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GenericDomTreeConstruction.h
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1//===- GenericDomTreeConstruction.h - Dominator Calculation ------*- 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/// \file
9///
10/// Generic dominator tree construction - this file provides routines to
11/// construct immediate dominator information for a flow-graph based on the
12/// Semi-NCA algorithm described in this dissertation:
13///
14/// [1] Linear-Time Algorithms for Dominators and Related Problems
15/// Loukas Georgiadis, Princeton University, November 2005, pp. 21-23:
16/// ftp://ftp.cs.princeton.edu/reports/2005/737.pdf
17///
18/// Semi-NCA algorithm runs in O(n^2) worst-case time but usually slightly
19/// faster than Simple Lengauer-Tarjan in practice.
20///
21/// O(n^2) worst cases happen when the computation of nearest common ancestors
22/// requires O(n) average time, which is very unlikely in real world. If this
23/// ever turns out to be an issue, consider implementing a hybrid algorithm
24/// that uses SLT to perform full constructions and SemiNCA for incremental
25/// updates.
26///
27/// The file uses the Depth Based Search algorithm to perform incremental
28/// updates (insertion and deletions). The implemented algorithm is based on
29/// this publication:
30///
31/// [2] An Experimental Study of Dynamic Dominators
32/// Loukas Georgiadis, et al., April 12 2016, pp. 5-7, 9-10:
33/// https://arxiv.org/pdf/1604.02711.pdf
34///
35//===----------------------------------------------------------------------===//
36
37#ifndef LLVM_SUPPORT_GENERICDOMTREECONSTRUCTION_H
38#define LLVM_SUPPORT_GENERICDOMTREECONSTRUCTION_H
39
40#include "llvm/ADT/ArrayRef.h"
41#include "llvm/ADT/DenseSet.h"
44#include "llvm/Support/Debug.h"
46#include <optional>
47#include <queue>
48
49#define DEBUG_TYPE "dom-tree-builder"
50
51namespace llvm {
52namespace DomTreeBuilder {
53
54template <typename DomTreeT> struct SemiNCAInfo {
55 using NodePtr = typename DomTreeT::NodePtr;
56 using NodeT = typename DomTreeT::NodeType;
58 using RootsT = decltype(DomTreeT::Roots);
59 static constexpr bool IsPostDom = DomTreeT::IsPostDominator;
61
62 // Information record used by Semi-NCA during tree construction.
63 struct InfoRec {
64 unsigned DFSNum = 0;
65 unsigned Parent = 0;
66 unsigned Semi = 0;
67 unsigned Label = 0;
68 NodePtr IDom = nullptr;
69 unsigned ReverseChildrenStart = 0; ///< Index in ReverseChildren vector.
70 };
71
72 // Number to node mapping is 1-based. Initialize the mapping to start with
73 // a dummy element.
75 // If blocks have numbers (e.g., BasicBlock, MachineBasicBlock), store node
76 // infos in a vector. Otherwise, store them in a map.
77 std::conditional_t<GraphHasNodeNumbers<NodePtr>, SmallVector<InfoRec, 64>,
80
81 /// Reverse children of nodes; pairs of (DFSNum (predecessor), next-or-zero);
82 /// forms a linked list in this vector; first entry is sentinel.
84
85 using UpdateT = typename DomTreeT::UpdateType;
86 using UpdateKind = typename DomTreeT::UpdateKind;
88 // Note: Updates inside PreViewCFG are already legalized.
92
93 // Remembers if the whole tree was recalculated at some point during the
94 // current batch update.
95 bool IsRecalculated = false;
98 const size_t NumLegalized;
99 };
100
103
104 // If BUI is a nullptr, then there's no batch update in progress.
106
107 void clear() {
108 NumToNode = {nullptr}; // Restore to initial state with a dummy start node.
109 NodeInfos.clear();
110 // Don't reset the pointer to BatchUpdateInfo here -- if there's an update
111 // in progress, we need this information to continue it.
112 }
113
114 template <bool Inversed>
116 if (BUI)
117 return BUI->PreViewCFG.template getChildren<Inversed>(N);
118 // Force the element type to NodePtr. some graphs (clang's
119 // CFGBlock::AdjacentBlock) yield a proxy convertible to NodePtr rather than
120 // NodePtr itself.
121 auto Children = getChildren<Inversed>(N);
122 return SmallVector<NodePtr, 8>(Children.begin(), Children.end());
123 }
124
125 // Returns a lazy range over N's children, reversed for non-inverted graphs so
126 // a LIFO worklist visits them in their natural order.
127 template <bool Inversed> static auto getChildren(NodePtr N) {
128 using DirectedNodeT =
129 std::conditional_t<Inversed, Inverse<NodePtr>, NodePtr>;
131 // Most graphs' iterators yield NodePtr directly; return the range as is.
132 // clang's CFGBlock instead yields a CFGBlock::AdjacentBlock proxy that is
133 // convertible to NodePtr but can be null for AB_Unreachable.
134 if constexpr (std::is_same_v<std::decay_t<decltype(*R.begin())>, NodePtr>)
135 return R;
136 else
137 return llvm::make_filter_range(R, [](NodePtr C) { return C != nullptr; });
138 }
139
141 if constexpr (GraphHasNodeNumbers<NodePtr>) {
142 unsigned Idx = BB ? GraphTraits<NodePtr>::getNumber(BB) + 1 : 0;
143 if (Idx >= NodeInfos.size()) {
144 unsigned Max = 0;
145 if (BB)
146 Max = GraphTraits<decltype(BB->getParent())>::getMaxNumber(
147 BB->getParent());
148 // Max might be zero, graphs might not support getMaxNumber().
149 NodeInfos.resize(Max ? Max + 1 : Idx + 1);
150 }
151 return NodeInfos[Idx];
152 } else {
153 return NodeInfos[BB];
154 }
155 }
156
158
160 if (TreeNodePtr Node = DT.getNode(BB))
161 return Node;
162
163 // Haven't calculated this node yet? Get or calculate the node for the
164 // immediate dominator.
165 NodePtr IDom = getIDom(BB);
166
167 assert(IDom || DT.getNode(nullptr));
168 TreeNodePtr IDomNode = getNodeForBlock(IDom, DT);
169
170 // Add a new tree node for this NodeT, and link it as a child of
171 // IDomNode
172 return DT.createNode(BB, IDomNode);
173 }
174
175 static bool AlwaysDescend(NodePtr, NodePtr) { return true; }
176
179
181 BlockNamePrinter(TreeNodePtr TN) : N(TN ? TN->getBlock() : nullptr) {}
182
184 if (!BP.N)
185 O << "nullptr";
186 else
187 BP.N->printAsOperand(O, false);
188
189 return O;
190 }
191 };
192
194
195 // Custom DFS implementation which can skip nodes based on a provided
196 // predicate. It also collects ReverseChildren so that we don't have to spend
197 // time getting predecessors in SemiNCA.
198 //
199 // If IsReverse is set to true, the DFS walk will be performed backwards
200 // relative to IsPostDom -- using reverse edges for dominators and forward
201 // edges for postdominators.
202 //
203 // If SuccOrder is specified then in this order the DFS traverses the children
204 // otherwise the order is implied by the results of getChildren().
205 template <bool IsReverse = false, typename DescendCondition>
206 unsigned runDFS(NodePtr V, unsigned LastNum, DescendCondition Condition,
207 unsigned AttachToNum,
208 const NodeOrderMap *SuccOrder = nullptr) {
209 assert(V);
210 SmallVector<std::pair<NodePtr, unsigned>, 64> WorkList = {{V, AttachToNum}};
211 getNodeInfo(V).Parent = AttachToNum;
212
213 while (!WorkList.empty()) {
214 const auto [BB, ParentNum] = WorkList.pop_back_val();
215 auto &BBInfo = getNodeInfo(BB);
216 ReverseChildren.emplace_back(ParentNum, BBInfo.ReverseChildrenStart);
217 BBInfo.ReverseChildrenStart = ReverseChildren.size() - 1;
218
219 // Visited nodes always have positive DFS numbers.
220 if (BBInfo.DFSNum != 0)
221 continue;
222 BBInfo.Parent = ParentNum;
223 BBInfo.DFSNum = BBInfo.Semi = BBInfo.Label = ++LastNum;
224 NumToNode.push_back(BB);
225
226 constexpr bool Direction = IsReverse != IsPostDom; // XOR.
227 // Common case: iterate the lazy successor range directly. Materializing
228 // is only needed to reorder by SuccOrder or to consult a batch update
229 // view.
230 if (!SuccOrder && !BatchUpdates) {
231 for (const NodePtr Succ : getChildren<Direction>(BB))
232 if (Condition(BB, Succ))
233 WorkList.push_back({Succ, LastNum});
234 continue;
235 }
236
237 auto Successors = getChildren<Direction>(BB, BatchUpdates);
238 if (SuccOrder && Successors.size() > 1)
240 Successors.begin(), Successors.end(), [=](NodePtr A, NodePtr B) {
241 return SuccOrder->find(A)->second < SuccOrder->find(B)->second;
242 });
243
244 for (const NodePtr Succ : Successors) {
245 if (!Condition(BB, Succ))
246 continue;
247
248 WorkList.push_back({Succ, LastNum});
249 }
250 }
251
252 return LastNum;
253 }
254
255 // V is a predecessor of W. eval() returns V if V < W, otherwise the minimum
256 // of sdom(U), where U > W and there is a virtual forest path from U to V. The
257 // virtual forest consists of linked edges of processed vertices.
258 //
259 // We can follow Parent pointers (virtual forest edges) to determine the
260 // ancestor U with minimum sdom(U). But it is slow and thus we employ the path
261 // compression technique to speed up to O(m*log(n)). Theoretically the virtual
262 // forest can be organized as balanced trees to achieve almost linear
263 // O(m*alpha(m,n)) running time. But it requires two auxiliary arrays (Size
264 // and Child) and is unlikely to be faster than the simple implementation.
265 //
266 // For each vertex V, its Label points to the vertex with the minimal sdom(U)
267 // (Semi) in its path from V (included) to NodeToInfo[V].Parent (excluded).
