gcc-4.4.0/libstdc++-v3/doc/xml/manual/debug.xml - toolchain/gcc - Git at Google

 <sect1 id="manual.intro.using.debug" xreflabel="Debugging Support">
 <?dbhtml filename="debug.html"?>

 <sect1info>
   <keywordset>
     <keyword>
       C++
     </keyword>
     <keyword>
       debug
     </keyword>
   </keywordset>
 </sect1info>

 <title>Debugging Support</title>

 <para>
   There are numerous things that can be done to improve the ease with
   which C++ binaries are debugged when using the GNU tool chain. Here
   are some of them.
 </para>

 <sect2 id="debug.compiler" xreflabel="debug.compiler">
 <title>Using <command>g++</command></title>
   <para>
     Compiler flags determine how debug information is transmitted
     between compilation and debug or analysis tools.
   </para>

   <para>
     The default optimizations and debug flags for a libstdc++ build
     are <code>-g -O2</code>. However, both debug and optimization
     flags can be varied to change debugging characteristics. For
     instance, turning off all optimization via the <code>-g -O0
     -fno-inline</code> flags will disable inlining and optimizations,
     and add debugging information, so that stepping through all functions,
     (including inlined constructors and destructors) is possible. In
     addition, <code>-fno-eliminate-unused-debug-types</code> can be
     used when additional debug information, such as nested class info,
     is desired.
 </para>

 <para>
   Or, the debug format that the compiler and debugger use to
   communicate information about source constructs can be changed via
   <code>-gdwarf-2</code> or <code>-gstabs</code> flags: some debugging
   formats permit more expressive type and scope information to be
   shown in gdb. Expressiveness can be enhanced by flags like
   <code>-g3</code>. The default debug information for a particular
   platform can be identified via the value set by the
   PREFERRED_DEBUGGING_TYPE macro in the gcc sources.
 </para>

 <para>
   Many other options are available: please see <ulink
   url="http://gcc.gnu.org/onlinedocs/gcc/Debugging-Options.html#Debugging%20Options">"Options
   for Debugging Your Program"</ulink> in Using the GNU Compiler
   Collection (GCC) for a complete list.
 </para>
 </sect2>

 <sect2 id="debug.req" xreflabel="debug.req">
 <title>Debug Versions of Library Binary Files</title>

 <para>
   If you would like debug symbols in libstdc++, there are two ways to
   build libstdc++ with debug flags. The first is to run make from the
   toplevel in a freshly-configured tree with
 </para>
 <programlisting>
      --enable-libstdcxx-debug
 </programlisting>
 <para>and perhaps</para>
 <programlisting>
      --enable-libstdcxx-debug-flags='...'
 </programlisting>
 <para>
   to create a separate debug build. Both the normal build and the
   debug build will persist, without having to specify
   <code>CXXFLAGS</code>, and the debug library will be installed in a
   separate directory tree, in <code>(prefix)/lib/debug</code>. For
   more information, look at the <link
   linkend="manual.intro.setup.configure">configuration</link> section.
 </para>

 <para>
   A second approach is to use the configuration flags
 </para>
 <programlisting>
      make CXXFLAGS='-g3 -fno-inline -O0' all
 </programlisting>

 <para>
   This quick and dirty approach is often sufficient for quick
   debugging tasks, when you cannot or don't want to recompile your
   application to use the <link linkend="manual.ext.debug_mode">debug mode</link>.</para>
 </sect2>

 <sect2 id="debug.memory" xreflabel="debug.memory">
 <title>Memory Leak Hunting</title>

 <para>
   There are various third party memory tracing and debug utilities
   that can be used to provide detailed memory allocation information
   about C++ code. An exhaustive list of tools is not going to be
   attempted, but includes <code>mtrace</code>, <code>valgrind</code>,
   <code>mudflap</code>, and the non-free commercial product
   <code>purify</code>. In addition, <code>libcwd</code> has a
   replacement for the global new and delete operators that can track
   memory allocation and deallocation and provide useful memory
   statistics.
 </para>

