/* * WSM host interface (HI) implementation for * ST-Ericsson CW1200 mac80211 drivers. * * Copyright (c) 2010, ST-Ericsson * Author: Dmitry Tarnyagin <dmitry.tarnyagin@lockless.no> * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation. */ #include <linux/skbuff.h> #include <linux/wait.h> #include <linux/delay.h> #include <linux/sched.h> #include <linux/random.h> #include "cw1200.h" #include "wsm.h" #include "bh.h" #include "sta.h" #include "debug.h" #define WSM_CMD_TIMEOUT (2 * HZ) /* With respect to interrupt loss */ #define WSM_CMD_START_TIMEOUT (7 * HZ) #define WSM_CMD_RESET_TIMEOUT (3 * HZ) /* 2 sec. timeout was observed. */ #define WSM_CMD_MAX_TIMEOUT (3 * HZ) #define WSM_SKIP(buf, size) \ do { \ if ((buf)->data + size > (buf)->end) \ goto underflow; \ (buf)->data += size; \ } while (0) #define WSM_GET(buf, ptr, size) \ do { \ if ((buf)->data + size > (buf)->end) \ goto underflow; \ memcpy(ptr, (buf)->data, size); \ (buf)->data += size; \ } while (0) #define __WSM_GET(buf, type, type2, cvt) \ ({ \ type val; \ if ((buf)->data + sizeof(type) > (buf)->end) \ goto underflow; \ val = cvt(*(type2 *)(buf)->data); \ (buf)->data += sizeof(type); \ val; \ }) #define WSM_GET8(buf) __WSM_GET(buf, u8, u8, (u8)) #define WSM_GET16(buf) __WSM_GET(buf, u16, __le16, __le16_to_cpu) #define WSM_GET32(buf) __WSM_GET(buf, u32, __le32, __le32_to_cpu) #define WSM_PUT(buf, ptr, size) \ do { \ if ((buf)->data + size > (buf)->end) \ if (wsm_buf_reserve((buf), size)) \ goto nomem; \ memcpy((buf)->data, ptr, size); \ (buf)->data += size; \ } while (0) #define __WSM_PUT(buf, val, type, type2, cvt) \ do { \ if ((buf)->data + sizeof(type) > (buf)->end) \ if (wsm_buf_reserve((buf), sizeof(type))) \ goto nomem; \ *(type2 *)(buf)->data = cvt(val); \ (buf)->data += sizeof(type); \ } while (0) #define WSM_PUT8(buf, val) __WSM_PUT(buf, val, u8, u8, (u8)) #define WSM_PUT16(buf, val) __WSM_PUT(buf, val, u16, __le16, __cpu_to_le16) #define WSM_PUT32(buf, val) __WSM_PUT(buf, val, u32, __le32, __cpu_to_le32) static void wsm_buf_reset(struct wsm_buf *buf); static int wsm_buf_reserve(struct wsm_buf *buf, size_t extra_size); static int wsm_cmd_send(struct cw1200_common *priv, struct wsm_buf *buf, void *arg, u16 cmd, long tmo); #define wsm_cmd_lock(__priv) mutex_lock(&((__priv)->wsm_cmd_mux)) #define wsm_cmd_unlock(__priv) mutex_unlock(&((__priv)->wsm_cmd_mux)) /* ******************************************************************** */ /* WSM API implementation */ static int wsm_generic_confirm(struct cw1200_common *priv, void *arg, struct wsm_buf *buf) { u32 status = WSM_GET32(buf); if (status != WSM_STATUS_SUCCESS) return -EINVAL; return 0; underflow: WARN_ON(1); return -EINVAL; } int wsm_configuration(struct cw1200_common *priv, struct wsm_configuration *arg) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; wsm_cmd_lock(priv); WSM_PUT32(buf, arg->dot11MaxTransmitMsduLifeTime); WSM_PUT32(buf, arg->dot11MaxReceiveLifeTime); WSM_PUT32(buf, arg->dot11RtsThreshold); /* DPD block. */ WSM_PUT16(buf, arg->dpdData_size + 12); WSM_PUT16(buf, 1); /* DPD version */ WSM_PUT(buf, arg->dot11StationId, ETH_ALEN); WSM_PUT16(buf, 5); /* DPD flags */ WSM_PUT(buf, arg->dpdData, arg->dpdData_size); ret = wsm_cmd_send(priv, buf, arg, WSM_CONFIGURATION_REQ_ID, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } static int wsm_configuration_confirm(struct cw1200_common *priv, struct wsm_configuration *arg, struct wsm_buf *buf) { int i; int status; status = WSM_GET32(buf); if (WARN_ON(status != WSM_STATUS_SUCCESS)) return -EINVAL; WSM_GET(buf, arg->dot11StationId, ETH_ALEN); arg->dot11FrequencyBandsSupported = WSM_GET8(buf); WSM_SKIP(buf, 1); arg->supportedRateMask = WSM_GET32(buf); for (i = 0; i < 2; ++i) { arg->txPowerRange[i].min_power_level = WSM_GET32(buf); arg->txPowerRange[i].max_power_level = WSM_GET32(buf); arg->txPowerRange[i].stepping = WSM_GET32(buf); } return 0; underflow: WARN_ON(1); return -EINVAL; } /* ******************************************************************** */ int wsm_reset(struct cw1200_common *priv, const struct wsm_reset *arg) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; u16 cmd = WSM_RESET_REQ_ID | WSM_TX_LINK_ID(arg->link_id); wsm_cmd_lock(priv); WSM_PUT32(buf, arg->reset_statistics ? 0 : 1); ret = wsm_cmd_send(priv, buf, NULL, cmd, WSM_CMD_RESET_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } /* ******************************************************************** */ struct wsm_mib { u16 mib_id; void *buf; size_t buf_size; }; int wsm_read_mib(struct cw1200_common *priv, u16 mib_id, void *_buf, size_t buf_size) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; struct wsm_mib mib_buf = { .mib_id = mib_id, .buf = _buf, .buf_size = buf_size, }; wsm_cmd_lock(priv); WSM_PUT16(buf, mib_id); WSM_PUT16(buf, 0); ret = wsm_cmd_send(priv, buf, &mib_buf, WSM_READ_MIB_REQ_ID, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } static int wsm_read_mib_confirm(struct cw1200_common *priv, struct wsm_mib *arg, struct wsm_buf *buf) { u16 size; if (WARN_ON(WSM_GET32(buf) != WSM_STATUS_SUCCESS)) return -EINVAL; if (WARN_ON(WSM_GET16(buf) != arg->mib_id)) return -EINVAL; size = WSM_GET16(buf); if (size > arg->buf_size) size = arg->buf_size; WSM_GET(buf, arg->buf, size); arg->buf_size = size; return 0; underflow: WARN_ON(1); return -EINVAL; } /* ******************************************************************** */ int wsm_write_mib(struct cw1200_common *priv, u16 mib_id, void *_buf, size_t buf_size) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; struct wsm_mib mib_buf = { .mib_id = mib_id, .buf = _buf, .buf_size = buf_size, }; wsm_cmd_lock(priv); WSM_PUT16(buf, mib_id); WSM_PUT16(buf, buf_size); WSM_PUT(buf, _buf, buf_size); ret = wsm_cmd_send(priv, buf, &mib_buf, WSM_WRITE_MIB_REQ_ID, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } static int wsm_write_mib_confirm(struct cw1200_common *priv, struct wsm_mib *arg, struct wsm_buf *buf) { int ret; ret = wsm_generic_confirm(priv, arg, buf); if (ret) return ret; if (arg->mib_id == WSM_MIB_ID_OPERATIONAL_POWER_MODE) { /* OperationalMode: update PM status. */ const char *p = arg->buf; cw1200_enable_powersave(priv, (p[0] & 0x0F) ? true : false); } return 0; } /* ******************************************************************** */ int wsm_scan(struct cw1200_common *priv, const struct wsm_scan *arg) { int i; int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; if (arg->num_channels > 48) return -EINVAL; if (arg->num_ssids > 2) return -EINVAL; if (arg->band > 1) return -EINVAL; wsm_cmd_lock(priv); WSM_PUT8(buf, arg->band); WSM_PUT8(buf, arg->type); WSM_PUT8(buf, arg->flags); WSM_PUT8(buf, arg->max_tx_rate); WSM_PUT32(buf, arg->auto_scan_interval); WSM_PUT8(buf, arg->num_probes); WSM_PUT8(buf, arg->num_channels); WSM_PUT8(buf, arg->num_ssids); WSM_PUT8(buf, arg->probe_delay); for (i = 0; i < arg->num_channels; ++i) { WSM_PUT16(buf, arg->ch[i].number); WSM_PUT16(buf, 0); WSM_PUT32(buf, arg->ch[i].min_chan_time); WSM_PUT32(buf, arg->ch[i].max_chan_time); WSM_PUT32(buf, 0); } for (i = 0; i < arg->num_ssids; ++i) { WSM_PUT32(buf, arg->ssids[i].length); WSM_PUT(buf, &arg->ssids[i].ssid[0], sizeof(arg->ssids[i].ssid)); } ret = wsm_cmd_send(priv, buf, NULL, WSM_START_SCAN_REQ_ID, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } /* ******************************************************************** */ int wsm_stop_scan(struct cw1200_common *priv) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; wsm_cmd_lock(priv); ret = wsm_cmd_send(priv, buf, NULL, WSM_STOP_SCAN_REQ_ID, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; } static int wsm_tx_confirm(struct cw1200_common *priv, struct wsm_buf *buf, int link_id) { struct wsm_tx_confirm tx_confirm; tx_confirm.packet_id = WSM_GET32(buf); tx_confirm.status = WSM_GET32(buf); tx_confirm.tx_rate = WSM_GET8(buf); tx_confirm.ack_failures = WSM_GET8(buf); tx_confirm.flags = WSM_GET16(buf); tx_confirm.media_delay = WSM_GET32(buf); tx_confirm.tx_queue_delay = WSM_GET32(buf); cw1200_tx_confirm_cb(priv, link_id, &tx_confirm); return 0; underflow: WARN_ON(1); return -EINVAL; } static int wsm_multi_tx_confirm(struct cw1200_common *priv, struct wsm_buf *buf, int link_id) { int ret; int count; int i; count = WSM_GET32(buf); if (WARN_ON(count <= 0)) return -EINVAL; if (count > 1) { /* We already released one buffer, now for the rest */ ret = wsm_release_tx_buffer(priv, count - 1); if (ret < 0) return ret; else if (ret > 0) cw1200_bh_wakeup(priv); } cw1200_debug_txed_multi(priv, count); for (i = 0; i < count; ++i) { ret = wsm_tx_confirm(priv, buf, link_id); if (ret) return ret; } return ret; underflow: WARN_ON(1); return -EINVAL; } /* ******************************************************************** */ static int wsm_join_confirm(struct cw1200_common *priv, struct wsm_join_cnf *arg, struct wsm_buf *buf) { arg->status = WSM_GET32(buf); if (WARN_ON(arg->status) != WSM_STATUS_SUCCESS) return -EINVAL; arg->min_power_level = WSM_GET32(buf); arg->max_power_level = WSM_GET32(buf); return 0; underflow: WARN_ON(1); return -EINVAL; } int wsm_join(struct cw1200_common *priv, struct wsm_join *arg) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; struct wsm_join_cnf resp; wsm_cmd_lock(priv); WSM_PUT8(buf, arg->mode); WSM_PUT8(buf, arg->band); WSM_PUT16(buf, arg->channel_number); WSM_PUT(buf, &arg->bssid[0], sizeof(arg->bssid)); WSM_PUT16(buf, arg->atim_window); WSM_PUT8(buf, arg->preamble_type); WSM_PUT8(buf, arg->probe_for_join); WSM_PUT8(buf, arg->dtim_period); WSM_PUT8(buf, arg->flags); WSM_PUT32(buf, arg->ssid_len); WSM_PUT(buf, &arg->ssid[0], sizeof(arg->ssid)); WSM_PUT32(buf, arg->beacon_interval); WSM_PUT32(buf, arg->basic_rate_set); priv->tx_burst_idx = -1; ret = wsm_cmd_send(priv, buf, &resp, WSM_JOIN_REQ_ID, WSM_CMD_TIMEOUT); /* TODO: Update state based on resp.min|max_power_level */ priv->join_complete_status = resp.status; wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } /* ******************************************************************** */ int wsm_set_bss_params(struct cw1200_common *priv, const struct wsm_set_bss_params *arg) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; wsm_cmd_lock(priv); WSM_PUT8(buf, (arg->reset_beacon_loss ? 