/*- * SPDX-License-Identifier: BSD-2-Clause * * Copyright 1998 Juniper Networks, Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include #include #include #include #include #ifdef WITH_SSL #include #include #define MD5Init MD5_Init #define MD5Update MD5_Update #define MD5Final MD5_Final #else #define MD5_DIGEST_LENGTH 16 #include #endif #define MAX_FIELDS 7 /* We need the MPPE_KEY_LEN define */ #include #include #include #include #include #include #include #include #include #include "radlib_private.h" static void clear_password(struct rad_handle *); static void generr(struct rad_handle *, const char *, ...) __printflike(2, 3); static void insert_scrambled_password(struct rad_handle *, int); static void insert_request_authenticator(struct rad_handle *, int); static void insert_message_authenticator(struct rad_handle *, int); static int is_valid_response(struct rad_handle *, int, const struct sockaddr_in *); static int put_password_attr(struct rad_handle *, int, const void *, size_t); static int put_raw_attr(struct rad_handle *, int, const void *, size_t); static int split(char *, char *[], int, char *, size_t); static void clear_password(struct rad_handle *h) { if (h->pass_len != 0) { explicit_bzero(h->pass, h->pass_len); h->pass_len = 0; } h->pass_pos = 0; } static void generr(struct rad_handle *h, const char *format, ...) { va_list ap; va_start(ap, format); vsnprintf(h->errmsg, ERRSIZE, format, ap); va_end(ap); } static void insert_scrambled_password(struct rad_handle *h, int srv) { MD5_CTX ctx; unsigned char md5[MD5_DIGEST_LENGTH]; const struct rad_server *srvp; int padded_len; int pos; srvp = &h->servers[srv]; padded_len = h->pass_len == 0 ? 16 : (h->pass_len+15) & ~0xf; memcpy(md5, &h->out[POS_AUTH], LEN_AUTH); for (pos = 0; pos < padded_len; pos += 16) { int i; /* Calculate the new scrambler */ MD5Init(&ctx); MD5Update(&ctx, srvp->secret, strlen(srvp->secret)); MD5Update(&ctx, md5, 16); MD5Final(md5, &ctx); /* * Mix in the current chunk of the password, and copy * the result into the right place in the request. Also * modify the scrambler in place, since we will use this * in calculating the scrambler for next time. */ for (i = 0; i < 16; i++) h->out[h->pass_pos + pos + i] = md5[i] ^= h->pass[pos + i]; } } static void insert_request_authenticator(struct rad_handle *h, int resp) { MD5_CTX ctx; const struct rad_server *srvp; srvp = &h->servers[h->srv]; /* Create the request authenticator */ MD5Init(&ctx); MD5Update(&ctx, &h->out[POS_CODE], POS_AUTH - POS_CODE); if (resp) MD5Update(&ctx, &h->in[POS_AUTH], LEN_AUTH); else MD5Update(&ctx, &h->out[POS_AUTH], LEN_AUTH); MD5Update(&ctx, &h->out[POS_ATTRS], h->out_len - POS_ATTRS); MD5Update(&ctx, srvp->secret, strlen(srvp->secret)); MD5Final(&h->out[POS_AUTH], &ctx); } static void insert_message_authenticator(struct rad_handle *h, int resp) { #ifdef WITH_SSL u_char md[EVP_MAX_MD_SIZE]; u_int md_len; const struct rad_server *srvp; HMAC_CTX *ctx; srvp = &h->servers[h->srv]; if (h->authentic_pos != 0) { ctx = HMAC_CTX_new(); HMAC_Init_ex(ctx, srvp->secret, strlen(srvp->secret), EVP_md5(), NULL); HMAC_Update(ctx, &h->out[POS_CODE], POS_AUTH - POS_CODE); if (resp) HMAC_Update(ctx, &h->in[POS_AUTH], LEN_AUTH); else HMAC_Update(ctx, &h->out[POS_AUTH], LEN_AUTH); HMAC_Update(ctx, &h->out[POS_ATTRS], h->out_len - POS_ATTRS); HMAC_Final(ctx, md, &md_len); HMAC_CTX_free(ctx); memcpy(&h->out[h->authentic_pos + 2], md, md_len); } #endif } /* * Return true if the current response is valid for a request to the * specified server. */ static int is_valid_response(struct rad_handle *h, int srv, const struct sockaddr_in *from) { MD5_CTX ctx; unsigned char md5[MD5_DIGEST_LENGTH]; const struct rad_server *srvp; int len; #ifdef WITH_SSL int alen; HMAC_CTX *hctx; u_char resp[MSGSIZE], md[EVP_MAX_MD_SIZE]; u_int md_len; int pos; #endif srvp = &h->servers[srv]; /* Check the source address */ if (from->sin_family != srvp->addr.sin_family || from->sin_addr.s_addr != srvp->addr.sin_addr.s_addr || from->sin_port != srvp->addr.sin_port) return 0; /* Check the message