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/*
* This file is part of NetSurf, http://netsurf.sourceforge.net/
* Licensed under the GNU General Public License,
* http://www.opensource.org/licenses/gpl-license
* Copyright 2006 Daniel Silverstone <dsilvers@digital-scurf.org>
* Copyright 2004 James Bursa <bursa@users.sourceforge.net>
* Copyright 2003 Phil Mellor <monkeyson@users.sourceforge.net>
*/
/** \file
* Fetching of data from a URL (implementation).
*
* This implementation uses libcurl's 'multi' interface.
*
* Active fetches are held in the linked list fetch_list. There may be at most
* one fetch in progress from each host. Any further fetches are queued until
* the previous one ends.
*/
#include <assert.h>
#include <stdbool.h>
#include <string.h>
#include <strings.h>
#include <time.h>
#include <sys/stat.h>
#ifdef riscos
#include <unixlib/local.h>
#endif
#include "curl/curl.h"
#include "netsurf/utils/config.h"
#ifdef WITH_SSL
#include "openssl/ssl.h"
#endif
#include "netsurf/content/fetch.h"
#include "netsurf/content/urldb.h"
#include "netsurf/desktop/options.h"
#include "netsurf/render/form.h"
#define NDEBUG
#include "netsurf/utils/log.h"
#include "netsurf/utils/messages.h"
#include "netsurf/utils/url.h"
#include "netsurf/utils/utils.h"
bool fetch_active; /**< Fetches in progress, please call fetch_poll(). */
#ifdef WITH_SSL
/** SSL certificate info */
struct cert_info {
X509 *cert; /**< Pointer to certificate */
long err; /**< OpenSSL error code */
};
#endif
/** Information for a single fetch. */
struct fetch {
CURL * curl_handle; /**< cURL handle if being fetched, or 0. */
void (*callback)(fetch_msg msg, void *p, const void *data,
unsigned long size);
/**< Callback function. */
bool had_headers; /**< Headers have been processed. */
bool abort; /**< Abort requested. */
bool stopped; /**< Download stopped on purpose. */
bool only_2xx; /**< Only HTTP 2xx responses acceptable. */
bool cookies; /**< Send & accept cookies. */
char *url; /**< URL. */
char *referer; /**< URL for Referer header. */
void *p; /**< Private data for callback. */
struct curl_slist *headers; /**< List of request headers. */
char *host; /**< Host part of URL. */
char *location; /**< Response Location header, or 0. */
unsigned long content_length; /**< Response Content-Length, or 0. */
long http_code; /**< HTTP response code, or 0. */
char *cookie_string; /**< Cookie string for this fetch */
char *realm; /**< HTTP Auth Realm */
char *post_urlenc; /**< Url encoded POST string, or 0. */
struct curl_httppost *post_multipart; /**< Multipart post data, or 0. */
struct cache_data cachedata; /**< Cache control data */
time_t last_modified; /**< If-Modified-Since time */
time_t file_etag; /**< ETag for local objects */
#ifdef WITH_SSL
#define MAX_CERTS 10
struct cert_info cert_data[MAX_CERTS]; /**< HTTPS certificate data */
#endif
struct fetch *r_prev; /**< Previous active fetch in ::fetch_ring. */
struct fetch *r_next; /**< Next active fetch in ::fetch_ring. */
};
struct cache_handle {
CURL *handle; /**< The cached cURL handle */
char *host; /**< The host for which this handle is cached */
struct cache_handle *r_prev; /**< Previous cached handle in ring. */
struct cache_handle *r_next; /**< Next cached handle in ring. */
};
static const char * const user_agent = "NetSurf";
CURLM *fetch_curl_multi; /**< Global cURL multi handle. */
/** Curl handle with default options set; not used for transfers. */
static CURL *fetch_blank_curl;
static struct fetch *fetch_ring = 0; /**< Ring of active fetches. */
static struct fetch *queue_ring = 0; /**< Ring of queued fetches */
static struct cache_handle *handle_ring = 0; /**< Ring of cached handles */
static char fetch_error_buffer[CURL_ERROR_SIZE]; /**< Error buffer for cURL. */
static char fetch_progress_buffer[256]; /**< Progress buffer for cURL */
static char fetch_proxy_userpwd[100]; /**< Proxy authentication details. */
static CURLcode fetch_set_options(struct fetch *f);
#ifdef WITH_SSL
static CURLcode fetch_sslctxfun(CURL *curl_handle, SSL_CTX *sslctx, void *p);
#endif
static void fetch_free(struct fetch *f);
static void fetch_stop(struct fetch *f);
static void fetch_done(CURL *curl_handle, CURLcode result);
static int fetch_curl_progress(void *clientp, double dltotal, double dlnow,
double ultotal, double ulnow);
static size_t fetch_curl_data(void *data, size_t size, size_t nmemb,
struct fetch *f);
static size_t fetch_curl_header(char *data, size_t size, size_t nmemb,
struct fetch *f);
static bool fetch_process_headers(struct fetch *f);
static struct curl_httppost *fetch_post_convert(
struct form_successful_control *control);
#ifdef WITH_SSL
static int fetch_verify_callback(int preverify_ok, X509_STORE_CTX *x509_ctx);
static int fetch_cert_verify_callback(X509_STORE_CTX *x509_ctx, void *parm);
#endif
/** Insert the given item into the specified ring.
* Assumes that the element is zeroed as appropriate.
*/
#define RING_INSERT(ring,element) \
LOG(("RING_INSERT(%s, %p(%s))", #ring, element, element->host)); \
if (ring) { \
element->r_next = ring; \
element->r_prev = ring->r_prev; \
ring->r_prev = element; \
element->r_prev->r_next = element; \
} else \
ring = element->r_prev = element->r_next = element
/** Remove the given element from the specified ring.
