| // Copyright 2019 The Chromium Authors. All rights reserved. |
| // Use of this source code is governed by a BSD-style license that can be |
| // found in the LICENSE file. |
| |
| #include "components/zucchini/arm_utils.h" |
| |
| #include <stddef.h> |
| #include <stdint.h> |
| |
| #include <algorithm> |
| #include <cctype> |
| #include <initializer_list> |
| #include <map> |
| #include <sstream> |
| #include <string> |
| #include <vector> |
| |
| #include "base/check_op.h" |
| #include "components/zucchini/address_translator.h" |
| #include "testing/gtest/include/gtest/gtest.h" |
| |
| namespace zucchini { |
| |
| namespace { |
| |
| // "Clean slate" |code|s for branch instruction encodings with |disp| = 0, and |
| // if applicable, |cond| = 0. |
| uint32_t kCleanSlateB_A1 = 0x0A000000; // A24. |
| uint32_t kCleanSlateBL_A1 = 0x0B000000; // A24. |
| uint32_t kCleanSlateBLX_A2 = 0xFA000000; // A24. |
| uint16_t kCleanSlateB_T1 = 0xD000; // T8. |
| uint16_t kCleanSlateB_T2 = 0xE000; // T11. |
| uint32_t kCleanSlateB_T3 = 0xF0008000; // T20. |
| // For T24 encodings, |disp| = 0 means J1 = J2 = 1, so include 0x00002800. |
| uint32_t kCleanSlateB_T4 = 0xF0009000 | 0x00002800; // T24. |
| uint32_t kCleanSlateBL_T1 = 0xF000D000 | 0x00002800; // T24. |
| uint32_t kCleanSlateBLX_T2 = 0xF000C000 | 0x00002800; // T24. |
| |
| // For AArch64. |
| uint32_t kCleanSlate64TBZw = 0x36000000; // Immd14. |
| uint32_t kCleanSlate64TBZz = 0xB6000000; // Immd14. |
| uint32_t kCleanSlate64TBNZw = 0x37000000; // Immd14. |
| uint32_t kCleanSlate64TBNZz = 0xB7000000; // Immd14. |
| uint32_t kCleanSlate64Bcond = 0x54000000; // Immd19. |
| uint32_t kCleanSlate64CBZw = 0x34000000; // Immd19. |
| uint32_t kCleanSlate64CBZz = 0xB4000000; // Immd19. |
| uint32_t kCleanSlate64CBNZw = 0x35000000; // Immd19. |
| uint32_t kCleanSlate64CBNZz = 0xB5000000; // Immd19. |
| uint32_t kCleanSlate64B = 0x14000000; // Immd26. |
| uint32_t kCleanSlate64BL = 0x94000000; // Immd26. |
| |
| // Special case: Cond = 0xE => AL. |
| uint32_t kCleanSlateBAL_A1 = kCleanSlateB_A1 | (0xE << 28); // |
| |
| // Test helper: Extracts |components| from |value| (may be |code| or |disp|) |
| // based on |pattern|. Also performs consistency checks. On success, writes to |
| // |*components| and returns true. Otherwise returns false. |
| // Example (all numbers are in binary): |
| // |pattern| = "11110Scc cciiiiii 10(J1)0(J2)jjj jjjj...." |
| // |value| = 11110111 00111000 10 1 0 0 111 11000101 |
| // Result: Noting that all 0's and 1's are consistent, returns true with: |
| // |*components| = {S: 1, c: 1100, i: 111000, J1: 1, J2: 0, j: 1111100} |
| // Rules for |pattern|: |
| // * Spaces are ignored. |
| // * '.' means "don't care". |
| // * '0' and '1' are expected literals; mismatch leads to failure. |
| // * A variable name is specified as: |
| // * A single letter. |
| // * "(var)", where "var" is a name that begins with a letter. |
| // * If a variable's first letter is uppercase, then it's a singleton bit. |
| // * If repeated, consistency check is applied (must be identical). |
| // * If a variable's first letter is lowercase, then it spans multiple bits. |
| // * These need not be contiguous, but order is preserved (big-endian). |
| static bool SplitBits(const std::string& pattern, |
| uint32_t value, |
| std::map<std::string, uint32_t>* components) { |
| CHECK(components); |
| |
| // Split |pattern| into |token_list|. |
| std::vector<std::string> token_list; |
| size_t bracket_start = std::string::npos; |
| for (size_t i = 0; i < pattern.size(); ++i) { |
| char ch = pattern[i]; |
| if (bracket_start == std::string::npos) { |
| if (ch == '(') |
| bracket_start = i + 1; |
| else if (ch != ' ') // Ignore space. |
| token_list.push_back(std::string(1, ch)); |
| } else if (ch == ')') { |
| token_list.push_back(pattern.substr(bracket_start, i - bracket_start)); |
| bracket_start = std::string::npos; |
| } |
| } |
| CHECK_EQ(std::string::npos, bracket_start); // No dangling "(". |
| |
| // Process each token. |
| size_t num_tokens = token_list.size(); |
| std::map<std::string, uint32_t> temp_components; |
| CHECK(num_tokens == 32 || (num_tokens == 16 && value <= 0xFFFF)); |
| for (size_t i = 0; i < num_tokens; ++i) { |
| const std::string& token = token_list[i]; |
| CHECK(!token.empty()); |
| uint32_t bit = (value >> (num_tokens - 1 - i)) & 1; |
| if (token == "0" || token == "1") { |
| if (token[0] != static_cast<char>('0' + bit)) |
| return false; // Fail: Mismatch. |
| } else if (isupper(token[0])) { |
