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strongswan/src/libcharon/encoding/message.c

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/*
* Copyright (C) 2006-2018 Tobias Brunner
* Copyright (C) 2005-2010 Martin Willi
* Copyright (C) 2010 revosec AG
* Copyright (C) 2006 Daniel Roethlisberger
* Copyright (C) 2005 Jan Hutter
* HSR Hochschule fuer Technik Rapperswil
*
* 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 <http://www.fsf.org/copyleft/gpl.txt>.
*
* 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.
*/
#include <stdlib.h>
#include <string.h>
#include "message.h"
#include <library.h>
#include <bio/bio_writer.h>
#include <collections/array.h>
#include <daemon.h>
#include <sa/ikev1/keymat_v1.h>
#include <encoding/generator.h>
#include <encoding/parser.h>
#include <encoding/payloads/encodings.h>
#include <encoding/payloads/payload.h>
#include <encoding/payloads/hash_payload.h>
#include <encoding/payloads/encrypted_payload.h>
#include <encoding/payloads/encrypted_fragment_payload.h>
#include <encoding/payloads/unknown_payload.h>
#include <encoding/payloads/cp_payload.h>
#include <encoding/payloads/fragment_payload.h>
/**
* Max number of notify payloads per IKEv2 message
*/
#define MAX_NOTIFY_PAYLOADS 20
/**
* Max number of delete payloads per IKEv2 message
*/
#define MAX_DELETE_PAYLOADS 20
/**
* Max number of certificate payloads per IKEv2 message
*/
#define MAX_CERT_PAYLOADS 8
/**
* Max number of vendor ID payloads per IKEv2 message
*/
#define MAX_VID_PAYLOADS 20
/**
* Max number of certificate request payloads per IKEv1 message
*/
#define MAX_CERTREQ_PAYLOADS 20
/**
* Max number of NAT-D payloads per IKEv1 message
*/
#define MAX_NAT_D_PAYLOADS 10
/**
* A payload rule defines the rules for a payload
* in a specific message rule. It defines if and how
* many times a payload must/can occur in a message
* and if it must be encrypted.
*/
typedef struct {
/* Payload type */
payload_type_t type;
/* Minimal occurrence of this payload. */
size_t min_occurrence;
/* Max occurrence of this payload. */
size_t max_occurrence;
/* TRUE if payload must be encrypted */
bool encrypted;
/* If payload occurs, the message rule is fulfilled */
bool sufficient;
} payload_rule_t;
/**
* payload ordering structure allows us to reorder payloads according to RFC.
*/
typedef struct {
/** payload type */
payload_type_t type;
/** notify type, if payload == PLV2_NOTIFY */
notify_type_t notify;
} payload_order_t;
/**
* A message rule defines the kind of a message,
* if it has encrypted contents and a list
* of payload ordering rules and payload parsing rules.
*/
typedef struct {
/** Type of message. */
exchange_type_t exchange_type;
/** Is message a request or response. */
bool is_request;
/** Message contains encrypted payloads. */
bool encrypted;
/** Number of payload rules which will follow */
int rule_count;
/** Pointer to first payload rule */
payload_rule_t *rules;
/** Number of payload order rules */
int order_count;
/** payload ordering rules */
payload_order_t *order;
} message_rule_t;
/**
* Message rule for IKE_SA_INIT from initiator.
*/
static payload_rule_t ike_sa_init_i_rules[] = {
/* payload type min max encr suff */
{PLV2_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, FALSE, FALSE},
{PLV2_SECURITY_ASSOCIATION, 1, 1, FALSE, FALSE},
{PLV2_KEY_EXCHANGE, 1, 1, FALSE, FALSE},
{PLV2_NONCE, 1, 1, FALSE, FALSE},
{PLV2_VENDOR_ID, 0, MAX_VID_PAYLOADS, FALSE, FALSE},
};
/**
* payload order for IKE_SA_INIT initiator
*/
static payload_order_t ike_sa_init_i_order[] = {
/* payload type notify type */
{PLV2_NOTIFY, COOKIE},
{PLV2_SECURITY_ASSOCIATION, 0},
{PLV2_KEY_EXCHANGE, 0},
{PLV2_NONCE, 0},
{PLV2_NOTIFY, NAT_DETECTION_SOURCE_IP},
{PLV2_NOTIFY, NAT_DETECTION_DESTINATION_IP},
{PLV2_NOTIFY, 0},
{PLV2_VENDOR_ID, 0},
};
/**
* Message rule for IKE_SA_INIT from responder.
*/
static payload_rule_t ike_sa_init_r_rules[] = {
/* payload type min max encr suff */
{PLV2_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, FALSE, TRUE},
{PLV2_SECURITY_ASSOCIATION, 1, 1, FALSE, FALSE},
{PLV2_KEY_EXCHANGE, 1, 1, FALSE, FALSE},
{PLV2_NONCE, 1, 1, FALSE, FALSE},
{PLV2_CERTREQ, 0, MAX_CERTREQ_PAYLOADS, FALSE, FALSE},
{PLV2_VENDOR_ID, 0, MAX_VID_PAYLOADS, FALSE, FALSE},
};
/**
* payload order for IKE_SA_INIT responder
*/
static payload_order_t ike_sa_init_r_order[] = {
/* payload type notify type */
{PLV2_SECURITY_ASSOCIATION, 0},
{PLV2_KEY_EXCHANGE, 0},
{PLV2_NONCE, 0},
{PLV2_NOTIFY, NAT_DETECTION_SOURCE_IP},
{PLV2_NOTIFY, NAT_DETECTION_DESTINATION_IP},
{PLV2_NOTIFY, HTTP_CERT_LOOKUP_SUPPORTED},
{PLV2_CERTREQ, 0},
{PLV2_NOTIFY, 0},
{PLV2_VENDOR_ID, 0},
};
/**
* Message rule for IKE_AUTH from initiator.
*/
static payload_rule_t ike_auth_i_rules[] = {
/* payload type min max encr suff */
{PLV2_FRAGMENT, 0, 1, TRUE, TRUE},
{PLV2_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, TRUE, FALSE},
{PLV2_EAP, 0, 1, TRUE, TRUE},
{PLV2_AUTH, 0, 1, TRUE, TRUE},
{PLV2_ID_INITIATOR, 0, 1, TRUE, FALSE},
{PLV2_CERTIFICATE, 0, MAX_CERT_PAYLOADS, TRUE, FALSE},
{PLV2_CERTREQ, 0, MAX_CERTREQ_PAYLOADS, TRUE, FALSE},
{PLV2_ID_RESPONDER, 0, 1, TRUE, FALSE},
#ifdef ME
{PLV2_SECURITY_ASSOCIATION, 0, 1, TRUE, FALSE},
{PLV2_TS_INITIATOR, 0, 1, TRUE, FALSE},
{PLV2_TS_RESPONDER, 0, 1, TRUE, FALSE},
#else
{PLV2_SECURITY_ASSOCIATION, 0, 1, TRUE, FALSE},
{PLV2_TS_INITIATOR, 0, 1, TRUE, FALSE},
{PLV2_TS_RESPONDER, 0, 1, TRUE, FALSE},
#endif /* ME */
{PLV2_CONFIGURATION, 0, 1, TRUE, FALSE},
{PLV2_VENDOR_ID, 0, MAX_VID_PAYLOADS, TRUE, FALSE},
};
/**
* payload order for IKE_AUTH initiator
*/
static payload_order_t ike_auth_i_order[] = {
/* payload type notify type */
{PLV2_ID_INITIATOR, 0},
{PLV2_CERTIFICATE, 0},
{PLV2_NOTIFY, INITIAL_CONTACT},
{PLV2_NOTIFY, HTTP_CERT_LOOKUP_SUPPORTED},
{PLV2_CERTREQ, 0},
{PLV2_ID_RESPONDER, 0},
{PLV2_AUTH, 0},
{PLV2_EAP, 0},
{PLV2_CONFIGURATION, 0},
{PLV2_NOTIFY, IPCOMP_SUPPORTED},
{PLV2_NOTIFY, USE_TRANSPORT_MODE},
{PLV2_NOTIFY, ESP_TFC_PADDING_NOT_SUPPORTED},
{PLV2_NOTIFY, NON_FIRST_FRAGMENTS_ALSO},
{PLV2_SECURITY_ASSOCIATION, 0},
{PLV2_TS_INITIATOR, 0},
{PLV2_TS_RESPONDER, 0},
{PLV2_NOTIFY, MOBIKE_SUPPORTED},
{PLV2_NOTIFY, ADDITIONAL_IP4_ADDRESS},
{PLV2_NOTIFY, ADDITIONAL_IP6_ADDRESS},
{PLV2_NOTIFY, NO_ADDITIONAL_ADDRESSES},
{PLV2_NOTIFY, 0},
{PLV2_VENDOR_ID, 0},
{PLV2_FRAGMENT, 0},
};
/**
* Message rule for IKE_AUTH from responder.
*/
static payload_rule_t ike_auth_r_rules[] = {
/* payload type min max encr suff */
{PLV2_FRAGMENT, 0, 1, TRUE, TRUE},
{PLV2_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, TRUE, TRUE},
{PLV2_EAP, 0, 1, TRUE, TRUE},
{PLV2_AUTH, 0, 1, TRUE, TRUE},
{PLV2_CERTIFICATE, 0, MAX_CERT_PAYLOADS, TRUE, FALSE},
{PLV2_ID_RESPONDER, 0, 1, TRUE, FALSE},
{PLV2_SECURITY_ASSOCIATION, 0, 1, TRUE, FALSE},
{PLV2_TS_INITIATOR, 0, 1, TRUE, FALSE},
{PLV2_TS_RESPONDER, 0, 1, TRUE, FALSE},
{PLV2_CONFIGURATION, 0, 1, TRUE, FALSE},
{PLV2_VENDOR_ID, 0, MAX_VID_PAYLOADS, TRUE, FALSE},
};
/**
* payload order for IKE_AUTH responder
*/
static payload_order_t ike_auth_r_order[] = {
/* payload type notify type */
{PLV2_ID_RESPONDER, 0},
{PLV2_CERTIFICATE, 0},
{PLV2_AUTH, 0},
{PLV2_EAP, 0},
{PLV2_CONFIGURATION, 0},
{PLV2_NOTIFY, IPCOMP_SUPPORTED},
{PLV2_NOTIFY, USE_TRANSPORT_MODE},
{PLV2_NOTIFY, ESP_TFC_PADDING_NOT_SUPPORTED},
{PLV2_NOTIFY, NON_FIRST_FRAGMENTS_ALSO},
{PLV2_SECURITY_ASSOCIATION, 0},
{PLV2_TS_INITIATOR, 0},
{PLV2_TS_RESPONDER, 0},
{PLV2_NOTIFY, AUTH_LIFETIME},
{PLV2_NOTIFY, MOBIKE_SUPPORTED},
{PLV2_NOTIFY, ADDITIONAL_IP4_ADDRESS},
{PLV2_NOTIFY, ADDITIONAL_IP6_ADDRESS},
{PLV2_NOTIFY, NO_ADDITIONAL_ADDRESSES},
{PLV2_NOTIFY, 0},
{PLV2_VENDOR_ID, 0},
{PLV2_FRAGMENT, 0},
};
/**
* Message rule for INFORMATIONAL from initiator.
