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nest-open-source / manifest_repos / dhd-driver / refs/heads/main / . / bcmdhd.101.10.361.x / wl_cfgnan.c
blob: 16012df02573f782742f59c2d45bdd738fd9eded [file] [log] [blame]
/*
* Neighbor Awareness Networking
*
* Copyright (C) 2020, Broadcom.
*
* Unless you and Broadcom execute a separate written software license
* agreement governing use of this software, this software is licensed to you
* under the terms of the GNU General Public License version 2 (the "GPL"),
* available at http://www.broadcom.com/licenses/GPLv2.php, with the
* following added to such license:
*
* As a special exception, the copyright holders of this software give you
* permission to link this software with independent modules, and to copy and
* distribute the resulting executable under terms of your choice, provided that
* you also meet, for each linked independent module, the terms and conditions of
* the license of that module. An independent module is a module which is not
* derived from this software. The special exception does not apply to any
* modifications of the software.
*
*
* <<Broadcom-WL-IPTag/Dual:>>
*/
#ifdef WL_NAN
#include <bcmutils.h>
#include <bcmendian.h>
#include <bcmwifi_channels.h>
#include <nan.h>
#include <bcmiov.h>
#include <net/rtnetlink.h>
#include <wl_cfg80211.h>
#include <wl_cfgscan.h>
#include <wl_android.h>
#include <wl_cfgnan.h>
#if defined(BCMDONGLEHOST)
#include <dngl_stats.h>
#include <dhd.h>
#endif /* BCMDONGLEHOST */
#include <wl_cfgvendor.h>
#include <bcmbloom.h>
#include <wl_cfgp2p.h>
#include <wl_cfgvif.h>
#ifdef RTT_SUPPORT
#include <dhd_rtt.h>
#endif /* RTT_SUPPORT */
#include <bcmstdlib_s.h>
#define NAN_RANGE_REQ_EVNT 1
#define NAN_RAND_MAC_RETRIES 10
#define NAN_SCAN_DWELL_TIME_DELTA_MS 10
#ifdef WL_NAN_DISC_CACHE
/* Disc Cache Parameters update Flags */
#define NAN_DISC_CACHE_PARAM_SDE_CONTROL 0x0001
static int wl_cfgnan_cache_disc_result(struct bcm_cfg80211 *cfg, void * data,
u16 *disc_cache_update_flags);
static int wl_cfgnan_remove_disc_result(struct bcm_cfg80211 * cfg, uint8 local_subid);
static nan_disc_result_cache * wl_cfgnan_get_disc_result(struct bcm_cfg80211 *cfg,
uint8 remote_pubid, struct ether_addr *peer);
#endif /* WL_NAN_DISC_CACHE */
static int wl_cfgnan_set_if_addr(struct bcm_cfg80211 *cfg);
static int wl_cfgnan_get_capability(struct net_device *ndev,
struct bcm_cfg80211 *cfg, nan_hal_capabilities_t *capabilities);
static void wl_cfgnan_clear_nan_event_data(struct bcm_cfg80211 *cfg,
nan_event_data_t *nan_event_data);
void wl_cfgnan_data_remove_peer(struct bcm_cfg80211 *cfg,
struct ether_addr *peer_addr);
static void wl_cfgnan_send_stop_event(struct bcm_cfg80211 *cfg);
static void wl_cfgnan_disable_cleanup(struct bcm_cfg80211 *cfg);
static s32 wl_cfgnan_get_ndi_idx(struct bcm_cfg80211 *cfg);
static int wl_cfgnan_init(struct bcm_cfg80211 *cfg);
static int wl_cfgnan_deinit(struct bcm_cfg80211 *cfg, uint8 busstate);
static void wl_cfgnan_update_dp_info(struct bcm_cfg80211 *cfg, bool add,
nan_data_path_id ndp_id);
static void wl_cfgnan_data_set_peer_dp_state(struct bcm_cfg80211 *cfg,
struct ether_addr *peer_addr, nan_peer_dp_state_t state);
static nan_ndp_peer_t* wl_cfgnan_data_get_peer(struct bcm_cfg80211 *cfg,
struct ether_addr *peer_addr);
static int wl_cfgnan_disable(struct bcm_cfg80211 *cfg);
static s32 wl_cfgnan_del_ndi_data(struct bcm_cfg80211 *cfg, char *name);
static s32 wl_cfgnan_add_ndi_data(struct bcm_cfg80211 *cfg, s32 idx, char *name);
#ifdef RTT_SUPPORT
static int wl_cfgnan_clear_disc_cache(struct bcm_cfg80211 *cfg, wl_nan_instance_id_t sub_id);
static int32 wl_cfgnan_notify_disc_with_ranging(struct bcm_cfg80211 *cfg,
nan_ranging_inst_t *rng_inst, nan_event_data_t *nan_event_data, uint32 distance);
static void wl_cfgnan_disc_result_on_geofence_cancel(struct bcm_cfg80211 *cfg,
nan_ranging_inst_t *rng_inst);
static void wl_cfgnan_terminate_ranging_session(struct bcm_cfg80211 *cfg,
nan_ranging_inst_t *ranging_inst);
static s32 wl_cfgnan_clear_peer_ranging(struct bcm_cfg80211 * cfg,
nan_ranging_inst_t *rng_inst, int reason);
static s32 wl_cfgnan_handle_dp_ranging_concurrency(struct bcm_cfg80211 *cfg,
struct ether_addr *peer, int reason);
static void wl_cfgnan_terminate_all_obsolete_ranging_sessions(struct bcm_cfg80211 *cfg);
static bool wl_ranging_geofence_session_with_peer(struct bcm_cfg80211 *cfg,
struct ether_addr *peer_addr);
static void wl_cfgnan_reset_remove_ranging_instance(struct bcm_cfg80211 *cfg,
nan_ranging_inst_t *ranging_inst);
static void wl_cfgnan_remove_ranging_instance(struct bcm_cfg80211 *cfg,
nan_ranging_inst_t *ranging_inst);
#endif /* RTT_SUPPORT */
static const char *
nan_role_to_str(u8 role)
{
const char *id2str;
switch (role) {
C2S(WL_NAN_ROLE_AUTO);
break;
C2S(WL_NAN_ROLE_NON_MASTER_NON_SYNC);
break;
C2S(WL_NAN_ROLE_NON_MASTER_SYNC);
break;
C2S(WL_NAN_ROLE_MASTER);
break;
C2S(WL_NAN_ROLE_ANCHOR_MASTER);
break;
default:
id2str = "WL_NAN_ROLE_UNKNOWN";
}
return id2str;
}
const char *
nan_event_to_str(u16 cmd)
{
const char *id2str;
switch (cmd) {
C2S(WL_NAN_EVENT_START);
break;
C2S(WL_NAN_EVENT_JOIN);
break;
C2S(WL_NAN_EVENT_ROLE);
break;
C2S(WL_NAN_EVENT_SCAN_COMPLETE);
break;
C2S(WL_NAN_EVENT_DISCOVERY_RESULT);
break;
C2S(WL_NAN_EVENT_REPLIED);
break;
C2S(WL_NAN_EVENT_TERMINATED);
break;
C2S(WL_NAN_EVENT_RECEIVE);
break;
C2S(WL_NAN_EVENT_STATUS_CHG);
break;
C2S(WL_NAN_EVENT_MERGE);
break;
C2S(WL_NAN_EVENT_STOP);
break;
C2S(WL_NAN_EVENT_P2P);
break;
C2S(WL_NAN_EVENT_WINDOW_BEGIN_P2P);
break;
C2S(WL_NAN_EVENT_WINDOW_BEGIN_MESH);
break;
C2S(WL_NAN_EVENT_WINDOW_BEGIN_IBSS);
break;
C2S(WL_NAN_EVENT_WINDOW_BEGIN_RANGING);
break;
C2S(WL_NAN_EVENT_POST_DISC);
break;
C2S(WL_NAN_EVENT_DATA_IF_ADD);
break;
C2S(WL_NAN_EVENT_DATA_PEER_ADD);
break;
C2S(WL_NAN_EVENT_PEER_DATAPATH_IND);
break;
C2S(WL_NAN_EVENT_DATAPATH_ESTB);
break;
C2S(WL_NAN_EVENT_SDF_RX);
break;
C2S(WL_NAN_EVENT_DATAPATH_END);
break;
C2S(WL_NAN_EVENT_BCN_RX);
break;
C2S(WL_NAN_EVENT_PEER_DATAPATH_RESP);
break;
C2S(WL_NAN_EVENT_PEER_DATAPATH_CONF);
break;
C2S(WL_NAN_EVENT_RNG_REQ_IND);
break;
C2S(WL_NAN_EVENT_RNG_RPT_IND);
break;
C2S(WL_NAN_EVENT_RNG_TERM_IND);
break;
C2S(WL_NAN_EVENT_PEER_DATAPATH_SEC_INST);
break;
C2S(WL_NAN_EVENT_TXS);
break;
C2S(WL_NAN_EVENT_DW_START);
break;
C2S(WL_NAN_EVENT_DW_END);
break;
C2S(WL_NAN_EVENT_CHAN_BOUNDARY);
break;
C2S(WL_NAN_EVENT_MR_CHANGED);
break;
C2S(WL_NAN_EVENT_RNG_RESP_IND);
break;
C2S(WL_NAN_EVENT_PEER_SCHED_UPD_NOTIF);
break;
C2S(WL_NAN_EVENT_PEER_SCHED_REQ);
break;
C2S(WL_NAN_EVENT_PEER_SCHED_RESP);
break;
C2S(WL_NAN_EVENT_PEER_SCHED_CONF);
break;
C2S(WL_NAN_EVENT_SENT_DATAPATH_END);
break;
C2S(WL_NAN_EVENT_SLOT_START);
break;
C2S(WL_NAN_EVENT_SLOT_END);
break;
C2S(WL_NAN_EVENT_HOST_ASSIST_REQ);
break;
C2S(WL_NAN_EVENT_RX_MGMT_FRM);
break;
C2S(WL_NAN_EVENT_DISC_CACHE_TIMEOUT);
break;
C2S(WL_NAN_EVENT_OOB_AF_TXS);
break;
C2S(WL_NAN_EVENT_OOB_AF_RX);
break;
C2S(WL_NAN_EVENT_INVALID);
break;
default:
id2str = "WL_NAN_EVENT_UNKNOWN";
}
return id2str;
}
static const char *
nan_frm_type_to_str(u16 frm_type)
{
const char *id2str;
switch (frm_type) {
C2S(WL_NAN_FRM_TYPE_PUBLISH);
break;
C2S(WL_NAN_FRM_TYPE_SUBSCRIBE);
break;
C2S(WL_NAN_FRM_TYPE_FOLLOWUP);
break;
C2S(WL_NAN_FRM_TYPE_DP_REQ);
break;
C2S(WL_NAN_FRM_TYPE_DP_RESP);
break;
C2S(WL_NAN_FRM_TYPE_DP_CONF);
break;
C2S(WL_NAN_FRM_TYPE_DP_INSTALL);
break;
C2S(WL_NAN_FRM_TYPE_DP_END);
break;
C2S(WL_NAN_FRM_TYPE_SCHED_REQ);
break;
C2S(WL_NAN_FRM_TYPE_SCHED_RESP);
break;
C2S(WL_NAN_FRM_TYPE_SCHED_CONF);
break;
C2S(WL_NAN_FRM_TYPE_SCHED_UPD);
break;
C2S(WL_NAN_FRM_TYPE_RNG_REQ);
break;
C2S(WL_NAN_FRM_TYPE_RNG_RESP);
break;
C2S(WL_NAN_FRM_TYPE_RNG_TERM);
break;
C2S(WL_NAN_FRM_TYPE_RNG_REPORT);
break;
default:
id2str = "WL_NAN_FRM_TYPE_UNKNOWN";
}
return id2str;
}
static const char *
nan_event_cause_to_str(u8 cause)
{
const char *id2str;
switch (cause) {
C2S(WL_NAN_DP_TERM_WITH_INACTIVITY);
break;
C2S(WL_NAN_DP_TERM_WITH_FSM_DESTROY);
break;
C2S(WL_NAN_DP_TERM_WITH_PEER_DP_END);
break;
C2S(WL_NAN_DP_TERM_WITH_STALE_NDP);
break;
C2S(WL_NAN_DP_TERM_WITH_DISABLE);
break;
C2S(WL_NAN_DP_TERM_WITH_NDI_DEL);
break;
C2S(WL_NAN_DP_TERM_WITH_PEER_HB_FAIL);
break;
C2S(WL_NAN_DP_TERM_WITH_HOST_IOVAR);
break;
C2S(WL_NAN_DP_TERM_WITH_ESTB_FAIL);
break;
C2S(WL_NAN_DP_TERM_WITH_SCHED_REJECT);
break;
default:
id2str = "WL_NAN_EVENT_CAUSE_UNKNOWN";
}
return id2str;
}
static int wl_cfgnan_execute_ioctl(struct net_device *ndev,
struct bcm_cfg80211 *cfg, bcm_iov_batch_buf_t *nan_buf,
uint16 nan_buf_size, uint32 *status, uint8 *resp_buf,
uint16 resp_buf_len);
int
wl_cfgnan_generate_inst_id(struct bcm_cfg80211 *cfg, uint8 *p_inst_id)
{
s32 ret = BCME_OK;
uint8 i = 0;
wl_nancfg_t *nancfg = cfg->nancfg;
if (p_inst_id == NULL) {
WL_ERR(("Invalid arguments\n"));
ret = -EINVAL;
goto exit;
}
if (nancfg->inst_id_start == NAN_ID_MAX) {
WL_ERR(("Consumed all IDs, resetting the counter\n"));
nancfg->inst_id_start = 0;
}
for (i = nancfg->inst_id_start; i < NAN_ID_MAX; i++) {
if (isclr(nancfg->svc_inst_id_mask, i)) {
setbit(nancfg->svc_inst_id_mask, i);
*p_inst_id = i + 1;
nancfg->inst_id_start = *p_inst_id;
WL_DBG(("Instance ID=%d\n", *p_inst_id));
goto exit;
}
}
WL_ERR(("Allocated maximum IDs\n"));
ret = BCME_NORESOURCE;
exit:
return ret;
}
int
wl_cfgnan_remove_inst_id(struct bcm_cfg80211 *cfg, uint8 inst_id)
{
s32 ret = BCME_OK;
WL_DBG(("%s: Removing svc instance id %d\n", __FUNCTION__, inst_id));
clrbit(cfg->nancfg->svc_inst_id_mask, inst_id-1);
return ret;
}
s32 wl_cfgnan_parse_sdea_data(osl_t *osh, const uint8 *p_attr,
uint16 len, nan_event_data_t *tlv_data)
{
const wifi_nan_svc_desc_ext_attr_t *nan_svc_desc_ext_attr = NULL;
uint8 offset;
s32 ret = BCME_OK;
/* service descriptor ext attributes */
nan_svc_desc_ext_attr = (const wifi_nan_svc_desc_ext_attr_t *)p_attr;
/* attribute ID */
WL_TRACE(("> attr id: 0x%02x\n", nan_svc_desc_ext_attr->id));
/* attribute length */
WL_TRACE(("> attr len: 0x%x\n", nan_svc_desc_ext_attr->len));
if (nan_svc_desc_ext_attr->instance_id == tlv_data->pub_id) {
tlv_data->sde_control_flag = nan_svc_desc_ext_attr->control;
}
offset = sizeof(*nan_svc_desc_ext_attr);
if (offset > len) {
WL_ERR(("Invalid event buffer len\n"));
ret = BCME_BUFTOOSHORT;
goto fail;
}
p_attr += offset;
len -= offset;
if (tlv_data->sde_control_flag & NAN_SC_RANGE_LIMITED) {
WL_TRACE(("> svc_control: range limited present\n"));
}
if (tlv_data->sde_control_flag & NAN_SDE_CF_SVC_UPD_IND_PRESENT) {
WL_TRACE(("> svc_control: sdea svc specific info present\n"));
tlv_data->sde_svc_info.dlen = (p_attr[1] | (p_attr[2] << 8));
WL_TRACE(("> sdea svc info len: 0x%02x\n", tlv_data->sde_svc_info.dlen));
if (!tlv_data->sde_svc_info.dlen ||
tlv_data->sde_svc_info.dlen > NAN_MAX_SERVICE_SPECIFIC_INFO_LEN) {
/* must be able to handle null msg which is not error */
tlv_data->sde_svc_info.dlen = 0;
WL_ERR(("sde data length is invalid\n"));
ret = BCME_BADLEN;
goto fail;
}
if (tlv_data->sde_svc_info.dlen > 0) {
tlv_data->sde_svc_info.data = MALLOCZ(osh, tlv_data->sde_svc_info.dlen);
if (!tlv_data->sde_svc_info.data) {
WL_ERR(("%s: memory allocation failed\n", __FUNCTION__));
tlv_data->sde_svc_info.dlen = 0;
ret = BCME_NOMEM;
goto fail;
}
/* advance read pointer, consider sizeof of Service Update Indicator */
offset = sizeof(tlv_data->sde_svc_info.dlen) - 1;
if (offset > len) {
WL_ERR(("Invalid event buffer len\n"));
ret = BCME_BUFTOOSHORT;
goto fail;
}
p_attr += offset;
len -= offset;
ret = memcpy_s(tlv_data->sde_svc_info.data, tlv_data->sde_svc_info.dlen,
p_attr, tlv_data->sde_svc_info.dlen);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy sde_svc_info\n"));
goto fail;
}
} else {
/* must be able to handle null msg which is not error */
tlv_data->sde_svc_info.dlen = 0;
WL_DBG(("%s: sdea svc info length is zero, null info data\n",
__FUNCTION__));
}
}
return ret;
fail:
if (tlv_data->sde_svc_info.data) {
MFREE(osh, tlv_data->sde_svc_info.data,
tlv_data->sde_svc_info.dlen);
tlv_data->sde_svc_info.data = NULL;
}
WL_DBG(("Parse SDEA event data, status = %d\n", ret));
return ret;
}
/*
* This attribute contains some mandatory fields and some optional fields
* depending on the content of the service discovery request.
*/
s32
wl_cfgnan_parse_sda_data(osl_t *osh, const uint8 *p_attr,
uint16 len, nan_event_data_t *tlv_data)
{
uint8 svc_control = 0, offset = 0;
s32 ret = BCME_OK;
const wifi_nan_svc_descriptor_attr_t *nan_svc_desc_attr = NULL;
/* service descriptor attributes */
nan_svc_desc_attr = (const wifi_nan_svc_descriptor_attr_t *)p_attr;
/* attribute ID */
WL_TRACE(("> attr id: 0x%02x\n", nan_svc_desc_attr->id));
/* attribute length */
WL_TRACE(("> attr len: 0x%x\n", nan_svc_desc_attr->len));
/* service ID */
ret = memcpy_s(tlv_data->svc_name, sizeof(tlv_data->svc_name),
nan_svc_desc_attr->svc_hash, NAN_SVC_HASH_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy svc_hash_name:\n"));
return ret;
}
WL_TRACE(("> svc_hash_name: " MACDBG "\n", MAC2STRDBG(tlv_data->svc_name)));
/* local instance ID */
tlv_data->local_inst_id = nan_svc_desc_attr->instance_id;
WL_TRACE(("> local instance id: 0x%02x\n", tlv_data->local_inst_id));
/* requestor instance ID */
tlv_data->requestor_id = nan_svc_desc_attr->requestor_id;
WL_TRACE(("> requestor id: 0x%02x\n", tlv_data->requestor_id));
/* service control */
svc_control = nan_svc_desc_attr->svc_control;
if ((svc_control & NAN_SVC_CONTROL_TYPE_MASK) == NAN_SC_PUBLISH) {
WL_TRACE(("> Service control type: NAN_SC_PUBLISH\n"));
} else if ((svc_control & NAN_SVC_CONTROL_TYPE_MASK) == NAN_SC_SUBSCRIBE) {
WL_TRACE(("> Service control type: NAN_SC_SUBSCRIBE\n"));
} else if ((svc_control & NAN_SVC_CONTROL_TYPE_MASK) == NAN_SC_FOLLOWUP) {
WL_TRACE(("> Service control type: NAN_SC_FOLLOWUP\n"));
}
offset = sizeof(*nan_svc_desc_attr);
if (offset > len) {
WL_ERR(("Invalid event buffer len\n"));
ret = BCME_BUFTOOSHORT;
goto fail;
}
p_attr += offset;
len -= offset;
/*
* optional fields:
* must be in order following by service descriptor attribute format
*/
/* binding bitmap */
if (svc_control & NAN_SC_BINDING_BITMAP_PRESENT) {
uint16 bitmap = 0;
WL_TRACE(("> svc_control: binding bitmap present\n"));
/* Copy binding bitmap */
ret = memcpy_s(&bitmap, sizeof(bitmap),
p_attr, NAN_BINDING_BITMAP_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy bit map\n"));
return ret;
}
WL_TRACE(("> sc binding bitmap: 0x%04x\n", bitmap));
if (NAN_BINDING_BITMAP_LEN > len) {
WL_ERR(("Invalid event buffer len\n"));
ret = BCME_BUFTOOSHORT;
goto fail;
}
p_attr += NAN_BINDING_BITMAP_LEN;
len -= NAN_BINDING_BITMAP_LEN;
}
/* matching filter */
if (svc_control & NAN_SC_MATCHING_FILTER_PRESENT) {
WL_TRACE(("> svc_control: matching filter present\n"));
tlv_data->tx_match_filter.dlen = *p_attr++;
WL_TRACE(("> matching filter len: 0x%02x\n",
tlv_data->tx_match_filter.dlen));
if (!tlv_data->tx_match_filter.dlen ||
tlv_data->tx_match_filter.dlen > MAX_MATCH_FILTER_LEN) {
tlv_data->tx_match_filter.dlen = 0;
WL_ERR(("tx match filter length is invalid\n"));
ret = -EINVAL;
goto fail;
}
tlv_data->tx_match_filter.data =
MALLOCZ(osh, tlv_data->tx_match_filter.dlen);
if (!tlv_data->tx_match_filter.data) {
WL_ERR(("%s: memory allocation failed\n", __FUNCTION__));
tlv_data->tx_match_filter.dlen = 0;
ret = -ENOMEM;
goto fail;
}
ret = memcpy_s(tlv_data->tx_match_filter.data, tlv_data->tx_match_filter.dlen,
p_attr, tlv_data->tx_match_filter.dlen);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy tx match filter data\n"));
goto fail;
}
/* advance read pointer */
offset = tlv_data->tx_match_filter.dlen;
if (offset > len) {
WL_ERR(("Invalid event buffer\n"));
ret = BCME_BUFTOOSHORT;
goto fail;
}
p_attr += offset;
len -= offset;
}
/* service response filter */
if (svc_control & NAN_SC_SR_FILTER_PRESENT) {
WL_TRACE(("> svc_control: service response filter present\n"));
tlv_data->rx_match_filter.dlen = *p_attr++;
WL_TRACE(("> sr match filter len: 0x%02x\n",
tlv_data->rx_match_filter.dlen));
if (!tlv_data->rx_match_filter.dlen ||
tlv_data->rx_match_filter.dlen > MAX_MATCH_FILTER_LEN) {
tlv_data->rx_match_filter.dlen = 0;
WL_ERR(("%s: sr matching filter length is invalid\n",
__FUNCTION__));
ret = BCME_BADLEN;
goto fail;
}
tlv_data->rx_match_filter.data =
MALLOCZ(osh, tlv_data->rx_match_filter.dlen);
if (!tlv_data->rx_match_filter.data) {
WL_ERR(("%s: memory allocation failed\n", __FUNCTION__));
tlv_data->rx_match_filter.dlen = 0;
ret = BCME_NOMEM;
goto fail;
}
ret = memcpy_s(tlv_data->rx_match_filter.data, tlv_data->rx_match_filter.dlen,
p_attr, tlv_data->rx_match_filter.dlen);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy rx match filter data\n"));
goto fail;
}
/* advance read pointer */
offset = tlv_data->rx_match_filter.dlen;
if (offset > len) {
WL_ERR(("Invalid event buffer len\n"));
ret = BCME_BUFTOOSHORT;
goto fail;
}
p_attr += offset;
len -= offset;
}
/* service specific info */
if (svc_control & NAN_SC_SVC_INFO_PRESENT) {
WL_TRACE(("> svc_control: svc specific info present\n"));
tlv_data->svc_info.dlen = *p_attr++;
WL_TRACE(("> svc info len: 0x%02x\n", tlv_data->svc_info.dlen));
if (!tlv_data->svc_info.dlen ||
tlv_data->svc_info.dlen > NAN_MAX_SERVICE_SPECIFIC_INFO_LEN) {
/* must be able to handle null msg which is not error */
tlv_data->svc_info.dlen = 0;
WL_ERR(("sde data length is invalid\n"));
ret = BCME_BADLEN;
goto fail;
}
if (tlv_data->svc_info.dlen > 0) {
tlv_data->svc_info.data =
MALLOCZ(osh, tlv_data->svc_info.dlen);
if (!tlv_data->svc_info.data) {
WL_ERR(("%s: memory allocation failed\n", __FUNCTION__));
tlv_data->svc_info.dlen = 0;
ret = BCME_NOMEM;
goto fail;
}
ret = memcpy_s(tlv_data->svc_info.data, tlv_data->svc_info.dlen,
p_attr, tlv_data->svc_info.dlen);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy svc info\n"));
goto fail;
}
/* advance read pointer */
offset = tlv_data->svc_info.dlen;
if (offset > len) {
WL_ERR(("Invalid event buffer len\n"));
ret = BCME_BUFTOOSHORT;
goto fail;
}
p_attr += offset;
len -= offset;
} else {
/* must be able to handle null msg which is not error */
tlv_data->svc_info.dlen = 0;
WL_TRACE(("%s: svc info length is zero, null info data\n",
__FUNCTION__));
}
}
/*
* discovery range limited:
* If set to 1, the pub/sub msg is limited in range to close proximity.
* If set to 0, the pub/sub msg is not limited in range.
* Valid only when the message is either of a publish or a sub.
*/
if (svc_control & NAN_SC_RANGE_LIMITED) {
if (((svc_control & NAN_SVC_CONTROL_TYPE_MASK) == NAN_SC_PUBLISH) ||
((svc_control & NAN_SVC_CONTROL_TYPE_MASK) == NAN_SC_SUBSCRIBE)) {
WL_TRACE(("> svc_control: range limited present\n"));
} else {
WL_TRACE(("range limited is only valid on pub or sub\n"));
}
/* TODO: send up */
/* advance read pointer */
p_attr++;
}
return ret;
fail:
if (tlv_data->tx_match_filter.data) {
MFREE(osh, tlv_data->tx_match_filter.data,
tlv_data->tx_match_filter.dlen);
tlv_data->tx_match_filter.data = NULL;
}
if (tlv_data->rx_match_filter.data) {
MFREE(osh, tlv_data->rx_match_filter.data,
tlv_data->rx_match_filter.dlen);
tlv_data->rx_match_filter.data = NULL;
}
if (tlv_data->svc_info.data) {
MFREE(osh, tlv_data->svc_info.data,
tlv_data->svc_info.dlen);
tlv_data->svc_info.data = NULL;
}
WL_DBG(("Parse SDA event data, status = %d\n", ret));
return ret;
}
static s32
wl_cfgnan_parse_sd_attr_data(osl_t *osh, uint16 len, const uint8 *data,
nan_event_data_t *tlv_data, uint16 type) {
const uint8 *p_attr = data;
uint16 offset = 0;
s32 ret = BCME_OK;
const wl_nan_event_disc_result_t *ev_disc = NULL;
const wl_nan_event_replied_t *ev_replied = NULL;
const wl_nan_ev_receive_t *ev_fup = NULL;
/*
* Mapping wifi_nan_svc_descriptor_attr_t, and svc controls are optional.
*/
if (type == WL_NAN_XTLV_SD_DISC_RESULTS) {
u8 iter;
ev_disc = (const wl_nan_event_disc_result_t *)p_attr;
WL_DBG((">> WL_NAN_XTLV_RESULTS: Discovery result\n"));
tlv_data->pub_id = (wl_nan_instance_id_t)ev_disc->pub_id;
tlv_data->sub_id = (wl_nan_instance_id_t)ev_disc->sub_id;
tlv_data->publish_rssi = ev_disc->publish_rssi;
ret = memcpy_s(&tlv_data->remote_nmi, ETHER_ADDR_LEN,
&ev_disc->pub_mac, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy remote nmi\n"));
goto fail;
}
WL_TRACE(("publish id: %d\n", ev_disc->pub_id));
WL_TRACE(("subscribe d: %d\n", ev_disc->sub_id));
WL_TRACE(("publish mac addr: " MACDBG "\n",
MAC2STRDBG(ev_disc->pub_mac.octet)));
WL_TRACE(("publish rssi: %d\n", (int8)ev_disc->publish_rssi));
WL_TRACE(("attribute no: %d\n", ev_disc->attr_num));
WL_TRACE(("attribute len: %d\n", (uint16)ev_disc->attr_list_len));
/* advance to the service descricptor */
offset = OFFSETOF(wl_nan_event_disc_result_t, attr_list[0]);
if (offset > len) {
WL_ERR(("Invalid event buffer len\n"));
ret = BCME_BUFTOOSHORT;
goto fail;
}
p_attr += offset;
len -= offset;
iter = ev_disc->attr_num;
while (iter) {
if ((uint8)*p_attr == NAN_ATTR_SVC_DESCRIPTOR) {
WL_TRACE(("> attr id: 0x%02x\n", (uint8)*p_attr));
ret = wl_cfgnan_parse_sda_data(osh, p_attr, len, tlv_data);
if (unlikely(ret)) {
WL_ERR(("wl_cfgnan_parse_sda_data failed,"
"error = %d \n", ret));
goto fail;
}
}
if ((uint8)*p_attr == NAN_ATTR_SVC_DESC_EXTENSION) {
WL_TRACE(("> attr id: 0x%02x\n", (uint8)*p_attr));
ret = wl_cfgnan_parse_sdea_data(osh, p_attr, len, tlv_data);
if (unlikely(ret)) {
WL_ERR(("wl_cfgnan_parse_sdea_data failed,"
"error = %d \n", ret));
goto fail;
}
}
offset = (sizeof(*p_attr) +
sizeof(ev_disc->attr_list_len) +
(p_attr[1] | (p_attr[2] << 8)));
if (offset > len) {
WL_ERR(("Invalid event buffer len\n"));
ret = BCME_BUFTOOSHORT;
goto fail;
}
p_attr += offset;
len -= offset;
iter--;
}
} else if (type == WL_NAN_XTLV_SD_FUP_RECEIVED) {
uint8 iter;
ev_fup = (const wl_nan_ev_receive_t *)p_attr;
WL_TRACE((">> WL_NAN_XTLV_SD_FUP_RECEIVED: Transmit follow-up\n"));
tlv_data->local_inst_id = (wl_nan_instance_id_t)ev_fup->local_id;
tlv_data->requestor_id = (wl_nan_instance_id_t)ev_fup->remote_id;
tlv_data->fup_rssi = ev_fup->fup_rssi;
ret = memcpy_s(&tlv_data->remote_nmi, ETHER_ADDR_LEN,
&ev_fup->remote_addr, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy remote nmi\n"));
goto fail;
}
WL_TRACE(("local id: %d\n", ev_fup->local_id));
WL_TRACE(("remote id: %d\n", ev_fup->remote_id));
WL_TRACE(("peer mac addr: " MACDBG "\n",
MAC2STRDBG(ev_fup->remote_addr.octet)));
WL_TRACE(("peer rssi: %d\n", (int8)ev_fup->fup_rssi));
WL_TRACE(("attribute no: %d\n", ev_fup->attr_num));
WL_TRACE(("attribute len: %d\n", ev_fup->attr_list_len));
/* advance to the service descriptor which is attr_list[0] */
offset = OFFSETOF(wl_nan_ev_receive_t, attr_list[0]);
if (offset > len) {
WL_ERR(("Invalid event buffer len\n"));
ret = BCME_BUFTOOSHORT;
goto fail;
}
p_attr += offset;
len -= offset;
iter = ev_fup->attr_num;
while (iter) {
if ((uint8)*p_attr == NAN_ATTR_SVC_DESCRIPTOR) {
WL_TRACE(("> attr id: 0x%02x\n", (uint8)*p_attr));
ret = wl_cfgnan_parse_sda_data(osh, p_attr, len, tlv_data);
if (unlikely(ret)) {
WL_ERR(("wl_cfgnan_parse_sda_data failed,"
"error = %d \n", ret));
goto fail;
}
}
if ((uint8)*p_attr == NAN_ATTR_SVC_DESC_EXTENSION) {
WL_TRACE(("> attr id: 0x%02x\n", (uint8)*p_attr));
ret = wl_cfgnan_parse_sdea_data(osh, p_attr, len, tlv_data);
if (unlikely(ret)) {
WL_ERR(("wl_cfgnan_parse_sdea_data failed,"
"error = %d \n", ret));
goto fail;
}
}
offset = (sizeof(*p_attr) +
sizeof(ev_fup->attr_list_len) +
(p_attr[1] | (p_attr[2] << 8)));
if (offset > len) {
WL_ERR(("Invalid event buffer len\n"));
ret = BCME_BUFTOOSHORT;
goto fail;
}
p_attr += offset;
len -= offset;
iter--;
}
} else if (type == WL_NAN_XTLV_SD_SDF_RX) {
/*
* SDF followed by nan2_pub_act_frame_t and wifi_nan_svc_descriptor_attr_t,
* and svc controls are optional.
*/
const nan2_pub_act_frame_t *nan_pub_af =
(const nan2_pub_act_frame_t *)p_attr;
WL_TRACE((">> WL_NAN_XTLV_SD_SDF_RX\n"));
/* nan2_pub_act_frame_t */
WL_TRACE(("pub category: 0x%02x\n", nan_pub_af->category_id));
WL_TRACE(("pub action: 0x%02x\n", nan_pub_af->action_field));
WL_TRACE(("nan oui: %2x-%2x-%2x\n",
nan_pub_af->oui[0], nan_pub_af->oui[1], nan_pub_af->oui[2]));
WL_TRACE(("oui type: 0x%02x\n", nan_pub_af->oui_type));
WL_TRACE(("oui subtype: 0x%02x\n", nan_pub_af->oui_sub_type));
offset = sizeof(*nan_pub_af);
if (offset > len) {
WL_ERR(("Invalid event buffer len\n"));
ret = BCME_BUFTOOSHORT;
goto fail;
}
p_attr += offset;
len -= offset;
} else if (type == WL_NAN_XTLV_SD_REPLIED) {
ev_replied = (const wl_nan_event_replied_t *)p_attr;
WL_TRACE((">> WL_NAN_XTLV_SD_REPLIED: Replied Event\n"));
tlv_data->pub_id = (wl_nan_instance_id_t)ev_replied->pub_id;
tlv_data->sub_id = (wl_nan_instance_id_t)ev_replied->sub_id;
tlv_data->sub_rssi = ev_replied->sub_rssi;
ret = memcpy_s(&tlv_data->remote_nmi, ETHER_ADDR_LEN,
&ev_replied->sub_mac, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy remote nmi\n"));
goto fail;
}
WL_TRACE(("publish id: %d\n", ev_replied->pub_id));
WL_TRACE(("subscribe d: %d\n", ev_replied->sub_id));
WL_TRACE(("Subscriber mac addr: " MACDBG "\n",
MAC2STRDBG(ev_replied->sub_mac.octet)));
WL_TRACE(("subscribe rssi: %d\n", (int8)ev_replied->sub_rssi));
WL_TRACE(("attribute no: %d\n", ev_replied->attr_num));
WL_TRACE(("attribute len: %d\n", (uint16)ev_replied->attr_list_len));
/* advance to the service descriptor which is attr_list[0] */
offset = OFFSETOF(wl_nan_event_replied_t, attr_list[0]);
if (offset > len) {
WL_ERR(("Invalid event buffer len\n"));
ret = BCME_BUFTOOSHORT;
goto fail;
}
p_attr += offset;
len -= offset;
ret = wl_cfgnan_parse_sda_data(osh, p_attr, len, tlv_data);
if (unlikely(ret)) {
WL_ERR(("wl_cfgnan_parse_sdea_data failed,"
"error = %d \n", ret));
}
}
fail:
return ret;
}
/* Based on each case of tlv type id, fill into tlv data */
static int
wl_cfgnan_set_vars_cbfn(void *ctx, const uint8 *data, uint16 type, uint16 len)
{
nan_parse_event_ctx_t *ctx_tlv_data = ((nan_parse_event_ctx_t *)(ctx));
nan_event_data_t *tlv_data = ((nan_event_data_t *)(ctx_tlv_data->nan_evt_data));
int ret = BCME_OK;
NAN_DBG_ENTER();
if (!data || !len) {
WL_ERR(("data length is invalid\n"));
ret = BCME_ERROR;
goto fail;
}
switch (type) {
/*
* Need to parse service descript attributes including service control,
* when Follow up or Discovery result come
*/
case WL_NAN_XTLV_SD_FUP_RECEIVED:
case WL_NAN_XTLV_SD_DISC_RESULTS: {
ret = wl_cfgnan_parse_sd_attr_data(ctx_tlv_data->cfg->osh,
len, data, tlv_data, type);
break;
}
case WL_NAN_XTLV_SD_NDPE_TLV_LIST:
/* Intentional fall through NDPE TLV list and SVC INFO is sent in same container
* to upper layers
*/
case WL_NAN_XTLV_SD_SVC_INFO: {
tlv_data->svc_info.data =
MALLOCZ(ctx_tlv_data->cfg->osh, len);
if (!tlv_data->svc_info.data) {
WL_ERR(("%s: memory allocation failed\n", __FUNCTION__));
tlv_data->svc_info.dlen = 0;
ret = BCME_NOMEM;
goto fail;
}
tlv_data->svc_info.dlen = len;
ret = memcpy_s(tlv_data->svc_info.data, tlv_data->svc_info.dlen,
data, tlv_data->svc_info.dlen);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy svc info data\n"));
goto fail;
}
break;
}
case WL_NAN_XTLV_SD_NAN_AF:
case WL_NAN_XTLV_DAM_NA_ATTR:
/* No action -intentionally added to avoid prints when these events are rcvd */
break;
default:
WL_ERR(("Not available for tlv type = 0x%x\n", type));
ret = BCME_ERROR;
break;
}
fail:
NAN_DBG_EXIT();
return ret;
}
int
wl_cfg_nan_check_cmd_len(uint16 nan_iov_len, uint16 data_size,
uint16 *subcmd_len)
{
s32 ret = BCME_OK;
if (subcmd_len != NULL) {
*subcmd_len = OFFSETOF(bcm_iov_batch_subcmd_t, data) +
ALIGN_SIZE(data_size, 4);
if (*subcmd_len > nan_iov_len) {
WL_ERR(("%s: Buf short, requested:%d, available:%d\n",
__FUNCTION__, *subcmd_len, nan_iov_len));
ret = BCME_NOMEM;
}
} else {
WL_ERR(("Invalid subcmd_len\n"));
ret = BCME_ERROR;
}
return ret;
}
int
wl_cfgnan_config_eventmask(struct net_device *ndev, struct bcm_cfg80211 *cfg,
uint8 event_ind_flag, bool disable_events)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
uint16 subcmd_len;
uint32 status;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
bcm_iov_batch_subcmd_t *sub_cmd_resp = NULL;
uint8 event_mask[WL_NAN_EVMASK_EXTN_LEN];
wl_nan_evmask_extn_t *evmask;
uint16 evmask_cmd_len;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
NAN_DBG_ENTER();
/* same src and dest len here */
bzero(event_mask, sizeof(event_mask));
evmask_cmd_len = OFFSETOF(wl_nan_evmask_extn_t, evmask) +
sizeof(event_mask);
ret = wl_add_remove_eventmsg(ndev, WLC_E_NAN, true);
if (unlikely(ret)) {
WL_ERR((" nan event enable failed, error = %d \n", ret));
goto fail;
}
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(uint8 *)(&nan_buf->cmds[0]);
ret = wl_cfg_nan_check_cmd_len(nan_buf_size,
evmask_cmd_len, &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
sub_cmd->id = htod16(WL_NAN_CMD_CFG_EVENT_MASK);
sub_cmd->len = sizeof(sub_cmd->u.options) + evmask_cmd_len;
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
evmask = (wl_nan_evmask_extn_t *)sub_cmd->data;
evmask->ver = WL_NAN_EVMASK_EXTN_VER;
evmask->len = WL_NAN_EVMASK_EXTN_LEN;
nan_buf_size -= subcmd_len;
nan_buf->count = 1;
if (disable_events) {
WL_DBG(("Disabling all nan events..except stop event\n"));
setbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_STOP));
} else {
/*
* Android framework event mask configuration.