| if (temp_components.count(token)) { |
| if (temp_components[token] != bit) |
| return false; // Fail: Singleton bit not uniform. |
| } else { |
| temp_components[token] = bit; |
| } |
| } else if (islower(token[0])) { |
| temp_components[token] = (temp_components[token] << 1) | bit; |
| } else if (token != ".") { |
| return false; // Fail: Unrecognized token. |
| } |
| } |
| components->swap(temp_components); |
| return true; |
| } |
| |
| // AArch32 or AArch64 instruction specification for tests. May be 16-bit or |
| // 32-bit (determined by INT_T). |
| template <typename INT_T> |
| struct ArmRelInstruction { |
| ArmRelInstruction(const std::string& code_pattern_in, INT_T code) |
| : code_pattern(code_pattern_in), clean_slate_code(code) {} |
| |
| // Code pattern for SplitBits(). |
| std::string code_pattern; |
| |
| // "Clean slate" |code| encodes |disp| = 0. |
| INT_T clean_slate_code; |
| }; |
| |
| // Tester for ARM Encode / Decode functions for |disp| <-> |code|. |
| template <typename TRAITS> |
| class ArmTranslatorEncodeDecodeTest { |
| public: |
| using CODE_T = typename TRAITS::code_t; |
| |
| ArmTranslatorEncodeDecodeTest() {} |
| |
| // For each instruction (with |clean_slate_code| in |instr_list|) and for each |
| // |disp| in |good_disp_list|, forms |code| with |encode_fun()| and checks for |
| // success. Extracts |disp_out| with |decode_fun()| and checks that it's the |
| // original |disp|. For each (|disp|, |code|) pair, extracts components using |
| // SplitBits(), and checks that components from |toks_list| are identical. For |
| // each |disp| in |bad_disp_list|, checks that |decode_fun_()| fails. |
| void Run(const std::string& disp_pattern, |
| const std::vector<std::string>& toks_list, |
| const std::vector<ArmRelInstruction<CODE_T>>& instr_list, |
| const std::vector<arm_disp_t>& good_disp_list, |
| const std::vector<arm_disp_t>& bad_disp_list) { |
| ArmAlign (*decode_fun)(CODE_T, arm_disp_t*) = TRAITS::Decode; |
| bool (*encode_fun)(arm_disp_t, CODE_T*) = TRAITS::Encode; |
| |
| for (const ArmRelInstruction<CODE_T> instr : instr_list) { |
| // Parse clean slate code bytes, and ensure it's well-formed. |
| std::map<std::string, uint32_t> clean_slate_code_components; |
| EXPECT_TRUE(SplitBits(instr.code_pattern, instr.clean_slate_code, |
| &clean_slate_code_components)); |
| |
| for (arm_disp_t disp : good_disp_list) { |
| CODE_T code = instr.clean_slate_code; |
| // Encode |disp| to |code|. |
| EXPECT_TRUE((*encode_fun)(disp, &code)) << disp; |
| arm_disp_t disp_out = 0; |
| |
| // Extract components (performs consistency checks) and compare. |
| std::map<std::string, uint32_t> disp_components; |
| EXPECT_TRUE(SplitBits(disp_pattern, static_cast<uint32_t>(disp), |
| &disp_components)); |
| std::map<std::string, uint32_t> code_components; |
| EXPECT_TRUE(SplitBits(instr.code_pattern, code, &code_components)); |
| for (const std::string& tok : toks_list) { |
| EXPECT_EQ(1U, disp_components.count(tok)) << tok; |
| EXPECT_EQ(1U, code_components.count(tok)) << tok; |
| EXPECT_EQ(disp_components[tok], code_components[tok]) << tok; |
| } |
| |
| // Decode |code| to |disp_out|, check fidelity. |
| EXPECT_NE(kArmAlignFail, (*decode_fun)(code, &disp_out)); |
| EXPECT_EQ(disp, disp_out); |
| |
| // Sanity check: Re-encode |disp| into |code|, ensure no change. |
| CODE_T code_copy = code; |
| EXPECT_TRUE((*encode_fun)(disp, &code)); |
| EXPECT_EQ(code_copy, code); |
| |
| // Encode 0, ensure we get clean slate |code| back. |
| EXPECT_TRUE((*encode_fun)(0, &code)); |
| EXPECT_EQ(instr.clean_slate_code, code); |
| } |
| |
| for (arm_disp_t disp : bad_disp_list) { |
| CODE_T code = instr.clean_slate_code; |
| EXPECT_FALSE((*encode_fun)(disp, &code)) << disp; |
| // Value does not get modified after failure. |
| EXPECT_EQ(instr.clean_slate_code, code); |
| } |
| } |
| } |
| }; |
| |
| // Tester for ARM Write / Read functions for |target_rva| <-> |code|. |
| template <typename TRAITS> |
| class ArmTranslatorWriteReadTest { |
| public: |
| using CODE_T = typename TRAITS::code_t; |
| |
| ArmTranslatorWriteReadTest() {} |
| |
| // Expects successful Write() to |clean_slate_code| for each |target_rva_list| |
| // RVA, using each |instr_rva_list| RVA, and that the resulting |code| leads |
| // to successful Read(), which recovers |instr_rva|. |
| void Accept(CODE_T clean_slate_code, |
| const std::vector<rva_t>& instr_rva_list, |
| const std::vector<rva_t>& target_rva_list) { |
| bool (*read_fun)(rva_t, CODE_T, rva_t*) = TRAITS::Read; |
