bgfx/3rdparty/spirv-tools/source/opt/loop_fusion.cpp
Бранимир Караџић 2d52b5f9af Updated spirv-tools.
2023-01-14 18:27:08 -08:00

734 lines
24 KiB
C++

// Copyright (c) 2018 Google LLC.
//
// 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.
#include "source/opt/loop_fusion.h"
#include <algorithm>
#include <vector>
#include "source/opt/ir_context.h"
#include "source/opt/loop_dependence.h"
#include "source/opt/loop_descriptor.h"
namespace spvtools {
namespace opt {
namespace {
// Append all the loops nested in |loop| to |loops|.
void CollectChildren(Loop* loop, std::vector<const Loop*>* loops) {
for (auto child : *loop) {
loops->push_back(child);
if (child->NumImmediateChildren() != 0) {
CollectChildren(child, loops);
}
}
}
// Return the set of locations accessed by |stores| and |loads|.
std::set<Instruction*> GetLocationsAccessed(
const std::map<Instruction*, std::vector<Instruction*>>& stores,
const std::map<Instruction*, std::vector<Instruction*>>& loads) {
std::set<Instruction*> locations{};
for (const auto& kv : stores) {
locations.insert(std::get<0>(kv));
}
for (const auto& kv : loads) {
locations.insert(std::get<0>(kv));
}
return locations;
}
// Append all dependences from |sources| to |destinations| to |dependences|.
void GetDependences(std::vector<DistanceVector>* dependences,
LoopDependenceAnalysis* analysis,
const std::vector<Instruction*>& sources,
const std::vector<Instruction*>& destinations,
size_t num_entries) {
for (auto source : sources) {
for (auto destination : destinations) {
DistanceVector dist(num_entries);
if (!analysis->GetDependence(source, destination, &dist)) {
dependences->push_back(dist);
}
}
}
}
// Apped all instructions in |block| to |instructions|.
void AddInstructionsInBlock(std::vector<Instruction*>* instructions,
BasicBlock* block) {
for (auto& inst : *block) {
instructions->push_back(&inst);
}
instructions->push_back(block->GetLabelInst());
}
} // namespace
bool LoopFusion::UsedInContinueOrConditionBlock(Instruction* phi_instruction,
Loop* loop) {
auto condition_block = loop->FindConditionBlock()->id();
auto continue_block = loop->GetContinueBlock()->id();
auto not_used = context_->get_def_use_mgr()->WhileEachUser(
phi_instruction,
[this, condition_block, continue_block](Instruction* instruction) {
auto block_id = context_->get_instr_block(instruction)->id();
return block_id != condition_block && block_id != continue_block;
});
return !not_used;
}
void LoopFusion::RemoveIfNotUsedContinueOrConditionBlock(
std::vector<Instruction*>* instructions, Loop* loop) {
instructions->erase(
std::remove_if(std::begin(*instructions), std::end(*instructions),
[this, loop](Instruction* instruction) {
return !UsedInContinueOrConditionBlock(instruction,
loop);
}),
std::end(*instructions));
}
bool LoopFusion::AreCompatible() {
// Check that the loops are in the same function.
if (loop_0_->GetHeaderBlock()->GetParent() !=
loop_1_->GetHeaderBlock()->GetParent()) {
return false;
}
// Check that both loops have pre-header blocks.
if (!loop_0_->GetPreHeaderBlock() || !loop_1_->GetPreHeaderBlock()) {
return false;
}
// Check there are no breaks.
if (context_->cfg()->preds(loop_0_->GetMergeBlock()->id()).size() != 1 ||
context_->cfg()->preds(loop_1_->GetMergeBlock()->id()).size() != 1) {
return false;
}
// Check there are no continues.
if (context_->cfg()->preds(loop_0_->GetContinueBlock()->id()).size() != 1 ||
context_->cfg()->preds(loop_1_->GetContinueBlock()->id()).size() != 1) {
return false;
}
// |GetInductionVariables| returns all OpPhi in the header. Check that both
// loops have exactly one that is used in the continue and condition blocks.
std::vector<Instruction*> inductions_0{}, inductions_1{};
loop_0_->GetInductionVariables(inductions_0);
RemoveIfNotUsedContinueOrConditionBlock(&inductions_0, loop_0_);
if (inductions_0.size() != 1) {
return false;
}
induction_0_ = inductions_0.front();
loop_1_->GetInductionVariables(inductions_1);
RemoveIfNotUsedContinueOrConditionBlock(&inductions_1, loop_1_);
if (inductions_1.size() != 1) {
return false;
}
induction_1_ = inductions_1.front();
if (!CheckInit()) {
return false;
}
if (!CheckCondition()) {
return false;
}
if (!CheckStep()) {
return false;
}
// Check adjacency, |loop_0_| should come just before |loop_1_|.
