[RFC,v2,54/96] cl8k: add power.c

Message ID	20220524113502.1094459-55-viktor.barna@celeno.com (mailing list archive)
State	RFC
Delegated to:	Kalle Valo
Headers	show Return-Path: <linux-wireless-owner@kernel.org> From: viktor.barna@celeno.com To: linux-wireless@vger.kernel.org Cc: Kalle Valo <kvalo@codeaurora.org>, "David S . Miller" <davem@davemloft.net>, Jakub Kicinski <kuba@kernel.org>, Aviad Brikman <aviad.brikman@celeno.com>, Eliav Farber <eliav.farber@gmail.com>, Maksym Kokhan <maksym.kokhan@celeno.com>, Oleksandr Savchenko <oleksandr.savchenko@celeno.com>, Shay Bar <shay.bar@celeno.com>, Viktor Barna <viktor.barna@celeno.com> Subject: [RFC v2 54/96] cl8k: add power.c Date: Tue, 24 May 2022 14:34:20 +0300 Message-Id: <20220524113502.1094459-55-viktor.barna@celeno.com> In-Reply-To: <20220524113502.1094459-1-viktor.barna@celeno.com> References: <20220524113502.1094459-1-viktor.barna@celeno.com> Content-Transfer-Encoding: 8bit Content-Type: text/plain MIME-Version: 1.0 Precedence: bulk
Series	wireless: cl8k driver for Celeno IEEE 802.11ax devices \| expand [RFC,v2,00/96] wireless: cl8k driver for Celeno IEEE 802.11ax devices [RFC,v2,01/96] celeno: add Kconfig [RFC,v2,02/96] celeno: add Makefile [RFC,v2,03/96] cl8k: add Kconfig [RFC,v2,04/96] cl8k: add Makefile [RFC,v2,05/96] cl8k: add ampdu.c [RFC,v2,06/96] cl8k: add ampdu.h [RFC,v2,07/96] cl8k: add bf.c [RFC,v2,08/96] cl8k: add bf.h [RFC,v2,09/96] cl8k: add calib.c [RFC,v2,10/96] cl8k: add calib.h [RFC,v2,11/96] cl8k: add channel.c [RFC,v2,12/96] cl8k: add channel.h [RFC,v2,13/96] cl8k: add chip.c [RFC,v2,14/96] cl8k: add chip.h [RFC,v2,15/96] cl8k: add config.c [RFC,v2,16/96] cl8k: add config.h [RFC,v2,17/96] cl8k: add debug.c [RFC,v2,18/96] cl8k: add debug.h [RFC,v2,19/96] cl8k: add def.h [RFC,v2,20/96] cl8k: add dfs.c [RFC,v2,21/96] cl8k: add dfs.h [RFC,v2,22/96] cl8k: add dsp.c [RFC,v2,23/96] cl8k: add dsp.h [RFC,v2,24/96] cl8k: add e2p.c [RFC,v2,25/96] cl8k: add e2p.h [RFC,v2,26/96] cl8k: add eeprom.h [RFC,v2,27/96] cl8k: add ela.c [RFC,v2,28/96] cl8k: add ela.h [RFC,v2,29/96] cl8k: add enhanced_tim.c [RFC,v2,30/96] cl8k: add enhanced_tim.h [RFC,v2,31/96] cl8k: add fw.c [RFC,v2,32/96] cl8k: add fw.h [RFC,v2,33/96] cl8k: add hw.c [RFC,v2,34/96] cl8k: add hw.h [RFC,v2,35/96] cl8k: add ipc_shared.h [RFC,v2,36/96] cl8k: add key.c [RFC,v2,37/96] cl8k: add key.h [RFC,v2,38/96] cl8k: add mac80211.c [RFC,v2,39/96] cl8k: add mac80211.h [RFC,v2,40/96] cl8k: add mac_addr.c [RFC,v2,41/96] cl8k: add mac_addr.h [RFC,v2,42/96] cl8k: add main.c [RFC,v2,43/96] cl8k: add main.h [RFC,v2,44/96] cl8k: add maintenance.c [RFC,v2,45/96] cl8k: add maintenance.h [RFC,v2,46/96] cl8k: add motion_sense.c [RFC,v2,47/96] cl8k: add motion_sense.h [RFC,v2,48/96] cl8k: add pci.c [RFC,v2,49/96] cl8k: add pci.h [RFC,v2,50/96] cl8k: add phy.c [RFC,v2,51/96] cl8k: add phy.h [RFC,v2,52/96] cl8k: add platform.c [RFC,v2,53/96] cl8k: add platform.h [RFC,v2,54/96] cl8k: add power.c [RFC,v2,55/96] cl8k: add power.h [RFC,v2,56/96] cl8k: add radio.c [RFC,v2,57/96] cl8k: add radio.h [RFC,v2,58/96] cl8k: add rates.c [RFC,v2,59/96] cl8k: add rates.h [RFC,v2,60/96] cl8k: add recovery.c [RFC,v2,61/96] cl8k: add recovery.h [RFC,v2,62/96] cl8k: add regdom.c [RFC,v2,63/96] cl8k: add regdom.h [RFC,v2,64/96] cl8k: add reg/reg_access.h [RFC,v2,65/96] cl8k: add reg/reg_defs.h [RFC,v2,66/96] cl8k: add rfic.c [RFC,v2,67/96] cl8k: add rfic.h [RFC,v2,68/96] cl8k: add rx.c [RFC,v2,69/96] cl8k: add rx.h [RFC,v2,70/96] cl8k: add scan.c [RFC,v2,71/96] cl8k: add scan.h [RFC,v2,72/96] cl8k: add sounding.c [RFC,v2,73/96] cl8k: add sounding.h [RFC,v2,74/96] cl8k: add sta.c [RFC,v2,75/96] cl8k: add sta.h [RFC,v2,76/96] cl8k: add stats.c [RFC,v2,77/96] cl8k: add stats.h [RFC,v2,78/96] cl8k: add tcv.c [RFC,v2,79/96] cl8k: add tcv.h [RFC,v2,80/96] cl8k: add temperature.c [RFC,v2,81/96] cl8k: add temperature.h [RFC,v2,82/96] cl8k: add traffic.c [RFC,v2,83/96] cl8k: add traffic.h [RFC,v2,84/96] cl8k: add tx.c [RFC,v2,85/96] cl8k: add tx.h [RFC,v2,86/96] cl8k: add utils.c [RFC,v2,87/96] cl8k: add utils.h [RFC,v2,88/96] cl8k: add version.c [RFC,v2,89/96] cl8k: add version.h [RFC,v2,90/96] cl8k: add vif.c [RFC,v2,91/96] cl8k: add vif.h [RFC,v2,92/96] cl8k: add vns.c [RFC,v2,93/96] cl8k: add vns.h [RFC,v2,94/96] cl8k: add wrs.c [RFC,v2,95/96] cl8k: add wrs.h [RFC,v2,96/96] wireless: add Celeno vendor

