/****************************************************************************** * * Copyright(c) 2007 - 2017 Realtek Corporation. * * This program is free software; you can redistribute it and/or modify it * under the terms of version 2 of the GNU General Public License as * published by the Free Software Foundation. * * 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. * * The full GNU General Public License is included in this distribution in the * file called LICENSE. * * Contact Information: * wlanfae * Realtek Corporation, No. 2, Innovation Road II, Hsinchu Science Park, * Hsinchu 300, Taiwan. * * Larry Finger * *****************************************************************************/ #include "mp_precomp.h" #include "phydm_precomp.h" void phydm_ccx_hw_restart(void *dm_void) /*@Will Restart NHM/CLM/FAHM simultaneously*/ { struct dm_struct *dm = (struct dm_struct *)dm_void; u32 reg1 = 0; if (dm->support_ic_type & ODM_IC_11AC_SERIES) reg1 = R_0x994; #ifdef PHYDM_IC_JGR3_SERIES_SUPPORT else if (dm->support_ic_type & ODM_IC_JGR3_SERIES) reg1 = R_0x1e60; #endif else reg1 = R_0x890; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); /*@disable NHM,CLM, FAHM*/ odm_set_bb_reg(dm, reg1, 0x7, 0x0); odm_set_bb_reg(dm, reg1, BIT(8), 0x0); odm_set_bb_reg(dm, reg1, BIT(8), 0x1); } #ifdef FAHM_SUPPORT u16 phydm_hw_divider(void *dm_void, u16 numerator, u16 denumerator) { struct dm_struct *dm = (struct dm_struct *)dm_void; u16 result = DEVIDER_ERROR; u32 tmp_u32 = ((numerator << 16) | denumerator); u32 reg_devider_input; u32 reg; u8 i; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); if (dm->support_ic_type & ODM_IC_11AC_SERIES) { reg_devider_input = 0x1cbc; reg = 0x1f98; } else { reg_devider_input = 0x980; reg = 0x9f0; } odm_set_bb_reg(dm, reg_devider_input, MASKDWORD, tmp_u32); for (i = 0; i < 10; i++) { ODM_delay_ms(1); if (odm_get_bb_reg(dm, reg, BIT(24))) { /*@Chk HW rpt is ready*/ result = (u16)odm_get_bb_reg(dm, reg, MASKBYTE2); break; } } return result; } void phydm_fahm_trigger(void *dm_void, u16 tgr_period) { /*@unit (4us)*/ struct dm_struct *dm = (struct dm_struct *)dm_void; u32 fahm_reg1; if (dm->support_ic_type & ODM_IC_11AC_SERIES) { odm_set_bb_reg(dm, R_0x1cf8, 0xffff00, tgr_period); fahm_reg1 = 0x994; } else { odm_set_bb_reg(dm, R_0x978, 0xff000000, (tgr_period & 0xff)); odm_set_bb_reg(dm, R_0x97c, 0xff, (tgr_period & 0xff00) >> 8); fahm_reg1 = 0x890; } odm_set_bb_reg(dm, fahm_reg1, BIT(2), 0); odm_set_bb_reg(dm, fahm_reg1, BIT(2), 1); } void phydm_fahm_set_valid_cnt(void *dm_void, u8 numerator_sel, u8 denominator_sel) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx_info = &dm->dm_ccx_info; u32 fahm_reg1; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); if (ccx_info->fahm_nume_sel == numerator_sel && ccx_info->fahm_denom_sel == denominator_sel) { PHYDM_DBG(dm, DBG_ENV_MNTR, "no need to update\n"); return; } ccx_info->fahm_nume_sel = numerator_sel; ccx_info->fahm_denom_sel = denominator_sel; if (dm->support_ic_type & ODM_IC_11AC_SERIES) fahm_reg1 = 0x994; else fahm_reg1 = 0x890; odm_set_bb_reg(dm, fahm_reg1, 0xe0, numerator_sel); odm_set_bb_reg(dm, fahm_reg1, 0x7000, denominator_sel); } void phydm_fahm_get_result(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; u16 fahm_cnt[12]; /*packet count*/ u16 fahm_rpt[12]; /*percentage*/ u16 denominator; /*@fahm_denominator packet count*/ u32 reg_rpt, reg_rpt_2; u32 reg_tmp; boolean is_ready = false; u8 i; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); if (dm->support_ic_type & ODM_IC_11AC_SERIES) { reg_rpt = 0x1f80; reg_rpt_2 = 0x1f98; } else { reg_rpt = 0x9d8; reg_rpt_2 = 0x9f0; } for (i = 0; i < 3; i++) { if (odm_get_bb_reg(dm, reg_rpt_2, BIT(31))) { /*@Chk HW rpt is ready*/ is_ready = true; break; } ODM_delay_ms(1); } if (!is_ready) return; /*@Get FAHM Denominator*/ denominator = (u16)odm_get_bb_reg(dm, reg_rpt_2, MASKLWORD); PHYDM_DBG(dm, DBG_ENV_MNTR, "Reg[0x%x] fahm_denmrtr = %d\n", reg_rpt_2, denominator); /*@Get FAHM nemerator*/ for (i = 0; i < 6; i++) { reg_tmp = odm_get_bb_reg(dm, reg_rpt + (i << 2), MASKDWORD); PHYDM_DBG(dm, DBG_ENV_MNTR, "Reg[0x%x] fahm_denmrtr = %d\n", reg_rpt + (i * 4), reg_tmp); fahm_cnt[i * 2] = (u16)(reg_tmp & MASKLWORD); fahm_cnt[i * 2 + 1] = (u16)((reg_tmp & MASKHWORD) >> 16); } for (i = 0; i < 12; i++) fahm_rpt[i] = phydm_hw_divider(dm, fahm_cnt[i], denominator); PHYDM_DBG(dm, DBG_ENV_MNTR, "FAHM_RPT_cnt[10:0]=[%d, %d, %d, %d, %d(IGI), %d, %d, %d, %d, %d, %d, %d]\n", fahm_cnt[11], fahm_cnt[10], fahm_cnt[9], fahm_cnt[8], fahm_cnt[7], fahm_cnt[6], fahm_cnt[5], fahm_cnt[4], fahm_cnt[3], fahm_cnt[2], fahm_cnt[1], fahm_cnt[0]); PHYDM_DBG(dm, DBG_ENV_MNTR, "FAHM_RPT[10:0]=[%d, %d, %d, %d, %d(IGI), %d, %d, %d, %d, %d, %d, %d]\n", fahm_rpt[11], fahm_rpt[10], fahm_rpt[9], fahm_rpt[8], fahm_rpt[7], fahm_rpt[6], fahm_rpt[5], fahm_rpt[4], fahm_rpt[3], fahm_rpt[2], fahm_rpt[1], fahm_rpt[0]); } void phydm_fahm_set_th_by_igi(void *dm_void, u8 igi) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx_info = &dm->dm_ccx_info; u32 val = 0; u8 f_th[11]; /*@FAHM Threshold*/ u8 rssi_th[11]; /*@in RSSI scale*/ u8 th_gap = 2 * IGI_TO_NHM_TH_MULTIPLIER; /*unit is 0.5dB for FAHM*/ u8 i; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); if (ccx_info->env_mntr_igi == igi) { PHYDM_DBG(dm, DBG_ENV_MNTR, "No need to update FAHM_th, IGI=0x%x\n", ccx_info->env_mntr_igi); return; } ccx_info->env_mntr_igi = igi; /*@bkp IGI*/ if (igi >= CCA_CAP) f_th[0] = (igi - CCA_CAP) * IGI_TO_NHM_TH_MULTIPLIER; else f_th[0] = 0; rssi_th[0] = igi - 10 - CCA_CAP; for (i = 1; i <= 10; i++) { f_th[i] = f_th[0] + th_gap * i; rssi_th[i] = rssi_th[0] + (i << 1); } PHYDM_DBG(dm, DBG_ENV_MNTR, "FAHM_RSSI_th[10:0]=[%d, %d, %d, (IGI)%d, %d, %d, %d, %d, %d, %d, %d]\n", rssi_th[10], rssi_th[9], rssi_th[8], rssi_th[7], rssi_th[6], rssi_th[5], rssi_th[4], rssi_th[3], rssi_th[2], rssi_th[1], rssi_th[0]); if (dm->support_ic_type & ODM_IC_11AC_SERIES) { val = BYTE_2_DWORD(0, f_th[2], f_th[1], f_th[0]); odm_set_bb_reg(dm, R_0x1c38, 0xffffff00, val); val = BYTE_2_DWORD(0, f_th[5], f_th[4], f_th[3]); odm_set_bb_reg(dm, R_0x1c78, 0xffffff00, val); val = BYTE_2_DWORD(0, 