/* * WebSocket lib with support for "wss://" encryption. * Copyright 2010 Joel Martin * Licensed under LGPL version 3 (see docs/LICENSE.LGPL-3) * * You can make a cert/key with openssl using: * openssl req -new -x509 -days 365 -nodes -out self.pem -keyout self.pem * as taken from http://docs.python.org/dev/library/ssl.html#certificates */ #include #include #include #include #include #include #include #include #include #include #include // daemonizing #include // daemonizing #include #include #include /* base64 encode/decode */ #include /* md5 hash */ #include /* sha1 hash */ #include "websocket.h" /* * Global state * * Warning: not thread safe */ int ssl_initialized = 0; int pipe_error = 0; settings_t settings; void traffic(char * token) { if ((settings.verbose) && (! settings.daemon)) { fprintf(stdout, "%s", token); fflush(stdout); } } void error(char *msg) { perror(msg); } void fatal(char *msg) { perror(msg); exit(1); } /* resolve host with also IP address parsing */ int resolve_host(struct in_addr *sin_addr, const char *hostname) { if (!inet_aton(hostname, sin_addr)) { struct addrinfo *ai, *cur; struct addrinfo hints; memset(&hints, 0, sizeof(hints)); hints.ai_family = AF_INET; if (getaddrinfo(hostname, NULL, &hints, &ai)) return -1; for (cur = ai; cur; cur = cur->ai_next) { if (cur->ai_family == AF_INET) { *sin_addr = ((struct sockaddr_in *)cur->ai_addr)->sin_addr; freeaddrinfo(ai); return 0; } } freeaddrinfo(ai); return -1; } return 0; } /* * SSL Wrapper Code */ ssize_t ws_recv(ws_ctx_t *ctx, void *buf, size_t len) { if (ctx->ssl) { //handler_msg("SSL recv\n"); return SSL_read(ctx->ssl, buf, len); } else { return recv(ctx->sockfd, buf, len, 0); } } ssize_t ws_send(ws_ctx_t *ctx, const void *buf, size_t len) { if (ctx->ssl) { //handler_msg("SSL send\n"); return SSL_write(ctx->ssl, buf, len); } else { return send(ctx->sockfd, buf, len, 0); } } ws_ctx_t *alloc_ws_ctx() { ws_ctx_t *ctx; if (! (ctx = malloc(sizeof(ws_ctx_t))) ) { fatal("malloc()"); } if (! (ctx->cin_buf = malloc(BUFSIZE)) ) { fatal("malloc of cin_buf"); } if (! (ctx->cout_buf = malloc(BUFSIZE)) ) { fatal("malloc of cout_buf"); } if (! (ctx->tin_buf = malloc(BUFSIZE)) ) { fatal("malloc of tin_buf"); } if (! (ctx->tout_buf = malloc(BUFSIZE)) ) { fatal("malloc of tout_buf"); } ctx->headers = malloc(sizeof(headers_t)); ctx->ssl = NULL; ctx->ssl_ctx = NULL; return ctx; } int free_ws_ctx(ws_ctx_t *ctx) { free(ctx->cin_buf); free(ctx->cout_buf); free(ctx->tin_buf); free(ctx->tout_buf); free(ctx); } ws_ctx_t *ws_socket(ws_ctx_t *ctx, int socket) { ctx->sockfd = socket; } ws_ctx_t *ws_socket_ssl(ws_ctx_t *ctx, int socket, char * certfile, char * keyfile) { int ret; char msg[1024]; char * use_keyfile; ws_socket(ctx, socket); if (keyfile && (keyfile[0] != '\0')) { // Separate key file use_keyfile = keyfile; } else { // Combined key and cert file use_keyfile = certfile; } // Initialize the library if (! ssl_initialized) { SSL_library_init(); OpenSSL_add_all_algorithms(); SSL_load_error_strings(); ssl_initialized = 1; } ctx->ssl_ctx = SSL_CTX_new(TLSv1_server_method()); if (ctx->ssl_ctx == NULL) { ERR_print_errors_fp(stderr); fatal("Failed to configure SSL context"); } if (SSL_CTX_use_PrivateKey_file(ctx->ssl_ctx, use_keyfile, SSL_FILETYPE_PEM) <= 0) { sprintf(msg, "Unable to load private key file %s\n", use_keyfile); fatal(msg); } if (SSL_CTX_use_certificate_file(ctx->ssl_ctx, certfile, SSL_FILETYPE_PEM) <= 0) { sprintf(msg, "Unable to load certificate file %s\n", certfile); fatal(msg); } // if (SSL_CTX_set_cipher_list(ctx->ssl_ctx, "DEFAULT") != 1) { // sprintf(msg, "Unable to set