hostapd/src/ap/pmksa_cache_auth.c

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/*
* hostapd - PMKSA cache for IEEE 802.11i RSN
* Copyright (c) 2004-2008, 2012-2015, Jouni Malinen <j@w1.fi>
*
* This software may be distributed under the terms of the BSD license.
* See README for more details.
*/
#include "utils/includes.h"
#include "utils/common.h"
#include "utils/eloop.h"
#include "eapol_auth/eapol_auth_sm.h"
#include "eapol_auth/eapol_auth_sm_i.h"
#include "radius/radius_das.h"
#include "sta_info.h"
#include "ap_config.h"
#include "pmksa_cache_auth.h"
static const int pmksa_cache_max_entries = 1024;
static const int dot11RSNAConfigPMKLifetime = 43200;
struct rsn_pmksa_cache {
#define PMKID_HASH_SIZE 128
#define PMKID_HASH(pmkid) (unsigned int) ((pmkid)[0] & 0x7f)
struct rsn_pmksa_cache_entry *pmkid[PMKID_HASH_SIZE];
struct rsn_pmksa_cache_entry *pmksa;
int pmksa_count;
void (*free_cb)(struct rsn_pmksa_cache_entry *entry, void *ctx);
void *ctx;
};
static void pmksa_cache_set_expiration(struct rsn_pmksa_cache *pmksa);
static void _pmksa_cache_free_entry(struct rsn_pmksa_cache_entry *entry)
{
VLAN: Separate station grouping and uplink configuration Separate uplink configuration (IEEE 802.1q VID) and grouping of stations into AP_VLAN interfaces. The int vlan_id will continue to identify the AP_VLAN interface the station should be assigned to. Each AP_VLAN interface corresponds to an instance of struct hostapd_vlan that is uniquely identified by int vlan_id within an BSS. New: Each station and struct hostapd_vlan holds a struct vlan_description vlan_desc member that describes the uplink configuration requested. Currently this is just an int untagged IEEE 802.1q VID, but can be extended to tagged VLANs and other settings easily. When the station was about to be assigned its vlan_id, vlan_desc and vlan_id will now be set simultaneously by ap_sta_set_vlan(). So sta->vlan_id can still be tested for whether the station needs to be moved to an AP_VLAN interface. To ease addition of tagged VLAN support, a member notempty is added to struct vlan_description. Is is set to 1 if an untagged or tagged VLAN assignment is requested and needs to be validated. The inverted form allows os_zalloc() to initialize an empty description. Though not depended on by the code, vlan_id assignment ensures: * vlan_id = 0 will continue to mean no AP_VLAN interface * vlan_id < 4096 will continue to mean vlan_id = untagged vlan id with no per_sta_vif and no extra tagged vlan. * vlan_id > 4096 will be used for per_sta_vif and/or tagged vlans. This way struct wpa_group and drivers API do not need to be changed in order to implement tagged VLANs or per_sta_vif support. DYNAMIC_VLAN_* will refer to (struct vlan_description).notempty only, thus grouping of the stations for per_sta_vif can be used with DYNAMIC_VLAN_DISABLED, but not with CONFIG_NO_VLAN, as struct hostapd_vlan is still used to manage AP_VLAN interfaces. MAX_VLAN_ID will be checked in hostapd_vlan_valid and during setup of VLAN interfaces and refer to IEEE 802.1q VID. VLAN_ID_WILDCARD will continue to refer to int vlan_id. Renaming vlan_id to vlan_desc when type changed from int to struct vlan_description was avoided when vlan_id was also used in a way that did not depend on its type (for example, when passed to another function). Output of "VLAN ID %d" continues to refer to int vlan_id, while "VLAN %d" will refer to untagged IEEE 802.1q VID. Signed-off-by: Michael Braun <michael-dev@fami-braun.de>
2016-01-21 14:51:56 +01:00
os_free(entry->vlan_desc);
os_free(entry->identity);
os_free(entry->dpp_pkhash);
wpabuf_free(entry->cui);
#ifndef CONFIG_NO_RADIUS
radius_free_class(&entry->radius_class);
#endif /* CONFIG_NO_RADIUS */
bin_clear_free(entry, sizeof(*entry));
}
void pmksa_cache_free_entry(struct rsn_pmksa_cache *pmksa,
struct rsn_pmksa_cache_entry *entry)
{
struct rsn_pmksa_cache_entry *pos, *prev;
unsigned int hash;
pmksa->pmksa_count--;
if (pmksa->free_cb)
pmksa->free_cb(entry, pmksa->ctx);
/* unlink from hash list */
hash = PMKID_HASH(entry->pmkid);
pos = pmksa->pmkid[hash];
prev = NULL;
while (pos) {
if (pos == entry) {
