hostapd/wpa_supplicant/robust_av.c

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/*
* wpa_supplicant - Robust AV procedures
* Copyright (c) 2020, The Linux Foundation
*
* 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 "common/wpa_ctrl.h"
#include "common/ieee802_11_common.h"
#include "wpa_supplicant_i.h"
#include "driver_i.h"
#include "bss.h"
#define SCS_RESP_TIMEOUT 1
#define DSCP_REQ_TIMEOUT 5
void wpas_populate_mscs_descriptor_ie(struct robust_av_data *robust_av,
struct wpabuf *buf)
{
u8 *len, *len1;
/* MSCS descriptor element */
wpabuf_put_u8(buf, WLAN_EID_EXTENSION);
len = wpabuf_put(buf, 1);
wpabuf_put_u8(buf, WLAN_EID_EXT_MSCS_DESCRIPTOR);
wpabuf_put_u8(buf, robust_av->request_type);
wpabuf_put_u8(buf, robust_av->up_bitmap);
wpabuf_put_u8(buf, robust_av->up_limit);
wpabuf_put_le32(buf, robust_av->stream_timeout);
if (robust_av->request_type != SCS_REQ_REMOVE) {
/* TCLAS mask element */
wpabuf_put_u8(buf, WLAN_EID_EXTENSION);
len1 = wpabuf_put(buf, 1);
wpabuf_put_u8(buf, WLAN_EID_EXT_TCLAS_MASK);
/* Frame classifier */
wpabuf_put_data(buf, robust_av->frame_classifier,
robust_av->frame_classifier_len);
*len1 = (u8 *) wpabuf_put(buf, 0) - len1 - 1;
}
*len = (u8 *) wpabuf_put(buf, 0) - len - 1;
}
static int wpas_populate_type4_classifier(struct type4_params *type4_param,
struct wpabuf *buf)
{
/* classifier parameters */
wpabuf_put_u8(buf, type4_param->classifier_mask);
if (type4_param->ip_version == IPV4) {
wpabuf_put_u8(buf, IPV4); /* IP version */
wpabuf_put_data(buf, &type4_param->ip_params.v4.src_ip.s_addr,
4);
wpabuf_put_data(buf, &type4_param->ip_params.v4.dst_ip.s_addr,
4);
wpabuf_put_be16(buf, type4_param->ip_params.v4.src_port);
wpabuf_put_be16(buf, type4_param->ip_params.v4.dst_port);
wpabuf_put_u8(buf, type4_param->ip_params.v4.dscp);
wpabuf_put_u8(buf, type4_param->ip_params.v4.protocol);
wpabuf_put_u8(buf, 0); /* Reserved octet */
} else {
wpabuf_put_u8(buf, IPV6);
wpabuf_put_data(buf, &type4_param->ip_params.v6.src_ip.s6_addr,
16);
wpabuf_put_data(buf, &type4_param->ip_params.v6.dst_ip.s6_addr,
16);
wpabuf_put_be16(buf, type4_param->ip_params.v6.src_port);
wpabuf_put_be16(buf, type4_param->ip_params.v6.dst_port);
wpabuf_put_u8(buf, type4_param->ip_params.v6.dscp);
wpabuf_put_u8(buf, type4_param->ip_params.v6.next_header);
wpabuf_put_data(buf, type4_param->ip_params.v6.flow_label, 3);
}
return 0;
}
static int wpas_populate_type10_classifier(struct type10_params *type10_param,
struct wpabuf *buf)
{
/* classifier parameters */
wpabuf_put_u8(buf, type10_param->prot_instance);
wpabuf_put_u8(buf, type10_param->prot_number);
wpabuf_put_data(buf, type10_param->filter_value,
type10_param->filter_len);
wpabuf_put_data(buf, type10_param->filter_mask,
type10_param->filter_len);
return 0;
}
static bool tclas_elem_required(const struct qos_characteristics *qos_elem)
{
if (!qos_elem || !qos_elem->available)
return true;
if (qos_elem->direction == SCS_DIRECTION_DOWN)
return true;
return false;
}
static int wpas_populate_scs_descriptor_ie(struct scs_desc_elem *desc_elem,
struct wpabuf *buf,
bool allow_scs_traffic_desc)
{
u8 *len, *len1;
struct tclas_element *tclas_elem;
unsigned int i;
struct qos_characteristics *qos_elem;
u32 control_info = 0;
/* SCS Descriptor element */
wpabuf_put_u8(buf, WLAN_EID_SCS_DESCRIPTOR);
len = wpabuf_put(buf, 1);
wpabuf_put_u8(buf, desc_elem->scs_id);
wpabuf_put_u8(buf, desc_elem->request_type);
if (desc_elem->request_type == SCS_REQ_REMOVE)
goto end;
if (!tclas_elem_required(&desc_elem->qos_char_elem))
goto skip_tclas_elem;
if (desc_elem->intra_access_priority || desc_elem->scs_up_avail) {
wpabuf_put_u8(buf, WLAN_EID_INTRA_ACCESS_CATEGORY_PRIORITY);
wpabuf_put_u8(buf, 1);
wpabuf_put_u8(buf, desc_elem->intra_access_priority);
}
tclas_elem = desc_elem->tclas_elems;
if (!tclas_elem)
return -1;
for (i = 0; i < desc_elem->num_tclas_elem; i++, tclas_elem++) {
int ret;
/* TCLAS element */
wpabuf_put_u8(buf, WLAN_EID_TCLAS);
len1 = wpabuf_put(buf, 1);
wpabuf_put_u8(buf, 255); /* User Priority: not compared */
/* Frame Classifier */
wpabuf_put_u8(buf, tclas_elem->classifier_type);
/* Frame classifier parameters */
switch (tclas_elem->classifier_type) {
case 4:
ret = wpas_populate_type4_classifier(
&tclas_elem->frame_classifier.type4_param,
buf);
break;
case 10:
ret = wpas_populate_type10_classifier(
&tclas_elem->frame_classifier.type10_param,
buf);
break;
default:
return -1;
}
if (ret == -1) {
wpa_printf(MSG_ERROR,
"Failed to populate frame classifier");
return -1;
}