| bool (*write_fun)(rva_t, rva_t, CODE_T*) = TRAITS::Write; |
| |
| for (rva_t instr_rva : instr_rva_list) { |
| for (rva_t target_rva : target_rva_list) { |
| CODE_T code = clean_slate_code; |
| // Write |target_rva| to |code|. |
| EXPECT_TRUE((*write_fun)(instr_rva, target_rva, &code)) << target_rva; |
| rva_t target_rva_out = kInvalidRva; |
| |
| // Read |code| to |target_rva_out|, check fidelity. |
| EXPECT_TRUE((*read_fun)(instr_rva, code, &target_rva_out)); |
| EXPECT_EQ(target_rva, target_rva_out); |
| |
| // Sanity check: Rewrite |target_rva| into |code|, ensure no change. |
| CODE_T code_copy = code; |
| EXPECT_TRUE((*write_fun)(instr_rva, target_rva, &code)); |
| EXPECT_EQ(code_copy, code); |
| } |
| } |
| } |
| |
| // Expects failed Write() to |clean_slate_code| for each |target_rva_list| |
| // RVA, using each |instr_rva_list| RVA. |
| void Reject(CODE_T clean_slate_code, |
| const std::vector<rva_t>& instr_rva_list, |
| const std::vector<rva_t>& target_rva_list) { |
| bool (*write_fun)(rva_t, rva_t, CODE_T*) = TRAITS::Write; |
| |
| for (rva_t instr_rva : instr_rva_list) { |
| for (rva_t target_rva : target_rva_list) { |
| CODE_T code = clean_slate_code; |
| EXPECT_FALSE((*write_fun)(instr_rva, target_rva, &code)) << target_rva; |
| // Output variable is unmodified after failure. |
| EXPECT_EQ(clean_slate_code, code); |
| } |
| } |
| } |
| }; |
| |
| } // namespace |
| |
| // Test for test helper. |
| TEST(ArmUtilsTest, SplitBits) { |
| // If |expected| == "BAD" then we expect failure. |
| auto run_test = [](const std::string& expected, const std::string& pattern, |
| uint32_t value) { |
| std::map<std::string, uint32_t> components; |
| if (expected == "BAD") { |
| EXPECT_FALSE(SplitBits(pattern, value, &components)); |
| EXPECT_TRUE(components.empty()); |
| } else { |
| EXPECT_TRUE(SplitBits(pattern, value, &components)); |
| std::ostringstream oss; |
| // Not using AsHex<>, since number of digits is not fixed. |
| oss << std::uppercase << std::hex; |
| std::string sep = ""; |
| for (auto it : components) { |
| oss << sep << it.first << "=" << it.second; |
| sep = ","; |
| } |
| EXPECT_EQ(expected, oss.str()); |
| } |
| }; |
| |
| run_test("a=ABCD0123", "aaaaaaaa aaaaaaaa aaaaaaaa aaaaaaaa", 0xABCD0123); |
| run_test("a=ABCD,b=123", "aaaaaaaa aaaaaaaa bbbbbbbb bbbbbbbb", 0xABCD0123); |
| run_test("a=23,b=1,c=CD,d=AB", "dddddddd cccccccc bbbbbbbb aaaaaaaa", |
| 0xABCD0123); |
| run_test("", "........ ........ ........ ........", 0xABCD0123); |
| run_test("t=AC02", " tttt.... tt tt.... tttt....tttt.... ", 0xABCD0123); |
| |
| run_test("a=8,b=C,c=E,d1=F", "aaaabbbb cccc(d1)(d1)(d1)(d1)", 0x8CEF); |
| run_test("a=F,b=7,c=3,d1=1", "abc(d1)abc(d1) abc(d1)abc(d1)", 0x8CEF); |
| |
| run_test("A1=0,X=1", "(A1)XX(A1) X(A1)(A1)(A1) (X)(A1)(X)X(X)(X)X(A1)", |
| 0x68BE); |
| run_test("BAD", "(A1)XX(A1) X(A1)(A1)(A1) (X)(A1)(X)X(X)(X)X(A1)", 0x68BF); |
| run_test("BAD", "(A1)XX(A1) X(A1)(A1)(A1) (X)(A1)(X)X(X)(X)X(A1)", 0x683E); |
| |
| run_test("A=1,B=0,a=C", "AAAAaaaa BBBB01..", 0xFC06); |
| run_test("A=1,B=0,a=4", "AAAAaaaa BBBB01..", 0xF406); |
| run_test("A=0,B=1,a=C", "AAAAaaaa BBBB01..", 0x0CF5); |
| run_test("BAD", "AAAAaaaa BBBB01..", 0xEC06); // Non-uniform A. |
| run_test("BAD", "AAAAaaaa BBBB01..", 0xFC16); // Non-uniform B. |
| run_test("BAD", "AAAAaaaa BBBB01..", 0xFC02); // Constant mismatch. |
| } |
| |
| TEST(AArch32Rel32Translator, Fetch) { |
| std::vector<uint8_t> bytes = {0x10, 0x32, 0x54, 0x76, 0x98, 0xBA, 0xDC, 0xFE}; |
| ConstBufferView region(&bytes[0], bytes.size()); |
| AArch32Rel32Translator translator; |
| EXPECT_EQ(0x76543210U, translator.FetchArmCode32(region, 0U)); |
| EXPECT_EQ(0xFEDCBA98U, translator.FetchArmCode32(region, 4U)); |
| |
| EXPECT_EQ(0x3210U, translator.FetchThumb2Code16(region, 0U)); |
| EXPECT_EQ(0xFEDCU, translator.FetchThumb2Code16(region, 6U)); |
| |
| EXPECT_EQ(0x32107654U, translator.FetchThumb2Code32(region, 0U)); |
| EXPECT_EQ(0xBA98FEDCU, translator.FetchThumb2Code32(region, 4U)); |
| } |
| |
| TEST(AArch32Rel32Translator, Store) { |
| std::vector<uint8_t> expected = { |
| 0xFF, 0xFF, 0xFF, 0xFF, // Padding. |
| 0x10, 0x32, 0x54, 0x76, // ARM 32-bit. |
| 0xFF, 0xFF, // Padding. |
| 0x42, 0x86, // THUMB2 16-bit. |
| 0xFF, 0xFF, // Padding. |
| 0xDC, 0xFE, 0x98, 0xBA, // THUMB2 32-bit. |
| 0xFF, 0xFF, 0xFF, 0xFF // Padding. |
| }; |
| |
| std::vector<uint8_t> bytes(4 * 2 + 2 * 3 + 4 * 2, 0xFF); |
| MutableBufferView region(&bytes[0], bytes.size()); |
| CHECK_EQ(expected.size(), bytes.size()); |