0, f_th[7], f_th[6]); odm_set_bb_reg(dm, R_0x1c7c, 0xffff0000, val); val = BYTE_2_DWORD(0, f_th[10], f_th[9], f_th[8]); odm_set_bb_reg(dm, R_0x1cb8, 0xffffff00, val); } else { val = BYTE_2_DWORD(f_th[3], f_th[2], f_th[1], f_th[0]); odm_set_bb_reg(dm, R_0x970, MASKDWORD, val); val = BYTE_2_DWORD(f_th[7], f_th[6], f_th[5], f_th[4]); odm_set_bb_reg(dm, R_0x974, MASKDWORD, val); val = BYTE_2_DWORD(0, f_th[10], f_th[9], f_th[8]); odm_set_bb_reg(dm, R_0x978, 0xffffff, val); } } void phydm_fahm_init(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx_info = &dm->dm_ccx_info; u32 fahm_reg1; u8 denumerator_sel = 0; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); PHYDM_DBG(dm, DBG_ENV_MNTR, "IGI=0x%x\n", dm->dm_dig_table.cur_ig_value); if (dm->support_ic_type & ODM_IC_11AC_SERIES) fahm_reg1 = 0x994; else fahm_reg1 = 0x890; ccx_info->fahm_period = 65535; odm_set_bb_reg(dm, fahm_reg1, 0x6, 3); /*@FAHM HW block enable*/ denumerator_sel = FAHM_INCLD_FA | FAHM_INCLD_CRC_OK | FAHM_INCLD_CRC_ER; phydm_fahm_set_valid_cnt(dm, FAHM_INCLD_FA, denumerator_sel); phydm_fahm_set_th_by_igi(dm, dm->dm_dig_table.cur_ig_value); } void phydm_fahm_dbg(void *dm_void, char input[][16], u32 *_used, char *output, u32 *_out_len) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx_info = &dm->dm_ccx_info; char help[] = "-h"; u32 var1[10] = {0}; u32 used = *_used; u32 out_len = *_out_len; u32 i; for (i = 0; i < 2; i++) { if (input[i + 1]) PHYDM_SSCANF(input[i + 1], DCMD_DECIMAL, &var1[i]); } if ((strcmp(input[1], help) == 0)) { PDM_SNPF(out_len, used, output + used, out_len - used, "{1: trigger, 2:get result}\n"); PDM_SNPF(out_len, used, output + used, out_len - used, "{3: MNTR mode sel} {1: driver, 2. FW}\n"); return; } else if (var1[0] == 1) { /* Set & trigger CLM */ phydm_fahm_set_th_by_igi(dm, dm->dm_dig_table.cur_ig_value); phydm_fahm_trigger(dm, ccx_info->fahm_period); PDM_SNPF(out_len, used, output + used, out_len - used, "Monitor FAHM for %d * 4us\n", ccx_info->fahm_period); } else if (var1[0] == 2) { /* @Get CLM results */ phydm_fahm_get_result(dm); PDM_SNPF(out_len, used, output + used, out_len - used, "FAHM_result=%d us\n", (ccx_info->clm_result << 2)); } else { PDM_SNPF(out_len, used, output + used, out_len - used, "Error\n"); } *_used = used; *_out_len = out_len; } #endif /*@#ifdef FAHM_SUPPORT*/ #ifdef NHM_SUPPORT void phydm_nhm_racing_release(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u32 value32 = 0; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); PHYDM_DBG(dm, DBG_ENV_MNTR, "lv:(%d)->(0)\n", ccx->nhm_set_lv); ccx->nhm_ongoing = false; ccx->nhm_set_lv = NHM_RELEASE; if (!(ccx->nhm_app == NHM_BACKGROUND || ccx->nhm_app == NHM_ACS)) { phydm_pause_func(dm, F00_DIG, PHYDM_RESUME, PHYDM_PAUSE_LEVEL_1, 1, &value32); } ccx->nhm_app = NHM_BACKGROUND; } u8 phydm_nhm_racing_ctrl(void *dm_void, enum phydm_nhm_level nhm_lv) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u8 set_result = PHYDM_SET_SUCCESS; /*@acquire to control NHM API*/ PHYDM_DBG(dm, DBG_ENV_MNTR, "nhm_ongoing=%d, lv:(%d)->(%d)\n", ccx->nhm_ongoing, ccx->nhm_set_lv, nhm_lv); if (ccx->nhm_ongoing) { if (nhm_lv <= ccx->nhm_set_lv) { set_result = PHYDM_SET_FAIL; } else { phydm_ccx_hw_restart(dm); ccx->nhm_ongoing = false; } } if (set_result) ccx->nhm_set_lv = nhm_lv; PHYDM_DBG(dm, DBG_ENV_MNTR, "nhm racing success=%d\n", set_result); return set_result; } void phydm_nhm_trigger(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u32 nhm_reg1 = 0; if (dm->support_ic_type & ODM_IC_11AC_SERIES) nhm_reg1 = R_0x994; #ifdef PHYDM_IC_JGR3_SERIES_SUPPORT else if (dm->support_ic_type & ODM_IC_JGR3_SERIES) nhm_reg1 = R_0x1e60; #endif else nhm_reg1 = R_0x890; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); /* @Trigger NHM*/ pdm_set_reg(dm, nhm_reg1, BIT(1), 0); pdm_set_reg(dm, nhm_reg1, BIT(1), 1); ccx->nhm_trigger_time = dm->phydm_sys_up_time; ccx->nhm_rpt_stamp++; ccx->nhm_ongoing = true; } boolean phydm_nhm_check_rdy(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; boolean is_ready = false; u32 reg1 = 0, reg1_bit = 0; if (dm->support_ic_type & ODM_IC_11AC_SERIES) { reg1 = R_0xfb4; reg1_bit = 16; #ifdef PHYDM_IC_JGR3_SERIES_SUPPORT } else if (dm->support_ic_type & ODM_IC_JGR3_SERIES) { reg1 = R_0x2d4c; reg1_bit = 16; #endif } else { reg1 = R_0x8b4; if (dm->support_ic_type & (ODM_RTL8710B | ODM_RTL8721D | ODM_RTL8710C)) reg1_bit = 25; else reg1_bit = 17; } if (odm_get_bb_reg(dm, reg1, BIT(reg1_bit))) is_ready = true; PHYDM_DBG(dm, DBG_ENV_MNTR, "NHM rdy=%d\n", is_ready); return is_ready; } u8 phydm_nhm_cal_noise(void *dm_void, u8 start_i, u8 end_i, u8 n_sum) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u8 i = 0; u32 noise_tmp = 0; u8 noise = 0; u32 nhm_valid = 0; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); if (n_sum == 0) { PHYDM_DBG(dm, DBG_ENV_MNTR, "n_sum = 0, don't need to update noise\n"); return 0x0; } else if (end_i > NHM_RPT_NUM - 1) { PHYDM_DBG(dm, DBG_ENV_MNTR, "[WARNING]end_i is larger than 11!!\n"); return 0x0; } for (i = start_i; i <= end_i; i++) { if (i == 0) noise_tmp += ccx->nhm_result[0] * MAX_2(ccx->nhm_th[0] - 2, 0); else if (i == (NHM_RPT_NUM - 1)) noise_tmp += ccx->nhm_result[NHM_RPT_NUM - 1] * (ccx->nhm_th[NHM_TH_NUM - 1] + 2); else noise_tmp += ccx->nhm_result[i] * (ccx->nhm_th[i - 1] + ccx->nhm_th[i]) >> 1; } /* protection for the case of minus noise(RSSI)*/ noise = (u8)(NTH_TH_2_RSSI(MAX_2(PHYDM_DIV(noise_tmp, n_sum), 20))); nhm_valid = (n_sum * 100) >> 8; PHYDM_DBG(dm, DBG_ENV_MNTR, "valid: ((%d)) percent, noise(RSSI)=((%d))\n", nhm_valid, noise); return noise; } void phydm_nhm_get_utility(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u8 nhm_rpt_non_0 = 0; u8 nhm_rpt_non_11 = 0; if (ccx->nhm_rpt_sum >= ccx->nhm_result[0]) { nhm_rpt_non_0 = ccx->nhm_rpt_sum - ccx->nhm_result[0]; nhm_rpt_non_11 = ccx->nhm_rpt_sum - ccx->nhm_result[11]; ccx->nhm_ratio = (nhm_rpt_non_0 * 100) >> 8; ccx->nhm_level_valid = (nhm_rpt_non_11 * 100) >> 8; ccx->nhm_level = phydm_nhm_cal_noise(dm, 0, NHM_RPT_NUM - 2, nhm_rpt_non_11); } else { PHYDM_DBG(dm, DBG_ENV_MNTR, "[warning] nhm_rpt_sum invalid\n"); ccx->nhm_ratio = 0; } PHYDM_DBG(dm, DBG_ENV_MNTR, "nhm_ratio=%d\n", ccx->nhm_ratio); } boolean phydm_nhm_get_result(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u32 value32 = 0; u8 i = 0; u32 nhm_reg1 = 0; u16 nhm_rpt_sum_tmp = 0; if (dm->support_ic_type & ODM_IC_11AC_SERIES) nhm_reg1 = R_0x994; #ifdef PHYDM_IC_JGR3_SERIES_SUPPORT else if (dm->support_ic_type & ODM_IC_JGR3_SERIES) nhm_reg1 = R_0x1e60; #endif else nhm_reg1 = R_0x890; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); if (!