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kunit / linux / c32324e31270514638d6d2df38436590862e0d8f / . / drivers / staging / brcm80211 / brcmsmac / srom.c
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/*
* Copyright (c) 2010 Broadcom Corporation
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
* SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION
* OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
* CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
#include <linux/kernel.h>
#include <linux/string.h>
#include <linux/io.h>
#include <linux/etherdevice.h>
#include <stdarg.h>
#include <chipcommon.h>
#include <brcmu_utils.h>
#include "nicpci.h"
#include "aiutils.h"
#include "otp.h"
#include "srom.h"
#define SROM_OFFSET(sih) ((sih->ccrev > 31) ? \
(((sih->cccaps & CC_CAP_SROM) == 0) ? NULL : \
((u8 *)curmap + PCI_16KB0_CCREGS_OFFSET + CC_SROM_OTP)) : \
((u8 *)curmap + PCI_BAR0_SPROM_OFFSET))
#if defined(BCMDBG)
#define WRITE_ENABLE_DELAY 500 /* 500 ms after write enable/disable toggle */
#define WRITE_WORD_DELAY 20 /* 20 ms between each word write */
#endif
/* Maximum srom: 6 Kilobits == 768 bytes */
#define SROM_MAX 768
/* PCI fields */
#define PCI_F0DEVID 48
#define SROM_WORDS 64
#define SROM_SSID 2
#define SROM_WL1LHMAXP 29
#define SROM_WL1LPAB0 30
#define SROM_WL1LPAB1 31
#define SROM_WL1LPAB2 32
#define SROM_WL1HPAB0 33
#define SROM_WL1HPAB1 34
#define SROM_WL1HPAB2 35
#define SROM_MACHI_IL0 36
#define SROM_MACMID_IL0 37
#define SROM_MACLO_IL0 38
#define SROM_MACHI_ET1 42
#define SROM_MACMID_ET1 43
#define SROM_MACLO_ET1 44
#define SROM3_MACHI 37
#define SROM3_MACMID 38
#define SROM3_MACLO 39
#define SROM_BXARSSI2G 40
#define SROM_BXARSSI5G 41
#define SROM_TRI52G 42
#define SROM_TRI5GHL 43
#define SROM_RXPO52G 45
#define SROM_AABREV 46
/* Fields in AABREV */
#define SROM_BR_MASK 0x00ff
#define SROM_CC_MASK 0x0f00
#define SROM_CC_SHIFT 8
#define SROM_AA0_MASK 0x3000
#define SROM_AA0_SHIFT 12
#define SROM_AA1_MASK 0xc000
#define SROM_AA1_SHIFT 14
#define SROM_WL0PAB0 47
#define SROM_WL0PAB1 48
#define SROM_WL0PAB2 49
#define SROM_LEDBH10 50
#define SROM_LEDBH32 51
#define SROM_WL10MAXP 52
#define SROM_WL1PAB0 53
#define SROM_WL1PAB1 54
#define SROM_WL1PAB2 55
#define SROM_ITT 56
#define SROM_BFL 57
#define SROM_BFL2 28
#define SROM3_BFL2 61
#define SROM_AG10 58
#define SROM_CCODE 59
#define SROM_OPO 60
#define SROM3_LEDDC 62
#define SROM_CRCREV 63
/* SROM Rev 4: Reallocate the software part of the srom to accommodate
* MIMO features. It assumes up to two PCIE functions and 440 bytes
* of usable srom i.e. the usable storage in chips with OTP that
* implements hardware redundancy.
*/
#define SROM4_WORDS 220
#define SROM4_SIGN 32
#define SROM4_SIGNATURE 0x5372
#define SROM4_BREV 33
#define SROM4_BFL0 34
#define SROM4_BFL1 35
#define SROM4_BFL2 36
#define SROM4_BFL3 37
#define SROM5_BFL0 37
#define SROM5_BFL1 38
#define SROM5_BFL2 39
#define SROM5_BFL3 40
#define SROM4_MACHI 38
#define SROM4_MACMID 39
#define SROM4_MACLO 40
#define SROM5_MACHI 41
#define SROM5_MACMID 42
#define SROM5_MACLO 43
#define SROM4_CCODE 41
#define SROM4_REGREV 42
#define SROM5_CCODE 34
#define SROM5_REGREV 35
#define SROM4_LEDBH10 43
#define SROM4_LEDBH32 44
#define SROM5_LEDBH10 59
#define SROM5_LEDBH32 60
#define SROM4_LEDDC 45
#define SROM5_LEDDC 45
#define SROM4_AA 46
#define SROM4_AG10 47
#define SROM4_AG32 48
#define SROM4_TXPID2G 49
#define SROM4_TXPID5G 51
#define SROM4_TXPID5GL 53
#define SROM4_TXPID5GH 55
#define SROM4_TXRXC 61
#define SROM4_TXCHAIN_MASK 0x000f
#define SROM4_TXCHAIN_SHIFT 0
#define SROM4_RXCHAIN_MASK 0x00f0
#define SROM4_RXCHAIN_SHIFT 4
#define SROM4_SWITCH_MASK 0xff00
#define SROM4_SWITCH_SHIFT 8
/* Per-path fields */
#define MAX_PATH_SROM 4
#define SROM4_PATH0 64
#define SROM4_PATH1 87
#define SROM4_PATH2 110
#define SROM4_PATH3 133
#define SROM4_2G_ITT_MAXP 0
#define SROM4_2G_PA 1
#define SROM4_5G_ITT_MAXP 5
#define SROM4_5GLH_MAXP 6
#define SROM4_5G_PA 7
#define SROM4_5GL_PA 11
#define SROM4_5GH_PA 15
/* All the miriad power offsets */
#define SROM4_2G_CCKPO 156
#define SROM4_2G_OFDMPO 157
#define SROM4_5G_OFDMPO 159
#define SROM4_5GL_OFDMPO 161
#define SROM4_5GH_OFDMPO 163
#define SROM4_2G_MCSPO 165
#define SROM4_5G_MCSPO 173
#define SROM4_5GL_MCSPO 181
#define SROM4_5GH_MCSPO 189
#define SROM4_CDDPO 197
#define SROM4_STBCPO 198
#define SROM4_BW40PO 199
#define SROM4_BWDUPPO 200
#define SROM4_CRCREV 219
/* SROM Rev 8: Make space for a 48word hardware header for PCIe rev >= 6.
* This is acombined srom for both MIMO and SISO boards, usable in
* the .130 4Kilobit OTP with hardware redundancy.