* Will zero the element as needed
*/
#define RING_REMOVE(ring, element) \
LOG(("RING_REMOVE(%s, %p(%s)", #ring, element, element->host)); \
if (element->r_next != element ) { \
/* Not the only thing in the ring */ \
element->r_next->r_prev = element->r_prev; \
element->r_prev->r_next = element->r_next; \
if (ring == element) ring = element->r_next; \
} else { \
/* Only thing in the ring */ \
ring = 0; \
} \
element->r_next = element->r_prev = 0
/** Find the element (by hostname) in the given ring, leave it in the
* provided element variable
*/
#define RING_FINDBYHOST(ring, element, hostname) \
LOG(("RING_FINDBYHOST(%s, %s)", #ring, hostname)); \
if (ring) { \
element = ring; \
do { \
if (strcasecmp(element->host, hostname) == 0) \
break; \
element = element->r_next; \
} while (element != ring); \
element = 0; \
} else element = 0
/** Measure the size of a ring and put it in the supplied variable */
#define RING_GETSIZE(ringtype, ring, sizevar) \
LOG(("RING_GETSIZE(%s)", #ring)); \
if (ring) { \
ringtype *p = ring; \
sizevar = 0; \
do { \
sizevar++; \
p = p->r_next; \
} while (p != ring); \
} else sizevar = 0
/** Count the number of elements in the ring which match the provided hostname */
#define RING_COUNTBYHOST(ringtype, ring, sizevar, hostname) \
LOG(("RING_COUNTBYHOST(%s, %s)", #ring, hostname)); \
if (ring) { \
ringtype *p = ring; \
sizevar = 0; \
do { \
if (strcasecmp(p->host, hostname) == 0) \
sizevar++; \
p = p->r_next; \
} while (p != ring); \
} else sizevar = 0
static void fetch_cache_handle(CURL *handle, char *hostname);
static void fetch_dispatch_jobs(void);
/**
* Initialise the fetcher.
*
* Must be called once before any other function.
*/
void fetch_init(void)
{
CURLcode code;
code = curl_global_init(CURL_GLOBAL_ALL);
if (code != CURLE_OK)
die("Failed to initialise the fetch module "
"(curl_global_init failed).");
fetch_curl_multi = curl_multi_init();
if (!fetch_curl_multi)
die("Failed to initialise the fetch module "
"(curl_multi_init failed).");
/* Create a curl easy handle with the options that are common to all
fetches. */
fetch_blank_curl = curl_easy_init();
if (!fetch_blank_curl)
die("Failed to initialise the fetch module "
"(curl_easy_init failed).");
#define SETOPT(option, value) \
code = curl_easy_setopt(fetch_blank_curl, option, value); \
if (code != CURLE_OK) \
goto curl_easy_setopt_failed;
SETOPT(CURLOPT_VERBOSE, 1);
SETOPT(CURLOPT_ERRORBUFFER, fetch_error_buffer);
SETOPT(CURLOPT_WRITEFUNCTION, fetch_curl_data);
SETOPT(CURLOPT_HEADERFUNCTION, fetch_curl_header);
SETOPT(CURLOPT_PROGRESSFUNCTION, fetch_curl_progress);
SETOPT(CURLOPT_NOPROGRESS, 0);
SETOPT(CURLOPT_USERAGENT, user_agent);
SETOPT(CURLOPT_ENCODING, "gzip");
SETOPT(CURLOPT_LOW_SPEED_LIMIT, 1L);
SETOPT(CURLOPT_LOW_SPEED_TIME, 180L);
SETOPT(CURLOPT_NOSIGNAL, 1L);
SETOPT(CURLOPT_CONNECTTIMEOUT, 30L);
if (option_ca_bundle)
SETOPT(CURLOPT_CAINFO, option_ca_bundle);
return;
curl_easy_setopt_failed:
die("Failed to initialise the fetch module "
"(curl_easy_setopt failed).");
}
/**
* Clean up for quit.
*
* Must be called before exiting.
*/
void fetch_quit(void)
{
CURLMcode codem;
curl_easy_cleanup(fetch_blank_curl);
codem = curl_multi_cleanup(fetch_curl_multi);
if (codem != CURLM_OK)
LOG(("curl_multi_cleanup failed: ignoring"));
curl_global_cleanup();
}
/**
* Start fetching data for the given URL.
*
* The function returns immediately. The fetch may be queued for later
* processing.
*
* A pointer to an opaque struct fetch is returned, which can be passed to
* fetch_abort() to abort the fetch at any time. Returns 0 if memory is
* exhausted (or some other fatal error occurred).
*
* The caller must supply a callback function which is called when anything
* interesting happens. The callback function is first called with msg
* FETCH_TYPE, with the Content-Type header in data, then one or more times
* with FETCH_DATA with some data for the url, and finally with
* FETCH_FINISHED. Alternatively, FETCH_ERROR indicates an error occurred:
* data contains an error message. FETCH_REDIRECT may replace the FETCH_TYPE,
* FETCH_DATA, FETCH_FINISHED sequence if the server sends a replacement URL.
*
* Some private data can be passed as the last parameter to fetch_start, and
* callbacks will contain this.