 <para>
   Regardless of the memory debugging tool being used, there is one
   thing of great importance to keep in mind when debugging C++ code
   that uses <code>new</code> and <code>delete</code>: there are
   different kinds of allocation schemes that can be used by <code>
   std::allocator </code>. For implementation details, see the <link
   linkend="manual.ext.allocator.mt">mt allocator</link> documentation and
   look specifically for <code>GLIBCXX_FORCE_NEW</code>.
 </para>

 <para>
   In a nutshell, the default allocator used by <code>
   std::allocator</code> is a high-performance pool allocator, and can
   give the mistaken impression that in a suspect executable, memory is
   being leaked, when in reality the memory "leak" is a pool being used
   by the library's allocator and is reclaimed after program
   termination.
 </para>

 <para>
   For valgrind, there are some specific items to keep in mind. First
   of all, use a version of valgrind that will work with current GNU
   C++ tools: the first that can do this is valgrind 1.0.4, but later
   versions should work at least as well. Second of all, use a
   completely unoptimized build to avoid confusing valgrind. Third, use
   GLIBCXX_FORCE_NEW to keep extraneous pool allocation noise from
   cluttering debug information.
 </para>

 <para>
   Fourth, it may be necessary to force deallocation in other libraries
   as well, namely the "C" library. On linux, this can be accomplished
   with the appropriate use of the <code>__cxa_atexit</code> or
   <code>atexit</code> functions.
 </para>

 <programlisting>
    #include &lt;cstdlib&gt;

    extern "C" void __libc_freeres(void);

    void do_something() { }

    int main()
    {
      atexit(__libc_freeres);
      do_something();
      return 0;
    }
 </programlisting>


 <para>or, using <code>__cxa_atexit</code>:</para>

 <programlisting>
    extern "C" void __libc_freeres(void);
    extern "C" int __cxa_atexit(void (*func) (void *), void *arg, void *d);

    void do_something() { }

    int main()
    {
       extern void* __dso_handle __attribute__ ((__weak__));
       __cxa_atexit((void (*) (void *)) __libc_freeres, NULL,
                    &amp;__dso_handle ? __dso_handle : NULL);
       do_test();
       return 0;
    }
 </programlisting>

 <para>
   Suggested valgrind flags, given the suggestions above about setting
   up the runtime environment, library, and test file, might be:
 </para>
 <programlisting>
    valgrind -v --num-callers=20 --leak-check=yes --leak-resolution=high --show-reachable=yes a.out
 </programlisting>

 </sect2>

 <sect2 id="debug.gdb" xreflabel="debug.gdb">
 <title>Using <command>gdb</command></title>
   <para>
   </para>

 <para>
   Many options are available for gdb itself: please see <ulink
   url="http://sources.redhat.com/gdb/current/onlinedocs/gdb_13.html#SEC125">
   "GDB features for C++" </ulink> in the gdb documentation. Also
   recommended: the other parts of this manual.
 </para>

 <para>
   These settings can either be switched on in at the gdb command line,
   or put into a .gdbint file to establish default debugging
   characteristics, like so:
 </para>

 <programlisting>
    set print pretty on
    set print object on
    set print static-members on
    set print vtbl on
    set print demangle on
    set demangle-style gnu-v3
 </programlisting>
 </sect2>

 <sect2 id="debug.exceptions" xreflabel="debug.exceptions">
 <title>Tracking uncaught exceptions</title>
 <para>
   The <link linkend="support.termination.verbose">verbose
   termination handler</link> gives information about uncaught
   exceptions which are killing the program.  It is described in the
   linked-to page.
 </para>
 </sect2>

 <sect2 id="debug.debug_mode" xreflabel="debug.debug_mode">
 <title>Debug Mode</title>
   <para> The <link linkend="manual.ext.debug_mode">Debug Mode</link>
   has compile and run-time checks for many containers.
   </para>
 </sect2>

 <sect2 id="debug.compile_time_checks" xreflabel="debug.compile_time_checks">
 <title>Compile Time Checking</title>
   <para> The <link linkend="manual.ext.compile_checks">Compile-Time
   Checks</link> Extension has compile-time checks for many algorithms.
   </para>
 </sect2>

