src/lb_chash.c - haproxy - Gitiles

 /*
  * Consistent Hash implementation
  * Please consult this very well detailed article for more information :
  * http://www.spiteful.com/2008/03/17/programmers-toolbox-part-3-consistent-hashing/
  *
  * Our implementation has to support both weighted hashing and weighted round
  * robin because we'll use it to replace the previous map-based implementation
  * which offered both algorithms.
  *
  * Copyright 2000-2010 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 <common/compat.h>
 #include <common/config.h>
 #include <common/debug.h>
 #include <common/standard.h>
 #include <eb32tree.h>

 #include <types/global.h>
 #include <types/server.h>

 #include <proto/backend.h>
 #include <proto/queue.h>

 /* Return next tree node after <node> which must still be in the tree, or be
  * NULL. Lookup wraps around the end to the beginning. If the next node is the
  * same node, return NULL. This is designed to find a valid next node before
  * deleting one from the tree.
  */
 static inline struct eb32_node *chash_skip_node(struct eb_root *root, struct eb32_node *node)
 {
 	struct eb32_node *stop = node;

 	if (!node)
 		return NULL;
 	node = eb32_next(node);
 	if (!node)
 		node = eb32_first(root);
 	if (node == stop)
 		return NULL;
 	return node;
 }

 /* Remove all of a server's entries from its tree. This may be used when
  * setting a server down.
  */
 static inline void chash_dequeue_srv(struct server *s)
 {
 	while (s->lb_nodes_now > 0) {
 		if (s->lb_nodes_now >= s->lb_nodes_tot) // should always be false anyway
 			s->lb_nodes_now = s->lb_nodes_tot;
 		s->lb_nodes_now--;
 		if (s->proxy->lbprm.chash.last == &s->lb_nodes[s->lb_nodes_now].node)
 			s->proxy->lbprm.chash.last = chash_skip_node(s->lb_tree, s->proxy->lbprm.chash.last);
 		eb32_delete(&s->lb_nodes[s->lb_nodes_now].node);
 	}
 }

 /* Adjust the number of entries of a server in its tree. The server must appear
  * as many times as its weight indicates it. If it's there too often, we remove
  * the last occurrences. If it's not there enough, we add more occurrences. To
  * remove a server from the tree, normally call this with eweight=0.
  *
  * The server's lock and the lbprm's lock must be held.
  */
 static inline void chash_queue_dequeue_srv(struct server *s)
 {
 	while (s->lb_nodes_now > s->next_eweight) {
 		if (s->lb_nodes_now >= s->lb_nodes_tot) // should always be false anyway
 			s->lb_nodes_now = s->lb_nodes_tot;
 		s->lb_nodes_now--;
 		if (s->proxy->lbprm.chash.last == &s->lb_nodes[s->lb_nodes_now].node)
 			s->proxy->lbprm.chash.last = chash_skip_node(s->lb_tree, s->proxy->lbprm.chash.last);
 		eb32_delete(&s->lb_nodes[s->lb_nodes_now].node);
 	}

 	/* Attempt to increase the total number of nodes, if the user
 	 * increased the weight beyond the original weight
 	 */
 	if (s->lb_nodes_tot < s->next_eweight) {
 		struct tree_occ *new_nodes;

 		/* First we need to remove all server's entries from its tree
 		 * because the realloc will change all nodes pointers */
 		chash_dequeue_srv(s);

 		new_nodes = realloc(s->lb_nodes, s->next_eweight * sizeof(*new_nodes));
 		if (new_nodes) {
 			unsigned int j;

 			s->lb_nodes = new_nodes;
 			memset(&s->lb_nodes[s->lb_nodes_tot], 0,
 			    (s->next_eweight - s->lb_nodes_tot) * sizeof(*s->lb_nodes));
 			for (j = s->lb_nodes_tot; j < s->next_eweight; j++) {
 				s->lb_nodes[j].server = s;
 				s->lb_nodes[j].node.key = full_hash(s->puid * SRV_EWGHT_RANGE + j);
 			}
 			s->lb_nodes_tot = s->next_eweight;
 		}
 	}
 	while (s->lb_nodes_now < s->next_eweight) {
 		if (s->lb_nodes_now >= s->lb_nodes_tot) // should always be false anyway
 			break;
 		if (s->proxy->lbprm.chash.last == &s->lb_nodes[s->lb_nodes_now].node)
 			s->proxy->lbprm.chash.last = chash_skip_node(s->lb_tree, s->proxy->lbprm.chash.last);
 		eb32_insert(s->lb_tree, &s->lb_nodes[s->lb_nodes_now].node);
 		s->lb_nodes_now++;
 	}
 }