268 unsigned eval(unsigned V, unsigned LastLinked,
270 ArrayRef<InfoRec *> NumToInfo) {
271 InfoRec *VInfo = NumToInfo[V];
272 if (VInfo->Parent < LastLinked)
273 return VInfo->Label;
274
275 // Store ancestors except the last (root of a virtual tree) into a stack.
276 assert(Stack.empty());
277 do {
278 Stack.push_back(VInfo);
279 VInfo = NumToInfo[VInfo->Parent];
280 } while (VInfo->Parent >= LastLinked);
281
282 // Path compression. Point each vertex's Parent to the root and update its
283 // Label if any of its ancestors (PInfo->Label) has a smaller Semi.
284 const InfoRec *PInfo = VInfo;
285 const InfoRec *PLabelInfo = NumToInfo[PInfo->Label];
286 do {
287 VInfo = Stack.pop_back_val();
288 VInfo->Parent = PInfo->Parent;
289 const InfoRec *VLabelInfo = NumToInfo[VInfo->Label];
290 if (PLabelInfo->Semi < VLabelInfo->Semi)
291 VInfo->Label = PInfo->Label;
292 else
293 PLabelInfo = VLabelInfo;
294 PInfo = VInfo;
295 } while (!Stack.empty());
296 return VInfo->Label;
297 }
298
299 // This function requires DFS to be run before calling it.
300 void runSemiNCA() {
301 const unsigned NextDFSNum(NumToNode.size());
302 // NumToInfo and IDoms are indexed by DFS number; index 0 is an unused
303 // sentinel. IDoms holds immediate dominators in DFS-number space,
304 // initialized below to spanning tree parents.
306 NumToInfo.resize_for_overwrite(NextDFSNum);
308 IDoms.resize_for_overwrite(NextDFSNum);
309 for (unsigned i = 1; i < NextDFSNum; ++i) {
310 auto &VInfo = getNodeInfo(NumToNode[i]);
311 IDoms[i] = VInfo.Parent;
312 NumToInfo[i] = &VInfo;
313 }
314
315 // Step #1: Calculate the semidominators of all vertices.
317 for (unsigned i = NextDFSNum - 1; i >= 2; --i) {
318 auto &WInfo = *NumToInfo[i];
319
320 // Initialize the semi dominator to point to the parent node.
321 WInfo.Semi = WInfo.Parent;
322 for (unsigned RCIdx = WInfo.ReverseChildrenStart; RCIdx != 0;) {
323 const auto &Entry = ReverseChildren[RCIdx];
324 RCIdx = Entry.second;
325 unsigned SemiU =
326 NumToInfo[eval(Entry.first, i + 1, EvalStack, NumToInfo)]->Semi;
327 if (SemiU < WInfo.Semi)
328 WInfo.Semi = SemiU;
329 }
330 }
331
332 // Step #2: Explicitly define the immediate dominator of each vertex.
333 // IDom[i] = NCA(SDom[i], SpanningTreeParent(i)).
334 // SDom[i]'s DFS number is just Semi.
335 for (unsigned i = 2; i < NextDFSNum; ++i) {
336 auto &WInfo = *NumToInfo[i];
337 assert(WInfo.Semi != 0);
338 unsigned WIDom = IDoms[i];
339 while (WIDom > WInfo.Semi)
340 WIDom = IDoms[WIDom];
341 IDoms[i] = WIDom;
342 WInfo.IDom = NumToNode[WIDom];
343 }
344 }
345
346 // PostDominatorTree always has a virtual root that represents a virtual CFG
347 // node that serves as a single exit from the function. All the other exits
348 // (CFG nodes with terminators and nodes in infinite loops are logically
349 // connected to this virtual CFG exit node).
350 // This functions maps a nullptr CFG node to the virtual root tree node.
352 assert(IsPostDom && "Only postdominators have a virtual root");
353 assert(NumToNode.size() == 1 && "SNCAInfo must be freshly constructed");
354
355 auto &BBInfo = getNodeInfo(nullptr);
356 BBInfo.DFSNum = BBInfo.Semi = BBInfo.Label = 1;
357
358 NumToNode.push_back(nullptr); // NumToNode[1] = nullptr;
359 }
360
361 // For postdominators, nodes with no forward successors are trivial roots that
362 // are always selected as tree roots. Roots with forward successors correspond
363 // to CFG nodes within infinite loops.
365 assert(N && "N must be a valid node");
366 return !getChildren<false>(N, BUI).empty();
367 }
368
369 static NodePtr GetEntryNode(const DomTreeT &DT) {
370 assert(DT.Parent && "Parent not set");
372 }
373
374 // Finds all roots without relaying on the set of roots already stored in the
375 // tree.
376 // We define roots to be some non-redundant set of the CFG nodes
377 static RootsT FindRoots(const DomTreeT &DT, BatchUpdatePtr BUI) {
378 assert(DT.Parent && "Parent pointer is not set");
379 RootsT Roots;
380
381 // For dominators, function entry CFG node is always a tree root node.
382 if (!IsPostDom) {
383 Roots.push_back(GetEntryNode(DT));
384 return Roots;
385 }
386
387 SemiNCAInfo SNCA(BUI);
388
389 // PostDominatorTree always has a virtual root.
390 SNCA.addVirtualRoot();
391 unsigned Num = 1;
392
393 LLVM_DEBUG(dbgs() << "\t\tLooking for trivial roots\n");
394
395 // Step #1: Find all the trivial roots that are going to will definitely
396 // remain tree roots.
397 unsigned Total = 0;
398 // It may happen that there are some new nodes in the CFG that are result of
399 // the ongoing batch update, but we cannot really pretend that they don't
400 // exist -- we won't see any outgoing or incoming edges to them, so it's
401 // fine to discover them here, as they would end up appearing in the CFG at
402 // some point anyway.
403 for (const NodePtr N : nodes(DT.Parent)) {
404 ++Total;
405 // If it has no *successors*, it is definitely a root.
406 if (!HasForwardSuccessors(N, BUI)) {
407 Roots.push_back(N);
408 // Run DFS not to walk this part of CFG later.
409 Num = SNCA.runDFS(N, Num, AlwaysDescend, 1);
410 LLVM_DEBUG(dbgs() << "Found a new trivial root: " << BlockNamePrinter(N)
411 << "\n");
412 LLVM_DEBUG(dbgs() << "Last visited node: "
413 << BlockNamePrinter(SNCA.NumToNode[Num]) << "\n");
414 }
415 }
416
417 LLVM_DEBUG(dbgs() << "\t\tLooking for non-trivial roots\n");
418
419 // Step #2: Find all non-trivial root candidates. Those are CFG nodes that
420 // are reverse-unreachable were not visited by previous DFS walks (i.e. CFG
421 // nodes in infinite loops).
422 bool HasNonTrivialRoots = false;
423 // Accounting for the virtual exit, see if we had any reverse-unreachable
424 // nodes.
425 if (Total + 1 != Num) {
426 HasNonTrivialRoots = true;
427
428 // SuccOrder is the order of blocks in the function. It is needed to make
429 // the calculation of the FurthestAway node and the whole PostDomTree
430 // immune to swap successors transformation (e.g. canonicalizing branch
431 // predicates). SuccOrder is initialized lazily only for successors of
432 // reverse unreachable nodes.
433 std::optional<NodeOrderMap> SuccOrder;
434 auto InitSuccOrderOnce = [&]() {
435 SuccOrder = NodeOrderMap();
436 for (const auto Node : nodes(DT.Parent))
437 if (SNCA.getNodeInfo(Node).DFSNum == 0)
438 for (const auto Succ : getChildren<false>(Node, SNCA.BatchUpdates))
439 SuccOrder->try_emplace(Succ, 0);
440
441 // Add mapping for all entries of SuccOrder.
442 unsigned NodeNum = 0;
443 for (const auto Node : nodes(DT.Parent)) {
444 ++NodeNum;
445 auto Order = SuccOrder->find(Node);
446 if (Order != SuccOrder->end()) {
447 assert(Order->second == 0);
448 Order->second = NodeNum;
449 }
450 }
451 };
452
453 // Make another DFS pass over all other nodes to find the
454 // reverse-unreachable blocks, and find the furthest paths we'll be able
455 // to make.
456 // Note that this looks N^2, but it's really 2N worst case, if every node
457 // is unreachable. This is because we are still going to only visit each
458 // unreachable node once, we may just visit it in two directions,
459 // depending on how lucky we get.
460 for (const NodePtr I : nodes(DT.Parent)) {
461 if (SNCA.getNodeInfo(I).DFSNum == 0) {
463 << "\t\t\tVisiting node " << BlockNamePrinter(I) << "\n");
464 // Find the furthest away we can get by following successors, then
465 // follow them in reverse. This gives us some reasonable answer about
466 // the post-dom tree inside any infinite loop. In particular, it
467 // guarantees we get to the farthest away point along *some*
468 // path. This also matches the GCC's behavior.
469 // If we really wanted a totally complete picture of dominance inside
470 // this infinite loop, we could do it with SCC-like algorithms to find
471 // the lowest and highest points in the infinite loop. In theory, it
472 // would be nice to give the canonical backedge for the loop, but it's
473 // expensive and does not always lead to a minimal set of roots.
