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

694 lines
27 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 <algorithm>
#include <memory>
#include <unordered_map>
#include <unordered_set>
#include <utility>
#include <vector>
#include "source/cfa.h"
#include "source/opt/cfg.h"
#include "source/opt/ir_builder.h"
#include "source/opt/ir_context.h"
#include "source/opt/loop_descriptor.h"
#include "source/opt/loop_utils.h"
namespace spvtools {
namespace opt {
namespace {
// Return true if |bb| is dominated by at least one block in |exits|
inline bool DominatesAnExit(BasicBlock* bb,
const std::unordered_set<BasicBlock*>& exits,
const DominatorTree& dom_tree) {
for (BasicBlock* e_bb : exits)
if (dom_tree.Dominates(bb, e_bb)) return true;
return false;
}
// Utility class to rewrite out-of-loop uses of an in-loop definition in terms
// of phi instructions to achieve a LCSSA form.
// For a given definition, the class user registers phi instructions using that
// definition in all loop exit blocks by which the definition escapes.
// Then, when rewriting a use of the definition, the rewriter walks the
// paths from the use the loop exits. At each step, it will insert a phi
// instruction to merge the incoming value according to exit blocks definition.
class LCSSARewriter {
public:
LCSSARewriter(IRContext* context, const DominatorTree& dom_tree,
const std::unordered_set<BasicBlock*>& exit_bb,
BasicBlock* merge_block)
: context_(context),
cfg_(context_->cfg()),
dom_tree_(dom_tree),
exit_bb_(exit_bb),
merge_block_id_(merge_block ? merge_block->id() : 0) {}
struct UseRewriter {
explicit UseRewriter(LCSSARewriter* base, const Instruction& def_insn)
: base_(base), def_insn_(def_insn) {}
// Rewrites the use of |def_insn_| by the instruction |user| at the index
// |operand_index| in terms of phi instruction. This recursively builds new
// phi instructions from |user| to the loop exit blocks' phis. The use of
// |def_insn_| in |user| is replaced by the relevant phi instruction at the
// end of the operation.
// It is assumed that |user| does not dominates any of the loop exit basic
// block. This operation does not update the def/use manager, instead it
// records what needs to be updated. The actual update is performed by
// UpdateManagers.
void RewriteUse(BasicBlock* bb, Instruction* user, uint32_t operand_index) {
assert(
(user->opcode() != spv::Op::OpPhi || bb != GetParent(user)) &&
"The root basic block must be the incoming edge if |user| is a phi "
"instruction");
assert((user->opcode() == spv::Op::OpPhi || bb == GetParent(user)) &&
"The root basic block must be the instruction parent if |user| is "
"not "
"phi instruction");
Instruction* new_def = GetOrBuildIncoming(bb->id());
user->SetOperand(operand_index, {new_def->result_id()});
rewritten_.insert(user);
}
// In-place update of some managers (avoid full invalidation).
inline void UpdateManagers() {
analysis::DefUseManager* def_use_mgr = base_->context_->get_def_use_mgr();
// Register all new definitions.
for (Instruction* insn : rewritten_) {
def_use_mgr->AnalyzeInstDef(insn);
}
// Register all new uses.
for (Instruction* insn : rewritten_) {
def_use_mgr->AnalyzeInstUse(insn);
}
}
private:
// Return the basic block that |instr| belongs to.
BasicBlock* GetParent(Instruction* instr) {
return base_->context_->get_instr_block(instr);
}
// Builds a phi instruction for the basic block |bb|. The function assumes
// that |defining_blocks| contains the list of basic block that define the
// usable value for each predecessor of |bb|.