0x1 : 0)); WSM_PUT8(buf, arg->beacon_lost_count); WSM_PUT16(buf, arg->aid); WSM_PUT32(buf, arg->operational_rate_set); ret = wsm_cmd_send(priv, buf, NULL, WSM_SET_BSS_PARAMS_REQ_ID, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } /* ******************************************************************** */ int wsm_add_key(struct cw1200_common *priv, const struct wsm_add_key *arg) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; wsm_cmd_lock(priv); WSM_PUT(buf, arg, sizeof(*arg)); ret = wsm_cmd_send(priv, buf, NULL, WSM_ADD_KEY_REQ_ID, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } /* ******************************************************************** */ int wsm_remove_key(struct cw1200_common *priv, const struct wsm_remove_key *arg) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; wsm_cmd_lock(priv); WSM_PUT8(buf, arg->index); WSM_PUT8(buf, 0); WSM_PUT16(buf, 0); ret = wsm_cmd_send(priv, buf, NULL, WSM_REMOVE_KEY_REQ_ID, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } /* ******************************************************************** */ int wsm_set_tx_queue_params(struct cw1200_common *priv, const struct wsm_set_tx_queue_params *arg, u8 id) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; u8 queue_id_to_wmm_aci[] = {3, 2, 0, 1}; wsm_cmd_lock(priv); WSM_PUT8(buf, queue_id_to_wmm_aci[id]); WSM_PUT8(buf, 0); WSM_PUT8(buf, arg->ackPolicy); WSM_PUT8(buf, 0); WSM_PUT32(buf, arg->maxTransmitLifetime); WSM_PUT16(buf, arg->allowedMediumTime); WSM_PUT16(buf, 0); ret = wsm_cmd_send(priv, buf, NULL, 0x0012, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } /* ******************************************************************** */ int wsm_set_edca_params(struct cw1200_common *priv, const struct wsm_edca_params *arg) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; wsm_cmd_lock(priv); /* Implemented according to specification. */ WSM_PUT16(buf, arg->params[3].cwmin); WSM_PUT16(buf, arg->params[2].cwmin); WSM_PUT16(buf, arg->params[1].cwmin); WSM_PUT16(buf, arg->params[0].cwmin); WSM_PUT16(buf, arg->params[3].cwmax); WSM_PUT16(buf, arg->params[2].cwmax); WSM_PUT16(buf, arg->params[1].cwmax); WSM_PUT16(buf, arg->params[0].cwmax); WSM_PUT8(buf, arg->params[3].aifns); WSM_PUT8(buf, arg->params[2].aifns); WSM_PUT8(buf, arg->params[1].aifns); WSM_PUT8(buf, arg->params[0].aifns); WSM_PUT16(buf, arg->params[3].txop_limit); WSM_PUT16(buf, arg->params[2].txop_limit); WSM_PUT16(buf, arg->params[1].txop_limit); WSM_PUT16(buf, arg->params[0].txop_limit); WSM_PUT32(buf, arg->params[3].max_rx_lifetime); WSM_PUT32(buf, arg->params[2].max_rx_lifetime); WSM_PUT32(buf, arg->params[1].max_rx_lifetime); WSM_PUT32(buf, arg->params[0].max_rx_lifetime); ret = wsm_cmd_send(priv, buf, NULL, WSM_EDCA_PARAMS_REQ_ID, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } /* ******************************************************************** */ int wsm_switch_channel(struct cw1200_common *priv, const struct wsm_switch_channel *arg) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; wsm_cmd_lock(priv); WSM_PUT8(buf, arg->mode); WSM_PUT8(buf, arg->switch_count); WSM_PUT16(buf, arg->channel_number); priv->channel_switch_in_progress = 1; ret = wsm_cmd_send(priv, buf, NULL, WSM_SWITCH_CHANNEL_REQ_ID, WSM_CMD_TIMEOUT); if (ret) priv->channel_switch_in_progress = 0; wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } /* ******************************************************************** */ int wsm_set_pm(struct cw1200_common *priv, const struct wsm_set_pm *arg) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; priv->ps_mode_switch_in_progress = 1; wsm_cmd_lock(priv); WSM_PUT8(buf, arg->mode); WSM_PUT8(buf, arg->fast_psm_idle_period); WSM_PUT8(buf, arg->ap_psm_change_period); WSM_PUT8(buf, arg->min_auto_pspoll_period); ret = wsm_cmd_send(priv, buf, NULL, WSM_SET_PM_REQ_ID, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } /* ******************************************************************** */ int wsm_start(struct cw1200_common *priv, const struct wsm_start *arg) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; wsm_cmd_lock(priv); WSM_PUT8(buf, arg->mode); WSM_PUT8(buf, arg->band); WSM_PUT16(buf, arg->channel_number); WSM_PUT32(buf, arg->ct_window); WSM_PUT32(buf, arg->beacon_interval); WSM_PUT8(buf, arg->dtim_period); WSM_PUT8(buf, arg->preamble); WSM_PUT8(buf, arg->probe_delay); WSM_PUT8(buf, arg->ssid_len); WSM_PUT(buf, arg->ssid, sizeof(arg->ssid)); WSM_PUT32(buf, arg->basic_rate_set); priv->tx_burst_idx = -1; ret = wsm_cmd_send(priv, buf, NULL, WSM_START_REQ_ID, WSM_CMD_START_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } /* ******************************************************************** */ int wsm_beacon_transmit(struct cw1200_common *priv, const struct wsm_beacon_transmit *arg) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; wsm_cmd_lock(priv); WSM_PUT32(buf, arg->enable_beaconing ? 