linux/drivers/net/wireless/iwlwifi/iwl-commands.h

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/******************************************************************************
*
* This file is provided under a dual BSD/GPLv2 license. When using or
* redistributing this file, you may do so under either license.
*
* GPL LICENSE SUMMARY
*
* Copyright(c) 2005 - 2011 Intel Corporation. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of version 2 of the GNU General Public License 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 Street, Fifth Floor, Boston, MA 02110,
* USA
*
* The full GNU General Public License is included in this distribution
* in the file called LICENSE.GPL.
*
* Contact Information:
* Intel Linux Wireless <ilw@linux.intel.com>
* Intel Corporation, 5200 N.E. Elam Young Parkway, Hillsboro, OR 97124-6497
*
* BSD LICENSE
*
* Copyright(c) 2005 - 2011 Intel Corporation. All rights reserved.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* * Neither the name Intel Corporation nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
*****************************************************************************/
/*
* Please use this file (iwl-commands.h) only for uCode API definitions.
* Please use iwl-xxxx-hw.h for hardware-related definitions.
* Please use iwl-dev.h for driver implementation definitions.
*/
#ifndef __iwl_commands_h__
#define __iwl_commands_h__
struct iwl_priv;
/* uCode version contains 4 values: Major/Minor/API/Serial */
#define IWL_UCODE_MAJOR(ver) (((ver) & 0xFF000000) >> 24)
#define IWL_UCODE_MINOR(ver) (((ver) & 0x00FF0000) >> 16)
#define IWL_UCODE_API(ver) (((ver) & 0x0000FF00) >> 8)
#define IWL_UCODE_SERIAL(ver) ((ver) & 0x000000FF)
/* Tx rates */
#define IWL_CCK_RATES 4
#define IWL_OFDM_RATES 8
#define IWL_MAX_RATES (IWL_CCK_RATES + IWL_OFDM_RATES)
enum {
REPLY_ALIVE = 0x1,
REPLY_ERROR = 0x2,
/* RXON and QOS commands */
REPLY_RXON = 0x10,
REPLY_RXON_ASSOC = 0x11,
REPLY_QOS_PARAM = 0x13,
REPLY_RXON_TIMING = 0x14,
/* Multi-Station support */
REPLY_ADD_STA = 0x18,
REPLY_REMOVE_STA = 0x19,
REPLY_REMOVE_ALL_STA = 0x1a, /* not used */
REPLY_TXFIFO_FLUSH = 0x1e,
/* Security */
REPLY_WEPKEY = 0x20,
/* RX, TX, LEDs */
REPLY_TX = 0x1c,
REPLY_LEDS_CMD = 0x48,
REPLY_TX_LINK_QUALITY_CMD = 0x4e, /* for 4965 and up */
/* WiMAX coexistence */
COEX_PRIORITY_TABLE_CMD = 0x5a, /* for 5000 series and up */
COEX_MEDIUM_NOTIFICATION = 0x5b,
COEX_EVENT_CMD = 0x5c,
/* Calibration */
TEMPERATURE_NOTIFICATION = 0x62,
CALIBRATION_CFG_CMD = 0x65,
CALIBRATION_RES_NOTIFICATION = 0x66,
CALIBRATION_COMPLETE_NOTIFICATION = 0x67,
/* 802.11h related */
REPLY_QUIET_CMD = 0x71, /* not used */
REPLY_CHANNEL_SWITCH = 0x72,
CHANNEL_SWITCH_NOTIFICATION = 0x73,
REPLY_SPECTRUM_MEASUREMENT_CMD = 0x74,
SPECTRUM_MEASURE_NOTIFICATION = 0x75,
/* Power Management */
POWER_TABLE_CMD = 0x77,
PM_SLEEP_NOTIFICATION = 0x7A,
PM_DEBUG_STATISTIC_NOTIFIC = 0x7B,
/* Scan commands and notifications */
REPLY_SCAN_CMD = 0x80,
REPLY_SCAN_ABORT_CMD = 0x81,
SCAN_START_NOTIFICATION = 0x82,
SCAN_RESULTS_NOTIFICATION = 0x83,
SCAN_COMPLETE_NOTIFICATION = 0x84,
/* IBSS/AP commands */
BEACON_NOTIFICATION = 0x90,
REPLY_TX_BEACON = 0x91,
WHO_IS_AWAKE_NOTIFICATION = 0x94, /* not used */
/* Miscellaneous commands */
REPLY_TX_POWER_DBM_CMD = 0x95,
QUIET_NOTIFICATION = 0x96, /* not used */
REPLY_TX_PWR_TABLE_CMD = 0x97,
REPLY_TX_POWER_DBM_CMD_V1 = 0x98, /* old version of API */
TX_ANT_CONFIGURATION_CMD = 0x98,
MEASURE_ABORT_NOTIFICATION = 0x99, /* not used */
/* Bluetooth device coexistence config command */
REPLY_BT_CONFIG = 0x9b,
/* Statistics */
REPLY_STATISTICS_CMD = 0x9c,
STATISTICS_NOTIFICATION = 0x9d,
/* RF-KILL commands and notifications */
REPLY_CARD_STATE_CMD = 0xa0,
CARD_STATE_NOTIFICATION = 0xa1,
/* Missed beacons notification */
MISSED_BEACONS_NOTIFICATION = 0xa2,
REPLY_CT_KILL_CONFIG_CMD = 0xa4,
SENSITIVITY_CMD = 0xa8,
REPLY_PHY_CALIBRATION_CMD = 0xb0,
REPLY_RX_PHY_CMD = 0xc0,
REPLY_RX_MPDU_CMD = 0xc1,
REPLY_RX = 0xc3,
REPLY_COMPRESSED_BA = 0xc5,
/* BT Coex */
REPLY_BT_COEX_PRIO_TABLE = 0xcc,
REPLY_BT_COEX_PROT_ENV = 0xcd,
REPLY_BT_COEX_PROFILE_NOTIF = 0xce,
/* PAN commands */
REPLY_WIPAN_PARAMS = 0xb2,
REPLY_WIPAN_RXON = 0xb3, /* use REPLY_RXON structure */
REPLY_WIPAN_RXON_TIMING = 0xb4, /* use REPLY_RXON_TIMING structure */
REPLY_WIPAN_RXON_ASSOC = 0xb6, /* use REPLY_RXON_ASSOC structure */
REPLY_WIPAN_QOS_PARAM = 0xb7, /* use REPLY_QOS_PARAM structure */
REPLY_WIPAN_WEPKEY = 0xb8, /* use REPLY_WEPKEY structure */
REPLY_WIPAN_P2P_CHANNEL_SWITCH = 0xb9,
REPLY_WIPAN_NOA_NOTIFICATION = 0xbc,
REPLY_WIPAN_DEACTIVATION_COMPLETE = 0xbd,
REPLY_MAX = 0xff
};
/******************************************************************************
* (0)
* Commonly used structures and definitions:
* Command header, rate_n_flags, txpower
*
*****************************************************************************/
/* iwl_cmd_header flags value */
#define IWL_CMD_FAILED_MSK 0x40
#define SEQ_TO_QUEUE(s) (((s) >> 8) & 0x1f)
#define QUEUE_TO_SEQ(q) (((q) & 0x1f) << 8)
#define SEQ_TO_INDEX(s) ((s) & 0xff)
#define INDEX_TO_SEQ(i) ((i) & 0xff)
#define SEQ_RX_FRAME cpu_to_le16(0x8000)
/**
* struct iwl_cmd_header
*
* This header format appears in the beginning of each command sent from the
* driver, and each response/notification received from uCode.
*/
struct iwl_cmd_header {
u8 cmd; /* Command ID: REPLY_RXON, etc. */
u8 flags; /* 0:5 reserved, 6 abort, 7 internal */
/*
* The driver sets up the sequence number to values of its choosing.
* uCode does not use this value, but passes it back to the driver
* when sending the response to each driver-originated command, so
* the driver can match the response to the command. Since the values
* don't get used by uCode, the driver may set up an arbitrary format.
*
* There is one exception: uCode sets bit 15 when it originates
* the response/notification, i.e. when the response/notification
* is not a direct response to a command sent by the driver. For
* example, uCode issues REPLY_RX when it sends a received frame
* to the driver; it is not a direct response to any driver command.
*
* The Linux driver uses the following format:
*
* 0:7 tfd index - position within TX queue
* 8:12 TX queue id
* 13:14 reserved
* 15 unsolicited RX or uCode-originated notification
*/
__le16 sequence;
/* command or response/notification data follows immediately */
u8 data[0];
} __packed;
/**
* iwlagn rate_n_flags bit fields
*
* rate_n_flags format is used in following iwlagn commands:
* REPLY_RX (response only)
* REPLY_RX_MPDU (response only)
* REPLY_TX (both command and response)
* REPLY_TX_LINK_QUALITY_CMD
*
* High-throughput (HT) rate format for bits 7:0 (bit 8 must be "1"):
* 2-0: 0) 6 Mbps
* 1) 12 Mbps
* 2) 18 Mbps
* 3) 24 Mbps
* 4) 36 Mbps
* 5) 48 Mbps
* 6) 54 Mbps
* 7) 60 Mbps
*
* 4-3: 0) Single stream (SISO)
* 1) Dual stream (MIMO)
* 2) Triple stream (MIMO)
*
* 5: Value of 0x20 in bits 7:0 indicates 6 Mbps HT40 duplicate data
*
* Legacy OFDM rate format for bits 7:0 (bit 8 must be "0", bit 9 "0"):
* 3-0: 0xD) 6 Mbps
* 0xF) 9 Mbps
* 0x5) 12 Mbps
* 0x7) 18 Mbps
* 0x9) 24 Mbps
* 0xB) 36 Mbps
* 0x1) 48 Mbps
* 0x3) 54 Mbps
*
* Legacy CCK rate format for bits 7:0 (bit 8 must be "0", bit 9 "1"):
* 6-0: 10) 1 Mbps
* 20) 2 Mbps
* 55) 5.5 Mbps
* 110) 11 Mbps
*/
#define RATE_MCS_CODE_MSK 0x7
#define RATE_MCS_SPATIAL_POS 3
#define RATE_MCS_SPATIAL_MSK 0x18
#define RATE_MCS_HT_DUP_POS 5
#define RATE_MCS_HT_DUP_MSK 0x20
/* Both legacy and HT use bits 7:0 as the CCK/OFDM rate or HT MCS */
#define RATE_MCS_RATE_MSK 0xff
/* Bit 8: (1) HT format, (0) legacy format in bits 7:0 */
#define RATE_MCS_FLAGS_POS 8
#define RATE_MCS_HT_POS 8
#define RATE_MCS_HT_MSK 0x100
/* Bit 9: (1) CCK, (0) OFDM. HT (bit 8) must be "0" for this bit to be valid */
#define RATE_MCS_CCK_POS 9
#define RATE_MCS_CCK_MSK 0x200
/* Bit 10: (1) Use Green Field preamble */
#define RATE_MCS_GF_POS 10
#define RATE_MCS_GF_MSK 0x400
/* Bit 11: (1) Use 40Mhz HT40 chnl width, (0) use 20 MHz legacy chnl width */
#define RATE_MCS_HT40_POS 11
#define RATE_MCS_HT40_MSK 0x800
/* Bit 12: (1) Duplicate data on both 20MHz chnls. HT40 (bit 11) must be set. */
#define RATE_MCS_DUP_POS 12
#define RATE_MCS_DUP_MSK 0x1000
/* Bit 13: (1) Short guard interval (0.4 usec), (0) normal GI (0.8 usec) */
#define RATE_MCS_SGI_POS 13
#define RATE_MCS_SGI_MSK 0x2000
/**
* rate_n_flags Tx antenna masks
* 4965 has 2 transmitters
* 5100 has 1 transmitter B
* 5150 has 1 transmitter A
* 5300 has 3 transmitters
* 5350 has 3 transmitters
* bit14:16
*/
#define RATE_MCS_ANT_POS 14
#define RATE_MCS_ANT_A_MSK 0x04000
#define RATE_MCS_ANT_B_MSK 0x08000
#define RATE_MCS_ANT_C_MSK 0x10000
#define RATE_MCS_ANT_AB_MSK (RATE_MCS_ANT_A_MSK | RATE_MCS_ANT_B_MSK)
#define RATE_MCS_ANT_ABC_MSK (RATE_MCS_ANT_AB_MSK | RATE_MCS_ANT_C_MSK)
#define RATE_ANT_NUM 3
#define POWER_TABLE_NUM_ENTRIES 33
#define POWER_TABLE_NUM_HT_OFDM_ENTRIES 32
#define POWER_TABLE_CCK_ENTRY 32
#define IWL_PWR_NUM_HT_OFDM_ENTRIES 24
#define IWL_PWR_CCK_ENTRIES 2
/**
* struct tx_power_dual_stream
*
* Table entries in REPLY_TX_PWR_TABLE_CMD, REPLY_CHANNEL_SWITCH
*
* Same format as iwl_tx_power_dual_stream, but __le32
*/
struct tx_power_dual_stream {
__le32 dw;
} __packed;
/**
* Command REPLY_TX_POWER_DBM_CMD = 0x98
* struct iwlagn_tx_power_dbm_cmd
*/
#define IWLAGN_TX_POWER_AUTO 0x7f
#define IWLAGN_TX_POWER_NO_CLOSED (0x1 << 6)
struct iwlagn_tx_power_dbm_cmd {
s8 global_lmt; /*in half-dBm (e.g. 30 = 15 dBm) */
u8 flags;
s8 srv_chan_lmt; /*in half-dBm (e.g. 30 = 15 dBm) */
u8 reserved;
} __packed;
/**
* Command TX_ANT_CONFIGURATION_CMD = 0x98
* This command is used to configure valid Tx antenna.
* By default uCode concludes the valid antenna according to the radio flavor.
* This command enables the driver to override/modify this conclusion.
*/
struct iwl_tx_ant_config_cmd {
__le32 valid;
} __packed;
/******************************************************************************
* (0a)
* Alive and Error Commands & Responses:
*
*****************************************************************************/
#define UCODE_VALID_OK cpu_to_le32(0x1)
/**
* REPLY_ALIVE = 0x1 (response only, not a command)
*
* uCode issues this "alive" notification once the runtime image is ready
* to receive commands from the driver. This is the *second* "alive"
* notification that the driver will receive after rebooting uCode;
* this "alive" is indicated by subtype field != 9.
*
* See comments documenting "BSM" (bootstrap state machine).
*
* This response includes two pointers to structures within the device's
* data SRAM (access via HBUS_TARG_MEM_* regs) that are useful for debugging:
*
* 1) log_event_table_ptr indicates base of the event log. This traces
* a 256-entry history of uCode execution within a circular buffer.
* Its header format is:
*
* __le32 log_size; log capacity (in number of entries)
* __le32 type; (1) timestamp with each entry, (0) no timestamp
* __le32 wraps; # times uCode has wrapped to top of circular buffer
* __le32 write_index; next circular buffer entry that uCode would fill
*
* The header is followed by the circular buffer of log entries. Entries
* with timestamps have the following format:
*
* __le32 event_id; range 0 - 1500
* __le32 timestamp; low 32 bits of TSF (of network, if associated)
* __le32 data; event_id-specific data value
*
* Entries without timestamps contain only event_id and data.
*
*
* 2) error_event_table_ptr indicates base of the error log. This contains
* information about any uCode error that occurs. For agn, the format
* of the error log is defined by struct iwl_error_event_table.
*
* The Linux driver can print both logs to the system log when a uCode error
* occurs.
*/
/*
* Note: This structure is read from the device with IO accesses,
* and the reading already does the endian conversion. As it is
* read with u32-sized accesses, any members with a different size
* need to be ordered correctly though!
*/
struct iwl_error_event_table {
u32 valid; /* (nonzero) valid, (0) log is empty */
u32 error_id; /* type of error */
u32 pc; /* program counter */
u32 blink1; /* branch link */
u32 blink2; /* branch link */
u32 ilink1; /* interrupt link */
u32 ilink2; /* interrupt link */
u32 data1; /* error-specific data */
u32 data2; /* error-specific data */
u32 line; /* source code line of error */
u32 bcon_time; /* beacon timer */
u32 tsf_low; /* network timestamp function timer */
u32 tsf_hi; /* network timestamp function timer */
u32 gp1; /* GP1 timer register */
u32 gp2; /* GP2 timer register */
u32 gp3; /* GP3 timer register */
u32 ucode_ver; /* uCode version */
u32 hw_ver; /* HW Silicon version */
u32 brd_ver; /* HW board version */
u32 log_pc; /* log program counter */
u32 frame_ptr; /* frame pointer */
u32 stack_ptr; /* stack pointer */
u32 hcmd; /* last host command header */
#if 0
/* no need to read the remainder, we don't use the values */
u32 isr0; /* isr status register LMPM_NIC_ISR0: rxtx_flag */
u32 isr1; /* isr status register LMPM_NIC_ISR1: host_flag */
u32 isr2; /* isr status register LMPM_NIC_ISR2: enc_flag */
u32 isr3; /* isr status register LMPM_NIC_ISR3: time_flag */
u32 isr4; /* isr status register LMPM_NIC_ISR4: wico interrupt */
u32 isr_pref; /* isr status register LMPM_NIC_PREF_STAT */
u32 wait_event; /* wait event() caller address */
u32 l2p_control; /* L2pControlField */
u32 l2p_duration; /* L2pDurationField */
u32 l2p_mhvalid; /* L2pMhValidBits */
u32 l2p_addr_match; /* L2pAddrMatchStat */
u32 lmpm_pmg_sel; /* indicate which clocks are turned on (LMPM_PMG_SEL) */
u32 u_timestamp; /* indicate when the date and time of the compilation */
u32 flow_handler; /* FH read/write pointers, RX credit */
#endif
} __packed;
struct iwl_alive_resp {
u8 ucode_minor;
u8 ucode_major;
__le16 reserved1;
u8 sw_rev[8];
u8 ver_type;
u8 ver_subtype; /* not "9" for runtime alive */
__le16 reserved2;
__le32 log_event_table_ptr; /* SRAM address for event log */
__le32 error_event_table_ptr; /* SRAM address for error log */
__le32 timestamp;
__le32 is_valid;
} __packed;
/*
* REPLY_ERROR = 0x2 (response only, not a command)
*/
struct iwl_error_resp {
__le32 error_type;
u8 cmd_id;
u8 reserved1;
__le16 bad_cmd_seq_num;
__le32 error_info;
__le64 timestamp;
} __packed;
/******************************************************************************
* (1)
* RXON Commands & Responses:
*
*****************************************************************************/
/*
* Rx config defines & structure
*/
/* rx_config device types */
enum {
RXON_DEV_TYPE_AP = 1,
RXON_DEV_TYPE_ESS = 3,
RXON_DEV_TYPE_IBSS = 4,
RXON_DEV_TYPE_SNIFFER = 6,
RXON_DEV_TYPE_CP = 7,
RXON_DEV_TYPE_2STA = 8,
RXON_DEV_TYPE_P2P = 9,
};
#define RXON_RX_CHAIN_DRIVER_FORCE_MSK cpu_to_le16(0x1 << 0)
#define RXON_RX_CHAIN_DRIVER_FORCE_POS (0)
#define RXON_RX_CHAIN_VALID_MSK cpu_to_le16(0x7 << 1)
#define RXON_RX_CHAIN_VALID_POS (1)
#define RXON_RX_CHAIN_FORCE_SEL_MSK cpu_to_le16(0x7 << 4)
#define RXON_RX_CHAIN_FORCE_SEL_POS (4)
#define RXON_RX_CHAIN_FORCE_MIMO_SEL_MSK cpu_to_le16(0x7 << 7)
#define RXON_RX_CHAIN_FORCE_MIMO_SEL_POS (7)
#define RXON_RX_CHAIN_CNT_MSK cpu_to_le16(0x3 << 10)
#define RXON_RX_CHAIN_CNT_POS (10)
#define RXON_RX_CHAIN_MIMO_CNT_MSK cpu_to_le16(0x3 << 12)
#define RXON_RX_CHAIN_MIMO_CNT_POS (12)
#define RXON_RX_CHAIN_MIMO_FORCE_MSK cpu_to_le16(0x1 << 14)
#define RXON_RX_CHAIN_MIMO_FORCE_POS (14)
/* rx_config flags */
/* band & modulation selection */
#define RXON_FLG_BAND_24G_MSK cpu_to_le32(1 << 0)
#define RXON_FLG_CCK_MSK cpu_to_le32(1 << 1)
/* auto detection enable */
#define RXON_FLG_AUTO_DETECT_MSK cpu_to_le32(1 << 2)
/* TGg protection when tx */
#define RXON_FLG_TGG_PROTECT_MSK cpu_to_le32(1 << 3)
/* cck short slot & preamble */
#define RXON_FLG_SHORT_SLOT_MSK cpu_to_le32(1 << 4)
#define RXON_FLG_SHORT_PREAMBLE_MSK cpu_to_le32(1 << 5)
/* antenna selection */
#define RXON_FLG_DIS_DIV_MSK cpu_to_le32(1 << 7)
#define RXON_FLG_ANT_SEL_MSK cpu_to_le32(0x0f00)
#define RXON_FLG_ANT_A_MSK cpu_to_le32(1 << 8)
#define RXON_FLG_ANT_B_MSK cpu_to_le32(1 << 9)
/* radar detection enable */
#define RXON_FLG_RADAR_DETECT_MSK cpu_to_le32(1 << 12)
#define RXON_FLG_TGJ_NARROW_BAND_MSK cpu_to_le32(1 << 13)
/* rx response to host with 8-byte TSF
* (according to ON_AIR deassertion) */
#define RXON_FLG_TSF2HOST_MSK cpu_to_le32(1 << 15)
/* HT flags */
#define RXON_FLG_CTRL_CHANNEL_LOC_POS (22)
#define RXON_FLG_CTRL_CHANNEL_LOC_HI_MSK cpu_to_le32(0x1 << 22)
#define RXON_FLG_HT_OPERATING_MODE_POS (23)
#define RXON_FLG_HT_PROT_MSK cpu_to_le32(0x1 << 23)
#define RXON_FLG_HT40_PROT_MSK cpu_to_le32(0x2 << 23)
#define RXON_FLG_CHANNEL_MODE_POS (25)
#define RXON_FLG_CHANNEL_MODE_MSK cpu_to_le32(0x3 << 25)
/* channel mode */
enum {
CHANNEL_MODE_LEGACY = 0,
CHANNEL_MODE_PURE_40 = 1,
CHANNEL_MODE_MIXED = 2,
CHANNEL_MODE_RESERVED = 3,
};
#define RXON_FLG_CHANNEL_MODE_LEGACY cpu_to_le32(CHANNEL_MODE_LEGACY << RXON_FLG_CHANNEL_MODE_POS)
#define RXON_FLG_CHANNEL_MODE_PURE_40 cpu_to_le32(CHANNEL_MODE_PURE_40 << RXON_FLG_CHANNEL_MODE_POS)
#define RXON_FLG_CHANNEL_MODE_MIXED cpu_to_le32(CHANNEL_MODE_MIXED << RXON_FLG_CHANNEL_MODE_POS)
/* CTS to self (if spec allows) flag */
#define RXON_FLG_SELF_CTS_EN cpu_to_le32(0x1<<30)
/* rx_config filter flags */
/* accept all data frames */
#define RXON_FILTER_PROMISC_MSK cpu_to_le32(1 << 0)
/* pass control & management to host */
#define RXON_FILTER_CTL2HOST_MSK cpu_to_le32(1 << 1)
/* accept multi-cast */
#define RXON_FILTER_ACCEPT_GRP_MSK cpu_to_le32(1 << 2)
/* don't decrypt uni-cast frames */
#define RXON_FILTER_DIS_DECRYPT_MSK cpu_to_le32(1 << 3)
/* don't decrypt multi-cast frames */
#define RXON_FILTER_DIS_GRP_DECRYPT_MSK cpu_to_le32(1 << 4)
/* STA is associated */
#define RXON_FILTER_ASSOC_MSK cpu_to_le32(1 << 5)
/* transfer to host non bssid beacons in associated state */
#define RXON_FILTER_BCON_AWARE_MSK cpu_to_le32(1 << 6)
/**
* REPLY_RXON = 0x10 (command, has simple generic response)
*
* RXON tunes the radio tuner to a service channel, and sets up a number
* of parameters that are used primarily for Rx, but also for Tx operations.