length */ if (h->in_len < POS_ATTRS) return 0; len = (h->in[POS_LENGTH] << 8) | h->in[POS_LENGTH + 1]; if (len < POS_ATTRS || len > h->in_len) return 0; /* Check the response authenticator */ MD5Init(&ctx); MD5Update(&ctx, &h->in[POS_CODE], POS_AUTH - POS_CODE); MD5Update(&ctx, &h->out[POS_AUTH], LEN_AUTH); MD5Update(&ctx, &h->in[POS_ATTRS], len - POS_ATTRS); MD5Update(&ctx, srvp->secret, strlen(srvp->secret)); MD5Final(md5, &ctx); if (memcmp(&h->in[POS_AUTH], md5, sizeof md5) != 0) return 0; #ifdef WITH_SSL /* * For non accounting responses check the message authenticator, * if any. */ if (h->in[POS_CODE] != RAD_ACCOUNTING_RESPONSE) { memcpy(resp, h->in, MSGSIZE); pos = POS_ATTRS; /* Search and verify the Message-Authenticator */ hctx = HMAC_CTX_new(); while (pos < len - 2) { if (h->in[pos] == RAD_MESSAGE_AUTHENTIC) { if (h->in[pos + 1] != MD5_DIGEST_LENGTH + 2) { HMAC_CTX_free(hctx); return 0; } if (len - pos < MD5_DIGEST_LENGTH + 2) { HMAC_CTX_free(hctx); return 0; } memset(&resp[pos + 2], 0, MD5_DIGEST_LENGTH); HMAC_Init_ex(hctx, srvp->secret, strlen(srvp->secret), EVP_md5(), NULL); HMAC_Update(hctx, &h->in[POS_CODE], POS_AUTH - POS_CODE); HMAC_Update(hctx, &h->out[POS_AUTH], LEN_AUTH); HMAC_Update(hctx, &resp[POS_ATTRS], h->in_len - POS_ATTRS); HMAC_Final(hctx, md, &md_len); HMAC_CTX_reset(hctx); if (memcmp(md, &h->in[pos + 2], MD5_DIGEST_LENGTH) != 0) { HMAC_CTX_free(hctx); return 0; } break; } alen = h->in[pos + 1]; if (alen < 2) { HMAC_CTX_free(hctx); return 0; } pos += alen; } HMAC_CTX_free(hctx); } #endif return 1; } /* * Return true if the current request is valid for the specified server. */ static int is_valid_request(struct rad_handle *h) { MD5_CTX ctx; unsigned char md5[MD5_DIGEST_LENGTH]; const struct rad_server *srvp; int len; #ifdef WITH_SSL int alen; HMAC_CTX *hctx; u_char resp[MSGSIZE], md[EVP_MAX_MD_SIZE]; u_int md_len; int pos; #endif srvp = &h->servers[h->srv]; /* Check the message length */ if (h->in_len < POS_ATTRS) return (0); len = (h->in[POS_LENGTH] << 8) | h->in[POS_LENGTH + 1]; if (len < POS_ATTRS || len > h->in_len) return (0); if (h->in[POS_CODE] != RAD_ACCESS_REQUEST) { uint32_t zeroes[4] = { 0, 0, 0, 0 }; /* Check the request authenticator */ MD5Init(&ctx); MD5Update(&ctx, &h->in[POS_CODE], POS_AUTH - POS_CODE); MD5Update(&ctx, zeroes, LEN_AUTH); MD5Update(&ctx, &h->in[POS_ATTRS], len - POS_ATTRS); MD5Update(&ctx, srvp->secret, strlen(srvp->secret)); MD5Final(md5, &ctx); if (memcmp(&h->in[POS_AUTH], md5, sizeof md5) != 0) return (0); } #ifdef WITH_SSL /* Search and verify the Message-Authenticator */ pos = POS_ATTRS; hctx = HMAC_CTX_new(); while (pos < len - 2) { alen = h->in[pos + 1]; if (alen < 2) return (0); if (h->in[pos] == RAD_MESSAGE_AUTHENTIC) { if (len - pos < MD5_DIGEST_LENGTH + 2) { HMAC_CTX_free(hctx); return (0); } if (alen < MD5_DIGEST_LENGTH + 2) { HMAC_CTX_free(hctx); return (0); } memcpy(resp, h->in, MSGSIZE); /* zero fill the Request-Authenticator */ if (h->in[POS_CODE] != RAD_ACCESS_REQUEST) memset(&resp[POS_AUTH], 0, LEN_AUTH); /* zero fill the Message-Authenticator */ memset(&resp[pos + 2], 0, MD5_DIGEST_LENGTH); HMAC_Init_ex(hctx, srvp->secret, strlen(srvp->secret), EVP_md5(), NULL); HMAC_Update(hctx, resp, h->in_len); HMAC_Final(hctx, md, &md_len); HMAC_CTX_reset(hctx); if (memcmp(md, &h->in[pos + 2], MD5_DIGEST_LENGTH) != 0) { HMAC_CTX_free(hctx); return (0); } break; } pos += alen; } HMAC_CTX_free(hctx); #endif return (1); } static int put_password_attr(struct rad_handle *h, int type, const void *value, size_t len) { int padded_len; int pad_len; if (h->pass_pos != 0) { generr(h, "Multiple User-Password attributes specified"); return -1; } if (len > PASSSIZE) len = PASSSIZE; padded_len = len == 0 ? 