/******************************************************************************
*
* 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 - 2008 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:
* James P. Ketrenos <ipw2100-admin@linux.intel.com>
* Intel Corporation, 5200 N.E. Elam Young Parkway, Hillsboro, OR 97124-6497
*
* BSD LICENSE
*
* Copyright(c) 2005 - 2008 Intel Corporation. All rights reserved.
* All rights reserved.
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* modification, are permitted provided that the following conditions
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*
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* * 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
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*****************************************************************************/
/*
* Please use this file (iwl-4965-hw.h) only for hardware-related definitions.
* Use iwl-commands.h for uCode API definitions.
* Use iwl-dev.h for driver implementation definitions.
*/
#ifndef __iwl_4965_hw_h__
#define __iwl_4965_hw_h__
#include "iwl-fh.h"
/* EERPROM */
#define IWL4965_EEPROM_IMG_SIZE 1024
/*
* uCode queue management definitions ...
* Queue #4 is the command queue for 3945 and 4965; map it to Tx FIFO chnl 4.
* The first queue used for block-ack aggregation is #7 (4965 only).
* All block-ack aggregation queues should map to Tx DMA/FIFO channel 7.
*/
#define IWL_CMD_QUEUE_NUM 4
#define IWL_CMD_FIFO_NUM 4
#define IWL_BACK_QUEUE_FIRST_ID 7
/* Tx rates */
#define IWL_CCK_RATES 4
#define IWL_OFDM_RATES 8
#define IWL_HT_RATES 16
#define IWL_MAX_RATES (IWL_CCK_RATES+IWL_OFDM_RATES+IWL_HT_RATES)
/* Time constants */
#define SHORT_SLOT_TIME 9
#define LONG_SLOT_TIME 20
/* RSSI to dBm */
#define IWL_RSSI_OFFSET 44
#include "iwl-commands.h"
#define PCI_LINK_CTRL 0x0F0
#define PCI_POWER_SOURCE 0x0C8
#define PCI_REG_WUM8 0x0E8
#define PCI_CFG_PMC_PME_FROM_D3COLD_SUPPORT (0x80000000)
#define TFD_QUEUE_SIZE_MAX (256)
#define IWL_NUM_SCAN_RATES (2)
#define IWL_DEFAULT_TX_RETRY 15
#define RX_QUEUE_SIZE 256
#define RX_QUEUE_MASK 255
#define RX_QUEUE_SIZE_LOG 8
#define TFD_TX_CMD_SLOTS 256
#define TFD_CMD_SLOTS 32
/*
* RX related structures and functions
*/
#define RX_FREE_BUFFERS 64
#define RX_LOW_WATERMARK 8
/* Size of one Rx buffer in host DRAM */
#define IWL_RX_BUF_SIZE_4K (4 * 1024)
#define IWL_RX_BUF_SIZE_8K (8 * 1024)
/* Sizes and addresses for instruction and data memory (SRAM) in
* 4965's embedded processor. Driver access is via HBUS_TARG_MEM_* regs. */
#define RTC_INST_LOWER_BOUND (0x000000)
#define IWL49_RTC_INST_UPPER_BOUND (0x018000)
#define RTC_DATA_LOWER_BOUND (0x800000)
#define IWL49_RTC_DATA_UPPER_BOUND (0x80A000)
#define IWL49_RTC_INST_SIZE (IWL49_RTC_INST_UPPER_BOUND - RTC_INST_LOWER_BOUND)
#define IWL49_RTC_DATA_SIZE (IWL49_RTC_DATA_UPPER_BOUND - RTC_DATA_LOWER_BOUND)
#define IWL_MAX_INST_SIZE IWL49_RTC_INST_SIZE
#define IWL_MAX_DATA_SIZE IWL49_RTC_DATA_SIZE
/* Size of uCode instruction memory in bootstrap state machine */
#define IWL_MAX_BSM_SIZE BSM_SRAM_SIZE
static inline int iwl4965_hw_valid_rtc_data_addr(u32 addr)
{
return (addr >= RTC_DATA_LOWER_BOUND) &&
(addr < IWL49_RTC_DATA_UPPER_BOUND);
}
/********************* START TEMPERATURE *************************************/
/**
* 4965 temperature calculation.
*
* The driver must calculate the device temperature before calculating
* a txpower setting (amplifier gain is temperature dependent). The
* calculation uses 4 measurements, 3 of which (R1, R2, R3) are calibration
* values used for the life of the driver, and one of which (R4) is the
* real-time temperature indicator.