// There is always at least one block between loops, even if it's empty.
// We'll check at most 2 preceding blocks.
auto pre_header_1 = loop_1_->GetPreHeaderBlock();
std::vector<BasicBlock*> block_to_check{};
block_to_check.push_back(pre_header_1);
if (loop_0_->GetMergeBlock() != loop_1_->GetPreHeaderBlock()) {
// Follow CFG for one more block.
auto preds = context_->cfg()->preds(pre_header_1->id());
if (preds.size() == 1) {
auto block = &*containing_function_->FindBlock(preds.front());
if (block == loop_0_->GetMergeBlock()) {
block_to_check.push_back(block);
} else {
return false;
}
} else {
return false;
}
}
// Check that the separating blocks are either empty or only contains a store
// to a local variable that is never read (left behind by
// '--eliminate-local-multi-store'). Also allow OpPhi, since the loop could be
// in LCSSA form.
for (auto block : block_to_check) {
for (auto& inst : *block) {
if (inst.opcode() == spv::Op::OpStore) {
// Get the definition of the target to check it's function scope so
// there are no observable side effects.
auto variable =
context_->get_def_use_mgr()->GetDef(inst.GetSingleWordInOperand(0));
if (variable->opcode() != spv::Op::OpVariable ||
spv::StorageClass(variable->GetSingleWordInOperand(0)) !=
spv::StorageClass::Function) {
return false;
}
// Check the target is never loaded.
auto is_used = false;
context_->get_def_use_mgr()->ForEachUse(
inst.GetSingleWordInOperand(0),
[&is_used](Instruction* use_inst, uint32_t) {
if (use_inst->opcode() == spv::Op::OpLoad) {
is_used = true;
}
});
if (is_used) {
return false;
}
} else if (inst.opcode() == spv::Op::OpPhi) {
if (inst.NumInOperands() != 2) {
return false;
}
} else if (inst.opcode() != spv::Op::OpBranch) {
return false;
}
}
}
return true;
} // namespace opt
bool LoopFusion::ContainsBarriersOrFunctionCalls(Loop* loop) {
for (const auto& block : loop->GetBlocks()) {
for (const auto& inst : *containing_function_->FindBlock(block)) {
auto opcode = inst.opcode();
if (opcode == spv::Op::OpFunctionCall ||
opcode == spv::Op::OpControlBarrier ||
opcode == spv::Op::OpMemoryBarrier ||
opcode == spv::Op::OpTypeNamedBarrier ||
opcode == spv::Op::OpNamedBarrierInitialize ||
opcode == spv::Op::OpMemoryNamedBarrier) {
return true;
}
}
}
return false;
}
bool LoopFusion::CheckInit() {
int64_t loop_0_init;
if (!loop_0_->GetInductionInitValue(induction_0_, &loop_0_init)) {
return false;
}
int64_t loop_1_init;
if (!loop_1_->GetInductionInitValue(induction_1_, &loop_1_init)) {
return false;
}
if (loop_0_init != loop_1_init) {
return false;
}
return true;
}
bool LoopFusion::CheckCondition() {
auto condition_0 = loop_0_->GetConditionInst();
auto condition_1 = loop_1_->GetConditionInst();
if (!loop_0_->IsSupportedCondition(condition_0->opcode()) ||
!loop_1_->IsSupportedCondition(condition_1->opcode())) {
return false;
}
if (condition_0->opcode() != condition_1->opcode()) {
return false;
}
for (uint32_t i = 0; i < condition_0->NumInOperandWords(); ++i) {
auto arg_0 = context_->get_def_use_mgr()->GetDef(
condition_0->GetSingleWordInOperand(i));
auto arg_1 = context_->get_def_use_mgr()->GetDef(
condition_1->GetSingleWordInOperand(i));
if (arg_0 == induction_0_ && arg_1 == induction_1_) {
continue;
}
if (arg_0 == induction_0_ && arg_1 != induction_1_) {
return false;
}