16 : (len+15) & ~0xf; pad_len = padded_len - len; /* * Put in a place-holder attribute containing all zeros, and * remember where it is so we can fill it in later. */ clear_password(h); put_raw_attr(h, type, h->pass, padded_len); h->pass_pos = h->out_len - padded_len; /* Save the cleartext password, padded as necessary */ memcpy(h->pass, value, len); h->pass_len = len; memset(h->pass + len, 0, pad_len); return 0; } static int put_raw_attr(struct rad_handle *h, int type, const void *value, size_t len) { if (len > 253) { generr(h, "Attribute too long"); return -1; } if (h->out_len + 2 + len > MSGSIZE) { generr(h, "Maximum message length exceeded"); return -1; } h->out[h->out_len++] = type; h->out[h->out_len++] = len + 2; memcpy(&h->out[h->out_len], value, len); h->out_len += len; return 0; } int rad_add_server(struct rad_handle *h, const char *host, int port, const char *secret, int timeout, int tries) { struct in_addr bindto; bindto.s_addr = INADDR_ANY; return rad_add_server_ex(h, host, port, secret, timeout, tries, DEAD_TIME, &bindto); } int rad_add_server_ex(struct rad_handle *h, const char *host, int port, const char *secret, int timeout, int tries, int dead_time, struct in_addr *bindto) { struct rad_server *srvp; if (h->num_servers >= MAXSERVERS) { generr(h, "Too many RADIUS servers specified"); return -1; } srvp = &h->servers[h->num_servers]; memset(&srvp->addr, 0, sizeof srvp->addr); srvp->addr.sin_len = sizeof srvp->addr; srvp->addr.sin_family = AF_INET; if (!inet_aton(host, &srvp->addr.sin_addr)) { struct hostent *hent; if ((hent = gethostbyname(host)) == NULL) { generr(h, "%s: host not found", host); return -1; } memcpy(&srvp->addr.sin_addr, hent->h_addr, sizeof srvp->addr.sin_addr); } if (port != 0) srvp->addr.sin_port = htons((u_short)port); else { struct servent *sent; if (h->type == RADIUS_AUTH) srvp->addr.sin_port = (sent = getservbyname("radius", "udp")) != NULL ? sent->s_port : htons(RADIUS_PORT); else srvp->addr.sin_port = (sent = getservbyname("radacct", "udp")) != NULL ? sent->s_port : htons(RADACCT_PORT); } if ((srvp->secret = strdup(secret)) == NULL) { generr(h, "Out of memory"); return -1; } srvp->timeout = timeout; srvp->max_tries = tries; srvp->num_tries = 0; srvp->is_dead = 0; srvp->dead_time = dead_time; srvp->next_probe = 0; srvp->bindto = bindto->s_addr; h->num_servers++; return 0; } void rad_close(struct rad_handle *h) { int srv; if (h->fd != -1) close(h->fd); for (srv = 0; srv < h->num_servers; srv++) { memset(h->servers[srv].secret, 0, strlen(h->servers[srv].secret)); free(h->servers[srv].secret); } clear_password(h); free(h); } void rad_bind_to(struct rad_handle *h, in_addr_t addr) { h->bindto = addr; } int rad_config(struct rad_handle *h, const char *path) { FILE *fp; char buf[MAXCONFLINE]; int linenum; int retval; if (path == NULL) path = PATH_RADIUS_CONF; if ((fp = fopen(path, "r")) == NULL) { generr(h, "Cannot open \"%s\": %s", path, strerror(errno)); return -1; } retval = 0; linenum = 0; while (fgets(buf, sizeof buf, fp) != NULL) { int len; char *fields[MAX_FIELDS]; int nfields; char msg[ERRSIZE]; char *type; char *host, *res; char *port_str; char *secret; char *timeout_str; char *maxtries_str; char *dead_time_str; char *bindto_str; char *end; char *wanttype; unsigned long timeout; unsigned long maxtries; unsigned long dead_time; int port; struct in_addr bindto; int i; linenum++; len = strlen(buf); /* We know len > 0, else fgets would have returned NULL. */ if (buf[len - 1] != '\n') { if (len == sizeof buf - 1) generr(h, "%s:%d: line too long", path, linenum); else generr(h, "%s:%d: missing newline", path, linenum); retval = -1; break; } buf[len - 1] = '\0'; /* Extract the fields from the line. */ nfields = split(buf, fields, MAX_FIELDS, msg, sizeof msg); if (nfields == -1) { generr(h, "%s:%d: %s", path, linenum, msg); retval = -1; break; } if (nfields == 0) continue; /* * The first field should contain "auth" or "acct" for * authentication or accounting, respectively. But older * versions of the file didn't have that field. Default * it to "auth" for backward compatibility. */ if (strcmp(fields[0], "auth") != 0 && strcmp(fields[0], "acct") != 0) { if (nfields >= MAX_FIELDS) { generr(h, "%s:%d: invalid service type", path, linenum); retval = -1; break; } nfields++; for (i = nfields; --i > 0; ) fields[i] = fields[i - 1]; fields[0] = "auth"; } if (nfields < 3) { generr(h, "%s:%d: