// Copyright 2015 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/access-builder.h" #include "src/compiler/graph.h" #include "src/compiler/graph-visualizer.h" #include "src/compiler/js-graph.h" #include "src/compiler/loop-peeling.h" #include "src/compiler/machine-operator.h" #include "src/compiler/node.h" #include "src/compiler/node-properties.h" #include "test/unittests/compiler/compiler-test-utils.h" #include "test/unittests/compiler/graph-unittest.h" #include "test/unittests/compiler/node-test-utils.h" #include "testing/gmock-support.h" using testing::AllOf; using testing::BitEq; using testing::Capture; using testing::CaptureEq; namespace v8 { namespace internal { namespace compiler { struct While { Node* loop; Node* branch; Node* if_true; Node* if_false; Node* exit; }; // A helper for building branches. struct Branch { Node* branch; Node* if_true; Node* if_false; }; // A helper for building counters attached to loops. struct Counter { Node* base; Node* inc; Node* phi; Node* add; Node* exit_marker; }; class LoopPeelingTest : public GraphTest { public: LoopPeelingTest() : GraphTest(1), machine_(zone()) {} ~LoopPeelingTest() override {} protected: MachineOperatorBuilder machine_; MachineOperatorBuilder* machine() { return &machine_; } LoopTree* GetLoopTree() { if (FLAG_trace_turbo_graph) { OFStream os(stdout); os << AsRPO(*graph()); } Zone zone(isolate()->allocator(), ZONE_NAME); return LoopFinder::BuildLoopTree(graph(), &zone); } PeeledIteration* PeelOne() { LoopTree* loop_tree = GetLoopTree(); LoopTree::Loop* loop = loop_tree->outer_loops()[0]; LoopPeeler peeler(graph(), common(), loop_tree, zone(), source_positions(), node_origins()); EXPECT_TRUE(peeler.CanPeel(loop)); return Peel(peeler, loop); } PeeledIteration* Peel(LoopPeeler peeler, LoopTree::Loop* loop) { EXPECT_TRUE(peeler.CanPeel(loop)); PeeledIteration* peeled = peeler.Peel(loop); if (FLAG_trace_turbo_graph) { OFStream os(stdout); os << AsRPO(*graph()); } return peeled; } Node* InsertReturn(Node* val, Node* effect, Node* control) { Node* zero = graph()->NewNode(common()->Int32Constant(0)); Node* r = graph()->NewNode(common()->Return(), zero, val, effect, control); graph()->SetEnd(r); return r; } Node* ExpectPeeled(Node* node, PeeledIteration* iter) { Node* p = iter->map(node); EXPECT_NE(node, p); return p; } void ExpectNotPeeled(Node* node, PeeledIteration* iter) { EXPECT_EQ(node, iter->map(node)); } While NewWhile(Node* cond, Node* control = nullptr) { if (control == nullptr) control = start(); While w; w.loop = graph()->NewNode(common()->Loop(2), control, control); w.branch = graph()->NewNode(common()->Branch(), cond, w.loop); w.if_true = graph()->NewNode(common()->IfTrue(), w.branch); w.if_false = graph()->NewNode(common()->IfFalse(), w.branch); w.exit = graph()->NewNode(common()->LoopExit(), w.if_false, w.loop); w.loop->ReplaceInput(1, w.if_true); return w; } void Chain(While* a, Node* control) { a->loop->ReplaceInput(0, control); } void Nest(While* a, While* b) { b->loop->ReplaceInput(1, a->exit); a->loop->ReplaceInput(0, b->if_true); } Node* NewPhi(While* w, Node* a, Node* b) { return graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2), a, b, w->loop); } Branch