/* * Copyright (C) 2015 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include "base/arena_allocator.h" #include "builder.h" #include "induction_var_analysis.h" #include "nodes.h" #include "optimizing_unit_test.h" namespace art { /** * Fixture class for the InductionVarAnalysis tests. */ class InductionVarAnalysisTest : public CommonCompilerTest { public: InductionVarAnalysisTest() : pool_(), allocator_(&pool_) { graph_ = CreateGraph(&allocator_); } ~InductionVarAnalysisTest() { } // Builds single for-loop at depth d. void BuildForLoop(int d, int n) { ASSERT_LT(d, n); loop_preheader_[d] = new (&allocator_) HBasicBlock(graph_); graph_->AddBlock(loop_preheader_[d]); loop_header_[d] = new (&allocator_) HBasicBlock(graph_); graph_->AddBlock(loop_header_[d]); loop_preheader_[d]->AddSuccessor(loop_header_[d]); if (d < (n - 1)) { BuildForLoop(d + 1, n); } loop_body_[d] = new (&allocator_) HBasicBlock(graph_); graph_->AddBlock(loop_body_[d]); loop_body_[d]->AddSuccessor(loop_header_[d]); if (d < (n - 1)) { loop_header_[d]->AddSuccessor(loop_preheader_[d + 1]); loop_header_[d + 1]->AddSuccessor(loop_body_[d]); } else { loop_header_[d]->AddSuccessor(loop_body_[d]); } } // Builds a n-nested loop in CFG where each loop at depth 0 <= d < n // is defined as "for (int i_d = 0; i_d < 100; i_d++)". Tests can further // populate the loop with instructions to set up interesting scenarios. void BuildLoopNest(int n) { ASSERT_LE(n, 10); graph_->SetNumberOfVRegs(n + 3); // Build basic blocks with entry, nested loop, exit. entry_ = new (&allocator_) HBasicBlock(graph_); graph_->AddBlock(entry_); BuildForLoop(0, n); return_ = new (&allocator_) HBasicBlock(graph_); graph_->AddBlock(return_); exit_ = new (&allocator_) HBasicBlock(graph_); graph_->AddBlock(exit_); entry_->AddSuccessor(loop_preheader_[0]); loop_header_[0]->AddSuccessor(return_); return_->AddSuccessor(exit_); graph_->SetEntryBlock(entry_); graph_->SetExitBlock(exit_); // Provide entry and exit instructions. parameter_ = new (&allocator_) HParameterValue( graph_->GetDexFile(), 0, 0, Primitive::kPrimNot, true); entry_->AddInstruction(parameter_); constant0_ = graph_->GetIntConstant(0); constant1_ = graph_->GetIntConstant(1); constant100_ = graph_->GetIntConstant(100); float_constant0_ = graph_->GetFloatConstant(0.0f); return_->AddInstruction(new (&allocator_) HReturnVoid()); exit_->AddInstruction(new (&allocator_) HExit()); // Provide loop instructions. for (int d = 0; d < n; d++) { basic_[d] = new (&allocator_) HPhi(&allocator_, d, 0, Primitive::kPrimInt); loop_preheader_[d]->AddInstruction(new (&allocator_) HGoto()); loop_header_[d]->AddPhi(basic_[d]); HInstruction* compare = new (&allocator_) HLessThan(basic_[d], constant100_); loop_header_[d]->AddInstruction(compare); loop_header_[d]->AddInstruction(new (&allocator_) HIf(compare)); increment_[d] = new (&allocator_) HAdd(Primitive::kPrimInt, basic_[d], constant1_); loop_body_[d]->AddInstruction(increment_[d]); loop_body_[d]->AddInstruction(new (&allocator_) HGoto()); basic_[d]->AddInput(constant0_); basic_[d]->AddInput(increment_[d]); } } // Builds if-statement at depth d. HPhi* BuildIf(int d, HBasicBlock** ifT, HBasicBlock **ifF) { HBasicBlock* cond = new (&allocator_) HBasicBlock(graph_); HBasicBlock* ifTrue = new (&allocator_) HBasicBlock(graph_); HBasicBlock* ifFalse = new (&allocator_) HBasicBlock(graph_); graph_->AddBlock(cond); graph_->AddBlock(ifTrue); graph_->AddBlock(ifFalse); // Conditional split. loop_header_[d]->ReplaceSuccessor(loop_body_[d], cond); cond->AddSuccessor(ifTrue); cond->AddSuccessor(ifFalse); ifTrue->AddSuccessor(loop_body_[d]); ifFalse->AddSuccessor(loop_body_[d]); cond->AddInstruction(new (&allocator_) HIf(parameter_)); *ifT = ifTrue; *ifF = ifFalse; HPhi* select_phi = new (&allocator_) HPhi(&allocator_, -1, 0, Primitive::kPrimInt); loop_body_[d]->AddPhi(select_phi); return select_phi; } // Inserts instruction right before increment at depth d. HInstruction* InsertInstruction(HInstruction* instruction, int d) { loop_body_[d]->InsertInstructionBefore(instruction, increment_[d]); return instruction; } // Inserts a phi to loop header at depth d and returns it. HPhi* InsertLoopPhi(int vreg, int d) { HPhi* phi = new (&allocator_) HPhi(&allocator_, vreg, 0, Primitive::kPrimInt); loop_header_[d]->AddPhi(phi); return phi; } // Inserts an array store with given `subscript` at depth d to // enable tests to inspect the computed induction at that point easily. HInstruction* InsertArrayStore(HInstruction* subscript, int d) { // ArraySet is given a float value in order to avoid SsaBuilder typing // it from the array's non-existent reference type info. return InsertInstruction(new (&allocator_) HArraySet( parameter_, subscript, float_constant0_, Primitive::kPrimFloat, 0), d); } // Returns induction information of instruction in loop at depth d. std::string GetInductionInfo(HInstruction* instruction, int d) { return HInductionVarAnalysis::InductionToString( iva_->LookupInfo(loop_body_[d]->GetLoopInformation(), instruction)); } // Returns true if instructions have identical induction. bool HaveSameInduction(HInstruction* instruction1, HInstruction* instruction2) { return HInductionVarAnalysis::InductionEqual( iva_->LookupInfo(loop_body_[0]->GetLoopInformation(), instruction1), iva_->LookupInfo(loop_body_[0]->GetLoopInformation(), instruction2)); } // Performs InductionVarAnalysis (after proper set up). void PerformInductionVarAnalysis() { graph_->BuildDominatorTree(); iva_ = new (&allocator_) HInductionVarAnalysis(graph_); iva_->Run(); } // General building fields. ArenaPool pool_; ArenaAllocator allocator_; HGraph* graph_; HInductionVarAnalysis* iva_; // Fixed basic blocks and instructions. HBasicBlock* entry_; HBasicBlock* return_; HBasicBlock* exit_; HInstruction* parameter_; // "this" HInstruction* constant0_; HInstruction* constant1_; HInstruction* constant100_; HInstruction* float_constant0_; // Loop