src/fst/fst_group.c - platform/external/wpa_supplicant_8 - Git at Google

 /*
  * FST module - FST group object implementation
  * Copyright (c) 2014, Qualcomm Atheros, Inc.
  *
  * This software may be distributed under the terms of the BSD license.
  * See README for more details.
  */

 #include "utils/includes.h"
 #include "utils/common.h"
 #include "common/defs.h"
 #include "common/ieee802_11_defs.h"
 #include "common/ieee802_11_common.h"
 #include "drivers/driver.h"
 #include "fst/fst_internal.h"
 #include "fst/fst_defs.h"


 struct dl_list fst_global_groups_list;


 static void fst_dump_mb_ies(const char *group_id, const char *ifname,
 			    struct wpabuf *mbies)
 {
 	const u8 *p = wpabuf_head(mbies);
 	size_t s = wpabuf_len(mbies);

 	while (s >= 2) {
 		const struct multi_band_ie *mbie =
 			(const struct multi_band_ie *) p;
 		WPA_ASSERT(mbie->eid == WLAN_EID_MULTI_BAND);
 		WPA_ASSERT(2U + mbie->len >= sizeof(*mbie));

 		fst_printf(MSG_WARNING,
 			   "%s: %s: mb_ctrl=%u band_id=%u op_class=%u chan=%u bssid="
 			   MACSTR
 			   " beacon_int=%u tsf_offs=[%u %u %u %u %u %u %u %u] mb_cc=0x%02x tmout=%u",
 			   group_id, ifname,
 			   mbie->mb_ctrl, mbie->band_id, mbie->op_class,
 			   mbie->chan, MAC2STR(mbie->bssid), mbie->beacon_int,
 			   mbie->tsf_offs[0], mbie->tsf_offs[1],
 			   mbie->tsf_offs[2], mbie->tsf_offs[3],
 			   mbie->tsf_offs[4], mbie->tsf_offs[5],
 			   mbie->tsf_offs[6], mbie->tsf_offs[7],
 			   mbie->mb_connection_capability,
 			   mbie->fst_session_tmout);

 		p += 2 + mbie->len;
 		s -= 2 + mbie->len;
 	}
 }


 static void fst_fill_mb_ie(struct wpabuf *buf, const u8 *bssid,
 			   const u8 *own_addr, enum mb_band_id band, u8 channel)
 {
 	struct multi_band_ie *mbie;
 	size_t len = sizeof(*mbie);

 	if (own_addr)
 		len += ETH_ALEN;

 	mbie = wpabuf_put(buf, len);

 	os_memset(mbie, 0, len);

 	mbie->eid = WLAN_EID_MULTI_BAND;
 	mbie->len = len - 2;
 #ifdef HOSTAPD
 	mbie->mb_ctrl = MB_STA_ROLE_AP;
 	mbie->mb_connection_capability = MB_CONNECTION_CAPABILITY_AP;
 #else /* HOSTAPD */
 	mbie->mb_ctrl = MB_STA_ROLE_NON_PCP_NON_AP;
 	mbie->mb_connection_capability = 0;
 #endif /* HOSTAPD */
 	if (bssid)
 		os_memcpy(mbie->bssid, bssid, ETH_ALEN);
 	mbie->band_id = band;
 	mbie->op_class = 0;  /* means all */
 	mbie->chan = channel;
 	mbie->fst_session_tmout = FST_DEFAULT_SESSION_TIMEOUT_TU;

 	if (own_addr) {
 		mbie->mb_ctrl |= MB_CTRL_STA_MAC_PRESENT;
 		os_memcpy(&mbie[1], own_addr, ETH_ALEN);
 	}
 }


 static unsigned fst_fill_iface_mb_ies(struct fst_iface *f, struct wpabuf *buf)
 {
 	const  u8 *bssid;

 	bssid = fst_iface_get_bssid(f);
 	if (bssid) {
 		enum hostapd_hw_mode hw_mode;
 		u8 channel;

 		if (buf) {
 			fst_iface_get_channel_info(f, &hw_mode, &channel);
 			fst_fill_mb_ie(buf, bssid, fst_iface_get_addr(f),
 				       fst_hw_mode_to_band(hw_mode), channel);
 		}
 		return 1;
 	} else {
 		unsigned bands[MB_BAND_ID_WIFI_60GHZ + 1] = {};
 		struct hostapd_hw_modes *modes;
 		enum mb_band_id b;
 		int num_modes = fst_iface_get_hw_modes(f, &modes);
 		int ret = 0;

