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af66a21d42
getRelocatedSection interface should not check that the object file is relocatable, as executable files may have relocations preserved with `--emit-relocs` linker flag. The relocations are useful in context of post-link binary analysis for function reference identification. For example, BOLT relies on relocations to perform function reordering. Reviewed By: MaskRay, jhenderson Differential Revision: https://reviews.llvm.org/D102296
658 lines
23 KiB
C++
658 lines
23 KiB
C++
//===- ELFObjectFileTest.cpp - Tests for ELFObjectFile --------------------===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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#include "llvm/Object/ELFObjectFile.h"
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#include "llvm/Support/MemoryBuffer.h"
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#include "llvm/ObjectYAML/yaml2obj.h"
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#include "llvm/Support/YAMLTraits.h"
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#include "llvm/Testing/Support/Error.h"
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#include "gtest/gtest.h"
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using namespace llvm;
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using namespace llvm::object;
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namespace {
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// A struct to initialize a buffer to represent an ELF object file.
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struct DataForTest {
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std::vector<uint8_t> Data;
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template <typename T>
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std::vector<uint8_t> makeElfData(uint8_t Class, uint8_t Encoding,
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uint16_t Machine) {
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T Ehdr{}; // Zero-initialise the header.
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Ehdr.e_ident[ELF::EI_MAG0] = 0x7f;
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Ehdr.e_ident[ELF::EI_MAG1] = 'E';
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Ehdr.e_ident[ELF::EI_MAG2] = 'L';
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Ehdr.e_ident[ELF::EI_MAG3] = 'F';
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Ehdr.e_ident[ELF::EI_CLASS] = Class;
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Ehdr.e_ident[ELF::EI_DATA] = Encoding;
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Ehdr.e_ident[ELF::EI_VERSION] = 1;
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Ehdr.e_type = ELF::ET_REL;
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Ehdr.e_machine = Machine;
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Ehdr.e_version = 1;
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Ehdr.e_ehsize = sizeof(T);
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bool IsLittleEndian = Encoding == ELF::ELFDATA2LSB;
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if (sys::IsLittleEndianHost != IsLittleEndian) {
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sys::swapByteOrder(Ehdr.e_type);
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sys::swapByteOrder(Ehdr.e_machine);
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sys::swapByteOrder(Ehdr.e_version);
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sys::swapByteOrder(Ehdr.e_ehsize);
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}
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uint8_t *EhdrBytes = reinterpret_cast<uint8_t *>(&Ehdr);
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std::vector<uint8_t> Bytes;
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std::copy(EhdrBytes, EhdrBytes + sizeof(Ehdr), std::back_inserter(Bytes));
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return Bytes;
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}
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DataForTest(uint8_t Class, uint8_t Encoding, uint16_t Machine) {
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if (Class == ELF::ELFCLASS64)
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Data = makeElfData<ELF::Elf64_Ehdr>(Class, Encoding, Machine);
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else {
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assert(Class == ELF::ELFCLASS32);
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Data = makeElfData<ELF::Elf32_Ehdr>(Class, Encoding, Machine);
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}
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}
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};
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void checkFormatAndArch(const DataForTest &D, StringRef Fmt,
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Triple::ArchType Arch) {
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Expected<std::unique_ptr<ObjectFile>> ELFObjOrErr =
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object::ObjectFile::createELFObjectFile(
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MemoryBufferRef(toStringRef(D.Data), "dummyELF"));
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ASSERT_THAT_EXPECTED(ELFObjOrErr, Succeeded());
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const ObjectFile &File = *(*ELFObjOrErr).get();
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EXPECT_EQ(Fmt, File.getFileFormatName());
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EXPECT_EQ(Arch, File.getArch());
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}
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std::array<DataForTest, 4> generateData(uint16_t Machine) {
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return {DataForTest(ELF::ELFCLASS32, ELF::ELFDATA2LSB, Machine),
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DataForTest(ELF::ELFCLASS32, ELF::ELFDATA2MSB, Machine),
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DataForTest(ELF::ELFCLASS64, ELF::ELFDATA2LSB, Machine),
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DataForTest(ELF::ELFCLASS64, ELF::ELFDATA2MSB, Machine)};
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}
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} // namespace
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TEST(ELFObjectFileTest, MachineTestForNoneOrUnused) {
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std::array<StringRef, 4> Formats = {"elf32-unknown", "elf32-unknown",
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"elf64-unknown", "elf64-unknown"};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_NONE))
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checkFormatAndArch(D, Formats[I++], Triple::UnknownArch);
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// Test an arbitrary unused EM_* value (255).
