// Copyright (c) 2010 Google Inc. // All rights reserved. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following disclaimer // in the documentation and/or other materials provided with the // distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived from // this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. #include <assert.h> #include <stdio.h> #include <string> #include "breakpad_googletest_includes.h" #include "common/scoped_ptr.h" #include "common/using_std_string.h" #include "google_breakpad/processor/basic_source_line_resolver.h" #include "google_breakpad/processor/code_module.h" #include "google_breakpad/processor/stack_frame.h" #include "google_breakpad/processor/memory_region.h" #include "processor/linked_ptr.h" #include "processor/logging.h" #include "processor/windows_frame_info.h" #include "processor/cfi_frame_info.h" namespace { using google_breakpad::BasicSourceLineResolver; using google_breakpad::CFIFrameInfo; using google_breakpad::CodeModule; using google_breakpad::MemoryRegion; using google_breakpad::StackFrame; using google_breakpad::WindowsFrameInfo; using google_breakpad::linked_ptr; using google_breakpad::scoped_ptr; using google_breakpad::SymbolParseHelper; class TestCodeModule : public CodeModule { public: TestCodeModule(string code_file) : code_file_(code_file) {} virtual ~TestCodeModule() {} virtual uint64_t base_address() const { return 0; } virtual uint64_t size() const { return 0xb000; } virtual string code_file() const { return code_file_; } virtual string code_identifier() const { return ""; } virtual string debug_file() const { return ""; } virtual string debug_identifier() const { return ""; } virtual string version() const { return ""; } virtual const CodeModule* Copy() const { return new TestCodeModule(code_file_); } private: string code_file_; }; // A mock memory region object, for use by the STACK CFI tests. class MockMemoryRegion: public MemoryRegion { uint64_t GetBase() const { return 0x10000; } uint32_t GetSize() const { return 0x01000; } bool GetMemoryAtAddress(uint64_t address, uint8_t *value) const { *value = address & 0xff; return true; } bool GetMemoryAtAddress(uint64_t address, uint16_t *value) const { *value = address & 0xffff; return true; } bool GetMemoryAtAddress(uint64_t address, uint32_t *value) const { switch (address) { case 0x10008: *value = 0x98ecadc3; break; // saved %ebx case 0x1000c: *value = 0x878f7524; break; // saved %esi case 0x10010: *value = 0x6312f9a5; break; // saved %edi case 0x10014: *value = 0x10038; break; // caller's %ebp case 0x10018: *value = 0xf6438648; break; // return address default: *value = 0xdeadbeef; break; // junk } return true; } bool GetMemoryAtAddress(uint64_t address, uint64_t *value) const { *value = address; return true; } void Print() const { assert(false); } }; // Verify that, for every association in ACTUAL, EXPECTED has the same // association. (That is, ACTUAL's associations should be a subset of // EXPECTED's.) Also verify that ACTUAL has associations for ".ra" and // ".cfa". static bool VerifyRegisters( const char *file, int line, const CFIFrameInfo::RegisterValueMap<uint32_t> &expected, const