third_party/SPIRV-Tools/source/val/function.cpp - SwiftShader - Git at Google

 // Copyright (c) 2015-2016 The Khronos Group Inc.
 //
 // 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/val/function.h"

 #include <algorithm>
 #include <cassert>
 #include <sstream>
 #include <unordered_map>
 #include <unordered_set>
 #include <utility>

 #include "source/cfa.h"
 #include "source/val/basic_block.h"
 #include "source/val/construct.h"
 #include "source/val/validate.h"

 namespace spvtools {
 namespace val {

 // Universal Limit of ResultID + 1
 static const uint32_t kInvalidId = 0x400000;

 Function::Function(uint32_t function_id, uint32_t result_type_id,
                    SpvFunctionControlMask function_control,
                    uint32_t function_type_id)
     : id_(function_id),
       function_type_id_(function_type_id),
       result_type_id_(result_type_id),
       function_control_(function_control),
       declaration_type_(FunctionDecl::kFunctionDeclUnknown),
       end_has_been_registered_(false),
       blocks_(),
       current_block_(nullptr),
       pseudo_entry_block_(0),
       pseudo_exit_block_(kInvalidId),
       cfg_constructs_(),
       variable_ids_(),
       parameter_ids_() {}

 bool Function::IsFirstBlock(uint32_t block_id) const {
   return !ordered_blocks_.empty() && *first_block() == block_id;
 }

 spv_result_t Function::RegisterFunctionParameter(uint32_t parameter_id,
                                                  uint32_t type_id) {
   assert(current_block_ == nullptr &&
          "RegisterFunctionParameter can only be called when parsing the binary "
          "ouside of a block");
   // TODO(umar): Validate function parameter type order and count
   // TODO(umar): Use these variables to validate parameter type
   (void)parameter_id;
   (void)type_id;
   return SPV_SUCCESS;
 }

 spv_result_t Function::RegisterLoopMerge(uint32_t merge_id,
                                          uint32_t continue_id) {
   RegisterBlock(merge_id, false);
   RegisterBlock(continue_id, false);
   BasicBlock& merge_block = blocks_.at(merge_id);
   BasicBlock& continue_target_block = blocks_.at(continue_id);
   assert(current_block_ &&
          "RegisterLoopMerge must be called when called within a block");

   current_block_->set_type(kBlockTypeLoop);
   merge_block.set_type(kBlockTypeMerge);
   continue_target_block.set_type(kBlockTypeContinue);
   Construct& loop_construct =
       AddConstruct({ConstructType::kLoop, current_block_, &merge_block});
   Construct& continue_construct =
       AddConstruct({ConstructType::kContinue, &continue_target_block});

   continue_construct.set_corresponding_constructs({&loop_construct});
   loop_construct.set_corresponding_constructs({&continue_construct});
   merge_block_header_[&merge_block] = current_block_;
   if (continue_target_headers_.find(&continue_target_block) ==
       continue_target_headers_.end()) {
     continue_target_headers_[&continue_target_block] = {current_block_};
   } else {
     continue_target_headers_[&continue_target_block].push_back(current_block_);
   }

   return SPV_SUCCESS;
 }

 spv_result_t Function::RegisterSelectionMerge(uint32_t merge_id) {
   RegisterBlock(merge_id, false);
   BasicBlock& merge_block = blocks_.at(merge_id);
   current_block_->set_type(kBlockTypeSelection);
   merge_block.set_type(kBlockTypeMerge);
   merge_block_header_[&merge_block] = current_block_;

   AddConstruct({ConstructType::kSelection, current_block(), &merge_block});

   return SPV_SUCCESS;
 }

 spv_result_t Function::RegisterSetFunctionDeclType(FunctionDecl type) {
   assert(declaration_type_ == FunctionDecl::kFunctionDeclUnknown);
   declaration_type_ = type;
   return SPV_SUCCESS;
 }

 spv_result_t Function::RegisterBlock(uint32_t block_id, bool is_definition) {
   assert(
       declaration_type_ == FunctionDecl::kFunctionDeclDefinition &&
       "RegisterBlocks can only be called after declaration_type_ is defined");

