libstdc++-v3/doc/xml/manual/support.xml - chromiumos/third_party/gcc - Git at Google

 <chapter xmlns="http://docbook.org/ns/docbook" version="5.0"
 	 xml:id="std.support" xreflabel="Support">
 <?dbhtml filename="support.html"?>

 <info><title>
   Support
   <indexterm><primary>Support</primary></indexterm>
 </title>
   <keywordset>
     <keyword>ISO C++</keyword>
     <keyword>library</keyword>
   </keywordset>
 </info>

   <para>
     This part deals with the functions called and objects created
     automatically during the course of a program's existence.
   </para>

   <para>
     While we can't reproduce the contents of the Standard here (you
     need to get your own copy from your nation's member body; see our
     homepage for help), we can mention a couple of changes in what
     kind of support a C++ program gets from the Standard Library.
   </para>

 <section xml:id="std.support.types" xreflabel="Types"><info><title>Types</title></info>
   <?dbhtml filename="fundamental_types.html"?>

   <section xml:id="std.support.types.fundamental" xreflabel="Fundamental Types"><info><title>Fundamental Types</title></info>

     <para>
       C++ has the following builtin types:
     </para>
     <itemizedlist>
       <listitem><para>
 	char
       </para></listitem>
       <listitem><para>
 	signed char
       </para></listitem>
       <listitem><para>
 	unsigned char
       </para></listitem>
       <listitem><para>
 	signed short
       </para></listitem>
       <listitem><para>
 	signed int
       </para></listitem>
       <listitem><para>
 	signed long
       </para></listitem>
       <listitem><para>
 	unsigned short
       </para></listitem>
       <listitem><para>
 	unsigned int
       </para></listitem>
       <listitem><para>
 	unsigned long
       </para></listitem>
       <listitem><para>
 	bool
       </para></listitem>
       <listitem><para>
 	wchar_t
       </para></listitem>
       <listitem><para>
 	float
       </para></listitem>
       <listitem><para>
 	double
       </para></listitem>
       <listitem><para>
 	long double
       </para></listitem>
     </itemizedlist>

     <para>
       These fundamental types are always available, without having to
       include a header file. These types are exactly the same in
       either C++ or in C.
     </para>

     <para>
       Specializing parts of the library on these types is prohibited:
       instead, use a POD.
     </para>

   </section>
   <section xml:id="std.support.types.numeric_limits" xreflabel="Numeric Properties"><info><title>Numeric Properties</title></info>


     <para>
     The header <filename class="headerfile">limits</filename> defines
     traits classes to give access to various implementation
     defined-aspects of the fundamental types. The traits classes --
     fourteen in total -- are all specializations of the template class
     <classname>numeric_limits</classname>, documented <link xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="http://gcc.gnu.org/onlinedocs/libstdc++/latest-doxygen/a00593.html">here</link>
     and defined as follows:
     </para>

    <programlisting>
    template&lt;typename T&gt;
      struct class
      {
        static const bool is_specialized;
        static T max() throw();
        static T min() throw();

        static const int digits;
        static const int digits10;
        static const bool is_signed;
        static const bool is_integer;
        static const bool is_exact;
        static const int radix;
        static T epsilon() throw();
        static T round_error() throw();

        static const int min_exponent;
        static const int min_exponent10;
        static const int max_exponent;
        static const int max_exponent10;

        static const bool has_infinity;
        static const bool has_quiet_NaN;
        static const bool has_signaling_NaN;
        static const float_denorm_style has_denorm;
        static const bool has_denorm_loss;
        static T infinity() throw();
        static T quiet_NaN() throw();
        static T denorm_min() throw();

        static const bool is_iec559;
        static const bool is_bounded;
        static const bool is_modulo;

        static const bool traps;
        static const bool tinyness_before;
        static const float_round_style round_style;
      };
    </programlisting>
   </section>

   <section xml:id="std.support.types.null" xreflabel="NULL"><info><title>NULL</title></info>

     <para>
      The only change that might affect people is the type of
      <constant>NULL</constant>: while it is required to be a macro,
      the definition of that macro is <emphasis>not</emphasis> allowed
      to be <constant>(void*)0</constant>, which is often used in C.
     </para>

