| #!/usr/bin/python |
| # |
| # Copyright (C) 2013 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. |
| |
| """Module for looking up symbolic debugging information. |
| |
| The information can include symbol names, offsets, and source locations. |
| """ |
| |
| import atexit |
| import glob |
| import os |
| import platform |
| import re |
| import signal |
| import subprocess |
| import unittest |
| |
| ANDROID_BUILD_TOP = os.environ["ANDROID_BUILD_TOP"] |
| if not ANDROID_BUILD_TOP: |
| ANDROID_BUILD_TOP = "." |
| |
| def FindSymbolsDir(): |
| saveddir = os.getcwd() |
| os.chdir(ANDROID_BUILD_TOP) |
| try: |
| cmd = "build/soong/soong_ui.bash --dumpvar-mode --abs TARGET_OUT_UNSTRIPPED" |
| stream = subprocess.Popen(cmd, stdout=subprocess.PIPE, shell=True).stdout |
| return os.path.join(ANDROID_BUILD_TOP, stream.read().strip()) |
| finally: |
| os.chdir(saveddir) |
| |
| SYMBOLS_DIR = FindSymbolsDir() |
| |
| ARCH = None |
| |
| |
| # These are private. Do not access them from other modules. |
| _CACHED_TOOLCHAIN = None |
| _CACHED_TOOLCHAIN_ARCH = None |
| |
| # Caches for symbolized information. |
| _SYMBOL_INFORMATION_ADDR2LINE_CACHE = {} |
| _SYMBOL_INFORMATION_OBJDUMP_CACHE = {} |
| _SYMBOL_DEMANGLING_CACHE = {} |
| |
| # Caches for pipes to subprocesses. |
| |
| class ProcessCache: |
| _cmd2pipe = {} |
| _lru = [] |
| |
| # Max number of open pipes. |
| _PIPE_MAX_OPEN = 10 |
| |
| def GetProcess(self, cmd): |
| cmd_tuple = tuple(cmd) # Need to use a tuple as lists can't be dict keys. |
| # Pipe already available? |
| if cmd_tuple in self._cmd2pipe: |
| pipe = self._cmd2pipe[cmd_tuple] |
| # Update LRU. |
| self._lru = [(cmd_tuple, pipe)] + [i for i in self._lru if i[0] != cmd_tuple] |
| return pipe |
| |
| # Not cached, yet. Open a new one. |
| |
| # Check if too many are open, close the old ones. |
| while len(self._lru) >= self._PIPE_MAX_OPEN: |
| open_cmd, open_pipe = self._lru.pop() |
| del self._cmd2pipe[open_cmd] |
| self.TerminateProcess(open_pipe) |
| |
| # Create and put into cache. |
| pipe = self.SpawnProcess(cmd) |
| self._cmd2pipe[cmd_tuple] = pipe |
| self._lru = [(cmd_tuple, pipe)] + self._lru |
| return pipe |
| |
| def SpawnProcess(self, cmd): |
| return subprocess.Popen(cmd, stdin=subprocess.PIPE, stdout=subprocess.PIPE) |
| |
| def TerminateProcess(self, pipe): |
| pipe.stdin.close() |
| pipe.stdout.close() |
| pipe.terminate() |
| pipe.wait() |
| |
| def KillAllProcesses(self): |
| for _, open_pipe in self._lru: |
| self.TerminateProcess(open_pipe) |
| _cmd2pipe = {} |
| _lru = [] |
| |
| |
| _PIPE_ADDR2LINE_CACHE = ProcessCache() |
| _PIPE_CPPFILT_CACHE = ProcessCache() |
| |
| |
| # Process cache cleanup on shutdown. |
| |
| def CloseAllPipes(): |
| _PIPE_ADDR2LINE_CACHE.KillAllProcesses() |
| _PIPE_CPPFILT_CACHE.KillAllProcesses() |
| |
| |
| atexit.register(CloseAllPipes) |
| |
| |
| def PipeTermHandler(signum, frame): |
| CloseAllPipes() |
| os._exit(0) |
| |
| |
| for sig in (signal.SIGABRT, signal.SIGINT, signal.SIGTERM): |
| signal.signal(sig, PipeTermHandler) |
| |
| |
| |
| |
| def ToolPath(tool, toolchain=None): |
| """Return a fully-qualified path to the specified tool""" |
| if not toolchain: |
| toolchain = FindToolchain() |
