/* * carl9170 firmware - used by the ar9170 wireless device * * PHY and RF functions * * Copyright (c) 2000-2005 ZyDAS Technology Corporation * Copyright (c) 2007-2009 Atheros Communications, Inc. * Copyright 2009 Johannes Berg * Copyright 2009-2011 Christian Lamparter * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * 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 02110-1301 USA. */ #include "carl9170.h" #include "timer.h" #include "printf.h" #include "rf.h" #include "shared/phy.h" #ifdef CONFIG_CARL9170FW_RADIO_FUNCTIONS static void set_channel_end(void) { /* Manipulate CCA threshold to resume transmission */ set(AR9170_PHY_REG_CCA_THRESHOLD, 0x0); /* Disable Virtual CCA */ andl(AR9170_MAC_REG_QOS_PRIORITY_VIRTUAL_CCA, ~AR9170_MAC_VIRTUAL_CCA_ALL); fw.phy.state = CARL9170_PHY_ON; } void rf_notify_set_channel(void) { /* Manipulate CCA threshold to stop transmission */ set(AR9170_PHY_REG_CCA_THRESHOLD, 0x300); /* Enable Virtual CCA */ orl(AR9170_MAC_REG_QOS_PRIORITY_VIRTUAL_CCA, AR9170_MAC_VIRTUAL_CCA_ALL); /* reset CCA stats */ fw.tally.active = 0; fw.tally.cca = 0; fw.tally.tx_time = 0; fw.phy.state = CARL9170_PHY_OFF; } /* * Update delta slope coeff man and exp */ static void hw_turn_off_dyn(const uint32_t delta_slope_coeff_exp, const uint32_t delta_slope_coeff_man, const uint32_t delta_slope_coeff_exp_shgi, const uint32_t delta_slope_coeff_man_shgi) { uint32_t tmp; tmp = get_async(AR9170_PHY_REG_TIMING3) & 0x00001fff; tmp |= (delta_slope_coeff_man << AR9170_PHY_TIMING3_DSC_MAN_S) & AR9170_PHY_TIMING3_DSC_MAN; tmp |= (delta_slope_coeff_exp << AR9170_PHY_TIMING3_DSC_EXP_S) & AR9170_PHY_TIMING3_DSC_EXP; set(AR9170_PHY_REG_TIMING3, tmp); tmp = (delta_slope_coeff_man_shgi << AR9170_PHY_HALFGI_DSC_MAN_S) & AR9170_PHY_HALFGI_DSC_MAN; tmp |= (delta_slope_coeff_exp_shgi << AR9170_PHY_HALFGI_DSC_EXP_S) & AR9170_PHY_HALFGI_DSC_EXP; set(AR9170_PHY_REG_HALFGI, tmp); } static void program_ADDAC(void) { /* ??? Select Internal ADDAC ??? (is external radio) */ set(AR9170_PHY_REG_ADC_SERIAL_CTL, AR9170_PHY_ADC_SCTL_SEL_EXTERNAL_RADIO); delay(10); set(0x1c589c, 0x00000000); /*# 7-0 */ set(0x1c589c, 0x00000000); /*# 15-8 */ set(0x1c589c, 0x00000000); /*# 23-16 */ set(0x1c589c, 0x00000000); /*# 31- */ set(0x1c589c, 0x00000000); /*# 39- */ set(0x1c589c, 0x00000000); /*# 47- */ set(0x1c589c, 0x00000000); /*# 55- [48]:doubles the xtalosc bias current */ set(0x1c589c, 0x00000000); /*# 63- */ set(0x1c589c, 0x00000000); /*# 71- */ set(0x1c589c, 0x00000000); /*# 79- */ set(0x1c589c, 0x00000000); /*# 87- */ set(0x1c589c, 0x00000000); /*# 95- */ set(0x1c589c, 0x00000000); /*# 103- */ set(0x1c589c, 0x00000000); /*# 111- */ set(0x1c589c, 0x00000000); /*# 119- */ set(0x1c589c, 0x00000000); /*# 127- */ set(0x1c589c, 0x00000000); /*# 135- */ set(0x1c589c, 0x00000000); /*# 143- */ set(0x1c589c, 0x00000000); /*# 151- */ set(0x1c589c, 0x00000030); /*# 159- #[158:156]=xlnabufmode */ set(0x1c589c, 0x00000004); /*# 167- [162]:disable clkp_driver to flow */ set(0x1c589c, 0x00000000); /*# 175- */ set(0x1c589c, 0x00000000); /*# 183-176 */ set(0x1c589c, 0x00000000); /*# 191-184 */ set(0x1c589c, 0x00000000); /*# 199- */ set(0x1c589c, 0x00000000); /*# 207- */ set(0x1c589c, 0x00000000); /*# 215- */ set(0x1c589c, 0x00000000); /*# 223- */ set(0x1c589c, 0x00000000); /*# 231- */ set(0x1c58c4, 0x00000000); /*# 233-232 */ delay(10); /* Select External Flow ???? (is internal addac??) */ set(AR9170_PHY_REG_ADC_SERIAL_CTL, AR9170_PHY_ADC_SCTL_SEL_INTERNAL_ADDAC); } static uint32_t AGC_calibration(uint32_t loop) { uint32_t wrdata; uint32_t ret; #define AGC_CAL_NF (AR9170_PHY_AGC_CONTROL_CAL | AR9170_PHY_AGC_CONTROL_NF) wrdata = get_async(AR9170_PHY_REG_AGC_CONTROL) | AGC_CAL_NF; set(AR9170_PHY_REG_AGC_CONTROL, wrdata); ret = get_async(AR9170_PHY_REG_AGC_CONTROL) & AGC_CAL_NF; /* sitesurvey : 100 ms / current connected 200 ms */ while ((ret != 0) && loop--) { udelay(100); ret = get_async(AR9170_PHY_REG_AGC_CONTROL) & AGC_CAL_NF; } /* return the AGC/Noise calibration state to the driver */ return ret; } #define EIGHTY_FLAG (CARL9170FW_PHY_HT_ENABLE | CARL9170FW_PHY_HT_DYN2040) static uint32_t rf_init(const uint32_t delta_slope_coeff_exp, const uint32_t delta_slope_coeff_man, const uint32_t delta_slope_coeff_exp_shgi, const uint32_t delta_slope_coeff_man_shgi, const uint32_t finiteLoopCount, const bool initialize) { uint32_t ret; hw_turn_off_dyn(delta_slope_coeff_exp, delta_slope_coeff_man, delta_slope_coeff_exp_shgi, delta_slope_coeff_man_shgi); if (initialize) { /* Real Chip */ program_ADDAC(); /* inverse chain 0 <-> chain 2 */ set(AR9170_PHY_REG_ANALOG_SWAP, AR9170_PHY_ANALOG_SWAP_AB); /* swap chain 0 and chain 2 */ set(AR9170_PHY_REG_ANALOG_SWAP, AR9170_PHY_ANALOG_SWAP_AB | AR9170_PHY_ANALOG_SWAP_ALT_CHAIN); /* Activate BB */ set(AR9170_PHY_REG_ACTIVE, AR9170_PHY_ACTIVE_EN); delay(10); } ret = AGC_calibration(finiteLoopCount); set_channel_end(); return ret; } void rf_cmd(const struct carl9170_cmd *cmd, struct carl9170_rsp *resp) { uint32_t ret; fw.phy.ht_settings = cmd->rf_init.ht_settings; fw.phy.frequency = cmd->rf_init.freq; /* * Is the clock controlled by the PHY? */ if ((fw.phy.ht_settings & EIGHTY_FLAG) == EIGHTY_FLAG) clock_set(AHB_80_88MHZ, true); else clock_set(AHB_40_44MHZ, true); ret = rf_init(le32_to_cpu(cmd->rf_init.delta_slope_coeff_exp), le32_to_cpu(cmd->rf_init.delta_slope_coeff_man), le32_to_cpu(cmd->rf_init.delta_slope_coeff_exp_shgi), le32_to_cpu(cmd->rf_init.delta_slope_coeff_man_shgi), le32_to_cpu(cmd->rf_init.finiteLoopCount), cmd->hdr.cmd == CARL9170_CMD_RF_INIT); resp->hdr.len = sizeof(struct carl9170_rf_init_result); resp->rf_init_res.ret = cpu_to_le32(ret); } void rf_psm(void) { u32 bank3; if (fw.phy.psm.state == CARL9170_PSM_SOFTWARE) { /* not enabled by the driver */ return; } if (fw.phy.psm.state & CARL9170_PSM_SLEEP) { fw.phy.psm.state &= ~CARL9170_PSM_SLEEP; /* disable all agc gain and offset updates to a2 */ set(AR9170_PHY_REG_TEST2, 0x8000000); /* power down ADDAC */ set(AR9170_PHY_REG_ADC_CTL, AR9170_PHY_ADC_CTL_OFF_PWDDAC | AR9170_PHY_ADC_CTL_OFF_PWDADC | 0xa0000000); /* Synthesizer off + RX off */ bank3 = 0x00400018; fw.phy.state = CARL9170_PHY_OFF; } else { /* advance to the next PSM step */ fw.phy.psm.state--; if (fw.phy.psm.state == CARL9170_PSM_WAKE) { /* wake up ADDAC */ set(AR9170_PHY_REG_ADC_CTL, AR9170_PHY_ADC_CTL_OFF_PWDDAC | AR9170_PHY_ADC_CTL_OFF_PWDADC); /* enable all agc gain and offset updates to a2 */ set(AR9170_PHY_REG_TEST2, 0x0); /* Synthesizer on + RX on */ bank3 = 0x01420098; fw.phy.state = CARL9170_PHY_ON; } else { return ; } } if (fw.phy.frequency < 3000000) bank3 |= 0x00800000; set(0x1c58f0, bank3); } #endif /* CONFIG_CARL9170FW_RADIO_FUNCTIONS */