/* * @(#) RFC2367 PF_KEYv2 Key management API message parser * Copyright (C) 1999, 2000, 2001 Richard Guy Briggs * * 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. See . * * 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. * * RCSID $Id: pfkey_v2_ext_process.c,v 1.3 2004/06/13 19:57:50 as Exp $ */ /* * Template from klips/net/ipsec/ipsec/ipsec_netlink.c. */ char pfkey_v2_ext_process_c_version[] = "$Id: pfkey_v2_ext_process.c,v 1.3 2004/06/13 19:57:50 as Exp $"; #include #include #include /* printk() */ #include "freeswan/ipsec_param.h" #ifdef MALLOC_SLAB # include /* kmalloc() */ #else /* MALLOC_SLAB */ # include /* kmalloc() */ #endif /* MALLOC_SLAB */ #include /* error codes */ #include /* size_t */ #include /* mark_bh */ #include /* struct device, and other headers */ #include /* eth_type_trans */ #include /* struct iphdr */ #include #include #include #ifdef SPINLOCK # ifdef SPINLOCK_23 # include /* *lock* */ # else /* SPINLOCK_23 */ # include /* *lock* */ # endif /* SPINLOCK_23 */ #endif /* SPINLOCK */ #ifdef NET_21 # include # include # define ip_chk_addr inet_addr_type # define IS_MYADDR RTN_LOCAL #endif #include #include #ifdef NETLINK_SOCK # include #else # include #endif #include /* get_random_bytes() */ #include "freeswan/radij.h" #include "freeswan/ipsec_encap.h" #include "freeswan/ipsec_sa.h" #include "freeswan/ipsec_radij.h" #include "freeswan/ipsec_xform.h" #include "freeswan/ipsec_ah.h" #include "freeswan/ipsec_esp.h" #include "freeswan/ipsec_tunnel.h" #include "freeswan/ipsec_rcv.h" #include "freeswan/ipcomp.h" #include #include #include "freeswan/ipsec_proto.h" #include "freeswan/ipsec_alg.h" #define SENDERR(_x) do { error = -(_x); goto errlab; } while (0) int pfkey_sa_process(struct sadb_ext *pfkey_ext, struct pfkey_extracted_data* extr) { struct sadb_sa *pfkey_sa = (struct sadb_sa *)pfkey_ext; int error = 0; struct ipsec_sa* ipsp; KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_sa_process: .\n"); if(!extr || !extr->ips) { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_sa_process: " "extr or extr->ips is NULL, fatal\n"); SENDERR(EINVAL); } switch(pfkey_ext->sadb_ext_type) { case SADB_EXT_SA: ipsp = extr->ips; break; case SADB_X_EXT_SA2: if(extr->ips2 == NULL) { extr->ips2 = ipsec_sa_alloc(&error); /* pass error var by pointer */ } if(extr->ips2 == NULL) { SENDERR(-error); } ipsp = extr->ips2; break; default: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_sa_process: " "invalid exttype=%d.\n", pfkey_ext->sadb_ext_type); SENDERR(EINVAL); } ipsp->ips_said.spi = pfkey_sa->sadb_sa_spi; ipsp->ips_replaywin = pfkey_sa->sadb_sa_replay; ipsp->ips_state = pfkey_sa->sadb_sa_state; ipsp->ips_flags = pfkey_sa->sadb_sa_flags; ipsp->ips_replaywin_lastseq = ipsp->ips_replaywin_bitmap = 0; ipsp->ips_ref_rel = pfkey_sa->sadb_x_sa_ref; switch(ipsp->ips_said.proto) { case IPPROTO_AH: ipsp->ips_authalg = pfkey_sa->sadb_sa_auth; ipsp->ips_encalg = SADB_EALG_NONE; break; case IPPROTO_ESP: ipsp->ips_authalg = pfkey_sa->sadb_sa_auth; ipsp->ips_encalg = pfkey_sa->sadb_sa_encrypt; #ifdef CONFIG_IPSEC_ALG ipsec_alg_sa_init(ipsp); #endif /* CONFIG_IPSEC_ALG */ break; case IPPROTO_IPIP: ipsp->ips_authalg = AH_NONE; ipsp->ips_encalg = ESP_NONE; break; #ifdef CONFIG_IPSEC_IPCOMP case IPPROTO_COMP: ipsp->ips_authalg = AH_NONE; ipsp->ips_encalg = pfkey_sa->sadb_sa_encrypt; break; #endif /* CONFIG_IPSEC_IPCOMP */ case IPPROTO_INT: ipsp->ips_authalg = AH_NONE; ipsp->ips_encalg = ESP_NONE; break; case 0: break; default: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_sa_process: " "unknown proto=%d.