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I = 0;
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for (const DataForTest &D : generateData(255))
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checkFormatAndArch(D, Formats[I++], Triple::UnknownArch);
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}
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TEST(ELFObjectFileTest, MachineTestForVE) {
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std::array<StringRef, 4> Formats = {"elf32-unknown", "elf32-unknown",
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"elf64-ve", "elf64-ve"};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_VE))
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checkFormatAndArch(D, Formats[I++], Triple::ve);
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}
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TEST(ELFObjectFileTest, MachineTestForX86_64) {
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std::array<StringRef, 4> Formats = {"elf32-x86-64", "elf32-x86-64",
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"elf64-x86-64", "elf64-x86-64"};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_X86_64))
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checkFormatAndArch(D, Formats[I++], Triple::x86_64);
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}
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TEST(ELFObjectFileTest, MachineTestFor386) {
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std::array<StringRef, 4> Formats = {"elf32-i386", "elf32-i386", "elf64-i386",
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"elf64-i386"};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_386))
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checkFormatAndArch(D, Formats[I++], Triple::x86);
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}
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TEST(ELFObjectFileTest, MachineTestForMIPS) {
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std::array<StringRef, 4> Formats = {"elf32-mips", "elf32-mips", "elf64-mips",
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"elf64-mips"};
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std::array<Triple::ArchType, 4> Archs = {Triple::mipsel, Triple::mips,
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Triple::mips64el, Triple::mips64};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_MIPS)) {
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checkFormatAndArch(D, Formats[I], Archs[I]);
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++I;
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}
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}
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TEST(ELFObjectFileTest, MachineTestForAMDGPU) {
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std::array<StringRef, 4> Formats = {"elf32-amdgpu", "elf32-amdgpu",
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"elf64-amdgpu", "elf64-amdgpu"};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_AMDGPU))
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checkFormatAndArch(D, Formats[I++], Triple::UnknownArch);
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}
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TEST(ELFObjectFileTest, MachineTestForIAMCU) {
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std::array<StringRef, 4> Formats = {"elf32-iamcu", "elf32-iamcu",
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"elf64-unknown", "elf64-unknown"};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_IAMCU))
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checkFormatAndArch(D, Formats[I++], Triple::x86);
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}
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TEST(ELFObjectFileTest, MachineTestForAARCH64) {
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std::array<StringRef, 4> Formats = {"elf32-unknown", "elf32-unknown",
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"elf64-littleaarch64",
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"elf64-bigaarch64"};
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std::array<Triple::ArchType, 4> Archs = {Triple::aarch64, Triple::aarch64_be,
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Triple::aarch64, Triple::aarch64_be};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_AARCH64)) {
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checkFormatAndArch(D, Formats[I], Archs[I]);
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++I;
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}
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}
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TEST(ELFObjectFileTest, MachineTestForPPC64) {
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std::array<StringRef, 4> Formats = {"elf32-unknown", "elf32-unknown",
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"elf64-powerpcle", "elf64-powerpc"};
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std::array<Triple::ArchType, 4> Archs = {Triple::ppc64le, Triple::ppc64,
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Triple::ppc64le, Triple::ppc64};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_PPC64)) {
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checkFormatAndArch(D, Formats[I], Archs[I]);
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++I;
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}
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}
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TEST(ELFObjectFileTest, MachineTestForPPC) {
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std::array<StringRef, 4> Formats = {"elf32-powerpcle", "elf32-powerpc",
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"elf64-unknown", "elf64-unknown"};
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std::array<Triple::ArchType, 4> Archs = {Triple::ppcle, Triple::ppc,
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Triple::ppcle, Triple::ppc};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_PPC)) {
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checkFormatAndArch(D, Formats[I], Archs[I]);
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++I;
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}
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}
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TEST(ELFObjectFileTest, MachineTestForRISCV) {
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std::array<StringRef, 4> Formats = {"elf32-littleriscv", "elf32-littleriscv",
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"elf64-littleriscv", "elf64-littleriscv"};
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std::array<Triple::ArchType, 4> Archs = {Triple::riscv32, Triple::riscv32,
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Triple::riscv64, Triple::riscv64};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_RISCV)) {
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checkFormatAndArch(D, Formats[I], Archs[I]);
