mirror of
https://github.com/KhronosGroup/SPIRV-Tools
synced 2024-11-26 05:10:05 +00:00
1a7f71afb4
Constexpr guaranteed no runtime init in addition to const semantics. Moving all opt/ to constexpr. Moving all compile-unit statics to anonymous namespaces to uniformize the method used (anonymous namespace vs static has the same behavior here AFAIK). Signed-off-by: Nathan Gauër <brioche@google.com>
510 lines
17 KiB
C++
510 lines
17 KiB
C++
// Copyright (c) 2017 The Khronos Group Inc.
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// Copyright (c) 2017 Valve Corporation
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// Copyright (c) 2017 LunarG Inc.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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#include "source/opt/mem_pass.h"
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#include <memory>
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#include <set>
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#include <vector>
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#include "source/cfa.h"
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#include "source/opt/basic_block.h"
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#include "source/opt/dominator_analysis.h"
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#include "source/opt/ir_context.h"
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#include "source/opt/iterator.h"
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namespace spvtools {
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namespace opt {
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namespace {
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constexpr uint32_t kCopyObjectOperandInIdx = 0;
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constexpr uint32_t kTypePointerStorageClassInIdx = 0;
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constexpr uint32_t kTypePointerTypeIdInIdx = 1;
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} // namespace
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bool MemPass::IsBaseTargetType(const Instruction* typeInst) const {
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switch (typeInst->opcode()) {
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case spv::Op::OpTypeInt:
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case spv::Op::OpTypeFloat:
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case spv::Op::OpTypeBool:
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case spv::Op::OpTypeVector:
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case spv::Op::OpTypeMatrix:
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case spv::Op::OpTypeImage:
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case spv::Op::OpTypeSampler:
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case spv::Op::OpTypeSampledImage:
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case spv::Op::OpTypePointer:
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return true;
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default:
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break;
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}
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return false;
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}
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bool MemPass::IsTargetType(const Instruction* typeInst) const {
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if (IsBaseTargetType(typeInst)) return true;
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if (typeInst->opcode() == spv::Op::OpTypeArray) {
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if (!IsTargetType(
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get_def_use_mgr()->GetDef(typeInst->GetSingleWordOperand(1)))) {
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return false;
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}
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return true;
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}
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if (typeInst->opcode() != spv::Op::OpTypeStruct) return false;
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// All struct members must be math type
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return typeInst->WhileEachInId([this](const uint32_t* tid) {
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Instruction* compTypeInst = get_def_use_mgr()->GetDef(*tid);
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if (!IsTargetType(compTypeInst)) return false;
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return true;
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});
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}
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bool MemPass::IsNonPtrAccessChain(const spv::Op opcode) const {
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return opcode == spv::Op::OpAccessChain ||
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opcode == spv::Op::OpInBoundsAccessChain;
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}
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bool MemPass::IsPtr(uint32_t ptrId) {
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uint32_t varId = ptrId;
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Instruction* ptrInst = get_def_use_mgr()->GetDef(varId);
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while (ptrInst->opcode() == spv::Op::OpCopyObject) {
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varId = ptrInst->GetSingleWordInOperand(kCopyObjectOperandInIdx);
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ptrInst = get_def_use_mgr()->GetDef(varId);
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}
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const spv::Op op = ptrInst->opcode();
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if (op == spv::Op::OpVariable || IsNonPtrAccessChain(op)) return true;
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const uint32_t varTypeId = ptrInst->type_id();
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if (varTypeId == 0) return false;
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const Instruction* varTypeInst = get_def_use_mgr()->GetDef(varTypeId);
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return varTypeInst->opcode() == spv::Op::OpTypePointer;
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}
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Instruction* MemPass::GetPtr(uint32_t ptrId, uint32_t* varId) {
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*varId = ptrId;
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Instruction* ptrInst = get_def_use_mgr()->GetDef(*varId);
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Instruction* varInst;
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if (ptrInst->opcode() == spv::Op::OpConstantNull) {
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*varId = 0;
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return ptrInst;
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}
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if (ptrInst->opcode() != spv::Op::OpVariable &&
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ptrInst->opcode() != spv::Op::OpFunctionParameter) {
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varInst = ptrInst->GetBaseAddress();
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} else {
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varInst = ptrInst;
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}
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if (varInst->opcode() == spv::Op::OpVariable) {
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*varId = varInst->result_id();
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} else {
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*varId = 0;
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}
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while (ptrInst->opcode() == spv::Op::OpCopyObject) {
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uint32_t temp = ptrInst->GetSingleWordInOperand(0);
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ptrInst = get_def_use_mgr()->GetDef(temp);
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}
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return ptrInst;
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}
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Instruction* MemPass::GetPtr(Instruction* ip, uint32_t* varId) {
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assert(ip->opcode() == spv::Op::OpStore || ip->opcode() == spv::Op::OpLoad ||
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ip->opcode() == spv::Op::OpImageTexelPointer ||
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ip->IsAtomicWithLoad());
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// All of these opcode place the pointer in position 0.
