libpurple/protocols/zephyr/Zinternal.c@56e1a1a5af0b
libpurple/protocols/zephyr/Zinternal.c
Mon, 23 Nov 2020 01:51:33 -0600
- author
- Elliott Sales de Andrade <quantum.analyst@gmail.com>
- date
- Mon, 23 Nov 2020 01:51:33 -0600
- changeset 40625
- 56e1a1a5af0b
- parent 40624
- 6f7bbd42d36c
- child 40628
- 4266008a7791
- permissions
- -rw-r--r--
Use a GSList for Zephyr hole list.
Testing Done:
Compile only.
Reviewed at https://reviews.imfreedom.org/r/250/
/* This file is part of the Project Athena Zephyr Notification System. * It contains source for the internal Zephyr routines. * * Created by: Robert French * * Copyright (c) 1987,1988,1991 by the Massachusetts Institute of * Technology. * For copying and distribution information, see the file * "mit-copyright.h". */ #include "internal.h" #ifdef WIN32 #include <winsock2.h> #else #include <arpa/inet.h> #include <sys/socket.h> #endif int __Zephyr_fd = -1; int __Zephyr_port = -1; struct in_addr __My_addr; int __Q_CompleteLength; int __Q_Size; struct _Z_InputQ *__Q_Head, *__Q_Tail; struct sockaddr_in __HM_addr; struct sockaddr_in __HM_addr_real; ZLocations_t *__locate_list; int __locate_num; int __locate_next; ZSubscription_t *__subscriptions_list; int __subscriptions_num; int __subscriptions_next; int Z_discarded_packets = 0; #ifdef ZEPHYR_USES_KERBEROS C_Block __Zephyr_session; #endif char __Zephyr_realm[REALM_SZ]; static int Z_AddField(char **ptr, const char *field, char *end); static int find_or_insert_uid(ZUnique_Id_t *uid, ZNotice_Kind_t kind); /* Find or insert uid in the old uids buffer. The buffer is a sorted * circular queue. We make the assumption that most packets arrive in * order, so we can usually search for a uid or insert it into the buffer * by looking back just a few entries from the end. Since this code is * only executed by the client, the implementation isn't microoptimized. */ static int find_or_insert_uid(ZUnique_Id_t *uid, ZNotice_Kind_t kind) { static struct _filter { ZUnique_Id_t uid; ZNotice_Kind_t kind; time_t t; } *buffer; static long size; static long start; static long num; time_t now; struct _filter *new; long i, j, new_size; int result; /* Initialize the uid buffer if it hasn't been done already. */ if (!buffer) { size = Z_INITFILTERSIZE; buffer = (struct _filter *) malloc(size * sizeof(*buffer)); if (!buffer) return 0; } /* Age the uid buffer, discarding any uids older than the clock skew. */ time(&now); while (num && (now - buffer[start % size].t) > CLOCK_SKEW) start++, num--; start %= size; /* Make room for a new uid, since we'll probably have to insert one. */ if (num == size) { new_size = size * 2 + 2; new = (struct _filter *) malloc(new_size * sizeof(*new)); if (!new) return 0; for (i = 0; i < num; i++) new[i] = buffer[(start + i) % size]; free(buffer); buffer = new; size = new_size; start = 0; } /* Search for this uid in the buffer, starting from the end. */ for (i = start + num - 1; i >= start; i--) { result = memcmp(uid, &buffer[i % size].uid, sizeof(*uid)); if (result == 0 && buffer[i % size].kind == kind) return 1; if (result > 0) break; } /* We didn't find it; insert the uid into the buffer after i. */ i++; for (j = start + num; j > i; j--) buffer[j % size] = buffer[(j - 1) % size]; buffer[i % size].uid = *uid; buffer[i % size].kind = kind; buffer[i % size].t = now; num++; return 0; } /* Return 1 if there is a packet waiting, 0 otherwise */ static int Z_PacketWaiting(void) { struct timeval tv; fd_set read; tv.tv_sec = tv.tv_usec = 0; FD_ZERO(&read); FD_SET(ZGetFD(), &read); return (select(ZGetFD() + 1, &read, NULL, NULL, &tv)); } /* Wait for a complete notice to become available */ Code_t Z_WaitForComplete(void) { Code_t retval; if (__Q_CompleteLength) return (Z_ReadEnqueue()); while (!