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++I;
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}
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}
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TEST(ELFObjectFileTest, MachineTestForARM) {
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std::array<StringRef, 4> Formats = {"elf32-littlearm", "elf32-bigarm",
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"elf64-unknown", "elf64-unknown"};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_ARM))
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checkFormatAndArch(D, Formats[I++], Triple::arm);
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}
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TEST(ELFObjectFileTest, MachineTestForS390) {
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std::array<StringRef, 4> Formats = {"elf32-unknown", "elf32-unknown",
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"elf64-s390", "elf64-s390"};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_S390))
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checkFormatAndArch(D, Formats[I++], Triple::systemz);
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}
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TEST(ELFObjectFileTest, MachineTestForSPARCV9) {
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std::array<StringRef, 4> Formats = {"elf32-unknown", "elf32-unknown",
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"elf64-sparc", "elf64-sparc"};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_SPARCV9))
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checkFormatAndArch(D, Formats[I++], Triple::sparcv9);
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}
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TEST(ELFObjectFileTest, MachineTestForSPARC) {
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std::array<StringRef, 4> Formats = {"elf32-sparc", "elf32-sparc",
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"elf64-unknown", "elf64-unknown"};
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std::array<Triple::ArchType, 4> Archs = {Triple::sparcel, Triple::sparc,
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Triple::sparcel, Triple::sparc};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_SPARC)) {
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checkFormatAndArch(D, Formats[I], Archs[I]);
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++I;
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}
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}
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TEST(ELFObjectFileTest, MachineTestForSPARC32PLUS) {
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std::array<StringRef, 4> Formats = {"elf32-sparc", "elf32-sparc",
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"elf64-unknown", "elf64-unknown"};
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std::array<Triple::ArchType, 4> Archs = {Triple::sparcel, Triple::sparc,
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Triple::sparcel, Triple::sparc};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_SPARC32PLUS)) {
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checkFormatAndArch(D, Formats[I], Archs[I]);
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++I;
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}
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}
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TEST(ELFObjectFileTest, MachineTestForBPF) {
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std::array<StringRef, 4> Formats = {"elf32-unknown", "elf32-unknown",
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"elf64-bpf", "elf64-bpf"};
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std::array<Triple::ArchType, 4> Archs = {Triple::bpfel, Triple::bpfeb,
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Triple::bpfel, Triple::bpfeb};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_BPF)) {
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checkFormatAndArch(D, Formats[I], Archs[I]);
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++I;
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}
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}
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TEST(ELFObjectFileTest, MachineTestForAVR) {
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std::array<StringRef, 4> Formats = {"elf32-avr", "elf32-avr", "elf64-unknown",
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"elf64-unknown"};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_AVR))
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checkFormatAndArch(D, Formats[I++], Triple::avr);
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}
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TEST(ELFObjectFileTest, MachineTestForHEXAGON) {
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std::array<StringRef, 4> Formats = {"elf32-hexagon", "elf32-hexagon",
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"elf64-unknown", "elf64-unknown"};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_HEXAGON))
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checkFormatAndArch(D, Formats[I++], Triple::hexagon);
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}
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TEST(ELFObjectFileTest, MachineTestForLANAI) {
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std::array<StringRef, 4> Formats = {"elf32-lanai", "elf32-lanai",
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"elf64-unknown", "elf64-unknown"};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_LANAI))
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checkFormatAndArch(D, Formats[I++], Triple::lanai);
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}
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TEST(ELFObjectFileTest, MachineTestForMSP430) {
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std::array<StringRef, 4> Formats = {"elf32-msp430", "elf32-msp430",
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"elf64-unknown", "elf64-unknown"};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_MSP430))
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checkFormatAndArch(D, Formats[I++], Triple::msp430);
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}
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TEST(ELFObjectFileTest, MachineTestForCSKY) {
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std::array<StringRef, 4> Formats = {"elf32-csky", "elf32-csky",
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"elf64-unknown", "elf64-unknown"};
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size_t I = 0;
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for (const DataForTest &D : generateData(ELF::EM_CSKY))
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checkFormatAndArch(D, Formats[I++], Triple::csky);
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}
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// ELF relative relocation type test.
