/* * 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 #include #include #include #include #include #include #include #include #include #include #include "ElfFake.h" #include "MemoryFake.h" #include "RegsFake.h" namespace unwindstack { class RegsTest : public ::testing::Test { protected: void SetUp() override { memory_ = new MemoryFake; elf_.reset(new ElfFake(memory_)); elf_interface_ = new ElfInterfaceFake(elf_->memory()); elf_->FakeSetInterface(elf_interface_); } ElfInterfaceFake* elf_interface_; MemoryFake* memory_; std::unique_ptr elf_; }; TEST_F(RegsTest, regs32) { RegsImplFake regs32(50); ASSERT_EQ(50U, regs32.total_regs()); uint32_t* raw = reinterpret_cast(regs32.RawData()); for (size_t i = 0; i < 50; i++) { raw[i] = 0xf0000000 + i; } regs32.set_pc(0xf0120340); regs32.set_sp(0xa0ab0cd0); for (size_t i = 0; i < 50; i++) { ASSERT_EQ(0xf0000000U + i, regs32[i]) << "Failed comparing register " << i; } ASSERT_EQ(0xf0120340U, regs32.pc()); ASSERT_EQ(0xa0ab0cd0U, regs32.sp()); regs32[32] = 10; ASSERT_EQ(10U, regs32[32]); } TEST_F(RegsTest, regs64) { RegsImplFake regs64(30); ASSERT_EQ(30U, regs64.total_regs()); uint64_t* raw = reinterpret_cast(regs64.RawData()); for (size_t i = 0; i < 30; i++) { raw[i] = 0xf123456780000000UL + i; } regs64.set_pc(0xf123456780102030UL); regs64.set_sp(0xa123456780a0b0c0UL); for (size_t i = 0; i < 30; i++) { ASSERT_EQ(0xf123456780000000U + i, regs64[i]) << "Failed reading register " << i; } ASSERT_EQ(0xf123456780102030UL, regs64.pc()); ASSERT_EQ(0xa123456780a0b0c0UL, regs64.sp()); regs64[8] = 10; ASSERT_EQ(10U, regs64[8]); } TEST_F(RegsTest, rel_pc) { EXPECT_EQ(4U, GetPcAdjustment(0x10, elf_.get(), ARCH_ARM64)); EXPECT_EQ(4U, GetPcAdjustment(0x4, elf_.get(), ARCH_ARM64)); EXPECT_EQ(0U, GetPcAdjustment(0x3, elf_.get(), ARCH_ARM64)); EXPECT_EQ(0U, GetPcAdjustment(0x2, elf_.get(), ARCH_ARM64)); EXPECT_EQ(0U, GetPcAdjustment(0x1, elf_.get(), ARCH_ARM64)); EXPECT_EQ(0U, GetPcAdjustment(0x0, elf_.get(), ARCH_ARM64)); EXPECT_EQ(1U, GetPcAdjustment(0x100, elf_.get(), ARCH_X86)); EXPECT_EQ(1U, GetPcAdjustment(0x2, elf_.get(), ARCH_X86)); EXPECT_EQ(1U, GetPcAdjustment(0x1, elf_.get(), ARCH_X86)); EXPECT_EQ(0U, GetPcAdjustment(0x0, elf_.get(), ARCH_X86)); EXPECT_EQ(1U, GetPcAdjustment(0x100, elf_.get(), ARCH_X86_64)); EXPECT_EQ(1U, GetPcAdjustment(0x2, elf_.get(), ARCH_X86_64)); EXPECT_EQ(1U, GetPcAdjustment(0x1, elf_.get(), ARCH_X86_64)); EXPECT_EQ(0U, GetPcAdjustment(0x0, elf_.get(), ARCH_X86_64)); EXPECT_EQ(8U, GetPcAdjustment(0x10, elf_.get(), ARCH_MIPS)); EXPECT_EQ(8U, GetPcAdjustment(0x8, elf_.get(), ARCH_MIPS)); EXPECT_EQ(0U, GetPcAdjustment(0x7, elf_.get(), ARCH_MIPS)); EXPECT_EQ(0U, GetPcAdjustment(0x6, elf_.get(), ARCH_MIPS)); EXPECT_EQ(0U, GetPcAdjustment(0x5, elf_.get(), ARCH_MIPS)); EXPECT_EQ(0U, GetPcAdjustment(0x4, elf_.get(), ARCH_MIPS)); EXPECT_EQ(0U, GetPcAdjustment(0x3, elf_.get(), ARCH_MIPS)); EXPECT_EQ(0U, GetPcAdjustment(0x2, elf_.get(), ARCH_MIPS)); EXPECT_EQ(0U, GetPcAdjustment(0x1, elf_.get(), ARCH_MIPS)); EXPECT_EQ(0U, GetPcAdjustment(0x0, elf_.get(), ARCH_MIPS)); EXPECT_EQ(8U, GetPcAdjustment(0x10, elf_.get(), ARCH_MIPS64)); EXPECT_EQ(8U, GetPcAdjustment(0x8, elf_.get(), ARCH_MIPS64)); EXPECT_EQ(0U, GetPcAdjustment(0x7, elf_.get(), ARCH_MIPS64)); EXPECT_EQ(0U, GetPcAdjustment(0x6, elf_.get(), ARCH_MIPS64)); EXPECT_EQ(0U, GetPcAdjustment(0x5, elf_.get(), ARCH_MIPS64)); EXPECT_EQ(0U, GetPcAdjustment(0x4, elf_.get(), ARCH_MIPS64)); EXPECT_EQ(0U, GetPcAdjustment(0x3, elf_.get(), ARCH_MIPS64)); EXPECT_EQ(0U, GetPcAdjustment(0x2, elf_.get(), ARCH_MIPS64)); EXPECT_EQ(0U, GetPcAdjustment(0x1, elf_.get(), ARCH_MIPS64)); EXPECT_EQ(0U, GetPcAdjustment(0x0, elf_.get(), ARCH_MIPS64)); } TEST_F(RegsTest, rel_pc_arm) { // Check fence posts. elf_->FakeSetLoadBias(0); EXPECT_EQ(2U, GetPcAdjustment(0x5, elf_.get(), ARCH_ARM)); EXPECT_EQ(2U, GetPcAdjustment(0x4, elf_.get(), ARCH_ARM)); EXPECT_EQ(2U, GetPcAdjustment(0x3, elf_.get(), ARCH_ARM)); EXPECT_EQ(2U, GetPcAdjustment(0x2, elf_.get(), ARCH_ARM)); EXPECT_EQ(0U, GetPcAdjustment(0x1, elf_.get(), ARCH_ARM)); EXPECT_EQ(0U, GetPcAdjustment(0x0, elf_.get(), ARCH_ARM)); elf_->FakeSetLoadBias(0x100); EXPECT_EQ(0U, GetPcAdjustment(0x1, elf_.get(), ARCH_ARM)); EXPECT_EQ(2U, GetPcAdjustment(0x2, elf_.get(), ARCH_ARM)); EXPECT_EQ(2U, GetPcAdjustment(0xff, elf_.get(), ARCH_ARM)); EXPECT_EQ(2U, GetPcAdjustment(0x105, elf_.get(), ARCH_ARM)); EXPECT_EQ(2U, GetPcAdjustment(0x104, elf_.get(), ARCH_ARM)); EXPECT_EQ(2U, GetPcAdjustment(0x103, elf_.get(), ARCH_ARM)); EXPECT_EQ(2U, GetPcAdjustment(0x102, elf_.get(), ARCH_ARM)); EXPECT_EQ(0U, GetPcAdjustment(0x101, elf_.get(), ARCH_ARM)); EXPECT_EQ(0U, GetPcAdjustment(0x100, elf_.get(), ARCH_ARM)); // Check thumb instructions handling. elf_->FakeSetLoadBias(0); memory_->SetData32(0x2000, 0); EXPECT_EQ(2U, GetPcAdjustment(0x2005, elf_.get(), ARCH_ARM)); memory_->SetData32(0x2000, 0xe000f000); EXPECT_EQ(4U, GetPcAdjustment(0x2005, elf_.get(), ARCH_ARM)); elf_->FakeSetLoadBias(0x400); memory_->SetData32(0x2100, 0); EXPECT_EQ(2U, GetPcAdjustment(0x2505, elf_.get(), ARCH_ARM)); memory_->SetData32(0x2100, 0xf111f111); EXPECT_EQ(4U, GetPcAdjustment(0x2505, elf_.get(), ARCH_ARM)); } TEST_F(RegsTest, elf_invalid) { MapInfo map_info(nullptr, nullptr, 0x1000, 0x2000, 0, 0, ""); Elf* invalid_elf = new Elf(nullptr); map_info.set_elf(invalid_elf); EXPECT_EQ(0x500U, invalid_elf->GetRelPc(0x1500, &map_info)); EXPECT_EQ(2U, GetPcAdjustment(0x500U, invalid_elf, ARCH_ARM)); EXPECT_EQ(2U, GetPcAdjustment(0x511U, invalid_elf, ARCH_ARM)); EXPECT_EQ(0x600U, invalid_elf->GetRelPc(0x1600, &map_info)); EXPECT_EQ(4U, GetPcAdjustment(0x600U, invalid_elf, ARCH_ARM64)); EXPECT_EQ(0x700U, invalid_elf->GetRelPc(0x1700, &map_info)); EXPECT_EQ(1U, GetPcAdjustment(0x700U, invalid_elf, ARCH_X86)); EXPECT_EQ(0x800U, invalid_elf->GetRelPc(0x1800, &map_info)); EXPECT_EQ(1U, GetPcAdjustment(0x800U, invalid_elf, ARCH_X86_64)); EXPECT_EQ(0x900U, invalid_elf->GetRelPc(0x1900, &map_info)); EXPECT_EQ(8U, GetPcAdjustment(0x900U, invalid_elf, ARCH_MIPS)); EXPECT_EQ(0xa00U, invalid_elf->GetRelPc(0x1a00, &map_info)); EXPECT_EQ(8U, GetPcAdjustment(0xa00U, invalid_elf, ARCH_MIPS64)); } TEST_F(RegsTest, arm_verify_sp_pc) { RegsArm