/* subnet_parse.c -- handle subnet parsing Copyright (C) 2000-2012 Guus Sliepen , 2000-2005 Ivo Timmermans This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include "system.h" #include "logger.h" #include "net.h" #include "netutl.h" #include "subnet.h" #include "utils.h" #include "xalloc.h" /* Changing this default will affect ADD_SUBNET messages - beware of inconsistencies between versions */ static const int DEFAULT_WEIGHT = 10; /* Subnet mask handling */ int maskcmp(const void *va, const void *vb, int masklen) { int i, m, result; const char *a = va; const char *b = vb; for(m = masklen, i = 0; m >= 8; m -= 8, i++) { result = a[i] - b[i]; if(result) { return result; } } if(m) return (a[i] & (0x100 - (1 << (8 - m)))) - (b[i] & (0x100 - (1 << (8 - m)))); return 0; } void mask(void *va, int masklen, int len) { int i; char *a = va; i = masklen / 8; masklen %= 8; if(masklen) { a[i++] &= (0x100 - (1 << (8 - masklen))); } for(; i < len; i++) { a[i] = 0; } } void maskcpy(void *va, const void *vb, int masklen, int len) { int i, m; char *a = va; const char *b = vb; for(m = masklen, i = 0; m >= 8; m -= 8, i++) { a[i] = b[i]; } if(m) { a[i] = b[i] & (0x100 - (1 << (8 - m))); i++; } for(; i < len; i++) { a[i] = 0; } } bool maskcheck(const void *va, int masklen, int len) { int i; const char *a = va; i = masklen / 8; masklen %= 8; if(masklen && a[i++] & (0xff >> masklen)) { return false; } for(; i < len; i++) if(a[i] != 0) { return false; } return true; } /* Subnet comparison */ static int subnet_compare_mac(const subnet_t *a, const subnet_t *b) { int result; result = memcmp(&a->net.mac.address, &b->net.mac.address, sizeof(a->net.mac.address)); if(result) { return result; } result = a->weight - b->weight; if(result || !a->owner || !b->owner) { return result; } return strcmp(a->owner->name, b->owner->name); } static int subnet_compare_ipv4(const subnet_t *a, const subnet_t *b) { int result; result = b->net.ipv4.prefixlength - a->net.ipv4.prefixlength; if(result) { return result; } result = memcmp(&a->net.ipv4.address, &b->net.ipv4.address, sizeof(ipv4_t)); if(result) { return result; } result = a->weight - b->weight; if(result || !a->owner || !b->owner) { return result; } return strcmp(a->owner->name, b->owner->name); } static int subnet_compare_ipv6(const subnet_t *a, const subnet_t *b) { int result; result = b->net.ipv6.prefixlength - a->net.ipv6.prefixlength; if(result) { return result; } result = memcmp(&a->net.ipv6.address, &b->net.ipv6.address, sizeof(ipv6_t)); if(result) { return result; } result = a->weight - b->weight; if(result || !a->owner || !b->owner) { return result; } return strcmp(a->owner->name, b->owner->name); } int subnet_compare(const subnet_t *a, const subnet_t *b) { int result; result = a->type - b->type; if(result) { return result; } switch(a->type) { case SUBNET_MAC: return subnet_compare_mac(a, b); case SUBNET_IPV4: return subnet_compare_ipv4(a, b); case SUBNET_IPV6: return subnet_compare_ipv6(a, b); default: logger(DEBUG_ALWAYS, LOG_ERR, "subnet_compare() was called with unknown subnet type %d, exitting!", a->type); exit(1); } return 0; } /* Ascii representation of subnets */ bool str2net(subnet_t *subnet, const char *subnetstr) { char str[1024]; strncpy(str, subnetstr, sizeof(str)); str[sizeof(str) - 1] = 0; int consumed; int weight = DEFAULT_WEIGHT; char *weight_separator = strchr(str, '#'); if(weight_separator) { char *weight_str = weight_separator + 1; if(sscanf(weight_str, "%d%n", &weight, &consumed) < 1) { return false; } if(weight_str[consumed]) { return false; } *weight_separator = 0; } int prefixlength = -1; char *prefixlength_separator = strchr(str, '/'); if(prefixlength_separator) { char *prefixlength_str = prefixlength_separator + 1; if(sscanf(prefixlength_str, "%d%n", &prefixlength, &consumed) < 1) { return false; } if(prefixlength_str[consumed]) { return false; } *prefixlength_separator = 0; if(prefixlength < 0) { return false; } } uint16_t x[8]; if(sscanf(str, "%hx:%hx:%hx:%hx:%hx:%hx%n", &x[0], &x[1], &x[2], &x[3], &x[4], &x[5], &consumed) >= 6 && !str[consumed]) { /* Normally we should check that each part has two digits to prevent ambiguities. However, in old tinc versions net2str() will aggressively return MAC addresses with one-digit parts, so we have to accept them otherwise we would be unable to parse ADD_SUBNET messages. */ if(prefixlength >= 0) { return false; } subnet->type = SUBNET_MAC; subnet->weight = weight; for(int i = 0; i < 6; i++) { subnet->net.mac.address.x[i] = x[i]; } return true; } if(sscanf(str, "%hu.