cipher\n"); // fatal(msg); // } // Associate socket and ssl object ctx->ssl = SSL_new(ctx->ssl_ctx); SSL_set_fd(ctx->ssl, socket); ret = SSL_accept(ctx->ssl); if (ret < 0) { ERR_print_errors_fp(stderr); return NULL; } return ctx; } int ws_socket_free(ws_ctx_t *ctx) { if (ctx->ssl) { SSL_free(ctx->ssl); ctx->ssl = NULL; } if (ctx->ssl_ctx) { SSL_CTX_free(ctx->ssl_ctx); ctx->ssl_ctx = NULL; } if (ctx->sockfd) { shutdown(ctx->sockfd, SHUT_RDWR); close(ctx->sockfd); ctx->sockfd = 0; } } /* ------------------------------------------------------- */ int encode_hixie(u_char const *src, size_t srclength, char *target, size_t targsize) { int sz = 0, len = 0; target[sz++] = '\x00'; len = b64_ntop(src, srclength, target+sz, targsize-sz); if (len < 0) { return len; } sz += len; target[sz++] = '\xff'; return sz; } int decode_hixie(char *src, size_t srclength, u_char *target, size_t targsize, unsigned int *opcode, unsigned int *left) { char *start, *end, cntstr[4]; int i, len, framecount = 0, retlen = 0; unsigned char chr; if ((src[0] != '\x00') || (src[srclength-1] != '\xff')) { handler_emsg("WebSocket framing error\n"); return -1; } *left = srclength; if (srclength == 2 && (src[0] == '\xff') && (src[1] == '\x00')) { // client sent orderly close frame *opcode = 0x8; // Close frame return 0; } *opcode = 0x1; // Text frame start = src+1; // Skip '\x00' start do { /* We may have more than one frame */ end = (char *)memchr(start, '\xff', srclength); *end = '\x00'; len = b64_pton(start, target+retlen, targsize-retlen); if (len < 0) { return len; } retlen += len; start = end + 2; // Skip '\xff' end and '\x00' start framecount++; } while (end < (src+srclength-1)); if (framecount > 1) { snprintf(cntstr, 3, "%d", framecount); traffic(cntstr); } *left = 0; return retlen; } int encode_hybi(u_char const *src, size_t srclength, char *target, size_t targsize, unsigned int opcode) { unsigned long long b64_sz, len_offset = 1, payload_offset = 2, len = 0; if ((int)srclength <= 0) { return 0; } b64_sz = ((srclength - 1) / 3) * 4 + 4; target[0] = (char)(opcode & 0x0F | 0x80); if (b64_sz <= 125) { target[1] = (char) b64_sz; payload_offset = 2; } else if ((b64_sz > 125) && (b64_sz < 65536)) { target[1] = (char) 126; *(u_short*)&(target[2]) = htons(b64_sz); payload_offset = 4; } else { handler_emsg("Sending frames larger than 65535 bytes not supported\n"); return -1; //target[1] = (char) 127; //*(u_long*)&(target[2]) = htonl(b64_sz); //payload_offset = 10; } len = b64_ntop(src, srclength, target+payload_offset, targsize-payload_offset); if (len < 0) { return len; } return len + payload_offset; } int decode_hybi(unsigned char *src, size_t srclength, u_char *target, size_t targsize, unsigned int *opcode, unsigned int *left) { unsigned char *frame, *mask, *payload, save_char, cntstr[4];; int masked = 0; int i = 0, len, framecount = 0; size_t remaining; unsigned int target_offset = 0, hdr_length = 0, payload_length = 0; *left = srclength; frame = src; //printf("Deocde new frame\n"); while (1) { // Need at least two bytes of the header // Find beginning of next frame. First time hdr_length, masked and // payload_length are zero frame += hdr_length + 4*masked + payload_length; //printf("frame[0..3]: 0x%x 0x%x 0x%x 0x%x (tot: %d)\n", // (unsigned char) frame[0], // (unsigned char) frame[1], // (unsigned char) frame[2], // (unsigned char) frame[3], srclength); if (frame > src + srclength) { //printf("Truncated frame from client, need %d more bytes\n", frame - (src + srclength) ); break; } remaining = (src + srclength) - frame; if (remaining < 2) { //printf("Truncated frame header from