// 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/codegen/source-position.h" #include "src/compiler/backend/instruction-codes.h" #include "src/compiler/backend/instruction.h" #include "src/compiler/backend/jump-threading.h" #include "test/cctest/cctest.h" namespace v8 { namespace internal { namespace compiler { class TestCode : public HandleAndZoneScope { public: explicit TestCode(size_t block_count) : HandleAndZoneScope(), blocks_(main_zone()), sequence_(main_isolate(), main_zone(), &blocks_), rpo_number_(RpoNumber::FromInt(0)), current_(nullptr) { sequence_.IncreaseRpoForTesting(block_count); } ZoneVector blocks_; InstructionSequence sequence_; RpoNumber rpo_number_; InstructionBlock* current_; int Jump(int target) { Start(); InstructionOperand ops[] = {UseRpo(target)}; sequence_.AddInstruction(Instruction::New(main_zone(), kArchJmp, 0, nullptr, 1, ops, 0, nullptr)); int pos = static_cast(sequence_.instructions().size() - 1); End(); return pos; } void Fallthru() { Start(); End(); } int Branch(int ttarget, int ftarget) { Start(); InstructionOperand ops[] = {UseRpo(ttarget), UseRpo(ftarget)}; InstructionCode code = 119 | FlagsModeField::encode(kFlags_branch) | FlagsConditionField::encode(kEqual); sequence_.AddInstruction( Instruction::New(main_zone(), code, 0, nullptr, 2, ops, 0, nullptr)); int pos = static_cast(sequence_.instructions().size() - 1); End(); return pos; } int Return(int size, bool defer = false, bool deconstruct_frame = false) { Start(defer, deconstruct_frame); InstructionOperand ops[] = {Immediate(size)}; sequence_.AddInstruction(Instruction::New(main_zone(), kArchRet, 0, nullptr, 1, ops, 0, nullptr)); int pos = static_cast(sequence_.instructions().size() - 1); End(); return pos; } void Nop() { Start(); sequence_.AddInstruction(Instruction::New(main_zone(), kArchNop)); } void RedundantMoves() { Start(); sequence_.AddInstruction(Instruction::New(main_zone(), kArchNop)); int index = static_cast(sequence_.instructions().size()) - 1; AddGapMove(index, AllocatedOperand(LocationOperand::REGISTER, MachineRepresentation::kWord32, 13), AllocatedOperand(LocationOperand::REGISTER, MachineRepresentation::kWord32, 13)); } void NonRedundantMoves() { Start(); sequence_.AddInstruction(Instruction::New(main_zone(), kArchNop)); int index = static_cast(sequence_.instructions().size()) - 1; AddGapMove(index, ConstantOperand(11), AllocatedOperand(LocationOperand::REGISTER, MachineRepresentation::kWord32, 11)); } int JumpWithGapMove(int target, int id = 10) { Start(); InstructionOperand ops[] = {UseRpo(target)}; sequence_.AddInstruction(Instruction::New(main_zone(), kArchJmp, 0, nullptr, 1, ops, 0, nullptr)); int index = static_cast(sequence_.instructions().size()) - 1; InstructionOperand from = AllocatedOperand( LocationOperand::REGISTER, MachineRepresentation::kWord32, id); InstructionOperand to = AllocatedOperand( LocationOperand::REGISTER, MachineRepresentation::kWord32, id + 1); AddGapMove(index, from, to); End(); return index; } void Other() { Start(); sequence_.AddInstruction(Instruction::New(main_zone(), 155)); } void End() { Start(); int end = static_cast(sequence_.instructions().size()); if (current_->code_start() == end) { // Empty block. Insert a nop. sequence_.AddInstruction(Instruction::New(main_zone(), kArchNop)); } sequence_.EndBlock(current_->rpo_number()); current_ = nullptr; rpo_number_ = RpoNumber::FromInt(rpo_number_.ToInt() + 1); } InstructionOperand UseRpo(int num) { return sequence_.AddImmediate(Constant(RpoNumber::FromInt(num))); } InstructionOperand