inline Instruction* CreatePhiInstruction(
BasicBlock* bb, const std::vector<uint32_t>& defining_blocks) {
std::vector<uint32_t> incomings;
const std::vector<uint32_t>& bb_preds = base_->cfg_->preds(bb->id());
assert(bb_preds.size() == defining_blocks.size());
for (size_t i = 0; i < bb_preds.size(); i++) {
incomings.push_back(
GetOrBuildIncoming(defining_blocks[i])->result_id());
incomings.push_back(bb_preds[i]);
}
InstructionBuilder builder(base_->context_, &*bb->begin(),
IRContext::kAnalysisInstrToBlockMapping);
Instruction* incoming_phi =
builder.AddPhi(def_insn_.type_id(), incomings);
rewritten_.insert(incoming_phi);
return incoming_phi;
}
// Builds a phi instruction for the basic block |bb|, all incoming values
// will be |value|.
inline Instruction* CreatePhiInstruction(BasicBlock* bb,
const Instruction& value) {
std::vector<uint32_t> incomings;
const std::vector<uint32_t>& bb_preds = base_->cfg_->preds(bb->id());
for (size_t i = 0; i < bb_preds.size(); i++) {
incomings.push_back(value.result_id());
incomings.push_back(bb_preds[i]);
}
InstructionBuilder builder(base_->context_, &*bb->begin(),
IRContext::kAnalysisInstrToBlockMapping);
Instruction* incoming_phi =
builder.AddPhi(def_insn_.type_id(), incomings);
rewritten_.insert(incoming_phi);
return incoming_phi;
}
// Return the new def to use for the basic block |bb_id|.
// If |bb_id| does not have a suitable def to use then we:
// - return the common def used by all predecessors;
// - if there is no common def, then we build a new phi instr at the
// beginning of |bb_id| and return this new instruction.
Instruction* GetOrBuildIncoming(uint32_t bb_id) {
assert(base_->cfg_->block(bb_id) != nullptr && "Unknown basic block");
Instruction*& incoming_phi = bb_to_phi_[bb_id];
if (incoming_phi) {
return incoming_phi;
}
BasicBlock* bb = &*base_->cfg_->block(bb_id);
// If this is an exit basic block, look if there already is an eligible
// phi instruction. An eligible phi has |def_insn_| as all incoming
// values.
if (base_->exit_bb_.count(bb)) {
// Look if there is an eligible phi in this block.
if (!bb->WhileEachPhiInst([&incoming_phi, this](Instruction* phi) {
for (uint32_t i = 0; i < phi->NumInOperands(); i += 2) {
if (phi->GetSingleWordInOperand(i) != def_insn_.result_id())
return true;
}
incoming_phi = phi;
rewritten_.insert(incoming_phi);
return false;
})) {
return incoming_phi;
}
incoming_phi = CreatePhiInstruction(bb, def_insn_);
return incoming_phi;
}
// Get the block that defines the value to use for each predecessor.
// If the vector has 1 value, then it means that this block does not need
// to build a phi instruction unless |bb_id| is the loop merge block.
const std::vector<uint32_t>& defining_blocks =
base_->GetDefiningBlocks(bb_id);
// Special case for structured loops: merge block might be different from
// the exit block set. To maintain structured properties it will ease
// transformations if the merge block also holds a phi instruction like
// the exit ones.
if (defining_blocks.size() > 1 || bb_id == base_->merge_block_id_) {
if (defining_blocks.size() > 1) {
incoming_phi = CreatePhiInstruction(bb, defining_blocks);
} else {
assert(bb_id == base_->merge_block_id_);
incoming_phi =
CreatePhiInstruction(bb, *GetOrBuildIncoming(defining_blocks[0]));
}
} else {
incoming_phi = GetOrBuildIncoming(defining_blocks[0]);
}
return incoming_phi;
}
LCSSARewriter* base_;
const Instruction& def_insn_;
std::unordered_map<uint32_t, Instruction*> bb_to_phi_;
std::unordered_set<Instruction*> rewritten_;
};
private:
// Return the new def to use for the basic block |bb_id|.