diff --git a/drivers/net/wireless/celeno/cl8k/power.c b/drivers/net/wireless/celeno/cl8k/power.c new file mode 100644 index 000000000000..ef62c4b7a332 --- /dev/null +++ b/drivers/net/wireless/celeno/cl8k/power.c @@ -0,0 +1,1123 @@ +// SPDX-License-Identifier: GPL-2.0 OR BSD-2-Clause +/* Copyright(c) 2019-2022, Celeno Communications Ltd. */ + +#include <linux/string.h> + +#include "reg/reg_access.h" +#include "channel.h" +#include "debug.h" +#include "utils.h" +#include "e2p.h" +#include "power.h" + +static u8 cl_power_table_read(struct cl_hw *cl_hw) +{ + u8 pwr_table_id = 0; + + if (cl_e2p_read(cl_hw->chip, &pwr_table_id, 1, ADDR_GEN_PWR_TABLE_ID + cl_hw->tcv_idx)) + return U8_MAX; + + return pwr_table_id; +} + +static int cl_power_table_fill(struct cl_hw *cl_hw) +{ + u8 pwr_table_id = cl_power_table_read(cl_hw); + u8 platform_idx = cl_hw->chip->platform.idx; + struct cl_platform_table *table = NULL; + + table = cl_platform_get_active_table(cl_hw->chip, platform_idx); + if (!table) + return cl_hw->chip->conf->ce_production_mode ? 0 : -1; + + switch (pwr_table_id) { + case 0: + if (cl_band_is_5g(cl_hw)) { + memcpy(cl_hw->power_table_info.data->conv_table, + table->power_conv_table_5, + NUM_POWER_WORDS); + cl_hw->tx_power_version = 5; + } else if (IS_REAL_PHY(cl_hw->chip)) { + CL_DBG_ERROR(cl_hw, "Power table ID (%u) is valid for 5g only\n", + pwr_table_id); + + if (!cl_hw_is_prod_or_listener(cl_hw)) + return -EINVAL; + } + break; + case 1: + if (cl_band_is_24g(cl_hw)) { + memcpy(cl_hw->power_table_info.data->conv_table, + table->power_conv_table_2, + NUM_POWER_WORDS); + cl_hw->tx_power_version = 25; + } else if (IS_REAL_PHY(cl_hw->chip)) { + CL_DBG_ERROR(cl_hw, "Power table ID (%u) is valid for 2.4g only\n", + pwr_table_id); + + if (!cl_hw_is_prod_or_listener(cl_hw)) + return -1; + } + break; + case 2: + if (cl_band_is_6g(cl_hw)) { + memcpy(cl_hw->power_table_info.data->conv_table, + table->power_conv_table_6, + NUM_POWER_WORDS); + cl_hw->tx_power_version = 1; + } else if (IS_REAL_PHY(cl_hw->chip)) { + CL_DBG_ERROR(cl_hw, "Power table ID (%u) is valid for 6g only\n", + pwr_table_id); + + if (!cl_hw_is_prod_or_listener(cl_hw)) + return -1; + } + break; + default: + if (IS_REAL_PHY(cl_hw->chip)) { + CL_DBG_ERROR(cl_hw, "Power table ID is not configured in EEPROM\n"); + + if (!cl_hw_is_prod_or_listener(cl_hw)) + return -1; + } + } + + cl_dbg_verbose(cl_hw, "Power table ID %u (V%u)\n", pwr_table_id, cl_hw->tx_power_version); + + return 0; +} + +int cl_power_table_alloc(struct cl_hw *cl_hw) +{ + struct cl_power_table_data *buf = NULL; + u32 len = sizeof(struct cl_power_table_data); + dma_addr_t phys_dma_addr; + + buf = dma_alloc_coherent(cl_hw->chip->dev, len, &phys_dma_addr, GFP_KERNEL); + if (!buf) + return -ENOMEM; + + cl_hw->power_table_info.data = buf; + cl_hw->power_table_info.dma_addr = phys_dma_addr; + + return cl_power_table_fill(cl_hw); +} + +void cl_power_table_free(struct cl_hw *cl_hw) +{ + struct cl_power_table_info *power_table_info = &cl_hw->power_table_info; + u32 len = sizeof(struct cl_power_table_data); + dma_addr_t phys_dma_addr = power_table_info->dma_addr; + + if (!power_table_info->data) + return; + + dma_free_coherent(cl_hw->chip->dev, len, (void *)power_table_info->data, phys_dma_addr); + power_table_info->data = NULL; +} + +static s32 convert_str_int_q8(s8 *str) +{ + s32 x, y; + + if (!str) + return 0; + if (sscanf(str, "%d.%2d", &x, &y) == 0) + return 0; + if (!strstr(str, ".")) + return x << 8; + if (y < 10 && (*(strstr(str, ".") + 1) != '0')) + y *= 10; + return ((x * 100 + y) << 8) / 100; +} + +u8 cl_power_tx_ant(struct cl_hw *cl_hw, enum cl_wrs_mode mode) +{ + if (mode == WRS_MODE_CCK) + return hweight8(cl_hw->conf->ce_cck_tx_ant_mask); + + if (mode <= WRS_MODE_VHT) + return min_t(u8, cl_hw->num_antennas, MAX_ANTENNAS_OFDM_HT_VHT); + + return cl_hw->num_antennas; +} + +s32 cl_power_antenna_gain_q8(struct cl_hw *cl_hw) +{ + u8 channel = cl_hw->channel; + + if (channel >= 36 && channel <= 64) + return convert_str_int_q8(cl_hw->conf->ce_ant_gain_36_64); + else if (channel >= 100 && channel <= 140) + return convert_str_int_q8(cl_hw->conf->ce_ant_gain_100_140); + else if (channel >= 149 && channel < 165) + return convert_str_int_q8(cl_hw->conf->ce_ant_gain_149_165); + else + return convert_str_int_q8(cl_hw->conf->ce_ant_gain); /* 2.4g and 6g */ +} + +s32 cl_power_antenna_gain_q1(struct cl_hw *cl_hw) +{ + return cl_power_antenna_gain_q8(cl_hw) >> 7; +} + +s32 cl_power_array_gain_q8(struct cl_hw *cl_hw, u8 tx_ant) +{ + /* + * Format in NVRAM of ce_arr_gain=A,B,C,D,E,F + * A is the array gain with 1 tx_ant, B is with 2 tx_ant and so on... + */ + int arr_gain_val = 0; + int arr_gain_len = 0; + int idx = 0; + char *arr_gain_cpy = NULL; + char *arr_gain_cpy_p = NULL; + char *arr_gain_str = NULL; + + arr_gain_len = strlen(cl_hw->conf->ce_arr_gain) + 