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elinks/src/network/connection.c

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/* Connections management */
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include <stdlib.h>
#include <string.h>
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#include "elinks.h"
#include "cache/cache.h"
#include "config/options.h"
#include "document/document.h"
#include "encoding/encoding.h"
#include "intl/gettext/libintl.h"
#include "main/object.h"
#include "main/select.h"
#include "main/timer.h"
#include "network/connection.h"
#include "network/dns.h"
#include "network/progress.h"
#include "network/socket.h"
#include "network/ssl/ssl.h"
#include "protocol/protocol.h"
#include "protocol/proxy.h"
#include "protocol/uri.h"
#include "session/session.h"
#include "util/error.h"
#include "util/memory.h"
#include "util/string.h"
#include "util/time.h"
struct keepalive_connection {
LIST_HEAD(struct keepalive_connection);
/* XXX: This is just the URI of the connection that registered the
* keepalive connection so only rely on the protocol, user, password,
* host and port part. */
struct uri *uri;
/* Function called when the keepalive has timed out or is deleted */
void (*done)(struct connection *);
timeval_T timeout;
timeval_T creation_time;
unsigned int protocol_family:1; /* 0 == PF_INET, 1 == PF_INET6 */
int socket;
};
static unsigned int connection_id = 0;
static int active_connections = 0;
static timer_id_T keepalive_timeout = TIMER_ID_UNDEF;
static INIT_LIST_HEAD(connection_queue);
static INIT_LIST_HEAD(host_connections);
static INIT_LIST_HEAD(keepalive_connections);
/* Prototypes */
static void notify_connection_callbacks(struct connection *conn);
static void check_keepalive_connections(void);
static /* inline */ enum connection_priority
get_priority(struct connection *conn)
{
enum connection_priority priority;
for (priority = 0; priority < PRIORITIES; priority++)
if (conn->pri[priority])
break;
assertm(priority != PRIORITIES, "Connection has no owner");
/* Recovery path ;-). (XXX?) */
return priority;
}
int
get_connections_count(void)
{
return list_size(&connection_queue);
}
int
get_keepalive_connections_count(void)
{
return list_size(&keepalive_connections);
}
int
get_connections_connecting_count(void)
{
struct connection *conn;
int i = 0;
foreach (conn, connection_queue)
i += is_in_connecting_state(conn->state);
return i;
}
int
get_connections_transfering_count(void)
{
struct connection *conn;
int i = 0;
foreach (conn, connection_queue)
i += is_in_transfering_state(conn->state);
return i;
}
static inline int
connection_disappeared(struct connection *conn)
{
struct connection *c;
foreach (c, connection_queue)
if (conn == c && conn->id == c->id)
return 0;
return 1;
}
/* Host connection management: */
/* Used to keep track on the number of connections to any given host. When
* trying to setup a new connection the list is searched to see if the maximum
* number of connection has been reached. If that is the case we try to suspend
* an already established connection. */
/* Some connections (like file://) that do not involve hosts are not maintained
* in the list. */
struct host_connection {
OBJECT_HEAD(struct host_connection);
/* XXX: This is just the URI of the connection that registered the
* host connection so only rely on the host part. */
struct uri *uri;
};
static struct host_connection *
get_host_connection(struct connection *conn)
{
struct host_connection *host_conn;
if (!conn->uri->host) return NULL;
foreach (host_conn, host_connections)
if (compare_uri(host_conn->uri, conn->uri, URI_HOST))
return host_conn;
return NULL;
}
/* Returns if the connection was successfully added. */