1 : 0); ret = wsm_cmd_send(priv, buf, NULL, WSM_BEACON_TRANSMIT_REQ_ID, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } /* ******************************************************************** */ int wsm_start_find(struct cw1200_common *priv) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; wsm_cmd_lock(priv); ret = wsm_cmd_send(priv, buf, NULL, 0x0019, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; } /* ******************************************************************** */ int wsm_stop_find(struct cw1200_common *priv) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; wsm_cmd_lock(priv); ret = wsm_cmd_send(priv, buf, NULL, 0x001A, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; } /* ******************************************************************** */ int wsm_map_link(struct cw1200_common *priv, const struct wsm_map_link *arg) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; u16 cmd = 0x001C | WSM_TX_LINK_ID(arg->link_id); wsm_cmd_lock(priv); WSM_PUT(buf, &arg->mac_addr[0], sizeof(arg->mac_addr)); WSM_PUT16(buf, 0); ret = wsm_cmd_send(priv, buf, NULL, cmd, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } /* ******************************************************************** */ int wsm_update_ie(struct cw1200_common *priv, const struct wsm_update_ie *arg) { int ret; struct wsm_buf *buf = &priv->wsm_cmd_buf; wsm_cmd_lock(priv); WSM_PUT16(buf, arg->what); WSM_PUT16(buf, arg->count); WSM_PUT(buf, arg->ies, arg->length); ret = wsm_cmd_send(priv, buf, NULL, 0x001B, WSM_CMD_TIMEOUT); wsm_cmd_unlock(priv); return ret; nomem: wsm_cmd_unlock(priv); return -ENOMEM; } /* ******************************************************************** */ int wsm_set_probe_responder(struct cw1200_common *priv, bool enable) { priv->rx_filter.probeResponder = enable; return wsm_set_rx_filter(priv, &priv->rx_filter); } /* ******************************************************************** */ /* WSM indication events implementation */ const char * const cw1200_fw_types[] = { "ETF", "WFM", "WSM", "HI test", "Platform test" }; static int wsm_startup_indication(struct cw1200_common *priv, struct wsm_buf *buf) { priv->wsm_caps.input_buffers = WSM_GET16(buf); priv->wsm_caps.input_buffer_size = WSM_GET16(buf); priv->wsm_caps.hw_id = WSM_GET16(buf); priv->wsm_caps.hw_subid = WSM_GET16(buf); priv->wsm_caps.status = WSM_GET16(buf); priv->wsm_caps.fw_cap = WSM_GET16(buf); priv->wsm_caps.fw_type = WSM_GET16(buf); priv->wsm_caps.fw_api = WSM_GET16(buf); priv->wsm_caps.fw_build = WSM_GET16(buf); priv->wsm_caps.fw_ver = WSM_GET16(buf); WSM_GET(buf, priv->wsm_caps.fw_label, sizeof(priv->wsm_caps.fw_label)); priv->wsm_caps.fw_label[sizeof(priv->wsm_caps.fw_label) - 1] = 0; /* Do not trust FW too much... */ if (WARN_ON(priv->wsm_caps.status)) return -EINVAL; if (WARN_ON(priv->wsm_caps.fw_type > 4)) return -EINVAL; pr_info("CW1200 WSM init done.\n" " Input buffers: %d x %d bytes\n" " Hardware: %d.%d\n" " %s firmware [%s], ver: %d, build: %d," " api: %d, cap: 0x%.4X\n", priv->wsm_caps.input_buffers, priv->wsm_caps.input_buffer_size, priv->wsm_caps.hw_id, priv->wsm_caps.hw_subid, cw1200_fw_types[priv->wsm_caps.fw_type], priv->wsm_caps.fw_label, priv->wsm_caps.fw_ver, priv->wsm_caps.fw_build, priv->wsm_caps.fw_api, priv->wsm_caps.fw_cap); /* Disable unsupported frequency bands */ if (!(priv->wsm_caps.fw_cap & 0x1)) priv->hw->wiphy->bands[IEEE80211_BAND_2GHZ] = NULL; if (!(priv->wsm_caps.fw_cap & 0x2)) priv->hw->wiphy->bands[IEEE80211_BAND_5GHZ] = NULL; priv->firmware_ready = 1; wake_up(&priv->wsm_startup_done); return 0; underflow: WARN_ON(1); return -EINVAL; } static int wsm_receive_indication(struct cw1200_common *priv, int link_id, struct wsm_buf *buf, struct sk_buff **skb_p) { struct wsm_rx rx; struct ieee80211_hdr *hdr; size_t hdr_len; __le16 fctl; rx.status = WSM_GET32(buf); rx.channel_number = WSM_GET16(buf); rx.rx_rate = WSM_GET8(buf); rx.rcpi_rssi = WSM_GET8(buf); rx.flags = WSM_GET32(buf); /* FW Workaround: Drop probe resp or beacon when RSSI is 0 */ hdr = (struct ieee80211_hdr *)(*skb_p)->data; if (!rx.rcpi_rssi && (ieee80211_is_probe_resp(hdr->frame_control) || ieee80211_is_beacon(hdr->frame_control))) return 0; /* If no RSSI subscription has been made, * convert RCPI to RSSI here */ if (!priv->cqm_use_rssi) rx.rcpi_rssi = rx.rcpi_rssi / 2 - 110; fctl = *(__le16 *)buf->data; hdr_len = buf->data - buf->begin; skb_pull(*skb_p, hdr_len); if (!rx.status && ieee80211_is_deauth(fctl)) { if (priv->join_status == CW1200_JOIN_STATUS_STA) { /* Shedule unjoin work */ pr_debug("[WSM] Issue unjoin command (RX).