*/
nan_buf->is_set = false;
memset(resp_buf, 0, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("get nan event mask failed ret %d status %d \n",
ret, status));
goto fail;
}
sub_cmd_resp = &((bcm_iov_batch_buf_t *)(resp_buf))->cmds[0];
evmask = (wl_nan_evmask_extn_t *)sub_cmd_resp->data;
/* check the response buff */
/* same src and dest len here */
(void)memcpy_s(&event_mask, WL_NAN_EVMASK_EXTN_LEN,
(uint8*)&evmask->evmask, WL_NAN_EVMASK_EXTN_LEN);
if (event_ind_flag) {
/* FIXME:BIT0 - Disable disc mac addr change event indication */
if (CHECK_BIT(event_ind_flag, WL_NAN_EVENT_DIC_MAC_ADDR_BIT)) {
WL_DBG(("Need to add disc mac addr change event\n"));
}
/* BIT2 - Disable nan cluster join indication (OTA). */
if (CHECK_BIT(event_ind_flag, WL_NAN_EVENT_JOIN_EVENT)) {
clrbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_MERGE));
}
}
setbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_DISCOVERY_RESULT));
setbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_RECEIVE));
setbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_TERMINATED));
setbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_STOP));
setbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_TXS));
setbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_PEER_DATAPATH_IND));
setbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_DATAPATH_ESTB));
setbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_DATAPATH_END));
setbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_RNG_REQ_IND));
setbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_RNG_TERM_IND));
setbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_DISC_CACHE_TIMEOUT));
/* Disable below events by default */
clrbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_PEER_SCHED_UPD_NOTIF));
clrbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_RNG_RPT_IND));
clrbit(event_mask, NAN_EVENT_MAP(WL_NAN_EVENT_DW_END));
}
nan_buf->is_set = true;
evmask = (wl_nan_evmask_extn_t *)sub_cmd->data;
/* same src and dest len here */
(void)memcpy_s((uint8*)&evmask->evmask, sizeof(event_mask),
&event_mask, sizeof(event_mask));
nan_buf_size = (NAN_IOCTL_BUF_SIZE - nan_buf_size);
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("set nan event mask failed ret %d status %d \n", ret, status));
goto fail;
}
WL_DBG(("set nan event mask successfull\n"));
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_set_nan_avail(struct net_device *ndev,
struct bcm_cfg80211 *cfg, nan_avail_cmd_data *cmd_data, uint8 avail_type)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
uint16 subcmd_len;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
wl_nan_iov_t *nan_iov_data = NULL;
wl_avail_t *avail = NULL;
wl_avail_entry_t *entry; /* used for filling entry structure */
uint8 *p; /* tracking pointer */
uint8 i;
u32 status;
int c;
char ndc_id[ETHER_ADDR_LEN] = { 0x50, 0x6f, 0x9a, 0x01, 0x0, 0x0 };
dhd_pub_t *dhdp = wl_cfg80211_get_dhdp(ndev);
char *a = WL_AVAIL_BIT_MAP;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
NAN_DBG_ENTER();
/* Do not disturb avail if dam is supported */
if (FW_SUPPORTED(dhdp, autodam)) {
WL_DBG(("DAM is supported, avail modification not allowed\n"));
return ret;
}
if (avail_type < WL_AVAIL_LOCAL || avail_type > WL_AVAIL_TYPE_MAX) {
WL_ERR(("Invalid availability type\n"));
ret = BCME_USAGE_ERROR;
goto fail;
}
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data = MALLOCZ(cfg->osh, sizeof(*nan_iov_data));
if (!nan_iov_data) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data->nan_iov_len = NAN_IOCTL_BUF_SIZE;
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_iov_data->nan_iov_buf = (uint8 *)(&nan_buf->cmds[0]);
nan_iov_data->nan_iov_len -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
sizeof(*avail), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
avail = (wl_avail_t *)sub_cmd->data;
/* populate wl_avail_type */
avail->flags = avail_type;
if (avail_type == WL_AVAIL_RANGING) {
ret = memcpy_s(&avail->addr, ETHER_ADDR_LEN,
&cmd_data->peer_nmi, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy peer nmi\n"));
goto fail;
}
}
sub_cmd->len = sizeof(sub_cmd->u.options) + subcmd_len;
sub_cmd->id = htod16(WL_NAN_CMD_CFG_AVAIL);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
nan_buf->is_set = false;
nan_buf->count++;
nan_iov_data->nan_iov_len -= subcmd_len;
nan_buf_size = (NAN_IOCTL_BUF_SIZE - nan_iov_data->nan_iov_len);
WL_TRACE(("Read wl nan avail status\n"));
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret)) {
WL_ERR(("\n Get nan avail failed ret %d, status %d \n", ret, status));
goto fail;
}
if (status == BCME_NOTFOUND) {
nan_buf->count = 0;
nan_iov_data->nan_iov_buf = (uint8 *)(&nan_buf->cmds[0]);
nan_iov_data->nan_iov_len -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
avail = (wl_avail_t *)sub_cmd->data;
p = avail->entry;
/* populate wl_avail fields */
avail->length = OFFSETOF(wl_avail_t, entry);
avail->flags = avail_type;
avail->num_entries = 0;
avail->id = 0;
entry = (wl_avail_entry_t*)p;
entry->flags = WL_AVAIL_ENTRY_COM;
/* set default values for optional parameters */
entry->start_offset = 0;
entry->u.band = 0;
if (cmd_data->avail_period) {
entry->period = cmd_data->avail_period;
} else {
entry->period = WL_AVAIL_PERIOD_1024;
}
if (cmd_data->duration != NAN_BAND_INVALID) {
entry->flags |= (3 << WL_AVAIL_ENTRY_USAGE_SHIFT) |
(cmd_data->duration << WL_AVAIL_ENTRY_BIT_DUR_SHIFT);
} else {
entry->flags |= (3 << WL_AVAIL_ENTRY_USAGE_SHIFT) |
(WL_AVAIL_BIT_DUR_16 << WL_AVAIL_ENTRY_BIT_DUR_SHIFT);
}
entry->bitmap_len = 0;
if (avail_type == WL_AVAIL_LOCAL) {
entry->flags |= 1 << WL_AVAIL_ENTRY_CHAN_SHIFT;
/* Check for 5g support, based on that choose 5g channel */
if (cfg->nancfg->support_5g) {
entry->u.channel_info =
htod32(wf_channel2chspec(WL_AVAIL_CHANNEL_5G,
WL_AVAIL_BANDWIDTH_5G));
} else {
entry->u.channel_info =
htod32(wf_channel2chspec(WL_AVAIL_CHANNEL_2G,
WL_AVAIL_BANDWIDTH_2G));
}
entry->flags = htod16(entry->flags);
}
if (cfg->nancfg->support_5g) {
a = WL_5G_AVAIL_BIT_MAP;
}
/* point to bitmap value for processing */
if (cmd_data->bmap) {
for (c = (WL_NAN_EVENT_CLEAR_BIT-1); c >= 0; c--) {
i = cmd_data->bmap >> c;
if (i & 1) {
setbit(entry->bitmap, (WL_NAN_EVENT_CLEAR_BIT-c-1));
}
}
} else {
for (i = 0; i < strlen(WL_AVAIL_BIT_MAP); i++) {
if (*a == '1') {
setbit(entry->bitmap, i);
}
a++;
}
}
/* account for partially filled most significant byte */
entry->bitmap_len = ((WL_NAN_EVENT_CLEAR_BIT) + NBBY - 1) / NBBY;
if (avail_type == WL_AVAIL_NDC) {
ret = memcpy_s(&avail->addr, ETHER_ADDR_LEN,
ndc_id, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy ndc id\n"));
goto fail;
}
} else if (avail_type == WL_AVAIL_RANGING) {
ret = memcpy_s(&avail->addr, ETHER_ADDR_LEN,
&cmd_data->peer_nmi, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy peer nmi\n"));
goto fail;
}
}
/* account for partially filled most significant byte */
/* update wl_avail and populate wl_avail_entry */
entry->length = OFFSETOF(wl_avail_entry_t, bitmap) + entry->bitmap_len;
avail->num_entries++;
avail->length += entry->length;
/* advance pointer for next entry */
p += entry->length;
/* convert to dongle endianness */
entry->length = htod16(entry->length);
entry->start_offset = htod16(entry->start_offset);
entry->u.channel_info = htod32(entry->u.channel_info);
entry->flags = htod16(entry->flags);
/* update avail_len only if
* there are avail entries
*/
if (avail->num_entries) {
nan_iov_data->nan_iov_len -= avail->length;
avail->length = htod16(avail->length);
avail->flags = htod16(avail->flags);
}
avail->length = htod16(avail->length);
sub_cmd->id = htod16(WL_NAN_CMD_CFG_AVAIL);
sub_cmd->len = sizeof(sub_cmd->u.options) + avail->length;
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
nan_buf->is_set = true;
nan_buf->count++;
/* Reduce the iov_len size by subcmd_len */
nan_iov_data->nan_iov_len -= subcmd_len;
nan_buf_size = (NAN_IOCTL_BUF_SIZE - nan_iov_data->nan_iov_len);
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("\n set nan avail failed ret %d status %d \n", ret, status));
ret = status;
goto fail;
}
} else if (status == BCME_OK) {
WL_DBG(("Avail type [%d] found to be configured\n", avail_type));
} else {
WL_ERR(("set nan avail failed ret %d status %d \n", ret, status));
}
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
if (nan_iov_data) {
MFREE(cfg->osh, nan_iov_data, sizeof(*nan_iov_data));
}
NAN_DBG_EXIT();
return ret;
}
/* API to configure nan ctrl and nan ctrl2 commands */
static int
wl_cfgnan_config_control_flag(struct net_device *ndev, struct bcm_cfg80211 *cfg,
uint32 flag1, uint32 flag2, uint16 cmd_id, uint32 *status, bool set)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
s32 ret = BCME_OK;
uint16 nan_iov_start, nan_iov_end;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
uint16 subcmd_len;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
bcm_iov_batch_subcmd_t *sub_cmd_resp = NULL;
wl_nan_iov_t *nan_iov_data = NULL;
uint32 *cfg_ctrl;
uint16 cfg_ctrl_size;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
NAN_DBG_ENTER();
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data = MALLOCZ(cfg->osh, sizeof(*nan_iov_data));
if (!nan_iov_data) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
if (cmd_id == WL_NAN_CMD_CFG_NAN_CONFIG) {
cfg_ctrl_size = sizeof(wl_nan_cfg_ctrl_t);
} else if (cmd_id == WL_NAN_CMD_CFG_NAN_CONFIG2) {
cfg_ctrl_size = sizeof(wl_nan_cfg_ctrl2_t);
} else {
ret = BCME_BADARG;
goto fail;
}
nan_iov_data->nan_iov_len = nan_iov_start = NAN_IOCTL_BUF_SIZE;
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_iov_data->nan_iov_buf = (uint8 *)(&nan_buf->cmds[0]);
nan_iov_data->nan_iov_len -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
cfg_ctrl_size, &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
sub_cmd->id = htod16(cmd_id);
sub_cmd->len = sizeof(sub_cmd->u.options) + cfg_ctrl_size;
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
nan_buf->is_set = false;
nan_buf->count++;
/* Reduce the iov_len size by subcmd_len */
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_end = nan_iov_data->nan_iov_len;
nan_buf_size = (nan_iov_start - nan_iov_end);
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size, status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(*status)) {
WL_ERR(("get nan cfg ctrl failed ret %d status %d \n", ret, *status));
goto fail;
}
sub_cmd_resp = &((bcm_iov_batch_buf_t *)(resp_buf))->cmds[0];
/* check the response buff */
if (cmd_id == WL_NAN_CMD_CFG_NAN_CONFIG) {
wl_nan_cfg_ctrl_t *cfg_ctrl1;
cfg_ctrl1 = ((uint32 *)&sub_cmd_resp->data[0]);
if (set) {
*cfg_ctrl1 |= flag1;
} else {
*cfg_ctrl1 &= ~flag1;
}
cfg_ctrl = cfg_ctrl1;
WL_INFORM_MEM(("%s: Modifying nan ctrl flag %x val %d\n",
__FUNCTION__, flag1, set));
} else {
wl_nan_cfg_ctrl2_t *cfg_ctrl2;
cfg_ctrl2 = ((wl_nan_cfg_ctrl2_t *)&sub_cmd_resp->data[0]);
if (set) {
cfg_ctrl2->flags1 |= flag1;
cfg_ctrl2->flags2 |= flag2;
} else {
cfg_ctrl2->flags1 &= ~flag1;
cfg_ctrl2->flags2 &= ~flag2;
}
cfg_ctrl = (uint32 *)cfg_ctrl2;
WL_INFORM_MEM(("%s: Modifying nan ctrl2 flag1 %x flag2 %x val %d\n",
__FUNCTION__, flag1, flag2, set));
}
ret = memcpy_s(sub_cmd->data, cfg_ctrl_size, cfg_ctrl, cfg_ctrl_size);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy cfg ctrl\n"));
goto fail;
}
nan_buf->is_set = true;
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size, status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(*status)) {
WL_ERR(("set nan cfg ctrl failed ret %d status %d \n", ret, *status));
goto fail;
}
WL_DBG(("set nan cfg ctrl successfull\n"));
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
if (nan_iov_data) {
MFREE(cfg->osh, nan_iov_data, sizeof(*nan_iov_data));
}
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_get_iovars_status(void *ctx, const uint8 *data, uint16 type, uint16 len)
{
bcm_iov_batch_buf_t *b_resp = (bcm_iov_batch_buf_t *)ctx;
uint32 status;
/* if all tlvs are parsed, we should not be here */
if (b_resp->count == 0) {
return BCME_BADLEN;
}
/* cbfn params may be used in f/w */
if (len < sizeof(status)) {
return BCME_BUFTOOSHORT;
}
/* first 4 bytes consists status */
if (memcpy_s(&status, sizeof(status),
data, sizeof(uint32)) != BCME_OK) {
WL_ERR(("Failed to copy status\n"));
goto exit;
}
status = dtoh32(status);
/* If status is non zero */
if (status != BCME_OK) {
printf("cmd type %d failed, status: %04x\n", type, status);
goto exit;
}
if (b_resp->count > 0) {
b_resp->count--;
}
if (!b_resp->count) {
status = BCME_IOV_LAST_CMD;
}
exit:
return status;
}
static int
wl_cfgnan_execute_ioctl(struct net_device *ndev, struct bcm_cfg80211 *cfg,
bcm_iov_batch_buf_t *nan_buf, uint16 nan_buf_size, uint32 *status,
uint8 *resp_buf, uint16 resp_buf_size)
{
int ret = BCME_OK;
uint16 tlvs_len;
int res = BCME_OK;
bcm_iov_batch_buf_t *p_resp = NULL;
char *iov = "nan";
int max_resp_len = WLC_IOCTL_MAXLEN;
WL_DBG(("Enter:\n"));
if (nan_buf->is_set) {
ret = wldev_iovar_setbuf(ndev, "nan", nan_buf, nan_buf_size,
resp_buf, resp_buf_size, NULL);
p_resp = (bcm_iov_batch_buf_t *)(resp_buf + strlen(iov) + 1);
} else {
ret = wldev_iovar_getbuf(ndev, "nan", nan_buf, nan_buf_size,
resp_buf, resp_buf_size, NULL);
p_resp = (bcm_iov_batch_buf_t *)(resp_buf);
}
if (unlikely(ret)) {
WL_ERR((" nan execute ioctl failed, error = %d \n", ret));
goto fail;
}
p_resp->is_set = nan_buf->is_set;
tlvs_len = max_resp_len - OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
/* Extract the tlvs and print their resp in cb fn */
res = bcm_unpack_xtlv_buf((void *)p_resp, (const uint8 *)&p_resp->cmds[0],
tlvs_len, BCM_IOV_CMD_OPT_ALIGN32, wl_cfgnan_get_iovars_status);
if (res == BCME_IOV_LAST_CMD) {
res = BCME_OK;
}
fail:
*status = res;
WL_DBG((" nan ioctl ret %d status %d \n", ret, *status));
return ret;
}
static int
wl_cfgnan_if_addr_handler(void *p_buf, uint16 *nan_buf_size,
struct ether_addr *if_addr)
{
/* nan enable */
s32 ret = BCME_OK;
uint16 subcmd_len;
NAN_DBG_ENTER();
if (p_buf != NULL) {
bcm_iov_batch_subcmd_t *sub_cmd = (bcm_iov_batch_subcmd_t*)(p_buf);
ret = wl_cfg_nan_check_cmd_len(*nan_buf_size,
sizeof(*if_addr), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
/* Fill the sub_command block */
sub_cmd->id = htod16(WL_NAN_CMD_CFG_IF_ADDR);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(*if_addr);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
ret = memcpy_s(sub_cmd->data, sizeof(*if_addr),
(uint8 *)if_addr, sizeof(*if_addr));
if (ret != BCME_OK) {
WL_ERR(("Failed to copy if addr\n"));
goto fail;
}
*nan_buf_size -= subcmd_len;
} else {
WL_ERR(("nan_iov_buf is NULL\n"));
ret = BCME_ERROR;
goto fail;
}
fail:
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_get_ver(struct net_device *ndev, struct bcm_cfg80211 *cfg)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
wl_nan_ver_t *nan_ver = NULL;
uint16 subcmd_len;
uint32 status;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
bcm_iov_batch_subcmd_t *sub_cmd_resp = NULL;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
NAN_DBG_ENTER();
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(uint8 *)(&nan_buf->cmds[0]);
ret = wl_cfg_nan_check_cmd_len(nan_buf_size,
sizeof(*nan_ver), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
nan_ver = (wl_nan_ver_t *)sub_cmd->data;
sub_cmd->id = htod16(WL_NAN_CMD_GLB_NAN_VER);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(*nan_ver);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
nan_buf_size -= subcmd_len;
nan_buf->count = 1;
nan_buf->is_set = false;
bzero(resp_buf, sizeof(resp_buf));
nan_buf_size = NAN_IOCTL_BUF_SIZE - nan_buf_size;
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("get nan ver failed ret %d status %d \n",
ret, status));
goto fail;
}
sub_cmd_resp = &((bcm_iov_batch_buf_t *)(resp_buf))->cmds[0];
nan_ver = ((wl_nan_ver_t *)&sub_cmd_resp->data[0]);
if (!nan_ver) {
ret = BCME_NOTFOUND;
WL_ERR(("nan_ver not found: err = %d\n", ret));
goto fail;
}
cfg->nancfg->version = *nan_ver;
WL_INFORM_MEM(("Nan Version is %d\n", cfg->nancfg->version));
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_set_if_addr(struct bcm_cfg80211 *cfg)
{
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
uint32 status;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
struct ether_addr if_addr;
uint8 buf[NAN_IOCTL_BUF_SIZE];
bcm_iov_batch_buf_t *nan_buf = (bcm_iov_batch_buf_t*)buf;
bool rand_mac = cfg->nancfg->mac_rand;
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
if (rand_mac) {
RANDOM_BYTES(if_addr.octet, 6);
/* restore mcast and local admin bits to 0 and 1 */
ETHER_SET_UNICAST(if_addr.octet);
ETHER_SET_LOCALADDR(if_addr.octet);
} else {
/* Use primary MAC with the locally administered bit for the
* NAN NMI I/F
*/
if (wl_get_vif_macaddr(cfg, WL_IF_TYPE_NAN_NMI,
if_addr.octet) != BCME_OK) {
ret = -EINVAL;
WL_ERR(("Failed to get mac addr for NMI\n"));
goto fail;
}
}
WL_INFORM_MEM(("%s: NMI " MACDBG "\n",
__FUNCTION__, MAC2STRDBG(if_addr.octet)));
ret = wl_cfgnan_if_addr_handler(&nan_buf->cmds[0],
&nan_buf_size, &if_addr);
if (unlikely(ret)) {
WL_ERR(("Nan if addr handler sub_cmd set failed\n"));
goto fail;
}
nan_buf->count++;
nan_buf->is_set = true;
nan_buf_size = NAN_IOCTL_BUF_SIZE - nan_buf_size;
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(bcmcfg_to_prmry_ndev(cfg), cfg,
nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("nan if addr handler failed ret %d status %d\n",
ret, status));
goto fail;
}
ret = memcpy_s(cfg->nancfg->nan_nmi_mac, ETH_ALEN,
if_addr.octet, ETH_ALEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy nmi addr\n"));
goto fail;
}
return ret;
fail:
if (!rand_mac) {
wl_release_vif_macaddr(cfg, if_addr.octet, WL_IF_TYPE_NAN_NMI);
}
return ret;
}
static int
wl_cfgnan_init_handler(void *p_buf, uint16 *nan_buf_size, bool val)
{
/* nan enable */
s32 ret = BCME_OK;
uint16 subcmd_len;
NAN_DBG_ENTER();
if (p_buf != NULL) {
bcm_iov_batch_subcmd_t *sub_cmd = (bcm_iov_batch_subcmd_t*)(p_buf);
ret = wl_cfg_nan_check_cmd_len(*nan_buf_size,
sizeof(val), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
/* Fill the sub_command block */
sub_cmd->id = htod16(WL_NAN_CMD_CFG_NAN_INIT);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(uint8);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
ret = memcpy_s(sub_cmd->data, sizeof(uint8),
(uint8*)&val, sizeof(uint8));
if (ret != BCME_OK) {
WL_ERR(("Failed to copy init value\n"));
goto fail;
}
*nan_buf_size -= subcmd_len;
} else {
WL_ERR(("nan_iov_buf is NULL\n"));
ret = BCME_ERROR;
goto fail;
}
fail:
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_enable_handler(wl_nan_iov_t *nan_iov_data, bool val)
{
/* nan enable */
s32 ret = BCME_OK;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
uint16 subcmd_len;
NAN_DBG_ENTER();
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
sizeof(val), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
return ret;
}
/* Fill the sub_command block */
sub_cmd->id = htod16(WL_NAN_CMD_CFG_NAN_ENAB);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(uint8);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
ret = memcpy_s(sub_cmd->data, sizeof(uint8),
(uint8*)&val, sizeof(uint8));
if (ret != BCME_OK) {
WL_ERR(("Failed to copy enab value\n"));
return ret;
}
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_data->nan_iov_buf += subcmd_len;
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_warmup_time_handler(nan_config_cmd_data_t *cmd_data,
wl_nan_iov_t *nan_iov_data)
{
/* wl nan warm_up_time */
s32 ret = BCME_OK;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
wl_nan_warmup_time_ticks_t *wup_ticks = NULL;
uint16 subcmd_len;
NAN_DBG_ENTER();
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
wup_ticks = (wl_nan_warmup_time_ticks_t *)sub_cmd->data;
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
sizeof(*wup_ticks), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
return ret;
}
/* Fill the sub_command block */
sub_cmd->id = htod16(WL_NAN_CMD_CFG_WARMUP_TIME);
sub_cmd->len = sizeof(sub_cmd->u.options) +
sizeof(*wup_ticks);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
*wup_ticks = cmd_data->warmup_time;
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_data->nan_iov_buf += subcmd_len;
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_set_election_metric(nan_config_cmd_data_t *cmd_data,
wl_nan_iov_t *nan_iov_data, uint32 nan_attr_mask)
{
s32 ret = BCME_OK;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
wl_nan_election_metric_config_t *metrics = NULL;
uint16 subcmd_len;
NAN_DBG_ENTER();
sub_cmd =
(bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
sizeof(*metrics), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
metrics = (wl_nan_election_metric_config_t *)sub_cmd->data;
if (nan_attr_mask & NAN_ATTR_RAND_FACTOR_CONFIG) {
metrics->random_factor = (uint8)cmd_data->metrics.random_factor;
}
if ((!cmd_data->metrics.master_pref) ||
(cmd_data->metrics.master_pref > NAN_MAXIMUM_MASTER_PREFERENCE)) {
WL_TRACE(("Master Pref is 0 or greater than 254, hence sending random value\n"));
/* Master pref for mobile devices can be from 1 - 127 as per Spec AppendixC */
metrics->master_pref = (RANDOM32()%(NAN_MAXIMUM_MASTER_PREFERENCE/2)) + 1;
} else {
metrics->master_pref = (uint8)cmd_data->metrics.master_pref;
}
sub_cmd->id = htod16(WL_NAN_CMD_ELECTION_METRICS_CONFIG);
sub_cmd->len = sizeof(sub_cmd->u.options) +
sizeof(*metrics);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_data->nan_iov_buf += subcmd_len;
fail:
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_set_rssi_proximity(nan_config_cmd_data_t *cmd_data,
wl_nan_iov_t *nan_iov_data, uint32 nan_attr_mask)
{
s32 ret = BCME_OK;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
wl_nan_rssi_notif_thld_t *rssi_notif_thld = NULL;
uint16 subcmd_len;
NAN_DBG_ENTER();
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
rssi_notif_thld = (wl_nan_rssi_notif_thld_t *)sub_cmd->data;
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
sizeof(*rssi_notif_thld), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
return ret;
}
if (nan_attr_mask & NAN_ATTR_RSSI_PROXIMITY_2G_CONFIG) {
rssi_notif_thld->bcn_rssi_2g =
cmd_data->rssi_attr.rssi_proximity_2dot4g_val;
} else {
/* Keeping RSSI threshold value to be -70dBm */
rssi_notif_thld->bcn_rssi_2g = NAN_DEF_RSSI_NOTIF_THRESH;
}
if (nan_attr_mask & NAN_ATTR_RSSI_PROXIMITY_5G_CONFIG) {
rssi_notif_thld->bcn_rssi_5g =
cmd_data->rssi_attr.rssi_proximity_5g_val;
} else {
/* Keeping RSSI threshold value to be -70dBm */
rssi_notif_thld->bcn_rssi_5g = NAN_DEF_RSSI_NOTIF_THRESH;
}
sub_cmd->id = htod16(WL_NAN_CMD_SYNC_BCN_RSSI_NOTIF_THRESHOLD);
sub_cmd->len = htod16(sizeof(sub_cmd->u.options) + sizeof(*rssi_notif_thld));
sub_cmd->u.options = htod32(BCM_XTLV_OPTION_ALIGN32);
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_data->nan_iov_buf += subcmd_len;
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_set_rssi_mid_or_close(nan_config_cmd_data_t *cmd_data,
wl_nan_iov_t *nan_iov_data, uint32 nan_attr_mask)
{
s32 ret = BCME_OK;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
wl_nan_rssi_thld_t *rssi_thld = NULL;
uint16 subcmd_len;
NAN_DBG_ENTER();
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
rssi_thld = (wl_nan_rssi_thld_t *)sub_cmd->data;
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
sizeof(*rssi_thld), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
return ret;
}
/*
* Keeping RSSI mid value -75dBm for both 2G and 5G
* Keeping RSSI close value -60dBm for both 2G and 5G
*/
if (nan_attr_mask & NAN_ATTR_RSSI_MIDDLE_2G_CONFIG) {
rssi_thld->rssi_mid_2g =
cmd_data->rssi_attr.rssi_middle_2dot4g_val;
} else {
rssi_thld->rssi_mid_2g = NAN_DEF_RSSI_MID;
}
if (nan_attr_mask & NAN_ATTR_RSSI_MIDDLE_5G_CONFIG) {
rssi_thld->rssi_mid_5g =
cmd_data->rssi_attr.rssi_middle_5g_val;
} else {
rssi_thld->rssi_mid_5g = NAN_DEF_RSSI_MID;
}
if (nan_attr_mask & NAN_ATTR_RSSI_CLOSE_CONFIG) {
rssi_thld->rssi_close_2g =
cmd_data->rssi_attr.rssi_close_2dot4g_val;
} else {
rssi_thld->rssi_close_2g = NAN_DEF_RSSI_CLOSE;
}
if (nan_attr_mask & NAN_ATTR_RSSI_CLOSE_5G_CONFIG) {
rssi_thld->rssi_close_5g =
cmd_data->rssi_attr.rssi_close_5g_val;
} else {
rssi_thld->rssi_close_5g = NAN_DEF_RSSI_CLOSE;
}
sub_cmd->id = htod16(WL_NAN_CMD_ELECTION_RSSI_THRESHOLD);
sub_cmd->len = htod16(sizeof(sub_cmd->u.options) + sizeof(*rssi_thld));
sub_cmd->u.options = htod32(BCM_XTLV_OPTION_ALIGN32);
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_data->nan_iov_buf += subcmd_len;
NAN_DBG_EXIT();
return ret;
}
static int
check_for_valid_5gchan(struct net_device *ndev, uint8 chan)
{
s32 ret = BCME_OK;
uint bitmap;
u8 ioctl_buf[WLC_IOCTL_SMLEN];
uint32 chanspec_arg;
NAN_DBG_ENTER();
chanspec_arg = CH20MHZ_CHSPEC(chan);
chanspec_arg = wl_chspec_host_to_driver(chanspec_arg);
bzero(ioctl_buf, WLC_IOCTL_SMLEN);
ret = wldev_iovar_getbuf(ndev, "per_chan_info",
(void *)&chanspec_arg, sizeof(chanspec_arg),
ioctl_buf, WLC_IOCTL_SMLEN, NULL);
if (ret != BCME_OK) {
WL_ERR(("Chaninfo for channel = %d, error %d\n", chan, ret));
goto exit;
}
bitmap = dtoh32(*(uint *)ioctl_buf);
if (!(bitmap & WL_CHAN_VALID_HW)) {
WL_ERR(("Invalid channel\n"));
ret = BCME_BADCHAN;
goto exit;
}
if (!(bitmap & WL_CHAN_VALID_SW)) {
WL_ERR(("Not supported in current locale\n"));
ret = BCME_BADCHAN;
goto exit;
}
exit:
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_set_nan_soc_chans(struct net_device *ndev, nan_config_cmd_data_t *cmd_data,
wl_nan_iov_t *nan_iov_data, uint32 nan_attr_mask)
{
s32 ret = BCME_OK;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
wl_nan_social_channels_t *soc_chans = NULL;
uint16 subcmd_len;
NAN_DBG_ENTER();
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
soc_chans =
(wl_nan_social_channels_t *)sub_cmd->data;
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
sizeof(*soc_chans), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
return ret;
}
sub_cmd->id = htod16(WL_NAN_CMD_SYNC_SOCIAL_CHAN);
sub_cmd->len = sizeof(sub_cmd->u.options) +
sizeof(*soc_chans);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
if (nan_attr_mask & NAN_ATTR_2G_CHAN_CONFIG) {
soc_chans->soc_chan_2g = cmd_data->chanspec[1];
} else {
soc_chans->soc_chan_2g = NAN_DEF_SOCIAL_CHAN_2G;
}
if (cmd_data->support_5g) {
if (nan_attr_mask & NAN_ATTR_5G_CHAN_CONFIG) {
soc_chans->soc_chan_5g = cmd_data->chanspec[2];
} else {
soc_chans->soc_chan_5g = NAN_DEF_SOCIAL_CHAN_5G;
}
ret = check_for_valid_5gchan(ndev, soc_chans->soc_chan_5g);
if (ret != BCME_OK) {
ret = check_for_valid_5gchan(ndev, NAN_DEF_SEC_SOCIAL_CHAN_5G);
if (ret == BCME_OK) {
soc_chans->soc_chan_5g = NAN_DEF_SEC_SOCIAL_CHAN_5G;
} else {
soc_chans->soc_chan_5g = 0;
ret = BCME_OK;
WL_ERR(("Current locale doesn't support 5G op"
"continuing with 2G only operation\n"));
}
}
} else {
WL_DBG(("5G support is disabled\n"));
}
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_data->nan_iov_buf += subcmd_len;
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_set_nan_scan_params(struct net_device *ndev, struct bcm_cfg80211 *cfg,
nan_config_cmd_data_t *cmd_data, uint8 band_index, uint32 nan_attr_mask)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
s32 ret = BCME_OK;
uint16 nan_iov_start, nan_iov_end;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
uint16 subcmd_len;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
wl_nan_iov_t *nan_iov_data = NULL;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
wl_nan_scan_params_t *scan_params = NULL;
uint32 status;
NAN_DBG_ENTER();
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data = MALLOCZ(cfg->osh, sizeof(*nan_iov_data));
if (!nan_iov_data) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data->nan_iov_len = nan_iov_start = NAN_IOCTL_BUF_SIZE;
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_iov_data->nan_iov_buf = (uint8 *)(&nan_buf->cmds[0]);
nan_iov_data->nan_iov_len -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
sizeof(*scan_params), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
scan_params = (wl_nan_scan_params_t *)sub_cmd->data;
sub_cmd->id = htod16(WL_NAN_CMD_CFG_SCAN_PARAMS);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(*scan_params);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
if (!band_index) {
/* Fw default: Dwell time for 2G is 210 */
if ((nan_attr_mask & NAN_ATTR_2G_DWELL_TIME_CONFIG) &&
cmd_data->dwell_time[0]) {
scan_params->dwell_time = cmd_data->dwell_time[0] +
NAN_SCAN_DWELL_TIME_DELTA_MS;
}
/* Fw default: Scan period for 2G is 10 */
if (nan_attr_mask & NAN_ATTR_2G_SCAN_PERIOD_CONFIG) {
scan_params->scan_period = cmd_data->scan_period[0];
}
} else {
if ((nan_attr_mask & NAN_ATTR_5G_DWELL_TIME_CONFIG) &&
cmd_data->dwell_time[1]) {
scan_params->dwell_time = cmd_data->dwell_time[1] +
NAN_SCAN_DWELL_TIME_DELTA_MS;
}
if (nan_attr_mask & NAN_ATTR_5G_SCAN_PERIOD_CONFIG) {
scan_params->scan_period = cmd_data->scan_period[1];
}
}
scan_params->band_index = band_index;
nan_buf->is_set = true;
nan_buf->count++;
/* Reduce the iov_len size by subcmd_len */
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_end = nan_iov_data->nan_iov_len;
nan_buf_size = (nan_iov_start - nan_iov_end);
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("set nan scan params failed ret %d status %d \n", ret, status));
goto fail;
}
WL_DBG(("set nan scan params successfull\n"));
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
if (nan_iov_data) {
MFREE(cfg->osh, nan_iov_data, sizeof(*nan_iov_data));
}
NAN_DBG_EXIT();
return ret;
}
static uint16
wl_cfgnan_gen_rand_cluster_id(uint16 low_val, uint16 high_val)
{
uint16 random_id;
ulong random_seed;
/* In negative case also, assigning to cluster_high value */
if (low_val >= high_val)
{
random_id = high_val;
} else {
RANDOM_BYTES(&random_seed, sizeof(random_seed));
random_id = (uint16)((random_seed % ((high_val + 1) -
low_val)) + low_val);
}
return random_id;
}
static int
wl_cfgnan_set_cluster_id(nan_config_cmd_data_t *cmd_data,
wl_nan_iov_t *nan_iov_data)
{
s32 ret = BCME_OK;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
uint16 subcmd_len;
NAN_DBG_ENTER();
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
(sizeof(cmd_data->clus_id) - sizeof(uint8)), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
return ret;
}
cmd_data->clus_id.octet[0] = 0x50;
cmd_data->clus_id.octet[1] = 0x6F;
cmd_data->clus_id.octet[2] = 0x9A;
cmd_data->clus_id.octet[3] = 0x01;
hton16_ua_store(wl_cfgnan_gen_rand_cluster_id(cmd_data->cluster_low,
cmd_data->cluster_high), &cmd_data->clus_id.octet[4]);
WL_TRACE(("cluster_id = " MACDBG "\n", MAC2STRDBG(cmd_data->clus_id.octet)));
sub_cmd->id = htod16(WL_NAN_CMD_CFG_CID);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(cmd_data->clus_id);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
ret = memcpy_s(sub_cmd->data, sizeof(cmd_data->clus_id),
(uint8 *)&cmd_data->clus_id,
sizeof(cmd_data->clus_id));
if (ret != BCME_OK) {
WL_ERR(("Failed to copy clus id\n"));
return ret;
}
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_data->nan_iov_buf += subcmd_len;
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_set_hop_count_limit(nan_config_cmd_data_t *cmd_data,
wl_nan_iov_t *nan_iov_data)
{
s32 ret = BCME_OK;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
wl_nan_hop_count_t *hop_limit = NULL;
uint16 subcmd_len;
NAN_DBG_ENTER();
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
hop_limit = (wl_nan_hop_count_t *)sub_cmd->data;
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
sizeof(*hop_limit), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
return ret;
}
*hop_limit = cmd_data->hop_count_limit;
sub_cmd->id = htod16(WL_NAN_CMD_CFG_HOP_LIMIT);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(*hop_limit);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_data->nan_iov_buf += subcmd_len;
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_set_sid_beacon_val(nan_config_cmd_data_t *cmd_data,
wl_nan_iov_t *nan_iov_data, uint32 nan_attr_mask)
{
s32 ret = BCME_OK;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
wl_nan_sid_beacon_control_t *sid_beacon = NULL;
uint16 subcmd_len;
NAN_DBG_ENTER();
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
sizeof(*sid_beacon), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
return ret;
}
sid_beacon = (wl_nan_sid_beacon_control_t *)sub_cmd->data;
sid_beacon->sid_enable = cmd_data->sid_beacon.sid_enable;
/* Need to have separate flag for sub beacons
* sid_beacon->sub_sid_enable = cmd_data->sid_beacon.sub_sid_enable;
*/
if (nan_attr_mask & NAN_ATTR_SID_BEACON_CONFIG) {
/* Limit for number of publish SIDs to be included in Beacons */
sid_beacon->sid_count = cmd_data->sid_beacon.sid_count;
}
if (nan_attr_mask & NAN_ATTR_SUB_SID_BEACON_CONFIG) {
/* Limit for number of subscribe SIDs to be included in Beacons */
sid_beacon->sub_sid_count = cmd_data->sid_beacon.sub_sid_count;
}
sub_cmd->id = htod16(WL_NAN_CMD_CFG_SID_BEACON);
sub_cmd->len = sizeof(sub_cmd->u.options) +
sizeof(*sid_beacon);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_data->nan_iov_buf += subcmd_len;
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_set_nan_oui(nan_config_cmd_data_t *cmd_data,
wl_nan_iov_t *nan_iov_data)
{
s32 ret = BCME_OK;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
uint16 subcmd_len;
NAN_DBG_ENTER();
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
sizeof(cmd_data->nan_oui), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
return ret;
}
sub_cmd->id = htod16(WL_NAN_CMD_CFG_OUI);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(cmd_data->nan_oui);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
ret = memcpy_s(sub_cmd->data, sizeof(cmd_data->nan_oui),
(uint32 *)&cmd_data->nan_oui,
sizeof(cmd_data->nan_oui));
if (ret != BCME_OK) {
WL_ERR(("Failed to copy nan oui\n"));
return ret;
}
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_data->nan_iov_buf += subcmd_len;
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_set_awake_dws(struct net_device *ndev, nan_config_cmd_data_t *cmd_data,
wl_nan_iov_t *nan_iov_data, struct bcm_cfg80211 *cfg, uint32 nan_attr_mask)
{
s32 ret = BCME_OK;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
wl_nan_awake_dws_t *awake_dws = NULL;
uint16 subcmd_len;
NAN_DBG_ENTER();
sub_cmd =
(bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
sizeof(*awake_dws), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
return ret;
}
awake_dws = (wl_nan_awake_dws_t *)sub_cmd->data;
if (nan_attr_mask & NAN_ATTR_2G_DW_CONFIG) {
awake_dws->dw_interval_2g = cmd_data->awake_dws.dw_interval_2g;
if (!awake_dws->dw_interval_2g) {
/* Set 2G awake dw value to fw default value 1 */
awake_dws->dw_interval_2g = NAN_SYNC_DEF_AWAKE_DW;
}
} else {
/* Set 2G awake dw value to fw default value 1 */
awake_dws->dw_interval_2g = NAN_SYNC_DEF_AWAKE_DW;
}
if (cfg->nancfg->support_5g) {
if (nan_attr_mask & NAN_ATTR_5G_DW_CONFIG) {
awake_dws->dw_interval_5g = cmd_data->awake_dws.dw_interval_5g;
/* config sync/discovery beacons on 5G band */
ret = wl_cfgnan_config_control_flag(ndev, cfg,
WL_NAN_CTRL_DISC_BEACON_TX_5G |
WL_NAN_CTRL_SYNC_BEACON_TX_5G,
0, WL_NAN_CMD_CFG_NAN_CONFIG,
&(cmd_data->status),
awake_dws->dw_interval_5g);
if (unlikely(ret) || unlikely(cmd_data->status)) {
WL_ERR((" nan control set config handler, ret = %d"
" status = %d \n", ret, cmd_data->status));
goto fail;
}
} else {
/* Set 5G awake dw value to fw default value 1 */
awake_dws->dw_interval_5g = NAN_SYNC_DEF_AWAKE_DW;
}
}
sub_cmd->id = htod16(WL_NAN_CMD_SYNC_AWAKE_DWS);
sub_cmd->len = sizeof(sub_cmd->u.options) +
sizeof(*awake_dws);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_data->nan_iov_buf += subcmd_len;
fail:
NAN_DBG_EXIT();
return ret;
}
int
wl_cfgnan_set_enable_merge(struct net_device *ndev,
struct bcm_cfg80211 *cfg, uint8 enable, uint32 *status)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
s32 ret = BCME_OK;
uint16 nan_iov_start, nan_iov_end;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
uint16 subcmd_len;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
wl_nan_iov_t *nan_iov_data = NULL;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
wl_nan_merge_enable_t merge_enable;
uint8 size_of_iov;
NAN_DBG_ENTER();
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data = MALLOCZ(cfg->osh, sizeof(*nan_iov_data));
if (!nan_iov_data) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
merge_enable = (wl_nan_merge_enable_t)enable;
size_of_iov = sizeof(wl_nan_merge_enable_t);
nan_iov_data->nan_iov_len = nan_iov_start = NAN_IOCTL_BUF_SIZE;
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_iov_data->nan_iov_buf = (uint8 *)(&nan_buf->cmds[0]);
nan_iov_data->nan_iov_len -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
size_of_iov, &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
sub_cmd->id = htod16(WL_NAN_CMD_ELECTION_MERGE);
sub_cmd->len = sizeof(sub_cmd->u.options) + size_of_iov;
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
/* Reduce the iov_len size by subcmd_len */
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_end = nan_iov_data->nan_iov_len;
nan_buf_size = (nan_iov_start - nan_iov_end);
(void)memcpy_s(sub_cmd->data, nan_iov_data->nan_iov_len,
&merge_enable, size_of_iov);
nan_buf->is_set = true;
nan_buf->count++;
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size, status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(*status)) {
WL_ERR(("Merge enable %d failed ret %d status %d \n", merge_enable, ret, *status));
goto fail;
}
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
if (nan_iov_data) {
MFREE(cfg->osh, nan_iov_data, sizeof(*nan_iov_data));
}
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_set_disc_beacon_interval_handler(struct net_device *ndev, struct bcm_cfg80211 *cfg,
wl_nan_disc_bcn_interval_t disc_beacon_interval)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
wl_nan_iov_t *nan_iov_data = NULL;
uint32 status;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
uint16 subcmd_len;
uint8 size_of_iov;
NAN_DBG_ENTER();
NAN_MUTEX_LOCK();
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data = MALLOCZ(cfg->osh, sizeof(*nan_iov_data));
if (!nan_iov_data) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
size_of_iov = sizeof(wl_nan_disc_bcn_interval_t);
nan_iov_data->nan_iov_len = NAN_IOCTL_BUF_SIZE;
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_iov_data->nan_iov_buf = (uint8 *)(&nan_buf->cmds[0]);
nan_iov_data->nan_iov_len -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
size_of_iov, &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
/* Choose default value discovery beacon interval if value is zero */
if (!disc_beacon_interval) {
disc_beacon_interval = cfg->nancfg->support_5g ? NAN_DISC_BCN_INTERVAL_5G_DEF:
NAN_DISC_BCN_INTERVAL_2G_DEF;
}
/* Fill the sub_command block */
sub_cmd->id = htod16(WL_NAN_CMD_CFG_BCN_INTERVAL);
sub_cmd->len = sizeof(sub_cmd->u.options) + size_of_iov;
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
ret = memcpy_s(sub_cmd->data, nan_iov_data->nan_iov_len,
&disc_beacon_interval, size_of_iov);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy disc_beacon_interval\n"));
goto fail;
}
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_data->nan_iov_buf += subcmd_len;
nan_buf->count++;
nan_buf->is_set = true;
nan_buf_size -= nan_iov_data->nan_iov_len;
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("Failed to set disc beacon interval, ret = %d status = %d\n",
ret, status));
goto fail;
}
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
if (nan_iov_data) {
MFREE(cfg->osh, nan_iov_data, sizeof(*nan_iov_data));
}
NAN_MUTEX_UNLOCK();
NAN_DBG_EXIT();
return ret;
}
void
wl_cfgnan_immediate_nan_disable_pending(struct bcm_cfg80211 *cfg)
{
if (delayed_work_pending(&cfg->nancfg->nan_disable)) {
WL_DBG(("Do immediate nan_disable work\n"));
DHD_NAN_WAKE_UNLOCK(cfg->pub);
if (cancel_delayed_work(&cfg->nancfg->nan_disable)) {
schedule_delayed_work(&cfg->nancfg->nan_disable, 0);
}
}
}
int
wl_cfgnan_check_nan_disable_pending(struct bcm_cfg80211 *cfg,
bool force_disable, bool is_sync_reqd)
{
int ret = BCME_OK;
struct net_device *ndev = NULL;
if (delayed_work_pending(&cfg->nancfg->nan_disable)) {
WL_DBG(("Cancel nan_disable work\n"));
/*
* Nan gets disabled from dhd_stop(dev_close) and other frameworks contexts.
