#include #include #include #include #include #include #include /* INT_MAX in ip_tables.h */ #include #include enum { O_TO_SRC = 0, O_RANDOM, O_RANDOM_FULLY, O_PERSISTENT, O_X_TO_SRC, F_TO_SRC = 1 << O_TO_SRC, F_RANDOM = 1 << O_RANDOM, F_RANDOM_FULLY = 1 << O_RANDOM_FULLY, F_X_TO_SRC = 1 << O_X_TO_SRC, }; /* Source NAT data consists of a multi-range, indicating where to map to. */ struct ipt_natinfo { struct xt_entry_target t; struct nf_nat_ipv4_multi_range_compat mr; }; static void SNAT_help(void) { printf( "SNAT target options:\n" " --to-source [[-]][:port[-port]]\n" " Address to map source to.\n" "[--random] [--random-fully] [--persistent]\n"); } static const struct xt_option_entry SNAT_opts[] = { {.name = "to-source", .id = O_TO_SRC, .type = XTTYPE_STRING, .flags = XTOPT_MAND | XTOPT_MULTI}, {.name = "random", .id = O_RANDOM, .type = XTTYPE_NONE}, {.name = "random-fully", .id = O_RANDOM_FULLY, .type = XTTYPE_NONE}, {.name = "persistent", .id = O_PERSISTENT, .type = XTTYPE_NONE}, XTOPT_TABLEEND, }; static struct ipt_natinfo * append_range(struct ipt_natinfo *info, const struct nf_nat_ipv4_range *range) { unsigned int size; /* One rangesize already in struct ipt_natinfo */ size = XT_ALIGN(sizeof(*info) + info->mr.rangesize * sizeof(*range)); info = realloc(info, size); if (!info) xtables_error(OTHER_PROBLEM, "Out of memory\n"); info->t.u.target_size = size; info->mr.range[info->mr.rangesize] = *range; info->mr.rangesize++; return info; } /* Ranges expected in network order. */ static struct xt_entry_target * parse_to(const char *orig_arg, int portok, struct ipt_natinfo *info) { struct nf_nat_ipv4_range range; char *arg, *colon, *dash, *error; const struct in_addr *ip; arg = strdup(orig_arg); if (arg == NULL) xtables_error(RESOURCE_PROBLEM, "strdup"); memset(&range, 0, sizeof(range)); colon = strchr(arg, ':'); if (colon) { int port; if (!portok) xtables_error(PARAMETER_PROBLEM, "Need TCP, UDP, SCTP or DCCP with port specification"); range.flags |= NF_NAT_RANGE_PROTO_SPECIFIED; port = atoi(colon+1); if (port <= 0 || port > 65535) xtables_error(PARAMETER_PROBLEM, "Port `%s' not valid\n", colon+1); error = strchr(colon+1, ':'); if (error) xtables_error(PARAMETER_PROBLEM, "Invalid port:port syntax - use dash\n"); dash = strchr(colon, '-'); if (!dash) { range.min.tcp.port = range.max.tcp.port = htons(port); } else { int maxport; maxport = atoi(dash + 1); if (maxport <= 0 || maxport > 65535) xtables_error(PARAMETER_PROBLEM, "Port `%s' not valid\n", dash+1); if (maxport < port) /* People are stupid. */ xtables_error(PARAMETER_PROBLEM, "Port range `%s' funky\n", colon+1); range.min.tcp.port = htons(port); range.max.tcp.port = htons(maxport); } /* Starts with a colon? No IP info...*/ if (colon == arg) { free(arg); return &(append_range(info, &range)->t); } *colon = '\0'; } range.flags |= NF_NAT_RANGE_MAP_IPS; dash = strchr(arg, '-'); if (colon && dash && dash > colon) dash = NULL; if (dash) *dash = '\0'; ip = xtables_numeric_to_ipaddr(arg); if (!ip) xtables_error(PARAMETER_PROBLEM, "Bad IP address \"%s\"\n", arg); range.min_ip = ip->s_addr; if (dash) { ip = xtables_numeric_to_ipaddr(dash+1); if (!ip) xtables_error(PARAMETER_PROBLEM, "Bad IP address \"%s\"\n", dash+1); range.max_ip = ip->s_addr; } else range.max_ip = range.min_ip; free(arg); return &(append_range(info, &range)->t); } static void SNAT_parse(struct xt_option_call *cb) { const struct ipt_entry *entry = cb->xt_entry; struct ipt_natinfo *info = (void *)(*cb->target); int portok; if (entry->ip.proto == IPPROTO_TCP || entry->ip.proto == IPPROTO_UDP || entry->ip.proto == IPPROTO_SCTP || entry->ip.proto == IPPROTO_DCCP || entry->ip.proto == IPPROTO_ICMP) portok = 1; else portok = 0; xtables_option_parse(cb); switch (cb->entry->id) { case O_TO_SRC: if (cb->xflags & F_X_TO_SRC) { if (!kernel_version) get_kernel_version(); if (kernel_version > LINUX_VERSION(2, 6, 10)) xtables_error(PARAMETER_PROBLEM, "SNAT: Multiple --to-source not supported"); } *cb->target = parse_to(cb->arg, portok, info); cb->xflags |= F_X_TO_SRC; break; case O_PERSISTENT: info->mr.range[0].flags |= NF_NAT_RANGE_PERSISTENT; break; } } static void SNAT_fcheck(struct xt_fcheck_call *cb) { static const unsigned int f = F_TO_SRC | F_RANDOM; static const unsigned int r = F_TO_SRC | F_RANDOM_FULLY; struct nf_nat_ipv4_multi_range_compat *mr = cb->data; if ((cb->xflags & f) == f) mr->range[0].flags |= NF_NAT_RANGE_PROTO_RANDOM; if ((cb->xflags & r) == r) mr->range[0].flags |= NF_NAT_RANGE_PROTO_RANDOM_FULLY; } static void print_range(const struct nf_nat_ipv4_range *r) { if (r->flags & NF_NAT_RANGE_MAP_IPS) { struct in_addr a; a.s_addr = r->min_ip; printf("%s", xtables_ipaddr_to_numeric(&a)); if (r->max_ip != r->min_ip) { a.s_addr = r->max_ip; printf("-%s", xtables_ipaddr_to_numeric(&a)); } } if (r->flags & NF_NAT_RANGE_PROTO_SPECIFIED) { printf(":"); printf("%hu", ntohs(r->min.tcp.port)); if (r->max.tcp.port != r->min.tcp.port) printf("-%hu", ntohs(r->max.tcp.port)); } } static void SNAT_print(const void *ip, const struct xt_entry_target *target, int numeric) { const struct ipt_natinfo *info = (const void *)target; unsigned int i = 0; printf(" to:"); for (i = 0; i < info->mr.rangesize; i++) { print_range(&info->mr.range[i]); if (info->mr.range[i].flags & NF_NAT_RANGE_PROTO_RANDOM) printf(" random"); if (info->mr.range[i].flags & NF_NAT_RANGE_PROTO_RANDOM_FULLY) printf(" random-fully"); if (info->mr.range[i].flags & NF_NAT_RANGE_PERSISTENT) printf(" persistent"); } } static void SNAT_save(const void *ip, const struct xt_entry_target *target) { const struct ipt_natinfo *info = (const void *)target; unsigned int i = 0; for (i = 0; i < info->mr.rangesize; i++) { printf(" --to-source "); print_range(&info->mr.range[i]); if (info->mr.range[i].flags & NF_NAT_RANGE_PROTO_RANDOM) printf(" --random"); if (info->mr.range[i].flags & NF_NAT_RANGE_PROTO_RANDOM_FULLY) printf(" --random-fully"); if (info->mr.range[i].flags & NF_NAT_RANGE_PERSISTENT) printf(" --persistent"); } } static void print_range_xlate(const struct nf_nat_ipv4_range *r, struct xt_xlate *xl) { if (r->flags & NF_NAT_RANGE_MAP_IPS) { struct in_addr a; a.s_addr = r->min_ip; xt_xlate_add(xl, "%s", xtables_ipaddr_to_numeric(&a)); if (r->max_ip != r->min_ip) { a.s_addr = r->max_ip; xt_xlate_add(xl, "-%s", xtables_ipaddr_to_numeric(&a)); } } if (r->flags & NF_NAT_RANGE_PROTO_SPECIFIED) { xt_xlate_add(xl, ":"); xt_xlate_add(xl, "%hu", ntohs(r->min.tcp.port)); if (r->max.tcp.port != r->min.tcp.port) xt_xlate_add(xl, "-%hu", ntohs(r->max.tcp.port)); } } static int SNAT_xlate(struct xt_xlate *xl, const struct xt_xlate_tg_params *params) { const struct ipt_natinfo *info = (const void *)params->target; unsigned int i = 0; bool sep_need = false; const char *sep = " "; for (i = 0; i < info->mr.rangesize; i++) { xt_xlate_add(xl, "snat to "); print_range_xlate(&info->mr.range[i], xl); if (info->mr.range[i].flags & NF_NAT_RANGE_PROTO_RANDOM) { xt_xlate_add(xl, " random"); sep_need = true; } if (info->mr.range[i].flags & NF_NAT_RANGE_PROTO_RANDOM_FULLY) { if (sep_need) sep = ","; xt_xlate_add(xl, "%sfully-random", sep); sep_need = true; } if (info->mr.range[i].flags & NF_NAT_RANGE_PERSISTENT) { if (sep_need) sep = ","; xt_xlate_add(xl, "%spersistent", sep); } } return 1; } static struct xtables_target snat_tg_reg = { .name = "SNAT", .version = XTABLES_VERSION, .family = NFPROTO_IPV4, .size = XT_ALIGN(sizeof(struct nf_nat_ipv4_multi_range_compat)), .userspacesize = XT_ALIGN(sizeof(struct nf_nat_ipv4_multi_range_compat)), .help = SNAT_help, .x6_parse = SNAT_parse, .x6_fcheck = SNAT_fcheck, .print = SNAT_print, .save = SNAT_save, .x6_options = SNAT_opts, .xlate = SNAT_xlate, }; void _init(void) { xtables_register_target(&snat_tg_reg); }