xref: /freebsd/contrib/llvm-project/llvm/include/llvm/CodeGen/PBQP/Graph.h (revision c66ec88fed842fbaad62c30d510644ceb7bd2d71)
1 //===- Graph.h - PBQP Graph -------------------------------------*- 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 // PBQP Graph class.
10 //
11 //===----------------------------------------------------------------------===//
12 
13 #ifndef LLVM_CODEGEN_PBQP_GRAPH_H
14 #define LLVM_CODEGEN_PBQP_GRAPH_H
15 
16 #include "llvm/ADT/STLExtras.h"
17 #include <algorithm>
18 #include <cassert>
19 #include <iterator>
20 #include <limits>
21 #include <vector>
22 
23 namespace llvm {
24 namespace PBQP {
25 
26   class GraphBase {
27   public:
28     using NodeId = unsigned;
29     using EdgeId = unsigned;
30 
31     /// Returns a value representing an invalid (non-existent) node.
32     static NodeId invalidNodeId() {
33       return std::numeric_limits<NodeId>::max();
34     }
35 
36     /// Returns a value representing an invalid (non-existent) edge.
37     static EdgeId invalidEdgeId() {
38       return std::numeric_limits<EdgeId>::max();
39     }
40   };
41 
42   /// PBQP Graph class.
43   /// Instances of this class describe PBQP problems.
44   ///
45   template <typename SolverT>
46   class Graph : public GraphBase {
47   private:
48     using CostAllocator = typename SolverT::CostAllocator;
49 
50   public:
51     using RawVector = typename SolverT::RawVector;
52     using RawMatrix = typename SolverT::RawMatrix;
53     using Vector = typename SolverT::Vector;
54     using Matrix = typename SolverT::Matrix;
55     using VectorPtr = typename CostAllocator::VectorPtr;
56     using MatrixPtr = typename CostAllocator::MatrixPtr;
57     using NodeMetadata = typename SolverT::NodeMetadata;
58     using EdgeMetadata = typename SolverT::EdgeMetadata;
59     using GraphMetadata = typename SolverT::GraphMetadata;
60 
61   private:
62     class NodeEntry {
63     public:
64       using AdjEdgeList = std::vector<EdgeId>;
65       using AdjEdgeIdx = AdjEdgeList::size_type;
66       using AdjEdgeItr = AdjEdgeList::const_iterator;
67 
68       NodeEntry(VectorPtr Costs) : Costs(std::move(Costs)) {}
69 
70       static AdjEdgeIdx getInvalidAdjEdgeIdx() {
71         return std::numeric_limits<AdjEdgeIdx>::max();
72       }
73 
74       AdjEdgeIdx addAdjEdgeId(EdgeId EId) {
75         AdjEdgeIdx Idx = AdjEdgeIds.size();
76         AdjEdgeIds.push_back(EId);
77         return Idx;
78       }
79 
80       void removeAdjEdgeId(Graph &G, NodeId ThisNId, AdjEdgeIdx Idx) {
81         // Swap-and-pop for fast removal.
82         //   1) Update the adj index of the edge currently at back().
83         //   2) Move last Edge down to Idx.
84         //   3) pop_back()
85         // If Idx == size() - 1 then the setAdjEdgeIdx and swap are
86         // redundant, but both operations are cheap.