NewBranch(Node* cond, Node* control = nullptr) { Branch b; if (control == nullptr) control = start(); b.branch = graph()->NewNode(common()->Branch(), cond, control); b.if_true = graph()->NewNode(common()->IfTrue(), b.branch); b.if_false = graph()->NewNode(common()->IfFalse(), b.branch); return b; } Counter NewCounter(While* w, int32_t b, int32_t k) { Counter c; c.base = Int32Constant(b); c.inc = Int32Constant(k); c.phi = graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2), c.base, c.base, w->loop); c.add = graph()->NewNode(machine()->Int32Add(), c.phi, c.inc); c.phi->ReplaceInput(1, c.add); c.exit_marker = graph()->NewNode(common()->LoopExitValue(), c.phi, w->exit); return c; } }; TEST_F(LoopPeelingTest, SimpleLoop) { Node* p0 = Parameter(0); While w = NewWhile(p0); Node* r = InsertReturn(p0, start(), w.exit); PeeledIteration* peeled = PeelOne(); Node* br1 = ExpectPeeled(w.branch, peeled); Node* if_true1 = ExpectPeeled(w.if_true, peeled); Node* if_false1 = ExpectPeeled(w.if_false, peeled); EXPECT_THAT(br1, IsBranch(p0, start())); EXPECT_THAT(if_true1, IsIfTrue(br1)); EXPECT_THAT(if_false1, IsIfFalse(br1)); EXPECT_THAT(w.loop, IsLoop(if_true1, w.if_true)); EXPECT_THAT(r, IsReturn(p0, start(), IsMerge(w.if_false, if_false1))); } TEST_F(LoopPeelingTest, SimpleLoopWithCounter) { Node* p0 = Parameter(0); While w = NewWhile(p0); Counter c = NewCounter(&w, 0, 1); Node* r = InsertReturn(c.exit_marker, start(), w.exit); PeeledIteration* peeled = PeelOne(); Node* br1 = ExpectPeeled(w.branch, peeled); Node* if_true1 = ExpectPeeled(w.if_true, peeled); Node* if_false1 = ExpectPeeled(w.if_false, peeled); EXPECT_THAT(br1, IsBranch(p0, start())); EXPECT_THAT(if_true1, IsIfTrue(br1)); EXPECT_THAT(if_false1, IsIfFalse(br1)); EXPECT_THAT(w.loop, IsLoop(if_true1, w.if_true)); EXPECT_THAT(peeled->map(c.add), IsInt32Add(c.base, c.inc)); EXPECT_THAT(w.exit, IsMerge(w.if_false, if_false1)); EXPECT_THAT( r, IsReturn(IsPhi(MachineRepresentation::kTagged, c.phi, c.base, w.exit), start(), w.exit)); } TEST_F(LoopPeelingTest, SimpleNestedLoopWithCounter_peel_outer) { Node* p0 = Parameter(0); While outer = NewWhile(p0); While inner = NewWhile(p0); Nest(&inner, &outer); Counter c = NewCounter(&outer, 0, 1); Node* r = InsertReturn(c.exit_marker, start(), outer.exit); PeeledIteration* peeled = PeelOne(); Node* bro = ExpectPeeled(outer.branch, peeled); Node* if_trueo = ExpectPeeled(outer.if_true, peeled); Node* if_falseo = ExpectPeeled(outer.if_false, peeled); EXPECT_THAT(bro, IsBranch(p0, start())); EXPECT_THAT(if_trueo, IsIfTrue(bro)); EXPECT_THAT(if_falseo, IsIfFalse(bro)); Node* bri = ExpectPeeled(inner.branch, peeled); Node* if_truei = ExpectPeeled(inner.if_true, peeled); Node* if_falsei = ExpectPeeled(inner.if_false, peeled); Node* exiti = ExpectPeeled(inner.exit, peeled); EXPECT_THAT(bri, IsBranch(p0, ExpectPeeled(inner.loop, peeled))); EXPECT_THAT(if_truei, IsIfTrue(bri)); EXPECT_THAT(if_falsei, IsIfFalse(bri)); EXPECT_THAT(outer.loop, IsLoop(exiti, inner.exit)); EXPECT_THAT(peeled->map(c.add), IsInt32Add(c.base, c.inc)); Capture