*
* NOTE: When tuning to a new channel, driver must set the
* RXON_FILTER_ASSOC_MSK to 0. This will clear station-dependent
* info within the device, including the station tables, tx retry
* rate tables, and txpower tables. Driver must build a new station
* table and txpower table before transmitting anything on the RXON
* channel.
*
* NOTE: All RXONs wipe clean the internal txpower table. Driver must
* issue a new REPLY_TX_PWR_TABLE_CMD after each REPLY_RXON (0x10),
* regardless of whether RXON_FILTER_ASSOC_MSK is set.
*/
struct iwl_rxon_cmd {
u8 node_addr[6];
__le16 reserved1;
u8 bssid_addr[6];
__le16 reserved2;
u8 wlap_bssid_addr[6];
__le16 reserved3;
u8 dev_type;
u8 air_propagation;
__le16 rx_chain;
u8 ofdm_basic_rates;
u8 cck_basic_rates;
__le16 assoc_id;
__le32 flags;
__le32 filter_flags;
__le16 channel;
u8 ofdm_ht_single_stream_basic_rates;
u8 ofdm_ht_dual_stream_basic_rates;
u8 ofdm_ht_triple_stream_basic_rates;
u8 reserved5;
__le16 acquisition_data;
__le16 reserved6;
} __packed;
/*
* REPLY_RXON_ASSOC = 0x11 (command, has simple generic response)
*/
struct iwl_rxon_assoc_cmd {
__le32 flags;
__le32 filter_flags;
u8 ofdm_basic_rates;
u8 cck_basic_rates;
__le16 reserved1;
u8 ofdm_ht_single_stream_basic_rates;
u8 ofdm_ht_dual_stream_basic_rates;
u8 ofdm_ht_triple_stream_basic_rates;
u8 reserved2;
__le16 rx_chain_select_flags;
__le16 acquisition_data;
__le32 reserved3;
} __packed;
#define IWL_CONN_MAX_LISTEN_INTERVAL 10
#define IWL_MAX_UCODE_BEACON_INTERVAL 4 /* 4096 */
#define IWL39_MAX_UCODE_BEACON_INTERVAL 1 /* 1024 */
/*
* REPLY_RXON_TIMING = 0x14 (command, has simple generic response)
*/
struct iwl_rxon_time_cmd {
__le64 timestamp;
__le16 beacon_interval;
__le16 atim_window;
__le32 beacon_init_val;
__le16 listen_interval;
u8 dtim_period;
u8 delta_cp_bss_tbtts;
} __packed;
/*
* REPLY_CHANNEL_SWITCH = 0x72 (command, has simple generic response)
*/
/**
* struct iwl5000_channel_switch_cmd
* @band: 0- 5.2GHz, 1- 2.4GHz
* @expect_beacon: 0- resume transmits after channel switch
* 1- wait for beacon to resume transmits
* @channel: new channel number
* @rxon_flags: Rx on flags
* @rxon_filter_flags: filtering parameters
* @switch_time: switch time in extended beacon format
* @reserved: reserved bytes
*/
struct iwl5000_channel_switch_cmd {
u8 band;
u8 expect_beacon;
__le16 channel;
__le32 rxon_flags;
__le32 rxon_filter_flags;
__le32 switch_time;
__le32 reserved[2][IWL_PWR_NUM_HT_OFDM_ENTRIES + IWL_PWR_CCK_ENTRIES];
} __packed;
/**
* struct iwl6000_channel_switch_cmd
* @band: 0- 5.2GHz, 1- 2.4GHz
* @expect_beacon: 0- resume transmits after channel switch
* 1- wait for beacon to resume transmits
* @channel: new channel number
* @rxon_flags: Rx on flags
* @rxon_filter_flags: filtering parameters
* @switch_time: switch time in extended beacon format
* @reserved: reserved bytes
*/
struct iwl6000_channel_switch_cmd {
u8 band;
u8 expect_beacon;
__le16 channel;
__le32 rxon_flags;
__le32 rxon_filter_flags;
__le32 switch_time;
__le32 reserved[3][IWL_PWR_NUM_HT_OFDM_ENTRIES + IWL_PWR_CCK_ENTRIES];
} __packed;
/*
* CHANNEL_SWITCH_NOTIFICATION = 0x73 (notification only, not a command)
*/
struct iwl_csa_notification {
__le16 band;
__le16 channel;
__le32 status; /* 0 - OK, 1 - fail */
} __packed;
/******************************************************************************
* (2)
* Quality-of-Service (QOS) Commands & Responses:
*
*****************************************************************************/
/**
* struct iwl_ac_qos -- QOS timing params for REPLY_QOS_PARAM
* One for each of 4 EDCA access categories in struct iwl_qosparam_cmd
*
* @cw_min: Contention window, start value in numbers of slots.
* Should be a power-of-2, minus 1. Device's default is 0x0f.
* @cw_max: Contention window, max value in numbers of slots.
* Should be a power-of-2, minus 1. Device's default is 0x3f.
* @aifsn: Number of slots in Arbitration Interframe Space (before
* performing random backoff timing prior to Tx). Device default 1.
* @edca_txop: Length of Tx opportunity, in uSecs. Device default is 0.
*
* Device will automatically increase contention window by (2*CW) + 1 for each
* transmission retry. Device uses cw_max as a bit mask, ANDed with new CW
* value, to cap the CW value.
*/
struct iwl_ac_qos {
__le16 cw_min;
__le16 cw_max;
u8 aifsn;
u8 reserved1;
__le16 edca_txop;
} __packed;
/* QoS flags defines */
#define QOS_PARAM_FLG_UPDATE_EDCA_MSK cpu_to_le32(0x01)
#define QOS_PARAM_FLG_TGN_MSK cpu_to_le32(0x02)
#define QOS_PARAM_FLG_TXOP_TYPE_MSK cpu_to_le32(0x10)
/* Number of Access Categories (AC) (EDCA), queues 0..3 */
#define AC_NUM 4
/*
* REPLY_QOS_PARAM = 0x13 (command, has simple generic response)
*
* This command sets up timings for each of the 4 prioritized EDCA Tx FIFOs
* 0: Background, 1: Best Effort, 2: Video, 3: Voice.
*/
struct iwl_qosparam_cmd {
__le32 qos_flags;
struct iwl_ac_qos ac[AC_NUM];
} __packed;
/******************************************************************************
* (3)
* Add/Modify Stations Commands & Responses:
*
*****************************************************************************/
/*
* Multi station support
*/
/* Special, dedicated locations within device's station table */
#define IWL_AP_ID 0
#define IWL_AP_ID_PAN 1
#define IWL_STA_ID 2
#define IWLAGN_PAN_BCAST_ID 14
#define IWLAGN_BROADCAST_ID 15
#define IWLAGN_STATION_COUNT 16
#define IWL_INVALID_STATION 255
#define STA_FLG_TX_RATE_MSK cpu_to_le32(1 << 2)
#define STA_FLG_PWR_SAVE_MSK cpu_to_le32(1 << 8)
#define STA_FLG_PAN_STATION cpu_to_le32(1 << 13)
#define STA_FLG_RTS_MIMO_PROT_MSK cpu_to_le32(1 << 17)
#define STA_FLG_AGG_MPDU_8US_MSK cpu_to_le32(1 << 18)
#define STA_FLG_MAX_AGG_SIZE_POS (19)
#define STA_FLG_MAX_AGG_SIZE_MSK cpu_to_le32(3 << 19)
#define STA_FLG_HT40_EN_MSK cpu_to_le32(1 << 21)
#define STA_FLG_MIMO_DIS_MSK cpu_to_le32(1 << 22)
#define STA_FLG_AGG_MPDU_DENSITY_POS (23)
#define STA_FLG_AGG_MPDU_DENSITY_MSK cpu_to_le32(7 << 23)
/* Use in mode field. 1: modify existing entry, 0: add new station entry */
#define STA_CONTROL_MODIFY_MSK 0x01
/* key flags __le16*/
#define STA_KEY_FLG_ENCRYPT_MSK cpu_to_le16(0x0007)
#define STA_KEY_FLG_NO_ENC cpu_to_le16(0x0000)
#define STA_KEY_FLG_WEP cpu_to_le16(0x0001)
#define STA_KEY_FLG_CCMP cpu_to_le16(0x0002)
#define STA_KEY_FLG_TKIP cpu_to_le16(0x0003)
#define STA_KEY_FLG_KEYID_POS 8
#define STA_KEY_FLG_INVALID cpu_to_le16(0x0800)
/* wep key is either from global key (0) or from station info array (1) */
#define STA_KEY_FLG_MAP_KEY_MSK cpu_to_le16(0x0008)
/* wep key in STA: 5-bytes (0) or 13-bytes (1) */
#define STA_KEY_FLG_KEY_SIZE_MSK cpu_to_le16(0x1000)
#define STA_KEY_MULTICAST_MSK cpu_to_le16(0x4000)
#define STA_KEY_MAX_NUM 8
#define STA_KEY_MAX_NUM_PAN 16
/* Flags indicate whether to modify vs. don't change various station params */
#define STA_MODIFY_KEY_MASK 0x01
#define STA_MODIFY_TID_DISABLE_TX 0x02
#define STA_MODIFY_TX_RATE_MSK 0x04
#define STA_MODIFY_ADDBA_TID_MSK 0x08
#define STA_MODIFY_DELBA_TID_MSK 0x10
#define STA_MODIFY_SLEEP_TX_COUNT_MSK 0x20
/* Receiver address (actually, Rx station's index into station table),
* combined with Traffic ID (QOS priority), in format used by Tx Scheduler */
#define BUILD_RAxTID(sta_id, tid) (((sta_id) << 4) + (tid))
/* agn */
struct iwl_keyinfo {
__le16 key_flags;
u8 tkip_rx_tsc_byte2; /* TSC[2] for key mix ph1 detection */
u8 reserved1;
__le16 tkip_rx_ttak[5]; /* 10-byte unicast TKIP TTAK */
u8 key_offset;
u8 reserved2;
u8 key[16]; /* 16-byte unicast decryption key */
__le64 tx_secur_seq_cnt;
__le64 hw_tkip_mic_rx_key;
__le64 hw_tkip_mic_tx_key;
} __packed;
/**
* struct sta_id_modify
* @addr[ETH_ALEN]: station's MAC address
* @sta_id: index of station in uCode's station table
* @modify_mask: STA_MODIFY_*, 1: modify, 0: don't change
*
* Driver selects unused table index when adding new station,
* or the index to a pre-existing station entry when modifying that station.
* Some indexes have special purposes (IWL_AP_ID, index 0, is for AP).
*
* modify_mask flags select which parameters to modify vs. leave alone.
*/
struct sta_id_modify {
u8 addr[ETH_ALEN];
__le16 reserved1;
u8 sta_id;
u8 modify_mask;
__le16 reserved2;
} __packed;
/*
* REPLY_ADD_STA = 0x18 (command)
*
* The device contains an internal table of per-station information,
* with info on security keys, aggregation parameters, and Tx rates for
* initial Tx attempt and any retries (agn devices uses
* REPLY_TX_LINK_QUALITY_CMD,
*
* REPLY_ADD_STA sets up the table entry for one station, either creating
* a new entry, or modifying a pre-existing one.
*
* NOTE: RXON command (without "associated" bit set) wipes the station table
* clean. Moving into RF_KILL state does this also. Driver must set up
* new station table before transmitting anything on the RXON channel
* (except active scans or active measurements; those commands carry
* their own txpower/rate setup data).
*
* When getting started on a new channel, driver must set up the
* IWL_BROADCAST_ID entry (last entry in the table). For a client
* station in a BSS, once an AP is selected, driver sets up the AP STA
* in the IWL_AP_ID entry (1st entry in the table). BROADCAST and AP
* are all that are needed for a BSS client station. If the device is
* used as AP, or in an IBSS network, driver must set up station table
* entries for all STAs in network, starting with index IWL_STA_ID.
*/
struct iwl_addsta_cmd {
u8 mode; /* 1: modify existing, 0: add new station */
u8 reserved[3];
struct sta_id_modify sta;
struct iwl_keyinfo key;
__le32 station_flags; /* STA_FLG_* */
__le32 station_flags_msk; /* STA_FLG_* */
/* bit field to disable (1) or enable (0) Tx for Traffic ID (TID)
* corresponding to bit (e.g. bit 5 controls TID 5).
* Set modify_mask bit STA_MODIFY_TID_DISABLE_TX to use this field. */
__le16 tid_disable_tx;
__le16 rate_n_flags; /* 3945 only */
/* TID for which to add block-ack support.
* Set modify_mask bit STA_MODIFY_ADDBA_TID_MSK to use this field. */
u8 add_immediate_ba_tid;
/* TID for which to remove block-ack support.
* Set modify_mask bit STA_MODIFY_DELBA_TID_MSK to use this field. */
u8 remove_immediate_ba_tid;
/* Starting Sequence Number for added block-ack support.
* Set modify_mask bit STA_MODIFY_ADDBA_TID_MSK to use this field. */
__le16 add_immediate_ba_ssn;
/*
* Number of packets OK to transmit to station even though
* it is asleep -- used to synchronise PS-poll and u-APSD
* responses while ucode keeps track of STA sleep state.
*/
__le16 sleep_tx_count;
__le16 reserved2;
} __packed;
#define ADD_STA_SUCCESS_MSK 0x1
#define ADD_STA_NO_ROOM_IN_TABLE 0x2
#define ADD_STA_NO_BLOCK_ACK_RESOURCE 0x4
#define ADD_STA_MODIFY_NON_EXIST_STA 0x8
/*
* REPLY_ADD_STA = 0x18 (response)
*/
struct iwl_add_sta_resp {
u8 status; /* ADD_STA_* */
} __packed;
#define REM_STA_SUCCESS_MSK 0x1
/*
* REPLY_REM_STA = 0x19 (response)
*/
struct iwl_rem_sta_resp {
u8 status;
} __packed;
/*
* REPLY_REM_STA = 0x19 (command)
*/
struct iwl_rem_sta_cmd {
u8 num_sta; /* number of removed stations */
u8 reserved[3];
u8 addr[ETH_ALEN]; /* MAC addr of the first station */
u8 reserved2[2];
} __packed;
/* WiFi queues mask */
#define IWL_SCD_BK_MSK cpu_to_le32(BIT(0))
#define IWL_SCD_BE_MSK cpu_to_le32(BIT(1))
#define IWL_SCD_VI_MSK cpu_to_le32(BIT(2))
#define IWL_SCD_VO_MSK cpu_to_le32(BIT(3))
#define IWL_SCD_MGMT_MSK cpu_to_le32(BIT(3))
/* PAN queues mask */
#define IWL_PAN_SCD_BK_MSK cpu_to_le32(BIT(4))
#define IWL_PAN_SCD_BE_MSK cpu_to_le32(BIT(5))
#define IWL_PAN_SCD_VI_MSK cpu_to_le32(BIT(6))
#define IWL_PAN_SCD_VO_MSK cpu_to_le32(BIT(7))
#define IWL_PAN_SCD_MGMT_MSK cpu_to_le32(BIT(7))
#define IWL_PAN_SCD_MULTICAST_MSK cpu_to_le32(BIT(8))
#define IWL_AGG_TX_QUEUE_MSK cpu_to_le32(0xffc00)
#define IWL_DROP_SINGLE 0
#define IWL_DROP_SELECTED 1
#define IWL_DROP_ALL 2
/*
* REPLY_TXFIFO_FLUSH = 0x1e(command and response)
*
* When using full FIFO flush this command checks the scheduler HW block WR/RD
* pointers to check if all the frames were transferred by DMA into the
* relevant TX FIFO queue. Only when the DMA is finished and the queue is
* empty the command can finish.
* This command is used to flush the TXFIFO from transmit commands, it may
* operate on single or multiple queues, the command queue can't be flushed by
* this command. The command response is returned when all the queue flush
* operations are done. Each TX command flushed return response with the FLUSH
* status set in the TX response status. When FIFO flush operation is used,
* the flush operation ends when both the scheduler DMA done and TXFIFO empty
* are set.
*
* @fifo_control: bit mask for which queues to flush
* @flush_control: flush controls
* 0: Dump single MSDU
* 1: Dump multiple MSDU according to PS, INVALID STA, TTL, TID disable.
