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fuchsia / garnet / refs/heads/sandbox/cphoenix/brcmfmac / . / drivers / wlan / third_party / broadcom / brcmfmac / cfg80211.c
blob: fb4a0daa95dfb0518f51faf96841ca268b1bdb0b [file] [log] [blame]
/*
* Copyright (c) 2010 Broadcom Corporation
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
* SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION
* OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
* CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
/* Toplevel file. Relies on dhd_linux.c to send commands to the dongle. */
#include "cfg80211.h"
#include <wlan/protocol/if-impl.h>
#include <zircon/status.h>
#include <threads.h>
#include "brcmu_utils.h"
#include "brcmu_wifi.h"
#include "btcoex.h"
#include "bus.h"
#include "common.h"
#include "core.h"
#include "debug.h"
#include "defs.h"
#include "device.h"
#include "feature.h"
#include "fwil.h"
#include "fwil_types.h"
#include "linuxisms.h"
#include "netbuf.h"
#include "p2p.h"
#include "pno.h"
#include "proto.h"
#include "tracepoint.h"
#include "vendor.h"
#include "workqueue.h"
#define BRCMF_SCAN_IE_LEN_MAX 2048
#define WPA_OUI "\x00\x50\xF2" /* WPA OUI */
#define WPA_OUI_TYPE 1
#define RSN_OUI "\x00\x0F\xAC" /* RSN OUI */
#define WME_OUI_TYPE 2
#define WPS_OUI_TYPE 4
#define VS_IE_FIXED_HDR_LEN 6
#define WPA_IE_VERSION_LEN 2
#define WPA_IE_MIN_OUI_LEN 4
#define WPA_IE_SUITE_COUNT_LEN 2
#define WPA_CIPHER_NONE 0 /* None */
#define WPA_CIPHER_WEP_40 1 /* WEP (40-bit) */
#define WPA_CIPHER_TKIP 2 /* TKIP: default for WPA */
#define WPA_CIPHER_AES_CCM 4 /* AES (CCM) */
#define WPA_CIPHER_WEP_104 5 /* WEP (104-bit) */
#define RSN_AKM_NONE 0 /* None (IBSS) */
#define RSN_AKM_UNSPECIFIED 1 /* Over 802.1x */
#define RSN_AKM_PSK 2 /* Pre-shared Key */
#define RSN_AKM_SHA256_1X 5 /* SHA256, 802.1X */
#define RSN_AKM_SHA256_PSK 6 /* SHA256, Pre-shared Key */
#define RSN_CAP_LEN 2 /* Length of RSN capabilities */
#define RSN_CAP_PTK_REPLAY_CNTR_MASK (BIT(2) | BIT(3))
#define RSN_CAP_MFPR_MASK BIT(6)
#define RSN_CAP_MFPC_MASK BIT(7)
#define RSN_PMKID_COUNT_LEN 2
#define VNDR_IE_CMD_LEN 4 /* length of the set command string :"add", "del" (+ NUL) */
#define VNDR_IE_COUNT_OFFSET 4
#define VNDR_IE_PKTFLAG_OFFSET 8
#define VNDR_IE_VSIE_OFFSET 12
#define VNDR_IE_HDR_SIZE 12
#define VNDR_IE_PARSE_LIMIT 5
#define DOT11_MGMT_HDR_LEN 24 /* d11 management header len */
#define DOT11_BCN_PRB_FIXED_LEN 12 /* beacon/probe fixed length */
#define BRCMF_SCAN_JOIN_ACTIVE_DWELL_TIME_MS 320
#define BRCMF_SCAN_JOIN_PASSIVE_DWELL_TIME_MS 400
#define BRCMF_SCAN_JOIN_PROBE_INTERVAL_MS 20
#define BRCMF_SCAN_CHANNEL_TIME 40
#define BRCMF_SCAN_UNASSOC_TIME 40
#define BRCMF_SCAN_PASSIVE_TIME 120
#define BRCMF_ND_INFO_TIMEOUT_MSEC 2000
#define BRCMF_ASSOC_PARAMS_FIXED_SIZE (sizeof(struct brcmf_assoc_params_le) - sizeof(uint16_t))
static bool check_vif_up(struct brcmf_cfg80211_vif* vif) {
if (!brcmf_test_bit_in_array(BRCMF_VIF_STATUS_READY, &vif->sme_state)) {
brcmf_dbg(INFO, "device is not ready : status (%lu)\n", vif->sme_state);
return false;
}
return true;
}
#define RATE_TO_BASE100KBPS(rate) (((rate)*10) / 2)
#define RATETAB_ENT(_rateid, _flags) \
{ .bitrate = RATE_TO_BASE100KBPS(_rateid), .hw_value = (_rateid), .flags = (_flags), }
static struct ieee80211_rate __wl_rates[] = {
RATETAB_ENT(BRCM_RATE_1M, 0),
RATETAB_ENT(BRCM_RATE_2M, IEEE80211_RATE_SHORT_PREAMBLE),
RATETAB_ENT(BRCM_RATE_5M5, IEEE80211_RATE_SHORT_PREAMBLE),
RATETAB_ENT(BRCM_RATE_11M, IEEE80211_RATE_SHORT_PREAMBLE),
RATETAB_ENT(BRCM_RATE_6M, 0),
RATETAB_ENT(BRCM_RATE_9M, 0),
RATETAB_ENT(BRCM_RATE_12M, 0),
RATETAB_ENT(BRCM_RATE_18M, 0),
RATETAB_ENT(BRCM_RATE_24M, 0),
RATETAB_ENT(BRCM_RATE_36M, 0),
RATETAB_ENT(BRCM_RATE_48M, 0),
RATETAB_ENT(BRCM_RATE_54M, 0),
};
#define wl_g_rates (__wl_rates + 0)
#define wl_g_rates_size ARRAY_SIZE(__wl_rates)
#define wl_a_rates (__wl_rates + 4)
#define wl_a_rates_size (wl_g_rates_size - 4)
#define CHAN2G(_channel, _freq) \
{ \
.band = NL80211_BAND_2GHZ, .center_freq = (_freq), .hw_value = (_channel), \
.max_antenna_gain = 0, .max_power = 30, \
}
#define CHAN5G(_channel) \
{ \
.band = NL80211_BAND_5GHZ, .center_freq = 5000 + (5 * (_channel)), .hw_value = (_channel), \
.max_antenna_gain = 0, .max_power = 30, \
}
static struct ieee80211_channel __wl_2ghz_channels[] = {
CHAN2G(1, 2412),
CHAN2G(2, 2417),
CHAN2G(3, 2422),
CHAN2G(4, 2427),
CHAN2G(5, 2432),
CHAN2G(6, 2437),
CHAN2G(7, 2442),
CHAN2G(8, 2447),
CHAN2G(9, 2452),
CHAN2G(10, 2457),
CHAN2G(11, 2462),
CHAN2G(12, 2467),
CHAN2G(13, 2472),
CHAN2G(14, 2484)
};
static struct ieee80211_channel __wl_5ghz_channels[] = {
CHAN5G(34),
CHAN5G(36),
CHAN5G(38),
CHAN5G(40),
CHAN5G(42),
CHAN5G(44),
CHAN5G(46),
CHAN5G(48),
CHAN5G(52),
CHAN5G(56),
CHAN5G(60),
CHAN5G(64),
CHAN5G(100),
CHAN5G(104),
CHAN5G(108),
CHAN5G(112),
CHAN5G(116),
CHAN5G(120),
CHAN5G(124),
CHAN5G(128),
CHAN5G(132),
CHAN5G(136),
CHAN5G(140),
CHAN5G(144),
CHAN5G(149),
CHAN5G(153),
CHAN5G(157),
CHAN5G(161),
CHAN5G(165)
};
/* Band templates duplicated per wiphy. The channel info
* above is added to the band during setup.
*/
static const struct ieee80211_supported_band __wl_band_2ghz = {
.band = NL80211_BAND_2GHZ,
.bitrates = wl_g_rates,
.n_bitrates = wl_g_rates_size,
};
static const struct ieee80211_supported_band __wl_band_5ghz = {
.band = NL80211_BAND_5GHZ,
.bitrates = wl_a_rates,
.n_bitrates = wl_a_rates_size,
};
/* This is to override regulatory domains defined in cfg80211 module (reg.c)
* By default world regulatory domain defined in reg.c puts the flags
* NL80211_RRF_NO_IR for 5GHz channels (for * 36..48 and 149..165).
* With respect to these flags, wpa_supplicant doesn't * start p2p
* operations on 5GHz channels. All the changes in world regulatory
* domain are to be done here.
*/
// TODO(cphoenix): Re-enable this when we know how to use it.
#ifdef REGULATORY_DOMAIN_OVERRIDE
static const struct ieee80211_regdomain brcmf_regdom = {
.n_reg_rules = 4,
.alpha2 = "99",
.reg_rules = {
/* IEEE 802.11b/g, channels 1..11 */
REG_RULE(2412 - 10, 2472 + 10, 40, 6, 20, 0),
/* If any */
/* IEEE 802.11 channel 14 - Only JP enables
* this and for 802.11b only
*/
REG_RULE(2484 - 10, 2484 + 10, 20, 6, 20, 0),
/* IEEE 802.11a, channel 36..64 */
REG_RULE(5150 - 10, 5350 + 10, 80, 6, 20, 0),
/* IEEE 802.11a, channel 100..165 */
REG_RULE(5470 - 10, 5850 + 10, 80, 6, 20, 0),
}
};
#endif // REGULATORY_DOMAIN_OVERRIDE
/* Note: brcmf_cipher_suites is an array of int defining which cipher suites
* are supported. A pointer to this array and the number of entries is passed
* on to upper layers. AES_CMAC defines whether or not the driver supports MFP.
* So the cipher suite AES_CMAC has to be the last one in the array, and when
* device does not support MFP then the number of suites will be decreased by 1
*/
static const uint32_t brcmf_cipher_suites[] = {
WLAN_CIPHER_SUITE_WEP40,
WLAN_CIPHER_SUITE_WEP104,
WLAN_CIPHER_SUITE_TKIP,
WLAN_CIPHER_SUITE_CCMP,
/* Keep as last entry: */
WLAN_CIPHER_SUITE_AES_CMAC
};
/* Vendor specific ie. id = 221, oui and type defines exact ie */
struct brcmf_vs_tlv {
uint8_t id;
uint8_t len;
uint8_t oui[3];
uint8_t oui_type;
};
struct parsed_vndr_ie_info {
uint8_t* ie_ptr;
uint32_t ie_len; /* total length including id & length field */
struct brcmf_vs_tlv vndrie;
};
struct parsed_vndr_ies {
uint32_t count;
struct parsed_vndr_ie_info ie_info[VNDR_IE_PARSE_LIMIT];
};
uint8_t nl80211_band_to_fwil(enum nl80211_band band) {
switch (band) {
case NL80211_BAND_2GHZ:
return WLC_BAND_2G;
case NL80211_BAND_5GHZ:
return WLC_BAND_5G;
default:
WARN_ON(1);
break;
}
return 0;
}
static uint16_t chandef_to_chanspec(struct brcmu_d11inf* d11inf, struct cfg80211_chan_def* ch) {
struct brcmu_chan ch_inf;
int32_t primary_offset;
brcmf_dbg(TRACE, "chandef: control %d center %d width %d\n", ch->chan->center_freq,
ch->center_freq1, ch->width);
ch_inf.chnum = ieee80211_frequency_to_channel(ch->center_freq1);
primary_offset = ch->chan->center_freq - ch->center_freq1;
switch (ch->width) {
case NL80211_CHAN_WIDTH_20:
case NL80211_CHAN_WIDTH_20_NOHT:
ch_inf.bw = BRCMU_CHAN_BW_20;
WARN_ON(primary_offset != 0);
break;
case NL80211_CHAN_WIDTH_40:
ch_inf.bw = BRCMU_CHAN_BW_40;
if (primary_offset > 0) {
ch_inf.sb = BRCMU_CHAN_SB_U;
} else {
ch_inf.sb = BRCMU_CHAN_SB_L;
}
break;
case NL80211_CHAN_WIDTH_80:
ch_inf.bw = BRCMU_CHAN_BW_80;
if (primary_offset == -30) {
ch_inf.sb = BRCMU_CHAN_SB_LL;
} else if (primary_offset == -10) {
ch_inf.sb = BRCMU_CHAN_SB_LU;
} else if (primary_offset == 10) {
ch_inf.sb = BRCMU_CHAN_SB_UL;
} else {
ch_inf.sb = BRCMU_CHAN_SB_UU;
}
break;
case NL80211_CHAN_WIDTH_80P80:
case NL80211_CHAN_WIDTH_160:
case NL80211_CHAN_WIDTH_5:
case NL80211_CHAN_WIDTH_10:
default:
WARN_ON_ONCE(1);
}
switch (ch->chan->band) {
case NL80211_BAND_2GHZ:
ch_inf.band = BRCMU_CHAN_BAND_2G;
break;
case NL80211_BAND_5GHZ:
ch_inf.band = BRCMU_CHAN_BAND_5G;
break;
case NL80211_BAND_60GHZ:
default:
WARN_ON_ONCE(1);
}
d11inf->encchspec(&ch_inf);
return ch_inf.chspec;
}
uint16_t channel_to_chanspec(struct brcmu_d11inf* d11inf, struct ieee80211_channel* ch) {
struct brcmu_chan ch_inf;
ch_inf.chnum = ieee80211_frequency_to_channel(ch->center_freq);
ch_inf.bw = BRCMU_CHAN_BW_20;
d11inf->encchspec(&ch_inf);
return ch_inf.chspec;
}
/* Traverse a string of 1-byte tag/1-byte length/variable-length value
* triples, returning a pointer to the substring whose first element
* matches tag
*/
const struct brcmf_tlv* brcmf_parse_tlvs(const void* buf, int buflen, uint key) {
const struct brcmf_tlv* elt = buf;
int totlen = buflen;
/* find tagged parameter */
while (totlen >= TLV_HDR_LEN) {
int len = elt->len;
/* validate remaining totlen */
if ((elt->id == key) && (totlen >= (len + TLV_HDR_LEN))) {
return elt;
}
elt = (struct brcmf_tlv*)((uint8_t*)elt + (len + TLV_HDR_LEN));
totlen -= (len + TLV_HDR_LEN);
}
return NULL;
}
/* Is any of the tlvs the expected entry? If
* not update the tlvs buffer pointer/length.
*/
static bool brcmf_tlv_has_ie(const uint8_t* ie, const uint8_t** tlvs, uint32_t* tlvs_len,
const uint8_t* oui, uint32_t oui_len, uint8_t type) {
/* If the contents match the OUI and the type */
if (ie[TLV_LEN_OFF] >= oui_len + 1 && !memcmp(&ie[TLV_BODY_OFF], oui, oui_len) &&
type == ie[TLV_BODY_OFF + oui_len]) {
return true;
}
if (tlvs == NULL) {
return false;
}
/* point to the next ie */
ie += ie[TLV_LEN_OFF] + TLV_HDR_LEN;
/* calculate the length of the rest of the buffer */
*tlvs_len -= (int)(ie - *tlvs);
/* update the pointer to the start of the buffer */
*tlvs = ie;
return false;
}
struct brcmf_vs_tlv* brcmf_find_wpaie(const uint8_t* parse, uint32_t len) {
const struct brcmf_tlv* ie;
while ((ie = brcmf_parse_tlvs(parse, len, WLAN_EID_VENDOR_SPECIFIC))) {
if (brcmf_tlv_has_ie((const uint8_t*)ie, &parse, &len, (const uint8_t*)WPA_OUI, TLV_OUI_LEN,
WPA_OUI_TYPE)) {
return (struct brcmf_vs_tlv*)ie;
}
}
return NULL;
}
struct brcmf_vs_tlv* brcmf_find_wpsie(const uint8_t* parse, uint32_t len) {
const struct brcmf_tlv* ie;
while ((ie = brcmf_parse_tlvs(parse, len, WLAN_EID_VENDOR_SPECIFIC))) {
if (brcmf_tlv_has_ie((uint8_t*)ie, &parse, &len, (const uint8_t*)WPA_OUI, TLV_OUI_LEN,
WPS_OUI_TYPE)) {
return (struct brcmf_vs_tlv*)ie;
}
}
return NULL;
}
static zx_status_t brcmf_vif_change_validate(struct brcmf_cfg80211_info* cfg,
struct brcmf_cfg80211_vif* vif,
enum nl80211_iftype new_type) {
struct brcmf_cfg80211_vif* pos;
bool check_combos = false;
zx_status_t ret = ZX_OK;
struct iface_combination_params params = {
.num_different_channels = 1,
};
list_for_every_entry(&cfg->vif_list, pos, struct brcmf_cfg80211_vif, list) {
if (pos == vif) {
params.iftype_num[new_type]++;
} else {
/* concurrent interfaces so need check combinations */
check_combos = true;
params.iftype_num[pos->wdev.iftype]++;
}
}
if (check_combos) {
ret = cfg80211_check_combinations(cfg->wiphy, &params);
}
return ret;
}
static zx_status_t brcmf_vif_add_validate(struct brcmf_cfg80211_info* cfg,
enum nl80211_iftype new_type) {
struct brcmf_cfg80211_vif* pos;
struct iface_combination_params params = {
.num_different_channels = 1,
};
list_for_every_entry(&cfg->vif_list, pos, struct brcmf_cfg80211_vif, list) {
params.iftype_num[pos->wdev.iftype]++;
}
params.iftype_num[new_type]++;
return cfg80211_check_combinations(cfg->wiphy, &params);
}
static void convert_key_from_CPU(struct brcmf_wsec_key* key, struct brcmf_wsec_key_le* key_le) {
key_le->index = key->index;
key_le->len = key->len;
key_le->algo = key->algo;
key_le->flags = key->flags;
key_le->rxiv.hi = key->rxiv.hi;
key_le->rxiv.lo = key->rxiv.lo;
key_le->iv_initialized = key->iv_initialized;
memcpy(key_le->data, key->data, sizeof(key->data));
memcpy(key_le->ea, key->ea, sizeof(key->ea));
}
static zx_status_t send_key_to_dongle(struct brcmf_if* ifp, struct brcmf_wsec_key* key) {
zx_status_t err;
struct brcmf_wsec_key_le key_le;
convert_key_from_CPU(key, &key_le);
brcmf_netdev_wait_pend8021x(ifp);
err = brcmf_fil_bsscfg_data_set(ifp, "wsec_key", &key_le, sizeof(key_le));
if (err != ZX_OK) {
brcmf_err("wsec_key error (%d)\n", err);
}
return err;
}
static void brcmf_cfg80211_update_proto_addr_mode(struct wireless_dev* wdev) {
struct brcmf_cfg80211_vif* vif;
struct brcmf_if* ifp;
vif = containerof(wdev, struct brcmf_cfg80211_vif, wdev);
ifp = vif->ifp;
if ((wdev->iftype == NL80211_IFTYPE_ADHOC) || (wdev->iftype == NL80211_IFTYPE_AP) ||
(wdev->iftype == NL80211_IFTYPE_P2P_GO)) {
brcmf_proto_configure_addr_mode(ifp->drvr, ifp->ifidx, ADDR_DIRECT);
} else {
brcmf_proto_configure_addr_mode(ifp->drvr, ifp->ifidx, ADDR_INDIRECT);
}
}
static zx_status_t brcmf_get_first_free_bsscfgidx(struct brcmf_pub* drvr) {
int bsscfgidx;
for (bsscfgidx = 0; bsscfgidx < BRCMF_MAX_IFS; bsscfgidx++) {
/* bsscfgidx 1 is reserved for legacy P2P */
if (bsscfgidx == 1) {
continue;
}
if (!drvr->iflist[bsscfgidx]) {
return bsscfgidx;
}
}
return ZX_ERR_NO_MEMORY;
}
static zx_status_t brcmf_cfg80211_request_ap_if(struct brcmf_if* ifp) {
struct brcmf_mbss_ssid_le mbss_ssid_le;
int bsscfgidx;
zx_status_t err;
memset(&mbss_ssid_le, 0, sizeof(mbss_ssid_le));
bsscfgidx = brcmf_get_first_free_bsscfgidx(ifp->drvr);
if (bsscfgidx < 0) {
return bsscfgidx;
}
mbss_ssid_le.bsscfgidx = bsscfgidx;
mbss_ssid_le.SSID_len = 5;
sprintf((char*)mbss_ssid_le.SSID, "ssid%d", bsscfgidx);
err = brcmf_fil_bsscfg_data_set(ifp, "bsscfg:ssid", &mbss_ssid_le, sizeof(mbss_ssid_le));
if (err != ZX_OK) {
brcmf_err("setting ssid failed %d\n", err);
}
return err;
}
/**
* brcmf_ap_add_vif() - create a new AP virtual interface for multiple BSS
*
* @wiphy: wiphy device of new interface.
* @name: name of the new interface.
* @params: contains mac address for AP device.
*/
static zx_status_t brcmf_ap_add_vif(struct wiphy* wiphy, const char* name,
struct vif_params* params, struct wireless_dev** dev_out) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_if* ifp = cfg_to_if(cfg);
struct brcmf_cfg80211_vif* vif;
zx_status_t err;
if (brcmf_cfg80211_vif_event_armed(cfg)) {
return ZX_ERR_UNAVAILABLE;
}
brcmf_dbg(INFO, "Adding vif \"%s\"\n", name);
err = brcmf_alloc_vif(cfg, NL80211_IFTYPE_AP, &vif);
if (err != ZX_OK) {
if (dev_out) {
*dev_out = NULL;
}
return err;
}
brcmf_cfg80211_arm_vif_event(cfg, vif, BRCMF_E_IF_ADD);
err = brcmf_cfg80211_request_ap_if(ifp);
if (err != ZX_OK) {
brcmf_cfg80211_disarm_vif_event(cfg);
goto fail;
}
// TODO(cphoenix): Lots of duplicated code between here and brcmf_p2p_add_vif() (p2p.c:2057).
/* wait for firmware event */
err = brcmf_cfg80211_wait_vif_event(cfg, ZX_MSEC(BRCMF_VIF_EVENT_TIMEOUT_MSEC));
brcmf_cfg80211_disarm_vif_event(cfg);
if (err != ZX_OK) {
brcmf_err("timeout occurred\n");
err = ZX_ERR_IO;
goto fail;
}
/* interface created in firmware */
ifp = vif->ifp;
if (!ifp) {
brcmf_err("no if pointer provided\n");
err = ZX_ERR_INVALID_ARGS;
goto fail;
}
strncpy(ifp->ndev->name, name, sizeof(ifp->ndev->name) - 1);
err = brcmf_net_attach(ifp, true);
if (err != ZX_OK) {
brcmf_err("Registering netdevice failed\n");
brcmf_free_net_device(ifp->ndev);
goto fail;
}
if (dev_out) {
*dev_out = &ifp->vif->wdev;
}
return ZX_OK;
fail:
brcmf_free_vif(vif);
if (dev_out) {
*dev_out = NULL;
}
return err;
}
static bool brcmf_is_apmode(struct brcmf_cfg80211_vif* vif) {
enum nl80211_iftype iftype;
iftype = vif->wdev.iftype;
return iftype == NL80211_IFTYPE_AP || iftype == NL80211_IFTYPE_P2P_GO;
}
static bool brcmf_is_ibssmode(struct brcmf_cfg80211_vif* vif) {
return vif->wdev.iftype == NL80211_IFTYPE_ADHOC;
}
zx_status_t brcmf_cfg80211_add_iface(struct wiphy* wiphy, const char* name,
unsigned char name_assign_type, enum nl80211_iftype type,
struct vif_params* params, struct wireless_dev** wdev_out) {
zx_status_t err;
brcmf_dbg(TRACE, "enter: %s type %d\n", name, type);
err = brcmf_vif_add_validate(wiphy_to_cfg(wiphy), type);
if (err != ZX_OK) {
brcmf_err("iface validation failed: err=%d\n", err);
if (wdev_out) {
*wdev_out = NULL;
}
return err;
}
switch (type) {
case NL80211_IFTYPE_ADHOC:
case NL80211_IFTYPE_STATION:
case NL80211_IFTYPE_AP_VLAN:
case NL80211_IFTYPE_WDS:
case NL80211_IFTYPE_MONITOR:
case NL80211_IFTYPE_MESH_POINT:
if (wdev_out) {
*wdev_out = NULL;
}
return ZX_ERR_WRONG_TYPE;
case NL80211_IFTYPE_AP:
err = brcmf_ap_add_vif(wiphy, name, params, wdev_out);
break;
case NL80211_IFTYPE_P2P_CLIENT:
case NL80211_IFTYPE_P2P_GO:
case NL80211_IFTYPE_P2P_DEVICE:
err = brcmf_p2p_add_vif(wiphy, name, type, params, wdev_out);
break;
case NL80211_IFTYPE_UNSPECIFIED:
default:
if (wdev_out) {
*wdev_out = NULL;
}
return ZX_ERR_INVALID_ARGS;
}
if (err != ZX_OK) {
brcmf_err("add iface %s type %d failed: err=%d\n", name, type, err);
if (wdev_out) {
*wdev_out = NULL;
}
return err;
} else {
brcmf_cfg80211_update_proto_addr_mode(*wdev_out);
return ZX_OK;
}
}
static void brcmf_scan_config_mpc(struct brcmf_if* ifp, int mpc) {
if (brcmf_feat_is_quirk_enabled(ifp, BRCMF_FEAT_QUIRK_NEED_MPC)) {
brcmf_set_mpc(ifp, mpc);
}
}
void brcmf_set_mpc(struct brcmf_if* ifp, int mpc) {
zx_status_t err = 0;
if (check_vif_up(ifp->vif)) {
err = brcmf_fil_iovar_int_set(ifp, "mpc", mpc);
if (err != ZX_OK) {
brcmf_err("fail to set mpc\n");
return;
}
brcmf_dbg(INFO, "MPC : %d\n", mpc);
}
}
static void brcmf_signal_scan_end(struct net_device* ndev, uint64_t txn_id,
enum wlanif_scan_result_codes code) {
wlanif_scan_end_t args;
args.txn_id = txn_id;
args.code = code;
if (ndev->if_callbacks != NULL) {
brcmf_dbg(TEMP, "Signaling on_scan_end with txn_id %ld and code %d", args.txn_id,
args.code);
ndev->if_callbacks->on_scan_end(ndev->if_callback_cookie, &args);
}
ndev_to_wiphy(ndev)->scan_busy = false;
}
zx_status_t brcmf_notify_escan_complete(struct brcmf_cfg80211_info* cfg, struct brcmf_if* ifp,
bool aborted, bool fw_abort) {
struct brcmf_scan_params_le params_le;
struct cfg80211_scan_request* scan_request;
uint64_t reqid;
uint32_t bucket;
zx_status_t err = ZX_OK;
brcmf_dbg(SCAN, "Enter\n");
/* clear scan request, because the FW abort can cause a second call */
/* to this function and might cause a double cfg80211_scan_done */
scan_request = cfg->scan_request;
cfg->scan_request = NULL;
// Canceling if it's inactive is OK. Checking if it's active just invites race conditions.
brcmf_timer_stop(&cfg->escan_timeout);
if (fw_abort) {
/* Do a scan abort to stop the driver's scan engine */
brcmf_dbg(SCAN, "ABORT scan in firmware\n");
memset(&params_le, 0, sizeof(params_le));
fill_with_broadcast_addr(params_le.bssid);
params_le.bss_type = DOT11_BSSTYPE_ANY;
params_le.scan_type = 0;
params_le.channel_num = 1;
params_le.nprobes = 1;
params_le.active_time = -1;
params_le.passive_time = -1;
params_le.home_time = -1;
/* Scan is aborted by setting channel_list[0] to -1 */
params_le.channel_list[0] = -1;
/* E-Scan (or anyother type) can be aborted by SCAN */
err = brcmf_fil_cmd_data_set(ifp, BRCMF_C_SCAN, &params_le, sizeof(params_le));
if (err != ZX_OK) {
brcmf_err("Scan abort failed\n");
}
}
brcmf_scan_config_mpc(ifp, 1);
/*
* e-scan can be initiated internally
* which takes precedence.
*/
if (cfg->int_escan_map) {
brcmf_dbg(SCAN, "scheduled scan completed (%x)\n", cfg->int_escan_map);
while (cfg->int_escan_map) {
bucket = ffs(cfg->int_escan_map) - 1; // ffs() index is 1-based
cfg->int_escan_map &= ~BIT(bucket);
reqid = brcmf_pno_find_reqid_by_bucket(cfg->pno, bucket);
if (!aborted) {
// TODO(cphoenix): Figure out how to use internal reqid infrastructure, rather
// than storing it separately in wiphy->scan_txn_id.
brcmf_dbg(SCAN, " * * report scan results: internal reqid=%lu\n", reqid);
brcmf_signal_scan_end(cfg_to_ndev(cfg), cfg_to_wiphy(cfg)->scan_txn_id,
SCAN_RESULT_SUCCESS);
}
}
} else if (scan_request) {
brcmf_dbg(SCAN, "ESCAN Completed scan: %s\n", aborted ? "Aborted" : "Done");
brcmf_signal_scan_end(cfg_to_ndev(cfg), cfg_to_wiphy(cfg)->scan_txn_id,
aborted ? SCAN_RESULT_INTERNAL_ERROR : SCAN_RESULT_SUCCESS);
}
if (!brcmf_test_and_clear_bit_in_array(BRCMF_SCAN_STATUS_BUSY, &cfg->scan_status)) {
brcmf_dbg(SCAN, "Scan complete, probably P2P scan\n");
}
return err;
}
static zx_status_t brcmf_cfg80211_del_ap_iface(struct wiphy* wiphy, struct wireless_dev* wdev) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct net_device* ndev = wdev->netdev;
struct brcmf_if* ifp = ndev_to_if(ndev);
zx_status_t err;
brcmf_cfg80211_arm_vif_event(cfg, ifp->vif, BRCMF_E_IF_DEL);
err = brcmf_fil_bsscfg_data_set(ifp, "interface_remove", NULL, 0);
if (err != ZX_OK) {
brcmf_err("interface_remove failed %d\n", err);
goto err_unarm;
}
/* wait for firmware event */
err = brcmf_cfg80211_wait_vif_event(cfg, ZX_MSEC(BRCMF_VIF_EVENT_TIMEOUT_MSEC));
if (err != ZX_OK) {
brcmf_err("timeout occurred\n");
err = ZX_ERR_IO;
goto err_unarm;
}
brcmf_remove_interface(ifp, true);
err_unarm:
brcmf_cfg80211_disarm_vif_event(cfg);
return err;
}
static int brcmf_cfg80211_del_iface(struct wiphy* wiphy, struct wireless_dev* wdev) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct net_device* ndev = wdev->netdev;
if (ndev && ndev == cfg_to_ndev(cfg)) {
return ZX_ERR_NOT_SUPPORTED;
}
/* vif event pending in firmware */
if (brcmf_cfg80211_vif_event_armed(cfg)) {
return ZX_ERR_UNAVAILABLE;
}
if (ndev) {
if (brcmf_test_bit_in_array(BRCMF_SCAN_STATUS_BUSY, &cfg->scan_status) &&
cfg->escan_info.ifp == ndev_to_if(ndev)) {
brcmf_notify_escan_complete(cfg, ndev_to_if(ndev), true, true);
}
brcmf_fil_iovar_int_set(ndev_to_if(ndev), "mpc", 1);
}
switch (wdev->iftype) {
case NL80211_IFTYPE_ADHOC:
case NL80211_IFTYPE_STATION:
case NL80211_IFTYPE_AP_VLAN:
case NL80211_IFTYPE_WDS:
case NL80211_IFTYPE_MONITOR:
case NL80211_IFTYPE_MESH_POINT:
return ZX_ERR_NOT_SUPPORTED;
case NL80211_IFTYPE_AP:
return brcmf_cfg80211_del_ap_iface(wiphy, wdev);
case NL80211_IFTYPE_P2P_CLIENT:
case NL80211_IFTYPE_P2P_GO:
case NL80211_IFTYPE_P2P_DEVICE:
return brcmf_p2p_del_vif(wiphy, wdev);
case NL80211_IFTYPE_UNSPECIFIED:
default:
return ZX_ERR_OUT_OF_RANGE;
}
return ZX_ERR_NOT_SUPPORTED;
}
static zx_status_t brcmf_cfg80211_change_iface(struct wiphy* wiphy, struct net_device* ndev,
enum nl80211_iftype type,
struct vif_params* params) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_cfg80211_vif* vif = ifp->vif;
int32_t infra = 0;
int32_t ap = 0;
zx_status_t err = ZX_OK;
brcmf_dbg(TRACE, "Enter");
/* WAR: There are a number of p2p interface related problems which
* need to be handled initially (before doing the validate).
* wpa_supplicant tends to do iface changes on p2p device/client/go
* which are not always possible/allowed. However we need to return
* OK otherwise the wpa_supplicant wont start. The situation differs
* on configuration and setup (p2pon=1 module param). The first check
* is to see if the request is a change to station for p2p iface.
*/
if ((type == NL80211_IFTYPE_STATION) && ((vif->wdev.iftype == NL80211_IFTYPE_P2P_CLIENT) ||
(vif->wdev.iftype == NL80211_IFTYPE_P2P_GO) ||
(vif->wdev.iftype == NL80211_IFTYPE_P2P_DEVICE))) {
brcmf_dbg(TRACE, "Ignoring cmd for p2p if\n");
/* Now depending on whether module param p2pon=1 was used the
* response needs to be either 0 or ZX_ERR_NOT_SUPPORTED. The reason is
* that if p2pon=1 is used, but a newer supplicant is used then
* we should return an error, as this combination wont work.
* In other situations 0 is returned and supplicant will start
* normally. It will give a trace in cfg80211, but it is the
* only way to get it working. Unfortunately this will result
* in situation where we wont support new supplicant in
* combination with module param p2pon=1, but that is the way
* it is. If the user tries this then unloading of driver might
* fail/lock.