     <para>
      For <command>g++</command>, <constant>NULL</constant> is
      <code>#define</code>'d to be
      <constant>__null</constant>, a magic keyword extension of
      <command>g++</command>.
     </para>

     <para>
      The biggest problem of #defining <constant>NULL</constant> to be
      something like <quote>0L</quote> is that the compiler will view
      that as a long integer before it views it as a pointer, so
      overloading won't do what you expect. (This is why
      <command>g++</command> has a magic extension, so that
      <constant>NULL</constant> is always a pointer.)
     </para>

     <para>In his book <link xmlns:xlink="http://www.w3.org/1999/xlink"
       xlink:href="http://www.aristeia.com/books.html"><emphasis>Effective
       C++</emphasis></link>, Scott Meyers points out that the best way
     to solve this problem is to not overload on pointer-vs-integer
     types to begin with.  He also offers a way to make your own magic
     <constant>NULL</constant> that will match pointers before it
     matches integers.
     </para>
     <para>See the
       <link xmlns:xlink="http://www.w3.org/1999/xlink"
       xlink:href="http://www.aristeia.com/books.html"><emphasis>Effective
       C++ CD</emphasis></link> example.
     </para>
   </section>

 </section>

 <section xml:id="std.support.memory" xreflabel="Dynamic Memory"><info><title>Dynamic Memory</title></info>
   <?dbhtml filename="dynamic_memory.html"?>

   <para>
     There are six flavors each of <function>new</function> and
     <function>delete</function>, so make certain that you're using the right
     ones. Here are quickie descriptions of <function>new</function>:
   </para>
   <itemizedlist>
       <listitem><para>
 	single object form, throwing a
 	<classname>bad_alloc</classname> on errors; this is what most
 	people are used to using
       </para></listitem>
       <listitem><para>
 	Single object "nothrow" form, returning NULL on errors
       </para></listitem>
       <listitem><para>
 	Array <function>new</function>, throwing
 	<classname>bad_alloc</classname> on errors
       </para></listitem>
       <listitem><para>
 	Array nothrow <function>new</function>, returning
 	<constant>NULL</constant> on errors
       </para></listitem>
       <listitem><para>
 	Placement <function>new</function>, which does nothing (like
 	it's supposed to)
       </para></listitem>
       <listitem><para>
 	Placement array <function>new</function>, which also does
 	nothing
       </para></listitem>
    </itemizedlist>
    <para>
      They are distinguished by the parameters that you pass to them, like
      any other overloaded function.  The six flavors of <function>delete</function>
      are distinguished the same way, but none of them are allowed to throw
      an exception under any circumstances anyhow.  (They match up for
      completeness' sake.)
    </para>
    <para>
      Remember that it is perfectly okay to call <function>delete</function> on a
      NULL pointer!  Nothing happens, by definition.  That is not the
      same thing as deleting a pointer twice.
    </para>
    <para>
      By default, if one of the <quote>throwing <function>new</function>s</quote> can't
      allocate the memory requested, it tosses an instance of a
      <classname>bad_alloc</classname> exception (or, technically, some class derived
      from it).  You can change this by writing your own function (called a
      new-handler) and then registering it with <function>set_new_handler()</function>:
    </para>
    <programlisting>
    typedef void (*PFV)(void);

    static char*  safety;
    static PFV    old_handler;

    void my_new_handler ()
    {
        delete[] safety;
        popup_window ("Dude, you are running low on heap memory.  You
 		      should, like, close some windows, or something.
 		      The next time you run out, we're gonna burn!");
        set_new_handler (old_handler);
        return;
    }

    int main ()
    {
        safety = new char[500000];
        old_handler = set_new_handler (&amp;my_new_handler);
        ...
    }
    </programlisting>
    <para>
      <classname>bad_alloc</classname> is derived from the base <classname>exception</classname>
      class defined in Sect1 19.
    </para>
 </section>

 <section xml:id="std.support.termination" xreflabel="Termination"><info><title>Termination</title></info>
   <?dbhtml filename="termination.html"?>

   <section xml:id="support.termination.handlers" xreflabel="Termination Handlers"><info><title>Termination Handlers</title></info>