if (arg_1 == induction_1_ && arg_0 != induction_0_) {
return false;
}
if (arg_0 != arg_1) {
return false;
}
}
return true;
}
bool LoopFusion::CheckStep() {
auto scalar_analysis = context_->GetScalarEvolutionAnalysis();
SENode* induction_node_0 = scalar_analysis->SimplifyExpression(
scalar_analysis->AnalyzeInstruction(induction_0_));
if (!induction_node_0->AsSERecurrentNode()) {
return false;
}
SENode* induction_step_0 =
induction_node_0->AsSERecurrentNode()->GetCoefficient();
if (!induction_step_0->AsSEConstantNode()) {
return false;
}
SENode* induction_node_1 = scalar_analysis->SimplifyExpression(
scalar_analysis->AnalyzeInstruction(induction_1_));
if (!induction_node_1->AsSERecurrentNode()) {
return false;
}
SENode* induction_step_1 =
induction_node_1->AsSERecurrentNode()->GetCoefficient();
if (!induction_step_1->AsSEConstantNode()) {
return false;
}
if (*induction_step_0 != *induction_step_1) {
return false;
}
return true;
}
std::map<Instruction*, std::vector<Instruction*>> LoopFusion::LocationToMemOps(
const std::vector<Instruction*>& mem_ops) {
std::map<Instruction*, std::vector<Instruction*>> location_map{};
for (auto instruction : mem_ops) {
auto access_location = context_->get_def_use_mgr()->GetDef(
instruction->GetSingleWordInOperand(0));
while (access_location->opcode() == spv::Op::OpAccessChain) {
access_location = context_->get_def_use_mgr()->GetDef(
access_location->GetSingleWordInOperand(0));
}
location_map[access_location].push_back(instruction);
}
return location_map;
}
std::pair<std::vector<Instruction*>, std::vector<Instruction*>>
LoopFusion::GetLoadsAndStoresInLoop(Loop* loop) {
std::vector<Instruction*> loads{};
std::vector<Instruction*> stores{};
for (auto block_id : loop->GetBlocks()) {
if (block_id == loop->GetContinueBlock()->id()) {
continue;
}
for (auto& instruction : *containing_function_->FindBlock(block_id)) {
if (instruction.opcode() == spv::Op::OpLoad) {
loads.push_back(&instruction);
} else if (instruction.opcode() == spv::Op::OpStore) {
stores.push_back(&instruction);
}
}
}
return std::make_pair(loads, stores);
}
bool LoopFusion::IsUsedInLoop(Instruction* instruction, Loop* loop) {
auto not_used = context_->get_def_use_mgr()->WhileEachUser(
instruction, [this, loop](Instruction* user) {
auto block_id = context_->get_instr_block(user)->id();
return !loop->IsInsideLoop(block_id);
});
return !not_used;
}
bool LoopFusion::IsLegal() {
assert(AreCompatible() && "Fusion can't be legal, loops are not compatible.");
// Bail out if there are function calls as they could have side-effects that
// cause dependencies or if there are any barriers.
if (ContainsBarriersOrFunctionCalls(loop_0_) ||
ContainsBarriersOrFunctionCalls(loop_1_)) {
return false;
}
std::vector<Instruction*> phi_instructions{};
loop_0_->GetInductionVariables(phi_instructions);
// Check no OpPhi in |loop_0_| is used in |loop_1_|.
for (auto phi_instruction : phi_instructions) {
if (IsUsedInLoop(phi_instruction, loop_1_)) {
return false;
}
}
// Check no LCSSA OpPhi in merge block of |loop_0_| is used in |loop_1_|.
auto phi_used = false;
loop_0_->GetMergeBlock()->ForEachPhiInst(
[this, &phi_used](Instruction* phi_instruction) {
phi_used |= IsUsedInLoop(phi_instruction, loop_1_);
});
if (phi_used) {
return false;
}
// Grab loads & stores from both loops.
