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linux/drivers/net/wireless/ti/wl12xx/main.c

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/*
* This file is part of wl1271
*
* Copyright (C) 2008-2010 Nokia Corporation
*
* 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.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA
* 02110-1301 USA
*
*/
#include <linux/module.h>
#include <linux/platform_device.h>
#include <linux/err.h>
#include <linux/wl12xx.h>
#include "../wlcore/wlcore.h"
#include "../wlcore/debug.h"
#include "../wlcore/io.h"
#include "../wlcore/acx.h"
#include "../wlcore/tx.h"
#include "../wlcore/rx.h"
#include "../wlcore/io.h"
#include "../wlcore/boot.h"
#include "wl12xx.h"
#include "reg.h"
#include "cmd.h"
#include "acx.h"
static struct wlcore_conf wl12xx_conf = {
.sg = {
.params = {
[CONF_SG_ACL_BT_MASTER_MIN_BR] = 10,
[CONF_SG_ACL_BT_MASTER_MAX_BR] = 180,
[CONF_SG_ACL_BT_SLAVE_MIN_BR] = 10,
[CONF_SG_ACL_BT_SLAVE_MAX_BR] = 180,
[CONF_SG_ACL_BT_MASTER_MIN_EDR] = 10,
[CONF_SG_ACL_BT_MASTER_MAX_EDR] = 80,
[CONF_SG_ACL_BT_SLAVE_MIN_EDR] = 10,
[CONF_SG_ACL_BT_SLAVE_MAX_EDR] = 80,
[CONF_SG_ACL_WLAN_PS_MASTER_BR] = 8,
[CONF_SG_ACL_WLAN_PS_SLAVE_BR] = 8,
[CONF_SG_ACL_WLAN_PS_MASTER_EDR] = 20,
[CONF_SG_ACL_WLAN_PS_SLAVE_EDR] = 20,
[CONF_SG_ACL_WLAN_ACTIVE_MASTER_MIN_BR] = 20,
[CONF_SG_ACL_WLAN_ACTIVE_MASTER_MAX_BR] = 35,
[CONF_SG_ACL_WLAN_ACTIVE_SLAVE_MIN_BR] = 16,
[CONF_SG_ACL_WLAN_ACTIVE_SLAVE_MAX_BR] = 35,
[CONF_SG_ACL_WLAN_ACTIVE_MASTER_MIN_EDR] = 32,
[CONF_SG_ACL_WLAN_ACTIVE_MASTER_MAX_EDR] = 50,
[CONF_SG_ACL_WLAN_ACTIVE_SLAVE_MIN_EDR] = 28,
[CONF_SG_ACL_WLAN_ACTIVE_SLAVE_MAX_EDR] = 50,
[CONF_SG_ACL_ACTIVE_SCAN_WLAN_BR] = 10,
[CONF_SG_ACL_ACTIVE_SCAN_WLAN_EDR] = 20,
[CONF_SG_ACL_PASSIVE_SCAN_BT_BR] = 75,
[CONF_SG_ACL_PASSIVE_SCAN_WLAN_BR] = 15,
[CONF_SG_ACL_PASSIVE_SCAN_BT_EDR] = 27,
[CONF_SG_ACL_PASSIVE_SCAN_WLAN_EDR] = 17,
/* active scan params */
[CONF_SG_AUTO_SCAN_PROBE_REQ] = 170,
[CONF_SG_ACTIVE_SCAN_DURATION_FACTOR_HV3] = 50,
[CONF_SG_ACTIVE_SCAN_DURATION_FACTOR_A2DP] = 100,
/* passive scan params */
[CONF_SG_PASSIVE_SCAN_DURATION_FACTOR_A2DP_BR] = 800,
[CONF_SG_PASSIVE_SCAN_DURATION_FACTOR_A2DP_EDR] = 200,
[CONF_SG_PASSIVE_SCAN_DURATION_FACTOR_HV3] = 200,
/* passive scan in dual antenna params */
[CONF_SG_CONSECUTIVE_HV3_IN_PASSIVE_SCAN] = 0,
[CONF_SG_BCN_HV3_COLLISION_THRESH_IN_PASSIVE_SCAN] = 0,
[CONF_SG_TX_RX_PROTECTION_BWIDTH_IN_PASSIVE_SCAN] = 0,
/* general params */
[CONF_SG_STA_FORCE_PS_IN_BT_SCO] = 1,
[CONF_SG_ANTENNA_CONFIGURATION] = 0,
[CONF_SG_BEACON_MISS_PERCENT] = 60,
[CONF_SG_DHCP_TIME] = 5000,
[CONF_SG_RXT] = 1200,
[CONF_SG_TXT] = 1000,
[CONF_SG_ADAPTIVE_RXT_TXT] = 1,
[CONF_SG_GENERAL_USAGE_BIT_MAP] = 3,
[CONF_SG_HV3_MAX_SERVED] = 6,
[CONF_SG_PS_POLL_TIMEOUT] = 10,
[CONF_SG_UPSD_TIMEOUT] = 10,
[CONF_SG_CONSECUTIVE_CTS_THRESHOLD] = 2,
[CONF_SG_STA_RX_WINDOW_AFTER_DTIM] = 5,
[CONF_SG_STA_CONNECTION_PROTECTION_TIME] = 30,
/* AP params */
[CONF_AP_BEACON_MISS_TX] = 3,
[CONF_AP_RX_WINDOW_AFTER_BEACON] = 10,
[CONF_AP_BEACON_WINDOW_INTERVAL] = 2,
[CONF_AP_CONNECTION_PROTECTION_TIME] = 0,
[CONF_AP_BT_ACL_VAL_BT_SERVE_TIME] = 25,
[CONF_AP_BT_ACL_VAL_WL_SERVE_TIME] = 25,
/* CTS Diluting params */
[CONF_SG_CTS_DILUTED_BAD_RX_PACKETS_TH] = 0,
[CONF_SG_CTS_CHOP_IN_DUAL_ANT_SCO_MASTER] = 0,
},
.state = CONF_SG_PROTECTIVE,
},
.rx = {
.rx_msdu_life_time = 512000,
.packet_detection_threshold = 0,
.ps_poll_timeout = 15,
.upsd_timeout = 15,
.rts_threshold = IEEE80211_MAX_RTS_THRESHOLD,
.rx_cca_threshold = 0,
.irq_blk_threshold = 0xFFFF,
.irq_pkt_threshold = 0,
.irq_timeout = 600,
.queue_type = CONF_RX_QUEUE_TYPE_LOW_PRIORITY,
},
.tx = {
.tx_energy_detection = 0,
.sta_rc_conf = {
.enabled_rates = 0,
.short_retry_limit = 10,