 		while (num_modes--) {
 			b = fst_hw_mode_to_band(modes->mode);
 			modes++;
 			if (b >= ARRAY_SIZE(bands) || bands[b]++)
 				continue;
 			ret++;
 			if (buf)
 				fst_fill_mb_ie(buf, NULL, fst_iface_get_addr(f),
 					       b, MB_STA_CHANNEL_ALL);
 		}
 		return ret;
 	}
 }


 static struct wpabuf * fst_group_create_mb_ie(struct fst_group *g,
 					      struct fst_iface *i)
 {
 	struct wpabuf *buf;
 	struct fst_iface *f;
 	unsigned int nof_mbies = 0;
 	unsigned int nof_ifaces_added = 0;

 	foreach_fst_group_iface(g, f) {
 		if (f == i)
 			continue;
 		nof_mbies += fst_fill_iface_mb_ies(f, NULL);
 	}

 	buf = wpabuf_alloc(nof_mbies *
 			   (sizeof(struct multi_band_ie) + ETH_ALEN));
 	if (!buf) {
 		fst_printf_iface(i, MSG_ERROR,
 				 "cannot allocate mem for %u MB IEs",
 				 nof_mbies);
 		return NULL;
 	}

 	/* The list is sorted in descending order by priorities, so MB IEs will
 	 * be arranged in the same order, as required by spec (see corresponding
 	 * comment in.fst_attach().
 	 */
 	foreach_fst_group_iface(g, f) {
 		if (f == i)
 			continue;

 		fst_fill_iface_mb_ies(f, buf);
 		++nof_ifaces_added;

 		fst_printf_iface(i, MSG_DEBUG, "added to MB IE");
 	}

 	if (!nof_ifaces_added) {
 		wpabuf_free(buf);
 		buf = NULL;
 		fst_printf_iface(i, MSG_INFO,
 				 "cannot add MB IE: no backup ifaces");
 	} else {
 		fst_dump_mb_ies(fst_group_get_id(g), fst_iface_get_name(i),
 				buf);
 	}

 	return buf;
 }


 static const u8 * fst_mbie_get_peer_addr(const struct multi_band_ie *mbie)
 {
 	const u8 *peer_addr = NULL;

 	switch (MB_CTRL_ROLE(mbie->mb_ctrl)) {
 	case MB_STA_ROLE_AP:
 		peer_addr = mbie->bssid;
 		break;
 	case MB_STA_ROLE_NON_PCP_NON_AP:
 		if (mbie->mb_ctrl & MB_CTRL_STA_MAC_PRESENT &&
 		    (size_t) 2 + mbie->len >= sizeof(*mbie) + ETH_ALEN)
 			peer_addr = (const u8 *) &mbie[1];
 		break;
 	default:
 		break;
 	}

 	return peer_addr;
 }


 static const u8 * fst_mbie_get_peer_addr_for_band(const struct wpabuf *mbies,
 						  u8 band_id)
 {
 	const u8 *p = wpabuf_head(mbies);
 	size_t s = wpabuf_len(mbies);

 	while (s >= 2) {
 		const struct multi_band_ie *mbie =
 			(const struct multi_band_ie *) p;

 		if (mbie->eid != WLAN_EID_MULTI_BAND) {
 			fst_printf(MSG_INFO, "unexpected eid %d", mbie->eid);
 			return NULL;
 		}

 		if (mbie->len < sizeof(*mbie) - 2 || mbie->len > s - 2) {
 			fst_printf(MSG_INFO, "invalid mbie len %d",
 				   mbie->len);
 			return NULL;
 		}

 		if (mbie->band_id == band_id)
 			return fst_mbie_get_peer_addr(mbie);

 		p += 2 + mbie->len;
 		s -= 2 + mbie->len;
 	}

 	fst_printf(MSG_INFO, "mbie doesn't contain band %d", band_id);
 	return NULL;
 }


 struct fst_iface * fst_group_get_iface_by_name(struct fst_group *g,
 					       const char *ifname)
 {
 	struct fst_iface *f;

 	foreach_fst_group_iface(g, f) {
 		const char *in = fst_iface_get_name(f);

 		if (os_strncmp(in, ifname, os_strlen(in)) == 0)
 			return f;
 	}

 	return NULL;
 }


 u8 fst_group_assign_dialog_token(struct fst_group *g)
 {
 	g->dialog_token++;
 	if (g->dialog_token == 0)
 		g->dialog_token++;
 	return g->dialog_token;
 }


 u32 fst_group_assign_fsts_id(struct fst_group *g)
 {
 	g->fsts_id++;
 	return g->fsts_id;
 }