 </sect1>
	<sect1 id="manual.intro.using.debug" xreflabel="Debugging Support">
	<?dbhtml filename="debug.html"?>

	<sect1info>
	<keywordset>
	<keyword>
	C++
	</keyword>
	<keyword>
	debug
	</keyword>
	</keywordset>
	</sect1info>

	<title>Debugging Support</title>

	<para>
	There are numerous things that can be done to improve the ease with
	which C++ binaries are debugged when using the GNU tool chain. Here
	are some of them.
	</para>

	<sect2 id="debug.compiler" xreflabel="debug.compiler">
	<title>Using <command>g++</command></title>
	<para>
	Compiler flags determine how debug information is transmitted
	between compilation and debug or analysis tools.
	</para>

	<para>
	The default optimizations and debug flags for a libstdc++ build
	are <code>-g -O2</code>. However, both debug and optimization
	flags can be varied to change debugging characteristics. For
	instance, turning off all optimization via the <code>-g -O0
	-fno-inline</code> flags will disable inlining and optimizations,
	and add debugging information, so that stepping through all functions,
	(including inlined constructors and destructors) is possible. In
	addition, <code>-fno-eliminate-unused-debug-types</code> can be
	used when additional debug information, such as nested class info,
	is desired.
	</para>

	<para>
	Or, the debug format that the compiler and debugger use to
	communicate information about source constructs can be changed via
	<code>-gdwarf-2</code> or <code>-gstabs</code> flags: some debugging
	formats permit more expressive type and scope information to be
	shown in gdb. Expressiveness can be enhanced by flags like
	<code>-g3</code>. The default debug information for a particular
	platform can be identified via the value set by the
	PREFERRED_DEBUGGING_TYPE macro in the gcc sources.
	</para>

	<para>
	Many other options are available: please see <ulink
	url="http://gcc.gnu.org/onlinedocs/gcc/Debugging-Options.html#Debugging%20Options">"Options
	for Debugging Your Program"</ulink> in Using the GNU Compiler
	Collection (GCC) for a complete list.
	</para>
	</sect2>

	<sect2 id="debug.req" xreflabel="debug.req">
	<title>Debug Versions of Library Binary Files</title>

	<para>
	If you would like debug symbols in libstdc++, there are two ways to
	build libstdc++ with debug flags. The first is to run make from the
	toplevel in a freshly-configured tree with
	</para>
	<programlisting>
	--enable-libstdcxx-debug
	</programlisting>
	<para>and perhaps</para>
	<programlisting>
	--enable-libstdcxx-debug-flags='...'
	</programlisting>
	<para>
	to create a separate debug build. Both the normal build and the
	debug build will persist, without having to specify
	<code>CXXFLAGS</code>, and the debug library will be installed in a
	separate directory tree, in <code>(prefix)/lib/debug</code>. For
	more information, look at the <link
	linkend="manual.intro.setup.configure">configuration</link> section.
	</para>

	<para>
	A second approach is to use the configuration flags
	</para>
	<programlisting>
	make CXXFLAGS='-g3 -fno-inline -O0' all
	</programlisting>

	<para>
	This quick and dirty approach is often sufficient for quick
	debugging tasks, when you cannot or don't want to recompile your
	application to use the <link linkend="manual.ext.debug_mode">debug mode</link>.</para>
	</sect2>

	<sect2 id="debug.memory" xreflabel="debug.memory">
	<title>Memory Leak Hunting</title>

	<para>
	There are various third party memory tracing and debug utilities
	that can be used to provide detailed memory allocation information
	about C++ code. An exhaustive list of tools is not going to be
	attempted, but includes <code>mtrace</code>, <code>valgrind</code>,
	<code>mudflap</code>, and the non-free commercial product
	<code>purify</code>. In addition, <code>libcwd</code> has a
	replacement for the global new and delete operators that can track
	memory allocation and deallocation and provide useful memory
	statistics.
	</para>