// If |bb_id| does not have a suitable def to use then we:
// - return the common def used by all predecessors;
// - if there is no common def, then we build a new phi instr at the
// beginning of |bb_id| and return this new instruction.
const std::vector<uint32_t>& GetDefiningBlocks(uint32_t bb_id) {
assert(cfg_->block(bb_id) != nullptr && "Unknown basic block");
std::vector<uint32_t>& defining_blocks = bb_to_defining_blocks_[bb_id];
if (defining_blocks.size()) return defining_blocks;
// Check if one of the loop exit basic block dominates |bb_id|.
for (const BasicBlock* e_bb : exit_bb_) {
if (dom_tree_.Dominates(e_bb->id(), bb_id)) {
defining_blocks.push_back(e_bb->id());
return defining_blocks;
}
}
// Process parents, they will returns their suitable blocks.
// If they are all the same, this means this basic block is dominated by a
// common block, so we won't need to build a phi instruction.
for (uint32_t pred_id : cfg_->preds(bb_id)) {
const std::vector<uint32_t>& pred_blocks = GetDefiningBlocks(pred_id);
if (pred_blocks.size() == 1)
defining_blocks.push_back(pred_blocks[0]);
else
defining_blocks.push_back(pred_id);
}
assert(defining_blocks.size());
if (std::all_of(defining_blocks.begin(), defining_blocks.end(),
[&defining_blocks](uint32_t id) {
return id == defining_blocks[0];
})) {
// No need for a phi.
defining_blocks.resize(1);
}
return defining_blocks;
}
IRContext* context_;
CFG* cfg_;
const DominatorTree& dom_tree_;
const std::unordered_set<BasicBlock*>& exit_bb_;
uint32_t merge_block_id_;
// This map represent the set of known paths. For each key, the vector
// represent the set of blocks holding the definition to be used to build the
// phi instruction.
// If the vector has 0 value, then the path is unknown yet, and must be built.
// If the vector has 1 value, then the value defined by that basic block
// should be used.
// If the vector has more than 1 value, then a phi node must be created, the
// basic block ordering is the same as the predecessor ordering.
std::unordered_map<uint32_t, std::vector<uint32_t>> bb_to_defining_blocks_;
};
// Make the set |blocks| closed SSA. The set is closed SSA if all the uses
// outside the set are phi instructions in exiting basic block set (hold by
// |lcssa_rewriter|).
inline void MakeSetClosedSSA(IRContext* context, Function* function,
const std::unordered_set<uint32_t>& blocks,
const std::unordered_set<BasicBlock*>& exit_bb,
LCSSARewriter* lcssa_rewriter) {
CFG& cfg = *context->cfg();
DominatorTree& dom_tree =
context->GetDominatorAnalysis(function)->GetDomTree();
analysis::DefUseManager* def_use_manager = context->get_def_use_mgr();
for (uint32_t bb_id : blocks) {
BasicBlock* bb = cfg.block(bb_id);
// If bb does not dominate an exit block, then it cannot have escaping defs.
if (!DominatesAnExit(bb, exit_bb, dom_tree)) continue;
for (Instruction& inst : *bb) {
LCSSARewriter::UseRewriter rewriter(lcssa_rewriter, inst);
def_use_manager->ForEachUse(
&inst, [&blocks, &rewriter, &exit_bb, context](
Instruction* use, uint32_t operand_index) {
BasicBlock* use_parent = context->get_instr_block(use);
assert(use_parent);
if (blocks.count(use_parent->id())) return;
if (use->opcode() == spv::Op::OpPhi) {
// If the use is a Phi instruction and the incoming block is
// coming from the loop, then that's consistent with LCSSA form.
if (exit_bb.count(use_parent)) {
return;
} else {
// That's not an exit block, but the user is a phi instruction.
