doc/internals/initcalls.txt - haproxy - Gitiles

 Initialization stages aka how to get your code initialized at the right moment


 1. Background

 Originally all subsystems were initialized via a dedicated function call
 from the huge main() function. Then some code started to become conditional
 or a bit more modular and the #ifdef placed there became a mess, resulting
 in init code being moved to function constructors in each subsystem's own
 file. Then pools of various things were introduced, starting to make the
 whole init sequence more complicated due to some forms of internal
 dependencies. Later epoll was introduced, requiring a post-fork callback,
 and finally threads arrived also requiring some post-thread init/deinit
 and allocation, marking the old architecture's last breath. Finally the
 whole thing resulted in lots of init code duplication and was simplified
 in 1.9 with the introduction of initcalls and initialization stages.


 2. New architecture

 The new architecture relies on two layers :
   - the registration functions
   - the INITCALL macros and initialization stages

 The first ones are mostly used to add a callback to a list. The second ones
 are used to specify when to call a function. Both are totally independent,
 however they are generally combined via another set consisting in the REGISTER
 macros which make some registration functions be called at some specific points
 during the init sequence.


 3. Registration functions

 Registration functions never fail. Or more precisely, if they fail it will only
 be on out-of-memory condition, and they will cause the process to immediately
 exit. As such they do not return any status and the caller doesn't have to care
 about their success.

 All available functions are described below in alphanumeric ordering. Please
 make sure to respect this ordering when adding new ones.

 - void hap_register_build_opts(const char *str, int must_free)

   This appends the zero-terminated constant string <str> to the list of known
   build options that will be reported on the output of "haproxy -vv". A line
   feed character ('\n') will automatically be appended after the string when it
   is displayed. The <must_free> argument must be zero, unless the string was
   allocated by any malloc-compatible function such as malloc()/calloc()/
   realloc()/strdup() or memprintf(), in which case it's better to pass a
   non-null value so that the string is freed upon exit. Note that despite the
   function's prototype taking a "const char *", the pointer will actually be
   cast and freed. The const char* is here to leave more freedom to use consts
   when making such options lists.

 - void hap_register_per_thread_alloc(int (*fct)())

   This adds a call to function <fct> to the list of functions to be called when
   threads are started, at the beginning of the polling loop. This is also valid
   for the main thread and will be called even if threads are disabled, so that
   it is guaranteed that this function will be called in any circumstance. Each
   thread will first call all these functions exactly once when it starts. Calls
   are serialized by the init_mutex, so that locking is not necessary in these
   functions. There is no relation between the thread numbers and the callback
   ordering. The function is expected to return non-zero on success, or zero on
   failure. A failure will make the process emit a succinct error message and
   immediately exit. See also hap_register_per_thread_free() for functions
   called after these ones.

 - void hap_register_per_thread_deinit(void (*fct)());

   This adds a call to function <fct> to the list of functions to be called when
   threads are gracefully stopped, at the end of the polling loop. This is also
   valid for the main thread and will be called even if threads are disabled, so
   that it is guaranteed that this function will be called in any circumstance
   if the process experiences a soft stop. Each thread will call this function
   exactly once when it stops. However contrary to _alloc() and _init(), the
   calls are made without any protection, thus if any shared resource if touched
   by the function, the function is responsible for protecting it. The reason
   behind this is that such resources are very likely to be still in use in one
   other thread and that most of the time the functions will in fact only touch
   a refcount or deinitialize their private resources. See also
   hap_register_per_thread_free() for functions called after these ones.

 - void hap_register_per_thread_free(void (*fct)());

   This adds a call to function <fct> to the list of functions to be called when
   threads are gracefully stopped, at the end of the polling loop, after all calls
   to _deinit() callbacks are done for this thread. This is also valid for the
   main thread and will be called even if threads are disabled, so that it is
   guaranteed that this function will be called in any circumstance if the
   process experiences a soft stop. Each thread will call this function exactly
   once when it stops. However contrary to _alloc() and _init(), the calls are
   made without any protection, thus if any shared resource if touched by the
   function, the function is responsible for protecting it. The reason behind
   this is that such resources are very likely to be still in use in one other
   thread and that most of the time the functions will in fact only touch a
   refcount or deinitialize their private resources. See also
   hap_register_per_thread_deinit() for functions called before these ones.