* Can't use cancel_work_sync from dhd_stop context for
* wl_cfgnan_delayed_disable since both contexts uses
* rtnl_lock resulting in deadlock. If dhd_stop gets invoked,
* rely on dhd_stop context to do the nan clean up work and
* just do return from delayed WQ based on state check.
*/
DHD_NAN_WAKE_UNLOCK(cfg->pub);
if (is_sync_reqd == true) {
cancel_delayed_work_sync(&cfg->nancfg->nan_disable);
} else {
cancel_delayed_work(&cfg->nancfg->nan_disable);
}
force_disable = true;
}
if ((force_disable == true) && (cfg->nancfg->nan_enable == true)) {
ret = wl_cfgnan_disable(cfg);
if (ret != BCME_OK) {
WL_ERR(("failed to disable nan, error[%d]\n", ret));
}
/* Intentional fall through to cleanup framework */
if (cfg->nancfg->notify_user == true) {
ndev = bcmcfg_to_prmry_ndev(cfg);
wl_cfgvendor_nan_send_async_disable_resp(ndev->ieee80211_ptr);
}
}
return ret;
}
int
wl_cfgnan_start_handler(struct net_device *ndev, struct bcm_cfg80211 *cfg,
nan_config_cmd_data_t *cmd_data, uint32 nan_attr_mask)
{
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
bcm_iov_batch_buf_t *nan_buf = NULL;
wl_nan_iov_t *nan_iov_data = NULL;
dhd_pub_t *dhdp = wl_cfg80211_get_dhdp(ndev);
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
int i;
s32 timeout = 0;
nan_hal_capabilities_t capabilities;
uint32 cfg_ctrl1_flags = 0;
uint32 cfg_ctrl2_flags1 = 0;
wl_nancfg_t *nancfg = cfg->nancfg;
NAN_DBG_ENTER();
if (!dhdp->up) {
WL_ERR(("bus is already down, hence blocking nan start\n"));
return BCME_ERROR;
}
/* Protect discovery creation. Ensure proper mutex precedence.
* If if_sync & nan_mutex comes together in same context, nan_mutex
* should follow if_sync.
*/
mutex_lock(&cfg->if_sync);
NAN_MUTEX_LOCK();
#ifdef WL_IFACE_MGMT
if ((ret = wl_cfg80211_handle_if_role_conflict(cfg, WL_IF_TYPE_NAN_NMI)) != BCME_OK) {
WL_ERR(("Conflicting iface is present, cant support nan\n"));
NAN_MUTEX_UNLOCK();
mutex_unlock(&cfg->if_sync);
goto fail;
}
#endif /* WL_IFACE_MGMT */
/* disable TDLS on NAN init */
wl_cfg80211_tdls_config(cfg, TDLS_STATE_NMI_CREATE, false);
WL_INFORM_MEM(("Initializing NAN\n"));
ret = wl_cfgnan_init(cfg);
if (ret != BCME_OK) {
WL_ERR(("failed to initialize NAN[%d]\n", ret));
NAN_MUTEX_UNLOCK();
mutex_unlock(&cfg->if_sync);
goto fail;
}
ret = wl_cfgnan_get_ver(ndev, cfg);
if (ret != BCME_OK) {
WL_ERR(("failed to Nan IOV version[%d]\n", ret));
NAN_MUTEX_UNLOCK();
mutex_unlock(&cfg->if_sync);
goto fail;
}
/* set nmi addr */
ret = wl_cfgnan_set_if_addr(cfg);
if (ret != BCME_OK) {
WL_ERR(("Failed to set nmi address \n"));
NAN_MUTEX_UNLOCK();
mutex_unlock(&cfg->if_sync);
goto fail;
}
nancfg->nan_event_recvd = false;
NAN_MUTEX_UNLOCK();
mutex_unlock(&cfg->if_sync);
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data = MALLOCZ(cfg->osh, sizeof(*nan_iov_data));
if (!nan_iov_data) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data->nan_iov_len = NAN_IOCTL_BUF_SIZE;
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_iov_data->nan_iov_buf = (uint8 *)(&nan_buf->cmds[0]);
nan_iov_data->nan_iov_len -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
if (nan_attr_mask & NAN_ATTR_SYNC_DISC_2G_BEACON_CONFIG) {
/* config sync/discovery beacons on 2G band */
/* 2g is mandatory */
if (!cmd_data->beacon_2g_val) {
WL_ERR(("Invalid NAN config...2G is mandatory\n"));
ret = BCME_BADARG;
}
cfg_ctrl1_flags |= (WL_NAN_CTRL_DISC_BEACON_TX_2G | WL_NAN_CTRL_SYNC_BEACON_TX_2G);
}
if (nan_attr_mask & NAN_ATTR_SYNC_DISC_5G_BEACON_CONFIG) {
/* config sync/discovery beacons on 5G band */
cfg_ctrl1_flags |= (WL_NAN_CTRL_DISC_BEACON_TX_5G | WL_NAN_CTRL_SYNC_BEACON_TX_5G);
}
if (cmd_data->warmup_time) {
ret = wl_cfgnan_warmup_time_handler(cmd_data, nan_iov_data);
if (unlikely(ret)) {
WL_ERR(("warm up time handler sub_cmd set failed\n"));
goto fail;
}
nan_buf->count++;
}
/* setting master preference and random factor */
ret = wl_cfgnan_set_election_metric(cmd_data, nan_iov_data, nan_attr_mask);
if (unlikely(ret)) {
WL_ERR(("election_metric sub_cmd set failed\n"));
goto fail;
} else {
nan_buf->count++;
}
/* setting nan social channels */
ret = wl_cfgnan_set_nan_soc_chans(ndev, cmd_data, nan_iov_data, nan_attr_mask);
if (unlikely(ret)) {
WL_ERR(("nan social channels set failed\n"));
goto fail;
} else {
/* Storing 5g capability which is reqd for avail chan config. */
nancfg->support_5g = cmd_data->support_5g;
nan_buf->count++;
}
if ((cmd_data->support_2g) && ((cmd_data->dwell_time[0]) ||
(cmd_data->scan_period[0]))) {
/* setting scan params */
ret = wl_cfgnan_set_nan_scan_params(ndev, cfg, cmd_data, 0, nan_attr_mask);
if (unlikely(ret)) {
WL_ERR(("scan params set failed for 2g\n"));
goto fail;
}
}
if ((cmd_data->support_5g) && ((cmd_data->dwell_time[1]) ||
(cmd_data->scan_period[1]))) {
/* setting scan params */
ret = wl_cfgnan_set_nan_scan_params(ndev, cfg, cmd_data,
cmd_data->support_5g, nan_attr_mask);
if (unlikely(ret)) {
WL_ERR(("scan params set failed for 5g\n"));
goto fail;
}
}
/*
* A cluster_low value matching cluster_high indicates a request
* to join a cluster with that value.
* If the requested cluster is not found the
* device will start its own cluster
*/
/* For Debug purpose, using clust id compulsion */
if (cmd_data->cluster_low == cmd_data->cluster_high) {
/* device will merge to configured CID only */
cfg_ctrl1_flags |= (WL_NAN_CTRL_MERGE_CONF_CID_ONLY);
}
/* setting cluster ID */
ret = wl_cfgnan_set_cluster_id(cmd_data, nan_iov_data);
if (unlikely(ret)) {
WL_ERR(("cluster_id sub_cmd set failed\n"));
goto fail;
}
nan_buf->count++;
/* setting rssi proximaty values for 2.4GHz and 5GHz */
ret = wl_cfgnan_set_rssi_proximity(cmd_data, nan_iov_data, nan_attr_mask);
if (unlikely(ret)) {
WL_ERR(("2.4GHz/5GHz rssi proximity threshold set failed\n"));
goto fail;
} else {
nan_buf->count++;
}
/* setting rssi middle/close values for 2.4GHz and 5GHz */
ret = wl_cfgnan_set_rssi_mid_or_close(cmd_data, nan_iov_data, nan_attr_mask);
if (unlikely(ret)) {
WL_ERR(("2.4GHz/5GHz rssi middle and close set failed\n"));
goto fail;
} else {
nan_buf->count++;
}
/* setting hop count limit or threshold */
if (nan_attr_mask & NAN_ATTR_HOP_COUNT_LIMIT_CONFIG) {
ret = wl_cfgnan_set_hop_count_limit(cmd_data, nan_iov_data);
if (unlikely(ret)) {
WL_ERR(("hop_count_limit sub_cmd set failed\n"));
goto fail;
}
nan_buf->count++;
}
/* setting sid beacon val */
if ((nan_attr_mask & NAN_ATTR_SID_BEACON_CONFIG) ||
(nan_attr_mask & NAN_ATTR_SUB_SID_BEACON_CONFIG)) {
ret = wl_cfgnan_set_sid_beacon_val(cmd_data, nan_iov_data, nan_attr_mask);
if (unlikely(ret)) {
WL_ERR(("sid_beacon sub_cmd set failed\n"));
goto fail;
}
nan_buf->count++;
}
/* setting nan oui */
if (nan_attr_mask & NAN_ATTR_OUI_CONFIG) {
ret = wl_cfgnan_set_nan_oui(cmd_data, nan_iov_data);
if (unlikely(ret)) {
WL_ERR(("nan_oui sub_cmd set failed\n"));
goto fail;
}
nan_buf->count++;
}
/* setting nan awake dws */
ret = wl_cfgnan_set_awake_dws(ndev, cmd_data,
nan_iov_data, cfg, nan_attr_mask);
if (unlikely(ret)) {
WL_ERR(("nan awake dws set failed\n"));
goto fail;
} else {
nan_buf->count++;
}
/* enable events */
ret = wl_cfgnan_config_eventmask(ndev, cfg, cmd_data->disc_ind_cfg, false);
if (unlikely(ret)) {
WL_ERR(("Failed to config disc ind flag in event_mask, ret = %d\n", ret));
goto fail;
}
/* setting nan enable sub_cmd */
ret = wl_cfgnan_enable_handler(nan_iov_data, true);
if (unlikely(ret)) {
WL_ERR(("enable handler sub_cmd set failed\n"));
goto fail;
}
nan_buf->count++;
nan_buf->is_set = true;
nan_buf_size -= nan_iov_data->nan_iov_len;
memset(resp_buf, 0, sizeof(resp_buf));
/* Reset conditon variable */
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size,
&(cmd_data->status), (void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(cmd_data->status)) {
WL_ERR((" nan start handler, enable failed, ret = %d status = %d \n",
ret, cmd_data->status));
goto fail;
}
timeout = wait_event_timeout(nancfg->nan_event_wait,
nancfg->nan_event_recvd, msecs_to_jiffies(NAN_START_STOP_TIMEOUT));
if (!timeout) {
WL_ERR(("Timed out while Waiting for WL_NAN_EVENT_START event !!!\n"));
ret = BCME_ERROR;
goto fail;
}
/* Default flags: set NAN proprietary rates and auto datapath confirm
* If auto datapath confirms is set, then DPCONF will be sent by FW
*/
cfg_ctrl1_flags |= (WL_NAN_CTRL_AUTO_DPCONF | WL_NAN_CTRL_PROP_RATE);
/* set CFG CTRL flags */
ret = wl_cfgnan_config_control_flag(ndev, cfg, cfg_ctrl1_flags,
0, WL_NAN_CMD_CFG_NAN_CONFIG,
&(cmd_data->status), true);
if (unlikely(ret) || unlikely(cmd_data->status)) {
WL_ERR((" nan ctrl1 config flags setting failed, ret = %d status = %d \n",
ret, cmd_data->status));
goto fail;
}
/* malloc for ndp peer list */
if ((ret = wl_cfgnan_get_capablities_handler(ndev, cfg, &capabilities))
== BCME_OK) {
nancfg->max_ndp_count = capabilities.max_ndp_sessions;
nancfg->max_ndi_supported = capabilities.max_ndi_interfaces;
nancfg->nan_ndp_peer_info = MALLOCZ(cfg->osh,
nancfg->max_ndp_count * sizeof(nan_ndp_peer_t));
if (!nancfg->nan_ndp_peer_info) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
if (!nancfg->ndi) {
nancfg->ndi = MALLOCZ(cfg->osh,
nancfg->max_ndi_supported * sizeof(*nancfg->ndi));
if (!nancfg->ndi) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
}
} else {
WL_ERR(("wl_cfgnan_get_capablities_handler failed, ret = %d\n", ret));
goto fail;
}
BCM_REFERENCE(i);
#ifdef NAN_IFACE_CREATE_ON_UP
for (i = 0; i < nancfg->max_ndi_supported; i++) {
/* Create NDI using the information provided by user space */
if (nancfg->ndi[i].in_use && !nancfg->ndi[i].created) {
ret = wl_cfgnan_data_path_iface_create_delete_handler(ndev, cfg,
nancfg->ndi[i].ifname,
NAN_WIFI_SUBCMD_DATA_PATH_IFACE_CREATE, dhdp->up);
if (ret) {
WL_ERR(("failed to create ndp interface [%d]\n", ret));
goto fail;
}
nancfg->ndi[i].created = true;
}
}
#endif /* NAN_IFACE_CREATE_ON_UP */
/* Check if NDPE is capable and use_ndpe_attr is set by framework */
/* TODO: For now enabling NDPE by default as framework is not setting use_ndpe_attr
* When (cmd_data->use_ndpe_attr) is set by framework, Add additional check for
* (cmd_data->use_ndpe_attr) as below
* if (capabilities.ndpe_attr_supported && cmd_data->use_ndpe_attr)
*/
if (capabilities.ndpe_attr_supported)
{
cfg_ctrl2_flags1 |= WL_NAN_CTRL2_FLAG1_NDPE_CAP;
nancfg->ndpe_enabled = true;
} else {
/* reset NDPE capability in FW */
ret = wl_cfgnan_config_control_flag(ndev, cfg, WL_NAN_CTRL2_FLAG1_NDPE_CAP,
0, WL_NAN_CMD_CFG_NAN_CONFIG2,
&(cmd_data->status), false);
if (unlikely(ret) || unlikely(cmd_data->status)) {
WL_ERR((" nan ctrl2 config flags resetting failed, ret = %d status = %d \n",
ret, cmd_data->status));
goto fail;
}
nancfg->ndpe_enabled = false;
}
/* set CFG CTRL2 flags1 and flags2 */
ret = wl_cfgnan_config_control_flag(ndev, cfg, cfg_ctrl2_flags1,
0, WL_NAN_CMD_CFG_NAN_CONFIG2,
&(cmd_data->status), true);
if (unlikely(ret) || unlikely(cmd_data->status)) {
WL_ERR((" nan ctrl2 config flags setting failed, ret = %d status = %d \n",
ret, cmd_data->status));
goto fail;
}
#ifdef RTT_SUPPORT
/* Initialize geofence cfg */
dhd_rtt_initialize_geofence_cfg(cfg->pub);
#endif /* RTT_SUPPORT */
if (cmd_data->dw_early_termination > 0) {
WL_ERR(("dw early termination is not supported, ignoring for now\n"));
}
if (nan_attr_mask & NAN_ATTR_DISC_BEACON_INTERVAL) {
ret = wl_cfgnan_set_disc_beacon_interval_handler(ndev, cfg,
cmd_data->disc_bcn_interval);
if (unlikely(ret)) {
WL_ERR(("Failed to set beacon interval\n"));
goto fail;
}
}
nancfg->nan_enable = true;
WL_INFORM_MEM(("[NAN] Enable successfull \n"));
fail:
/* Enable back TDLS if connected interface is <= 1 */
wl_cfg80211_tdls_config(cfg, TDLS_STATE_IF_DELETE, false);
/* reset conditon variable */
nancfg->nan_event_recvd = false;
if (unlikely(ret) || unlikely(cmd_data->status)) {
nancfg->nan_enable = false;
mutex_lock(&cfg->if_sync);
ret = wl_cfg80211_delete_iface(cfg, WL_IF_TYPE_NAN);
if (ret != BCME_OK) {
WL_ERR(("failed to delete NDI[%d]\n", ret));
}
mutex_unlock(&cfg->if_sync);
if (nancfg->nan_ndp_peer_info) {
MFREE(cfg->osh, nancfg->nan_ndp_peer_info,
nancfg->max_ndp_count * sizeof(nan_ndp_peer_t));
nancfg->nan_ndp_peer_info = NULL;
}
if (nancfg->ndi) {
MFREE(cfg->osh, nancfg->ndi,
nancfg->max_ndi_supported * sizeof(*nancfg->ndi));
nancfg->ndi = NULL;
}
}
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
if (nan_iov_data) {
MFREE(cfg->osh, nan_iov_data, sizeof(*nan_iov_data));
}
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_disable(struct bcm_cfg80211 *cfg)
{
s32 ret = BCME_OK;
dhd_pub_t *dhdp = (dhd_pub_t *)(cfg->pub);
NAN_DBG_ENTER();
if ((cfg->nancfg->nan_init_state == TRUE) &&
(cfg->nancfg->nan_enable == TRUE)) {
struct net_device *ndev;
ndev = bcmcfg_to_prmry_ndev(cfg);
/* We have to remove NDIs so that P2P/Softap can work */
ret = wl_cfg80211_delete_iface(cfg, WL_IF_TYPE_NAN);
if (ret != BCME_OK) {
WL_ERR(("failed to delete NDI[%d]\n", ret));
}
ret = wl_cfgnan_stop_handler(ndev, cfg);
if (ret == -ENODEV) {
WL_ERR(("Bus is down, no need to proceed\n"));
} else if (ret != BCME_OK) {
WL_ERR(("failed to stop nan, error[%d]\n", ret));
}
ret = wl_cfgnan_deinit(cfg, dhdp->up);
if (ret != BCME_OK) {
WL_ERR(("failed to de-initialize NAN[%d]\n", ret));
if (!dhd_query_bus_erros(dhdp)) {
ASSERT(0);
}
}
wl_cfgnan_disable_cleanup(cfg);
}
NAN_DBG_EXIT();
return ret;
}
static void
wl_cfgnan_send_stop_event(struct bcm_cfg80211 *cfg)
{
s32 ret = BCME_OK;
nan_event_data_t *nan_event_data = NULL;
NAN_DBG_ENTER();
nan_event_data = MALLOCZ(cfg->osh, sizeof(nan_event_data_t));
if (!nan_event_data) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto exit;
}
bzero(nan_event_data, sizeof(nan_event_data_t));
nan_event_data->status = NAN_STATUS_SUCCESS;
ret = memcpy_s(nan_event_data->nan_reason, NAN_ERROR_STR_LEN,
"NAN_STATUS_SUCCESS", strlen("NAN_STATUS_SUCCESS"));
if (ret != BCME_OK) {
WL_ERR(("Failed to copy nan reason string, ret = %d\n", ret));
goto exit;
}
#if (LINUX_VERSION_CODE > KERNEL_VERSION(3, 13, 0)) || defined(WL_VENDOR_EXT_SUPPORT)
ret = wl_cfgvendor_send_nan_event(cfg->wdev->wiphy, bcmcfg_to_prmry_ndev(cfg),
GOOGLE_NAN_EVENT_DISABLED, nan_event_data);
if (ret != BCME_OK) {
WL_ERR(("Failed to send event to nan hal, (%d)\n",
GOOGLE_NAN_EVENT_DISABLED));
}
#endif /* (LINUX_VERSION_CODE > KERNEL_VERSION(3, 13, 0)) || defined(WL_VENDOR_EXT_SUPPORT) */
exit:
if (nan_event_data) {
MFREE(cfg->osh, nan_event_data, sizeof(nan_event_data_t));
}
NAN_DBG_EXIT();
return;
}
static void
wl_cfgnan_disable_cleanup(struct bcm_cfg80211 *cfg)
{
int i = 0;
wl_nancfg_t *nancfg = cfg->nancfg;
#ifdef RTT_SUPPORT
dhd_pub_t *dhdp = (dhd_pub_t *)(cfg->pub);
rtt_status_info_t *rtt_status = GET_RTTSTATE(dhdp);
rtt_target_info_t *target_info = NULL;
/* Delete the geofence rtt target list */
dhd_rtt_delete_geofence_target_list(dhdp);
/* Cancel pending retry timer if any */
if (delayed_work_pending(&rtt_status->rtt_retry_timer)) {
cancel_delayed_work_sync(&rtt_status->rtt_retry_timer);
}
/* Remove if any pending proxd timeout for nan-rtt */
target_info = &rtt_status->rtt_config.target_info[rtt_status->cur_idx];
if (target_info && target_info->peer == RTT_PEER_NAN) {
/* Cancel pending proxd timeout work if any */
if (delayed_work_pending(&rtt_status->proxd_timeout)) {
cancel_delayed_work_sync(&rtt_status->proxd_timeout);
}
}
/* Delete if any directed nan rtt session */
dhd_rtt_delete_nan_session(dhdp);
#endif /* RTT_SUPPORT */
/* Clear the NDP ID array and dp count */
for (i = 0; i < NAN_MAX_NDP_PEER; i++) {
nancfg->ndp_id[i] = 0;
}
nancfg->nan_dp_count = 0;
if (nancfg->nan_ndp_peer_info) {
MFREE(cfg->osh, nancfg->nan_ndp_peer_info,
nancfg->max_ndp_count * sizeof(nan_ndp_peer_t));
nancfg->nan_ndp_peer_info = NULL;
}
if (nancfg->ndi) {
MFREE(cfg->osh, nancfg->ndi,
nancfg->max_ndi_supported * sizeof(*nancfg->ndi));
nancfg->ndi = NULL;
}
wl_cfg80211_concurrent_roam(cfg, false);
return;
}
/*
* Deferred nan disable work,
* scheduled with NAN_DISABLE_CMD_DELAY
* delay in order to remove any active nan dps
*/
void
wl_cfgnan_delayed_disable(struct work_struct *work)
{
struct bcm_cfg80211 *cfg = NULL;
struct net_device *ndev = NULL;
wl_nancfg_t *nancfg = NULL;
BCM_SET_CONTAINER_OF(nancfg, work, wl_nancfg_t, nan_disable.work);
cfg = nancfg->cfg;
rtnl_lock();
if (nancfg->nan_enable == true) {
wl_cfgnan_disable(cfg);
ndev = bcmcfg_to_prmry_ndev(cfg);
wl_cfgvendor_nan_send_async_disable_resp(ndev->ieee80211_ptr);
} else {
WL_INFORM_MEM(("nan is in disabled state\n"));
}
rtnl_unlock();
DHD_NAN_WAKE_UNLOCK(cfg->pub);
return;
}
int
wl_cfgnan_stop_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
wl_nan_iov_t *nan_iov_data = NULL;
uint32 status;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
dhd_pub_t *dhdp = (dhd_pub_t *)(cfg->pub);
wl_nancfg_t *nancfg = cfg->nancfg;
NAN_DBG_ENTER();
NAN_MUTEX_LOCK();
if (!nancfg->nan_enable) {
WL_INFORM(("Nan is not enabled\n"));
ret = BCME_OK;
goto fail;
}
if (dhdp->up != DHD_BUS_DOWN) {
/*
* Framework doing cleanup(iface remove) on disable command,
* so avoiding event to prevent iface delete calls again
*/
WL_INFORM_MEM(("[NAN] Disabling Nan events\n"));
wl_cfgnan_config_eventmask(ndev, cfg, 0, true);
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data = MALLOCZ(cfg->osh, sizeof(*nan_iov_data));
if (!nan_iov_data) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data->nan_iov_len = NAN_IOCTL_BUF_SIZE;
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_iov_data->nan_iov_buf = (uint8 *)(&nan_buf->cmds[0]);
nan_iov_data->nan_iov_len -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
ret = wl_cfgnan_enable_handler(nan_iov_data, false);
if (unlikely(ret)) {
WL_ERR(("nan disable handler failed\n"));
goto fail;
}
nan_buf->count++;
nan_buf->is_set = true;
nan_buf_size -= nan_iov_data->nan_iov_len;
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("nan disable failed ret = %d status = %d\n", ret, status));
goto fail;
}
/* Enable back TDLS if connected interface is <= 1 */
wl_cfg80211_tdls_config(cfg, TDLS_STATE_IF_DELETE, false);
}
if (!nancfg->notify_user) {
wl_cfgnan_send_stop_event(cfg);
}
fail:
/* Resetting instance ID mask */
nancfg->inst_id_start = 0;
memset(nancfg->svc_inst_id_mask, 0, sizeof(nancfg->svc_inst_id_mask));
memset(nancfg->svc_info, 0, NAN_MAX_SVC_INST * sizeof(nan_svc_info_t));
nancfg->nan_enable = false;
WL_INFORM_MEM(("[NAN] Disable done\n"));
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
if (nan_iov_data) {
MFREE(cfg->osh, nan_iov_data, sizeof(*nan_iov_data));
}
NAN_MUTEX_UNLOCK();
NAN_DBG_EXIT();
return ret;
}
int
wl_cfgnan_config_handler(struct net_device *ndev, struct bcm_cfg80211 *cfg,
nan_config_cmd_data_t *cmd_data, uint32 nan_attr_mask)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
wl_nan_iov_t *nan_iov_data = NULL;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
NAN_DBG_ENTER();
/* Nan need to be enabled before configuring/updating params */
if (!cfg->nancfg->nan_enable) {
WL_INFORM(("nan is not enabled\n"));
ret = BCME_NOTENABLED;
goto fail;
}
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data = MALLOCZ(cfg->osh, sizeof(*nan_iov_data));
if (!nan_iov_data) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data->nan_iov_len = NAN_IOCTL_BUF_SIZE;
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_iov_data->nan_iov_buf = (uint8 *)(&nan_buf->cmds[0]);
nan_iov_data->nan_iov_len -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
/* setting sid beacon val */
if ((nan_attr_mask & NAN_ATTR_SID_BEACON_CONFIG) ||
(nan_attr_mask & NAN_ATTR_SUB_SID_BEACON_CONFIG)) {
ret = wl_cfgnan_set_sid_beacon_val(cmd_data, nan_iov_data, nan_attr_mask);
if (unlikely(ret)) {
WL_ERR(("sid_beacon sub_cmd set failed\n"));
goto fail;
}
nan_buf->count++;
}
/* setting master preference and random factor */
if (cmd_data->metrics.random_factor ||
cmd_data->metrics.master_pref) {
ret = wl_cfgnan_set_election_metric(cmd_data, nan_iov_data,
nan_attr_mask);
if (unlikely(ret)) {
WL_ERR(("election_metric sub_cmd set failed\n"));
goto fail;
} else {
nan_buf->count++;
}
}
/* setting hop count limit or threshold */
if (nan_attr_mask & NAN_ATTR_HOP_COUNT_LIMIT_CONFIG) {
ret = wl_cfgnan_set_hop_count_limit(cmd_data, nan_iov_data);
if (unlikely(ret)) {
WL_ERR(("hop_count_limit sub_cmd set failed\n"));
goto fail;
}
nan_buf->count++;
}
/* setting rssi proximaty values for 2.4GHz and 5GHz */
ret = wl_cfgnan_set_rssi_proximity(cmd_data, nan_iov_data,
nan_attr_mask);
if (unlikely(ret)) {
WL_ERR(("2.4GHz/5GHz rssi proximity threshold set failed\n"));
goto fail;
} else {
nan_buf->count++;
}
/* setting nan awake dws */
ret = wl_cfgnan_set_awake_dws(ndev, cmd_data, nan_iov_data,
cfg, nan_attr_mask);
if (unlikely(ret)) {
WL_ERR(("nan awake dws set failed\n"));
goto fail;
} else {
nan_buf->count++;
}
/* TODO: Add below code once use_ndpe_attr is being updated by framework
* If NDPE is enabled (cfg.nancfg.ndpe_enabled) and use_ndpe_attr is reset
* by framework, then disable NDPE using nan ctrl2 configuration setting.
* Else if NDPE is disabled and use_ndpe_attr is set by framework enable NDPE in FW
*/
if (cmd_data->disc_ind_cfg) {
/* Disable events */
WL_TRACE(("Disable events based on flag\n"));
ret = wl_cfgnan_config_eventmask(ndev, cfg,
cmd_data->disc_ind_cfg, false);
if (unlikely(ret)) {
WL_ERR(("Failed to config disc ind flag in event_mask, ret = %d\n",
ret));
goto fail;
}
}
if ((cfg->nancfg->support_5g) && ((cmd_data->dwell_time[1]) ||
(cmd_data->scan_period[1]))) {
/* setting scan params */
ret = wl_cfgnan_set_nan_scan_params(ndev, cfg,
cmd_data, cfg->nancfg->support_5g, nan_attr_mask);
if (unlikely(ret)) {
WL_ERR(("scan params set failed for 5g\n"));
goto fail;
}
}
if ((cmd_data->dwell_time[0]) ||
(cmd_data->scan_period[0])) {
ret = wl_cfgnan_set_nan_scan_params(ndev, cfg, cmd_data, 0, nan_attr_mask);
if (unlikely(ret)) {
WL_ERR(("scan params set failed for 2g\n"));
goto fail;
}
}
nan_buf->is_set = true;
nan_buf_size -= nan_iov_data->nan_iov_len;
if (nan_buf->count) {
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size,
&(cmd_data->status),
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(cmd_data->status)) {
WL_ERR((" nan config handler failed ret = %d status = %d\n",
ret, cmd_data->status));
goto fail;
}
} else {
WL_DBG(("No commands to send\n"));
}
if ((!cmd_data->bmap) || (cmd_data->avail_params.duration == NAN_BAND_INVALID) ||
(!cmd_data->chanspec[0])) {
WL_TRACE(("mandatory arguments are not present to set avail\n"));
ret = BCME_OK;
} else {
cmd_data->avail_params.chanspec[0] = cmd_data->chanspec[0];
cmd_data->avail_params.bmap = cmd_data->bmap;
/* 1=local, 2=peer, 3=ndc, 4=immutable, 5=response, 6=counter */
ret = wl_cfgnan_set_nan_avail(bcmcfg_to_prmry_ndev(cfg),
cfg, &cmd_data->avail_params, WL_AVAIL_LOCAL);
if (unlikely(ret)) {
WL_ERR(("Failed to set avail value with type local\n"));
goto fail;
}
ret = wl_cfgnan_set_nan_avail(bcmcfg_to_prmry_ndev(cfg),
cfg, &cmd_data->avail_params, WL_AVAIL_NDC);
if (unlikely(ret)) {
WL_ERR(("Failed to set avail value with type ndc\n"));
goto fail;
}
}
if (cmd_data->nmi_rand_intvl > 0) {
#ifdef WL_NAN_ENABLE_MERGE
/* Cluster merge enable/disable are being set using nmi random interval config param
* If MSB(31st bit) is set that indicates cluster merge enable/disable config is set
* MSB 30th bit indicates cluser merge enable/disable value to set in firmware
*/
if (cmd_data->nmi_rand_intvl & NAN_NMI_RAND_PVT_CMD_VENDOR) {
uint8 merge_enable;
uint8 lwt_mode_enable;
int status = BCME_OK;
merge_enable = !!(cmd_data->nmi_rand_intvl &
NAN_NMI_RAND_CLUSTER_MERGE_ENAB);
ret = wl_cfgnan_set_enable_merge(bcmcfg_to_prmry_ndev(cfg), cfg,
merge_enable, &status);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("Enable merge: failed to set config request [%d]\n", ret));
/* As there is no cmd_reply, check if error is in status or ret */
if (status) {
ret = status;
}
goto fail;
}
lwt_mode_enable = !!(cmd_data->nmi_rand_intvl &
NAN_NMI_RAND_AUTODAM_LWT_MODE_ENAB);
/* set CFG CTRL2 flags1 and flags2 */
ret = wl_cfgnan_config_control_flag(ndev, cfg,
WL_NAN_CTRL2_FLAG1_AUTODAM_LWT_MODE,
0, WL_NAN_CMD_CFG_NAN_CONFIG2,
&status, lwt_mode_enable);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("Enable dam lwt mode: "
"failed to set config request [%d]\n", ret));
/* As there is no cmd_reply, check if error is in status or ret */
if (status) {
ret = status;
}
goto fail;
}
/* reset pvt merge enable bits */
cmd_data->nmi_rand_intvl &= ~(NAN_NMI_RAND_PVT_CMD_VENDOR |
NAN_NMI_RAND_CLUSTER_MERGE_ENAB |
NAN_NMI_RAND_AUTODAM_LWT_MODE_ENAB);
}
#endif /* WL_NAN_ENABLE_MERGE */
if (cmd_data->nmi_rand_intvl) {
/* run time nmi rand not supported as of now.
