mirror of
https://github.com/KhronosGroup/SPIRV-Tools
synced 2024-11-30 15:00:06 +00:00
3497a94460
It moves all conditional branching and switch whose conditions are loop invariant and uniform. Before performing the loop unswitch we check that the loop does not contain any instruction that would prevent it (barriers, group instructions etc.).
307 lines
12 KiB
C++
307 lines
12 KiB
C++
// Copyright (c) 2017 Google 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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#ifndef LIBSPIRV_OPT_DOMINATOR_ANALYSIS_TREE_H_
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#define LIBSPIRV_OPT_DOMINATOR_ANALYSIS_TREE_H_
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#include <algorithm>
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#include <cstdint>
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#include <map>
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#include <utility>
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#include <vector>
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#include "cfg.h"
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#include "module.h"
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#include "tree_iterator.h"
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namespace spvtools {
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namespace opt {
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// This helper struct forms the nodes in the tree, with each node containing its
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// children. It also contains two values, for the pre and post indexes in the
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// tree which are used to compare two nodes.
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struct DominatorTreeNode {
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explicit DominatorTreeNode(ir::BasicBlock* bb)
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: bb_(bb),
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parent_(nullptr),
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children_({}),
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dfs_num_pre_(-1),
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dfs_num_post_(-1) {}
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using iterator = std::vector<DominatorTreeNode*>::iterator;
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using const_iterator = std::vector<DominatorTreeNode*>::const_iterator;
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// depth first preorder iterator.
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using df_iterator = TreeDFIterator<DominatorTreeNode>;
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using const_df_iterator = TreeDFIterator<const DominatorTreeNode>;
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// depth first postorder iterator.
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using post_iterator = PostOrderTreeDFIterator<DominatorTreeNode>;
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using const_post_iterator = PostOrderTreeDFIterator<const DominatorTreeNode>;
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iterator begin() { return children_.begin(); }
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iterator end() { return children_.end(); }
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const_iterator begin() const { return cbegin(); }
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const_iterator end() const { return cend(); }
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const_iterator cbegin() const { return children_.begin(); }
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const_iterator cend() const { return children_.end(); }
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// Depth first preorder iterator using this node as root.
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df_iterator df_begin() { return df_iterator(this); }
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df_iterator df_end() { return df_iterator(); }
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const_df_iterator df_begin() const { return df_cbegin(); }
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const_df_iterator df_end() const { return df_cend(); }
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const_df_iterator df_cbegin() const { return const_df_iterator(this); }
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const_df_iterator df_cend() const { return const_df_iterator(); }
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// Depth first postorder iterator using this node as root.
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post_iterator post_begin() { return post_iterator::begin(this); }
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post_iterator post_end() { return post_iterator::end(nullptr); }
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const_post_iterator post_begin() const { return post_cbegin(); }
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const_post_iterator post_end() const { return post_cend(); }
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const_post_iterator post_cbegin() const {
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return const_post_iterator::begin(this);
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}
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const_post_iterator post_cend() const {
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return const_post_iterator::end(nullptr);
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}
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inline uint32_t id() const { return bb_->id(); }
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ir::BasicBlock* bb_;
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DominatorTreeNode* parent_;
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std::vector<DominatorTreeNode*> children_;
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// These indexes are used to compare two given nodes. A node is a child or
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// grandchild of another node if its preorder index is greater than the
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// first nodes preorder index AND if its postorder index is less than the
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// first nodes postorder index.
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int dfs_num_pre_;
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int dfs_num_post_;
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};
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// A class representing a tree of BasicBlocks in a given function, where each
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// node is dominated by its parent.
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class DominatorTree {
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public:
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// Map OpLabel ids to dominator tree nodes
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using DominatorTreeNodeMap = std::map<uint32_t, DominatorTreeNode>;
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using iterator = TreeDFIterator<DominatorTreeNode>;
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using const_iterator = TreeDFIterator<const DominatorTreeNode>;
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using post_iterator = PostOrderTreeDFIterator<DominatorTreeNode>;
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using const_post_iterator = PostOrderTreeDFIterator<const DominatorTreeNode>;
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// List of DominatorTreeNode to define the list of roots
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using DominatorTreeNodeList = std::vector<DominatorTreeNode*>;
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using roots_iterator = DominatorTreeNodeList::iterator;
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using roots_const_iterator = DominatorTreeNodeList::const_iterator;
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DominatorTree() : postdominator_(false) {}
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explicit DominatorTree(bool post) : postdominator_(post) {}
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// Depth first iterators.