 - void hap_register_per_thread_init(int (*fct)())

   This adds a call to function <fct> to the list of functions to be called when
   threads are started, at the beginning of the polling loop, right after the
   list of _alloc() functions. This is also valid for the main thread and will
   be called even if threads are disabled, so that it is guaranteed that this
   function will be called in any circumstance. Each thread will call this
   function exactly once when it starts, and calls are serialized by the
   init_mutex which is held over all _alloc() and _init() calls, so that locking
   is not necessary in these functions. In other words for all threads but the
   current one, the sequence of _alloc() and _init() calls will be atomic. There
   is no relation between the thread numbers and the callback ordering. The
   function is expected to return non-zero on success, or zero on failure. A
   failure will make the process emit a succinct error message and immediately
   exit. See also hap_register_per_thread_alloc() for functions called before
   these ones.

 - void hap_register_post_check(int (*fct)())

   This adds a call to function <fct> to the list of functions to be called at
   the end of the configuration validity checks, just at the point where the
   program either forks or exits depending whether it's called with "-c" or not.
   Such calls are suited for memory allocation or internal table pre-computation
   that would preferably not be done on the fly to avoid inducing extra time to
   a pure configuration check. Threads are not yet started so no protection is
   required. The function is expected to return non-zero on success, or zero on
   failure. A failure will make the process emit a succinct error message and
   immediately exit.

 - void hap_register_post_deinit(void (*fct)())

   This adds a call to function <fct> to the list of functions to be called when
   freeing the global sections at the end of deinit(), after everything is
   stopped. The process is single-threaded at this point, thus these functions
   are suitable for releasing configuration elements provided that no other
   _deinit() function uses them, i.e. only close/release what is strictly
   private to the subsystem. Since such functions are mostly only called during
   soft stops (reloads) or failed startups, they tend to experience much less
   test coverage than others despite being more exposed, and as such a lot of
   care must be taken to test them especially when facing partial subsystem
   initializations followed by errors.

 - void hap_register_post_proxy_check(int (*fct)(struct proxy *))

   This adds a call to function <fct> to the list of functions to be called for
   each proxy, after the calls to _post_server_check(). This can allow, for
   example, to pre-configure default values for an option in a frontend based on
   the "bind" lines or something in a backend based on the "server" lines. It's
   worth being aware that such a function must be careful not to waste too much
   time in order not to significantly slow down configurations with tens of
   thousands of backends. The function is expected to return non-zero on
   success, or zero on failure. A failure will make the process emit a succinct
   error message and immediately exit.

 - void hap_register_post_server_check(int (*fct)(struct server *))

   This adds a call to function <fct> to the list of functions to be called for
   each server, after the call to check_config_validity(). This can allow, for
   example, to preset a health state on a server or to allocate a protocol-
   specific memory area. It's worth being aware that such a function must be
   careful not to waste too much time in order not to significantly slow down
   configurations with tens of thousands of servers. The function is expected
   to return non-zero on success, or zero on failure. A failure will make the
   process emit a succinct error message and immediately exit.

 - void hap_register_proxy_deinit(void (*fct)(struct proxy *))

   This adds a call to function <fct> to the list of functions to be called when
   freeing the resources during deinit(). These functions will be called as part
   of the proxy's resource cleanup. Note that some of the proxy's fields will
   already have been freed and others not, so such a function must not use any
   information from the proxy that is subject to being released. In particular,
   all servers have already been deleted. Since such functions are mostly only
   called during soft stops (reloads) or failed startups, they tend to
   experience much less test coverage than others despite being more exposed,
   and as such a lot of care must be taken to test them especially when facing
   partial subsystem initializations followed by errors. It's worth mentioning
   that too slow functions could have a significant impact on the configuration
   check or exit time especially on large configurations.