*/
static payload_rule_t informational_i_rules[] = {
/* payload type min max encr suff */
{PLV2_FRAGMENT, 0, 1, TRUE, TRUE},
{PLV2_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, TRUE, FALSE},
{PLV2_CONFIGURATION, 0, 1, TRUE, FALSE},
{PLV2_DELETE, 0, MAX_DELETE_PAYLOADS, TRUE, FALSE},
{PLV2_VENDOR_ID, 0, MAX_VID_PAYLOADS, TRUE, FALSE},
};
/**
* payload order for INFORMATIONAL initiator
*/
static payload_order_t informational_i_order[] = {
/* payload type notify type */
{PLV2_NOTIFY, UPDATE_SA_ADDRESSES},
{PLV2_NOTIFY, NAT_DETECTION_SOURCE_IP},
{PLV2_NOTIFY, NAT_DETECTION_DESTINATION_IP},
{PLV2_NOTIFY, COOKIE2},
{PLV2_NOTIFY, 0},
{PLV2_DELETE, 0},
{PLV2_CONFIGURATION, 0},
{PLV2_FRAGMENT, 0},
};
/**
* Message rule for INFORMATIONAL from responder.
*/
static payload_rule_t informational_r_rules[] = {
/* payload type min max encr suff */
{PLV2_FRAGMENT, 0, 1, TRUE, TRUE},
{PLV2_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, TRUE, FALSE},
{PLV2_CONFIGURATION, 0, 1, TRUE, FALSE},
{PLV2_DELETE, 0, MAX_DELETE_PAYLOADS, TRUE, FALSE},
{PLV2_VENDOR_ID, 0, MAX_VID_PAYLOADS, TRUE, FALSE},
};
/**
* payload order for INFORMATIONAL responder
*/
static payload_order_t informational_r_order[] = {
/* payload type notify type */
{PLV2_NOTIFY, UPDATE_SA_ADDRESSES},
{PLV2_NOTIFY, NAT_DETECTION_SOURCE_IP},
{PLV2_NOTIFY, NAT_DETECTION_DESTINATION_IP},
{PLV2_NOTIFY, COOKIE2},
{PLV2_NOTIFY, 0},
{PLV2_DELETE, 0},
{PLV2_CONFIGURATION, 0},
{PLV2_FRAGMENT, 0},
};
/**
* Message rule for CREATE_CHILD_SA from initiator.
*/
static payload_rule_t create_child_sa_i_rules[] = {
/* payload type min max encr suff */
{PLV2_FRAGMENT, 0, 1, TRUE, TRUE},
{PLV2_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, TRUE, FALSE},
{PLV2_SECURITY_ASSOCIATION, 1, 1, TRUE, FALSE},
{PLV2_NONCE, 1, 1, TRUE, FALSE},
{PLV2_KEY_EXCHANGE, 0, 1, TRUE, FALSE},
{PLV2_TS_INITIATOR, 0, 1, TRUE, FALSE},
{PLV2_TS_RESPONDER, 0, 1, TRUE, FALSE},
{PLV2_CONFIGURATION, 0, 1, TRUE, FALSE},
{PLV2_VENDOR_ID, 0, MAX_VID_PAYLOADS, TRUE, FALSE},
};
/**
* payload order for CREATE_CHILD_SA from initiator.
*/
static payload_order_t create_child_sa_i_order[] = {
/* payload type notify type */
{PLV2_NOTIFY, REKEY_SA},
{PLV2_NOTIFY, IPCOMP_SUPPORTED},
{PLV2_NOTIFY, USE_TRANSPORT_MODE},
{PLV2_NOTIFY, ESP_TFC_PADDING_NOT_SUPPORTED},
{PLV2_NOTIFY, NON_FIRST_FRAGMENTS_ALSO},
{PLV2_SECURITY_ASSOCIATION, 0},
{PLV2_NONCE, 0},
{PLV2_KEY_EXCHANGE, 0},
{PLV2_TS_INITIATOR, 0},
{PLV2_TS_RESPONDER, 0},
{PLV2_NOTIFY, 0},
{PLV2_FRAGMENT, 0},
};
/**
* Message rule for CREATE_CHILD_SA from responder.
*/
static payload_rule_t create_child_sa_r_rules[] = {
/* payload type min max encr suff */
{PLV2_FRAGMENT, 0, 1, TRUE, TRUE},
{PLV2_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, TRUE, TRUE},
{PLV2_SECURITY_ASSOCIATION, 1, 1, TRUE, FALSE},
{PLV2_NONCE, 1, 1, TRUE, FALSE},
{PLV2_KEY_EXCHANGE, 0, 1, TRUE, FALSE},
{PLV2_TS_INITIATOR, 0, 1, TRUE, FALSE},
{PLV2_TS_RESPONDER, 0, 1, TRUE, FALSE},
{PLV2_CONFIGURATION, 0, 1, TRUE, FALSE},
{PLV2_VENDOR_ID, 0, MAX_VID_PAYLOADS, TRUE, FALSE},
};
/**
* payload order for CREATE_CHILD_SA from responder.
*/
static payload_order_t create_child_sa_r_order[] = {
/* payload type notify type */
{PLV2_NOTIFY, IPCOMP_SUPPORTED},
{PLV2_NOTIFY, USE_TRANSPORT_MODE},
{PLV2_NOTIFY, ESP_TFC_PADDING_NOT_SUPPORTED},
{PLV2_NOTIFY, NON_FIRST_FRAGMENTS_ALSO},
{PLV2_SECURITY_ASSOCIATION, 0},
{PLV2_NONCE, 0},
{PLV2_KEY_EXCHANGE, 0},
{PLV2_TS_INITIATOR, 0},
{PLV2_TS_RESPONDER, 0},
{PLV2_NOTIFY, ADDITIONAL_TS_POSSIBLE},
{PLV2_NOTIFY, 0},
{PLV2_FRAGMENT, 0},
};
#ifdef ME
/**
* Message rule for ME_CONNECT from initiator.
*/
static payload_rule_t me_connect_i_rules[] = {
/* payload type min max encr suff */
{PLV2_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, TRUE, TRUE},
{PLV2_ID_PEER, 1, 1, TRUE, FALSE},
{PLV2_VENDOR_ID, 0, MAX_VID_PAYLOADS, TRUE, FALSE}
};
/**
* payload order for ME_CONNECT from initiator.
*/
static payload_order_t me_connect_i_order[] = {
/* payload type notify type */
{PLV2_NOTIFY, 0},
{PLV2_ID_PEER, 0},
{PLV2_VENDOR_ID, 0},
};
/**
* Message rule for ME_CONNECT from responder.
*/
static payload_rule_t me_connect_r_rules[] = {
/* payload type min max encr suff */
{PLV2_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, TRUE, TRUE},
{PLV2_VENDOR_ID, 0, MAX_VID_PAYLOADS, TRUE, FALSE}
};
/**
* payload order for ME_CONNECT from responder.
*/
static payload_order_t me_connect_r_order[] = {
/* payload type notify type */
{PLV2_NOTIFY, 0},
{PLV2_VENDOR_ID, 0},
};
#endif /* ME */
#ifdef USE_IKEV1
/**
* Message rule for ID_PROT from initiator.
*/
static payload_rule_t id_prot_i_rules[] = {
/* payload type min max encr suff */
{PLV1_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, FALSE, FALSE},
{PLV1_SECURITY_ASSOCIATION, 0, 1, FALSE, FALSE},
{PLV1_KEY_EXCHANGE, 0, 1, FALSE, FALSE},
{PLV1_NONCE, 0, 1, FALSE, FALSE},
{PLV1_VENDOR_ID, 0, MAX_VID_PAYLOADS, FALSE, FALSE},
{PLV1_CERTREQ, 0, MAX_CERTREQ_PAYLOADS, FALSE, FALSE},
{PLV1_NAT_D, 0, MAX_NAT_D_PAYLOADS, FALSE, FALSE},
{PLV1_NAT_D_DRAFT_00_03, 0, MAX_NAT_D_PAYLOADS, FALSE, FALSE},
{PLV1_ID, 0, 1, TRUE, FALSE},
{PLV1_CERTIFICATE, 0, MAX_CERT_PAYLOADS, TRUE, FALSE},
{PLV1_SIGNATURE, 0, 1, TRUE, FALSE},
{PLV1_HASH, 0, 1, TRUE, FALSE},
{PLV1_FRAGMENT, 0, 1, FALSE, TRUE},
};
/**
* payload order for ID_PROT from initiator.
*/
static payload_order_t id_prot_i_order[] = {
/* payload type notify type */
{PLV1_SECURITY_ASSOCIATION, 0},
{PLV1_KEY_EXCHANGE, 0},
{PLV1_NONCE, 0},
{PLV1_ID, 0},
{PLV1_CERTIFICATE, 0},
{PLV1_SIGNATURE, 0},
{PLV1_HASH, 0},
{PLV1_CERTREQ, 0},
{PLV1_NOTIFY, 0},
{PLV1_VENDOR_ID, 0},
{PLV1_NAT_D, 0},
{PLV1_NAT_D_DRAFT_00_03, 0},
{PLV1_FRAGMENT, 0},
};
/**
* Message rule for ID_PROT from responder.
*/
static payload_rule_t id_prot_r_rules[] = {
/* payload type min max encr suff */
{PLV1_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, FALSE, FALSE},
{PLV1_SECURITY_ASSOCIATION, 0, 1, FALSE, FALSE},
{PLV1_KEY_EXCHANGE, 0, 1, FALSE, FALSE},
{PLV1_NONCE, 0, 1, FALSE, FALSE},
{PLV1_VENDOR_ID, 0, MAX_VID_PAYLOADS, FALSE, FALSE},
{PLV1_CERTREQ, 0, MAX_CERTREQ_PAYLOADS, FALSE, FALSE},
{PLV1_NAT_D, 0, MAX_NAT_D_PAYLOADS, FALSE, FALSE},
{PLV1_NAT_D_DRAFT_00_03, 0, MAX_NAT_D_PAYLOADS, FALSE, FALSE},
{PLV1_ID, 0, 1, TRUE, FALSE},
{PLV1_CERTIFICATE, 0, MAX_CERT_PAYLOADS, TRUE, FALSE},
{PLV1_SIGNATURE, 0, 1, TRUE, FALSE},
{PLV1_HASH, 0, 1, TRUE, FALSE},
{PLV1_FRAGMENT, 0, 1, FALSE, TRUE},
};
/**
* payload order for ID_PROT from responder.
*/
static payload_order_t id_prot_r_order[] = {
/* payload type notify type */
{PLV1_SECURITY_ASSOCIATION, 0},
{PLV1_KEY_EXCHANGE, 0},
{PLV1_NONCE, 0},
{PLV1_ID, 0},
{PLV1_CERTIFICATE, 0},
{PLV1_SIGNATURE, 0},
{PLV1_HASH, 0},
{PLV1_CERTREQ, 0},
{PLV1_NOTIFY, 0},
{PLV1_VENDOR_ID, 0},
{PLV1_NAT_D, 0},
{PLV1_NAT_D_DRAFT_00_03, 0},
{PLV1_FRAGMENT, 0},
};
/**
* Message rule for AGGRESSIVE from initiator.
*/
static payload_rule_t aggressive_i_rules[] = {
/* payload type min max encr suff */
{PLV1_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, FALSE, FALSE},
{PLV1_SECURITY_ASSOCIATION, 0, 1, FALSE, FALSE},
{PLV1_KEY_EXCHANGE, 0, 1, FALSE, FALSE},
{PLV1_NONCE, 0, 1, FALSE, FALSE},
{PLV1_VENDOR_ID, 0, MAX_VID_PAYLOADS, FALSE, FALSE},
{PLV1_CERTREQ, 0, MAX_CERTREQ_PAYLOADS, FALSE, FALSE},
{PLV1_NAT_D, 0, MAX_NAT_D_PAYLOADS, FALSE, FALSE},
{PLV1_NAT_D_DRAFT_00_03, 0, MAX_NAT_D_PAYLOADS, FALSE, FALSE},
{PLV1_ID, 0, 1, FALSE, FALSE},
{PLV1_CERTIFICATE, 0, MAX_CERT_PAYLOADS, TRUE, FALSE},
{PLV1_SIGNATURE, 0, 1, TRUE, FALSE},
{PLV1_HASH, 0, 1, TRUE, FALSE},
{PLV1_FRAGMENT, 0, 1, FALSE, TRUE},
};
/**
* payload order for AGGRESSIVE from initiator.