| return glob.glob(os.path.join(toolchain, "*-" + tool))[0] |
| |
| |
| def FindToolchain(): |
| """Returns the toolchain matching ARCH.""" |
| global _CACHED_TOOLCHAIN, _CACHED_TOOLCHAIN_ARCH |
| if _CACHED_TOOLCHAIN is not None and _CACHED_TOOLCHAIN_ARCH == ARCH: |
| return _CACHED_TOOLCHAIN |
| |
| # We use slightly different names from GCC, and there's only one toolchain |
| # for x86/x86_64. Note that these are the names of the top-level directory |
| # rather than the _different_ names used lower down the directory hierarchy! |
| gcc_dir = ARCH |
| if gcc_dir == "arm64": |
| gcc_dir = "aarch64" |
| elif gcc_dir == "mips64": |
| gcc_dir = "mips" |
| elif gcc_dir == "x86_64": |
| gcc_dir = "x86" |
| |
| os_name = platform.system().lower(); |
| |
| available_toolchains = glob.glob("%s/prebuilts/gcc/%s-x86/%s/*-linux-*/bin/" % (ANDROID_BUILD_TOP, os_name, gcc_dir)) |
| if len(available_toolchains) == 0: |
| raise Exception("Could not find tool chain for %s" % (ARCH)) |
| |
| toolchain = sorted(available_toolchains)[-1] |
| |
| if not os.path.exists(ToolPath("addr2line", toolchain)): |
| raise Exception("No addr2line for %s" % (toolchain)) |
| |
| _CACHED_TOOLCHAIN = toolchain |
| _CACHED_TOOLCHAIN_ARCH = ARCH |
| print "Using %s toolchain from: %s" % (_CACHED_TOOLCHAIN_ARCH, _CACHED_TOOLCHAIN) |
| return _CACHED_TOOLCHAIN |
| |
| |
| def SymbolInformation(lib, addr): |
| """Look up symbol information about an address. |
| |
| Args: |
| lib: library (or executable) pathname containing symbols |
| addr: string hexidecimal address |
| |
| Returns: |
| A list of the form [(source_symbol, source_location, |
| object_symbol_with_offset)]. |
| |
| If the function has been inlined then the list may contain |
| more than one element with the symbols for the most deeply |
| nested inlined location appearing first. The list is |
| always non-empty, even if no information is available. |
| |
| Usually you want to display the source_location and |
| object_symbol_with_offset from the last element in the list. |
| """ |
| info = SymbolInformationForSet(lib, set([addr])) |
| return (info and info.get(addr)) or [(None, None, None)] |
| |
| |
| def SymbolInformationForSet(lib, unique_addrs): |
| """Look up symbol information for a set of addresses from the given library. |
| |
| Args: |
| lib: library (or executable) pathname containing symbols |
| unique_addrs: set of hexidecimal addresses |
| |
| Returns: |
| A dictionary of the form {addr: [(source_symbol, source_location, |
| object_symbol_with_offset)]} where each address has a list of |
| associated symbols and locations. The list is always non-empty. |
| |
| If the function has been inlined then the list may contain |
| more than one element with the symbols for the most deeply |
| nested inlined location appearing first. The list is |
| always non-empty, even if no information is available. |
| |
| Usually you want to display the source_location and |
| object_symbol_with_offset from the last element in the list. |
| """ |
| if not lib: |
| return None |
| |
| addr_to_line = CallAddr2LineForSet(lib, unique_addrs) |
| if not addr_to_line: |
| return None |
| |
| addr_to_objdump = CallObjdumpForSet(lib, unique_addrs) |
| if not addr_to_objdump: |
