/* * Copyright (c) 2008-2009 Atheros Communications Inc. * * 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. */ /** * DOC: Programming Atheros 802.11n analog front end radios * * AR5416 MAC based PCI devices and AR518 MAC based PCI-Express * devices have either an external AR2133 analog front end radio for single * band 2.4 GHz communication or an AR5133 analog front end radio for dual * band 2.4 GHz / 5 GHz communication. * * All devices after the AR5416 and AR5418 family starting with the AR9280 * have their analog front radios, MAC/BB and host PCIe/USB interface embedded * into a single-chip and require less programming. * * The following single-chips exist with a respective embedded radio: * * AR9280 - 11n dual-band 2x2 MIMO for PCIe * AR9281 - 11n single-band 1x2 MIMO for PCIe * AR9285 - 11n single-band 1x1 for PCIe * AR9287 - 11n single-band 2x2 MIMO for PCIe * * AR9220 - 11n dual-band 2x2 MIMO for PCI * AR9223 - 11n single-band 2x2 MIMO for PCI * * AR9287 - 11n single-band 1x1 MIMO for USB */ #include #include "hw.h" /** * ath9k_hw_write_regs - ?? * * @ah: atheros hardware structure * @freqIndex: * @regWrites: * * Used for both the chipsets with an external AR2133/AR5133 radios and * single-chip devices. */ void ath9k_hw_write_regs(struct ath_hw *ah, u32 freqIndex, int regWrites) { REG_WRITE_ARRAY(&ah->iniBB_RfGain, freqIndex, regWrites); } /** * ath9k_hw_ar9280_set_channel - set channel on single-chip device * @ah: atheros hardware structure * @chan: * * This is the function to change channel on single-chip devices, that is * all devices after ar9280. * * This function takes the channel value in MHz and sets * hardware channel value. Assumes writes have been enabled to analog bus. * * Actual Expression, * * For 2GHz channel, * Channel Frequency = (3/4) * freq_ref * (chansel[8:0] + chanfrac[16:0]/2^17) * (freq_ref = 40MHz) * * For 5GHz channel, * Channel Frequency = (3/2) * freq_ref * (chansel[8:0] + chanfrac[16:0]/2^10) * (freq_ref = 40MHz/(24>>amodeRefSel)) */ int ath9k_hw_ar9280_set_channel(struct ath_hw *ah, struct ath9k_channel *chan) { u16 bMode, fracMode, aModeRefSel = 0; u32 freq, ndiv, channelSel = 0, channelFrac = 0, reg32 = 0; struct chan_centers centers; u32 refDivA = 24; ath9k_hw_get_channel_centers(ah, chan, ¢ers); freq = centers.synth_center; reg32 = REG_READ(ah, AR_PHY_SYNTH_CONTROL); reg32 &= 0xc0000000; if (freq < 4800) { /* 2 GHz, fractional mode */ u32 txctl; int regWrites = 0; bMode = 1; fracMode = 1; aModeRefSel = 0; channelSel = (freq * 0x10000) / 15; if (AR_SREV_9287_11_OR_LATER(ah)) { if (freq == 2484) { /* Enable channel spreading for channel 14 */ REG_WRITE_ARRAY(&ah->iniCckfirJapan2484, 1, regWrites); } else { REG_WRITE_ARRAY(&ah->iniCckfirNormal, 1, regWrites); } } else { txctl = REG_READ(ah, AR_PHY_CCK_TX_CTRL); if (freq == 2484) { /* Enable channel spreading for channel 14 */ REG_WRITE(ah, AR_PHY_CCK_TX_CTRL, txctl | AR_PHY_CCK_TX_CTRL_JAPAN); } else { REG_WRITE(ah, AR_PHY_CCK_TX_CTRL, txctl &~ AR_PHY_CCK_TX_CTRL_JAPAN); } } } else { bMode = 0; fracMode = 0; switch(ah->eep_ops->get_eeprom(ah, EEP_FRAC_N_5G)) { case 0: if ((freq % 20) == 0) { aModeRefSel = 3; } else if ((freq % 10) == 0) { aModeRefSel = 2; } if (aModeRefSel) break; case 1: default: aModeRefSel = 