Immediate(int num) { return sequence_.AddImmediate(Constant(num)); } void Start(bool deferred = false, bool deconstruct_frame = false) { if (current_ == nullptr) { current_ = main_zone()->New( main_zone(), rpo_number_, RpoNumber::Invalid(), RpoNumber::Invalid(), RpoNumber::Invalid(), deferred, false); if (deconstruct_frame) { current_->mark_must_deconstruct_frame(); } blocks_.push_back(current_); sequence_.StartBlock(rpo_number_); } } void Defer() { CHECK_NULL(current_); Start(true); } void AddGapMove(int index, const InstructionOperand& from, const InstructionOperand& to) { sequence_.InstructionAt(index) ->GetOrCreateParallelMove(Instruction::START, main_zone()) ->AddMove(from, to); } }; void VerifyForwarding(TestCode* code, int count, int* expected) { v8::internal::AccountingAllocator allocator; Zone local_zone(&allocator, ZONE_NAME); ZoneVector result(&local_zone); JumpThreading::ComputeForwarding(&local_zone, &result, &code->sequence_, true); CHECK(count == static_cast(result.size())); for (int i = 0; i < count; i++) { CHECK_EQ(expected[i], result[i].ToInt()); } } TEST(FwEmpty1) { constexpr size_t kBlockCount = 3; TestCode code(kBlockCount); // B0 code.Jump(1); // B1 code.Jump(2); // B2 code.End(); static int expected[] = {2, 2, 2}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwEmptyN) { constexpr size_t kBlockCount = 3; for (int i = 0; i < 9; i++) { TestCode code(kBlockCount); // B0 code.Jump(1); // B1 for (int j = 0; j < i; j++) code.Nop(); code.Jump(2); // B2 code.End(); static int expected[] = {2, 2, 2}; VerifyForwarding(&code, kBlockCount, expected); } } TEST(FwNone1) { constexpr size_t kBlockCount = 1; TestCode code(kBlockCount); // B0 code.End(); static int expected[] = {0}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwMoves1) { constexpr size_t kBlockCount = 1; TestCode code(kBlockCount); // B0 code.RedundantMoves(); code.End(); static int expected[] = {0}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwMoves2) { constexpr size_t kBlockCount = 2; TestCode code(kBlockCount); // B0 code.RedundantMoves(); code.Fallthru(); // B1 code.End(); static int expected[] = {1, 1}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwMoves2b) { constexpr size_t kBlockCount = 2; TestCode code(kBlockCount); // B0 code.NonRedundantMoves(); code.Fallthru(); // B1 code.End(); static int expected[] = {0, 1}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwMoves3a) { constexpr size_t kBlockCount = 4; TestCode code(kBlockCount); // B0 code.JumpWithGapMove(3, 10); // B1 (merge B1 into B0, because they have the same gap moves.) code.JumpWithGapMove(3, 10); // B2 (can not merge B2 into B0, because they have different gap moves.) code.JumpWithGapMove(3, 11); // B3 code.End(); static int expected[] = {0, 0, 2, 3}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwMoves3b) { constexpr size_t kBlockCount = 7; TestCode code(kBlockCount); // B0 code.JumpWithGapMove(6); // B1 code.Jump(2); // B2 code.Jump(3); // B3 code.JumpWithGapMove(6); // B4 code.Jump(3); // B5 code.Jump(2); // B6 code.End(); static int expected[] = {0, 0, 0, 0, 0, 0, 6}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwOther2) { constexpr size_t kBlockCount = 2; TestCode code(kBlockCount); // B0 code.Other(); code.Fallthru(); // B1 code.End(); static int expected[] = {0, 1}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwNone2a) { constexpr size_t kBlockCount = 2; TestCode code(kBlockCount); // B0 code.Fallthru(); // B1 