     <para>
       Not many changes here to <filename class="headerfile">cstdlib</filename>.  You should note that the
       <function>abort()</function> function does not call the
       destructors of automatic nor static objects, so if you're
       depending on those to do cleanup, it isn't going to happen.
       (The functions registered with <function>atexit()</function>
       don't get called either, so you can forget about that
       possibility, too.)
     </para>
     <para>
       The good old <function>exit()</function> function can be a bit
       funky, too, until you look closer.  Basically, three points to
       remember are:
     </para>
     <orderedlist inheritnum="ignore" continuation="restarts">
       <listitem>
 	<para>
 	Static objects are destroyed in reverse order of their creation.
 	</para>
       </listitem>
       <listitem>
 	<para>
 	Functions registered with <function>atexit()</function> are called in
 	reverse order of registration, once per registration call.
 	(This isn't actually new.)
 	</para>
       </listitem>
       <listitem>
 	<para>
 	The previous two actions are <quote>interleaved,</quote> that is,
 	given this pseudocode:
 	</para>
 <programlisting>
   extern "C or C++" void  f1 (void);
   extern "C or C++" void  f2 (void);

   static Thing obj1;
   atexit(f1);
   static Thing obj2;
   atexit(f2);
 </programlisting>
 	<para>
 	then at a call of <function>exit()</function>,
 	<varname>f2</varname> will be called, then
 	<varname>obj2</varname> will be destroyed, then
 	<varname>f1</varname> will be called, and finally
 	<varname>obj1</varname> will be destroyed. If
 	<varname>f1</varname> or <varname>f2</varname> allow an
 	exception to propagate out of them, Bad Things happen.
 	</para>
       </listitem>
     </orderedlist>
     <para>
       Note also that <function>atexit()</function> is only required to store 32
       functions, and the compiler/library might already be using some of
       those slots.  If you think you may run out, we recommend using
       the <function>xatexit</function>/<function>xexit</function> combination from <literal>libiberty</literal>, which has no such limit.
     </para>
   </section>

   <section xml:id="support.termination.verbose" xreflabel="Verbose Terminate Handler"><info><title>Verbose Terminate Handler</title></info>
   <?dbhtml filename="verbose_termination.html"?>

     <para>
       If you are having difficulty with uncaught exceptions and want a
       little bit of help debugging the causes of the core dumps, you can
       make use of a GNU extension, the verbose terminate handler.
     </para>

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

 int main()
 {
   std::set_terminate(__gnu_cxx::__verbose_terminate_handler);
   ...

   throw <replaceable>anything</replaceable>;
 }
 </programlisting>

    <para>
      The <function>__verbose_terminate_handler</function> function
      obtains the name of the current exception, attempts to demangle
      it, and prints it to stderr.  If the exception is derived from
      <classname>exception</classname> then the output from
      <function>what()</function> will be included.
    </para>

    <para>
      Any replacement termination function is required to kill the
      program without returning; this one calls abort.
    </para>

    <para>
      For example:
    </para>

 <programlisting>
 #include &lt;exception&gt;
 #include &lt;stdexcept&gt;

 struct argument_error : public std::runtime_error
 {
   argument_error(const std::string&amp; s): std::runtime_error(s) { }
 };

 int main(int argc)
 {
   std::set_terminate(__gnu_cxx::__verbose_terminate_handler);
   if (argc &gt; 5)
     throw argument_error(<quote>argc is greater than 5!</quote>);
   else
     throw argc;
 }
 </programlisting>

    <para>
      With the verbose terminate handler active, this gives:
    </para>

    <screen>
    <computeroutput>
    % ./a.out
    terminate called after throwing a `int'
    Aborted
    % ./a.out f f f f f f f f f f f
    terminate called after throwing an instance of `argument_error'
    what(): argc is greater than 5!
    Aborted
    </computeroutput>
    </screen>

    <para>
      The 'Aborted' line comes from the call to
      <function>abort()</function>, of course.
    </para>

    <para>
      This is the default termination handler; nothing need be done to
      use it.  To go back to the previous <quote>silent death</quote>
      method, simply include <filename>exception</filename> and
      <filename>cstdlib</filename>, and call
    </para>

    <programlisting>
      std::set_terminate(std::abort);
    </programlisting>

    <para>
      After this, all calls to <function>terminate</function> will use
      <function>abort</function> as the terminate handler.
    </para>