*/
static payload_order_t aggressive_i_order[] = {
/* payload type notify type */
{PLV1_SECURITY_ASSOCIATION, 0},
{PLV1_KEY_EXCHANGE, 0},
{PLV1_NONCE, 0},
{PLV1_ID, 0},
{PLV1_CERTIFICATE, 0},
{PLV1_CERTREQ, 0},
{PLV1_NOTIFY, 0},
{PLV1_VENDOR_ID, 0},
{PLV1_HASH, 0},
{PLV1_NAT_D, 0},
{PLV1_NAT_D_DRAFT_00_03, 0},
{PLV1_SIGNATURE, 0},
{PLV1_FRAGMENT, 0},
};
/**
* Message rule for AGGRESSIVE from responder.
*/
static payload_rule_t aggressive_r_rules[] = {
/* payload type min max encr suff */
{PLV1_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, FALSE, FALSE},
{PLV1_SECURITY_ASSOCIATION, 0, 1, FALSE, FALSE},
{PLV1_KEY_EXCHANGE, 0, 1, FALSE, FALSE},
{PLV1_NONCE, 0, 1, FALSE, FALSE},
{PLV1_VENDOR_ID, 0, MAX_VID_PAYLOADS, FALSE, FALSE},
{PLV1_CERTREQ, 0, MAX_CERTREQ_PAYLOADS, FALSE, FALSE},
{PLV1_NAT_D, 0, MAX_NAT_D_PAYLOADS, FALSE, FALSE},
{PLV1_NAT_D_DRAFT_00_03, 0, MAX_NAT_D_PAYLOADS, FALSE, FALSE},
{PLV1_ID, 0, 1, FALSE, FALSE},
{PLV1_CERTIFICATE, 0, MAX_CERT_PAYLOADS, FALSE, FALSE},
{PLV1_SIGNATURE, 0, 1, FALSE, FALSE},
{PLV1_HASH, 0, 1, FALSE, FALSE},
{PLV1_FRAGMENT, 0, 1, FALSE, TRUE},
};
/**
* payload order for AGGRESSIVE from responder.
*/
static payload_order_t aggressive_r_order[] = {
/* payload type notify type */
{PLV1_SECURITY_ASSOCIATION, 0},
{PLV1_KEY_EXCHANGE, 0},
{PLV1_NONCE, 0},
{PLV1_ID, 0},
{PLV1_CERTIFICATE, 0},
{PLV1_CERTREQ, 0},
{PLV1_NOTIFY, 0},
{PLV1_VENDOR_ID, 0},
{PLV1_NAT_D, 0},
{PLV1_NAT_D_DRAFT_00_03, 0},
{PLV1_SIGNATURE, 0},
{PLV1_HASH, 0},
{PLV1_FRAGMENT, 0},
};
/**
* Message rule for INFORMATIONAL_V1 from initiator.
*/
static payload_rule_t informational_i_rules_v1[] = {
/* payload type min max encr suff */
{PLV1_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, FALSE, FALSE},
{PLV1_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, TRUE, FALSE},
{PLV1_DELETE, 0, MAX_DELETE_PAYLOADS, TRUE, FALSE},
{PLV1_VENDOR_ID, 0, MAX_VID_PAYLOADS, TRUE, FALSE},
};
/**
* payload order for INFORMATIONAL_V1 from initiator.
*/
static payload_order_t informational_i_order_v1[] = {
/* payload type notify type */
{PLV1_NOTIFY, 0},
{PLV1_DELETE, 0},
{PLV1_VENDOR_ID, 0},
};
/**
* Message rule for INFORMATIONAL_V1 from responder.
*/
static payload_rule_t informational_r_rules_v1[] = {
/* payload type min max encr suff */
{PLV1_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, FALSE, FALSE},
{PLV1_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, TRUE, FALSE},
{PLV1_DELETE, 0, MAX_DELETE_PAYLOADS, TRUE, FALSE},
{PLV1_VENDOR_ID, 0, MAX_VID_PAYLOADS, TRUE, FALSE},
};
/**
* payload order for INFORMATIONAL_V1 from responder.
*/
static payload_order_t informational_r_order_v1[] = {
/* payload type notify type */
{PLV1_NOTIFY, 0},
{PLV1_DELETE, 0},
{PLV1_VENDOR_ID, 0},
};
/**
* Message rule for QUICK_MODE from initiator.
*/
static payload_rule_t quick_mode_i_rules[] = {
/* payload type min max encr suff */
{PLV1_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, TRUE, FALSE},
{PLV1_VENDOR_ID, 0, MAX_VID_PAYLOADS, TRUE, FALSE},
{PLV1_HASH, 0, 1, TRUE, FALSE},
{PLV1_SECURITY_ASSOCIATION, 0, 2, TRUE, FALSE},
{PLV1_NONCE, 0, 1, TRUE, FALSE},
{PLV1_KEY_EXCHANGE, 0, 1, TRUE, FALSE},
{PLV1_ID, 0, 2, TRUE, FALSE},
{PLV1_NAT_OA, 0, 2, TRUE, FALSE},
{PLV1_NAT_OA_DRAFT_00_03, 0, 2, TRUE, FALSE},
{PLV1_FRAGMENT, 0, 1, FALSE, TRUE},
};
/**
* payload order for QUICK_MODE from initiator.
*/
static payload_order_t quick_mode_i_order[] = {
/* payload type notify type */
{PLV1_NOTIFY, 0},
{PLV1_VENDOR_ID, 0},
{PLV1_HASH, 0},
{PLV1_SECURITY_ASSOCIATION, 0},
{PLV1_NONCE, 0},
{PLV1_KEY_EXCHANGE, 0},
{PLV1_ID, 0},
{PLV1_NAT_OA, 0},
{PLV1_NAT_OA_DRAFT_00_03, 0},
{PLV1_FRAGMENT, 0},
};
/**
* Message rule for QUICK_MODE from responder.
*/
static payload_rule_t quick_mode_r_rules[] = {
/* payload type min max encr suff */
{PLV1_NOTIFY, 0, MAX_NOTIFY_PAYLOADS, TRUE, FALSE},
{PLV1_VENDOR_ID, 0, MAX_VID_PAYLOADS, TRUE, FALSE},
{PLV1_HASH, 0, 1, TRUE, FALSE},
{PLV1_SECURITY_ASSOCIATION, 0, 2, TRUE, FALSE},
{PLV1_NONCE, 0, 1, TRUE, FALSE},
{PLV1_KEY_EXCHANGE, 0, 1, TRUE, FALSE},
{PLV1_ID, 0, 2, TRUE, FALSE},
{PLV1_NAT_OA, 0, 2, TRUE, FALSE},
{PLV1_NAT_OA_DRAFT_00_03, 0, 2, TRUE, FALSE},
{PLV1_FRAGMENT, 0, 1, FALSE, TRUE},
};
/**
* payload order for QUICK_MODE from responder.
*/
static payload_order_t quick_mode_r_order[] = {
/* payload type notify type */
{PLV1_NOTIFY, 0},
{PLV1_VENDOR_ID, 0},
{PLV1_HASH, 0},
{PLV1_SECURITY_ASSOCIATION, 0},
{PLV1_NONCE, 0},
{PLV1_KEY_EXCHANGE, 0},
{PLV1_ID, 0},
{PLV1_NAT_OA, 0},
{PLV1_NAT_OA_DRAFT_00_03, 0},
{PLV1_FRAGMENT, 0},
};
/**
* Message rule for TRANSACTION.
*/
static payload_rule_t transaction_payload_rules_v1[] = {
/* payload type min max encr suff */
{PLV1_HASH, 0, 1, TRUE, FALSE},
{PLV1_CONFIGURATION, 1, 1, FALSE, FALSE},
};
/**
* Payload order for TRANSACTION.
*/
static payload_order_t transaction_payload_order_v1[] = {
/* payload type notify type */
{PLV1_HASH, 0},
{PLV1_CONFIGURATION, 0},
};
#endif /* USE_IKEV1 */
/**
* Message rules, defines allowed payloads.
*/
static message_rule_t message_rules[] = {
{IKE_SA_INIT, TRUE, FALSE,
countof(ike_sa_init_i_rules), ike_sa_init_i_rules,
countof(ike_sa_init_i_order), ike_sa_init_i_order,
},
{IKE_SA_INIT, FALSE, FALSE,
countof(ike_sa_init_r_rules), ike_sa_init_r_rules,
countof(ike_sa_init_r_order), ike_sa_init_r_order,
},
{IKE_AUTH, TRUE, TRUE,
countof(ike_auth_i_rules), ike_auth_i_rules,
countof(ike_auth_i_order), ike_auth_i_order,
},
{IKE_AUTH, FALSE, TRUE,
countof(ike_auth_r_rules), ike_auth_r_rules,
countof(ike_auth_r_order), ike_auth_r_order,
},
{INFORMATIONAL, TRUE, TRUE,
countof(informational_i_rules), informational_i_rules,
countof(informational_i_order), informational_i_order,
},
{INFORMATIONAL, FALSE, TRUE,
countof(informational_r_rules), informational_r_rules,
countof(informational_r_order), informational_r_order,
},
{CREATE_CHILD_SA, TRUE, TRUE,
countof(create_child_sa_i_rules), create_child_sa_i_rules,
countof(create_child_sa_i_order), create_child_sa_i_order,
},
{CREATE_CHILD_SA, FALSE, TRUE,
countof(create_child_sa_r_rules), create_child_sa_r_rules,
countof(create_child_sa_r_order), create_child_sa_r_order,
},
#ifdef ME
{ME_CONNECT, TRUE, TRUE,
countof(me_connect_i_rules), me_connect_i_rules,
countof(me_connect_i_order), me_connect_i_order,
},
{ME_CONNECT, FALSE, TRUE,
countof(me_connect_r_rules), me_connect_r_rules,
countof(me_connect_r_order), me_connect_r_order,
},
#endif /* ME */
#ifdef USE_IKEV1
{ID_PROT, TRUE, FALSE,
countof(id_prot_i_rules), id_prot_i_rules,
countof(id_prot_i_order), id_prot_i_order,
},
{ID_PROT, FALSE, FALSE,
countof(id_prot_r_rules), id_prot_r_rules,
countof(id_prot_r_order), id_prot_r_order,
},
{AGGRESSIVE, TRUE, FALSE,
countof(aggressive_i_rules), aggressive_i_rules,
countof(aggressive_i_order), aggressive_i_order,
},
{AGGRESSIVE, FALSE, FALSE,
countof(aggressive_r_rules), aggressive_r_rules,
countof(aggressive_r_order), aggressive_r_order,
},
{INFORMATIONAL_V1, TRUE, TRUE,
countof(informational_i_rules_v1), informational_i_rules_v1,
countof(informational_i_order_v1), informational_i_order_v1,
},
{INFORMATIONAL_V1, FALSE, TRUE,
countof(informational_r_rules_v1), informational_r_rules_v1,
countof(informational_r_order_v1), informational_r_order_v1,
},
{QUICK_MODE, TRUE, TRUE,
countof(quick_mode_i_rules), quick_mode_i_rules,
countof(quick_mode_i_order), quick_mode_i_order,
},
{QUICK_MODE, FALSE, TRUE,
countof(quick_mode_r_rules), quick_mode_r_rules,
countof(quick_mode_r_order), quick_mode_r_order,
},
{TRANSACTION, TRUE, TRUE,
countof(transaction_payload_rules_v1), transaction_payload_rules_v1,
countof(transaction_payload_order_v1), transaction_payload_order_v1,
},
{TRANSACTION, FALSE, TRUE,
countof(transaction_payload_rules_v1), transaction_payload_rules_v1,
countof(transaction_payload_order_v1), transaction_payload_order_v1,
},
/* TODO-IKEv1: define rules for other exchanges */
#endif /* USE_IKEV1 */
};
/**
* Data for fragment reassembly.
