/* * Copyright (C) 2014 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 "dex/mir_field_info.h" #include "global_value_numbering.h" #include "local_value_numbering.h" #include "gtest/gtest.h" namespace art { class LocalValueNumberingTest : public testing::Test { protected: struct IFieldDef { uint16_t field_idx; uintptr_t declaring_dex_file; uint16_t declaring_field_idx; bool is_volatile; DexMemAccessType type; }; struct SFieldDef { uint16_t field_idx; uintptr_t declaring_dex_file; uint16_t declaring_field_idx; bool is_volatile; DexMemAccessType type; }; struct MIRDef { static constexpr size_t kMaxSsaDefs = 2; static constexpr size_t kMaxSsaUses = 4; Instruction::Code opcode; int64_t value; uint32_t field_info; size_t num_uses; int32_t uses[kMaxSsaUses]; size_t num_defs; int32_t defs[kMaxSsaDefs]; }; #define DEF_CONST(opcode, reg, value) \ { opcode, value, 0u, 0, { }, 1, { reg } } #define DEF_CONST_WIDE(opcode, reg, value) \ { opcode, value, 0u, 0, { }, 2, { reg, reg + 1 } } #define DEF_CONST_STRING(opcode, reg, index) \ { opcode, index, 0u, 0, { }, 1, { reg } } #define DEF_IGET(opcode, reg, obj, field_info) \ { opcode, 0u, field_info, 1, { obj }, 1, { reg } } #define DEF_IGET_WIDE(opcode, reg, obj, field_info) \ { opcode, 0u, field_info, 1, { obj }, 2, { reg, reg + 1 } } #define DEF_IPUT(opcode, reg, obj, field_info) \ { opcode, 0u, field_info, 2, { reg, obj }, 0, { } } #define DEF_IPUT_WIDE(opcode, reg, obj, field_info) \ { opcode, 0u, field_info, 3, { reg, reg + 1, obj }, 0, { } } #define DEF_SGET(opcode, reg, field_info) \ { opcode, 0u, field_info, 0, { }, 1, { reg } } #define DEF_SGET_WIDE(opcode, reg, field_info) \ { opcode, 0u, field_info, 0, { }, 2, { reg, reg + 1 } } #define DEF_SPUT(opcode, reg, field_info) \ { opcode, 0u, field_info, 1, { reg }, 0, { } } #define DEF_SPUT_WIDE(opcode, reg, field_info) \ { opcode, 0u, field_info, 2, { reg, reg + 1 }, 0, { } } #define DEF_AGET(opcode, reg, obj, idx) \ { opcode, 0u, 0u, 2, { obj, idx }, 1, { reg } } #define DEF_AGET_WIDE(opcode, reg, obj, idx) \ { opcode, 0u, 0u, 2, { obj, idx }, 2, { reg, reg + 1 } } #define DEF_APUT(opcode, reg, obj, idx) \ { opcode, 0u, 0u, 3, { reg, obj, idx }, 0, { } } #define DEF_APUT_WIDE(opcode, reg, obj, idx) \ { opcode, 0u, 0u, 4, { reg, reg + 1, obj, idx }, 0, { } } #define DEF_INVOKE1(opcode, reg) \ { opcode, 0u, 0u, 1, { reg }, 0, { } } #define DEF_UNIQUE_REF(opcode, reg) \ { opcode, 0u, 0u, 0, { }, 1, { reg } } // CONST_CLASS, CONST_STRING, NEW_ARRAY, ... #define DEF_DIV_REM(opcode, result, dividend, divisor) \ { opcode, 0u, 0u, 2, { dividend, divisor }, 1, { result } } #define DEF_DIV_REM_WIDE(opcode, result, dividend, divisor) \ { opcode, 0u, 0u, 4, { dividend, dividend + 1, divisor, divisor + 1 }, 2, { result, result + 1 } } void DoPrepareIFields(const IFieldDef* defs, size_t count) { cu_.mir_graph->ifield_lowering_infos_.clear(); cu_.mir_graph->ifield_lowering_infos_.reserve(count); for (size_t i = 0u; i != count; ++i) { const IFieldDef* def = &defs[i]; MirIFieldLoweringInfo field_info(def->field_idx, def->type, false); if (def->declaring_dex_file != 0u) { field_info.declaring_dex_file_ = reinterpret_cast(def->declaring_dex_file); field_info.declaring_field_idx_ = def->declaring_field_idx; field_info.flags_ &= ~(def->is_volatile ? 0u : MirSFieldLoweringInfo::kFlagIsVolatile); } cu_.mir_graph->ifield_lowering_infos_.push_back(field_info); } } template void PrepareIFields(const IFieldDef (&defs)[count]) { DoPrepareIFields(defs, count); } void DoPrepareSFields(const SFieldDef* defs, size_t count) { cu_.mir_graph->sfield_lowering_infos_.clear(); cu_.mir_graph->sfield_lowering_infos_.reserve(count); for (size_t i = 0u; i != count; ++i) { const SFieldDef* def = &defs[i]; MirSFieldLoweringInfo field_info(def->field_idx, def->type); // Mark even unresolved fields as initialized. field_info.flags_ |= MirSFieldLoweringInfo::kFlagClassIsInitialized; // NOTE: MirSFieldLoweringInfo::kFlagClassIsInDexCache isn't used by LVN. if (def->declaring_dex_file != 0u) { field_info.declaring_dex_file_ = reinterpret_cast(def->declaring_dex_file); field_info.declaring_field_idx_ = def->declaring_field_idx; field_info.flags_ &= ~(def->is_volatile ? 