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4bd434d1b0
as DDG and PDG. Summary: This is an implementation of a directed graph base class with explicit representation of both nodes and edges. This implementation makes the edges explicit because we expect to assign various attributes (such as dependence type, distribution interference weight, etc) to the edges in the derived classes such as DDG and DIG. The DirectedGraph consists of a list of DGNode's. Each node consists of a (possibly empty) list of outgoing edges to other nodes in the graph. A DGEdge contains a reference to a single target node. Note that nodes do not know about their incoming edges so the DirectedGraph class provides a function to find all incoming edges to a given node. This is the first patch in a series of patches that we are planning to contribute upstream in order to implement Data Dependence Graph and Program Dependence Graph. More information about the proposed design can be found here: https://ibm.ent.box.com/v/directed-graph-and-ddg Authored By: bmahjour Reviewer: Meinersbur, myhsum hfinkel, fhahn, jdoerfert, kbarton Reviewed By: Meinersbur Subscribers: mgorny, wuzish, jsji, lebedev.ri, dexonsmith, kristina, llvm-commits, Whitney, etiotto Tag: LLVM Differential Revision: https://reviews.llvm.org/D64088 llvm-svn: 367043
296 lines
8.2 KiB
C++
296 lines
8.2 KiB
C++
//===- llvm/unittest/ADT/DirectedGraphTest.cpp ------------------*- C++ -*-===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// This file defines concrete derivations of the directed-graph base classes
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// for testing purposes.
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//
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//===----------------------------------------------------------------------===//
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#include "llvm/ADT/DirectedGraph.h"
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#include "llvm/ADT/GraphTraits.h"
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#include "llvm/ADT/SCCIterator.h"
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#include "llvm/ADT/SmallPtrSet.h"
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#include "gtest/gtest.h"
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namespace llvm {
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//===--------------------------------------------------------------------===//
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// Derived nodes, edges and graph types based on DirectedGraph.
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//===--------------------------------------------------------------------===//
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class DGTestNode;
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class DGTestEdge;
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using DGTestNodeBase = DGNode<DGTestNode, DGTestEdge>;
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using DGTestEdgeBase = DGEdge<DGTestNode, DGTestEdge>;
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using DGTestBase = DirectedGraph<DGTestNode, DGTestEdge>;
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class DGTestNode : public DGTestNodeBase {
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public:
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DGTestNode() = default;
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};
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class DGTestEdge : public DGTestEdgeBase {
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public:
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DGTestEdge() = delete;
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DGTestEdge(DGTestNode &N) : DGTestEdgeBase(N) {}
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};
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class DGTestGraph : public DGTestBase {
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public:
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DGTestGraph() = default;
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~DGTestGraph(){};
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};
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using EdgeListTy = SmallVector<DGTestEdge *, 2>;
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//===--------------------------------------------------------------------===//
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// GraphTraits specializations for the DGTest
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//===--------------------------------------------------------------------===//
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template <> struct GraphTraits<DGTestNode *> {
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using NodeRef = DGTestNode *;
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static DGTestNode *DGTestGetTargetNode(DGEdge<DGTestNode, DGTestEdge> *P) {
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return &P->getTargetNode();
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}
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// Provide a mapped iterator so that the GraphTrait-based implementations can
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// find the target nodes without having to explicitly go through the edges.
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using ChildIteratorType =
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mapped_iterator<DGTestNode::iterator, decltype(&DGTestGetTargetNode)>;
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using ChildEdgeIteratorType = DGTestNode::iterator;
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static NodeRef getEntryNode(NodeRef N) { return N; }
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static ChildIteratorType child_begin(NodeRef N) {
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return ChildIteratorType(N->begin(), &DGTestGetTargetNode);
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}
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static ChildIteratorType child_end(NodeRef N) {
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return ChildIteratorType(N->end(), &DGTestGetTargetNode);
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}
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static ChildEdgeIteratorType child_edge_begin(NodeRef N) {
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return N->begin();
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}
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static ChildEdgeIteratorType child_edge_end(NodeRef N) { return N->end(); }
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};
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template <>
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struct GraphTraits<DGTestGraph *> : public GraphTraits<DGTestNode *> {
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using nodes_iterator = DGTestGraph::iterator;
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static NodeRef getEntryNode(DGTestGraph *DG) { return *DG->begin(); }
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static nodes_iterator nodes_begin(DGTestGraph *DG) { return DG->begin(); }
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static nodes_iterator nodes_end(DGTestGraph *DG) { return DG->end(); }
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};
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//===--------------------------------------------------------------------===//
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// Test various modification and query functions.