 - void hap_register_server_deinit(void (*fct)(struct server *))

   This adds a call to function <fct> to the list of functions to be called when
   freeing the resources during deinit(). These functions will be called as part
   of the server's resource cleanup. Note that some of the server's fields will
   already have been freed and others not, so such a function must not use any
   information from the server that is subject to being released. Since such
   functions are mostly only called during soft stops (reloads) or failed
   startups, they tend to experience much less test coverage than others despite
   being more exposed, and as such a lot of care must be taken to test them
   especially when facing partial subsystem initializations followed by errors.
   It's worth mentioning that too slow functions could have a significant impact
   on the configuration check or exit time especially on large configurations.


 4. Initialization stages

 In order to offer some guarantees, the startup of the program is split into
 several stages. Some callbacks can be placed into each of these stages using
 an INITCALL macro, with 0 to 3 arguments, respectively called INITCALL0 to
 INITCALL3. These macros must be placed anywhere at the top level of a C file,
 preferably at the end so that the referenced symbols have already been met,
 but it may also be fine to place them right after the callbacks themselves.

 Such callbacks are referenced into small structures containing a pointer to the
 function and 3 arguments. NULL replaces unused arguments. The callbacks are
 cast to (void (*)(void *, void *, void *)) and the arguments to (void *).

 The first argument to the INITCALL macro is the initialization stage. The
 second one is the callback function, and others if any are the arguments.
 The init stage must be among the values of the "init_stage" enum, currently,
 and in this execution order:

   - STG_PREPARE  : used to preset variables, pre-initialize lookup tables and
                    pre-initialize list heads
   - STG_LOCK     : used to pre-initialize locks
   - STG_ALLOC    : used to allocate the required structures
   - STG_POOL     : used to create pools
   - STG_REGISTER : used to register static lists such as keywords
   - STG_INIT     : used to initialize subsystems

 Each stage is guaranteed that previous stages have successfully completed. This
 means that an INITCALL placed at stage STG_REGISTER is guaranteed that all
 pools were already created and will be usable. Conversely, an INITCALL placed
 at stage STG_PREPARE must not rely on any field that requires preliminary
 allocation nor initialization. A callback cannot rely on other callbacks of the
 same stage, as the execution order within a stage is undefined and essentially
 depends on the linking order.

 Example: register a very early call to init_log() with no argument, and another
          call to cli_register_kw(&cli_kws) much later:

    INITCALL0(STG_PREPARE, init_log);
    INITCALL1(STG_REGISTER, cli_register_kw, &cli_kws);

 Technically speaking, each call to such a macro adds a distinct local symbol
 whose dynamic name involves the line number. These symbols are placed into a
 separate section and the beginning and end section pointers are provided by the
 linker. When too old a linker is used, a fallback is applied consisting in
 placing them into a linked list which is built by a constructor function for
 each initcall (this takes more room).

 Due to the symbols internally using the line number, it is very important not
 to place more than one INITCALL per line in the source file.

 It is also strongly recommended that functions and referenced arguments are
 static symbols local to the source file, unless they are global registration
 functions like in the example above with cli_register_kw(), where only the
 argument is a local keywords table.

 INITCALLs do not expect the callback function to return anything and as such
 do not perform any error check. As such, they are very similar to constructors
 offered by the compiler except that they are segmented in stages. It is thus
 the responsibility of the called functions to perform their own error checking
 and to exit in case of error. This may change in the future.


 5. REGISTER family of macros

 The association of INITCALLs and registration functions allows to perform some
 early dynamic registration of functions to be used anywhere, as well as values
 to be added to existing lists without having to manipulate list elements. For
 the sake of simplification, these combinations are available as a set of
 REGISTER macros which register calls to certain functions at the appropriate
 init stage. Such macros must be used at the top level in a file, just like
 INITCALL macros. The following macros are currently supported. Please keep them
 alphanumerically ordered:

 - REGISTER_BUILD_OPTS(str)

   Adds the constant string <str> to the list of build options. This is done by
   registering a call to hap_register_build_opts(str, 0) at stage STG_REGISTER.
   The string will not be freed.