*
* uCode provides all 4 values to the driver via the "initialize alive"
* notification (see struct iwl4965_init_alive_resp). After the runtime uCode
* image loads, uCode updates the R4 value via statistics notifications
* (see STATISTICS_NOTIFICATION), which occur after each received beacon
* when associated, or can be requested via REPLY_STATISTICS_CMD.
*
* NOTE: uCode provides the R4 value as a 23-bit signed value. Driver
* must sign-extend to 32 bits before applying formula below.
*
* Formula:
*
* degrees Kelvin = ((97 * 259 * (R4 - R2) / (R3 - R1)) / 100) + 8
*
* NOTE: The basic formula is 259 * (R4-R2) / (R3-R1). The 97/100 is
* an additional correction, which should be centered around 0 degrees
* Celsius (273 degrees Kelvin). The 8 (3 percent of 273) compensates for
* centering the 97/100 correction around 0 degrees K.
*
* Add 273 to Kelvin value to find degrees Celsius, for comparing current
* temperature with factory-measured temperatures when calculating txpower
* settings.
*/
#define TEMPERATURE_CALIB_KELVIN_OFFSET 8
#define TEMPERATURE_CALIB_A_VAL 259
/* Limit range of calculated temperature to be between these Kelvin values */
#define IWL_TX_POWER_TEMPERATURE_MIN (263)
#define IWL_TX_POWER_TEMPERATURE_MAX (410)
#define IWL_TX_POWER_TEMPERATURE_OUT_OF_RANGE(t) \
(((t) < IWL_TX_POWER_TEMPERATURE_MIN) || \
((t) > IWL_TX_POWER_TEMPERATURE_MAX))
/********************* END TEMPERATURE ***************************************/
/********************* START TXPOWER *****************************************/
/**
* 4965 txpower calculations rely on information from three sources:
*
* 1) EEPROM
* 2) "initialize" alive notification
* 3) statistics notifications
*
* EEPROM data consists of:
*
* 1) Regulatory information (max txpower and channel usage flags) is provided
* separately for each channel that can possibly supported by 4965.
* 40 MHz wide (.11n fat) channels are listed separately from 20 MHz
* (legacy) channels.
*
* See struct iwl4965_eeprom_channel for format, and struct iwl4965_eeprom
* for locations in EEPROM.
*
* 2) Factory txpower calibration information is provided separately for
* sub-bands of contiguous channels. 2.4GHz has just one sub-band,
* but 5 GHz has several sub-bands.
*
* In addition, per-band (2.4 and 5 Ghz) saturation txpowers are provided.
*
* See struct iwl4965_eeprom_calib_info (and the tree of structures
* contained within it) for format, and struct iwl4965_eeprom for
* locations in EEPROM.
*
* "Initialization alive" notification (see struct iwl4965_init_alive_resp)
* consists of:
*
* 1) Temperature calculation parameters.
*
* 2) Power supply voltage measurement.
*
* 3) Tx gain compensation to balance 2 transmitters for MIMO use.
*
* Statistics notifications deliver:
*
* 1) Current values for temperature param R4.
*/
/**
* To calculate a txpower setting for a given desired target txpower, channel,
* modulation bit rate, and transmitter chain (4965 has 2 transmitters to
* support MIMO and transmit diversity), driver must do the following:
*
* 1) Compare desired txpower vs. (EEPROM) regulatory limit for this channel.
* Do not exceed regulatory limit; reduce target txpower if necessary.
*
* If setting up txpowers for MIMO rates (rate indexes 8-15, 24-31),
* 2 transmitters will be used simultaneously; driver must reduce the
* regulatory limit by 3 dB (half-power) for each transmitter, so the
* combined total output of the 2 transmitters is within regulatory limits.
*
*
* 2) Compare target txpower vs. (EEPROM) saturation txpower *reduced by
* backoff for this bit rate*. Do not exceed (saturation - backoff[rate]);
* reduce target txpower if necessary.
*
* Backoff values below are in 1/2 dB units (equivalent to steps in
* txpower gain tables):
*
* OFDM 6 - 36 MBit: 10 steps (5 dB)
* OFDM 48 MBit: 15 steps (7.5 dB)
* OFDM 54 MBit: 17 steps (8.5 dB)
* OFDM 60 MBit: 20 steps (10 dB)
* CCK all rates: 10 steps (5 dB)
*
* Backoff values apply to saturation txpower on a per-transmitter basis;
* when using MIMO (2 transmitters), each transmitter uses the same
* saturation level provided in EEPROM, and the same backoff values;
* no reduction (such as with regulatory txpower limits) is required.
*
* Saturation and Backoff values apply equally to 20 Mhz (legacy) channel
* widths and 40 Mhz (.11n fat) channel widths; there is no separate
* factory measurement for fat channels.