code.End(); static int expected[] = {1, 1}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwNone2b) { constexpr size_t kBlockCount = 2; TestCode code(kBlockCount); // B0 code.Jump(1); // B1 code.End(); static int expected[] = {1, 1}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwLoop1) { constexpr size_t kBlockCount = 1; TestCode code(kBlockCount); // B0 code.Jump(0); static int expected[] = {0}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwLoop2) { constexpr size_t kBlockCount = 2; TestCode code(kBlockCount); // B0 code.Fallthru(); // B1 code.Jump(0); static int expected[] = {0, 0}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwLoop3) { constexpr size_t kBlockCount = 3; TestCode code(kBlockCount); // B0 code.Fallthru(); // B1 code.Fallthru(); // B2 code.Jump(0); static int expected[] = {0, 0, 0}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwLoop1b) { constexpr size_t kBlockCount = 2; TestCode code(kBlockCount); // B0 code.Fallthru(); // B1 code.Jump(1); static int expected[] = {1, 1}; VerifyForwarding(&code, 2, expected); } TEST(FwLoop2b) { constexpr size_t kBlockCount = 3; TestCode code(kBlockCount); // B0 code.Fallthru(); // B1 code.Fallthru(); // B2 code.Jump(1); static int expected[] = {1, 1, 1}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwLoop3b) { constexpr size_t kBlockCount = 4; TestCode code(kBlockCount); // B0 code.Fallthru(); // B1 code.Fallthru(); // B2 code.Fallthru(); // B3 code.Jump(1); static int expected[] = {1, 1, 1, 1}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwLoop2_1a) { constexpr size_t kBlockCount = 5; TestCode code(kBlockCount); // B0 code.Fallthru(); // B1 code.Fallthru(); // B2 code.Fallthru(); // B3 code.Jump(1); // B4 code.Jump(2); static int expected[] = {1, 1, 1, 1, 1}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwLoop2_1b) { constexpr size_t kBlockCount = 5; TestCode code(kBlockCount); // B0 code.Fallthru(); // B1 code.Fallthru(); // B2 code.Jump(4); // B3 code.Jump(1); // B4 code.Jump(2); static int expected[] = {2, 2, 2, 2, 2}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwLoop2_1c) { constexpr size_t kBlockCount = 5; TestCode code(kBlockCount); // B0 code.Fallthru(); // B1 code.Fallthru(); // B2 code.Jump(4); // B3 code.Jump(2); // B4 code.Jump(1); static int expected[] = {1, 1, 1, 1, 1}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwLoop2_1d) { constexpr size_t kBlockCount = 5; TestCode code(kBlockCount); // B0 code.Fallthru(); // B1 code.Fallthru(); // B2 code.Jump(1); // B3 code.Jump(1); // B4 code.Jump(1); static int expected[] = {1, 1, 1, 1, 1}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwLoop3_1a) { constexpr size_t kBlockCount = 6; TestCode code(kBlockCount); // B0 code.Fallthru(); // B1 code.Fallthru(); // B2 code.Fallthru(); // B3 code.Jump(2); // B4 code.Jump(1); // B5 code.Jump(0); static int expected[] = {2, 2, 2, 2, 2, 2}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwLoop4a) { constexpr size_t kBlockCount = 2; TestCode code(kBlockCount); // B0 code.JumpWithGapMove(1); // B1 code.JumpWithGapMove(0); static int expected[] = {0, 1}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwLoop4b) { constexpr size_t kBlockCount = 4; TestCode code(kBlockCount); // B0 code.Jump(3); // B1 code.JumpWithGapMove(2); // B2 code.Jump(0); // B3 code.JumpWithGapMove(2); static int expected[] = {3, 3, 3, 3}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwDiamonds) { constexpr size_t kBlockCount = 4; for (int i = 0; i < 2; i++) { for (int j = 0; j < 2; j++) { TestCode code(kBlockCount); // B0 code.Branch(1, 2); // B1 if (i) code.Other(); code.Jump(3); // B2 if (j) code.Other(); code.Jump(3); // B3 code.End(); int expected[] = {0, i ? 