*/
if (cfg->p2p.p2pdev_dynamically) {
return ZX_ERR_NOT_SUPPORTED;
} else {
return ZX_OK;
}
}
err = brcmf_vif_change_validate(wiphy_to_cfg(wiphy), vif, type);
if (err != ZX_OK) {
brcmf_err("iface validation failed: err=%d\n", err);
return err;
}
switch (type) {
case NL80211_IFTYPE_MONITOR:
case NL80211_IFTYPE_WDS:
brcmf_err("type (%d) : currently we do not support this type\n", type);
return ZX_ERR_NOT_SUPPORTED;
case NL80211_IFTYPE_ADHOC:
infra = 0;
break;
case NL80211_IFTYPE_STATION:
infra = 1;
break;
case NL80211_IFTYPE_AP:
case NL80211_IFTYPE_P2P_GO:
ap = 1;
break;
default:
err = ZX_ERR_OUT_OF_RANGE;
goto done;
}
if (ap) {
if (type == NL80211_IFTYPE_P2P_GO) {
brcmf_dbg(INFO, "IF Type = P2P GO\n");
err = brcmf_p2p_ifchange(cfg, BRCMF_FIL_P2P_IF_GO);
}
if (err == ZX_OK) {
brcmf_dbg(INFO, "IF Type = AP\n");
}
} else {
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_INFRA, infra);
if (err != ZX_OK) {
brcmf_err("WLC_SET_INFRA error (%d)\n", err);
err = ZX_ERR_UNAVAILABLE;
goto done;
}
brcmf_dbg(INFO, "IF Type = %s\n", brcmf_is_ibssmode(vif) ? "Adhoc" : "Infra");
}
ndev->ieee80211_ptr->iftype = type;
brcmf_cfg80211_update_proto_addr_mode(&vif->wdev);
done:
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static void brcmf_escan_prep(struct brcmf_cfg80211_info* cfg,
struct brcmf_scan_params_le* params_le,
struct cfg80211_scan_request* request) {
uint32_t n_ssids;
uint32_t n_channels;
int32_t i;
int32_t offset;
uint16_t chanspec;
char* ptr;
struct brcmf_ssid_le ssid_le;
fill_with_broadcast_addr(params_le->bssid);
params_le->bss_type = DOT11_BSSTYPE_ANY;
params_le->scan_type = BRCMF_SCANTYPE_ACTIVE;
params_le->channel_num = 0;
params_le->nprobes = -1;
params_le->active_time = -1;
params_le->passive_time = -1;
params_le->home_time = -1;
memset(&params_le->ssid_le, 0, sizeof(params_le->ssid_le));
n_ssids = request->n_ssids;
n_channels = request->n_channels;
/* Copy channel array if applicable */
brcmf_dbg(SCAN, "### List of channelspecs to scan ### %d\n", n_channels);
if (n_channels > 0) {
for (i = 0; i < (int32_t)n_channels; i++) {
chanspec = channel_to_chanspec(&cfg->d11inf, request->channels[i]);
brcmf_dbg(SCAN, "Chan : %d, Channel spec: %x\n", request->channels[i]->hw_value,
chanspec);
params_le->channel_list[i] = chanspec;
}
} else {
brcmf_dbg(SCAN, "Scanning all channels\n");
}
/* Copy ssid array if applicable */
brcmf_dbg(SCAN, "### List of SSIDs to scan ### %d\n", n_ssids);
if (n_ssids > 0) {
offset = offsetof(struct brcmf_scan_params_le, channel_list) +
n_channels * sizeof(uint16_t);
offset = roundup(offset, sizeof(uint32_t));
ptr = (char*)params_le + offset;
for (i = 0; i < (int32_t)n_ssids; i++) {
memset(&ssid_le, 0, sizeof(ssid_le));
ssid_le.SSID_len = request->ssids[i].ssid_len;
memcpy(ssid_le.SSID, request->ssids[i].ssid, request->ssids[i].ssid_len);
if (!ssid_le.SSID_len) {
brcmf_dbg(SCAN, "%d: Broadcast scan\n", i);
} else {
brcmf_dbg(SCAN, "%d: scan for %.32s size=%d\n", i, ssid_le.SSID, ssid_le.SSID_len);
}
memcpy(ptr, &ssid_le, sizeof(ssid_le));
ptr += sizeof(ssid_le);
}
} else {
brcmf_dbg(SCAN, "Performing passive scan\n");
params_le->scan_type = BRCMF_SCANTYPE_PASSIVE;
}
/* Adding mask to channel numbers */
params_le->channel_num = (n_ssids << BRCMF_SCAN_PARAMS_NSSID_SHIFT) |
(n_channels & BRCMF_SCAN_PARAMS_COUNT_MASK);
}
static zx_status_t brcmf_run_escan(struct brcmf_cfg80211_info* cfg, struct brcmf_if* ifp,
struct cfg80211_scan_request* request) {
int32_t params_size =
BRCMF_SCAN_PARAMS_FIXED_SIZE + offsetof(struct brcmf_escan_params_le, params_le);
struct brcmf_escan_params_le* params;
zx_status_t err = ZX_OK;
brcmf_dbg(SCAN, "E-SCAN START\n");
if (request != NULL) {
/* Allocate space for populating ssids in struct */
params_size += sizeof(uint32_t) * ((request->n_channels + 1) / 2);
/* Allocate space for populating ssids in struct */
params_size += sizeof(struct brcmf_ssid_le) * request->n_ssids;
}
params = calloc(1, params_size);
if (!params) {
err = ZX_ERR_NO_MEMORY;
goto exit;
}
ZX_ASSERT(params_size + sizeof("escan") < BRCMF_DCMD_MEDLEN);
brcmf_escan_prep(cfg, &params->params_le, request);
params->version = BRCMF_ESCAN_REQ_VERSION;
params->action = WL_ESCAN_ACTION_START;
params->sync_id = 0x1234;
err = brcmf_fil_iovar_data_set(ifp, "escan", params, params_size);
if (err != ZX_OK) {
if (err == ZX_ERR_UNAVAILABLE) {
brcmf_dbg(INFO, "system busy : escan canceled\n");
} else {
brcmf_err("error (%d)\n", err);
}
}
free(params);
exit:
return err;
}
static zx_status_t brcmf_do_escan(struct brcmf_if* ifp, struct cfg80211_scan_request* request) {
struct brcmf_cfg80211_info* cfg = ifp->drvr->config;
zx_status_t err;
struct brcmf_scan_results* results;
struct escan_info* escan = &cfg->escan_info;
brcmf_dbg(SCAN, "Enter\n");
escan->ifp = ifp;
escan->wiphy = cfg->wiphy;
escan->escan_state = WL_ESCAN_STATE_SCANNING;
brcmf_scan_config_mpc(ifp, 0);
results = (struct brcmf_scan_results*)cfg->escan_info.escan_buf;
results->version = 0;
results->count = 0;
results->buflen = WL_ESCAN_RESULTS_FIXED_SIZE;
err = escan->run(cfg, ifp, request);
if (err != ZX_OK) {
brcmf_scan_config_mpc(ifp, 1);
}
return err;
}
zx_status_t brcmf_cfg80211_scan(struct wiphy* wiphy, struct cfg80211_scan_request* request) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_cfg80211_vif* vif;
zx_status_t err = ZX_OK;
brcmf_dbg(TRACE, "Enter\n");
vif = containerof(request->wdev, struct brcmf_cfg80211_vif, wdev);
if (!check_vif_up(vif)) {
brcmf_dbg(TEMP, "Vif not up");
return ZX_ERR_IO;
}
if (brcmf_test_bit_in_array(BRCMF_SCAN_STATUS_BUSY, &cfg->scan_status)) {
brcmf_err("Scanning already: status (%lu)\n", cfg->scan_status);
return ZX_ERR_UNAVAILABLE;
}
if (brcmf_test_bit_in_array(BRCMF_SCAN_STATUS_ABORT, &cfg->scan_status)) {
brcmf_err("Scanning being aborted: status (%lu)\n", cfg->scan_status);
return ZX_ERR_UNAVAILABLE;
}
if (brcmf_test_bit_in_array(BRCMF_SCAN_STATUS_SUPPRESS, &cfg->scan_status)) {
brcmf_err("Scanning suppressed: status (%lu)\n", cfg->scan_status);
return ZX_ERR_UNAVAILABLE;
}
if (brcmf_test_bit_in_array(BRCMF_VIF_STATUS_CONNECTING, &vif->sme_state)) {
brcmf_err("Connecting: status (%lu)\n", vif->sme_state);
return ZX_ERR_UNAVAILABLE;
}
/* If scan req comes for p2p0, send it over primary I/F */
if (vif == cfg->p2p.bss_idx[P2PAPI_BSSCFG_DEVICE].vif) {
vif = cfg->p2p.bss_idx[P2PAPI_BSSCFG_PRIMARY].vif;
}
brcmf_dbg(SCAN, "START ESCAN\n");
cfg->scan_request = request;
brcmf_set_bit_in_array(BRCMF_SCAN_STATUS_BUSY, &cfg->scan_status);
cfg->escan_info.run = brcmf_run_escan;
err = brcmf_p2p_scan_prep(wiphy, request, vif);
if (err != ZX_OK) {
goto scan_out;
}
err = brcmf_vif_set_mgmt_ie(vif, BRCMF_VNDR_IE_PRBREQ_FLAG, request->ie, request->ie_len);
if (err != ZX_OK) {
goto scan_out;
}
err = brcmf_do_escan(vif->ifp, request);
if (err != ZX_OK) {
goto scan_out;
}
/* Arm scan timeout timer */
brcmf_timer_set(&cfg->escan_timeout, ZX_MSEC(BRCMF_ESCAN_TIMER_INTERVAL_MS));
return ZX_OK;
scan_out:
brcmf_err("scan error (%d)\n", err);
brcmf_clear_bit_in_array(BRCMF_SCAN_STATUS_BUSY, &cfg->scan_status);
cfg->scan_request = NULL;
return err;
}
static zx_status_t brcmf_set_rts(struct net_device* ndev, uint32_t rts_threshold) {
zx_status_t err = ZX_OK;
err = brcmf_fil_iovar_int_set(ndev_to_if(ndev), "rtsthresh", rts_threshold);
if (err != ZX_OK) {
brcmf_err("Error (%d)\n", err);
}
return err;
}
static zx_status_t brcmf_set_frag(struct net_device* ndev, uint32_t frag_threshold) {
zx_status_t err = ZX_OK;
err = brcmf_fil_iovar_int_set(ndev_to_if(ndev), "fragthresh", frag_threshold);
if (err != ZX_OK) {
brcmf_err("Error (%d)\n", err);
}
return err;
}
static zx_status_t brcmf_set_retry(struct net_device* ndev, uint32_t retry, bool l) {
zx_status_t err = ZX_OK;
uint32_t cmd = (l ? BRCMF_C_SET_LRL : BRCMF_C_SET_SRL);
err = brcmf_fil_cmd_int_set(ndev_to_if(ndev), cmd, retry);
if (err != ZX_OK) {
brcmf_err("cmd (%d) , error (%d)\n", cmd, err);
return err;
}
return err;
}
static zx_status_t brcmf_cfg80211_set_wiphy_params(struct wiphy* wiphy, uint32_t changed) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct net_device* ndev = cfg_to_ndev(cfg);
struct brcmf_if* ifp = ndev_to_if(ndev);
zx_status_t err = ZX_OK;
brcmf_dbg(TRACE, "Enter\n");
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
if (changed & WIPHY_PARAM_RTS_THRESHOLD && (cfg->conf->rts_threshold != wiphy->rts_threshold)) {
cfg->conf->rts_threshold = wiphy->rts_threshold;
err = brcmf_set_rts(ndev, cfg->conf->rts_threshold);
if (err == ZX_OK) {
goto done;
}
}
if (changed & WIPHY_PARAM_FRAG_THRESHOLD &&
(cfg->conf->frag_threshold != wiphy->frag_threshold)) {
cfg->conf->frag_threshold = wiphy->frag_threshold;
err = brcmf_set_frag(ndev, cfg->conf->frag_threshold);
if (err == ZX_OK) {
goto done;
}
}
if (changed & WIPHY_PARAM_RETRY_LONG && (cfg->conf->retry_long != wiphy->retry_long)) {
cfg->conf->retry_long = wiphy->retry_long;
err = brcmf_set_retry(ndev, cfg->conf->retry_long, true);
if (err == ZX_OK) {
goto done;
}
}
if (changed & WIPHY_PARAM_RETRY_SHORT && (cfg->conf->retry_short != wiphy->retry_short)) {
cfg->conf->retry_short = wiphy->retry_short;
err = brcmf_set_retry(ndev, cfg->conf->retry_short, false);
if (err == ZX_OK) {
goto done;
}
}
done:
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static void brcmf_init_prof(struct brcmf_cfg80211_profile* prof) {
memset(prof, 0, sizeof(*prof));
}
static uint16_t brcmf_map_fw_linkdown_reason(const struct brcmf_event_msg* e) {
uint16_t reason;
switch (e->event_code) {
case BRCMF_E_DEAUTH:
case BRCMF_E_DEAUTH_IND:
case BRCMF_E_DISASSOC_IND:
reason = e->reason;
break;
case BRCMF_E_LINK:
default:
reason = 0;
break;
}
return reason;
}
static zx_status_t brcmf_set_pmk(struct brcmf_if* ifp, const uint8_t* pmk_data, uint16_t pmk_len) {
struct brcmf_wsec_pmk_le pmk;
int i;
zx_status_t err;
/* convert to firmware key format */
pmk.key_len = pmk_len << 1;
pmk.flags = BRCMF_WSEC_PASSPHRASE;
for (i = 0; i < pmk_len; i++) {
// TODO(cphoenix): Make sure handling of pmk keys is consistent with their being
// binary values, not ASCII chars.
snprintf((char*)&pmk.key[2 * i], 3, "%02x", pmk_data[i]);
}
/* store psk in firmware */
err = brcmf_fil_cmd_data_set(ifp, BRCMF_C_SET_WSEC_PMK, &pmk, sizeof(pmk));
if (err != ZX_OK) {
brcmf_err("failed to change PSK in firmware (len=%u)\n", pmk_len);
}
return err;
}
static void brcmf_link_down(struct brcmf_cfg80211_vif* vif, uint16_t reason) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(vif->wdev.wiphy);
zx_status_t err = ZX_OK;
brcmf_dbg(TRACE, "Enter\n");
if (brcmf_test_and_clear_bit_in_array(BRCMF_VIF_STATUS_CONNECTED, &vif->sme_state)) {
brcmf_dbg(INFO, "Call WLC_DISASSOC to stop excess roaming\n ");
err = brcmf_fil_cmd_data_set(vif->ifp, BRCMF_C_DISASSOC, NULL, 0);
if (err != ZX_OK) {
brcmf_err("WLC_DISASSOC failed (%d)\n", err);
}
if ((vif->wdev.iftype == NL80211_IFTYPE_STATION) ||
(vif->wdev.iftype == NL80211_IFTYPE_P2P_CLIENT)) {
cfg80211_disconnected(vif->wdev.netdev, reason, NULL, 0, true);
}
}
brcmf_clear_bit_in_array(BRCMF_VIF_STATUS_CONNECTING, &vif->sme_state);
brcmf_clear_bit_in_array(BRCMF_SCAN_STATUS_SUPPRESS, &cfg->scan_status);
brcmf_btcoex_set_mode(vif, BRCMF_BTCOEX_ENABLED, 0);
if (vif->profile.use_fwsup != BRCMF_PROFILE_FWSUP_NONE) {
brcmf_set_pmk(vif->ifp, NULL, 0);
vif->profile.use_fwsup = BRCMF_PROFILE_FWSUP_NONE;
}
brcmf_dbg(TRACE, "Exit\n");
}
static zx_status_t brcmf_cfg80211_join_ibss(struct wiphy* wiphy, struct net_device* ndev,
struct cfg80211_ibss_params* params) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_cfg80211_profile* profile = &ifp->vif->profile;
struct brcmf_join_params join_params;
size_t join_params_size = 0;
zx_status_t err = ZX_OK;
int32_t wsec = 0;
int32_t bcnprd;
uint16_t chanspec;
uint32_t ssid_len;
brcmf_dbg(TRACE, "Enter\n");
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
if (params->ssid) {
brcmf_dbg(CONN, "SSID: %s\n", params->ssid);
} else {
brcmf_dbg(CONN, "SSID: NULL, Not supported\n");
return ZX_ERR_NOT_SUPPORTED;
}
brcmf_set_bit_in_array(BRCMF_VIF_STATUS_CONNECTING, &ifp->vif->sme_state);
if (params->bssid) {
brcmf_dbg(CONN, "BSSID: %pM\n", params->bssid);
} else {
brcmf_dbg(CONN, "No BSSID specified\n");
}
if (params->chandef.chan) {
brcmf_dbg(CONN, "channel: %d\n", params->chandef.chan->center_freq);
} else {
brcmf_dbg(CONN, "no channel specified\n");
}
if (params->channel_fixed) {
brcmf_dbg(CONN, "fixed channel required\n");
} else {
brcmf_dbg(CONN, "no fixed channel required\n");
}
if (params->ie && params->ie_len) {
brcmf_dbg(CONN, "ie len: %d\n", params->ie_len);
} else {
brcmf_dbg(CONN, "no ie specified\n");
}
if (params->beacon_interval) {
brcmf_dbg(CONN, "beacon interval: %d\n", params->beacon_interval);
} else {
brcmf_dbg(CONN, "no beacon interval specified\n");
}
if (params->basic_rates) {
brcmf_dbg(CONN, "basic rates: %08X\n", params->basic_rates);
} else {
brcmf_dbg(CONN, "no basic rates specified\n");
}
if (params->privacy) {
brcmf_dbg(CONN, "privacy required\n");
} else {
brcmf_dbg(CONN, "no privacy required\n");
}
/* Configure Privacy for starter */
if (params->privacy) {
wsec |= WEP_ENABLED;
}
err = brcmf_fil_iovar_int_set(ifp, "wsec", wsec);
if (err != ZX_OK) {
brcmf_err("wsec failed (%d)\n", err);
goto done;
}
/* Configure Beacon Interval for starter */
if (params->beacon_interval) {
bcnprd = params->beacon_interval;
} else {
bcnprd = 100;
}
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_BCNPRD, bcnprd);
if (err != ZX_OK) {
brcmf_err("WLC_SET_BCNPRD failed (%d)\n", err);
goto done;
}
/* Configure required join parameter */
memset(&join_params, 0, sizeof(struct brcmf_join_params));
/* SSID */
ssid_len = min_t(uint32_t, params->ssid_len, IEEE80211_MAX_SSID_LEN);
memcpy(join_params.ssid_le.SSID, params->ssid, ssid_len);
join_params.ssid_le.SSID_len = ssid_len;
join_params_size = sizeof(join_params.ssid_le);
/* BSSID */
if (params->bssid) {
memcpy(join_params.params_le.bssid, params->bssid, ETH_ALEN);
join_params_size += BRCMF_ASSOC_PARAMS_FIXED_SIZE;
memcpy(profile->bssid, params->bssid, ETH_ALEN);
} else {
fill_with_broadcast_addr(join_params.params_le.bssid);
fill_with_zero_addr(profile->bssid);
}
/* Channel */
if (params->chandef.chan) {
uint32_t target_channel;
cfg->channel = ieee80211_frequency_to_channel(params->chandef.chan->center_freq);
if (params->channel_fixed) {
/* adding chanspec */
chanspec = chandef_to_chanspec(&cfg->d11inf, &params->chandef);
join_params.params_le.chanspec_list[0] = chanspec;
join_params.params_le.chanspec_num = 1;
join_params_size += sizeof(join_params.params_le);
}
/* set channel for starter */
target_channel = cfg->channel;
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_CHANNEL, target_channel);
if (err != ZX_OK) {
brcmf_err("WLC_SET_CHANNEL failed (%d)\n", err);
goto done;
}
} else {
cfg->channel = 0;
}
cfg->ibss_starter = false;
err = brcmf_fil_cmd_data_set(ifp, BRCMF_C_SET_SSID, &join_params, join_params_size);
if (err != ZX_OK) {
brcmf_err("WLC_SET_SSID failed (%d)\n", err);
goto done;
}
done:
if (err != ZX_OK) {
brcmf_clear_bit_in_array(BRCMF_VIF_STATUS_CONNECTING, &ifp->vif->sme_state);
}
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static zx_status_t brcmf_cfg80211_leave_ibss(struct wiphy* wiphy, struct net_device* ndev) {
struct brcmf_if* ifp = ndev_to_if(ndev);
brcmf_dbg(TRACE, "Enter\n");
if (!check_vif_up(ifp->vif)) {
/* When driver is being unloaded, it can end up here. If an
* error is returned then later on a debug trace in the wireless
* core module will be printed. To avoid this 0 is returned.
*/
return ZX_OK;
}
brcmf_link_down(ifp->vif, WLAN_REASON_DEAUTH_LEAVING);
brcmf_net_setcarrier(ifp, false);
brcmf_dbg(TRACE, "Exit\n");
return ZX_OK;
}
static zx_status_t brcmf_set_wpa_version_disabled(struct net_device* ndev) {
struct brcmf_cfg80211_profile* profile = ndev_to_prof(ndev);
struct brcmf_cfg80211_security* sec;
int32_t val = 0;
zx_status_t err = ZX_OK;
val = WPA_AUTH_DISABLED;
brcmf_dbg(CONN, "setting wpa_auth to 0x%0x\n", val);
err = brcmf_fil_bsscfg_int_set(ndev_to_if(ndev), "wpa_auth", val);
if (err != ZX_OK) {
brcmf_err("set wpa_auth failed (%d)\n", err);
return err;
}
sec = &profile->sec;
sec->wpa_versions = 0;
return err;
}
static zx_status_t brcmf_set_auth_type_open(struct net_device* ndev) {
struct brcmf_cfg80211_profile* profile = ndev_to_prof(ndev);
struct brcmf_cfg80211_security* sec;
int32_t val = 0;
zx_status_t err = ZX_OK;
err = brcmf_fil_bsscfg_int_set(ndev_to_if(ndev), "auth", val);
if (err != ZX_OK) {
brcmf_err("set auth failed (%d)\n", err);
return err;
}
sec = &profile->sec;
sec->auth_type = 0;
return err;
}
static zx_status_t brcmf_set_wsec_mode_zero(struct net_device* ndev) {
struct brcmf_cfg80211_profile* profile = ndev_to_prof(ndev);
struct brcmf_cfg80211_security* sec;
int32_t wsec;
zx_status_t err = ZX_OK;
wsec = 0;
err = brcmf_fil_bsscfg_int_set(ndev_to_if(ndev), "wsec", wsec);
if (err != ZX_OK) {
brcmf_err("error (%d)\n", err);
return err;
}
sec = &profile->sec;
sec->cipher_pairwise = 0;
sec->cipher_group = 0;
return err;
}
#ifdef FIGURE_THIS_OUT_LATER
static zx_status_t brcmf_set_key_mgmt(struct net_device* ndev,
struct cfg80211_connect_params* sme) {
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_cfg80211_profile* profile = &ifp->vif->profile;
int32_t val;
zx_status_t err;
const struct brcmf_tlv* rsn_ie;
const uint8_t* ie;
uint32_t ie_len;
uint32_t offset;
uint16_t rsn_cap;
uint32_t mfp;
uint16_t count;
profile->use_fwsup = BRCMF_PROFILE_FWSUP_NONE;
if (!sme->crypto.n_akm_suites) {
return ZX_OK;
}
err = brcmf_fil_bsscfg_int_get(ndev_to_if(ndev), "wpa_auth", (uint32_t*)&val);
if (err != ZX_OK) {
brcmf_err("could not get wpa_auth (%d)\n", err);
return err;
}
if (val & (WPA_AUTH_PSK | WPA_AUTH_UNSPECIFIED)) {
switch (sme->crypto.akm_suites[0]) {
case WLAN_AKM_SUITE_8021X:
val = WPA_AUTH_UNSPECIFIED;
if (sme->want_1x) {
profile->use_fwsup = BRCMF_PROFILE_FWSUP_1X;
}
break;
case WLAN_AKM_SUITE_PSK:
val = WPA_AUTH_PSK;
break;
default:
brcmf_err("invalid cipher group (%d)\n", sme->crypto.cipher_group);
return ZX_ERR_INVALID_ARGS;
}
} else if (val & (WPA2_AUTH_PSK | WPA2_AUTH_UNSPECIFIED)) {
switch (sme->crypto.akm_suites[0]) {
case WLAN_AKM_SUITE_8021X:
val = WPA2_AUTH_UNSPECIFIED;
if (sme->want_1x) {
profile->use_fwsup = BRCMF_PROFILE_FWSUP_1X;
}
break;
case WLAN_AKM_SUITE_8021X_SHA256:
val = WPA2_AUTH_1X_SHA256;
if (sme->want_1x) {
profile->use_fwsup = BRCMF_PROFILE_FWSUP_1X;
}
break;
case WLAN_AKM_SUITE_PSK_SHA256:
val = WPA2_AUTH_PSK_SHA256;
break;
case WLAN_AKM_SUITE_PSK:
val = WPA2_AUTH_PSK;
break;
default:
brcmf_err("invalid cipher group (%d)\n", sme->crypto.cipher_group);
return ZX_ERR_INVALID_ARGS;
}
}
if (profile->use_fwsup == BRCMF_PROFILE_FWSUP_1X) {
brcmf_dbg(INFO, "using 1X offload\n");
}
if (!brcmf_feat_is_enabled(ifp, BRCMF_FEAT_MFP)) {
goto skip_mfp_config;
}
/* The MFP mode (1 or 2) needs to be determined, parse IEs. The
* IE will not be verified, just a quick search for MFP config
*/
rsn_ie = brcmf_parse_tlvs((const uint8_t*)sme->ie, sme->ie_len, WLAN_EID_RSN);
if (!rsn_ie) {
goto skip_mfp_config;
}
ie = (const uint8_t*)rsn_ie;
ie_len = rsn_ie->len + TLV_HDR_LEN;
/* Skip unicast suite */
offset = TLV_HDR_LEN + WPA_IE_VERSION_LEN + WPA_IE_MIN_OUI_LEN;
if (offset + WPA_IE_SUITE_COUNT_LEN >= ie_len) {
goto skip_mfp_config;
}
/* Skip multicast suite */
count = ie[offset] + (ie[offset + 1] << 8);
offset += WPA_IE_SUITE_COUNT_LEN + (count * WPA_IE_MIN_OUI_LEN);
if (offset + WPA_IE_SUITE_COUNT_LEN >= ie_len) {
goto skip_mfp_config;
}
/* Skip auth key management suite(s) */
count = ie[offset] + (ie[offset + 1] << 8);
offset += WPA_IE_SUITE_COUNT_LEN + (count * WPA_IE_MIN_OUI_LEN);
if (offset + WPA_IE_SUITE_COUNT_LEN > ie_len) {
goto skip_mfp_config;
}
/* Ready to read capabilities */
mfp = BRCMF_MFP_NONE;
rsn_cap = ie[offset] + (ie[offset + 1] << 8);
if (rsn_cap & RSN_CAP_MFPR_MASK) {
mfp = BRCMF_MFP_REQUIRED;
} else if (rsn_cap & RSN_CAP_MFPC_MASK) {
mfp = BRCMF_MFP_CAPABLE;
}
brcmf_fil_bsscfg_int_set(ndev_to_if(ndev), "mfp", mfp);
skip_mfp_config:
brcmf_dbg(CONN, "setting wpa_auth to %d\n", val);
err = brcmf_fil_bsscfg_int_set(ndev_to_if(ndev), "wpa_auth", val);
if (err != ZX_OK) {
brcmf_err("could not set wpa_auth (%d)\n", err);
return err;
}
return err;
}
static zx_status_t brcmf_set_sharedkey(struct net_device* ndev,
struct cfg80211_connect_params* sme) {
struct brcmf_cfg80211_profile* profile = ndev_to_prof(ndev);
struct brcmf_cfg80211_security* sec;
struct brcmf_wsec_key key;
int32_t val;
zx_status_t err = ZX_OK;
brcmf_dbg(CONN, "key len (%d)\n", sme->key_len);
if (sme->key_len == 0) {
return ZX_OK;
}
sec = &profile->sec;
brcmf_dbg(CONN, "wpa_versions 0x%x cipher_pairwise 0x%x\n", sec->wpa_versions,
sec->cipher_pairwise);
if (sec->wpa_versions & (NL80211_WPA_VERSION_1 | NL80211_WPA_VERSION_2)) {
return ZX_OK;
}
if (!(sec->cipher_pairwise & (WLAN_CIPHER_SUITE_WEP40 | WLAN_CIPHER_SUITE_WEP104))) {
return ZX_OK;
}
memset(&key, 0, sizeof(key));
key.len = (uint32_t)sme->key_len;
key.index = (uint32_t)sme->key_idx;
if (key.len > sizeof(key.data)) {
brcmf_err("Too long key length (%u)\n", key.len);
return ZX_ERR_INVALID_ARGS;
}
memcpy(key.data, sme->key, key.len);
key.flags = BRCMF_PRIMARY_KEY;
switch (sec->cipher_pairwise) {
case WLAN_CIPHER_SUITE_WEP40:
key.algo = CRYPTO_ALGO_WEP1;
break;
case WLAN_CIPHER_SUITE_WEP104:
key.algo = CRYPTO_ALGO_WEP128;
break;
default:
brcmf_err("Invalid algorithm (%d)\n", sme->crypto.ciphers_pairwise[0]);
return ZX_ERR_INVALID_ARGS;
}
/* Set the new key/index */
brcmf_dbg(CONN, "key length (%d) key index (%d) algo (%d)\n", key.len, key.index, key.algo);
brcmf_dbg(CONN, "key \"%s\"\n", key.data);
err = send_key_to_dongle(ndev_to_if(ndev), &key);
if (err != ZX_OK) {
return err;
}
if (sec->auth_type == NL80211_AUTHTYPE_SHARED_KEY) {
brcmf_dbg(CONN, "set auth_type to shared key\n");
val = WL_AUTH_SHARED_KEY; /* shared key */
err = brcmf_fil_bsscfg_int_set(ndev_to_if(ndev), "auth", val);
if (err != ZX_OK) {
brcmf_err("set auth failed (%d)\n", err);
}
}
return err;
}
#endif // FIGURE_THIS_OUT_LATER
enum nl80211_auth_type brcmf_war_auth_type(struct brcmf_if* ifp,
enum nl80211_auth_type type) {
if (type == NL80211_AUTHTYPE_AUTOMATIC &&
brcmf_feat_is_quirk_enabled(ifp, BRCMF_FEAT_QUIRK_AUTO_AUTH)) {
brcmf_dbg(CONN, "WAR: use OPEN instead of AUTO\n");
type = NL80211_AUTHTYPE_OPEN_SYSTEM;
}
return type;
}
static void brcmf_set_join_pref(struct brcmf_if* ifp, wlanif_join_req_t* req) {
// struct brcmf_join_pref_params join_pref_params[2];
// enum nl80211_band band;
// int i = 0;
// join_pref_params[i].len = 2;
// join_pref_params[i].rssi_gain = 0;
//if (bss_select->behaviour != NL80211_BSS_SELECT_ATTR_BAND_PREF) {
// TODO(cphoenix): Do we ever want to do this?
brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_ASSOC_PREFER, WLC_BAND_AUTO);
//}
brcmf_c_set_joinpref_default(ifp); // This sets "join_pref" iovar.
#ifdef PROBABLY_NOT
switch (bss_select->behaviour) {
case __NL80211_BSS_SELECT_ATTR_INVALID:
brcmf_c_set_joinpref_default(ifp);
return;
case NL80211_BSS_SELECT_ATTR_BAND_PREF:
join_pref_params[i].type = BRCMF_JOIN_PREF_BAND;
band = bss_select->param.band_pref;
join_pref_params[i].band = nl80211_band_to_fwil(band);
i++;
break;
case NL80211_BSS_SELECT_ATTR_RSSI_ADJUST:
join_pref_params[i].type = BRCMF_JOIN_PREF_RSSI_DELTA;
band = bss_select->param.adjust.band;
join_pref_params[i].band = nl80211_band_to_fwil(band);
join_pref_params[i].rssi_gain = bss_select->param.adjust.delta;
i++;
break;
case NL80211_BSS_SELECT_ATTR_RSSI:
default:
break;
}
join_pref_params[i].type = BRCMF_JOIN_PREF_RSSI;
join_pref_params[i].len = 2;
join_pref_params[i].rssi_gain = 0;
join_pref_params[i].band = 0;
err = brcmf_fil_iovar_data_set(ifp, "join_pref", join_pref_params, sizeof(join_pref_params));
if (err != ZX_OK) {
brcmf_err("Set join_pref error (%d)\n", err);
}
#endif // PROBABLY_NOT
}
static void brcmf_return_join_result(struct net_device* ndev, enum wlanif_join_result_codes code) {
wlanif_join_confirm_t result;
result.result_code = code;
ndev->if_callbacks->join_conf(ndev->if_callback_cookie, &result);
}
zx_status_t brcmf_cfg80211_connect(struct wiphy* wiphy, struct net_device* ndev,
wlanif_join_req_t* req) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_if* ifp = ndev_to_if(ndev);
// struct brcmf_cfg80211_profile* profile = &ifp->vif->profile;
struct brcmf_join_params join_params;
size_t join_params_size;
// const struct brcmf_tlv* rsn_ie;
// const struct brcmf_vs_tlv* wpa_ie;
const void* ie;
uint32_t ie_len;
struct brcmf_ext_join_params_le* ext_join_params;
uint16_t chanspec;
zx_status_t err = ZX_OK;
uint32_t ssid_len;
brcmf_dbg(TRACE, "Enter\n");
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
if (!req->selected_bss.ssid) {
brcmf_err("Invalid ssid\n");
return ZX_ERR_NOT_FOUND;
}
if (ifp->vif == cfg->p2p.bss_idx[P2PAPI_BSSCFG_PRIMARY].vif) {
/* A normal (non P2P) connection request setup. */
ie = NULL;
ie_len = 0;
#ifdef TODO_LATER
// TODO(cphoenix): WPA info used to arrive in IEs in the sme data structure.
// When we start connecting to secured networks, we'll need to extract it at the
// proper time -- and maybe that means giving the join command later on in the
// call sequence. I'm leaving this section in for now, for reference, to show that
// the "wpaie" fil_iovar really was an IE. (For unprotected networks, there was no
// IE, so setting NULL/0 is the correct behavior for now.)
