// SPDX-License-Identifier: GPL-2.0-only /* * Implementation of host-to-chip commands (aka request/confirmation) of WFxxx * Split Mac (WSM) API. * * Copyright (c) 2017-2019, Silicon Laboratories, Inc. * Copyright (c) 2010, ST-Ericsson */ #include #include "hif_tx.h" #include "wfx.h" #include "bh.h" #include "hwio.h" #include "debug.h" #include "sta.h" void wfx_init_hif_cmd(struct wfx_hif_cmd *hif_cmd) { init_completion(&hif_cmd->ready); init_completion(&hif_cmd->done); mutex_init(&hif_cmd->lock); mutex_init(&hif_cmd->key_renew_lock); } static void wfx_fill_header(struct hif_msg *hif, int if_id, unsigned int cmd, size_t size) { if (if_id == -1) if_id = 2; WARN(cmd > 0x3f, "invalid WSM command %#.2x", cmd); WARN(size > 0xFFF, "requested buffer is too large: %zu bytes", size); WARN(if_id > 0x3, "invalid interface ID %d", if_id); hif->len = cpu_to_le16(size + 4); hif->id = cmd; hif->interface = if_id; } static void *wfx_alloc_hif(size_t body_len, struct hif_msg **hif) { *hif = kzalloc(sizeof(struct hif_msg) + body_len, GFP_KERNEL); if (*hif) return (*hif)->body; else return NULL; } int wfx_cmd_send(struct wfx_dev *wdev, struct hif_msg *request, void *reply, size_t reply_len, bool async) { const char *mib_name = ""; const char *mib_sep = ""; int cmd = request->id; int vif = request->interface; int ret; WARN(wdev->hif_cmd.buf_recv && wdev->hif_cmd.async, "API usage error"); // Do not wait for any reply if chip is frozen if (wdev->chip_frozen) return -ETIMEDOUT; if (cmd != HIF_REQ_ID_SL_EXCHANGE_PUB_KEYS) mutex_lock(&wdev->hif_cmd.key_renew_lock); mutex_lock(&wdev->hif_cmd.lock); WARN(wdev->hif_cmd.buf_send, "data locking error"); // Note: call to complete() below has an implicit memory barrier that // hopefully protect buf_send wdev->hif_cmd.buf_send = request; wdev->hif_cmd.buf_recv = reply; wdev->hif_cmd.len_recv = reply_len; wdev->hif_cmd.async = async; complete(&wdev->hif_cmd.ready); wfx_bh_request_tx(wdev); // NOTE: no timeout is catched async is enabled if (async) return 0; ret = wait_for_completion_timeout(&wdev->hif_cmd.done, 1 * HZ); if (!ret) { dev_err(wdev->dev, "chip is abnormally long to answer\n"); reinit_completion(&wdev->hif_cmd.ready); ret = wait_for_completion_timeout(&wdev->hif_cmd.done, 3 * HZ); } if (!ret) { dev_err(wdev->dev, "chip did not answer\n"); wfx_pending_dump_old_frames(wdev, 3000); wdev->chip_frozen = 1; reinit_completion(&wdev->hif_cmd.done); ret = -ETIMEDOUT; } else { ret = wdev->hif_cmd.ret; } wdev->hif_cmd.buf_send = NULL; mutex_unlock(&wdev->hif_cmd.lock); if (ret && (cmd == HIF_REQ_ID_READ_MIB || cmd == HIF_REQ_ID_WRITE_MIB)) { mib_name = get_mib_name(((u16 *) request)[2]); mib_sep = "/"; } if (ret < 0) dev_err(wdev->dev, "WSM request %s%s%s (%#.2x) on vif %d returned error %d\n", get_hif_name(cmd), mib_sep, mib_name, cmd, vif, ret); if (ret > 0) dev_warn(wdev->dev, "WSM request %s%s%s (%#.2x) on vif %d returned status %d\n", get_hif_name(cmd), mib_sep, mib_name, cmd, vif, ret); if (cmd != HIF_REQ_ID_SL_EXCHANGE_PUB_KEYS) mutex_unlock(&wdev->hif_cmd.key_renew_lock); return