*/
#define SROM8_BREV 65
#define SROM8_BFL0 66
#define SROM8_BFL1 67
#define SROM8_BFL2 68
#define SROM8_BFL3 69
#define SROM8_MACHI 70
#define SROM8_MACMID 71
#define SROM8_MACLO 72
#define SROM8_CCODE 73
#define SROM8_REGREV 74
#define SROM8_LEDBH10 75
#define SROM8_LEDBH32 76
#define SROM8_LEDDC 77
#define SROM8_AA 78
#define SROM8_AG10 79
#define SROM8_AG32 80
#define SROM8_TXRXC 81
#define SROM8_BXARSSI2G 82
#define SROM8_BXARSSI5G 83
#define SROM8_TRI52G 84
#define SROM8_TRI5GHL 85
#define SROM8_RXPO52G 86
#define SROM8_FEM2G 87
#define SROM8_FEM5G 88
#define SROM8_FEM_ANTSWLUT_MASK 0xf800
#define SROM8_FEM_ANTSWLUT_SHIFT 11
#define SROM8_FEM_TR_ISO_MASK 0x0700
#define SROM8_FEM_TR_ISO_SHIFT 8
#define SROM8_FEM_PDET_RANGE_MASK 0x00f8
#define SROM8_FEM_PDET_RANGE_SHIFT 3
#define SROM8_FEM_EXTPA_GAIN_MASK 0x0006
#define SROM8_FEM_EXTPA_GAIN_SHIFT 1
#define SROM8_FEM_TSSIPOS_MASK 0x0001
#define SROM8_FEM_TSSIPOS_SHIFT 0
#define SROM8_THERMAL 89
/* Temp sense related entries */
#define SROM8_MPWR_RAWTS 90
#define SROM8_TS_SLP_OPT_CORRX 91
/* FOC: freiquency offset correction, HWIQ: H/W IOCAL enable, IQSWP: IQ CAL swap disable */
#define SROM8_FOC_HWIQ_IQSWP 92
/* Temperature delta for PHY calibration */
#define SROM8_PHYCAL_TEMPDELTA 93
/* Per-path offsets & fields */
#define SROM8_PATH0 96
#define SROM8_PATH1 112
#define SROM8_PATH2 128
#define SROM8_PATH3 144
#define SROM8_2G_ITT_MAXP 0
#define SROM8_2G_PA 1
#define SROM8_5G_ITT_MAXP 4
#define SROM8_5GLH_MAXP 5
#define SROM8_5G_PA 6
#define SROM8_5GL_PA 9
#define SROM8_5GH_PA 12
/* All the miriad power offsets */
#define SROM8_2G_CCKPO 160
#define SROM8_2G_OFDMPO 161
#define SROM8_5G_OFDMPO 163
#define SROM8_5GL_OFDMPO 165
#define SROM8_5GH_OFDMPO 167
#define SROM8_2G_MCSPO 169
#define SROM8_5G_MCSPO 177
#define SROM8_5GL_MCSPO 185
#define SROM8_5GH_MCSPO 193
#define SROM8_CDDPO 201
#define SROM8_STBCPO 202
#define SROM8_BW40PO 203
#define SROM8_BWDUPPO 204
/* SISO PA parameters are in the path0 spaces */
#define SROM8_SISO 96
/* Legacy names for SISO PA paramters */
#define SROM8_W0_ITTMAXP (SROM8_SISO + SROM8_2G_ITT_MAXP)
#define SROM8_W0_PAB0 (SROM8_SISO + SROM8_2G_PA)
#define SROM8_W0_PAB1 (SROM8_SISO + SROM8_2G_PA + 1)
#define SROM8_W0_PAB2 (SROM8_SISO + SROM8_2G_PA + 2)
#define SROM8_W1_ITTMAXP (SROM8_SISO + SROM8_5G_ITT_MAXP)
#define SROM8_W1_MAXP_LCHC (SROM8_SISO + SROM8_5GLH_MAXP)
#define SROM8_W1_PAB0 (SROM8_SISO + SROM8_5G_PA)
#define SROM8_W1_PAB1 (SROM8_SISO + SROM8_5G_PA + 1)
#define SROM8_W1_PAB2 (SROM8_SISO + SROM8_5G_PA + 2)
#define SROM8_W1_PAB0_LC (SROM8_SISO + SROM8_5GL_PA)
#define SROM8_W1_PAB1_LC (SROM8_SISO + SROM8_5GL_PA + 1)
#define SROM8_W1_PAB2_LC (SROM8_SISO + SROM8_5GL_PA + 2)
#define SROM8_W1_PAB0_HC (SROM8_SISO + SROM8_5GH_PA)
#define SROM8_W1_PAB1_HC (SROM8_SISO + SROM8_5GH_PA + 1)
#define SROM8_W1_PAB2_HC (SROM8_SISO + SROM8_5GH_PA + 2)
/* SROM REV 9 */
#define SROM9_2GPO_CCKBW20 160
#define SROM9_2GPO_CCKBW20UL 161
#define SROM9_2GPO_LOFDMBW20 162
#define SROM9_2GPO_LOFDMBW20UL 164
#define SROM9_5GLPO_LOFDMBW20 166
#define SROM9_5GLPO_LOFDMBW20UL 168
#define SROM9_5GMPO_LOFDMBW20 170
#define SROM9_5GMPO_LOFDMBW20UL 172
#define SROM9_5GHPO_LOFDMBW20 174
#define SROM9_5GHPO_LOFDMBW20UL 176
#define SROM9_2GPO_MCSBW20 178
#define SROM9_2GPO_MCSBW20UL 180
#define SROM9_2GPO_MCSBW40 182
#define SROM9_5GLPO_MCSBW20 184
#define SROM9_5GLPO_MCSBW20UL 186
#define SROM9_5GLPO_MCSBW40 188
#define SROM9_5GMPO_MCSBW20 190
#define SROM9_5GMPO_MCSBW20UL 192
#define SROM9_5GMPO_MCSBW40 194
#define SROM9_5GHPO_MCSBW20 196
#define SROM9_5GHPO_MCSBW20UL 198
#define SROM9_5GHPO_MCSBW40 200
#define SROM9_PO_MCS32 202
#define SROM9_PO_LOFDM40DUP 203
/* SROM flags (see sromvar_t) */
#define SRFL_MORE 1 /* value continues as described by the next entry */
#define SRFL_NOFFS 2 /* value bits can't be all one's */
#define SRFL_PRHEX 4 /* value is in hexdecimal format */
#define SRFL_PRSIGN 8 /* value is in signed decimal format */
#define SRFL_CCODE 0x10 /* value is in country code format */
#define SRFL_ETHADDR 0x20 /* value is an Ethernet address */
#define SRFL_LEDDC 0x40 /* value is an LED duty cycle */
#define SRFL_NOVAR 0x80 /* do not generate a nvram param, entry is for mfgc */
/* Max. nvram variable table size */
#define MAXSZ_NVRAM_VARS 4096
struct brcms_sromvar {
const char *name;
u32 revmask;
u32 flags;
u16 off;
u16 mask;
};
struct brcms_varbuf {
char *base; /* pointer to buffer base */
char *buf; /* pointer to current position */
unsigned int size; /* current (residual) size in bytes */
};
/* Assumptions:
* - Ethernet address spans across 3 consective words
*
* Table rules:
* - Add multiple entries next to each other if a value spans across multiple words
* (even multiple fields in the same word) with each entry except the last having
* it's SRFL_MORE bit set.
* - Ethernet address entry does not follow above rule and must not have SRFL_MORE
* bit set. Its SRFL_ETHADDR bit implies it takes multiple words.
