMmQ; if (Type::isVec(srcTypeId)) goto MovXmmQ; break; case Type::kIdF32: case Type::kIdF32x1: if (Type::isVec(srcTypeId)) goto MovXmmD; break; case Type::kIdF64: case Type::kIdF64x1: if (Type::isVec(srcTypeId)) goto MovXmmQ; break; default: // TODO: Vector types by stack. break; } return DebugUtils::errored(kErrorInvalidState); // Extend+Move Gp. ExtendMovGpD: mem.setSize(4); r0.setRegT(reg.id()); ASMJIT_PROPAGATE(cc()->emit(instId, r0, r1)); ASMJIT_PROPAGATE(cc()->emit(Inst::kIdMov, mem, r0)); return kErrorOk; ExtendMovGpXQ: if (gpSize == 8) { mem.setSize(8); r0.setRegT(reg.id()); ASMJIT_PROPAGATE(cc()->emit(instId, r0, r1)); ASMJIT_PROPAGATE(cc()->emit(Inst::kIdMov, mem, r0)); } else { mem.setSize(4); r0.setRegT(reg.id()); ASMJIT_PROPAGATE(cc()->emit(instId, r0, r1)); ExtendMovGpDQ: ASMJIT_PROPAGATE(cc()->emit(Inst::kIdMov, mem, r0)); mem.addOffsetLo32(4); ASMJIT_PROPAGATE(cc()->emit(Inst::kIdAnd, mem, 0)); } return kErrorOk; ZeroExtendGpDQ: mem.setSize(4); r0.setRegT(reg.id()); goto ExtendMovGpDQ; MovGpD: mem.setSize(4); r0.setRegT(reg.id()); return cc()->emit(Inst::kIdMov, mem, r0); MovGpQ: mem.setSize(8); r0.setRegT(reg.id()); return cc()->emit(Inst::kIdMov, mem, r0); MovMmD: mem.setSize(4); r0.setRegT(reg.id()); return cc()->emit(choose(Inst::kIdMovd, Inst::kIdVmovd), mem, r0); MovMmQ: mem.setSize(8); r0.setRegT(reg.id()); return cc()->emit(choose(Inst::kIdMovq, Inst::kIdVmovq), mem, r0); MovXmmD: mem.setSize(4); r0.setRegT(reg.id()); return cc()->emit(choose(Inst::kIdMovss, Inst::kIdVmovss), mem, r0); MovXmmQ: mem.setSize(8); r0.setRegT(reg.id()); return cc()->emit(choose(Inst::kIdMovlps, Inst::kIdVmovlps), mem, r0); } // ============================================================================ // [asmjit::x86::X86RACFGBuilder - OnReg] // ============================================================================ Error X86RACFGBuilder::onBeforeRet(FuncRetNode* funcRet) noexcept { const FuncDetail& funcDetail = _pass->func()->detail(); const Operand* opArray = funcRet->operands(); uint32_t opCount = funcRet->opCount(); cc()->_setCursor(funcRet->prev()); for (uint32_t i = 0; i < opCount; i++) { const Operand& op = opArray[i]; const FuncValue& ret = funcDetail.ret(i); if (!op.isReg()) continue; if (ret.regType() == Reg::kTypeSt) { const Reg& reg = op.as(); uint32_t vIndex = Operand::virtIdToIndex(reg.id()); if (vIndex < Operand::kVirtIdCount) { RAWorkReg* workReg; ASMJIT_PROPAGATE(_pass->virtIndexAsWorkReg(vIndex, &workReg)); if (workReg->group() != Reg::kGroupVec) return DebugUtils::errored(kErrorInvalidAssignment); Reg src = Reg(workReg->signature(), workReg->virtId()); Mem mem; uint32_t typeId = Type::baseOf(workReg->typeId()); if (ret.hasTypeId()) typeId = ret.typeId(); switch (typeId) { case Type::kIdF32: ASMJIT_PROPAGATE(_pass->useTemporaryMem(mem, 4, 4)); mem.setSize(4); ASMJIT_PROPAGATE(cc()->emit(choose(Inst::kIdMovss, Inst::kIdVmovss), mem, src.as())); ASMJIT_PROPAGATE(cc()->fld(mem)); break; case Type::kIdF64: ASMJIT_PROPAGATE(_pass->useTemporaryMem(mem, 8, 4)); mem.setSize(8); ASMJIT_PROPAGATE(cc()->emit(choose(Inst::kIdMovsd, Inst::kIdVmovsd), mem, src.as())); ASMJIT_PROPAGATE(cc()->fld(mem)); break; default: return DebugUtils::errored(kErrorInvalidAssignment); } } } } return kErrorOk; } Error X86RACFGBuilder::onRet(FuncRetNode* funcRet, RAInstBuilder& ib) noexcept { const FuncDetail& funcDetail = _pass->func()->detail(); const Operand* opArray = funcRet->operands(); uint32_t