/* Don't add hostnameless host connections but they're valid. */
static int
add_host_connection(struct connection *conn)
{
struct host_connection *host_conn = get_host_connection(conn);
if (!host_conn && conn->uri->host) {
host_conn = mem_calloc(1, sizeof(*host_conn));
if (!host_conn) return 0;
host_conn->uri = get_uri_reference(conn->uri);
object_nolock(host_conn, "host_connection");
add_to_list(host_connections, host_conn);
}
if (host_conn) object_lock(host_conn);
return 1;
}
/* Decrements and free()s the host connection if it is the last 'refcount'. */
static void
done_host_connection(struct connection *conn)
{
struct host_connection *host_conn = get_host_connection(conn);
if (!host_conn) return;
object_unlock(host_conn);
if (is_object_used(host_conn)) return;
del_from_list(host_conn);
done_uri(host_conn->uri);
mem_free(host_conn);
}
static void sort_queue();
#ifdef CONFIG_DEBUG
static void
check_queue_bugs(void)
{
struct connection *conn;
enum connection_priority prev_priority = 0;
int cc = 0;
foreach (conn, connection_queue) {
enum connection_priority priority = get_priority(conn);
cc += conn->running;
assertm(priority >= prev_priority, "queue is not sorted");
assertm(is_in_progress_state(conn->state),
"interrupted connection on queue (conn %s, state %d)",
struri(conn->uri), conn->state);
prev_priority = priority;
}
assertm(cc == active_connections,
"bad number of active connections (counted %d, stored %d)",
cc, active_connections);
}
#else
#define check_queue_bugs()
#endif
static void
set_connection_socket_state(struct socket *socket, enum connection_state state)
{
assert(socket);
set_connection_state(socket->conn, state);
}
static void
set_connection_socket_timeout(struct socket *socket, enum connection_state state)
{
assert(socket);
set_connection_timeout(socket->conn);
}
static void
retry_connection_socket(struct socket *socket, enum connection_state state)
{
assert(socket);
retry_connection(socket->conn, state);
}
static void
done_connection_socket(struct socket *socket, enum connection_state state)
{
assert(socket);
abort_connection(socket->conn, state);
}
static struct connection *
init_connection(struct uri *uri, struct uri *proxied_uri, struct uri *referrer,
off_t start, enum cache_mode cache_mode,
enum connection_priority priority)
{
static struct socket_operations connection_socket_operations = {
set_connection_socket_state,
set_connection_socket_timeout,
retry_connection_socket,
done_connection_socket,
};
struct connection *conn = mem_calloc(1, sizeof(*conn));
if (!conn) return NULL;
assert(proxied_uri->protocol != PROTOCOL_PROXY);
conn->socket = init_socket(conn, &connection_socket_operations);
if (!conn->socket) {
mem_free(conn);
return NULL;
}
conn->data_socket = init_socket(conn, &connection_socket_operations);
if (!conn->data_socket) {
mem_free(conn->socket);
mem_free(conn);
return NULL;
}
conn->progress = init_progress(start);
if (!conn->progress) {
mem_free(conn->data_socket);
mem_free(conn->socket);
mem_free(conn);
return NULL;
}
/* load_uri() gets the URI from get_proxy() which grabs a reference for
* us. */
conn->uri = uri;
conn->proxied_uri = proxied_uri;
conn->id = connection_id++;
conn->pri[priority] = 1;
conn->cache_mode = cache_mode;
conn->content_encoding = ENCODING_NONE;
conn->stream_pipes[0] = conn->stream_pipes[1] = -1;
conn->cgi_pipes[0] = conn->cgi_pipes[1] = -1;
init_list(conn->downloads);
conn->est_length = -1;
conn->timer = TIMER_ID_UNDEF;
if (referrer) {
/* Don't set referrer when it is the file protocol and the URI
* being loaded is not. This means CGI scripts will have it
* available while preventing information about the local
* system from being leaked to external servers. */
if (referrer->protocol != PROTOCOL_FILE
|| uri->protocol == PROTOCOL_FILE)
