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/*
* Copyright (C) 2017 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 "load_store_analysis.h"
#include "nodes.h"
#include "optimizing_unit_test.h"
#include "gtest/gtest.h"
namespace art {
class LoadStoreAnalysisTest : public OptimizingUnitTest {
public:
LoadStoreAnalysisTest() : graph_(CreateGraph()) { }
HGraph* graph_;
};
TEST_F(LoadStoreAnalysisTest, ArrayHeapLocations) {
HBasicBlock* entry = new (GetAllocator()) HBasicBlock(graph_);
graph_->AddBlock(entry);
graph_->SetEntryBlock(entry);
// entry:
// array ParameterValue
// index ParameterValue
// c1 IntConstant
// c2 IntConstant
// c3 IntConstant
// array_get1 ArrayGet [array, c1]
// array_get2 ArrayGet [array, c2]
// array_set1 ArraySet [array, c1, c3]
// array_set2 ArraySet [array, index, c3]
HInstruction* array = new (GetAllocator()) HParameterValue(
graph_->GetDexFile(), dex::TypeIndex(0), 0, DataType::Type::kReference);
HInstruction* index = new (GetAllocator()) HParameterValue(
graph_->GetDexFile(), dex::TypeIndex(1), 1, DataType::Type::kInt32);
HInstruction* c1 = graph_->GetIntConstant(1);
HInstruction* c2 = graph_->GetIntConstant(2);
HInstruction* c3 = graph_->GetIntConstant(3);
HInstruction* array_get1 = new (GetAllocator()) HArrayGet(array, c1, DataType::Type::kInt32, 0);
HInstruction* array_get2 = new (GetAllocator()) HArrayGet(array, c2, DataType::Type::kInt32, 0);
HInstruction* array_set1 =
new (GetAllocator()) HArraySet(array, c1, c3, DataType::Type::kInt32, 0);
HInstruction* array_set2 =
new (GetAllocator()) HArraySet(array, index, c3, DataType::Type::kInt32, 0);
entry->AddInstruction(array);
entry->AddInstruction(index);
entry->AddInstruction(array_get1);
entry->AddInstruction(array_get2);
entry->AddInstruction(array_set1);
entry->AddInstruction(array_set2);
// Test HeapLocationCollector initialization.
// Should be no heap locations, no operations on the heap.
ScopedArenaAllocator allocator(graph_->GetArenaStack());
HeapLocationCollector heap_location_collector(graph_, &allocator);
ASSERT_EQ(heap_location_collector.GetNumberOfHeapLocations(), 0U);
ASSERT_FALSE(heap_location_collector.HasHeapStores());
// Test that after visiting the graph_, it must see following heap locations
// array[c1], array[c2], array[index]; and it should see heap stores.
heap_location_collector.VisitBasicBlock(entry);
ASSERT_EQ(heap_location_collector.GetNumberOfHeapLocations(), 3U);
ASSERT_TRUE(heap_location_collector.HasHeapStores());
// Test queries on HeapLocationCollector's ref info and index records.
ReferenceInfo* ref = heap_location_collector.FindReferenceInfoOf(array);
DataType::Type type = DataType::Type::kInt32;
size_t field = HeapLocation::kInvalidFieldOffset;
size_t vec = HeapLocation::kScalar;
size_t class_def = HeapLocation::kDeclaringClassDefIndexForArrays;
size_t loc1 = heap_location_collector.FindHeapLocationIndex(
ref, type, field, c1, vec, class_def);
size_t loc2 = heap_location_collector.FindHeapLocationIndex(
ref, type, field, c2, vec, class_def);
size_t loc3 = heap_location_collector.FindHeapLocationIndex(
ref, type, field, index, vec, class_def);
// must find this reference info for array in HeapLocationCollector.
ASSERT_TRUE(ref != nullptr);
// must find these heap locations;
// and array[1], array[2], array[3] should be different heap locations.
ASSERT_TRUE(loc1 != HeapLocationCollector::kHeapLocationNotFound);
ASSERT_TRUE(loc2 != HeapLocationCollector::kHeapLocationNotFound);
ASSERT_TRUE(loc3 != HeapLocationCollector::kHeapLocationNotFound);
ASSERT_TRUE(loc1 != loc2);
ASSERT_TRUE(loc2 != loc3);
ASSERT_TRUE(loc1 != loc3);
// Test alias relationships after building aliasing matrix.