 /**
  * fst_group_get_peer_other_connection_1 - Find peer's "other" connection
  * (iface, MAC tuple) by using peer's MB IE on iface.
  *
  * @iface: iface on which FST Setup Request was received
  * @peer_addr: Peer address on iface
  * @band_id: "other" connection band id
  * @other_peer_addr (out): Peer's MAC address on the "other" connection (on the
  *   "other" iface)
  *
  * This function parses peer's MB IE on iface. It looks for peer's MAC address
  * on band_id (tmp_peer_addr). Next all interfaces are iterated to find an
  * interface which correlates with band_id. If such interface is found, peer
  * database is iterated to see if tmp_peer_addr is connected over it.
  */
 static struct fst_iface *
 fst_group_get_peer_other_connection_1(struct fst_iface *iface,
 				      const u8 *peer_addr, u8 band_id,
 				      u8 *other_peer_addr)
 {
 	const struct wpabuf *mbies;
 	struct fst_iface *other_iface;
 	const u8 *tmp_peer_addr;

 	/* Get peer's MB IEs on iface */
 	mbies = fst_iface_get_peer_mb_ie(iface, peer_addr);
 	if (!mbies)
 		return NULL;

 	/* Get peer's MAC address on the "other" interface */
 	tmp_peer_addr = fst_mbie_get_peer_addr_for_band(mbies, band_id);
 	if (!tmp_peer_addr) {
 		fst_printf(MSG_INFO,
 			   "couldn't extract other peer addr from mbies");
 		return NULL;
 	}

 	fst_printf(MSG_DEBUG, "found other peer addr from mbies: " MACSTR,
 		   MAC2STR(tmp_peer_addr));

 	foreach_fst_group_iface(fst_iface_get_group(iface), other_iface) {
 		if (other_iface == iface ||
 		    band_id != fst_iface_get_band_id(other_iface))
 			continue;
 		if (fst_iface_is_connected(other_iface, tmp_peer_addr, FALSE)) {
 			os_memcpy(other_peer_addr, tmp_peer_addr, ETH_ALEN);
 			return other_iface;
 		}
 	}

 	return NULL;
 }


 /**
  * fst_group_get_peer_other_connection_2 - Find peer's "other" connection
  * (iface, MAC tuple) by using MB IEs of other peers.
  *
  * @iface: iface on which FST Setup Request was received
  * @peer_addr: Peer address on iface
  * @band_id: "other" connection band id
  * @other_peer_addr (out): Peer's MAC address on the "other" connection (on the
  *   "other" iface)
  *
  * This function iterates all connection (other_iface, cur_peer_addr tuples).
  * For each connection, MB IE (of cur_peer_addr on other_iface) is parsed and
  * MAC address on iface's band_id is extracted (this_peer_addr).
  * this_peer_addr is then compared to peer_addr. A match indicates we have
  * found the "other" connection.
  */
 static struct fst_iface *
 fst_group_get_peer_other_connection_2(struct fst_iface *iface,
 				      const u8 *peer_addr, u8 band_id,
 				      u8 *other_peer_addr)
 {
 	u8 this_band_id = fst_iface_get_band_id(iface);
 	const u8 *cur_peer_addr, *this_peer_addr;
 	struct fst_get_peer_ctx *ctx;
 	struct fst_iface *other_iface;
 	const struct wpabuf *cur_mbie;

 	foreach_fst_group_iface(fst_iface_get_group(iface), other_iface) {
 		if (other_iface == iface ||
 		    band_id != fst_iface_get_band_id(other_iface))
 			continue;
 		cur_peer_addr = fst_iface_get_peer_first(other_iface, &ctx,
 							 TRUE);
 		for (; cur_peer_addr;
 		     cur_peer_addr = fst_iface_get_peer_next(other_iface, &ctx,
 							     TRUE)) {
 			cur_mbie = fst_iface_get_peer_mb_ie(other_iface,
 							    cur_peer_addr);
 			if (!cur_mbie)
 				continue;
 			this_peer_addr = fst_mbie_get_peer_addr_for_band(
 				cur_mbie, this_band_id);
 			if (!this_peer_addr)
 				continue;
 			if (os_memcmp(this_peer_addr, peer_addr, ETH_ALEN) ==
 			    0) {
 				os_memcpy(other_peer_addr, cur_peer_addr,
 					  ETH_ALEN);
 				return other_iface;
 			}
 		}
 	}