conn->referrer = get_uri_reference(referrer);
}
return conn;
}
static void
update_connection_progress(struct connection *conn)
{
update_progress(conn->progress, conn->received, conn->est_length, conn->from);
}
static void
stat_timer(struct connection *conn)
{
update_connection_progress(conn);
notify_connection_callbacks(conn);
}
void
set_connection_state(struct connection *conn, enum connection_state state)
{
struct download *download;
struct progress *progress = conn->progress;
if (is_in_result_state(conn->state) && is_in_progress_state(state))
conn->prev_error = conn->state;
conn->state = state;
if (conn->state == S_TRANS) {
if (progress->timer == TIMER_ID_UNDEF) {
start_update_progress(progress, (void (*)(void *)) stat_timer, conn);
update_connection_progress(conn);
if (connection_disappeared(conn))
return;
}
} else {
kill_timer(&progress->timer);
}
foreach (download, conn->downloads) {
download->state = state;
download->prev_error = conn->prev_error;
}
if (is_in_progress_state(state)) notify_connection_callbacks(conn);
}
void
shutdown_connection_stream(struct connection *conn)
{
if (conn->stream) {
close_encoded(conn->stream);
conn->stream = NULL;
}
if (conn->stream_pipes[1] >= 0)
close(conn->stream_pipes[1]);
conn->stream_pipes[0] = conn->stream_pipes[1] = -1;
}
static void
free_connection_data(struct connection *conn)
{
assertm(conn->running, "connection already suspended");
/* XXX: Recovery path? Originally, there was none. I think we'll get
* at least active_connections underflows along the way. --pasky */
conn->running = 0;
active_connections--;
assertm(active_connections >= 0, "active connections underflow");
if_assert_failed active_connections = 0;
#ifdef CONFIG_SSL
if (conn->socket->ssl && conn->cached)
mem_free_set(&conn->cached->ssl_info, get_ssl_connection_cipher(conn->socket));
#endif
if (conn->done)
conn->done(conn);
done_socket(conn->socket);
done_socket(conn->data_socket);
shutdown_connection_stream(conn);
if (conn->cgi_pipes[0] >= 0)
close(conn->cgi_pipes[0]);
if (conn->cgi_pipes[1] >= 0)
close(conn->cgi_pipes[1]);
conn->cgi_pipes[0] = conn->cgi_pipes[1] = -1;
mem_free_set(&conn->info, NULL);
kill_timer(&conn->timer);
if (conn->state != S_WAIT)
done_host_connection(conn);
}
void
notify_connection_callbacks(struct connection *conn)
{
enum connection_state state = conn->state;
struct download *download, *next;
foreachsafe (download, next, conn->downloads) {
download->cached = conn->cached;
if (download->callback)
download->callback(download, download->data);
if (is_in_progress_state(state) && connection_disappeared(conn))
return;
}
}
static void
done_connection(struct connection *conn)
{
/* When removing the connection callbacks should always be aware of it
* so they can unregister themselves. We do this by enforcing that the
* connection is in a result state. If it is not already it is an
* internal bug. This should never happen but it does. ;) --jonas */
if (!is_in_result_state(conn->state))
set_connection_state(conn, S_INTERNAL);
del_from_list(conn);
notify_connection_callbacks(conn);
if (conn->referrer) done_uri(conn->referrer);
done_uri(conn->uri);
done_uri(conn->proxied_uri);
mem_free(conn->socket);
mem_free(conn->data_socket);
done_progress(conn->progress);
mem_free(conn);
check_queue_bugs();
}
static inline void add_to_queue(struct connection *conn);
/* Returns zero if no callback was done and the keepalive connection should be
* deleted or non-zero if the keepalive connection should not be deleted. */
static int
do_keepalive_connection_callback(struct keepalive_connection *keep_conn)
{
struct uri *proxied_uri = get_proxied_uri(keep_conn->uri);
struct uri *proxy_uri = get_proxy_uri(keep_conn->uri, NULL);
if (proxied_uri && proxy_uri) {