ret; } // This function is special. After HIF_REQ_ID_SHUT_DOWN, chip won't reply to any // request anymore. We need to slightly hack struct wfx_hif_cmd for that job. Be // carefull to only call this funcion during device unregister. int hif_shutdown(struct wfx_dev *wdev) { int ret; struct hif_msg *hif; wfx_alloc_hif(0, &hif); wfx_fill_header(hif, -1, HIF_REQ_ID_SHUT_DOWN, 0); ret = wfx_cmd_send(wdev, hif, NULL, 0, true); // After this command, chip won't reply. Be sure to give enough time to // bh to send buffer: msleep(100); wdev->hif_cmd.buf_send = NULL; if (wdev->pdata.gpio_wakeup) gpiod_set_value(wdev->pdata.gpio_wakeup, 0); else control_reg_write(wdev, 0); mutex_unlock(&wdev->hif_cmd.lock); mutex_unlock(&wdev->hif_cmd.key_renew_lock); kfree(hif); return ret; } int hif_configuration(struct wfx_dev *wdev, const u8 *conf, size_t len) { int ret; size_t buf_len = sizeof(struct hif_req_configuration) + len; struct hif_msg *hif; struct hif_req_configuration *body = wfx_alloc_hif(buf_len, &hif); body->length = cpu_to_le16(len); memcpy(body->pds_data, conf, len); wfx_fill_header(hif, -1, HIF_REQ_ID_CONFIGURATION, buf_len); ret = wfx_cmd_send(wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_reset(struct wfx_vif *wvif, bool reset_stat) { int ret; struct hif_msg *hif; struct hif_req_reset *body = wfx_alloc_hif(sizeof(*body), &hif); body->reset_flags.reset_stat = reset_stat; wfx_fill_header(hif, wvif->id, HIF_REQ_ID_RESET, sizeof(*body)); ret = wfx_cmd_send(wvif->wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_read_mib(struct wfx_dev *wdev, int vif_id, u16 mib_id, void *val, size_t val_len) { int ret; struct hif_msg *hif; int buf_len = sizeof(struct hif_cnf_read_mib) + val_len; struct hif_req_read_mib *body = wfx_alloc_hif(sizeof(*body), &hif); struct hif_cnf_read_mib *reply = kmalloc(buf_len, GFP_KERNEL); body->mib_id = cpu_to_le16(mib_id); wfx_fill_header(hif, vif_id, HIF_REQ_ID_READ_MIB, sizeof(*body)); ret = wfx_cmd_send(wdev, hif, reply, buf_len, false); if (!ret && mib_id != reply->mib_id) { dev_warn(wdev->dev, "%s: confirmation mismatch request\n", __func__); ret = -EIO; } if (ret == -ENOMEM) dev_err(wdev->dev, "buffer is too small to receive %s (%zu < %d)\n", get_mib_name(mib_id), val_len, reply->length); if (!ret) memcpy(val, &reply->mib_data, reply->length); else memset(val, 0xFF, val_len); kfree(hif); kfree(reply); return ret; } int hif_write_mib(struct wfx_dev *wdev, int vif_id, u16 mib_id, void *val, size_t val_len) { int ret; struct hif_msg *hif; int buf_len = sizeof(struct hif_req_write_mib) + val_len; struct hif_req_write_mib *body = wfx_alloc_hif(buf_len, &hif); body->mib_id = cpu_to_le16(mib_id); body->length = cpu_to_le16(val_len); memcpy(&body->mib_data, val, val_len); wfx_fill_header(hif, vif_id, HIF_REQ_ID_WRITE_MIB, buf_len); ret = wfx_cmd_send(wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_scan(struct wfx_vif *wvif, struct cfg80211_scan_request *req, int chan_start_idx, int chan_num) { int ret, i; struct hif_msg *hif; size_t buf_len = sizeof(struct hif_req_start_scan_alt) + chan_num * sizeof(u8); struct hif_req_start_scan_alt *body = wfx_alloc_hif(buf_len, &hif); int tmo_chan_fg, tmo_chan_bg, tmo; WARN(chan_num > HIF_API_MAX_NB_CHANNELS, "invalid params"); WARN(req->n_ssids > HIF_API_MAX_NB_SSIDS, "invalid params"); compiletime_assert(IEEE80211_MAX_SSID_LEN == HIF_API_SSID_SIZE, "API inconsistency"); for (i = 0; i < req->n_ssids; i++) { memcpy(body->ssid_def[i].ssid, req->ssids[i].ssid, IEEE80211_MAX_SSID_LEN); body->ssid_def[i].ssid_length = cpu_to_le32(req->ssids[i].ssid_len); } body->num_of_ssids = HIF_API_MAX_NB_SSIDS; // Background scan is always a good idea body->scan_type.type = 1; body->scan_flags.fbg = 1; body->tx_power_level = cpu_to_le32(req->channels[chan_start_idx]->max_power); body->num_of_channels = chan_num; for (i = 0; i < chan_num; i++) body->channel_list[i] = req->channels[i + chan_start_idx]->hw_value; if (req->no_cck) body->max_transmit_rate = API_RATE_INDEX_G_6MBPS; else body->max_transmit_rate = API_RATE_INDEX_B_1MBPS; if (req->channels[chan_start_idx]->flags & IEEE80211_CHAN_NO_IR) { body->min_channel_time = cpu_to_le32(50); body->max_channel_time = cpu_to_le32(150); } else { body->min_channel_time = cpu_to_le32(10); body->max_channel_time = cpu_to_le32(50); body->num_of_probe_requests = 2; body->probe_delay = 100; } tmo_chan_bg = le32_to_cpu(body->max_channel_time) * USEC_PER_TU; tmo_chan_fg = 512 * USEC_PER_TU + body->probe_delay; tmo_chan_fg *= body->num_of_probe_requests; tmo = chan_num * max(tmo_chan_bg, tmo_chan_fg); wfx_fill_header(hif, wvif->id, HIF_REQ_ID_START_SCAN, buf_len); ret = wfx_cmd_send(wvif->wdev, hif, NULL, 0, false); kfree(hif); return ret ? ret : usecs_to_jiffies(tmo); } int hif_stop_scan(struct wfx_vif *wvif) { int ret; struct hif_msg *hif; // body associated to HIF_REQ_ID_STOP_SCAN is empty wfx_alloc_hif(0, &hif); wfx_fill_header(hif, wvif->id, HIF_REQ_ID_STOP_SCAN, 0); ret = wfx_cmd_send(wvif->wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_join(struct wfx_vif *wvif, const struct ieee80211_bss_conf *conf, struct ieee80211_channel *channel, const u8 *ssid, int ssidlen) { int ret; struct hif_msg *hif; struct hif_req_join *body = wfx_alloc_hif(sizeof(*body), &hif); WARN_ON(!conf->basic_rates); body->infrastructure_bss_mode = !conf->ibss_joined; body->short_preamble = conf->use_short_preamble; if (channel && channel->flags & IEEE80211_CHAN_NO_IR) body->probe_for_join = 0; else body->probe_for_join = 1; body->channel_number = cpu_to_le16(channel->hw_value); body->beacon_interval = cpu_to_le32(conf->beacon_int); body->basic_rate_set = cpu_to_le32(wfx_rate_mask_to_hw(wvif->wdev, conf->basic_rates)); memcpy(body->bssid, conf->bssid, sizeof(body->bssid)); if (!conf->ibss_joined && ssid) { body->ssid_length = cpu_to_le32(ssidlen); memcpy(body->ssid, ssid, ssidlen); } wfx_fill_header(hif, wvif->id, HIF_REQ_ID_JOIN, sizeof(*body)); ret = wfx_cmd_send(wvif->wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_set_bss_params(struct wfx_vif *wvif, const struct hif_req_set_bss_params *arg) { int ret; struct hif_msg *hif; struct hif_req_set_bss_params *body = wfx_alloc_hif(sizeof(*body), &hif); memcpy(body, arg, sizeof(*body)); cpu_to_le16s(&body->aid); cpu_to_le32s(&body->operational_rate_set); wfx_fill_header(hif, wvif->id, HIF_REQ_ID_SET_BSS_PARAMS, sizeof(*body)); ret = wfx_cmd_send(wvif->wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_add_key(struct wfx_dev *wdev, const struct hif_req_add_key *arg) { int ret; struct hif_msg *hif; // FIXME: only send necessary bits struct hif_req_add_key *body = wfx_alloc_hif(sizeof(*body), &hif); // FIXME: swap bytes as necessary in body memcpy(body, arg, sizeof(*body)); if (wfx_api_older_than(wdev, 1, 5)) // Legacy firmwares expect that add_key to be sent on right // interface. wfx_fill_header(hif, arg->int_id, HIF_REQ_ID_ADD_KEY, sizeof(*body)); else wfx_fill_header(hif, -1, HIF_REQ_ID_ADD_KEY, sizeof(*body)); ret = wfx_cmd_send(wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_remove_key(struct wfx_dev *wdev, int idx) { int ret; struct hif_msg *hif; struct hif_req_remove_key *body = wfx_alloc_hif(sizeof(*body), &hif); body->entry_index = idx; wfx_fill_header(hif, -1, HIF_REQ_ID_REMOVE_KEY, sizeof(*body)); ret = wfx_cmd_send(wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_set_edca_queue_params(struct wfx_vif *wvif, u16 queue, const struct ieee80211_tx_queue_params *arg) { int ret; struct hif_msg *hif; struct hif_req_edca_queue_params *body = wfx_alloc_hif(sizeof(*body), &hif); if (!body) return -ENOMEM; WARN_ON(arg->aifs > 255); body->aifsn = arg->aifs; body->cw_min = cpu_to_le16(arg->cw_min); body->cw_max = cpu_to_le16(arg->cw_max); body->tx_op_limit = cpu_to_le16(arg->txop * USEC_PER_TXOP); body->queue_id = 3 - queue; // API 2.0 has changed queue IDs values if (wfx_api_older_than(wvif->wdev, 2, 0) && queue == IEEE80211_AC_BE) body->queue_id = HIF_QUEUE_ID_BACKGROUND; if (wfx_api_older_than(wvif->wdev, 2, 0) && queue == IEEE80211_AC_BK) body->queue_id = HIF_QUEUE_ID_BESTEFFORT; wfx_fill_header(hif, wvif->id, HIF_REQ_ID_EDCA_QUEUE_PARAMS, sizeof(*body)); ret = wfx_cmd_send(wvif->wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_set_pm(struct wfx_vif *wvif, bool ps, int dynamic_ps_timeout) { int ret; struct hif_msg *hif; struct hif_req_set_pm_mode *body = wfx_alloc_hif(sizeof(*body), &hif); if (!body) return -ENOMEM; if (ps) { body->pm_mode.enter_psm = 1; // Firmware does not support more than 128ms body->fast_psm_idle_period = min(dynamic_ps_timeout * 2, 255); if (body->fast_psm_idle_period) body->pm_mode.fast_psm = 1; } wfx_fill_header(hif, wvif->id, HIF_REQ_ID_SET_PM_MODE, sizeof(*body)); ret = wfx_cmd_send(wvif->wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_start(struct wfx_vif *wvif, const struct ieee80211_bss_conf *conf, const struct ieee80211_channel *channel) { int ret; struct hif_msg *hif; struct hif_req_start *body = wfx_alloc_hif(sizeof(*body), &hif); body->dtim_period = conf->dtim_period; body->short_preamble = conf->use_short_preamble; body->channel_number = cpu_to_le16(channel->hw_value); body->beacon_interval = cpu_to_le32(conf->beacon_int); body->basic_rate_set = cpu_to_le32(wfx_rate_mask_to_hw(wvif->wdev, conf->basic_rates)); body->ssid_length = conf->ssid_len; memcpy(body->ssid, conf->ssid, conf->ssid_len); wfx_fill_header(hif, wvif->id, HIF_REQ_ID_START, sizeof(*body)); ret = wfx_cmd_send(wvif->wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_beacon_transmit(struct wfx_vif *wvif, bool enable) { int ret; struct hif_msg *hif; struct hif_req_beacon_transmit *body = wfx_alloc_hif(sizeof(*body), &hif); body->enable_beaconing = enable ? 1 : 0; wfx_fill_header(hif, wvif->id, HIF_REQ_ID_BEACON_TRANSMIT, sizeof(*body)); ret = wfx_cmd_send(wvif->wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_map_link(struct wfx_vif *wvif, u8 *mac_addr, int flags, int sta_id) { int ret; struct hif_msg *hif; struct hif_req_map_link *body = wfx_alloc_hif(sizeof(*body), &hif); if (mac_addr) ether_addr_copy(body->mac_addr, mac_addr); body->map_link_flags = *(struct hif_map_link_flags *) &flags; body->peer_sta_id = sta_id; wfx_fill_header(hif, wvif->id, HIF_REQ_ID_MAP_LINK, sizeof(*body)); ret = wfx_cmd_send(wvif->wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_update_ie_beacon(struct wfx_vif *wvif, const u8 *ies, size_t ies_len) { int ret; struct hif_msg *hif; int buf_len = sizeof(struct hif_req_update_ie) + ies_len; struct hif_req_update_ie *body = wfx_alloc_hif(buf_len, &hif); body->ie_flags.beacon = 1; body->num_ies = cpu_to_le16(1); memcpy(body->ie, ies, ies_len); wfx_fill_header(hif, wvif->id, HIF_REQ_ID_UPDATE_IE, buf_len); ret = wfx_cmd_send(wvif->wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_sl_send_pub_keys(struct wfx_dev *wdev, const uint8_t *pubkey, const uint8_t *pubkey_hmac) { int ret; struct hif_msg *hif; struct hif_req_sl_exchange_pub_keys *body = wfx_alloc_hif(sizeof(*body), &hif); body->algorithm = HIF_SL_CURVE25519; memcpy(body->host_pub_key, pubkey, sizeof(body->host_pub_key)); memcpy(body->host_pub_key_mac, pubkey_hmac, sizeof(body->host_pub_key_mac)); wfx_fill_header(hif, -1, HIF_REQ_ID_SL_EXCHANGE_PUB_KEYS, sizeof(*body)); ret = wfx_cmd_send(wdev, hif, NULL, 0, false); kfree(hif); // Compatibility with legacy secure link if (ret == SL_PUB_KEY_EXCHANGE_STATUS_SUCCESS) ret = 0; return ret; } int hif_sl_config(struct wfx_dev *wdev, const unsigned long *bitmap) { int ret; struct hif_msg *hif; struct hif_req_sl_configure *body = wfx_alloc_hif(sizeof(*body), &hif); memcpy(body->encr_bmp, bitmap, sizeof(body->encr_bmp)); wfx_fill_header(hif, -1, HIF_REQ_ID_SL_CONFIGURE, sizeof(*body)); ret = wfx_cmd_send(wdev, hif, NULL, 0, false); kfree(hif); return ret; } int hif_sl_set_mac_key(struct wfx_dev *wdev, const u8 *slk_key, int destination) { int ret; struct hif_msg *hif; struct hif_req_set_sl_mac_key *body = wfx_alloc_hif(sizeof(*body), &hif); memcpy(body->key_value, slk_key, sizeof(body->key_value)); body->otp_or_ram = destination; wfx_fill_header(hif, -1, HIF_REQ_ID_SET_SL_MAC_KEY, sizeof(*body)); ret = wfx_cmd_send(wdev, hif, NULL, 0, false); kfree(hif); // Compatibility with legacy secure link if (ret == SL_MAC_KEY_STATUS_SUCCESS) ret = 0; return ret; }