* - The last entry's name field must be NULL to indicate the end of the table. Other
* entries must have non-NULL name.
*/
static const struct brcms_sromvar pci_sromvars[] = {
{"devid", 0xffffff00, SRFL_PRHEX | SRFL_NOVAR, PCI_F0DEVID, 0xffff},
{"boardrev", 0x0000000e, SRFL_PRHEX, SROM_AABREV, SROM_BR_MASK},
{"boardrev", 0x000000f0, SRFL_PRHEX, SROM4_BREV, 0xffff},
{"boardrev", 0xffffff00, SRFL_PRHEX, SROM8_BREV, 0xffff},
{"boardflags", 0x00000002, SRFL_PRHEX, SROM_BFL, 0xffff},
{"boardflags", 0x00000004, SRFL_PRHEX | SRFL_MORE, SROM_BFL, 0xffff},
{"", 0, 0, SROM_BFL2, 0xffff},
{"boardflags", 0x00000008, SRFL_PRHEX | SRFL_MORE, SROM_BFL, 0xffff},
{"", 0, 0, SROM3_BFL2, 0xffff},
{"boardflags", 0x00000010, SRFL_PRHEX | SRFL_MORE, SROM4_BFL0, 0xffff},
{"", 0, 0, SROM4_BFL1, 0xffff},
{"boardflags", 0x000000e0, SRFL_PRHEX | SRFL_MORE, SROM5_BFL0, 0xffff},
{"", 0, 0, SROM5_BFL1, 0xffff},
{"boardflags", 0xffffff00, SRFL_PRHEX | SRFL_MORE, SROM8_BFL0, 0xffff},
{"", 0, 0, SROM8_BFL1, 0xffff},
{"boardflags2", 0x00000010, SRFL_PRHEX | SRFL_MORE, SROM4_BFL2, 0xffff},
{"", 0, 0, SROM4_BFL3, 0xffff},
{"boardflags2", 0x000000e0, SRFL_PRHEX | SRFL_MORE, SROM5_BFL2, 0xffff},
{"", 0, 0, SROM5_BFL3, 0xffff},
{"boardflags2", 0xffffff00, SRFL_PRHEX | SRFL_MORE, SROM8_BFL2, 0xffff},
{"", 0, 0, SROM8_BFL3, 0xffff},
{"boardtype", 0xfffffffc, SRFL_PRHEX, SROM_SSID, 0xffff},
{"boardnum", 0x00000006, 0, SROM_MACLO_IL0, 0xffff},
{"boardnum", 0x00000008, 0, SROM3_MACLO, 0xffff},
{"boardnum", 0x00000010, 0, SROM4_MACLO, 0xffff},
{"boardnum", 0x000000e0, 0, SROM5_MACLO, 0xffff},
{"boardnum", 0xffffff00, 0, SROM8_MACLO, 0xffff},
{"cc", 0x00000002, 0, SROM_AABREV, SROM_CC_MASK},
{"regrev", 0x00000008, 0, SROM_OPO, 0xff00},
{"regrev", 0x00000010, 0, SROM4_REGREV, 0x00ff},
{"regrev", 0x000000e0, 0, SROM5_REGREV, 0x00ff},
{"regrev", 0xffffff00, 0, SROM8_REGREV, 0x00ff},
{"ledbh0", 0x0000000e, SRFL_NOFFS, SROM_LEDBH10, 0x00ff},
{"ledbh1", 0x0000000e, SRFL_NOFFS, SROM_LEDBH10, 0xff00},
{"ledbh2", 0x0000000e, SRFL_NOFFS, SROM_LEDBH32, 0x00ff},
{"ledbh3", 0x0000000e, SRFL_NOFFS, SROM_LEDBH32, 0xff00},
{"ledbh0", 0x00000010, SRFL_NOFFS, SROM4_LEDBH10, 0x00ff},
{"ledbh1", 0x00000010, SRFL_NOFFS, SROM4_LEDBH10, 0xff00},
{"ledbh2", 0x00000010, SRFL_NOFFS, SROM4_LEDBH32, 0x00ff},
{"ledbh3", 0x00000010, SRFL_NOFFS, SROM4_LEDBH32, 0xff00},
{"ledbh0", 0x000000e0, SRFL_NOFFS, SROM5_LEDBH10, 0x00ff},
{"ledbh1", 0x000000e0, SRFL_NOFFS, SROM5_LEDBH10, 0xff00},
{"ledbh2", 0x000000e0, SRFL_NOFFS, SROM5_LEDBH32, 0x00ff},
{"ledbh3", 0x000000e0, SRFL_NOFFS, SROM5_LEDBH32, 0xff00},
{"ledbh0", 0xffffff00, SRFL_NOFFS, SROM8_LEDBH10, 0x00ff},
{"ledbh1", 0xffffff00, SRFL_NOFFS, SROM8_LEDBH10, 0xff00},
{"ledbh2", 0xffffff00, SRFL_NOFFS, SROM8_LEDBH32, 0x00ff},
{"ledbh3", 0xffffff00, SRFL_NOFFS, SROM8_LEDBH32, 0xff00},
{"pa0b0", 0x0000000e, SRFL_PRHEX, SROM_WL0PAB0, 0xffff},
{"pa0b1", 0x0000000e, SRFL_PRHEX, SROM_WL0PAB1, 0xffff},
{"pa0b2", 0x0000000e, SRFL_PRHEX, SROM_WL0PAB2, 0xffff},
{"pa0itssit", 0x0000000e, 0, SROM_ITT, 0x00ff},
{"pa0maxpwr", 0x0000000e, 0, SROM_WL10MAXP, 0x00ff},
{"pa0b0", 0xffffff00, SRFL_PRHEX, SROM8_W0_PAB0, 0xffff},
{"pa0b1", 0xffffff00, SRFL_PRHEX, SROM8_W0_PAB1, 0xffff},
{"pa0b2", 0xffffff00, SRFL_PRHEX, SROM8_W0_PAB2, 0xffff},
{"pa0itssit", 0xffffff00, 0, SROM8_W0_ITTMAXP, 0xff00},
{"pa0maxpwr", 0xffffff00, 0, SROM8_W0_ITTMAXP, 0x00ff},
{"opo", 0x0000000c, 0, SROM_OPO, 0x00ff},
{"opo", 0xffffff00, 0, SROM8_2G_OFDMPO, 0x00ff},
{"aa2g", 0x0000000e, 0, SROM_AABREV, SROM_AA0_MASK},
{"aa2g", 0x000000f0, 0, SROM4_AA, 0x00ff},
{"aa2g", 0xffffff00, 0, SROM8_AA, 0x00ff},
{"aa5g", 0x0000000e, 0, SROM_AABREV, SROM_AA1_MASK},
{"aa5g", 0x000000f0, 0, SROM4_AA, 0xff00},
{"aa5g", 0xffffff00, 0, SROM8_AA, 0xff00},
{"ag0", 0x0000000e, 0, SROM_AG10, 0x00ff},
{"ag1", 0x0000000e, 0, SROM_AG10, 0xff00},
{"ag0", 0x000000f0, 0, SROM4_AG10, 0x00ff},
{"ag1", 0x000000f0, 0, SROM4_AG10, 0xff00},
{"ag2", 0x000000f0, 0, SROM4_AG32, 0x00ff},
{"ag3", 0x000000f0, 0, SROM4_AG32, 0xff00},
{"ag0", 0xffffff00, 0, SROM8_AG10, 0x00ff},
{"ag1", 0xffffff00, 0, SROM8_AG10, 0xff00},
{"ag2", 0xffffff00, 0, SROM8_AG32, 0x00ff},
{"ag3", 0xffffff00, 0, SROM8_AG32, 0xff00},
{"pa1b0", 0x0000000e, SRFL_PRHEX, SROM_WL1PAB0, 0xffff},
{"pa1b1", 0x0000000e, SRFL_PRHEX, SROM_WL1PAB1, 0xffff},
{"pa1b2", 0x0000000e, SRFL_PRHEX, SROM_WL1PAB2, 0xffff},
{"pa1lob0", 0x0000000c, SRFL_PRHEX, SROM_WL1LPAB0, 0xffff},
{"pa1lob1", 0x0000000c, SRFL_PRHEX, SROM_WL1LPAB1, 0xffff},
{"pa1lob2", 0x0000000c, SRFL_PRHEX, SROM_WL1LPAB2, 0xffff},
{"pa1hib0", 0x0000000c, SRFL_PRHEX, SROM_WL1HPAB0, 0xffff},
{"pa1hib1", 0x0000000c, SRFL_PRHEX, SROM_WL1HPAB1, 0xffff},
{"pa1hib2", 0x0000000c, SRFL_PRHEX, SROM_WL1HPAB2, 0xffff},
{"pa1itssit", 0x0000000e, 0, SROM_ITT, 0xff00},
{"pa1maxpwr", 0x0000000e, 0, SROM_WL10MAXP, 0xff00},
{"pa1lomaxpwr", 0x0000000c, 0, SROM_WL1LHMAXP, 0xff00},
{"pa1himaxpwr", 0x0000000c, 0, SROM_WL1LHMAXP, 0x00ff},