 - REGISTER_CONFIG_POSTPARSER(name, parser)

   Adds a call to function <parser> at the end of the config parsing. The
   function is called at the very end of check_config_validity() and may be used
   to initialize a subsystem based on global settings for example. This is done
   by registering a call to cfg_register_postparser(name, parser) at stage
   STG_REGISTER.

 - REGISTER_CONFIG_SECTION(name, parse, post)

   Registers a new config section name <name> which will be parsed by function
   <parse> (if not null), and with an optional call to function <post> at the
   end of the section. Function <parse> must be of type (int (*parse)(const char
   *file, int linenum, char **args, int inv)), and returns 0 on success or an
   error code among the ERR_* set on failure. The <post> callback takes no
   argument and returns a similar error code. This is achieved by registering a
   call to cfg_register_section() with the three arguments at stage
   STG_REGISTER.

 - REGISTER_PER_THREAD_ALLOC(fct)

   Registers a call to register_per_thread_alloc(fct) at stage STG_REGISTER.

 - REGISTER_PER_THREAD_DEINIT(fct)

   Registers a call to register_per_thread_deinit(fct) at stage STG_REGISTER.

 - REGISTER_PER_THREAD_FREE(fct)

   Registers a call to register_per_thread_free(fct) at stage STG_REGISTER.

 - REGISTER_PER_THREAD_INIT(fct)

   Registers a call to register_per_thread_init(fct) at stage STG_REGISTER.

 - REGISTER_POOL(ptr, name, size)

   Used internally to declare a new pool. This is made by calling function
   create_pool_callback() with these arguments at stage STG_POOL. Do not use it
   directly, use either DECLARE_POOL() or DECLARE_STATIC_POOL() instead (see
   below).

 - REGISTER_POST_CHECK(fct)

   Registers a call to register_post_check(fct) at stage STG_REGISTER.

 - REGISTER_POST_DEINIT(fct)

   Registers a call to register_post_deinit(fct) at stage STG_REGISTER.

 - REGISTER_POST_PROXY_CHECK(fct)

   Registers a call to register_post_proxy_check(fct) at stage STG_REGISTER.

 - REGISTER_POST_SERVER_CHECK(fct)

   Registers a call to register_post_server_check(fct) at stage STG_REGISTER.

 - REGISTER_PROXY_DEINIT(fct)

   Registers a call to register_proxy_deinit(fct) at stage STG_REGISTER.

 - REGISTER_SERVER_DEINIT(fct)

   Registers a call to register_server_deinit(fct) at stage STG_REGISTER.


 6. Other initialization macros

 On top of the INITCALL family of macros, a few other convenient macros were
 created in order to simplify declarations or allocations:

 - DECLARE_POOL(ptr, name, size)

   Placed at the top level of a file, this declares a global memory pool as
   variable <ptr>, name <name> and size <size> bytes per element. This is made
   via a call to REGISTER_POOL() and by assigning the resulting pointer to
   variable <ptr>. <ptr> will be created of type "struct pool_head *". If the
   pool needs to be visible outside of the function (which is likely), it will
   also need to be declared somewhere as "extern struct pool_head *<ptr>;". It
   is recommended to place such declarations very early in the source file so
   that the variable is already known to all subsequent functions which may use
   it.