 /* This function updates the server trees according to server <srv>'s new
  * state. It should be called when server <srv>'s status changes to down.
  * It is not important whether the server was already down or not. It is not
  * important either that the new state is completely down (the caller may not
  * know all the variables of a server's state).
  *
  * The server's lock must be held. The lbprm lock will be used.
  */
 static void chash_set_server_status_down(struct server *srv)
 {
 	struct proxy *p = srv->proxy;

 	if (!srv_lb_status_changed(srv))
                return;

 	HA_SPIN_LOCK(LBPRM_LOCK, &p->lbprm.lock);

 	if (srv_willbe_usable(srv))
 		goto out_update_state;

 	if (!srv_currently_usable(srv))
 		/* server was already down */
 		goto out_update_backend;

 	if (srv->flags & SRV_F_BACKUP) {
 		p->lbprm.tot_wbck -= srv->cur_eweight;
 		p->srv_bck--;

 		if (srv == p->lbprm.fbck) {
 			/* we lost the first backup server in a single-backup
 			 * configuration, we must search another one.
 			 */
 			struct server *srv2 = p->lbprm.fbck;
 			do {
 				srv2 = srv2->next;
 			} while (srv2 &&
 				 !((srv2->flags & SRV_F_BACKUP) &&
 				   srv_willbe_usable(srv2)));
 			p->lbprm.fbck = srv2;
 		}
 	} else {
 		p->lbprm.tot_wact -= srv->cur_eweight;
 		p->srv_act--;
 	}

 	chash_dequeue_srv(srv);

 out_update_backend:
 	/* check/update tot_used, tot_weight */
 	update_backend_weight(p);
  out_update_state:
 	srv_lb_commit_status(srv);

 	HA_SPIN_UNLOCK(LBPRM_LOCK, &p->lbprm.lock);
 }

 /* This function updates the server trees according to server <srv>'s new
  * state. It should be called when server <srv>'s status changes to up.
  * It is not important whether the server was already down or not. It is not
  * important either that the new state is completely UP (the caller may not
  * know all the variables of a server's state). This function will not change
  * the weight of a server which was already up.
  *
  * The server's lock must be held. The lbprm lock will be used.
  */
 static void chash_set_server_status_up(struct server *srv)
 {
 	struct proxy *p = srv->proxy;

 	if (!srv_lb_status_changed(srv))
                return;

 	HA_SPIN_LOCK(LBPRM_LOCK, &p->lbprm.lock);

 	if (!srv_willbe_usable(srv))
 		goto out_update_state;

 	if (srv_currently_usable(srv))
 		/* server was already up */
 		goto out_update_backend;

 	if (srv->flags & SRV_F_BACKUP) {
 		p->lbprm.tot_wbck += srv->next_eweight;
 		p->srv_bck++;

 		if (!(p->options & PR_O_USE_ALL_BK)) {
 			if (!p->lbprm.fbck) {
 				/* there was no backup server anymore */
 				p->lbprm.fbck = srv;
 			} else {
 				/* we may have restored a backup server prior to fbck,
 				 * in which case it should replace it.
 				 */
 				struct server *srv2 = srv;
 				do {
 					srv2 = srv2->next;
 				} while (srv2 && (srv2 != p->lbprm.fbck));
 				if (srv2)
 					p->lbprm.fbck = srv;
 			}
 		}
 	} else {
 		p->lbprm.tot_wact += srv->next_eweight;
 		p->srv_act++;
 	}

 	/* note that eweight cannot be 0 here */
 	chash_queue_dequeue_srv(srv);

  out_update_backend:
 	/* check/update tot_used, tot_weight */
 	update_backend_weight(p);
  out_update_state:
 	srv_lb_commit_status(srv);

 	HA_SPIN_UNLOCK(LBPRM_LOCK, &p->lbprm.lock);
 }

 /* This function must be called after an update to server <srv>'s effective
  * weight. It may be called after a state change too.
  *
  * The server's lock must be held. The lbprm lock may be used.
  */
 static void chash_update_server_weight(struct server *srv)
 {
 	int old_state, new_state;
 	struct proxy *p = srv->proxy;

 	if (!srv_lb_status_changed(srv))
 		return;