opCount = funcRet->opCount(); for (uint32_t i = 0; i < opCount; i++) { const Operand& op = opArray[i]; if (op.isNone()) continue; const FuncValue& ret = funcDetail.ret(i); if (ASMJIT_UNLIKELY(!ret.isReg())) return DebugUtils::errored(kErrorInvalidAssignment); // Not handled here... if (ret.regType() == Reg::kTypeSt) continue; if (op.isReg()) { // Register return value. const Reg& reg = op.as(); uint32_t vIndex = Operand::virtIdToIndex(reg.id()); if (vIndex < Operand::kVirtIdCount) { RAWorkReg* workReg; ASMJIT_PROPAGATE(_pass->virtIndexAsWorkReg(vIndex, &workReg)); uint32_t group = workReg->group(); uint32_t allocable = _pass->_availableRegs[group]; ASMJIT_PROPAGATE(ib.add(workReg, RATiedReg::kUse | RATiedReg::kRead, allocable, ret.regId(), 0, BaseReg::kIdBad, 0)); } } else { return DebugUtils::errored(kErrorInvalidAssignment); } } return kErrorOk; } // ============================================================================ // [asmjit::x86::X86RAPass - Construction / Destruction] // ============================================================================ X86RAPass::X86RAPass() noexcept : RAPass(), _avxEnabled(false) {} X86RAPass::~X86RAPass() noexcept {} // ============================================================================ // [asmjit::x86::X86RAPass - OnInit / OnDone] // ============================================================================ void X86RAPass::onInit() noexcept { uint32_t archId = cc()->archId(); uint32_t baseRegCount = archId == ArchInfo::kIdX86 ? 8u : 16u; _archRegsInfo = &opData.archRegs; _archTraits[Reg::kGroupGp] |= RAArchTraits::kHasSwap; _physRegCount.set(Reg::kGroupGp , baseRegCount); _physRegCount.set(Reg::kGroupVec , baseRegCount); _physRegCount.set(Reg::kGroupMm , 8); _physRegCount.set(Reg::kGroupKReg, 8); _buildPhysIndex(); _availableRegCount = _physRegCount; _availableRegs[Reg::kGroupGp ] = Support::lsbMask(_physRegCount.get(Reg::kGroupGp )); _availableRegs[Reg::kGroupVec ] = Support::lsbMask(_physRegCount.get(Reg::kGroupVec )); _availableRegs[Reg::kGroupMm ] = Support::lsbMask(_physRegCount.get(Reg::kGroupMm )); _availableRegs[Reg::kGroupKReg] = Support::lsbMask(_physRegCount.get(Reg::kGroupKReg)); // The architecture specific setup makes implicitly all registers available. So // make unavailable all registers that are special and cannot be used in general. bool hasFP = _func->frame().hasPreservedFP(); makeUnavailable(Reg::kGroupGp, Gp::kIdSp); // ESP|RSP used as a stack-pointer (SP). if (hasFP) makeUnavailable(Reg::kGroupGp, Gp::kIdBp); // EBP|RBP used as a frame-pointer (FP). _sp = cc()->zsp(); _fp = cc()->zbp(); _avxEnabled = _func->frame().isAvxEnabled(); } void X86RAPass::onDone() noexcept {} // ============================================================================ // [asmjit::x86::X86RAPass - BuildCFG] // ============================================================================ Error X86RAPass::buildCFG() noexcept { return X86RACFGBuilder(this).run(); } // ============================================================================ // [asmjit::x86::X86RAPass - OnEmit] // ============================================================================ Error X86RAPass::onEmitMove(uint32_t workId, uint32_t dstPhysId, uint32_t srcPhysId) noexcept { RAWorkReg* wReg = workRegById(workId); BaseReg dst(wReg->info().signature(), dstPhysId); BaseReg src(wReg->info().signature(), srcPhysId); const char* comment = nullptr; #ifndef