*/
struct fetch * fetch_start(char *url, char *referer,
void (*callback)(fetch_msg msg, void *p, const void *data,
unsigned long size),
void *p, bool only_2xx, char *post_urlenc,
struct form_successful_control *post_multipart, bool cookies,
char *headers[])
{
char *host;
struct fetch *fetch;
struct curl_slist *slist;
url_func_result res;
char *ref1 = 0, *ref2 = 0;
int i;
fetch = malloc(sizeof (*fetch));
if (!fetch)
return 0;
res = url_host(url, &host);
if (res != URL_FUNC_OK) {
/* we only fail memory exhaustion */
if (res == URL_FUNC_NOMEM)
goto failed;
host = strdup("");
if (!host)
goto failed;
}
res = url_scheme(url, &ref1);
if (res != URL_FUNC_OK) {
/* we only fail memory exhaustion */
if (res == URL_FUNC_NOMEM)
goto failed;
ref1 = NULL;
}
if (referer) {
res = url_scheme(referer, &ref2);
if (res != URL_FUNC_OK) {
/* we only fail memory exhaustion */
if (res == URL_FUNC_NOMEM)
goto failed;
ref2 = NULL;
}
}
LOG(("fetch %p, url '%s'", fetch, url));
/* construct a new fetch structure */
fetch->curl_handle = 0;
fetch->callback = callback;
fetch->had_headers = false;
fetch->abort = false;
fetch->stopped = false;
fetch->only_2xx = only_2xx;
fetch->cookies = cookies;
fetch->url = strdup(url);
fetch->referer = 0;
/* only send the referer if the schemes match */
if (referer) {
if (ref1 && ref2 && strcasecmp(ref1, ref2) == 0)
fetch->referer = strdup(referer);
}
fetch->p = p;
fetch->headers = 0;
fetch->host = host;
fetch->location = 0;
fetch->content_length = 0;
fetch->http_code = 0;
fetch->cookie_string = 0;
fetch->realm = 0;
fetch->post_urlenc = 0;
fetch->post_multipart = 0;
if (post_urlenc)
fetch->post_urlenc = strdup(post_urlenc);
else if (post_multipart)
fetch->post_multipart = fetch_post_convert(post_multipart);
fetch->cachedata.req_time = time(0);
fetch->cachedata.res_time = 0;
fetch->cachedata.date = 0;
fetch->cachedata.expires = 0;
fetch->cachedata.age = INVALID_AGE;
fetch->cachedata.max_age = INVALID_AGE;
fetch->cachedata.no_cache = false;
fetch->cachedata.etag = 0;
fetch->cachedata.last_modified = 0;
fetch->last_modified = 0;
fetch->file_etag = 0;
#ifdef WITH_SSL
memset(fetch->cert_data, 0, sizeof(fetch->cert_data));
#endif
fetch->r_prev = 0;
fetch->r_next = 0;
if (!fetch->url || (referer &&
(ref1 && ref2 && strcasecmp(ref1, ref2) == 0) &&
!fetch->referer) ||
(post_urlenc && !fetch->post_urlenc) ||
(post_multipart && !fetch->post_multipart))
goto failed;
/* these aren't needed past here */
if (ref1) {
free(ref1);
ref1 = 0;
}
if (ref2) {
free(ref2);
ref2 = 0;
}
#define APPEND(list, value) \
slist = curl_slist_append(list, value); \
if (!slist) \
goto failed; \
list = slist;
/* remove curl default headers */
APPEND(fetch->headers, "Accept:");
APPEND(fetch->headers, "Pragma:");
/* when doing a POST libcurl sends Expect: 100-continue" by default
* which fails with lighttpd, so disable it (see bug 1429054) */
APPEND(fetch->headers, "Expect:");
if (option_accept_language) {
char s[80];
snprintf(s, sizeof s, "Accept-Language: %s, *;q=0.1",
option_accept_language);
s[sizeof s - 1] = 0;
APPEND(fetch->headers, s);
}
/* And add any headers specified by the caller */
for (i = 0; headers[i]; i++) {
if (strncasecmp(headers[i], "If-Modified-Since:", 18) == 0) {
char *d = headers[i] + 18;
for (; *d && (*d == ' ' || *d == '\t'); d++)
/* do nothing */;
fetch->last_modified = curl_getdate(d, NULL);
}
else if (strncasecmp(headers[i], "If-None-Match:", 14) == 0) {
char *d = headers[i] + 14;
for (; *d && (*d == ' ' || *d == '\t' || *d == '"');
d++)
/* do nothing */;
fetch->file_etag = atoi(d);
}
APPEND(fetch->headers, headers[i]);
}
/* Dump us in the queue and ask the queue to run. */
RING_INSERT(queue_ring, fetch);
fetch_dispatch_jobs();
return fetch;
failed:
free(host);
if (ref1)
free(ref1);
if (ref2)
free(ref2);
free(fetch->url);
free(fetch->referer);
free(fetch->post_urlenc);
if (fetch->post_multipart)
curl_formfree(fetch->post_multipart);
curl_slist_free_all(fetch->headers);
free(fetch);
return 0;
}
/**
* Initiate a fetch from the queue.
*
* Called with a fetch structure and a CURL handle to be used to fetch the content.
*
* This will return whether or not the fetch was successfully initiated.
*/
static bool fetch_initiate_fetch(struct fetch *fetch, CURL *handle)
{
CURLcode code;
CURLMcode codem;
fetch->curl_handle = handle;
/* Initialise the handle */
code = fetch_set_options(fetch);
if (code != CURLE_OK) {
fetch->curl_handle = 0;
return false;
}
/* add to the global curl multi handle */
codem = curl_multi_add_handle(fetch_curl_multi, fetch->curl_handle);
assert(codem == CURLM_OK || codem == CURLM_CALL_MULTI_PERFORM);
fetch_active = true;
return true;
}
/**
* Find a CURL handle to use to dispatch a job
*/
static CURL *fetch_get_handle(char *host)
{
struct cache_handle *h;
CURL *ret;
RING_FINDBYHOST(handle_ring, h, host);
if (h) {
ret = h->handle;
free(h->host);
RING_REMOVE(handle_ring, h);
free(h);
} else {
ret = curl_easy_duphandle(fetch_blank_curl);
}
return ret;
}
/**
* Dispatch a single job
*/
static bool fetch_dispatch_job(struct fetch *fetch)
{
RING_REMOVE(queue_ring, fetch);
if (!fetch_initiate_fetch(fetch, fetch_get_handle(fetch->host))) {
RING_INSERT(queue_ring, fetch); /* Put it back on the end of the queue */
return false;
} else {
RING_INSERT(fetch_ring, fetch);
return true;
}
}
/**
* Choose and dispatch a single job. Return false if we failed to dispatch anything.