client\n"); break; } framecount ++; *opcode = frame[0] & 0x0f; masked = (frame[1] & 0x80) >> 7; if (*opcode == 0x8) { // client sent orderly close frame break; } payload_length = frame[1] & 0x7f; if (payload_length < 126) { hdr_length = 2; //frame += 2 * sizeof(char); } else if (payload_length == 126) { payload_length = (frame[2] << 8) + frame[3]; hdr_length = 4; } else { handler_emsg("Receiving frames larger than 65535 bytes not supported\n"); return -1; } if ((hdr_length + 4*masked + payload_length) > remaining) { continue; } //printf(" payload_length: %u, raw remaining: %u\n", payload_length, remaining); payload = frame + hdr_length + 4*masked; if (*opcode != 1 && *opcode != 2) { handler_msg("Ignoring non-data frame, opcode 0x%x\n", *opcode); continue; } if (payload_length == 0) { handler_msg("Ignoring empty frame\n"); continue; } if ((payload_length > 0) && (!masked)) { handler_emsg("Received unmasked payload from client\n"); return -1; } // Terminate with a null for base64 decode save_char = payload[payload_length]; payload[payload_length] = '\0'; // unmask the data mask = payload - 4; for (i = 0; i < payload_length; i++) { payload[i] ^= mask[i%4]; } // base64 decode the data len = b64_pton((const char*)payload, target+target_offset, targsize); // Restore the first character of the next frame payload[payload_length] = save_char; if (len < 0) { handler_emsg("Base64 decode error code %d", len); return len; } target_offset += len; //printf(" len %d, raw %s\n", len, frame); } if (framecount > 1) { snprintf(cntstr, 3, "%d", framecount); traffic(cntstr); } *left = remaining; return target_offset; } int parse_handshake(ws_ctx_t *ws_ctx, char *handshake) { char *start, *end; headers_t *headers = ws_ctx->headers; headers->key1[0] = '\0'; headers->key2[0] = '\0'; headers->key3[0] = '\0'; if ((strlen(handshake) < 92) || (bcmp(handshake, "GET ", 4) != 0)) { return 0; } start = handshake+4; end = strstr(start, " HTTP/1.1"); if (!end) { return 0; } strncpy(headers->path, start, end-start); headers->path[end-start] = '\0'; start = strstr(handshake, "\r\nHost: "); if (!start) { return 0; } start += 8; end = strstr(start, "\r\n"); strncpy(headers->host, start, end-start); headers->host[end-start] = '\0'; headers->origin[0] = '\0'; start = strstr(handshake, "\r\nOrigin: "); if (start) { start += 10; } else { start = strstr(handshake, "\r\nSec-WebSocket-Origin: "); if (!start) { return 0; } start += 24; } end = strstr(start, "\r\n"); strncpy(headers->origin, start, end-start); headers->origin[end-start] = '\0'; start = strstr(handshake, "\r\nSec-WebSocket-Version: "); if (start) { // HyBi/RFC 6455 start += 25; end = strstr(start, "\r\n"); strncpy(headers->version, start, end-start); headers->version[end-start] = '\0'; ws_ctx->hixie = 0; ws_ctx->hybi = strtol(headers->version, NULL, 10); start = strstr(handshake, "\r\nSec-WebSocket-Key: "); if (!start) { return 0; } start += 21; end = strstr(start, "\r\n"); strncpy(headers->key1, start, end-start); headers->key1[end-start] = '\0'; start = strstr(handshake, "\r\nConnection: "); if (!start) { return 0; } start += 14; end = strstr(start, "\r\n"); strncpy(headers->connection, start, end-start); headers->connection[end-start] = '\0'; start = strstr(handshake, "\r\nSec-WebSocket-Protocol: "); if (!start) { return 0; } start += 26; end = strstr(start, "\r\n"); strncpy(headers->protocols, start, end-start); headers->protocols[end-start] = '\0'; } else { // Hixie 75 or 76 ws_ctx->hybi = 0; start = strstr(handshake, "\r\n\r\n"); if (!start) { return 0; } start += 4; if (strlen(start) == 8) { ws_ctx->hixie = 