/* * Fast Weighted Round Robin load balancing algorithm. * * Copyright 2000-2009 Willy Tarreau * * 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 #include #include #include #include static inline void fwrr_remove_from_tree(struct server *s); static inline void fwrr_queue_by_weight(struct eb_root *root, struct server *s); static inline void fwrr_dequeue_srv(struct server *s); static void fwrr_get_srv(struct server *s); static void fwrr_queue_srv(struct server *s); /* This function updates the server trees according to server 's new * state. It should be called when server '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's lock will be used. */ static void fwrr_set_server_status_down(struct server *srv) { struct proxy *p = srv->proxy; struct fwrr_group *grp; if (!srv_lb_status_changed(srv)) return; if (srv_willbe_usable(srv)) goto out_update_state; HA_RWLOCK_WRLOCK(LBPRM_LOCK, &p->lbprm.lock); if (!srv_currently_usable(srv)) /* server was already down */ goto out_update_backend; grp = (srv->flags & SRV_F_BACKUP) ? &p->lbprm.fwrr.bck : &p->lbprm.fwrr.act; grp->next_weight -= srv->cur_eweight; if (srv->flags & SRV_F_BACKUP) { p->lbprm.tot_wbck = p->lbprm.fwrr.bck.next_weight; 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 = p->lbprm.fwrr.act.next_weight; p->srv_act--; } fwrr_dequeue_srv(srv); fwrr_remove_from_tree(srv); out_update_backend: /* check/update tot_used, tot_weight */ update_backend_weight(p); HA_RWLOCK_WRUNLOCK(LBPRM_LOCK, &p->lbprm.lock); out_update_state: srv_lb_commit_status(srv); } /* This function updates the server trees according to server 's new * state. It should be called when server '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's lock will be used. */ static void fwrr_set_server_status_up(struct server *srv) { struct proxy *p = srv->proxy; struct fwrr_group *grp; if (!srv_lb_status_changed(srv)) return; if (!srv_willbe_usable(srv)) goto out_update_state; HA_RWLOCK_WRLOCK(LBPRM_LOCK, &p->lbprm.lock); if (srv_currently_usable(srv)) /* server was already up */ goto out_update_backend; grp = (srv->flags & SRV_F_BACKUP) ? &p->lbprm.fwrr.bck : &p->lbprm.fwrr.act; grp->next_weight += srv->next_eweight; if (srv->flags & SRV_F_BACKUP) { p->lbprm.tot_wbck = p->lbprm.fwrr.bck.next_weight; 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 = p->lbprm.fwrr.act.next_weight; p->srv_act++; } /* note that eweight cannot be 0 here */ fwrr_get_srv(srv); srv->npos = grp->curr_pos + (grp->next_weight + grp->curr_weight - grp->curr_pos) / srv->next_eweight; fwrr_queue_srv(srv); out_update_backend: /* check/update tot_used, tot_weight */ update_backend_weight(p); HA_RWLOCK_WRUNLOCK(LBPRM_LOCK, &p->lbprm.lock); out_update_state: srv_lb_commit_status(srv); } /* This function must be called after an update to server 's effective * weight. It may be called after a state change too. * * The server's lock must be held. The lbprm's lock will be used. */ static void fwrr_update_server_weight(struct server *srv) { int old_state, new_state; struct proxy *p = srv->proxy; struct fwrr_group *grp; 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) { fwrr_set_server_status_up(srv); return; } else if (old_state && !new_state) { fwrr_set_server_status_down(srv); return; } HA_RWLOCK_WRLOCK(LBPRM_LOCK, &p->lbprm.lock); grp = (srv->flags & SRV_F_BACKUP) ? &p->lbprm.fwrr.bck : &p->lbprm.fwrr.act; grp->next_weight = grp->next_weight - srv->cur_eweight + srv->next_eweight; p->lbprm.tot_wact = p->lbprm.fwrr.act.next_weight; p->lbprm.tot_wbck = p->lbprm.fwrr.bck.next_weight; if (srv->lb_tree == grp->init) { fwrr_dequeue_srv(srv); fwrr_queue_by_weight(grp->init, srv); } else if (!srv->lb_tree) { /* FIXME: server was down. This is not possible right now but * may be needed soon for slowstart or graceful shutdown. */ fwrr_dequeue_srv(srv); fwrr_get_srv(srv); srv->npos = grp->curr_pos + (grp->next_weight + grp->curr_weight - grp->curr_pos) / srv->next_eweight; fwrr_queue_srv(srv); } else { /* The server is either active or in the next queue. If it's * still in the active queue and it has not consumed all of its * places, let's adjust its next position. */ fwrr_get_srv(srv); if (srv->next_eweight > 0) { int prev_next = srv->npos; int step = grp->next_weight / srv->next_eweight; srv->npos = srv->lpos + step; srv->rweight = 0; if (srv->npos > prev_next) srv->npos = prev_next; if (srv->npos < grp->curr_pos + 2) srv->npos = grp->curr_pos + step; } else { /* push it into the next tree */ srv->npos = grp->curr_pos + grp->curr_weight; } fwrr_dequeue_srv(srv); fwrr_queue_srv(srv); } update_backend_weight(p); HA_RWLOCK_WRUNLOCK(LBPRM_LOCK, &p->lbprm.lock); srv_lb_commit_status(srv); } /* Remove a server from a tree. It must have previously been dequeued. This * function is meant to be called when a server is going down or has its * weight disabled. * * The lbprm's lock must be held. The server's lock is not used. */ static inline void fwrr_remove_from_tree(struct server *s) { s->lb_tree = NULL; } /* Queue a server in the weight tree , assuming the weight is >0. * We want to sort them by inverted weights, because we need to place * heavy servers first in order to get a smooth distribution. * * The lbprm's lock must be held. The server's lock is not used. */ static inline void fwrr_queue_by_weight(struct eb_root *root, struct server *s) { s->lb_node.key = SRV_EWGHT_MAX - s->next_eweight; eb32_insert(root, &s->lb_node); s->lb_tree = root; } /* This function is responsible for building the weight trees in case of fast * weighted round-robin. It also sets p->lbprm.wdiv to the eweight to uweight * ratio. Both active and backup groups are initialized. */ void fwrr_init_server_groups(struct proxy *p) { struct server *srv; struct eb_root init_head = EB_ROOT; p->lbprm.set_server_status_up = fwrr_set_server_status_up; p->lbprm.set_server_status_down = fwrr_set_server_status_down; p->lbprm.update_server_eweight = fwrr_update_server_weight; 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); /* prepare the active servers group */ p->lbprm.fwrr.act.curr_pos = p->lbprm.fwrr.act.curr_weight = p->lbprm.fwrr.act.next_weight = p->lbprm.tot_wact; p->lbprm.fwrr.act.curr = p->lbprm.fwrr.act.t0 = p->lbprm.fwrr.act.t1 = init_head; p->lbprm.fwrr.act.init = &p->lbprm.fwrr.act.t0; p->lbprm.fwrr.act.next = &p->lbprm.fwrr.act.t1; /* prepare the backup servers group */ p->lbprm.fwrr.bck.curr_pos = p->lbprm.fwrr.bck.curr_weight = p->lbprm.fwrr.bck.next_weight = p->lbprm.tot_wbck; p->lbprm.fwrr.bck.curr = p->lbprm.fwrr.bck.t0 = p->lbprm.fwrr.bck.t1 = init_head; p->lbprm.fwrr.bck.init = &p->lbprm.fwrr.bck.t0; p->lbprm.fwrr.bck.next = &p->lbprm.fwrr.bck.t1; /* queue active and backup servers in two distinct groups */ for (srv = p->srv; srv; srv = srv->next) { if (!srv_currently_usable(srv)) continue; fwrr_queue_by_weight((srv->flags & SRV_F_BACKUP) ? p->lbprm.fwrr.bck.init : p->lbprm.fwrr.act.init, srv); } } /* simply removes a server from a weight tree. * * The lbprm's lock must be held. The server's lock is not used. */ static inline void fwrr_dequeue_srv(struct server *s) { eb32_delete(&s->lb_node); } /* queues a server into the appropriate group and tree depending on its * backup status, and ->npos. If the server is disabled, simply assign * it to the NULL tree. * * The lbprm's lock must be held. The