*
* We don't check the overall dispatch size here because we're not called unless
* there is room in the fetch queue for us.
*/
static bool fetch_choose_and_dispatch(void)
{
struct fetch *queueitem;
queueitem = queue_ring;
do {
/* We can dispatch the selected item if there is room in the
* fetch ring
*/
int countbyhost;
RING_COUNTBYHOST(struct fetch, fetch_ring, countbyhost, queueitem->host);
if (countbyhost < option_max_fetchers_per_host) {
/* We can dispatch this item in theory */
return fetch_dispatch_job(queueitem);
}
queueitem = queueitem->r_next;
} while (queueitem != queue_ring);
return false;
}
/**
* Dispatch as many jobs as we have room to dispatch.
*/
static void fetch_dispatch_jobs(void)
{
int all_active, all_queued;
if (!queue_ring) return; /* Nothing to do, the queue is empty */
RING_GETSIZE(struct fetch, queue_ring, all_queued);
RING_GETSIZE(struct fetch, fetch_ring, all_active);
while( all_queued && all_active < option_max_fetchers ) {
LOG(("%d queued, %d fetching", all_queued, all_active));
if (fetch_choose_and_dispatch()) {
all_queued--;
all_active++;
} else {
/* Either a dispatch failed or we ran out. Just stop */
break;
}
}
}
/**
* Cache a CURL handle for the provided host (if wanted)
*
*/
static void fetch_cache_handle(CURL *handle, char *host)
{
struct cache_handle *h = 0;
int c;
RING_FINDBYHOST(handle_ring, h, host);
if (h) {
/* Already have a handle cached for this hostname */
curl_easy_cleanup(handle);
return;
}
/* We do not have a handle cached, first up determine if the cache is full */
RING_GETSIZE(struct cache_handle, handle_ring, c);
if (c >= option_max_cached_fetch_handles) {
/* Cache is full, so, we rotate the ring by one and replace the
* oldest handle with this one. We do this without freeing/allocating
* memory (except the hostname) and without removing the entry from the
* ring and then re-inserting it, in order to be as efficient as we can.
*/
h = handle_ring;
handle_ring = h->r_next;
curl_easy_cleanup(h->handle);
h->handle = handle;
free(h->host);
h->host = strdup(host);
return;
}
/* The table isn't full yet, so make a shiny new handle to add to the ring */
h = (struct cache_handle*)malloc(sizeof(struct cache_handle));
h->handle = handle;
h->host = strdup(host);
RING_INSERT(handle_ring, h);
}
/**
* Set options specific for a fetch.
*/
CURLcode fetch_set_options(struct fetch *f)
{
CURLcode code;
const char *auth;
#undef SETOPT
#define SETOPT(option, value) \
code = curl_easy_setopt(f->curl_handle, option, value); \
if (code != CURLE_OK) \
return code;
SETOPT(CURLOPT_URL, f->url);
SETOPT(CURLOPT_PRIVATE, f);
SETOPT(CURLOPT_WRITEDATA, f);
SETOPT(CURLOPT_WRITEHEADER, f);
SETOPT(CURLOPT_PROGRESSDATA, f);
SETOPT(CURLOPT_REFERER, f->referer);
SETOPT(CURLOPT_HTTPHEADER, f->headers);
if (f->post_urlenc) {
SETOPT(CURLOPT_POSTFIELDS, f->post_urlenc);
} else if (f->post_multipart) {
SETOPT(CURLOPT_HTTPPOST, f->post_multipart);
} else {
SETOPT(CURLOPT_HTTPGET, 1L);
}
if (f->cookies) {
f->cookie_string = urldb_get_cookie(f->url, f->referer);
if (f->cookie_string)
SETOPT(CURLOPT_COOKIE, f->cookie_string);
}
#ifdef WITH_AUTH
if ((auth = urldb_get_auth_details(f->url)) != NULL) {
SETOPT(CURLOPT_HTTPAUTH, CURLAUTH_ANY);
SETOPT(CURLOPT_USERPWD, auth);
} else {
#endif
SETOPT(CURLOPT_USERPWD, 0);
#ifdef WITH_AUTH
}
#endif
if (option_http_proxy && option_http_proxy_host) {
SETOPT(CURLOPT_PROXY, option_http_proxy_host);
SETOPT(CURLOPT_PROXYPORT, (long) option_http_proxy_port);
if (option_http_proxy_auth != OPTION_HTTP_PROXY_AUTH_NONE) {
SETOPT(CURLOPT_PROXYAUTH,
option_http_proxy_auth ==
OPTION_HTTP_PROXY_AUTH_BASIC ?
(long) CURLAUTH_BASIC :
(long) CURLAUTH_NTLM);
snprintf(fetch_proxy_userpwd,
sizeof fetch_proxy_userpwd,
"%s:%s",
option_http_proxy_auth_user,
option_http_proxy_auth_pass);
SETOPT(CURLOPT_PROXYUSERPWD, fetch_proxy_userpwd);
}
}
#ifdef WITH_SSL
if (urldb_get_cert_permissions(f->url)) {
/* Disable certificate verification */
SETOPT(CURLOPT_SSL_VERIFYPEER, 0L);
SETOPT(CURLOPT_SSL_VERIFYHOST, 0L);
} else {
/* do verification */
SETOPT(CURLOPT_SSL_CTX_FUNCTION, fetch_sslctxfun);
SETOPT(CURLOPT_SSL_CTX_DATA, f);
}
#endif
return CURLE_OK;
}
#ifdef WITH_SSL
/**
* cURL SSL setup callback
*/
CURLcode fetch_sslctxfun(CURL *curl_handle, SSL_CTX *sslctx, void *parm)
{
SSL_CTX_set_verify(sslctx, SSL_VERIFY_PEER, fetch_verify_callback);
SSL_CTX_set_cert_verify_callback(sslctx, fetch_cert_verify_callback,
parm);
return CURLE_OK;
}
#endif
/**
* Abort a fetch.
