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1 //===- Dominance.h - Dominator analysis for CFGs ----------------*- C++ -*-===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 
9 #ifndef MLIR_IR_DOMINANCE_H
10 #define MLIR_IR_DOMINANCE_H
11 
12 #include "mlir/IR/RegionGraphTraits.h"
13 #include "llvm/Support/GenericDomTree.h"
14 
15 extern template class llvm::DominatorTreeBase<mlir::Block, false>;
16 extern template class llvm::DominatorTreeBase<mlir::Block, true>;
17 
18 namespace mlir {
19 using DominanceInfoNode = llvm::DomTreeNodeBase<Block>;
20 class Operation;
21 
22 namespace detail {
23 template <bool IsPostDom> class DominanceInfoBase {
24   using base = llvm::DominatorTreeBase<Block, IsPostDom>;
25 
26 public:
DominanceInfoBase(Operation * op)27   DominanceInfoBase(Operation *op) { recalculate(op); }
28   DominanceInfoBase(DominanceInfoBase &&) = default;
29   DominanceInfoBase &operator=(DominanceInfoBase &&) = default;
30 
31   DominanceInfoBase(const DominanceInfoBase &) = delete;
32   DominanceInfoBase &operator=(const DominanceInfoBase &) = delete;
33 
34   /// Recalculate the dominance info.
35   void recalculate(Operation *op);
36 
37   /// Finds the nearest common dominator block for the two given blocks a
38   /// and b. If no common dominator can be found, this function will return
39   /// nullptr.
40   Block *findNearestCommonDominator(Block *a, Block *b) const;
41 
42   /// Return true if there is dominanceInfo for the given region.
hasDominanceInfo(Region * region)43   bool hasDominanceInfo(Region *region) {
44     return dominanceInfos.count(region) != 0;
45   }
46 
47   /// Get the root dominance node of the given region.
getRootNode(Region * region)48   DominanceInfoNode *getRootNode(Region *region) {
49     assert(dominanceInfos.count(region) != 0);
50     return dominanceInfos[region]->getRootNode();
51   }
52 
53   /// Return the dominance node from the Region containing block A.
54   DominanceInfoNode *getNode(Block *a);
55 
56 protected:
57   using super = DominanceInfoBase<IsPostDom>;
58 
59   /// Return true if the specified block A properly dominates block B.
60   bool properlyDominates(Block *a, Block *b) const;
61 
62   /// Return true if the specified block is reachable from the entry
63   /// block of its region.
64   bool isReachableFromEntry(Block *a) const;
65 
66   /// A mapping of regions to their base dominator tree.
67   DenseMap<Region *, std::unique_ptr<base>> dominanceInfos;
68 };
69 } // end namespace detail
70 
71 /// A class for computing basic dominance information. Note that this
72 /// class is aware of different types of regions and returns a
73 /// region-kind specific concept of dominance. See RegionKindInterface.
74 class DominanceInfo : public detail::DominanceInfoBase</*IsPostDom=*/false> {
75 public:
76   using super::super;
77 
78   /// Return true if the specified block is reachable from the entry block of
79   /// its region. In an SSACFG region, a block is reachable from the entry block
80   /// if it is the successor of the entry block or another reachable block. In a
81   /// Graph region, all blocks are reachable.
isReachableFromEntry(Block * a)82   bool isReachableFromEntry(Block *a) const {
83     return super::isReachableFromEntry(a);
84   }
85 
86   /// Return true if operation A properly dominates operation B, i.e. if A and B
87   /// are in the same block and A properly dominates B within the block, or if
88   /// the block that contains A properly dominates the block that contains B. In
89   /// an SSACFG region, Operation A dominates Operation B in the same block if A
90   /// preceeds B. In a Graph region, all operations in a block dominate all
91   /// other operations in the same block.
