mirror of
https://github.com/KhronosGroup/SPIRV-Tools
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58a6876cee
This CL rewrites the include guards to make PRESUBMIT.py include guard check happy.
348 lines
13 KiB
C++
348 lines
13 KiB
C++
// Copyright (c) 2015-2016 The Khronos Group 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 SOURCE_CFA_H_
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#define SOURCE_CFA_H_
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#include <algorithm>
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#include <cassert>
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#include <cstdint>
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#include <functional>
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#include <map>
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#include <unordered_map>
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#include <unordered_set>
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#include <utility>
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#include <vector>
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namespace spvtools {
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// Control Flow Analysis of control flow graphs of basic block nodes |BB|.
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template <class BB>
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class CFA {
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using bb_ptr = BB*;
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using cbb_ptr = const BB*;
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using bb_iter = typename std::vector<BB*>::const_iterator;
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using get_blocks_func = std::function<const std::vector<BB*>*(const BB*)>;
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struct block_info {
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cbb_ptr block; ///< pointer to the block
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bb_iter iter; ///< Iterator to the current child node being processed
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};
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/// Returns true if a block with @p id is found in the @p work_list vector
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///
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/// @param[in] work_list Set of blocks visited in the the depth first
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/// traversal
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/// of the CFG
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/// @param[in] id The ID of the block being checked
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///
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/// @return true if the edge work_list.back().block->id() => id is a back-edge
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static bool FindInWorkList(const std::vector<block_info>& work_list,
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uint32_t id);
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public:
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/// @brief Depth first traversal starting from the \p entry BasicBlock
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///
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/// This function performs a depth first traversal from the \p entry
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/// BasicBlock and calls the pre/postorder functions when it needs to process
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/// the node in pre order, post order. It also calls the backedge function
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/// when a back edge is encountered.
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///
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/// @param[in] entry The root BasicBlock of a CFG
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/// @param[in] successor_func A function which will return a pointer to the
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/// successor nodes
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/// @param[in] preorder A function that will be called for every block in a
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/// CFG following preorder traversal semantics
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/// @param[in] postorder A function that will be called for every block in a
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/// CFG following postorder traversal semantics
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/// @param[in] backedge A function that will be called when a backedge is
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/// encountered during a traversal
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/// NOTE: The @p successor_func and predecessor_func each return a pointer to
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/// a
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/// collection such that iterators to that collection remain valid for the
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/// lifetime of the algorithm.
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static void DepthFirstTraversal(
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const BB* entry, get_blocks_func successor_func,
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std::function<void(cbb_ptr)> preorder,
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std::function<void(cbb_ptr)> postorder,
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std::function<void(cbb_ptr, cbb_ptr)> backedge);
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/// @brief Calculates dominator edges for a set of blocks
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///
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/// Computes dominators using the algorithm of Cooper, Harvey, and Kennedy
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/// "A Simple, Fast Dominance Algorithm", 2001.
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///
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/// The algorithm assumes there is a unique root node (a node without
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/// predecessors), and it is therefore at the end of the postorder vector.
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///
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/// This function calculates the dominator edges for a set of blocks in the
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/// CFG.
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/// Uses the dominator algorithm by Cooper et al.
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///
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/// @param[in] postorder A vector of blocks in post order traversal
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/// order
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/// in a CFG
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/// @param[in] predecessor_func Function used to get the predecessor nodes of
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/// a
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/// block
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///
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/// @return the dominator tree of the graph, as a vector of 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 in the sense of Cooper et.al., where a
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/// block
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/// without predecessors (such as the root node) is its own immediate
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/// dominator.
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static std::vector<std::pair<BB*, BB*>> CalculateDominators(
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const std::vector<cbb_ptr>& postorder, get_blocks_func predecessor_func);
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// Computes a minimal set of root nodes required to traverse, in the forward
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// direction, the CFG represented by the given vector of blocks, and successor
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// and predecessor functions. When considering adding two nodes, each having
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// predecessors, favour using the one that appears earlier on the input blocks
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// list.