0; /* * Enable 2G (fractional) mode for channels * which are 5MHz spaced. */ fracMode = 1; refDivA = 1; channelSel = (freq * 0x8000) / 15; /* RefDivA setting */ REG_RMW_FIELD(ah, AR_AN_SYNTH9, AR_AN_SYNTH9_REFDIVA, refDivA); } if (!fracMode) { ndiv = (freq * (refDivA >> aModeRefSel)) / 60; channelSel = ndiv & 0x1ff; channelFrac = (ndiv & 0xfffffe00) * 2; channelSel = (channelSel << 17) | channelFrac; } } reg32 = reg32 | (bMode << 29) | (fracMode << 28) | (aModeRefSel << 26) | (channelSel); REG_WRITE(ah, AR_PHY_SYNTH_CONTROL, reg32); ah->curchan = chan; ah->curchan_rad_index = -1; return 0; } /** * ath9k_hw_9280_spur_mitigate - convert baseband spur frequency * @ah: atheros hardware structure * @chan: * * For single-chip solutions. Converts to baseband spur frequency given the * input channel frequency and compute register settings below. */ void ath9k_hw_9280_spur_mitigate(struct ath_hw *ah, struct ath9k_channel *chan) { int bb_spur = AR_NO_SPUR; int freq; int bin, cur_bin; int bb_spur_off, spur_subchannel_sd; int spur_freq_sd; int spur_delta_phase; int denominator; int upper, lower, cur_vit_mask; int tmp, newVal; int i; int pilot_mask_reg[4] = { AR_PHY_TIMING7, AR_PHY_TIMING8, AR_PHY_PILOT_MASK_01_30, AR_PHY_PILOT_MASK_31_60 }; int chan_mask_reg[4] = { AR_PHY_TIMING9, AR_PHY_TIMING10, AR_PHY_CHANNEL_MASK_01_30, AR_PHY_CHANNEL_MASK_31_60 }; int inc[4] = { 0, 100, 0, 0 }; struct chan_centers centers; int8_t mask_m[123]; int8_t mask_p[123]; int8_t mask_amt; int tmp_mask; int cur_bb_spur; bool is2GHz = IS_CHAN_2GHZ(chan); memset(&mask_m, 0, sizeof(int8_t) * 123); memset(&mask_p, 0, sizeof(int8_t) * 123); ath9k_hw_get_channel_centers(ah, chan, ¢ers); freq = centers.synth_center; ah->config.spurmode = SPUR_ENABLE_EEPROM; for (i = 0; i < AR_EEPROM_MODAL_SPURS; i++) { cur_bb_spur = ah->eep_ops->get_spur_channel(ah, i, is2GHz); if (is2GHz) cur_bb_spur = (cur_bb_spur / 10) + AR_BASE_FREQ_2GHZ; else cur_bb_spur = (cur_bb_spur / 10) + AR_BASE_FREQ_5GHZ; if (AR_NO_SPUR == cur_bb_spur) break; cur_bb_spur = cur_bb_spur - freq; if (IS_CHAN_HT40(chan)) { if ((cur_bb_spur > -AR_SPUR_FEEQ_BOUND_HT40) && (cur_bb_spur < AR_SPUR_FEEQ_BOUND_HT40)) { bb_spur = cur_bb_spur; break; } } else if ((cur_bb_spur > -AR_SPUR_FEEQ_BOUND_HT20) && (cur_bb_spur < AR_SPUR_FEEQ_BOUND_HT20)) { bb_spur = cur_bb_spur; break; } } if (AR_NO_SPUR == bb_spur) { REG_CLR_BIT(ah, AR_PHY_FORCE_CLKEN_CCK, AR_PHY_FORCE_CLKEN_CCK_MRC_MUX); return; } else { REG_CLR_BIT(ah, AR_PHY_FORCE_CLKEN_CCK, AR_PHY_FORCE_CLKEN_CCK_MRC_MUX); } bin = bb_spur * 320; tmp = REG_READ(ah, AR_PHY_TIMING_CTRL4(0)); newVal = tmp | (AR_PHY_TIMING_CTRL4_ENABLE_SPUR_RSSI | AR_PHY_TIMING_CTRL4_ENABLE_SPUR_FILTER | AR_PHY_TIMING_CTRL4_ENABLE_CHAN_MASK | AR_PHY_TIMING_CTRL4_ENABLE_PILOT_MASK); REG_WRITE(ah, AR_PHY_TIMING_CTRL4(0), newVal); newVal = (AR_PHY_SPUR_REG_MASK_RATE_CNTL | AR_PHY_SPUR_REG_ENABLE_MASK_PPM | AR_PHY_SPUR_REG_MASK_RATE_SELECT | AR_PHY_SPUR_REG_ENABLE_VIT_SPUR_RSSI | SM(SPUR_RSSI_THRESH, AR_PHY_SPUR_REG_SPUR_RSSI_THRESH)); REG_WRITE(ah, AR_PHY_SPUR_REG, newVal); if (IS_CHAN_HT40(chan)) { if (bb_spur < 0) { spur_subchannel_sd = 1; bb_spur_off = bb_spur + 10; } else { spur_subchannel_sd = 0; bb_spur_off = bb_spur - 10; } } else { spur_subchannel_sd = 0; bb_spur_off = bb_spur; } if (IS_CHAN_HT40(chan)) spur_delta_phase = ((bb_spur * 262144) / 10) & AR_PHY_TIMING11_SPUR_DELTA_PHASE; else spur_delta_phase = ((bb_spur * 524288) / 10) & AR_PHY_TIMING11_SPUR_DELTA_PHASE; denominator = IS_CHAN_2GHZ(chan) ? 