* 2: Dump all FIFO
*/
struct iwl_txfifo_flush_cmd {
__le32 fifo_control;
__le16 flush_control;
__le16 reserved;
} __packed;
/*
* REPLY_WEP_KEY = 0x20
*/
struct iwl_wep_key {
u8 key_index;
u8 key_offset;
u8 reserved1[2];
u8 key_size;
u8 reserved2[3];
u8 key[16];
} __packed;
struct iwl_wep_cmd {
u8 num_keys;
u8 global_key_type;
u8 flags;
u8 reserved;
struct iwl_wep_key key[0];
} __packed;
#define WEP_KEY_WEP_TYPE 1
#define WEP_KEYS_MAX 4
#define WEP_INVALID_OFFSET 0xff
#define WEP_KEY_LEN_64 5
#define WEP_KEY_LEN_128 13
/******************************************************************************
* (4)
* Rx Responses:
*
*****************************************************************************/
#define RX_RES_STATUS_NO_CRC32_ERROR cpu_to_le32(1 << 0)
#define RX_RES_STATUS_NO_RXE_OVERFLOW cpu_to_le32(1 << 1)
#define RX_RES_PHY_FLAGS_BAND_24_MSK cpu_to_le16(1 << 0)
#define RX_RES_PHY_FLAGS_MOD_CCK_MSK cpu_to_le16(1 << 1)
#define RX_RES_PHY_FLAGS_SHORT_PREAMBLE_MSK cpu_to_le16(1 << 2)
#define RX_RES_PHY_FLAGS_NARROW_BAND_MSK cpu_to_le16(1 << 3)
#define RX_RES_PHY_FLAGS_ANTENNA_MSK 0xf0
#define RX_RES_PHY_FLAGS_ANTENNA_POS 4
#define RX_RES_STATUS_SEC_TYPE_MSK (0x7 << 8)
#define RX_RES_STATUS_SEC_TYPE_NONE (0x0 << 8)
#define RX_RES_STATUS_SEC_TYPE_WEP (0x1 << 8)
#define RX_RES_STATUS_SEC_TYPE_CCMP (0x2 << 8)
#define RX_RES_STATUS_SEC_TYPE_TKIP (0x3 << 8)
#define RX_RES_STATUS_SEC_TYPE_ERR (0x7 << 8)
#define RX_RES_STATUS_STATION_FOUND (1<<6)
#define RX_RES_STATUS_NO_STATION_INFO_MISMATCH (1<<7)
#define RX_RES_STATUS_DECRYPT_TYPE_MSK (0x3 << 11)
#define RX_RES_STATUS_NOT_DECRYPT (0x0 << 11)
#define RX_RES_STATUS_DECRYPT_OK (0x3 << 11)
#define RX_RES_STATUS_BAD_ICV_MIC (0x1 << 11)
#define RX_RES_STATUS_BAD_KEY_TTAK (0x2 << 11)
#define RX_MPDU_RES_STATUS_ICV_OK (0x20)
#define RX_MPDU_RES_STATUS_MIC_OK (0x40)
#define RX_MPDU_RES_STATUS_TTAK_OK (1 << 7)
#define RX_MPDU_RES_STATUS_DEC_DONE_MSK (0x800)
#define IWLAGN_RX_RES_PHY_CNT 8
#define IWLAGN_RX_RES_AGC_IDX 1
#define IWLAGN_RX_RES_RSSI_AB_IDX 2
#define IWLAGN_RX_RES_RSSI_C_IDX 3
#define IWLAGN_OFDM_AGC_MSK 0xfe00
#define IWLAGN_OFDM_AGC_BIT_POS 9
#define IWLAGN_OFDM_RSSI_INBAND_A_BITMSK 0x00ff
#define IWLAGN_OFDM_RSSI_ALLBAND_A_BITMSK 0xff00
#define IWLAGN_OFDM_RSSI_A_BIT_POS 0
#define IWLAGN_OFDM_RSSI_INBAND_B_BITMSK 0xff0000
#define IWLAGN_OFDM_RSSI_ALLBAND_B_BITMSK 0xff000000
#define IWLAGN_OFDM_RSSI_B_BIT_POS 16
#define IWLAGN_OFDM_RSSI_INBAND_C_BITMSK 0x00ff
#define IWLAGN_OFDM_RSSI_ALLBAND_C_BITMSK 0xff00
#define IWLAGN_OFDM_RSSI_C_BIT_POS 0
struct iwlagn_non_cfg_phy {
__le32 non_cfg_phy[IWLAGN_RX_RES_PHY_CNT]; /* up to 8 phy entries */
} __packed;
/*
* REPLY_RX = 0xc3 (response only, not a command)
* Used only for legacy (non 11n) frames.
*/
struct iwl_rx_phy_res {
u8 non_cfg_phy_cnt; /* non configurable DSP phy data byte count */
u8 cfg_phy_cnt; /* configurable DSP phy data byte count */
u8 stat_id; /* configurable DSP phy data set ID */
u8 reserved1;
__le64 timestamp; /* TSF at on air rise */
__le32 beacon_time_stamp; /* beacon at on-air rise */
__le16 phy_flags; /* general phy flags: band, modulation, ... */
__le16 channel; /* channel number */
u8 non_cfg_phy_buf[32]; /* for various implementations of non_cfg_phy */
__le32 rate_n_flags; /* RATE_MCS_* */
__le16 byte_count; /* frame's byte-count */
__le16 frame_time; /* frame's time on the air */
} __packed;
struct iwl_rx_mpdu_res_start {
__le16 byte_count;
__le16 reserved;
} __packed;
/******************************************************************************
* (5)
* Tx Commands & Responses:
*
* Driver must place each REPLY_TX command into one of the prioritized Tx
* queues in host DRAM, shared between driver and device (see comments for
* SCD registers and Tx/Rx Queues). When the device's Tx scheduler and uCode
* are preparing to transmit, the device pulls the Tx command over the PCI
* bus via one of the device's Tx DMA channels, to fill an internal FIFO
* from which data will be transmitted.
*
* uCode handles all timing and protocol related to control frames
* (RTS/CTS/ACK), based on flags in the Tx command. uCode and Tx scheduler
* handle reception of block-acks; uCode updates the host driver via
* REPLY_COMPRESSED_BA.
*
* uCode handles retrying Tx when an ACK is expected but not received.
* This includes trying lower data rates than the one requested in the Tx
* command, as set up by the REPLY_RATE_SCALE (for 3945) or
* REPLY_TX_LINK_QUALITY_CMD (agn).
*
* Driver sets up transmit power for various rates via REPLY_TX_PWR_TABLE_CMD.
* This command must be executed after every RXON command, before Tx can occur.
*****************************************************************************/
/* REPLY_TX Tx flags field */
/*
* 1: Use RTS/CTS protocol or CTS-to-self if spec allows it
* before this frame. if CTS-to-self required check
* RXON_FLG_SELF_CTS_EN status.
* unused in 3945/4965, used in 5000 series and after
*/
#define TX_CMD_FLG_PROT_REQUIRE_MSK cpu_to_le32(1 << 0)
/*
* 1: Use Request-To-Send protocol before this frame.
* Mutually exclusive vs. TX_CMD_FLG_CTS_MSK.
* used in 3945/4965, unused in 5000 series and after
*/
#define TX_CMD_FLG_RTS_MSK cpu_to_le32(1 << 1)
/*
* 1: Transmit Clear-To-Send to self before this frame.
* Driver should set this for AUTH/DEAUTH/ASSOC-REQ/REASSOC mgmnt frames.
* Mutually exclusive vs. TX_CMD_FLG_RTS_MSK.
* used in 3945/4965, unused in 5000 series and after
*/
#define TX_CMD_FLG_CTS_MSK cpu_to_le32(1 << 2)
/* 1: Expect ACK from receiving station
* 0: Don't expect ACK (MAC header's duration field s/b 0)
* Set this for unicast frames, but not broadcast/multicast. */
#define TX_CMD_FLG_ACK_MSK cpu_to_le32(1 << 3)
/* For agn devices:
* 1: Use rate scale table (see REPLY_TX_LINK_QUALITY_CMD).
* Tx command's initial_rate_index indicates first rate to try;
* uCode walks through table for additional Tx attempts.
* 0: Use Tx rate/MCS from Tx command's rate_n_flags field.
* This rate will be used for all Tx attempts; it will not be scaled. */
#define TX_CMD_FLG_STA_RATE_MSK cpu_to_le32(1 << 4)
/* 1: Expect immediate block-ack.
* Set when Txing a block-ack request frame. Also set TX_CMD_FLG_ACK_MSK. */
#define TX_CMD_FLG_IMM_BA_RSP_MASK cpu_to_le32(1 << 6)
/*
* 1: Frame requires full Tx-Op protection.
* Set this if either RTS or CTS Tx Flag gets set.
* used in 3945/4965, unused in 5000 series and after
*/
#define TX_CMD_FLG_FULL_TXOP_PROT_MSK cpu_to_le32(1 << 7)
/* Tx antenna selection field; used only for 3945, reserved (0) for agn devices.
* Set field to "0" to allow 3945 uCode to select antenna (normal usage). */
#define TX_CMD_FLG_ANT_SEL_MSK cpu_to_le32(0xf00)
#define TX_CMD_FLG_ANT_A_MSK cpu_to_le32(1 << 8)
#define TX_CMD_FLG_ANT_B_MSK cpu_to_le32(1 << 9)
/* 1: Ignore Bluetooth priority for this frame.
* 0: Delay Tx until Bluetooth device is done (normal usage). */
#define TX_CMD_FLG_IGNORE_BT cpu_to_le32(1 << 12)
/* 1: uCode overrides sequence control field in MAC header.
* 0: Driver provides sequence control field in MAC header.
* Set this for management frames, non-QOS data frames, non-unicast frames,
* and also in Tx command embedded in REPLY_SCAN_CMD for active scans. */
#define TX_CMD_FLG_SEQ_CTL_MSK cpu_to_le32(1 << 13)
/* 1: This frame is non-last MPDU; more fragments are coming.
* 0: Last fragment, or not using fragmentation. */
#define TX_CMD_FLG_MORE_FRAG_MSK cpu_to_le32(1 << 14)
/* 1: uCode calculates and inserts Timestamp Function (TSF) in outgoing frame.
* 0: No TSF required in outgoing frame.
* Set this for transmitting beacons and probe responses. */
#define TX_CMD_FLG_TSF_MSK cpu_to_le32(1 << 16)
/* 1: Driver inserted 2 bytes pad after the MAC header, for (required) dword
* alignment of frame's payload data field.
* 0: No pad
* Set this for MAC headers with 26 or 30 bytes, i.e. those with QOS or ADDR4
* field (but not both). Driver must align frame data (i.e. data following
* MAC header) to DWORD boundary. */
#define TX_CMD_FLG_MH_PAD_MSK cpu_to_le32(1 << 20)
/* accelerate aggregation support
* 0 - no CCMP encryption; 1 - CCMP encryption */
#define TX_CMD_FLG_AGG_CCMP_MSK cpu_to_le32(1 << 22)
/* HCCA-AP - disable duration overwriting. */
#define TX_CMD_FLG_DUR_MSK cpu_to_le32(1 << 25)
/*
* TX command security control
*/
#define TX_CMD_SEC_WEP 0x01
#define TX_CMD_SEC_CCM 0x02
#define TX_CMD_SEC_TKIP 0x03
#define TX_CMD_SEC_MSK 0x03
#define TX_CMD_SEC_SHIFT 6
#define TX_CMD_SEC_KEY128 0x08
/*
* security overhead sizes
*/
#define WEP_IV_LEN 4
#define WEP_ICV_LEN 4
#define CCMP_MIC_LEN 8
#define TKIP_ICV_LEN 4
/*
* REPLY_TX = 0x1c (command)
*/
/*
* 4965 uCode updates these Tx attempt count values in host DRAM.
* Used for managing Tx retries when expecting block-acks.
* Driver should set these fields to 0.
*/
struct iwl_dram_scratch {
u8 try_cnt; /* Tx attempts */
u8 bt_kill_cnt; /* Tx attempts blocked by Bluetooth device */
__le16 reserved;
} __packed;
struct iwl_tx_cmd {
/*
* MPDU byte count:
* MAC header (24/26/30/32 bytes) + 2 bytes pad if 26/30 header size,
* + 8 byte IV for CCM or TKIP (not used for WEP)
* + Data payload
* + 8-byte MIC (not used for CCM/WEP)
* NOTE: Does not include Tx command bytes, post-MAC pad bytes,
* MIC (CCM) 8 bytes, ICV (WEP/TKIP/CKIP) 4 bytes, CRC 4 bytes.i
* Range: 14-2342 bytes.
*/
__le16 len;
/*
* MPDU or MSDU byte count for next frame.
* Used for fragmentation and bursting, but not 11n aggregation.
* Same as "len", but for next frame. Set to 0 if not applicable.
*/
__le16 next_frame_len;
__le32 tx_flags; /* TX_CMD_FLG_* */
/* uCode may modify this field of the Tx command (in host DRAM!).
* Driver must also set dram_lsb_ptr and dram_msb_ptr in this cmd. */
struct iwl_dram_scratch scratch;
/* Rate for *all* Tx attempts, if TX_CMD_FLG_STA_RATE_MSK is cleared. */
__le32 rate_n_flags; /* RATE_MCS_* */
/* Index of destination station in uCode's station table */
u8 sta_id;
/* Type of security encryption: CCM or TKIP */
u8 sec_ctl; /* TX_CMD_SEC_* */
/*
* Index into rate table (see REPLY_TX_LINK_QUALITY_CMD) for initial
* Tx attempt, if TX_CMD_FLG_STA_RATE_MSK is set. Normally "0" for
* data frames, this field may be used to selectively reduce initial
* rate (via non-0 value) for special frames (e.g. management), while
* still supporting rate scaling for all frames.
*/
u8 initial_rate_index;
u8 reserved;
u8 key[16];
__le16 next_frame_flags;
__le16 reserved2;
union {
__le32 life_time;
__le32 attempt;
} stop_time;
/* Host DRAM physical address pointer to "scratch" in this command.
* Must be dword aligned. "0" in dram_lsb_ptr disables usage. */
__le32 dram_lsb_ptr;
u8 dram_msb_ptr;
u8 rts_retry_limit; /*byte 50 */
u8 data_retry_limit; /*byte 51 */
u8 tid_tspec;
union {
__le16 pm_frame_timeout;
__le16 attempt_duration;
} timeout;
/*
* Duration of EDCA burst Tx Opportunity, in 32-usec units.
* Set this if txop time is not specified by HCCA protocol (e.g. by AP).
*/
__le16 driver_txop;
/*
* MAC header goes here, followed by 2 bytes padding if MAC header
* length is 26 or 30 bytes, followed by payload data
*/
u8 payload[0];
struct ieee80211_hdr hdr[0];
} __packed;
/*
* TX command response is sent after *agn* transmission attempts.
*
* both postpone and abort status are expected behavior from uCode. there is
* no special operation required from driver; except for RFKILL_FLUSH,
* which required tx flush host command to flush all the tx frames in queues
*/
enum {
TX_STATUS_SUCCESS = 0x01,
TX_STATUS_DIRECT_DONE = 0x02,
/* postpone TX */
TX_STATUS_POSTPONE_DELAY = 0x40,
TX_STATUS_POSTPONE_FEW_BYTES = 0x41,
TX_STATUS_POSTPONE_BT_PRIO = 0x42,
TX_STATUS_POSTPONE_QUIET_PERIOD = 0x43,
TX_STATUS_POSTPONE_CALC_TTAK = 0x44,
/* abort TX */
TX_STATUS_FAIL_INTERNAL_CROSSED_RETRY = 0x81,
TX_STATUS_FAIL_SHORT_LIMIT = 0x82,
TX_STATUS_FAIL_LONG_LIMIT = 0x83,
TX_STATUS_FAIL_FIFO_UNDERRUN = 0x84,
TX_STATUS_FAIL_DRAIN_FLOW = 0x85,
TX_STATUS_FAIL_RFKILL_FLUSH = 0x86,
TX_STATUS_FAIL_LIFE_EXPIRE = 0x87,
TX_STATUS_FAIL_DEST_PS = 0x88,
TX_STATUS_FAIL_HOST_ABORTED = 0x89,
TX_STATUS_FAIL_BT_RETRY = 0x8a,
TX_STATUS_FAIL_STA_INVALID = 0x8b,
TX_STATUS_FAIL_FRAG_DROPPED = 0x8c,
TX_STATUS_FAIL_TID_DISABLE = 0x8d,
TX_STATUS_FAIL_FIFO_FLUSHED = 0x8e,
TX_STATUS_FAIL_INSUFFICIENT_CF_POLL = 0x8f,
TX_STATUS_FAIL_PASSIVE_NO_RX = 0x90,
TX_STATUS_FAIL_NO_BEACON_ON_RADAR = 0x91,
};
#define TX_PACKET_MODE_REGULAR 0x0000
#define TX_PACKET_MODE_BURST_SEQ 0x0100
#define TX_PACKET_MODE_BURST_FIRST 0x0200
enum {
TX_POWER_PA_NOT_ACTIVE = 0x0,
};
enum {
TX_STATUS_MSK = 0x000000ff, /* bits 0:7 */
TX_STATUS_DELAY_MSK = 0x00000040,
TX_STATUS_ABORT_MSK = 0x00000080,
TX_PACKET_MODE_MSK = 0x0000ff00, /* bits 8:15 */
TX_FIFO_NUMBER_MSK = 0x00070000, /* bits 16:18 */
TX_RESERVED = 0x00780000, /* bits 19:22 */
TX_POWER_PA_DETECT_MSK = 0x7f800000, /* bits 23:30 */
TX_ABORT_REQUIRED_MSK = 0x80000000, /* bits 31:31 */
};
/* *******************************
* TX aggregation status
******************************* */
enum {
AGG_TX_STATE_TRANSMITTED = 0x00,
AGG_TX_STATE_UNDERRUN_MSK = 0x01,
AGG_TX_STATE_BT_PRIO_MSK = 0x02,
AGG_TX_STATE_FEW_BYTES_MSK = 0x04,
AGG_TX_STATE_ABORT_MSK = 0x08,
AGG_TX_STATE_LAST_SENT_TTL_MSK = 0x10,
AGG_TX_STATE_LAST_SENT_TRY_CNT_MSK = 0x20,
AGG_TX_STATE_LAST_SENT_BT_KILL_MSK = 0x40,
AGG_TX_STATE_SCD_QUERY_MSK = 0x80,
AGG_TX_STATE_TEST_BAD_CRC32_MSK = 0x100,
AGG_TX_STATE_RESPONSE_MSK = 0x1ff,
AGG_TX_STATE_DUMP_TX_MSK = 0x200,
AGG_TX_STATE_DELAY_TX_MSK = 0x400
};
#define AGG_TX_STATUS_MSK 0x00000fff /* bits 0:11 */
#define AGG_TX_TRY_MSK 0x0000f000 /* bits 12:15 */
#define AGG_TX_STATE_LAST_SENT_MSK (AGG_TX_STATE_LAST_SENT_TTL_MSK | \
AGG_TX_STATE_LAST_SENT_TRY_CNT_MSK | \
AGG_TX_STATE_LAST_SENT_BT_KILL_MSK)
/* # tx attempts for first frame in aggregation */
#define AGG_TX_STATE_TRY_CNT_POS 12
#define AGG_TX_STATE_TRY_CNT_MSK 0xf000
/* Command ID and sequence number of Tx command for this frame */
#define AGG_TX_STATE_SEQ_NUM_POS 16
#define AGG_TX_STATE_SEQ_NUM_MSK 0xffff0000
/*
* REPLY_TX = 0x1c (response)
*
* This response may be in one of two slightly different formats, indicated
* by the frame_count field:
*
* 1) No aggregation (frame_count == 1). This reports Tx results for
* a single frame. Multiple attempts, at various bit rates, may have
* been made for this frame.
*
* 2) Aggregation (frame_count > 1). This reports Tx results for
* 2 or more frames that used block-acknowledge. All frames were
* transmitted at same rate. Rate scaling may have been used if first
* frame in this new agg block failed in previous agg block(s).
*
* Note that, for aggregation, ACK (block-ack) status is not delivered here;
* block-ack has not been received by the time the agn device records
* this status.
* This status relates to reasons the tx might have been blocked or aborted
* within the sending station (this agn device), rather than whether it was
* received successfully by the destination station.
*/
struct agg_tx_status {
__le16 status;
__le16 sequence;
} __packed;
/*
* definitions for initial rate index field
* bits [3:0] initial rate index
* bits [6:4] rate table color, used for the initial rate
* bit-7 invalid rate indication
* i.e. rate was not chosen from rate table
* or rate table color was changed during frame retries
* refer tlc rate info
*/
#define IWL50_TX_RES_INIT_RATE_INDEX_POS 0
#define IWL50_TX_RES_INIT_RATE_INDEX_MSK 0x0f
#define IWL50_TX_RES_RATE_TABLE_COLOR_POS 4
#define IWL50_TX_RES_RATE_TABLE_COLOR_MSK 0x70
#define IWL50_TX_RES_INV_RATE_INDEX_MSK 0x80
/* refer to ra_tid */
#define IWLAGN_TX_RES_TID_POS 0
#define IWLAGN_TX_RES_TID_MSK 0x0f
#define IWLAGN_TX_RES_RA_POS 4
#define IWLAGN_TX_RES_RA_MSK 0xf0
struct iwlagn_tx_resp {
u8 frame_count; /* 1 no aggregation, >1 aggregation */
u8 bt_kill_count; /* # blocked by bluetooth (unused for agg) */
u8 failure_rts; /* # failures due to unsuccessful RTS */
u8 failure_frame; /* # failures due to no ACK (unused for agg) */
/* For non-agg: Rate at which frame was successful.