missing shared secret", path, linenum); retval = -1; break; } type = fields[0]; host = fields[1]; secret = fields[2]; timeout_str = fields[3]; maxtries_str = fields[4]; dead_time_str = fields[5]; bindto_str = fields[6]; /* Ignore the line if it is for the wrong service type. */ wanttype = h->type == RADIUS_AUTH ? "auth" : "acct"; if (strcmp(type, wanttype) != 0) continue; /* Parse and validate the fields. */ res = host; host = strsep(&res, ":"); port_str = strsep(&res, ":"); if (port_str != NULL) { port = strtoul(port_str, &end, 10); if (*end != '\0') { generr(h, "%s:%d: invalid port", path, linenum); retval = -1; break; } } else port = 0; if (timeout_str != NULL) { timeout = strtoul(timeout_str, &end, 10); if (*end != '\0') { generr(h, "%s:%d: invalid timeout", path, linenum); retval = -1; break; } } else timeout = TIMEOUT; if (maxtries_str != NULL) { maxtries = strtoul(maxtries_str, &end, 10); if (*end != '\0') { generr(h, "%s:%d: invalid maxtries", path, linenum); retval = -1; break; } } else maxtries = MAXTRIES; if (dead_time_str != NULL) { dead_time = strtoul(dead_time_str, &end, 10); if (*end != '\0') { generr(h, "%s:%d: invalid dead_time", path, linenum); retval = -1; break; } } else dead_time = DEAD_TIME; if (bindto_str != NULL) { bindto.s_addr = inet_addr(bindto_str); if (bindto.s_addr == INADDR_NONE) { generr(h, "%s:%d: invalid bindto", path, linenum); retval = -1; break; } } else bindto.s_addr = INADDR_ANY; if (rad_add_server_ex(h, host, port, secret, timeout, maxtries, dead_time, &bindto) == -1) { strcpy(msg, h->errmsg); generr(h, "%s:%d: %s", path, linenum, msg); retval = -1; break; } } /* Clear out the buffer to wipe a possible copy of a shared secret */ memset(buf, 0, sizeof buf); fclose(fp); return retval; } /* * rad_init_send_request() must have previously been called. * Returns: * 0 The application should select on *fd with a timeout of tv before * calling rad_continue_send_request again. * < 0 Failure * > 0 Success */ int rad_continue_send_request(struct rad_handle *h, int selected, int *fd, struct timeval *tv) { int n, cur_srv; time_t now; struct sockaddr_in sin; if (h->type == RADIUS_SERVER) { generr(h, "denied function call"); return (-1); } if (selected) { struct sockaddr_in from; socklen_t fromlen; fromlen = sizeof from; h->in_len = recvfrom(h->fd, h->in, MSGSIZE, MSG_WAITALL, (struct sockaddr *)&from, &fromlen); if (h->in_len == -1) { generr(h, "recvfrom: %s", strerror(errno)); return -1; } if (is_valid_response(h, h->srv, &from)) { h->in_len = h->in[POS_LENGTH] << 8 | h->in[POS_LENGTH+1]; h->in_pos = POS_ATTRS; return h->in[POS_CODE]; } } /* * Scan round-robin to the next server that has some * tries left. There is guaranteed to be one, or we * would have exited this loop by now. */ cur_srv = h->srv; now = time(NULL); if (h->servers[h->srv].num_tries >= h->servers[h->srv].max_tries) { /* Set next probe time for this server */ if (h->servers[h->srv].dead_time) { h->servers[h->srv].is_dead = 1; h->servers[h->srv].next_probe = now + h->servers[h->srv].dead_time; } do { h->srv++; if (h->srv >= h->num_servers) h->srv = 0; if (h->servers[h->srv].is_dead == 0) break; if (h->servers[h->srv].dead_time && h->servers[h->srv].next_probe <= now) { h->servers[h->srv].is_dead = 0; h->servers[h->srv].num_tries = 0; break; } } while (h->srv != cur_srv); if (h->srv == cur_srv) { generr(h, "No valid RADIUS responses received"); return (-1); } } /* Rebind */ if (h->bindto != h->servers[h->srv].bindto) { h->bindto = h->servers[h->srv].bindto; close(h->fd); if ((h->fd = socket(PF_INET, SOCK_DGRAM, IPPROTO_UDP)) == -1) { generr(h, "Cannot create socket: %s", strerror(errno)); return -1; } memset(&sin, 0, sizeof sin); sin.sin_len = sizeof sin; sin.sin_family = AF_INET; sin.sin_addr.s_addr = h->bindto; sin.sin_port = 0; if (bind(h->fd, (const struct sockaddr *)&sin, sizeof sin) == -1) { generr(h, "bind: %s", strerror(errno)); close(h->fd); h->fd = -1; return (-1); } } if (h->out[POS_CODE] == RAD_ACCESS_REQUEST) { /* Insert the scrambled password into the request */ if (h->pass_pos != 