*len1 = (u8 *) wpabuf_put(buf, 0) - len1 - 1;
}
if (desc_elem->num_tclas_elem > 1) {
/* TCLAS Processing element */
wpabuf_put_u8(buf, WLAN_EID_TCLAS_PROCESSING);
wpabuf_put_u8(buf, 1);
wpabuf_put_u8(buf, desc_elem->tclas_processing);
}
skip_tclas_elem:
if (allow_scs_traffic_desc && desc_elem->qos_char_elem.available) {
qos_elem = &desc_elem->qos_char_elem;
/* Element ID, Length, and Element ID Extension */
wpabuf_put_u8(buf, WLAN_EID_EXTENSION);
len1 = wpabuf_put(buf, 1);
wpabuf_put_u8(buf, WLAN_EID_EXT_QOS_CHARACTERISTICS);
/* IEEE P802.11be/D4.0, 9.4.2.316 QoS Characteristics element,
* Figure 9-1001av (Control Info field format)
*/
control_info = ((u32) qos_elem->direction <<
EHT_QOS_CONTROL_INFO_DIRECTION_OFFSET);
control_info |= ((u32) desc_elem->intra_access_priority <<
EHT_QOS_CONTROL_INFO_TID_OFFSET);
control_info |= ((u32) desc_elem->intra_access_priority <<
EHT_QOS_CONTROL_INFO_USER_PRIORITY_OFFSET);
control_info |= ((u32) qos_elem->mask <<
EHT_QOS_CONTROL_INFO_PRESENCE_MASK_OFFSET);
/* Control Info */
wpabuf_put_le32(buf, control_info);
/* Minimum Service Interval */
wpabuf_put_le32(buf, qos_elem->min_si);
/* Maximum Service Interval */
wpabuf_put_le32(buf, qos_elem->max_si);
/* Minimum Data Rate */
wpabuf_put_le24(buf, qos_elem->min_data_rate);
/* Delay Bound */
wpabuf_put_le24(buf, qos_elem->delay_bound);
*len1 = (u8 *) wpabuf_put(buf, 0) - len1 - 1;
}
end:
*len = (u8 *) wpabuf_put(buf, 0) - len - 1;
return 0;
}
int wpas_send_mscs_req(struct wpa_supplicant *wpa_s)
{
struct wpabuf *buf;
size_t buf_len;
int ret;
if (wpa_s->wpa_state != WPA_COMPLETED || !wpa_s->current_ssid)
return 0;
if (!wpa_bss_ext_capab(wpa_s->current_bss, WLAN_EXT_CAPAB_MSCS)) {
wpa_dbg(wpa_s, MSG_INFO,
"AP does not support MSCS - could not send MSCS Req");
return -1;
}
if (!wpa_s->mscs_setup_done &&
wpa_s->robust_av.request_type != SCS_REQ_ADD) {
wpa_msg(wpa_s, MSG_INFO,
"MSCS: Failed to send MSCS Request: request type invalid");
return -1;
}
buf_len = 3 + /* Action frame header */
3 + /* MSCS descriptor IE header */
1 + /* Request type */
2 + /* User priority control */
4 + /* Stream timeout */
3 + /* TCLAS Mask IE header */
wpa_s->robust_av.frame_classifier_len;
buf = wpabuf_alloc(buf_len);
if (!buf) {
wpa_printf(MSG_ERROR, "Failed to allocate MSCS req");
return -1;
}
wpabuf_put_u8(buf, WLAN_ACTION_ROBUST_AV_STREAMING);
wpabuf_put_u8(buf, ROBUST_AV_MSCS_REQ);
wpa_s->robust_av.dialog_token++;
wpabuf_put_u8(buf, wpa_s->robust_av.dialog_token);
/* MSCS descriptor element */
wpas_populate_mscs_descriptor_ie(&wpa_s->robust_av, buf);
wpa_hexdump_buf(MSG_MSGDUMP, "MSCS Request", buf);
ret = wpa_drv_send_action(wpa_s, wpa_s->assoc_freq, 0, wpa_s->bssid,
wpa_s->own_addr, wpa_s->bssid,
wpabuf_head(buf), wpabuf_len(buf), 0);
if (ret < 0)
wpa_dbg(wpa_s, MSG_INFO, "MSCS: Failed to send MSCS Request");
wpabuf_free(buf);
return ret;
}
static size_t tclas_elem_len(const struct tclas_element *elem)
{
size_t buf_len = 0;
buf_len += 2 + /* TCLAS element header */
1 + /* User Priority */
1 ; /* Classifier Type */
if (elem->classifier_type == 4) {
enum ip_version ip_ver;
buf_len += 1 + /* Classifier mask */
1 + /* IP version */
1 + /* user priority */
2 + /* src_port */
2 + /* dst_port */
1 ; /* dscp */
ip_ver = elem->frame_classifier.type4_param.ip_version;
if (ip_ver == IPV4) {
buf_len += 4 + /* src_ip */
4 + /* dst_ip */
1 + /* protocol */
1 ; /* Reserved */
} else if (ip_ver == IPV6) {
buf_len += 16 + /* src_ip */
16 + /* dst_ip */
1 + /* next_header */
3 ; /* flow_label */
} else {
wpa_printf(MSG_ERROR, "%s: Incorrect IP version %d",
__func__, ip_ver);
return 0;
}
} else if (elem->classifier_type == 10) {
buf_len += 1 + /* protocol instance */
1 + /* protocol number */
2 * elem->frame_classifier.type10_param.filter_len;
} else {
wpa_printf(MSG_ERROR, "%s: Incorrect classifier type %u",
__func__, elem->classifier_type);
return 0;
}
return buf_len;
}
static size_t qos_char_len(const struct qos_characteristics *qos_elem)
{
size_t buf_len = 0;
buf_len += 1 + /* Element ID */
1 + /* Length */
1 + /* Element ID Extension */
4 + /* Control Info */
4 + /* Minimum Service Interval */
4 + /* Maximum Service Interval */
3 + /* Minimum Data Rate */
3; /* Delay Bound */
return buf_len;
}
static struct wpabuf * allocate_scs_buf(struct scs_desc_elem *desc_elem,
unsigned int num_scs_desc,
bool allow_scs_traffic_desc)
{
struct wpabuf *buf;
size_t buf_len = 0;
unsigned int i, j;
buf_len = 3; /* Action frame header */
for (i = 0; i < num_scs_desc; i++, desc_elem++) {
struct tclas_element *tclas_elem;