   std::unordered_map<uint32_t, BasicBlock>::iterator inserted_block;
   bool success = false;
   tie(inserted_block, success) =
       blocks_.insert({block_id, BasicBlock(block_id)});
   if (is_definition) {  // new block definition
     assert(current_block_ == nullptr &&
            "Register Block can only be called when parsing a binary outside of "
            "a BasicBlock");

     undefined_blocks_.erase(block_id);
     current_block_ = &inserted_block->second;
     ordered_blocks_.push_back(current_block_);
   } else if (success) {  // Block doesn't exsist but this is not a definition
     undefined_blocks_.insert(block_id);
   }

   return SPV_SUCCESS;
 }

 void Function::RegisterBlockEnd(std::vector<uint32_t> next_list) {
   assert(
       current_block_ &&
       "RegisterBlockEnd can only be called when parsing a binary in a block");
   std::vector<BasicBlock*> next_blocks;
   next_blocks.reserve(next_list.size());

   std::unordered_map<uint32_t, BasicBlock>::iterator inserted_block;
   bool success;
   for (uint32_t successor_id : next_list) {
     tie(inserted_block, success) =
         blocks_.insert({successor_id, BasicBlock(successor_id)});
     if (success) {
       undefined_blocks_.insert(successor_id);
     }
     next_blocks.push_back(&inserted_block->second);
   }

   if (current_block_->is_type(kBlockTypeLoop)) {
     // For each loop header, record the set of its successors, and include
     // its continue target if the continue target is not the loop header
     // itself.
     std::vector<BasicBlock*>& next_blocks_plus_continue_target =
         loop_header_successors_plus_continue_target_map_[current_block_];
     next_blocks_plus_continue_target = next_blocks;
     auto continue_target =
         FindConstructForEntryBlock(current_block_, ConstructType::kLoop)
             .corresponding_constructs()
             .back()
             ->entry_block();
     if (continue_target != current_block_) {
       next_blocks_plus_continue_target.push_back(continue_target);
     }
   }

   current_block_->RegisterSuccessors(next_blocks);
   current_block_ = nullptr;
   return;
 }

 void Function::RegisterFunctionEnd() {
   if (!end_has_been_registered_) {
     end_has_been_registered_ = true;

     ComputeAugmentedCFG();
   }
 }

 size_t Function::block_count() const { return blocks_.size(); }

 size_t Function::undefined_block_count() const {
   return undefined_blocks_.size();
 }

 const std::vector<BasicBlock*>& Function::ordered_blocks() const {
   return ordered_blocks_;
 }
 std::vector<BasicBlock*>& Function::ordered_blocks() { return ordered_blocks_; }

 const BasicBlock* Function::current_block() const { return current_block_; }
 BasicBlock* Function::current_block() { return current_block_; }

 const std::list<Construct>& Function::constructs() const {
   return cfg_constructs_;
 }
 std::list<Construct>& Function::constructs() { return cfg_constructs_; }

 const BasicBlock* Function::first_block() const {
   if (ordered_blocks_.empty()) return nullptr;
   return ordered_blocks_[0];
 }
 BasicBlock* Function::first_block() {
   if (ordered_blocks_.empty()) return nullptr;
   return ordered_blocks_[0];
 }

 bool Function::IsBlockType(uint32_t merge_block_id, BlockType type) const {
   bool ret = false;
   const BasicBlock* block;
   std::tie(block, std::ignore) = GetBlock(merge_block_id);
   if (block) {
     ret = block->is_type(type);
   }
   return ret;
 }

 std::pair<const BasicBlock*, bool> Function::GetBlock(uint32_t block_id) const {
   const auto b = blocks_.find(block_id);
   if (b != end(blocks_)) {
     const BasicBlock* block = &(b->second);
     bool defined =
         undefined_blocks_.find(block->id()) == std::end(undefined_blocks_);
     return std::make_pair(block, defined);
   } else {
     return std::make_pair(nullptr, false);
   }
 }

 std::pair<BasicBlock*, bool> Function::GetBlock(uint32_t block_id) {
   const BasicBlock* out;
   bool defined;
   std::tie(out, defined) =
       const_cast<const Function*>(this)->GetBlock(block_id);
   return std::make_pair(const_cast<BasicBlock*>(out), defined);
 }