if (prev != NULL)
prev->hnext = entry->hnext;
else
pmksa->pmkid[hash] = entry->hnext;
break;
}
prev = pos;
pos = pos->hnext;
}
/* unlink from entry list */
pos = pmksa->pmksa;
prev = NULL;
while (pos) {
if (pos == entry) {
if (prev != NULL)
prev->next = entry->next;
else
pmksa->pmksa = entry->next;
break;
}
prev = pos;
pos = pos->next;
}
_pmksa_cache_free_entry(entry);
}
/**
* pmksa_cache_auth_flush - Flush all PMKSA cache entries
* @pmksa: Pointer to PMKSA cache data from pmksa_cache_auth_init()
*/
void pmksa_cache_auth_flush(struct rsn_pmksa_cache *pmksa)
{
while (pmksa->pmksa) {
wpa_printf(MSG_DEBUG, "RSN: Flush PMKSA cache entry for "
MACSTR, MAC2STR(pmksa->pmksa->spa));
pmksa_cache_free_entry(pmksa, pmksa->pmksa);
}
}
static void pmksa_cache_expire(void *eloop_ctx, void *timeout_ctx)
{
struct rsn_pmksa_cache *pmksa = eloop_ctx;
struct os_reltime now;
os_get_reltime(&now);
while (pmksa->pmksa && pmksa->pmksa->expiration <= now.sec) {
wpa_printf(MSG_DEBUG, "RSN: expired PMKSA cache entry for "
MACSTR, MAC2STR(pmksa->pmksa->spa));
pmksa_cache_free_entry(pmksa, pmksa->pmksa);
}
pmksa_cache_set_expiration(pmksa);
}
static void pmksa_cache_set_expiration(struct rsn_pmksa_cache *pmksa)
{
int sec;
struct os_reltime now;
eloop_cancel_timeout(pmksa_cache_expire, pmksa, NULL);
if (pmksa->pmksa == NULL)
return;
os_get_reltime(&now);
sec = pmksa->pmksa->expiration - now.sec;
if (sec < 0)
sec = 0;
eloop_register_timeout(sec + 1, 0, pmksa_cache_expire, pmksa, NULL);
}
static void pmksa_cache_from_eapol_data(struct rsn_pmksa_cache_entry *entry,
struct eapol_state_machine *eapol)
{
VLAN: Separate station grouping and uplink configuration Separate uplink configuration (IEEE 802.1q VID) and grouping of stations into AP_VLAN interfaces. The int vlan_id will continue to identify the AP_VLAN interface the station should be assigned to. Each AP_VLAN interface corresponds to an instance of struct hostapd_vlan that is uniquely identified by int vlan_id within an BSS. New: Each station and struct hostapd_vlan holds a struct vlan_description vlan_desc member that describes the uplink configuration requested. Currently this is just an int untagged IEEE 802.1q VID, but can be extended to tagged VLANs and other settings easily. When the station was about to be assigned its vlan_id, vlan_desc and vlan_id will now be set simultaneously by ap_sta_set_vlan(). So sta->vlan_id can still be tested for whether the station needs to be moved to an AP_VLAN interface. To ease addition of tagged VLAN support, a member notempty is added to struct vlan_description. Is is set to 1 if an untagged or tagged VLAN assignment is requested and needs to be validated. The inverted form allows os_zalloc() to initialize an empty description. Though not depended on by the code, vlan_id assignment ensures: * vlan_id = 0 will continue to mean no AP_VLAN interface * vlan_id < 4096 will continue to mean vlan_id = untagged vlan id with no per_sta_vif and no extra tagged vlan. * vlan_id > 4096 will be used for per_sta_vif and/or tagged vlans. This way struct wpa_group and drivers API do not need to be changed in order to implement tagged VLANs or per_sta_vif support. DYNAMIC_VLAN_* will refer to (struct vlan_description).notempty only, thus grouping of the stations for per_sta_vif can be used with DYNAMIC_VLAN_DISABLED, but not with CONFIG_NO_VLAN, as struct hostapd_vlan is still used to manage AP_VLAN interfaces. MAX_VLAN_ID will be checked in hostapd_vlan_valid and during setup of VLAN interfaces and refer to IEEE 802.1q VID. VLAN_ID_WILDCARD will continue to refer to int vlan_id. Renaming vlan_id to vlan_desc when type changed from int to struct vlan_description was avoided when vlan_id was also used in a way that did not depend on its type (for example, when passed to another function). Output of "VLAN ID %d" continues to refer to int vlan_id, while "VLAN %d" will refer to untagged IEEE 802.1q VID. Signed-off-by: Michael Braun <michael-dev@fami-braun.de>
2016-01-21 14:51:56 +01:00
struct vlan_description *vlan_desc;
if (eapol == NULL)
return;
if (eapol->identity) {
entry->identity = os_malloc(eapol->identity_len);