auto loads_stores_0 = GetLoadsAndStoresInLoop(loop_0_);
auto loads_stores_1 = GetLoadsAndStoresInLoop(loop_1_);
// Build memory location to operation maps.
auto load_locs_0 = LocationToMemOps(std::get<0>(loads_stores_0));
auto store_locs_0 = LocationToMemOps(std::get<1>(loads_stores_0));
auto load_locs_1 = LocationToMemOps(std::get<0>(loads_stores_1));
auto store_locs_1 = LocationToMemOps(std::get<1>(loads_stores_1));
// Get the locations accessed in both loops.
auto locations_0 = GetLocationsAccessed(store_locs_0, load_locs_0);
auto locations_1 = GetLocationsAccessed(store_locs_1, load_locs_1);
std::vector<Instruction*> potential_clashes{};
std::set_intersection(std::begin(locations_0), std::end(locations_0),
std::begin(locations_1), std::end(locations_1),
std::back_inserter(potential_clashes));
// If the loops don't access the same variables, the fusion is legal.
if (potential_clashes.empty()) {
return true;
}
// Find variables that have at least one store.
std::vector<Instruction*> potential_clashes_with_stores{};
for (auto location : potential_clashes) {
if (store_locs_0.find(location) != std::end(store_locs_0) ||
store_locs_1.find(location) != std::end(store_locs_1)) {
potential_clashes_with_stores.push_back(location);
}
}
// If there are only loads to the same variables, the fusion is legal.
if (potential_clashes_with_stores.empty()) {
return true;
}
// Else if loads and at least one store (across loops) to the same variable
// there is a potential dependence and we need to check the dependence
// distance.
// Find all the loops in this loop nest for the dependency analysis.
std::vector<const Loop*> loops{};
// Find the parents.
for (auto current_loop = loop_0_; current_loop != nullptr;
current_loop = current_loop->GetParent()) {
loops.push_back(current_loop);
}
auto this_loop_position = loops.size() - 1;
std::reverse(std::begin(loops), std::end(loops));
// Find the children.
CollectChildren(loop_0_, &loops);
CollectChildren(loop_1_, &loops);
// Check that any dependes created are legal. That means the fused loops do
// not have any dependencies with dependence distance greater than 0 that did
// not exist in the original loops.
LoopDependenceAnalysis analysis(context_, loops);
analysis.GetScalarEvolution()->AddLoopsToPretendAreTheSame(
{loop_0_, loop_1_});
for (auto location : potential_clashes_with_stores) {
// Analyse dependences from |loop_0_| to |loop_1_|.
std::vector<DistanceVector> dependences;
// Read-After-Write.
GetDependences(&dependences, &analysis, store_locs_0[location],
load_locs_1[location], loops.size());
// Write-After-Read.
GetDependences(&dependences, &analysis, load_locs_0[location],
store_locs_1[location], loops.size());
// Write-After-Write.
GetDependences(&dependences, &analysis, store_locs_0[location],
store_locs_1[location], loops.size());
// Check that the induction variables either don't appear in the subscripts
// or the dependence distance is negative.
for (const auto& dependence : dependences) {
const auto& entry = dependence.GetEntries()[this_loop_position];
if ((entry.dependence_information ==
DistanceEntry::DependenceInformation::DISTANCE &&
entry.distance < 1) ||
(entry.dependence_information ==
DistanceEntry::DependenceInformation::IRRELEVANT)) {
continue;
} else {
return false;
}
}
}
return true;
}
void ReplacePhiParentWith(Instruction* inst, uint32_t orig_block,
uint32_t new_block) {
if (inst->GetSingleWordInOperand(1) == orig_block) {
inst->SetInOperand(1, {new_block});
} else {
inst->SetInOperand(3, {new_block});
}
}
void LoopFusion::Fuse() {
assert(AreCompatible() && "Can't fuse, loops aren't compatible");
assert(IsLegal() && "Can't fuse, illegal");
// Save the pointers/ids, won't be found in the middle of doing modifications.
auto header_1 = loop_1_->GetHeaderBlock()->id();
auto condition_1 = loop_1_->FindConditionBlock()->id();
auto continue_1 = loop_1_->GetContinueBlock()->id();
auto continue_0 = loop_0_->GetContinueBlock()->id();
auto condition_block_of_0 = loop_0_->FindConditionBlock();
// Find the blocks whose branches need updating.