 	return NULL;
 }


 /**
  * fst_group_get_peer_other_connection - Find peer's "other" connection (iface,
  * MAC tuple).
  *
  * @iface: iface on which FST Setup Request was received
  * @peer_addr: Peer address on iface
  * @band_id: "other" connection band id
  * @other_peer_addr (out): Peer's MAC address on the "other" connection (on the
  *   "other" iface)
  *
  * This function is called upon receiving FST Setup Request from some peer who
  * has peer_addr on iface. It searches for another connection of the same peer
  * on different interface which correlates with band_id. MB IEs received from
  * peer (on the two different interfaces) are used to identify same peer.
  */
 struct fst_iface *
 fst_group_get_peer_other_connection(struct fst_iface *iface,
 				    const u8 *peer_addr, u8 band_id,
 				    u8 *other_peer_addr)
 {
 	struct fst_iface *other_iface;

 	fst_printf(MSG_DEBUG, "%s: %s:" MACSTR ", %d", __func__,
 		   fst_iface_get_name(iface), MAC2STR(peer_addr), band_id);

 	/*
 	 * Two search methods are used:
 	 * 1. Use peer's MB IE on iface to extract peer's MAC address on
 	 *    "other" connection. Then check if such "other" connection exists.
 	 * 2. Iterate peer database, examine each MB IE to see if it points to
 	 *    (iface, peer_addr) tuple
 	 */

 	other_iface = fst_group_get_peer_other_connection_1(iface, peer_addr,
 							    band_id,
 							    other_peer_addr);
 	if (other_iface) {
 		fst_printf(MSG_DEBUG, "found by method #1. %s:" MACSTR,
 			   fst_iface_get_name(other_iface),
 			   MAC2STR(other_peer_addr));
 		return other_iface;
 	}

 	other_iface = fst_group_get_peer_other_connection_2(iface, peer_addr,
 							    band_id,
 							    other_peer_addr);
 	if (other_iface) {
 		fst_printf(MSG_DEBUG, "found by method #2. %s:" MACSTR,
 			   fst_iface_get_name(other_iface),
 			   MAC2STR(other_peer_addr));
 		return other_iface;
 	}

 	fst_printf(MSG_INFO, "%s: other connection not found", __func__);
 	return NULL;
 }


 struct fst_group * fst_group_create(const char *group_id)
 {
 	struct fst_group *g;

 	g = os_zalloc(sizeof(*g));
 	if (g == NULL) {
 		fst_printf(MSG_ERROR, "%s: Cannot alloc group", group_id);
 		return NULL;
 	}

 	dl_list_init(&g->ifaces);
 	os_strlcpy(g->group_id, group_id, sizeof(g->group_id));

 	dl_list_add_tail(&fst_global_groups_list, &g->global_groups_lentry);
 	fst_printf_group(g, MSG_DEBUG, "instance created");

 	foreach_fst_ctrl_call(on_group_created, g);

 	return g;
 }


 void fst_group_attach_iface(struct fst_group *g, struct fst_iface *i)
 {
 	struct dl_list *list = &g->ifaces;
 	struct fst_iface *f;

 	/*
 	 * Add new interface to the list.
 	 * The list is sorted in descending order by priority to allow
 	 * multiple MB IEs creation according to the spec (see 10.32 Multi-band
 	 * operation, 10.32.1 General), as they should be ordered according to
 	 * priorities.
 	 */
 	foreach_fst_group_iface(g, f) {
 		if (fst_iface_get_priority(f) < fst_iface_get_priority(i))
 			break;
 		list = &f->group_lentry;
 	}
 	dl_list_add(list, &i->group_lentry);
 }


 void fst_group_detach_iface(struct fst_group *g, struct fst_iface *i)
 {
 	dl_list_del(&i->group_lentry);
 }


 void fst_group_delete(struct fst_group *group)
 {
 	struct fst_session *s;

 	dl_list_del(&group->global_groups_lentry);
 	WPA_ASSERT(dl_list_empty(&group->ifaces));
 	foreach_fst_ctrl_call(on_group_deleted, group);
 	fst_printf_group(group, MSG_DEBUG, "instance deleted");
 	while ((s = fst_session_global_get_first_by_group(group)) != NULL)
 		fst_session_delete(s);
 	os_free(group);
 }