0u : MirSFieldLoweringInfo::kFlagIsVolatile); } cu_.mir_graph->sfield_lowering_infos_.push_back(field_info); } } template void PrepareSFields(const SFieldDef (&defs)[count]) { DoPrepareSFields(defs, count); } void DoPrepareMIRs(const MIRDef* defs, size_t count) { mir_count_ = count; mirs_ = cu_.arena.AllocArray(count, kArenaAllocMIR); ssa_reps_.resize(count); for (size_t i = 0u; i != count; ++i) { const MIRDef* def = &defs[i]; MIR* mir = &mirs_[i]; mir->dalvikInsn.opcode = def->opcode; mir->dalvikInsn.vB = static_cast(def->value); mir->dalvikInsn.vB_wide = def->value; if (IsInstructionIGetOrIPut(def->opcode)) { ASSERT_LT(def->field_info, cu_.mir_graph->ifield_lowering_infos_.size()); mir->meta.ifield_lowering_info = def->field_info; ASSERT_EQ(cu_.mir_graph->ifield_lowering_infos_[def->field_info].MemAccessType(), IGetOrIPutMemAccessType(def->opcode)); } else if (IsInstructionSGetOrSPut(def->opcode)) { ASSERT_LT(def->field_info, cu_.mir_graph->sfield_lowering_infos_.size()); mir->meta.sfield_lowering_info = def->field_info; ASSERT_EQ(cu_.mir_graph->sfield_lowering_infos_[def->field_info].MemAccessType(), SGetOrSPutMemAccessType(def->opcode)); } mir->ssa_rep = &ssa_reps_[i]; mir->ssa_rep->num_uses = def->num_uses; mir->ssa_rep->uses = const_cast(def->uses); // Not modified by LVN. mir->ssa_rep->num_defs = def->num_defs; mir->ssa_rep->defs = const_cast(def->defs); // Not modified by LVN. mir->dalvikInsn.opcode = def->opcode; mir->offset = i; // LVN uses offset only for debug output mir->optimization_flags = 0u; if (i != 0u) { mirs_[i - 1u].next = mir; } } mirs_[count - 1u].next = nullptr; } template void PrepareMIRs(const MIRDef (&defs)[count]) { DoPrepareMIRs(defs, count); } void MakeSFieldUninitialized(uint32_t sfield_index) { CHECK_LT(sfield_index, cu_.mir_graph->sfield_lowering_infos_.size()); cu_.mir_graph->sfield_lowering_infos_[sfield_index].flags_ &= ~MirSFieldLoweringInfo::kFlagClassIsInitialized; } template void MarkAsWideSRegs(const int32_t (&sregs)[count]) { for (int32_t sreg : sregs) { cu_.mir_graph->reg_location_[sreg].wide = true; cu_.mir_graph->reg_location_[sreg + 1].wide = true; cu_.mir_graph->reg_location_[sreg + 1].high_word = true; } } void PerformLVN() { cu_.mir_graph->temp_.gvn.ifield_ids = GlobalValueNumbering::PrepareGvnFieldIds( allocator_.get(), cu_.mir_graph->ifield_lowering_infos_); cu_.mir_graph->temp_.gvn.sfield_ids = GlobalValueNumbering::PrepareGvnFieldIds( allocator_.get(), cu_.mir_graph->sfield_lowering_infos_); gvn_.reset(new (allocator_.get()) GlobalValueNumbering(&cu_, allocator_.get(), GlobalValueNumbering::kModeLvn)); lvn_.reset(new (allocator_.get()) LocalValueNumbering(gvn_.get(), 0u, allocator_.get())); value_names_.resize(mir_count_); for (size_t i = 0; i != mir_count_; ++i) { value_names_[i] = lvn_->GetValueNumber(&mirs_[i]); } EXPECT_TRUE(gvn_->Good()); } LocalValueNumberingTest() : pool_(), cu_(&pool_, kRuntimeISA, nullptr, nullptr), mir_count_(0u), mirs_(nullptr), ssa_reps_(), allocator_(), gvn_(), lvn_(), value_names_() { cu_.mir_graph.reset(new MIRGraph(&cu_, &cu_.arena)); allocator_.reset(ScopedArenaAllocator::Create(&cu_.arena_stack)); // By default, the zero-initialized reg_location_[.] with ref == false tells LVN that // 0 constants are integral, not references, and the values are all narrow. // Nothing else is used by LVN/GVN. Tests can override the default values as needed. cu_.mir_graph->reg_location_ = static_cast(cu_.arena.Alloc( kMaxSsaRegs * sizeof(cu_.mir_graph->reg_location_[0]), kArenaAllocRegAlloc)); cu_.mir_graph->num_ssa_regs_ = kMaxSsaRegs; } static constexpr size_t kMaxSsaRegs = 16384u; ArenaPool pool_; CompilationUnit cu_; size_t mir_count_; MIR* mirs_; std::vector ssa_reps_; std::unique_ptr allocator_; std::unique_ptr gvn_; std::unique_ptr lvn_; std::vector value_names_; }; TEST_F(LocalValueNumberingTest, IGetIGetInvokeIGet) { static const IFieldDef ifields[] = { { 1u, 1u, 1u, false, kDexMemAccessWord }, }; static const MIRDef mirs[] = { DEF_IGET(Instruction::IGET, 0u, 10u, 0u), DEF_IGET(Instruction::IGET, 1u, 10u, 0u), DEF_INVOKE1(Instruction::INVOKE_VIRTUAL, 11u), DEF_IGET(Instruction::IGET, 2u, 10u, 0u), }; PrepareIFields(ifields); PrepareMIRs(mirs); PerformLVN(); ASSERT_EQ(value_names_.size(), 4u); EXPECT_EQ(value_names_[0], value_names_[1]); EXPECT_NE(value_names_[0], value_names_[3]); EXPECT_EQ(mirs_[0].optimization_flags, 0u); EXPECT_EQ(mirs_[1].optimization_flags, MIR_IGNORE_NULL_CHECK); EXPECT_EQ(mirs_[2].optimization_flags, 