 Function::GetBlocksFunction Function::AugmentedCFGSuccessorsFunction() const {
   return [this](const BasicBlock* block) {
     auto where = augmented_successors_map_.find(block);
     return where == augmented_successors_map_.end() ? block->successors()
                                                     : &(*where).second;
   };
 }

 Function::GetBlocksFunction
 Function::AugmentedCFGSuccessorsFunctionIncludingHeaderToContinueEdge() const {
   return [this](const BasicBlock* block) {
     auto where = loop_header_successors_plus_continue_target_map_.find(block);
     return where == loop_header_successors_plus_continue_target_map_.end()
                ? AugmentedCFGSuccessorsFunction()(block)
                : &(*where).second;
   };
 }

 Function::GetBlocksFunction Function::AugmentedCFGPredecessorsFunction() const {
   return [this](const BasicBlock* block) {
     auto where = augmented_predecessors_map_.find(block);
     return where == augmented_predecessors_map_.end() ? block->predecessors()
                                                       : &(*where).second;
   };
 }

 void Function::ComputeAugmentedCFG() {
   // Compute the successors of the pseudo-entry block, and
   // the predecessors of the pseudo exit block.
   auto succ_func = [](const BasicBlock* b) { return b->successors(); };
   auto pred_func = [](const BasicBlock* b) { return b->predecessors(); };
   CFA<BasicBlock>::ComputeAugmentedCFG(
       ordered_blocks_, &pseudo_entry_block_, &pseudo_exit_block_,
       &augmented_successors_map_, &augmented_predecessors_map_, succ_func,
       pred_func);
 }

 Construct& Function::AddConstruct(const Construct& new_construct) {
   cfg_constructs_.push_back(new_construct);
   auto& result = cfg_constructs_.back();
   entry_block_to_construct_[std::make_pair(new_construct.entry_block(),
                                            new_construct.type())] = &result;
   return result;
 }

 Construct& Function::FindConstructForEntryBlock(const BasicBlock* entry_block,
                                                 ConstructType type) {
   auto where =
       entry_block_to_construct_.find(std::make_pair(entry_block, type));
   assert(where != entry_block_to_construct_.end());
   auto construct_ptr = (*where).second;
   assert(construct_ptr);
   return *construct_ptr;
 }

 int Function::GetBlockDepth(BasicBlock* bb) {
   // Guard against nullptr.
   if (!bb) {
     return 0;
   }
   // Only calculate the depth if it's not already calculated.
   // This function uses memoization to avoid duplicate CFG depth calculations.
   if (block_depth_.find(bb) != block_depth_.end()) {
     return block_depth_[bb];
   }
   // Avoid recursion. Something is wrong if the same block is encountered
   // multiple times.
   block_depth_[bb] = 0;

   BasicBlock* bb_dom = bb->immediate_dominator();
   if (!bb_dom || bb == bb_dom) {
     // This block has no dominator, so it's at depth 0.
     block_depth_[bb] = 0;
   } else if (bb->is_type(kBlockTypeContinue)) {
     // This rule must precede the rule for merge blocks in order to set up
     // depths correctly. If a block is both a merge and continue then the merge
     // is nested within the continue's loop (or the graph is incorrect).
     // The depth of the continue block entry point is 1 + loop header depth.
     Construct* continue_construct =
         entry_block_to_construct_[std::make_pair(bb, ConstructType::kContinue)];
     assert(continue_construct);
     // Continue construct has only 1 corresponding construct (loop header).
     Construct* loop_construct =
         continue_construct->corresponding_constructs()[0];
     assert(loop_construct);
     BasicBlock* loop_header = loop_construct->entry_block();
     // The continue target may be the loop itself (while 1).
     // In such cases, the depth of the continue block is: 1 + depth of the
     // loop's dominator block.
     if (loop_header == bb) {
       block_depth_[bb] = 1 + GetBlockDepth(bb_dom);
     } else {
       block_depth_[bb] = 1 + GetBlockDepth(loop_header);
     }
   } else if (bb->is_type(kBlockTypeMerge)) {
     // If this is a merge block, its depth is equal to the block before
     // branching.
     BasicBlock* header = merge_block_header_[bb];
     assert(header);
     block_depth_[bb] = GetBlockDepth(header);
   } else if (bb_dom->is_type(kBlockTypeSelection) ||
              bb_dom->is_type(kBlockTypeLoop)) {
     // The dominator of the given block is a header block. So, the nesting
     // depth of this block is: 1 + nesting depth of the header.
     block_depth_[bb] = 1 + GetBlockDepth(bb_dom);
   } else {
     block_depth_[bb] = GetBlockDepth(bb_dom);
   }
   return block_depth_[bb];
 }