| |
| AArch32Rel32Translator translator; |
| translator.StoreArmCode32(region, 4U, 0x76543210U); |
| translator.StoreThumb2Code16(region, 10U, 0x8642U); |
| translator.StoreThumb2Code32(region, 14U, 0xFEDCBA98U); |
| |
| EXPECT_EQ(expected, bytes); |
| } |
| |
| // Detailed test of Encode/Decode: Check valid and invalid |disp| for various |
| // clean slate |code| cases. Also check |disp| and |code| binary components, |
| // which in AArch32Rel32Translator comments. |
| TEST(AArch32Rel32Translator, EncodeDecode) { |
| // A24 tests. |
| ArmTranslatorEncodeDecodeTest<AArch32Rel32Translator::AddrTraits_A24> |
| test_A24; |
| for (int cond = 0; cond <= 0x0E; ++cond) { |
| ArmRelInstruction<uint32_t> B_A1_cond("cccc1010 Siiiiiii iiiiiiii iiiiiiii", |
| kCleanSlateB_A1 | (cond << 28)); |
| ArmRelInstruction<uint32_t> BL_A1_cond( |
| "cccc1011 Siiiiiii iiiiiiii iiiiiiii", kCleanSlateBL_A1 | (cond << 28)); |
| test_A24.Run("SSSSSSSi iiiiiiii iiiiiiii iiiiii00", {"S", "i"}, |
| {B_A1_cond, BL_A1_cond}, |
| {0x01FFFFFC, -0x02000000, 0, 4, -4, 0x40, 0x44}, |
| {2, -2, 0x41, 0x42, 0x43, 0x02000000, -0x02000004}); |
| } |
| // BLX encoding A2, which has 2-byte alignment. |
| ArmRelInstruction<uint32_t> BLX_A2("1111101H Siiiiiii iiiiiiii iiiiiiii", |
| kCleanSlateBLX_A2); |
| test_A24.Run("SSSSSSSi iiiiiiii iiiiiiii iiiiiiH0", {"S", "i", "H"}, {BLX_A2}, |
| {0x01FFFFFC, 0x01FFFFFE, -0x02000000, 0, 2, -2, 4, 0x40, 0x42}, |
| {1, -1, 0x41, 0x43, 0x02000000, -0x02000002}); |
| |
| // T8 tests. |
| ArmTranslatorEncodeDecodeTest<AArch32Rel32Translator::AddrTraits_T8> test_T8; |
| for (int cond = 0; cond <= 0x0E; ++cond) { |
| ArmRelInstruction<uint16_t> B_T1_cond("1101cccc Siiiiiii", |
| kCleanSlateB_T1 | (cond << 8)); |
| test_T8.Run("SSSSSSSS SSSSSSSS SSSSSSSS iiiiiii0", {"S", "i"}, {B_T1_cond}, |
| {0x00FE, -0x0100, 0, 2, -2, 4, 0x40, 0x42}, |
| {1, -1, 0x41, 0x43, 0x0100, -0x0102}); |
| } |
| ArmRelInstruction<uint16_t> B_T1_invalid("11011111 ........", |
| kCleanSlateB_T1 | (0x0F << 8)); |
| test_T8.Run("........ ........ ........ ........", std::vector<std::string>(), |
| {B_T1_invalid}, std::vector<arm_disp_t>(), |
| {0x00FE, -0x0100, 0, 2, 4, 0x40, 0x41, 0x0100, -0x0102}); |
| |
| // T11 tests. |
| ArmTranslatorEncodeDecodeTest<AArch32Rel32Translator::AddrTraits_T11> |
| test_T11; |
| ArmRelInstruction<uint16_t> B_T2("11100Sii iiiiiiii", kCleanSlateB_T2); |
| test_T11.Run("SSSSSSSS SSSSSSSS SSSSSiii iiiiiii0", {"S", "i"}, {B_T2}, |
| {0x07FE, -0x0800, 0, 2, -2, 4, 0x40, 0x42}, |
| {1, -1, 0x41, 0x43, 0x0800, -0x0802}); |
| |
| // T20 tests. |
| ArmTranslatorEncodeDecodeTest<AArch32Rel32Translator::AddrTraits_T20> |
| test_T20; |
| for (int cond = 0; cond <= 0x0E; ++cond) { |
| ArmRelInstruction<uint32_t> B_T3_cond( |
| "11110Scc cciiiiii 10(J1)0(J2)jjj jjjjjjjj", |
| kCleanSlateB_T3 | (cond << 22)); |
| test_T20.Run("SSSSSSSS SSSS(J2)(J1)ii iiiijjjj jjjjjjj0", |
| {"S", "J2", "J1", "i", "j"}, {B_T3_cond}, |
| {0x000FFFFE, -0x00100000, 0, 2, -2, 4, 0x40, 0x42}, |
| {1, -1, 0x41, 0x43, 0x00100000, -0x00100002}); |
| } |
| ArmRelInstruction<uint32_t> B_T3_invalid( |
| "11110.11 11...... 10.0.... ........", kCleanSlateB_T3 | (0x0F << 22)); |
| test_T20.Run("........ ........ ........ ........", |
| std::vector<std::string>(), {B_T3_invalid}, |
| std::vector<arm_disp_t>(), |
| {0x000FFFFE, -0x00100000, 0, 2, 4, 0x40, 0x42, 1, 0x41, 0x43, |
| 0x00100000, -0x00100002}); |
| |
| // T24 tests. |
| ArmTranslatorEncodeDecodeTest<AArch32Rel32Translator::AddrTraits_T24> |
| test_T24; |
| // "Clean slate" means J1 = J2 = 1, so we include 0x00002800. |
| ArmRelInstruction<uint32_t> B_T4("11110Sii iiiiiiii 10(J1)1(J2)jjj jjjjjjjj", |
| kCleanSlateB_T4); |
| ArmRelInstruction<uint32_t> BL_T1("11110Sii iiiiiiii 11(J1)1(J2)jjj jjjjjjjj", |
| kCleanSlateBL_T1); |
| test_T24.Run("SSSSSSSS (I1)(I2)iiiiii iiiijjjj jjjjjjj0", |
| {"S", "i", "j"}, // Skip "J1", "J2", "I1", "I2" checks. |
| {B_T4, BL_T1}, |
| {0x00FFFFFE, -0x01000000, 0, 2, -2, 4, -4, 0x40, 0x42}, |
| {1, -1, 0x41, 0x43, 0x01000000, -0x01000002}); |
| |
| // For BLX encoding T2, |disp| must be multiple of 4. |
| ArmRelInstruction<uint32_t> BLX_T2( |
| "11110Sii iiiiiiii 11(J1)0(J2)jjj jjjjjjj0", kCleanSlateBLX_T2); |
| test_T24.Run( |
| "SSSSSSSS (I1)(I2)iiiiii iiiijjjj jjjjjj00", |
| {"S", "i", "j"}, // Skip "J1", "J2", "I1", "I2" checks. |
| {BLX_T2}, {0x00FFFFFC, -0x01000000, 0, 4, -4, 0x40}, |
| {1, -1, 2, -2, 0x41, 0x42, 0x43, 0x00FFFFFE, 0x01000000, -0x01000002}); |
| } |
| |
| TEST(AArch32Rel32Translator, WriteRead) { |
