/* * Multiple format streaming server * Copyright (c) 2000, 2001, 2002 Fabrice Bellard * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #define HAVE_AV_CONFIG_H #include "avformat.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "ffserver.h" /* maximum number of simultaneous HTTP connections */ #define HTTP_MAX_CONNECTIONS 2000 enum HTTPState { HTTPSTATE_WAIT_REQUEST, HTTPSTATE_SEND_HEADER, HTTPSTATE_SEND_DATA_HEADER, HTTPSTATE_SEND_DATA, /* sending TCP or UDP data */ HTTPSTATE_SEND_DATA_TRAILER, HTTPSTATE_RECEIVE_DATA, HTTPSTATE_WAIT_FEED, /* wait for data from the feed */ HTTPSTATE_WAIT, /* wait before sending next packets */ HTTPSTATE_WAIT_SHORT, /* short wait for short term bandwidth limitation */ HTTPSTATE_READY, RTSPSTATE_WAIT_REQUEST, RTSPSTATE_SEND_REPLY, }; const char *http_state[] = { "HTTP_WAIT_REQUEST", "HTTP_SEND_HEADER", "SEND_DATA_HEADER", "SEND_DATA", "SEND_DATA_TRAILER", "RECEIVE_DATA", "WAIT_FEED", "WAIT", "WAIT_SHORT", "READY", "RTSP_WAIT_REQUEST", "RTSP_SEND_REPLY", }; #define IOBUFFER_INIT_SIZE 8192 /* coef for exponential mean for bitrate estimation in statistics */ #define AVG_COEF 0.9 /* timeouts are in ms */ #define HTTP_REQUEST_TIMEOUT (15 * 1000) #define RTSP_REQUEST_TIMEOUT (3600 * 24 * 1000) #define SYNC_TIMEOUT (10 * 1000) typedef struct { INT64 count1, count2; long time1, time2; } DataRateData; /* context associated with one connection */ typedef struct HTTPContext { enum HTTPState state; int fd; /* socket file descriptor */ struct sockaddr_in from_addr; /* origin */ struct pollfd *poll_entry; /* used when polling */ long timeout; UINT8 *buffer_ptr, *buffer_end; int http_error; struct HTTPContext *next; int got_key_frame; /* stream 0 => 1, stream 1 => 2, stream 2=> 4 */ INT64 data_count; /* feed input */ int feed_fd; /* input format handling */ AVFormatContext *fmt_in; long start_time; /* In milliseconds - this wraps fairly often */ INT64 first_pts; /* initial pts value */ int pts_stream_index; /* stream we choose as clock reference */ /* output format handling */ struct FFStream *stream; /* -1 is invalid stream */ int feed_streams[MAX_STREAMS]; /* index of streams in the feed */ int switch_feed_streams[MAX_STREAMS]; /* index of streams in the feed */ int switch_pending; AVFormatContext fmt_ctx; /* instance of FFStream for one user */ int last_packet_sent; /* true if last data packet was sent */ int suppress_log; int bandwidth; DataRateData datarate; int wmp_client_id; char protocol[16]; char method[16]; char url[128]; int buffer_size; UINT8 *buffer; int is_packetized; /* if true, the stream is packetized */ int packet_stream_index; /* current stream for output in state machine */ /* RTSP state specific */ UINT8 *pb_buffer; /* XXX: use that in all the code */ ByteIOContext *pb; int seq; /* RTSP sequence number */ /* RTP state specific */ enum RTSPProtocol rtp_protocol; char session_id[32]; /* session id */ AVFormatContext *rtp_ctx[MAX_STREAMS]; URLContext *rtp_handles[MAX_STREAMS]; /* RTP short term bandwidth limitation */ int packet_byte_count; int packet_start_time_us; /* used for short durations (a few seconds max) */ } HTTPContext; /* each generated stream is described here */ enum StreamType { STREAM_TYPE_LIVE, STREAM_TYPE_STATUS, STREAM_TYPE_REDIRECT, }; enum IPAddressAction { IP_ALLOW = 1, IP_DENY, }; typedef struct IPAddressACL { struct IPAddressACL *next; enum IPAddressAction action; struct in_addr first; struct in_addr last; } IPAddressACL; /* description of each stream of the ffserver.conf file */ typedef struct FFStream { enum StreamType stream_type; char filename[1024]; /* stream filename */ struct FFStream *feed; /* feed we are using (can be null if coming from file) */ AVOutputFormat *fmt; IPAddressACL *acl; int nb_streams; int prebuffer; /* Number of millseconds early to start */ long max_time; /* Number of milliseconds to run */ int send_on_key; AVStream *streams[MAX_STREAMS]; int feed_streams[MAX_STREAMS]; /* index of streams in the feed */ char feed_filename[1024]; /* file name of the feed storage, or input file name for a stream */ char author[512]; char title[512]; char copyright[512]; char comment[512]; pid_t pid; /* Of ffmpeg process */ time_t pid_start; /* Of ffmpeg process */ char **child_argv; struct FFStream *next; /* RTSP options */ char *rtsp_option; /* feed specific */ int feed_opened; /* true if someone is writing to the feed */ int is_feed; /* true if it is a feed */ int conns_served; INT64 bytes_served; INT64 feed_max_size; /* maximum storage size */ INT64 feed_write_index; /* current write position in feed (it wraps round) */ INT64 feed_size; /* current size of feed */ struct FFStream *next_feed; } FFStream; typedef struct FeedData { long long data_count; float avg_frame_size; /* frame size averraged over last frames with exponential mean */ } FeedData; struct sockaddr_in my_http_addr; struct sockaddr_in my_rtsp_addr; char logfilename[1024]; HTTPContext *first_http_ctx; FFStream *first_feed; /* contains only feeds */ FFStream *first_stream; /* contains all streams, including feeds */ static void new_connection(int server_fd, int is_rtsp); static void close_connection(HTTPContext *c); /* HTTP handling */ static int handle_connection(HTTPContext *c); static int http_parse_request(HTTPContext *c); static int http_send_data(HTTPContext *c); static void compute_stats(HTTPContext *c); static int open_input_stream(HTTPContext *c, const char *info); static int http_start_receive_data(HTTPContext *c); static int http_receive_data(HTTPContext *c); static int compute_send_delay(HTTPContext *c); /* RTSP handling */ static int rtsp_parse_request(HTTPContext *c); static void rtsp_cmd_describe(HTTPContext *c, const char *url); static void rtsp_cmd_setup(HTTPContext *c, const char *url, RTSPHeader *h); static void rtsp_cmd_play(HTTPContext *c, const char *url, RTSPHeader *h); static void rtsp_cmd_pause(HTTPContext *c, const char *url, RTSPHeader *h); static void rtsp_cmd_teardown(HTTPContext *c, const char *url, RTSPHeader *h); /* RTP handling */ static HTTPContext *rtp_new_connection(HTTPContext *rtsp_c, FFStream *stream, const char *session_id); static int rtp_new_av_stream(HTTPContext *c, int stream_index, struct sockaddr_in *dest_addr); static const char *my_program_name; static const char *my_program_dir; static int ffserver_debug; static int ffserver_daemon; static int no_launch; static int need_to_start_children; int nb_max_connections; int nb_connections; int nb_max_bandwidth; int nb_bandwidth; static long cur_time; // Making this global saves on passing it around everywhere static long gettime_ms(void) { struct timeval tv; gettimeofday(&tv,NULL); return (long long)tv.tv_sec * 1000 + (tv.tv_usec / 1000); } static FILE *logfile = NULL; static void http_log(char *fmt, ...) { va_list ap; va_start(ap, fmt); if (logfile) { vfprintf(logfile, fmt, ap); fflush(logfile); } va_end(ap); } static void log_connection(HTTPContext *c) { char buf1[32], buf2[32], *p; time_t ti; if (c->suppress_log) return; /* XXX: reentrant function ? */ p = inet_ntoa(c->from_addr.sin_addr); strcpy(buf1, p); ti = time(NULL); p = ctime(&ti); strcpy(buf2, p); p = buf2 + strlen(p) - 1; if (*p == '\n') *p = '\0'; http_log("%s - - [%s] \"%s %s %s\" %d %lld\n", buf1, buf2, c->method, c->url, c->protocol, (c->http_error ? c->http_error : 200), c->data_count); } static void update_datarate(DataRateData *drd, INT64 count) { if (!drd->time1 && !drd->count1) { drd->time1 = drd->time2 = cur_time; drd->count1 = drd->count2 = count; } else { if (cur_time - drd->time2 > 5000) { drd->time1 = drd->time2; drd->count1 = drd->count2; drd->time2 = cur_time; drd->count2 = count; } } } /* In bytes per second */ static int compute_datarate(DataRateData *drd, INT64 count) { if (cur_time == drd->time1) return 0; return ((count - drd->count1) * 1000) / (cur_time - drd->time1); } static int get_longterm_datarate(DataRateData *drd, INT64 count) { /* You get the first 3 seconds flat out */ if (cur_time - drd->time1 < 3000) return 0; return compute_datarate(drd, count); } static void start_children(FFStream *feed) { if (no_launch) return; for (; feed; feed = feed->next) { if (feed->child_argv && !feed->pid) { feed->pid_start = time(0); feed->pid = fork(); if (feed->pid < 0) { fprintf(stderr, "Unable to create children\n"); exit(1); } if (!feed->pid) { /* In child */ char pathname[1024]; char *slash; int i; for (i = 3; i < 256; i++) { close(i); } if (!ffserver_debug) { i = open("/dev/null", O_RDWR); if (i) dup2(i, 0); dup2(i, 1); dup2(i, 2); if (i) close(i); } pstrcpy(pathname, sizeof(pathname), my_program_name); slash = strrchr(pathname, '/'); if (!slash) { slash = pathname; } else { slash++; } strcpy(slash, "ffmpeg"); /* This is needed to make relative pathnames work */ chdir(my_program_dir); execvp(pathname, feed->child_argv); _exit(1); } } } } /* open a listening socket */ static int socket_open_listen(struct sockaddr_in *my_addr) { int server_fd, tmp; server_fd = socket(AF_INET,SOCK_STREAM,0); if (server_fd < 0) { perror ("socket"); return -1; } tmp = 1; setsockopt(server_fd, SOL_SOCKET, SO_REUSEADDR, &tmp, sizeof(tmp)); if (bind (server_fd, (struct sockaddr *) my_addr, sizeof (*my_addr)) < 0) { perror ("bind"); close(server_fd); return -1; } if (listen (server_fd, 5) < 0) { perror ("listen"); close(server_fd); return -1; } fcntl(server_fd, F_SETFL, O_NONBLOCK); return server_fd; } /* main loop of the http server */ static int http_server(void) { int server_fd, ret, rtsp_server_fd, delay, delay1; struct pollfd poll_table[HTTP_MAX_CONNECTIONS + 2], *poll_entry; HTTPContext *c, *c_next; server_fd = socket_open_listen(&my_http_addr); if (server_fd < 0) return -1; rtsp_server_fd = socket_open_listen(&my_rtsp_addr); if (rtsp_server_fd < 0) return -1; http_log("ffserver started.\n"); start_children(first_feed); first_http_ctx = NULL; nb_connections = 0; first_http_ctx = NULL; for(;;) { poll_entry = poll_table; poll_entry->fd = server_fd; poll_entry->events = POLLIN; poll_entry++; poll_entry->fd = rtsp_server_fd; poll_entry->events = POLLIN; poll_entry++; /* wait for events on each HTTP handle */ c = first_http_ctx; delay = 1000; while (c != NULL) { int fd; fd = c->fd; switch(c->state) { case HTTPSTATE_SEND_HEADER: case RTSPSTATE_SEND_REPLY: c->poll_entry = poll_entry; poll_entry->fd = fd; poll_entry->events = POLLOUT; poll_entry++; break; case HTTPSTATE_SEND_DATA_HEADER: case HTTPSTATE_SEND_DATA: case HTTPSTATE_SEND_DATA_TRAILER: if (!c->is_packetized) { /* for TCP, we output as much as we can (may need to put a limit) */ c->poll_entry = poll_entry; poll_entry->fd = fd; poll_entry->events = POLLOUT; poll_entry++; } else { /* not strictly correct, but currently cannot add more than one fd in poll entry */ delay = 0; } break; case HTTPSTATE_WAIT_REQUEST: case HTTPSTATE_RECEIVE_DATA: case HTTPSTATE_WAIT_FEED: case RTSPSTATE_WAIT_REQUEST: /* need to catch errors */ c->poll_entry = poll_entry; poll_entry->fd = fd; poll_entry->events = POLLIN;/* Maybe this will work */ poll_entry++; break; case HTTPSTATE_WAIT: c->poll_entry = NULL; delay1 = compute_send_delay(c); if (delay1 < delay) delay = delay1; break; case HTTPSTATE_WAIT_SHORT: c->poll_entry = NULL; delay1 = 10; /* one tick wait XXX: 10 ms assumed */ if (delay1 < delay) delay = delay1; break; default: c->poll_entry = NULL; break; } c = c->next; } /* wait for an event on one connection. We poll at least every second to handle timeouts */ do { ret = poll(poll_table, poll_entry - poll_table, delay); } while (ret == -1); cur_time = gettime_ms(); if (need_to_start_children) { need_to_start_children = 0; start_children(first_feed); } /* now handle the events */ for(c = first_http_ctx; c != NULL; c = c_next) { c_next = c->next; if (handle_connection(c) < 0) { /* close and free the connection */ log_connection(c); close_connection(c); } } poll_entry = poll_table; /* new HTTP connection request ? */ if (poll_entry->revents & POLLIN) { new_connection(server_fd, 0); } poll_entry++; /* new RTSP connection request ? */ if (poll_entry->revents & POLLIN) { new_connection(rtsp_server_fd, 1); } } } /* start waiting for a new HTTP/RTSP request */ static void start_wait_request(HTTPContext *c, int is_rtsp) { c->buffer_ptr = c->buffer; c->buffer_end = c->buffer + c->buffer_size - 1; /* leave room for '\0' */ if (is_rtsp) { c->timeout = cur_time + RTSP_REQUEST_TIMEOUT; c->state = RTSPSTATE_WAIT_REQUEST; } else { c->timeout = cur_time + HTTP_REQUEST_TIMEOUT; c->state = HTTPSTATE_WAIT_REQUEST; } } static void new_connection(int server_fd, int is_rtsp) { struct sockaddr_in from_addr; int fd, len; HTTPContext *c = NULL; len = sizeof(from_addr); fd = accept(server_fd, (struct sockaddr *)&from_addr, &len); if (fd < 0) return; fcntl(fd, F_SETFL, O_NONBLOCK); /* XXX: should output a warning page when coming close to the connection limit */ if (nb_connections >= nb_max_connections) goto fail; /* add a new connection */ c = av_mallocz(sizeof(HTTPContext)); if (!c) goto fail; c->next = first_http_ctx; first_http_ctx = c; c->fd = fd; c->poll_entry = NULL; c->from_addr = from_addr; c->buffer_size = IOBUFFER_INIT_SIZE; c->buffer = av_malloc(c->buffer_size); if (!c->buffer) goto fail; nb_connections++; start_wait_request(c, is_rtsp); return; fail: if (c) { av_free(c->buffer); av_free(c); } close(fd); } static void close_connection(HTTPContext *c) { HTTPContext **cp, *c1; int i, nb_streams; AVFormatContext *ctx; URLContext *h; AVStream *st; /* remove connection from list */ cp = &first_http_ctx; while ((*cp) != NULL) { c1 = *cp; if (c1 == c) { *cp = c->next; } else { cp = &c1->next; } } /* remove connection associated resources */ if (c->fd >= 0) close(c->fd); if (c->fmt_in) { /* close each frame parser */ for(i=0;ifmt_in->nb_streams;i++) { st = c->fmt_in->streams[i]; if (st->codec.codec) { avcodec_close(&st->codec); } } av_close_input_file(c->fmt_in); } /* free RTP output streams if any */ nb_streams = 0; if (c->stream) nb_streams = c->stream->nb_streams; for(i=0;irtp_ctx[i]; if (ctx) { av_write_trailer(ctx); av_free(ctx); } h = c->rtp_handles[i]; if (h) { url_close(h); } } nb_bandwidth -= c->bandwidth; av_freep(&c->pb_buffer); av_free(c->buffer); av_free(c); nb_connections--; } static int handle_connection(HTTPContext *c) { int len, ret; switch(c->state) { case HTTPSTATE_WAIT_REQUEST: case RTSPSTATE_WAIT_REQUEST: /* timeout ? */ if ((c->timeout - cur_time) < 0) return -1; if (c->poll_entry->revents & (POLLERR | POLLHUP)) return -1; /* no need to read if no events */ if (!(c->poll_entry->revents & POLLIN)) return 0; /* read the data */ len = read(c->fd, c->buffer_ptr, c->buffer_end - c->buffer_ptr); if (len < 0) { if (errno != EAGAIN && errno != EINTR) return -1; } else if (len == 0) { return -1; } else { /* search for end of request. XXX: not fully correct since garbage could come after the end */ UINT8 *ptr; c->buffer_ptr += len; ptr = c->buffer_ptr; if ((ptr >= c->buffer + 2 && !memcmp(ptr-2, "\n\n", 2)) || (ptr >= c->buffer + 4 && !memcmp(ptr-4, "\r\n\r\n", 4))) { /* request found : parse it and reply */ if (c->state == HTTPSTATE_WAIT_REQUEST) { ret = http_parse_request(c); } else { ret = rtsp_parse_request(c); } if (ret < 0) return -1; } else if (ptr >= c->buffer_end) { /* request too long: cannot do anything */ return -1; } } break; case HTTPSTATE_SEND_HEADER: if (c->poll_entry->revents & (POLLERR | POLLHUP)) return -1; /* no need to write if no events */ if (!(c->poll_entry->revents & POLLOUT)) return 0; len = write(c->fd, c->buffer_ptr, c->buffer_end - c->buffer_ptr); if (len < 0) { if (errno != EAGAIN && errno != EINTR) { /* error : close connection */ av_freep(&c->pb_buffer); return -1; } } else { c->buffer_ptr += len; if (c->stream) c->stream->bytes_served += len; c->data_count += len; if (c->buffer_ptr >= c->buffer_end) { av_freep(&c->pb_buffer); /* if error, exit */ if (c->http_error) { return -1; } /* all the buffer was sent : synchronize to the incoming stream */ c->state = HTTPSTATE_SEND_DATA_HEADER; c->buffer_ptr = c->buffer_end = c->buffer; } } break; case HTTPSTATE_SEND_DATA: case HTTPSTATE_SEND_DATA_HEADER: case HTTPSTATE_SEND_DATA_TRAILER: /* for packetized output, we consider we can always write (the input streams sets the speed). It may be better to verify that we do not rely too much on the kernel queues */ if (!c->is_packetized) { if (c->poll_entry->revents & (POLLERR | POLLHUP)) return -1; /* no need to read if no events */ if (!(c->poll_entry->revents & POLLOUT)) return 0; } if (http_send_data(c) < 0) return -1; break; case HTTPSTATE_RECEIVE_DATA: /* no need to read if no events */ if (c->poll_entry->revents & (POLLERR | POLLHUP)) return -1; if (!(c->poll_entry->revents & POLLIN)) return 0; if (http_receive_data(c) < 0) return -1; break; case HTTPSTATE_WAIT_FEED: /* no need to read if no events */ if (c->poll_entry->revents & (POLLIN | POLLERR | POLLHUP)) return -1; /* nothing to do, we'll be waken up by incoming feed packets */ break; case HTTPSTATE_WAIT: /* if the delay expired, we can send new packets */ if (compute_send_delay(c) <= 0) c->state = HTTPSTATE_SEND_DATA; break; case HTTPSTATE_WAIT_SHORT: /* just return back to send data */ c->state = HTTPSTATE_SEND_DATA; break; case RTSPSTATE_SEND_REPLY: if (c->poll_entry->revents & (POLLERR | POLLHUP)) { av_freep(&c->pb_buffer); return -1; } /* no need to write if no events */ if (!(c->poll_entry->revents & POLLOUT)) return 0; len = write(c->fd, c->buffer_ptr, c->buffer_end - c->buffer_ptr); if (len < 0) { if (errno != EAGAIN && errno != EINTR) { /* error : close connection */ av_freep(&c->pb_buffer); return -1; } } else { c->buffer_ptr += len; c->data_count += len; if (c->buffer_ptr >= c->buffer_end) { /* all the buffer was sent : wait for a new request */ av_freep(&c->pb_buffer); start_wait_request(c, 1); } } break; case HTTPSTATE_READY: /* nothing to do */ break; default: return -1; } return 0; } static int extract_rates(char *rates, int ratelen, const char *request) { const char *p; for (p = request; *p && *p != '\r' && *p != '\n'; ) { if (strncasecmp(p, "Pragma:", 7) == 0) { const char *q = p + 7; while (*q && *q != '\n' && isspace(*q)) q++; if (strncasecmp(q, "stream-switch-entry=", 20) == 0) { int stream_no; int rate_no; q += 20; memset(rates, 0xff, ratelen); while (1) { while (*q && *q != '\n' && *q != ':') q++; if (sscanf(q, ":%d:%d", &stream_no, &rate_no) != 2) { break; } stream_no--; if (stream_no < ratelen && stream_no >= 0) { rates[stream_no] = rate_no; } while (*q && *q != '\n' && !isspace(*q)) q++; } return 1; } } p = strchr(p, '\n'); if (!p) break; p++; } return 0; } static int find_stream_in_feed(FFStream *feed, AVCodecContext *codec, int bit_rate) { int i; int best_bitrate = 100000000; int best = -1; for (i = 0; i < feed->nb_streams; i++) { AVCodecContext *feed_codec = &feed->streams[i]->codec; if (feed_codec->codec_id != codec->codec_id || feed_codec->sample_rate != codec->sample_rate || feed_codec->width != codec->width || feed_codec->height != codec->height) { continue; } /* Potential stream */ /* We want the fastest stream less than bit_rate, or the slowest * faster than bit_rate */ if (feed_codec->bit_rate <= bit_rate) { if (best_bitrate > bit_rate || feed_codec->bit_rate > best_bitrate) { best_bitrate = feed_codec->bit_rate; best = i; } } else { if (feed_codec->bit_rate < best_bitrate) { best_bitrate = feed_codec->bit_rate; best = i; } } } return best; } static int modify_current_stream(HTTPContext *c, char *rates) { int i; FFStream *req = c->stream; int action_required = 0; for (i = 0; i < req->nb_streams; i++) { AVCodecContext *codec = &req->streams[i]->codec; switch(rates[i]) { case 0: c->switch_feed_streams[i] = req->feed_streams[i]; break; case 1: c->switch_feed_streams[i] = find_stream_in_feed(req->feed, codec, codec->bit_rate / 2); break; case 2: /* Wants off or slow */ c->switch_feed_streams[i] = find_stream_in_feed(req->feed, codec, codec->bit_rate / 4); #ifdef WANTS_OFF /* This doesn't work well when it turns off the only stream! */ c->switch_feed_streams[i] = -2; c->feed_streams[i] = -2; #endif break; } if (c->switch_feed_streams[i] >= 0 && c->switch_feed_streams[i] != c->feed_streams[i]) action_required = 1; } return action_required; } static void do_switch_stream(HTTPContext *c, int i) { if (c->switch_feed_streams[i] >= 0) { #ifdef PHILIP c->feed_streams[i] = c->switch_feed_streams[i]; #endif /* Now update the stream */ } c->switch_feed_streams[i] = -1; } /* XXX: factorize in utils.c ? */ /* XXX: take care with different space meaning */ static void skip_spaces(const char **pp) { const char *p; p = *pp; while (*p == ' ' || *p == '\t') p++; *pp = p; } static void get_word(char *buf, int buf_size, const char **pp) { const char *p; char *q; p = *pp; skip_spaces(&p); q = buf; while (!isspace(*p) && *p != '\0') { if ((q - buf) < buf_size - 1) *q++ = *p; p++; } if (buf_size > 0) *q = '\0'; *pp = p; } static int validate_acl(FFStream *stream, HTTPContext *c) { enum IPAddressAction last_action = IP_DENY; IPAddressACL *acl; struct in_addr *src = &c->from_addr.sin_addr; for (acl = stream->acl; acl; acl = acl->next) { if (src->s_addr >= acl->first.s_addr && src->s_addr <= acl->last.s_addr) { return (acl->action == IP_ALLOW) ? 1 : 0; } last_action = acl->action; } /* Nothing matched, so return not the last action */ return (last_action == IP_DENY) ? 1 : 0; } /* parse http request and prepare header */ static int http_parse_request(HTTPContext *c) { char *p; int post; int doing_asx; int doing_asf_redirector; int doing_ram; int doing_rtsp_redirector; char cmd[32]; char info[1024], *filename; char url[1024], *q; char protocol[32]; char msg[1024]; const char *mime_type; FFStream *stream; int i; char ratebuf[32]; char *useragent = 0; p = c->buffer; get_word(cmd, sizeof(cmd), (const char **)&p); pstrcpy(c->method, sizeof(c->method), cmd); if (!strcmp(cmd, "GET")) post = 0; else if (!strcmp(cmd, "POST")) post = 1; else return -1; get_word(url, sizeof(url), (const char **)&p); pstrcpy(c->url, sizeof(c->url), url); get_word(protocol, sizeof(protocol), (const char **)&p); if (strcmp(protocol, "HTTP/1.0") && strcmp(protocol, "HTTP/1.1")) return -1; pstrcpy(c->protocol, sizeof(c->protocol), protocol); /* find the filename and the optional info string in the request */ p = url; if (*p == '/') p++; filename = p; p = strchr(p, '?'); if (p) { pstrcpy(info, sizeof(info), p); *p = '\0'; } else { info[0] = '\0'; } for (p = c->buffer; *p && *p != '\r' && *p != '\n'; ) { if (strncasecmp(p, "User-Agent:", 11) == 0) { useragent = p + 11; if (*useragent && *useragent != '\n' && isspace(*useragent)) useragent++; break; } p = strchr(p, '\n'); if (!p) break; p++; } if (strlen(filename) > 4 && strcmp(".asx", filename + strlen(filename) - 4) == 0) { doing_asx = 1; filename[strlen(filename)-1] = 'f'; } else { doing_asx = 0; } if (strlen(filename) > 4 && strcmp(".asf", filename + strlen(filename) - 4) == 0 && (!useragent || strncasecmp(useragent, "NSPlayer", 8) != 0)) { /* if this isn't WMP or lookalike, return the redirector file */ doing_asf_redirector = 1; } else { doing_asf_redirector = 0; } if (strlen(filename) > 4 && (strcmp(".rpm", filename + strlen(filename) - 4) == 0 || strcmp(".ram", filename + strlen(filename) - 4) == 0)) { doing_ram = 1; strcpy(filename + strlen(filename)-2, "m"); } else { doing_ram = 0; } if (strlen(filename) > 5 && strcmp(".rtsp", filename + strlen(filename) - 5) == 0) { char file1[1024]; char file2[1024]; char *p; doing_rtsp_redirector = 1; /* compute filename by matching without the file extensions */ pstrcpy(file1, sizeof(file1), filename); p = strrchr(file1, '.'); if (p) *p = '\0'; for(stream = first_stream; stream != NULL; stream = stream->next) { pstrcpy(file2, sizeof(file2), stream->filename); p = strrchr(file2, '.'); if (p) *p = '\0'; if (!strcmp(file1, file2)) { pstrcpy(url, sizeof(url), stream->filename); filename = url; break; } } } else { doing_rtsp_redirector = 0; } stream = first_stream; while (stream != NULL) { if (!strcmp(stream->filename, filename) && validate_acl(stream, c)) break; stream = stream->next; } if (stream == NULL) { sprintf(msg, "File '%s' not found", url); goto send_error; } c->stream = stream; memcpy(c->feed_streams, stream->feed_streams, sizeof(c->feed_streams)); memset(c->switch_feed_streams, -1, sizeof(c->switch_feed_streams)); if (stream->stream_type == STREAM_TYPE_REDIRECT) { c->http_error = 301; q = c->buffer; q += sprintf(q, "HTTP/1.0 301 Moved\r\n"); q += sprintf(q, "Location: %s\r\n", stream->feed_filename); q += sprintf(q, "Content-type: text/html\r\n"); q += sprintf(q, "\r\n"); q += sprintf(q, "Moved\r\n"); q += sprintf(q, "You should be redirected.\r\n", stream->feed_filename); q += sprintf(q, "\r\n"); /* prepare output buffer */ c->buffer_ptr = c->buffer; c->buffer_end = q; c->state = HTTPSTATE_SEND_HEADER; return 0; } /* If this is WMP, get the rate information */ if (extract_rates(ratebuf, sizeof(ratebuf), c->buffer)) { if (modify_current_stream(c, ratebuf)) { for (i = 0; i < sizeof(c->feed_streams) / sizeof(c->feed_streams[0]); i++) { if (c->switch_feed_streams[i] >= 0) do_switch_stream(c, i); } } } if (post == 0 && stream->stream_type == STREAM_TYPE_LIVE) { /* See if we meet the bandwidth requirements */ for(i=0;inb_streams;i++) { AVStream *st = stream->streams[i]; switch(st->codec.codec_type) { case CODEC_TYPE_AUDIO: c->bandwidth += st->codec.bit_rate; break; case CODEC_TYPE_VIDEO: c->bandwidth += st->codec.bit_rate; break; default: av_abort(); } } } c->bandwidth /= 1000; nb_bandwidth += c->bandwidth; if (post == 0 && nb_max_bandwidth < nb_bandwidth) { c->http_error = 200; q = c->buffer; q += sprintf(q, "HTTP/1.0 200 Server too busy\r\n"); q += sprintf(q, "Content-type: text/html\r\n"); q += sprintf(q, "\r\n"); q += sprintf(q, "Too busy\r\n"); q += sprintf(q, "The server is too busy to serve your request at this time.