87         G.getEdge(AdjEdgeIds.back()).setAdjEdgeIdx(ThisNId, Idx);
88         AdjEdgeIds[Idx] = AdjEdgeIds.back();
89         AdjEdgeIds.pop_back();
90       }
91 
92       const AdjEdgeList& getAdjEdgeIds() const { return AdjEdgeIds; }
93 
94       VectorPtr Costs;
95       NodeMetadata Metadata;
96 
97     private:
98       AdjEdgeList AdjEdgeIds;
99     };
100 
101     class EdgeEntry {
102     public:
103       EdgeEntry(NodeId N1Id, NodeId N2Id, MatrixPtr Costs)
104           : Costs(std::move(Costs)) {
105         NIds[0] = N1Id;
106         NIds[1] = N2Id;
107         ThisEdgeAdjIdxs[0] = NodeEntry::getInvalidAdjEdgeIdx();
108         ThisEdgeAdjIdxs[1] = NodeEntry::getInvalidAdjEdgeIdx();
109       }
110 
111       void connectToN(Graph &G, EdgeId ThisEdgeId, unsigned NIdx) {
112         assert(ThisEdgeAdjIdxs[NIdx] == NodeEntry::getInvalidAdjEdgeIdx() &&
113                "Edge already connected to NIds[NIdx].");
114         NodeEntry &N = G.getNode(NIds[NIdx]);
115         ThisEdgeAdjIdxs[NIdx] = N.addAdjEdgeId(ThisEdgeId);
116       }
117 
118       void connect(Graph &G, EdgeId ThisEdgeId) {
119         connectToN(G, ThisEdgeId, 0);
120         connectToN(G, ThisEdgeId, 1);
121       }
122 
123       void setAdjEdgeIdx(NodeId NId, typename NodeEntry::AdjEdgeIdx NewIdx) {
124         if (NId == NIds[0])
125           ThisEdgeAdjIdxs[0] = NewIdx;
126         else {
127           assert(NId == NIds[1] && "Edge not connected to NId");
128           ThisEdgeAdjIdxs[1] = NewIdx;
129         }
130       }
131 
132       void disconnectFromN(Graph &G, unsigned NIdx) {
133         assert(ThisEdgeAdjIdxs[NIdx] != NodeEntry::getInvalidAdjEdgeIdx() &&
134                "Edge not connected to NIds[NIdx].");
135         NodeEntry &N = G.getNode(NIds[NIdx]);
136         N.removeAdjEdgeId(G, NIds[NIdx], ThisEdgeAdjIdxs[NIdx]);
137         ThisEdgeAdjIdxs[NIdx] = NodeEntry::getInvalidAdjEdgeIdx();
138       }
139 
140       void disconnectFrom(Graph &G, NodeId NId) {
141         if (NId == NIds[0])
142           disconnectFromN(G, 0);
143         else {
144           assert(NId == NIds[1] && "Edge does not connect NId");
145           disconnectFromN(G, 1);
146         }
147       }
148 
149       NodeId getN1Id() const { return NIds[0]; }
150       NodeId getN2Id() const { return NIds[1]; }
151 
152       MatrixPtr Costs;
153       EdgeMetadata Metadata;
154 
155     private:
156       NodeId NIds[2];
157       typename NodeEntry::AdjEdgeIdx ThisEdgeAdjIdxs[2];
158     };
159 
160     // ----- MEMBERS -----
161 
162     GraphMetadata Metadata;
163     CostAllocator CostAlloc;
164     SolverT *Solver = nullptr;
165 
166     using NodeVector = std::vector<NodeEntry>;
167     using FreeNodeVector = std::vector<NodeId>;
168     NodeVector Nodes;
169     FreeNodeVector FreeNodeIds;
170 
171     using EdgeVector = std::vector<EdgeEntry>;
172     using FreeEdgeVector = std::vector<EdgeId>;
173     EdgeVector Edges;
174     FreeEdgeVector FreeEdgeIds;
175 
176     Graph(const Graph &Other) {}
177 
178     // ----- INTERNAL METHODS -----
179 
180     NodeEntry &getNode(NodeId NId) {
181       assert(NId < Nodes.size() && "Out of bound NodeId");
182       return Nodes[NId];
183     }
184     const NodeEntry &getNode(NodeId NId) const {
185       assert(NId < Nodes.size() && "Out of bound NodeId");
186       return Nodes[NId];
187     }
188 
189     EdgeEntry& getEdge(EdgeId EId) { return Edges[EId]; }
190     const EdgeEntry& getEdge(EdgeId EId) const { return Edges[EId]; }
191 
192     NodeId addConstructedNode(NodeEntry N) {
193       NodeId NId = 0;
194       if (!FreeNodeIds.empty()) {
195         NId = FreeNodeIds.back();
196         FreeNodeIds.pop_back();
197         Nodes[NId] = std::move(N);
198       } else {
199         NId = Nodes.size();
200         Nodes.push_back(std::move(N));
201       }
202       return NId;
203     }
204 
205     EdgeId addConstructedEdge(EdgeEntry E) {
206       assert(findEdge(E.getN1Id(), E.getN2Id()) == invalidEdgeId() &&
207              "Attempt to add duplicate edge.");
208       EdgeId EId = 0;
209       if (!FreeEdgeIds.empty()) {
210         EId = FreeEdgeIds.back();
211         FreeEdgeIds.pop_back();
212         Edges[EId] = std::move(E);
213       } else {
214         EId = Edges.size();
215         Edges.push_back(std::move(E));
216       }
217 
218       EdgeEntry &NE = getEdge(EId);
219 
220       // Add the edge to the adjacency sets of its nodes.