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//===--------------------------------------------------------------------===//
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TEST(DirectedGraphTest, AddAndConnectNodes) {
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DGTestGraph DG;
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DGTestNode N1, N2, N3;
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DGTestEdge E1(N1), E2(N2), E3(N3);
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// Check that new nodes can be added successfully.
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EXPECT_TRUE(DG.addNode(N1));
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EXPECT_TRUE(DG.addNode(N2));
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EXPECT_TRUE(DG.addNode(N3));
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// Check that duplicate nodes are not added to the graph.
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EXPECT_FALSE(DG.addNode(N1));
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// Check that nodes can be connected using valid edges with no errors.
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EXPECT_TRUE(DG.connect(N1, N2, E2));
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EXPECT_TRUE(DG.connect(N2, N3, E3));
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EXPECT_TRUE(DG.connect(N3, N1, E1));
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// The graph looks like this now:
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//
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// +---------------+
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// v |
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// N1 -> N2 -> N3 -+
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// Check that already connected nodes with the given edge are not connected
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// again (ie. edges are between nodes are not duplicated).
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EXPECT_FALSE(DG.connect(N3, N1, E1));
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// Check that there are 3 nodes in the graph.
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EXPECT_TRUE(DG.size() == 3);
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// Check that the added nodes can be found in the graph.
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EXPECT_NE(DG.findNode(N3), DG.end());
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// Check that nodes that are not part of the graph are not found.
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DGTestNode N4;
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EXPECT_EQ(DG.findNode(N4), DG.end());
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// Check that findIncommingEdgesToNode works correctly.
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EdgeListTy EL;
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EXPECT_TRUE(DG.findIncomingEdgesToNode(N1, EL));
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EXPECT_TRUE(EL.size() == 1);
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EXPECT_EQ(*EL[0], E1);
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}
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TEST(DirectedGraphTest, AddRemoveEdge) {
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DGTestGraph DG;
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DGTestNode N1, N2, N3;
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DGTestEdge E1(N1), E2(N2), E3(N3);
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DG.addNode(N1);
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DG.addNode(N2);
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DG.addNode(N3);
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DG.connect(N1, N2, E2);
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DG.connect(N2, N3, E3);
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DG.connect(N3, N1, E1);
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// The graph looks like this now:
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//
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// +---------------+
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// v |
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// N1 -> N2 -> N3 -+
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// Check that there are 3 nodes in the graph.
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EXPECT_TRUE(DG.size() == 3);
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// Check that the target nodes of the edges are correct.
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EXPECT_EQ(E1.getTargetNode(), N1);
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EXPECT_EQ(E2.getTargetNode(), N2);
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EXPECT_EQ(E3.getTargetNode(), N3);
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// Remove the edge from N1 to N2.
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N1.removeEdge(E2);
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// The graph looks like this now:
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//
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// N2 -> N3 -> N1
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// Check that there are no incoming edges to N2.
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EdgeListTy EL;
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EXPECT_FALSE(DG.findIncomingEdgesToNode(N2, EL));
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EXPECT_TRUE(EL.empty());
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// Put the edge from N1 to N2 back in place.
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N1.addEdge(E2);
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// Check that E2 is the only incoming edge to N2.