\n"); wsm_lock_tx_async(priv); if (queue_work(priv->workqueue, &priv->unjoin_work) <= 0) wsm_unlock_tx(priv); } } cw1200_rx_cb(priv, &rx, link_id, skb_p); if (*skb_p) skb_push(*skb_p, hdr_len); return 0; underflow: return -EINVAL; } static int wsm_event_indication(struct cw1200_common *priv, struct wsm_buf *buf) { int first; struct cw1200_wsm_event *event; if (priv->mode == NL80211_IFTYPE_UNSPECIFIED) { /* STA is stopped. */ return 0; } event = kzalloc(sizeof(struct cw1200_wsm_event), GFP_KERNEL); if (!event) return -ENOMEM; event->evt.id = WSM_GET32(buf); event->evt.data = WSM_GET32(buf); pr_debug("[WSM] Event: %d(%d)\n", event->evt.id, event->evt.data); spin_lock(&priv->event_queue_lock); first = list_empty(&priv->event_queue); list_add_tail(&event->link, &priv->event_queue); spin_unlock(&priv->event_queue_lock); if (first) queue_work(priv->workqueue, &priv->event_handler); return 0; underflow: kfree(event); return -EINVAL; } static int wsm_channel_switch_indication(struct cw1200_common *priv, struct wsm_buf *buf) { WARN_ON(WSM_GET32(buf)); priv->channel_switch_in_progress = 0; wake_up(&priv->channel_switch_done); wsm_unlock_tx(priv); return 0; underflow: return -EINVAL; } static int wsm_set_pm_indication(struct cw1200_common *priv, struct wsm_buf *buf) { /* TODO: Check buf (struct wsm_set_pm_complete) for validity */ if (priv->ps_mode_switch_in_progress) { priv->ps_mode_switch_in_progress = 0; wake_up(&priv->ps_mode_switch_done); } return 0; } static int wsm_scan_started(struct cw1200_common *priv, void *arg, struct wsm_buf *buf) { u32 status = WSM_GET32(buf); if (status != WSM_STATUS_SUCCESS) { cw1200_scan_failed_cb(priv); return -EINVAL; } return 0; underflow: WARN_ON(1); return -EINVAL; } static int wsm_scan_complete_indication(struct cw1200_common *priv, struct wsm_buf *buf) { struct wsm_scan_complete arg; arg.status = WSM_GET32(buf); arg.psm = WSM_GET8(buf); arg.num_channels = WSM_GET8(buf); cw1200_scan_complete_cb(priv, &arg); return 0; underflow: return -EINVAL; } static int wsm_join_complete_indication(struct cw1200_common *priv, struct wsm_buf *buf) { struct wsm_join_complete arg; arg.status = WSM_GET32(buf); pr_debug("[WSM] Join complete indication, status: %d\n", arg.status); cw1200_join_complete_cb(priv, &arg); return 0; underflow: return -EINVAL; } static int wsm_find_complete_indication(struct cw1200_common *priv, struct wsm_buf *buf) { pr_warn("Implement find_complete_indication\n"); return 0; } static int wsm_ba_timeout_indication(struct cw1200_common *priv, struct wsm_buf *buf) { u32 dummy; u8 tid; u8 dummy2; u8 addr[ETH_ALEN]; dummy = WSM_GET32(buf); tid = WSM_GET8(buf); dummy2 = WSM_GET8(buf); WSM_GET(buf, addr, ETH_ALEN); pr_info("BlockACK timeout, tid %d, addr %pM\n", tid, addr); return 0; underflow: return -EINVAL; } static int wsm_suspend_resume_indication(struct cw1200_common *priv, int link_id, struct wsm_buf *buf) { u32 flags; struct wsm_suspend_resume arg; flags = WSM_GET32(buf); arg.link_id = link_id; arg.stop = !(flags & 1); arg.multicast = !!(flags & 8); arg.queue = (flags >> 1) & 3; cw1200_suspend_resume(priv, &arg); return 0; underflow: return -EINVAL; } /* ******************************************************************** */ /* WSM TX */ static int wsm_cmd_send(struct cw1200_common *priv, struct wsm_buf *buf, void *arg, u16 cmd, long tmo) { size_t buf_len = buf->data - buf->begin; int ret; /* Don't bother if we're dead. */ if (priv->bh_error) { ret = 0; goto done; } /* Block until the cmd buffer is completed. Tortuous. */ spin_lock(&priv->wsm_cmd.lock); while (!priv->wsm_cmd.done) { spin_unlock(&priv->wsm_cmd.lock); spin_lock(&priv->wsm_cmd.lock); } priv->wsm_cmd.done = 0; spin_unlock(&priv->wsm_cmd.lock); if (cmd == WSM_WRITE_MIB_REQ_ID || cmd == WSM_READ_MIB_REQ_ID) pr_debug("[WSM] >>> 0x%.4X [MIB: 0x%.4X] (%zu)\n", cmd, __le16_to_cpu(((__le16 *)buf->begin)[2]), buf_len); else pr_debug("[WSM] >>> 0x%.4X (%zu)\n", cmd, buf_len); /* Due to buggy SPI on CW1200, we need to * pad the message by a few bytes to ensure * that it's completely received. */ buf_len += 4; /* Fill HI message header */ /* BH will add sequence number */ ((__le16 *)buf->begin)[0] = __cpu_to_le16(buf_len); ((__le16 *)buf->begin)[1] = __cpu_to_le16(cmd); spin_lock(&priv->wsm_cmd.lock); BUG_ON(priv->wsm_cmd.ptr); priv->wsm_cmd.ptr = buf->begin; priv->wsm_cmd.len = buf_len; priv->wsm_cmd.arg = arg; priv->wsm_cmd.cmd = cmd; spin_unlock(&priv->wsm_cmd.lock); cw1200_bh_wakeup(priv); /* Wait for command completion */ ret = wait_event_timeout(priv->wsm_cmd_wq, priv->wsm_cmd.done, tmo); if (!ret && !priv->wsm_cmd.done) { spin_lock(&priv->wsm_cmd.lock); priv->wsm_cmd.done = 1; priv->wsm_cmd.ptr = NULL; spin_unlock(&priv->wsm_cmd.lock); if (priv->bh_error) { /* Return ok to help system cleanup */ ret = 0; } else { pr_err("CMD req (0x%04x) stuck in firmware, killing BH\n", priv->wsm_cmd.cmd); print_hex_dump_bytes("REQDUMP: ", DUMP_PREFIX_NONE, buf->begin, buf_len); pr_err("Outstanding outgoing frames: %d\n", priv->hw_bufs_used); /* Kill BH thread to report the error to the top layer. */ atomic_add(1, &priv->bh_term); wake_up(&priv->bh_wq); ret = -ETIMEDOUT; } } else { spin_lock(&priv->wsm_cmd.lock); BUG_ON(!priv->wsm_cmd.done); ret = priv->wsm_cmd.ret; spin_unlock(&priv->wsm_cmd.lock); } done: wsm_buf_reset(buf); return ret; } /* ******************************************************************** */ /* WSM TX port control */ void wsm_lock_tx(struct cw1200_common *priv) { wsm_cmd_lock(priv); if (atomic_add_return(1, &priv->tx_lock) == 1) { if (wsm_flush_tx(priv)) pr_debug("[WSM] TX is locked.