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path: root/src/shader_recompiler/frontend/ir/microinstruction.cpp
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// Copyright 2021 yuzu Emulator Project
// Licensed under GPLv2 or any later version
// Refer to the license.txt file included.

#include <algorithm>
#include <memory>

#include "shader_recompiler/exception.h"
#include "shader_recompiler/frontend/ir/microinstruction.h"
#include "shader_recompiler/frontend/ir/type.h"

namespace Shader::IR {
namespace {
void CheckPseudoInstruction(IR::Inst* inst, IR::Opcode opcode) {
    if (inst && inst->Opcode() != opcode) {
        throw LogicError("Invalid pseudo-instruction");
    }
}

void SetPseudoInstruction(IR::Inst*& dest_inst, IR::Inst* pseudo_inst) {
    if (dest_inst) {
        throw LogicError("Only one of each type of pseudo-op allowed");
    }
    dest_inst = pseudo_inst;
}

void RemovePseudoInstruction(IR::Inst*& inst, IR::Opcode expected_opcode) {
    if (inst->Opcode() != expected_opcode) {
        throw LogicError("Undoing use of invalid pseudo-op");
    }
    inst = nullptr;
}
} // Anonymous namespace

Inst::Inst(IR::Opcode op_, u32 flags_) noexcept : op{op_}, flags{flags_} {
    if (op == Opcode::Phi) {
        std::construct_at(&phi_args);
    } else {
        std::construct_at(&args);
    }
}

Inst::~Inst() {
    if (op == Opcode::Phi) {
        std::destroy_at(&phi_args);
    } else {
        std::destroy_at(&args);
    }
}

bool Inst::MayHaveSideEffects() const noexcept {
    switch (op) {
    case Opcode::Branch:
    case Opcode::BranchConditional:
    case Opcode::LoopMerge:
    case Opcode::SelectionMerge:
    case Opcode::Return:
    case Opcode::Unreachable:
    case Opcode::DemoteToHelperInvocation:
    case Opcode::Barrier:
    case Opcode::MemoryBarrierWorkgroupLevel:
    case Opcode::MemoryBarrierDeviceLevel:
    case Opcode::MemoryBarrierSystemLevel:
    case Opcode::Prologue:
    case Opcode::Epilogue:
    case Opcode::SetAttribute:
    case Opcode::SetAttributeIndexed:
    case Opcode::SetFragColor:
    case Opcode::SetFragDepth:
    case Opcode::WriteGlobalU8:
    case Opcode::WriteGlobalS8:
    case Opcode::WriteGlobalU16:
    case Opcode::WriteGlobalS16:
    case Opcode::WriteGlobal32:
    case Opcode::WriteGlobal64:
    case Opcode::WriteGlobal128:
    case Opcode::WriteStorageU8:
    case Opcode::WriteStorageS8:
    case Opcode::WriteStorageU16:
    case Opcode::WriteStorageS16:
    case Opcode::WriteStorage32:
    case Opcode::WriteStorage64:
    case Opcode::WriteStorage128:
    case Opcode::WriteLocal:
    case Opcode::WriteSharedU8:
    case Opcode::WriteSharedU16:
    case Opcode::WriteSharedU32:
    case Opcode::WriteSharedU64:
    case Opcode::WriteSharedU128:
        return true;
    default:
        return false;
    }
}

bool Inst::IsPseudoInstruction() const noexcept {
    switch (op) {
    case Opcode::GetZeroFromOp:
    case Opcode::GetSignFromOp:
    case Opcode::GetCarryFromOp:
    case Opcode::GetOverflowFromOp:
    case Opcode::GetSparseFromOp:
    case Opcode::GetInBoundsFromOp:
        return true;
    default:
        return false;
    }
}

bool Inst::AreAllArgsImmediates() const {
    if (op == Opcode::Phi) {
        throw LogicError("Testing for all arguments are immediates on phi instruction");
    }
    return std::all_of(args.begin(), args.begin() + NumArgs(),
                       [](const IR::Value& value) { return value.IsImmediate(); });
}

Inst* Inst::GetAssociatedPseudoOperation(IR::Opcode opcode) {
    if (!associated_insts) {
        return nullptr;
    }
    switch (opcode) {
    case Opcode::GetZeroFromOp:
        CheckPseudoInstruction(associated_insts->zero_inst, Opcode::GetZeroFromOp);
        return associated_insts->zero_inst;
    case Opcode::GetSignFromOp:
        CheckPseudoInstruction(associated_insts->sign_inst, Opcode::GetSignFromOp);
        return associated_insts->sign_inst;
    case Opcode::GetCarryFromOp:
        CheckPseudoInstruction(associated_insts->carry_inst, Opcode::GetCarryFromOp);
        return associated_insts->carry_inst;
    case Opcode::GetOverflowFromOp:
        CheckPseudoInstruction(associated_insts->overflow_inst, Opcode::GetOverflowFromOp);
        return associated_insts->overflow_inst;
    case Opcode::GetSparseFromOp:
        CheckPseudoInstruction(associated_insts->sparse_inst, Opcode::GetSparseFromOp);
        return associated_insts->sparse_inst;
    case Opcode::GetInBoundsFromOp:
        CheckPseudoInstruction(associated_insts->in_bounds_inst, Opcode::GetInBoundsFromOp);
        return associated_insts->in_bounds_inst;
    default:
        throw InvalidArgument("{} is not a pseudo-instruction", opcode);
    }
}

size_t Inst::NumArgs() const {
    return op == Opcode::Phi ? phi_args.size() : NumArgsOf(op);
}