/* find the WPA_IE */
wpa_ie = brcmf_find_wpaie((uint8_t*)sme->ie, sme->ie_len);
if (wpa_ie) {
ie = wpa_ie;
ie_len = wpa_ie->len + TLV_HDR_LEN;
} else {
/* find the RSN_IE */
rsn_ie = brcmf_parse_tlvs((const uint8_t*)sme->ie, sme->ie_len, WLAN_EID_RSN);
if (rsn_ie) {
ie = rsn_ie;
ie_len = rsn_ie->len + TLV_HDR_LEN;
}
}
#endif // TODO_LATER
brcmf_fil_iovar_data_set(ifp, "wpaie", ie, ie_len);
}
err = brcmf_vif_set_mgmt_ie(ifp->vif, BRCMF_VNDR_IE_ASSOCREQ_FLAG, NULL, 0); //sme->ie, sme->ie_len);
if (err != ZX_OK) {
brcmf_err("Set Assoc REQ IE Failed\n");
} else {
brcmf_dbg(TRACE, "Applied Vndr IEs for Assoc request\n");
}
brcmf_set_bit_in_array(BRCMF_VIF_STATUS_CONNECTING, &ifp->vif->sme_state);
/*if (chan) { // TODO(cphoenix): Figure out how "chanspec" is generated...
cfg->channel = ieee80211_frequency_to_channel(chan->center_freq);
chanspec = channel_to_chanspec(&cfg->d11inf, chan);
brcmf_dbg(CONN, "channel=%d, center_req=%d, chanspec=0x%04x\n", cfg->channel,
chan->center_freq, chanspec);
} else*/ {
cfg->channel = 0;
chanspec = 0;
}
err = brcmf_set_wpa_version_disabled(ndev); // wpa_auth
if (err != ZX_OK) {
brcmf_err("wl_set_wpa_version failed (%d)\n", err);
goto done;
}
//sme->auth_type = brcmf_war_auth_type(ifp, sme->auth_type); // auth
err = brcmf_set_auth_type_open(ndev); // TODO(cphoenix): Correct this for PSK if necessary
if (err != ZX_OK) {
brcmf_err("wl_set_auth_type failed (%d)\n", err);
goto done;
}
err = brcmf_set_wsec_mode_zero(ndev); // wsec
if (err != ZX_OK) {
brcmf_err("wl_set_set_cipher failed (%d)\n", err);
goto done;
}
#ifdef FIGURE_THIS_OUT_LATER
err = brcmf_set_key_mgmt(ndev, sme);
if (err != ZX_OK) {
brcmf_err("wl_set_key_mgmt failed (%d)\n", err);
goto done;
}
brcmf_dbg(TEMP, "A");
err = brcmf_set_sharedkey(ndev, sme);
if (err != ZX_OK) {
brcmf_err("brcmf_set_sharedkey failed (%d)\n", err);
goto done;
}
brcmf_dbg(TEMP, "B");
if (sme->crypto.psk) {
if (WARN_ON(profile->use_fwsup != BRCMF_PROFILE_FWSUP_NONE)) {
err = ZX_ERR_INVALID_ARGS;
goto done;
}
brcmf_dbg(INFO, "using PSK offload\n");
profile->use_fwsup = BRCMF_PROFILE_FWSUP_PSK;
}
brcmf_dbg(TEMP, "C");
if (profile->use_fwsup != BRCMF_PROFILE_FWSUP_NONE) {
/* enable firmware supplicant for this interface */
err = brcmf_fil_iovar_int_set(ifp, "sup_wpa", 1);
if (err != ZX_OK) {
brcmf_err("failed to enable fw supplicant\n");
goto done;
}
}
brcmf_dbg(TEMP, "D");
if (profile->use_fwsup == BRCMF_PROFILE_FWSUP_PSK) {
err = brcmf_set_pmk(ifp, sme->crypto.psk, BRCMF_WSEC_MAX_PSK_LEN);
if (err != ZX_OK) {
goto done;
}
}
#endif // FIGURE_THIS_OUT_LATER
/* Join with specific BSSID and cached SSID
* If SSID is zero join based on BSSID only
*/
join_params_size = offsetof(struct brcmf_ext_join_params_le, assoc_le) +
offsetof(struct brcmf_assoc_params_le, chanspec_list);
if (cfg->channel) {
join_params_size += sizeof(uint16_t);
}
ext_join_params = calloc(1, join_params_size);
if (ext_join_params == NULL) {
err = ZX_ERR_NO_MEMORY;
goto done;
}
ssid_len = min_t(uint32_t, strlen(req->selected_bss.ssid), IEEE80211_MAX_SSID_LEN);
ext_join_params->ssid_le.SSID_len = ssid_len;
memcpy(&ext_join_params->ssid_le.SSID, req->selected_bss.ssid, ssid_len);
if (ssid_len < IEEE80211_MAX_SSID_LEN) {
brcmf_dbg(CONN, "SSID \"%s\", len (%d)\n", ext_join_params->ssid_le.SSID, ssid_len);
}
brcmf_dbg(TEMP, "F");
/* Set up join scan parameters */
ext_join_params->scan_le.scan_type = -1;
ext_join_params->scan_le.home_time = -1;
memcpy(&ext_join_params->assoc_le.bssid, req->selected_bss.bssid, ETH_ALEN);
if (cfg->channel) {
ext_join_params->assoc_le.chanspec_num = 1;
ext_join_params->assoc_le.chanspec_list[0] = chanspec;
/* Increase dwell time to receive probe response or detect
* beacon from target AP at a noisy air only during connect
* command.
*/
ext_join_params->scan_le.active_time = BRCMF_SCAN_JOIN_ACTIVE_DWELL_TIME_MS;
ext_join_params->scan_le.passive_time = BRCMF_SCAN_JOIN_PASSIVE_DWELL_TIME_MS;
/* To sync with presence period of VSDB GO send probe request
* more frequently. Probe request will be stopped when it gets
* probe response from target AP/GO.
*/
ext_join_params->scan_le.nprobes =
BRCMF_SCAN_JOIN_ACTIVE_DWELL_TIME_MS / BRCMF_SCAN_JOIN_PROBE_INTERVAL_MS;
} else {
ext_join_params->scan_le.active_time = -1;
ext_join_params->scan_le.passive_time = -1;
ext_join_params->scan_le.nprobes = -1;
}
brcmf_dbg(TEMP, "G");
brcmf_set_join_pref(ifp, req); // join_pref
err = brcmf_fil_bsscfg_data_set(ifp, "join", ext_join_params, join_params_size);
free(ext_join_params);
if (err == ZX_OK) { /* This is it. join command worked, we are done */
brcmf_dbg(TEMP, "Join succeeded early!");
goto done;
}
/* join command failed, fallback to set ssid */
memset(&join_params, 0, sizeof(join_params));
join_params_size = sizeof(join_params.ssid_le);
memcpy(&join_params.ssid_le.SSID, req->selected_bss.ssid, ssid_len);
join_params.ssid_le.SSID_len = ssid_len;
memcpy(join_params.params_le.bssid, req->selected_bss.bssid, ETH_ALEN);
if (cfg->channel) {
join_params.params_le.chanspec_list[0] = chanspec;
join_params.params_le.chanspec_num = 1;
join_params_size += sizeof(join_params.params_le);
}
err = brcmf_fil_cmd_data_set(ifp, BRCMF_C_SET_SSID, &join_params, join_params_size);
if (err != ZX_OK) {
brcmf_err("BRCMF_C_SET_SSID failed (%d)\n", err);
}
// TODO(cphoenix): Find where the delayed join is handled, and report result there.
done:
if (err != ZX_OK) {
brcmf_clear_bit_in_array(BRCMF_VIF_STATUS_CONNECTING, &ifp->vif->sme_state);
brcmf_dbg(TEMP, "Doing early brcmf_return_join_result, err %d %s", err,
zx_status_get_string(err));
brcmf_return_join_result(ndev, JOIN_RESULT_FAILURE_TIMEOUT);
}
brcmf_dbg(TRACE, "Exit, err %s\n", zx_status_get_string(err));
return err;
}
static zx_status_t brcmf_cfg80211_disconnect(struct wiphy* wiphy, struct net_device* ndev,
uint16_t reason_code) {
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_cfg80211_profile* profile = &ifp->vif->profile;
struct brcmf_scb_val_le scbval;
zx_status_t err = ZX_OK;
brcmf_dbg(TRACE, "Enter. Reason code = %d\n", reason_code);
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
brcmf_clear_bit_in_array(BRCMF_VIF_STATUS_CONNECTED, &ifp->vif->sme_state);
brcmf_clear_bit_in_array(BRCMF_VIF_STATUS_CONNECTING, &ifp->vif->sme_state);
cfg80211_disconnected(ndev, reason_code, NULL, 0, true);
memcpy(&scbval.ea, &profile->bssid, ETH_ALEN);
scbval.val = reason_code;
err = brcmf_fil_cmd_data_set(ifp, BRCMF_C_DISASSOC, &scbval, sizeof(scbval));
if (err != ZX_OK) {
brcmf_err("error (%d)\n", err);
}
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static zx_status_t brcmf_cfg80211_set_tx_power(struct wiphy* wiphy, struct wireless_dev* wdev,
enum nl80211_tx_power_setting type, int32_t mbm) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct net_device* ndev = cfg_to_ndev(cfg);
struct brcmf_if* ifp = ndev_to_if(ndev);
zx_status_t err;
int32_t disable;
uint32_t qdbm = 127;
brcmf_dbg(TRACE, "Enter %d %d\n", type, mbm);
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
switch (type) {
case NL80211_TX_POWER_AUTOMATIC:
break;
case NL80211_TX_POWER_LIMITED:
case NL80211_TX_POWER_FIXED:
if (mbm < 0) {
brcmf_err("TX_POWER_FIXED - dbm is negative\n");
err = ZX_ERR_INVALID_ARGS;
goto done;
}
qdbm = MBM_TO_DBM(4 * mbm);
if (qdbm > 127) {
qdbm = 127;
}
qdbm |= WL_TXPWR_OVERRIDE;
break;
default:
brcmf_err("Unsupported type %d\n", type);
err = ZX_ERR_INVALID_ARGS;
goto done;
}
/* Make sure radio is off or on as far as software is concerned */
disable = WL_RADIO_SW_DISABLE << 16;
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_RADIO, disable);
if (err != ZX_OK) {
brcmf_err("WLC_SET_RADIO error (%d)\n", err);
}
err = brcmf_fil_iovar_int_set(ifp, "qtxpower", qdbm);
if (err != ZX_OK) {
brcmf_err("qtxpower error (%d)\n", err);
}
done:
brcmf_dbg(TRACE, "Exit %d (qdbm)\n", qdbm & ~WL_TXPWR_OVERRIDE);
return err;
}
static zx_status_t brcmf_cfg80211_get_tx_power(struct wiphy* wiphy, struct wireless_dev* wdev,
int32_t* dbm) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct net_device* ndev = cfg_to_ndev(cfg);
struct brcmf_if* ifp = ndev_to_if(ndev);
int32_t qdbm = 0;
zx_status_t err;
brcmf_dbg(TRACE, "Enter\n");
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
err = brcmf_fil_iovar_int_get(ifp, "qtxpower", (uint32_t*)&qdbm);
if (err != ZX_OK) {
brcmf_err("error (%d)\n", err);
goto done;
}
*dbm = (qdbm & ~WL_TXPWR_OVERRIDE) / 4;
done:
brcmf_dbg(TRACE, "Exit (0x%x %d)\n", qdbm, *dbm);
return err;
}
static zx_status_t brcmf_cfg80211_config_default_key(struct wiphy* wiphy, struct net_device* ndev,
uint8_t key_idx, bool unicast,
bool multicast) {
struct brcmf_if* ifp = ndev_to_if(ndev);
uint32_t index;
uint32_t wsec;
zx_status_t err = ZX_OK;
brcmf_dbg(TRACE, "Enter\n");
brcmf_dbg(CONN, "key index (%d)\n", key_idx);
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
err = brcmf_fil_bsscfg_int_get(ifp, "wsec", &wsec);
if (err != ZX_OK) {
brcmf_err("WLC_GET_WSEC error (%d)\n", err);
goto done;
}
if (wsec & WEP_ENABLED) {
/* Just select a new current key */
index = key_idx;
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_KEY_PRIMARY, index);
if (err != ZX_OK) {
brcmf_err("error (%d)\n", err);
}
}
done:
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static zx_status_t brcmf_cfg80211_del_key(struct wiphy* wiphy, struct net_device* ndev,
uint8_t key_idx, bool pairwise, const uint8_t* mac_addr) {
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_wsec_key* key;
zx_status_t err;
brcmf_dbg(TRACE, "Enter\n");
brcmf_dbg(CONN, "key index (%d)\n", key_idx);
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
if (key_idx >= BRCMF_MAX_DEFAULT_KEYS) {
/* we ignore this key index in this case */
return ZX_ERR_INVALID_ARGS;
}
key = &ifp->vif->profile.key[key_idx];
if (key->algo == CRYPTO_ALGO_OFF) {
brcmf_dbg(CONN, "Ignore clearing of (never configured) key\n");
return ZX_ERR_BAD_STATE;
}
memset(key, 0, sizeof(*key));
key->index = (uint32_t)key_idx;
key->flags = BRCMF_PRIMARY_KEY;
/* Clear the key/index */
err = send_key_to_dongle(ifp, key);
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static zx_status_t brcmf_cfg80211_add_key(struct wiphy* wiphy, struct net_device* ndev,
uint8_t key_idx, bool pairwise, const uint8_t* mac_addr,
struct key_params* params) {
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_wsec_key* key;
int32_t val;
int32_t wsec;
zx_status_t err;
uint8_t keybuf[8];
bool ext_key;
brcmf_dbg(TRACE, "Enter\n");
brcmf_dbg(CONN, "key index (%d)\n", key_idx);
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
if (key_idx >= BRCMF_MAX_DEFAULT_KEYS) {
/* we ignore this key index in this case */
brcmf_err("invalid key index (%d)\n", key_idx);
return ZX_ERR_INVALID_ARGS;
}
if (params->key_len == 0) {
return brcmf_cfg80211_del_key(wiphy, ndev, key_idx, pairwise, mac_addr);
}
if (params->key_len > sizeof(key->data)) {
brcmf_err("Too long key length (%u)\n", params->key_len);
return ZX_ERR_INVALID_ARGS;
}
ext_key = false;
if (mac_addr && (params->cipher != WLAN_CIPHER_SUITE_WEP40) &&
(params->cipher != WLAN_CIPHER_SUITE_WEP104)) {
brcmf_dbg(TRACE, "Ext key, mac %pM", mac_addr);
ext_key = true;
}
key = &ifp->vif->profile.key[key_idx];
memset(key, 0, sizeof(*key));
if ((ext_key) && (!address_is_multicast(mac_addr))) {
memcpy((char*)&key->ea, (void*)mac_addr, ETH_ALEN);
}
key->len = params->key_len;
key->index = key_idx;
memcpy(key->data, params->key, key->len);
if (!ext_key) {
key->flags = BRCMF_PRIMARY_KEY;
}
switch (params->cipher) {
case WLAN_CIPHER_SUITE_WEP40:
key->algo = CRYPTO_ALGO_WEP1;
val = WEP_ENABLED;
brcmf_dbg(CONN, "WLAN_CIPHER_SUITE_WEP40\n");
break;
case WLAN_CIPHER_SUITE_WEP104:
key->algo = CRYPTO_ALGO_WEP128;
val = WEP_ENABLED;
brcmf_dbg(CONN, "WLAN_CIPHER_SUITE_WEP104\n");
break;
case WLAN_CIPHER_SUITE_TKIP:
if (!brcmf_is_apmode(ifp->vif)) {
brcmf_dbg(CONN, "Swapping RX/TX MIC key\n");
memcpy(keybuf, &key->data[24], sizeof(keybuf));
memcpy(&key->data[24], &key->data[16], sizeof(keybuf));
memcpy(&key->data[16], keybuf, sizeof(keybuf));
}
key->algo = CRYPTO_ALGO_TKIP;
val = TKIP_ENABLED;
brcmf_dbg(CONN, "WLAN_CIPHER_SUITE_TKIP\n");
break;
case WLAN_CIPHER_SUITE_AES_CMAC:
key->algo = CRYPTO_ALGO_AES_CCM;
val = AES_ENABLED;
brcmf_dbg(CONN, "WLAN_CIPHER_SUITE_AES_CMAC\n");
break;
case WLAN_CIPHER_SUITE_CCMP:
key->algo = CRYPTO_ALGO_AES_CCM;
val = AES_ENABLED;
brcmf_dbg(CONN, "WLAN_CIPHER_SUITE_CCMP\n");
break;
default:
brcmf_err("Invalid cipher (0x%x)\n", params->cipher);
err = ZX_ERR_INVALID_ARGS;
goto done;
}
err = send_key_to_dongle(ifp, key);
if (ext_key || err != ZX_OK) {
goto done;
}
err = brcmf_fil_bsscfg_int_get(ifp, "wsec", (uint32_t*)&wsec); // TODO(cphoenix): This cast?!?
if (err != ZX_OK) {
brcmf_err("get wsec error (%d)\n", err);
goto done;
}
wsec |= val;
err = brcmf_fil_bsscfg_int_set(ifp, "wsec", wsec);
if (err != ZX_OK) {
brcmf_err("set wsec error (%d)\n", err);
goto done;
}
done:
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static zx_status_t brcmf_cfg80211_get_key(struct wiphy* wiphy, struct net_device* ndev,
uint8_t key_idx, bool pairwise, const uint8_t* mac_addr,
void* cookie,
void (*callback)(void* cookie,
struct key_params* params)) {
struct key_params params;
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_cfg80211_profile* profile = &ifp->vif->profile;
struct brcmf_cfg80211_security* sec;
int32_t wsec;
zx_status_t err = ZX_OK;
brcmf_dbg(TRACE, "Enter\n");
brcmf_dbg(CONN, "key index (%d)\n", key_idx);
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
memset(&params, 0, sizeof(params));
err = brcmf_fil_bsscfg_int_get(ifp, "wsec", (uint32_t*)&wsec);
if (err != ZX_OK) {
brcmf_err("WLC_GET_WSEC error (%d)\n", err);
/* Ignore this error, may happen during DISASSOC */
err = ZX_ERR_UNAVAILABLE;
goto done;
}
if (wsec & WEP_ENABLED) {
sec = &profile->sec;
if (sec->cipher_pairwise & WLAN_CIPHER_SUITE_WEP40) {
params.cipher = WLAN_CIPHER_SUITE_WEP40;
brcmf_dbg(CONN, "WLAN_CIPHER_SUITE_WEP40\n");
} else if (sec->cipher_pairwise & WLAN_CIPHER_SUITE_WEP104) {
params.cipher = WLAN_CIPHER_SUITE_WEP104;
brcmf_dbg(CONN, "WLAN_CIPHER_SUITE_WEP104\n");
}
} else if (wsec & TKIP_ENABLED) {
params.cipher = WLAN_CIPHER_SUITE_TKIP;
brcmf_dbg(CONN, "WLAN_CIPHER_SUITE_TKIP\n");
} else if (wsec & AES_ENABLED) {
params.cipher = WLAN_CIPHER_SUITE_AES_CMAC;
brcmf_dbg(CONN, "WLAN_CIPHER_SUITE_AES_CMAC\n");
} else {
brcmf_err("Invalid algo (0x%x)\n", wsec);
err = ZX_ERR_INVALID_ARGS;
goto done;
}
callback(cookie, &params);
done:
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static zx_status_t brcmf_cfg80211_config_default_mgmt_key(struct wiphy* wiphy,
struct net_device* ndev,
uint8_t key_idx) {
struct brcmf_if* ifp = ndev_to_if(ndev);
brcmf_dbg(TRACE, "Enter key_idx %d\n", key_idx);
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_MFP)) {
return ZX_OK;
}
brcmf_dbg(INFO, "Not supported\n");
return ZX_ERR_NOT_SUPPORTED;
}
static void brcmf_cfg80211_reconfigure_wep(struct brcmf_if* ifp) {
zx_status_t err;
uint8_t key_idx;
struct brcmf_wsec_key* key;
int32_t wsec;
for (key_idx = 0; key_idx < BRCMF_MAX_DEFAULT_KEYS; key_idx++) {
key = &ifp->vif->profile.key[key_idx];
if ((key->algo == CRYPTO_ALGO_WEP1) || (key->algo == CRYPTO_ALGO_WEP128)) {
break;
}
}
if (key_idx == BRCMF_MAX_DEFAULT_KEYS) {
return;
}
err = send_key_to_dongle(ifp, key);
if (err != ZX_OK) {
brcmf_err("Setting WEP key failed (%d)\n", err);
return;
}
err = brcmf_fil_bsscfg_int_get(ifp, "wsec", (uint32_t*)&wsec);
if (err != ZX_OK) {
brcmf_err("get wsec error (%d)\n", err);
return;
}
wsec |= WEP_ENABLED;
err = brcmf_fil_bsscfg_int_set(ifp, "wsec", (uint32_t)wsec);
if (err != ZX_OK) {
brcmf_err("set wsec error (%d)\n", err);
}
}
static void brcmf_convert_sta_flags(uint32_t fw_sta_flags, struct station_info* si) {
struct nl80211_sta_flag_update* sfu;
brcmf_dbg(TRACE, "flags %08x\n", fw_sta_flags);
si->filled |= BIT(NL80211_STA_INFO_STA_FLAGS);
sfu = &si->sta_flags;
sfu->mask = BIT(NL80211_STA_FLAG_WME) | BIT(NL80211_STA_FLAG_AUTHENTICATED) |
BIT(NL80211_STA_FLAG_ASSOCIATED) | BIT(NL80211_STA_FLAG_AUTHORIZED);
if (fw_sta_flags & BRCMF_STA_WME) {
sfu->set |= BIT(NL80211_STA_FLAG_WME);
}
if (fw_sta_flags & BRCMF_STA_AUTHE) {
sfu->set |= BIT(NL80211_STA_FLAG_AUTHENTICATED);
}
if (fw_sta_flags & BRCMF_STA_ASSOC) {
sfu->set |= BIT(NL80211_STA_FLAG_ASSOCIATED);
}
if (fw_sta_flags & BRCMF_STA_AUTHO) {
sfu->set |= BIT(NL80211_STA_FLAG_AUTHORIZED);
}
}
static void brcmf_fill_bss_param(struct brcmf_if* ifp, struct station_info* si) {
struct {
uint32_t len;
struct brcmf_bss_info_le bss_le;
} * buf;
uint16_t capability;
zx_status_t err;
buf = calloc(1, WL_BSS_INFO_MAX);
if (!buf) {
return;
}
buf->len = WL_BSS_INFO_MAX;
err = brcmf_fil_cmd_data_get(ifp, BRCMF_C_GET_BSS_INFO, buf, WL_BSS_INFO_MAX);
if (err != ZX_OK) {
brcmf_err("Failed to get bss info (%d)\n", err);
goto out_kfree;
}
si->filled |= BIT(NL80211_STA_INFO_BSS_PARAM);
si->bss_param.beacon_interval = buf->bss_le.beacon_period;
si->bss_param.dtim_period = buf->bss_le.dtim_period;
capability = buf->bss_le.capability;
if (capability & IEEE80211_HT_STBC_PARAM_DUAL_CTS_PROT) {
si->bss_param.flags |= BSS_PARAM_FLAGS_CTS_PROT;
}
if (capability & WLAN_CAPABILITY_SHORT_PREAMBLE) {
si->bss_param.flags |= BSS_PARAM_FLAGS_SHORT_PREAMBLE;
}
if (capability & WLAN_CAPABILITY_SHORT_SLOT_TIME) {
si->bss_param.flags |= BSS_PARAM_FLAGS_SHORT_SLOT_TIME;
}
out_kfree:
free(buf);
}
static zx_status_t brcmf_cfg80211_get_station_ibss(struct brcmf_if* ifp,
struct station_info* sinfo) {
struct brcmf_scb_val_le scbval;
struct brcmf_pktcnt_le pktcnt;
zx_status_t err;
uint32_t rate;
uint32_t rssi;
/* Get the current tx rate */
err = brcmf_fil_cmd_int_get(ifp, BRCMF_C_GET_RATE, &rate);
if (err != ZX_OK) {
brcmf_err("BRCMF_C_GET_RATE error (%d)\n", err);
return err;
}
sinfo->filled |= BIT(NL80211_STA_INFO_TX_BITRATE);
sinfo->txrate.legacy = rate * 5;
memset(&scbval, 0, sizeof(scbval));
err = brcmf_fil_cmd_data_get(ifp, BRCMF_C_GET_RSSI, &scbval, sizeof(scbval));
if (err != ZX_OK) {
brcmf_err("BRCMF_C_GET_RSSI error (%d)\n", err);
return err;
}
rssi = scbval.val;
sinfo->filled |= BIT(NL80211_STA_INFO_SIGNAL);
sinfo->signal = rssi;
err = brcmf_fil_cmd_data_get(ifp, BRCMF_C_GET_GET_PKTCNTS, &pktcnt, sizeof(pktcnt));
if (err != ZX_OK) {
brcmf_err("BRCMF_C_GET_GET_PKTCNTS error (%d)\n", err);
return err;
}
sinfo->filled |= BIT(NL80211_STA_INFO_RX_PACKETS) | BIT(NL80211_STA_INFO_RX_DROP_MISC) |
BIT(NL80211_STA_INFO_TX_PACKETS) | BIT(NL80211_STA_INFO_TX_FAILED);
sinfo->rx_packets = pktcnt.rx_good_pkt;
sinfo->rx_dropped_misc = pktcnt.rx_bad_pkt;
sinfo->tx_packets = pktcnt.tx_good_pkt;
sinfo->tx_failed = pktcnt.tx_bad_pkt;
return ZX_OK;
}
static zx_status_t brcmf_cfg80211_get_station(struct wiphy* wiphy, struct net_device* ndev,
const uint8_t* mac, struct station_info* sinfo) {
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_scb_val_le scb_val;
zx_status_t err = ZX_OK;
struct brcmf_sta_info_le sta_info_le;
uint32_t sta_flags;
uint32_t is_tdls_peer;
int32_t total_rssi;
int32_t count_rssi;
int rssi;
uint32_t i;
brcmf_dbg(TRACE, "Enter, MAC %pM\n", mac);
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
if (brcmf_is_ibssmode(ifp->vif)) {
return brcmf_cfg80211_get_station_ibss(ifp, sinfo);
}
memset(&sta_info_le, 0, sizeof(sta_info_le));
memcpy(&sta_info_le, mac, ETH_ALEN);
err = brcmf_fil_iovar_data_get(ifp, "tdls_sta_info", &sta_info_le, sizeof(sta_info_le));
is_tdls_peer = err == ZX_OK;
if (err != ZX_OK) {
err = brcmf_fil_iovar_data_get(ifp, "sta_info", &sta_info_le, sizeof(sta_info_le));
if (err != ZX_OK) {
brcmf_err("GET STA INFO failed, %d\n", err);
goto done;
}
}
brcmf_dbg(TRACE, "version %d\n", sta_info_le.ver);
sinfo->filled = BIT(NL80211_STA_INFO_INACTIVE_TIME);
sinfo->inactive_time = sta_info_le.idle * 1000;
sta_flags = sta_info_le.flags;
brcmf_convert_sta_flags(sta_flags, sinfo);
sinfo->sta_flags.mask |= BIT(NL80211_STA_FLAG_TDLS_PEER);
if (is_tdls_peer) {
sinfo->sta_flags.set |= BIT(NL80211_STA_FLAG_TDLS_PEER);
} else {
sinfo->sta_flags.set &= ~BIT(NL80211_STA_FLAG_TDLS_PEER);
}
if (sta_flags & BRCMF_STA_ASSOC) {
sinfo->filled |= BIT(NL80211_STA_INFO_CONNECTED_TIME);
sinfo->connected_time = sta_info_le.in;
brcmf_fill_bss_param(ifp, sinfo);
}
if (sta_flags & BRCMF_STA_SCBSTATS) {
sinfo->filled |= BIT(NL80211_STA_INFO_TX_FAILED);
sinfo->tx_failed = sta_info_le.tx_failures;
sinfo->filled |= BIT(NL80211_STA_INFO_TX_PACKETS);
sinfo->tx_packets = sta_info_le.tx_pkts;
sinfo->tx_packets += sta_info_le.tx_mcast_pkts;
sinfo->filled |= BIT(NL80211_STA_INFO_RX_PACKETS);
sinfo->rx_packets = sta_info_le.rx_ucast_pkts;
sinfo->rx_packets += sta_info_le.rx_mcast_pkts;
if (sinfo->tx_packets) {
sinfo->filled |= BIT(NL80211_STA_INFO_TX_BITRATE);
sinfo->txrate.legacy = sta_info_le.tx_rate / 100;
}
if (sinfo->rx_packets) {
sinfo->filled |= BIT(NL80211_STA_INFO_RX_BITRATE);
sinfo->rxrate.legacy = sta_info_le.rx_rate / 100;
}
if (sta_info_le.ver >= 4) {
sinfo->filled |= BIT(NL80211_STA_INFO_TX_BYTES);
sinfo->tx_bytes = sta_info_le.tx_tot_bytes;
sinfo->filled |= BIT(NL80211_STA_INFO_RX_BYTES);
sinfo->rx_bytes = sta_info_le.rx_tot_bytes;
}
total_rssi = 0;
count_rssi = 0;
for (i = 0; i < BRCMF_ANT_MAX; i++) {
if (sta_info_le.rssi[i]) {
sinfo->chain_signal_avg[count_rssi] = sta_info_le.rssi[i];
sinfo->chain_signal[count_rssi] = sta_info_le.rssi[i];
total_rssi += sta_info_le.rssi[i];
count_rssi++;
}
}
if (count_rssi) {
sinfo->filled |= BIT(NL80211_STA_INFO_CHAIN_SIGNAL);
sinfo->chains = count_rssi;
sinfo->filled |= BIT(NL80211_STA_INFO_SIGNAL);
total_rssi /= count_rssi;
sinfo->signal = total_rssi;
} else if (brcmf_test_bit_in_array(BRCMF_VIF_STATUS_CONNECTED, &ifp->vif->sme_state)) {
memset(&scb_val, 0, sizeof(scb_val));
err = brcmf_fil_cmd_data_get(ifp, BRCMF_C_GET_RSSI, &scb_val, sizeof(scb_val));
if (err != ZX_OK) {
brcmf_err("Could not get rssi (%d)\n", err);
goto done;
} else {
rssi = scb_val.val;
sinfo->filled |= BIT(NL80211_STA_INFO_SIGNAL);
sinfo->signal = rssi;
brcmf_dbg(CONN, "RSSI %d dBm\n", rssi);
}
}
}
done:
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static zx_status_t brcmf_cfg80211_dump_station(struct wiphy* wiphy, struct net_device* ndev,
int idx, uint8_t* mac, struct station_info* sinfo) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_if* ifp = ndev_to_if(ndev);
zx_status_t err;
brcmf_dbg(TRACE, "Enter, idx %d\n", idx);
if (idx == 0) {
cfg->assoclist.count = BRCMF_MAX_ASSOCLIST;
err = brcmf_fil_cmd_data_get(ifp, BRCMF_C_GET_ASSOCLIST, &cfg->assoclist,
sizeof(cfg->assoclist));
if (err != ZX_OK) {
brcmf_err("BRCMF_C_GET_ASSOCLIST unsupported, err=%d\n", err);
cfg->assoclist.count = 0;
return ZX_ERR_NOT_SUPPORTED;
}
}
if (idx < (int)cfg->assoclist.count) {
memcpy(mac, cfg->assoclist.mac[idx], ETH_ALEN);
return brcmf_cfg80211_get_station(wiphy, ndev, mac, sinfo);
}
return ZX_ERR_NOT_FOUND;
}
static zx_status_t brcmf_cfg80211_set_power_mgmt(struct wiphy* wiphy, struct net_device* ndev,
bool enabled, int32_t timeout) {
int32_t pm;
zx_status_t err = ZX_OK;
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_if* ifp = ndev_to_if(ndev);
brcmf_dbg(TRACE, "Enter\n");
/*
* Powersave enable/disable request is coming from the
* cfg80211 even before the interface is up. In that
* scenario, driver will be storing the power save
* preference in cfg struct to apply this to
* FW later while initializing the dongle
*/
cfg->pwr_save = enabled;
if (!check_vif_up(ifp->vif)) {
brcmf_dbg(INFO, "Device is not ready, storing the value in cfg_info struct\n");
goto done;
}
pm = enabled ? PM_FAST : PM_OFF;
/* Do not enable the power save after assoc if it is a p2p interface */
if (ifp->vif->wdev.iftype == NL80211_IFTYPE_P2P_CLIENT) {
brcmf_dbg(INFO, "Do not enable power save for P2P clients\n");
pm = PM_OFF;
}
brcmf_dbg(INFO, "power save %s\n", (pm ? "enabled" : "disabled"));
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_PM, pm);
if (err != ZX_OK) {
if (err == ZX_ERR_UNAVAILABLE) {
brcmf_err("net_device is not ready yet\n");
} else {
brcmf_err("error (%d)\n", err);
}
}
done:
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static void brcmf_ies_extract_name(uint8_t* ie, size_t length, char* nameptr, size_t name_size) {
size_t offset = 0;
while (offset < length) {
uint8_t type = ie[offset];
uint8_t length = ie[offset + 1];
if (type == 0) {
memcpy(nameptr, ie + offset + 2, min(length, name_size));
nameptr[min(length, name_size)] = '\0';
}
offset += length + 2;
}
}
#ifdef WANTED_FOR_DEBUG
static void brcmf_iedump(uint8_t* ie, size_t length) {
size_t offset = 0;
char ieinfo[500] = "";
char* ieinfoptr = ieinfo;
while (offset < length) {
uint8_t type = ie[offset];
uint8_t length = ie[offset + 1];
if (type == 0) {
brcmf_dbg(TEMP, " * * ie 0 (name), len %d", length);
brcmf_alphadump(ie + offset + 2, length);
} else {
//brcmf_dbg(TEMP, "ie %d, len %d", type, length);
//brcmf_hexdump("iedump", ie + offset + 2, length);
if (ieinfoptr < ieinfo + sizeof(ieinfo)) {
ieinfoptr += snprintf(ieinfoptr, sizeof(ieinfo) - (ieinfoptr - ieinfo),
"ie %d, len %d. ", ie[offset], length);
}
}
offset += length + 2;
}
brcmf_dbg(TEMP, "IEs: %s", ieinfo);
if (offset != length) {
brcmf_dbg(TEMP, " * * Offset %ld didn't match length %ld", offset, length);
}
}
#endif // WANTED_FOR_DEBUG
void brcmf_cfg80211_rx(struct brcmf_if* ifp, struct brcmf_netbuf* packet) {
struct net_device* ndev = ifp->ndev;
brcmf_dbg(TEMP, "Calling data_recv with data 0x%016lx %016lx len %d", *(uint64_t*)packet->data,
*(uint64_t*)(packet->data+8), packet->len);
ndev->if_callbacks->data_recv(ndev->if_callback_cookie, packet->data, packet->len, 0);
brcmu_pkt_buf_free_netbuf(packet);
}
static void brcmf_return_scan_result(struct wiphy* wiphy, uint16_t channel, const uint8_t* bssid,
uint16_t capability, uint16_t interval, uint8_t* ie,
size_t ie_len, int16_t rssi_dbm) {
struct net_device* ndev = wiphy_to_ndev(wiphy);
wlanif_scan_result_t result;
char ssid_buf[IEEE80211_MAX_SSID_LEN + 1];
if (!wiphy->scan_busy) {
return;
}
result.txn_id = wiphy->scan_txn_id;
memcpy(result.bss.bssid, bssid, ETH_ALEN);
result.bss.ssid = ssid_buf;
brcmf_ies_extract_name(ie, ie_len, ssid_buf, sizeof(ssid_buf));
result.bss.bss_type = BSS_TYPE_ANY_BSS;
result.bss.beacon_period = 0;
result.bss.dtim_period = 0;
result.bss.timestamp = 0;
result.bss.local_time = 0;
result.bss.rsne_len = 0;
result.bss.rsne = NULL;
result.bss.chan.primary = (uint8_t)channel;
result.bss.chan.cbw = CBW20; // TODO(cphoenix): Don't hard-code this.