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// Traverse the dominator tree in a depth first pre-order.
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// The pseudo-block is ignored.
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iterator begin() { return ++iterator(GetRoot()); }
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iterator end() { return iterator(); }
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const_iterator begin() const { return cbegin(); }
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const_iterator end() const { return cend(); }
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const_iterator cbegin() const { return ++const_iterator(GetRoot()); }
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const_iterator cend() const { return const_iterator(); }
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// Traverse the dominator tree in a depth first post-order.
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// The pseudo-block is ignored.
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post_iterator post_begin() { return post_iterator::begin(GetRoot()); }
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post_iterator post_end() { return post_iterator::end(GetRoot()); }
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const_post_iterator post_begin() const { return post_cbegin(); }
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const_post_iterator post_end() const { return post_cend(); }
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const_post_iterator post_cbegin() const {
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return const_post_iterator::begin(GetRoot());
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}
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const_post_iterator post_cend() const {
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return const_post_iterator::end(GetRoot());
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}
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roots_iterator roots_begin() { return roots_.begin(); }
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roots_iterator roots_end() { return roots_.end(); }
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roots_const_iterator roots_begin() const { return roots_cbegin(); }
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roots_const_iterator roots_end() const { return roots_cend(); }
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roots_const_iterator roots_cbegin() const { return roots_.begin(); }
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roots_const_iterator roots_cend() const { return roots_.end(); }
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// Get the unique root of the tree.
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// It is guaranteed to work on a dominator tree.
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// post-dominator might have a list.
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DominatorTreeNode* GetRoot() {
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assert(roots_.size() == 1);
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return *roots_.begin();
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}
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const DominatorTreeNode* GetRoot() const {
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assert(roots_.size() == 1);
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return *roots_.begin();
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}
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const DominatorTreeNodeList& Roots() const { return roots_; }
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// Dumps the tree in the graphvis dot format into the |out_stream|.
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void DumpTreeAsDot(std::ostream& out_stream) const;
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// Build the (post-)dominator tree for the function |f|
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// Any existing data will be overwritten
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void InitializeTree(const ir::Function* f, const ir::CFG& cfg);
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// Check if the basic block |a| dominates the basic block |b|.
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bool Dominates(const ir::BasicBlock* a, const ir::BasicBlock* b) const;
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// Check if the basic block id |a| dominates the basic block id |b|.
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bool Dominates(uint32_t a, uint32_t b) const;
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// Check if the dominator tree node |a| dominates the dominator tree node |b|.
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bool Dominates(const DominatorTreeNode* a, const DominatorTreeNode* b) const;
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// Check if the basic block |a| strictly dominates the basic block |b|.
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bool StrictlyDominates(const ir::BasicBlock* a,
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const ir::BasicBlock* b) const;
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// Check if the basic block id |a| strictly dominates the basic block id |b|.
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bool StrictlyDominates(uint32_t a, uint32_t b) const;
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// Check if the dominator tree node |a| strictly dominates the dominator tree
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// node |b|.
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bool StrictlyDominates(const DominatorTreeNode* a,
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const DominatorTreeNode* b) const;
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// Returns the immediate dominator of basic block |a|.
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ir::BasicBlock* ImmediateDominator(const ir::BasicBlock* A) const;
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// Returns the immediate dominator of basic block id |a|.
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ir::BasicBlock* ImmediateDominator(uint32_t a) const;
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// Returns true if the basic block |a| is reachable by this tree. A node would
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// be unreachable if it cannot be reached by traversal from the start node or
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// for a postdominator tree, cannot be reached from the exit nodes.
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inline bool ReachableFromRoots(const ir::BasicBlock* a) const {
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if (!a) return false;
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return ReachableFromRoots(a->id());
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}
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// Returns true if the basic block id |a| is reachable by this tree.