    <para>
      Note: the verbose terminate handler will attempt to write to
      stderr.  If your application closes stderr or redirects it to an
      inappropriate location,
      <function>__verbose_terminate_handler</function> will behave in
      an unspecified manner.
    </para>

   </section>
 </section>

 </chapter>
	<chapter xmlns="http://docbook.org/ns/docbook" version="5.0"
	xml:id="std.support" xreflabel="Support">
	<?dbhtml filename="support.html"?>

	<info><title>
	Support
	<indexterm><primary>Support</primary></indexterm>
	</title>
	<keywordset>
	<keyword>ISO C++</keyword>
	<keyword>library</keyword>
	</keywordset>
	</info>

	<para>
	This part deals with the functions called and objects created
	automatically during the course of a program's existence.
	</para>

	<para>
	While we can't reproduce the contents of the Standard here (you
	need to get your own copy from your nation's member body; see our
	homepage for help), we can mention a couple of changes in what
	kind of support a C++ program gets from the Standard Library.
	</para>

	<section xml:id="std.support.types" xreflabel="Types"><info><title>Types</title></info>
	<?dbhtml filename="fundamental_types.html"?>

	<section xml:id="std.support.types.fundamental" xreflabel="Fundamental Types"><info><title>Fundamental Types</title></info>

	<para>
	C++ has the following builtin types:
	</para>
	<itemizedlist>
	<listitem><para>
	char
	</para></listitem>
	<listitem><para>
	signed char
	</para></listitem>
	<listitem><para>
	unsigned char
	</para></listitem>
	<listitem><para>
	signed short
	</para></listitem>
	<listitem><para>
	signed int
	</para></listitem>
	<listitem><para>
	signed long
	</para></listitem>
	<listitem><para>
	unsigned short
	</para></listitem>
	<listitem><para>
	unsigned int
	</para></listitem>
	<listitem><para>
	unsigned long
	</para></listitem>
	<listitem><para>
	bool
	</para></listitem>
	<listitem><para>
	wchar_t
	</para></listitem>
	<listitem><para>
	float
	</para></listitem>
	<listitem><para>
	double
	</para></listitem>
	<listitem><para>
	long double
	</para></listitem>
	</itemizedlist>

	<para>
	These fundamental types are always available, without having to
	include a header file. These types are exactly the same in
	either C++ or in C.
	</para>

	<para>
	Specializing parts of the library on these types is prohibited:
	instead, use a POD.
	</para>

	</section>
	<section xml:id="std.support.types.numeric_limits" xreflabel="Numeric Properties"><info><title>Numeric Properties</title></info>



	<para>
	The header <filename class="headerfile">limits</filename> defines
	traits classes to give access to various implementation
	defined-aspects of the fundamental types. The traits classes --
	fourteen in total -- are all specializations of the template class
	<classname>numeric_limits</classname>, documented <link xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="http://gcc.gnu.org/onlinedocs/libstdc++/latest-doxygen/a00593.html">here</link>
	and defined as follows:
	</para>

	<programlisting>
	template<typename T>
	struct class
	{
	static const bool is_specialized;
	static T max() throw();
	static T min() throw();

	static const int digits;
	static const int digits10;
	static const bool is_signed;
	static const bool is_integer;
	static const bool is_exact;
	static const int radix;
	static T epsilon() throw();
	static T round_error() throw();

	static const int min_exponent;
	static const int min_exponent10;
	static const int max_exponent;
	static const int max_exponent10;

	static const bool has_infinity;
	static const bool has_quiet_NaN;
	static const bool has_signaling_NaN;
	static const float_denorm_style has_denorm;
	static const bool has_denorm_loss;
	static T infinity() throw();
	static T quiet_NaN() throw();
	static T denorm_min() throw();

	static const bool is_iec559;
	static const bool is_bounded;
	static const bool is_modulo;

	static const bool traps;
	static const bool tinyness_before;
	static const float_round_style round_style;
	};
	</programlisting>
	</section>

	<section xml:id="std.support.types.null" xreflabel="NULL"><info><title>NULL</title></info>

	<para>
	The only change that might affect people is the type of
	<constant>NULL</constant>: while it is required to be a macro,
	the definition of that macro is <emphasis>not</emphasis> allowed
	to be <constant>(void*)0</constant>, which is often used in C.
	</para>