* Only during nan enable/iface-create rand mac is used
*/
WL_ERR(("run time nmi rand not supported, ignoring for now\n"));
}
}
if (cmd_data->dw_early_termination > 0) {
WL_ERR(("dw early termination is not supported, ignoring for now\n"));
}
if (nan_attr_mask & NAN_ATTR_DISC_BEACON_INTERVAL) {
ret = wl_cfgnan_set_disc_beacon_interval_handler(ndev, cfg,
cmd_data->disc_bcn_interval);
if (unlikely(ret)) {
WL_ERR(("Failed to set beacon interval\n"));
goto fail;
}
}
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
if (nan_iov_data) {
MFREE(cfg->osh, nan_iov_data, sizeof(*nan_iov_data));
}
NAN_DBG_EXIT();
return ret;
}
int
wl_cfgnan_support_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg, nan_config_cmd_data_t *cmd_data)
{
/* TODO: */
return BCME_OK;
}
int
wl_cfgnan_status_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg, nan_config_cmd_data_t *cmd_data)
{
/* TODO: */
return BCME_OK;
}
#ifdef WL_NAN_DISC_CACHE
static
nan_svc_info_t *
wl_cfgnan_get_svc_inst(struct bcm_cfg80211 *cfg,
wl_nan_instance_id svc_inst_id, uint8 ndp_id)
{
uint8 i, j;
wl_nancfg_t *nancfg = cfg->nancfg;
if (ndp_id) {
for (i = 0; i < NAN_MAX_SVC_INST; i++) {
for (j = 0; j < NAN_MAX_SVC_INST; j++) {
if (nancfg->svc_info[i].ndp_id[j] == ndp_id) {
return &nancfg->svc_info[i];
}
}
}
} else if (svc_inst_id) {
for (i = 0; i < NAN_MAX_SVC_INST; i++) {
if (nancfg->svc_info[i].svc_id == svc_inst_id) {
return &nancfg->svc_info[i];
}
}
}
return NULL;
}
static int
wl_cfgnan_svc_inst_add_ndp(struct bcm_cfg80211 *cfg,
wl_nan_instance_id svc_inst_id, uint8 ndp_id)
{
int ret = BCME_OK, i;
nan_svc_info_t *svc_info;
svc_info = wl_cfgnan_get_svc_inst(cfg, svc_inst_id, 0);
if (svc_info) {
for (i = 0; i < NAN_MAX_SVC_INST; i++) {
if (!svc_info->ndp_id[i]) {
WL_TRACE(("Found empty field\n"));
break;
}
}
if (i == NAN_MAX_SVC_INST) {
WL_ERR(("%s:cannot accommadate ndp id\n", __FUNCTION__));
ret = BCME_NORESOURCE;
goto done;
}
svc_info->ndp_id[i] = ndp_id;
}
done:
return ret;
}
static int
wl_cfgnan_svc_inst_del_ndp(struct bcm_cfg80211 *cfg,
wl_nan_instance_id svc_inst_id, uint8 ndp_id)
{
int ret = BCME_OK, i;
nan_svc_info_t *svc_info;
svc_info = wl_cfgnan_get_svc_inst(cfg, svc_inst_id, 0);
if (svc_info) {
for (i = 0; i < NAN_MAX_SVC_INST; i++) {
if (svc_info->ndp_id[i] == ndp_id) {
svc_info->ndp_id[i] = 0;
break;
}
}
if (i == NAN_MAX_SVC_INST) {
WL_ERR(("couldn't find entry for ndp id = %d\n", ndp_id));
ret = BCME_NOTFOUND;
}
}
return ret;
}
nan_ranging_inst_t *
wl_cfgnan_check_for_ranging(struct bcm_cfg80211 *cfg, struct ether_addr *peer)
{
uint8 i;
if (peer) {
for (i = 0; i < NAN_MAX_RANGING_INST; i++) {
if (!memcmp(peer, &cfg->nancfg->nan_ranging_info[i].peer_addr,
ETHER_ADDR_LEN)) {
return &(cfg->nancfg->nan_ranging_info[i]);
}
}
}
return NULL;
}
nan_ranging_inst_t *
wl_cfgnan_get_rng_inst_by_id(struct bcm_cfg80211 *cfg, uint8 rng_id)
{
uint8 i;
if (rng_id) {
for (i = 0; i < NAN_MAX_RANGING_INST; i++) {
if (cfg->nancfg->nan_ranging_info[i].range_id == rng_id)
{
return &(cfg->nancfg->nan_ranging_info[i]);
}
}
}
WL_ERR(("Couldn't find the ranging instance for rng_id %d\n", rng_id));
return NULL;
}
/*
* Find ranging inst for given peer,
* On not found, create one
* with given range role
*/
nan_ranging_inst_t *
wl_cfgnan_get_ranging_inst(struct bcm_cfg80211 *cfg, struct ether_addr *peer,
nan_range_role_t range_role)
{
nan_ranging_inst_t *ranging_inst = NULL;
uint8 i;
if (!peer) {
WL_ERR(("Peer address is NULL"));
goto done;
}
ranging_inst = wl_cfgnan_check_for_ranging(cfg, peer);
if (ranging_inst) {
goto done;
}
WL_TRACE(("Creating Ranging instance \n"));
for (i = 0; i < NAN_MAX_RANGING_INST; i++) {
if (cfg->nancfg->nan_ranging_info[i].in_use == FALSE) {
break;
}
}
if (i == NAN_MAX_RANGING_INST) {
WL_ERR(("No buffer available for the ranging instance"));
goto done;
}
ranging_inst = &cfg->nancfg->nan_ranging_info[i];
memcpy(&ranging_inst->peer_addr, peer, ETHER_ADDR_LEN);
ranging_inst->range_status = NAN_RANGING_REQUIRED;
ranging_inst->prev_distance_mm = INVALID_DISTANCE;
ranging_inst->range_role = range_role;
ranging_inst->in_use = TRUE;
done:
return ranging_inst;
}
#endif /* WL_NAN_DISC_CACHE */
static int
process_resp_buf(void *iov_resp,
uint8 *instance_id, uint16 sub_cmd_id)
{
int res = BCME_OK;
NAN_DBG_ENTER();
if (sub_cmd_id == WL_NAN_CMD_DATA_DATAREQ) {
wl_nan_dp_req_ret_t *dpreq_ret = NULL;
dpreq_ret = (wl_nan_dp_req_ret_t *)(iov_resp);
*instance_id = dpreq_ret->ndp_id;
WL_TRACE(("%s: Initiator NDI: " MACDBG "\n",
__FUNCTION__, MAC2STRDBG(dpreq_ret->indi.octet)));
} else if (sub_cmd_id == WL_NAN_CMD_RANGE_REQUEST) {
wl_nan_range_id *range_id = NULL;
range_id = (wl_nan_range_id *)(iov_resp);
*instance_id = *range_id;
WL_TRACE(("Range id: %d\n", *range_id));
}
WL_DBG(("instance_id: %d\n", *instance_id));
NAN_DBG_EXIT();
return res;
}
int
wl_cfgnan_cancel_ranging(struct net_device *ndev,
struct bcm_cfg80211 *cfg, uint8 *range_id, uint8 flags, uint32 *status)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
s32 ret = BCME_OK;
uint16 nan_iov_start, nan_iov_end;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
uint16 subcmd_len;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
wl_nan_iov_t *nan_iov_data = NULL;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
wl_nan_range_cancel_ext_t rng_cncl;
uint8 size_of_iov;
NAN_DBG_ENTER();
if (*range_id == 0) {
WL_ERR(("Invalid Range ID\n"));
ret = BCME_BADARG;
goto fail;
}
if (cfg->nancfg->version >= NAN_RANGE_EXT_CANCEL_SUPPORT_VER) {
size_of_iov = sizeof(rng_cncl);
} else {
size_of_iov = sizeof(*range_id);
}
bzero(&rng_cncl, sizeof(rng_cncl));
rng_cncl.range_id = *range_id;
rng_cncl.flags = flags;
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data = MALLOCZ(cfg->osh, sizeof(*nan_iov_data));
if (!nan_iov_data) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_iov_data->nan_iov_len = nan_iov_start = NAN_IOCTL_BUF_SIZE;
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_iov_data->nan_iov_buf = (uint8 *)(&nan_buf->cmds[0]);
nan_iov_data->nan_iov_len -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(nan_iov_data->nan_iov_buf);
ret = wl_cfg_nan_check_cmd_len(nan_iov_data->nan_iov_len,
size_of_iov, &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
sub_cmd->id = htod16(WL_NAN_CMD_RANGE_CANCEL);
sub_cmd->len = sizeof(sub_cmd->u.options) + size_of_iov;
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
/* Reduce the iov_len size by subcmd_len */
nan_iov_data->nan_iov_len -= subcmd_len;
nan_iov_end = nan_iov_data->nan_iov_len;
nan_buf_size = (nan_iov_start - nan_iov_end);
if (size_of_iov >= sizeof(rng_cncl)) {
(void)memcpy_s(sub_cmd->data, nan_iov_data->nan_iov_len,
&rng_cncl, size_of_iov);
} else {
(void)memcpy_s(sub_cmd->data, nan_iov_data->nan_iov_len,
range_id, size_of_iov);
}
nan_buf->is_set = true;
nan_buf->count++;
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size, status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(*status)) {
WL_ERR(("Range ID %d cancel failed ret %d status %d \n", *range_id, ret, *status));
goto fail;
}
WL_MEM(("Range cancel with Range ID [%d] successfull\n", *range_id));
/* Resetting range id */
*range_id = 0;
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
if (nan_iov_data) {
MFREE(cfg->osh, nan_iov_data, sizeof(*nan_iov_data));
}
NAN_DBG_EXIT();
return ret;
}
#ifdef WL_NAN_DISC_CACHE
static void
wl_cfgnan_clear_svc_cache(struct bcm_cfg80211 *cfg,
wl_nan_instance_id svc_id)
{
nan_svc_info_t *svc;
svc = wl_cfgnan_get_svc_inst(cfg, svc_id, 0);
if (svc) {
WL_DBG(("clearing cached svc info for svc id %d\n", svc_id));
memset(svc, 0, sizeof(*svc));
}
}
static int
wl_cfgnan_cache_svc_info(struct bcm_cfg80211 *cfg,
nan_discover_cmd_data_t *cmd_data, uint16 cmd_id, bool update)
{
int ret = BCME_OK;
int i;
nan_svc_info_t *svc_info;
uint8 svc_id = (cmd_id == WL_NAN_CMD_SD_SUBSCRIBE) ? cmd_data->sub_id :
cmd_data->pub_id;
wl_nancfg_t *nancfg = cfg->nancfg;
for (i = 0; i < NAN_MAX_SVC_INST; i++) {
if (update) {
if (nancfg->svc_info[i].svc_id == svc_id) {
svc_info = &nancfg->svc_info[i];
break;
} else {
continue;
}
}
if (!nancfg->svc_info[i].svc_id) {
svc_info = &nancfg->svc_info[i];
break;
}
}
if (i == NAN_MAX_SVC_INST) {
WL_ERR(("%s:cannot accomodate ranging session\n", __FUNCTION__));
ret = BCME_NORESOURCE;
goto fail;
}
if (cmd_data->sde_control_flag & NAN_SDE_CF_RANGING_REQUIRED) {
WL_TRACE(("%s: updating ranging info, enabling", __FUNCTION__));
svc_info->status = 1;
svc_info->ranging_interval = cmd_data->ranging_intvl_msec;
svc_info->ranging_ind = cmd_data->ranging_indication;
svc_info->ingress_limit = cmd_data->ingress_limit;
svc_info->egress_limit = cmd_data->egress_limit;
svc_info->ranging_required = 1;
} else {
WL_TRACE(("%s: updating ranging info, disabling", __FUNCTION__));
svc_info->status = 0;
svc_info->ranging_interval = 0;
svc_info->ranging_ind = 0;
svc_info->ingress_limit = 0;
svc_info->egress_limit = 0;
svc_info->ranging_required = 0;
}
/* Reset Range status flags on svc creation/update */
svc_info->svc_range_status = 0;
svc_info->flags = cmd_data->flags;
if (cmd_id == WL_NAN_CMD_SD_SUBSCRIBE) {
svc_info->svc_id = cmd_data->sub_id;
if ((cmd_data->flags & WL_NAN_SUB_ACTIVE) &&
(cmd_data->tx_match.dlen)) {
ret = memcpy_s(svc_info->tx_match_filter, sizeof(svc_info->tx_match_filter),
cmd_data->tx_match.data, cmd_data->tx_match.dlen);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy tx match filter data\n"));
goto fail;
}
svc_info->tx_match_filter_len = cmd_data->tx_match.dlen;
}
} else {
svc_info->svc_id = cmd_data->pub_id;
}
ret = memcpy_s(svc_info->svc_hash, sizeof(svc_info->svc_hash),
cmd_data->svc_hash.data, WL_NAN_SVC_HASH_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy svc hash\n"));
}
fail:
return ret;
}
#ifdef RTT_SUPPORT
/*
* Reset for Initiator
* Remove for Responder if no pending
* geofence target or else reset
*/
static void
wl_cfgnan_reset_remove_ranging_instance(struct bcm_cfg80211 *cfg,
nan_ranging_inst_t *ranging_inst)
{
dhd_pub_t *dhd = (struct dhd_pub *)(cfg->pub);
int8 index;
rtt_geofence_target_info_t* geofence_target;
ASSERT(ranging_inst);
if (!ranging_inst) {
return;
}
if ((ranging_inst->range_role == NAN_RANGING_ROLE_RESPONDER) ||
(ranging_inst->range_type == RTT_TYPE_NAN_DIRECTED)) {
/* Remove ranging instance for responder */
geofence_target = dhd_rtt_get_geofence_target(dhd,
&ranging_inst->peer_addr, &index);
if (!geofence_target) {
/* Remove rng inst if no pend target */
WL_INFORM_MEM(("Removing Ranging Instance "
"peer: " MACDBG "\n",
MAC2STRDBG(&ranging_inst->peer_addr)));
bzero(ranging_inst, sizeof(*ranging_inst));
} else {
ranging_inst->range_status = NAN_RANGING_REQUIRED;
/* resolve range role concurrency */
WL_INFORM_MEM(("Resolving Role Concurrency constraint, peer : "
MACDBG "\n", MAC2STRDBG(&ranging_inst->peer_addr)));
ranging_inst->role_concurrency_status = FALSE;
}
} else {
/* For geofence Initiator */
ranging_inst->range_status = NAN_RANGING_REQUIRED;
}
}
/*
* Forcecully Remove Ranging instance
* Remove if any corresponding Geofence Target
*/
static void
wl_cfgnan_remove_ranging_instance(struct bcm_cfg80211 *cfg,
nan_ranging_inst_t *ranging_inst)
{
dhd_pub_t *dhd = (struct dhd_pub *)(cfg->pub);
int8 index;
rtt_geofence_target_info_t* geofence_target;
ASSERT(ranging_inst);
if (!ranging_inst) {
return;
}
geofence_target = dhd_rtt_get_geofence_target(dhd,
&ranging_inst->peer_addr, &index);
if (geofence_target) {
dhd_rtt_remove_geofence_target(dhd,
&geofence_target->peer_addr);
}
WL_INFORM_MEM(("Removing Ranging Instance " MACDBG "\n",
MAC2STRDBG(&(ranging_inst->peer_addr))));
bzero(ranging_inst, sizeof(nan_ranging_inst_t));
return;
}
static bool
wl_cfgnan_clear_svc_from_ranging_inst(struct bcm_cfg80211 *cfg,
nan_ranging_inst_t *ranging_inst, nan_svc_info_t *svc)
{
int i = 0;
bool cleared = FALSE;
if (svc && ranging_inst->in_use) {
for (i = 0; i < MAX_SUBSCRIBES; i++) {
if (svc == ranging_inst->svc_idx[i]) {
ranging_inst->num_svc_ctx--;
ranging_inst->svc_idx[i] = NULL;
cleared = TRUE;
/*
* This list is maintained dupes free,
* hence can break
*/
break;
}
}
}
return cleared;
}
static int
wl_cfgnan_clear_svc_from_all_ranging_inst(struct bcm_cfg80211 *cfg, uint8 svc_id)
{
nan_ranging_inst_t *ranging_inst;
int i = 0;
int ret = BCME_OK;
nan_svc_info_t *svc = wl_cfgnan_get_svc_inst(cfg, svc_id, 0);
if (!svc) {
WL_ERR(("\n svc not found \n"));
ret = BCME_NOTFOUND;
goto done;
}
for (i = 0; i < NAN_MAX_RANGING_INST; i++) {
ranging_inst = &(cfg->nancfg->nan_ranging_info[i]);
wl_cfgnan_clear_svc_from_ranging_inst(cfg, ranging_inst, svc);
}
done:
return ret;
}
static int
wl_cfgnan_ranging_clear_publish(struct bcm_cfg80211 *cfg,
struct ether_addr *peer, uint8 svc_id)
{
nan_ranging_inst_t *ranging_inst = NULL;
nan_svc_info_t *svc = NULL;
bool cleared = FALSE;
int ret = BCME_OK;
ranging_inst = wl_cfgnan_check_for_ranging(cfg, peer);
if (!ranging_inst || !ranging_inst->in_use) {
goto done;
}
WL_INFORM_MEM(("Check clear Ranging for pub update, sub id = %d,"
" range_id = %d, peer addr = " MACDBG " \n", svc_id,
ranging_inst->range_id, MAC2STRDBG(peer)));
svc = wl_cfgnan_get_svc_inst(cfg, svc_id, 0);
if (!svc) {
WL_ERR(("\n svc not found, svc_id = %d\n", svc_id));
ret = BCME_NOTFOUND;
goto done;
}
cleared = wl_cfgnan_clear_svc_from_ranging_inst(cfg, ranging_inst, svc);
if (!cleared) {
/* Only if this svc was cleared, any update needed */
ret = BCME_NOTFOUND;
goto done;
}
wl_cfgnan_terminate_ranging_session(cfg, ranging_inst);
wl_cfgnan_reset_geofence_ranging(cfg, NULL,
RTT_SCHED_RNG_TERM_PUB_RNG_CLEAR, TRUE);
done:
return ret;
}
/* API to terminate/clear all directed nan-rtt sessions.
* Can be called from framework RTT stop context
*/
int
wl_cfgnan_terminate_directed_rtt_sessions(struct net_device *ndev,
struct bcm_cfg80211 *cfg)
{
nan_ranging_inst_t *ranging_inst;
int i, ret = BCME_OK;
uint32 status;
for (i = 0; i < NAN_MAX_RANGING_INST; i++) {
ranging_inst = &cfg->nancfg->nan_ranging_info[i];
if (ranging_inst->range_id && ranging_inst->range_type == RTT_TYPE_NAN_DIRECTED) {
if (NAN_RANGING_IS_IN_PROG(ranging_inst->range_status)) {
ret = wl_cfgnan_cancel_ranging(ndev, cfg, &ranging_inst->range_id,
NAN_RNG_TERM_FLAG_IMMEDIATE, &status);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("nan range cancel failed ret = %d status = %d\n",
ret, status));
}
}
wl_cfgnan_reset_geofence_ranging(cfg, ranging_inst,
RTT_SHCED_HOST_DIRECTED_TERM, FALSE);
}
}
return ret;
}
/*
* suspend ongoing geofence ranging session
* with a peer if on-going ranging is with given peer
* If peer NULL,
* Suspend all on-going ranging sessions blindly
* Do nothing on:
* If ranging is not in progress
* If ranging in progress but not with given peer
*/
int
wl_cfgnan_suspend_geofence_rng_session(struct net_device *ndev,
struct ether_addr *peer, int suspend_reason, u8 cancel_flags)
{
int ret = BCME_OK;
uint32 status;
nan_ranging_inst_t *ranging_inst = NULL;
struct bcm_cfg80211 *cfg = wl_get_cfg(ndev);
int suspend_req_dropped_at = 0;
dhd_pub_t *dhd = (struct dhd_pub *)(cfg->pub);
UNUSED_PARAMETER(suspend_req_dropped_at);
ASSERT(peer);
if (!peer) {
WL_DBG(("Incoming Peer is NULL, suspend req dropped\n"));
suspend_req_dropped_at = 1;
goto exit;
}
if (!wl_ranging_geofence_session_with_peer(cfg, peer)) {
WL_DBG(("Geofence Ranging not in progress with given peer,"
" suspend req dropped\n"));
suspend_req_dropped_at = 2;
goto exit;
}
ranging_inst = wl_cfgnan_check_for_ranging(cfg, peer);
if (ranging_inst) {
cancel_flags |= NAN_RNG_TERM_FLAG_IMMEDIATE;
ret = wl_cfgnan_cancel_ranging(ndev, cfg,
&ranging_inst->range_id, cancel_flags, &status);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("Geofence Range suspended failed, err = %d, status = %d,"
"suspend_reason = %d, peer: " MACDBG " \n",
ret, status, suspend_reason, MAC2STRDBG(peer)));
}
ranging_inst->range_status = NAN_RANGING_REQUIRED;
dhd_rtt_update_geofence_sessions_cnt(dhd, FALSE,
&ranging_inst->peer_addr);
if (ranging_inst->range_role == NAN_RANGING_ROLE_RESPONDER &&
ranging_inst->role_concurrency_status) {
/* resolve range role concurrency */
WL_INFORM_MEM(("Resolving Role Concurrency constraint, peer : "
MACDBG "\n", MAC2STRDBG(&ranging_inst->peer_addr)));
ranging_inst->role_concurrency_status = FALSE;
}
WL_INFORM_MEM(("Geofence Range suspended, "
" suspend_reason = %d, peer: " MACDBG " \n",
suspend_reason, MAC2STRDBG(peer)));
}
exit:
/* Post pending discovery results */
if (ranging_inst &&
((suspend_reason == RTT_GEO_SUSPN_HOST_NDP_TRIGGER) ||
(suspend_reason == RTT_GEO_SUSPN_PEER_NDP_TRIGGER))) {
wl_cfgnan_disc_result_on_geofence_cancel(cfg, ranging_inst);
}
if (suspend_req_dropped_at) {
if (ranging_inst) {
WL_INFORM_MEM(("Ranging Suspend Req with peer: " MACDBG
", dropped at = %d\n", MAC2STRDBG(&ranging_inst->peer_addr),
suspend_req_dropped_at));
} else {
WL_INFORM_MEM(("Ranging Suspend Req dropped at = %d\n",
suspend_req_dropped_at));
}
}
return ret;
}
/*
* suspends all geofence ranging sessions
* including initiators and responders
*/
void
wl_cfgnan_suspend_all_geofence_rng_sessions(struct net_device *ndev,
int suspend_reason, u8 cancel_flags)
{
uint8 i = 0;
int ret = BCME_OK;
uint32 status;
nan_ranging_inst_t *ranging_inst = NULL;
struct bcm_cfg80211 *cfg = wl_get_cfg(ndev);
dhd_pub_t *dhd = (struct dhd_pub *)(cfg->pub);
WL_INFORM_MEM(("Suspending all geofence sessions: "
"suspend_reason = %d\n", suspend_reason));
cancel_flags |= NAN_RNG_TERM_FLAG_IMMEDIATE;
for (i = 0; i < NAN_MAX_RANGING_INST; i++) {
ranging_inst = &cfg->nancfg->nan_ranging_info[i];
/* Cancel Ranging if in progress for rang_inst */
if (ranging_inst->in_use &&
NAN_RANGING_IS_IN_PROG(ranging_inst->range_status)) {
ret = wl_cfgnan_cancel_ranging(bcmcfg_to_prmry_ndev(cfg),
cfg, &ranging_inst->range_id,
NAN_RNG_TERM_FLAG_IMMEDIATE, &status);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("wl_cfgnan_suspend_all_geofence_rng_sessions: "
"nan range cancel failed ret = %d status = %d\n",
ret, status));
} else {
dhd_rtt_update_geofence_sessions_cnt(dhd, FALSE,
&ranging_inst->peer_addr);
wl_cfgnan_reset_remove_ranging_instance(cfg, ranging_inst);
}
}
}
return;
}
/*
* Terminate given ranging instance
* if no pending ranging sub service
*/
static void
wl_cfgnan_terminate_ranging_session(struct bcm_cfg80211 *cfg,
nan_ranging_inst_t *ranging_inst)
{
int ret = BCME_OK;
uint32 status;
dhd_pub_t *dhd = (struct dhd_pub *)(cfg->pub);
if (ranging_inst->num_svc_ctx != 0) {
/*
* Make sure to remove all svc_insts for range_inst
* in order to cancel ranging and remove target in caller
*/
return;
}
/* Cancel Ranging if in progress for rang_inst */
if (NAN_RANGING_IS_IN_PROG(ranging_inst->range_status)) {
ret = wl_cfgnan_cancel_ranging(bcmcfg_to_prmry_ndev(cfg),
cfg, &ranging_inst->range_id,
NAN_RNG_TERM_FLAG_IMMEDIATE, &status);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("%s:nan range cancel failed ret = %d status = %d\n",
__FUNCTION__, ret, status));
} else {
WL_DBG(("Range cancelled \n"));
dhd_rtt_update_geofence_sessions_cnt(dhd, FALSE,
&ranging_inst->peer_addr);
}
}
/* Remove ranging instance and clean any corresponding target */
wl_cfgnan_remove_ranging_instance(cfg, ranging_inst);
}
/*
* Terminate all ranging sessions
* with no pending ranging sub service
*/
static void
wl_cfgnan_terminate_all_obsolete_ranging_sessions(
struct bcm_cfg80211 *cfg)
{
/* cancel all related ranging instances */
uint8 i = 0;
nan_ranging_inst_t *ranging_inst = NULL;
for (i = 0; i < NAN_MAX_RANGING_INST; i++) {
ranging_inst = &cfg->nancfg->nan_ranging_info[i];
if (ranging_inst->in_use) {
wl_cfgnan_terminate_ranging_session(cfg, ranging_inst);
}
}
return;
}
/*
* Store svc_ctx for processing during RNG_RPT
* Return BCME_OK only when svc is added
*/
static int
wl_cfgnan_update_ranging_svc_inst(nan_ranging_inst_t *ranging_inst,
nan_svc_info_t *svc)
{
int ret = BCME_OK;
int i = 0;
for (i = 0; i < MAX_SUBSCRIBES; i++) {
if (ranging_inst->svc_idx[i] == svc) {
WL_DBG(("SVC Ctx for ranging already present, "
" Duplication not supported: sub_id: %d\n", svc->svc_id));
ret = BCME_UNSUPPORTED;
goto done;
}
}
for (i = 0; i < MAX_SUBSCRIBES; i++) {
if (ranging_inst->svc_idx[i]) {
continue;
} else {
WL_DBG(("Adding SVC Ctx for ranging..svc_id %d\n", svc->svc_id));
ranging_inst->svc_idx[i] = svc;
ranging_inst->num_svc_ctx++;
ret = BCME_OK;
goto done;
}
}
if (i == MAX_SUBSCRIBES) {
WL_ERR(("wl_cfgnan_update_ranging_svc_inst: "
"No resource to hold Ref SVC ctx..svc_id %d\n", svc->svc_id));
ret = BCME_NORESOURCE;
goto done;
}
done:
return ret;
}
bool
wl_ranging_geofence_session_with_peer(struct bcm_cfg80211 *cfg,
struct ether_addr *peer_addr)
{
bool ret = FALSE;
nan_ranging_inst_t *rng_inst = NULL;
rng_inst = wl_cfgnan_check_for_ranging(cfg,
peer_addr);
if (rng_inst &&
(NAN_RANGING_IS_IN_PROG(rng_inst->range_status))) {
ret = TRUE;
}
return ret;
}
int
wl_cfgnan_trigger_geofencing_ranging(struct net_device *dev,
struct ether_addr *peer_addr)
{
int ret = BCME_OK;
int err_at = 0;
struct bcm_cfg80211 *cfg = wl_get_cfg(dev);
dhd_pub_t *dhd = (struct dhd_pub *)(cfg->pub);
nan_ranging_inst_t *ranging_inst;
ranging_inst = wl_cfgnan_check_for_ranging(cfg, peer_addr);
if (!ranging_inst) {
WL_INFORM_MEM(("Ranging Entry for peer:" MACDBG ", not found\n",
MAC2STRDBG(peer_addr)));
ASSERT(0);
/* Ranging inst should have been added before adding target */
dhd_rtt_remove_geofence_target(dhd, peer_addr);
ret = BCME_ERROR;
err_at = 1;
goto exit;
}
if (!NAN_RANGING_IS_IN_PROG(ranging_inst->range_status)) {
WL_DBG(("Trigger range request with first svc in svc list of range inst\n"));
ret = wl_cfgnan_trigger_ranging(bcmcfg_to_prmry_ndev(cfg),
cfg, ranging_inst, ranging_inst->svc_idx[0],
NAN_RANGE_REQ_CMD, TRUE);
if (ret != BCME_OK) {
/* Unsupported is for already ranging session for peer */
if (ret == BCME_BUSY) {
/* TODO: Attempt again over a timer */
err_at = 2;
} else {
/* Remove target and clean ranging inst */
wl_cfgnan_remove_ranging_instance(cfg, ranging_inst);
err_at = 3;
goto exit;
}
} else {
ranging_inst->range_type = RTT_TYPE_NAN_GEOFENCE;
ranging_inst->range_role = NAN_RANGING_ROLE_INITIATOR;
}
} else if (ranging_inst->range_role != NAN_RANGING_ROLE_RESPONDER) {
/* already in progress but not as responder.. This should not happen */
ASSERT(!NAN_RANGING_IS_IN_PROG(ranging_inst->range_status));
ret = BCME_ERROR;
err_at = 4;
goto exit;
} else {
/* Already in progress as responder, bail out */
goto exit;
}
exit:
if (ret) {
WL_ERR(("wl_cfgnan_trigger_geofencing_ranging: Failed to "
"trigger ranging, peer: " MACDBG " ret"
" = (%d), err_at = %d\n", MAC2STRDBG(peer_addr),
ret, err_at));
}
return ret;
}
static int
wl_cfgnan_check_disc_result_for_ranging(struct bcm_cfg80211 *cfg,
nan_event_data_t* nan_event_data, bool *send_disc_result)
{
nan_svc_info_t *svc;
int ret = BCME_OK;
rtt_geofence_target_info_t geofence_target;
dhd_pub_t *dhd = (struct dhd_pub *)(cfg->pub);
uint8 index, rtt_invalid_reason = RTT_STATE_VALID;
bool add_target;
*send_disc_result = TRUE;
svc = wl_cfgnan_get_svc_inst(cfg, nan_event_data->sub_id, 0);
if (svc && svc->ranging_required) {
nan_ranging_inst_t *ranging_inst;
ranging_inst = wl_cfgnan_get_ranging_inst(cfg,
&nan_event_data->remote_nmi,
NAN_RANGING_ROLE_INITIATOR);
if (!ranging_inst) {
ret = BCME_NORESOURCE;
goto exit;
}
ASSERT(ranging_inst->range_role != NAN_RANGING_ROLE_INVALID);
/* For responder role, range state should be in progress only */
ASSERT((ranging_inst->range_role == NAN_RANGING_ROLE_INITIATOR) ||
NAN_RANGING_IS_IN_PROG(ranging_inst->range_status));
/*
* On rec disc result with ranging required, add target, if
* ranging role is responder (range state has to be in prog always)
* Or ranging role is initiator and ranging is not already in prog
*/
add_target = ((ranging_inst->range_role == NAN_RANGING_ROLE_RESPONDER) ||
((ranging_inst->range_role == NAN_RANGING_ROLE_INITIATOR) &&
(!NAN_RANGING_IS_IN_PROG(ranging_inst->range_status))));
if (add_target) {
WL_DBG(("Add Range request to geofence target list\n"));
memcpy(&geofence_target.peer_addr, &nan_event_data->remote_nmi,
ETHER_ADDR_LEN);
/* check if target is already added */
if (!dhd_rtt_get_geofence_target(dhd, &nan_event_data->remote_nmi, &index))
{
ret = dhd_rtt_add_geofence_target(dhd, &geofence_target);
if (unlikely(ret)) {
WL_ERR(("Failed to add geofence Tgt, ret = (%d)\n", ret));
bzero(ranging_inst, sizeof(*ranging_inst));
goto exit;
} else {
WL_INFORM_MEM(("Geofence Tgt Added:" MACDBG " sub_id:%d\n",
MAC2STRDBG(&geofence_target.peer_addr),
svc->svc_id));
}
}
if (wl_cfgnan_update_ranging_svc_inst(ranging_inst, svc)
!= BCME_OK) {
goto exit;
}
if (ranging_inst->range_role == NAN_RANGING_ROLE_RESPONDER) {
/* Adding RTT target while responder, leads to role concurrency */
WL_INFORM_MEM(("Entering Role Concurrency constraint, peer : "
MACDBG "\n", MAC2STRDBG(&ranging_inst->peer_addr)));
ranging_inst->role_concurrency_status = TRUE;
} else {
/* Trigger/Reset geofence RTT */
wl_cfgnan_reset_geofence_ranging(cfg, ranging_inst,
RTT_SCHED_SUB_MATCH, TRUE);
}
} else {
/* Target already added, check & add svc_inst ref to rang_inst */
wl_cfgnan_update_ranging_svc_inst(ranging_inst, svc);
}
/* Disc event will be given on receving range_rpt event */
WL_TRACE(("Disc event will given when Range RPT event is recvd"));
} else {
ret = BCME_UNSUPPORTED;
}
exit:
if (ret == BCME_OK) {
/* Check if we have to send disc result immediately or not */
rtt_invalid_reason = dhd_rtt_invalid_states
(bcmcfg_to_prmry_ndev(cfg), &nan_event_data->remote_nmi);
/*
* If instant RTT not possible (RTT postpone),
* send discovery result instantly like
* incase of invalid rtt state as
* ndp connected/connecting,
* or role_concurrency active with peer.
* Otherwise, result should be posted
* on ranging report event after RTT done
*/
if ((rtt_invalid_reason == RTT_STATE_VALID) &&
(!wl_cfgnan_check_role_concurrency(cfg,
&nan_event_data->remote_nmi))) {
/* Avoid sending disc result instantly */
*send_disc_result = FALSE;
}
}
return ret;
}
bool
wl_cfgnan_ranging_allowed(struct bcm_cfg80211 *cfg)
{
int i = 0;
uint8 rng_progress_count = 0;
nan_ranging_inst_t *ranging_inst = NULL;
for (i = 0; i < NAN_MAX_RANGING_INST; i++) {
ranging_inst = &cfg->nancfg->nan_ranging_info[i];
if (NAN_RANGING_IS_IN_PROG(ranging_inst->range_status)) {
rng_progress_count++;
}
}
if (rng_progress_count >= NAN_MAX_RANGING_SSN_ALLOWED) {
return FALSE;
}
return TRUE;
}
uint8
wl_cfgnan_cancel_rng_responders(struct net_device *ndev)
{
int i = 0;
uint8 num_resp_cancelled = 0;
int status, ret;
nan_ranging_inst_t *ranging_inst = NULL;
struct bcm_cfg80211 *cfg = wl_get_cfg(ndev);
for (i = 0; i < NAN_MAX_RANGING_INST; i++) {
ranging_inst = &cfg->nancfg->nan_ranging_info[i];
if (NAN_RANGING_IS_IN_PROG(ranging_inst->range_status) &&
(ranging_inst->range_role == NAN_RANGING_ROLE_RESPONDER)) {
num_resp_cancelled++;
ret = wl_cfgnan_cancel_ranging(bcmcfg_to_prmry_ndev(cfg), cfg,
&ranging_inst->range_id, NAN_RNG_TERM_FLAG_IMMEDIATE, &status);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("wl_cfgnan_cancel_rng_responders: Failed to cancel"
" existing ranging, ret = (%d)\n", ret));
}
WL_INFORM_MEM(("Removing Ranging Instance " MACDBG "\n",
MAC2STRDBG(&(ranging_inst->peer_addr))));
bzero(ranging_inst, sizeof(*ranging_inst));
}
}
return num_resp_cancelled;
}
/* ranging reqeust event handler */
static int
wl_cfgnan_handle_ranging_ind(struct bcm_cfg80211 *cfg,
wl_nan_ev_rng_req_ind_t *rng_ind)
{
int ret = BCME_OK;
nan_ranging_inst_t *ranging_inst = NULL;
uint8 cancel_flags = 0;
bool accept = TRUE;
nan_ranging_inst_t tmp_rng_inst;
struct net_device *ndev = bcmcfg_to_prmry_ndev(cfg);
struct ether_addr * peer_addr = &(rng_ind->peer_m_addr);
uint8 rtt_invalid_state;
dhd_pub_t *dhd = (struct dhd_pub *)(cfg->pub);
rtt_status_info_t *rtt_status = GET_RTTSTATE(dhd);
int err_at = 0;
WL_DBG(("Trigger range response\n"));
/* Check if ranging is allowed */
rtt_invalid_state = dhd_rtt_invalid_states(ndev, peer_addr);
if (rtt_invalid_state != RTT_STATE_VALID) {
WL_INFORM_MEM(("Cannot allow ranging due to reason %d \n", rtt_invalid_state));
ret = BCME_NORESOURCE;
err_at = 1;
goto done;
}
mutex_lock(&rtt_status->rtt_mutex);
if (rtt_status && !RTT_IS_STOPPED(rtt_status)) {
WL_INFORM_MEM(("Direcetd RTT in progress..reject RNG_REQ\n"));
ret = BCME_NORESOURCE;
err_at = 2;
goto done;
}
/* Check if ranging set up in progress */
if (dhd_rtt_is_geofence_setup_inprog(dhd)) {
WL_INFORM_MEM(("Ranging set up already in progress, "
"RNG IND event dropped\n"));
err_at = 3;
ret = BCME_NOTREADY;
goto done;
}
/* check if we are already having any ranging session with peer.
* If so below are the policies
* If we are already a Geofence Initiator or responder w.r.t the peer
* then silently teardown the current session and accept the REQ.
* If we are in direct rtt initiator role then reject.
