2022-05-24 18:06:29 +00:00
/*
* backward . hpp
* Copyright 2013 Google Inc . All Rights Reserved .
*
* Permission is hereby granted , free of charge , to any person obtaining a copy
* of this software and associated documentation files ( the " Software " ) , to deal
* in the Software without restriction , including without limitation the rights
* to use , copy , modify , merge , publish , distribute , sublicense , and / or sell
* copies of the Software , and to permit persons to whom the Software is
* furnished to do so , subject to the following conditions :
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software .
*
* THE SOFTWARE IS PROVIDED " AS IS " , WITHOUT WARRANTY OF ANY KIND , EXPRESS OR
* IMPLIED , INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY ,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT . IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM , DAMAGES OR OTHER
* LIABILITY , WHETHER IN AN ACTION OF CONTRACT , TORT OR OTHERWISE , ARISING FROM ,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE .
*/
# ifndef H_6B9572DA_A64B_49E6_B234_051480991C89
# define H_6B9572DA_A64B_49E6_B234_051480991C89
# ifndef __cplusplus
# error "It's not going to compile without a C++ compiler..."
# endif
# if defined(BACKWARD_CXX11)
# elif defined(BACKWARD_CXX98)
# else
# if __cplusplus >= 201103L || (defined(_MSC_VER) && _MSC_VER >= 1800)
# define BACKWARD_CXX11
# define BACKWARD_ATLEAST_CXX11
# define BACKWARD_ATLEAST_CXX98
# if __cplusplus >= 201703L || (defined(_MSVC_LANG) && _MSVC_LANG >= 201703L)
# define BACKWARD_ATLEAST_CXX17
# endif
# else
# define BACKWARD_CXX98
# define BACKWARD_ATLEAST_CXX98
# endif
# endif
// You can define one of the following (or leave it to the auto-detection):
//
// #define BACKWARD_SYSTEM_LINUX
// - specialization for linux
//
// #define BACKWARD_SYSTEM_DARWIN
// - specialization for Mac OS X 10.5 and later.
//
// #define BACKWARD_SYSTEM_WINDOWS
// - specialization for Windows (Clang 9 and MSVC2017)
//
// #define BACKWARD_SYSTEM_UNKNOWN
// - placebo implementation, does nothing.
//
# if defined(BACKWARD_SYSTEM_LINUX)
# elif defined(BACKWARD_SYSTEM_DARWIN)
# elif defined(BACKWARD_SYSTEM_UNKNOWN)
# elif defined(BACKWARD_SYSTEM_WINDOWS)
# else
# if defined(__linux) || defined(__linux__)
# define BACKWARD_SYSTEM_LINUX
# elif defined(__APPLE__)
# define BACKWARD_SYSTEM_DARWIN
# elif defined(_WIN32)
# define BACKWARD_SYSTEM_WINDOWS
# else
# define BACKWARD_SYSTEM_UNKNOWN
# endif
# endif
# define NOINLINE __attribute__((noinline))
# include <algorithm>
# include <cctype>
# include <cstdio>
# include <cstdlib>
# include <cstring>
# include <fstream>
# include <iomanip>
# include <iostream>
# include <limits>
# include <new>
# include <sstream>
# include <streambuf>
# include <string>
# include <vector>
# include <exception>
# include <iterator>
# if defined(BACKWARD_SYSTEM_LINUX)
// On linux, backtrace can back-trace or "walk" the stack using the following
// libraries:
//
// #define BACKWARD_HAS_UNWIND 1
// - unwind comes from libgcc, but I saw an equivalent inside clang itself.
// - with unwind, the stacktrace is as accurate as it can possibly be, since
// this is used by the C++ runtine in gcc/clang for stack unwinding on
// exception.
// - normally libgcc is already linked to your program by default.
//
// #define BACKWARD_HAS_LIBUNWIND 1
// - libunwind provides, in some cases, a more accurate stacktrace as it knows
// to decode signal handler frames and lets us edit the context registers when
// unwinding, allowing stack traces over bad function references.
//
// #define BACKWARD_HAS_BACKTRACE == 1
// - backtrace seems to be a little bit more portable than libunwind, but on
// linux, it uses unwind anyway, but abstract away a tiny information that is
// sadly really important in order to get perfectly accurate stack traces.
// - backtrace is part of the (e)glib library.
//
// The default is:
// #define BACKWARD_HAS_UNWIND == 1
//
// Note that only one of the define should be set to 1 at a time.
//
# if BACKWARD_HAS_UNWIND == 1
# elif BACKWARD_HAS_LIBUNWIND == 1
# elif BACKWARD_HAS_BACKTRACE == 1
# else
# undef BACKWARD_HAS_UNWIND
# define BACKWARD_HAS_UNWIND 1
# undef BACKWARD_HAS_LIBUNWIND
# define BACKWARD_HAS_LIBUNWIND 0
# undef BACKWARD_HAS_BACKTRACE
# define BACKWARD_HAS_BACKTRACE 0
# endif
// On linux, backward can extract detailed information about a stack trace
// using one of the following libraries:
//
// #define BACKWARD_HAS_DW 1
// - libdw gives you the most juicy details out of your stack traces:
// - object filename
// - function name
// - source filename
// - line and column numbers
// - source code snippet (assuming the file is accessible)
// - variable names (if not optimized out)
// - variable values (not supported by backward-cpp)
// - You need to link with the lib "dw":
// - apt-get install libdw-dev
// - g++/clang++ -ldw ...
//
// #define BACKWARD_HAS_BFD 1
// - With libbfd, you get a fair amount of details:
// - object filename
// - function name
// - source filename
// - line numbers
// - source code snippet (assuming the file is accessible)
// - You need to link with the lib "bfd":
// - apt-get install binutils-dev
// - g++/clang++ -lbfd ...
//
// #define BACKWARD_HAS_DWARF 1
// - libdwarf gives you the most juicy details out of your stack traces:
// - object filename
// - function name
// - source filename
// - line and column numbers
// - source code snippet (assuming the file is accessible)
// - variable names (if not optimized out)
// - variable values (not supported by backward-cpp)
// - You need to link with the lib "dwarf":
// - apt-get install libdwarf-dev
// - g++/clang++ -ldwarf ...
//
// #define BACKWARD_HAS_BACKTRACE_SYMBOL 1
// - backtrace provides minimal details for a stack trace:
// - object filename
// - function name
// - backtrace is part of the (e)glib library.
//
// The default is:
// #define BACKWARD_HAS_BACKTRACE_SYMBOL == 1
//
// Note that only one of the define should be set to 1 at a time.
//
# if BACKWARD_HAS_DW == 1
# elif BACKWARD_HAS_BFD == 1
# elif BACKWARD_HAS_DWARF == 1
# elif BACKWARD_HAS_BACKTRACE_SYMBOL == 1
# else
# undef BACKWARD_HAS_DW
# define BACKWARD_HAS_DW 0
# undef BACKWARD_HAS_BFD
# define BACKWARD_HAS_BFD 0
# undef BACKWARD_HAS_DWARF
# define BACKWARD_HAS_DWARF 0
# undef BACKWARD_HAS_BACKTRACE_SYMBOL
# define BACKWARD_HAS_BACKTRACE_SYMBOL 1
# endif
# include <cxxabi.h>
# include <fcntl.h>
# ifdef __ANDROID__
// Old Android API levels define _Unwind_Ptr in both link.h and
// unwind.h Rename the one in link.h as we are not going to be using
// it
# define _Unwind_Ptr _Unwind_Ptr_Custom
# include <link.h>
# undef _Unwind_Ptr
# else
# include <link.h>
# endif
# if defined(__ppc__) || defined(__powerpc) || defined(__powerpc__) || \
defined ( __POWERPC__ )
// Linux kernel header required for the struct pt_regs definition
// to access the NIP (Next Instruction Pointer) register value
# include <asm/ptrace.h>
# endif
# include <signal.h>
# include <sys/stat.h>
# include <syscall.h>
# include <unistd.h>
# if BACKWARD_HAS_BFD == 1
// NOTE: defining PACKAGE{,_VERSION} is required before including
// bfd.h on some platforms, see also:
// https://sourceware.org/bugzilla/show_bug.cgi?id=14243
# ifndef PACKAGE
# define PACKAGE
# endif
# ifndef PACKAGE_VERSION
# define PACKAGE_VERSION
# endif
# include <bfd.h>
# ifndef _GNU_SOURCE
# define _GNU_SOURCE
# include <dlfcn.h>
# undef _GNU_SOURCE
# else
# include <dlfcn.h>
# endif
# endif
# if BACKWARD_HAS_DW == 1
# include <dwarf.h>
# include <elfutils/libdw.h>
# include <elfutils/libdwfl.h>
# endif
# if BACKWARD_HAS_DWARF == 1
# include <algorithm>
# include <dwarf.h>
# include <libdwarf.h>
# include <libelf.h>
# include <map>
# ifndef _GNU_SOURCE
# define _GNU_SOURCE
# include <dlfcn.h>
# undef _GNU_SOURCE
# else
# include <dlfcn.h>
# endif
# endif
# if (BACKWARD_HAS_BACKTRACE == 1) || (BACKWARD_HAS_BACKTRACE_SYMBOL == 1)
// then we shall rely on backtrace
# include <execinfo.h>
# endif
# endif // defined(BACKWARD_SYSTEM_LINUX)
# if defined(BACKWARD_SYSTEM_DARWIN)
// On Darwin, backtrace can back-trace or "walk" the stack using the following
// libraries:
//
// #define BACKWARD_HAS_UNWIND 1
// - unwind comes from libgcc, but I saw an equivalent inside clang itself.
// - with unwind, the stacktrace is as accurate as it can possibly be, since
// this is used by the C++ runtine in gcc/clang for stack unwinding on
// exception.
// - normally libgcc is already linked to your program by default.
//
// #define BACKWARD_HAS_LIBUNWIND 1
// - libunwind comes from clang, which implements an API compatible version.
// - libunwind provides, in some cases, a more accurate stacktrace as it knows
// to decode signal handler frames and lets us edit the context registers when
// unwinding, allowing stack traces over bad function references.
//
// #define BACKWARD_HAS_BACKTRACE == 1
// - backtrace is available by default, though it does not produce as much
// information as another library might.
//
// The default is:
// #define BACKWARD_HAS_UNWIND == 1
//
// Note that only one of the define should be set to 1 at a time.
//
# if BACKWARD_HAS_UNWIND == 1
# elif BACKWARD_HAS_BACKTRACE == 1
# elif BACKWARD_HAS_LIBUNWIND == 1
# else
# undef BACKWARD_HAS_UNWIND
# define BACKWARD_HAS_UNWIND 1
# undef BACKWARD_HAS_BACKTRACE
# define BACKWARD_HAS_BACKTRACE 0
# undef BACKWARD_HAS_LIBUNWIND
# define BACKWARD_HAS_LIBUNWIND 0
# endif
// On Darwin, backward can extract detailed information about a stack trace
// using one of the following libraries:
//
// #define BACKWARD_HAS_BACKTRACE_SYMBOL 1
// - backtrace provides minimal details for a stack trace:
// - object filename
// - function name
//
// The default is:
// #define BACKWARD_HAS_BACKTRACE_SYMBOL == 1
//
# if BACKWARD_HAS_BACKTRACE_SYMBOL == 1
# else
# undef BACKWARD_HAS_BACKTRACE_SYMBOL
# define BACKWARD_HAS_BACKTRACE_SYMBOL 1
# endif
# include <cxxabi.h>
# include <fcntl.h>
# include <pthread.h>
# include <signal.h>
# include <sys/stat.h>
# include <unistd.h>
# if (BACKWARD_HAS_BACKTRACE == 1) || (BACKWARD_HAS_BACKTRACE_SYMBOL == 1)
# include <execinfo.h>
# endif
# endif // defined(BACKWARD_SYSTEM_DARWIN)
# if defined(BACKWARD_SYSTEM_WINDOWS)
# include <condition_variable>
# include <mutex>
# include <thread>
# include <basetsd.h>
# ifdef _WIN64
typedef SSIZE_T ssize_t ;
# else
typedef int ssize_t ;
# endif
# ifndef NOMINMAX
# define NOMINMAX
# endif
# include <windows.h>
# include <winnt.h>
# include <psapi.h>
# include <signal.h>
# ifndef __clang__
# undef NOINLINE
# define NOINLINE __declspec(noinline)
# endif
# ifdef _MSC_VER
# pragma comment(lib, "psapi.lib")
# pragma comment(lib, "dbghelp.lib")
# endif
// Comment / packing is from stackoverflow:
// https://stackoverflow.com/questions/6205981/windows-c-stack-trace-from-a-running-app/28276227#28276227
// Some versions of imagehlp.dll lack the proper packing directives themselves
// so we need to do it.
# pragma pack(push, before_imagehlp, 8)
# include <imagehlp.h>
# pragma pack(pop, before_imagehlp)
// TODO maybe these should be undefined somewhere else?
# undef BACKWARD_HAS_UNWIND
# undef BACKWARD_HAS_BACKTRACE
# if BACKWARD_HAS_PDB_SYMBOL == 1
# else
# undef BACKWARD_HAS_PDB_SYMBOL
# define BACKWARD_HAS_PDB_SYMBOL 1
# endif
# endif
# if BACKWARD_HAS_UNWIND == 1
# include <unwind.h>
// while gcc's unwind.h defines something like that:
// extern _Unwind_Ptr _Unwind_GetIP (struct _Unwind_Context *);
// extern _Unwind_Ptr _Unwind_GetIPInfo (struct _Unwind_Context *, int *);
//
// clang's unwind.h defines something like this:
// uintptr_t _Unwind_GetIP(struct _Unwind_Context* __context);
//
// Even if the _Unwind_GetIPInfo can be linked to, it is not declared, worse we
// cannot just redeclare it because clang's unwind.h doesn't define _Unwind_Ptr
// anyway.
//
// Luckily we can play on the fact that the guard macros have a different name:
# ifdef __CLANG_UNWIND_H
// In fact, this function still comes from libgcc (on my different linux boxes,
// clang links against libgcc).
# include <inttypes.h>
extern " C " uintptr_t _Unwind_GetIPInfo ( _Unwind_Context * , int * ) ;
# endif
# endif // BACKWARD_HAS_UNWIND == 1
# if BACKWARD_HAS_LIBUNWIND == 1
# define UNW_LOCAL_ONLY
# include <libunwind.h>
# endif // BACKWARD_HAS_LIBUNWIND == 1
# ifdef BACKWARD_ATLEAST_CXX11
# include <unordered_map>
# include <utility> // for std::swap
namespace backward {
namespace details {
template < typename K , typename V > struct hashtable {
typedef std : : unordered_map < K , V > type ;
} ;
using std : : move ;
} // namespace details
} // namespace backward
# else // NOT BACKWARD_ATLEAST_CXX11
# define nullptr NULL
# define override
# include <map>
namespace backward {
namespace details {
template < typename K , typename V > struct hashtable {
typedef std : : map < K , V > type ;
} ;
template < typename T > const T & move ( const T & v ) { return v ; }
template < typename T > T & move ( T & v ) { return v ; }
} // namespace details
} // namespace backward
# endif // BACKWARD_ATLEAST_CXX11
namespace backward {
namespace details {
# if defined(BACKWARD_SYSTEM_WINDOWS)
const char kBackwardPathDelimiter [ ] = " ; " ;
# else
const char kBackwardPathDelimiter [ ] = " : " ;
# endif
} // namespace details
} // namespace backward
namespace backward {
namespace system_tag {
struct linux_tag ; // seems that I cannot call that "linux" because the name
// is already defined... so I am adding _tag everywhere.
struct darwin_tag ;
struct windows_tag ;
struct unknown_tag ;
# if defined(BACKWARD_SYSTEM_LINUX)
typedef linux_tag current_tag ;
# elif defined(BACKWARD_SYSTEM_DARWIN)
typedef darwin_tag current_tag ;
# elif defined(BACKWARD_SYSTEM_WINDOWS)
typedef windows_tag current_tag ;
# elif defined(BACKWARD_SYSTEM_UNKNOWN)
typedef unknown_tag current_tag ;
# else
# error "May I please get my system defines?"
# endif
} // namespace system_tag
namespace trace_resolver_tag {
# if defined(BACKWARD_SYSTEM_LINUX)
struct libdw ;
struct libbfd ;
struct libdwarf ;
struct backtrace_symbol ;
# if BACKWARD_HAS_DW == 1
typedef libdw current ;
# elif BACKWARD_HAS_BFD == 1
typedef libbfd current ;
# elif BACKWARD_HAS_DWARF == 1
typedef libdwarf current ;
# elif BACKWARD_HAS_BACKTRACE_SYMBOL == 1
typedef backtrace_symbol current ;
# else
# error "You shall not pass, until you know what you want."
# endif
# elif defined(BACKWARD_SYSTEM_DARWIN)
struct backtrace_symbol ;
# if BACKWARD_HAS_BACKTRACE_SYMBOL == 1
typedef backtrace_symbol current ;
# else
# error "You shall not pass, until you know what you want."
# endif
# elif defined(BACKWARD_SYSTEM_WINDOWS)
struct pdb_symbol ;
# if BACKWARD_HAS_PDB_SYMBOL == 1
typedef pdb_symbol current ;
# else
# error "You shall not pass, until you know what you want."
# endif
# endif
} // namespace trace_resolver_tag
namespace details {
template < typename T > struct rm_ptr { typedef T type ; } ;
template < typename T > struct rm_ptr < T * > { typedef T type ; } ;
template < typename T > struct rm_ptr < const T * > { typedef const T type ; } ;
template < typename R , typename T , R ( * F ) ( T ) > struct deleter {
template < typename U > void operator ( ) ( U & ptr ) const { ( * F ) ( ptr ) ; }
} ;
template < typename T > struct default_delete {
void operator ( ) ( T & ptr ) const { delete ptr ; }
} ;
template < typename T , typename Deleter = deleter < void , void * , & : : free > >
class handle {
struct dummy ;
T _val ;
bool _empty ;
# ifdef BACKWARD_ATLEAST_CXX11
handle ( const handle & ) = delete ;
handle & operator = ( const handle & ) = delete ;
# endif
public :
~ handle ( ) {
if ( ! _empty ) {
Deleter ( ) ( _val ) ;
}
}
explicit handle ( ) : _val ( ) , _empty ( true ) { }
explicit handle ( T val ) : _val ( val ) , _empty ( false ) {
if ( ! _val )
_empty = true ;
}
# ifdef BACKWARD_ATLEAST_CXX11
handle ( handle & & from ) : _empty ( true ) { swap ( from ) ; }
handle & operator = ( handle & & from ) {
swap ( from ) ;
return * this ;
}
# else
explicit handle ( const handle & from ) : _empty ( true ) {
// some sort of poor man's move semantic.
swap ( const_cast < handle & > ( from ) ) ;
}
handle & operator = ( const handle & from ) {
// some sort of poor man's move semantic.
swap ( const_cast < handle & > ( from ) ) ;
return * this ;
}
# endif
void reset ( T new_val ) {
handle tmp ( new_val ) ;
swap ( tmp ) ;
}
void update ( T new_val ) {
_val = new_val ;
_empty = ! static_cast < bool > ( new_val ) ;
}
operator const dummy * ( ) const {
if ( _empty ) {
return nullptr ;
}
return reinterpret_cast < const dummy * > ( _val ) ;
}
T get ( ) { return _val ; }
T release ( ) {
_empty = true ;
return _val ;
}
void swap ( handle & b ) {
using std : : swap ;
swap ( b . _val , _val ) ; // can throw, we are safe here.
swap ( b . _empty , _empty ) ; // should not throw: if you cannot swap two
// bools without throwing... It's a lost cause anyway!
