/* * 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 #include #include #include #include "ElfFake.h" #include "MemoryFake.h" namespace unwindstack { class JitDebugTest : public ::testing::Test { protected: void CreateFakeElf(MapInfo* map_info) { MemoryFake* memory = new MemoryFake; ElfFake* elf = new ElfFake(memory); elf->FakeSetValid(true); ElfInterfaceFake* interface = new ElfInterfaceFake(memory); elf->FakeSetInterface(interface); interface->FakeSetGlobalVariable("__jit_debug_descriptor", 0x800); map_info->elf.reset(elf); } void Init(ArchEnum arch) { jit_debug_.reset(new JitDebug(process_memory_)); jit_debug_->SetArch(arch); maps_.reset( new BufferMaps("1000-4000 ---s 00000000 00:00 0 /fake/elf1\n" "4000-6000 r--s 00000000 00:00 0 /fake/elf1\n" "6000-8000 -wxs 00000000 00:00 0 /fake/elf1\n" "a000-c000 --xp 00000000 00:00 0 /fake/elf2\n" "c000-f000 rw-p 00001000 00:00 0 /fake/elf2\n" "f000-11000 r--p 00000000 00:00 0 /fake/elf3\n" "11000-12000 rw-p 00001000 00:00 0 /fake/elf3\n" "12000-14000 r--p 00000000 00:00 0 /fake/elf4\n" "100000-110000 rw-p 0001000 00:00 0 /fake/elf4\n" "200000-210000 rw-p 0002000 00:00 0 /fake/elf4\n")); ASSERT_TRUE(maps_->Parse()); MapInfo* map_info = maps_->Get(3); ASSERT_TRUE(map_info != nullptr); CreateFakeElf(map_info); map_info = maps_->Get(5); ASSERT_TRUE(map_info != nullptr); CreateFakeElf(map_info); map_info = maps_->Get(7); ASSERT_TRUE(map_info != nullptr); CreateFakeElf(map_info); } void SetUp() override { memory_ = new MemoryFake; process_memory_.reset(memory_); Init(ARCH_ARM); } template void CreateElf(uint64_t offset, uint8_t class_type, uint8_t machine_type, uint32_t pc, uint32_t size) { EhdrType ehdr; memset(&ehdr, 0, sizeof(ehdr)); uint64_t sh_offset = sizeof(ehdr); memcpy(ehdr.e_ident, ELFMAG, SELFMAG); ehdr.e_ident[EI_CLASS] = class_type; ehdr.e_machine = machine_type; ehdr.e_shstrndx = 1; ehdr.e_shoff = sh_offset; ehdr.e_shentsize = sizeof(ShdrType); ehdr.e_shnum = 3; memory_->SetMemory(offset, &ehdr, sizeof(ehdr)); ShdrType shdr; memset(&shdr, 0, sizeof(shdr)); shdr.sh_type = SHT_NULL; memory_->SetMemory(offset + sh_offset, &shdr, sizeof(shdr)); sh_offset += sizeof(shdr); memset(&shdr, 0, sizeof(shdr)); shdr.sh_type = SHT_STRTAB; shdr.sh_name = 1; shdr.sh_offset = 0x500; shdr.sh_size = 0x100; memory_->SetMemory(offset + sh_offset, &shdr, sizeof(shdr)); memory_->SetMemory(offset + 0x500, ".debug_frame"); sh_offset += sizeof(shdr); memset(&shdr, 0, sizeof(shdr)); shdr.sh_type = SHT_PROGBITS; shdr.sh_name = 0; shdr.sh_addr = 0x600; shdr.sh_offset = 0x600; shdr.sh_size = 0x200; memory_->SetMemory(offset + sh_offset, &shdr, sizeof(shdr)); // Now add a single cie/fde. uint64_t dwarf_offset = offset + 0x600; if (class_type == ELFCLASS32) { // CIE 32 information. memory_->SetData32(dwarf_offset, 0xfc); memory_->SetData32(dwarf_offset + 0x4, 0xffffffff); memory_->SetData8(dwarf_offset + 0x8, 1); memory_->SetData8(dwarf_offset + 0x9, '\0'); memory_->SetData8(dwarf_offset + 0xa, 0x4); memory_->SetData8(dwarf_offset + 0xb, 0x4); memory_->SetData8(dwarf_offset + 0xc, 0x1); // FDE 32 information. memory_->SetData32(dwarf_offset + 0x100, 0xfc); memory_->SetData32(dwarf_offset + 0x104, 0); memory_->SetData32(dwarf_offset + 0x108, pc); memory_->SetData32(dwarf_offset + 0x10c, size); } else { // CIE 64 information. memory_->SetData32(dwarf_offset, 0xffffffff); memory_->SetData64(dwarf_offset + 4, 0xf4); memory_->SetData64(dwarf_offset + 0xc, 0xffffffffffffffffULL); memory_->SetData8(dwarf_offset + 0x14, 1); memory_->SetData8(dwarf_offset + 0x15, '\0'); memory_->SetData8(dwarf_offset + 0x16, 0x4); memory_->SetData8(dwarf_offset + 0x17, 0x4); memory_->SetData8(dwarf_offset + 0x18, 0x1); // FDE 64 information. memory_->SetData32(dwarf_offset + 0x100, 0xffffffff); memory_->SetData64(dwarf_offset + 0x104, 0xf4); memory_->SetData64(dwarf_offset + 0x10c, 0); memory_->SetData64(dwarf_offset + 0x114, pc); memory_->SetData64(dwarf_offset + 0x11c, size); } } void WriteDescriptor32(uint64_t addr, uint32_t entry); void WriteDescriptor64(uint64_t addr, uint64_t entry); void WriteEntry32Pack(uint64_t addr, uint32_t prev, uint32_t next, uint32_t elf_addr, uint64_t elf_size); void WriteEntry32Pad(uint64_t addr, uint32_t prev, uint32_t next, uint32_t elf_addr, uint64_t elf_size); void WriteEntry64(uint64_t addr, uint64_t prev, uint64_t next, uint64_t elf_addr, uint64_t elf_size); std::shared_ptr process_memory_; MemoryFake* memory_; std::unique_ptr jit_debug_; std::unique_ptr maps_; }; void JitDebugTest::WriteDescriptor32(uint64_t addr, uint32_t entry) { // Format of the 32 bit JITDescriptor structure: // uint32_t version memory_->SetData32(addr, 1); // uint32_t action_flag memory_->SetData32(addr + 4, 0); // uint32_t relevant_entry memory_->SetData32(addr + 8, 0); // uint32_t first_entry memory_->SetData32(addr + 12, entry); } void JitDebugTest::WriteDescriptor64(uint64_t addr, uint64_t entry) { // Format of the 64 bit JITDescriptor structure: // uint32_t version memory_->SetData32(addr, 1); // uint32_t action_flag memory_->SetData32(addr + 4, 0); // uint64_t relevant_entry memory_->SetData64(addr + 8, 0); // uint64_t first_entry memory_->SetData64(addr + 16, entry); } void JitDebugTest::WriteEntry32Pack(uint64_t addr, uint32_t prev, uint32_t next, uint32_t elf_addr, uint64_t elf_size) { // Format of the 32 bit JITCodeEntry structure: // uint32_t next memory_->SetData32(addr, next); // uint32_t prev memory_->SetData32(addr + 4, prev); // uint32_t symfile_addr memory_->SetData32(addr + 8, elf_addr); // uint64_t symfile_size memory_->SetData64(addr + 12, elf_size); } void JitDebugTest::WriteEntry32Pad(uint64_t addr, uint32_t prev, uint32_t next, uint32_t elf_addr, uint64_t elf_size) { // Format of the 32 bit JITCodeEntry structure: // uint32_t next memory_->SetData32(addr, next); // uint32_t prev memory_->SetData32(addr + 4, prev); // uint32_t symfile_addr memory_->SetData32(addr + 8, elf_addr); // uint32_t pad memory_->SetData32(addr + 12, 0); // uint64_t symfile_size memory_->SetData64(addr + 16, elf_size); } void JitDebugTest::WriteEntry64(uint64_t addr, uint64_t prev, uint64_t next, uint64_t elf_addr, uint64_t elf_size) { // Format of the 64 bit JITCodeEntry structure: // uint64_t next memory_->SetData64(addr, next); // uint64_t prev memory_->SetData64(addr + 8, prev); // uint64_t symfile_addr memory_->SetData64(addr + 16, elf_addr); // uint64_t symfile_size memory_->SetData64(addr + 24, elf_size); } TEST_F(JitDebugTest, get_elf_invalid) { Elf* elf = jit_debug_->GetElf(maps_.get(), 0x1500); ASSERT_TRUE(elf == nullptr); } TEST_F(JitDebugTest, get_elf_no_global_variable) { maps_.reset(new BufferMaps("")); Elf* elf = jit_debug_->GetElf(maps_.get(), 0x1500); ASSERT_TRUE(elf == nullptr); } TEST_F(JitDebugTest, get_elf_no_valid_descriptor_in_memory) { CreateElf(0x4000, ELFCLASS32, EM_ARM, 0x1500, 0x200); Elf* elf = jit_debug_->GetElf(maps_.get(), 0x1500); ASSERT_TRUE(elf == nullptr); } TEST_F(JitDebugTest, get_elf_no_valid_code_entry) { CreateElf(0x4000, ELFCLASS32, EM_ARM, 0x1500, 0x200); WriteDescriptor32(0xf800, 0x200000); Elf* elf = jit_debug_->GetElf(maps_.get(), 0x1500); ASSERT_TRUE(elf == nullptr); } TEST_F(JitDebugTest, get_elf_invalid_descriptor_first_entry) { CreateElf(0x4000, ELFCLASS32, EM_ARM, 0x1500, 0x200); WriteDescriptor32(0xf800, 0); Elf* elf = jit_debug_->GetElf(maps_.get(), 0x1500); ASSERT_TRUE(elf == nullptr); } TEST_F(JitDebugTest, get_elf_invalid_descriptor_version) { CreateElf(0x4000, ELFCLASS32, EM_ARM, 0x1500, 0x200); WriteDescriptor32(0xf800, 0x20000); // Set the version to an invalid value. memory_->SetData32(0xf800, 2); Elf* elf = jit_debug_->GetElf(maps_.get(), 0x1500); ASSERT_TRUE(elf == nullptr); } TEST_F(JitDebugTest, get_elf_32) { CreateElf(0x4000, ELFCLASS32, EM_ARM, 0x1500, 0x200); WriteDescriptor32(0xf800, 0x200000); WriteEntry32Pad(0x200000, 0, 0, 0x4000, 0x1000); Elf* elf = jit_debug_->GetElf(maps_.get(), 0x1500); ASSERT_TRUE(elf != nullptr); // Clear the memory and verify all of the data is cached. memory_->Clear(); Elf* elf2 = jit_debug_->GetElf(maps_.get(), 0x1500); ASSERT_TRUE(elf2 != nullptr); EXPECT_EQ(elf, elf2); } TEST_F(JitDebugTest, get_multiple_jit_debug_descriptors_valid) { CreateElf(0x4000, ELFCLASS32, EM_ARM, 0x1500, 0x200); CreateElf(0x5000, ELFCLASS32, EM_ARM, 0x2000, 0x300); WriteDescriptor32(0xf800, 0x200000); WriteEntry32Pad(0x200000, 0, 0, 0x4000, 0x1000); WriteDescriptor32(0x12800, 0x201000); WriteEntry32Pad(0x201000, 0, 0, 0x5000, 0x1000); ASSERT_TRUE(jit_debug_->GetElf(maps_.get(), 0x1500) != nullptr); ASSERT_TRUE(jit_debug_->GetElf(maps_.get(), 0x2000) == nullptr); // Now clear the descriptor entry for the first one. WriteDescriptor32(0xf800, 0); jit_debug_.reset(new