\n", ipsp->ips_said.proto); SENDERR(EINVAL); } errlab: return error; } int pfkey_lifetime_process(struct sadb_ext *pfkey_ext, struct pfkey_extracted_data* extr) { int error = 0; struct sadb_lifetime *pfkey_lifetime = (struct sadb_lifetime *)pfkey_ext; KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_lifetime_process: .\n"); if(!extr || !extr->ips) { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_lifetime_process: " "extr or extr->ips is NULL, fatal\n"); SENDERR(EINVAL); } switch(pfkey_lifetime->sadb_lifetime_exttype) { case SADB_EXT_LIFETIME_CURRENT: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_lifetime_process: " "lifetime_current not supported yet.\n"); SENDERR(EINVAL); break; case SADB_EXT_LIFETIME_HARD: ipsec_lifetime_update_hard(&extr->ips->ips_life.ipl_allocations, pfkey_lifetime->sadb_lifetime_allocations); ipsec_lifetime_update_hard(&extr->ips->ips_life.ipl_bytes, pfkey_lifetime->sadb_lifetime_bytes); ipsec_lifetime_update_hard(&extr->ips->ips_life.ipl_addtime, pfkey_lifetime->sadb_lifetime_addtime); ipsec_lifetime_update_hard(&extr->ips->ips_life.ipl_usetime, pfkey_lifetime->sadb_lifetime_usetime); break; case SADB_EXT_LIFETIME_SOFT: ipsec_lifetime_update_soft(&extr->ips->ips_life.ipl_allocations, pfkey_lifetime->sadb_lifetime_allocations); ipsec_lifetime_update_soft(&extr->ips->ips_life.ipl_bytes, pfkey_lifetime->sadb_lifetime_bytes); ipsec_lifetime_update_soft(&extr->ips->ips_life.ipl_addtime, pfkey_lifetime->sadb_lifetime_addtime); ipsec_lifetime_update_soft(&extr->ips->ips_life.ipl_usetime, pfkey_lifetime->sadb_lifetime_usetime); break; default: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_lifetime_process: " "invalid exttype=%d.\n", pfkey_ext->sadb_ext_type); SENDERR(EINVAL); } errlab: return error; } int pfkey_address_process(struct sadb_ext *pfkey_ext, struct pfkey_extracted_data* extr) { int error = 0; int saddr_len = 0; char ipaddr_txt[ADDRTOA_BUF]; unsigned char **sap; unsigned short * portp = 0; struct sadb_address *pfkey_address = (struct sadb_address *)pfkey_ext; struct sockaddr* s = (struct sockaddr*)((char*)pfkey_address + sizeof(*pfkey_address)); struct ipsec_sa* ipsp; KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process:\n"); if(!extr || !extr->ips) { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "extr or extr->ips is NULL, fatal\n"); SENDERR(EINVAL); } switch(s->sa_family) { case AF_INET: saddr_len = sizeof(struct sockaddr_in); addrtoa(((struct sockaddr_in*)s)->sin_addr, 0, ipaddr_txt, sizeof(ipaddr_txt)); KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "found address family=%d, AF_INET, %s.\n", s->sa_family, ipaddr_txt); break; #if defined(CONFIG_IPV6) || defined(CONFIG_IPV6_MODULE) case AF_INET6: saddr_len = sizeof(struct sockaddr_in6); break; #endif /* defined(CONFIG_IPV6) || defined(CONFIG_IPV6_MODULE) */ default: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "s->sa_family=%d not supported.\n", s->sa_family); SENDERR(EPFNOSUPPORT); } switch(pfkey_address->sadb_address_exttype) { case SADB_EXT_ADDRESS_SRC: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "found src address.\n"); sap = (unsigned char **)&(extr->ips->ips_addr_s); extr->ips->ips_addr_s_size = saddr_len; break; case SADB_EXT_ADDRESS_DST: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "found dst address.\n"); sap = (unsigned char **)&(extr->ips->ips_addr_d); extr->ips->ips_addr_d_size = saddr_len; break; case SADB_EXT_ADDRESS_PROXY: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "found proxy address.\n"); sap = (unsigned char **)&(extr->ips->ips_addr_p); extr->ips->ips_addr_p_size = saddr_len; break; case SADB_X_EXT_ADDRESS_DST2: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "found 2nd dst address.