CFIFrameInfo::RegisterValueMap<uint32_t> &actual) { CFIFrameInfo::RegisterValueMap<uint32_t>::const_iterator a; a = actual.find(".cfa"); if (a == actual.end()) return false; a = actual.find(".ra"); if (a == actual.end()) return false; for (a = actual.begin(); a != actual.end(); a++) { CFIFrameInfo::RegisterValueMap<uint32_t>::const_iterator e = expected.find(a->first); if (e == expected.end()) { fprintf(stderr, "%s:%d: unexpected register '%s' recovered, value 0x%x\n", file, line, a->first.c_str(), a->second); return false; } if (e->second != a->second) { fprintf(stderr, "%s:%d: register '%s' recovered value was 0x%x, expected 0x%x\n", file, line, a->first.c_str(), a->second, e->second); return false; } // Don't complain if this doesn't recover all registers. Although // the DWARF spec says that unmentioned registers are undefined, // GCC uses omission to mean that they are unchanged. } return true; } static bool VerifyEmpty(const StackFrame &frame) { if (frame.function_name.empty() && frame.source_file_name.empty() && frame.source_line == 0) return true; return false; } static void ClearSourceLineInfo(StackFrame *frame) { frame->function_name.clear(); frame->module = NULL; frame->source_file_name.clear(); frame->source_line = 0; } class TestBasicSourceLineResolver : public ::testing::Test { public: void SetUp() { testdata_dir = string(getenv("srcdir") ? getenv("srcdir") : ".") + "/src/processor/testdata"; } BasicSourceLineResolver resolver; string testdata_dir; }; TEST_F(TestBasicSourceLineResolver, TestLoadAndResolve) { TestCodeModule module1("module1"); ASSERT_TRUE(resolver.LoadModule(&module1, testdata_dir + "/module1.out")); ASSERT_TRUE(resolver.HasModule(&module1)); TestCodeModule module2("module2"); ASSERT_TRUE(resolver.LoadModule(&module2, testdata_dir + "/module2.out")); ASSERT_TRUE(resolver.HasModule(&module2)); StackFrame frame; scoped_ptr<WindowsFrameInfo> windows_frame_info; scoped_ptr<CFIFrameInfo> cfi_frame_info; frame.instruction = 0x1000; frame.module = NULL; resolver.FillSourceLineInfo(&frame); ASSERT_FALSE(frame.module); ASSERT_TRUE(frame.function_name.empty()); ASSERT_EQ(frame.function_base, 0U); ASSERT_TRUE(frame.source_file_name.empty()); ASSERT_EQ(frame.source_line, 0); ASSERT_EQ(frame.source_line_base, 0U); frame.module = &module1; resolver.FillSourceLineInfo(&frame); ASSERT_EQ(frame.function_name, "Function1_1"); ASSERT_TRUE(frame.module); ASSERT_EQ(frame.module->code_file(), "module1"); ASSERT_EQ(frame.function_base, 0x1000U); ASSERT_EQ(frame.source_file_name, "file1_1.cc"); ASSERT_EQ(frame.source_line, 44); ASSERT_EQ(frame.source_line_base, 0x1000U); windows_frame_info.reset(resolver.FindWindowsFrameInfo(&frame)); ASSERT_TRUE(windows_frame_info.get()); ASSERT_EQ(windows_frame_info->type_, WindowsFrameInfo::STACK_INFO_FRAME_DATA); ASSERT_FALSE(windows_frame_info->allocates_base_pointer); ASSERT_EQ(windows_frame_info->program_string, "$eip 4 + ^ = $esp $ebp 8 + = $ebp $ebp ^ ="); ClearSourceLineInfo(&frame); frame.instruction = 0x800; frame.module = &module1; resolver.FillSourceLineInfo(&frame); ASSERT_TRUE(VerifyEmpty(frame)); windows_frame_info.reset(resolver.FindWindowsFrameInfo(&frame)); ASSERT_FALSE(windows_frame_info.get()); frame.instruction = 