// Consider the incoming branch only.
use_parent = context->get_instr_block(
use->GetSingleWordOperand(operand_index + 1));
}
}
// Rewrite the use. Note that this call does not invalidate the
// def/use manager. So this operation is safe.
rewriter.RewriteUse(use_parent, use, operand_index);
});
rewriter.UpdateManagers();
}
}
}
} // namespace
void LoopUtils::CreateLoopDedicatedExits() {
Function* function = loop_->GetHeaderBlock()->GetParent();
LoopDescriptor& loop_desc = *context_->GetLoopDescriptor(function);
CFG& cfg = *context_->cfg();
analysis::DefUseManager* def_use_mgr = context_->get_def_use_mgr();
const IRContext::Analysis PreservedAnalyses =
IRContext::kAnalysisDefUse | IRContext::kAnalysisInstrToBlockMapping;
// Gathers the set of basic block that are not in this loop and have at least
// one predecessor in the loop and one not in the loop.
std::unordered_set<uint32_t> exit_bb_set;
loop_->GetExitBlocks(&exit_bb_set);
std::unordered_set<BasicBlock*> new_loop_exits;
bool made_change = false;
// For each block, we create a new one that gathers all branches from
// the loop and fall into the block.
for (uint32_t non_dedicate_id : exit_bb_set) {
BasicBlock* non_dedicate = cfg.block(non_dedicate_id);
const std::vector<uint32_t>& bb_pred = cfg.preds(non_dedicate_id);
// Ignore the block if all the predecessors are in the loop.
if (std::all_of(bb_pred.begin(), bb_pred.end(),
[this](uint32_t id) { return loop_->IsInsideLoop(id); })) {
new_loop_exits.insert(non_dedicate);
continue;
}
made_change = true;
Function::iterator insert_pt = function->begin();
for (; insert_pt != function->end() && &*insert_pt != non_dedicate;
++insert_pt) {
}
assert(insert_pt != function->end() && "Basic Block not found");
// Create the dedicate exit basic block.
// TODO(1841): Handle id overflow.
BasicBlock& exit = *insert_pt.InsertBefore(std::unique_ptr<BasicBlock>(
new BasicBlock(std::unique_ptr<Instruction>(new Instruction(
context_, spv::Op::OpLabel, 0, context_->TakeNextId(), {})))));
exit.SetParent(function);
// Redirect in loop predecessors to |exit| block.
for (uint32_t exit_pred_id : bb_pred) {
if (loop_->IsInsideLoop(exit_pred_id)) {
BasicBlock* pred_block = cfg.block(exit_pred_id);
pred_block->ForEachSuccessorLabel([non_dedicate, &exit](uint32_t* id) {
if (*id == non_dedicate->id()) *id = exit.id();
});
// Update the CFG.
// |non_dedicate|'s predecessor list will be updated at the end of the
// loop.
cfg.RegisterBlock(pred_block);
}
}
// Register the label to the def/use manager, requires for the phi patching.
def_use_mgr->AnalyzeInstDefUse(exit.GetLabelInst());
context_->set_instr_block(exit.GetLabelInst(), &exit);
InstructionBuilder builder(context_, &exit, PreservedAnalyses);
// Now jump from our dedicate basic block to the old exit.
// We also reset the insert point so all instructions are inserted before
// the branch.
builder.SetInsertPoint(builder.AddBranch(non_dedicate->id()));
non_dedicate->ForEachPhiInst(
[&builder, &exit, def_use_mgr, this](Instruction* phi) {
// New phi operands for this instruction.
std::vector<uint32_t> new_phi_op;
// Phi operands for the dedicated exit block.
std::vector<uint32_t> exit_phi_op;
for (uint32_t i = 0; i < phi->NumInOperands(); i += 2) {
uint32_t def_id = phi->GetSingleWordInOperand(i);
uint32_t incoming_id = phi->GetSingleWordInOperand(i + 1);
if (loop_->IsInsideLoop(incoming_id)) {
exit_phi_op.push_back(def_id);
exit_phi_op.push_back(incoming_id);
} else {
new_phi_op.push_back(def_id);
new_phi_op.push_back(incoming_id);
}
}
// Build the new phi instruction dedicated exit block.