*/
void fetch_abort(struct fetch *f)
{
assert(f);
LOG(("fetch %p, url '%s'", f, f->url));
if (f->curl_handle) {
f->abort = true;
} else {
RING_REMOVE(queue_ring, f);
fetch_free(f);
}
}
/**
* Clean up the provided fetch object and free it.
*
* Will prod the queue afterwards to allow pending requests to be initiated.
*/
void fetch_stop(struct fetch *f)
{
CURLMcode codem;
assert(f);
LOG(("fetch %p, url '%s'", f, f->url));
if (f->curl_handle) {
/* remove from curl multi handle */
codem = curl_multi_remove_handle(fetch_curl_multi,
f->curl_handle);
assert(codem == CURLM_OK);
if (strncasecmp(f->url, "https:", 6)) {
/* Put this curl handle into the cache if wanted. */
fetch_cache_handle(f->curl_handle, f->host);
} else {
curl_easy_cleanup(f->curl_handle);
}
f->curl_handle = 0;
/* Remove this from the active set of fetches (if it's still there) */
RING_REMOVE(fetch_ring, f);
} else {
/* Remove this from the queued set of fetches (if it's still there) */
RING_REMOVE(queue_ring, f);
}
fetch_free(f);
if (!fetch_ring && !queue_ring)
fetch_active = false;
else if (queue_ring)
fetch_dispatch_jobs();
}
/**
* Free a fetch structure and associated resources.
*/
void fetch_free(struct fetch *f)
{
#ifdef WITH_SSL
int i;
#endif
if (f->curl_handle)
curl_easy_cleanup(f->curl_handle);
free(f->url);
free(f->host);
free(f->referer);
free(f->location);
free(f->cookie_string);
free(f->realm);
if (f->headers)
curl_slist_free_all(f->headers);
free(f->post_urlenc);
if (f->post_multipart)
curl_formfree(f->post_multipart);
free(f->cachedata.etag);
#ifdef WITH_SSL
for (i = 0; i < MAX_CERTS && f->cert_data[i].cert; i++) {
f->cert_data[i].cert->references--;
if (f->cert_data[i].cert->references == 0)
X509_free(f->cert_data[i].cert);
}
#endif
free(f);
}
/**
* Do some work on current fetches.
*
* Must be called regularly to make progress on fetches.
*/
void fetch_poll(void)
{
int running, queue;
CURLMcode codem;
CURLMsg *curl_msg;
/* do any possible work on the current fetches */
do {
codem = curl_multi_perform(fetch_curl_multi, &running);
assert(codem == CURLM_OK || codem == CURLM_CALL_MULTI_PERFORM);
} while (codem == CURLM_CALL_MULTI_PERFORM);
/* process curl results */
curl_msg = curl_multi_info_read(fetch_curl_multi, &queue);
while (curl_msg) {
switch (curl_msg->msg) {
case CURLMSG_DONE:
fetch_done(curl_msg->easy_handle,
curl_msg->data.result);
break;
default:
break;
}
curl_msg = curl_multi_info_read(fetch_curl_multi, &queue);
}
}
/**
* Handle a completed fetch (CURLMSG_DONE from curl_multi_info_read()).
*
* \param curl_handle curl easy handle of fetch
*/
void fetch_done(CURL *curl_handle, CURLcode result)
{
bool finished = false;
bool error = false;
#ifdef WITH_SSL
bool cert = false;
#endif
bool abort;
struct fetch *f;
void *p;
void (*callback)(fetch_msg msg, void *p, const void *data,
unsigned long size);
CURLcode code;
struct cache_data cachedata;
#ifdef WITH_SSL
struct cert_info certs[MAX_CERTS];
memset(certs, 0, sizeof(certs));
#endif
/* find the structure associated with this fetch */
code = curl_easy_getinfo(curl_handle, CURLINFO_PRIVATE, &f);
assert(code == CURLE_OK);
abort = f->abort;
callback = f->callback;
p = f->p;
if (!abort && result == CURLE_OK) {
/* fetch completed normally */
if (f->stopped ||
(!f->had_headers &&
fetch_process_headers(f)))
; /* redirect with no body or similar */
else
finished = true;
} else if (result == CURLE_WRITE_ERROR && f->stopped)
/* CURLE_WRITE_ERROR occurs when fetch_curl_data
* returns 0, which we use to abort intentionally */
;
#ifdef WITH_SSL
else if (result == CURLE_SSL_PEER_CERTIFICATE ||
result == CURLE_SSL_CACERT) {
memcpy(certs, f->cert_data, sizeof(certs));
memset(f->cert_data, 0, sizeof(f->cert_data));
cert = true;
}
#endif
else
error = true;
/* If finished, acquire cache info to pass to callback */
if (finished) {
memcpy(&cachedata, &f->cachedata, sizeof(struct cache_data));