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TEST(ELFObjectFileTest, RelativeRelocationTypeTest) {
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EXPECT_EQ(ELF::R_CKCORE_RELATIVE, getELFRelativeRelocationType(ELF::EM_CSKY));
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}
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template <class ELFT>
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static Expected<ELFObjectFile<ELFT>> toBinary(SmallVectorImpl<char> &Storage,
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StringRef Yaml) {
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raw_svector_ostream OS(Storage);
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yaml::Input YIn(Yaml);
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if (!yaml::convertYAML(YIn, OS, [](const Twine &Msg) {}))
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return createStringError(std::errc::invalid_argument,
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"unable to convert YAML");
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return ELFObjectFile<ELFT>::create(MemoryBufferRef(OS.str(), "dummyELF"));
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}
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// Check we are able to create an ELFObjectFile even when the content of the
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// SHT_SYMTAB_SHNDX section can't be read properly.
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TEST(ELFObjectFileTest, InvalidSymtabShndxTest) {
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SmallString<0> Storage;
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Expected<ELFObjectFile<ELF64LE>> ExpectedFile = toBinary<ELF64LE>(Storage, R"(
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--- !ELF
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FileHeader:
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Class: ELFCLASS64
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Data: ELFDATA2LSB
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Type: ET_REL
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Sections:
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- Name: .symtab_shndx
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Type: SHT_SYMTAB_SHNDX
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Entries: [ 0 ]
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ShSize: 0xFFFFFFFF
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)");
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ASSERT_THAT_EXPECTED(ExpectedFile, Succeeded());
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}
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// Test that we are able to create an ELFObjectFile even when loadable segments
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// are unsorted by virtual address.
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// Test that ELFFile<ELFT>::toMappedAddr works properly in this case.
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TEST(ELFObjectFileTest, InvalidLoadSegmentsOrderTest) {
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SmallString<0> Storage;
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Expected<ELFObjectFile<ELF64LE>> ExpectedFile = toBinary<ELF64LE>(Storage, R"(
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--- !ELF
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FileHeader:
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Class: ELFCLASS64
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Data: ELFDATA2LSB
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Type: ET_EXEC
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Sections:
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- Name: .foo
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Type: SHT_PROGBITS
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Address: 0x1000
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Offset: 0x3000
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ContentArray: [ 0x11 ]
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- Name: .bar
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Type: SHT_PROGBITS
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Address: 0x2000
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Offset: 0x4000
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ContentArray: [ 0x99 ]
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ProgramHeaders:
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- Type: PT_LOAD
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VAddr: 0x2000
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FirstSec: .bar
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LastSec: .bar
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- Type: PT_LOAD
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VAddr: 0x1000
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FirstSec: .foo
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LastSec: .foo
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)");
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ASSERT_THAT_EXPECTED(ExpectedFile, Succeeded());
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std::string WarnString;
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auto ToMappedAddr = [&](uint64_t Addr) -> const uint8_t * {
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Expected<const uint8_t *> DataOrErr =
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ExpectedFile->getELFFile().toMappedAddr(Addr, [&](const Twine &Msg) {
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EXPECT_TRUE(WarnString.empty());
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WarnString = Msg.str();
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return Error::success();
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});
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if (!DataOrErr) {
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ADD_FAILURE() << toString(DataOrErr.takeError());
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return nullptr;
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}
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EXPECT_TRUE(WarnString ==
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"loadable segments are unsorted by virtual address");
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WarnString = "";
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return *DataOrErr;
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};
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const uint8_t *Data = ToMappedAddr(0x1000);
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ASSERT_TRUE(Data);
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MemoryBufferRef Buf = ExpectedFile->getMemoryBufferRef();
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EXPECT_EQ((const char *)Data - Buf.getBufferStart(), 0x3000);
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EXPECT_EQ(Data[0], 0x11);
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Data = ToMappedAddr(0x2000);
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ASSERT_TRUE(Data);
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Buf = ExpectedFile->getMemoryBufferRef();
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EXPECT_EQ((const char *)Data - Buf.getBufferStart(), 0x4000);
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EXPECT_EQ(Data[0], 0x99);
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}
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// This is a test for API that is related to symbols.
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// We check that errors are properly reported here.