arm; uint32_t* regs = reinterpret_cast(arm.RawData()); regs[13] = 0x100; regs[15] = 0x200; EXPECT_EQ(0x100U, arm.sp()); EXPECT_EQ(0x200U, arm.pc()); } TEST_F(RegsTest, arm64_verify_sp_pc) { RegsArm64 arm64; uint64_t* regs = reinterpret_cast(arm64.RawData()); regs[31] = 0xb100000000ULL; regs[32] = 0xc200000000ULL; EXPECT_EQ(0xb100000000U, arm64.sp()); EXPECT_EQ(0xc200000000U, arm64.pc()); } TEST_F(RegsTest, x86_verify_sp_pc) { RegsX86 x86; uint32_t* regs = reinterpret_cast(x86.RawData()); regs[4] = 0x23450000; regs[8] = 0xabcd0000; EXPECT_EQ(0x23450000U, x86.sp()); EXPECT_EQ(0xabcd0000U, x86.pc()); } TEST_F(RegsTest, x86_64_verify_sp_pc) { RegsX86_64 x86_64; uint64_t* regs = reinterpret_cast(x86_64.RawData()); regs[7] = 0x1200000000ULL; regs[16] = 0x4900000000ULL; EXPECT_EQ(0x1200000000U, x86_64.sp()); EXPECT_EQ(0x4900000000U, x86_64.pc()); } TEST_F(RegsTest, mips_verify_sp_pc) { RegsMips mips; uint32_t* regs = reinterpret_cast(mips.RawData()); regs[29] = 0x100; regs[32] = 0x200; EXPECT_EQ(0x100U, mips.sp()); EXPECT_EQ(0x200U, mips.pc()); } TEST_F(RegsTest, mips64_verify_sp_pc) { RegsMips64 mips64; uint64_t* regs = reinterpret_cast(mips64.RawData()); regs[29] = 0xb100000000ULL; regs[32] = 0xc200000000ULL; EXPECT_EQ(0xb100000000U, mips64.sp()); EXPECT_EQ(0xc200000000U, mips64.pc()); } TEST_F(RegsTest, arm64_strip_pac_mask) { RegsArm64 arm64; arm64.SetPseudoRegister(Arm64Reg::ARM64_PREG_RA_SIGN_STATE, 1); arm64.SetPACMask(0x007fff8000000000ULL); arm64.set_pc(0x0020007214bb3a04ULL); EXPECT_EQ(0x0000007214bb3a04ULL, arm64.pc()); } TEST_F(RegsTest, arm64_fallback_pc) { RegsArm64 arm64; arm64.SetPACMask(0x007fff8000000000ULL); arm64.set_pc(0x0020007214bb3a04ULL); arm64.fallback_pc(); EXPECT_EQ(0x0000007214bb3a04ULL, arm64.pc()); } TEST_F(RegsTest, machine_type) { RegsArm arm_regs; EXPECT_EQ(ARCH_ARM, arm_regs.Arch()); RegsArm64 arm64_regs; EXPECT_EQ(ARCH_ARM64, arm64_regs.Arch()); RegsX86 x86_regs; EXPECT_EQ(ARCH_X86, x86_regs.Arch()); RegsX86_64 x86_64_regs; EXPECT_EQ(ARCH_X86_64, x86_64_regs.Arch()); RegsMips mips_regs; EXPECT_EQ(ARCH_MIPS, mips_regs.Arch()); RegsMips64 mips64_regs; EXPECT_EQ(ARCH_MIPS64, mips64_regs.Arch()); } template void clone_test(Regs* regs) { RegisterType* register_values = reinterpret_cast(regs->RawData()); int num_regs = regs->total_regs(); for (int i = 0; i < num_regs; ++i) { register_values[i] = i; } std::unique_ptr clone(regs->Clone()); ASSERT_EQ(regs->total_regs(), clone->total_regs()); RegisterType* clone_values = reinterpret_cast(clone->RawData()); for (int i = 0; i < num_regs; ++i) { EXPECT_EQ(register_values[i], clone_values[i]); EXPECT_NE(®ister_values[i], &clone_values[i]); } } TEST_F(RegsTest, clone) { std::vector> regs; regs.emplace_back(new RegsArm()); regs.emplace_back(new RegsArm64()); regs.emplace_back(new RegsX86()); regs.emplace_back(new RegsX86_64()); regs.emplace_back(new RegsMips()); regs.emplace_back(new RegsMips64()); for (auto& r : regs) { if (r->Is32Bit()) { clone_test(r.get()); } else { clone_test(r.get()); } } } } // namespace unwindstack