44 : 40; spur_freq_sd = ((bb_spur_off * 2048) / denominator) & 0x3ff; newVal = (AR_PHY_TIMING11_USE_SPUR_IN_AGC | SM(spur_freq_sd, AR_PHY_TIMING11_SPUR_FREQ_SD) | SM(spur_delta_phase, AR_PHY_TIMING11_SPUR_DELTA_PHASE)); REG_WRITE(ah, AR_PHY_TIMING11, newVal); newVal = spur_subchannel_sd << AR_PHY_SFCORR_SPUR_SUBCHNL_SD_S; REG_WRITE(ah, AR_PHY_SFCORR_EXT, newVal); cur_bin = -6000; upper = bin + 100; lower = bin - 100; for (i = 0; i < 4; i++) { int pilot_mask = 0; int chan_mask = 0; int bp = 0; for (bp = 0; bp < 30; bp++) { if ((cur_bin > lower) && (cur_bin < upper)) { pilot_mask = pilot_mask | 0x1 << bp; chan_mask = chan_mask | 0x1 << bp; } cur_bin += 100; } cur_bin += inc[i]; REG_WRITE(ah, pilot_mask_reg[i], pilot_mask); REG_WRITE(ah, chan_mask_reg[i], chan_mask); } cur_vit_mask = 6100; upper = bin + 120; lower = bin - 120; for (i = 0; i < 123; i++) { if ((cur_vit_mask > lower) && (cur_vit_mask < upper)) { /* workaround for gcc bug #37014 */ volatile int tmp_v = abs(cur_vit_mask - bin); if (tmp_v < 75) mask_amt = 1; else mask_amt = 0; if (cur_vit_mask < 0) mask_m[abs(cur_vit_mask / 100)] = mask_amt; else mask_p[cur_vit_mask / 100] = mask_amt; } cur_vit_mask -= 100; } tmp_mask = (mask_m[46] << 30) | (mask_m[47] << 28) | (mask_m[48] << 26) | (mask_m[49] << 24) | (mask_m[50] << 22) | (mask_m[51] << 20) | (mask_m[52] << 18) | (mask_m[53] << 16) | (mask_m[54] << 14) | (mask_m[55] << 12) | (mask_m[56] << 10) | (mask_m[57] << 8) | (mask_m[58] << 6) | (mask_m[59] << 4) | (mask_m[60] << 2) | (mask_m[61] << 0); REG_WRITE(ah, AR_PHY_BIN_MASK_1, tmp_mask); REG_WRITE(ah, AR_PHY_VIT_MASK2_M_46_61, tmp_mask); tmp_mask = (mask_m[31] << 28) | (mask_m[32] << 26) | (mask_m[33] << 24) | (mask_m[34] << 22) | (mask_m[35] << 20) | (mask_m[36] << 18) | (mask_m[37] << 16) | (mask_m[48] << 14) | (mask_m[39] << 12) | (mask_m[40] << 10) | (mask_m[41] << 8) | (mask_m[42] << 6) | (mask_m[43] << 4) | (mask_m[44] << 2) | (mask_m[45] << 0); REG_WRITE(ah, AR_PHY_BIN_MASK_2, tmp_mask); REG_WRITE(ah, AR_PHY_MASK2_M_31_45, tmp_mask); tmp_mask = (mask_m[16] << 30) | (mask_m[16] << 28) | (mask_m[18] << 26) | (mask_m[18] << 24) | (mask_m[20] << 22) | (mask_m[20] << 20) | (mask_m[22] << 18) | (mask_m[22] << 16) | (mask_m[24] << 14) | (mask_m[24] << 12) | (mask_m[25] << 10) | (mask_m[26] << 8) | (mask_m[27] << 6) | (mask_m[28] << 4) | (mask_m[29] << 2) | (mask_m[30] << 0); REG_WRITE(ah, AR_PHY_BIN_MASK_3, tmp_mask); REG_WRITE(ah, AR_PHY_MASK2_M_16_30, tmp_mask); tmp_mask = (mask_m[0] << 30) | (mask_m[1] << 28) | (mask_m[2] << 26) | (mask_m[3] << 24) | (mask_m[4] << 22) | (mask_m[5] << 20) | (mask_m[6] << 18) | (mask_m[7] << 16) | (mask_m[8] << 14) | (mask_m[9] << 12) | (mask_m[10] << 10) | (mask_m[11] << 8) | (mask_m[12] << 6) | (mask_m[13] << 4) | (mask_m[14] << 2) | (mask_m[15] << 0); REG_WRITE(ah, AR_PHY_MASK_CTL, tmp_mask); REG_WRITE(ah, AR_PHY_MASK2_M_00_15, tmp_mask); tmp_mask = (mask_p[15] << 28) | (mask_p[14] << 26) | (mask_p[13] << 24) | (mask_p[12] << 22) | (mask_p[11] << 20) | (mask_p[10] << 18) | (mask_p[9] << 