*/
ranging_inst = wl_cfgnan_check_for_ranging(cfg, peer_addr);
if (ranging_inst) {
if (NAN_RANGING_IS_IN_PROG(ranging_inst->range_status)) {
if (ranging_inst->range_type == RTT_TYPE_NAN_GEOFENCE ||
ranging_inst->range_role == NAN_RANGING_ROLE_RESPONDER) {
WL_INFORM_MEM(("Already responder/geofence for the Peer, cancel "
"current ssn and accept new one,"
" range_type = %d, role = %d\n",
ranging_inst->range_type, ranging_inst->range_role));
cancel_flags = NAN_RNG_TERM_FLAG_IMMEDIATE |
NAN_RNG_TERM_FLAG_SILENT_TEARDOWN;
wl_cfgnan_suspend_geofence_rng_session(ndev,
&(rng_ind->peer_m_addr),
RTT_GEO_SUSPN_PEER_RTT_TRIGGER, cancel_flags);
} else {
WL_ERR(("Reject the RNG_REQ_IND in direct rtt initiator role\n"));
err_at = 4;
ret = BCME_BUSY;
goto done;
}
} else {
/* Check if new Ranging session is allowed */
if (dhd_rtt_geofence_sessions_maxed_out(dhd)) {
WL_ERR(("Cannot allow more ranging sessions\n"));
err_at = 5;
ret = BCME_NORESOURCE;
goto done;
}
}
/* reset ranging instance for responder role */
ranging_inst->range_status = NAN_RANGING_REQUIRED;
ranging_inst->range_role = NAN_RANGING_ROLE_RESPONDER;
ranging_inst->range_type = 0;
} else {
/* Check if new Ranging session is allowed */
if (dhd_rtt_geofence_sessions_maxed_out(dhd)) {
WL_ERR(("Cannot allow more ranging sessions\n"));
err_at = 6;
ret = BCME_NORESOURCE;
goto done;
}
ranging_inst = wl_cfgnan_get_ranging_inst(cfg, &rng_ind->peer_m_addr,
NAN_RANGING_ROLE_RESPONDER);
ASSERT(ranging_inst);
if (!ranging_inst) {
WL_ERR(("Failed to create ranging instance \n"));
err_at = 7;
ret = BCME_NORESOURCE;
goto done;
}
}
done:
if (ret != BCME_OK) {
/* reject the REQ using temp ranging instance */
bzero(&tmp_rng_inst, sizeof(tmp_rng_inst));
ranging_inst = &tmp_rng_inst;
(void)memcpy_s(&tmp_rng_inst.peer_addr, ETHER_ADDR_LEN,
&rng_ind->peer_m_addr, ETHER_ADDR_LEN);
accept = FALSE;
}
ranging_inst->range_id = rng_ind->rng_id;
WL_INFORM_MEM(("Trigger Ranging at Responder, ret = %d, err_at = %d, "
"accept = %d, rng_id = %d\n", ret, err_at,
accept, rng_ind->rng_id));
ret = wl_cfgnan_trigger_ranging(ndev, cfg, ranging_inst,
NULL, NAN_RANGE_REQ_EVNT, accept);
if (unlikely(ret) || !accept) {
WL_ERR(("Failed to trigger ranging while handling range request, "
" ret = %d, rng_id = %d, accept %d\n", ret,
rng_ind->rng_id, accept));
wl_cfgnan_reset_remove_ranging_instance(cfg, ranging_inst);
} else {
dhd_rtt_set_geofence_setup_status(dhd, TRUE,
&ranging_inst->peer_addr);
}
mutex_unlock(&rtt_status->rtt_mutex);
return ret;
}
/* ranging quest and response iovar handler */
int
wl_cfgnan_trigger_ranging(struct net_device *ndev, struct bcm_cfg80211 *cfg,
void *ranging_ctxt, nan_svc_info_t *svc,
uint8 range_cmd, bool accept_req)
{
s32 ret = BCME_OK;
bcm_iov_batch_buf_t *nan_buf = NULL;
wl_nan_range_req_t *range_req = NULL;
wl_nan_range_resp_t *range_resp = NULL;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
uint32 status;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE_MED];
nan_ranging_inst_t *ranging_inst = (nan_ranging_inst_t *)ranging_ctxt;
nan_avail_cmd_data cmd_data;
NAN_DBG_ENTER();
bzero(&cmd_data, sizeof(cmd_data));
ret = memcpy_s(&cmd_data.peer_nmi, ETHER_ADDR_LEN,
&ranging_inst->peer_addr, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy ranging peer addr\n"));
goto fail;
}
cmd_data.avail_period = NAN_RANGING_PERIOD;
ret = wl_cfgnan_set_nan_avail(bcmcfg_to_prmry_ndev(cfg),
cfg, &cmd_data, WL_AVAIL_LOCAL);
if (ret != BCME_OK) {
WL_ERR(("Failed to set avail value with type [WL_AVAIL_LOCAL]\n"));
goto fail;
}
ret = wl_cfgnan_set_nan_avail(bcmcfg_to_prmry_ndev(cfg),
cfg, &cmd_data, WL_AVAIL_RANGING);
if (unlikely(ret)) {
WL_ERR(("Failed to set avail value with type [WL_AVAIL_RANGING]\n"));
goto fail;
}
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(&nan_buf->cmds[0]);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
if (range_cmd == NAN_RANGE_REQ_CMD) {
sub_cmd->id = htod16(WL_NAN_CMD_RANGE_REQUEST);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(wl_nan_range_req_t);
range_req = (wl_nan_range_req_t *)(sub_cmd->data);
/* ranging config */
range_req->peer = ranging_inst->peer_addr;
if (svc) {
range_req->interval = svc->ranging_interval;
/* Limits are in cm from host */
range_req->ingress = svc->ingress_limit;
range_req->egress = svc->egress_limit;
}
range_req->indication = NAN_RANGING_INDICATE_CONTINUOUS_MASK;
} else {
/* range response config */
sub_cmd->id = htod16(WL_NAN_CMD_RANGE_RESPONSE);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(wl_nan_range_resp_t);
range_resp = (wl_nan_range_resp_t *)(sub_cmd->data);
range_resp->range_id = ranging_inst->range_id;
range_resp->indication = NAN_RANGING_INDICATE_CONTINUOUS_MASK;
if (accept_req) {
range_resp->status = NAN_RNG_REQ_ACCEPTED_BY_HOST;
} else {
range_resp->status = NAN_RNG_REQ_REJECTED_BY_HOST;
}
nan_buf->is_set = true;
}
nan_buf_size -= (sub_cmd->len +
OFFSETOF(bcm_iov_batch_subcmd_t, u.options));
nan_buf->count++;
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size,
&status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("nan ranging failed ret = %d status = %d\n",
ret, status));
ret = (ret == BCME_OK) ? status : ret;
goto fail;
}
WL_TRACE(("nan ranging trigger successful\n"));
if (range_cmd == NAN_RANGE_REQ_CMD) {
WL_INFORM_MEM(("Ranging Req Triggered"
" peer: " MACDBG ", ind : %d, ingress : %d, egress : %d\n",
MAC2STRDBG(&ranging_inst->peer_addr), range_req->indication,
range_req->ingress, range_req->egress));
} else {
WL_INFORM_MEM(("Ranging Resp Triggered"
" peer: " MACDBG ", ind : %d, ingress : %d, egress : %d\n",
MAC2STRDBG(&ranging_inst->peer_addr), range_resp->indication,
range_resp->ingress, range_resp->egress));
}
/* check the response buff for request */
if (range_cmd == NAN_RANGE_REQ_CMD) {
ret = process_resp_buf(resp_buf + WL_NAN_OBUF_DATA_OFFSET,
&ranging_inst->range_id, WL_NAN_CMD_RANGE_REQUEST);
WL_INFORM_MEM(("ranging instance returned %d\n", ranging_inst->range_id));
}
/* Move Ranging instance to set up in progress state */
ranging_inst->range_status = NAN_RANGING_SETUP_IN_PROGRESS;
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
NAN_DBG_EXIT();
return ret;
}
bool
wl_cfgnan_ranging_is_in_prog_for_peer(struct bcm_cfg80211 *cfg, struct ether_addr *peer_addr)
{
nan_ranging_inst_t *rng_inst = NULL;
rng_inst = wl_cfgnan_check_for_ranging(cfg, peer_addr);
return (rng_inst && NAN_RANGING_IS_IN_PROG(rng_inst->range_status));
}
#endif /* RTT_SUPPORT */
#endif /* WL_NAN_DISC_CACHE */
static void *wl_nan_bloom_alloc(void *ctx, uint size)
{
uint8 *buf;
BCM_REFERENCE(ctx);
buf = kmalloc(size, GFP_KERNEL);
if (!buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
buf = NULL;
}
return buf;
}
static void wl_nan_bloom_free(void *ctx, void *buf, uint size)
{
BCM_REFERENCE(ctx);
BCM_REFERENCE(size);
if (buf) {
kfree(buf);
}
}
static uint wl_nan_hash(void *ctx, uint index, const uint8 *input, uint input_len)
{
uint8* filter_idx = (uint8*)ctx;
uint8 i = (*filter_idx * WL_NAN_HASHES_PER_BLOOM) + (uint8)index;
uint b = 0;
/* Steps 1 and 2 as explained in Section 6.2 */
/* Concatenate index to input and run CRC32 by calling hndcrc32 twice */
GCC_DIAGNOSTIC_PUSH_SUPPRESS_CAST();
b = hndcrc32(&i, sizeof(uint8), CRC32_INIT_VALUE);
b = hndcrc32((uint8*)input, input_len, b);
GCC_DIAGNOSTIC_POP();
/* Obtain the last 2 bytes of the CRC32 output */
b &= NAN_BLOOM_CRC32_MASK;
/* Step 3 is completed by bcmbloom functions */
return b;
}
static int wl_nan_bloom_create(bcm_bloom_filter_t **bp, uint *idx, uint size)
{
uint i;
int err;
err = bcm_bloom_create(wl_nan_bloom_alloc, wl_nan_bloom_free,
idx, WL_NAN_HASHES_PER_BLOOM, size, bp);
if (err != BCME_OK) {
goto exit;
}
/* Populate bloom filter with hash functions */
for (i = 0; i < WL_NAN_HASHES_PER_BLOOM; i++) {
err = bcm_bloom_add_hash(*bp, wl_nan_hash, &i);
if (err) {
WL_ERR(("bcm_bloom_add_hash failed\n"));
goto exit;
}
}
exit:
return err;
}
static int
wl_cfgnan_sd_params_handler(struct net_device *ndev,
nan_discover_cmd_data_t *cmd_data, uint16 cmd_id,
void *p_buf, uint16 *nan_buf_size)
{
s32 ret = BCME_OK;
uint8 *pxtlv, *srf = NULL, *srf_mac = NULL, *srftmp = NULL;
uint16 buflen_avail;
bcm_iov_batch_subcmd_t *sub_cmd = (bcm_iov_batch_subcmd_t*)(p_buf);
wl_nan_sd_params_t *sd_params = (wl_nan_sd_params_t *)sub_cmd->data;
uint16 srf_size = 0;
uint bloom_size, a;
bcm_bloom_filter_t *bp = NULL;
/* Bloom filter index default, indicates it has not been set */
uint bloom_idx = 0xFFFFFFFF;
uint16 bloom_len = NAN_BLOOM_LENGTH_DEFAULT;
/* srf_ctrl_size = bloom_len + src_control field */
uint16 srf_ctrl_size = bloom_len + 1;
dhd_pub_t *dhdp = wl_cfg80211_get_dhdp(ndev);
struct bcm_cfg80211 *cfg = wl_get_cfg(ndev);
BCM_REFERENCE(cfg);
NAN_DBG_ENTER();
if (cmd_data->period) {
sd_params->awake_dw = cmd_data->period;
}
sd_params->period = 1;
if (cmd_data->ttl) {
sd_params->ttl = cmd_data->ttl;
} else {
sd_params->ttl = WL_NAN_TTL_UNTIL_CANCEL;
}
sd_params->flags = 0;
sd_params->flags = cmd_data->flags;
/* Nan Service Based event suppression Flags */
if (cmd_data->recv_ind_flag) {
/* BIT0 - If set, host wont rec event "terminated" */
if (CHECK_BIT(cmd_data->recv_ind_flag, WL_NAN_EVENT_SUPPRESS_TERMINATE_BIT)) {
sd_params->flags |= WL_NAN_SVC_CTRL_SUPPRESS_EVT_TERMINATED;
}
/* BIT1 - If set, host wont receive match expiry evt */
/* TODO: Exp not yet supported */
if (CHECK_BIT(cmd_data->recv_ind_flag, WL_NAN_EVENT_SUPPRESS_MATCH_EXP_BIT)) {
WL_DBG(("Need to add match expiry event\n"));
}
/* BIT2 - If set, host wont rec event "receive" */
if (CHECK_BIT(cmd_data->recv_ind_flag, WL_NAN_EVENT_SUPPRESS_RECEIVE_BIT)) {
sd_params->flags |= WL_NAN_SVC_CTRL_SUPPRESS_EVT_RECEIVE;
}
/* BIT3 - If set, host wont rec event "replied" */
if (CHECK_BIT(cmd_data->recv_ind_flag, WL_NAN_EVENT_SUPPRESS_REPLIED_BIT)) {
sd_params->flags |= WL_NAN_SVC_CTRL_SUPPRESS_EVT_REPLIED;
}
}
if (cmd_id == WL_NAN_CMD_SD_PUBLISH) {
sd_params->instance_id = cmd_data->pub_id;
if (cmd_data->service_responder_policy) {
/* Do not disturb avail if dam is supported */
if (FW_SUPPORTED(dhdp, autodam)) {
/* Nan Accept policy: Per service basis policy
* Based on this policy(ALL/NONE), responder side
* will send ACCEPT/REJECT
* If set, auto datapath responder will be sent by FW
*/
sd_params->flags |= WL_NAN_SVC_CTRL_AUTO_DPRESP;
} else {
WL_ERR(("svc specifiv auto dp resp is not"
" supported in non-auto dam fw\n"));
}
}
} else if (cmd_id == WL_NAN_CMD_SD_SUBSCRIBE) {
sd_params->instance_id = cmd_data->sub_id;
} else {
ret = BCME_USAGE_ERROR;
WL_ERR(("wrong command id = %d \n", cmd_id));
goto fail;
}
if ((cmd_data->svc_hash.dlen == WL_NAN_SVC_HASH_LEN) &&
(cmd_data->svc_hash.data)) {
ret = memcpy_s((uint8*)sd_params->svc_hash,
sizeof(sd_params->svc_hash),
cmd_data->svc_hash.data,
cmd_data->svc_hash.dlen);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy svc hash\n"));
goto fail;
}
#ifdef WL_NAN_DEBUG
prhex("hashed svc name", cmd_data->svc_hash.data,
cmd_data->svc_hash.dlen);
#endif /* WL_NAN_DEBUG */
} else {
ret = BCME_ERROR;
WL_ERR(("invalid svc hash data or length = %d\n",
cmd_data->svc_hash.dlen));
goto fail;
}
/* check if ranging support is present in firmware */
if ((cmd_data->sde_control_flag & NAN_SDE_CF_RANGING_REQUIRED) &&
!FW_SUPPORTED(dhdp, nanrange)) {
WL_ERR(("Service requires ranging but fw doesnt support it\n"));
ret = BCME_UNSUPPORTED;
goto fail;
}
/* Optional parameters: fill the sub_command block with service descriptor attr */
sub_cmd->id = htod16(cmd_id);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
sub_cmd->len = sizeof(sub_cmd->u.options) +
OFFSETOF(wl_nan_sd_params_t, optional[0]);
pxtlv = (uint8*)&sd_params->optional[0];
*nan_buf_size -= sub_cmd->len;
buflen_avail = *nan_buf_size;
if (cmd_data->svc_info.data && cmd_data->svc_info.dlen) {
WL_TRACE(("optional svc_info present, pack it\n"));
ret = bcm_pack_xtlv_entry(&pxtlv, nan_buf_size,
WL_NAN_XTLV_SD_SVC_INFO,
cmd_data->svc_info.dlen,
cmd_data->svc_info.data, BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: fail to pack WL_NAN_XTLV_SD_SVC_INFO\n", __FUNCTION__));
goto fail;
}
}
if (cmd_data->sde_svc_info.data && cmd_data->sde_svc_info.dlen) {
WL_TRACE(("optional sdea svc_info present, pack it, %d\n",
cmd_data->sde_svc_info.dlen));
ret = bcm_pack_xtlv_entry(&pxtlv, nan_buf_size,
WL_NAN_XTLV_SD_SDE_SVC_INFO,
cmd_data->sde_svc_info.dlen,
cmd_data->sde_svc_info.data, BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: fail to pack sdea svc info\n", __FUNCTION__));
goto fail;
}
}
if (cmd_data->tx_match.dlen) {
WL_TRACE(("optional tx match filter presnet (len=%d)\n",
cmd_data->tx_match.dlen));
ret = bcm_pack_xtlv_entry(&pxtlv, nan_buf_size,
WL_NAN_XTLV_CFG_MATCH_TX, cmd_data->tx_match.dlen,
cmd_data->tx_match.data, BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: failed on xtlv_pack for tx match filter\n", __FUNCTION__));
goto fail;
}
}
if (cmd_data->life_count) {
WL_TRACE(("optional life count is present, pack it\n"));
ret = bcm_pack_xtlv_entry(&pxtlv, nan_buf_size, WL_NAN_XTLV_CFG_SVC_LIFE_COUNT,
sizeof(cmd_data->life_count), &cmd_data->life_count,
BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: failed to WL_NAN_XTLV_CFG_SVC_LIFE_COUNT\n", __FUNCTION__));
goto fail;
}
}
if (cmd_data->use_srf) {
uint8 srf_control = 0;
/* set include bit */
if (cmd_data->srf_include == true) {
srf_control |= 0x2;
}
if (!ETHER_ISNULLADDR(&cmd_data->mac_list.list) &&
(cmd_data->mac_list.num_mac_addr
< NAN_SRF_MAX_MAC)) {
if (cmd_data->srf_type == SRF_TYPE_SEQ_MAC_ADDR) {
/* mac list */
srf_size = (cmd_data->mac_list.num_mac_addr
* ETHER_ADDR_LEN) + NAN_SRF_CTRL_FIELD_LEN;
WL_TRACE(("srf size = %d\n", srf_size));
srf_mac = MALLOCZ(cfg->osh, srf_size);
if (srf_mac == NULL) {
WL_ERR(("%s: memory allocation failed\n", __FUNCTION__));
ret = -ENOMEM;
goto fail;
}
ret = memcpy_s(srf_mac, NAN_SRF_CTRL_FIELD_LEN,
&srf_control, NAN_SRF_CTRL_FIELD_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy srf control\n"));
goto fail;
}
ret = memcpy_s(srf_mac+1, (srf_size - NAN_SRF_CTRL_FIELD_LEN),
cmd_data->mac_list.list,
(srf_size - NAN_SRF_CTRL_FIELD_LEN));
if (ret != BCME_OK) {
WL_ERR(("Failed to copy srf control mac list\n"));
goto fail;
}
ret = bcm_pack_xtlv_entry(&pxtlv, nan_buf_size,
WL_NAN_XTLV_CFG_SR_FILTER, srf_size, srf_mac,
BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: failed to WL_NAN_XTLV_CFG_SR_FILTER\n",
__FUNCTION__));
goto fail;
}
} else if (cmd_data->srf_type == SRF_TYPE_BLOOM_FILTER) {
/* Create bloom filter */
srf = MALLOCZ(cfg->osh, srf_ctrl_size);
if (srf == NULL) {
WL_ERR(("%s: memory allocation failed\n", __FUNCTION__));
ret = -ENOMEM;
goto fail;
}
/* Bloom filter */
srf_control |= 0x1;
/* Instance id must be from 1 to 255, 0 is Reserved */
if (sd_params->instance_id == NAN_ID_RESERVED) {
WL_ERR(("Invalid instance id: %d\n",
sd_params->instance_id));
ret = BCME_BADARG;
goto fail;
}
if (bloom_idx == 0xFFFFFFFF) {
bloom_idx = sd_params->instance_id % 4;
} else {
WL_ERR(("Invalid bloom_idx\n"));
ret = BCME_BADARG;
goto fail;
}
srf_control |= bloom_idx << 2;
ret = wl_nan_bloom_create(&bp, &bloom_idx, bloom_len);
if (unlikely(ret)) {
WL_ERR(("%s: Bloom create failed\n", __FUNCTION__));
goto fail;
}
srftmp = cmd_data->mac_list.list;
for (a = 0;
a < cmd_data->mac_list.num_mac_addr; a++) {
ret = bcm_bloom_add_member(bp, srftmp, ETHER_ADDR_LEN);
if (unlikely(ret)) {
WL_ERR(("%s: Cannot add to bloom filter\n",
__FUNCTION__));
goto fail;
}
srftmp += ETHER_ADDR_LEN;
}
ret = memcpy_s(srf, NAN_SRF_CTRL_FIELD_LEN,
&srf_control, NAN_SRF_CTRL_FIELD_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy srf control\n"));
goto fail;
}
ret = bcm_bloom_get_filter_data(bp, bloom_len,
(srf + NAN_SRF_CTRL_FIELD_LEN),
&bloom_size);
if (unlikely(ret)) {
WL_ERR(("%s: Cannot get filter data\n", __FUNCTION__));
goto fail;
}
ret = bcm_pack_xtlv_entry(&pxtlv, nan_buf_size,
WL_NAN_XTLV_CFG_SR_FILTER, srf_ctrl_size,
srf, BCM_XTLV_OPTION_ALIGN32);
if (ret != BCME_OK) {
WL_ERR(("Failed to pack SR FILTER data, ret = %d\n", ret));
goto fail;
}
} else {
WL_ERR(("Invalid SRF Type = %d !!!\n",
cmd_data->srf_type));
goto fail;
}
} else {
WL_ERR(("Invalid MAC Addr/Too many mac addr = %d !!!\n",
cmd_data->mac_list.num_mac_addr));
goto fail;
}
}
if (cmd_data->rx_match.dlen) {
WL_TRACE(("optional rx match filter is present, pack it\n"));
ret = bcm_pack_xtlv_entry(&pxtlv, nan_buf_size,
WL_NAN_XTLV_CFG_MATCH_RX, cmd_data->rx_match.dlen,
cmd_data->rx_match.data, BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: failed on xtlv_pack for rx match filter\n", __func__));
goto fail;
}
}
/* Security elements */
if (cmd_data->csid) {
WL_TRACE(("Cipher suite type is present, pack it\n"));
ret = bcm_pack_xtlv_entry(&pxtlv, nan_buf_size,
WL_NAN_XTLV_CFG_SEC_CSID, sizeof(nan_sec_csid_e),
(uint8*)&cmd_data->csid, BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: fail to pack on csid\n", __FUNCTION__));
goto fail;
}
}
if (cmd_data->ndp_cfg.security_cfg) {
if ((cmd_data->key_type == NAN_SECURITY_KEY_INPUT_PMK) ||
(cmd_data->key_type == NAN_SECURITY_KEY_INPUT_PASSPHRASE)) {
if (cmd_data->key.data && cmd_data->key.dlen) {
WL_TRACE(("optional pmk present, pack it\n"));
ret = bcm_pack_xtlv_entry(&pxtlv, nan_buf_size,
WL_NAN_XTLV_CFG_SEC_PMK, cmd_data->key.dlen,
cmd_data->key.data, BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: fail to pack WL_NAN_XTLV_CFG_SEC_PMK\n",
__FUNCTION__));
goto fail;
}
}
} else {
WL_ERR(("Invalid security key type\n"));
ret = BCME_BADARG;
goto fail;
}
}
if (cmd_data->scid.data && cmd_data->scid.dlen) {
WL_TRACE(("optional scid present, pack it\n"));
ret = bcm_pack_xtlv_entry(&pxtlv, nan_buf_size, WL_NAN_XTLV_CFG_SEC_SCID,
cmd_data->scid.dlen, cmd_data->scid.data, BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: fail to pack WL_NAN_XTLV_CFG_SEC_SCID\n", __FUNCTION__));
goto fail;
}
}
if (cmd_data->sde_control_config) {
ret = bcm_pack_xtlv_entry(&pxtlv, nan_buf_size,
WL_NAN_XTLV_SD_SDE_CONTROL,
sizeof(uint16), (uint8*)&cmd_data->sde_control_flag,
BCM_XTLV_OPTION_ALIGN32);
if (ret != BCME_OK) {
WL_ERR(("%s: fail to pack WL_NAN_XTLV_SD_SDE_CONTROL\n", __FUNCTION__));
goto fail;
}
}
sub_cmd->len += (buflen_avail - *nan_buf_size);
fail:
if (srf) {
MFREE(cfg->osh, srf, srf_ctrl_size);
}
if (srf_mac) {
MFREE(cfg->osh, srf_mac, srf_size);
}
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_aligned_data_size_of_opt_disc_params(uint16 *data_size, nan_discover_cmd_data_t *cmd_data)
{
s32 ret = BCME_OK;
if (cmd_data->svc_info.dlen)
*data_size += ALIGN_SIZE(cmd_data->svc_info.dlen + NAN_XTLV_ID_LEN_SIZE, 4);
if (cmd_data->sde_svc_info.dlen)
*data_size += ALIGN_SIZE(cmd_data->sde_svc_info.dlen + NAN_XTLV_ID_LEN_SIZE, 4);
if (cmd_data->tx_match.dlen)
*data_size += ALIGN_SIZE(cmd_data->tx_match.dlen + NAN_XTLV_ID_LEN_SIZE, 4);
if (cmd_data->rx_match.dlen)
*data_size += ALIGN_SIZE(cmd_data->rx_match.dlen + NAN_XTLV_ID_LEN_SIZE, 4);
if (cmd_data->use_srf) {
if (cmd_data->srf_type == SRF_TYPE_SEQ_MAC_ADDR) {
*data_size += (cmd_data->mac_list.num_mac_addr * ETHER_ADDR_LEN)
+ NAN_SRF_CTRL_FIELD_LEN;
} else { /* Bloom filter type */
*data_size += NAN_BLOOM_LENGTH_DEFAULT + 1;
}
*data_size += ALIGN_SIZE(*data_size + NAN_XTLV_ID_LEN_SIZE, 4);
}
if (cmd_data->csid)
*data_size += ALIGN_SIZE(sizeof(nan_sec_csid_e) + NAN_XTLV_ID_LEN_SIZE, 4);
if (cmd_data->key.dlen)
*data_size += ALIGN_SIZE(cmd_data->key.dlen + NAN_XTLV_ID_LEN_SIZE, 4);
if (cmd_data->scid.dlen)
*data_size += ALIGN_SIZE(cmd_data->scid.dlen + NAN_XTLV_ID_LEN_SIZE, 4);
if (cmd_data->sde_control_config)
*data_size += ALIGN_SIZE(sizeof(uint16) + NAN_XTLV_ID_LEN_SIZE, 4);
if (cmd_data->life_count)
*data_size += ALIGN_SIZE(sizeof(cmd_data->life_count) + NAN_XTLV_ID_LEN_SIZE, 4);
return ret;
}
static int
wl_cfgnan_aligned_data_size_of_opt_dp_params(struct bcm_cfg80211 *cfg, uint16 *data_size,
nan_datapath_cmd_data_t *cmd_data)
{
s32 ret = BCME_OK;
if (cmd_data->svc_info.dlen) {
*data_size += ALIGN_SIZE(cmd_data->svc_info.dlen + NAN_XTLV_ID_LEN_SIZE, 4);
/* When NDPE is enabled, adding this extra data_size to provide backward
* compatability for non-ndpe devices. Duplicating NDP specific info and sending it
* to FW in SD SVCINFO and NDPE TLV list as host doesn't know peer's NDPE capability
*/
if (cfg->nancfg->ndpe_enabled) {
*data_size += ALIGN_SIZE(cmd_data->svc_info.dlen + NAN_XTLV_ID_LEN_SIZE, 4);
}
}
if (cmd_data->key.dlen)
*data_size += ALIGN_SIZE(cmd_data->key.dlen + NAN_XTLV_ID_LEN_SIZE, 4);
if (cmd_data->csid)
*data_size += ALIGN_SIZE(sizeof(nan_sec_csid_e) + NAN_XTLV_ID_LEN_SIZE, 4);
*data_size += ALIGN_SIZE(WL_NAN_SVC_HASH_LEN + NAN_XTLV_ID_LEN_SIZE, 4);
return ret;
}
int
wl_cfgnan_svc_get_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg, uint16 cmd_id, nan_discover_cmd_data_t *cmd_data)
{
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
uint32 instance_id;
s32 ret = BCME_OK;
bcm_iov_batch_buf_t *nan_buf = NULL;
uint8 *resp_buf = NULL;
uint16 data_size = WL_NAN_OBUF_DATA_OFFSET + sizeof(instance_id);
NAN_DBG_ENTER();
nan_buf = MALLOCZ(cfg->osh, data_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
resp_buf = MALLOCZ(cfg->osh, NAN_IOCTL_BUF_SIZE_LARGE);
if (!resp_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 1;
/* check if service is present */
nan_buf->is_set = false;
sub_cmd = (bcm_iov_batch_subcmd_t*)(&nan_buf->cmds[0]);
if (cmd_id == WL_NAN_CMD_SD_PUBLISH) {
instance_id = cmd_data->pub_id;
} else if (cmd_id == WL_NAN_CMD_SD_SUBSCRIBE) {
instance_id = cmd_data->sub_id;
} else {
ret = BCME_USAGE_ERROR;
WL_ERR(("wrong command id = %u\n", cmd_id));
goto fail;
}
/* Fill the sub_command block */
sub_cmd->id = htod16(cmd_id);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(instance_id);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
ret = memcpy_s(sub_cmd->data, (data_size - WL_NAN_OBUF_DATA_OFFSET),
&instance_id, sizeof(instance_id));
if (ret != BCME_OK) {
WL_ERR(("Failed to copy instance id, ret = %d\n", ret));
goto fail;
}
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, data_size,
&(cmd_data->status), resp_buf, NAN_IOCTL_BUF_SIZE_LARGE);
if (unlikely(ret) || unlikely(cmd_data->status)) {
WL_ERR(("nan svc check failed ret = %d status = %d\n", ret, cmd_data->status));
goto fail;
} else {
WL_DBG(("nan svc check successful..proceed to update\n"));
}
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, data_size);
}
if (resp_buf) {
MFREE(cfg->osh, resp_buf, NAN_IOCTL_BUF_SIZE_LARGE);
}
NAN_DBG_EXIT();
return ret;
}
int
wl_cfgnan_svc_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg, uint16 cmd_id, nan_discover_cmd_data_t *cmd_data)
{
s32 ret = BCME_OK;
bcm_iov_batch_buf_t *nan_buf = NULL;
uint16 nan_buf_size;
uint8 *resp_buf = NULL;
/* Considering fixed params */
uint16 data_size = WL_NAN_OBUF_DATA_OFFSET +
OFFSETOF(wl_nan_sd_params_t, optional[0]);
if (cmd_data->svc_update) {
ret = wl_cfgnan_svc_get_handler(ndev, cfg, cmd_id, cmd_data);
if (ret != BCME_OK) {
WL_ERR(("Failed to update svc handler, ret = %d\n", ret));
goto fail;
} else {
/* Ignoring any other svc get error */
if (cmd_data->status == WL_NAN_E_BAD_INSTANCE) {
WL_ERR(("Bad instance status, failed to update svc handler\n"));
goto fail;
}
}
}
ret = wl_cfgnan_aligned_data_size_of_opt_disc_params(&data_size, cmd_data);
if (unlikely(ret)) {
WL_ERR(("Failed to get alligned size of optional params\n"));
goto fail;
}
nan_buf_size = data_size;
NAN_DBG_ENTER();
nan_buf = MALLOCZ(cfg->osh, data_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
resp_buf = MALLOCZ(cfg->osh, data_size + NAN_IOVAR_NAME_SIZE);
if (!resp_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf->is_set = true;
ret = wl_cfgnan_sd_params_handler(ndev, cmd_data, cmd_id,
&nan_buf->cmds[0], &nan_buf_size);
if (unlikely(ret)) {
WL_ERR((" Service discovery params handler failed, ret = %d\n", ret));
goto fail;
}
nan_buf->count++;
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, data_size,
&(cmd_data->status), resp_buf, data_size + NAN_IOVAR_NAME_SIZE);
if (cmd_data->svc_update && (cmd_data->status == BCME_DATA_NOTFOUND)) {
/* return OK if update tlv data is not present
* which means nothing to update
*/
cmd_data->status = BCME_OK;
}
if (unlikely(ret) || unlikely(cmd_data->status)) {
WL_ERR(("nan svc failed ret = %d status = %d\n", ret, cmd_data->status));
goto fail;
} else {
WL_DBG(("nan svc successful\n"));
#ifdef WL_NAN_DISC_CACHE
ret = wl_cfgnan_cache_svc_info(cfg, cmd_data, cmd_id, cmd_data->svc_update);
if (ret < 0) {
WL_ERR(("%s: fail to cache svc info, ret=%d\n",
__FUNCTION__, ret));
goto fail;
}
#endif /* WL_NAN_DISC_CACHE */
}
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, data_size);
}
if (resp_buf) {
MFREE(cfg->osh, resp_buf, data_size + NAN_IOVAR_NAME_SIZE);
}
NAN_DBG_EXIT();
return ret;
}
int
wl_cfgnan_publish_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg, nan_discover_cmd_data_t *cmd_data)
{
int ret = BCME_OK;
NAN_DBG_ENTER();
NAN_MUTEX_LOCK();
/*
* proceed only if mandatory arguments are present - subscriber id,
* service hash
*/
if ((!cmd_data->pub_id) || (!cmd_data->svc_hash.data) ||
(!cmd_data->svc_hash.dlen)) {
WL_ERR(("mandatory arguments are not present\n"));
ret = BCME_BADARG;
goto fail;
}
ret = wl_cfgnan_svc_handler(ndev, cfg, WL_NAN_CMD_SD_PUBLISH, cmd_data);
if (ret < 0) {
WL_ERR(("%s: fail to handle pub, ret=%d\n", __FUNCTION__, ret));
goto fail;
}
WL_INFORM_MEM(("[NAN] Service published for instance id:%d is_update %d\n",
cmd_data->pub_id, cmd_data->svc_update));
fail:
NAN_MUTEX_UNLOCK();
NAN_DBG_EXIT();
return ret;
}
int
wl_cfgnan_subscribe_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg, nan_discover_cmd_data_t *cmd_data)
{
int ret = BCME_OK;
#ifdef WL_NAN_DISC_CACHE
nan_svc_info_t *svc_info;
#ifdef RTT_SUPPORT
uint8 upd_ranging_required;
#endif /* RTT_SUPPORT */
#endif /* WL_NAN_DISC_CACHE */
#ifdef RTT_SUPPORT
#ifdef RTT_GEOFENCE_CONT
dhd_pub_t *dhd = (struct dhd_pub *)(cfg->pub);
rtt_status_info_t *rtt_status = GET_RTTSTATE(dhd);
#endif /* RTT_GEOFENCE_CONT */
#endif /* RTT_SUPPORT */
NAN_DBG_ENTER();
NAN_MUTEX_LOCK();
/*
* proceed only if mandatory arguments are present - subscriber id,
* service hash
*/
if ((!cmd_data->sub_id) || (!cmd_data->svc_hash.data) ||
(!cmd_data->svc_hash.dlen)) {
WL_ERR(("mandatory arguments are not present\n"));
ret = BCME_BADARG;
goto fail;
}
/* Check for ranging sessions if any */
if (cmd_data->svc_update) {
#ifdef WL_NAN_DISC_CACHE
svc_info = wl_cfgnan_get_svc_inst(cfg, cmd_data->sub_id, 0);
if (svc_info) {
#ifdef RTT_SUPPORT
wl_cfgnan_clear_svc_from_all_ranging_inst(cfg, cmd_data->sub_id);
/* terminate ranging sessions for this svc, avoid clearing svc cache */
wl_cfgnan_terminate_all_obsolete_ranging_sessions(cfg);
/* Attempt RTT for current geofence target */
wl_cfgnan_reset_geofence_ranging(cfg, NULL,
RTT_SCHED_RNG_TERM_SUB_SVC_UPD, TRUE);
WL_DBG(("Ranging sessions handled for svc update\n"));
upd_ranging_required = !!(cmd_data->sde_control_flag &
NAN_SDE_CF_RANGING_REQUIRED);
if ((svc_info->ranging_required ^ upd_ranging_required) ||
(svc_info->ingress_limit != cmd_data->ingress_limit) ||
(svc_info->egress_limit != cmd_data->egress_limit)) {
/* Clear cache info in Firmware */
ret = wl_cfgnan_clear_disc_cache(cfg, cmd_data->sub_id);
if (ret != BCME_OK) {
WL_ERR(("couldn't send clear cache to FW \n"));
goto fail;
}
/* Invalidate local cache info */
wl_cfgnan_remove_disc_result(cfg, cmd_data->sub_id);
}
#endif /* RTT_SUPPORT */
}
#endif /* WL_NAN_DISC_CACHE */
}
#ifdef RTT_SUPPORT
#ifdef RTT_GEOFENCE_CONT
/* Override ranging Indication */
if (rtt_status->geofence_cfg.geofence_cont) {
if (cmd_data->ranging_indication !=
NAN_RANGE_INDICATION_NONE) {
cmd_data->ranging_indication = NAN_RANGE_INDICATION_CONT;
}
}
#endif /* RTT_GEOFENCE_CONT */
#endif /* RTT_SUPPORT */
ret = wl_cfgnan_svc_handler(ndev, cfg, WL_NAN_CMD_SD_SUBSCRIBE, cmd_data);
if (ret < 0) {
WL_ERR(("%s: fail to handle svc, ret=%d\n", __FUNCTION__, ret));
goto fail;
}
WL_INFORM_MEM(("[NAN] Service subscribed for instance id:%d is_update %d\n",
cmd_data->sub_id, cmd_data->svc_update));
fail:
NAN_MUTEX_UNLOCK();
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_cancel_handler(nan_discover_cmd_data_t *cmd_data,
uint16 cmd_id, void *p_buf, uint16 *nan_buf_size)
{
s32 ret = BCME_OK;
NAN_DBG_ENTER();
if (p_buf != NULL) {
bcm_iov_batch_subcmd_t *sub_cmd = (bcm_iov_batch_subcmd_t*)(p_buf);
wl_nan_instance_id_t instance_id;
if (cmd_id == WL_NAN_CMD_SD_CANCEL_PUBLISH) {
instance_id = cmd_data->pub_id;
} else if (cmd_id == WL_NAN_CMD_SD_CANCEL_SUBSCRIBE) {
instance_id = cmd_data->sub_id;
} else {
ret = BCME_USAGE_ERROR;
WL_ERR(("wrong command id = %u\n", cmd_id));
goto fail;
}
/* Fill the sub_command block */
sub_cmd->id = htod16(cmd_id);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(instance_id);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
ret = memcpy_s(sub_cmd->data, *nan_buf_size,
&instance_id, sizeof(instance_id));
if (ret != BCME_OK) {
WL_ERR(("Failed to copy instance id, ret = %d\n", ret));
goto fail;
}
/* adjust iov data len to the end of last data record */
*nan_buf_size -= (sub_cmd->len +
OFFSETOF(bcm_iov_batch_subcmd_t, u.options));
WL_INFORM_MEM(("[NAN] Service with instance id:%d cancelled\n", instance_id));
} else {
WL_ERR(("nan_iov_buf is NULL\n"));
ret = BCME_ERROR;
goto fail;
}
fail:
NAN_DBG_EXIT();
return ret;
}
int
wl_cfgnan_cancel_pub_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg, nan_discover_cmd_data_t *cmd_data)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
NAN_DBG_ENTER();
NAN_MUTEX_LOCK();
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
/* proceed only if mandatory argument is present - publisher id */
if (!cmd_data->pub_id) {
WL_ERR(("mandatory argument is not present\n"));
ret = BCME_BADARG;
goto fail;
}
#ifdef WL_NAN_DISC_CACHE
wl_cfgnan_clear_svc_cache(cfg, cmd_data->pub_id);
#endif /* WL_NAN_DISC_CACHE */
ret = wl_cfgnan_cancel_handler(cmd_data, WL_NAN_CMD_SD_CANCEL_PUBLISH,
&nan_buf->cmds[0], &nan_buf_size);
if (unlikely(ret)) {
WL_ERR(("cancel publish failed\n"));
goto fail;
}
nan_buf->is_set = true;
nan_buf->count++;
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size,
&(cmd_data->status),
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(cmd_data->status)) {
WL_ERR(("nan cancel publish failed ret = %d status = %d\n",
ret, cmd_data->status));
goto fail;
}
WL_DBG(("nan cancel publish successfull\n"));
wl_cfgnan_remove_inst_id(cfg, cmd_data->pub_id);
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
NAN_MUTEX_UNLOCK();
NAN_DBG_EXIT();
return ret;
}
int
wl_cfgnan_cancel_sub_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg, nan_discover_cmd_data_t *cmd_data)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
NAN_DBG_ENTER();
NAN_MUTEX_LOCK();
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
/* proceed only if mandatory argument is present - subscriber id */
if (!cmd_data->sub_id) {
WL_ERR(("mandatory argument is not present\n"));
ret = BCME_BADARG;
goto fail;
}
#ifdef WL_NAN_DISC_CACHE
#ifdef RTT_SUPPORT
/* terminate ranging sessions for this svc */
wl_cfgnan_clear_svc_from_all_ranging_inst(cfg, cmd_data->sub_id);
wl_cfgnan_terminate_all_obsolete_ranging_sessions(cfg);
wl_cfgnan_reset_geofence_ranging(cfg, NULL,
RTT_SCHED_RNG_TERM_SUB_SVC_CANCEL, TRUE);
#endif /* RTT_SUPPORT */
/* clear svc cache for the service */
wl_cfgnan_clear_svc_cache(cfg, cmd_data->sub_id);
wl_cfgnan_remove_disc_result(cfg, cmd_data->sub_id);
#endif /* WL_NAN_DISC_CACHE */
ret = wl_cfgnan_cancel_handler(cmd_data, WL_NAN_CMD_SD_CANCEL_SUBSCRIBE,
&nan_buf->cmds[0], &nan_buf_size);
if (unlikely(ret)) {
WL_ERR(("cancel subscribe failed\n"));
goto fail;
}
nan_buf->is_set = true;
nan_buf->count++;
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size,
&(cmd_data->status),
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(cmd_data->status)) {
WL_ERR(("nan cancel subscribe failed ret = %d status = %d\n",
ret, cmd_data->status));
goto fail;
}
WL_DBG(("subscribe cancel successfull\n"));
wl_cfgnan_remove_inst_id(cfg, cmd_data->sub_id);
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
NAN_MUTEX_UNLOCK();
NAN_DBG_EXIT();
return ret;
}
int
wl_cfgnan_transmit_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg, nan_discover_cmd_data_t *cmd_data)
{
s32 ret = BCME_OK;
bcm_iov_batch_buf_t *nan_buf = NULL;
wl_nan_sd_transmit_t *sd_xmit = NULL;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
bool is_lcl_id = FALSE;
bool is_dest_id = FALSE;
bool is_dest_mac = FALSE;
uint16 buflen_avail;
uint8 *pxtlv;
uint16 nan_buf_size;
uint8 *resp_buf = NULL;
/* Considering fixed params */
uint16 data_size = WL_NAN_OBUF_DATA_OFFSET +
OFFSETOF(wl_nan_sd_transmit_t, opt_tlv);
data_size = ALIGN_SIZE(data_size, 4);
ret = wl_cfgnan_aligned_data_size_of_opt_disc_params(&data_size, cmd_data);
if (unlikely(ret)) {
WL_ERR(("Failed to get alligned size of optional params\n"));
goto fail;
}
NAN_DBG_ENTER();
NAN_MUTEX_LOCK();
nan_buf_size = data_size;
nan_buf = MALLOCZ(cfg->osh, data_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
resp_buf = MALLOCZ(cfg->osh, data_size + NAN_IOVAR_NAME_SIZE);
if (!resp_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
/* nan transmit */
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
/*
* proceed only if mandatory arguments are present - subscriber id,
* publisher id, mac address
*/
if ((!cmd_data->local_id) || (!cmd_data->remote_id) ||
ETHER_ISNULLADDR(&cmd_data->mac_addr.octet)) {
WL_ERR(("mandatory arguments are not present\n"));
ret = -EINVAL;
goto fail;
}
sub_cmd = (bcm_iov_batch_subcmd_t*)(&nan_buf->cmds[0]);
sd_xmit = (wl_nan_sd_transmit_t *)(sub_cmd->data);
/* local instance id must be from 1 to 255, 0 is reserved */
if (cmd_data->local_id == NAN_ID_RESERVED) {
WL_ERR(("Invalid local instance id: %d\n", cmd_data->local_id));