474 LLVM_DEBUG(dbgs() << "\t\t\tRunning forward DFS\n");
475
476 if (!SuccOrder)
477 InitSuccOrderOnce();
478 assert(SuccOrder);
479
480 const unsigned NewNum =
481 SNCA.runDFS<true>(I, Num, AlwaysDescend, Num, &*SuccOrder);
482 const NodePtr FurthestAway = SNCA.NumToNode[NewNum];
483 LLVM_DEBUG(dbgs() << "\t\t\tFound a new furthest away node "
484 << "(non-trivial root): "
485 << BlockNamePrinter(FurthestAway) << "\n");
486 Roots.push_back(FurthestAway);
487 LLVM_DEBUG(dbgs() << "\t\t\tPrev DFSNum: " << Num << ", new DFSNum: "
488 << NewNum << "\n\t\t\tRemoving DFS info\n");
489 for (unsigned i = NewNum; i > Num; --i) {
490 const NodePtr N = SNCA.NumToNode[i];
491 LLVM_DEBUG(dbgs() << "\t\t\t\tRemoving DFS info for "
492 << BlockNamePrinter(N) << "\n");
493 SNCA.getNodeInfo(N) = {};
494 SNCA.NumToNode.pop_back();
495 }
496 const unsigned PrevNum = Num;
497 LLVM_DEBUG(dbgs() << "\t\t\tRunning reverse DFS\n");
498 Num = SNCA.runDFS(FurthestAway, Num, AlwaysDescend, 1);
499 for (unsigned i = PrevNum + 1; i <= Num; ++i)
500 LLVM_DEBUG(dbgs() << "\t\t\t\tfound node "
501 << BlockNamePrinter(SNCA.NumToNode[i]) << "\n");
502 }
503 }
504 }
505
506 LLVM_DEBUG(dbgs() << "Total: " << Total << ", Num: " << Num << "\n");
507 LLVM_DEBUG(dbgs() << "Discovered CFG nodes:\n");
508 LLVM_DEBUG(for (size_t i = 0; i <= Num; ++i) dbgs()
509 << i << ": " << BlockNamePrinter(SNCA.NumToNode[i]) << "\n");
510
511 assert((Total + 1 == Num) && "Everything should have been visited");
512
513 // Step #3: If we found some non-trivial roots, make them non-redundant.
514 if (HasNonTrivialRoots)
515 RemoveRedundantRoots(DT, BUI, Roots);
516
517 LLVM_DEBUG(dbgs() << "Found roots: ");
518 LLVM_DEBUG(for (auto *Root : Roots) dbgs()
519 << BlockNamePrinter(Root) << " ");
520 LLVM_DEBUG(dbgs() << "\n");
521
522 return Roots;
523 }
524
525 // This function only makes sense for postdominators.
526 // We define roots to be some set of CFG nodes where (reverse) DFS walks have
527 // to start in order to visit all the CFG nodes (including the
528 // reverse-unreachable ones).
529 // When the search for non-trivial roots is done it may happen that some of
530 // the non-trivial roots are reverse-reachable from other non-trivial roots,
531 // which makes them redundant. This function removes them from the set of
532 // input roots.
533 static void RemoveRedundantRoots(const DomTreeT &DT, BatchUpdatePtr BUI,
534 RootsT &Roots) {
535 assert(IsPostDom && "This function is for postdominators only");
536 LLVM_DEBUG(dbgs() << "Removing redundant roots\n");
537
538 SemiNCAInfo SNCA(BUI);
539
540 for (unsigned i = 0; i < Roots.size(); ++i) {
541 auto &Root = Roots[i];
542 // Trivial roots are always non-redundant.
543 if (!HasForwardSuccessors(Root, BUI))
544 continue;
545 LLVM_DEBUG(dbgs() << "\tChecking if " << BlockNamePrinter(Root)
546 << " remains a root\n");
547 SNCA.clear();
548 // Do a forward walk looking for the other roots.
549 const unsigned Num = SNCA.runDFS<true>(Root, 0, AlwaysDescend, 0);
550 // Skip the start node and begin from the second one (note that DFS uses
551 // 1-based indexing).
552 for (unsigned x = 2; x <= Num; ++x) {
553 const NodePtr N = SNCA.NumToNode[x];
554 // If we wound another root in a (forward) DFS walk, remove the current
555 // root from the set of roots, as it is reverse-reachable from the other
556 // one.
557 if (llvm::is_contained(Roots, N)) {
558 LLVM_DEBUG(dbgs() << "\tForward DFS walk found another root "
559 << BlockNamePrinter(N) << "\n\tRemoving root "
560 << BlockNamePrinter(Root) << "\n");
561 std::swap(Root, Roots.back());
562 Roots.pop_back();
563
564 // Root at the back takes the current root's place.
565 // Start the next loop iteration with the same index.
566 --i;
567 break;
568 }
569 }
570 }
571 }
572
573 template <typename DescendCondition>
574 void doFullDFSWalk(const DomTreeT &DT, DescendCondition DC) {
575 if (!IsPostDom) {
576 assert(DT.Roots.size() == 1 && "Dominators should have a singe root");
577 runDFS(DT.Roots[0], 0, DC, 0);
578 return;
579 }
580
582 unsigned Num = 1;
583 for (const NodePtr Root : DT.Roots)
584 Num = runDFS(Root, Num, DC, 1);
585 }
586
587 static void CalculateFromScratch(DomTreeT &DT, BatchUpdatePtr BUI) {
588 auto *Parent = DT.Parent;
589 DT.reset();
590 DT.Parent = Parent;
591 // If the update is using the actual CFG, BUI is null. If it's using a view,
592 // BUI is non-null and the PreCFGView is used. When calculating from
593 // scratch, make the PreViewCFG equal to the PostCFGView, so Post is used.
594 BatchUpdatePtr PostViewBUI = nullptr;
595 if (BUI && BUI->PostViewCFG) {
596 BUI->PreViewCFG = *BUI->PostViewCFG;
597 PostViewBUI = BUI;
598 }
599 // This is rebuilding the whole tree, not incrementally, but PostViewBUI is
600 // used in case the caller needs a DT update with a CFGView.
601 SemiNCAInfo SNCA(PostViewBUI);
602
603 // Step #0: Number blocks in depth-first order and initialize variables used
604 // in later stages of the algorithm.
605 DT.Roots = FindRoots(DT, PostViewBUI);
607
608 SNCA.runSemiNCA();
609 if (BUI) {
610 BUI->IsRecalculated = true;
612 dbgs() << "DomTree recalculated, skipping future batch updates\n");
613 }
614
615 if (DT.Roots.empty())
616 return;
617
618 // Add a node for the root. If the tree is a PostDominatorTree it will be
619 // the virtual exit (denoted by (BasicBlock *) nullptr) which postdominates
620 // all real exits (including multiple exit blocks, infinite loops).
621 NodePtr Root = IsPostDom ? nullptr : DT.Roots[0];
622
623 DT.RootNode = DT.createNode(Root);
624 SNCA.attachNewSubtree(DT, DT.RootNode);
625 }
626
627 void attachNewSubtree(DomTreeT &DT, const TreeNodePtr AttachTo) {
628 // Attach the first unreachable block to AttachTo.
629 getNodeInfo(NumToNode[1]).IDom = AttachTo->getBlock();
630 // Loop over all of the discovered blocks in the function...
632 if (DT.getNode(W))
633 continue; // Already calculated the node before
634
635 NodePtr ImmDom = getIDom(W);
636
637 // Get or calculate the node for the immediate dominator.
638 TreeNodePtr IDomNode = getNodeForBlock(ImmDom, DT);
639
640 // Add a new tree node for this BasicBlock, and link it as a child of
641 // IDomNode.
642 DT.createNode(W, IDomNode);
643 }
644 }
645
646 void reattachExistingSubtree(DomTreeT &DT, const TreeNodePtr AttachTo) {
647 getNodeInfo(NumToNode[1]).IDom = AttachTo->getBlock();
648 for (const NodePtr N : llvm::drop_begin(NumToNode)) {
649 const TreeNodePtr TN = DT.getNode(N);
650 assert(TN);
651 const TreeNodePtr NewIDom = DT.getNode(getNodeInfo(N).IDom);
652 TN->setIDom(NewIDom);
653 }
654 }
655
656 // Helper struct used during edge insertions.
658 struct Compare {
660 return LHS->getLevel() < RHS->getLevel();
661 }
662 };
663
664 // Bucket queue of tree nodes ordered by descending level. For simplicity,
665 // we use a priority_queue here.
666 std::priority_queue<TreeNodePtr, SmallVector<TreeNodePtr, 8>, Compare>
670#if LLVM_ENABLE_ABI_BREAKING_CHECKS
671 SmallVector<TreeNodePtr, 8> VisitedUnaffected;
672#endif
673 };
674
675 static void InsertEdge(DomTreeT &DT, const BatchUpdatePtr BUI,
676 const NodePtr From, const NodePtr To) {
677 assert((From || IsPostDom) &&
678 "From has to be a valid CFG node or a virtual root");
679 assert(To && "Cannot be a nullptr");
680 LLVM_DEBUG(dbgs() << "Inserting edge " << BlockNamePrinter(From) << " -> "
681 << BlockNamePrinter(To) << "\n");
682 TreeNodePtr FromTN = DT.getNode(From);
683
684 if (!FromTN) {
685 // Ignore edges from unreachable nodes for (forward) dominators.
686 if (!IsPostDom)
687 return;
688
689 // The unreachable node becomes a new root -- a tree node for it.
690 TreeNodePtr VirtualRoot = DT.getNode(nullptr);
691 FromTN = DT.createNode(From, VirtualRoot);
692 DT.Roots.push_back(From);
693 }
694
695 DT.DFSInfoValid = false;
696
697 const TreeNodePtr ToTN = DT.getNode(To);
698 if (!ToTN)
699 InsertUnreachable(DT, BUI, FromTN, To);
700 else
701 InsertReachable(DT, BUI, FromTN, ToTN);
702 }
703
704 // Determines if some existing root becomes reverse-reachable after the
705 // insertion. Rebuilds the whole tree if that situation happens.
706 static bool UpdateRootsBeforeInsertion(DomTreeT &DT, const BatchUpdatePtr BUI,
707 const TreeNodePtr From,
708 const TreeNodePtr To) {
709 assert(IsPostDom && "This function is only for postdominators");
710 // Destination node is not attached to the virtual root, so it cannot be a
711 // root.
712 if (!DT.isVirtualRoot(To->getIDom()))
713 return false;
714
715 if (!llvm::is_contained(DT.Roots, To->getBlock()))
716 return false; // To is not a root, nothing to update.