 void Function::RegisterExecutionModelLimitation(SpvExecutionModel model,
                                                 const std::string& message) {
   execution_model_limitations_.push_back(
       [model, message](SpvExecutionModel in_model, std::string* out_message) {
         if (model != in_model) {
           if (out_message) {
             *out_message = message;
           }
           return false;
         }
         return true;
       });
 }

 bool Function::IsCompatibleWithExecutionModel(SpvExecutionModel model,
                                               std::string* reason) const {
   bool return_value = true;
   std::stringstream ss_reason;

   for (const auto& is_compatible : execution_model_limitations_) {
     std::string message;
     if (!is_compatible(model, &message)) {
       if (!reason) return false;
       return_value = false;
       if (!message.empty()) {
         ss_reason << message << "\n";
       }
     }
   }

   if (!return_value && reason) {
     *reason = ss_reason.str();
   }

   return return_value;
 }

 bool Function::CheckLimitations(const ValidationState_t& _,
                                 const Function* entry_point,
                                 std::string* reason) const {
   bool return_value = true;
   std::stringstream ss_reason;

   for (const auto& is_compatible : limitations_) {
     std::string message;
     if (!is_compatible(_, entry_point, &message)) {
       if (!reason) return false;
       return_value = false;
       if (!message.empty()) {
         ss_reason << message << "\n";
       }
     }
   }

   if (!return_value && reason) {
     *reason = ss_reason.str();
   }

   return return_value;
 }

 }  // namespace val
 }  // namespace spvtools
	// Copyright (c) 2015-2016 The Khronos Group Inc.
	//
	// 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/val/function.h"

	#include <algorithm>
	#include <cassert>
	#include <sstream>
	#include <unordered_map>
	#include <unordered_set>
	#include <utility>

	#include "source/cfa.h"
	#include "source/val/basic_block.h"
	#include "source/val/construct.h"
	#include "source/val/validate.h"

	namespace spvtools {
	namespace val {

	// Universal Limit of ResultID + 1
	static const uint32_t kInvalidId = 0x400000;

	Function::Function(uint32_t function_id, uint32_t result_type_id,
	SpvFunctionControlMask function_control,
	uint32_t function_type_id)
	: id_(function_id),
	function_type_id_(function_type_id),
	result_type_id_(result_type_id),
	function_control_(function_control),
	declaration_type_(FunctionDecl::kFunctionDeclUnknown),
	end_has_been_registered_(false),
	blocks_(),
	current_block_(nullptr),
	pseudo_entry_block_(0),
	pseudo_exit_block_(kInvalidId),
	cfg_constructs_(),
	variable_ids_(),
	parameter_ids_() {}

	bool Function::IsFirstBlock(uint32_t block_id) const {
	return !ordered_blocks_.empty() && *first_block() == block_id;
	}

	spv_result_t Function::RegisterFunctionParameter(uint32_t parameter_id,
	uint32_t type_id) {
	assert(current_block_ == nullptr &&
	"RegisterFunctionParameter can only be called when parsing the binary "
	"ouside of a block");
	// TODO(umar): Validate function parameter type order and count
	// TODO(umar): Use these variables to validate parameter type
	(void)parameter_id;
	(void)type_id;
	return SPV_SUCCESS;
	}

	spv_result_t Function::RegisterLoopMerge(uint32_t merge_id,
	uint32_t continue_id) {
	RegisterBlock(merge_id, false);
	RegisterBlock(continue_id, false);
	BasicBlock& merge_block = blocks_.at(merge_id);
	BasicBlock& continue_target_block = blocks_.at(continue_id);
	assert(current_block_ &&
	"RegisterLoopMerge must be called when called within a block");