	<para>
	For <command>g++</command>, <constant>NULL</constant> is
	<code>#define</code>'d to be
	<constant>__null</constant>, a magic keyword extension of
	<command>g++</command>.
	</para>

	<para>
	The biggest problem of #defining <constant>NULL</constant> to be
	something like <quote>0L</quote> is that the compiler will view
	that as a long integer before it views it as a pointer, so
	overloading won't do what you expect. (This is why
	<command>g++</command> has a magic extension, so that
	<constant>NULL</constant> is always a pointer.)
	</para>

	<para>In his book <link xmlns:xlink="http://www.w3.org/1999/xlink"
	xlink:href="http://www.aristeia.com/books.html"><emphasis>Effective
	C++</emphasis></link>, Scott Meyers points out that the best way
	to solve this problem is to not overload on pointer-vs-integer
	types to begin with. He also offers a way to make your own magic
	<constant>NULL</constant> that will match pointers before it
	matches integers.
	</para>
	<para>See the
	<link xmlns:xlink="http://www.w3.org/1999/xlink"
	xlink:href="http://www.aristeia.com/books.html"><emphasis>Effective
	C++ CD</emphasis></link> example.
	</para>
	</section>

	</section>

	<section xml:id="std.support.memory" xreflabel="Dynamic Memory"><info><title>Dynamic Memory</title></info>
	<?dbhtml filename="dynamic_memory.html"?>

	<para>
	There are six flavors each of <function>new</function> and
	<function>delete</function>, so make certain that you're using the right
	ones. Here are quickie descriptions of <function>new</function>:
	</para>
	<itemizedlist>
	<listitem><para>
	single object form, throwing a
	<classname>bad_alloc</classname> on errors; this is what most
	people are used to using
	</para></listitem>
	<listitem><para>
	Single object "nothrow" form, returning NULL on errors
	</para></listitem>
	<listitem><para>
	Array <function>new</function>, throwing
	<classname>bad_alloc</classname> on errors
	</para></listitem>
	<listitem><para>
	Array nothrow <function>new</function>, returning
	<constant>NULL</constant> on errors
	</para></listitem>
	<listitem><para>
	Placement <function>new</function>, which does nothing (like
	it's supposed to)
	</para></listitem>
	<listitem><para>
	Placement array <function>new</function>, which also does
	nothing
	</para></listitem>
	</itemizedlist>
	<para>
	They are distinguished by the parameters that you pass to them, like
	any other overloaded function. The six flavors of <function>delete</function>
	are distinguished the same way, but none of them are allowed to throw
	an exception under any circumstances anyhow. (They match up for
	completeness' sake.)
	</para>
	<para>
	Remember that it is perfectly okay to call <function>delete</function> on a
	NULL pointer! Nothing happens, by definition. That is not the
	same thing as deleting a pointer twice.
	</para>
	<para>
	By default, if one of the <quote>throwing <function>new</function>s</quote> can't
	allocate the memory requested, it tosses an instance of a
	<classname>bad_alloc</classname> exception (or, technically, some class derived
	from it). You can change this by writing your own function (called a
	new-handler) and then registering it with <function>set_new_handler()</function>:
	</para>
	<programlisting>
	typedef void (*PFV)(void);

	static char* safety;
	static PFV old_handler;

	void my_new_handler ()
	{
	delete[] safety;
	popup_window ("Dude, you are running low on heap memory. You
	should, like, close some windows, or something.
	The next time you run out, we're gonna burn!");
	set_new_handler (old_handler);
	return;
	}

	int main ()
	{
	safety = new char[500000];
	old_handler = set_new_handler (&my_new_handler);
	...
	}
	</programlisting>
	<para>
	<classname>bad_alloc</classname> is derived from the base <classname>exception</classname>
	class defined in Sect1 19.
	</para>
	</section>

	<section xml:id="std.support.termination" xreflabel="Termination"><info><title>Termination</title></info>
	<?dbhtml filename="termination.html"?>

	<section xml:id="support.termination.handlers" xreflabel="Termination Handlers"><info><title>Termination Handlers</title></info>