__Q_CompleteLength) if ((retval = Z_ReadWait()) != ZERR_NONE) return (retval); return (ZERR_NONE); } /* Read any available packets and enqueue them */ Code_t Z_ReadEnqueue(void) { Code_t retval; if (ZGetFD() < 0) return (ZERR_NOPORT); while (Z_PacketWaiting()) if ((retval = Z_ReadWait()) != ZERR_NONE) return (retval); return (ZERR_NONE); } /* * Search the queue for a notice with the proper multiuid - remove any * notices that haven't been touched in a while */ static struct _Z_InputQ *Z_SearchQueue(ZUnique_Id_t *uid, ZNotice_Kind_t kind) { register struct _Z_InputQ *qptr; struct _Z_InputQ *next; gint64 now; now = g_get_monotonic_time(); qptr = __Q_Head; while (qptr) { if (ZCompareUID(uid, &qptr->uid) && qptr->kind == kind) { return qptr; } next = qptr->next; if (qptr->time && qptr->time + Z_NOTICETIMELIMIT < now) { Z_RemQueue(qptr); } qptr = next; } return NULL; } /* * Now we delve into really convoluted queue handling and * fragmentation reassembly algorithms and other stuff you probably * don't want to look at... * * This routine does NOT guarantee a complete packet will be ready when it * returns. */ Code_t Z_ReadWait(void) { register struct _Z_InputQ *qptr; Z_Hole *hole = NULL; ZNotice_t notice; ZPacket_t packet; struct sockaddr_in olddest, from; int packet_len, zvlen, part, partof; socklen_t from_len; char *slash; Code_t retval; fd_set fds; struct timeval tv; if (ZGetFD() < 0) return (ZERR_NOPORT); FD_ZERO(&fds); FD_SET(ZGetFD(), &fds); tv.tv_sec = 60; tv.tv_usec = 0; if (select(ZGetFD() + 1, &fds, NULL, NULL, &tv) < 0) return (errno); if (!FD_ISSET(ZGetFD(), &fds)) return ETIMEDOUT; from_len = sizeof(struct sockaddr_in); packet_len = recvfrom(ZGetFD(), packet, sizeof(packet) - 1, 0, (struct sockaddr *)&from, &from_len); if (packet_len < 0) return (errno); if (!packet_len) return (ZERR_EOF); packet[packet_len] = '\0'; /* Ignore obviously non-Zephyr packets. */ zvlen = sizeof(ZVERSIONHDR) - 1; if (packet_len < zvlen || memcmp(packet, ZVERSIONHDR, zvlen) != 0) { Z_discarded_packets++; return (ZERR_NONE); } /* Parse the notice */ if ((retval = ZParseNotice(packet, packet_len, ¬ice)) != ZERR_NONE) { return retval; } /* If the notice is of an appropriate kind, send back a CLIENTACK to * whoever sent it to say we got it. */ if (notice.z_kind != HMACK && notice.z_kind != SERVACK && notice.z_kind != SERVNAK && notice.z_kind != CLIENTACK) { ZNotice_t tmpnotice; ZPacket_t pkt; int len; tmpnotice = notice; tmpnotice.z_kind = CLIENTACK; tmpnotice.z_message_len = 0; olddest = __HM_addr; __HM_addr = from; if ((retval = ZFormatSmallRawNotice(&tmpnotice, pkt, &len)) != ZERR_NONE) { return retval; } if ((retval = ZSendPacket(pkt, len, 0)) != ZERR_NONE) { return retval; } __HM_addr = olddest; } if (find_or_insert_uid(¬ice.z_uid, notice.z_kind)) { return ZERR_NONE; } /* Check authentication on the notice. */ notice.z_checked_auth = ZCheckAuthentication(¬ice, &from); /* * Parse apart the z_multinotice field - if the field is blank for * some reason, assume this packet stands by itself. */ slash = strchr(notice.z_multinotice, '/'); if (slash) { part = atoi(notice.z_multinotice); partof = atoi(slash+1); if (part > partof || partof == 0) { part = 0; partof = notice.z_message_len; } } else { part = 0; partof = notice.z_message_len; } /* Too big a packet...just ignore it! */ if (partof > Z_MAXNOTICESIZE) return (ZERR_NONE); /* If we can find a notice in the queue with the same multiuid field, * insert the current fragment as appropriate. */ switch (notice.z_kind) { case SERVACK: case SERVNAK: /* The SERVACK and SERVNAK replies shouldn't be reassembled (they have no parts). Instead, we should hold on to the reply ONLY if it's the first part of a fragmented message, i.e. multi_uid == uid. This allows programs to wait for the uid of the first packet, and get a response when that notice arrives. Acknowledgements of the other fragments are discarded (XXX we assume here that they all carry the same information regarding failure/success) */ if (!ZCompareUID(¬ice.z_multiuid, ¬ice.z_uid)) { /* they're not the same... throw away this packet. */ return(ZERR_NONE); } /* fall thru & process it */ default: /* for HMACK types, we assume no packet loss (local loopback connections). The other types can be fragmented and MUST run through this code. */ if ((qptr = Z_SearchQueue(¬ice.z_multiuid, notice.z_kind)) != NULL) { /* * If this is the first fragment, and we haven't already * gotten a first fragment, grab the header from it. */ if (part == 0 && !qptr->header) { qptr->header_len = packet_len-notice.z_message_len; qptr->header = (char *) malloc((unsigned) qptr->header_len); if (!qptr->header) return (ENOMEM); (void) memcpy(qptr->header, packet, qptr->header_len); } return (Z_AddNoticeToEntry(qptr, ¬ice, part)); } } /* We'll have to create a new entry...make sure the queue isn't going * to get too big. */ if (__Q_Size + partof > Z_MAXQUEUESIZE) { return ZERR_NONE; } /* * This is a notice we haven't heard of, so create a new queue * entry for it and zero it out. */ qptr = (struct _Z_InputQ *)malloc(sizeof(struct _Z_InputQ)); if (!qptr) return (ENOMEM); (void) memset((char *)qptr, 0, sizeof(struct _Z_InputQ)); /* Insert the entry at the end of the queue */ qptr->next = NULL; qptr->prev = __Q_Tail; if (__Q_Tail) __Q_Tail->next = qptr; __Q_Tail = qptr; if (!__Q_Head) __Q_Head = qptr; /* Copy the from field, multiuid, kind, and checked authentication. */ qptr->from = from; qptr->uid = notice.z_multiuid; qptr->kind = notice.z_kind; qptr->auth = notice.z_checked_auth; /* If this is the first part of the notice, we take the header from it. We * only take it if this is the first fragment so that the Unique ID's will * be predictable. */ if (part == 0) { qptr->header_len = packet_len-notice.z_message_len; qptr->header = (char *) malloc((unsigned) qptr->header_len); if (!qptr->header) return ENOMEM; (void) memcpy(qptr->header, packet, qptr->header_len); } /* If this is not a fragmented notice, then don't bother with a hole * list. */ if (part == 0 && notice.z_message_len == partof) { __Q_CompleteLength++; qptr->holelist = NULL; qptr->complete = 1; /* allocate a msg buf for this piece */ if (notice.z_message_len == 0) qptr->msg = 0; else if (!(qptr->msg = (char *) malloc((unsigned) notice.z_message_len))) return(ENOMEM); else (void) memcpy(qptr->msg, notice.z_message, notice.z_message_len); qptr->msg_len = notice.z_message_len; __Q_Size += notice.z_message_len; qptr->packet_len = qptr->header_len+qptr->msg_len; if (!