Mercurial > hg > freeDiameter
view libfdproto/dictionary_functions.c @ 1405:3cbe458fbfa9
Fix compiler warnings
| author | Luke Mewburn <luke@mewburn.net> |
|---|---|
| date | Tue, 18 Feb 2020 16:23:53 +1100 |
| parents | 3f1e79e1273e |
| children | 566bb46cc73f |
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/********************************************************************************************************* * Software License Agreement (BSD License) * * Author: Sebastien Decugis <sdecugis@freediameter.net> * * * * Copyright (c) 2015, WIDE Project and NICT * * All rights reserved. * * * * Redistribution and use of this software in source and binary forms, with or without modification, are * * permitted provided that the following conditions are met: * * * * * Redistributions of source code must retain the above * * copyright notice, this list of conditions and the * * following disclaimer. * * * * * 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. * * * * * Neither the name of the WIDE Project or NICT nor the * * names of its contributors may be used to endorse or * * promote products derived from this software without * * specific prior written permission of WIDE Project and * * NICT. * * * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS 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 COPYRIGHT OWNER 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 "fdproto-internal.h" #include <time.h> /* This file contains helpers functions to be reused as callbacks in the struct dict_type_data structure. There are three callbacks there: - type_encode : - type_interpret : Those two callbacks allow to manipulate more natural structures of data in the code, and to map transparently these natural structures with the AVP-encoded format by calling the functions msg_avp_value_encode or msg_avp_value_interpret. - type_dump : This callback if provided gives a more human-readable debug information. */ /****************************/ /* Address AVP type */ /****************************/ /* The interpret and encode functions work with a "struct sockaddr_storage" pointer for mapping the contents of the AVP */ int fd_dictfct_Address_encode(void * data, union avp_value * avp_value) { sSS * ss = (sSS *) data; uint16_t AddressType = 0; size_t size = 0; unsigned char * buf = NULL; TRACE_ENTRY("%p %p", data, avp_value); CHECK_PARAMS( data && avp_value ); switch (ss->ss_family) { case AF_INET: { /* We are encoding an IP address */ sSA4 * sin = (sSA4 *)ss; AddressType = 1;/* see http://www.iana.org/assignments/address-family-numbers/ */ size = 6; /* 2 for AddressType + 4 for data */ CHECK_MALLOC( buf = malloc(size) ); /* may not work because of alignment: *(uint32_t *)(buf+2) = htonl(sin->sin_addr.s_addr); */ memcpy(buf + 2, &sin->sin_addr.s_addr, 4); } break; case AF_INET6: { /* We are encoding an IPv6 address */ sSA6 * sin6 = (sSA6 *)ss; AddressType = 2;/* see http://www.iana.org/assignments/address-family-numbers/ */ size = 18; /* 2 for AddressType + 16 for data */ CHECK_MALLOC( buf = malloc(size) ); /* The order is already good here */ memcpy(buf + 2, &sin6->sin6_addr.s6_addr, 16); } break; default: CHECK_PARAMS( AddressType = 0 ); } *(uint16_t *)buf = htons(AddressType); avp_value->os.len = size; avp_value->os.data = buf; return 0; } int fd_dictfct_Address_interpret(union avp_value * avp_value, void * interpreted) { uint16_t AddressType = 0; unsigned char * buf; TRACE_ENTRY("%p %p", avp_value, interpreted); CHECK_PARAMS( avp_value && interpreted && (avp_value->os.len >= 2) ); AddressType = ntohs(*(uint16_t *)avp_value->os.data); buf = &avp_value->os.data[2]; switch (AddressType) { case 1 /* IP */: { sSA4 * sin = (sSA4 *)interpreted; CHECK_PARAMS( avp_value->os.len == 6 ); sin->sin_family = AF_INET; /* sin->sin_addr.s_addr = ntohl( * (uint32_t *) buf); -- may not work because of bad alignment */ memcpy(&sin->sin_addr.s_addr, buf, 4); } break; case 2 /* IP6 */: { sSA6 * sin6 = (sSA6 *)interpreted; CHECK_PARAMS( avp_value->os.len == 18 ); sin6->sin6_family = AF_INET6; memcpy(&sin6->sin6_addr.s6_addr, buf, 16); } break; default: CHECK_PARAMS( AddressType = 0 ); } return 0; } /* Dump the content of an Address AVP */ DECLARE_FD_DUMP_PROTOTYPE(fd_dictfct_Address_dump, union avp_value * avp_value) { union { sSA sa; sSS ss; sSA4 sin; sSA6 sin6; } s; uint16_t fam; FD_DUMP_HANDLE_OFFSET(); memset(&s, 0, sizeof(s)); /* The first two octets represent the address family, http://www.iana.org/assignments/address-family-numbers/ */ if (avp_value->os.len < 2) { CHECK_MALLOC_DO( fd_dump_extend(FD_DUMP_STD_PARAMS, "[invalid length: %zd]", avp_value->os.len), return NULL); return *buf; } /* Following octets are the address in network byte order already */ fam = avp_value->os.data[0] << 8 | avp_value->os.data[1]; switch (fam) { case 1: /* IP */ s.sa.sa_family = AF_INET; if ((avp_value->os.len != 6) && (avp_value->os.len != 8)) { CHECK_MALLOC_DO( fd_dump_extend(FD_DUMP_STD_PARAMS, "[invalid IP length: %zd]", avp_value->os.len), return NULL); return *buf; } memcpy(&s.sin.sin_addr.s_addr, avp_value->os.data + 2, 4); if (avp_value->os.len == 8) memcpy(&s.sin.sin_port, avp_value->os.data + 6, 2); break; case 2: /* IP6 */ s.sa.sa_family = AF_INET6; if ((avp_value->os.len != 18) && (avp_value->os.len != 20)) { CHECK_MALLOC_DO( fd_dump_extend(FD_DUMP_STD_PARAMS, "[invalid IP6 length: %zd]", avp_value->os.len), return NULL); return *buf; } memcpy(&s.sin6.sin6_addr.s6_addr, avp_value->os.data + 2, 16); if (avp_value->os.len == 20) memcpy(&s.sin6.sin6_port, avp_value->os.data + 18, 2); break; case 8: /* E.164 */ CHECK_MALLOC_DO( fd_dump_extend(FD_DUMP_STD_PARAMS, "%.*s", (int)(avp_value->os.len-2), avp_value->os.data+2), return NULL); return *buf; default: CHECK_MALLOC_DO( fd_dump_extend(FD_DUMP_STD_PARAMS, "[unsupported family: 0x%hx]", fam), return NULL); return *buf; } return fd_sa_dump(FD_DUMP_STD_PARAMS, &s.sa, NI_NUMERICHOST); } /*******************************/ /* UTF8String AVP type */ /*******************************/ /* Dump the AVP in a natural human-readable format. This dumps the complete length of the AVP, it is up to the caller to truncate if needed */ DECLARE_FD_DUMP_PROTOTYPE(fd_dictfct_UTF8String_dump, union avp_value * avp_value) { size_t l; FD_DUMP_HANDLE_OFFSET(); l = avp_value->os.len; /* Just in case the string ends in invalid UTF-8 chars, we shorten it */ while ((l > 0) && (avp_value->os.data[l - 1] & 0x80)) { /* this byte is start or cont. of multibyte sequence, as we do not know the next byte we need to delete it. */ l--; if (avp_value->os.data[l] & 0x40) break; /* This was a start byte, we can stop the loop */ } CHECK_MALLOC_DO( fd_dump_extend(FD_DUMP_STD_PARAMS, "\"%.