 	/* If changing the server's weight changes its state, we simply apply
 	 * the procedures we already have for status change. If the state
 	 * remains down, the server is not in any tree, so it's as easy as
 	 * updating its values. If the state remains up with different weights,
 	 * there are some computations to perform to find a new place and
 	 * possibly a new tree for this server.
 	 */

 	old_state = srv_currently_usable(srv);
 	new_state = srv_willbe_usable(srv);

 	if (!old_state && !new_state) {
 		srv_lb_commit_status(srv);
 		return;
 	}
 	else if (!old_state && new_state) {
 		chash_set_server_status_up(srv);
 		return;
 	}
 	else if (old_state && !new_state) {
 		chash_set_server_status_down(srv);
 		return;
 	}

 	HA_SPIN_LOCK(LBPRM_LOCK, &p->lbprm.lock);

 	/* only adjust the server's presence in the tree */
 	chash_queue_dequeue_srv(srv);

 	if (srv->flags & SRV_F_BACKUP)
 		p->lbprm.tot_wbck += srv->next_eweight - srv->cur_eweight;
 	else
 		p->lbprm.tot_wact += srv->next_eweight - srv->cur_eweight;

 	update_backend_weight(p);
 	srv_lb_commit_status(srv);

 	HA_SPIN_UNLOCK(LBPRM_LOCK, &p->lbprm.lock);
 }

 /*
  * This function implements the "Consistent Hashing with Bounded Loads" algorithm
  * of Mirrokni, Thorup, and Zadimoghaddam (arxiv:1608.01350), adapted for use with
  * unequal server weights.
  */
 int chash_server_is_eligible(struct server *s)
 {
 	/* The total number of slots to allocate is the total number of outstanding requests
 	 * (including the one we're about to make) times the load-balance-factor, rounded up.
 	 */
 	unsigned tot_slots = ((s->proxy->served + 1) * s->proxy->lbprm.hash_balance_factor + 99) / 100;
 	unsigned slots_per_weight = tot_slots / s->proxy->lbprm.tot_weight;
 	unsigned remainder = tot_slots % s->proxy->lbprm.tot_weight;

 	/* Allocate a whole number of slots per weight unit... */
 	unsigned slots = s->cur_eweight * slots_per_weight;

 	/* And then distribute the rest among servers proportionally to their weight. */
 	slots += ((s->cumulative_weight + s->cur_eweight) * remainder) / s->proxy->lbprm.tot_weight
 		- (s->cumulative_weight * remainder) / s->proxy->lbprm.tot_weight;

 	/* But never leave a server with 0. */
 	if (slots == 0)
 		slots = 1;

 	return s->served < slots;
 }

 /*
  * This function returns the running server from the CHASH tree, which is at
  * the closest distance from the value of <hash>. Doing so ensures that even
  * with a well imbalanced hash, if some servers are close to each other, they
  * will still both receive traffic. If any server is found, it will be returned.
  * It will also skip server <avoid> if the hash result ends on this one.
  * If no valid server is found, NULL is returned.
  */
 struct server *chash_get_server_hash(struct proxy *p, unsigned int hash, const struct server *avoid)
 {
 	struct eb32_node *next, *prev;
 	struct server *nsrv, *psrv;
 	struct eb_root *root;
 	unsigned int dn, dp;
 	int loop;

 	HA_SPIN_LOCK(LBPRM_LOCK, &p->lbprm.lock);

 	if (p->srv_act)
 		root = &p->lbprm.chash.act;
 	else if (p->lbprm.fbck) {
 		nsrv = p->lbprm.fbck;
 		goto out;
 	}
 	else if (p->srv_bck)
 		root = &p->lbprm.chash.bck;
 	else {
 		nsrv = NULL;
 		goto out;
 	}

 	/* find the node after and the node before */
 	next = eb32_lookup_ge(root, hash);
 	if (!next)
 		next = eb32_first(root);
 	if (!next) {
 		nsrv = NULL; /* tree is empty */
 		goto out;
 	}

 	prev = eb32_prev(next);
 	if (!prev)
 		prev = eb32_last(root);

 	nsrv = eb32_entry(next, struct tree_occ, node)->server;
 	psrv = eb32_entry(prev, struct tree_occ, node)->server;