buf_len += 2 + /* SCS descriptor IE header */
1 + /* SCSID */
1 ; /* Request type */
if (desc_elem->request_type == SCS_REQ_REMOVE)
continue;
if (allow_scs_traffic_desc &&
desc_elem->qos_char_elem.available)
buf_len += qos_char_len(&desc_elem->qos_char_elem);
if (!tclas_elem_required(&desc_elem->qos_char_elem))
continue;
if (desc_elem->intra_access_priority || desc_elem->scs_up_avail)
buf_len += 3;
tclas_elem = desc_elem->tclas_elems;
if (!tclas_elem) {
wpa_printf(MSG_ERROR, "%s: TCLAS element null",
__func__);
return NULL;
}
for (j = 0; j < desc_elem->num_tclas_elem; j++, tclas_elem++) {
size_t elen;
elen = tclas_elem_len(tclas_elem);
if (elen == 0)
return NULL;
buf_len += elen;
}
if (desc_elem->num_tclas_elem > 1) {
buf_len += 1 + /* TCLAS Processing eid */
1 + /* length */
1 ; /* processing */
}
}
buf = wpabuf_alloc(buf_len);
if (!buf) {
wpa_printf(MSG_ERROR, "Failed to allocate SCS req");
return NULL;
}
return buf;
}
static void scs_request_timer(void *eloop_ctx, void *timeout_ctx)
{
struct wpa_supplicant *wpa_s = eloop_ctx;
struct active_scs_elem *scs_desc, *prev;
if (wpa_s->wpa_state != WPA_COMPLETED || !wpa_s->current_ssid)
return;
/* Once timeout is over, remove all SCS descriptors with no response */
dl_list_for_each_safe(scs_desc, prev, &wpa_s->active_scs_ids,
struct active_scs_elem, list) {
u8 bssid[ETH_ALEN] = { 0 };
const u8 *src;
if (scs_desc->status == SCS_DESC_SUCCESS)
continue;
if (wpa_s->current_bss)
src = wpa_s->current_bss->bssid;
else
src = bssid;
wpa_msg(wpa_s, MSG_INFO, WPA_EVENT_SCS_RESULT "bssid=" MACSTR
" SCSID=%u status_code=timedout", MAC2STR(src),
scs_desc->scs_id);
dl_list_del(&scs_desc->list);
wpa_printf(MSG_INFO, "%s: SCSID %d removed after timeout",
__func__, scs_desc->scs_id);
os_free(scs_desc);
}
eloop_cancel_timeout(scs_request_timer, wpa_s, NULL);
wpa_s->ongoing_scs_req = false;
}
int wpas_send_scs_req(struct wpa_supplicant *wpa_s)
{
struct wpabuf *buf = NULL;
struct scs_desc_elem *desc_elem = NULL;
const struct ieee80211_eht_capabilities *eht;
const u8 *eht_ie;
int ret = -1;
unsigned int i;
bool allow_scs_traffic_desc = false;
if (wpa_s->wpa_state != WPA_COMPLETED || !wpa_s->current_ssid)
return -1;
if (!wpa_bss_ext_capab(wpa_s->current_bss, WLAN_EXT_CAPAB_SCS)) {
wpa_dbg(wpa_s, MSG_INFO,
"AP does not support SCS - could not send SCS Request");
return -1;
}
desc_elem = wpa_s->scs_robust_av_req.scs_desc_elems;
if (!desc_elem)
return -1;
if (wpa_is_non_eht_scs_traffic_desc_supported(wpa_s->current_bss))
allow_scs_traffic_desc = true;
/* Allow SCS Traffic descriptor support for EHT connection */
eht_ie = wpa_bss_get_ie_ext(wpa_s->current_bss,
WLAN_EID_EXT_EHT_CAPABILITIES);
if (wpa_s->connection_eht && eht_ie &&
eht_ie[1] >= 1 + IEEE80211_EHT_CAPAB_MIN_LEN) {
eht = (const struct ieee80211_eht_capabilities *) &eht_ie[3];
if (eht->mac_cap & EHT_MACCAP_SCS_TRAFFIC_DESC)
allow_scs_traffic_desc = true;
}
if (!allow_scs_traffic_desc && desc_elem->qos_char_elem.available) {
wpa_dbg(wpa_s, MSG_INFO,
"Connection does not support EHT/non-EHT SCS Traffic Description - could not send SCS Request with QoS Characteristics");
return -1;
}
buf = allocate_scs_buf(desc_elem,
wpa_s->scs_robust_av_req.num_scs_desc,
allow_scs_traffic_desc);
if (!buf)
return -1;
wpabuf_put_u8(buf, WLAN_ACTION_ROBUST_AV_STREAMING);
wpabuf_put_u8(buf, ROBUST_AV_SCS_REQ);
wpa_s->scs_dialog_token++;
if (wpa_s->scs_dialog_token == 0)
wpa_s->scs_dialog_token++;
wpabuf_put_u8(buf, wpa_s->scs_dialog_token);
for (i = 0; i < wpa_s->scs_robust_av_req.num_scs_desc;
i++, desc_elem++) {
/* SCS Descriptor element */
if (wpas_populate_scs_descriptor_ie(desc_elem, buf,
allow_scs_traffic_desc) < 0)
goto end;
}
wpa_hexdump_buf(MSG_DEBUG, "SCS Request", buf);
ret = wpa_drv_send_action(wpa_s, wpa_s->assoc_freq, 0, wpa_s->bssid,
wpa_s->own_addr, wpa_s->bssid,
wpabuf_head(buf), wpabuf_len(buf), 0);
if (ret < 0) {
wpa_dbg(wpa_s, MSG_ERROR, "SCS: Failed to send SCS Request");
wpa_s->scs_dialog_token--;
goto end;
}
desc_elem = wpa_s->scs_robust_av_req.scs_desc_elems;
for (i = 0; i < wpa_s->scs_robust_av_req.num_scs_desc;
i++, desc_elem++) {
struct active_scs_elem *active_scs_elem;
if (desc_elem->request_type != SCS_REQ_ADD)
continue;
active_scs_elem = os_malloc(sizeof(struct active_scs_elem));
if (!active_scs_elem)
break;
active_scs_elem->scs_id = desc_elem->scs_id;
active_scs_elem->status = SCS_DESC_SENT;
dl_list_add(&wpa_s->active_scs_ids, &active_scs_elem->list);
}
/*
* Register a timeout after which this request will be removed from
* the cache.