}
T & operator - > ( ) { return _val ; }
const T & operator - > ( ) const { return _val ; }
typedef typename rm_ptr < T > : : type & ref_t ;
typedef const typename rm_ptr < T > : : type & const_ref_t ;
ref_t operator * ( ) { return * _val ; }
const_ref_t operator * ( ) const { return * _val ; }
ref_t operator [ ] ( size_t idx ) { return _val [ idx ] ; }
// Watch out, we've got a badass over here
T * operator & ( ) {
_empty = false ;
return & _val ;
}
} ;
// Default demangler implementation (do nothing).
template < typename TAG > struct demangler_impl {
static std : : string demangle ( const char * funcname ) { return funcname ; }
} ;
# if defined(BACKWARD_SYSTEM_LINUX) || defined(BACKWARD_SYSTEM_DARWIN)
template < > struct demangler_impl < system_tag : : current_tag > {
demangler_impl ( ) : _demangle_buffer_length ( 0 ) { }
std : : string demangle ( const char * funcname ) {
using namespace details ;
char * result = abi : : __cxa_demangle ( funcname , _demangle_buffer . get ( ) ,
& _demangle_buffer_length , nullptr ) ;
if ( result ) {
_demangle_buffer . update ( result ) ;
return result ;
}
return funcname ;
}
private :
details : : handle < char * > _demangle_buffer ;
size_t _demangle_buffer_length ;
} ;
# endif // BACKWARD_SYSTEM_LINUX || BACKWARD_SYSTEM_DARWIN
struct demangler : public demangler_impl < system_tag : : current_tag > { } ;
// Split a string on the platform's PATH delimiter. Example: if delimiter
// is ":" then:
// "" --> []
// ":" --> ["",""]
// "::" --> ["","",""]
// "/a/b/c" --> ["/a/b/c"]
// "/a/b/c:/d/e/f" --> ["/a/b/c","/d/e/f"]
// etc.
inline std : : vector < std : : string > split_source_prefixes ( const std : : string & s ) {
std : : vector < std : : string > out ;
size_t last = 0 ;
size_t next = 0 ;
size_t delimiter_size = sizeof ( kBackwardPathDelimiter ) - 1 ;
while ( ( next = s . find ( kBackwardPathDelimiter , last ) ) ! = std : : string : : npos ) {
out . push_back ( s . substr ( last , next - last ) ) ;
last = next + delimiter_size ;
}
if ( last < = s . length ( ) ) {
out . push_back ( s . substr ( last ) ) ;
}
return out ;
}
} // namespace details
/*************** A TRACE ***************/
struct Trace {
void * addr ;
size_t idx ;
Trace ( ) : addr ( nullptr ) , idx ( 0 ) { }
explicit Trace ( void * _addr , size_t _idx ) : addr ( _addr ) , idx ( _idx ) { }
} ;
struct ResolvedTrace : public Trace {
struct SourceLoc {
std : : string function ;
std : : string filename ;
unsigned line ;
unsigned col ;
SourceLoc ( ) : line ( 0 ) , col ( 0 ) { }
bool operator = = ( const SourceLoc & b ) const {
return function = = b . function & & filename = = b . filename & &
line = = b . line & & col = = b . col ;
}
bool operator ! = ( const SourceLoc & b ) const { return ! ( * this = = b ) ; }
} ;
// In which binary object this trace is located.
std : : string object_filename ;
// The function in the object that contain the trace. This is not the same
// as source.function which can be an function inlined in object_function.
std : : string object_function ;
// The source location of this trace. It is possible for filename to be
// empty and for line/col to be invalid (value 0) if this information
// couldn't be deduced, for example if there is no debug information in the
// binary object.
SourceLoc source ;
// An optionals list of "inliners". All the successive sources location
// from where the source location of the trace (the attribute right above)
// is inlined. It is especially useful when you compiled with optimization.
typedef std : : vector < SourceLoc > source_locs_t ;
source_locs_t inliners ;
ResolvedTrace ( ) : Trace ( ) { }
ResolvedTrace ( const Trace & mini_trace ) : Trace ( mini_trace ) { }
} ;
/*************** STACK TRACE ***************/
// default implemention.
template < typename TAG > class StackTraceImpl {
public :
size_t size ( ) const { return 0 ; }
Trace operator [ ] ( size_t ) const { return Trace ( ) ; }
size_t load_here ( size_t = 0 ) { return 0 ; }
size_t load_from ( void * , size_t = 0 , void * = nullptr , void * = nullptr ) {
return 0 ;
}
size_t thread_id ( ) const { return 0 ; }
void skip_n_firsts ( size_t ) { }
} ;
class StackTraceImplBase {
public :
StackTraceImplBase ( )
: _thread_id ( 0 ) , _skip ( 0 ) , _context ( nullptr ) , _error_addr ( nullptr ) { }
size_t thread_id ( ) const { return _thread_id ; }
void skip_n_firsts ( size_t n ) { _skip = n ; }
protected :
void load_thread_info ( ) {
# ifdef BACKWARD_SYSTEM_LINUX
# ifndef __ANDROID__
_thread_id = static_cast < size_t > ( syscall ( SYS_gettid ) ) ;
# else
_thread_id = static_cast < size_t > ( gettid ( ) ) ;
# endif
if ( _thread_id = = static_cast < size_t > ( getpid ( ) ) ) {
// If the thread is the main one, let's hide that.
// I like to keep little secret sometimes.
_thread_id = 0 ;
}
# elif defined(BACKWARD_SYSTEM_DARWIN)
_thread_id = reinterpret_cast < size_t > ( pthread_self ( ) ) ;
if ( pthread_main_np ( ) = = 1 ) {
// If the thread is the main one, let's hide that.
_thread_id = 0 ;
}
# endif
}
void set_context ( void * context ) { _context = context ; }
void * context ( ) const { return _context ; }
void set_error_addr ( void * error_addr ) { _error_addr = error_addr ; }
void * error_addr ( ) const { return _error_addr ; }
size_t skip_n_firsts ( ) const { return _skip ; }
private :
size_t _thread_id ;
size_t _skip ;
void * _context ;
void * _error_addr ;
} ;
class StackTraceImplHolder : public StackTraceImplBase {
public :
size_t size ( ) const {
return ( _stacktrace . size ( ) > = skip_n_firsts ( ) )
? _stacktrace . size ( ) - skip_n_firsts ( )
: 0 ;
}
Trace operator [ ] ( size_t idx ) const {
if ( idx > = size ( ) ) {
return Trace ( ) ;
}
return Trace ( _stacktrace [ idx + skip_n_firsts ( ) ] , idx ) ;
}
void * const * begin ( ) const {
if ( size ( ) ) {
return & _stacktrace [ skip_n_firsts ( ) ] ;
}
return nullptr ;
}
protected :
std : : vector < void * > _stacktrace ;
} ;
# if BACKWARD_HAS_UNWIND == 1
namespace details {
template < typename F > class Unwinder {
public :
size_t operator ( ) ( F & f , size_t depth ) {
_f = & f ;
_index = - 1 ;
_depth = depth ;
_Unwind_Backtrace ( & this - > backtrace_trampoline , this ) ;
return static_cast < size_t > ( _index ) ;
}
private :
F * _f ;
ssize_t _index ;
size_t _depth ;
static _Unwind_Reason_Code backtrace_trampoline ( _Unwind_Context * ctx ,
void * self ) {
return ( static_cast < Unwinder * > ( self ) ) - > backtrace ( ctx ) ;
}
_Unwind_Reason_Code backtrace ( _Unwind_Context * ctx ) {
if ( _index > = 0 & & static_cast < size_t > ( _index ) > = _depth )
return _URC_END_OF_STACK ;
int ip_before_instruction = 0 ;
uintptr_t ip = _Unwind_GetIPInfo ( ctx , & ip_before_instruction ) ;
if ( ! ip_before_instruction ) {
// calculating 0-1 for unsigned, looks like a possible bug to sanitiziers,
// so let's do it explicitly:
if ( ip = = 0 ) {
ip = std : : numeric_limits < uintptr_t > : : max ( ) ; // set it to 0xffff... (as
// from casting 0-1)
} else {
ip - = 1 ; // else just normally decrement it (no overflow/underflow will
// happen)
}
}
if ( _index > = 0 ) { // ignore first frame.
( * _f ) ( static_cast < size_t > ( _index ) , reinterpret_cast < void * > ( ip ) ) ;
}
_index + = 1 ;
return _URC_NO_REASON ;
}
} ;
template < typename F > size_t unwind ( F f , size_t depth ) {
Unwinder < F > unwinder ;
return unwinder ( f , depth ) ;
}
} // namespace details
template < >
class StackTraceImpl < system_tag : : current_tag > : public StackTraceImplHolder {
public :
NOINLINE
size_t load_here ( size_t depth = 32 , void * context = nullptr ,
void * error_addr = nullptr ) {
load_thread_info ( ) ;
set_context ( context ) ;
set_error_addr ( error_addr ) ;
if ( depth = = 0 ) {
return 0 ;
}
_stacktrace . resize ( depth ) ;
size_t trace_cnt = details : : unwind ( callback ( * this ) , depth ) ;
_stacktrace . resize ( trace_cnt ) ;
skip_n_firsts ( 0 ) ;
return size ( ) ;
}
size_t load_from ( void * addr , size_t depth = 32 , void * context = nullptr ,
void * error_addr = nullptr ) {
load_here ( depth + 8 , context , error_addr ) ;
for ( size_t i = 0 ; i < _stacktrace . size ( ) ; + + i ) {
if ( _stacktrace [ i ] = = addr ) {
skip_n_firsts ( i ) ;
break ;
}
}
_stacktrace . resize ( std : : min ( _stacktrace . size ( ) , skip_n_firsts ( ) + depth ) ) ;
return size ( ) ;
}
private :
struct callback {
StackTraceImpl & self ;
callback ( StackTraceImpl & _self ) : self ( _self ) { }
void operator ( ) ( size_t idx , void * addr ) { self . _stacktrace [ idx ] = addr ; }
} ;
} ;
# elif BACKWARD_HAS_LIBUNWIND == 1
template < >
class StackTraceImpl < system_tag : : current_tag > : public StackTraceImplHolder {
public :
__attribute__ ( ( noinline ) ) size_t load_here ( size_t depth = 32 ,
void * _context = nullptr ,
void * _error_addr = nullptr ) {
set_context ( _context ) ;
set_error_addr ( _error_addr ) ;
load_thread_info ( ) ;
if ( depth = = 0 ) {
return 0 ;
}
_stacktrace . resize ( depth + 1 ) ;
int result = 0 ;
unw_context_t ctx ;
size_t index = 0 ;
// Add the tail call. If the Instruction Pointer is the crash address it
// means we got a bad function pointer dereference, so we "unwind" the
// bad pointer manually by using the return address pointed to by the
// Stack Pointer as the Instruction Pointer and letting libunwind do
// the rest
if ( context ( ) ) {
ucontext_t * uctx = reinterpret_cast < ucontext_t * > ( context ( ) ) ;
# ifdef REG_RIP // x86_64
if ( uctx - > uc_mcontext . gregs [ REG_RIP ] = =
reinterpret_cast < greg_t > ( error_addr ( ) ) ) {
uctx - > uc_mcontext . gregs [ REG_RIP ] =
* reinterpret_cast < size_t * > ( uctx - > uc_mcontext . gregs [ REG_RSP ] ) ;
}
_stacktrace [ index ] =
reinterpret_cast < void * > ( uctx - > uc_mcontext . gregs [ REG_RIP ] ) ;
+ + index ;
ctx = * reinterpret_cast < unw_context_t * > ( uctx ) ;
# elif defined(REG_EIP) // x86_32
if ( uctx - > uc_mcontext . gregs [ REG_EIP ] = =
reinterpret_cast < greg_t > ( error_addr ( ) ) ) {
uctx - > uc_mcontext . gregs [ REG_EIP ] =
* reinterpret_cast < size_t * > ( uctx - > uc_mcontext . gregs [ REG_ESP ] ) ;
}
_stacktrace [ index ] =
reinterpret_cast < void * > ( uctx - > uc_mcontext . gregs [ REG_EIP ] ) ;
+ + index ;
ctx = * reinterpret_cast < unw_context_t * > ( uctx ) ;
# elif defined(__arm__)
// libunwind uses its own context type for ARM unwinding.
// Copy the registers from the signal handler's context so we can
// unwind
unw_getcontext ( & ctx ) ;
ctx . regs [ UNW_ARM_R0 ] = uctx - > uc_mcontext . arm_r0 ;
ctx . regs [ UNW_ARM_R1 ] = uctx - > uc_mcontext . arm_r1 ;
ctx . regs [ UNW_ARM_R2 ] = uctx - > uc_mcontext . arm_r2 ;
ctx . regs [ UNW_ARM_R3 ] = uctx - > uc_mcontext . arm_r3 ;
ctx . regs [ UNW_ARM_R4 ] = uctx - > uc_mcontext . arm_r4 ;
ctx . regs [ UNW_ARM_R5 ] = uctx - > uc_mcontext . arm_r5 ;
ctx . regs [ UNW_ARM_R6 ] = uctx - > uc_mcontext . arm_r6 ;
ctx . regs [ UNW_ARM_R7 ] = uctx - > uc_mcontext . arm_r7 ;
ctx . regs [ UNW_ARM_R8 ] = uctx - > uc_mcontext . arm_r8 ;
ctx . regs [ UNW_ARM_R9 ] = uctx - > uc_mcontext . arm_r9 ;
ctx . regs [ UNW_ARM_R10 ] = uctx - > uc_mcontext . arm_r10 ;
ctx . regs [ UNW_ARM_R11 ] = uctx - > uc_mcontext . arm_fp ;
ctx . regs [ UNW_ARM_R12 ] = uctx - > uc_mcontext . arm_ip ;
ctx . regs [ UNW_ARM_R13 ] = uctx - > uc_mcontext . arm_sp ;
ctx . regs [ UNW_ARM_R14 ] = uctx - > uc_mcontext . arm_lr ;
ctx . regs [ UNW_ARM_R15 ] = uctx - > uc_mcontext . arm_pc ;
// If we have crashed in the PC use the LR instead, as this was
// a bad function dereference
if ( reinterpret_cast < unsigned long > ( error_addr ( ) ) = =
uctx - > uc_mcontext . arm_pc ) {
ctx . regs [ UNW_ARM_R15 ] =
uctx - > uc_mcontext . arm_lr - sizeof ( unsigned long ) ;
}
_stacktrace [ index ] = reinterpret_cast < void * > ( ctx . regs [ UNW_ARM_R15 ] ) ;
+ + index ;
# elif defined(__APPLE__) && defined(__x86_64__)
unw_getcontext ( & ctx ) ;
// OS X's implementation of libunwind uses its own context object
// so we need to convert the passed context to libunwind's format
// (information about the data layout taken from unw_getcontext.s
// in Apple's libunwind source
ctx . data [ 0 ] = uctx - > uc_mcontext - > __ss . __rax ;
ctx . data [ 1 ] = uctx - > uc_mcontext - > __ss . __rbx ;
ctx . data [ 2 ] = uctx - > uc_mcontext - > __ss . __rcx ;
ctx . data [ 3 ] = uctx - > uc_mcontext - > __ss . __rdx ;
ctx . data [ 4 ] = uctx - > uc_mcontext - > __ss . __rdi ;
ctx . data [ 5 ] = uctx - > uc_mcontext - > __ss . __rsi ;
ctx . data [ 6 ] = uctx - > uc_mcontext - > __ss . __rbp ;
ctx . data [ 7 ] = uctx - > uc_mcontext - > __ss . __rsp ;
ctx . data [ 8 ] = uctx - > uc_mcontext - > __ss . __r8 ;
ctx . data [ 9 ] = uctx - > uc_mcontext - > __ss . __r9 ;
ctx . data [ 10 ] = uctx - > uc_mcontext - > __ss . __r10 ;
ctx . data [ 11 ] = uctx - > uc_mcontext - > __ss . __r11 ;
ctx . data [ 12 ] = uctx - > uc_mcontext - > __ss . __r12 ;
ctx . data [ 13 ] = uctx - > uc_mcontext - > __ss . __r13 ;
ctx . data [ 14 ] = uctx - > uc_mcontext - > __ss . __r14 ;
ctx . data [ 15 ] = uctx - > uc_mcontext - > __ss . __r15 ;
ctx . data [ 16 ] = uctx - > uc_mcontext - > __ss . __rip ;
// If the IP is the same as the crash address we have a bad function
// dereference The caller's address is pointed to by %rsp, so we
// dereference that value and set it to be the next frame's IP.
if ( uctx - > uc_mcontext - > __ss . __rip = =
reinterpret_cast < __uint64_t > ( error_addr ( ) ) ) {
ctx . data [ 16 ] =
* reinterpret_cast < __uint64_t * > ( uctx - > uc_mcontext - > __ss . __rsp ) ;
}
_stacktrace [ index ] = reinterpret_cast < void * > ( ctx . data [ 16 ] ) ;
+ + index ;
# elif defined(__APPLE__)
unw_getcontext ( & ctx )
// TODO: Convert the ucontext_t to libunwind's unw_context_t like
// we do in 64 bits
if ( ctx . uc_mcontext - > __ss . __eip = =
reinterpret_cast < greg_t > ( error_addr ( ) ) ) {
ctx . uc_mcontext - > __ss . __eip = ctx . uc_mcontext - > __ss . __esp ;
}
_stacktrace [ index ] =
reinterpret_cast < void * > ( ctx . uc_mcontext - > __ss . __eip ) ;
+ + index ;
# endif
}
unw_cursor_t cursor ;
if ( context ( ) ) {
# if defined(UNW_INIT_SIGNAL_FRAME)
result = unw_init_local2 ( & cursor , & ctx , UNW_INIT_SIGNAL_FRAME ) ;
# else
result = unw_init_local ( & cursor , & ctx ) ;
# endif
} else {
unw_getcontext ( & ctx ) ;
;
result = unw_init_local ( & cursor , & ctx ) ;
}
if ( result ! = 0 )
return 1 ;
unw_word_t ip = 0 ;
while ( index < = depth & & unw_step ( & cursor ) > 0 ) {
result = unw_get_reg ( & cursor , UNW_REG_IP , & ip ) ;
if ( result = = 0 ) {
_stacktrace [ index ] = reinterpret_cast < void * > ( - - ip ) ;
+ + index ;
}
}
- - index ;
_stacktrace . resize ( index + 1 ) ;
skip_n_firsts ( 0 ) ;
return size ( ) ;
}
size_t load_from ( void * addr , size_t depth = 32 , void * context = nullptr ,
void * error_addr = nullptr ) {
load_here ( depth + 8 , context , error_addr ) ;
for ( size_t i = 0 ; i < _stacktrace . size ( ) ; + + i ) {
if ( _stacktrace [ i ] = = addr ) {
skip_n_firsts ( i ) ;
_stacktrace [ i ] = ( void * ) ( ( uintptr_t ) _stacktrace [ i ] ) ;
break ;
}
}
_stacktrace . resize ( std : : min ( _stacktrace . size ( ) , skip_n_firsts ( ) + depth ) ) ;
return size ( ) ;
}
} ;
# elif defined(BACKWARD_HAS_BACKTRACE)
template < >
class StackTraceImpl < system_tag : : current_tag > : public StackTraceImplHolder {
public :
NOINLINE
size_t load_here ( size_t depth = 32 , void * context = nullptr ,
void * error_addr = nullptr ) {
set_context ( context ) ;
set_error_addr ( error_addr ) ;
load_thread_info ( ) ;
if ( depth = = 0 ) {
return 0 ;
}
_stacktrace . resize ( depth + 1 ) ;
size_t trace_cnt = backtrace ( & _stacktrace [ 0 ] , _stacktrace . size ( ) ) ;
_stacktrace . resize ( trace_cnt ) ;
skip_n_firsts ( 1 ) ;
return size ( ) ;
}
size_t load_from ( void * addr , size_t depth = 32 , void * context = nullptr ,
void * error_addr = nullptr ) {
load_here ( depth + 8 , context , error_addr ) ;
for ( size_t i = 0 ; i < _stacktrace . size ( ) ; + + i ) {
if ( _stacktrace [ i ] = = addr ) {
skip_n_firsts ( i ) ;
_stacktrace [ i ] = ( void * ) ( ( uintptr_t ) _stacktrace [ i ] + 1 ) ;
break ;
}
}
_stacktrace . resize ( std : : min ( _stacktrace . size ( ) , skip_n_firsts ( ) + depth ) ) ;
return size ( ) ;
}
} ;
# elif defined(BACKWARD_SYSTEM_WINDOWS)
template < >
class StackTraceImpl < system_tag : : current_tag > : public StackTraceImplHolder {
public :
// We have to load the machine type from the image info
// So we first initialize the resolver, and it tells us this info
void set_machine_type ( DWORD machine_type ) { machine_type_ = machine_type ; }
void set_context ( CONTEXT * ctx ) { ctx_ = ctx ; }
void set_thread_handle ( HANDLE handle ) { thd_ = handle ; }
NOINLINE
size_t load_here ( size_t depth = 32 , void * context = nullptr ,
void * error_addr = nullptr ) {
set_context ( static_cast < CONTEXT * > ( context ) ) ;
set_error_addr ( error_addr ) ;
CONTEXT localCtx ; // used when no context is provided
if ( depth = = 0 ) {
return 0 ;
}
if ( ! ctx_ ) {
ctx_ = & localCtx ;
RtlCaptureContext ( ctx_ ) ;
}
if ( ! thd_ ) {
thd_ = GetCurrentThread ( ) ;
}
HANDLE process = GetCurrentProcess ( ) ;
STACKFRAME64 s ;
memset ( & s , 0 , sizeof ( STACKFRAME64 ) ) ;
// TODO: 32 bit context capture
s . AddrStack . Mode = AddrModeFlat ;
s . AddrFrame . Mode = AddrModeFlat ;
s . AddrPC . Mode = AddrModeFlat ;
# ifdef _M_X64
s . AddrPC . Offset = ctx_ - > Rip ;
s . AddrStack . Offset = ctx_ - > Rsp ;
s . AddrFrame . Offset = ctx_ - > Rbp ;
# else
s . AddrPC . Offset = ctx_ - > Eip ;
s . AddrStack . Offset = ctx_ - > Esp ;
s . AddrFrame . Offset = ctx_ - > Ebp ;
# endif
if ( ! machine_type_ ) {
# ifdef _M_X64
machine_type_ = IMAGE_FILE_MACHINE_AMD64 ;
# else
machine_type_ = IMAGE_FILE_MACHINE_I386 ;
# endif
}
for ( ; ; ) {
// NOTE: this only works if PDBs are already loaded!