| return None |
| |
| result = {} |
| for addr in unique_addrs: |
| source_info = addr_to_line.get(addr) |
| if not source_info: |
| source_info = [(None, None)] |
| if addr in addr_to_objdump: |
| (object_symbol, object_offset) = addr_to_objdump.get(addr) |
| object_symbol_with_offset = FormatSymbolWithOffset(object_symbol, |
| object_offset) |
| else: |
| object_symbol_with_offset = None |
| result[addr] = [(source_symbol, source_location, object_symbol_with_offset) |
| for (source_symbol, source_location) in source_info] |
| |
| return result |
| |
| |
| def CallAddr2LineForSet(lib, unique_addrs): |
| """Look up line and symbol information for a set of addresses. |
| |
| Args: |
| lib: library (or executable) pathname containing symbols |
| unique_addrs: set of string hexidecimal addresses look up. |
| |
| Returns: |
| A dictionary of the form {addr: [(symbol, file:line)]} where |
| each address has a list of associated symbols and locations |
| or an empty list if no symbol information was found. |
| |
| If the function has been inlined then the list may contain |
| more than one element with the symbols for the most deeply |
| nested inlined location appearing first. |
| """ |
| if not lib: |
| return None |
| |
| result = {} |
| addrs = sorted(unique_addrs) |
| |
| if lib in _SYMBOL_INFORMATION_ADDR2LINE_CACHE: |
| addr_cache = _SYMBOL_INFORMATION_ADDR2LINE_CACHE[lib] |
| |
| # Go through and handle all known addresses. |
| for x in range(len(addrs)): |
| next_addr = addrs.pop(0) |
| if next_addr in addr_cache: |
| result[next_addr] = addr_cache[next_addr] |
| else: |
| # Re-add, needs to be symbolized. |
| addrs.append(next_addr) |
| |
| if not addrs: |
| # Everything was cached, we're done. |
| return result |
| else: |
| addr_cache = {} |
| _SYMBOL_INFORMATION_ADDR2LINE_CACHE[lib] = addr_cache |
| |
| symbols = SYMBOLS_DIR + lib |
| if not os.path.exists(symbols): |
| symbols = lib |
| if not os.path.exists(symbols): |
| return None |
| |
| # Make sure the symbols path is not a directory. |
| if os.path.isdir(symbols): |
| return None |
| |
| cmd = [ToolPath("addr2line"), "--functions", "--inlines", |
| "--demangle", "--exe=" + symbols] |
| child = _PIPE_ADDR2LINE_CACHE.GetProcess(cmd) |
| |
| for addr in addrs: |
| child.stdin.write("0x%s\n" % addr) |
| child.stdin.flush() |
| records = [] |
| first = True |
| while True: |
| symbol = child.stdout.readline().strip() |
| if symbol == "??": |
| symbol = None |
| location = child.stdout.readline().strip() |
| if location == "??:0" or location == "??:?": |
| location = None |
| if symbol is None and location is None: |
| break |
| records.append((symbol, location)) |
| if first: |
| # Write a blank line as a sentinel so we know when to stop |
| # reading inlines from the output. |
| # The blank line will cause addr2line to emit "??\n??:0\n". |
| child.stdin.write("\n") |
| first = False |
| result[addr] = records |
| addr_cache[addr] = records |
| return result |
| |
| |
| def StripPC(addr): |
| """Strips the Thumb bit a program counter address when appropriate. |
| |
| Args: |
| addr: the program counter address |
| |
| Returns: |
| The stripped program counter address. |
| """ |
| global ARCH |
| if ARCH == "arm": |