 - DECLARE_STATIC_POOL(ptr, name, size)

   Placed at the top level of a file, this declares a static memory pool as
   variable <ptr>, name <name> and size <size> bytes per element. This is made
   via a call to REGISTER_POOL() and by assigning the resulting pointer to local
   variable <ptr>. <ptr> will be created of type "static struct pool_head *". It
   is recommended to place such declarations very early in the source file so
   that the variable is already known to all subsequent functions which may use
   it.
	Initialization stages aka how to get your code initialized at the right moment


	1. Background

	Originally all subsystems were initialized via a dedicated function call
	from the huge main() function. Then some code started to become conditional
	or a bit more modular and the #ifdef placed there became a mess, resulting
	in init code being moved to function constructors in each subsystem's own
	file. Then pools of various things were introduced, starting to make the
	whole init sequence more complicated due to some forms of internal
	dependencies. Later epoll was introduced, requiring a post-fork callback,
	and finally threads arrived also requiring some post-thread init/deinit
	and allocation, marking the old architecture's last breath. Finally the
	whole thing resulted in lots of init code duplication and was simplified
	in 1.9 with the introduction of initcalls and initialization stages.


	2. New architecture

	The new architecture relies on two layers :
	- the registration functions
	- the INITCALL macros and initialization stages

	The first ones are mostly used to add a callback to a list. The second ones
	are used to specify when to call a function. Both are totally independent,
	however they are generally combined via another set consisting in the REGISTER
	macros which make some registration functions be called at some specific points
	during the init sequence.


	3. Registration functions

	Registration functions never fail. Or more precisely, if they fail it will only
	be on out-of-memory condition, and they will cause the process to immediately
	exit. As such they do not return any status and the caller doesn't have to care
	about their success.

	All available functions are described below in alphanumeric ordering. Please
	make sure to respect this ordering when adding new ones.

	- void hap_register_build_opts(const char *str, int must_free)

	This appends the zero-terminated constant string <str> to the list of known
	build options that will be reported on the output of "haproxy -vv". A line
	feed character ('\n') will automatically be appended after the string when it
	is displayed. The <must_free> argument must be zero, unless the string was
	allocated by any malloc-compatible function such as malloc()/calloc()/
	realloc()/strdup() or memprintf(), in which case it's better to pass a
	non-null value so that the string is freed upon exit. Note that despite the
	function's prototype taking a "const char *", the pointer will actually be
	cast and freed. The const char* is here to leave more freedom to use consts
	when making such options lists.

	- void hap_register_per_thread_alloc(int (*fct)())

	This adds a call to function <fct> to the list of functions to be called when
	threads are started, at the beginning of the polling loop. This is also valid
	for the main thread and will be called even if threads are disabled, so that
	it is guaranteed that this function will be called in any circumstance. Each
	thread will first call all these functions exactly once when it starts. Calls
	are serialized by the init_mutex, so that locking is not necessary in these
	functions. There is no relation between the thread numbers and the callback
	ordering. The function is expected to return non-zero on success, or zero on
	failure. A failure will make the process emit a succinct error message and
	immediately exit. See also hap_register_per_thread_free() for functions
	called after these ones.

	- void hap_register_per_thread_deinit(void (*fct)());

	This adds a call to function <fct> to the list of functions to be called when
	threads are gracefully stopped, at the end of the polling loop. This is also
	valid for the main thread and will be called even if threads are disabled, so
	that it is guaranteed that this function will be called in any circumstance
	if the process experiences a soft stop. Each thread will call this function
	exactly once when it stops. However contrary to _alloc() and _init(), the
	calls are made without any protection, thus if any shared resource if touched
	by the function, the function is responsible for protecting it. The reason
	behind this is that such resources are very likely to be still in use in one
	other thread and that most of the time the functions will in fact only touch
	a refcount or deinitialize their private resources. See also
	hap_register_per_thread_free() for functions called after these ones.

	- void hap_register_per_thread_free(void (*fct)());

	This adds a call to function <fct> to the list of functions to be called when
	threads are gracefully stopped, at the end of the polling loop, after all calls
	to _deinit() callbacks are done for this thread. This is also valid for the
	main thread and will be called even if threads are disabled, so that it is
	guaranteed that this function will be called in any circumstance if the
	process experiences a soft stop. Each thread will call this function exactly
	once when it stops. However contrary to _alloc() and _init(), the calls are
	made without any protection, thus if any shared resource if touched by the
	function, the function is responsible for protecting it. The reason behind
	this is that such resources are very likely to be still in use in one other
	thread and that most of the time the functions will in fact only touch a
	refcount or deinitialize their private resources. See also
	hap_register_per_thread_deinit() for functions called before these ones.