| std::vector<rva_t> aligned4; |
| std::vector<rva_t> misaligned4; |
| std::vector<rva_t> aligned2; |
| std::vector<rva_t> misaligned2; |
| for (rva_t rva = 0x1FFC; rva <= 0x2010; ++rva) { |
| ((rva % 4 == 0) ? aligned4 : misaligned4).push_back(rva); |
| ((rva % 2 == 0) ? aligned2 : misaligned2).push_back(rva); |
| } |
| CHECK_EQ(6U, aligned4.size()); |
| CHECK_EQ(15U, misaligned4.size()); |
| CHECK_EQ(11U, aligned2.size()); |
| CHECK_EQ(10U, misaligned2.size()); |
| |
| // Helpers to convert an instruction's RVA to PC. |
| auto pcArm = [](rva_t instr_rva) -> rva_t { return instr_rva + 8; }; |
| auto pcThumb2 = [](rva_t instr_rva) -> rva_t { return instr_rva + 4; }; |
| |
| // A24 tests. |
| ArmTranslatorWriteReadTest<AArch32Rel32Translator::AddrTraits_A24> test_A24; |
| for (uint32_t clean_slate_code : {kCleanSlateB_A1, kCleanSlateBL_A1}) { |
| test_A24.Accept(clean_slate_code, aligned4, aligned4); |
| test_A24.Reject(clean_slate_code, aligned4, misaligned4); |
| test_A24.Reject(clean_slate_code, misaligned4, aligned4); |
| test_A24.Reject(clean_slate_code, misaligned4, misaligned4); |
| // Signed (24 + 2)-bit range, 4-byte aligned: [-0x02000000, 0x01FFFFFC]. |
| test_A24.Accept(clean_slate_code, {0x15000000}, |
| {pcArm(0x13000000), pcArm(0x16FFFFFC)}); |
| test_A24.Reject(clean_slate_code, {0x15000000}, |
| {pcArm(0x13000000 - 4), pcArm(0x16FFFFFC + 4)}); |
| } |
| |
| // BLX complication: ARM -> THUMB2. |
| test_A24.Accept(kCleanSlateBLX_A2, aligned4, aligned2); |
| test_A24.Reject(kCleanSlateBLX_A2, aligned4, misaligned2); |
| test_A24.Reject(kCleanSlateBLX_A2, misaligned4, aligned2); |
| test_A24.Reject(kCleanSlateBLX_A2, misaligned4, misaligned2); |
| test_A24.Accept(kCleanSlateBLX_A2, {0x15000000}, |
| {pcArm(0x13000000), pcArm(0x16FFFFFE)}); |
| test_A24.Reject(kCleanSlateBLX_A2, {0x15000000}, |
| {pcArm(0x13000000 - 4), pcArm(0x13000000 - 2), |
| pcArm(0x16FFFFFE + 2), pcArm(0x16FFFFFE + 4)}); |
| |
| // T8 tests. |
| ArmTranslatorWriteReadTest<AArch32Rel32Translator::AddrTraits_T8> test_T8; |
| test_T8.Accept(kCleanSlateB_T1, aligned2, aligned2); |
| test_T8.Reject(kCleanSlateB_T1, aligned2, misaligned2); |
| test_T8.Reject(kCleanSlateB_T1, misaligned2, aligned2); |
| test_T8.Reject(kCleanSlateB_T1, misaligned2, misaligned2); |
| // Signed (8 + 1)-bit range, 2-byte aligned: [-0x0100, 0x00FE]. |
| test_T8.Accept(kCleanSlateB_T1, {0x10000500}, |
| {pcThumb2(0x10000400), pcThumb2(0x100005FE)}); |
| test_T8.Reject(kCleanSlateB_T1, {0x10000500}, |
| {pcThumb2(0x10000400 - 2), pcThumb2(0x100005FE + 2)}); |
| |
| // T11 tests. |
| ArmTranslatorWriteReadTest<AArch32Rel32Translator::AddrTraits_T11> test_T11; |
| test_T11.Accept(kCleanSlateB_T2, aligned2, aligned2); |
| test_T11.Reject(kCleanSlateB_T2, aligned2, misaligned2); |
| test_T11.Reject(kCleanSlateB_T2, misaligned2, aligned2); |
| test_T11.Reject(kCleanSlateB_T2, misaligned2, misaligned2); |
| // Signed (11 + 1)-bit range, 2-byte aligned: [-0x0800, 0x07FE]. |
| test_T11.Accept(kCleanSlateB_T2, {0x10003000}, |
| {pcThumb2(0x10002800), pcThumb2(0x100037FE)}); |
| test_T11.Reject(kCleanSlateB_T2, {0x10003000}, |
| {pcThumb2(0x10002800 - 2), pcThumb2(0x100037FE + 2)}); |
| |
| // T20 tests. |
| ArmTranslatorWriteReadTest<AArch32Rel32Translator::AddrTraits_T20> test_T20; |
| test_T20.Accept(kCleanSlateB_T3, aligned2, aligned2); |
| test_T20.Reject(kCleanSlateB_T3, aligned2, misaligned2); |
| test_T20.Reject(kCleanSlateB_T3, misaligned2, aligned2); |
| test_T20.Reject(kCleanSlateB_T3, misaligned2, misaligned2); |
| // Signed (20 + 1)-bit range, 2-byte aligned: [-0x00100000, 0x000FFFFE]. |
| test_T20.Accept(kCleanSlateB_T3, {0x10300000}, |
| {pcThumb2(0x10200000), pcThumb2(0x103FFFFE)}); |
| test_T20.Reject(kCleanSlateB_T3, {0x10300000}, |
| {pcThumb2(0x10200000 - 2), pcThumb2(0x103FFFFE + 2)}); |
| |
| // T24 tests. |
| ArmTranslatorWriteReadTest<AArch32Rel32Translator::AddrTraits_T24> test_T24; |
| for (uint32_t clean_slate_code : {kCleanSlateB_T4, kCleanSlateBL_T1}) { |
| test_T24.Accept(clean_slate_code, aligned2, aligned2); |
| test_T24.Reject(clean_slate_code, aligned2, misaligned2); |
| test_T24.Reject(clean_slate_code, misaligned2, aligned2); |
| test_T24.Reject(clean_slate_code, misaligned2, misaligned2); |
| // Signed (24 + 1)-bit range, 2-byte aligned: [-0x01000000, 0x00FFFFFE]. |
| test_T24.Accept(clean_slate_code, {0x16000000}, |
| {pcThumb2(0x15000000), pcThumb2(0x16FFFFFE)}); |
| test_T24.Reject(clean_slate_code, {0x16000000}, |
| {pcThumb2(0x15000000 - 2), pcThumb2(0x16FFFFFE + 2)}); |