server's lock is not used. */ static void fwrr_queue_srv(struct server *s) { struct proxy *p = s->proxy; struct fwrr_group *grp; grp = (s->flags & SRV_F_BACKUP) ? &p->lbprm.fwrr.bck : &p->lbprm.fwrr.act; /* Delay everything which does not fit into the window and everything * which does not fit into the theoretical new window. */ if (!srv_willbe_usable(s)) { fwrr_remove_from_tree(s); } else if (s->next_eweight <= 0 || s->npos >= 2 * grp->curr_weight || s->npos >= grp->curr_weight + grp->next_weight) { /* put into next tree, and readjust npos in case we could * finally take this back to current. */ s->npos -= grp->curr_weight; fwrr_queue_by_weight(grp->next, s); } else { /* The sorting key is stored in units of s->npos * user_weight * in order to avoid overflows. As stated in backend.h, the * lower the scale, the rougher the weights modulation, and the * higher the scale, the lower the number of servers without * overflow. With this formula, the result is always positive, * so we can use eb32_insert(). */ s->lb_node.key = SRV_UWGHT_RANGE * s->npos + (unsigned)(SRV_EWGHT_MAX + s->rweight - s->next_eweight) / BE_WEIGHT_SCALE; eb32_insert(&grp->curr, &s->lb_node); s->lb_tree = &grp->curr; } } /* prepares a server when extracting it from the "init" tree. * * The lbprm's lock must be held. The server's lock is not used. */ static inline void fwrr_get_srv_init(struct server *s) { s->npos = s->rweight = 0; } /* prepares a server when extracting it from the "next" tree. * * The lbprm's lock must be held. The server's lock is not used. */ static inline void fwrr_get_srv_next(struct server *s) { struct fwrr_group *grp = (s->flags & SRV_F_BACKUP) ? &s->proxy->lbprm.fwrr.bck : &s->proxy->lbprm.fwrr.act; s->npos += grp->curr_weight; } /* prepares a server when it was marked down. * * The lbprm's lock must be held. The server's lock is not used. */ static inline void fwrr_get_srv_down(struct server *s) { struct fwrr_group *grp = (s->flags & SRV_F_BACKUP) ? &s->proxy->lbprm.fwrr.bck : &s->proxy->lbprm.fwrr.act; s->npos = grp->curr_pos; } /* prepares a server when extracting it from its tree. * * The lbprm's lock must be held. The server's lock is not used. */ static void fwrr_get_srv(struct server *s) { struct proxy *p = s->proxy; struct fwrr_group *grp = (s->flags & SRV_F_BACKUP) ? &p->lbprm.fwrr.bck : &p->lbprm.fwrr.act; if (s->lb_tree == grp->init) { fwrr_get_srv_init(s); } else if (s->lb_tree == grp->next) { fwrr_get_srv_next(s); } else if (s->lb_tree == NULL) { fwrr_get_srv_down(s); } } /* switches trees "init" and "next" for FWRR group . "init" should be empty * when this happens, and "next" filled with servers sorted by weights. * * The lbprm's lock must be held. The server's lock is not used. */ static inline void fwrr_switch_trees(struct fwrr_group *grp) { struct eb_root *swap; swap = grp->init; grp->init = grp->next; grp->next = swap; grp->curr_weight = grp->next_weight; grp->curr_pos = grp->curr_weight; } /* return next server from the current tree in FWRR group , or a server * from the "init" tree if appropriate. If both trees are empty, return NULL. * * The lbprm's lock must be held. The server's lock is not used. */ static struct server *fwrr_get_server_from_group(struct fwrr_group *grp) { struct eb32_node *node1; struct eb32_node *node2; struct server *s1 = NULL; struct server *s2 = NULL; node1 = eb32_first(&grp->curr); if (node1) { s1 = eb32_entry(node1, struct server, lb_node); if (s1->cur_eweight && s1->npos <= grp->curr_pos) return s1; } /* Either we have no server left, or we have a hole. We'll look in the * init tree or a better proposal. At this point, if is non-null, * it is