if (entry->identity) {
entry->identity_len = eapol->identity_len;
os_memcpy(entry->identity, eapol->identity,
eapol->identity_len);
}
}
if (eapol->radius_cui)
entry->cui = wpabuf_dup(eapol->radius_cui);
#ifndef CONFIG_NO_RADIUS
radius_copy_class(&entry->radius_class, &eapol->radius_class);
#endif /* CONFIG_NO_RADIUS */
entry->eap_type_authsrv = eapol->eap_type_authsrv;
VLAN: Separate station grouping and uplink configuration Separate uplink configuration (IEEE 802.1q VID) and grouping of stations into AP_VLAN interfaces. The int vlan_id will continue to identify the AP_VLAN interface the station should be assigned to. Each AP_VLAN interface corresponds to an instance of struct hostapd_vlan that is uniquely identified by int vlan_id within an BSS. New: Each station and struct hostapd_vlan holds a struct vlan_description vlan_desc member that describes the uplink configuration requested. Currently this is just an int untagged IEEE 802.1q VID, but can be extended to tagged VLANs and other settings easily. When the station was about to be assigned its vlan_id, vlan_desc and vlan_id will now be set simultaneously by ap_sta_set_vlan(). So sta->vlan_id can still be tested for whether the station needs to be moved to an AP_VLAN interface. To ease addition of tagged VLAN support, a member notempty is added to struct vlan_description. Is is set to 1 if an untagged or tagged VLAN assignment is requested and needs to be validated. The inverted form allows os_zalloc() to initialize an empty description. Though not depended on by the code, vlan_id assignment ensures: * vlan_id = 0 will continue to mean no AP_VLAN interface * vlan_id < 4096 will continue to mean vlan_id = untagged vlan id with no per_sta_vif and no extra tagged vlan. * vlan_id > 4096 will be used for per_sta_vif and/or tagged vlans. This way struct wpa_group and drivers API do not need to be changed in order to implement tagged VLANs or per_sta_vif support. DYNAMIC_VLAN_* will refer to (struct vlan_description).notempty only, thus grouping of the stations for per_sta_vif can be used with DYNAMIC_VLAN_DISABLED, but not with CONFIG_NO_VLAN, as struct hostapd_vlan is still used to manage AP_VLAN interfaces. MAX_VLAN_ID will be checked in hostapd_vlan_valid and during setup of VLAN interfaces and refer to IEEE 802.1q VID. VLAN_ID_WILDCARD will continue to refer to int vlan_id. Renaming vlan_id to vlan_desc when type changed from int to struct vlan_description was avoided when vlan_id was also used in a way that did not depend on its type (for example, when passed to another function). Output of "VLAN ID %d" continues to refer to int vlan_id, while "VLAN %d" will refer to untagged IEEE 802.1q VID. Signed-off-by: Michael Braun <michael-dev@fami-braun.de>
2016-01-21 14:51:56 +01:00
vlan_desc = ((struct sta_info *) eapol->sta)->vlan_desc;
if (vlan_desc && vlan_desc->notempty) {
entry->vlan_desc = os_zalloc(sizeof(struct vlan_description));
if (entry->vlan_desc)
*entry->vlan_desc = *vlan_desc;
} else {
entry->vlan_desc = NULL;
}
entry->acct_multi_session_id = eapol->acct_multi_session_id;
}
VLAN: Separate station grouping and uplink configuration Separate uplink configuration (IEEE 802.1q VID) and grouping of stations into AP_VLAN interfaces. The int vlan_id will continue to identify the AP_VLAN interface the station should be assigned to. Each AP_VLAN interface corresponds to an instance of struct hostapd_vlan that is uniquely identified by int vlan_id within an BSS. New: Each station and struct hostapd_vlan holds a struct vlan_description vlan_desc member that describes the uplink configuration requested. Currently this is just an int untagged IEEE 802.1q VID, but can be extended to tagged VLANs and other settings easily. When the station was about to be assigned its vlan_id, vlan_desc and vlan_id will now be set simultaneously by ap_sta_set_vlan(). So sta->vlan_id can still be tested for whether the station needs to be moved to an AP_VLAN interface. To ease addition of tagged VLAN support, a member notempty is added to struct vlan_description. Is is set to 1 if an untagged or tagged VLAN