1; + arr_gain_cpy_p = kzalloc(arr_gain_len, GFP_ATOMIC); + arr_gain_cpy = arr_gain_cpy_p; + + if (!arr_gain_cpy) + return 0; + + /* Copy cl_hw->conf->ce_arr_gain so its value won't be changed by strsep() */ + memcpy(arr_gain_cpy, cl_hw->conf->ce_arr_gain, arr_gain_len); + + /* Arr_gain_str points to the array gain of 1 tx_ant */ + arr_gain_str = strsep(&arr_gain_cpy, ","); + + /* Only a single value in ce_arr_gain - same value will be applied for all tx_ant */ + if (!arr_gain_cpy) { + arr_gain_val = convert_str_int_q8(arr_gain_str); + } else { + /* Keep iterating until getting to the correct ant idx */ + for (idx = 1; arr_gain_str && (idx < tx_ant); idx++) + arr_gain_str = strsep(&arr_gain_cpy, ","); + + arr_gain_val = arr_gain_str ? convert_str_int_q8(arr_gain_str) : 0; + } + + kfree(arr_gain_cpy_p); + + return arr_gain_val; +} + +s8 cl_power_array_gain_q2(struct cl_hw *cl_hw, u8 tx_ant) +{ + return (s8)(cl_power_array_gain_q8(cl_hw, tx_ant) >> 6); +} + +s32 cl_power_array_gain_q1(struct cl_hw *cl_hw, u8 tx_ant) +{ + return cl_power_array_gain_q8(cl_hw, tx_ant) >> 7; +} + +static s32 cl_power_bf_gain_q8(struct cl_hw *cl_hw, u8 tx_ant, u8 nss) +{ + /* + * Format in NVRAM of ce_bf_gain=A,B,C,D + * A is the bf gain with 1 NSS, B is with 2 NSS and so on... + */ + int bf_gain_val = 0; + int bf_gain_len = 0; + int idx = 0; + char *bf_gain_cpy = NULL; + char *bf_gain_cpy_p = NULL; + char *bf_gain_str = NULL; + s8 *bf_gain_ptr = NULL; + + if (tx_ant == 6) { + bf_gain_ptr = cl_hw->conf->ce_bf_gain_6_ant; + } else if (tx_ant == 5) { + bf_gain_ptr = cl_hw->conf->ce_bf_gain_5_ant; + } else if (tx_ant == 4) { + bf_gain_ptr = cl_hw->conf->ce_bf_gain_4_ant; + } else if (tx_ant == 3) { + bf_gain_ptr = cl_hw->conf->ce_bf_gain_3_ant; + } else if (tx_ant == 2) { + bf_gain_ptr = cl_hw->conf->ce_bf_gain_2_ant; + } else if (tx_ant == 1) { + goto out; + } else { + pr_err("[%s]: invalid tx_ant %u\n", __func__, tx_ant); + goto out; + } + + bf_gain_len = strlen(bf_gain_ptr) + 1; + bf_gain_cpy_p = kzalloc(bf_gain_len, GFP_ATOMIC); + bf_gain_cpy = bf_gain_cpy_p; + + if (!bf_gain_cpy) + return 0; + + /* Copy cl_hw->conf->ce_bf_gain_*_ant so its value won't be changed by strsep() */ + memcpy(bf_gain_cpy, bf_gain_ptr, bf_gain_len); + + /* Bf_gain_str points to the bf gain of 1 SS */ + bf_gain_str = strsep(&bf_gain_cpy, ","); + + /* Keep iterating until getting to the correct ss index */ + for (idx = 0; bf_gain_str && (idx < nss); idx++) + bf_gain_str = strsep(&bf_gain_cpy, ","); + + bf_gain_val = bf_gain_str ? convert_str_int_q8(bf_gain_str) : 0; + + kfree(bf_gain_cpy_p); + out: + return bf_gain_val; +} + +s32 cl_power_bf_gain_q1(struct cl_hw *cl_hw, u8 tx_ant, u8 nss) +{ + return cl_power_bf_gain_q8(cl_hw, tx_ant, nss) >> 7; +} + +static s32 cl_power_min_ant_q8(struct cl_hw *cl_hw) +{ + return convert_str_int_q8(cl_hw->conf->ci_min_ant_pwr); +} + +s32 cl_power_min_ant_q1(struct cl_hw *cl_hw) +{ + return cl_power_min_ant_q8(cl_hw) >> 7; +}; + +s8 cl_power_bw_factor_q2(struct cl_hw *cl_hw, u8 bw) +{ + /* + * Format in NVRAM of ci_bw_factor=A,B,C,D + * A is the bw factor for bw 20MHz, B is for 40MHz and so on.. + */ + int bw_factor_val = 0; + int bw_factor_len = 0; + int idx = 0; + char *bw_factor_cpy = NULL; + char *bw_factor_cpy_p = NULL; + char *bw_factor_str = NULL; + + bw_factor_len = strlen(cl_hw->conf->ci_bw_factor) + 1; + bw_factor_cpy = kzalloc(bw_factor_len, GFP_ATOMIC); + bw_factor_cpy = bw_factor_cpy_p; + + if (!bw_factor_cpy) + return 0; + + /* Copy cl_hw->conf->ci_bw_factor so its value won't be changed by strsep() */ + memcpy(bw_factor_cpy, cl_hw->conf->ci_bw_factor, bw_factor_len); + + /* Bw_factor_str points to the bw factor of 20MHz */ + bw_factor_str = strsep(&bw_factor_cpy, ","); + + /* Only a single value in ci_bw_factor - same value will be applied for all bandwidths */ + if (!bw_factor_cpy) { + bw_factor_val = convert_str_int_q8(bw_factor_str); + } else { + /* Keep iterating until getting to the correct bw index */ + for (idx = 0; bw_factor_str && (idx < bw); idx++) + bw_factor_str = strsep(&bw_factor_cpy, ","); + + bw_factor_val = bw_factor_str ? convert_str_int_q8(bw_factor_str) : 0; + } + + kfree(bw_factor_cpy_p); + + return (s8)(bw_factor_val >> 6); +} + +static s32 cl_power_average_calib_q8(struct cl_hw *cl_hw, u8 ant_num) +{ + u8 ant = 0, ant_cnt = 0; + u8 chan_idx = cl_channel_to_index(cl_hw, cl_hw->channel); + s32 total_calib_pow = 0; + + if (chan_idx == INVALID_CHAN_IDX) + return 0; + + for (ant = 0; ant < MAX_ANTENNAS && ant_cnt < ant_num; ant++) { + if (!