	current_block_->set_type(kBlockTypeLoop);
	merge_block.set_type(kBlockTypeMerge);
	continue_target_block.set_type(kBlockTypeContinue);
	Construct& loop_construct =
	AddConstruct({ConstructType::kLoop, current_block_, &merge_block});
	Construct& continue_construct =
	AddConstruct({ConstructType::kContinue, &continue_target_block});

	continue_construct.set_corresponding_constructs({&loop_construct});
	loop_construct.set_corresponding_constructs({&continue_construct});
	merge_block_header_[&merge_block] = current_block_;
	if (continue_target_headers_.find(&continue_target_block) ==
	continue_target_headers_.end()) {
	continue_target_headers_[&continue_target_block] = {current_block_};
	} else {
	continue_target_headers_[&continue_target_block].push_back(current_block_);
	}

	return SPV_SUCCESS;
	}

	spv_result_t Function::RegisterSelectionMerge(uint32_t merge_id) {
	RegisterBlock(merge_id, false);
	BasicBlock& merge_block = blocks_.at(merge_id);
	current_block_->set_type(kBlockTypeSelection);
	merge_block.set_type(kBlockTypeMerge);
	merge_block_header_[&merge_block] = current_block_;

	AddConstruct({ConstructType::kSelection, current_block(), &merge_block});

	return SPV_SUCCESS;
	}

	spv_result_t Function::RegisterSetFunctionDeclType(FunctionDecl type) {
	assert(declaration_type_ == FunctionDecl::kFunctionDeclUnknown);
	declaration_type_ = type;
	return SPV_SUCCESS;
	}

	spv_result_t Function::RegisterBlock(uint32_t block_id, bool is_definition) {
	assert(
	declaration_type_ == FunctionDecl::kFunctionDeclDefinition &&
	"RegisterBlocks can only be called after declaration_type_ is defined");

	std::unordered_map<uint32_t, BasicBlock>::iterator inserted_block;
	bool success = false;
	tie(inserted_block, success) =
	blocks_.insert({block_id, BasicBlock(block_id)});
	if (is_definition) { // new block definition
	assert(current_block_ == nullptr &&
	"Register Block can only be called when parsing a binary outside of "
	"a BasicBlock");

	undefined_blocks_.erase(block_id);
	current_block_ = &inserted_block->second;
	ordered_blocks_.push_back(current_block_);
	} else if (success) { // Block doesn't exsist but this is not a definition
	undefined_blocks_.insert(block_id);
	}

	return SPV_SUCCESS;
	}

	void Function::RegisterBlockEnd(std::vector<uint32_t> next_list) {
	assert(
	current_block_ &&
	"RegisterBlockEnd can only be called when parsing a binary in a block");
	std::vector<BasicBlock*> next_blocks;
	next_blocks.reserve(next_list.size());

	std::unordered_map<uint32_t, BasicBlock>::iterator inserted_block;
	bool success;
	for (uint32_t successor_id : next_list) {
	tie(inserted_block, success) =
	blocks_.insert({successor_id, BasicBlock(successor_id)});
	if (success) {
	undefined_blocks_.insert(successor_id);
	}
	next_blocks.push_back(&inserted_block->second);
	}

	if (current_block_->is_type(kBlockTypeLoop)) {
	// For each loop header, record the set of its successors, and include
	// its continue target if the continue target is not the loop header
	// itself.
	std::vector<BasicBlock*>& next_blocks_plus_continue_target =
	loop_header_successors_plus_continue_target_map_[current_block_];
	next_blocks_plus_continue_target = next_blocks;
	auto continue_target =
	FindConstructForEntryBlock(current_block_, ConstructType::kLoop)
	.corresponding_constructs()
	.back()
	->entry_block();
	if (continue_target != current_block_) {
	next_blocks_plus_continue_target.push_back(continue_target);
	}
	}

	current_block_->RegisterSuccessors(next_blocks);
	current_block_ = nullptr;
	return;
	}

	void Function::RegisterFunctionEnd() {
	if (!end_has_been_registered_) {
	end_has_been_registered_ = true;