// array[1] and array[2] clearly should not alias;
// array[index] should alias with the others, because index is an unknow value.
heap_location_collector.BuildAliasingMatrix();
ASSERT_FALSE(heap_location_collector.MayAlias(loc1, loc2));
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc3));
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc3));
EXPECT_TRUE(CheckGraph(graph_));
}
TEST_F(LoadStoreAnalysisTest, FieldHeapLocations) {
HBasicBlock* entry = new (GetAllocator()) HBasicBlock(graph_);
graph_->AddBlock(entry);
graph_->SetEntryBlock(entry);
// entry:
// object ParameterValue
// c1 IntConstant
// set_field10 InstanceFieldSet [object, c1, 10]
// get_field10 InstanceFieldGet [object, 10]
// get_field20 InstanceFieldGet [object, 20]
HInstruction* c1 = graph_->GetIntConstant(1);
HInstruction* object = new (GetAllocator()) HParameterValue(graph_->GetDexFile(),
dex::TypeIndex(0),
0,
DataType::Type::kReference);
HInstanceFieldSet* set_field10 = new (GetAllocator()) HInstanceFieldSet(object,
c1,
nullptr,
DataType::Type::kInt32,
MemberOffset(10),
false,
kUnknownFieldIndex,
kUnknownClassDefIndex,
graph_->GetDexFile(),
0);
HInstanceFieldGet* get_field10 = new (GetAllocator()) HInstanceFieldGet(object,
nullptr,
DataType::Type::kInt32,
MemberOffset(10),
false,
kUnknownFieldIndex,
kUnknownClassDefIndex,
graph_->GetDexFile(),
0);
HInstanceFieldGet* get_field20 = new (GetAllocator()) HInstanceFieldGet(object,
nullptr,
DataType::Type::kInt32,
MemberOffset(20),
false,
kUnknownFieldIndex,
kUnknownClassDefIndex,
graph_->GetDexFile(),
0);
entry->AddInstruction(object);
entry->AddInstruction(set_field10);
entry->AddInstruction(get_field10);
entry->AddInstruction(get_field20);
// Test HeapLocationCollector initialization.
// Should be no heap locations, no operations on the heap.
ScopedArenaAllocator allocator(graph_->GetArenaStack());
HeapLocationCollector heap_location_collector(graph_, &allocator);
ASSERT_EQ(heap_location_collector.GetNumberOfHeapLocations(), 0U);
ASSERT_FALSE(heap_location_collector.HasHeapStores());
// Test that after visiting the graph, it must see following heap locations
// object.field10, object.field20 and it should see heap stores.
heap_location_collector.VisitBasicBlock(entry);
ASSERT_EQ(heap_location_collector.GetNumberOfHeapLocations(), 2U);
ASSERT_TRUE(heap_location_collector.HasHeapStores());
// Test queries on HeapLocationCollector's ref info and index records.
ReferenceInfo* ref = heap_location_collector.FindReferenceInfoOf(object);
size_t loc1 = heap_location_collector.GetFieldHeapLocation(object, &get_field10->GetFieldInfo());
size_t loc2 = heap_location_collector.GetFieldHeapLocation(object, &get_field20->GetFieldInfo());
// must find references info for object and in HeapLocationCollector.
ASSERT_TRUE(ref != nullptr);
// must find these heap locations.
ASSERT_TRUE(loc1 != HeapLocationCollector::kHeapLocationNotFound);
ASSERT_TRUE(loc2 != HeapLocationCollector::kHeapLocationNotFound);
// different fields of same object.
ASSERT_TRUE(loc1 != loc2);
// accesses to different fields of the same object should not alias.