*/
eloop_register_timeout(SCS_RESP_TIMEOUT, 0, scs_request_timer, wpa_s,
NULL);
wpa_s->ongoing_scs_req = true;
end:
wpabuf_free(buf);
free_up_scs_desc(&wpa_s->scs_robust_av_req);
return ret;
}
void free_up_tclas_elem(struct scs_desc_elem *elem)
{
struct tclas_element *tclas_elems = elem->tclas_elems;
unsigned int num_tclas_elem = elem->num_tclas_elem;
struct tclas_element *tclas_data;
unsigned int j;
elem->tclas_elems = NULL;
elem->num_tclas_elem = 0;
if (!tclas_elems)
return;
tclas_data = tclas_elems;
for (j = 0; j < num_tclas_elem; j++, tclas_data++) {
if (tclas_data->classifier_type != 10)
continue;
os_free(tclas_data->frame_classifier.type10_param.filter_value);
os_free(tclas_data->frame_classifier.type10_param.filter_mask);
}
os_free(tclas_elems);
}
void free_up_scs_desc(struct scs_robust_av_data *data)
{
struct scs_desc_elem *desc_elems = data->scs_desc_elems;
unsigned int num_scs_desc = data->num_scs_desc;
struct scs_desc_elem *desc_data;
unsigned int i;
data->scs_desc_elems = NULL;
data->num_scs_desc = 0;
if (!desc_elems)
return;
desc_data = desc_elems;
for (i = 0; i < num_scs_desc; i++, desc_data++) {
if (desc_data->request_type == SCS_REQ_REMOVE ||
!desc_data->tclas_elems)
continue;
free_up_tclas_elem(desc_data);
}
os_free(desc_elems);
}
void wpas_handle_robust_av_recv_action(struct wpa_supplicant *wpa_s,
const u8 *src, const u8 *buf, size_t len)
{
u8 dialog_token;
u16 status_code;
if (len < 3)
return;
dialog_token = *buf++;
if (dialog_token != wpa_s->robust_av.dialog_token) {
wpa_printf(MSG_INFO,
"MSCS: Drop received frame due to dialog token mismatch: received:%u expected:%u",
dialog_token, wpa_s->robust_av.dialog_token);
return;
}
status_code = WPA_GET_LE16(buf);
wpa_msg(wpa_s, MSG_INFO, WPA_EVENT_MSCS_RESULT "bssid=" MACSTR
" status_code=%u", MAC2STR(src), status_code);
wpa_s->mscs_setup_done = status_code == WLAN_STATUS_SUCCESS;
}
void wpas_handle_assoc_resp_mscs(struct wpa_supplicant *wpa_s, const u8 *bssid,
const u8 *ies, size_t ies_len)
{
const u8 *mscs_desc_ie, *mscs_status;
u16 status;
/* Process optional MSCS Status subelement when MSCS IE is in
* (Re)Association Response frame */
if (!ies || ies_len == 0 || !wpa_s->robust_av.valid_config)
return;
mscs_desc_ie = get_ie_ext(ies, ies_len, WLAN_EID_EXT_MSCS_DESCRIPTOR);
if (!mscs_desc_ie || mscs_desc_ie[1] <= 8)
return;
/* Subelements start after (ie_id(1) + ie_len(1) + ext_id(1) +
* request type(1) + upc(2) + stream timeout(4) =) 10.
*/
mscs_status = get_ie(&mscs_desc_ie[10], mscs_desc_ie[1] - 8,
MCSC_SUBELEM_STATUS);
if (!mscs_status || mscs_status[1] < 2)
return;
status = WPA_GET_LE16(mscs_status + 2);
wpa_msg(wpa_s, MSG_INFO, WPA_EVENT_MSCS_RESULT "bssid=" MACSTR
" status_code=%u", MAC2STR(bssid), status);
wpa_s->mscs_setup_done = status == WLAN_STATUS_SUCCESS;
}
static void wpas_wait_for_dscp_req_timer(void *eloop_ctx, void *timeout_ctx)
{
struct wpa_supplicant *wpa_s = eloop_ctx;
/* Once timeout is over, reset wait flag and allow sending DSCP query */
wpa_printf(MSG_DEBUG,
"QM: Wait time over for sending DSCP request - allow DSCP query");
wpa_s->wait_for_dscp_req = 0;
wpa_msg(wpa_s, MSG_INFO, WPA_EVENT_DSCP_POLICY "request_wait end");
}
void wpas_handle_assoc_resp_qos_mgmt(struct wpa_supplicant *wpa_s,
const u8 *ies, size_t ies_len)
{
const u8 *wfa_capa;
wpa_s->connection_dscp = 0;
if (wpa_s->wait_for_dscp_req)
eloop_cancel_timeout(wpas_wait_for_dscp_req_timer, wpa_s, NULL);
if (!ies || ies_len == 0 || !wpa_s->enable_dscp_policy_capa)
return;
wfa_capa = get_vendor_ie(ies, ies_len, WFA_CAPA_IE_VENDOR_TYPE);
if (!wfa_capa || wfa_capa[1] < 6 || wfa_capa[6] < 1 ||
!(wfa_capa[7] & WFA_CAPA_QM_DSCP_POLICY))
return; /* AP does not enable QM DSCP Policy */
wpa_s->connection_dscp = 1;
wpa_s->wait_for_dscp_req = !!(wfa_capa[7] &
WFA_CAPA_QM_UNSOLIC_DSCP);
if (!wpa_s->wait_for_dscp_req)
return;
/* Register a timeout after which dscp query can be sent to AP. */
wpa_msg(wpa_s, MSG_INFO, WPA_EVENT_DSCP_POLICY "request_wait start");
eloop_register_timeout(DSCP_REQ_TIMEOUT, 0,
wpas_wait_for_dscp_req_timer, wpa_s, NULL);
}
void wpas_handle_robust_av_scs_recv_action(struct wpa_supplicant *wpa_s,
const u8 *src, const u8 *buf,
size_t len)
{
u8 dialog_token;
unsigned int i, count;
struct active_scs_elem *scs_desc, *prev;
if (len < 2)
return;
if (!wpa_s->ongoing_scs_req) {
wpa_printf(MSG_INFO,
"SCS: Drop received response due to no ongoing request");
return;
}
dialog_token = *buf++;
len--;
if (dialog_token != wpa_s->scs_dialog_token) {
wpa_printf(MSG_INFO,
"SCS: Drop received frame due to dialog token mismatch: received:%u expected:%u",
dialog_token, wpa_s->scs_dialog_token);
return;
}
/* This Count field does not exist in the IEEE Std 802.11-2020
* definition of the SCS Response frame. However, it was accepted to
* be added into REVme per REVme/D0.0 CC35 CID 49 (edits in document
* 11-21-0688-07). */
count = *buf++;
len--;
if (count == 0 || count * 3 > len) {
wpa_printf(MSG_INFO,
"SCS: Drop received frame due to invalid count: %u (remaining %zu octets)",