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static std::vector<BB*> TraversalRoots(const std::vector<BB*>& blocks,
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get_blocks_func succ_func,
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get_blocks_func pred_func);
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static void ComputeAugmentedCFG(
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std::vector<BB*>& ordered_blocks, BB* pseudo_entry_block,
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BB* pseudo_exit_block,
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std::unordered_map<const BB*, std::vector<BB*>>* augmented_successors_map,
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std::unordered_map<const BB*, std::vector<BB*>>*
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augmented_predecessors_map,
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get_blocks_func succ_func, get_blocks_func pred_func);
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};
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template <class BB>
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bool CFA<BB>::FindInWorkList(const std::vector<block_info>& work_list,
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uint32_t id) {
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for (const auto b : work_list) {
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if (b.block->id() == id) return true;
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}
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return false;
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}
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template <class BB>
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void CFA<BB>::DepthFirstTraversal(
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const BB* entry, get_blocks_func successor_func,
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std::function<void(cbb_ptr)> preorder,
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std::function<void(cbb_ptr)> postorder,
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std::function<void(cbb_ptr, cbb_ptr)> backedge) {
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std::unordered_set<uint32_t> processed;
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/// NOTE: work_list is the sequence of nodes from the root node to the node
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/// being processed in the traversal
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std::vector<block_info> work_list;
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work_list.reserve(10);
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work_list.push_back({entry, std::begin(*successor_func(entry))});
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preorder(entry);
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processed.insert(entry->id());
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while (!work_list.empty()) {
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block_info& top = work_list.back();
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if (top.iter == end(*successor_func(top.block))) {
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postorder(top.block);
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work_list.pop_back();
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} else {
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BB* child = *top.iter;
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top.iter++;
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if (FindInWorkList(work_list, child->id())) {
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backedge(top.block, child);
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}
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if (processed.count(child->id()) == 0) {
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preorder(child);
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work_list.emplace_back(
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block_info{child, std::begin(*successor_func(child))});
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processed.insert(child->id());
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}
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}
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}
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}
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template <class BB>
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std::vector<std::pair<BB*, BB*>> CFA<BB>::CalculateDominators(
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const std::vector<cbb_ptr>& postorder, get_blocks_func predecessor_func) {
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struct block_detail {
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size_t dominator; ///< The index of blocks's dominator in post order array
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size_t postorder_index; ///< The index of the block in the post order array
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};
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const size_t undefined_dom = postorder.size();
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std::unordered_map<cbb_ptr, block_detail> idoms;
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for (size_t i = 0; i < postorder.size(); i++) {
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idoms[postorder[i]] = {undefined_dom, i};
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}
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idoms[postorder.back()].dominator = idoms[postorder.back()].postorder_index;
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bool changed = true;
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while (changed) {
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changed = false;
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for (auto b = postorder.rbegin() + 1; b != postorder.rend(); ++b) {
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const std::vector<BB*>& predecessors = *predecessor_func(*b);
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// Find the first processed/reachable predecessor that is reachable
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// in the forward traversal.
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auto res = std::find_if(std::begin(predecessors), std::end(predecessors),
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[&idoms, undefined_dom](BB* pred) {
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return idoms.count(pred) &&
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idoms[pred].dominator != undefined_dom;
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});
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if (res == end(predecessors)) continue;
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const BB* idom = *res;
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size_t idom_idx = idoms[idom].postorder_index;
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// all other predecessors
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for (const auto* p : predecessors) {
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if (idom == p) continue;
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// Only consider nodes reachable in the forward traversal.
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// Otherwise the intersection doesn't make sense and will never
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// terminate.
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if (!idoms.count(p)) continue;
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if (idoms[p].dominator != undefined_dom) {
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size_t finger1 = idoms[p].postorder_index;
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size_t finger2 = idom_idx;
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while (finger1 != finger2) {
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while (finger1 < finger2) {
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finger1 = idoms[postorder[finger1]].dominator;
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}
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while (finger2 < finger1) {
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finger2 = idoms[postorder[finger2]].dominator;
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}
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}
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idom_idx = finger1;
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}
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}
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if (idoms[*b].dominator != idom_idx) {
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idoms[*b].dominator = idom_idx;
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changed = true;
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}
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}
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}
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std::vector<std::pair<bb_ptr, bb_ptr>> out;
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for (auto idom : idoms) {
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// NOTE: performing a const cast for convenient usage with
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// UpdateImmediateDominators
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out.push_back({const_cast<BB*>(std::get<0>(idom)),
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const_cast<BB*>(postorder[std::get<1>(idom).dominator])});
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}
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// Sort by postorder index to generate a deterministic ordering of edges.