*/
typedef struct {
/**
* For IKEv1 the number of the last fragment (in case we receive them out
* of order), since the first one starts with 1 this defines the number of
* fragments we expect.
* For IKEv2 we store the total number of fragment we received last.
*/
uint16_t last;
/**
* Length of all currently received fragments.
*/
size_t len;
/**
* Maximum length of a fragmented packet.
*/
size_t max_packet;
} fragment_data_t;
typedef struct private_message_t private_message_t;
/**
* Private data of an message_t object.
*/
struct private_message_t {
/**
* Public part of a message_t object.
*/
message_t public;
/**
* Minor version of message.
*/
uint8_t major_version;
/**
* Major version of message.
*/
uint8_t minor_version;
/**
* First Payload in message.
*/
payload_type_t first_payload;
/**
* Assigned exchange type.
*/
exchange_type_t exchange_type;
/**
* TRUE if message is a request, FALSE if a reply.
*/
bool is_request;
/**
* The message is encrypted (IKEv1)
*/
bool is_encrypted;
/**
* Higher version supported?
*/
bool version_flag;
/**
* Reserved bits in IKE header
*/
bool reserved[2];
/**
* Sorting of message disabled?
*/
bool sort_disabled;
/**
* Message ID of this message.
*/
uint32_t message_id;
/**
* ID of assigned IKE_SA.
*/
ike_sa_id_t *ike_sa_id;
/**
* Assigned UDP packet, stores incoming packet or last generated one.
*/
packet_t *packet;
/**
* Array of generated fragments (if any), as packet_t*.
* If defragmenting (i.e. frag != NULL) this contains fragment_t*
*/
array_t *fragments;
/**
* Linked List where payload data are stored in.
*/
linked_list_t *payloads;
/**
* Assigned parser to parse Header and Body of this message.
*/
parser_t *parser;
/**
* The message rule for this message instance
*/
message_rule_t *rule;
/**
* Data used to reassemble a fragmented message
*/
fragment_data_t *frag;
};
/**
* Maximum number of fragments we will handle
*/
#define MAX_FRAGMENTS 255
/**
* A single fragment within a fragmented message
*/
typedef struct {
/** fragment number */
uint8_t num;
/** fragment data */
chunk_t data;
} fragment_t;
static void fragment_destroy(fragment_t *this)
{
chunk_free(&this->data);
free(this);
}
static void reset_defrag(private_message_t *this)
{
array_destroy_function(this->fragments, (void*)fragment_destroy, NULL);
this->fragments = NULL;
this->frag->last = 0;
this->frag->len = 0;
}
/**
* Get the message rule that applies to this message
*/
static message_rule_t* get_message_rule(private_message_t *this)
{
int i;
for (i = 0; i < countof(message_rules); i++)
{
if ((this->exchange_type == message_rules[i].exchange_type) &&
(this->is_request == message_rules[i].is_request))
{
return &message_rules[i];
}
}
return NULL;
}
/**
* Look up a payload rule
*/
static payload_rule_t* get_payload_rule(private_message_t *this,
payload_type_t type)
{
int i;
for (i = 0; i < this->rule->rule_count;i++)
{
if (this->rule->rules[i].type == type)
{
return &this->rule->rules[i];
}
}
return NULL;
}
METHOD(message_t, set_ike_sa_id, void,
private_message_t *this,ike_sa_id_t *ike_sa_id)
{
DESTROY_IF(this->ike_sa_id);
this->ike_sa_id = ike_sa_id->clone(ike_sa_id);
}
METHOD(message_t, get_ike_sa_id, ike_sa_id_t*,
private_message_t *this)
{
return this->ike_sa_id;
}
METHOD(message_t, set_message_id, void,
private_message_t *this,uint32_t message_id)
{
this->message_id = message_id;
}
METHOD(message_t, get_message_id, uint32_t,
private_message_t *this)
{
return this->message_id;
}
METHOD(message_t, get_initiator_spi, uint64_t,
private_message_t *this)
{
return (this->ike_sa_id->get_initiator_spi(this->ike_sa_id));
}
METHOD(message_t, get_responder_spi, uint64_t,
private_message_t *this)
{
return (this->ike_sa_id->get_responder_spi(this->ike_sa_id));
}
METHOD(message_t, set_major_version, void,
private_message_t *this, uint8_t major_version)
{
this->major_version = major_version;
}
METHOD(message_t, get_major_version, uint8_t,
private_message_t *this)
{
return this->major_version;
}
METHOD(message_t, set_minor_version, void,
private_message_t *this,uint8_t minor_version)
{
this->minor_version = minor_version;
}
METHOD(message_t, get_minor_version, uint8_t,
private_message_t *this)
{
return this->minor_version;
}
METHOD(message_t, set_exchange_type, void,
private_message_t *this, exchange_type_t exchange_type)
{
this->exchange_type = exchange_type;
}
METHOD(message_t, get_exchange_type, exchange_type_t,
private_message_t *this)
{
return this->exchange_type;
}
METHOD(message_t, get_first_payload_type, payload_type_t,
private_message_t *this)
{
return this->first_payload;
}
METHOD(message_t, set_request, void,
private_message_t *this, bool request)
{
this->is_request = request;
}
METHOD(message_t, get_request, bool,
private_message_t *this)
{
return this->is_request;
}
METHOD(message_t, set_version_flag, void,
private_message_t *this)
{
this->version_flag = TRUE;
}
METHOD(message_t, get_reserved_header_bit, bool,
private_message_t *this, u_int nr)
{
if (nr < countof(this->reserved))
{
return this->reserved[nr];
}
return FALSE;
}
METHOD(message_t, set_reserved_header_bit, void,
private_message_t *this, u_int nr)
{
if (nr < countof(this->reserved))
{
this->reserved[nr] = TRUE;
}
}
METHOD(message_t, is_encoded, bool,
private_message_t *this)
{
return this->packet->get_data(this->packet).ptr != NULL;
}
METHOD(message_t, is_fragmented, bool,
private_message_t *this)
{
return array_count(this->fragments) > 0;
}
METHOD(message_t, add_payload, void,
private_message_t *this, payload_t *payload)
{
payload_t *last_payload;
if (this->payloads->get_count(this->payloads) > 0)
{
this->payloads->get_last(this->payloads, (void **)&last_payload);
last_payload->set_next_type(last_payload, payload->get_type(payload));
}
else
{
this->first_payload = payload->get_type(payload);
}
payload->set_next_type(payload, PL_NONE);
this->payloads->insert_last(this->payloads, payload);
DBG2(DBG_ENC ,"added payload of type %N to message",
payload_type_names, payload->get_type(payload));
}
METHOD(message_t, add_notify, void,
private_message_t *this, bool flush, notify_type_t type, chunk_t data)
{
notify_payload_t *notify;
payload_t *payload;
if (flush)
{
while (this->payloads->remove_last(this->payloads,
(void**)&payload) == SUCCESS)
{
payload->destroy(payload);
}
}
if (this->major_version == IKEV2_MAJOR_VERSION)
{
notify = notify_payload_create(PLV2_NOTIFY);
}
else
{
notify = notify_payload_create(PLV1_NOTIFY);
}
notify->set_notify_type(notify, type);
notify->set_notification_data(notify, data);
add_payload(this, (payload_t*)notify);
}
METHOD(message_t, set_source, void,
private_message_t *this, host_t *host)
{
this->packet->set_source(this->packet, host);
}
METHOD(message_t, set_destination, void,
private_message_t *this, host_t *host)
{
this->packet->set_destination(this->packet, host);
}
METHOD(message_t, get_source, host_t*,
private_message_t *this)
{
return this->packet->get_source(this->packet);
}
METHOD(message_t, get_destination, host_t*,
private_message_t *this)
{
return this->packet->get_destination(this->packet);
}
METHOD(message_t, create_payload_enumerator, enumerator_t*,
private_message_t *this)
{
return this->payloads->create_enumerator(this->payloads);
}
METHOD(message_t, remove_payload_at, void,
private_message_t *this, enumerator_t *enumerator)
{
this->payloads->remove_at(this->payloads, enumerator);
}
METHOD(message_t, get_payload, payload_t*,
private_message_t *this, payload_type_t type)
{
payload_t *current, *found = NULL;
enumerator_t *enumerator;
enumerator = create_payload_enumerator(this);
while (enumerator->enumerate(enumerator, &current))
{
if (current->get_type(current) == type)
{
found = current;
break;
}
}
enumerator->destroy(enumerator);
return found;
}
METHOD(message_t, get_notify, notify_payload_t*,
private_message_t *this, notify_type_t type)
{
enumerator_t *enumerator;
notify_payload_t *notify = NULL;
payload_t *payload;
enumerator = create_payload_enumerator(this);
while (enumerator->enumerate(enumerator, &payload))
{
if (payload->get_type(payload) == PLV2_NOTIFY ||
payload->get_type(payload) == PLV1_NOTIFY)
{
notify = (notify_payload_t*)payload;
if (notify->get_notify_type(notify) == type)
{
break;
}
notify = NULL;
}
}
enumerator->destroy(enumerator);
return notify;
}
/**
* get a string representation of the message
*/
static char* get_string(private_message_t *this, char *buf, int len)
{
enumerator_t *enumerator;
payload_t *payload;
int written;
char *pos = buf;
memset(buf, 0, len);
len--;
written = snprintf(pos, len, "%N %s %u [",
exchange_type_names, this->exchange_type,
this->is_request ? "request" : "response",
this->message_id);
if (written >= len || written < 0)
{
return "";
}
pos += written;
len -= written;
enumerator = create_payload_enumerator(this);
while (enumerator->enumerate(enumerator, &payload))
{
written = snprintf(pos, len, " %N", payload_type_short_names,
payload->get_type(payload));
if (written >= len || written < 0)
{
return buf;
}
pos += written;
len -= written;
if (payload->get_type(payload) == PLV2_NOTIFY ||
payload->get_type(payload) == PLV1_NOTIFY)
{
notify_payload_t *notify;
notify_type_t type;
chunk_t data;
notify = (notify_payload_t*)payload;
type = notify->get_notify_type(notify);
data = notify->get_notification_data(notify);
if (type == MS_NOTIFY_STATUS && data.len == 4)
{
written = snprintf(pos, len, "(%N(%d))", notify_type_short_names,
type, untoh32(data.ptr));
}
else
{
written = snprintf(pos, len, "(%N)", notify_type_short_names,
type);
}
if (written >= len || written < 0)
{
return buf;
}
pos += written;
len -= written;
}
if (payload->get_type(payload) == PLV2_EAP)
{
eap_payload_t *eap = (eap_payload_t*)payload;
uint32_t vendor;
eap_type_t type;
char method[64] = "";
type = eap->get_type(eap, &vendor);
if (type)
{
if (vendor)
{
snprintf(method, sizeof(method), "/%d-%d", type, vendor);
}
else
{
snprintf(method, sizeof(method), "/%N",
eap_type_short_names, type);
}
}
written = snprintf(pos, len, "/%N%s", eap_code_short_names,
eap->get_code(eap), method);
if (written >= len || written < 0)
{
return buf;
}
pos += written;
len -= written;
}
if (payload->get_type(payload) == PLV2_CONFIGURATION ||