92   bool properlyDominates(Operation *a, Operation *b) const;
93 
94   /// Return true if operation A dominates operation B, i.e. if A and B are the
95   /// same operation or A properly dominates B.
dominates(Operation * a,Operation * b)96   bool dominates(Operation *a, Operation *b) const {
97     return a == b || properlyDominates(a, b);
98   }
99 
100   /// Return true if value A properly dominates operation B, i.e if the
101   /// operation that defines A properlyDominates B and the operation that
102   /// defines A does not contain B.
103   bool properlyDominates(Value a, Operation *b) const;
104 
105   /// Return true if operation A dominates operation B, i.e if the operation
106   /// that defines A dominates B.
dominates(Value a,Operation * b)107   bool dominates(Value a, Operation *b) const {
108     return (Operation *)a.getDefiningOp() == b || properlyDominates(a, b);
109   }
110 
111   /// Return true if the specified block A dominates block B, i.e. if block A
112   /// and block B are the same block or block A properly dominates block B.
dominates(Block * a,Block * b)113   bool dominates(Block *a, Block *b) const {
114     return a == b || properlyDominates(a, b);
115   }
116 
117   /// Return true if the specified block A properly dominates block B, i.e.: if
118   /// block A contains block B, or if the region which contains block A also
119   /// contains block B or some parent of block B and block A dominates that
120   /// block in that kind of region.  In an SSACFG region, block A dominates
121   /// block B if all control flow paths from the entry block to block B flow
122   /// through block A. In a Graph region, all blocks dominate all other blocks.
properlyDominates(Block * a,Block * b)123   bool properlyDominates(Block *a, Block *b) const {
124     return super::properlyDominates(a, b);
125   }
126 
127   /// Update the internal DFS numbers for the dominance nodes.
128   void updateDFSNumbers();
129 };
130 
131 /// A class for computing basic postdominance information.
132 class PostDominanceInfo : public detail::DominanceInfoBase</*IsPostDom=*/true> {
133 public:
134   using super::super;
135 
136   /// Return true if the specified block is reachable from the entry
137   /// block of its region.
isReachableFromEntry(Block * a)138   bool isReachableFromEntry(Block *a) const {
139     return super::isReachableFromEntry(a);
140   }
141 
142   /// Return true if operation A properly postdominates operation B.
143   bool properlyPostDominates(Operation *a, Operation *b);
144 
145   /// Return true if operation A postdominates operation B.
postDominates(Operation * a,Operation * b)146   bool postDominates(Operation *a, Operation *b) {
147     return a == b || properlyPostDominates(a, b);
148   }
149 
150   /// Return true if the specified block A properly postdominates block B.
properlyPostDominates(Block * a,Block * b)151   bool properlyPostDominates(Block *a, Block *b) {
152     return super::properlyDominates(a, b);
153   }
154 
155   /// Return true if the specified block A postdominates block B.
postDominates(Block * a,Block * b)156   bool postDominates(Block *a, Block *b) {
157     return a == b || properlyPostDominates(a, b);
158   }
159 };
160 
161 } //  end namespace mlir
162 
163 namespace llvm {
164 
165 /// DominatorTree GraphTraits specialization so the DominatorTree can be
166 /// iterated by generic graph iterators.
167 template <> struct GraphTraits<mlir::DominanceInfoNode *> {
168   using ChildIteratorType = mlir::DominanceInfoNode::const_iterator;
169   using NodeRef = mlir::DominanceInfoNode *;
170 
171   static NodeRef getEntryNode(NodeRef N) { return N; }
172   static inline ChildIteratorType child_begin(NodeRef N) { return N->begin(); }
173   static inline ChildIteratorType child_end(NodeRef N) { return N->end(); }
174 };
175 
176 template <> struct GraphTraits<const mlir::DominanceInfoNode *> {
177   using ChildIteratorType = mlir::DominanceInfoNode::const_iterator;
178   using NodeRef = const mlir::DominanceInfoNode *;
179 
180   static NodeRef getEntryNode(NodeRef N) { return N; }
181   static inline ChildIteratorType child_begin(NodeRef N) { return N->begin(); }
182   static inline ChildIteratorType child_end(NodeRef N) { return N->end(); }
183 };
184 
185 } // end namespace llvm
186 #endif
187