SetLastError ( 0 ) ;
if ( ! StackWalk64 ( machine_type_ , process , thd_ , & s , ctx_ , NULL ,
SymFunctionTableAccess64 , SymGetModuleBase64 , NULL ) )
break ;
if ( s . AddrReturn . Offset = = 0 )
break ;
_stacktrace . push_back ( reinterpret_cast < void * > ( s . AddrPC . Offset ) ) ;
if ( size ( ) > = depth )
break ;
}
return size ( ) ;
}
size_t load_from ( void * addr , size_t depth = 32 , void * context = nullptr ,
void * error_addr = nullptr ) {
load_here ( depth + 8 , context , error_addr ) ;
for ( size_t i = 0 ; i < _stacktrace . size ( ) ; + + i ) {
if ( _stacktrace [ i ] = = addr ) {
skip_n_firsts ( i ) ;
break ;
}
}
_stacktrace . resize ( std : : min ( _stacktrace . size ( ) , skip_n_firsts ( ) + depth ) ) ;
return size ( ) ;
}
private :
DWORD machine_type_ = 0 ;
HANDLE thd_ = 0 ;
CONTEXT * ctx_ = nullptr ;
} ;
# endif
class StackTrace : public StackTraceImpl < system_tag : : current_tag > { } ;
/*************** TRACE RESOLVER ***************/
class TraceResolverImplBase {
public :
virtual ~ TraceResolverImplBase ( ) { }
virtual void load_addresses ( void * const * addresses , int address_count ) {
( void ) addresses ;
( void ) address_count ;
}
template < class ST > void load_stacktrace ( ST & st ) {
load_addresses ( st . begin ( ) , static_cast < int > ( st . size ( ) ) ) ;
}
virtual ResolvedTrace resolve ( ResolvedTrace t ) { return t ; }
protected :
std : : string demangle ( const char * funcname ) {
return _demangler . demangle ( funcname ) ;
}
private :
details : : demangler _demangler ;
} ;
template < typename TAG > class TraceResolverImpl ;
# ifdef BACKWARD_SYSTEM_UNKNOWN
template < > class TraceResolverImpl < system_tag : : unknown_tag >
: public TraceResolverImplBase { } ;
# endif
# ifdef BACKWARD_SYSTEM_LINUX
class TraceResolverLinuxBase : public TraceResolverImplBase {
public :
TraceResolverLinuxBase ( )
: argv0_ ( get_argv0 ( ) ) , exec_path_ ( read_symlink ( " /proc/self/exe " ) ) { }
std : : string resolve_exec_path ( Dl_info & symbol_info ) const {
// mutates symbol_info.dli_fname to be filename to open and returns filename
// to display
if ( symbol_info . dli_fname = = argv0_ ) {
// dladdr returns argv[0] in dli_fname for symbols contained in
// the main executable, which is not a valid path if the
// executable was found by a search of the PATH environment
// variable; In that case, we actually open /proc/self/exe, which
// is always the actual executable (even if it was deleted/replaced!)
// but display the path that /proc/self/exe links to.
// However, this right away reduces probability of successful symbol
// resolution, because libbfd may try to find *.debug files in the
// same dir, in case symbols are stripped. As a result, it may try
// to find a file /proc/self/<exe_name>.debug, which obviously does
// not exist. /proc/self/exe is a last resort. First load attempt
// should go for the original executable file path.
symbol_info . dli_fname = " /proc/self/exe " ;
return exec_path_ ;
} else {
return symbol_info . dli_fname ;
}
}
private :
std : : string argv0_ ;
std : : string exec_path_ ;
static std : : string get_argv0 ( ) {
std : : string argv0 ;
std : : ifstream ifs ( " /proc/self/cmdline " ) ;
std : : getline ( ifs , argv0 , ' \0 ' ) ;
return argv0 ;
}
static std : : string read_symlink ( std : : string const & symlink_path ) {
std : : string path ;
path . resize ( 100 ) ;
while ( true ) {
ssize_t len =
: : readlink ( symlink_path . c_str ( ) , & * path . begin ( ) , path . size ( ) ) ;
if ( len < 0 ) {
return " " ;
}
if ( static_cast < size_t > ( len ) = = path . size ( ) ) {
path . resize ( path . size ( ) * 2 ) ;
} else {
path . resize ( static_cast < std : : string : : size_type > ( len ) ) ;
break ;
}
}
return path ;
}
} ;
template < typename STACKTRACE_TAG > class TraceResolverLinuxImpl ;
# if BACKWARD_HAS_BACKTRACE_SYMBOL == 1
template < >
class TraceResolverLinuxImpl < trace_resolver_tag : : backtrace_symbol >
: public TraceResolverLinuxBase {
public :
void load_addresses ( void * const * addresses , int address_count ) override {
if ( address_count = = 0 ) {
return ;
}
_symbols . reset ( backtrace_symbols ( addresses , address_count ) ) ;
}
ResolvedTrace resolve ( ResolvedTrace trace ) override {
char * filename = _symbols [ trace . idx ] ;
char * funcname = filename ;
while ( * funcname & & * funcname ! = ' ( ' ) {
funcname + = 1 ;
}
trace . object_filename . assign ( filename ,
funcname ) ; // ok even if funcname is the ending
// \0 (then we assign entire string)
if ( * funcname ) { // if it's not end of string (e.g. from last frame ip==0)
funcname + = 1 ;
char * funcname_end = funcname ;
while ( * funcname_end & & * funcname_end ! = ' ) ' & & * funcname_end ! = ' + ' ) {
funcname_end + = 1 ;
}
* funcname_end = ' \0 ' ;
trace . object_function = this - > demangle ( funcname ) ;
trace . source . function = trace . object_function ; // we cannot do better.
}
return trace ;
}
private :
details : : handle < char * * > _symbols ;
} ;
# endif // BACKWARD_HAS_BACKTRACE_SYMBOL == 1
# if BACKWARD_HAS_BFD == 1
template < >
class TraceResolverLinuxImpl < trace_resolver_tag : : libbfd >
: public TraceResolverLinuxBase {
public :
TraceResolverLinuxImpl ( ) : _bfd_loaded ( false ) { }
ResolvedTrace resolve ( ResolvedTrace trace ) override {
Dl_info symbol_info ;
// trace.addr is a virtual address in memory pointing to some code.
// Let's try to find from which loaded object it comes from.
// The loaded object can be yourself btw.
if ( ! dladdr ( trace . addr , & symbol_info ) ) {
return trace ; // dat broken trace...
}
// Now we get in symbol_info:
// .dli_fname:
// pathname of the shared object that contains the address.
// .dli_fbase:
// where the object is loaded in memory.
// .dli_sname:
// the name of the nearest symbol to trace.addr, we expect a
// function name.
// .dli_saddr:
// the exact address corresponding to .dli_sname.
if ( symbol_info . dli_sname ) {
trace . object_function = demangle ( symbol_info . dli_sname ) ;
}
if ( ! symbol_info . dli_fname ) {
return trace ;
}
trace . object_filename = resolve_exec_path ( symbol_info ) ;
bfd_fileobject * fobj ;
// Before rushing to resolution need to ensure the executable
// file still can be used. For that compare inode numbers of
// what is stored by the executable's file path, and in the
// dli_fname, which not necessarily equals to the executable.
// It can be a shared library, or /proc/self/exe, and in the
// latter case has drawbacks. See the exec path resolution for
// details. In short - the dli object should be used only as
// the last resort.
// If inode numbers are equal, it is known dli_fname and the
// executable file are the same. This is guaranteed by Linux,
// because if the executable file is changed/deleted, it will
// be done in a new inode. The old file will be preserved in
// /proc/self/exe, and may even have inode 0. The latter can
// happen if the inode was actually reused, and the file was
// kept only in the main memory.
//
struct stat obj_stat ;
struct stat dli_stat ;
if ( stat ( trace . object_filename . c_str ( ) , & obj_stat ) = = 0 & &
stat ( symbol_info . dli_fname , & dli_stat ) = = 0 & &
obj_stat . st_ino = = dli_stat . st_ino ) {
// The executable file, and the shared object containing the
// address are the same file. Safe to use the original path.
// this is preferable. Libbfd will search for stripped debug
// symbols in the same directory.
fobj = load_object_with_bfd ( trace . object_filename ) ;
} else {
// The original object file was *deleted*! The only hope is
// that the debug symbols are either inside the shared
// object file, or are in the same directory, and this is
// not /proc/self/exe.
fobj = nullptr ;
}
if ( fobj = = nullptr | | ! fobj - > handle ) {
fobj = load_object_with_bfd ( symbol_info . dli_fname ) ;
if ( ! fobj - > handle ) {
return trace ;
}
}
find_sym_result * details_selected ; // to be filled.
// trace.addr is the next instruction to be executed after returning
// from the nested stack frame. In C++ this usually relate to the next
// statement right after the function call that leaded to a new stack
// frame. This is not usually what you want to see when printing out a
// stacktrace...
find_sym_result details_call_site =
find_symbol_details ( fobj , trace . addr , symbol_info . dli_fbase ) ;
details_selected = & details_call_site ;
# if BACKWARD_HAS_UNWIND == 0
// ...this is why we also try to resolve the symbol that is right
// before the return address. If we are lucky enough, we will get the
// line of the function that was called. But if the code is optimized,
// we might get something absolutely not related since the compiler
// can reschedule the return address with inline functions and
// tail-call optimisation (among other things that I don't even know
// or cannot even dream about with my tiny limited brain).
find_sym_result details_adjusted_call_site = find_symbol_details (
fobj , ( void * ) ( uintptr_t ( trace . addr ) - 1 ) , symbol_info . dli_fbase ) ;
// In debug mode, we should always get the right thing(TM).
if ( details_call_site . found & & details_adjusted_call_site . found ) {
// Ok, we assume that details_adjusted_call_site is a better estimation.
details_selected = & details_adjusted_call_site ;
trace . addr = ( void * ) ( uintptr_t ( trace . addr ) - 1 ) ;
}
if ( details_selected = = & details_call_site & & details_call_site . found ) {
// we have to re-resolve the symbol in order to reset some
// internal state in BFD... so we can call backtrace_inliners
// thereafter...
details_call_site =
find_symbol_details ( fobj , trace . addr , symbol_info . dli_fbase ) ;
}
# endif // BACKWARD_HAS_UNWIND
if ( details_selected - > found ) {
if ( details_selected - > filename ) {
trace . source . filename = details_selected - > filename ;
}
trace . source . line = details_selected - > line ;
if ( details_selected - > funcname ) {
// this time we get the name of the function where the code is
// located, instead of the function were the address is
// located. In short, if the code was inlined, we get the
// function correspoding to the code. Else we already got in
// trace.function.
trace . source . function = demangle ( details_selected - > funcname ) ;
if ( ! symbol_info . dli_sname ) {
// for the case dladdr failed to find the symbol name of
// the function, we might as well try to put something
// here.
trace . object_function = trace . source . function ;
}
}
// Maybe the source of the trace got inlined inside the function
// (trace.source.function). Let's see if we can get all the inlined
// calls along the way up to the initial call site.
trace . inliners = backtrace_inliners ( fobj , * details_selected ) ;
#if 0
if ( trace . inliners . size ( ) = = 0 ) {
// Maybe the trace was not inlined... or maybe it was and we
// are lacking the debug information. Let's try to make the
// world better and see if we can get the line number of the
// function (trace.source.function) now.
//
// We will get the location of where the function start (to be
// exact: the first instruction that really start the
// function), not where the name of the function is defined.
// This can be quite far away from the name of the function
// btw.
//
// If the source of the function is the same as the source of
// the trace, we cannot say if the trace was really inlined or
// not. However, if the filename of the source is different
// between the function and the trace... we can declare it as
// an inliner. This is not 100% accurate, but better than
// nothing.
if ( symbol_info . dli_saddr ) {
find_sym_result details = find_symbol_details ( fobj ,
symbol_info . dli_saddr ,
symbol_info . dli_fbase ) ;
if ( details . found ) {
ResolvedTrace : : SourceLoc diy_inliner ;
diy_inliner . line = details . line ;
if ( details . filename ) {
diy_inliner . filename = details . filename ;
}
if ( details . funcname ) {
diy_inliner . function = demangle ( details . funcname ) ;
} else {
diy_inliner . function = trace . source . function ;
}
if ( diy_inliner ! = trace . source ) {
trace . inliners . push_back ( diy_inliner ) ;
}
}
}
}
# endif
}
return trace ;
}
private :
bool _bfd_loaded ;
typedef details : : handle < bfd * ,
details : : deleter < bfd_boolean , bfd * , & bfd_close > >
bfd_handle_t ;
typedef details : : handle < asymbol * * > bfd_symtab_t ;
struct bfd_fileobject {
bfd_handle_t handle ;
bfd_vma base_addr ;
bfd_symtab_t symtab ;
bfd_symtab_t dynamic_symtab ;
} ;
typedef details : : hashtable < std : : string , bfd_fileobject > : : type fobj_bfd_map_t ;
fobj_bfd_map_t _fobj_bfd_map ;
bfd_fileobject * load_object_with_bfd ( const std : : string & filename_object ) {
using namespace details ;
if ( ! _bfd_loaded ) {
using namespace details ;
bfd_init ( ) ;
_bfd_loaded = true ;
}
fobj_bfd_map_t : : iterator it = _fobj_bfd_map . find ( filename_object ) ;
if ( it ! = _fobj_bfd_map . end ( ) ) {
return & it - > second ;
}
// this new object is empty for now.
bfd_fileobject * r = & _fobj_bfd_map [ filename_object ] ;
// we do the work temporary in this one;
bfd_handle_t bfd_handle ;
int fd = open ( filename_object . c_str ( ) , O_RDONLY ) ;
bfd_handle . reset ( bfd_fdopenr ( filename_object . c_str ( ) , " default " , fd ) ) ;
if ( ! bfd_handle ) {
close ( fd ) ;
return r ;
}
if ( ! bfd_check_format ( bfd_handle . get ( ) , bfd_object ) ) {
return r ; // not an object? You lose.
}
if ( ( bfd_get_file_flags ( bfd_handle . get ( ) ) & HAS_SYMS ) = = 0 ) {
return r ; // that's what happen when you forget to compile in debug.
}
ssize_t symtab_storage_size = bfd_get_symtab_upper_bound ( bfd_handle . get ( ) ) ;
ssize_t dyn_symtab_storage_size =
bfd_get_dynamic_symtab_upper_bound ( bfd_handle . get ( ) ) ;
if ( symtab_storage_size < = 0 & & dyn_symtab_storage_size < = 0 ) {
return r ; // weird, is the file is corrupted?
}
bfd_symtab_t symtab , dynamic_symtab ;
ssize_t symcount = 0 , dyn_symcount = 0 ;
if ( symtab_storage_size > 0 ) {
symtab . reset ( static_cast < bfd_symbol * * > (
malloc ( static_cast < size_t > ( symtab_storage_size ) ) ) ) ;
symcount = bfd_canonicalize_symtab ( bfd_handle . get ( ) , symtab . get ( ) ) ;
}
if ( dyn_symtab_storage_size > 0 ) {
dynamic_symtab . reset ( static_cast < bfd_symbol * * > (
malloc ( static_cast < size_t > ( dyn_symtab_storage_size ) ) ) ) ;
dyn_symcount = bfd_canonicalize_dynamic_symtab ( bfd_handle . get ( ) ,
dynamic_symtab . get ( ) ) ;
}
if ( symcount < = 0 & & dyn_symcount < = 0 ) {
return r ; // damned, that's a stripped file that you got there!
}
r - > handle = move ( bfd_handle ) ;
r - > symtab = move ( symtab ) ;
r - > dynamic_symtab = move ( dynamic_symtab ) ;
return r ;
}
struct find_sym_result {
bool found ;
const char * filename ;
const char * funcname ;
unsigned int line ;
} ;
struct find_sym_context {
TraceResolverLinuxImpl * self ;
bfd_fileobject * fobj ;
void * addr ;
void * base_addr ;
find_sym_result result ;
} ;
find_sym_result find_symbol_details ( bfd_fileobject * fobj , void * addr ,
void * base_addr ) {
find_sym_context context ;
context . self = this ;
context . fobj = fobj ;
context . addr = addr ;
context . base_addr = base_addr ;
context . result . found = false ;
bfd_map_over_sections ( fobj - > handle . get ( ) , & find_in_section_trampoline ,
static_cast < void * > ( & context ) ) ;
return context . result ;
}
static void find_in_section_trampoline ( bfd * , asection * section , void * data ) {
find_sym_context * context = static_cast < find_sym_context * > ( data ) ;
context - > self - > find_in_section (
reinterpret_cast < bfd_vma > ( context - > addr ) ,
reinterpret_cast < bfd_vma > ( context - > base_addr ) , context - > fobj , section ,
context - > result ) ;
}
void find_in_section ( bfd_vma addr , bfd_vma base_addr , bfd_fileobject * fobj ,
asection * section , find_sym_result & result ) {
if ( result . found )
return ;
# ifdef bfd_get_section_flags
if ( ( bfd_get_section_flags ( fobj - > handle . get ( ) , section ) & SEC_ALLOC ) = = 0 )
# else
if ( ( bfd_section_flags ( section ) & SEC_ALLOC ) = = 0 )
# endif
return ; // a debug section is never loaded automatically.