payload->get_type(payload) == PLV1_CONFIGURATION)
{
cp_payload_t *cp = (cp_payload_t*)payload;
enumerator_t *attributes;
configuration_attribute_t *attribute;
bool first = TRUE;
char *pfx;
switch (cp->get_type(cp))
{
case CFG_REQUEST:
pfx = "RQ(";
break;
case CFG_REPLY:
pfx = "RP(";
break;
case CFG_SET:
pfx = "S(";
break;
case CFG_ACK:
pfx = "A(";
break;
default:
pfx = "(";
break;
}
attributes = cp->create_attribute_enumerator(cp);
while (attributes->enumerate(attributes, &attribute))
{
written = snprintf(pos, len, "%s%N", first ? pfx : " ",
configuration_attribute_type_short_names,
attribute->get_type(attribute));
if (written >= len || written < 0)
{
return buf;
}
pos += written;
len -= written;
first = FALSE;
}
attributes->destroy(attributes);
if (!first)
{
written = snprintf(pos, len, ")");
if (written >= len || written < 0)
{
return buf;
}
pos += written;
len -= written;
}
}
if (payload->get_type(payload) == PLV1_FRAGMENT)
{
fragment_payload_t *frag;
frag = (fragment_payload_t*)payload;
if (frag->is_last(frag))
{
written = snprintf(pos, len, "(%u/%u)",
frag->get_number(frag), frag->get_number(frag));
}
else
{
written = snprintf(pos, len, "(%u)", frag->get_number(frag));
}
if (written >= len || written < 0)
{
return buf;
}
pos += written;
len -= written;
}
if (payload->get_type(payload) == PLV2_FRAGMENT)
{
encrypted_fragment_payload_t *frag;
frag = (encrypted_fragment_payload_t*)payload;
written = snprintf(pos, len, "(%u/%u)",
frag->get_fragment_number(frag),
frag->get_total_fragments(frag));
if (written >= len || written < 0)
{
return buf;
}
pos += written;
len -= written;
}
if (payload->get_type(payload) == PL_UNKNOWN)
{
unknown_payload_t *unknown;
unknown = (unknown_payload_t*)payload;
written = snprintf(pos, len, "(%d)", unknown->get_type(unknown));
if (written >= len || written < 0)
{
return buf;
}
pos += written;
len -= written;
}
}
enumerator->destroy(enumerator);
/* remove last space */
snprintf(pos, len, " ]");
return buf;
}
METHOD(message_t, disable_sort, void,
private_message_t *this)
{
this->sort_disabled = TRUE;
}
/**
* reorder payloads depending on reordering rules
*/
static void order_payloads(private_message_t *this)
{
linked_list_t *list;
payload_t *payload;
int i;
DBG2(DBG_ENC, "order payloads in message");
/* move to temp list */
list = linked_list_create();
while (this->payloads->remove_last(this->payloads,
(void**)&payload) == SUCCESS)
{
list->insert_first(list, payload);
}
/* for each rule, ... */
for (i = 0; i < this->rule->order_count; i++)
{
enumerator_t *enumerator;
notify_payload_t *notify;
payload_order_t order;
order = this->rule->order[i];
/* ... find all payload ... */
enumerator = list->create_enumerator(list);
while (enumerator->enumerate(enumerator, &payload))
{
/* ... with that type ... */
if (payload->get_type(payload) == order.type)
{
notify = (notify_payload_t*)payload;
/**... and check notify for type. */
if (order.type != PLV2_NOTIFY || order.notify == 0 ||
order.notify == notify->get_notify_type(notify))
{
list->remove_at(list, enumerator);
add_payload(this, payload);
}
}
}
enumerator->destroy(enumerator);
}
/* append all payloads without a rule to the end */
while (list->remove_last(list, (void**)&payload) == SUCCESS)
{
/* do not complain about payloads in private use space */
if (payload->get_type(payload) < 128)
{
DBG1(DBG_ENC, "payload %N has no ordering rule in %N %s",
payload_type_names, payload->get_type(payload),
exchange_type_names, this->rule->exchange_type,
this->rule->is_request ? "request" : "response");
}
add_payload(this, payload);
}
list->destroy(list);
}
/**
* Wrap payloads in an encrypted payload
*/
static encrypted_payload_t* wrap_payloads(private_message_t *this)
{
encrypted_payload_t *encrypted = NULL;
linked_list_t *payloads;
payload_t *current;
/* move all payloads to a temporary list */
payloads = linked_list_create();
while (this->payloads->remove_first(this->payloads,
(void**)&current) == SUCCESS)
{
if (current->get_type(current) == PLV2_FRAGMENT)
{ /* treat encrypted fragment payload as encrypted payload */
encrypted = (encrypted_payload_t*)current;
}
else
{
payloads->insert_last(payloads, current);
}
}
if (encrypted)
{ /* simply adopt all the unencrypted payloads */
this->payloads->destroy(this->payloads);
this->payloads = payloads;
return encrypted;
}
if (this->is_encrypted)
{
encrypted = encrypted_payload_create(PLV1_ENCRYPTED);
}
else
{
encrypted = encrypted_payload_create(PLV2_ENCRYPTED);
}
while (payloads->remove_first(payloads, (void**)&current) == SUCCESS)
{
payload_rule_t *rule;
payload_type_t type;
bool encrypt = TRUE;
type = current->get_type(current);
rule = get_payload_rule(this, type);
if (rule)
{
encrypt = rule->encrypted;
}
if (encrypt || this->is_encrypted)
{ /* encryption is forced for IKEv1 */
DBG2(DBG_ENC, "insert payload %N into encrypted payload",
payload_type_names, type);
encrypted->add_payload(encrypted, current);
}
else
{
DBG2(DBG_ENC, "insert payload %N unencrypted",
payload_type_names, type);
add_payload(this, current);
}
}
payloads->destroy(payloads);
return encrypted;
}
/**
* Creates the IKE header for this message
*/
static ike_header_t *create_header(private_message_t *this)
{
ike_header_t *ike_header;
bool *reserved;
int i;
ike_header = ike_header_create_version(this->major_version,
this->minor_version);
ike_header->set_exchange_type(ike_header, this->exchange_type);
ike_header->set_message_id(ike_header, this->message_id);
if (this->major_version == IKEV2_MAJOR_VERSION)
{
ike_header->set_response_flag(ike_header, !this->is_request);
ike_header->set_version_flag(ike_header, this->version_flag);
ike_header->set_initiator_flag(ike_header,
this->ike_sa_id->is_initiator(this->ike_sa_id));
}
else
{
ike_header->set_encryption_flag(ike_header, this->is_encrypted);
}
ike_header->set_initiator_spi(ike_header,
this->ike_sa_id->get_initiator_spi(this->ike_sa_id));
ike_header->set_responder_spi(ike_header,
this->ike_sa_id->get_responder_spi(this->ike_sa_id));
for (i = 0; i < countof(this->reserved); i++)
{
reserved = payload_get_field(&ike_header->payload_interface,
RESERVED_BIT, i);
if (reserved)
{
*reserved = this->reserved[i];
}
}
return ike_header;
}
/**
* Generates the message, if needed, wraps the payloads in an encrypted payload.
*
* The generator and the possible encrypted payload are returned. The latter
* is not yet encrypted (but the transform is set). It is also not added to
* the payload list (so unless there are unencrypted payloads that list will
* be empty afterwards).
*/
static status_t generate_message(private_message_t *this, keymat_t *keymat,
generator_t **out_generator, encrypted_payload_t **encrypted)
{
keymat_v1_t *keymat_v1 = (keymat_v1_t*)keymat;
generator_t *generator;
payload_type_t next_type;
enumerator_t *enumerator;
aead_t *aead = NULL;
chunk_t hash = chunk_empty;
char str[BUF_LEN];
ike_header_t *ike_header;
payload_t *payload, *next;
bool encrypting = FALSE;
if (this->exchange_type == EXCHANGE_TYPE_UNDEFINED)
{
DBG1(DBG_ENC, "exchange type is not defined");
return INVALID_STATE;
}
if (this->packet->get_source(this->packet) == NULL ||
this->packet->get_destination(this->packet) == NULL)
{
DBG1(DBG_ENC, "source/destination not defined");
return INVALID_STATE;
}
this->rule = get_message_rule(this);
if (!this->rule)
{
DBG1(DBG_ENC, "no message rules specified for this message type");
return NOT_SUPPORTED;
}
if (!this->sort_disabled)
{
order_payloads(this);
}
if (keymat && keymat->get_version(keymat) == IKEV1)
{
/* get a hash for this message, if any is required */
if (keymat_v1->get_hash_phase2(keymat_v1, &this->public, &hash))
{ /* insert a HASH payload as first payload */
hash_payload_t *hash_payload;
hash_payload = hash_payload_create(PLV1_HASH);
hash_payload->set_hash(hash_payload, hash);
this->payloads->insert_first(this->payloads, hash_payload);
if (this->exchange_type == INFORMATIONAL_V1)
{
this->is_encrypted = encrypting = TRUE;
}
chunk_free(&hash);
}
}
if (this->major_version == IKEV2_MAJOR_VERSION)
{
encrypting = this->rule->encrypted;
}
else if (!encrypting)
{
/* If at least one payload requires encryption, encrypt the message.
* If no key material is available, the flag will be reset below. */
enumerator = this->payloads->create_enumerator(this->payloads);
while (enumerator->enumerate(enumerator, (void**)&payload))
{
payload_rule_t *rule;
rule = get_payload_rule(this, payload->get_type(payload));
if (rule && rule->encrypted)
{
this->is_encrypted = encrypting = TRUE;
break;
}
}
enumerator->destroy(enumerator);
}
DBG1(DBG_ENC, "generating %s", get_string(this, str, sizeof(str)));
if (keymat)
{
aead = keymat->get_aead(keymat, FALSE);
}
if (encrypting)
{
if (aead)
{
*encrypted = wrap_payloads(this);
(*encrypted)->set_transform(*encrypted, aead);
}
else if (this->exchange_type == INFORMATIONAL ||
this->exchange_type == INFORMATIONAL_V1)
{ /* allow sending unencrypted INFORMATIONALs */
encrypting = FALSE;
}
else
{
DBG1(DBG_ENC, "unable to encrypt payloads without AEAD transform");
return FAILED;
}
}
if (!encrypting)
{
DBG2(DBG_ENC, "not encrypting payloads");
this->is_encrypted = FALSE;
}
/* generate all payloads with proper next type */
*out_generator = generator = generator_create();
ike_header = create_header(this);
payload = (payload_t*)ike_header;
enumerator = create_payload_enumerator(this);
while (enumerator->enumerate(enumerator, &next))
{
payload->set_next_type(payload, next->get_type(next));
generator->generate_payload(generator, payload);
payload = next;
}
enumerator->destroy(enumerator);
next_type = PL_NONE;
if (this->is_encrypted)
{ /* for encrypted IKEv1 messages */
next_type = (*encrypted)->payload_interface.get_next_type(
(payload_t*)*encrypted);
}
else if (*encrypted)
{ /* use proper IKEv2 encrypted (fragment) payload type */
next_type = (*encrypted)->payload_interface.get_type(
(payload_t*)*encrypted);
}
payload->set_next_type(payload, next_type);
generator->generate_payload(generator, payload);
ike_header->destroy(ike_header);
return SUCCESS;
}
/**
* Encrypts and adds the encrypted payload (if any) to the payload list and
* finalizes the message generation. Destroys the given generator.