ASSERT_FALSE(heap_location_collector.MayAlias(loc1, loc2));
EXPECT_TRUE(CheckGraph(graph_));
}
TEST_F(LoadStoreAnalysisTest, ArrayIndexAliasingTest) {
HBasicBlock* entry = new (GetAllocator()) HBasicBlock(graph_);
graph_->AddBlock(entry);
graph_->SetEntryBlock(entry);
graph_->BuildDominatorTree();
HInstruction* array = new (GetAllocator()) HParameterValue(
graph_->GetDexFile(), dex::TypeIndex(0), 0, DataType::Type::kReference);
HInstruction* index = new (GetAllocator()) HParameterValue(
graph_->GetDexFile(), dex::TypeIndex(1), 1, DataType::Type::kInt32);
HInstruction* c0 = graph_->GetIntConstant(0);
HInstruction* c1 = graph_->GetIntConstant(1);
HInstruction* c_neg1 = graph_->GetIntConstant(-1);
HInstruction* add0 = new (GetAllocator()) HAdd(DataType::Type::kInt32, index, c0);
HInstruction* add1 = new (GetAllocator()) HAdd(DataType::Type::kInt32, index, c1);
HInstruction* sub0 = new (GetAllocator()) HSub(DataType::Type::kInt32, index, c0);
HInstruction* sub1 = new (GetAllocator()) HSub(DataType::Type::kInt32, index, c1);
HInstruction* sub_neg1 = new (GetAllocator()) HSub(DataType::Type::kInt32, index, c_neg1);
HInstruction* rev_sub1 = new (GetAllocator()) HSub(DataType::Type::kInt32, c1, index);
HInstruction* arr_set1 = new (GetAllocator()) HArraySet(array, c0, c0, DataType::Type::kInt32, 0);
HInstruction* arr_set2 = new (GetAllocator()) HArraySet(array, c1, c0, DataType::Type::kInt32, 0);
HInstruction* arr_set3 =
new (GetAllocator()) HArraySet(array, add0, c0, DataType::Type::kInt32, 0);
HInstruction* arr_set4 =
new (GetAllocator()) HArraySet(array, add1, c0, DataType::Type::kInt32, 0);
HInstruction* arr_set5 =
new (GetAllocator()) HArraySet(array, sub0, c0, DataType::Type::kInt32, 0);
HInstruction* arr_set6 =
new (GetAllocator()) HArraySet(array, sub1, c0, DataType::Type::kInt32, 0);
HInstruction* arr_set7 =
new (GetAllocator()) HArraySet(array, rev_sub1, c0, DataType::Type::kInt32, 0);
HInstruction* arr_set8 =
new (GetAllocator()) HArraySet(array, sub_neg1, c0, DataType::Type::kInt32, 0);
entry->AddInstruction(array);
entry->AddInstruction(index);
entry->AddInstruction(add0);
entry->AddInstruction(add1);
entry->AddInstruction(sub0);
entry->AddInstruction(sub1);
entry->AddInstruction(sub_neg1);
entry->AddInstruction(rev_sub1);
entry->AddInstruction(arr_set1); // array[0] = c0
entry->AddInstruction(arr_set2); // array[1] = c0
entry->AddInstruction(arr_set3); // array[i+0] = c0
entry->AddInstruction(arr_set4); // array[i+1] = c0
entry->AddInstruction(arr_set5); // array[i-0] = c0
entry->AddInstruction(arr_set6); // array[i-1] = c0
entry->AddInstruction(arr_set7); // array[1-i] = c0
entry->AddInstruction(arr_set8); // array[i-(-1)] = c0
ScopedArenaAllocator allocator(graph_->GetArenaStack());
LoadStoreAnalysis lsa(graph_, &allocator);
lsa.Run();
const HeapLocationCollector& heap_location_collector = lsa.GetHeapLocationCollector();
// LSA/HeapLocationCollector should see those ArrayGet instructions.
ASSERT_EQ(heap_location_collector.GetNumberOfHeapLocations(), 8U);
ASSERT_TRUE(heap_location_collector.HasHeapStores());
// Test queries on HeapLocationCollector's aliasing matrix after load store analysis.