0u); EXPECT_EQ(mirs_[3].optimization_flags, MIR_IGNORE_NULL_CHECK); } TEST_F(LocalValueNumberingTest, IGetIPutIGetIGetIGet) { static const IFieldDef ifields[] = { { 1u, 1u, 1u, false, kDexMemAccessObject }, { 2u, 1u, 2u, false, kDexMemAccessWord }, }; static const MIRDef mirs[] = { DEF_IGET(Instruction::IGET_OBJECT, 0u, 10u, 0u), DEF_IPUT(Instruction::IPUT_OBJECT, 1u, 11u, 0u), // May alias. DEF_IGET(Instruction::IGET_OBJECT, 2u, 10u, 0u), DEF_IGET(Instruction::IGET, 3u, 0u, 1u), DEF_IGET(Instruction::IGET, 4u, 2u, 1u), }; PrepareIFields(ifields); PrepareMIRs(mirs); PerformLVN(); ASSERT_EQ(value_names_.size(), 5u); EXPECT_NE(value_names_[0], value_names_[2]); EXPECT_NE(value_names_[3], value_names_[4]); for (size_t i = 0; i != arraysize(mirs); ++i) { EXPECT_EQ((i == 2u) ? MIR_IGNORE_NULL_CHECK : 0, mirs_[i].optimization_flags) << i; } } TEST_F(LocalValueNumberingTest, UniquePreserve1) { static const IFieldDef ifields[] = { { 1u, 1u, 1u, false, kDexMemAccessWord }, }; static const MIRDef mirs[] = { DEF_UNIQUE_REF(Instruction::NEW_INSTANCE, 10u), DEF_IGET(Instruction::IGET, 0u, 10u, 0u), DEF_IPUT(Instruction::IPUT, 1u, 11u, 0u), // No aliasing since 10u is unique. DEF_IGET(Instruction::IGET, 2u, 10u, 0u), }; PrepareIFields(ifields); PrepareMIRs(mirs); PerformLVN(); ASSERT_EQ(value_names_.size(), 4u); EXPECT_EQ(value_names_[1], value_names_[3]); for (size_t i = 0; i != arraysize(mirs); ++i) { EXPECT_EQ((i == 1u || i == 3u) ? MIR_IGNORE_NULL_CHECK : 0, mirs_[i].optimization_flags) << i; } } TEST_F(LocalValueNumberingTest, UniquePreserve2) { static const IFieldDef ifields[] = { { 1u, 1u, 1u, false, kDexMemAccessWord }, }; static const MIRDef mirs[] = { DEF_UNIQUE_REF(Instruction::NEW_INSTANCE, 11u), DEF_IGET(Instruction::IGET, 0u, 10u, 0u), DEF_IPUT(Instruction::IPUT, 1u, 11u, 0u), // No aliasing since 11u is unique. DEF_IGET(Instruction::IGET, 2u, 10u, 0u), }; PrepareIFields(ifields); PrepareMIRs(mirs); PerformLVN(); ASSERT_EQ(value_names_.size(), 4u); EXPECT_EQ(value_names_[1], value_names_[3]); for (size_t i = 0; i != arraysize(mirs); ++i) { EXPECT_EQ((i == 2u || i == 3u) ? MIR_IGNORE_NULL_CHECK : 0, mirs_[i].optimization_flags) << i; } } TEST_F(LocalValueNumberingTest, UniquePreserveAndEscape) { static const IFieldDef ifields[] = { { 1u, 1u, 1u, false, kDexMemAccessWord }, }; static const MIRDef mirs[] = { DEF_UNIQUE_REF(Instruction::NEW_INSTANCE, 10u), DEF_IGET(Instruction::IGET, 0u, 10u, 0u), DEF_INVOKE1(Instruction::INVOKE_VIRTUAL, 11u), // 10u still unique. DEF_IGET(Instruction::IGET, 2u, 10u, 0u), DEF_INVOKE1(Instruction::INVOKE_VIRTUAL, 10u), // 10u not unique anymore. DEF_IGET(Instruction::IGET, 3u, 10u, 0u), }; PrepareIFields(ifields); PrepareMIRs(mirs); PerformLVN(); ASSERT_EQ(value_names_.size(), 6u); EXPECT_EQ(value_names_[1], value_names_[3]); EXPECT_NE(value_names_[1], value_names_[5]); for (size_t i = 0; i != arraysize(mirs); ++i) { EXPECT_EQ((i == 1u || i == 3u || i == 4u || i == 5u) ? MIR_IGNORE_NULL_CHECK : 0, mirs_[i].optimization_flags) << i; } } TEST_F(LocalValueNumberingTest, Volatile) { static const IFieldDef ifields[] = { { 1u, 1u, 1u, false, kDexMemAccessWord }, { 2u, 1u, 2u, true, kDexMemAccessWord }, }; static const MIRDef mirs[] = { DEF_IGET(Instruction::IGET, 0u, 10u, 1u), // Volatile. DEF_IGET(Instruction::IGET, 1u, 0u, 0u), // Non-volatile. DEF_IGET(Instruction::IGET, 2u, 10u, 1u), // Volatile. DEF_IGET(Instruction::IGET, 3u, 2u, 1u), // Non-volatile. DEF_IGET(Instruction::IGET, 4u, 0u, 0u), // Non-volatile. }; PrepareIFields(ifields); PrepareMIRs(mirs); PerformLVN(); ASSERT_EQ(value_names_.size(), 5u); EXPECT_NE(value_names_[0], value_names_[2]); // Volatile has always different value name. EXPECT_NE(value_names_[1], value_names_[3]); // Used different base because of volatile. EXPECT_NE(value_names_[1], value_names_[4]); // Not guaranteed to be the same after "acquire". for (size_t i = 0; i != arraysize(mirs); ++i) { EXPECT_EQ((i == 2u || i == 4u) ? MIR_IGNORE_NULL_CHECK : 0, mirs_[i].optimization_flags) << i; } } TEST_F(LocalValueNumberingTest, UnresolvedIField) { static const IFieldDef ifields[] = { { 1u, 1u, 1u, false, kDexMemAccessWord }, // Resolved field #1. { 2u, 1u, 2u, false, kDexMemAccessWide }, // Resolved field #2. { 3u, 0u, 0u, false, kDexMemAccessWord }, // Unresolved field. }; static const MIRDef mirs[] = { DEF_UNIQUE_REF(Instruction::NEW_INSTANCE, 