0) insert_scrambled_password(h, h->srv); } insert_message_authenticator(h, 0); if (h->out[POS_CODE] != RAD_ACCESS_REQUEST) { /* Insert the request authenticator into the request */ memset(&h->out[POS_AUTH], 0, LEN_AUTH); insert_request_authenticator(h, 0); } /* Send the request */ n = sendto(h->fd, h->out, h->out_len, 0, (const struct sockaddr *)&h->servers[h->srv].addr, sizeof h->servers[h->srv].addr); if (n != h->out_len) tv->tv_sec = 1; /* Do not wait full timeout if send failed. */ else tv->tv_sec = h->servers[h->srv].timeout; h->servers[h->srv].num_tries++; tv->tv_usec = 0; *fd = h->fd; return 0; } int rad_receive_request(struct rad_handle *h) { struct sockaddr_in from; socklen_t fromlen; int n; if (h->type != RADIUS_SERVER) { generr(h, "denied function call"); return (-1); } h->srv = -1; fromlen = sizeof(from); h->in_len = recvfrom(h->fd, h->in, MSGSIZE, MSG_WAITALL, (struct sockaddr *)&from, &fromlen); if (h->in_len == -1) { generr(h, "recvfrom: %s", strerror(errno)); return (-1); } for (n = 0; n < h->num_servers; n++) { if (h->servers[n].addr.sin_addr.s_addr == from.sin_addr.s_addr) { h->servers[n].addr.sin_port = from.sin_port; h->srv = n; break; } } if (h->srv == -1) return (-2); if (is_valid_request(h)) { h->in_len = h->in[POS_LENGTH] << 8 | h->in[POS_LENGTH+1]; h->in_pos = POS_ATTRS; return (h->in[POS_CODE]); } return (-3); } int rad_send_response(struct rad_handle *h) { int n; if (h->type != RADIUS_SERVER) { generr(h, "denied function call"); return (-1); } /* Fill in the length field in the message */ h->out[POS_LENGTH] = h->out_len >> 8; h->out[POS_LENGTH+1] = h->out_len; insert_message_authenticator(h, (h->in[POS_CODE] == RAD_ACCESS_REQUEST) ? 1 : 0); insert_request_authenticator(h, 1); /* Send the request */ n = sendto(h->fd, h->out, h->out_len, 0, (const struct sockaddr *)&h->servers[h->srv].addr, sizeof h->servers[h->srv].addr); if (n != h->out_len) { if (n == -1) generr(h, "sendto: %s", strerror(errno)); else generr(h, "sendto: short write"); return -1; } return 0; } int rad_create_request(struct rad_handle *h, int code) { int i; if (h->type == RADIUS_SERVER) { generr(h, "denied function call"); return (-1); } if (h->num_servers == 0) { generr(h, "No RADIUS servers specified"); return (-1); } h->out[POS_CODE] = code; h->out[POS_IDENT] = ++h->ident; if (code == RAD_ACCESS_REQUEST) { /* Create a random authenticator */ for (i = 0; i < LEN_AUTH; i += 2) { uint32_t r; r = arc4random(); h->out[POS_AUTH+i] = (u_char)r; h->out[POS_AUTH+i+1] = (u_char)(r >> 8); } } else memset(&h->out[POS_AUTH], 0, LEN_AUTH); h->out_len = POS_ATTRS; clear_password(h); h->authentic_pos = 0; h->out_created = 1; return 0; } int rad_create_response(struct rad_handle *h, int code) { if (h->type != RADIUS_SERVER) { generr(h, "denied function call"); return (-1); } h->out[POS_CODE] = code; h->out[POS_IDENT] = h->in[POS_IDENT]; memset(&h->out[POS_AUTH], 0, LEN_AUTH); h->out_len = POS_ATTRS; clear_password(h); h->authentic_pos = 0; h->out_created = 1; return 0; } struct in_addr rad_cvt_addr(const void *data) { struct in_addr value; memcpy(&value.s_addr, data, sizeof value.s_addr); return value; } struct in6_addr rad_cvt_addr6(const void *data) { struct in6_addr value; memcpy(&value.s6_addr, data, sizeof value.s6_addr); return value; } u_int32_t rad_cvt_int(const void *data) { u_int32_t value; memcpy(&value, data, sizeof value); return ntohl(value); } char * rad_cvt_string(const void *data, size_t len) { char *s; s = malloc(len + 1); if (s != NULL) { memcpy(s, data, len); s[len] = '\0'; } return s; } /* * Returns the attribute type. If none are left, returns 0. On failure, * returns -1. */ int rad_get_attr(struct rad_handle *h, const void **value, size_t *lenp) { int len, type; if (h->in_pos >= h->in_len) return 0; if (h->in_pos + 2 > h->in_len) { generr(h, "Malformed attribute in response"); return -1; } type = h->in[h->in_pos++]; len = h->in[h->in_pos++]; if (len < 2) { generr(h, "Malformed attribute in response"); return -1; } len -= 2; if (h->in_pos + len > h->in_len) { generr(h, "Malformed attribute in