src/applet.c - haproxy - Gitiles

 /*
  * Functions managing applets
  *
  * Copyright 2000-2015 Willy Tarreau <w@1wt.eu>
  *
  * This program is free software; you can redistribute it and/or
  * modify it under the terms of the GNU General Public License
  * as published by the Free Software Foundation; either version
  * 2 of the License, or (at your option) any later version.
  *
  */

 #include <stdio.h>
 #include <stdlib.h>

 #include <haproxy/api.h>
 #include <haproxy/applet.h>
 #include <haproxy/channel.h>
 #include <haproxy/list.h>
 #include <haproxy/sc_strm.h>
 #include <haproxy/stconn.h>
 #include <haproxy/stream.h>
 #include <haproxy/task.h>

 unsigned int nb_applets = 0;

 DECLARE_POOL(pool_head_appctx,  "appctx",  sizeof(struct appctx));

 /* Tries to allocate a new appctx and initialize all of its fields. The appctx
  * is returned on success, NULL on failure. The appctx must be released using
  * appctx_free(). <applet> is assigned as the applet, but it can be NULL. <thr>
  * is the thread ID to start the applet on, and a negative value allows the
  * applet to start anywhere. Backend applets may only be created on the current
  * thread.
  */
 struct appctx *appctx_new_on(struct applet *applet, struct sedesc *sedesc, int thr)
 {
 	struct appctx *appctx;

 	/* Backend appctx cannot be started on another thread than the local one */
 	BUG_ON(thr != tid && sedesc);

 	appctx = pool_zalloc(pool_head_appctx);
 	if (unlikely(!appctx))
 		goto fail_appctx;

 	LIST_INIT(&appctx->wait_entry);
 	appctx->obj_type = OBJ_TYPE_APPCTX;
 	appctx->applet = applet;
 	appctx->sess = NULL;
 	if (!sedesc) {
 		sedesc = sedesc_new();
 		if (!sedesc)
 			goto fail_endp;
 		sedesc->se = appctx;
 		se_fl_set(sedesc, SE_FL_T_APPLET | SE_FL_ORPHAN);
 	}
 	appctx->sedesc = sedesc;

 	appctx->t = task_new_on(thr);
 	if (unlikely(!appctx->t))
 		goto fail_task;
 	appctx->t->process = task_run_applet;
 	appctx->t->context = appctx;

 	LIST_INIT(&appctx->buffer_wait.list);
 	appctx->buffer_wait.target = appctx;
 	appctx->buffer_wait.wakeup_cb = appctx_buf_available;

 	_HA_ATOMIC_INC(&nb_applets);
 	return appctx;

   fail_task:
 	sedesc_free(appctx->sedesc);
   fail_endp:
 	pool_free(pool_head_appctx, appctx);
   fail_appctx:
 	return NULL;
 }

 /* Finalize the frontend appctx startup. It must not be called for a backend
  * appctx. This function is responsible to create the appctx's session and the
  * frontend stream connector. By transitivity, the stream is also created.
  *
  * It returns 0 on success and -1 on error. In this case, it is the caller
  * responsibility to release the appctx. However, the session is released if it
  * was created. On success, if an error is encountered in the caller function,
  * the stream must be released instead of the appctx. To be sure,
  * appctx_free_on_early_error() must be called in this case.
  */
 int appctx_finalize_startup(struct appctx *appctx, struct proxy *px, struct buffer *input)
 {
 	struct session *sess;

 	/* async startup is only possible for frontend appctx. Thus for orphan
 	 * appctx. Because no backend appctx can be orphan.
 	 */
 	BUG_ON(!se_fl_test(appctx->sedesc, SE_FL_ORPHAN));

 	sess = session_new(px, NULL, &appctx->obj_type);
 	if (!sess)
 		return -1;
 	if (!sc_new_from_endp(appctx->sedesc, sess, input)) {
 		session_free(sess);
 		return -1;
 	}
 	appctx->sess = sess;
 	return 0;
 }