# ifdef bfd_get_section_vma
bfd_vma sec_addr = bfd_get_section_vma ( fobj - > handle . get ( ) , section ) ;
# else
bfd_vma sec_addr = bfd_section_vma ( section ) ;
# endif
# ifdef bfd_get_section_size
bfd_size_type size = bfd_get_section_size ( section ) ;
# else
bfd_size_type size = bfd_section_size ( section ) ;
# endif
// are we in the boundaries of the section?
if ( addr < sec_addr | | addr > = sec_addr + size ) {
addr - = base_addr ; // oups, a relocated object, lets try again...
if ( addr < sec_addr | | addr > = sec_addr + size ) {
return ;
}
}
# if defined(__clang__)
# pragma clang diagnostic push
# pragma clang diagnostic ignored "-Wzero-as-null-pointer-constant"
# endif
if ( ! result . found & & fobj - > symtab ) {
result . found = bfd_find_nearest_line (
fobj - > handle . get ( ) , section , fobj - > symtab . get ( ) , addr - sec_addr ,
& result . filename , & result . funcname , & result . line ) ;
}
if ( ! result . found & & fobj - > dynamic_symtab ) {
result . found = bfd_find_nearest_line (
fobj - > handle . get ( ) , section , fobj - > dynamic_symtab . get ( ) ,
addr - sec_addr , & result . filename , & result . funcname , & result . line ) ;
}
# if defined(__clang__)
# pragma clang diagnostic pop
# endif
}
ResolvedTrace : : source_locs_t
backtrace_inliners ( bfd_fileobject * fobj , find_sym_result previous_result ) {
// This function can be called ONLY after a SUCCESSFUL call to
// find_symbol_details. The state is global to the bfd_handle.
ResolvedTrace : : source_locs_t results ;
while ( previous_result . found ) {
find_sym_result result ;
result . found = bfd_find_inliner_info ( fobj - > handle . get ( ) , & result . filename ,
& result . funcname , & result . line ) ;
if ( result
. found ) /* and not (
cstrings_eq ( previous_result . filename ,
result . filename ) and
cstrings_eq ( previous_result . funcname , result . funcname )
and result . line = = previous_result . line
) ) */
{
ResolvedTrace : : SourceLoc src_loc ;
src_loc . line = result . line ;
if ( result . filename ) {
src_loc . filename = result . filename ;
}
if ( result . funcname ) {
src_loc . function = demangle ( result . funcname ) ;
}
results . push_back ( src_loc ) ;
}
previous_result = result ;
}
return results ;
}
bool cstrings_eq ( const char * a , const char * b ) {
if ( ! a | | ! b ) {
return false ;
}
return strcmp ( a , b ) = = 0 ;
}
} ;
# endif // BACKWARD_HAS_BFD == 1
# if BACKWARD_HAS_DW == 1
template < >
class TraceResolverLinuxImpl < trace_resolver_tag : : libdw >
: public TraceResolverLinuxBase {
public :
TraceResolverLinuxImpl ( ) : _dwfl_handle_initialized ( false ) { }
ResolvedTrace resolve ( ResolvedTrace trace ) override {
using namespace details ;
Dwarf_Addr trace_addr = ( Dwarf_Addr ) trace . addr ;
if ( ! _dwfl_handle_initialized ) {
// initialize dwfl...
_dwfl_cb . reset ( new Dwfl_Callbacks ) ;
_dwfl_cb - > find_elf = & dwfl_linux_proc_find_elf ;
_dwfl_cb - > find_debuginfo = & dwfl_standard_find_debuginfo ;
_dwfl_cb - > debuginfo_path = 0 ;
_dwfl_handle . reset ( dwfl_begin ( _dwfl_cb . get ( ) ) ) ;
_dwfl_handle_initialized = true ;
if ( ! _dwfl_handle ) {
return trace ;
}
// ...from the current process.
dwfl_report_begin ( _dwfl_handle . get ( ) ) ;
int r = dwfl_linux_proc_report ( _dwfl_handle . get ( ) , getpid ( ) ) ;
dwfl_report_end ( _dwfl_handle . get ( ) , NULL , NULL ) ;
if ( r < 0 ) {
return trace ;
}
}
if ( ! _dwfl_handle ) {
return trace ;
}
// find the module (binary object) that contains the trace's address.
// This is not using any debug information, but the addresses ranges of
// all the currently loaded binary object.
Dwfl_Module * mod = dwfl_addrmodule ( _dwfl_handle . get ( ) , trace_addr ) ;
if ( mod ) {
// now that we found it, lets get the name of it, this will be the
// full path to the running binary or one of the loaded library.
const char * module_name = dwfl_module_info ( mod , 0 , 0 , 0 , 0 , 0 , 0 , 0 ) ;
if ( module_name ) {
trace . object_filename = module_name ;
}
// We also look after the name of the symbol, equal or before this
// address. This is found by walking the symtab. We should get the
// symbol corresponding to the function (mangled) containing the
// address. If the code corresponding to the address was inlined,
// this is the name of the out-most inliner function.
const char * sym_name = dwfl_module_addrname ( mod , trace_addr ) ;
if ( sym_name ) {
trace . object_function = demangle ( sym_name ) ;
}
}
// now let's get serious, and find out the source location (file and
// line number) of the address.
// This function will look in .debug_aranges for the address and map it
// to the location of the compilation unit DIE in .debug_info and
// return it.
Dwarf_Addr mod_bias = 0 ;
Dwarf_Die * cudie = dwfl_module_addrdie ( mod , trace_addr , & mod_bias ) ;
# if 1
if ( ! cudie ) {
// Sadly clang does not generate the section .debug_aranges, thus
// dwfl_module_addrdie will fail early. Clang doesn't either set
// the lowpc/highpc/range info for every compilation unit.
//
// So in order to save the world:
// for every compilation unit, we will iterate over every single
// DIEs. Normally functions should have a lowpc/highpc/range, which
// we will use to infer the compilation unit.
// note that this is probably badly inefficient.
while ( ( cudie = dwfl_module_nextcu ( mod , cudie , & mod_bias ) ) ) {
Dwarf_Die die_mem ;
Dwarf_Die * fundie =
find_fundie_by_pc ( cudie , trace_addr - mod_bias , & die_mem ) ;
if ( fundie ) {
break ;
}
}
}
# endif
//#define BACKWARD_I_DO_NOT_RECOMMEND_TO_ENABLE_THIS_HORRIBLE_PIECE_OF_CODE
# ifdef BACKWARD_I_DO_NOT_RECOMMEND_TO_ENABLE_THIS_HORRIBLE_PIECE_OF_CODE
if ( ! cudie ) {
// If it's still not enough, lets dive deeper in the shit, and try
// to save the world again: for every compilation unit, we will
// load the corresponding .debug_line section, and see if we can
// find our address in it.
Dwarf_Addr cfi_bias ;
Dwarf_CFI * cfi_cache = dwfl_module_eh_cfi ( mod , & cfi_bias ) ;
Dwarf_Addr bias ;
while ( ( cudie = dwfl_module_nextcu ( mod , cudie , & bias ) ) ) {
if ( dwarf_getsrc_die ( cudie , trace_addr - bias ) ) {
// ...but if we get a match, it might be a false positive
// because our (address - bias) might as well be valid in a
// different compilation unit. So we throw our last card on
// the table and lookup for the address into the .eh_frame
// section.
handle < Dwarf_Frame * > frame ;
dwarf_cfi_addrframe ( cfi_cache , trace_addr - cfi_bias , & frame ) ;
if ( frame ) {
break ;
}
}
}
}
# endif
if ( ! cudie ) {
return trace ; // this time we lost the game :/
}
// Now that we have a compilation unit DIE, this function will be able
// to load the corresponding section in .debug_line (if not already
// loaded) and hopefully find the source location mapped to our
// address.
Dwarf_Line * srcloc = dwarf_getsrc_die ( cudie , trace_addr - mod_bias ) ;
if ( srcloc ) {
const char * srcfile = dwarf_linesrc ( srcloc , 0 , 0 ) ;
if ( srcfile ) {
trace . source . filename = srcfile ;
}
int line = 0 , col = 0 ;
dwarf_lineno ( srcloc , & line ) ;
dwarf_linecol ( srcloc , & col ) ;
trace . source . line = line ;
trace . source . col = col ;
}
deep_first_search_by_pc ( cudie , trace_addr - mod_bias ,
inliners_search_cb ( trace ) ) ;
if ( trace . source . function . size ( ) = = 0 ) {
// fallback.
trace . source . function = trace . object_function ;
}
return trace ;
}
private :
typedef details : : handle < Dwfl * , details : : deleter < void , Dwfl * , & dwfl_end > >
dwfl_handle_t ;
details : : handle < Dwfl_Callbacks * , details : : default_delete < Dwfl_Callbacks * > >
_dwfl_cb ;
dwfl_handle_t _dwfl_handle ;
bool _dwfl_handle_initialized ;
// defined here because in C++98, template function cannot take locally
// defined types... grrr.
struct inliners_search_cb {
void operator ( ) ( Dwarf_Die * die ) {
switch ( dwarf_tag ( die ) ) {
const char * name ;
case DW_TAG_subprogram :
if ( ( name = dwarf_diename ( die ) ) ) {
trace . source . function = name ;
}
break ;
case DW_TAG_inlined_subroutine :
ResolvedTrace : : SourceLoc sloc ;
Dwarf_Attribute attr_mem ;
if ( ( name = dwarf_diename ( die ) ) ) {
sloc . function = name ;
}
if ( ( name = die_call_file ( die ) ) ) {
sloc . filename = name ;
}
Dwarf_Word line = 0 , col = 0 ;
dwarf_formudata ( dwarf_attr ( die , DW_AT_call_line , & attr_mem ) , & line ) ;
dwarf_formudata ( dwarf_attr ( die , DW_AT_call_column , & attr_mem ) , & col ) ;
sloc . line = ( unsigned ) line ;
sloc . col = ( unsigned ) col ;
trace . inliners . push_back ( sloc ) ;
break ;
} ;
}
ResolvedTrace & trace ;
inliners_search_cb ( ResolvedTrace & t ) : trace ( t ) { }
} ;
static bool die_has_pc ( Dwarf_Die * die , Dwarf_Addr pc ) {
Dwarf_Addr low , high ;
// continuous range
if ( dwarf_hasattr ( die , DW_AT_low_pc ) & & dwarf_hasattr ( die , DW_AT_high_pc ) ) {
if ( dwarf_lowpc ( die , & low ) ! = 0 ) {
return false ;
}
if ( dwarf_highpc ( die , & high ) ! = 0 ) {
Dwarf_Attribute attr_mem ;
Dwarf_Attribute * attr = dwarf_attr ( die , DW_AT_high_pc , & attr_mem ) ;
Dwarf_Word value ;
if ( dwarf_formudata ( attr , & value ) ! = 0 ) {
return false ;
}
high = low + value ;
}
return pc > = low & & pc < high ;
}
// non-continuous range.
Dwarf_Addr base ;
ptrdiff_t offset = 0 ;
while ( ( offset = dwarf_ranges ( die , offset , & base , & low , & high ) ) > 0 ) {
if ( pc > = low & & pc < high ) {
return true ;
}
}
return false ;
}
static Dwarf_Die * find_fundie_by_pc ( Dwarf_Die * parent_die , Dwarf_Addr pc ,
Dwarf_Die * result ) {
if ( dwarf_child ( parent_die , result ) ! = 0 ) {
return 0 ;
}
Dwarf_Die * die = result ;
do {
switch ( dwarf_tag ( die ) ) {
case DW_TAG_subprogram :
case DW_TAG_inlined_subroutine :
if ( die_has_pc ( die , pc ) ) {
return result ;
}
} ;
bool declaration = false ;
Dwarf_Attribute attr_mem ;
dwarf_formflag ( dwarf_attr ( die , DW_AT_declaration , & attr_mem ) ,
& declaration ) ;
if ( ! declaration ) {
// let's be curious and look deeper in the tree,
// function are not necessarily at the first level, but
// might be nested inside a namespace, structure etc.
Dwarf_Die die_mem ;
Dwarf_Die * indie = find_fundie_by_pc ( die , pc , & die_mem ) ;
if ( indie ) {
* result = die_mem ;
return result ;
}
}
} while ( dwarf_siblingof ( die , result ) = = 0 ) ;
return 0 ;
}
template < typename CB >
static bool deep_first_search_by_pc ( Dwarf_Die * parent_die , Dwarf_Addr pc ,
CB cb ) {
Dwarf_Die die_mem ;
if ( dwarf_child ( parent_die , & die_mem ) ! = 0 ) {
return false ;
}
bool branch_has_pc = false ;
Dwarf_Die * die = & die_mem ;
do {
bool declaration = false ;
Dwarf_Attribute attr_mem ;
dwarf_formflag ( dwarf_attr ( die , DW_AT_declaration , & attr_mem ) ,
& declaration ) ;
if ( ! declaration ) {
// let's be curious and look deeper in the tree, function are
// not necessarily at the first level, but might be nested
// inside a namespace, structure, a function, an inlined
// function etc.
branch_has_pc = deep_first_search_by_pc ( die , pc , cb ) ;
}
if ( ! branch_has_pc ) {
branch_has_pc = die_has_pc ( die , pc ) ;
}
if ( branch_has_pc ) {
cb ( die ) ;
}
} while ( dwarf_siblingof ( die , & die_mem ) = = 0 ) ;
return branch_has_pc ;
}
static const char * die_call_file ( Dwarf_Die * die ) {
Dwarf_Attribute attr_mem ;
Dwarf_Word file_idx = 0 ;
dwarf_formudata ( dwarf_attr ( die , DW_AT_call_file , & attr_mem ) , & file_idx ) ;
if ( file_idx = = 0 ) {
return 0 ;
}
Dwarf_Die die_mem ;
Dwarf_Die * cudie = dwarf_diecu ( die , & die_mem , 0 , 0 ) ;
if ( ! cudie ) {
return 0 ;
}
Dwarf_Files * files = 0 ;
size_t nfiles ;
dwarf_getsrcfiles ( cudie , & files , & nfiles ) ;
if ( ! files ) {
return 0 ;
}
return dwarf_filesrc ( files , file_idx , 0 , 0 ) ;
}
} ;
# endif // BACKWARD_HAS_DW == 1
# if BACKWARD_HAS_DWARF == 1
template < >
class TraceResolverLinuxImpl < trace_resolver_tag : : libdwarf >
: public TraceResolverLinuxBase {
public :
TraceResolverLinuxImpl ( ) : _dwarf_loaded ( false ) { }
ResolvedTrace resolve ( ResolvedTrace trace ) override {
// trace.addr is a virtual address in memory pointing to some code.
// Let's try to find from which loaded object it comes from.
// The loaded object can be yourself btw.
Dl_info symbol_info ;
int dladdr_result = 0 ;
# if defined(__GLIBC__)
link_map * link_map ;
// We request the link map so we can get information about offsets
dladdr_result =
dladdr1 ( trace . addr , & symbol_info , reinterpret_cast < void * * > ( & link_map ) ,
RTLD_DL_LINKMAP ) ;
# else
// Android doesn't have dladdr1. Don't use the linker map.
dladdr_result = dladdr ( trace . addr , & symbol_info ) ;
# endif
if ( ! dladdr_result ) {
return trace ; // dat broken trace...
}
// Now we get in symbol_info:
// .dli_fname:
// pathname of the shared object that contains the address.
// .dli_fbase:
// where the object is loaded in memory.
// .dli_sname:
// the name of the nearest symbol to trace.addr, we expect a
// function name.
// .dli_saddr:
// the exact address corresponding to .dli_sname.
//
// And in link_map:
// .l_addr:
// difference between the address in the ELF file and the address
// in memory
// l_name:
// absolute pathname where the object was found
if ( symbol_info . dli_sname ) {
trace . object_function = demangle ( symbol_info . dli_sname ) ;
}
if ( ! symbol_info . dli_fname ) {
return trace ;
}
trace . object_filename = resolve_exec_path ( symbol_info ) ;
dwarf_fileobject & fobj = load_object_with_dwarf ( symbol_info . dli_fname ) ;
if ( ! fobj . dwarf_handle ) {
return trace ; // sad, we couldn't load the object :(
}
# if defined(__GLIBC__)
// Convert the address to a module relative one by looking at
// the module's loading address in the link map
Dwarf_Addr address = reinterpret_cast < uintptr_t > ( trace . addr ) -
reinterpret_cast < uintptr_t > ( link_map - > l_addr ) ;
# else
Dwarf_Addr address = reinterpret_cast < uintptr_t > ( trace . addr ) ;
# endif
if ( trace . object_function . empty ( ) ) {
symbol_cache_t : : iterator it = fobj . symbol_cache . lower_bound ( address ) ;
if ( it ! = fobj . symbol_cache . end ( ) ) {
if ( it - > first ! = address ) {
if ( it ! = fobj . symbol_cache . begin ( ) ) {
- - it ;
}
}
trace . object_function = demangle ( it - > second . c_str ( ) ) ;
}
}
// Get the Compilation Unit DIE for the address
Dwarf_Die die = find_die ( fobj , address ) ;
if ( ! die ) {
return trace ; // this time we lost the game :/
}
// libdwarf doesn't give us direct access to its objects, it always
// allocates a copy for the caller. We keep that copy alive in a cache
// and we deallocate it later when it's no longer required.
die_cache_entry & die_object = get_die_cache ( fobj , die ) ;
if ( die_object . isEmpty ( ) )
return trace ; // We have no line section for this DIE
die_linemap_t : : iterator it = die_object . line_section . lower_bound ( address ) ;
if ( it ! = die_object . line_section . end ( ) ) {
if ( it - > first ! = address ) {
if ( it = = die_object . line_section . begin ( ) ) {
// If we are on the first item of the line section
// but the address does not match it means that
// the address is below the range of the DIE. Give up.
return trace ;
} else {
- - it ;
}
}
} else {
return trace ; // We didn't find the address.
}
// Get the Dwarf_Line that the address points to and call libdwarf
// to get source file, line and column info.
Dwarf_Line line = die_object . line_buffer [ it - > second ] ;
Dwarf_Error error = DW_DLE_NE ;
char * filename ;
if ( dwarf_linesrc ( line , & filename , & error ) = = DW_DLV_OK ) {
trace . source . filename = std : : string ( filename ) ;
dwarf_dealloc ( fobj . dwarf_handle . get ( ) , filename , DW_DLA_STRING ) ;
}
Dwarf_Unsigned number = 0 ;
if ( dwarf_lineno ( line , & number , & error ) = = DW_DLV_OK ) {
trace . source . line = number ;
} else {
trace . source . line = 0 ;
}
if ( dwarf_lineoff_b ( line , & number , & error ) = = DW_DLV_OK ) {
trace . source . col = number ;
} else {
trace . source . col = 0 ;
}
std : : vector < std : : string > namespace_stack ;
deep_first_search_by_pc ( fobj , die , address , namespace_stack ,
inliners_search_cb ( trace , fobj , die ) ) ;
dwarf_dealloc ( fobj . dwarf_handle . get ( ) , die , DW_DLA_DIE ) ;
return trace ;
}
public :
static int close_dwarf ( Dwarf_Debug dwarf ) {
return dwarf_finish ( dwarf , NULL ) ;
}
private :
bool _dwarf_loaded ;
typedef details : : handle < int , details : : deleter < int , int , & : : close > >
dwarf_file_t ;
typedef details : : handle < Elf * , details : : deleter < int , Elf * , & elf_end > >
dwarf_elf_t ;
typedef details : : handle < Dwarf_Debug ,
details : : deleter < int , Dwarf_Debug , & close_dwarf > >
dwarf_handle_t ;
typedef std : : map < Dwarf_Addr , int > die_linemap_t ;
typedef std : : map < Dwarf_Off , Dwarf_Off > die_specmap_t ;
struct die_cache_entry {
die_specmap_t spec_section ;
die_linemap_t line_section ;
Dwarf_Line * line_buffer ;
Dwarf_Signed line_count ;
Dwarf_Line_Context line_context ;
inline bool isEmpty ( ) {
return line_buffer = = NULL | | line_count = = 0 | | line_context = = NULL | |
line_section . empty ( ) ;
}
die_cache_entry ( ) : line_buffer ( 0 ) , line_count ( 0 ) , line_context ( 0 ) { }
~ die_cache_entry ( ) {
if ( line_context ) {
dwarf_srclines_dealloc_b ( line_context ) ;
}
}
} ;
typedef std : : map < Dwarf_Off , die_cache_entry > die_cache_t ;
typedef std : : map < uintptr_t , std : : string > symbol_cache_t ;
struct dwarf_fileobject {
dwarf_file_t file_handle ;
dwarf_elf_t elf_handle ;
dwarf_handle_t dwarf_handle ;
symbol_cache_t symbol_cache ;
// Die cache
die_cache_t die_cache ;
die_cache_entry * current_cu ;
} ;
typedef details : : hashtable < std : : string , dwarf_fileobject > : : type
fobj_dwarf_map_t ;
fobj_dwarf_map_t _fobj_dwarf_map ;
static bool cstrings_eq ( const char * a , const char * b ) {
if ( ! a | | ! b ) {
return false ;
}
return strcmp ( a , b ) = = 0 ;
}
dwarf_fileobject & load_object_with_dwarf ( const std : : string & filename_object ) {
if ( ! _dwarf_loaded ) {
// Set the ELF library operating version
// If that fails there's nothing we can do
_dwarf_loaded = elf_version ( EV_CURRENT ) ! = EV_NONE ;
}
fobj_dwarf_map_t : : iterator it = _fobj_dwarf_map . find ( filename_object ) ;
if ( it ! = _fobj_dwarf_map . end ( ) ) {
return it - > second ;
}
// this new object is empty for now
dwarf_fileobject & r = _fobj_dwarf_map [ filename_object ] ;
dwarf_file_t file_handle ;
file_handle . reset ( open ( filename_object . c_str ( ) , O_RDONLY ) ) ;
if ( file_handle . get ( ) < 0 ) {
return r ;
}
// Try to get an ELF handle. We need to read the ELF sections
// because we want to see if there is a .gnu_debuglink section
// that points to a split debug file
dwarf_elf_t elf_handle ;
elf_handle . reset ( elf_begin ( file_handle . get ( ) , ELF_C_READ , NULL ) ) ;
if ( ! elf_handle ) {
return r ;
}
const char * e_ident = elf_getident ( elf_handle . get ( ) , 0 ) ;
if ( ! e_ident ) {
return r ;
}
// Get the number of sections
// We use the new APIs as elf_getshnum is deprecated
size_t shdrnum = 0 ;
if ( elf_getshdrnum ( elf_handle . get ( ) , & shdrnum ) = = - 1 ) {
return r ;
}
// Get the index to the string section
size_t shdrstrndx = 0 ;
if ( elf_getshdrstrndx ( elf_handle . get ( ) , & shdrstrndx ) = = - 1 ) {
return r ;
}
std : : string debuglink ;
// Iterate through the ELF sections to try to get a gnu_debuglink
// note and also to cache the symbol table.