 	/* OK we're located between two servers, let's
 	 * compare distances between hash and the two servers
 	 * and select the closest server.
 	 */
 	dp = hash - prev->key;
 	dn = next->key - hash;

 	if (dp <= dn) {
 		next = prev;
 		nsrv = psrv;
 	}

 	loop = 0;
 	while (nsrv == avoid || (p->lbprm.hash_balance_factor && !chash_server_is_eligible(nsrv))) {
 		next = eb32_next(next);
 		if (!next) {
 			next = eb32_first(root);
 			if (++loop > 1) // protection against accidental loop
 				break;
 		}
 		nsrv = eb32_entry(next, struct tree_occ, node)->server;
 	}

  out:
 	HA_SPIN_UNLOCK(LBPRM_LOCK, &p->lbprm.lock);
 	return nsrv;
 }

 /* Return next server from the CHASH tree in backend <p>. If the tree is empty,
  * return NULL. Saturated servers are skipped.
  */
 struct server *chash_get_next_server(struct proxy *p, struct server *srvtoavoid)
 {
 	struct server *srv, *avoided;
 	struct eb32_node *node, *stop, *avoided_node;
 	struct eb_root *root;

 	srv = avoided = NULL;
 	avoided_node = NULL;

 	HA_SPIN_LOCK(LBPRM_LOCK, &p->lbprm.lock);
 	if (p->srv_act)
 		root = &p->lbprm.chash.act;
 	else if (p->lbprm.fbck) {
 		srv = p->lbprm.fbck;
 		goto out;
 	}
 	else if (p->srv_bck)
 		root = &p->lbprm.chash.bck;
 	else {
 		srv = NULL;
 		goto out;
 	}

 	stop = node = p->lbprm.chash.last;
 	do {
 		struct server *s;

 		if (node)
 			node = eb32_next(node);
 		if (!node)
 			node = eb32_first(root);

 		p->lbprm.chash.last = node;
 		if (!node) {
 			/* no node is available */
 			srv = NULL;
 			goto out;
 		}

 		/* Note: if we came here after a down/up cycle with no last
 		 * pointer, and after a redispatch (srvtoavoid is set), we
 		 * must set stop to non-null otherwise we can loop forever.
 		 */
 		if (!stop)
 			stop = node;

 		/* OK, we have a server. However, it may be saturated, in which
 		 * case we don't want to reconsider it for now, so we'll simply
 		 * skip it. Same if it's the server we try to avoid, in which
 		 * case we simply remember it for later use if needed.
 		 */
 		s = eb32_entry(node, struct tree_occ, node)->server;
 		if (!s->maxconn || (!s->nbpend && s->served < srv_dynamic_maxconn(s))) {
 			if (s != srvtoavoid) {
 				srv = s;
 				break;
 			}
 			avoided = s;
 			avoided_node = node;
 		}
 	} while (node != stop);

 	if (!srv) {
 		srv = avoided;
 		p->lbprm.chash.last = avoided_node;
 	}

  out:
 	HA_SPIN_UNLOCK(LBPRM_LOCK, &p->lbprm.lock);
 	return srv;
 }

 /* This function is responsible for building the active and backup trees for
  * constistent hashing. The servers receive an array of initialized nodes
  * with their assigned keys. It also sets p->lbprm.wdiv to the eweight to
  * uweight ratio.
  */
 void chash_init_server_tree(struct proxy *p)
 {
 	struct server *srv;
 	struct eb_root init_head = EB_ROOT;
 	int node;

 	p->lbprm.set_server_status_up   = chash_set_server_status_up;
 	p->lbprm.set_server_status_down = chash_set_server_status_down;
 	p->lbprm.update_server_eweight  = chash_update_server_weight;
 	p->lbprm.server_take_conn = NULL;
 	p->lbprm.server_drop_conn = NULL;

 	p->lbprm.wdiv = BE_WEIGHT_SCALE;
 	for (srv = p->srv; srv; srv = srv->next) {
 		srv->next_eweight = (srv->uweight * p->lbprm.wdiv + p->lbprm.wmult - 1) / p->lbprm.wmult;
 		srv_lb_commit_status(srv);
 	}

 	recount_servers(p);
 	update_backend_weight(p);

 	p->lbprm.chash.act = init_head;
 	p->lbprm.chash.bck = init_head;
 	p->lbprm.chash.last = NULL;