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bool ReachableFromRoots(uint32_t a) const {
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return GetTreeNode(a) != nullptr;
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}
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// Returns true if this tree is a post dominator tree.
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bool IsPostDominator() const { return postdominator_; }
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// Clean up the tree.
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void ClearTree() {
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nodes_.clear();
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roots_.clear();
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}
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// Applies the std::function |func| to all nodes in the dominator tree.
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// Tree nodes are visited in a depth first pre-order.
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bool Visit(std::function<bool(DominatorTreeNode*)> func) {
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for (auto n : *this) {
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if (!func(&n)) return false;
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}
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return true;
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}
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// Applies the std::function |func| to all nodes in the dominator tree.
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// Tree nodes are visited in a depth first pre-order.
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bool Visit(std::function<bool(const DominatorTreeNode*)> func) const {
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for (auto n : *this) {
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if (!func(&n)) return false;
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}
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return true;
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}
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// Applies the std::function |func| to all nodes in the dominator tree from
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// |node| downwards. The boolean return from |func| is used to determine
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// whether or not the children should also be traversed. Tree nodes are
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// visited in a depth first pre-order.
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void VisitChildrenIf(std::function<bool(DominatorTreeNode*)> func,
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iterator node) {
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if (func(&*node)) {
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for (auto n : *node) {
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VisitChildrenIf(func, n->df_begin());
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}
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}
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}
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// Returns the DominatorTreeNode associated with the basic block |bb|.
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// If the |bb| is unknown to the dominator tree, it returns null.
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inline DominatorTreeNode* GetTreeNode(ir::BasicBlock* bb) {
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return GetTreeNode(bb->id());
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}
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// Returns the DominatorTreeNode associated with the basic block |bb|.
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// If the |bb| is unknown to the dominator tree, it returns null.
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inline const DominatorTreeNode* GetTreeNode(ir::BasicBlock* bb) const {
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return GetTreeNode(bb->id());
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}
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// Returns the DominatorTreeNode associated with the basic block id |id|.
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// If the id |id| is unknown to the dominator tree, it returns null.
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inline DominatorTreeNode* GetTreeNode(uint32_t id) {
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DominatorTreeNodeMap::iterator node_iter = nodes_.find(id);
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if (node_iter == nodes_.end()) {
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return nullptr;
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}
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return &node_iter->second;
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}
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// Returns the DominatorTreeNode associated with the basic block id |id|.
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// If the id |id| is unknown to the dominator tree, it returns null.
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inline const DominatorTreeNode* GetTreeNode(uint32_t id) const {
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DominatorTreeNodeMap::const_iterator node_iter = nodes_.find(id);
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if (node_iter == nodes_.end()) {
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return nullptr;
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}
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return &node_iter->second;
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}
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// Adds the basic block |bb| to the tree structure if it doesn't already
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// exist.
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DominatorTreeNode* GetOrInsertNode(ir::BasicBlock* bb);
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// Recomputes the DF numbering of the tree.
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void ResetDFNumbering();
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private:
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// Wrapper function which gets the list of pairs of each BasicBlocks to its
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// immediately dominating BasicBlock and stores the result in the the edges
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// parameter.
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//
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// The |edges| vector will contain the dominator tree as pairs of nodes.
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// The first node in the pair is a node in the graph. The second node in the
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// pair is its immediate dominator.
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// The root of the tree has themself as immediate dominator.
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void GetDominatorEdges(
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const ir::Function* f, const ir::BasicBlock* dummy_start_node,
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std::vector<std::pair<ir::BasicBlock*, ir::BasicBlock*>>* edges);
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// The roots of the tree.
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std::vector<DominatorTreeNode*> roots_;
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// Pairs each basic block id to the tree node containing that basic block.
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DominatorTreeNodeMap nodes_;
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// True if this is a post dominator tree.
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bool postdominator_;
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};
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} // namespace opt
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} // namespace spvtools
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#endif // LIBSPIRV_OPT_DOMINATOR_ANALYSIS_TREE_H_
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