*/
static status_t finalize_message(private_message_t *this, keymat_t *keymat,
generator_t *generator, encrypted_payload_t *encrypted)
{
keymat_v1_t *keymat_v1 = (keymat_v1_t*)keymat;
chunk_t chunk;
uint32_t *lenpos;
if (encrypted)
{
if (this->is_encrypted)
{ /* for IKEv1 instead of associated data we provide the IV */
if (!keymat_v1->get_iv(keymat_v1, this->message_id, &chunk))
{
generator->destroy(generator);
encrypted->destroy(encrypted);
return FAILED;
}
}
else
{ /* build associated data (without header of encrypted payload) */
chunk = generator->get_chunk(generator, &lenpos);
/* fill in length, including encrypted payload */
htoun32(lenpos, chunk.len + encrypted->get_length(encrypted));
}
this->payloads->insert_last(this->payloads, encrypted);
if (encrypted->encrypt(encrypted, this->message_id, chunk) != SUCCESS)
{
generator->destroy(generator);
return INVALID_STATE;
}
generator->generate_payload(generator, &encrypted->payload_interface);
}
chunk = generator->get_chunk(generator, &lenpos);
htoun32(lenpos, chunk.len);
this->packet->set_data(this->packet, chunk_clone(chunk));
if (this->is_encrypted && this->exchange_type != INFORMATIONAL_V1)
{
/* update the IV for the next IKEv1 message */
chunk_t last_block;
aead_t *aead;
size_t bs;
aead = keymat->get_aead(keymat, FALSE);
bs = aead->get_block_size(aead);
last_block = chunk_create(chunk.ptr + chunk.len - bs, bs);
if (!keymat_v1->update_iv(keymat_v1, this->message_id, last_block) ||
!keymat_v1->confirm_iv(keymat_v1, this->message_id))
{
generator->destroy(generator);
return FAILED;
}
}
generator->destroy(generator);
return SUCCESS;
}
METHOD(message_t, generate, status_t,
private_message_t *this, keymat_t *keymat, packet_t **packet)
{
generator_t *generator = NULL;
encrypted_payload_t *encrypted = NULL;
status_t status;
status = generate_message(this, keymat, &generator, &encrypted);
if (status != SUCCESS)
{
DESTROY_IF(generator);
return status;
}
status = finalize_message(this, keymat, generator, encrypted);
if (status != SUCCESS)
{
return status;
}
if (packet)
{
*packet = this->packet->clone(this->packet);
}
return SUCCESS;
}
/**
* Creates a (basic) clone of the given message
*/
static message_t *clone_message(private_message_t *this)
{
message_t *message;
host_t *src, *dst;
src = this->packet->get_source(this->packet);
dst = this->packet->get_destination(this->packet);
message = message_create(this->major_version, this->minor_version);
message->set_ike_sa_id(message, this->ike_sa_id);
message->set_message_id(message, this->message_id);
message->set_request(message, this->is_request);
message->set_source(message, src->clone(src));
message->set_destination(message, dst->clone(dst));
message->set_exchange_type(message, this->exchange_type);
memcpy(((private_message_t*)message)->reserved, this->reserved,
sizeof(this->reserved));
return message;
}
/**
* Create a single fragment with the given data
*/
static message_t *create_fragment(private_message_t *this, payload_type_t next,
uint16_t num, uint16_t count, chunk_t data)
{
enumerator_t *enumerator;
payload_t *fragment, *payload;
message_t *message;
peer_cfg_t *peer_cfg;
ike_sa_t *ike_sa;
message = clone_message(this);
if (this->major_version == IKEV1_MAJOR_VERSION)
{
/* other implementations seem to just use 0 as message ID, so here we go */
message->set_message_id(message, 0);
/* always use the initial message type for fragments, even for quick mode
* or transaction messages. */
ike_sa = charon->bus->get_sa(charon->bus);
if (ike_sa && (peer_cfg = ike_sa->get_peer_cfg(ike_sa)) &&
peer_cfg->use_aggressive(peer_cfg))
{
message->set_exchange_type(message, AGGRESSIVE);
}
else
{
message->set_exchange_type(message, ID_PROT);
}
fragment = (payload_t*)fragment_payload_create_from_data(
num, num == count, data);
}
else
{
fragment = (payload_t*)encrypted_fragment_payload_create_from_data(
num, count, data);
if (num == 1)
{
/* only in the first fragment is this set to the type of the first
* payload in the encrypted payload */
fragment->set_next_type(fragment, next);
/* move unencrypted payloads to the first fragment */
enumerator = this->payloads->create_enumerator(this->payloads);
while (enumerator->enumerate(enumerator, &payload))
{
if (payload->get_type(payload) != PLV2_ENCRYPTED)
{
this->payloads->remove_at(this->payloads, enumerator);
message->add_payload(message, payload);
}
}
enumerator->destroy(enumerator);
}
}
message->add_payload(message, (payload_t*)fragment);
return message;
}
/**
* Destroy all fragments
*/
static void clear_fragments(private_message_t *this)
{
array_destroy_offset(this->fragments, offsetof(packet_t, destroy));
this->fragments = NULL;
}
/**
* Reduce the fragment length but ensure it stays > 0
*/
#define REDUCE_FRAG_LEN(fl, amount) ({ \
fl = max(1, (ssize_t)fl - (amount)); \
})
METHOD(message_t, fragment, status_t,
private_message_t *this, keymat_t *keymat, size_t frag_len,
enumerator_t **fragments)
{
encrypted_payload_t *encrypted = NULL;
generator_t *generator = NULL;
message_t *fragment;
packet_t *packet;
payload_type_t next = PL_NONE;
uint16_t num, count;
host_t *src, *dst;
chunk_t data;
status_t status;
uint32_t *lenpos;
size_t len;
src = this->packet->get_source(this->packet);
dst = this->packet->get_destination(this->packet);
if (!frag_len)
{
frag_len = (src->get_family(src) == AF_INET) ? 576 : 1280;
}
/* frag_len is the complete IP datagram length, account for overhead (we
* assume no IP options/extension headers are used) */
REDUCE_FRAG_LEN(frag_len, (src->get_family(src) == AF_INET) ? 20 : 40);
/* 8 (UDP header) */
REDUCE_FRAG_LEN(frag_len, 8);
if (dst->get_port(dst) != IKEV2_UDP_PORT &&
src->get_port(src) != IKEV2_UDP_PORT)
{ /* reduce length due to non-ESP marker */
REDUCE_FRAG_LEN(frag_len, 4);
}
if (is_encoded(this))
{
if (this->major_version == IKEV2_MAJOR_VERSION)
{
encrypted = (encrypted_payload_t*)get_payload(this, PLV2_ENCRYPTED);
}
data = this->packet->get_data(this->packet);
len = data.len;
}
else
{
status = generate_message(this, keymat, &generator, &encrypted);
if (status != SUCCESS)
{
DESTROY_IF(generator);
return status;
}
data = generator->get_chunk(generator, &lenpos);
len = data.len + (encrypted ? encrypted->get_length(encrypted) : 0);
}
/* check if we actually need to fragment the message and if we have an
* encrypted payload for IKEv2 */
if (len <= frag_len ||
(this->major_version == IKEV2_MAJOR_VERSION && !encrypted))
{
if (generator)
{
status = finalize_message(this, keymat, generator, encrypted);
if (status != SUCCESS)
{
return status;
}
}
*fragments = enumerator_create_single(this->packet, NULL);
return SUCCESS;
}
/* frag_len denoted the maximum IKE message size so far, later on it will
* denote the maximum content size of a fragment payload, therefore,
* account for IKE header */
REDUCE_FRAG_LEN(frag_len, 28);
if (this->major_version == IKEV1_MAJOR_VERSION)
{
if (generator)
{
status = finalize_message(this, keymat, generator, encrypted);
if (status != SUCCESS)
{
return status;
}
data = this->packet->get_data(this->packet);
generator = NULL;
}
/* overhead for the fragmentation payload header */
REDUCE_FRAG_LEN(frag_len, 8);
}
else
{
aead_t *aead;
if (generator)
{
generator->destroy(generator);
generator = generator_create();
}
else
{ /* do not log again if it was generated previously */
generator = generator_create_no_dbg();
}
next = encrypted->payload_interface.get_next_type((payload_t*)encrypted);
encrypted->generate_payloads(encrypted, generator);
data = generator->get_chunk(generator, &lenpos);
if (!is_encoded(this))
{
encrypted->destroy(encrypted);
}
aead = keymat->get_aead(keymat, FALSE);
/* overhead for the encrypted fragment payload */
REDUCE_FRAG_LEN(frag_len, aead->get_iv_size(aead));
REDUCE_FRAG_LEN(frag_len, aead->get_icv_size(aead));
/* header */
REDUCE_FRAG_LEN(frag_len, 8);
/* padding and padding length */
frag_len = round_down(frag_len, aead->get_block_size(aead));
REDUCE_FRAG_LEN(frag_len, 1);
/* TODO-FRAG: if there are unencrypted payloads, should we account for
* their length in the first fragment? we still would have to add
* an encrypted fragment payload (albeit empty), even so we couldn't
* prevent IP fragmentation in every case */
}
count = data.len / frag_len + (data.len % frag_len ? 1 : 0);
this->fragments = array_create(0, count);
DBG1(DBG_ENC, "splitting IKE message (%zu bytes) into %hu fragments", len,
count);
for (num = 1; num <= count; num++)
{
len = min(data.len, frag_len);
fragment = create_fragment(this, next, num, count,
chunk_create(data.ptr, len));
status = fragment->generate(fragment, keymat, &packet);
fragment->destroy(fragment);
if (status != SUCCESS)
{
DBG1(DBG_ENC, "failed to generate IKE fragment");
clear_fragments(this);
DESTROY_IF(generator);
return FAILED;
}
array_insert(this->fragments, ARRAY_TAIL, packet);
data = chunk_skip(data, len);
}
*fragments = array_create_enumerator(this->fragments);
DESTROY_IF(generator);
return SUCCESS;
}
METHOD(message_t, get_packet, packet_t*,
private_message_t *this)
{
return this->packet->clone(this->packet);
}
METHOD(message_t, get_packet_data, chunk_t,
private_message_t *this)
{
return this->packet->get_data(this->packet);
}
METHOD(message_t, get_fragments, enumerator_t*,
private_message_t *this)
{
return array_create_enumerator(this->fragments);
}
METHOD(message_t, parse_header, status_t,
private_message_t *this)
{
ike_header_t *ike_header;
status_t status;
bool *reserved;
int i;
DBG2(DBG_ENC, "parsing header of message");
if (!this->parser)
{ /* reassembled IKEv2 message, header is inherited from fragments */
return SUCCESS;
}
this->parser->reset_context(this->parser);
status = this->parser->parse_payload(this->parser, PL_HEADER,
(payload_t**)&ike_header);
if (status != SUCCESS)
{
DBG1(DBG_ENC, "header could not be parsed");
return status;
}
status = ike_header->payload_interface.verify(
&ike_header->payload_interface);
if (status != SUCCESS)
{
DBG1(DBG_ENC, "header verification failed");
ike_header->destroy(ike_header);
return status;
}
DESTROY_IF(this->ike_sa_id);
this->ike_sa_id = ike_sa_id_create(
ike_header->get_maj_version(ike_header),
ike_header->get_initiator_spi(ike_header),
ike_header->get_responder_spi(ike_header),
ike_header->get_initiator_flag(ike_header));
this->exchange_type = ike_header->get_exchange_type(ike_header);
this->message_id = ike_header->get_message_id(ike_header);
this->major_version = ike_header->get_maj_version(ike_header);
this->minor_version = ike_header->get_min_version(ike_header);
if (this->major_version == IKEV2_MAJOR_VERSION)
{
this->is_request = !ike_header->get_response_flag(ike_header);
}
else
{
this->is_encrypted = ike_header->get_encryption_flag(ike_header);
}
this->first_payload = ike_header->payload_interface.get_next_type(
&ike_header->payload_interface);
if (this->first_payload == PLV1_FRAGMENT && this->is_encrypted)
{ /* racoon sets the encrypted bit when sending a fragment, but these
* messages are really not encrypted */
this->is_encrypted = FALSE;
}
for (i = 0; i < countof(this->reserved); i++)
{
reserved = payload_get_field(&ike_header->payload_interface,
RESERVED_BIT, i);
if (reserved)
{
this->reserved[i] = *reserved;
}
}
ike_header->destroy(ike_header);
this->parser->set_major_version(this->parser, this->major_version);
DBG2(DBG_ENC, "parsed a %N %s header", exchange_type_names,
this->exchange_type, this->major_version == IKEV1_MAJOR_VERSION ?
