source/opt/cfg.h - external/github.com/KhronosGroup/SPIRV-Tools - Git at Google

 // Copyright (c) 2017 Google 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.

 #ifndef SOURCE_OPT_CFG_H_
 #define SOURCE_OPT_CFG_H_

 #include <algorithm>
 #include <list>
 #include <unordered_map>
 #include <unordered_set>
 #include <vector>

 #include "source/opt/basic_block.h"

 namespace spvtools {
 namespace opt {

 class CFG {
  public:
   explicit CFG(Module* module);

   // Return the list of predecesors for basic block with label |blkid|.
   // TODO(dnovillo): Move this to BasicBlock.
   const std::vector<uint32_t>& preds(uint32_t blk_id) const {
     assert(label2preds_.count(blk_id));
     return label2preds_.at(blk_id);
   }

   // Return a pointer to the basic block instance corresponding to the label
   // |blk_id|.
   BasicBlock* block(uint32_t blk_id) const { return id2block_.at(blk_id); }

   // Return the pseudo entry and exit blocks.
   const BasicBlock* pseudo_entry_block() const { return &pseudo_entry_block_; }
   BasicBlock* pseudo_entry_block() { return &pseudo_entry_block_; }

   const BasicBlock* pseudo_exit_block() const { return &pseudo_exit_block_; }
   BasicBlock* pseudo_exit_block() { return &pseudo_exit_block_; }

   // Return true if |block_ptr| is the pseudo-entry block.
   bool IsPseudoEntryBlock(BasicBlock* block_ptr) const {
     return block_ptr == &pseudo_entry_block_;
   }

   // Return true if |block_ptr| is the pseudo-exit block.
   bool IsPseudoExitBlock(BasicBlock* block_ptr) const {
     return block_ptr == &pseudo_exit_block_;
   }

   // Compute structured block order into |order| for |func| starting at |root|.
   // This order has the property that dominators come before all blocks they
   // dominate and merge blocks come after all blocks that are in the control
   // constructs of their header.
   void ComputeStructuredOrder(Function* func, BasicBlock* root,
                               std::list<BasicBlock*>* order);

   // Applies |f| to the basic block in post order starting with |bb|.
   // Note that basic blocks that cannot be reached from |bb| node will not be
   // processed.
   void ForEachBlockInPostOrder(BasicBlock* bb,
                                const std::function<void(BasicBlock*)>& f);

   // Applies |f| to the basic block in reverse post order starting with |bb|.
   // Note that basic blocks that cannot be reached from |bb| node will not be
   // processed.
   void ForEachBlockInReversePostOrder(
       BasicBlock* bb, const std::function<void(BasicBlock*)>& f);

   // Registers |blk| as a basic block in the cfg, this also updates the
   // predecessor lists of each successor of |blk|. |blk| must have a terminator
   // instruction at the end of the block.
   void RegisterBlock(BasicBlock* blk) {
     assert(blk->begin() != blk->end() &&
            "Basic blocks must have a terminator before registering.");
     assert(blk->tail()->IsBlockTerminator() &&
            "Basic blocks must have a terminator before registering.");
     uint32_t blk_id = blk->id();
     id2block_[blk_id] = blk;
     AddEdges(blk);
   }

   // Removes from the CFG any mapping for the basic block id |blk_id|.
   void ForgetBlock(const BasicBlock* blk) {
     id2block_.erase(blk->id());
     label2preds_.erase(blk->id());
     RemoveSuccessorEdges(blk);
   }

   void RemoveEdge(uint32_t pred_blk_id, uint32_t succ_blk_id) {
     auto pred_it = label2preds_.find(succ_blk_id);
     if (pred_it == label2preds_.end()) return;
     auto& preds_list = pred_it->second;
     auto it = std::find(preds_list.begin(), preds_list.end(), pred_blk_id);
     if (it != preds_list.end()) preds_list.erase(it);
   }

   // Registers |blk| to all of its successors.
   void AddEdges(BasicBlock* blk);

   // Registers the basic block id |pred_blk_id| as being a predecessor of the
   // basic block id |succ_blk_id|.
   void AddEdge(uint32_t pred_blk_id, uint32_t succ_blk_id) {
     label2preds_[succ_blk_id].push_back(pred_blk_id);
   }

   // Removes any edges that no longer exist from the predecessor mapping for
   // the basic block id |blk_id|.
   void RemoveNonExistingEdges(uint32_t blk_id);

