Current Path : /compat/linux/proc/self/root/usr/src/usr.sbin/ppp/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //compat/linux/proc/self/root/usr/src/usr.sbin/ppp/radius.c |
/* * Copyright 1999 Internet Business Solutions Ltd., Switzerland * 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. * * $FreeBSD: release/9.1.0/usr.sbin/ppp/radius.c 169986 2007-05-25 13:45:49Z novel $ * */ #include <stdint.h> #include <sys/param.h> #include <sys/select.h> #include <sys/socket.h> #include <netinet/in_systm.h> #include <netinet/in.h> #include <netinet/ip.h> #include <arpa/inet.h> #include <sys/un.h> #include <net/route.h> #ifdef LOCALRAD #include "radlib.h" #include "radlib_vs.h" #else #include <radlib.h> #include <radlib_vs.h> #endif #include <errno.h> #ifndef NODES #include <md5.h> #endif #include <stdarg.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include <sys/time.h> #include <termios.h> #include <unistd.h> #include <netdb.h> #include "layer.h" #include "defs.h" #include "log.h" #include "descriptor.h" #include "prompt.h" #include "timer.h" #include "fsm.h" #include "iplist.h" #include "slcompress.h" #include "throughput.h" #include "lqr.h" #include "hdlc.h" #include "mbuf.h" #include "ncpaddr.h" #include "ip.h" #include "ipcp.h" #include "ipv6cp.h" #include "route.h" #include "command.h" #include "filter.h" #include "lcp.h" #include "ccp.h" #include "link.h" #include "mp.h" #include "radius.h" #include "auth.h" #include "async.h" #include "physical.h" #include "chat.h" #include "cbcp.h" #include "chap.h" #include "datalink.h" #include "ncp.h" #include "bundle.h" #include "proto.h" #include "iface.h" #ifndef NODES struct mschap_response { u_char ident; u_char flags; u_char lm_response[24]; u_char nt_response[24]; }; struct mschap2_response { u_char ident; u_char flags; u_char pchallenge[16]; u_char reserved[8]; u_char response[24]; }; #define AUTH_LEN 16 #define SALT_LEN 2 #endif static const char * radius_policyname(int policy) { switch(policy) { case MPPE_POLICY_ALLOWED: return "Allowed"; case MPPE_POLICY_REQUIRED: return "Required"; } return NumStr(policy, NULL, 0); } static const char * radius_typesname(int types) { switch(types) { case MPPE_TYPE_40BIT: return "40 bit"; case MPPE_TYPE_128BIT: return "128 bit"; case MPPE_TYPE_40BIT|MPPE_TYPE_128BIT: return "40 or 128 bit"; } return NumStr(types, NULL, 0); } #ifndef NODES static void demangle(struct radius *r, const void *mangled, size_t mlen, char **buf, size_t *len) { char R[AUTH_LEN]; /* variable names as per rfc2548 */ const char *S; u_char b[16]; const u_char *A, *C; MD5_CTX Context; int Slen, i, Clen, Ppos; u_char *P; if (mlen % 16 != SALT_LEN) { log_Printf(LogWARN, "Cannot interpret mangled data of length %ld\n", (u_long)mlen); *buf = NULL; *len = 0; return; } /* We need the RADIUS Request-Authenticator */ if (rad_request_authenticator(r->cx.rad, R, sizeof R) != AUTH_LEN) { log_Printf(LogWARN, "Cannot obtain the RADIUS request authenticator\n"); *buf = NULL; *len = 0; return; } 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(r->cx.rad); /* We need the RADIUS secret */ Slen = strlen(S); P = alloca(Clen); /* We derive our plaintext */ MD5Init(&Context); MD5Update(&Context, S, Slen); MD5Update(&Context, R, AUTH_LEN); 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) { log_Printf(LogWARN, "Mangled data seems to be garbage\n"); *buf = NULL; *len = 0; return; } if ((*buf = malloc(*len)) == NULL) { log_Printf(LogWARN, "demangle: Out of memory (%lu bytes)\n", (u_long)*len); *len = 0; } else memcpy(*buf, P + 1, *len); } #endif /* XXX: This should go into librarius. */ #ifndef NOINET6 static uint8_t * rad_cvt_ipv6prefix(const void *data, size_t len) { const size_t ipv6len = sizeof(struct in6_addr) + 2; uint8_t *s; if (len > ipv6len) return NULL; s = malloc(ipv6len); if (s != NULL) { memset(s, 0, ipv6len); memcpy(s, data, len); } return s; } #endif /* * rad_continue_send_request() has given us `got' (non-zero). Deal with it. */ static void radius_Process(struct radius *r, int got) { char *argv[MAXARGS], *nuke; struct bundle *bundle; int argc, addrs, res, width; size_t len; struct ncprange dest; struct ncpaddr gw; const void *data; const char *stype; u_int32_t ipaddr, vendor; struct in_addr ip; #ifndef NOINET6 uint8_t ipv6addr[INET6_ADDRSTRLEN]; struct in6_addr ip6; #endif r->cx.fd = -1; /* Stop select()ing */ stype = r->cx.auth ? "auth" : "acct"; switch (got) { case RAD_ACCESS_ACCEPT: log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, "Radius(%s): ACCEPT received\n", stype); if (!r->cx.auth) { rad_close(r->cx.rad); return; } break; case RAD_ACCESS_REJECT: log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, "Radius(%s): REJECT received\n", stype); if (!r->cx.auth) { rad_close(r->cx.rad); return; } break; case RAD_ACCESS_CHALLENGE: /* we can't deal with this (for now) ! */ log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, "Radius: CHALLENGE received (can't handle yet)\n"); if (r->cx.auth) auth_Failure(r->cx.auth); rad_close(r->cx.rad); return; case RAD_ACCOUNTING_RESPONSE: /* * It's probably not ideal to log this at PHASE level as we'll see * too much stuff going to the log when ``set rad_alive'' is used. * So we differ from older behaviour (ppp version 3.1 and before) * and just log accounting responses to LogRADIUS. */ log_Printf(LogRADIUS, "Radius(%s): Accounting response received\n", stype); if (r->cx.auth) auth_Failure(r->cx.auth); /* unexpected !!! */ /* No further processing for accounting requests, please */ rad_close(r->cx.rad); return; case -1: log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, "radius(%s): %s\n", stype, rad_strerror(r->cx.rad)); if (r->cx.auth) auth_Failure(r->cx.auth); rad_close(r->cx.rad); return; default: log_Printf(LogERROR, "rad_send_request(%s): Failed %d: %s\n", stype, got, rad_strerror(r->cx.rad)); if (r->cx.auth) auth_Failure(r->cx.auth); rad_close(r->cx.rad); return; } /* Let's see what we've got in our reply */ r->ip.s_addr = r->mask.s_addr = INADDR_NONE; r->mtu = 0; r->vj = 0; while ((res = rad_get_attr(r->cx.rad, &data, &len)) > 0) { switch (res) { case RAD_FRAMED_IP_ADDRESS: r->ip = rad_cvt_addr(data); log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " IP %s\n", inet_ntoa(r->ip)); break; case RAD_FILTER_ID: free(r->filterid); if ((r->filterid = rad_cvt_string(data, len)) == NULL) { log_Printf(LogERROR, "rad_cvt_string: %s\n", rad_strerror(r->cx.rad)); auth_Failure(r->cx.auth); rad_close(r->cx.rad); return; } log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " Filter \"%s\"\n", r->filterid); break; case RAD_SESSION_TIMEOUT: r->sessiontime = rad_cvt_int(data); log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " Session-Timeout %lu\n", r->sessiontime); break; case RAD_FRAMED_IP_NETMASK: r->mask = rad_cvt_addr(data); log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " Netmask %s\n", inet_ntoa(r->mask)); break; case RAD_FRAMED_MTU: r->mtu = rad_cvt_int(data); log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " MTU %lu\n", r->mtu); break; case RAD_FRAMED_ROUTING: /* Disabled for now - should we automatically set up some filters ? */ /* rad_cvt_int(data); */ /* bit 1 = Send routing packets */ /* bit 2 = Receive routing packets */ break; case RAD_FRAMED_COMPRESSION: r->vj = rad_cvt_int(data) == 1 ? 1 : 0; log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " VJ %sabled\n", r->vj ? "en" : "dis"); break; case RAD_FRAMED_ROUTE: /* * We expect a string of the format ``dest[/bits] gw [metrics]'' * Any specified metrics are ignored. MYADDR and HISADDR are * understood for ``dest'' and ``gw'' and ``0.0.0.0'' is the same * as ``HISADDR''. */ if ((nuke = rad_cvt_string(data, len)) == NULL) { log_Printf(LogERROR, "rad_cvt_string: %s\n", rad_strerror(r->cx.rad)); auth_Failure(r->cx.auth); rad_close(r->cx.rad); return; } log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " Route: %s\n", nuke); bundle = r->cx.auth->physical->dl->bundle; ip.s_addr = INADDR_ANY; ncpaddr_setip4(&gw, ip); ncprange_setip4host(&dest, ip); argc = command_Interpret(nuke, strlen(nuke), argv); if (argc < 0) log_Printf(LogWARN, "radius: %s: Syntax error\n", argc == 1 ? argv[0] : "\"\""); else if (argc < 2) log_Printf(LogWARN, "radius: %s: Invalid route\n", argc == 1 ? argv[0] : "\"\""); else if ((strcasecmp(argv[0], "default") != 0 && !ncprange_aton(&dest, &bundle->ncp, argv[0])) || !ncpaddr_aton(&gw, &bundle->ncp, argv[1])) log_Printf(LogWARN, "radius: %s %s: Invalid route\n", argv[0], argv[1]); else { ncprange_getwidth(&dest, &width); if (width == 32 && strchr(argv[0], '/') == NULL) { /* No mask specified - use the natural mask */ ncprange_getip4addr(&dest, &ip); ncprange_setip4mask(&dest, addr2mask(ip)); } addrs = 0; if (!strncasecmp(argv[0], "HISADDR", 7)) addrs = ROUTE_DSTHISADDR; else if (!strncasecmp(argv[0], "MYADDR", 6)) addrs = ROUTE_DSTMYADDR; if (ncpaddr_getip4addr(&gw, &ipaddr) && ipaddr == INADDR_ANY) { addrs |= ROUTE_GWHISADDR; ncpaddr_setip4(&gw, bundle->ncp.ipcp.peer_ip); } else if (strcasecmp(argv[1], "HISADDR") == 0) addrs |= ROUTE_GWHISADDR; route_Add(&r->routes, addrs, &dest, &gw); } free(nuke); break; case RAD_REPLY_MESSAGE: free(r->repstr); if ((r->repstr = rad_cvt_string(data, len)) == NULL) { log_Printf(LogERROR, "rad_cvt_string: %s\n", rad_strerror(r->cx.rad)); auth_Failure(r->cx.auth); rad_close(r->cx.rad); return; } log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " Reply-Message \"%s\"\n", r->repstr); break; #ifndef NOINET6 case RAD_FRAMED_IPV6_PREFIX: free(r->ipv6prefix); if ((r->ipv6prefix = rad_cvt_ipv6prefix(data, len)) == NULL) { log_Printf(LogERROR, "rad_cvt_ipv6prefix: %s\n", "Malformed attribute in response"); auth_Failure(r->cx.auth); rad_close(r->cx.rad); return; } inet_ntop(AF_INET6, &r->ipv6prefix[2], ipv6addr, sizeof(ipv6addr)); log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " IPv6 %s/%d\n", ipv6addr, r->ipv6prefix[1]); break; case RAD_FRAMED_IPV6_ROUTE: /* * We expect a string of the format ``dest[/bits] gw [metrics]'' * Any specified metrics are ignored. MYADDR6 and HISADDR6 are * understood for ``dest'' and ``gw'' and ``::'' is the same * as ``HISADDR6''. */ if ((nuke = rad_cvt_string(data, len)) == NULL) { log_Printf(LogERROR, "rad_cvt_string: %s\n", rad_strerror(r->cx.rad)); auth_Failure(r->cx.auth); rad_close(r->cx.rad); return; } log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " IPv6 Route: %s\n", nuke); bundle = r->cx.auth->physical->dl->bundle; ncpaddr_setip6(&gw, &in6addr_any); ncprange_set(&dest, &gw, 0); argc = command_Interpret(nuke, strlen(nuke), argv); if (argc < 0) log_Printf(LogWARN, "radius: %s: Syntax error\n", argc == 1 ? argv[0] : "\"\""); else if (argc < 2) log_Printf(LogWARN, "radius: %s: Invalid route\n", argc == 1 ? argv[0] : "\"\""); else if ((strcasecmp(argv[0], "default") != 0 && !ncprange_aton(&dest, &bundle->ncp, argv[0])) || !ncpaddr_aton(&gw, &bundle->ncp, argv[1])) log_Printf(LogWARN, "radius: %s %s: Invalid route\n", argv[0], argv[1]); else { addrs = 0; if (!strncasecmp(argv[0], "HISADDR6", 8)) addrs = ROUTE_DSTHISADDR6; else if (!strncasecmp(argv[0], "MYADDR6", 7)) addrs = ROUTE_DSTMYADDR6; if (ncpaddr_getip6(&gw, &ip6) && IN6_IS_ADDR_UNSPECIFIED(&ip6)) { addrs |= ROUTE_GWHISADDR6; ncpaddr_copy(&gw, &bundle->ncp.ipv6cp.hisaddr); } else if (strcasecmp(argv[1], "HISADDR6") == 0) addrs |= ROUTE_GWHISADDR6; route_Add(&r->ipv6routes, addrs, &dest, &gw); } free(nuke); break; #endif case RAD_VENDOR_SPECIFIC: if ((res = rad_get_vendor_attr(&vendor, &data, &len)) <= 0) { log_Printf(LogERROR, "rad_get_vendor_attr: %s (failing!)