// We go the preprocessor way to avoid having to create templated
// classes or using gelf (which might throw a compiler error if 64 bit
// is not supported
# define ELF_GET_DATA(ARCH) \
Elf_Scn * elf_section = 0 ; \
Elf_Data * elf_data = 0 ; \
Elf # # ARCH # # _Shdr * section_header = 0 ; \
Elf_Scn * symbol_section = 0 ; \
size_t symbol_count = 0 ; \
size_t symbol_strings = 0 ; \
Elf # # ARCH # # _Sym * symbol = 0 ; \
const char * section_name = 0 ; \
\
while ( ( elf_section = elf_nextscn ( elf_handle . get ( ) , elf_section ) ) ! = NULL ) { \
section_header = elf # # ARCH # # _getshdr ( elf_section ) ; \
if ( section_header = = NULL ) { \
return r ; \
} \
\
if ( ( section_name = elf_strptr ( elf_handle . get ( ) , shdrstrndx , \
section_header - > sh_name ) ) = = NULL ) { \
return r ; \
} \
\
if ( cstrings_eq ( section_name , " .gnu_debuglink " ) ) { \
elf_data = elf_getdata ( elf_section , NULL ) ; \
if ( elf_data & & elf_data - > d_size > 0 ) { \
debuglink = \
std : : string ( reinterpret_cast < const char * > ( elf_data - > d_buf ) ) ; \
} \
} \
\
switch ( section_header - > sh_type ) { \
case SHT_SYMTAB : \
symbol_section = elf_section ; \
symbol_count = section_header - > sh_size / section_header - > sh_entsize ; \
symbol_strings = section_header - > sh_link ; \
break ; \
\
/* We use .dynsyms as a last resort, we prefer .symtab */ \
case SHT_DYNSYM : \
if ( ! symbol_section ) { \
symbol_section = elf_section ; \
symbol_count = section_header - > sh_size / section_header - > sh_entsize ; \
symbol_strings = section_header - > sh_link ; \
} \
break ; \
} \
} \
\
if ( symbol_section & & symbol_count & & symbol_strings ) { \
elf_data = elf_getdata ( symbol_section , NULL ) ; \
symbol = reinterpret_cast < Elf # # ARCH # # _Sym * > ( elf_data - > d_buf ) ; \
for ( size_t i = 0 ; i < symbol_count ; + + i ) { \
int type = ELF # # ARCH # # _ST_TYPE ( symbol - > st_info ) ; \
if ( type = = STT_FUNC & & symbol - > st_value > 0 ) { \
r . symbol_cache [ symbol - > st_value ] = std : : string ( \
elf_strptr ( elf_handle . get ( ) , symbol_strings , symbol - > st_name ) ) ; \
} \
+ + symbol ; \
} \
}
if ( e_ident [ EI_CLASS ] = = ELFCLASS32 ) {
ELF_GET_DATA ( 32 )
} else if ( e_ident [ EI_CLASS ] = = ELFCLASS64 ) {
// libelf might have been built without 64 bit support
# if __LIBELF64
ELF_GET_DATA ( 64 )
# endif
}
if ( ! debuglink . empty ( ) ) {
// We have a debuglink section! Open an elf instance on that
// file instead. If we can't open the file, then return
// the elf handle we had already opened.
dwarf_file_t debuglink_file ;
debuglink_file . reset ( open ( debuglink . c_str ( ) , O_RDONLY ) ) ;
if ( debuglink_file . get ( ) > 0 ) {
dwarf_elf_t debuglink_elf ;
debuglink_elf . reset ( elf_begin ( debuglink_file . get ( ) , ELF_C_READ , NULL ) ) ;
// If we have a valid elf handle, return the new elf handle
// and file handle and discard the original ones
if ( debuglink_elf ) {
elf_handle = move ( debuglink_elf ) ;
file_handle = move ( debuglink_file ) ;
}
}
}
// Ok, we have a valid ELF handle, let's try to get debug symbols
Dwarf_Debug dwarf_debug ;
Dwarf_Error error = DW_DLE_NE ;
dwarf_handle_t dwarf_handle ;
int dwarf_result = dwarf_elf_init ( elf_handle . get ( ) , DW_DLC_READ , NULL , NULL ,
& dwarf_debug , & error ) ;
// We don't do any special handling for DW_DLV_NO_ENTRY specially.
// If we get an error, or the file doesn't have debug information
// we just return.
if ( dwarf_result ! = DW_DLV_OK ) {
return r ;
}
dwarf_handle . reset ( dwarf_debug ) ;
r . file_handle = move ( file_handle ) ;
r . elf_handle = move ( elf_handle ) ;
r . dwarf_handle = move ( dwarf_handle ) ;
return r ;
}
die_cache_entry & get_die_cache ( dwarf_fileobject & fobj , Dwarf_Die die ) {
Dwarf_Error error = DW_DLE_NE ;
// Get the die offset, we use it as the cache key
Dwarf_Off die_offset ;
if ( dwarf_dieoffset ( die , & die_offset , & error ) ! = DW_DLV_OK ) {
die_offset = 0 ;
}
die_cache_t : : iterator it = fobj . die_cache . find ( die_offset ) ;
if ( it ! = fobj . die_cache . end ( ) ) {
fobj . current_cu = & it - > second ;
return it - > second ;
}
die_cache_entry & de = fobj . die_cache [ die_offset ] ;
fobj . current_cu = & de ;
Dwarf_Addr line_addr ;
Dwarf_Small table_count ;
// The addresses in the line section are not fully sorted (they might
// be sorted by block of code belonging to the same file), which makes
// it necessary to do so before searching is possible.
//
// As libdwarf allocates a copy of everything, let's get the contents
// of the line section and keep it around. We also create a map of
// program counter to line table indices so we can search by address
// and get the line buffer index.
//
// To make things more difficult, the same address can span more than
// one line, so we need to keep the index pointing to the first line
// by using insert instead of the map's [ operator.
// Get the line context for the DIE
if ( dwarf_srclines_b ( die , 0 , & table_count , & de . line_context , & error ) = =
DW_DLV_OK ) {
// Get the source lines for this line context, to be deallocated
// later
if ( dwarf_srclines_from_linecontext ( de . line_context , & de . line_buffer ,
& de . line_count ,
& error ) = = DW_DLV_OK ) {
// Add all the addresses to our map
for ( int i = 0 ; i < de . line_count ; i + + ) {
if ( dwarf_lineaddr ( de . line_buffer [ i ] , & line_addr , & error ) ! =
DW_DLV_OK ) {
line_addr = 0 ;
}
de . line_section . insert ( std : : pair < Dwarf_Addr , int > ( line_addr , i ) ) ;
}
}
}
// For each CU, cache the function DIEs that contain the
// DW_AT_specification attribute. When building with -g3 the function
// DIEs are separated in declaration and specification, with the
// declaration containing only the name and parameters and the
// specification the low/high pc and other compiler attributes.
//
// We cache those specifications so we don't skip over the declarations,
// because they have no pc, and we can do namespace resolution for
// DWARF function names.
Dwarf_Debug dwarf = fobj . dwarf_handle . get ( ) ;
Dwarf_Die current_die = 0 ;
if ( dwarf_child ( die , & current_die , & error ) = = DW_DLV_OK ) {
for ( ; ; ) {
Dwarf_Die sibling_die = 0 ;
Dwarf_Half tag_value ;
dwarf_tag ( current_die , & tag_value , & error ) ;
if ( tag_value = = DW_TAG_subprogram | |
tag_value = = DW_TAG_inlined_subroutine ) {
Dwarf_Bool has_attr = 0 ;
if ( dwarf_hasattr ( current_die , DW_AT_specification , & has_attr ,
& error ) = = DW_DLV_OK ) {
if ( has_attr ) {
Dwarf_Attribute attr_mem ;
if ( dwarf_attr ( current_die , DW_AT_specification , & attr_mem ,
& error ) = = DW_DLV_OK ) {
Dwarf_Off spec_offset = 0 ;
if ( dwarf_formref ( attr_mem , & spec_offset , & error ) = =
DW_DLV_OK ) {
Dwarf_Off spec_die_offset ;
if ( dwarf_dieoffset ( current_die , & spec_die_offset , & error ) = =
DW_DLV_OK ) {
de . spec_section [ spec_offset ] = spec_die_offset ;
}
}
}
dwarf_dealloc ( dwarf , attr_mem , DW_DLA_ATTR ) ;
}
}
}
int result = dwarf_siblingof ( dwarf , current_die , & sibling_die , & error ) ;
if ( result = = DW_DLV_ERROR ) {
break ;
} else if ( result = = DW_DLV_NO_ENTRY ) {
break ;
}
if ( current_die ! = die ) {
dwarf_dealloc ( dwarf , current_die , DW_DLA_DIE ) ;
current_die = 0 ;
}
current_die = sibling_die ;
}
}
return de ;
}
static Dwarf_Die get_referenced_die ( Dwarf_Debug dwarf , Dwarf_Die die ,
Dwarf_Half attr , bool global ) {
Dwarf_Error error = DW_DLE_NE ;
Dwarf_Attribute attr_mem ;
Dwarf_Die found_die = NULL ;
if ( dwarf_attr ( die , attr , & attr_mem , & error ) = = DW_DLV_OK ) {
Dwarf_Off offset ;
int result = 0 ;
if ( global ) {
result = dwarf_global_formref ( attr_mem , & offset , & error ) ;
} else {
result = dwarf_formref ( attr_mem , & offset , & error ) ;
}
if ( result = = DW_DLV_OK ) {
if ( dwarf_offdie ( dwarf , offset , & found_die , & error ) ! = DW_DLV_OK ) {
found_die = NULL ;
}
}
dwarf_dealloc ( dwarf , attr_mem , DW_DLA_ATTR ) ;
}
return found_die ;
}
static std : : string get_referenced_die_name ( Dwarf_Debug dwarf , Dwarf_Die die ,
Dwarf_Half attr , bool global ) {
Dwarf_Error error = DW_DLE_NE ;
std : : string value ;
Dwarf_Die found_die = get_referenced_die ( dwarf , die , attr , global ) ;
if ( found_die ) {
char * name ;
if ( dwarf_diename ( found_die , & name , & error ) = = DW_DLV_OK ) {
if ( name ) {
value = std : : string ( name ) ;
}
dwarf_dealloc ( dwarf , name , DW_DLA_STRING ) ;
}
dwarf_dealloc ( dwarf , found_die , DW_DLA_DIE ) ;
}
return value ;
}
// Returns a spec DIE linked to the passed one. The caller should
// deallocate the DIE
static Dwarf_Die get_spec_die ( dwarf_fileobject & fobj , Dwarf_Die die ) {
Dwarf_Debug dwarf = fobj . dwarf_handle . get ( ) ;
Dwarf_Error error = DW_DLE_NE ;
Dwarf_Off die_offset ;
if ( fobj . current_cu & &
dwarf_die_CU_offset ( die , & die_offset , & error ) = = DW_DLV_OK ) {
die_specmap_t : : iterator it =
fobj . current_cu - > spec_section . find ( die_offset ) ;
// If we have a DIE that completes the current one, check if
// that one has the pc we are looking for
if ( it ! = fobj . current_cu - > spec_section . end ( ) ) {
Dwarf_Die spec_die = 0 ;
if ( dwarf_offdie ( dwarf , it - > second , & spec_die , & error ) = = DW_DLV_OK ) {
return spec_die ;
}
}
}
// Maybe we have an abstract origin DIE with the function information?
return get_referenced_die ( fobj . dwarf_handle . get ( ) , die ,
DW_AT_abstract_origin , true ) ;
}
static bool die_has_pc ( dwarf_fileobject & fobj , Dwarf_Die die , Dwarf_Addr pc ) {
Dwarf_Addr low_pc = 0 , high_pc = 0 ;
Dwarf_Half high_pc_form = 0 ;
Dwarf_Form_Class return_class ;
Dwarf_Error error = DW_DLE_NE ;
Dwarf_Debug dwarf = fobj . dwarf_handle . get ( ) ;
bool has_lowpc = false ;
bool has_highpc = false ;
bool has_ranges = false ;
if ( dwarf_lowpc ( die , & low_pc , & error ) = = DW_DLV_OK ) {
// If we have a low_pc check if there is a high pc.
// If we don't have a high pc this might mean we have a base
// address for the ranges list or just an address.
has_lowpc = true ;
if ( dwarf_highpc_b ( die , & high_pc , & high_pc_form , & return_class , & error ) = =
DW_DLV_OK ) {
// We do have a high pc. In DWARF 4+ this is an offset from the
// low pc, but in earlier versions it's an absolute address.
has_highpc = true ;
// In DWARF 2/3 this would be a DW_FORM_CLASS_ADDRESS
if ( return_class = = DW_FORM_CLASS_CONSTANT ) {
high_pc = low_pc + high_pc ;
}
// We have low and high pc, check if our address
// is in that range
return pc > = low_pc & & pc < high_pc ;
}
} else {
// Reset the low_pc, in case dwarf_lowpc failing set it to some
// undefined value.
low_pc = 0 ;
}
// Check if DW_AT_ranges is present and search for the PC in the
// returned ranges list. We always add the low_pc, as it not set it will
// be 0, in case we had a DW_AT_low_pc and DW_AT_ranges pair
bool result = false ;
Dwarf_Attribute attr ;
if ( dwarf_attr ( die , DW_AT_ranges , & attr , & error ) = = DW_DLV_OK ) {
Dwarf_Off offset ;
if ( dwarf_global_formref ( attr , & offset , & error ) = = DW_DLV_OK ) {
Dwarf_Ranges * ranges ;
Dwarf_Signed ranges_count = 0 ;
Dwarf_Unsigned byte_count = 0 ;
if ( dwarf_get_ranges_a ( dwarf , offset , die , & ranges , & ranges_count ,
& byte_count , & error ) = = DW_DLV_OK ) {
has_ranges = ranges_count ! = 0 ;
for ( int i = 0 ; i < ranges_count ; i + + ) {
if ( ranges [ i ] . dwr_addr1 ! = 0 & &
pc > = ranges [ i ] . dwr_addr1 + low_pc & &
pc < ranges [ i ] . dwr_addr2 + low_pc ) {
result = true ;
break ;
}
}
dwarf_ranges_dealloc ( dwarf , ranges , ranges_count ) ;
}
}
}
// Last attempt. We might have a single address set as low_pc.
if ( ! result & & low_pc ! = 0 & & pc = = low_pc ) {
result = true ;
}
// If we don't have lowpc, highpc and ranges maybe this DIE is a
// declaration that relies on a DW_AT_specification DIE that happens
// later. Use the specification cache we filled when we loaded this CU.
if ( ! result & & ( ! has_lowpc & & ! has_highpc & & ! has_ranges ) ) {
Dwarf_Die spec_die = get_spec_die ( fobj , die ) ;
if ( spec_die ) {
result = die_has_pc ( fobj , spec_die , pc ) ;
dwarf_dealloc ( dwarf , spec_die , DW_DLA_DIE ) ;
}
}
return result ;
}
static void get_type ( Dwarf_Debug dwarf , Dwarf_Die die , std : : string & type ) {
Dwarf_Error error = DW_DLE_NE ;
Dwarf_Die child = 0 ;
if ( dwarf_child ( die , & child , & error ) = = DW_DLV_OK ) {
get_type ( dwarf , child , type ) ;
}
if ( child ) {
type . insert ( 0 , " :: " ) ;
dwarf_dealloc ( dwarf , child , DW_DLA_DIE ) ;
}
char * name ;
if ( dwarf_diename ( die , & name , & error ) = = DW_DLV_OK ) {
type . insert ( 0 , std : : string ( name ) ) ;
dwarf_dealloc ( dwarf , name , DW_DLA_STRING ) ;
} else {
type . insert ( 0 , " <unknown> " ) ;
}
}
static std : : string get_type_by_signature ( Dwarf_Debug dwarf , Dwarf_Die die ) {
Dwarf_Error error = DW_DLE_NE ;
Dwarf_Sig8 signature ;
Dwarf_Bool has_attr = 0 ;
if ( dwarf_hasattr ( die , DW_AT_signature , & has_attr , & error ) = = DW_DLV_OK ) {
if ( has_attr ) {
Dwarf_Attribute attr_mem ;
if ( dwarf_attr ( die , DW_AT_signature , & attr_mem , & error ) = = DW_DLV_OK ) {
if ( dwarf_formsig8 ( attr_mem , & signature , & error ) ! = DW_DLV_OK ) {
return std : : string ( " <no type signature> " ) ;
}
}
dwarf_dealloc ( dwarf , attr_mem , DW_DLA_ATTR ) ;
}
}
Dwarf_Unsigned next_cu_header ;
Dwarf_Sig8 tu_signature ;
std : : string result ;
bool found = false ;
while ( dwarf_next_cu_header_d ( dwarf , 0 , 0 , 0 , 0 , 0 , 0 , 0 , & tu_signature , 0 ,
& next_cu_header , 0 , & error ) = = DW_DLV_OK ) {
if ( strncmp ( signature . signature , tu_signature . signature , 8 ) = = 0 ) {
Dwarf_Die type_cu_die = 0 ;
if ( dwarf_siblingof_b ( dwarf , 0 , 0 , & type_cu_die , & error ) = = DW_DLV_OK ) {
Dwarf_Die child_die = 0 ;
if ( dwarf_child ( type_cu_die , & child_die , & error ) = = DW_DLV_OK ) {
get_type ( dwarf , child_die , result ) ;
found = ! result . empty ( ) ;
dwarf_dealloc ( dwarf , child_die , DW_DLA_DIE ) ;
}
dwarf_dealloc ( dwarf , type_cu_die , DW_DLA_DIE ) ;
}
}
}
if ( found ) {
while ( dwarf_next_cu_header_d ( dwarf , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 ,
& next_cu_header , 0 , & error ) = = DW_DLV_OK ) {
// Reset the cu header state. Unfortunately, libdwarf's
// next_cu_header API keeps its own iterator per Dwarf_Debug
// that can't be reset. We need to keep fetching elements until
// the end.