0x1280; resolver.FillSourceLineInfo(&frame); ASSERT_EQ(frame.function_name, "Function1_3"); ASSERT_TRUE(frame.source_file_name.empty()); ASSERT_EQ(frame.source_line, 0); windows_frame_info.reset(resolver.FindWindowsFrameInfo(&frame)); ASSERT_TRUE(windows_frame_info.get()); ASSERT_EQ(windows_frame_info->type_, WindowsFrameInfo::STACK_INFO_UNKNOWN); ASSERT_FALSE(windows_frame_info->allocates_base_pointer); ASSERT_TRUE(windows_frame_info->program_string.empty()); frame.instruction = 0x1380; resolver.FillSourceLineInfo(&frame); ASSERT_EQ(frame.function_name, "Function1_4"); ASSERT_TRUE(frame.source_file_name.empty()); ASSERT_EQ(frame.source_line, 0); windows_frame_info.reset(resolver.FindWindowsFrameInfo(&frame)); ASSERT_EQ(windows_frame_info->type_, WindowsFrameInfo::STACK_INFO_FRAME_DATA); ASSERT_TRUE(windows_frame_info.get()); ASSERT_FALSE(windows_frame_info->allocates_base_pointer); ASSERT_FALSE(windows_frame_info->program_string.empty()); frame.instruction = 0x2000; windows_frame_info.reset(resolver.FindWindowsFrameInfo(&frame)); ASSERT_FALSE(windows_frame_info.get()); // module1 has STACK CFI records covering 3d40..3def; // module2 has STACK CFI records covering 3df0..3e9f; // check that FindCFIFrameInfo doesn't claim to find any outside those ranges. frame.instruction = 0x3d3f; frame.module = &module1; cfi_frame_info.reset(resolver.FindCFIFrameInfo(&frame)); ASSERT_FALSE(cfi_frame_info.get()); frame.instruction = 0x3e9f; frame.module = &module1; cfi_frame_info.reset(resolver.FindCFIFrameInfo(&frame)); ASSERT_FALSE(cfi_frame_info.get()); CFIFrameInfo::RegisterValueMap<uint32_t> current_registers; CFIFrameInfo::RegisterValueMap<uint32_t> caller_registers; CFIFrameInfo::RegisterValueMap<uint32_t> expected_caller_registers; MockMemoryRegion memory; // Regardless of which instruction evaluation takes place at, it // should produce the same values for the caller's registers. expected_caller_registers[".cfa"] = 0x1001c; expected_caller_registers[".ra"] = 0xf6438648; expected_caller_registers["$ebp"] = 0x10038; expected_caller_registers["$ebx"] = 0x98ecadc3; expected_caller_registers["$esi"] = 0x878f7524; expected_caller_registers["$edi"] = 0x6312f9a5; frame.instruction = 0x3d40; frame.module = &module1; current_registers.clear(); current_registers["$esp"] = 0x10018; current_registers["$ebp"] = 0x10038; current_registers["$ebx"] = 0x98ecadc3; current_registers["$esi"] = 0x878f7524; current_registers["$edi"] = 0x6312f9a5; cfi_frame_info.reset(resolver.FindCFIFrameInfo(&frame)); ASSERT_TRUE(cfi_frame_info.get()); ASSERT_TRUE(cfi_frame_info.get() ->FindCallerRegs<uint32_t>(current_registers, memory, &caller_registers)); ASSERT_TRUE(VerifyRegisters(__FILE__, __LINE__, expected_caller_registers, caller_registers)); frame.instruction = 0x3d41; current_registers["$esp"] = 0x10014; cfi_frame_info.reset(resolver.FindCFIFrameInfo(&frame)); ASSERT_TRUE(cfi_frame_info.get()); ASSERT_TRUE(cfi_frame_info.get() ->FindCallerRegs<uint32_t>(current_registers, memory, &caller_registers)); ASSERT_TRUE(VerifyRegisters(__FILE__, __LINE__, expected_caller_registers, caller_registers)); frame.instruction = 0x3d43; current_registers["$ebp"] = 