 /* Release function to call when an error occurred during init stage of a
  * frontend appctx. For a backend appctx, it just calls appctx_free()
  */
 void appctx_free_on_early_error(struct appctx *appctx)
 {
 	/* If a frontend appctx is attached to a stream connector, release the stream
 	 * instead of the appctx.
 	 */
 	if (!se_fl_test(appctx->sedesc, SE_FL_ORPHAN) && !(appctx_sc(appctx)->flags & SC_FL_ISBACK)) {
 		stream_free(appctx_strm(appctx));
 		return;
 	}
 	appctx_free(appctx);
 }

 /* reserves a command context of at least <size> bytes in the <appctx>, for
  * use by a CLI command or any regular applet. The pointer to this context is
  * stored in ctx.svcctx and is returned. The caller doesn't need to release
  * it as it's allocated from reserved space. If the size is larger than
  * APPLET_MAX_SVCCTX a crash will occur (hence that will never happen outside
  * of development).
  *
  * Note that the command does *not* initialize the area, so that it can easily
  * be used upon each entry in a function. It's left to the initialization code
  * to do it if needed. The CLI will always zero the whole area before calling
  * a keyword's ->parse() function.
  */
 void *applet_reserve_svcctx(struct appctx *appctx, size_t size)
 {
 	BUG_ON(size > APPLET_MAX_SVCCTX);
 	appctx->svcctx = &appctx->svc.storage;
 	return appctx->svcctx;
 }

 /* This is used to reset an svcctx and the svc.storage without releasing the
  * appctx. In fact this is only used by the CLI applet between commands.
  */
 void applet_reset_svcctx(struct appctx *appctx)
 {
 	memset(&appctx->svc.storage, 0, APPLET_MAX_SVCCTX);
 	appctx->svcctx = NULL;
 }

 /* call the applet's release() function if any, and marks the sedesc as shut.
  * Needs to be called upon close().
  */
 void appctx_shut(struct appctx *appctx)
 {
 	if (se_fl_test(appctx->sedesc, SE_FL_SHR | SE_FL_SHW))
 		return;

 	if (appctx->applet->release)
 		appctx->applet->release(appctx);

 	se_fl_set(appctx->sedesc, SE_FL_SHRR | SE_FL_SHWN);
 }

 /* Callback used to wake up an applet when a buffer is available. The applet
  * <appctx> is woken up if an input buffer was requested for the associated
  * stream connector. In this case the buffer is immediately allocated and the
  * function returns 1. Otherwise it returns 0. Note that this automatically
  * covers multiple wake-up attempts by ensuring that the same buffer will not
  * be accounted for multiple times.
  */
 int appctx_buf_available(void *arg)
 {
 	struct appctx *appctx = arg;
 	struct stconn *sc = appctx_sc(appctx);

 	/* allocation requested ? */
 	if (!(sc->flags & SC_FL_NEED_BUFF))
 		return 0;

 	sc_have_buff(sc);

 	/* was already allocated another way ? if so, don't take this one */
 	if (c_size(sc_ic(sc)) || sc_ic(sc)->pipe)
 		return 0;

 	/* allocation possible now ? */
 	if (!b_alloc(&sc_ic(sc)->buf)) {
 		sc_need_buff(sc);
 		return 0;
 	}

 	task_wakeup(appctx->t, TASK_WOKEN_RES);
 	return 1;
 }

 /* Default applet handler */
 struct task *task_run_applet(struct task *t, void *context, unsigned int state)
 {
 	struct appctx *app = context;
 	struct stconn *sc;
 	unsigned int rate;
 	size_t count;

 	if (app->state & APPLET_WANT_DIE) {
 		__appctx_free(app);
 		return NULL;
 	}

 	if (se_fl_test(app->sedesc, SE_FL_ORPHAN)) {
 		/* Finalize init of orphan appctx. .init callback function must
 		 * be defined and it must finalize appctx startup.
 		 */
 		BUG_ON(!app->applet->init);

 		if (appctx_init(app) == -1) {
 			appctx_free_on_early_error(app);
 			return NULL;
 		}
 		BUG_ON(!app->sess || !appctx_sc(app) || !appctx_strm(app));
 	}

 	sc = appctx_sc(app);