.long_retry_limit = 10,
.aflags = 0,
},
.ac_conf_count = 4,
.ac_conf = {
[CONF_TX_AC_BE] = {
.ac = CONF_TX_AC_BE,
.cw_min = 15,
.cw_max = 63,
.aifsn = 3,
.tx_op_limit = 0,
},
[CONF_TX_AC_BK] = {
.ac = CONF_TX_AC_BK,
.cw_min = 15,
.cw_max = 63,
.aifsn = 7,
.tx_op_limit = 0,
},
[CONF_TX_AC_VI] = {
.ac = CONF_TX_AC_VI,
.cw_min = 15,
.cw_max = 63,
.aifsn = CONF_TX_AIFS_PIFS,
.tx_op_limit = 3008,
},
[CONF_TX_AC_VO] = {
.ac = CONF_TX_AC_VO,
.cw_min = 15,
.cw_max = 63,
.aifsn = CONF_TX_AIFS_PIFS,
.tx_op_limit = 1504,
},
},
.max_tx_retries = 100,
.ap_aging_period = 300,
.tid_conf_count = 4,
.tid_conf = {
[CONF_TX_AC_BE] = {
.queue_id = CONF_TX_AC_BE,
.channel_type = CONF_CHANNEL_TYPE_EDCF,
.tsid = CONF_TX_AC_BE,
.ps_scheme = CONF_PS_SCHEME_LEGACY,
.ack_policy = CONF_ACK_POLICY_LEGACY,
.apsd_conf = {0, 0},
},
[CONF_TX_AC_BK] = {
.queue_id = CONF_TX_AC_BK,
.channel_type = CONF_CHANNEL_TYPE_EDCF,
.tsid = CONF_TX_AC_BK,
.ps_scheme = CONF_PS_SCHEME_LEGACY,
.ack_policy = CONF_ACK_POLICY_LEGACY,
.apsd_conf = {0, 0},
},
[CONF_TX_AC_VI] = {
.queue_id = CONF_TX_AC_VI,
.channel_type = CONF_CHANNEL_TYPE_EDCF,
.tsid = CONF_TX_AC_VI,
.ps_scheme = CONF_PS_SCHEME_LEGACY,
.ack_policy = CONF_ACK_POLICY_LEGACY,
.apsd_conf = {0, 0},
},
[CONF_TX_AC_VO] = {
.queue_id = CONF_TX_AC_VO,
.channel_type = CONF_CHANNEL_TYPE_EDCF,
.tsid = CONF_TX_AC_VO,
.ps_scheme = CONF_PS_SCHEME_LEGACY,
.ack_policy = CONF_ACK_POLICY_LEGACY,
.apsd_conf = {0, 0},
},
},
.frag_threshold = IEEE80211_MAX_FRAG_THRESHOLD,
.tx_compl_timeout = 700,
.tx_compl_threshold = 4,
.basic_rate = CONF_HW_BIT_RATE_1MBPS,
.basic_rate_5 = CONF_HW_BIT_RATE_6MBPS,
.tmpl_short_retry_limit = 10,
.tmpl_long_retry_limit = 10,
.tx_watchdog_timeout = 5000,
},
.conn = {
.wake_up_event = CONF_WAKE_UP_EVENT_DTIM,
.listen_interval = 1,
.suspend_wake_up_event = CONF_WAKE_UP_EVENT_N_DTIM,
.suspend_listen_interval = 3,
.bcn_filt_mode = CONF_BCN_FILT_MODE_ENABLED,
.bcn_filt_ie_count = 2,
.bcn_filt_ie = {
[0] = {
.ie = WLAN_EID_CHANNEL_SWITCH,
.rule = CONF_BCN_RULE_PASS_ON_APPEARANCE,
},
[1] = {
.ie = WLAN_EID_HT_OPERATION,
.rule = CONF_BCN_RULE_PASS_ON_CHANGE,
},
},
.synch_fail_thold = 10,
.bss_lose_timeout = 100,
.beacon_rx_timeout = 10000,
.broadcast_timeout = 20000,
.rx_broadcast_in_ps = 1,
.ps_poll_threshold = 10,
.bet_enable = CONF_BET_MODE_ENABLE,
.bet_max_consecutive = 50,
.psm_entry_retries = 8,
.psm_exit_retries = 16,
.psm_entry_nullfunc_retries = 3,
.dynamic_ps_timeout = 40,
.forced_ps = false,
.keep_alive_interval = 55000,
.max_listen_interval = 20,
},
.itrim = {
.enable = false,
.timeout = 50000,
},
.pm_config = {
.host_clk_settling_time = 5000,
.host_fast_wakeup_support = false
},
.roam_trigger = {
.trigger_pacing = 1,
.avg_weight_rssi_beacon = 20,
.avg_weight_rssi_data = 10,
.avg_weight_snr_beacon = 20,
.avg_weight_snr_data = 10,
},
.scan = {
.min_dwell_time_active = 7500,
.max_dwell_time_active = 30000,
.min_dwell_time_passive = 100000,
.max_dwell_time_passive = 100000,
.num_probe_reqs = 2,
.split_scan_timeout = 50000,
},
.sched_scan = {
/*
* Values are in TU/1000 but since sched scan FW command
* params are in TUs rounding up may occur.
*/
.base_dwell_time = 7500,
.max_dwell_time_delta = 22500,
/* based on 250bits per probe @1Mbps */
.dwell_time_delta_per_probe = 2000,
/* based on 250bits per probe @6Mbps (plus a bit more) */
.dwell_time_delta_per_probe_5 = 350,
.dwell_time_passive = 100000,
.dwell_time_dfs = 150000,
.num_probe_reqs = 2,
.rssi_threshold = -90,
.snr_threshold = 0,
},
.ht = {
.rx_ba_win_size = 8,
.tx_ba_win_size = 64,
.inactivity_timeout = 10000,
.tx_ba_tid_bitmap = CONF_TX_BA_ENABLED_TID_BITMAP,
},
/*
* Memory config for wl127x chips is given in the
* wl12xx_default_priv_conf struct. The below configuration is
* for wl128x chips.