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TEST(ELFObjectFileTest, InvalidSymbolTest) {
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SmallString<0> Storage;
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Expected<ELFObjectFile<ELF64LE>> ElfOrErr = toBinary<ELF64LE>(Storage, R"(
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--- !ELF
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FileHeader:
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Class: ELFCLASS64
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Data: ELFDATA2LSB
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Type: ET_DYN
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Machine: EM_X86_64
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Sections:
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- Name: .symtab
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Type: SHT_SYMTAB
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)");
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ASSERT_THAT_EXPECTED(ElfOrErr, Succeeded());
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const ELFFile<ELF64LE> &Elf = ElfOrErr->getELFFile();
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const ELFObjectFile<ELF64LE> &Obj = *ElfOrErr;
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Expected<const typename ELF64LE::Shdr *> SymtabSecOrErr = Elf.getSection(1);
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ASSERT_THAT_EXPECTED(SymtabSecOrErr, Succeeded());
|
|
ASSERT_EQ((*SymtabSecOrErr)->sh_type, ELF::SHT_SYMTAB);
|
|
|
|
auto DoCheck = [&](unsigned BrokenSymIndex, const char *ErrMsg) {
|
|
ELFSymbolRef BrokenSym = Obj.toSymbolRef(*SymtabSecOrErr, BrokenSymIndex);
|
|
|
|
// 1) Check the behavior of ELFObjectFile<ELFT>::getSymbolName().
|
|
// SymbolRef::getName() calls it internally. We can't test it directly,
|
|
// because it is protected.
|
|
EXPECT_THAT_ERROR(BrokenSym.getName().takeError(),
|
|
FailedWithMessage(ErrMsg));
|
|
|
|
// 2) Check the behavior of ELFObjectFile<ELFT>::getSymbol().
|
|
EXPECT_THAT_ERROR(Obj.getSymbol(BrokenSym.getRawDataRefImpl()).takeError(),
|
|
FailedWithMessage(ErrMsg));
|
|
|
|
// 3) Check the behavior of ELFObjectFile<ELFT>::getSymbolSection().
|
|
// SymbolRef::getSection() calls it internally. We can't test it
|
|
// directly, because it is protected.
|
|
EXPECT_THAT_ERROR(BrokenSym.getSection().takeError(),
|
|
FailedWithMessage(ErrMsg));
|
|
|
|
// 4) Check the behavior of ELFObjectFile<ELFT>::getSymbolFlags().
|
|
// SymbolRef::getFlags() calls it internally. We can't test it directly,
|
|
// because it is protected.
|
|
EXPECT_THAT_ERROR(BrokenSym.getFlags().takeError(),
|
|
FailedWithMessage(ErrMsg));
|
|
|
|
// 5) Check the behavior of ELFObjectFile<ELFT>::getSymbolType().
|
|
// SymbolRef::getType() calls it internally. We can't test it directly,
|
|
// because it is protected.
|
|
EXPECT_THAT_ERROR(BrokenSym.getType().takeError(),
|
|
FailedWithMessage(ErrMsg));
|
|
|
|
// 6) Check the behavior of ELFObjectFile<ELFT>::getSymbolAddress().
|
|
// SymbolRef::getAddress() calls it internally. We can't test it
|
|
// directly, because it is protected.
|
|
EXPECT_THAT_ERROR(BrokenSym.getAddress().takeError(),
|
|
FailedWithMessage(ErrMsg));
|
|
|
|
// Finally, check the `ELFFile<ELFT>::getEntry` API. This is an underlying
|
|
// method that generates errors for all cases above.
|
|
EXPECT_THAT_EXPECTED(
|
|
Elf.getEntry<typename ELF64LE::Sym>(**SymtabSecOrErr, 0), Succeeded());
|
|
EXPECT_THAT_ERROR(
|
|
Elf.getEntry<typename ELF64LE::Sym>(**SymtabSecOrErr, BrokenSymIndex)
|
|
.takeError(),
|
|
FailedWithMessage(ErrMsg));
|
|
};
|
|
|
|
// We create a symbol with an index that is too large to exist in the symbol
|
|
// table.
|
|
DoCheck(0x1, "can't read an entry at 0x18: it goes past the end of the "
|
|
"section (0x18)");
|
|
|
|
// We create a symbol with an index that is too large to exist in the object.
|
|
DoCheck(0xFFFFFFFF, "can't read an entry at 0x17ffffffe8: it goes past the "
|
|
"end of the section (0x18)");
|
|
}
|
|
|
|
// Tests for error paths of the ELFFile::decodeBBAddrMap API.