auto first_block_of_1 = &*(++containing_function_->FindBlock(condition_1));
auto last_block_of_1 = &*(--containing_function_->FindBlock(continue_1));
auto last_block_of_0 = &*(--containing_function_->FindBlock(continue_0));
// Update the branch for |last_block_of_loop_0| to go to |first_block_of_1|.
last_block_of_0->ForEachSuccessorLabel(
[first_block_of_1](uint32_t* succ) { *succ = first_block_of_1->id(); });
// Update the branch for the |last_block_of_loop_1| to go to the continue
// block of |loop_0_|.
last_block_of_1->ForEachSuccessorLabel(
[this](uint32_t* succ) { *succ = loop_0_->GetContinueBlock()->id(); });
// Update merge block id in the header of |loop_0_| to the merge block of
// |loop_1_|.
loop_0_->GetHeaderBlock()->ForEachInst([this](Instruction* inst) {
if (inst->opcode() == spv::Op::OpLoopMerge) {
inst->SetInOperand(0, {loop_1_->GetMergeBlock()->id()});
}
});
// Update condition branch target in |loop_0_| to the merge block of
// |loop_1_|.
condition_block_of_0->ForEachInst([this](Instruction* inst) {
if (inst->opcode() == spv::Op::OpBranchConditional) {
auto loop_0_merge_block_id = loop_0_->GetMergeBlock()->id();
if (inst->GetSingleWordInOperand(1) == loop_0_merge_block_id) {
inst->SetInOperand(1, {loop_1_->GetMergeBlock()->id()});
} else {
inst->SetInOperand(2, {loop_1_->GetMergeBlock()->id()});
}
}
});
// Move OpPhi instructions not corresponding to the induction variable from
// the header of |loop_1_| to the header of |loop_0_|.
std::vector<Instruction*> instructions_to_move{};
for (auto& instruction : *loop_1_->GetHeaderBlock()) {
if (instruction.opcode() == spv::Op::OpPhi &&
&instruction != induction_1_) {
instructions_to_move.push_back(&instruction);
}
}
for (auto& it : instructions_to_move) {
it->RemoveFromList();
it->InsertBefore(induction_0_);
}
// Update the OpPhi parents to the correct blocks in |loop_0_|.
loop_0_->GetHeaderBlock()->ForEachPhiInst([this](Instruction* i) {
ReplacePhiParentWith(i, loop_1_->GetPreHeaderBlock()->id(),
loop_0_->GetPreHeaderBlock()->id());
ReplacePhiParentWith(i, loop_1_->GetContinueBlock()->id(),
loop_0_->GetContinueBlock()->id());
});
// Update instruction to block mapping & DefUseManager.
for (auto& phi_instruction : instructions_to_move) {
context_->set_instr_block(phi_instruction, loop_0_->GetHeaderBlock());
context_->get_def_use_mgr()->AnalyzeInstUse(phi_instruction);
}
// Replace the uses of the induction variable of |loop_1_| with that the
// induction variable of |loop_0_|.
context_->ReplaceAllUsesWith(induction_1_->result_id(),
induction_0_->result_id());
// Replace LCSSA OpPhi in merge block of |loop_0_|.
loop_0_->GetMergeBlock()->ForEachPhiInst([this](Instruction* instruction) {
context_->ReplaceAllUsesWith(instruction->result_id(),
instruction->GetSingleWordInOperand(0));
});
// Update LCSSA OpPhi in merge block of |loop_1_|.
loop_1_->GetMergeBlock()->ForEachPhiInst(
[condition_block_of_0](Instruction* instruction) {
instruction->SetInOperand(1, {condition_block_of_0->id()});
});
// Move the continue block of |loop_0_| after the last block of |loop_1_|.
containing_function_->MoveBasicBlockToAfter(continue_0, last_block_of_1);
// Gather all instructions to be killed from |loop_1_| (induction variable
// initialisation, header, condition and continue blocks).