221       NE.connect(*this, EId);
222       return EId;
223     }
224 
225     void operator=(const Graph &Other) {}
226 
227   public:
228     using AdjEdgeItr = typename NodeEntry::AdjEdgeItr;
229 
230     class NodeItr {
231     public:
232       using iterator_category = std::forward_iterator_tag;
233       using value_type = NodeId;
234       using difference_type = int;
235       using pointer = NodeId *;
236       using reference = NodeId &;
237 
238       NodeItr(NodeId CurNId, const Graph &G)
239         : CurNId(CurNId), EndNId(G.Nodes.size()), FreeNodeIds(G.FreeNodeIds) {
240         this->CurNId = findNextInUse(CurNId); // Move to first in-use node id
241       }
242 
243       bool operator==(const NodeItr &O) const { return CurNId == O.CurNId; }
244       bool operator!=(const NodeItr &O) const { return !(*this == O); }
245       NodeItr& operator++() { CurNId = findNextInUse(++CurNId); return *this; }
246       NodeId operator*() const { return CurNId; }
247 
248     private:
249       NodeId findNextInUse(NodeId NId) const {
250         while (NId < EndNId && is_contained(FreeNodeIds, NId)) {
251           ++NId;
252         }
253         return NId;
254       }
255 
256       NodeId CurNId, EndNId;
257       const FreeNodeVector &FreeNodeIds;
258     };
259 
260     class EdgeItr {
261     public:
262       EdgeItr(EdgeId CurEId, const Graph &G)
263         : CurEId(CurEId), EndEId(G.Edges.size()), FreeEdgeIds(G.FreeEdgeIds) {
264         this->CurEId = findNextInUse(CurEId); // Move to first in-use edge id
265       }
266 
267       bool operator==(const EdgeItr &O) const { return CurEId == O.CurEId; }
268       bool operator!=(const EdgeItr &O) const { return !(*this == O); }
269       EdgeItr& operator++() { CurEId = findNextInUse(++CurEId); return *this; }
270       EdgeId operator*() const { return CurEId; }
271 
272     private:
273       EdgeId findNextInUse(EdgeId EId) const {
274         while (EId < EndEId && is_contained(FreeEdgeIds, EId)) {
275           ++EId;
276         }
277         return EId;
278       }
279 
280       EdgeId CurEId, EndEId;
281       const FreeEdgeVector &FreeEdgeIds;
282     };
283 
284     class NodeIdSet {
285     public:
286       NodeIdSet(const Graph &G) : G(G) {}
287 
288       NodeItr begin() const { return NodeItr(0, G); }
289       NodeItr end() const { return NodeItr(G.Nodes.size(), G); }
290 
291       bool empty() const { return G.Nodes.empty(); }
292 
293       typename NodeVector::size_type size() const {
294         return G.Nodes.size() - G.FreeNodeIds.size();
295       }
296 
297     private:
298       const Graph& G;
299     };
300 
301     class EdgeIdSet {
302     public:
303       EdgeIdSet(const Graph &G) : G(G) {}
304 
305       EdgeItr begin() const { return EdgeItr(0, G); }
306       EdgeItr end() const { return EdgeItr(G.Edges.size(), G); }
307 
308       bool empty() const { return G.Edges.empty(); }
309 
310       typename NodeVector::size_type size() const {
311         return G.Edges.size() - G.FreeEdgeIds.size();
312       }
313 
314     private:
315       const Graph& G;
316     };
317 
318     class AdjEdgeIdSet {
319     public:
320       AdjEdgeIdSet(const NodeEntry &NE) : NE(NE) {}
321 
322       typename NodeEntry::AdjEdgeItr begin() const {
323         return NE.getAdjEdgeIds().begin();
324       }
325 
326       typename NodeEntry::AdjEdgeItr end() const {
327         return NE.getAdjEdgeIds().end();
328       }
329 
330       bool empty() const { return NE.getAdjEdgeIds().empty(); }
331 
332       typename NodeEntry::AdjEdgeList::size_type size() const {
333         return NE.getAdjEdgeIds().size();
334       }
335 
336     private:
337       const NodeEntry &NE;
338     };
339 
340     /// Construct an empty PBQP graph.
341     Graph() = default;
342 
343     /// Construct an empty PBQP graph with the given graph metadata.
344     Graph(GraphMetadata Metadata) : Metadata(std::move(Metadata)) {}
345 
346     /// Get a reference to the graph metadata.
347     GraphMetadata& getMetadata() { return Metadata; }
348 
349     /// Get a const-reference to the graph metadata.
350     const GraphMetadata& getMetadata() const { return Metadata; }
351 
352     /// Lock this graph to the given solver instance in preparation
353     /// for running the solver. This method will call solver.handleAddNode for
354     /// each node in the graph, and handleAddEdge for each edge, to give the
355     /// solver an opportunity to set up any requried metadata.
356     void setSolver(SolverT &S) {
357       assert(!Solver && "Solver already set. Call unsetSolver().");
358       Solver = &S;
359       for (auto NId : nodeIds())
360         Solver->handleAddNode(NId);
361       for (auto EId : edgeIds())
362         Solver->handleAddEdge(EId);
363     }
364 
365     /// Release from solver instance.
366     void unsetSolver() {
367       assert(Solver && "Solver not set.");
368       Solver = nullptr;
369     }
370 
371     /// Add a node with the given costs.
372     /// @param Costs Cost vector for the new node.
373     /// @return Node iterator for the added node.
374     template <typename OtherVectorT>
375     NodeId addNode(OtherVectorT Costs) {
376       // Get cost vector from the problem domain
377       VectorPtr AllocatedCosts = CostAlloc.getVector(std::move(Costs));
378       NodeId NId = addConstructedNode(NodeEntry(AllocatedCosts));
379       if (Solver)
380         Solver->handleAddNode(NId);
381       return NId;
382     }
383 
384     /// Add a node bypassing the cost allocator.
385     /// @param Costs Cost vector ptr for the new node (must be convertible to
386     ///        VectorPtr).
387     /// @return Node iterator for the added node.
388     ///
389     ///   This method allows for fast addition of a node whose costs don't need
390     /// to be passed through the cost allocator. The most common use case for
391     /// this is when duplicating costs from an existing node (when using a
392     /// pooling allocator). These have already been uniqued, so we can avoid
393     /// re-constructing and re-uniquing them by attaching them directly to the
394     /// new node.
