gcc/libsanitizer/sanitizer_common/sanitizer_symbolizer_libcdep.cc
Max Ostapenko 696d846a56 libsanitizer merge from upstream r250806.
libsanitizer/

2015-10-20  Maxim Ostapenko  <m.ostapenko@partner.samsung.com>

	* All source files: Merge from upstream r250806.
	* configure.ac (link_sanitizer_common): Add -lrt flag.
	* configure.tgt: Enable TSAN and LSAN for aarch64-linux targets.
	Set CXX_ABI_NEEDED=true for darwin.
	* asan/Makefile.am (asan_files): Add new files.
	(DEFS): Add DCAN_SANITIZE_UB=0 and remove unused and legacy
	DASAN_FLEXIBLE_MAPPING_AND_OFFSET=0.
	* asan/Makefile.in: Regenerate.
	* ubsan/Makefile.am (ubsan_files): Add new files.
	(DEFS): Add DCAN_SANITIZE_UB=1.
	(libubsan_la_LIBADD): Add -lc++abi if CXX_ABI_NEEDED is true.
	* ubsan/Makefile.in: Regenerate.
	* tsan/Makefile.am (tsan_files): Add new files.
	(DEFS): Add DCAN_SANITIZE_UB=0.
	* tsan/Makefile.in: Regenerate.
	* sanitizer_common/Makefile.am (sanitizer_common_files): Add new files.
	* sanitizer_common/Makefile.in: Regenerate.
	* asan/libtool-version: Bump the libasan SONAME.

From-SVN: r229111
2015-10-21 10:32:45 +03:00

427 lines
14 KiB
C++

//===-- sanitizer_symbolizer_libcdep.cc -----------------------------------===//
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file is shared between AddressSanitizer and ThreadSanitizer
// run-time libraries.
//===----------------------------------------------------------------------===//
#include "sanitizer_allocator_internal.h"
#include "sanitizer_internal_defs.h"
#include "sanitizer_symbolizer_internal.h"
namespace __sanitizer {
const char *ExtractToken(const char *str, const char *delims, char **result) {
uptr prefix_len = internal_strcspn(str, delims);
*result = (char*)InternalAlloc(prefix_len + 1);
internal_memcpy(*result, str, prefix_len);
(*result)[prefix_len] = '\0';
const char *prefix_end = str + prefix_len;
if (*prefix_end != '\0') prefix_end++;
return prefix_end;
}
const char *ExtractInt(const char *str, const char *delims, int *result) {
char *buff;
const char *ret = ExtractToken(str, delims, &buff);
if (buff != 0) {
*result = (int)internal_atoll(buff);
}
InternalFree(buff);
return ret;
}
const char *ExtractUptr(const char *str, const char *delims, uptr *result) {
char *buff;
const char *ret = ExtractToken(str, delims, &buff);
if (buff != 0) {
*result = (uptr)internal_atoll(buff);
}
InternalFree(buff);
return ret;
}
const char *ExtractTokenUpToDelimiter(const char *str, const char *delimiter,
char **result) {
const char *found_delimiter = internal_strstr(str, delimiter);
uptr prefix_len =
found_delimiter ? found_delimiter - str : internal_strlen(str);
*result = (char *)InternalAlloc(prefix_len + 1);
internal_memcpy(*result, str, prefix_len);
(*result)[prefix_len] = '\0';
const char *prefix_end = str + prefix_len;
if (*prefix_end != '\0') prefix_end += internal_strlen(delimiter);
return prefix_end;
}
SymbolizedStack *Symbolizer::SymbolizePC(uptr addr) {
BlockingMutexLock l(&mu_);
const char *module_name;
uptr module_offset;
SymbolizedStack *res = SymbolizedStack::New(addr);
if (!FindModuleNameAndOffsetForAddress(addr, &module_name, &module_offset))
return res;
// Always fill data about module name and offset.