717
718 LLVM_DEBUG(dbgs() << "\t\tAfter the insertion, " << BlockNamePrinter(To)
719 << " is no longer a root\n\t\tRebuilding the tree!!!\n");
720
721 CalculateFromScratch(DT, BUI);
722 return true;
723 }
724
727 if (A.size() != B.size())
728 return false;
730 for (NodePtr N : B)
731 if (Set.count(N) == 0)
732 return false;
733 return true;
734 }
735
736 // Updates the set of roots after insertion or deletion. This ensures that
737 // roots are the same when after a series of updates and when the tree would
738 // be built from scratch.
739 static void UpdateRootsAfterUpdate(DomTreeT &DT, const BatchUpdatePtr BUI) {
740 assert(IsPostDom && "This function is only for postdominators");
741
742 // The tree has only trivial roots -- nothing to update.
743 if (llvm::none_of(DT.Roots, [BUI](const NodePtr N) {
744 return HasForwardSuccessors(N, BUI);
745 }))
746 return;
747
748 // Recalculate the set of roots.
749 RootsT Roots = FindRoots(DT, BUI);
750 if (!isPermutation(DT.Roots, Roots)) {
751 // The roots chosen in the CFG have changed. This is because the
752 // incremental algorithm does not really know or use the set of roots and
753 // can make a different (implicit) decision about which node within an
754 // infinite loop becomes a root.
755
756 LLVM_DEBUG(dbgs() << "Roots are different in updated trees\n"
757 << "The entire tree needs to be rebuilt\n");
758 // It may be possible to update the tree without recalculating it, but
759 // we do not know yet how to do it, and it happens rarely in practice.
760 CalculateFromScratch(DT, BUI);
761 }
762 }
763
764 // Handles insertion to a node already in the dominator tree.
765 static void InsertReachable(DomTreeT &DT, const BatchUpdatePtr BUI,
766 const TreeNodePtr From, const TreeNodePtr To) {
767 LLVM_DEBUG(dbgs() << "\tReachable " << BlockNamePrinter(From->getBlock())
768 << " -> " << BlockNamePrinter(To->getBlock()) << "\n");
769 if (IsPostDom && UpdateRootsBeforeInsertion(DT, BUI, From, To))
770 return;
771 // DT.findNCD expects both pointers to be valid. When From is a virtual
772 // root, then its CFG block pointer is a nullptr, so we have to 'compute'
773 // the NCD manually.
774 const NodePtr NCDBlock =
775 (From->getBlock() && To->getBlock())
776 ? DT.findNearestCommonDominator(From->getBlock(), To->getBlock())
777 : nullptr;
778 assert(NCDBlock || DT.isPostDominator());
779 const TreeNodePtr NCD = DT.getNode(NCDBlock);
780 assert(NCD);
781
782 LLVM_DEBUG(dbgs() << "\t\tNCA == " << BlockNamePrinter(NCD) << "\n");
783 const unsigned NCDLevel = NCD->getLevel();
784
785 // Based on Lemma 2.5 from [2], after insertion of (From,To), v is affected
786 // iff depth(NCD)+1 < depth(v) && a path P from To to v exists where every
787 // w on P s.t. depth(v) <= depth(w)
788 //
789 // This reduces to a widest path problem (maximizing the depth of the
790 // minimum vertex in the path) which can be solved by a modified version of
791 // Dijkstra with a bucket queue (named depth-based search in [2]).
792
793 // To is in the path, so depth(NCD)+1 < depth(v) <= depth(To). Nothing
794 // affected if this does not hold.
795 if (NCDLevel + 1 >= To->getLevel())
796 return;
797
799 SmallVector<TreeNodePtr, 8> UnaffectedOnCurrentLevel;
800 II.Bucket.push(To);
801 II.Visited.insert(To);
802
803 while (!II.Bucket.empty()) {
804 TreeNodePtr TN = II.Bucket.top();
805 II.Bucket.pop();
806 II.Affected.push_back(TN);
807
808 const unsigned CurrentLevel = TN->getLevel();
809 LLVM_DEBUG(dbgs() << "Mark " << BlockNamePrinter(TN)
810 << "as affected, CurrentLevel " << CurrentLevel
811 << "\n");
812
813 assert(TN->getBlock() && II.Visited.count(TN) && "Preconditions!");
814
815 while (true) {
816 // Unlike regular Dijkstra, we have an inner loop to expand more
817 // vertices. The first iteration is for the (affected) vertex popped
818 // from II.Bucket and the rest are for vertices in
819 // UnaffectedOnCurrentLevel, which may eventually expand to affected
820 // vertices.
821 //
822 // Invariant: there is an optimal path from `To` to TN with the minimum
823 // depth being CurrentLevel.
824 for (const NodePtr Succ : getChildren<IsPostDom>(TN->getBlock(), BUI)) {
825 const TreeNodePtr SuccTN = DT.getNode(Succ);
826 assert(SuccTN &&
827 "Unreachable successor found at reachable insertion");
828 const unsigned SuccLevel = SuccTN->getLevel();
829
830 LLVM_DEBUG(dbgs() << "\tSuccessor " << BlockNamePrinter(Succ)
831 << ", level = " << SuccLevel << "\n");
832
833 // There is an optimal path from `To` to Succ with the minimum depth
834 // being min(CurrentLevel, SuccLevel).
835 //
836 // If depth(NCD)+1 < depth(Succ) is not satisfied, Succ is unaffected
837 // and no affected vertex may be reached by a path passing through it.
838 // Stop here. Also, Succ may be visited by other predecessors but the
839 // first visit has the optimal path. Stop if Succ has been visited.
840 if (SuccLevel <= NCDLevel + 1 || !II.Visited.insert(SuccTN).second)
841 continue;
842
843 if (SuccLevel > CurrentLevel) {
844 // Succ is unaffected but it may (transitively) expand to affected
845 // vertices. Store it in UnaffectedOnCurrentLevel.
846 LLVM_DEBUG(dbgs() << "\t\tMarking visited not affected "
847 << BlockNamePrinter(Succ) << "\n");
848 UnaffectedOnCurrentLevel.push_back(SuccTN);
849#if LLVM_ENABLE_ABI_BREAKING_CHECKS
850 II.VisitedUnaffected.push_back(SuccTN);
851#endif
852 } else {
853 // The condition is satisfied (Succ is affected). Add Succ to the
854 // bucket queue.
855 LLVM_DEBUG(dbgs() << "\t\tAdd " << BlockNamePrinter(Succ)
856 << " to a Bucket\n");
857 II.Bucket.push(SuccTN);
858 }
859 }
860
861 if (UnaffectedOnCurrentLevel.empty())
862 break;
863 TN = UnaffectedOnCurrentLevel.pop_back_val();
864 LLVM_DEBUG(dbgs() << " Next: " << BlockNamePrinter(TN) << "\n");
865 }
866 }
867
868 // Finish by updating immediate dominators and levels.
869 UpdateInsertion(DT, BUI, NCD, II);
870 }
871
872 // Updates immediate dominators and levels after insertion.
873 static void UpdateInsertion(DomTreeT &DT, const BatchUpdatePtr BUI,
874 const TreeNodePtr NCD, InsertionInfo &II) {
875 LLVM_DEBUG(dbgs() << "Updating NCD = " << BlockNamePrinter(NCD) << "\n");
876
877 for (const TreeNodePtr TN : II.Affected) {
878 LLVM_DEBUG(dbgs() << "\tIDom(" << BlockNamePrinter(TN)
879 << ") = " << BlockNamePrinter(NCD) << "\n");
880 TN->setIDom(NCD);
881 }
882
883#if LLVM_ENABLE_ABI_BREAKING_CHECKS && !defined(NDEBUG)
884 for (const TreeNodePtr TN : II.VisitedUnaffected)
885 assert(TN->getLevel() == TN->getIDom()->getLevel() + 1 &&
886 "TN should have been updated by an affected ancestor");
887#endif
888
889 if (IsPostDom)
890 UpdateRootsAfterUpdate(DT, BUI);
891 }
892
893 // Handles insertion to previously unreachable nodes.
894 static void InsertUnreachable(DomTreeT &DT, const BatchUpdatePtr BUI,
895 const TreeNodePtr From, const NodePtr To) {
896 LLVM_DEBUG(dbgs() << "Inserting " << BlockNamePrinter(From)
897 << " -> (unreachable) " << BlockNamePrinter(To) << "\n");
898
899 // Collect discovered edges to already reachable nodes.
900 SmallVector<std::pair<NodePtr, TreeNodePtr>, 8> DiscoveredEdgesToReachable;
901 // Discover and connect nodes that became reachable with the insertion.
902 ComputeUnreachableDominators(DT, BUI, To, From, DiscoveredEdgesToReachable);
903
904 LLVM_DEBUG(dbgs() << "Inserted " << BlockNamePrinter(From)
905 << " -> (prev unreachable) " << BlockNamePrinter(To)
906 << "\n");
907
908 // Used the discovered edges and inset discovered connecting (incoming)
909 // edges.
910 for (const auto &Edge : DiscoveredEdgesToReachable) {
911 LLVM_DEBUG(dbgs() << "\tInserting discovered connecting edge "
912 << BlockNamePrinter(Edge.first) << " -> "
913 << BlockNamePrinter(Edge.second) << "\n");
914 InsertReachable(DT, BUI, DT.getNode(Edge.first), Edge.second);
915 }
916 }
917
918 // Connects nodes that become reachable with an insertion.
919 static void
921 const NodePtr Root, const TreeNodePtr Incoming,
922 SmallVectorImpl<std::pair<NodePtr, TreeNodePtr>>
923 &DiscoveredConnectingEdges) {
924 assert(!DT.getNode(Root) && "Root must not be reachable");
925
926 // Visit only previously unreachable nodes.