assignment is requested and needs to be validated. The inverted form allows os_zalloc() to initialize an empty description. Though not depended on by the code, vlan_id assignment ensures: * vlan_id = 0 will continue to mean no AP_VLAN interface * vlan_id < 4096 will continue to mean vlan_id = untagged vlan id with no per_sta_vif and no extra tagged vlan. * vlan_id > 4096 will be used for per_sta_vif and/or tagged vlans. This way struct wpa_group and drivers API do not need to be changed in order to implement tagged VLANs or per_sta_vif support. DYNAMIC_VLAN_* will refer to (struct vlan_description).notempty only, thus grouping of the stations for per_sta_vif can be used with DYNAMIC_VLAN_DISABLED, but not with CONFIG_NO_VLAN, as struct hostapd_vlan is still used to manage AP_VLAN interfaces. MAX_VLAN_ID will be checked in hostapd_vlan_valid and during setup of VLAN interfaces and refer to IEEE 802.1q VID. VLAN_ID_WILDCARD will continue to refer to int vlan_id. Renaming vlan_id to vlan_desc when type changed from int to struct vlan_description was avoided when vlan_id was also used in a way that did not depend on its type (for example, when passed to another function). Output of "VLAN ID %d" continues to refer to int vlan_id, while "VLAN %d" will refer to untagged IEEE 802.1q VID. Signed-off-by: Michael Braun <michael-dev@fami-braun.de>
2016-01-21 14:51:56 +01:00
void pmksa_cache_to_eapol_data(struct hostapd_data *hapd,
struct rsn_pmksa_cache_entry *entry,
struct eapol_state_machine *eapol)
{
if (entry == NULL || eapol == NULL)
return;
if (entry->identity) {
os_free(eapol->identity);
eapol->identity = os_malloc(entry->identity_len);
if (eapol->identity) {
eapol->identity_len = entry->identity_len;
os_memcpy(eapol->identity, entry->identity,
entry->identity_len);
}
wpa_hexdump_ascii(MSG_DEBUG, "STA identity from PMKSA",
eapol->identity, eapol->identity_len);
}
if (entry->cui) {
wpabuf_free(eapol->radius_cui);
eapol->radius_cui = wpabuf_dup(entry->cui);
}
#ifndef CONFIG_NO_RADIUS
radius_free_class(&eapol->radius_class);
radius_copy_class(&eapol->radius_class, &entry->radius_class);
#endif /* CONFIG_NO_RADIUS */
if (eapol->radius_class.attr) {
wpa_printf(MSG_DEBUG, "Copied %lu Class attribute(s) from "
"PMKSA", (unsigned long) eapol->radius_class.count);
}
eapol->eap_type_authsrv = entry->eap_type_authsrv;
#ifndef CONFIG_NO_VLAN
ap_sta_set_vlan(hapd, eapol->sta, entry->vlan_desc);
#endif /* CONFIG_NO_VLAN */
eapol->acct_multi_session_id = entry->acct_multi_session_id;
}
static void pmksa_cache_link_entry(struct rsn_pmksa_cache *pmksa,
struct rsn_pmksa_cache_entry *entry)
{
struct rsn_pmksa_cache_entry *pos, *prev;
int hash;
/* Add the new entry; order by expiration time */
pos = pmksa->pmksa;
prev = NULL;
while (pos) {
if (pos->expiration > entry->expiration)
break;
prev = pos;
pos = pos->next;
}
if (prev == NULL) {
entry->next = pmksa->pmksa;
pmksa->pmksa = entry;
} else {
entry->next = prev->next;
prev->next = entry;
}
hash = PMKID_HASH(entry->pmkid);
entry->hnext = pmksa->pmkid[hash];
pmksa->pmkid[hash] = entry;
pmksa->pmksa_count++;
if (prev == NULL)
pmksa_cache_set_expiration(pmksa);
wpa_printf(MSG_DEBUG, "RSN: added PMKSA cache entry for " MACSTR,
MAC2STR(entry->spa));
wpa_hexdump(MSG_DEBUG, "RSN: added PMKID", entry->pmkid, PMKID_LEN);
}
/**
* pmksa_cache_auth_add - Add a PMKSA cache entry
* @pmksa: Pointer to PMKSA cache data from pmksa_cache_auth_init()
* @pmk: The new pairwise master key
* @pmk_len: PMK length in bytes, usually PMK_LEN (32)
* @pmkid: Calculated PMKID
* @kck: Key confirmation key or %NULL if not yet derived
* @kck_len: KCK length in bytes
* @aa: Authenticator address
* @spa: Supplicant address
* @session_timeout: Session timeout
* @eapol: Pointer to EAPOL state machine data
* @akmp: WPA_KEY_MGMT_* used in key derivation
* Returns: Pointer to the added PMKSA cache entry or %NULL on error
*
* This function create a PMKSA entry for a new PMK and adds it to the PMKSA
* cache. If an old entry is already in the cache for the same Supplicant,
* this entry will be replaced with the new entry. PMKID will be calculated
* based on the PMK.