1 : 3, j ? 2 : 3, 3}; VerifyForwarding(&code, kBlockCount, expected); } } } TEST(FwDiamonds2) { constexpr size_t kBlockCount = 5; for (int i = 0; i < 2; i++) { for (int j = 0; j < 2; j++) { for (int k = 0; k < 2; k++) { TestCode code(kBlockCount); // B0 code.Branch(1, 2); // B1 if (i) code.Other(); code.Jump(3); // B2 if (j) code.Other(); code.Jump(3); // B3 if (k) code.NonRedundantMoves(); code.Jump(4); // B4 code.End(); int merge = k ? 3 : 4; int expected[] = {0, i ? 1 : merge, j ? 2 : merge, merge, 4}; VerifyForwarding(&code, kBlockCount, expected); } } } } TEST(FwDoubleDiamonds) { constexpr size_t kBlockCount = 7; for (int i = 0; i < 2; i++) { for (int j = 0; j < 2; j++) { for (int x = 0; x < 2; x++) { for (int y = 0; y < 2; y++) { TestCode code(kBlockCount); // B0 code.Branch(1, 2); // B1 if (i) code.Other(); code.Jump(3); // B2 if (j) code.Other(); code.Jump(3); // B3 code.Branch(4, 5); // B4 if (x) code.Other(); code.Jump(6); // B5 if (y) code.Other(); code.Jump(6); // B6 code.End(); int expected[] = {0, i ? 1 : 3, j ? 2 : 3, 3, x ? 4 : 6, y ? 5 : 6, 6}; VerifyForwarding(&code, kBlockCount, expected); } } } } } template void RunPermutationsRecursive(int outer[kSize], int start, void (*run)(int*, int)) { int permutation[kSize]; for (int i = 0; i < kSize; i++) permutation[i] = outer[i]; int count = kSize - start; if (count == 0) return run(permutation, kSize); for (int i = start; i < kSize; i++) { permutation[start] = outer[i]; permutation[i] = outer[start]; RunPermutationsRecursive(permutation, start + 1, run); permutation[i] = outer[i]; permutation[start] = outer[start]; } } template void RunAllPermutations(void (*run)(int*, int)) { int permutation[kSize]; for (int i = 0; i < kSize; i++) permutation[i] = i; RunPermutationsRecursive(permutation, 0, run); } void PrintPermutation(int* permutation, int size) { printf("{ "); for (int i = 0; i < size; i++) { if (i > 0) printf(", "); printf("%d", permutation[i]); } printf(" }\n"); } int find(int x, int* permutation, int size) { for (int i = 0; i < size; i++) { if (permutation[i] == x) return i; } return size; } void RunPermutedChain(int* permutation, int size) { const int kBlockCount = size + 2; TestCode code(kBlockCount); int cur = -1; for (int i = 0; i < size; i++) { code.Jump(find(cur + 1, permutation, size) + 1); cur = permutation[i]; } code.Jump(find(cur + 1, permutation, size) + 1); code.End(); int expected[] = {size + 1, size + 1, size + 1, size + 1, size + 1, size + 1, size + 1}; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwPermuted_chain) { RunAllPermutations<3>(RunPermutedChain); RunAllPermutations<4>(RunPermutedChain); RunAllPermutations<5>(RunPermutedChain); } void RunPermutedDiamond(int* permutation, int size) { constexpr size_t kBlockCount = 6; TestCode code(kBlockCount); int br = 1 + find(0, permutation, size); code.Jump(br); for (int i = 0; i < size; i++) { switch (permutation[i]) { case 0: code.Branch(1 + find(1, permutation, size), 1 + find(2, permutation, size)); break; case 1: code.Jump(1 + find(3, permutation, size)); break; case 2: code.Jump(1 + find(3, permutation, size)); break; case 3: code.Jump(5); break; } } code.End(); int expected[] = {br, 5, 5, 5, 5, 5}; expected[br] = br; VerifyForwarding(&code, kBlockCount, expected); } TEST(FwPermuted_diamond) { RunAllPermutations<4>(RunPermutedDiamond); } void