\r\n"); q += sprintf(q, "The bandwidth being served (including your stream) is %dkbit/sec, and this exceeds the limit of %dkbit/sec\r\n", nb_bandwidth, nb_max_bandwidth); q += sprintf(q, "\r\n"); /* prepare output buffer */ c->buffer_ptr = c->buffer; c->buffer_end = q; c->state = HTTPSTATE_SEND_HEADER; return 0; } if (doing_asx || doing_ram || doing_asf_redirector || doing_rtsp_redirector) { char *hostinfo = 0; for (p = c->buffer; *p && *p != '\r' && *p != '\n'; ) { if (strncasecmp(p, "Host:", 5) == 0) { hostinfo = p + 5; break; } p = strchr(p, '\n'); if (!p) break; p++; } if (hostinfo) { char *eoh; char hostbuf[260]; while (isspace(*hostinfo)) hostinfo++; eoh = strchr(hostinfo, '\n'); if (eoh) { if (eoh[-1] == '\r') eoh--; if (eoh - hostinfo < sizeof(hostbuf) - 1) { memcpy(hostbuf, hostinfo, eoh - hostinfo); hostbuf[eoh - hostinfo] = 0; c->http_error = 200; q = c->buffer; if (doing_asx) { q += sprintf(q, "HTTP/1.0 200 ASX Follows\r\n"); q += sprintf(q, "Content-type: video/x-ms-asf\r\n"); q += sprintf(q, "\r\n"); q += sprintf(q, "\r\n"); q += sprintf(q, "\r\n"); q += sprintf(q, "\r\n", hostbuf, filename, info); q += sprintf(q, "\r\n"); } else if (doing_ram) { q += sprintf(q, "HTTP/1.0 200 RAM Follows\r\n"); q += sprintf(q, "Content-type: audio/x-pn-realaudio\r\n"); q += sprintf(q, "\r\n"); q += sprintf(q, "# Autogenerated by ffserver\r\n"); q += sprintf(q, "http://%s/%s%s\r\n", hostbuf, filename, info); } else if (doing_asf_redirector) { q += sprintf(q, "HTTP/1.0 200 ASF Redirect follows\r\n"); q += sprintf(q, "Content-type: video/x-ms-asf\r\n"); q += sprintf(q, "\r\n"); q += sprintf(q, "[Reference]\r\n"); q += sprintf(q, "Ref1=http://%s/%s%s\r\n", hostbuf, filename, info); } else if (doing_rtsp_redirector) { char hostname[256], *p; /* extract only hostname */ pstrcpy(hostname, sizeof(hostname), hostbuf); p = strrchr(hostname, ':'); if (p) *p = '\0'; q += sprintf(q, "HTTP/1.0 200 RTSP Redirect follows\r\n"); /* XXX: incorrect mime type ? */ q += sprintf(q, "Content-type: application/x-rtsp\r\n"); q += sprintf(q, "\r\n"); q += sprintf(q, "rtsp://%s:%d/%s\r\n", hostname, ntohs(my_rtsp_addr.sin_port), filename); } else { av_abort(); } /* prepare output buffer */ c->buffer_ptr = c->buffer; c->buffer_end = q; c->state = HTTPSTATE_SEND_HEADER; return 0; } } } sprintf(msg, "ASX/RAM file not handled"); goto send_error; } stream->conns_served++; /* XXX: add there authenticate and IP match */ if (post) { /* if post, it means a feed is being sent */ if (!stream->is_feed) { /* However it might be a status report from WMP! Lets log the data * as it might come in handy one day */ char *logline = 0; int client_id = 0; for (p = c->buffer; *p && *p != '\r' && *p != '\n'; ) { if (strncasecmp(p, "Pragma: log-line=", 17) == 0) { logline = p; break; } if (strncasecmp(p, "Pragma: client-id=", 18) == 0) { client_id = strtol(p + 18, 0, 10); } p = strchr(p, '\n'); if (!p) break; p++; } if (logline) { char *eol = strchr(logline, '\n'); logline += 17; if (eol) { if (eol[-1] == '\r') eol--; http_log("%.*s\n", eol - logline, logline); c->suppress_log = 1; } } #ifdef DEBUG_WMP http_log("\nGot request:\n%s\n", c->buffer); #endif if (client_id && extract_rates(ratebuf, sizeof(ratebuf), c->buffer)) { HTTPContext *wmpc; /* Now we have to find the client_id */ for (wmpc = first_http_ctx; wmpc; wmpc = wmpc->next) { if (wmpc->wmp_client_id == client_id) break; } if (wmpc) { if (modify_current_stream(wmpc, ratebuf)) { wmpc->switch_pending = 1; } } } sprintf(msg, "POST command not handled"); goto send_error; } if (http_start_receive_data(c) < 0) { sprintf(msg, "could not open feed"); goto send_error; } c->http_error = 0; c->state = HTTPSTATE_RECEIVE_DATA; return 0; } #ifdef DEBUG_WMP if (strcmp(stream->filename + strlen(stream->filename) - 4, ".asf") == 0) { http_log("\nGot request:\n%s\n", c->buffer); } #endif if (c->stream->stream_type == STREAM_TYPE_STATUS) goto send_stats; /* open input stream */ if (open_input_stream(c, info) < 0) { sprintf(msg, "Input stream corresponding to '%s' not found", url); goto send_error; } /* prepare http header */ q = c->buffer; q += sprintf(q, "HTTP/1.0 200 OK\r\n"); mime_type = c->stream->fmt->mime_type; if (!mime_type) mime_type = "application/x-octet_stream"; q += sprintf(q, "Pragma: no-cache\r\n"); /* for asf, we need extra headers */ if (!strcmp(c->stream->fmt->name,"asf_stream")) { /* Need to allocate a client id */ c->wmp_client_id = random() & 0x7fffffff; q += sprintf(q, "Server: Cougar 4.1.0.3923\r\nCache-Control: no-cache\r\nPragma: client-id=%d\r\nPragma: features=\"broadcast\"\r\n", c->wmp_client_id); mime_type = "application/octet-stream"; } q += sprintf(q, "Content-Type: %s\r\n", mime_type); q += sprintf(q, "\r\n"); /* prepare output buffer */ c->http_error = 0; c->buffer_ptr = c->buffer; c->buffer_end = q; c->state = HTTPSTATE_SEND_HEADER; return 0; send_error: c->http_error = 404; q = c->buffer; q += sprintf(q, "HTTP/1.0 404 Not Found\r\n"); q += sprintf(q, "Content-type: %s\r\n", "text/html"); q += sprintf(q, "\r\n"); q += sprintf(q, "\n"); q += sprintf(q, "404 Not Found\n"); q += sprintf(q, "%s\n", msg); q += sprintf(q, "\n"); /* prepare output buffer */ c->buffer_ptr = c->buffer; c->buffer_end = q; c->state = HTTPSTATE_SEND_HEADER; return 0; send_stats: compute_stats(c); c->http_error = 200; /* horrible : we use this value to avoid going to the send data state */ c->state = HTTPSTATE_SEND_HEADER; return 0; } static void fmt_bytecount(ByteIOContext *pb, INT64 count) { static const char *suffix = " kMGTP"; const char *s; for (s = suffix; count >= 100000 && s[1]; count /= 1000, s++) { } url_fprintf(pb, "%lld%c", count, *s); } static void compute_stats(HTTPContext *c) { HTTPContext *c1; FFStream *stream; char *p; time_t ti; int i, len; ByteIOContext pb1, *pb = &pb1; if (url_open_dyn_buf(pb) < 0) { /* XXX: return an error ? */ c->buffer_ptr = c->buffer; c->buffer_end = c->buffer; return; } url_fprintf(pb, "HTTP/1.0 200 OK\r\n"); url_fprintf(pb, "Content-type: %s\r\n", "text/html"); url_fprintf(pb, "Pragma: no-cache\r\n"); url_fprintf(pb, "\r\n"); url_fprintf(pb, "FFServer Status\n"); if (c->stream->feed_filename) { url_fprintf(pb, "\n", c->stream->feed_filename); } url_fprintf(pb, "\n"); url_fprintf(pb, "