0x10014; cfi_frame_info.reset(resolver.FindCFIFrameInfo(&frame)); ASSERT_TRUE(cfi_frame_info.get()); ASSERT_TRUE(cfi_frame_info.get() ->FindCallerRegs<uint32_t>(current_registers, memory, &caller_registers)); VerifyRegisters(__FILE__, __LINE__, expected_caller_registers, caller_registers); frame.instruction = 0x3d54; current_registers["$ebx"] = 0x6864f054U; cfi_frame_info.reset(resolver.FindCFIFrameInfo(&frame)); ASSERT_TRUE(cfi_frame_info.get()); ASSERT_TRUE(cfi_frame_info.get() ->FindCallerRegs<uint32_t>(current_registers, memory, &caller_registers)); VerifyRegisters(__FILE__, __LINE__, expected_caller_registers, caller_registers); frame.instruction = 0x3d5a; current_registers["$esi"] = 0x6285f79aU; cfi_frame_info.reset(resolver.FindCFIFrameInfo(&frame)); ASSERT_TRUE(cfi_frame_info.get()); ASSERT_TRUE(cfi_frame_info.get() ->FindCallerRegs<uint32_t>(current_registers, memory, &caller_registers)); VerifyRegisters(__FILE__, __LINE__, expected_caller_registers, caller_registers); frame.instruction = 0x3d84; current_registers["$edi"] = 0x64061449U; cfi_frame_info.reset(resolver.FindCFIFrameInfo(&frame)); ASSERT_TRUE(cfi_frame_info.get()); ASSERT_TRUE(cfi_frame_info.get() ->FindCallerRegs<uint32_t>(current_registers, memory, &caller_registers)); VerifyRegisters(__FILE__, __LINE__, expected_caller_registers, caller_registers); frame.instruction = 0x2900; frame.module = &module1; resolver.FillSourceLineInfo(&frame); ASSERT_EQ(frame.function_name, string("PublicSymbol")); frame.instruction = 0x4000; frame.module = &module1; resolver.FillSourceLineInfo(&frame); ASSERT_EQ(frame.function_name, string("LargeFunction")); frame.instruction = 0x2181; frame.module = &module2; resolver.FillSourceLineInfo(&frame); ASSERT_EQ(frame.function_name, "Function2_2"); ASSERT_EQ(frame.function_base, 0x2170U); ASSERT_TRUE(frame.module); ASSERT_EQ(frame.module->code_file(), "module2"); ASSERT_EQ(frame.source_file_name, "file2_2.cc"); ASSERT_EQ(frame.source_line, 21); ASSERT_EQ(frame.source_line_base, 0x2180U); windows_frame_info.reset(resolver.FindWindowsFrameInfo(&frame)); ASSERT_TRUE(windows_frame_info.get()); ASSERT_EQ(windows_frame_info->type_, WindowsFrameInfo::STACK_INFO_FRAME_DATA); ASSERT_EQ(windows_frame_info->prolog_size, 1U); frame.instruction = 0x216f; resolver.FillSourceLineInfo(&frame); ASSERT_EQ(frame.function_name, "Public2_1"); ClearSourceLineInfo(&frame); frame.instruction = 0x219f; frame.module = &module2; resolver.FillSourceLineInfo(&frame); ASSERT_TRUE(frame.function_name.empty()); frame.instruction = 0x21a0; frame.module = &module2; resolver.FillSourceLineInfo(&frame); ASSERT_EQ(frame.function_name, "Public2_2"); } TEST_F(TestBasicSourceLineResolver, TestInvalidLoads) { TestCodeModule module3("module3"); ASSERT_TRUE(resolver.LoadModule(&module3, testdata_dir + "/module3_bad.out")); ASSERT_TRUE(resolver.HasModule(&module3)); ASSERT_TRUE(resolver.IsModuleCorrupt(&module3)); TestCodeModule module4("module4"); ASSERT_TRUE(resolver.LoadModule(&module4, testdata_dir + "/module4_bad.out")); ASSERT_TRUE(resolver.HasModule(&module4)); ASSERT_TRUE(resolver.IsModuleCorrupt(&module4)); TestCodeModule module5("module5"); ASSERT_FALSE(resolver.LoadModule(&module5, testdata_dir + "/invalid-filename")); ASSERT_FALSE(resolver.HasModule(&module5)); TestCodeModule