395     template <typename OtherVectorPtrT>
396     NodeId addNodeBypassingCostAllocator(OtherVectorPtrT Costs) {
397       NodeId NId = addConstructedNode(NodeEntry(Costs));
398       if (Solver)
399         Solver->handleAddNode(NId);
400       return NId;
401     }
402 
403     /// Add an edge between the given nodes with the given costs.
404     /// @param N1Id First node.
405     /// @param N2Id Second node.
406     /// @param Costs Cost matrix for new edge.
407     /// @return Edge iterator for the added edge.
408     template <typename OtherVectorT>
409     EdgeId addEdge(NodeId N1Id, NodeId N2Id, OtherVectorT Costs) {
410       assert(getNodeCosts(N1Id).getLength() == Costs.getRows() &&
411              getNodeCosts(N2Id).getLength() == Costs.getCols() &&
412              "Matrix dimensions mismatch.");
413       // Get cost matrix from the problem domain.
414       MatrixPtr AllocatedCosts = CostAlloc.getMatrix(std::move(Costs));
415       EdgeId EId = addConstructedEdge(EdgeEntry(N1Id, N2Id, AllocatedCosts));
416       if (Solver)
417         Solver->handleAddEdge(EId);
418       return EId;
419     }
420 
421     /// Add an edge bypassing the cost allocator.
422     /// @param N1Id First node.
423     /// @param N2Id Second node.
424     /// @param Costs Cost matrix for new edge.
425     /// @return Edge iterator for the added edge.
426     ///
427     ///   This method allows for fast addition of an edge whose costs don't need
428     /// to be passed through the cost allocator. The most common use case for
429     /// this is when duplicating costs from an existing edge (when using a
430     /// pooling allocator). These have already been uniqued, so we can avoid
431     /// re-constructing and re-uniquing them by attaching them directly to the
432     /// new edge.
433     template <typename OtherMatrixPtrT>
434     NodeId addEdgeBypassingCostAllocator(NodeId N1Id, NodeId N2Id,
435                                          OtherMatrixPtrT Costs) {
436       assert(getNodeCosts(N1Id).getLength() == Costs->getRows() &&
437              getNodeCosts(N2Id).getLength() == Costs->getCols() &&
438              "Matrix dimensions mismatch.");
439       // Get cost matrix from the problem domain.
440       EdgeId EId = addConstructedEdge(EdgeEntry(N1Id, N2Id, Costs));
441       if (Solver)
442         Solver->handleAddEdge(EId);
443       return EId;
444     }
445 
446     /// Returns true if the graph is empty.
447     bool empty() const { return NodeIdSet(*this).empty(); }
448 
449     NodeIdSet nodeIds() const { return NodeIdSet(*this); }
450     EdgeIdSet edgeIds() const { return EdgeIdSet(*this); }
451 
452     AdjEdgeIdSet adjEdgeIds(NodeId NId) { return AdjEdgeIdSet(getNode(NId)); }
453 
454     /// Get the number of nodes in the graph.
455     /// @return Number of nodes in the graph.
456     unsigned getNumNodes() const { return NodeIdSet(*this).size(); }
457 
458     /// Get the number of edges in the graph.
459     /// @return Number of edges in the graph.
460     unsigned getNumEdges() const { return EdgeIdSet(*this).size(); }
461 
462     /// Set a node's cost vector.
463     /// @param NId Node to update.
464     /// @param Costs New costs to set.
465     template <typename OtherVectorT>
466     void setNodeCosts(NodeId NId, OtherVectorT Costs) {
467       VectorPtr AllocatedCosts = CostAlloc.getVector(std::move(Costs));
468       if (Solver)
469         Solver->handleSetNodeCosts(NId, *AllocatedCosts);
470       getNode(NId).Costs = AllocatedCosts;
471     }
472 
473     /// Get a VectorPtr to a node's cost vector. Rarely useful - use
474     ///        getNodeCosts where possible.
475     /// @param NId Node id.
476     /// @return VectorPtr to node cost vector.