 Boolean fst_group_delete_if_empty(struct fst_group *group)
 {
 	Boolean is_empty = !fst_group_has_ifaces(group) &&
 		!fst_session_global_get_first_by_group(group);

 	if (is_empty)
 		fst_group_delete(group);

 	return is_empty;
 }


 void fst_group_update_ie(struct fst_group *g)
 {
 	struct fst_iface *i;

 	foreach_fst_group_iface(g, i) {
 		struct wpabuf *mbie = fst_group_create_mb_ie(g, i);

 		if (!mbie)
 			fst_printf_iface(i, MSG_WARNING, "cannot create MB IE");

 		fst_iface_attach_mbie(i, mbie);
 		fst_iface_set_ies(i, mbie);
 		fst_printf_iface(i, MSG_DEBUG, "multi-band IE set to %p", mbie);
 	}
 }
	/*
	* FST module - FST group object implementation
	* Copyright (c) 2014, Qualcomm Atheros, Inc.
	*
	* This software may be distributed under the terms of the BSD license.
	* See README for more details.
	*/

	#include "utils/includes.h"
	#include "utils/common.h"
	#include "common/defs.h"
	#include "common/ieee802_11_defs.h"
	#include "common/ieee802_11_common.h"
	#include "drivers/driver.h"
	#include "fst/fst_internal.h"
	#include "fst/fst_defs.h"


	struct dl_list fst_global_groups_list;


	static void fst_dump_mb_ies(const char group_id, const char ifname,
	struct wpabuf *mbies)
	{
	const u8 *p = wpabuf_head(mbies);
	size_t s = wpabuf_len(mbies);

	while (s >= 2) {
	const struct multi_band_ie *mbie =
	(const struct multi_band_ie *) p;
	WPA_ASSERT(mbie->eid == WLAN_EID_MULTI_BAND);
	WPA_ASSERT(2U + mbie->len >= sizeof(*mbie));

	fst_printf(MSG_WARNING,
	"%s: %s: mb_ctrl=%u band_id=%u op_class=%u chan=%u bssid="
	MACSTR
	" beacon_int=%u tsf_offs=[%u %u %u %u %u %u %u %u] mb_cc=0x%02x tmout=%u",
	group_id, ifname,
	mbie->mb_ctrl, mbie->band_id, mbie->op_class,
	mbie->chan, MAC2STR(mbie->bssid), mbie->beacon_int,
	mbie->tsf_offs[0], mbie->tsf_offs[1],
	mbie->tsf_offs[2], mbie->tsf_offs[3],
	mbie->tsf_offs[4], mbie->tsf_offs[5],
	mbie->tsf_offs[6], mbie->tsf_offs[7],
	mbie->mb_connection_capability,
	mbie->fst_session_tmout);

	p += 2 + mbie->len;
	s -= 2 + mbie->len;
	}
	}


	static void fst_fill_mb_ie(struct wpabuf buf, const u8 bssid,
	const u8 *own_addr, enum mb_band_id band, u8 channel)
	{
	struct multi_band_ie *mbie;
	size_t len = sizeof(*mbie);

	if (own_addr)
	len += ETH_ALEN;

	mbie = wpabuf_put(buf, len);

	os_memset(mbie, 0, len);

	mbie->eid = WLAN_EID_MULTI_BAND;
	mbie->len = len - 2;
	#ifdef HOSTAPD
	mbie->mb_ctrl = MB_STA_ROLE_AP;
	mbie->mb_connection_capability = MB_CONNECTION_CAPABILITY_AP;
	#else /* HOSTAPD */
	mbie->mb_ctrl = MB_STA_ROLE_NON_PCP_NON_AP;
	mbie->mb_connection_capability = 0;
	#endif /* HOSTAPD */
	if (bssid)
	os_memcpy(mbie->bssid, bssid, ETH_ALEN);
	mbie->band_id = band;
	mbie->op_class = 0; /* means all */
	mbie->chan = channel;
	mbie->fst_session_tmout = FST_DEFAULT_SESSION_TIMEOUT_TU;

	if (own_addr) {
	mbie->mb_ctrl \|= MB_CTRL_STA_MAC_PRESENT;
	os_memcpy(&mbie[1], own_addr, ETH_ALEN);
	}
	}


	static unsigned fst_fill_iface_mb_ies(struct fst_iface f, struct wpabuf buf)
	{
	const u8 *bssid;

	bssid = fst_iface_get_bssid(f);
	if (bssid) {
	enum hostapd_hw_mode hw_mode;
	u8 channel;

	if (buf) {
	fst_iface_get_channel_info(f, &hw_mode, &channel);
	fst_fill_mb_ie(buf, bssid, fst_iface_get_addr(f),
	fst_hw_mode_to_band(hw_mode), channel);
	}
	return 1;
	} else {
	unsigned bands[MB_BAND_ID_WIFI_60GHZ + 1] = {};
	struct hostapd_hw_modes *modes;
	enum mb_band_id b;
	int num_modes = fst_iface_get_hw_modes(f, &modes);
	int ret = 0;