count, len);
return;
}
for (i = 0; i < count; i++) {
u8 id;
u16 status;
bool scs_desc_found = false;
id = *buf++;
status = WPA_GET_LE16(buf);
buf += 2;
len -= 3;
dl_list_for_each(scs_desc, &wpa_s->active_scs_ids,
struct active_scs_elem, list) {
if (id == scs_desc->scs_id) {
scs_desc_found = true;
break;
}
}
if (!scs_desc_found) {
wpa_printf(MSG_INFO, "SCS: SCS ID invalid %u", id);
continue;
}
if (status != WLAN_STATUS_SUCCESS) {
dl_list_del(&scs_desc->list);
os_free(scs_desc);
} else if (status == WLAN_STATUS_SUCCESS) {
scs_desc->status = SCS_DESC_SUCCESS;
}
wpa_msg(wpa_s, MSG_INFO, WPA_EVENT_SCS_RESULT "bssid=" MACSTR
" SCSID=%u status_code=%u", MAC2STR(src), id, status);
}
eloop_cancel_timeout(scs_request_timer, wpa_s, NULL);
wpa_s->ongoing_scs_req = false;
dl_list_for_each_safe(scs_desc, prev, &wpa_s->active_scs_ids,
struct active_scs_elem, list) {
if (scs_desc->status != SCS_DESC_SUCCESS) {
wpa_msg(wpa_s, MSG_INFO,
WPA_EVENT_SCS_RESULT "bssid=" MACSTR
" SCSID=%u status_code=response_not_received",
MAC2STR(src), scs_desc->scs_id);
dl_list_del(&scs_desc->list);
os_free(scs_desc);
}
}
}
static void wpas_clear_active_scs_ids(struct wpa_supplicant *wpa_s)
{
struct active_scs_elem *scs_elem;
while ((scs_elem = dl_list_first(&wpa_s->active_scs_ids,
struct active_scs_elem, list))) {
dl_list_del(&scs_elem->list);
os_free(scs_elem);
}
}
void wpas_scs_deinit(struct wpa_supplicant *wpa_s)
{
free_up_scs_desc(&wpa_s->scs_robust_av_req);
wpa_s->scs_dialog_token = 0;
wpas_clear_active_scs_ids(wpa_s);
eloop_cancel_timeout(scs_request_timer, wpa_s, NULL);
wpa_s->ongoing_scs_req = false;
}
static int write_ipv4_info(char *pos, int total_len,
const struct ipv4_params *v4,
u8 classifier_mask)
{
int res, rem_len;
char addr[INET_ADDRSTRLEN];
rem_len = total_len;
if (classifier_mask & BIT(1)) {
if (!inet_ntop(AF_INET, &v4->src_ip, addr, INET_ADDRSTRLEN)) {
wpa_printf(MSG_ERROR,
"QM: Failed to set IPv4 source address");
return -1;
}
res = os_snprintf(pos, rem_len, " src_ip=%s", addr);
if (os_snprintf_error(rem_len, res))
return -1;
pos += res;
rem_len -= res;
}
if (classifier_mask & BIT(2)) {
if (!inet_ntop(AF_INET, &v4->dst_ip, addr, INET_ADDRSTRLEN)) {
wpa_printf(MSG_ERROR,
"QM: Failed to set IPv4 destination address");
return -1;
}
res = os_snprintf(pos, rem_len, " dst_ip=%s", addr);
if (os_snprintf_error(rem_len, res))
return -1;
pos += res;
rem_len -= res;
}
if (classifier_mask & BIT(3)) {
res = os_snprintf(pos, rem_len, " src_port=%d", v4->src_port);
if (os_snprintf_error(rem_len, res))
return -1;
pos += res;
rem_len -= res;
}
if (classifier_mask & BIT(4)) {
res = os_snprintf(pos, rem_len, " dst_port=%d", v4->dst_port);
if (os_snprintf_error(rem_len, res))
return -1;
pos += res;
rem_len -= res;
}
if (classifier_mask & BIT(6)) {
res = os_snprintf(pos, rem_len, " protocol=%d", v4->protocol);
if (os_snprintf_error(rem_len, res))
return -1;
pos += res;
rem_len -= res;
}
return total_len - rem_len;
}
static int write_ipv6_info(char *pos, int total_len,
const struct ipv6_params *v6,
u8 classifier_mask)
{
int res, rem_len;
char addr[INET6_ADDRSTRLEN];
rem_len = total_len;
if (classifier_mask & BIT(1)) {
if (!inet_ntop(AF_INET6, &v6->src_ip, addr, INET6_ADDRSTRLEN)) {
wpa_printf(MSG_ERROR,
"QM: Failed to set IPv6 source addr");
return -1;
}
res = os_snprintf(pos, rem_len, " src_ip=%s", addr);
if (os_snprintf_error(rem_len, res))
return -1;
pos += res;
rem_len -= res;
}
if (classifier_mask & BIT(2)) {
if (!inet_ntop(AF_INET6, &v6->dst_ip, addr, INET6_ADDRSTRLEN)) {
wpa_printf(MSG_ERROR,
"QM: Failed to set IPv6 destination addr");
return -1;
}
res = os_snprintf(pos, rem_len, " dst_ip=%s", addr);
if (os_snprintf_error(rem_len, res))
return -1;
pos += res;
rem_len -= res;
}
if (classifier_mask & BIT(3)) {
res = os_snprintf(pos, rem_len, " src_port=%d", v6->src_port);
if (os_snprintf_error(rem_len, res))
return -1;
pos += res;
rem_len -= res;
}
if (classifier_mask & BIT(4)) {
res = os_snprintf(pos, rem_len, " dst_port=%d", v6->dst_port);
if (os_snprintf_error(rem_len, res))
return -1;
pos += res;
rem_len -= res;
}
if (classifier_mask & BIT(6)) {
res = os_snprintf(pos, rem_len, " protocol=%d",
v6->next_header);
if (os_snprintf_error(rem_len, res))
return -1;
pos += res;
rem_len -= res;
}
return total_len - rem_len;
}
struct dscp_policy_data {
u8 policy_id;
u8 req_type;
u8 dscp;
bool dscp_info;
const u8 *frame_classifier;
u8 frame_classifier_len;
struct type4_params type4_param;
const u8 *domain_name;
u8 domain_name_len;
u16 start_port;
u16 end_port;
bool port_range_info;
};
static int set_frame_classifier_type4_ipv4(struct dscp_policy_data *policy)
{
u8 classifier_mask;
const u8 *frame_classifier = policy->frame_classifier;
struct type4_params *type4_param = &policy->type4_param;
if (policy->frame_classifier_len < 18) {
wpa_printf(MSG_ERROR,
"QM: Received IPv4 frame classifier with insufficient length %d",
policy->frame_classifier_len);
return -1;
}