   // Remove all edges that leave |bb|.
   void RemoveSuccessorEdges(const BasicBlock* bb) {
     bb->ForEachSuccessorLabel(
         [bb, this](uint32_t succ_id) { RemoveEdge(bb->id(), succ_id); });
   }

   // Divides |block| into two basic blocks.  The first block will have the same
   // id as |block| and will become a preheader for the loop.  The other block
   // is a new block that will be the new loop header.
   //
   // Returns a pointer to the new loop header.  Returns |nullptr| if the new
   // loop pointer could not be created.
   BasicBlock* SplitLoopHeader(BasicBlock* bb);

  private:
   // Compute structured successors for function |func|. A block's structured
   // successors are the blocks it branches to together with its declared merge
   // block and continue block if it has them. When order matters, the merge
   // block and continue block always appear first. This assures correct depth
   // first search in the presence of early returns and kills. If the successor
   // vector contain duplicates of the merge or continue blocks, they are safely
   // ignored by DFS.
   void ComputeStructuredSuccessors(Function* func);

   // Computes the post-order traversal of the cfg starting at |bb| skipping
   // nodes in |seen|.  The order of the traversal is appended to |order|, and
   // all nodes in the traversal are added to |seen|.
   void ComputePostOrderTraversal(BasicBlock* bb,
                                  std::vector<BasicBlock*>* order,
                                  std::unordered_set<BasicBlock*>* seen);

   // Module for this CFG.
   Module* module_;

   // Map from block to its structured successor blocks. See
   // ComputeStructuredSuccessors() for definition.
   std::unordered_map<const BasicBlock*, std::vector<BasicBlock*>>
       block2structured_succs_;

   // Extra block whose successors are all blocks with no predecessors
   // in function.
   BasicBlock pseudo_entry_block_;

   // Augmented CFG Exit Block.
   BasicBlock pseudo_exit_block_;

   // Map from block's label id to its predecessor blocks ids
   std::unordered_map<uint32_t, std::vector<uint32_t>> label2preds_;

   // Map from block's label id to block.
   std::unordered_map<uint32_t, BasicBlock*> id2block_;
 };

 }  // namespace opt
 }  // namespace spvtools

 #endif  // SOURCE_OPT_CFG_H_
	// Copyright (c) 2017 Google 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.

	#ifndef SOURCE_OPT_CFG_H_
	#define SOURCE_OPT_CFG_H_

	#include <algorithm>
	#include <list>
	#include <unordered_map>
	#include <unordered_set>
	#include <vector>

	#include "source/opt/basic_block.h"

	namespace spvtools {
	namespace opt {

	class CFG {
	public:
	explicit CFG(Module* module);

	// Return the list of predecesors for basic block with label \|blkid\|.
	// TODO(dnovillo): Move this to BasicBlock.
	const std::vector<uint32_t>& preds(uint32_t blk_id) const {
	assert(label2preds_.count(blk_id));
	return label2preds_.at(blk_id);
	}

	// Return a pointer to the basic block instance corresponding to the label
	// \|blk_id\|.
	BasicBlock* block(uint32_t blk_id) const { return id2block_.at(blk_id); }

	// Return the pseudo entry and exit blocks.
	const BasicBlock* pseudo_entry_block() const { return &pseudo_entry_block_; }
	BasicBlock* pseudo_entry_block() { return &pseudo_entry_block_; }

	const BasicBlock* pseudo_exit_block() const { return &pseudo_exit_block_; }
	BasicBlock* pseudo_exit_block() { return &pseudo_exit_block_; }

	// Return true if \|block_ptr\| is the pseudo-entry block.
	bool IsPseudoEntryBlock(BasicBlock* block_ptr) const {
	return block_ptr == &pseudo_entry_block_;
	}

	// Return true if \|block_ptr\| is the pseudo-exit block.
	bool IsPseudoExitBlock(BasicBlock* block_ptr) const {
	return block_ptr == &pseudo_exit_block_;
	}

	// Compute structured block order into \|order\| for \|func\| starting at \|root\|.
	// This order has the property that dominators come before all blocks they
	// dominate and merge blocks come after all blocks that are in the control
	// constructs of their header.
	void ComputeStructuredOrder(Function* func, BasicBlock* root,
	std::list<BasicBlock> order);

	// Applies \|f\| to the basic block in post order starting with \|bb\|.
	// Note that basic blocks that cannot be reached from \|bb\| node will not be
	// processed.
	void ForEachBlockInPostOrder(BasicBlock* bb,
	const std::function<void(BasicBlock*)>& f);