ret = BCME_BADARG;
goto fail;
}
sd_xmit->local_service_id = cmd_data->local_id;
is_lcl_id = TRUE;
/* remote instance id must be from 1 to 255, 0 is reserved */
if (cmd_data->remote_id == NAN_ID_RESERVED) {
WL_ERR(("Invalid remote instance id: %d\n", cmd_data->remote_id));
ret = BCME_BADARG;
goto fail;
}
sd_xmit->requestor_service_id = cmd_data->remote_id;
is_dest_id = TRUE;
if (!ETHER_ISNULLADDR(&cmd_data->mac_addr.octet)) {
ret = memcpy_s(&sd_xmit->destination_addr, ETHER_ADDR_LEN,
&cmd_data->mac_addr, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy dest mac address\n"));
goto fail;
}
} else {
WL_ERR(("Invalid ether addr provided\n"));
ret = BCME_BADARG;
goto fail;
}
is_dest_mac = TRUE;
if (cmd_data->priority) {
sd_xmit->priority = cmd_data->priority;
}
sd_xmit->token = cmd_data->token;
if (cmd_data->recv_ind_flag) {
/* BIT0 - If set, host wont rec event "txs" */
if (CHECK_BIT(cmd_data->recv_ind_flag,
WL_NAN_EVENT_SUPPRESS_FOLLOWUP_RECEIVE_BIT)) {
sd_xmit->flags = WL_NAN_FUP_SUPR_EVT_TXS;
}
}
/* Optional parameters: fill the sub_command block with service descriptor attr */
sub_cmd->id = htod16(WL_NAN_CMD_SD_TRANSMIT);
sub_cmd->len = sizeof(sub_cmd->u.options) +
OFFSETOF(wl_nan_sd_transmit_t, opt_tlv);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
pxtlv = (uint8 *)&sd_xmit->opt_tlv;
nan_buf_size -= (sub_cmd->len +
OFFSETOF(bcm_iov_batch_subcmd_t, u.options));
buflen_avail = nan_buf_size;
if (cmd_data->svc_info.data && cmd_data->svc_info.dlen) {
bcm_xtlv_t *pxtlv_svc_info = (bcm_xtlv_t *)pxtlv;
ret = bcm_pack_xtlv_entry(&pxtlv, &nan_buf_size,
WL_NAN_XTLV_SD_SVC_INFO, cmd_data->svc_info.dlen,
cmd_data->svc_info.data, BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: fail to pack on bcm_pack_xtlv_entry, ret=%d\n",
__FUNCTION__, ret));
goto fail;
}
/* 0xFF is max length for svc_info */
if (pxtlv_svc_info->len > 0xFF) {
WL_ERR(("Invalid service info length %d\n",
(pxtlv_svc_info->len)));
ret = BCME_USAGE_ERROR;
goto fail;
}
sd_xmit->opt_len = (uint8)(pxtlv_svc_info->len);
}
if (cmd_data->sde_svc_info.data && cmd_data->sde_svc_info.dlen) {
WL_TRACE(("optional sdea svc_info present, pack it\n"));
ret = bcm_pack_xtlv_entry(&pxtlv, &nan_buf_size,
WL_NAN_XTLV_SD_SDE_SVC_INFO, cmd_data->sde_svc_info.dlen,
cmd_data->sde_svc_info.data, BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: fail to pack sdea svc info\n", __FUNCTION__));
goto fail;
}
}
/* Check if all mandatory params are provided */
if (is_lcl_id && is_dest_id && is_dest_mac) {
nan_buf->count++;
sub_cmd->len += (buflen_avail - nan_buf_size);
} else {
WL_ERR(("Missing parameters\n"));
ret = BCME_USAGE_ERROR;
}
nan_buf->is_set = TRUE;
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, data_size,
&(cmd_data->status), resp_buf, data_size + NAN_IOVAR_NAME_SIZE);
if (unlikely(ret) || unlikely(cmd_data->status)) {
WL_ERR(("nan transmit failed for token %d ret = %d status = %d\n",
sd_xmit->token, ret, cmd_data->status));
goto fail;
}
WL_INFORM_MEM(("nan transmit successful for token %d\n", sd_xmit->token));
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, data_size);
}
if (resp_buf) {
MFREE(cfg->osh, resp_buf, data_size + NAN_IOVAR_NAME_SIZE);
}
NAN_MUTEX_UNLOCK();
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_get_capability(struct net_device *ndev,
struct bcm_cfg80211 *cfg, nan_hal_capabilities_t *capabilities)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
wl_nan_fw_cap_t *fw_cap = NULL;
uint16 subcmd_len;
uint32 status;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
bcm_iov_batch_subcmd_t *sub_cmd_resp = NULL;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
const bcm_xtlv_t *xtlv;
uint16 type = 0;
int len = 0;
NAN_DBG_ENTER();
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(uint8 *)(&nan_buf->cmds[0]);
ret = wl_cfg_nan_check_cmd_len(nan_buf_size,
sizeof(*fw_cap), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
fw_cap = (wl_nan_fw_cap_t *)sub_cmd->data;
sub_cmd->id = htod16(WL_NAN_CMD_GEN_FW_CAP);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(*fw_cap);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
nan_buf_size -= subcmd_len;
nan_buf->count = 1;
nan_buf->is_set = false;
memset(resp_buf, 0, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("get nan fw cap failed ret %d status %d \n",
ret, status));
goto fail;
}
sub_cmd_resp = &((bcm_iov_batch_buf_t *)(resp_buf))->cmds[0];
/* check the response buff */
xtlv = ((const bcm_xtlv_t *)&sub_cmd_resp->data[0]);
if (!xtlv) {
ret = BCME_NOTFOUND;
WL_ERR(("xtlv not found: err = %d\n", ret));
goto fail;
}
bcm_xtlv_unpack_xtlv(xtlv, &type, (uint16*)&len, NULL, BCM_XTLV_OPTION_ALIGN32);
do
{
switch (type) {
case WL_NAN_XTLV_GEN_FW_CAP:
if (len > sizeof(wl_nan_fw_cap_t)) {
ret = BCME_BADARG;
goto fail;
}
GCC_DIAGNOSTIC_PUSH_SUPPRESS_CAST();
fw_cap = (wl_nan_fw_cap_t*)xtlv->data;
GCC_DIAGNOSTIC_POP();
break;
default:
WL_ERR(("Unknown xtlv: id %u\n", type));
ret = BCME_ERROR;
break;
}
if (ret != BCME_OK) {
goto fail;
}
} while ((xtlv = bcm_next_xtlv(xtlv, &len, BCM_XTLV_OPTION_ALIGN32)));
memset(capabilities, 0, sizeof(nan_hal_capabilities_t));
capabilities->max_publishes = fw_cap->max_svc_publishes;
capabilities->max_subscribes = fw_cap->max_svc_subscribes;
capabilities->max_ndi_interfaces = fw_cap->max_lcl_ndi_interfaces;
capabilities->max_ndp_sessions = fw_cap->max_ndp_sessions;
capabilities->max_concurrent_nan_clusters = fw_cap->max_concurrent_nan_clusters;
capabilities->max_service_name_len = fw_cap->max_service_name_len;
capabilities->max_match_filter_len = fw_cap->max_match_filter_len;
capabilities->max_total_match_filter_len = fw_cap->max_total_match_filter_len;
capabilities->max_service_specific_info_len = fw_cap->max_service_specific_info_len;
capabilities->max_app_info_len = fw_cap->max_app_info_len;
capabilities->max_sdea_service_specific_info_len = fw_cap->max_sdea_svc_specific_info_len;
capabilities->max_queued_transmit_followup_msgs = fw_cap->max_queued_tx_followup_msgs;
capabilities->max_subscribe_address = fw_cap->max_subscribe_address;
capabilities->is_ndp_security_supported = fw_cap->is_ndp_security_supported;
capabilities->ndp_supported_bands = fw_cap->ndp_supported_bands;
capabilities->cipher_suites_supported = fw_cap->cipher_suites_supported_mask;
if (fw_cap->flags1 & WL_NAN_FW_CAP_FLAG1_NDPE) {
capabilities->ndpe_attr_supported = true;
}
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
NAN_DBG_EXIT();
return ret;
}
int
wl_cfgnan_get_capablities_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg, nan_hal_capabilities_t *capabilities)
{
s32 ret = BCME_OK;
dhd_pub_t *dhdp = wl_cfg80211_get_dhdp(ndev);
NAN_DBG_ENTER();
/* Do not query fw about nan if feature is not supported */
if (!FW_SUPPORTED(dhdp, nan)) {
WL_DBG(("NAN is not supported\n"));
return ret;
}
if (cfg->nancfg->nan_init_state) {
ret = wl_cfgnan_get_capability(ndev, cfg, capabilities);
if (ret != BCME_OK) {
WL_ERR(("NAN init state: %d, failed to get capability from FW[%d]\n",
cfg->nancfg->nan_init_state, ret));
goto exit;
}
} else {
/* Initialize NAN before sending iovar */
WL_ERR(("Initializing NAN\n"));
ret = wl_cfgnan_init(cfg);
if (ret != BCME_OK) {
WL_ERR(("failed to initialize NAN[%d]\n", ret));
goto fail;
}
ret = wl_cfgnan_get_capability(ndev, cfg, capabilities);
if (ret != BCME_OK) {
WL_ERR(("NAN init state: %d, failed to get capability from FW[%d]\n",
cfg->nancfg->nan_init_state, ret));
goto exit;
}
WL_ERR(("De-Initializing NAN\n"));
ret = wl_cfgnan_deinit(cfg, dhdp->up);
if (ret != BCME_OK) {
WL_ERR(("failed to de-initialize NAN[%d]\n", ret));
goto fail;
}
}
fail:
NAN_DBG_EXIT();
return ret;
exit:
/* Keeping backward campatibility */
capabilities->max_concurrent_nan_clusters = MAX_CONCURRENT_NAN_CLUSTERS;
capabilities->max_publishes = MAX_PUBLISHES;
capabilities->max_subscribes = MAX_SUBSCRIBES;
capabilities->max_service_name_len = MAX_SVC_NAME_LEN;
capabilities->max_match_filter_len = MAX_MATCH_FILTER_LEN;
capabilities->max_total_match_filter_len = MAX_TOTAL_MATCH_FILTER_LEN;
capabilities->max_service_specific_info_len = NAN_MAX_SERVICE_SPECIFIC_INFO_LEN;
capabilities->max_ndi_interfaces = NAN_MAX_NDI;
capabilities->max_ndp_sessions = MAX_NDP_SESSIONS;
capabilities->max_app_info_len = MAX_APP_INFO_LEN;
capabilities->max_queued_transmit_followup_msgs = MAX_QUEUED_TX_FOLLOUP_MSGS;
capabilities->max_sdea_service_specific_info_len = MAX_SDEA_SVC_INFO_LEN;
capabilities->max_subscribe_address = MAX_SUBSCRIBE_ADDRESS;
capabilities->cipher_suites_supported = WL_NAN_CIPHER_SUITE_SHARED_KEY_128_MASK;
capabilities->max_scid_len = MAX_SCID_LEN;
capabilities->is_ndp_security_supported = true;
capabilities->ndp_supported_bands = NDP_SUPPORTED_BANDS;
capabilities->ndpe_attr_supported = false;
ret = BCME_OK;
NAN_DBG_EXIT();
return ret;
}
bool wl_cfgnan_is_enabled(struct bcm_cfg80211 *cfg)
{
wl_nancfg_t *nancfg = cfg->nancfg;
if (nancfg) {
if (nancfg->nan_init_state && nancfg->nan_enable) {
return TRUE;
}
}
return FALSE;
}
static int
wl_cfgnan_init(struct bcm_cfg80211 *cfg)
{
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
uint32 status;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
uint8 buf[NAN_IOCTL_BUF_SIZE];
bcm_iov_batch_buf_t *nan_buf = (bcm_iov_batch_buf_t*)buf;
NAN_DBG_ENTER();
if (cfg->nancfg->nan_init_state) {
WL_ERR(("nan initialized/nmi exists\n"));
return BCME_OK;
}
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
ret = wl_cfgnan_init_handler(&nan_buf->cmds[0], &nan_buf_size, true);
if (unlikely(ret)) {
WL_ERR(("init handler sub_cmd set failed\n"));
goto fail;
}
nan_buf->count++;
nan_buf->is_set = true;
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(bcmcfg_to_prmry_ndev(cfg), cfg,
nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("nan init handler failed ret %d status %d\n",
ret, status));
goto fail;
}
#ifdef WL_NAN_DISC_CACHE
/* malloc for disc result */
cfg->nancfg->nan_disc_cache = MALLOCZ(cfg->osh,
NAN_MAX_CACHE_DISC_RESULT * sizeof(nan_disc_result_cache));
if (!cfg->nancfg->nan_disc_cache) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
#endif /* WL_NAN_DISC_CACHE */
cfg->nancfg->nan_init_state = true;
return ret;
fail:
NAN_DBG_EXIT();
return ret;
}
static void
wl_cfgnan_deinit_cleanup(struct bcm_cfg80211 *cfg)
{
uint8 i = 0;
wl_nancfg_t *nancfg = cfg->nancfg;
nancfg->nan_dp_count = 0;
nancfg->nan_init_state = false;
#ifdef WL_NAN_DISC_CACHE
if (nancfg->nan_disc_cache) {
for (i = 0; i < NAN_MAX_CACHE_DISC_RESULT; i++) {
if (nancfg->nan_disc_cache[i].tx_match_filter.data) {
MFREE(cfg->osh, nancfg->nan_disc_cache[i].tx_match_filter.data,
nancfg->nan_disc_cache[i].tx_match_filter.dlen);
}
if (nancfg->nan_disc_cache[i].svc_info.data) {
MFREE(cfg->osh, nancfg->nan_disc_cache[i].svc_info.data,
nancfg->nan_disc_cache[i].svc_info.dlen);
}
}
MFREE(cfg->osh, nancfg->nan_disc_cache,
NAN_MAX_CACHE_DISC_RESULT * sizeof(nan_disc_result_cache));
nancfg->nan_disc_cache = NULL;
}
nancfg->nan_disc_count = 0;
bzero(nancfg->svc_info, NAN_MAX_SVC_INST * sizeof(nan_svc_info_t));
bzero(nancfg->nan_ranging_info, NAN_MAX_RANGING_INST * sizeof(nan_ranging_inst_t));
#endif /* WL_NAN_DISC_CACHE */
return;
}
static int
wl_cfgnan_deinit(struct bcm_cfg80211 *cfg, uint8 busstate)
{
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
uint32 status;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
uint8 buf[NAN_IOCTL_BUF_SIZE];
bcm_iov_batch_buf_t *nan_buf = (bcm_iov_batch_buf_t*)buf;
wl_nancfg_t *nancfg = cfg->nancfg;
NAN_DBG_ENTER();
NAN_MUTEX_LOCK();
if (!nancfg->nan_init_state) {
WL_ERR(("nan is not initialized/nmi doesnt exists\n"));
ret = BCME_OK;
goto fail;
}
if (busstate != DHD_BUS_DOWN) {
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
WL_DBG(("nan deinit\n"));
ret = wl_cfgnan_init_handler(&nan_buf->cmds[0], &nan_buf_size, false);
if (unlikely(ret)) {
WL_ERR(("deinit handler sub_cmd set failed\n"));
} else {
nan_buf->count++;
nan_buf->is_set = true;
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(cfg->wdev->netdev, cfg,
nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("nan init handler failed ret %d status %d\n",
ret, status));
}
}
}
wl_cfgnan_deinit_cleanup(cfg);
fail:
if (!nancfg->mac_rand && !ETHER_ISNULLADDR(nancfg->nan_nmi_mac)) {
wl_release_vif_macaddr(cfg, nancfg->nan_nmi_mac, WL_IF_TYPE_NAN_NMI);
}
NAN_MUTEX_UNLOCK();
NAN_DBG_EXIT();
return ret;
}
static int
wl_cfgnan_get_ndi_macaddr(struct bcm_cfg80211 *cfg, u8* mac_addr)
{
int i = 0;
int ret = BCME_OK;
bool rand_mac = cfg->nancfg->mac_rand;
BCM_REFERENCE(i);
if (rand_mac) {
/* ensure nmi != ndi */
do {
RANDOM_BYTES(mac_addr, ETHER_ADDR_LEN);
/* restore mcast and local admin bits to 0 and 1 */
ETHER_SET_UNICAST(mac_addr);
ETHER_SET_LOCALADDR(mac_addr);
i++;
if (i == NAN_RAND_MAC_RETRIES) {
break;
}
} while (eacmp(cfg->nancfg->nan_nmi_mac, mac_addr) == 0);
if (i == NAN_RAND_MAC_RETRIES) {
if (eacmp(cfg->nancfg->nan_nmi_mac, mac_addr) == 0) {
WL_ERR(("\nCouldn't generate rand NDI which != NMI\n"));
ret = BCME_NORESOURCE;
goto fail;
}
}
} else {
if (wl_get_vif_macaddr(cfg, WL_IF_TYPE_NAN,
mac_addr) != BCME_OK) {
ret = -EINVAL;
WL_ERR(("Failed to get mac addr for NDI\n"));
goto fail;
}
}
fail:
return ret;
}
int
wl_cfgnan_data_path_iface_create_delete_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg, char *ifname, uint16 type, uint8 busstate)
{
u8 mac_addr[ETH_ALEN];
s32 ret = BCME_OK;
s32 idx;
struct wireless_dev *wdev;
NAN_DBG_ENTER();
if (busstate != DHD_BUS_DOWN) {
ASSERT(cfg->nancfg->ndi);
if (type == NAN_WIFI_SUBCMD_DATA_PATH_IFACE_CREATE) {
if ((idx = wl_cfgnan_get_ndi_idx(cfg)) < 0) {
WL_ERR(("No free idx for NAN NDI\n"));
ret = BCME_NORESOURCE;
goto fail;
}
ret = wl_cfgnan_get_ndi_macaddr(cfg, mac_addr);
if (ret != BCME_OK) {
WL_ERR(("Couldn't get mac addr for NDI ret %d\n", ret));
goto fail;
}
wdev = wl_cfg80211_add_if(cfg, ndev, WL_IF_TYPE_NAN,
ifname, mac_addr);
if (!wdev) {
ret = -ENODEV;
WL_ERR(("Failed to create NDI iface = %s, wdev is NULL\n", ifname));
goto fail;
}
/* Store the iface name to pub data so that it can be used
* during NAN enable
*/
wl_cfgnan_add_ndi_data(cfg, idx, ifname);
cfg->nancfg->ndi[idx].created = true;
/* Store nan ndev */
cfg->nancfg->ndi[idx].nan_ndev = wdev_to_ndev(wdev);
} else if (type == NAN_WIFI_SUBCMD_DATA_PATH_IFACE_DELETE) {
ret = wl_cfg80211_del_if(cfg, ndev, NULL, ifname);
if (ret == BCME_OK) {
if (wl_cfgnan_del_ndi_data(cfg, ifname) < 0) {
WL_ERR(("Failed to find matching data for ndi:%s\n",
ifname));
}
} else if (ret == -ENODEV) {
WL_INFORM(("Already deleted: %s\n", ifname));
ret = BCME_OK;
} else if (ret != BCME_OK) {
WL_ERR(("failed to delete NDI[%d]\n", ret));
}
}
} else {
ret = -ENODEV;
WL_ERR(("Bus is already down, no dev found to remove, ret = %d\n", ret));
}
fail:
NAN_DBG_EXIT();
return ret;
}
/*
* Return data peer from peer list
* for peer_addr
* NULL if not found
*/
static nan_ndp_peer_t *
wl_cfgnan_data_get_peer(struct bcm_cfg80211 *cfg,
struct ether_addr *peer_addr)
{
uint8 i;
nan_ndp_peer_t* peer = cfg->nancfg->nan_ndp_peer_info;
if (!peer) {
WL_ERR(("wl_cfgnan_data_get_peer: nan_ndp_peer_info is NULL\n"));
goto exit;
}
for (i = 0; i < cfg->nancfg->max_ndp_count; i++) {
if (peer[i].peer_dp_state != NAN_PEER_DP_NOT_CONNECTED &&
(!memcmp(peer_addr, &peer[i].peer_addr, ETHER_ADDR_LEN))) {
return &peer[i];
}
}
exit:
return NULL;
}
/*
* Returns True if
* datapath exists for nan cfg
* for given peer
*/
bool
wl_cfgnan_data_dp_exists_with_peer(struct bcm_cfg80211 *cfg,
struct ether_addr *peer_addr)
{
bool ret = FALSE;
nan_ndp_peer_t* peer = NULL;
if ((cfg->nancfg->nan_init_state == FALSE) ||
(cfg->nancfg->nan_enable == FALSE)) {
goto exit;
}
/* check for peer exist */
peer = wl_cfgnan_data_get_peer(cfg, peer_addr);
if (peer) {
ret = TRUE;
}
exit:
return ret;
}
/*
* As of now API only available
* for setting state to CONNECTED
* if applicable
*/
static void
wl_cfgnan_data_set_peer_dp_state(struct bcm_cfg80211 *cfg,
struct ether_addr *peer_addr, nan_peer_dp_state_t state)
{
nan_ndp_peer_t* peer = NULL;
/* check for peer exist */
peer = wl_cfgnan_data_get_peer(cfg, peer_addr);
if (!peer) {
goto end;
}
peer->peer_dp_state = state;
end:
return;
}
/* Adds peer to nan data peer list */
void
wl_cfgnan_data_add_peer(struct bcm_cfg80211 *cfg,
struct ether_addr *peer_addr)
{
uint8 i;
nan_ndp_peer_t* peer = NULL;
/* check for peer exist */
peer = wl_cfgnan_data_get_peer(cfg, peer_addr);
if (peer) {
peer->dp_count++;
goto end;
}
peer = cfg->nancfg->nan_ndp_peer_info;
for (i = 0; i < cfg->nancfg->max_ndp_count; i++) {
if (peer[i].peer_dp_state == NAN_PEER_DP_NOT_CONNECTED) {
break;
}
}
if (i == NAN_MAX_NDP_PEER) {
WL_DBG(("DP Peer list full, Droopping add peer req\n"));
goto end;
}
/* Add peer to list */
memcpy(&peer[i].peer_addr, peer_addr, ETHER_ADDR_LEN);
peer[i].dp_count = 1;
peer[i].peer_dp_state = NAN_PEER_DP_CONNECTING;
end:
return;
}
/* Removes nan data peer from peer list */
void
wl_cfgnan_data_remove_peer(struct bcm_cfg80211 *cfg,
struct ether_addr *peer_addr)
{
nan_ndp_peer_t* peer = NULL;
/* check for peer exist */
peer = wl_cfgnan_data_get_peer(cfg, peer_addr);
if (!peer) {
WL_DBG(("DP Peer not present in list, "
"Droopping remove peer req\n"));
goto end;
}
peer->dp_count--;
if (peer->dp_count == 0) {
/* No more NDPs, delete entry */
memset(peer, 0, sizeof(nan_ndp_peer_t));
} else {
/* Set peer dp state to connected if any ndp still exits */
peer->peer_dp_state = NAN_PEER_DP_CONNECTED;
}
end:
return;
}
int
wl_cfgnan_data_path_request_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg, nan_datapath_cmd_data_t *cmd_data,
uint8 *ndp_instance_id)
{
s32 ret = BCME_OK;
bcm_iov_batch_buf_t *nan_buf = NULL;
wl_nan_dp_req_t *datareq = NULL;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
uint16 buflen_avail;
uint8 *pxtlv;
struct wireless_dev *wdev;
uint16 nan_buf_size;
uint8 *resp_buf = NULL;
/* Considering fixed params */
uint16 data_size = WL_NAN_OBUF_DATA_OFFSET +
OFFSETOF(wl_nan_dp_req_t, tlv_params);
data_size = ALIGN_SIZE(data_size, 4);
ret = wl_cfgnan_aligned_data_size_of_opt_dp_params(cfg, &data_size, cmd_data);
if (unlikely(ret)) {
WL_ERR(("Failed to get alligned size of optional params\n"));
goto fail;
}
nan_buf_size = data_size;
NAN_DBG_ENTER();
mutex_lock(&cfg->if_sync);
NAN_MUTEX_LOCK();
#ifdef WL_IFACE_MGMT
if ((ret = wl_cfg80211_handle_if_role_conflict(cfg, WL_IF_TYPE_NAN)) < 0) {
WL_ERR(("Conflicting iface found to be active\n"));
ret = BCME_UNSUPPORTED;
goto fail;
}
#endif /* WL_IFACE_MGMT */
#ifdef RTT_SUPPORT
/* cancel any ongoing RTT session with peer
* as we donot support DP and RNG to same peer
*/
wl_cfgnan_handle_dp_ranging_concurrency(cfg, &cmd_data->mac_addr,
RTT_GEO_SUSPN_HOST_NDP_TRIGGER);
#endif /* RTT_SUPPORT */
nan_buf = MALLOCZ(cfg->osh, data_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
resp_buf = MALLOCZ(cfg->osh, data_size + NAN_IOVAR_NAME_SIZE);
if (!resp_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
ret = wl_cfgnan_set_nan_avail(bcmcfg_to_prmry_ndev(cfg),
cfg, &cmd_data->avail_params, WL_AVAIL_LOCAL);
if (unlikely(ret)) {
WL_ERR(("Failed to set avail value with type local\n"));
goto fail;
}
ret = wl_cfgnan_set_nan_avail(bcmcfg_to_prmry_ndev(cfg),
cfg, &cmd_data->avail_params, WL_AVAIL_NDC);
if (unlikely(ret)) {
WL_ERR(("Failed to set avail value with type ndc\n"));
goto fail;
}
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(&nan_buf->cmds[0]);
datareq = (wl_nan_dp_req_t *)(sub_cmd->data);
/* setting default data path type to unicast */
datareq->type = WL_NAN_DP_TYPE_UNICAST;
if (cmd_data->pub_id) {
datareq->pub_id = cmd_data->pub_id;
}
if (!ETHER_ISNULLADDR(&cmd_data->mac_addr.octet)) {
ret = memcpy_s(&datareq->peer_mac, ETHER_ADDR_LEN,
&cmd_data->mac_addr, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy ether addr provided\n"));
goto fail;
}
} else {
WL_ERR(("Invalid ether addr provided\n"));
ret = BCME_BADARG;
goto fail;
}
/* Retrieve mac from given iface name */
wdev = wl_cfg80211_get_wdev_from_ifname(cfg,
(char *)cmd_data->ndp_iface);
if (!wdev || ETHER_ISNULLADDR(wdev->netdev->dev_addr)) {
ret = -EINVAL;
WL_ERR(("Failed to retrieve wdev/dev addr for ndp_iface = %s\n",
(char *)cmd_data->ndp_iface));
goto fail;
}
if (!ETHER_ISNULLADDR(wdev->netdev->dev_addr)) {
ret = memcpy_s(&datareq->ndi, ETHER_ADDR_LEN,
wdev->netdev->dev_addr, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy ether addr provided\n"));
goto fail;
}
WL_TRACE(("%s: Retrieved ndi mac " MACDBG "\n",
__FUNCTION__, MAC2STRDBG(datareq->ndi.octet)));
} else {
WL_ERR(("Invalid NDI addr retrieved\n"));
ret = BCME_BADARG;
goto fail;
}
datareq->ndl_qos.min_slots = NAN_NDL_QOS_MIN_SLOT_NO_PREF;
datareq->ndl_qos.max_latency = NAN_NDL_QOS_MAX_LAT_NO_PREF;
/* Fill the sub_command block */
sub_cmd->id = htod16(WL_NAN_CMD_DATA_DATAREQ);
sub_cmd->len = sizeof(sub_cmd->u.options) +
OFFSETOF(wl_nan_dp_req_t, tlv_params);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
pxtlv = (uint8 *)&datareq->tlv_params;
nan_buf_size -= (sub_cmd->len +
OFFSETOF(bcm_iov_batch_subcmd_t, u.options));
buflen_avail = nan_buf_size;
if (cmd_data->svc_info.data && cmd_data->svc_info.dlen) {
ret = bcm_pack_xtlv_entry(&pxtlv, &nan_buf_size,
WL_NAN_XTLV_SD_SVC_INFO, cmd_data->svc_info.dlen,
cmd_data->svc_info.data,
BCM_XTLV_OPTION_ALIGN32);
if (ret != BCME_OK) {
WL_ERR(("unable to process svc_spec_info: %d\n", ret));
goto fail;
}
/* If NDPE is enabled, duplicating svc_info and sending it as part of NDPE TLV list
* too along with SD SVC INFO, as FW is considering both of them as different
* entities where as framework is sending both of them in same variable
* (cmd_data->svc_info). FW will decide which one to use based on
* peer's capability (NDPE capable or not)
*/
if (cfg->nancfg->ndpe_enabled) {
ret = bcm_pack_xtlv_entry(&pxtlv, &nan_buf_size,
WL_NAN_XTLV_SD_NDPE_TLV_LIST, cmd_data->svc_info.dlen,
cmd_data->svc_info.data,
BCM_XTLV_OPTION_ALIGN32);
if (ret != BCME_OK) {
WL_ERR(("unable to process NDPE TLV list: %d\n", ret));
goto fail;
}
}
datareq->flags |= WL_NAN_DP_FLAG_SVC_INFO;
}
/* Security elements */
if (cmd_data->csid) {
WL_TRACE(("Cipher suite type is present, pack it\n"));
ret = bcm_pack_xtlv_entry(&pxtlv, &nan_buf_size,
WL_NAN_XTLV_CFG_SEC_CSID, sizeof(nan_sec_csid_e),
(uint8*)&cmd_data->csid, BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: fail to pack on csid\n", __FUNCTION__));
goto fail;
}
}
if (cmd_data->ndp_cfg.security_cfg) {
if ((cmd_data->key_type == NAN_SECURITY_KEY_INPUT_PMK) ||
(cmd_data->key_type == NAN_SECURITY_KEY_INPUT_PASSPHRASE)) {
if (cmd_data->key.data && cmd_data->key.dlen) {
WL_TRACE(("optional pmk present, pack it\n"));
ret = bcm_pack_xtlv_entry(&pxtlv, &nan_buf_size,
WL_NAN_XTLV_CFG_SEC_PMK, cmd_data->key.dlen,
cmd_data->key.data, BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: fail to pack on WL_NAN_XTLV_CFG_SEC_PMK\n",
__FUNCTION__));
goto fail;
}
}
} else {
WL_ERR(("Invalid security key type\n"));
ret = BCME_BADARG;
goto fail;
}
if ((cmd_data->svc_hash.dlen == WL_NAN_SVC_HASH_LEN) &&
(cmd_data->svc_hash.data)) {
WL_TRACE(("svc hash present, pack it\n"));
ret = bcm_pack_xtlv_entry(&pxtlv, &nan_buf_size,
WL_NAN_XTLV_CFG_SVC_HASH, WL_NAN_SVC_HASH_LEN,
cmd_data->svc_hash.data, BCM_XTLV_OPTION_ALIGN32);
if (ret != BCME_OK) {
WL_ERR(("%s: fail to pack WL_NAN_XTLV_CFG_SVC_HASH\n",
__FUNCTION__));
goto fail;
}
} else {
#ifdef WL_NAN_DISC_CACHE
/* check in cache */
nan_disc_result_cache *cache;
cache = wl_cfgnan_get_disc_result(cfg,
datareq->pub_id, &datareq->peer_mac);
if (!cache) {
ret = BCME_ERROR;
WL_ERR(("invalid svc hash data or length = %d\n",
cmd_data->svc_hash.dlen));
goto fail;
}
WL_TRACE(("svc hash present, pack it\n"));
ret = bcm_pack_xtlv_entry(&pxtlv, &nan_buf_size,
WL_NAN_XTLV_CFG_SVC_HASH, WL_NAN_SVC_HASH_LEN,
cache->svc_hash, BCM_XTLV_OPTION_ALIGN32);
if (ret != BCME_OK) {
WL_ERR(("%s: fail to pack WL_NAN_XTLV_CFG_SVC_HASH\n",
__FUNCTION__));
goto fail;
}
#else
ret = BCME_ERROR;
WL_ERR(("invalid svc hash data or length = %d\n",
cmd_data->svc_hash.dlen));
goto fail;
#endif /* WL_NAN_DISC_CACHE */
}
/* If the Data req is for secure data connection */
datareq->flags |= WL_NAN_DP_FLAG_SECURITY;
}
sub_cmd->len += (buflen_avail - nan_buf_size);
nan_buf->is_set = false;
nan_buf->count++;
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, data_size,
&(cmd_data->status), resp_buf, data_size + NAN_IOVAR_NAME_SIZE);
if (unlikely(ret) || unlikely(cmd_data->status)) {
WL_ERR(("nan data path request handler failed, ret = %d,"
" status %d, peer: " MACDBG "\n",
ret, cmd_data->status, MAC2STRDBG(&(cmd_data->mac_addr))));
goto fail;
}
/* check the response buff */
if (ret == BCME_OK) {
ret = process_resp_buf(resp_buf + WL_NAN_OBUF_DATA_OFFSET,
ndp_instance_id, WL_NAN_CMD_DATA_DATAREQ);
cmd_data->ndp_instance_id = *ndp_instance_id;
}
WL_INFORM_MEM(("[NAN] DP request successfull (ndp_id:%d), peer: " MACDBG " \n",
cmd_data->ndp_instance_id, MAC2STRDBG(&cmd_data->mac_addr)));
/* Add peer to data ndp peer list */
wl_cfgnan_data_add_peer(cfg, &datareq->peer_mac);
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, data_size);
}
if (resp_buf) {
MFREE(cfg->osh, resp_buf, data_size + NAN_IOVAR_NAME_SIZE);
}
NAN_MUTEX_UNLOCK();
mutex_unlock(&cfg->if_sync);
NAN_DBG_EXIT();
return ret;
}
int
wl_cfgnan_data_path_response_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg, nan_datapath_cmd_data_t *cmd_data)
{
s32 ret = BCME_OK;
bcm_iov_batch_buf_t *nan_buf = NULL;
wl_nan_dp_resp_t *dataresp = NULL;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
uint16 buflen_avail;
uint8 *pxtlv;
struct wireless_dev *wdev;
uint16 nan_buf_size;
uint8 *resp_buf = NULL;
/* Considering fixed params */
uint16 data_size = WL_NAN_OBUF_DATA_OFFSET +
OFFSETOF(wl_nan_dp_resp_t, tlv_params);
data_size = ALIGN_SIZE(data_size, 4);
ret = wl_cfgnan_aligned_data_size_of_opt_dp_params(cfg, &data_size, cmd_data);
if (unlikely(ret)) {
WL_ERR(("Failed to get alligned size of optional params\n"));
goto fail;
}
nan_buf_size = data_size;
NAN_DBG_ENTER();
mutex_lock(&cfg->if_sync);
NAN_MUTEX_LOCK();
#ifdef WL_IFACE_MGMT
if ((ret = wl_cfg80211_handle_if_role_conflict(cfg, WL_IF_TYPE_NAN)) < 0) {
WL_ERR(("Conflicting iface found to be active\n"));
ret = BCME_UNSUPPORTED;
goto fail;
}
#endif /* WL_IFACE_MGMT */
nan_buf = MALLOCZ(cfg->osh, data_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
resp_buf = MALLOCZ(cfg->osh, data_size + NAN_IOVAR_NAME_SIZE);
if (!resp_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
ret = wl_cfgnan_set_nan_avail(bcmcfg_to_prmry_ndev(cfg),
cfg, &cmd_data->avail_params, WL_AVAIL_LOCAL);
if (unlikely(ret)) {
WL_ERR(("Failed to set avail value with type local\n"));
goto fail;
}
ret = wl_cfgnan_set_nan_avail(bcmcfg_to_prmry_ndev(cfg),
cfg, &cmd_data->avail_params, WL_AVAIL_NDC);
if (unlikely(ret)) {
WL_ERR(("Failed to set avail value with type ndc\n"));
goto fail;
}
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(&nan_buf->cmds[0]);
dataresp = (wl_nan_dp_resp_t *)(sub_cmd->data);
/* Setting default data path type to unicast */
dataresp->type = WL_NAN_DP_TYPE_UNICAST;
/* Changing status value as per fw convention */
dataresp->status = cmd_data->rsp_code ^= 1;
dataresp->reason_code = 0;
/* ndp instance id must be from 1 to 255, 0 is reserved */
if (cmd_data->ndp_instance_id < NAN_ID_MIN ||
cmd_data->ndp_instance_id > NAN_ID_MAX) {
WL_ERR(("Invalid ndp instance id: %d\n", cmd_data->ndp_instance_id));
ret = BCME_BADARG;
goto fail;
}
dataresp->ndp_id = cmd_data->ndp_instance_id;
/* Retrieved initiator ndi from NanDataPathRequestInd */
if (!ETHER_ISNULLADDR(&cfg->nancfg->initiator_ndi.octet)) {
ret = memcpy_s(&dataresp->mac_addr, ETHER_ADDR_LEN,
&cfg->nancfg->initiator_ndi, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy initiator ndi\n"));
goto fail;
}
} else {
WL_ERR(("Invalid ether addr retrieved\n"));
ret = BCME_BADARG;
goto fail;
}
/* Interface is not mandatory, when it is a reject from framework */
if (dataresp->status != WL_NAN_DP_STATUS_REJECTED) {
#ifdef RTT_SUPPORT
/* cancel any ongoing RTT session with peer
* as we donot support DP and RNG to same peer
*/
wl_cfgnan_handle_dp_ranging_concurrency(cfg, &cmd_data->mac_addr,
RTT_GEO_SUSPN_HOST_NDP_TRIGGER);
#endif /* RTT_SUPPORT */
/* Retrieve mac from given iface name */
wdev = wl_cfg80211_get_wdev_from_ifname(cfg,
(char *)cmd_data->ndp_iface);
if (!wdev || ETHER_ISNULLADDR(wdev->netdev->dev_addr)) {
ret = -EINVAL;
WL_ERR(("Failed to retrieve wdev/dev addr for ndp_iface = %s\n",
(char *)cmd_data->ndp_iface));
goto fail;
}
if (!ETHER_ISNULLADDR(wdev->netdev->dev_addr)) {
ret = memcpy_s(&dataresp->ndi, ETHER_ADDR_LEN,
wdev->netdev->dev_addr, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy responder ndi\n"));
goto fail;
}
WL_TRACE(("%s: Retrieved ndi mac " MACDBG "\n",
__FUNCTION__, MAC2STRDBG(dataresp->ndi.octet)));
} else {
WL_ERR(("Invalid NDI addr retrieved\n"));
ret = BCME_BADARG;
goto fail;
}
}
dataresp->ndl_qos.min_slots = NAN_NDL_QOS_MIN_SLOT_NO_PREF;
dataresp->ndl_qos.max_latency = NAN_NDL_QOS_MAX_LAT_NO_PREF;
/* Fill the sub_command block */
sub_cmd->id = htod16(WL_NAN_CMD_DATA_DATARESP);
sub_cmd->len = sizeof(sub_cmd->u.options) +
OFFSETOF(wl_nan_dp_resp_t, tlv_params);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
pxtlv = (uint8 *)&dataresp->tlv_params;
nan_buf_size -= (sub_cmd->len +
OFFSETOF(bcm_iov_batch_subcmd_t, u.options));
buflen_avail = nan_buf_size;
if (cmd_data->svc_info.data && cmd_data->svc_info.dlen) {
ret = bcm_pack_xtlv_entry(&pxtlv, &nan_buf_size,
WL_NAN_XTLV_SD_SVC_INFO, cmd_data->svc_info.dlen,
cmd_data->svc_info.data,
BCM_XTLV_OPTION_ALIGN32);
if (ret != BCME_OK) {
WL_ERR(("unable to process svc_spec_info: %d\n", ret));
goto fail;
}
/* If NDPE is enabled, duplicating svc_info and sending it as part of NDPE TLV list
* too along with SD SVC INFO, as FW is considering both of them as different
* entities where as framework is sending both of them in same variable
* (cmd_data->svc_info). FW will decide which one to use based on
* peer's capability (NDPE capable or not)
*/
if (cfg->nancfg->ndpe_enabled) {
ret = bcm_pack_xtlv_entry(&pxtlv, &nan_buf_size,
WL_NAN_XTLV_SD_NDPE_TLV_LIST, cmd_data->svc_info.dlen,
cmd_data->svc_info.data,
BCM_XTLV_OPTION_ALIGN32);
if (ret != BCME_OK) {
WL_ERR(("unable to process NDPE TLV list: %d\n", ret));
goto fail;
}
}
dataresp->flags |= WL_NAN_DP_FLAG_SVC_INFO;
}
/* Security elements */
if (cmd_data->csid) {
WL_TRACE(("Cipher suite type is present, pack it\n"));
ret = bcm_pack_xtlv_entry(&pxtlv, &nan_buf_size,
WL_NAN_XTLV_CFG_SEC_CSID, sizeof(nan_sec_csid_e),
(uint8*)&cmd_data->csid, BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: fail to pack csid\n", __FUNCTION__));
goto fail;
}
}
if (cmd_data->ndp_cfg.security_cfg) {
if ((cmd_data->key_type == NAN_SECURITY_KEY_INPUT_PMK) ||
(cmd_data->key_type == NAN_SECURITY_KEY_INPUT_PASSPHRASE)) {
if (cmd_data->key.data && cmd_data->key.dlen) {
WL_TRACE(("optional pmk present, pack it\n"));
ret = bcm_pack_xtlv_entry(&pxtlv, &nan_buf_size,
WL_NAN_XTLV_CFG_SEC_PMK, cmd_data->key.dlen,
cmd_data->key.data, BCM_XTLV_OPTION_ALIGN32);
if (unlikely(ret)) {
WL_ERR(("%s: fail to pack WL_NAN_XTLV_CFG_SEC_PMK\n",
__FUNCTION__));
goto fail;
}
}
} else {
WL_ERR(("Invalid security key type\n"));
ret = BCME_BADARG;
goto fail;
}
if ((cmd_data->svc_hash.dlen == WL_NAN_SVC_HASH_LEN) &&
(cmd_data->svc_hash.data)) {
WL_TRACE(("svc hash present, pack it\n"));
ret = bcm_pack_xtlv_entry(&pxtlv, &nan_buf_size,
WL_NAN_XTLV_CFG_SVC_HASH, WL_NAN_SVC_HASH_LEN,
cmd_data->svc_hash.data,
BCM_XTLV_OPTION_ALIGN32);
if (ret != BCME_OK) {
WL_ERR(("%s: fail to pack WL_NAN_XTLV_CFG_SVC_HASH\n",
__FUNCTION__));
goto fail;
}
}
/* If the Data resp is for secure data connection */
dataresp->flags |= WL_NAN_DP_FLAG_SECURITY;
}
sub_cmd->len += (buflen_avail - nan_buf_size);
nan_buf->is_set = false;
nan_buf->count++;
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, data_size,
&(cmd_data->status), resp_buf, data_size + NAN_IOVAR_NAME_SIZE);
if (unlikely(ret) || unlikely(cmd_data->status)) {
WL_ERR(("nan data path response handler failed, error = %d, status %d\n",
ret, cmd_data->status));
goto fail;
}
WL_INFORM_MEM(("[NAN] DP response successfull (ndp_id:%d)\n", dataresp->ndp_id));
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, data_size);
}
if (resp_buf) {
MFREE(cfg->osh, resp_buf, data_size + NAN_IOVAR_NAME_SIZE);
}
NAN_MUTEX_UNLOCK();
mutex_unlock(&cfg->if_sync);
NAN_DBG_EXIT();
return ret;
}
int wl_cfgnan_data_path_end_handler(struct net_device *ndev,
struct bcm_cfg80211 *cfg, nan_data_path_id ndp_instance_id,
int *status)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
wl_nan_dp_end_t *dataend = NULL;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
dhd_pub_t *dhdp = wl_cfg80211_get_dhdp(ndev);
NAN_DBG_ENTER();
NAN_MUTEX_LOCK();
if (!dhdp->up) {
WL_ERR(("bus is already down, hence blocking nan dp end\n"));
ret = BCME_OK;
goto fail;
}
if (!cfg->nancfg->nan_enable) {
WL_ERR(("nan is not enabled, nan dp end blocked\n"));
ret = BCME_OK;
goto fail;
}
/* ndp instance id must be from 1 to 255, 0 is reserved */
if (ndp_instance_id < NAN_ID_MIN ||
ndp_instance_id > NAN_ID_MAX) {
WL_ERR(("Invalid ndp instance id: %d\n", ndp_instance_id));
ret = BCME_BADARG;
goto fail;
}
nan_buf = MALLOCZ(cfg->osh, nan_buf_size);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(&nan_buf->cmds[0]);
dataend = (wl_nan_dp_end_t *)(sub_cmd->data);
/* Fill sub_cmd block */
sub_cmd->id = htod16(WL_NAN_CMD_DATA_DATAEND);
sub_cmd->len = sizeof(sub_cmd->u.options) +
sizeof(*dataend);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
dataend->lndp_id = ndp_instance_id;
/*
* Currently fw requires ndp_id and reason to end the data path
* But wifi_nan.h takes ndp_instances_count and ndp_id.
* Will keep reason = accept always.