classifier_mask = frame_classifier[1];
/* Classifier Mask - bit 1 = Source IP Address */
if (classifier_mask & BIT(1)) {
type4_param->classifier_mask |= BIT(1);
os_memcpy(&type4_param->ip_params.v4.src_ip,
&frame_classifier[3], 4);
}
/* Classifier Mask - bit 2 = Destination IP Address */
if (classifier_mask & BIT(2)) {
if (policy->domain_name) {
wpa_printf(MSG_ERROR,
"QM: IPv4: Both domain name and destination IP address not expected");
return -1;
}
type4_param->classifier_mask |= BIT(2);
os_memcpy(&type4_param->ip_params.v4.dst_ip,
&frame_classifier[7], 4);
}
/* Classifier Mask - bit 3 = Source Port */
if (classifier_mask & BIT(3)) {
type4_param->classifier_mask |= BIT(3);
type4_param->ip_params.v4.src_port =
WPA_GET_BE16(&frame_classifier[11]);
}
/* Classifier Mask - bit 4 = Destination Port */
if (classifier_mask & BIT(4)) {
if (policy->port_range_info) {
wpa_printf(MSG_ERROR,
"QM: IPv4: Both port range and destination port not expected");
return -1;
}
type4_param->classifier_mask |= BIT(4);
type4_param->ip_params.v4.dst_port =
WPA_GET_BE16(&frame_classifier[13]);
}
/* Classifier Mask - bit 5 = DSCP (ignored) */
/* Classifier Mask - bit 6 = Protocol */
if (classifier_mask & BIT(6)) {
type4_param->classifier_mask |= BIT(6);
type4_param->ip_params.v4.protocol = frame_classifier[16];
}
return 0;
}
static int set_frame_classifier_type4_ipv6(struct dscp_policy_data *policy)
{
u8 classifier_mask;
const u8 *frame_classifier = policy->frame_classifier;
struct type4_params *type4_param = &policy->type4_param;
if (policy->frame_classifier_len < 44) {
wpa_printf(MSG_ERROR,
"QM: Received IPv6 frame classifier with insufficient length %d",
policy->frame_classifier_len);
return -1;
}
classifier_mask = frame_classifier[1];
/* Classifier Mask - bit 1 = Source IP Address */
if (classifier_mask & BIT(1)) {
type4_param->classifier_mask |= BIT(1);
os_memcpy(&type4_param->ip_params.v6.src_ip,
&frame_classifier[3], 16);
}
/* Classifier Mask - bit 2 = Destination IP Address */
if (classifier_mask & BIT(2)) {
if (policy->domain_name) {
wpa_printf(MSG_ERROR,
"QM: IPv6: Both domain name and destination IP address not expected");
return -1;
}
type4_param->classifier_mask |= BIT(2);
os_memcpy(&type4_param->ip_params.v6.dst_ip,
&frame_classifier[19], 16);
}
/* Classifier Mask - bit 3 = Source Port */
if (classifier_mask & BIT(3)) {
type4_param->classifier_mask |= BIT(3);
type4_param->ip_params.v6.src_port =
WPA_GET_BE16(&frame_classifier[35]);
}
/* Classifier Mask - bit 4 = Destination Port */
if (classifier_mask & BIT(4)) {
if (policy->port_range_info) {
wpa_printf(MSG_ERROR,
"IPv6: Both port range and destination port not expected");
return -1;
}
type4_param->classifier_mask |= BIT(4);
type4_param->ip_params.v6.dst_port =
WPA_GET_BE16(&frame_classifier[37]);
}
/* Classifier Mask - bit 5 = DSCP (ignored) */
/* Classifier Mask - bit 6 = Next Header */
if (classifier_mask & BIT(6)) {
type4_param->classifier_mask |= BIT(6);
type4_param->ip_params.v6.next_header = frame_classifier[40];
}
return 0;
}
static int wpas_set_frame_classifier_params(struct dscp_policy_data *policy)
{
const u8 *frame_classifier = policy->frame_classifier;
u8 frame_classifier_len = policy->frame_classifier_len;
if (frame_classifier_len < 3) {
wpa_printf(MSG_ERROR,
"QM: Received frame classifier with insufficient length %d",
frame_classifier_len);
return -1;
}
/* Only allowed Classifier Type: IP and higher layer parameters (4) */
if (frame_classifier[0] != 4) {
wpa_printf(MSG_ERROR,
"QM: Received frame classifier with invalid classifier type %d",
frame_classifier[0]);
return -1;
}
/* Classifier Mask - bit 0 = Version */
if (!(frame_classifier[1] & BIT(0))) {
wpa_printf(MSG_ERROR,
"QM: Received frame classifier without IP version");
return -1;
}
/* Version (4 or 6) */
if (frame_classifier[2] == 4) {
if (set_frame_classifier_type4_ipv4(policy)) {
wpa_printf(MSG_ERROR,
"QM: Failed to set IPv4 parameters");
return -1;
}
policy->type4_param.ip_version = IPV4;
} else if (frame_classifier[2] == 6) {
if (set_frame_classifier_type4_ipv6(policy)) {
wpa_printf(MSG_ERROR,
"QM: Failed to set IPv6 parameters");
return -1;
}
policy->type4_param.ip_version = IPV6;
} else {
wpa_printf(MSG_ERROR,
"QM: Received unknown IP version %d",
frame_classifier[2]);
return -1;
}
return 0;
}
static bool dscp_valid_domain_name(const char *str)
{
if (!str[0])
return false;
while (*str) {
if (is_ctrl_char(*str) || *str == ' ' || *str == '=')
return false;
str++;
}
return true;
}
static void wpas_add_dscp_policy(struct wpa_supplicant *wpa_s,
struct dscp_policy_data *policy)
{
int ip_ver = 0, res;
char policy_str[1000], *pos;
int len;
if (!policy->frame_classifier && !policy->domain_name &&
!policy->port_range_info) {
wpa_printf(MSG_ERROR,
"QM: Invalid DSCP policy - no attributes present");
goto fail;
}
policy_str[0] = '\0';
pos = policy_str;
len = sizeof(policy_str);
if (policy->frame_classifier) {
struct type4_params *type4 = &policy->type4_param;
if (wpas_set_frame_classifier_params(policy)) {