| } |
| |
| // BLX complication: THUMB2 -> ARM. |
| test_T24.Accept(kCleanSlateBLX_T2, aligned2, aligned4); |
| test_T24.Reject(kCleanSlateBLX_T2, aligned2, misaligned4); |
| test_T24.Reject(kCleanSlateBLX_T2, misaligned2, aligned4); |
| test_T24.Reject(kCleanSlateBLX_T2, misaligned2, misaligned4); |
| test_T24.Accept(kCleanSlateBLX_T2, {0x16000000}, |
| {pcThumb2(0x15000000), pcThumb2(0x16FFFFFC)}); |
| test_T24.Reject(kCleanSlateBLX_T2, {0x16000000}, |
| {pcThumb2(0x15000000 - 4), pcThumb2(0x15000000 - 2), |
| pcThumb2(0x16FFFFFC + 2), pcThumb2(0x16FFFFFC + 4)}); |
| } |
| |
| // Typical usage in |target_rva| extraction. |
| TEST(AArch32Rel32Translator, Main) { |
| // ARM mode (32-bit). |
| // 00103050: 00 01 02 EA B 00183458 ; B encoding A1 (cond = AL). |
| { |
| rva_t instr_rva = 0x00103050U; |
| AArch32Rel32Translator translator; |
| std::vector<uint8_t> bytes = {0x00, 0x01, 0x02, 0xEA}; |
| MutableBufferView region(&bytes[0], bytes.size()); |
| uint32_t code = translator.FetchArmCode32(region, 0U); |
| EXPECT_EQ(0xEA020100U, code); |
| |
| // |code| <-> |disp|. |
| arm_disp_t disp = 0; |
| EXPECT_EQ(kArmAlign4, translator.DecodeA24(code, &disp)); |
| EXPECT_EQ(+0x00080400, disp); |
| |
| uint32_t code_from_disp = kCleanSlateBAL_A1; |
| EXPECT_TRUE(translator.EncodeA24(disp, &code_from_disp)); |
| EXPECT_EQ(code, code_from_disp); |
| |
| // |code| <-> |target_rva|. |
| rva_t target_rva = kInvalidRva; |
| EXPECT_TRUE(translator.ReadA24(instr_rva, code, &target_rva)); |
| // 0x00103050 + 8 + 0x00080400. |
| EXPECT_EQ(0x00183458U, target_rva); |
| |
| uint32_t code_from_rva = kCleanSlateBAL_A1; |
| EXPECT_TRUE(translator.WriteA24(instr_rva, target_rva, &code_from_rva)); |
| EXPECT_EQ(code, code_from_rva); |
| } |
| |
| // THUMB2 mode (16-bit). |
| // 001030A2: F3 E7 B 0010308C ; B encoding T2. |
| { |
| rva_t instr_rva = 0x001030A2U; |
| AArch32Rel32Translator translator; |
| std::vector<uint8_t> bytes = {0xF3, 0xE7}; |
| MutableBufferView region(&bytes[0], bytes.size()); |
| uint16_t code = translator.FetchThumb2Code16(region, 0U); |
| // Sii iiiiiiii = 111 11110011 = -1101 = -0x0D. |
| EXPECT_EQ(0xE7F3U, code); |
| |
| // |code| <-> |disp|. |
| arm_disp_t disp = 0; |
| EXPECT_EQ(kArmAlign2, translator.DecodeT11(code, &disp)); |
| EXPECT_EQ(-0x0000001A, disp); // -0x0D * 2 = -0x1A. |
| |
| uint16_t code_from_disp = kCleanSlateB_T2; |
| EXPECT_TRUE(translator.EncodeT11(disp, &code_from_disp)); |
| EXPECT_EQ(code, code_from_disp); |
| |
| // |code| <-> |target_rva|. |
| rva_t target_rva = kInvalidRva; |
| EXPECT_TRUE(translator.ReadT11(instr_rva, code, &target_rva)); |
| // 0x001030A2 + 4 - 0x0000001A. |
| EXPECT_EQ(0x0010308CU, target_rva); |
| |
| uint16_t code_from_rva = kCleanSlateB_T2; |
| EXPECT_TRUE(translator.WriteT11(instr_rva, target_rva, &code_from_rva)); |
| EXPECT_EQ(code, code_from_rva); |
| } |
| |
| // THUMB2 mode (32-bit). |
| // 001030A2: 00 F0 01 FA BL 001034A8 ; BL encoding T1. |
| { |
| rva_t instr_rva = 0x001030A2U; |
| AArch32Rel32Translator translator; |
| std::vector<uint8_t> bytes = {0x00, 0xF0, 0x01, 0xFA}; |
| MutableBufferView region(&bytes[0], bytes.size()); |
| uint32_t code = translator.FetchThumb2Code32(region, 0U); |
| EXPECT_EQ(0xF000FA01U, code); |
| |
| // |code| <-> |disp|. |
| arm_disp_t disp = 0; |
| EXPECT_EQ(kArmAlign2, translator.DecodeT24(code, &disp)); |
| EXPECT_EQ(+0x00000402, disp); |
| |
| uint32_t code_from_disp = kCleanSlateBL_T1; |
| EXPECT_TRUE(translator.EncodeT24(disp, &code_from_disp)); |
| EXPECT_EQ(code, code_from_disp); |
| |
| // |code| <-> |target_rva|. |
| rva_t target_rva = kInvalidRva; |
| EXPECT_TRUE(translator.ReadT24(instr_rva, code, &target_rva)); |
| // 0x001030A2 + 4 + 0x00000002. |
| EXPECT_EQ(0x001034A8U, target_rva); |
| |
| uint32_t code_from_rva = kCleanSlateBL_T1; |
| EXPECT_TRUE(translator.WriteT24(instr_rva, target_rva, &code_from_rva)); |
| EXPECT_EQ(code, code_from_rva); |
| } |
| } |
| |
| TEST(AArch32Rel32Translator, BLXComplication) { |
| auto run_test = [](rva_t instr_rva, |
| std::vector<uint8_t> bytes, // Pass by value. |
| uint32_t expected_code, arm_disp_t expected_disp, |
| uint32_t clean_slate_code, rva_t expected_target_rva) { |
| AArch32Rel32Translator translator; |
| MutableBufferView region(&bytes[0], bytes.size()); |
| uint32_t code = translator.FetchThumb2Code32(region, 0U); |
| EXPECT_EQ(expected_code, code); |
| |
| // |code| <-> |disp|. |
| arm_disp_t disp = 0; |
| EXPECT_TRUE(translator.DecodeT24(code, &disp)); |