\n", rad_strerror(r->cx.rad)); auth_Failure(r->cx.auth); rad_close(r->cx.rad); return; } switch (vendor) { case RAD_VENDOR_MICROSOFT: switch (res) { #ifndef NODES case RAD_MICROSOFT_MS_CHAP_ERROR: free(r->errstr); if (len == 0) r->errstr = NULL; else { if (len < 3 || ((const char *)data)[1] != '=') { /* * Only point at the String field if we don't think the * peer has misformatted the response. */ data = (const char *)data + 1; len--; } else log_Printf(LogWARN, "Warning: The MS-CHAP-Error " "attribute is mis-formatted. Compensating\n"); if ((r->errstr = rad_cvt_string((const char *)data, len)) == NULL) { log_Printf(LogERROR, "rad_cvt_string: %s\n", rad_strerror(r->cx.rad)); auth_Failure(r->cx.auth); rad_close(r->cx.rad); return; } log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " MS-CHAP-Error \"%s\"\n", r->errstr); } break; case RAD_MICROSOFT_MS_CHAP2_SUCCESS: free(r->msrepstr); if (len == 0) r->msrepstr = NULL; else { if (len < 3 || ((const char *)data)[1] != '=') { /* * Only point at the String field if we don't think the * peer has misformatted the response. */ data = (const char *)data + 1; len--; } else log_Printf(LogWARN, "Warning: The MS-CHAP2-Success " "attribute is mis-formatted. Compensating\n"); if ((r->msrepstr = rad_cvt_string((const char *)data, len)) == NULL) { log_Printf(LogERROR, "rad_cvt_string: %s\n", rad_strerror(r->cx.rad)); auth_Failure(r->cx.auth); rad_close(r->cx.rad); return; } log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " MS-CHAP2-Success \"%s\"\n", r->msrepstr); } break; case RAD_MICROSOFT_MS_MPPE_ENCRYPTION_POLICY: r->mppe.policy = rad_cvt_int(data); log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " MS-MPPE-Encryption-Policy %s\n", radius_policyname(r->mppe.policy)); break; case RAD_MICROSOFT_MS_MPPE_ENCRYPTION_TYPES: r->mppe.types = rad_cvt_int(data); log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " MS-MPPE-Encryption-Types %s\n", radius_typesname(r->mppe.types)); break; case RAD_MICROSOFT_MS_MPPE_RECV_KEY: free(r->mppe.recvkey); demangle(r, data, len, &r->mppe.recvkey, &r->mppe.recvkeylen); log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " MS-MPPE-Recv-Key ********\n"); break; case RAD_MICROSOFT_MS_MPPE_SEND_KEY: demangle(r, data, len, &r->mppe.sendkey, &r->mppe.sendkeylen); log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, " MS-MPPE-Send-Key ********\n"); break; #endif default: log_Printf(LogDEBUG, "Dropping MICROSOFT vendor specific " "RADIUS attribute %d\n", res); break; } break; default: log_Printf(LogDEBUG, "Dropping vendor %lu RADIUS attribute %d\n", (unsigned long)vendor, res); break; } break; default: log_Printf(LogDEBUG, "Dropping RADIUS attribute %d\n", res); break; } } if (res == -1) { log_Printf(LogERROR, "rad_get_attr: %s (failing!)\n", rad_strerror(r->cx.rad)); auth_Failure(r->cx.auth); } else if (got == RAD_ACCESS_REJECT) auth_Failure(r->cx.auth); else { r->valid = 1; auth_Success(r->cx.auth); } rad_close(r->cx.rad); } /* * We've either timed out or select()ed on the read descriptor */ static void radius_Continue(struct radius *r, int sel) { struct timeval tv; int got; timer_Stop(&r->cx.timer); if ((got = rad_continue_send_request(r->cx.rad, sel, &r->cx.fd, &tv)) == 0) { log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, "Radius: Request re-sent\n"); r->cx.timer.load = tv.tv_usec / TICKUNIT + tv.tv_sec * SECTICKS; timer_Start(&r->cx.timer); return; } radius_Process(r, got); } /* * Time to call rad_continue_send_request() - timed out. */ static void radius_Timeout(void *v) { radius_Continue((struct radius *)v, 0); } /* * Time to call rad_continue_send_request() - something to read. */ static void radius_Read(struct fdescriptor *d, struct bundle *bundle __unused, const fd_set *fdset __unused) { radius_Continue(descriptor2radius(d), 1); } /* * Flush any pending transactions */ void radius_Flush(struct radius *r) { struct timeval tv; fd_set s; while (r->cx.fd != -1) { FD_ZERO(&s); FD_SET(r->cx.fd, &s); tv.tv_sec = 0; tv.tv_usec = TICKUNIT; select(r->cx.fd + 1, &s, NULL, NULL, &tv); radius_Continue(r, 1); } } /* * Behave as a struct fdescriptor (descriptor.h) */ static int radius_UpdateSet(struct fdescriptor *d, fd_set *r, fd_set *w __unused, fd_set *e __unused, int *n) { struct radius *rad = descriptor2radius(d); if (r && rad->cx.fd != -1) { FD_SET(rad->cx.fd, r); if (*n < rad->cx.fd + 1) *n = rad->cx.fd + 1; log_Printf(LogTIMER, "Radius: fdset(r) %d\n", rad->cx.fd); return 1; } return 0; } /* * Behave as a struct fdescriptor (descriptor.h) */ static int radius_IsSet(struct fdescriptor *d, const fd_set *fdset) { struct radius *r = descriptor2radius(d); return r && r->cx.fd != -1 && FD_ISSET(r->cx.fd, fdset); } /* * Behave as a struct fdescriptor (descriptor.h) */ static int radius_Write(struct fdescriptor *d __unused, struct bundle *bundle __unused, const fd_set *fdset __unused) { /* We never want to write here ! */ log_Printf(LogALERT, "radius_Write: Internal error: Bad call !