}
} else {
// If we couldn't resolve the type just print out the signature
std : : ostringstream string_stream ;
string_stream < < " <0x " < < std : : hex < < std : : setfill ( ' 0 ' ) ;
for ( int i = 0 ; i < 8 ; + + i ) {
string_stream < < std : : setw ( 2 ) < < std : : hex
< < ( int ) ( unsigned char ) ( signature . signature [ i ] ) ;
}
string_stream < < " > " ;
result = string_stream . str ( ) ;
}
return result ;
}
struct type_context_t {
bool is_const ;
bool is_typedef ;
bool has_type ;
bool has_name ;
std : : string text ;
type_context_t ( )
: is_const ( false ) , is_typedef ( false ) , has_type ( false ) , has_name ( false ) {
}
} ;
// Types are resolved from right to left: we get the variable name first
// and then all specifiers (like const or pointer) in a chain of DW_AT_type
// DIEs. Call this function recursively until we get a complete type
// string.
static void set_parameter_string ( dwarf_fileobject & fobj , Dwarf_Die die ,
type_context_t & context ) {
char * name ;
Dwarf_Error error = DW_DLE_NE ;
// typedefs contain also the base type, so we skip it and only
// print the typedef name
if ( ! context . is_typedef ) {
if ( dwarf_diename ( die , & name , & error ) = = DW_DLV_OK ) {
if ( ! context . text . empty ( ) ) {
context . text . insert ( 0 , " " ) ;
}
context . text . insert ( 0 , std : : string ( name ) ) ;
dwarf_dealloc ( fobj . dwarf_handle . get ( ) , name , DW_DLA_STRING ) ;
}
} else {
context . is_typedef = false ;
context . has_type = true ;
if ( context . is_const ) {
context . text . insert ( 0 , " const " ) ;
context . is_const = false ;
}
}
bool next_type_is_const = false ;
bool is_keyword = true ;
Dwarf_Half tag = 0 ;
Dwarf_Bool has_attr = 0 ;
if ( dwarf_tag ( die , & tag , & error ) = = DW_DLV_OK ) {
switch ( tag ) {
case DW_TAG_structure_type :
case DW_TAG_union_type :
case DW_TAG_class_type :
case DW_TAG_enumeration_type :
context . has_type = true ;
if ( dwarf_hasattr ( die , DW_AT_signature , & has_attr , & error ) = =
DW_DLV_OK ) {
// If we have a signature it means the type is defined
// in .debug_types, so we need to load the DIE pointed
// at by the signature and resolve it
if ( has_attr ) {
std : : string type =
get_type_by_signature ( fobj . dwarf_handle . get ( ) , die ) ;
if ( context . is_const )
type . insert ( 0 , " const " ) ;
if ( ! context . text . empty ( ) )
context . text . insert ( 0 , " " ) ;
context . text . insert ( 0 , type ) ;
}
// Treat enums like typedefs, and skip printing its
// base type
context . is_typedef = ( tag = = DW_TAG_enumeration_type ) ;
}
break ;
case DW_TAG_const_type :
next_type_is_const = true ;
break ;
case DW_TAG_pointer_type :
context . text . insert ( 0 , " * " ) ;
break ;
case DW_TAG_reference_type :
context . text . insert ( 0 , " & " ) ;
break ;
case DW_TAG_restrict_type :
context . text . insert ( 0 , " restrict " ) ;
break ;
case DW_TAG_rvalue_reference_type :
context . text . insert ( 0 , " && " ) ;
break ;
case DW_TAG_volatile_type :
context . text . insert ( 0 , " volatile " ) ;
break ;
case DW_TAG_typedef :
// Propagate the const-ness to the next type
// as typedefs are linked to its base type
next_type_is_const = context . is_const ;
context . is_typedef = true ;
context . has_type = true ;
break ;
case DW_TAG_base_type :
context . has_type = true ;
break ;
case DW_TAG_formal_parameter :
context . has_name = true ;
break ;
default :
is_keyword = false ;
break ;
}
}
if ( ! is_keyword & & context . is_const ) {
context . text . insert ( 0 , " const " ) ;
}
context . is_const = next_type_is_const ;
Dwarf_Die ref =
get_referenced_die ( fobj . dwarf_handle . get ( ) , die , DW_AT_type , true ) ;
if ( ref ) {
set_parameter_string ( fobj , ref , context ) ;
dwarf_dealloc ( fobj . dwarf_handle . get ( ) , ref , DW_DLA_DIE ) ;
}
if ( ! context . has_type & & context . has_name ) {
context . text . insert ( 0 , " void " ) ;
context . has_type = true ;
}
}
// Resolve the function return type and parameters
static void set_function_parameters ( std : : string & function_name ,
std : : vector < std : : string > & ns ,
dwarf_fileobject & fobj , Dwarf_Die die ) {
Dwarf_Debug dwarf = fobj . dwarf_handle . get ( ) ;
Dwarf_Error error = DW_DLE_NE ;
Dwarf_Die current_die = 0 ;
std : : string parameters ;
bool has_spec = true ;
// Check if we have a spec DIE. If we do we use it as it contains
// more information, like parameter names.
Dwarf_Die spec_die = get_spec_die ( fobj , die ) ;
if ( ! spec_die ) {
has_spec = false ;
spec_die = die ;
}
std : : vector < std : : string > : : const_iterator it = ns . begin ( ) ;
std : : string ns_name ;
for ( it = ns . begin ( ) ; it < ns . end ( ) ; + + it ) {
ns_name . append ( * it ) . append ( " :: " ) ;
}
if ( ! ns_name . empty ( ) ) {
function_name . insert ( 0 , ns_name ) ;
}
// See if we have a function return type. It can be either on the
// current die or in its spec one (usually true for inlined functions)
std : : string return_type =
get_referenced_die_name ( dwarf , die , DW_AT_type , true ) ;
if ( return_type . empty ( ) ) {
return_type = get_referenced_die_name ( dwarf , spec_die , DW_AT_type , true ) ;
}
if ( ! return_type . empty ( ) ) {
return_type . append ( " " ) ;
function_name . insert ( 0 , return_type ) ;
}
if ( dwarf_child ( spec_die , & current_die , & error ) = = DW_DLV_OK ) {
for ( ; ; ) {
Dwarf_Die sibling_die = 0 ;
Dwarf_Half tag_value ;
dwarf_tag ( current_die , & tag_value , & error ) ;
if ( tag_value = = DW_TAG_formal_parameter ) {
// Ignore artificial (ie, compiler generated) parameters
bool is_artificial = false ;
Dwarf_Attribute attr_mem ;
if ( dwarf_attr ( current_die , DW_AT_artificial , & attr_mem , & error ) = =
DW_DLV_OK ) {
Dwarf_Bool flag = 0 ;
if ( dwarf_formflag ( attr_mem , & flag , & error ) = = DW_DLV_OK ) {
is_artificial = flag ! = 0 ;
}
dwarf_dealloc ( dwarf , attr_mem , DW_DLA_ATTR ) ;
}
if ( ! is_artificial ) {
type_context_t context ;
set_parameter_string ( fobj , current_die , context ) ;
if ( parameters . empty ( ) ) {
parameters . append ( " ( " ) ;
} else {
parameters . append ( " , " ) ;
}
parameters . append ( context . text ) ;
}
}
int result = dwarf_siblingof ( dwarf , current_die , & sibling_die , & error ) ;
if ( result = = DW_DLV_ERROR ) {
break ;
} else if ( result = = DW_DLV_NO_ENTRY ) {
break ;
}
if ( current_die ! = die ) {
dwarf_dealloc ( dwarf , current_die , DW_DLA_DIE ) ;
current_die = 0 ;
}
current_die = sibling_die ;
}
}
if ( parameters . empty ( ) )
parameters = " ( " ;
parameters . append ( " ) " ) ;
// If we got a spec DIE we need to deallocate it
if ( has_spec )
dwarf_dealloc ( dwarf , spec_die , DW_DLA_DIE ) ;
function_name . append ( parameters ) ;
}
// defined here because in C++98, template function cannot take locally
// defined types... grrr.
struct inliners_search_cb {
void operator ( ) ( Dwarf_Die die , std : : vector < std : : string > & ns ) {
Dwarf_Error error = DW_DLE_NE ;
Dwarf_Half tag_value ;
Dwarf_Attribute attr_mem ;
Dwarf_Debug dwarf = fobj . dwarf_handle . get ( ) ;
dwarf_tag ( die , & tag_value , & error ) ;
switch ( tag_value ) {
char * name ;
case DW_TAG_subprogram :
if ( ! trace . source . function . empty ( ) )
break ;
if ( dwarf_diename ( die , & name , & error ) = = DW_DLV_OK ) {
trace . source . function = std : : string ( name ) ;
dwarf_dealloc ( dwarf , name , DW_DLA_STRING ) ;
} else {
// We don't have a function name in this DIE.
// Check if there is a referenced non-defining
// declaration.
trace . source . function =
get_referenced_die_name ( dwarf , die , DW_AT_abstract_origin , true ) ;
if ( trace . source . function . empty ( ) ) {
trace . source . function =
get_referenced_die_name ( dwarf , die , DW_AT_specification , true ) ;
}
}
// Append the function parameters, if available
set_function_parameters ( trace . source . function , ns , fobj , die ) ;
// If the object function name is empty, it's possible that
// there is no dynamic symbol table (maybe the executable
// was stripped or not built with -rdynamic). See if we have
// a DWARF linkage name to use instead. We try both
// linkage_name and MIPS_linkage_name because the MIPS tag
// was the unofficial one until it was adopted in DWARF4.
// Old gcc versions generate MIPS_linkage_name
if ( trace . object_function . empty ( ) ) {
details : : demangler demangler ;
if ( dwarf_attr ( die , DW_AT_linkage_name , & attr_mem , & error ) ! =
DW_DLV_OK ) {
if ( dwarf_attr ( die , DW_AT_MIPS_linkage_name , & attr_mem , & error ) ! =
DW_DLV_OK ) {
break ;
}
}
char * linkage ;
if ( dwarf_formstring ( attr_mem , & linkage , & error ) = = DW_DLV_OK ) {
trace . object_function = demangler . demangle ( linkage ) ;
dwarf_dealloc ( dwarf , linkage , DW_DLA_STRING ) ;
}
dwarf_dealloc ( dwarf , attr_mem , DW_DLA_ATTR ) ;
}
break ;
case DW_TAG_inlined_subroutine :
ResolvedTrace : : SourceLoc sloc ;
if ( dwarf_diename ( die , & name , & error ) = = DW_DLV_OK ) {
sloc . function = std : : string ( name ) ;
dwarf_dealloc ( dwarf , name , DW_DLA_STRING ) ;
} else {
// We don't have a name for this inlined DIE, it could
// be that there is an abstract origin instead.
// Get the DW_AT_abstract_origin value, which is a
// reference to the source DIE and try to get its name
sloc . function =
get_referenced_die_name ( dwarf , die , DW_AT_abstract_origin , true ) ;
}
set_function_parameters ( sloc . function , ns , fobj , die ) ;
std : : string file = die_call_file ( dwarf , die , cu_die ) ;
if ( ! file . empty ( ) )
sloc . filename = file ;
Dwarf_Unsigned number = 0 ;
if ( dwarf_attr ( die , DW_AT_call_line , & attr_mem , & error ) = = DW_DLV_OK ) {
if ( dwarf_formudata ( attr_mem , & number , & error ) = = DW_DLV_OK ) {
sloc . line = number ;
}
dwarf_dealloc ( dwarf , attr_mem , DW_DLA_ATTR ) ;
}
if ( dwarf_attr ( die , DW_AT_call_column , & attr_mem , & error ) = =
DW_DLV_OK ) {
if ( dwarf_formudata ( attr_mem , & number , & error ) = = DW_DLV_OK ) {
sloc . col = number ;
}
dwarf_dealloc ( dwarf , attr_mem , DW_DLA_ATTR ) ;
}
trace . inliners . push_back ( sloc ) ;
break ;
} ;
}
ResolvedTrace & trace ;
dwarf_fileobject & fobj ;
Dwarf_Die cu_die ;
inliners_search_cb ( ResolvedTrace & t , dwarf_fileobject & f , Dwarf_Die c )
: trace ( t ) , fobj ( f ) , cu_die ( c ) { }
} ;
static Dwarf_Die find_fundie_by_pc ( dwarf_fileobject & fobj ,
Dwarf_Die parent_die , Dwarf_Addr pc ,
Dwarf_Die result ) {
Dwarf_Die current_die = 0 ;
Dwarf_Error error = DW_DLE_NE ;
Dwarf_Debug dwarf = fobj . dwarf_handle . get ( ) ;
if ( dwarf_child ( parent_die , & current_die , & error ) ! = DW_DLV_OK ) {
return NULL ;
}
for ( ; ; ) {
Dwarf_Die sibling_die = 0 ;
Dwarf_Half tag_value ;
dwarf_tag ( current_die , & tag_value , & error ) ;
switch ( tag_value ) {
case DW_TAG_subprogram :
case DW_TAG_inlined_subroutine :
if ( die_has_pc ( fobj , current_die , pc ) ) {
return current_die ;
}
} ;
bool declaration = false ;
Dwarf_Attribute attr_mem ;
if ( dwarf_attr ( current_die , DW_AT_declaration , & attr_mem , & error ) = =
DW_DLV_OK ) {
Dwarf_Bool flag = 0 ;
if ( dwarf_formflag ( attr_mem , & flag , & error ) = = DW_DLV_OK ) {
declaration = flag ! = 0 ;
}
dwarf_dealloc ( dwarf , attr_mem , DW_DLA_ATTR ) ;
}
if ( ! declaration ) {
// let's be curious and look deeper in the tree, functions are
// not necessarily at the first level, but might be nested
// inside a namespace, structure, a function, an inlined
// function etc.
Dwarf_Die die_mem = 0 ;
Dwarf_Die indie = find_fundie_by_pc ( fobj , current_die , pc , die_mem ) ;
if ( indie ) {
result = die_mem ;
return result ;
}
}
int res = dwarf_siblingof ( dwarf , current_die , & sibling_die , & error ) ;
if ( res = = DW_DLV_ERROR ) {
return NULL ;
} else if ( res = = DW_DLV_NO_ENTRY ) {
break ;
}
if ( current_die ! = parent_die ) {
dwarf_dealloc ( dwarf , current_die , DW_DLA_DIE ) ;
current_die = 0 ;
}
current_die = sibling_die ;
}
return NULL ;
}
template < typename CB >
static bool deep_first_search_by_pc ( dwarf_fileobject & fobj ,
Dwarf_Die parent_die , Dwarf_Addr pc ,
std : : vector < std : : string > & ns , CB cb ) {
Dwarf_Die current_die = 0 ;
Dwarf_Debug dwarf = fobj . dwarf_handle . get ( ) ;
Dwarf_Error error = DW_DLE_NE ;
if ( dwarf_child ( parent_die , & current_die , & error ) ! = DW_DLV_OK ) {
return false ;
}
bool branch_has_pc = false ;
bool has_namespace = false ;
for ( ; ; ) {
Dwarf_Die sibling_die = 0 ;
Dwarf_Half tag ;
if ( dwarf_tag ( current_die , & tag , & error ) = = DW_DLV_OK ) {
if ( tag = = DW_TAG_namespace | | tag = = DW_TAG_class_type ) {
char * ns_name = NULL ;
if ( dwarf_diename ( current_die , & ns_name , & error ) = = DW_DLV_OK ) {
if ( ns_name ) {
ns . push_back ( std : : string ( ns_name ) ) ;
} else {
ns . push_back ( " <unknown> " ) ;
}
dwarf_dealloc ( dwarf , ns_name , DW_DLA_STRING ) ;
} else {
ns . push_back ( " <unknown> " ) ;
}
has_namespace = true ;
}
}
bool declaration = false ;
Dwarf_Attribute attr_mem ;
if ( tag ! = DW_TAG_class_type & &
dwarf_attr ( current_die , DW_AT_declaration , & attr_mem , & error ) = =
DW_DLV_OK ) {
Dwarf_Bool flag = 0 ;
if ( dwarf_formflag ( attr_mem , & flag , & error ) = = DW_DLV_OK ) {
declaration = flag ! = 0 ;
}
dwarf_dealloc ( dwarf , attr_mem , DW_DLA_ATTR ) ;
}
if ( ! declaration ) {
// let's be curious and look deeper in the tree, function are
// not necessarily at the first level, but might be nested
// inside a namespace, structure, a function, an inlined
// function etc.
branch_has_pc = deep_first_search_by_pc ( fobj , current_die , pc , ns , cb ) ;
}
if ( ! branch_has_pc ) {
branch_has_pc = die_has_pc ( fobj , current_die , pc ) ;
}
if ( branch_has_pc ) {
cb ( current_die , ns ) ;
}
int result = dwarf_siblingof ( dwarf , current_die , & sibling_die , & error ) ;
if ( result = = DW_DLV_ERROR ) {
return false ;
} else if ( result = = DW_DLV_NO_ENTRY ) {
break ;
}
if ( current_die ! = parent_die ) {
dwarf_dealloc ( dwarf , current_die , DW_DLA_DIE ) ;
current_die = 0 ;
}
if ( has_namespace ) {
has_namespace = false ;
ns . pop_back ( ) ;
}
current_die = sibling_die ;
}
if ( has_namespace ) {
ns . pop_back ( ) ;
}
return branch_has_pc ;
}
static std : : string die_call_file ( Dwarf_Debug dwarf , Dwarf_Die die ,
Dwarf_Die cu_die ) {
Dwarf_Attribute attr_mem ;
Dwarf_Error error = DW_DLE_NE ;
Dwarf_Unsigned file_index ;
std : : string file ;
if ( dwarf_attr ( die , DW_AT_call_file , & attr_mem , & error ) = = DW_DLV_OK ) {
if ( dwarf_formudata ( attr_mem , & file_index , & error ) ! = DW_DLV_OK ) {
file_index = 0 ;
}
dwarf_dealloc ( dwarf , attr_mem , DW_DLA_ATTR ) ;
if ( file_index = = 0 ) {
return file ;
}
char * * srcfiles = 0 ;
Dwarf_Signed file_count = 0 ;
if ( dwarf_srcfiles ( cu_die , & srcfiles , & file_count , & error ) = = DW_DLV_OK ) {
if ( file_count > 0 & & file_index < = static_cast < Dwarf_Unsigned > ( file_count ) ) {
file = std : : string ( srcfiles [ file_index - 1 ] ) ;
}
// Deallocate all strings!
for ( int i = 0 ; i < file_count ; + + i ) {
dwarf_dealloc ( dwarf , srcfiles [ i ] , DW_DLA_STRING ) ;
}
dwarf_dealloc ( dwarf , srcfiles , DW_DLA_LIST ) ;
}
}
return file ;
}
Dwarf_Die find_die ( dwarf_fileobject & fobj , Dwarf_Addr addr ) {
// Let's get to work! First see if we have a debug_aranges section so
// we can speed up the search
Dwarf_Debug dwarf = fobj . dwarf_handle . get ( ) ;
Dwarf_Error error = DW_DLE_NE ;
Dwarf_Arange * aranges ;
Dwarf_Signed arange_count ;
Dwarf_Die returnDie ;
bool found = false ;
if ( dwarf_get_aranges ( dwarf , & aranges , & arange_count , & error ) ! =
DW_DLV_OK ) {
aranges = NULL ;
}
if ( aranges ) {
// We have aranges. Get the one where our address is.
Dwarf_Arange arange ;
if ( dwarf_get_arange ( aranges , arange_count , addr , & arange , & error ) = =
DW_DLV_OK ) {
// We found our address. Get the compilation-unit DIE offset
// represented by the given address range.