76; strncpy(headers->key3, start, 8); headers->key3[8] = '\0'; start = strstr(handshake, "\r\nSec-WebSocket-Key1: "); if (!start) { return 0; } start += 22; end = strstr(start, "\r\n"); strncpy(headers->key1, start, end-start); headers->key1[end-start] = '\0'; start = strstr(handshake, "\r\nSec-WebSocket-Key2: "); if (!start) { return 0; } start += 22; end = strstr(start, "\r\n"); strncpy(headers->key2, start, end-start); headers->key2[end-start] = '\0'; } else { ws_ctx->hixie = 75; } } return 1; } int parse_hixie76_key(char * key) { unsigned long i, spaces = 0, num = 0; for (i=0; i < strlen(key); i++) { if (key[i] == ' ') { spaces += 1; } if ((key[i] >= 48) && (key[i] <= 57)) { num = num * 10 + (key[i] - 48); } } return num / spaces; } int gen_md5(headers_t *headers, char *target) { unsigned long key1 = parse_hixie76_key(headers->key1); unsigned long key2 = parse_hixie76_key(headers->key2); char *key3 = headers->key3; MD5_CTX c; char in[HIXIE_MD5_DIGEST_LENGTH] = { key1 >> 24, key1 >> 16, key1 >> 8, key1, key2 >> 24, key2 >> 16, key2 >> 8, key2, key3[0], key3[1], key3[2], key3[3], key3[4], key3[5], key3[6], key3[7] }; MD5_Init(&c); MD5_Update(&c, (void *)in, sizeof in); MD5_Final((void *)target, &c); target[HIXIE_MD5_DIGEST_LENGTH] = '\0'; return 1; } static void gen_sha1(headers_t *headers, char *target) { SHA_CTX c; unsigned char hash[SHA_DIGEST_LENGTH]; int r; SHA1_Init(&c); SHA1_Update(&c, headers->key1, strlen(headers->key1)); SHA1_Update(&c, HYBI_GUID, 36); SHA1_Final(hash, &c); r = b64_ntop(hash, sizeof hash, target, HYBI10_ACCEPTHDRLEN); //assert(r == HYBI10_ACCEPTHDRLEN - 1); } ws_ctx_t *do_handshake(int sock) { char handshake[4096], response[4096], sha1[29], trailer[17]; char *scheme, *pre; headers_t *headers; int len, ret, i, offset; ws_ctx_t * ws_ctx; // Peek, but don't read the data len = recv(sock, handshake, 1024, MSG_PEEK); handshake[len] = 0; if (len == 0) { handler_msg("ignoring empty handshake\n"); return NULL; } else if ((bcmp(handshake, "\x16", 1) == 0) || (bcmp(handshake, "\x80", 1) == 0)) { // SSL if (!settings.cert) { handler_msg("SSL connection but no cert specified\n"); return NULL; } else if (access(settings.cert, R_OK) != 0) { handler_msg("SSL connection but '%s' not found\n", settings.cert); return NULL; } ws_ctx = alloc_ws_ctx(); ws_socket_ssl(ws_ctx, sock, settings.cert, settings.key); if (! ws_ctx) { return NULL; } scheme = "wss"; handler_msg("using SSL socket\n"); } else if (settings.ssl_only) { handler_msg("non-SSL connection disallowed\n"); return NULL; } else { ws_ctx = alloc_ws_ctx(); ws_socket(ws_ctx, sock); if (! ws_ctx) { return NULL; } scheme = "ws"; handler_msg("using plain (not SSL) socket\n"); } offset = 0; for (i = 0; i < 10; i++) { /* (offset + 1): reserve one byte for the trailing '\0' */ if (0 > (len = ws_recv(ws_ctx, handshake + offset, sizeof(handshake) - (offset + 1)))) { handler_emsg("Read error during handshake: %m\n"); free_ws_ctx(ws_ctx); return NULL; } else if (0 == len) { handler_emsg("Client closed during handshake\n"); free_ws_ctx(ws_ctx); return NULL; } offset += len; handshake[offset] = 0; if (strstr(handshake, "\r\n\r\n")) { break; } else if (sizeof(handshake) <= (size_t)(offset + 1)) { handler_emsg("Oversized handshake\n"); free_ws_ctx(ws_ctx); return NULL; } else if (9 == i) { handler_emsg("Incomplete handshake\n"); free_ws_ctx(ws_ctx); return NULL; } usleep(10); } //handler_msg("handshake: %s\n", handshake); if (!parse_handshake(ws_ctx, handshake)) { handler_emsg("Invalid WS request\n"); free_ws_ctx(ws_ctx); return NULL; } headers = ws_ctx->headers; if (ws_ctx->hybi > 0) { handler_msg("using