// 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_TREE_ITERATOR_H_ #define SOURCE_OPT_TREE_ITERATOR_H_ #include #include #include namespace spvtools { namespace opt { // Helper class to iterate over a tree in a depth first order. // The class assumes the data structure is a tree, tree node type implements a // forward iterator. // At each step, the iterator holds the pointer to the current node and state of // the walk. // The state is recorded by stacking the iteration position of the node // children. To move to the next node, the iterator: // - Looks at the top of the stack; // - Sets the node behind the iterator as the current node; // - Increments the iterator if it has more children to visit, pops otherwise; // - If the current node has children, the children iterator is pushed into the // stack. template class TreeDFIterator { static_assert(!std::is_pointer::value && !std::is_reference::value, "NodeTy should be a class"); // Type alias to keep track of the const qualifier. using NodeIterator = typename std::conditional::value, typename NodeTy::const_iterator, typename NodeTy::iterator>::type; // Type alias to keep track of the const qualifier. using NodePtr = NodeTy*; public: // Standard iterator interface. using reference = NodeTy&; using value_type = NodeTy; explicit inline TreeDFIterator(NodePtr top_node) : current_(top_node) { if (current_ && current_->begin() != current_->end()) parent_iterators_.emplace(make_pair(current_, current_->begin())); } // end() iterator. inline TreeDFIterator() : TreeDFIterator(nullptr) {} bool operator==(const TreeDFIterator& x) const { return current_ == x.current_; } bool operator!=(const TreeDFIterator& x) const { return !(*this == x); } reference operator*() const { return *current_; } NodePtr operator->() const { return current_; } TreeDFIterator& operator++() { MoveToNextNode(); return *this; } TreeDFIterator operator++(int) { TreeDFIterator tmp = *this; ++*this; return tmp; } private: // Moves the iterator to the next node in the tree. // If we are at the end, do nothing, otherwise // if our current node has children, use the children iterator and push the // current node into the stack. // If we reach the end of the local iterator, pop it. inline void MoveToNextNode() { if (!current_) return; if (parent_iterators_.empty()) { current_ = nullptr; return; } std::pair& next_it = parent_iterators_.top(); // Set the new node. current_ = *next_it.second; // Update the iterator for the next child. ++next_it.second; // If we finished with node, pop it. if (next_it.first->end() == next_it.second) parent_iterators_.pop(); // If our current node is not a leaf, store the iteration state for later. if (current_->begin() != current_->end()) parent_iterators_.emplace(make_pair(current_, current_->begin())); } // The current node of the tree. NodePtr current_; // State of the tree walk: each pair contains the parent node (which has been // already visited) and the iterator of the next children to visit. // When all the children has been visited, we pop the entry, get the next // child and push back the pair if the children iterator is not end(). std::stack> parent_iterators_; }; // Helper class to iterate over a tree in a depth first post-order. // The class assumes the data structure is a tree, tree node type implements a // forward iterator. // At each step, the iterator holds the pointer to the current node and state of // the walk. // The state is recorded by stacking the iteration position of the node // children. To move to the next node, the iterator: // - Looks at the top of the stack; // - If the children iterator has reach the end, then the node become the // current one and we pop the stack; // - Otherwise, we save the child and increment the iterator; // - We walk the child sub-tree until we find a leaf, stacking all non-leaves // states (pair of node pointer and child iterator) as we walk it. template class PostOrderTreeDFIterator { static_assert(!std::is_pointer::value && !std::is_reference::value, "NodeTy should be a class"); // Type alias to keep track of the const qualifier. using NodeIterator = typename std::conditional::value, typename NodeTy::const_iterator, typename NodeTy::iterator>::type; // Type alias to keep track of the const qualifier. using NodePtr = NodeTy*; public: // Standard iterator interface. using reference = NodeTy&; using value_type = NodeTy; static inline PostOrderTreeDFIterator begin(NodePtr top_node) { return PostOrderTreeDFIterator(top_node); } static inline PostOrderTreeDFIterator end(NodePtr sentinel_node) { return PostOrderTreeDFIterator(sentinel_node, false); } bool operator==(const PostOrderTreeDFIterator& x) const { return current_ == x.current_; } bool operator!=(const PostOrderTreeDFIterator& x) const { return !(*this == x); } reference operator*() const { return *current_; } NodePtr operator->() const { return current_; } PostOrderTreeDFIterator& operator++() { MoveToNextNode(); return *this; } PostOrderTreeDFIterator operator++(int) { PostOrderTreeDFIterator tmp = *this; ++*this; return tmp; } private: explicit inline PostOrderTreeDFIterator(NodePtr top_node) : current_(top_node) { if (current_) WalkToLeaf(); } // Constructor for the "end()" iterator. // |end_sentinel| is the value that acts as end value (can be null). The bool // parameters is to distinguish from the start() Ctor. inline PostOrderTreeDFIterator(NodePtr sentinel_node, bool) : current_(sentinel_node) {} // Moves the iterator to the next node in the tree. // If we are at the end, do nothing, otherwise // if our current node has children, use the children iterator and push the // current node into the stack. // If we reach the end of the local iterator, pop it. inline void MoveToNextNode() { if (!current_) return; if (parent_iterators_.empty()) { current_ = nullptr; return; } std::pair& next_it = parent_iterators_.top(); // If we visited all children, the current node is the top of the stack. if (next_it.second == next_it.first->end()) { // Set the new node. current_ = next_it.first; parent_iterators_.pop(); return; } // We have more children to visit, set the current node to the first child // and dive to leaf. current_ = *next_it.second; // Update the iterator for the next child (avoid unneeded pop). ++next_it.second; WalkToLeaf(); } // Moves the iterator to the next node in the tree. // If we are at the end, do nothing, otherwise // if our current node has children, use the children iterator and push the // current node into the stack. // If we reach the end of the local iterator, pop it. inline void WalkToLeaf() { while (current_->begin() != current_->end()) { NodeIterator next = ++current_->begin(); parent_iterators_.emplace(make_pair(current_, next)); // Set the first child as the new node. current_ = *current_->begin(); } } // The current node of the tree. NodePtr current_; // State of the tree walk: each pair contains the parent node and the iterator // of the next children to visit. // When all the children has been visited, we pop the first entry and the // parent node become the current node. std::stack> parent_iterators_; }; } // namespace opt } // namespace spvtools #endif // SOURCE_OPT_TREE_ITERATOR_H_