\n"); if(extr->ips2 == NULL) { extr->ips2 = ipsec_sa_alloc(&error); /* pass error var by pointer */ } if(extr->ips2 == NULL) { SENDERR(-error); } sap = (unsigned char **)&(extr->ips2->ips_addr_d); extr->ips2->ips_addr_d_size = saddr_len; break; case SADB_X_EXT_ADDRESS_SRC_FLOW: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "found src flow address.\n"); if(pfkey_alloc_eroute(&(extr->eroute)) == ENOMEM) { SENDERR(ENOMEM); } sap = (unsigned char **)&(extr->eroute->er_eaddr.sen_ip_src); portp = &(extr->eroute->er_eaddr.sen_sport); break; case SADB_X_EXT_ADDRESS_DST_FLOW: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "found dst flow address.\n"); if(pfkey_alloc_eroute(&(extr->eroute)) == ENOMEM) { SENDERR(ENOMEM); } sap = (unsigned char **)&(extr->eroute->er_eaddr.sen_ip_dst); portp = &(extr->eroute->er_eaddr.sen_dport); break; case SADB_X_EXT_ADDRESS_SRC_MASK: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "found src mask address.\n"); if(pfkey_alloc_eroute(&(extr->eroute)) == ENOMEM) { SENDERR(ENOMEM); } sap = (unsigned char **)&(extr->eroute->er_emask.sen_ip_src); portp = &(extr->eroute->er_emask.sen_sport); break; case SADB_X_EXT_ADDRESS_DST_MASK: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "found dst mask address.\n"); if(pfkey_alloc_eroute(&(extr->eroute)) == ENOMEM) { SENDERR(ENOMEM); } sap = (unsigned char **)&(extr->eroute->er_emask.sen_ip_dst); portp = &(extr->eroute->er_emask.sen_dport); break; #ifdef NAT_TRAVERSAL case SADB_X_EXT_NAT_T_OA: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "found NAT-OA address.\n"); sap = (unsigned char **)&(extr->ips->ips_natt_oa); extr->ips->ips_natt_oa_size = saddr_len; break; #endif default: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "unrecognised ext_type=%d.\n", pfkey_address->sadb_address_exttype); SENDERR(EINVAL); } switch(pfkey_address->sadb_address_exttype) { case SADB_EXT_ADDRESS_SRC: case SADB_EXT_ADDRESS_DST: case SADB_EXT_ADDRESS_PROXY: case SADB_X_EXT_ADDRESS_DST2: #ifdef NAT_TRAVERSAL case SADB_X_EXT_NAT_T_OA: #endif KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "allocating %d bytes for saddr.\n", saddr_len); if(!(*sap = kmalloc(saddr_len, GFP_KERNEL))) { SENDERR(ENOMEM); } memcpy(*sap, s, saddr_len); break; default: if(s->sa_family != AF_INET) { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "s->sa_family=%d not supported.\n", s->sa_family); SENDERR(EPFNOSUPPORT); } (unsigned long)(*sap) = ((struct sockaddr_in*)s)->sin_addr.s_addr; if (portp != 0) *portp = ((struct sockaddr_in*)s)->sin_port; #ifdef CONFIG_IPSEC_DEBUG if(extr->eroute) { char buf1[64], buf2[64]; if (debug_pfkey) { subnettoa(extr->eroute->er_eaddr.sen_ip_src, extr->eroute->er_emask.sen_ip_src, 0, buf1, sizeof(buf1)); subnettoa(extr->eroute->er_eaddr.sen_ip_dst, extr->eroute->er_emask.sen_ip_dst, 0, buf2, sizeof(buf2)); KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_parse: " "extr->eroute set to %s:%d->%s:%d\n", buf1, ntohs(extr->eroute->er_eaddr.sen_sport), buf2, ntohs(extr->eroute->er_eaddr.sen_dport)); } } #endif /* CONFIG_IPSEC_DEBUG */ } ipsp = extr->ips; switch(pfkey_address->sadb_address_exttype) { case SADB_X_EXT_ADDRESS_DST2: ipsp = extr->ips2; case SADB_EXT_ADDRESS_DST: if(s->sa_family == AF_INET) { ipsp->ips_said.dst.s_addr = ((struct sockaddr_in*)(ipsp->ips_addr_d))->sin_addr.s_addr; addrtoa(((struct sockaddr_in*)(ipsp->ips_addr_d))->sin_addr, 0, ipaddr_txt, sizeof(ipaddr_txt)); KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "ips_said.dst set to %s.\n", ipaddr_txt); } else { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: " "uh, ips_said.dst doesn't do address family=%d yet, said will be invalid.