invalidmodule("invalid-module"); ASSERT_FALSE(resolver.HasModule(&invalidmodule)); } TEST_F(TestBasicSourceLineResolver, TestUnload) { TestCodeModule module1("module1"); ASSERT_FALSE(resolver.HasModule(&module1)); ASSERT_TRUE(resolver.LoadModule(&module1, testdata_dir + "/module1.out")); ASSERT_TRUE(resolver.HasModule(&module1)); resolver.UnloadModule(&module1); ASSERT_FALSE(resolver.HasModule(&module1)); ASSERT_TRUE(resolver.LoadModule(&module1, testdata_dir + "/module1.out")); ASSERT_TRUE(resolver.HasModule(&module1)); } // Test parsing of valid FILE lines. The format is: // FILE <id> <filename> TEST(SymbolParseHelper, ParseFileValid) { long index; char *filename; char kTestLine[] = "FILE 1 file name"; ASSERT_TRUE(SymbolParseHelper::ParseFile(kTestLine, &index, &filename)); EXPECT_EQ(1, index); EXPECT_EQ("file name", string(filename)); // 0 is a valid index. char kTestLine1[] = "FILE 0 file name"; ASSERT_TRUE(SymbolParseHelper::ParseFile(kTestLine1, &index, &filename)); EXPECT_EQ(0, index); EXPECT_EQ("file name", string(filename)); } // Test parsing of invalid FILE lines. The format is: // FILE <id> <filename> TEST(SymbolParseHelper, ParseFileInvalid) { long index; char *filename; // Test missing file name. char kTestLine[] = "FILE 1 "; ASSERT_FALSE(SymbolParseHelper::ParseFile(kTestLine, &index, &filename)); // Test bad index. char kTestLine1[] = "FILE x1 file name"; ASSERT_FALSE(SymbolParseHelper::ParseFile(kTestLine1, &index, &filename)); // Test large index. char kTestLine2[] = "FILE 123123123123123123123123 file name"; ASSERT_FALSE(SymbolParseHelper::ParseFile(kTestLine2, &index, &filename)); // Test negative index. char kTestLine3[] = "FILE -2 file name"; ASSERT_FALSE(SymbolParseHelper::ParseFile(kTestLine3, &index, &filename)); } // Test parsing of valid FUNC lines. The format is: // FUNC <address> <size> <stack_param_size> <name> TEST(SymbolParseHelper, ParseFunctionValid) { uint64_t address; uint64_t size; long stack_param_size; char *name; char kTestLine[] = "FUNC 1 2 3 function name"; ASSERT_TRUE(SymbolParseHelper::ParseFunction(kTestLine, &address, &size, &stack_param_size, &name)); EXPECT_EQ(1ULL, address); EXPECT_EQ(2ULL, size); EXPECT_EQ(3, stack_param_size); EXPECT_EQ("function name", string(name)); // Test hex address, size, and param size. char kTestLine1[] = "FUNC a1 a2 a3 function name"; ASSERT_TRUE(SymbolParseHelper::ParseFunction(kTestLine1, &address, &size, &stack_param_size, &name)); EXPECT_EQ(0xa1ULL, address); EXPECT_EQ(0xa2ULL, size); EXPECT_EQ(0xa3, stack_param_size); EXPECT_EQ("function name", string(name)); char kTestLine2[] = "FUNC 0 0 0 function name"; ASSERT_TRUE(SymbolParseHelper::ParseFunction(kTestLine2, &address, &size, &stack_param_size, &name)); EXPECT_EQ(0ULL, address); EXPECT_EQ(0ULL, size); EXPECT_EQ(0, stack_param_size); EXPECT_EQ("function name", string(name)); } // Test parsing of invalid FUNC lines. The format is: // FUNC <address> <size> <stack_param_size> <name> TEST(SymbolParseHelper, ParseFunctionInvalid) { uint64_t address; uint64_t size; long stack_param_size; char *name; // Test missing function name. char kTestLine[] = "FUNC 1 2 3 "; ASSERT_FALSE(SymbolParseHelper::ParseFunction(kTestLine, &address, &size, &stack_param_size, &name)); // Test bad address. char kTestLine1[] = "FUNC 1z 2 3 function name"; ASSERT_FALSE(SymbolParseHelper::ParseFunction(kTestLine1, &address, &size, &stack_param_size, &name)); // Test large address. char kTestLine2[] = "FUNC 123123123123123123123123123 2 3 function name"; ASSERT_FALSE(SymbolParseHelper::ParseFunction(kTestLine2, &address, &size, &stack_param_size, &name)); // Test bad size. char kTestLine3[] = "FUNC 1 z2 3 function name"; ASSERT_FALSE(SymbolParseHelper::ParseFunction(kTestLine3, &address, &size, &stack_param_size, &name)); // Test large size. char kTestLine4[] = "FUNC 1 231231231231231231231231232 3 function name"; ASSERT_FALSE(SymbolParseHelper::ParseFunction(kTestLine4, &address, &size, &stack_param_size, &name)); // Test bad param size. char kTestLine5[] = "FUNC 1 2 3z function name"; ASSERT_FALSE(SymbolParseHelper::ParseFunction(kTestLine5, &address, &size, &stack_param_size, &name)); // Test large param size. char kTestLine6[] = "FUNC 1 2 312312312312312312312312323 function name"; ASSERT_FALSE(SymbolParseHelper::ParseFunction(kTestLine6, &address, &size, &stack_param_size, &name)); // Negative param size. char kTestLine7[] = "FUNC 1 2 -5 function name"; ASSERT_FALSE(SymbolParseHelper::ParseFunction(kTestLine7, &address, &size, &stack_param_size, &name)); } // Test parsing of valid lines. The format is: // <address> <size> <line number> <source file id> TEST(SymbolParseHelper, ParseLineValid) { uint64_t address; uint64_t size; long line_number; long source_file; char kTestLine[] = "1 2 3 4"; ASSERT_TRUE(SymbolParseHelper::ParseLine(kTestLine, &address, &size, &line_number, &source_file)); EXPECT_EQ(1ULL, address); EXPECT_EQ(2ULL, size); EXPECT_EQ(3, line_number); EXPECT_EQ(4, source_file); // Test hex size and address. char kTestLine1[] = "a1 a2 3 4 // some comment"; ASSERT_TRUE(SymbolParseHelper::ParseLine(kTestLine1, &address, &size, &line_number, &source_file)); EXPECT_EQ(0xa1ULL, address); EXPECT_EQ(0xa2ULL, size); EXPECT_EQ(3, line_number); EXPECT_EQ(4, source_file); // 0 is a valid line number. char kTestLine2[] = "a1 a2 0 4 // some comment"; ASSERT_TRUE(SymbolParseHelper::ParseLine(kTestLine2, &address, &size, &line_number, &source_file)); EXPECT_EQ(0xa1ULL, address); EXPECT_EQ(0xa2ULL, size); EXPECT_EQ(0, line_number); EXPECT_EQ(4, source_file); } // Test parsing of invalid lines. The format is: // <address> <size> <line number> <source file id> TEST(SymbolParseHelper, ParseLineInvalid) { uint64_t address; uint64_t size; long line_number; long source_file; // Test missing source file id. char kTestLine[] = "1 2 3"; ASSERT_FALSE(SymbolParseHelper::ParseLine(kTestLine, &address, &size, &line_number, &source_file)); // Test bad address. char kTestLine1[] = "1z 2 3 4"; ASSERT_FALSE(SymbolParseHelper::ParseLine(kTestLine1, &address, &size, &line_number, &source_file)); // Test large address. char kTestLine2[] = "123123123123123123123123 2 3 4"; ASSERT_FALSE(SymbolParseHelper::ParseLine(kTestLine2, &address, &size, &line_number, &source_file)); // Test bad size. char kTestLine3[] = "1 z2 3 4"; ASSERT_FALSE(SymbolParseHelper::ParseLine(kTestLine3, &address, &size, &line_number, &source_file)); // Test