"message" : (this->is_request ? "request" : "response"));
return SUCCESS;
}
/**
* Check if a payload is for a mediation extension connectivity check
*/
static bool is_connectivity_check(private_message_t *this, payload_t *payload)
{
#ifdef ME
if (this->exchange_type == INFORMATIONAL &&
payload->get_type(payload) == PLV2_NOTIFY)
{
notify_payload_t *notify = (notify_payload_t*)payload;
switch (notify->get_notify_type(notify))
{
case ME_CONNECTID:
case ME_ENDPOINT:
case ME_CONNECTAUTH:
return TRUE;
default:
break;
}
}
#endif /* !ME */
return FALSE;
}
/**
* Parses and verifies the unencrypted payloads contained in the message
*/
static status_t parse_payloads(private_message_t *this)
{
payload_type_t type = this->first_payload;
payload_t *payload;
status_t status;
if (this->is_encrypted)
{ /* wrap the whole encrypted IKEv1 message in a special encrypted
* payload which is then handled just like a regular payload */
encrypted_payload_t *encryption;
status = this->parser->parse_payload(this->parser, PLV1_ENCRYPTED,
(payload_t**)&encryption);
if (status != SUCCESS)
{
DBG1(DBG_ENC, "failed to wrap encrypted IKEv1 message");
return PARSE_ERROR;
}
encryption->payload_interface.set_next_type((payload_t*)encryption,
this->first_payload);
this->payloads->insert_last(this->payloads, encryption);
return SUCCESS;
}
while (type != PL_NONE)
{
DBG2(DBG_ENC, "starting parsing a %N payload",
payload_type_names, type);
status = this->parser->parse_payload(this->parser, type, &payload);
if (status != SUCCESS)
{
DBG1(DBG_ENC, "payload type %N could not be parsed",
payload_type_names, type);
return PARSE_ERROR;
}
DBG2(DBG_ENC, "verifying payload of type %N", payload_type_names, type);
status = payload->verify(payload);
if (status != SUCCESS)
{
DBG1(DBG_ENC, "%N payload verification failed",
payload_type_names, type);
payload->destroy(payload);
return VERIFY_ERROR;
}
if (payload->get_type(payload) == PL_UNKNOWN)
{
DBG2(DBG_ENC, "%N payload unknown or not allowed",
payload_type_names, type);
}
else
{
DBG2(DBG_ENC, "%N payload verified, adding to payload list",
payload_type_names, type);
}
this->payloads->insert_last(this->payloads, payload);
/* an encrypted (fragment) payload MUST be the last one, so STOP here.
* decryption is done later */
if (type == PLV2_ENCRYPTED || type == PLV2_FRAGMENT)
{
DBG2(DBG_ENC, "%N payload found, stop parsing",
payload_type_names, type);
break;
}
type = payload->get_next_type(payload);
}
return SUCCESS;
}
/**
* Decrypt an encrypted payload and extract all contained payloads.
*/
static status_t decrypt_and_extract(private_message_t *this, keymat_t *keymat,
payload_t *previous, encrypted_payload_t *encryption)
{
payload_t *encrypted;
payload_type_t type;
chunk_t chunk;
aead_t *aead;
size_t bs;
status_t status = SUCCESS;
if (!keymat)
{
DBG1(DBG_ENC, "found encrypted payload, but no keymat");
return INVALID_ARG;
}
aead = keymat->get_aead(keymat, TRUE);
if (!aead)
{
DBG1(DBG_ENC, "found encrypted payload, but no transform set");
return INVALID_ARG;
}
if (!this->parser)
{
/* reassembled IKEv2 messages are already decrypted, we still call
* decrypt() to parse the contained payloads */
status = encryption->decrypt(encryption, chunk_empty);
}
else
{
bs = aead->get_block_size(aead);
encryption->set_transform(encryption, aead);
chunk = this->packet->get_data(this->packet);
if (chunk.len < encryption->get_length(encryption) ||
chunk.len < bs)
{
DBG1(DBG_ENC, "invalid payload length");
return VERIFY_ERROR;
}
if (keymat->get_version(keymat) == IKEV1)
{ /* instead of associated data we provide the IV, we also update
* the IV with the last encrypted block */
keymat_v1_t *keymat_v1 = (keymat_v1_t*)keymat;
chunk_t iv;
if (keymat_v1->get_iv(keymat_v1, this->message_id, &iv))
{
status = encryption->decrypt(encryption, iv);
if (status == SUCCESS)
{
if (!keymat_v1->update_iv(keymat_v1, this->message_id,
chunk_create(chunk.ptr + chunk.len - bs, bs)))
{
status = FAILED;
}
}
}
else
{
status = FAILED;
}
}
else
{
chunk.len -= encryption->get_length(encryption);
status = encryption->decrypt(encryption, chunk);
}
}
if (status != SUCCESS)
{
return status;
}
while ((encrypted = encryption->remove_payload(encryption)))
{
type = encrypted->get_type(encrypted);
if (previous)
{
previous->set_next_type(previous, type);
}
else
{
this->first_payload = type;
}
DBG2(DBG_ENC, "insert decrypted payload of type %N at end of list",
payload_type_names, type);
this->payloads->insert_last(this->payloads, encrypted);
previous = encrypted;
}
return SUCCESS;
}
/**
* Decrypt an encrypted fragment payload.
*/
static status_t decrypt_fragment(private_message_t *this, keymat_t *keymat,
encrypted_fragment_payload_t *fragment)
{
encrypted_payload_t *encrypted = (encrypted_payload_t*)fragment;
chunk_t chunk;
aead_t *aead;
size_t bs;
if (!keymat)
{
DBG1(DBG_ENC, "found encrypted fragment payload, but no keymat");
return INVALID_ARG;
}
aead = keymat->get_aead(keymat, TRUE);
if (!aead)
{
DBG1(DBG_ENC, "found encrypted fragment payload, but no transform set");
return INVALID_ARG;
}
bs = aead->get_block_size(aead);
encrypted->set_transform(encrypted, aead);
chunk = this->packet->get_data(this->packet);
if (chunk.len < encrypted->get_length(encrypted) ||
chunk.len < bs)
{
DBG1(DBG_ENC, "invalid payload length");
return VERIFY_ERROR;
}
chunk.len -= encrypted->get_length(encrypted);
return encrypted->decrypt(encrypted, chunk);
}
/**
* Do we accept unencrypted ID/HASH payloads in Main Mode, as seen from
* some SonicWall boxes?
*/
static bool accept_unencrypted_mm(private_message_t *this, payload_type_t type)
{
if (this->exchange_type == ID_PROT)
{
if (type == PLV1_ID || type == PLV1_HASH)
{
return lib->settings->get_bool(lib->settings,
"%s.accept_unencrypted_mainmode_messages",
FALSE, lib->ns);
}
}
return FALSE;
}
/**
* Decrypt payload from the encrypted payload
*/
static status_t decrypt_payloads(private_message_t *this, keymat_t *keymat)
{
payload_t *payload, *previous = NULL;
enumerator_t *enumerator;
payload_rule_t *rule;
payload_type_t type;
status_t status = SUCCESS;
char *was_encrypted = NULL;
enumerator = this->payloads->create_enumerator(this->payloads);
while (enumerator->enumerate(enumerator, &payload))
{
type = payload->get_type(payload);
DBG2(DBG_ENC, "process payload of type %N", payload_type_names, type);
if (type == PLV2_ENCRYPTED || type == PLV1_ENCRYPTED ||
type == PLV2_FRAGMENT)
{
if (was_encrypted)
{
DBG1(DBG_ENC, "%s can't contain other payloads of type %N",
was_encrypted, payload_type_names, type);
status = VERIFY_ERROR;
break;
}
}
if (type == PLV2_ENCRYPTED || type == PLV1_ENCRYPTED)
{
encrypted_payload_t *encryption;
DBG2(DBG_ENC, "found an encrypted payload");
encryption = (encrypted_payload_t*)payload;
this->payloads->remove_at(this->payloads, enumerator);
if (enumerator->enumerate(enumerator, NULL))
{
DBG1(DBG_ENC, "encrypted payload is not last payload");
encryption->destroy(encryption);
status = VERIFY_ERROR;
break;
}
status = decrypt_and_extract(this, keymat, previous, encryption);
encryption->destroy(encryption);
if (status != SUCCESS)
{
break;
}
was_encrypted = "encrypted payload";
}
else if (type == PLV2_FRAGMENT)
{
encrypted_fragment_payload_t *fragment;
DBG2(DBG_ENC, "found an encrypted fragment payload");
fragment = (encrypted_fragment_payload_t*)payload;
if (enumerator->enumerate(enumerator, NULL))
{
DBG1(DBG_ENC, "encrypted fragment payload is not last payload");
status = VERIFY_ERROR;
break;
}
status = decrypt_fragment(this, keymat, fragment);
if (status != SUCCESS)
{
break;
}
was_encrypted = "encrypted fragment payload";
}
if (type != PL_UNKNOWN && !was_encrypted &&
!is_connectivity_check(this, payload) &&
this->exchange_type != AGGRESSIVE)
{
rule = get_payload_rule(this, type);
if ((!rule || rule->encrypted) &&
!accept_unencrypted_mm(this, type))
{
DBG1(DBG_ENC, "payload type %N was not encrypted",
payload_type_names, type);
status = FAILED;
break;
}
}
previous = payload;
}
enumerator->destroy(enumerator);
return status;
}
/**
* Verify a message and all payload according to message/payload rules
*/
static status_t verify(private_message_t *this)
{
bool complete = FALSE;
int i;
DBG2(DBG_ENC, "verifying message structure");
/* check for payloads with wrong count */
for (i = 0; i < this->rule->rule_count; i++)
{
enumerator_t *enumerator;
payload_t *payload;
payload_rule_t *rule;
int found = 0;
rule = &this->rule->rules[i];
enumerator = create_payload_enumerator(this);
while (enumerator->enumerate(enumerator, &payload))
{
payload_type_t type;
type = payload->get_type(payload);
if (type == rule->type)
{
found++;
DBG2(DBG_ENC, "found payload of type %N",
payload_type_names, type);
if (found > rule->max_occurrence)
{
DBG1(DBG_ENC, "payload of type %N more than %d times (%d) "
"occurred in current message", payload_type_names,
type, rule->max_occurrence, found);
enumerator->destroy(enumerator);
return VERIFY_ERROR;
}
}
}
enumerator->destroy(enumerator);
if (!complete && found < rule->min_occurrence)
{
DBG1(DBG_ENC, "payload of type %N not occurred %d times (%d)",
payload_type_names, rule->type, rule->min_occurrence, found);
return VERIFY_ERROR;
}
if (found && rule->sufficient)
{
complete = TRUE;
}
}
return SUCCESS;
}
METHOD(message_t, parse_body, status_t,
private_message_t *this, keymat_t *keymat)
{
status_t status = SUCCESS;
char str[BUF_LEN];
DBG2(DBG_ENC, "parsing body of message, first payload is %N",
payload_type_names, this->first_payload);
this->rule = get_message_rule(this);
if (!this->rule)
{
DBG1(DBG_ENC, "no message rules specified for a %N %s",
exchange_type_names, this->exchange_type,
this->is_request ? "request" : "response");
return NOT_SUPPORTED;
}
/* reassembled IKEv2 messages are already parsed (except for the payloads
* contained in the encrypted payload, which are handled below) */
if (this->parser)
{
status = parse_payloads(this);
if (status != SUCCESS)
{ /* error is already logged */
return status;
}
}
status = decrypt_payloads(this, keymat);
if (status != SUCCESS)
{
DBG1(DBG_ENC, "could not decrypt payloads");
return status;
}
status = verify(this);
if (status != SUCCESS)
{
return status;
}
DBG1(DBG_ENC, "parsed %s", get_string(this, str, sizeof(str)));
if (keymat && keymat->get_version(keymat) == IKEV1)
{
keymat_v1_t *keymat_v1 = (keymat_v1_t*)keymat;
chunk_t hash;
if (keymat_v1->get_hash_phase2(keymat_v1, &this->public, &hash))
{
hash_payload_t *hash_payload;
chunk_t other_hash;
if (this->first_payload != PLV1_HASH)
{
if (this->exchange_type == INFORMATIONAL_V1)
{
DBG1(DBG_ENC, "ignoring unprotected INFORMATIONAL from %H",
this->packet->get_source(this->packet));
}
else
{
DBG1(DBG_ENC, "expected HASH payload as first payload");
}
chunk_free(&hash);
return VERIFY_ERROR;
}
hash_payload = (hash_payload_t*)get_payload(this, PLV1_HASH);
other_hash = hash_payload->get_hash(hash_payload);
DBG3(DBG_ENC, "HASH received %B\nHASH expected %B",
&other_hash, &hash);
if (!chunk_equals_const(hash, other_hash))
{
DBG1(DBG_ENC, "received HASH payload does not match");
chunk_free(&hash);
return FAILED;
}
chunk_free(&hash);
}
if (this->is_encrypted && this->exchange_type != INFORMATIONAL_V1)
{ /* message verified, confirm IV */
if (!keymat_v1->confirm_iv(keymat_v1, this->message_id))
{
return FAILED;
}
}
}
return SUCCESS;
}
/**
* Store the fragment data for the fragment with the given fragment number.