std::vector<Instruction*> instr_to_delete{};
AddInstructionsInBlock(&instr_to_delete, loop_1_->GetPreHeaderBlock());
AddInstructionsInBlock(&instr_to_delete, loop_1_->GetHeaderBlock());
AddInstructionsInBlock(&instr_to_delete, loop_1_->FindConditionBlock());
AddInstructionsInBlock(&instr_to_delete, loop_1_->GetContinueBlock());
// There was an additional empty block between the loops, kill that too.
if (loop_0_->GetMergeBlock() != loop_1_->GetPreHeaderBlock()) {
AddInstructionsInBlock(&instr_to_delete, loop_0_->GetMergeBlock());
}
// Update the CFG, so it wouldn't need invalidating.
auto cfg = context_->cfg();
cfg->ForgetBlock(loop_1_->GetPreHeaderBlock());
cfg->ForgetBlock(loop_1_->GetHeaderBlock());
cfg->ForgetBlock(loop_1_->FindConditionBlock());
cfg->ForgetBlock(loop_1_->GetContinueBlock());
if (loop_0_->GetMergeBlock() != loop_1_->GetPreHeaderBlock()) {
cfg->ForgetBlock(loop_0_->GetMergeBlock());
}
cfg->RemoveEdge(last_block_of_0->id(), loop_0_->GetContinueBlock()->id());
cfg->AddEdge(last_block_of_0->id(), first_block_of_1->id());
cfg->AddEdge(last_block_of_1->id(), loop_0_->GetContinueBlock()->id());
cfg->AddEdge(loop_0_->GetContinueBlock()->id(),
loop_1_->GetHeaderBlock()->id());
cfg->AddEdge(condition_block_of_0->id(), loop_1_->GetMergeBlock()->id());
// Update DefUseManager.
auto def_use_mgr = context_->get_def_use_mgr();
// Uses of labels that are in updated branches need analysing.
def_use_mgr->AnalyzeInstUse(last_block_of_0->terminator());
def_use_mgr->AnalyzeInstUse(last_block_of_1->terminator());
def_use_mgr->AnalyzeInstUse(loop_0_->GetHeaderBlock()->GetLoopMergeInst());
def_use_mgr->AnalyzeInstUse(condition_block_of_0->terminator());
// Update the LoopDescriptor, so it wouldn't need invalidating.
auto ld = context_->GetLoopDescriptor(containing_function_);
// Create a copy, so the iterator wouldn't be invalidated.
std::vector<Loop*> loops_to_add_remove{};
for (auto child_loop : *loop_1_) {
loops_to_add_remove.push_back(child_loop);
}
for (auto child_loop : loops_to_add_remove) {
loop_1_->RemoveChildLoop(child_loop);
loop_0_->AddNestedLoop(child_loop);
}
auto loop_1_blocks = loop_1_->GetBlocks();
for (auto block : loop_1_blocks) {
loop_1_->RemoveBasicBlock(block);
if (block != header_1 && block != condition_1 && block != continue_1) {
loop_0_->AddBasicBlock(block);
if ((*ld)[block] == loop_1_) {
ld->SetBasicBlockToLoop(block, loop_0_);
}
}
if ((*ld)[block] == loop_1_) {
ld->ForgetBasicBlock(block);
}
}
loop_1_->RemoveBasicBlock(loop_1_->GetPreHeaderBlock()->id());
ld->ForgetBasicBlock(loop_1_->GetPreHeaderBlock()->id());
if (loop_0_->GetMergeBlock() != loop_1_->GetPreHeaderBlock()) {
loop_0_->RemoveBasicBlock(loop_0_->GetMergeBlock()->id());
ld->ForgetBasicBlock(loop_0_->GetMergeBlock()->id());
}
loop_0_->SetMergeBlock(loop_1_->GetMergeBlock());
loop_1_->ClearBlocks();
ld->RemoveLoop(loop_1_);
// Kill unnecessary instructions and remove all empty blocks.
for (auto inst : instr_to_delete) {
context_->KillInst(inst);
}
containing_function_->RemoveEmptyBlocks();
// Invalidate analyses.
context_->InvalidateAnalysesExceptFor(
IRContext::Analysis::kAnalysisInstrToBlockMapping |
IRContext::Analysis::kAnalysisLoopAnalysis |
IRContext::Analysis::kAnalysisDefUse | IRContext::Analysis::kAnalysisCFG);
}
} // namespace opt
} // namespace spvtools