 	/* queue active and backup servers in two distinct groups */
 	for (srv = p->srv; srv; srv = srv->next) {
 		srv->lb_tree = (srv->flags & SRV_F_BACKUP) ? &p->lbprm.chash.bck : &p->lbprm.chash.act;
 		srv->lb_nodes_tot = srv->uweight * BE_WEIGHT_SCALE;
 		srv->lb_nodes_now = 0;
 		srv->lb_nodes = calloc(srv->lb_nodes_tot, sizeof(struct tree_occ));
 		for (node = 0; node < srv->lb_nodes_tot; node++) {
 			srv->lb_nodes[node].server = srv;
 			srv->lb_nodes[node].node.key = full_hash(srv->puid * SRV_EWGHT_RANGE + node);
 		}

 		if (srv_currently_usable(srv))
 			chash_queue_dequeue_srv(srv);
 	}
 }
	/*
	* Consistent Hash implementation
	* Please consult this very well detailed article for more information :
	* http://www.spiteful.com/2008/03/17/programmers-toolbox-part-3-consistent-hashing/
	*
	* Our implementation has to support both weighted hashing and weighted round
	* robin because we'll use it to replace the previous map-based implementation
	* which offered both algorithms.
	*
	* Copyright 2000-2010 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 <common/compat.h>
	#include <common/config.h>
	#include <common/debug.h>
	#include <common/standard.h>
	#include <eb32tree.h>

	#include <types/global.h>
	#include <types/server.h>

	#include <proto/backend.h>
	#include <proto/queue.h>

	/* Return next tree node after <node> which must still be in the tree, or be
	* NULL. Lookup wraps around the end to the beginning. If the next node is the
	* same node, return NULL. This is designed to find a valid next node before
	* deleting one from the tree.
	*/
	static inline struct eb32_node chash_skip_node(struct eb_root root, struct eb32_node *node)
	{
	struct eb32_node *stop = node;

	if (!node)
	return NULL;
	node = eb32_next(node);
	if (!node)
	node = eb32_first(root);
	if (node == stop)
	return NULL;
	return node;
	}

	/* Remove all of a server's entries from its tree. This may be used when
	* setting a server down.
	*/
	static inline void chash_dequeue_srv(struct server *s)
	{
	while (s->lb_nodes_now > 0) {
	if (s->lb_nodes_now >= s->lb_nodes_tot) // should always be false anyway
	s->lb_nodes_now = s->lb_nodes_tot;
	s->lb_nodes_now--;
	if (s->proxy->lbprm.chash.last == &s->lb_nodes[s->lb_nodes_now].node)
	s->proxy->lbprm.chash.last = chash_skip_node(s->lb_tree, s->proxy->lbprm.chash.last);
	eb32_delete(&s->lb_nodes[s->lb_nodes_now].node);
	}
	}

	/* Adjust the number of entries of a server in its tree. The server must appear
	* as many times as its weight indicates it. If it's there too often, we remove
	* the last occurrences. If it's not there enough, we add more occurrences. To
	* remove a server from the tree, normally call this with eweight=0.
	*
	* The server's lock and the lbprm's lock must be held.
	*/
	static inline void chash_queue_dequeue_srv(struct server *s)
	{
	while (s->lb_nodes_now > s->next_eweight) {
	if (s->lb_nodes_now >= s->lb_nodes_tot) // should always be false anyway
	s->lb_nodes_now = s->lb_nodes_tot;
	s->lb_nodes_now--;
	if (s->proxy->lbprm.chash.last == &s->lb_nodes[s->lb_nodes_now].node)
	s->proxy->lbprm.chash.last = chash_skip_node(s->lb_tree, s->proxy->lbprm.chash.last);
	eb32_delete(&s->lb_nodes[s->lb_nodes_now].node);
	}

	/* Attempt to increase the total number of nodes, if the user
	* increased the weight beyond the original weight
	*/
	if (s->lb_nodes_tot < s->next_eweight) {
	struct tree_occ *new_nodes;

	/* First we need to remove all server's entries from its tree
	* because the realloc will change all nodes pointers */
	chash_dequeue_srv(s);

	new_nodes = realloc(s->lb_nodes, s->next_eweight * sizeof(*new_nodes));
	if (new_nodes) {
	unsigned int j;

	s->lb_nodes = new_nodes;
	memset(&s->lb_nodes[s->lb_nodes_tot], 0,
	(s->next_eweight - s->lb_nodes_tot) * sizeof(*s->lb_nodes));
	for (j = s->lb_nodes_tot; j < s->next_eweight; j++) {
	s->lb_nodes[j].server = s;
	s->lb_nodes[j].node.key = full_hash(s->puid * SRV_EWGHT_RANGE + j);
	}
	s->lb_nodes_tot = s->next_eweight;
	}
	}
	while (s->lb_nodes_now < s->next_eweight) {
	if (s->lb_nodes_now >= s->lb_nodes_tot) // should always be false anyway
	break;
	if (s->proxy->lbprm.chash.last == &s->lb_nodes[s->lb_nodes_now].node)
	s->proxy->lbprm.chash.last = chash_skip_node(s->lb_tree, s->proxy->lbprm.chash.last);
	eb32_insert(s->lb_tree, &s->lb_nodes[s->lb_nodes_now].node);
	s->lb_nodes_now++;
	}
	}