*/
.mem = {
.num_stations = 1,
.ssid_profiles = 1,
.rx_block_num = 40,
.tx_min_block_num = 40,
.dynamic_memory = 1,
.min_req_tx_blocks = 45,
.min_req_rx_blocks = 22,
.tx_min = 27,
},
.fm_coex = {
.enable = true,
.swallow_period = 5,
.n_divider_fref_set_1 = 0xff, /* default */
.n_divider_fref_set_2 = 12,
.m_divider_fref_set_1 = 148,
.m_divider_fref_set_2 = 0xffff, /* default */
.coex_pll_stabilization_time = 0xffffffff, /* default */
.ldo_stabilization_time = 0xffff, /* default */
.fm_disturbed_band_margin = 0xff, /* default */
.swallow_clk_diff = 0xff, /* default */
},
.rx_streaming = {
.duration = 150,
.queues = 0x1,
.interval = 20,
.always = 0,
},
.fwlog = {
.mode = WL12XX_FWLOG_ON_DEMAND,
.mem_blocks = 2,
.severity = 0,
.timestamp = WL12XX_FWLOG_TIMESTAMP_DISABLED,
.output = WL12XX_FWLOG_OUTPUT_HOST,
.threshold = 0,
},
.rate = {
.rate_retry_score = 32000,
.per_add = 8192,
.per_th1 = 2048,
.per_th2 = 4096,
.max_per = 8100,
.inverse_curiosity_factor = 5,
.tx_fail_low_th = 4,
.tx_fail_high_th = 10,
.per_alpha_shift = 4,
.per_add_shift = 13,
.per_beta1_shift = 10,
.per_beta2_shift = 8,
.rate_check_up = 2,
.rate_check_down = 12,
.rate_retry_policy = {
0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00,
},
},
.hangover = {
.recover_time = 0,
.hangover_period = 20,
.dynamic_mode = 1,
.early_termination_mode = 1,
.max_period = 20,
.min_period = 1,
.increase_delta = 1,
.decrease_delta = 2,
.quiet_time = 4,
.increase_time = 1,
.window_size = 16,
},
};
static struct wl12xx_priv_conf wl12xx_default_priv_conf = {
.rf = {
.tx_per_channel_power_compensation_2 = {
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
},
.tx_per_channel_power_compensation_5 = {
0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
},
},
.mem_wl127x = {
.num_stations = 1,
.ssid_profiles = 1,
.rx_block_num = 70,
.tx_min_block_num = 40,
.dynamic_memory = 1,
.min_req_tx_blocks = 100,
.min_req_rx_blocks = 22,
.tx_min = 27,
},
};
#define WL12XX_TX_HW_BLOCK_SPARE_DEFAULT 1
#define WL12XX_TX_HW_BLOCK_GEM_SPARE 2
#define WL12XX_TX_HW_BLOCK_SIZE 252
static const u8 wl12xx_rate_to_idx_2ghz[] = {
/* MCS rates are used only with 11n */
7, /* WL12XX_CONF_HW_RXTX_RATE_MCS7_SGI */
7, /* WL12XX_CONF_HW_RXTX_RATE_MCS7 */
6, /* WL12XX_CONF_HW_RXTX_RATE_MCS6 */
5, /* WL12XX_CONF_HW_RXTX_RATE_MCS5 */
4, /* WL12XX_CONF_HW_RXTX_RATE_MCS4 */
3, /* WL12XX_CONF_HW_RXTX_RATE_MCS3 */
2, /* WL12XX_CONF_HW_RXTX_RATE_MCS2 */
1, /* WL12XX_CONF_HW_RXTX_RATE_MCS1 */
0, /* WL12XX_CONF_HW_RXTX_RATE_MCS0 */
11, /* WL12XX_CONF_HW_RXTX_RATE_54 */
10, /* WL12XX_CONF_HW_RXTX_RATE_48 */
9, /* WL12XX_CONF_HW_RXTX_RATE_36 */
8, /* WL12XX_CONF_HW_RXTX_RATE_24 */
/* TI-specific rate */
CONF_HW_RXTX_RATE_UNSUPPORTED, /* WL12XX_CONF_HW_RXTX_RATE_22 */
7, /* WL12XX_CONF_HW_RXTX_RATE_18 */
6, /* WL12XX_CONF_HW_RXTX_RATE_12 */
3, /* WL12XX_CONF_HW_RXTX_RATE_11 */
5, /* WL12XX_CONF_HW_RXTX_RATE_9 */
4, /* WL12XX_CONF_HW_RXTX_RATE_6 */
2, /* WL12XX_CONF_HW_RXTX_RATE_5_5 */
1, /* WL12XX_CONF_HW_RXTX_RATE_2 */
0 /* WL12XX_CONF_HW_RXTX_RATE_1 */
};
static const u8 wl12xx_rate_to_idx_5ghz[] = {
/* MCS rates are used only with 11n */
7, /* WL12XX_CONF_HW_RXTX_RATE_MCS7_SGI */
7, /* WL12XX_CONF_HW_RXTX_RATE_MCS7 */
6, /* WL12XX_CONF_HW_RXTX_RATE_MCS6 */
5, /* WL12XX_CONF_HW_RXTX_RATE_MCS5 */
4, /* WL12XX_CONF_HW_RXTX_RATE_MCS4 */
3, /* WL12XX_CONF_HW_RXTX_RATE_MCS3 */
2, /* WL12XX_CONF_HW_RXTX_RATE_MCS2 */
1, /* WL12XX_CONF_HW_RXTX_RATE_MCS1 */
0, /* WL12XX_CONF_HW_RXTX_RATE_MCS0 */
7, /* WL12XX_CONF_HW_RXTX_RATE_54 */
6, /* WL12XX_CONF_HW_RXTX_RATE_48 */
5, /* WL12XX_CONF_HW_RXTX_RATE_36 */
4, /* WL12XX_CONF_HW_RXTX_RATE_24 */
/* TI-specific rate */
CONF_HW_RXTX_RATE_UNSUPPORTED, /* WL12XX_CONF_HW_RXTX_RATE_22 */
3, /* WL12XX_CONF_HW_RXTX_RATE_18 */
2, /* WL12XX_CONF_HW_RXTX_RATE_12 */
CONF_HW_RXTX_RATE_UNSUPPORTED, /* WL12XX_CONF_HW_RXTX_RATE_11 */