477     ///
478     ///   This method is primarily useful for duplicating costs quickly by
479     /// bypassing the cost allocator. See addNodeBypassingCostAllocator. Prefer
480     /// getNodeCosts when dealing with node cost values.
481     const VectorPtr& getNodeCostsPtr(NodeId NId) const {
482       return getNode(NId).Costs;
483     }
484 
485     /// Get a node's cost vector.
486     /// @param NId Node id.
487     /// @return Node cost vector.
488     const Vector& getNodeCosts(NodeId NId) const {
489       return *getNodeCostsPtr(NId);
490     }
491 
492     NodeMetadata& getNodeMetadata(NodeId NId) {
493       return getNode(NId).Metadata;
494     }
495 
496     const NodeMetadata& getNodeMetadata(NodeId NId) const {
497       return getNode(NId).Metadata;
498     }
499 
500     typename NodeEntry::AdjEdgeList::size_type getNodeDegree(NodeId NId) const {
501       return getNode(NId).getAdjEdgeIds().size();
502     }
503 
504     /// Update an edge's cost matrix.
505     /// @param EId Edge id.
506     /// @param Costs New cost matrix.
507     template <typename OtherMatrixT>
508     void updateEdgeCosts(EdgeId EId, OtherMatrixT Costs) {
509       MatrixPtr AllocatedCosts = CostAlloc.getMatrix(std::move(Costs));
510       if (Solver)
511         Solver->handleUpdateCosts(EId, *AllocatedCosts);
512       getEdge(EId).Costs = AllocatedCosts;
513     }
514 
515     /// Get a MatrixPtr to a node's cost matrix. Rarely useful - use
516     ///        getEdgeCosts where possible.
517     /// @param EId Edge id.
518     /// @return MatrixPtr to edge cost matrix.
519     ///
520     ///   This method is primarily useful for duplicating costs quickly by
521     /// bypassing the cost allocator. See addNodeBypassingCostAllocator. Prefer
522     /// getEdgeCosts when dealing with edge cost values.
523     const MatrixPtr& getEdgeCostsPtr(EdgeId EId) const {
524       return getEdge(EId).Costs;
525     }
526 
527     /// Get an edge's cost matrix.
528     /// @param EId Edge id.
529     /// @return Edge cost matrix.
530     const Matrix& getEdgeCosts(EdgeId EId) const {
531       return *getEdge(EId).Costs;
532     }
533 
534     EdgeMetadata& getEdgeMetadata(EdgeId EId) {
535       return getEdge(EId).Metadata;
536     }
537 
538     const EdgeMetadata& getEdgeMetadata(EdgeId EId) const {
539       return getEdge(EId).Metadata;
540     }
541 
542     /// Get the first node connected to this edge.
543     /// @param EId Edge id.
544     /// @return The first node connected to the given edge.
545     NodeId getEdgeNode1Id(EdgeId EId) const {
546       return getEdge(EId).getN1Id();
547     }
548 
549     /// Get the second node connected to this edge.
550     /// @param EId Edge id.
551     /// @return The second node connected to the given edge.
552     NodeId getEdgeNode2Id(EdgeId EId) const {
553       return getEdge(EId).getN2Id();
554     }
555 
556     /// Get the "other" node connected to this edge.
557     /// @param EId Edge id.
558     /// @param NId Node id for the "given" node.
559     /// @return The iterator for the "other" node connected to this edge.
560     NodeId getEdgeOtherNodeId(EdgeId EId, NodeId NId) {
561       EdgeEntry &E = getEdge(EId);
562       if (E.getN1Id() == NId) {
563         return E.getN2Id();
564       } // else
565       return E.getN1Id();
566     }
567 
568     /// Get the edge connecting two nodes.
569     /// @param N1Id First node id.
570     /// @param N2Id Second node id.
571     /// @return An id for edge (N1Id, N2Id) if such an edge exists,
572     ///         otherwise returns an invalid edge id.