*/
struct rsn_pmksa_cache_entry *
pmksa_cache_auth_add(struct rsn_pmksa_cache *pmksa,
const u8 *pmk, size_t pmk_len, const u8 *pmkid,
const u8 *kck, size_t kck_len,
const u8 *aa, const u8 *spa, int session_timeout,
struct eapol_state_machine *eapol, int akmp)
{
struct rsn_pmksa_cache_entry *entry;
entry = pmksa_cache_auth_create_entry(pmk, pmk_len, pmkid, kck, kck_len,
aa, spa, session_timeout, eapol,
akmp);
if (pmksa_cache_auth_add_entry(pmksa, entry) < 0)
return NULL;
return entry;
}
/**
* pmksa_cache_auth_create_entry - Create a PMKSA cache entry
* @pmk: The new pairwise master key
* @pmk_len: PMK length in bytes, usually PMK_LEN (32)
* @pmkid: Calculated PMKID
* @kck: Key confirmation key or %NULL if not yet derived
* @kck_len: KCK length in bytes
* @aa: Authenticator address
* @spa: Supplicant address
* @session_timeout: Session timeout
* @eapol: Pointer to EAPOL state machine data
* @akmp: WPA_KEY_MGMT_* used in key derivation
* Returns: Pointer to the added PMKSA cache entry or %NULL on error
*
* This function creates a PMKSA entry.
*/
struct rsn_pmksa_cache_entry *
pmksa_cache_auth_create_entry(const u8 *pmk, size_t pmk_len, const u8 *pmkid,
const u8 *kck, size_t kck_len, const u8 *aa,
const u8 *spa, int session_timeout,
struct eapol_state_machine *eapol, int akmp)
{
struct rsn_pmksa_cache_entry *entry;
struct os_reltime now;
if (pmk_len > PMK_LEN_MAX)
return NULL;
if (wpa_key_mgmt_suite_b(akmp) && !kck)
return NULL;
entry = os_zalloc(sizeof(*entry));
if (entry == NULL)
return NULL;
os_memcpy(entry->pmk, pmk, pmk_len);
entry->pmk_len = pmk_len;
if (pmkid)
os_memcpy(entry->pmkid, pmkid, PMKID_LEN);
else if (akmp == WPA_KEY_MGMT_IEEE8021X_SUITE_B_192)
rsn_pmkid_suite_b_192(kck, kck_len, aa, spa, entry->pmkid);
else if (wpa_key_mgmt_suite_b(akmp))
rsn_pmkid_suite_b(kck, kck_len, aa, spa, entry->pmkid);
else
rsn_pmkid(pmk, pmk_len, aa, spa, entry->pmkid, akmp);
os_get_reltime(&now);
entry->expiration = now.sec;
if (session_timeout > 0)
entry->expiration += session_timeout;
else
entry->expiration += dot11RSNAConfigPMKLifetime;
entry->akmp = akmp;
os_memcpy(entry->spa, spa, ETH_ALEN);
pmksa_cache_from_eapol_data(entry, eapol);
return entry;
}
/**
* pmksa_cache_auth_add_entry - Add a PMKSA cache entry
* @pmksa: Pointer to PMKSA cache data from pmksa_cache_auth_init()
* @entry: Pointer to PMKSA cache entry
*
* This function adds PMKSA cache entry to the PMKSA cache. If an old entry is
* already in the cache for the same Supplicant, this entry will be replaced
* with the new entry. PMKID will be calculated based on the PMK.