927 auto UnreachableDescender = [&DT, &DiscoveredConnectingEdges](NodePtr From,
928 NodePtr To) {
929 const TreeNodePtr ToTN = DT.getNode(To);
930 if (!ToTN)
931 return true;
932
933 DiscoveredConnectingEdges.push_back({From, ToTN});
934 return false;
935 };
936
937 SemiNCAInfo SNCA(BUI);
938 SNCA.runDFS(Root, 0, UnreachableDescender, 0);
939 SNCA.runSemiNCA();
940 SNCA.attachNewSubtree(DT, Incoming);
941
942 LLVM_DEBUG(dbgs() << "After adding unreachable nodes\n");
943 }
944
945 static void DeleteEdge(DomTreeT &DT, const BatchUpdatePtr BUI,
946 const NodePtr From, const NodePtr To) {
947 assert(From && To && "Cannot disconnect nullptrs");
948 LLVM_DEBUG(dbgs() << "Deleting edge " << BlockNamePrinter(From) << " -> "
949 << BlockNamePrinter(To) << "\n");
950
951#if LLVM_ENABLE_ABI_BREAKING_CHECKS
952 // Ensure that the edge was in fact deleted from the CFG before informing
953 // the DomTree about it.
954 // The check is O(N), so run it only in debug configuration.
955 auto IsSuccessor = [BUI](const NodePtr SuccCandidate, const NodePtr Of) {
956 auto Successors = getChildren<IsPostDom>(Of, BUI);
957 return llvm::is_contained(Successors, SuccCandidate);
958 };
959 (void)IsSuccessor;
960 assert(!IsSuccessor(To, From) && "Deleted edge still exists in the CFG!");
961#endif
962
963 const TreeNodePtr FromTN = DT.getNode(From);
964 // Deletion in an unreachable subtree -- nothing to do.
965 if (!FromTN)
966 return;
967
968 const TreeNodePtr ToTN = DT.getNode(To);
969 if (!ToTN) {
971 dbgs() << "\tTo (" << BlockNamePrinter(To)
972 << ") already unreachable -- there is no edge to delete\n");
973 return;
974 }
975
976 const NodePtr NCDBlock = DT.findNearestCommonDominator(From, To);
977 const TreeNodePtr NCD = DT.getNode(NCDBlock);
978
979 // If To dominates From -- nothing to do.
980 if (ToTN != NCD) {
981 DT.DFSInfoValid = false;
982
983 const TreeNodePtr ToIDom = ToTN->getIDom();
984 LLVM_DEBUG(dbgs() << "\tNCD " << BlockNamePrinter(NCD) << ", ToIDom "
985 << BlockNamePrinter(ToIDom) << "\n");
986
987 // To remains reachable after deletion.
988 // (Based on the caption under Figure 4. from [2].)
989 if (FromTN != ToIDom || HasProperSupport(DT, BUI, ToTN))
990 DeleteReachable(DT, BUI, FromTN, ToTN);
991 else
992 DeleteUnreachable(DT, BUI, ToTN);
993 }
994
995 if (IsPostDom)
996 UpdateRootsAfterUpdate(DT, BUI);
997 }
998
999 // Handles deletions that leave destination nodes reachable.
1000 static void DeleteReachable(DomTreeT &DT, const BatchUpdatePtr BUI,
1001 const TreeNodePtr FromTN,
1002 const TreeNodePtr ToTN) {
1003 LLVM_DEBUG(dbgs() << "Deleting reachable " << BlockNamePrinter(FromTN)
1004 << " -> " << BlockNamePrinter(ToTN) << "\n");
1005 LLVM_DEBUG(dbgs() << "\tRebuilding subtree\n");
1006
1007 // Find the top of the subtree that needs to be rebuilt.
1008 // (Based on the lemma 2.6 from [2].)
1009 const NodePtr ToIDom =
1010 DT.findNearestCommonDominator(FromTN->getBlock(), ToTN->getBlock());
1011 assert(ToIDom || DT.isPostDominator());
1012 const TreeNodePtr ToIDomTN = DT.getNode(ToIDom);
1013 assert(ToIDomTN);
1014 const TreeNodePtr PrevIDomSubTree = ToIDomTN->getIDom();
1015 // Top of the subtree to rebuild is the root node. Rebuild the tree from
1016 // scratch.
1017 if (!PrevIDomSubTree) {
1018 LLVM_DEBUG(dbgs() << "The entire tree needs to be rebuilt\n");
1019 CalculateFromScratch(DT, BUI);
1020 return;
1021 }
1022
1023 // Only visit nodes in the subtree starting at To.
1024 const unsigned Level = ToIDomTN->getLevel();
1025 auto DescendBelow = [Level, &DT](NodePtr, NodePtr To) {
1026 return DT.getNode(To)->getLevel() > Level;
1027 };
1028
1029 LLVM_DEBUG(dbgs() << "\tTop of subtree: " << BlockNamePrinter(ToIDomTN)
1030 << "\n");
1031
1032 SemiNCAInfo SNCA(BUI);
1033 SNCA.runDFS(ToIDom, 0, DescendBelow, 0);
1034 LLVM_DEBUG(dbgs() << "\tRunning Semi-NCA\n");
1035 SNCA.runSemiNCA();
1036 SNCA.reattachExistingSubtree(DT, PrevIDomSubTree);
1037 }
1038
1039 // Checks if a node has proper support, as defined on the page 3 and later
1040 // explained on the page 7 of [2].
1041 static bool HasProperSupport(DomTreeT &DT, const BatchUpdatePtr BUI,
1042 const TreeNodePtr TN) {
1043 LLVM_DEBUG(dbgs() << "IsReachableFromIDom " << BlockNamePrinter(TN)
1044 << "\n");
1045 auto TNB = TN->getBlock();
1046 for (const NodePtr Pred : getChildren<!IsPostDom>(TNB, BUI)) {
1047 LLVM_DEBUG(dbgs() << "\tPred " << BlockNamePrinter(Pred) << "\n");
1048 if (!DT.getNode(Pred))
1049 continue;
1050
1051 const NodePtr Support = DT.findNearestCommonDominator(TNB, Pred);
1052 LLVM_DEBUG(dbgs() << "\tSupport " << BlockNamePrinter(Support) << "\n");
1053 if (Support != TNB) {
1054 LLVM_DEBUG(dbgs() << "\t" << BlockNamePrinter(TN)
1055 << " is reachable from support "
1056 << BlockNamePrinter(Support) << "\n");
1057 return true;
1058 }
1059 }
1060
1061 return false;
1062 }
1063
1064 // Handle deletions that make destination node unreachable.
1065 // (Based on the lemma 2.7 from the [2].)
1066 static void DeleteUnreachable(DomTreeT &DT, const BatchUpdatePtr BUI,
1067 const TreeNodePtr ToTN) {
1068 LLVM_DEBUG(dbgs() << "Deleting unreachable subtree "
1069 << BlockNamePrinter(ToTN) << "\n");
1070 assert(ToTN);
1071 assert(ToTN->getBlock());
1072
1073 if (IsPostDom) {
1074 // Deletion makes a region reverse-unreachable and creates a new root.
1075 // Simulate that by inserting an edge from the virtual root to ToTN and
1076 // adding it as a new root.
1077 LLVM_DEBUG(dbgs() << "\tDeletion made a region reverse-unreachable\n");
1078 LLVM_DEBUG(dbgs() << "\tAdding new root " << BlockNamePrinter(ToTN)
1079 << "\n");
1080 DT.Roots.push_back(ToTN->getBlock());
1081 InsertReachable(DT, BUI, DT.getNode(nullptr), ToTN);
1082 return;
1083 }
1084
1085 SmallVector<NodePtr, 16> AffectedQueue;
1086 const unsigned Level = ToTN->getLevel();
1087
1088 // Traverse destination node's descendants with greater level in the tree
1089 // and collect visited nodes.
1090 auto DescendAndCollect = [Level, &AffectedQueue, &DT](NodePtr, NodePtr To) {
1091 const TreeNodePtr TN = DT.getNode(To);
1092 assert(TN);
1093 if (TN->getLevel() > Level)
1094 return true;
1095 if (!llvm::is_contained(AffectedQueue, To))
1096 AffectedQueue.push_back(To);
1097
1098 return false;
1099 };
1100
1101 SemiNCAInfo SNCA(BUI);
1102 unsigned LastDFSNum =
1103 SNCA.runDFS(ToTN->getBlock(), 0, DescendAndCollect, 0);
1104
1105 TreeNodePtr MinNode = ToTN;
1106
1107 // Identify the top of the subtree to rebuild by finding the NCD of all
1108 // the affected nodes.
1109 for (const NodePtr N : AffectedQueue) {
1110 const TreeNodePtr TN = DT.getNode(N);
1111 const NodePtr NCDBlock =
1112 DT.findNearestCommonDominator(TN->getBlock(), ToTN->getBlock());
1113 assert(NCDBlock || DT.isPostDominator());
1114 const TreeNodePtr NCD = DT.getNode(NCDBlock);
1115 assert(NCD);
1116
1117 LLVM_DEBUG(dbgs() << "Processing affected node " << BlockNamePrinter(TN)
1118 << " with NCD = " << BlockNamePrinter(NCD)
1119 << ", MinNode =" << BlockNamePrinter(MinNode) << "\n");
1120 if (NCD != TN && NCD->getLevel() < MinNode->getLevel())
1121 MinNode = NCD;
1122 }
1123
1124 // Root reached, rebuild the whole tree from scratch.
1125 if (!MinNode->getIDom()) {
1126 LLVM_DEBUG(dbgs() << "The entire tree needs to be rebuilt\n");
1127 CalculateFromScratch(DT, BUI);
1128 return;
1129 }
1130
1131 // Erase the unreachable subtree in reverse preorder to process all children
1132 // before deleting their parent.
1133 for (unsigned i = LastDFSNum; i > 0; --i) {
1134 const NodePtr N = SNCA.NumToNode[i];
1135 LLVM_DEBUG(dbgs() << "Erasing node " << BlockNamePrinter(DT.getNode(N))
1136 << "\n");
1137 DT.eraseNode(N);
1138 }
1139
1140 // The affected subtree start at the To node -- there's no extra work to do.
1141 if (MinNode == ToTN)
1142 return;
1143
1144 LLVM_DEBUG(dbgs() << "DeleteUnreachable: running DFS with MinNode = "
1145 << BlockNamePrinter(MinNode) << "\n");
1146 const unsigned MinLevel = MinNode->getLevel();
1147 const TreeNodePtr PrevIDom = MinNode->getIDom();
1148 assert(PrevIDom);
1149 SNCA.clear();
1150
1151 // Identify nodes that remain in the affected subtree.