| return addr & ~1 |
| return addr |
| |
| |
| def CallObjdumpForSet(lib, unique_addrs): |
| """Use objdump to find out the names of the containing functions. |
| |
| Args: |
| lib: library (or executable) pathname containing symbols |
| unique_addrs: set of string hexidecimal addresses to find the functions for. |
| |
| Returns: |
| A dictionary of the form {addr: (string symbol, offset)}. |
| """ |
| if not lib: |
| return None |
| |
| result = {} |
| addrs = sorted(unique_addrs) |
| |
| addr_cache = None |
| if lib in _SYMBOL_INFORMATION_OBJDUMP_CACHE: |
| addr_cache = _SYMBOL_INFORMATION_OBJDUMP_CACHE[lib] |
| |
| # Go through and handle all known addresses. |
| for x in range(len(addrs)): |
| next_addr = addrs.pop(0) |
| if next_addr in addr_cache: |
| result[next_addr] = addr_cache[next_addr] |
| else: |
| # Re-add, needs to be symbolized. |
| addrs.append(next_addr) |
| |
| if not addrs: |
| # Everything was cached, we're done. |
| return result |
| else: |
| addr_cache = {} |
| _SYMBOL_INFORMATION_OBJDUMP_CACHE[lib] = addr_cache |
| |
| symbols = SYMBOLS_DIR + lib |
| if not os.path.exists(symbols): |
| symbols = lib |
| if not os.path.exists(symbols): |
| return None |
| |
| start_addr_dec = str(StripPC(int(addrs[0], 16))) |
| stop_addr_dec = str(StripPC(int(addrs[-1], 16)) + 8) |
| cmd = [ToolPath("objdump"), |
| "--section=.text", |
| "--demangle", |
| "--disassemble", |
| "--start-address=" + start_addr_dec, |
| "--stop-address=" + stop_addr_dec, |
| symbols] |
| |
| # Function lines look like: |
| # 000177b0 <android::IBinder::~IBinder()+0x2c>: |
| # We pull out the address and function first. Then we check for an optional |
| # offset. This is tricky due to functions that look like "operator+(..)+0x2c" |
| func_regexp = re.compile("(^[a-f0-9]*) \<(.*)\>:$") |
| offset_regexp = re.compile("(.*)\+0x([a-f0-9]*)") |
| |
| # A disassembly line looks like: |
| # 177b2: b510 push {r4, lr} |
| asm_regexp = re.compile("(^[ a-f0-9]*):[ a-f0-0]*.*$") |
| |
| current_symbol = None # The current function symbol in the disassembly. |
| current_symbol_addr = 0 # The address of the current function. |
| addr_index = 0 # The address that we are currently looking for. |
| |
| stream = subprocess.Popen(cmd, stdout=subprocess.PIPE).stdout |
| for line in stream: |
| # Is it a function line like: |
| # 000177b0 <android::IBinder::~IBinder()>: |
| components = func_regexp.match(line) |
| if components: |
| # This is a new function, so record the current function and its address. |
| current_symbol_addr = int(components.group(1), 16) |
| current_symbol = components.group(2) |
| |
| # Does it have an optional offset like: "foo(..)+0x2c"? |
| components = offset_regexp.match(current_symbol) |
| if components: |
| current_symbol = components.group(1) |
| offset = components.group(2) |
| if offset: |
| current_symbol_addr -= int(offset, 16) |
| |
| # Is it an disassembly line like: |
| # 177b2: b510 push {r4, lr} |
| components = asm_regexp.match(line) |
| if components: |
| addr = components.group(1) |
| target_addr = addrs[addr_index] |
| i_addr = int(addr, 16) |
| i_target = StripPC(int(target_addr, 16)) |
| if i_addr == i_target: |
| result[target_addr] = (current_symbol, i_target - current_symbol_addr) |