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const uint32_t ptrId = ip->GetSingleWordInOperand(0);
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return GetPtr(ptrId, varId);
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}
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bool MemPass::HasOnlyNamesAndDecorates(uint32_t id) const {
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return get_def_use_mgr()->WhileEachUser(id, [this](Instruction* user) {
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spv::Op op = user->opcode();
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if (op != spv::Op::OpName && !IsNonTypeDecorate(op)) {
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return false;
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}
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return true;
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});
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}
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void MemPass::KillAllInsts(BasicBlock* bp, bool killLabel) {
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bp->KillAllInsts(killLabel);
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}
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bool MemPass::HasLoads(uint32_t varId) const {
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return !get_def_use_mgr()->WhileEachUser(varId, [this](Instruction* user) {
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spv::Op op = user->opcode();
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// TODO(): The following is slightly conservative. Could be
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// better handling of non-store/name.
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if (IsNonPtrAccessChain(op) || op == spv::Op::OpCopyObject) {
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if (HasLoads(user->result_id())) {
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return false;
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}
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} else if (op != spv::Op::OpStore && op != spv::Op::OpName &&
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!IsNonTypeDecorate(op)) {
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return false;
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}
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return true;
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});
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}
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bool MemPass::IsLiveVar(uint32_t varId) const {
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const Instruction* varInst = get_def_use_mgr()->GetDef(varId);
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// assume live if not a variable eg. function parameter
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if (varInst->opcode() != spv::Op::OpVariable) return true;
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// non-function scope vars are live
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const uint32_t varTypeId = varInst->type_id();
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const Instruction* varTypeInst = get_def_use_mgr()->GetDef(varTypeId);
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if (spv::StorageClass(varTypeInst->GetSingleWordInOperand(
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kTypePointerStorageClassInIdx)) != spv::StorageClass::Function)
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return true;
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// test if variable is loaded from
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return HasLoads(varId);
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}
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void MemPass::AddStores(uint32_t ptr_id, std::queue<Instruction*>* insts) {
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get_def_use_mgr()->ForEachUser(ptr_id, [this, insts](Instruction* user) {
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spv::Op op = user->opcode();
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if (IsNonPtrAccessChain(op)) {
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AddStores(user->result_id(), insts);
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} else if (op == spv::Op::OpStore) {
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insts->push(user);
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}
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});
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}
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void MemPass::DCEInst(Instruction* inst,
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const std::function<void(Instruction*)>& call_back) {
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std::queue<Instruction*> deadInsts;
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deadInsts.push(inst);
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while (!deadInsts.empty()) {
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Instruction* di = deadInsts.front();
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// Don't delete labels
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if (di->opcode() == spv::Op::OpLabel) {
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deadInsts.pop();
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continue;
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}
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// Remember operands
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std::set<uint32_t> ids;
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di->ForEachInId([&ids](uint32_t* iid) { ids.insert(*iid); });
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uint32_t varId = 0;
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// Remember variable if dead load
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if (di->opcode() == spv::Op::OpLoad) (void)GetPtr(di, &varId);
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if (call_back) {
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call_back(di);
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}
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context()->KillInst(di);
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// For all operands with no remaining uses, add their instruction
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// to the dead instruction queue.
