#- # Copyright (c) 2015-2016 Landon Fuller # Copyright (C) 2008-2015, Broadcom Corporation. # All Rights Reserved. # # The contents of this file (variable names, descriptions, and offsets) were # extracted or derived from Broadcom's ISC-licensed sources. # # 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. # # $FreeBSD$ # # NVRAM variable definitions and revision-specific SPROM offsets. # # Processed by nvram_map_gen.awk to produce bhnd_nvram_map.h # # NOTE: file was originally generated automatically by using libclang # to analyze and extract format information and descriptions from Broadcom's # available ISC-licensed CIS and SROM code and associated headers. # # Board Info # u16 boardvendor {} # PCI vendor ID (SoC NVRAM-only) u16 subvid { srom >= 2 0x6 } # PCI subvendor ID u16 devid { srom >= 8 0x60 } # PCI device ID u32 boardflags { srom 1 u16 0x72 srom 2 u16 0x72 | u16 0x38 (<<16) srom 3 u16 0x72 | u16 0x7A (<<16) srom 4 0x44 srom 5-7 0x4A srom >= 8 0x84 } u32 boardflags2 { srom 4 0x48 srom 5-7 0x4E srom >= 8 0x88 } u32 boardflags3 { srom >= 11 0x8C } # Board serial number, independent of mac addr u16 boardnum { srom 1-2 0x4C srom 3 0x4E srom 4 0x50 srom 5-7 0x56 srom 8-10 0x90 srom >= 11 0x94 } # Board revision u16 boardrev { srom 1-3 u8 0x5D srom 4-7 0x42 srom >= 8 0x82 } # Board type u16 boardtype { srom >= 2 0x4 } # SROM revision u8 sromrev { srom 1-3 0x74 srom 4-9 0x1B6 srom 10 0x1CA srom 11 0x1D2 } # Antennas available u8 aa2g { srom 1-3 0x5C (&0x30, >>4) srom 4-7 0x5D srom 8-10 0x9D srom >= 11 0xA1 } u8 aa5g { srom 1-3 0x5C (&0xC0, >>6) srom 4-7 0x5C srom 8-10 0x9C srom >= 11 0xA0 } # ACPHY PA trimming parameters: 40 u16[12] pa5gbw40a0 { srom >= 11 0x110 } # ACPHY PA trimming parameters: 80 u16[12] pa5gbw80a0 { srom >= 11 0x138 } # ACPHY PA trimming parameters: 40/80 u16[12] pa5gbw4080a0 { srom >= 11 0x138 } u16[12] pa5gbw4080a1 { srom >= 11 u16 0xB6, u16 0xBC, u16 0xCE, u16 0xD4, u16[8] 0x128 } # ACPHY PA trimming parameters: CCK u16[3] pa2gccka0 { srom >= 11 0x102 } # ACPHY Power-per-rate 2gpo u16 dot11agofdmhrbw202gpo { srom >= 11 0x15C } u16 ofdmlrbw202gpo { srom >= 11 0x15E } # ACPHY Power-per-rate 5gpo u32 mcsbw805glpo { srom >= 11 0x168 } u32 mcsbw805gmpo { srom >= 11 0x178 } u32 mcsbw805ghpo { srom >= 11 0x188 } u16 mcslr5glpo { srom >= 11 0x190 (&0xFFF) } u16 mcslr5gmpo { srom >= 11 0x192 } u16 mcslr5ghpo { srom >= 11 0x194 } # ACPHY Power-per-rate sbpo u16 sb20in40hrpo { srom >= 11 0x196 } u16 sb20in80and160hr5glpo { srom >= 11 0x198 } u16 sb40and80hr5glpo { srom >= 11 0x19A } u16 sb20in80and160hr5gmpo { srom >= 11 0x19C } u16 sb40and80hr5gmpo { srom >= 11 0x19E } u16 sb20in80and160hr5ghpo { srom >= 11 0x1A0 } u16 sb40and80hr5ghpo { srom >= 11 0x1A2 } u16 sb20in40lrpo { srom >= 11 0x1A4 } u16 sb20in80and160lr5glpo { srom >= 11 0x1A6 } u16 sb40and80lr5glpo { srom >= 11 0x1A8 } u16 sb20in80and160lr5gmpo { srom >= 11 0x1AA } u16 sb40and80lr5gmpo { srom >= 11 0x1AC } u16 sb20in80and160lr5ghpo { srom >= 11 0x1AE } u16 sb40and80lr5ghpo { srom >= 11 0x1B0 } u16 dot11agduphrpo { srom >= 11 0x1B2 } u16 dot11agduplrpo { srom >= 11 0x1B4 } # Antenna gain u8 ag0 { srom 1-3 0x75 srom 4-7 0x5F srom 8-10 0x9F } u8 ag1 { srom 1-3 0x74 srom 4-7 0x5E srom 8-10 0x9E } u8 ag2 { srom 4-7 0x61 srom 8-10 0xA1 } u8 ag3 { srom 4-7 0x60 srom 8-10 0xA0 } u8 agbg0 { srom >= 11 0xA2 } u8 agbg1 { srom >= 11 0xA3 } u8 agbg2 { srom >= 11 0xA4 } u8 aga0 { srom >= 11 0xA5 } u8 aga1 { srom >= 11 0xA6 } u8 aga2 { srom >= 11 0xA7 } # Default country code (sromrev == 1) u8 cc { srom 1 0x5C (&0xF) } # 2 bytes each # CCK Power offsets for 20 MHz rates (11, 5.5, 2, 1Mbps) # cckbw202gpo cckbw20ul2gpo # u16 cckbw202gpo { srom 9-10 0x140 srom >= 11 0x150 } u16 cckbw20ul2gpo { srom 9-10 0x142 srom >= 11 0x152 } # Country code (2 bytes ascii + 1 byte cctl) # in rev 2 # char[2] ccode { sfmt ccode srom 0-3 0x76 srom 4 0x52 srom 5-7 0x44 srom 8-10 0x92 srom >= 11 0x96 } # 2 byte; txchain, rxchain u8 txchain { all1 ignore srom 4-7 0x7B (&0xF) srom 8-10 0xA3 (&0xF) srom >= 11 0xA9 (&0xF) } u8 rxchain { all1 ignore srom 4-7 0x7B (&0xF0, >>4) srom 8-10 0xA3 (&0xF0, >>4) srom >= 11 0xA9 (&0xF0, >>4) } u16 antswitch { all1 ignore srom 4-7 u8 0x7A srom 8-10 u8 0xA2 srom >= 11 u8 0xA8 } u8 elna2g { srom 8-10 0xBB } u8 elna5g { srom 8-10 0xBA } # 11n front-end specification u8 antswctl2g { srom 8-10 0xAE (&0xF8, >>3) } u8 triso2g { srom 8-10 0xAE (&0x7) } u8 pdetrange2g { srom 8-10 0xAF (&0xF8, >>3) } u8 extpagain2g { srom 8-10 0xAF (&0x6, >>1) } u8 tssipos2g { srom 8-10 0xAF (&0x1) } u8 antswctl5g { srom 8-10 0xB0 (&0xF8, >>3) } u8 triso5g { srom 8-10 0xB0 (&0x7) } u8 pdetrange5g { srom 8-10 0xB1 (&0xF8, >>3) } u8 extpagain5g { srom 8-10 0xB1 (&0x6, >>1) } u8 tssipos5g { srom 8-10 0xB1 (&0x1) } # FEM config u8 femctrl { sfmt decimal srom >= 11 0xAA (&0xF8, >>3) } u8 papdcap2g { sfmt decimal srom >= 11 0xAA (&0x4, >>2) } u8 tworangetssi2g { sfmt decimal srom >= 11 0xAA (&0x2, >>1) } u8 pdgain2g { sfmt decimal srom >= 11 u16 0xAA (&0x1F0, >>4) } u8 epagain2g { sfmt decimal srom >= 11 0xAB (&0xE, >>1) } u8 tssiposslope2g { sfmt decimal srom >= 11 0xAB (&0x1) } u8 gainctrlsph { sfmt decimal srom >= 11 0xAC (&0xF8, >>3) } u8 papdcap5g { sfmt decimal srom >= 11 0xAC (&0x4, >>2) } u8 tworangetssi5g { sfmt decimal srom >= 11 0xAC (&0x2, >>1) } u8 pdgain5g { sfmt decimal srom >= 11 u16 0xAC (&0x1F0, >>4) } u8 epagain5g { sfmt decimal srom >= 11 0xAD (&0xE, >>1) } u8 tssiposslope5g { sfmt decimal srom >= 11 0xAD (&0x1) } # LED duty cycle u8[2] leddc { sfmt led_dc all1 ignore srom 3 0x7C srom 4 0x5A srom 5-7 0x5A srom 8-10 0x9A srom >= 11 0x9E } # LED set u8 ledbh0 { all1 ignore srom 1-3 0x65 srom 4 0x57 srom 5-7 0x77 srom 8-10 0x97 srom >= 11 0x9B } u8 ledbh1 { all1 ignore srom 1-3 0x64 srom 4 0x56 srom 5-7 0x76 srom 8-10 0x96 srom >= 11 0x9A } u8 ledbh2 { all1 ignore srom 1-3 0x67 srom 4 0x59 srom 5-7 0x79 srom 8-10 0x99 srom >= 11 0x9D } u8 ledbh3 { all1 ignore srom 1-3 0x66 srom 4 0x58 srom 5-7 0x78 srom 8-10 0x98 srom >= 11 0x9C } # 2 bytes total # Additional power offset for Legacy Dup40 transmissions. # Applied in addition to legofdmbw20ulXpo, X=2g, 5gl, 5gm, or 5gh. # LSB nibble: 2G band, MSB nibble: 5G band high subband. # leg40dup5ghpo, leg40dup5gmpo, leg40dup5glpo, leg40dup2gpo # u16 legofdm40duppo { srom 9-10 0x196 } # 4 bytes each # OFDM power offsets for 20 MHz Legacy rates # (54, 48, 36, 24, 18, 12, 9, 6 Mbps) # legofdmbw202gpo legofdmbw20ul2gpo # u32 legofdmbw202gpo { srom 9-10 0x144 } u32 legofdmbw20ul2gpo { srom 9-10 0x148 } # 4 bytes each # 5G band: OFDM power offsets for 20 MHz Legacy rates # (54, 48, 36, 24, 18, 12, 9, 6 Mbps) # low subband : legofdmbw205glpo legofdmbw20ul2glpo # mid subband :legofdmbw205gmpo legofdmbw20ul2gmpo # high subband :legofdmbw205ghpo legofdmbw20ul2ghpo # u32 legofdmbw205glpo { srom 9-10 0x14C } u32 legofdmbw20ul5glpo { srom 9-10 0x150 } u32 legofdmbw205gmpo { srom 9-10 0x154 } u32 legofdmbw20ul5gmpo { srom 9-10 0x158 } u32 legofdmbw205ghpo { srom 9-10 0x15C } u32 legofdmbw20ul5ghpo { srom 9-10 0x160 } # mac addr override for the standard CIS LAN_NID u8[6] macaddr { sfmt macaddr srom 3 u8 0x4B, u8 0x4A, u8 0x4D, u8 0x4C, u8 0x4F, u8 0x4E srom 4 u8 0x4D, u8 0x4C, u8 0x4F, u8 0x4E, u8 0x51, u8 0x50 srom 5-7 u8 0x53, u8 0x52, u8 0x55, u8 0x54, u8 0x57, u8 0x56 srom 8-10 u8 0x8D, u8 0x8C, u8 0x8F, u8 0x8E, u8 0x91, u8 0x90 srom >= 11 u8 0x91, u8 0x90, u8 0x93, u8 0x92, u8 0x95, u8 0x94 } # 4 bytes each # mcs 0-7 power-offset. LSB nibble: m0, MSB nibble: m7 # mcsbw202gpo mcsbw20ul2gpo mcsbw402gpo # u32 mcsbw202gpo { srom 9-10 0x164 srom >= 11 0x154 } u32 mcsbw20ul2gpo { srom 9-10 0x168 } u32 mcsbw402gpo { srom 9-10 0x16C srom >= 11 0x158 } # 4 bytes each # 5G high subband mcs 0-7 power-offset. # LSB nibble: m0, MSB nibble: m7 # mcsbw205ghpo mcsbw20ul5ghpo mcsbw405ghpo # u32 mcsbw205ghpo { srom 9-10 0x188 srom >= 11 0x180 } u32 mcsbw20ul5ghpo { srom 9-10 0x18C } u32 mcsbw405ghpo { srom 9-10 0x190 srom >= 11 0x184 } # 4 bytes