/* $OpenBSD: confpars.c,v 1.20 2010/04/02 17:03:58 zinovik Exp $ */ /* * Copyright (c) 1995, 1996, 1997 The Internet Software Consortium. * 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. * 3. Neither the name of The Internet Software Consortium nor the names * of its contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE INTERNET SOFTWARE CONSORTIUM 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 INTERNET SOFTWARE CONSORTIUM 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. * * This software has been written for the Internet Software Consortium * by Ted Lemon in cooperation with Vixie * Enterprises. To learn more about the Internet Software Consortium, * see ``http://www.vix.com/isc''. To learn more about Vixie * Enterprises, see ``http://www.vix.com''. */ #include "dhcpd.h" #include "dhctoken.h" /* conf-file :== parameters declarations EOF parameters :== | parameter | parameters parameter declarations :== | declaration | declarations declaration */ int readconf(void) { FILE *cfile; char *val; int token; int declaration = 0; new_parse(path_dhcpd_conf); /* Set up the initial dhcp option universe. */ initialize_universes(); /* Set up the global defaults... */ root_group.default_lease_time = 43200; /* 12 hours. */ root_group.max_lease_time = 86400; /* 24 hours. */ root_group.bootp_lease_cutoff = MAX_TIME; root_group.boot_unknown_clients = 1; root_group.allow_bootp = 1; root_group.allow_booting = 1; root_group.authoritative = 1; if ((cfile = fopen(path_dhcpd_conf, "r")) == NULL) error("Can't open %s: %m", path_dhcpd_conf); do { token = peek_token(&val, cfile); if (token == EOF) break; declaration = parse_statement(cfile, &root_group, ROOT_GROUP, NULL, declaration); } while (1); token = next_token(&val, cfile); /* Clear the peek buffer */ fclose(cfile); return !warnings_occurred; } /* lease-file :== lease-declarations EOF lease-statments :== | lease-declaration | lease-declarations lease-declaration */ void read_leases(void) { FILE *cfile; char *val; int token; new_parse(path_dhcpd_db); /* Open the lease file. If we can't open it, fail. The reason for this is that although on initial startup, the absence of a lease file is perfectly benign, if dhcpd has been running and this file is absent, it means that dhcpd tried and failed to rewrite the lease database. If we proceed and the problem which caused the rewrite to fail has been fixed, but no human has corrected the database problem, then we are left thinking that no leases have been assigned to anybody, which could create severe network chaos. */ if ((cfile = fopen(path_dhcpd_db, "r")) == NULL) { warning("Can't open lease database %s: %m -- %s", path_dhcpd_db, "check for failed database rewrite attempt!"); warning("Please read the dhcpd.leases manual page if you"); error("don't know what to do about this."); } do { token = next_token(&val, cfile); if (token == EOF) break; if (token != TOK_LEASE) { warning("Corrupt lease file - possible data loss!"); skip_to_semi(cfile); } else { struct lease *lease; lease = parse_lease_declaration(cfile); if (lease) enter_lease(lease); else parse_warn("possibly corrupt lease file"); } } while (1); fclose(cfile); } /* statement :== parameter | declaration parameter :== timestamp | DEFAULT_LEASE_TIME lease_time | MAX_LEASE_TIME lease_time | DYNAMIC_BOOTP_LEASE_CUTOFF date | DYNAMIC_BOOTP_LEASE_LENGTH lease_time | BOOT_UNKNOWN_CLIENTS boolean | GET_LEASE_HOSTNAMES boolean | USE_HOST_DECL_NAME boolean | NEXT_SERVER ip-addr-or-hostname SEMI | option_parameter | SERVER-IDENTIFIER ip-addr-or-hostname