result.bss.rssi_dbm = (uint8_t)(min(0, max(-255, rssi_dbm)));
result.bss.rcpi_dbmh = 0;
result.bss.rsni_dbh = 0;
//brcmf_dbg(TEMP, "Returning scan result %s, channel %d, dbm %d, id %lu", result.bss.ssid,
// result.bss.chan.primary, result.bss.rssi_dbm, result.txn_id);
ndev->if_callbacks->on_scan_result(ndev->if_callback_cookie, &result);
}
static zx_status_t brcmf_inform_single_bss(struct brcmf_cfg80211_info* cfg,
struct brcmf_bss_info_le* bi) {
struct wiphy* wiphy = cfg_to_wiphy(cfg);
struct ieee80211_supported_band* band;
struct brcmu_chan ch;
uint16_t channel;
uint16_t notify_capability;
uint16_t notify_interval;
uint8_t* notify_ie;
size_t notify_ielen;
int16_t notify_rssi_dbm;
if (bi->length > WL_BSS_INFO_MAX) {
brcmf_err("Bss info is larger than buffer. Discarding\n");
brcmf_dbg(TEMP, "Early return, due to length.");
return ZX_OK;
}
if (!bi->ctl_ch) {
ch.chspec = bi->chanspec;
cfg->d11inf.decchspec(&ch);
bi->ctl_ch = ch.control_ch_num;
}
channel = bi->ctl_ch;
if (channel <= CH_MAX_2G_CHANNEL) {
band = wiphy->bands[NL80211_BAND_2GHZ];
} else {
band = wiphy->bands[NL80211_BAND_5GHZ];
}
notify_capability = bi->capability;
notify_interval = bi->beacon_period;
notify_ie = (uint8_t*)bi + bi->ie_offset;
notify_ielen = bi->ie_length;
notify_rssi_dbm = (int16_t)bi->RSSI;
//brcmf_dbg(CONN, "bssid: %pM\n", bi->BSSID);
//brcmf_dbg(CONN, "Channel: %d\n", channel);
//brcmf_dbg(CONN, "Capability: %X\n", notify_capability);
//brcmf_dbg(CONN, "Beacon interval: %d\n", notify_interval);
//brcmf_dbg(CONN, "Signal: %d\n", notify_rssi_dbm);
//brcmf_dbg(TEMP, " * * Got a scan result:");
// brcmf_iedump(notify_ie, notify_ielen);
brcmf_return_scan_result(wiphy, (uint8_t)channel,
(const uint8_t*)bi->BSSID, notify_capability, notify_interval,
notify_ie, notify_ielen, notify_rssi_dbm);
return ZX_OK;
}
static struct brcmf_bss_info_le* next_bss_le(struct brcmf_scan_results* list,
struct brcmf_bss_info_le* bss) {
if (bss == NULL) {
return list->bss_info_le;
}
return (struct brcmf_bss_info_le*)((unsigned long)bss + bss->length);
}
static zx_status_t brcmf_inform_bss(struct brcmf_cfg80211_info* cfg) {
struct brcmf_scan_results* bss_list;
struct brcmf_bss_info_le* bi = NULL; /* must be initialized */
zx_status_t err = ZX_OK;
int i;
bss_list = (struct brcmf_scan_results*)cfg->escan_info.escan_buf;
if (bss_list->count != 0 && bss_list->version != BRCMF_BSS_INFO_VERSION) {
brcmf_err("Version %d != WL_BSS_INFO_VERSION\n", bss_list->version);
return ZX_ERR_NOT_SUPPORTED;
}
brcmf_dbg(SCAN, "scanned AP count (%d), wiphy %p", bss_list->count, cfg_to_wiphy(cfg));
for (i = 0; i < (int32_t)bss_list->count; i++) {
bi = next_bss_le(bss_list, bi);
err = brcmf_inform_single_bss(cfg, bi);
if (err != ZX_OK) {
break;
}
}
return err;
}
static zx_status_t brcmf_inform_ibss(struct brcmf_cfg80211_info* cfg, struct net_device* ndev,
const uint8_t* bssid) {
struct wiphy* wiphy = cfg_to_wiphy(cfg);
struct brcmf_bss_info_le* bi = NULL;
struct ieee80211_supported_band* band;
struct brcmu_chan ch;
uint8_t* buf = NULL;
zx_status_t err = ZX_OK;
uint16_t notify_capability;
uint16_t notify_interval;
uint8_t* notify_ie;
size_t notify_ielen;
int32_t notify_signal;
brcmf_dbg(TRACE, "Enter\n");
buf = calloc(1, WL_BSS_INFO_MAX);
if (buf == NULL) {
err = ZX_ERR_NO_MEMORY;
goto CleanUp;
}
*(uint32_t*)buf = WL_BSS_INFO_MAX;
err = brcmf_fil_cmd_data_get(ndev_to_if(ndev), BRCMF_C_GET_BSS_INFO, buf, WL_BSS_INFO_MAX);
if (err != ZX_OK) {
brcmf_err("WLC_GET_BSS_INFO failed: %d\n", err);
goto CleanUp;
}
bi = (struct brcmf_bss_info_le*)(buf + 4);
ch.chspec = bi->chanspec;
cfg->d11inf.decchspec(&ch);
if (ch.band == BRCMU_CHAN_BAND_2G) {
band = wiphy->bands[NL80211_BAND_2GHZ];
} else {
band = wiphy->bands[NL80211_BAND_5GHZ];
}
notify_capability = bi->capability;
notify_interval = bi->beacon_period;
notify_ie = (uint8_t*)bi + bi->ie_offset;
notify_ielen = bi->ie_length;
notify_signal = (int16_t)bi->RSSI * 100;
brcmf_dbg(CONN, "channel: %d(%d)\n", ch.control_ch_num, ch.chnum);
brcmf_dbg(CONN, "capability: %X\n", notify_capability);
brcmf_dbg(CONN, "beacon interval: %d\n", notify_interval);
brcmf_dbg(CONN, "signal: %d\n", notify_signal);
brcmf_return_scan_result(wiphy, ch.chnum, bssid,
notify_capability, notify_interval, notify_ie, notify_ielen,
notify_signal);
CleanUp:
free(buf);
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static zx_status_t brcmf_update_bss_info(struct brcmf_cfg80211_info* cfg, struct brcmf_if* ifp) {
struct brcmf_bss_info_le* bi;
const struct brcmf_tlv* tim;
uint16_t beacon_interval;
uint8_t dtim_period;
size_t ie_len;
uint8_t* ie;
zx_status_t err = ZX_OK;
brcmf_dbg(TRACE, "Enter\n");
if (brcmf_is_ibssmode(ifp->vif)) {
return err;
}
*(uint32_t*)cfg->extra_buf = WL_EXTRA_BUF_MAX;
err = brcmf_fil_cmd_data_get(ifp, BRCMF_C_GET_BSS_INFO, cfg->extra_buf, WL_EXTRA_BUF_MAX);
if (err != ZX_OK) {
brcmf_err("Could not get bss info %d\n", err);
goto update_bss_info_out;
}
bi = (struct brcmf_bss_info_le*)(cfg->extra_buf + 4);
err = brcmf_inform_single_bss(cfg, bi);
if (err != ZX_OK) {
goto update_bss_info_out;
}
ie = ((uint8_t*)bi) + bi->ie_offset;
ie_len = bi->ie_length;
beacon_interval = bi->beacon_period;
tim = brcmf_parse_tlvs(ie, ie_len, WLAN_EID_TIM);
if (tim) {
dtim_period = tim->data[1];
} else {
/*
* active scan was done so we could not get dtim
* information out of probe response.
* so we speficially query dtim information to dongle.
*/
uint32_t var;
err = brcmf_fil_iovar_int_get(ifp, "dtim_assoc", &var);
if (err != ZX_OK) {
brcmf_err("wl dtim_assoc failed (%d)\n", err);
goto update_bss_info_out;
}
dtim_period = (uint8_t)var;
}
update_bss_info_out:
brcmf_dbg(TRACE, "Exit");
return err;
}
void brcmf_abort_scanning(struct brcmf_cfg80211_info* cfg) {
struct escan_info* escan = &cfg->escan_info;
brcmf_set_bit_in_array(BRCMF_SCAN_STATUS_ABORT, &cfg->scan_status);
if (cfg->int_escan_map || cfg->scan_request) {
escan->escan_state = WL_ESCAN_STATE_IDLE;
brcmf_notify_escan_complete(cfg, escan->ifp, true, true);
}
brcmf_clear_bit_in_array(BRCMF_SCAN_STATUS_BUSY, &cfg->scan_status);
brcmf_clear_bit_in_array(BRCMF_SCAN_STATUS_ABORT, &cfg->scan_status);
}
static void brcmf_cfg80211_escan_timeout_worker(struct work_struct* work) {
struct brcmf_cfg80211_info* cfg =
containerof(work, struct brcmf_cfg80211_info, escan_timeout_work);
brcmf_inform_bss(cfg);
brcmf_notify_escan_complete(cfg, cfg->escan_info.ifp, true, true);
}
static void brcmf_escan_timeout(void* data) {
pthread_mutex_lock(&irq_callback_lock);
struct brcmf_cfg80211_info* cfg = data;
if (cfg->int_escan_map || cfg->scan_request) {
brcmf_err("timer expired\n");
workqueue_schedule_default(&cfg->escan_timeout_work);
}
pthread_mutex_unlock(&irq_callback_lock);
}
static bool brcmf_compare_update_same_bss(struct brcmf_cfg80211_info* cfg,
struct brcmf_bss_info_le* bss,
struct brcmf_bss_info_le* bss_info_le) {
struct brcmu_chan ch_bss, ch_bss_info_le;
ch_bss.chspec = bss->chanspec;
cfg->d11inf.decchspec(&ch_bss);
ch_bss_info_le.chspec = bss_info_le->chanspec;
cfg->d11inf.decchspec(&ch_bss_info_le);
if (!memcmp(&bss_info_le->BSSID, &bss->BSSID, ETH_ALEN) && ch_bss.band == ch_bss_info_le.band &&
bss_info_le->SSID_len == bss->SSID_len &&
!memcmp(bss_info_le->SSID, bss->SSID, bss_info_le->SSID_len)) {
if ((bss->flags & BRCMF_BSS_RSSI_ON_CHANNEL) ==
(bss_info_le->flags & BRCMF_BSS_RSSI_ON_CHANNEL)) {
int16_t bss_rssi = bss->RSSI;
int16_t bss_info_rssi = bss_info_le->RSSI;
/* preserve max RSSI if the measurements are
* both on-channel or both off-channel
*/
if (bss_info_rssi > bss_rssi) {
bss->RSSI = bss_info_le->RSSI;
}
} else if ((bss->flags & BRCMF_BSS_RSSI_ON_CHANNEL) &&
(bss_info_le->flags & BRCMF_BSS_RSSI_ON_CHANNEL) == 0) {
/* preserve the on-channel rssi measurement
* if the new measurement is off channel
*/
bss->RSSI = bss_info_le->RSSI;
bss->flags |= BRCMF_BSS_RSSI_ON_CHANNEL;
}
return true;
}
return false;
}
static zx_status_t brcmf_cfg80211_escan_handler(struct brcmf_if* ifp,
const struct brcmf_event_msg* e, void* data) {
struct brcmf_cfg80211_info* cfg = ifp->drvr->config;
int32_t status;
struct brcmf_escan_result_le* escan_result_le;
uint32_t escan_buflen;
struct brcmf_bss_info_le* bss_info_le;
struct brcmf_bss_info_le* bss = NULL;
uint32_t bi_length;
struct brcmf_scan_results* list;
uint32_t i;
bool aborted;
status = e->status;
if (status == BRCMF_E_STATUS_ABORT) {
goto exit;
}
if (!brcmf_test_bit_in_array(BRCMF_SCAN_STATUS_BUSY, &cfg->scan_status)) {
brcmf_err("scan not ready, bsscfgidx=%d\n", ifp->bsscfgidx);
return ZX_ERR_UNAVAILABLE;
}
if (status == BRCMF_E_STATUS_PARTIAL) {
//brcmf_dbg(SCAN, "ESCAN Partial result\n");
if (e->datalen < sizeof(*escan_result_le)) {
brcmf_err("invalid event data length\n");
goto exit;
}
escan_result_le = (struct brcmf_escan_result_le*)data;
if (!escan_result_le) {
brcmf_err("Invalid escan result (NULL pointer)\n");
goto exit;
}
escan_buflen = escan_result_le->buflen;
if (escan_buflen > BRCMF_ESCAN_BUF_SIZE || escan_buflen > e->datalen ||
escan_buflen < sizeof(*escan_result_le)) {
brcmf_err("Invalid escan buffer length: %d\n", escan_buflen);
goto exit;
}
if (escan_result_le->bss_count != 1) {
brcmf_err("Invalid bss_count %d: ignoring\n", escan_result_le->bss_count);
goto exit;
}
bss_info_le = &escan_result_le->bss_info_le;
if (brcmf_p2p_scan_finding_common_channel(cfg, bss_info_le)) {
goto exit;
}
if (!cfg->int_escan_map && !cfg->scan_request) {
brcmf_dbg(SCAN, "result without cfg80211 request\n");
goto exit;
}
bi_length = bss_info_le->length;
if (bi_length != escan_buflen - WL_ESCAN_RESULTS_FIXED_SIZE) {
brcmf_err("Ignoring invalid bss_info length: %d\n", bi_length);
goto exit;
}
if (!(cfg_to_wiphy(cfg)->interface_modes & BIT(NL80211_IFTYPE_ADHOC))) {
if (bss_info_le->capability & WLAN_CAPABILITY_IBSS) {
brcmf_err("Ignoring IBSS result\n");
goto exit;
}
}
list = (struct brcmf_scan_results*)cfg->escan_info.escan_buf;
if (bi_length > BRCMF_ESCAN_BUF_SIZE - list->buflen) {
brcmf_err("Buffer is too small: ignoring\n");
goto exit;
}
for (i = 0; i < list->count; i++) {
bss = bss ? (struct brcmf_bss_info_le*)((unsigned char*)bss + bss->length)
: list->bss_info_le;
if (brcmf_compare_update_same_bss(cfg, bss, bss_info_le)) {
goto exit;
}
}
memcpy(&cfg->escan_info.escan_buf[list->buflen], bss_info_le, bi_length);
list->version = bss_info_le->version;
list->buflen += bi_length;
list->count++;
} else {
cfg->escan_info.escan_state = WL_ESCAN_STATE_IDLE;
if (brcmf_p2p_scan_finding_common_channel(cfg, NULL)) {
goto exit;
}
if (cfg->int_escan_map || cfg->scan_request) {
brcmf_inform_bss(cfg);
aborted = status != BRCMF_E_STATUS_SUCCESS;
brcmf_notify_escan_complete(cfg, ifp, aborted, false);
} else {
brcmf_dbg(SCAN, "Ignored scan complete result 0x%x\n", status);
}
}
exit:
return ZX_OK;
}
static void brcmf_init_escan(struct brcmf_cfg80211_info* cfg) {
brcmf_fweh_register(cfg->pub, BRCMF_E_ESCAN_RESULT, brcmf_cfg80211_escan_handler);
cfg->escan_info.escan_state = WL_ESCAN_STATE_IDLE;
/* Init scan_timeout timer */
cfg->escan_timeout.data = cfg;
brcmf_timer_init(&cfg->escan_timeout, brcmf_escan_timeout, cfg);
workqueue_init_work(&cfg->escan_timeout_work, brcmf_cfg80211_escan_timeout_worker);
}
static struct cfg80211_scan_request* brcmf_alloc_internal_escan_request(struct wiphy* wiphy,
uint32_t n_netinfo) {
struct cfg80211_scan_request* req;
size_t req_size;
req_size =
sizeof(*req) + n_netinfo * sizeof(req->channels[0]) + n_netinfo * sizeof(*req->ssids);
req = calloc(1, req_size);
if (req) {
req->wiphy = wiphy;
req->ssids = (void*)(&req->channels[0]) + n_netinfo * sizeof(req->channels[0]);
}
return req;
}
static zx_status_t brcmf_internal_escan_add_info(struct cfg80211_scan_request* req, uint8_t* ssid,
uint8_t ssid_len, uint8_t channel) {
struct ieee80211_channel* chan;
enum nl80211_band band;
int freq, i;
if (channel <= CH_MAX_2G_CHANNEL) {
band = NL80211_BAND_2GHZ;
} else {
band = NL80211_BAND_5GHZ;
}
freq = ieee80211_channel_to_frequency(channel, band);
if (!freq) {
return ZX_ERR_INVALID_ARGS;
}
chan = ieee80211_get_channel(req->wiphy, freq);
if (!chan) {
return ZX_ERR_INVALID_ARGS;
}
for (i = 0; i < req->n_channels; i++) {
if (req->channels[i] == chan) {
break;
}
}
if (i == req->n_channels) {
req->channels[req->n_channels++] = chan;
}
for (i = 0; i < req->n_ssids; i++) {
if (req->ssids[i].ssid_len == ssid_len && !memcmp(req->ssids[i].ssid, ssid, ssid_len)) {
break;
}
}
if (i == req->n_ssids) {
memcpy(req->ssids[req->n_ssids].ssid, ssid, ssid_len);
req->ssids[req->n_ssids++].ssid_len = ssid_len;
}
return ZX_OK;
}
static zx_status_t brcmf_start_internal_escan(struct brcmf_if* ifp, uint32_t fwmap,
struct cfg80211_scan_request* request) {
struct brcmf_cfg80211_info* cfg = ifp->drvr->config;
zx_status_t err;
if (brcmf_test_bit_in_array(BRCMF_SCAN_STATUS_BUSY, &cfg->scan_status)) {
if (cfg->int_escan_map) {
brcmf_dbg(SCAN, "aborting internal scan: map=%u\n", cfg->int_escan_map);
}
/* Abort any on-going scan */
brcmf_abort_scanning(cfg);
}
brcmf_dbg(SCAN, "start internal scan: map=%u\n", fwmap);
brcmf_set_bit_in_array(BRCMF_SCAN_STATUS_BUSY, &cfg->scan_status);
cfg->escan_info.run = brcmf_run_escan;
err = brcmf_do_escan(ifp, request);
if (err != ZX_OK) {
brcmf_clear_bit_in_array(BRCMF_SCAN_STATUS_BUSY, &cfg->scan_status);
return err;
}
cfg->int_escan_map = fwmap;
return ZX_OK;
}
static struct brcmf_pno_net_info_le* brcmf_get_netinfo_array(
struct brcmf_pno_scanresults_le* pfn_v1) {
struct brcmf_pno_scanresults_v2_le* pfn_v2;
struct brcmf_pno_net_info_le* netinfo;
switch (pfn_v1->version) {
default:
WARN_ON(1);
/* fall-thru */
case 1:
netinfo = (struct brcmf_pno_net_info_le*)(pfn_v1 + 1);
break;
case 2:
pfn_v2 = (struct brcmf_pno_scanresults_v2_le*)pfn_v1;
netinfo = (struct brcmf_pno_net_info_le*)(pfn_v2 + 1);
break;
}
return netinfo;
}
/* PFN result doesn't have all the info which are required by the supplicant
* (For e.g IEs) Do a target Escan so that sched scan results are reported
* via wl_inform_single_bss in the required format. Escan does require the
* scan request in the form of cfg80211_scan_request. For timebeing, create
* cfg80211_scan_request one out of the received PNO event.
*/
static zx_status_t brcmf_notify_sched_scan_results(struct brcmf_if* ifp,
const struct brcmf_event_msg* e, void* data) {
struct brcmf_cfg80211_info* cfg = ifp->drvr->config;
struct brcmf_pno_net_info_le* netinfo;
struct brcmf_pno_net_info_le* netinfo_start;
struct cfg80211_scan_request* request = NULL;
struct wiphy* wiphy = cfg_to_wiphy(cfg);
int i;
zx_status_t err = ZX_OK;
struct brcmf_pno_scanresults_le* pfn_result;
uint32_t bucket_map;
uint32_t result_count;
uint32_t status;
uint32_t datalen;
brcmf_dbg(SCAN, "Enter\n");
if (e->datalen < (sizeof(*pfn_result) + sizeof(*netinfo))) {
brcmf_dbg(SCAN, "Event data to small. Ignore\n");
return ZX_OK;
}
if (e->event_code == BRCMF_E_PFN_NET_LOST) {
brcmf_dbg(SCAN, "PFN NET LOST event. Do Nothing\n");
return ZX_OK;
}
pfn_result = (struct brcmf_pno_scanresults_le*)data;
result_count = pfn_result->count;
status = pfn_result->status;
/* PFN event is limited to fit 512 bytes so we may get
* multiple NET_FOUND events. For now place a warning here.
*/
WARN_ON(status != BRCMF_PNO_SCAN_COMPLETE);
brcmf_dbg(SCAN, "PFN NET FOUND event. count: %d\n", result_count);
if (!result_count) {
brcmf_err("FALSE PNO Event. (pfn_count == 0)\n");
// TODO(cphoenix): err isn't set here. Should it be?
goto out_err;
}
netinfo_start = brcmf_get_netinfo_array(pfn_result);
datalen = e->datalen - ((void*)netinfo_start - (void*)pfn_result);
if (datalen < result_count * sizeof(*netinfo)) {
brcmf_err("insufficient event data\n");
// TODO(cphoenix): err isn't set here. Should it be?
goto out_err;
}
request = brcmf_alloc_internal_escan_request(wiphy, result_count);
if (!request) {
err = ZX_ERR_NO_MEMORY;
goto out_err;
}
bucket_map = 0;
for (i = 0; i < (int32_t)result_count; i++) {
netinfo = &netinfo_start[i];
if (netinfo->SSID_len > IEEE80211_MAX_SSID_LEN) {
netinfo->SSID_len = IEEE80211_MAX_SSID_LEN;
}
brcmf_dbg(SCAN, "SSID:%.32s Channel:%d\n", netinfo->SSID, netinfo->channel);
bucket_map |= brcmf_pno_get_bucket_map(cfg->pno, netinfo);
err = brcmf_internal_escan_add_info(request, netinfo->SSID, netinfo->SSID_len,
netinfo->channel);
if (err != ZX_OK) {
goto out_err;
}
}
if (!bucket_map) {
goto free_req;
}
err = brcmf_start_internal_escan(ifp, bucket_map, request);
if (err == ZX_OK) {
goto free_req;
}
out_err:
if (wiphy->scan_busy) {
brcmf_dbg(TEMP, "out_err %d, signaling scan end", err);
brcmf_signal_scan_end(wiphy_to_ndev(wiphy), wiphy->scan_txn_id, SCAN_RESULT_INTERNAL_ERROR);
}
free_req:
free(request);
return err;
}
static zx_status_t brcmf_cfg80211_sched_scan_start(struct wiphy* wiphy, struct net_device* ndev,
struct cfg80211_sched_scan_request* req) {
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
brcmf_dbg(SCAN, "Enter: n_match_sets=%d n_ssids=%d\n", req->n_match_sets, req->n_ssids);
if (brcmf_test_bit_in_array(BRCMF_SCAN_STATUS_SUPPRESS, &cfg->scan_status)) {
brcmf_err("Scanning suppressed: status=%lu\n", cfg->scan_status);
return ZX_ERR_UNAVAILABLE;
}
if (req->n_match_sets <= 0) {
brcmf_dbg(SCAN, "invalid number of matchsets specified: %d\n", req->n_match_sets);
return ZX_ERR_INVALID_ARGS;
}
return brcmf_pno_start_sched_scan(ifp, req);
}
static zx_status_t brcmf_cfg80211_sched_scan_stop(struct wiphy* wiphy, struct net_device* ndev,
uint64_t reqid) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_if* ifp = ndev_to_if(ndev);
brcmf_dbg(SCAN, "enter\n");
brcmf_pno_stop_sched_scan(ifp, reqid);
if (cfg->int_escan_map) {
brcmf_notify_escan_complete(cfg, ifp, true, true);
}
return ZX_OK;
}
static zx_status_t brcmf_config_wowl_pattern(struct brcmf_if* ifp, uint8_t cmd[4], uint8_t* pattern,
uint32_t patternsize, uint8_t* mask,
uint32_t packet_offset) {
struct brcmf_fil_wowl_pattern_le* filter;
uint32_t masksize;
uint32_t patternoffset;
uint8_t* buf;
uint32_t bufsize;
zx_status_t ret;
masksize = (patternsize + 7) / 8;
patternoffset = sizeof(*filter) - sizeof(filter->cmd) + masksize;
bufsize = sizeof(*filter) + patternsize + masksize;
buf = calloc(1, bufsize);
if (!buf) {
return ZX_ERR_NO_MEMORY;
}
filter = (struct brcmf_fil_wowl_pattern_le*)buf;
memcpy(filter->cmd, cmd, 4);
filter->masksize = masksize;
filter->offset = packet_offset;
filter->patternoffset = patternoffset;
filter->patternsize = patternsize;
filter->type = BRCMF_WOWL_PATTERN_TYPE_BITMAP;
if ((mask) && (masksize)) {
memcpy(buf + sizeof(*filter), mask, masksize);
}
if ((pattern) && (patternsize)) {
memcpy(buf + sizeof(*filter) + masksize, pattern, patternsize);
}
ret = brcmf_fil_iovar_data_set(ifp, "wowl_pattern", buf, bufsize);
free(buf);
return ret;
}
static zx_status_t brcmf_wowl_nd_results(struct brcmf_if* ifp, const struct brcmf_event_msg* e,
void* data) {
struct brcmf_cfg80211_info* cfg = ifp->drvr->config;
struct brcmf_pno_scanresults_le* pfn_result;
struct brcmf_pno_net_info_le* netinfo;
brcmf_dbg(SCAN, "Enter\n");
if (e->datalen < (sizeof(*pfn_result) + sizeof(*netinfo))) {
brcmf_dbg(SCAN, "Event data to small. Ignore\n");
return ZX_OK;
}
pfn_result = (struct brcmf_pno_scanresults_le*)data;
if (e->event_code == BRCMF_E_PFN_NET_LOST) {
brcmf_dbg(SCAN, "PFN NET LOST event. Ignore\n");
return ZX_OK;
}
if (pfn_result->count < 1) {
brcmf_err("Invalid result count, expected 1 (%d)\n", pfn_result->count);
return ZX_ERR_INVALID_ARGS;
}
netinfo = brcmf_get_netinfo_array(pfn_result);
memcpy(cfg->wowl.nd->ssid.ssid, netinfo->SSID, netinfo->SSID_len);
cfg->wowl.nd->ssid.ssid_len = netinfo->SSID_len;
cfg->wowl.nd->n_channels = 1;
cfg->wowl.nd->channels[0] = ieee80211_channel_to_frequency(
netinfo->channel,
netinfo->channel <= CH_MAX_2G_CHANNEL ? NL80211_BAND_2GHZ : NL80211_BAND_5GHZ);
cfg->wowl.nd_info->n_matches = 1;
cfg->wowl.nd_info->matches[0] = cfg->wowl.nd;
/* Inform (the resume task) that the net detect information was recvd */
sync_completion_signal(&cfg->wowl.nd_data_wait);
return ZX_OK;
}
#ifdef CONFIG_PM
static void brcmf_report_wowl_wakeind(struct wiphy* wiphy, struct brcmf_if* ifp) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_wowl_wakeind_le wake_ind_le;
struct cfg80211_wowlan_wakeup wakeup_data;
struct cfg80211_wowlan_wakeup* wakeup;
uint32_t wakeind;
zx_status_t err;
int timeout;
err = brcmf_fil_iovar_data_get(ifp, "wowl_wakeind", &wake_ind_le, sizeof(wake_ind_le));
if (err != ZX_OK) {
brcmf_err("Get wowl_wakeind failed, err = %d\n", err);
return;
}
wakeind = wake_ind_le.ucode_wakeind;
if (wakeind & (BRCMF_WOWL_MAGIC | BRCMF_WOWL_DIS | BRCMF_WOWL_BCN | BRCMF_WOWL_RETR |
BRCMF_WOWL_NET | BRCMF_WOWL_PFN_FOUND)) {
wakeup = &wakeup_data;
memset(&wakeup_data, 0, sizeof(wakeup_data));
wakeup_data.pattern_idx = -1;
if (wakeind & BRCMF_WOWL_MAGIC) {
brcmf_dbg(INFO, "WOWL Wake indicator: BRCMF_WOWL_MAGIC\n");
wakeup_data.magic_pkt = true;
}
if (wakeind & BRCMF_WOWL_DIS) {
brcmf_dbg(INFO, "WOWL Wake indicator: BRCMF_WOWL_DIS\n");
wakeup_data.disconnect = true;
}
if (wakeind & BRCMF_WOWL_BCN) {
brcmf_dbg(INFO, "WOWL Wake indicator: BRCMF_WOWL_BCN\n");
wakeup_data.disconnect = true;
}
if (wakeind & BRCMF_WOWL_RETR) {
brcmf_dbg(INFO, "WOWL Wake indicator: BRCMF_WOWL_RETR\n");
wakeup_data.disconnect = true;
}
if (wakeind & BRCMF_WOWL_NET) {
brcmf_dbg(INFO, "WOWL Wake indicator: BRCMF_WOWL_NET\n");
/* For now always map to pattern 0, no API to get
* correct information available at the moment.
*/
wakeup_data.pattern_idx = 0;
}
if (wakeind & BRCMF_WOWL_PFN_FOUND) {
brcmf_dbg(INFO, "WOWL Wake indicator: BRCMF_WOWL_PFN_FOUND\n");
err = sync_completion_wait(&cfg->wowl.nd_data_wait, ZX_MSEC(BRCMF_ND_INFO_TIMEOUT_MSEC));
if (err != ZX_OK) {
brcmf_err("No result for wowl net detect\n");
} else {
wakeup_data.net_detect = cfg->wowl.nd_info;
}
}
if (wakeind & BRCMF_WOWL_GTK_FAILURE) {
brcmf_dbg(INFO, "WOWL Wake indicator: BRCMF_WOWL_GTK_FAILURE\n");
wakeup_data.gtk_rekey_failure = true;
}
} else {
wakeup = NULL;
}
cfg80211_report_wowlan_wakeup(&ifp->vif->wdev, wakeup);
}
#else
static void brcmf_report_wowl_wakeind(struct wiphy* wiphy, struct brcmf_if* ifp) {}
#endif /* CONFIG_PM */
static zx_status_t brcmf_cfg80211_resume(struct wiphy* wiphy) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct net_device* ndev = cfg_to_ndev(cfg);
struct brcmf_if* ifp = ndev_to_if(ndev);
brcmf_dbg(TRACE, "Enter\n");
if (cfg->wowl.active) {
brcmf_report_wowl_wakeind(wiphy, ifp);
brcmf_fil_iovar_int_set(ifp, "wowl_clear", 0);
brcmf_config_wowl_pattern(ifp, (uint8_t*)"clr", NULL, 0, NULL, 0);
if (!brcmf_feat_is_enabled(ifp, BRCMF_FEAT_WOWL_ARP_ND)) {
brcmf_configure_arp_nd_offload(ifp, true);
}
brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_PM, cfg->wowl.pre_pmmode);
cfg->wowl.active = false;
if (cfg->wowl.nd_enabled) {
brcmf_cfg80211_sched_scan_stop(cfg->wiphy, ifp->ndev, 0);
brcmf_fweh_unregister(cfg->pub, BRCMF_E_PFN_NET_FOUND);
brcmf_fweh_register(cfg->pub, BRCMF_E_PFN_NET_FOUND, brcmf_notify_sched_scan_results);
cfg->wowl.nd_enabled = false;
}
}
return ZX_OK;
}
static void brcmf_configure_wowl(struct brcmf_cfg80211_info* cfg, struct brcmf_if* ifp,
struct cfg80211_wowlan* wowl) {
uint32_t wowl_config;
struct brcmf_wowl_wakeind_le wowl_wakeind;
uint32_t i;
brcmf_dbg(TRACE, "Suspend, wowl config.\n");
if (!brcmf_feat_is_enabled(ifp, BRCMF_FEAT_WOWL_ARP_ND)) {
brcmf_configure_arp_nd_offload(ifp, false);
}
brcmf_fil_cmd_int_get(ifp, BRCMF_C_GET_PM, &cfg->wowl.pre_pmmode);
brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_PM, PM_MAX);
wowl_config = 0;
if (wowl->disconnect) {
wowl_config = BRCMF_WOWL_DIS | BRCMF_WOWL_BCN | BRCMF_WOWL_RETR;
}
if (wowl->magic_pkt) {
wowl_config |= BRCMF_WOWL_MAGIC;
}
if ((wowl->patterns) && (wowl->n_patterns)) {
wowl_config |= BRCMF_WOWL_NET;
for (i = 0; i < wowl->n_patterns; i++) {
brcmf_config_wowl_pattern(ifp, (uint8_t*)"add", (uint8_t*)wowl->patterns[i].pattern,
wowl->patterns[i].pattern_len,
(uint8_t*)wowl->patterns[i].mask,
wowl->patterns[i].pkt_offset);
}
}
if (wowl->nd_config) {
brcmf_cfg80211_sched_scan_start(cfg->wiphy, ifp->ndev, wowl->nd_config);
wowl_config |= BRCMF_WOWL_PFN_FOUND;
sync_completion_reset(&cfg->wowl.nd_data_wait);
cfg->wowl.nd_enabled = true;
/* Now reroute the event for PFN to the wowl function. */
brcmf_fweh_unregister(cfg->pub, BRCMF_E_PFN_NET_FOUND);
brcmf_fweh_register(cfg->pub, BRCMF_E_PFN_NET_FOUND, brcmf_wowl_nd_results);
}
if (wowl->gtk_rekey_failure) {
wowl_config |= BRCMF_WOWL_GTK_FAILURE;
}
if (!brcmf_test_bit_in_array(BRCMF_VIF_STATUS_CONNECTED, &ifp->vif->sme_state)) {
wowl_config |= BRCMF_WOWL_UNASSOC;
}
memcpy(&wowl_wakeind, "clear", 6);
brcmf_fil_iovar_data_set(ifp, "wowl_wakeind", &wowl_wakeind, sizeof(wowl_wakeind));
brcmf_fil_iovar_int_set(ifp, "wowl", wowl_config);
brcmf_fil_iovar_int_set(ifp, "wowl_activate", 1);
brcmf_bus_wowl_config(cfg->pub->bus_if, true);
cfg->wowl.active = true;
}
static zx_status_t brcmf_cfg80211_suspend(struct wiphy* wiphy, struct cfg80211_wowlan* wowl) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct net_device* ndev = cfg_to_ndev(cfg);
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_cfg80211_vif* vif;
brcmf_dbg(TRACE, "Enter\n");
/* if the primary net_device is not READY there is nothing
* we can do but pray resume goes smoothly.