* For agg: Rate at which all frames were transmitted. */
__le32 rate_n_flags; /* RATE_MCS_* */
/* For non-agg: RTS + CTS + frame tx attempts time + ACK.
* For agg: RTS + CTS + aggregation tx time + block-ack time. */
__le16 wireless_media_time; /* uSecs */
u8 pa_status; /* RF power amplifier measurement (not used) */
u8 pa_integ_res_a[3];
u8 pa_integ_res_b[3];
u8 pa_integ_res_C[3];
__le32 tfd_info;
__le16 seq_ctl;
__le16 byte_cnt;
u8 tlc_info;
u8 ra_tid; /* tid (0:3), sta_id (4:7) */
__le16 frame_ctrl;
/*
* For non-agg: frame status TX_STATUS_*
* For agg: status of 1st frame, AGG_TX_STATE_*; other frame status
* fields follow this one, up to frame_count.
* Bit fields:
* 11- 0: AGG_TX_STATE_* status code
* 15-12: Retry count for 1st frame in aggregation (retries
* occur if tx failed for this frame when it was a
* member of a previous aggregation block). If rate
* scaling is used, retry count indicates the rate
* table entry used for all frames in the new agg.
* 31-16: Sequence # for this frame's Tx cmd (not SSN!)
*/
struct agg_tx_status status; /* TX status (in aggregation -
* status of 1st frame) */
} __packed;
/*
* REPLY_COMPRESSED_BA = 0xc5 (response only, not a command)
*
* Reports Block-Acknowledge from recipient station
*/
struct iwl_compressed_ba_resp {
__le32 sta_addr_lo32;
__le16 sta_addr_hi16;
__le16 reserved;
/* Index of recipient (BA-sending) station in uCode's station table */
u8 sta_id;
u8 tid;
__le16 seq_ctl;
__le64 bitmap;
__le16 scd_flow;
__le16 scd_ssn;
/* following only for 5000 series and up */
u8 txed; /* number of frames sent */
u8 txed_2_done; /* number of frames acked */
} __packed;
/*
* REPLY_TX_PWR_TABLE_CMD = 0x97 (command, has simple generic response)
*
*/
/*RS_NEW_API: only TLC_RTS remains and moved to bit 0 */
#define LINK_QUAL_FLAGS_SET_STA_TLC_RTS_MSK (1 << 0)
/* # of EDCA prioritized tx fifos */
#define LINK_QUAL_AC_NUM AC_NUM
/* # entries in rate scale table to support Tx retries */
#define LINK_QUAL_MAX_RETRY_NUM 16
/* Tx antenna selection values */
#define LINK_QUAL_ANT_A_MSK (1 << 0)
#define LINK_QUAL_ANT_B_MSK (1 << 1)
#define LINK_QUAL_ANT_MSK (LINK_QUAL_ANT_A_MSK|LINK_QUAL_ANT_B_MSK)
/**
* struct iwl_link_qual_general_params
*
* Used in REPLY_TX_LINK_QUALITY_CMD
*/
struct iwl_link_qual_general_params {
u8 flags;
/* No entries at or above this (driver chosen) index contain MIMO */
u8 mimo_delimiter;
/* Best single antenna to use for single stream (legacy, SISO). */
u8 single_stream_ant_msk; /* LINK_QUAL_ANT_* */
/* Best antennas to use for MIMO (unused for 4965, assumes both). */
u8 dual_stream_ant_msk; /* LINK_QUAL_ANT_* */
/*
* If driver needs to use different initial rates for different
* EDCA QOS access categories (as implemented by tx fifos 0-3),
* this table will set that up, by indicating the indexes in the
* rs_table[LINK_QUAL_MAX_RETRY_NUM] rate table at which to start.
* Otherwise, driver should set all entries to 0.
*
* Entry usage:
* 0 = Background, 1 = Best Effort (normal), 2 = Video, 3 = Voice
* TX FIFOs above 3 use same value (typically 0) as TX FIFO 3.
*/
u8 start_rate_index[LINK_QUAL_AC_NUM];
} __packed;
#define LINK_QUAL_AGG_TIME_LIMIT_DEF (4000) /* 4 milliseconds */
#define LINK_QUAL_AGG_TIME_LIMIT_MAX (8000)
#define LINK_QUAL_AGG_TIME_LIMIT_MIN (100)
#define LINK_QUAL_AGG_DISABLE_START_DEF (3)
#define LINK_QUAL_AGG_DISABLE_START_MAX (255)
#define LINK_QUAL_AGG_DISABLE_START_MIN (0)
#define LINK_QUAL_AGG_FRAME_LIMIT_DEF (63)
#define LINK_QUAL_AGG_FRAME_LIMIT_MAX (63)
#define LINK_QUAL_AGG_FRAME_LIMIT_MIN (0)
/**
* struct iwl_link_qual_agg_params
*
* Used in REPLY_TX_LINK_QUALITY_CMD
*/
struct iwl_link_qual_agg_params {
/*
*Maximum number of uSec in aggregation.
* default set to 4000 (4 milliseconds) if not configured in .cfg
*/
__le16 agg_time_limit;
/*
* Number of Tx retries allowed for a frame, before that frame will
* no longer be considered for the start of an aggregation sequence
* (scheduler will then try to tx it as single frame).
* Driver should set this to 3.
*/
u8 agg_dis_start_th;
/*
* Maximum number of frames in aggregation.
* 0 = no limit (default). 1 = no aggregation.
* Other values = max # frames in aggregation.
*/
u8 agg_frame_cnt_limit;
__le32 reserved;
} __packed;
/*
* REPLY_TX_LINK_QUALITY_CMD = 0x4e (command, has simple generic response)
*
* For agn devices only; 3945 uses REPLY_RATE_SCALE.
*
* Each station in the agn device's internal station table has its own table
* of 16
* Tx rates and modulation modes (e.g. legacy/SISO/MIMO) for retrying Tx when
* an ACK is not received. This command replaces the entire table for
* one station.
*
* NOTE: Station must already be in agn device's station table.
* Use REPLY_ADD_STA.
*
* The rate scaling procedures described below work well. Of course, other
* procedures are possible, and may work better for particular environments.
*
*
* FILLING THE RATE TABLE
*
* Given a particular initial rate and mode, as determined by the rate
* scaling algorithm described below, the Linux driver uses the following
* formula to fill the rs_table[LINK_QUAL_MAX_RETRY_NUM] rate table in the
* Link Quality command:
*
*
* 1) If using High-throughput (HT) (SISO or MIMO) initial rate:
* a) Use this same initial rate for first 3 entries.
* b) Find next lower available rate using same mode (SISO or MIMO),
* use for next 3 entries. If no lower rate available, switch to
* legacy mode (no HT40 channel, no MIMO, no short guard interval).
* c) If using MIMO, set command's mimo_delimiter to number of entries
* using MIMO (3 or 6).
* d) After trying 2 HT rates, switch to legacy mode (no HT40 channel,
* no MIMO, no short guard interval), at the next lower bit rate
* (e.g. if second HT bit rate was 54, try 48 legacy), and follow
* legacy procedure for remaining table entries.
*
* 2) If using legacy initial rate:
* a) Use the initial rate for only one entry.
* b) For each following entry, reduce the rate to next lower available
* rate, until reaching the lowest available rate.
* c) When reducing rate, also switch antenna selection.
* d) Once lowest available rate is reached, repeat this rate until
* rate table is filled (16 entries), switching antenna each entry.
*
*
* ACCUMULATING HISTORY
*
* The rate scaling algorithm for agn devices, as implemented in Linux driver,
* uses two sets of frame Tx success history: One for the current/active
* modulation mode, and one for a speculative/search mode that is being
* attempted. If the speculative mode turns out to be more effective (i.e.
* actual transfer rate is better), then the driver continues to use the
* speculative mode as the new current active mode.
*
* Each history set contains, separately for each possible rate, data for a
* sliding window of the 62 most recent tx attempts at that rate. The data
* includes a shifting bitmap of success(1)/failure(0), and sums of successful
* and attempted frames, from which the driver can additionally calculate a
* success ratio (success / attempted) and number of failures
* (attempted - success), and control the size of the window (attempted).
* The driver uses the bit map to remove successes from the success sum, as
* the oldest tx attempts fall out of the window.
*
* When the agn device makes multiple tx attempts for a given frame, each
* attempt might be at a different rate, and have different modulation
* characteristics (e.g. antenna, fat channel, short guard interval), as set
* up in the rate scaling table in the Link Quality command. The driver must
* determine which rate table entry was used for each tx attempt, to determine
* which rate-specific history to update, and record only those attempts that
* match the modulation characteristics of the history set.
*
* When using block-ack (aggregation), all frames are transmitted at the same
* rate, since there is no per-attempt acknowledgment from the destination
* station. The Tx response struct iwl_tx_resp indicates the Tx rate in
* rate_n_flags field. After receiving a block-ack, the driver can update
* history for the entire block all at once.
*
*
* FINDING BEST STARTING RATE:
*
* When working with a selected initial modulation mode (see below), the
* driver attempts to find a best initial rate. The initial rate is the
* first entry in the Link Quality command's rate table.
*
* 1) Calculate actual throughput (success ratio * expected throughput, see
* table below) for current initial rate. Do this only if enough frames
* have been attempted to make the value meaningful: at least 6 failed
* tx attempts, or at least 8 successes. If not enough, don't try rate
* scaling yet.
*
* 2) Find available rates adjacent to current initial rate. Available means:
* a) supported by hardware &&
* b) supported by association &&
* c) within any constraints selected by user
*
* 3) Gather measured throughputs for adjacent rates. These might not have
* enough history to calculate a throughput. That's okay, we might try
* using one of them anyway!
*
* 4) Try decreasing rate if, for current rate:
* a) success ratio is < 15% ||
* b) lower adjacent rate has better measured throughput ||
* c) higher adjacent rate has worse throughput, and lower is unmeasured
*
* As a sanity check, if decrease was determined above, leave rate
* unchanged if:
* a) lower rate unavailable
* b) success ratio at current rate > 85% (very good)
* c) current measured throughput is better than expected throughput
* of lower rate (under perfect 100% tx conditions, see table below)
*
* 5) Try increasing rate if, for current rate:
* a) success ratio is < 15% ||
* b) both adjacent rates' throughputs are unmeasured (try it!) ||
* b) higher adjacent rate has better measured throughput ||
* c) lower adjacent rate has worse throughput, and higher is unmeasured
*
* As a sanity check, if increase was determined above, leave rate
* unchanged if:
* a) success ratio at current rate < 70%. This is not particularly
* good performance; higher rate is sure to have poorer success.
*
* 6) Re-evaluate the rate after each tx frame. If working with block-
* acknowledge, history and statistics may be calculated for the entire
* block (including prior history that fits within the history windows),
* before re-evaluation.
*
* FINDING BEST STARTING MODULATION MODE:
*
* After working with a modulation mode for a "while" (and doing rate scaling),
* the driver searches for a new initial mode in an attempt to improve
* throughput. The "while" is measured by numbers of attempted frames:
*
* For legacy mode, search for new mode after:
* 480 successful frames, or 160 failed frames
* For high-throughput modes (SISO or MIMO), search for new mode after:
* 4500 successful frames, or 400 failed frames
*
* Mode switch possibilities are (3 for each mode):
*
* For legacy:
* Change antenna, try SISO (if HT association), try MIMO (if HT association)
* For SISO:
* Change antenna, try MIMO, try shortened guard interval (SGI)
* For MIMO:
* Try SISO antenna A, SISO antenna B, try shortened guard interval (SGI)
*
* When trying a new mode, use the same bit rate as the old/current mode when
* trying antenna switches and shortened guard interval. When switching to
* SISO from MIMO or legacy, or to MIMO from SISO or legacy, use a rate
* for which the expected throughput (under perfect conditions) is about the
* same or slightly better than the actual measured throughput delivered by
* the old/current mode.
*
* Actual throughput can be estimated by multiplying the expected throughput
* by the success ratio (successful / attempted tx frames). Frame size is
* not considered in this calculation; it assumes that frame size will average
* out to be fairly consistent over several samples. The following are
* metric values for expected throughput assuming 100% success ratio.
* Only G band has support for CCK rates:
*
* RATE: 1 2 5 11 6 9 12 18 24 36 48 54 60
*
* G: 7 13 35 58 40 57 72 98 121 154 177 186 186
* A: 0 0 0 0 40 57 72 98 121 154 177 186 186
* SISO 20MHz: 0 0 0 0 42 42 76 102 124 159 183 193 202
* SGI SISO 20MHz: 0 0 0 0 46 46 82 110 132 168 192 202 211
* MIMO 20MHz: 0 0 0 0 74 74 123 155 179 214 236 244 251
* SGI MIMO 20MHz: 0 0 0 0 81 81 131 164 188 222 243 251 257
* SISO 40MHz: 0 0 0 0 77 77 127 160 184 220 242 250 257
* SGI SISO 40MHz: 0 0 0 0 83 83 135 169 193 229 250 257 264
* MIMO 40MHz: 0 0 0 0 123 123 182 214 235 264 279 285 289
* SGI MIMO 40MHz: 0 0 0 0 131 131 191 222 242 270 284 289 293
*
* After the new mode has been tried for a short while (minimum of 6 failed
* frames or 8 successful frames), compare success ratio and actual throughput
* estimate of the new mode with the old. If either is better with the new
* mode, continue to use the new mode.
*
* Continue comparing modes until all 3 possibilities have been tried.
* If moving from legacy to HT, try all 3 possibilities from the new HT
* mode. After trying all 3, a best mode is found. Continue to use this mode
* for the longer "while" described above (e.g. 480 successful frames for
* legacy), and then repeat the search process.
*
*/
struct iwl_link_quality_cmd {
/* Index of destination/recipient station in uCode's station table */
u8 sta_id;
u8 reserved1;
__le16 control; /* not used */
struct iwl_link_qual_general_params general_params;
struct iwl_link_qual_agg_params agg_params;
/*
* Rate info; when using rate-scaling, Tx command's initial_rate_index
* specifies 1st Tx rate attempted, via index into this table.
* agn devices works its way through table when retrying Tx.
*/
struct {
__le32 rate_n_flags; /* RATE_MCS_*, IWL_RATE_* */
} rs_table[LINK_QUAL_MAX_RETRY_NUM];
__le32 reserved2;
} __packed;
/*
* BT configuration enable flags:
* bit 0 - 1: BT channel announcement enabled
* 0: disable
* bit 1 - 1: priority of BT device enabled
* 0: disable
* bit 2 - 1: BT 2 wire support enabled
* 0: disable
*/
#define BT_COEX_DISABLE (0x0)
#define BT_ENABLE_CHANNEL_ANNOUNCE BIT(0)
#define BT_ENABLE_PRIORITY BIT(1)
#define BT_ENABLE_2_WIRE BIT(2)
#define BT_COEX_DISABLE (0x0)
#define BT_COEX_ENABLE (BT_ENABLE_CHANNEL_ANNOUNCE | BT_ENABLE_PRIORITY)
#define BT_LEAD_TIME_MIN (0x0)
#define BT_LEAD_TIME_DEF (0x1E)
#define BT_LEAD_TIME_MAX (0xFF)
#define BT_MAX_KILL_MIN (0x1)
#define BT_MAX_KILL_DEF (0x5)
#define BT_MAX_KILL_MAX (0xFF)
#define BT_DURATION_LIMIT_DEF 625
#define BT_DURATION_LIMIT_MAX 1250
#define BT_DURATION_LIMIT_MIN 625
#define BT_ON_THRESHOLD_DEF 4
#define BT_ON_THRESHOLD_MAX 1000
#define BT_ON_THRESHOLD_MIN 1
#define BT_FRAG_THRESHOLD_DEF 0
#define BT_FRAG_THRESHOLD_MAX 0
#define BT_FRAG_THRESHOLD_MIN 0
#define BT_AGG_THRESHOLD_DEF 1200
#define BT_AGG_THRESHOLD_MAX 8000
#define BT_AGG_THRESHOLD_MIN 400
/*
* REPLY_BT_CONFIG = 0x9b (command, has simple generic response)
*
* 3945 and agn devices support hardware handshake with Bluetooth device on
* same platform. Bluetooth device alerts wireless device when it will Tx;
* wireless device can delay or kill its own Tx to accommodate.