FFServer Status

\n"); /* format status */ url_fprintf(pb, "

Available Streams

\n"); url_fprintf(pb, "\n"); url_fprintf(pb, "
PathServed
Conns

bytes
FormatBit rate
kbits/s
Video
kbits/s

Codec
Audio
kbits/s

Codec
Feed\n"); stream = first_stream; while (stream != NULL) { char sfilename[1024]; char *eosf; if (stream->feed != stream) { pstrcpy(sfilename, sizeof(sfilename) - 10, stream->filename); eosf = sfilename + strlen(sfilename); if (eosf - sfilename >= 4) { if (strcmp(eosf - 4, ".asf") == 0) { strcpy(eosf - 4, ".asx"); } else if (strcmp(eosf - 3, ".rm") == 0) { strcpy(eosf - 3, ".ram"); } else if (stream->fmt == &rtp_mux) { /* generate a sample RTSP director - maybe should generate a .sdp file ? */ eosf = strrchr(sfilename, '.'); if (!eosf) eosf = sfilename + strlen(sfilename); strcpy(eosf, ".rtsp"); } } url_fprintf(pb, "
%s ", sfilename, stream->filename); url_fprintf(pb, " %d ", stream->conns_served); fmt_bytecount(pb, stream->bytes_served); switch(stream->stream_type) { case STREAM_TYPE_LIVE: { int audio_bit_rate = 0; int video_bit_rate = 0; char *audio_codec_name = ""; char *video_codec_name = ""; char *audio_codec_name_extra = ""; char *video_codec_name_extra = ""; for(i=0;inb_streams;i++) { AVStream *st = stream->streams[i]; AVCodec *codec = avcodec_find_encoder(st->codec.codec_id); switch(st->codec.codec_type) { case CODEC_TYPE_AUDIO: audio_bit_rate += st->codec.bit_rate; if (codec) { if (*audio_codec_name) audio_codec_name_extra = "..."; audio_codec_name = codec->name; } break; case CODEC_TYPE_VIDEO: video_bit_rate += st->codec.bit_rate; if (codec) { if (*video_codec_name) video_codec_name_extra = "..."; video_codec_name = codec->name; } break; default: av_abort(); } } url_fprintf(pb, " %s %d %d %s %s %d %s %s", stream->fmt->name, (audio_bit_rate + video_bit_rate) / 1000, video_bit_rate / 1000, video_codec_name, video_codec_name_extra, audio_bit_rate / 1000, audio_codec_name, audio_codec_name_extra); if (stream->feed) { url_fprintf(pb, "%s", stream->feed->filename); } else { url_fprintf(pb, "%s", stream->feed_filename); } url_fprintf(pb, "\n"); } break; default: url_fprintf(pb, " - - - - \n"); break; } } stream = stream->next; } url_fprintf(pb, "
\n"); stream = first_stream; while (stream != NULL) { if (stream->feed == stream) { url_fprintf(pb, "

Feed %s

", stream->filename); if (stream->pid) { url_fprintf(pb, "Running as pid %d.\n", stream->pid); #if defined(linux) && !defined(CONFIG_NOCUTILS) { FILE *pid_stat; char ps_cmd[64]; /* This is somewhat linux specific I guess */ snprintf(ps_cmd, sizeof(ps_cmd), "ps -o \"%%cpu,cputime\" --no-headers %d", stream->pid); pid_stat = popen(ps_cmd, "r"); if (pid_stat) { char cpuperc[10]; char cpuused[64]; if (fscanf(pid_stat, "%10s %64s", cpuperc, cpuused) == 2) { url_fprintf(pb, "Currently using %s%% of the cpu. Total time used %s.\n", cpuperc, cpuused); } fclose(pid_stat); } } #endif url_fprintf(pb, "