each # 5G low subband mcs 0-7 power-offset. # LSB nibble: m0, MSB nibble: m7 # mcsbw205glpo mcsbw20ul5glpo mcsbw405glpo # u32 mcsbw205glpo { srom 9-10 0x170 srom >= 11 0x160 } u32 mcsbw20ul5glpo { srom 9-10 0x174 } u32 mcsbw405glpo { srom 9-10 0x178 srom >= 11 0x164 } # 4 bytes each # 5G mid subband mcs 0-7 power-offset. # LSB nibble: m0, MSB nibble: m7 # mcsbw205gmpo mcsbw20ul5gmpo mcsbw405gmpo # u32 mcsbw205gmpo { srom 9-10 0x17C srom >= 11 0x170 } u32 mcsbw20ul5gmpo { srom 9-10 0x180 } u32 mcsbw405gmpo { srom 9-10 0x184 srom >= 11 0x174 } # 2 bytes total # mcs-32 power offset for each band/subband. # LSB nibble: 2G band, MSB nibble: # mcs322ghpo, mcs325gmpo, mcs325glpo, mcs322gpo # u16 mcs32po { srom 9-10 0x194 } u8 measpower { srom 8-10 0xB4 (&0xFE, >>1) srom >= 11 0xB0 (&0xFE, >>1) } u8 measpower1 { srom 8-10 0xBF (&0x7F) srom >= 11 0xBB (&0x7F) } u8 measpower2 { srom 8-10 u16 0xBE (&0x3F80, >>7) srom >= 11 u16 0xBA (&0x3F80, >>7) } u16 rawtempsense { srom 8-10 0xB4 (&0x1FF) srom >= 11 0xB0 (&0x1FF) } u8 noiselvl2ga0 { sfmt decimal srom 8-10 0x1AB (&0x1F) srom >= 11 0x1BD (&0x1F) } u8 noiselvl2ga1 { sfmt decimal srom 8-10 u16 0x1AA (&0x3E0, >>5) srom >= 11 u16 0x1BC (&0x3E0, >>5) } u8 noiselvl2ga2 { sfmt decimal srom 8-10 0x1AA (&0x7C, >>2) srom >= 11 0x1BC (&0x7C, >>2) } u8[4] noiselvl5ga0 { sfmt decimal srom >= 11 u8 0x1BF (&0x1F), u8 0x1C1 (&0x1F), u8 0x1C3 (&0x1F), u8 0x1C5 (&0x1F) } u8[4] noiselvl5ga1 { sfmt decimal srom >= 11 u16[4] 0x1BE (&0x3E0, >>5) } u8[4] noiselvl5ga2 { sfmt decimal srom >= 11 u8 0x1BE (&0x7C, >>2), u8 0x1C0 (&0x7C, >>2), u8 0x1C2 (&0x7C, >>2), u8 0x1C4 (&0x7C, >>2) } # paparambwver u8 paparambwver { sfmt decimal srom >= 11 0x190 (&0xF0, >>4) } # PA parameters: 8 (sromrev == 1) # or 9 (sromrev > 1) bytes # u16 pa0b0 { sfmt decimal srom 1-3 0x5E srom 8-10 0xC2 } u16 pa0b1 { sfmt decimal srom 1-3 0x60 srom 8-10 0xC4 } u16 pa0b2 { sfmt decimal srom 1-3 0x62 srom 8-10 0xC6 } u8 pa0itssit { sfmt decimal srom 1-3 0x71 srom 8-10 0xC0 } u8 pa0maxpwr { sfmt decimal srom 1-3 0x69 srom 8-10 0xC1 } u8 opo { srom 2-3 0x79 srom 8-10 0x143 } # 5G PA params u16 pa1b0 { sfmt decimal srom 1-3 0x6A srom 8-10 0xCC } u16 pa1b1 { sfmt decimal srom 1-3 0x6C srom 8-10 0xCE } u16 pa1b2 { sfmt decimal srom 1-3 0x6E srom 8-10 0xD0 } u16 pa1lob0 { sfmt decimal srom 2-3 0x3C srom 8-10 0xD2 } u16 pa1lob1 { sfmt decimal srom 2-3 0x3E srom 8-10 0xD4 } u16 pa1lob2 { sfmt decimal srom 2-3 0x40 srom 8-10 0xD6 } u16 pa1hib0 { sfmt decimal srom 2-3 0x42 srom 8-10 0xD8 } u16 pa1hib1 { sfmt decimal srom 2-3 0x44 srom 8-10 0xDA } u16 pa1hib2 { sfmt decimal srom 2-3 0x46 srom 8-10 0xDC } u8 pa1itssit { sfmt decimal srom 