1, /* WL12XX_CONF_HW_RXTX_RATE_9 */
0, /* WL12XX_CONF_HW_RXTX_RATE_6 */
CONF_HW_RXTX_RATE_UNSUPPORTED, /* WL12XX_CONF_HW_RXTX_RATE_5_5 */
CONF_HW_RXTX_RATE_UNSUPPORTED, /* WL12XX_CONF_HW_RXTX_RATE_2 */
CONF_HW_RXTX_RATE_UNSUPPORTED /* WL12XX_CONF_HW_RXTX_RATE_1 */
};
static const u8 *wl12xx_band_rate_to_idx[] = {
[IEEE80211_BAND_2GHZ] = wl12xx_rate_to_idx_2ghz,
[IEEE80211_BAND_5GHZ] = wl12xx_rate_to_idx_5ghz
};
enum wl12xx_hw_rates {
WL12XX_CONF_HW_RXTX_RATE_MCS7_SGI = 0,
WL12XX_CONF_HW_RXTX_RATE_MCS7,
WL12XX_CONF_HW_RXTX_RATE_MCS6,
WL12XX_CONF_HW_RXTX_RATE_MCS5,
WL12XX_CONF_HW_RXTX_RATE_MCS4,
WL12XX_CONF_HW_RXTX_RATE_MCS3,
WL12XX_CONF_HW_RXTX_RATE_MCS2,
WL12XX_CONF_HW_RXTX_RATE_MCS1,
WL12XX_CONF_HW_RXTX_RATE_MCS0,
WL12XX_CONF_HW_RXTX_RATE_54,
WL12XX_CONF_HW_RXTX_RATE_48,
WL12XX_CONF_HW_RXTX_RATE_36,
WL12XX_CONF_HW_RXTX_RATE_24,
WL12XX_CONF_HW_RXTX_RATE_22,
WL12XX_CONF_HW_RXTX_RATE_18,
WL12XX_CONF_HW_RXTX_RATE_12,
WL12XX_CONF_HW_RXTX_RATE_11,
WL12XX_CONF_HW_RXTX_RATE_9,
WL12XX_CONF_HW_RXTX_RATE_6,
WL12XX_CONF_HW_RXTX_RATE_5_5,
WL12XX_CONF_HW_RXTX_RATE_2,
WL12XX_CONF_HW_RXTX_RATE_1,
WL12XX_CONF_HW_RXTX_RATE_MAX,
};
static struct wlcore_partition_set wl12xx_ptable[PART_TABLE_LEN] = {
[PART_DOWN] = {
.mem = {
.start = 0x00000000,
.size = 0x000177c0
},
.reg = {
.start = REGISTERS_BASE,
.size = 0x00008800
},
.mem2 = {
.start = 0x00000000,
.size = 0x00000000
},
.mem3 = {
.start = 0x00000000,
.size = 0x00000000
},
},
[PART_BOOT] = { /* in wl12xx we can use a mix of work and down
* partition here */
.mem = {
.start = 0x00040000,
.size = 0x00014fc0
},
.reg = {
.start = REGISTERS_BASE,
.size = 0x00008800
},
.mem2 = {
.start = 0x00000000,
.size = 0x00000000
},
.mem3 = {
.start = 0x00000000,
.size = 0x00000000
},
},
[PART_WORK] = {
.mem = {
.start = 0x00040000,
.size = 0x00014fc0
},
.reg = {
.start = REGISTERS_BASE,
.size = 0x0000a000
},
.mem2 = {
.start = 0x003004f8,
.size = 0x00000004
},
.mem3 = {
.start = 0x00040404,
.size = 0x00000000
},
},
[PART_DRPW] = {
.mem = {
.start = 0x00040000,
.size = 0x00014fc0
},
.reg = {
.start = DRPW_BASE,
.size = 0x00006000
},
.mem2 = {
.start = 0x00000000,
.size = 0x00000000
},
.mem3 = {
.start = 0x00000000,
.size = 0x00000000
}
}
};
static const int wl12xx_rtable[REG_TABLE_LEN] = {
[REG_ECPU_CONTROL] = WL12XX_REG_ECPU_CONTROL,
[REG_INTERRUPT_NO_CLEAR] = WL12XX_REG_INTERRUPT_NO_CLEAR,
[REG_INTERRUPT_ACK] = WL12XX_REG_INTERRUPT_ACK,
[REG_COMMAND_MAILBOX_PTR] = WL12XX_REG_COMMAND_MAILBOX_PTR,
[REG_EVENT_MAILBOX_PTR] = WL12XX_REG_EVENT_MAILBOX_PTR,
[REG_INTERRUPT_TRIG] = WL12XX_REG_INTERRUPT_TRIG,
[REG_INTERRUPT_MASK] = WL12XX_REG_INTERRUPT_MASK,
[REG_PC_ON_RECOVERY] = WL12XX_SCR_PAD4,
[REG_CHIP_ID_B] = WL12XX_CHIP_ID_B,
[REG_CMD_MBOX_ADDRESS] = WL12XX_CMD_MBOX_ADDRESS,
/* data access memory addresses, used with partition translation */
[REG_SLV_MEM_DATA] = WL1271_SLV_MEM_DATA,
[REG_SLV_REG_DATA] = WL1271_SLV_REG_DATA,
/* raw data access memory addresses */
[REG_RAW_FW_STATUS_ADDR] = FW_STATUS_ADDR,
};
/* TODO: maybe move to a new header file? */
#define WL127X_FW_NAME_MULTI "ti-connectivity/wl127x-fw-4-mr.bin"
#define WL127X_FW_NAME_SINGLE "ti-connectivity/wl127x-fw-4-sr.bin"
#define WL127X_PLT_FW_NAME "ti-connectivity/wl127x-fw-4-plt.bin"
#define WL128X_FW_NAME_MULTI "ti-connectivity/wl128x-fw-4-mr.bin"
#define WL128X_FW_NAME_SINGLE "ti-connectivity/wl128x-fw-4-sr.bin"
#define WL128X_PLT_FW_NAME "ti-connectivity/wl128x-fw-4-plt.bin"
static void wl127x_prepare_read(struct wl1271 *wl, u32 rx_desc, u32 len)
{
if (wl->chip.id != CHIP_ID_1283_PG20) {
struct wl1271_acx_mem_map *wl_mem_map = wl->target_mem_map;
struct wl1271_rx_mem_pool_addr rx_mem_addr;
/*
* Choose the block we want to read
* For aggregated packets, only the first memory block
* should be retrieved. The FW takes care of the rest.