|
|
TEST(ELFObjectFileTest, InvalidBBAddrMap) {
|
|
StringRef CommonYamlString(R"(
|
|
--- !ELF
|
|
FileHeader:
|
|
Class: ELFCLASS64
|
|
Data: ELFDATA2LSB
|
|
Type: ET_EXEC
|
|
Sections:
|
|
- Name: .llvm_bb_addr_map
|
|
Type: SHT_LLVM_BB_ADDR_MAP
|
|
Entries:
|
|
- Address: 0x11111
|
|
BBEntries:
|
|
- AddressOffset: 0x0
|
|
Size: 0x1
|
|
Metadata: 0x2
|
|
)");
|
|
|
|
auto DoCheck = [&](StringRef YamlString, const char *ErrMsg) {
|
|
SmallString<0> Storage;
|
|
Expected<ELFObjectFile<ELF64LE>> ElfOrErr =
|
|
toBinary<ELF64LE>(Storage, YamlString);
|
|
ASSERT_THAT_EXPECTED(ElfOrErr, Succeeded());
|
|
const ELFFile<ELF64LE> &Elf = ElfOrErr->getELFFile();
|
|
|
|
Expected<const typename ELF64LE::Shdr *> BBAddrMapSecOrErr =
|
|
Elf.getSection(1);
|
|
ASSERT_THAT_EXPECTED(BBAddrMapSecOrErr, Succeeded());
|
|
EXPECT_THAT_ERROR(Elf.decodeBBAddrMap(**BBAddrMapSecOrErr).takeError(),
|
|
FailedWithMessage(ErrMsg));
|
|
};
|
|
|
|
// Check that we can detect the malformed encoding when the section is
|
|
// truncated.
|
|
SmallString<128> TruncatedYamlString(CommonYamlString);
|
|
TruncatedYamlString += R"(
|
|
ShSize: 0x8
|
|
)";
|
|
DoCheck(TruncatedYamlString, "unable to decode LEB128 at offset 0x00000008: "
|
|
"malformed uleb128, extends past end");
|
|
|
|
// Check that we can detect when the encoded BB entry fields exceed the UINT32
|
|
// limit.
|
|
SmallVector<SmallString<128>, 3> OverInt32LimitYamlStrings(3,
|
|
CommonYamlString);
|
|
OverInt32LimitYamlStrings[0] += R"(
|
|
- AddressOffset: 0x100000000
|
|
Size: 0xFFFFFFFF
|
|
Metadata: 0xFFFFFFFF
|
|
)";
|
|
|
|
OverInt32LimitYamlStrings[1] += R"(
|
|
- AddressOffset: 0xFFFFFFFF
|
|
Size: 0x100000000
|
|
Metadata: 0xFFFFFFFF
|
|
)";
|
|
|
|
OverInt32LimitYamlStrings[2] += R"(
|
|
- AddressOffset: 0xFFFFFFFF
|
|
Size: 0xFFFFFFFF
|
|
Metadata: 0x100000000
|
|
)";
|
|
|
|
DoCheck(OverInt32LimitYamlStrings[0],
|
|
"ULEB128 value at offset 0xc exceeds UINT32_MAX (0x100000000)");
|
|
DoCheck(OverInt32LimitYamlStrings[1],
|
|
"ULEB128 value at offset 0x11 exceeds UINT32_MAX (0x100000000)");
|
|
DoCheck(OverInt32LimitYamlStrings[2],
|
|
"ULEB128 value at offset 0x16 exceeds UINT32_MAX (0x100000000)");
|
|
|
|
// Check the proper error handling when the section has fields exceeding
|
|
// UINT32 and is also truncated. This is for checking that we don't generate
|
|
// unhandled errors.
|
|
SmallVector<SmallString<128>, 3> OverInt32LimitAndTruncated(
|
|
3, OverInt32LimitYamlStrings[1]);
|
|
// Truncate before the end of the 5-byte field.
|
|
OverInt32LimitAndTruncated[0] += R"(
|
|
ShSize: 0x15
|
|
)";
|
|
// Truncate at the end of the 5-byte field.
|
|
OverInt32LimitAndTruncated[1] += R"(
|
|
ShSize: 0x16
|
|
)";
|
|
// Truncate after the end of the 5-byte field.