wpa_printf(MSG_ERROR,
"QM: Failed to set frame classifier parameters");
goto fail;
}
if (type4->ip_version == IPV4)
res = write_ipv4_info(pos, len, &type4->ip_params.v4,
type4->classifier_mask);
else
res = write_ipv6_info(pos, len, &type4->ip_params.v6,
type4->classifier_mask);
if (res <= 0) {
wpa_printf(MSG_ERROR,
"QM: Failed to write IP parameters");
goto fail;
}
ip_ver = type4->ip_version;
pos += res;
len -= res;
}
if (policy->port_range_info) {
res = os_snprintf(pos, len, " start_port=%u end_port=%u",
policy->start_port, policy->end_port);
if (os_snprintf_error(len, res)) {
wpa_printf(MSG_ERROR,
"QM: Failed to write port range attributes for policy id = %d",
policy->policy_id);
goto fail;
}
pos += res;
len -= res;
}
if (policy->domain_name) {
char domain_name_str[250];
if (policy->domain_name_len >= sizeof(domain_name_str)) {
wpa_printf(MSG_ERROR,
"QM: Domain name length higher than max expected");
goto fail;
}
os_memcpy(domain_name_str, policy->domain_name,
policy->domain_name_len);
domain_name_str[policy->domain_name_len] = '\0';
if (!dscp_valid_domain_name(domain_name_str)) {
wpa_printf(MSG_ERROR, "QM: Invalid domain name string");
goto fail;
}
res = os_snprintf(pos, len, " domain_name=%s", domain_name_str);
if (os_snprintf_error(len, res)) {
wpa_printf(MSG_ERROR,
"QM: Failed to write domain name attribute for policy id = %d",
policy->policy_id);
goto fail;
}
}
wpa_msg(wpa_s, MSG_INFO, WPA_EVENT_DSCP_POLICY
"add policy_id=%u dscp=%u ip_version=%d%s",
policy->policy_id, policy->dscp, ip_ver, policy_str);
return;
fail:
wpa_msg(wpa_s, MSG_INFO, WPA_EVENT_DSCP_POLICY "reject policy_id=%u",
policy->policy_id);
}
void wpas_dscp_deinit(struct wpa_supplicant *wpa_s)
{
wpa_printf(MSG_DEBUG, "QM: Clear all active DSCP policies");
wpa_msg(wpa_s, MSG_INFO, WPA_EVENT_DSCP_POLICY "clear_all");
wpa_s->dscp_req_dialog_token = 0;
wpa_s->dscp_query_dialog_token = 0;
wpa_s->connection_dscp = 0;
if (wpa_s->wait_for_dscp_req) {
wpa_s->wait_for_dscp_req = 0;
eloop_cancel_timeout(wpas_wait_for_dscp_req_timer, wpa_s, NULL);
}
}
static void wpas_fill_dscp_policy(struct dscp_policy_data *policy, u8 attr_id,
u8 attr_len, const u8 *attr_data)
{
switch (attr_id) {
case QM_ATTR_PORT_RANGE:
if (attr_len < 4) {
wpa_printf(MSG_ERROR,
"QM: Received Port Range attribute with insufficient length %d",
attr_len);
break;
}
policy->start_port = WPA_GET_BE16(attr_data);
policy->end_port = WPA_GET_BE16(attr_data + 2);
policy->port_range_info = true;
break;
case QM_ATTR_DSCP_POLICY:
if (attr_len < 3) {
wpa_printf(MSG_ERROR,
"QM: Received DSCP Policy attribute with insufficient length %d",
attr_len);
return;
}
policy->policy_id = attr_data[0];
policy->req_type = attr_data[1];
policy->dscp = attr_data[2];
policy->dscp_info = true;
break;
case QM_ATTR_TCLAS:
if (attr_len < 1) {
wpa_printf(MSG_ERROR,
"QM: Received TCLAS attribute with insufficient length %d",
attr_len);
return;
}
policy->frame_classifier = attr_data;
policy->frame_classifier_len = attr_len;
break;
case QM_ATTR_DOMAIN_NAME:
if (attr_len < 1) {
wpa_printf(MSG_ERROR,
"QM: Received domain name attribute with insufficient length %d",
attr_len);
return;
}
policy->domain_name = attr_data;
policy->domain_name_len = attr_len;
break;
default:
wpa_printf(MSG_ERROR, "QM: Received invalid QoS attribute %d",
attr_id);
break;
}
}
void wpas_handle_qos_mgmt_recv_action(struct wpa_supplicant *wpa_s,
const u8 *src,
const u8 *buf, size_t len)
{
int rem_len;
const u8 *qos_ie, *attr;
int more, reset;
if (!wpa_s->enable_dscp_policy_capa) {
wpa_printf(MSG_ERROR,
"QM: Ignore DSCP Policy frame since the capability is not enabled");
return;
}
if (!pmf_in_use(wpa_s, src)) {
wpa_printf(MSG_ERROR,
"QM: Ignore DSCP Policy frame since PMF is not in use");
return;
}
if (!wpa_s->connection_dscp) {
wpa_printf(MSG_DEBUG,
"QM: DSCP Policy capability not enabled for the current association - ignore QoS Management Action frames");
return;
}
if (len < 1)
return;
/* Handle only DSCP Policy Request frame */
if (buf[0] != QM_DSCP_POLICY_REQ) {
wpa_printf(MSG_ERROR, "QM: Received unexpected QoS action frame %d",
buf[0]);
return;
}
if (len < 3) {
wpa_printf(MSG_ERROR,
"Received QoS Management DSCP Policy Request frame with invalid length %zu",
len);
return;
}
/* Clear wait_for_dscp_req on receiving first DSCP request from AP */
if (wpa_s->wait_for_dscp_req) {
wpa_s->wait_for_dscp_req = 0;
eloop_cancel_timeout(wpas_wait_for_dscp_req_timer, wpa_s, NULL);
}
wpa_s->dscp_req_dialog_token = buf[1];
more = buf[2] & DSCP_POLICY_CTRL_MORE;
reset = buf[2] & DSCP_POLICY_CTRL_RESET;
wpa_msg(wpa_s, MSG_INFO, WPA_EVENT_DSCP_POLICY "request_start%s%s",
reset ? " clear_all" : "", more ? " more" : "");
qos_ie = buf + 3;
rem_len = len - 3;
while (rem_len > 2) {
struct dscp_policy_data policy;
int rem_attrs_len, ie_len;
ie_len = 2 + qos_ie[1];
if (rem_len < ie_len)
break;
if (rem_len < 6 || qos_ie[0] != WLAN_EID_VENDOR_SPECIFIC ||
qos_ie[1] < 4 ||
WPA_GET_BE32(&qos_ie[2]) != QM_IE_VENDOR_TYPE) {