 	/* We always pretend the applet can't get and doesn't want to
 	 * put, it's up to it to change this if needed. This ensures
 	 * that one applet which ignores any event will not spin.
 	 */
 	applet_need_more_data(app);
 	applet_have_no_more_data(app);

 	/* Now we'll try to allocate the input buffer. We wake up the applet in
 	 * all cases. So this is the applet's responsibility to check if this
 	 * buffer was allocated or not. This leaves a chance for applets to do
 	 * some other processing if needed. The applet doesn't have anything to
 	 * do if it needs the buffer, it will be called again upon readiness.
 	 */
 	if (!sc_alloc_ibuf(sc, &app->buffer_wait))
 		applet_have_more_data(app);

 	count = co_data(sc_oc(sc));
 	app->applet->fct(app);

 	/* now check if the applet has released some room and forgot to
 	 * notify the other side about it.
 	 */
 	if (count != co_data(sc_oc(sc))) {
 		sc_oc(sc)->flags |= CF_WRITE_PARTIAL | CF_WROTE_DATA;
 		sc_have_room(sc_opposite(sc));
 	}

 	/* measure the call rate and check for anomalies when too high */
 	if (((b_size(sc_ib(sc)) && sc->flags & SC_FL_NEED_BUFF) || // asks for a buffer which is present
 	     (b_size(sc_ib(sc)) && !b_data(sc_ib(sc)) && sc->flags & SC_FL_NEED_ROOM) || // asks for room in an empty buffer
 	     (b_data(sc_ob(sc)) && sc_is_send_allowed(sc)) || // asks for data already present
 	     (!b_data(sc_ib(sc)) && b_data(sc_ob(sc)) && // didn't return anything ...
 	      (sc_oc(sc)->flags & (CF_WRITE_PARTIAL|CF_SHUTW_NOW)) == CF_SHUTW_NOW))) { // ... and left data pending after a shut
 		rate = update_freq_ctr(&app->call_rate, 1);
 		if (rate >= 100000 && app->call_rate.prev_ctr) // looped like this more than 100k times over last second
 			stream_dump_and_crash(&app->obj_type, read_freq_ctr(&app->call_rate));
 	}

 	sc->app_ops->wake(sc);
 	channel_release_buffer(sc_ic(sc), &app->buffer_wait);
 	return t;
 }
	/*
	* Functions managing applets
	*
	* Copyright 2000-2015 Willy Tarreau <w@1wt.eu>
	*
	* This program is free software; you can redistribute it and/or
	* modify it under the terms of the GNU General Public License
	* as published by the Free Software Foundation; either version
	* 2 of the License, or (at your option) any later version.
	*
	*/

	#include <stdio.h>
	#include <stdlib.h>

	#include <haproxy/api.h>
	#include <haproxy/applet.h>
	#include <haproxy/channel.h>
	#include <haproxy/list.h>
	#include <haproxy/sc_strm.h>
	#include <haproxy/stconn.h>
	#include <haproxy/stream.h>
	#include <haproxy/task.h>

	unsigned int nb_applets = 0;

	DECLARE_POOL(pool_head_appctx, "appctx", sizeof(struct appctx));

	/* Tries to allocate a new appctx and initialize all of its fields. The appctx
	* is returned on success, NULL on failure. The appctx must be released using
	* appctx_free(). <applet> is assigned as the applet, but it can be NULL. <thr>
	* is the thread ID to start the applet on, and a negative value allows the
	* applet to start anywhere. Backend applets may only be created on the current
	* thread.
	*/
	struct appctx appctx_new_on(struct applet applet, struct sedesc *sedesc, int thr)
	{
	struct appctx *appctx;

	/* Backend appctx cannot be started on another thread than the local one */
	BUG_ON(thr != tid && sedesc);

	appctx = pool_zalloc(pool_head_appctx);
	if (unlikely(!appctx))
	goto fail_appctx;