specifics. HBasicBlock* loop_preheader_[10]; HBasicBlock* loop_header_[10]; HBasicBlock* loop_body_[10]; HInstruction* increment_[10]; HPhi* basic_[10]; // "vreg_d", the "i_d" }; // // The actual InductionVarAnalysis tests. // TEST_F(InductionVarAnalysisTest, ProperLoopSetup) { // Setup: // for (int i_0 = 0; i_0 < 100; i_0++) { // .. // for (int i_9 = 0; i_9 < 100; i_9++) { // } // .. // } BuildLoopNest(10); graph_->BuildDominatorTree(); ASSERT_EQ(entry_->GetLoopInformation(), nullptr); for (int d = 0; d < 1; d++) { ASSERT_EQ(loop_preheader_[d]->GetLoopInformation(), (d == 0) ? nullptr : loop_header_[d - 1]->GetLoopInformation()); ASSERT_NE(loop_header_[d]->GetLoopInformation(), nullptr); ASSERT_NE(loop_body_[d]->GetLoopInformation(), nullptr); ASSERT_EQ(loop_header_[d]->GetLoopInformation(), loop_body_[d]->GetLoopInformation()); } ASSERT_EQ(exit_->GetLoopInformation(), nullptr); } TEST_F(InductionVarAnalysisTest, FindBasicInduction) { // Setup: // for (int i = 0; i < 100; i++) { // a[i] = 0; // } BuildLoopNest(1); HInstruction* store = InsertArrayStore(basic_[0], 0); PerformInductionVarAnalysis(); EXPECT_STREQ("((1) * i + (0)):PrimInt", GetInductionInfo(store->InputAt(1), 0).c_str()); EXPECT_STREQ("((1) * i + (1)):PrimInt", GetInductionInfo(increment_[0], 0).c_str()); // Offset matters! EXPECT_FALSE(HaveSameInduction(store->InputAt(1), increment_[0])); // Trip-count. EXPECT_STREQ("((100) (TC-loop) ((0) < (100)))", GetInductionInfo(loop_header_[0]->GetLastInstruction(), 0).c_str()); } TEST_F(InductionVarAnalysisTest, FindDerivedInduction) { // Setup: // for (int i = 0; i < 100; i++) { // k = 100 + i; // k = 100 - i; // k = 100 * i; // k = i << 1; // k = - i; // } BuildLoopNest(1); HInstruction *add = InsertInstruction( new (&allocator_) HAdd(Primitive::kPrimInt, constant100_, basic_[0]), 0); HInstruction *sub = InsertInstruction( new (&allocator_) HSub(Primitive::kPrimInt, constant100_, basic_[0]), 0); HInstruction *mul = InsertInstruction( new (&allocator_) HMul(Primitive::kPrimInt, constant100_, basic_[0]), 0); HInstruction *shl = InsertInstruction( new (&allocator_) HShl(Primitive::kPrimInt, basic_[0], constant1_), 0); HInstruction *neg = InsertInstruction( new (&allocator_) HNeg(Primitive::kPrimInt, basic_[0]), 0); PerformInductionVarAnalysis(); EXPECT_STREQ("((1) * i + (100)):PrimInt", GetInductionInfo(add, 0).c_str()); EXPECT_STREQ("(( - (1)) * i + (100)):PrimInt", GetInductionInfo(sub, 0).c_str()); EXPECT_STREQ("((100) * i + (0)):PrimInt", GetInductionInfo(mul, 0).c_str()); EXPECT_STREQ("((2) * i + (0)):PrimInt", GetInductionInfo(shl, 0).c_str()); EXPECT_STREQ("(( - (1)) * i + (0)):PrimInt", GetInductionInfo(neg, 0).c_str()); } TEST_F(InductionVarAnalysisTest, FindChainInduction) { // Setup: // k = 0; // for (int i = 0; i < 100; i++) { // k = k + 100; // a[k] = 0; // k = k - 1; // a[k] = 0; // } BuildLoopNest(1); HPhi* k = InsertLoopPhi(0, 0); k->AddInput(constant0_); HInstruction *add = InsertInstruction( new (&allocator_) HAdd(Primitive::kPrimInt, k, constant100_), 0); HInstruction* store1 = InsertArrayStore(add, 0); HInstruction *sub = InsertInstruction( new (&allocator_) HSub(Primitive::kPrimInt, add, constant1_), 0); HInstruction* store2 = InsertArrayStore(sub, 0); k->AddInput(sub); PerformInductionVarAnalysis(); EXPECT_STREQ("(((100) - (1)) * i + (100)):PrimInt", GetInductionInfo(store1->InputAt(1), 0).c_str()); EXPECT_STREQ("(((100) - (1)) * i + ((100) - (1))):PrimInt", GetInductionInfo(store2->InputAt(1), 0).c_str()); } TEST_F(InductionVarAnalysisTest, FindTwoWayBasicInduction) { // Setup: // k = 0; // for (int i = 0; i < 100; i++) { // if () k = k + 1; // else k = k + 1; // a[k] = 0; // } BuildLoopNest(1); HPhi* k_header = InsertLoopPhi(0, 0); k_header->AddInput(constant0_); HBasicBlock* ifTrue; HBasicBlock* ifFalse; HPhi* k_body = BuildIf(0, &ifTrue, &ifFalse); // True-branch. HInstruction* inc1 = new (&allocator_) HAdd(Primitive::kPrimInt, k_header, constant1_); ifTrue->AddInstruction(inc1); k_body->AddInput(inc1); // False-branch. HInstruction* inc2 = new (&allocator_) HAdd(Primitive::kPrimInt, k_header, constant1_); ifFalse->AddInstruction(inc2); k_body->AddInput(inc2); // Merge over a phi. HInstruction* store = InsertArrayStore(k_body, 0); k_header->AddInput(k_body); PerformInductionVarAnalysis(); EXPECT_STREQ("((1) * i + (1)):PrimInt", GetInductionInfo(store->InputAt(1), 0).c_str()); // Both increments get same induction. EXPECT_TRUE(HaveSameInduction(store->InputAt(1), inc1)); EXPECT_TRUE(HaveSameInduction(store->InputAt(1), inc2)); } TEST_F(InductionVarAnalysisTest, FindTwoWayDerivedInduction) { // Setup: // for (int i = 0; i < 100; i++) { // if () k = i + 1; // else k = i + 1; // a[k] = 0; // } BuildLoopNest(1); HBasicBlock* ifTrue; HBasicBlock* ifFalse; HPhi* k = BuildIf(0, &ifTrue, &ifFalse); // True-branch. HInstruction* inc1 = new (&allocator_) HAdd(Primitive::kPrimInt, basic_[0], constant1_); ifTrue->AddInstruction(inc1); k->AddInput(inc1); // False-branch. HInstruction* inc2 = new (&allocator_) HAdd(Primitive::kPrimInt, basic_[0], constant1_); ifFalse->AddInstruction(inc2); k->AddInput(inc2); // Merge over a phi. HInstruction* store = InsertArrayStore(k, 0); PerformInductionVarAnalysis(); EXPECT_STREQ("((1) * i + (1)):PrimInt", GetInductionInfo(store->InputAt(1), 0).c_str()); } TEST_F(InductionVarAnalysisTest, FindFirstOrderWrapAroundInduction) { // Setup: // k = 0; // for (int i = 0; i < 100; i++) { // a[k] = 0; // k = 100 - i; // } BuildLoopNest(1); HPhi* k = InsertLoopPhi(0, 0); k->AddInput(constant0_); HInstruction* store = InsertArrayStore(k, 0); HInstruction *sub = InsertInstruction( new (&allocator_) HSub(Primitive::kPrimInt, constant100_, basic_[0]), 0); k->AddInput(sub); PerformInductionVarAnalysis(); EXPECT_STREQ("wrap((0), (( - (1)) * i + (100)):PrimInt):PrimInt", GetInductionInfo(store->InputAt(1), 0).c_str()); } TEST_F(InductionVarAnalysisTest, FindSecondOrderWrapAroundInduction) { // Setup: // k = 0; // t = 100; // for (int i = 0; i < 100; i++) { // a[k] = 0; // k = t; // t = 100 - i; // } BuildLoopNest(1); HPhi* k = InsertLoopPhi(0, 0); k->AddInput(constant0_); HPhi* t = InsertLoopPhi(1, 0); t->AddInput(constant100_); HInstruction* store = InsertArrayStore(k, 0); k->AddInput(t); HInstruction *sub = InsertInstruction( new (&allocator_) HSub(Primitive::kPrimInt, constant100_, basic_[0], 0), 0); t->AddInput(sub); PerformInductionVarAnalysis(); EXPECT_STREQ("wrap((0), wrap((100), (( - (1)) * i + (100)):PrimInt):PrimInt):PrimInt", GetInductionInfo(store->InputAt(1), 0).c_str()); } TEST_F(InductionVarAnalysisTest, FindWrapAroundDerivedInduction) { // Setup: // k = 0; // for (int i = 0; i < 100; i++) { // t = k + 100; // t = k - 100; // t = k * 100; // t = k << 1; // t = - k; // k = i << 1; // } BuildLoopNest(1); HPhi* k = InsertLoopPhi(0, 0); k->AddInput(constant0_); HInstruction *add = InsertInstruction( new (&allocator_) HAdd(Primitive::kPrimInt, k, constant100_), 0); HInstruction *sub = InsertInstruction( new (&allocator_) HSub(Primitive::kPrimInt, k, constant100_), 0); HInstruction *mul = InsertInstruction( new (&allocator_) HMul(Primitive::kPrimInt, k, constant100_), 0); HInstruction *shl = InsertInstruction( new (&allocator_) HShl(Primitive::kPrimInt, k, constant1_), 0); HInstruction *neg = InsertInstruction( new (&allocator_) HNeg(Primitive::kPrimInt, k), 0); k->AddInput( InsertInstruction(new (&allocator_) HShl(Primitive::kPrimInt, basic_[0], constant1_), 0)); PerformInductionVarAnalysis(); EXPECT_STREQ("wrap((100), ((2) * i + (100)):PrimInt):PrimInt", GetInductionInfo(add, 0).c_str()); EXPECT_STREQ("wrap(((0) - (100)), ((2) * i + ((0) - (100))):PrimInt):PrimInt", GetInductionInfo(sub, 0).c_str()); EXPECT_STREQ("wrap((0), (((2) * (100)) * i + (0)):PrimInt):PrimInt", GetInductionInfo(mul, 0).c_str()); EXPECT_STREQ("wrap((0), (((2) * (2)) * i + (0)):PrimInt):PrimInt", GetInductionInfo(shl, 0).c_str()); EXPECT_STREQ("wrap((0), (( - (2)) * i + (0)):PrimInt):PrimInt", GetInductionInfo(neg, 0).c_str()); } TEST_F(InductionVarAnalysisTest, FindPeriodicInduction) { // Setup: // k = 0; // t = 100; // for (int i = 0; i < 100; i++) { // a[k] = 0; // a[t] = 0; // // Swap t <-> k. // d = t; // t = k; // k = d; // } BuildLoopNest(1); HPhi* k = InsertLoopPhi(0, 0); k->AddInput(constant0_); HPhi* t = InsertLoopPhi(1, 0); t->AddInput(constant100_); HInstruction* store1 = InsertArrayStore(k, 0); HInstruction* store2 = InsertArrayStore(t, 0); k->AddInput(t); t->AddInput(k); PerformInductionVarAnalysis(); EXPECT_STREQ("periodic((0), (100)):PrimInt", GetInductionInfo(store1->InputAt(1), 0).c_str()); EXPECT_STREQ("periodic((100), (0)):PrimInt", GetInductionInfo(store2->InputAt(1), 0).c_str()); } TEST_F(InductionVarAnalysisTest, FindIdiomaticPeriodicInduction) { // Setup: // k = 0; // for (int i = 0; i < 100; i++) { // a[k] = 0; // k = 1 - k; // } BuildLoopNest(1); HPhi* k = InsertLoopPhi(0, 0); k->AddInput(constant0_); HInstruction* store = InsertArrayStore(k, 0); HInstruction *sub = InsertInstruction( new (&allocator_) HSub(Primitive::kPrimInt, constant1_, k), 0); k->AddInput(sub); PerformInductionVarAnalysis(); EXPECT_STREQ("periodic((0), (1)):PrimInt", GetInductionInfo(store->InputAt(1), 0).c_str()); EXPECT_STREQ("periodic((1), (0)):PrimInt", GetInductionInfo(sub, 0).c_str()); } TEST_F(InductionVarAnalysisTest, FindDerivedPeriodicInduction) { // Setup: // k = 0; // for (int i = 0; i < 100; i++) { // k = 1 - k; // t = k + 100; // t = k - 100; // t = k * 100; // t = k << 1; // t = - k; // } BuildLoopNest(1); HPhi* k_header = InsertLoopPhi(0, 0); k_header->AddInput(constant0_); HInstruction* k_body = InsertInstruction( new (&allocator_) HSub(Primitive::kPrimInt, constant1_, k_header), 0); k_header->AddInput(k_body); // Derived expressions. HInstruction *add = InsertInstruction( new (&allocator_) HAdd(Primitive::kPrimInt, k_body, constant100_), 0); HInstruction *sub = InsertInstruction( new (&allocator_) HSub(Primitive::kPrimInt, k_body, constant100_), 0); HInstruction *mul = InsertInstruction( new (&allocator_) HMul(Primitive::kPrimInt, k_body, constant100_), 0); HInstruction *shl = InsertInstruction( new (&allocator_) HShl(Primitive::kPrimInt, k_body, constant1_), 0); HInstruction *neg = InsertInstruction( new (&allocator_) HNeg(Primitive::kPrimInt, k_body), 0); PerformInductionVarAnalysis(); EXPECT_STREQ("periodic(((1) + (100)), (100)):PrimInt", GetInductionInfo(add, 0).c_str()); EXPECT_STREQ("periodic(((1) - (100)), ((0) - (100))):PrimInt", GetInductionInfo(sub, 0).c_str()); EXPECT_STREQ("periodic((100), (0)):PrimInt", GetInductionInfo(mul, 0).c_str()); EXPECT_STREQ("periodic((2), (0)):PrimInt", GetInductionInfo(shl, 0).c_str()); EXPECT_STREQ("periodic(( - (1)), (0)):PrimInt", GetInductionInfo(neg, 0).c_str()); } TEST_F(InductionVarAnalysisTest, FindDeepLoopInduction) { // Setup: // k = 0; // for (int i_0 = 0; i_0 < 100; i_0++) { // .. // for (int i_9 = 0; i_9 < 100; i_9++) { // k = 1 + k; // a[k] = 0; // } // .. // } BuildLoopNest(10); HPhi* k[10]; for (int d = 0; d < 10; d++) { k[d] = InsertLoopPhi(0, d); } HInstruction *inc = InsertInstruction( new (&allocator_) HAdd(Primitive::kPrimInt, constant1_, k[9]), 9); HInstruction* store = InsertArrayStore(inc, 9); for (int d = 0; d < 10; d++) { k[d]->AddInput((d != 0) ? k[d - 1] : constant0_); k[d]->AddInput((d != 9) ? k[d + 1] : inc); } PerformInductionVarAnalysis(); // Avoid exact phi number, since that depends on the SSA building phase. std::regex r("\\(\\(1\\) \\* i \\+ " "\\(\\(1\\) \\+ \\(\\d+:Phi\\)\\)\\):PrimInt"); for (int d = 0; d < 10; d++) { if (d == 9) { EXPECT_TRUE(std::regex_match(GetInductionInfo(store->InputAt(1), d), r)); } else { EXPECT_STREQ("", GetInductionInfo(store->InputAt(1), d).c_str()); } EXPECT_STREQ("((1) * i + (1)):PrimInt", GetInductionInfo(increment_[d], d).c_str()); // Trip-count. EXPECT_STREQ("((100) (TC-loop) ((0) < (100)))", GetInductionInfo(loop_header_[d]->GetLastInstruction(), d).c_str()); } } TEST_F(InductionVarAnalysisTest, ByteInductionIntLoopControl) { // Setup: // for (int i = 0; i < 100; i++) { // k = (byte) i; // a[k] = 0; // a[i] = 0; // } BuildLoopNest(1); HInstruction *conv = InsertInstruction( new (&allocator_) HTypeConversion(Primitive::kPrimByte, basic_[0], -1), 0); HInstruction* store1 = InsertArrayStore(conv, 0); HInstruction* store2 = InsertArrayStore(basic_[0], 0); PerformInductionVarAnalysis(); // Regular int induction (i) is "transferred" over conversion into byte induction (k). EXPECT_STREQ("((1) * i + (0)):PrimByte", GetInductionInfo(store1->InputAt(1), 0).c_str()); EXPECT_STREQ("((1) * i + (0)):PrimInt", GetInductionInfo(store2->InputAt(1), 0).c_str()); EXPECT_STREQ("((1) * i + (1)):PrimInt", GetInductionInfo(increment_[0], 0).c_str()); // Type matters! EXPECT_FALSE(HaveSameInduction(store1->InputAt(1), store2->InputAt(1))); // Trip-count. EXPECT_STREQ("((100) (TC-loop) ((0) < (100)))", GetInductionInfo(loop_header_[0]->GetLastInstruction(), 0).c_str()); } TEST_F(InductionVarAnalysisTest, ByteLoopControl1) { // Setup: // for (byte i = -128; i < 127; i++) { // just fits! // } BuildLoopNest(1); basic_[0]->ReplaceInput(graph_->GetIntConstant(-128), 0); HInstruction* ifs = loop_header_[0]->GetLastInstruction()->GetPrevious(); ifs->ReplaceInput(graph_->GetIntConstant(127), 1); HInstruction* conv = new(&allocator_) HTypeConversion(Primitive::kPrimByte, increment_[0], -1); loop_body_[0]->InsertInstructionBefore(conv, increment_[0]->GetNext()); basic_[0]->ReplaceInput(conv, 1); PerformInductionVarAnalysis(); EXPECT_STREQ("((1) * i + ((-128) + (1))):PrimByte", GetInductionInfo(increment_[0], 0).c_str()); // Trip-count. EXPECT_STREQ("(((127) - (-128)) (TC-loop) ((-128) < (127)))", GetInductionInfo(loop_header_[0]->GetLastInstruction(), 0).c_str()); } TEST_F(InductionVarAnalysisTest, ByteLoopControl2) { // Setup: // for (byte i = -128; i < 128; i++) { // infinite loop! // } BuildLoopNest(1); basic_[0]->ReplaceInput(graph_->GetIntConstant(-128), 0); HInstruction* ifs = loop_header_[0]->GetLastInstruction()->GetPrevious(); ifs->ReplaceInput(graph_->GetIntConstant(128), 1); HInstruction* conv = new(&allocator_) HTypeConversion(Primitive::kPrimByte, increment_[0], -1); loop_body_[0]->InsertInstructionBefore(conv, increment_[0]->GetNext()); basic_[0]->ReplaceInput(conv, 1); PerformInductionVarAnalysis(); EXPECT_STREQ("((1) * i + ((-128) + (1))):PrimByte", GetInductionInfo(increment_[0], 0).c_str()); // Trip-count undefined. EXPECT_STREQ("", GetInductionInfo(loop_header_[0]->GetLastInstruction(), 0).c_str()); } TEST_F(InductionVarAnalysisTest, ShortLoopControl1) { // Setup: // for (short i = -32768; i < 32767; i++) { // just