struct connection *conn;
conn = init_connection(proxy_uri, proxied_uri, NULL, 0,
CACHE_MODE_NEVER, PRI_CANCEL);
if (conn) {
void (*done)(struct connection *) = keep_conn->done;
add_to_queue(conn);
/* Get the keepalive info and let it clean up */
if (!has_keepalive_connection(conn)
|| !add_host_connection(conn)) {
free_connection_data(conn);
done_connection(conn);
return 0;
}
active_connections++;
conn->running = 1;
done(conn);
return 1;
}
}
if (proxied_uri) done_uri(proxied_uri);
if (proxy_uri) done_uri(proxy_uri);
return 0;
}
static inline void
done_keepalive_connection(struct keepalive_connection *keep_conn)
{
if (keep_conn->done && do_keepalive_connection_callback(keep_conn))
return;
del_from_list(keep_conn);
if (keep_conn->socket != -1) close(keep_conn->socket);
done_uri(keep_conn->uri);
mem_free(keep_conn);
}
static struct keepalive_connection *
init_keepalive_connection(struct connection *conn, long timeout_in_seconds,
void (*done)(struct connection *))
{
struct keepalive_connection *keep_conn;
struct uri *uri = conn->uri;
assert(uri->host);
if_assert_failed return NULL;
keep_conn = mem_calloc(1, sizeof(*keep_conn));
if (!keep_conn) return NULL;
keep_conn->uri = get_uri_reference(uri);
keep_conn->done = done;
keep_conn->protocol_family = conn->socket->protocol_family;
keep_conn->socket = conn->socket->fd;
timeval_from_seconds(&keep_conn->timeout, timeout_in_seconds);
timeval_now(&keep_conn->creation_time);
return keep_conn;
}
static struct keepalive_connection *
get_keepalive_connection(struct connection *conn)
{
struct keepalive_connection *keep_conn;
if (!conn->uri->host) return NULL;
foreach (keep_conn, keepalive_connections)
if (compare_uri(keep_conn->uri, conn->uri, URI_KEEPALIVE))
return keep_conn;
return NULL;
}
int
has_keepalive_connection(struct connection *conn)
{
struct keepalive_connection *keep_conn = get_keepalive_connection(conn);
if (!keep_conn) return 0;
conn->socket->fd = keep_conn->socket;
conn->socket->protocol_family = keep_conn->protocol_family;
/* Mark that the socket should not be closed and the callback should be
* ignored. */
keep_conn->socket = -1;
keep_conn->done = NULL;
done_keepalive_connection(keep_conn);
return 1;
}
void
add_keepalive_connection(struct connection *conn, long timeout_in_seconds,
void (*done)(struct connection *))
{
struct keepalive_connection *keep_conn;
assertm(conn->socket->fd != -1, "keepalive connection not connected");
if_assert_failed goto done;
keep_conn = init_keepalive_connection(conn, timeout_in_seconds, done);
if (keep_conn) {
/* Make sure that the socket descriptor will not periodically be
* checked or closed by free_connection_data(). */
clear_handlers(conn->socket->fd);
conn->socket->fd = -1;
add_to_list(keepalive_connections, keep_conn);
} else if (done) {
/* It will take just a little more time */
done(conn);
return;
}
done:
free_connection_data(conn);
done_connection(conn);
register_check_queue();
}
static void
keepalive_timer(void *x)
{
keepalive_timeout = TIMER_ID_UNDEF;
check_keepalive_connections();
}
void
check_keepalive_connections(void)
{
struct keepalive_connection *keep_conn, *next;
timeval_T now;
int p = 0;
timeval_now(&now);
kill_timer(&keepalive_timeout);
foreachsafe (keep_conn, next, keepalive_connections) {
timeval_T age;
if (can_read(keep_conn->socket)) {
done_keepalive_connection(keep_conn);
continue;
}
timeval_sub(&age, &keep_conn->creation_time, &now);
if (timeval_cmp(&age, &keep_conn->timeout) > 0) {
done_keepalive_connection(keep_conn);
continue;
}
p++;
}
for (; p > MAX_KEEPALIVE_CONNECTIONS; p--) {
assertm(!list_empty(keepalive_connections), "keepalive list empty");
if_assert_failed return;
done_keepalive_connection(keepalive_connections.prev);
}