*/
static status_t add_fragment(private_message_t *this, uint16_t num,
chunk_t data)
{
fragment_t *fragment;
int i, insert_at = -1;
for (i = 0; i < array_count(this->fragments); i++)
{
array_get(this->fragments, i, &fragment);
if (fragment->num == num)
{
/* ignore a duplicate fragment */
DBG1(DBG_ENC, "received duplicate fragment #%hu", num);
return NEED_MORE;
}
if (fragment->num > num)
{
insert_at = i;
break;
}
}
this->frag->len += data.len;
if (this->frag->len > this->frag->max_packet)
{
DBG1(DBG_ENC, "fragmented IKE message is too large");
reset_defrag(this);
return FAILED;
}
INIT(fragment,
.num = num,
.data = chunk_clone(data),
);
array_insert(this->fragments, insert_at, fragment);
return SUCCESS;
}
/**
* Merge the cached fragment data and resets the defragmentation state.
* Also updates the IP addresses to those of the last received fragment.
*/
static chunk_t merge_fragments(private_message_t *this, message_t *last)
{
fragment_t *fragment;
bio_writer_t *writer;
host_t *src, *dst;
chunk_t data;
int i;
writer = bio_writer_create(this->frag->len);
for (i = 0; i < array_count(this->fragments); i++)
{
array_get(this->fragments, i, &fragment);
writer->write_data(writer, fragment->data);
}
data = writer->extract_buf(writer);
writer->destroy(writer);
/* set addresses to those of the last fragment we received */
src = last->get_source(last);
dst = last->get_destination(last);
this->packet->set_source(this->packet, src->clone(src));
this->packet->set_destination(this->packet, dst->clone(dst));
reset_defrag(this);
free(this->frag);
this->frag = NULL;
return data;
}
METHOD(message_t, add_fragment_v1, status_t,
private_message_t *this, message_t *message)
{
fragment_payload_t *payload;
chunk_t data;
uint8_t num;
status_t status;
if (!this->frag)
{
return INVALID_STATE;
}
payload = (fragment_payload_t*)message->get_payload(message, PLV1_FRAGMENT);
if (!payload)
{
return INVALID_ARG;
}
if (!this->fragments || this->message_id != payload->get_id(payload))
{
reset_defrag(this);
this->message_id = payload->get_id(payload);
/* we don't know the total number of fragments, assume something */
this->fragments = array_create(0, 4);
}
num = payload->get_number(payload);
data = payload->get_data(payload);
if (!this->frag->last && payload->is_last(payload))
{
this->frag->last = num;
}
status = add_fragment(this, num, data);
if (status != SUCCESS)
{
return status;
}
if (array_count(this->fragments) != this->frag->last)
{
/* there are some fragments missing */
DBG1(DBG_ENC, "received fragment #%hhu, waiting for complete IKE "
"message", num);
return NEED_MORE;
}
data = merge_fragments(this, message);
this->packet->set_data(this->packet, data);
DBG1(DBG_ENC, "received fragment #%hhu, reassembled fragmented IKE "
"message (%zu bytes)", num, data.len);
this->parser = parser_create(data);
if (parse_header(this) != SUCCESS)
{
DBG1(DBG_IKE, "failed to parse header of reassembled IKE message");
return FAILED;
}
return SUCCESS;
}
METHOD(message_t, add_fragment_v2, status_t,
private_message_t *this, message_t *message)
{
encrypted_fragment_payload_t *encrypted_fragment;
encrypted_payload_t *encrypted;
payload_t *payload;
aead_t *aead;
enumerator_t *enumerator;
chunk_t data;
uint16_t total, num;
size_t len;
status_t status;
if (!this->frag)
{
return INVALID_STATE;
}
payload = message->get_payload(message, PLV2_FRAGMENT);
if (!payload || this->message_id != message->get_message_id(message))
{
return INVALID_ARG;
}
encrypted_fragment = (encrypted_fragment_payload_t*)payload;
total = encrypted_fragment->get_total_fragments(encrypted_fragment);
if (total > MAX_FRAGMENTS)
{
DBG1(DBG_IKE, "maximum fragment count exceeded");
reset_defrag(this);
return FAILED;
}
if (!this->fragments || total > this->frag->last)
{
reset_defrag(this);
this->frag->last = total;
this->fragments = array_create(0, total);
}
num = encrypted_fragment->get_fragment_number(encrypted_fragment);
data = encrypted_fragment->get_content(encrypted_fragment);
status = add_fragment(this, num, data);
if (status != SUCCESS)
{
return status;
}
if (num == 1)
{
/* the first fragment denotes the payload type of the first payload in
* the original encrypted payload, cache that */
this->first_payload = payload->get_next_type(payload);
/* move all unencrypted payloads contained in the first fragment */
enumerator = message->create_payload_enumerator(message);
while (enumerator->enumerate(enumerator, &payload))
{
if (payload->get_type(payload) != PLV2_FRAGMENT)
{
message->remove_payload_at(message, enumerator);
this->payloads->insert_last(this->payloads, payload);
}
}
enumerator->destroy(enumerator);
}
if (array_count(this->fragments) != total)
{
/* there are some fragments missing */
DBG1(DBG_ENC, "received fragment #%hu of %hu, waiting for complete IKE "
"message", num, total);
return NEED_MORE;
}
encrypted = (encrypted_payload_t*)encrypted_fragment;
aead = encrypted->get_transform(encrypted);
data = merge_fragments(this, message);
encrypted = encrypted_payload_create_from_plain(this->first_payload, data);
encrypted->set_transform(encrypted, aead);
this->payloads->insert_last(this->payloads, encrypted);
/* update next payload type (could be an unencrypted payload) */
this->payloads->get_first(this->payloads, (void**)&payload);
this->first_payload = payload->get_type(payload);
/* we report the length of the complete IKE message when splitting, do the
* same here, so add the IKEv2 header len to the reassembled payload data */
len = 28;
enumerator = create_payload_enumerator(this);
while (enumerator->enumerate(enumerator, &payload))
{
len += payload->get_length(payload);
}
enumerator->destroy(enumerator);
DBG1(DBG_ENC, "received fragment #%hu of %hu, reassembled fragmented IKE "
"message (%zu bytes)", num, total, len);
return SUCCESS;
}
METHOD(message_t, destroy, void,
private_message_t *this)
{
DESTROY_IF(this->ike_sa_id);
DESTROY_IF(this->parser);
this->payloads->destroy_offset(this->payloads, offsetof(payload_t, destroy));
this->packet->destroy(this->packet);
if (this->frag)
{
reset_defrag(this);
free(this->frag);
}
else
{
array_destroy_offset(this->fragments, offsetof(packet_t, destroy));
}
free(this);
}
/*
* Described in header.
*/
message_t *message_create_from_packet(packet_t *packet)
{
private_message_t *this;
INIT(this,
.public = {
.set_major_version = _set_major_version,
.get_major_version = _get_major_version,
.set_minor_version = _set_minor_version,
.get_minor_version = _get_minor_version,
.set_message_id = _set_message_id,
.get_message_id = _get_message_id,
.get_initiator_spi = _get_initiator_spi,
.get_responder_spi = _get_responder_spi,
.set_ike_sa_id = _set_ike_sa_id,
.get_ike_sa_id = _get_ike_sa_id,
.set_exchange_type = _set_exchange_type,
.get_exchange_type = _get_exchange_type,
.get_first_payload_type = _get_first_payload_type,
.set_request = _set_request,
.get_request = _get_request,
.set_version_flag = _set_version_flag,
.get_reserved_header_bit = _get_reserved_header_bit,
.set_reserved_header_bit = _set_reserved_header_bit,
.add_payload = _add_payload,
.add_notify = _add_notify,
.disable_sort = _disable_sort,
.generate = _generate,
.is_encoded = _is_encoded,
.is_fragmented = _is_fragmented,
.fragment = _fragment,
.add_fragment = _add_fragment_v2,
.set_source = _set_source,
.get_source = _get_source,
.set_destination = _set_destination,
.get_destination = _get_destination,
.create_payload_enumerator = _create_payload_enumerator,
.remove_payload_at = _remove_payload_at,
.get_payload = _get_payload,
.get_notify = _get_notify,
.parse_header = _parse_header,
.parse_body = _parse_body,
.get_packet = _get_packet,
.get_packet_data = _get_packet_data,
.get_fragments = _get_fragments,
.destroy = _destroy,
},
.exchange_type = EXCHANGE_TYPE_UNDEFINED,
.is_request = TRUE,
.first_payload = PL_NONE,
.packet = packet,
.payloads = linked_list_create(),
.parser = parser_create(packet->get_data(packet)),
);
return &this->public;
}
/*
* Described in header.
*/
message_t *message_create(int major, int minor)
{
message_t *this = message_create_from_packet(packet_create());
this->set_major_version(this, major);
this->set_minor_version(this, minor);
return this;
}
/*
* Described in header.
*/
message_t *message_create_defrag(message_t *fragment)
{
private_message_t *this;
if (!fragment->get_payload(fragment, PLV1_FRAGMENT) &&
!fragment->get_payload(fragment, PLV2_FRAGMENT))
{
return NULL;
}
this = (private_message_t*)clone_message((private_message_t*)fragment);
/* we don't need a parser for IKEv2, the one for IKEv1 is created after
* reassembling the original message */
this->parser->destroy(this->parser);
this->parser = NULL;
if (fragment->get_major_version(fragment) == IKEV1_MAJOR_VERSION)
{
/* we store the fragment ID in the message ID field, which should be
* zero for fragments, but make sure */
this->message_id = 0;
this->public.add_fragment = _add_fragment_v1;
}
INIT(this->frag,
.max_packet = lib->settings->get_int(lib->settings,
"%s.max_packet", PACKET_MAX_DEFAULT, lib->ns),
);
return &this->public;
}
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