{"pa1b0", 0xffffff00, SRFL_PRHEX, SROM8_W1_PAB0, 0xffff},
{"pa1b1", 0xffffff00, SRFL_PRHEX, SROM8_W1_PAB1, 0xffff},
{"pa1b2", 0xffffff00, SRFL_PRHEX, SROM8_W1_PAB2, 0xffff},
{"pa1lob0", 0xffffff00, SRFL_PRHEX, SROM8_W1_PAB0_LC, 0xffff},
{"pa1lob1", 0xffffff00, SRFL_PRHEX, SROM8_W1_PAB1_LC, 0xffff},
{"pa1lob2", 0xffffff00, SRFL_PRHEX, SROM8_W1_PAB2_LC, 0xffff},
{"pa1hib0", 0xffffff00, SRFL_PRHEX, SROM8_W1_PAB0_HC, 0xffff},
{"pa1hib1", 0xffffff00, SRFL_PRHEX, SROM8_W1_PAB1_HC, 0xffff},
{"pa1hib2", 0xffffff00, SRFL_PRHEX, SROM8_W1_PAB2_HC, 0xffff},
{"pa1itssit", 0xffffff00, 0, SROM8_W1_ITTMAXP, 0xff00},
{"pa1maxpwr", 0xffffff00, 0, SROM8_W1_ITTMAXP, 0x00ff},
{"pa1lomaxpwr", 0xffffff00, 0, SROM8_W1_MAXP_LCHC, 0xff00},
{"pa1himaxpwr", 0xffffff00, 0, SROM8_W1_MAXP_LCHC, 0x00ff},
{"bxa2g", 0x00000008, 0, SROM_BXARSSI2G, 0x1800},
{"rssisav2g", 0x00000008, 0, SROM_BXARSSI2G, 0x0700},
{"rssismc2g", 0x00000008, 0, SROM_BXARSSI2G, 0x00f0},
{"rssismf2g", 0x00000008, 0, SROM_BXARSSI2G, 0x000f},
{"bxa2g", 0xffffff00, 0, SROM8_BXARSSI2G, 0x1800},
{"rssisav2g", 0xffffff00, 0, SROM8_BXARSSI2G, 0x0700},
{"rssismc2g", 0xffffff00, 0, SROM8_BXARSSI2G, 0x00f0},
{"rssismf2g", 0xffffff00, 0, SROM8_BXARSSI2G, 0x000f},
{"bxa5g", 0x00000008, 0, SROM_BXARSSI5G, 0x1800},
{"rssisav5g", 0x00000008, 0, SROM_BXARSSI5G, 0x0700},
{"rssismc5g", 0x00000008, 0, SROM_BXARSSI5G, 0x00f0},
{"rssismf5g", 0x00000008, 0, SROM_BXARSSI5G, 0x000f},
{"bxa5g", 0xffffff00, 0, SROM8_BXARSSI5G, 0x1800},
{"rssisav5g", 0xffffff00, 0, SROM8_BXARSSI5G, 0x0700},
{"rssismc5g", 0xffffff00, 0, SROM8_BXARSSI5G, 0x00f0},
{"rssismf5g", 0xffffff00, 0, SROM8_BXARSSI5G, 0x000f},
{"tri2g", 0x00000008, 0, SROM_TRI52G, 0x00ff},
{"tri5g", 0x00000008, 0, SROM_TRI52G, 0xff00},
{"tri5gl", 0x00000008, 0, SROM_TRI5GHL, 0x00ff},
{"tri5gh", 0x00000008, 0, SROM_TRI5GHL, 0xff00},
{"tri2g", 0xffffff00, 0, SROM8_TRI52G, 0x00ff},
{"tri5g", 0xffffff00, 0, SROM8_TRI52G, 0xff00},
{"tri5gl", 0xffffff00, 0, SROM8_TRI5GHL, 0x00ff},
{"tri5gh", 0xffffff00, 0, SROM8_TRI5GHL, 0xff00},
{"rxpo2g", 0x00000008, SRFL_PRSIGN, SROM_RXPO52G, 0x00ff},
{"rxpo5g", 0x00000008, SRFL_PRSIGN, SROM_RXPO52G, 0xff00},
{"rxpo2g", 0xffffff00, SRFL_PRSIGN, SROM8_RXPO52G, 0x00ff},
{"rxpo5g", 0xffffff00, SRFL_PRSIGN, SROM8_RXPO52G, 0xff00},
{"txchain", 0x000000f0, SRFL_NOFFS, SROM4_TXRXC, SROM4_TXCHAIN_MASK},
{"rxchain", 0x000000f0, SRFL_NOFFS, SROM4_TXRXC, SROM4_RXCHAIN_MASK},
{"antswitch", 0x000000f0, SRFL_NOFFS, SROM4_TXRXC, SROM4_SWITCH_MASK},
{"txchain", 0xffffff00, SRFL_NOFFS, SROM8_TXRXC, SROM4_TXCHAIN_MASK},
{"rxchain", 0xffffff00, SRFL_NOFFS, SROM8_TXRXC, SROM4_RXCHAIN_MASK},
{"antswitch", 0xffffff00, SRFL_NOFFS, SROM8_TXRXC, SROM4_SWITCH_MASK},
{"tssipos2g", 0xffffff00, 0, SROM8_FEM2G, SROM8_FEM_TSSIPOS_MASK},
{"extpagain2g", 0xffffff00, 0, SROM8_FEM2G, SROM8_FEM_EXTPA_GAIN_MASK},
{"pdetrange2g", 0xffffff00, 0, SROM8_FEM2G, SROM8_FEM_PDET_RANGE_MASK},
{"triso2g", 0xffffff00, 0, SROM8_FEM2G, SROM8_FEM_TR_ISO_MASK},
{"antswctl2g", 0xffffff00, 0, SROM8_FEM2G, SROM8_FEM_ANTSWLUT_MASK},
{"tssipos5g", 0xffffff00, 0, SROM8_FEM5G, SROM8_FEM_TSSIPOS_MASK},
{"extpagain5g", 0xffffff00, 0, SROM8_FEM5G, SROM8_FEM_EXTPA_GAIN_MASK},
{"pdetrange5g", 0xffffff00, 0, SROM8_FEM5G, SROM8_FEM_PDET_RANGE_MASK},
{"triso5g", 0xffffff00, 0, SROM8_FEM5G, SROM8_FEM_TR_ISO_MASK},
{"antswctl5g", 0xffffff00, 0, SROM8_FEM5G, SROM8_FEM_ANTSWLUT_MASK},
{"tempthresh", 0xffffff00, 0, SROM8_THERMAL, 0xff00},
{"tempoffset", 0xffffff00, 0, SROM8_THERMAL, 0x00ff},
{"txpid2ga0", 0x000000f0, 0, SROM4_TXPID2G, 0x00ff},
{"txpid2ga1", 0x000000f0, 0, SROM4_TXPID2G, 0xff00},
{"txpid2ga2", 0x000000f0, 0, SROM4_TXPID2G + 1, 0x00ff},
{"txpid2ga3", 0x000000f0, 0, SROM4_TXPID2G + 1, 0xff00},
{"txpid5ga0", 0x000000f0, 0, SROM4_TXPID5G, 0x00ff},
{"txpid5ga1", 0x000000f0, 0, SROM4_TXPID5G, 0xff00},
{"txpid5ga2", 0x000000f0, 0, SROM4_TXPID5G + 1, 0x00ff},
{"txpid5ga3", 0x000000f0, 0, SROM4_TXPID5G + 1, 0xff00},
{"txpid5gla0", 0x000000f0, 0, SROM4_TXPID5GL, 0x00ff},
{"txpid5gla1", 0x000000f0, 0, SROM4_TXPID5GL, 0xff00},
{"txpid5gla2", 0x000000f0, 0, SROM4_TXPID5GL + 1, 0x00ff},
{"txpid5gla3", 0x000000f0, 0, SROM4_TXPID5GL + 1, 0xff00},
{"txpid5gha0", 0x000000f0, 0, SROM4_TXPID5GH, 0x00ff},
{"txpid5gha1", 0x000000f0, 0, SROM4_TXPID5GH, 0xff00},
{"txpid5gha2", 0x000000f0, 0, SROM4_TXPID5GH + 1, 0x00ff},
{"txpid5gha3", 0x000000f0, 0, SROM4_TXPID5GH + 1, 0xff00},
{"ccode", 0x0000000f, SRFL_CCODE, SROM_CCODE, 0xffff},
{"ccode", 0x00000010, SRFL_CCODE, SROM4_CCODE, 0xffff},
{"ccode", 0x000000e0, SRFL_CCODE, SROM5_CCODE, 0xffff},
{"ccode", 0xffffff00, SRFL_CCODE, SROM8_CCODE, 0xffff},
{"macaddr", 0xffffff00, SRFL_ETHADDR, SROM8_MACHI, 0xffff},
{"macaddr", 0x000000e0, SRFL_ETHADDR, SROM5_MACHI, 0xffff},
{"macaddr", 0x00000010, SRFL_ETHADDR, SROM4_MACHI, 0xffff},
{"macaddr", 0x00000008, SRFL_ETHADDR, SROM3_MACHI, 0xffff},
{"il0macaddr", 0x00000007, SRFL_ETHADDR, SROM_MACHI_IL0, 0xffff},
{"et1macaddr", 0x00000007, SRFL_ETHADDR, SROM_MACHI_ET1, 0xffff},