Dwarf_Off cu_die_offset ;
if ( dwarf_get_cu_die_offset ( arange , & cu_die_offset , & error ) = =
DW_DLV_OK ) {
// Get the DIE at the offset returned by the aranges search.
// We set is_info to 1 to specify that the offset is from
// the .debug_info section (and not .debug_types)
int dwarf_result =
dwarf_offdie_b ( dwarf , cu_die_offset , 1 , & returnDie , & error ) ;
found = dwarf_result = = DW_DLV_OK ;
}
dwarf_dealloc ( dwarf , arange , DW_DLA_ARANGE ) ;
}
}
if ( found )
return returnDie ; // The caller is responsible for freeing the die
// The search for aranges failed. Try to find our address by scanning
// all compilation units.
Dwarf_Unsigned next_cu_header ;
Dwarf_Half tag = 0 ;
returnDie = 0 ;
while ( ! found & &
dwarf_next_cu_header_d ( dwarf , 1 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 ,
& next_cu_header , 0 , & error ) = = DW_DLV_OK ) {
if ( returnDie )
dwarf_dealloc ( dwarf , returnDie , DW_DLA_DIE ) ;
if ( dwarf_siblingof ( dwarf , 0 , & returnDie , & error ) = = DW_DLV_OK ) {
if ( ( dwarf_tag ( returnDie , & tag , & error ) = = DW_DLV_OK ) & &
tag = = DW_TAG_compile_unit ) {
if ( die_has_pc ( fobj , returnDie , addr ) ) {
found = true ;
}
}
}
}
if ( found ) {
while ( dwarf_next_cu_header_d ( dwarf , 1 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 ,
& next_cu_header , 0 , & error ) = = DW_DLV_OK ) {
// Reset the cu header state. Libdwarf's next_cu_header API
// keeps its own iterator per Dwarf_Debug that can't be reset.
// We need to keep fetching elements until the end.
}
}
if ( found )
return returnDie ;
// We couldn't find any compilation units with ranges or a high/low pc.
// Try again by looking at all DIEs in all compilation units.
Dwarf_Die cudie ;
while ( dwarf_next_cu_header_d ( dwarf , 1 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 ,
& next_cu_header , 0 , & error ) = = DW_DLV_OK ) {
if ( dwarf_siblingof ( dwarf , 0 , & cudie , & error ) = = DW_DLV_OK ) {
Dwarf_Die die_mem = 0 ;
Dwarf_Die resultDie = find_fundie_by_pc ( fobj , cudie , addr , die_mem ) ;
if ( resultDie ) {
found = true ;
break ;
}
}
}
if ( found ) {
while ( dwarf_next_cu_header_d ( dwarf , 1 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 ,
& next_cu_header , 0 , & error ) = = DW_DLV_OK ) {
// Reset the cu header state. Libdwarf's next_cu_header API
// keeps its own iterator per Dwarf_Debug that can't be reset.
// We need to keep fetching elements until the end.
}
}
if ( found )
return cudie ;
// We failed.
return NULL ;
}
} ;
# endif // BACKWARD_HAS_DWARF == 1
template < >
class TraceResolverImpl < system_tag : : linux_tag >
: public TraceResolverLinuxImpl < trace_resolver_tag : : current > { } ;
# endif // BACKWARD_SYSTEM_LINUX
# ifdef BACKWARD_SYSTEM_DARWIN
template < typename STACKTRACE_TAG > class TraceResolverDarwinImpl ;
template < >
class TraceResolverDarwinImpl < trace_resolver_tag : : backtrace_symbol >
: public TraceResolverImplBase {
public :
void load_addresses ( void * const * addresses , int address_count ) override {
if ( address_count = = 0 ) {
return ;
}
_symbols . reset ( backtrace_symbols ( addresses , address_count ) ) ;
}
ResolvedTrace resolve ( ResolvedTrace trace ) override {
// parse:
// <n> <file> <addr> <mangled-name> + <offset>
char * filename = _symbols [ trace . idx ] ;
// skip "<n> "
while ( * filename & & * filename ! = ' ' )
filename + + ;
while ( * filename = = ' ' )
filename + + ;
// find start of <mangled-name> from end (<file> may contain a space)
char * p = filename + strlen ( filename ) - 1 ;
// skip to start of " + <offset>"
while ( p > filename & & * p ! = ' ' )
p - - ;
while ( p > filename & & * p = = ' ' )
p - - ;
while ( p > filename & & * p ! = ' ' )
p - - ;
while ( p > filename & & * p = = ' ' )
p - - ;
char * funcname_end = p + 1 ;
// skip to start of "<manged-name>"
while ( p > filename & & * p ! = ' ' )
p - - ;
char * funcname = p + 1 ;
// skip to start of " <addr> "
while ( p > filename & & * p = = ' ' )
p - - ;
while ( p > filename & & * p ! = ' ' )
p - - ;
while ( p > filename & & * p = = ' ' )
p - - ;
// skip "<file>", handling the case where it contains a
char * filename_end = p + 1 ;
if ( p = = filename ) {
// something went wrong, give up
filename_end = filename + strlen ( filename ) ;
funcname = filename_end ;
}
trace . object_filename . assign (
filename , filename_end ) ; // ok even if filename_end is the ending \0
// (then we assign entire string)
if ( * funcname ) { // if it's not end of string
* funcname_end = ' \0 ' ;
trace . object_function = this - > demangle ( funcname ) ;
trace . object_function + = " " ;
trace . object_function + = ( funcname_end + 1 ) ;
trace . source . function = trace . object_function ; // we cannot do better.
}
return trace ;
}
private :
details : : handle < char * * > _symbols ;
} ;
template < >
class TraceResolverImpl < system_tag : : darwin_tag >
: public TraceResolverDarwinImpl < trace_resolver_tag : : current > { } ;
# endif // BACKWARD_SYSTEM_DARWIN
# ifdef BACKWARD_SYSTEM_WINDOWS
// Load all symbol info
// Based on:
// https://stackoverflow.com/questions/6205981/windows-c-stack-trace-from-a-running-app/28276227#28276227
struct module_data {
std : : string image_name ;
std : : string module_name ;
void * base_address ;
DWORD load_size ;
} ;
class get_mod_info {
HANDLE process ;
static const int buffer_length = 4096 ;
public :
get_mod_info ( HANDLE h ) : process ( h ) { }
module_data operator ( ) ( HMODULE module ) {
module_data ret ;
char temp [ buffer_length ] ;
MODULEINFO mi ;
GetModuleInformation ( process , module , & mi , sizeof ( mi ) ) ;
ret . base_address = mi . lpBaseOfDll ;
ret . load_size = mi . SizeOfImage ;
GetModuleFileNameExA ( process , module , temp , sizeof ( temp ) ) ;
ret . image_name = temp ;
GetModuleBaseNameA ( process , module , temp , sizeof ( temp ) ) ;
ret . module_name = temp ;
std : : vector < char > img ( ret . image_name . begin ( ) , ret . image_name . end ( ) ) ;
std : : vector < char > mod ( ret . module_name . begin ( ) , ret . module_name . end ( ) ) ;
SymLoadModule64 ( process , 0 , & img [ 0 ] , & mod [ 0 ] , ( DWORD64 ) ret . base_address ,
ret . load_size ) ;
return ret ;
}
} ;
template < > class TraceResolverImpl < system_tag : : windows_tag >
: public TraceResolverImplBase {
public :
TraceResolverImpl ( ) {
HANDLE process = GetCurrentProcess ( ) ;
std : : vector < module_data > modules ;
DWORD cbNeeded ;
std : : vector < HMODULE > module_handles ( 1 ) ;
SymInitialize ( process , NULL , false ) ;
DWORD symOptions = SymGetOptions ( ) ;
symOptions | = SYMOPT_LOAD_LINES | SYMOPT_UNDNAME ;
SymSetOptions ( symOptions ) ;
EnumProcessModules ( process , & module_handles [ 0 ] ,
module_handles . size ( ) * sizeof ( HMODULE ) , & cbNeeded ) ;
module_handles . resize ( cbNeeded / sizeof ( HMODULE ) ) ;
EnumProcessModules ( process , & module_handles [ 0 ] ,
module_handles . size ( ) * sizeof ( HMODULE ) , & cbNeeded ) ;
std : : transform ( module_handles . begin ( ) , module_handles . end ( ) ,
std : : back_inserter ( modules ) , get_mod_info ( process ) ) ;
void * base = modules [ 0 ] . base_address ;
IMAGE_NT_HEADERS * h = ImageNtHeader ( base ) ;
image_type = h - > FileHeader . Machine ;
}
static const int max_sym_len = 255 ;
struct symbol_t {
SYMBOL_INFO sym ;
char buffer [ max_sym_len ] ;
} sym ;
DWORD64 displacement ;
ResolvedTrace resolve ( ResolvedTrace t ) override {
HANDLE process = GetCurrentProcess ( ) ;
char name [ 256 ] ;
memset ( & sym , 0 , sizeof ( sym ) ) ;
sym . sym . SizeOfStruct = sizeof ( SYMBOL_INFO ) ;
sym . sym . MaxNameLen = max_sym_len ;
if ( ! SymFromAddr ( process , ( ULONG64 ) t . addr , & displacement , & sym . sym ) ) {
// TODO: error handling everywhere
char * lpMsgBuf ;
DWORD dw = GetLastError ( ) ;
if ( FormatMessageA ( FORMAT_MESSAGE_ALLOCATE_BUFFER |
FORMAT_MESSAGE_FROM_SYSTEM |
FORMAT_MESSAGE_IGNORE_INSERTS ,
NULL , dw , MAKELANGID ( LANG_NEUTRAL , SUBLANG_DEFAULT ) ,
( char * ) & lpMsgBuf , 0 , NULL ) ) {
std : : fprintf ( stderr , " %s \n " , lpMsgBuf ) ;
LocalFree ( lpMsgBuf ) ;
}
// abort();
}
UnDecorateSymbolName ( sym . sym . Name , ( PSTR ) name , 256 , UNDNAME_COMPLETE ) ;
DWORD offset = 0 ;
IMAGEHLP_LINE line ;
if ( SymGetLineFromAddr ( process , ( ULONG64 ) t . addr , & offset , & line ) ) {
t . object_filename = line . FileName ;
t . source . filename = line . FileName ;
t . source . line = line . LineNumber ;
t . source . col = offset ;
}
t . source . function = name ;
t . object_filename = " " ;
t . object_function = name ;
return t ;
}
DWORD machine_type ( ) const { return image_type ; }
private :
DWORD image_type ;
} ;
# endif
class TraceResolver : public TraceResolverImpl < system_tag : : current_tag > { } ;
/*************** CODE SNIPPET ***************/
class SourceFile {
public :
typedef std : : vector < std : : pair < unsigned , std : : string > > lines_t ;
SourceFile ( ) { }
SourceFile ( const std : : string & path ) {
// 1. If BACKWARD_CXX_SOURCE_PREFIXES is set then assume it contains
// a colon-separated list of path prefixes. Try prepending each
// to the given path until a valid file is found.
const std : : vector < std : : string > & prefixes = get_paths_from_env_variable ( ) ;
for ( size_t i = 0 ; i < prefixes . size ( ) ; + + i ) {
// Double slashes (//) should not be a problem.
std : : string new_path = prefixes [ i ] + ' / ' + path ;
_file . reset ( new std : : ifstream ( new_path . c_str ( ) ) ) ;
if ( is_open ( ) )
break ;
}
// 2. If no valid file found then fallback to opening the path as-is.
if ( ! _file | | ! is_open ( ) ) {
_file . reset ( new std : : ifstream ( path . c_str ( ) ) ) ;
}
}
bool is_open ( ) const { return _file - > is_open ( ) ; }
lines_t & get_lines ( unsigned line_start , unsigned line_count , lines_t & lines ) {
using namespace std ;
// This function make uses of the dumbest algo ever:
// 1) seek(0)
// 2) read lines one by one and discard until line_start
// 3) read line one by one until line_start + line_count
//
// If you are getting snippets many time from the same file, it is
// somewhat a waste of CPU, feel free to benchmark and propose a
// better solution ;)
_file - > clear ( ) ;
_file - > seekg ( 0 ) ;
string line ;
unsigned line_idx ;
for ( line_idx = 1 ; line_idx < line_start ; + + line_idx ) {
std : : getline ( * _file , line ) ;
if ( ! * _file ) {
return lines ;
}
}
// think of it like a lambda in C++98 ;)
// but look, I will reuse it two times!
// What a good boy am I.
struct isspace {
bool operator ( ) ( char c ) { return std : : isspace ( c ) ; }
} ;
bool started = false ;
for ( ; line_idx < line_start + line_count ; + + line_idx ) {
getline ( * _file , line ) ;
if ( ! * _file ) {
return lines ;
}
if ( ! started ) {
if ( std : : find_if ( line . begin ( ) , line . end ( ) , not_isspace ( ) ) = = line . end ( ) )
continue ;
started = true ;
}
lines . push_back ( make_pair ( line_idx , line ) ) ;
}
lines . erase (
std : : find_if ( lines . rbegin ( ) , lines . rend ( ) , not_isempty ( ) ) . base ( ) ,
lines . end ( ) ) ;
return lines ;
}
lines_t get_lines ( unsigned line_start , unsigned line_count ) {
lines_t lines ;
return get_lines ( line_start , line_count , lines ) ;
}
// there is no find_if_not in C++98, lets do something crappy to
// workaround.
struct not_isspace {
bool operator ( ) ( char c ) { return ! std : : isspace ( c ) ; }
} ;
// and define this one here because C++98 is not happy with local defined
// struct passed to template functions, fuuuu.
struct not_isempty {
bool operator ( ) ( const lines_t : : value_type & p ) {
return ! ( std : : find_if ( p . second . begin ( ) , p . second . end ( ) , not_isspace ( ) ) = =
p . second . end ( ) ) ;
}
} ;
void swap ( SourceFile & b ) { _file . swap ( b . _file ) ; }
# ifdef BACKWARD_ATLEAST_CXX11
SourceFile ( SourceFile & & from ) : _file ( nullptr ) { swap ( from ) ; }
SourceFile & operator = ( SourceFile & & from ) {
swap ( from ) ;
return * this ;
}
# else
explicit SourceFile ( const SourceFile & from ) {
// some sort of poor man's move semantic.
swap ( const_cast < SourceFile & > ( from ) ) ;
}
SourceFile & operator = ( const SourceFile & from ) {
// some sort of poor man's move semantic.
swap ( const_cast < SourceFile & > ( from ) ) ;
return * this ;
}
# endif
private :
details : : handle < std : : ifstream * , details : : default_delete < std : : ifstream * > >
_file ;
std : : vector < std : : string > get_paths_from_env_variable_impl ( ) {
std : : vector < std : : string > paths ;
const char * prefixes_str = std : : getenv ( " BACKWARD_CXX_SOURCE_PREFIXES " ) ;
if ( prefixes_str & & prefixes_str [ 0 ] ) {
paths = details : : split_source_prefixes ( prefixes_str ) ;
}
return paths ;
}
const std : : vector < std : : string > & get_paths_from_env_variable ( ) {
static std : : vector < std : : string > paths = get_paths_from_env_variable_impl ( ) ;
return paths ;
}
# ifdef BACKWARD_ATLEAST_CXX11
SourceFile ( const SourceFile & ) = delete ;
SourceFile & operator = ( const SourceFile & ) = delete ;
# endif
} ;
class SnippetFactory {
public :
typedef SourceFile : : lines_t lines_t ;
lines_t get_snippet ( const std : : string & filename , unsigned line_start ,
unsigned context_size ) {
SourceFile & src_file = get_src_file ( filename ) ;
unsigned start = line_start - context_size / 2 ;
return src_file . get_lines ( start , context_size ) ;
}
lines_t get_combined_snippet ( const std : : string & filename_a , unsigned line_a ,
const std : : string & filename_b , unsigned line_b ,
unsigned context_size ) {
SourceFile & src_file_a = get_src_file ( filename_a ) ;
SourceFile & src_file_b = get_src_file ( filename_b ) ;
lines_t lines =
src_file_a . get_lines ( line_a - context_size / 4 , context_size / 2 ) ;
src_file_b . get_lines ( line_b - context_size / 4 , context_size / 2 , lines ) ;
return lines ;
}
lines_t get_coalesced_snippet ( const std : : string & filename , unsigned line_a ,
unsigned line_b , unsigned context_size ) {
SourceFile & src_file = get_src_file ( filename ) ;
using std : : max ;
using std : : min ;
unsigned a = min ( line_a , line_b ) ;
unsigned b = max ( line_a , line_b ) ;
if ( ( b - a ) < ( context_size / 3 ) ) {
return src_file . get_lines ( ( a + b - context_size + 1 ) / 2 , context_size ) ;
}
lines_t lines = src_file . get_lines ( a - context_size / 4 , context_size / 2 ) ;
src_file . get_lines ( b - context_size / 4 , context_size / 2 , lines ) ;
return lines ;
}
private :
typedef details : : hashtable < std : : string , SourceFile > : : type src_files_t ;
src_files_t _src_files ;
SourceFile & get_src_file ( const std : : string & filename ) {
src_files_t : : iterator it = _src_files . find ( filename ) ;
if ( it ! = _src_files . end ( ) ) {
return it - > second ;
}
SourceFile & new_src_file = _src_files [ filename ] ;
new_src_file = SourceFile ( filename ) ;
return new_src_file ;
}
} ;
/*************** PRINTER ***************/
namespace ColorMode {
enum type { automatic , never , always } ;
}
class cfile_streambuf : public std : : streambuf {
public :
cfile_streambuf ( FILE * _sink ) : sink ( _sink ) { }
int_type underflow ( ) override { return traits_type : : eof ( ) ; }
int_type overflow ( int_type ch ) override {
if ( traits_type : : not_eof ( ch ) & & fputc ( ch , sink ) ! = EOF ) {
return ch ;
}
return traits_type : : eof ( ) ;
}
std : : streamsize xsputn ( const char_type * s , std : : streamsize count ) override {
return static_cast < std : : streamsize > (
fwrite ( s , sizeof * s , static_cast < size_t > ( count ) , sink ) ) ;
}
# ifdef BACKWARD_ATLEAST_CXX11
public :
cfile_streambuf ( const cfile_streambuf & ) = delete ;
cfile_streambuf & operator = ( const cfile_streambuf & ) = delete ;
# else
private :
cfile_streambuf ( const cfile_streambuf & ) ;
cfile_streambuf & operator = ( const cfile_streambuf & ) ;
# endif
private :
FILE * sink ;
std : : vector < char > buffer ;
} ;
# ifdef BACKWARD_SYSTEM_LINUX
namespace Color {
enum type { yellow = 33 , purple = 35 , reset = 39 } ;
} // namespace Color
class Colorize {
public :
Colorize ( std : : ostream & os ) : _os ( os ) , _reset ( false ) , _enabled ( false ) { }
void activate ( ColorMode : : type mode ) { _enabled = mode = = ColorMode : : always ; }
void activate ( ColorMode : : type mode , FILE * fp ) { activate ( mode , fileno ( fp ) ) ; }
void set_color ( Color : : type ccode ) {
if ( ! _enabled )
return ;
// I assume that the terminal can handle basic colors. Seriously I
// don't want to deal with all the termcap shit.