fits! // } BuildLoopNest(1); basic_[0]->ReplaceInput(graph_->GetIntConstant(-32768), 0); HInstruction* ifs = loop_header_[0]->GetLastInstruction()->GetPrevious(); ifs->ReplaceInput(graph_->GetIntConstant(32767), 1); HInstruction* conv = new(&allocator_) HTypeConversion(Primitive::kPrimShort, increment_[0], -1); loop_body_[0]->InsertInstructionBefore(conv, increment_[0]->GetNext()); basic_[0]->ReplaceInput(conv, 1); PerformInductionVarAnalysis(); EXPECT_STREQ("((1) * i + ((-32768) + (1))):PrimShort", GetInductionInfo(increment_[0], 0).c_str()); // Trip-count. EXPECT_STREQ("(((32767) - (-32768)) (TC-loop) ((-32768) < (32767)))", GetInductionInfo(loop_header_[0]->GetLastInstruction(), 0).c_str()); } TEST_F(InductionVarAnalysisTest, ShortLoopControl2) { // Setup: // for (short i = -32768; i < 32768; i++) { // infinite loop! // } BuildLoopNest(1); basic_[0]->ReplaceInput(graph_->GetIntConstant(-32768), 0); HInstruction* ifs = loop_header_[0]->GetLastInstruction()->GetPrevious(); ifs->ReplaceInput(graph_->GetIntConstant(32768), 1); HInstruction* conv = new(&allocator_) HTypeConversion(Primitive::kPrimShort, increment_[0], -1); loop_body_[0]->InsertInstructionBefore(conv, increment_[0]->GetNext()); basic_[0]->ReplaceInput(conv, 1); PerformInductionVarAnalysis(); EXPECT_STREQ("((1) * i + ((-32768) + (1))):PrimShort", GetInductionInfo(increment_[0], 0).c_str()); // Trip-count undefined. EXPECT_STREQ("", GetInductionInfo(loop_header_[0]->GetLastInstruction(), 0).c_str()); } TEST_F(InductionVarAnalysisTest, CharLoopControl1) { // Setup: // for (char i = 0; i < 65535; i++) { // just fits! // } BuildLoopNest(1); HInstruction* ifs = loop_header_[0]->GetLastInstruction()->GetPrevious(); ifs->ReplaceInput(graph_->GetIntConstant(65535), 1); HInstruction* conv = new(&allocator_) HTypeConversion(Primitive::kPrimChar, increment_[0], -1); loop_body_[0]->InsertInstructionBefore(conv, increment_[0]->GetNext()); basic_[0]->ReplaceInput(conv, 1); PerformInductionVarAnalysis(); EXPECT_STREQ("((1) * i + (1)):PrimChar", GetInductionInfo(increment_[0], 0).c_str()); // Trip-count. EXPECT_STREQ("((65535) (TC-loop) ((0) < (65535)))", GetInductionInfo(loop_header_[0]->GetLastInstruction(), 0).c_str()); } TEST_F(InductionVarAnalysisTest, CharLoopControl2) { // Setup: // for (char i = 0; i < 65536; i++) { // infinite loop! // } BuildLoopNest(1); HInstruction* ifs = loop_header_[0]->GetLastInstruction()->GetPrevious(); ifs->ReplaceInput(graph_->GetIntConstant(65536), 1); HInstruction* conv = new(&allocator_) HTypeConversion(Primitive::kPrimChar, increment_[0], -1); loop_body_[0]->InsertInstructionBefore(conv, increment_[0]->GetNext()); basic_[0]->ReplaceInput(conv, 1); PerformInductionVarAnalysis(); EXPECT_STREQ("((1) * i + (1)):PrimChar", GetInductionInfo(increment_[0], 0).c_str()); // Trip-count undefined. EXPECT_STREQ("", GetInductionInfo(loop_header_[0]->GetLastInstruction(), 0).c_str()); } } // namespace art