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LeafOS / LeafOS-Project / android_art / 719d1a33f6569864f529e5a3fff59e7bca97aad0 / . / compiler / optimizing / dominator_test.cc
blob: 30f288ff54dd8b32a592eac9bd64a2088c339d52 [file] [log] [blame]
/*
* 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 "builder.h"
#include "dex_instruction.h"
#include "nodes.h"
#include "utils/arena_allocator.h"
#include "gtest/gtest.h"
namespace art {
static void TestCode(const uint16_t* data, int length, const int* blocks, size_t blocks_length) {
ArenaPool pool;
ArenaAllocator allocator(&pool);
HGraphBuilder builder(&allocator);
HGraph* graph = builder.BuildGraph(data, data + length);
ASSERT_NE(graph, nullptr);
graph->BuildDominatorTree();
ASSERT_EQ(graph->blocks()->Size(), blocks_length);
for (size_t i = 0; i < blocks_length; i++) {
if (blocks[i] == -1) {
ASSERT_EQ(nullptr, graph->blocks()->Get(i)->dominator());
} else {
ASSERT_NE(nullptr, graph->blocks()->Get(i)->dominator());
ASSERT_EQ(blocks[i], graph->blocks()->Get(i)->dominator()->block_id());
}
}
}
TEST(OptimizerTest, ReturnVoid) {
const uint16_t data[] = {
Instruction::RETURN_VOID // Block number 1
};
const int dominators[] = {
-1,
0,
1
};
TestCode(data, sizeof(data) / sizeof(uint16_t), dominators, sizeof(dominators) / sizeof(int));
}
TEST(OptimizerTest, CFG1) {
const uint16_t data[] = {
Instruction::GOTO | 0x100, // Block number 1
Instruction::RETURN_VOID // Block number 2
};
const int dominators[] = {
-1,
0,
1,
2
};
TestCode(data, sizeof(data) / sizeof(uint16_t), dominators, sizeof(dominators) / sizeof(int));
}
TEST(OptimizerTest, CFG2) {
const uint16_t data[] = {
Instruction::GOTO | 0x100, // Block number 1
Instruction::GOTO | 0x100, // Block number 2
Instruction::RETURN_VOID // Block number 3
};
const int dominators[] = {
-1,
0,
1,
2,
3
};
TestCode(data, sizeof(data) / sizeof(uint16_t), dominators, sizeof(dominators) / sizeof(int));
}
TEST(OptimizerTest, CFG3) {
const uint16_t data1[] = {
Instruction::GOTO | 0x200, // Block number 1
Instruction::RETURN_VOID, // Block number 2
Instruction::GOTO | 0xFF00 // Block number 3
};
const int dominators[] = {
-1,
0,
3,
1,
2
};
TestCode(data1, sizeof(data1) / sizeof(uint16_t), dominators, sizeof(dominators) / sizeof(int));
const uint16_t data2[] = {
Instruction::GOTO_16, 3,
Instruction::RETURN_VOID,
Instruction::GOTO_16, 0xFFFF
};
TestCode(data2, sizeof(data2) / sizeof(uint16_t), dominators, sizeof(dominators) / sizeof(int));
const uint16_t data3[] = {
Instruction::GOTO_32, 4, 0,
Instruction::RETURN_VOID,
Instruction::GOTO_32, 0xFFFF, 0xFFFF
};
TestCode(data3, sizeof(data3) / sizeof(uint16_t), dominators, sizeof(dominators) / sizeof(int));
}
TEST(OptimizerTest, CFG4) {
const uint16_t data1[] = {
Instruction::NOP,
Instruction::GOTO | 0xFF00
};
const int dominators[] = {
-1,
0,
-1
};
TestCode(data1, sizeof(data1) / sizeof(uint16_t), dominators, sizeof(dominators) / sizeof(int));
const uint16_t data2[] = {
Instruction::GOTO_32, 0, 0
};
TestCode(data2, sizeof(data2) / sizeof(uint16_t), dominators, sizeof(dominators) / sizeof(int));
}
TEST(OptimizerTest, CFG5) {
const uint16_t data[] = {
Instruction::RETURN_VOID, // Block number 1
Instruction::GOTO | 0x100, // Dead block
Instruction::GOTO | 0xFE00 // Block number 2
};
const int dominators[] = {
-1,
0,
-1,
1
};
TestCode(data, sizeof(data) / sizeof(uint16_t), dominators, sizeof(dominators) / sizeof(int));
}
TEST(OptimizerTest, CFG6) {
const uint16_t data[] = {
Instruction::IF_EQ, 3,
Instruction::GOTO | 0x100,
Instruction::RETURN_VOID
};
const int dominators[] = {
-1,
0,
1,
1,
3
};
TestCode(data, sizeof(data) / sizeof(uint16_t), dominators, sizeof(dominators) / sizeof(int));
}
TEST(OptimizerTest, CFG7) {
const uint16_t data[] = {
Instruction::IF_EQ, 3, // Block number 1
Instruction::GOTO | 0x100, // Block number 2
Instruction::GOTO | 0xFF00 // Block number 3
};
const int dominators[] = {
-1,
0,
1,
1,
-1 // exit block is not dominated by any block due to the spin loop.
};
TestCode(data, sizeof(data) / sizeof(uint16_t), dominators, sizeof(dominators) / sizeof(int));
}
TEST(OptimizerTest, CFG8) {
const uint16_t data[] = {
Instruction::IF_EQ, 3, // Block number 1
Instruction::GOTO | 0x200, // Block number 2
Instruction::GOTO | 0x100, // Block number 3
Instruction::GOTO | 0xFF00 // Block number 4
};
const int dominators[] = {
-1,
0,
1,
1,
1,
-1 // exit block is not dominated by any block due to the spin loop.
};
TestCode(data, sizeof(data) / sizeof(uint16_t), dominators, sizeof(dominators) / sizeof(int));
}
TEST(OptimizerTest, CFG9) {
const uint16_t data[] = {
Instruction::IF_EQ, 3, // Block number 1
Instruction::GOTO | 0x200, // Block number 2
Instruction::GOTO | 0x100, // Block number 3
Instruction::GOTO | 0xFE00 // Block number 4
};
const int dominators[] = {
-1,
0,
1,
1,
1,
-1 // exit block is not dominated by any block due to the spin loop.
};
TestCode(data, sizeof(data) / sizeof(uint16_t), dominators, sizeof(dominators) / sizeof(int));
}
TEST(OptimizerTest, CFG10) {
const uint16_t data[] = {
Instruction::IF_EQ, 6, // Block number 1
Instruction::IF_EQ, 3, // Block number 2
Instruction::GOTO | 0x100, // Block number 3
Instruction::GOTO | 0x100, // Block number 4
Instruction::RETURN_VOID // Block number 5
};
const int dominators[] = {
-1,
0,
1,
2,
2,
1,
5 // Block number 5 dominates exit block
};
TestCode(data, sizeof(data) / sizeof(uint16_t), dominators, sizeof(dominators) / sizeof(int));
}
} // namespace art