16) | (mask_p[8] << 14) | (mask_p[7] << 12) | (mask_p[6] << 10) | (mask_p[5] << 8) | (mask_p[4] << 6) | (mask_p[3] << 4) | (mask_p[2] << 2) | (mask_p[1] << 0); REG_WRITE(ah, AR_PHY_BIN_MASK2_1, tmp_mask); REG_WRITE(ah, AR_PHY_MASK2_P_15_01, tmp_mask); tmp_mask = (mask_p[30] << 28) | (mask_p[29] << 26) | (mask_p[28] << 24) | (mask_p[27] << 22) | (mask_p[26] << 20) | (mask_p[25] << 18) | (mask_p[24] << 16) | (mask_p[23] << 14) | (mask_p[22] << 12) | (mask_p[21] << 10) | (mask_p[20] << 8) | (mask_p[19] << 6) | (mask_p[18] << 4) | (mask_p[17] << 2) | (mask_p[16] << 0); REG_WRITE(ah, AR_PHY_BIN_MASK2_2, tmp_mask); REG_WRITE(ah, AR_PHY_MASK2_P_30_16, tmp_mask); tmp_mask = (mask_p[45] << 28) | (mask_p[44] << 26) | (mask_p[43] << 24) | (mask_p[42] << 22) | (mask_p[41] << 20) | (mask_p[40] << 18) | (mask_p[39] << 16) | (mask_p[38] << 14) | (mask_p[37] << 12) | (mask_p[36] << 10) | (mask_p[35] << 8) | (mask_p[34] << 6) | (mask_p[33] << 4) | (mask_p[32] << 2) | (mask_p[31] << 0); REG_WRITE(ah, AR_PHY_BIN_MASK2_3, tmp_mask); REG_WRITE(ah, AR_PHY_MASK2_P_45_31, tmp_mask); tmp_mask = (mask_p[61] << 30) | (mask_p[60] << 28) | (mask_p[59] << 26) | (mask_p[58] << 24) | (mask_p[57] << 22) | (mask_p[56] << 20) | (mask_p[55] << 18) | (mask_p[54] << 16) | (mask_p[53] << 14) | (mask_p[52] << 12) | (mask_p[51] << 10) | (mask_p[50] << 8) | (mask_p[49] << 6) | (mask_p[48] << 4) | (mask_p[47] << 2) | (mask_p[46] << 0); REG_WRITE(ah, AR_PHY_BIN_MASK2_4, tmp_mask); REG_WRITE(ah, AR_PHY_MASK2_P_61_45, tmp_mask); } /* All code below is for non single-chip solutions */ /** * ath9k_phy_modify_rx_buffer() - perform analog swizzling of parameters * @rfbuf: * @reg32: * @numBits: * @firstBit: * @column: * * Performs analog "swizzling" of parameters into their location. * Used on external AR2133/AR5133 radios. */ static void ath9k_phy_modify_rx_buffer(u32 *rfBuf, u32 reg32, u32 numBits, u32 firstBit, u32 column) { u32 tmp32, mask, arrayEntry, lastBit; int32_t bitPosition, bitsLeft; tmp32 = ath9k_hw_reverse_bits(reg32, numBits); arrayEntry = (firstBit - 1) / 8; bitPosition = (firstBit - 1) % 8; bitsLeft = numBits; while (bitsLeft > 0) { lastBit = (bitPosition + bitsLeft > 8) ? 8 : bitPosition + bitsLeft; mask = (((1 << lastBit) - 1) ^ ((1 << bitPosition) - 1)) << (column * 8); rfBuf[arrayEntry] &= ~mask; rfBuf[arrayEntry] |= ((tmp32 << bitPosition) << (column * 8)) & mask; bitsLeft -= 8 - bitPosition; tmp32 = tmp32 >> (8 - bitPosition); bitPosition = 0; arrayEntry++; } } /* * Fix on 2.4 GHz band for orientation sensitivity issue by increasing * rf_pwd_icsyndiv. * * Theoretical Rules: * if 2 GHz band * if forceBiasAuto * if synth_freq < 2412 * bias = 0 * else if 2412 <= synth_freq <= 2422 * bias = 1 * else // synth_freq > 2422 * bias = 2 * else if forceBias > 0 * bias = forceBias & 7 * else * no change, use value from ini file * else * no change, invalid band * * 1st Mod: * 2422 also uses value of 2 * * * 2nd Mod: * Less than 2412 uses value of 0, 2412 and above uses value of 2 */ static void ath9k_hw_force_bias(struct ath_hw *ah, u16 synth_freq) { struct ath_common *common = ath9k_hw_common(ah); u32 tmp_reg; int reg_writes = 0; u32 new_bias = 0; if (!AR_SREV_5416(ah) || synth_freq >= 3000) { return; } BUG_ON(AR_SREV_9280_10_OR_LATER(ah)); if (synth_freq < 2412) new_bias = 0; else if (synth_freq < 2422) new_bias = 1; else new_bias = 2; /* pre-reverse this field */ tmp_reg = ath9k_hw_reverse_bits(new_bias, 3); ath_print(common, ATH_DBG_CONFIG, "Force rf_pwd_icsyndiv to %1d on %4d\n", new_bias, synth_freq); /* swizzle rf_pwd_icsyndiv */ ath9k_phy_modify_rx_buffer(ah->analogBank6Data, tmp_reg, 3, 181, 3); /* write Bank 6 with new params */ REG_WRITE_RF_ARRAY(&ah->iniBank6, ah->analogBank6Data, reg_writes); } /** * ath9k_hw_set_channel - tune to a channel on the external AR2133/AR5133 radios * @ah: atheros hardware stucture * @chan: * * For the external AR2133/AR5133 radios, takes the MHz channel value and set * the channel value. Assumes writes enabled to analog bus and bank6 register * cache in ah->analogBank6Data. */ int ath9k_hw_set_channel(struct ath_hw *ah, struct ath9k_channel *chan) { struct ath_common *common = ath9k_hw_common(ah); u32 channelSel = 0; u32 bModeSynth = 0; u32 aModeRefSel = 0; u32 reg32 = 0; u16 freq; struct chan_centers centers; ath9k_hw_get_channel_centers(ah, chan, ¢ers); freq = centers.synth_center; if (freq < 4800) { u32 txctl; if (((freq - 2192) % 5) == 0) { channelSel = ((freq - 672) * 2 - 3040) / 10; bModeSynth = 0; } else if (((freq - 2224) % 5) == 0) { channelSel = ((freq - 704) * 2 - 3040) / 10; bModeSynth = 1; } else { ath_print(common, ATH_DBG_FATAL, "Invalid channel %u MHz\n", freq); return -EINVAL; } channelSel = (channelSel << 2) & 0xff; channelSel = ath9k_hw_reverse_bits(channelSel, 8); txctl = REG_READ(ah, AR_PHY_CCK_TX_CTRL); if (freq == 2484) { REG_WRITE(ah, AR_PHY_CCK_TX_CTRL, txctl | AR_PHY_CCK_TX_CTRL_JAPAN); } else { REG_WRITE(ah, AR_PHY_CCK_TX_CTRL, txctl & ~AR_PHY_CCK_TX_CTRL_JAPAN); } } else if ((freq % 20) == 0 && freq >= 5120) { channelSel = ath9k_hw_reverse_bits(((freq - 4800) / 20 << 2), 8); aModeRefSel = ath9k_hw_reverse_bits(1, 2); } else if ((freq % 10) == 0) { channelSel = ath9k_hw_reverse_bits(((freq - 4800) / 10 << 1), 8); if (AR_SREV_9100(ah) || AR_SREV_9160_10_OR_LATER(ah)) aModeRefSel = ath9k_hw_reverse_bits(2, 2); else aModeRefSel = ath9k_hw_reverse_bits(1, 2); } else if ((freq % 5) == 0) { channelSel = ath9k_hw_reverse_bits((freq - 4800) / 5, 8); aModeRefSel = ath9k_hw_reverse_bits(1, 2); } else { ath_print(common, ATH_DBG_FATAL, "Invalid channel %u MHz\n", freq); return -EINVAL; } ath9k_hw_force_bias(ah, freq); reg32 = (channelSel << 8) | (aModeRefSel << 2) | (bModeSynth << 1) | (1 << 5) | 0x1; REG_WRITE(ah, AR_PHY(0x37), reg32); ah->curchan = chan; ah->curchan_rad_index = -1; return 0; } /** * ath9k_hw_spur_mitigate - convert baseband spur frequency for external radios * @ah: atheros hardware structure * @chan: * * For non single-chip solutions. Converts to baseband spur frequency given the * input channel frequency and compute register settings below. */ void ath9k_hw_spur_mitigate(struct ath_hw *ah, struct ath9k_channel *chan) { int bb_spur = AR_NO_SPUR; int bin, cur_bin; int spur_freq_sd; int spur_delta_phase; int denominator; int upper, lower, cur_vit_mask; int tmp, new; int i; int pilot_mask_reg[4] = { AR_PHY_TIMING7, AR_PHY_TIMING8, AR_PHY_PILOT_MASK_01_30, AR_PHY_PILOT_MASK_31_60 }; int chan_mask_reg[4] = { AR_PHY_TIMING9, AR_PHY_TIMING10, AR_PHY_CHANNEL_MASK_01_30, AR_PHY_CHANNEL_MASK_31_60 }; int inc[4] = { 0, 100, 0, 0 }; int8_t mask_m[123]; int8_t mask_p[123]; int8_t mask_amt; int tmp_mask; int cur_bb_spur; bool is2GHz = IS_CHAN_2GHZ(chan); memset(&mask_m, 0, sizeof(int8_t) * 123); memset(&mask_p, 0, sizeof(int8_t) * 123); for (i = 0; i < AR_EEPROM_MODAL_SPURS; i++) { cur_bb_spur = ah->eep_ops->get_spur_channel(ah, i, is2GHz); if (AR_NO_SPUR == cur_bb_spur) break; cur_bb_spur = cur_bb_spur - (chan->channel * 10); if ((cur_bb_spur > -95) && (cur_bb_spur < 95)) { bb_spur = cur_bb_spur; break; } } if (AR_NO_SPUR == bb_spur) return; bin = bb_spur * 32; tmp = REG_READ(ah, AR_PHY_TIMING_CTRL4(0)); new = tmp | (AR_PHY_TIMING_CTRL4_ENABLE_SPUR_RSSI | AR_PHY_TIMING_CTRL4_ENABLE_SPUR_FILTER | AR_PHY_TIMING_CTRL4_ENABLE_CHAN_MASK | AR_PHY_TIMING_CTRL4_ENABLE_PILOT_MASK); REG_WRITE(ah, AR_PHY_TIMING_CTRL4(0), new); new = (AR_PHY_SPUR_REG_MASK_RATE_CNTL | AR_PHY_SPUR_REG_ENABLE_MASK_PPM | AR_PHY_SPUR_REG_MASK_RATE_SELECT | AR_PHY_SPUR_REG_ENABLE_VIT_SPUR_RSSI | SM(SPUR_RSSI_THRESH, AR_PHY_SPUR_REG_SPUR_RSSI_THRESH)); REG_WRITE(ah, AR_PHY_SPUR_REG, new); spur_delta_phase = ((bb_spur * 524288) / 100) & AR_PHY_TIMING11_SPUR_DELTA_PHASE; denominator = IS_CHAN_2GHZ(chan) ? 440 : 400; spur_freq_sd = ((bb_spur * 2048) / denominator) & 0x3ff; new = (AR_PHY_TIMING11_USE_SPUR_IN_AGC | SM(spur_freq_sd, AR_PHY_TIMING11_SPUR_FREQ_SD) | SM(spur_delta_phase, AR_PHY_TIMING11_SPUR_DELTA_PHASE)); REG_WRITE(ah, AR_PHY_TIMING11, new); cur_bin = -6000; upper = bin + 100; lower = bin - 100; for (i = 0; i < 4; i++) { int pilot_mask = 0; int chan_mask = 0; int bp = 0; for (bp = 0; bp < 30; bp++) { if ((cur_bin > lower) && (cur_bin < upper)) { pilot_mask = pilot_mask | 0x1 << bp; chan_mask = chan_mask | 0x1 << bp; } cur_bin += 100; } cur_bin += inc[i]; REG_WRITE(ah, pilot_mask_reg[i], pilot_mask); REG_WRITE(ah, chan_mask_reg[i], chan_mask); } cur_vit_mask = 6100; upper = bin + 120; lower = bin - 120; for (i = 0; i < 123; i++) { if ((cur_vit_mask > lower) && (cur_vit_mask < upper)) { /* workaround for gcc bug #37014 */ volatile int tmp_v = abs(cur_vit_mask - bin); if (tmp_v < 75) mask_amt = 1; else mask_amt = 0; if (cur_vit_mask < 0) mask_m[abs(cur_vit_mask / 100)] = mask_amt; else mask_p[cur_vit_mask / 100] = mask_amt; } cur_vit_mask -= 100; } tmp_mask = (mask_m[46] << 30) | (mask_m[47] << 28) | (mask_m[48] << 26) | (mask_m[49] << 24) | (mask_m[50] << 22) | (mask_m[51] << 20) | (mask_m[52] << 18) | (mask_m[53] << 16) | (mask_m[54] << 14) | (mask_m[55] << 12) | (mask_m[56] << 10) | (mask_m[57] << 8) | (mask_m[58] << 6) | (mask_m[59] << 4) | (mask_m[60] << 2) | (mask_m[61] << 0); REG_WRITE(ah, AR_PHY_BIN_MASK_1, tmp_mask); REG_WRITE(ah, AR_PHY_VIT_MASK2_M_46_61, tmp_mask); tmp_mask = (mask_m[31] << 28) | (mask_m[32] << 26) | (mask_m[33] << 24) | (mask_m[34] << 22) | (mask_m[35] << 20) | (mask_m[36] << 18) | (mask_m[37] << 16) | (mask_m[48] << 14) | (mask_m[39] << 12) | (mask_m[40] << 10) | (mask_m[41] << 8) | (mask_m[42] << 6) | (mask_m[43] << 4) | (mask_m[44] << 2) | (mask_m[45] << 0); REG_WRITE(ah, AR_PHY_BIN_MASK_2, tmp_mask); REG_WRITE(ah, AR_PHY_MASK2_M_31_45, tmp_mask); tmp_mask = (mask_m[16] << 30) | (mask_m[16] << 28) | (mask_m[18] << 26) | (mask_m[18] << 24) | (mask_m[20] << 22) | (mask_m[20] << 20) | (mask_m[22] << 