| addr_cache[target_addr] = result[target_addr] |
| addr_index += 1 |
| if addr_index >= len(addrs): |
| break |
| stream.close() |
| |
| return result |
| |
| |
| def CallCppFilt(mangled_symbol): |
| if mangled_symbol in _SYMBOL_DEMANGLING_CACHE: |
| return _SYMBOL_DEMANGLING_CACHE[mangled_symbol] |
| |
| cmd = [ToolPath("c++filt")] |
| process = _PIPE_CPPFILT_CACHE.GetProcess(cmd) |
| process.stdin.write(mangled_symbol) |
| process.stdin.write("\n") |
| process.stdin.flush() |
| |
| demangled_symbol = process.stdout.readline().strip() |
| |
| _SYMBOL_DEMANGLING_CACHE[mangled_symbol] = demangled_symbol |
| |
| return demangled_symbol |
| |
| |
| def FormatSymbolWithOffset(symbol, offset): |
| if offset == 0: |
| return symbol |
| return "%s+%d" % (symbol, offset) |
| |
| |
| def GetAbiFromToolchain(toolchain_var, bits): |
| toolchain = os.environ.get(toolchain_var) |
| if not toolchain: |
| return None |
| |
| toolchain_match = re.search("\/(aarch64|arm|mips|x86)\/", toolchain) |
| if toolchain_match: |
| abi = toolchain_match.group(1) |
| if abi == "aarch64": |
| return "arm64" |
| elif bits == 64: |
| if abi == "x86": |
| return "x86_64" |
| elif abi == "mips": |
| return "mips64" |
| return abi |
| return None |
| |
| def Get32BitArch(): |
| # Check for ANDROID_TOOLCHAIN_2ND_ARCH first, if set, use that. |
| # If not try ANDROID_TOOLCHAIN to find the arch. |
| # If this is not set, then default to arm. |
| arch = GetAbiFromToolchain("ANDROID_TOOLCHAIN_2ND_ARCH", 32) |
| if not arch: |
| arch = GetAbiFromToolchain("ANDROID_TOOLCHAIN", 32) |
| if not arch: |
| return "arm" |
| return arch |
| |
| def Get64BitArch(): |
| # Check for ANDROID_TOOLCHAIN, if it is set, we can figure out the |
| # arch this way. If this is not set, then default to arm64. |
| arch = GetAbiFromToolchain("ANDROID_TOOLCHAIN", 64) |
| if not arch: |
| return "arm64" |
| return arch |
| |
| def SetAbi(lines): |
| global ARCH |
| |
| abi_line = re.compile("ABI: \'(.*)\'") |
| trace_line = re.compile("\#[0-9]+[ \t]+..[ \t]+([0-9a-f]{8}|[0-9a-f]{16})([ \t]+|$)") |
| asan_trace_line = re.compile("\#[0-9]+[ \t]+0x([0-9a-f]+)[ \t]+") |
| |
| ARCH = None |
| for line in lines: |
| abi_match = abi_line.search(line) |
| if abi_match: |
| ARCH = abi_match.group(1) |
| break |
| trace_match = trace_line.search(line) |
| if trace_match: |
| # Try to guess the arch, we know the bitness. |
| if len(trace_match.group(1)) == 16: |
| ARCH = Get64BitArch() |
| else: |
| ARCH = Get32BitArch() |
| break |
| asan_trace_match = asan_trace_line.search(line) |
| if asan_trace_match: |
| # We might be able to guess the bitness by the length of the address. |
| if len(asan_trace_match.group(1)) > 8: |
| ARCH = Get64BitArch() |
| # We know for a fact this is 64 bit, so we are done. |
| break |
| else: |
| ARCH = Get32BitArch() |
| # This might be 32 bit, or just a small address. Keep going in this |
| # case, but if we couldn't figure anything else out, go with 32 bit. |
| if not ARCH: |
| raise Exception("Could not determine arch from input, use --arch=XXX to specify it") |
| |
| |
| class FindToolchainTests(unittest.TestCase): |
| def assert_toolchain_found(self, abi): |
| global ARCH |
| ARCH = abi |