merge; EXPECT_THAT(outer.exit, IsMerge(outer.if_false, if_falseo)); EXPECT_THAT(r, IsReturn(IsPhi(MachineRepresentation::kTagged, c.phi, c.base, outer.exit), start(), outer.exit)); } TEST_F(LoopPeelingTest, SimpleNestedLoopWithCounter_peel_inner) { Node* p0 = Parameter(0); While outer = NewWhile(p0); While inner = NewWhile(p0); Nest(&inner, &outer); Counter c = NewCounter(&outer, 0, 1); Node* r = InsertReturn(c.exit_marker, start(), outer.exit); LoopTree* loop_tree = GetLoopTree(); LoopTree::Loop* loop = loop_tree->ContainingLoop(inner.loop); EXPECT_NE(nullptr, loop); EXPECT_EQ(1u, loop->depth()); LoopPeeler peeler(graph(), common(), loop_tree, zone(), source_positions(), node_origins()); PeeledIteration* peeled = Peel(peeler, loop); ExpectNotPeeled(outer.loop, peeled); ExpectNotPeeled(outer.branch, peeled); ExpectNotPeeled(outer.if_true, peeled); ExpectNotPeeled(outer.if_false, peeled); ExpectNotPeeled(outer.exit, peeled); Node* bri = ExpectPeeled(inner.branch, peeled); Node* if_truei = ExpectPeeled(inner.if_true, peeled); Node* if_falsei = ExpectPeeled(inner.if_false, peeled); EXPECT_THAT(bri, IsBranch(p0, ExpectPeeled(inner.loop, peeled))); EXPECT_THAT(if_truei, IsIfTrue(bri)); EXPECT_THAT(if_falsei, IsIfFalse(bri)); EXPECT_THAT(inner.exit, IsMerge(inner.if_false, if_falsei)); EXPECT_THAT(outer.loop, IsLoop(start(), inner.exit)); ExpectNotPeeled(c.add, peeled); EXPECT_THAT(r, IsReturn(c.exit_marker, start(), outer.exit)); } TEST_F(LoopPeelingTest, SimpleInnerCounter_peel_inner) { Node* p0 = Parameter(0); While outer = NewWhile(p0); While inner = NewWhile(p0); Nest(&inner, &outer); Counter c = NewCounter(&inner, 0, 1); Node* phi = NewPhi(&outer, Int32Constant(11), c.exit_marker); Node* r = InsertReturn(phi, start(), outer.exit); LoopTree* loop_tree = GetLoopTree(); LoopTree::Loop* loop = loop_tree->ContainingLoop(inner.loop); EXPECT_NE(nullptr, loop); EXPECT_EQ(1u, loop->depth()); LoopPeeler peeler(graph(), common(), loop_tree, zone(), source_positions(), node_origins()); PeeledIteration* peeled = Peel(peeler, loop); ExpectNotPeeled(outer.loop, peeled); ExpectNotPeeled(outer.branch, peeled); ExpectNotPeeled(outer.if_true, peeled); ExpectNotPeeled(outer.if_false, peeled); ExpectNotPeeled(outer.exit, peeled); Node* bri = ExpectPeeled(inner.branch, peeled); Node* if_truei = ExpectPeeled(inner.if_true, peeled); Node* if_falsei = ExpectPeeled(inner.if_false, peeled); EXPECT_THAT(bri, IsBranch(p0, ExpectPeeled(inner.loop, peeled))); EXPECT_THAT(if_truei, IsIfTrue(bri)); EXPECT_THAT(if_falsei, IsIfFalse(bri)); EXPECT_THAT(inner.exit, IsMerge(inner.if_false, if_falsei)); EXPECT_THAT(outer.loop, IsLoop(start(), inner.exit)); EXPECT_THAT(peeled->map(c.add), IsInt32Add(c.base, c.inc)); EXPECT_THAT(c.exit_marker, IsPhi(MachineRepresentation::kTagged, c.phi, c.base, inner.exit)); EXPECT_THAT(phi, IsPhi(MachineRepresentation::kTagged, IsInt32Constant(11), c.exit_marker, outer.loop)); EXPECT_THAT(r, IsReturn(phi, start(), outer.exit)); } TEST_F(LoopPeelingTest, TwoBackedgeLoop) { Node* p0 = Parameter(0); Node* loop = graph()->NewNode(common()->Loop(3), start(), start(), start()); Branch b1 = NewBranch(p0, loop); Branch b2 = NewBranch(p0, b1.if_true); loop->ReplaceInput(1, b2.if_true); loop->ReplaceInput(2, b2.if_false); Node* exit = graph()->NewNode(common()->LoopExit(), b1.if_false, loop); Node* r = InsertReturn(p0, start(), exit); PeeledIteration* peeled = PeelOne(); Node* b1b = ExpectPeeled(b1.branch, peeled); Node* b1t = ExpectPeeled(b1.if_true, peeled); Node* b1f = ExpectPeeled(b1.if_false, peeled); EXPECT_THAT(b1b, IsBranch(p0, start())); EXPECT_THAT(ExpectPeeled(b1.if_true, peeled), IsIfTrue(b1b)); EXPECT_THAT(b1f, IsIfFalse(b1b)); Node* b2b = ExpectPeeled(b2.branch, peeled); Node* b2t = ExpectPeeled(b2.if_true, peeled); Node* b2f = ExpectPeeled(b2.if_false, peeled); EXPECT_THAT(b2b, IsBranch(p0, b1t)); EXPECT_THAT(b2t, IsIfTrue(b2b)); EXPECT_THAT(b2f, IsIfFalse(b2b)); EXPECT_THAT(loop, IsLoop(IsMerge(b2t, b2f), b2.if_true, b2.if_false)); EXPECT_THAT(exit, IsMerge(b1.if_false, b1f)); EXPECT_THAT(r, IsReturn(p0, start(), exit)); } TEST_F(LoopPeelingTest, TwoBackedgeLoopWithPhi) { Node* p0 = Parameter(0); Node* loop = graph()->NewNode(common()->Loop(3), start(), start(), start()); Branch b1 = NewBranch(p0, loop); Branch b2 = NewBranch(p0, b1.if_true); Node* phi = graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 3), Int32Constant(0), Int32Constant(1), Int32Constant(2), loop); loop->ReplaceInput(1, b2.if_true); loop->ReplaceInput(2, b2.if_false); Node* exit = graph()->NewNode(common()->LoopExit(), b1.if_false, loop); Node* exit_marker = graph()->NewNode(common()->LoopExitValue(), phi, exit); Node* r = InsertReturn(exit_marker, start(), exit); PeeledIteration* peeled = PeelOne(); Node* b1b = ExpectPeeled(b1.branch, peeled); Node* b1t = ExpectPeeled(b1.if_true, peeled); Node* b1f = ExpectPeeled(b1.if_false, peeled); EXPECT_THAT(b1b, IsBranch(p0, start())); EXPECT_THAT(ExpectPeeled(b1.if_true, peeled), IsIfTrue(b1b)); EXPECT_THAT(b1f, IsIfFalse(b1b)); Node* b2b = ExpectPeeled(b2.branch, peeled); Node* b2t = ExpectPeeled(b2.if_true, peeled); Node* b2f = ExpectPeeled(b2.if_false, peeled); EXPECT_THAT(b2b, IsBranch(p0, b1t)); EXPECT_THAT(b2t, IsIfTrue(b2b)); EXPECT_THAT(b2f, IsIfFalse(b2b)); EXPECT_THAT(loop, IsLoop(IsMerge(b2t, b2f), b2.if_true, b2.if_false)); EXPECT_THAT(phi, IsPhi(MachineRepresentation::kTagged, IsPhi(MachineRepresentation::kTagged, IsInt32Constant(1), IsInt32Constant(2), IsMerge(b2t, b2f)), IsInt32Constant(1), IsInt32Constant(2), loop)); EXPECT_THAT(exit, IsMerge(b1.if_false, b1f)); EXPECT_THAT(exit_marker, IsPhi(MachineRepresentation::kTagged, phi, IsInt32Constant(0), exit)); EXPECT_THAT(r, IsReturn(exit_marker, start(), exit)); } TEST_F(LoopPeelingTest, TwoBackedgeLoopWithCounter) { Node* p0 = Parameter(0); Node* loop = graph()->NewNode(common()->Loop(3), start(), start(), start()); Branch b1 = NewBranch(p0, loop); Branch b2 = NewBranch(p0, b1.if_true); Node* phi = graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 3), Int32Constant(0), Int32Constant(1), Int32Constant(2), loop); phi->ReplaceInput( 1, graph()->NewNode(machine()->Int32Add(), phi, Int32Constant(1))); phi->ReplaceInput( 2, graph()->NewNode(machine()->Int32Add(), phi, Int32Constant(2))); loop->ReplaceInput(1, b2.if_true); loop->ReplaceInput(2, b2.if_false); Node* exit = graph()->NewNode(common()->LoopExit(), b1.if_false, loop); Node* exit_marker = graph()->NewNode(common()->LoopExitValue(), phi, exit); Node* r = InsertReturn(exit_marker, start(), exit); PeeledIteration* peeled = PeelOne(); Node* b1b = ExpectPeeled(b1.branch, peeled); Node* b1t = ExpectPeeled(b1.if_true, peeled); Node* b1f = ExpectPeeled(b1.if_false, peeled); EXPECT_THAT(b1b, IsBranch(p0, start())); EXPECT_THAT(ExpectPeeled(b1.if_true, peeled), IsIfTrue(b1b)); EXPECT_THAT(b1f, IsIfFalse(b1b)); Node* b2b = ExpectPeeled(b2.branch, peeled); Node* b2t = ExpectPeeled(b2.if_true, peeled); Node* b2f = ExpectPeeled(b2.if_false, peeled); EXPECT_THAT(b2b, IsBranch(p0, b1t)); EXPECT_THAT(b2t, IsIfTrue(b2b)); EXPECT_THAT(b2f, IsIfFalse(b2b)); Capture entry; EXPECT_THAT(loop, IsLoop(AllOf(CaptureEq(&entry), IsMerge(b2t, b2f)), b2.if_true, b2.if_false)); Node* eval = phi->InputAt(0); EXPECT_THAT(eval, IsPhi(MachineRepresentation::kTagged, IsInt32Add(IsInt32Constant(0), IsInt32Constant(1)), IsInt32Add(IsInt32Constant(0), IsInt32Constant(2)), CaptureEq(&entry))); EXPECT_THAT(phi, IsPhi(MachineRepresentation::kTagged, eval, IsInt32Add(phi, IsInt32Constant(1)), IsInt32Add(phi, IsInt32Constant(2)), loop)); EXPECT_THAT(exit, IsMerge(b1.if_false, b1f)); EXPECT_THAT(exit_marker, IsPhi(MachineRepresentation::kTagged, phi, IsInt32Constant(0), exit)); EXPECT_THAT(r, IsReturn(exit_marker, start(), exit)); } TEST_F(LoopPeelingTest, TwoExitLoop) { Node* p0 = Parameter(0); Node* loop = graph()->NewNode(common()->Loop(2), start(), start()); Branch b1 = NewBranch(p0, loop); Branch b2 = NewBranch(p0, b1.if_true); loop->ReplaceInput(1, b2.if_true); Node* exit1 = graph()->NewNode(common()->LoopExit(), b1.if_false, loop); Node* exit2 = graph()->NewNode(common()->LoopExit(), b2.if_false, loop); Node* merge = graph()->NewNode(common()->Merge(2), exit1, exit2); Node* r = InsertReturn(p0, start(), merge); PeeledIteration* peeled = PeelOne(); Node* b1p = ExpectPeeled(b1.branch, peeled); Node* if_true1p = ExpectPeeled(b1.if_true, peeled); Node* if_false1p = ExpectPeeled(b1.if_false, peeled); Node* b2p = ExpectPeeled(b2.branch, peeled); Node* if_true2p = ExpectPeeled(b2.if_true, peeled); Node* if_false2p = ExpectPeeled(b2.if_false, peeled); EXPECT_THAT(b1p, IsBranch(p0, start())); EXPECT_THAT(if_true1p, IsIfTrue(b1p)); EXPECT_THAT(if_false1p, IsIfFalse(b1p)); EXPECT_THAT(b2p, IsBranch(p0, if_true1p)); EXPECT_THAT(if_true2p, IsIfTrue(b2p)); EXPECT_THAT(if_false2p, IsIfFalse(b2p)); EXPECT_THAT(exit1, IsMerge(b1.if_false, if_false1p)); EXPECT_THAT(exit2, IsMerge(b2.if_false, if_false2p)); EXPECT_THAT(loop, IsLoop(if_true2p, b2.if_true)); EXPECT_THAT(merge, IsMerge(exit1, exit2)); EXPECT_THAT(r, IsReturn(p0, start(), merge)); } TEST_F(LoopPeelingTest, SimpleLoopWithUnmarkedExit) { Node* p0 = Parameter(0); Node* loop = graph()->NewNode(common()->Loop(2), start(), start()); Branch b = NewBranch(p0, loop); loop->ReplaceInput(1, b.if_true); InsertReturn(p0, start(), b.if_false); { LoopTree* loop_tree = GetLoopTree(); LoopTree::Loop* loop = loop_tree->outer_loops()[0]; LoopPeeler peeler(graph(), common(), loop_tree, zone(), source_positions(), node_origins()); EXPECT_FALSE(peeler.CanPeel(loop)); } } } // namespace compiler } // namespace internal } // namespace v8