if (!list_empty(keepalive_connections))
install_timer(&keepalive_timeout, KEEPALIVE_CHECK_TIME,
keepalive_timer, NULL);
}
static inline void
abort_all_keepalive_connections(void)
{
while (!list_empty(keepalive_connections))
done_keepalive_connection(keepalive_connections.next);
check_keepalive_connections();
}
static inline void
add_to_queue(struct connection *conn)
{
struct connection *c;
enum connection_priority priority = get_priority(conn);
foreach (c, connection_queue)
if (get_priority(c) > priority)
break;
add_at_pos(c->prev, conn);
}
static void
sort_queue(void)
{
int swp;
do {
struct connection *conn;
swp = 0;
foreach (conn, connection_queue) {
if (!list_has_next(connection_queue, conn)) break;
if (get_priority(conn->next) < get_priority(conn)) {
struct connection *c = conn->next;
del_from_list(conn);
add_at_pos(c, conn);
swp = 1;
}
}
} while (swp);
}
static void
interrupt_connection(struct connection *conn)
{
free_connection_data(conn);
}
static inline void
suspend_connection(struct connection *conn)
{
interrupt_connection(conn);
set_connection_state(conn, S_WAIT);
}
static void
run_connection(struct connection *conn)
{
protocol_handler_T *func = get_protocol_handler(conn->uri->protocol);
assert(func);
assertm(!conn->running, "connection already running");
if_assert_failed return;
if (!add_host_connection(conn)) {
set_connection_state(conn, S_OUT_OF_MEM);
done_connection(conn);
return;
}
active_connections++;
conn->running = 1;
func(conn);
}
/* Set certain state on a connection and then abort the connection. */
void
abort_connection(struct connection *conn, enum connection_state state)
{
assertm(is_in_result_state(state),
"connection didn't end in result state (%d)", state);
set_connection_state(conn, state);
if (conn->running) interrupt_connection(conn);
done_connection(conn);
register_check_queue();
}
/* Set certain state on a connection and then retry the connection. */
void
retry_connection(struct connection *conn, enum connection_state state)
{
int max_tries = get_opt_int("connection.retries");
assertm(is_in_result_state(state),
"connection didn't end in result state (%d)", state);
set_connection_state(conn, state);
interrupt_connection(conn);
if (conn->uri->post || !max_tries || ++conn->tries >= max_tries) {
done_connection(conn);
register_check_queue();
} else {
conn->prev_error = conn->state;
run_connection(conn);
}
}
static int
try_to_suspend_connection(struct connection *conn, struct uri *uri)
{
enum connection_priority priority = get_priority(conn);
struct connection *c;
foreachback (c, connection_queue) {
if (get_priority(c) <= priority) return -1;
if (c->state == S_WAIT) continue;
if (c->uri->post && get_priority(c) < PRI_CANCEL) continue;
if (uri && !compare_uri(uri, c->uri, URI_HOST)) continue;
suspend_connection(c);
return 0;
}
return -1;
}
static inline int
try_connection(struct connection *conn, int max_conns_to_host, int max_conns)
{
struct host_connection *host_conn = get_host_connection(conn);
if (host_conn && get_object_refcount(host_conn) >= max_conns_to_host)
return try_to_suspend_connection(conn, host_conn->uri) ? 0 : -1;
if (active_connections >= max_conns)
return try_to_suspend_connection(conn, NULL) ? 0 : -1;
run_connection(conn);
return 1;
}
static void
check_queue(void)
{
struct connection *conn;
int max_conns_to_host = get_opt_int("connection.max_connections_to_host");
int max_conns = get_opt_int("connection.max_connections");
again:
conn = connection_queue.next;
check_queue_bugs();
check_keepalive_connections();
while (conn != (struct connection *) &connection_queue) {
struct connection *c;
enum connection_priority pri = get_priority(conn);
for (c = conn; c != (struct connection *) &connection_queue && get_priority(c) == pri;) {