	ComputeAugmentedCFG();
	}
	}

	size_t Function::block_count() const { return blocks_.size(); }

	size_t Function::undefined_block_count() const {
	return undefined_blocks_.size();
	}

	const std::vector<BasicBlock*>& Function::ordered_blocks() const {
	return ordered_blocks_;
	}
	std::vector<BasicBlock*>& Function::ordered_blocks() { return ordered_blocks_; }

	const BasicBlock* Function::current_block() const { return current_block_; }
	BasicBlock* Function::current_block() { return current_block_; }

	const std::list<Construct>& Function::constructs() const {
	return cfg_constructs_;
	}
	std::list<Construct>& Function::constructs() { return cfg_constructs_; }

	const BasicBlock* Function::first_block() const {
	if (ordered_blocks_.empty()) return nullptr;
	return ordered_blocks_[0];
	}
	BasicBlock* Function::first_block() {
	if (ordered_blocks_.empty()) return nullptr;
	return ordered_blocks_[0];
	}

	bool Function::IsBlockType(uint32_t merge_block_id, BlockType type) const {
	bool ret = false;
	const BasicBlock* block;
	std::tie(block, std::ignore) = GetBlock(merge_block_id);
	if (block) {
	ret = block->is_type(type);
	}
	return ret;
	}

	std::pair<const BasicBlock*, bool> Function::GetBlock(uint32_t block_id) const {
	const auto b = blocks_.find(block_id);
	if (b != end(blocks_)) {
	const BasicBlock* block = &(b->second);
	bool defined =
	undefined_blocks_.find(block->id()) == std::end(undefined_blocks_);
	return std::make_pair(block, defined);
	} else {
	return std::make_pair(nullptr, false);
	}
	}

	std::pair<BasicBlock*, bool> Function::GetBlock(uint32_t block_id) {
	const BasicBlock* out;
	bool defined;
	std::tie(out, defined) =
	const_cast<const Function*>(this)->GetBlock(block_id);
	return std::make_pair(const_cast<BasicBlock*>(out), defined);
	}

	Function::GetBlocksFunction Function::AugmentedCFGSuccessorsFunction() const {
	return [this](const BasicBlock* block) {
	auto where = augmented_successors_map_.find(block);
	return where == augmented_successors_map_.end() ? block->successors()
	: &(*where).second;
	};
	}

	Function::GetBlocksFunction
	Function::AugmentedCFGSuccessorsFunctionIncludingHeaderToContinueEdge() const {
	return [this](const BasicBlock* block) {
	auto where = loop_header_successors_plus_continue_target_map_.find(block);
	return where == loop_header_successors_plus_continue_target_map_.end()
	? AugmentedCFGSuccessorsFunction()(block)
	: &(*where).second;
	};
	}

	Function::GetBlocksFunction Function::AugmentedCFGPredecessorsFunction() const {
	return [this](const BasicBlock* block) {
	auto where = augmented_predecessors_map_.find(block);
	return where == augmented_predecessors_map_.end() ? block->predecessors()
	: &(*where).second;
	};
	}

	void Function::ComputeAugmentedCFG() {
	// Compute the successors of the pseudo-entry block, and
	// the predecessors of the pseudo exit block.
	auto succ_func = [](const BasicBlock* b) { return b->successors(); };
	auto pred_func = [](const BasicBlock* b) { return b->predecessors(); };
	CFA<BasicBlock>::ComputeAugmentedCFG(
	ordered_blocks_, &pseudo_entry_block_, &pseudo_exit_block_,
	&augmented_successors_map_, &augmented_predecessors_map_, succ_func,
	pred_func);
	}

	Construct& Function::AddConstruct(const Construct& new_construct) {
	cfg_constructs_.push_back(new_construct);
	auto& result = cfg_constructs_.back();
	entry_block_to_construct_[std::make_pair(new_construct.entry_block(),
	new_construct.type())] = &result;
	return result;
	}