30u), DEF_IGET(Instruction::IGET, 1u, 30u, 0u), // Resolved field #1, unique object. DEF_IGET(Instruction::IGET, 2u, 31u, 0u), // Resolved field #1. DEF_IGET_WIDE(Instruction::IGET_WIDE, 3u, 31u, 1u), // Resolved field #2. DEF_IGET(Instruction::IGET, 5u, 32u, 2u), // Unresolved IGET can be "acquire". DEF_IGET(Instruction::IGET, 6u, 30u, 0u), // Resolved field #1, unique object. DEF_IGET(Instruction::IGET, 7u, 31u, 0u), // Resolved field #1. DEF_IGET_WIDE(Instruction::IGET_WIDE, 8u, 31u, 1u), // Resolved field #2. DEF_IPUT(Instruction::IPUT, 10u, 32u, 2u), // IPUT clobbers field #1 (#2 is wide). DEF_IGET(Instruction::IGET, 11u, 30u, 0u), // Resolved field #1, unique object. DEF_IGET(Instruction::IGET, 12u, 31u, 0u), // Resolved field #1, new value name. DEF_IGET_WIDE(Instruction::IGET_WIDE, 13u, 31u, 1u), // Resolved field #2. DEF_IGET_WIDE(Instruction::IGET_WIDE, 15u, 30u, 1u), // Resolved field #2, unique object. DEF_IPUT(Instruction::IPUT, 17u, 30u, 2u), // IPUT clobbers field #1 (#2 is wide). DEF_IGET(Instruction::IGET, 18u, 30u, 0u), // Resolved field #1, unique object. DEF_IGET_WIDE(Instruction::IGET_WIDE, 19u, 30u, 1u), // Resolved field #2, unique object. }; PrepareIFields(ifields); PrepareMIRs(mirs); static const int32_t wide_sregs[] = { 3, 8, 13, 15, 19 }; MarkAsWideSRegs(wide_sregs); PerformLVN(); ASSERT_EQ(value_names_.size(), 16u); // Unresolved field is potentially volatile, so we need to adhere to the volatile semantics. EXPECT_EQ(value_names_[1], value_names_[5]); // Unique object. EXPECT_NE(value_names_[2], value_names_[6]); // Not guaranteed to be the same after "acquire". EXPECT_NE(value_names_[3], value_names_[7]); // Not guaranteed to be the same after "acquire". EXPECT_EQ(value_names_[1], value_names_[9]); // Unique object. EXPECT_NE(value_names_[6], value_names_[10]); // This aliased with unresolved IPUT. EXPECT_EQ(value_names_[7], value_names_[11]); // Still the same after "release". EXPECT_EQ(value_names_[12], value_names_[15]); // Still the same after "release". EXPECT_NE(value_names_[1], value_names_[14]); // This aliased with unresolved IPUT. EXPECT_EQ(mirs_[0].optimization_flags, 0u); EXPECT_EQ(mirs_[1].optimization_flags, MIR_IGNORE_NULL_CHECK); EXPECT_EQ(mirs_[2].optimization_flags, 0u); EXPECT_EQ(mirs_[3].optimization_flags, MIR_IGNORE_NULL_CHECK); EXPECT_EQ(mirs_[4].optimization_flags, 0u); for (size_t i = 5u; i != mir_count_; ++i) { EXPECT_EQ((i == 1u || i == 3u || i >=5u) ? MIR_IGNORE_NULL_CHECK : 0, mirs_[i].optimization_flags) << i; } } TEST_F(LocalValueNumberingTest, UnresolvedSField) { static const SFieldDef sfields[] = { { 1u, 1u, 1u, false, kDexMemAccessWord }, // Resolved field #1. { 2u, 1u, 2u, false, kDexMemAccessWide }, // Resolved field #2. { 3u, 0u, 0u, false, kDexMemAccessWord }, // Unresolved field. }; static const MIRDef mirs[] = { DEF_SGET(Instruction::SGET, 0u, 0u), // Resolved field #1. DEF_SGET_WIDE(Instruction::SGET_WIDE, 1u, 1u), // Resolved field #2. DEF_SGET(Instruction::SGET, 3u, 2u), // Unresolved SGET can be "acquire". DEF_SGET(Instruction::SGET, 4u, 0u), // Resolved field #1. DEF_SGET_WIDE(Instruction::SGET_WIDE, 5u, 1u), // Resolved field #2. DEF_SPUT(Instruction::SPUT, 7u, 2u), // SPUT clobbers field #1 (#2 is wide). DEF_SGET(Instruction::SGET, 8u, 0u), // Resolved field #1. DEF_SGET_WIDE(Instruction::SGET_WIDE, 9u, 1u), // Resolved field #2. }; PrepareSFields(sfields); PrepareMIRs(mirs); static const int32_t wide_sregs[] = { 1, 5, 9 }; MarkAsWideSRegs(wide_sregs); PerformLVN(); ASSERT_EQ(value_names_.size(), 8u); // Unresolved field is potentially volatile, so we need to adhere to the volatile semantics. EXPECT_NE(value_names_[0], value_names_[3]); // Not guaranteed to be the same after "acquire". EXPECT_NE(value_names_[1], value_names_[4]); // Not guaranteed to be the same after "acquire". EXPECT_NE(value_names_[3], value_names_[6]); // This aliased with unresolved IPUT. EXPECT_EQ(value_names_[4], value_names_[7]); // Still the same after "release". for (size_t i = 0u; i != mir_count_; ++i) { EXPECT_EQ(0, mirs_[i].optimization_flags) << i; } } TEST_F(LocalValueNumberingTest, UninitializedSField) { static const IFieldDef ifields[] = { { 1u, 1u, 1u, false, kDexMemAccessWord }, // Resolved field #1. }; static const SFieldDef sfields[] = { { 1u, 1u, 1u, false, kDexMemAccessWord }, // Resolved field #1. { 2u, 1u, 2u, false, kDexMemAccessWord }, // Resolved field #2; uninitialized. }; static const MIRDef mirs[] = { DEF_UNIQUE_REF(Instruction::NEW_INSTANCE, 200u), DEF_IGET(Instruction::IGET, 1u, 100u, 0u), DEF_IGET(Instruction::IGET, 2u, 200u, 0u), DEF_SGET(Instruction::SGET, 3u, 0u), DEF_SGET(Instruction::SGET, 4u, 1u), // Can call (). DEF_IGET(Instruction::IGET, 5u, 100u, 0u), // Differs from 1u. DEF_IGET(Instruction::IGET, 6u, 200u, 0u), // Same as 2u. DEF_SGET(Instruction::SGET, 7u, 0u), // Differs from 3u. }; PrepareIFields(ifields); PrepareSFields(sfields); MakeSFieldUninitialized(1u); PrepareMIRs(mirs); PerformLVN(); ASSERT_EQ(value_names_.size(), 8u); EXPECT_NE(value_names_[1], value_names_[5]); EXPECT_EQ(value_names_[2], value_names_[6]); EXPECT_NE(value_names_[3], value_names_[7]); } TEST_F(LocalValueNumberingTest, ConstString) { static const MIRDef mirs[] = { DEF_CONST_STRING(Instruction::CONST_STRING, 0u, 0u), DEF_CONST_STRING(Instruction::CONST_STRING, 1u, 0u), DEF_CONST_STRING(Instruction::CONST_STRING, 2u, 2u), DEF_CONST_STRING(Instruction::CONST_STRING, 3u, 0u), DEF_INVOKE1(Instruction::INVOKE_DIRECT, 2u), DEF_CONST_STRING(Instruction::CONST_STRING, 4u, 2u), }; PrepareMIRs(mirs); PerformLVN(); ASSERT_EQ(value_names_.size(), 6u); EXPECT_EQ(value_names_[1], value_names_[0]); EXPECT_NE(value_names_[2], value_names_[0]); EXPECT_EQ(value_names_[3], value_names_[0]); EXPECT_EQ(value_names_[5], value_names_[2]); } TEST_F(LocalValueNumberingTest, SameValueInDifferentMemoryLocations) { static const IFieldDef ifields[] = { { 1u, 1u, 1u, false, kDexMemAccessWord }, { 2u, 1u, 2u, false, kDexMemAccessWord }, }; static const SFieldDef sfields[] = { { 3u, 1u, 3u, false, kDexMemAccessWord }, }; static const MIRDef mirs[] = { DEF_UNIQUE_REF(Instruction::NEW_ARRAY, 201u), DEF_IGET(Instruction::IGET, 0u, 100u, 0u), DEF_IPUT(Instruction::IPUT, 0u, 100u, 1u), DEF_IPUT(Instruction::IPUT, 0u, 101u, 1u), DEF_APUT(Instruction::APUT, 0u, 200u, 300u), DEF_APUT(Instruction::APUT, 0u, 200u, 301u), DEF_APUT(Instruction::APUT, 0u, 201u, 300u), DEF_APUT(Instruction::APUT, 0u, 201u, 301u), DEF_SPUT(Instruction::SPUT, 0u, 0u), DEF_IGET(Instruction::IGET, 9u, 100u, 0u), DEF_IGET(Instruction::IGET, 10u, 100u, 1u), DEF_IGET(Instruction::IGET, 11u, 101u, 1u), DEF_AGET(Instruction::AGET, 12u, 200u, 300u), DEF_AGET(Instruction::AGET, 13u, 200u, 301u), DEF_AGET(Instruction::AGET, 14u, 201u, 300u), DEF_AGET(Instruction::AGET, 15u, 201u, 301u), DEF_SGET(Instruction::SGET, 16u, 0u), }; PrepareIFields(ifields); PrepareSFields(sfields); PrepareMIRs(mirs); PerformLVN(); ASSERT_EQ(value_names_.size(), 17u); for (size_t i = 9; i != arraysize(mirs); ++i) { EXPECT_EQ(value_names_[1], value_names_[i]) << i; } for (size_t i = 0; i != arraysize(mirs); ++i) { int expected_flags = ((i == 2u || (i >= 5u && i <= 7u) || (i >= 9u && i <= 15u)) ? MIR_IGNORE_NULL_CHECK : 0) | ((i >= 12u && i <= 15u) ? MIR_IGNORE_RANGE_CHECK : 0); EXPECT_EQ(expected_flags, mirs_[i].optimization_flags) << i; } } TEST_F(LocalValueNumberingTest, UniqueArrayAliasing) { static const MIRDef mirs[] = { DEF_UNIQUE_REF(Instruction::NEW_ARRAY, 20u), DEF_AGET(Instruction::AGET, 1u, 20u, 40u), DEF_APUT(Instruction::APUT, 2u, 20u, 41u), // May alias with index for sreg 40u. DEF_AGET(Instruction::AGET, 3u, 20u, 40u), }; PrepareMIRs(mirs); PerformLVN(); ASSERT_EQ(value_names_.size(), 4u); EXPECT_NE(value_names_[1], value_names_[3]); for (size_t i = 0; i != arraysize(mirs); ++i) { int expected_flags = ((i >= 1u) ? MIR_IGNORE_NULL_CHECK : 0) | ((i == 3u) ? MIR_IGNORE_RANGE_CHECK : 0); EXPECT_EQ(expected_flags, mirs_[i].optimization_flags) << i; } } TEST_F(LocalValueNumberingTest, EscapingRefs) { static const IFieldDef ifields[] = { { 1u, 1u, 1u, false, kDexMemAccessWord }, // Field #1. { 2u, 1u, 2u, false, kDexMemAccessWord }, // Field #2. { 3u, 1u, 3u, false, kDexMemAccessObject }, // For storing escaping refs. { 4u, 1u, 4u, false, kDexMemAccessWide }, // Wide. { 5u, 0u, 0u, false, kDexMemAccessWord }, // Unresolved field, int. { 6u, 0u, 0u, false, kDexMemAccessWide }, // Unresolved field, wide. }; static const MIRDef mirs[] = { DEF_UNIQUE_REF(Instruction::NEW_INSTANCE, 20u), DEF_IGET(Instruction::IGET, 1u, 20u, 0u), DEF_IGET(Instruction::IGET, 2u, 20u, 1u), DEF_IPUT(Instruction::IPUT_OBJECT, 20u, 30u, 2u), // Ref escapes. DEF_IGET(Instruction::IGET, 4u, 20u, 0u), DEF_IGET(Instruction::IGET, 