*/
int pmksa_cache_auth_add_entry(struct rsn_pmksa_cache *pmksa,
struct rsn_pmksa_cache_entry *entry)
{
struct rsn_pmksa_cache_entry *pos;
if (entry == NULL)
return -1;
/* Replace an old entry for the same STA (if found) with the new entry
*/
pos = pmksa_cache_auth_get(pmksa, entry->spa, NULL);
if (pos)
pmksa_cache_free_entry(pmksa, pos);
if (pmksa->pmksa_count >= pmksa_cache_max_entries && pmksa->pmksa) {
/* Remove the oldest entry to make room for the new entry */
wpa_printf(MSG_DEBUG, "RSN: removed the oldest PMKSA cache "
"entry (for " MACSTR ") to make room for new one",
MAC2STR(pmksa->pmksa->spa));
pmksa_cache_free_entry(pmksa, pmksa->pmksa);
}
pmksa_cache_link_entry(pmksa, entry);
return 0;
}
struct rsn_pmksa_cache_entry *
pmksa_cache_add_okc(struct rsn_pmksa_cache *pmksa,
const struct rsn_pmksa_cache_entry *old_entry,
const u8 *aa, const u8 *pmkid)
{
struct rsn_pmksa_cache_entry *entry;
entry = os_zalloc(sizeof(*entry));
if (entry == NULL)
return NULL;
os_memcpy(entry->pmkid, pmkid, PMKID_LEN);
os_memcpy(entry->pmk, old_entry->pmk, old_entry->pmk_len);
entry->pmk_len = old_entry->pmk_len;
entry->expiration = old_entry->expiration;
entry->akmp = old_entry->akmp;
os_memcpy(entry->spa, old_entry->spa, ETH_ALEN);
entry->opportunistic = 1;
if (old_entry->identity) {
entry->identity = os_malloc(old_entry->identity_len);
if (entry->identity) {
entry->identity_len = old_entry->identity_len;
os_memcpy(entry->identity, old_entry->identity,
old_entry->identity_len);
}
}
if (old_entry->cui)
entry->cui = wpabuf_dup(old_entry->cui);
#ifndef CONFIG_NO_RADIUS
radius_copy_class(&entry->radius_class, &old_entry->radius_class);
#endif /* CONFIG_NO_RADIUS */
entry->eap_type_authsrv = old_entry->eap_type_authsrv;
VLAN: Separate station grouping and uplink configuration Separate uplink configuration (IEEE 802.1q VID) and grouping of stations into AP_VLAN interfaces. The int vlan_id will continue to identify the AP_VLAN interface the station should be assigned to. Each AP_VLAN interface corresponds to an instance of struct hostapd_vlan that is uniquely identified by int vlan_id within an BSS. New: Each station and struct hostapd_vlan holds a struct vlan_description vlan_desc member that describes the uplink configuration requested. Currently this is just an int untagged IEEE 802.1q VID, but can be extended to tagged VLANs and other settings easily. When the station was about to be assigned its vlan_id, vlan_desc and vlan_id will now be set simultaneously by ap_sta_set_vlan(). So sta->vlan_id can still be tested for whether the station needs to be moved to an AP_VLAN interface. To ease addition of tagged VLAN support, a member notempty is added to struct vlan_description. Is is set to 1 if an untagged or tagged VLAN assignment is requested and needs to be validated. The inverted form allows os_zalloc() to initialize an empty description. Though not depended on by the code, vlan_id assignment ensures: * vlan_id = 0 will continue to mean no AP_VLAN interface * vlan_id < 4096 will continue to mean vlan_id = untagged vlan id with no per_sta_vif and no extra tagged vlan. * vlan_id > 4096 will be used for per_sta_vif and/or tagged vlans. This way struct wpa_group and drivers API do not need to be changed in order to implement tagged VLANs or per_sta_vif support. DYNAMIC_VLAN_* will refer to (struct vlan_description).notempty only, thus grouping of the stations for per_sta_vif can be used with DYNAMIC_VLAN_DISABLED, but not with CONFIG_NO_VLAN, as struct hostapd_vlan is still used to manage AP_VLAN interfaces. MAX_VLAN_ID will be checked in hostapd_vlan_valid and during setup of VLAN interfaces and refer to IEEE 802.1q VID. VLAN_ID_WILDCARD will continue to refer to int vlan_id. Renaming vlan_id to vlan_desc when type changed from int to struct vlan_description was avoided when vlan_id was also used in a way that did not depend on its type (for example, when passed to another function). Output of "VLAN ID %d" continues to refer to int vlan_id, while "VLAN %d" will refer to untagged IEEE 802.1q VID. Signed-off-by: Michael Braun <michael-dev@fami-braun.de>
2016-01-21 14:51:56 +01:00
if (old_entry->vlan_desc) {
entry->vlan_desc = os_zalloc(sizeof(struct vlan_description));
if (entry->vlan_desc)
*entry->vlan_desc = *old_entry->vlan_desc;
} else {
entry->vlan_desc = NULL;
}
entry->opportunistic = 1;
pmksa_cache_link_entry(pmksa, entry);
return entry;
}
/**
* pmksa_cache_auth_deinit - Free all entries in PMKSA cache