(dm->support_ic_type & (ODM_RTL8822C | ODM_RTL8812F | ODM_RTL8197G))) pdm_set_reg(dm, nhm_reg1, BIT(1), 0); if (!(phydm_nhm_check_rdy(dm))) { PHYDM_DBG(dm, DBG_ENV_MNTR, "Get NHM report Fail\n"); phydm_nhm_racing_release(dm); return false; } if (dm->support_ic_type & ODM_IC_11AC_SERIES) { value32 = odm_read_4byte(dm, R_0xfa8); odm_move_memory(dm, &ccx->nhm_result[0], &value32, 4); value32 = odm_read_4byte(dm, R_0xfac); odm_move_memory(dm, &ccx->nhm_result[4], &value32, 4); value32 = odm_read_4byte(dm, R_0xfb0); odm_move_memory(dm, &ccx->nhm_result[8], &value32, 4); /*@Get NHM duration*/ value32 = odm_read_4byte(dm, R_0xfb4); ccx->nhm_duration = (u16)(value32 & MASKLWORD); #ifdef PHYDM_IC_JGR3_SERIES_SUPPORT } else if (dm->support_ic_type & ODM_IC_JGR3_SERIES) { value32 = odm_read_4byte(dm, R_0x2d40); odm_move_memory(dm, &ccx->nhm_result[0], &value32, 4); value32 = odm_read_4byte(dm, R_0x2d44); odm_move_memory(dm, &ccx->nhm_result[4], &value32, 4); value32 = odm_read_4byte(dm, R_0x2d48); odm_move_memory(dm, &ccx->nhm_result[8], &value32, 4); /*@Get NHM duration*/ value32 = odm_read_4byte(dm, R_0x2d4c); ccx->nhm_duration = (u16)(value32 & MASKLWORD); #endif } else { value32 = odm_read_4byte(dm, R_0x8d8); odm_move_memory(dm, &ccx->nhm_result[0], &value32, 4); value32 = odm_read_4byte(dm, R_0x8dc); odm_move_memory(dm, &ccx->nhm_result[4], &value32, 4); value32 = odm_get_bb_reg(dm, R_0x8d0, 0xffff0000); odm_move_memory(dm, &ccx->nhm_result[8], &value32, 2); value32 = odm_read_4byte(dm, R_0x8d4); ccx->nhm_result[10] = (u8)((value32 & MASKBYTE2) >> 16); ccx->nhm_result[11] = (u8)((value32 & MASKBYTE3) >> 24); /*@Get NHM duration*/ ccx->nhm_duration = (u16)(value32 & MASKLWORD); } /* sum all nhm_result */ if (ccx->nhm_period >= 65530) { value32 = (ccx->nhm_duration * 100) >> 16; PHYDM_DBG(dm, DBG_ENV_MNTR, "NHM valid time = %d, valid: %d percent\n", ccx->nhm_duration, value32); } for (i = 0; i < NHM_RPT_NUM; i++) nhm_rpt_sum_tmp += (u16)ccx->nhm_result[i]; ccx->nhm_rpt_sum = (u8)nhm_rpt_sum_tmp; PHYDM_DBG(dm, DBG_ENV_MNTR, "NHM_Rpt[%d](H->L)[%d %d %d %d %d %d %d %d %d %d %d %d]\n", ccx->nhm_rpt_stamp, ccx->nhm_result[11], ccx->nhm_result[10], ccx->nhm_result[9], ccx->nhm_result[8], ccx->nhm_result[7], ccx->nhm_result[6], ccx->nhm_result[5], ccx->nhm_result[4], ccx->nhm_result[3], ccx->nhm_result[2], ccx->nhm_result[1], ccx->nhm_result[0]); phydm_nhm_racing_release(dm); if (nhm_rpt_sum_tmp > 255) { PHYDM_DBG(dm, DBG_ENV_MNTR, "[Warning] Invalid NHM RPT, total=%d\n", nhm_rpt_sum_tmp); return false; } return true; } void phydm_nhm_set_th_reg(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u32 reg1 = 0, reg2 = 0, reg3 = 0, reg4 = 0, reg4_bit = 0; u32 val = 0; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); if (dm->support_ic_type & ODM_IC_11AC_SERIES) { reg1 = R_0x994; reg2 = R_0x998; reg3 = R_0x99c; reg4 = R_0x9a0; reg4_bit = MASKBYTE0; #ifdef PHYDM_IC_JGR3_SERIES_SUPPORT } else if (dm->support_ic_type & ODM_IC_JGR3_SERIES) { reg1 = R_0x1e60; reg2 = R_0x1e44; reg3 = R_0x1e48; reg4 = R_0x1e5c; reg4_bit = MASKBYTE2; #endif } else { reg1 = R_0x890; reg2 = R_0x898; reg3 = R_0x89c; reg4 = R_0xe28; reg4_bit = MASKBYTE0; } /*Set NHM threshold*/ /*Unit: PWdB U(8,1)*/ val = BYTE_2_DWORD(ccx->nhm_th[3], ccx->nhm_th[2], ccx->nhm_th[1], ccx->nhm_th[0]); pdm_set_reg(dm, reg2, MASKDWORD, val); val = BYTE_2_DWORD(ccx->nhm_th[7], ccx->nhm_th[6], ccx->nhm_th[5], ccx->nhm_th[4]); pdm_set_reg(dm, reg3, MASKDWORD, val); pdm_set_reg(dm, reg4, reg4_bit, ccx->nhm_th[8]); val = BYTE_2_DWORD(0, 0, ccx->nhm_th[10], ccx->nhm_th[9]); pdm_set_reg(dm, reg1, 0xffff0000, val); PHYDM_DBG(dm, DBG_ENV_MNTR, "Update NHM_th[H->L]=[%d %d %d %d %d %d %d %d %d %d %d]\n", ccx->nhm_th[10], ccx->nhm_th[9], ccx->nhm_th[8], ccx->nhm_th[7], ccx->nhm_th[6], ccx->nhm_th[5], ccx->nhm_th[4], ccx->nhm_th[3], ccx->nhm_th[2], ccx->nhm_th[1], ccx->nhm_th[0]); } boolean phydm_nhm_th_update_chk(void *dm_void, enum nhm_application nhm_app, u8 *nhm_th, u32 *igi_new, boolean en_1db_mode, u8 nhm_th0_manual) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; boolean is_update = false; u8 igi_curr = phydm_get_igi(dm, BB_PATH_A); u8 nhm_igi_th_11k_low[NHM_TH_NUM] = {0x12, 0x15, 0x18, 0x1b, 0x1e, 0x23, 0x28, 0x2c, 0x78, 0x78, 0x78}; u8 nhm_igi_th_11k_high[NHM_TH_NUM] = {0x1e, 0x23, 0x28, 0x2d, 0x32, 0x37, 0x78, 0x78, 0x78, 0x78, 0x78}; u8 nhm_igi_th_xbox[NHM_TH_NUM] = {0x1a, 0x2c, 0x2e, 0x30, 0x32, 0x34, 0x36, 0x38, 0x3a, 0x3c, 0x3d}; u8 i = 0; u8 th_tmp = igi_curr - CCA_CAP; u8 th_step = 2; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); PHYDM_DBG(dm, DBG_ENV_MNTR, "App=%d, nhm_igi=0x%x, igi_curr=0x%x\n", nhm_app, ccx->nhm_igi, igi_curr); if (igi_curr < 0x10) /* Protect for invalid IGI*/ return false; switch (nhm_app) { case NHM_BACKGROUND: /* @Get IGI form driver parameter(cur_ig_value)*/ if (ccx->nhm_igi != igi_curr || ccx->nhm_app != nhm_app) { is_update = true; *igi_new = (u32)igi_curr; #ifdef NHM_DYM_PW_TH_SUPPORT if (ccx->nhm_dym_pw_th_en) { th_tmp = MAX_2(igi_curr - DYM_PWTH_CCA_CAP, 0); th_step = 3; } #endif nhm_th[0] = (u8)IGI_2_NHM_TH(th_tmp); for (i = 1; i <= 10; i++) nhm_th[i] = nhm_th[0] + IGI_2_NHM_TH(th_step * i); } break; case NHM_ACS: if (ccx->nhm_igi != igi_curr || ccx->nhm_app != nhm_app) { is_update = true; *igi_new = (u32)igi_curr; nhm_th[0] = (u8)IGI_2_NHM_TH(igi_curr - CCA_CAP); for (i = 1; i <= 10; i++) nhm_th[i] = nhm_th[0] + IGI_2_NHM_TH(2 * i); } break; case IEEE_11K_HIGH: is_update = true; *igi_new = 0x2c; for (i = 0; i < NHM_TH_NUM; i++) nhm_th[i] = IGI_2_NHM_TH(nhm_igi_th_11k_high[i]); break; case IEEE_11K_LOW: is_update = true; *igi_new = 0x20; for (i = 0; i < NHM_TH_NUM; i++) nhm_th[i] = IGI_2_NHM_TH(nhm_igi_th_11k_low[i]); break; case INTEL_XBOX: is_update = true; *igi_new = 0x36; for (i = 0; i < NHM_TH_NUM; i++) nhm_th[i] = IGI_2_NHM_TH(nhm_igi_th_xbox[i]); break; case NHM_DBG: /*@Get IGI form register*/ igi_curr = phydm_get_igi(dm, BB_PATH_A); if (ccx->nhm_igi != igi_curr || ccx->nhm_app != nhm_app) { is_update = true; *igi_new = (u32)igi_curr; if (en_1db_mode) { nhm_th[0] = (u8)IGI_2_NHM_TH(nhm_th0_manual + 10); th_step = 1; } else { nhm_th[0] = (u8)IGI_2_NHM_TH(igi_curr - CCA_CAP); } for (i = 1; i <= 10; i++) nhm_th[i] = nhm_th[0] + IGI_2_NHM_TH(th_step * i); } break; } if (is_update) { PHYDM_DBG(dm, DBG_ENV_MNTR, "[Update NHM_TH] igi_RSSI=%d\n", IGI_2_RSSI(*igi_new)); for (i = 0; i < NHM_TH_NUM; i++) { PHYDM_DBG(dm, DBG_ENV_MNTR, "NHM_th[%d](RSSI) = %d\n", i, NTH_TH_2_RSSI(nhm_th[i])); } } else { PHYDM_DBG(dm, DBG_ENV_MNTR, "No need to update NHM_TH\n"); } return is_update; } void phydm_nhm_set(void *dm_void, enum nhm_option_txon_all include_tx, enum nhm_option_cca_all include_cca, enum nhm_divider_opt_all divi_opt, enum nhm_application nhm_app, u16 period, boolean en_1db_mode, u8 nhm_th0_manual) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u8 nhm_th[NHM_TH_NUM] = {0}; u32 igi = 0x20; u32 reg1 = 0, reg2 = 0; u32 val_tmp = 0; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); PHYDM_DBG(dm, DBG_ENV_MNTR, "incld{tx, cca}={%d, %d}, divi_opt=%d, period=%d\n", include_tx, include_cca, divi_opt, period); if (dm->support_ic_type & ODM_IC_11AC_SERIES) { reg1 = R_0x994; reg2 = R_0x990; #ifdef PHYDM_IC_JGR3_SERIES_SUPPORT } else if (dm->support_ic_type & ODM_IC_JGR3_SERIES) { reg1 = R_0x1e60; reg2 = R_0x1e40; #endif } else { reg1 = R_0x890; reg2 = R_0x894; } /*Set disable_ignore_cca, disable_ignore_txon, ccx_en*/ if (include_tx != ccx->nhm_include_txon || include_cca != ccx->nhm_include_cca || divi_opt != ccx->nhm_divider_opt) { /* some old ic is not supported on NHM divider option */ if (dm->support_ic_type & (ODM_RTL8188E | ODM_RTL8723B | ODM_RTL8195A | ODM_RTL8192E)) { val_tmp = (u32)((include_tx << 2) | (include_cca << 1) | 1); pdm_set_reg(dm, reg1, 0x700, val_tmp); } else { val_tmp = (u32)BIT_2_BYTE(divi_opt, include_tx, include_cca, 1); pdm_set_reg(dm, reg1, 0xf00, val_tmp); } ccx->nhm_include_txon = include_tx; ccx->nhm_include_cca = include_cca; ccx->nhm_divider_opt = divi_opt; } /*Set NHM period*/ if (period != ccx->nhm_period) { pdm_set_reg(dm, reg2, MASKHWORD, period); PHYDM_DBG(dm, DBG_ENV_MNTR, "Update NHM period ((%d)) -> ((%d))\n", ccx->nhm_period, period); ccx->nhm_period = period; } /*Set NHM threshold*/ if (phydm_nhm_th_update_chk(dm, nhm_app, &nhm_th[0], &igi, en_1db_mode, nhm_th0_manual)) { /*Pause IGI*/ if (nhm_app == NHM_BACKGROUND || nhm_app == NHM_ACS) { PHYDM_DBG(dm, DBG_ENV_MNTR, "DIG Free Run\n"); } else if (phydm_pause_func(dm, F00_DIG, PHYDM_PAUSE, PHYDM_PAUSE_LEVEL_1, 1, &igi) == PAUSE_FAIL) { PHYDM_DBG(dm, DBG_ENV_MNTR, "pause DIG Fail\n"); return; } else { PHYDM_DBG(dm, DBG_ENV_MNTR, "pause DIG=0x%x\n", igi); } ccx->nhm_app = nhm_app; ccx->nhm_igi = (u8)igi; odm_move_memory(dm, &ccx->nhm_th[0], &nhm_th, NHM_TH_NUM); /*Set NHM th*/ phydm_nhm_set_th_reg(dm); } } u8 phydm_nhm_mntr_set(void *dm_void, struct nhm_para_info *nhm_para) { struct dm_struct *dm = (struct dm_struct *)dm_void; u16 nhm_time = 0; /*unit: 4us*/ PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); if (nhm_para->mntr_time == 0) return PHYDM_SET_FAIL; if (nhm_para->nhm_lv >= NHM_MAX_NUM) { PHYDM_DBG(dm, DBG_ENV_MNTR, "Wrong LV=%d\n", nhm_para->nhm_lv); return PHYDM_SET_FAIL; } if (phydm_nhm_racing_ctrl(dm, nhm_para->nhm_lv) == PHYDM_SET_FAIL) return PHYDM_SET_FAIL; if (nhm_para->mntr_time >= 262) nhm_time = NHM_PERIOD_MAX; else nhm_time = nhm_para->mntr_time * MS_TO_4US_RATIO; phydm_nhm_set(dm, nhm_para->incld_txon, nhm_para->incld_cca, nhm_para->div_opt, nhm_para->nhm_app, nhm_time, nhm_para->en_1db_mode, nhm_para->nhm_th0_manual); return PHYDM_SET_SUCCESS; } #ifdef NHM_DYM_PW_TH_SUPPORT void phydm_nhm_restore_pw_th(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; odm_set_bb_reg(dm, R_0x82c, 0x3f, ccx->pw_th_rf20_ori); } void phydm_nhm_set_pw_th(void *dm_void, u8 noise, boolean chk_succ) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; boolean not_update = false; u8 pw_th_rf20_new = 0; u8 pw_th_u_bnd = 0; s8 noise_diff = 0; u8 point_mean = 15; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); if (*dm->band_width != CHANNEL_WIDTH_20 || *dm->band_type == ODM_BAND_5G) { PHYDM_DBG(dm, DBG_ENV_MNTR, "bandwidth=((%d)), band=((%d))\n", *dm->band_width, *dm->band_type); phydm_nhm_restore_pw_th(dm); return; } if (chk_succ) { noise_diff = noise - (ccx->nhm_igi - 10); pw_th_u_bnd = (u8)(noise_diff + 32 + point_mean); pw_th_u_bnd = MIN_2(pw_th_u_bnd, ccx->nhm_pw_th_max); PHYDM_DBG(dm, DBG_ENV_MNTR, "noise_diff=((%d)), max=((%d)), pw_th_u_bnd=((%d))\n", noise_diff, ccx->nhm_pw_th_max, pw_th_u_bnd); if (pw_th_u_bnd > ccx->pw_th_rf20_cur) { pw_th_rf20_new = ccx->pw_th_rf20_cur + 1; } else if (pw_th_u_bnd < ccx->pw_th_rf20_cur) { if (ccx->pw_th_rf20_cur > ccx->pw_th_rf20_ori) pw_th_rf20_new = ccx->pw_th_rf20_cur - 1; else /*ccx->pw_th_rf20_cur == ccx->pw_th_ori*/ not_update = true; } else {/*pw_th_u_bnd == ccx->pw_th_rf20_cur*/ not_update = true; } } else { if (ccx->pw_th_rf20_cur > ccx->pw_th_rf20_ori) pw_th_rf20_new = ccx->pw_th_rf20_cur - 1; else /*ccx->pw_th_rf20_cur == ccx->pw_th_ori*/ not_update = true; } PHYDM_DBG(dm, DBG_ENV_MNTR, "pw_th_cur=((%d)), pw_th_new=((%d))\n", ccx->pw_th_rf20_cur, pw_th_rf20_new); if (!not_update) { odm_set_bb_reg(dm, R_0x82c, 0x3f, pw_th_rf20_new); ccx->pw_th_rf20_cur = pw_th_rf20_new; } } void phydm_nhm_dym_pw_th(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u8 i = 0; u8 n_sum = 0; u8 noise = 0; boolean chk_succ = false; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); for (i = 0; i < NHM_RPT_NUM - 3; i++) { n_sum = ccx->nhm_result[i] + ccx->nhm_result[i + 1] + ccx->nhm_result[i + 2] + ccx->nhm_result[i + 3]; if (n_sum >= ccx->nhm_sl_pw_th) { PHYDM_DBG(dm, DBG_ENV_MNTR, "Do sl[%d:%d]\n", i, i + 3); chk_succ = true; noise = phydm_nhm_cal_noise(dm, i, i + 3, n_sum); break; } } if (!chk_succ) PHYDM_DBG(dm, DBG_ENV_MNTR, "SL method failed!