\n", s->sa_family); } default: break; } /* XXX check if port!=0 */ KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_address_process: successful.\n"); errlab: return error; } int pfkey_key_process(struct sadb_ext *pfkey_ext, struct pfkey_extracted_data* extr) { int error = 0; struct sadb_key *pfkey_key = (struct sadb_key *)pfkey_ext; KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_key_process: .\n"); if(!extr || !extr->ips) { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_key_process: " "extr or extr->ips is NULL, fatal\n"); SENDERR(EINVAL); } switch(pfkey_key->sadb_key_exttype) { case SADB_EXT_KEY_AUTH: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_key_process: " "allocating %d bytes for authkey.\n", DIVUP(pfkey_key->sadb_key_bits, 8)); if(!(extr->ips->ips_key_a = kmalloc(DIVUP(pfkey_key->sadb_key_bits, 8), GFP_KERNEL))) { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_key_process: " "memory allocation error.\n"); SENDERR(ENOMEM); } extr->ips->ips_key_bits_a = pfkey_key->sadb_key_bits; extr->ips->ips_key_a_size = DIVUP(pfkey_key->sadb_key_bits, 8); memcpy(extr->ips->ips_key_a, (char*)pfkey_key + sizeof(struct sadb_key), extr->ips->ips_key_a_size); break; case SADB_EXT_KEY_ENCRYPT: /* Key(s) */ KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_key_process: " "allocating %d bytes for enckey.\n", DIVUP(pfkey_key->sadb_key_bits, 8)); if(!(extr->ips->ips_key_e = kmalloc(DIVUP(pfkey_key->sadb_key_bits, 8), GFP_KERNEL))) { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_key_process: " "memory allocation error.\n"); SENDERR(ENOMEM); } extr->ips->ips_key_bits_e = pfkey_key->sadb_key_bits; extr->ips->ips_key_e_size = DIVUP(pfkey_key->sadb_key_bits, 8); memcpy(extr->ips->ips_key_e, (char*)pfkey_key + sizeof(struct sadb_key), extr->ips->ips_key_e_size); break; default: SENDERR(EINVAL); } KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_key_process: " "success.\n"); errlab: return error; } int pfkey_ident_process(struct sadb_ext *pfkey_ext, struct pfkey_extracted_data* extr) { int error = 0; struct sadb_ident *pfkey_ident = (struct sadb_ident *)pfkey_ext; int data_len; KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_ident_process: .\n"); if(!extr || !extr->ips) { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_ident_process: " "extr or extr->ips is NULL, fatal\n"); SENDERR(EINVAL); } switch(pfkey_ident->sadb_ident_exttype) { case SADB_EXT_IDENTITY_SRC: data_len = pfkey_ident->sadb_ident_len * IPSEC_PFKEYv2_ALIGN - sizeof(struct sadb_ident); extr->ips->ips_ident_s.type = pfkey_ident->sadb_ident_type; extr->ips->ips_ident_s.id = pfkey_ident->sadb_ident_id; extr->ips->ips_ident_s.len = pfkey_ident->sadb_ident_len; if(data_len) { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_ident_process: " "allocating %d bytes for ident_s.\n", data_len); if(!(extr->ips->ips_ident_s.data = kmalloc(data_len, GFP_KERNEL))) { SENDERR(ENOMEM); } memcpy(extr->ips->ips_ident_s.data, (char*)pfkey_ident + sizeof(struct sadb_ident), data_len); } else { extr->ips->ips_ident_s.data = NULL; } break; case SADB_EXT_IDENTITY_DST: /* Identity(ies) */ data_len = pfkey_ident->sadb_ident_len * IPSEC_PFKEYv2_ALIGN - sizeof(struct sadb_ident); extr->ips->ips_ident_d.type = pfkey_ident->sadb_ident_type; extr->ips->ips_ident_d.id = pfkey_ident->sadb_ident_id; extr->ips->ips_ident_d.len = pfkey_ident->sadb_ident_len; if(data_len) { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_ident_process: " "allocating %d bytes for ident_d.\n", data_len); if(!