{"leddc", 0xffffff00, SRFL_NOFFS | SRFL_LEDDC, SROM8_LEDDC, 0xffff},
{"leddc", 0x000000e0, SRFL_NOFFS | SRFL_LEDDC, SROM5_LEDDC, 0xffff},
{"leddc", 0x00000010, SRFL_NOFFS | SRFL_LEDDC, SROM4_LEDDC, 0xffff},
{"leddc", 0x00000008, SRFL_NOFFS | SRFL_LEDDC, SROM3_LEDDC, 0xffff},
{"rawtempsense", 0xffffff00, SRFL_PRHEX, SROM8_MPWR_RAWTS, 0x01ff},
{"measpower", 0xffffff00, SRFL_PRHEX, SROM8_MPWR_RAWTS, 0xfe00},
{"tempsense_slope", 0xffffff00, SRFL_PRHEX, SROM8_TS_SLP_OPT_CORRX,
0x00ff},
{"tempcorrx", 0xffffff00, SRFL_PRHEX, SROM8_TS_SLP_OPT_CORRX, 0xfc00},
{"tempsense_option", 0xffffff00, SRFL_PRHEX, SROM8_TS_SLP_OPT_CORRX,
0x0300},
{"freqoffset_corr", 0xffffff00, SRFL_PRHEX, SROM8_FOC_HWIQ_IQSWP,
0x000f},
{"iqcal_swp_dis", 0xffffff00, SRFL_PRHEX, SROM8_FOC_HWIQ_IQSWP, 0x0010},
{"hw_iqcal_en", 0xffffff00, SRFL_PRHEX, SROM8_FOC_HWIQ_IQSWP, 0x0020},
{"phycal_tempdelta", 0xffffff00, 0, SROM8_PHYCAL_TEMPDELTA, 0x00ff},
{"cck2gpo", 0x000000f0, 0, SROM4_2G_CCKPO, 0xffff},
{"cck2gpo", 0x00000100, 0, SROM8_2G_CCKPO, 0xffff},
{"ofdm2gpo", 0x000000f0, SRFL_MORE, SROM4_2G_OFDMPO, 0xffff},
{"", 0, 0, SROM4_2G_OFDMPO + 1, 0xffff},
{"ofdm5gpo", 0x000000f0, SRFL_MORE, SROM4_5G_OFDMPO, 0xffff},
{"", 0, 0, SROM4_5G_OFDMPO + 1, 0xffff},
{"ofdm5glpo", 0x000000f0, SRFL_MORE, SROM4_5GL_OFDMPO, 0xffff},
{"", 0, 0, SROM4_5GL_OFDMPO + 1, 0xffff},
{"ofdm5ghpo", 0x000000f0, SRFL_MORE, SROM4_5GH_OFDMPO, 0xffff},
{"", 0, 0, SROM4_5GH_OFDMPO + 1, 0xffff},
{"ofdm2gpo", 0x00000100, SRFL_MORE, SROM8_2G_OFDMPO, 0xffff},
{"", 0, 0, SROM8_2G_OFDMPO + 1, 0xffff},
{"ofdm5gpo", 0x00000100, SRFL_MORE, SROM8_5G_OFDMPO, 0xffff},
{"", 0, 0, SROM8_5G_OFDMPO + 1, 0xffff},
{"ofdm5glpo", 0x00000100, SRFL_MORE, SROM8_5GL_OFDMPO, 0xffff},
{"", 0, 0, SROM8_5GL_OFDMPO + 1, 0xffff},
{"ofdm5ghpo", 0x00000100, SRFL_MORE, SROM8_5GH_OFDMPO, 0xffff},
{"", 0, 0, SROM8_5GH_OFDMPO + 1, 0xffff},
{"mcs2gpo0", 0x000000f0, 0, SROM4_2G_MCSPO, 0xffff},
{"mcs2gpo1", 0x000000f0, 0, SROM4_2G_MCSPO + 1, 0xffff},
{"mcs2gpo2", 0x000000f0, 0, SROM4_2G_MCSPO + 2, 0xffff},
{"mcs2gpo3", 0x000000f0, 0, SROM4_2G_MCSPO + 3, 0xffff},
{"mcs2gpo4", 0x000000f0, 0, SROM4_2G_MCSPO + 4, 0xffff},
{"mcs2gpo5", 0x000000f0, 0, SROM4_2G_MCSPO + 5, 0xffff},
{"mcs2gpo6", 0x000000f0, 0, SROM4_2G_MCSPO + 6, 0xffff},
{"mcs2gpo7", 0x000000f0, 0, SROM4_2G_MCSPO + 7, 0xffff},
{"mcs5gpo0", 0x000000f0, 0, SROM4_5G_MCSPO, 0xffff},
{"mcs5gpo1", 0x000000f0, 0, SROM4_5G_MCSPO + 1, 0xffff},
{"mcs5gpo2", 0x000000f0, 0, SROM4_5G_MCSPO + 2, 0xffff},
{"mcs5gpo3", 0x000000f0, 0, SROM4_5G_MCSPO + 3, 0xffff},
{"mcs5gpo4", 0x000000f0, 0, SROM4_5G_MCSPO + 4, 0xffff},
{"mcs5gpo5", 0x000000f0, 0, SROM4_5G_MCSPO + 5, 0xffff},
{"mcs5gpo6", 0x000000f0, 0, SROM4_5G_MCSPO + 6, 0xffff},
{"mcs5gpo7", 0x000000f0, 0, SROM4_5G_MCSPO + 7, 0xffff},
{"mcs5glpo0", 0x000000f0, 0, SROM4_5GL_MCSPO, 0xffff},
{"mcs5glpo1", 0x000000f0, 0, SROM4_5GL_MCSPO + 1, 0xffff},
{"mcs5glpo2", 0x000000f0, 0, SROM4_5GL_MCSPO + 2, 0xffff},
{"mcs5glpo3", 0x000000f0, 0, SROM4_5GL_MCSPO + 3, 0xffff},
{"mcs5glpo4", 0x000000f0, 0, SROM4_5GL_MCSPO + 4, 0xffff},
{"mcs5glpo5", 0x000000f0, 0, SROM4_5GL_MCSPO + 5, 0xffff},
{"mcs5glpo6", 0x000000f0, 0, SROM4_5GL_MCSPO + 6, 0xffff},
{"mcs5glpo7", 0x000000f0, 0, SROM4_5GL_MCSPO + 7, 0xffff},
{"mcs5ghpo0", 0x000000f0, 0, SROM4_5GH_MCSPO, 0xffff},
{"mcs5ghpo1", 0x000000f0, 0, SROM4_5GH_MCSPO + 1, 0xffff},
{"mcs5ghpo2", 0x000000f0, 0, SROM4_5GH_MCSPO + 2, 0xffff},
{"mcs5ghpo3", 0x000000f0, 0, SROM4_5GH_MCSPO + 3, 0xffff},
{"mcs5ghpo4", 0x000000f0, 0, SROM4_5GH_MCSPO + 4, 0xffff},
{"mcs5ghpo5", 0x000000f0, 0, SROM4_5GH_MCSPO + 5, 0xffff},
{"mcs5ghpo6", 0x000000f0, 0, SROM4_5GH_MCSPO + 6, 0xffff},
{"mcs5ghpo7", 0x000000f0, 0, SROM4_5GH_MCSPO + 7, 0xffff},
{"mcs2gpo0", 0x00000100, 0, SROM8_2G_MCSPO, 0xffff},
{"mcs2gpo1", 0x00000100, 0, SROM8_2G_MCSPO + 1, 0xffff},
{"mcs2gpo2", 0x00000100, 0, SROM8_2G_MCSPO + 2, 0xffff},
{"mcs2gpo3", 0x00000100, 0, SROM8_2G_MCSPO + 3, 0xffff},
{"mcs2gpo4", 0x00000100, 0, SROM8_2G_MCSPO + 4, 0xffff},
{"mcs2gpo5", 0x00000100, 0, SROM8_2G_MCSPO + 5, 0xffff},
{"mcs2gpo6", 0x00000100, 0, SROM8_2G_MCSPO + 6, 0xffff},
{"mcs2gpo7", 0x00000100, 0, SROM8_2G_MCSPO + 7, 0xffff},
{"mcs5gpo0", 0x00000100, 0, SROM8_5G_MCSPO, 0xffff},
{"mcs5gpo1", 0x00000100, 0, SROM8_5G_MCSPO + 1, 0xffff},
{"mcs5gpo2", 0x00000100, 0, SROM8_5G_MCSPO + 2, 0xffff},
{"mcs5gpo3", 0x00000100, 0, SROM8_5G_MCSPO + 3, 0xffff},
{"mcs5gpo4", 0x00000100, 0, SROM8_5G_MCSPO + 4, 0xffff},
{"mcs5gpo5", 0x00000100, 0, SROM8_5G_MCSPO + 5, 0xffff},
{"mcs5gpo6", 0x00000100, 0, SROM8_5G_MCSPO + 6, 0xffff},
{"mcs5gpo7", 0x00000100, 0, SROM8_5G_MCSPO + 7, 0xffff},
{"mcs5glpo0", 0x00000100, 0, SROM8_5GL_MCSPO, 0xffff},
{"mcs5glpo1", 0x00000100, 0, SROM8_5GL_MCSPO + 1, 0xffff},
{"mcs5glpo2", 0x00000100, 0, SROM8_5GL_MCSPO + 2, 0xffff},
{"mcs5glpo3", 0x00000100, 0, SROM8_5GL_MCSPO + 3, 0xffff},
{"mcs5glpo4", 0x00000100, 0, SROM8_5GL_MCSPO + 4, 0xffff},