*/
u32 mem_block = rx_desc & RX_MEM_BLOCK_MASK;
rx_mem_addr.addr = (mem_block << 8) +
le32_to_cpu(wl_mem_map->packet_memory_pool_start);
rx_mem_addr.addr_extra = rx_mem_addr.addr + 4;
wl1271_write(wl, WL1271_SLV_REG_DATA,
&rx_mem_addr, sizeof(rx_mem_addr), false);
}
}
static int wl12xx_identify_chip(struct wl1271 *wl)
{
int ret = 0;
switch (wl->chip.id) {
case CHIP_ID_1271_PG10:
wl1271_warning("chip id 0x%x (1271 PG10) support is obsolete",
wl->chip.id);
/* clear the alignment quirk, since we don't support it */
wl->quirks &= ~WLCORE_QUIRK_TX_BLOCKSIZE_ALIGN;
wl->quirks |= WLCORE_QUIRK_LEGACY_NVS;
wl->sr_fw_name = WL127X_FW_NAME_SINGLE;
wl->mr_fw_name = WL127X_FW_NAME_MULTI;
memcpy(&wl->conf.mem, &wl12xx_default_priv_conf.mem_wl127x,
sizeof(wl->conf.mem));
/* read data preparation is only needed by wl127x */
wl->ops->prepare_read = wl127x_prepare_read;
break;
case CHIP_ID_1271_PG20:
wl1271_debug(DEBUG_BOOT, "chip id 0x%x (1271 PG20)",
wl->chip.id);
/* clear the alignment quirk, since we don't support it */
wl->quirks &= ~WLCORE_QUIRK_TX_BLOCKSIZE_ALIGN;
wl->quirks |= WLCORE_QUIRK_LEGACY_NVS;
wl->plt_fw_name = WL127X_PLT_FW_NAME;
wl->sr_fw_name = WL127X_FW_NAME_SINGLE;
wl->mr_fw_name = WL127X_FW_NAME_MULTI;
memcpy(&wl->conf.mem, &wl12xx_default_priv_conf.mem_wl127x,
sizeof(wl->conf.mem));
/* read data preparation is only needed by wl127x */
wl->ops->prepare_read = wl127x_prepare_read;
break;
case CHIP_ID_1283_PG20:
wl1271_debug(DEBUG_BOOT, "chip id 0x%x (1283 PG20)",
wl->chip.id);
wl->plt_fw_name = WL128X_PLT_FW_NAME;
wl->sr_fw_name = WL128X_FW_NAME_SINGLE;
wl->mr_fw_name = WL128X_FW_NAME_MULTI;
break;
case CHIP_ID_1283_PG10:
default:
wl1271_warning("unsupported chip id: 0x%x", wl->chip.id);
ret = -ENODEV;
goto out;
}
out:
return ret;
}
static void wl12xx_top_reg_write(struct wl1271 *wl, int addr, u16 val)
{
/* write address >> 1 + 0x30000 to OCP_POR_CTR */
addr = (addr >> 1) + 0x30000;
wl1271_write32(wl, WL12XX_OCP_POR_CTR, addr);
/* write value to OCP_POR_WDATA */
wl1271_write32(wl, WL12XX_OCP_DATA_WRITE, val);
/* write 1 to OCP_CMD */
wl1271_write32(wl, WL12XX_OCP_CMD, OCP_CMD_WRITE);
}
static u16 wl12xx_top_reg_read(struct wl1271 *wl, int addr)
{
u32 val;
int timeout = OCP_CMD_LOOP;
/* write address >> 1 + 0x30000 to OCP_POR_CTR */
addr = (addr >> 1) + 0x30000;
wl1271_write32(wl, WL12XX_OCP_POR_CTR, addr);
/* write 2 to OCP_CMD */
wl1271_write32(wl, WL12XX_OCP_CMD, OCP_CMD_READ);
/* poll for data ready */
do {
val = wl1271_read32(wl, WL12XX_OCP_DATA_READ);
} while (!(val & OCP_READY_MASK) && --timeout);
if (!timeout) {
wl1271_warning("Top register access timed out.");
return 0xffff;
}
/* check data status and return if OK */
if ((val & OCP_STATUS_MASK) == OCP_STATUS_OK)
return val & 0xffff;
else {
wl1271_warning("Top register access returned error.");
return 0xffff;
}
}
static int wl128x_switch_tcxo_to_fref(struct wl1271 *wl)
{
u16 spare_reg;
/* Mask bits [2] & [8:4] in the sys_clk_cfg register */
spare_reg = wl12xx_top_reg_read(wl, WL_SPARE_REG);
if (spare_reg == 0xFFFF)
return -EFAULT;
spare_reg |= (BIT(3) | BIT(5) | BIT(6));
wl12xx_top_reg_write(wl, WL_SPARE_REG, spare_reg);
/* Enable FREF_CLK_REQ & mux MCS and coex PLLs to FREF */
wl12xx_top_reg_write(wl, SYS_CLK_CFG_REG,
WL_CLK_REQ_TYPE_PG2 | MCS_PLL_CLK_SEL_FREF);
/* Delay execution for 15msec, to let the HW settle */
mdelay(15);
return 0;
}
static bool wl128x_is_tcxo_valid(struct wl1271 *wl)
{
u16 tcxo_detection;
tcxo_detection = wl12xx_top_reg_read(wl, TCXO_CLK_DETECT_REG);
if (tcxo_detection & TCXO_DET_FAILED)
return false;
return true;
}
static bool wl128x_is_fref_valid(struct wl1271 *wl)
{
u16 fref_detection;
fref_detection = wl12xx_top_reg_read(wl, FREF_CLK_DETECT_REG);
if (fref_detection & FREF_CLK_DETECT_FAIL)
return false;
return true;
}
static int wl128x_manually_configure_mcs_pll(struct wl1271 *wl)
{
wl12xx_top_reg_write(wl, MCS_PLL_M_REG, MCS_PLL_M_REG_VAL);
wl12xx_top_reg_write(wl, MCS_PLL_N_REG, MCS_PLL_N_REG_VAL);
wl12xx_top_reg_write(wl, MCS_PLL_CONFIG_REG, MCS_PLL_CONFIG_REG_VAL);
return 0;
}
static int wl128x_configure_mcs_pll(struct wl1271 *wl, int clk)
{
u16 spare_reg;
u16 pll_config;
u8 input_freq;
/* Mask bits [3:1] in the sys_clk_cfg register */
spare_reg = wl12xx_top_reg_read(wl, WL_SPARE_REG);
if (spare_reg == 0xFFFF)
return -EFAULT;
spare_reg |= BIT(2);
wl12xx_top_reg_write(wl, WL_SPARE_REG, spare_reg);
/* Handle special cases of the TCXO clock */
if (wl->tcxo_clock == WL12XX_TCXOCLOCK_16_8 ||
wl->tcxo_clock == WL12XX_TCXOCLOCK_33_6)
return wl128x_manually_configure_mcs_pll(wl);
/* Set the input frequency according to the selected clock source */
input_freq = (clk & 1) + 1;
pll_config = wl12xx_top_reg_read(wl, MCS_PLL_CONFIG_REG);
if (pll_config == 0xFFFF)
return -EFAULT;
pll_config |= (input_freq << MCS_SEL_IN_FREQ_SHIFT);
pll_config |= MCS_PLL_ENABLE_HP;
wl12xx_top_reg_write(wl, MCS_PLL_CONFIG_REG, pll_config);
return 0;
}
/*
* WL128x has two clocks input - TCXO and FREF.
* TCXO is the main clock of the device, while FREF is used to sync
* between the GPS and the cellular modem.
* In cases where TCXO is 32.736MHz or 16.368MHz, the FREF will be used
* as the WLAN/BT main clock.