	while (num_modes--) {
	b = fst_hw_mode_to_band(modes->mode);
	modes++;
	if (b >= ARRAY_SIZE(bands) \|\| bands[b]++)
	continue;
	ret++;
	if (buf)
	fst_fill_mb_ie(buf, NULL, fst_iface_get_addr(f),
	b, MB_STA_CHANNEL_ALL);
	}
	return ret;
	}
	}


	static struct wpabuf * fst_group_create_mb_ie(struct fst_group *g,
	struct fst_iface *i)
	{
	struct wpabuf *buf;
	struct fst_iface *f;
	unsigned int nof_mbies = 0;
	unsigned int nof_ifaces_added = 0;

	foreach_fst_group_iface(g, f) {
	if (f == i)
	continue;
	nof_mbies += fst_fill_iface_mb_ies(f, NULL);
	}

	buf = wpabuf_alloc(nof_mbies *
	(sizeof(struct multi_band_ie) + ETH_ALEN));
	if (!buf) {
	fst_printf_iface(i, MSG_ERROR,
	"cannot allocate mem for %u MB IEs",
	nof_mbies);
	return NULL;
	}

	/* The list is sorted in descending order by priorities, so MB IEs will
	* be arranged in the same order, as required by spec (see corresponding
	* comment in.fst_attach().
	*/
	foreach_fst_group_iface(g, f) {
	if (f == i)
	continue;

	fst_fill_iface_mb_ies(f, buf);
	++nof_ifaces_added;

	fst_printf_iface(i, MSG_DEBUG, "added to MB IE");
	}

	if (!nof_ifaces_added) {
	wpabuf_free(buf);
	buf = NULL;
	fst_printf_iface(i, MSG_INFO,
	"cannot add MB IE: no backup ifaces");
	} else {
	fst_dump_mb_ies(fst_group_get_id(g), fst_iface_get_name(i),
	buf);
	}

	return buf;
	}


	static const u8 * fst_mbie_get_peer_addr(const struct multi_band_ie *mbie)
	{
	const u8 *peer_addr = NULL;

	switch (MB_CTRL_ROLE(mbie->mb_ctrl)) {
	case MB_STA_ROLE_AP:
	peer_addr = mbie->bssid;
	break;
	case MB_STA_ROLE_NON_PCP_NON_AP:
	if (mbie->mb_ctrl & MB_CTRL_STA_MAC_PRESENT &&
	(size_t) 2 + mbie->len >= sizeof(*mbie) + ETH_ALEN)
	peer_addr = (const u8 *) &mbie[1];
	break;
	default:
	break;
	}

	return peer_addr;
	}


	static const u8 * fst_mbie_get_peer_addr_for_band(const struct wpabuf *mbies,
	u8 band_id)
	{
	const u8 *p = wpabuf_head(mbies);
	size_t s = wpabuf_len(mbies);

	while (s >= 2) {
	const struct multi_band_ie *mbie =
	(const struct multi_band_ie *) p;

	if (mbie->eid != WLAN_EID_MULTI_BAND) {
	fst_printf(MSG_INFO, "unexpected eid %d", mbie->eid);
	return NULL;
	}

	if (mbie->len < sizeof(*mbie) - 2 \|\| mbie->len > s - 2) {
	fst_printf(MSG_INFO, "invalid mbie len %d",
	mbie->len);
	return NULL;
	}

	if (mbie->band_id == band_id)
	return fst_mbie_get_peer_addr(mbie);

	p += 2 + mbie->len;
	s -= 2 + mbie->len;
	}

	fst_printf(MSG_INFO, "mbie doesn't contain band %d", band_id);
	return NULL;
	}


	struct fst_iface * fst_group_get_iface_by_name(struct fst_group *g,
	const char *ifname)
	{
	struct fst_iface *f;

	foreach_fst_group_iface(g, f) {
	const char *in = fst_iface_get_name(f);

	if (os_strncmp(in, ifname, os_strlen(in)) == 0)
	return f;
	}

	return NULL;
	}


	u8 fst_group_assign_dialog_token(struct fst_group *g)
	{
	g->dialog_token++;
	if (g->dialog_token == 0)
	g->dialog_token++;
	return g->dialog_token;
	}


	u32 fst_group_assign_fsts_id(struct fst_group *g)
	{
	g->fsts_id++;
	return g->fsts_id;
	}