res->info.FillModuleInfo(module_name, module_offset);
for (auto iter = Iterator(&tools_); iter.hasNext();) {
auto *tool = iter.next();
SymbolizerScope sym_scope(this);
if (tool->SymbolizePC(addr, res)) {
return res;
}
}
return res;
}
bool Symbolizer::SymbolizeData(uptr addr, DataInfo *info) {
BlockingMutexLock l(&mu_);
const char *module_name;
uptr module_offset;
if (!FindModuleNameAndOffsetForAddress(addr, &module_name, &module_offset))
return false;
info->Clear();
info->module = internal_strdup(module_name);
info->module_offset = module_offset;
for (auto iter = Iterator(&tools_); iter.hasNext();) {
auto *tool = iter.next();
SymbolizerScope sym_scope(this);
if (tool->SymbolizeData(addr, info)) {
return true;
}
}
return true;
}
bool Symbolizer::GetModuleNameAndOffsetForPC(uptr pc, const char **module_name,
uptr *module_address) {
BlockingMutexLock l(&mu_);
const char *internal_module_name = nullptr;
if (!FindModuleNameAndOffsetForAddress(pc, &internal_module_name,
module_address))
return false;
if (module_name)
*module_name = module_names_.GetOwnedCopy(internal_module_name);
return true;
}
void Symbolizer::Flush() {
BlockingMutexLock l(&mu_);
for (auto iter = Iterator(&tools_); iter.hasNext();) {
auto *tool = iter.next();
SymbolizerScope sym_scope(this);
tool->Flush();
}
}
const char *Symbolizer::Demangle(const char *name) {
BlockingMutexLock l(&mu_);
for (auto iter = Iterator(&tools_); iter.hasNext();) {
auto *tool = iter.next();
SymbolizerScope sym_scope(this);
if (const char *demangled = tool->Demangle(name))
return demangled;
}
return PlatformDemangle(name);
}
void Symbolizer::PrepareForSandboxing() {
BlockingMutexLock l(&mu_);
PlatformPrepareForSandboxing();
}
bool Symbolizer::FindModuleNameAndOffsetForAddress(uptr address,
const char **module_name,
uptr *module_offset) {
LoadedModule *module = FindModuleForAddress(address);
if (module == 0)
return false;
*module_name = module->full_name();
*module_offset = address - module->base_address();
return true;
}
LoadedModule *Symbolizer::FindModuleForAddress(uptr address) {
bool modules_were_reloaded = false;
if (!modules_fresh_) {
for (uptr i = 0; i < n_modules_; i++)
modules_[i].clear();
n_modules_ =
GetListOfModules(modules_, kMaxNumberOfModules, /* filter */ nullptr);
CHECK_GT(n_modules_, 0);
CHECK_LT(n_modules_, kMaxNumberOfModules);
modules_fresh_ = true;
modules_were_reloaded = true;
}
for (uptr i = 0; i < n_modules_; i++) {
if (modules_[i].containsAddress(address)) {
return &modules_[i];
}
}
// Reload the modules and look up again, if we haven't tried it yet.
if (!modules_were_reloaded) {
// FIXME: set modules_fresh_ from dlopen()/dlclose() interceptors.
// It's too aggressive to reload the list of modules each time we fail
// to find a module for a given address.
modules_fresh_ = false;
return FindModuleForAddress(address);
}
return 0;
}
Symbolizer *Symbolizer::GetOrInit() {
SpinMutexLock l(&init_mu_);
if (symbolizer_)
return symbolizer_;
symbolizer_ = PlatformInit();
CHECK(symbolizer_);
return symbolizer_;
}
// For now we assume the following protocol:
// For each request of the form
// <module_name> <module_offset>
// passed to STDIN, external symbolizer prints to STDOUT response:
// <function_name>
// <file_name>:<line_number>:<column_number>
// <function_name>
// <file_name>:<line_number>:<column_number>
// ...