*
* The result of this step is the final target txpower. The rest of
* the steps figure out the proper settings for the device to achieve
* that target txpower.
*
*
* 3) Determine (EEPROM) calibration subband for the target channel, by
* comparing against first and last channels in each subband
* (see struct iwl4965_eeprom_calib_subband_info).
*
*
* 4) Linearly interpolate (EEPROM) factory calibration measurement sets,
* referencing the 2 factory-measured (sample) channels within the subband.
*
* Interpolation is based on difference between target channel's frequency
* and the sample channels' frequencies. Since channel numbers are based
* on frequency (5 MHz between each channel number), this is equivalent
* to interpolating based on channel number differences.
*
* Note that the sample channels may or may not be the channels at the
* edges of the subband. The target channel may be "outside" of the
* span of the sampled channels.
*
* Driver may choose the pair (for 2 Tx chains) of measurements (see
* struct iwl4965_eeprom_calib_ch_info) for which the actual measured
* txpower comes closest to the desired txpower. Usually, though,
* the middle set of measurements is closest to the regulatory limits,
* and is therefore a good choice for all txpower calculations (this
* assumes that high accuracy is needed for maximizing legal txpower,
* while lower txpower configurations do not need as much accuracy).
*
* Driver should interpolate both members of the chosen measurement pair,
* i.e. for both Tx chains (radio transmitters), unless the driver knows
* that only one of the chains will be used (e.g. only one tx antenna
* connected, but this should be unusual). The rate scaling algorithm
* switches antennas to find best performance, so both Tx chains will
* be used (although only one at a time) even for non-MIMO transmissions.
*
* Driver should interpolate factory values for temperature, gain table
* index, and actual power. The power amplifier detector values are
* not used by the driver.
*
* Sanity check: If the target channel happens to be one of the sample
* channels, the results should agree with the sample channel's
* measurements!
*
*
* 5) Find difference between desired txpower and (interpolated)
* factory-measured txpower. Using (interpolated) factory gain table index
* (shown elsewhere) as a starting point, adjust this index lower to
* increase txpower, or higher to decrease txpower, until the target
* txpower is reached. Each step in the gain table is 1/2 dB.
*
* For example, if factory measured txpower is 16 dBm, and target txpower
* is 13 dBm, add 6 steps to the factory gain index to reduce txpower
* by 3 dB.
*
*
* 6) Find difference between current device temperature and (interpolated)
* factory-measured temperature for sub-band. Factory values are in
* degrees Celsius. To calculate current temperature, see comments for
* "4965 temperature calculation".
*
* If current temperature is higher than factory temperature, driver must
* increase gain (lower gain table index), and vice versa.
*
* Temperature affects gain differently for different channels:
*
* 2.4 GHz all channels: 3.5 degrees per half-dB step
* 5 GHz channels 34-43: 4.5 degrees per half-dB step
* 5 GHz channels >= 44: 4.0 degrees per half-dB step
*
* NOTE: Temperature can increase rapidly when transmitting, especially
* with heavy traffic at high txpowers. Driver should update
* temperature calculations often under these conditions to
* maintain strong txpower in the face of rising temperature.
*
*
* 7) Find difference between current power supply voltage indicator
* (from "initialize alive") and factory-measured power supply voltage
* indicator (EEPROM).
*
* If the current voltage is higher (indicator is lower) than factory
* voltage, gain should be reduced (gain table index increased) by:
*
* (eeprom - current) / 7
*
* If the current voltage is lower (indicator is higher) than factory
* voltage, gain should be increased (gain table index decreased) by:
*
* 2 * (current - eeprom) / 7
*
* If number of index steps in either direction turns out to be > 2,
* something is wrong ... just use 0.
*
* NOTE: Voltage compensation is independent of band/channel.
*
* NOTE: "Initialize" uCode measures current voltage, which is assumed
* to be constant after this initial measurement. Voltage
* compensation for txpower (number of steps in gain table)
* may be calculated once and used until the next uCode bootload.
*
*
* 8) If setting up txpowers for MIMO rates (rate indexes 8-15, 24-31),
* adjust txpower for each transmitter chain, so txpower is balanced
* between the two chains. There are 5 pairs of tx_atten[group][chain]
* values in "initialize alive", one pair for each of 5 channel ranges:
*
* Group 0: 5 GHz channel 34-43
* Group 1: 5 GHz channel 44-70
* Group 2: 5 GHz channel 71-124
* Group 3: 5 GHz channel 125-200
* Group 4: 2.4 GHz all channels
*
* Add the tx_atten[group][chain] value to the index for the target chain.