*/
if (!check_vif_up(ifp->vif)) {
goto exit;
}
/* Stop scheduled scan */
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_PNO)) {
brcmf_cfg80211_sched_scan_stop(wiphy, ndev, 0);
}
/* end any scanning */
if (brcmf_test_bit_in_array(BRCMF_SCAN_STATUS_BUSY, &cfg->scan_status)) {
brcmf_abort_scanning(cfg);
}
if (wowl == NULL) {
brcmf_bus_wowl_config(cfg->pub->bus_if, false);
list_for_every_entry(&cfg->vif_list, vif, struct brcmf_cfg80211_vif, list) {
if (!brcmf_test_bit_in_array(BRCMF_VIF_STATUS_READY, &vif->sme_state)) {
continue;
}
/* While going to suspend if associated with AP
* disassociate from AP to save power while system is
* in suspended state
*/
brcmf_link_down(vif, WLAN_REASON_UNSPECIFIED);
/* Make sure WPA_Supplicant receives all the event
* generated due to DISASSOC call to the fw to keep
* the state fw and WPA_Supplicant state consistent
*/
msleep(500);
}
/* Configure MPC */
brcmf_set_mpc(ifp, 1);
} else {
/* Configure WOWL paramaters */
brcmf_configure_wowl(cfg, ifp, wowl);
}
exit:
brcmf_dbg(TRACE, "Exit\n");
/* clear any scanning activity */
atomic_store(&cfg->scan_status, 0);
return ZX_OK;
}
static __USED zx_status_t brcmf_update_pmklist(struct brcmf_cfg80211_info* cfg,
struct brcmf_if* ifp) {
struct brcmf_pmk_list_le* pmk_list;
int i;
uint32_t npmk;
zx_status_t err;
pmk_list = &cfg->pmk_list;
npmk = pmk_list->npmk;
brcmf_dbg(CONN, "No of elements %d\n", npmk);
for (i = 0; i < (int)npmk; i++) {
brcmf_dbg(CONN, "PMK[%d]: %pM\n", i, &pmk_list->pmk[i].bssid);
}
err = brcmf_fil_iovar_data_set(ifp, "pmkid_info", pmk_list, sizeof(*pmk_list));
return err;
}
static zx_status_t brcmf_cfg80211_set_pmksa(struct wiphy* wiphy, struct net_device* ndev,
struct cfg80211_pmksa* pmksa) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_pmksa* pmk = &cfg->pmk_list.pmk[0];
zx_status_t err;
uint32_t npmk, i;
brcmf_dbg(TRACE, "Enter\n");
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
npmk = cfg->pmk_list.npmk;
for (i = 0; i < npmk; i++)
if (!memcmp(pmksa->bssid, pmk[i].bssid, ETH_ALEN)) {
break;
}
if (i < BRCMF_MAXPMKID) {
memcpy(pmk[i].bssid, pmksa->bssid, ETH_ALEN);
memcpy(pmk[i].pmkid, pmksa->pmkid, WLAN_PMKID_LEN);
if (i == npmk) {
npmk++;
cfg->pmk_list.npmk = npmk;
}
} else {
brcmf_err("Too many PMKSA entries cached %d\n", npmk);
return ZX_ERR_NO_RESOURCES;
}
brcmf_dbg(CONN, "set_pmksa - PMK bssid: %pM =\n", pmk[npmk].bssid);
for (i = 0; i < WLAN_PMKID_LEN; i += 4)
brcmf_dbg(CONN, "%02x %02x %02x %02x\n", pmk[npmk].pmkid[i], pmk[npmk].pmkid[i + 1],
pmk[npmk].pmkid[i + 2], pmk[npmk].pmkid[i + 3]);
err = brcmf_update_pmklist(cfg, ifp);
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static zx_status_t brcmf_cfg80211_del_pmksa(struct wiphy* wiphy, struct net_device* ndev,
struct cfg80211_pmksa* pmksa) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_pmksa* pmk = &cfg->pmk_list.pmk[0];
zx_status_t err;
uint32_t npmk, i;
brcmf_dbg(TRACE, "Enter\n");
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
brcmf_dbg(CONN, "del_pmksa - PMK bssid = %pM\n", pmksa->bssid);
npmk = cfg->pmk_list.npmk;
for (i = 0; i < npmk; i++)
if (!memcmp(pmksa->bssid, pmk[i].bssid, ETH_ALEN)) {
break;
}
if ((npmk > 0) && (i < npmk)) {
for (; i < (npmk - 1); i++) {
memcpy(&pmk[i].bssid, &pmk[i + 1].bssid, ETH_ALEN);
memcpy(&pmk[i].pmkid, &pmk[i + 1].pmkid, WLAN_PMKID_LEN);
}
memset(&pmk[i], 0, sizeof(*pmk));
cfg->pmk_list.npmk = npmk - 1;
} else {
brcmf_err("Cache entry not found\n");
return ZX_ERR_BAD_STATE;
}
err = brcmf_update_pmklist(cfg, ifp);
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static zx_status_t brcmf_cfg80211_flush_pmksa(struct wiphy* wiphy, struct net_device* ndev) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_if* ifp = ndev_to_if(ndev);
zx_status_t err;
brcmf_dbg(TRACE, "Enter\n");
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
memset(&cfg->pmk_list, 0, sizeof(cfg->pmk_list));
err = brcmf_update_pmklist(cfg, ifp);
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static zx_status_t brcmf_configure_opensecurity(struct brcmf_if* ifp) {
zx_status_t err;
int32_t wpa_val;
/* set auth */
err = brcmf_fil_bsscfg_int_set(ifp, "auth", 0);
if (err != ZX_OK) {
brcmf_err("auth error %d\n", err);
return err;
}
/* set wsec */
err = brcmf_fil_bsscfg_int_set(ifp, "wsec", 0);
if (err != ZX_OK) {
brcmf_err("wsec error %d\n", err);
return err;
}
/* set upper-layer auth */
if (brcmf_is_ibssmode(ifp->vif)) {
wpa_val = WPA_AUTH_NONE;
} else {
wpa_val = WPA_AUTH_DISABLED;
}
err = brcmf_fil_bsscfg_int_set(ifp, "wpa_auth", wpa_val);
if (err != ZX_OK) {
brcmf_err("wpa_auth error %d\n", err);
return err;
}
return ZX_OK;
}
static bool brcmf_valid_wpa_oui(uint8_t* oui, bool is_rsn_ie) {
if (is_rsn_ie) {
return (memcmp(oui, RSN_OUI, TLV_OUI_LEN) == 0);
}
return (memcmp(oui, WPA_OUI, TLV_OUI_LEN) == 0);
}
static zx_status_t brcmf_configure_wpaie(struct brcmf_if* ifp, const struct brcmf_vs_tlv* wpa_ie,
bool is_rsn_ie) {
uint32_t auth = 0; /* d11 open authentication */
uint16_t count;
zx_status_t err = ZX_OK;
int32_t len;
uint32_t i;
uint32_t wsec;
uint32_t pval = 0;
uint32_t gval = 0;
uint32_t wpa_auth = 0;
uint32_t offset;
uint8_t* data;
uint16_t rsn_cap;
uint32_t wme_bss_disable;
uint32_t mfp;
brcmf_dbg(TRACE, "Enter\n");
if (wpa_ie == NULL) {
goto exit;
}
len = wpa_ie->len + TLV_HDR_LEN;
data = (uint8_t*)wpa_ie;
offset = TLV_HDR_LEN;
if (!is_rsn_ie) {
offset += VS_IE_FIXED_HDR_LEN;
} else {
offset += WPA_IE_VERSION_LEN;
}
/* check for multicast cipher suite */
if ((int32_t)offset + WPA_IE_MIN_OUI_LEN > len) {
err = ZX_ERR_INVALID_ARGS;
brcmf_err("no multicast cipher suite\n");
goto exit;
}
if (!brcmf_valid_wpa_oui(&data[offset], is_rsn_ie)) {
err = ZX_ERR_INVALID_ARGS;
brcmf_err("invalid OUI\n");
goto exit;
}
offset += TLV_OUI_LEN;
/* pick up multicast cipher */
switch (data[offset]) {
case WPA_CIPHER_NONE:
gval = 0;
break;
case WPA_CIPHER_WEP_40:
case WPA_CIPHER_WEP_104:
gval = WEP_ENABLED;
break;
case WPA_CIPHER_TKIP:
gval = TKIP_ENABLED;
break;
case WPA_CIPHER_AES_CCM:
gval = AES_ENABLED;
break;
default:
err = ZX_ERR_INVALID_ARGS;
brcmf_err("Invalid multi cast cipher info\n");
goto exit;
}
offset++;
/* walk thru unicast cipher list and pick up what we recognize */
count = data[offset] + (data[offset + 1] << 8);
offset += WPA_IE_SUITE_COUNT_LEN;
/* Check for unicast suite(s) */
if ((int32_t)(offset + (WPA_IE_MIN_OUI_LEN * count)) > len) {
err = ZX_ERR_INVALID_ARGS;
brcmf_err("no unicast cipher suite\n");
goto exit;
}
for (i = 0; i < count; i++) {
if (!brcmf_valid_wpa_oui(&data[offset], is_rsn_ie)) {
err = ZX_ERR_INVALID_ARGS;
brcmf_err("ivalid OUI\n");
goto exit;
}
offset += TLV_OUI_LEN;
switch (data[offset]) {
case WPA_CIPHER_NONE:
break;
case WPA_CIPHER_WEP_40:
case WPA_CIPHER_WEP_104:
pval |= WEP_ENABLED;
break;
case WPA_CIPHER_TKIP:
pval |= TKIP_ENABLED;
break;
case WPA_CIPHER_AES_CCM:
pval |= AES_ENABLED;
break;
default:
brcmf_err("Invalid unicast security info\n");
}
offset++;
}
/* walk thru auth management suite list and pick up what we recognize */
count = data[offset] + (data[offset + 1] << 8);
offset += WPA_IE_SUITE_COUNT_LEN;
/* Check for auth key management suite(s) */
if ((int32_t)(offset + (WPA_IE_MIN_OUI_LEN * count)) > len) {
err = ZX_ERR_INVALID_ARGS;
brcmf_err("no auth key mgmt suite\n");
goto exit;
}
for (i = 0; i < count; i++) {
if (!brcmf_valid_wpa_oui(&data[offset], is_rsn_ie)) {
err = ZX_ERR_INVALID_ARGS;
brcmf_err("ivalid OUI\n");
goto exit;
}
offset += TLV_OUI_LEN;
switch (data[offset]) {
case RSN_AKM_NONE:
brcmf_dbg(TRACE, "RSN_AKM_NONE\n");
wpa_auth |= WPA_AUTH_NONE;
break;
case RSN_AKM_UNSPECIFIED:
brcmf_dbg(TRACE, "RSN_AKM_UNSPECIFIED\n");
is_rsn_ie ? (wpa_auth |= WPA2_AUTH_UNSPECIFIED) : (wpa_auth |= WPA_AUTH_UNSPECIFIED);
break;
case RSN_AKM_PSK:
brcmf_dbg(TRACE, "RSN_AKM_PSK\n");
is_rsn_ie ? (wpa_auth |= WPA2_AUTH_PSK) : (wpa_auth |= WPA_AUTH_PSK);
break;
case RSN_AKM_SHA256_PSK:
brcmf_dbg(TRACE, "RSN_AKM_MFP_PSK\n");
wpa_auth |= WPA2_AUTH_PSK_SHA256;
break;
case RSN_AKM_SHA256_1X:
brcmf_dbg(TRACE, "RSN_AKM_MFP_1X\n");
wpa_auth |= WPA2_AUTH_1X_SHA256;
break;
default:
brcmf_err("Invalid key mgmt info\n");
}
offset++;
}
mfp = BRCMF_MFP_NONE;
if (is_rsn_ie) {
wme_bss_disable = 1;
if (((int32_t)offset + RSN_CAP_LEN) <= len) {
rsn_cap = data[offset] + (data[offset + 1] << 8);
if (rsn_cap & RSN_CAP_PTK_REPLAY_CNTR_MASK) {
wme_bss_disable = 0;
}
if (rsn_cap & RSN_CAP_MFPR_MASK) {
brcmf_dbg(TRACE, "MFP Required\n");
mfp = BRCMF_MFP_REQUIRED;
/* Firmware only supports mfp required in
* combination with WPA2_AUTH_PSK_SHA256 or
* WPA2_AUTH_1X_SHA256.
*/
if (!(wpa_auth & (WPA2_AUTH_PSK_SHA256 | WPA2_AUTH_1X_SHA256))) {
err = ZX_ERR_INVALID_ARGS;
goto exit;
}
/* Firmware has requirement that WPA2_AUTH_PSK/
* WPA2_AUTH_UNSPECIFIED be set, if SHA256 OUI
* is to be included in the rsn ie.
*/
if (wpa_auth & WPA2_AUTH_PSK_SHA256) {
wpa_auth |= WPA2_AUTH_PSK;
} else if (wpa_auth & WPA2_AUTH_1X_SHA256) {
wpa_auth |= WPA2_AUTH_UNSPECIFIED;
}
} else if (rsn_cap & RSN_CAP_MFPC_MASK) {
brcmf_dbg(TRACE, "MFP Capable\n");
mfp = BRCMF_MFP_CAPABLE;
}
}
offset += RSN_CAP_LEN;
/* set wme_bss_disable to sync RSN Capabilities */
err = brcmf_fil_bsscfg_int_set(ifp, "wme_bss_disable", wme_bss_disable);
if (err != ZX_OK) {
brcmf_err("wme_bss_disable error %d\n", err);
goto exit;
}
/* Skip PMKID cnt as it is know to be 0 for AP. */
offset += RSN_PMKID_COUNT_LEN;
/* See if there is BIP wpa suite left for MFP */
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_MFP) &&
((int32_t)(offset + WPA_IE_MIN_OUI_LEN) <= len)) {
err = brcmf_fil_bsscfg_data_set(ifp, "bip", &data[offset], WPA_IE_MIN_OUI_LEN);
if (err != ZX_OK) {
brcmf_err("bip error %d\n", err);
goto exit;
}
}
}
/* FOR WPS , set SES_OW_ENABLED */
wsec = (pval | gval | SES_OW_ENABLED);
/* set auth */
err = brcmf_fil_bsscfg_int_set(ifp, "auth", auth);
if (err != ZX_OK) {
brcmf_err("auth error %d\n", err);
goto exit;
}
/* set wsec */
err = brcmf_fil_bsscfg_int_set(ifp, "wsec", wsec);
if (err != ZX_OK) {
brcmf_err("wsec error %d\n", err);
goto exit;
}
/* Configure MFP, this needs to go after wsec otherwise the wsec command
* will overwrite the values set by MFP
*/
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_MFP)) {
err = brcmf_fil_bsscfg_int_set(ifp, "mfp", mfp);
if (err != ZX_OK) {
brcmf_err("mfp error %d\n", err);
goto exit;
}
}
/* set upper-layer auth */
err = brcmf_fil_bsscfg_int_set(ifp, "wpa_auth", wpa_auth);
if (err != ZX_OK) {
brcmf_err("wpa_auth error %d\n", err);
goto exit;
}
exit:
return err;
}
static zx_status_t brcmf_parse_vndr_ies(const uint8_t* vndr_ie_buf, uint32_t vndr_ie_len,
struct parsed_vndr_ies* vndr_ies) {
struct brcmf_vs_tlv* vndrie;
struct brcmf_tlv* ie;
struct parsed_vndr_ie_info* parsed_info;
int32_t remaining_len;
remaining_len = (int32_t)vndr_ie_len;
memset(vndr_ies, 0, sizeof(*vndr_ies));
ie = (struct brcmf_tlv*)vndr_ie_buf;
while (ie) {
if (ie->id != WLAN_EID_VENDOR_SPECIFIC) {
goto next;
}
vndrie = (struct brcmf_vs_tlv*)ie;
/* len should be bigger than OUI length + one */
if (vndrie->len < (VS_IE_FIXED_HDR_LEN - TLV_HDR_LEN + 1)) {
brcmf_err("invalid vndr ie. length is too small %d\n", vndrie->len);
goto next;
}
/* if wpa or wme ie, do not add ie */
if (!memcmp(vndrie->oui, (uint8_t*)WPA_OUI, TLV_OUI_LEN) &&
((vndrie->oui_type == WPA_OUI_TYPE) || (vndrie->oui_type == WME_OUI_TYPE))) {
brcmf_dbg(TRACE, "Found WPA/WME oui. Do not add it\n");
goto next;
}
parsed_info = &vndr_ies->ie_info[vndr_ies->count];
/* save vndr ie information */
parsed_info->ie_ptr = (uint8_t*)vndrie;
parsed_info->ie_len = vndrie->len + TLV_HDR_LEN;
memcpy(&parsed_info->vndrie, vndrie, sizeof(*vndrie));
vndr_ies->count++;
brcmf_dbg(TRACE, "** OUI %02x %02x %02x, type 0x%02x\n", parsed_info->vndrie.oui[0],
parsed_info->vndrie.oui[1], parsed_info->vndrie.oui[2],
parsed_info->vndrie.oui_type);
if (vndr_ies->count >= VNDR_IE_PARSE_LIMIT) {
break;
}
next:
remaining_len -= (ie->len + TLV_HDR_LEN);
if (remaining_len <= TLV_HDR_LEN) {
ie = NULL;
} else {
ie = (struct brcmf_tlv*)(((uint8_t*)ie) + ie->len + TLV_HDR_LEN);
}
}
return ZX_OK;
}
static uint32_t brcmf_vndr_ie(uint8_t* iebuf, int32_t pktflag, uint8_t* ie_ptr, uint32_t ie_len,
int8_t* add_del_cmd) {
strncpy((char*)iebuf, (char*)add_del_cmd, VNDR_IE_CMD_LEN - 1);
iebuf[VNDR_IE_CMD_LEN - 1] = '\0';
*(uint32_t*)&iebuf[VNDR_IE_COUNT_OFFSET] = 1;
*(uint32_t*)&iebuf[VNDR_IE_PKTFLAG_OFFSET] = pktflag;
memcpy(&iebuf[VNDR_IE_VSIE_OFFSET], ie_ptr, ie_len);
return ie_len + VNDR_IE_HDR_SIZE;
}
zx_status_t brcmf_vif_set_mgmt_ie(struct brcmf_cfg80211_vif* vif, int32_t pktflag,
const uint8_t* vndr_ie_buf, uint32_t vndr_ie_len) {
struct brcmf_if* ifp;
struct vif_saved_ie* saved_ie;
zx_status_t err = ZX_OK;
uint8_t* iovar_ie_buf;
uint8_t* curr_ie_buf;
uint8_t* mgmt_ie_buf = NULL;
int mgmt_ie_buf_len;
uint32_t* mgmt_ie_len;
uint32_t del_add_ie_buf_len = 0;
uint32_t total_ie_buf_len = 0;
uint32_t parsed_ie_buf_len = 0;
struct parsed_vndr_ies old_vndr_ies;
struct parsed_vndr_ies new_vndr_ies;
struct parsed_vndr_ie_info* vndrie_info;
int32_t i;
uint8_t* ptr;
int remained_buf_len;
if (!vif) {
return ZX_ERR_IO_NOT_PRESENT;
}
ifp = vif->ifp;
saved_ie = &vif->saved_ie;
brcmf_dbg(TRACE, "bsscfgidx %d, pktflag : 0x%02X\n", ifp->bsscfgidx, pktflag);
iovar_ie_buf = calloc(1, WL_EXTRA_BUF_MAX);
if (!iovar_ie_buf) {
return ZX_ERR_NO_MEMORY;
}
curr_ie_buf = iovar_ie_buf;
switch (pktflag) {
case BRCMF_VNDR_IE_PRBREQ_FLAG:
mgmt_ie_buf = saved_ie->probe_req_ie;
mgmt_ie_len = &saved_ie->probe_req_ie_len;
mgmt_ie_buf_len = sizeof(saved_ie->probe_req_ie);
break;
case BRCMF_VNDR_IE_PRBRSP_FLAG:
mgmt_ie_buf = saved_ie->probe_res_ie;
mgmt_ie_len = &saved_ie->probe_res_ie_len;
mgmt_ie_buf_len = sizeof(saved_ie->probe_res_ie);
break;
case BRCMF_VNDR_IE_BEACON_FLAG:
mgmt_ie_buf = saved_ie->beacon_ie;
mgmt_ie_len = &saved_ie->beacon_ie_len;
mgmt_ie_buf_len = sizeof(saved_ie->beacon_ie);
break;
case BRCMF_VNDR_IE_ASSOCREQ_FLAG:
mgmt_ie_buf = saved_ie->assoc_req_ie;
mgmt_ie_len = &saved_ie->assoc_req_ie_len;
mgmt_ie_buf_len = sizeof(saved_ie->assoc_req_ie);
break;
default:
err = ZX_ERR_WRONG_TYPE;
brcmf_err("not suitable type\n");
goto exit;
}
if ((int)vndr_ie_len > mgmt_ie_buf_len) {
err = ZX_ERR_NO_MEMORY;
brcmf_err("extra IE size too big\n");
goto exit;
}
/* parse and save new vndr_ie in curr_ie_buff before comparing it */
if (vndr_ie_buf && vndr_ie_len && curr_ie_buf) {
ptr = curr_ie_buf;
brcmf_parse_vndr_ies(vndr_ie_buf, vndr_ie_len, &new_vndr_ies);
for (i = 0; i < (int32_t)new_vndr_ies.count; i++) {
vndrie_info = &new_vndr_ies.ie_info[i];
memcpy(ptr + parsed_ie_buf_len, vndrie_info->ie_ptr, vndrie_info->ie_len);
parsed_ie_buf_len += vndrie_info->ie_len;
}
}
if (mgmt_ie_buf && *mgmt_ie_len) {
if (parsed_ie_buf_len && (parsed_ie_buf_len == *mgmt_ie_len) &&
(memcmp(mgmt_ie_buf, curr_ie_buf, parsed_ie_buf_len) == 0)) {
brcmf_dbg(TRACE, "Previous mgmt IE equals to current IE\n");
goto exit;
}
/* parse old vndr_ie */
brcmf_parse_vndr_ies(mgmt_ie_buf, *mgmt_ie_len, &old_vndr_ies);
/* make a command to delete old ie */
for (i = 0; i < (int32_t)old_vndr_ies.count; i++) {
vndrie_info = &old_vndr_ies.ie_info[i];
brcmf_dbg(TRACE, "DEL ID : %d, Len: %d , OUI:%02x:%02x:%02x\n", vndrie_info->vndrie.id,
vndrie_info->vndrie.len, vndrie_info->vndrie.oui[0],
vndrie_info->vndrie.oui[1], vndrie_info->vndrie.oui[2]);
del_add_ie_buf_len = brcmf_vndr_ie(curr_ie_buf, pktflag, vndrie_info->ie_ptr,
vndrie_info->ie_len, (int8_t*)"del");
curr_ie_buf += del_add_ie_buf_len;
total_ie_buf_len += del_add_ie_buf_len;
}
}
*mgmt_ie_len = 0;
/* Add if there is any extra IE */
if (mgmt_ie_buf && parsed_ie_buf_len) {
ptr = mgmt_ie_buf;
remained_buf_len = mgmt_ie_buf_len;
/* make a command to add new ie */
for (i = 0; i < (int32_t)new_vndr_ies.count; i++) {
vndrie_info = &new_vndr_ies.ie_info[i];
/* verify remained buf size before copy data */
if (remained_buf_len < (vndrie_info->vndrie.len + VNDR_IE_VSIE_OFFSET)) {
brcmf_err("no space in mgmt_ie_buf: len left %d", remained_buf_len);
break;
}
remained_buf_len -= (vndrie_info->ie_len + VNDR_IE_VSIE_OFFSET);
brcmf_dbg(TRACE, "ADDED ID : %d, Len: %d, OUI:%02x:%02x:%02x\n", vndrie_info->vndrie.id,
vndrie_info->vndrie.len, vndrie_info->vndrie.oui[0],
vndrie_info->vndrie.oui[1], vndrie_info->vndrie.oui[2]);
del_add_ie_buf_len = brcmf_vndr_ie(curr_ie_buf, pktflag, vndrie_info->ie_ptr,
vndrie_info->ie_len, (int8_t*)"add");
/* save the parsed IE in wl struct */
memcpy(ptr + (*mgmt_ie_len), vndrie_info->ie_ptr, vndrie_info->ie_len);
*mgmt_ie_len += vndrie_info->ie_len;
curr_ie_buf += del_add_ie_buf_len;
total_ie_buf_len += del_add_ie_buf_len;
}
}
if (total_ie_buf_len) {
err = brcmf_fil_bsscfg_data_set(ifp, "vndr_ie", iovar_ie_buf, total_ie_buf_len);
if (err != ZX_OK) {
brcmf_err("vndr ie set error : %d\n", err);
}
}
exit:
free(iovar_ie_buf);
return err;
}
zx_status_t brcmf_vif_clear_mgmt_ies(struct brcmf_cfg80211_vif* vif) {
int32_t pktflags[] = {
BRCMF_VNDR_IE_PRBREQ_FLAG,
BRCMF_VNDR_IE_PRBRSP_FLAG,
BRCMF_VNDR_IE_BEACON_FLAG
};
int i;
for (i = 0; i < (int)ARRAY_SIZE(pktflags); i++) {
brcmf_vif_set_mgmt_ie(vif, pktflags[i], NULL, 0);
}
memset(&vif->saved_ie, 0, sizeof(vif->saved_ie));
return ZX_OK;
}
static zx_status_t brcmf_config_ap_mgmt_ie(struct brcmf_cfg80211_vif* vif,
struct cfg80211_beacon_data* beacon) {
zx_status_t err;
/* Set Beacon IEs to FW */
err = brcmf_vif_set_mgmt_ie(vif, BRCMF_VNDR_IE_BEACON_FLAG, beacon->tail, beacon->tail_len);
if (err != ZX_OK) {
brcmf_err("Set Beacon IE Failed\n");
return err;
}
brcmf_dbg(TRACE, "Applied Vndr IEs for Beacon\n");
/* Set Probe Response IEs to FW */
err = brcmf_vif_set_mgmt_ie(vif, BRCMF_VNDR_IE_PRBRSP_FLAG, beacon->proberesp_ies,
beacon->proberesp_ies_len);
if (err != ZX_OK) {
brcmf_err("Set Probe Resp IE Failed\n");
} else {
brcmf_dbg(TRACE, "Applied Vndr IEs for Probe Resp\n");
}
return err;
}
static zx_status_t brcmf_cfg80211_start_ap(struct wiphy* wiphy, struct net_device* ndev,
struct cfg80211_ap_settings* settings) {
int32_t ie_offset;
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_if* ifp = ndev_to_if(ndev);
const struct brcmf_tlv* ssid_ie;
const struct brcmf_tlv* country_ie;
struct brcmf_ssid_le ssid_le;
int32_t err = ZX_ERR_WRONG_TYPE;
const struct brcmf_tlv* rsn_ie;
const struct brcmf_vs_tlv* wpa_ie;
struct brcmf_join_params join_params;
enum nl80211_iftype dev_role;
struct brcmf_fil_bss_enable_le bss_enable;
uint16_t chanspec = chandef_to_chanspec(&cfg->d11inf, &settings->chandef);
bool mbss;
int is_11d;
bool supports_11d;
brcmf_dbg(TRACE, "ctrlchn=%d, center=%d, bw=%d, beacon_interval=%d, dtim_period=%d,\n",
settings->chandef.chan->hw_value, settings->chandef.center_freq1,
settings->chandef.width, settings->beacon_interval, settings->dtim_period);
brcmf_dbg(TRACE, "ssid=%s(%zu), auth_type=%d, inactivity_timeout=%d\n", settings->ssid,
settings->ssid_len, settings->auth_type, settings->inactivity_timeout);
dev_role = ifp->vif->wdev.iftype;
mbss = ifp->vif->mbss;
/* store current 11d setting */
if (brcmf_fil_cmd_int_get(ifp, BRCMF_C_GET_REGULATORY, (uint32_t*)&ifp->vif->is_11d) != ZX_OK) {
is_11d = supports_11d = false;
} else {
country_ie = brcmf_parse_tlvs((uint8_t*)settings->beacon.tail, settings->beacon.tail_len,
WLAN_EID_COUNTRY);
is_11d = country_ie ? 1 : 0;
supports_11d = true;
}
memset(&ssid_le, 0, sizeof(ssid_le));
if (settings->ssid == NULL || settings->ssid_len == 0) {
ie_offset = DOT11_MGMT_HDR_LEN + DOT11_BCN_PRB_FIXED_LEN;
ssid_ie = brcmf_parse_tlvs((uint8_t*)&settings->beacon.head[ie_offset],
settings->beacon.head_len - ie_offset, WLAN_EID_SSID);
if (!ssid_ie || ssid_ie->len > IEEE80211_MAX_SSID_LEN) {
return ZX_ERR_INVALID_ARGS;
}
memcpy(ssid_le.SSID, ssid_ie->data, ssid_ie->len);
ssid_le.SSID_len = ssid_ie->len;
brcmf_dbg(TRACE, "SSID is (%s) in Head\n", ssid_le.SSID);
} else {
memcpy(ssid_le.SSID, settings->ssid, settings->ssid_len);
ssid_le.SSID_len = (uint32_t)settings->ssid_len;
}
if (!mbss) {
brcmf_set_mpc(ifp, 0);
brcmf_configure_arp_nd_offload(ifp, false);
}
/* find the RSN_IE */
rsn_ie = brcmf_parse_tlvs((uint8_t*)settings->beacon.tail, settings->beacon.tail_len,
WLAN_EID_RSN);
/* find the WPA_IE */
wpa_ie = brcmf_find_wpaie((uint8_t*)settings->beacon.tail, settings->beacon.tail_len);
if ((wpa_ie != NULL || rsn_ie != NULL)) {
brcmf_dbg(TRACE, "WPA(2) IE is found\n");
if (wpa_ie != NULL) {
/* WPA IE */
err = brcmf_configure_wpaie(ifp, wpa_ie, false);
if (err != ZX_OK) {
goto exit;
}
} else {
struct brcmf_vs_tlv* tmp_ie;
tmp_ie = (struct brcmf_vs_tlv*)rsn_ie;
/* RSN IE */
err = brcmf_configure_wpaie(ifp, tmp_ie, true);
if (err != ZX_OK) {
goto exit;
}
}
} else {
brcmf_dbg(TRACE, "No WPA(2) IEs found\n");
brcmf_configure_opensecurity(ifp);
}
/* Parameters shared by all radio interfaces */
if (!mbss) {
if ((supports_11d) && (is_11d != ifp->vif->is_11d)) {
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_REGULATORY, is_11d);
if (err != ZX_OK) {
brcmf_err("Regulatory Set Error, %d\n", err);
goto exit;
}
}
if (settings->beacon_interval) {
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_BCNPRD, settings->beacon_interval);
if (err != ZX_OK) {
brcmf_err("Beacon Interval Set Error, %d\n", err);
goto exit;
}
}
if (settings->dtim_period) {
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_DTIMPRD, settings->dtim_period);
if (err != ZX_OK) {
brcmf_err("DTIM Interval Set Error, %d\n", err);
goto exit;
}
}
if ((dev_role == NL80211_IFTYPE_AP) &&
((ifp->ifidx == 0) || !brcmf_feat_is_enabled(ifp, BRCMF_FEAT_RSDB))) {
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_DOWN, 1);
if (err != ZX_OK) {
brcmf_err("BRCMF_C_DOWN error %d\n", err);
goto exit;
}
brcmf_fil_iovar_int_set(ifp, "apsta", 0);
}
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_INFRA, 1);
if (err != ZX_OK) {
brcmf_err("SET INFRA error %d\n", err);
goto exit;
}
} else if (WARN_ON(supports_11d && (is_11d != ifp->vif->is_11d))) {
/* Multiple-BSS should use same 11d configuration */
err = ZX_ERR_INVALID_ARGS;
goto exit;
}
/* Interface specific setup */
if (dev_role == NL80211_IFTYPE_AP) {
if ((brcmf_feat_is_enabled(ifp, BRCMF_FEAT_MBSS)) && (!mbss)) {
brcmf_fil_iovar_int_set(ifp, "mbss", 1);
}
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_AP, 1);
if (err != ZX_OK) {
brcmf_err("setting AP mode failed %d\n", err);
goto exit;
}
if (!mbss) {
/* Firmware 10.x requires setting channel after enabling
* AP and before bringing interface up.
*/
err = brcmf_fil_iovar_int_set(ifp, "chanspec", chanspec);
if (err != ZX_OK) {
brcmf_err("Set Channel failed: chspec=%d, %d\n", chanspec, err);
goto exit;
}
}
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_UP, 1);
if (err != ZX_OK) {
brcmf_err("BRCMF_C_UP error (%d)\n", err);
goto exit;
}
/* On DOWN the firmware removes the WEP keys, reconfigure
* them if they were set.