| FindToolchain() # Will throw on failure. |
| |
| def test_toolchains_found(self): |
| self.assert_toolchain_found("arm") |
| self.assert_toolchain_found("arm64") |
| self.assert_toolchain_found("mips") |
| self.assert_toolchain_found("x86") |
| self.assert_toolchain_found("x86_64") |
| |
| class SetArchTests(unittest.TestCase): |
| def test_abi_check(self): |
| global ARCH |
| |
| SetAbi(["ABI: 'arm'"]) |
| self.assertEqual(ARCH, "arm") |
| SetAbi(["ABI: 'arm64'"]) |
| self.assertEqual(ARCH, "arm64") |
| |
| SetAbi(["ABI: 'mips'"]) |
| self.assertEqual(ARCH, "mips") |
| SetAbi(["ABI: 'mips64'"]) |
| self.assertEqual(ARCH, "mips64") |
| |
| SetAbi(["ABI: 'x86'"]) |
| self.assertEqual(ARCH, "x86") |
| SetAbi(["ABI: 'x86_64'"]) |
| self.assertEqual(ARCH, "x86_64") |
| |
| def test_32bit_trace_line_toolchain(self): |
| global ARCH |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/arm/arm-linux-androideabi-4.9/bin" |
| SetAbi(["#00 pc 000374e0"]) |
| self.assertEqual(ARCH, "arm") |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/mips/arm-linux-androideabi-4.9/bin" |
| SetAbi(["#00 pc 000374e0"]) |
| self.assertEqual(ARCH, "mips") |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/x86/arm-linux-androideabi-4.9/bin" |
| SetAbi(["#00 pc 000374e0"]) |
| self.assertEqual(ARCH, "x86") |
| |
| def test_32bit_trace_line_toolchain_2nd(self): |
| global ARCH |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN_2ND_ARCH"] = "linux-x86/arm/arm-linux-androideabi-4.9/bin" |
| os.environ["ANDROID_TOOLCHAIN_ARCH"] = "linux-x86/aarch64/aarch64-linux-android-4.9/bin" |
| SetAbi(["#00 pc 000374e0"]) |
| self.assertEqual(ARCH, "arm") |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN_2ND_ARCH"] = "linux-x86/mips/mips-linux-androideabi-4.9/bin" |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/unknown/unknown-linux-androideabi-4.9/bin" |
| SetAbi(["#00 pc 000374e0"]) |
| self.assertEqual(ARCH, "mips") |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN_2ND_ARCH"] = "linux-x86/x86/x86-linux-androideabi-4.9/bin" |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/unknown/unknown-linux-androideabi-4.9/bin" |
| SetAbi(["#00 pc 000374e0"]) |
| self.assertEqual(ARCH, "x86") |
| |
| def test_64bit_trace_line_toolchain(self): |
| global ARCH |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/aarch/aarch-linux-androideabi-4.9/bin" |
| SetAbi(["#00 pc 00000000000374e0"]) |
| self.assertEqual(ARCH, "arm64") |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/mips/arm-linux-androideabi-4.9/bin" |
| SetAbi(["#00 pc 00000000000374e0"]) |
| self.assertEqual(ARCH, "mips64") |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/x86/arm-linux-androideabi-4.9/bin" |
| SetAbi(["#00 pc 00000000000374e0"]) |
| self.assertEqual(ARCH, "x86_64") |
| |
| def test_trace_default_abis(self): |
| global ARCH |
| |
| os.environ.clear() |
| SetAbi(["#00 pc 000374e0"]) |
| self.assertEqual(ARCH, "arm") |
| SetAbi(["#00 pc 00000000000374e0"]) |
| self.assertEqual(ARCH, "arm64") |
| |
| def test_32bit_asan_trace_line_toolchain(self): |
| global ARCH |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/arm/arm-linux-androideabi-4.9/bin" |
| SetAbi(["#10 0xb5eeba5d (/system/vendor/lib/egl/libGLESv1_CM_adreno.so+0xfa5d)"]) |