	LIST_INIT(&appctx->wait_entry);
	appctx->obj_type = OBJ_TYPE_APPCTX;
	appctx->applet = applet;
	appctx->sess = NULL;
	if (!sedesc) {
	sedesc = sedesc_new();
	if (!sedesc)
	goto fail_endp;
	sedesc->se = appctx;
	se_fl_set(sedesc, SE_FL_T_APPLET \| SE_FL_ORPHAN);
	}
	appctx->sedesc = sedesc;

	appctx->t = task_new_on(thr);
	if (unlikely(!appctx->t))
	goto fail_task;
	appctx->t->process = task_run_applet;
	appctx->t->context = appctx;

	LIST_INIT(&appctx->buffer_wait.list);
	appctx->buffer_wait.target = appctx;
	appctx->buffer_wait.wakeup_cb = appctx_buf_available;

	_HA_ATOMIC_INC(&nb_applets);
	return appctx;

	fail_task:
	sedesc_free(appctx->sedesc);
	fail_endp:
	pool_free(pool_head_appctx, appctx);
	fail_appctx:
	return NULL;
	}

	/* Finalize the frontend appctx startup. It must not be called for a backend
	* appctx. This function is responsible to create the appctx's session and the
	* frontend stream connector. By transitivity, the stream is also created.
	*
	* It returns 0 on success and -1 on error. In this case, it is the caller
	* responsibility to release the appctx. However, the session is released if it
	* was created. On success, if an error is encountered in the caller function,
	* the stream must be released instead of the appctx. To be sure,
	* appctx_free_on_early_error() must be called in this case.
	*/
	int appctx_finalize_startup(struct appctx appctx, struct proxy px, struct buffer *input)
	{
	struct session *sess;

	/* async startup is only possible for frontend appctx. Thus for orphan
	* appctx. Because no backend appctx can be orphan.
	*/
	BUG_ON(!se_fl_test(appctx->sedesc, SE_FL_ORPHAN));

	sess = session_new(px, NULL, &appctx->obj_type);
	if (!sess)
	return -1;
	if (!sc_new_from_endp(appctx->sedesc, sess, input)) {
	session_free(sess);
	return -1;
	}
	appctx->sess = sess;
	return 0;
	}

	/* Release function to call when an error occurred during init stage of a
	* frontend appctx. For a backend appctx, it just calls appctx_free()
	*/
	void appctx_free_on_early_error(struct appctx *appctx)
	{
	/* If a frontend appctx is attached to a stream connector, release the stream
	* instead of the appctx.
	*/
	if (!se_fl_test(appctx->sedesc, SE_FL_ORPHAN) && !(appctx_sc(appctx)->flags & SC_FL_ISBACK)) {
	stream_free(appctx_strm(appctx));
	return;
	}
	appctx_free(appctx);
	}

	/* reserves a command context of at least <size> bytes in the <appctx>, for
	* use by a CLI command or any regular applet. The pointer to this context is
	* stored in ctx.svcctx and is returned. The caller doesn't need to release
	* it as it's allocated from reserved space. If the size is larger than
	* APPLET_MAX_SVCCTX a crash will occur (hence that will never happen outside
	* of development).
	*
	* Note that the command does not initialize the area, so that it can easily
	* be used upon each entry in a function. It's left to the initialization code
	* to do it if needed. The CLI will always zero the whole area before calling
	* a keyword's ->parse() function.
	*/
	void applet_reserve_svcctx(struct appctx appctx, size_t size)
	{
	BUG_ON(size > APPLET_MAX_SVCCTX);
	appctx->svcctx = &appctx->svc.storage;
	return appctx->svcctx;
	}

	/* This is used to reset an svcctx and the svc.storage without releasing the
	* appctx. In fact this is only used by the CLI applet between commands.
	*/
	void applet_reset_svcctx(struct appctx *appctx)
	{
	memset(&appctx->svc.storage, 0, APPLET_MAX_SVCCTX);
	appctx->svcctx = NULL;
	}