* The values are signed, but are in pairs of 0 and a non-negative number,
* so as to reduce gain (if necessary) of the "hotter" channel. This
* avoids any need to double-check for regulatory compliance after
* this step.
*
*
* 9) If setting up for a CCK rate, lower the gain by adding a CCK compensation
* value to the index:
*
* Hardware rev B: 9 steps (4.5 dB)
* Hardware rev C: 5 steps (2.5 dB)
*
* Hardware rev for 4965 can be determined by reading CSR_HW_REV_WA_REG,
* bits [3:2], 1 = B, 2 = C.
*
* NOTE: This compensation is in addition to any saturation backoff that
* might have been applied in an earlier step.
*
*
* 10) Select the gain table, based on band (2.4 vs 5 GHz).
*
* Limit the adjusted index to stay within the table!
*
*
* 11) Read gain table entries for DSP and radio gain, place into appropriate
* location(s) in command (struct iwl4965_txpowertable_cmd).
*/
/* Limit range of txpower output target to be between these values */
#define IWL_TX_POWER_TARGET_POWER_MIN (0) /* 0 dBm = 1 milliwatt */
#define IWL_TX_POWER_TARGET_POWER_MAX (16) /* 16 dBm */
/**
* When MIMO is used (2 transmitters operating simultaneously), driver should
* limit each transmitter to deliver a max of 3 dB below the regulatory limit
* for the device. That is, use half power for each transmitter, so total
* txpower is within regulatory limits.
*
* The value "6" represents number of steps in gain table to reduce power 3 dB.
* Each step is 1/2 dB.
*/
#define IWL_TX_POWER_MIMO_REGULATORY_COMPENSATION (6)
/**
* CCK gain compensation.
*
* When calculating txpowers for CCK, after making sure that the target power
* is within regulatory and saturation limits, driver must additionally
* back off gain by adding these values to the gain table index.
*
* Hardware rev for 4965 can be determined by reading CSR_HW_REV_WA_REG,
* bits [3:2], 1 = B, 2 = C.
*/
#define IWL_TX_POWER_CCK_COMPENSATION_B_STEP (9)
#define IWL_TX_POWER_CCK_COMPENSATION_C_STEP (5)
/*
* 4965 power supply voltage compensation for txpower
*/
#define TX_POWER_IWL_VOLTAGE_CODES_PER_03V (7)
/**
* Gain tables.
*
* The following tables contain pair of values for setting txpower, i.e.
* gain settings for the output of the device's digital signal processor (DSP),
* and for the analog gain structure of the transmitter.
*
* Each entry in the gain tables represents a step of 1/2 dB. Note that these
* are *relative* steps, not indications of absolute output power. Output
* power varies with temperature, voltage, and channel frequency, and also
* requires consideration of average power (to satisfy regulatory constraints),
* and peak power (to avoid distortion of the output signal).
*
* Each entry contains two values:
* 1) DSP gain (or sometimes called DSP attenuation). This is a fine-grained
* linear value that multiplies the output of the digital signal processor,
* before being sent to the analog radio.
* 2) Radio gain. This sets the analog gain of the radio Tx path.
* It is a coarser setting, and behaves in a logarithmic (dB) fashion.
*
* EEPROM contains factory calibration data for txpower. This maps actual
* measured txpower levels to gain settings in the "well known" tables
* below ("well-known" means here that both factory calibration *and* the
* driver work with the same table).
*
* There are separate tables for 2.4 GHz and 5 GHz bands. The 5 GHz table
* has an extension (into negative indexes), in case the driver needs to
* boost power setting for high device temperatures (higher than would be
* present during factory calibration). A 5 Ghz EEPROM index of "40"
* corresponds to the 49th entry in the table used by the driver.