_os < < " \033 [ " < < static_cast < int > ( ccode ) < < " m " ;
_reset = ( ccode ! = Color : : reset ) ;
}
~ Colorize ( ) {
if ( _reset ) {
set_color ( Color : : reset ) ;
}
}
private :
void activate ( ColorMode : : type mode , int fd ) {
activate ( mode = = ColorMode : : automatic & & isatty ( fd ) ? ColorMode : : always
: mode ) ;
}
std : : ostream & _os ;
bool _reset ;
bool _enabled ;
} ;
# else // ndef BACKWARD_SYSTEM_LINUX
namespace Color {
enum type { yellow = 0 , purple = 0 , reset = 0 } ;
} // namespace Color
class Colorize {
public :
Colorize ( std : : ostream & ) { }
void activate ( ColorMode : : type ) { }
void activate ( ColorMode : : type , FILE * ) { }
void set_color ( Color : : type ) { }
} ;
# endif // BACKWARD_SYSTEM_LINUX
class Printer {
public :
bool snippet ;
ColorMode : : type color_mode ;
bool address ;
bool object ;
int inliner_context_size ;
int trace_context_size ;
Printer ( )
: snippet ( true ) , color_mode ( ColorMode : : automatic ) , address ( false ) ,
object ( false ) , inliner_context_size ( 5 ) , trace_context_size ( 7 ) { }
template < typename ST > FILE * print ( ST & st , FILE * fp = stderr ) {
cfile_streambuf obuf ( fp ) ;
std : : ostream os ( & obuf ) ;
Colorize colorize ( os ) ;
colorize . activate ( color_mode , fp ) ;
print_stacktrace ( st , os , colorize ) ;
return fp ;
}
template < typename ST > std : : ostream & print ( ST & st , std : : ostream & os ) {
Colorize colorize ( os ) ;
colorize . activate ( color_mode ) ;
print_stacktrace ( st , os , colorize ) ;
return os ;
}
template < typename IT >
FILE * print ( IT begin , IT end , FILE * fp = stderr , size_t thread_id = 0 ) {
cfile_streambuf obuf ( fp ) ;
std : : ostream os ( & obuf ) ;
Colorize colorize ( os ) ;
colorize . activate ( color_mode , fp ) ;
print_stacktrace ( begin , end , os , thread_id , colorize ) ;
return fp ;
}
template < typename IT >
std : : ostream & print ( IT begin , IT end , std : : ostream & os ,
size_t thread_id = 0 ) {
Colorize colorize ( os ) ;
colorize . activate ( color_mode ) ;
print_stacktrace ( begin , end , os , thread_id , colorize ) ;
return os ;
}
TraceResolver const & resolver ( ) const { return _resolver ; }
private :
TraceResolver _resolver ;
SnippetFactory _snippets ;
template < typename ST >
void print_stacktrace ( ST & st , std : : ostream & os , Colorize & colorize ) {
print_header ( os , st . thread_id ( ) ) ;
_resolver . load_stacktrace ( st ) ;
for ( size_t trace_idx = st . size ( ) ; trace_idx > 0 ; - - trace_idx ) {
print_trace ( os , _resolver . resolve ( st [ trace_idx - 1 ] ) , colorize ) ;
}
}
template < typename IT >
void print_stacktrace ( IT begin , IT end , std : : ostream & os , size_t thread_id ,
Colorize & colorize ) {
print_header ( os , thread_id ) ;
for ( ; begin ! = end ; + + begin ) {
print_trace ( os , * begin , colorize ) ;
}
}
void print_header ( std : : ostream & os , size_t thread_id ) {
os < < " Stack trace (most recent call last) " ;
if ( thread_id ) {
os < < " in thread " < < thread_id ;
}
os < < " : \n " ;
}
void print_trace ( std : : ostream & os , const ResolvedTrace & trace ,
Colorize & colorize ) {
os < < " # " < < std : : left < < std : : setw ( 2 ) < < trace . idx < < std : : right ;
bool already_indented = true ;
if ( ! trace . source . filename . size ( ) | | object ) {
os < < " Object \" " < < trace . object_filename < < " \" , at " < < trace . addr
< < " , in " < < trace . object_function < < " \n " ;
already_indented = false ;
}
for ( size_t inliner_idx = trace . inliners . size ( ) ; inliner_idx > 0 ;
- - inliner_idx ) {
if ( ! already_indented ) {
os < < " " ;
}
const ResolvedTrace : : SourceLoc & inliner_loc =
trace . inliners [ inliner_idx - 1 ] ;
print_source_loc ( os , " | " , inliner_loc ) ;
if ( snippet ) {
print_snippet ( os , " | " , inliner_loc , colorize , Color : : purple ,
inliner_context_size ) ;
}
already_indented = false ;
}
if ( trace . source . filename . size ( ) ) {
if ( ! already_indented ) {
os < < " " ;
}
print_source_loc ( os , " " , trace . source , trace . addr ) ;
if ( snippet ) {
print_snippet ( os , " " , trace . source , colorize , Color : : yellow ,
trace_context_size ) ;
}
}
}
void print_snippet ( std : : ostream & os , const char * indent ,
const ResolvedTrace : : SourceLoc & source_loc ,
Colorize & colorize , Color : : type color_code ,
int context_size ) {
using namespace std ;
typedef SnippetFactory : : lines_t lines_t ;
lines_t lines = _snippets . get_snippet ( source_loc . filename , source_loc . line ,
static_cast < unsigned > ( context_size ) ) ;
for ( lines_t : : const_iterator it = lines . begin ( ) ; it ! = lines . end ( ) ; + + it ) {
if ( it - > first = = source_loc . line ) {
colorize . set_color ( color_code ) ;
os < < indent < < " > " ;
} else {
os < < indent < < " " ;
}
os < < std : : setw ( 4 ) < < it - > first < < " : " < < it - > second < < " \n " ;
if ( it - > first = = source_loc . line ) {
colorize . set_color ( Color : : reset ) ;
}
}
}
void print_source_loc ( std : : ostream & os , const char * indent ,
const ResolvedTrace : : SourceLoc & source_loc ,
void * addr = nullptr ) {
os < < indent < < " Source \" " < < source_loc . filename < < " \" , line "
< < source_loc . line < < " , in " < < source_loc . function ;
if ( address & & addr ! = nullptr ) {
os < < " [ " < < addr < < " ] " ;
}
os < < " \n " ;
}
} ;
/*************** SIGNALS HANDLING ***************/
# if defined(BACKWARD_SYSTEM_LINUX) || defined(BACKWARD_SYSTEM_DARWIN)
class SignalHandling {
public :
static std : : vector < int > make_default_signals ( ) {
const int posix_signals [ ] = {
// Signals for which the default action is "Core".
SIGABRT , // Abort signal from abort(3)
SIGBUS , // Bus error (bad memory access)
SIGFPE , // Floating point exception
SIGILL , // Illegal Instruction
SIGIOT , // IOT trap. A synonym for SIGABRT
SIGQUIT , // Quit from keyboard
SIGSEGV , // Invalid memory reference
SIGSYS , // Bad argument to routine (SVr4)
SIGTRAP , // Trace/breakpoint trap
SIGXCPU , // CPU time limit exceeded (4.2BSD)
SIGXFSZ , // File size limit exceeded (4.2BSD)
# if defined(BACKWARD_SYSTEM_DARWIN)
SIGEMT , // emulation instruction executed
# endif
} ;
return std : : vector < int > ( posix_signals ,
posix_signals +
sizeof posix_signals / sizeof posix_signals [ 0 ] ) ;
}
SignalHandling ( const std : : vector < int > & posix_signals = make_default_signals ( ) )
: _loaded ( false ) {
bool success = true ;
const size_t stack_size = 1024 * 1024 * 8 ;
_stack_content . reset ( static_cast < char * > ( malloc ( stack_size ) ) ) ;
if ( _stack_content ) {
stack_t ss ;
ss . ss_sp = _stack_content . get ( ) ;
ss . ss_size = stack_size ;
ss . ss_flags = 0 ;
if ( sigaltstack ( & ss , nullptr ) < 0 ) {
success = false ;
}
} else {
success = false ;
}
for ( size_t i = 0 ; i < posix_signals . size ( ) ; + + i ) {
struct sigaction action ;
memset ( & action , 0 , sizeof action ) ;
action . sa_flags =
static_cast < int > ( SA_SIGINFO | SA_ONSTACK | SA_NODEFER | SA_RESETHAND ) ;
sigfillset ( & action . sa_mask ) ;
sigdelset ( & action . sa_mask , posix_signals [ i ] ) ;
# if defined(__clang__)
# pragma clang diagnostic push
# pragma clang diagnostic ignored "-Wdisabled-macro-expansion"
# endif
action . sa_sigaction = & sig_handler ;
# if defined(__clang__)
# pragma clang diagnostic pop
# endif
int r = sigaction ( posix_signals [ i ] , & action , nullptr ) ;
if ( r < 0 )
success = false ;
}
_loaded = success ;
}
bool loaded ( ) const { return _loaded ; }
static void handleSignal ( int , siginfo_t * info , void * _ctx ) {
ucontext_t * uctx = static_cast < ucontext_t * > ( _ctx ) ;
StackTrace st ;
void * error_addr = nullptr ;
# ifdef REG_RIP // x86_64
error_addr = reinterpret_cast < void * > ( uctx - > uc_mcontext . gregs [ REG_RIP ] ) ;
# elif defined(REG_EIP) // x86_32
error_addr = reinterpret_cast < void * > ( uctx - > uc_mcontext . gregs [ REG_EIP ] ) ;
# elif defined(__arm__)
error_addr = reinterpret_cast < void * > ( uctx - > uc_mcontext . arm_pc ) ;
# elif defined(__aarch64__)
# if defined(__APPLE__)
error_addr = reinterpret_cast < void * > ( uctx - > uc_mcontext - > __ss . __pc ) ;
# else
error_addr = reinterpret_cast < void * > ( uctx - > uc_mcontext . pc ) ;
# endif
# elif defined(__mips__)
error_addr = reinterpret_cast < void * > (
reinterpret_cast < struct sigcontext * > ( & uctx - > uc_mcontext ) - > sc_pc ) ;
# elif defined(__ppc__) || defined(__powerpc) || defined(__powerpc__) || \
defined ( __POWERPC__ )
error_addr = reinterpret_cast < void * > ( uctx - > uc_mcontext . regs - > nip ) ;
# elif defined(__riscv)
error_addr = reinterpret_cast < void * > ( uctx - > uc_mcontext . __gregs [ REG_PC ] ) ;
# elif defined(__s390x__)
error_addr = reinterpret_cast < void * > ( uctx - > uc_mcontext . psw . addr ) ;
# elif defined(__APPLE__) && defined(__x86_64__)
error_addr = reinterpret_cast < void * > ( uctx - > uc_mcontext - > __ss . __rip ) ;
# elif defined(__APPLE__)
error_addr = reinterpret_cast < void * > ( uctx - > uc_mcontext - > __ss . __eip ) ;
# else
# warning ": / sorry, ain't know no nothing none not of your architecture!"
# endif
if ( error_addr ) {
st . load_from ( error_addr , 32 , reinterpret_cast < void * > ( uctx ) ,
info - > si_addr ) ;
} else {
st . load_here ( 32 , reinterpret_cast < void * > ( uctx ) , info - > si_addr ) ;
}
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# ifdef _WIN32
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MessageBox ( NULL , " Error " , " Furnace has crashed! please report this to the issue tracker immediately: \r \n https://github.com/tildearrow/furnace/issues/new \r \n \r \n a file called furnace_crash.txt will be created in your user directory. \r \n this will be important for locating the origin of the crash. " , MB_OK | MB_ICONERROR ) ;
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std : : string crashLocation ;
char * userProfile = getenv ( " USERPROFILE " ) ;
if ( userProfile = = NULL ) {
crashLocation = " C: \\ furnace_crash.txt " ;
} else {
crashLocation = userProfile ;
crashLocation + = " \\ furnace_crash.txt " ;
}
FILE * crashDump = fopen ( crashLocation . c_str ( ) , " w " ) ;
# else
FILE * crashDump = fopen ( " /tmp/furnace_crash.txt " , " w " ) ;
# endif
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Printer printer ;
printer . address = true ;
printer . print ( st , stderr ) ;
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if ( crashDump ! = NULL ) {
Printer printer ;
printer . address = true ;
printer . print ( st , crashDump ) ;
fclose ( crashDump ) ;
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} else {
# ifdef _WIN32
std : : string str ;
Printer failedPrinter ;
failedPrinter . address = true ;
failedPrinter . print ( st , str ) ;
str + = " \r \n could not open furnace_crash.txt! \r \n please take a screenshot of this error message box! " ;
fprintf ( stderr , " NOTICE: could not open furnace_crash.txt! \n " ) ;
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MessageBox ( NULL , " Error " , str . c_str ( ) , MB_OK | MB_ICONERROR ) ;
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# endif
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}
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# if (defined(_XOPEN_SOURCE) && _XOPEN_SOURCE >= 700) || \
( defined ( _POSIX_C_SOURCE ) & & _POSIX_C_SOURCE > = 200809L )
psiginfo ( info , nullptr ) ;
# else
( void ) info ;
# endif
}
private :
details : : handle < char * > _stack_content ;
bool _loaded ;
# ifdef __GNUC__
__attribute__ ( ( noreturn ) )
# endif
static void
sig_handler ( int signo , siginfo_t * info , void * _ctx ) {
handleSignal ( signo , info , _ctx ) ;
// try to forward the signal.
raise ( info - > si_signo ) ;
// terminate the process immediately.
puts ( " watf? exit " ) ;
_exit ( EXIT_FAILURE ) ;
}
} ;
# endif // BACKWARD_SYSTEM_LINUX || BACKWARD_SYSTEM_DARWIN
# ifdef BACKWARD_SYSTEM_WINDOWS
class SignalHandling {
public :
SignalHandling ( const std : : vector < int > & = std : : vector < int > ( ) )
: reporter_thread_ ( [ ] ( ) {
/* We handle crashes in a utility thread:
backward structures and some Windows functions called here
need stack space , which we do not have when we encounter a
stack overflow .
To support reporting stack traces during a stack overflow ,
we create a utility thread at startup , which waits until a
crash happens or the program exits normally . */
{
std : : unique_lock < std : : mutex > lk ( mtx ( ) ) ;
cv ( ) . wait ( lk , [ ] { return crashed ( ) ! = crash_status : : running ; } ) ;
}
if ( crashed ( ) = = crash_status : : crashed ) {
handle_stacktrace ( skip_recs ( ) ) ;
}
{
std : : unique_lock < std : : mutex > lk ( mtx ( ) ) ;
crashed ( ) = crash_status : : ending ;
}
cv ( ) . notify_one ( ) ;
} ) {
SetUnhandledExceptionFilter ( crash_handler ) ;
signal ( SIGABRT , signal_handler ) ;
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# ifdef _MSC_VER
// TODO: fix for MinGW
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_set_abort_behavior ( 0 , _WRITE_ABORT_MSG | _CALL_REPORTFAULT ) ;
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# endif
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std : : set_terminate ( & terminator ) ;
# ifndef BACKWARD_ATLEAST_CXX17
std : : set_unexpected ( & terminator ) ;
# endif
_set_purecall_handler ( & terminator ) ;
_set_invalid_parameter_handler ( & invalid_parameter_handler ) ;
}
bool loaded ( ) const { return true ; }
~ SignalHandling ( ) {
{
std : : unique_lock < std : : mutex > lk ( mtx ( ) ) ;
crashed ( ) = crash_status : : normal_exit ;
}
cv ( ) . notify_one ( ) ;
reporter_thread_ . join ( ) ;
}
private :
static CONTEXT * ctx ( ) {
static CONTEXT data ;
return & data ;
}
enum class crash_status { running , crashed , normal_exit , ending } ;
static crash_status & crashed ( ) {
static crash_status data ;
return data ;
}
static std : : mutex & mtx ( ) {
static std : : mutex data ;
return data ;
}
static std : : condition_variable & cv ( ) {
static std : : condition_variable data ;
return data ;
}
static HANDLE & thread_handle ( ) {
static HANDLE handle ;
return handle ;
}
std : : thread reporter_thread_ ;
// TODO: how not to hardcode these?
static const constexpr int signal_skip_recs =
# ifdef __clang__
// With clang, RtlCaptureContext also captures the stack frame of the
// current function Below that, there ar 3 internal Windows functions
4
# else
// With MSVC cl, RtlCaptureContext misses the stack frame of the current
// function The first entries during StackWalk are the 3 internal Windows
// functions
3
# endif
;
static int & skip_recs ( ) {
static int data ;
return data ;
}
static inline void terminator ( ) {
crash_handler ( signal_skip_recs ) ;
abort ( ) ;
}
static inline void signal_handler ( int ) {
crash_handler ( signal_skip_recs ) ;
abort ( ) ;
}
static inline void __cdecl invalid_parameter_handler ( const wchar_t * ,
const wchar_t * ,
const wchar_t * ,
unsigned int ,
uintptr_t ) {
crash_handler ( signal_skip_recs ) ;
abort ( ) ;
}
NOINLINE static LONG WINAPI crash_handler ( EXCEPTION_POINTERS * info ) {
// The exception info supplies a trace from exactly where the issue was,
// no need to skip records
crash_handler ( 0 , info - > ContextRecord ) ;
return EXCEPTION_CONTINUE_SEARCH ;
}
NOINLINE static void crash_handler ( int skip , CONTEXT * ct = nullptr ) {
if ( ct = = nullptr ) {
RtlCaptureContext ( ctx ( ) ) ;
} else {
memcpy ( ctx ( ) , ct , sizeof ( CONTEXT ) ) ;
}
DuplicateHandle ( GetCurrentProcess ( ) , GetCurrentThread ( ) ,
GetCurrentProcess ( ) , & thread_handle ( ) , 0 , FALSE ,
DUPLICATE_SAME_ACCESS ) ;
skip_recs ( ) = skip ;
{
std : : unique_lock < std : : mutex > lk ( mtx ( ) ) ;
crashed ( ) = crash_status : : crashed ;
}
cv ( ) . notify_one ( ) ;
{
std : : unique_lock < std : : mutex > lk ( mtx ( ) ) ;
cv ( ) . wait ( lk , [ ] { return crashed ( ) ! = crash_status : : crashed ; } ) ;
}
}
static void handle_stacktrace ( int skip_frames = 0 ) {
// printer creates the TraceResolver, which can supply us a machine type
// for stack walking. Without this, StackTrace can only guess using some
// macros.
// StackTrace also requires that the PDBs are already loaded, which is done
// in the constructor of TraceResolver
Printer printer ;
StackTrace st ;
st . set_machine_type ( printer . resolver ( ) . machine_type ( ) ) ;
st . set_thread_handle ( thread_handle ( ) ) ;
st . load_here ( 32 + skip_frames , ctx ( ) ) ;
st . skip_n_firsts ( skip_frames ) ;
printer . address = true ;
printer . print ( st , std : : cerr ) ;
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# ifdef _WIN32
MessageBox ( NULL , " Furnace has crashed! please report this to the issue tracker immediately: \r \n https://github.com/tildearrow/furnace/issues/new \r \n \r \n a file called furnace_crash.txt will be created in your user directory. \r \n this will be important for locating the origin of the crash. " , " Error " , MB_OK | MB_ICONERROR ) ;
std : : string crashLocation ;
char * userProfile = getenv ( " USERPROFILE " ) ;
if ( userProfile = = NULL ) {
crashLocation = " furnace_crash.txt " ;
} else {
crashLocation = userProfile ;
crashLocation + = " \\ furnace_crash.txt " ;
}
FILE * crashDump = fopen ( crashLocation . c_str ( ) , " w " ) ;
# else
FILE * crashDump = fopen ( " /tmp/furnace_crash.txt " , " w " ) ;
# endif
if ( crashDump ! = NULL ) {
Printer printer ;
printer . address = true ;
printer . print ( st , crashDump ) ;
fclose ( crashDump ) ;
} else {
# ifdef _WIN32
std : : string str ;
//Printer failedPrinter;
//failedPrinter.address = true;
//failedPrinter.print(st, str);
str + = " \r \n could not open furnace_crash.txt! \r \n please take a screenshot of this error message box! " ;
fprintf ( stderr , " NOTICE: could not open furnace_crash.txt! \n " ) ;
MessageBox ( NULL , str . c_str ( ) , " Error " , MB_OK | MB_ICONERROR ) ;
# endif
}
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}
} ;
# endif // BACKWARD_SYSTEM_WINDOWS
# ifdef BACKWARD_SYSTEM_UNKNOWN
class SignalHandling {
public :
SignalHandling ( const std : : vector < int > & = std : : vector < int > ( ) ) { }
bool init ( ) { return false ; }
bool loaded ( ) { return false ; }
} ;
# endif // BACKWARD_SYSTEM_UNKNOWN
} // namespace backward
# endif /* H_GUARD */