*/
dataend->status = 1;
nan_buf->is_set = true;
nan_buf->count++;
nan_buf_size -= (sub_cmd->len +
OFFSETOF(bcm_iov_batch_subcmd_t, u.options));
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size,
status, (void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(*status)) {
WL_ERR(("nan data path end handler failed, error = %d status %d\n",
ret, *status));
goto fail;
}
WL_INFORM_MEM(("[NAN] DP end successfull (ndp_id:%d)\n",
dataend->lndp_id));
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
NAN_MUTEX_UNLOCK();
NAN_DBG_EXIT();
return ret;
}
#ifdef WL_NAN_DISC_CACHE
int wl_cfgnan_sec_info_handler(struct bcm_cfg80211 *cfg,
nan_datapath_sec_info_cmd_data_t *cmd_data, nan_hal_resp_t *nan_req_resp)
{
s32 ret = BCME_NOTFOUND;
/* check in cache */
nan_disc_result_cache *disc_cache = NULL;
nan_svc_info_t *svc_info = NULL;
NAN_DBG_ENTER();
NAN_MUTEX_LOCK();
if (!cfg->nancfg->nan_init_state) {
WL_ERR(("nan is not initialized/nmi doesnt exists\n"));
ret = BCME_NOTENABLED;
goto fail;
}
/* datapath request context */
if (cmd_data->pub_id && !ETHER_ISNULLADDR(&cmd_data->mac_addr)) {
disc_cache = wl_cfgnan_get_disc_result(cfg,
cmd_data->pub_id, &cmd_data->mac_addr);
WL_DBG(("datapath request: PUB ID: = %d\n",
cmd_data->pub_id));
if (disc_cache) {
(void)memcpy_s(nan_req_resp->svc_hash, WL_NAN_SVC_HASH_LEN,
disc_cache->svc_hash, WL_NAN_SVC_HASH_LEN);
ret = BCME_OK;
} else {
WL_ERR(("disc_cache is NULL\n"));
goto fail;
}
}
/* datapath response context */
if (cmd_data->ndp_instance_id) {
WL_DBG(("datapath response: NDP ID: = %d\n",
cmd_data->ndp_instance_id));
svc_info = wl_cfgnan_get_svc_inst(cfg, 0, cmd_data->ndp_instance_id);
/* Note: svc_info will not be present in OOB cases
* In such case send NMI alone and let HAL handle if
* svc_hash is mandatory
*/
if (svc_info) {
WL_DBG(("svc hash present, pack it\n"));
(void)memcpy_s(nan_req_resp->svc_hash, WL_NAN_SVC_HASH_LEN,
svc_info->svc_hash, WL_NAN_SVC_HASH_LEN);
} else {
WL_INFORM_MEM(("svc_info not present..assuming OOB DP\n"));
}
/* Always send NMI */
(void)memcpy_s(nan_req_resp->pub_nmi, ETHER_ADDR_LEN,
cfg->nancfg->nan_nmi_mac, ETHER_ADDR_LEN);
ret = BCME_OK;
}
fail:
NAN_MUTEX_UNLOCK();
NAN_DBG_EXIT();
return ret;
}
#endif /* WL_NAN_DISC_CACHE */
#ifdef RTT_SUPPORT
static s32 wl_nan_cache_to_event_data(nan_disc_result_cache *cache,
nan_event_data_t *nan_event_data, osl_t *osh)
{
s32 ret = BCME_OK;
NAN_DBG_ENTER();
nan_event_data->pub_id = cache->pub_id;
nan_event_data->sub_id = cache->sub_id;
nan_event_data->publish_rssi = cache->publish_rssi;
nan_event_data->peer_cipher_suite = cache->peer_cipher_suite;
ret = memcpy_s(&nan_event_data->remote_nmi, ETHER_ADDR_LEN,
&cache->peer, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy cached peer nan nmi\n"));
goto fail;
}
if (cache->svc_info.dlen && cache->svc_info.data) {
nan_event_data->svc_info.dlen = cache->svc_info.dlen;
nan_event_data->svc_info.data =
MALLOCZ(osh, nan_event_data->svc_info.dlen);
if (!nan_event_data->svc_info.data) {
WL_ERR(("%s: memory allocation failed\n", __FUNCTION__));
nan_event_data->svc_info.dlen = 0;
ret = -ENOMEM;
goto fail;
}
ret = memcpy_s(nan_event_data->svc_info.data, nan_event_data->svc_info.dlen,
cache->svc_info.data, cache->svc_info.dlen);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy cached svc info data\n"));
goto fail;
}
}
if (cache->tx_match_filter.dlen && cache->tx_match_filter.data) {
nan_event_data->tx_match_filter.dlen = cache->tx_match_filter.dlen;
nan_event_data->tx_match_filter.data =
MALLOCZ(osh, nan_event_data->tx_match_filter.dlen);
if (!nan_event_data->tx_match_filter.data) {
WL_ERR(("%s: memory allocation failed\n", __FUNCTION__));
nan_event_data->tx_match_filter.dlen = 0;
ret = -ENOMEM;
goto fail;
}
ret = memcpy_s(nan_event_data->tx_match_filter.data,
nan_event_data->tx_match_filter.dlen,
cache->tx_match_filter.data, cache->tx_match_filter.dlen);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy cached tx match filter data\n"));
goto fail;
}
}
fail:
NAN_DBG_EXIT();
return ret;
}
/*
* API to cancel the ranging for given instance
* For geofence initiator, suspend ranging.
* for directed RTT initiator , report fail result, cancel ranging
* and clear ranging instance
* For responder, cancel ranging and clear ranging instance
*/
static s32
wl_cfgnan_clear_peer_ranging(struct bcm_cfg80211 *cfg,
nan_ranging_inst_t *rng_inst, int reason)
{
uint32 status = 0;
int err = BCME_OK;
struct net_device *ndev = bcmcfg_to_prmry_ndev(cfg);
dhd_pub_t *dhdp = (dhd_pub_t *)(cfg->pub);
if (rng_inst->range_type == RTT_TYPE_NAN_GEOFENCE &&
rng_inst->range_role == NAN_RANGING_ROLE_INITIATOR) {
err = wl_cfgnan_suspend_geofence_rng_session(ndev,
&rng_inst->peer_addr, reason, 0);
} else {
if (rng_inst->range_type == RTT_TYPE_NAN_DIRECTED) {
dhd_rtt_handle_nan_rtt_session_end(dhdp,
&rng_inst->peer_addr);
}
/* responder */
err = wl_cfgnan_cancel_ranging(ndev, cfg,
&rng_inst->range_id,
NAN_RNG_TERM_FLAG_IMMEDIATE, &status);
wl_cfgnan_reset_remove_ranging_instance(cfg, rng_inst);
}
if (err) {
WL_ERR(("Failed to stop ranging with peer, err : %d\n", err));
}
return err;
}
/*
* Handle NDP-Ranging Concurrency,
* for incoming DP Reuest
* Cancel Ranging with same peer
* Cancel Ranging for set up in prog
* for all other peers
*/
static s32
wl_cfgnan_handle_dp_ranging_concurrency(struct bcm_cfg80211 *cfg,
struct ether_addr *peer, int reason)
{
uint8 i = 0;
nan_ranging_inst_t *cur_rng_inst = NULL;
nan_ranging_inst_t *rng_inst = NULL;
int err = BCME_OK;
/*
* FixMe:
* DP Ranging Concurrency will need more
* than what has been addressed till now
* Poll max rng sessions and update it
* take relevant actions accordingly
*/
cur_rng_inst = wl_cfgnan_check_for_ranging(cfg, peer);
for (i = 0; i < NAN_MAX_RANGING_INST; i++) {
rng_inst = &cfg->nancfg->nan_ranging_info[i];
if (rng_inst->in_use) {
if ((cur_rng_inst && cur_rng_inst == rng_inst) &&
NAN_RANGING_IS_IN_PROG(rng_inst->range_status)) {
err = wl_cfgnan_clear_peer_ranging(cfg, rng_inst,
RTT_GEO_SUSPN_HOST_NDP_TRIGGER);
}
}
}
if (err) {
WL_ERR(("Failed to handle dp ranging concurrency, err : %d\n", err));
}
return err;
}
bool
wl_cfgnan_check_role_concurrency(struct bcm_cfg80211 *cfg,
struct ether_addr *peer_addr)
{
nan_ranging_inst_t *rng_inst = NULL;
bool role_conc_status = FALSE;
rng_inst = wl_cfgnan_check_for_ranging(cfg, peer_addr);
if (rng_inst) {
role_conc_status = rng_inst->role_concurrency_status;
}
return role_conc_status;
}
#endif /* RTT_SUPPORT */
static s32
wl_nan_dp_cmn_event_data(struct bcm_cfg80211 *cfg, void *event_data,
uint16 data_len, uint16 *tlvs_offset,
uint16 *nan_opts_len, uint32 event_num,
int *hal_event_id, nan_event_data_t *nan_event_data)
{
s32 ret = BCME_OK;
uint8 i;
wl_nan_ev_datapath_cmn_t *ev_dp;
nan_svc_info_t *svc_info;
bcm_xtlv_t *xtlv = (bcm_xtlv_t *)event_data;
#ifdef RTT_SUPPORT
nan_ranging_inst_t *rng_inst = NULL;
#endif /* RTT_SUPPORT */
if (xtlv->id == WL_NAN_XTLV_DATA_DP_INFO) {
ev_dp = (wl_nan_ev_datapath_cmn_t *)xtlv->data;
NAN_DBG_ENTER();
BCM_REFERENCE(svc_info);
BCM_REFERENCE(i);
/* Mapping to common struct between DHD and HAL */
WL_TRACE(("Event type: %d\n", ev_dp->type));
nan_event_data->type = ev_dp->type;
WL_TRACE(("pub_id: %d\n", ev_dp->pub_id));
nan_event_data->pub_id = ev_dp->pub_id;
WL_TRACE(("security: %d\n", ev_dp->security));
nan_event_data->security = ev_dp->security;
/* Store initiator_ndi, required for data_path_response_request */
ret = memcpy_s(&cfg->nancfg->initiator_ndi, ETHER_ADDR_LEN,
&ev_dp->initiator_ndi, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy event's initiator addr\n"));
goto fail;
}
if (ev_dp->type == NAN_DP_SESSION_UNICAST) {
WL_INFORM_MEM(("NDP ID: %d\n", ev_dp->ndp_id));
nan_event_data->ndp_id = ev_dp->ndp_id;
WL_TRACE(("INITIATOR_NDI: " MACDBG "\n",
MAC2STRDBG(ev_dp->initiator_ndi.octet)));
WL_TRACE(("RESPONDOR_NDI: " MACDBG "\n",
MAC2STRDBG(ev_dp->responder_ndi.octet)));
WL_TRACE(("PEER NMI: " MACDBG "\n",
MAC2STRDBG(ev_dp->peer_nmi.octet)));
ret = memcpy_s(&nan_event_data->remote_nmi, ETHER_ADDR_LEN,
&ev_dp->peer_nmi, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy event's peer nmi\n"));
goto fail;
}
} else {
/* type is multicast */
WL_INFORM_MEM(("NDP ID: %d\n", ev_dp->mc_id));
nan_event_data->ndp_id = ev_dp->mc_id;
WL_TRACE(("PEER NMI: " MACDBG "\n",
MAC2STRDBG(ev_dp->peer_nmi.octet)));
ret = memcpy_s(&nan_event_data->remote_nmi, ETHER_ADDR_LEN,
&ev_dp->peer_nmi,
ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy event's peer nmi\n"));
goto fail;
}
}
*tlvs_offset = OFFSETOF(wl_nan_ev_datapath_cmn_t, opt_tlvs) +
OFFSETOF(bcm_xtlv_t, data);
*nan_opts_len = data_len - *tlvs_offset;
if (event_num == WL_NAN_EVENT_PEER_DATAPATH_IND) {
*hal_event_id = GOOGLE_NAN_EVENT_DATA_REQUEST;
#ifdef WL_NAN_DISC_CACHE
ret = wl_cfgnan_svc_inst_add_ndp(cfg, nan_event_data->pub_id,
nan_event_data->ndp_id);
if (ret != BCME_OK) {
goto fail;
}
#endif /* WL_NAN_DISC_CACHE */
/* Add peer to data ndp peer list */
wl_cfgnan_data_add_peer(cfg, &ev_dp->peer_nmi);
#ifdef RTT_SUPPORT
/* cancel any ongoing RTT session with peer
* as we donot support DP and RNG to same peer
*/
wl_cfgnan_handle_dp_ranging_concurrency(cfg, &ev_dp->peer_nmi,
RTT_GEO_SUSPN_PEER_NDP_TRIGGER);
#endif /* RTT_SUPPORT */
} else if (event_num == WL_NAN_EVENT_DATAPATH_ESTB) {
*hal_event_id = GOOGLE_NAN_EVENT_DATA_CONFIRMATION;
if (ev_dp->role == NAN_DP_ROLE_INITIATOR) {
ret = memcpy_s(&nan_event_data->responder_ndi, ETHER_ADDR_LEN,
&ev_dp->responder_ndi,
ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy event's responder ndi\n"));
goto fail;
}
WL_TRACE(("REMOTE_NDI: " MACDBG "\n",
MAC2STRDBG(ev_dp->responder_ndi.octet)));
WL_TRACE(("Initiator status %d\n", nan_event_data->status));
} else {
ret = memcpy_s(&nan_event_data->responder_ndi, ETHER_ADDR_LEN,
&ev_dp->initiator_ndi,
ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy event's responder ndi\n"));
goto fail;
}
WL_TRACE(("REMOTE_NDI: " MACDBG "\n",
MAC2STRDBG(ev_dp->initiator_ndi.octet)));
}
if (ev_dp->status == NAN_NDP_STATUS_ACCEPT) {
nan_event_data->status = NAN_DP_REQUEST_ACCEPT;
wl_cfgnan_data_set_peer_dp_state(cfg, &ev_dp->peer_nmi,
NAN_PEER_DP_CONNECTED);
wl_cfgnan_update_dp_info(cfg, true, nan_event_data->ndp_id);
wl_cfgnan_get_stats(cfg);
} else if (ev_dp->status == NAN_NDP_STATUS_REJECT) {
nan_event_data->status = NAN_DP_REQUEST_REJECT;
#ifdef WL_NAN_DISC_CACHE
if (ev_dp->role != NAN_DP_ROLE_INITIATOR) {
/* Only at Responder side,
* If dp is ended,
* clear the resp ndp id from the svc info cache
*/
ret = wl_cfgnan_svc_inst_del_ndp(cfg,
nan_event_data->pub_id,
nan_event_data->ndp_id);
if (ret != BCME_OK) {
goto fail;
}
}
#endif /* WL_NAN_DISC_CACHE */
/* Remove peer from data ndp peer list */
wl_cfgnan_data_remove_peer(cfg, &ev_dp->peer_nmi);
#ifdef RTT_SUPPORT
rng_inst = wl_cfgnan_check_for_ranging(cfg, &ev_dp->peer_nmi);
if (rng_inst) {
/* Trigger/Reset geofence RTT */
wl_cfgnan_reset_geofence_ranging(cfg,
rng_inst, RTT_SCHED_DP_REJECTED, TRUE);
}
#endif /* RTT_SUPPORT */
} else {
WL_ERR(("%s:Status code = %x not expected\n",
__FUNCTION__, ev_dp->status));
ret = BCME_ERROR;
goto fail;
}
WL_TRACE(("Responder status %d\n", nan_event_data->status));
} else if (event_num == WL_NAN_EVENT_DATAPATH_END) {
/* Mapping to common struct between DHD and HAL */
*hal_event_id = GOOGLE_NAN_EVENT_DATA_END;
#ifdef WL_NAN_DISC_CACHE
if (ev_dp->role != NAN_DP_ROLE_INITIATOR) {
/* Only at Responder side,
* If dp is ended,
* clear the resp ndp id from the svc info cache
*/
ret = wl_cfgnan_svc_inst_del_ndp(cfg,
nan_event_data->pub_id,
nan_event_data->ndp_id);
if (ret != BCME_OK) {
goto fail;
}
}
#endif /* WL_NAN_DISC_CACHE */
/* Remove peer from data ndp peer list */
wl_cfgnan_data_remove_peer(cfg, &ev_dp->peer_nmi);
wl_cfgnan_update_dp_info(cfg, false, nan_event_data->ndp_id);
WL_INFORM_MEM(("DP_END for REMOTE_NMI: " MACDBG " with %s\n",
MAC2STRDBG(&ev_dp->peer_nmi),
nan_event_cause_to_str(ev_dp->event_cause)));
#ifdef RTT_SUPPORT
rng_inst = wl_cfgnan_check_for_ranging(cfg, &ev_dp->peer_nmi);
if (rng_inst) {
/* Trigger/Reset geofence RTT */
WL_INFORM_MEM(("sched geofence rtt from DP_END ctx: " MACDBG "\n",
MAC2STRDBG(&rng_inst->peer_addr)));
wl_cfgnan_reset_geofence_ranging(cfg, rng_inst,
RTT_SCHED_DP_END, TRUE);
}
#endif /* RTT_SUPPORT */
}
} else {
/* Follow though, not handling other IDs as of now */
WL_DBG(("%s:ID = 0x%02x not supported\n", __FUNCTION__, xtlv->id));
}
fail:
NAN_DBG_EXIT();
return ret;
}
#ifdef RTT_SUPPORT
static int
wl_cfgnan_event_disc_result(struct bcm_cfg80211 *cfg,
nan_event_data_t *nan_event_data)
{
int ret = BCME_OK;
#if (LINUX_VERSION_CODE > KERNEL_VERSION(3, 13, 0)) || defined(WL_VENDOR_EXT_SUPPORT)
ret = wl_cfgvendor_send_nan_event(cfg->wdev->wiphy, bcmcfg_to_prmry_ndev(cfg),
GOOGLE_NAN_EVENT_SUBSCRIBE_MATCH, nan_event_data);
if (ret != BCME_OK) {
WL_ERR(("Failed to send event to nan hal\n"));
}
#endif /* (LINUX_VERSION_CODE > KERNEL_VERSION(3, 13, 0)) || defined(WL_VENDOR_EXT_SUPPORT) */
return ret;
}
#define IN_GEOFENCE(ingress, egress, distance) (((distance) <= (ingress)) && \
((distance) >= (egress)))
#define IS_INGRESS_VAL(ingress, distance) ((distance) < (ingress))
#define IS_EGRESS_VAL(egress, distance) ((distance) > (egress))
static bool
wl_cfgnan_check_ranging_cond(nan_svc_info_t *svc_info, uint32 distance,
uint8 *ranging_ind, uint32 prev_distance)
{
uint8 svc_ind = svc_info->ranging_ind;
bool notify = FALSE;
bool range_rep_ev_once =
!!(svc_info->svc_range_status & SVC_RANGE_REP_EVENT_ONCE);
uint32 ingress_limit = svc_info->ingress_limit;
uint32 egress_limit = svc_info->egress_limit;
if (svc_ind & NAN_RANGE_INDICATION_CONT) {
*ranging_ind = NAN_RANGE_INDICATION_CONT;
notify = TRUE;
WL_ERR(("\n%s :Svc has continous Ind %d\n",
__FUNCTION__, __LINE__));
goto done;
}
if (svc_ind == (NAN_RANGE_INDICATION_INGRESS |
NAN_RANGE_INDICATION_EGRESS)) {
if (IN_GEOFENCE(ingress_limit, egress_limit, distance)) {
/* if not already in geofence */
if ((range_rep_ev_once == FALSE) ||
(!IN_GEOFENCE(ingress_limit, egress_limit,
prev_distance))) {
notify = TRUE;
if (distance > prev_distance) {
*ranging_ind = NAN_RANGE_INDICATION_EGRESS;
} else {
*ranging_ind = NAN_RANGE_INDICATION_INGRESS;
}
WL_ERR(("\n%s :Svc has geofence Ind %d res_ind %d\n",
__FUNCTION__, __LINE__, *ranging_ind));
}
}
goto done;
}
if (svc_ind == NAN_RANGE_INDICATION_INGRESS) {
if (IS_INGRESS_VAL(ingress_limit, distance)) {
if ((range_rep_ev_once == FALSE) ||
(prev_distance == INVALID_DISTANCE) ||
!IS_INGRESS_VAL(ingress_limit, prev_distance)) {
notify = TRUE;
*ranging_ind = NAN_RANGE_INDICATION_INGRESS;
WL_ERR(("\n%s :Svc has ingress Ind %d\n",
__FUNCTION__, __LINE__));
}
}
goto done;
}
if (svc_ind == NAN_RANGE_INDICATION_EGRESS) {
if (IS_EGRESS_VAL(egress_limit, distance)) {
if ((range_rep_ev_once == FALSE) ||
(prev_distance == INVALID_DISTANCE) ||
!IS_EGRESS_VAL(egress_limit, prev_distance)) {
notify = TRUE;
*ranging_ind = NAN_RANGE_INDICATION_EGRESS;
WL_ERR(("\n%s :Svc has egress Ind %d\n",
__FUNCTION__, __LINE__));
}
}
goto done;
}
done:
WL_INFORM_MEM(("SVC ranging Ind %d distance %d prev_distance %d, "
"range_rep_ev_once %d ingress_limit %d egress_limit %d notify %d\n",
svc_ind, distance, prev_distance, range_rep_ev_once,
ingress_limit, egress_limit, notify));
svc_info->svc_range_status |= SVC_RANGE_REP_EVENT_ONCE;
return notify;
}
static int32
wl_cfgnan_notify_disc_with_ranging(struct bcm_cfg80211 *cfg,
nan_ranging_inst_t *rng_inst, nan_event_data_t *nan_event_data, uint32 distance)
{
nan_svc_info_t *svc_info;
bool notify_svc = TRUE;
nan_disc_result_cache *disc_res = cfg->nancfg->nan_disc_cache;
uint8 ranging_ind = 0;
int ret = BCME_OK;
int i = 0, j = 0;
uint8 result_present = nan_event_data->ranging_result_present;
for (i = 0; i < MAX_SUBSCRIBES; i++) {
svc_info = rng_inst->svc_idx[i];
if (svc_info && svc_info->ranging_required) {
/* if ranging_result is present notify disc result if
* result satisfies the conditions.
* if ranging_result is not present, then notify disc
* result with out ranging info.
*/
if (result_present) {
notify_svc = wl_cfgnan_check_ranging_cond(svc_info, distance,
&ranging_ind, rng_inst->prev_distance_mm);
nan_event_data->ranging_ind = ranging_ind;
}
WL_DBG(("Ranging notify for svc_id %d, notify %d and ind %d"
" distance_mm %d result_present %d\n", svc_info->svc_id, notify_svc,
ranging_ind, distance, result_present));
} else {
continue;
}
if (notify_svc) {
for (j = 0; j < NAN_MAX_CACHE_DISC_RESULT; j++) {
if (!memcmp(&disc_res[j].peer,
&(rng_inst->peer_addr), ETHER_ADDR_LEN) &&
(svc_info->svc_id == disc_res[j].sub_id)) {
ret = wl_nan_cache_to_event_data(&disc_res[j],
nan_event_data, cfg->osh);
ret = wl_cfgnan_event_disc_result(cfg, nan_event_data);
/* If its not match once, clear it as the FW indicates
* again.
*/
if (!(svc_info->flags & WL_NAN_MATCH_ONCE)) {
wl_cfgnan_remove_disc_result(cfg, svc_info->svc_id);
}
}
}
}
}
WL_DBG(("notify_disc_with_ranging done ret %d\n", ret));
return ret;
}
static int32
wl_cfgnan_handle_directed_rtt_report(struct bcm_cfg80211 *cfg,
nan_ranging_inst_t *rng_inst)
{
int ret = BCME_OK;
uint32 status;
dhd_pub_t *dhd = (struct dhd_pub *)(cfg->pub);
ret = wl_cfgnan_cancel_ranging(bcmcfg_to_prmry_ndev(cfg), cfg,
&rng_inst->range_id, NAN_RNG_TERM_FLAG_IMMEDIATE, &status);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("nan range cancel failed ret = %d status = %d\n", ret, status));
}
dhd_rtt_handle_nan_rtt_session_end(dhd, &rng_inst->peer_addr);
dhd_rtt_nan_update_directed_sessions_cnt(dhd, FALSE);
wl_cfgnan_reset_remove_ranging_instance(cfg, rng_inst);
WL_DBG(("Ongoing ranging session is cancelled \n"));
return ret;
}
static void
wl_cfgnan_disc_result_on_geofence_cancel(struct bcm_cfg80211 *cfg,
nan_ranging_inst_t *rng_inst)
{
nan_event_data_t *nan_event_data = NULL;
nan_event_data = MALLOCZ(cfg->osh, sizeof(*nan_event_data));
if (!nan_event_data) {
WL_ERR(("%s: memory allocation failed\n", __func__));
goto exit;
}
wl_cfgnan_notify_disc_with_ranging(cfg, rng_inst, nan_event_data, 0);
exit:
wl_cfgnan_clear_nan_event_data(cfg, nan_event_data);
return;
}
void
wl_cfgnan_process_range_report(struct bcm_cfg80211 *cfg,
wl_nan_ev_rng_rpt_ind_t *range_res, int status)
{
nan_ranging_inst_t *rng_inst = NULL;
nan_event_data_t nan_event_data;
dhd_pub_t *dhd = (struct dhd_pub *)(cfg->pub);
UNUSED_PARAMETER(nan_event_data);
rng_inst = wl_cfgnan_check_for_ranging(cfg, &range_res->peer_m_addr);
if (!rng_inst) {
WL_ERR(("No ranging instance but received RNG RPT event..check \n"));
goto exit;
}
if (rng_inst->range_status != NAN_RANGING_SESSION_IN_PROGRESS) {
WL_ERR(("SSN not in prog but received RNG RPT event..ignore \n"));
goto exit;
}
#ifdef NAN_RTT_DBG
DUMP_NAN_RTT_INST(rng_inst);
DUMP_NAN_RTT_RPT(range_res);
#endif
range_res->rng_id = rng_inst->range_id;
bzero(&nan_event_data, sizeof(nan_event_data));
if (status == BCME_OK) {
nan_event_data.ranging_result_present = 1;
nan_event_data.range_measurement_cm = range_res->dist_mm;
nan_event_data.ranging_ind = range_res->indication;
}
(void)memcpy_s(&nan_event_data.remote_nmi, ETHER_ADDR_LEN,
&range_res->peer_m_addr, ETHER_ADDR_LEN);
if (rng_inst->range_type == RTT_TYPE_NAN_GEOFENCE) {
/* check in cache and event match to host */
wl_cfgnan_notify_disc_with_ranging(cfg, rng_inst, &nan_event_data,
range_res->dist_mm);
rng_inst->prev_distance_mm = range_res->dist_mm;
/* Reset geof retry count on valid measurement */
rng_inst->geof_retry_count = 0;
/*
* Suspend and trigger other targets,
* if running sessions maxed out and more
* pending targets waiting for trigger
*/
if (dhd_rtt_geofence_sessions_maxed_out(dhd) &&
(dhd_rtt_get_geofence_target_cnt(dhd) >=
dhd_rtt_get_geofence_max_sessions(dhd))) {
/*
* Update the target idx first, before suspending current target
* or else current target will become eligible again
* and will get scheduled again on reset ranging
*/
wl_cfgnan_update_geofence_target_idx(cfg);
wl_cfgnan_suspend_geofence_rng_session(bcmcfg_to_prmry_ndev(cfg),
&rng_inst->peer_addr, RTT_GEO_SUSPN_RANGE_RES_REPORTED, 0);
}
wl_cfgnan_reset_geofence_ranging(cfg,
rng_inst, RTT_SCHED_RNG_RPT_GEOFENCE, TRUE);
} else if (rng_inst->range_type == RTT_TYPE_NAN_DIRECTED) {
wl_cfgnan_handle_directed_rtt_report(cfg, rng_inst);
}
rng_inst->ftm_ssn_retry_count = 0;
exit:
return;
}
#endif /* RTT_SUPPORT */
static void
wl_nan_print_status(wl_nan_conf_status_t *nstatus)
{
WL_INFORM_MEM(("> NMI: " MACDBG " Cluster_ID: " MACDBG "\n",
MAC2STRDBG(nstatus->nmi.octet),
MAC2STRDBG(nstatus->cid.octet)));
WL_INFORM_MEM(("> NAN Device Role %s\n", nan_role_to_str(nstatus->role)));
WL_INFORM_MEM(("> Social channels: %d, %d\n",
nstatus->social_chans[0], nstatus->social_chans[1]));
WL_INFORM_MEM(("> Master_rank: " NMRSTR " AMR : " NMRSTR " Hop Count : %d, AMBTT : %d\n",
NMR2STR(nstatus->mr),
NMR2STR(nstatus->amr),
nstatus->hop_count,
nstatus->ambtt));
WL_INFORM_MEM(("> Cluster TSF_H: %x , Cluster TSF_L: %x\n",
nstatus->cluster_tsf_h, nstatus->cluster_tsf_l));
}
static void
wl_cfgnan_clear_nan_event_data(struct bcm_cfg80211 *cfg,
nan_event_data_t *nan_event_data)
{
if (nan_event_data) {
if (nan_event_data->tx_match_filter.data) {
MFREE(cfg->osh, nan_event_data->tx_match_filter.data,
nan_event_data->tx_match_filter.dlen);
nan_event_data->tx_match_filter.data = NULL;
}
if (nan_event_data->rx_match_filter.data) {
MFREE(cfg->osh, nan_event_data->rx_match_filter.data,
nan_event_data->rx_match_filter.dlen);
nan_event_data->rx_match_filter.data = NULL;
}
if (nan_event_data->svc_info.data) {
MFREE(cfg->osh, nan_event_data->svc_info.data,
nan_event_data->svc_info.dlen);
nan_event_data->svc_info.data = NULL;
}
if (nan_event_data->sde_svc_info.data) {
MFREE(cfg->osh, nan_event_data->sde_svc_info.data,
nan_event_data->sde_svc_info.dlen);
nan_event_data->sde_svc_info.data = NULL;
}
MFREE(cfg->osh, nan_event_data, sizeof(*nan_event_data));
}
}
#ifdef RTT_SUPPORT
bool
wl_cfgnan_update_geofence_target_idx(struct bcm_cfg80211 *cfg)
{
int8 i = 0, target_cnt = 0;
int8 cur_idx = DHD_RTT_INVALID_TARGET_INDEX;
rtt_geofence_target_info_t *geofence_target_info = NULL;
bool found = false;
nan_ranging_inst_t *rng_inst = NULL;
dhd_pub_t *dhd = (struct dhd_pub *)(cfg->pub);
rtt_status_info_t *rtt_status = GET_RTTSTATE(dhd);
target_cnt = dhd_rtt_get_geofence_target_cnt(dhd);
ASSERT(target_cnt);
if (target_cnt == 0) {
WL_DBG(("No geofence targets to schedule\n"));
dhd_rtt_set_geofence_cur_target_idx(dhd,
DHD_RTT_INVALID_TARGET_INDEX);
goto exit;
}
/* cur idx is validated too, in the following API */
cur_idx = dhd_rtt_get_geofence_cur_target_idx(dhd);
if (cur_idx == DHD_RTT_INVALID_TARGET_INDEX) {
WL_DBG(("invalid current target index, start looking from first\n"));
cur_idx = 0;
}
geofence_target_info = rtt_status->geofence_cfg.geofence_target_info;
/* Loop through to find eligible target idx */
i = cur_idx;
do {
if (geofence_target_info[i].valid == TRUE) {
rng_inst = wl_cfgnan_check_for_ranging(cfg,
&geofence_target_info[i].peer_addr);
if (rng_inst &&
(!NAN_RANGING_IS_IN_PROG(rng_inst->range_status)) &&
(!wl_cfgnan_check_role_concurrency(cfg,
&rng_inst->peer_addr))) {
found = TRUE;
break;
}
}
i++;
if (i == target_cnt) {
i = 0;
}
} while (i != cur_idx);
if (found) {
dhd_rtt_set_geofence_cur_target_idx(dhd, i);
WL_DBG(("Updated cur index, cur_idx = %d, target_cnt = %d\n",
i, target_cnt));
} else {
dhd_rtt_set_geofence_cur_target_idx(dhd,
DHD_RTT_INVALID_TARGET_INDEX);
WL_DBG(("Invalidated cur_idx, as either no target present, or all "
"target already running, target_cnt = %d\n", target_cnt));
}
exit:
return found;
}
/*
* Triggers rtt work thread
* if set up not in prog already
* and max sessions not maxed out,
* after setting next eligible target index
*/
void
wl_cfgnan_reset_geofence_ranging(struct bcm_cfg80211 *cfg,
nan_ranging_inst_t * rng_inst, int sched_reason,
bool need_rtt_mutex)
{
dhd_pub_t *dhd = (struct dhd_pub *)(cfg->pub);
u8 rtt_invalid_reason = RTT_STATE_VALID;
rtt_status_info_t *rtt_status = GET_RTTSTATE(dhd);
int8 target_cnt = 0;
int reset_req_drop = 0;
if (need_rtt_mutex == TRUE) {
mutex_lock(&rtt_status->rtt_mutex);
}
WL_INFORM_MEM(("wl_cfgnan_reset_geofence_ranging: "
"sched_reason = %d, cur_idx = %d, target_cnt = %d\n",
sched_reason, rtt_status->geofence_cfg.cur_target_idx,
rtt_status->geofence_cfg.geofence_target_cnt));
if (rtt_status->rtt_sched == TRUE) {
reset_req_drop = 1;
goto exit;
}
target_cnt = dhd_rtt_get_geofence_target_cnt(dhd);
if (target_cnt == 0) {
WL_DBG(("No geofence targets to schedule\n"));
/*
* FIXME:
* No Geofence target
* Remove all valid ranging inst
*/
if (rng_inst) {
WL_INFORM_MEM(("Removing Ranging Instance " MACDBG "\n",
MAC2STRDBG(&(rng_inst->peer_addr))));
bzero(rng_inst, sizeof(*rng_inst));
}
/* Cancel pending retry timer if any */
if (delayed_work_pending(&rtt_status->rtt_retry_timer)) {
cancel_delayed_work(&rtt_status->rtt_retry_timer);
}
/* invalidate current index as there are no targets */
dhd_rtt_set_geofence_cur_target_idx(dhd,
DHD_RTT_INVALID_TARGET_INDEX);
reset_req_drop = 2;
goto exit;
}
if (dhd_rtt_is_geofence_setup_inprog(dhd)) {
/* Will be called again for schedule once lock is removed */
reset_req_drop = 3;
goto exit;
}
/* Avoid schedule if
* already geofence running
* or Directed RTT in progress
* or Invalid RTT state like
* NDP with Peer
*/
if ((!RTT_IS_STOPPED(rtt_status)) ||
(rtt_invalid_reason != RTT_STATE_VALID)) {
/* Not in valid RTT state, avoid schedule */
reset_req_drop = 4;
goto exit;
}
if (dhd_rtt_geofence_sessions_maxed_out(dhd)) {
reset_req_drop = 5;
goto exit;
}
if (!wl_cfgnan_update_geofence_target_idx(cfg)) {
reset_req_drop = 6;
goto exit;
}
/*
* FixMe: Retry geofence target over a timer Logic
* to be brought back later again
* in accordance to new multipeer implementation
*/
/* schedule RTT */
dhd_rtt_schedule_rtt_work_thread(dhd, sched_reason);
exit:
if (reset_req_drop) {
WL_INFORM_MEM(("reset geofence req dropped, reason = %d\n",
reset_req_drop));
}
if (need_rtt_mutex == TRUE) {
mutex_unlock(&rtt_status->rtt_mutex);
}
return;
}
void
wl_cfgnan_reset_geofence_ranging_for_cur_target(dhd_pub_t *dhd, int sched_reason)
{
struct net_device *dev = dhd_linux_get_primary_netdev(dhd);
struct bcm_cfg80211 *cfg = wl_get_cfg(dev);
rtt_geofence_target_info_t *geofence_target = NULL;
nan_ranging_inst_t *ranging_inst = NULL;
geofence_target = dhd_rtt_get_geofence_current_target(dhd);
if (!geofence_target) {
WL_DBG(("reset ranging request dropped: geofence target null\n"));
goto exit;
}
ranging_inst = wl_cfgnan_check_for_ranging(cfg,
&geofence_target->peer_addr);
if (!ranging_inst) {
WL_DBG(("reset ranging request dropped: ranging instance null\n"));
goto exit;
}
if (NAN_RANGING_IS_IN_PROG(ranging_inst->range_status) &&
(ranging_inst->range_type == RTT_TYPE_NAN_GEOFENCE)) {
WL_DBG(("Ranging is already in progress for Current target "
MACDBG " \n", MAC2STRDBG(&ranging_inst->peer_addr)));
goto exit;
}
wl_cfgnan_reset_geofence_ranging(cfg, ranging_inst, sched_reason, TRUE);
exit:
return;
}
static bool
wl_cfgnan_geofence_retry_check(nan_ranging_inst_t *rng_inst, uint8 reason_code)
{
bool geof_retry = FALSE;
switch (reason_code) {
case NAN_RNG_TERM_IDLE_TIMEOUT:
/* Fallthrough: Keep adding more reason code if needed */
case NAN_RNG_TERM_RNG_RESP_TIMEOUT:
case NAN_RNG_TERM_RNG_RESP_REJ:
case NAN_RNG_TERM_RNG_TXS_FAIL:
if (rng_inst->geof_retry_count <
NAN_RNG_GEOFENCE_MAX_RETRY_CNT) {
rng_inst->geof_retry_count++;
geof_retry = TRUE;
}
break;
default:
/* FALSE for any other case */
break;
}
return geof_retry;
}
#endif /* RTT_SUPPORT */
s32
wl_cfgnan_notify_nan_status(struct bcm_cfg80211 *cfg,
bcm_struct_cfgdev *cfgdev, const wl_event_msg_t *event, void *event_data)
{
uint16 data_len;
uint32 event_num;
s32 event_type;
int hal_event_id = 0;
nan_event_data_t *nan_event_data = NULL;
nan_parse_event_ctx_t nan_event_ctx;
uint16 tlvs_offset = 0;
uint16 nan_opts_len = 0;
uint8 *tlv_buf;
s32 ret = BCME_OK;
bcm_xtlv_opts_t xtlv_opt = BCM_IOV_CMD_OPT_ALIGN32;
uint32 status;
nan_svc_info_t *svc;
#ifdef RTT_SUPPORT
dhd_pub_t *dhd = (struct dhd_pub *)(cfg->pub);
rtt_status_info_t *rtt_status = GET_RTTSTATE(dhd);
UNUSED_PARAMETER(dhd);
UNUSED_PARAMETER(rtt_status);
if (rtt_status == NULL) {
return -EINVAL;
}
#endif /* RTT_SUPPORT */
UNUSED_PARAMETER(wl_nan_print_status);
UNUSED_PARAMETER(status);
NAN_DBG_ENTER();
if (!event || !event_data) {
WL_ERR(("event data is NULL\n"));
return -EINVAL;
}
event_type = ntoh32(event->event_type);
event_num = ntoh32(event->reason);
data_len = ntoh32(event->datalen);
#ifdef RTT_SUPPORT
if (event_num == WL_NAN_EVENT_RNG_REQ_IND)
{
/* Flush any RTT work to avoid any
* inconsistencies & ensure RNG REQ
* is handling in a stable RTT state.