	<para>
	Not many changes here to <filename class="headerfile">cstdlib</filename>. You should note that the
	<function>abort()</function> function does not call the
	destructors of automatic nor static objects, so if you're
	depending on those to do cleanup, it isn't going to happen.
	(The functions registered with <function>atexit()</function>
	don't get called either, so you can forget about that
	possibility, too.)
	</para>
	<para>
	The good old <function>exit()</function> function can be a bit
	funky, too, until you look closer. Basically, three points to
	remember are:
	</para>
	<orderedlist inheritnum="ignore" continuation="restarts">
	<listitem>
	<para>
	Static objects are destroyed in reverse order of their creation.
	</para>
	</listitem>
	<listitem>
	<para>
	Functions registered with <function>atexit()</function> are called in
	reverse order of registration, once per registration call.
	(This isn't actually new.)
	</para>
	</listitem>
	<listitem>
	<para>
	The previous two actions are <quote>interleaved,</quote> that is,
	given this pseudocode:
	</para>
	<programlisting>
	extern "C or C++" void f1 (void);
	extern "C or C++" void f2 (void);

	static Thing obj1;
	atexit(f1);
	static Thing obj2;
	atexit(f2);
	</programlisting>
	<para>
	then at a call of <function>exit()</function>,
	<varname>f2</varname> will be called, then
	<varname>obj2</varname> will be destroyed, then
	<varname>f1</varname> will be called, and finally
	<varname>obj1</varname> will be destroyed. If
	<varname>f1</varname> or <varname>f2</varname> allow an
	exception to propagate out of them, Bad Things happen.
	</para>
	</listitem>
	</orderedlist>
	<para>
	Note also that <function>atexit()</function> is only required to store 32
	functions, and the compiler/library might already be using some of
	those slots. If you think you may run out, we recommend using
	the <function>xatexit</function>/<function>xexit</function> combination from <literal>libiberty</literal>, which has no such limit.
	</para>
	</section>

	<section xml:id="support.termination.verbose" xreflabel="Verbose Terminate Handler"><info><title>Verbose Terminate Handler</title></info>
	<?dbhtml filename="verbose_termination.html"?>

	<para>
	If you are having difficulty with uncaught exceptions and want a
	little bit of help debugging the causes of the core dumps, you can
	make use of a GNU extension, the verbose terminate handler.
	</para>

	<programlisting>
	#include <exception>

	int main()
	{
	std::set_terminate(__gnu_cxx::__verbose_terminate_handler);
	...

	throw <replaceable>anything</replaceable>;
	}
	</programlisting>

	<para>
	The <function>__verbose_terminate_handler</function> function
	obtains the name of the current exception, attempts to demangle
	it, and prints it to stderr. If the exception is derived from
	<classname>exception</classname> then the output from
	<function>what()</function> will be included.
	</para>

	<para>
	Any replacement termination function is required to kill the
	program without returning; this one calls abort.
	</para>

	<para>
	For example:
	</para>

	<programlisting>
	#include <exception>
	#include <stdexcept>

	struct argument_error : public std::runtime_error
	{
	argument_error(const std::string& s): std::runtime_error(s) { }
	};

	int main(int argc)
	{
	std::set_terminate(__gnu_cxx::__verbose_terminate_handler);
	if (argc > 5)
	throw argument_error(<quote>argc is greater than 5!</quote>);
	else
	throw argc;
	}
	</programlisting>

	<para>
	With the verbose terminate handler active, this gives:
	</para>

	<screen>
	<computeroutput>
	% ./a.out
	terminate called after throwing a `int'
	Aborted
	% ./a.out f f f f f f f f f f f
	terminate called after throwing an instance of `argument_error'
	what(): argc is greater than 5!
	Aborted
	</computeroutput>
	</screen>

	<para>
	The 'Aborted' line comes from the call to
	<function>abort()</function>, of course.
	</para>

	<para>
	This is the default termination handler; nothing need be done to
	use it. To go back to the previous <quote>silent death</quote>
	method, simply include <filename>exception</filename> and
	<filename>cstdlib</filename>, and call
	</para>

	<programlisting>
	std::set_terminate(std::abort);
	</programlisting>

	<para>
	After this, all calls to <function>terminate</function> will use
	<function>abort</function> as the terminate handler.
	</para>

	<para>
	Note: the verbose terminate handler will attempt to write to
	stderr. If your application closes stderr or redirects it to an
	inappropriate location,
	<function>__verbose_terminate_handler</function> will behave in
	an unspecified manner.
	</para>

	</section>
	</section>

	</chapter>