	<para>
	Regardless of the memory debugging tool being used, there is one
	thing of great importance to keep in mind when debugging C++ code
	that uses <code>new</code> and <code>delete</code>: there are
	different kinds of allocation schemes that can be used by <code>
	std::allocator </code>. For implementation details, see the <link
	linkend="manual.ext.allocator.mt">mt allocator</link> documentation and
	look specifically for <code>GLIBCXX_FORCE_NEW</code>.
	</para>

	<para>
	In a nutshell, the default allocator used by <code>
	std::allocator</code> is a high-performance pool allocator, and can
	give the mistaken impression that in a suspect executable, memory is
	being leaked, when in reality the memory "leak" is a pool being used
	by the library's allocator and is reclaimed after program
	termination.
	</para>

	<para>
	For valgrind, there are some specific items to keep in mind. First
	of all, use a version of valgrind that will work with current GNU
	C++ tools: the first that can do this is valgrind 1.0.4, but later
	versions should work at least as well. Second of all, use a
	completely unoptimized build to avoid confusing valgrind. Third, use
	GLIBCXX_FORCE_NEW to keep extraneous pool allocation noise from
	cluttering debug information.
	</para>

	<para>
	Fourth, it may be necessary to force deallocation in other libraries
	as well, namely the "C" library. On linux, this can be accomplished
	with the appropriate use of the <code>__cxa_atexit</code> or
	<code>atexit</code> functions.
	</para>

	<programlisting>
	#include <cstdlib>

	extern "C" void __libc_freeres(void);

	void do_something() { }

	int main()
	{
	atexit(__libc_freeres);
	do_something();
	return 0;
	}
	</programlisting>


	<para>or, using <code>__cxa_atexit</code>:</para>

	<programlisting>
	extern "C" void __libc_freeres(void);
	extern "C" int __cxa_atexit(void (func) (void ), void arg, void d);

	void do_something() { }

	int main()
	{
	extern void* __dso_handle __attribute__ ((__weak__));
	__cxa_atexit((void () (void )) __libc_freeres, NULL,
	&__dso_handle ? __dso_handle : NULL);
	do_test();
	return 0;
	}
	</programlisting>

	<para>
	Suggested valgrind flags, given the suggestions above about setting
	up the runtime environment, library, and test file, might be:
	</para>
	<programlisting>
	valgrind -v --num-callers=20 --leak-check=yes --leak-resolution=high --show-reachable=yes a.out
	</programlisting>

	</sect2>

	<sect2 id="debug.gdb" xreflabel="debug.gdb">
	<title>Using <command>gdb</command></title>
	<para>
	</para>

	<para>
	Many options are available for gdb itself: please see <ulink
	url="http://sources.redhat.com/gdb/current/onlinedocs/gdb_13.html#SEC125">
	"GDB features for C++" </ulink> in the gdb documentation. Also
	recommended: the other parts of this manual.
	</para>

	<para>
	These settings can either be switched on in at the gdb command line,
	or put into a .gdbint file to establish default debugging
	characteristics, like so:
	</para>

	<programlisting>
	set print pretty on
	set print object on
	set print static-members on
	set print vtbl on
	set print demangle on
	set demangle-style gnu-v3
	</programlisting>
	</sect2>

	<sect2 id="debug.exceptions" xreflabel="debug.exceptions">
	<title>Tracking uncaught exceptions</title>
	<para>
	The <link linkend="support.termination.verbose">verbose
	termination handler</link> gives information about uncaught
	exceptions which are killing the program. It is described in the
	linked-to page.
	</para>
	</sect2>

	<sect2 id="debug.debug_mode" xreflabel="debug.debug_mode">
	<title>Debug Mode</title>
	<para> The <link linkend="manual.ext.debug_mode">Debug Mode</link>
	has compile and run-time checks for many containers.
	</para>
	</sect2>

	<sect2 id="debug.compile_time_checks" xreflabel="debug.compile_time_checks">
	<title>Compile Time Checking</title>
	<para> The <link linkend="manual.ext.compile_checks">Compile-Time
	Checks</link> Extension has compile-time checks for many algorithms.
	</para>
	</sect2>

	</sect1>