*/
#define MIN_TX_GAIN_INDEX (0) /* highest gain, lowest idx, 2.4 */
#define MIN_TX_GAIN_INDEX_52GHZ_EXT (-9) /* highest gain, lowest idx, 5 */
/**
* 2.4 GHz gain table
*
* Index Dsp gain Radio gain
* 0 110 0x3f (highest gain)
* 1 104 0x3f
* 2 98 0x3f
* 3 110 0x3e
* 4 104 0x3e
* 5 98 0x3e
* 6 110 0x3d
* 7 104 0x3d
* 8 98 0x3d
* 9 110 0x3c
* 10 104 0x3c
* 11 98 0x3c
* 12 110 0x3b
* 13 104 0x3b
* 14 98 0x3b
* 15 110 0x3a
* 16 104 0x3a
* 17 98 0x3a
* 18 110 0x39
* 19 104 0x39
* 20 98 0x39
* 21 110 0x38
* 22 104 0x38
* 23 98 0x38
* 24 110 0x37
* 25 104 0x37
* 26 98 0x37
* 27 110 0x36
* 28 104 0x36
* 29 98 0x36
* 30 110 0x35
* 31 104 0x35
* 32 98 0x35
* 33 110 0x34
* 34 104 0x34
* 35 98 0x34
* 36 110 0x33
* 37 104 0x33
* 38 98 0x33
* 39 110 0x32
* 40 104 0x32
* 41 98 0x32
* 42 110 0x31
* 43 104 0x31
* 44 98 0x31
* 45 110 0x30
* 46 104 0x30
* 47 98 0x30
* 48 110 0x6
* 49 104 0x6
* 50 98 0x6
* 51 110 0x5
* 52 104 0x5
* 53 98 0x5
* 54 110 0x4
* 55 104 0x4
* 56 98 0x4
* 57 110 0x3
* 58 104 0x3
* 59 98 0x3
* 60 110 0x2
* 61 104 0x2
* 62 98 0x2
* 63 110 0x1
* 64 104 0x1
* 65 98 0x1
* 66 110 0x0
* 67 104 0x0
* 68 98 0x0
* 69 97 0
* 70 96 0
* 71 95 0
* 72 94 0
* 73 93 0
* 74 92 0
* 75 91 0
* 76 90 0
* 77 89 0
* 78 88 0
* 79 87 0
* 80 86 0
* 81 85 0
* 82 84 0
* 83 83 0
* 84 82 0
* 85 81 0
* 86 80 0
* 87 79 0
* 88 78 0
* 89 77 0
* 90 76 0
* 91 75 0
* 92 74 0
* 93 73 0
* 94 72 0
* 95 71 0
* 96 70 0
* 97 69 0
* 98 68 0
*/
/**
* 5 GHz gain table
*
* Index Dsp gain Radio gain
* -9 123 0x3F (highest gain)
* -8 117 0x3F
* -7 110 0x3F
* -6 104 0x3F
* -5 98 0x3F
* -4 110 0x3E
* -3 104 0x3E
* -2 98 0x3E
* -1 110 0x3D
* 0 104 0x3D
* 1 98 0x3D
* 2 110 0x3C
* 3 104 0x3C
* 4 98 0x3C
* 5 110 0x3B
* 6 104 0x3B
* 7 98 0x3B
* 8 110 0x3A
* 9 104 0x3A
* 10 98 0x3A
* 11 110 0x39
* 12 104 0x39
* 13 98 0x39
* 14 110 0x38
* 15 104 0x38
* 16 98 0x38
* 17 110 0x37
* 18 104 0x37
* 19 98 0x37
* 20 110 0x36
* 21 104 0x36
* 22 98 0x36
* 23 110 0x35
* 24 104 0x35
* 25 98 0x35
* 26 110 0x34
* 27 104 0x34
* 28 98 0x34
* 29 110 0x33
* 30 104 0x33
* 31 98 0x33
* 32 110 0x32
* 33 104 0x32
* 34 98 0x32
* 35 110 0x31
* 36 104 0x31
* 37 98 0x31
* 38 110 0x30
* 39 104 0x30
* 40 98 0x30
* 41 110 0x25
* 42 104 0x25
* 43 98 0x25
* 44 110 0x24
* 45 104 0x24
* 46 98 0x24
* 47 110 0x23
* 48 104 0x23
* 49 98 0x23
* 50 110 0x22
* 51 104 0x18
* 52 98 0x18
* 53 110 0x17
* 54 104 0x17
* 55 98 0x17
* 56 110 0x16
* 57 104 0x16
* 58 98 0x16
* 59 110 0x15
* 60 104 0x15
* 61 98 0x15
* 62 110 0x14
* 63 104 0x14
* 64 98 0x14
* 65 110 0x13
* 66 104 0x13
* 67 98 0x13
* 68 110 0x12
* 69 104 0x08
* 70 98 0x08
* 71 110 0x07
* 72 104 0x07
* 73 98 0x07
* 74 110 0x06
* 75 104 0x06
* 76 98 0x06
* 77 110 0x05
* 78 104 0x05
* 79 98 0x05
* 80 110 0x04
* 81 104 0x04
* 82 98 0x04
* 83 110 0x03
* 84 104 0x03
* 85 98 0x03
* 86 110 0x02
* 87 104 0x02
* 88 98 0x02
* 89 110 0x01
* 90 104 0x01
* 91 98 0x01
* 92 110 0x00
* 93 104 0x00
* 94 98 0x00
* 95 93 0x00
* 96 88 0x00
* 97 83 0x00
* 98 78 0x00
*/
/**
* Sanity checks and default values for EEPROM regulatory levels.