1152 auto DescendBelow = [MinLevel, &DT](NodePtr R, NodePtr To) {
1153 const TreeNodePtr ToTN = DT.getNode(To);
1154 if (ToTN)
1155 return ToTN->getLevel() > MinLevel;
1156 DT.createNode(To, DT.getNode(R));
1157 return true;
1158 };
1159 SNCA.runDFS(MinNode->getBlock(), 0, DescendBelow, 0);
1160
1161 LLVM_DEBUG(dbgs() << "Previous IDom(MinNode) = "
1162 << BlockNamePrinter(PrevIDom) << "\nRunning Semi-NCA\n");
1163
1164 // Rebuild the remaining part of affected subtree.
1165 SNCA.runSemiNCA();
1166 SNCA.reattachExistingSubtree(DT, PrevIDom);
1167 }
1168
1169 //~~
1170 //===--------------------- DomTree Batch Updater --------------------------===
1171 //~~
1172
1173 static void ApplyUpdates(DomTreeT &DT, GraphDiffT &PreViewCFG,
1174 GraphDiffT *PostViewCFG) {
1175 // Note: the PostViewCFG is only used when computing from scratch. It's data
1176 // should already included in the PreViewCFG for incremental updates.
1177 const size_t NumUpdates = PreViewCFG.getNumLegalizedUpdates();
1178 if (NumUpdates == 0)
1179 return;
1180
1181 // Take the fast path for a single update and avoid running the batch update
1182 // machinery.
1183 if (NumUpdates == 1) {
1184 UpdateT Update = PreViewCFG.popUpdateForIncrementalUpdates();
1185 if (!PostViewCFG) {
1186 if (Update.getKind() == UpdateKind::Insert)
1187 InsertEdge(DT, /*BUI=*/nullptr, Update.getFrom(), Update.getTo());
1188 else
1189 DeleteEdge(DT, /*BUI=*/nullptr, Update.getFrom(), Update.getTo());
1190 } else {
1191 BatchUpdateInfo BUI(*PostViewCFG, PostViewCFG);
1192 if (Update.getKind() == UpdateKind::Insert)
1193 InsertEdge(DT, &BUI, Update.getFrom(), Update.getTo());
1194 else
1195 DeleteEdge(DT, &BUI, Update.getFrom(), Update.getTo());
1196 }
1197 return;
1198 }
1199
1200 BatchUpdateInfo BUI(PreViewCFG, PostViewCFG);
1201 // Recalculate the DominatorTree when the number of updates
1202 // exceeds a threshold, which usually makes direct updating slower than
1203 // recalculation. We select this threshold proportional to the
1204 // size of the DominatorTree. The constant is selected
1205 // by choosing the one with an acceptable performance on some real-world
1206 // inputs.
1207
1208 // Make unittests of the incremental algorithm work
1209 if (DT.DomTreeNodes.size() <= 100) {
1210 if (BUI.NumLegalized > DT.DomTreeNodes.size())
1211 CalculateFromScratch(DT, &BUI);
1212 } else if (BUI.NumLegalized > DT.DomTreeNodes.size() / 40)
1213 CalculateFromScratch(DT, &BUI);
1214
1215 // If the DominatorTree was recalculated at some point, stop the batch
1216 // updates. Full recalculations ignore batch updates and look at the actual
1217 // CFG.
1218 for (size_t i = 0; i < BUI.NumLegalized && !BUI.IsRecalculated; ++i)
1219 ApplyNextUpdate(DT, BUI);
1220 }
1221
1222 static void ApplyNextUpdate(DomTreeT &DT, BatchUpdateInfo &BUI) {
1223 // Popping the next update, will move the PreViewCFG to the next snapshot.
1225#if 0
1226 // FIXME: The LLVM_DEBUG macro only plays well with a modular
1227 // build of LLVM when the header is marked as textual, but doing
1228 // so causes redefinition errors.
1229 LLVM_DEBUG(dbgs() << "Applying update: ");
1230 LLVM_DEBUG(CurrentUpdate.dump(); dbgs() << "\n");
1231#endif
1232
1233 if (CurrentUpdate.getKind() == UpdateKind::Insert)
1234 InsertEdge(DT, &BUI, CurrentUpdate.getFrom(), CurrentUpdate.getTo());
1235 else
1236 DeleteEdge(DT, &BUI, CurrentUpdate.getFrom(), CurrentUpdate.getTo());
1237 }
1238
1239 //~~
1240 //===--------------- DomTree correctness verification ---------------------===
1241 //~~
1242
1243 // Check if the tree has correct roots. A DominatorTree always has a single
1244 // root which is the function's entry node. A PostDominatorTree can have
1245 // multiple roots - one for each node with no successors and for infinite
1246 // loops.
1247 // Running time: O(N).
1248 bool verifyRoots(const DomTreeT &DT) {
1249 if (!DT.Parent && !DT.Roots.empty()) {
1250 errs() << "Tree has no parent but has roots!\n";
1251 errs().flush();
1252 return false;
1253 }
1254
1255 if (!IsPostDom) {
1256 if (DT.Roots.empty()) {
1257 errs() << "Tree doesn't have a root!\n";
1258 errs().flush();
1259 return false;
1260 }
1261
1262 if (DT.getRoot() != GetEntryNode(DT)) {
1263 errs() << "Tree's root is not its parent's entry node!\n";
1264 errs().flush();
1265 return false;
1266 }
1267 }
1268
1269 RootsT ComputedRoots = FindRoots(DT, nullptr);
1270 if (!isPermutation(DT.Roots, ComputedRoots)) {
1271 errs() << "Tree has different roots than freshly computed ones!\n";
1272 errs() << "\tPDT roots: ";
1273 for (const NodePtr N : DT.Roots)
1274 errs() << BlockNamePrinter(N) << ", ";
1275 errs() << "\n\tComputed roots: ";
1276 for (const NodePtr N : ComputedRoots)
1277 errs() << BlockNamePrinter(N) << ", ";
1278 errs() << "\n";
1279 errs().flush();
1280 return false;
1281 }
1282
1283 return true;
1284 }
1285
1286 // Checks if the tree contains all reachable nodes in the input graph.
1287 // Running time: O(N).
1288 bool verifyReachability(const DomTreeT &DT) {
1289 clear();
1291
1292 for (auto *TN : DT.DomTreeNodes) {
1293 if (!TN)
1294 continue;
1295 const NodePtr BB = TN->getBlock();
1296
1297 // Virtual root has a corresponding virtual CFG node.
1298 if (DT.isVirtualRoot(TN))
1299 continue;
1300
1301 if (getNodeInfo(BB).DFSNum == 0) {
1302 errs() << "DomTree node " << BlockNamePrinter(BB)
1303 << " not found by DFS walk!\n";
1304 errs().flush();
1305
1306 return false;
1307 }
1308 }
1309
1310 for (const NodePtr N : NumToNode) {
1311 if (N && !DT.getNode(N)) {
1312 errs() << "CFG node " << BlockNamePrinter(N)
1313 << " not found in the DomTree!\n";
1314 errs().flush();
1315
1316 return false;
1317 }
1318 }
1319
1320 return true;
1321 }
1322
1323 // Check if for every parent with a level L in the tree all of its children
1324 // have level L + 1.
1325 // Running time: O(N).
1326 static bool VerifyLevels(const DomTreeT &DT) {
1327 for (auto *TN : DT.DomTreeNodes) {
1328 if (!TN)
1329 continue;
1330 const NodePtr BB = TN->getBlock();
1331 if (!BB)
1332 continue;
1333
1334 const TreeNodePtr IDom = TN->getIDom();
1335 if (!IDom && TN->getLevel() != 0) {
1336 errs() << "Node without an IDom " << BlockNamePrinter(BB)
1337 << " has a nonzero level " << TN->getLevel() << "!\n";
1338 errs().flush();
1339
1340 return false;
1341 }
1342
1343 if (IDom && TN->getLevel() != IDom->getLevel() + 1) {
1344 errs() << "Node " << BlockNamePrinter(BB) << " has level "
1345 << TN->getLevel() << " while its IDom "
1346 << BlockNamePrinter(IDom->getBlock()) << " has level "
1347 << IDom->getLevel() << "!\n";
1348 errs().flush();
1349
1350 return false;
1351 }
1352 }
1353
1354 return true;
1355 }
1356
1357 // Check if the computed DFS numbers are correct. Note that DFS info may not
1358 // be valid, and when that is the case, we don't verify the numbers.
1359 // Running time: O(N log(N)).
1360 static bool VerifyDFSNumbers(const DomTreeT &DT) {
1361 if (!DT.DFSInfoValid || !DT.Parent)
1362 return true;
1363
1364 const NodePtr RootBB = IsPostDom ? nullptr : *DT.root_begin();
1365 const TreeNodePtr Root = DT.getNode(RootBB);
1366
1367 auto PrintNodeAndDFSNums = [](const TreeNodePtr TN) {
1368 errs() << BlockNamePrinter(TN) << " {" << TN->getDFSNumIn() << ", "
1369 << TN->getDFSNumOut() << '}';
1370 };
1371
1372 // Verify the root's DFS In number. Although DFS numbering would also work
1373 // if we started from some other value, we assume 0-based numbering.
1374 if (Root->getDFSNumIn() != 0) {
1375 errs() << "DFSIn number for the tree root is not:\n\t";
1376 PrintNodeAndDFSNums(Root);
1377 errs() << '\n';
1378 errs().flush();
1379 return false;
1380 }
1381
1382 // For each tree node verify if children's DFS numbers cover their parent's
1383 // DFS numbers with no gaps.
1384 for (auto *Node : DT.DomTreeNodes) {
1385 if (!Node)
1386 continue;
1387
1388 // Handle tree leaves.
1389 if (Node->isLeaf()) {
1390 if (Node->getDFSNumIn() + 1 != Node->getDFSNumOut()) {
1391 errs() << "Tree leaf should have DFSOut = DFSIn + 1:\n\t";
1392 PrintNodeAndDFSNums(Node);
1393 errs() << '\n';
1394 errs().flush();
1395 return false;
1396 }
1397
1398 continue;
1399 }
1400
1401 // Make a copy and sort it such that it is possible to check if there are
1402 // no gaps between DFS numbers of adjacent children.