response"); return -1; } *lenp = len; *value = &h->in[h->in_pos]; h->in_pos += len; return type; } /* * Returns -1 on error, 0 to indicate no event and >0 for success */ int rad_init_send_request(struct rad_handle *h, int *fd, struct timeval *tv) { int srv; time_t now; struct sockaddr_in sin; if (h->type == RADIUS_SERVER) { generr(h, "denied function call"); return (-1); } /* Make sure we have a socket to use */ if (h->fd == -1) { if ((h->fd = socket(PF_INET, SOCK_DGRAM, IPPROTO_UDP)) == -1) { generr(h, "Cannot create socket: %s", strerror(errno)); return -1; } memset(&sin, 0, sizeof sin); sin.sin_len = sizeof sin; sin.sin_family = AF_INET; sin.sin_addr.s_addr = h->bindto; sin.sin_port = htons(0); if (bind(h->fd, (const struct sockaddr *)&sin, sizeof sin) == -1) { generr(h, "bind: %s", strerror(errno)); close(h->fd); h->fd = -1; return -1; } } if (h->out[POS_CODE] != RAD_ACCESS_REQUEST) { /* Make sure no password given */ if (h->pass_pos || h->chap_pass) { generr(h, "User or Chap Password" " in accounting request"); return -1; } } else { if (h->eap_msg == 0) { /* Make sure the user gave us a password */ if (h->pass_pos == 0 && !h->chap_pass) { generr(h, "No User or Chap Password" " attributes given"); return -1; } if (h->pass_pos != 0 && h->chap_pass) { generr(h, "Both User and Chap Password" " attributes given"); return -1; } } } /* Fill in the length field in the message */ h->out[POS_LENGTH] = h->out_len >> 8; h->out[POS_LENGTH+1] = h->out_len; h->srv = 0; now = time(NULL); for (srv = 0; srv < h->num_servers; srv++) h->servers[srv].num_tries = 0; /* Find a first good server. */ for (srv = 0; srv < h->num_servers; srv++) { if (h->servers[srv].is_dead == 0) break; if (h->servers[srv].dead_time && h->servers[srv].next_probe <= now) { h->servers[srv].is_dead = 0; break; } h->srv++; } /* If all servers was dead on the last probe, try from beginning */ if (h->srv == h->num_servers) { for (srv = 0; srv < h->num_servers; srv++) { h->servers[srv].is_dead = 0; h->servers[srv].next_probe = 0; } h->srv = 0; } return rad_continue_send_request(h, 0, fd, tv); } /* * Create and initialize a rad_handle structure, and return it to the * caller. Can fail only if the necessary memory cannot be allocated. * In that case, it returns NULL. */ struct rad_handle * rad_auth_open(void) { struct rad_handle *h; h = (struct rad_handle *)malloc(sizeof(struct rad_handle)); if (h != NULL) { h->fd = -1; h->num_servers = 0; h->ident = arc4random(); h->errmsg[0] = '\0'; memset(h->pass, 0, sizeof h->pass); h->pass_len = 0; h->pass_pos = 0; h->chap_pass = 0; h->authentic_pos = 0; h->type = RADIUS_AUTH; h->out_created = 0; h->eap_msg = 0; h->bindto = INADDR_ANY; } return h; } struct rad_handle * rad_acct_open(void) { struct rad_handle *h; h = rad_open(); if (h != NULL) h->type = RADIUS_ACCT; return h; } struct rad_handle * rad_server_open(int fd) { struct rad_handle *h; h = rad_open(); if (h != NULL) { h->type = RADIUS_SERVER; h->fd = fd; } return h; } struct rad_handle * rad_open(void) { return rad_auth_open(); } int rad_put_addr(struct rad_handle *h, int type, struct in_addr addr) { return rad_put_attr(h, type, &addr.s_addr, sizeof addr.s_addr); } int rad_put_addr6(struct rad_handle *h, int type, struct in6_addr addr) { return rad_put_attr(h, type, &addr.s6_addr, sizeof addr.s6_addr); } int rad_put_attr(struct rad_handle *h, int type, const void *value, size_t len) { int result; if (!h->out_created) { generr(h, "Please call rad_create_request()" " before putting attributes"); return -1; } if (h->out[POS_CODE] == RAD_ACCOUNTING_REQUEST) { if (type == RAD_EAP_MESSAGE) { generr(h, "EAP-Message attribute is not valid" " in accounting requests"); return -1; } } /* * When proxying EAP Messages, the Message Authenticator * MUST be present; see RFC 3579. */ if (type == RAD_EAP_MESSAGE) { if (rad_put_message_authentic(h) == -1) return -1; } if (type == RAD_USER_PASSWORD) { result = put_password_attr(h, type, value, len); } else if (type == RAD_MESSAGE_AUTHENTIC) { result = rad_put_message_authentic(h); } else { result = put_raw_attr(h, type, value, len); if (result == 0) { if (type == RAD_CHAP_PASSWORD) h->chap_pass = 1; else if (type == RAD_EAP_MESSAGE) h->eap_msg = 1; } } return result; } int rad_put_int(struct rad_handle *h, int type, u_int32_t value) { u_int32_t nvalue; nvalue = htonl(value); return rad_put_attr(h, type, &nvalue, sizeof nvalue); } int rad_put_string(struct rad_handle *h, int type, const char *str) { return rad_put_attr(h, type, str, strlen(str)); } int rad_put_message_authentic(struct rad_handle *h) { #ifdef WITH_SSL u_char md_zero[MD5_DIGEST_LENGTH]; if (h->out[POS_CODE] == RAD_ACCOUNTING_REQUEST) { generr(h, "Message-Authenticator is not valid" " in accounting requests"); return -1; } if (h->authentic_pos == 0) { h->authentic_pos = h->out_len; memset(md_zero, 0, sizeof(md_zero)); return (put_raw_attr(h, RAD_MESSAGE_AUTHENTIC, md_zero, sizeof(md_zero))); } return 0; #else generr(h, "Message Authenticator not supported," " please recompile libradius with SSL support"); return -1; #endif } /* * Returns the response type code on success, or -1 on failure. */ int rad_send_request(struct rad_handle *h) { struct timeval timelimit; struct timeval tv; int fd; int n; n = rad_init_send_request(h, &fd, &tv); if (n != 0) return n; gettimeofday(&timelimit, NULL); timeradd(&tv, &timelimit, &timelimit); for ( ; ; ) { fd_set readfds; FD_ZERO(&readfds); FD_SET(fd, &readfds); n = select(fd + 1, &readfds, NULL, NULL, &tv); if (n == -1) { generr(h, "select: %s", strerror(errno)); return -1; } if (!FD_ISSET(fd, &readfds)) { /* Compute a new timeout */ gettimeofday(&tv, NULL); timersub(&timelimit, &tv, &tv); if (tv.tv_sec > 0 || (tv.tv_sec == 0 && tv.tv_usec > 0)) /* Continue the select */ continue; } n = rad_continue_send_request(h, n, &fd, &tv); if (n != 0) return n; gettimeofday(&timelimit, NULL); timeradd(&tv, &timelimit, &timelimit); } } const char * rad_strerror(struct rad_handle *h) { return h->errmsg; } /* * Destructively split a string into fields separated by white space. * `#' at the beginning of a field begins a comment that extends to the * end of the string. Fields may be quoted with `"'. Inside quoted * strings, the backslash escapes `\"' and `\\' are honored. * * Pointers to up to the first maxfields fields are stored in the fields * array. Missing fields get NULL pointers. * * The return value is the actual number of fields parsed, and is always * <= maxfields. * * On a syntax error, places a message in the msg string, and returns -1. */ static int split(char *str, char *fields[], int maxfields, char *msg, size_t msglen) { char *p; int i; static const char ws[] = " \t"; for (i = 0; i < maxfields; i++) fields[i] = NULL; p = str; i = 0; while (*p != '\0') { p += strspn(p, ws); if (*p == '#' || *p == '\0') break; if (i >= maxfields) { snprintf(msg, msglen, "line has too many fields"); return -1; } if (*p == '"') { char *dst; dst = ++p; fields[i] = dst; while (*p != '"') { if (*p == '\\') { p++; if (*p != '"' && *p != '\\' && *p != '\0') { snprintf(msg, msglen, "invalid `\\' escape"); return -1; } } if (*p == '\0') { snprintf(msg, msglen, "unterminated quoted string"); return -1; } *dst++ = *p++; } *dst = '\0'; p++; if (*fields[i] == '\0') { snprintf(msg, msglen, "empty quoted string not permitted"); return -1; } if (*p != '\0' && strspn(p, ws) == 0) { snprintf(msg, msglen, "quoted string not" " followed by white space"); return -1; } } else { fields[i] = p; p += strcspn(p, ws); if (*p != '\0') *p++ = '\0'; } i++; } return i; } int rad_get_vendor_attr(u_int32_t *vendor, const void **data, size_t *len) { struct vendor_attribute *attr; attr = (struct vendor_attribute *)*data; *vendor = ntohl(attr->vendor_value); *data = attr->attrib_data; *len = attr->attrib_len - 2; return (attr->attrib_type); } int rad_put_vendor_addr(struct rad_handle *h, int vendor, int type, struct in_addr addr) { return (rad_put_vendor_attr(h, vendor, type, &addr.s_addr, sizeof addr.s_addr)); } int rad_put_vendor_addr6(struct rad_handle *h, int vendor, int type, struct in6_addr addr) { return (rad_put_vendor_attr(h, vendor, type, &addr.s6_addr, sizeof