SEMI | FILENAME string-parameter | SERVER_NAME string-parameter | hardware-parameter | fixed-address-parameter | ALLOW allow-deny-keyword | DENY allow-deny-keyword | USE_LEASE_ADDR_FOR_DEFAULT_ROUTE boolean declaration :== host-declaration | group-declaration | shared-network-declaration | subnet-declaration | VENDOR_CLASS class-declaration | USER_CLASS class-declaration | RANGE address-range-declaration */ int parse_statement(cfile, group, type, host_decl, declaration) FILE *cfile; struct group *group; int type; struct host_decl *host_decl; int declaration; { int token; char *val; struct shared_network *share; char *n; struct tree *tree; struct tree_cache *cache; struct hardware hardware; switch (next_token(&val, cfile)) { case TOK_HOST: if (type != HOST_DECL) parse_host_declaration(cfile, group); else { parse_warn("host declarations not allowed here."); skip_to_semi(cfile); } return 1; case TOK_GROUP: if (type != HOST_DECL) parse_group_declaration(cfile, group); else { parse_warn("host declarations not allowed here."); skip_to_semi(cfile); } return 1; case TOK_TIMESTAMP: break; case TOK_SHARED_NETWORK: if (type == SHARED_NET_DECL || type == HOST_DECL || type == SUBNET_DECL) { parse_warn("shared-network parameters not %s.", "allowed here"); skip_to_semi(cfile); break; } parse_shared_net_declaration(cfile, group); return 1; case TOK_SUBNET: if (type == HOST_DECL || type == SUBNET_DECL) { parse_warn("subnet declarations not allowed here."); skip_to_semi(cfile); return 1; } /* If we're in a subnet declaration, just do the parse. */ if (group->shared_network) { parse_subnet_declaration(cfile, group->shared_network); break; } /* Otherwise, cons up a fake shared network structure and populate it with the lone subnet... */ share = calloc(1, sizeof(struct shared_network)); if (!share) error("No memory for shared subnet"); share->group = clone_group(group, "parse_statement:subnet"); share->group->shared_network = share; parse_subnet_declaration(cfile, share); /* share->subnets is the subnet we just parsed. */ if (share->subnets) { share->interface = share->subnets->interface; /* Make the shared network name from network number. */ n = piaddr(share->subnets->net); share->name = strdup(n); if (share->name == NULL) error("no memory for subnet name"); /* Copy the authoritative parameter from the subnet, since there is no opportunity to declare it here. */ share->group->authoritative = share->subnets->group->authoritative; enter_shared_network(share); } return 1; case TOK_VENDOR_CLASS: parse_class_declaration(cfile, group, 0); return 1; case TOK_USER_CLASS: parse_class_declaration(cfile, group, 1); return 1; case TOK_DEFAULT_LEASE_TIME: parse_lease_time(cfile, &group->default_lease_time); break; case TOK_MAX_LEASE_TIME: parse_lease_time(cfile, &group->max_lease_time); break; case TOK_DYNAMIC_BOOTP_LEASE_CUTOFF: group->bootp_lease_cutoff = parse_date(cfile); break; case TOK_DYNAMIC_BOOTP_LEASE_LENGTH: parse_lease_time(cfile, &group->bootp_lease_length); break; case TOK_BOOT_UNKNOWN_CLIENTS: if (type == HOST_DECL) parse_warn("boot-unknown-clients not allowed here."); group->boot_unknown_clients = parse_boolean(cfile); break; case TOK_GET_LEASE_HOSTNAMES: if (type == HOST_DECL) parse_warn("get-lease-hostnames not allowed here."); group->get_lease_hostnames = parse_boolean(cfile); break; case TOK_ALWAYS_REPLY_RFC1048: group->always_reply_rfc1048 = parse_boolean(cfile); break; case TOK_USE_HOST_DECL_NAMES: if (type == HOST_DECL) parse_warn("use-host-decl-names not allowed here."); group->use_host_decl_names = parse_boolean(cfile); break; case TOK_USE_LEASE_ADDR_FOR_DEFAULT_ROUTE: group->use_lease_addr_for_default_route = parse_boolean(cfile); break; case TOK_TOKEN_NOT: token = next_token(&val, cfile); switch (token) { case TOK_AUTHORITATIVE: if (type == HOST_DECL) parse_warn("authority makes no sense here."); group->authoritative = 0; parse_semi(cfile); break; default: parse_warn("expecting assertion"); skip_to_semi(cfile); break; } break; case TOK_AUTHORITATIVE: if (type == HOST_DECL) parse_warn("authority makes no sense here."); group->authoritative = 1; parse_semi(cfile); break; case TOK_NEXT_SERVER: tree = parse_ip_addr_or_hostname(cfile, 0); if (!tree) break; cache = tree_cache(tree); if (!tree_evaluate (cache)) error("next-server is not known"); group->next_server.len = 4; memcpy(group->next_server.iabuf, cache->value, group->next_server.len); parse_semi(cfile); break; case TOK_OPTION: parse_option_param(cfile, group); break; case TOK_SERVER_IDENTIFIER: tree = parse_ip_addr_or_hostname(cfile, 0); if (!tree) return declaration; group->options[DHO_DHCP_SERVER_IDENTIFIER] = tree_cache(tree); token = next_token(&val, cfile); break; case TOK_FILENAME: group->filename = parse_string(cfile); break; case TOK_SERVER_NAME: group->server_name = parse_string(cfile); break; case TOK_HARDWARE: parse_hardware_param(cfile, &hardware); if (host_decl) host_decl->interface = hardware; else parse_warn("hardware address parameter %s", "not allowed here."); break; case TOK_FIXED_ADDR: cache = parse_fixed_addr_param(cfile); if (host_decl) host_decl->fixed_addr = cache; else parse_warn("fixed-address parameter not %s", "allowed here."); break; case TOK_RANGE: if (type != SUBNET_DECL || !group->subnet) { parse_warn("range declaration not allowed here."); skip_to_semi(cfile); return declaration; } parse_address_range(cfile, group->subnet); return declaration; case TOK_ALLOW: parse_allow_deny(cfile, group, 1); break; case TOK_DENY: parse_allow_deny(cfile, group, 0); break; default: if (declaration) parse_warn("expecting a declaration."); else parse_warn("expecting a parameter or declaration."); skip_to_semi(cfile); return declaration; } if (declaration) { parse_warn("parameters not allowed after first declaration."); return 1; } return 0; } /* allow-deny-keyword :== BOOTP | BOOTING | DYNAMIC_BOOTP | UNKNOWN_CLIENTS */ void parse_allow_deny(cfile, group, flag) FILE *cfile; struct group *group; int flag; { int token; char *val; token = next_token(&val, cfile); switch (token) { case TOK_BOOTP: group->allow_bootp = flag; break; case TOK_BOOTING: group->allow_booting = flag; break; case TOK_DYNAMIC_BOOTP: group->dynamic_bootp = flag; break; case TOK_UNKNOWN_CLIENTS: group->boot_unknown_clients = flag; break; default: parse_warn("expecting allow/deny key"); skip_to_semi(cfile); return; } parse_semi(cfile); } /* boolean :== ON SEMI | OFF SEMI | TRUE SEMI | FALSE SEMI */ int parse_boolean(FILE *cfile) { char *val; int rv; next_token(&val, cfile); if (!strcasecmp (val, "true") || !strcasecmp (val, "on")) rv = 1; else if (!strcasecmp (val, "false") || !strcasecmp (val, "off")) rv = 0; else { parse_warn("boolean value (true/false/on/off) expected"); skip_to_semi(cfile); return 0; } parse_semi(cfile); return rv; } /* Expect a left brace; if there isn't one, skip over the rest of the statement and return zero; otherwise, return 1. */ int parse_lbrace(FILE *cfile) { int token; char *val; token = next_token(&val, cfile); if (token != '{') { parse_warn("expecting left brace."); skip_to_semi(cfile); return 0; } return 