f->cachedata.etag = 0;
}
/* clean up fetch and start any queued fetch for this host */
fetch_stop(f);
/* postponed until after stop so that queue fetches are started */
if (abort)
; /* fetch was aborted: no callback */
else if (finished) {
callback(FETCH_FINISHED, p, &cachedata, 0);
free(cachedata.etag);
}
#ifdef WITH_SSL
else if (cert) {
int i;
BIO *mem;
BUF_MEM *buf;
struct ssl_cert_info ssl_certs[MAX_CERTS];
for (i = 0; i < MAX_CERTS && certs[i].cert; i++) {
ssl_certs[i].version =
X509_get_version(certs[i].cert);
mem = BIO_new(BIO_s_mem());
ASN1_TIME_print(mem,
X509_get_notBefore(certs[i].cert));
BIO_get_mem_ptr(mem, &buf);
BIO_set_close(mem, BIO_NOCLOSE);
BIO_free(mem);
snprintf(ssl_certs[i].not_before,
min(sizeof ssl_certs[i].not_before,
(unsigned) buf->length + 1),
"%s", buf->data);
BUF_MEM_free(buf);
mem = BIO_new(BIO_s_mem());
ASN1_TIME_print(mem,
X509_get_notAfter(certs[i].cert));
BIO_get_mem_ptr(mem, &buf);
BIO_set_close(mem, BIO_NOCLOSE);
BIO_free(mem);
snprintf(ssl_certs[i].not_after,
min(sizeof ssl_certs[i].not_after,
(unsigned) buf->length + 1),
"%s", buf->data);
BUF_MEM_free(buf);
ssl_certs[i].sig_type =
X509_get_signature_type(certs[i].cert);
ssl_certs[i].serial =
ASN1_INTEGER_get(
X509_get_serialNumber(certs[i].cert));
mem = BIO_new(BIO_s_mem());
X509_NAME_print_ex(mem,
X509_get_issuer_name(certs[i].cert),
0, XN_FLAG_SEP_CPLUS_SPC |
XN_FLAG_DN_REV | XN_FLAG_FN_NONE);
BIO_get_mem_ptr(mem, &buf);
BIO_set_close(mem, BIO_NOCLOSE);
BIO_free(mem);
snprintf(ssl_certs[i].issuer,
min(sizeof ssl_certs[i].issuer,
(unsigned) buf->length + 1),
"%s", buf->data);
BUF_MEM_free(buf);
mem = BIO_new(BIO_s_mem());
X509_NAME_print_ex(mem,
X509_get_subject_name(certs[i].cert),
0, XN_FLAG_SEP_CPLUS_SPC |
XN_FLAG_DN_REV | XN_FLAG_FN_NONE);
BIO_get_mem_ptr(mem, &buf);
BIO_set_close(mem, BIO_NOCLOSE);
BIO_free(mem);
snprintf(ssl_certs[i].subject,
min(sizeof ssl_certs[i].subject,
(unsigned) buf->length + 1),
"%s", buf->data);
BUF_MEM_free(buf);
ssl_certs[i].cert_type =
X509_certificate_type(certs[i].cert,
X509_get_pubkey(certs[i].cert));
/* and clean up */
certs[i].cert->references--;
if (certs[i].cert->references == 0)
X509_free(certs[i].cert);
}
callback(FETCH_CERT_ERR, p, &ssl_certs, i);
}
#endif
else if (error)
callback(FETCH_ERROR, p, fetch_error_buffer, 0);
}
/**
* Callback function for fetch progress.
*/
int fetch_curl_progress(void *clientp, double dltotal, double dlnow,
double ultotal, double ulnow)
{
struct fetch *f = (struct fetch *) clientp;
double percent;
if (f->abort)
return 0;
if (dltotal > 0) {
percent = dlnow * 100.0f / dltotal;
snprintf(fetch_progress_buffer, 255,
messages_get("Progress"),
human_friendly_bytesize(dlnow),
human_friendly_bytesize(dltotal));
f->callback(FETCH_PROGRESS, f->p, fetch_progress_buffer,
(unsigned long) percent);
} else {
snprintf(fetch_progress_buffer, 255,
messages_get("ProgressU"),
human_friendly_bytesize(dlnow));
f->callback(FETCH_PROGRESS, f->p, fetch_progress_buffer, 0);
}
return 0;
}
/**
* Callback function for cURL.
*/
size_t fetch_curl_data(void *data, size_t size, size_t nmemb,
struct fetch *f)
{
/* ensure we only have to get this information once */
if (!f->http_code)
{
CURLcode code;
code = curl_easy_getinfo(f->curl_handle, CURLINFO_HTTP_CODE,
&f->http_code);
assert(code == CURLE_OK);
}
/* ignore body if this is a 401 reply by skipping it and reset
the HTTP response code to enable follow up fetches */
if (f->http_code == 401)
{
f->http_code = 0;
return size * nmemb;
}
LOG(("fetch %p, size %u", f, size * nmemb));
if (f->abort || (!f->had_headers && fetch_process_headers(f))) {
f->stopped = true;
return 0;
}
/* send data to the caller */
LOG(("FETCH_DATA"));
f->callback(FETCH_DATA, f->p, data, size * nmemb);
if (f->abort) {
f->stopped = true;
return 0;
}
return size * nmemb;
}
/**
* Callback function for headers.