rem_len -= ie_len;
qos_ie += ie_len;
continue;
}
os_memset(&policy, 0, sizeof(struct dscp_policy_data));
attr = qos_ie + 6;
rem_attrs_len = qos_ie[1] - 4;
while (rem_attrs_len > 2) {
u8 attr_id, attr_len;
attr_id = *attr++;
attr_len = *attr++;
rem_attrs_len -= 2;
if (attr_len > rem_attrs_len)
break;
wpas_fill_dscp_policy(&policy, attr_id, attr_len, attr);
rem_attrs_len -= attr_len;
attr += attr_len;
}
rem_len -= ie_len;
qos_ie += ie_len;
if (!policy.dscp_info) {
wpa_printf(MSG_ERROR,
"QM: Received QoS IE without DSCP Policy attribute");
continue;
}
if (policy.req_type == DSCP_POLICY_REQ_ADD)
wpas_add_dscp_policy(wpa_s, &policy);
else if (policy.req_type == DSCP_POLICY_REQ_REMOVE)
wpa_msg(wpa_s, MSG_INFO, WPA_EVENT_DSCP_POLICY
"remove policy_id=%u", policy.policy_id);
else
wpa_msg(wpa_s, MSG_INFO, WPA_EVENT_DSCP_POLICY
"reject policy_id=%u", policy.policy_id);
}
wpa_msg(wpa_s, MSG_INFO, WPA_EVENT_DSCP_POLICY "request_end");
}
int wpas_send_dscp_response(struct wpa_supplicant *wpa_s,
struct dscp_resp_data *resp_data)
{
struct wpabuf *buf = NULL;
size_t buf_len;
int ret = -1, i;
u8 resp_control = 0;
if (wpa_s->wpa_state != WPA_COMPLETED || !wpa_s->current_ssid) {
wpa_printf(MSG_ERROR,
"QM: Failed to send DSCP response - not connected to AP");
return -1;
}
if (resp_data->solicited && !wpa_s->dscp_req_dialog_token) {
wpa_printf(MSG_ERROR, "QM: No ongoing DSCP request");
return -1;
}
if (!wpa_s->connection_dscp) {
wpa_printf(MSG_ERROR,
"QM: Failed to send DSCP response - DSCP capability not enabled for the current association");
return -1;
}
buf_len = 1 + /* Category */
3 + /* OUI */
1 + /* OUI Type */
1 + /* OUI Subtype */
1 + /* Dialog Token */
1 + /* Response Control */
1 + /* Count */
2 * resp_data->num_policies; /* Status list */
buf = wpabuf_alloc(buf_len);
if (!buf) {
wpa_printf(MSG_ERROR,
"QM: Failed to allocate DSCP policy response");
return -1;
}
wpabuf_put_u8(buf, WLAN_ACTION_VENDOR_SPECIFIC_PROTECTED);
wpabuf_put_be24(buf, OUI_WFA);
wpabuf_put_u8(buf, QM_ACTION_OUI_TYPE);
wpabuf_put_u8(buf, QM_DSCP_POLICY_RESP);
wpabuf_put_u8(buf, resp_data->solicited ?
wpa_s->dscp_req_dialog_token : 0);
if (resp_data->more)
resp_control |= DSCP_POLICY_CTRL_MORE;
if (resp_data->reset)
resp_control |= DSCP_POLICY_CTRL_RESET;
wpabuf_put_u8(buf, resp_control);
wpabuf_put_u8(buf, resp_data->num_policies);
for (i = 0; i < resp_data->num_policies; i++) {
wpabuf_put_u8(buf, resp_data->policy[i].id);
wpabuf_put_u8(buf, resp_data->policy[i].status);
}
wpa_hexdump_buf(MSG_MSGDUMP, "DSCP response frame: ", buf);
ret = wpa_drv_send_action(wpa_s, wpa_s->assoc_freq, 0, wpa_s->bssid,
wpa_s->own_addr, wpa_s->bssid,
wpabuf_head(buf), wpabuf_len(buf), 0);
if (ret < 0) {
wpa_msg(wpa_s, MSG_INFO, "QM: Failed to send DSCP response");
goto fail;
}
/*
* Mark DSCP request complete whether response sent is solicited or
* unsolicited
*/
wpa_s->dscp_req_dialog_token = 0;
fail:
wpabuf_free(buf);
return ret;
}
int wpas_send_dscp_query(struct wpa_supplicant *wpa_s, const char *domain_name,
size_t domain_name_length)
{
struct wpabuf *buf = NULL;
int ret, dscp_query_size;
if (wpa_s->wpa_state != WPA_COMPLETED || !wpa_s->current_ssid)
return -1;
if (!wpa_s->connection_dscp) {
wpa_printf(MSG_ERROR,
"QM: Failed to send DSCP query - DSCP capability not enabled for the current association");
return -1;
}
if (wpa_s->wait_for_dscp_req) {
wpa_printf(MSG_INFO, "QM: Wait until AP sends a DSCP request");
return -1;
}
#define DOMAIN_NAME_OFFSET (4 /* OUI */ + 1 /* Attr Id */ + 1 /* Attr len */)
if (domain_name_length > 255 - DOMAIN_NAME_OFFSET) {
wpa_printf(MSG_ERROR, "QM: Too long domain name");
return -1;
}
dscp_query_size = 1 + /* Category */
4 + /* OUI Type */
1 + /* OUI subtype */
1; /* Dialog Token */
if (domain_name && domain_name_length)
dscp_query_size += 1 + /* Element ID */
1 + /* IE Length */
DOMAIN_NAME_OFFSET + domain_name_length;
buf = wpabuf_alloc(dscp_query_size);
if (!buf) {
wpa_printf(MSG_ERROR, "QM: Failed to allocate DSCP query");
return -1;
}
wpabuf_put_u8(buf, WLAN_ACTION_VENDOR_SPECIFIC_PROTECTED);
wpabuf_put_be32(buf, QM_ACTION_VENDOR_TYPE);
wpabuf_put_u8(buf, QM_DSCP_POLICY_QUERY);
wpa_s->dscp_query_dialog_token++;
if (wpa_s->dscp_query_dialog_token == 0)
wpa_s->dscp_query_dialog_token++;
wpabuf_put_u8(buf, wpa_s->dscp_query_dialog_token);
if (domain_name && domain_name_length) {
/* Domain Name attribute */
wpabuf_put_u8(buf, WLAN_EID_VENDOR_SPECIFIC);
wpabuf_put_u8(buf, DOMAIN_NAME_OFFSET + domain_name_length);
wpabuf_put_be32(buf, QM_IE_VENDOR_TYPE);
wpabuf_put_u8(buf, QM_ATTR_DOMAIN_NAME);
wpabuf_put_u8(buf, domain_name_length);
wpabuf_put_data(buf, domain_name, domain_name_length);
}
#undef DOMAIN_NAME_OFFSET
ret = wpa_drv_send_action(wpa_s, wpa_s->assoc_freq, 0, wpa_s->bssid,
wpa_s->own_addr, wpa_s->bssid,
wpabuf_head(buf), wpabuf_len(buf), 0);
if (ret < 0) {
wpa_dbg(wpa_s, MSG_ERROR, "QM: Failed to send DSCP query");
wpa_s->dscp_query_dialog_token--;
}
wpabuf_free(buf);
return ret;
}