1; } /* host-declaration :== hostname '{' parameters declarations '}' */ void parse_host_declaration(cfile, group) FILE *cfile; struct group *group; { char *val; int token; struct host_decl *host; char *name = parse_host_name(cfile); int declaration = 0; if (!name) return; host = calloc(1, sizeof (struct host_decl)); if (!host) error("can't allocate host decl struct %s.", name); host->name = name; host->group = clone_group(group, "parse_host_declaration"); if (!parse_lbrace(cfile)) { free(host->name); free(host->group); free(host); return; } do { token = peek_token(&val, cfile); if (token == '}') { token = next_token(&val, cfile); break; } if (token == EOF) { token = next_token(&val, cfile); parse_warn("unexpected end of file"); break; } declaration = parse_statement(cfile, host->group, HOST_DECL, host, declaration); } while (1); if (!host->group->options[DHO_HOST_NAME] && host->group->use_host_decl_names) { host->group->options[DHO_HOST_NAME] = new_tree_cache("parse_host_declaration"); if (!host->group->options[DHO_HOST_NAME]) error("can't allocate a tree cache for hostname."); host->group->options[DHO_HOST_NAME]->len = strlen(name); host->group->options[DHO_HOST_NAME]->value = (unsigned char *)name; host->group->options[DHO_HOST_NAME]->buf_size = host->group->options[DHO_HOST_NAME]->len; host->group->options[DHO_HOST_NAME]->timeout = -1; host->group->options[DHO_HOST_NAME]->tree = NULL; } enter_host(host); } /* class-declaration :== STRING '{' parameters declarations '}' */ void parse_class_declaration(cfile, group, type) FILE *cfile; struct group *group; int type; { char *val; int token; struct class *class; int declaration = 0; token = next_token(&val, cfile); if (token != TOK_STRING) { parse_warn("Expecting class name"); skip_to_semi(cfile); return; } class = add_class (type, val); if (!class) error("No memory for class %s.", val); class->group = clone_group(group, "parse_class_declaration"); if (!parse_lbrace(cfile)) { free(class->name); free(class->group); free(class); return; } do { token = peek_token(&val, cfile); if (token == '}') { token = next_token(&val, cfile); break; } else if (token == EOF) { token = next_token(&val, cfile); parse_warn("unexpected end of file"); break; } else { declaration = parse_statement(cfile, class->group, CLASS_DECL, NULL, declaration); } } while (1); } /* shared-network-declaration :== hostname LBRACE declarations parameters RBRACE */ void parse_shared_net_declaration(cfile, group) FILE *cfile; struct group *group; { char *val; int token; struct shared_network *share; char *name; int declaration = 0; share = calloc(1, sizeof(struct shared_network)); if (!share) error("No memory for shared subnet"); share->leases = NULL; share->last_lease = NULL; share->insertion_point = NULL; share->next = NULL; share->interface = NULL; share->group = clone_group(group, "parse_shared_net_declaration"); share->group->shared_network = share; /* Get the name of the shared network... */ token = peek_token(&val, cfile); if (token == TOK_STRING) { token = next_token(&val, cfile); if (val[0] == 0) { parse_warn("zero-length shared network name"); val = ""; } name = strdup(val); if (name == NULL) error("no memory for shared network name"); } else { name = parse_host_name(cfile); if (!name) { free(share->group); free(share); return; } } share->name = name; if (!parse_lbrace(cfile)) { free(share->group); free(share->name); free(share); return; } do { token = peek_token(&val, cfile); if (token == '}') { token = next_token(&val, cfile); if (!share->subnets) { free(share->group); free(share->name); free(share); parse_warn("empty shared-network decl"); return; } enter_shared_network(share); return; } else if (token == EOF) { token = next_token(&val, cfile); parse_warn("unexpected end of file"); break; } declaration = parse_statement(cfile, share->group, SHARED_NET_DECL, NULL, declaration); } while (1); } /* subnet-declaration :== net NETMASK netmask RBRACE parameters declarations LBRACE */ void parse_subnet_declaration(cfile, share) FILE *cfile; struct shared_network *share; { char *val; int token; struct subnet *subnet, *t, *u; struct iaddr iaddr; unsigned char addr[4]; int len = sizeof addr; int declaration = 0; subnet = calloc(1, sizeof(struct subnet)); if (!subnet) error("No memory for new subnet"); subnet->shared_network = share; subnet->group = clone_group(share->group, "parse_subnet_declaration"); subnet->group->subnet = subnet; /* Get the network number... */ if (!parse_numeric_aggregate(cfile, addr, &len, '.', 10, 8)) { free(subnet->group); free(subnet); return; } memcpy(iaddr.iabuf, addr, len); iaddr.len = len; subnet->net = iaddr; token = next_token(&val, cfile); if (token != TOK_NETMASK) { free(subnet->group); free(subnet); parse_warn("Expecting netmask"); skip_to_semi(cfile); return; } /* Get the netmask... */ if (!parse_numeric_aggregate(cfile, addr, &len, '.', 10, 8)) { free(subnet->group); free(subnet); return; } memcpy(iaddr.iabuf, addr, len); iaddr.len = len; subnet->netmask = iaddr; enter_subnet(subnet); if (!parse_lbrace(cfile)) return; do { token = peek_token(&val, cfile); if (token == '}') { token = next_token(&val, cfile); break; } else if (token == EOF) { token = next_token(&val, cfile); parse_warn("unexpected end of file"); break; } declaration = parse_statement(cfile, subnet->group, SUBNET_DECL, NULL, declaration); } while (1); /* If this subnet supports dynamic bootp, flag it so in the shared_network containing it. */ if (subnet->group->dynamic_bootp) share->group->dynamic_bootp = 1; /* Add the subnet to the list of subnets in this shared net. */ if (!share->subnets) share->subnets = subnet; else { u = NULL; for (t = share->subnets; t; t = t->next_sibling) { if (subnet_inner_than(subnet, t, 0)) { if (u) u->next_sibling = subnet; else share->subnets = subnet; subnet->next_sibling = t; return; } u = t; } u->next_sibling = subnet; } } /* group-declaration :== RBRACE parameters declarations LBRACE */ void parse_group_declaration(cfile, group) FILE *cfile; struct group *group; { char *val; int token; struct group *g; int declaration = 0; g = clone_group(group, "parse_group_declaration"); if (!parse_lbrace(cfile)) { free(g); return; } do { token = peek_token(&val, cfile); if (token == '}') { token = next_token(&val, cfile); break; } else if (token == EOF) { token = next_token(&val, cfile); parse_warn("unexpected end of file"); break; } declaration = parse_statement(cfile, g, GROUP_DECL, NULL, declaration); } while (1); } /* ip-addr-or-hostname :== ip-address | hostname ip-address :== NUMBER DOT NUMBER DOT NUMBER DOT NUMBER Parse an ip address or a hostname. If uniform is zero, put in a TREE_LIMIT node to catch hostnames that evaluate to more than one IP address. */ struct tree *parse_ip_addr_or_hostname(cfile, uniform) FILE *cfile; int uniform; { char *val; int token; unsigned char addr[4]; int len = sizeof addr; char *name; struct tree *rv; struct hostent *h; token = peek_token(&val, cfile); if (is_identifier(token)) { name = parse_host_name(cfile); if (!name) return NULL; h = gethostbyname(name); if (h == NULL) { parse_warn("%s (%d): could not