size_t loc1 = HeapLocationCollector::kHeapLocationNotFound;
size_t loc2 = HeapLocationCollector::kHeapLocationNotFound;
// Test alias: array[0] and array[1]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set1);
loc2 = heap_location_collector.GetArrayHeapLocation(arr_set2);
ASSERT_FALSE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[i+0] and array[i-0]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set3);
loc2 = heap_location_collector.GetArrayHeapLocation(arr_set5);
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[i+1] and array[i-1]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set4);
loc2 = heap_location_collector.GetArrayHeapLocation(arr_set6);
ASSERT_FALSE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[i+1] and array[1-i]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set4);
loc2 = heap_location_collector.GetArrayHeapLocation(arr_set7);
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[i+1] and array[i-(-1)]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set4);
loc2 = heap_location_collector.GetArrayHeapLocation(arr_set8);
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc2));
EXPECT_TRUE(CheckGraphSkipRefTypeInfoChecks(graph_));
}
TEST_F(LoadStoreAnalysisTest, ArrayAliasingTest) {
HBasicBlock* entry = new (GetAllocator()) HBasicBlock(graph_);
graph_->AddBlock(entry);
graph_->SetEntryBlock(entry);
graph_->BuildDominatorTree();
HInstruction* array = new (GetAllocator()) HParameterValue(
graph_->GetDexFile(), dex::TypeIndex(0), 0, DataType::Type::kReference);
HInstruction* index = new (GetAllocator()) HParameterValue(
graph_->GetDexFile(), dex::TypeIndex(1), 1, DataType::Type::kInt32);
HInstruction* c0 = graph_->GetIntConstant(0);
HInstruction* c1 = graph_->GetIntConstant(1);
HInstruction* c6 = graph_->GetIntConstant(6);
HInstruction* c8 = graph_->GetIntConstant(8);
HInstruction* arr_set_0 = new (GetAllocator()) HArraySet(array,
c0,
c0,
DataType::Type::kInt32,
0);
HInstruction* arr_set_1 = new (GetAllocator()) HArraySet(array,
c1,
c0,
DataType::Type::kInt32,
0);
HInstruction* arr_set_i = new (GetAllocator()) HArraySet(array,
index,
c0,
DataType::Type::kInt32,
0);
HVecOperation* v1 = new (GetAllocator()) HVecReplicateScalar(GetAllocator(),
c1,
DataType::Type::kInt32,
4,
kNoDexPc);
HVecOperation* v2 = new (GetAllocator()) HVecReplicateScalar(GetAllocator(),
c1,
DataType::Type::kInt32,
2,
kNoDexPc);
HInstruction* i_add6 = new (GetAllocator()) HAdd(DataType::Type::kInt32, index, c6);
HInstruction* i_add8 = new (GetAllocator()) HAdd(DataType::Type::kInt32, index, c8);
HInstruction* vstore_0 = new (GetAllocator()) HVecStore(
GetAllocator(),
array,
c0,
v1,
DataType::Type::kInt32,
SideEffects::ArrayWriteOfType(DataType::Type::kInt32),
4,
kNoDexPc);
HInstruction* vstore_1 = new (GetAllocator()) HVecStore(
GetAllocator(),
array,
c1,
v1,
DataType::Type::kInt32,
SideEffects::ArrayWriteOfType(DataType::Type::kInt32),
4,
kNoDexPc);
HInstruction* vstore_8 = new (GetAllocator()) HVecStore(
GetAllocator(),
array,
c8,
v1,
DataType::Type::kInt32,
SideEffects::ArrayWriteOfType(DataType::Type::kInt32),
4,
kNoDexPc);
HInstruction* vstore_i = new (GetAllocator()) HVecStore(
GetAllocator(),
array,
index,
v1,
DataType::Type::kInt32,
SideEffects::ArrayWriteOfType(DataType::Type::kInt32),
4,
kNoDexPc);
HInstruction* vstore_i_add6 = new (GetAllocator()) HVecStore(
GetAllocator(),
array,
i_add6,
v1,
DataType::Type::kInt32,
SideEffects::ArrayWriteOfType(DataType::Type::kInt32),
4,
kNoDexPc);
HInstruction* vstore_i_add8 = new (GetAllocator()) HVecStore(
GetAllocator(),
array,
i_add8,
v1,
DataType::Type::kInt32,
SideEffects::ArrayWriteOfType(DataType::Type::kInt32),
4,
kNoDexPc);
HInstruction* vstore_i_add6_vlen2 = new (GetAllocator()) HVecStore(
GetAllocator(),
array,
i_add6,
v2,
DataType::Type::kInt32,
SideEffects::ArrayWriteOfType(DataType::Type::kInt32),
2,
kNoDexPc);
entry->AddInstruction(array);
entry->AddInstruction(index);
entry->AddInstruction(arr_set_0);
entry->AddInstruction(arr_set_1);
entry->AddInstruction(arr_set_i);
entry->AddInstruction(v1);
entry->AddInstruction(v2);
entry->AddInstruction(i_add6);
entry->AddInstruction(i_add8);
entry->AddInstruction(vstore_0);
entry->AddInstruction(vstore_1);
entry->AddInstruction(vstore_8);
entry->AddInstruction(vstore_i);
entry->AddInstruction(vstore_i_add6);
entry->AddInstruction(vstore_i_add8);
entry->AddInstruction(vstore_i_add6_vlen2);
ScopedArenaAllocator allocator(graph_->GetArenaStack());
LoadStoreAnalysis lsa(graph_, &allocator);
lsa.Run();
const HeapLocationCollector& heap_location_collector = lsa.GetHeapLocationCollector();
// LSA/HeapLocationCollector should see those instructions.