* @pmksa: Pointer to PMKSA cache data from pmksa_cache_auth_init()
*/
void pmksa_cache_auth_deinit(struct rsn_pmksa_cache *pmksa)
{
struct rsn_pmksa_cache_entry *entry, *prev;
int i;
if (pmksa == NULL)
return;
entry = pmksa->pmksa;
while (entry) {
prev = entry;
entry = entry->next;
_pmksa_cache_free_entry(prev);
}
eloop_cancel_timeout(pmksa_cache_expire, pmksa, NULL);
pmksa->pmksa_count = 0;
pmksa->pmksa = NULL;
for (i = 0; i < PMKID_HASH_SIZE; i++)
pmksa->pmkid[i] = NULL;
os_free(pmksa);
}
/**
* pmksa_cache_auth_get - Fetch a PMKSA cache entry
* @pmksa: Pointer to PMKSA cache data from pmksa_cache_auth_init()
* @spa: Supplicant address or %NULL to match any
* @pmkid: PMKID or %NULL to match any
* Returns: Pointer to PMKSA cache entry or %NULL if no match was found
*/
struct rsn_pmksa_cache_entry *
pmksa_cache_auth_get(struct rsn_pmksa_cache *pmksa,
const u8 *spa, const u8 *pmkid)
{
struct rsn_pmksa_cache_entry *entry;
if (pmkid) {
for (entry = pmksa->pmkid[PMKID_HASH(pmkid)]; entry;
entry = entry->hnext) {
if ((spa == NULL ||
os_memcmp(entry->spa, spa, ETH_ALEN) == 0) &&
os_memcmp(entry->pmkid, pmkid, PMKID_LEN) == 0)
return entry;
}
} else {
for (entry = pmksa->pmksa; entry; entry = entry->next) {
if (spa == NULL ||
os_memcmp(entry->spa, spa, ETH_ALEN) == 0)
return entry;
}
}
return NULL;
}
/**
* pmksa_cache_get_okc - Fetch a PMKSA cache entry using OKC
* @pmksa: Pointer to PMKSA cache data from pmksa_cache_auth_init()
2009-01-02 21:28:04 +01:00
* @aa: Authenticator address
* @spa: Supplicant address
* @pmkid: PMKID
* Returns: Pointer to PMKSA cache entry or %NULL if no match was found
*
* Use opportunistic key caching (OKC) to find a PMK for a supplicant.
*/
struct rsn_pmksa_cache_entry * pmksa_cache_get_okc(
struct rsn_pmksa_cache *pmksa, const u8 *aa, const u8 *spa,
const u8 *pmkid)
{
struct rsn_pmksa_cache_entry *entry;
u8 new_pmkid[PMKID_LEN];
for (entry = pmksa->pmksa; entry; entry = entry->next) {
if (os_memcmp(entry->spa, spa, ETH_ALEN) != 0)
continue;
if (wpa_key_mgmt_sae(entry->akmp) ||
wpa_key_mgmt_fils(entry->akmp)) {
if (os_memcmp(entry->pmkid, pmkid, PMKID_LEN) == 0)
return entry;
continue;
}
rsn_pmkid(entry->pmk, entry->pmk_len, aa, spa, new_pmkid,
entry->akmp);
if (os_memcmp(new_pmkid, pmkid, PMKID_LEN) == 0)
return entry;
}
return NULL;
}
/**
* pmksa_cache_auth_init - Initialize PMKSA cache
* @free_cb: Callback function to be called when a PMKSA cache entry is freed
* @ctx: Context pointer for free_cb function
* Returns: Pointer to PMKSA cache data or %NULL on failure
*/
struct rsn_pmksa_cache *
pmksa_cache_auth_init(void (*free_cb)(struct rsn_pmksa_cache_entry *entry,
void *ctx), void *ctx)
{
struct rsn_pmksa_cache *pmksa;
pmksa = os_zalloc(sizeof(*pmksa));
if (pmksa) {
pmksa->free_cb = free_cb;
pmksa->ctx = ctx;
}
return pmksa;
}
static int das_attr_match(struct rsn_pmksa_cache_entry *entry,
struct radius_das_attrs *attr)
{
int match = 0;
if (attr->sta_addr) {
if (os_memcmp(attr->sta_addr, entry->spa, ETH_ALEN) != 0)
return 0;
match++;
}
if (attr->acct_multi_session_id) {
char buf[20];
if (attr->acct_multi_session_id_len != 16)
return 0;
os_snprintf(buf, sizeof(buf), "%016llX",
(unsigned long long) entry->acct_multi_session_id);
if (os_memcmp(attr->acct_multi_session_id, buf, 16) != 0)
return 0;
match++;
}
if (attr->cui) {
if (!entry->cui ||
attr->cui_len != wpabuf_len(entry->cui) ||
os_memcmp(attr->cui, wpabuf_head(entry->cui),
attr->cui_len) != 0)
return 0;
match++;
}
if (attr->user_name) {
if (!entry->identity ||
attr->user_name_len != entry->identity_len ||
os_memcmp(attr->user_name, entry->identity,
attr->user_name_len) != 0)
return 0;
match++;
}
return match;
}
int pmksa_cache_auth_radius_das_disconnect(struct rsn_pmksa_cache *pmksa,
struct radius_das_attrs *attr)
{
int found = 0;
struct rsn_pmksa_cache_entry *entry, *prev;
if (attr->acct_session_id)
return -1;
entry = pmksa->pmksa;
while (entry) {
if (das_attr_match(entry, attr)) {
found++;
prev = entry;
entry = entry->next;
pmksa_cache_free_entry(pmksa, prev);
continue;
}
entry = entry->next;
}
return found ? 0 : -1;
}
/**
* pmksa_cache_auth_list - Dump text list of entries in PMKSA cache
* @pmksa: Pointer to PMKSA cache data from pmksa_cache_auth_init()
* @buf: Buffer for the list
* @len: Length of the buffer
* Returns: Number of bytes written to buffer
*
* This function is used to generate a text format representation of the
* current PMKSA cache contents for the ctrl_iface PMKSA command.