	- void hap_register_per_thread_init(int (*fct)())

	This adds a call to function <fct> to the list of functions to be called when
	threads are started, at the beginning of the polling loop, right after the
	list of _alloc() functions. This is also valid for the main thread and will
	be called even if threads are disabled, so that it is guaranteed that this
	function will be called in any circumstance. Each thread will call this
	function exactly once when it starts, and calls are serialized by the
	init_mutex which is held over all _alloc() and _init() calls, so that locking
	is not necessary in these functions. In other words for all threads but the
	current one, the sequence of _alloc() and _init() calls will be atomic. There
	is no relation between the thread numbers and the callback ordering. The
	function is expected to return non-zero on success, or zero on failure. A
	failure will make the process emit a succinct error message and immediately
	exit. See also hap_register_per_thread_alloc() for functions called before
	these ones.

	- void hap_register_post_check(int (*fct)())

	This adds a call to function <fct> to the list of functions to be called at
	the end of the configuration validity checks, just at the point where the
	program either forks or exits depending whether it's called with "-c" or not.
	Such calls are suited for memory allocation or internal table pre-computation
	that would preferably not be done on the fly to avoid inducing extra time to
	a pure configuration check. Threads are not yet started so no protection is
	required. The function is expected to return non-zero on success, or zero on
	failure. A failure will make the process emit a succinct error message and
	immediately exit.

	- void hap_register_post_deinit(void (*fct)())

	This adds a call to function <fct> to the list of functions to be called when
	freeing the global sections at the end of deinit(), after everything is
	stopped. The process is single-threaded at this point, thus these functions
	are suitable for releasing configuration elements provided that no other
	_deinit() function uses them, i.e. only close/release what is strictly
	private to the subsystem. Since such functions are mostly only called during
	soft stops (reloads) or failed startups, they tend to experience much less
	test coverage than others despite being more exposed, and as such a lot of
	care must be taken to test them especially when facing partial subsystem
	initializations followed by errors.

	- void hap_register_post_proxy_check(int (fct)(struct proxy ))

	This adds a call to function <fct> to the list of functions to be called for
	each proxy, after the calls to _post_server_check(). This can allow, for
	example, to pre-configure default values for an option in a frontend based on
	the "bind" lines or something in a backend based on the "server" lines. It's
	worth being aware that such a function must be careful not to waste too much
	time in order not to significantly slow down configurations with tens of
	thousands of backends. The function is expected to return non-zero on
	success, or zero on failure. A failure will make the process emit a succinct
	error message and immediately exit.

	- void hap_register_post_server_check(int (fct)(struct server ))

	This adds a call to function <fct> to the list of functions to be called for
	each server, after the call to check_config_validity(). This can allow, for
	example, to preset a health state on a server or to allocate a protocol-
	specific memory area. It's worth being aware that such a function must be
	careful not to waste too much time in order not to significantly slow down
	configurations with tens of thousands of servers. The function is expected
	to return non-zero on success, or zero on failure. A failure will make the
	process emit a succinct error message and immediately exit.

	- void hap_register_proxy_deinit(void (fct)(struct proxy ))

	This adds a call to function <fct> to the list of functions to be called when
	freeing the resources during deinit(). These functions will be called as part
	of the proxy's resource cleanup. Note that some of the proxy's fields will
	already have been freed and others not, so such a function must not use any
	information from the proxy that is subject to being released. In particular,
	all servers have already been deleted. Since such functions are mostly only
	called during soft stops (reloads) or failed startups, they tend to
	experience much less test coverage than others despite being more exposed,
	and as such a lot of care must be taken to test them especially when facing
	partial subsystem initializations followed by errors. It's worth mentioning
	that too slow functions could have a significant impact on the configuration
	check or exit time especially on large configurations.