\n"); phydm_nhm_set_pw_th(dm, noise, chk_succ); } boolean phydm_nhm_dym_pw_th_en(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; struct phydm_iot_center *iot_table = &dm->iot_table; if (!ccx->dym_pwth_manual_ctrl) ccx->nhm_dym_pw_th_en = false; if (!(dm->support_ic_type & ODM_RTL8822C)) ccx->nhm_dym_pw_th_en = false; if (dm->iot_table.phydm_patch_id == 0x100f0401 || iot_table->patch_id_100f0401) { ccx->nhm_dym_pw_th_en = true; } else if (ccx->nhm_dym_pw_th_en) { phydm_nhm_restore_pw_th(dm); ccx->nhm_dym_pw_th_en = false; } return ccx->nhm_dym_pw_th_en; } #endif /*@Environment Monitor*/ boolean phydm_nhm_mntr_chk(void *dm_void, u16 monitor_time /*unit ms*/) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; struct nhm_para_info nhm_para = {0}; boolean nhm_chk_result = false; boolean nhm_polling_result = false; u32 sys_return_time = 0; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); if (ccx->nhm_manual_ctrl) { PHYDM_DBG(dm, DBG_ENV_MNTR, "NHM in manual ctrl\n"); return nhm_chk_result; } sys_return_time = ccx->nhm_trigger_time + MAX_ENV_MNTR_TIME; if (ccx->nhm_app != NHM_BACKGROUND && (sys_return_time > dm->phydm_sys_up_time)) { PHYDM_DBG(dm, DBG_ENV_MNTR, "nhm_app=%d, trigger_time %d, sys_time=%d\n", ccx->nhm_app, ccx->nhm_trigger_time, dm->phydm_sys_up_time); return nhm_chk_result; } /*[NHM get result & calculate Utility----------------------------*/ nhm_polling_result = phydm_nhm_get_result(dm); if (nhm_polling_result) { PHYDM_DBG(dm, DBG_ENV_MNTR, "Get NHM_rpt success\n"); phydm_nhm_get_utility(dm); } #ifdef NHM_DYM_PW_TH_SUPPORT if (phydm_nhm_dym_pw_th_en(dm)) { if (nhm_polling_result) phydm_nhm_dym_pw_th(dm); else phydm_nhm_set_pw_th(dm, 0x0, false); } #endif /*@[NHM trigger setting]------------------------------------------*/ nhm_para.incld_txon = NHM_EXCLUDE_TXON; nhm_para.incld_cca = NHM_EXCLUDE_CCA; nhm_para.div_opt = NHM_CNT_ALL; nhm_para.nhm_app = NHM_BACKGROUND; nhm_para.nhm_lv = NHM_LV_1; nhm_para.mntr_time = monitor_time; #ifdef NHM_DYM_PW_TH_SUPPORT if (ccx->nhm_dym_pw_th_en) { nhm_para.div_opt = NHM_VALID; nhm_para.mntr_time = monitor_time >> ccx->nhm_period_decre; } #endif nhm_chk_result = phydm_nhm_mntr_set(dm, &nhm_para); return nhm_chk_result; } void phydm_nhm_init(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); PHYDM_DBG(dm, DBG_ENV_MNTR, "cur_igi=0x%x\n", dm->dm_dig_table.cur_ig_value); ccx->nhm_app = NHM_BACKGROUND; ccx->nhm_igi = 0xff; /*Set NHM threshold*/ ccx->nhm_ongoing = false; ccx->nhm_set_lv = NHM_RELEASE; if (phydm_nhm_th_update_chk(dm, ccx->nhm_app, &ccx->nhm_th[0], (u32 *)&ccx->nhm_igi, false, 0)) phydm_nhm_set_th_reg(dm); ccx->nhm_period = 0; ccx->nhm_include_cca = NHM_CCA_INIT; ccx->nhm_include_txon = NHM_TXON_INIT; ccx->nhm_divider_opt = NHM_CNT_INIT; ccx->nhm_manual_ctrl = 0; ccx->nhm_rpt_stamp = 0; #ifdef NHM_DYM_PW_TH_SUPPORT if (dm->support_ic_type & ODM_RTL8822C) { ccx->nhm_dym_pw_th_en = false; ccx->pw_th_rf20_ori = (u8)odm_get_bb_reg(dm, R_0x82c, 0x3f); ccx->pw_th_rf20_cur = ccx->pw_th_rf20_ori; ccx->nhm_pw_th_max = 63; ccx->nhm_sl_pw_th = 100; /*39%*/ ccx->nhm_period_decre = 1; ccx->dym_pwth_manual_ctrl = false; } #endif } void phydm_nhm_dbg(void *dm_void, char input[][16], u32 *_used, char *output, u32 *_out_len) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; struct nhm_para_info nhm_para = {0}; char help[] = "-h"; u32 var1[10] = {0}; u32 used = *_used; u32 out_len = *_out_len; u8 result_tmp = 0; u8 i = 0; PHYDM_SSCANF(input[1], DCMD_DECIMAL, &var1[0]); if ((strcmp(input[1], help) == 0)) { PDM_SNPF(out_len, used, output + used, out_len - used, "NHM Basic-Trigger 262ms: {1}\n"); PDM_SNPF(out_len, used, output + used, out_len - used, "NHM Adv-Trigger: {2} {Include TXON} {Include CCA}\n{0:Cnt_all, 1:Cnt valid} {App} {LV:1~4} {0~262ms}, 1dB mode :{en} {t[0](RSSI)}\n"); #ifdef NHM_DYM_PW_TH_SUPPORT if (dm->support_ic_type & ODM_RTL8822C) { PDM_SNPF(out_len, used, output + used, out_len - used, "NHM dym_pw_th: {3} {0:off}\n"); PDM_SNPF(out_len, used, output + used, out_len - used, "NHM dym_pw_th: {3} {1:on} {max} {period_decre} {sl_th}\n"); PDM_SNPF(out_len, used, output + used, out_len - used, "NHM dym_pw_th: {3} {2:fast on}\n"); } #endif PDM_SNPF(out_len, used, output + used, out_len - used, "NHM Get Result: {100}\n"); } else if (var1[0] == 100) { /*@Get NHM results*/ PDM_SNPF(out_len, used, output + used, out_len - used, "IGI=0x%x, rpt_stamp=%d\n", ccx->nhm_igi, ccx->nhm_rpt_stamp); if (phydm_nhm_get_result(dm)) { for (i = 0; i <= 11; i++) { result_tmp = ccx->nhm_result[i]; PDM_SNPF(out_len, used, output + used, out_len - used, "nhm_rpt[%d] = %d (%d percent)\n", i, result_tmp, (((result_tmp * 100) + 128) >> 8)); } phydm_nhm_get_utility(dm); PDM_SNPF(out_len, used, output + used, out_len - used, "[NHM] valid: %d percent, noise(RSSI) = %d\n", ccx->nhm_level_valid, ccx->nhm_level); } else { PDM_SNPF(out_len, used, output + used, out_len - used, "Get NHM_rpt Fail\n"); } ccx->nhm_manual_ctrl = 0; #ifdef NHM_DYM_PW_TH_SUPPORT } else if (var1[0] == 3) { /*NMH dym_pw_th*/ if (dm->support_ic_type & ODM_RTL8822C) { for (i = 1; i < 7; i++) { PHYDM_SSCANF(input[i + 1], DCMD_DECIMAL, &var1[i]); } if (var1[1] == 1) { ccx->nhm_dym_pw_th_en = true; ccx->nhm_pw_th_max = (u8)var1[2]; ccx->nhm_period_decre = (u8)var1[3]; ccx->nhm_sl_pw_th = (u8)var1[4]; ccx->dym_pwth_manual_ctrl = true; } else if (var1[1] == 2) { ccx->nhm_dym_pw_th_en = true; ccx->nhm_pw_th_max = 63; ccx->nhm_period_decre = 1; ccx->nhm_sl_pw_th = 100; ccx->dym_pwth_manual_ctrl = true; } else { ccx->nhm_dym_pw_th_en = false; phydm_nhm_restore_pw_th(dm); ccx->dym_pwth_manual_ctrl = false; } } #endif } else { /*NMH trigger*/ ccx->nhm_manual_ctrl = 1; for (i = 1; i < 9; i++) { PHYDM_SSCANF(input[i + 1], DCMD_DECIMAL, &var1[i]); } if (var1[0] == 1) { nhm_para.incld_txon = NHM_EXCLUDE_TXON; nhm_para.incld_cca = NHM_EXCLUDE_CCA; nhm_para.div_opt = NHM_CNT_ALL; nhm_para.nhm_app = NHM_DBG; nhm_para.nhm_lv = NHM_LV_4; nhm_para.mntr_time = 262; nhm_para.en_1db_mode = false; nhm_para.nhm_th0_manual = 0; } else { nhm_para.incld_txon = (enum nhm_option_txon_all)var1[1]; nhm_para.incld_cca = (enum nhm_option_cca_all)var1[2]; nhm_para.div_opt = (enum nhm_divider_opt_all)var1[3]; nhm_para.nhm_app = (enum nhm_application)var1[4]; nhm_para.nhm_lv = (enum phydm_nhm_level)var1[5]; nhm_para.mntr_time = (u16)var1[6]; nhm_para.en_1db_mode = (boolean)var1[7]; nhm_para.nhm_th0_manual = (u8)var1[8]; /* some old ic is not supported on NHM divider option */ if (dm->support_ic_type & (ODM_RTL8188E | ODM_RTL8723B | ODM_RTL8195A | ODM_RTL8192E)) { nhm_para.div_opt = NHM_CNT_ALL; } } PDM_SNPF(out_len, used, output + used, out_len - used, "txon=%d, cca=%d, dev=%d, app=%d, lv=%d, time=%d ms\n", nhm_para.incld_txon, nhm_para.incld_cca, nhm_para.div_opt, nhm_para.nhm_app, nhm_para.nhm_lv, nhm_para.mntr_time); PDM_SNPF(out_len, used, output + used, out_len - used, "en_1db_mode =%d, th0(for 1db mode)=%d\n", nhm_para.en_1db_mode, nhm_para.nhm_th0_manual); if (phydm_nhm_mntr_set(dm, &nhm_para) == PHYDM_SET_SUCCESS) phydm_nhm_trigger(dm); PDM_SNPF(out_len, used, output + used, out_len - used, "IGI=0x%x, rpt_stamp=%d\n", ccx->nhm_igi, ccx->nhm_rpt_stamp); for (i = 0; i <= 10; i++) { PDM_SNPF(out_len, used, output + used, out_len - used, "NHM_th[%d] RSSI = %d\n", i, NTH_TH_2_RSSI(ccx->nhm_th[i])); } } *_used = used; *_out_len = out_len; } #endif /*@#ifdef NHM_SUPPORT*/ #ifdef CLM_SUPPORT void phydm_clm_racing_release(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); PHYDM_DBG(dm, DBG_ENV_MNTR, "lv:(%d)->(0)\n", ccx->clm_set_lv); ccx->clm_ongoing = false; ccx->clm_set_lv = CLM_RELEASE; ccx->clm_app = CLM_BACKGROUND; } u8 phydm_clm_racing_ctrl(void *dm_void, enum phydm_clm_level clm_lv) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u8 set_result = PHYDM_SET_SUCCESS; /*@acquire to control CLM API*/ PHYDM_DBG(dm, DBG_ENV_MNTR, "clm_ongoing=%d, lv:(%d)->(%d)\n", ccx->clm_ongoing, ccx->clm_set_lv, clm_lv); if (ccx->clm_ongoing) { if (clm_lv <= ccx->clm_set_lv) { set_result = PHYDM_SET_FAIL; } else { phydm_ccx_hw_restart(dm); ccx->clm_ongoing = false; } } if (set_result) ccx->clm_set_lv = clm_lv; PHYDM_DBG(dm, DBG_ENV_MNTR, "clm racing success=%d\n", set_result); return set_result; } void phydm_clm_c2h_report_handler(void *dm_void, u8 *cmd_buf, u8 cmd_len) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx_info = &dm->dm_ccx_info; u8 clm_report = cmd_buf[0]; /*@u8 clm_report_idx = cmd_buf[1];*/ if (cmd_len >= 12) return; ccx_info->clm_fw_result_acc += clm_report; ccx_info->clm_fw_result_cnt++; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%d] clm_report= %d\n", ccx_info->clm_fw_result_cnt, clm_report); } void phydm_clm_h2c(void *dm_void, u16 obs_time, u8 fw_clm_en) { struct dm_struct *dm = (struct dm_struct *)dm_void; u8 h2c_val[H2C_MAX_LENGTH] = {0}; u8 i = 0; u8 obs_time_idx = 0; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s] ======>\n", __func__); PHYDM_DBG(dm, DBG_ENV_MNTR, "obs_time_index=%d *4 us\n", obs_time); for (i = 1; i <= 16; i++) { if (obs_time & BIT(16 - i)) { obs_time_idx = 16 - i; break; } } #if 0 obs_time = (2 ^ 16 - 1)~(2 ^ 15) => obs_time_idx = 15 (65535 ~32768) obs_time = (2 ^ 15 - 1)~(2 ^ 14) => obs_time_idx = 14 ... ... ... obs_time = (2 ^ 1 - 1)~(2 ^ 0) => obs_time_idx = 0 #endif h2c_val[0] = obs_time_idx | (((fw_clm_en) ? 1 : 0) << 7); h2c_val[1] = CLM_MAX_REPORT_TIME; PHYDM_DBG(dm, DBG_ENV_MNTR, "PHYDM h2c[0x4d]=0x%x %x %x %x %x %x %x\n", h2c_val[6], h2c_val[5], h2c_val[4], h2c_val[3], h2c_val[2], h2c_val[1], h2c_val[0]); odm_fill_h2c_cmd(dm, PHYDM_H2C_FW_CLM_MNTR, H2C_MAX_LENGTH, h2c_val); } void phydm_clm_setting(void *dm_void, u16 clm_period /*@4us sample 1 time*/) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; if (ccx->clm_period != clm_period) { if (dm->support_ic_type & ODM_IC_11AC_SERIES) odm_set_bb_reg(dm, R_0x990, MASKLWORD, clm_period); #ifdef PHYDM_IC_JGR3_SERIES_SUPPORT else if (dm->support_ic_type & ODM_IC_JGR3_SERIES) odm_set_bb_reg(dm, R_0x1e40, MASKLWORD, clm_period); #endif else if (dm->support_ic_type & ODM_IC_11N_SERIES) odm_set_bb_reg(dm, R_0x894, MASKLWORD, clm_period); ccx->clm_period = clm_period; PHYDM_DBG(dm, DBG_ENV_MNTR, "Update CLM period ((%d)) -> ((%d))\n", ccx->clm_period, clm_period); } PHYDM_DBG(dm, DBG_ENV_MNTR, "Set CLM period=%d * 4us\n", ccx->clm_period); } void phydm_clm_trigger(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u32 reg1 = 0; if (dm->support_ic_type & ODM_IC_11AC_SERIES) reg1 = R_0x994; #ifdef PHYDM_IC_JGR3_SERIES_SUPPORT else if (dm->support_ic_type & ODM_IC_JGR3_SERIES) reg1 = R_0x1e60; #endif else reg1 = R_0x890; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); odm_set_bb_reg(dm, reg1, BIT(0), 0x0); odm_set_bb_reg(dm, reg1, BIT(0), 0x1); ccx->clm_trigger_time = dm->phydm_sys_up_time; ccx->clm_rpt_stamp++; ccx->clm_ongoing = true; } boolean phydm_clm_check_rdy(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; boolean is_ready = false; u32 reg1 = 0, reg1_bit = 0; if (dm->support_ic_type & ODM_IC_11AC_SERIES) { reg1 = R_0xfa4; reg1_bit = 16; #ifdef PHYDM_IC_JGR3_SERIES_SUPPORT } else if (dm->support_ic_type & ODM_IC_JGR3_SERIES) { reg1 = R_0x2d88; reg1_bit = 16; #endif } else if (dm->support_ic_type & ODM_IC_11N_SERIES) { if (dm->support_ic_type & (ODM_RTL8710B | ODM_RTL8721D | ODM_RTL8710C)) { reg1 = R_0x8b4; reg1_bit = 24; } else { reg1 = R_0x8b4; reg1_bit = 16; } } if (odm_get_bb_reg(dm, reg1, BIT(reg1_bit))) is_ready = true; PHYDM_DBG(dm, DBG_ENV_MNTR, "CLM rdy=%d\n", is_ready); return is_ready; } void phydm_clm_get_utility(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u32 clm_result_tmp; if (ccx->clm_period == 0) { PHYDM_DBG(dm, DBG_ENV_MNTR, "[warning] clm_period = 0\n"); ccx->clm_ratio = 0; } else if (ccx->clm_period >= 65530) { clm_result_tmp = (u32)(ccx->clm_result * 100); ccx->clm_ratio = (u8)((clm_result_tmp + (1 << 15)) >> 16); } else { clm_result_tmp = (u32)(ccx->clm_result * 100); ccx->clm_ratio = (u8)(clm_result_tmp / (u32)ccx->clm_period); } } boolean phydm_clm_get_result(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx_info = &dm->dm_ccx_info; u32 reg1 = 0; u32 val = 0; if (dm->support_ic_type & ODM_IC_11AC_SERIES) reg1 = R_0x994; #ifdef PHYDM_IC_JGR3_SERIES_SUPPORT else if (dm->support_ic_type & ODM_IC_JGR3_SERIES) reg1 = R_0x1e60; #endif else reg1 = R_0x890; if (!