// <empty line>
class LLVMSymbolizerProcess : public SymbolizerProcess {
public:
explicit LLVMSymbolizerProcess(const char *path) : SymbolizerProcess(path) {}
private:
bool ReachedEndOfOutput(const char *buffer, uptr length) const override {
// Empty line marks the end of llvm-symbolizer output.
return length >= 2 && buffer[length - 1] == '\n' &&
buffer[length - 2] == '\n';
}
void GetArgV(const char *path_to_binary,
const char *(&argv)[kArgVMax]) const override {
#if defined(__x86_64h__)
const char* const kSymbolizerArch = "--default-arch=x86_64h";
#elif defined(__x86_64__)
const char* const kSymbolizerArch = "--default-arch=x86_64";
#elif defined(__i386__)
const char* const kSymbolizerArch = "--default-arch=i386";
#elif defined(__powerpc64__) && defined(__BIG_ENDIAN__)
const char* const kSymbolizerArch = "--default-arch=powerpc64";
#elif defined(__powerpc64__) && defined(__LITTLE_ENDIAN__)
const char* const kSymbolizerArch = "--default-arch=powerpc64le";
#else
const char* const kSymbolizerArch = "--default-arch=unknown";
#endif
const char *const inline_flag = common_flags()->symbolize_inline_frames
? "--inlining=true"
: "--inlining=false";
int i = 0;
argv[i++] = path_to_binary;
argv[i++] = inline_flag;
argv[i++] = kSymbolizerArch;
argv[i++] = nullptr;
}
};
LLVMSymbolizer::LLVMSymbolizer(const char *path, LowLevelAllocator *allocator)
: symbolizer_process_(new(*allocator) LLVMSymbolizerProcess(path)) {}
// Parse a <file>:<line>[:<column>] buffer. The file path may contain colons on
// Windows, so extract tokens from the right hand side first. The column info is
// also optional.
static const char *ParseFileLineInfo(AddressInfo *info, const char *str) {
char *file_line_info = 0;
str = ExtractToken(str, "\n", &file_line_info);
CHECK(file_line_info);
// Parse the last :<int>, which must be there.
char *last_colon = internal_strrchr(file_line_info, ':');
CHECK(last_colon);
int line_or_column = internal_atoll(last_colon + 1);
// Truncate the string at the last colon and find the next-to-last colon.
*last_colon = '\0';
last_colon = internal_strrchr(file_line_info, ':');
if (last_colon && IsDigit(last_colon[1])) {
// If the second-to-last colon is followed by a digit, it must be the line
// number, and the previous parsed number was a column.
info->line = internal_atoll(last_colon + 1);
info->column = line_or_column;
*last_colon = '\0';
} else {
// Otherwise, we have line info but no column info.
info->line = line_or_column;
info->column = 0;
}
ExtractToken(file_line_info, "", &info->file);
InternalFree(file_line_info);
return str;
}
// Parses one or more two-line strings in the following format:
// <function_name>
// <file_name>:<line_number>[:<column_number>]
// Used by LLVMSymbolizer, Addr2LinePool and InternalSymbolizer, since all of
// them use the same output format.
void ParseSymbolizePCOutput(const char *str, SymbolizedStack *res) {
bool top_frame = true;
SymbolizedStack *last = res;
while (true) {
char *function_name = 0;
str = ExtractToken(str, "\n", &function_name);
CHECK(function_name);
if (function_name[0] == '\0') {
// There are no more frames.
InternalFree(function_name);
break;
}
SymbolizedStack *cur;
if (top_frame) {
cur = res;
top_frame = false;
} else {
cur = SymbolizedStack::New(res->info.address);
cur->info.FillModuleInfo(res->info.module, res->info.module_offset);
last->next = cur;
last = cur;
}
AddressInfo *info = &cur->info;
info->function = function_name;
str = ParseFileLineInfo(info, str);
// Functions and filenames can be "??", in which case we write 0
// to address info to mark that names are unknown.