| self.assertEqual(ARCH, "arm") |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/mips/arm-linux-androideabi-4.9/bin" |
| SetAbi(["#10 0xb5eeba5d (/system/vendor/lib/egl/libGLESv1_CM_adreno.so+0xfa5d)"]) |
| self.assertEqual(ARCH, "mips") |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/x86/arm-linux-androideabi-4.9/bin" |
| SetAbi(["#10 0xb5eeba5d (/system/vendor/lib/egl/libGLESv1_CM_adreno.so+0xfa5d)"]) |
| self.assertEqual(ARCH, "x86") |
| |
| def test_32bit_asan_trace_line_toolchain_2nd(self): |
| global ARCH |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN_2ND_ARCH"] = "linux-x86/arm/arm-linux-androideabi-4.9/bin" |
| os.environ["ANDROID_TOOLCHAIN_ARCH"] = "linux-x86/aarch64/aarch64-linux-android-4.9/bin" |
| SetAbi(["#3 0xae1725b5 (/system/vendor/lib/libllvm-glnext.so+0x6435b5)"]) |
| self.assertEqual(ARCH, "arm") |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN_2ND_ARCH"] = "linux-x86/mips/mips-linux-androideabi-4.9/bin" |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/unknown/unknown-linux-androideabi-4.9/bin" |
| SetAbi(["#3 0xae1725b5 (/system/vendor/lib/libllvm-glnext.so+0x6435b5)"]) |
| self.assertEqual(ARCH, "mips") |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN_2ND_ARCH"] = "linux-x86/x86/x86-linux-androideabi-4.9/bin" |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/unknown/unknown-linux-androideabi-4.9/bin" |
| SetAbi(["#3 0xae1725b5 (/system/vendor/lib/libllvm-glnext.so+0x6435b5)"]) |
| self.assertEqual(ARCH, "x86") |
| |
| def test_64bit_asan_trace_line_toolchain(self): |
| global ARCH |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/aarch/aarch-linux-androideabi-4.9/bin" |
| SetAbi(["#0 0x11b35d33bf (/system/lib/libclang_rt.asan-arm-android.so+0x823bf)"]) |
| self.assertEqual(ARCH, "arm64") |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/mips/arm-linux-androideabi-4.9/bin" |
| SetAbi(["#1 0x11b35d33bf (/system/lib/libclang_rt.asan-arm-android.so+0x823bf)"]) |
| self.assertEqual(ARCH, "mips64") |
| |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/x86/arm-linux-androideabi-4.9/bin" |
| SetAbi(["#12 0x11b35d33bf (/system/lib/libclang_rt.asan-arm-android.so+0x823bf)"]) |
| self.assertEqual(ARCH, "x86_64") |
| |
| # Verify that if an address that might be 32 bit comes first, that |
| # encountering a 64 bit address returns a 64 bit abi. |
| ARCH = None |
| os.environ.clear() |
| os.environ["ANDROID_TOOLCHAIN"] = "linux-x86/x86/arm-linux-androideabi-4.9/bin" |
| SetAbi(["#12 0x5d33bf (/system/lib/libclang_rt.asan-arm-android.so+0x823bf)", |
| "#12 0x11b35d33bf (/system/lib/libclang_rt.asan-arm-android.so+0x823bf)"]) |
| self.assertEqual(ARCH, "x86_64") |
| |
| def test_asan_trace_default_abis(self): |
| global ARCH |
| |
| os.environ.clear() |
| SetAbi(["#4 0x1234349ab (/system/vendor/lib/libllvm-glnext.so+0x64fc4f)"]) |
| self.assertEqual(ARCH, "arm64") |
| SetAbi(["#1 0xae17ec4f (/system/vendor/lib/libllvm-glnext.so+0x64fc4f)"]) |
| self.assertEqual(ARCH, "arm") |
| |
| def test_no_abi(self): |
| global ARCH |
| |
| self.assertRaisesRegexp(Exception, "Could not determine arch from input, use --arch=XXX to specify it", SetAbi, []) |
| |
| if __name__ == '__main__': |
| unittest.main() |