1-3 0x70 srom 8-10 0xC8 } u8 pa1maxpwr { sfmt decimal srom 1-3 0x68 srom 8-10 0xC9 } u8 pa1lomaxpwr { sfmt decimal srom 2-3 0x3A srom 8-10 0xCA } u8 pa1himaxpwr { sfmt decimal srom 2-3 0x3B srom 8-10 0xCB } u16 pdoffset40ma0 { srom >= 11 0xCA } u16 pdoffset40ma1 { srom >= 11 0xCC } u16 pdoffset40ma2 { srom >= 11 0xCE } u16 pdoffset80ma0 { srom >= 11 0xD0 } u16 pdoffset80ma1 { srom >= 11 0xD2 } u16 pdoffset80ma2 { srom >= 11 0xD4 } u8 pdoffset2g40ma0 { srom >= 11 0xC9 (&0xF) } u8 pdoffset2g40ma1 { srom >= 11 0xC9 (&0xF0, >>4) } u8 pdoffset2g40ma2 { srom >= 11 0xC8 (&0xF) } u8 pdoffset2g40mvalid { srom >= 11 0xC8 (&0x80, >>7) } # 40Mhz channel 2g/5g power offset u16 bw40po { srom 4-7 0x18E srom 8 0x196 } # 40Mhz channel dup 2g/5g power offset u16 bwduppo { srom 4-7 0x190 srom 8 0x198 } # cck2g/ofdm2g/ofdm5g power offset u16 cck2gpo { srom 4-7 0x138 srom 8 0x140 } u32 ofdm2gpo { srom 4-7 0x13A srom 8 0x142 } u32 ofdm5gpo { srom 4-7 0x13E srom 8 0x146 } u32 ofdm5glpo { srom 4-7 0x142 srom 8 0x14A } u32 ofdm5ghpo { srom 4-7 0x146 srom 8 0x14E } # cdd2g/5g power offset u16 cddpo { srom 4-7 0x18A srom 8 0x192 } # mcs2g power offset u16 mcs2gpo0 { srom 4-7 0x14A srom 8 0x152 } u16 mcs2gpo1 { srom 4-7 0x14C srom 8 0x154 } u16 mcs2gpo2 { srom 4-7 0x14E srom 8 0x156 } u16 mcs2gpo3 { srom 4-7 0x150 srom 8 0x158 } u16 mcs2gpo4 { srom 4-7 0x152 srom 8 0x15A } u16 mcs2gpo5 { srom 4-7 0x154 srom 8 0x15C } u16 mcs2gpo6 { srom 4-7 0x156 srom 8 0x15E } u16 mcs2gpo7 { srom 4-7 0x158 srom 8 0x160 } # mcs5g low-high band power offset u16 mcs5glpo0 { srom 4-7 0x16A srom 8 0x172 } u16 mcs5glpo1 { srom 4-7 0x16C srom 8 0x174 } u16 mcs5glpo2 { srom 4-7 0x16E srom 8 0x176 } u16 mcs5glpo3 { srom 4-7 0x170 srom 8 0x178 } u16 mcs5glpo4 { srom 4-7 0x172 srom 8 0x17A } u16 mcs5glpo5 { srom 4-7 0x174 srom 8 0x17C } u16 mcs5glpo6 { srom 4-7 0x176 srom 8 0x17E } u16 mcs5glpo7 { srom 4-7 0x178 srom 8 0x180 } u16 mcs5ghpo0 { srom 4-7 0x17A srom 8 0x182 } u16 mcs5ghpo1 { srom 4-7 0x17C srom 8 0x184 } u16 mcs5ghpo2 { srom 4-7 0x17E srom 8 0x186 } u16 mcs5ghpo3 { srom 4-7 0x180 srom 8 0x188 } u16 mcs5ghpo4 { srom 4-7 0x182 srom 8 0x18A } u16 mcs5ghpo5 { srom 4-7 0x184 srom 8 0x18C } u16 mcs5ghpo6 { srom 4-7 0x186 srom 8 0x18E } u16 mcs5ghpo7 { srom 4-7 0x188 srom 8 0x190 } # mcs5g mid band power offset u16 mcs5gpo0 { srom 4-7 0x15A srom 8 0x162 } u16 mcs5gpo1 { srom 4-7 0x15C srom 8 0x164 } u16 mcs5gpo2 { srom 4-7 0x15E srom 8 0x166 } u16 mcs5gpo3 { srom 4-7 0x160 srom 8 0x168 } u16 mcs5gpo4 { srom 4-7 0x162 srom 8 0x16A } u16 mcs5gpo5 { srom 4-7 0x164 srom 8 0x16C } u16 mcs5gpo6 { srom 4-7 0x166 srom 8 0x16E } u16 mcs5gpo7 { srom 4-7 0x168 srom 8 0x170 } # stbc2g/5g power offset u16 stbcpo { srom 4-7 0x18C srom 8 0x194 } u8 regrev { srom 3 0x78 srom 4 0x55 srom 5-7 0x47 srom 8-10 0x95 srom >= 11 0x99 } # 4328 2G RSSI mid pt sel & board switch arch, # 2 bytes, rev 3. # u8 rssismf2g { srom 3 0x51 (&0xF) srom 8-10 0xA5 (&0xF) } u8 rssismc2g { srom 3 0x51 (&0xF0, >>4) srom 8-10 0xA5 (&0xF0, >>4) } u8 rssisav2g { srom 3 0x50 (&0x7) srom 8-10 0xA4 (&0x7) } u8 bxa2g { srom 3 0x50 (&0x18, >>3) srom 8-10 0xA4 (&0x18, >>3) } # 4328 5G RSSI mid pt sel & board switch arch, # 2 bytes, rev 3. # u8 rssismf5g { srom 3 0x53 (&0xF) srom 8-10 0xA7 (&0xF) } u8 rssismc5g { srom 3 0x53 (&0xF0, >>4) srom 8-10 0xA7 (&0xF0, >>4) } u8 rssisav5g { srom 3 0x52 (&0x7) srom 8-10 0xA6 (&0x7) } u8 bxa5g { srom 3 0x52 (&0x18, >>3) srom 8-10 0xA6 (&0x18, >>3) } u8 rxgainerr2ga0 { srom 8-10 0x19B (&0x3F) srom >= 11 0x1C7 (&0x3F) } u8 rxgainerr2ga1 { srom 8-10 u16 0x19A (&0x7C0, >>6) srom >= 11 u16 0x1C6 (&0x7C0, >>6) } u8 rxgainerr2ga2 { srom 8-10 0x19A (&0xF8, >>3) srom >= 11 0x1C6 (&0xF8, >>3) } u8[4] rxgainerr5ga0 { srom >= 11 u8 0x1C9 (&0x3F), u8 0x1CB (&0x3F), u8 0x1CD (&0x3F), u8 0x1CF (&0x3F) } u8[4] rxgainerr5ga1 { srom >= 11 u16[4] 0x1C8 (&0x7C0, >>6) } u8[4] rxgainerr5ga2 { srom >= 11 u8 0x1C8 (&0xF8, >>3), u8 0x1CA (&0xF8, >>3), u8 0x1CC (&0xF8, >>3), u8 0x1CE (&0xF8, >>3) } u8 rxgainerr5gha0 { srom 8-10 0x1A1 (&0x3F) } u8 rxgainerr5gha1 { srom 8-10 u16 0x1A0 (&0x7C0, >>6) } u8 rxgainerr5gha2 { srom 8-10 0x1A0 (&0xF8, >>3) } u8 rxgainerr5gla0 { srom 8-10 0x19D (&0x3F) } u8 rxgainerr5gla1 { srom 8-10 u16 0x19C (&0x7C0, >>6) } u8 rxgainerr5gla2 { srom 8-10 0x19C (&0xF8, >>3) } u8 rxgainerr5gma0 { srom 8-10 0x19F (&0x3F) } u8 rxgainerr5gma1 { srom 8-10 u16 0x19E (&0x7C0, >>6) } u8 rxgainerr5gma2 { srom 8-10 0x19E (&0xF8, >>3) } u8 rxgainerr5gua0 { srom 8-10 0x1A3 (&0x3F) } u8 rxgainerr5gua1 { srom 8-10 u16 0x1A2 (&0x7C0, >>6) } u8 rxgainerr5gua2 { srom 8-10 0x1A2 (&0xF8, >>3) } # 4328 2G RX power offset i8 rxpo2g { sfmt decimal srom 3 0x5B srom 8-10 0xAD } # 4328 5G RX power offset i8 rxpo5g { sfmt decimal srom 3 0x5A srom 8-10 0xAC } u16 subband5gver { srom 8-10 u8 0x1A5 (&0x7) srom >= 11 0xD6 } # 2 bytes # byte1 tempthresh # byte2 period(msb 4 bits) | hysterisis(lsb 4 bits) # u8 tempthresh { srom 8-10 0xB2 srom >= 11 0xAE } u8 temps_period { sfmt decimal srom 8-10 0xBC (&0xF) srom >= 11 0xB8 (&0xF) } u8 temps_hysteresis { sfmt decimal srom 8-10 0xBC (&0xF0, >>4) srom >= 11 0xB8 (&0xF0, >>4) } u8 tempoffset { sfmt decimal srom 8-10 0xB3 srom >= 11 0xAF } u8 tempsense_slope { srom 8-10 0xB7 srom >= 11 0xB3 } u8 tempcorrx { srom 8-10 0xB6 (&0xFC, >>2) srom >= 11 0xB2 (&0xFC, >>2) } u8 