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haproxy/src/lb_chash.c
Willy Tarreau 1b87748ff5 BUG/MEDIUM: lb/threads: always properly lock LB algorithms on maintenance operations 
Since commit 3ff577e ("MAJOR: server: make server state changes
synchronous again"), srv_update_status() calls the various maintenance
operations of the LB algorithms (->set_server_up, ->set_server_down,
->update_server_weight()). These ones are called with a single thread
guaranteed by the rendez-vous point, so the fact that they're lacking
some locks has no effect. However we'll need to remove the rendez-vous
point so we have to take care of properly locking all the LB algos.

The comments have been properly updated on the various functions to
mention their locking expectations. All these functions are called
with the server lock held, and all of them now support concurrent
calls by using the lbprm's lock.

This fix doesn't need to be backported at the moment, though if any
check-specific issue surfaced in 1.8, it could make sense to reuse it.
2018-08-21 19:44:53 +02:00

506 lines
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/*
* 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 = realloc(s->lb_nodes, s->next_eweight);
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.chash.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.
* If no valid server is found, NULL is returned.
*/
struct server *chash_get_server_hash(struct proxy *p, unsigned int hash)
{
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 (p->lbprm.chash.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);
}
}
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