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for (auto id : ids)
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if (HasOnlyNamesAndDecorates(id)) {
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Instruction* odi = get_def_use_mgr()->GetDef(id);
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if (context()->IsCombinatorInstruction(odi)) deadInsts.push(odi);
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}
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// if a load was deleted and it was the variable's
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// last load, add all its stores to dead queue
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if (varId != 0 && !IsLiveVar(varId)) AddStores(varId, &deadInsts);
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deadInsts.pop();
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}
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}
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MemPass::MemPass() {}
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bool MemPass::HasOnlySupportedRefs(uint32_t varId) {
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return get_def_use_mgr()->WhileEachUser(varId, [this](Instruction* user) {
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auto dbg_op = user->GetCommonDebugOpcode();
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if (dbg_op == CommonDebugInfoDebugDeclare ||
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dbg_op == CommonDebugInfoDebugValue) {
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return true;
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}
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spv::Op op = user->opcode();
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if (op != spv::Op::OpStore && op != spv::Op::OpLoad &&
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op != spv::Op::OpName && !IsNonTypeDecorate(op)) {
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return false;
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}
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return true;
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});
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}
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uint32_t MemPass::Type2Undef(uint32_t type_id) {
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const auto uitr = type2undefs_.find(type_id);
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if (uitr != type2undefs_.end()) return uitr->second;
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const uint32_t undefId = TakeNextId();
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if (undefId == 0) {
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return 0;
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}
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std::unique_ptr<Instruction> undef_inst(
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new Instruction(context(), spv::Op::OpUndef, type_id, undefId, {}));
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get_def_use_mgr()->AnalyzeInstDefUse(&*undef_inst);
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get_module()->AddGlobalValue(std::move(undef_inst));
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type2undefs_[type_id] = undefId;
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return undefId;
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}
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bool MemPass::IsTargetVar(uint32_t varId) {
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if (varId == 0) {
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return false;
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}
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if (seen_non_target_vars_.find(varId) != seen_non_target_vars_.end())
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return false;
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if (seen_target_vars_.find(varId) != seen_target_vars_.end()) return true;
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const Instruction* varInst = get_def_use_mgr()->GetDef(varId);
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if (varInst->opcode() != spv::Op::OpVariable) return false;
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const uint32_t varTypeId = varInst->type_id();
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const Instruction* varTypeInst = get_def_use_mgr()->GetDef(varTypeId);
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if (spv::StorageClass(varTypeInst->GetSingleWordInOperand(
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kTypePointerStorageClassInIdx)) != spv::StorageClass::Function) {
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seen_non_target_vars_.insert(varId);
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return false;
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}
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const uint32_t varPteTypeId =
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varTypeInst->GetSingleWordInOperand(kTypePointerTypeIdInIdx);
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Instruction* varPteTypeInst = get_def_use_mgr()->GetDef(varPteTypeId);
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if (!IsTargetType(varPteTypeInst)) {
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seen_non_target_vars_.insert(varId);
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return false;
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}
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seen_target_vars_.insert(varId);
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return true;
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}
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// Remove all |phi| operands coming from unreachable blocks (i.e., blocks not in
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// |reachable_blocks|). There are two types of removal that this function can
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// perform:
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//
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// 1- Any operand that comes directly from an unreachable block is completely
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// removed. Since the block is unreachable, the edge between the unreachable
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// block and the block holding |phi| has been removed.
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//
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// 2- Any operand that comes via a live block and was defined at an unreachable
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// block gets its value replaced with an OpUndef value. Since the argument
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// was generated in an unreachable block, it no longer exists, so it cannot
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// be referenced. However, since the value does not reach |phi| directly
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// from the unreachable block, the operand cannot be removed from |phi|.