*/
static int wl128x_boot_clk(struct wl1271 *wl, int *selected_clock)
{
u16 sys_clk_cfg;
/* For XTAL-only modes, FREF will be used after switching from TCXO */
if (wl->ref_clock == WL12XX_REFCLOCK_26_XTAL ||
wl->ref_clock == WL12XX_REFCLOCK_38_XTAL) {
if (!wl128x_switch_tcxo_to_fref(wl))
return -EINVAL;
goto fref_clk;
}
/* Query the HW, to determine which clock source we should use */
sys_clk_cfg = wl12xx_top_reg_read(wl, SYS_CLK_CFG_REG);
if (sys_clk_cfg == 0xFFFF)
return -EINVAL;
if (sys_clk_cfg & PRCM_CM_EN_MUX_WLAN_FREF)
goto fref_clk;
/* If TCXO is either 32.736MHz or 16.368MHz, switch to FREF */
if (wl->tcxo_clock == WL12XX_TCXOCLOCK_16_368 ||
wl->tcxo_clock == WL12XX_TCXOCLOCK_32_736) {
if (!wl128x_switch_tcxo_to_fref(wl))
return -EINVAL;
goto fref_clk;
}
/* TCXO clock is selected */
if (!wl128x_is_tcxo_valid(wl))
return -EINVAL;
*selected_clock = wl->tcxo_clock;
goto config_mcs_pll;
fref_clk:
/* FREF clock is selected */
if (!wl128x_is_fref_valid(wl))
return -EINVAL;
*selected_clock = wl->ref_clock;
config_mcs_pll:
return wl128x_configure_mcs_pll(wl, *selected_clock);
}
static int wl127x_boot_clk(struct wl1271 *wl)
{
u32 pause;
u32 clk;
if (WL127X_PG_GET_MAJOR(wl->hw_pg_ver) < 3)
wl->quirks |= WLCORE_QUIRK_END_OF_TRANSACTION;
if (wl->ref_clock == CONF_REF_CLK_19_2_E ||
wl->ref_clock == CONF_REF_CLK_38_4_E ||
wl->ref_clock == CONF_REF_CLK_38_4_M_XTAL)
/* ref clk: 19.2/38.4/38.4-XTAL */
clk = 0x3;
else if (wl->ref_clock == CONF_REF_CLK_26_E ||
wl->ref_clock == CONF_REF_CLK_52_E)
/* ref clk: 26/52 */
clk = 0x5;
else
return -EINVAL;
if (wl->ref_clock != CONF_REF_CLK_19_2_E) {
u16 val;
/* Set clock type (open drain) */
val = wl12xx_top_reg_read(wl, OCP_REG_CLK_TYPE);
val &= FREF_CLK_TYPE_BITS;
wl12xx_top_reg_write(wl, OCP_REG_CLK_TYPE, val);
/* Set clock pull mode (no pull) */
val = wl12xx_top_reg_read(wl, OCP_REG_CLK_PULL);
val |= NO_PULL;
wl12xx_top_reg_write(wl, OCP_REG_CLK_PULL, val);
} else {
u16 val;
/* Set clock polarity */
val = wl12xx_top_reg_read(wl, OCP_REG_CLK_POLARITY);
val &= FREF_CLK_POLARITY_BITS;
val |= CLK_REQ_OUTN_SEL;
wl12xx_top_reg_write(wl, OCP_REG_CLK_POLARITY, val);
}
wl1271_write32(wl, WL12XX_PLL_PARAMETERS, clk);
pause = wl1271_read32(wl, WL12XX_PLL_PARAMETERS);
wl1271_debug(DEBUG_BOOT, "pause1 0x%x", pause);
pause &= ~(WU_COUNTER_PAUSE_VAL);
pause |= WU_COUNTER_PAUSE_VAL;
wl1271_write32(wl, WL12XX_WU_COUNTER_PAUSE, pause);
return 0;
}
static int wl1271_boot_soft_reset(struct wl1271 *wl)
{
unsigned long timeout;
u32 boot_data;
/* perform soft reset */
wl1271_write32(wl, WL12XX_SLV_SOFT_RESET, ACX_SLV_SOFT_RESET_BIT);
/* SOFT_RESET is self clearing */
timeout = jiffies + usecs_to_jiffies(SOFT_RESET_MAX_TIME);
while (1) {
boot_data = wl1271_read32(wl, WL12XX_SLV_SOFT_RESET);
wl1271_debug(DEBUG_BOOT, "soft reset bootdata 0x%x", boot_data);
if ((boot_data & ACX_SLV_SOFT_RESET_BIT) == 0)
break;
if (time_after(jiffies, timeout)) {
/* 1.2 check pWhalBus->uSelfClearTime if the
* timeout was reached */
wl1271_error("soft reset timeout");
return -1;
}
udelay(SOFT_RESET_STALL_TIME);
}
/* disable Rx/Tx */
wl1271_write32(wl, WL12XX_ENABLE, 0x0);
/* disable auto calibration on start*/
wl1271_write32(wl, WL12XX_SPARE_A2, 0xffff);
return 0;
}
static int wl12xx_pre_boot(struct wl1271 *wl)
{
int ret = 0;
u32 clk;
int selected_clock = -1;
if (wl->chip.id == CHIP_ID_1283_PG20) {
ret = wl128x_boot_clk(wl, &selected_clock);
if (ret < 0)
goto out;
} else {
ret = wl127x_boot_clk(wl);
if (ret < 0)
goto out;
}
/* Continue the ELP wake up sequence */
wl1271_write32(wl, WL12XX_WELP_ARM_COMMAND, WELP_ARM_COMMAND_VAL);
udelay(500);
wlcore_set_partition(wl, &wl->ptable[PART_DRPW]);
/* Read-modify-write DRPW_SCRATCH_START register (see next state)
to be used by DRPw FW. The RTRIM value will be added by the FW
before taking DRPw out of reset */
clk = wl1271_read32(wl, WL12XX_DRPW_SCRATCH_START);
wl1271_debug(DEBUG_BOOT, "clk2 0x%x", clk);
if (wl->chip.id == CHIP_ID_1283_PG20)
clk |= ((selected_clock & 0x3) << 1) << 4;
else
clk |= (wl->ref_clock << 1) << 4;
wl1271_write32(wl, WL12XX_DRPW_SCRATCH_START, clk);
wlcore_set_partition(wl, &wl->ptable[PART_WORK]);
/* Disable interrupts */
wlcore_write_reg(wl, REG_INTERRUPT_MASK, WL1271_ACX_INTR_ALL);
ret = wl1271_boot_soft_reset(wl);
if (ret < 0)
goto out;
out:
return ret;
}
static void wl12xx_pre_upload(struct wl1271 *wl)
{
u32 tmp;
/* write firmware's last address (ie. it's length) to
* ACX_EEPROMLESS_IND_REG */
wl1271_debug(DEBUG_BOOT, "ACX_EEPROMLESS_IND_REG");
wl1271_write32(wl, WL12XX_EEPROMLESS_IND, WL12XX_EEPROMLESS_IND);
tmp = wlcore_read_reg(wl, REG_CHIP_ID_B);
wl1271_debug(DEBUG_BOOT, "chip id 0x%x", tmp);
/* 6. read the EEPROM parameters */
tmp = wl1271_read32(wl, WL12XX_SCR_PAD2);