	/**
	* fst_group_get_peer_other_connection_1 - Find peer's "other" connection
	* (iface, MAC tuple) by using peer's MB IE on iface.
	*
	* @iface: iface on which FST Setup Request was received
	* @peer_addr: Peer address on iface
	* @band_id: "other" connection band id
	* @other_peer_addr (out): Peer's MAC address on the "other" connection (on the
	* "other" iface)
	*
	* This function parses peer's MB IE on iface. It looks for peer's MAC address
	* on band_id (tmp_peer_addr). Next all interfaces are iterated to find an
	* interface which correlates with band_id. If such interface is found, peer
	* database is iterated to see if tmp_peer_addr is connected over it.
	*/
	static struct fst_iface *
	fst_group_get_peer_other_connection_1(struct fst_iface *iface,
	const u8 *peer_addr, u8 band_id,
	u8 *other_peer_addr)
	{
	const struct wpabuf *mbies;
	struct fst_iface *other_iface;
	const u8 *tmp_peer_addr;

	/* Get peer's MB IEs on iface */
	mbies = fst_iface_get_peer_mb_ie(iface, peer_addr);
	if (!mbies)
	return NULL;

	/* Get peer's MAC address on the "other" interface */
	tmp_peer_addr = fst_mbie_get_peer_addr_for_band(mbies, band_id);
	if (!tmp_peer_addr) {
	fst_printf(MSG_INFO,
	"couldn't extract other peer addr from mbies");
	return NULL;
	}

	fst_printf(MSG_DEBUG, "found other peer addr from mbies: " MACSTR,
	MAC2STR(tmp_peer_addr));

	foreach_fst_group_iface(fst_iface_get_group(iface), other_iface) {
	if (other_iface == iface \|\|
	band_id != fst_iface_get_band_id(other_iface))
	continue;
	if (fst_iface_is_connected(other_iface, tmp_peer_addr, FALSE)) {
	os_memcpy(other_peer_addr, tmp_peer_addr, ETH_ALEN);
	return other_iface;
	}
	}

	return NULL;
	}


	/**
	* fst_group_get_peer_other_connection_2 - Find peer's "other" connection
	* (iface, MAC tuple) by using MB IEs of other peers.
	*
	* @iface: iface on which FST Setup Request was received
	* @peer_addr: Peer address on iface
	* @band_id: "other" connection band id
	* @other_peer_addr (out): Peer's MAC address on the "other" connection (on the
	* "other" iface)
	*
	* This function iterates all connection (other_iface, cur_peer_addr tuples).
	* For each connection, MB IE (of cur_peer_addr on other_iface) is parsed and
	* MAC address on iface's band_id is extracted (this_peer_addr).
	* this_peer_addr is then compared to peer_addr. A match indicates we have
	* found the "other" connection.
	*/
	static struct fst_iface *
	fst_group_get_peer_other_connection_2(struct fst_iface *iface,
	const u8 *peer_addr, u8 band_id,
	u8 *other_peer_addr)
	{
	u8 this_band_id = fst_iface_get_band_id(iface);
	const u8 cur_peer_addr, this_peer_addr;
	struct fst_get_peer_ctx *ctx;
	struct fst_iface *other_iface;
	const struct wpabuf *cur_mbie;

	foreach_fst_group_iface(fst_iface_get_group(iface), other_iface) {
	if (other_iface == iface \|\|
	band_id != fst_iface_get_band_id(other_iface))
	continue;
	cur_peer_addr = fst_iface_get_peer_first(other_iface, &ctx,
	TRUE);
	for (; cur_peer_addr;
	cur_peer_addr = fst_iface_get_peer_next(other_iface, &ctx,
	TRUE)) {
	cur_mbie = fst_iface_get_peer_mb_ie(other_iface,
	cur_peer_addr);
	if (!cur_mbie)
	continue;
	this_peer_addr = fst_mbie_get_peer_addr_for_band(
	cur_mbie, this_band_id);
	if (!this_peer_addr)
	continue;
	if (os_memcmp(this_peer_addr, peer_addr, ETH_ALEN) ==
	0) {
	os_memcpy(other_peer_addr, cur_peer_addr,
	ETH_ALEN);
	return other_iface;
	}
	}
	}