if (0 == internal_strcmp(info->function, "??")) {
InternalFree(info->function);
info->function = 0;
}
if (0 == internal_strcmp(info->file, "??")) {
InternalFree(info->file);
info->file = 0;
}
}
}
// Parses a two-line string in the following format:
// <symbol_name>
// <start_address> <size>
// Used by LLVMSymbolizer and InternalSymbolizer.
void ParseSymbolizeDataOutput(const char *str, DataInfo *info) {
str = ExtractToken(str, "\n", &info->name);
str = ExtractUptr(str, " ", &info->start);
str = ExtractUptr(str, "\n", &info->size);
}
bool LLVMSymbolizer::SymbolizePC(uptr addr, SymbolizedStack *stack) {
if (const char *buf = SendCommand(/*is_data*/ false, stack->info.module,
stack->info.module_offset)) {
ParseSymbolizePCOutput(buf, stack);
return true;
}
return false;
}
bool LLVMSymbolizer::SymbolizeData(uptr addr, DataInfo *info) {
if (const char *buf =
SendCommand(/*is_data*/ true, info->module, info->module_offset)) {
ParseSymbolizeDataOutput(buf, info);
info->start += (addr - info->module_offset); // Add the base address.
return true;
}
return false;
}
const char *LLVMSymbolizer::SendCommand(bool is_data, const char *module_name,
uptr module_offset) {
CHECK(module_name);
internal_snprintf(buffer_, kBufferSize, "%s\"%s\" 0x%zx\n",
is_data ? "DATA " : "", module_name, module_offset);
return symbolizer_process_->SendCommand(buffer_);
}
SymbolizerProcess::SymbolizerProcess(const char *path, bool use_forkpty)
: path_(path),
input_fd_(kInvalidFd),
output_fd_(kInvalidFd),
times_restarted_(0),
failed_to_start_(false),
reported_invalid_path_(false),
use_forkpty_(use_forkpty) {
CHECK(path_);
CHECK_NE(path_[0], '\0');
}
const char *SymbolizerProcess::SendCommand(const char *command) {
for (; times_restarted_ < kMaxTimesRestarted; times_restarted_++) {
// Start or restart symbolizer if we failed to send command to it.
if (const char *res = SendCommandImpl(command))
return res;
Restart();
}
if (!failed_to_start_) {
Report("WARNING: Failed to use and restart external symbolizer!\n");
failed_to_start_ = true;
}
return 0;
}
const char *SymbolizerProcess::SendCommandImpl(const char *command) {
if (input_fd_ == kInvalidFd || output_fd_ == kInvalidFd)
return 0;
if (!WriteToSymbolizer(command, internal_strlen(command)))
return 0;
if (!ReadFromSymbolizer(buffer_, kBufferSize))
return 0;
return buffer_;
}
bool SymbolizerProcess::Restart() {
if (input_fd_ != kInvalidFd)
CloseFile(input_fd_);
if (output_fd_ != kInvalidFd)
CloseFile(output_fd_);
return StartSymbolizerSubprocess();
}
bool SymbolizerProcess::ReadFromSymbolizer(char *buffer, uptr max_length) {
if (max_length == 0)
return true;
uptr read_len = 0;
while (true) {
uptr just_read = 0;
bool success = ReadFromFile(input_fd_, buffer + read_len,
max_length - read_len - 1, &just_read);
// We can't read 0 bytes, as we don't expect external symbolizer to close
// its stdout.
if (!success || just_read == 0) {
Report("WARNING: Can't read from symbolizer at fd %d\n", input_fd_);
return false;
}
read_len += just_read;
if (ReachedEndOfOutput(buffer, read_len))
break;
}
buffer[read_len] = '\0';
return true;
}
bool SymbolizerProcess::WriteToSymbolizer(const char *buffer, uptr length) {
if (length == 0)
return true;
uptr write_len = 0;
bool success = WriteToFile(output_fd_, buffer, length, &write_len);
if (!success || write_len != length) {
Report("WARNING: Can't write to symbolizer at fd %d\n", output_fd_);
return false;
}
return true;
}
} // namespace __sanitizer