\n"); return 0; } /* * Initialise ourselves */ void radius_Init(struct radius *r) { r->desc.type = RADIUS_DESCRIPTOR; r->desc.UpdateSet = radius_UpdateSet; r->desc.IsSet = radius_IsSet; r->desc.Read = radius_Read; r->desc.Write = radius_Write; r->cx.fd = -1; r->cx.rad = NULL; memset(&r->cx.timer, '\0', sizeof r->cx.timer); r->cx.auth = NULL; r->valid = 0; r->vj = 0; r->ip.s_addr = INADDR_ANY; r->mask.s_addr = INADDR_NONE; r->routes = NULL; r->mtu = DEF_MTU; r->msrepstr = NULL; r->repstr = NULL; #ifndef NOINET6 r->ipv6prefix = NULL; r->ipv6routes = NULL; #endif r->errstr = NULL; r->mppe.policy = 0; r->mppe.types = 0; r->mppe.recvkey = NULL; r->mppe.recvkeylen = 0; r->mppe.sendkey = NULL; r->mppe.sendkeylen = 0; *r->cfg.file = '\0';; log_Printf(LogDEBUG, "Radius: radius_Init\n"); } /* * Forget everything and go back to initialised state. */ void radius_Destroy(struct radius *r) { r->valid = 0; log_Printf(LogDEBUG, "Radius: radius_Destroy\n"); timer_Stop(&r->cx.timer); route_DeleteAll(&r->routes); #ifndef NOINET6 route_DeleteAll(&r->ipv6routes); #endif free(r->filterid); r->filterid = NULL; free(r->msrepstr); r->msrepstr = NULL; free(r->repstr); r->repstr = NULL; #ifndef NOINET6 free(r->ipv6prefix); r->ipv6prefix = NULL; #endif free(r->errstr); r->errstr = NULL; free(r->mppe.recvkey); r->mppe.recvkey = NULL; r->mppe.recvkeylen = 0; free(r->mppe.sendkey); r->mppe.sendkey = NULL; r->mppe.sendkeylen = 0; if (r->cx.fd != -1) { r->cx.fd = -1; rad_close(r->cx.rad); } } static int radius_put_physical_details(struct radius *rad, struct physical *p) { int slot, type; type = RAD_VIRTUAL; if (p->handler) switch (p->handler->type) { case I4B_DEVICE: type = RAD_ISDN_SYNC; break; case TTY_DEVICE: type = RAD_ASYNC; break; case ETHER_DEVICE: type = RAD_ETHERNET; break; case TCP_DEVICE: case UDP_DEVICE: case EXEC_DEVICE: case ATM_DEVICE: case NG_DEVICE: type = RAD_VIRTUAL; break; } if (rad_put_int(rad->cx.rad, RAD_NAS_PORT_TYPE, type) != 0) { log_Printf(LogERROR, "rad_put: rad_put_int: %s\n", rad_strerror(rad->cx.rad)); rad_close(rad->cx.rad); return 0; } switch (rad->port_id_type) { case RPI_PID: slot = (int)getpid(); break; case RPI_IFNUM: slot = p->dl->bundle->iface->index; break; case RPI_TUNNUM: slot = p->dl->bundle->unit; break; case RPI_DEFAULT: default: slot = physical_Slot(p); break; } if (slot >= 0) if (rad_put_int(rad->cx.rad, RAD_NAS_PORT, slot) != 0) { log_Printf(LogERROR, "rad_put: rad_put_int: %s\n", rad_strerror(rad->cx.rad)); rad_close(rad->cx.rad); return 0; } return 1; } /* * Start an authentication request to the RADIUS server. */ int radius_Authenticate(struct radius *r, struct authinfo *authp, const char *name, const char *key, int klen, const char *nchallenge, int nclen) { char hostname[MAXHOSTNAMELEN]; struct timeval tv; const char *what = "questionable"; /* silence warnings! */ char *mac_addr; int got; struct hostent *hp; struct in_addr hostaddr; #ifndef NODES struct mschap_response msresp; struct mschap2_response msresp2; const struct MSCHAPv2_resp *keyv2; #endif if (!