	/* This function updates the server trees according to server <srv>'s new
	* state. It should be called when server <srv>'s status changes to down.
	* It is not important whether the server was already down or not. It is not
	* important either that the new state is completely down (the caller may not
	* know all the variables of a server's state).
	*
	* The server's lock must be held. The lbprm lock will be used.
	*/
	static void chash_set_server_status_down(struct server *srv)
	{
	struct proxy *p = srv->proxy;

	if (!srv_lb_status_changed(srv))
	return;

	HA_SPIN_LOCK(LBPRM_LOCK, &p->lbprm.lock);

	if (srv_willbe_usable(srv))
	goto out_update_state;

	if (!srv_currently_usable(srv))
	/* server was already down */
	goto out_update_backend;

	if (srv->flags & SRV_F_BACKUP) {
	p->lbprm.tot_wbck -= srv->cur_eweight;
	p->srv_bck--;

	if (srv == p->lbprm.fbck) {
	/* we lost the first backup server in a single-backup
	* configuration, we must search another one.
	*/
	struct server *srv2 = p->lbprm.fbck;
	do {
	srv2 = srv2->next;
	} while (srv2 &&
	!((srv2->flags & SRV_F_BACKUP) &&
	srv_willbe_usable(srv2)));
	p->lbprm.fbck = srv2;
	}
	} else {
	p->lbprm.tot_wact -= srv->cur_eweight;
	p->srv_act--;
	}

	chash_dequeue_srv(srv);

	out_update_backend:
	/* check/update tot_used, tot_weight */
	update_backend_weight(p);
	out_update_state:
	srv_lb_commit_status(srv);

	HA_SPIN_UNLOCK(LBPRM_LOCK, &p->lbprm.lock);
	}

	/* This function updates the server trees according to server <srv>'s new
	* state. It should be called when server <srv>'s status changes to up.
	* It is not important whether the server was already down or not. It is not
	* important either that the new state is completely UP (the caller may not
	* know all the variables of a server's state). This function will not change
	* the weight of a server which was already up.
	*
	* The server's lock must be held. The lbprm lock will be used.
	*/
	static void chash_set_server_status_up(struct server *srv)
	{
	struct proxy *p = srv->proxy;

	if (!srv_lb_status_changed(srv))
	return;

	HA_SPIN_LOCK(LBPRM_LOCK, &p->lbprm.lock);

	if (!srv_willbe_usable(srv))
	goto out_update_state;

	if (srv_currently_usable(srv))
	/* server was already up */
	goto out_update_backend;

	if (srv->flags & SRV_F_BACKUP) {
	p->lbprm.tot_wbck += srv->next_eweight;
	p->srv_bck++;

	if (!(p->options & PR_O_USE_ALL_BK)) {
	if (!p->lbprm.fbck) {
	/* there was no backup server anymore */
	p->lbprm.fbck = srv;
	} else {
	/* we may have restored a backup server prior to fbck,
	* in which case it should replace it.
	*/
	struct server *srv2 = srv;
	do {
	srv2 = srv2->next;
	} while (srv2 && (srv2 != p->lbprm.fbck));
	if (srv2)
	p->lbprm.fbck = srv;
	}
	}
	} else {
	p->lbprm.tot_wact += srv->next_eweight;
	p->srv_act++;
	}

	/* note that eweight cannot be 0 here */
	chash_queue_dequeue_srv(srv);

	out_update_backend:
	/* check/update tot_used, tot_weight */
	update_backend_weight(p);
	out_update_state:
	srv_lb_commit_status(srv);

	HA_SPIN_UNLOCK(LBPRM_LOCK, &p->lbprm.lock);
	}

	/* This function must be called after an update to server <srv>'s effective
	* weight. It may be called after a state change too.
	*
	* The server's lock must be held. The lbprm lock may be used.
	*/
	static void chash_update_server_weight(struct server *srv)
	{
	int old_state, new_state;
	struct proxy *p = srv->proxy;

	if (!srv_lb_status_changed(srv))
	return;