1403 SmallVector<TreeNodePtr, 8> Children(Node->begin(), Node->end());
1404 llvm::sort(Children, [](const TreeNodePtr Ch1, const TreeNodePtr Ch2) {
1405 return Ch1->getDFSNumIn() < Ch2->getDFSNumIn();
1406 });
1407
1408 auto PrintChildrenError =
1409 [Node, &Children, PrintNodeAndDFSNums](const TreeNodePtr FirstCh,
1410 const TreeNodePtr SecondCh) {
1411 assert(FirstCh);
1412
1413 errs() << "Incorrect DFS numbers for:\n\tParent ";
1414 PrintNodeAndDFSNums(Node);
1415
1416 errs() << "\n\tChild ";
1417 PrintNodeAndDFSNums(FirstCh);
1418
1419 if (SecondCh) {
1420 errs() << "\n\tSecond child ";
1421 PrintNodeAndDFSNums(SecondCh);
1422 }
1423
1424 errs() << "\nAll children: ";
1425 for (const TreeNodePtr Ch : Children) {
1426 PrintNodeAndDFSNums(Ch);
1427 errs() << ", ";
1428 }
1429
1430 errs() << '\n';
1431 errs().flush();
1432 };
1433
1434 if (Children.front()->getDFSNumIn() != Node->getDFSNumIn() + 1) {
1435 PrintChildrenError(Children.front(), nullptr);
1436 return false;
1437 }
1438
1439 if (Children.back()->getDFSNumOut() + 1 != Node->getDFSNumOut()) {
1440 PrintChildrenError(Children.back(), nullptr);
1441 return false;
1442 }
1443
1444 for (size_t i = 0, e = Children.size() - 1; i != e; ++i) {
1445 if (Children[i]->getDFSNumOut() + 1 != Children[i + 1]->getDFSNumIn()) {
1446 PrintChildrenError(Children[i], Children[i + 1]);
1447 return false;
1448 }
1449 }
1450 }
1451
1452 return true;
1453 }
1454
1455 // The below routines verify the correctness of the dominator tree relative to
1456 // the CFG it's coming from. A tree is a dominator tree iff it has two
1457 // properties, called the parent property and the sibling property. Tarjan
1458 // and Lengauer prove (but don't explicitly name) the properties as part of
1459 // the proofs in their 1972 paper, but the proofs are mostly part of proving
1460 // things about semidominators and idoms, and some of them are simply asserted
1461 // based on even earlier papers (see, e.g., lemma 2). Some papers refer to
1462 // these properties as "valid" and "co-valid". See, e.g., "Dominators,
1463 // directed bipolar orders, and independent spanning trees" by Loukas
1464 // Georgiadis and Robert E. Tarjan, as well as "Dominator Tree Verification
1465 // and Vertex-Disjoint Paths " by the same authors.
1466
1467 // A very simple and direct explanation of these properties can be found in
1468 // "An Experimental Study of Dynamic Dominators", found at
1469 // https://arxiv.org/abs/1604.02711
1470
1471 // The easiest way to think of the parent property is that it's a requirement
1472 // of being a dominator. Let's just take immediate dominators. For PARENT to
1473 // be an immediate dominator of CHILD, all paths in the CFG must go through
1474 // PARENT before they hit CHILD. This implies that if you were to cut PARENT
1475 // out of the CFG, there should be no paths to CHILD that are reachable. If
1476 // there are, then you now have a path from PARENT to CHILD that goes around
1477 // PARENT and still reaches CHILD, which by definition, means PARENT can't be
1478 // a dominator of CHILD (let alone an immediate one).
1479
1480 // The sibling property is similar. It says that for each pair of sibling
1481 // nodes in the dominator tree (LEFT and RIGHT) , they must not dominate each
1482 // other. If sibling LEFT dominated sibling RIGHT, it means there are no
1483 // paths in the CFG from sibling LEFT to sibling RIGHT that do not go through
1484 // LEFT, and thus, LEFT is really an ancestor (in the dominator tree) of
1485 // RIGHT, not a sibling.
1486
1487 // It is possible to verify the parent and sibling properties in linear time,
1488 // but the algorithms are complex. Instead, we do it in a straightforward
1489 // N^2 and N^3 way below, using direct path reachability.
1490
1491 // Checks if the tree has the parent property: if for all edges from V to W in
1492 // the input graph, such that V is reachable, the parent of W in the tree is
1493 // an ancestor of V in the tree.
1494 // Running time: O(N^2).
1495 //
1496 // This means that if a node gets disconnected from the graph, then all of
1497 // the nodes it dominated previously will now become unreachable.
1498 bool verifyParentProperty(const DomTreeT &DT) {
1499 for (auto *TN : DT.DomTreeNodes) {
1500 if (!TN)
1501 continue;
1502 const NodePtr BB = TN->getBlock();
1503 if (!BB || TN->isLeaf())
1504 continue;
1505
1506 LLVM_DEBUG(dbgs() << "Verifying parent property of node "
1507 << BlockNamePrinter(TN) << "\n");
1508 clear();
1509 doFullDFSWalk(DT, [BB](NodePtr From, NodePtr To) {
1510 return From != BB && To != BB;
1511 });
1512
1513 for (TreeNodePtr Child : TN->children())
1514 if (getNodeInfo(Child->getBlock()).DFSNum != 0) {
1515 errs() << "Child " << BlockNamePrinter(Child)
1516 << " reachable after its parent " << BlockNamePrinter(BB)
1517 << " is removed!\n";
1518 errs().flush();
1519
1520 return false;
1521 }
1522 }
1523
1524 return true;
1525 }
1526
1527 // Check if the tree has sibling property: if a node V does not dominate a
1528 // node W for all siblings V and W in the tree.
1529 // Running time: O(N^3).
1530 //
1531 // This means that if a node gets disconnected from the graph, then all of its
1532 // siblings will now still be reachable.
1533 bool verifySiblingProperty(const DomTreeT &DT) {
1534 for (auto *TN : DT.DomTreeNodes) {
1535 if (!TN)
1536 continue;
1537 const NodePtr BB = TN->getBlock();
1538 if (!BB || TN->isLeaf())
1539 continue;
1540
1541 for (const TreeNodePtr N : TN->children()) {
1542 clear();
1543 NodePtr BBN = N->getBlock();
1544 doFullDFSWalk(DT, [BBN](NodePtr From, NodePtr To) {
1545 return From != BBN && To != BBN;
1546 });
1547
1548 for (const TreeNodePtr S : TN->children()) {
1549 if (S == N)
1550 continue;
1551
1552 if (getNodeInfo(S->getBlock()).DFSNum == 0) {
1553 errs() << "Node " << BlockNamePrinter(S)
1554 << " not reachable when its sibling " << BlockNamePrinter(N)
1555 << " is removed!\n";
1556 errs().flush();
1557
1558 return false;
1559 }
1560 }
1561 }
1562 }
1563
1564 return true;
1565 }
1566
1567 // Check if the given tree is the same as a freshly computed one for the same
1568 // Parent.
1569 // Running time: O(N^2), but faster in practice (same as tree construction).
1570 //
1571 // Note that this does not check if that the tree construction algorithm is
1572 // correct and should be only used for fast (but possibly unsound)
1573 // verification.
1574 static bool IsSameAsFreshTree(const DomTreeT &DT) {
1575 DomTreeT FreshTree;
1576 FreshTree.recalculate(*DT.Parent);
1577 const bool Different = DT.compare(FreshTree);
1578
1579 if (Different) {
1580 errs() << (DT.isPostDominator() ? "Post" : "")
1581 << "DominatorTree is different than a freshly computed one!\n"
1582 << "\tCurrent:\n";
1583 DT.print(errs());
1584 errs() << "\n\tFreshly computed tree:\n";
1585 FreshTree.print(errs());
1586 errs().flush();
1587 }
1588
1589 return !Different;
1590 }
1591};
1592
1593template <class DomTreeT> void Calculate(DomTreeT &DT) {
1595}
1596
1597template <typename DomTreeT>
1598void CalculateWithUpdates(DomTreeT &DT,
1600 // FIXME: Updated to use the PreViewCFG and behave the same as until now.
1601 // This behavior is however incorrect; this actually needs the PostViewCFG.
1603 Updates, /*ReverseApplyUpdates=*/true);
1604 typename SemiNCAInfo<DomTreeT>::BatchUpdateInfo BUI(PreViewCFG);
1606}
1607
1608template <class DomTreeT>
1609void InsertEdge(DomTreeT &DT, typename DomTreeT::NodePtr From,
1610 typename DomTreeT::NodePtr To) {
1611 if (DT.isPostDominator())
1612 std::swap(From, To);
1613 SemiNCAInfo<DomTreeT>::InsertEdge(DT, nullptr, From, To);
1614}
1615
1616template <class DomTreeT>
1617void DeleteEdge(DomTreeT &DT, typename DomTreeT::NodePtr From,
1618 typename DomTreeT::NodePtr To) {
1619 if (DT.isPostDominator())
1620 std::swap(From, To);
1621 SemiNCAInfo<DomTreeT>::DeleteEdge(DT, nullptr, From, To);
1622}
1623
1624template <class DomTreeT>
1625void ApplyUpdates(DomTreeT &DT,
1626 GraphDiff<typename DomTreeT::NodePtr,
1627 DomTreeT::IsPostDominator> &PreViewCFG,
1628 GraphDiff<typename DomTreeT::NodePtr,
1629 DomTreeT::IsPostDominator> *PostViewCFG) {
1630 SemiNCAInfo<DomTreeT>::ApplyUpdates(DT, PreViewCFG, PostViewCFG);
1631}
1632
1633template <class DomTreeT>
1634bool Verify(const DomTreeT &DT, typename DomTreeT::VerificationLevel VL) {
1635 SemiNCAInfo<DomTreeT> SNCA(nullptr);
1636
1637 // Simplist check is to compare against a new tree. This will also
1638 // usefully print the old and new trees, if they are different.