	// Applies \|f\| to the basic block in reverse post order starting with \|bb\|.
	// Note that basic blocks that cannot be reached from \|bb\| node will not be
	// processed.
	void ForEachBlockInReversePostOrder(
	BasicBlock* bb, const std::function<void(BasicBlock*)>& f);

	// Registers \|blk\| as a basic block in the cfg, this also updates the
	// predecessor lists of each successor of \|blk\|. \|blk\| must have a terminator
	// instruction at the end of the block.
	void RegisterBlock(BasicBlock* blk) {
	assert(blk->begin() != blk->end() &&
	"Basic blocks must have a terminator before registering.");
	assert(blk->tail()->IsBlockTerminator() &&
	"Basic blocks must have a terminator before registering.");
	uint32_t blk_id = blk->id();
	id2block_[blk_id] = blk;
	AddEdges(blk);
	}

	// Removes from the CFG any mapping for the basic block id \|blk_id\|.
	void ForgetBlock(const BasicBlock* blk) {
	id2block_.erase(blk->id());
	label2preds_.erase(blk->id());
	RemoveSuccessorEdges(blk);
	}

	void RemoveEdge(uint32_t pred_blk_id, uint32_t succ_blk_id) {
	auto pred_it = label2preds_.find(succ_blk_id);
	if (pred_it == label2preds_.end()) return;
	auto& preds_list = pred_it->second;
	auto it = std::find(preds_list.begin(), preds_list.end(), pred_blk_id);
	if (it != preds_list.end()) preds_list.erase(it);
	}

	// Registers \|blk\| to all of its successors.
	void AddEdges(BasicBlock* blk);

	// Registers the basic block id \|pred_blk_id\| as being a predecessor of the
	// basic block id \|succ_blk_id\|.
	void AddEdge(uint32_t pred_blk_id, uint32_t succ_blk_id) {
	label2preds_[succ_blk_id].push_back(pred_blk_id);
	}

	// Removes any edges that no longer exist from the predecessor mapping for
	// the basic block id \|blk_id\|.
	void RemoveNonExistingEdges(uint32_t blk_id);

	// Remove all edges that leave \|bb\|.
	void RemoveSuccessorEdges(const BasicBlock* bb) {
	bb->ForEachSuccessorLabel(
	[bb, this](uint32_t succ_id) { RemoveEdge(bb->id(), succ_id); });
	}

	// Divides \|block\| into two basic blocks. The first block will have the same
	// id as \|block\| and will become a preheader for the loop. The other block
	// is a new block that will be the new loop header.
	//
	// Returns a pointer to the new loop header. Returns \|nullptr\| if the new
	// loop pointer could not be created.
	BasicBlock* SplitLoopHeader(BasicBlock* bb);

	private:
	// Compute structured successors for function \|func\|. A block's structured
	// successors are the blocks it branches to together with its declared merge
	// block and continue block if it has them. When order matters, the merge
	// block and continue block always appear first. This assures correct depth
	// first search in the presence of early returns and kills. If the successor
	// vector contain duplicates of the merge or continue blocks, they are safely
	// ignored by DFS.
	void ComputeStructuredSuccessors(Function* func);

	// Computes the post-order traversal of the cfg starting at \|bb\| skipping
	// nodes in \|seen\|. The order of the traversal is appended to \|order\|, and
	// all nodes in the traversal are added to \|seen\|.
	void ComputePostOrderTraversal(BasicBlock* bb,
	std::vector<BasicBlock> order,
	std::unordered_set<BasicBlock> seen);

	// Module for this CFG.
	Module* module_;

	// Map from block to its structured successor blocks. See
	// ComputeStructuredSuccessors() for definition.
	std::unordered_map<const BasicBlock, std::vector<BasicBlock>>
	block2structured_succs_;

	// Extra block whose successors are all blocks with no predecessors
	// in function.
	BasicBlock pseudo_entry_block_;

	// Augmented CFG Exit Block.
	BasicBlock pseudo_exit_block_;

	// Map from block's label id to its predecessor blocks ids
	std::unordered_map<uint32_t, std::vector<uint32_t>> label2preds_;

	// Map from block's label id to block.
	std::unordered_map<uint32_t, BasicBlock*> id2block_;
	};

	} // namespace opt
	} // namespace spvtools

	#endif // SOURCE_OPT_CFG_H_