(dm->support_ic_type & (ODM_RTL8822C | ODM_RTL8812F | ODM_RTL8197G))) odm_set_bb_reg(dm, reg1, BIT(0), 0x0); if (!(phydm_clm_check_rdy(dm))) { PHYDM_DBG(dm, DBG_ENV_MNTR, "Get CLM report Fail\n"); phydm_clm_racing_release(dm); return false; } if (dm->support_ic_type & ODM_IC_11AC_SERIES) { val = odm_get_bb_reg(dm, R_0xfa4, MASKLWORD); ccx_info->clm_result = (u16)val; #ifdef PHYDM_IC_JGR3_SERIES_SUPPORT } else if (dm->support_ic_type & ODM_IC_JGR3_SERIES) { val = odm_get_bb_reg(dm, R_0x2d88, MASKLWORD); ccx_info->clm_result = (u16)val; #endif } else if (dm->support_ic_type & ODM_IC_11N_SERIES) { val = odm_get_bb_reg(dm, R_0x8d0, MASKLWORD); ccx_info->clm_result = (u16)val; } PHYDM_DBG(dm, DBG_ENV_MNTR, "CLM result = %d *4 us\n", ccx_info->clm_result); phydm_clm_racing_release(dm); return true; } void phydm_clm_mntr_fw(void *dm_void, u16 monitor_time /*unit ms*/) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u32 val = 0; /*@[Get CLM report]*/ if (ccx->clm_fw_result_cnt != 0) { val = ccx->clm_fw_result_acc / ccx->clm_fw_result_cnt; ccx->clm_ratio = (u8)val; } else { ccx->clm_ratio = 0; } PHYDM_DBG(dm, DBG_ENV_MNTR, "clm_fw_result_acc=%d, clm_fw_result_cnt=%d\n", ccx->clm_fw_result_acc, ccx->clm_fw_result_cnt); ccx->clm_fw_result_acc = 0; ccx->clm_fw_result_cnt = 0; /*@[CLM trigger]*/ if (monitor_time >= 262) ccx->clm_period = 65535; else ccx->clm_period = monitor_time * MS_TO_4US_RATIO; phydm_clm_h2c(dm, ccx->clm_period, true); } u8 phydm_clm_mntr_set(void *dm_void, struct clm_para_info *clm_para) { /*@Driver Monitor CLM*/ struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u16 clm_period = 0; if (clm_para->mntr_time == 0) return PHYDM_SET_FAIL; if (clm_para->clm_lv >= CLM_MAX_NUM) { PHYDM_DBG(dm, DBG_ENV_MNTR, "[WARNING] Wrong LV=%d\n", clm_para->clm_lv); return PHYDM_SET_FAIL; } if (phydm_clm_racing_ctrl(dm, clm_para->clm_lv) == PHYDM_SET_FAIL) return PHYDM_SET_FAIL; if (clm_para->mntr_time >= 262) clm_period = CLM_PERIOD_MAX; else clm_period = clm_para->mntr_time * MS_TO_4US_RATIO; ccx->clm_app = clm_para->clm_app; phydm_clm_setting(dm, clm_period); return PHYDM_SET_SUCCESS; } boolean phydm_clm_mntr_chk(void *dm_void, u16 monitor_time /*unit ms*/) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; struct clm_para_info clm_para = {0}; boolean clm_chk_result = false; u32 sys_return_time = 0; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s] ======>\n", __func__); if (ccx->clm_manual_ctrl) { PHYDM_DBG(dm, DBG_ENV_MNTR, "CLM in manual ctrl\n"); return clm_chk_result; } sys_return_time = ccx->clm_trigger_time + MAX_ENV_MNTR_TIME; if (ccx->clm_app != CLM_BACKGROUND && sys_return_time > dm->phydm_sys_up_time) { PHYDM_DBG(dm, DBG_ENV_MNTR, "trigger_time %d, sys_time=%d\n", ccx->clm_trigger_time, dm->phydm_sys_up_time); return clm_chk_result; } clm_para.clm_app = CLM_BACKGROUND; clm_para.clm_lv = CLM_LV_1; clm_para.mntr_time = monitor_time; if (ccx->clm_mntr_mode == CLM_DRIVER_MNTR) { /*@[Get CLM report]*/ if (phydm_clm_get_result(dm)) { PHYDM_DBG(dm, DBG_ENV_MNTR, "Get CLM_rpt success\n"); phydm_clm_get_utility(dm); } /*@[CLM trigger]----------------------------------------------*/ if (phydm_clm_mntr_set(dm, &clm_para) == PHYDM_SET_SUCCESS) clm_chk_result = true; } else { phydm_clm_mntr_fw(dm, monitor_time); } PHYDM_DBG(dm, DBG_ENV_MNTR, "clm_ratio=%d\n", ccx->clm_ratio); /*@PHYDM_DBG(dm, DBG_ENV_MNTR, "clm_chk_result=%d\n",clm_chk_result);*/ return clm_chk_result; } void phydm_set_clm_mntr_mode(void *dm_void, enum clm_monitor_mode mode) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx_info = &dm->dm_ccx_info; if (ccx_info->clm_mntr_mode != mode) { ccx_info->clm_mntr_mode = mode; phydm_ccx_hw_restart(dm); if (mode == CLM_DRIVER_MNTR) phydm_clm_h2c(dm, 0, 0); } } void phydm_clm_init(void *dm_void) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); ccx->clm_ongoing = false; ccx->clm_manual_ctrl = 0; ccx->clm_mntr_mode = CLM_DRIVER_MNTR; ccx->clm_period = 0; ccx->clm_rpt_stamp = 0; phydm_clm_setting(dm, 65535); } void phydm_clm_dbg(void *dm_void, char input[][16], u32 *_used, char *output, u32 *_out_len) { struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; char help[] = "-h"; u32 var1[10] = {0}; u32 used = *_used; u32 out_len = *_out_len; struct clm_para_info clm_para = {0}; u32 i; for (i = 0; i < 4; i++) { PHYDM_SSCANF(input[i + 1], DCMD_DECIMAL, &var1[i]); } if ((strcmp(input[1], help) == 0)) { PDM_SNPF(out_len, used, output + used, out_len - used, "CLM Driver Basic-Trigger 262ms: {1}\n"); PDM_SNPF(out_len, used, output + used, out_len - used, "CLM Driver Adv-Trigger: {2} {app} {LV} {0~262ms}\n"); PDM_SNPF(out_len, used, output + used, out_len - used, "CLM FW Trigger: {3} {1:drv, 2:fw}\n"); PDM_SNPF(out_len, used, output + used, out_len - used, "CLM Get Result: {100}\n"); } else if (var1[0] == 100) { /* @Get CLM results */ if (phydm_clm_get_result(dm)) phydm_clm_get_utility(dm); PDM_SNPF(out_len, used, output + used, out_len - used, "clm_rpt_stamp=%d\n", ccx->clm_rpt_stamp); PDM_SNPF(out_len, used, output + used, out_len - used, "clm_ratio:((%d percent)) = (%d us/ %d us)\n", ccx->clm_ratio, ccx->clm_result << 2, ccx->clm_period << 2); ccx->clm_manual_ctrl = 0; } else if (var1[0] == 3) { phydm_set_clm_mntr_mode(dm, (enum clm_monitor_mode)var1[1]); PDM_SNPF(out_len, used, output + used, out_len - used, "CLM mode: %s mode\n", ((ccx->clm_mntr_mode == CLM_FW_MNTR) ? "FW" : "Drv")); } else { /* Set & trigger CLM */ ccx->clm_manual_ctrl = 1; if (var1[0] == 1) { clm_para.clm_app = CLM_BACKGROUND; clm_para.clm_lv = CLM_LV_4; clm_para.mntr_time = 262; ccx->clm_mntr_mode = CLM_DRIVER_MNTR; } else if (var1[0] == 2) { clm_para.clm_app = (enum clm_application)var1[1]; clm_para.clm_lv = (enum phydm_clm_level)var1[2]; ccx->clm_mntr_mode = CLM_DRIVER_MNTR; clm_para.mntr_time = (u16)var1[3]; } PDM_SNPF(out_len, used, output + used, out_len - used, "app=%d, lv=%d, mode=%s, time=%d ms\n", clm_para.clm_app, clm_para.clm_lv, ((ccx->clm_mntr_mode == CLM_FW_MNTR) ? "FW" : "driver"), clm_para.mntr_time); if (phydm_clm_mntr_set(dm, &clm_para) == PHYDM_SET_SUCCESS) phydm_clm_trigger(dm); PDM_SNPF(out_len, used, output + used, out_len - used, "clm_rpt_stamp=%d\n", ccx->clm_rpt_stamp); } *_used = used; *_out_len = out_len; } #endif /*@#ifdef CLM_SUPPORT*/ u8 phydm_env_mntr_trigger(void *dm_void, struct nhm_para_info *nhm_para, struct clm_para_info *clm_para, struct env_trig_rpt *trig_rpt) { #if (defined(NHM_SUPPORT) && defined(CLM_SUPPORT)) struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; boolean nhm_set_ok = false; boolean clm_set_ok = false; u8 trigger_result = 0; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s] ======>\n", __func__); /*@[NHM]*/ nhm_set_ok = phydm_nhm_mntr_set(dm, nhm_para); /*@[CLM]*/ if (ccx->clm_mntr_mode == CLM_DRIVER_MNTR) { clm_set_ok = phydm_clm_mntr_set(dm, clm_para); } else if (ccx->clm_mntr_mode == CLM_FW_MNTR) { phydm_clm_h2c(dm, CLM_PERIOD_MAX, true); trigger_result |= CLM_SUCCESS; } if (nhm_set_ok) { phydm_nhm_trigger(dm); trigger_result |= NHM_SUCCESS; } if (clm_set_ok) { phydm_clm_trigger(dm); trigger_result |= CLM_SUCCESS; } /*@monitor for the test duration*/ ccx->start_time = odm_get_current_time(dm); trig_rpt->nhm_rpt_stamp = ccx->nhm_rpt_stamp; trig_rpt->clm_rpt_stamp = ccx->clm_rpt_stamp; PHYDM_DBG(dm, DBG_ENV_MNTR, "nhm_rpt_stamp=%d, clm_rpt_stamp=%d,\n\n", trig_rpt->nhm_rpt_stamp, trig_rpt->clm_rpt_stamp); return trigger_result; #endif } u8 phydm_env_mntr_result(void *dm_void, struct env_mntr_rpt *rpt) { #if (defined(NHM_SUPPORT) && defined(CLM_SUPPORT)) struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; u8 env_mntr_rpt = 0; u64 progressing_time = 0; u32 val_tmp = 0; /*@monitor for the test duration*/ progressing_time = odm_get_progressing_time(dm, ccx->start_time); PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s] ======>\n", __func__); PHYDM_DBG(dm, DBG_ENV_MNTR, "env_time=%lld\n", progressing_time); /*@Get NHM result*/ if (phydm_nhm_get_result(dm)) { PHYDM_DBG(dm, DBG_ENV_MNTR, "Get NHM_rpt success\n"); phydm_nhm_get_utility(dm); rpt->nhm_ratio = ccx->nhm_ratio; rpt->nhm_noise_pwr = ccx->nhm_level; env_mntr_rpt |= NHM_SUCCESS; odm_move_memory(dm, &rpt->nhm_result[0], &ccx->nhm_result[0], NHM_RPT_NUM); } else { rpt->nhm_ratio = ENV_MNTR_FAIL; } /*@Get CLM result*/ if (ccx->clm_mntr_mode == CLM_DRIVER_MNTR) { if (phydm_clm_get_result(dm)) { PHYDM_DBG(dm, DBG_ENV_MNTR, "Get CLM_rpt success\n"); phydm_clm_get_utility(dm); env_mntr_rpt |= CLM_SUCCESS; rpt->clm_ratio = ccx->clm_ratio; } else { rpt->clm_ratio = ENV_MNTR_FAIL; } } else { if (ccx->clm_fw_result_cnt != 0) { val_tmp = ccx->clm_fw_result_acc / ccx->clm_fw_result_cnt; ccx->clm_ratio = (u8)val_tmp; } else { ccx->clm_ratio = 0; } rpt->clm_ratio = ccx->clm_ratio; PHYDM_DBG(dm, DBG_ENV_MNTR, "clm_fw_result_acc=%d, clm_fw_result_cnt=%d\n", ccx->clm_fw_result_acc, ccx->clm_fw_result_cnt); ccx->clm_fw_result_acc = 0; ccx->clm_fw_result_cnt = 0; env_mntr_rpt |= CLM_SUCCESS; } rpt->nhm_rpt_stamp = ccx->nhm_rpt_stamp; rpt->clm_rpt_stamp = ccx->clm_rpt_stamp; PHYDM_DBG(dm, DBG_ENV_MNTR, "IGI=0x%x, nhm_ratio=%d, clm_ratio=%d, nhm_rpt_stamp=%d, clm_rpt_stamp=%d\n\n", ccx->nhm_igi, rpt->nhm_ratio, rpt->clm_ratio, rpt->nhm_rpt_stamp, rpt->clm_rpt_stamp); return env_mntr_rpt; #endif } /*@Environment Monitor*/ void phydm_env_mntr_watchdog(void *dm_void) { #if (defined(NHM_SUPPORT) && defined(CLM_SUPPORT)) struct dm_struct *dm = (struct dm_struct *)dm_void; struct ccx_info *ccx = &dm->dm_ccx_info; boolean nhm_chk_ok = false; boolean clm_chk_ok = false; if (!(dm->support_ability & ODM_BB_ENV_MONITOR)) return; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); nhm_chk_ok = phydm_nhm_mntr_chk(dm, 262); /*@monitor 262ms*/ clm_chk_ok = phydm_clm_mntr_chk(dm, 262); /*@monitor 262ms*/ /*@PHYDM_DBG(dm, DBG_ENV_MNTR, "nhm_chk_ok %d\n\n",nhm_chk_ok);*/ /*@PHYDM_DBG(dm, DBG_ENV_MNTR, "clm_chk_ok %d\n\n",clm_chk_ok);*/ if (nhm_chk_ok) phydm_nhm_trigger(dm); if (clm_chk_ok) phydm_clm_trigger(dm); PHYDM_DBG(dm, DBG_ENV_MNTR, "Summary: nhm_ratio=((%d)) clm_ratio=((%d))\n\n", ccx->nhm_ratio, ccx->clm_ratio); #endif } void phydm_env_monitor_init(void *dm_void) { #if (defined(NHM_SUPPORT) && defined(CLM_SUPPORT)) struct dm_struct *dm = (struct dm_struct *)dm_void; if (!(dm->support_ability & ODM_BB_ENV_MONITOR)) return; PHYDM_DBG(dm, DBG_ENV_MNTR, "[%s]===>\n", __func__); phydm_ccx_hw_restart(dm); phydm_nhm_init(dm); phydm_clm_init(dm); #endif } void phydm_env_mntr_dbg(void *dm_void, char input[][16], u32 *_used, char *output, u32 *_out_len) { struct dm_struct *dm = (struct dm_struct *)dm_void; char help[] = "-h"; u32 var1[10] = {0}; u32 used = *_used; u32 out_len = *_out_len; struct clm_para_info clm_para = {0}; struct nhm_para_info nhm_para = {0}; struct env_mntr_rpt rpt = {0}; struct env_trig_rpt trig_rpt = {0}; struct ccx_info *ccx = &dm->dm_ccx_info; u8 set_result = 0; u8 i = 0; PHYDM_SSCANF(input[1], DCMD_DECIMAL, &var1[0]); if ((strcmp(input[1], help) == 0)) { PDM_SNPF(out_len, used, output + used, out_len - used, "Basic-Trigger 262ms: {1}\n"); PDM_SNPF(out_len, used, output + used, out_len - used, "Get Result: {100}\n"); } else if (var1[0] == 100) { /* Get results */ set_result = phydm_env_mntr_result(dm, &rpt); PDM_SNPF(out_len, used, output + used, out_len - used, "Set Result=%d\n nhm_ratio=%d clm_ratio=%d\n nhm_rpt_stamp=%d, clm_rpt_stamp=%d,\n", set_result, rpt.nhm_ratio, rpt.clm_ratio, rpt.nhm_rpt_stamp, rpt.clm_rpt_stamp); for (i = 0; i <= 11; i++) { PDM_SNPF(out_len, used, output + used, out_len - used, "nhm_rpt[%d] = %d (%d percent)\n", i, rpt.nhm_result[i], (((rpt.nhm_result[i] * 100) + 128) >> 8)); } PDM_SNPF(out_len, used, output + used, out_len - used, "[NHM] valid: %d percent, noise(RSSI) = %d\n", ccx->nhm_level_valid, ccx->nhm_level); } else { /* Set & trigger*/ /*nhm para*/ nhm_para.incld_txon = NHM_EXCLUDE_TXON; nhm_para.incld_cca = NHM_EXCLUDE_CCA; nhm_para.div_opt = NHM_CNT_ALL; nhm_para.nhm_app = NHM_ACS; nhm_para.nhm_lv = NHM_LV_2; nhm_para.mntr_time = 262; /*clm para*/ clm_para.clm_app = CLM_ACS; clm_para.clm_lv = CLM_LV_2; clm_para.mntr_time = 262; set_result = phydm_env_mntr_trigger(dm, &nhm_para, &clm_para, &trig_rpt); PDM_SNPF(out_len, used, output + used, out_len - used, "Set Result=%d, nhm_rpt_stamp=%d, clm_rpt_stamp=%d\n", set_result, trig_rpt.nhm_rpt_stamp, trig_rpt.clm_rpt_stamp); } *_used = used; *_out_len = out_len; }