	/* If changing the server's weight changes its state, we simply apply
	* the procedures we already have for status change. If the state
	* remains down, the server is not in any tree, so it's as easy as
	* updating its values. If the state remains up with different weights,
	* there are some computations to perform to find a new place and
	* possibly a new tree for this server.
	*/

	old_state = srv_currently_usable(srv);
	new_state = srv_willbe_usable(srv);

	if (!old_state && !new_state) {
	srv_lb_commit_status(srv);
	return;
	}
	else if (!old_state && new_state) {
	chash_set_server_status_up(srv);
	return;
	}
	else if (old_state && !new_state) {
	chash_set_server_status_down(srv);
	return;
	}

	HA_SPIN_LOCK(LBPRM_LOCK, &p->lbprm.lock);

	/* only adjust the server's presence in the tree */
	chash_queue_dequeue_srv(srv);

	if (srv->flags & SRV_F_BACKUP)
	p->lbprm.tot_wbck += srv->next_eweight - srv->cur_eweight;
	else
	p->lbprm.tot_wact += srv->next_eweight - srv->cur_eweight;

	update_backend_weight(p);
	srv_lb_commit_status(srv);

	HA_SPIN_UNLOCK(LBPRM_LOCK, &p->lbprm.lock);
	}

	/*
	* This function implements the "Consistent Hashing with Bounded Loads" algorithm
	* of Mirrokni, Thorup, and Zadimoghaddam (arxiv:1608.01350), adapted for use with
	* unequal server weights.
	*/
	int chash_server_is_eligible(struct server *s)
	{
	/* The total number of slots to allocate is the total number of outstanding requests
	* (including the one we're about to make) times the load-balance-factor, rounded up.
	*/
	unsigned tot_slots = ((s->proxy->served + 1) * s->proxy->lbprm.hash_balance_factor + 99) / 100;
	unsigned slots_per_weight = tot_slots / s->proxy->lbprm.tot_weight;
	unsigned remainder = tot_slots % s->proxy->lbprm.tot_weight;

	/* Allocate a whole number of slots per weight unit... */
	unsigned slots = s->cur_eweight * slots_per_weight;

	/* And then distribute the rest among servers proportionally to their weight. */
	slots += ((s->cumulative_weight + s->cur_eweight) * remainder) / s->proxy->lbprm.tot_weight
	- (s->cumulative_weight * remainder) / s->proxy->lbprm.tot_weight;

	/* But never leave a server with 0. */
	if (slots == 0)
	slots = 1;

	return s->served < slots;
	}

	/*
	* This function returns the running server from the CHASH tree, which is at
	* the closest distance from the value of <hash>. Doing so ensures that even
	* with a well imbalanced hash, if some servers are close to each other, they
	* will still both receive traffic. If any server is found, it will be returned.
	* It will also skip server <avoid> if the hash result ends on this one.
	* If no valid server is found, NULL is returned.
	*/
	struct server chash_get_server_hash(struct proxy p, unsigned int hash, const struct server *avoid)
	{
	struct eb32_node next, prev;
	struct server nsrv, psrv;
	struct eb_root *root;
	unsigned int dn, dp;
	int loop;

	HA_SPIN_LOCK(LBPRM_LOCK, &p->lbprm.lock);

	if (p->srv_act)
	root = &p->lbprm.chash.act;
	else if (p->lbprm.fbck) {
	nsrv = p->lbprm.fbck;
	goto out;
	}
	else if (p->srv_bck)
	root = &p->lbprm.chash.bck;
	else {
	nsrv = NULL;
	goto out;
	}

	/* find the node after and the node before */
	next = eb32_lookup_ge(root, hash);
	if (!next)
	next = eb32_first(root);
	if (!next) {
	nsrv = NULL; /* tree is empty */
	goto out;
	}

	prev = eb32_prev(next);
	if (!prev)
	prev = eb32_last(root);

	nsrv = eb32_entry(next, struct tree_occ, node)->server;
	psrv = eb32_entry(prev, struct tree_occ, node)->server;