|
|
OverInt32LimitAndTruncated[2] += R"(
|
|
ShSize: 0x17
|
|
)";
|
|
|
|
DoCheck(OverInt32LimitAndTruncated[0],
|
|
"unable to decode LEB128 at offset 0x00000011: malformed uleb128, "
|
|
"extends past end");
|
|
DoCheck(OverInt32LimitAndTruncated[1],
|
|
"ULEB128 value at offset 0x11 exceeds UINT32_MAX (0x100000000)");
|
|
DoCheck(OverInt32LimitAndTruncated[2],
|
|
"ULEB128 value at offset 0x11 exceeds UINT32_MAX (0x100000000)");
|
|
|
|
// Check for proper error handling when the 'NumBlocks' field is overridden
|
|
// with an out-of-range value.
|
|
SmallString<128> OverLimitNumBlocks(CommonYamlString);
|
|
OverLimitNumBlocks += R"(
|
|
NumBlocks: 0x100000000
|
|
)";
|
|
|
|
DoCheck(OverLimitNumBlocks,
|
|
"ULEB128 value at offset 0x8 exceeds UINT32_MAX (0x100000000)");
|
|
}
|
|
|
|
// Test for ObjectFile::getRelocatedSection: check that it returns a relocated
|
|
// section for executable and relocatable files.
|
|
TEST(ELFObjectFileTest, ExecutableWithRelocs) {
|
|
StringRef HeaderString(R"(
|
|
--- !ELF
|
|
FileHeader:
|
|
Class: ELFCLASS64
|
|
Data: ELFDATA2LSB
|
|
)");
|
|
StringRef ContentsString(R"(
|
|
Sections:
|
|
- Name: .text
|
|
Type: SHT_PROGBITS
|
|
Flags: [ SHF_ALLOC, SHF_EXECINSTR ]
|
|
- Name: .rela.text
|
|
Type: SHT_RELA
|
|
Flags: [ SHF_INFO_LINK ]
|
|
Info: .text
|
|
)");
|
|
|
|
auto DoCheck = [&](StringRef YamlString) {
|
|
SmallString<0> Storage;
|
|
Expected<ELFObjectFile<ELF64LE>> ElfOrErr =
|
|
toBinary<ELF64LE>(Storage, YamlString);
|
|
ASSERT_THAT_EXPECTED(ElfOrErr, Succeeded());
|
|
const ELFObjectFile<ELF64LE> &Obj = *ElfOrErr;
|
|
|
|
bool FoundRela;
|
|
|
|
for (SectionRef Sec : Obj.sections()) {
|
|
Expected<StringRef> SecNameOrErr = Sec.getName();
|
|
ASSERT_THAT_EXPECTED(SecNameOrErr, Succeeded());
|
|
StringRef SecName = *SecNameOrErr;
|
|
if (SecName != ".rela.text")
|
|
continue;
|
|
FoundRela = true;
|
|
Expected<section_iterator> RelSecOrErr = Sec.getRelocatedSection();
|
|
ASSERT_THAT_EXPECTED(RelSecOrErr, Succeeded());
|
|
section_iterator RelSec = *RelSecOrErr;
|
|
ASSERT_NE(RelSec, Obj.section_end());
|
|
Expected<StringRef> TextSecNameOrErr = RelSec->getName();
|
|
ASSERT_THAT_EXPECTED(TextSecNameOrErr, Succeeded());
|
|
StringRef TextSecName = *TextSecNameOrErr;
|
|
EXPECT_EQ(TextSecName, ".text");
|
|
}
|
|
ASSERT_TRUE(FoundRela);
|
|
};
|
|
|
|
// Check ET_EXEC file (`ld --emit-relocs` use-case).
|
|
SmallString<128> ExecFileYamlString(HeaderString);
|
|
ExecFileYamlString += R"(
|
|
Type: ET_EXEC
|
|
)";
|
|
ExecFileYamlString += ContentsString;
|
|
DoCheck(ExecFileYamlString);
|
|
|
|
// Check ET_REL file.
|
|
SmallString<128> RelocatableFileYamlString(HeaderString);
|
|
RelocatableFileYamlString += R"(
|
|
Type: ET_REL
|
|
)";
|
|
RelocatableFileYamlString += ContentsString;
|
|
DoCheck(RelocatableFileYamlString);
|
|
}
|