IR::Type Inst::Type() const {
    return TypeOf(op);
}

Value Inst::Arg(size_t index) const {
    if (op == Opcode::Phi) {
        if (index >= phi_args.size()) {
            throw InvalidArgument("Out of bounds argument index {} in phi instruction", index);
        }
        return phi_args[index].second;
    } else {
        if (index >= NumArgsOf(op)) {
            throw InvalidArgument("Out of bounds argument index {} in opcode {}", index, op);
        }
        return args[index];
    }
}

void Inst::SetArg(size_t index, Value value) {
    if (index >= NumArgs()) {
        throw InvalidArgument("Out of bounds argument index {} in opcode {}", index, op);
    }
    const IR::Value arg{Arg(index)};
    if (!arg.IsImmediate()) {
        UndoUse(arg);
    }
    if (!value.IsImmediate()) {
        Use(value);
    }
    if (op == Opcode::Phi) {
        phi_args[index].second = value;
    } else {
        args[index] = value;
    }
}

Block* Inst::PhiBlock(size_t index) const {
    if (op != Opcode::Phi) {
        throw LogicError("{} is not a Phi instruction", op);
    }
    if (index >= phi_args.size()) {
        throw InvalidArgument("Out of bounds argument index {} in phi instruction");
    }
    return phi_args[index].first;
}

void Inst::AddPhiOperand(Block* predecessor, const Value& value) {
    if (!value.IsImmediate()) {
        Use(value);
    }
    if (Flags<IR::Type>() == IR::Type::Void) {
        // Set the type of the phi node
        SetFlags<IR::Type>(value.Type());
    }
    phi_args.emplace_back(predecessor, value);
}

void Inst::Invalidate() {
    ClearArgs();
    ReplaceOpcode(Opcode::Void);
}

void Inst::ClearArgs() {
    if (op == Opcode::Phi) {
        for (auto& pair : phi_args) {
            IR::Value& value{pair.second};
            if (!value.IsImmediate()) {
                UndoUse(value);
            }
        }
        phi_args.clear();
    } else {
        for (auto& value : args) {
            if (!value.IsImmediate()) {
                UndoUse(value);
            }
            value = {};
        }
    }
}

void Inst::ReplaceUsesWith(Value replacement) {
    Invalidate();
    ReplaceOpcode(Opcode::Identity);
    if (!replacement.IsImmediate()) {
        Use(replacement);
    }
    args[0] = replacement;
}

void Inst::ReplaceOpcode(IR::Opcode opcode) {
    if (opcode == IR::Opcode::Phi) {
        throw LogicError("Cannot transition into Phi");
    }
    if (op == Opcode::Phi) {
        // Transition out of phi arguments into non-phi
        std::destroy_at(&phi_args);
        std::construct_at(&args);
    }
    op = opcode;
}

void AllocAssociatedInsts(std::unique_ptr<AssociatedInsts>& associated_insts) {
    if (!associated_insts) {
        associated_insts = std::make_unique<AssociatedInsts>();
    }
}

void Inst::Use(const Value& value) {
    Inst* const inst{value.Inst()};
    ++inst->use_count;

    std::unique_ptr<AssociatedInsts>& assoc_inst{inst->associated_insts};
    switch (op) {
    case Opcode::GetZeroFromOp:
        AllocAssociatedInsts(assoc_inst);
        SetPseudoInstruction(assoc_inst->zero_inst, this);
        break;
    case Opcode::GetSignFromOp:
        AllocAssociatedInsts(assoc_inst);
        SetPseudoInstruction(assoc_inst->sign_inst, this);
        break;
    case Opcode::GetCarryFromOp:
        AllocAssociatedInsts(assoc_inst);
        SetPseudoInstruction(assoc_inst->carry_inst, this);
        break;
    case Opcode::GetOverflowFromOp:
        AllocAssociatedInsts(assoc_inst);
        SetPseudoInstruction(assoc_inst->overflow_inst, this);
        break;
    case Opcode::GetSparseFromOp:
        AllocAssociatedInsts(assoc_inst);
        SetPseudoInstruction(assoc_inst->sparse_inst, this);
        break;
    case Opcode::GetInBoundsFromOp:
        AllocAssociatedInsts(assoc_inst);
        SetPseudoInstruction(assoc_inst->in_bounds_inst, this);
        break;
    default:
        break;
    }
}

void Inst::UndoUse(const Value& value) {
    Inst* const inst{value.Inst()};
    --inst->use_count;

    std::unique_ptr<AssociatedInsts>& assoc_inst{inst->associated_insts};
    switch (op) {
    case Opcode::GetZeroFromOp:
        AllocAssociatedInsts(assoc_inst);
        RemovePseudoInstruction(assoc_inst->zero_inst, Opcode::GetZeroFromOp);
        break;
    case Opcode::GetSignFromOp:
        AllocAssociatedInsts(assoc_inst);
        RemovePseudoInstruction(assoc_inst->sign_inst, Opcode::GetSignFromOp);
        break;
    case Opcode::GetCarryFromOp:
        AllocAssociatedInsts(assoc_inst);
        RemovePseudoInstruction(assoc_inst->carry_inst, Opcode::GetCarryFromOp);
        break;
    case Opcode::GetOverflowFromOp:
        AllocAssociatedInsts(assoc_inst);
        RemovePseudoInstruction(assoc_inst->overflow_inst, Opcode::GetOverflowFromOp);
        break;
    case Opcode::GetInBoundsFromOp:
        AllocAssociatedInsts(assoc_inst);
        RemovePseudoInstruction(assoc_inst->in_bounds_inst, Opcode::GetInBoundsFromOp);
        break;
    default:
        break;
    }
}

} // namespace Shader::IR