* If EEPROM values fall outside MIN/MAX range, use default values.
*
* Regulatory limits refer to the maximum average txpower allowed by
* regulatory agencies in the geographies in which the device is meant
* to be operated. These limits are SKU-specific (i.e. geography-specific),
* and channel-specific; each channel has an individual regulatory limit
* listed in the EEPROM.
*
* Units are in half-dBm (i.e. "34" means 17 dBm).
*/
#define IWL_TX_POWER_DEFAULT_REGULATORY_24 (34)
#define IWL_TX_POWER_DEFAULT_REGULATORY_52 (34)
#define IWL_TX_POWER_REGULATORY_MIN (0)
#define IWL_TX_POWER_REGULATORY_MAX (34)
/**
* Sanity checks and default values for EEPROM saturation levels.
* If EEPROM values fall outside MIN/MAX range, use default values.
*
* Saturation is the highest level that the output power amplifier can produce
* without significant clipping distortion. This is a "peak" power level.
* Different types of modulation (i.e. various "rates", and OFDM vs. CCK)
* require differing amounts of backoff, relative to their average power output,
* in order to avoid clipping distortion.
*
* Driver must make sure that it is violating neither the saturation limit,
* nor the regulatory limit, when calculating Tx power settings for various
* rates.
*
* Units are in half-dBm (i.e. "38" means 19 dBm).
*/
#define IWL_TX_POWER_DEFAULT_SATURATION_24 (38)
#define IWL_TX_POWER_DEFAULT_SATURATION_52 (38)
#define IWL_TX_POWER_SATURATION_MIN (20)
#define IWL_TX_POWER_SATURATION_MAX (50)
/**
* Channel groups used for Tx Attenuation calibration (MIMO tx channel balance)
* and thermal Txpower calibration.
*
* When calculating txpower, driver must compensate for current device
* temperature; higher temperature requires higher gain. Driver must calculate
* current temperature (see "4965 temperature calculation"), then compare vs.
* factory calibration temperature in EEPROM; if current temperature is higher
* than factory temperature, driver must *increase* gain by proportions shown
* in table below. If current temperature is lower than factory, driver must
* *decrease* gain.
*
* Different frequency ranges require different compensation, as shown below.
*/
/* Group 0, 5.2 GHz ch 34-43: 4.5 degrees per 1/2 dB. */
#define CALIB_IWL_TX_ATTEN_GR1_FCH 34
#define CALIB_IWL_TX_ATTEN_GR1_LCH 43
/* Group 1, 5.3 GHz ch 44-70: 4.0 degrees per 1/2 dB. */
#define CALIB_IWL_TX_ATTEN_GR2_FCH 44
#define CALIB_IWL_TX_ATTEN_GR2_LCH 70
/* Group 2, 5.5 GHz ch 71-124: 4.0 degrees per 1/2 dB. */
#define CALIB_IWL_TX_ATTEN_GR3_FCH 71
#define CALIB_IWL_TX_ATTEN_GR3_LCH 124
/* Group 3, 5.7 GHz ch 125-200: 4.0 degrees per 1/2 dB. */
#define CALIB_IWL_TX_ATTEN_GR4_FCH 125
#define CALIB_IWL_TX_ATTEN_GR4_LCH 200
/* Group 4, 2.4 GHz all channels: 3.5 degrees per 1/2 dB. */
#define CALIB_IWL_TX_ATTEN_GR5_FCH 1
#define CALIB_IWL_TX_ATTEN_GR5_LCH 20
enum {
CALIB_CH_GROUP_1 = 0,
CALIB_CH_GROUP_2 = 1,
CALIB_CH_GROUP_3 = 2,
CALIB_CH_GROUP_4 = 3,
CALIB_CH_GROUP_5 = 4,
CALIB_CH_GROUP_MAX
};
/********************* END TXPOWER *****************************************/
static inline u8 iwl4965_hw_get_rate(__le32 rate_n_flags)
{
return le32_to_cpu(rate_n_flags) & 0xFF;
}
static inline u32 iwl4965_hw_get_rate_n_flags(__le32 rate_n_flags)
{
return le32_to_cpu(rate_n_flags) & 0x1FFFF;
}
static inline __le32 iwl4965_hw_set_rate_n_flags(u8 rate, u16 flags)
{
return cpu_to_le32(flags|(u16)rate);
}
/**
* Tx/Rx Queues
*
* Most communication between driver and 4965 is via queues of data buffers.