(cl_hw->mask_num_antennas & BIT(ant))) + continue; + + total_calib_pow += cl_hw->tx_pow_info[chan_idx][ant].power; + ant_cnt++; + } + + return ((total_calib_pow << 8) / ant_num); +} + +s32 cl_power_average_calib_q1(struct cl_hw *cl_hw, u8 ant_num) +{ + return cl_power_average_calib_q8(cl_hw, ant_num) >> 7; +} + +static s32 cl_power_total_q8(struct cl_hw *cl_hw, s8 pwr_offset_q1, u8 tx_ant, u8 nss, + enum cl_wrs_mode mode, bool is_auto_resp) +{ + s32 bf_gain_q8 = 0; + s32 antenna_gain_q8 = cl_power_antenna_gain_q8(cl_hw); + s32 array_gain_q8 = cl_power_array_gain_q8(cl_hw, tx_ant); + s32 pwr_offset_q8 = (s32)pwr_offset_q1 << 7; + s32 calib_power_q8 = cl_power_average_calib_q8(cl_hw, tx_ant); + s32 total_power_q8 = 0; + + if (!is_auto_resp) + bf_gain_q8 = (mode > WRS_MODE_OFDM) ? cl_power_bf_gain_q8(cl_hw, tx_ant, nss) : 0; + + total_power_q8 = calib_power_q8 + bf_gain_q8 + array_gain_q8 + + antenna_gain_q8 + pwr_offset_q8; + + /* FCC calculation */ + if (cl_hw->channel_info.standard == NL80211_DFS_FCC) + total_power_q8 -= min(bf_gain_q8 + antenna_gain_q8, 6 << 8); + + return total_power_q8; +} + +static s32 cl_power_eirp_delta_q1(struct cl_hw *cl_hw, u8 bw, s8 pwr_offset_q1, u8 tx_ant, + u8 nss, enum cl_wrs_mode mode, bool is_auto_resp) +{ + /* Calculate total TX power */ + s32 total_power_q8 = cl_power_total_q8(cl_hw, pwr_offset_q1, tx_ant, nss, + mode, is_auto_resp); + + /* EIRP power limit */ + s32 eirp_power_limit_q8 = cl_chan_info_get_eirp_limit_q8(cl_hw, bw); + + /* Delta between total TX power and EIRP limit */ + return (total_power_q8 - eirp_power_limit_q8) >> 7; +} + +static s8 cl_power_calc_q1(struct cl_hw *cl_hw, s8 mcs_offset_q1, u8 bw, u8 nss, + enum cl_wrs_mode mode, bool is_auto_resp, u8 *trunc_pwr_q1) +{ + /* Result is in 0.5dBm resolution */ + u8 tx_ant = cl_power_tx_ant(cl_hw, mode); + s32 calib_power_q1 = cl_power_average_calib_q1(cl_hw, tx_ant); + s32 res_q1 = calib_power_q1 + mcs_offset_q1; + s32 min_pwr_q1 = POWER_MIN_DB_Q1; + u32 trunc_pwr_val_q1 = 0; + bool eirp_regulatory_en = cl_hw->chip->conf->ce_production_mode ? + cl_hw->conf->ce_eirp_regulatory_prod_en : cl_hw->conf->ce_eirp_regulatory_op_en; + + if (cl_hw->channel_info.use_channel_info && eirp_regulatory_en) { + s32 delta_power_q1 = cl_power_eirp_delta_q1(cl_hw, bw, mcs_offset_q1, + tx_ant, nss, mode, is_auto_resp); + + if (delta_power_q1 > 0) { + /* + * If tx power is greater than the limitation + * subtract delta power from the result + */ + res_q1 -= delta_power_q1; + trunc_pwr_val_q1 = delta_power_q1; + } + } + + if (is_auto_resp) + min_pwr_q1 += cl_power_min_ant_q1(cl_hw); + + if (res_q1 < min_pwr_q1) { + trunc_pwr_val_q1 = max((s32)trunc_pwr_val_q1 - min_pwr_q1 - res_q1, 0); + res_q1 = min_pwr_q1; + } + + if (is_auto_resp) + res_q1 += cl_power_array_gain_q1(cl_hw, tx_ant); + + if (trunc_pwr_q1) + *trunc_pwr_q1 = (u8)trunc_pwr_val_q1; + + return (s8)res_q1; +} + +static s8 cl_power_offset_he(struct cl_hw *cl_hw, u8 bw, u8 mcs) +{ + u8 channel = cl_hw->channel; + s8 *ppmcs = NULL; + + switch (cl_hw->conf->ci_band_num) { + case BAND_5G: + if (channel >= 36 && channel <= 64) + ppmcs = cl_hw->conf->ce_ppmcs_offset_he_36_64; + else if (channel >= 100 && channel <= 140) + ppmcs = cl_hw->conf->ce_ppmcs_offset_he_100_140; + else + ppmcs = cl_hw->conf->ce_ppmcs_offset_he_149_165; + break; + case BAND_24G: + ppmcs = cl_hw->conf->ce_ppmcs_offset_he; + break; + case BAND_6G: + ppmcs = cl_hw->conf->ce_ppmcs_offset_he_6g; + break; + default: + return 0; + } + + return ppmcs[mcs] + cl_hw->conf->ce_ppbw_offset[bw]; +} + +static s8 cl_power_offset_ht_vht(struct cl_hw *cl_hw, u8 bw, u8 mcs) +{ + u8 channel = cl_hw->channel; + s8 *ppmcs = NULL; + + switch (cl_hw->conf->ci_band_num) { + case BAND_5G: + if (channel >= 36 && channel <= 64) + ppmcs = cl_hw->conf->ce_ppmcs_offset_ht_vht_36_64; + else if (channel >= 100 && channel <= 140) + ppmcs = cl_hw->conf->ce_ppmcs_offset_ht_vht_100_140; + else + ppmcs = cl_hw->conf->ce_ppmcs_offset_ht_vht_149_165; + break; + case BAND_24G: + ppmcs = cl_hw->conf->ce_ppmcs_offset_ht; + break; + case BAND_6G: + default: + return 0; + } + + return ppmcs[mcs] + cl_hw->conf->ce_ppbw_offset[bw]; +} + +static s8 cl_power_offset_ofdm(struct cl_hw *cl_hw, u8 mcs) +{ + u8 channel = cl_hw->channel; + s8 *ppmcs = NULL; + + switch (cl_hw->conf->ci_band_num) { + case BAND_5G: + if (channel >= 36 && channel <= 64) + ppmcs = cl_hw->conf->ce_ppmcs_offset_ofdm_36_64; + else if (channel >= 100 && channel <= 140) + ppmcs = cl_hw->conf->ce_ppmcs_offset_ofdm_100_140; + else + ppmcs = cl_hw->conf->ce_ppmcs_offset_ofdm_149_165; + break; + case BAND_24G: + ppmcs = cl_hw->conf->ce_ppmcs_offset_ofdm; + break; + case BAND_6G: + default: + return 0; + } + + return ppmcs[mcs] + cl_hw->conf->ce_ppbw_offset[CHNL_BW_20]; +} + +static s8 cl_power_offset_cck(struct cl_hw *cl_hw, u8 mcs) +{ + s8 *ppmcs = cl_hw->conf->ce_ppmcs_offset_cck; + + if (cl_band_is_24g(cl_hw)) + return ppmcs[mcs] + cl_hw->conf->ce_ppbw_offset[CHNL_BW_20]; + + return 0; +} + +s8 cl_power_offset_q1(struct cl_hw *cl_hw, u8 mode, u8 bw, u8 mcs) +{ + if (mode == WRS_MODE_HE) + return cl_power_offset_he(cl_hw, bw, mcs); + else if (mode == WRS_MODE_HT || mode == WRS_MODE_VHT) + return cl_power_offset_ht_vht(cl_hw, bw, mcs); + else if (mode == WRS_MODE_OFDM) + return cl_power_offset_ofdm(cl_hw, mcs); + else if (mode == WRS_MODE_CCK) + return cl_power_offset_cck(cl_hw, mcs); + + return 0; +} + +#define UPPER_POWER_MARGIN_Q2 (38 << 2) +#define LOWER_POWER_MARGIN_Q2 (50 << 2) + +s8 cl_power_offset_check_margin(struct cl_hw *cl_hw, u8 bw, u8 ant_idx, s8 offset_q2) +{ + s8 new_offset_q2 = 0; + s8 bw_factor_q2 = cl_hw->power_db.bw_factor_q2[bw]; + s8 ant_factor_q2 = cl_hw->power_db.ant_factor_q2[ant_idx]; + s8 total_offset_upper_q2 = bw_factor_q2 + offset_q2; + s8 total_offset_lower_q2 = bw_factor_q2 + ant_factor_q2 + offset_q2; + bool upper_limit_valid = (total_offset_upper_q2 <= UPPER_POWER_MARGIN_Q2); + bool lower_limit_valid = (total_offset_lower_q2 <= LOWER_POWER_MARGIN_Q2); + + if (upper_limit_valid && lower_limit_valid) { + return offset_q2; + } else if (!upper_limit_valid && lower_limit_valid) { + new_offset_q2 = UPPER_POWER_MARGIN_Q2 - bw_factor_q2; + + return new_offset_q2; + } else if (upper_limit_valid && !lower_limit_valid) { + new_offset_q2 = LOWER_POWER_MARGIN_Q2 - bw_factor_q2 - ant_factor_q2; + + return new_offset_q2; + } + + new_offset_q2 = min(UPPER_POWER_MARGIN_Q2 - bw_factor_q2, + LOWER_POWER_MARGIN_Q2 - bw_factor_q2 - ant_factor_q2); + + return new_offset_q2; +} + +static s32 cl_power_calc_total_from_eirp_q1(struct cl_hw *cl_hw, s32 tx_power, u8 nss, + enum cl_wrs_mode mode, u8 *trunc_pwr_q1) +{ + s32 pwr_q1, total_pwr_q1, delta_pwr_q1 = 0; + u8 tx_ant; + s32 antenna_gain_q1; + s32 array_gain_q1; + s32 bf_gain_q1; + bool eirp_regulatory_en = cl_hw->chip->conf->ce_production_mode ? + cl_hw->conf->ce_eirp_regulatory_prod_en : cl_hw->conf->ce_eirp_regulatory_op_en; + + pwr_q1 = tx_power << 1; + + tx_ant = cl_power_tx_ant(cl_hw, mode); + array_gain_q1 = cl_power_array_gain_q1(cl_hw, tx_ant); + antenna_gain_q1 = cl_power_antenna_gain_q1(cl_hw); + /* bf gain is not used for CCK or OFDM */ + bf_gain_q1 = (mode > WRS_MODE_OFDM) ? cl_power_bf_gain_q1(cl_hw, tx_ant, nss) : 0; + + /* FCC calculation */ + if (cl_hw->channel_info.standard == NL80211_DFS_FCC) + pwr_q1 -= min(bf_gain_q1 + antenna_gain_q1, 6 << 1); + + if (cl_hw->channel_info.use_channel_info && eirp_regulatory_en) { + s32 eirp_pwr_limit_q1; + + eirp_pwr_limit_q1 = cl_chan_info_get_eirp_limit_q8(cl_hw, 0) >> 7; + if (pwr_q1 > eirp_pwr_limit_q1) { + delta_pwr_q1 = pwr_q1 - eirp_pwr_limit_q1; + pwr_q1 = eirp_pwr_limit_q1; + } + } + + total_pwr_q1 = pwr_q1 - antenna_gain_q1 - array_gain_q1 - bf_gain_q1; + if (total_pwr_q1 < POWER_MIN_DB_Q1) { + delta_pwr_q1 = max(delta_pwr_q1 - (POWER_MIN_DB_Q1 - total_pwr_q1), 0); + total_pwr_q1 = POWER_MIN_DB_Q1; + } + + if (trunc_pwr_q1) + *trunc_pwr_q1 = (u8)delta_pwr_q1; + + return total_pwr_q1; +} + +static s32 cl_power_calc_auto_resp_from_eirp_q1(struct cl_hw *cl_hw, s32 tx_power, u8 nss, + enum cl_wrs_mode mode) +{ + s32 auto_resp_total_pwr_q1, auto_resp_min_pwr_q1; + u8 tx_ant; + s32 array_gain_q1; + s32 total_pwr_q1; + + auto_resp_min_pwr_q1 = POWER_MIN_DB_Q1 + cl_power_min_ant_q1(cl_hw); + tx_ant = cl_power_tx_ant(cl_hw, mode); + array_gain_q1 = cl_power_array_gain_q1(cl_hw, tx_ant); + total_pwr_q1 = cl_power_calc_total_from_eirp_q1(cl_hw, tx_power, nss, mode, NULL); + + auto_resp_total_pwr_q1 = array_gain_q1 + total_pwr_q1; + if (auto_resp_total_pwr_q1 < auto_resp_min_pwr_q1) + auto_resp_total_pwr_q1 = auto_resp_min_pwr_q1; + + return auto_resp_total_pwr_q1; +} + +static s8 cl_calc_ant_pwr_q1(struct cl_hw *cl_hw, u8 bw, u8 nss, u8 mcs, + enum cl_wrs_mode mode, u8 *trunc_val) +{ + s32 eirp_pwr = 0; + s8 ant_pwr_q1; + + eirp_pwr = cl_hw->new_tx_power; + if (eirp_pwr) { + ant_pwr_q1 = cl_power_calc_total_from_eirp_q1(cl_hw, eirp_pwr, nss, + mode, trunc_val); + } else { + s8 pwr_offset_q1; + + pwr_offset_q1 = cl_power_offset_q1(cl_hw, mode, bw, mcs); + ant_pwr_q1 = cl_power_calc_q1(cl_hw, pwr_offset_q1, bw, nss, + mode, false, trunc_val); + } + return ant_pwr_q1; +} + +static s8 cl_calc_auto_resp_pwr_q1(struct cl_hw *cl_hw, u8 bw, u8 nss, u8 mcs, + enum cl_wrs_mode mode) +{ + s32 eirp_pwr = 