	- void hap_register_server_deinit(void (fct)(struct server ))

	This adds a call to function <fct> to the list of functions to be called when
	freeing the resources during deinit(). These functions will be called as part
	of the server's resource cleanup. Note that some of the server's fields will
	already have been freed and others not, so such a function must not use any
	information from the server that is subject to being released. Since such
	functions are mostly only called during soft stops (reloads) or failed
	startups, they tend to experience much less test coverage than others despite
	being more exposed, and as such a lot of care must be taken to test them
	especially when facing partial subsystem initializations followed by errors.
	It's worth mentioning that too slow functions could have a significant impact
	on the configuration check or exit time especially on large configurations.


	4. Initialization stages

	In order to offer some guarantees, the startup of the program is split into
	several stages. Some callbacks can be placed into each of these stages using
	an INITCALL macro, with 0 to 3 arguments, respectively called INITCALL0 to
	INITCALL3. These macros must be placed anywhere at the top level of a C file,
	preferably at the end so that the referenced symbols have already been met,
	but it may also be fine to place them right after the callbacks themselves.

	Such callbacks are referenced into small structures containing a pointer to the
	function and 3 arguments. NULL replaces unused arguments. The callbacks are
	cast to (void ()(void , void , void )) and the arguments to (void *).

	The first argument to the INITCALL macro is the initialization stage. The
	second one is the callback function, and others if any are the arguments.
	The init stage must be among the values of the "init_stage" enum, currently,
	and in this execution order:

	- STG_PREPARE : used to preset variables, pre-initialize lookup tables and
	pre-initialize list heads
	- STG_LOCK : used to pre-initialize locks
	- STG_ALLOC : used to allocate the required structures
	- STG_POOL : used to create pools
	- STG_REGISTER : used to register static lists such as keywords
	- STG_INIT : used to initialize subsystems

	Each stage is guaranteed that previous stages have successfully completed. This
	means that an INITCALL placed at stage STG_REGISTER is guaranteed that all
	pools were already created and will be usable. Conversely, an INITCALL placed
	at stage STG_PREPARE must not rely on any field that requires preliminary
	allocation nor initialization. A callback cannot rely on other callbacks of the
	same stage, as the execution order within a stage is undefined and essentially
	depends on the linking order.

	Example: register a very early call to init_log() with no argument, and another
	call to cli_register_kw(&cli_kws) much later:

	INITCALL0(STG_PREPARE, init_log);
	INITCALL1(STG_REGISTER, cli_register_kw, &cli_kws);

	Technically speaking, each call to such a macro adds a distinct local symbol
	whose dynamic name involves the line number. These symbols are placed into a
	separate section and the beginning and end section pointers are provided by the
	linker. When too old a linker is used, a fallback is applied consisting in
	placing them into a linked list which is built by a constructor function for
	each initcall (this takes more room).

	Due to the symbols internally using the line number, it is very important not
	to place more than one INITCALL per line in the source file.

	It is also strongly recommended that functions and referenced arguments are
	static symbols local to the source file, unless they are global registration
	functions like in the example above with cli_register_kw(), where only the
	argument is a local keywords table.

	INITCALLs do not expect the callback function to return anything and as such
	do not perform any error check. As such, they are very similar to constructors
	offered by the compiler except that they are segmented in stages. It is thus
	the responsibility of the called functions to perform their own error checking
	and to exit in case of error. This may change in the future.


	5. REGISTER family of macros

	The association of INITCALLs and registration functions allows to perform some
	early dynamic registration of functions to be used anywhere, as well as values
	to be added to existing lists without having to manipulate list elements. For
	the sake of simplification, these combinations are available as a set of
	REGISTER macros which register calls to certain functions at the appropriate
	init stage. Such macros must be used at the top level in a file, just like
	INITCALL macros. The following macros are currently supported. Please keep them
	alphanumerically ordered:

	- REGISTER_BUILD_OPTS(str)

	Adds the constant string <str> to the list of build options. This is done by
	registering a call to hap_register_build_opts(str, 0) at stage STG_REGISTER.
	The string will not be freed.