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EL.clear();
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EXPECT_TRUE(DG.findIncomingEdgesToNode(N2, EL));
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EXPECT_EQ(*EL[0], E2);
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}
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TEST(DirectedGraphTest, hasEdgeTo) {
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DGTestGraph DG;
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DGTestNode N1, N2, N3;
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DGTestEdge E1(N1), E2(N2), E3(N3), E4(N1);
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DG.addNode(N1);
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DG.addNode(N2);
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DG.addNode(N3);
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DG.connect(N1, N2, E2);
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DG.connect(N2, N3, E3);
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DG.connect(N3, N1, E1);
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DG.connect(N2, N1, E4);
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// The graph looks like this now:
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//
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// +-----+
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// v |
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// N1 -> N2 -> N3
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// ^ |
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// +-----------+
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EXPECT_TRUE(N2.hasEdgeTo(N1));
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EXPECT_TRUE(N3.hasEdgeTo(N1));
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}
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TEST(DirectedGraphTest, AddRemoveNode) {
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DGTestGraph DG;
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DGTestNode N1, N2, N3;
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DGTestEdge E1(N1), E2(N2), E3(N3);
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DG.addNode(N1);
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DG.addNode(N2);
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DG.addNode(N3);
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DG.connect(N1, N2, E2);
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DG.connect(N2, N3, E3);
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DG.connect(N3, N1, E1);
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// The graph looks like this now:
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//
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// +---------------+
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// v |
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// N1 -> N2 -> N3 -+
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// Check that there are 3 nodes in the graph.
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EXPECT_TRUE(DG.size() == 3);
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// Check that a node in the graph can be removed, but not more than once.
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EXPECT_TRUE(DG.removeNode(N1));
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EXPECT_EQ(DG.findNode(N1), DG.end());
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EXPECT_FALSE(DG.removeNode(N1));
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// The graph looks like this now:
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//
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// N2 -> N3
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// Check that there are 2 nodes in the graph and only N2 is connected to N3.
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EXPECT_TRUE(DG.size() == 2);
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EXPECT_TRUE(N3.getEdges().empty());
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EdgeListTy EL;
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EXPECT_FALSE(DG.findIncomingEdgesToNode(N2, EL));
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EXPECT_TRUE(EL.empty());
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}
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TEST(DirectedGraphTest, SCC) {
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DGTestGraph DG;
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DGTestNode N1, N2, N3, N4;
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DGTestEdge E1(N1), E2(N2), E3(N3), E4(N4);
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DG.addNode(N1);
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DG.addNode(N2);
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DG.addNode(N3);
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DG.addNode(N4);
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DG.connect(N1, N2, E2);
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DG.connect(N2, N3, E3);
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DG.connect(N3, N1, E1);
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DG.connect(N3, N4, E4);
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// The graph looks like this now:
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//
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// +---------------+
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// v |
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// N1 -> N2 -> N3 -+ N4
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// | ^
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// +--------+
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// Test that there are two SCCs:
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// 1. {N1, N2, N3}
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// 2. {N4}
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using NodeListTy = SmallPtrSet<DGTestNode *, 3>;
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SmallVector<NodeListTy, 4> ListOfSCCs;
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for (auto &SCC : make_range(scc_begin(&DG), scc_end(&DG)))
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ListOfSCCs.push_back(NodeListTy(SCC.begin(), SCC.end()));
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EXPECT_TRUE(ListOfSCCs.size() == 2);
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for (auto &SCC : ListOfSCCs) {
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if (SCC.size() > 1)
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continue;
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EXPECT_TRUE(SCC.size() == 1);
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EXPECT_TRUE(SCC.count(&N4) == 1);
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}
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for (auto &SCC : ListOfSCCs) {
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if (SCC.size() <= 1)
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continue;
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EXPECT_TRUE(SCC.size() == 3);
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EXPECT_TRUE(SCC.count(&N1) == 1);
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EXPECT_TRUE(SCC.count(&N2) == 1);
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EXPECT_TRUE(SCC.count(&N3) == 1);
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EXPECT_TRUE(SCC.count(&N4) == 0);
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}
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}
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} // namespace llvm
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