*/
struct iwl_bt_cmd {
u8 flags;
u8 lead_time;
u8 max_kill;
u8 reserved;
__le32 kill_ack_mask;
__le32 kill_cts_mask;
} __packed;
#define IWLAGN_BT_FLAG_CHANNEL_INHIBITION BIT(0)
#define IWLAGN_BT_FLAG_COEX_MODE_MASK (BIT(3)|BIT(4)|BIT(5))
#define IWLAGN_BT_FLAG_COEX_MODE_SHIFT 3
#define IWLAGN_BT_FLAG_COEX_MODE_DISABLED 0
#define IWLAGN_BT_FLAG_COEX_MODE_LEGACY_2W 1
#define IWLAGN_BT_FLAG_COEX_MODE_3W 2
#define IWLAGN_BT_FLAG_COEX_MODE_4W 3
#define IWLAGN_BT_FLAG_UCODE_DEFAULT BIT(6)
/* Disable Sync PSPoll on SCO/eSCO */
#define IWLAGN_BT_FLAG_SYNC_2_BT_DISABLE BIT(7)
#define IWLAGN_BT_PRIO_BOOST_MAX 0xFF
#define IWLAGN_BT_PRIO_BOOST_MIN 0x00
#define IWLAGN_BT_PRIO_BOOST_DEFAULT 0xF0
#define IWLAGN_BT_MAX_KILL_DEFAULT 5
#define IWLAGN_BT3_T7_DEFAULT 1
#define IWLAGN_BT_KILL_ACK_MASK_DEFAULT cpu_to_le32(0xffff0000)
#define IWLAGN_BT_KILL_CTS_MASK_DEFAULT cpu_to_le32(0xffff0000)
#define IWLAGN_BT_KILL_ACK_CTS_MASK_SCO cpu_to_le32(0xffffffff)
#define IWLAGN_BT3_PRIO_SAMPLE_DEFAULT 2
#define IWLAGN_BT3_T2_DEFAULT 0xc
#define IWLAGN_BT_VALID_ENABLE_FLAGS cpu_to_le16(BIT(0))
#define IWLAGN_BT_VALID_BOOST cpu_to_le16(BIT(1))
#define IWLAGN_BT_VALID_MAX_KILL cpu_to_le16(BIT(2))
#define IWLAGN_BT_VALID_3W_TIMERS cpu_to_le16(BIT(3))
#define IWLAGN_BT_VALID_KILL_ACK_MASK cpu_to_le16(BIT(4))
#define IWLAGN_BT_VALID_KILL_CTS_MASK cpu_to_le16(BIT(5))
#define IWLAGN_BT_VALID_BT4_TIMES cpu_to_le16(BIT(6))
#define IWLAGN_BT_VALID_3W_LUT cpu_to_le16(BIT(7))
#define IWLAGN_BT_ALL_VALID_MSK (IWLAGN_BT_VALID_ENABLE_FLAGS | \
IWLAGN_BT_VALID_BOOST | \
IWLAGN_BT_VALID_MAX_KILL | \
IWLAGN_BT_VALID_3W_TIMERS | \
IWLAGN_BT_VALID_KILL_ACK_MASK | \
IWLAGN_BT_VALID_KILL_CTS_MASK | \
IWLAGN_BT_VALID_BT4_TIMES | \
IWLAGN_BT_VALID_3W_LUT)
struct iwl_basic_bt_cmd {
u8 flags;
u8 ledtime; /* unused */
u8 max_kill;
u8 bt3_timer_t7_value;
__le32 kill_ack_mask;
__le32 kill_cts_mask;
u8 bt3_prio_sample_time;
u8 bt3_timer_t2_value;
__le16 bt4_reaction_time; /* unused */
__le32 bt3_lookup_table[12];
__le16 bt4_decision_time; /* unused */
__le16 valid;
};
struct iwl6000_bt_cmd {
struct iwl_basic_bt_cmd basic;
u8 prio_boost;
/*
* set IWLAGN_BT_VALID_BOOST to "1" in "valid" bitmask
* if configure the following patterns
*/
u8 tx_prio_boost; /* SW boost of WiFi tx priority */
__le16 rx_prio_boost; /* SW boost of WiFi rx priority */
};
struct iwl2000_bt_cmd {
struct iwl_basic_bt_cmd basic;
__le32 prio_boost;
/*
* set IWLAGN_BT_VALID_BOOST to "1" in "valid" bitmask
* if configure the following patterns
*/
u8 reserved;
u8 tx_prio_boost; /* SW boost of WiFi tx priority */
__le16 rx_prio_boost; /* SW boost of WiFi rx priority */
};
#define IWLAGN_BT_SCO_ACTIVE cpu_to_le32(BIT(0))
struct iwlagn_bt_sco_cmd {
__le32 flags;
};
/******************************************************************************
* (6)
* Spectrum Management (802.11h) Commands, Responses, Notifications:
*
*****************************************************************************/
/*
* Spectrum Management
*/
#define MEASUREMENT_FILTER_FLAG (RXON_FILTER_PROMISC_MSK | \
RXON_FILTER_CTL2HOST_MSK | \
RXON_FILTER_ACCEPT_GRP_MSK | \
RXON_FILTER_DIS_DECRYPT_MSK | \
RXON_FILTER_DIS_GRP_DECRYPT_MSK | \
RXON_FILTER_ASSOC_MSK | \
RXON_FILTER_BCON_AWARE_MSK)
struct iwl_measure_channel {
__le32 duration; /* measurement duration in extended beacon
* format */
u8 channel; /* channel to measure */
u8 type; /* see enum iwl_measure_type */
__le16 reserved;
} __packed;
/*
* REPLY_SPECTRUM_MEASUREMENT_CMD = 0x74 (command)
*/
struct iwl_spectrum_cmd {
__le16 len; /* number of bytes starting from token */
u8 token; /* token id */
u8 id; /* measurement id -- 0 or 1 */
u8 origin; /* 0 = TGh, 1 = other, 2 = TGk */
u8 periodic; /* 1 = periodic */
__le16 path_loss_timeout;
__le32 start_time; /* start time in extended beacon format */
__le32 reserved2;
__le32 flags; /* rxon flags */
__le32 filter_flags; /* rxon filter flags */
__le16 channel_count; /* minimum 1, maximum 10 */
__le16 reserved3;
struct iwl_measure_channel channels[10];
} __packed;
/*
* REPLY_SPECTRUM_MEASUREMENT_CMD = 0x74 (response)
*/
struct iwl_spectrum_resp {
u8 token;
u8 id; /* id of the prior command replaced, or 0xff */
__le16 status; /* 0 - command will be handled
* 1 - cannot handle (conflicts with another
* measurement) */
} __packed;
enum iwl_measurement_state {
IWL_MEASUREMENT_START = 0,
IWL_MEASUREMENT_STOP = 1,
};
enum iwl_measurement_status {
IWL_MEASUREMENT_OK = 0,
IWL_MEASUREMENT_CONCURRENT = 1,
IWL_MEASUREMENT_CSA_CONFLICT = 2,
IWL_MEASUREMENT_TGH_CONFLICT = 3,
/* 4-5 reserved */
IWL_MEASUREMENT_STOPPED = 6,
IWL_MEASUREMENT_TIMEOUT = 7,
IWL_MEASUREMENT_PERIODIC_FAILED = 8,
};
#define NUM_ELEMENTS_IN_HISTOGRAM 8
struct iwl_measurement_histogram {
__le32 ofdm[NUM_ELEMENTS_IN_HISTOGRAM]; /* in 0.8usec counts */
__le32 cck[NUM_ELEMENTS_IN_HISTOGRAM]; /* in 1usec counts */
} __packed;
/* clear channel availability counters */
struct iwl_measurement_cca_counters {
__le32 ofdm;
__le32 cck;
} __packed;
enum iwl_measure_type {
IWL_MEASURE_BASIC = (1 << 0),
IWL_MEASURE_CHANNEL_LOAD = (1 << 1),
IWL_MEASURE_HISTOGRAM_RPI = (1 << 2),
IWL_MEASURE_HISTOGRAM_NOISE = (1 << 3),
IWL_MEASURE_FRAME = (1 << 4),
/* bits 5:6 are reserved */
IWL_MEASURE_IDLE = (1 << 7),
};
/*
* SPECTRUM_MEASURE_NOTIFICATION = 0x75 (notification only, not a command)
*/
struct iwl_spectrum_notification {
u8 id; /* measurement id -- 0 or 1 */
u8 token;
u8 channel_index; /* index in measurement channel list */
u8 state; /* 0 - start, 1 - stop */
__le32 start_time; /* lower 32-bits of TSF */
u8 band; /* 0 - 5.2GHz, 1 - 2.4GHz */
u8 channel;
u8 type; /* see enum iwl_measurement_type */
u8 reserved1;
/* NOTE: cca_ofdm, cca_cck, basic_type, and histogram are only only
* valid if applicable for measurement type requested. */
__le32 cca_ofdm; /* cca fraction time in 40Mhz clock periods */
__le32 cca_cck; /* cca fraction time in 44Mhz clock periods */
__le32 cca_time; /* channel load time in usecs */
u8 basic_type; /* 0 - bss, 1 - ofdm preamble, 2 -
* unidentified */
u8 reserved2[3];
struct iwl_measurement_histogram histogram;
__le32 stop_time; /* lower 32-bits of TSF */
__le32 status; /* see iwl_measurement_status */
} __packed;
/******************************************************************************
* (7)
* Power Management Commands, Responses, Notifications:
*
*****************************************************************************/
/**
* struct iwl_powertable_cmd - Power Table Command
* @flags: See below:
*
* POWER_TABLE_CMD = 0x77 (command, has simple generic response)
*
* PM allow:
* bit 0 - '0' Driver not allow power management
* '1' Driver allow PM (use rest of parameters)
*
* uCode send sleep notifications:
* bit 1 - '0' Don't send sleep notification
* '1' send sleep notification (SEND_PM_NOTIFICATION)
*
* Sleep over DTIM
* bit 2 - '0' PM have to walk up every DTIM
* '1' PM could sleep over DTIM till listen Interval.
*
* PCI power managed
* bit 3 - '0' (PCI_CFG_LINK_CTRL & 0x1)
* '1' !(PCI_CFG_LINK_CTRL & 0x1)
*
* Fast PD
* bit 4 - '1' Put radio to sleep when receiving frame for others
*
* Force sleep Modes
* bit 31/30- '00' use both mac/xtal sleeps
* '01' force Mac sleep
* '10' force xtal sleep
* '11' Illegal set
*
* NOTE: if sleep_interval[SLEEP_INTRVL_TABLE_SIZE-1] > DTIM period then
* ucode assume sleep over DTIM is allowed and we don't need to wake up
* for every DTIM.
*/
#define IWL_POWER_VEC_SIZE 5
#define IWL_POWER_DRIVER_ALLOW_SLEEP_MSK cpu_to_le16(BIT(0))
#define IWL_POWER_POWER_SAVE_ENA_MSK cpu_to_le16(BIT(0))
#define IWL_POWER_POWER_MANAGEMENT_ENA_MSK cpu_to_le16(BIT(1))
#define IWL_POWER_SLEEP_OVER_DTIM_MSK cpu_to_le16(BIT(2))
#define IWL_POWER_PCI_PM_MSK cpu_to_le16(BIT(3))
#define IWL_POWER_FAST_PD cpu_to_le16(BIT(4))
#define IWL_POWER_BEACON_FILTERING cpu_to_le16(BIT(5))
#define IWL_POWER_SHADOW_REG_ENA cpu_to_le16(BIT(6))
#define IWL_POWER_CT_KILL_SET cpu_to_le16(BIT(7))
#define IWL_POWER_BT_SCO_ENA cpu_to_le16(BIT(8))
#define IWL_POWER_ADVANCE_PM_ENA_MSK cpu_to_le16(BIT(9))
struct iwl_powertable_cmd {
__le16 flags;
u8 keep_alive_seconds; /* 3945 reserved */
u8 debug_flags; /* 3945 reserved */
__le32 rx_data_timeout;
__le32 tx_data_timeout;
__le32 sleep_interval[IWL_POWER_VEC_SIZE];
__le32 keep_alive_beacons;
} __packed;
/*
* PM_SLEEP_NOTIFICATION = 0x7A (notification only, not a command)
* all devices identical.
*/
struct iwl_sleep_notification {
u8 pm_sleep_mode;
u8 pm_wakeup_src;
__le16 reserved;
__le32 sleep_time;
__le32 tsf_low;
__le32 bcon_timer;
} __packed;
/* Sleep states. all devices identical. */
enum {
IWL_PM_NO_SLEEP = 0,
IWL_PM_SLP_MAC = 1,
IWL_PM_SLP_FULL_MAC_UNASSOCIATE = 2,
IWL_PM_SLP_FULL_MAC_CARD_STATE = 3,
IWL_PM_SLP_PHY = 4,
IWL_PM_SLP_REPENT = 5,
IWL_PM_WAKEUP_BY_TIMER = 6,
IWL_PM_WAKEUP_BY_DRIVER = 7,
IWL_PM_WAKEUP_BY_RFKILL = 8,
/* 3 reserved */
IWL_PM_NUM_OF_MODES = 12,
};
/*
* REPLY_CARD_STATE_CMD = 0xa0 (command, has simple generic response)
*/
#define CARD_STATE_CMD_DISABLE 0x00 /* Put card to sleep */
#define CARD_STATE_CMD_ENABLE 0x01 /* Wake up card */
#define CARD_STATE_CMD_HALT 0x02 /* Power down permanently */
struct iwl_card_state_cmd {
__le32 status; /* CARD_STATE_CMD_* request new power state */
} __packed;
/*
* CARD_STATE_NOTIFICATION = 0xa1 (notification only, not a command)
*/
struct iwl_card_state_notif {
__le32 flags;
} __packed;
#define HW_CARD_DISABLED 0x01
#define SW_CARD_DISABLED 0x02
#define CT_CARD_DISABLED 0x04
#define RXON_CARD_DISABLED 0x10
struct iwl_ct_kill_config {
__le32 reserved;
__le32 critical_temperature_M;
__le32 critical_temperature_R;
} __packed;
/* 1000, and 6x00 */
struct iwl_ct_kill_throttling_config {
__le32 critical_temperature_exit;
__le32 reserved;
__le32 critical_temperature_enter;
} __packed;
/******************************************************************************
* (8)
* Scan Commands, Responses, Notifications:
*
*****************************************************************************/
#define SCAN_CHANNEL_TYPE_PASSIVE cpu_to_le32(0)
#define SCAN_CHANNEL_TYPE_ACTIVE cpu_to_le32(1)
/**
* struct iwl_scan_channel - entry in REPLY_SCAN_CMD channel table
*
* One for each channel in the scan list.
* Each channel can independently select:
* 1) SSID for directed active scans
* 2) Txpower setting (for rate specified within Tx command)
* 3) How long to stay on-channel (behavior may be modified by quiet_time,
* quiet_plcp_th, good_CRC_th)
*
* To avoid uCode errors, make sure the following are true (see comments
* under struct iwl_scan_cmd about max_out_time and quiet_time):
* 1) If using passive_dwell (i.e. passive_dwell != 0):
* active_dwell <= passive_dwell (< max_out_time if max_out_time != 0)
* 2) quiet_time <= active_dwell
* 3) If restricting off-channel time (i.e. max_out_time !=0):
* passive_dwell < max_out_time
* active_dwell < max_out_time
*/
struct iwl_scan_channel {
/*
* type is defined as:
* 0:0 1 = active, 0 = passive
* 1:20 SSID direct bit map; if a bit is set, then corresponding
* SSID IE is transmitted in probe request.
* 21:31 reserved
*/
__le32 type;
__le16 channel; /* band is selected by iwl_scan_cmd "flags" field */
u8 tx_gain; /* gain for analog radio */
u8 dsp_atten; /* gain for DSP */
__le16 active_dwell; /* in 1024-uSec TU (time units), typ 5-50 */
__le16 passive_dwell; /* in 1024-uSec TU (time units), typ 20-500 */
} __packed;
/* set number of direct probes __le32 type */
#define IWL_SCAN_PROBE_MASK(n) cpu_to_le32((BIT(n) | (BIT(n) - BIT(1))))
/**
* struct iwl_ssid_ie - directed scan network information element
*
* Up to 20 of these may appear in REPLY_SCAN_CMD (Note: Only 4 are in
* 3945 SCAN api), selected by "type" bit field in struct iwl_scan_channel;
* each channel may select different ssids from among the 20 (4) entries.
* SSID IEs get transmitted in reverse order of entry.
*/
struct iwl_ssid_ie {
u8 id;
u8 len;
u8 ssid[32];
} __packed;
#define PROBE_OPTION_MAX_3945 4
#define PROBE_OPTION_MAX 20
#define TX_CMD_LIFE_TIME_INFINITE cpu_to_le32(0xFFFFFFFF)
#define IWL_GOOD_CRC_TH_DISABLED 0
#define IWL_GOOD_CRC_TH_DEFAULT cpu_to_le16(1)
#define IWL_GOOD_CRC_TH_NEVER cpu_to_le16(0xffff)
#define IWL_MAX_SCAN_SIZE 1024
#define IWL_MAX_CMD_SIZE 4096
/*
* REPLY_SCAN_CMD = 0x80 (command)
*
* The hardware scan command is very powerful; the driver can set it up to
* maintain (relatively) normal network traffic while doing a scan in the
* background. The max_out_time and suspend_time control the ratio of how
* long the device stays on an associated network channel ("service channel")
* vs. how long it's away from the service channel, i.e. tuned to other channels
* for scanning.
*
* max_out_time is the max time off-channel (in usec), and suspend_time
* is how long (in "extended beacon" format) that the scan is "suspended"
* after returning to the service channel. That is, suspend_time is the
* time that we stay on the service channel, doing normal work, between
* scan segments. The driver may set these parameters differently to support
* scanning when associated vs. not associated, and light vs. heavy traffic
* loads when associated.
*
* After receiving this command, the device's scan engine does the following;
*
* 1) Sends SCAN_START notification to driver
* 2) Checks to see if it has time to do scan for one channel
* 3) Sends NULL packet, with power-save (PS) bit set to 1,
* to tell AP that we're going off-channel
* 4) Tunes to first channel in scan list, does active or passive scan
* 5) Sends SCAN_RESULT notification to driver
* 6) Checks to see if it has time to do scan on *next* channel in list
* 7) Repeats 4-6 until it no longer has time to scan the next channel
* before max_out_time expires
* 8) Returns to service channel
* 9) Sends NULL packet with PS=0 to tell AP that we're back
* 10) Stays on service channel until suspend_time expires
* 11) Repeats entire process 2-10 until list is complete
* 12) Sends SCAN_COMPLETE notification
*
* For fast, efficient scans, the scan command also has support for staying on
* a channel for just a short time, if doing active scanning and getting no
* responses to the transmitted probe request. This time is controlled by
* quiet_time, and the number of received packets below which a channel is
* considered "quiet" is controlled by quiet_plcp_threshold.
*
* For active scanning on channels that have regulatory restrictions against
* blindly transmitting, the scan can listen before transmitting, to make sure
* that there is already legitimate activity on the channel. If enough
* packets are cleanly received on the channel (controlled by good_CRC_th,
* typical value 1), the scan engine starts transmitting probe requests.
*
* Driver must use separate scan commands for 2.4 vs. 5 GHz bands.
*
* To avoid uCode errors, see timing restrictions described under
* struct iwl_scan_channel.
*/
enum iwl_scan_flags {
/* BIT(0) currently unused */
IWL_SCAN_FLAGS_ACTION_FRAME_TX = BIT(1),
/* bits 2-7 reserved */
};
struct iwl_scan_cmd {
__le16 len;
u8 scan_flags; /* scan flags: see enum iwl_scan_flags */
u8 channel_count; /* # channels in channel list */
__le16 quiet_time; /* dwell only this # millisecs on quiet channel
* (only for active scan) */
__le16 quiet_plcp_th; /* quiet chnl is < this # pkts (typ. 1) */
__le16 good_CRC_th; /* passive -> active promotion threshold */
__le16 rx_chain; /* RXON_RX_CHAIN_* */
__le32 max_out_time; /* max usec to be away from associated (service)
* channel */
__le32 suspend_time; /* pause scan this long (in "extended beacon
* format") when returning to service chnl:
* 3945; 31:24 # beacons, 19:0 additional usec,
* 4965; 31:22 # beacons, 21:0 additional usec.
*/
__le32 flags; /* RXON_FLG_* */
__le32 filter_flags; /* RXON_FILTER_* */
/* For active scans (set to all-0s for passive scans).
* Does not include payload. Must specify Tx rate; no rate scaling. */
struct iwl_tx_cmd tx_cmd;
/* For directed active scans (set to all-0s otherwise) */
struct iwl_ssid_ie direct_scan[PROBE_OPTION_MAX];
/*
* Probe request frame, followed by channel list.
*
* Size of probe request frame is specified by byte count in tx_cmd.
* Channel list follows immediately after probe request frame.
* Number of channels in list is specified by channel_count.
* Each channel in list is of type:
*
* struct iwl_scan_channel channels[0];
*
* NOTE: Only one band of channels can be scanned per pass. You
* must not mix 2.4GHz channels and 5.2GHz channels, and you must wait
* for one scan to complete (i.e. receive SCAN_COMPLETE_NOTIFICATION)
* before requesting another scan.