* For example, all commands that the driver issues to device's embedded
* controller (uCode) are via the command queue (one of the Tx queues). All
* uCode command responses/replies/notifications, including Rx frames, are
* conveyed from uCode to driver via the Rx queue.
*
* Most support for these queues, including handshake support, resides in
* structures in host DRAM, shared between the driver and the device. When
* allocating this memory, the driver must make sure that data written by
* the host CPU updates DRAM immediately (and does not get "stuck" in CPU's
* cache memory), so DRAM and cache are consistent, and the device can
* immediately see changes made by the driver.
*
* 4965 supports up to 16 DRAM-based Tx queues, and services these queues via
* up to 7 DMA channels (FIFOs). Each Tx queue is supported by a circular array
* in DRAM containing 256 Transmit Frame Descriptors (TFDs).
*/
#define IWL49_MAX_WIN_SIZE 64
#define IWL49_QUEUE_SIZE 256
#define IWL49_NUM_FIFOS 7
#define IWL49_CMD_FIFO_NUM 4
#define IWL49_NUM_QUEUES 16
/**
* struct iwl_tfd_frame_data
*
* Describes up to 2 buffers containing (contiguous) portions of a Tx frame.
* Each buffer must be on dword boundary.
* Up to 10 iwl_tfd_frame_data structures, describing up to 20 buffers,
* may be filled within a TFD (iwl_tfd_frame).
*
* Bit fields in tb1_addr:
* 31- 0: Tx buffer 1 address bits [31:0]
*
* Bit fields in val1:
* 31-16: Tx buffer 2 address bits [15:0]
* 15- 4: Tx buffer 1 length (bytes)
* 3- 0: Tx buffer 1 address bits [32:32]
*
* Bit fields in val2:
* 31-20: Tx buffer 2 length (bytes)
* 19- 0: Tx buffer 2 address bits [35:16]
*/
struct iwl_tfd_frame_data {
__le32 tb1_addr;
__le32 val1;
/* __le32 ptb1_32_35:4; */
#define IWL_tb1_addr_hi_POS 0
#define IWL_tb1_addr_hi_LEN 4
#define IWL_tb1_addr_hi_SYM val1
/* __le32 tb_len1:12; */
#define IWL_tb1_len_POS 4
#define IWL_tb1_len_LEN 12
#define IWL_tb1_len_SYM val1
/* __le32 ptb2_0_15:16; */
#define IWL_tb2_addr_lo16_POS 16
#define IWL_tb2_addr_lo16_LEN 16
#define IWL_tb2_addr_lo16_SYM val1
__le32 val2;
/* __le32 ptb2_16_35:20; */
#define IWL_tb2_addr_hi20_POS 0
#define IWL_tb2_addr_hi20_LEN 20
#define IWL_tb2_addr_hi20_SYM val2
/* __le32 tb_len2:12; */
#define IWL_tb2_len_POS 20
#define IWL_tb2_len_LEN 12
#define IWL_tb2_len_SYM val2
} __attribute__ ((packed));
/**
* struct iwl_tfd_frame
*
* Transmit Frame Descriptor (TFD)
*
* 4965 supports up to 16 Tx queues resident in host DRAM.
* Each Tx queue uses a circular buffer of 256 TFDs stored in host DRAM.
* Both driver and device share these circular buffers, each of which must be
* contiguous 256 TFDs x 128 bytes-per-TFD = 32 KBytes for 4965.
*
* Driver must indicate the physical address of the base of each
* circular buffer via the 4965's FH_MEM_CBBC_QUEUE registers.
*
* Each TFD contains pointer/size information for up to 20 data buffers
* in host DRAM. These buffers collectively contain the (one) frame described
* by the TFD. Each buffer must be a single contiguous block of memory within
* itself, but buffers may be scattered in host DRAM. Each buffer has max size
* of (4K - 4). The 4965 concatenates all of a TFD's buffers into a single
* Tx frame, up to 8 KBytes in size.
*
* Bit fields in the control dword (val0):
* 31-30: # dwords (0-3) of padding required at end of frame for 16-byte bound
* 29: reserved
* 28-24: # Transmit Buffer Descriptors in TFD
* 23- 0: reserved
*
* A maximum of 255 (not 256!) TFDs may be on a queue waiting for Tx.