ASSERT_EQ(heap_location_collector.GetNumberOfHeapLocations(), 10U);
ASSERT_TRUE(heap_location_collector.HasHeapStores());
// Test queries on HeapLocationCollector's aliasing matrix after load store analysis.
size_t loc1, loc2;
// Test alias: array[0] and array[0,1,2,3]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_0);
loc2 = heap_location_collector.GetArrayHeapLocation(vstore_0);
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[0] and array[1,2,3,4]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_0);
loc2 = heap_location_collector.GetArrayHeapLocation(vstore_1);
ASSERT_FALSE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[0] and array[8,9,10,11]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_0);
loc2 = heap_location_collector.GetArrayHeapLocation(vstore_8);
ASSERT_FALSE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[1] and array[8,9,10,11]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_1);
loc2 = heap_location_collector.GetArrayHeapLocation(vstore_8);
ASSERT_FALSE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[1] and array[0,1,2,3]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_1);
loc2 = heap_location_collector.GetArrayHeapLocation(vstore_0);
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[0,1,2,3] and array[8,9,10,11]
loc1 = heap_location_collector.GetArrayHeapLocation(vstore_0);
loc2 = heap_location_collector.GetArrayHeapLocation(vstore_8);
ASSERT_FALSE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[0,1,2,3] and array[1,2,3,4]
loc1 = heap_location_collector.GetArrayHeapLocation(vstore_0);
loc2 = heap_location_collector.GetArrayHeapLocation(vstore_1);
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[0] and array[i,i+1,i+2,i+3]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_0);
loc2 = heap_location_collector.GetArrayHeapLocation(vstore_i);
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[i] and array[0,1,2,3]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_i);
loc2 = heap_location_collector.GetArrayHeapLocation(vstore_0);
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[i] and array[i,i+1,i+2,i+3]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_i);
loc2 = heap_location_collector.GetArrayHeapLocation(vstore_i);
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[i] and array[i+8,i+9,i+10,i+11]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_i);
loc2 = heap_location_collector.GetArrayHeapLocation(vstore_i_add8);
ASSERT_FALSE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[i+6,i+7,i+8,i+9] and array[i+8,i+9,i+10,i+11]
// Test partial overlap.
loc1 = heap_location_collector.GetArrayHeapLocation(vstore_i_add6);
loc2 = heap_location_collector.GetArrayHeapLocation(vstore_i_add8);
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[i+6,i+7] and array[i,i+1,i+2,i+3]
// Test different vector lengths.
loc1 = heap_location_collector.GetArrayHeapLocation(vstore_i_add6_vlen2);
loc2 = heap_location_collector.GetArrayHeapLocation(vstore_i);
ASSERT_FALSE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[i+6,i+7] and array[i+8,i+9,i+10,i+11]
loc1 = heap_location_collector.GetArrayHeapLocation(vstore_i_add6_vlen2);
loc2 = heap_location_collector.GetArrayHeapLocation(vstore_i_add8);
ASSERT_FALSE(heap_location_collector.MayAlias(loc1, loc2));
}
TEST_F(LoadStoreAnalysisTest, ArrayIndexCalculationOverflowTest) {
HBasicBlock* entry = new (GetAllocator()) HBasicBlock(graph_);
graph_->AddBlock(entry);
graph_->SetEntryBlock(entry);
graph_->BuildDominatorTree();
HInstruction* array = new (GetAllocator()) HParameterValue(
graph_->GetDexFile(), dex::TypeIndex(0), 0, DataType::Type::kReference);
HInstruction* index = new (GetAllocator()) HParameterValue(
graph_->GetDexFile(), dex::TypeIndex(1), 1, DataType::Type::kInt32);
HInstruction* c0 = graph_->GetIntConstant(0);
HInstruction* c_0x80000000 = graph_->GetIntConstant(0x80000000);
HInstruction* c_0x10 = graph_->GetIntConstant(0x10);
HInstruction* c_0xFFFFFFF0 = graph_->GetIntConstant(0xFFFFFFF0);
HInstruction* c_0x7FFFFFFF = graph_->GetIntConstant(0x7FFFFFFF);
HInstruction* c_0x80000001 = graph_->GetIntConstant(0x80000001);
// `index+0x80000000` and `index-0x80000000` array indices MAY alias.