*/
brcmf_cfg80211_reconfigure_wep(ifp);
memset(&join_params, 0, sizeof(join_params));
/* join parameters starts with ssid */
memcpy(&join_params.ssid_le, &ssid_le, sizeof(ssid_le));
/* create softap */
err = brcmf_fil_cmd_data_set(ifp, BRCMF_C_SET_SSID, &join_params, sizeof(join_params));
if (err != ZX_OK) {
brcmf_err("SET SSID error (%d)\n", err);
goto exit;
}
if (settings->hidden_ssid) {
err = brcmf_fil_iovar_int_set(ifp, "closednet", 1);
if (err != ZX_OK) {
brcmf_err("closednet error (%d)\n", err);
goto exit;
}
}
brcmf_dbg(TRACE, "AP mode configuration complete\n");
} else if (dev_role == NL80211_IFTYPE_P2P_GO) {
err = brcmf_fil_iovar_int_set(ifp, "chanspec", chanspec);
if (err != ZX_OK) {
brcmf_err("Set Channel failed: chspec=%d, %d\n", chanspec, err);
goto exit;
}
err = brcmf_fil_bsscfg_data_set(ifp, "ssid", &ssid_le, sizeof(ssid_le));
if (err != ZX_OK) {
brcmf_err("setting ssid failed %d\n", err);
goto exit;
}
bss_enable.bsscfgidx = ifp->bsscfgidx;
bss_enable.enable = 1;
err = brcmf_fil_iovar_data_set(ifp, "bss", &bss_enable, sizeof(bss_enable));
if (err != ZX_OK) {
brcmf_err("bss_enable config failed %d\n", err);
goto exit;
}
brcmf_dbg(TRACE, "GO mode configuration complete\n");
} else {
WARN_ON(1);
}
brcmf_config_ap_mgmt_ie(ifp->vif, &settings->beacon);
brcmf_set_bit_in_array(BRCMF_VIF_STATUS_AP_CREATED, &ifp->vif->sme_state);
brcmf_net_setcarrier(ifp, true);
exit:
if ((err != ZX_OK) && (!mbss)) {
brcmf_set_mpc(ifp, 1);
brcmf_configure_arp_nd_offload(ifp, true);
}
return err;
}
static zx_status_t brcmf_cfg80211_stop_ap(struct wiphy* wiphy, struct net_device* ndev) {
struct brcmf_if* ifp = ndev_to_if(ndev);
zx_status_t err;
struct brcmf_fil_bss_enable_le bss_enable;
struct brcmf_join_params join_params;
brcmf_dbg(TRACE, "Enter\n");
if (ifp->vif->wdev.iftype == NL80211_IFTYPE_AP) {
/* Due to most likely deauths outstanding we sleep */
/* first to make sure they get processed by fw. */
msleep(400);
if (ifp->vif->mbss) {
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_DOWN, 1);
return err;
}
/* First BSS doesn't get a full reset */
if (ifp->bsscfgidx == 0) {
brcmf_fil_iovar_int_set(ifp, "closednet", 0);
}
memset(&join_params, 0, sizeof(join_params));
err = brcmf_fil_cmd_data_set(ifp, BRCMF_C_SET_SSID, &join_params, sizeof(join_params));
if (err != ZX_OK) {
brcmf_err("SET SSID error (%d)\n", err);
}
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_DOWN, 1);
if (err != ZX_OK) {
brcmf_err("BRCMF_C_DOWN error %d\n", err);
}
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_AP, 0);
if (err != ZX_OK) {
brcmf_err("setting AP mode failed %d\n", err);
}
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_MBSS)) {
brcmf_fil_iovar_int_set(ifp, "mbss", 0);
}
brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_REGULATORY, ifp->vif->is_11d);
/* Bring device back up so it can be used again */
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_UP, 1);
if (err != ZX_OK) {
brcmf_err("BRCMF_C_UP error %d\n", err);
}
brcmf_vif_clear_mgmt_ies(ifp->vif);
} else {
bss_enable.bsscfgidx = ifp->bsscfgidx;
bss_enable.enable = 0;
err = brcmf_fil_iovar_data_set(ifp, "bss", &bss_enable, sizeof(bss_enable));
if (err != ZX_OK) {
brcmf_err("bss_enable config failed %d\n", err);
}
}
brcmf_set_mpc(ifp, 1);
brcmf_configure_arp_nd_offload(ifp, true);
brcmf_clear_bit_in_array(BRCMF_VIF_STATUS_AP_CREATED, &ifp->vif->sme_state);
brcmf_net_setcarrier(ifp, false);
return err;
}
static zx_status_t brcmf_cfg80211_change_beacon(struct wiphy* wiphy, struct net_device* ndev,
struct cfg80211_beacon_data* info) {
struct brcmf_if* ifp = ndev_to_if(ndev);
zx_status_t err;
brcmf_dbg(TRACE, "Enter\n");
err = brcmf_config_ap_mgmt_ie(ifp->vif, info);
return err;
}
static zx_status_t brcmf_cfg80211_del_station(struct wiphy* wiphy, struct net_device* ndev,
struct station_del_parameters* params) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_scb_val_le scbval;
struct brcmf_if* ifp = ndev_to_if(ndev);
zx_status_t err;
if (!params->mac) {
return ZX_ERR_IO_NOT_PRESENT;
}
brcmf_dbg(TRACE, "Enter %pM\n", params->mac);
if (ifp->vif == cfg->p2p.bss_idx[P2PAPI_BSSCFG_DEVICE].vif) {
ifp = cfg->p2p.bss_idx[P2PAPI_BSSCFG_PRIMARY].vif->ifp;
}
if (!check_vif_up(ifp->vif)) {
return ZX_ERR_IO;
}
memcpy(&scbval.ea, params->mac, ETH_ALEN);
scbval.val = params->reason_code;
err =
brcmf_fil_cmd_data_set(ifp, BRCMF_C_SCB_DEAUTHENTICATE_FOR_REASON, &scbval, sizeof(scbval));
if (err != ZX_OK) {
brcmf_err("SCB_DEAUTHENTICATE_FOR_REASON failed %d\n", err);
}
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static zx_status_t brcmf_cfg80211_change_station(struct wiphy* wiphy, struct net_device* ndev,
const uint8_t* mac,
struct station_parameters* params) {
struct brcmf_if* ifp = ndev_to_if(ndev);
zx_status_t err;
brcmf_dbg(TRACE, "Enter, MAC %pM, mask 0x%04x set 0x%04x\n", mac, params->sta_flags_mask,
params->sta_flags_set);
/* Ignore all 00 MAC */
if (address_is_zero(mac)) {
return ZX_OK;
}
if (!(params->sta_flags_mask & BIT(NL80211_STA_FLAG_AUTHORIZED))) {
return ZX_OK;
}
if (params->sta_flags_set & BIT(NL80211_STA_FLAG_AUTHORIZED)) {
err = brcmf_fil_cmd_data_set(ifp, BRCMF_C_SET_SCB_AUTHORIZE, (void*)mac, ETH_ALEN);
} else {
err = brcmf_fil_cmd_data_set(ifp, BRCMF_C_SET_SCB_DEAUTHORIZE, (void*)mac, ETH_ALEN);
}
if (err != ZX_OK) {
brcmf_err("Setting SCB (de-)authorize failed, %d\n", err);
}
return err;
}
static void brcmf_cfg80211_mgmt_frame_register(struct wiphy* wiphy, struct wireless_dev* wdev,
uint16_t frame_type, bool reg) {
struct brcmf_cfg80211_vif* vif;
uint16_t mgmt_type;
brcmf_dbg(TRACE, "Enter, frame_type %04x, reg=%d\n", frame_type, reg);
mgmt_type = (frame_type & IEEE80211_FCTL_STYPE) >> 4;
vif = containerof(wdev, struct brcmf_cfg80211_vif, wdev);
if (reg) {
vif->mgmt_rx_reg |= BIT(mgmt_type);
} else {
vif->mgmt_rx_reg &= ~BIT(mgmt_type);
}
}
static zx_status_t brcmf_cfg80211_mgmt_tx(struct wiphy* wiphy, struct wireless_dev* wdev,
struct cfg80211_mgmt_tx_params* params,
uint64_t* cookie) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct ieee80211_channel* chan = params->chan;
const uint8_t* buf = params->buf;
size_t len = params->len;
const struct ieee80211_mgmt* mgmt;
struct brcmf_cfg80211_vif* vif;
zx_status_t err = ZX_OK;
int32_t ie_offset;
int32_t ie_len;
struct brcmf_fil_action_frame_le* action_frame;
struct brcmf_fil_af_params_le* af_params;
bool ack;
int32_t chan_nr;
uint32_t freq;
brcmf_dbg(TRACE, "Enter\n");
*cookie = 0;
mgmt = (const struct ieee80211_mgmt*)buf;
if (!ieee80211_is_mgmt(mgmt->frame_control)) {
brcmf_err("Driver only allows MGMT packet type\n");
return ZX_ERR_WRONG_TYPE;
}
vif = containerof(wdev, struct brcmf_cfg80211_vif, wdev);
if (ieee80211_is_probe_resp(mgmt->frame_control)) {
/* Right now the only reason to get a probe response */
/* is for p2p listen response or for p2p GO from */
/* wpa_supplicant. Unfortunately the probe is send */
/* on primary ndev, while dongle wants it on the p2p */
/* vif. Since this is only reason for a probe */
/* response to be sent, the vif is taken from cfg. */
/* If ever desired to send proberesp for non p2p */
/* response then data should be checked for */
/* "DIRECT-". Note in future supplicant will take */
/* dedicated p2p wdev to do this and then this 'hack'*/
/* is not needed anymore. */
ie_offset = DOT11_MGMT_HDR_LEN + DOT11_BCN_PRB_FIXED_LEN;
ie_len = len - ie_offset;
if (vif == cfg->p2p.bss_idx[P2PAPI_BSSCFG_PRIMARY].vif) {
vif = cfg->p2p.bss_idx[P2PAPI_BSSCFG_DEVICE].vif;
}
err = brcmf_vif_set_mgmt_ie(vif, BRCMF_VNDR_IE_PRBRSP_FLAG, &buf[ie_offset], ie_len);
cfg80211_mgmt_tx_status(wdev, *cookie, buf, len, true);
} else if (ieee80211_is_action(mgmt->frame_control)) {
if (len > BRCMF_FIL_ACTION_FRAME_SIZE + DOT11_MGMT_HDR_LEN) {
brcmf_err("invalid action frame length\n");
err = ZX_ERR_INVALID_ARGS;
goto exit;
}
af_params = calloc(1, sizeof(*af_params));
if (af_params == NULL) {
brcmf_err("unable to allocate frame\n");
err = ZX_ERR_NO_MEMORY;
goto exit;
}
action_frame = &af_params->action_frame;
/* Add the packet Id */
action_frame->packet_id = *cookie;
/* Add BSSID */
memcpy(&action_frame->da[0], &mgmt->da[0], ETH_ALEN);
memcpy(&af_params->bssid[0], &mgmt->bssid[0], ETH_ALEN);
/* Add the length exepted for 802.11 header */
action_frame->len = len - DOT11_MGMT_HDR_LEN;
/* Add the channel. Use the one specified as parameter if any or
* the current one (got from the firmware) otherwise
*/
if (chan) {
freq = chan->center_freq;
} else {
brcmf_fil_cmd_int_get(vif->ifp, BRCMF_C_GET_CHANNEL, &freq);
}
chan_nr = ieee80211_frequency_to_channel(freq);
af_params->channel = chan_nr;
memcpy(action_frame->data, &buf[DOT11_MGMT_HDR_LEN], action_frame->len);
brcmf_dbg(TRACE, "Action frame, cookie=%ld, len=%d, freq=%d\n", *cookie,
action_frame->len, freq);
ack = brcmf_p2p_send_action_frame(cfg, cfg_to_ndev(cfg), af_params);
cfg80211_mgmt_tx_status(wdev, *cookie, buf, len, ack);
free(af_params);
} else {
brcmf_dbg(TRACE, "Unhandled, fc=%04x!!\n", mgmt->frame_control);
brcmf_dbg_hex_dump(true, buf, len, "payload, len=%zu\n", len);
}
exit:
return err;
}
static zx_status_t brcmf_cfg80211_cancel_remain_on_channel(struct wiphy* wiphy,
struct wireless_dev* wdev,
uint64_t cookie) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_cfg80211_vif* vif;
zx_status_t err = ZX_OK;
brcmf_dbg(TRACE, "Enter p2p listen cancel\n");
vif = cfg->p2p.bss_idx[P2PAPI_BSSCFG_DEVICE].vif;
if (vif == NULL) {
brcmf_err("No p2p device available for probe response\n");
err = ZX_ERR_IO_NOT_PRESENT;
goto exit;
}
brcmf_p2p_cancel_remain_on_channel(vif->ifp);
exit:
return err;
}
static zx_status_t brcmf_cfg80211_get_channel(struct wiphy* wiphy, struct wireless_dev* wdev,
struct cfg80211_chan_def* chandef) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct net_device* ndev = wdev->netdev;
struct brcmf_if* ifp;
struct brcmu_chan ch;
enum nl80211_band band = 0; // TODO(cphoenix): init to the right enum value
enum nl80211_chan_width width = 0; // TODO(cphoenix): init to the right enum value
uint32_t chanspec;
int freq;
zx_status_t err;
if (!ndev) {
return ZX_ERR_IO_NOT_PRESENT;
}
ifp = ndev_to_if(ndev);
err = brcmf_fil_iovar_int_get(ifp, "chanspec", &chanspec);
if (err != ZX_OK) {
brcmf_err("chanspec failed (%d)\n", err);
return err;
}
ch.chspec = chanspec;
cfg->d11inf.decchspec(&ch);
switch (ch.band) {
case BRCMU_CHAN_BAND_2G:
band = NL80211_BAND_2GHZ;
break;
case BRCMU_CHAN_BAND_5G:
band = NL80211_BAND_5GHZ;
break;
}
switch (ch.bw) {
case BRCMU_CHAN_BW_80:
width = NL80211_CHAN_WIDTH_80;
break;
case BRCMU_CHAN_BW_40:
width = NL80211_CHAN_WIDTH_40;
break;
case BRCMU_CHAN_BW_20:
width = NL80211_CHAN_WIDTH_20;
break;
case BRCMU_CHAN_BW_80P80:
width = NL80211_CHAN_WIDTH_80P80;
break;
case BRCMU_CHAN_BW_160:
width = NL80211_CHAN_WIDTH_160;
break;
}
freq = ieee80211_channel_to_frequency(ch.control_ch_num, band);
chandef->chan = ieee80211_get_channel(wiphy, freq);
chandef->width = width;
chandef->center_freq1 = ieee80211_channel_to_frequency(ch.chnum, band);
chandef->center_freq2 = 0;
return ZX_OK;
}
static zx_status_t brcmf_cfg80211_crit_proto_start(struct wiphy* wiphy, struct wireless_dev* wdev,
enum nl80211_crit_proto_id proto,
uint16_t duration) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_cfg80211_vif* vif;
vif = containerof(wdev, struct brcmf_cfg80211_vif, wdev);
/* only DHCP support for now */
if (proto != NL80211_CRIT_PROTO_DHCP) {
return ZX_ERR_NOT_SUPPORTED;
}
/* suppress and abort scanning */
brcmf_set_bit_in_array(BRCMF_SCAN_STATUS_SUPPRESS, &cfg->scan_status);
brcmf_abort_scanning(cfg);
return brcmf_btcoex_set_mode(vif, BRCMF_BTCOEX_DISABLED, duration);
}
static void brcmf_cfg80211_crit_proto_stop(struct wiphy* wiphy, struct wireless_dev* wdev) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_cfg80211_vif* vif;
vif = containerof(wdev, struct brcmf_cfg80211_vif, wdev);
brcmf_btcoex_set_mode(vif, BRCMF_BTCOEX_ENABLED, 0);
brcmf_clear_bit_in_array(BRCMF_SCAN_STATUS_SUPPRESS, &cfg->scan_status);
}
static zx_status_t brcmf_notify_tdls_peer_event(struct brcmf_if* ifp,
const struct brcmf_event_msg* e, void* data) {
switch (e->reason) {
case BRCMF_E_REASON_TDLS_PEER_DISCOVERED:
brcmf_dbg(TRACE, "TDLS Peer Discovered\n");
break;
case BRCMF_E_REASON_TDLS_PEER_CONNECTED:
brcmf_dbg(TRACE, "TDLS Peer Connected\n");
brcmf_proto_add_tdls_peer(ifp->drvr, ifp->ifidx, (uint8_t*)e->addr);
break;
case BRCMF_E_REASON_TDLS_PEER_DISCONNECTED:
brcmf_dbg(TRACE, "TDLS Peer Disconnected\n");
brcmf_proto_delete_peer(ifp->drvr, ifp->ifidx, (uint8_t*)e->addr);
break;
}
return ZX_OK;
}
static zx_status_t brcmf_convert_nl80211_tdls_oper(enum nl80211_tdls_operation oper,
enum brcmf_tdls_manual_ep_ops* op_out) {
zx_status_t ret = ZX_OK;
if (!op_out) {
return ZX_ERR_INVALID_ARGS;
}
switch (oper) {
case NL80211_TDLS_DISCOVERY_REQ:
*op_out = BRCMF_TDLS_MANUAL_EP_DISCOVERY;
break;
case NL80211_TDLS_SETUP:
*op_out = BRCMF_TDLS_MANUAL_EP_CREATE;
break;
case NL80211_TDLS_TEARDOWN:
*op_out = BRCMF_TDLS_MANUAL_EP_DELETE;
break;
default:
brcmf_err("unsupported operation: %d\n", oper);
ret = ZX_ERR_NOT_SUPPORTED;
}
return ret;
}
static zx_status_t brcmf_cfg80211_tdls_oper(struct wiphy* wiphy, struct net_device* ndev,
const uint8_t* peer, enum nl80211_tdls_operation oper) {
struct brcmf_if* ifp;
struct brcmf_tdls_iovar_le info;
zx_status_t ret = ZX_OK;
enum brcmf_tdls_manual_ep_ops mode;
ret = brcmf_convert_nl80211_tdls_oper(oper, &mode);
if (ret != ZX_OK) {
return ret;
}
ifp = ndev_to_if(ndev);
memset(&info, 0, sizeof(info));
info.mode = (uint8_t)mode;
if (peer) {
memcpy(info.ea, peer, ETH_ALEN);
}
ret = brcmf_fil_iovar_data_set(ifp, "tdls_endpoint", &info, sizeof(info));
if (ret != ZX_OK) {
brcmf_err("tdls_endpoint iovar failed: ret=%d\n", ret);
}
return ret;
}
#ifdef FIGURE_THIS_OUT_LATER
static zx_status_t brcmf_cfg80211_update_conn_params(struct wiphy* wiphy, struct net_device* ndev,
struct cfg80211_connect_params* sme, uint32_t changed) {
struct brcmf_if* ifp;
zx_status_t err;
if (!(changed & UPDATE_ASSOC_IES)) {
return ZX_OK;
}
ifp = ndev_to_if(ndev);
err = brcmf_vif_set_mgmt_ie(ifp->vif, BRCMF_VNDR_IE_ASSOCREQ_FLAG, sme->ie, sme->ie_len);
if (err != ZX_OK) {
brcmf_err("Set Assoc REQ IE Failed\n");
} else {
brcmf_dbg(TRACE, "Applied Vndr IEs for Assoc request\n");
}
return err;
}
#endif // FIGURE_THIS_OUT_LATER
#ifdef CONFIG_PM
static zx_status_t brcmf_cfg80211_set_rekey_data(struct wiphy* wiphy, struct net_device* ndev,
struct cfg80211_gtk_rekey_data* gtk) {
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_gtk_keyinfo_le gtk_le;
zx_status_t ret;
brcmf_dbg(TRACE, "Enter, bssidx=%d\n", ifp->bsscfgidx);
memcpy(gtk_le.kck, gtk->kck, sizeof(gtk_le.kck));
memcpy(gtk_le.kek, gtk->kek, sizeof(gtk_le.kek));
memcpy(gtk_le.replay_counter, gtk->replay_ctr, sizeof(gtk_le.replay_counter));
ret = brcmf_fil_iovar_data_set(ifp, "gtk_key_info", &gtk_le, sizeof(gtk_le));
if (ret != ZX_OK) {
brcmf_err("gtk_key_info iovar failed: ret=%d\n", ret);
}
return ret;
}
#endif
static zx_status_t brcmf_cfg80211_set_pmk(struct wiphy* wiphy, struct net_device* dev,
const struct cfg80211_pmk_conf* conf) {
struct brcmf_if* ifp;
brcmf_dbg(TRACE, "enter\n");
/* expect using firmware supplicant for 1X */
ifp = ndev_to_if(dev);
if (WARN_ON(ifp->vif->profile.use_fwsup != BRCMF_PROFILE_FWSUP_1X)) {
return ZX_ERR_NOT_SUPPORTED;
}
return brcmf_set_pmk(ifp, conf->pmk, conf->pmk_len);
}
static zx_status_t brcmf_cfg80211_del_pmk(struct wiphy* wiphy, struct net_device* dev,
const uint8_t* aa) {
struct brcmf_if* ifp;
brcmf_dbg(TRACE, "enter\n");
ifp = ndev_to_if(dev);
if (WARN_ON(ifp->vif->profile.use_fwsup != BRCMF_PROFILE_FWSUP_1X)) {
return ZX_ERR_NOT_SUPPORTED;
}
return brcmf_set_pmk(ifp, NULL, 0);
}
static struct cfg80211_ops brcmf_cfg80211_ops = {
.add_virtual_intf = brcmf_cfg80211_add_iface,
.del_virtual_intf = brcmf_cfg80211_del_iface,
.change_virtual_intf = brcmf_cfg80211_change_iface,
.scan = brcmf_cfg80211_scan,
.set_wiphy_params = brcmf_cfg80211_set_wiphy_params,
.join_ibss = brcmf_cfg80211_join_ibss,
.leave_ibss = brcmf_cfg80211_leave_ibss,
.get_station = brcmf_cfg80211_get_station,
.dump_station = brcmf_cfg80211_dump_station,
.set_tx_power = brcmf_cfg80211_set_tx_power,
.get_tx_power = brcmf_cfg80211_get_tx_power,
.add_key = brcmf_cfg80211_add_key,
.del_key = brcmf_cfg80211_del_key,
.get_key = brcmf_cfg80211_get_key,
.set_default_key = brcmf_cfg80211_config_default_key,
.set_default_mgmt_key = brcmf_cfg80211_config_default_mgmt_key,
.set_power_mgmt = brcmf_cfg80211_set_power_mgmt,
.connect = brcmf_cfg80211_connect,
.disconnect = brcmf_cfg80211_disconnect,
.suspend = brcmf_cfg80211_suspend,
.resume = brcmf_cfg80211_resume,
.set_pmksa = brcmf_cfg80211_set_pmksa,
.del_pmksa = brcmf_cfg80211_del_pmksa,
.flush_pmksa = brcmf_cfg80211_flush_pmksa,
.start_ap = brcmf_cfg80211_start_ap,
.stop_ap = brcmf_cfg80211_stop_ap,
.change_beacon = brcmf_cfg80211_change_beacon,
.del_station = brcmf_cfg80211_del_station,
.change_station = brcmf_cfg80211_change_station,
.sched_scan_start = brcmf_cfg80211_sched_scan_start,
.sched_scan_stop = brcmf_cfg80211_sched_scan_stop,
.mgmt_frame_register = brcmf_cfg80211_mgmt_frame_register,
.mgmt_tx = brcmf_cfg80211_mgmt_tx,
.remain_on_channel = brcmf_p2p_remain_on_channel,
.cancel_remain_on_channel = brcmf_cfg80211_cancel_remain_on_channel,
.get_channel = brcmf_cfg80211_get_channel,
.start_p2p_device = brcmf_p2p_start_device,
.stop_p2p_device = brcmf_p2p_stop_device,
.crit_proto_start = brcmf_cfg80211_crit_proto_start,
.crit_proto_stop = brcmf_cfg80211_crit_proto_stop,
.tdls_oper = brcmf_cfg80211_tdls_oper,
// .update_connect_params = brcmf_cfg80211_update_conn_params,
.set_pmk = brcmf_cfg80211_set_pmk,
.del_pmk = brcmf_cfg80211_del_pmk,
};
static zx_status_t brcmf_setup_wiphybands(struct wiphy* wiphy);
static void brcmf_cfg80211_set_country(struct wiphy* wiphy, char code[3]) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_if* ifp = cfg_to_if(cfg);
struct brcmf_fil_country_le ccreq;
zx_status_t err;
brcmf_dbg(TRACE, "Enter: code=%c%c\n", code[0], code[1]);
err = brcmf_fil_iovar_data_get(ifp, "country", &ccreq, sizeof(ccreq));
if (err != ZX_OK) {
brcmf_err("Country code iovar returned err = %d\n", err);
return;
}
//memset(&ccreq, 0, sizeof(ccreq));
//ccreq.rev = country_codes->table[found_index].rev;
brcmf_dbg(TEMP, "ccode 0x%x, abbrev 0x%x, rev %d", *(uint32_t*)ccreq.ccode,
*(uint32_t*)ccreq.country_abbrev, ccreq.rev);
ccreq.ccode[0] = code[0];
ccreq.ccode[1] = code[1];
ccreq.ccode[2] = 0;
ccreq.country_abbrev[0] = code[0];
ccreq.country_abbrev[1] = code[1];
ccreq.country_abbrev[2] = 0;
err = brcmf_fil_iovar_data_set(ifp, "country", &ccreq, sizeof(ccreq));
if (err != ZX_OK) {
brcmf_err("Firmware rejected country setting\n");
return;
}
brcmf_setup_wiphybands(wiphy);
}
static zx_status_t brcmf_if_start(void* ctx, wlanif_impl_ifc_t* ifc, void* cookie) {
struct net_device* ndev = ctx;
brcmf_dbg(TEMP, "Enter");
ndev->if_callbacks = malloc(sizeof(*ifc));
memcpy(ndev->if_callbacks, ifc, sizeof(*ifc));
ndev->if_callback_cookie = cookie;
brcmf_netdev_open(ndev);
ndev->flags = IFF_UP;
brcmf_cfg80211_set_country(ndev_to_wiphy(ndev), "US");
return ZX_OK;
}
static void brcmf_if_stop(void* ctx) {
struct net_device* ndev = ctx;
brcmf_dbg(TEMP, "Enter");
free(ndev->if_callbacks);
ndev->if_callbacks = NULL;
}
void brcmf_hook_start_scan(void* ctx, wlanif_scan_req_t* req) {
struct net_device* ndev = ctx;
struct wiphy* wiphy = ndev_to_wiphy(ndev);
zx_status_t result;
brcmf_dbg(TEMP, "Enter");
if (wiphy->scan_busy) {
brcmf_signal_scan_end(ndev, req->txn_id, SCAN_RESULT_INTERNAL_ERROR);
} else {
wiphy->scan_txn_id = req->txn_id;
wiphy->scan_busy = true;
}
struct cfg80211_scan_request request;
memset(&request, 0, sizeof(request));
struct ieee80211_channel channels[11];
memset(channels, 0, sizeof(channels));
request.n_channels = 11;
request.wdev = ndev_to_wdev(ndev);
for (int i = 0; i < 11; i++) {
// TODO(cphoenix): Fix this hack along with ieee80211_frequency_to_channel() hack
// in device.h
channels[i].center_freq = i+1;
channels[i].hw_value = i+1;
request.channels[i] = &channels[i];
}
brcmf_dbg(TEMP, "About to scan! Txn ID %lu wiphy %p", wiphy->scan_txn_id, wiphy);
result = brcmf_cfg80211_scan(wiphy, &request);
if (result != ZX_OK) {
brcmf_dbg(TEMP, "Couldn't start scan: %d %s", result, zx_status_get_string(result));
brcmf_signal_scan_end(ndev, req->txn_id, SCAN_RESULT_INTERNAL_ERROR);
wiphy->scan_busy = false;
}
}
void brcmf_hook_join_req(void* ctx, wlanif_join_req_t* req) {
struct net_device* ndev = ctx;
struct wiphy* wiphy = ndev_to_wiphy(ndev);
brcmf_dbg(TEMP, "Enter, ssid %s, bssid %lx", req->selected_bss.ssid,
*(uint64_t*)(req->selected_bss.bssid) & 0xffffffffffff);
//uint8_t ie_1[] = {0x82, 0x84, 0x8b, 0x96, 0x24, 0x30, 0x48, 0x6c};
//uint8_t ie_50[] = {0x0c, 0x12, 0x18, 0x60};
brcmf_cfg80211_connect(wiphy, ndev, req);
}
void brcmf_hook_auth_req(void* ctx, wlanif_auth_req_t* req) {
struct net_device* ndev = ctx;
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_cfg80211_profile* profile = &ifp->vif->profile;
wlanif_auth_confirm_t response;
brcmf_dbg(TEMP, "Enter");
response.result_code = AUTH_RESULT_SUCCESS;
response.auth_type = req->auth_type;
// At this point, the firmware should already have fully connected, and filled in
// profile->bssid.
if (memcmp(req->peer_sta_address, profile->bssid, ETH_ALEN)) {
brcmf_dbg(TEMP, " * * ERROR * * Requested MAC %lx != connected MAC %lx",
*(uint64_t*)req->peer_sta_address & 0xffffffffffff,
*(uint64_t*)profile->bssid & 0xffffffffffff);
}
memcpy(&response.peer_sta_address, profile->bssid, ETH_ALEN);
ndev->if_callbacks->auth_conf(ndev->if_callback_cookie, &response);
}
void brcmf_hook_auth_ind(void* ctx, wlanif_auth_ind_t* ind) {
brcmf_dbg(TEMP, "Called hook auth_ind");
}
void brcmf_hook_deauth_req(void* ctx, wlanif_deauth_req_t* req) {
brcmf_dbg(TEMP, "Called hook deauth_req");
}
void brcmf_hook_assoc_req(void* ctx, wlanif_assoc_req_t* req) {
struct net_device* ndev = ctx;
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_cfg80211_profile* profile = &ifp->vif->profile;
wlanif_assoc_confirm_t response;
brcmf_dbg(TEMP, "Enter");
if (req->rsne_len != 0) {
brcmf_dbg(TEMP, " * * RSNE non-zero! %ld", req->rsne_len);
brcmf_hexdump("assoc-rsne", req->rsne, req->rsne_len);
}
if (memcmp(req->peer_sta_address, profile->bssid, ETH_ALEN)) {
brcmf_dbg(TEMP, " * * ERROR * * Requested MAC %lx != connected MAC %lx",
*(uint64_t*)req->peer_sta_address & 0xffffffffffff,
*(uint64_t*)profile->bssid & 0xffffffffffff);
}
response.result_code = ASSOC_RESULT_SUCCESS;
brcmf_dbg(TEMP, " * Hard-coding association_id to 42; this will likely break something!");
response.association_id = 42; // TODO(cphoenix): Don't hard-code this!!!
ndev->if_callbacks->assoc_conf(ndev->if_callback_cookie, &response);
}
void brcmf_hook_assoc_ind(void* ctx, wlanif_assoc_ind_t* ind) {
brcmf_dbg(TEMP, "Called hook assoc_ind");
}
void brcmf_hook_disassoc_req(void* ctx, wlanif_disassoc_req_t* req) {
brcmf_dbg(TEMP, "Called hook disassoc_req");
}
void brcmf_hook_reset_req(void* ctx, wlanif_reset_req_t* req) {
brcmf_dbg(TEMP, "Called hook reset_req");
}
void brcmf_hook_start_req(void* ctx, wlanif_start_req_t* req) {
brcmf_dbg(TEMP, "Called hook start_req");
}
void brcmf_hook_stop_req(void* ctx, wlanif_stop_req_t* req) {
brcmf_dbg(TEMP, "Called hook stop_req");
}
void brcmf_hook_set_keys_req(void* ctx, wlanif_set_keys_req_t* req) {
brcmf_dbg(TEMP, "Called hook set_keys_req");
}
void brcmf_hook_del_keys_req(void* ctx, wlanif_del_keys_req_t* req) {
brcmf_dbg(TEMP, "Called hook del_keys_req");
}
void brcmf_hook_eapol_req(void* ctx, wlanif_eapol_req_t* req) {
brcmf_dbg(TEMP, "Called hook eapol_req");
}
void brcmf_hook_query(void* ctx, wlanif_query_info_t* info) {
struct net_device* ndev = ctx;
struct brcmf_if* ifp = ndev_to_if(ndev);
//struct wireless_dev* wdev = ndev_to_wdev(ndev);
brcmf_dbg(TEMP, "Enter");
memset(info, 0, sizeof(*info));
// TODO(cphoenix): Don't hard-code all this.
brcmf_dbg(TEMP, "Mac ADDR: 0x%lx", *(uint64_t*)ifp->mac_addr & 0xffffffffffff);
memcpy(info->mac_addr, ifp->mac_addr, ETH_ALEN);
info->role = MAC_ROLE_CLIENT;
info->num_bands = 1;
static uint16_t basic_rates[] = { 2, 4, 11, 22, 12, 18, 24, 36, 48, 72, 96, 108 };
static uint8_t channels[] = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14 };
static wlanif_band_capabilities_t band = {
.num_basic_rates = 12,
.basic_rates = basic_rates,
.base_frequency = 2407,
.num_channels = 14,
.channels = channels,
};
info->bands = &band;
}
void brcmf_hook_stats_query_req(void* ctx) {
struct net_device* ndev = ctx;
brcmf_dbg(TEMP, "Enter");
wlanif_stats_query_response_t response = {};
wlanif_mlme_stats_t mlme_stats = {};
response.stats.mlme_stats = &mlme_stats;
// TODO(cphoenix): Fill in all the stats fields.
ndev->if_callbacks->stats_query_resp(ndev->if_callback_cookie, &response);
}
// Ethernet operations
zx_status_t brcmf_hook_eth_start(void* ctx) {
brcmf_dbg(TEMP, "Enter");
return ZX_OK;
}
void brcmf_hook_eth_stop(void* ctx) {
brcmf_dbg(TEMP, "Called hook eth_stop");
}
zx_status_t brcmf_hook_eth_query(void* ctx, uint32_t options, ethmac_info_t* info) {
brcmf_dbg(TEMP, "Enter");
info->features = ETHMAC_FEATURE_WLAN;
// TODO(cphoenix): Don't hard-code this
info->mtu = 1500;
uint8_t mac_addr[ETH_MAC_SIZE] = {1, 2, 3, 4, 5, 6};
memcpy(info->mac, mac_addr, ETH_MAC_SIZE);
return ZX_OK;
}
zx_status_t brcmf_hook_eth_queue_tx(void* ctx, uint32_t options, ethmac_netbuf_t* netbuf) {
struct net_device* ndev = ctx;
brcmf_dbg(TEMP, "Enter. Options %d 0x%x, len %d", options, options, netbuf->len);
brcmf_netdev_start_xmit(ndev, netbuf);
return ZX_OK;
}
zx_status_t brcmf_hook_eth_set_param(void* ctx, uint32_t param, int32_t value, void* data) {
brcmf_dbg(TEMP, "Enter. param %d, value %d, data %p. NOP - returning OK.", param, value, data);
return ZX_OK;
}
static wlanif_impl_protocol_ops_t if_impl_proto_ops = {
.start = brcmf_if_start,
.stop = brcmf_if_stop,
.start_scan = brcmf_hook_start_scan,
.join_req = brcmf_hook_join_req,
.auth_req = brcmf_hook_auth_req,
.auth_ind = brcmf_hook_auth_ind,
.deauth_req = brcmf_hook_deauth_req,
.assoc_req = brcmf_hook_assoc_req,
.assoc_ind = brcmf_hook_assoc_ind,
.disassoc_req = brcmf_hook_disassoc_req,
.reset_req = brcmf_hook_reset_req,
.start_req = brcmf_hook_start_req,
.stop_req = brcmf_hook_stop_req,
.set_keys_req = brcmf_hook_set_keys_req,
.del_keys_req = brcmf_hook_del_keys_req,
.eapol_req = brcmf_hook_eapol_req,
.query = brcmf_hook_query,
.stats_query_req = brcmf_hook_stats_query_req,
// Ethernet operations
//.eth_start = brcmf_hook_eth_start,
//.eth_stop = brcmf_hook_eth_stop,
//.eth_query = brcmf_hook_eth_query,
.data_queue_tx = brcmf_hook_eth_queue_tx,
//.eth_set_param = brcmf_hook_eth_set_param,
};
static void brcmf_release_zx_if_device(void* ctx) {
// TODO(cphoenix): Implement unbind/release
// Unbind - remove device from tree
// Release - dealloc resources
brcmf_err("* * Need to unload and release all driver structs");
}
static zx_protocol_device_t if_impl_device_ops = {
.version = DEVICE_OPS_VERSION,
.release = brcmf_release_zx_if_device,
};
zx_status_t brcmf_phy_create_iface(void* ctx, uint16_t role, uint16_t* iface_id) {
struct brcmf_if* ifp = ctx;
struct net_device* ndev = ifp->ndev;
zx_status_t result;
brcmf_dbg(TEMP, "brcmf_phy_create_iface called!");
device_add_args_t args = {
.version = DEVICE_ADD_ARGS_VERSION,
.name = "broadcom-wlanif", // TODO(cphoenix): Uniquify this?