/* WL1271: The reference driver skips steps 7 to 10 (jumps directly
* to upload_fw) */
if (wl->chip.id == CHIP_ID_1283_PG20)
wl12xx_top_reg_write(wl, SDIO_IO_DS, HCI_IO_DS_6MA);
}
static void wl12xx_enable_interrupts(struct wl1271 *wl)
{
u32 polarity;
polarity = wl12xx_top_reg_read(wl, OCP_REG_POLARITY);
/* We use HIGH polarity, so unset the LOW bit */
polarity &= ~POLARITY_LOW;
wl12xx_top_reg_write(wl, OCP_REG_POLARITY, polarity);
wlcore_write_reg(wl, REG_INTERRUPT_MASK, WL1271_ACX_ALL_EVENTS_VECTOR);
wlcore_enable_interrupts(wl);
wlcore_write_reg(wl, REG_INTERRUPT_MASK,
WL1271_ACX_INTR_ALL & ~(WL1271_INTR_MASK));
wl1271_write32(wl, WL12XX_HI_CFG, HI_CFG_DEF_VAL);
}
static int wl12xx_boot(struct wl1271 *wl)
{
int ret;
ret = wl12xx_pre_boot(wl);
if (ret < 0)
goto out;
ret = wlcore_boot_upload_nvs(wl);
if (ret < 0)
goto out;
wl12xx_pre_upload(wl);
ret = wlcore_boot_upload_firmware(wl);
if (ret < 0)
goto out;
ret = wlcore_boot_run_firmware(wl);
if (ret < 0)
goto out;
wl12xx_enable_interrupts(wl);
out:
return ret;
}
static void wl12xx_trigger_cmd(struct wl1271 *wl, int cmd_box_addr,
void *buf, size_t len)
{
wl1271_write(wl, cmd_box_addr, buf, len, false);
wlcore_write_reg(wl, REG_INTERRUPT_TRIG, WL12XX_INTR_TRIG_CMD);
}
static void wl12xx_ack_event(struct wl1271 *wl)
{
wlcore_write_reg(wl, REG_INTERRUPT_TRIG, WL12XX_INTR_TRIG_EVENT_ACK);
}
static u32 wl12xx_calc_tx_blocks(struct wl1271 *wl, u32 len, u32 spare_blks)
{
u32 blk_size = WL12XX_TX_HW_BLOCK_SIZE;
u32 align_len = wlcore_calc_packet_alignment(wl, len);
return (align_len + blk_size - 1) / blk_size + spare_blks;
}
static void
wl12xx_set_tx_desc_blocks(struct wl1271 *wl, struct wl1271_tx_hw_descr *desc,
u32 blks, u32 spare_blks)
{
if (wl->chip.id == CHIP_ID_1283_PG20) {
desc->wl128x_mem.total_mem_blocks = blks;
} else {
desc->wl127x_mem.extra_blocks = spare_blks;
desc->wl127x_mem.total_mem_blocks = blks;
}
}
static void
wl12xx_set_tx_desc_data_len(struct wl1271 *wl, struct wl1271_tx_hw_descr *desc,
struct sk_buff *skb)
{
u32 aligned_len = wlcore_calc_packet_alignment(wl, skb->len);
if (wl->chip.id == CHIP_ID_1283_PG20) {
desc->wl128x_mem.extra_bytes = aligned_len - skb->len;
desc->length = cpu_to_le16(aligned_len >> 2);
wl1271_debug(DEBUG_TX,
"tx_fill_hdr: hlid: %d len: %d life: %d mem: %d extra: %d",
desc->hlid,
le16_to_cpu(desc->length),
le16_to_cpu(desc->life_time),
desc->wl128x_mem.total_mem_blocks,
desc->wl128x_mem.extra_bytes);
} else {
/* calculate number of padding bytes */
int pad = aligned_len - skb->len;
desc->tx_attr |=
cpu_to_le16(pad << TX_HW_ATTR_OFST_LAST_WORD_PAD);
/* Store the aligned length in terms of words */
desc->length = cpu_to_le16(aligned_len >> 2);
wl1271_debug(DEBUG_TX,
"tx_fill_hdr: pad: %d hlid: %d len: %d life: %d mem: %d",
pad, desc->hlid,
le16_to_cpu(desc->length),
le16_to_cpu(desc->life_time),
desc->wl127x_mem.total_mem_blocks);
}
}
static enum wl_rx_buf_align
wl12xx_get_rx_buf_align(struct wl1271 *wl, u32 rx_desc)
{
if (rx_desc & RX_BUF_UNALIGNED_PAYLOAD)
return WLCORE_RX_BUF_UNALIGNED;
return WLCORE_RX_BUF_ALIGNED;
}
static u32 wl12xx_get_rx_packet_len(struct wl1271 *wl, void *rx_data,
u32 data_len)
{
struct wl1271_rx_descriptor *desc = rx_data;
/* invalid packet */
if (data_len < sizeof(*desc) ||
data_len < sizeof(*desc) + desc->pad_len)
return 0;
return data_len - sizeof(*desc) - desc->pad_len;
}
static void wl12xx_tx_delayed_compl(struct wl1271 *wl)
{
if (wl->fw_status->tx_results_counter == (wl->tx_results_count & 0xff))
return;
wl1271_tx_complete(wl);
}
static int wl12xx_hw_init(struct wl1271 *wl)
{
int ret;
if (wl->chip.id == CHIP_ID_1283_PG20) {
u32 host_cfg_bitmap = HOST_IF_CFG_RX_FIFO_ENABLE;
ret = wl128x_cmd_general_parms(wl);
if (ret < 0)
goto out;
ret = wl128x_cmd_radio_parms(wl);
if (ret < 0)
goto out;
if (wl->quirks & WLCORE_QUIRK_TX_BLOCKSIZE_ALIGN)
/* Enable SDIO padding */
host_cfg_bitmap |= HOST_IF_CFG_TX_PAD_TO_SDIO_BLK;
/* Must be before wl1271_acx_init_mem_config() */
ret = wl1271_acx_host_if_cfg_bitmap(wl, host_cfg_bitmap);
if (ret < 0)
goto out;
} else {
ret = wl1271_cmd_general_parms(wl);
if (ret < 0)
goto out;
ret = wl1271_cmd_radio_parms(wl);
if (ret < 0)
goto out;
ret = wl1271_cmd_ext_radio_parms(wl);
if (ret < 0)
goto out;
}
out:
return ret;
}
static u32 wl12xx_sta_get_ap_rate_mask(struct wl1271 *wl,
struct wl12xx_vif *wlvif)
{
return wlvif->rate_set;
}
static int wl12xx_identify_fw(struct wl1271 *wl)
{
unsigned int *fw_ver = wl->chip.fw_ver;
/* Only new station firmwares support routing fw logs to the host */
if ((fw_ver[FW_VER_IF_TYPE] == FW_VER_IF_TYPE_STA) &&
(fw_ver[FW_VER_MINOR] < FW_VER_MINOR_FWLOG_STA_MIN))
wl->quirks |= WLCORE_QUIRK_FWLOG_NOT_IMPLEMENTED;
/* This feature is not yet supported for AP mode */