	return NULL;
	}


	/**
	* fst_group_get_peer_other_connection - Find peer's "other" connection (iface,
	* MAC tuple).
	*
	* @iface: iface on which FST Setup Request was received
	* @peer_addr: Peer address on iface
	* @band_id: "other" connection band id
	* @other_peer_addr (out): Peer's MAC address on the "other" connection (on the
	* "other" iface)
	*
	* This function is called upon receiving FST Setup Request from some peer who
	* has peer_addr on iface. It searches for another connection of the same peer
	* on different interface which correlates with band_id. MB IEs received from
	* peer (on the two different interfaces) are used to identify same peer.
	*/
	struct fst_iface *
	fst_group_get_peer_other_connection(struct fst_iface *iface,
	const u8 *peer_addr, u8 band_id,
	u8 *other_peer_addr)
	{
	struct fst_iface *other_iface;

	fst_printf(MSG_DEBUG, "%s: %s:" MACSTR ", %d", __func__,
	fst_iface_get_name(iface), MAC2STR(peer_addr), band_id);

	/*
	* Two search methods are used:
	* 1. Use peer's MB IE on iface to extract peer's MAC address on
	* "other" connection. Then check if such "other" connection exists.
	* 2. Iterate peer database, examine each MB IE to see if it points to
	* (iface, peer_addr) tuple
	*/

	other_iface = fst_group_get_peer_other_connection_1(iface, peer_addr,
	band_id,
	other_peer_addr);
	if (other_iface) {
	fst_printf(MSG_DEBUG, "found by method #1. %s:" MACSTR,
	fst_iface_get_name(other_iface),
	MAC2STR(other_peer_addr));
	return other_iface;
	}

	other_iface = fst_group_get_peer_other_connection_2(iface, peer_addr,
	band_id,
	other_peer_addr);
	if (other_iface) {
	fst_printf(MSG_DEBUG, "found by method #2. %s:" MACSTR,
	fst_iface_get_name(other_iface),
	MAC2STR(other_peer_addr));
	return other_iface;
	}

	fst_printf(MSG_INFO, "%s: other connection not found", __func__);
	return NULL;
	}


	struct fst_group * fst_group_create(const char *group_id)
	{
	struct fst_group *g;

	g = os_zalloc(sizeof(*g));
	if (g == NULL) {
	fst_printf(MSG_ERROR, "%s: Cannot alloc group", group_id);
	return NULL;
	}

	dl_list_init(&g->ifaces);
	os_strlcpy(g->group_id, group_id, sizeof(g->group_id));

	dl_list_add_tail(&fst_global_groups_list, &g->global_groups_lentry);
	fst_printf_group(g, MSG_DEBUG, "instance created");

	foreach_fst_ctrl_call(on_group_created, g);

	return g;
	}


	void fst_group_attach_iface(struct fst_group g, struct fst_iface i)
	{
	struct dl_list *list = &g->ifaces;
	struct fst_iface *f;

	/*
	* Add new interface to the list.
	* The list is sorted in descending order by priority to allow
	* multiple MB IEs creation according to the spec (see 10.32 Multi-band
	* operation, 10.32.1 General), as they should be ordered according to
	* priorities.
	*/
	foreach_fst_group_iface(g, f) {
	if (fst_iface_get_priority(f) < fst_iface_get_priority(i))
	break;
	list = &f->group_lentry;
	}
	dl_list_add(list, &i->group_lentry);
	}


	void fst_group_detach_iface(struct fst_group g, struct fst_iface i)
	{
	dl_list_del(&i->group_lentry);
	}


	void fst_group_delete(struct fst_group *group)
	{
	struct fst_session *s;

	dl_list_del(&group->global_groups_lentry);
	WPA_ASSERT(dl_list_empty(&group->ifaces));
	foreach_fst_ctrl_call(on_group_deleted, group);
	fst_printf_group(group, MSG_DEBUG, "instance deleted");
	while ((s = fst_session_global_get_first_by_group(group)) != NULL)
	fst_session_delete(s);
	os_free(group);
	}


	Boolean fst_group_delete_if_empty(struct fst_group *group)
	{
	Boolean is_empty = !fst_group_has_ifaces(group) &&
	!fst_session_global_get_first_by_group(group);

	if (is_empty)
	fst_group_delete(group);

	return is_empty;
	}


	void fst_group_update_ie(struct fst_group *g)
	{
	struct fst_iface *i;

	foreach_fst_group_iface(g, i) {
	struct wpabuf *mbie = fst_group_create_mb_ie(g, i);

	if (!mbie)
	fst_printf_iface(i, MSG_WARNING, "cannot create MB IE");

	fst_iface_attach_mbie(i, mbie);
	fst_iface_set_ies(i, mbie);
	fst_printf_iface(i, MSG_DEBUG, "multi-band IE set to %p", mbie);
	}
	}