HInstruction* add_0x80000000 = new (GetAllocator()) HAdd(
DataType::Type::kInt32, index, c_0x80000000);
HInstruction* sub_0x80000000 = new (GetAllocator()) HSub(
DataType::Type::kInt32, index, c_0x80000000);
HInstruction* arr_set_1 = new (GetAllocator()) HArraySet(
array, add_0x80000000, c0, DataType::Type::kInt32, 0);
HInstruction* arr_set_2 = new (GetAllocator()) HArraySet(
array, sub_0x80000000, c0, DataType::Type::kInt32, 0);
// `index+0x10` and `index-0xFFFFFFF0` array indices MAY alias.
HInstruction* add_0x10 = new (GetAllocator()) HAdd(DataType::Type::kInt32, index, c_0x10);
HInstruction* sub_0xFFFFFFF0 = new (GetAllocator()) HSub(
DataType::Type::kInt32, index, c_0xFFFFFFF0);
HInstruction* arr_set_3 = new (GetAllocator()) HArraySet(
array, add_0x10, c0, DataType::Type::kInt32, 0);
HInstruction* arr_set_4 = new (GetAllocator()) HArraySet(
array, sub_0xFFFFFFF0, c0, DataType::Type::kInt32, 0);
// `index+0x7FFFFFFF` and `index-0x80000001` array indices MAY alias.
HInstruction* add_0x7FFFFFFF = new (GetAllocator()) HAdd(
DataType::Type::kInt32, index, c_0x7FFFFFFF);
HInstruction* sub_0x80000001 = new (GetAllocator()) HSub(
DataType::Type::kInt32, index, c_0x80000001);
HInstruction* arr_set_5 = new (GetAllocator()) HArraySet(
array, add_0x7FFFFFFF, c0, DataType::Type::kInt32, 0);
HInstruction* arr_set_6 = new (GetAllocator()) HArraySet(
array, sub_0x80000001, c0, DataType::Type::kInt32, 0);
// `index+0` and `index-0` array indices MAY alias.
HInstruction* add_0 = new (GetAllocator()) HAdd(DataType::Type::kInt32, index, c0);
HInstruction* sub_0 = new (GetAllocator()) HSub(DataType::Type::kInt32, index, c0);
HInstruction* arr_set_7 = new (GetAllocator()) HArraySet(
array, add_0, c0, DataType::Type::kInt32, 0);
HInstruction* arr_set_8 = new (GetAllocator()) HArraySet(
array, sub_0, c0, DataType::Type::kInt32, 0);
entry->AddInstruction(array);
entry->AddInstruction(index);
entry->AddInstruction(add_0x80000000);
entry->AddInstruction(sub_0x80000000);
entry->AddInstruction(add_0x10);
entry->AddInstruction(sub_0xFFFFFFF0);
entry->AddInstruction(add_0x7FFFFFFF);
entry->AddInstruction(sub_0x80000001);
entry->AddInstruction(add_0);
entry->AddInstruction(sub_0);
entry->AddInstruction(arr_set_1);
entry->AddInstruction(arr_set_2);
entry->AddInstruction(arr_set_3);
entry->AddInstruction(arr_set_4);
entry->AddInstruction(arr_set_5);
entry->AddInstruction(arr_set_6);
entry->AddInstruction(arr_set_7);
entry->AddInstruction(arr_set_8);
ScopedArenaAllocator allocator(graph_->GetArenaStack());
LoadStoreAnalysis lsa(graph_, &allocator);
lsa.Run();
const HeapLocationCollector& heap_location_collector = lsa.GetHeapLocationCollector();
// LSA/HeapLocationCollector should see those ArrayGet instructions.