resolve hostname", val, token); return NULL; } rv = tree_const(h->h_addr_list[0], h->h_length); if (!uniform) rv = tree_limit(rv, 4); } else if (token == TOK_NUMBER) { if (!parse_numeric_aggregate(cfile, addr, &len, '.', 10, 8)) return NULL; rv = tree_const(addr, len); } else { if (token != '{' && token != '}') token = next_token(&val, cfile); parse_warn("%s (%d): expecting IP address or hostname", val, token); if (token != ';') skip_to_semi(cfile); return NULL; } return rv; } /* fixed-addr-parameter :== ip-addrs-or-hostnames SEMI ip-addrs-or-hostnames :== ip-addr-or-hostname | ip-addrs-or-hostnames ip-addr-or-hostname */ struct tree_cache *parse_fixed_addr_param(cfile) FILE *cfile; { char *val; int token; struct tree *tree = NULL; struct tree *tmp; do { tmp = parse_ip_addr_or_hostname(cfile, 0); if (tree) tree = tree_concat(tree, tmp); else tree = tmp; token = peek_token(&val, cfile); if (token == ',') token = next_token(&val, cfile); } while (token == ','); if (!parse_semi(cfile)) return NULL; return tree_cache(tree); } /* option_parameter :== identifier DOT identifier SEMI | identifier SEMI Option syntax is handled specially through format strings, so it would be painful to come up with BNF for it. However, it always starts as above and ends in a SEMI. */ void parse_option_param(cfile, group) FILE *cfile; struct group *group; { char *val; int token; unsigned char buf[4]; char *vendor; char *fmt; struct universe *universe; struct option *option; struct tree *tree = NULL; struct tree *t; token = next_token(&val, cfile); if (!is_identifier(token)) { parse_warn("expecting identifier after option keyword."); if (token != ';') skip_to_semi(cfile); return; } vendor = strdup(val); if (vendor == NULL) error("no memory for vendor token."); token = peek_token(&val, cfile); if (token == '.') { /* Go ahead and take the DOT token... */ token = next_token(&val, cfile); /* The next token should be an identifier... */ token = next_token(&val, cfile); if (!is_identifier(token)) { parse_warn("expecting identifier after '.'"); if (token != ';') skip_to_semi(cfile); free(vendor); return; } /* Look up the option name hash table for the specified vendor. */ universe = ((struct universe *)hash_lookup(&universe_hash, (unsigned char *)vendor, 0)); /* If it's not there, we can't parse the rest of the declaration. */ if (!universe) { parse_warn("no vendor named %s.", vendor); skip_to_semi(cfile); free(vendor); return; } } else { /* Use the default hash table, which contains all the standard dhcp option names. */ val = vendor; universe = &dhcp_universe; } /* Look up the actual option info... */ option = (struct option *)hash_lookup(universe->hash, (unsigned char *)val, 0); /* If we didn't get an option structure, it's an undefined option. */ if (!option) { if (val == vendor) parse_warn("no option named %s", val); else parse_warn("no option named %s for vendor %s", val, vendor); skip_to_semi(cfile); free(vendor); return; } /* Free the initial identifier token. */ free(vendor); /* Parse the option data... */ do { /* Set a flag if this is an array of a simple type (i.e., not an array of pairs of IP addresses, or something like that. */ int uniform = option->format[1] == 'A'; for (fmt = option->format; *fmt; fmt++) { if (*fmt == 'A') break; switch (*fmt) { case 'X': token = peek_token(&val, cfile); if (token == TOK_NUMBER_OR_NAME || token == TOK_NUMBER) { do { token = next_token (&val, cfile); if (token != TOK_NUMBER && token != TOK_NUMBER_OR_NAME) { parse_warn("expecting " "number."); if (token != ';') skip_to_semi( cfile); return; } convert_num(buf, val, 16, 8); tree = tree_concat(tree, tree_const(buf, 1)); token = peek_token(&val, cfile); if (token == ':') token = next_token(&val, cfile); } while (token == ':'); } else if (token == TOK_STRING) { token = next_token(&val, cfile); tree = tree_concat(tree, tree_const((unsigned char *)val, strlen(val))); } else { parse_warn("expecting string %s.", "or hexadecimal data"); skip_to_semi(cfile); return; } break; case 't': /* Text string... */ token = next_token(&val, cfile); if (token != TOK_STRING && !is_identifier(token)) { parse_warn("expecting string."); if (token != ';') skip_to_semi(cfile); return; } tree = tree_concat(tree, tree_const((unsigned char *)val, strlen(val))); break; case 'I': /* IP address or hostname. */ t = parse_ip_addr_or_hostname(cfile, uniform); if (!t) return; tree = tree_concat(tree, t); break; case 'L': /* Unsigned 32-bit integer... */ case 'l': /* Signed 32-bit integer... */ token = next_token(&val, cfile); if (token != TOK_NUMBER) { parse_warn("expecting number."); if (token != ';') skip_to_semi(cfile); return; } convert_num(buf, val, 0, 32); tree = tree_concat(tree, tree_const(buf, 4)); break; case 's': /* Signed 16-bit integer. */ case 'S': /* Unsigned 16-bit integer. */ token = next_token(&val, cfile); if (token != TOK_NUMBER) { parse_warn("expecting number."); if (token != ';') skip_to_semi(cfile); return; } convert_num(buf, val, 0, 16); tree = tree_concat(tree, tree_const(buf, 2)); break; case 'b': /* Signed 8-bit integer. */ case 'B': /* Unsigned 8-bit integer. */ token = next_token(&val, cfile); if (token != TOK_NUMBER) { parse_warn("expecting number."); if (token != ';') skip_to_semi(cfile); return; } convert_num(buf, val, 0, 8); tree = tree_concat(tree, tree_const(buf, 1)); break; case 'f': /* Boolean flag. */ token = next_token(&val, cfile); if (!is_identifier(token)) { parse_warn("expecting identifier."); if (token != ';') skip_to_semi(cfile); return; } if (!strcasecmp(val, "true") || !strcasecmp(val, "on")) buf[0] = 1; else if (!strcasecmp(val, "false") || !strcasecmp(val, "off")) buf[0] = 0; else { parse_warn("expecting boolean."); if (token != ';') skip_to_semi(cfile); return; } tree = tree_concat(tree, tree_const(buf, 1)); break; default: warning("Bad format %c in parse_option_param.", *fmt); skip_to_semi(cfile); return; } } if (*fmt == 'A') { token = peek_token(&val, cfile); if (token == ',') { token = next_token(&val, cfile); continue; } break; } } while (*fmt == 'A'); token = next_token(&val, cfile); if (token != ';') { parse_warn("semicolon expected."); skip_to_semi(cfile); return; } group->options[option->code] = tree_cache(tree); } /* lease_declaration :== LEASE ip_address LBRACE lease_parameters RBRACE lease_parameters :== | lease_parameter | lease_parameters lease_parameter lease_parameter :== STARTS date | ENDS date | TIMESTAMP date | HARDWARE hardware-parameter | UID hex_numbers SEMI | HOSTNAME hostname SEMI | CLIENT_HOSTNAME hostname SEMI | CLASS identifier SEMI | DYNAMIC_BOOTP SEMI */ struct lease * parse_lease_declaration(FILE *cfile) { char *val; int token; unsigned char addr[4]; int len = sizeof addr; int seenmask = 0; int seenbit; char tbuf[32]; static struct lease lease; /* Zap the lease structure... */ memset(&lease, 0, sizeof lease); /* Get the address for which the lease has been issued. */ if (!parse_numeric_aggregate(cfile, addr, &len, '.', 10, 8)) return NULL; memcpy(lease.ip_addr.iabuf, addr, len); lease.ip_addr.len = len; if (!parse_lbrace(cfile)) return NULL; do { token = next_token(&val, cfile); if (token == '}') break; else if (token == EOF) { parse_warn("unexpected end of file"); break; } strlcpy(tbuf, val, sizeof tbuf); /* Parse any of the times associated with the lease. */ if (token == TOK_STARTS || token == TOK_ENDS || token == TOK_TIMESTAMP) { time_t t; t = parse_date(cfile); switch (token) { case TOK_STARTS: seenbit = 1; lease.starts = t; break; case TOK_ENDS: seenbit = 2; lease.ends = t; break; case TOK_TIMESTAMP: seenbit = 4; lease.timestamp = t; break; default: /*NOTREACHED*/ seenbit = 0; break; } } else { switch (token) { /* Colon-separated hexadecimal octets... */ case TOK_UID: seenbit = 8; token = peek_token(&val, cfile); if (token == TOK_STRING) { token = next_token(&val, cfile); lease.uid_len = strlen(val); lease.uid = (unsigned char *) malloc(lease.uid_len); if (!lease.uid) { warning("no space for uid"); return NULL; } memcpy(lease.uid, val, lease.uid_len); parse_semi(cfile); } else { lease.uid_len = 0; lease.uid = parse_numeric_aggregate(cfile, NULL, &lease.uid_len, ':', 16, 8); if (!lease.uid) { warning("no space for uid"); return NULL; } if (lease.uid_len == 0) { lease.uid = NULL; parse_warn("zero-length uid"); seenbit = 0; break; } } if (!lease.uid) error("No memory for lease uid"); break; case TOK_CLASS: seenbit = 32; token = next_token(&val, cfile); if (!is_identifier(token)) { if (token != ';') skip_to_semi(cfile); return NULL; } /* for now, we aren't using this. */ break; case TOK_HARDWARE: seenbit = 64; parse_hardware_param(cfile, &lease.hardware_addr); break; case TOK_DYNAMIC_BOOTP: seenbit = 128; lease.flags |= BOOTP_LEASE; break; case TOK_ABANDONED: seenbit = 256; lease.flags |= ABANDONED_LEASE; break; case TOK_HOSTNAME: seenbit = 512; token = peek_token(&val, cfile); if (token == TOK_STRING) lease.hostname = parse_string(cfile); else lease.hostname = parse_host_name(cfile); if (!lease.hostname) { seenbit = 0; return NULL; } break; case TOK_CLIENT_HOSTNAME: seenbit = 1024; token = peek_token(&val, cfile); if (token == TOK_STRING) lease.client_hostname = parse_string(cfile); else lease.client_hostname = parse_host_name(cfile); break; default: skip_to_semi(cfile); seenbit = 0; return NULL; } if (token != TOK_HARDWARE && token != TOK_STRING) { token = next_token(&val, cfile); if (token != ';') { parse_warn("semicolon expected."); skip_to_semi(cfile); return NULL; } } } if (seenmask & seenbit) { parse_warn("Too many %s parameters in lease %s\n", tbuf, piaddr(lease.ip_addr)); } else seenmask |= seenbit; } while (1); return &lease; } /* * address-range-declaration :== ip-address ip-address SEMI * | DYNAMIC_BOOTP ip-address ip-address SEMI */ void parse_address_range(FILE *cfile, struct subnet *subnet) { struct iaddr low, high; unsigned char addr[4]; int len = sizeof addr, token, dynamic = 0; char *val; if ((token = peek_token(&val, cfile)) == TOK_DYNAMIC_BOOTP) { token = next_token(&val, cfile); subnet->group->dynamic_bootp = dynamic = 1; } /* Get the bottom address in the range... */ if (!parse_numeric_aggregate(cfile, addr, &len, '.', 10, 8)) return; memcpy(low.iabuf, addr, len); low.len = len; /* Only one address? */ token = peek_token(&val, cfile); if (token == ';') high = low; else { /* Get the top address in the range... */ if (!parse_numeric_aggregate(cfile, addr, &len, '.', 10, 8)) return; memcpy(high.iabuf, addr, len); high.len = len; } token = next_token(&val, cfile); if (token != ';') { parse_warn("semicolon expected."); skip_to_semi(cfile); return; } /* Create the new address range... */ new_address_range(low, high, subnet, dynamic); }