ApplyForwarding(TestCode* code, int size, int* forward) { code->sequence_.RecomputeAssemblyOrderForTesting(); ZoneVector vector(code->main_zone()); for (int i = 0; i < size; i++) { vector.push_back(RpoNumber::FromInt(forward[i])); } JumpThreading::ApplyForwarding(code->main_zone(), vector, &code->sequence_); } void CheckJump(TestCode* code, int pos, int target) { Instruction* instr = code->sequence_.InstructionAt(pos); CHECK_EQ(kArchJmp, instr->arch_opcode()); CHECK_EQ(1, static_cast(instr->InputCount())); CHECK_EQ(0, static_cast(instr->OutputCount())); CHECK_EQ(0, static_cast(instr->TempCount())); CHECK_EQ(target, code->sequence_.InputRpo(instr, 0).ToInt()); } void CheckRet(TestCode* code, int pos) { Instruction* instr = code->sequence_.InstructionAt(pos); CHECK_EQ(kArchRet, instr->arch_opcode()); CHECK_EQ(1, static_cast(instr->InputCount())); CHECK_EQ(0, static_cast(instr->OutputCount())); CHECK_EQ(0, static_cast(instr->TempCount())); } void CheckNop(TestCode* code, int pos) { Instruction* instr = code->sequence_.InstructionAt(pos); CHECK_EQ(kArchNop, instr->arch_opcode()); CHECK_EQ(0, static_cast(instr->InputCount())); CHECK_EQ(0, static_cast(instr->OutputCount())); CHECK_EQ(0, static_cast(instr->TempCount())); } void CheckBranch(TestCode* code, int pos, int t1, int t2) { Instruction* instr = code->sequence_.InstructionAt(pos); CHECK_EQ(2, static_cast(instr->InputCount())); CHECK_EQ(0, static_cast(instr->OutputCount())); CHECK_EQ(0, static_cast(instr->TempCount())); CHECK_EQ(t1, code->sequence_.InputRpo(instr, 0).ToInt()); CHECK_EQ(t2, code->sequence_.InputRpo(instr, 1).ToInt()); } void CheckAssemblyOrder(TestCode* code, int size, int* expected) { int i = 0; for (auto const block : code->sequence_.instruction_blocks()) { CHECK_EQ(expected[i++], block->ao_number().ToInt()); } } TEST(Rewire1) { constexpr size_t kBlockCount = 3; TestCode code(kBlockCount); // B0 int j1 = code.Jump(1); // B1 int j2 = code.Jump(2); // B2 code.End(); static int forward[] = {2, 2, 2}; ApplyForwarding(&code, kBlockCount, forward); CheckJump(&code, j1, 2); CheckNop(&code, j2); static int assembly[] = {0, 1, 1}; CheckAssemblyOrder(&code, kBlockCount, assembly); } TEST(Rewire1_deferred) { constexpr size_t kBlockCount = 4; TestCode code(kBlockCount); // B0 int j1 = code.Jump(1); // B1 int j2 = code.Jump(2); // B2 code.Defer(); int j3 = code.Jump(3); // B3 code.Return(0); static int forward[] = {3, 3, 3, 3}; ApplyForwarding(&code, kBlockCount, forward); CheckJump(&code, j1, 3); CheckNop(&code, j2); CheckNop(&code, j3); static int assembly[] = {0, 1, 2, 1}; CheckAssemblyOrder(&code, kBlockCount, assembly); } TEST(Rewire2_deferred) { constexpr size_t kBlockCount = 4; TestCode code(kBlockCount); // B0 code.Other(); int j1 = code.Jump(1); // B1 code.Defer(); code.Fallthru(); // B2 code.Defer(); int j2 = code.Jump(3); // B3 code.End(); static int forward[] = {0, 1, 2, 3}; ApplyForwarding(&code, kBlockCount, forward); CheckJump(&code, j1, 1); CheckJump(&code, j2, 3); static int assembly[] = {0, 2, 3, 1}; CheckAssemblyOrder(&code, kBlockCount, assembly); } TEST(Rewire_deferred_diamond) { constexpr size_t kBlockCount = 4; TestCode code(kBlockCount); // B0 int b1 = code.Branch(1, 2); // B1 code.Fallthru(); // To B3 // B2 code.Defer(); int j1 = code.Jump(3); // B3 code.Return(0); static int forward[] = {0, 3, 3, 3}; VerifyForwarding(&code, kBlockCount, forward); ApplyForwarding(&code, kBlockCount, forward); CheckBranch(&code, b1, 3, 3); CheckNop(&code, j1); static int assembly[] = {0, 1, 2, 1}; CheckAssemblyOrder(&code, kBlockCount, assembly); } TEST(Rewire_diamond) { constexpr size_t kBlockCount = 5; for (int i = 0; i < 2; i++) { for (int j = 0; j < 2; j++) { TestCode code(kBlockCount); // B0 int j1 = code.Jump(1); // B1 int b1 = code.Branch(2, 3); // B2 int j2 = code.Jump(4); // B3 int j3 = code.Jump(4); // B5 code.End(); int forward[] = {0, 1, i ? 