Instruction* exit_phi = builder.AddPhi(phi->type_id(), exit_phi_op);
// Build the new incoming branch.
new_phi_op.push_back(exit_phi->result_id());
new_phi_op.push_back(exit.id());
// Rewrite operands.
uint32_t idx = 0;
for (; idx < new_phi_op.size(); idx++)
phi->SetInOperand(idx, {new_phi_op[idx]});
// Remove extra operands, from last to first (more efficient).
for (uint32_t j = phi->NumInOperands() - 1; j >= idx; j--)
phi->RemoveInOperand(j);
// Update the def/use manager for this |phi|.
def_use_mgr->AnalyzeInstUse(phi);
});
// Update the CFG.
cfg.RegisterBlock(&exit);
cfg.RemoveNonExistingEdges(non_dedicate->id());
new_loop_exits.insert(&exit);
// If non_dedicate is in a loop, add the new dedicated exit in that loop.
if (Loop* parent_loop = loop_desc[non_dedicate])
parent_loop->AddBasicBlock(&exit);
}
if (new_loop_exits.size() == 1) {
loop_->SetMergeBlock(*new_loop_exits.begin());
}
if (made_change) {
context_->InvalidateAnalysesExceptFor(
PreservedAnalyses | IRContext::kAnalysisCFG |
IRContext::Analysis::kAnalysisLoopAnalysis);
}
}
void LoopUtils::MakeLoopClosedSSA() {
CreateLoopDedicatedExits();
Function* function = loop_->GetHeaderBlock()->GetParent();
CFG& cfg = *context_->cfg();
DominatorTree& dom_tree =
context_->GetDominatorAnalysis(function)->GetDomTree();
std::unordered_set<BasicBlock*> exit_bb;
{
std::unordered_set<uint32_t> exit_bb_id;
loop_->GetExitBlocks(&exit_bb_id);
for (uint32_t bb_id : exit_bb_id) {
exit_bb.insert(cfg.block(bb_id));
}
}
LCSSARewriter lcssa_rewriter(context_, dom_tree, exit_bb,
loop_->GetMergeBlock());
MakeSetClosedSSA(context_, function, loop_->GetBlocks(), exit_bb,
&lcssa_rewriter);
// Make sure all defs post-dominated by the merge block have their last use no
// further than the merge block.
if (loop_->GetMergeBlock()) {
std::unordered_set<uint32_t> merging_bb_id;
loop_->GetMergingBlocks(&merging_bb_id);
merging_bb_id.erase(loop_->GetMergeBlock()->id());
// Reset the exit set, now only the merge block is the exit.
exit_bb.clear();
exit_bb.insert(loop_->GetMergeBlock());
// LCSSARewriter is reusable here only because it forces the creation of a
// phi instruction in the merge block.
MakeSetClosedSSA(context_, function, merging_bb_id, exit_bb,
&lcssa_rewriter);
}
context_->InvalidateAnalysesExceptFor(
IRContext::Analysis::kAnalysisCFG |
IRContext::Analysis::kAnalysisDominatorAnalysis |
IRContext::Analysis::kAnalysisLoopAnalysis);
}
Loop* LoopUtils::CloneLoop(LoopCloningResult* cloning_result) const {
// Compute the structured order of the loop basic blocks and store it in the
// vector ordered_loop_blocks.
std::vector<BasicBlock*> ordered_loop_blocks;
loop_->ComputeLoopStructuredOrder(&ordered_loop_blocks);
// Clone the loop.
return CloneLoop(cloning_result, ordered_loop_blocks);
}
Loop* LoopUtils::CloneAndAttachLoopToHeader(LoopCloningResult* cloning_result) {
// Clone the loop.
Loop* new_loop = CloneLoop(cloning_result);
// Create a new exit block/label for the new loop.
// TODO(1841): Handle id overflow.
std::unique_ptr<Instruction> new_label{new Instruction(
context_, spv::Op::OpLabel, 0, context_->TakeNextId(), {})};
std::unique_ptr<BasicBlock> new_exit_bb{new BasicBlock(std::move(new_label))};
new_exit_bb->SetParent(loop_->GetMergeBlock()->GetParent());
// Create an unconditional branch to the header block.