\n"); } wsm_cmd_unlock(priv); } void wsm_lock_tx_async(struct cw1200_common *priv) { if (atomic_add_return(1, &priv->tx_lock) == 1) pr_debug("[WSM] TX is locked (async).\n"); } bool wsm_flush_tx(struct cw1200_common *priv) { unsigned long timestamp = jiffies; bool pending = false; long timeout; int i; /* Flush must be called with TX lock held. */ BUG_ON(!atomic_read(&priv->tx_lock)); /* First check if we really need to do something. * It is safe to use unprotected access, as hw_bufs_used * can only decrements. */ if (!priv->hw_bufs_used) return true; if (priv->bh_error) { /* In case of failure do not wait for magic. */ pr_err("[WSM] Fatal error occurred, will not flush TX.\n"); return false; } else { /* Get a timestamp of "oldest" frame */ for (i = 0; i < 4; ++i) pending |= cw1200_queue_get_xmit_timestamp( &priv->tx_queue[i], ×tamp, 0xffffffff); /* If there's nothing pending, we're good */ if (!pending) return true; timeout = timestamp + WSM_CMD_LAST_CHANCE_TIMEOUT - jiffies; if (timeout < 0 || wait_event_timeout(priv->bh_evt_wq, !priv->hw_bufs_used, timeout) <= 0) { /* Hmmm... Not good. Frame had stuck in firmware. */ priv->bh_error = 1; wiphy_err(priv->hw->wiphy, "[WSM] TX Frames (%d) stuck in firmware, killing BH\n", priv->hw_bufs_used); wake_up(&priv->bh_wq); return false; } /* Ok, everything is flushed. */ return true; } } void wsm_unlock_tx(struct cw1200_common *priv) { int tx_lock; tx_lock = atomic_sub_return(1, &priv->tx_lock); BUG_ON(tx_lock < 0); if (tx_lock == 0) { if (!priv->bh_error) cw1200_bh_wakeup(priv); pr_debug("[WSM] TX is unlocked.\n"); } } /* ******************************************************************** */ /* WSM RX */ int wsm_handle_exception(struct cw1200_common *priv, u8 *data, size_t len) { struct wsm_buf buf; u32 reason; u32 reg[18]; char fname[48]; unsigned int i; static const char * const reason_str[] = { "undefined instruction", "prefetch abort", "data abort", "unknown error", }; buf.begin = buf.data = data; buf.end = &buf.begin[len]; reason = WSM_GET32(&buf); for (i = 0; i < ARRAY_SIZE(reg); ++i) reg[i] = WSM_GET32(&buf); WSM_GET(&buf, fname, sizeof(fname)); if (reason < 4) wiphy_err(priv->hw->wiphy, "Firmware exception: %s.\n", reason_str[reason]); else wiphy_err(priv->hw->wiphy, "Firmware assert at %.*s, line %d\n", (int) sizeof(fname), fname, reg[1]); for (i = 0; i < 12; i += 4) wiphy_err(priv->hw->wiphy, "R%d: 0x%.8X, R%d: 0x%.8X, R%d: 0x%.8X, R%d: 0x%.8X,\n", i + 0, reg[i + 0], i + 1, reg[i + 1], i + 2, reg[i + 2], i + 3, reg[i + 3]); wiphy_err(priv->hw->wiphy, "R12: 0x%.8X, SP: 0x%.8X, LR: 0x%.8X, PC: 0x%.8X,\n", reg[i + 0], reg[i + 1], reg[i + 2], reg[i + 3]); i += 4; wiphy_err(priv->hw->wiphy, "CPSR: 0x%.8X, SPSR: 0x%.8X\n", reg[i + 0], reg[i + 1]); print_hex_dump_bytes("R1: ", DUMP_PREFIX_NONE, fname, sizeof(fname)); return 0; underflow: wiphy_err(priv->hw->wiphy, "Firmware exception.\n"); print_hex_dump_bytes("Exception: ", DUMP_PREFIX_NONE, data, len); return -EINVAL; } int wsm_handle_rx(struct cw1200_common *priv, u16 id, struct wsm_hdr *wsm, struct sk_buff **skb_p) { int ret = 0; struct wsm_buf wsm_buf; int link_id = (id >> 6) & 0x0F; /* Strip link id. */ id &= ~WSM_TX_LINK_ID(WSM_TX_LINK_ID_MAX); wsm_buf.begin = (u8 *)&wsm[0]; wsm_buf.data = (u8 *)&wsm[1]; wsm_buf.end = &wsm_buf.begin[__le16_to_cpu(wsm->len)]; pr_debug("[WSM] <<< 0x%.4X (%td)\n", id, wsm_buf.end - wsm_buf.begin); if (id == WSM_TX_CONFIRM_IND_ID) { ret = wsm_tx_confirm(priv, &wsm_buf, link_id); } else if (id == WSM_MULTI_TX_CONFIRM_ID) { ret = wsm_multi_tx_confirm(priv, &wsm_buf, link_id); } else if (id & 0x0400) { void *wsm_arg; u16 wsm_cmd; /* Do not trust FW too much. Protection against repeated * response and race condition removal (see above). */ spin_lock(&priv->wsm_cmd.lock); wsm_arg = priv->wsm_cmd.arg; wsm_cmd = priv->wsm_cmd.cmd & ~WSM_TX_LINK_ID(WSM_TX_LINK_ID_MAX); priv->wsm_cmd.cmd = 0xFFFF; spin_unlock(&priv->wsm_cmd.lock); if (WARN_ON((id & ~0x0400) != wsm_cmd)) { /* Note that any non-zero is a fatal retcode. */ ret = -EINVAL; goto out; } /* Note that wsm_arg can be NULL in case of timeout in * wsm_cmd_send(). */ switch (id) { case WSM_READ_MIB_RESP_ID: if (wsm_arg) ret = wsm_read_mib_confirm(priv, wsm_arg, &wsm_buf); break; case WSM_WRITE_MIB_RESP_ID: if (wsm_arg) ret = wsm_write_mib_confirm(priv, wsm_arg, &wsm_buf); break; case WSM_START_SCAN_RESP_ID: if (wsm_arg) ret = wsm_scan_started(priv, wsm_arg, &wsm_buf); break; case WSM_CONFIGURATION_RESP_ID: if (wsm_arg) ret = wsm_configuration_confirm(priv, wsm_arg, &wsm_buf); break; case WSM_JOIN_RESP_ID: if (wsm_arg) ret = wsm_join_confirm(priv, wsm_arg, &wsm_buf); break; case WSM_STOP_SCAN_RESP_ID: case WSM_RESET_RESP_ID: case WSM_ADD_KEY_RESP_ID: case WSM_REMOVE_KEY_RESP_ID: case WSM_SET_PM_RESP_ID: case WSM_SET_BSS_PARAMS_RESP_ID: case 0x0412: /* set_tx_queue_params */ case WSM_EDCA_PARAMS_RESP_ID: case WSM_SWITCH_CHANNEL_RESP_ID: case WSM_START_RESP_ID: case WSM_BEACON_TRANSMIT_RESP_ID: case 0x0419: /* start_find */ case 0x041A: /* stop_find */ case 0x041B: /* update_ie */ case 0x041C: /* map_link */ WARN_ON(wsm_arg != NULL); ret = wsm_generic_confirm(priv, wsm_arg, &wsm_buf); if (ret) { wiphy_warn(priv->hw->wiphy, "wsm_generic_confirm failed for request 0x%04x.