(extr->ips->ips_ident_d.data = kmalloc(data_len, GFP_KERNEL))) { SENDERR(ENOMEM); } memcpy(extr->ips->ips_ident_d.data, (char*)pfkey_ident + sizeof(struct sadb_ident), data_len); } else { extr->ips->ips_ident_d.data = NULL; } break; default: SENDERR(EINVAL); } errlab: return error; } int pfkey_sens_process(struct sadb_ext *pfkey_ext, struct pfkey_extracted_data* extr) { int error = 0; KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_sens_process: " "Sorry, I can't process exttype=%d yet.\n", pfkey_ext->sadb_ext_type); SENDERR(EINVAL); /* don't process these yet */ errlab: return error; } int pfkey_prop_process(struct sadb_ext *pfkey_ext, struct pfkey_extracted_data* extr) { int error = 0; KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_prop_process: " "Sorry, I can't process exttype=%d yet.\n", pfkey_ext->sadb_ext_type); SENDERR(EINVAL); /* don't process these yet */ errlab: return error; } int pfkey_supported_process(struct sadb_ext *pfkey_ext, struct pfkey_extracted_data* extr) { int error = 0; KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_supported_process: " "Sorry, I can't process exttype=%d yet.\n", pfkey_ext->sadb_ext_type); SENDERR(EINVAL); /* don't process these yet */ errlab: return error; } int pfkey_spirange_process(struct sadb_ext *pfkey_ext, struct pfkey_extracted_data* extr) { int error = 0; KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_spirange_process: .\n"); /* errlab: */ return error; } int pfkey_x_kmprivate_process(struct sadb_ext *pfkey_ext, struct pfkey_extracted_data* extr) { int error = 0; KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_x_kmprivate_process: " "Sorry, I can't process exttype=%d yet.\n", pfkey_ext->sadb_ext_type); SENDERR(EINVAL); /* don't process these yet */ errlab: return error; } int pfkey_x_satype_process(struct sadb_ext *pfkey_ext, struct pfkey_extracted_data* extr) { int error = 0; struct sadb_x_satype *pfkey_x_satype = (struct sadb_x_satype *)pfkey_ext; KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_x_satype_process: .\n"); if(!extr || !extr->ips) { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_x_satype_process: " "extr or extr->ips is NULL, fatal\n"); SENDERR(EINVAL); } if(extr->ips2 == NULL) { extr->ips2 = ipsec_sa_alloc(&error); /* pass error var by pointer */ } if(extr->ips2 == NULL) { SENDERR(-error); } if(!(extr->ips2->ips_said.proto = satype2proto(pfkey_x_satype->sadb_x_satype_satype))) { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_x_satype_process: " "proto lookup from satype=%d failed.\n", pfkey_x_satype->sadb_x_satype_satype); SENDERR(EINVAL); } KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_x_satype_process: " "protocol==%d decoded from satype==%d(%s).\n", extr->ips2->ips_said.proto, pfkey_x_satype->sadb_x_satype_satype, satype2name(pfkey_x_satype->sadb_x_satype_satype)); errlab: return error; } #ifdef CONFIG_IPSEC_NAT_TRAVERSAL int pfkey_x_nat_t_type_process(struct sadb_ext *pfkey_ext, struct pfkey_extracted_data* extr) { int error = 0; struct sadb_x_nat_t_type *pfkey_x_nat_t_type = (struct sadb_x_nat_t_type *)pfkey_ext; if(!pfkey_x_nat_t_type) { printk("klips_debug:pfkey_x_nat_t_type_process: " "null pointer passed in\n"); SENDERR(EINVAL); } KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_x_nat_t_type_process: %d.\n", pfkey_x_nat_t_type->sadb_x_nat_t_type_type); if(!extr || !extr->ips) { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_nat_t_type_process: " "extr or extr->ips is NULL, fatal\n"); SENDERR(EINVAL); } switch(pfkey_x_nat_t_type->sadb_x_nat_t_type_type) { case ESPINUDP_WITH_NON_IKE: /* with Non-IKE */ case ESPINUDP_WITH_NON_ESP: /* with Non-ESP */ extr->ips->ips_natt_type = pfkey_x_nat_t_type->sadb_x_nat_t_type_type; break; default: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_x_nat_t_type_process: " "unknown type %d.