0; + s8 auto_resp_pwr_q1; + + eirp_pwr = cl_hw->new_tx_power; + if (eirp_pwr) { + auto_resp_pwr_q1 = cl_power_calc_auto_resp_from_eirp_q1(cl_hw, eirp_pwr, + nss, mode); + } else { + s8 pwr_offset_q1; + + pwr_offset_q1 = cl_power_offset_q1(cl_hw, mode, bw, mcs); + auto_resp_pwr_q1 = cl_power_calc_q1(cl_hw, pwr_offset_q1, bw, nss, + mode, true, NULL); + } + return auto_resp_pwr_q1; +} + +static void cl_power_tables_update_cck(struct cl_hw *cl_hw, + struct cl_pwr_tables *pwr_tables) +{ + u8 mcs; + u8 trunc_value = 0; + + /* CCK - Enforce EIRP limitations */ + for (mcs = 0; mcs < WRS_MCS_MAX_CCK; mcs++) { + pwr_tables->ant_pwr_cck[mcs] = cl_calc_ant_pwr_q1(cl_hw, 0, 0, mcs, WRS_MODE_CCK, + &trunc_value); + + cl_hw->pwr_trunc.cck[mcs] = trunc_value; + + /* Auto response */ + pwr_tables->pwr_auto_resp_cck[mcs] = cl_calc_auto_resp_pwr_q1(cl_hw, 0, 0, mcs, + WRS_MODE_CCK); + } +} + +static void cl_power_tables_update_ofdm(struct cl_hw *cl_hw, + struct cl_pwr_tables *pwr_tables) +{ + u8 mcs; + u8 trunc_value = 0; + + /* OFDM - Enforce EIRP limitations */ + for (mcs = 0; mcs < WRS_MCS_MAX_OFDM; mcs++) { + pwr_tables->ant_pwr_ofdm[mcs] = cl_calc_ant_pwr_q1(cl_hw, 0, 0, mcs, WRS_MODE_OFDM, + &trunc_value); + cl_hw->pwr_trunc.ofdm[mcs] = trunc_value; + + /* Auto response */ + pwr_tables->pwr_auto_resp_ofdm[mcs] = cl_calc_auto_resp_pwr_q1(cl_hw, 0, 0, mcs, + WRS_MODE_OFDM); + } +} + +static u8 cl_power_tables_update_ht_vht(struct cl_hw *cl_hw, + struct cl_pwr_tables *pwr_tables) +{ + bool is_24g = cl_band_is_24g(cl_hw); + bool is_5g = cl_band_is_5g(cl_hw); + u8 bw; + u8 nss; + u8 mcs; + u8 trunc_value = 0; + u8 min_bw_idx_limit_vht = 0; + u8 max_mcs_ht_vht = (is_5g || (is_24g && cl_hw->conf->ci_vht_cap_24g)) ? + WRS_MCS_MAX_VHT : WRS_MCS_MAX_HT; + s16 min_bw_limit = 0; + s32 eirp_power_limit_q8; + + for (bw = 0, min_bw_limit = 0xFFFF; bw < cl_max_bw_idx(WRS_MODE_VHT, is_24g); bw++) { + if (!cl_hw_is_prod_or_listener(cl_hw) && + !cl_chan_info_get(cl_hw, cl_hw->channel, bw)) + continue; + + /* Find lowest EIRP power limitation among all bw for auto resp calculations */ + eirp_power_limit_q8 = cl_chan_info_get_eirp_limit_q8(cl_hw, bw); + if (eirp_power_limit_q8 < min_bw_limit) { + min_bw_limit = eirp_power_limit_q8; + min_bw_idx_limit_vht = bw; + } + + /* HT/VHT - Enforce EIRP limitations */ + for (mcs = 0; mcs < max_mcs_ht_vht; mcs++) { + for (nss = 0; nss < PWR_TBL_VHT_BF_SIZE; nss++) { + pwr_tables->ant_pwr_ht_vht[bw][mcs][nss] = + cl_calc_ant_pwr_q1(cl_hw, bw, nss, mcs, WRS_MODE_VHT, + &trunc_value); + cl_hw->pwr_trunc.ht_vht[bw][mcs][nss] = trunc_value; + } + } + } + + /* Auto resp HT/VHT - Enforce EIRP limitations */ + for (mcs = 0; mcs < max_mcs_ht_vht; mcs++) + pwr_tables->pwr_auto_resp_ht_vht[mcs] = + cl_calc_auto_resp_pwr_q1(cl_hw, min_bw_idx_limit_vht, 0, mcs, + WRS_MODE_VHT); + + return min_bw_idx_limit_vht; +} + +static u8 cl_power_tables_update_he(struct cl_hw *cl_hw, + struct cl_pwr_tables *pwr_tables) +{ + bool is_24g = cl_band_is_24g(cl_hw); + u8 bw; + u8 nss; + u8 mcs; + u8 trunc_value = 0; + u8 min_bw_idx_limit_he = 0; + s16 min_bw_limit = 0; + s32 eirp_power_limit_q8; + + for (bw = 0, min_bw_limit = 0xFFFF; bw < cl_max_bw_idx(WRS_MODE_HE, is_24g); bw++) { + if (!cl_hw_is_prod_or_listener(cl_hw) && + !cl_chan_info_get(cl_hw, cl_hw->channel, bw)) + continue; + + /* Find lowest EIRP power limitation among all bw for auto resp calculations */ + eirp_power_limit_q8 = cl_chan_info_get_eirp_limit_q8(cl_hw, bw); + if (eirp_power_limit_q8 < min_bw_limit) { + min_bw_limit = eirp_power_limit_q8; + min_bw_idx_limit_he = bw; + } + + /* HE - Enforce EIRP limitations */ + for (mcs = 0; mcs < WRS_MCS_MAX_HE; mcs++) { + for (nss = 0; nss < PWR_TBL_HE_BF_SIZE; nss++) { + pwr_tables->ant_pwr_he[bw][mcs][nss] = + cl_calc_ant_pwr_q1(cl_hw, bw, nss, mcs, WRS_MODE_HE, + &trunc_value); + cl_hw->pwr_trunc.he[bw][mcs][nss] = trunc_value; + } + } + } + + /* Auto resp HE - Enforce EIRP limitations */ + for (mcs = 0; mcs < WRS_MCS_MAX_HE; mcs++) + pwr_tables->pwr_auto_resp_he[mcs] = + cl_calc_auto_resp_pwr_q1(cl_hw, min_bw_idx_limit_he, 0, mcs, WRS_MODE_HE); + + return min_bw_idx_limit_he; +} + +static u8 cl_power_calc_max(struct cl_hw *cl_hw, u8 bw, enum cl_wrs_mode mode) +{ + u8 tx_ant = cl_power_tx_ant(cl_hw, mode); + /* Total TX power - pass is_auto_resp = true in order to ignore bf gain */ + s32 total_power_q8 = cl_power_total_q8(cl_hw, 0, tx_ant, 0, mode, true); + /* EIRP power limit */ + s32 eirp_power_limit_q8 = cl_chan_info_get_eirp_limit_q8(cl_hw, bw); + + return (min(total_power_q8, eirp_power_limit_q8) >> 8); +} + +static s8 cl_power_vns_calc_q1(struct cl_hw *cl_hw, u8 bw, + enum cl_wrs_mode mode, bool is_auto_resp) +{ + u8 max_tx_pwr = cl_power_calc_max(cl_hw, bw, mode); + u8 tx_ant = cl_power_tx_ant(cl_hw, mode); + s32 vns_pwr_limit_q8 = min_t(u8, cl_hw->conf->ci_vns_pwr_limit, max_tx_pwr) << 8; + s32 antenna_gain_q8 = cl_power_antenna_gain_q8(cl_hw); + s32 array_gain_q8 = (is_auto_resp ? 