guaranteed to remain available as the tree is locked. */ node2 = eb32_first(grp->init); if (node2) { s2 = eb32_entry(node2, struct server, lb_node); if (s2->cur_eweight) { fwrr_get_srv_init(s2); return s2; } } return s1; } /* Computes next position of server in the group. Nothing is done if * has a zero weight. * * The lbprm's lock must be held to protect lpos/npos/rweight. */ static inline void fwrr_update_position(struct fwrr_group *grp, struct server *s) { unsigned int eweight = *(volatile unsigned int *)&s->cur_eweight; if (!eweight) return; if (!s->npos) { /* first time ever for this server */ s->npos = grp->curr_pos; } s->lpos = s->npos; s->npos += grp->next_weight / eweight; s->rweight += grp->next_weight % eweight; if (s->rweight >= eweight) { s->rweight -= eweight; s->npos++; } } /* Return next server from the current tree in backend

, or a server from * the init tree if appropriate. If both trees are empty, return NULL. * Saturated servers are skipped and requeued. * * The lbprm's lock will be used in R/W mode. The server's lock is not used. */ struct server *fwrr_get_next_server(struct proxy *p, struct server *srvtoavoid) { struct server *srv, *full, *avoided; struct fwrr_group *grp; int switched; HA_RWLOCK_WRLOCK(LBPRM_LOCK, &p->lbprm.lock); if (p->srv_act) grp = &p->lbprm.fwrr.act; else if (p->lbprm.fbck) { srv = p->lbprm.fbck; goto out; } else if (p->srv_bck) grp = &p->lbprm.fwrr.bck; else { srv = NULL; goto out; } switched = 0; avoided = NULL; full = NULL; /* NULL-terminated list of saturated servers */ while (1) { /* if we see an empty group, let's first try to collect weights * which might have recently changed. */ if (!grp->curr_weight) grp->curr_pos = grp->curr_weight = grp->next_weight; /* get first server from the "current" tree. When the end of * the tree is reached, we may have to switch, but only once. */ while (1) { srv = fwrr_get_server_from_group(grp); if (srv) break; if (switched) { if (avoided) { srv = avoided; goto take_this_one; } goto requeue_servers; } switched = 1; fwrr_switch_trees(grp); } /* OK, we have a server. However, it may be saturated, in which * case we don't want to reconsider it for now. We'll update * its position and dequeue it anyway, so that we can move it * to a better place afterwards. */ fwrr_update_position(grp, srv); fwrr_dequeue_srv(srv); grp->curr_pos++; if (!srv->maxconn || (!srv->queue.length && srv->served < srv_dynamic_maxconn(srv))) { /* make sure it is not the server we are trying to exclude... */ if (srv != srvtoavoid || avoided) break; avoided = srv; /* ...but remember that is was selected yet avoided */ } /* the server is saturated or avoided, let's chain it for later reinsertion. */ srv->next_full = full; full = srv; } take_this_one: /* OK, we got the best server, let's update it */ fwrr_queue_srv(srv); requeue_servers: /* Requeue all extracted servers. If full==srv then it was * avoided (unsuccessfully) and chained, omit it now. The * only way to get there is by having ==NULL or * ==. */ if (unlikely(full != NULL)) { if (switched) { /* the tree has switched, requeue all extracted servers * into "init", because their place was lost, and only * their weight matters. */ do { if (likely(full != srv)) fwrr_queue_by_weight(grp->init, full); full = full->next_full; } while (full); } else { /* requeue all extracted servers just as if they were consumed * so that they regain their expected place. */ do { if (likely(full != srv)) fwrr_queue_srv(full); full = full->next_full; } while (full); } } out: HA_RWLOCK_WRUNLOCK(LBPRM_LOCK, &p->lbprm.lock); return srv; } /* * Local variables: * c-indent-level: 8 * c-basic-offset: 8 * End: */