*/
int pmksa_cache_auth_list(struct rsn_pmksa_cache *pmksa, char *buf, size_t len)
{
int i, ret;
char *pos = buf;
struct rsn_pmksa_cache_entry *entry;
struct os_reltime now;
os_get_reltime(&now);
ret = os_snprintf(pos, buf + len - pos,
"Index / SPA / PMKID / expiration (in seconds) / opportunistic\n");
if (os_snprintf_error(buf + len - pos, ret))
return pos - buf;
pos += ret;
i = 0;
entry = pmksa->pmksa;
while (entry) {
ret = os_snprintf(pos, buf + len - pos, "%d " MACSTR " ",
i, MAC2STR(entry->spa));
if (os_snprintf_error(buf + len - pos, ret))
return pos - buf;
pos += ret;
pos += wpa_snprintf_hex(pos, buf + len - pos, entry->pmkid,
PMKID_LEN);
ret = os_snprintf(pos, buf + len - pos, " %d %d\n",
(int) (entry->expiration - now.sec),
entry->opportunistic);
if (os_snprintf_error(buf + len - pos, ret))
return pos - buf;
pos += ret;
entry = entry->next;
}
return pos - buf;
}
#ifdef CONFIG_PMKSA_CACHE_EXTERNAL
#ifdef CONFIG_MESH
/**
* pmksa_cache_auth_list_mesh - Dump text list of entries in PMKSA cache
* @pmksa: Pointer to PMKSA cache data from pmksa_cache_auth_init()
* @addr: MAC address of the peer (NULL means any)
* @buf: Buffer for the list
* @len: Length of the buffer
* Returns: Number of bytes written to buffer
*
* This function is used to generate a text format representation of the
* current PMKSA cache contents for the ctrl_iface PMKSA_GET command to store
* in external storage.
*/
int pmksa_cache_auth_list_mesh(struct rsn_pmksa_cache *pmksa, const u8 *addr,
char *buf, size_t len)
{
int ret;
char *pos, *end;
struct rsn_pmksa_cache_entry *entry;
struct os_reltime now;
pos = buf;
end = buf + len;
os_get_reltime(&now);
/*
* Entry format:
* <BSSID> <PMKID> <PMK> <expiration in seconds>
*/
for (entry = pmksa->pmksa; entry; entry = entry->next) {
if (addr && os_memcmp(entry->spa, addr, ETH_ALEN) != 0)
continue;
ret = os_snprintf(pos, end - pos, MACSTR " ",
MAC2STR(entry->spa));
if (os_snprintf_error(end - pos, ret))
return 0;
pos += ret;
pos += wpa_snprintf_hex(pos, end - pos, entry->pmkid,
PMKID_LEN);
ret = os_snprintf(pos, end - pos, " ");
if (os_snprintf_error(end - pos, ret))
return 0;
pos += ret;
pos += wpa_snprintf_hex(pos, end - pos, entry->pmk,
entry->pmk_len);
ret = os_snprintf(pos, end - pos, " %d\n",
(int) (entry->expiration - now.sec));
if (os_snprintf_error(end - pos, ret))
return 0;
pos += ret;
}
return pos - buf;
}
#endif /* CONFIG_MESH */
#endif /* CONFIG_PMKSA_CACHE_EXTERNAL */