*s\"", (int)l, (char *)avp_value->os.data), return NULL); return *buf; } /*******************************/ /* Time AVP type */ /*******************************/ /* The interpret and encode functions work with a "time_t" pointer for mapping the contents of the AVP */ /* Unix Epoch starts 1970-01-01, NTP 0 is at 1900-01-01 */ #define DIFF_EPOCH_TO_NTP ((365*(1970-1900) + 17ul) * 24 * 60 * 60) static int diameter_string_to_time_t(const char *str, size_t len, time_t *result) { time_t time_stamp; CHECK_PARAMS(len == 4); time_stamp = (((unsigned long)(str[0]&0xff))<<24) + ((str[1]&0xff)<<16) + ((str[2]&0xff)<<8) + ((str[3]&0xff)); time_stamp -= DIFF_EPOCH_TO_NTP; #ifdef FIX__NEEDED_FOR_YEAR_2036_AND_LATER /* NTP overflows in 2036; after that, values start at zero again */ #define NTP_OVERFLOW_CORRECTION (0x100000000ull) /* XXX: debug and find correct conversion */ if (str[0] & 0x80 == 0x00) { time_stamp += NTP_OVERFLOW_CORRECTION; } #endif *result = time_stamp; return 0; } static int time_t_to_diameter_string(time_t time_stamp, char **result) { uint64_t out = time_stamp; char *conv; /* XXX: 2036 fix */ out += DIFF_EPOCH_TO_NTP; CHECK_PARAMS( (out >> 32) == 0); CHECK_MALLOC(conv=(char *)malloc(5)); conv[0] = (out>>24) & 0xff; conv[1] = (out>>16) & 0xff; conv[2] = (out>> 8) & 0xff; conv[3] = out & 0xff; conv[4] = '\0'; *result = conv; return 0; } int fd_dictfct_Time_encode(void * data, union avp_value * avp_value) { char * buf = NULL; size_t len; TRACE_ENTRY("%p %p", data, avp_value); CHECK_PARAMS( data && avp_value ); CHECK_FCT( time_t_to_diameter_string( *((time_t *)data), &buf) ); /* FIXME: return len from the function above? */ len = 4; avp_value->os.len = len; avp_value->os.data = (uint8_t *)buf; return 0; } int fd_dictfct_Time_interpret(union avp_value * avp_value, void * interpreted) { TRACE_ENTRY("%p %p", avp_value, interpreted); CHECK_PARAMS( avp_value && interpreted ); return diameter_string_to_time_t((const char *)avp_value->os.data, avp_value->os.len, interpreted); } static void _format_offs (long offset, char *buf) { int offs_hours, offs_minutes, sgn = 1; if (offset < 0) { offset = -offset; sgn = 1; } offs_hours = (int)(offset/3600); offs_minutes = (offset%3600)/60; char* s = buf; *(s++) = sgn == 1 ? '+' : '-'; *(s++) = (char)(offs_hours/10) + '0'; *(s++) = offs_hours%10 + '0'; if (offs_minutes == 0) { *(s++) = '\0'; } else { *(s++) = (char)(offs_minutes/10) + '0'; *(s++) = offs_minutes%10 + '0'; *(s++) = '\0'; } } DECLARE_FD_DUMP_PROTOTYPE(fd_dictfct_Time_dump, union avp_value * avp_value) { time_t val; struct tm conv; char tz_buf[7]; FD_DUMP_HANDLE_OFFSET(); if (avp_value->os.len != 4) { CHECK_MALLOC_DO( fd_dump_extend(FD_DUMP_STD_PARAMS, "[invalid length: %zd]", avp_value->os.len), return NULL); return *buf; } if (diameter_string_to_time_t((char *)avp_value->os.data, avp_value->os.len, &val) != 0) { CHECK_MALLOC_DO( fd_dump_extend(FD_DUMP_STD_PARAMS, "[time conversion error]"), return NULL); return *buf; } CHECK_MALLOC_DO( localtime_r(&val, &conv), return NULL); _format_offs(conv.tm_gmtoff, tz_buf); CHECK_MALLOC_DO( fd_dump_extend(FD_DUMP_STD_PARAMS, "%d%02d%02dT%02d%02d%02d%s", conv.tm_year+1900, conv.tm_mon+1, conv.tm_mday, conv.tm_hour, conv.tm_min, conv.tm_sec, tz_buf), return NULL); return *buf; } /* Check that a given AVP value contains all the characters from data in the same order */ static char error_message[80]; int fd_dictfct_CharInOS_check(void * data, union avp_value * val, char ** error_msg) { char * inChar = data; char * inData = (char *)val->os.data; int i = 0; CHECK_PARAMS(data); while (*inChar != '\0') { while (i < val->os.len) { if (*inChar == inData[i++]) { inChar++; break; } } if (i >= val->os.len) break; } if (*inChar == '\0') return 0; if (error_msg) { snprintf(error_message, sizeof(error_message), "Could not find '%c' in AVP", *inChar); *error_msg = error_message; } return EBADMSG; }