5u, 20u, 1u), DEF_IPUT(Instruction::IPUT, 6u, 31u, 0u), // May alias with field #1. DEF_IGET(Instruction::IGET, 7u, 20u, 0u), // New value. DEF_IGET(Instruction::IGET, 8u, 20u, 1u), // Still the same. DEF_IPUT_WIDE(Instruction::IPUT_WIDE, 9u, 31u, 3u), // No aliasing, different type. DEF_IGET(Instruction::IGET, 11u, 20u, 0u), DEF_IGET(Instruction::IGET, 12u, 20u, 1u), DEF_IPUT_WIDE(Instruction::IPUT_WIDE, 13u, 31u, 5u), // No aliasing, different type. DEF_IGET(Instruction::IGET, 15u, 20u, 0u), DEF_IGET(Instruction::IGET, 16u, 20u, 1u), DEF_IPUT(Instruction::IPUT, 17u, 31u, 4u), // Aliasing, same type. DEF_IGET(Instruction::IGET, 18u, 20u, 0u), DEF_IGET(Instruction::IGET, 19u, 20u, 1u), }; PrepareIFields(ifields); PrepareMIRs(mirs); static const int32_t wide_sregs[] = { 9, 13 }; MarkAsWideSRegs(wide_sregs); PerformLVN(); ASSERT_EQ(value_names_.size(), 18u); EXPECT_EQ(value_names_[1], value_names_[4]); EXPECT_EQ(value_names_[2], value_names_[5]); EXPECT_NE(value_names_[4], value_names_[7]); // New value. EXPECT_EQ(value_names_[5], value_names_[8]); EXPECT_EQ(value_names_[7], value_names_[10]); EXPECT_EQ(value_names_[8], value_names_[11]); EXPECT_EQ(value_names_[10], value_names_[13]); EXPECT_EQ(value_names_[11], value_names_[14]); EXPECT_NE(value_names_[13], value_names_[16]); // New value. EXPECT_NE(value_names_[14], value_names_[17]); // New value. for (size_t i = 0u; i != mir_count_; ++i) { int expected = ((i != 0u && i != 3u && i != 6u) ? MIR_IGNORE_NULL_CHECK : 0) | ((i == 3u) ? MIR_STORE_NON_NULL_VALUE: 0); EXPECT_EQ(expected, mirs_[i].optimization_flags) << i; } } TEST_F(LocalValueNumberingTest, EscapingArrayRefs) { static const MIRDef mirs[] = { DEF_UNIQUE_REF(Instruction::NEW_ARRAY, 20u), DEF_AGET(Instruction::AGET, 1u, 20u, 40u), DEF_AGET(Instruction::AGET, 2u, 20u, 41u), DEF_APUT(Instruction::APUT_OBJECT, 20u, 30u, 42u), // Array ref escapes. DEF_AGET(Instruction::AGET, 4u, 20u, 40u), DEF_AGET(Instruction::AGET, 5u, 20u, 41u), DEF_APUT_WIDE(Instruction::APUT_WIDE, 6u, 31u, 43u), // No aliasing, different type. DEF_AGET(Instruction::AGET, 8u, 20u, 40u), DEF_AGET(Instruction::AGET, 9u, 20u, 41u), DEF_APUT(Instruction::APUT, 10u, 32u, 40u), // May alias with all elements. DEF_AGET(Instruction::AGET, 11u, 20u, 40u), // New value (same index name). DEF_AGET(Instruction::AGET, 12u, 20u, 41u), // New value (different index name). }; PrepareMIRs(mirs); static const int32_t wide_sregs[] = { 6 }; MarkAsWideSRegs(wide_sregs); PerformLVN(); ASSERT_EQ(value_names_.size(), 12u); EXPECT_EQ(value_names_[1], value_names_[4]); EXPECT_EQ(value_names_[2], value_names_[5]); EXPECT_EQ(value_names_[4], value_names_[7]); EXPECT_EQ(value_names_[5], value_names_[8]); EXPECT_NE(value_names_[7], value_names_[10]); // New value. EXPECT_NE(value_names_[8], value_names_[11]); // New value. for (size_t i = 0u; i != mir_count_; ++i) { int expected = ((i != 0u && i != 3u && i != 6u && i != 9u) ? MIR_IGNORE_NULL_CHECK : 0u) | ((i >= 4 && i != 6u && i != 9u) ? MIR_IGNORE_RANGE_CHECK : 0u) | ((i == 3u) ? MIR_STORE_NON_NULL_VALUE: 0); EXPECT_EQ(expected, mirs_[i].optimization_flags) << i; } } TEST_F(LocalValueNumberingTest, StoringSameValueKeepsMemoryVersion) { static const IFieldDef ifields[] = { { 1u, 1u, 1u, false, kDexMemAccessWord }, { 2u, 1u, 2u, false, kDexMemAccessWord }, }; static const SFieldDef sfields[] = { { 2u, 1u, 2u, false, kDexMemAccessWord }, }; static const MIRDef mirs[] = { DEF_IGET(Instruction::IGET, 0u, 30u, 0u), DEF_IGET(Instruction::IGET, 1u, 31u, 0u), DEF_IPUT(Instruction::IPUT, 1u, 31u, 0u), // Store the same value. DEF_IGET(Instruction::IGET, 3u, 30u, 0u), DEF_AGET(Instruction::AGET, 4u, 32u, 40u), DEF_AGET(Instruction::AGET, 5u, 33u, 40u), DEF_APUT(Instruction::APUT, 5u, 33u, 40u), // Store the same value. DEF_AGET(Instruction::AGET, 7u, 32u, 40u), DEF_SGET(Instruction::SGET, 8u, 0u), DEF_SPUT(Instruction::SPUT, 8u, 0u), // Store the same value. DEF_SGET(Instruction::SGET, 10u, 0u), DEF_UNIQUE_REF(Instruction::NEW_INSTANCE, 50u), // Test with unique references. { Instruction::FILLED_NEW_ARRAY, 0, 0u, 2, { 12u, 13u }, 0, { } }, DEF_UNIQUE_REF(Instruction::MOVE_RESULT_OBJECT, 51u), DEF_IGET(Instruction::IGET, 14u, 50u, 0u), DEF_IGET(Instruction::IGET, 15u, 50u, 1u), DEF_IPUT(Instruction::IPUT, 15u, 50u, 1u), // Store the same value. DEF_IGET(Instruction::IGET, 17u, 50u, 