*/
size_t fetch_curl_header(char *data, size_t size, size_t nmemb,
struct fetch *f)
{
int i;
size *= nmemb;
#define SKIP_ST(o) for (i = (o); i < (int) size && (data[i] == ' ' || data[i] == '\t'); i++)
/* Set fetch response time if not already set */
if (f->cachedata.res_time == 0)
f->cachedata.res_time = time(0);
if (12 < size && strncasecmp(data, "Location:", 9) == 0) {
/* extract Location header */
free(f->location);
f->location = malloc(size);
if (!f->location) {
LOG(("malloc failed"));
return size;
}
SKIP_ST(9);
strncpy(f->location, data + i, size - i);
f->location[size - i] = '\0';
for (i = size - i - 1; i >= 0 &&
(f->location[i] == ' ' ||
f->location[i] == '\t' ||
f->location[i] == '\r' ||
f->location[i] == '\n'); i--)
f->location[i] = '\0';
} else if (15 < size && strncasecmp(data, "Content-Length:", 15) == 0) {
/* extract Content-Length header */
SKIP_ST(15);
if (i < (int)size && '0' <= data[i] && data[i] <= '9')
f->content_length = atol(data + i);
#ifdef WITH_AUTH
} else if (17 < size && strncasecmp(data, "WWW-Authenticate:", 17) == 0) {
/* extract the first Realm from WWW-Authenticate header */
free(f->realm);
f->realm = malloc(size);
if (!f->realm) {
LOG(("malloc failed"));
return size;
}
SKIP_ST(17);
while (i < (int) size && strncasecmp(data + i, "realm", 5))
i++;
while (i < (int)size && data[++i] != '"')
/* */;
i++;
strncpy(f->realm, data + i, size - i);
f->realm[size - i] = '\0';
for (i = size - i - 1; i >= 0 &&
(f->realm[i] == ' ' ||
f->realm[i] == '"' ||
f->realm[i] == '\t' ||
f->realm[i] == '\r' ||
f->realm[i] == '\n'); --i)
f->realm[i] = '\0';
#endif
} else if (5 < size && strncasecmp(data, "Date:", 5) == 0) {
/* extract Date header */
SKIP_ST(5);
if (i < (int) size)
f->cachedata.date = curl_getdate(&data[i], NULL);
} else if (4 < size && strncasecmp(data, "Age:", 4) == 0) {
/* extract Age header */
SKIP_ST(4);
if (i < (int) size && '0' <= data[i] && data[i] <= '9')
f->cachedata.age = atoi(data + i);
} else if (8 < size && strncasecmp(data, "Expires:", 8) == 0) {
/* extract Expires header */
SKIP_ST(8);
if (i < (int) size)
f->cachedata.expires = curl_getdate(&data[i], NULL);
} else if (14 < size && strncasecmp(data, "Cache-Control:", 14) == 0) {
/* extract and parse Cache-Control header */
int comma;
SKIP_ST(14);
while (i < (int) size) {
for (comma = i; comma < (int) size; comma++)
if (data[comma] == ',')
break;
SKIP_ST(i);
if (8 < comma - i && (strncasecmp(data + i, "no-cache", 8) == 0 || strncasecmp(data + i, "no-store", 8) == 0))
/* When we get a disk cache we should
* distinguish between these two */
f->cachedata.no_cache = true;
else if (7 < comma - i && strncasecmp(data + i, "max-age", 7) == 0) {
for (; i < comma; i++)
if (data[i] == '=')
break;
SKIP_ST(i+1);
if (i < comma)
f->cachedata.max_age =
atoi(data + i);
}
i = comma + 1;
}
} else if (5 < size && strncasecmp(data, "ETag:", 5) == 0) {
/* extract ETag header */
free(f->cachedata.etag);
f->cachedata.etag = malloc(size);
if (!f->cachedata.etag) {
LOG(("malloc failed"));
return size;
}
SKIP_ST(5);
strncpy(f->cachedata.etag, data + i, size - i);
f->cachedata.etag[size - i] = '\0';
for (i = size - i - 1; i >= 0 &&
(f->cachedata.etag[i] == ' ' ||
f->cachedata.etag[i] == '\t' ||
f->cachedata.etag[i] == '\r' ||
f->cachedata.etag[i] == '\n'); --i)
f->cachedata.etag[i] = '\0';
} else if (14 < size && strncasecmp(data, "Last-Modified:", 14) == 0) {
/* extract Last-Modified header */
SKIP_ST(14);
if (i < (int) size) {
f->cachedata.last_modified =
curl_getdate(&data[i], NULL);
}
} else if (f->cookies && 11 < size &&
strncasecmp(data, "Set-Cookie:", 11) == 0) {
/* extract Set-Cookie header */
SKIP_ST(11);
urldb_set_cookie(&data[i], f->url);
}
return size;
#undef SKIP_ST
}
/**
* Find the status code and content type and inform the caller.
*
* Return true if the fetch is being aborted.
*/
bool fetch_process_headers(struct fetch *f)
{
long http_code;
const char *type;
CURLcode code;
struct stat s;
char *url_path = 0;
f->had_headers = true;
/* Set fetch response time if not already set */
if (f->cachedata.res_time == 0)
f->cachedata.res_time = time(0);
code = curl_easy_getinfo(f->curl_handle, CURLINFO_HTTP_CODE, &http_code);
assert(code == CURLE_OK);
LOG(("HTTP status code %li", http_code));
if (http_code == 304 && !f->post_urlenc && !f->post_multipart) {
/* Not Modified && GET request */
f->callback(FETCH_NOTMODIFIED, f->p,
(const char *)&f->cachedata, 0);
return true;
}
/* handle HTTP redirects (3xx response codes) */
if (300 <= http_code && http_code < 400 && f->location != 0) {
LOG(("FETCH_REDIRECT, '%s'", f->location));
f->callback(FETCH_REDIRECT, f->p, f->location, 0);
return true;
}
/* handle HTTP 401 (Authentication errors) */
#ifdef WITH_AUTH
if (http_code == 401) {
f->callback(FETCH_AUTH, f->p, f->realm,0);
return true;
}
#endif
/* handle HTTP errors (non 2xx response codes) */
if (f->only_2xx && strncmp(f->url, "http", 4) == 0 &&
(http_code < 200 || 299 < http_code)) {
f->callback(FETCH_ERROR, f->p, messages_get("Not2xx"), 0);
return true;
}
/* find MIME type from headers or filetype for local files */
code = curl_easy_getinfo(f->curl_handle, CURLINFO_CONTENT_TYPE, &type);
assert(code == CURLE_OK);
if (strncmp(f->url, "file:///", 8) == 0)
url_path = curl_unescape(f->url + 7,
(int) strlen(f->url) - 7);
if (url_path && stat(url_path, &s) == 0) {
/* file: URL and file exists */
/* create etag */
free(f->cachedata.etag);
f->cachedata.etag = malloc(13);
if (f->cachedata.etag)
sprintf(f->cachedata.etag,
"\"%10d\"", (int)s.st_mtime);
/* don't set last modified time so as to ensure that local
* files are revalidated at all times. */
/* If performed a conditional request and unmodified ... */
if (f->last_modified && f->file_etag &&
f->last_modified > s.st_mtime &&
f->file_etag == s.st_mtime) {
f->callback(FETCH_NOTMODIFIED, f->p,
(const char *)&f->cachedata, 0);
curl_free(url_path);
return true;
}
}
if (type == 0) {
type = "text/html";
if (url_path) {
type = fetch_filetype(url_path);
}
}
curl_free(url_path);
LOG(("FETCH_TYPE, '%s'", type));
f->callback(FETCH_TYPE, f->p, type, f->content_length);
if (f->abort)
return true;
return false;
}
/**
* Convert a list of struct ::form_successful_control to a list of
* struct curl_httppost for libcurl.