.ctx = ndev,
.ops = &if_impl_device_ops,
.proto_id = ZX_PROTOCOL_WLANIF_IMPL,
.proto_ops = &if_impl_proto_ops,
};
struct brcmf_device* device = ifp->drvr->bus_if->dev;
brcmf_dbg(TEMP, "About to add if_dev");
result = device_add(device->phy_zxdev, &args, &device->if_zxdev);
if (result != ZX_OK) {
brcmf_err("Failed to device_add: %s", zx_status_get_string(result));
return result;
}
brcmf_dbg(TEMP, "device_add() succeeded. Added iface hooks.");
*iface_id = 42;
/* set appropriate operations */
ndev->initialized_for_ap = true;
/* set the mac address & netns */
memcpy(ndev->dev_addr, ifp->mac_addr, ETH_ALEN);
ndev->priv_destructor = brcmf_free_net_device_vif;
brcmf_dbg(INFO, "%s: Broadcom Dongle Host Driver\n", ndev->name);
return ZX_OK;
}
zx_status_t brcmf_alloc_vif(struct brcmf_cfg80211_info* cfg, enum nl80211_iftype type,
struct brcmf_cfg80211_vif** vif_out) {
struct brcmf_cfg80211_vif* vif_walk;
struct brcmf_cfg80211_vif* vif;
bool mbss;
brcmf_dbg(TRACE, "allocating virtual interface (size=%zu)\n", sizeof(*vif));
vif = calloc(1, sizeof(*vif));
if (!vif) {
if (vif_out) {
*vif_out = NULL;
}
return ZX_ERR_NO_MEMORY;
}
vif->wdev.wiphy = cfg->wiphy;
vif->wdev.iftype = type;
brcmf_init_prof(&vif->profile);
if (type == NL80211_IFTYPE_AP) {
mbss = false;
list_for_every_entry(&cfg->vif_list, vif_walk, struct brcmf_cfg80211_vif, list) {
if (vif_walk->wdev.iftype == NL80211_IFTYPE_AP) {
mbss = true;
break;
}
}
vif->mbss = mbss;
}
list_add_tail(&cfg->vif_list, &vif->list);
if (vif_out) {
*vif_out = vif;
}
return ZX_OK;
}
void brcmf_free_vif(struct brcmf_cfg80211_vif* vif) {
list_delete(&vif->list);
free(vif);
}
void brcmf_free_net_device_vif(struct net_device* ndev) {
struct brcmf_cfg80211_vif* vif = ndev_to_vif(ndev);
if (vif) {
brcmf_free_vif(vif);
}
}
// TODO(cphoenix): Rename and/or refactor this function - it has way too many side effects for a
// function that looks like it just returns info about state.
static bool brcmf_is_linkup(struct brcmf_cfg80211_vif* vif, const struct brcmf_event_msg* e) {
uint32_t event = e->event_code;
uint32_t status = e->status;
brcmf_dbg(TEMP, "Enter, event %d, status %d, sme_state 0x%lx", event, status,
atomic_load(&vif->sme_state));
if (vif->profile.use_fwsup == BRCMF_PROFILE_FWSUP_PSK && event == BRCMF_E_PSK_SUP &&
status == BRCMF_E_STATUS_FWSUP_COMPLETED) {
brcmf_set_bit_in_array(BRCMF_VIF_STATUS_EAP_SUCCESS, &vif->sme_state);
}
if (event == BRCMF_E_SET_SSID && status == BRCMF_E_STATUS_SUCCESS) {
brcmf_dbg(CONN, "Processing set ssid\n");
memcpy(vif->profile.bssid, e->addr, ETH_ALEN);
if (vif->profile.use_fwsup != BRCMF_PROFILE_FWSUP_PSK) {
brcmf_dbg(TEMP, "Ret true");
return true;
}
brcmf_set_bit_in_array(BRCMF_VIF_STATUS_ASSOC_SUCCESS, &vif->sme_state);
}
if (brcmf_test_bit_in_array(BRCMF_VIF_STATUS_EAP_SUCCESS, &vif->sme_state) &&
brcmf_test_bit_in_array(BRCMF_VIF_STATUS_ASSOC_SUCCESS, &vif->sme_state)) {
brcmf_clear_bit_in_array(BRCMF_VIF_STATUS_EAP_SUCCESS, &vif->sme_state);
brcmf_clear_bit_in_array(BRCMF_VIF_STATUS_ASSOC_SUCCESS, &vif->sme_state);
brcmf_dbg(TEMP, "Ret true");
return true;
}
brcmf_dbg(TEMP, "Ret false");
return false;
}
static bool brcmf_is_linkdown(const struct brcmf_event_msg* e) {
uint32_t event = e->event_code;
uint16_t flags = e->flags;
if ((event == BRCMF_E_DEAUTH) || (event == BRCMF_E_DEAUTH_IND) ||
(event == BRCMF_E_DISASSOC_IND) ||
((event == BRCMF_E_LINK) && (!(flags & BRCMF_EVENT_MSG_LINK)))) {
brcmf_dbg(CONN, "Processing link down\n");
return true;
}
return false;
}
static bool brcmf_is_nonetwork(struct brcmf_cfg80211_info* cfg, const struct brcmf_event_msg* e) {
uint32_t event = e->event_code;
uint32_t status = e->status;
if (event == BRCMF_E_LINK && status == BRCMF_E_STATUS_NO_NETWORKS) {
brcmf_dbg(CONN, "Processing Link %s & no network found\n",
e->flags & BRCMF_EVENT_MSG_LINK ? "up" : "down");
return true;
}
if (event == BRCMF_E_SET_SSID && status != BRCMF_E_STATUS_SUCCESS) {
brcmf_dbg(CONN, "Processing connecting & no network found\n");
return true;
}
if (event == BRCMF_E_PSK_SUP && status != BRCMF_E_STATUS_FWSUP_COMPLETED) {
brcmf_dbg(CONN, "Processing failed supplicant state: %u\n", status);
return true;
}
return false;
}
static void brcmf_clear_assoc_ies(struct brcmf_cfg80211_info* cfg) {
struct brcmf_cfg80211_connect_info* conn_info = cfg_to_conn(cfg);
free(conn_info->req_ie);
conn_info->req_ie = NULL;
conn_info->req_ie_len = 0;
free(conn_info->resp_ie);
conn_info->resp_ie = NULL;
conn_info->resp_ie_len = 0;
}
static zx_status_t brcmf_get_assoc_ies(struct brcmf_cfg80211_info* cfg, struct brcmf_if* ifp) {
struct brcmf_cfg80211_assoc_ielen_le* assoc_info;
struct brcmf_cfg80211_connect_info* conn_info = cfg_to_conn(cfg);
uint32_t req_len;
uint32_t resp_len;
zx_status_t err = ZX_OK;
brcmf_clear_assoc_ies(cfg);
err = brcmf_fil_iovar_data_get(ifp, "assoc_info", cfg->extra_buf, WL_ASSOC_INFO_MAX);
if (err != ZX_OK) {
brcmf_err("could not get assoc info (%d)\n", err);
return err;
}
assoc_info = (struct brcmf_cfg80211_assoc_ielen_le*)cfg->extra_buf;
req_len = assoc_info->req_len;
resp_len = assoc_info->resp_len;
if (req_len) {
err = brcmf_fil_iovar_data_get(ifp, "assoc_req_ies", cfg->extra_buf, WL_ASSOC_INFO_MAX);
if (err != ZX_OK) {
brcmf_err("could not get assoc req (%d)\n", err);
return err;
}
conn_info->req_ie_len = req_len;
conn_info->req_ie = brcmu_alloc_and_copy(cfg->extra_buf, conn_info->req_ie_len);
} else {
conn_info->req_ie_len = 0;
conn_info->req_ie = NULL;
}
if (resp_len) {
err = brcmf_fil_iovar_data_get(ifp, "assoc_resp_ies", cfg->extra_buf, WL_ASSOC_INFO_MAX);
if (err != ZX_OK) {
brcmf_err("could not get assoc resp (%d)\n", err);
return err;
}
conn_info->resp_ie_len = resp_len;
conn_info->resp_ie = brcmu_alloc_and_copy(cfg->extra_buf, conn_info->resp_ie_len);
} else {
conn_info->resp_ie_len = 0;
conn_info->resp_ie = NULL;
}
brcmf_dbg(CONN, "req len (%d) resp len (%d)\n", conn_info->req_ie_len, conn_info->resp_ie_len);
return err;
}
static zx_status_t brcmf_bss_roaming_done(struct brcmf_cfg80211_info* cfg, struct net_device* ndev,
const struct brcmf_event_msg* e) {
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_cfg80211_profile* profile = &ifp->vif->profile;
struct brcmf_cfg80211_connect_info* conn_info = cfg_to_conn(cfg);
struct wiphy* wiphy = cfg_to_wiphy(cfg);
struct ieee80211_channel* notify_channel = NULL;
struct ieee80211_supported_band* band;
struct brcmf_bss_info_le* bi;
struct brcmu_chan ch;
struct cfg80211_roam_info roam_info = {};
uint32_t freq;
zx_status_t err = ZX_OK;
uint8_t* buf;
brcmf_dbg(TRACE, "Enter\n");
brcmf_get_assoc_ies(cfg, ifp);
memcpy(profile->bssid, e->addr, ETH_ALEN);
brcmf_update_bss_info(cfg, ifp);
buf = calloc(1, WL_BSS_INFO_MAX);
if (buf == NULL) {
err = ZX_ERR_NO_MEMORY;
goto done;
}
/* data sent to dongle has to be little endian */
*(uint32_t*)buf = WL_BSS_INFO_MAX;
err = brcmf_fil_cmd_data_get(ifp, BRCMF_C_GET_BSS_INFO, buf, WL_BSS_INFO_MAX);
if (err != ZX_OK) {
goto done;
}
bi = (struct brcmf_bss_info_le*)(buf + 4);
ch.chspec = bi->chanspec;
cfg->d11inf.decchspec(&ch);
if (ch.band == BRCMU_CHAN_BAND_2G) {
band = wiphy->bands[NL80211_BAND_2GHZ];
} else {
band = wiphy->bands[NL80211_BAND_5GHZ];
}
freq = ieee80211_channel_to_frequency(ch.control_ch_num, band->band);
notify_channel = ieee80211_get_channel(wiphy, freq);
done:
free(buf);
roam_info.channel = notify_channel;
roam_info.bssid = profile->bssid;
roam_info.req_ie = conn_info->req_ie;
roam_info.req_ie_len = conn_info->req_ie_len;
roam_info.resp_ie = conn_info->resp_ie;
roam_info.resp_ie_len = conn_info->resp_ie_len;
cfg80211_roamed(ndev, &roam_info);
brcmf_dbg(CONN, "Report roaming result\n");
brcmf_set_bit_in_array(BRCMF_VIF_STATUS_CONNECTED, &ifp->vif->sme_state);
brcmf_dbg(TRACE, "Exit\n");
return err;
}
static zx_status_t brcmf_bss_connect_done(struct brcmf_cfg80211_info* cfg, struct net_device* ndev,
const struct brcmf_event_msg* e, bool completed) {
struct brcmf_if* ifp = ndev_to_if(ndev);
brcmf_dbg(TRACE, "Enter\n");
if (brcmf_test_and_clear_bit_in_array(BRCMF_VIF_STATUS_CONNECTING, &ifp->vif->sme_state)) {
if (completed) {
brcmf_get_assoc_ies(cfg, ifp);
brcmf_update_bss_info(cfg, ifp);
brcmf_set_bit_in_array(BRCMF_VIF_STATUS_CONNECTED, &ifp->vif->sme_state);
}
// Connected bssid is in profile->bssid.
// connection IEs are in conn_info->req_ie, req_ie_len, resp_ie, resp_ie_len.
brcmf_dbg(CONN, "Report connect result - connection %s\n",
completed ? "succeeded" : "timed out");
brcmf_return_join_result(ndev, completed ? JOIN_RESULT_SUCCESS :
JOIN_RESULT_FAILURE_TIMEOUT);
}
brcmf_dbg(TRACE, "Exit\n");
return ZX_OK;
}
static zx_status_t brcmf_notify_connect_status_ap(struct brcmf_cfg80211_info* cfg,
struct net_device* ndev,
const struct brcmf_event_msg* e, void* data) {
static int generation;
uint32_t event = e->event_code;
uint32_t reason = e->reason;
struct station_info sinfo;
brcmf_dbg(CONN, "event %s (%u), reason %d\n", brcmf_fweh_event_name(event), event, reason);
if (event == BRCMF_E_LINK && reason == BRCMF_E_REASON_LINK_BSSCFG_DIS &&
ndev != cfg_to_ndev(cfg)) {
brcmf_dbg(CONN, "AP mode link down\n");
sync_completion_signal(&cfg->vif_disabled);
return ZX_OK;
}
if (((event == BRCMF_E_ASSOC_IND) || (event == BRCMF_E_REASSOC_IND)) &&
(reason == BRCMF_E_STATUS_SUCCESS)) {
memset(&sinfo, 0, sizeof(sinfo));
if (!data) {
brcmf_err("No IEs present in ASSOC/REASSOC_IND");
return ZX_ERR_INVALID_ARGS;
}
sinfo.assoc_req_ies = data;
sinfo.assoc_req_ies_len = e->datalen;
generation++;
sinfo.generation = generation;
cfg80211_new_sta(ndev, e->addr, &sinfo);
} else if ((event == BRCMF_E_DISASSOC_IND) || (event == BRCMF_E_DEAUTH_IND) ||
(event == BRCMF_E_DEAUTH)) {
cfg80211_del_sta(ndev, e->addr);
}
return ZX_OK;
}
static zx_status_t brcmf_notify_connect_status(struct brcmf_if* ifp,
const struct brcmf_event_msg* e, void* data) {
struct brcmf_cfg80211_info* cfg = ifp->drvr->config;
struct net_device* ndev = ifp->ndev;
struct brcmf_cfg80211_profile* profile = &ifp->vif->profile;
struct ieee80211_channel* chan;
zx_status_t err = ZX_OK;
brcmf_dbg(TEMP, "Enter, event code %d", e->event_code);
if ((e->event_code == BRCMF_E_DEAUTH) || (e->event_code == BRCMF_E_DEAUTH_IND) ||
(e->event_code == BRCMF_E_DISASSOC_IND) ||
((e->event_code == BRCMF_E_LINK) && (!e->flags))) {
brcmf_proto_delete_peer(ifp->drvr, ifp->ifidx, (uint8_t*)e->addr);
}
if (brcmf_is_apmode(ifp->vif)) {
err = brcmf_notify_connect_status_ap(cfg, ndev, e, data);
} else if (brcmf_is_linkup(ifp->vif, e)) {
brcmf_dbg(CONN, "Linkup\n");
if (brcmf_is_ibssmode(ifp->vif)) {
brcmf_inform_ibss(cfg, ndev, e->addr);
chan = ieee80211_get_channel(cfg->wiphy, cfg->channel);
memcpy(profile->bssid, e->addr, ETH_ALEN);
cfg80211_ibss_joined(ndev, e->addr, chan);
brcmf_clear_bit_in_array(BRCMF_VIF_STATUS_CONNECTING, &ifp->vif->sme_state);
brcmf_set_bit_in_array(BRCMF_VIF_STATUS_CONNECTED, &ifp->vif->sme_state);
} else {
brcmf_bss_connect_done(cfg, ndev, e, true);
}
brcmf_net_setcarrier(ifp, true);
} else if (brcmf_is_linkdown(e)) {
brcmf_dbg(CONN, "Linkdown\n");
if (!brcmf_is_ibssmode(ifp->vif)) {
brcmf_bss_connect_done(cfg, ndev, e, false);
brcmf_link_down(ifp->vif, brcmf_map_fw_linkdown_reason(e));
brcmf_init_prof(ndev_to_prof(ndev));
if (ndev != cfg_to_ndev(cfg)) {
sync_completion_signal(&cfg->vif_disabled);
}
brcmf_net_setcarrier(ifp, false);
}
} else if (brcmf_is_nonetwork(cfg, e)) {
if (brcmf_is_ibssmode(ifp->vif)) {
brcmf_clear_bit_in_array(BRCMF_VIF_STATUS_CONNECTING, &ifp->vif->sme_state);
} else {
brcmf_bss_connect_done(cfg, ndev, e, false);
}
}
return err;
}
static zx_status_t brcmf_notify_roaming_status(struct brcmf_if* ifp,
const struct brcmf_event_msg* e, void* data) {
struct brcmf_cfg80211_info* cfg = ifp->drvr->config;
uint32_t event = e->event_code;
uint32_t status = e->status;
if (event == BRCMF_E_ROAM && status == BRCMF_E_STATUS_SUCCESS) {
if (brcmf_test_bit_in_array(BRCMF_VIF_STATUS_CONNECTED, &ifp->vif->sme_state)) {
brcmf_bss_roaming_done(cfg, ifp->ndev, e);
} else {
brcmf_bss_connect_done(cfg, ifp->ndev, e, true);
brcmf_net_setcarrier(ifp, true);
}
}
return ZX_OK;
}
static zx_status_t brcmf_notify_mic_status(struct brcmf_if* ifp, const struct brcmf_event_msg* e,
void* data) {
uint16_t flags = e->flags;
enum nl80211_key_type key_type;
if (flags & BRCMF_EVENT_MSG_GROUP) {
key_type = NL80211_KEYTYPE_GROUP;
} else {
key_type = NL80211_KEYTYPE_PAIRWISE;
}
cfg80211_michael_mic_failure(ifp->ndev, (uint8_t*)&e->addr, key_type, -1, NULL);
return ZX_OK;
}
static zx_status_t brcmf_notify_vif_event(struct brcmf_if* ifp, const struct brcmf_event_msg* e,
void* data) {
struct brcmf_cfg80211_info* cfg = ifp->drvr->config;
struct brcmf_if_event* ifevent = (struct brcmf_if_event*)data;
struct brcmf_cfg80211_vif_event* event = &cfg->vif_event;
struct brcmf_cfg80211_vif* vif;
brcmf_dbg(TRACE, "Enter: action %u flags %u ifidx %u bsscfgidx %u\n", ifevent->action,
ifevent->flags, ifevent->ifidx, ifevent->bsscfgidx);
mtx_lock(&event->vif_event_lock);
event->action = ifevent->action;
vif = event->vif;
switch (ifevent->action) {
case BRCMF_E_IF_ADD:
/* waiting process may have timed out */
if (!cfg->vif_event.vif) {
mtx_unlock(&event->vif_event_lock);
return ZX_ERR_SHOULD_WAIT;
}
ifp->vif = vif;
vif->ifp = ifp;
if (ifp->ndev) {
vif->wdev.netdev = ifp->ndev;
ifp->ndev->ieee80211_ptr = &vif->wdev;
}
mtx_unlock(&event->vif_event_lock);
if (event->action == cfg->vif_event_pending_action) {
sync_completion_signal(&event->vif_event_wait);
}
return ZX_OK;
case BRCMF_E_IF_DEL:
mtx_unlock(&event->vif_event_lock);
/* event may not be upon user request */
if (brcmf_cfg80211_vif_event_armed(cfg) && event->action == cfg->vif_event_pending_action) {
sync_completion_signal(&event->vif_event_wait);
}
return ZX_OK;
case BRCMF_E_IF_CHANGE:
mtx_unlock(&event->vif_event_lock);
if (event->action == cfg->vif_event_pending_action) {
sync_completion_signal(&event->vif_event_wait);
}
return ZX_OK;
default:
mtx_unlock(&event->vif_event_lock);
break;
}
return ZX_ERR_INVALID_ARGS;
}
static void brcmf_init_conf(struct brcmf_cfg80211_conf* conf) {
conf->frag_threshold = (uint32_t)-1;
conf->rts_threshold = (uint32_t)-1;
conf->retry_short = (uint32_t)-1;
conf->retry_long = (uint32_t)-1;
}
static void brcmf_register_event_handlers(struct brcmf_cfg80211_info* cfg) {
brcmf_fweh_register(cfg->pub, BRCMF_E_LINK, brcmf_notify_connect_status);
brcmf_fweh_register(cfg->pub, BRCMF_E_DEAUTH_IND, brcmf_notify_connect_status);
brcmf_fweh_register(cfg->pub, BRCMF_E_DEAUTH, brcmf_notify_connect_status);
brcmf_fweh_register(cfg->pub, BRCMF_E_DISASSOC_IND, brcmf_notify_connect_status);
brcmf_fweh_register(cfg->pub, BRCMF_E_ASSOC_IND, brcmf_notify_connect_status);
brcmf_fweh_register(cfg->pub, BRCMF_E_REASSOC_IND, brcmf_notify_connect_status);
brcmf_fweh_register(cfg->pub, BRCMF_E_ROAM, brcmf_notify_roaming_status);
brcmf_fweh_register(cfg->pub, BRCMF_E_MIC_ERROR, brcmf_notify_mic_status);
brcmf_fweh_register(cfg->pub, BRCMF_E_SET_SSID, brcmf_notify_connect_status);
brcmf_fweh_register(cfg->pub, BRCMF_E_PFN_NET_FOUND, brcmf_notify_sched_scan_results);
brcmf_fweh_register(cfg->pub, BRCMF_E_IF, brcmf_notify_vif_event);
brcmf_fweh_register(cfg->pub, BRCMF_E_P2P_PROBEREQ_MSG, brcmf_p2p_notify_rx_mgmt_p2p_probereq);
brcmf_fweh_register(cfg->pub, BRCMF_E_P2P_DISC_LISTEN_COMPLETE,
brcmf_p2p_notify_listen_complete);
brcmf_fweh_register(cfg->pub, BRCMF_E_ACTION_FRAME_RX, brcmf_p2p_notify_action_frame_rx);
brcmf_fweh_register(cfg->pub, BRCMF_E_ACTION_FRAME_COMPLETE,
brcmf_p2p_notify_action_tx_complete);
brcmf_fweh_register(cfg->pub, BRCMF_E_ACTION_FRAME_OFF_CHAN_COMPLETE,
brcmf_p2p_notify_action_tx_complete);
brcmf_fweh_register(cfg->pub, BRCMF_E_PSK_SUP, brcmf_notify_connect_status);
}
static void brcmf_deinit_priv_mem(struct brcmf_cfg80211_info* cfg) {
free(cfg->conf);
cfg->conf = NULL;
free(cfg->extra_buf);
cfg->extra_buf = NULL;
free(cfg->wowl.nd);
cfg->wowl.nd = NULL;
free(cfg->wowl.nd_info);
cfg->wowl.nd_info = NULL;
free(cfg->escan_info.escan_buf);
cfg->escan_info.escan_buf = NULL;
}
static zx_status_t brcmf_init_priv_mem(struct brcmf_cfg80211_info* cfg) {
cfg->conf = calloc(1, sizeof(*cfg->conf));
if (!cfg->conf) {
goto init_priv_mem_out;
}
cfg->extra_buf = calloc(1, WL_EXTRA_BUF_MAX);
if (!cfg->extra_buf) {
goto init_priv_mem_out;
}
cfg->wowl.nd = calloc(1, sizeof(*cfg->wowl.nd) + sizeof(uint32_t));
if (!cfg->wowl.nd) {
goto init_priv_mem_out;
}
cfg->wowl.nd_info =
calloc(1, sizeof(*cfg->wowl.nd_info) + sizeof(struct cfg80211_wowlan_nd_match*));
if (!cfg->wowl.nd_info) {
goto init_priv_mem_out;
}
cfg->escan_info.escan_buf = calloc(1, BRCMF_ESCAN_BUF_SIZE);
if (!cfg->escan_info.escan_buf) {
goto init_priv_mem_out;
}
return ZX_OK;
init_priv_mem_out:
brcmf_deinit_priv_mem(cfg);
return ZX_ERR_NO_MEMORY;
}
static zx_status_t wl_init_priv(struct brcmf_cfg80211_info* cfg) {
zx_status_t err = ZX_OK;
cfg->scan_request = NULL;
cfg->pwr_save = true;
cfg->dongle_up = false; /* dongle is not up yet */
err = brcmf_init_priv_mem(cfg);
if (err != ZX_OK) {
return err;
}
brcmf_register_event_handlers(cfg);
mtx_init(&cfg->usr_sync, mtx_plain);
brcmf_init_escan(cfg);
brcmf_init_conf(cfg->conf);
cfg->vif_disabled = SYNC_COMPLETION_INIT;
return err;
}
static void wl_deinit_priv(struct brcmf_cfg80211_info* cfg) {
cfg->dongle_up = false; /* dongle down */
brcmf_abort_scanning(cfg);
brcmf_deinit_priv_mem(cfg);
}
static void init_vif_event(struct brcmf_cfg80211_vif_event* event) {
event->vif_event_wait = SYNC_COMPLETION_INIT;
mtx_init(&event->vif_event_lock, mtx_plain);
}
extern bool gl_chip_is_4359;
static zx_status_t brcmf_dongle_roam(struct brcmf_if* ifp) {
zx_status_t err;
uint32_t bcn_timeout;
uint32_t roamtrigger[2];
uint32_t roam_delta[2];
if (gl_chip_is_4359) {
return 0;
}
/* Configure beacon timeout value based upon roaming setting */
if (ifp->drvr->settings->roamoff) {
bcn_timeout = BRCMF_DEFAULT_BCN_TIMEOUT_ROAM_OFF;
} else {
bcn_timeout = BRCMF_DEFAULT_BCN_TIMEOUT_ROAM_ON;
}
err = brcmf_fil_iovar_int_set(ifp, "bcn_timeout", bcn_timeout);
if (err != ZX_OK) {
brcmf_err("bcn_timeout error (%d)\n", err);
goto roam_setup_done;
}
/* Enable/Disable built-in roaming to allow supplicant to take care of
* roaming.
*/
brcmf_dbg(INFO, "Internal Roaming = %s\n", ifp->drvr->settings->roamoff ? "Off" : "On");
err = brcmf_fil_iovar_int_set(ifp, "roam_off", ifp->drvr->settings->roamoff);
if (err != ZX_OK) {
brcmf_err("roam_off error (%d)\n", err);
goto roam_setup_done;
}
roamtrigger[0] = WL_ROAM_TRIGGER_LEVEL;
roamtrigger[1] = BRCM_BAND_ALL;
err = brcmf_fil_cmd_data_set(ifp, BRCMF_C_SET_ROAM_TRIGGER, (void*)roamtrigger,
sizeof(roamtrigger));
if (err != ZX_OK) {
brcmf_err("WLC_SET_ROAM_TRIGGER error (%d)\n", err);
goto roam_setup_done;
}
roam_delta[0] = WL_ROAM_DELTA;
roam_delta[1] = BRCM_BAND_ALL;
err =
brcmf_fil_cmd_data_set(ifp, BRCMF_C_SET_ROAM_DELTA, (void*)roam_delta, sizeof(roam_delta));
if (err != ZX_OK) {
brcmf_err("WLC_SET_ROAM_DELTA error (%d)\n", err);
goto roam_setup_done;
}
roam_setup_done:
return err;
}
static zx_status_t brcmf_dongle_scantime(struct brcmf_if* ifp) {
zx_status_t err = ZX_OK;
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_SCAN_CHANNEL_TIME, BRCMF_SCAN_CHANNEL_TIME);
if (err != ZX_OK) {
brcmf_err("Scan assoc time error (%d)\n", err);
goto dongle_scantime_out;
}
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_SCAN_UNASSOC_TIME, BRCMF_SCAN_UNASSOC_TIME);
if (err != ZX_OK) {
brcmf_err("Scan unassoc time error (%d)\n", err);
goto dongle_scantime_out;
}
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_SCAN_PASSIVE_TIME, BRCMF_SCAN_PASSIVE_TIME);
if (err != ZX_OK) {
brcmf_err("Scan passive time error (%d)\n", err);
goto dongle_scantime_out;
}
dongle_scantime_out:
return err;
}
static void brcmf_update_bw40_channel_flag(struct ieee80211_channel* channel,
struct brcmu_chan* ch) {
uint32_t ht40_flag;
ht40_flag = channel->flags & IEEE80211_CHAN_NO_HT40;
if (ch->sb == BRCMU_CHAN_SB_U) {
if (ht40_flag == IEEE80211_CHAN_NO_HT40) {
channel->flags &= ~IEEE80211_CHAN_NO_HT40;
}
channel->flags |= IEEE80211_CHAN_NO_HT40PLUS;
} else {
/* It should be one of
* IEEE80211_CHAN_NO_HT40 or
* IEEE80211_CHAN_NO_HT40PLUS
*/
channel->flags &= ~IEEE80211_CHAN_NO_HT40;
if (ht40_flag == IEEE80211_CHAN_NO_HT40) {
channel->flags |= IEEE80211_CHAN_NO_HT40MINUS;
}
}
}
static zx_status_t brcmf_construct_chaninfo(struct brcmf_cfg80211_info* cfg, uint32_t bw_cap[]) {
struct brcmf_if* ifp = cfg_to_if(cfg);
struct ieee80211_supported_band* band;
struct ieee80211_channel* channel;
struct wiphy* wiphy;
struct brcmf_chanspec_list* list;
struct brcmu_chan ch;
zx_status_t err;
uint8_t* pbuf;
uint32_t i, j;
uint32_t total;
uint32_t chaninfo;
pbuf = calloc(1, BRCMF_DCMD_MEDLEN);
if (pbuf == NULL) {
return ZX_ERR_NO_MEMORY;
}
list = (struct brcmf_chanspec_list*)pbuf;
err = brcmf_fil_iovar_data_get(ifp, "chanspecs", pbuf, BRCMF_DCMD_MEDLEN);
if (err != ZX_OK) {
brcmf_err("get chanspecs error (%d)\n", err);
goto fail_pbuf;
}
wiphy = cfg_to_wiphy(cfg);
band = wiphy->bands[NL80211_BAND_2GHZ];
if (band)
for (i = 0; i < band->n_channels; i++) {
band->channels[i].flags = IEEE80211_CHAN_DISABLED;
}
band = wiphy->bands[NL80211_BAND_5GHZ];
if (band)
for (i = 0; i < band->n_channels; i++) {
band->channels[i].flags = IEEE80211_CHAN_DISABLED;
}
total = list->count;
for (i = 0; i < total; i++) {
ch.chspec = (uint16_t)list->element[i];
cfg->d11inf.decchspec(&ch);
if (ch.band == BRCMU_CHAN_BAND_2G) {
band = wiphy->bands[NL80211_BAND_2GHZ];
} else if (ch.band == BRCMU_CHAN_BAND_5G) {
band = wiphy->bands[NL80211_BAND_5GHZ];
} else {
brcmf_err("Invalid channel Spec. 0x%x.\n", ch.chspec);
continue;
}
if (!band) {
continue;
}
if (!(bw_cap[band->band] & WLC_BW_40MHZ_BIT) && ch.bw == BRCMU_CHAN_BW_40) {
continue;
}
if (!(bw_cap[band->band] & WLC_BW_80MHZ_BIT) && ch.bw == BRCMU_CHAN_BW_80) {
continue;
}
channel = NULL;
for (j = 0; j < band->n_channels; j++) {
if (band->channels[j].hw_value == ch.control_ch_num) {
channel = &band->channels[j];
break;
}
}
if (!channel) {
/* It seems firmware supports some channel we never
* considered. Something new in IEEE standard?
*/
brcmf_err("Ignoring unexpected firmware channel %d\n", ch.control_ch_num);
continue;
}
if (channel->orig_flags & IEEE80211_CHAN_DISABLED) {
continue;
}
/* assuming the chanspecs order is HT20,
* HT40 upper, HT40 lower, and VHT80.
*/
if (ch.bw == BRCMU_CHAN_BW_80) {
channel->flags &= ~IEEE80211_CHAN_NO_80MHZ;
} else if (ch.bw == BRCMU_CHAN_BW_40) {
brcmf_update_bw40_channel_flag(channel, &ch);
} else {
/* enable the channel and disable other bandwidths
* for now as mentioned order assure they are enabled
* for subsequent chanspecs.