573     EdgeId findEdge(NodeId N1Id, NodeId N2Id) {
574       for (auto AEId : adjEdgeIds(N1Id)) {
575         if ((getEdgeNode1Id(AEId) == N2Id) ||
576             (getEdgeNode2Id(AEId) == N2Id)) {
577           return AEId;
578         }
579       }
580       return invalidEdgeId();
581     }
582 
583     /// Remove a node from the graph.
584     /// @param NId Node id.
585     void removeNode(NodeId NId) {
586       if (Solver)
587         Solver->handleRemoveNode(NId);
588       NodeEntry &N = getNode(NId);
589       // TODO: Can this be for-each'd?
590       for (AdjEdgeItr AEItr = N.adjEdgesBegin(),
591              AEEnd = N.adjEdgesEnd();
592            AEItr != AEEnd;) {
593         EdgeId EId = *AEItr;
594         ++AEItr;
595         removeEdge(EId);
596       }
597       FreeNodeIds.push_back(NId);
598     }
599 
600     /// Disconnect an edge from the given node.
601     ///
602     /// Removes the given edge from the adjacency list of the given node.
603     /// This operation leaves the edge in an 'asymmetric' state: It will no
604     /// longer appear in an iteration over the given node's (NId's) edges, but
605     /// will appear in an iteration over the 'other', unnamed node's edges.
606     ///
607     /// This does not correspond to any normal graph operation, but exists to
608     /// support efficient PBQP graph-reduction based solvers. It is used to
609     /// 'effectively' remove the unnamed node from the graph while the solver
610     /// is performing the reduction. The solver will later call reconnectNode
611     /// to restore the edge in the named node's adjacency list.
612     ///
613     /// Since the degree of a node is the number of connected edges,
614     /// disconnecting an edge from a node 'u' will cause the degree of 'u' to
615     /// drop by 1.
616     ///
617     /// A disconnected edge WILL still appear in an iteration over the graph
618     /// edges.
619     ///
620     /// A disconnected edge should not be removed from the graph, it should be
621     /// reconnected first.
622     ///
623     /// A disconnected edge can be reconnected by calling the reconnectEdge
624     /// method.
625     void disconnectEdge(EdgeId EId, NodeId NId) {
626       if (Solver)
627         Solver->handleDisconnectEdge(EId, NId);
628 
629       EdgeEntry &E = getEdge(EId);
630       E.disconnectFrom(*this, NId);
631     }
632 
633     /// Convenience method to disconnect all neighbours from the given
634     ///        node.
635     void disconnectAllNeighborsFromNode(NodeId NId) {
636       for (auto AEId : adjEdgeIds(NId))
637         disconnectEdge(AEId, getEdgeOtherNodeId(AEId, NId));
638     }
639 
640     /// Re-attach an edge to its nodes.
641     ///
642     /// Adds an edge that had been previously disconnected back into the
643     /// adjacency set of the nodes that the edge connects.
644     void reconnectEdge(EdgeId EId, NodeId NId) {
645       EdgeEntry &E = getEdge(EId);
646       E.connectTo(*this, EId, NId);
647       if (Solver)
648         Solver->handleReconnectEdge(EId, NId);
649     }
650 
651     /// Remove an edge from the graph.
652     /// @param EId Edge id.
653     void removeEdge(EdgeId EId) {
654       if (Solver)
655         Solver->handleRemoveEdge(EId);
656       EdgeEntry &E = getEdge(EId);
657       E.disconnect();
658       FreeEdgeIds.push_back(EId);
659       Edges[EId].invalidate();
660     }
661 
662     /// Remove all nodes and edges from the graph.
663     void clear() {
664       Nodes.clear();
665       FreeNodeIds.clear();
666       Edges.clear();
667       FreeEdgeIds.clear();
668     }
669   };
670 
671 } // end namespace PBQP
672 } // end namespace llvm
673 
674 #endif // LLVM_CODEGEN_PBQP_GRAPH_HPP
675