large size. char kTestLine4[] = "1 123123123123123123123123 3 4"; ASSERT_FALSE(SymbolParseHelper::ParseLine(kTestLine4, &address, &size, &line_number, &source_file)); // Test bad line number. char kTestLine5[] = "1 2 z3 4"; ASSERT_FALSE(SymbolParseHelper::ParseLine(kTestLine5, &address, &size, &line_number, &source_file)); // Test negative line number. char kTestLine6[] = "1 2 -1 4"; ASSERT_FALSE(SymbolParseHelper::ParseLine(kTestLine6, &address, &size, &line_number, &source_file)); // Test large line number. char kTestLine7[] = "1 2 123123123123123123123 4"; ASSERT_FALSE(SymbolParseHelper::ParseLine(kTestLine7, &address, &size, &line_number, &source_file)); // Test bad source file id. char kTestLine8[] = "1 2 3 f"; ASSERT_FALSE(SymbolParseHelper::ParseLine(kTestLine8, &address, &size, &line_number, &source_file)); } // Test parsing of valid PUBLIC lines. The format is: // PUBLIC <address> <stack_param_size> <name> TEST(SymbolParseHelper, ParsePublicSymbolValid) { uint64_t address; long stack_param_size; char *name; char kTestLine[] = "PUBLIC 1 2 3"; ASSERT_TRUE(SymbolParseHelper::ParsePublicSymbol(kTestLine, &address, &stack_param_size, &name)); EXPECT_EQ(1ULL, address); EXPECT_EQ(2, stack_param_size); EXPECT_EQ("3", string(name)); // Test hex size and address. char kTestLine1[] = "PUBLIC a1 a2 function name"; ASSERT_TRUE(SymbolParseHelper::ParsePublicSymbol(kTestLine1, &address, &stack_param_size, &name)); EXPECT_EQ(0xa1ULL, address); EXPECT_EQ(0xa2, stack_param_size); EXPECT_EQ("function name", string(name)); // Test 0 is a valid address. char kTestLine2[] = "PUBLIC 0 a2 function name"; ASSERT_TRUE(SymbolParseHelper::ParsePublicSymbol(kTestLine2, &address, &stack_param_size, &name)); EXPECT_EQ(0ULL, address); EXPECT_EQ(0xa2, stack_param_size); EXPECT_EQ("function name", string(name)); } // Test parsing of invalid PUBLIC lines. The format is: // PUBLIC <address> <stack_param_size> <name> TEST(SymbolParseHelper, ParsePublicSymbolInvalid) { uint64_t address; long stack_param_size; char *name; // Test missing source function name. char kTestLine[] = "PUBLIC 1 2 "; ASSERT_FALSE(SymbolParseHelper::ParsePublicSymbol(kTestLine, &address, &stack_param_size, &name)); // Test bad address. char kTestLine1[] = "PUBLIC 1z 2 3"; ASSERT_FALSE(SymbolParseHelper::ParsePublicSymbol(kTestLine1, &address, &stack_param_size, &name)); // Test large address. char kTestLine2[] = "PUBLIC 123123123123123123123123 2 3"; ASSERT_FALSE(SymbolParseHelper::ParsePublicSymbol(kTestLine2, &address, &stack_param_size, &name)); // Test bad param stack size. char kTestLine3[] = "PUBLIC 1 z2 3"; ASSERT_FALSE(SymbolParseHelper::ParsePublicSymbol(kTestLine3, &address, &stack_param_size, &name)); // Test large param stack size. char kTestLine4[] = "PUBLIC 1 123123123123123123123123123 3"; ASSERT_FALSE(SymbolParseHelper::ParsePublicSymbol(kTestLine4, &address, &stack_param_size, &name)); // Test negative param stack size. char kTestLine5[] = "PUBLIC 1 -5 3"; ASSERT_FALSE(SymbolParseHelper::ParsePublicSymbol(kTestLine5, &address, &stack_param_size, &name)); } } // namespace int main(int argc, char *argv[]) { ::testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); }