\n", id & ~0x0400); /* often 0x407 and 0x410 occur, this means we're dead.. */ if (priv->join_status >= CW1200_JOIN_STATUS_JOINING) { wsm_lock_tx(priv); if (queue_work(priv->workqueue, &priv->unjoin_work) <= 0) wsm_unlock_tx(priv); } } break; default: wiphy_warn(priv->hw->wiphy, "Unrecognized confirmation 0x%04x\n", id & ~0x0400); } spin_lock(&priv->wsm_cmd.lock); priv->wsm_cmd.ret = ret; priv->wsm_cmd.done = 1; spin_unlock(&priv->wsm_cmd.lock); ret = 0; /* Error response from device should ne stop BH. */ wake_up(&priv->wsm_cmd_wq); } else if (id & 0x0800) { switch (id) { case WSM_STARTUP_IND_ID: ret = wsm_startup_indication(priv, &wsm_buf); break; case WSM_RECEIVE_IND_ID: ret = wsm_receive_indication(priv, link_id, &wsm_buf, skb_p); break; case 0x0805: ret = wsm_event_indication(priv, &wsm_buf); break; case WSM_SCAN_COMPLETE_IND_ID: ret = wsm_scan_complete_indication(priv, &wsm_buf); break; case 0x0808: ret = wsm_ba_timeout_indication(priv, &wsm_buf); break; case 0x0809: ret = wsm_set_pm_indication(priv, &wsm_buf); break; case 0x080A: ret = wsm_channel_switch_indication(priv, &wsm_buf); break; case 0x080B: ret = wsm_find_complete_indication(priv, &wsm_buf); break; case 0x080C: ret = wsm_suspend_resume_indication(priv, link_id, &wsm_buf); break; case 0x080F: ret = wsm_join_complete_indication(priv, &wsm_buf); break; default: pr_warn("Unrecognised WSM ID %04x\n", id); } } else { WARN_ON(1); ret = -EINVAL; } out: return ret; } static bool wsm_handle_tx_data(struct cw1200_common *priv, struct wsm_tx *wsm, const struct ieee80211_tx_info *tx_info, const struct cw1200_txpriv *txpriv, struct cw1200_queue *queue) { bool handled = false; const struct ieee80211_hdr *frame = (struct ieee80211_hdr *)&((u8 *)wsm)[txpriv->offset]; __le16 fctl = frame->frame_control; enum { do_probe, do_drop, do_wep, do_tx, } action = do_tx; switch (priv->mode) { case NL80211_IFTYPE_STATION: if (priv->join_status == CW1200_JOIN_STATUS_MONITOR) action = do_tx; else if (priv->join_status < CW1200_JOIN_STATUS_PRE_STA) action = do_drop; break; case NL80211_IFTYPE_AP: if (!priv->join_status) { action = do_drop; } else if (!(BIT(txpriv->raw_link_id) & (BIT(0) | priv->link_id_map))) { wiphy_warn(priv->hw->wiphy, "A frame with expired link id is dropped.\n"); action = do_drop; } if (cw1200_queue_get_generation(wsm->packet_id) > CW1200_MAX_REQUEUE_ATTEMPTS) { /* HACK!!! WSM324 firmware has tendency to requeue * multicast frames in a loop, causing performance * drop and high power consumption of the driver. * In this situation it is better just to drop * the problematic frame. */ wiphy_warn(priv->hw->wiphy, "Too many attempts to requeue a frame; dropped.\n"); action = do_drop; } break; case NL80211_IFTYPE_ADHOC: if (priv->join_status != CW1200_JOIN_STATUS_IBSS) action = do_drop; break; case NL80211_IFTYPE_MESH_POINT: action = do_tx; /* TODO: Test me! */ break; case NL80211_IFTYPE_MONITOR: default: action = do_drop; break; } if (action == do_tx) { if (ieee80211_is_nullfunc(fctl)) { spin_lock(&priv->bss_loss_lock); if (priv->bss_loss_state) { priv->bss_loss_confirm_id = wsm->packet_id; wsm->queue_id = WSM_QUEUE_VOICE; } spin_unlock(&priv->bss_loss_lock); } else if (ieee80211_is_probe_req(fctl)) { action = do_probe; } else if (ieee80211_is_deauth(fctl) && priv->mode != NL80211_IFTYPE_AP) { pr_debug("[WSM] Issue unjoin command due to tx deauth.\n"); wsm_lock_tx_async(priv); if (queue_work(priv->workqueue, &priv->unjoin_work) <= 0) wsm_unlock_tx(priv); } else if (ieee80211_has_protected(fctl) && tx_info->control.hw_key && tx_info->control.hw_key->keyidx != priv->wep_default_key_id && (tx_info->control.hw_key->cipher == WLAN_CIPHER_SUITE_WEP40 || tx_info->control.hw_key->cipher == WLAN_CIPHER_SUITE_WEP104)) { action = do_wep; } } switch (action) { case do_probe: /* An interesting FW "feature". Device filters probe responses. * The easiest way to get it back is to convert * probe request into WSM start_scan command. */ pr_debug("[WSM] Convert probe request to scan.\n"); wsm_lock_tx_async(priv); priv->pending_frame_id = wsm->packet_id; if (queue_delayed_work(priv->workqueue, &priv->scan.probe_work, 0) <= 0) wsm_unlock_tx(priv); handled = true; break; case do_drop: pr_debug("[WSM] Drop frame (0x%.4X).\n", fctl); BUG_ON(cw1200_queue_remove(queue, wsm->packet_id)); handled = true; break; case do_wep: pr_debug("[WSM] Issue set_default_wep_key.\n"); wsm_lock_tx_async(priv); priv->wep_default_key_id = tx_info->control.hw_key->keyidx; priv->pending_frame_id = wsm->packet_id; if (queue_work(priv->workqueue, &priv->wep_key_work) <= 0) wsm_unlock_tx(priv); handled = true; break; case do_tx: pr_debug("[WSM] Transmit frame.