| EXPECT_EQ(expected_disp, disp); |
| |
| uint32_t code_from_disp = clean_slate_code; |
| EXPECT_TRUE(translator.EncodeT24(disp, &code_from_disp)); |
| EXPECT_EQ(code, code_from_disp); |
| |
| // |code| <-> |target_rva|. |
| rva_t target_rva = kInvalidRva; |
| EXPECT_TRUE(translator.ReadT24(instr_rva, code, &target_rva)); |
| EXPECT_EQ(expected_target_rva, target_rva); |
| |
| uint32_t code_from_rva = clean_slate_code; |
| EXPECT_TRUE(translator.WriteT24(instr_rva, target_rva, &code_from_rva)); |
| EXPECT_EQ(code, code_from_rva); |
| }; |
| |
| // No complication, 4-byte aligned. |
| // 001030A0: 01 F0 06 B0 B 005040B0 ; B encoding T4. |
| run_test(0x001030A0U, // Multiple of 4. |
| {0x01, 0xF0, 0x06, 0xB0}, 0xF001B006U, 0x0040100C, kCleanSlateB_T4, |
| // "Canonical" |target_rva|: 0x001030A0 + 4 + 0x0040100C. |
| 0x005040B0U); |
| |
| // No complication, not 4-byte aligned. |
| // 001030A2: 01 F0 06 B0 B 005040B2 ; B encoding T4. |
| run_test(0x001030A2U, // Shift by 2: Not multiple of 4. |
| {0x01, 0xF0, 0x06, 0xB0}, 0xF001B006U, 0x0040100C, kCleanSlateB_T4, |
| // Shifted by 2: 0x001030A2 + 4 + 0x0040100C. |
| 0x005040B2U); |
| |
| // Repeat the above, but use BLX instead of B. |
| |
| // BLX complication, 4-byte aligned. |
| // 001030A0: 01 F0 06 E0 BLX 005040B0 ; BLX encoding T2. |
| run_test(0x001030A0U, // Multiple of 4. |
| {0x01, 0xF0, 0x06, 0xE0}, 0xF001E006U, 0x0040100C, kCleanSlateBLX_T2, |
| // Canonical again: align_down_4(0x001030A0 + 4 + 0x0040100C). |
| 0x005040B0U); |
| |
| // BLX complication, not 4-byte aligned. |
| // 001030A2: 01 F0 06 E0 BLX 005040B0 ; BLX encoding T2. |
| run_test(0x001030A2U, // Shift by 2: Not multiple of 4. |
| {0x01, 0xF0, 0x06, 0xE0}, 0xF001E006U, 0x0040100C, kCleanSlateBLX_T2, |
| // No shift: align_down_4(0x001030A2 + 4 + 0x0040100C). |
| 0x005040B0U); |
| } |
| |
| TEST(AArch64Rel32Translator, FetchStore) { |
| std::vector<uint8_t> bytes = {0x10, 0x32, 0x54, 0x76, 0x98, 0xBA, 0xDC, 0xFE}; |
| std::vector<uint8_t> expected = {0xAB, 0x33, 0x22, 0x11, |
| 0x69, 0x5A, 0xFF, 0x00}; |
| MutableBufferView region(&bytes[0], bytes.size()); |
| AArch64Rel32Translator translator; |
| EXPECT_EQ(0x76543210U, translator.FetchCode32(region, 0U)); |
| EXPECT_EQ(0xFEDCBA98U, translator.FetchCode32(region, 4U)); |
| |
| translator.StoreCode32(region, 0U, 0x112233ABU); |
| translator.StoreCode32(region, 4U, 0x00FF5A69); |
| EXPECT_EQ(expected, bytes); |
| } |
| |
| TEST(AArch64Rel32Translator, EncodeDecode) { |
| // Immd14 tests. |
| ArmTranslatorEncodeDecodeTest<AArch64Rel32Translator::AddrTraits_Immd14> |
| test_immd14; |
| for (int b40 : {0, 1, 7, 31}) { |
| uint32_t b40_mask = b40 << 19; |
| for (int Rt : {0, 1, 15, 30}) { |
| uint32_t mask = b40_mask | Rt; |
| ArmRelInstruction<uint32_t> TBZw_Rt("00110110 bbbbbSii iiiiiiii iiittttt", |
| kCleanSlate64TBZw | mask); |
| ArmRelInstruction<uint32_t> TBZz_Rt("10110110 bbbbbSii iiiiiiii iiittttt", |
| kCleanSlate64TBZz | mask); |
| ArmRelInstruction<uint32_t> TBNZw_Rt( |
| "00110111 bbbbbSii iiiiiiii iiittttt", kCleanSlate64TBNZw | mask); |
| ArmRelInstruction<uint32_t> TBNZz_Rt( |
| "10110111 bbbbbSii iiiiiiii iiittttt", kCleanSlate64TBNZz | mask); |
| test_immd14.Run("SSSSSSSS SSSSSSSS Siiiiiii iiiiii00", {"S", "i"}, |
| {TBZw_Rt, TBZz_Rt, TBNZw_Rt, TBNZz_Rt}, |
| {0x00007FFC, -0x00008000, 0, 4, -4, 0x40, 0x44}, |
| {2, -2, 0x41, 0x42, 0x43, 0x00008000, -0x00008004}); |
| } |
| } |
| |
| // Immd19 tests. |
| ArmTranslatorEncodeDecodeTest<AArch64Rel32Translator::AddrTraits_Immd19> |
| test_immd19; |
| for (int cond = 0; cond <= 0x0E; ++cond) { |
| ArmRelInstruction<uint32_t> B_cond("01010100 Siiiiiii iiiiiiii iii0cccc", |
| kCleanSlate64Bcond | cond); |
| test_immd19.Run("SSSSSSSS SSSSiiii iiiiiiii iiiiii00", {"S", "i"}, {B_cond}, |
| {0x000FFFFC, -0x00100000, 0, 4, -4, 0x40, 0x44}, |
| {2, -2, 0x41, 0x42, 0x43, 0x00100000, -0x00100004}); |
| } |
| for (int Rt : {0, 1, 15, 30}) { |
| ArmRelInstruction<uint32_t> CBZw_Rt("00110100 Siiiiiii iiiiiiii iiittttt", |
| kCleanSlate64CBZw | Rt); |
| ArmRelInstruction<uint32_t> CBZz_Rt("10110100 Siiiiiii iiiiiiii iiittttt", |
| kCleanSlate64CBZz | Rt); |
| ArmRelInstruction<uint32_t> CBNZw_Rt("00110101 Siiiiiii iiiiiiii iiittttt", |
| kCleanSlate64CBNZw | Rt); |
| ArmRelInstruction<uint32_t> CBNZz_Rt("10110101 Siiiiiii iiiiiiii iiittttt", |
| kCleanSlate64CBNZz | Rt); |
| test_immd19.Run("SSSSSSSS SSSSiiii iiiiiiii iiiiii00", {"S", "i"}, |
| {CBZw_Rt, CBZz_Rt, CBNZw_Rt, CBNZz_Rt}, |
| {0x000FFFFC, -0x00100000, 0, 4, -4, 0x40, 0x44}, |