* Note new RTT work can be enqueued from
* a. host command context - synchronized over rtt_mutex & state
* b. event context - event processing is synchronized/serialised
*/
flush_work(&rtt_status->work);
}
#endif /* RTT_SUPPORT */
NAN_MUTEX_LOCK();
if (NAN_INVALID_EVENT(event_num)) {
WL_ERR(("unsupported event, num: %d, event type: %d\n", event_num, event_type));
ret = -EINVAL;
goto exit;
}
WL_DBG((">> Nan Event Received: %s (num=%d, len=%d)\n",
nan_event_to_str(event_num), event_num, data_len));
#ifdef WL_NAN_DEBUG
prhex("nan_event_data:", event_data, data_len);
#endif /* WL_NAN_DEBUG */
if (!cfg->nancfg->nan_init_state) {
WL_ERR(("nan is not in initialized state, dropping nan related events\n"));
ret = BCME_OK;
goto exit;
}
nan_event_data = MALLOCZ(cfg->osh, sizeof(*nan_event_data));
if (!nan_event_data) {
WL_ERR(("%s: memory allocation failed\n", __func__));
goto exit;
}
nan_event_ctx.cfg = cfg;
nan_event_ctx.nan_evt_data = nan_event_data;
/*
* send as preformatted hex string
* EVENT_NAN <event_type> <tlv_hex_string>
*/
switch (event_num) {
case WL_NAN_EVENT_START:
case WL_NAN_EVENT_MERGE:
case WL_NAN_EVENT_ROLE: {
/* get nan status info as-is */
bcm_xtlv_t *xtlv = (bcm_xtlv_t *)event_data;
wl_nan_conf_status_t *nstatus = (wl_nan_conf_status_t *)xtlv->data;
WL_INFORM_MEM((">> Nan Mac Event Received: %s (num=%d, len=%d)\n",
nan_event_to_str(event_num), event_num, data_len));
WL_INFORM_MEM(("Nan Device Role %s\n", nan_role_to_str(nstatus->role)));
/* Mapping to common struct between DHD and HAL */
nan_event_data->enabled = nstatus->enabled;
ret = memcpy_s(&nan_event_data->local_nmi, ETHER_ADDR_LEN,
&nstatus->nmi, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy nmi\n"));
goto exit;
}
ret = memcpy_s(&nan_event_data->clus_id, ETHER_ADDR_LEN,
&nstatus->cid, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy cluster id\n"));
goto exit;
}
nan_event_data->nan_de_evt_type = event_num;
if (event_num == WL_NAN_EVENT_ROLE) {
wl_nan_print_status(nstatus);
}
if (event_num == WL_NAN_EVENT_START) {
OSL_SMP_WMB();
cfg->nancfg->nan_event_recvd = true;
OSL_SMP_WMB();
wake_up(&cfg->nancfg->nan_event_wait);
}
hal_event_id = GOOGLE_NAN_EVENT_DE_EVENT;
break;
}
case WL_NAN_EVENT_TERMINATED: {
bcm_xtlv_t *xtlv = (bcm_xtlv_t *)event_data;
wl_nan_ev_terminated_t *pev = (wl_nan_ev_terminated_t *)xtlv->data;
/* Mapping to common struct between DHD and HAL */
WL_TRACE(("Instance ID: %d\n", pev->instance_id));
nan_event_data->local_inst_id = pev->instance_id;
WL_TRACE(("Service Type: %d\n", pev->svctype));
#ifdef WL_NAN_DISC_CACHE
wl_cfgnan_clear_svc_cache(cfg, pev->instance_id);
/* if we have to store disc_res even after sub_cancel
* donot call below api..but need to device on the criteria to expire
*/
if (pev->svctype == NAN_SC_SUBSCRIBE) {
wl_cfgnan_remove_disc_result(cfg, pev->instance_id);
}
#endif /* WL_NAN_DISC_CACHE */
/* Mapping reason code of FW to status code of framework */
if (pev->reason == NAN_TERM_REASON_TIMEOUT ||
pev->reason == NAN_TERM_REASON_USER_REQ ||
pev->reason == NAN_TERM_REASON_COUNT_REACHED) {
nan_event_data->status = NAN_STATUS_SUCCESS;
ret = memcpy_s(nan_event_data->nan_reason,
sizeof(nan_event_data->nan_reason),
"NAN_STATUS_SUCCESS",
strlen("NAN_STATUS_SUCCESS"));
if (ret != BCME_OK) {
WL_ERR(("Failed to copy nan_reason\n"));
goto exit;
}
} else {
nan_event_data->status = NAN_STATUS_INTERNAL_FAILURE;
ret = memcpy_s(nan_event_data->nan_reason,
sizeof(nan_event_data->nan_reason),
"NAN_STATUS_INTERNAL_FAILURE",
strlen("NAN_STATUS_INTERNAL_FAILURE"));
if (ret != BCME_OK) {
WL_ERR(("Failed to copy nan_reason\n"));
goto exit;
}
}
if (pev->svctype == NAN_SC_SUBSCRIBE) {
hal_event_id = GOOGLE_NAN_EVENT_SUBSCRIBE_TERMINATED;
} else {
hal_event_id = GOOGLE_NAN_EVENT_PUBLISH_TERMINATED;
}
#ifdef WL_NAN_DISC_CACHE
#ifdef RTT_SUPPORT
if (pev->reason != NAN_TERM_REASON_USER_REQ) {
wl_cfgnan_clear_svc_from_all_ranging_inst(cfg, pev->instance_id);
/* terminate ranging sessions */
wl_cfgnan_terminate_all_obsolete_ranging_sessions(cfg);
}
#endif /* RTT_SUPPORT */
#endif /* WL_NAN_DISC_CACHE */
break;
}
case WL_NAN_EVENT_RECEIVE: {
nan_opts_len = data_len;
hal_event_id = GOOGLE_NAN_EVENT_FOLLOWUP;
xtlv_opt = BCM_IOV_CMD_OPT_ALIGN_NONE;
break;
}
case WL_NAN_EVENT_TXS: {
bcm_xtlv_t *xtlv = (bcm_xtlv_t *)event_data;
wl_nan_event_txs_t *txs = (wl_nan_event_txs_t *)xtlv->data;
wl_nan_event_sd_txs_t *txs_sd = NULL;
if (txs->status == WL_NAN_TXS_SUCCESS) {
WL_INFORM_MEM(("TXS success for type %s(%d) token %d\n",
nan_frm_type_to_str(txs->type), txs->type, txs->host_seq));
nan_event_data->status = NAN_STATUS_SUCCESS;
ret = memcpy_s(nan_event_data->nan_reason,
sizeof(nan_event_data->nan_reason),
"NAN_STATUS_SUCCESS",
strlen("NAN_STATUS_SUCCESS"));
if (ret != BCME_OK) {
WL_ERR(("Failed to copy nan_reason\n"));
goto exit;
}
} else {
/* TODO : populate status based on reason codes
For now adding it as no ACK, so that app/framework can retry
*/
WL_INFORM_MEM(("TXS failed for type %s(%d) status %d token %d\n",
nan_frm_type_to_str(txs->type), txs->type, txs->status,
txs->host_seq));
nan_event_data->status = NAN_STATUS_NO_OTA_ACK;
ret = memcpy_s(nan_event_data->nan_reason,
sizeof(nan_event_data->nan_reason),
"NAN_STATUS_NO_OTA_ACK",
strlen("NAN_STATUS_NO_OTA_ACK"));
if (ret != BCME_OK) {
WL_ERR(("Failed to copy nan_reason\n"));
goto exit;
}
}
nan_event_data->reason = txs->reason_code;
nan_event_data->token = txs->host_seq;
if (txs->type == WL_NAN_FRM_TYPE_FOLLOWUP) {
hal_event_id = GOOGLE_NAN_EVENT_TRANSMIT_FOLLOWUP_IND;
xtlv = (bcm_xtlv_t *)(txs->opt_tlvs);
if (txs->opt_tlvs_len && xtlv->id == WL_NAN_XTLV_SD_TXS) {
txs_sd = (wl_nan_event_sd_txs_t*)xtlv->data;
nan_event_data->local_inst_id = txs_sd->inst_id;
} else {
WL_ERR(("Invalid params in TX status for trasnmit followup"));
ret = -EINVAL;
goto exit;
}
#ifdef RTT_SUPPORT
} else if (txs->type == WL_NAN_FRM_TYPE_RNG_RESP) {
xtlv = (bcm_xtlv_t *)(txs->opt_tlvs);
if (txs->opt_tlvs_len && xtlv->id == WL_NAN_XTLV_RNG_TXS) {
wl_nan_range_txs_t* txs_rng_resp = (wl_nan_range_txs_t*)xtlv->data;
nan_ranging_inst_t *rng_inst =
wl_cfgnan_get_rng_inst_by_id(cfg, txs_rng_resp->range_id);
if (rng_inst &&
NAN_RANGING_SETUP_IS_IN_PROG(rng_inst->range_status)) {
/* Unset ranging set up in progress */
dhd_rtt_update_geofence_sessions_cnt(dhd, FALSE,
&rng_inst->peer_addr);
if (txs->status == WL_NAN_TXS_SUCCESS) {
/* range set up is over, move range in progress */
rng_inst->range_status =
NAN_RANGING_SESSION_IN_PROGRESS;
/* Increment geofence session count */
dhd_rtt_update_geofence_sessions_cnt(dhd,
TRUE, NULL);
WL_DBG(("Txs for range resp, rng_id = %d\n",
rng_inst->range_id));
} else {
wl_cfgnan_reset_remove_ranging_instance(cfg,
rng_inst);
}
}
} else {
WL_ERR(("Invalid params in TX status for range response"));
ret = -EINVAL;
goto exit;
}
#endif /* RTT_SUPPORT */
} else { /* TODO: add for other frame types if required */
ret = -EINVAL;
goto exit;
}
break;
}
case WL_NAN_EVENT_DISCOVERY_RESULT: {
nan_opts_len = data_len;
hal_event_id = GOOGLE_NAN_EVENT_SUBSCRIBE_MATCH;
xtlv_opt = BCM_IOV_CMD_OPT_ALIGN_NONE;
break;
}
#ifdef WL_NAN_DISC_CACHE
case WL_NAN_EVENT_DISC_CACHE_TIMEOUT: {
bcm_xtlv_t *xtlv = (bcm_xtlv_t *)event_data;
wl_nan_ev_disc_cache_timeout_t *cache_data =
(wl_nan_ev_disc_cache_timeout_t *)xtlv->data;
wl_nan_disc_expired_cache_entry_t *cache_entry = NULL;
uint16 xtlv_len = xtlv->len;
uint8 entry_idx = 0;
if (xtlv->id == WL_NAN_XTLV_SD_DISC_CACHE_TIMEOUT) {
xtlv_len = xtlv_len -
OFFSETOF(wl_nan_ev_disc_cache_timeout_t, cache_exp_list);
while ((entry_idx < cache_data->count) &&
(xtlv_len >= sizeof(*cache_entry))) {
cache_entry = &cache_data->cache_exp_list[entry_idx];
/* Handle ranging cases for cache timeout */
WL_INFORM_MEM(("WL_NAN_EVENT_DISC_CACHE_TIMEOUT peer: " MACDBG
" l_id:%d r_id:%d\n", MAC2STRDBG(&cache_entry->r_nmi_addr),
cache_entry->l_sub_id, cache_entry->r_pub_id));
#ifdef RTT_SUPPORT
wl_cfgnan_ranging_clear_publish(cfg, &cache_entry->r_nmi_addr,
cache_entry->l_sub_id);
#endif /* RTT_SUPPORT */
/* Invalidate local cache info */
wl_cfgnan_remove_disc_result(cfg, cache_entry->l_sub_id);
xtlv_len = xtlv_len - sizeof(*cache_entry);
entry_idx++;
}
}
break;
}
#ifdef RTT_SUPPORT
case WL_NAN_EVENT_RNG_REQ_IND: {
wl_nan_ev_rng_req_ind_t *rng_ind;
bcm_xtlv_t *xtlv = (bcm_xtlv_t *)event_data;
nan_opts_len = data_len;
rng_ind = (wl_nan_ev_rng_req_ind_t *)xtlv->data;
xtlv_opt = BCM_IOV_CMD_OPT_ALIGN_NONE;
WL_INFORM_MEM(("Received WL_NAN_EVENT_RNG_REQ_IND range_id %d"
" peer:" MACDBG "\n", rng_ind->rng_id,
MAC2STRDBG(&rng_ind->peer_m_addr)));
ret = wl_cfgnan_handle_ranging_ind(cfg, rng_ind);
/* no need to event to HAL */
goto exit;
}
case WL_NAN_EVENT_RNG_TERM_IND: {
bcm_xtlv_t *xtlv = (bcm_xtlv_t *)event_data;
nan_ranging_inst_t *rng_inst;
wl_nan_ev_rng_term_ind_t *range_term = (wl_nan_ev_rng_term_ind_t *)xtlv->data;
int rng_sched_reason = 0;
int8 index = -1;
rtt_geofence_target_info_t* geofence_target;
BCM_REFERENCE(dhd);
WL_INFORM_MEM(("Received WL_NAN_EVENT_RNG_TERM_IND peer: " MACDBG ", "
" Range ID:%d Reason Code:%d\n", MAC2STRDBG(&range_term->peer_m_addr),
range_term->rng_id, range_term->reason_code));
rng_inst = wl_cfgnan_get_rng_inst_by_id(cfg, range_term->rng_id);
if (rng_inst) {
if (!NAN_RANGING_IS_IN_PROG(rng_inst->range_status)) {
WL_DBG(("Late or unsynchronized nan term indicator event\n"));
break;
}
rng_sched_reason = RTT_SCHED_RNG_TERM;
if (rng_inst->range_role == NAN_RANGING_ROLE_RESPONDER) {
dhd_rtt_update_geofence_sessions_cnt(dhd, FALSE,
&rng_inst->peer_addr);
wl_cfgnan_reset_remove_ranging_instance(cfg, rng_inst);
} else {
if (rng_inst->range_type == RTT_TYPE_NAN_DIRECTED) {
dhd_rtt_handle_nan_rtt_session_end(dhd,
&rng_inst->peer_addr);
if (dhd_rtt_nan_is_directed_setup_in_prog_with_peer(dhd,
&rng_inst->peer_addr)) {
dhd_rtt_nan_update_directed_setup_inprog(dhd,
NULL, FALSE);
} else {
dhd_rtt_nan_update_directed_sessions_cnt(dhd,
FALSE);
}
} else if (rng_inst->range_type == RTT_TYPE_NAN_GEOFENCE) {
rng_inst->range_status = NAN_RANGING_REQUIRED;
dhd_rtt_update_geofence_sessions_cnt(dhd, FALSE,
&rng_inst->peer_addr);
if (!wl_cfgnan_geofence_retry_check(rng_inst,
range_term->reason_code)) {
/* Report on ranging failure */
wl_cfgnan_disc_result_on_geofence_cancel(cfg,
rng_inst);
WL_TRACE(("Reset the state on terminate\n"));
geofence_target = dhd_rtt_get_geofence_target(dhd,
&rng_inst->peer_addr, &index);
if (geofence_target) {
dhd_rtt_remove_geofence_target(dhd,
&geofence_target->peer_addr);
}
}
}
}
/* Reset Ranging Instance and trigger ranging if applicable */
wl_cfgnan_reset_geofence_ranging(cfg, rng_inst, rng_sched_reason, TRUE);
} else {
/*
* This can happen in some scenarios
* like receiving term after a fail txs for range resp
* where ranging instance is already cleared
*/
WL_DBG(("Term Indication recieved for a peer without rng inst\n"));
}
break;
}
case WL_NAN_EVENT_RNG_RESP_IND: {
bcm_xtlv_t *xtlv = (bcm_xtlv_t *)event_data;
nan_ranging_inst_t *rng_inst;
wl_nan_ev_rng_resp_t *range_resp = (wl_nan_ev_rng_resp_t *)xtlv->data;
WL_INFORM_MEM(("Received WL_NAN_EVENT_RNG_RESP_IND peer: " MACDBG ", "
" Range ID:%d Ranging Status:%d\n", MAC2STRDBG(&range_resp->peer_m_addr),
range_resp->rng_id, range_resp->status));
rng_inst = wl_cfgnan_get_rng_inst_by_id(cfg, range_resp->rng_id);
if (!rng_inst) {
WL_DBG(("Late or unsynchronized resp indicator event\n"));
break;
}
//ASSERT(NAN_RANGING_SETUP_IS_IN_PROG(rng_inst->range_status));
if (!NAN_RANGING_SETUP_IS_IN_PROG(rng_inst->range_status)) {
WL_INFORM_MEM(("Resp Indicator received for not in prog range inst\n"));
break;
}
/* range set up is over now, move to range in progress */
rng_inst->range_status = NAN_RANGING_SESSION_IN_PROGRESS;
if (rng_inst->range_type == RTT_TYPE_NAN_DIRECTED) {
/* FixMe: Ideally, all below like update session cnt
* should be appilicabe to nan rtt and not specific to
* geofence. To be fixed in next RB
*/
dhd_rtt_nan_update_directed_setup_inprog(dhd, NULL, FALSE);
/*
* Increase session count here,
* failure status is followed by Term Ind
* and handled accordingly
*/
dhd_rtt_nan_update_directed_sessions_cnt(dhd, TRUE);
/*
* If pending targets to be triggered,
* and max sessions, not running already,
* schedule next target for RTT
*/
if ((!dhd_rtt_nan_all_directed_sessions_triggered(dhd)) &&
dhd_rtt_nan_directed_sessions_allowed(dhd)) {
/* Find and set next directed target */
dhd_rtt_set_next_target_idx(dhd,
(dhd_rtt_get_cur_target_idx(dhd) + 1));
/* schedule RTT */
dhd_rtt_schedule_rtt_work_thread(dhd,
RTT_SCHED_RNG_RESP_IND);
}
break;
}
/*
ASSERT(dhd_rtt_is_geofence_setup_inprog_with_peer(dhd,
&rng_inst->peer_addr));
*/
if (!dhd_rtt_is_geofence_setup_inprog_with_peer(dhd,
&rng_inst->peer_addr)) {
WL_INFORM_MEM(("Resp Indicator received for not in prog range peer\n"));
break;
}
/* Unset geof ranging setup status */
dhd_rtt_update_geofence_sessions_cnt(dhd, FALSE, &rng_inst->peer_addr);
/* Increase geofence session count */
dhd_rtt_update_geofence_sessions_cnt(dhd, TRUE, NULL);
wl_cfgnan_reset_geofence_ranging(cfg,
rng_inst, RTT_SCHED_RNG_RESP_IND, TRUE);
break;
}
#endif /* RTT_SUPPORT */
#endif /* WL_NAN_DISC_CACHE */
/*
* Data path events data are received in common event struct,
* Handling all the events as part of one case, hence fall through is intentional
*/
case WL_NAN_EVENT_PEER_DATAPATH_IND:
case WL_NAN_EVENT_DATAPATH_ESTB:
case WL_NAN_EVENT_DATAPATH_END: {
ret = wl_nan_dp_cmn_event_data(cfg, event_data, data_len,
&tlvs_offset, &nan_opts_len,
event_num, &hal_event_id, nan_event_data);
/* Avoiding optional param parsing for DP END Event */
if (event_num == WL_NAN_EVENT_DATAPATH_END) {
nan_opts_len = 0;
xtlv_opt = BCM_IOV_CMD_OPT_ALIGN_NONE;
}
if (unlikely(ret)) {
WL_ERR(("nan dp common event data parse failed\n"));
goto exit;
}
break;
}
case WL_NAN_EVENT_PEER_DATAPATH_RESP:
{
/* No action -intentionally added to avoid prints when this event is rcvd */
break;
}
default:
WL_ERR_RLMT(("WARNING: unimplemented NAN APP EVENT = %d\n", event_num));
ret = BCME_ERROR;
goto exit;
}
if (nan_opts_len) {
tlv_buf = (uint8 *)event_data + tlvs_offset;
/* Extract event data tlvs and pass their resp to cb fn */
ret = bcm_unpack_xtlv_buf((void *)&nan_event_ctx, (const uint8*)tlv_buf,
nan_opts_len, xtlv_opt, wl_cfgnan_set_vars_cbfn);
if (ret != BCME_OK) {
WL_ERR(("Failed to unpack tlv data, ret=%d\n", ret));
}
}
#ifdef WL_NAN_DISC_CACHE
if (hal_event_id == GOOGLE_NAN_EVENT_SUBSCRIBE_MATCH) {
#ifdef RTT_SUPPORT
bool send_disc_result;
#endif /* RTT_SUPPORT */
u16 update_flags = 0;
WL_TRACE(("Cache disc res\n"));
ret = wl_cfgnan_cache_disc_result(cfg, nan_event_data, &update_flags);
if (ret) {
WL_ERR(("Failed to cache disc result ret %d\n", ret));
}
#ifdef RTT_SUPPORT
if (nan_event_data->sde_control_flag & NAN_SDE_CF_RANGING_REQUIRED) {
ret = wl_cfgnan_check_disc_result_for_ranging(cfg,
nan_event_data, &send_disc_result);
if ((ret == BCME_OK) && (send_disc_result == FALSE)) {
/* Avoid sending disc result instantly and exit */
goto exit;
} else {
/* TODO: should we terminate service if ranging fails ? */
WL_INFORM_MEM(("Ranging failed or not required, " MACDBG
" sub_id:%d , pub_id:%d, ret = %d, send_disc_result = %d\n",
MAC2STRDBG(&nan_event_data->remote_nmi),
nan_event_data->sub_id, nan_event_data->pub_id,
ret, send_disc_result));
}
} else {
nan_svc_info_t *svc_info = wl_cfgnan_get_svc_inst(cfg,
nan_event_data->sub_id, 0);
if (svc_info && svc_info->ranging_required &&
(update_flags & NAN_DISC_CACHE_PARAM_SDE_CONTROL)) {
wl_cfgnan_ranging_clear_publish(cfg,
&nan_event_data->remote_nmi, nan_event_data->sub_id);
}
}
#endif /* RTT_SUPPORT */
/*
* If tx match filter is present as part of active subscribe, keep same filter
* values in discovery results also.
*/
if (nan_event_data->sub_id == nan_event_data->requestor_id) {
svc = wl_cfgnan_get_svc_inst(cfg, nan_event_data->sub_id, 0);
if (svc && svc->tx_match_filter_len) {
nan_event_data->tx_match_filter.dlen = svc->tx_match_filter_len;
nan_event_data->tx_match_filter.data =
MALLOCZ(cfg->osh, svc->tx_match_filter_len);
if (!nan_event_data->tx_match_filter.data) {
WL_ERR(("%s: tx_match_filter_data alloc failed\n",
__FUNCTION__));
nan_event_data->tx_match_filter.dlen = 0;
ret = -ENOMEM;
goto exit;
}
ret = memcpy_s(nan_event_data->tx_match_filter.data,
nan_event_data->tx_match_filter.dlen,
svc->tx_match_filter, svc->tx_match_filter_len);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy tx match filter data\n"));
goto exit;
}
}
}
}
#endif /* WL_NAN_DISC_CACHE */
WL_TRACE(("Send up %s (%d) data to HAL, hal_event_id=%d\n",
nan_event_to_str(event_num), event_num, hal_event_id));
#if (LINUX_VERSION_CODE > KERNEL_VERSION(3, 13, 0)) || defined(WL_VENDOR_EXT_SUPPORT)
ret = wl_cfgvendor_send_nan_event(cfg->wdev->wiphy, bcmcfg_to_prmry_ndev(cfg),
hal_event_id, nan_event_data);
if (ret != BCME_OK) {
WL_ERR(("Failed to send event to nan hal, %s (%d)\n",
nan_event_to_str(event_num), event_num));
}
#endif /* (LINUX_VERSION_CODE > KERNEL_VERSION(3, 13, 0)) || defined(WL_VENDOR_EXT_SUPPORT) */
exit:
wl_cfgnan_clear_nan_event_data(cfg, nan_event_data);
NAN_MUTEX_UNLOCK();
NAN_DBG_EXIT();
return ret;
}
#ifdef WL_NAN_DISC_CACHE
static int
wl_cfgnan_cache_disc_result(struct bcm_cfg80211 *cfg, void * data,
u16 *disc_cache_update_flags)
{
nan_event_data_t* disc = (nan_event_data_t*)data;
int i, add_index = 0;
int ret = BCME_OK;
wl_nancfg_t *nancfg = cfg->nancfg;
nan_disc_result_cache *disc_res = nancfg->nan_disc_cache;
*disc_cache_update_flags = 0;
if (!nancfg->nan_enable) {
WL_DBG(("nan not enabled"));
return BCME_NOTENABLED;
}
if (nancfg->nan_disc_count == NAN_MAX_CACHE_DISC_RESULT) {
WL_DBG(("cache full"));
ret = BCME_NORESOURCE;
goto done;
}
for (i = 0; i < NAN_MAX_CACHE_DISC_RESULT; i++) {
if (!disc_res[i].valid) {
add_index = i;
continue;
}
if (!memcmp(&disc_res[i].peer, &disc->remote_nmi, ETHER_ADDR_LEN) &&
!memcmp(disc_res[i].svc_hash, disc->svc_name, WL_NAN_SVC_HASH_LEN)) {
WL_DBG(("cache entry already present, i = %d", i));
/* Update needed parameters here */
if (disc_res[i].sde_control_flag != disc->sde_control_flag) {
disc_res[i].sde_control_flag = disc->sde_control_flag;
*disc_cache_update_flags |= NAN_DISC_CACHE_PARAM_SDE_CONTROL;
}
ret = BCME_OK; /* entry already present */
goto done;
}
}
WL_DBG(("adding cache entry: add_index = %d\n", add_index));
disc_res[add_index].valid = 1;
disc_res[add_index].pub_id = disc->pub_id;
disc_res[add_index].sub_id = disc->sub_id;
disc_res[add_index].publish_rssi = disc->publish_rssi;
disc_res[add_index].peer_cipher_suite = disc->peer_cipher_suite;
disc_res[add_index].sde_control_flag = disc->sde_control_flag;
ret = memcpy_s(&disc_res[add_index].peer, ETHER_ADDR_LEN,
&disc->remote_nmi, ETHER_ADDR_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy remote nmi\n"));
goto done;
}
ret = memcpy_s(disc_res[add_index].svc_hash, WL_NAN_SVC_HASH_LEN,
disc->svc_name, WL_NAN_SVC_HASH_LEN);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy svc hash\n"));
goto done;
}
if (disc->svc_info.dlen && disc->svc_info.data) {
disc_res[add_index].svc_info.dlen = disc->svc_info.dlen;
disc_res[add_index].svc_info.data =
MALLOCZ(cfg->osh, disc_res[add_index].svc_info.dlen);
if (!disc_res[add_index].svc_info.data) {
WL_ERR(("%s: memory allocation failed\n", __FUNCTION__));
disc_res[add_index].svc_info.dlen = 0;
ret = BCME_NOMEM;
goto done;
}
ret = memcpy_s(disc_res[add_index].svc_info.data, disc_res[add_index].svc_info.dlen,
disc->svc_info.data, disc->svc_info.dlen);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy svc info\n"));
goto done;
}
}
if (disc->tx_match_filter.dlen && disc->tx_match_filter.data) {
disc_res[add_index].tx_match_filter.dlen = disc->tx_match_filter.dlen;
disc_res[add_index].tx_match_filter.data =
MALLOCZ(cfg->osh, disc_res[add_index].tx_match_filter.dlen);
if (!disc_res[add_index].tx_match_filter.data) {
WL_ERR(("%s: memory allocation failed\n", __FUNCTION__));
disc_res[add_index].tx_match_filter.dlen = 0;
ret = BCME_NOMEM;
goto done;
}
ret = memcpy_s(disc_res[add_index].tx_match_filter.data,
disc_res[add_index].tx_match_filter.dlen,
disc->tx_match_filter.data, disc->tx_match_filter.dlen);
if (ret != BCME_OK) {
WL_ERR(("Failed to copy tx match filter\n"));
goto done;
}
}
nancfg->nan_disc_count++;
WL_DBG(("cfg->nan_disc_count = %d\n", nancfg->nan_disc_count));
done:
return ret;
}
#ifdef RTT_SUPPORT
/* Sending command to FW for clearing discovery cache info in FW */
static int
wl_cfgnan_clear_disc_cache(struct bcm_cfg80211 *cfg, wl_nan_instance_id_t sub_id)
{
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
uint32 status;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
uint8 buf[NAN_IOCTL_BUF_SIZE];
bcm_iov_batch_buf_t *nan_buf;
bcm_iov_batch_subcmd_t *sub_cmd;
uint16 subcmd_len;
bzero(buf, sizeof(buf));
nan_buf = (bcm_iov_batch_buf_t*)buf;
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t *)(&nan_buf->cmds[0]);
ret = wl_cfg_nan_check_cmd_len(nan_buf_size,
sizeof(sub_id), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
/* Fill the sub_command block */
sub_cmd->id = htod16(WL_NAN_CMD_SD_DISC_CACHE_CLEAR);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(sub_id);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
/* Data size len vs buffer len check is already done above.
* So, short buffer error is impossible.
*/
(void)memcpy_s(sub_cmd->data, (nan_buf_size - OFFSETOF(bcm_iov_batch_subcmd_t, data)),
&sub_id, sizeof(sub_id));
/* adjust iov data len to the end of last data record */
nan_buf_size -= (subcmd_len);
nan_buf->count++;
nan_buf->is_set = true;
nan_buf_size = NAN_IOCTL_BUF_SIZE - nan_buf_size;
/* Same src and dest len here */
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(bcmcfg_to_prmry_ndev(cfg), cfg,
nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("Disc cache clear handler failed ret %d status %d\n",
ret, status));
goto fail;
}
fail:
return ret;
}
#endif /* RTT_SUPPORT */
static int wl_cfgnan_remove_disc_result(struct bcm_cfg80211 *cfg,
uint8 local_subid)
{
int i;
int ret = BCME_NOTFOUND;
nan_disc_result_cache *disc_res = cfg->nancfg->nan_disc_cache;
if (!cfg->nancfg->nan_enable) {
WL_DBG(("nan not enabled\n"));
ret = BCME_NOTENABLED;
goto done;
}
for (i = 0; i < NAN_MAX_CACHE_DISC_RESULT; i++) {
if ((disc_res[i].valid) && (disc_res[i].sub_id == local_subid)) {
WL_TRACE(("make cache entry invalid\n"));
if (disc_res[i].tx_match_filter.data) {
MFREE(cfg->osh, disc_res[i].tx_match_filter.data,
disc_res[i].tx_match_filter.dlen);
}
if (disc_res[i].svc_info.data) {
MFREE(cfg->osh, disc_res[i].svc_info.data,
disc_res[i].svc_info.dlen);
}
bzero(&disc_res[i], sizeof(disc_res[i]));
cfg->nancfg->nan_disc_count--;
ret = BCME_OK;
}
}
WL_DBG(("couldn't find entry\n"));
done:
return ret;
}
static nan_disc_result_cache *
wl_cfgnan_get_disc_result(struct bcm_cfg80211 *cfg, uint8 remote_pubid,
struct ether_addr *peer)
{
int i;
nan_disc_result_cache *disc_res = cfg->nancfg->nan_disc_cache;
if (remote_pubid) {
for (i = 0; i < NAN_MAX_CACHE_DISC_RESULT; i++) {
if ((disc_res[i].pub_id == remote_pubid) &&
!memcmp(&disc_res[i].peer, peer, ETHER_ADDR_LEN)) {
WL_DBG(("Found entry: i = %d\n", i));
return &disc_res[i];
}
}
} else {
for (i = 0; i < NAN_MAX_CACHE_DISC_RESULT; i++) {
if (!memcmp(&disc_res[i].peer, peer, ETHER_ADDR_LEN)) {
WL_DBG(("Found entry: %d\n", i));
return &disc_res[i];
}
}
}
return NULL;
}
#endif /* WL_NAN_DISC_CACHE */
static void
wl_cfgnan_update_dp_info(struct bcm_cfg80211 *cfg, bool add,
nan_data_path_id ndp_id)
{
uint8 i;
bool match_found = false;
wl_nancfg_t *nancfg = cfg->nancfg;
/* As of now, we don't see a need to know which ndp is active.
* so just keep tracking of ndp via count. If we need to know
* the status of each ndp based on ndp id, we need to change
* this implementation to use a bit mask.
*/
if (add) {
/* On first NAN DP establishment, disable ARP. */
for (i = 0; i < NAN_MAX_NDP_PEER; i++) {
if (!nancfg->ndp_id[i]) {
WL_TRACE(("Found empty field\n"));
break;
}
}
if (i == NAN_MAX_NDP_PEER) {
WL_ERR(("%s:cannot accommodate ndp id\n", __FUNCTION__));
return;
}
if (ndp_id) {
nancfg->nan_dp_count++;
nancfg->ndp_id[i] = ndp_id;
WL_DBG(("%s:Added ndp id = [%d] at i = %d\n",
__FUNCTION__, nancfg->ndp_id[i], i));
wl_cfg80211_concurrent_roam(cfg, true);
}
} else {
ASSERT(nancfg->nan_dp_count);
if (ndp_id) {
for (i = 0; i < NAN_MAX_NDP_PEER; i++) {
if (nancfg->ndp_id[i] == ndp_id) {
nancfg->ndp_id[i] = 0;
WL_DBG(("%s:Removed ndp id = [%d] from i = %d\n",
__FUNCTION__, ndp_id, i));
match_found = true;
if (nancfg->nan_dp_count) {
nancfg->nan_dp_count--;
}
break;
} else {
WL_DBG(("couldn't find entry for ndp id = %d\n",
ndp_id));
}
}
if (match_found == false) {
WL_ERR(("Received unsaved NDP Id = %d !!\n", ndp_id));
} else {
if (nancfg->nan_dp_count == 0) {
wl_cfg80211_concurrent_roam(cfg, false);
wl_cfgnan_immediate_nan_disable_pending(cfg);
}
}
}
}
WL_INFORM_MEM(("NAN_DP_COUNT: %d\n", nancfg->nan_dp_count));
}
bool
wl_cfgnan_is_dp_active(struct net_device *ndev)
{
struct bcm_cfg80211 *cfg;
bool nan_dp;
if (!ndev || !ndev->ieee80211_ptr) {
WL_ERR(("ndev/wdev null\n"));
return false;
}
cfg = wiphy_priv(ndev->ieee80211_ptr->wiphy);
nan_dp = cfg->nancfg->nan_dp_count ? true : false;
WL_DBG(("NAN DP status:%d\n", nan_dp));
return nan_dp;
}
static s32
wl_cfgnan_get_ndi_idx(struct bcm_cfg80211 *cfg)
{
int i;
for (i = 0; i < cfg->nancfg->max_ndi_supported; i++) {
if (!cfg->nancfg->ndi[i].in_use) {
/* Free interface, use it */
return i;
}
}
/* Don't have a free interface */
return WL_INVALID;
}
static s32
wl_cfgnan_add_ndi_data(struct bcm_cfg80211 *cfg, s32 idx, char *name)
{
u16 len;
wl_nancfg_t *nancfg = cfg->nancfg;
if (!name || (idx < 0) || (idx >= cfg->nancfg->max_ndi_supported)) {
return -EINVAL;
}
/* Ensure ifname string size <= IFNAMSIZ including null termination */
len = MIN(strlen(name), (IFNAMSIZ - 1));
strncpy(nancfg->ndi[idx].ifname, name, len);
nancfg->ndi[idx].ifname[len] = '\0';
nancfg->ndi[idx].in_use = true;
nancfg->ndi[idx].created = false;
/* Don't have a free interface */
return WL_INVALID;
}
static s32
wl_cfgnan_del_ndi_data(struct bcm_cfg80211 *cfg, char *name)
{
u16 len;
int i;
wl_nancfg_t *nancfg = cfg->nancfg;
if (!name) {
return -EINVAL;
}
len = MIN(strlen(name), IFNAMSIZ);
for (i = 0; i < cfg->nancfg->max_ndi_supported; i++) {
if (strncmp(nancfg->ndi[i].ifname, name, len) == 0) {
bzero(&nancfg->ndi[i].ifname, IFNAMSIZ);
nancfg->ndi[i].in_use = false;
nancfg->ndi[i].created = false;
nancfg->ndi[i].nan_ndev = NULL;
return i;
}
}
return -EINVAL;
}
s32
wl_cfgnan_delete_ndp(struct bcm_cfg80211 *cfg,
struct net_device *nan_ndev)
{
s32 ret = BCME_OK;
uint8 i = 0;
wl_nancfg_t *nancfg = cfg->nancfg;
for (i = 0; i < cfg->nancfg->max_ndi_supported; i++) {
if (nancfg->ndi[i].in_use && nancfg->ndi[i].created &&
(nancfg->ndi[i].nan_ndev == nan_ndev)) {
WL_INFORM_MEM(("iface name: %s, cfg->nancfg->ndi[i].nan_ndev = %p"
" and nan_ndev = %p\n",
(char*)nancfg->ndi[i].ifname,
nancfg->ndi[i].nan_ndev, nan_ndev));
ret = _wl_cfg80211_del_if(cfg, nan_ndev, NULL,
(char*)nancfg->ndi[i].ifname);
if (ret) {
WL_ERR(("failed to del ndi [%d]\n", ret));
}
/*
* Intentional fall through to clear the host data structs
* Unconditionally delete the ndi data and states
*/
if (wl_cfgnan_del_ndi_data(cfg,
(char*)nancfg->ndi[i].ifname) < 0) {
WL_ERR(("Failed to find matching data for ndi:%s\n",
(char*)nancfg->ndi[i].ifname));
}
}
}
return ret;
}
int
wl_cfgnan_get_status(struct net_device *ndev, wl_nan_conf_status_t *nan_status)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
uint16 subcmd_len;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
bcm_iov_batch_subcmd_t *sub_cmd_resp = NULL;
uint8 resp_buf[NAN_IOCTL_BUF_SIZE];
wl_nan_conf_status_t *nstatus = NULL;
uint32 status;
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
struct bcm_cfg80211 *cfg = wl_get_cfg(ndev);
NAN_DBG_ENTER();
nan_buf = MALLOCZ(cfg->osh, NAN_IOCTL_BUF_SIZE);
if (!nan_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(uint8 *)(&nan_buf->cmds[0]);
ret = wl_cfg_nan_check_cmd_len(nan_buf_size,
sizeof(*nstatus), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
nstatus = (wl_nan_conf_status_t *)sub_cmd->data;
sub_cmd->id = htod16(WL_NAN_CMD_CFG_STATUS);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(*nstatus);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
nan_buf_size -= subcmd_len;
nan_buf->count = 1;
nan_buf->is_set = false;
bzero(resp_buf, sizeof(resp_buf));
ret = wl_cfgnan_execute_ioctl(ndev, cfg, nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("get nan status failed ret %d status %d \n",
ret, status));
goto fail;
}
sub_cmd_resp = &((bcm_iov_batch_buf_t *)(resp_buf))->cmds[0];
/* WL_NAN_CMD_CFG_STATUS return value doesn't use xtlv package */
nstatus = ((wl_nan_conf_status_t *)&sub_cmd_resp->data[0]);
ret = memcpy_s(nan_status, sizeof(wl_nan_conf_status_t),
nstatus, sizeof(wl_nan_conf_status_t));
if (ret != BCME_OK) {
WL_ERR(("Failed to copy tx match filter\n"));
goto fail;
}
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
NAN_DBG_EXIT();
return ret;
}
s32
wl_nan_print_avail_stats(const uint8 *data)
{
int idx;
s32 ret = BCME_OK;
int s_chan = 0;
char pbuf[NAN_IOCTL_BUF_SIZE_MED];
const wl_nan_stats_sched_t *sched = (const wl_nan_stats_sched_t *)data;
#define SLOT_PRINT_SIZE 4
char *buf = pbuf;
int remained_len = 0, bytes_written = 0;
bzero(pbuf, sizeof(pbuf));
if ((sched->num_slot * SLOT_PRINT_SIZE) > (sizeof(pbuf)-1)) {
WL_ERR(("overflowed slot number %d detected\n",
sched->num_slot));
ret = BCME_BUFTOOSHORT;
goto exit;
}
remained_len = NAN_IOCTL_BUF_SIZE_MED;
bytes_written = snprintf(buf, remained_len, "Map ID:%u, %u/%u, Slot#:%u ",
sched->map_id, sched->period, sched->slot_dur, sched->num_slot);
for (idx = 0; idx < sched->num_slot; idx++) {
const wl_nan_stats_sched_slot_t *slot;
slot = &sched->slot[idx];
s_chan = 0;
if (!wf_chspec_malformed(slot->chanspec)) {
s_chan = wf_chspec_ctlchan(slot->chanspec);
}
buf += bytes_written;
remained_len -= bytes_written;
bytes_written = snprintf(buf, remained_len, "%03d|", s_chan);
}
WL_INFORM_MEM(("%s\n", pbuf));
exit:
return ret;
}
static int
wl_nan_print_stats_tlvs(void *ctx, const uint8 *data, uint16 type, uint16 len)
{
int err = BCME_OK;
switch (type) {
/* Avail stats xtlvs */
case WL_NAN_XTLV_GEN_AVAIL_STATS_SCHED:
err = wl_nan_print_avail_stats(data);
break;
default:
err = BCME_BADARG;
WL_ERR(("Unknown xtlv type received: %x\n", type));
break;
}
return err;
}
int
wl_cfgnan_get_stats(struct bcm_cfg80211 *cfg)
{
bcm_iov_batch_buf_t *nan_buf = NULL;
uint16 subcmd_len;
bcm_iov_batch_subcmd_t *sub_cmd = NULL;
bcm_iov_batch_subcmd_t *sub_cmd_resp = NULL;
uint8 *resp_buf = NULL;
wl_nan_cmn_get_stat_t *get_stat = NULL;
wl_nan_cmn_stat_t *stats = NULL;
uint32 status;
s32 ret = BCME_OK;
uint16 nan_buf_size = NAN_IOCTL_BUF_SIZE;
NAN_DBG_ENTER();
nan_buf = MALLOCZ(cfg->osh, NAN_IOCTL_BUF_SIZE);
resp_buf = MALLOCZ(cfg->osh, NAN_IOCTL_BUF_SIZE_LARGE);
if (!nan_buf || !resp_buf) {
WL_ERR(("%s: memory allocation failed\n", __func__));
ret = BCME_NOMEM;
goto fail;
}
nan_buf->version = htol16(WL_NAN_IOV_BATCH_VERSION);
nan_buf->count = 0;
nan_buf_size -= OFFSETOF(bcm_iov_batch_buf_t, cmds[0]);
sub_cmd = (bcm_iov_batch_subcmd_t*)(uint8 *)(&nan_buf->cmds[0]);
ret = wl_cfg_nan_check_cmd_len(nan_buf_size,
sizeof(*get_stat), &subcmd_len);
if (unlikely(ret)) {
WL_ERR(("nan_sub_cmd check failed\n"));
goto fail;
}
get_stat = (wl_nan_cmn_get_stat_t *)sub_cmd->data;
/* get only local availabiity stats */
get_stat->modules_btmap = (1 << NAN_AVAIL);
get_stat->operation = WLA_NAN_STATS_GET;
sub_cmd->id = htod16(WL_NAN_CMD_GEN_STATS);
sub_cmd->len = sizeof(sub_cmd->u.options) + sizeof(*get_stat);
sub_cmd->u.options = htol32(BCM_XTLV_OPTION_ALIGN32);
nan_buf_size -= subcmd_len;
nan_buf->count = 1;
nan_buf->is_set = false;
ret = wl_cfgnan_execute_ioctl(bcmcfg_to_prmry_ndev(cfg),
cfg, nan_buf, nan_buf_size, &status,
(void*)resp_buf, NAN_IOCTL_BUF_SIZE_LARGE);
if (unlikely(ret) || unlikely(status)) {
WL_ERR(("get nan stats failed ret %d status %d \n",
ret, status));
goto fail;
}
sub_cmd_resp = &((bcm_iov_batch_buf_t *)(resp_buf))->cmds[0];
stats = (wl_nan_cmn_stat_t *)&sub_cmd_resp->data[0];
if (stats->n_stats) {
WL_INFORM_MEM((" == Aware Local Avail Schedule ==\n"));
ret = bcm_unpack_xtlv_buf((void *)&stats->n_stats,
(const uint8 *)&stats->stats_tlvs,
stats->totlen - 8, BCM_IOV_CMD_OPT_ALIGN32,
wl_nan_print_stats_tlvs);
}
fail:
if (nan_buf) {
MFREE(cfg->osh, nan_buf, NAN_IOCTL_BUF_SIZE);
}
if (resp_buf) {
MFREE(cfg->osh, resp_buf, NAN_IOCTL_BUF_SIZE_LARGE);
}
NAN_DBG_EXIT();
return ret;
}
int
wl_cfgnan_attach(struct bcm_cfg80211 *cfg)
{
int err = BCME_OK;
wl_nancfg_t *nancfg = NULL;
if (cfg) {
cfg->nancfg = (wl_nancfg_t *)MALLOCZ(cfg->osh, sizeof(wl_nancfg_t));
if (cfg->nancfg == NULL) {
err = BCME_NOMEM;
goto done;
}
cfg->nancfg->cfg = cfg;
} else {
err = BCME_BADARG;
goto done;
}
nancfg = cfg->nancfg;
mutex_init(&nancfg->nan_sync);
init_waitqueue_head(&nancfg->nan_event_wait);
INIT_DELAYED_WORK(&nancfg->nan_disable, wl_cfgnan_delayed_disable);
nancfg->nan_dp_state = NAN_DP_STATE_DISABLED;
init_waitqueue_head(&nancfg->ndp_if_change_event);
done:
return err;
}
void
wl_cfgnan_detach(struct bcm_cfg80211 *cfg)
{
if (cfg && cfg->nancfg) {
if (delayed_work_pending(&cfg->nancfg->nan_disable)) {
WL_DBG(("Cancel nan_disable work\n"));
DHD_NAN_WAKE_UNLOCK(cfg->pub);
cancel_delayed_work_sync(&cfg->nancfg->nan_disable);
}
MFREE(cfg->osh, cfg->nancfg, sizeof(wl_nancfg_t));
cfg->nancfg = NULL;
}
}
#endif /* WL_NAN */