0u), DEF_AGET(Instruction::AGET, 18u, 51u, 40u), DEF_AGET(Instruction::AGET, 19u, 51u, 41u), DEF_APUT(Instruction::APUT, 19u, 51u, 41u), // Store the same value. DEF_AGET(Instruction::AGET, 21u, 51u, 40u), }; PrepareIFields(ifields); PrepareSFields(sfields); PrepareMIRs(mirs); PerformLVN(); ASSERT_EQ(value_names_.size(), 22u); EXPECT_NE(value_names_[0], value_names_[1]); EXPECT_EQ(value_names_[0], value_names_[3]); EXPECT_NE(value_names_[4], value_names_[5]); EXPECT_EQ(value_names_[4], value_names_[7]); EXPECT_EQ(value_names_[8], value_names_[10]); EXPECT_NE(value_names_[14], value_names_[15]); EXPECT_EQ(value_names_[14], value_names_[17]); EXPECT_NE(value_names_[18], value_names_[19]); EXPECT_EQ(value_names_[18], value_names_[21]); for (size_t i = 0u; i != mir_count_; ++i) { int expected = ((i == 2u || i == 3u || i == 6u || i == 7u || (i >= 14u)) ? MIR_IGNORE_NULL_CHECK : 0u) | ((i == 6u || i == 7u || i >= 20u) ? MIR_IGNORE_RANGE_CHECK : 0u); EXPECT_EQ(expected, mirs_[i].optimization_flags) << i; } } TEST_F(LocalValueNumberingTest, FilledNewArrayTracking) { if (!kLocalValueNumberingEnableFilledNewArrayTracking) { // Feature disabled. return; } static const MIRDef mirs[] = { DEF_CONST(Instruction::CONST, 0u, 100), DEF_CONST(Instruction::CONST, 1u, 200), { Instruction::FILLED_NEW_ARRAY, 0, 0u, 2, { 0u, 1u }, 0, { } }, DEF_UNIQUE_REF(Instruction::MOVE_RESULT_OBJECT, 10u), DEF_CONST(Instruction::CONST, 20u, 0), DEF_CONST(Instruction::CONST, 21u, 1), DEF_AGET(Instruction::AGET, 6u, 10u, 20u), DEF_AGET(Instruction::AGET, 7u, 10u, 21u), }; PrepareMIRs(mirs); PerformLVN(); ASSERT_EQ(value_names_.size(), 8u); EXPECT_EQ(value_names_[0], value_names_[6]); EXPECT_EQ(value_names_[1], value_names_[7]); for (size_t i = 0u; i != mir_count_; ++i) { int expected = (i == 6u || i == 7u) ? (MIR_IGNORE_NULL_CHECK | MIR_IGNORE_RANGE_CHECK) : 0u; EXPECT_EQ(expected, mirs_[i].optimization_flags) << i; } } TEST_F(LocalValueNumberingTest, ClInitOnSget) { static const SFieldDef sfields[] = { { 0u, 1u, 0u, false, kDexMemAccessObject }, { 1u, 2u, 1u, false, kDexMemAccessObject }, }; static const MIRDef mirs[] = { DEF_SGET(Instruction::SGET_OBJECT, 0u, 0u), DEF_AGET(Instruction::AGET, 1u, 0u, 100u), DEF_SGET(Instruction::SGET_OBJECT, 2u, 1u), DEF_SGET(Instruction::SGET_OBJECT, 3u, 0u), DEF_AGET(Instruction::AGET, 4u, 3u, 100u), }; PrepareSFields(sfields); MakeSFieldUninitialized(1u); PrepareMIRs(mirs); PerformLVN(); ASSERT_EQ(value_names_.size(), 5u); EXPECT_NE(value_names_[0], value_names_[3]); } TEST_F(LocalValueNumberingTest, DivZeroCheck) { static const MIRDef mirs[] = { DEF_DIV_REM(Instruction::DIV_INT, 1u, 10u, 20u), DEF_DIV_REM(Instruction::DIV_INT, 2u, 20u, 20u), DEF_DIV_REM(Instruction::DIV_INT_2ADDR, 3u, 10u, 1u), DEF_DIV_REM(Instruction::REM_INT, 4u, 30u, 20u), DEF_DIV_REM_WIDE(Instruction::REM_LONG, 5u, 12u, 14u), DEF_DIV_REM_WIDE(Instruction::DIV_LONG_2ADDR, 7u, 16u, 14u), }; static const bool expected_ignore_div_zero_check[] = { false, true, false, true, false, true, }; PrepareMIRs(mirs); static const int32_t wide_sregs[] = { 5, 7, 12, 14, 16 }; MarkAsWideSRegs(wide_sregs); PerformLVN(); for (size_t i = 0u; i != mir_count_; ++i) { int expected = expected_ignore_div_zero_check[i] ? MIR_IGNORE_DIV_ZERO_CHECK : 0u; EXPECT_EQ(expected, mirs_[i].optimization_flags) << i; } } TEST_F(LocalValueNumberingTest, ConstWide) { static const MIRDef mirs[] = { // Core reg constants. DEF_CONST(Instruction::CONST_WIDE_16, 0u, 0), DEF_CONST(Instruction::CONST_WIDE_16, 2u, 1), DEF_CONST(Instruction::CONST_WIDE_16, 4u, -1), DEF_CONST(Instruction::CONST_WIDE_32, 6u, 1 << 16), DEF_CONST(Instruction::CONST_WIDE_32, 8u, -1 << 16), DEF_CONST(Instruction::CONST_WIDE_32, 10u, (1 << 16) + 1), DEF_CONST(Instruction::CONST_WIDE_32, 12u, (1 << 16) - 1), DEF_CONST(Instruction::CONST_WIDE_32, 14u, -(1 << 16) + 1), DEF_CONST(Instruction::CONST_WIDE_32, 16u, -(1 << 16) - 1), DEF_CONST(Instruction::CONST_WIDE, 18u, INT64_C(1) << 32), DEF_CONST(Instruction::CONST_WIDE, 20u, INT64_C(-1) << 32), DEF_CONST(Instruction::CONST_WIDE, 22u, (INT64_C(1) << 32) + 1), DEF_CONST(Instruction::CONST_WIDE, 24u, (INT64_C(1) << 32) - 1), DEF_CONST(Instruction::CONST_WIDE, 26u, (INT64_C(-1) << 32) + 1), DEF_CONST(Instruction::CONST_WIDE, 28u, (INT64_C(-1) << 32) - 1), DEF_CONST(Instruction::CONST_WIDE_HIGH16, 30u, 1), // Effectively 1 << 