*/
struct iwl_tfd_frame {
__le32 val0;
/* __le32 rsvd1:24; */
/* __le32 num_tbs:5; */
#define IWL_num_tbs_POS 24
#define IWL_num_tbs_LEN 5
#define IWL_num_tbs_SYM val0
/* __le32 rsvd2:1; */
/* __le32 padding:2; */
struct iwl_tfd_frame_data pa[10];
__le32 reserved;
} __attribute__ ((packed));
/**
* struct iwl4965_queue_byte_cnt_entry
*
* Byte Count Table Entry
*
* Bit fields:
* 15-12: reserved
* 11- 0: total to-be-transmitted byte count of frame (does not include command)
*/
struct iwl4965_queue_byte_cnt_entry {
__le16 val;
/* __le16 byte_cnt:12; */
#define IWL_byte_cnt_POS 0
#define IWL_byte_cnt_LEN 12
#define IWL_byte_cnt_SYM val
/* __le16 rsvd:4; */
} __attribute__ ((packed));
/**
* struct iwl4965_sched_queue_byte_cnt_tbl
*
* Byte Count table
*
* Each Tx queue uses a byte-count table containing 320 entries:
* one 16-bit entry for each of 256 TFDs, plus an additional 64 entries that
* duplicate the first 64 entries (to avoid wrap-around within a Tx window;
* max Tx window is 64 TFDs).
*
* When driver sets up a new TFD, it must also enter the total byte count
* of the frame to be transmitted into the corresponding entry in the byte
* count table for the chosen Tx queue. If the TFD index is 0-63, the driver
* must duplicate the byte count entry in corresponding index 256-319.
*
* "dont_care" padding puts each byte count table on a 1024-byte boundary;
* 4965 assumes tables are separated by 1024 bytes.
*/
struct iwl4965_sched_queue_byte_cnt_tbl {
struct iwl4965_queue_byte_cnt_entry tfd_offset[IWL49_QUEUE_SIZE +
IWL49_MAX_WIN_SIZE];
u8 dont_care[1024 -
(IWL49_QUEUE_SIZE + IWL49_MAX_WIN_SIZE) *
sizeof(__le16)];
} __attribute__ ((packed));
/**
* struct iwl4965_shared - handshake area for Tx and Rx
*
* For convenience in allocating memory, this structure combines 2 areas of
* DRAM which must be shared between driver and 4965. These do not need to
* be combined, if better allocation would result from keeping them separate:
*
* 1) The Tx byte count tables occupy 1024 bytes each (16 KBytes total for
* 16 queues). Driver uses SCD_DRAM_BASE_ADDR to tell 4965 where to find
* the first of these tables. 4965 assumes tables are 1024 bytes apart.
*
* 2) The Rx status (val0 and val1) occupies only 8 bytes. Driver uses
* FH_RSCSR_CHNL0_STTS_WPTR_REG to tell 4965 where to find this area.
* Driver reads val0 to determine the latest Receive Buffer Descriptor (RBD)
* that has been filled by the 4965.
*
* Bit fields val0:
* 31-12: Not used
* 11- 0: Index of last filled Rx buffer descriptor (4965 writes, driver reads)
*
* Bit fields val1:
* 31- 0: Not used
*/
struct iwl4965_shared {
struct iwl4965_sched_queue_byte_cnt_tbl
queues_byte_cnt_tbls[IWL49_NUM_QUEUES];
__le32 rb_closed;
/* __le32 rb_closed_stts_rb_num:12; */
#define IWL_rb_closed_stts_rb_num_POS 0
#define IWL_rb_closed_stts_rb_num_LEN 12
#define IWL_rb_closed_stts_rb_num_SYM rb_closed
/* __le32 rsrv1:4; */
/* __le32 rb_closed_stts_rx_frame_num:12; */
#define IWL_rb_closed_stts_rx_frame_num_POS 16
#define IWL_rb_closed_stts_rx_frame_num_LEN 12
#define IWL_rb_closed_stts_rx_frame_num_SYM rb_closed
/* __le32 rsrv2:4; */
__le32 frm_finished;
/* __le32 frame_finished_stts_rb_num:12; */
#define IWL_frame_finished_stts_rb_num_POS 0
#define IWL_frame_finished_stts_rb_num_LEN 12
#define IWL_frame_finished_stts_rb_num_SYM frm_finished
/* __le32 rsrv3:4; */
/* __le32 frame_finished_stts_rx_frame_num:12; */
#define IWL_frame_finished_stts_rx_frame_num_POS 16
#define IWL_frame_finished_stts_rx_frame_num_LEN 12
#define IWL_frame_finished_stts_rx_frame_num_SYM frm_finished
/* __le32 rsrv4:4; */
__le32 padding1; /* so that allocation will be aligned to 16B */
__le32 padding2;
} __attribute__ ((packed));
#endif /* __iwl4965_4965_hw_h__ */