*/
u8 data[0];
} __packed;
/* Can abort will notify by complete notification with abort status. */
#define CAN_ABORT_STATUS cpu_to_le32(0x1)
/* complete notification statuses */
#define ABORT_STATUS 0x2
/*
* REPLY_SCAN_CMD = 0x80 (response)
*/
struct iwl_scanreq_notification {
__le32 status; /* 1: okay, 2: cannot fulfill request */
} __packed;
/*
* SCAN_START_NOTIFICATION = 0x82 (notification only, not a command)
*/
struct iwl_scanstart_notification {
__le32 tsf_low;
__le32 tsf_high;
__le32 beacon_timer;
u8 channel;
u8 band;
u8 reserved[2];
__le32 status;
} __packed;
#define SCAN_OWNER_STATUS 0x1;
#define MEASURE_OWNER_STATUS 0x2;
#define IWL_PROBE_STATUS_OK 0
#define IWL_PROBE_STATUS_TX_FAILED BIT(0)
/* error statuses combined with TX_FAILED */
#define IWL_PROBE_STATUS_FAIL_TTL BIT(1)
#define IWL_PROBE_STATUS_FAIL_BT BIT(2)
#define NUMBER_OF_STATISTICS 1 /* first __le32 is good CRC */
/*
* SCAN_RESULTS_NOTIFICATION = 0x83 (notification only, not a command)
*/
struct iwl_scanresults_notification {
u8 channel;
u8 band;
u8 probe_status;
u8 num_probe_not_sent; /* not enough time to send */
__le32 tsf_low;
__le32 tsf_high;
__le32 statistics[NUMBER_OF_STATISTICS];
} __packed;
/*
* SCAN_COMPLETE_NOTIFICATION = 0x84 (notification only, not a command)
*/
struct iwl_scancomplete_notification {
u8 scanned_channels;
u8 status;
u8 bt_status; /* BT On/Off status */
u8 last_channel;
__le32 tsf_low;
__le32 tsf_high;
} __packed;
/******************************************************************************
* (9)
* IBSS/AP Commands and Notifications:
*
*****************************************************************************/
enum iwl_ibss_manager {
IWL_NOT_IBSS_MANAGER = 0,
IWL_IBSS_MANAGER = 1,
};
/*
* BEACON_NOTIFICATION = 0x90 (notification only, not a command)
*/
struct iwlagn_beacon_notif {
struct iwlagn_tx_resp beacon_notify_hdr;
__le32 low_tsf;
__le32 high_tsf;
__le32 ibss_mgr_status;
} __packed;
/*
* REPLY_TX_BEACON = 0x91 (command, has simple generic response)
*/
struct iwl_tx_beacon_cmd {
struct iwl_tx_cmd tx;
__le16 tim_idx;
u8 tim_size;
u8 reserved1;
struct ieee80211_hdr frame[0]; /* beacon frame */
} __packed;
/******************************************************************************
* (10)
* Statistics Commands and Notifications:
*
*****************************************************************************/
#define IWL_TEMP_CONVERT 260
#define SUP_RATE_11A_MAX_NUM_CHANNELS 8
#define SUP_RATE_11B_MAX_NUM_CHANNELS 4
#define SUP_RATE_11G_MAX_NUM_CHANNELS 12
/* Used for passing to driver number of successes and failures per rate */
struct rate_histogram {
union {
__le32 a[SUP_RATE_11A_MAX_NUM_CHANNELS];
__le32 b[SUP_RATE_11B_MAX_NUM_CHANNELS];
__le32 g[SUP_RATE_11G_MAX_NUM_CHANNELS];
} success;
union {
__le32 a[SUP_RATE_11A_MAX_NUM_CHANNELS];
__le32 b[SUP_RATE_11B_MAX_NUM_CHANNELS];
__le32 g[SUP_RATE_11G_MAX_NUM_CHANNELS];
} failed;
} __packed;
/* statistics command response */
struct statistics_dbg {
__le32 burst_check;
__le32 burst_count;
__le32 wait_for_silence_timeout_cnt;
__le32 reserved[3];
} __packed;
struct statistics_rx_phy {
__le32 ina_cnt;
__le32 fina_cnt;
__le32 plcp_err;
__le32 crc32_err;
__le32 overrun_err;
__le32 early_overrun_err;
__le32 crc32_good;
__le32 false_alarm_cnt;
__le32 fina_sync_err_cnt;
__le32 sfd_timeout;
__le32 fina_timeout;
__le32 unresponded_rts;
__le32 rxe_frame_limit_overrun;
__le32 sent_ack_cnt;
__le32 sent_cts_cnt;
__le32 sent_ba_rsp_cnt;
__le32 dsp_self_kill;
__le32 mh_format_err;
__le32 re_acq_main_rssi_sum;
__le32 reserved3;
} __packed;
struct statistics_rx_ht_phy {
__le32 plcp_err;
__le32 overrun_err;
__le32 early_overrun_err;
__le32 crc32_good;
__le32 crc32_err;
__le32 mh_format_err;
__le32 agg_crc32_good;
__le32 agg_mpdu_cnt;
__le32 agg_cnt;
__le32 unsupport_mcs;
} __packed;
#define INTERFERENCE_DATA_AVAILABLE cpu_to_le32(1)
struct statistics_rx_non_phy {
__le32 bogus_cts; /* CTS received when not expecting CTS */
__le32 bogus_ack; /* ACK received when not expecting ACK */
__le32 non_bssid_frames; /* number of frames with BSSID that
* doesn't belong to the STA BSSID */
__le32 filtered_frames; /* count frames that were dumped in the
* filtering process */
__le32 non_channel_beacons; /* beacons with our bss id but not on
* our serving channel */
__le32 channel_beacons; /* beacons with our bss id and in our
* serving channel */
__le32 num_missed_bcon; /* number of missed beacons */
__le32 adc_rx_saturation_time; /* count in 0.8us units the time the
* ADC was in saturation */
__le32 ina_detection_search_time;/* total time (in 0.8us) searched
* for INA */
__le32 beacon_silence_rssi_a; /* RSSI silence after beacon frame */
__le32 beacon_silence_rssi_b; /* RSSI silence after beacon frame */
__le32 beacon_silence_rssi_c; /* RSSI silence after beacon frame */
__le32 interference_data_flag; /* flag for interference data
* availability. 1 when data is
* available. */
__le32 channel_load; /* counts RX Enable time in uSec */
__le32 dsp_false_alarms; /* DSP false alarm (both OFDM
* and CCK) counter */
__le32 beacon_rssi_a;
__le32 beacon_rssi_b;
__le32 beacon_rssi_c;
__le32 beacon_energy_a;
__le32 beacon_energy_b;
__le32 beacon_energy_c;
} __packed;
struct statistics_rx_non_phy_bt {
struct statistics_rx_non_phy common;
/* additional stats for bt */
__le32 num_bt_kills;
__le32 reserved[2];
} __packed;
struct statistics_rx {
struct statistics_rx_phy ofdm;
struct statistics_rx_phy cck;
struct statistics_rx_non_phy general;
struct statistics_rx_ht_phy ofdm_ht;
} __packed;
struct statistics_rx_bt {
struct statistics_rx_phy ofdm;
struct statistics_rx_phy cck;
struct statistics_rx_non_phy_bt general;
struct statistics_rx_ht_phy ofdm_ht;
} __packed;
/**
* struct statistics_tx_power - current tx power
*
* @ant_a: current tx power on chain a in 1/2 dB step
* @ant_b: current tx power on chain b in 1/2 dB step
* @ant_c: current tx power on chain c in 1/2 dB step
*/
struct statistics_tx_power {
u8 ant_a;
u8 ant_b;
u8 ant_c;
u8 reserved;
} __packed;
struct statistics_tx_non_phy_agg {
__le32 ba_timeout;
__le32 ba_reschedule_frames;
__le32 scd_query_agg_frame_cnt;
__le32 scd_query_no_agg;
__le32 scd_query_agg;
__le32 scd_query_mismatch;
__le32 frame_not_ready;
__le32 underrun;
__le32 bt_prio_kill;
__le32 rx_ba_rsp_cnt;
} __packed;
struct statistics_tx {
__le32 preamble_cnt;
__le32 rx_detected_cnt;
__le32 bt_prio_defer_cnt;
__le32 bt_prio_kill_cnt;
__le32 few_bytes_cnt;
__le32 cts_timeout;
__le32 ack_timeout;
__le32 expected_ack_cnt;
__le32 actual_ack_cnt;
__le32 dump_msdu_cnt;
__le32 burst_abort_next_frame_mismatch_cnt;
__le32 burst_abort_missing_next_frame_cnt;
__le32 cts_timeout_collision;
__le32 ack_or_ba_timeout_collision;
struct statistics_tx_non_phy_agg agg;
/*
* "tx_power" are optional parameters provided by uCode,
* 6000 series is the only device provide the information,
* Those are reserved fields for all the other devices
*/
struct statistics_tx_power tx_power;
__le32 reserved1;
} __packed;
struct statistics_div {
__le32 tx_on_a;
__le32 tx_on_b;
__le32 exec_time;
__le32 probe_time;
__le32 reserved1;
__le32 reserved2;
} __packed;
struct statistics_general_common {
__le32 temperature; /* radio temperature */
__le32 temperature_m; /* for 5000 and up, this is radio voltage */
struct statistics_dbg dbg;
__le32 sleep_time;
__le32 slots_out;
__le32 slots_idle;
__le32 ttl_timestamp;
struct statistics_div div;
__le32 rx_enable_counter;
/*
* num_of_sos_states:
* count the number of times we have to re-tune
* in order to get out of bad PHY status
*/
__le32 num_of_sos_states;
} __packed;
struct statistics_bt_activity {
/* Tx statistics */
__le32 hi_priority_tx_req_cnt;
__le32 hi_priority_tx_denied_cnt;
__le32 lo_priority_tx_req_cnt;
__le32 lo_priority_tx_denied_cnt;
/* Rx statistics */
__le32 hi_priority_rx_req_cnt;
__le32 hi_priority_rx_denied_cnt;
__le32 lo_priority_rx_req_cnt;
__le32 lo_priority_rx_denied_cnt;
} __packed;
struct statistics_general {
struct statistics_general_common common;
__le32 reserved2;
__le32 reserved3;
} __packed;
struct statistics_general_bt {
struct statistics_general_common common;
struct statistics_bt_activity activity;
__le32 reserved2;
__le32 reserved3;
} __packed;
#define UCODE_STATISTICS_CLEAR_MSK (0x1 << 0)
#define UCODE_STATISTICS_FREQUENCY_MSK (0x1 << 1)
#define UCODE_STATISTICS_NARROW_BAND_MSK (0x1 << 2)
/*
* REPLY_STATISTICS_CMD = 0x9c,
* all devices identical.
*
* This command triggers an immediate response containing uCode statistics.
* The response is in the same format as STATISTICS_NOTIFICATION 0x9d, below.
*
* If the CLEAR_STATS configuration flag is set, uCode will clear its
* internal copy of the statistics (counters) after issuing the response.
* This flag does not affect STATISTICS_NOTIFICATIONs after beacons (see below).
*
* If the DISABLE_NOTIF configuration flag is set, uCode will not issue
* STATISTICS_NOTIFICATIONs after received beacons (see below). This flag
* does not affect the response to the REPLY_STATISTICS_CMD 0x9c itself.
*/
#define IWL_STATS_CONF_CLEAR_STATS cpu_to_le32(0x1) /* see above */
#define IWL_STATS_CONF_DISABLE_NOTIF cpu_to_le32(0x2)/* see above */
struct iwl_statistics_cmd {
__le32 configuration_flags; /* IWL_STATS_CONF_* */
} __packed;
/*
* STATISTICS_NOTIFICATION = 0x9d (notification only, not a command)
*
* By default, uCode issues this notification after receiving a beacon
* while associated. To disable this behavior, set DISABLE_NOTIF flag in the
* REPLY_STATISTICS_CMD 0x9c, above.
*
* Statistics counters continue to increment beacon after beacon, but are
* cleared when changing channels or when driver issues REPLY_STATISTICS_CMD
* 0x9c with CLEAR_STATS bit set (see above).
*
* uCode also issues this notification during scans. uCode clears statistics
* appropriately so that each notification contains statistics for only the
* one channel that has just been scanned.
*/
#define STATISTICS_REPLY_FLG_BAND_24G_MSK cpu_to_le32(0x2)
#define STATISTICS_REPLY_FLG_HT40_MODE_MSK cpu_to_le32(0x8)
struct iwl_notif_statistics {
__le32 flag;
struct statistics_rx rx;
struct statistics_tx tx;
struct statistics_general general;
} __packed;
struct iwl_bt_notif_statistics {
__le32 flag;
struct statistics_rx_bt rx;
struct statistics_tx tx;
struct statistics_general_bt general;
} __packed;
/*
* MISSED_BEACONS_NOTIFICATION = 0xa2 (notification only, not a command)
*
* uCode send MISSED_BEACONS_NOTIFICATION to driver when detect beacon missed
* in regardless of how many missed beacons, which mean when driver receive the
* notification, inside the command, it can find all the beacons information
* which include number of total missed beacons, number of consecutive missed
* beacons, number of beacons received and number of beacons expected to
* receive.
*
* If uCode detected consecutive_missed_beacons > 5, it will reset the radio
* in order to bring the radio/PHY back to working state; which has no relation
* to when driver will perform sensitivity calibration.
*
* Driver should set it own missed_beacon_threshold to decide when to perform
* sensitivity calibration based on number of consecutive missed beacons in
* order to improve overall performance, especially in noisy environment.
*
*/
#define IWL_MISSED_BEACON_THRESHOLD_MIN (1)
#define IWL_MISSED_BEACON_THRESHOLD_DEF (5)
#define IWL_MISSED_BEACON_THRESHOLD_MAX IWL_MISSED_BEACON_THRESHOLD_DEF
struct iwl_missed_beacon_notif {
__le32 consecutive_missed_beacons;
__le32 total_missed_becons;
__le32 num_expected_beacons;
__le32 num_recvd_beacons;
} __packed;
/******************************************************************************
* (11)
* Rx Calibration Commands:
*
* With the uCode used for open source drivers, most Tx calibration (except
* for Tx Power) and most Rx calibration is done by uCode during the
* "initialize" phase of uCode boot. Driver must calibrate only:
*
* 1) Tx power (depends on temperature), described elsewhere
* 2) Receiver gain balance (optimize MIMO, and detect disconnected antennas)
* 3) Receiver sensitivity (to optimize signal detection)
*
*****************************************************************************/
/**
* SENSITIVITY_CMD = 0xa8 (command, has simple generic response)
*
* This command sets up the Rx signal detector for a sensitivity level that
* is high enough to lock onto all signals within the associated network,
* but low enough to ignore signals that are below a certain threshold, so as
* not to have too many "false alarms". False alarms are signals that the
* Rx DSP tries to lock onto, but then discards after determining that they
* are noise.
*
* The optimum number of false alarms is between 5 and 50 per 200 TUs
* (200 * 1024 uSecs, i.e. 204.8 milliseconds) of actual Rx time (i.e.
* time listening, not transmitting). Driver must adjust sensitivity so that
* the ratio of actual false alarms to actual Rx time falls within this range.
*
* While associated, uCode delivers STATISTICS_NOTIFICATIONs after each
* received beacon. These provide information to the driver to analyze the
* sensitivity. Don't analyze statistics that come in from scanning, or any
* other non-associated-network source. Pertinent statistics include:
*
* From "general" statistics (struct statistics_rx_non_phy):
*
* (beacon_energy_[abc] & 0x0FF00) >> 8 (unsigned, higher value is lower level)
* Measure of energy of desired signal. Used for establishing a level
* below which the device does not detect signals.
*
* (beacon_silence_rssi_[abc] & 0x0FF00) >> 8 (unsigned, units in dB)
* Measure of background noise in silent period after beacon.
*
* channel_load
* uSecs of actual Rx time during beacon period (varies according to
* how much time was spent transmitting).
*
* From "cck" and "ofdm" statistics (struct statistics_rx_phy), separately:
*
* false_alarm_cnt
* Signal locks abandoned early (before phy-level header).
*
* plcp_err
* Signal locks abandoned late (during phy-level header).
*
* NOTE: Both false_alarm_cnt and plcp_err increment monotonically from
* beacon to beacon, i.e. each value is an accumulation of all errors
* before and including the latest beacon. Values will wrap around to 0
* after counting up to 2^32 - 1. Driver must differentiate vs.
* previous beacon's values to determine # false alarms in the current
* beacon period.
*
* Total number of false alarms = false_alarms + plcp_errs
*
* For OFDM, adjust the following table entries in struct iwl_sensitivity_cmd
* (notice that the start points for OFDM are at or close to settings for
* maximum sensitivity):
*
* START / MIN / MAX
* HD_AUTO_CORR32_X1_TH_ADD_MIN_INDEX 90 / 85 / 120
* HD_AUTO_CORR32_X1_TH_ADD_MIN_MRC_INDEX 170 / 170 / 210
* HD_AUTO_CORR32_X4_TH_ADD_MIN_INDEX 105 / 105 / 140
* HD_AUTO_CORR32_X4_TH_ADD_MIN_MRC_INDEX 220 / 220 / 270
*
* If actual rate of OFDM false alarms (+ plcp_errors) is too high
* (greater than 50 for each 204.8 msecs listening), reduce sensitivity
* by *adding* 1 to all 4 of the table entries above, up to the max for
* each entry. Conversely, if false alarm rate is too low (less than 5
* for each 204.8 msecs listening), *subtract* 1 from each entry to
* increase sensitivity.
*
* For CCK sensitivity, keep track of the following:
*
* 1). 20-beacon history of maximum background noise, indicated by
* (beacon_silence_rssi_[abc] & 0x0FF00), units in dB, across the
* 3 receivers. For any given beacon, the "silence reference" is
* the maximum of last 60 samples (20 beacons * 3 receivers).
*
* 2). 10-beacon history of strongest signal level, as indicated
* by (beacon_energy_[abc] & 0x0FF00) >> 8, across the 3 receivers,
* i.e. the strength of the signal through the best receiver at the
* moment. These measurements are "upside down", with lower values
* for stronger signals, so max energy will be *minimum* value.
*
* Then for any given beacon, the driver must determine the *weakest*
* of the strongest signals; this is the minimum level that needs to be
* successfully detected, when using the best receiver at the moment.
* "Max cck energy" is the maximum (higher value means lower energy!)
* of the last 10 minima. Once this is determined, driver must add
* a little margin by adding "6" to it.
*
* 3). Number of consecutive beacon periods with too few false alarms.
* Reset this to 0 at the first beacon period that falls within the
* "good" range (5 to 50 false alarms per 204.8 milliseconds rx).
*
* Then, adjust the following CCK table entries in struct iwl_sensitivity_cmd
* (notice that the start points for CCK are at maximum sensitivity):
*
* START / MIN / MAX
* HD_AUTO_CORR40_X4_TH_ADD_MIN_INDEX 125 / 125 / 200
* HD_AUTO_CORR40_X4_TH_ADD_MIN_MRC_INDEX 200 / 200 / 400
* HD_MIN_ENERGY_CCK_DET_INDEX 100 / 0 / 100
*
* If actual rate of CCK false alarms (+ plcp_errors) is too high
* (greater than 50 for each 204.8 msecs listening), method for reducing
* sensitivity is:
*
* 1) *Add* 3 to value in HD_AUTO_CORR40_X4_TH_ADD_MIN_MRC_INDEX,
* up to max 400.
*
* 2) If current value in HD_AUTO_CORR40_X4_TH_ADD_MIN_INDEX is < 160,
* sensitivity has been reduced a significant amount; bring it up to
* a moderate 161. Otherwise, *add* 3, up to max 200.
*
* 3) a) If current value in HD_AUTO_CORR40_X4_TH_ADD_MIN_INDEX is > 160,
* sensitivity has been reduced only a moderate or small amount;
* *subtract* 2 from value in HD_MIN_ENERGY_CCK_DET_INDEX,
* down to min 0. Otherwise (if gain has been significantly reduced),
* don't change the HD_MIN_ENERGY_CCK_DET_INDEX value.
*
* b) Save a snapshot of the "silence reference".
*
* If actual rate of CCK false alarms (+ plcp_errors) is too low
* (less than 5 for each 204.8 msecs listening), method for increasing
* sensitivity is used only if:
*
* 1a) Previous beacon did not have too many false alarms
* 1b) AND difference between previous "silence reference" and current
* "silence reference" (prev - current) is 2 or more,
* OR 2) 100 or more consecutive beacon periods have had rate of
* less than 5 false alarms per 204.8 milliseconds rx time.
*
* Method for increasing sensitivity:
*
* 1) *Subtract* 3 from value in HD_AUTO_CORR40_X4_TH_ADD_MIN_INDEX,
* down to min 125.
*
* 2) *Subtract* 3 from value in HD_AUTO_CORR40_X4_TH_ADD_MIN_MRC_INDEX,
* down to min 200.
*
* 3) *Add* 2 to value in HD_MIN_ENERGY_CCK_DET_INDEX, up to max 100.
*
* If actual rate of CCK false alarms (+ plcp_errors) is within good range
* (between 5 and 50 for each 204.8 msecs listening):
*
* 1) Save a snapshot of the silence reference.
*
* 2) If previous beacon had too many CCK false alarms (+ plcp_errors),
* give some extra margin to energy threshold by *subtracting* 8
* from value in HD_MIN_ENERGY_CCK_DET_INDEX.
*
* For all cases (too few, too many, good range), make sure that the CCK
* detection threshold (energy) is below the energy level for robust
* detection over the past 10 beacon periods, the "Max cck energy".
* Lower values mean higher energy; this means making sure that the value
* in HD_MIN_ENERGY_CCK_DET_INDEX is at or *above* "Max cck energy".
*
*/
/*
* Table entries in SENSITIVITY_CMD (struct iwl_sensitivity_cmd)
*/
#define HD_TABLE_SIZE (11) /* number of entries */
#define HD_MIN_ENERGY_CCK_DET_INDEX (0) /* table indexes */
#define HD_MIN_ENERGY_OFDM_DET_INDEX (1)
#define HD_AUTO_CORR32_X1_TH_ADD_MIN_INDEX (2)
#define HD_AUTO_CORR32_X1_TH_ADD_MIN_MRC_INDEX (3)
#define HD_AUTO_CORR40_X4_TH_ADD_MIN_MRC_INDEX (4)
#define HD_AUTO_CORR32_X4_TH_ADD_MIN_INDEX (5)
#define HD_AUTO_CORR32_X4_TH_ADD_MIN_MRC_INDEX (6)
#define HD_BARKER_CORR_TH_ADD_MIN_INDEX (7)
#define HD_BARKER_CORR_TH_ADD_MIN_MRC_INDEX (8)
#define HD_AUTO_CORR40_X4_TH_ADD_MIN_INDEX (9)
#define HD_OFDM_ENERGY_TH_IN_INDEX (10)
/*
* Additional table entries in enhance SENSITIVITY_CMD
*/
#define HD_INA_NON_SQUARE_DET_OFDM_INDEX (11)
#define HD_INA_NON_SQUARE_DET_CCK_INDEX (12)
#define HD_CORR_11_INSTEAD_OF_CORR_9_EN_INDEX (13)
#define HD_OFDM_NON_SQUARE_DET_SLOPE_MRC_INDEX (14)
#define HD_OFDM_NON_SQUARE_DET_INTERCEPT_MRC_INDEX (15)
#define HD_OFDM_NON_SQUARE_DET_SLOPE_INDEX (16)
#define HD_OFDM_NON_SQUARE_DET_INTERCEPT_INDEX (17)
#define HD_CCK_NON_SQUARE_DET_SLOPE_MRC_INDEX (18)
#define HD_CCK_NON_SQUARE_DET_INTERCEPT_MRC_INDEX (19)
#define HD_CCK_NON_SQUARE_DET_SLOPE_INDEX (20)
#define HD_CCK_NON_SQUARE_DET_INTERCEPT_INDEX (21)
#define HD_RESERVED (22)
/* number of entries for enhanced tbl */
#define ENHANCE_HD_TABLE_SIZE (23)
/* number of additional entries for enhanced tbl */
#define ENHANCE_HD_TABLE_ENTRIES (ENHANCE_HD_TABLE_SIZE - HD_TABLE_SIZE)
#define HD_INA_NON_SQUARE_DET_OFDM_DATA cpu_to_le16(0)
#define HD_INA_NON_SQUARE_DET_CCK_DATA cpu_to_le16(0)
#define HD_CORR_11_INSTEAD_OF_CORR_9_EN_DATA cpu_to_le16(0)
#define HD_OFDM_NON_SQUARE_DET_SLOPE_MRC_DATA cpu_to_le16(668)
#define HD_OFDM_NON_SQUARE_DET_INTERCEPT_MRC_DATA cpu_to_le16(4)
#define HD_OFDM_NON_SQUARE_DET_SLOPE_DATA cpu_to_le16(486)
#define HD_OFDM_NON_SQUARE_DET_INTERCEPT_DATA cpu_to_le16(37)
#define HD_CCK_NON_SQUARE_DET_SLOPE_MRC_DATA cpu_to_le16(853)
#define HD_CCK_NON_SQUARE_DET_INTERCEPT_MRC_DATA cpu_to_le16(4)
#define HD_CCK_NON_SQUARE_DET_SLOPE_DATA cpu_to_le16(476)
#define HD_CCK_NON_SQUARE_DET_INTERCEPT_DATA cpu_to_le16(99)
/* Control field in struct iwl_sensitivity_cmd */
#define SENSITIVITY_CMD_CONTROL_DEFAULT_TABLE cpu_to_le16(0)
#define SENSITIVITY_CMD_CONTROL_WORK_TABLE cpu_to_le16(1)
/**
* struct iwl_sensitivity_cmd
* @control: (1) updates working table, (0) updates default table
* @table: energy threshold values, use HD_* as index into table
*
* Always use "1" in "control" to update uCode's working table and DSP.