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// Therefore, we replace the argument value with OpUndef.
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//
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// For example, in the switch() below, assume that we want to remove the
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// argument with value %11 coming from block %41.
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//
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// [ ... ]
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// %41 = OpLabel <--- Unreachable block
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// %11 = OpLoad %int %y
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// [ ... ]
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// OpSelectionMerge %16 None
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// OpSwitch %12 %16 10 %13 13 %14 18 %15
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// %13 = OpLabel
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// OpBranch %16
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// %14 = OpLabel
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// OpStore %outparm %int_14
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// OpBranch %16
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// %15 = OpLabel
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// OpStore %outparm %int_15
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// OpBranch %16
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// %16 = OpLabel
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// %30 = OpPhi %int %11 %41 %int_42 %13 %11 %14 %11 %15
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//
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// Since %41 is now an unreachable block, the first operand of |phi| needs to
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// be removed completely. But the operands (%11 %14) and (%11 %15) cannot be
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// removed because %14 and %15 are reachable blocks. Since %11 no longer exist,
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// in those arguments, we replace all references to %11 with an OpUndef value.
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// This results in |phi| looking like:
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//
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// %50 = OpUndef %int
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// [ ... ]
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// %30 = OpPhi %int %int_42 %13 %50 %14 %50 %15
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void MemPass::RemovePhiOperands(
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Instruction* phi, const std::unordered_set<BasicBlock*>& reachable_blocks) {
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std::vector<Operand> keep_operands;
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uint32_t type_id = 0;
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// The id of an undefined value we've generated.
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uint32_t undef_id = 0;
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// Traverse all the operands in |phi|. Build the new operand vector by adding
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// all the original operands from |phi| except the unwanted ones.
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for (uint32_t i = 0; i < phi->NumOperands();) {
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if (i < 2) {
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// The first two arguments are always preserved.
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keep_operands.push_back(phi->GetOperand(i));
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++i;
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continue;
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}
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// The remaining Phi arguments come in pairs. Index 'i' contains the
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// variable id, index 'i + 1' is the originating block id.
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assert(i % 2 == 0 && i < phi->NumOperands() - 1 &&
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"malformed Phi arguments");
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BasicBlock* in_block = cfg()->block(phi->GetSingleWordOperand(i + 1));
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if (reachable_blocks.find(in_block) == reachable_blocks.end()) {
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// If the incoming block is unreachable, remove both operands as this
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// means that the |phi| has lost an incoming edge.
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i += 2;
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continue;
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}
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// In all other cases, the operand must be kept but may need to be changed.
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uint32_t arg_id = phi->GetSingleWordOperand(i);
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Instruction* arg_def_instr = get_def_use_mgr()->GetDef(arg_id);
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BasicBlock* def_block = context()->get_instr_block(arg_def_instr);
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if (def_block &&
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reachable_blocks.find(def_block) == reachable_blocks.end()) {
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// If the current |phi| argument was defined in an unreachable block, it
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// means that this |phi| argument is no longer defined. Replace it with
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// |undef_id|.
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if (!undef_id) {
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type_id = arg_def_instr->type_id();
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undef_id = Type2Undef(type_id);
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}
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keep_operands.push_back(
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Operand(spv_operand_type_t::SPV_OPERAND_TYPE_ID, {undef_id}));
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} else {
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// Otherwise, the argument comes from a reachable block or from no block
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// at all (meaning that it was defined in the global section of the
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// program). In both cases, keep the argument intact.
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keep_operands.push_back(phi->GetOperand(i));
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}
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keep_operands.push_back(phi->GetOperand(i + 1));
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i += 2;
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}
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context()->ForgetUses(phi);
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phi->ReplaceOperands(keep_operands);
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context()->AnalyzeUses(phi);
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}
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void MemPass::RemoveBlock(Function::iterator* bi) {
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auto& rm_block = **bi;
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// Remove instructions from the block.