4 : 2, j ? 4 : 3, 4}; ApplyForwarding(&code, kBlockCount, forward); CheckJump(&code, j1, 1); CheckBranch(&code, b1, i ? 4 : 2, j ? 4 : 3); if (i) { CheckNop(&code, j2); } else { CheckJump(&code, j2, 4); } if (j) { CheckNop(&code, j3); } else { CheckJump(&code, j3, 4); } int assembly[] = {0, 1, 2, 3, 4}; if (i) { for (int k = 3; k < 5; k++) assembly[k]--; } if (j) { for (int k = 4; k < 5; k++) assembly[k]--; } CheckAssemblyOrder(&code, kBlockCount, assembly); } } } TEST(RewireRet) { constexpr size_t kBlockCount = 4; TestCode code(kBlockCount); // B0 code.Branch(1, 2); // B1 int j1 = code.Return(0); // B2 int j2 = code.Return(0); // B3 code.End(); int forward[] = {0, 1, 1, 3}; VerifyForwarding(&code, 4, forward); ApplyForwarding(&code, 4, forward); CheckRet(&code, j1); CheckNop(&code, j2); } TEST(RewireRet1) { constexpr size_t kBlockCount = 4; TestCode code(kBlockCount); // B0 code.Branch(1, 2); // B1 int j1 = code.Return(0); // B2 int j2 = code.Return(0, true, true); // B3 code.End(); int forward[] = {0, 1, 2, 3}; VerifyForwarding(&code, kBlockCount, forward); ApplyForwarding(&code, kBlockCount, forward); CheckRet(&code, j1); CheckRet(&code, j2); } TEST(RewireRet2) { constexpr size_t kBlockCount = 4; TestCode code(kBlockCount); // B0 code.Branch(1, 2); // B1 int j1 = code.Return(0, true, true); // B2 int j2 = code.Return(0, true, true); // B3 code.End(); int forward[] = {0, 1, 1, 3}; VerifyForwarding(&code, kBlockCount, forward); ApplyForwarding(&code, kBlockCount, forward); CheckRet(&code, j1); CheckNop(&code, j2); } TEST(DifferentSizeRet) { constexpr size_t kBlockCount = 4; TestCode code(kBlockCount); // B0 code.Branch(1, 2); // B1 int j1 = code.Return(0); // B2 int j2 = code.Return(1); // B3 code.End(); int forward[] = {0, 1, 2, 3}; VerifyForwarding(&code, kBlockCount, forward); ApplyForwarding(&code, kBlockCount, forward); CheckRet(&code, j1); CheckRet(&code, j2); } TEST(RewireGapJump1) { constexpr size_t kBlockCount = 4; TestCode code(kBlockCount); // B0 int j1 = code.JumpWithGapMove(3); // B1 int j2 = code.JumpWithGapMove(3); // B2 int j3 = code.JumpWithGapMove(3); // B3 code.End(); int forward[] = {0, 0, 0, 3}; VerifyForwarding(&code, kBlockCount, forward); ApplyForwarding(&code, kBlockCount, forward); CheckJump(&code, j1, 3); CheckNop(&code, j2); CheckNop(&code, j3); static int assembly[] = {0, 1, 1, 1}; CheckAssemblyOrder(&code, kBlockCount, assembly); } TEST(RewireGapJump2) { constexpr size_t kBlockCount = 6; TestCode code(kBlockCount); // B0 int j1 = code.JumpWithGapMove(4); // B1 int j2 = code.JumpWithGapMove(4); // B2 code.Other(); int j3 = code.Jump(3); // B3 int j4 = code.Jump(1); // B4 int j5 = code.Jump(5); // B5 code.End(); int forward[] = {0, 0, 2, 0, 5, 5}; VerifyForwarding(&code, kBlockCount, forward); ApplyForwarding(&code, kBlockCount, forward); CheckJump(&code, j1, 5); CheckNop(&code, j2); CheckJump(&code, j3, 0); CheckNop(&code, j4); CheckNop(&code, j5); static int assembly[] = {0, 1, 1, 2, 2, 2}; CheckAssemblyOrder(&code, kBlockCount, assembly); } } // namespace compiler } // namespace internal } // namespace v8