\n"); break; default: /* Do nothing */ break; } return handled; } static int cw1200_get_prio_queue(struct cw1200_common *priv, u32 link_id_map, int *total) { static const int urgent = BIT(CW1200_LINK_ID_AFTER_DTIM) | BIT(CW1200_LINK_ID_UAPSD); struct wsm_edca_queue_params *edca; unsigned score, best = -1; int winner = -1; int queued; int i; /* search for a winner using edca params */ for (i = 0; i < 4; ++i) { queued = cw1200_queue_get_num_queued(&priv->tx_queue[i], link_id_map); if (!queued) continue; *total += queued; edca = &priv->edca.params[i]; score = ((edca->aifns + edca->cwmin) << 16) + ((edca->cwmax - edca->cwmin) * (get_random_int() & 0xFFFF)); if (score < best && (winner < 0 || i != 3)) { best = score; winner = i; } } /* override winner if bursting */ if (winner >= 0 && priv->tx_burst_idx >= 0 && winner != priv->tx_burst_idx && !cw1200_queue_get_num_queued( &priv->tx_queue[winner], link_id_map & urgent) && cw1200_queue_get_num_queued( &priv->tx_queue[priv->tx_burst_idx], link_id_map)) winner = priv->tx_burst_idx; return winner; } static int wsm_get_tx_queue_and_mask(struct cw1200_common *priv, struct cw1200_queue **queue_p, u32 *tx_allowed_mask_p, bool *more) { int idx; u32 tx_allowed_mask; int total = 0; /* Search for a queue with multicast frames buffered */ if (priv->tx_multicast) { tx_allowed_mask = BIT(CW1200_LINK_ID_AFTER_DTIM); idx = cw1200_get_prio_queue(priv, tx_allowed_mask, &total); if (idx >= 0) { *more = total > 1; goto found; } } /* Search for unicast traffic */ tx_allowed_mask = ~priv->sta_asleep_mask; tx_allowed_mask |= BIT(CW1200_LINK_ID_UAPSD); if (priv->sta_asleep_mask) { tx_allowed_mask |= priv->pspoll_mask; tx_allowed_mask &= ~BIT(CW1200_LINK_ID_AFTER_DTIM); } else { tx_allowed_mask |= BIT(CW1200_LINK_ID_AFTER_DTIM); } idx = cw1200_get_prio_queue(priv, tx_allowed_mask, &total); if (idx < 0) return -ENOENT; found: *queue_p = &priv->tx_queue[idx]; *tx_allowed_mask_p = tx_allowed_mask; return 0; } int wsm_get_tx(struct cw1200_common *priv, u8 **data, size_t *tx_len, int *burst) { struct wsm_tx *wsm = NULL; struct ieee80211_tx_info *tx_info; struct cw1200_queue *queue = NULL; int queue_num; u32 tx_allowed_mask = 0; const struct cw1200_txpriv *txpriv = NULL; int count = 0; /* More is used only for broadcasts. */ bool more = false; if (priv->wsm_cmd.ptr) { /* CMD request */ ++count; spin_lock(&priv->wsm_cmd.lock); BUG_ON(!priv->wsm_cmd.ptr); *data = priv->wsm_cmd.ptr; *tx_len = priv->wsm_cmd.len; *burst = 1; spin_unlock(&priv->wsm_cmd.lock); } else { for (;;) { int ret; if (atomic_add_return(0, &priv->tx_lock)) break; spin_lock_bh(&priv->ps_state_lock); ret = wsm_get_tx_queue_and_mask(priv, &queue, &tx_allowed_mask, &more); queue_num = queue - priv->tx_queue; if (priv->buffered_multicasts && (ret || !more) && (priv->tx_multicast || !priv->sta_asleep_mask)) { priv->buffered_multicasts = false; if (priv->tx_multicast) { priv->tx_multicast = false; queue_work(priv->workqueue, &priv->multicast_stop_work); } } spin_unlock_bh(&priv->ps_state_lock); if (ret) break; if (cw1200_queue_get(queue, tx_allowed_mask, &wsm, &tx_info, &txpriv)) continue; if (wsm_handle_tx_data(priv, wsm, tx_info, txpriv, queue)) continue; /* Handled by WSM */ wsm->hdr.id &= __cpu_to_le16( ~WSM_TX_LINK_ID(WSM_TX_LINK_ID_MAX)); wsm->hdr.id |= cpu_to_le16( WSM_TX_LINK_ID(txpriv->raw_link_id)); priv->pspoll_mask &= ~BIT(txpriv->raw_link_id); *data = (u8 *)wsm; *tx_len = __le16_to_cpu(wsm->hdr.len); /* allow bursting if txop is set */ if (priv->edca.params[queue_num].txop_limit) *burst = min(*burst, (int)cw1200_queue_get_num_queued(queue, tx_allowed_mask) + 1); else *burst = 1; /* store index of bursting queue */ if (*burst > 1) priv->tx_burst_idx = queue_num; else priv->tx_burst_idx = -1; if (more) { struct ieee80211_hdr *hdr = (struct ieee80211_hdr *) &((u8 *)wsm)[txpriv->offset]; /* more buffered multicast/broadcast frames * ==> set MoreData flag in IEEE 802.11 header * to inform PS STAs */ hdr->frame_control |= cpu_to_le16(IEEE80211_FCTL_MOREDATA); } pr_debug("[WSM] >>> 0x%.4X (%zu) %p %c\n", 0x0004, *tx_len, *data, wsm->more ? 'M' : ' '); ++count; break; } } return count; } void wsm_txed(struct cw1200_common *priv, u8 *data) { if (data == priv->wsm_cmd.ptr) { spin_lock(&priv->wsm_cmd.lock); priv->wsm_cmd.ptr = NULL; spin_unlock(&priv->wsm_cmd.lock); } } /* ******************************************************************** */ /* WSM buffer */ void wsm_buf_init(struct wsm_buf *buf) { BUG_ON(buf->begin); buf->begin = kmalloc(FWLOAD_BLOCK_SIZE, GFP_KERNEL | GFP_DMA); buf->end = buf->begin ? &buf->begin[FWLOAD_BLOCK_SIZE] : buf->begin; wsm_buf_reset(buf); } void wsm_buf_deinit(struct wsm_buf *buf) { kfree(buf->begin); buf->begin = buf->data = buf->end = NULL; } static void wsm_buf_reset(struct wsm_buf *buf) { if (buf->begin) { buf->data = &buf->begin[4]; *(u32 *)buf->begin = 0; } else { buf->data = buf->begin; } } static int wsm_buf_reserve(struct wsm_buf *buf, size_t extra_size) { size_t pos = buf->data - buf->begin; size_t size = pos + extra_size; size = round_up(size, FWLOAD_BLOCK_SIZE); buf->begin = krealloc(buf->begin, size, GFP_KERNEL | GFP_DMA); if (buf->begin) { buf->data = &buf->begin[pos]; buf->end = &buf->begin[size]; return 0; } else { buf->end = buf->data = buf->begin; return -ENOMEM; } }