//===-- SerialSnippetGenerator.cpp ------------------------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "SerialSnippetGenerator.h" #include "CodeTemplate.h" #include "MCInstrDescView.h" #include "Target.h" #include #include #include namespace llvm { namespace exegesis { struct ExecutionClass { ExecutionMode Mask; const char *Description; } static const kExecutionClasses[] = { {ExecutionMode::ALWAYS_SERIAL_IMPLICIT_REGS_ALIAS | ExecutionMode::ALWAYS_SERIAL_TIED_REGS_ALIAS, "Repeating a single implicitly serial instruction"}, {ExecutionMode::SERIAL_VIA_EXPLICIT_REGS, "Repeating a single explicitly serial instruction"}, {ExecutionMode::SERIAL_VIA_MEMORY_INSTR | ExecutionMode::SERIAL_VIA_NON_MEMORY_INSTR, "Repeating two instructions"}, }; static constexpr size_t kMaxAliasingInstructions = 10; static std::vector computeAliasingInstructions(const LLVMState &State, const Instruction *Instr, size_t MaxAliasingInstructions, const BitVector &ForbiddenRegisters) { // Randomly iterate the set of instructions. std::vector Opcodes; Opcodes.resize(State.getInstrInfo().getNumOpcodes()); std::iota(Opcodes.begin(), Opcodes.end(), 0U); llvm::shuffle(Opcodes.begin(), Opcodes.end(), randomGenerator()); std::vector AliasingInstructions; for (const unsigned OtherOpcode : Opcodes) { if (OtherOpcode == Instr->Description.getOpcode()) continue; const Instruction &OtherInstr = State.getIC().getInstr(OtherOpcode); const MCInstrDesc &OtherInstrDesc = OtherInstr.Description; // Ignore instructions that we cannot run. if (OtherInstrDesc.isPseudo() || OtherInstrDesc.usesCustomInsertionHook() || OtherInstrDesc.isBranch() || OtherInstrDesc.isIndirectBranch() || OtherInstrDesc.isCall() || OtherInstrDesc.isReturn()) { continue; } if (OtherInstr.hasMemoryOperands()) continue; if (!State.getExegesisTarget().allowAsBackToBack(OtherInstr)) continue; if (Instr->hasAliasingRegistersThrough(OtherInstr, ForbiddenRegisters)) AliasingInstructions.push_back(&OtherInstr); if (AliasingInstructions.size() >= MaxAliasingInstructions) break; } return AliasingInstructions; } static ExecutionMode getExecutionModes(const Instruction &Instr, const BitVector &ForbiddenRegisters) { ExecutionMode EM = ExecutionMode::UNKNOWN; if (Instr.hasAliasingImplicitRegisters()) EM |= ExecutionMode::ALWAYS_SERIAL_IMPLICIT_REGS_ALIAS; if (Instr.hasTiedRegisters()) EM |= ExecutionMode::ALWAYS_SERIAL_TIED_REGS_ALIAS; if (Instr.hasMemoryOperands()) EM |= ExecutionMode::SERIAL_VIA_MEMORY_INSTR; else { if (Instr.hasAliasingRegisters(ForbiddenRegisters)) EM |= ExecutionMode::SERIAL_VIA_EXPLICIT_REGS; if (Instr.hasOneUseOrOneDef()) EM |= ExecutionMode::SERIAL_VIA_NON_MEMORY_INSTR; } return EM; } static void appendCodeTemplates(const LLVMState &State, InstructionTemplate Variant, const BitVector &ForbiddenRegisters, ExecutionMode ExecutionModeBit, StringRef ExecutionClassDescription, std::vector &CodeTemplates) { assert(isEnumValue(ExecutionModeBit) && "Bit must be a power of two"); switch (ExecutionModeBit) { case ExecutionMode::ALWAYS_SERIAL_IMPLICIT_REGS_ALIAS: // Nothing to do, the instruction is always serial. LLVM_FALLTHROUGH; case ExecutionMode::ALWAYS_SERIAL_TIED_REGS_ALIAS: { // Picking whatever value for the tied variable will make the instruction // serial. CodeTemplate CT; CT.Execution = ExecutionModeBit; CT.Info = std::string(ExecutionClassDescription); CT.Instructions.push_back(std::move(Variant)); CodeTemplates.push_back(std::move(CT)); return; } case ExecutionMode::SERIAL_VIA_MEMORY_INSTR: { // Select back-to-back memory instruction. // TODO: Implement me. return; } case ExecutionMode::SERIAL_VIA_EXPLICIT_REGS: { // Making the execution of this instruction serial by selecting one def // register to alias with one use register. const AliasingConfigurations SelfAliasing(Variant.getInstr(), Variant.getInstr()); assert(!SelfAliasing.empty() && !SelfAliasing.hasImplicitAliasing() && "Instr must alias itself explicitly"); // This is a self aliasing instruction so defs and uses are from the same // instance, hence twice Variant in the following call. setRandomAliasing(SelfAliasing, Variant, Variant); CodeTemplate CT; CT.Execution = ExecutionModeBit; CT.Info = std::string(ExecutionClassDescription); CT.Instructions.push_back(std::move(Variant)); CodeTemplates.push_back(std::move(CT)); return; } case ExecutionMode::SERIAL_VIA_NON_MEMORY_INSTR: { const Instruction &Instr = Variant.getInstr(); // Select back-to-back non-memory instruction. for (const auto *OtherInstr : computeAliasingInstructions( State, &Instr, kMaxAliasingInstructions, ForbiddenRegisters)) { const AliasingConfigurations Forward(Instr, *OtherInstr); const AliasingConfigurations Back(*OtherInstr, Instr); InstructionTemplate ThisIT(Variant); InstructionTemplate OtherIT(OtherInstr); if (!Forward.hasImplicitAliasing()) setRandomAliasing(Forward, ThisIT, OtherIT); else if (!Back.hasImplicitAliasing()) setRandomAliasing(Back, OtherIT, ThisIT); CodeTemplate CT; CT.Execution = ExecutionModeBit; CT.Info = std::string(ExecutionClassDescription); CT.Instructions.push_back(std::move(ThisIT)); CT.Instructions.push_back(std::move(OtherIT)); CodeTemplates.push_back(std::move(CT)); } return; } default: llvm_unreachable("Unhandled enum value"); } } SerialSnippetGenerator::~SerialSnippetGenerator() = default; Expected> SerialSnippetGenerator::generateCodeTemplates( InstructionTemplate Variant, const BitVector &ForbiddenRegisters) const { std::vector Results; const ExecutionMode EM = getExecutionModes(Variant.getInstr(), ForbiddenRegisters); for (const auto EC : kExecutionClasses) { for (const auto ExecutionModeBit : getExecutionModeBits(EM & EC.Mask)) appendCodeTemplates(State, Variant, ForbiddenRegisters, ExecutionModeBit, EC.Description, Results); if (!Results.empty()) break; } if (Results.empty()) return make_error( "No strategy found to make the execution serial"); return std::move(Results); } } // namespace exegesis } // namespace llvm