	Construct& Function::FindConstructForEntryBlock(const BasicBlock* entry_block,
	ConstructType type) {
	auto where =
	entry_block_to_construct_.find(std::make_pair(entry_block, type));
	assert(where != entry_block_to_construct_.end());
	auto construct_ptr = (*where).second;
	assert(construct_ptr);
	return *construct_ptr;
	}

	int Function::GetBlockDepth(BasicBlock* bb) {
	// Guard against nullptr.
	if (!bb) {
	return 0;
	}
	// Only calculate the depth if it's not already calculated.
	// This function uses memoization to avoid duplicate CFG depth calculations.
	if (block_depth_.find(bb) != block_depth_.end()) {
	return block_depth_[bb];
	}
	// Avoid recursion. Something is wrong if the same block is encountered
	// multiple times.
	block_depth_[bb] = 0;

	BasicBlock* bb_dom = bb->immediate_dominator();
	if (!bb_dom \|\| bb == bb_dom) {
	// This block has no dominator, so it's at depth 0.
	block_depth_[bb] = 0;
	} else if (bb->is_type(kBlockTypeContinue)) {
	// This rule must precede the rule for merge blocks in order to set up
	// depths correctly. If a block is both a merge and continue then the merge
	// is nested within the continue's loop (or the graph is incorrect).
	// The depth of the continue block entry point is 1 + loop header depth.
	Construct* continue_construct =
	entry_block_to_construct_[std::make_pair(bb, ConstructType::kContinue)];
	assert(continue_construct);
	// Continue construct has only 1 corresponding construct (loop header).
	Construct* loop_construct =
	continue_construct->corresponding_constructs()[0];
	assert(loop_construct);
	BasicBlock* loop_header = loop_construct->entry_block();
	// The continue target may be the loop itself (while 1).
	// In such cases, the depth of the continue block is: 1 + depth of the
	// loop's dominator block.
	if (loop_header == bb) {
	block_depth_[bb] = 1 + GetBlockDepth(bb_dom);
	} else {
	block_depth_[bb] = 1 + GetBlockDepth(loop_header);
	}
	} else if (bb->is_type(kBlockTypeMerge)) {
	// If this is a merge block, its depth is equal to the block before
	// branching.
	BasicBlock* header = merge_block_header_[bb];
	assert(header);
	block_depth_[bb] = GetBlockDepth(header);
	} else if (bb_dom->is_type(kBlockTypeSelection) \|\|
	bb_dom->is_type(kBlockTypeLoop)) {
	// The dominator of the given block is a header block. So, the nesting
	// depth of this block is: 1 + nesting depth of the header.
	block_depth_[bb] = 1 + GetBlockDepth(bb_dom);
	} else {
	block_depth_[bb] = GetBlockDepth(bb_dom);
	}
	return block_depth_[bb];
	}

	void Function::RegisterExecutionModelLimitation(SpvExecutionModel model,
	const std::string& message) {
	execution_model_limitations_.push_back(
	[model, message](SpvExecutionModel in_model, std::string* out_message) {
	if (model != in_model) {
	if (out_message) {
	*out_message = message;
	}
	return false;
	}
	return true;
	});
	}

	bool Function::IsCompatibleWithExecutionModel(SpvExecutionModel model,
	std::string* reason) const {
	bool return_value = true;
	std::stringstream ss_reason;

	for (const auto& is_compatible : execution_model_limitations_) {
	std::string message;
	if (!is_compatible(model, &message)) {
	if (!reason) return false;
	return_value = false;
	if (!message.empty()) {
	ss_reason << message << "\n";
	}
	}
	}

	if (!return_value && reason) {
	*reason = ss_reason.str();
	}

	return return_value;
	}

	bool Function::CheckLimitations(const ValidationState_t& _,
	const Function* entry_point,
	std::string* reason) const {
	bool return_value = true;
	std::stringstream ss_reason;

	for (const auto& is_compatible : limitations_) {
	std::string message;
	if (!is_compatible(_, entry_point, &message)) {
	if (!reason) return false;
	return_value = false;
	if (!message.empty()) {
	ss_reason << message << "\n";
	}
	}
	}

	if (!return_value && reason) {
	*reason = ss_reason.str();
	}

	return return_value;
	}

	} // namespace val
	} // namespace spvtools