*/
struct curl_httppost *fetch_post_convert(struct form_successful_control *control)
{
struct curl_httppost *post = 0, *last = 0;
char *mimetype = 0;
char *leafname = 0;
#ifdef riscos
char *temp;
int leaflen;
#endif
for (; control; control = control->next) {
if (control->file) {
mimetype = fetch_mimetype(control->value);
#ifdef riscos
temp = strrchr(control->value, '.');
if (!temp)
temp = control->value; /* already leafname */
else
temp += 1;
leaflen = strlen(temp);
leafname = malloc(leaflen + 1);
if (!leafname) {
LOG(("malloc failed"));
free(mimetype);
continue;
}
memcpy(leafname, temp, leaflen + 1);
/* and s/\//\./g */
for (temp = leafname; *temp; temp++)
if (*temp == '/')
*temp = '.';
#else
leafname = strrchr(control->value, '/') ;
if (!leafname)
leafname = control->value;
else
leafname += 1;
#endif
curl_formadd(&post, &last,
CURLFORM_COPYNAME, control->name,
CURLFORM_FILE, control->value,
CURLFORM_FILENAME, leafname,
CURLFORM_CONTENTTYPE,
(mimetype != 0 ? mimetype : "text/plain"),
CURLFORM_END);
#ifdef riscos
free(leafname);
#endif
free(mimetype);
}
else {
curl_formadd(&post, &last,
CURLFORM_COPYNAME, control->name,
CURLFORM_COPYCONTENTS, control->value,
CURLFORM_END);
}
}
return post;
}
/**
* Check if a URL's scheme can be fetched.
*
* \param url URL to check
* \return true if the scheme is supported
*/
bool fetch_can_fetch(const char *url)
{
unsigned int i;
const char *semi;
size_t len;
curl_version_info_data *data;
if ((semi = strchr(url, ':')) == NULL)
return false;
len = semi - url;
data = curl_version_info(CURLVERSION_NOW);
for (i = 0; data->protocols[i]; i++)
if (strlen(data->protocols[i]) == len &&
strncasecmp(url, data->protocols[i], len) == 0)
return true;
return false;
}
/**
* Change the callback function for a fetch.
*/
void fetch_change_callback(struct fetch *fetch,
void (*callback)(fetch_msg msg, void *p, const void *data,
unsigned long size),
void *p)
{
assert(fetch);
fetch->callback = callback;
fetch->p = p;
}
#ifdef WITH_SSL
/**
* OpenSSL Certificate verification callback
* Stores certificate details in fetch struct.
*/
int fetch_verify_callback(int preverify_ok, X509_STORE_CTX *x509_ctx)
{
X509 *cert = X509_STORE_CTX_get_current_cert(x509_ctx);
int depth = X509_STORE_CTX_get_error_depth(x509_ctx);
int err = X509_STORE_CTX_get_error(x509_ctx);
struct fetch *f = X509_STORE_CTX_get_app_data(x509_ctx);
/* save the certificate by incrementing the reference count and
* keeping a pointer */
if (depth < MAX_CERTS && !f->cert_data[depth].cert) {
f->cert_data[depth].cert = cert;
f->cert_data[depth].err = err;
cert->references++;
}
return preverify_ok;
}
/**
* OpenSSL certificate chain verification callback
* Verifies certificate chain, setting up context for fetch_verify_callback
*/
int fetch_cert_verify_callback(X509_STORE_CTX *x509_ctx, void *parm)
{
int ok;
/* Store fetch struct in context for verify callback */
ok = X509_STORE_CTX_set_app_data(x509_ctx, parm);
/* and verify the certificate chain */
if (ok)
ok = X509_verify_cert(x509_ctx);
return ok;
}
#endif
/**
* testing framework
*/
#ifdef TEST
#include <unistd.h>
struct test {char *url; struct fetch *f;};
void callback(fetch_msg msg, struct test *t, char *data, unsigned long size)
{
printf("%s: ", t->url);
switch (msg) {
case FETCH_TYPE:
printf("FETCH_TYPE '%s'", data);
break;
case FETCH_DATA:
printf("FETCH_DATA %lu", size);
break;
case FETCH_FINISHED:
printf("FETCH_FINISHED");
break;
case FETCH_ERROR:
printf("FETCH_ERROR '%s'", data);
break;
default:
assert(0);
}
printf("\n");
}
struct test test[] = {
{"http://127.0.0.1/", 0},
{"http://netsurf.strcprstskrzkrk.co.uk/", 0},
{"http://www.oxfordstudent.com/", 0},
{"http://www.google.co.uk/", 0},
{"http://news.bbc.co.uk/", 0},
{"http://doesnt.exist/", 0},
{"blah://blah", 0},
};
int main(void)
{
int i;
fetch_init();
for (i = 0; i != sizeof(test) / sizeof(test[0]); i++)
test[i].f = fetch_start(test[i].url, 0, callback, &test[i]);
while (1) {
fetch_poll();
sleep(1);
}
return 0;
}
#endif
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