0 : cl_power_array_gain_q8(cl_hw, tx_ant)); + s32 min_ant_pwr_q8 = cl_power_min_ant_q8(cl_hw); + s32 min_pwr_q8 = is_auto_resp ? (POWER_MIN_DB_Q8 + min_ant_pwr_q8) : POWER_MIN_DB_Q8; + s32 res_q8 = vns_pwr_limit_q8 - antenna_gain_q8 - array_gain_q8; + + if (res_q8 < min_pwr_q8) + res_q8 = min_pwr_q8; + + /* Result should be in 0.5dBm resolution */ + return (s8)(res_q8 >> 7); +} + +static void cl_power_tables_update_vns(struct cl_hw *cl_hw, + struct cl_pwr_tables *pwr_tables, + u8 min_bw_idx_limit_vht, + u8 min_bw_idx_limit_he) +{ + /* VNS */ + pwr_tables->ant_pwr_vns_he = + cl_power_vns_calc_q1(cl_hw, min_bw_idx_limit_he, WRS_MODE_HE, false); + pwr_tables->ant_pwr_vns_ht_vht = + cl_power_vns_calc_q1(cl_hw, min_bw_idx_limit_vht, WRS_MODE_VHT, false); + pwr_tables->ant_pwr_vns_ofdm = + cl_power_vns_calc_q1(cl_hw, 0, WRS_MODE_OFDM, false); + pwr_tables->ant_pwr_vns_cck = + cl_power_vns_calc_q1(cl_hw, 0, WRS_MODE_CCK, false); + + /* Auto response VNS */ + pwr_tables->pwr_auto_resp_vns_he = + cl_power_vns_calc_q1(cl_hw, min_bw_idx_limit_he, WRS_MODE_HE, true); + pwr_tables->pwr_auto_resp_vns_ht_vht = + cl_power_vns_calc_q1(cl_hw, min_bw_idx_limit_vht, WRS_MODE_VHT, true); + pwr_tables->pwr_auto_resp_vns_ofdm = + cl_power_vns_calc_q1(cl_hw, 0, WRS_MODE_OFDM, true); + pwr_tables->pwr_auto_resp_vns_cck = + cl_power_vns_calc_q1(cl_hw, 0, WRS_MODE_CCK, true); +} + +static void cl_power_tables_update_by_offset(struct cl_hw *cl_hw, + struct cl_pwr_tables *pwr_tables, + s8 offset) +{ + u8 mcs = 0; + u8 bw = 0; + u8 nss = 0; + + /* CCK - Enforce EIRP limitations */ + for (mcs = 0; mcs < WRS_MCS_MAX_CCK; mcs++) { + pwr_tables->ant_pwr_cck[mcs] += offset; + + /* Auto response */ + pwr_tables->pwr_auto_resp_cck[mcs] += offset; + } + + /* OFDM - Enforce EIRP limitations */ + for (mcs = 0; mcs < WRS_MCS_MAX_OFDM; mcs++) { + pwr_tables->ant_pwr_ofdm[mcs] += offset; + + /* Auto response */ + pwr_tables->pwr_auto_resp_ofdm[mcs] += offset; + } + + for (bw = 0; bw < CHNL_BW_MAX; bw++) { + /* HT/VHT - Enforce EIRP limitations */ + for (mcs = 0; mcs < WRS_MCS_MAX_VHT; mcs++) { + for (nss = 0; nss < PWR_TBL_VHT_BF_SIZE; nss++) + pwr_tables->ant_pwr_ht_vht[bw][mcs][nss] += offset; + + /* + * Auto response: + * always with disabled BF so the offset of the last nss is used + */ + pwr_tables->pwr_auto_resp_ht_vht[mcs] += offset; + } + + /* HE - Enforce EIRP limitations */ + for (mcs = 0; mcs < WRS_MCS_MAX_HE; mcs++) { + for (nss = 0; nss < PWR_TBL_HE_BF_SIZE; nss++) + pwr_tables->ant_pwr_he[bw][mcs][nss] += offset; + + /* + * Auto response: + * always with disabled BF so the offset of the last nss is used + */ + pwr_tables->pwr_auto_resp_he[mcs] += offset; + } + } +} + +static s8 cl_power_get_offset(u16 percentage) +{ + if (percentage >= 94) + return 0; + else if (percentage >= 84) + return -1; /* -0.5dBm */ + else if (percentage >= 75) + return -2; /* -1dBm */ + else if (percentage >= 67) + return -3; /* -1.5dBm */ + else if (percentage >= 59) + return -4; /* -2dBm */ + else if (percentage >= 54) + return -5; /* -2.5dBm */ + else if (percentage >= 48) + return -6; /* -3dBm */ + else if (percentage >= 43) + return -7; /* -3.5dBm */ + else if (percentage >= 38) + return -8; /* -4dBm */ + else if (percentage >= 34) + return -9; /* -4.5dBm */ + else if (percentage >= 30) + return -10; /* -5dBm */ + else if (percentage >= 27) + return -11; /* -5.5dBm */ + else if (percentage >= 24) + return -12; /* -6dBm */ + else if (percentage >= 22) + return -13; /* -6.5dBm */ + else if (percentage >= 19) + return -14; /* -7dBm */ + else if (percentage >= 17) + return -15; /* -7.5dBm */ + else if (percentage >= 15) + return -16; /* -8dBm */ + else if (percentage >= 14) + return -17; /* -8.5dBm */ + else if (percentage >= 12) + return -18; /* -9dBm */ + else if (percentage >= 11) + return -19; /* -9.5dBm */ + else if (percentage >= 10) + return -20; /* -10dBm */ + else if (percentage >= 9) + return -21; /* -10.5dBm */ + else if (percentage >= 8) + return -22; /* -11dBm */ + else if (percentage >= 7) + return -23; /* -11.5dBm */ + else if (percentage >= 6) + return -24; /* -12dBm */ + else if (percentage >= 5) + return -26; /* -13dBm */ + else if (percentage >= 4) + return -28; /* -14dBm */ + else if (percentage >= 3) + return -30; /* -15dBm */ + else if (percentage >= 2) + return -34; /* -17dBm */ + else if (percentage >= 1) + return -40; /* -20dBm */ + + /* Should not get here */ + return 0; +} + +static void cl_power_control_apply_percentage(struct cl_hw *cl_hw) +{ + struct cl_power_db *power_db = &cl_hw->power_db; + u8 percentage = cl_hw->conf->ce_tx_power_control; + + power_db->curr_percentage = percentage; + + if (percentage != 100) { + power_db->curr_offset = cl_power_get_offset(percentage); + cl_power_tables_update_by_offset(cl_hw, + &cl_hw->phy_data_info.data->pwr_tables, + power_db->curr_offset); + } +} + +void cl_power_tables_update(struct cl_hw *cl_hw, struct cl_pwr_tables *pwr_tables) +{ + bool is_24g = cl_band_is_24g(cl_hw); + bool is_6g = cl_band_is_6g(cl_hw); + u8 min_bw_idx_limit_he = 0; + u8 min_bw_idx_limit_vht = 0; + + memset(pwr_tables, 0, sizeof(struct cl_pwr_tables)); + + if (is_24g) + cl_power_tables_update_cck(cl_hw, pwr_tables); + + cl_power_tables_update_ofdm(cl_hw, pwr_tables); + + if (!is_6g) + min_bw_idx_limit_vht = cl_power_tables_update_ht_vht(cl_hw, pwr_tables); + + min_bw_idx_limit_he = cl_power_tables_update_he(cl_hw, pwr_tables); + + cl_hw->new_tx_power = 0; + + cl_power_tables_update_vns(cl_hw, pwr_tables, min_bw_idx_limit_vht, min_bw_idx_limit_he); + + cl_power_control_apply_percentage(cl_hw); +} + +static s32 cl_power_get_max_cck(struct cl_hw *cl_hw) +{ + struct cl_pwr_tables *pwr_tables = &cl_hw->phy_data_info.data->pwr_tables; + u8 mcs = 0; + u8 tx_ant = cl_power_tx_ant(cl_hw, WRS_MODE_CCK); + s32 ant_gain_q1 = cl_power_antenna_gain_q1(cl_hw); + s32 arr_gain_q1 = cl_power_array_gain_q1(cl_hw, tx_ant); + s32 total_pwr_q1 = 0; + s32 max_pwr_q1 = 0; + + for (mcs = 0; mcs < WRS_MCS_MAX_CCK; mcs++) { + total_pwr_q1 = pwr_tables->ant_pwr_cck[mcs] + ant_gain_q1 + arr_gain_q1; + + if (total_pwr_q1 > max_pwr_q1) + max_pwr_q1 = total_pwr_q1; + } + + return max_pwr_q1; +} + +static s32 cl_power_get_max_ofdm(struct cl_hw *cl_hw) +{ + struct cl_pwr_tables *pwr_tables = &cl_hw->phy_data_info.data->pwr_tables; + u8 mcs = 0; + u8 tx_ant = cl_power_tx_ant(cl_hw, WRS_MODE_OFDM); + s32 ant_gain_q1 = cl_power_antenna_gain_q1(cl_hw); + s32 arr_gain_q1 = cl_power_array_gain_q1(cl_hw, tx_ant); + s32 total_pwr_q1 = 0; + s32 max_pwr_q1 = 0; + + for (mcs = 0; mcs < WRS_MCS_MAX_OFDM; mcs++) { + total_pwr_q1 = pwr_tables->ant_pwr_ofdm[mcs] + ant_gain_q1 + arr_gain_q1; + + if (total_pwr_q1 > max_pwr_q1) + max_pwr_q1 = total_pwr_q1; + } + + return max_pwr_q1; +} + +static s32 cl_power_get_max_ht_vht(struct cl_hw *cl_hw) +{ + struct cl_pwr_tables *pwr_tables = &cl_hw->phy_data_info.data->pwr_tables; + u8 tx_ant = cl_power_tx_ant(cl_hw, WRS_MODE_VHT); + u8 mcs = 0; + u8 bw = 0; + u8 bf = 0; + s32 ant_gain_q1 = cl_power_antenna_gain_q1(cl_hw); + s32 arr_gain_q1 = cl_power_array_gain_q1(cl_hw, tx_ant); + s32 total_pwr_q1 = 0; + s32 max_pwr_q1 = 0; + + for (bw = 0; bw < CHNL_BW_MAX; bw++) { + for (mcs = 0; mcs < WRS_MCS_MAX_VHT; mcs++) { + for (bf = 0; bf < PWR_TBL_VHT_BF_SIZE; bf++) { + total_pwr_q1 = pwr_tables->ant_pwr_ht_vht[bw][mcs][bf] + + ant_gain_q1 + arr_gain_q1; + + if (total_pwr_q1 > max_pwr_q1) + max_pwr_q1 = total_pwr_q1; + } + } + } + + return max_pwr_q1; +} + +static s32 cl_power_get_max_he(struct cl_hw *cl_hw) +{ + struct cl_pwr_tables *pwr_tables = &cl_hw->phy_data_info.data->pwr_tables; + u8 tx_ant = cl_power_tx_ant(cl_hw, WRS_MODE_HE); + u8 mcs = 0; + u8 bw = 0; + u8 bf = 0; + s32 ant_gain_q1 = cl_power_antenna_gain_q1(cl_hw); + s32 arr_gain_q1 = cl_power_array_gain_q1(cl_hw, tx_ant); + s32 total_pwr_q1 = 0; + s32 max_pwr_q1 = 0; + + for (bw = 0; bw < CHNL_BW_MAX; bw++) { + for (mcs = 0; mcs < WRS_MCS_MAX_HE; mcs++) { + for (bf = 0; bf < PWR_TBL_HE_BF_SIZE; bf++) { + total_pwr_q1 = pwr_tables->ant_pwr_he[bw][mcs][bf] + + ant_gain_q1 + arr_gain_q1; + + if (total_pwr_q1 > max_pwr_q1) + max_pwr_q1 = total_pwr_q1; + } + } + } + + return max_pwr_q1; +} + +s32 cl_power_get_max(struct cl_hw *cl_hw) +{ + bool is_24g = cl_band_is_24g(cl_hw); + bool is_6g = cl_band_is_6g(cl_hw); + s32 max_pwr_cck_q1 = is_24g ? cl_power_get_max_cck(cl_hw) : S32_MIN; + s32 max_pwr_ofdm_q1 = cl_power_get_max_ofdm(cl_hw); + s32 max_pwr_ht_vht_q1 = !is_6g ? cl_power_get_max_ht_vht(cl_hw) : S32_MIN; + s32 max_pwr_he_q1 = cl_power_get_max_he(cl_hw); + s32 max_pwr_q1 = 0; + + max_pwr_q1 = max(max_pwr_q1, max_pwr_cck_q1); + max_pwr_q1 = max(max_pwr_q1, max_pwr_ofdm_q1); + max_pwr_q1 = max(max_pwr_q1, max_pwr_ht_vht_q1); + max_pwr_q1 = max(max_pwr_q1, max_pwr_he_q1); + + return (max_pwr_q1 >> 1); +} +

[RFC,v2,54/96] cl8k: add power.c

Commit Message

Patch