tempsense_option { srom 8-10 0xB6 (&0x3) srom >= 11 0xB2 (&0x3) } u8 phycal_tempdelta { sfmt decimal srom 8-10 0xBD srom >= 11 0xB9 } # 4328 2G TR isolation, 1 byte u8 tri2g { srom 3 0x55 srom 8-10 0xA9 } # 4328 5G TR isolation, 3 bytes u8 tri5gl { srom 3 0x57 srom 8-10 0xAB } u8 tri5g { srom 3 0x54 srom 8-10 0xA8 } u8 tri5gh { srom 3 0x56 srom 8-10 0xAA } # phy txbf rpcalvars u16 rpcal2g { srom >= 11 0x16C } u16 rpcal5gb0 { srom >= 11 0x16E } u16 rpcal5gb1 { srom >= 11 0x17C } u16 rpcal5gb2 { srom >= 11 0x17E } u16 rpcal5gb3 { srom >= 11 0x18C } # Crystal frequency in kilohertz u32 xtalfreq { sfmt decimal srom >= 11 u16 0xB4 } # N-PHY tx power workaround u8 txpid2ga0 { srom 4-7 0x63 } u8 txpid2ga1 { srom 4-7 0x62 } u8 txpid2ga2 { srom 4-7 0x65 } u8 txpid2ga3 { srom 4-7 0x64 } u8 txpid5ga0 { srom 4-7 0x67 } u8 txpid5ga1 { srom 4-7 0x66 } u8 txpid5ga2 { srom 4-7 0x69 } u8 txpid5ga3 { srom 4-7 0x68 } u8 txpid5gha0 { srom 4-7 0x6F } u8 txpid5gha1 { srom 4-7 0x6E } u8 txpid5gha2 { srom 4-7 0x71 } u8 txpid5gha3 { srom 4-7 0x70 } u8 txpid5gla0 { srom 4-7 0x6B } u8 txpid5gla1 { srom 4-7 0x6A } u8 txpid5gla2 { srom 4-7 0x6D } u8 txpid5gla3 { srom 4-7 0x6C } u16 cckPwrOffset { srom 10 0x1B4 } u8[6] et1macaddr { sfmt macaddr srom 0-2 u8 0x55, u8 0x54, u8 0x57, u8 0x56, u8 0x59, u8 0x58 } u8 eu_edthresh2g { srom 8 0x1A9 srom 9 0x199 srom 10 0x199 srom 11 0x1D1 } u8 eu_edthresh5g { srom 8 0x1A8 srom 9 0x198 srom 10 0x198 srom 11 0x1D0 } u8 freqoffset_corr { srom 8-10 0xB9 (&0xF) } u8 hw_iqcal_en { srom 8-10 0xB9 (&0x20, >>5) } u8[6] il0macaddr { sfmt macaddr srom 0-2 u8 0x49, u8 0x48, u8 0x51, u8 0x50, u8 0x53, u8 0x52 } u8 iqcal_swp_dis { srom 8-10 0xB9 (&0x10, >>4) } u8 noisecaloffset { srom 8-9 0x1B5 } u8 noisecaloffset5g { srom 8-9 0x1B4 } u8 noiselvl5gha0 { srom 8-10 0x1B1 (&0x1F) } u8 noiselvl5gha1 { srom 8-10 u16 0x1B0 (&0x3E0, >>5) } u8 noiselvl5gha2 { srom 8-10 0x1B0 (&0x7C, >>2) } u8 noiselvl5gla0 { srom 8-10 0x1AD (&0x1F) } u8 noiselvl5gla1 { srom 8-10 u16 0x1AC (&0x3E0, >>5) } u8 noiselvl5gla2 { srom 8-10 0x1AC (&0x7C, >>2) } u8 noiselvl5gma0 { srom 8-10 0x1AF (&0x1F) } u8 noiselvl5gma1 { srom 8-10 u16 0x1AE (&0x3E0, >>5) } u8 noiselvl5gma2 { srom 8-10 0x1AE (&0x7C, >>2) } u8 noiselvl5gua0 { srom 8-10 0x1B3 (&0x1F) } u8 noiselvl5gua1 { srom 8-10 u16 0x1B2 (&0x3E0, >>5) } u8 noiselvl5gua2 { srom 8-10 0x1B2 (&0x7C, >>2) } u8 pcieingress_war { srom 8-10 0x1A7 (&0xF) } u8 pdoffsetcckma0 { srom >= 11 0x18F (&0xF) } u8 pdoffsetcckma1 { srom >= 11 0x18F (&0xF0, >>4) } u8 pdoffsetcckma2 { srom >= 11 0x18E (&0xF) } u8 sar2g { srom 9-10 0x1A9 srom >= 11 0x1BB } u8 sar5g { srom 9-10 0x1A8 srom >= 11 0x1BA } u32[5] swctrlmap_2g { srom 10 u32[4] 0x1B8, u16 0x1C8 } u16 tssifloor2g { srom >= 11 0xBE (&0x3FF) } u16[4] tssifloor5g { srom >= 11 0xC0 (&0x3FF) } u8 txidxcap2g { srom >= 11 u16 0x1A8 (&0xFF0, >>4) } u8 txidxcap5g { srom >= 11 u16 0x1AC (&0xFF0, >>4) } # # Any variables defined within a `struct` block will be interpreted relative to # the provided array of SPROM base addresses; this is used to define # a common layout defined at the given base addresses. # # To produce SPROM variable names matching those used in the Broadcom HND # ASCII 'key=value\0' NVRAM, the index number of the variable's # struct instance will be appended (e.g., given a variable of noiselvl5ga, the # generated variable instances will be named noiselvl5ga0, noiselvl5ga1, # noiselvl5ga2, noiselvl5ga3 ...) # # PHY chain[0-4] parameters struct phy_chains[] { srom 4-7 [0x080, 0x0AE, 0x0DC, 0x10A] srom 8-10 [0x0C0, 0x0E0, 0x100, 0x120] srom >= 11 [0x0D8, 0x100, 0x128] # AC-PHY PA parameters u8[4] maxp5ga { srom 4-7 u8 0xB srom 8-10 u8 0x9 srom >= 11 u8 0xD, u8 0xC, u8 0xF, u8 0xE } u16[3] pa2ga { srom >= 11 0x2 } u8 maxp2ga { srom 4-7 0x1 srom 8-10 0x1 srom >= 11 0x1 } u16[12] pa5ga { srom >= 11 0x10 } # AC-PHY rxgains u8 rxgains5ghtrelnabypa { srom >= 11 0x8 (&0x80, >>7) } u8 rxgains5ghelnagaina { srom >= 11 0x8 (&0x7) } u8 rxgains5gelnagaina { srom >= 11 0xA (&0x7) } u8 rxgains5gmtrelnabypa { srom >= 11 0x9 (&0x80, >>7) } u8 rxgains2gtrelnabypa { srom >= 11 0xB (&0x80, >>7) } u8 rxgains5gmtrisoa { srom >= 11 0x9 (&0x78, >>3) } u8 rxgains5gmelnagaina { srom >= 11 0x9 (&0x7) } u8 rxgains2gelnagaina { srom >= 11 0xB (&0x7) } u8 rxgains5gtrisoa { srom >= 11 0xA (&0x78, >>3) } u8 rxgains5gtrelnabypa { srom >= 11 0xA (&0x80, >>7) } u8 rxgains2gtrisoa { srom >= 11 0xB (&0x78, >>3) } u8 rxgains5ghtrisoa { srom >= 11 0x8 (&0x78, >>3) } # 11n PA parameters u16 pa5gw2a { srom 4-7 0x12 srom 8-10 0x10 } u16 pa5ghw1a { srom 4-7 0x20 srom 8-10 0x1A } u16 pa5glw3a { srom 4-7 0x1C } u16 pa5glw1a { srom 4-7 0x18 srom 8-10 0x14 } u16 pa5gw1a { srom 4-7 0x10 srom 8-10 0xE } u16 pa5glw0a { srom 4-7 0x16 srom 8-10 0x12 } u16 pa5gw3a { srom 4-7 0x14 } u16 pa5glw2a { srom 4-7 0x1A srom 8-10 0x16 } u16 pa5ghw3a { srom 4-7 0x24 } u16 pa5gw0a { srom 4-7 0xE srom 8-10 0xC } u8 maxp5gha { srom 4-7 0xD srom 8-10 0xB } u16 pa5ghw2a { srom 4-7 0x22 srom 8-10 0x1C } u16 pa5ghw0a { srom 4-7 0x1E srom 8-10 0x18 } u16 pa2gw3a { srom 4-7 0x8 } u16 pa2gw2a { srom 4-7 0x6 srom 8-10 0x6 } u16 pa2gw1a { srom 4-7 0x4 srom 8-10 0x4 } u16 pa2gw0a { srom 4-7 0x2 srom 8-10 0x2 } u8 maxp5gla { srom 4-7 0xC srom 8-10 0xA } u8 itt5ga { srom 4-7 0xA srom 8-10 0x8 } u8 itt2ga { srom 4-7 0x0 srom 8-10 0x0 } }