addr.s6_addr)); } int rad_put_vendor_attr(struct rad_handle *h, int vendor, int type, const void *value, size_t len) { struct vendor_attribute *attr; int res; if (!h->out_created) { generr(h, "Please call rad_create_request()" " before putting attributes"); return -1; } if ((attr = malloc(len + 6)) == NULL) { generr(h, "malloc failure (%zu bytes)", len + 6); return -1; } attr->vendor_value = htonl(vendor); attr->attrib_type = type; attr->attrib_len = len + 2; memcpy(attr->attrib_data, value, len); res = put_raw_attr(h, RAD_VENDOR_SPECIFIC, attr, len + 6); free(attr); if (res == 0 && vendor == RAD_VENDOR_MICROSOFT && (type == RAD_MICROSOFT_MS_CHAP_RESPONSE || type == RAD_MICROSOFT_MS_CHAP2_RESPONSE)) { h->chap_pass = 1; } return (res); } int rad_put_vendor_int(struct rad_handle *h, int vendor, int type, u_int32_t i) { u_int32_t value; value = htonl(i); return (rad_put_vendor_attr(h, vendor, type, &value, sizeof value)); } int rad_put_vendor_string(struct rad_handle *h, int vendor, int type, const char *str) { return (rad_put_vendor_attr(h, vendor, type, str, strlen(str))); } ssize_t rad_request_authenticator(struct rad_handle *h, char *buf, size_t len) { if (len < LEN_AUTH) return (-1); memcpy(buf, h->out + POS_AUTH, LEN_AUTH); if (len > LEN_AUTH) buf[LEN_AUTH] = '\0'; return (LEN_AUTH); } u_char * rad_demangle(struct rad_handle *h, const void *mangled, size_t mlen) { char R[LEN_AUTH]; const char *S; int i, Ppos; MD5_CTX Context; u_char b[MD5_DIGEST_LENGTH], *C, *demangled; if ((mlen % 16 != 0) || mlen > 128) { generr(h, "Cannot interpret mangled data of length %lu", (u_long)mlen); return NULL; } C = (u_char *)mangled; /* We need the shared secret as Salt */ S = rad_server_secret(h); /* We need the request authenticator */ if (rad_request_authenticator(h, R, sizeof R) != LEN_AUTH) { generr(h, "Cannot obtain the RADIUS request authenticator"); return NULL; } demangled = malloc(mlen); if (!demangled) return NULL; MD5Init(&Context); MD5Update(&Context, S, strlen(S)); MD5Update(&Context, R, LEN_AUTH); MD5Final(b, &Context); Ppos = 0; while (mlen) { mlen -= 16; for (i = 0; i < 16; i++) demangled[Ppos++] = C[i] ^ b[i]; if (mlen) { MD5Init(&Context); MD5Update(&Context, S, strlen(S)); MD5Update(&Context, C, 16); MD5Final(b, &Context); } C += 16; } return demangled; } u_char * rad_demangle_mppe_key(struct rad_handle *h, const void *mangled, size_t mlen, size_t *len) { char R[LEN_AUTH]; /* variable names as per rfc2548 */ const char *S; u_char b[MD5_DIGEST_LENGTH], *demangled; const u_char *A, *C; MD5_CTX Context; int Slen, i, Clen, Ppos; u_char *P; if (mlen % 16 != SALT_LEN) { generr(h, "Cannot interpret mangled data of length %lu", (u_long)mlen); return NULL; } /* We need the RADIUS Request-Authenticator */ if (rad_request_authenticator(h, R, sizeof R) != LEN_AUTH) { generr(h, "Cannot obtain the RADIUS request authenticator"); return NULL; } A = (const u_char *)mangled; /* Salt comes first */ C = (const u_char *)mangled + SALT_LEN; /* Then the ciphertext */ Clen = mlen - SALT_LEN; S = rad_server_secret(h); /* We need the RADIUS secret */ Slen = strlen(S); P = alloca(Clen); /* We derive our plaintext */ MD5Init(&Context); MD5Update(&Context, S, Slen); MD5Update(&Context, R, LEN_AUTH); MD5Update(&Context, A, SALT_LEN); MD5Final(b, &Context); Ppos = 0; while (Clen) { Clen -= 16; for (i = 0; i < 16; i++) P[Ppos++] = C[i] ^ b[i]; if (Clen) { MD5Init(&Context); MD5Update(&Context, S, Slen); MD5Update(&Context, C, 16); MD5Final(b, &Context); } C += 16; } /* * The resulting plain text consists of a one-byte length, the text and * maybe some padding. */ *len = *P; if (*len > mlen - 1) { generr(h, "Mangled data seems to be garbage %zu %zu", *len, mlen-1); return NULL; } if (*len > MPPE_KEY_LEN * 2) { generr(h, "Key to long (%zu) for me max. %d", *len, MPPE_KEY_LEN * 2); return NULL; } demangled = malloc(*len); if (!demangled) return NULL; memcpy(demangled, P + 1, *len); return demangled; } const char * rad_server_secret(struct rad_handle *h) { return (h->servers[h->srv].secret); }