| {2, -2, 0x41, 0x42, 0x43, 0x00100000, -0x00100004}); |
| } |
| |
| // Immd26 tests. |
| ArmTranslatorEncodeDecodeTest<AArch64Rel32Translator::AddrTraits_Immd26> |
| test_immd26; |
| ArmRelInstruction<uint32_t> B("000101Si iiiiiiii iiiiiiii iiiiiiii", |
| kCleanSlate64B); |
| ArmRelInstruction<uint32_t> BL("100101Si iiiiiiii iiiiiiii iiiiiiii", |
| kCleanSlate64BL); |
| test_immd26.Run("SSSSSiii iiiiiiii iiiiiiii iiiiii00", {"S", "i"}, {B, BL}, |
| {0x07FFFFFC, -0x08000000, 0, 4, -4, 0x40, 0x44}, |
| {2, -2, 0x41, 0x42, 0x43, 0x08000000, -0x08000004}); |
| } |
| |
| TEST(AArch64Rel32Translator, WriteRead) { |
| std::vector<rva_t> aligned4; |
| std::vector<rva_t> misaligned4; |
| for (rva_t rva = 0x1FFC; rva <= 0x2010; ++rva) { |
| ((rva % 4 == 0) ? aligned4 : misaligned4).push_back(rva); |
| } |
| CHECK_EQ(6U, aligned4.size()); |
| CHECK_EQ(15U, misaligned4.size()); |
| |
| // Helper to convert an instruction's RVA to PC. |
| auto pcAArch64 = [](rva_t instr_rva) -> rva_t { return instr_rva; }; |
| |
| // Immd14 tests. |
| ArmTranslatorWriteReadTest<AArch64Rel32Translator::AddrTraits_Immd14> |
| test_immd14; |
| for (uint32_t clean_slate_code : {kCleanSlate64TBZw, kCleanSlate64TBZz, |
| kCleanSlate64TBNZw, kCleanSlate64TBNZz}) { |
| test_immd14.Accept(clean_slate_code, aligned4, aligned4); |
| test_immd14.Reject(clean_slate_code, aligned4, misaligned4); |
| test_immd14.Reject(clean_slate_code, misaligned4, aligned4); |
| test_immd14.Reject(clean_slate_code, misaligned4, misaligned4); |
| // Signed (14 + 2)-bit range, 4-byte aligned: [-0x00008000, 0x00007FFC]. |
| test_immd14.Accept(clean_slate_code, {0x10040000}, |
| {pcAArch64(0x10038000), pcAArch64(0x10047FFC)}); |
| test_immd14.Reject(clean_slate_code, {0x15000000}, |
| {pcAArch64(0x10038000 - 4), pcAArch64(0x10047FFC + 4)}); |
| } |
| |
| // Immd19 tests. |
| ArmTranslatorWriteReadTest<AArch64Rel32Translator::AddrTraits_Immd19> |
| test_immd19; |
| for (uint32_t clean_slate_code : |
| {kCleanSlate64Bcond, kCleanSlate64CBZw, kCleanSlate64CBZz, |
| kCleanSlate64CBNZw, kCleanSlate64CBNZz}) { |
| test_immd19.Accept(clean_slate_code, aligned4, aligned4); |
| test_immd19.Reject(clean_slate_code, aligned4, misaligned4); |
| test_immd19.Reject(clean_slate_code, misaligned4, aligned4); |
| test_immd19.Reject(clean_slate_code, misaligned4, misaligned4); |
| // Signed (19 + 2)-bit range, 4-byte aligned: [-0x00100000, 0x000FFFFC]. |
| test_immd19.Accept(clean_slate_code, {0x10300000}, |
| {pcAArch64(0x10200000), pcAArch64(0x103FFFFC)}); |
| test_immd19.Reject(clean_slate_code, {0x10300000}, |
| {pcAArch64(0x10200000 - 4), pcAArch64(0x103FFFFC + 4)}); |
| } |
| |
| // Immd26 tests. |
| ArmTranslatorWriteReadTest<AArch64Rel32Translator::AddrTraits_Immd26> |
| test_immd26; |
| for (uint32_t clean_slate_code : {kCleanSlate64B, kCleanSlate64BL}) { |
| test_immd26.Accept(clean_slate_code, aligned4, aligned4); |
| test_immd26.Reject(clean_slate_code, aligned4, misaligned4); |
| test_immd26.Reject(clean_slate_code, misaligned4, aligned4); |
| test_immd26.Reject(clean_slate_code, misaligned4, misaligned4); |
| // Signed (26 + 2)-bit range, 4-byte aligned: [-0x08000000, 0x07FFFFFC]. |
| test_immd26.Accept(clean_slate_code, {0x30000000}, |
| {pcAArch64(0x28000000), pcAArch64(0x37FFFFFC)}); |
| test_immd26.Reject(clean_slate_code, {0x30000000}, |
| {pcAArch64(0x28000000 - 4), pcAArch64(0x37FFFFFC + 4)}); |
| } |
| } |
| |
| // Typical usage in |target_rva| extraction. |
| TEST(AArch64Rel32Translator, Main) { |
| // 00103050: 02 01 02 14 B 00183458 |
| rva_t instr_rva = 0x00103050U; |
| AArch64Rel32Translator translator; |
| std::vector<uint8_t> bytes = {0x02, 0x01, 0x02, 0x14}; |
| MutableBufferView region(&bytes[0], bytes.size()); |
| uint32_t code = translator.FetchCode32(region, 0U); |
| EXPECT_EQ(0x14020102U, code); |
| |
| // |code| <-> |disp|. |
| arm_disp_t disp = 0; |
| EXPECT_TRUE(translator.DecodeImmd26(code, &disp)); |
| EXPECT_EQ(+0x00080408, disp); |
| |
| uint32_t code_from_disp = kCleanSlate64B; |
| EXPECT_TRUE(translator.EncodeImmd26(disp, &code_from_disp)); |
| EXPECT_EQ(code, code_from_disp); |
| |
| // |code| <-> |target_rva|. |
| rva_t target_rva = kInvalidRva; |
| EXPECT_TRUE(translator.ReadImmd26(instr_rva, code, &target_rva)); |
| // 0x00103050 + 0 + 0x00080408. |
| EXPECT_EQ(0x00183458U, target_rva); |
| |
| uint32_t code_from_rva = kCleanSlate64B; |
| EXPECT_TRUE(translator.WriteImmd26(instr_rva, target_rva, &code_from_rva)); |
| EXPECT_EQ(code, code_from_rva); |
| } |
| |
| } // namespace zucchini |