protocol HyBi/IETF 6455 %d\n", ws_ctx->hybi); gen_sha1(headers, sha1); sprintf(response, SERVER_HANDSHAKE_HYBI, sha1, "base64"); } else { if (ws_ctx->hixie == 76) { handler_msg("using protocol Hixie 76\n"); gen_md5(headers, trailer); pre = "Sec-"; } else { handler_msg("using protocol Hixie 75\n"); trailer[0] = '\0'; pre = ""; } sprintf(response, SERVER_HANDSHAKE_HIXIE, pre, headers->origin, pre, scheme, headers->host, headers->path, pre, "base64", trailer); } //handler_msg("response: %s\n", response); ws_send(ws_ctx, response, strlen(response)); return ws_ctx; } void signal_handler(sig) { switch (sig) { case SIGHUP: break; // ignore for now case SIGPIPE: pipe_error = 1; break; // handle inline case SIGTERM: exit(0); break; } } void daemonize(int keepfd) { int pid, i; umask(0); chdir("/"); setgid(getgid()); setuid(getuid()); /* Double fork to daemonize */ pid = fork(); if (pid<0) { fatal("fork error"); } if (pid>0) { exit(0); } // parent exits setsid(); // Obtain new process group pid = fork(); if (pid<0) { fatal("fork error"); } if (pid>0) { exit(0); } // parent exits /* Signal handling */ signal(SIGHUP, signal_handler); // catch HUP signal(SIGTERM, signal_handler); // catch kill /* Close open files */ for (i=getdtablesize(); i>=0; --i) { if (i != keepfd) { close(i); } else if (settings.verbose) { printf("keeping fd %d\n", keepfd); } } i=open("/dev/null", O_RDWR); // Redirect stdin dup(i); // Redirect stdout dup(i); // Redirect stderr } void start_server() { int lsock, csock, pid, clilen, sopt = 1, i; struct sockaddr_in serv_addr, cli_addr; ws_ctx_t *ws_ctx; /* Initialize buffers */ lsock = socket(AF_INET, SOCK_STREAM, 0); if (lsock < 0) { error("ERROR creating listener socket"); } bzero((char *) &serv_addr, sizeof(serv_addr)); serv_addr.sin_family = AF_INET; serv_addr.sin_port = htons(settings.listen_port); /* Resolve listen address */ if (settings.listen_host && (settings.listen_host[0] != '\0')) { if (resolve_host(&serv_addr.sin_addr, settings.listen_host) < -1) { fatal("Could not resolve listen address"); } } else { serv_addr.sin_addr.s_addr = INADDR_ANY; } setsockopt(lsock, SOL_SOCKET, SO_REUSEADDR, (char *)&sopt, sizeof(sopt)); if (bind(lsock, (struct sockaddr *) &serv_addr, sizeof(serv_addr)) < 0) { fatal("ERROR on binding listener socket"); } listen(lsock,100); signal(SIGPIPE, signal_handler); // catch pipe if (settings.daemon) { daemonize(lsock); } // Reep zombies signal(SIGCHLD, SIG_IGN); printf("Waiting for connections on %s:%d\n", settings.listen_host, settings.listen_port); while (1) { clilen = sizeof(cli_addr); pipe_error = 0; pid = 0; csock = accept(lsock, (struct sockaddr *) &cli_addr, &clilen); if (csock < 0) { error("ERROR on accept"); continue; } handler_msg("got client connection from %s\n", inet_ntoa(cli_addr.sin_addr)); if (!settings.run_once) { handler_msg("forking handler process\n"); pid = fork(); } if (pid == 0) { // handler process ws_ctx = do_handshake(csock); if (settings.run_once) { if (ws_ctx == NULL) { // Not a real WebSocket connection continue; } else { // Successful connection, stop listening for new // connections close(lsock); } } if (ws_ctx == NULL) { handler_msg("No connection after handshake\n"); break; // Child process exits } settings.handler(ws_ctx); if (pipe_error) { handler_emsg("Closing due to SIGPIPE\n"); } break; // Child process exits } else { // parent process settings.handler_id += 1; } } if (pid == 0) { if (ws_ctx) { ws_socket_free(ws_ctx); free_ws_ctx(ws_ctx); } else { shutdown(csock, SHUT_RDWR); close(csock); } handler_msg("handler exit\n"); } else { handler_msg("websockify exit\n"); } }