InstructionBuilder builder{context_, new_exit_bb.get()};
builder.AddBranch(loop_->GetHeaderBlock()->id());
// Save the ids of the new and old merge block.
const uint32_t old_merge_block = loop_->GetMergeBlock()->id();
const uint32_t new_merge_block = new_exit_bb->id();
// Replace the uses of the old merge block in the new loop with the new merge
// block.
for (std::unique_ptr<BasicBlock>& basic_block : cloning_result->cloned_bb_) {
for (Instruction& inst : *basic_block) {
// For each operand in each instruction check if it is using the old merge
// block and change it to be the new merge block.
auto replace_merge_use = [old_merge_block,
new_merge_block](uint32_t* id) {
if (*id == old_merge_block) *id = new_merge_block;
};
inst.ForEachInOperand(replace_merge_use);
}
}
const uint32_t old_header = loop_->GetHeaderBlock()->id();
const uint32_t new_header = new_loop->GetHeaderBlock()->id();
analysis::DefUseManager* def_use = context_->get_def_use_mgr();
def_use->ForEachUse(old_header,
[new_header, this](Instruction* inst, uint32_t operand) {
if (!this->loop_->IsInsideLoop(inst))
inst->SetOperand(operand, {new_header});
});
// TODO(1841): Handle failure to create pre-header.
def_use->ForEachUse(
loop_->GetOrCreatePreHeaderBlock()->id(),
[new_merge_block, this](Instruction* inst, uint32_t operand) {
if (this->loop_->IsInsideLoop(inst))
inst->SetOperand(operand, {new_merge_block});
});
new_loop->SetMergeBlock(new_exit_bb.get());
new_loop->SetPreHeaderBlock(loop_->GetPreHeaderBlock());
// Add the new block into the cloned instructions.
cloning_result->cloned_bb_.push_back(std::move(new_exit_bb));
return new_loop;
}
Loop* LoopUtils::CloneLoop(
LoopCloningResult* cloning_result,
const std::vector<BasicBlock*>& ordered_loop_blocks) const {
analysis::DefUseManager* def_use_mgr = context_->get_def_use_mgr();
std::unique_ptr<Loop> new_loop = MakeUnique<Loop>(context_);
CFG& cfg = *context_->cfg();
// Clone and place blocks in a SPIR-V compliant order (dominators first).
for (BasicBlock* old_bb : ordered_loop_blocks) {
// For each basic block in the loop, we clone it and register the mapping
// between old and new ids.
BasicBlock* new_bb = old_bb->Clone(context_);
new_bb->SetParent(&function_);
// TODO(1841): Handle id overflow.
new_bb->GetLabelInst()->SetResultId(context_->TakeNextId());
def_use_mgr->AnalyzeInstDef(new_bb->GetLabelInst());
context_->set_instr_block(new_bb->GetLabelInst(), new_bb);
cloning_result->cloned_bb_.emplace_back(new_bb);
cloning_result->old_to_new_bb_[old_bb->id()] = new_bb;
cloning_result->new_to_old_bb_[new_bb->id()] = old_bb;
cloning_result->value_map_[old_bb->id()] = new_bb->id();
if (loop_->IsInsideLoop(old_bb)) new_loop->AddBasicBlock(new_bb);
for (auto new_inst = new_bb->begin(), old_inst = old_bb->begin();
new_inst != new_bb->end(); ++new_inst, ++old_inst) {
cloning_result->ptr_map_[&*new_inst] = &*old_inst;
if (new_inst->HasResultId()) {
// TODO(1841): Handle id overflow.
new_inst->SetResultId(context_->TakeNextId());
cloning_result->value_map_[old_inst->result_id()] =
new_inst->result_id();
// Only look at the defs for now, uses are not updated yet.
def_use_mgr->AnalyzeInstDef(&*new_inst);
}
}
}
// All instructions (including all labels) have been cloned,
// remap instruction operands id with the new ones.