JitDebug(process_memory_)); jit_debug_->SetArch(ARCH_ARM); ASSERT_TRUE(jit_debug_->GetElf(maps_.get(), 0x1500) == nullptr); ASSERT_TRUE(jit_debug_->GetElf(maps_.get(), 0x2000) != nullptr); } TEST_F(JitDebugTest, get_elf_x86) { Init(ARCH_X86); CreateElf(0x4000, ELFCLASS32, EM_ARM, 0x1500, 0x200); WriteDescriptor32(0xf800, 0x200000); WriteEntry32Pack(0x200000, 0, 0, 0x4000, 0x1000); jit_debug_->SetArch(ARCH_X86); Elf* elf = jit_debug_->GetElf(maps_.get(), 0x1500); ASSERT_TRUE(elf != nullptr); // Clear the memory and verify all of the data is cached. memory_->Clear(); Elf* elf2 = jit_debug_->GetElf(maps_.get(), 0x1500); ASSERT_TRUE(elf2 != nullptr); EXPECT_EQ(elf, elf2); } TEST_F(JitDebugTest, get_elf_64) { Init(ARCH_ARM64); CreateElf(0x4000, ELFCLASS64, EM_AARCH64, 0x1500, 0x200); WriteDescriptor64(0xf800, 0x200000); WriteEntry64(0x200000, 0, 0, 0x4000, 0x1000); Elf* elf = jit_debug_->GetElf(maps_.get(), 0x1500); ASSERT_TRUE(elf != nullptr); // Clear the memory and verify all of the data is cached. memory_->Clear(); Elf* elf2 = jit_debug_->GetElf(maps_.get(), 0x1500); ASSERT_TRUE(elf2 != nullptr); EXPECT_EQ(elf, elf2); } TEST_F(JitDebugTest, get_elf_multiple_entries) { CreateElf(0x4000, ELFCLASS32, EM_ARM, 0x1500, 0x200); CreateElf(0x5000, ELFCLASS32, EM_ARM, 0x2300, 0x400); WriteDescriptor32(0xf800, 0x200000); WriteEntry32Pad(0x200000, 0, 0x200100, 0x4000, 0x1000); WriteEntry32Pad(0x200100, 0x200100, 0, 0x5000, 0x1000); Elf* elf_2 = jit_debug_->GetElf(maps_.get(), 0x2400); ASSERT_TRUE(elf_2 != nullptr); Elf* elf_1 = jit_debug_->GetElf(maps_.get(), 0x1600); ASSERT_TRUE(elf_1 != nullptr); // Clear the memory and verify all of the data is cached. memory_->Clear(); EXPECT_EQ(elf_1, jit_debug_->GetElf(maps_.get(), 0x1500)); EXPECT_EQ(elf_1, jit_debug_->GetElf(maps_.get(), 0x16ff)); EXPECT_EQ(elf_2, jit_debug_->GetElf(maps_.get(), 0x2300)); EXPECT_EQ(elf_2, jit_debug_->GetElf(maps_.get(), 0x26ff)); EXPECT_EQ(nullptr, jit_debug_->GetElf(maps_.get(), 0x1700)); EXPECT_EQ(nullptr, jit_debug_->GetElf(maps_.get(), 0x2700)); } TEST_F(JitDebugTest, get_elf_search_libs) { CreateElf(0x4000, ELFCLASS32, EM_ARM, 0x1500, 0x200); WriteDescriptor32(0xf800, 0x200000); WriteEntry32Pad(0x200000, 0, 0, 0x4000, 0x1000); // Only search a given named list of libs. std::vector libs{"libart.so"}; jit_debug_.reset(new JitDebug(process_memory_, libs)); jit_debug_->SetArch(ARCH_ARM); EXPECT_TRUE(jit_debug_->GetElf(maps_.get(), 0x1500) == nullptr); // Change the name of the map that includes the value and verify this works. MapInfo* map_info = maps_->Get(5); map_info->name = "/system/lib/libart.so"; map_info = maps_->Get(6); map_info->name = "/system/lib/libart.so"; jit_debug_.reset(new JitDebug(process_memory_, libs)); // Make sure that clearing our copy of the libs doesn't affect the // JitDebug object. libs.clear(); jit_debug_->SetArch(ARCH_ARM); EXPECT_TRUE(jit_debug_->GetElf(maps_.get(), 0x1500) != nullptr); } } // namespace unwindstack