*/
channel->flags = IEEE80211_CHAN_NO_HT40 | IEEE80211_CHAN_NO_80MHZ;
ch.bw = BRCMU_CHAN_BW_20;
cfg->d11inf.encchspec(&ch);
chaninfo = ch.chspec;
err = brcmf_fil_bsscfg_int_get(ifp, "per_chan_info", &chaninfo);
if (err == ZX_OK) {
if (chaninfo & WL_CHAN_RADAR) {
channel->flags |= (IEEE80211_CHAN_RADAR | IEEE80211_CHAN_NO_IR);
}
if (chaninfo & WL_CHAN_PASSIVE) {
channel->flags |= IEEE80211_CHAN_NO_IR;
}
}
}
}
fail_pbuf:
free(pbuf);
return err;
}
static zx_status_t brcmf_enable_bw40_2g(struct brcmf_cfg80211_info* cfg) {
struct brcmf_if* ifp = cfg_to_if(cfg);
struct ieee80211_supported_band* band;
struct brcmf_fil_bwcap_le band_bwcap;
struct brcmf_chanspec_list* list;
uint8_t* pbuf;
uint32_t val;
zx_status_t err;
struct brcmu_chan ch;
uint32_t num_chan;
int i, j;
/* verify support for bw_cap command */
val = WLC_BAND_5G;
err = brcmf_fil_iovar_int_get(ifp, "bw_cap", &val);
if (err == ZX_OK) {
/* only set 2G bandwidth using bw_cap command */
band_bwcap.band = WLC_BAND_2G;
band_bwcap.bw_cap = WLC_BW_CAP_40MHZ;
err = brcmf_fil_iovar_data_set(ifp, "bw_cap", &band_bwcap, sizeof(band_bwcap));
} else {
brcmf_dbg(INFO, "fallback to mimo_bw_cap\n");
val = WLC_N_BW_40ALL;
err = brcmf_fil_iovar_int_set(ifp, "mimo_bw_cap", val);
}
if (err == ZX_OK) {
/* update channel info in 2G band */
pbuf = calloc(1, BRCMF_DCMD_MEDLEN);
if (pbuf == NULL) {
return ZX_ERR_NO_MEMORY;
}
ch.band = BRCMU_CHAN_BAND_2G;
ch.bw = BRCMU_CHAN_BW_40;
ch.sb = BRCMU_CHAN_SB_NONE;
ch.chnum = 0;
cfg->d11inf.encchspec(&ch);
/* pass encoded chanspec in query */
*(uint16_t*)pbuf = ch.chspec;
err = brcmf_fil_iovar_data_get(ifp, "chanspecs", pbuf, BRCMF_DCMD_MEDLEN);
if (err != ZX_OK) {
brcmf_err("get chanspecs error (%d)\n", err);
free(pbuf);
return err;
}
band = cfg_to_wiphy(cfg)->bands[NL80211_BAND_2GHZ];
list = (struct brcmf_chanspec_list*)pbuf;
num_chan = list->count;
for (i = 0; i < (int)num_chan; i++) {
ch.chspec = (uint16_t)list->element[i];
cfg->d11inf.decchspec(&ch);
if (WARN_ON(ch.band != BRCMU_CHAN_BAND_2G)) {
continue;
}
if (WARN_ON(ch.bw != BRCMU_CHAN_BW_40)) {
continue;
}
for (j = 0; j < (int)band->n_channels; j++) {
if (band->channels[j].hw_value == ch.control_ch_num) {
break;
}
}
if (WARN_ON(j == (int)band->n_channels)) {
continue;
}
brcmf_update_bw40_channel_flag(&band->channels[j], &ch);
}
free(pbuf);
}
return err;
}
static void brcmf_get_bwcap(struct brcmf_if* ifp, uint32_t bw_cap[]) {
uint32_t band, mimo_bwcap;
zx_status_t err;
band = WLC_BAND_2G;
err = brcmf_fil_iovar_int_get(ifp, "bw_cap", &band);
if (err == ZX_OK) {
bw_cap[NL80211_BAND_2GHZ] = band;
band = WLC_BAND_5G;
err = brcmf_fil_iovar_int_get(ifp, "bw_cap", &band);
if (err == ZX_OK) {
bw_cap[NL80211_BAND_5GHZ] = band;
return;
}
WARN_ON(1);
return;
}
brcmf_dbg(INFO, "fallback to mimo_bw_cap info\n");
mimo_bwcap = 0;
err = brcmf_fil_iovar_int_get(ifp, "mimo_bw_cap", &mimo_bwcap);
if (err != ZX_OK) { /* assume 20MHz if firmware does not give a clue */
mimo_bwcap = WLC_N_BW_20ALL;
}
switch (mimo_bwcap) {
case WLC_N_BW_40ALL:
bw_cap[NL80211_BAND_2GHZ] |= WLC_BW_40MHZ_BIT;
/* fall-thru */
case WLC_N_BW_20IN2G_40IN5G:
bw_cap[NL80211_BAND_5GHZ] |= WLC_BW_40MHZ_BIT;
/* fall-thru */
case WLC_N_BW_20ALL:
bw_cap[NL80211_BAND_2GHZ] |= WLC_BW_20MHZ_BIT;
bw_cap[NL80211_BAND_5GHZ] |= WLC_BW_20MHZ_BIT;
break;
default:
brcmf_err("invalid mimo_bw_cap value\n");
}
}
static void brcmf_update_ht_cap(struct ieee80211_supported_band* band, uint32_t bw_cap[2],
uint32_t nchain) {
band->ht_cap.ht_supported = true;
if (bw_cap[band->band] & WLC_BW_40MHZ_BIT) {
band->ht_cap.cap |= IEEE80211_HT_CAP_SGI_40;
band->ht_cap.cap |= IEEE80211_HT_CAP_SUP_WIDTH_20_40;
}
band->ht_cap.cap |= IEEE80211_HT_CAP_SGI_20;
band->ht_cap.cap |= IEEE80211_HT_CAP_DSSSCCK40;
band->ht_cap.ampdu_factor = IEEE80211_HT_MAX_AMPDU_64K;
band->ht_cap.ampdu_density = IEEE80211_HT_MPDU_DENSITY_16;
memset(band->ht_cap.mcs.rx_mask, 0xff, nchain);
band->ht_cap.mcs.tx_params = IEEE80211_HT_MCS_TX_DEFINED;
}
static uint16_t brcmf_get_mcs_map(uint32_t nchain, enum ieee80211_vht_mcs_support supp) {
uint16_t mcs_map;
int i;
for (i = 0, mcs_map = 0xFFFF; i < (int)nchain; i++) {
mcs_map = (mcs_map << 2) | supp;
}
return mcs_map;
}
static void brcmf_update_vht_cap(struct ieee80211_supported_band* band, uint32_t bw_cap[2],
uint32_t nchain, uint32_t txstreams, uint32_t txbf_bfe_cap,
uint32_t txbf_bfr_cap) {
uint16_t mcs_map;
/* not allowed in 2.4G band */
if (band->band == NL80211_BAND_2GHZ) {
return;
}
band->vht_cap.vht_supported = true;
/* 80MHz is mandatory */
band->vht_cap.cap |= IEEE80211_VHT_CAP_SHORT_GI_80;
if (bw_cap[band->band] & WLC_BW_160MHZ_BIT) {
band->vht_cap.cap |= IEEE80211_VHT_CAP_SUPP_CHAN_WIDTH_160MHZ;
band->vht_cap.cap |= IEEE80211_VHT_CAP_SHORT_GI_160;
}
/* all support 256-QAM */
mcs_map = brcmf_get_mcs_map(nchain, IEEE80211_VHT_MCS_SUPPORT_0_9);
band->vht_cap.vht_mcs.rx_mcs_map = mcs_map;
band->vht_cap.vht_mcs.tx_mcs_map = mcs_map;
/* Beamforming support information */
if (txbf_bfe_cap & BRCMF_TXBF_SU_BFE_CAP) {
band->vht_cap.cap |= IEEE80211_VHT_CAP_SU_BEAMFORMEE_CAPABLE;
}
if (txbf_bfe_cap & BRCMF_TXBF_MU_BFE_CAP) {
band->vht_cap.cap |= IEEE80211_VHT_CAP_MU_BEAMFORMEE_CAPABLE;
}
if (txbf_bfr_cap & BRCMF_TXBF_SU_BFR_CAP) {
band->vht_cap.cap |= IEEE80211_VHT_CAP_SU_BEAMFORMER_CAPABLE;
}
if (txbf_bfr_cap & BRCMF_TXBF_MU_BFR_CAP) {
band->vht_cap.cap |= IEEE80211_VHT_CAP_MU_BEAMFORMER_CAPABLE;
}
if ((txbf_bfe_cap || txbf_bfr_cap) && (txstreams > 1)) {
band->vht_cap.cap |= (2 << IEEE80211_VHT_CAP_BEAMFORMEE_STS_SHIFT);
band->vht_cap.cap |= ((txstreams - 1) << IEEE80211_VHT_CAP_SOUNDING_DIMENSIONS_SHIFT);
band->vht_cap.cap |= IEEE80211_VHT_CAP_VHT_LINK_ADAPTATION_VHT_MRQ_MFB;
}
}
static zx_status_t brcmf_setup_wiphybands(struct wiphy* wiphy) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_if* ifp = cfg_to_if(cfg);
uint32_t nmode = 0;
uint32_t vhtmode = 0;
uint32_t bw_cap[2] = {WLC_BW_20MHZ_BIT, WLC_BW_20MHZ_BIT};
uint32_t rxchain;
uint32_t nchain;
zx_status_t err;
int32_t i;
struct ieee80211_supported_band* band;
uint32_t txstreams = 0;
uint32_t txbf_bfe_cap = 0;
uint32_t txbf_bfr_cap = 0;
brcmf_dbg(TEMP, "Enter");
(void)brcmf_fil_iovar_int_get(ifp, "vhtmode", &vhtmode);
err = brcmf_fil_iovar_int_get(ifp, "nmode", &nmode);
if (err != ZX_OK) {
brcmf_err("nmode error (%d)\n", err);
} else {
brcmf_get_bwcap(ifp, bw_cap);
}
brcmf_dbg(INFO, "nmode=%d, vhtmode=%d, bw_cap=(%d, %d)\n", nmode, vhtmode,
bw_cap[NL80211_BAND_2GHZ], bw_cap[NL80211_BAND_5GHZ]);
err = brcmf_fil_iovar_int_get(ifp, "rxchain", &rxchain);
if (err != ZX_OK) {
brcmf_err("rxchain error (%d)\n", err);
nchain = 1;
} else {
for (nchain = 0; rxchain; nchain++) {
rxchain = rxchain & (rxchain - 1);
}
}
brcmf_dbg(INFO, "nchain=%d\n", nchain);
err = brcmf_construct_chaninfo(cfg, bw_cap);
if (err != ZX_OK) {
brcmf_err("brcmf_construct_chaninfo failed (%d)\n", err);
return err;
}
if (vhtmode) {
(void)brcmf_fil_iovar_int_get(ifp, "txstreams", &txstreams);
(void)brcmf_fil_iovar_int_get(ifp, "txbf_bfe_cap", &txbf_bfe_cap);
(void)brcmf_fil_iovar_int_get(ifp, "txbf_bfr_cap", &txbf_bfr_cap);
}
for (i = 0; i < (int32_t)ARRAY_SIZE(wiphy->bands); i++) {
band = wiphy->bands[i];
if (band == NULL) {
continue;
}
if (nmode) {
brcmf_update_ht_cap(band, bw_cap, nchain);
}
if (vhtmode) {
brcmf_update_vht_cap(band, bw_cap, nchain, txstreams, txbf_bfe_cap, txbf_bfr_cap);
}
}
return ZX_OK;
}
static const struct ieee80211_txrx_stypes brcmf_txrx_stypes[NUM_NL80211_IFTYPES] = {
[NL80211_IFTYPE_STATION] = {
.tx = 0xffff,
.rx = BIT(IEEE80211_STYPE_ACTION >> 4) |
BIT(IEEE80211_STYPE_PROBE_REQ >> 4)
},
[NL80211_IFTYPE_P2P_CLIENT] = {
.tx = 0xffff,
.rx = BIT(IEEE80211_STYPE_ACTION >> 4) |
BIT(IEEE80211_STYPE_PROBE_REQ >> 4)
},
[NL80211_IFTYPE_P2P_GO] = {
.tx = 0xffff,
.rx = BIT(IEEE80211_STYPE_ASSOC_REQ >> 4) |
BIT(IEEE80211_STYPE_REASSOC_REQ >> 4) |
BIT(IEEE80211_STYPE_PROBE_REQ >> 4) |
BIT(IEEE80211_STYPE_DISASSOC >> 4) |
BIT(IEEE80211_STYPE_AUTH >> 4) |
BIT(IEEE80211_STYPE_DEAUTH >> 4) |
BIT(IEEE80211_STYPE_ACTION >> 4)
},
[NL80211_IFTYPE_P2P_DEVICE] = {
.tx = 0xffff,
.rx = BIT(IEEE80211_STYPE_ACTION >> 4) | BIT(IEEE80211_STYPE_PROBE_REQ >> 4)
}
};
/**
* brcmf_setup_ifmodes() - determine interface modes and combinations.
*
* @wiphy: wiphy object.
* @ifp: interface object needed for feat module api.
*
* The interface modes and combinations are determined dynamically here
* based on firmware functionality.
*
* no p2p and no mbss:
*
* #STA <= 1, #AP <= 1, channels = 1, 2 total
*
* no p2p and mbss:
*
* #STA <= 1, #AP <= 1, channels = 1, 2 total
* #AP <= 4, matching BI, channels = 1, 4 total
*
* p2p, no mchan, and mbss:
*
* #STA <= 1, #P2P-DEV <= 1, #{P2P-CL, P2P-GO} <= 1, channels = 1, 3 total
* #STA <= 1, #P2P-DEV <= 1, #AP <= 1, #P2P-CL <= 1, channels = 1, 4 total
* #AP <= 4, matching BI, channels = 1, 4 total
*
* p2p, mchan, and mbss:
*
* #STA <= 1, #P2P-DEV <= 1, #{P2P-CL, P2P-GO} <= 1, channels = 2, 3 total
* #STA <= 1, #P2P-DEV <= 1, #AP <= 1, #P2P-CL <= 1, channels = 1, 4 total
* #AP <= 4, matching BI, channels = 1, 4 total
*/
static zx_status_t brcmf_setup_ifmodes(struct wiphy* wiphy, struct brcmf_if* ifp) {
struct ieee80211_iface_combination* combo = NULL;
struct ieee80211_iface_limit* c0_limits = NULL;
struct ieee80211_iface_limit* p2p_limits = NULL;
struct ieee80211_iface_limit* mbss_limits = NULL;
bool mbss, p2p;
int i, c, n_combos;
mbss = brcmf_feat_is_enabled(ifp, BRCMF_FEAT_MBSS);
p2p = brcmf_feat_is_enabled(ifp, BRCMF_FEAT_P2P);
n_combos = 1 + !!p2p + !!mbss;
combo = calloc(n_combos, sizeof(*combo));
if (!combo) {
goto err;
}
wiphy->interface_modes =
BIT(NL80211_IFTYPE_STATION) | BIT(NL80211_IFTYPE_ADHOC) | BIT(NL80211_IFTYPE_AP);
c = 0;
i = 0;
c0_limits = calloc(p2p ? 3 : 2, sizeof(*c0_limits));
if (!c0_limits) {
goto err;
}
c0_limits[i].max = 1;
c0_limits[i++].types = BIT(NL80211_IFTYPE_STATION);
if (p2p) {
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_MCHAN)) {
combo[c].num_different_channels = 2;
} else {
combo[c].num_different_channels = 1;
}
wiphy->interface_modes |= BIT(NL80211_IFTYPE_P2P_CLIENT) | BIT(NL80211_IFTYPE_P2P_GO) |
BIT(NL80211_IFTYPE_P2P_DEVICE);
c0_limits[i].max = 1;
c0_limits[i++].types = BIT(NL80211_IFTYPE_P2P_DEVICE);
c0_limits[i].max = 1;
c0_limits[i++].types = BIT(NL80211_IFTYPE_P2P_CLIENT) | BIT(NL80211_IFTYPE_P2P_GO);
} else {
combo[c].num_different_channels = 1;
c0_limits[i].max = 1;
c0_limits[i++].types = BIT(NL80211_IFTYPE_AP);
}
combo[c].max_interfaces = i;
combo[c].n_limits = i;
combo[c].limits = c0_limits;
if (p2p) {
c++;
i = 0;
p2p_limits = calloc(4, sizeof(*p2p_limits));
if (!p2p_limits) {
goto err;
}
p2p_limits[i].max = 1;
p2p_limits[i++].types = BIT(NL80211_IFTYPE_STATION);
p2p_limits[i].max = 1;
p2p_limits[i++].types = BIT(NL80211_IFTYPE_AP);
p2p_limits[i].max = 1;
p2p_limits[i++].types = BIT(NL80211_IFTYPE_P2P_CLIENT);
p2p_limits[i].max = 1;
p2p_limits[i++].types = BIT(NL80211_IFTYPE_P2P_DEVICE);
combo[c].num_different_channels = 1;
combo[c].max_interfaces = i;
combo[c].n_limits = i;
combo[c].limits = p2p_limits;
}
if (mbss) {
c++;
i = 0;
mbss_limits = calloc(1, sizeof(*mbss_limits));
if (!mbss_limits) {
goto err;
}
mbss_limits[i].max = 4;
mbss_limits[i++].types = BIT(NL80211_IFTYPE_AP);
combo[c].beacon_int_infra_match = true;
combo[c].num_different_channels = 1;
combo[c].max_interfaces = 4;
combo[c].n_limits = i;
combo[c].limits = mbss_limits;
}
wiphy->n_iface_combinations = n_combos;
wiphy->iface_combinations = combo;
return ZX_OK;
err:
free(c0_limits);
free(p2p_limits);
free(mbss_limits);
free(combo);
return ZX_ERR_NO_MEMORY;
}
#ifdef CONFIG_PM
static const struct wiphy_wowlan_support brcmf_wowlan_support = {
.flags = WIPHY_WOWLAN_MAGIC_PKT | WIPHY_WOWLAN_DISCONNECT,
.n_patterns = BRCMF_WOWL_MAXPATTERNS,
.pattern_max_len = BRCMF_WOWL_MAXPATTERNSIZE,
.pattern_min_len = 1,
.max_pkt_offset = 1500,
};
#endif
static void brcmf_wiphy_wowl_params(struct wiphy* wiphy, struct brcmf_if* ifp) {
#ifdef CONFIG_PM
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct wiphy_wowlan_support* wowl;
wowl = brcmu_alloc_and_copy(&brcmf_wowlan_support, sizeof(brcmf_wowlan_support));
if (!wowl) {
brcmf_err("only support basic wowlan features\n");
wiphy->wowlan = &brcmf_wowlan_support;
return;
}
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_PNO)) {
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_WOWL_ND)) {
wowl->flags |= WIPHY_WOWLAN_NET_DETECT;
wowl->max_nd_match_sets = BRCMF_PNO_MAX_PFN_COUNT;
cfg->wowl.nd_data_wait = SYNC_COMPLETION_INIT;
}
}
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_WOWL_GTK)) {
wowl->flags |= WIPHY_WOWLAN_SUPPORTS_GTK_REKEY;
wowl->flags |= WIPHY_WOWLAN_GTK_REKEY_FAILURE;
}
wiphy->wowlan = wowl;
#endif
}
static zx_status_t brcmf_setup_wiphy(struct wiphy* wiphy, struct brcmf_if* ifp) {
struct brcmf_pub* drvr = ifp->drvr;
const struct ieee80211_iface_combination* combo;
struct ieee80211_supported_band* band;
uint16_t max_interfaces = 0;
bool gscan;
uint32_t bandlist[3];
uint32_t n_bands;
zx_status_t err;
int i;
wiphy->max_scan_ssids = WL_NUM_SCAN_MAX;
wiphy->max_scan_ie_len = BRCMF_SCAN_IE_LEN_MAX;
wiphy->max_num_pmkids = BRCMF_MAXPMKID;
err = brcmf_setup_ifmodes(wiphy, ifp);
if (err != ZX_OK) {
return err;
}
for (i = 0, combo = wiphy->iface_combinations; i < wiphy->n_iface_combinations; i++, combo++) {
max_interfaces = max(max_interfaces, combo->max_interfaces);
}
for (i = 0; i < max_interfaces && i < (int)ARRAY_SIZE(drvr->addresses); i++) {
uint8_t* addr = drvr->addresses[i].addr;
memcpy(addr, drvr->mac, ETH_ALEN);
if (i) {
addr[0] |= BIT(1);
addr[ETH_ALEN - 1] ^= i;
}
}
wiphy->addresses = drvr->addresses;
wiphy->n_addresses = i;
wiphy->signal_type = CFG80211_SIGNAL_TYPE_MBM;
wiphy->cipher_suites = brcmf_cipher_suites;
wiphy->n_cipher_suites = ARRAY_SIZE(brcmf_cipher_suites);
if (!brcmf_feat_is_enabled(ifp, BRCMF_FEAT_MFP)) {
wiphy->n_cipher_suites--;
}
wiphy->bss_select_support = BIT(NL80211_BSS_SELECT_ATTR_RSSI) |
BIT(NL80211_BSS_SELECT_ATTR_BAND_PREF) |
BIT(NL80211_BSS_SELECT_ATTR_RSSI_ADJUST);
wiphy->flags |= WIPHY_FLAG_NETNS_OK | WIPHY_FLAG_PS_ON_BY_DEFAULT | WIPHY_FLAG_OFFCHAN_TX |
WIPHY_FLAG_HAS_REMAIN_ON_CHANNEL;
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_TDLS)) {
wiphy->flags |= WIPHY_FLAG_SUPPORTS_TDLS;
}
if (!ifp->drvr->settings->roamoff) {
wiphy->flags |= WIPHY_FLAG_SUPPORTS_FW_ROAM;
}
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_FWSUP)) {
brcmf_dbg(TEMP, "* * Set feature NL80211_EXT_FEATURE_4WAY_HANDSHAKE_STA_PSK on wiphy");
brcmf_dbg(TEMP, "* * Set feature NL80211_EXT_FEATURE_4WAY_HANDSHAKE_STA_1X on wiphy");
}
wiphy->mgmt_stypes = brcmf_txrx_stypes;
wiphy->max_remain_on_channel_duration = 5000;
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_PNO)) {
gscan = brcmf_feat_is_enabled(ifp, BRCMF_FEAT_GSCAN);
brcmf_pno_wiphy_params(wiphy, gscan);
}
/* vendor commands/events support */
wiphy->vendor_commands = brcmf_vendor_cmds;
wiphy->n_vendor_commands = BRCMF_VNDR_CMDS_LAST - 1;
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_WOWL)) {
brcmf_wiphy_wowl_params(wiphy, ifp);
}
err = brcmf_fil_cmd_data_get(ifp, BRCMF_C_GET_BANDLIST, &bandlist, sizeof(bandlist));
if (err != ZX_OK) {
brcmf_err("could not obtain band info: err=%d\n", err);
return err;
}
/* first entry in bandlist is number of bands */
n_bands = bandlist[0];
for (i = 1; i <= (int)n_bands && i < (int)ARRAY_SIZE(bandlist); i++) {
if (bandlist[i] == WLC_BAND_2G) {
band = brcmu_alloc_and_copy(&__wl_band_2ghz, sizeof(__wl_band_2ghz));
if (!band) {
return ZX_ERR_NO_MEMORY;
}
band->channels = brcmu_alloc_and_copy(&__wl_2ghz_channels, sizeof(__wl_2ghz_channels));
if (!band->channels) {
free(band);
return ZX_ERR_NO_MEMORY;
}
band->n_channels = ARRAY_SIZE(__wl_2ghz_channels);
wiphy->bands[NL80211_BAND_2GHZ] = band;
}
if (bandlist[i] == WLC_BAND_5G) {
band = brcmu_alloc_and_copy(&__wl_band_5ghz, sizeof(__wl_band_5ghz));
if (!band) {
return ZX_ERR_NO_MEMORY;
}
band->channels = brcmu_alloc_and_copy(&__wl_5ghz_channels, sizeof(__wl_5ghz_channels));
if (!band->channels) {
free(band);
return ZX_ERR_NO_MEMORY;
}
band->n_channels = ARRAY_SIZE(__wl_5ghz_channels);
wiphy->bands[NL80211_BAND_5GHZ] = band;
}
}
// TODO(cphoenix): Apply channel limits from device tree equivalent
brcmf_dbg(TEMP, "* * Tried to wiphy_read_of_freq_limits(wiphy)");
brcmf_dbg(TEMP, "* * This reads and applies channel limits from device tree");
return ZX_OK;
}
static zx_status_t brcmf_config_dongle(struct brcmf_cfg80211_info* cfg) {
struct net_device* ndev;
struct wireless_dev* wdev;
struct brcmf_if* ifp;
int32_t power_mode;
zx_status_t err = ZX_OK;
brcmf_dbg(TEMP, "Enter");
if (cfg->dongle_up) {
brcmf_dbg(TEMP, "Early done");
return err;
}
ndev = cfg_to_ndev(cfg);
wdev = ndev->ieee80211_ptr;
ifp = ndev_to_if(ndev);
/* make sure RF is ready for work */
brcmf_fil_cmd_int_set(ifp, BRCMF_C_UP, 0);
brcmf_dongle_scantime(ifp);
power_mode = cfg->pwr_save ? PM_FAST : PM_OFF;
err = brcmf_fil_cmd_int_set(ifp, BRCMF_C_SET_PM, power_mode);
if (err != ZX_OK) {
goto default_conf_out;
}
brcmf_dbg(INFO, "power save set to %s\n", (power_mode ? "enabled" : "disabled"));
err = brcmf_dongle_roam(ifp);
if (err != ZX_OK) {
goto default_conf_out;
}
err = brcmf_cfg80211_change_iface(wdev->wiphy, ndev, wdev->iftype, NULL);
if (err != ZX_OK) {
goto default_conf_out;
}
brcmf_configure_arp_nd_offload(ifp, true);
cfg->dongle_up = true;
default_conf_out:
brcmf_dbg(TEMP, "Returning %d", err);
return err;
}
static zx_status_t __brcmf_cfg80211_up(struct brcmf_if* ifp) {
brcmf_set_bit_in_array(BRCMF_VIF_STATUS_READY, &ifp->vif->sme_state);
return brcmf_config_dongle(ifp->drvr->config);
}
static zx_status_t __brcmf_cfg80211_down(struct brcmf_if* ifp) {
struct brcmf_cfg80211_info* cfg = ifp->drvr->config;
/*
* While going down, if associated with AP disassociate
* from AP to save power
*/
if (check_vif_up(ifp->vif)) {
brcmf_link_down(ifp->vif, WLAN_REASON_UNSPECIFIED);
/* Make sure WPA_Supplicant receives all the event
generated due to DISASSOC call to the fw to keep
the state fw and WPA_Supplicant state consistent
*/
msleep(500);
}
brcmf_abort_scanning(cfg);
brcmf_clear_bit_in_array(BRCMF_VIF_STATUS_READY, &ifp->vif->sme_state);
return ZX_OK;
}
zx_status_t brcmf_cfg80211_up(struct net_device* ndev) {
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_cfg80211_info* cfg = ifp->drvr->config;
zx_status_t err = ZX_OK;
mtx_lock(&cfg->usr_sync);
err = __brcmf_cfg80211_up(ifp);
mtx_unlock(&cfg->usr_sync);
return err;
}
zx_status_t brcmf_cfg80211_down(struct net_device* ndev) {
struct brcmf_if* ifp = ndev_to_if(ndev);
struct brcmf_cfg80211_info* cfg = ifp->drvr->config;
zx_status_t err = ZX_OK;
mtx_lock(&cfg->usr_sync);
err = __brcmf_cfg80211_down(ifp);
mtx_unlock(&cfg->usr_sync);
return err;
}
enum nl80211_iftype brcmf_cfg80211_get_iftype(struct brcmf_if* ifp) {
struct wireless_dev* wdev = &ifp->vif->wdev;
return wdev->iftype;
}
bool brcmf_get_vif_state_any(struct brcmf_cfg80211_info* cfg, unsigned long state) {
struct brcmf_cfg80211_vif* vif;
list_for_every_entry(&cfg->vif_list, vif, struct brcmf_cfg80211_vif, list) {
if (brcmf_test_bit_in_array(state, &vif->sme_state)) {
return true;
}
}
return false;
}
void brcmf_cfg80211_arm_vif_event(struct brcmf_cfg80211_info* cfg, struct brcmf_cfg80211_vif* vif,
uint8_t pending_action) {
struct brcmf_cfg80211_vif_event* event = &cfg->vif_event;
mtx_lock(&event->vif_event_lock);
event->vif = vif;
event->action = 0;
sync_completion_reset(&event->vif_event_wait);
cfg->vif_event_pending_action = pending_action;
mtx_unlock(&event->vif_event_lock);
}
void brcmf_cfg80211_disarm_vif_event(struct brcmf_cfg80211_info* cfg) {
struct brcmf_cfg80211_vif_event* event = &cfg->vif_event;
mtx_lock(&event->vif_event_lock);
event->vif = NULL;
event->action = 0;
mtx_unlock(&event->vif_event_lock);
}
bool brcmf_cfg80211_vif_event_armed(struct brcmf_cfg80211_info* cfg) {
struct brcmf_cfg80211_vif_event* event = &cfg->vif_event;
bool armed;
mtx_lock(&event->vif_event_lock);
armed = event->vif != NULL;
mtx_unlock(&event->vif_event_lock);
return armed;
}
zx_status_t brcmf_cfg80211_wait_vif_event(struct brcmf_cfg80211_info* cfg, zx_duration_t timeout) {
struct brcmf_cfg80211_vif_event* event = &cfg->vif_event;
return sync_completion_wait(&event->vif_event_wait, timeout);
}
static zx_status_t brcmf_translate_country_code(struct brcmf_pub* drvr, char alpha2[2],
struct brcmf_fil_country_le* ccreq) {
struct brcmfmac_pd_cc* country_codes;
struct brcmfmac_pd_cc_entry* cc;
int32_t found_index;
int i;
country_codes = drvr->settings->country_codes;
if (!country_codes) {
brcmf_dbg(TRACE, "No country codes configured for device\n");
return ZX_ERR_INVALID_ARGS;
}
if ((alpha2[0] == ccreq->country_abbrev[0]) && (alpha2[1] == ccreq->country_abbrev[1])) {
brcmf_dbg(TRACE, "Country code already set\n");
return ZX_ERR_ALREADY_EXISTS;
}
found_index = -1;
for (i = 0; i < country_codes->table_size; i++) {
cc = &country_codes->table[i];
if ((cc->iso3166[0] == '\0') && (found_index == -1)) {
found_index = i;
}
if ((cc->iso3166[0] == alpha2[0]) && (cc->iso3166[1] == alpha2[1])) {
found_index = i;
break;
}
}
if (found_index == -1) {
brcmf_dbg(TRACE, "No country code match found\n");
return ZX_ERR_INVALID_ARGS;
}
memset(ccreq, 0, sizeof(*ccreq));
ccreq->rev = country_codes->table[found_index].rev;
memcpy(ccreq->ccode, country_codes->table[found_index].cc, BRCMF_COUNTRY_BUF_SZ);
ccreq->country_abbrev[0] = alpha2[0];
ccreq->country_abbrev[1] = alpha2[1];
ccreq->country_abbrev[2] = 0;
return ZX_OK;
}
static void brcmf_cfg80211_reg_notifier(struct wiphy* wiphy, struct regulatory_request* req) {
struct brcmf_cfg80211_info* cfg = wiphy_to_cfg(wiphy);
struct brcmf_if* ifp = cfg_to_if(cfg);
struct brcmf_fil_country_le ccreq;
zx_status_t err;
int i;
/* The country code gets set to "00" by default at boot, ignore */
if (req->alpha2[0] == '0' && req->alpha2[1] == '0') {
return;
}
/* ignore non-ISO3166 country codes */
for (i = 0; i < (int)sizeof(req->alpha2); i++)
if (req->alpha2[i] < 'A' || req->alpha2[i] > 'Z') {
brcmf_err("not an ISO3166 code (0x%02x 0x%02x)\n", req->alpha2[0], req->alpha2[1]);
return;
}
brcmf_dbg(TRACE, "Enter: initiator=%d, alpha=%c%c\n", req->initiator, req->alpha2[0],
req->alpha2[1]);
err = brcmf_fil_iovar_data_get(ifp, "country", &ccreq, sizeof(ccreq));
if (err != ZX_OK) {
brcmf_err("Country code iovar returned err = %d\n", err);
return;
}
err = brcmf_translate_country_code(ifp->drvr, req->alpha2, &ccreq);
if (err != ZX_OK) {
return;
}
err = brcmf_fil_iovar_data_set(ifp, "country", &ccreq, sizeof(ccreq));
if (err != ZX_OK) {
brcmf_err("Firmware rejected country setting\n");
return;
}
brcmf_setup_wiphybands(wiphy);
}
static void brcmf_free_wiphy(struct wiphy* wiphy) {
int i;
if (!wiphy) {
return;
}
if (wiphy->iface_combinations) {
for (i = 0; i < wiphy->n_iface_combinations; i++) {
free(wiphy->iface_combinations[i].limits);
}
}
free(wiphy->iface_combinations);
if (wiphy->bands[NL80211_BAND_2GHZ]) {
free(wiphy->bands[NL80211_BAND_2GHZ]->channels);
free(wiphy->bands[NL80211_BAND_2GHZ]);
}
if (wiphy->bands[NL80211_BAND_5GHZ]) {
free(wiphy->bands[NL80211_BAND_5GHZ]->channels);
free(wiphy->bands[NL80211_BAND_5GHZ]);
}
#if IS_ENABLED(CONFIG_PM)
if (wiphy->wowlan != &brcmf_wowlan_support) {
free(wiphy->wowlan);
}
#endif
free(wiphy_to_cfg(wiphy));
free(wiphy);
}
struct brcmf_cfg80211_info* brcmf_cfg80211_attach(struct brcmf_pub* drvr,
struct brcmf_device* busdev,
bool p2pdev_forced) {
struct net_device* ndev = brcmf_get_ifp(drvr, 0)->ndev;
struct brcmf_cfg80211_info* cfg;
struct wiphy* wiphy;
struct cfg80211_ops* ops;
struct brcmf_cfg80211_vif* vif;
struct brcmf_if* ifp;
zx_status_t err = ZX_OK;
int32_t io_type;
uint16_t* cap = NULL;
brcmf_dbg(TEMP, "Enter");
if (!ndev) {
brcmf_err("ndev is invalid\n");
return NULL;
}
ops = brcmu_alloc_and_copy(&brcmf_cfg80211_ops, sizeof(*ops));
if (!ops) {
return NULL;
}
ifp = ndev_to_if(ndev);
#ifdef CONFIG_PM
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_WOWL_GTK)) {
ops->set_rekey_data = brcmf_cfg80211_set_rekey_data;
}
#endif
wiphy = calloc(1, sizeof(struct wiphy));
if (!wiphy) {
brcmf_err("Could not allocate wiphy device\n");
goto ops_out;
}
wiphy->ops = ops;
wiphy->cfg80211_info = calloc(1, sizeof(struct brcmf_cfg80211_info));
if (wiphy->cfg80211_info == NULL) {
free(wiphy);
goto ops_out;
}
memcpy(wiphy->perm_addr, drvr->mac, ETH_ALEN);
wiphy->dev = busdev;
cfg = wiphy_to_cfg(wiphy);
cfg->wiphy = wiphy;
cfg->ops = ops;
cfg->pub = drvr;
init_vif_event(&cfg->vif_event);
list_initialize(&cfg->vif_list);
err = brcmf_alloc_vif(cfg, NL80211_IFTYPE_STATION, &vif);
if (err != ZX_OK) {
goto wiphy_out;
}
vif->ifp = ifp;
vif->wdev.netdev = ndev;
ndev->ieee80211_ptr = &vif->wdev;
err = wl_init_priv(cfg);
if (err != ZX_OK) {
brcmf_err("Failed to init iwm_priv (%d)\n", err);
brcmf_free_vif(vif);
goto wiphy_out;
}
ifp->vif = vif;
/* determine d11 io type before wiphy setup */
err = brcmf_fil_cmd_int_get(ifp, BRCMF_C_GET_VERSION, (uint32_t*)&io_type);
if (err != ZX_OK) {
brcmf_err("Failed to get D11 version (%d)\n", err);
goto priv_out;
}
cfg->d11inf.io_type = (uint8_t)io_type;
brcmu_d11_attach(&cfg->d11inf);
err = brcmf_setup_wiphy(wiphy, ifp);
if (err != ZX_OK) {
goto priv_out;
}
brcmf_dbg(INFO, "Registering custom regulatory\n");
wiphy->reg_notifier = brcmf_cfg80211_reg_notifier;
wiphy->regulatory_flags |= REGULATORY_CUSTOM_REG;
brcmf_dbg(TEMP, "* * Wanted to wiphy_apply_custom_regulatory(wiphy, &brcmf_regdom);");
/* firmware defaults to 40MHz disabled in 2G band. We signal
* cfg80211 here that we do and have it decide we can enable
* it. But first check if device does support 2G operation.
*/
if (wiphy->bands[NL80211_BAND_2GHZ]) {
cap = &wiphy->bands[NL80211_BAND_2GHZ]->ht_cap.cap;
*cap |= IEEE80211_HT_CAP_SUP_WIDTH_20_40;
}
err = wiphy_register(wiphy);
if (err != ZX_OK) {
brcmf_err("Could not register wiphy device (%d)\n", err);
goto priv_out;
}
err = brcmf_setup_wiphybands(wiphy);
if (err != ZX_OK) {
brcmf_err("Setting wiphy bands failed (%d)\n", err);
goto wiphy_unreg_out;
}
/* If cfg80211 didn't disable 40MHz HT CAP in wiphy_register(),
* setup 40MHz in 2GHz band and enable OBSS scanning.
*/
if (cap && (*cap & IEEE80211_HT_CAP_SUP_WIDTH_20_40)) {
err = brcmf_enable_bw40_2g(cfg);
if (err == ZX_OK) {
err = brcmf_fil_iovar_int_set(ifp, "obss_coex", BRCMF_OBSS_COEX_AUTO);
} else {
*cap &= ~IEEE80211_HT_CAP_SUP_WIDTH_20_40;
}
}
/* p2p might require that "if-events" get processed by fweh. So
* activate the already registered event handlers now and activate
* the rest when initialization has completed. drvr->config needs to
* be assigned before activating events.
*/
drvr->config = cfg;
err = brcmf_fweh_activate_events(ifp);
if (err != ZX_OK) {
brcmf_err("FWEH activation failed (%d)\n", err);
goto wiphy_unreg_out;
}
err = brcmf_p2p_attach(cfg, p2pdev_forced);
if (err != ZX_OK) {
brcmf_err("P2P initialisation failed (%d)\n", err);
goto wiphy_unreg_out;
}
err = brcmf_btcoex_attach(cfg);
if (err != ZX_OK) {
brcmf_err("BT-coex initialisation failed (%d)\n", err);
brcmf_p2p_detach(&cfg->p2p);
goto wiphy_unreg_out;
}
err = brcmf_pno_attach(cfg);
if (err != ZX_OK) {
brcmf_err("PNO initialisation failed (%d)\n", err);
brcmf_btcoex_detach(cfg);
brcmf_p2p_detach(&cfg->p2p);
goto wiphy_unreg_out;
}
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_TDLS)) {
err = brcmf_fil_iovar_int_set(ifp, "tdls_enable", 1);
if (err != ZX_OK) {
brcmf_dbg(INFO, "TDLS not enabled (%d)\n", err);
wiphy->flags &= ~WIPHY_FLAG_SUPPORTS_TDLS;
} else {
brcmf_fweh_register(cfg->pub, BRCMF_E_TDLS_PEER_EVENT, brcmf_notify_tdls_peer_event);
}
}
/* (re-) activate FWEH event handling */
err = brcmf_fweh_activate_events(ifp);
if (err != ZX_OK) {
brcmf_err("FWEH activation failed (%d)\n", err);
goto detach;
}
/* Fill in some of the advertised nl80211 supported features */
if (brcmf_feat_is_enabled(ifp, BRCMF_FEAT_SCAN_RANDOM_MAC)) {
wiphy->features |= NL80211_FEATURE_SCHED_SCAN_RANDOM_MAC_ADDR;
#ifdef CONFIG_PM
if (wiphy->wowlan && wiphy->wowlan->flags & WIPHY_WOWLAN_NET_DETECT) {
wiphy->features |= NL80211_FEATURE_ND_RANDOM_MAC_ADDR;
}
#endif
}
brcmf_dbg(TEMP, "Exit");
return cfg;
detach:
brcmf_pno_detach(cfg);
brcmf_btcoex_detach(cfg);
brcmf_p2p_detach(&cfg->p2p);
wiphy_unreg_out:
brcmf_dbg(TEMP, "* * Would have called wiphy_unregister(cfg->wiphy);");
priv_out:
wl_deinit_priv(cfg);
brcmf_free_vif(vif);
ifp->vif = NULL;
wiphy_out:
brcmf_free_wiphy(wiphy);
ops_out:
free(ops);
return NULL;
}
void brcmf_cfg80211_detach(struct brcmf_cfg80211_info* cfg) {
if (!cfg) {
return;
}
brcmf_pno_detach(cfg);
brcmf_btcoex_detach(cfg);
brcmf_dbg(TEMP, "* * Would have called wiphy_unregister(cfg->wiphy);");
free(cfg->ops);
wl_deinit_priv(cfg);
brcmf_free_wiphy(cfg->wiphy);
}