/* * Copyright (C) 2018 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 #include #include #include #include #include "ElfTestUtils.h" #include "MemoryFake.h" namespace unwindstack { class ElfCacheTest : public ::testing::Test { protected: static void SetUpTestSuite() { memory_.reset(new MemoryFake); } void SetUp() override { Elf::SetCachingEnabled(true); } void TearDown() override { Elf::SetCachingEnabled(false); } void WriteElfFile(uint64_t offset, TemporaryFile* tf, uint32_t type) { ASSERT_TRUE(type == EM_ARM || type == EM_386 || type == EM_X86_64); size_t ehdr_size; Elf32_Ehdr ehdr32; Elf64_Ehdr ehdr64; void* ptr; if (type == EM_ARM || type == EM_386) { ehdr_size = sizeof(ehdr32); ptr = &ehdr32; TestInitEhdr(&ehdr32, ELFCLASS32, type); } else { ehdr_size = sizeof(ehdr64); ptr = &ehdr64; TestInitEhdr(&ehdr64, ELFCLASS64, type); } ASSERT_EQ(offset, static_cast(lseek(tf->fd, offset, SEEK_SET))); ASSERT_TRUE(android::base::WriteFully(tf->fd, ptr, ehdr_size)); } void VerifyWithinSameMap(bool cache_enabled); void VerifySameMap(bool cache_enabled); void VerifyWithinSameMapNeverReadAtZero(bool cache_enabled); static std::shared_ptr memory_; }; std::shared_ptr ElfCacheTest::memory_; void ElfCacheTest::VerifySameMap(bool cache_enabled) { if (!cache_enabled) { Elf::SetCachingEnabled(false); } TemporaryFile tf; ASSERT_TRUE(tf.fd != -1); WriteElfFile(0, &tf, EM_ARM); close(tf.fd); uint64_t start = 0x1000; uint64_t end = 0x20000; MapInfo info1(nullptr, nullptr, start, end, 0, 0x5, tf.path); MapInfo info2(nullptr, nullptr, start, end, 0, 0x5, tf.path); Elf* elf1 = info1.GetElf(memory_, ARCH_ARM); ASSERT_TRUE(elf1->valid()); Elf* elf2 = info2.GetElf(memory_, ARCH_ARM); ASSERT_TRUE(elf2->valid()); if (cache_enabled) { EXPECT_EQ(elf1, elf2); } else { EXPECT_NE(elf1, elf2); } } TEST_F(ElfCacheTest, no_caching) { VerifySameMap(false); } TEST_F(ElfCacheTest, caching_invalid_elf) { VerifySameMap(true); } void ElfCacheTest::VerifyWithinSameMap(bool cache_enabled) { if (!cache_enabled) { Elf::SetCachingEnabled(false); } TemporaryFile tf; ASSERT_TRUE(tf.fd != -1); WriteElfFile(0, &tf, EM_ARM); WriteElfFile(0x100, &tf, EM_386); WriteElfFile(0x200, &tf, EM_X86_64); lseek(tf.fd, 0x500, SEEK_SET); uint8_t value = 0; write(tf.fd, &value, 1); close(tf.fd); uint64_t start = 0x1000; uint64_t end = 0x20000; // Will have an elf at offset 0 in file. MapInfo info0_1(nullptr, nullptr, start, end, 0, 0x5, tf.path); MapInfo info0_2(nullptr, nullptr, start, end, 0, 0x5, tf.path); // Will have an elf at offset 0x100 in file. MapInfo info100_1(nullptr, nullptr, start, end, 0x100, 0x5, tf.path); MapInfo info100_2(nullptr, nullptr, start, end, 0x100, 0x5, tf.path); // Will have an elf at offset 0x200 in file. MapInfo info200_1(nullptr, nullptr, start, end, 0x200, 0x5, tf.path); MapInfo info200_2(nullptr, nullptr, start, end, 0x200, 0x5, tf.path); // Will have an elf at offset 0 in file. MapInfo info300_1(nullptr, nullptr, start, end, 0x300, 0x5, tf.path); MapInfo info300_2(nullptr, nullptr, start, end, 0x300, 0x5, tf.path); Elf* elf0_1 = info0_1.GetElf(memory_, ARCH_ARM); ASSERT_TRUE(elf0_1->valid()); EXPECT_EQ(ARCH_ARM, elf0_1->arch()); Elf* elf0_2 = info0_2.GetElf(memory_, ARCH_ARM); ASSERT_TRUE(elf0_2->valid()); EXPECT_EQ(ARCH_ARM, elf0_2->arch()); EXPECT_EQ(0U, info0_1.elf_offset()); EXPECT_EQ(0U, info0_2.elf_offset()); if (cache_enabled) { EXPECT_EQ(elf0_1, elf0_2); } else { EXPECT_NE(elf0_1, elf0_2); } Elf* elf100_1 = info100_1.GetElf(memory_, ARCH_X86); ASSERT_TRUE(elf100_1->valid()); EXPECT_EQ(ARCH_X86, elf100_1->arch()); Elf* elf100_2 = info100_2.GetElf(memory_, ARCH_X86); ASSERT_TRUE(elf100_2->valid()); EXPECT_EQ(ARCH_X86, elf100_2->arch()); EXPECT_EQ(0U, info100_1.elf_offset()); EXPECT_EQ(0U, info100_2.elf_offset()); if (cache_enabled) { EXPECT_EQ(elf100_1, elf100_2); } else { EXPECT_NE(elf100_1, elf100_2); } Elf* elf200_1 = info200_1.GetElf(memory_, ARCH_X86_64); ASSERT_TRUE(elf200_1->valid()); EXPECT_EQ(ARCH_X86_64, elf200_1->arch()); Elf* elf200_2 = info200_2.GetElf(memory_, ARCH_X86_64); ASSERT_TRUE(elf200_2->valid()); EXPECT_EQ(ARCH_X86_64, elf200_2->arch()); EXPECT_EQ(0U, info200_1.elf_offset()); EXPECT_EQ(0U, info200_2.elf_offset()); if (cache_enabled) { EXPECT_EQ(elf200_1, elf200_2); } else { EXPECT_NE(elf200_1, elf200_2); } Elf* elf300_1 = info300_1.GetElf(memory_, ARCH_ARM); ASSERT_TRUE(elf300_1->valid()); EXPECT_EQ(ARCH_ARM, elf300_1->arch()); Elf* elf300_2 = info300_2.GetElf(memory_, ARCH_ARM); ASSERT_TRUE(elf300_2->valid()); EXPECT_EQ(ARCH_ARM, elf300_2->arch()); EXPECT_EQ(0x300U, info300_1.elf_offset()); EXPECT_EQ(0x300U, info300_2.elf_offset()); if (cache_enabled) { EXPECT_EQ(elf300_1, elf300_2); EXPECT_EQ(elf0_1, elf300_1); } else { EXPECT_NE(elf300_1, elf300_2); EXPECT_NE(elf0_1, elf300_1); } } TEST_F(ElfCacheTest, no_caching_valid_elf_offset_non_zero) { VerifyWithinSameMap(false); } TEST_F(ElfCacheTest, caching_valid_elf_offset_non_zero) { VerifyWithinSameMap(true); } // Verify that when reading from multiple non-zero offsets in the same map // that when cached, all of the elf objects are the same. void ElfCacheTest::VerifyWithinSameMapNeverReadAtZero(bool cache_enabled) { if (!cache_enabled) { Elf::SetCachingEnabled(false); } TemporaryFile tf; ASSERT_TRUE(tf.fd != -1); WriteElfFile(0, &tf, EM_ARM); lseek(tf.fd, 0x500, SEEK_SET); uint8_t value = 0; write(tf.fd, &value, 1); close(tf.fd); uint64_t start = 0x1000; uint64_t end = 0x20000; // Multiple info sections at different offsets will have non-zero elf offsets. MapInfo info300_1(nullptr, nullptr, start, end, 0x300, 0x5, tf.path); MapInfo info300_2(nullptr, nullptr, start, end, 0x300, 0x5, tf.path); MapInfo info400_1(nullptr, nullptr, start, end, 0x400, 0x5, tf.path); MapInfo info400_2(nullptr, nullptr, start, end, 0x400, 0x5, tf.path); Elf* elf300_1 = info300_1.GetElf(memory_, ARCH_ARM); ASSERT_TRUE(elf300_1->valid()); EXPECT_EQ(ARCH_ARM, elf300_1->arch()); Elf* elf300_2 = info300_2.GetElf(memory_, ARCH_ARM); ASSERT_TRUE(elf300_2->valid()); EXPECT_EQ(ARCH_ARM, elf300_2->arch()); EXPECT_EQ(0x300U, info300_1.elf_offset()); EXPECT_EQ(0x300U, info300_2.elf_offset()); if (cache_enabled) { EXPECT_EQ(elf300_1, elf300_2); } else { EXPECT_NE(elf300_1, elf300_2); } Elf* elf400_1 = info400_1.GetElf(memory_, ARCH_ARM); ASSERT_TRUE(elf400_1->valid()); EXPECT_EQ(ARCH_ARM, elf400_1->arch()); Elf* elf400_2 = info400_2.GetElf(memory_, ARCH_ARM); ASSERT_TRUE(elf400_2->valid()); EXPECT_EQ(ARCH_ARM, elf400_2->arch()); EXPECT_EQ(0x400U, info400_1.elf_offset()); EXPECT_EQ(0x400U, info400_2.elf_offset()); if (cache_enabled) { EXPECT_EQ(elf400_1, elf400_2); EXPECT_EQ(elf300_1, elf400_1); } else { EXPECT_NE(elf400_1, elf400_2); EXPECT_NE(elf300_1, elf400_1); } } TEST_F(ElfCacheTest, no_caching_valid_elf_offset_non_zero_never_read_at_zero) { VerifyWithinSameMapNeverReadAtZero(false); } TEST_F(ElfCacheTest, caching_valid_elf_offset_non_zero_never_read_at_zero) { VerifyWithinSameMapNeverReadAtZero(true); } } // namespace unwindstack