struct connection *cc = c;
c = c->next;
if (cc->state == S_WAIT && get_keepalive_connection(cc)
&& try_connection(cc, max_conns_to_host, max_conns))
goto again;
}
for (c = conn; c != (struct connection *) &connection_queue && get_priority(c) == pri;) {
struct connection *cc = c;
c = c->next;
if (cc->state == S_WAIT
&& try_connection(cc, max_conns_to_host, max_conns))
goto again;
}
conn = c;
}
again2:
foreachback (conn, connection_queue) {
if (get_priority(conn) < PRI_CANCEL) break;
if (conn->state == S_WAIT) {
set_connection_state(conn, S_INTERRUPTED);
done_connection(conn);
goto again2;
}
}
check_queue_bugs();
}
int
register_check_queue(void)
{
return register_bottom_half(check_queue, NULL);
}
int
load_uri(struct uri *uri, struct uri *referrer, struct download *download,
enum connection_priority pri, enum cache_mode cache_mode, off_t start)
{
struct cache_entry *cached;
struct connection *conn;
struct uri *proxy_uri, *proxied_uri;
enum connection_state connection_state = S_OK;
if (download) {
download->conn = NULL;
download->cached = NULL;
download->pri = pri;
download->state = S_OUT_OF_MEM;
download->prev_error = 0;
}
#ifdef CONFIG_DEBUG
foreach (conn, connection_queue) {
struct download *assigned;
foreach (assigned, conn->downloads) {
assertm(assigned != download, "Download assigned to '%s'", struri(conn->uri));
if_assert_failed {
download->state = S_INTERNAL;
if (download->callback)
download->callback(download, download->data);
return 0;
}
/* No recovery path should be necessary. */
}
}
#endif
cached = get_validated_cache_entry(uri, cache_mode);
if (cached) {
if (download) {
download->cached = cached;
download->state = S_OK;
/* XXX:
* This doesn't work since sometimes |download->progress|
* is undefined and contains random memory locations.
* It's not supposed to point on anything here since
* |download| has no connection attached.
* Downloads resuming will probably break in some
* cases without this, though.
* FIXME: Needs more investigation. --pasky */
/* if (download->progress) download->progress->start = start; */
if (download->callback)
download->callback(download, download->data);
}
return 0;
}
proxied_uri = get_proxied_uri(uri);
proxy_uri = get_proxy_uri(uri, &connection_state);
if (!proxy_uri
|| !proxied_uri
|| (get_protocol_need_slash_after_host(proxy_uri->protocol)
&& !proxy_uri->hostlen)) {
if (download) {
if (connection_state == S_OK) {
connection_state = proxy_uri && proxied_uri
? S_BAD_URL : S_OUT_OF_MEM;
}
download->state = connection_state;
download->callback(download, download->data);
}
if (proxy_uri) done_uri(proxy_uri);
if (proxied_uri) done_uri(proxied_uri);
return -1;
}
foreach (conn, connection_queue) {
if (conn->detached
|| !compare_uri(conn->uri, proxy_uri, 0))
continue;
done_uri(proxy_uri);
done_uri(proxied_uri);
if (get_priority(conn) > pri) {
del_from_list(conn);
conn->pri[pri]++;
add_to_queue(conn);
register_check_queue();
} else {
conn->pri[pri]++;
}
if (download) {
download->progress = conn->progress;
download->conn = conn;
download->cached = conn->cached;
add_to_list(conn->downloads, download);
/* This is likely to call download->callback() now! */
set_connection_state(conn, conn->state);
}
check_queue_bugs();
return 0;
}
conn = init_connection(proxy_uri, proxied_uri, referrer, start, cache_mode, pri);
if (!conn) {
if (download) {
download->state = S_OUT_OF_MEM;
download->callback(download, download->data);
}
if (proxy_uri) done_uri(proxy_uri);
if (proxied_uri) done_uri(proxied_uri);
return -1;
}
if (cache_mode < CACHE_MODE_FORCE_RELOAD && cached && !list_empty(cached->frag)
&& !((struct fragment *) cached->frag.next)->offset)
conn->from = ((struct fragment *) cached->frag.next)->length;
if (download) {
download->progress = conn->progress;