(qptr->packet = (char *) malloc((unsigned) qptr->packet_len))) return (ENOMEM); (void) memcpy(qptr->packet, qptr->header, qptr->header_len); if(qptr->msg) (void) memcpy(qptr->packet+qptr->header_len, qptr->msg, qptr->msg_len); return (ZERR_NONE); } /* * We know how long the message is going to be (this is better * than IP fragmentation...), so go ahead and allocate it all. */ if (!(qptr->msg = (char *) malloc((unsigned) partof)) && partof) return (ENOMEM); qptr->msg_len = partof; __Q_Size += partof; /* * Well, it's a fragmented notice...allocate a hole list and * initialize it to the full packet size. Then insert the * current fragment. */ hole = g_new0(Z_Hole, 1); if (hole == NULL) { return ENOMEM; } hole->first = 0; hole->last = partof - 1; qptr->holelist = g_slist_prepend(qptr->holelist, hole); return Z_AddNoticeToEntry(qptr, ¬ice, part); } /* Fragment management routines - compliments, more or less, of RFC815 */ static gint find_hole(gconstpointer element, gconstpointer data) { Z_Hole *thishole = (Z_Hole *)element; Z_Hole *tofind = (Z_Hole *)data; if (tofind->first <= thishole->last && tofind->last >= thishole->first) { return 0; } return 1; } Code_t Z_AddNoticeToEntry(struct _Z_InputQ *qptr, ZNotice_t *notice, int part) { GSList *thishole; Z_Hole *hole; gint last; /* Incorporate this notice's checked authentication. */ if (notice->z_checked_auth == ZAUTH_FAILED) { qptr->auth = ZAUTH_FAILED; } else if (notice->z_checked_auth == ZAUTH_NO && qptr->auth != ZAUTH_FAILED) { qptr->auth = ZAUTH_NO; } qptr->time = g_get_monotonic_time(); last = part + notice->z_message_len - 1; /* copy in the message body */ (void)memcpy(qptr->msg + part, notice->z_message, notice->z_message_len); /* Search for a hole that overlaps with the current fragment */ hole = g_new(Z_Hole, 1); hole->first = part; hole->last = last; thishole = g_slist_find_custom(qptr->holelist, hole, find_hole); g_free(hole); /* If we found one, delete it and reconstruct a new hole */ if (thishole) { gint oldfirst, oldlast; hole = (Z_Hole *)thishole->data; oldfirst = hole->first; oldlast = hole->last; qptr->holelist = g_slist_delete_link(qptr->holelist, thishole); g_free(hole); /* * Now create a new hole that is the original hole without the * current fragment. */ if (part > oldfirst) { hole = g_new0(Z_Hole, 1); qptr->holelist = g_slist_prepend(qptr->holelist, hole); hole->first = oldfirst; hole->last = part - 1; } if (last < oldlast) { hole = g_new0(Z_Hole, 1); qptr->holelist = g_slist_prepend(qptr->holelist, hole); hole->first = last + 1; hole->last = oldlast; } } /* If there are no more holes, the packet is complete. */ if (qptr->holelist == NULL) { if (!qptr->complete) { __Q_CompleteLength++; } qptr->complete = 1; qptr->time = 0; /* don't time out anymore */ qptr->packet_len = qptr->header_len + qptr->msg_len; if (!(qptr->packet = (char *)malloc((unsigned)qptr->packet_len))) { return ENOMEM; } (void)memcpy(qptr->packet, qptr->header, qptr->header_len); (void)memcpy(qptr->packet + qptr->header_len, qptr->msg, qptr->msg_len); } return ZERR_NONE; } Code_t Z_FormatHeader(ZNotice_t *notice, char *buffer, int buffer_len, int *len, Z_AuthProc cert_routine) { Code_t retval; static char version[BUFSIZ]; /* default init should be all \0 */ gint64 realtime; struct sockaddr_in name; socklen_t namelen = sizeof(name); if (!notice->z_sender) notice->z_sender = ZGetSender(); if (notice->z_port == 0) { if (ZGetFD() < 0) { retval = ZOpenPort((unsigned short *)0); if (retval != ZERR_NONE) return (retval); } retval = getsockname(ZGetFD(), (struct