{"mcs5glpo5", 0x00000100, 0, SROM8_5GL_MCSPO + 5, 0xffff},
{"mcs5glpo6", 0x00000100, 0, SROM8_5GL_MCSPO + 6, 0xffff},
{"mcs5glpo7", 0x00000100, 0, SROM8_5GL_MCSPO + 7, 0xffff},
{"mcs5ghpo0", 0x00000100, 0, SROM8_5GH_MCSPO, 0xffff},
{"mcs5ghpo1", 0x00000100, 0, SROM8_5GH_MCSPO + 1, 0xffff},
{"mcs5ghpo2", 0x00000100, 0, SROM8_5GH_MCSPO + 2, 0xffff},
{"mcs5ghpo3", 0x00000100, 0, SROM8_5GH_MCSPO + 3, 0xffff},
{"mcs5ghpo4", 0x00000100, 0, SROM8_5GH_MCSPO + 4, 0xffff},
{"mcs5ghpo5", 0x00000100, 0, SROM8_5GH_MCSPO + 5, 0xffff},
{"mcs5ghpo6", 0x00000100, 0, SROM8_5GH_MCSPO + 6, 0xffff},
{"mcs5ghpo7", 0x00000100, 0, SROM8_5GH_MCSPO + 7, 0xffff},
{"cddpo", 0x000000f0, 0, SROM4_CDDPO, 0xffff},
{"stbcpo", 0x000000f0, 0, SROM4_STBCPO, 0xffff},
{"bw40po", 0x000000f0, 0, SROM4_BW40PO, 0xffff},
{"bwduppo", 0x000000f0, 0, SROM4_BWDUPPO, 0xffff},
{"cddpo", 0x00000100, 0, SROM8_CDDPO, 0xffff},
{"stbcpo", 0x00000100, 0, SROM8_STBCPO, 0xffff},
{"bw40po", 0x00000100, 0, SROM8_BW40PO, 0xffff},
{"bwduppo", 0x00000100, 0, SROM8_BWDUPPO, 0xffff},
/* power per rate from sromrev 9 */
{"cckbw202gpo", 0xfffffe00, 0, SROM9_2GPO_CCKBW20, 0xffff},
{"cckbw20ul2gpo", 0xfffffe00, 0, SROM9_2GPO_CCKBW20UL, 0xffff},
{"legofdmbw202gpo", 0xfffffe00, SRFL_MORE, SROM9_2GPO_LOFDMBW20,
0xffff},
{"", 0, 0, SROM9_2GPO_LOFDMBW20 + 1, 0xffff},
{"legofdmbw20ul2gpo", 0xfffffe00, SRFL_MORE, SROM9_2GPO_LOFDMBW20UL,
0xffff},
{"", 0, 0, SROM9_2GPO_LOFDMBW20UL + 1, 0xffff},
{"legofdmbw205glpo", 0xfffffe00, SRFL_MORE, SROM9_5GLPO_LOFDMBW20,
0xffff},
{"", 0, 0, SROM9_5GLPO_LOFDMBW20 + 1, 0xffff},
{"legofdmbw20ul5glpo", 0xfffffe00, SRFL_MORE, SROM9_5GLPO_LOFDMBW20UL,
0xffff},
{"", 0, 0, SROM9_5GLPO_LOFDMBW20UL + 1, 0xffff},
{"legofdmbw205gmpo", 0xfffffe00, SRFL_MORE, SROM9_5GMPO_LOFDMBW20,
0xffff},
{"", 0, 0, SROM9_5GMPO_LOFDMBW20 + 1, 0xffff},
{"legofdmbw20ul5gmpo", 0xfffffe00, SRFL_MORE, SROM9_5GMPO_LOFDMBW20UL,
0xffff},
{"", 0, 0, SROM9_5GMPO_LOFDMBW20UL + 1, 0xffff},
{"legofdmbw205ghpo", 0xfffffe00, SRFL_MORE, SROM9_5GHPO_LOFDMBW20,
0xffff},
{"", 0, 0, SROM9_5GHPO_LOFDMBW20 + 1, 0xffff},
{"legofdmbw20ul5ghpo", 0xfffffe00, SRFL_MORE, SROM9_5GHPO_LOFDMBW20UL,
0xffff},
{"", 0, 0, SROM9_5GHPO_LOFDMBW20UL + 1, 0xffff},
{"mcsbw202gpo", 0xfffffe00, SRFL_MORE, SROM9_2GPO_MCSBW20, 0xffff},
{"", 0, 0, SROM9_2GPO_MCSBW20 + 1, 0xffff},
{"mcsbw20ul2gpo", 0xfffffe00, SRFL_MORE, SROM9_2GPO_MCSBW20UL, 0xffff},
{"", 0, 0, SROM9_2GPO_MCSBW20UL + 1, 0xffff},
{"mcsbw402gpo", 0xfffffe00, SRFL_MORE, SROM9_2GPO_MCSBW40, 0xffff},
{"", 0, 0, SROM9_2GPO_MCSBW40 + 1, 0xffff},
{"mcsbw205glpo", 0xfffffe00, SRFL_MORE, SROM9_5GLPO_MCSBW20, 0xffff},
{"", 0, 0, SROM9_5GLPO_MCSBW20 + 1, 0xffff},
{"mcsbw20ul5glpo", 0xfffffe00, SRFL_MORE, SROM9_5GLPO_MCSBW20UL,
0xffff},
{"", 0, 0, SROM9_5GLPO_MCSBW20UL + 1, 0xffff},
{"mcsbw405glpo", 0xfffffe00, SRFL_MORE, SROM9_5GLPO_MCSBW40, 0xffff},
{"", 0, 0, SROM9_5GLPO_MCSBW40 + 1, 0xffff},
{"mcsbw205gmpo", 0xfffffe00, SRFL_MORE, SROM9_5GMPO_MCSBW20, 0xffff},
{"", 0, 0, SROM9_5GMPO_MCSBW20 + 1, 0xffff},
{"mcsbw20ul5gmpo", 0xfffffe00, SRFL_MORE, SROM9_5GMPO_MCSBW20UL,
0xffff},
{"", 0, 0, SROM9_5GMPO_MCSBW20UL + 1, 0xffff},
{"mcsbw405gmpo", 0xfffffe00, SRFL_MORE, SROM9_5GMPO_MCSBW40, 0xffff},
{"", 0, 0, SROM9_5GMPO_MCSBW40 + 1, 0xffff},
{"mcsbw205ghpo", 0xfffffe00, SRFL_MORE, SROM9_5GHPO_MCSBW20, 0xffff},
{"", 0, 0, SROM9_5GHPO_MCSBW20 + 1, 0xffff},
{"mcsbw20ul5ghpo", 0xfffffe00, SRFL_MORE, SROM9_5GHPO_MCSBW20UL,
0xffff},
{"", 0, 0, SROM9_5GHPO_MCSBW20UL + 1, 0xffff},
{"mcsbw405ghpo", 0xfffffe00, SRFL_MORE, SROM9_5GHPO_MCSBW40, 0xffff},
{"", 0, 0, SROM9_5GHPO_MCSBW40 + 1, 0xffff},
{"mcs32po", 0xfffffe00, 0, SROM9_PO_MCS32, 0xffff},
{"legofdm40duppo", 0xfffffe00, 0, SROM9_PO_LOFDM40DUP, 0xffff},
{NULL, 0, 0, 0, 0}
};
static const struct brcms_sromvar perpath_pci_sromvars[] = {
{"maxp2ga", 0x000000f0, 0, SROM4_2G_ITT_MAXP, 0x00ff},
{"itt2ga", 0x000000f0, 0, SROM4_2G_ITT_MAXP, 0xff00},
{"itt5ga", 0x000000f0, 0, SROM4_5G_ITT_MAXP, 0xff00},
{"pa2gw0a", 0x000000f0, SRFL_PRHEX, SROM4_2G_PA, 0xffff},
{"pa2gw1a", 0x000000f0, SRFL_PRHEX, SROM4_2G_PA + 1, 0xffff},
{"pa2gw2a", 0x000000f0, SRFL_PRHEX, SROM4_2G_PA + 2, 0xffff},
{"pa2gw3a", 0x000000f0, SRFL_PRHEX, SROM4_2G_PA + 3, 0xffff},
{"maxp5ga", 0x000000f0, 0, SROM4_5G_ITT_MAXP, 0x00ff},
{"maxp5gha", 0x000000f0, 0, SROM4_5GLH_MAXP, 0x00ff},
{"maxp5gla", 0x000000f0, 0, SROM4_5GLH_MAXP, 0xff00},
{"pa5gw0a", 0x000000f0, SRFL_PRHEX, SROM4_5G_PA, 0xffff},
{"pa5gw1a", 0x000000f0, SRFL_PRHEX, SROM4_5G_PA + 1, 0xffff},
{"pa5gw2a", 0x000000f0, SRFL_PRHEX, SROM4_5G_PA + 2, 0xffff},
{"pa5gw3a", 0x000000f0, SRFL_PRHEX, SROM4_5G_PA + 3, 0xffff},
{"pa5glw0a", 0x000000f0, SRFL_PRHEX, SROM4_5GL_PA, 0xffff},
{"pa5glw1a", 0x000000f0, SRFL_PRHEX, SROM4_5GL_PA + 1, 0xffff},
{"pa5glw2a", 0x000000f0, SRFL_PRHEX, SROM4_5GL_PA + 2, 0xffff},
{"pa5glw3a", 0x000000f0, SRFL_PRHEX, SROM4_5GL_PA + 3, 0xffff},
{"pa5ghw0a", 0x000000f0, SRFL_PRHEX, SROM4_5GH_PA, 0xffff},
{"pa5ghw1a", 0x000000f0, SRFL_PRHEX, SROM4_5GH_PA + 1, 0xffff},