*/
struct iwl_sensitivity_cmd {
__le16 control; /* always use "1" */
__le16 table[HD_TABLE_SIZE]; /* use HD_* as index */
} __packed;
/*
*
*/
struct iwl_enhance_sensitivity_cmd {
__le16 control; /* always use "1" */
__le16 enhance_table[ENHANCE_HD_TABLE_SIZE]; /* use HD_* as index */
} __packed;
/**
* REPLY_PHY_CALIBRATION_CMD = 0xb0 (command, has simple generic response)
*
* This command sets the relative gains of agn device's 3 radio receiver chains.
*
* After the first association, driver should accumulate signal and noise
* statistics from the STATISTICS_NOTIFICATIONs that follow the first 20
* beacons from the associated network (don't collect statistics that come
* in from scanning, or any other non-network source).
*
* DISCONNECTED ANTENNA:
*
* Driver should determine which antennas are actually connected, by comparing
* average beacon signal levels for the 3 Rx chains. Accumulate (add) the
* following values over 20 beacons, one accumulator for each of the chains
* a/b/c, from struct statistics_rx_non_phy:
*
* beacon_rssi_[abc] & 0x0FF (unsigned, units in dB)
*
* Find the strongest signal from among a/b/c. Compare the other two to the
* strongest. If any signal is more than 15 dB (times 20, unless you
* divide the accumulated values by 20) below the strongest, the driver
* considers that antenna to be disconnected, and should not try to use that
* antenna/chain for Rx or Tx. If both A and B seem to be disconnected,
* driver should declare the stronger one as connected, and attempt to use it
* (A and B are the only 2 Tx chains!).
*
*
* RX BALANCE:
*
* Driver should balance the 3 receivers (but just the ones that are connected
* to antennas, see above) for gain, by comparing the average signal levels
* detected during the silence after each beacon (background noise).
* Accumulate (add) the following values over 20 beacons, one accumulator for
* each of the chains a/b/c, from struct statistics_rx_non_phy:
*
* beacon_silence_rssi_[abc] & 0x0FF (unsigned, units in dB)
*
* Find the weakest background noise level from among a/b/c. This Rx chain
* will be the reference, with 0 gain adjustment. Attenuate other channels by
* finding noise difference:
*
* (accum_noise[i] - accum_noise[reference]) / 30
*
* The "30" adjusts the dB in the 20 accumulated samples to units of 1.5 dB.
* For use in diff_gain_[abc] fields of struct iwl_calibration_cmd, the
* driver should limit the difference results to a range of 0-3 (0-4.5 dB),
* and set bit 2 to indicate "reduce gain". The value for the reference
* (weakest) chain should be "0".
*
* diff_gain_[abc] bit fields:
* 2: (1) reduce gain, (0) increase gain
* 1-0: amount of gain, units of 1.5 dB
*/
/* Phy calibration command for series */
/* The default calibrate table size if not specified by firmware */
#define IWL_DEFAULT_STANDARD_PHY_CALIBRATE_TBL_SIZE 18
enum {
IWL_PHY_CALIBRATE_DIFF_GAIN_CMD = 7,
IWL_PHY_CALIBRATE_DC_CMD = 8,
IWL_PHY_CALIBRATE_LO_CMD = 9,
IWL_PHY_CALIBRATE_TX_IQ_CMD = 11,
IWL_PHY_CALIBRATE_CRYSTAL_FRQ_CMD = 15,
IWL_PHY_CALIBRATE_BASE_BAND_CMD = 16,
IWL_PHY_CALIBRATE_TX_IQ_PERD_CMD = 17,
IWL_PHY_CALIBRATE_TEMP_OFFSET_CMD = 18,
IWL_MAX_STANDARD_PHY_CALIBRATE_TBL_SIZE = 19,
};
#define IWL_MAX_PHY_CALIBRATE_TBL_SIZE (253)
#define IWL_CALIB_INIT_CFG_ALL cpu_to_le32(0xffffffff)
/* This enum defines the bitmap of various calibrations to enable in both
* init ucode and runtime ucode through CALIBRATION_CFG_CMD.
*/
enum iwl_ucode_calib_cfg {
IWL_CALIB_CFG_RX_BB_IDX,
IWL_CALIB_CFG_DC_IDX,
IWL_CALIB_CFG_TX_IQ_IDX,
IWL_CALIB_CFG_RX_IQ_IDX,
IWL_CALIB_CFG_NOISE_IDX,
IWL_CALIB_CFG_CRYSTAL_IDX,
IWL_CALIB_CFG_TEMPERATURE_IDX,
IWL_CALIB_CFG_PAPD_IDX,
};
struct iwl_calib_cfg_elmnt_s {
__le32 is_enable;
__le32 start;
__le32 send_res;
__le32 apply_res;
__le32 reserved;
} __packed;
struct iwl_calib_cfg_status_s {
struct iwl_calib_cfg_elmnt_s once;
struct iwl_calib_cfg_elmnt_s perd;
__le32 flags;
} __packed;
struct iwl_calib_cfg_cmd {
struct iwl_calib_cfg_status_s ucd_calib_cfg;
struct iwl_calib_cfg_status_s drv_calib_cfg;
__le32 reserved1;
} __packed;
struct iwl_calib_hdr {
u8 op_code;
u8 first_group;
u8 groups_num;
u8 data_valid;
} __packed;
struct iwl_calib_cmd {
struct iwl_calib_hdr hdr;
u8 data[0];
} __packed;
/* IWL_PHY_CALIBRATE_DIFF_GAIN_CMD (7) */
struct iwl_calib_diff_gain_cmd {
struct iwl_calib_hdr hdr;
s8 diff_gain_a; /* see above */
s8 diff_gain_b;
s8 diff_gain_c;
u8 reserved1;
} __packed;
struct iwl_calib_xtal_freq_cmd {
struct iwl_calib_hdr hdr;
u8 cap_pin1;
u8 cap_pin2;
u8 pad[2];
} __packed;
#define DEFAULT_RADIO_SENSOR_OFFSET 2700
struct iwl_calib_temperature_offset_cmd {
struct iwl_calib_hdr hdr;
s16 radio_sensor_offset;
s16 reserved;
} __packed;
/* IWL_PHY_CALIBRATE_CHAIN_NOISE_RESET_CMD */
struct iwl_calib_chain_noise_reset_cmd {
struct iwl_calib_hdr hdr;
u8 data[0];
};
/* IWL_PHY_CALIBRATE_CHAIN_NOISE_GAIN_CMD */
struct iwl_calib_chain_noise_gain_cmd {
struct iwl_calib_hdr hdr;
u8 delta_gain_1;
u8 delta_gain_2;
u8 pad[2];
} __packed;
/******************************************************************************
* (12)
* Miscellaneous Commands:
*
*****************************************************************************/
/*
* LEDs Command & Response
* REPLY_LEDS_CMD = 0x48 (command, has simple generic response)
*
* For each of 3 possible LEDs (Activity/Link/Tech, selected by "id" field),
* this command turns it on or off, or sets up a periodic blinking cycle.
*/
struct iwl_led_cmd {
__le32 interval; /* "interval" in uSec */
u8 id; /* 1: Activity, 2: Link, 3: Tech */
u8 off; /* # intervals off while blinking;
* "0", with >0 "on" value, turns LED on */
u8 on; /* # intervals on while blinking;
* "0", regardless of "off", turns LED off */
u8 reserved;
} __packed;
/*
* station priority table entries
* also used as potential "events" value for both
* COEX_MEDIUM_NOTIFICATION and COEX_EVENT_CMD
*/
/*
* COEX events entry flag masks
* RP - Requested Priority
* WP - Win Medium Priority: priority assigned when the contention has been won
*/
#define COEX_EVT_FLAG_MEDIUM_FREE_NTFY_FLG (0x1)
#define COEX_EVT_FLAG_MEDIUM_ACTV_NTFY_FLG (0x2)
#define COEX_EVT_FLAG_DELAY_MEDIUM_FREE_NTFY_FLG (0x4)
#define COEX_CU_UNASSOC_IDLE_RP 4
#define COEX_CU_UNASSOC_MANUAL_SCAN_RP 4
#define COEX_CU_UNASSOC_AUTO_SCAN_RP 4
#define COEX_CU_CALIBRATION_RP 4
#define COEX_CU_PERIODIC_CALIBRATION_RP 4
#define COEX_CU_CONNECTION_ESTAB_RP 4
#define COEX_CU_ASSOCIATED_IDLE_RP 4
#define COEX_CU_ASSOC_MANUAL_SCAN_RP 4
#define COEX_CU_ASSOC_AUTO_SCAN_RP 4
#define COEX_CU_ASSOC_ACTIVE_LEVEL_RP 4
#define COEX_CU_RF_ON_RP 6
#define COEX_CU_RF_OFF_RP 4
#define COEX_CU_STAND_ALONE_DEBUG_RP 6
#define COEX_CU_IPAN_ASSOC_LEVEL_RP 4
#define COEX_CU_RSRVD1_RP 4
#define COEX_CU_RSRVD2_RP 4
#define COEX_CU_UNASSOC_IDLE_WP 3
#define COEX_CU_UNASSOC_MANUAL_SCAN_WP 3
#define COEX_CU_UNASSOC_AUTO_SCAN_WP 3
#define COEX_CU_CALIBRATION_WP 3
#define COEX_CU_PERIODIC_CALIBRATION_WP 3
#define COEX_CU_CONNECTION_ESTAB_WP 3
#define COEX_CU_ASSOCIATED_IDLE_WP 3
#define COEX_CU_ASSOC_MANUAL_SCAN_WP 3
#define COEX_CU_ASSOC_AUTO_SCAN_WP 3
#define COEX_CU_ASSOC_ACTIVE_LEVEL_WP 3
#define COEX_CU_RF_ON_WP 3
#define COEX_CU_RF_OFF_WP 3
#define COEX_CU_STAND_ALONE_DEBUG_WP 6
#define COEX_CU_IPAN_ASSOC_LEVEL_WP 3
#define COEX_CU_RSRVD1_WP 3
#define COEX_CU_RSRVD2_WP 3
#define COEX_UNASSOC_IDLE_FLAGS 0
#define COEX_UNASSOC_MANUAL_SCAN_FLAGS \
(COEX_EVT_FLAG_MEDIUM_FREE_NTFY_FLG | \
COEX_EVT_FLAG_MEDIUM_ACTV_NTFY_FLG)
#define COEX_UNASSOC_AUTO_SCAN_FLAGS \
(COEX_EVT_FLAG_MEDIUM_FREE_NTFY_FLG | \
COEX_EVT_FLAG_MEDIUM_ACTV_NTFY_FLG)
#define COEX_CALIBRATION_FLAGS \
(COEX_EVT_FLAG_MEDIUM_FREE_NTFY_FLG | \
COEX_EVT_FLAG_MEDIUM_ACTV_NTFY_FLG)
#define COEX_PERIODIC_CALIBRATION_FLAGS 0
/*
* COEX_CONNECTION_ESTAB:
* we need DELAY_MEDIUM_FREE_NTFY to let WiMAX disconnect from network.
*/
#define COEX_CONNECTION_ESTAB_FLAGS \
(COEX_EVT_FLAG_MEDIUM_FREE_NTFY_FLG | \
COEX_EVT_FLAG_MEDIUM_ACTV_NTFY_FLG | \
COEX_EVT_FLAG_DELAY_MEDIUM_FREE_NTFY_FLG)
#define COEX_ASSOCIATED_IDLE_FLAGS 0
#define COEX_ASSOC_MANUAL_SCAN_FLAGS \
(COEX_EVT_FLAG_MEDIUM_FREE_NTFY_FLG | \
COEX_EVT_FLAG_MEDIUM_ACTV_NTFY_FLG)
#define COEX_ASSOC_AUTO_SCAN_FLAGS \
(COEX_EVT_FLAG_MEDIUM_FREE_NTFY_FLG | \
COEX_EVT_FLAG_MEDIUM_ACTV_NTFY_FLG)
#define COEX_ASSOC_ACTIVE_LEVEL_FLAGS 0
#define COEX_RF_ON_FLAGS 0
#define COEX_RF_OFF_FLAGS 0
#define COEX_STAND_ALONE_DEBUG_FLAGS \
(COEX_EVT_FLAG_MEDIUM_FREE_NTFY_FLG | \
COEX_EVT_FLAG_MEDIUM_ACTV_NTFY_FLG)
#define COEX_IPAN_ASSOC_LEVEL_FLAGS \
(COEX_EVT_FLAG_MEDIUM_FREE_NTFY_FLG | \
COEX_EVT_FLAG_MEDIUM_ACTV_NTFY_FLG | \
COEX_EVT_FLAG_DELAY_MEDIUM_FREE_NTFY_FLG)
#define COEX_RSRVD1_FLAGS 0
#define COEX_RSRVD2_FLAGS 0
/*
* COEX_CU_RF_ON is the event wrapping all radio ownership.
* We need DELAY_MEDIUM_FREE_NTFY to let WiMAX disconnect from network.
*/
#define COEX_CU_RF_ON_FLAGS \
(COEX_EVT_FLAG_MEDIUM_FREE_NTFY_FLG | \
COEX_EVT_FLAG_MEDIUM_ACTV_NTFY_FLG | \
COEX_EVT_FLAG_DELAY_MEDIUM_FREE_NTFY_FLG)
enum {
/* un-association part */
COEX_UNASSOC_IDLE = 0,
COEX_UNASSOC_MANUAL_SCAN = 1,
COEX_UNASSOC_AUTO_SCAN = 2,
/* calibration */
COEX_CALIBRATION = 3,
COEX_PERIODIC_CALIBRATION = 4,
/* connection */
COEX_CONNECTION_ESTAB = 5,
/* association part */
COEX_ASSOCIATED_IDLE = 6,
COEX_ASSOC_MANUAL_SCAN = 7,
COEX_ASSOC_AUTO_SCAN = 8,
COEX_ASSOC_ACTIVE_LEVEL = 9,
/* RF ON/OFF */
COEX_RF_ON = 10,
COEX_RF_OFF = 11,
COEX_STAND_ALONE_DEBUG = 12,
/* IPAN */
COEX_IPAN_ASSOC_LEVEL = 13,
/* reserved */
COEX_RSRVD1 = 14,
COEX_RSRVD2 = 15,
COEX_NUM_OF_EVENTS = 16
};
/*
* Coexistence WIFI/WIMAX Command
* COEX_PRIORITY_TABLE_CMD = 0x5a
*
*/
struct iwl_wimax_coex_event_entry {
u8 request_prio;
u8 win_medium_prio;
u8 reserved;
u8 flags;
} __packed;
/* COEX flag masks */
/* Station table is valid */
#define COEX_FLAGS_STA_TABLE_VALID_MSK (0x1)
/* UnMask wake up src at unassociated sleep */
#define COEX_FLAGS_UNASSOC_WA_UNMASK_MSK (0x4)
/* UnMask wake up src at associated sleep */
#define COEX_FLAGS_ASSOC_WA_UNMASK_MSK (0x8)
/* Enable CoEx feature. */
#define COEX_FLAGS_COEX_ENABLE_MSK (0x80)
struct iwl_wimax_coex_cmd {
u8 flags;
u8 reserved[3];
struct iwl_wimax_coex_event_entry sta_prio[COEX_NUM_OF_EVENTS];
} __packed;
/*
* Coexistence MEDIUM NOTIFICATION
* COEX_MEDIUM_NOTIFICATION = 0x5b
*
* notification from uCode to host to indicate medium changes
*
*/
/*
* status field
* bit 0 - 2: medium status
* bit 3: medium change indication
* bit 4 - 31: reserved
*/
/* status option values, (0 - 2 bits) */
#define COEX_MEDIUM_BUSY (0x0) /* radio belongs to WiMAX */
#define COEX_MEDIUM_ACTIVE (0x1) /* radio belongs to WiFi */
#define COEX_MEDIUM_PRE_RELEASE (0x2) /* received radio release */
#define COEX_MEDIUM_MSK (0x7)
/* send notification status (1 bit) */
#define COEX_MEDIUM_CHANGED (0x8)
#define COEX_MEDIUM_CHANGED_MSK (0x8)
#define COEX_MEDIUM_SHIFT (3)
struct iwl_coex_medium_notification {
__le32 status;
__le32 events;
} __packed;
/*
* Coexistence EVENT Command
* COEX_EVENT_CMD = 0x5c
*
* send from host to uCode for coex event request.
*/
/* flags options */
#define COEX_EVENT_REQUEST_MSK (0x1)
struct iwl_coex_event_cmd {
u8 flags;
u8 event;
__le16 reserved;
} __packed;
struct iwl_coex_event_resp {
__le32 status;
} __packed;
/******************************************************************************
* Bluetooth Coexistence commands
*
*****************************************************************************/
/*
* BT Status notification
* REPLY_BT_COEX_PROFILE_NOTIF = 0xce
*/
enum iwl_bt_coex_profile_traffic_load {
IWL_BT_COEX_TRAFFIC_LOAD_NONE = 0,
IWL_BT_COEX_TRAFFIC_LOAD_LOW = 1,
IWL_BT_COEX_TRAFFIC_LOAD_HIGH = 2,
IWL_BT_COEX_TRAFFIC_LOAD_CONTINUOUS = 3,
/*
* There are no more even though below is a u8, the
* indication from the BT device only has two bits.