sockaddr *) &name, &namelen); if (retval != 0) return (retval); notice->z_port = name.sin_port; } notice->z_multinotice = ""; realtime = g_get_real_time(); notice->z_uid.tv.tv_sec = realtime / G_USEC_PER_SEC; notice->z_uid.tv.tv_usec = realtime - notice->z_uid.tv.tv_sec * G_USEC_PER_SEC; notice->z_uid.tv.tv_sec = htonl((unsigned long)notice->z_uid.tv.tv_sec); notice->z_uid.tv.tv_usec = htonl((unsigned long)notice->z_uid.tv.tv_usec); (void) memcpy(¬ice->z_uid.zuid_addr, &__My_addr, sizeof(__My_addr)); notice->z_multiuid = notice->z_uid; if (!version[0]) (void) sprintf(version, "%s%d.%d", ZVERSIONHDR, ZVERSIONMAJOR, ZVERSIONMINOR); notice->z_version = version; return Z_FormatAuthHeader(notice, buffer, buffer_len, len, cert_routine); } Code_t Z_FormatAuthHeader(ZNotice_t *notice, char *buffer, int buffer_len, int *len, Z_AuthProc cert_routine) { if (!cert_routine) { notice->z_auth = 0; notice->z_authent_len = 0; notice->z_ascii_authent = ""; notice->z_checksum = 0; return (Z_FormatRawHeader(notice, buffer, buffer_len, len, NULL, NULL)); } return ((*cert_routine)(notice, buffer, buffer_len, len)); } Code_t Z_FormatRawHeader(ZNotice_t *notice, char *buffer, gsize buffer_len, int *len, char **cstart, char **cend) { char newrecip[BUFSIZ]; char *ptr, *end; int i; if (!notice->z_class) notice->z_class = ""; if (!notice->z_class_inst) notice->z_class_inst = ""; if (!notice->z_opcode) notice->z_opcode = ""; if (!notice->z_recipient) notice->z_recipient = ""; if (!notice->z_default_format) notice->z_default_format = ""; ptr = buffer; end = buffer+buffer_len; if (buffer_len < strlen(notice->z_version)+1) return (ZERR_HEADERLEN); g_strlcpy(ptr, notice->z_version, buffer_len); ptr += strlen(ptr)+1; if (ZMakeAscii32(ptr, end-ptr, Z_NUMFIELDS + notice->z_num_other_fields) == ZERR_FIELDLEN) return (ZERR_HEADERLEN); ptr += strlen(ptr)+1; if (ZMakeAscii32(ptr, end-ptr, notice->z_kind) == ZERR_FIELDLEN) return (ZERR_HEADERLEN); ptr += strlen(ptr)+1; if (ZMakeAscii(ptr, end-ptr, (unsigned char *)¬ice->z_uid, sizeof(ZUnique_Id_t)) == ZERR_FIELDLEN) return (ZERR_HEADERLEN); ptr += strlen(ptr)+1; if (ZMakeAscii16(ptr, end-ptr, ntohs(notice->z_port)) == ZERR_FIELDLEN) return (ZERR_HEADERLEN); ptr += strlen(ptr)+1; if (ZMakeAscii32(ptr, end-ptr, notice->z_auth) == ZERR_FIELDLEN) return (ZERR_HEADERLEN); ptr += strlen(ptr)+1; if (ZMakeAscii32(ptr, end-ptr, notice->z_authent_len) == ZERR_FIELDLEN) return (ZERR_HEADERLEN); ptr += strlen(ptr)+1; if (Z_AddField(&ptr, notice->z_ascii_authent, end)) return (ZERR_HEADERLEN); if (Z_AddField(&ptr, notice->z_class, end)) return (ZERR_HEADERLEN); if (Z_AddField(&ptr, notice->z_class_inst, end)) return (ZERR_HEADERLEN); if (Z_AddField(&ptr, notice->z_opcode, end)) return (ZERR_HEADERLEN); if (Z_AddField(&ptr, notice->z_sender, end)) return (ZERR_HEADERLEN); if (strchr(notice->z_recipient, '@') || !*notice->z_recipient) { if (Z_AddField(&ptr, notice->z_recipient, end)) return (ZERR_HEADERLEN); } else { if (strlen(notice->z_recipient) + strlen(__Zephyr_realm) + 2 > sizeof(newrecip)) return (ZERR_HEADERLEN); (void) sprintf(newrecip, "%s@%s", notice->z_recipient, __Zephyr_realm); if (Z_AddField(&ptr, newrecip, end)) return (ZERR_HEADERLEN); } if (Z_AddField(&ptr, notice->z_default_format, end)) return (ZERR_HEADERLEN); /* copy back the end pointer location for crypto checksum */ if (cstart) *cstart = ptr; if (ZMakeAscii32(ptr, end-ptr, notice->z_checksum) == ZERR_FIELDLEN) return (ZERR_HEADERLEN); ptr += strlen(ptr)+1; if (cend) *cend = ptr; if (Z_AddField(&ptr, notice->z_multinotice, end)) return (ZERR_HEADERLEN); if (ZMakeAscii(ptr, end-ptr, (unsigned char *)¬ice->z_multiuid, sizeof(ZUnique_Id_t)) == ZERR_FIELDLEN) return (ZERR_HEADERLEN); ptr += strlen(ptr)+1; for (i=0;i<notice->z_num_other_fields;i++) if (Z_AddField(&ptr, notice->z_other_fields[i], end)) return (ZERR_HEADERLEN); *len = ptr-buffer; return (ZERR_NONE); } static int Z_AddField(char **ptr, const char *field, char *end) { register int len; len = field ? strlen (field) + 1 : 1; if (*ptr+len > end) return 1; if (field) strcpy(*ptr, field); else **ptr = '\0'; *ptr += len; return 0; } struct _Z_InputQ * Z_GetFirstComplete(void) { struct _Z_InputQ *qptr; qptr = __Q_Head; while (qptr) { if (qptr->complete) return (qptr); qptr = qptr->next; } return ((struct _Z_InputQ *)0); } struct _Z_InputQ * Z_GetNextComplete(struct _Z_InputQ *qptr) { qptr = qptr->next; while (qptr) { if (qptr->complete) return (qptr); qptr = qptr->next; } return ((struct _Z_InputQ *)0); } void Z_RemQueue(struct _Z_InputQ *qptr) { if (qptr->complete) __Q_CompleteLength--; __Q_Size -= qptr->msg_len; free(qptr->header); free(qptr->msg); free(qptr->packet); g_slist_free_full(qptr->holelist, g_free); if (qptr == __Q_Head && __Q_Head == __Q_Tail) { free ((char *)qptr); __Q_Head = (struct _Z_InputQ *)0; __Q_Tail = (struct _Z_InputQ *)0; return; } if (qptr == __Q_Head) { __Q_Head = qptr->next; __Q_Head->prev = (struct _Z_InputQ *)0; free ((char *)qptr); return; } if (qptr == __Q_Tail) { __Q_Tail = qptr->prev; __Q_Tail->next = (struct _Z_InputQ *)0; free ((char *)qptr); return; } qptr->prev->next = qptr->next; qptr->next->prev = qptr->prev; free ((char *)qptr); } Code_t Z_SendFragmentedNotice(ZNotice_t *notice, int len, Z_AuthProc cert_func, Z_SendProc send_func) { ZNotice_t partnotice; ZPacket_t buffer; char multi[64]; int offset, hdrsize, fragsize, ret_len, message_len, waitforack; Code_t retval; hdrsize = len-notice->z_message_len; fragsize = Z_MAXPKTLEN-hdrsize-Z_FRAGFUDGE; offset = 0; waitforack = (notice->z_kind == UNACKED || notice->z_kind == ACKED); partnotice = *notice; while (offset < notice->z_message_len || !notice->z_message_len) { (void) sprintf(multi, "%d/%d", offset, notice->z_message_len); partnotice.z_multinotice = multi; if (offset > 0) { gint64 realtime = g_get_real_time(); partnotice.z_uid.tv.tv_sec = realtime / G_USEC_PER_SEC; partnotice.z_uid.tv.tv_usec = realtime - partnotice.z_uid.tv.tv_sec * G_USEC_PER_SEC; partnotice.z_uid.tv.tv_sec = htonl((unsigned long)partnotice.z_uid.tv.tv_sec); partnotice.z_uid.tv.tv_usec = htonl((unsigned long)partnotice.z_uid.tv.tv_usec); (void) memcpy((char *)&partnotice.z_uid.zuid_addr, &__My_addr, sizeof(__My_addr)); } message_len = MIN(notice->z_message_len - offset, fragsize); partnotice.z_message = (char*)notice->z_message+offset; partnotice.z_message_len = message_len; if ((retval = Z_FormatAuthHeader(&partnotice, buffer, Z_MAXHEADERLEN, &ret_len, cert_func)) != ZERR_NONE) { return (retval); } memcpy(buffer + ret_len, partnotice.z_message, message_len); if ((retval = (*send_func)(&partnotice, buffer, ret_len+message_len, waitforack)) != ZERR_NONE) { return (retval); } offset += fragsize; if (!notice->z_message_len) break; } return (ZERR_NONE); } /*ARGSUSED*/ Code_t Z_XmitFragment(ZNotice_t *notice, char *buf, int len, int wait) { return(ZSendPacket(buf, len, wait)); }