ASSERT_EQ(heap_location_collector.GetNumberOfHeapLocations(), 8U);
ASSERT_TRUE(heap_location_collector.HasHeapStores());
// Test queries on HeapLocationCollector's aliasing matrix after load store analysis.
size_t loc1 = HeapLocationCollector::kHeapLocationNotFound;
size_t loc2 = HeapLocationCollector::kHeapLocationNotFound;
// Test alias: array[i+0x80000000] and array[i-0x80000000]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_1);
loc2 = heap_location_collector.GetArrayHeapLocation(arr_set_2);
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[i+0x10] and array[i-0xFFFFFFF0]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_3);
loc2 = heap_location_collector.GetArrayHeapLocation(arr_set_4);
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[i+0x7FFFFFFF] and array[i-0x80000001]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_5);
loc2 = heap_location_collector.GetArrayHeapLocation(arr_set_6);
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc2));
// Test alias: array[i+0] and array[i-0]
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_7);
loc2 = heap_location_collector.GetArrayHeapLocation(arr_set_8);
ASSERT_TRUE(heap_location_collector.MayAlias(loc1, loc2));
// Should not alias:
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_2);
loc2 = heap_location_collector.GetArrayHeapLocation(arr_set_6);
ASSERT_FALSE(heap_location_collector.MayAlias(loc1, loc2));
// Should not alias:
loc1 = heap_location_collector.GetArrayHeapLocation(arr_set_7);
loc2 = heap_location_collector.GetArrayHeapLocation(arr_set_2);
ASSERT_FALSE(heap_location_collector.MayAlias(loc1, loc2));
}
TEST_F(LoadStoreAnalysisTest, TestHuntOriginalRef) {
HBasicBlock* entry = new (GetAllocator()) HBasicBlock(graph_);
graph_->AddBlock(entry);
graph_->SetEntryBlock(entry);
// Different ways where orignal array reference are transformed & passed to ArrayGet.
// ParameterValue --> ArrayGet
// ParameterValue --> BoundType --> ArrayGet
// ParameterValue --> BoundType --> NullCheck --> ArrayGet
// ParameterValue --> BoundType --> NullCheck --> IntermediateAddress --> ArrayGet
HInstruction* c1 = graph_->GetIntConstant(1);
HInstruction* array = new (GetAllocator()) HParameterValue(graph_->GetDexFile(),
dex::TypeIndex(0),
0,
DataType::Type::kReference);
HInstruction* array_get1 = new (GetAllocator()) HArrayGet(array,
c1,
DataType::Type::kInt32,
0);
HInstruction* bound_type = new (GetAllocator()) HBoundType(array);
HInstruction* array_get2 = new (GetAllocator()) HArrayGet(bound_type,
c1,
DataType::Type::kInt32,
0);
HInstruction* null_check = new (GetAllocator()) HNullCheck(bound_type, 0);
HInstruction* array_get3 = new (GetAllocator()) HArrayGet(null_check,
c1,
DataType::Type::kInt32,
0);
HInstruction* inter_addr = new (GetAllocator()) HIntermediateAddress(null_check, c1, 0);
HInstruction* array_get4 = new (GetAllocator()) HArrayGet(inter_addr,
c1,
DataType::Type::kInt32,
0);
entry->AddInstruction(array);
entry->AddInstruction(array_get1);
entry->AddInstruction(bound_type);
entry->AddInstruction(array_get2);
entry->AddInstruction(null_check);
entry->AddInstruction(array_get3);
entry->AddInstruction(inter_addr);
entry->AddInstruction(array_get4);
ScopedArenaAllocator allocator(graph_->GetArenaStack());
HeapLocationCollector heap_location_collector(graph_, &allocator);
heap_location_collector.VisitBasicBlock(entry);
// Test that the HeapLocationCollector should be able to tell
// that there is only ONE array location, no matter how many
// times the original reference has been transformed by BoundType,
// NullCheck, IntermediateAddress, etc.
ASSERT_EQ(heap_location_collector.GetNumberOfHeapLocations(), 1U);
size_t loc1 = heap_location_collector.GetArrayHeapLocation(array_get1);
size_t loc2 = heap_location_collector.GetArrayHeapLocation(array_get2);
size_t loc3 = heap_location_collector.GetArrayHeapLocation(array_get3);
size_t loc4 = heap_location_collector.GetArrayHeapLocation(array_get4);
ASSERT_TRUE(loc1 != HeapLocationCollector::kHeapLocationNotFound);
ASSERT_EQ(loc1, loc2);
ASSERT_EQ(loc1, loc3);
ASSERT_EQ(loc1, loc4);
}
} // namespace art