{"pa5ghw2a", 0x000000f0, SRFL_PRHEX, SROM4_5GH_PA + 2, 0xffff},
{"pa5ghw3a", 0x000000f0, SRFL_PRHEX, SROM4_5GH_PA + 3, 0xffff},
{"maxp2ga", 0xffffff00, 0, SROM8_2G_ITT_MAXP, 0x00ff},
{"itt2ga", 0xffffff00, 0, SROM8_2G_ITT_MAXP, 0xff00},
{"itt5ga", 0xffffff00, 0, SROM8_5G_ITT_MAXP, 0xff00},
{"pa2gw0a", 0xffffff00, SRFL_PRHEX, SROM8_2G_PA, 0xffff},
{"pa2gw1a", 0xffffff00, SRFL_PRHEX, SROM8_2G_PA + 1, 0xffff},
{"pa2gw2a", 0xffffff00, SRFL_PRHEX, SROM8_2G_PA + 2, 0xffff},
{"maxp5ga", 0xffffff00, 0, SROM8_5G_ITT_MAXP, 0x00ff},
{"maxp5gha", 0xffffff00, 0, SROM8_5GLH_MAXP, 0x00ff},
{"maxp5gla", 0xffffff00, 0, SROM8_5GLH_MAXP, 0xff00},
{"pa5gw0a", 0xffffff00, SRFL_PRHEX, SROM8_5G_PA, 0xffff},
{"pa5gw1a", 0xffffff00, SRFL_PRHEX, SROM8_5G_PA + 1, 0xffff},
{"pa5gw2a", 0xffffff00, SRFL_PRHEX, SROM8_5G_PA + 2, 0xffff},
{"pa5glw0a", 0xffffff00, SRFL_PRHEX, SROM8_5GL_PA, 0xffff},
{"pa5glw1a", 0xffffff00, SRFL_PRHEX, SROM8_5GL_PA + 1, 0xffff},
{"pa5glw2a", 0xffffff00, SRFL_PRHEX, SROM8_5GL_PA + 2, 0xffff},
{"pa5ghw0a", 0xffffff00, SRFL_PRHEX, SROM8_5GH_PA, 0xffff},
{"pa5ghw1a", 0xffffff00, SRFL_PRHEX, SROM8_5GH_PA + 1, 0xffff},
{"pa5ghw2a", 0xffffff00, SRFL_PRHEX, SROM8_5GH_PA + 2, 0xffff},
{NULL, 0, 0, 0, 0}
};
static void _initvars_srom_pci(u8 sromrev, u16 *srom, uint off,
struct brcms_varbuf *b);
static int initvars_srom_pci(struct si_pub *sih, void *curmap, char **vars,
uint *count);
static int sprom_read_pci(struct si_pub *sih, u16 *sprom,
uint wordoff, u16 *buf, uint nwords, bool check_crc);
#if defined(BCMNVRAMR)
static int otp_read_pci(struct si_pub *sih, u16 *buf, uint bufsz);
#endif
static int initvars_table(char *start, char *end,
char **vars, uint *count);
/* Initialization of varbuf structure */
static void varbuf_init(struct brcms_varbuf *b, char *buf, uint size)
{
b->size = size;
b->base = b->buf = buf;
}
/* append a null terminated var=value string */
static int varbuf_append(struct brcms_varbuf *b, const char *fmt, ...)
{
va_list ap;
int r;
size_t len;
char *s;
if (b->size < 2)
return 0;
va_start(ap, fmt);
r = vsnprintf(b->buf, b->size, fmt, ap);
va_end(ap);
/* C99 snprintf behavior returns r >= size on overflow,
* others return -1 on overflow.
* All return -1 on format error.
* We need to leave room for 2 null terminations, one for the current var
* string, and one for final null of the var table. So check that the
* strlen written, r, leaves room for 2 chars.
*/
if ((r == -1) || (r > (int)(b->size - 2))) {
b->size = 0;
return 0;
}
/* Remove any earlier occurrence of the same variable */
s = strchr(b->buf, '=');
if (s != NULL) {
len = (size_t) (s - b->buf);
for (s = b->base; s < b->buf;) {
if ((memcmp(s, b->buf, len) == 0) && s[len] == '=') {
len = strlen(s) + 1;
memmove(s, (s + len),
((b->buf + r + 1) - (s + len)));
b->buf -= len;
b->size += (unsigned int)len;
break;
}
while (*s++)
;
}
}
/* skip over this string's null termination */
r++;
b->size -= r;
b->buf += r;
return r;
}
/*
* Initialize local vars from the right source for this platform.
* Return 0 on success, nonzero on error.
*/
int srom_var_init(struct si_pub *sih, uint bustype, void *curmap,
char **vars, uint *count)
{
uint len;
len = 0;
if (vars == NULL || count == NULL)
return 0;
*vars = NULL;
*count = 0;
if (curmap != NULL && bustype == PCI_BUS)
return initvars_srom_pci(sih, curmap, vars, count);
return -EINVAL;
}
static inline void ltoh16_buf(u16 *buf, unsigned int size)
{
for (size /= 2; size; size--)
*(buf + size) = le16_to_cpu(*(buf + size));
}
static inline void htol16_buf(u16 *buf, unsigned int size)
{
for (size /= 2; size; size--)
*(buf + size) = cpu_to_le16(*(buf + size));
}
/*
* Read in and validate sprom.
* Return 0 on success, nonzero on error.
*/
static int
sprom_read_pci(struct si_pub *sih, u16 *sprom, uint wordoff,
u16 *buf, uint nwords, bool check_crc)
{
int err = 0;
uint i;
/* read the sprom */
for (i = 0; i < nwords; i++)
buf[i] = R_REG(&sprom[wordoff + i]);
if (check_crc) {
if (buf[0] == 0xffff) {
/* The hardware thinks that an srom that starts with 0xffff
* is blank, regardless of the rest of the content, so declare
* it bad.
*/
return -ENODATA;
}
/* fixup the endianness so crc8 will pass */
htol16_buf(buf, nwords * 2);
if (brcmu_crc8((u8 *) buf, nwords * 2, CRC8_INIT_VALUE) !=
CRC8_GOOD_VALUE) {
/* DBG only pci always read srom4 first, then srom8/9 */
err = -EIO;
}
/* now correct the endianness of the byte array */
ltoh16_buf(buf, nwords * 2);
}
return err;
}
#if defined(BCMNVRAMR)
static int otp_read_pci(struct si_pub *sih, u16 *buf, uint bufsz)
{
u8 *otp;
uint sz = OTP_SZ_MAX / 2; /* size in words */
int err = 0;
otp = kzalloc(OTP_SZ_MAX, GFP_ATOMIC);
if (otp == NULL) {
return -ENOMEM;
}
err = otp_read_region(sih, OTP_HW_RGN, (u16 *) otp, &sz);
memcpy(buf, otp, bufsz);
kfree(otp);
/* Check CRC */
if (buf[0] == 0xffff) {
/* The hardware thinks that an srom that starts with 0xffff
* is blank, regardless of the rest of the content, so declare
* it bad.