18) | (mask_m[22] << 16) | (mask_m[24] << 14) | (mask_m[24] << 12) | (mask_m[25] << 10) | (mask_m[26] << 8) | (mask_m[27] << 6) | (mask_m[28] << 4) | (mask_m[29] << 2) | (mask_m[30] << 0); REG_WRITE(ah, AR_PHY_BIN_MASK_3, tmp_mask); REG_WRITE(ah, AR_PHY_MASK2_M_16_30, tmp_mask); tmp_mask = (mask_m[0] << 30) | (mask_m[1] << 28) | (mask_m[2] << 26) | (mask_m[3] << 24) | (mask_m[4] << 22) | (mask_m[5] << 20) | (mask_m[6] << 18) | (mask_m[7] << 16) | (mask_m[8] << 14) | (mask_m[9] << 12) | (mask_m[10] << 10) | (mask_m[11] << 8) | (mask_m[12] << 6) | (mask_m[13] << 4) | (mask_m[14] << 2) | (mask_m[15] << 0); REG_WRITE(ah, AR_PHY_MASK_CTL, tmp_mask); REG_WRITE(ah, AR_PHY_MASK2_M_00_15, tmp_mask); tmp_mask = (mask_p[15] << 28) | (mask_p[14] << 26) | (mask_p[13] << 24) | (mask_p[12] << 22) | (mask_p[11] << 20) | (mask_p[10] << 18) | (mask_p[9] << 16) | (mask_p[8] << 14) | (mask_p[7] << 12) | (mask_p[6] << 10) | (mask_p[5] << 8) | (mask_p[4] << 6) | (mask_p[3] << 4) | (mask_p[2] << 2) | (mask_p[1] << 0); REG_WRITE(ah, AR_PHY_BIN_MASK2_1, tmp_mask); REG_WRITE(ah, AR_PHY_MASK2_P_15_01, tmp_mask); tmp_mask = (mask_p[30] << 28) | (mask_p[29] << 26) | (mask_p[28] << 24) | (mask_p[27] << 22) | (mask_p[26] << 20) | (mask_p[25] << 18) | (mask_p[24] << 16) | (mask_p[23] << 14) | (mask_p[22] << 12) | (mask_p[21] << 10) | (mask_p[20] << 8) | (mask_p[19] << 6) | (mask_p[18] << 4) | (mask_p[17] << 2) | (mask_p[16] << 0); REG_WRITE(ah, AR_PHY_BIN_MASK2_2, tmp_mask); REG_WRITE(ah, AR_PHY_MASK2_P_30_16, tmp_mask); tmp_mask = (mask_p[45] << 28) | (mask_p[44] << 26) | (mask_p[43] << 24) | (mask_p[42] << 22) | (mask_p[41] << 20) | (mask_p[40] << 18) | (mask_p[39] << 16) | (mask_p[38] << 14) | (mask_p[37] << 12) | (mask_p[36] << 10) | (mask_p[35] << 8) | (mask_p[34] << 6) | (mask_p[33] << 4) | (mask_p[32] << 2) | (mask_p[31] << 0); REG_WRITE(ah, AR_PHY_BIN_MASK2_3, tmp_mask); REG_WRITE(ah, AR_PHY_MASK2_P_45_31, tmp_mask); tmp_mask = (mask_p[61] << 30) | (mask_p[60] << 28) | (mask_p[59] << 26) | (mask_p[58] << 24) | (mask_p[57] << 22) | (mask_p[56] << 20) | (mask_p[55] << 18) | (mask_p[54] << 16) | (mask_p[53] << 14) | (mask_p[52] << 12) | (mask_p[51] << 10) | (mask_p[50] << 8) | (mask_p[49] << 6) | (mask_p[48] << 4) | (mask_p[47] << 2) | (mask_p[46] << 0); REG_WRITE(ah, AR_PHY_BIN_MASK2_4, tmp_mask); REG_WRITE(ah, AR_PHY_MASK2_P_61_45, tmp_mask); } /** * ath9k_hw_rf_alloc_ext_banks - allocates banks for external radio programming * @ah: atheros hardware structure * * Only required for older devices with external AR2133/AR5133 radios. */ int ath9k_hw_rf_alloc_ext_banks(struct ath_hw *ah) { #define ATH_ALLOC_BANK(bank, size) do { \ bank = kzalloc((sizeof(u32) * size), GFP_KERNEL); \ if (!bank) { \ ath_print(common, ATH_DBG_FATAL, \ "Cannot allocate RF banks\n"); \ return -ENOMEM; \ } \ } while (0); struct ath_common *common = ath9k_hw_common(ah); BUG_ON(AR_SREV_9280_10_OR_LATER(ah)); ATH_ALLOC_BANK(ah->analogBank0Data, ah->iniBank0.ia_rows); ATH_ALLOC_BANK(ah->analogBank1Data, ah->iniBank1.ia_rows); ATH_ALLOC_BANK(ah->analogBank2Data, ah->iniBank2.ia_rows); ATH_ALLOC_BANK(ah->analogBank3Data, ah->iniBank3.ia_rows); ATH_ALLOC_BANK(ah->analogBank6Data, ah->iniBank6.ia_rows); ATH_ALLOC_BANK(ah->analogBank6TPCData, ah->iniBank6TPC.ia_rows); ATH_ALLOC_BANK(ah->analogBank7Data, ah->iniBank7.ia_rows); ATH_ALLOC_BANK(ah->addac5416_21, ah->iniAddac.ia_rows * ah->iniAddac.ia_columns); ATH_ALLOC_BANK(ah->bank6Temp, ah->iniBank6.ia_rows); return 0; #undef ATH_ALLOC_BANK } /** * ath9k_hw_rf_free_ext_banks - Free memory for analog bank scratch buffers * @ah: atheros hardware struture * For the external AR2133/AR5133 radios banks. */ void ath9k_hw_rf_free_ext_banks(struct ath_hw *ah) { #define ATH_FREE_BANK(bank) do { \ kfree(bank); \ bank = NULL; \ } while (0); BUG_ON(AR_SREV_9280_10_OR_LATER(ah)); ATH_FREE_BANK(ah->analogBank0Data); ATH_FREE_BANK(ah->analogBank1Data); ATH_FREE_BANK(ah->analogBank2Data); ATH_FREE_BANK(ah->analogBank3Data); ATH_FREE_BANK(ah->analogBank6Data); ATH_FREE_BANK(ah->analogBank6TPCData); ATH_FREE_BANK(ah->analogBank7Data); ATH_FREE_BANK(ah->addac5416_21); ATH_FREE_BANK(ah->bank6Temp); #undef ATH_FREE_BANK } /* * * ath9k_hw_set_rf_regs - programs rf registers based on EEPROM * @ah: atheros hardware structure * @chan: * @modesIndex: * * Used for the external AR2133/AR5133 radios. * * Reads the EEPROM header info from the device structure and programs * all rf registers. This routine requires access to the analog * rf device. This is not required for single-chip devices. */ bool ath9k_hw_set_rf_regs(struct ath_hw *ah, struct ath9k_channel *chan, u16 modesIndex) { u32 eepMinorRev; u32 ob5GHz = 0, db5GHz = 0; u32 ob2GHz = 0, db2GHz = 0; int regWrites = 0; /* * Software does not need to program bank data * for single chip devices, that is AR9280 or anything * after that. */ if (AR_SREV_9280_10_OR_LATER(ah)) return true; /* Setup rf parameters */ eepMinorRev = ah->eep_ops->get_eeprom(ah, EEP_MINOR_REV); /* Setup Bank 0 Write */ RF_BANK_SETUP(ah->analogBank0Data, &ah->iniBank0, 1); /* Setup Bank 1 Write */ RF_BANK_SETUP(ah->analogBank1Data, &ah->iniBank1, 1); /* Setup Bank 2 Write */ RF_BANK_SETUP(ah->analogBank2Data, &ah->iniBank2, 1); /* Setup Bank 6 Write */ RF_BANK_SETUP(ah->analogBank3Data, &ah->iniBank3, modesIndex); { int i; for (i = 0; i < ah->iniBank6TPC.ia_rows; i++) { ah->analogBank6Data[i] = INI_RA(&ah->iniBank6TPC, i, modesIndex); } } /* Only the 5 or 2 GHz OB/DB need to be set for a mode */ if (eepMinorRev >= 2) { if (IS_CHAN_2GHZ(chan)) { ob2GHz = ah->eep_ops->get_eeprom(ah, EEP_OB_2); db2GHz = ah->eep_ops->get_eeprom(ah, EEP_DB_2); ath9k_phy_modify_rx_buffer(ah->analogBank6Data, ob2GHz, 3, 197, 0); ath9k_phy_modify_rx_buffer(ah->analogBank6Data, db2GHz, 3, 194, 0); } else { ob5GHz = ah->eep_ops->get_eeprom(ah, EEP_OB_5); db5GHz = ah->eep_ops->get_eeprom(ah, EEP_DB_5); ath9k_phy_modify_rx_buffer(ah->analogBank6Data, ob5GHz, 3, 203, 0); ath9k_phy_modify_rx_buffer(ah->analogBank6Data, db5GHz, 3, 200, 0); } } /* Setup Bank 7 Setup */ RF_BANK_SETUP(ah->analogBank7Data, &ah->iniBank7, 1); /* Write Analog registers */ REG_WRITE_RF_ARRAY(&ah->iniBank0, ah->analogBank0Data, regWrites); REG_WRITE_RF_ARRAY(&ah->iniBank1, ah->analogBank1Data, regWrites); REG_WRITE_RF_ARRAY(&ah->iniBank2, ah->analogBank2Data, regWrites); REG_WRITE_RF_ARRAY(&ah->iniBank3, ah->analogBank3Data, regWrites); REG_WRITE_RF_ARRAY(&ah->iniBank6TPC, ah->analogBank6Data, regWrites); REG_WRITE_RF_ARRAY(&ah->iniBank7, ah->analogBank7Data, regWrites); return true; }