	- REGISTER_CONFIG_POSTPARSER(name, parser)

	Adds a call to function <parser> at the end of the config parsing. The
	function is called at the very end of check_config_validity() and may be used
	to initialize a subsystem based on global settings for example. This is done
	by registering a call to cfg_register_postparser(name, parser) at stage
	STG_REGISTER.

	- REGISTER_CONFIG_SECTION(name, parse, post)

	Registers a new config section name <name> which will be parsed by function
	<parse> (if not null), and with an optional call to function <post> at the
	end of the section. Function <parse> must be of type (int (*parse)(const char
	file, int linenum, char *args, int inv)), and returns 0 on success or an
	error code among the ERR_* set on failure. The <post> callback takes no
	argument and returns a similar error code. This is achieved by registering a
	call to cfg_register_section() with the three arguments at stage
	STG_REGISTER.

	- REGISTER_PER_THREAD_ALLOC(fct)

	Registers a call to register_per_thread_alloc(fct) at stage STG_REGISTER.

	- REGISTER_PER_THREAD_DEINIT(fct)

	Registers a call to register_per_thread_deinit(fct) at stage STG_REGISTER.

	- REGISTER_PER_THREAD_FREE(fct)

	Registers a call to register_per_thread_free(fct) at stage STG_REGISTER.

	- REGISTER_PER_THREAD_INIT(fct)

	Registers a call to register_per_thread_init(fct) at stage STG_REGISTER.

	- REGISTER_POOL(ptr, name, size)

	Used internally to declare a new pool. This is made by calling function
	create_pool_callback() with these arguments at stage STG_POOL. Do not use it
	directly, use either DECLARE_POOL() or DECLARE_STATIC_POOL() instead (see
	below).

	- REGISTER_POST_CHECK(fct)

	Registers a call to register_post_check(fct) at stage STG_REGISTER.

	- REGISTER_POST_DEINIT(fct)

	Registers a call to register_post_deinit(fct) at stage STG_REGISTER.

	- REGISTER_POST_PROXY_CHECK(fct)

	Registers a call to register_post_proxy_check(fct) at stage STG_REGISTER.

	- REGISTER_POST_SERVER_CHECK(fct)

	Registers a call to register_post_server_check(fct) at stage STG_REGISTER.

	- REGISTER_PROXY_DEINIT(fct)

	Registers a call to register_proxy_deinit(fct) at stage STG_REGISTER.

	- REGISTER_SERVER_DEINIT(fct)

	Registers a call to register_server_deinit(fct) at stage STG_REGISTER.


	6. Other initialization macros

	On top of the INITCALL family of macros, a few other convenient macros were
	created in order to simplify declarations or allocations:

	- DECLARE_POOL(ptr, name, size)

	Placed at the top level of a file, this declares a global memory pool as
	variable <ptr>, name <name> and size <size> bytes per element. This is made
	via a call to REGISTER_POOL() and by assigning the resulting pointer to
	variable <ptr>. <ptr> will be created of type "struct pool_head *". If the
	pool needs to be visible outside of the function (which is likely), it will
	also need to be declared somewhere as "extern struct pool_head *<ptr>;". It
	is recommended to place such declarations very early in the source file so
	that the variable is already known to all subsequent functions which may use
	it.

	- DECLARE_STATIC_POOL(ptr, name, size)

	Placed at the top level of a file, this declares a static memory pool as
	variable <ptr>, name <name> and size <size> bytes per element. This is made
	via a call to REGISTER_POOL() and by assigning the resulting pointer to local
	variable <ptr>. <ptr> will be created of type "static struct pool_head *". It
	is recommended to place such declarations very early in the source file so
	that the variable is already known to all subsequent functions which may use
	it.