*r->cfg.file) return 0; if (r->cx.fd != -1) /* * We assume that our name/key/challenge is the same as last time, * and just continue to wait for the RADIUS server(s). */ return 1; radius_Destroy(r); if ((r->cx.rad = rad_auth_open()) == NULL) { log_Printf(LogERROR, "rad_auth_open: %s\n", strerror(errno)); return 0; } if (rad_config(r->cx.rad, r->cfg.file) != 0) { log_Printf(LogERROR, "rad_config: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return 0; } if (rad_create_request(r->cx.rad, RAD_ACCESS_REQUEST) != 0) { log_Printf(LogERROR, "rad_create_request: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return 0; } if (rad_put_string(r->cx.rad, RAD_USER_NAME, name) != 0 || rad_put_int(r->cx.rad, RAD_SERVICE_TYPE, RAD_FRAMED) != 0 || rad_put_int(r->cx.rad, RAD_FRAMED_PROTOCOL, RAD_PPP) != 0) { log_Printf(LogERROR, "rad_put: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return 0; } switch (authp->physical->link.lcp.want_auth) { case PROTO_PAP: /* We're talking PAP */ if (rad_put_attr(r->cx.rad, RAD_USER_PASSWORD, key, klen) != 0) { log_Printf(LogERROR, "PAP: rad_put_string: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return 0; } what = "PAP"; break; case PROTO_CHAP: switch (authp->physical->link.lcp.want_authtype) { case 0x5: if (rad_put_attr(r->cx.rad, RAD_CHAP_PASSWORD, key, klen) != 0 || rad_put_attr(r->cx.rad, RAD_CHAP_CHALLENGE, nchallenge, nclen) != 0) { log_Printf(LogERROR, "CHAP: rad_put_string: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return 0; } what = "CHAP"; break; #ifndef NODES case 0x80: if (klen != 50) { log_Printf(LogERROR, "CHAP80: Unrecognised key length %d\n", klen); rad_close(r->cx.rad); return 0; } rad_put_vendor_attr(r->cx.rad, RAD_VENDOR_MICROSOFT, RAD_MICROSOFT_MS_CHAP_CHALLENGE, nchallenge, nclen); msresp.ident = *key; msresp.flags = 0x01; memcpy(msresp.lm_response, key + 1, 24); memcpy(msresp.nt_response, key + 25, 24); rad_put_vendor_attr(r->cx.rad, RAD_VENDOR_MICROSOFT, RAD_MICROSOFT_MS_CHAP_RESPONSE, &msresp, sizeof msresp); what = "MSCHAP"; break; case 0x81: if (klen != sizeof(*keyv2) + 1) { log_Printf(LogERROR, "CHAP81: Unrecognised key length %d\n", klen); rad_close(r->cx.rad); return 0; } keyv2 = (const struct MSCHAPv2_resp *)(key + 1); rad_put_vendor_attr(r->cx.rad, RAD_VENDOR_MICROSOFT, RAD_MICROSOFT_MS_CHAP_CHALLENGE, nchallenge, nclen); msresp2.ident = *key; msresp2.flags = keyv2->Flags; memcpy(msresp2.response, keyv2->NTResponse, sizeof msresp2.response); memset(msresp2.reserved, '\0', sizeof msresp2.reserved); memcpy(msresp2.pchallenge, keyv2->PeerChallenge, sizeof msresp2.pchallenge); rad_put_vendor_attr(r->cx.rad, RAD_VENDOR_MICROSOFT, RAD_MICROSOFT_MS_CHAP2_RESPONSE, &msresp2, sizeof msresp2); what = "MSCHAPv2"; break; #endif default: log_Printf(LogERROR, "CHAP: Unrecognised type 0x%02x\n", authp->physical->link.lcp.want_authtype); rad_close(r->cx.rad); return 0; } } if (gethostname(hostname, sizeof hostname) != 0) log_Printf(LogERROR, "rad_put: gethostname(): %s\n", strerror(errno)); else { if (Enabled(authp->physical->dl->bundle, OPT_NAS_IP_ADDRESS) && (hp = gethostbyname(hostname)) != NULL) { hostaddr.s_addr = *(u_long *)hp->h_addr; if (rad_put_addr(r->cx.rad, RAD_NAS_IP_ADDRESS, hostaddr) != 0) { log_Printf(LogERROR, "rad_put: rad_put_string: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return 0; } } if (Enabled(authp->physical->dl->bundle, OPT_NAS_IDENTIFIER) && rad_put_string(r->cx.rad, RAD_NAS_IDENTIFIER, hostname) != 0) { log_Printf(LogERROR, "rad_put: rad_put_string: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return 0; } } if ((mac_addr = getenv("HISMACADDR")) != NULL && rad_put_string(r->cx.rad, RAD_CALLING_STATION_ID, mac_addr) != 0) { log_Printf(LogERROR, "rad_put: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return 0; } radius_put_physical_details(r, authp->physical); log_Printf(LogRADIUS, "Radius(auth): %s data sent for %s\n", what, name); r->cx.auth = authp; if ((got = rad_init_send_request(r->cx.rad, &r->cx.fd, &tv))) radius_Process(r, got); else { log_Printf(log_IsKept(LogRADIUS) ? LogRADIUS : LogPHASE, "Radius: Request sent\n"); log_Printf(LogDEBUG, "Using radius_Timeout [%p]\n", radius_Timeout); r->cx.timer.load = tv.tv_usec / TICKUNIT + tv.tv_sec * SECTICKS; r->cx.timer.func = radius_Timeout; r->cx.timer.name = "radius auth"; r->cx.timer.arg = r; timer_Start(&r->cx.timer); } return 1; } /* Fetch IP, netmask from IPCP */ void radius_Account_Set_Ip(struct radacct *ac, struct in_addr *peer_ip, struct in_addr *netmask) { ac->proto = PROTO_IPCP; memcpy(&ac->peer.ip.addr, peer_ip, sizeof(ac->peer.ip.addr)); memcpy(&ac->peer.ip.mask, netmask, sizeof(ac->peer.ip.mask)); } #ifndef NOINET6 /* Fetch interface-id from IPV6CP */ void radius_Account_Set_Ipv6(struct radacct *ac, u_char *ifid) { ac->proto = PROTO_IPV6CP; memcpy(&ac->peer.ipv6.ifid, ifid, sizeof(ac->peer.ipv6.ifid)); } #endif /* * Send an accounting request to the RADIUS server */ void radius_Account(struct radius *r, struct radacct *ac, struct datalink *dl, int acct_type, struct pppThroughput *stats) { struct timeval tv; int got; char hostname[MAXHOSTNAMELEN]; char *mac_addr; struct hostent *hp; struct in_addr hostaddr; if (!