// Copyright 2014 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "src/compiler/control-equivalence.h" #include "src/bit-vector.h" #include "src/compiler/compiler-source-position-table.h" #include "src/compiler/graph-visualizer.h" #include "src/compiler/node-origin-table.h" #include "src/compiler/node-properties.h" #include "src/zone/zone-containers.h" #include "test/unittests/compiler/graph-unittest.h" namespace v8 { namespace internal { namespace compiler { #define ASSERT_EQUIVALENCE(...) \ do { \ Node* __n[] = {__VA_ARGS__}; \ ASSERT_TRUE(IsEquivalenceClass(arraysize(__n), __n)); \ } while (false) class ControlEquivalenceTest : public GraphTest { public: ControlEquivalenceTest() : all_nodes_(zone()), classes_(zone()) { Store(graph()->start()); } protected: void ComputeEquivalence(Node* node) { graph()->SetEnd(graph()->NewNode(common()->End(1), node)); if (FLAG_trace_turbo) { OFStream os(stdout); SourcePositionTable table(graph()); NodeOriginTable table2(graph()); os << AsJSON(*graph(), &table, &table2); } ControlEquivalence equivalence(zone(), graph()); equivalence.Run(node); classes_.resize(graph()->NodeCount()); for (Node* node : all_nodes_) { classes_[node->id()] = equivalence.ClassOf(node); } } bool IsEquivalenceClass(size_t length, Node** nodes) { BitVector in_class(static_cast(graph()->NodeCount()), zone()); size_t expected_class = classes_[nodes[0]->id()]; for (size_t i = 0; i < length; ++i) { in_class.Add(nodes[i]->id()); } for (Node* node : all_nodes_) { if (in_class.Contains(node->id())) { if (classes_[node->id()] != expected_class) return false; } else { if (classes_[node->id()] == expected_class) return false; } } return true; } Node* Value() { return NumberConstant(0.0); } Node* Branch(Node* control) { return Store(graph()->NewNode(common()->Branch(), Value(), control)); } Node* IfTrue(Node* control) { return Store(graph()->NewNode(common()->IfTrue(), control)); } Node* IfFalse(Node* control) { return Store(graph()->NewNode(common()->IfFalse(), control)); } Node* Merge1(Node* control) { return Store(graph()->NewNode(common()->Merge(1), control)); } Node* Merge2(Node* control1, Node* control2) { return Store(graph()->NewNode(common()->Merge(2), control1, control2)); } Node* Loop2(Node* control) { return Store(graph()->NewNode(common()->Loop(2), control, control)); } Node* End(Node* control) { return Store(graph()->NewNode(common()->End(1), control)); } private: Node* Store(Node* node) { all_nodes_.push_back(node); return node; } ZoneVector all_nodes_; ZoneVector classes_; }; // ----------------------------------------------------------------------------- // Test cases. TEST_F(ControlEquivalenceTest, Empty1) { Node* start = graph()->start(); ComputeEquivalence(start); ASSERT_EQUIVALENCE(start); } TEST_F(ControlEquivalenceTest, Empty2) { Node* start = graph()->start(); Node* merge1 = Merge1(start); ComputeEquivalence(merge1); ASSERT_EQUIVALENCE(start, merge1); } TEST_F(ControlEquivalenceTest, Diamond1) { Node* start = graph()->start(); Node* b = Branch(start); Node* t = IfTrue(b); Node* f = IfFalse(b); Node* m = Merge2(t, f); ComputeEquivalence(m); ASSERT_EQUIVALENCE(b, m, start); ASSERT_EQUIVALENCE(f); ASSERT_EQUIVALENCE(t); } TEST_F(ControlEquivalenceTest, Diamond2) { Node* start = graph()->start(); Node* b1 = Branch(start); Node* t1 = IfTrue(b1); Node* f1 = IfFalse(b1); Node* b2 = Branch(f1); Node* t2 = IfTrue(b2); Node* f2 = IfFalse(b2); Node* m2 = Merge2(t2, f2); Node* m1 = Merge2(t1, m2); ComputeEquivalence(m1); ASSERT_EQUIVALENCE(b1, m1, start); ASSERT_EQUIVALENCE(t1); ASSERT_EQUIVALENCE(f1, b2, m2); ASSERT_EQUIVALENCE(t2); ASSERT_EQUIVALENCE(f2); } TEST_F(ControlEquivalenceTest, Diamond3) { Node* start = graph()->start(); Node* b1 = Branch(start); Node* t1 = IfTrue(b1); Node* f1 = IfFalse(b1); Node* m1 = Merge2(t1, f1); Node* b2 = Branch(m1); Node* t2 = IfTrue(b2); Node* f2 = IfFalse(b2); Node* m2 = Merge2(t2, f2); ComputeEquivalence(m2); ASSERT_EQUIVALENCE(b1, m1, b2, m2, start); ASSERT_EQUIVALENCE(t1); ASSERT_EQUIVALENCE(f1); ASSERT_EQUIVALENCE(t2); ASSERT_EQUIVALENCE(f2); } TEST_F(ControlEquivalenceTest, Switch1) { Node* start = graph()->start(); Node* b1 = Branch(start); Node* t1 = IfTrue(b1); Node* f1 = IfFalse(b1); Node* b2 = Branch(f1); Node* t2 = IfTrue(b2); Node* f2 = IfFalse(b2); Node* b3 = Branch(f2); Node* t3 = IfTrue(b3); Node* f3 = IfFalse(b3); Node* m1 = Merge2(t1, t2); Node* m2 = Merge2(m1, t3); Node* m3 = Merge2(m2, f3); ComputeEquivalence(m3); ASSERT_EQUIVALENCE(b1, m3, start); ASSERT_EQUIVALENCE(t1); ASSERT_EQUIVALENCE(f1, b2); ASSERT_EQUIVALENCE(t2); ASSERT_EQUIVALENCE(f2, b3); ASSERT_EQUIVALENCE(t3); ASSERT_EQUIVALENCE(f3); ASSERT_EQUIVALENCE(m1); ASSERT_EQUIVALENCE(m2); } TEST_F(ControlEquivalenceTest, Loop1) { Node* start = graph()->start(); Node* l = Loop2(start); l->ReplaceInput(1, l); ComputeEquivalence(l); ASSERT_EQUIVALENCE(start); ASSERT_EQUIVALENCE(l); } TEST_F(ControlEquivalenceTest, Loop2) { Node* start = graph()->start(); Node* l = Loop2(start); Node* b = Branch(l); Node* t = IfTrue(b); Node* f = IfFalse(b); l->ReplaceInput(1, t); ComputeEquivalence(f); ASSERT_EQUIVALENCE(f, start); ASSERT_EQUIVALENCE(t); ASSERT_EQUIVALENCE(l, b); } TEST_F(ControlEquivalenceTest, Irreducible) { Node* start = graph()->start(); Node* b1 = Branch(start); Node* t1 = IfTrue(b1); Node* f1 = IfFalse(b1); Node* lp = Loop2(f1); Node* m1 = Merge2(t1, lp); Node* b2 = Branch(m1); Node* t2 = IfTrue(b2); Node* f2 = IfFalse(b2); Node* m2 = Merge2(t2, f2); Node* b3 = Branch(m2); Node* t3 = IfTrue(b3); Node* f3 = IfFalse(b3); lp->ReplaceInput(1, f3); ComputeEquivalence(t3); ASSERT_EQUIVALENCE(b1, t3, start); ASSERT_EQUIVALENCE(t1); ASSERT_EQUIVALENCE(f1); ASSERT_EQUIVALENCE(m1, b2, m2, b3); ASSERT_EQUIVALENCE(t2); ASSERT_EQUIVALENCE(f2); ASSERT_EQUIVALENCE(f3); ASSERT_EQUIVALENCE(lp); } } // namespace compiler } // namespace internal } // namespace v8