"); } url_fprintf(pb, "
Streamtypekbits/scodecParameters\n"); for (i = 0; i < stream->nb_streams; i++) { AVStream *st = stream->streams[i]; AVCodec *codec = avcodec_find_encoder(st->codec.codec_id); char *type = "unknown"; char parameters[64]; parameters[0] = 0; switch(st->codec.codec_type) { case CODEC_TYPE_AUDIO: type = "audio"; break; case CODEC_TYPE_VIDEO: type = "video"; sprintf(parameters, "%dx%d, q=%d-%d, fps=%d", st->codec.width, st->codec.height, st->codec.qmin, st->codec.qmax, st->codec.frame_rate / FRAME_RATE_BASE); break; default: av_abort(); } url_fprintf(pb, "
%d%s%d%s%s\n", i, type, st->codec.bit_rate/1000, codec ? codec->name : "", parameters); } url_fprintf(pb, "
\n"); } stream = stream->next; } #if 0 { float avg; AVCodecContext *enc; char buf[1024]; /* feed status */ stream = first_feed; while (stream != NULL) { url_fprintf(pb, "

Feed '%s'

\n", stream->filename); url_fprintf(pb, "\n"); url_fprintf(pb, "
ParametersFrame countSizeAvg bitrate (kbits/s)\n"); for(i=0;inb_streams;i++) { AVStream *st = stream->streams[i]; FeedData *fdata = st->priv_data; enc = &st->codec; avcodec_string(buf, sizeof(buf), enc); avg = fdata->avg_frame_size * (float)enc->rate * 8.0; if (enc->codec->type == CODEC_TYPE_AUDIO && enc->frame_size > 0) avg /= enc->frame_size; url_fprintf(pb, "
%s %d %Ld %0.1f\n", buf, enc->frame_number, fdata->data_count, avg / 1000.0); } url_fprintf(pb, "
\n"); stream = stream->next_feed; } } #endif /* connection status */ url_fprintf(pb, "