*/
return -ENODATA;
}
/* fixup the endianness so crc8 will pass */
htol16_buf(buf, bufsz);
if (brcmu_crc8((u8 *) buf, SROM4_WORDS * 2, CRC8_INIT_VALUE) !=
CRC8_GOOD_VALUE) {
err = -EIO;
}
/* now correct the endianness of the byte array */
ltoh16_buf(buf, bufsz);
return err;
}
#endif /* defined(BCMNVRAMR) */
/*
* Create variable table from memory.
* Return 0 on success, nonzero on error.
*/
static int initvars_table(char *start, char *end,
char **vars, uint *count)
{
int c = (int)(end - start);
/* do it only when there is more than just the null string */
if (c > 1) {
char *vp = kmalloc(c, GFP_ATOMIC);
if (!vp)
return -ENOMEM;
memcpy(vp, start, c);
*vars = vp;
*count = c;
} else {
*vars = NULL;
*count = 0;
}
return 0;
}
/* Parse SROM and create name=value pairs. 'srom' points to
* the SROM word array. 'off' specifies the offset of the
* first word 'srom' points to, which should be either 0 or
* SROM3_SWRG_OFF (full SROM or software region).
*/
static uint mask_shift(u16 mask)
{
uint i;
for (i = 0; i < (sizeof(mask) << 3); i++) {
if (mask & (1 << i))
return i;
}
return 0;
}
static uint mask_width(u16 mask)
{
int i;
for (i = (sizeof(mask) << 3) - 1; i >= 0; i--) {
if (mask & (1 << i))
return (uint) (i - mask_shift(mask) + 1);
}
return 0;
}
static void
_initvars_srom_pci(u8 sromrev, u16 *srom, uint off, struct brcms_varbuf *b)
{
u16 w;
u32 val;
const struct brcms_sromvar *srv;
uint width;
uint flags;
u32 sr = (1 << sromrev);
varbuf_append(b, "sromrev=%d", sromrev);
for (srv = pci_sromvars; srv->name != NULL; srv++) {
const char *name;
if ((srv->revmask & sr) == 0)
continue;
if (srv->off < off)
continue;
flags = srv->flags;
name = srv->name;
/* This entry is for mfgc only. Don't generate param for it, */
if (flags & SRFL_NOVAR)
continue;
if (flags & SRFL_ETHADDR) {
u8 ea[ETH_ALEN];
ea[0] = (srom[srv->off - off] >> 8) & 0xff;
ea[1] = srom[srv->off - off] & 0xff;
ea[2] = (srom[srv->off + 1 - off] >> 8) & 0xff;
ea[3] = srom[srv->off + 1 - off] & 0xff;
ea[4] = (srom[srv->off + 2 - off] >> 8) & 0xff;
ea[5] = srom[srv->off + 2 - off] & 0xff;
varbuf_append(b, "%s=%pM", name, ea);
} else {
w = srom[srv->off - off];
val = (w & srv->mask) >> mask_shift(srv->mask);
width = mask_width(srv->mask);
while (srv->flags & SRFL_MORE) {
srv++;
if (srv->off == 0 || srv->off < off)
continue;
w = srom[srv->off - off];
val +=
((w & srv->mask) >> mask_shift(srv->
mask)) <<
width;
width += mask_width(srv->mask);
}
if ((flags & SRFL_NOFFS)
&& ((int)val == (1 << width) - 1))
continue;
if (flags & SRFL_CCODE) {
if (val == 0)
varbuf_append(b, "ccode=");
else
varbuf_append(b, "ccode=%c%c",
(val >> 8), (val & 0xff));
}
/* LED Powersave duty cycle has to be scaled:
*(oncount >> 24) (offcount >> 8)
*/
else if (flags & SRFL_LEDDC) {
u32 w32 = (((val >> 8) & 0xff) << 24) | /* oncount */
(((val & 0xff)) << 8); /* offcount */
varbuf_append(b, "leddc=%d", w32);
} else if (flags & SRFL_PRHEX)
varbuf_append(b, "%s=0x%x", name, val);
else if ((flags & SRFL_PRSIGN)
&& (val & (1 << (width - 1))))
varbuf_append(b, "%s=%d", name,
(int)(val | (~0 << width)));
else
varbuf_append(b, "%s=%u", name, val);
}
}
if (sromrev >= 4) {
/* Do per-path variables */
uint p, pb, psz;
if (sromrev >= 8) {
pb = SROM8_PATH0;
psz = SROM8_PATH1 - SROM8_PATH0;
} else {
pb = SROM4_PATH0;
psz = SROM4_PATH1 - SROM4_PATH0;
}
for (p = 0; p < MAX_PATH_SROM; p++) {
for (srv = perpath_pci_sromvars; srv->name != NULL;
srv++) {
if ((srv->revmask & sr) == 0)
continue;
if (pb + srv->off < off)
continue;
/* This entry is for mfgc only. Don't generate param for it, */
if (srv->flags & SRFL_NOVAR)
continue;
w = srom[pb + srv->off - off];
val = (w & srv->mask) >> mask_shift(srv->mask);
width = mask_width(srv->mask);
/* Cheating: no per-path var is more than 1 word */
if ((srv->flags & SRFL_NOFFS)
&& ((int)val == (1 << width) - 1))
continue;
if (srv->flags & SRFL_PRHEX)
varbuf_append(b, "%s%d=0x%x", srv->name,
p, val);
else
varbuf_append(b, "%s%d=%d", srv->name,
p, val);
}
pb += psz;
}
}
}
/*
* Initialize nonvolatile variable table from sprom.
* Return 0 on success, nonzero on error.
*/
static int initvars_srom_pci(struct si_pub *sih, void *curmap, char **vars,
uint *count)
{
u16 *srom, *sromwindow;
u8 sromrev = 0;
u32 sr;
struct brcms_varbuf b;
char *vp, *base = NULL;
int err = 0;
/*
* Apply CRC over SROM content regardless SROM is present or not.
*/
srom = kmalloc(SROM_MAX, GFP_ATOMIC);
if (!srom)
return -ENOMEM;
sromwindow = (u16 *) SROM_OFFSET(sih);
if (ai_is_sprom_available(sih)) {
err = sprom_read_pci(sih, sromwindow, 0, srom, SROM_WORDS,
true);
if ((srom[SROM4_SIGN] == SROM4_SIGNATURE) ||
(((sih->buscoretype == PCIE_CORE_ID)
&& (sih->buscorerev >= 6))
|| ((sih->buscoretype == PCI_CORE_ID)
&& (sih->buscorerev >= 0xe)))) {
/* sromrev >= 4, read more */
err = sprom_read_pci(sih, sromwindow, 0, srom,
SROM4_WORDS, true);
sromrev = srom[SROM4_CRCREV] & 0xff;
} else if (err == 0) {
/* srom is good and is rev < 4 */
/* top word of sprom contains version and crc8 */
sromrev = srom[SROM_CRCREV] & 0xff;
/* bcm4401 sroms misprogrammed */
if (sromrev == 0x10)
sromrev = 1;
}
}
#if defined(BCMNVRAMR)
/* Use OTP if SPROM not available */
else {
err = otp_read_pci(sih, srom, SROM_MAX);
if (err == 0)
/* OTP only contain SROM rev8/rev9 for now */
sromrev = srom[SROM4_CRCREV] & 0xff;
}
#else
else
err = -ENODEV;
#endif
if (!err) {
/* Bitmask for the sromrev */
sr = 1 << sromrev;
/* srom version check: Current valid versions: 1, 2, 3, 4, 5, 8, 9 */
if ((sr & 0x33e) == 0) {
err = -EINVAL;
goto errout;
}
base = kmalloc(MAXSZ_NVRAM_VARS, GFP_ATOMIC);
if (!base) {
err = -ENOMEM;
goto errout;
}
varbuf_init(&b, base, MAXSZ_NVRAM_VARS);
/* parse SROM into name=value pairs. */
_initvars_srom_pci(sromrev, srom, 0, &b);
/* final nullbyte terminator */
vp = b.buf;
*vp++ = '\0';
err = initvars_table(base, vp, vars, count);
kfree(base);
}
errout:
kfree(srom);
return err;
}