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view src/event/ngx_event_timer.c @ 7419:c5d7a72abadc stable-1.14

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SSL: logging level of "no suitable signature algorithm". The "no suitable signature algorithm" errors are reported by OpenSSL 1.1.1 when using TLSv1.3 if there are no shared signature algorithms. In particular, this can happen if the client limits available signature algorithms to something we don't have a certificate for, or to an empty list. For example, the following command: openssl s_client -connect 127.0.0.1:8443 -sigalgs rsa_pkcs1_sha1 will always result in the "no suitable signature algorithm" error as the "rsa_pkcs1_sha1" algorithm refers solely to signatures which appear in certificates and not defined for use in TLS 1.3 handshake messages. The SSL_R_NO_COMMON_SIGNATURE_ALGORITHMS error is what BoringSSL returns in the same situation.
author Maxim Dounin <mdounin@mdounin.ru>
date Tue, 25 Sep 2018 14:00:04 +0300
parents 03928f7f209b
children 0c5e84096d99
line wrap: on
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/*
 * Copyright (C) Igor Sysoev
 * Copyright (C) Nginx, Inc.
 */


#include <ngx_config.h>
#include <ngx_core.h>
#include <ngx_event.h>


ngx_rbtree_t              ngx_event_timer_rbtree;
static ngx_rbtree_node_t  ngx_event_timer_sentinel;

/*
 * the event timer rbtree may contain the duplicate keys, however,
 * it should not be a problem, because we use the rbtree to find
 * a minimum timer value only
 */

ngx_int_t
ngx_event_timer_init(ngx_log_t *log)
{
    ngx_rbtree_init(&ngx_event_timer_rbtree, &ngx_event_timer_sentinel,
                    ngx_rbtree_insert_timer_value);

    return NGX_OK;
}


ngx_msec_t
ngx_event_find_timer(void)
{
    ngx_msec_int_t      timer;
    ngx_rbtree_node_t  *node, *root, *sentinel;

    if (ngx_event_timer_rbtree.root == &ngx_event_timer_sentinel) {
        return NGX_TIMER_INFINITE;
    }

    root = ngx_event_timer_rbtree.root;
    sentinel = ngx_event_timer_rbtree.sentinel;

    node = ngx_rbtree_min(root, sentinel);

    timer = (ngx_msec_int_t) (node->key - ngx_current_msec);

    return (ngx_msec_t) (timer > 0 ? timer : 0);
}


void
ngx_event_expire_timers(void)
{
    ngx_event_t        *ev;
    ngx_rbtree_node_t  *node, *root, *sentinel;

    sentinel = ngx_event_timer_rbtree.sentinel;

    for ( ;; ) {
        root = ngx_event_timer_rbtree.root;

        if (root == sentinel) {
            return;
        }

        node = ngx_rbtree_min(root, sentinel);

        /* node->key > ngx_current_msec */

        if ((ngx_msec_int_t) (node->key - ngx_current_msec) > 0) {
            return;
        }

        ev = (ngx_event_t *) ((char *) node - offsetof(ngx_event_t, timer));

        ngx_log_debug2(NGX_LOG_DEBUG_EVENT, ev->log, 0,
                       "event timer del: %d: %M",
                       ngx_event_ident(ev->data), ev->timer.key);

        ngx_rbtree_delete(&ngx_event_timer_rbtree, &ev->timer);

#if (NGX_DEBUG)
        ev->timer.left = NULL;
        ev->timer.right = NULL;
        ev->timer.parent = NULL;
#endif

        ev->timer_set = 0;

        ev->timedout = 1;

        ev->handler(ev);
    }
}


ngx_int_t
ngx_event_no_timers_left(void)
{
    ngx_event_t        *ev;
    ngx_rbtree_node_t  *node, *root, *sentinel;

    sentinel = ngx_event_timer_rbtree.sentinel;
    root = ngx_event_timer_rbtree.root;

    if (root == sentinel) {
        return NGX_OK;
    }

    for (node = ngx_rbtree_min(root, sentinel);
         node;
         node = ngx_rbtree_next(&ngx_event_timer_rbtree, node))
    {
        ev = (ngx_event_t *) ((char *) node - offsetof(ngx_event_t, timer));

        if (!ev->cancelable) {
            return NGX_AGAIN;
        }
    }

    /* only cancelable timers left */

    return NGX_OK;
}