*r->cfg.file) return; if (r->cx.fd != -1) /* * We assume that our name/key/challenge is the same as last time, * and just continue to wait for the RADIUS server(s). */ return; timer_Stop(&r->cx.timer); if ((r->cx.rad = rad_acct_open()) == NULL) { log_Printf(LogERROR, "rad_auth_open: %s\n", strerror(errno)); return; } if (rad_config(r->cx.rad, r->cfg.file) != 0) { log_Printf(LogERROR, "rad_config: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return; } if (rad_create_request(r->cx.rad, RAD_ACCOUNTING_REQUEST) != 0) { log_Printf(LogERROR, "rad_create_request: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return; } /* Grab some accounting data and initialize structure */ if (acct_type == RAD_START) { ac->rad_parent = r; /* Fetch username from datalink */ strncpy(ac->user_name, dl->peer.authname, sizeof ac->user_name); ac->user_name[AUTHLEN-1] = '\0'; ac->authentic = 2; /* Assume RADIUS verified auth data */ /* Generate a session ID */ snprintf(ac->session_id, sizeof ac->session_id, "%s%ld-%s%lu", dl->bundle->cfg.auth.name, (long)getpid(), dl->peer.authname, (unsigned long)stats->uptime); /* And grab our MP socket name */ snprintf(ac->multi_session_id, sizeof ac->multi_session_id, "%s", dl->bundle->ncp.mp.active ? dl->bundle->ncp.mp.server.socket.sun_path : ""); }; if (rad_put_string(r->cx.rad, RAD_USER_NAME, ac->user_name) != 0 || rad_put_int(r->cx.rad, RAD_SERVICE_TYPE, RAD_FRAMED) != 0 || rad_put_int(r->cx.rad, RAD_FRAMED_PROTOCOL, RAD_PPP) != 0) { log_Printf(LogERROR, "rad_put: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return; } switch (ac->proto) { case PROTO_IPCP: if (rad_put_addr(r->cx.rad, RAD_FRAMED_IP_ADDRESS, ac->peer.ip.addr) != 0 || rad_put_addr(r->cx.rad, RAD_FRAMED_IP_NETMASK, ac->peer.ip.mask) != 0) { log_Printf(LogERROR, "rad_put: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return; } break; #ifndef NOINET6 case PROTO_IPV6CP: if (rad_put_attr(r->cx.rad, RAD_FRAMED_INTERFACE_ID, ac->peer.ipv6.ifid, sizeof(ac->peer.ipv6.ifid)) != 0) { log_Printf(LogERROR, "rad_put_attr: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return; } if (r->ipv6prefix) { /* * Since PPP doesn't delegate an IPv6 prefix to a peer, * Framed-IPv6-Prefix may be not used, actually. */ if (rad_put_attr(r->cx.rad, RAD_FRAMED_IPV6_PREFIX, r->ipv6prefix, sizeof(struct in6_addr) + 2) != 0) { log_Printf(LogERROR, "rad_put_attr: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return; } } break; #endif default: /* We don't log any protocol specific information */ break; } if ((mac_addr = getenv("HISMACADDR")) != NULL && rad_put_string(r->cx.rad, RAD_CALLING_STATION_ID, mac_addr) != 0) { log_Printf(LogERROR, "rad_put: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return; } if (gethostname(hostname, sizeof hostname) != 0) log_Printf(LogERROR, "rad_put: gethostname(): %s\n", strerror(errno)); else { if (Enabled(dl->bundle, OPT_NAS_IP_ADDRESS) && (hp = gethostbyname(hostname)) != NULL) { hostaddr.s_addr = *(u_long *)hp->h_addr; if (rad_put_addr(r->cx.rad, RAD_NAS_IP_ADDRESS, hostaddr) != 0) { log_Printf(LogERROR, "rad_put: rad_put_string: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return; } } if (Enabled(dl->bundle, OPT_NAS_IDENTIFIER) && rad_put_string(r->cx.rad, RAD_NAS_IDENTIFIER, hostname) != 0) { log_Printf(LogERROR, "rad_put: rad_put_string: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return; } } radius_put_physical_details(r, dl->physical); if (rad_put_int(r->cx.rad, RAD_ACCT_STATUS_TYPE, acct_type) != 0 || rad_put_string(r->cx.rad, RAD_ACCT_SESSION_ID, ac->session_id) != 0 || rad_put_string(r->cx.rad, RAD_ACCT_MULTI_SESSION_ID, ac->multi_session_id) != 0 || rad_put_int(r->cx.rad, RAD_ACCT_DELAY_TIME, 0) != 0) { /* XXX ACCT_DELAY_TIME should be increased each time a packet is waiting */ log_Printf(LogERROR, "rad_put: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return; } if (acct_type == RAD_STOP || acct_type == RAD_ALIVE) /* Show some statistics */ if (rad_put_int(r->cx.rad, RAD_ACCT_INPUT_OCTETS, stats->OctetsIn % UINT32_MAX) != 0 || rad_put_int(r->cx.rad, RAD_ACCT_INPUT_GIGAWORDS, stats->OctetsIn / UINT32_MAX) != 0 || rad_put_int(r->cx.rad, RAD_ACCT_INPUT_PACKETS, stats->PacketsIn) != 0 || rad_put_int(r->cx.rad, RAD_ACCT_OUTPUT_OCTETS, stats->OctetsOut % UINT32_MAX) != 0 || rad_put_int(r->cx.rad, RAD_ACCT_OUTPUT_GIGAWORDS, stats->OctetsOut / UINT32_MAX) != 0 || rad_put_int(r->cx.rad, RAD_ACCT_OUTPUT_PACKETS, stats->PacketsOut) != 0 || rad_put_int(r->cx.rad, RAD_ACCT_SESSION_TIME, throughput_uptime(stats)) != 0) { log_Printf(LogERROR, "rad_put: %s\n", rad_strerror(r->cx.rad)); rad_close(r->cx.rad); return; } if (log_IsKept(LogPHASE) || log_IsKept(LogRADIUS)) { const char *what; int level; switch (acct_type) { case RAD_START: what = "START"; level = log_IsKept(LogPHASE) ? LogPHASE : LogRADIUS; break; case RAD_STOP: what = "STOP"; level = log_IsKept(LogPHASE) ? LogPHASE : LogRADIUS; break; case RAD_ALIVE: what = "ALIVE"; level = LogRADIUS; break; default: what = "<unknown>"; level = log_IsKept(LogPHASE) ? LogPHASE : LogRADIUS; break; } log_Printf(level, "Radius(acct): %s data sent\n", what); } r->cx.auth = NULL; /* Not valid for accounting requests */ if ((got = rad_init_send_request(r->cx.rad, &r->cx.fd, &tv))) radius_Process(r, got); else { log_Printf(LogDEBUG, "Using radius_Timeout [%p]\n", radius_Timeout); r->cx.timer.load = tv.tv_usec / TICKUNIT + tv.tv_sec * SECTICKS; r->cx.timer.func = radius_Timeout; r->cx.timer.name = "radius acct"; r->cx.timer.arg = r; timer_Start(&r->cx.timer); } } /* * How do things look at the moment ? */ void radius_Show(struct radius *r, struct prompt *p) { prompt_Printf(p, " Radius config: %s", *r->cfg.file ? r->cfg.file : "none"); if (r->valid) { prompt_Printf(p, "\n IP: %s\n", inet_ntoa(r->ip)); prompt_Printf(p, " Netmask: %s\n", inet_ntoa(r->mask)); prompt_Printf(p, " MTU: %lu\n", r->mtu); prompt_Printf(p, " VJ: %sabled\n", r->vj ? "en" : "dis"); prompt_Printf(p, " Message: %s\n", r->repstr ? r->repstr : ""); prompt_Printf(p, " MPPE Enc Policy: %s\n", radius_policyname(r->mppe.policy)); prompt_Printf(p, " MPPE Enc Types: %s\n", radius_typesname(r->mppe.types)); prompt_Printf(p, " MPPE Recv Key: %seceived\n", r->mppe.recvkey ? "R" : "Not r"); prompt_Printf(p, " MPPE Send Key: %seceived\n", r->mppe.sendkey ? "R" : "Not r"); prompt_Printf(p, " MS-CHAP2-Response: %s\n", r->msrepstr ? r->msrepstr : ""); prompt_Printf(p, " Error Message: %s\n", r->errstr ? r->errstr : ""); if (r->routes) route_ShowSticky(p, r->routes, " Routes", 16); #ifndef NOINET6 if (r->ipv6routes) route_ShowSticky(p, r->ipv6routes, " IPv6 Routes", 16); #endif } else prompt_Printf(p, " (not authenticated)\n"); } static void radius_alive(void *v) { struct bundle *bundle = (struct bundle *)v; timer_Stop(&bundle->radius.alive.timer); bundle->radius.alive.timer.load = bundle->radius.alive.interval * SECTICKS; if (bundle->radius.alive.timer.load) { radius_Account(&bundle->radius, &bundle->radacct, bundle->links, RAD_ALIVE, &bundle->ncp.ipcp.throughput); timer_Start(&bundle->radius.alive.timer); } } void radius_StartTimer(struct bundle *bundle) { if (bundle->radius.cfg.file && bundle->radius.alive.interval) { bundle->radius.alive.timer.func = radius_alive; bundle->radius.alive.timer.name = "radius alive"; bundle->radius.alive.timer.load = bundle->radius.alive.interval * SECTICKS; bundle->radius.alive.timer.arg = bundle; radius_alive(bundle); } } void radius_StopTimer(struct radius *r) { timer_Stop(&r->alive.timer); }