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std::sort(
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out.begin(), out.end(),
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[&idoms](const std::pair<bb_ptr, bb_ptr>& lhs,
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const std::pair<bb_ptr, bb_ptr>& rhs) {
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assert(lhs.first);
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assert(lhs.second);
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assert(rhs.first);
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assert(rhs.second);
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auto lhs_indices = std::make_pair(idoms[lhs.first].postorder_index,
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idoms[lhs.second].postorder_index);
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auto rhs_indices = std::make_pair(idoms[rhs.first].postorder_index,
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idoms[rhs.second].postorder_index);
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return lhs_indices < rhs_indices;
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});
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return out;
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}
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template <class BB>
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std::vector<BB*> CFA<BB>::TraversalRoots(const std::vector<BB*>& blocks,
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get_blocks_func succ_func,
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get_blocks_func pred_func) {
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// The set of nodes which have been visited from any of the roots so far.
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std::unordered_set<const BB*> visited;
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auto mark_visited = [&visited](const BB* b) { visited.insert(b); };
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auto ignore_block = [](const BB*) {};
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auto ignore_blocks = [](const BB*, const BB*) {};
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auto traverse_from_root = [&mark_visited, &succ_func, &ignore_block,
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&ignore_blocks](const BB* entry) {
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DepthFirstTraversal(entry, succ_func, mark_visited, ignore_block,
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ignore_blocks);
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};
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std::vector<BB*> result;
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// First collect nodes without predecessors.
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for (auto block : blocks) {
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if (pred_func(block)->empty()) {
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assert(visited.count(block) == 0 && "Malformed graph!");
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result.push_back(block);
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traverse_from_root(block);
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}
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}
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// Now collect other stranded nodes. These must be in unreachable cycles.
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for (auto block : blocks) {
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if (visited.count(block) == 0) {
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result.push_back(block);
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traverse_from_root(block);
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}
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}
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return result;
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}
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template <class BB>
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void CFA<BB>::ComputeAugmentedCFG(
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std::vector<BB*>& ordered_blocks, BB* pseudo_entry_block,
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BB* pseudo_exit_block,
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std::unordered_map<const BB*, std::vector<BB*>>* augmented_successors_map,
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std::unordered_map<const BB*, std::vector<BB*>>* augmented_predecessors_map,
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get_blocks_func succ_func, get_blocks_func pred_func) {
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// Compute the successors of the pseudo-entry block, and
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// the predecessors of the pseudo exit block.
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auto sources = TraversalRoots(ordered_blocks, succ_func, pred_func);
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// For the predecessor traversals, reverse the order of blocks. This
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// will affect the post-dominance calculation as follows:
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// - Suppose you have blocks A and B, with A appearing before B in
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// the list of blocks.
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// - Also, A branches only to B, and B branches only to A.
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// - We want to compute A as dominating B, and B as post-dominating B.
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// By using reversed blocks for predecessor traversal roots discovery,
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// we'll add an edge from B to the pseudo-exit node, rather than from A.
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// All this is needed to correctly process the dominance/post-dominance
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// constraint when A is a loop header that points to itself as its
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// own continue target, and B is the latch block for the loop.
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std::vector<BB*> reversed_blocks(ordered_blocks.rbegin(),
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ordered_blocks.rend());
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auto sinks = TraversalRoots(reversed_blocks, pred_func, succ_func);
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// Wire up the pseudo entry block.
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(*augmented_successors_map)[pseudo_entry_block] = sources;
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for (auto block : sources) {
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auto& augmented_preds = (*augmented_predecessors_map)[block];
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const auto preds = pred_func(block);
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augmented_preds.reserve(1 + preds->size());
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augmented_preds.push_back(pseudo_entry_block);
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augmented_preds.insert(augmented_preds.end(), preds->begin(), preds->end());
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}
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// Wire up the pseudo exit block.
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(*augmented_predecessors_map)[pseudo_exit_block] = sinks;
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for (auto block : sinks) {
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auto& augmented_succ = (*augmented_successors_map)[block];
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const auto succ = succ_func(block);
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augmented_succ.reserve(1 + succ->size());
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augmented_succ.push_back(pseudo_exit_block);
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augmented_succ.insert(augmented_succ.end(), succ->begin(), succ->end());
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}
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}
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} // namespace spvtools
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#endif // SOURCE_CFA_H_
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