\n", pfkey_x_nat_t_type->sadb_x_nat_t_type_type); SENDERR(EINVAL); break; } errlab: return error; } int pfkey_x_nat_t_port_process(struct sadb_ext *pfkey_ext, struct pfkey_extracted_data* extr) { int error = 0; struct sadb_x_nat_t_port *pfkey_x_nat_t_port = (struct sadb_x_nat_t_port *)pfkey_ext; if(!pfkey_x_nat_t_port) { printk("klips_debug:pfkey_x_nat_t_port_process: " "null pointer passed in\n"); SENDERR(EINVAL); } KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_x_nat_t_port_process: %d/%d.\n", pfkey_x_nat_t_port->sadb_x_nat_t_port_exttype, pfkey_x_nat_t_port->sadb_x_nat_t_port_port); if(!extr || !extr->ips) { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_nat_t_type_process: " "extr or extr->ips is NULL, fatal\n"); SENDERR(EINVAL); } switch(pfkey_x_nat_t_port->sadb_x_nat_t_port_exttype) { case SADB_X_EXT_NAT_T_SPORT: extr->ips->ips_natt_sport = pfkey_x_nat_t_port->sadb_x_nat_t_port_port; break; case SADB_X_EXT_NAT_T_DPORT: extr->ips->ips_natt_dport = pfkey_x_nat_t_port->sadb_x_nat_t_port_port; break; default: KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_x_nat_t_port_process: " "unknown exttype %d.\n", pfkey_x_nat_t_port->sadb_x_nat_t_port_exttype); SENDERR(EINVAL); break; } errlab: return error; } #endif int pfkey_x_debug_process(struct sadb_ext *pfkey_ext, struct pfkey_extracted_data* extr) { int error = 0; struct sadb_x_debug *pfkey_x_debug = (struct sadb_x_debug *)pfkey_ext; if(!pfkey_x_debug) { printk("klips_debug:pfkey_x_debug_process: " "null pointer passed in\n"); SENDERR(EINVAL); } KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_x_debug_process: .\n"); #ifdef CONFIG_IPSEC_DEBUG if(pfkey_x_debug->sadb_x_debug_netlink >> (sizeof(pfkey_x_debug->sadb_x_debug_netlink) * 8 - 1)) { pfkey_x_debug->sadb_x_debug_netlink &= ~(1 << (sizeof(pfkey_x_debug->sadb_x_debug_netlink) * 8 -1)); debug_tunnel |= pfkey_x_debug->sadb_x_debug_tunnel; debug_netlink |= pfkey_x_debug->sadb_x_debug_netlink; debug_xform |= pfkey_x_debug->sadb_x_debug_xform; debug_eroute |= pfkey_x_debug->sadb_x_debug_eroute; debug_spi |= pfkey_x_debug->sadb_x_debug_spi; debug_radij |= pfkey_x_debug->sadb_x_debug_radij; debug_esp |= pfkey_x_debug->sadb_x_debug_esp; debug_ah |= pfkey_x_debug->sadb_x_debug_ah; debug_rcv |= pfkey_x_debug->sadb_x_debug_rcv; debug_pfkey |= pfkey_x_debug->sadb_x_debug_pfkey; #ifdef CONFIG_IPSEC_IPCOMP sysctl_ipsec_debug_ipcomp |= pfkey_x_debug->sadb_x_debug_ipcomp; #endif /* CONFIG_IPSEC_IPCOMP */ sysctl_ipsec_debug_verbose |= pfkey_x_debug->sadb_x_debug_verbose; KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_x_debug_process: " "set\n"); } else { KLIPS_PRINT(debug_pfkey, "klips_debug:pfkey_x_debug_process: " "unset\n"); debug_tunnel &= pfkey_x_debug->sadb_x_debug_tunnel; debug_netlink &= pfkey_x_debug->sadb_x_debug_netlink; debug_xform &= pfkey_x_debug->sadb_x_debug_xform; debug_eroute &= pfkey_x_debug->sadb_x_debug_eroute; debug_spi &= pfkey_x_debug->sadb_x_debug_spi; debug_radij &= pfkey_x_debug->sadb_x_debug_radij; debug_esp &= pfkey_x_debug->sadb_x_debug_esp; debug_ah &= pfkey_x_debug->sadb_x_debug_ah; debug_rcv &= pfkey_x_debug->sadb_x_debug_rcv; debug_pfkey &= pfkey_x_debug->sadb_x_debug_pfkey; #ifdef CONFIG_IPSEC_IPCOMP sysctl_ipsec_debug_ipcomp &= pfkey_x_debug->sadb_x_debug_ipcomp; #endif /* CONFIG_IPSEC_IPCOMP */ sysctl_ipsec_debug_verbose &= pfkey_x_debug->sadb_x_debug_verbose; } #else /* CONFIG_IPSEC_DEBUG */ printk("klips_debug:pfkey_x_debug_process: " "debugging not enabled\n"); SENDERR(EINVAL); #endif /* CONFIG_IPSEC_DEBUG */ errlab: return error; }