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rm_block.ForEachInst([&rm_block, this](Instruction* inst) {
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// Note that we do not kill the block label instruction here. The label
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// instruction is needed to identify the block, which is needed by the
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// removal of phi operands.
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if (inst != rm_block.GetLabelInst()) {
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context()->KillInst(inst);
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}
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});
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// Remove the label instruction last.
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auto label = rm_block.GetLabelInst();
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context()->KillInst(label);
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*bi = bi->Erase();
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}
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bool MemPass::RemoveUnreachableBlocks(Function* func) {
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bool modified = false;
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// Mark reachable all blocks reachable from the function's entry block.
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std::unordered_set<BasicBlock*> reachable_blocks;
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std::unordered_set<BasicBlock*> visited_blocks;
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std::queue<BasicBlock*> worklist;
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reachable_blocks.insert(func->entry().get());
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// Initially mark the function entry point as reachable.
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worklist.push(func->entry().get());
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auto mark_reachable = [&reachable_blocks, &visited_blocks, &worklist,
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this](uint32_t label_id) {
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auto successor = cfg()->block(label_id);
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if (visited_blocks.count(successor) == 0) {
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reachable_blocks.insert(successor);
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worklist.push(successor);
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visited_blocks.insert(successor);
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}
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};
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// Transitively mark all blocks reachable from the entry as reachable.
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while (!worklist.empty()) {
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BasicBlock* block = worklist.front();
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worklist.pop();
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// All the successors of a live block are also live.
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static_cast<const BasicBlock*>(block)->ForEachSuccessorLabel(
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mark_reachable);
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// All the Merge and ContinueTarget blocks of a live block are also live.
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block->ForMergeAndContinueLabel(mark_reachable);
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}
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// Update operands of Phi nodes that reference unreachable blocks.
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for (auto& block : *func) {
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// If the block is about to be removed, don't bother updating its
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// Phi instructions.
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if (reachable_blocks.count(&block) == 0) {
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continue;
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}
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// If the block is reachable and has Phi instructions, remove all
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// operands from its Phi instructions that reference unreachable blocks.
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// If the block has no Phi instructions, this is a no-op.
|
|
block.ForEachPhiInst([&reachable_blocks, this](Instruction* phi) {
|
|
RemovePhiOperands(phi, reachable_blocks);
|
|
});
|
|
}
|
|
|
|
// Erase unreachable blocks.
|
|
for (auto ebi = func->begin(); ebi != func->end();) {
|
|
if (reachable_blocks.count(&*ebi) == 0) {
|
|
RemoveBlock(&ebi);
|
|
modified = true;
|
|
} else {
|
|
++ebi;
|
|
}
|
|
}
|
|
|
|
return modified;
|
|
}
|
|
|
|
bool MemPass::CFGCleanup(Function* func) {
|
|
bool modified = false;
|
|
modified |= RemoveUnreachableBlocks(func);
|
|
return modified;
|
|
}
|
|
|
|
void MemPass::CollectTargetVars(Function* func) {
|
|
seen_target_vars_.clear();
|
|
seen_non_target_vars_.clear();
|
|
type2undefs_.clear();
|
|
|
|
// Collect target (and non-) variable sets. Remove variables with
|
|
// non-load/store refs from target variable set
|
|
for (auto& blk : *func) {
|
|
for (auto& inst : blk) {
|
|
switch (inst.opcode()) {
|
|
case spv::Op::OpStore:
|
|
case spv::Op::OpLoad: {
|
|
uint32_t varId;
|
|
(void)GetPtr(&inst, &varId);
|
|
if (!IsTargetVar(varId)) break;
|
|
if (HasOnlySupportedRefs(varId)) break;
|
|
seen_non_target_vars_.insert(varId);
|
|
seen_target_vars_.erase(varId);
|
|
} break;
|
|
default:
|
|
break;
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
} // namespace opt
|
|
} // namespace spvtools
|