ASMJIT_NO_LOGGING if (_loggerFlags & FormatOptions::kFlagAnnotations) { _tmpString.assignFormat(" %s", workRegById(workId)->name()); comment = _tmpString.data(); } #endif return X86Internal::emitRegMove(cc()->as(), dst, src, wReg->typeId(), _avxEnabled, comment); } Error X86RAPass::onEmitSwap(uint32_t aWorkId, uint32_t aPhysId, uint32_t bWorkId, uint32_t bPhysId) noexcept { RAWorkReg* waReg = workRegById(aWorkId); RAWorkReg* wbReg = workRegById(bWorkId); bool is64Bit = Support::max(waReg->typeId(), wbReg->typeId()) >= Type::kIdI64; uint32_t sign = is64Bit ? uint32_t(RegTraits::kSignature) : uint32_t(RegTraits::kSignature); #ifndef ASMJIT_NO_LOGGING if (_loggerFlags & FormatOptions::kFlagAnnotations) { _tmpString.assignFormat(" %s, %s", waReg->name(), wbReg->name()); cc()->setInlineComment(_tmpString.data()); } #endif return cc()->emit(Inst::kIdXchg, Reg(sign, aPhysId), Reg(sign, bPhysId)); } Error X86RAPass::onEmitLoad(uint32_t workId, uint32_t dstPhysId) noexcept { RAWorkReg* wReg = workRegById(workId); BaseReg dstReg(wReg->info().signature(), dstPhysId); BaseMem srcMem(workRegAsMem(wReg)); const char* comment = nullptr; #ifndef ASMJIT_NO_LOGGING if (_loggerFlags & FormatOptions::kFlagAnnotations) { _tmpString.assignFormat(" %s", workRegById(workId)->name()); comment = _tmpString.data(); } #endif return X86Internal::emitRegMove(cc()->as(), dstReg, srcMem, wReg->typeId(), _avxEnabled, comment); } Error X86RAPass::onEmitSave(uint32_t workId, uint32_t srcPhysId) noexcept { RAWorkReg* wReg = workRegById(workId); BaseMem dstMem(workRegAsMem(wReg)); BaseReg srcReg(wReg->info().signature(), srcPhysId); const char* comment = nullptr; #ifndef ASMJIT_NO_LOGGING if (_loggerFlags & FormatOptions::kFlagAnnotations) { _tmpString.assignFormat(" %s", workRegById(workId)->name()); comment = _tmpString.data(); } #endif return X86Internal::emitRegMove(cc()->as(), dstMem, srcReg, wReg->typeId(), _avxEnabled, comment); } Error X86RAPass::onEmitJump(const Label& label) noexcept { return cc()->jmp(label); } Error X86RAPass::onEmitPreCall(FuncCallNode* call) noexcept { if (call->detail().hasVarArgs()) { uint32_t argCount = call->argCount(); const FuncDetail& fd = call->detail(); switch (call->detail().callConv().id()) { case CallConv::kIdX86SysV64: { // AL register contains the number of arguments passed in XMM register(s). uint32_t n = 0; for (uint32_t argIndex = 0; argIndex < argCount; argIndex++) { for (uint32_t argHi = 0; argHi <= kFuncArgHi; argHi += kFuncArgHi) { if (!fd.hasArg(argIndex + argHi)) continue; const FuncValue& arg = fd.arg(argIndex + argHi); if (arg.isReg() && Reg::groupOf(arg.regType()) == Reg::kGroupVec) n++; } } if (!n) ASMJIT_PROPAGATE(cc()->xor_(eax, eax)); else ASMJIT_PROPAGATE(cc()->mov(eax, n)); break; } case CallConv::kIdX86Win64: { // Each double-precision argument passed in XMM must be also passed in GP. for (uint32_t argIndex = 0; argIndex < argCount; argIndex++) { for (uint32_t argHi = 0; argHi <= kFuncArgHi; argHi += kFuncArgHi) { if (!fd.hasArg(argIndex + argHi)) continue; const FuncValue& arg = fd.arg(argIndex + argHi); if (arg.isReg() && Reg::groupOf(arg.regType()) == Reg::kGroupVec) { Gp dst = gpq(fd.callConv().passedOrder(Reg::kGroupGp)[argIndex]); Xmm src = xmm(arg.regId()); ASMJIT_PROPAGATE(cc()->emit(choose(Inst::kIdMovq, Inst::kIdVmovq), dst, src)); } } } break; } } } return kErrorOk; } ASMJIT_END_SUB_NAMESPACE #endif // ASMJIT_BUILD_X86 && !ASMJIT_NO_COMPILER