1639 if (!SNCA.IsSameAsFreshTree(DT))
1640 return false;
1641
1642 // Common checks to verify the properties of the tree. O(N log N) at worst.
1643 if (!SNCA.verifyRoots(DT) || !SNCA.verifyReachability(DT) ||
1644 !SNCA.VerifyLevels(DT) || !SNCA.VerifyDFSNumbers(DT))
1645 return false;
1646
1647 // Extra checks depending on VerificationLevel. Up to O(N^3).
1648 if (VL == DomTreeT::VerificationLevel::Basic ||
1649 VL == DomTreeT::VerificationLevel::Full)
1650 if (!SNCA.verifyParentProperty(DT))
1651 return false;
1652 if (VL == DomTreeT::VerificationLevel::Full)
1653 if (!SNCA.verifySiblingProperty(DT))
1654 return false;
1655
1656 return true;
1657}
1658
1659} // namespace DomTreeBuilder
1660} // namespace llvm
1661
1662#undef DEBUG_TYPE
1663
1664#endif
assert(UImm &&(UImm !=~static_cast< T >(0)) &&"Invalid immediate!")
Unify divergent function exit nodes
static GCRegistry::Add< ErlangGC > A("erlang", "erlang-compatible garbage collector")
static GCRegistry::Add< OcamlGC > B("ocaml", "ocaml 3.10-compatible GC")
This file defines the DenseSet and SmallDenseSet classes.
This file builds on the ADT/GraphTraits.h file to build generic depth first graph iterator.
This file defines a set of templates that efficiently compute a dominator tree over a generic graph.
Loop::LoopBounds::Direction Direction
Definition LoopInfo.cpp:253
#define I(x, y, z)
Definition MD5.cpp:57
uint64_t IntrinsicInst * II
ppc ctr loops PowerPC CTR Loops Verify
This file defines the SmallPtrSet class.
#define LLVM_DEBUG(...)
Definition Debug.h:119
Value * RHS
Value * LHS
Represent a constant reference to an array (0 or more elements consecutively in memory),...
Definition ArrayRef.h:40
Base class for the actual dominator tree node.
void setIDom(DomTreeNodeBase *NewIDom)
DomTreeNodeBase * getIDom() const
unsigned getDFSNumIn() const
getDFSNumIn/getDFSNumOut - These return the DFS visitation order for nodes in the dominator tree.
NodeT * getBlock() const
unsigned getLevel() const
cfg::Update< NodePtr > popUpdateForIncrementalUpdates()
Definition CFGDiff.h:111
unsigned getNumLegalizedUpdates() const
Definition CFGDiff.h:109
Implements a dense probed hash-table based set with some number of buckets stored inline.
Definition DenseSet.h:293
SmallPtrSet - This class implements a set which is optimized for holding SmallSize or less elements.
This class consists of common code factored out of the SmallVector class to reduce code duplication b...
void resize_for_overwrite(size_type N)
Like resize, but T is POD, the new values won't be initialized.
void push_back(const T &Elt)
This is a 'vector' (really, a variable-sized array), optimized for the case when the array is small.
This class implements an extremely fast bulk output stream that can only output to a stream.
Definition raw_ostream.h:53
@ C
The default llvm calling convention, compatible with C.
Definition CallingConv.h:34
void CalculateWithUpdates(DomTreeT &DT, ArrayRef< typename DomTreeT::UpdateType > Updates)
void DeleteEdge(DomTreeT &DT, typename DomTreeT::NodePtr From, typename DomTreeT::NodePtr To)
void ApplyUpdates(DomTreeT &DT, GraphDiff< typename DomTreeT::NodePtr, DomTreeT::IsPostDominator > &PreViewCFG, GraphDiff< typename DomTreeT::NodePtr, DomTreeT::IsPostDominator > *PostViewCFG)
void InsertEdge(DomTreeT &DT, typename DomTreeT::NodePtr From, typename DomTreeT::NodePtr To)
auto reverse_if(Range &&R)
Definition CFGDiff.h:45
This is an optimization pass for GlobalISel generic memory operations.
auto drop_begin(T &&RangeOrContainer, size_t N=1)
Return a range covering RangeOrContainer with the first N elements excluded.
Definition STLExtras.h:315
constexpr from_range_t from_range
constexpr bool GraphHasNodeNumbers
Indicate whether a GraphTraits<NodeT>::getNumber() is supported.
void sort(IteratorTy Start, IteratorTy End)
Definition STLExtras.h:1636
LLVM_ABI raw_ostream & dbgs()
dbgs() - This returns a reference to a raw_ostream for debugging messages.
Definition Debug.cpp:209
bool none_of(R &&Range, UnaryPredicate P)
Provide wrappers to std::none_of which take ranges instead of having to pass begin/end explicitly.
Definition STLExtras.h:1753
iterator_range< filter_iterator< detail::IterOfRange< RangeT >, PredicateT > > make_filter_range(RangeT &&Range, PredicateT Pred)
Convenience function that takes a range of elements and a predicate, and return a new filter_iterator...
Definition STLExtras.h:551
LLVM_ABI raw_fd_ostream & errs()
This returns a reference to a raw_ostream for standard error.
iterator_range< typename GraphTraits< GraphType >::ChildIteratorType > children(const typename GraphTraits< GraphType >::NodeRef &G)
bool is_contained(R &&Range, const E &Element)
Returns true if Element is found in Range.
Definition STLExtras.h:1947
void swap(llvm::BitVector &LHS, llvm::BitVector &RHS)
Implement std::swap in terms of BitVector swap.
Definition BitVector.h:862
#define N
BatchUpdateInfo(GraphDiffT &PreViewCFG, GraphDiffT *PostViewCFG=nullptr)
friend raw_ostream & operator<<(raw_ostream &O, const BlockNamePrinter &BP)
unsigned ReverseChildrenStart
Index in ReverseChildren vector.
std::priority_queue< TreeNodePtr, SmallVector< TreeNodePtr, 8 >, Compare > Bucket
static void UpdateInsertion(DomTreeT &DT, const BatchUpdatePtr BUI, const TreeNodePtr NCD, InsertionInfo &II)
static void DeleteEdge(DomTreeT &DT, const BatchUpdatePtr BUI, const NodePtr From, const NodePtr To)
void doFullDFSWalk(const DomTreeT &DT, DescendCondition DC)
DenseMap< NodePtr, unsigned > NodeOrderMap
static RootsT FindRoots(const DomTreeT &DT, BatchUpdatePtr BUI)
static SmallVector< NodePtr, 8 > getChildren(NodePtr N, BatchUpdatePtr BUI)
static void ComputeUnreachableDominators(DomTreeT &DT, const BatchUpdatePtr BUI, const NodePtr Root, const TreeNodePtr Incoming, SmallVectorImpl< std::pair< NodePtr, TreeNodePtr > > &DiscoveredConnectingEdges)
static bool VerifyLevels(const DomTreeT &DT)
unsigned eval(unsigned V, unsigned LastLinked, SmallVectorImpl< InfoRec * > &Stack, ArrayRef< InfoRec * > NumToInfo)
static bool IsSameAsFreshTree(const DomTreeT &DT)
GraphDiff< NodePtr, IsPostDom > GraphDiffT
static void ApplyUpdates(DomTreeT &DT, GraphDiffT &PreViewCFG, GraphDiffT *PostViewCFG)
typename DomTreeT::UpdateKind UpdateKind
static bool UpdateRootsBeforeInsertion(DomTreeT &DT, const BatchUpdatePtr BUI, const TreeNodePtr From, const TreeNodePtr To)
void reattachExistingSubtree(DomTreeT &DT, const TreeNodePtr AttachTo)
static NodePtr GetEntryNode(const DomTreeT &DT)
static bool AlwaysDescend(NodePtr, NodePtr)
static void UpdateRootsAfterUpdate(DomTreeT &DT, const BatchUpdatePtr BUI)
unsigned runDFS(NodePtr V, unsigned LastNum, DescendCondition Condition, unsigned AttachToNum, const NodeOrderMap *SuccOrder=nullptr)
static void DeleteReachable(DomTreeT &DT, const BatchUpdatePtr BUI, const TreeNodePtr FromTN, const TreeNodePtr ToTN)
static void RemoveRedundantRoots(const DomTreeT &DT, BatchUpdatePtr BUI, RootsT &Roots)
static bool HasProperSupport(DomTreeT &DT, const BatchUpdatePtr BUI, const TreeNodePtr TN)
static bool isPermutation(const SmallVectorImpl< NodePtr > &A, const SmallVectorImpl< NodePtr > &B)
static void CalculateFromScratch(DomTreeT &DT, BatchUpdatePtr BUI)
TreeNodePtr getNodeForBlock(NodePtr BB, DomTreeT &DT)
static void InsertReachable(DomTreeT &DT, const BatchUpdatePtr BUI, const TreeNodePtr From, const TreeNodePtr To)
static bool HasForwardSuccessors(const NodePtr N, BatchUpdatePtr BUI)
static void InsertUnreachable(DomTreeT &DT, const BatchUpdatePtr BUI, const TreeNodePtr From, const NodePtr To)
static void ApplyNextUpdate(DomTreeT &DT, BatchUpdateInfo &BUI)
static bool VerifyDFSNumbers(const DomTreeT &DT)
static void DeleteUnreachable(DomTreeT &DT, const BatchUpdatePtr BUI, const TreeNodePtr ToTN)
void attachNewSubtree(DomTreeT &DT, const TreeNodePtr AttachTo)
static void InsertEdge(DomTreeT &DT, const BatchUpdatePtr BUI, const NodePtr From, const NodePtr To)
SmallVector< std::pair< unsigned, unsigned >, 32 > ReverseChildren
Reverse children of nodes; pairs of (DFSNum (predecessor), next-or-zero); forms a linked list in this...
std::conditional_t< GraphHasNodeNumbers< NodePtr >, SmallVector< InfoRec, 64 >, DenseMap< NodePtr, InfoRec > > NodeInfos