%hu.%hu.%hu%n", &x[0], &x[1], &x[2], &x[3], &consumed) >= 4 && !str[consumed]) { if(prefixlength == -1) { prefixlength = 32; } if(prefixlength > 32) { return false; } subnet->type = SUBNET_IPV4; subnet->net.ipv4.prefixlength = prefixlength; subnet->weight = weight; for(int i = 0; i < 4; i++) { if(x[i] > 255) { return false; } subnet->net.ipv4.address.x[i] = x[i]; } return true; } /* IPv6 */ char *last_colon = strrchr(str, ':'); if(last_colon && sscanf(last_colon, ":%hu.%hu.%hu.%hu%n", &x[0], &x[1], &x[2], &x[3], &consumed) >= 4 && !last_colon[consumed]) { /* Dotted quad suffix notation, convert to standard IPv6 notation */ for(int i = 0; i < 4; i++) if(x[i] > 255) { return false; } snprintf(last_colon, sizeof(str) - (last_colon - str), ":%02x%02x:%02x%02x", x[0], x[1], x[2], x[3]); } char *double_colon = strstr(str, "::"); if(double_colon) { /* Figure out how many zero groups we need to expand */ int zero_group_count = 8; for(const char *cur = str; *cur; cur++) if(*cur != ':') { zero_group_count--; while(cur[1] && cur[1] != ':') { cur++; } } if(zero_group_count < 1) { return false; } /* Split the double colon in the middle to make room for zero groups */ double_colon++; memmove(double_colon + (zero_group_count * 2 - 1), double_colon, strlen(double_colon) + 1); /* Write zero groups in the resulting gap, overwriting the second colon */ for(int i = 0; i < zero_group_count; i++) { memcpy(&double_colon[i * 2], "0:", 2); } /* Remove any leading or trailing colons */ if(str[0] == ':') { memmove(&str[0], &str[1], strlen(&str[1]) + 1); } if(str[strlen(str) - 1] == ':') { str[strlen(str) - 1] = 0; } } if(sscanf(str, "%hx:%hx:%hx:%hx:%hx:%hx:%hx:%hx%n", &x[0], &x[1], &x[2], &x[3], &x[4], &x[5], &x[6], &x[7], &consumed) >= 8 && !str[consumed]) { if(prefixlength == -1) { prefixlength = 128; } if(prefixlength > 128) { return false; } subnet->type = SUBNET_IPV6; subnet->net.ipv6.prefixlength = prefixlength; subnet->weight = weight; for(int i = 0; i < 8; i++) { subnet->net.ipv6.address.x[i] = htons(x[i]); } return true; } return false; } bool net2str(char *netstr, int len, const subnet_t *subnet) { if(!netstr || !subnet) { logger(DEBUG_ALWAYS, LOG_ERR, "net2str() was called with netstr=%p, subnet=%p!", (void *)netstr, (void *)subnet); return false; } int result; int prefixlength = -1; switch(subnet->type) { case SUBNET_MAC: result = snprintf(netstr, len, "%02x:%02x:%02x:%02x:%02x:%02x", subnet->net.mac.address.x[0], subnet->net.mac.address.x[1], subnet->net.mac.address.x[2], subnet->net.mac.address.x[3], subnet->net.mac.address.x[4], subnet->net.mac.address.x[5]); netstr += result; len -= result; break; case SUBNET_IPV4: result = snprintf(netstr, len, "%u.%u.%u.%u", subnet->net.ipv4.address.x[0], subnet->net.ipv4.address.x[1], subnet->net.ipv4.address.x[2], subnet->net.ipv4.address.x[3]); netstr += result; len -= result; prefixlength = subnet->net.ipv4.prefixlength; if(prefixlength == 32) { prefixlength = -1; } break; case SUBNET_IPV6: { /* Find the longest sequence of consecutive zeroes */ int max_zero_length = 0; int max_zero_length_index = 0; int current_zero_length = 0; int current_zero_length_index = 0; for(int i = 0; i < 8; i++) { if(subnet->net.ipv6.address.x[i] != 0) { current_zero_length = 0; } else { if(current_zero_length == 0) { current_zero_length_index = i; } current_zero_length++; if(current_zero_length > max_zero_length) { max_zero_length = current_zero_length; max_zero_length_index = current_zero_length_index; } } } /* Print the address */ for(int i = 0; i < 8;) { if(max_zero_length > 1 && max_zero_length_index == i) { /* Shorten the representation as per RFC 5952 */ const char *const FORMATS[] = { "%.1s", "%.2s", "%.3s" }; const char *const *format = &FORMATS[0]; if(i == 0) { format++; } if(i + max_zero_length == 8) { format++; } result = snprintf(netstr, len, *format, ":::"); i += max_zero_length; } else { result = snprintf(netstr, len, "%x:", ntohs(subnet->net.ipv6.address.x[i])); i++; } netstr += result; len -= result; } /* Remove the trailing colon */ netstr--; len++; *netstr = 0; prefixlength = subnet->net.ipv6.prefixlength; if(prefixlength == 128) { prefixlength = -1; } break; } default: logger(DEBUG_ALWAYS, LOG_ERR, "net2str() was called with unknown subnet type %d, exiting!", subnet->type); exit(1); } if(prefixlength >= 0) { result = snprintf(netstr, len, "/%d", prefixlength); netstr += result; len -= result; } if(subnet->weight != DEFAULT_WEIGHT) { snprintf(netstr, len, "#%d", subnet->weight); } return true; }