for (std::unique_ptr<BasicBlock>& bb_ref : cloning_result->cloned_bb_) {
BasicBlock* bb = bb_ref.get();
for (Instruction& insn : *bb) {
insn.ForEachInId([cloning_result](uint32_t* old_id) {
// If the operand is defined in the loop, remap the id.
auto id_it = cloning_result->value_map_.find(*old_id);
if (id_it != cloning_result->value_map_.end()) {
*old_id = id_it->second;
}
});
// Only look at what the instruction uses. All defs are register, so all
// should be fine now.
def_use_mgr->AnalyzeInstUse(&insn);
context_->set_instr_block(&insn, bb);
}
cfg.RegisterBlock(bb);
}
PopulateLoopNest(new_loop.get(), *cloning_result);
return new_loop.release();
}
void LoopUtils::PopulateLoopNest(
Loop* new_loop, const LoopCloningResult& cloning_result) const {
std::unordered_map<Loop*, Loop*> loop_mapping;
loop_mapping[loop_] = new_loop;
if (loop_->HasParent()) loop_->GetParent()->AddNestedLoop(new_loop);
PopulateLoopDesc(new_loop, loop_, cloning_result);
for (Loop& sub_loop :
make_range(++TreeDFIterator<Loop>(loop_), TreeDFIterator<Loop>())) {
Loop* cloned = new Loop(context_);
if (Loop* parent = loop_mapping[sub_loop.GetParent()])
parent->AddNestedLoop(cloned);
loop_mapping[&sub_loop] = cloned;
PopulateLoopDesc(cloned, &sub_loop, cloning_result);
}
loop_desc_->AddLoopNest(std::unique_ptr<Loop>(new_loop));
}
// Populates |new_loop| descriptor according to |old_loop|'s one.
void LoopUtils::PopulateLoopDesc(
Loop* new_loop, Loop* old_loop,
const LoopCloningResult& cloning_result) const {
for (uint32_t bb_id : old_loop->GetBlocks()) {
BasicBlock* bb = cloning_result.old_to_new_bb_.at(bb_id);
new_loop->AddBasicBlock(bb);
}
new_loop->SetHeaderBlock(
cloning_result.old_to_new_bb_.at(old_loop->GetHeaderBlock()->id()));
if (old_loop->GetLatchBlock())
new_loop->SetLatchBlock(
cloning_result.old_to_new_bb_.at(old_loop->GetLatchBlock()->id()));
if (old_loop->GetContinueBlock())
new_loop->SetContinueBlock(
cloning_result.old_to_new_bb_.at(old_loop->GetContinueBlock()->id()));
if (old_loop->GetMergeBlock()) {
auto it =
cloning_result.old_to_new_bb_.find(old_loop->GetMergeBlock()->id());
BasicBlock* bb = it != cloning_result.old_to_new_bb_.end()
? it->second
: old_loop->GetMergeBlock();
new_loop->SetMergeBlock(bb);
}
if (old_loop->GetPreHeaderBlock()) {
auto it =
cloning_result.old_to_new_bb_.find(old_loop->GetPreHeaderBlock()->id());
if (it != cloning_result.old_to_new_bb_.end()) {
new_loop->SetPreHeaderBlock(it->second);
}
}
}
// Class to gather some metrics about a region of interest.
void CodeMetrics::Analyze(const Loop& loop) {
CFG& cfg = *loop.GetContext()->cfg();
roi_size_ = 0;
block_sizes_.clear();
for (uint32_t id : loop.GetBlocks()) {
const BasicBlock* bb = cfg.block(id);
size_t bb_size = 0;
bb->ForEachInst([&bb_size](const Instruction* insn) {
if (insn->opcode() == spv::Op::OpLabel) return;
if (insn->IsNop()) return;
if (insn->opcode() == spv::Op::OpPhi) return;
bb_size++;
});
block_sizes_[bb->id()] = bb_size;
roi_size_ += bb_size;
}
}
} // namespace opt
} // namespace spvtools