if (fw_ver[FW_VER_IF_TYPE] == FW_VER_IF_TYPE_AP)
wl->quirks |= WLCORE_QUIRK_FWLOG_NOT_IMPLEMENTED;
return 0;
}
static void wl12xx_conf_init(struct wl1271 *wl)
{
struct wl12xx_priv *priv = wl->priv;
/* apply driver default configuration */
memcpy(&wl->conf, &wl12xx_conf, sizeof(wl12xx_conf));
/* apply default private configuration */
memcpy(&priv->conf, &wl12xx_default_priv_conf, sizeof(priv->conf));
}
static bool wl12xx_mac_in_fuse(struct wl1271 *wl)
{
bool supported = false;
u8 major, minor;
if (wl->chip.id == CHIP_ID_1283_PG20) {
major = WL128X_PG_GET_MAJOR(wl->hw_pg_ver);
minor = WL128X_PG_GET_MINOR(wl->hw_pg_ver);
/* in wl128x we have the MAC address if the PG is >= (2, 1) */
if (major > 2 || (major == 2 && minor >= 1))
supported = true;
} else {
major = WL127X_PG_GET_MAJOR(wl->hw_pg_ver);
minor = WL127X_PG_GET_MINOR(wl->hw_pg_ver);
/* in wl127x we have the MAC address if the PG is >= (3, 1) */
if (major == 3 && minor >= 1)
supported = true;
}
wl1271_debug(DEBUG_PROBE,
"PG Ver major = %d minor = %d, MAC %s present",
major, minor, supported ? "is" : "is not");
return supported;
}
static void wl12xx_get_fuse_mac(struct wl1271 *wl)
{
u32 mac1, mac2;
wlcore_set_partition(wl, &wl->ptable[PART_DRPW]);
mac1 = wl1271_read32(wl, WL12XX_REG_FUSE_BD_ADDR_1);
mac2 = wl1271_read32(wl, WL12XX_REG_FUSE_BD_ADDR_2);
/* these are the two parts of the BD_ADDR */
wl->fuse_oui_addr = ((mac2 & 0xffff) << 8) +
((mac1 & 0xff000000) >> 24);
wl->fuse_nic_addr = mac1 & 0xffffff;
wlcore_set_partition(wl, &wl->ptable[PART_DOWN]);
}
static s8 wl12xx_get_pg_ver(struct wl1271 *wl)
{
u32 die_info;
if (wl->chip.id == CHIP_ID_1283_PG20)
die_info = wl12xx_top_reg_read(wl, WL128X_REG_FUSE_DATA_2_1);
else
die_info = wl12xx_top_reg_read(wl, WL127X_REG_FUSE_DATA_2_1);
return (s8) (die_info & PG_VER_MASK) >> PG_VER_OFFSET;
}
static void wl12xx_get_mac(struct wl1271 *wl)
{
if (wl12xx_mac_in_fuse(wl))
wl12xx_get_fuse_mac(wl);
}
static struct wlcore_ops wl12xx_ops = {
.identify_chip = wl12xx_identify_chip,
.identify_fw = wl12xx_identify_fw,
.boot = wl12xx_boot,
.trigger_cmd = wl12xx_trigger_cmd,
.ack_event = wl12xx_ack_event,
.calc_tx_blocks = wl12xx_calc_tx_blocks,
.set_tx_desc_blocks = wl12xx_set_tx_desc_blocks,
.set_tx_desc_data_len = wl12xx_set_tx_desc_data_len,
.get_rx_buf_align = wl12xx_get_rx_buf_align,
.get_rx_packet_len = wl12xx_get_rx_packet_len,
.tx_immediate_compl = NULL,
.tx_delayed_compl = wl12xx_tx_delayed_compl,
.hw_init = wl12xx_hw_init,
.init_vif = NULL,
.sta_get_ap_rate_mask = wl12xx_sta_get_ap_rate_mask,
.get_pg_ver = wl12xx_get_pg_ver,
.get_mac = wl12xx_get_mac,
};
static struct ieee80211_sta_ht_cap wl12xx_ht_cap = {
.cap = IEEE80211_HT_CAP_GRN_FLD | IEEE80211_HT_CAP_SGI_20 |
(1 << IEEE80211_HT_CAP_RX_STBC_SHIFT),
.ht_supported = true,
.ampdu_factor = IEEE80211_HT_MAX_AMPDU_8K,
.ampdu_density = IEEE80211_HT_MPDU_DENSITY_8,
.mcs = {
.rx_mask = { 0xff, 0, 0, 0, 0, 0, 0, 0, 0, 0, },
.rx_highest = cpu_to_le16(72),
.tx_params = IEEE80211_HT_MCS_TX_DEFINED,
},
};
static int __devinit wl12xx_probe(struct platform_device *pdev)
{
struct wl1271 *wl;
struct ieee80211_hw *hw;
struct wl12xx_priv *priv;
hw = wlcore_alloc_hw(sizeof(*priv));
if (IS_ERR(hw)) {
wl1271_error("can't allocate hw");
return PTR_ERR(hw);
}
wl = hw->priv;
wl->ops = &wl12xx_ops;
wl->ptable = wl12xx_ptable;
wl->rtable = wl12xx_rtable;
wl->num_tx_desc = 16;
wl->normal_tx_spare = WL12XX_TX_HW_BLOCK_SPARE_DEFAULT;
wl->gem_tx_spare = WL12XX_TX_HW_BLOCK_GEM_SPARE;
wl->band_rate_to_idx = wl12xx_band_rate_to_idx;
wl->hw_tx_rate_tbl_size = WL12XX_CONF_HW_RXTX_RATE_MAX;
wl->hw_min_ht_rate = WL12XX_CONF_HW_RXTX_RATE_MCS0;
wl->fw_status_priv_len = 0;
memcpy(&wl->ht_cap, &wl12xx_ht_cap, sizeof(wl12xx_ht_cap));
wl12xx_conf_init(wl);
return wlcore_probe(wl, pdev);
}
static const struct platform_device_id wl12xx_id_table[] __devinitconst = {
{ "wl12xx", 0 },
{ } /* Terminating Entry */
};
MODULE_DEVICE_TABLE(platform, wl12xx_id_table);
static struct platform_driver wl12xx_driver = {
.probe = wl12xx_probe,
.remove = __devexit_p(wlcore_remove),
.id_table = wl12xx_id_table,
.driver = {
.name = "wl12xx_driver",
.owner = THIS_MODULE,
}
};
static int __init wl12xx_init(void)
{
return platform_driver_register(&wl12xx_driver);
}
module_init(wl12xx_init);
static void __exit wl12xx_exit(void)
{
platform_driver_unregister(&wl12xx_driver);
}
module_exit(wl12xx_exit);
MODULE_LICENSE("GPL v2");
MODULE_AUTHOR("Luciano Coelho <coelho@ti.com>");
MODULE_FIRMWARE(WL127X_FW_NAME_SINGLE);
MODULE_FIRMWARE(WL127X_FW_NAME_MULTI);
MODULE_FIRMWARE(WL127X_PLT_FW_NAME);
MODULE_FIRMWARE(WL128X_FW_NAME_SINGLE);
MODULE_FIRMWARE(WL128X_FW_NAME_MULTI);
MODULE_FIRMWARE(WL128X_PLT_FW_NAME);
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