48. DEF_CONST(Instruction::CONST_WIDE_HIGH16, 32u, 0xffff), // Effectively -1 << 48. DEF_CONST(Instruction::CONST_WIDE, 34u, (INT64_C(1) << 48) + 1), DEF_CONST(Instruction::CONST_WIDE, 36u, (INT64_C(1) << 48) - 1), DEF_CONST(Instruction::CONST_WIDE, 38u, (INT64_C(-1) << 48) + 1), DEF_CONST(Instruction::CONST_WIDE, 40u, (INT64_C(-1) << 48) - 1), // FP reg constants. DEF_CONST(Instruction::CONST_WIDE_16, 42u, 0), DEF_CONST(Instruction::CONST_WIDE_16, 44u, 1), DEF_CONST(Instruction::CONST_WIDE_16, 46u, -1), DEF_CONST(Instruction::CONST_WIDE_32, 48u, 1 << 16), DEF_CONST(Instruction::CONST_WIDE_32, 50u, -1 << 16), DEF_CONST(Instruction::CONST_WIDE_32, 52u, (1 << 16) + 1), DEF_CONST(Instruction::CONST_WIDE_32, 54u, (1 << 16) - 1), DEF_CONST(Instruction::CONST_WIDE_32, 56u, -(1 << 16) + 1), DEF_CONST(Instruction::CONST_WIDE_32, 58u, -(1 << 16) - 1), DEF_CONST(Instruction::CONST_WIDE, 60u, INT64_C(1) << 32), DEF_CONST(Instruction::CONST_WIDE, 62u, INT64_C(-1) << 32), DEF_CONST(Instruction::CONST_WIDE, 64u, (INT64_C(1) << 32) + 1), DEF_CONST(Instruction::CONST_WIDE, 66u, (INT64_C(1) << 32) - 1), DEF_CONST(Instruction::CONST_WIDE, 68u, (INT64_C(-1) << 32) + 1), DEF_CONST(Instruction::CONST_WIDE, 70u, (INT64_C(-1) << 32) - 1), DEF_CONST(Instruction::CONST_WIDE_HIGH16, 72u, 1), // Effectively 1 << 48. DEF_CONST(Instruction::CONST_WIDE_HIGH16, 74u, 0xffff), // Effectively -1 << 48. DEF_CONST(Instruction::CONST_WIDE, 76u, (INT64_C(1) << 48) + 1), DEF_CONST(Instruction::CONST_WIDE, 78u, (INT64_C(1) << 48) - 1), DEF_CONST(Instruction::CONST_WIDE, 80u, (INT64_C(-1) << 48) + 1), DEF_CONST(Instruction::CONST_WIDE, 82u, (INT64_C(-1) << 48) - 1), }; PrepareMIRs(mirs); for (size_t i = 0; i != arraysize(mirs); ++i) { const int32_t wide_sregs[] = { mirs_[i].ssa_rep->defs[0] }; MarkAsWideSRegs(wide_sregs); } for (size_t i = arraysize(mirs) / 2u; i != arraysize(mirs); ++i) { cu_.mir_graph->reg_location_[mirs_[i].ssa_rep->defs[0]].fp = true; } PerformLVN(); for (size_t i = 0u; i != mir_count_; ++i) { for (size_t j = i + 1u; j != mir_count_; ++j) { EXPECT_NE(value_names_[i], value_names_[j]) << i << " " << j; } } } TEST_F(LocalValueNumberingTest, Const) { static const MIRDef mirs[] = { // Core reg constants. DEF_CONST(Instruction::CONST_4, 0u, 0), DEF_CONST(Instruction::CONST_4, 1u, 1), DEF_CONST(Instruction::CONST_4, 2u, -1), DEF_CONST(Instruction::CONST_16, 3u, 1 << 4), DEF_CONST(Instruction::CONST_16, 4u, -1 << 4), DEF_CONST(Instruction::CONST_16, 5u, (1 << 4) + 1), DEF_CONST(Instruction::CONST_16, 6u, (1 << 4) - 1), DEF_CONST(Instruction::CONST_16, 7u, -(1 << 4) + 1), DEF_CONST(Instruction::CONST_16, 8u, -(1 << 4) - 1), DEF_CONST(Instruction::CONST_HIGH16, 9u, 1), // Effectively 1 << 16. DEF_CONST(Instruction::CONST_HIGH16, 10u, 0xffff), // Effectively -1 << 16. DEF_CONST(Instruction::CONST, 11u, (1 << 16) + 1), DEF_CONST(Instruction::CONST, 12u, (1 << 16) - 1), DEF_CONST(Instruction::CONST, 13u, (-1 << 16) + 1), DEF_CONST(Instruction::CONST, 14u, (-1 << 16) - 1), // FP reg constants. DEF_CONST(Instruction::CONST_4, 15u, 0), DEF_CONST(Instruction::CONST_4, 16u, 1), DEF_CONST(Instruction::CONST_4, 17u, -1), DEF_CONST(Instruction::CONST_16, 18u, 1 << 4), DEF_CONST(Instruction::CONST_16, 19u, -1 << 4), DEF_CONST(Instruction::CONST_16, 20u, (1 << 4) + 1), DEF_CONST(Instruction::CONST_16, 21u, (1 << 4) - 1), DEF_CONST(Instruction::CONST_16, 22u, -(1 << 4) + 1), DEF_CONST(Instruction::CONST_16, 23u, -(1 << 4) - 1), DEF_CONST(Instruction::CONST_HIGH16, 24u, 1), // Effectively 1 << 16. DEF_CONST(Instruction::CONST_HIGH16, 25u, 0xffff), // Effectively -1 << 16. DEF_CONST(Instruction::CONST, 26u, (1 << 16) + 1), DEF_CONST(Instruction::CONST, 27u, (1 << 16) - 1), DEF_CONST(Instruction::CONST, 28u, (-1 << 16) + 1), DEF_CONST(Instruction::CONST, 29u, (-1 << 16) - 1), // null reference constant. DEF_CONST(Instruction::CONST_4, 30u, 0), }; PrepareMIRs(mirs); static_assert((arraysize(mirs) & 1) != 0, "missing null or unmatched fp/core"); cu_.mir_graph->reg_location_[arraysize(mirs) - 1].ref = true; for (size_t i = arraysize(mirs) / 2u; i != arraysize(mirs) - 1; ++i) { cu_.mir_graph->reg_location_[mirs_[i].ssa_rep->defs[0]].fp = true; } PerformLVN(); for (size_t i = 0u; i != mir_count_; ++i) { for (size_t j = i + 1u; j != mir_count_; ++j) { EXPECT_NE(value_names_[i], value_names_[j]) << i << " " << j; } } } } // namespace art