download->conn = conn;
download->cached = NULL;
add_to_list(conn->downloads, download);
}
add_to_queue(conn);
set_connection_state(conn, S_WAIT);
check_queue_bugs();
register_check_queue();
return 0;
}
/* FIXME: one object in more connections */
void
change_connection(struct download *old, struct download *new,
enum connection_priority newpri, int interrupt)
{
struct connection *conn;
assert(old);
if_assert_failed return;
if (is_in_result_state(old->state)) {
if (new) {
new->cached = old->cached;
new->state = old->state;
new->prev_error = old->prev_error;
if (new->callback)
new->callback(new, new->data);
}
return;
}
check_queue_bugs();
conn = old->conn;
conn->pri[old->pri]--;
assertm(conn->pri[old->pri] >= 0, "priority counter underflow");
if_assert_failed conn->pri[old->pri] = 0;
conn->pri[newpri]++;
del_from_list(old);
old->state = S_INTERRUPTED;
if (new) {
new->progress = conn->progress;
add_to_list(conn->downloads, new);
new->state = conn->state;
new->prev_error = conn->prev_error;
new->pri = newpri;
new->conn = conn;
new->cached = conn->cached;
} else if (conn->detached || interrupt) {
abort_connection(conn, S_INTERRUPTED);
}
sort_queue();
check_queue_bugs();
register_check_queue();
}
/* This will remove 'pos' bytes from the start of the cache for the specified
* connection, if the cached object is already too big. */
void
detach_connection(struct download *download, off_t pos)
{
struct connection *conn = download->conn;
if (is_in_result_state(download->state)) return;
if (!conn->detached) {
off_t total_len;
off_t i, total_pri = 0;
if (!conn->cached)
return;
total_len = (conn->est_length == -1) ? conn->from
: conn->est_length;
if (total_len < (get_opt_long("document.cache.memory.size")
* MAX_CACHED_OBJECT_PERCENT / 100)) {
/* This whole thing will fit to the memory anyway, so
* there's no problem in detaching the connection. */
return;
}
for (i = 0; i < PRI_CANCEL; i++)
total_pri += conn->pri[i];
assertm(total_pri, "detaching free connection");
/* No recovery path should be necessary...? */
/* Pre-clean cache. */
shrink_format_cache(0);
if (total_pri != 1 || is_object_used(conn->cached)) {
/* We're too important, or someone uses our cache
* entry. */
return;
}
/* DBG("detached"); */
/* We aren't valid cache entry anymore. */
conn->cached->valid = 0;
conn->detached = 1;
}
/* Strip the entry. */
free_entry_to(conn->cached, pos);
}
static void
connection_timeout(struct connection *conn)
{
conn->timer = TIMER_ID_UNDEF;
timeout_socket(conn->socket);
}
/* Huh, using two timers? Is this to account for changes of c->unrestartable
* or can it be reduced? --jonas */
static void
connection_timeout_1(struct connection *conn)
{
install_timer(&conn->timer, (milliseconds_T)
((conn->unrestartable
? get_opt_int("connection.unrestartable_receive_timeout")
: get_opt_int("connection.receive_timeout"))
* 500), (void (*)(void *)) connection_timeout, conn);
}
void
set_connection_timeout(struct connection *conn)
{
kill_timer(&conn->timer);
install_timer(&conn->timer, (milliseconds_T)
((conn->unrestartable
? get_opt_int("connection.unrestartable_receive_timeout")
: get_opt_int("connection.receive_timeout"))
* 500), (void (*)(void *)) connection_timeout_1, conn);
}
void
abort_all_connections(void)
{
while (!list_empty(connection_queue)) {
abort_connection(connection_queue.next, S_INTERRUPTED);
}
abort_all_keepalive_connections();
}
void
abort_background_connections(void)
{
struct connection *conn, *next;
foreachsafe (conn, next, connection_queue) {
if (get_priority(conn) >= PRI_CANCEL)
abort_connection(conn, S_INTERRUPTED);
}
}
int
is_entry_used(struct cache_entry *cached)
{
struct connection *conn;
foreach (conn, connection_queue)
if (conn->cached == cached)
return 1;
return 0;
}