	/* call the applet's release() function if any, and marks the sedesc as shut.
	* Needs to be called upon close().
	*/
	void appctx_shut(struct appctx *appctx)
	{
	if (se_fl_test(appctx->sedesc, SE_FL_SHR \| SE_FL_SHW))
	return;

	if (appctx->applet->release)
	appctx->applet->release(appctx);

	se_fl_set(appctx->sedesc, SE_FL_SHRR \| SE_FL_SHWN);
	}

	/* Callback used to wake up an applet when a buffer is available. The applet
	* <appctx> is woken up if an input buffer was requested for the associated
	* stream connector. In this case the buffer is immediately allocated and the
	* function returns 1. Otherwise it returns 0. Note that this automatically
	* covers multiple wake-up attempts by ensuring that the same buffer will not
	* be accounted for multiple times.
	*/
	int appctx_buf_available(void *arg)
	{
	struct appctx *appctx = arg;
	struct stconn *sc = appctx_sc(appctx);

	/* allocation requested ? */
	if (!(sc->flags & SC_FL_NEED_BUFF))
	return 0;

	sc_have_buff(sc);

	/* was already allocated another way ? if so, don't take this one */
	if (c_size(sc_ic(sc)) \|\| sc_ic(sc)->pipe)
	return 0;

	/* allocation possible now ? */
	if (!b_alloc(&sc_ic(sc)->buf)) {
	sc_need_buff(sc);
	return 0;
	}

	task_wakeup(appctx->t, TASK_WOKEN_RES);
	return 1;
	}

	/* Default applet handler */
	struct task task_run_applet(struct task t, void *context, unsigned int state)
	{
	struct appctx *app = context;
	struct stconn *sc;
	unsigned int rate;
	size_t count;

	if (app->state & APPLET_WANT_DIE) {
	__appctx_free(app);
	return NULL;
	}

	if (se_fl_test(app->sedesc, SE_FL_ORPHAN)) {
	/* Finalize init of orphan appctx. .init callback function must
	* be defined and it must finalize appctx startup.
	*/
	BUG_ON(!app->applet->init);

	if (appctx_init(app) == -1) {
	appctx_free_on_early_error(app);
	return NULL;
	}
	BUG_ON(!app->sess \|\| !appctx_sc(app) \|\| !appctx_strm(app));
	}

	sc = appctx_sc(app);

	/* We always pretend the applet can't get and doesn't want to
	* put, it's up to it to change this if needed. This ensures
	* that one applet which ignores any event will not spin.
	*/
	applet_need_more_data(app);
	applet_have_no_more_data(app);

	/* Now we'll try to allocate the input buffer. We wake up the applet in
	* all cases. So this is the applet's responsibility to check if this
	* buffer was allocated or not. This leaves a chance for applets to do
	* some other processing if needed. The applet doesn't have anything to
	* do if it needs the buffer, it will be called again upon readiness.
	*/
	if (!sc_alloc_ibuf(sc, &app->buffer_wait))
	applet_have_more_data(app);

	count = co_data(sc_oc(sc));
	app->applet->fct(app);

	/* now check if the applet has released some room and forgot to
	* notify the other side about it.
	*/
	if (count != co_data(sc_oc(sc))) {
	sc_oc(sc)->flags \|= CF_WRITE_PARTIAL \| CF_WROTE_DATA;
	sc_have_room(sc_opposite(sc));
	}

	/* measure the call rate and check for anomalies when too high */
	if (((b_size(sc_ib(sc)) && sc->flags & SC_FL_NEED_BUFF) \|\| // asks for a buffer which is present
	(b_size(sc_ib(sc)) && !b_data(sc_ib(sc)) && sc->flags & SC_FL_NEED_ROOM) \|\| // asks for room in an empty buffer
	(b_data(sc_ob(sc)) && sc_is_send_allowed(sc)) \|\| // asks for data already present
	(!b_data(sc_ib(sc)) && b_data(sc_ob(sc)) && // didn't return anything ...
	(sc_oc(sc)->flags & (CF_WRITE_PARTIAL\|CF_SHUTW_NOW)) == CF_SHUTW_NOW))) { // ... and left data pending after a shut
	rate = update_freq_ctr(&app->call_rate, 1);
	if (rate >= 100000 && app->call_rate.prev_ctr) // looped like this more than 100k times over last second
	stream_dump_and_crash(&app->obj_type, read_freq_ctr(&app->call_rate));
	}

	sc->app_ops->wake(sc);
	channel_release_buffer(sc_ic(sc), &app->buffer_wait);
	return t;
	}