*/
};
#define BT_SESSION_ACTIVITY_1_UART_MSG 0x1
#define BT_SESSION_ACTIVITY_2_UART_MSG 0x2
/* BT UART message - Share Part (BT -> WiFi) */
#define BT_UART_MSG_FRAME1MSGTYPE_POS (0)
#define BT_UART_MSG_FRAME1MSGTYPE_MSK \
(0x7 << BT_UART_MSG_FRAME1MSGTYPE_POS)
#define BT_UART_MSG_FRAME1SSN_POS (3)
#define BT_UART_MSG_FRAME1SSN_MSK \
(0x3 << BT_UART_MSG_FRAME1SSN_POS)
#define BT_UART_MSG_FRAME1UPDATEREQ_POS (5)
#define BT_UART_MSG_FRAME1UPDATEREQ_MSK \
(0x1 << BT_UART_MSG_FRAME1UPDATEREQ_POS)
#define BT_UART_MSG_FRAME1RESERVED_POS (6)
#define BT_UART_MSG_FRAME1RESERVED_MSK \
(0x3 << BT_UART_MSG_FRAME1RESERVED_POS)
#define BT_UART_MSG_FRAME2OPENCONNECTIONS_POS (0)
#define BT_UART_MSG_FRAME2OPENCONNECTIONS_MSK \
(0x3 << BT_UART_MSG_FRAME2OPENCONNECTIONS_POS)
#define BT_UART_MSG_FRAME2TRAFFICLOAD_POS (2)
#define BT_UART_MSG_FRAME2TRAFFICLOAD_MSK \
(0x3 << BT_UART_MSG_FRAME2TRAFFICLOAD_POS)
#define BT_UART_MSG_FRAME2CHLSEQN_POS (4)
#define BT_UART_MSG_FRAME2CHLSEQN_MSK \
(0x1 << BT_UART_MSG_FRAME2CHLSEQN_POS)
#define BT_UART_MSG_FRAME2INBAND_POS (5)
#define BT_UART_MSG_FRAME2INBAND_MSK \
(0x1 << BT_UART_MSG_FRAME2INBAND_POS)
#define BT_UART_MSG_FRAME2RESERVED_POS (6)
#define BT_UART_MSG_FRAME2RESERVED_MSK \
(0x3 << BT_UART_MSG_FRAME2RESERVED_POS)
#define BT_UART_MSG_FRAME3SCOESCO_POS (0)
#define BT_UART_MSG_FRAME3SCOESCO_MSK \
(0x1 << BT_UART_MSG_FRAME3SCOESCO_POS)
#define BT_UART_MSG_FRAME3SNIFF_POS (1)
#define BT_UART_MSG_FRAME3SNIFF_MSK \
(0x1 << BT_UART_MSG_FRAME3SNIFF_POS)
#define BT_UART_MSG_FRAME3A2DP_POS (2)
#define BT_UART_MSG_FRAME3A2DP_MSK \
(0x1 << BT_UART_MSG_FRAME3A2DP_POS)
#define BT_UART_MSG_FRAME3ACL_POS (3)
#define BT_UART_MSG_FRAME3ACL_MSK \
(0x1 << BT_UART_MSG_FRAME3ACL_POS)
#define BT_UART_MSG_FRAME3MASTER_POS (4)
#define BT_UART_MSG_FRAME3MASTER_MSK \
(0x1 << BT_UART_MSG_FRAME3MASTER_POS)
#define BT_UART_MSG_FRAME3OBEX_POS (5)
#define BT_UART_MSG_FRAME3OBEX_MSK \
(0x1 << BT_UART_MSG_FRAME3OBEX_POS)
#define BT_UART_MSG_FRAME3RESERVED_POS (6)
#define BT_UART_MSG_FRAME3RESERVED_MSK \
(0x3 << BT_UART_MSG_FRAME3RESERVED_POS)
#define BT_UART_MSG_FRAME4IDLEDURATION_POS (0)
#define BT_UART_MSG_FRAME4IDLEDURATION_MSK \
(0x3F << BT_UART_MSG_FRAME4IDLEDURATION_POS)
#define BT_UART_MSG_FRAME4RESERVED_POS (6)
#define BT_UART_MSG_FRAME4RESERVED_MSK \
(0x3 << BT_UART_MSG_FRAME4RESERVED_POS)
#define BT_UART_MSG_FRAME5TXACTIVITY_POS (0)
#define BT_UART_MSG_FRAME5TXACTIVITY_MSK \
(0x3 << BT_UART_MSG_FRAME5TXACTIVITY_POS)
#define BT_UART_MSG_FRAME5RXACTIVITY_POS (2)
#define BT_UART_MSG_FRAME5RXACTIVITY_MSK \
(0x3 << BT_UART_MSG_FRAME5RXACTIVITY_POS)
#define BT_UART_MSG_FRAME5ESCORETRANSMIT_POS (4)
#define BT_UART_MSG_FRAME5ESCORETRANSMIT_MSK \
(0x3 << BT_UART_MSG_FRAME5ESCORETRANSMIT_POS)
#define BT_UART_MSG_FRAME5RESERVED_POS (6)
#define BT_UART_MSG_FRAME5RESERVED_MSK \
(0x3 << BT_UART_MSG_FRAME5RESERVED_POS)
#define BT_UART_MSG_FRAME6SNIFFINTERVAL_POS (0)
#define BT_UART_MSG_FRAME6SNIFFINTERVAL_MSK \
(0x1F << BT_UART_MSG_FRAME6SNIFFINTERVAL_POS)
#define BT_UART_MSG_FRAME6DISCOVERABLE_POS (5)
#define BT_UART_MSG_FRAME6DISCOVERABLE_MSK \
(0x1 << BT_UART_MSG_FRAME6DISCOVERABLE_POS)
#define BT_UART_MSG_FRAME6RESERVED_POS (6)
#define BT_UART_MSG_FRAME6RESERVED_MSK \
(0x3 << BT_UART_MSG_FRAME6RESERVED_POS)
#define BT_UART_MSG_FRAME7SNIFFACTIVITY_POS (0)
#define BT_UART_MSG_FRAME7SNIFFACTIVITY_MSK \
(0x7 << BT_UART_MSG_FRAME7SNIFFACTIVITY_POS)
#define BT_UART_MSG_FRAME7PAGE_POS (3)
#define BT_UART_MSG_FRAME7PAGE_MSK \
(0x1 << BT_UART_MSG_FRAME7PAGE_POS)
#define BT_UART_MSG_FRAME7INQUIRY_POS (4)
#define BT_UART_MSG_FRAME7INQUIRY_MSK \
(0x1 << BT_UART_MSG_FRAME7INQUIRY_POS)
#define BT_UART_MSG_FRAME7CONNECTABLE_POS (5)
#define BT_UART_MSG_FRAME7CONNECTABLE_MSK \
(0x1 << BT_UART_MSG_FRAME7CONNECTABLE_POS)
#define BT_UART_MSG_FRAME7RESERVED_POS (6)
#define BT_UART_MSG_FRAME7RESERVED_MSK \
(0x3 << BT_UART_MSG_FRAME7RESERVED_POS)
/* BT Session Activity 2 UART message (BT -> WiFi) */
#define BT_UART_MSG_2_FRAME1RESERVED1_POS (5)
#define BT_UART_MSG_2_FRAME1RESERVED1_MSK \
(0x1<<BT_UART_MSG_2_FRAME1RESERVED1_POS)
#define BT_UART_MSG_2_FRAME1RESERVED2_POS (6)
#define BT_UART_MSG_2_FRAME1RESERVED2_MSK \
(0x3<<BT_UART_MSG_2_FRAME1RESERVED2_POS)
#define BT_UART_MSG_2_FRAME2AGGTRAFFICLOAD_POS (0)
#define BT_UART_MSG_2_FRAME2AGGTRAFFICLOAD_MSK \
(0x3F<<BT_UART_MSG_2_FRAME2AGGTRAFFICLOAD_POS)
#define BT_UART_MSG_2_FRAME2RESERVED_POS (6)
#define BT_UART_MSG_2_FRAME2RESERVED_MSK \
(0x3<<BT_UART_MSG_2_FRAME2RESERVED_POS)
#define BT_UART_MSG_2_FRAME3BRLASTTXPOWER_POS (0)
#define BT_UART_MSG_2_FRAME3BRLASTTXPOWER_MSK \
(0xF<<BT_UART_MSG_2_FRAME3BRLASTTXPOWER_POS)
#define BT_UART_MSG_2_FRAME3INQPAGESRMODE_POS (4)
#define BT_UART_MSG_2_FRAME3INQPAGESRMODE_MSK \
(0x1<<BT_UART_MSG_2_FRAME3INQPAGESRMODE_POS)
#define BT_UART_MSG_2_FRAME3LEMASTER_POS (5)
#define BT_UART_MSG_2_FRAME3LEMASTER_MSK \
(0x1<<BT_UART_MSG_2_FRAME3LEMASTER_POS)
#define BT_UART_MSG_2_FRAME3RESERVED_POS (6)
#define BT_UART_MSG_2_FRAME3RESERVED_MSK \
(0x3<<BT_UART_MSG_2_FRAME3RESERVED_POS)
#define BT_UART_MSG_2_FRAME4LELASTTXPOWER_POS (0)
#define BT_UART_MSG_2_FRAME4LELASTTXPOWER_MSK \
(0xF<<BT_UART_MSG_2_FRAME4LELASTTXPOWER_POS)
#define BT_UART_MSG_2_FRAME4NUMLECONN_POS (4)
#define BT_UART_MSG_2_FRAME4NUMLECONN_MSK \
(0x3<<BT_UART_MSG_2_FRAME4NUMLECONN_POS)
#define BT_UART_MSG_2_FRAME4RESERVED_POS (6)
#define BT_UART_MSG_2_FRAME4RESERVED_MSK \
(0x3<<BT_UART_MSG_2_FRAME4RESERVED_POS)
#define BT_UART_MSG_2_FRAME5BTMINRSSI_POS (0)
#define BT_UART_MSG_2_FRAME5BTMINRSSI_MSK \
(0xF<<BT_UART_MSG_2_FRAME5BTMINRSSI_POS)
#define BT_UART_MSG_2_FRAME5LESCANINITMODE_POS (4)
#define BT_UART_MSG_2_FRAME5LESCANINITMODE_MSK \
(0x1<<BT_UART_MSG_2_FRAME5LESCANINITMODE_POS)
#define BT_UART_MSG_2_FRAME5LEADVERMODE_POS (5)
#define BT_UART_MSG_2_FRAME5LEADVERMODE_MSK \
(0x1<<BT_UART_MSG_2_FRAME5LEADVERMODE_POS)
#define BT_UART_MSG_2_FRAME5RESERVED_POS (6)
#define BT_UART_MSG_2_FRAME5RESERVED_MSK \
(0x3<<BT_UART_MSG_2_FRAME5RESERVED_POS)
#define BT_UART_MSG_2_FRAME6LECONNINTERVAL_POS (0)
#define BT_UART_MSG_2_FRAME6LECONNINTERVAL_MSK \
(0x1F<<BT_UART_MSG_2_FRAME6LECONNINTERVAL_POS)
#define BT_UART_MSG_2_FRAME6RFU_POS (5)
#define BT_UART_MSG_2_FRAME6RFU_MSK \
(0x1<<BT_UART_MSG_2_FRAME6RFU_POS)
#define BT_UART_MSG_2_FRAME6RESERVED_POS (6)
#define BT_UART_MSG_2_FRAME6RESERVED_MSK \
(0x3<<BT_UART_MSG_2_FRAME6RESERVED_POS)
#define BT_UART_MSG_2_FRAME7LECONNSLAVELAT_POS (0)
#define BT_UART_MSG_2_FRAME7LECONNSLAVELAT_MSK \
(0x7<<BT_UART_MSG_2_FRAME7LECONNSLAVELAT_POS)
#define BT_UART_MSG_2_FRAME7LEPROFILE1_POS (3)
#define BT_UART_MSG_2_FRAME7LEPROFILE1_MSK \
(0x1<<BT_UART_MSG_2_FRAME7LEPROFILE1_POS)
#define BT_UART_MSG_2_FRAME7LEPROFILE2_POS (4)
#define BT_UART_MSG_2_FRAME7LEPROFILE2_MSK \
(0x1<<BT_UART_MSG_2_FRAME7LEPROFILE2_POS)
#define BT_UART_MSG_2_FRAME7LEPROFILEOTHER_POS (5)
#define BT_UART_MSG_2_FRAME7LEPROFILEOTHER_MSK \
(0x1<<BT_UART_MSG_2_FRAME7LEPROFILEOTHER_POS)
#define BT_UART_MSG_2_FRAME7RESERVED_POS (6)
#define BT_UART_MSG_2_FRAME7RESERVED_MSK \
(0x3<<BT_UART_MSG_2_FRAME7RESERVED_POS)
struct iwl_bt_uart_msg {
u8 header;
u8 frame1;
u8 frame2;
u8 frame3;
u8 frame4;
u8 frame5;
u8 frame6;
u8 frame7;
} __attribute__((packed));
struct iwl_bt_coex_profile_notif {
struct iwl_bt_uart_msg last_bt_uart_msg;
u8 bt_status; /* 0 - off, 1 - on */
u8 bt_traffic_load; /* 0 .. 3? */
u8 bt_ci_compliance; /* 0 - not complied, 1 - complied */
u8 reserved;
} __attribute__((packed));
#define IWL_BT_COEX_PRIO_TBL_SHARED_ANTENNA_POS 0
#define IWL_BT_COEX_PRIO_TBL_SHARED_ANTENNA_MSK 0x1
#define IWL_BT_COEX_PRIO_TBL_PRIO_POS 1
#define IWL_BT_COEX_PRIO_TBL_PRIO_MASK 0x0e
#define IWL_BT_COEX_PRIO_TBL_RESERVED_POS 4
#define IWL_BT_COEX_PRIO_TBL_RESERVED_MASK 0xf0
#define IWL_BT_COEX_PRIO_TBL_PRIO_SHIFT 1
/*
* BT Coexistence Priority table
* REPLY_BT_COEX_PRIO_TABLE = 0xcc
*/
enum bt_coex_prio_table_events {
BT_COEX_PRIO_TBL_EVT_INIT_CALIB1 = 0,
BT_COEX_PRIO_TBL_EVT_INIT_CALIB2 = 1,
BT_COEX_PRIO_TBL_EVT_PERIODIC_CALIB_LOW1 = 2,
BT_COEX_PRIO_TBL_EVT_PERIODIC_CALIB_LOW2 = 3, /* DC calib */
BT_COEX_PRIO_TBL_EVT_PERIODIC_CALIB_HIGH1 = 4,
BT_COEX_PRIO_TBL_EVT_PERIODIC_CALIB_HIGH2 = 5,
BT_COEX_PRIO_TBL_EVT_DTIM = 6,
BT_COEX_PRIO_TBL_EVT_SCAN52 = 7,
BT_COEX_PRIO_TBL_EVT_SCAN24 = 8,
BT_COEX_PRIO_TBL_EVT_RESERVED0 = 9,
BT_COEX_PRIO_TBL_EVT_RESERVED1 = 10,
BT_COEX_PRIO_TBL_EVT_RESERVED2 = 11,
BT_COEX_PRIO_TBL_EVT_RESERVED3 = 12,
BT_COEX_PRIO_TBL_EVT_RESERVED4 = 13,
BT_COEX_PRIO_TBL_EVT_RESERVED5 = 14,
BT_COEX_PRIO_TBL_EVT_RESERVED6 = 15,
/* BT_COEX_PRIO_TBL_EVT_MAX should always be last */
BT_COEX_PRIO_TBL_EVT_MAX,
};
enum bt_coex_prio_table_priorities {
BT_COEX_PRIO_TBL_DISABLED = 0,
BT_COEX_PRIO_TBL_PRIO_LOW = 1,
BT_COEX_PRIO_TBL_PRIO_HIGH = 2,
BT_COEX_PRIO_TBL_PRIO_BYPASS = 3,
BT_COEX_PRIO_TBL_PRIO_COEX_OFF = 4,
BT_COEX_PRIO_TBL_PRIO_COEX_ON = 5,
BT_COEX_PRIO_TBL_PRIO_RSRVD1 = 6,
BT_COEX_PRIO_TBL_PRIO_RSRVD2 = 7,
BT_COEX_PRIO_TBL_MAX,
};
struct iwl_bt_coex_prio_table_cmd {
u8 prio_tbl[BT_COEX_PRIO_TBL_EVT_MAX];
} __attribute__((packed));
#define IWL_BT_COEX_ENV_CLOSE 0
#define IWL_BT_COEX_ENV_OPEN 1
/*
* BT Protection Envelope
* REPLY_BT_COEX_PROT_ENV = 0xcd
*/
struct iwl_bt_coex_prot_env_cmd {
u8 action; /* 0 = closed, 1 = open */
u8 type; /* 0 .. 15 */
u8 reserved[2];
} __attribute__((packed));
/******************************************************************************
* (13)
* Union of all expected notifications/responses:
*
*****************************************************************************/
struct iwl_rx_packet {
/*
* The first 4 bytes of the RX frame header contain both the RX frame
* size and some flags.
* Bit fields:
* 31: flag flush RB request
* 30: flag ignore TC (terminal counter) request
* 29: flag fast IRQ request
* 28-14: Reserved
* 13-00: RX frame size
*/
iwlwifi: fix erroneous use of iwl_rx_packet.len as a length The field called 'len' in struct iwl_rx_packet is in fact not just a length field but also includes some flags from the flow handler. In several places throughout the driver, this causes incorrect values to be interpreted as lengths when the field is improperly masked. In most situations the improper use is for debugging output, and simply results in an erroneous message, such as: [551933.070224] ieee80211 phy0: I iwl_rx_statistics Statistics notification received (480 vs -1367342620). which should read '(480 vs 484)'. In at least one case this could case bad things to happen: void iwl_rx_pm_debug_statistics_notif(struct iwl_priv *priv, struct iwl_rx_mem_buffer *rxb) { struct iwl_rx_packet *pkt = (struct iwl_rx_packet *)rxb->skb->data; IWL_DEBUG_RADIO(priv, "Dumping %d bytes of unhandled " "notification for %s:\n", le32_to_cpu(pkt->len), get_cmd_string(pkt->hdr.cmd)); iwl_print_hex_dump(priv, IWL_DL_RADIO, pkt->u.raw, le32_to_cpu(pkt->len) ); } EXPORT_SYMBOL(iwl_rx_pm_debug_statistics_notif); Given the rampant misuse of this field without proper masking throughout the driver (every use but one), this patch renames the field from 'len' to 'len_n_flags' to reduce confusion. It also adds the proper masking when this field is used as a length value. Signed-off-by: Daniel C Halperin <daniel.c.halperin@intel.com> Signed-off-by: Reinette Chatre <reinette.chatre@intel.com> Signed-off-by: John W. Linville <linville@tuxdriver.com>
2009-08-13 20:31:01 +00:00
__le32 len_n_flags;
struct iwl_cmd_header hdr;
union {
struct iwl_alive_resp alive_frame;
struct iwl_spectrum_notification spectrum_notif;
struct iwl_csa_notification csa_notif;
struct iwl_error_resp err_resp;
struct iwl_card_state_notif card_state_notif;
struct iwl_add_sta_resp add_sta;
struct iwl_rem_sta_resp rem_sta;
struct iwl_sleep_notification sleep_notif;
struct iwl_spectrum_resp spectrum;
struct iwl_notif_statistics stats;
struct iwl_bt_notif_statistics stats_bt;
struct iwl_compressed_ba_resp compressed_ba;
struct iwl_missed_beacon_notif missed_beacon;
struct iwl_coex_medium_notification coex_medium_notif;
struct iwl_coex_event_resp coex_event;
struct iwl_bt_coex_profile_notif bt_coex_profile_notif;
__le32 status;
u8 raw[0];
} u;
} __packed;
int iwl_agn_check_rxon_cmd(struct iwl_priv *priv);
/*
* REPLY_WIPAN_PARAMS = 0xb2 (Commands and Notification)
*/
/*
* Minimum slot time in TU
*/
#define IWL_MIN_SLOT_TIME 20
/**
* struct iwl_wipan_slot
* @width: Time in TU
* @type:
* 0 - BSS
* 1 - PAN
*/
struct iwl_wipan_slot {
__le16 width;
u8 type;
u8 reserved;
} __packed;
#define IWL_WIPAN_PARAMS_FLG_LEAVE_CHANNEL_CTS BIT(1) /* reserved */
#define IWL_WIPAN_PARAMS_FLG_LEAVE_CHANNEL_QUIET BIT(2) /* reserved */
#define IWL_WIPAN_PARAMS_FLG_SLOTTED_MODE BIT(3) /* reserved */
#define IWL_WIPAN_PARAMS_FLG_FILTER_BEACON_NOTIF BIT(4)
#define IWL_WIPAN_PARAMS_FLG_FULL_SLOTTED_MODE BIT(5)
/**
* struct iwl_wipan_params_cmd
* @flags:
* bit0: reserved
* bit1: CP leave channel with CTS
* bit2: CP leave channel qith Quiet
* bit3: slotted mode
* 1 - work in slotted mode
* 0 - work in non slotted mode
* bit4: filter beacon notification
* bit5: full tx slotted mode. if this flag is set,
* uCode will perform leaving channel methods in context switch
* also when working in same channel mode
* @num_slots: 1 - 10
*/
struct iwl_wipan_params_cmd {
__le16 flags;
u8 reserved;
u8 num_slots;
struct iwl_wipan_slot slots[10];
} __packed;
/*
* REPLY_WIPAN_P2P_CHANNEL_SWITCH = 0xb9
*
* TODO: Figure out what this is used for,
* it can only switch between 2.4 GHz
* channels!!
*/
struct iwl_wipan_p2p_channel_switch_cmd {
__le16 channel;
__le16 reserved;
};
/*
* REPLY_WIPAN_NOA_NOTIFICATION = 0xbc
*
* This is used by the device to notify us of the
* NoA schedule it determined so we can forward it
* to userspace for inclusion in probe responses.
*
* In beacons, the NoA schedule is simply appended
* to the frame we give the device.
*/
struct iwl_wipan_noa_descriptor {
u8 count;
__le32 duration;
__le32 interval;
__le32 starttime;
} __packed;
struct iwl_wipan_noa_attribute {
u8 id;
__le16 length;
u8 index;
u8 ct_window;
struct iwl_wipan_noa_descriptor descr0, descr1;
u8 reserved;
} __packed;
struct iwl_wipan_noa_notification {
u32 noa_active;
struct iwl_wipan_noa_attribute noa_attribute;
} __packed;
#endif /* __iwl_commands_h__ */