Connection Status

\n"); url_fprintf(pb, "Number of connections: %d / %d
\n", nb_connections, nb_max_connections); url_fprintf(pb, "Bandwidth in use: %dk / %dk
\n", nb_bandwidth, nb_max_bandwidth); url_fprintf(pb, "\n"); url_fprintf(pb, "
#FileIPProtoStateTarget bits/secActual bits/secBytes transferred\n"); c1 = first_http_ctx; i = 0; while (c1 != NULL) { int bitrate; int j; bitrate = 0; if (c1->stream) { for (j = 0; j < c1->stream->nb_streams; j++) { if (!c1->stream->feed) { bitrate += c1->stream->streams[j]->codec.bit_rate; } else { if (c1->feed_streams[j] >= 0) { bitrate += c1->stream->feed->streams[c1->feed_streams[j]]->codec.bit_rate; } } } } i++; p = inet_ntoa(c1->from_addr.sin_addr); url_fprintf(pb, "
%d%s%s%s%s%s", i, c1->stream ? c1->stream->filename : "", c1->state == HTTPSTATE_RECEIVE_DATA ? "(input)" : "", p, c1->protocol, http_state[c1->state]); fmt_bytecount(pb, bitrate); url_fprintf(pb, ""); fmt_bytecount(pb, compute_datarate(&c1->datarate, c1->data_count) * 8); url_fprintf(pb, ""); fmt_bytecount(pb, c1->data_count); url_fprintf(pb, "\n"); c1 = c1->next; } url_fprintf(pb, "
\n"); /* date */ ti = time(NULL); p = ctime(&ti); url_fprintf(pb, "
Generated at %s", p); url_fprintf(pb, "\n\n"); len = url_close_dyn_buf(pb, &c->pb_buffer); c->buffer_ptr = c->pb_buffer; c->buffer_end = c->pb_buffer + len; } /* check if the parser needs to be opened for stream i */ static void open_parser(AVFormatContext *s, int i) { AVStream *st = s->streams[i]; AVCodec *codec; if (!st->codec.codec) { codec = avcodec_find_decoder(st->codec.codec_id); if (codec && (codec->capabilities & CODEC_CAP_PARSE_ONLY)) { st->codec.parse_only = 1; if (avcodec_open(&st->codec, codec) < 0) { st->codec.parse_only = 0; } } } } static int open_input_stream(HTTPContext *c, const char *info) { char buf[128]; char input_filename[1024]; AVFormatContext *s; int buf_size, i; INT64 stream_pos; /* find file name */ if (c->stream->feed) { strcpy(input_filename, c->stream->feed->feed_filename); buf_size = FFM_PACKET_SIZE; /* compute position (absolute time) */ if (find_info_tag(buf, sizeof(buf), "date", info)) { stream_pos = parse_date(buf, 0); } else if (find_info_tag(buf, sizeof(buf), "buffer", info)) { int prebuffer = strtol(buf, 0, 10); stream_pos = av_gettime() - prebuffer * (INT64)1000000; } else { stream_pos = av_gettime() - c->stream->prebuffer * (INT64)1000; } } else { strcpy(input_filename, c->stream->feed_filename); buf_size = 0; /* compute position (relative time) */ if (find_info_tag(buf, sizeof(buf), "date", info)) { stream_pos = parse_date(buf, 1); } else { stream_pos = 0; } } if (input_filename[0] == '\0') return -1; #if 0 { time_t when = stream_pos / 1000000; http_log("Stream pos = %lld, time=%s", stream_pos, ctime(&when)); } #endif /* open stream */ if (av_open_input_file(&s, input_filename, NULL, buf_size, NULL) < 0) { http_log("%s not found", input_filename); return -1; } c->fmt_in = s; /* open each parser */ for(i=0;inb_streams;i++) open_parser(s, i); /* choose stream as clock source (we favorize video stream if present) for packet sending */ c->pts_stream_index = 0; for(i=0;istream->nb_streams;i++) { if (c->pts_stream_index == 0 && c->stream->streams[i]->codec.codec_type == CODEC_TYPE_VIDEO) { c->pts_stream_index = i; } } if (c->fmt_in->iformat->read_seek) { c->fmt_in->iformat->read_seek(c->fmt_in, stream_pos); } /* set the start time (needed for maxtime and RTP packet timing) */ c->start_time = cur_time; c->first_pts = AV_NOPTS_VALUE; return 0; } /* currently desactivated because the new PTS handling is not satisfactory yet */ //#define AV_READ_FRAME #ifdef AV_READ_FRAME /* XXX: generalize that in ffmpeg for picture/audio/data. Currently the return packet MUST NOT be freed */ int av_read_frame(AVFormatContext *s, AVPacket *pkt) { AVStream *st; int len, ret, old_nb_streams, i; /* see if remaining frames must be parsed */ for(;;) { if (s->cur_len > 0) { st = s->streams[s->cur_pkt.stream_index]; len = avcodec_parse_frame(&st->codec, &pkt->data, &pkt->size, s->cur_ptr, s->cur_len); if (len < 0) { /* error: get next packet */ s->cur_len = 0; } else { s->cur_ptr += len; s->cur_len -= len; if (pkt->size) { /* init pts counter if not done */ if (st->pts.den == 0) { switch(st->codec.codec_type) { case CODEC_TYPE_AUDIO: st->pts_incr = (INT64)s->pts_den; av_frac_init(&st->pts, st->pts.val, 0, (INT64)s->pts_num * st->codec.sample_rate); break; case CODEC_TYPE_VIDEO: st->pts_incr = (INT64)s->pts_den * FRAME_RATE_BASE; av_frac_init(&st->pts, st->pts.val, 0, (INT64)s->pts_num * st->codec.frame_rate); break; default: av_abort(); } } /* a frame was read: return it */ pkt->pts = st->pts.val; #if 0 printf("add pts=%Lx num=%Lx den=%Lx incr=%Lx\n", st->pts.val, st->pts.num, st->pts.den, st->pts_incr); #endif switch(st->codec.codec_type) { case CODEC_TYPE_AUDIO: av_frac_add(&st->pts, st->pts_incr * st->codec.frame_size); break; case CODEC_TYPE_VIDEO: av_frac_add(&st->pts, st->pts_incr); break; default: av_abort(); } pkt->stream_index = s->cur_pkt.stream_index; /* we use the codec indication because it is more accurate than the demux flags */ pkt->flags = 0; if (st->codec.key_frame) pkt->flags |= PKT_FLAG_KEY; return 0; } } } else { /* free previous packet */ av_free_packet(&s->cur_pkt); old_nb_streams = s->nb_streams; ret = av_read_packet(s, &s->cur_pkt); if (ret) return ret; /* open parsers for each new streams */ for(i = old_nb_streams; i < s->nb_streams; i++) open_parser(s, i); st = s->streams[s->cur_pkt.stream_index]; /* update current pts (XXX: dts handling) from packet, or use current pts if none given */ if (s->cur_pkt.pts != AV_NOPTS_VALUE) { av_frac_set(&st->pts, s->cur_pkt.pts); } else { s->cur_pkt.pts = st->pts.val; } if (!st->codec.codec) { /* no codec opened: just return the raw packet */ *pkt = s->cur_pkt; /* no codec opened: just update the pts by considering we have one frame and free the packet */ if (st->pts.den == 0) { switch(st->codec.codec_type) { case CODEC_TYPE_AUDIO: st->pts_incr = (INT64)s->pts_den * st->codec.frame_size; av_frac_init(&st->pts, st->pts.val, 0, (INT64)s->pts_num * st->codec.sample_rate); break; case CODEC_TYPE_VIDEO: st->pts_incr = (INT64)s->pts_den * FRAME_RATE_BASE; av_frac_init(&st->pts, st->pts.val, 0, (INT64)s->pts_num * st->codec.frame_rate); break; default: av_abort(); } } av_frac_add(&st->pts, st->pts_incr); return 0; } else { s->cur_ptr = s->cur_pkt.data; s->cur_len = s->cur_pkt.size; } } } } static int compute_send_delay(HTTPContext *c) { INT64 cur_pts, delta_pts, next_pts; int delay1; /* compute current pts value from system time */ cur_pts = ((INT64)(cur_time - c->start_time) * c->fmt_in->pts_den) / (c->fmt_in->pts_num * 1000LL); /* compute the delta from the stream we choose as main clock (we do that to avoid using explicit buffers to do exact packet reordering for each stream */ /* XXX: really need to fix the number of streams */ if (c->pts_stream_index >= c->fmt_in->nb_streams) next_pts = cur_pts; else next_pts = c->fmt_in->streams[c->pts_stream_index]->pts.val; delta_pts = next_pts - cur_pts; if (delta_pts <= 0) { delay1 = 0; } else { delay1 = (delta_pts * 1000 * c->fmt_in->pts_num) / c->fmt_in->pts_den; } return delay1; } #else /* just fall backs */ int av_read_frame(AVFormatContext *s, AVPacket *pkt) { return av_read_packet(s, pkt); } static int compute_send_delay(HTTPContext *c) { int datarate = 8 * get_longterm_datarate(&c->datarate, c->data_count); if (datarate > c->bandwidth * 2000) { return 1000; } return 0; } #endif static int http_prepare_data(HTTPContext *c) { int i, len, ret; AVFormatContext *ctx; switch(c->state) { case HTTPSTATE_SEND_DATA_HEADER: memset(&c->fmt_ctx, 0, sizeof(c->fmt_ctx)); pstrcpy(c->fmt_ctx.author, sizeof(c->fmt_ctx.author), c->stream->author); pstrcpy(c->fmt_ctx.comment, sizeof(c->fmt_ctx.comment), c->stream->comment); pstrcpy(c->fmt_ctx.copyright, sizeof(c->fmt_ctx.copyright), c->stream->copyright); pstrcpy(c->fmt_ctx.title, sizeof(c->fmt_ctx.title), c->stream->title); /* open output stream by using specified codecs */ c->fmt_ctx.oformat = c->stream->fmt; c->fmt_ctx.nb_streams = c->stream->nb_streams; for(i=0;ifmt_ctx.nb_streams;i++) { AVStream *st; st = av_mallocz(sizeof(AVStream)); c->fmt_ctx.streams[i] = st; /* if file or feed, then just take streams from FFStream struct */ if (!c->stream->feed || c->stream->feed == c->stream) memcpy(st, c->stream->streams[i], sizeof(AVStream)); else memcpy(st, c->stream->feed->streams[c->stream->feed_streams[i]], sizeof(AVStream)); st->codec.frame_number = 0; /* XXX: should be done in AVStream, not in codec */ } c->got_key_frame = 0; /* prepare header and save header data in a stream */ if (url_open_dyn_buf(&c->fmt_ctx.pb) < 0) { /* XXX: potential leak */ return -1; } c->fmt_ctx.pb.is_streamed = 1; av_write_header(&c->fmt_ctx); len = url_close_dyn_buf(&c->fmt_ctx.pb, &c->pb_buffer); c->buffer_ptr = c->pb_buffer; c->buffer_end = c->pb_buffer + len; c->state = HTTPSTATE_SEND_DATA; c->last_packet_sent = 0; break; case HTTPSTATE_SEND_DATA: /* find a new packet */ { AVPacket pkt; /* read a packet from the input stream */ if (c->stream->feed) { ffm_set_write_index(c->fmt_in, c->stream->feed->feed_write_index, c->stream->feed->feed_size); } if (c->stream->max_time && c->stream->max_time + c->start_time - cur_time < 0) { /* We have timed out */ c->state = HTTPSTATE_SEND_DATA_TRAILER; } else { if (1 || c->is_packetized) { if (compute_send_delay(c) > 0) { c->state = HTTPSTATE_WAIT; return 1; /* state changed */ } } if (av_read_frame(c->fmt_in, &pkt) < 0) { if (c->stream->feed && c->stream->feed->feed_opened) { /* if coming from feed, it means we reached the end of the ffm file, so must wait for more data */ c->state = HTTPSTATE_WAIT_FEED; return 1; /* state changed */ } else { /* must send trailer now because eof or error */ c->state = HTTPSTATE_SEND_DATA_TRAILER; } } else { /* update first pts if needed */ if (c->first_pts == AV_NOPTS_VALUE) c->first_pts = pkt.pts; /* send it to the appropriate stream */ if (c->stream->feed) { /* if coming from a feed, select the right stream */ if (c->switch_pending) { c->switch_pending = 0; for(i=0;istream->nb_streams;i++) { if (c->switch_feed_streams[i] == pkt.stream_index) { if (pkt.flags & PKT_FLAG_KEY) { do_switch_stream(c, i); } } if (c->switch_feed_streams[i] >= 0) { c->switch_pending = 1; } } } for(i=0;istream->nb_streams;i++) { if (c->feed_streams[i] == pkt.stream_index) { pkt.stream_index = i; if (pkt.flags & PKT_FLAG_KEY) { c->got_key_frame |= 1 << i; } /* See if we have all the key frames, then * we start to send. This logic is not quite * right, but it works for the case of a * single video stream with one or more * audio streams (for which every frame is * typically a key frame). */ if (!c->stream->send_on_key || ((c->got_key_frame + 1) >> c->stream->nb_streams)) { goto send_it; } } } } else { AVCodecContext *codec; send_it: /* specific handling for RTP: we use several output stream (one for each RTP connection). XXX: need more abstract handling */ if (c->is_packetized) { c->packet_stream_index = pkt.stream_index; ctx = c->rtp_ctx[c->packet_stream_index]; codec = &ctx->streams[0]->codec; } else { ctx = &c->fmt_ctx; /* Fudge here */ codec = &ctx->streams[pkt.stream_index]->codec; } codec->key_frame = ((pkt.flags & PKT_FLAG_KEY) != 0); #ifdef PJSG if (codec->codec_type == CODEC_TYPE_AUDIO) { codec->frame_size = (codec->sample_rate * pkt.duration + 500000) / 1000000; /* printf("Calculated size %d, from sr %d, duration %d\n", codec->frame_size, codec->sample_rate, pkt.duration); */ } #endif if (c->is_packetized) { ret = url_open_dyn_packet_buf(&ctx->pb, url_get_max_packet_size(c->rtp_handles[c->packet_stream_index])); c->packet_byte_count = 0; c->packet_start_time_us = av_gettime(); } else { ret = url_open_dyn_buf(&ctx->pb); } if (ret < 0) { /* XXX: potential leak */ return -1; } if (av_write_frame(ctx, pkt.stream_index, pkt.data, pkt.size)) { c->state = HTTPSTATE_SEND_DATA_TRAILER; } len = url_close_dyn_buf(&ctx->pb, &c->pb_buffer); c->buffer_ptr = c->pb_buffer; c->buffer_end = c->pb_buffer + len; codec->frame_number++; } #ifndef AV_READ_FRAME av_free_packet(&pkt); #endif } } } break; default: case HTTPSTATE_SEND_DATA_TRAILER: /* last packet test ? */ if (c->last_packet_sent || c->is_packetized) return -1; ctx = &c->fmt_ctx; /* prepare header */ if (url_open_dyn_buf(&ctx->pb) < 0) { /* XXX: potential leak */ return -1; } av_write_trailer(ctx); len = url_close_dyn_buf(&ctx->pb, &c->pb_buffer); c->buffer_ptr = c->pb_buffer; c->buffer_end = c->pb_buffer + len; c->last_packet_sent = 1; break; } return 0; } /* in bit/s */ #define SHORT_TERM_BANDWIDTH 8000000 /* should convert the format at the same time */ static int http_send_data(HTTPContext *c) { int len, ret, dt; while (c->buffer_ptr >= c->buffer_end) { av_freep(&c->pb_buffer); ret = http_prepare_data(c); if (ret < 0) return -1; else if (ret == 0) { continue; } else { /* state change requested */ return 0; } } if (c->buffer_ptr < c->buffer_end) { if (c->is_packetized) { /* RTP/UDP data output */ len = c->buffer_end - c->buffer_ptr; if (len < 4) { /* fail safe - should never happen */ fail1: c->buffer_ptr = c->buffer_end; return 0; } len = (c->buffer_ptr[0] << 24) | (c->buffer_ptr[1] << 16) | (c->buffer_ptr[2] << 8) | (c->buffer_ptr[3]); if (len > (c->buffer_end - c->buffer_ptr)) goto fail1; /* short term bandwidth limitation */ dt = av_gettime() - c->packet_start_time_us; if (dt < 1) dt = 1; if ((c->packet_byte_count + len) * (INT64)1000000 >= (SHORT_TERM_BANDWIDTH / 8) * (INT64)dt) { /* bandwidth overflow : wait at most one tick and retry */ c->state = HTTPSTATE_WAIT_SHORT; return 0; } c->buffer_ptr += 4; url_write(c->rtp_handles[c->packet_stream_index], c->buffer_ptr, len); c->buffer_ptr += len; c->packet_byte_count += len; } else { /* TCP data output */ len = write(c->fd, c->buffer_ptr, c->buffer_end - c->buffer_ptr); if (len < 0) { if (errno != EAGAIN && errno != EINTR) { /* error : close connection */ return -1; } else { return 0; } } else { c->buffer_ptr += len; } } c->data_count += len; update_datarate(&c->datarate, c->data_count); if (c->stream) c->stream->bytes_served += len; } return 0; } static int http_start_receive_data(HTTPContext *c) { int fd; if (c->stream->feed_opened) return -1; /* open feed */ fd = open(c->stream->feed_filename, O_RDWR); if (fd < 0) return -1; c->feed_fd = fd; c->stream->feed_write_index = ffm_read_write_index(fd); c->stream->feed_size = lseek(fd, 0, SEEK_END); lseek(fd, 0, SEEK_SET); /* init buffer input */ c->buffer_ptr = c->buffer; c->buffer_end = c->buffer + FFM_PACKET_SIZE; c->stream->feed_opened = 1; return 0; } static int http_receive_data(HTTPContext *c) { HTTPContext *c1; if (c->buffer_end > c->buffer_ptr) { int len; len = read(c->fd, c->buffer_ptr, c->buffer_end - c->buffer_ptr); if (len < 0) { if (errno != EAGAIN && errno != EINTR) { /* error : close connection */ goto fail; } } else if (len == 0) { /* end of connection : close it */ goto fail; } else { c->buffer_ptr += len; c->data_count += len; update_datarate(&c->datarate, c->data_count); } } if (c->buffer_ptr >= c->buffer_end) { FFStream *feed = c->stream; /* a packet has been received : write it in the store, except if header */ if (c->data_count > FFM_PACKET_SIZE) { // printf("writing pos=0x%Lx size=0x%Lx\n", feed->feed_write_index, feed->feed_size); /* XXX: use llseek or url_seek */ lseek(c->feed_fd, feed->feed_write_index, SEEK_SET); write(c->feed_fd, c->buffer, FFM_PACKET_SIZE); feed->feed_write_index += FFM_PACKET_SIZE; /* update file size */ if (feed->feed_write_index > c->stream->feed_size) feed->feed_size = feed->feed_write_index; /* handle wrap around if max file size reached */ if (feed->feed_write_index >= c->stream->feed_max_size) feed->feed_write_index = FFM_PACKET_SIZE; /* write index */ ffm_write_write_index(c->feed_fd, feed->feed_write_index); /* wake up any waiting connections */ for(c1 = first_http_ctx; c1 != NULL; c1 = c1->next) { if (c1->state == HTTPSTATE_WAIT_FEED && c1->stream->feed == c->stream->feed) { c1->state = HTTPSTATE_SEND_DATA; } } } else { /* We have a header in our hands that contains useful data */ AVFormatContext s; AVInputFormat *fmt_in; ByteIOContext *pb = &s.pb; int i; memset(&s, 0, sizeof(s)); url_open_buf(pb, c->buffer, c->buffer_end - c->buffer, URL_RDONLY); pb->buf_end = c->buffer_end; /* ?? */ pb->is_streamed = 1; /* use feed output format name to find corresponding input format */ fmt_in = av_find_input_format(feed->fmt->name); if (!fmt_in) goto fail; s.priv_data = av_mallocz(fmt_in->priv_data_size); if (!s.priv_data) goto fail; if (fmt_in->read_header(&s, 0) < 0) { av_freep(&s.priv_data); goto fail; } /* Now we have the actual streams */ if (s.nb_streams != feed->nb_streams) { av_freep(&s.priv_data); goto fail; } for (i = 0; i < s.nb_streams; i++) { memcpy(&feed->streams[i]->codec, &s.streams[i]->codec, sizeof(AVCodecContext)); } av_freep(&s.priv_data); } c->buffer_ptr = c->buffer; } return 0; fail: c->stream->feed_opened = 0; close(c->feed_fd); return -1; } /********************************************************************/ /* RTSP handling */ static void rtsp_reply_header(HTTPContext *c, enum RTSPStatusCode error_number) { const char *str; time_t ti; char *p; char buf2[32]; switch(error_number) { #define DEF(n, c, s) case c: str = s; break; #include "rtspcodes.h" #undef DEF default: str = "Unknown Error"; break; } url_fprintf(c->pb, "RTSP/1.0 %d %s\r\n", error_number, str); url_fprintf(c->pb, "CSeq: %d\r\n", c->seq); /* output GMT time */ ti = time(NULL); p = ctime(&ti); strcpy(buf2, p); p = buf2 + strlen(p) - 1; if (*p == '\n') *p = '\0'; url_fprintf(c->pb, "Date: %s GMT\r\n", buf2); } static void rtsp_reply_error(HTTPContext *c, enum RTSPStatusCode error_number) { rtsp_reply_header(c, error_number); url_fprintf(c->pb, "\r\n"); } static int rtsp_parse_request(HTTPContext *c) { const char *p, *p1, *p2; char cmd[32]; char url[1024]; char protocol[32]; char line[1024]; ByteIOContext pb1; int len; RTSPHeader header1, *header = &header1; c->buffer_ptr[0] = '\0'; p = c->buffer; get_word(cmd, sizeof(cmd), &p); get_word(url, sizeof(url), &p); get_word(protocol, sizeof(protocol), &p); pstrcpy(c->method, sizeof(c->method), cmd); pstrcpy(c->url, sizeof(c->url), url); pstrcpy(c->protocol, sizeof(c->protocol), protocol); c->pb = &pb1; if (url_open_dyn_buf(c->pb) < 0) { /* XXX: cannot do more */ c->pb = NULL; /* safety */ return -1; } /* check version name */ if (strcmp(protocol, "RTSP/1.0") != 0) { rtsp_reply_error(c, RTSP_STATUS_VERSION); goto the_end; } /* parse each header line */ memset(header, 0, sizeof(RTSPHeader)); /* skip to next line */ while (*p != '\n' && *p != '\0') p++; if (*p == '\n') p++; while (*p != '\0') { p1 = strchr(p, '\n'); if (!p1) break; p2 = p1; if (p2 > p && p2[-1] == '\r') p2--; /* skip empty line */ if (p2 == p) break; len = p2 - p; if (len > sizeof(line) - 1) len = sizeof(line) - 1; memcpy(line, p, len); line[len] = '\0'; rtsp_parse_line(header, line); p = p1 + 1; } /* handle sequence number */ c->seq = header->seq; if (!strcmp(cmd, "DESCRIBE")) { rtsp_cmd_describe(c, url); } else if (!strcmp(cmd, "SETUP")) { rtsp_cmd_setup(c, url, header); } else if (!strcmp(cmd, "PLAY")) { rtsp_cmd_play(c, url, header); } else if (!strcmp(cmd, "PAUSE")) { rtsp_cmd_pause(c, url, header); } else if (!strcmp(cmd, "TEARDOWN")) { rtsp_cmd_teardown(c, url, header); } else { rtsp_reply_error(c, RTSP_STATUS_METHOD); } the_end: len = url_close_dyn_buf(c->pb, &c->pb_buffer); c->pb = NULL; /* safety */ if (len < 0) { /* XXX: cannot do more */ return -1; } c->buffer_ptr = c->pb_buffer; c->buffer_end = c->pb_buffer + len; c->state = RTSPSTATE_SEND_REPLY; return 0; } static int prepare_sdp_description(HTTPContext *c, FFStream *stream, UINT8 **pbuffer) { ByteIOContext pb1, *pb = &pb1; struct sockaddr_in my_addr; int len, i, payload_type; const char *ipstr, *title, *mediatype; AVStream *st; len = sizeof(my_addr); getsockname(c->fd, (struct sockaddr *)&my_addr, &len); ipstr = inet_ntoa(my_addr.sin_addr); if (url_open_dyn_buf(pb) < 0) return -1; /* general media info */ url_fprintf(pb, "v=0\n"); url_fprintf(pb, "o=- 0 0 IN IP4 %s\n", ipstr); title = stream->title; if (title[0] == '\0') title = "No Title"; url_fprintf(pb, "s=%s\n", title); if (stream->comment[0] != '\0') url_fprintf(pb, "i=%s\n", stream->comment); /* for each stream, we output the necessary info */ for(i = 0; i < stream->nb_streams; i++) { st = stream->streams[i]; switch(st->codec.codec_type) { case CODEC_TYPE_AUDIO: mediatype = "audio"; break; case CODEC_TYPE_VIDEO: mediatype = "video"; break; default: mediatype = "application"; break; } /* XXX: the port indication is not correct (but should be correct for broadcast) */ payload_type = rtp_get_payload_type(&st->codec); url_fprintf(pb, "m=%s %d RTP/AVP %d\n", mediatype, 0, payload_type); url_fprintf(pb, "a=control:streamid=%d\n", i); } return url_close_dyn_buf(pb, pbuffer); } static void rtsp_cmd_describe(HTTPContext *c, const char *url) { FFStream *stream; char path1[1024]; const char *path; UINT8 *content; int content_length; /* find which url is asked */ url_split(NULL, 0, NULL, 0, NULL, path1, sizeof(path1), url); path = path1; if (*path == '/') path++; for(stream = first_stream; stream != NULL; stream = stream->next) { if (!stream->is_feed && stream->fmt == &rtp_mux && !strcmp(path, stream->filename)) { goto found; } } /* no stream found */ rtsp_reply_error(c, RTSP_STATUS_SERVICE); /* XXX: right error ? */ return; found: /* prepare the media description in sdp format */ content_length = prepare_sdp_description(c, stream, &content); if (content_length < 0) { rtsp_reply_error(c, RTSP_STATUS_INTERNAL); return; } rtsp_reply_header(c, RTSP_STATUS_OK); url_fprintf(c->pb, "Content-Type: application/sdp\r\n"); url_fprintf(c->pb, "Content-Length: %d\r\n", content_length); url_fprintf(c->pb, "\r\n"); put_buffer(c->pb, content, content_length); } static HTTPContext *find_rtp_session(const char *session_id) { HTTPContext *c; if (session_id[0] == '\0') return NULL; for(c = first_http_ctx; c != NULL; c = c->next) { if (!strcmp(c->session_id, session_id)) return c; } return NULL; } RTSPTransportField *find_transport(RTSPHeader *h, enum RTSPProtocol protocol) { RTSPTransportField *th; int i; for(i=0;inb_transports;i++) { th = &h->transports[i]; if (th->protocol == protocol) return th; } return NULL; } static void rtsp_cmd_setup(HTTPContext *c, const char *url, RTSPHeader *h) { FFStream *stream; int stream_index, port; char buf[1024]; char path1[1024]; const char *path; HTTPContext *rtp_c; RTSPTransportField *th; struct sockaddr_in dest_addr; RTSPActionServerSetup setup; /* find which url is asked */ url_split(NULL, 0, NULL, 0, NULL, path1, sizeof(path1), url); path = path1; if (*path == '/') path++; /* now check each stream */ for(stream = first_stream; stream != NULL; stream = stream->next) { if (!stream->is_feed && stream->fmt == &rtp_mux) { /* accept aggregate filenames only if single stream */ if (!strcmp(path, stream->filename)) { if (stream->nb_streams != 1) { rtsp_reply_error(c, RTSP_STATUS_AGGREGATE); return; } stream_index = 0; goto found; } for(stream_index = 0; stream_index < stream->nb_streams; stream_index++) { snprintf(buf, sizeof(buf), "%s/streamid=%d", stream->filename, stream_index); if (!strcmp(path, buf)) goto found; } } } /* no stream found */ rtsp_reply_error(c, RTSP_STATUS_SERVICE); /* XXX: right error ? */ return; found: /* generate session id if needed */ if (h->session_id[0] == '\0') { snprintf(h->session_id, sizeof(h->session_id), "%08x%08x", (int)random(), (int)random()); } /* find rtp session, and create it if none found */ rtp_c = find_rtp_session(h->session_id); if (!rtp_c) { rtp_c = rtp_new_connection(c, stream, h->session_id); if (!rtp_c) { rtsp_reply_error(c, RTSP_STATUS_BANDWIDTH); return; } /* open input stream */ if (open_input_stream(rtp_c, "") < 0) { rtsp_reply_error(c, RTSP_STATUS_INTERNAL); return; } /* always prefer UDP */ th = find_transport(h, RTSP_PROTOCOL_RTP_UDP); if (!th) { th = find_transport(h, RTSP_PROTOCOL_RTP_TCP); if (!th) { rtsp_reply_error(c, RTSP_STATUS_TRANSPORT); return; } } rtp_c->rtp_protocol = th->protocol; } /* test if stream is OK (test needed because several SETUP needs to be done for a given file) */ if (rtp_c->stream != stream) { rtsp_reply_error(c, RTSP_STATUS_SERVICE); return; } /* test if stream is already set up */ if (rtp_c->rtp_ctx[stream_index]) { rtsp_reply_error(c, RTSP_STATUS_STATE); return; } /* check transport */ th = find_transport(h, rtp_c->rtp_protocol); if (!th || (th->protocol == RTSP_PROTOCOL_RTP_UDP && th->client_port_min <= 0)) { rtsp_reply_error(c, RTSP_STATUS_TRANSPORT); return; } /* setup default options */ setup.transport_option[0] = '\0'; dest_addr = rtp_c->from_addr; dest_addr.sin_port = htons(th->client_port_min); /* add transport option if needed */ if (ff_rtsp_callback) { setup.ipaddr = ntohl(dest_addr.sin_addr.s_addr); if (ff_rtsp_callback(RTSP_ACTION_SERVER_SETUP, rtp_c->session_id, (char *)&setup, sizeof(setup), stream->rtsp_option) < 0) { rtsp_reply_error(c, RTSP_STATUS_TRANSPORT); return; } dest_addr.sin_addr.s_addr = htonl(setup.ipaddr); } /* setup stream */ if (rtp_new_av_stream(rtp_c, stream_index, &dest_addr) < 0) { rtsp_reply_error(c, RTSP_STATUS_TRANSPORT); return; } /* now everything is OK, so we can send the connection parameters */ rtsp_reply_header(c, RTSP_STATUS_OK); /* session ID */ url_fprintf(c->pb, "Session: %s\r\n", rtp_c->session_id); switch(rtp_c->rtp_protocol) { case RTSP_PROTOCOL_RTP_UDP: port = rtp_get_local_port(rtp_c->rtp_handles[stream_index]); url_fprintf(c->pb, "Transport: RTP/AVP/UDP;unicast;" "client_port=%d-%d;server_port=%d-%d", th->client_port_min, th->client_port_min + 1, port, port + 1); break; case RTSP_PROTOCOL_RTP_TCP: url_fprintf(c->pb, "Transport: RTP/AVP/TCP;interleaved=%d-%d", stream_index * 2, stream_index * 2 + 1); break; default: break; } if (setup.transport_option[0] != '\0') { url_fprintf(c->pb, ";%s", setup.transport_option); } url_fprintf(c->pb, "\r\n"); url_fprintf(c->pb, "\r\n"); } /* find an rtp connection by using the session ID. Check consistency with filename */ static HTTPContext *find_rtp_session_with_url(const char *url, const char *session_id) { HTTPContext *rtp_c; char path1[1024]; const char *path; rtp_c = find_rtp_session(session_id); if (!rtp_c) return NULL; /* find which url is asked */ url_split(NULL, 0, NULL, 0, NULL, path1, sizeof(path1), url); path = path1; if (*path == '/') path++; if (strcmp(path, rtp_c->stream->filename) != 0) return NULL; return rtp_c; } static void rtsp_cmd_play(HTTPContext *c, const char *url, RTSPHeader *h) { HTTPContext *rtp_c; rtp_c = find_rtp_session_with_url(url, h->session_id); if (!rtp_c) { rtsp_reply_error(c, RTSP_STATUS_SESSION); return; } if (rtp_c->state != HTTPSTATE_SEND_DATA && rtp_c->state != HTTPSTATE_WAIT_FEED && rtp_c->state != HTTPSTATE_READY) { rtsp_reply_error(c, RTSP_STATUS_STATE); return; } rtp_c->state = HTTPSTATE_SEND_DATA; /* now everything is OK, so we can send the connection parameters */ rtsp_reply_header(c, RTSP_STATUS_OK); /* session ID */ url_fprintf(c->pb, "Session: %s\r\n", rtp_c->session_id); url_fprintf(c->pb, "\r\n"); } static void rtsp_cmd_pause(HTTPContext *c, const char *url, RTSPHeader *h) { HTTPContext *rtp_c; rtp_c = find_rtp_session_with_url(url, h->session_id); if (!rtp_c) { rtsp_reply_error(c, RTSP_STATUS_SESSION); return; } if (rtp_c->state != HTTPSTATE_SEND_DATA && rtp_c->state != HTTPSTATE_WAIT_FEED) { rtsp_reply_error(c, RTSP_STATUS_STATE); return; } rtp_c->state = HTTPSTATE_READY; /* now everything is OK, so we can send the connection parameters */ rtsp_reply_header(c, RTSP_STATUS_OK); /* session ID */ url_fprintf(c->pb, "Session: %s\r\n", rtp_c->session_id); url_fprintf(c->pb, "\r\n"); } static void rtsp_cmd_teardown(HTTPContext *c, const char *url, RTSPHeader *h) { HTTPContext *rtp_c; rtp_c = find_rtp_session_with_url(url, h->session_id); if (!rtp_c) { rtsp_reply_error(c, RTSP_STATUS_SESSION); return; } /* abort the session */ close_connection(rtp_c); if (ff_rtsp_callback) { ff_rtsp_callback(RTSP_ACTION_SERVER_TEARDOWN, rtp_c->session_id, NULL, 0, rtp_c->stream->rtsp_option); } /* now everything is OK, so we can send the connection parameters */ rtsp_reply_header(c, RTSP_STATUS_OK); /* session ID */ url_fprintf(c->pb, "Session: %s\r\n", rtp_c->session_id); url_fprintf(c->pb, "\r\n"); } /********************************************************************/ /* RTP handling */ static HTTPContext *rtp_new_connection(HTTPContext *rtsp_c, FFStream *stream, const char *session_id) { HTTPContext *c = NULL; /* XXX: should output a warning page when coming close to the connection limit */ if (nb_connections >= nb_max_connections) goto fail; /* add a new connection */ c = av_mallocz(sizeof(HTTPContext)); if (!c) goto fail; c->fd = -1; c->poll_entry = NULL; c->from_addr = rtsp_c->from_addr; c->buffer_size = IOBUFFER_INIT_SIZE; c->buffer = av_malloc(c->buffer_size); if (!c->buffer) goto fail; nb_connections++; c->stream = stream; pstrcpy(c->session_id, sizeof(c->session_id), session_id); c->state = HTTPSTATE_READY; c->is_packetized = 1; /* protocol is shown in statistics */ pstrcpy(c->protocol, sizeof(c->protocol), "RTP"); c->next = first_http_ctx; first_http_ctx = c; return c; fail: if (c) { av_free(c->buffer); av_free(c); } return NULL; } /* add a new RTP stream in an RTP connection (used in RTSP SETUP command). if dest_addr is NULL, then TCP tunneling in RTSP is used. */ static int rtp_new_av_stream(HTTPContext *c, int stream_index, struct sockaddr_in *dest_addr) { AVFormatContext *ctx; AVStream *st; char *ipaddr; URLContext *h; UINT8 *dummy_buf; /* now we can open the relevant output stream */ ctx = av_mallocz(sizeof(AVFormatContext)); if (!ctx) return -1; ctx->oformat = &rtp_mux; st = av_mallocz(sizeof(AVStream)); if (!st) goto fail; ctx->nb_streams = 1; ctx->streams[0] = st; if (!c->stream->feed || c->stream->feed == c->stream) { memcpy(st, c->stream->streams[stream_index], sizeof(AVStream)); } else { memcpy(st, c->stream->feed->streams[c->stream->feed_streams[stream_index]], sizeof(AVStream)); } if (dest_addr) { /* build destination RTP address */ ipaddr = inet_ntoa(dest_addr->sin_addr); snprintf(ctx->filename, sizeof(ctx->filename), "rtp://%s:%d", ipaddr, ntohs(dest_addr->sin_port)); printf("open %s\n", ctx->filename); if (url_open(&h, ctx->filename, URL_WRONLY) < 0) goto fail; c->rtp_handles[stream_index] = h; } else { goto fail; } /* normally, no packets should be output here, but the packet size may be checked */ if (url_open_dyn_packet_buf(&ctx->pb, url_get_max_packet_size(h)) < 0) { /* XXX: close stream */ goto fail; } if (av_write_header(ctx) < 0) { fail: if (h) url_close(h); av_free(ctx); return -1; } url_close_dyn_buf(&ctx->pb, &dummy_buf); av_free(dummy_buf); c->rtp_ctx[stream_index] = ctx; return 0; } /********************************************************************/ /* ffserver initialization */ AVStream *add_av_stream1(FFStream *stream, AVCodecContext *codec) { AVStream *fst; fst = av_mallocz(sizeof(AVStream)); if (!fst) return NULL; fst->priv_data = av_mallocz(sizeof(FeedData)); memcpy(&fst->codec, codec, sizeof(AVCodecContext)); stream->streams[stream->nb_streams++] = fst; return fst; } /* return the stream number in the feed */ int add_av_stream(FFStream *feed, AVStream *st) { AVStream *fst; AVCodecContext *av, *av1; int i; av = &st->codec; for(i=0;inb_streams;i++) { st = feed->streams[i]; av1 = &st->codec; if (av1->codec_id == av->codec_id && av1->codec_type == av->codec_type && av1->bit_rate == av->bit_rate) { switch(av->codec_type) { case CODEC_TYPE_AUDIO: if (av1->channels == av->channels && av1->sample_rate == av->sample_rate) goto found; break; case CODEC_TYPE_VIDEO: if (av1->width == av->width && av1->height == av->height && av1->frame_rate == av->frame_rate && av1->gop_size == av->gop_size) goto found; break; default: av_abort(); } } } fst = add_av_stream1(feed, av); if (!fst) return -1; return feed->nb_streams - 1; found: return i; } void remove_stream(FFStream *stream) { FFStream **ps; ps = &first_stream; while (*ps != NULL) { if (*ps == stream) { *ps = (*ps)->next; } else { ps = &(*ps)->next; } } } /* compute the needed AVStream for each file */ void build_file_streams(void) { FFStream *stream, *stream_next; AVFormatContext *infile; int i; /* gather all streams */ for(stream = first_stream; stream != NULL; stream = stream_next) { stream_next = stream->next; if (stream->stream_type == STREAM_TYPE_LIVE && !stream->feed) { /* the stream comes from a file */ /* try to open the file */ /* open stream */ if (av_open_input_file(&infile, stream->feed_filename, NULL, 0, NULL) < 0) { http_log("%s not found", stream->feed_filename); /* remove stream (no need to spend more time on it) */ fail: remove_stream(stream); } else { /* find all the AVStreams inside and reference them in 'stream' */ if (av_find_stream_info(infile) < 0) { http_log("Could not find codec parameters from '%s'", stream->feed_filename); av_close_input_file(infile); goto fail; } for(i=0;inb_streams;i++) { add_av_stream1(stream, &infile->streams[i]->codec); } av_close_input_file(infile); } } } } /* compute the needed AVStream for each feed */ void build_feed_streams(void) { FFStream *stream, *feed; int i; /* gather all streams */ for(stream = first_stream; stream != NULL; stream = stream->next) { feed = stream->feed; if (feed) { if (!stream->is_feed) { /* we handle a stream coming from a feed */ for(i=0;inb_streams;i++) { stream->feed_streams[i] = add_av_stream(feed, stream->streams[i]); } } } } /* gather all streams */ for(stream = first_stream; stream != NULL; stream = stream->next) { feed = stream->feed; if (feed) { if (stream->is_feed) { for(i=0;inb_streams;i++) { stream->feed_streams[i] = i; } } } } /* create feed files if needed */ for(feed = first_feed; feed != NULL; feed = feed->next_feed) { int fd; if (url_exist(feed->feed_filename)) { /* See if it matches */ AVFormatContext *s; int matches = 0; if (av_open_input_file(&s, feed->feed_filename, NULL, FFM_PACKET_SIZE, NULL) >= 0) { /* Now see if it matches */ if (s->nb_streams == feed->nb_streams) { matches = 1; for(i=0;inb_streams;i++) { AVStream *sf, *ss; sf = feed->streams[i]; ss = s->streams[i]; if (sf->index != ss->index || sf->id != ss->id) { printf("Index & Id do not match for stream %d\n", i); matches = 0; } else { AVCodecContext *ccf, *ccs; ccf = &sf->codec; ccs = &ss->codec; #define CHECK_CODEC(x) (ccf->x != ccs->x) if (CHECK_CODEC(codec) || CHECK_CODEC(codec_type)) { printf("Codecs do not match for stream %d\n", i); matches = 0; } else if (CHECK_CODEC(bit_rate) || CHECK_CODEC(flags)) { printf("Codec bitrates do not match for stream %d\n", i); matches = 0; } else if (ccf->codec_type == CODEC_TYPE_VIDEO) { if (CHECK_CODEC(frame_rate) || CHECK_CODEC(width) || CHECK_CODEC(height)) { printf("Codec width, height and framerate do not match for stream %d\n", i); matches = 0; } } else if (ccf->codec_type == CODEC_TYPE_AUDIO) { if (CHECK_CODEC(sample_rate) || CHECK_CODEC(channels) || CHECK_CODEC(frame_size)) { printf("Codec sample_rate, channels, frame_size do not match for stream %d\n", i); matches = 0; } } else { printf("Unknown codec type\n"); matches = 0; } } if (!matches) { break; } } } else { printf("Deleting feed file '%s' as stream counts differ (%d != %d)\n", feed->feed_filename, s->nb_streams, feed->nb_streams); } av_close_input_file(s); } else { printf("Deleting feed file '%s' as it appears to be corrupt\n", feed->feed_filename); } if (!matches) unlink(feed->feed_filename); } if (!url_exist(feed->feed_filename)) { AVFormatContext s1, *s = &s1; /* only write the header of the ffm file */ if (url_fopen(&s->pb, feed->feed_filename, URL_WRONLY) < 0) { fprintf(stderr, "Could not open output feed file '%s'\n", feed->feed_filename); exit(1); } s->oformat = feed->fmt; s->nb_streams = feed->nb_streams; for(i=0;inb_streams;i++) { AVStream *st; st = feed->streams[i]; s->streams[i] = st; } av_write_header(s); /* XXX: need better api */ av_freep(&s->priv_data); url_fclose(&s->pb); } /* get feed size and write index */ fd = open(feed->feed_filename, O_RDONLY); if (fd < 0) { fprintf(stderr, "Could not open output feed file '%s'\n", feed->feed_filename); exit(1); } feed->feed_write_index = ffm_read_write_index(fd); feed->feed_size = lseek(fd, 0, SEEK_END); /* ensure that we do not wrap before the end of file */ if (feed->feed_max_size < feed->feed_size) feed->feed_max_size = feed->feed_size; close(fd); } } static void get_arg(char *buf, int buf_size, const char **pp) { const char *p; char *q; int quote; p = *pp; while (isspace(*p)) p++; q = buf; quote = 0; if (*p == '\"' || *p == '\'') quote = *p++; for(;;) { if (quote) { if (*p == quote) break; } else { if (isspace(*p)) break; } if (*p == '\0') break; if ((q - buf) < buf_size - 1) *q++ = *p; p++; } *q = '\0'; if (quote && *p == quote) p++; *pp = p; } /* add a codec and set the default parameters */ void add_codec(FFStream *stream, AVCodecContext *av) { AVStream *st; /* compute default parameters */ switch(av->codec_type) { case CODEC_TYPE_AUDIO: if (av->bit_rate == 0) av->bit_rate = 64000; if (av->sample_rate == 0) av->sample_rate = 22050; if (av->channels == 0) av->channels = 1; break; case CODEC_TYPE_VIDEO: if (av->bit_rate == 0) av->bit_rate = 64000; if (av->frame_rate == 0) av->frame_rate = 5 * FRAME_RATE_BASE; if (av->width == 0 || av->height == 0) { av->width = 160; av->height = 128; } /* Bitrate tolerance is less for streaming */ if (av->bit_rate_tolerance == 0) av->bit_rate_tolerance = av->bit_rate / 4; if (av->qmin == 0) av->qmin = 3; if (av->qmax == 0) av->qmax = 31; if (av->max_qdiff == 0) av->max_qdiff = 3; av->qcompress = 0.5; av->qblur = 0.5; if (!av->rc_eq) av->rc_eq = "tex^qComp"; if (!av->i_quant_factor) av->i_quant_factor = -0.8; if (!av->b_quant_factor) av->b_quant_factor = 1.25; if (!av->b_quant_offset) av->b_quant_offset = 1.25; if (!av->rc_min_rate) av->rc_min_rate = av->bit_rate / 2; if (!av->rc_max_rate) av->rc_max_rate = av->bit_rate * 2; break; default: av_abort(); } st = av_mallocz(sizeof(AVStream)); if (!st) return; stream->streams[stream->nb_streams++] = st; memcpy(&st->codec, av, sizeof(AVCodecContext)); } int opt_audio_codec(const char *arg) { AVCodec *p; p = first_avcodec; while (p) { if (!strcmp(p->name, arg) && p->type == CODEC_TYPE_AUDIO) break; p = p->next; } if (p == NULL) { return CODEC_ID_NONE; } return p->id; } int opt_video_codec(const char *arg) { AVCodec *p; p = first_avcodec; while (p) { if (!strcmp(p->name, arg) && p->type == CODEC_TYPE_VIDEO) break; p = p->next; } if (p == NULL) { return CODEC_ID_NONE; } return p->id; } /* simplistic plugin support */ void load_module(const char *filename) { void *dll; void (*init_func)(void); dll = dlopen(filename, RTLD_NOW); if (!dll) { fprintf(stderr, "Could not load module '%s' - %s\n", filename, dlerror()); return; } init_func = dlsym(dll, "ffserver_module_init"); if (!init_func) { fprintf(stderr, "%s: init function 'ffserver_module_init()' not found\n", filename); dlclose(dll); } init_func(); } int parse_ffconfig(const char *filename) { FILE *f; char line[1024]; char cmd[64]; char arg[1024]; const char *p; int val, errors, line_num; FFStream **last_stream, *stream, *redirect; FFStream **last_feed, *feed; AVCodecContext audio_enc, video_enc; int audio_id, video_id; f = fopen(filename, "r"); if (!f) { perror(filename); return -1; } errors = 0; line_num = 0; first_stream = NULL; last_stream = &first_stream; first_feed = NULL; last_feed = &first_feed; stream = NULL; feed = NULL; redirect = NULL; audio_id = CODEC_ID_NONE; video_id = CODEC_ID_NONE; for(;;) { if (fgets(line, sizeof(line), f) == NULL) break; line_num++; p = line; while (isspace(*p)) p++; if (*p == '\0' || *p == '#') continue; get_arg(cmd, sizeof(cmd), &p); if (!strcasecmp(cmd, "Port")) { get_arg(arg, sizeof(arg), &p); my_http_addr.sin_port = htons (atoi(arg)); } else if (!strcasecmp(cmd, "BindAddress")) { get_arg(arg, sizeof(arg), &p); if (!inet_aton(arg, &my_http_addr.sin_addr)) { fprintf(stderr, "%s:%d: Invalid IP address: %s\n", filename, line_num, arg); errors++; } } else if (!strcasecmp(cmd, "NoDaemon")) { ffserver_daemon = 0; } else if (!strcasecmp(cmd, "RTSPPort")) { get_arg(arg, sizeof(arg), &p); my_rtsp_addr.sin_port = htons (atoi(arg)); } else if (!strcasecmp(cmd, "RTSPBindAddress")) { get_arg(arg, sizeof(arg), &p); if (!inet_aton(arg, &my_rtsp_addr.sin_addr)) { fprintf(stderr, "%s:%d: Invalid IP address: %s\n", filename, line_num, arg); errors++; } } else if (!strcasecmp(cmd, "MaxClients")) { get_arg(arg, sizeof(arg), &p); val = atoi(arg); if (val < 1 || val > HTTP_MAX_CONNECTIONS) { fprintf(stderr, "%s:%d: Invalid MaxClients: %s\n", filename, line_num, arg); errors++; } else { nb_max_connections = val; } } else if (!strcasecmp(cmd, "MaxBandwidth")) { get_arg(arg, sizeof(arg), &p); val = atoi(arg); if (val < 10 || val > 100000) { fprintf(stderr, "%s:%d: Invalid MaxBandwidth: %s\n", filename, line_num, arg); errors++; } else { nb_max_bandwidth = val; } } else if (!strcasecmp(cmd, "CustomLog")) { get_arg(logfilename, sizeof(logfilename), &p); } else if (!strcasecmp(cmd, "next; /* add in feed list */ *last_feed = feed; last_feed = &feed->next_feed; get_arg(feed->filename, sizeof(feed->filename), &p); q = strrchr(feed->filename, '>'); if (*q) *q = '\0'; feed->fmt = guess_format("ffm", NULL, NULL); /* defaut feed file */ snprintf(feed->feed_filename, sizeof(feed->feed_filename), "/tmp/%s.ffm", feed->filename); feed->feed_max_size = 5 * 1024 * 1024; feed->is_feed = 1; feed->feed = feed; /* self feeding :-) */ } } else if (!strcasecmp(cmd, "Launch")) { if (feed) { int i; feed->child_argv = (char **) av_mallocz(64 * sizeof(char *)); feed->child_argv[0] = av_malloc(7); strcpy(feed->child_argv[0], "ffmpeg"); for (i = 1; i < 62; i++) { char argbuf[256]; get_arg(argbuf, sizeof(argbuf), &p); if (!argbuf[0]) break; feed->child_argv[i] = av_malloc(strlen(argbuf + 1)); strcpy(feed->child_argv[i], argbuf); } feed->child_argv[i] = av_malloc(30 + strlen(feed->filename)); snprintf(feed->child_argv[i], 256, "http://127.0.0.1:%d/%s", ntohs(my_http_addr.sin_port), feed->filename); } } else if (!strcasecmp(cmd, "File")) { if (feed) { get_arg(feed->feed_filename, sizeof(feed->feed_filename), &p); } else if (stream) { get_arg(stream->feed_filename, sizeof(stream->feed_filename), &p); } } else if (!strcasecmp(cmd, "FileMaxSize")) { if (feed) { const char *p1; double fsize; get_arg(arg, sizeof(arg), &p); p1 = arg; fsize = strtod(p1, (char **)&p1); switch(toupper(*p1)) { case 'K': fsize *= 1024; break; case 'M': fsize *= 1024 * 1024; break; case 'G': fsize *= 1024 * 1024 * 1024; break; } feed->feed_max_size = (INT64)fsize; } } else if (!strcasecmp(cmd, "")) { if (!feed) { fprintf(stderr, "%s:%d: No corresponding for \n", filename, line_num); errors++; #if 0 } else { /* Make sure that we start out clean */ if (unlink(feed->feed_filename) < 0 && errno != ENOENT) { fprintf(stderr, "%s:%d: Unable to clean old feed file '%s': %s\n", filename, line_num, feed->feed_filename, strerror(errno)); errors++; } #endif } feed = NULL; } else if (!strcasecmp(cmd, "next; get_arg(stream->filename, sizeof(stream->filename), &p); q = strrchr(stream->filename, '>'); if (*q) *q = '\0'; stream->fmt = guess_stream_format(NULL, stream->filename, NULL); memset(&audio_enc, 0, sizeof(AVCodecContext)); memset(&video_enc, 0, sizeof(AVCodecContext)); audio_id = CODEC_ID_NONE; video_id = CODEC_ID_NONE; if (stream->fmt) { audio_id = stream->fmt->audio_codec; video_id = stream->fmt->video_codec; } } } else if (!strcasecmp(cmd, "Feed")) { get_arg(arg, sizeof(arg), &p); if (stream) { FFStream *sfeed; sfeed = first_feed; while (sfeed != NULL) { if (!strcmp(sfeed->filename, arg)) break; sfeed = sfeed->next_feed; } if (!sfeed) { fprintf(stderr, "%s:%d: feed '%s' not defined\n", filename, line_num, arg); } else { stream->feed = sfeed; } } } else if (!strcasecmp(cmd, "Format")) { get_arg(arg, sizeof(arg), &p); if (!strcmp(arg, "status")) { stream->stream_type = STREAM_TYPE_STATUS; stream->fmt = NULL; } else { stream->stream_type = STREAM_TYPE_LIVE; /* jpeg cannot be used here, so use single frame jpeg */ if (!strcmp(arg, "jpeg")) strcpy(arg, "singlejpeg"); stream->fmt = guess_stream_format(arg, NULL, NULL); if (!stream->fmt) { fprintf(stderr, "%s:%d: Unknown Format: %s\n", filename, line_num, arg); errors++; } } if (stream->fmt) { audio_id = stream->fmt->audio_codec; video_id = stream->fmt->video_codec; } } else if (!strcasecmp(cmd, "FaviconURL")) { if (stream && stream->stream_type == STREAM_TYPE_STATUS) { get_arg(stream->feed_filename, sizeof(stream->feed_filename), &p); } else { fprintf(stderr, "%s:%d: FaviconURL only permitted for status streams\n", filename, line_num); errors++; } } else if (!strcasecmp(cmd, "Author")) { if (stream) { get_arg(stream->author, sizeof(stream->author), &p); } } else if (!strcasecmp(cmd, "Comment")) { if (stream) { get_arg(stream->comment, sizeof(stream->comment), &p); } } else if (!strcasecmp(cmd, "Copyright")) { if (stream) { get_arg(stream->copyright, sizeof(stream->copyright), &p); } } else if (!strcasecmp(cmd, "Title")) { if (stream) { get_arg(stream->title, sizeof(stream->title), &p); } } else if (!strcasecmp(cmd, "Preroll")) { get_arg(arg, sizeof(arg), &p); if (stream) { stream->prebuffer = atof(arg) * 1000; } } else if (!strcasecmp(cmd, "StartSendOnKey")) { if (stream) { stream->send_on_key = 1; } } else if (!strcasecmp(cmd, "AudioCodec")) { get_arg(arg, sizeof(arg), &p); audio_id = opt_audio_codec(arg); if (audio_id == CODEC_ID_NONE) { fprintf(stderr, "%s:%d: Unknown AudioCodec: %s\n", filename, line_num, arg); errors++; } } else if (!strcasecmp(cmd, "VideoCodec")) { get_arg(arg, sizeof(arg), &p); video_id = opt_video_codec(arg); if (video_id == CODEC_ID_NONE) { fprintf(stderr, "%s:%d: Unknown VideoCodec: %s\n", filename, line_num, arg); errors++; } } else if (!strcasecmp(cmd, "MaxTime")) { get_arg(arg, sizeof(arg), &p); if (stream) { stream->max_time = atof(arg) * 1000; } } else if (!strcasecmp(cmd, "AudioBitRate")) { get_arg(arg, sizeof(arg), &p); if (stream) { audio_enc.bit_rate = atoi(arg) * 1000; } } else if (!strcasecmp(cmd, "AudioChannels")) { get_arg(arg, sizeof(arg), &p); if (stream) { audio_enc.channels = atoi(arg); } } else if (!strcasecmp(cmd, "AudioSampleRate")) { get_arg(arg, sizeof(arg), &p); if (stream) { audio_enc.sample_rate = atoi(arg); } } else if (!strcasecmp(cmd, "AudioQuality")) { get_arg(arg, sizeof(arg), &p); if (stream) { audio_enc.quality = atof(arg) * 1000; } } else if (!strcasecmp(cmd, "VideoBitRateRange")) { if (stream) { int minrate, maxrate; get_arg(arg, sizeof(arg), &p); if (sscanf(arg, "%d-%d", &minrate, &maxrate) == 2) { video_enc.rc_min_rate = minrate * 1000; video_enc.rc_max_rate = maxrate * 1000; } else { fprintf(stderr, "%s:%d: Incorrect format for VideoBitRateRange -- should be -: %s\n", filename, line_num, arg); errors++; } } } else if (!strcasecmp(cmd, "VideoBitRateTolerance")) { if (stream) { get_arg(arg, sizeof(arg), &p); video_enc.bit_rate_tolerance = atoi(arg) * 1000; } } else if (!strcasecmp(cmd, "VideoBitRate")) { get_arg(arg, sizeof(arg), &p); if (stream) { video_enc.bit_rate = atoi(arg) * 1000; } } else if (!strcasecmp(cmd, "VideoSize")) { get_arg(arg, sizeof(arg), &p); if (stream) { parse_image_size(&video_enc.width, &video_enc.height, arg); if ((video_enc.width % 16) != 0 || (video_enc.height % 16) != 0) { fprintf(stderr, "%s:%d: Image size must be a multiple of 16\n", filename, line_num); errors++; } } } else if (!strcasecmp(cmd, "VideoFrameRate")) { get_arg(arg, sizeof(arg), &p); if (stream) { video_enc.frame_rate = (int)(strtod(arg, NULL) * FRAME_RATE_BASE); } } else if (!strcasecmp(cmd, "VideoGopSize")) { get_arg(arg, sizeof(arg), &p); if (stream) { video_enc.gop_size = atoi(arg); } } else if (!strcasecmp(cmd, "VideoIntraOnly")) { if (stream) { video_enc.gop_size = 1; } } else if (!strcasecmp(cmd, "VideoHighQuality")) { if (stream) { video_enc.flags |= CODEC_FLAG_HQ; } } else if (!strcasecmp(cmd, "VideoQDiff")) { get_arg(arg, sizeof(arg), &p); if (stream) { video_enc.max_qdiff = atoi(arg); if (video_enc.max_qdiff < 1 || video_enc.max_qdiff > 31) { fprintf(stderr, "%s:%d: VideoQDiff out of range\n", filename, line_num); errors++; } } } else if (!strcasecmp(cmd, "VideoQMax")) { get_arg(arg, sizeof(arg), &p); if (stream) { video_enc.qmax = atoi(arg); if (video_enc.qmax < 1 || video_enc.qmax > 31) { fprintf(stderr, "%s:%d: VideoQMax out of range\n", filename, line_num); errors++; } } } else if (!strcasecmp(cmd, "VideoQMin")) { get_arg(arg, sizeof(arg), &p); if (stream) { video_enc.qmin = atoi(arg); if (video_enc.qmin < 1 || video_enc.qmin > 31) { fprintf(stderr, "%s:%d: VideoQMin out of range\n", filename, line_num); errors++; } } } else if (!strcasecmp(cmd, "LumaElim")) { get_arg(arg, sizeof(arg), &p); if (stream) { video_enc.luma_elim_threshold = atoi(arg); } } else if (!strcasecmp(cmd, "ChromaElim")) { get_arg(arg, sizeof(arg), &p); if (stream) { video_enc.chroma_elim_threshold = atoi(arg); } } else if (!strcasecmp(cmd, "LumiMask")) { get_arg(arg, sizeof(arg), &p); if (stream) { video_enc.lumi_masking = atof(arg); } } else if (!strcasecmp(cmd, "DarkMask")) { get_arg(arg, sizeof(arg), &p); if (stream) { video_enc.dark_masking = atof(arg); } } else if (!strcasecmp(cmd, "NoVideo")) { video_id = CODEC_ID_NONE; } else if (!strcasecmp(cmd, "NoAudio")) { audio_id = CODEC_ID_NONE; } else if (!strcasecmp(cmd, "ACL")) { IPAddressACL acl; struct hostent *he; get_arg(arg, sizeof(arg), &p); if (strcasecmp(arg, "allow") == 0) { acl.action = IP_ALLOW; } else if (strcasecmp(arg, "deny") == 0) { acl.action = IP_DENY; } else { fprintf(stderr, "%s:%d: ACL action '%s' is not ALLOW or DENY\n", filename, line_num, arg); errors++; } get_arg(arg, sizeof(arg), &p); he = gethostbyname(arg); if (!he) { fprintf(stderr, "%s:%d: ACL refers to invalid host or ip address '%s'\n", filename, line_num, arg); errors++; } else { /* Only take the first */ acl.first = *(struct in_addr *) he->h_addr_list[0]; acl.last = acl.first; } get_arg(arg, sizeof(arg), &p); if (arg[0]) { he = gethostbyname(arg); if (!he) { fprintf(stderr, "%s:%d: ACL refers to invalid host or ip address '%s'\n", filename, line_num, arg); errors++; } else { /* Only take the first */ acl.last = *(struct in_addr *) he->h_addr_list[0]; } } if (!errors) { IPAddressACL *nacl = (IPAddressACL *) av_mallocz(sizeof(*nacl)); IPAddressACL **naclp = 0; *nacl = acl; nacl->next = 0; if (stream) { naclp = &stream->acl; } else if (feed) { naclp = &feed->acl; } else { fprintf(stderr, "%s:%d: ACL found not in or \n", filename, line_num); errors++; } if (naclp) { while (*naclp) naclp = &(*naclp)->next; *naclp = nacl; } } } else if (!strcasecmp(cmd, "RTSPOption")) { get_arg(arg, sizeof(arg), &p); if (stream) { av_freep(&stream->rtsp_option); /* XXX: av_strdup ? */ stream->rtsp_option = av_malloc(strlen(arg) + 1); if (stream->rtsp_option) { strcpy(stream->rtsp_option, arg); } } } else if (!strcasecmp(cmd, "")) { if (!stream) { fprintf(stderr, "%s:%d: No corresponding for \n", filename, line_num); errors++; } if (stream->feed && stream->fmt && strcmp(stream->fmt->name, "ffm") != 0) { if (audio_id != CODEC_ID_NONE) { audio_enc.codec_type = CODEC_TYPE_AUDIO; audio_enc.codec_id = audio_id; add_codec(stream, &audio_enc); } if (video_id != CODEC_ID_NONE) { video_enc.codec_type = CODEC_TYPE_VIDEO; video_enc.codec_id = video_id; add_codec(stream, &video_enc); } } stream = NULL; } else if (!strcasecmp(cmd, "next; get_arg(redirect->filename, sizeof(redirect->filename), &p); q = strrchr(redirect->filename, '>'); if (*q) *q = '\0'; redirect->stream_type = STREAM_TYPE_REDIRECT; } } else if (!strcasecmp(cmd, "URL")) { if (redirect) { get_arg(redirect->feed_filename, sizeof(redirect->feed_filename), &p); } } else if (!strcasecmp(cmd, "")) { if (!redirect) { fprintf(stderr, "%s:%d: No corresponding for \n", filename, line_num); errors++; } if (!redirect->feed_filename[0]) { fprintf(stderr, "%s:%d: No URL found for \n", filename, line_num); errors++; } redirect = NULL; } else if (!strcasecmp(cmd, "LoadModule")) { get_arg(arg, sizeof(arg), &p); load_module(arg); } else { fprintf(stderr, "%s:%d: Incorrect keyword: '%s'\n", filename, line_num, cmd); errors++; } } fclose(f); if (errors) return -1; else return 0; } #if 0 static void write_packet(FFCodec *ffenc, UINT8 *buf, int size) { PacketHeader hdr; AVCodecContext *enc = &ffenc->enc; UINT8 *wptr; mk_header(&hdr, enc, size); wptr = http_fifo.wptr; fifo_write(&http_fifo, (UINT8 *)&hdr, sizeof(hdr), &wptr); fifo_write(&http_fifo, buf, size, &wptr); /* atomic modification of wptr */ http_fifo.wptr = wptr; ffenc->data_count += size; ffenc->avg_frame_size = ffenc->avg_frame_size * AVG_COEF + size * (1.0 - AVG_COEF); } #endif void help(void) { printf("ffserver version " FFMPEG_VERSION ", Copyright (c) 2000, 2001, 2002 Fabrice Bellard\n" "usage: ffserver [-L] [-h] [-f configfile]\n" "Hyper fast multi format Audio/Video streaming server\n" "\n" "-L : print the LICENCE\n" "-h : this help\n" "-f configfile : use configfile instead of /etc/ffserver.conf\n" ); } void licence(void) { printf( "ffserver version " FFMPEG_VERSION "\n" "Copyright (c) 2000, 2001, 2002 Fabrice Bellard\n" "This library is free software; you can redistribute it and/or\n" "modify it under the terms of the GNU Lesser General Public\n" "License as published by the Free Software Foundation; either\n" "version 2 of the License, or (at your option) any later version.\n" "\n" "This library is distributed in the hope that it will be useful,\n" "but WITHOUT ANY WARRANTY; without even the implied warranty of\n" "MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU\n" "Lesser General Public License for more details.\n" "\n" "You should have received a copy of the GNU Lesser General Public\n" "License along with this library; if not, write to the Free Software\n" "Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA\n" ); } static void handle_child_exit(int sig) { pid_t pid; int status; while ((pid = waitpid(-1, &status, WNOHANG)) > 0) { FFStream *feed; for (feed = first_feed; feed; feed = feed->next) { if (feed->pid == pid) { int uptime = time(0) - feed->pid_start; feed->pid = 0; fprintf(stderr, "%s: Pid %d exited with status %d after %d seconds\n", feed->filename, pid, status, uptime); if (uptime < 30) { /* Turn off any more restarts */ feed->child_argv = 0; } } } } need_to_start_children = 1; } int main(int argc, char **argv) { const char *config_filename; int c; struct sigaction sigact; av_register_all(); config_filename = "/etc/ffserver.conf"; my_program_name = argv[0]; my_program_dir = getcwd(0, 0); ffserver_daemon = 1; for(;;) { c = getopt(argc, argv, "ndLh?f:"); if (c == -1) break; switch(c) { case 'L': licence(); exit(1); case '?': case 'h': help(); exit(1); case 'n': no_launch = 1; break; case 'd': ffserver_debug = 1; ffserver_daemon = 0; break; case 'f': config_filename = optarg; break; default: exit(2); } } putenv("http_proxy"); /* Kill the http_proxy */ srandom(gettime_ms() + (getpid() << 16)); /* address on which the server will handle HTTP connections */ my_http_addr.sin_family = AF_INET; my_http_addr.sin_port = htons (8080); my_http_addr.sin_addr.s_addr = htonl (INADDR_ANY); /* address on which the server will handle RTSP connections */ my_rtsp_addr.sin_family = AF_INET; my_rtsp_addr.sin_port = htons (5454); my_rtsp_addr.sin_addr.s_addr = htonl (INADDR_ANY); nb_max_connections = 5; nb_max_bandwidth = 1000; first_stream = NULL; logfilename[0] = '\0'; memset(&sigact, 0, sizeof(sigact)); sigact.sa_handler = handle_child_exit; sigact.sa_flags = SA_NOCLDSTOP | SA_RESTART; sigaction(SIGCHLD, &sigact, 0); if (parse_ffconfig(config_filename) < 0) { fprintf(stderr, "Incorrect config file - exiting.\n"); exit(1); } build_file_streams(); build_feed_streams(); /* put the process in background and detach it from its TTY */ if (ffserver_daemon) { int pid; pid = fork(); if (pid < 0) { perror("fork"); exit(1); } else if (pid > 0) { /* parent : exit */ exit(0); } else { /* child */ setsid(); chdir("/"); close(0); open("/dev/null", O_RDWR); if (strcmp(logfilename, "-") != 0) { close(1); dup(0); } close(2); dup(0); } } /* signal init */ signal(SIGPIPE, SIG_IGN); /* open log file if needed */ if (logfilename[0] != '\0') { if (!strcmp(logfilename, "-")) logfile = stdout; else logfile = fopen(logfilename, "w"); } if (http_server() < 0) { fprintf(stderr, "Could not start server\n"); exit(1); } return 0; }