	/* OK we're located between two servers, let's
	* compare distances between hash and the two servers
	* and select the closest server.
	*/
	dp = hash - prev->key;
	dn = next->key - hash;

	if (dp <= dn) {
	next = prev;
	nsrv = psrv;
	}

	loop = 0;
	while (nsrv == avoid \|\| (p->lbprm.hash_balance_factor && !chash_server_is_eligible(nsrv))) {
	next = eb32_next(next);
	if (!next) {
	next = eb32_first(root);
	if (++loop > 1) // protection against accidental loop
	break;
	}
	nsrv = eb32_entry(next, struct tree_occ, node)->server;
	}

	out:
	HA_SPIN_UNLOCK(LBPRM_LOCK, &p->lbprm.lock);
	return nsrv;
	}

	/* Return next server from the CHASH tree in backend <p>. If the tree is empty,
	* return NULL. Saturated servers are skipped.
	*/
	struct server chash_get_next_server(struct proxy p, struct server *srvtoavoid)
	{
	struct server srv, avoided;
	struct eb32_node node, stop, *avoided_node;
	struct eb_root *root;

	srv = avoided = NULL;
	avoided_node = NULL;

	HA_SPIN_LOCK(LBPRM_LOCK, &p->lbprm.lock);
	if (p->srv_act)
	root = &p->lbprm.chash.act;
	else if (p->lbprm.fbck) {
	srv = p->lbprm.fbck;
	goto out;
	}
	else if (p->srv_bck)
	root = &p->lbprm.chash.bck;
	else {
	srv = NULL;
	goto out;
	}

	stop = node = p->lbprm.chash.last;
	do {
	struct server *s;

	if (node)
	node = eb32_next(node);
	if (!node)
	node = eb32_first(root);

	p->lbprm.chash.last = node;
	if (!node) {
	/* no node is available */
	srv = NULL;
	goto out;
	}

	/* Note: if we came here after a down/up cycle with no last
	* pointer, and after a redispatch (srvtoavoid is set), we
	* must set stop to non-null otherwise we can loop forever.
	*/
	if (!stop)
	stop = node;

	/* OK, we have a server. However, it may be saturated, in which
	* case we don't want to reconsider it for now, so we'll simply
	* skip it. Same if it's the server we try to avoid, in which
	* case we simply remember it for later use if needed.
	*/
	s = eb32_entry(node, struct tree_occ, node)->server;
	if (!s->maxconn \|\| (!s->nbpend && s->served < srv_dynamic_maxconn(s))) {
	if (s != srvtoavoid) {
	srv = s;
	break;
	}
	avoided = s;
	avoided_node = node;
	}
	} while (node != stop);

	if (!srv) {
	srv = avoided;
	p->lbprm.chash.last = avoided_node;
	}

	out:
	HA_SPIN_UNLOCK(LBPRM_LOCK, &p->lbprm.lock);
	return srv;
	}

	/* This function is responsible for building the active and backup trees for
	* constistent hashing. The servers receive an array of initialized nodes
	* with their assigned keys. It also sets p->lbprm.wdiv to the eweight to
	* uweight ratio.
	*/
	void chash_init_server_tree(struct proxy *p)
	{
	struct server *srv;
	struct eb_root init_head = EB_ROOT;
	int node;

	p->lbprm.set_server_status_up = chash_set_server_status_up;
	p->lbprm.set_server_status_down = chash_set_server_status_down;
	p->lbprm.update_server_eweight = chash_update_server_weight;
	p->lbprm.server_take_conn = NULL;
	p->lbprm.server_drop_conn = NULL;

	p->lbprm.wdiv = BE_WEIGHT_SCALE;
	for (srv = p->srv; srv; srv = srv->next) {
	srv->next_eweight = (srv->uweight * p->lbprm.wdiv + p->lbprm.wmult - 1) / p->lbprm.wmult;
	srv_lb_commit_status(srv);
	}

	recount_servers(p);
	update_backend_weight(p);

	p->lbprm.chash.act = init_head;
	p->lbprm.chash.bck = init_head;
	p->lbprm.chash.last = NULL;

	/* queue active and backup servers in two distinct groups */
	for (srv = p->srv; srv; srv = srv->next) {
	srv->lb_tree = (srv->flags & SRV_F_BACKUP) ? &p->lbprm.chash.bck : &p->lbprm.chash.act;
	srv->lb_nodes_tot = srv->uweight * BE_WEIGHT_SCALE;
	srv->lb_nodes_now = 0;
	srv->lb_nodes = calloc(srv->lb_nodes_tot, sizeof(struct tree_occ));
	for (node = 0; node < srv->lb_nodes_tot; node++) {
	srv->lb_nodes[node].server = srv;
	srv->lb_nodes[node].node.key = full_hash(srv->puid * SRV_EWGHT_RANGE + node);
	}

	if (srv_currently_usable(srv))
	chash_queue_dequeue_srv(srv);
	}
	}