/****************************************************************************** * * Copyright(c) 2007 - 2020 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 "../halbb_precomp.h" #ifdef BB_8852B_SUPPORT #ifdef HALBB_FW_OFLD_SUPPORT bool halbb_fwcfg_bb_phy_8852b(struct bb_info *bb, u32 addr, u32 data, enum phl_phy_idx phy_idx) { bool ret = true; if (addr == 0xfe) { halbb_delay_ms(bb, 50); BB_DBG(bb, DBG_INIT, "Delay 50 ms\n"); } else if (addr == 0xfd) { halbb_delay_ms(bb, 5); BB_DBG(bb, DBG_INIT, "Delay 5 ms\n"); } else if (addr == 0xfc) { halbb_delay_ms(bb, 1); BB_DBG(bb, DBG_INIT, "Delay 1 ms\n"); } else if (addr == 0xfb) { halbb_delay_us(bb, 50); BB_DBG(bb, DBG_INIT, "Delay 50 us\n"); } else if (addr == 0xfa) { halbb_delay_us(bb, 5); BB_DBG(bb, DBG_INIT, "Delay 5 us\n"); } else if (addr == 0xf9) { halbb_delay_us(bb, 1); BB_DBG(bb, DBG_INIT, "Delay 1 us\n"); } else { /*FWOFLD in init BB reg flow */ if (halbb_check_fw_ofld(bb)) { ret &= halbb_fw_set_reg(bb, addr, MASKDWORD, data, 0); BB_DBG(bb, DBG_INIT, "[REG FWOFLD]0x%04X = 0x%08X, ret = %d\n", addr, data, (u8)ret); } else { halbb_set_reg(bb, addr, MASKDWORD, data); #ifdef HALBB_DBCC_SUPPORT BB_DBG(bb, DBG_INIT, "[REG][%d]0x%04X = 0x%08X\n", phy_idx, addr, data); #else BB_DBG(bb, DBG_INIT, "[REG]0x%04X = 0x%08X\n", addr, data); #endif } } return ret; } void halbb_fwofld_bb_reset_8852b(struct bb_info *bb, enum phl_phy_idx phy_idx) { BB_DBG(bb, DBG_DBG_API, "%s\n", __func__); // === [TSSI protect on] === // halbb_fw_set_reg(bb, 0x58dc, BIT(30), 0x1, 0); halbb_fw_set_reg(bb, 0x5818, BIT(30), 0x1, 0); halbb_fw_set_reg(bb, 0x78dc, BIT(30), 0x1, 0); halbb_fw_set_reg(bb, 0x7818, BIT(30), 0x1, 0); // === [BB reset] === // halbb_fw_set_reg(bb, 0x704, BIT(1), 1, 0); halbb_fw_set_reg(bb, 0x704, BIT(1), 0, 0); halbb_fw_set_reg(bb, 0x704, BIT(1), 1, 0); // === [TSSI protect off] === // halbb_fw_set_reg(bb, 0x58dc, BIT(30), 0x0, 0); halbb_fw_set_reg(bb, 0x5818, BIT(30), 0x0, 0); halbb_fw_set_reg(bb, 0x78dc, BIT(30), 0x0, 0); halbb_fw_set_reg(bb, 0x7818, BIT(30), 0x0, 0); } void halbb_fwofld_dfs_en_8852b(struct bb_info *bb, bool en) { BB_DBG(bb, DBG_DBG_API, "%s\n", __func__); if (en) halbb_fw_set_reg(bb, 0x0, BIT(31), 1, 0); else halbb_fw_set_reg(bb, 0x0, BIT(31), 0, 0); } void halbb_fwofld_adc_en_8852b(struct bb_info *bb, bool en) { BB_DBG(bb, DBG_DBG_API, "%s\n", __func__); if (en) halbb_fw_set_reg(bb, 0x20fc, 0xff000000, 0x0, 0); else halbb_fw_set_reg(bb, 0x20fc, 0xff000000, 0xf, 0); } void halbb_fwofld_tssi_cont_en_8852b(struct bb_info *bb, bool en, enum rf_path path) { u32 tssi_trk_man[2] = {0x5818, 0x7818}; BB_DBG(bb, DBG_DBG_API, "%s\n", __func__); if (en) halbb_fw_set_reg(bb, tssi_trk_man[path], BIT(30), 0x0, 0); else halbb_fw_set_reg(bb, tssi_trk_man[path], BIT(30), 0x1, 0); } void halbb_fwofld_bb_reset_all_8852b(struct bb_info *bb, enum phl_phy_idx phy_idx) { BB_DBG(bb, DBG_DBG_API, "%s\n", __func__); //Protest SW-SI halbb_fw_set_reg_cmn(bb, 0x1200, BIT(28) | BIT(29) | BIT(30), 0x7, phy_idx, 0); halbb_fw_set_reg_cmn(bb, 0x3200, BIT(28) | BIT(29) | BIT(30), 0x7, phy_idx, 0); halbb_fw_delay(bb, 1); // === [BB reset] === // halbb_fw_set_reg_cmn(bb, 0x704, BIT(1), 1, phy_idx, 0); halbb_fw_set_reg_cmn(bb, 0x704, BIT(1), 0, phy_idx, 0); halbb_fw_set_reg_cmn(bb, 0x1200, BIT(28) | BIT(29) | BIT(30), 0x0, phy_idx, 0); halbb_fw_set_reg_cmn(bb, 0x3200, BIT(28) | BIT(29) | BIT(30), 0x0, phy_idx, 0); halbb_fw_set_reg_cmn(bb, 0x704, BIT(1), 1, phy_idx, 0); } void halbb_fwofld_bb_reset_en_8852b(struct bb_info *bb, bool en, enum phl_phy_idx phy_idx) { BB_DBG(bb, DBG_DBG_API, "%s\n", __func__); if (en) { halbb_fw_set_reg_cmn(bb, 0x1200, BIT(28) | BIT(29) | BIT(30), 0x0, phy_idx, 0); halbb_fw_set_reg_cmn(bb, 0x3200, BIT(28) | BIT(29) | BIT(30), 0x0, phy_idx, 0); halbb_fw_set_reg_cmn(bb, 0x704, BIT(1), 1, phy_idx, 0); //PD Enable if(bb->hal_com->band[0].cur_chandef.band == BAND_ON_24G) halbb_fw_set_reg(bb,0x2344, BIT(31), 0x0, 0); halbb_fw_set_reg(bb,0xc3c, BIT(9), 0x0, 0); } else { //PD Disable halbb_fw_set_reg(bb,0x2344, BIT(31), 0x1, 0); halbb_fw_set_reg(bb,0xc3c, BIT(9), 0x1, 0); //Protest SW-SI halbb_fw_set_reg_cmn(bb, 0x1200, BIT(28) | BIT(29) | BIT(30), 0x7, phy_idx, 0); halbb_fw_set_reg_cmn(bb, 0x3200, BIT(28) | BIT(29) | BIT(30), 0x7, phy_idx, 0); halbb_fw_delay(bb, 1); halbb_fw_set_reg_cmn(bb, 0x704, BIT(1), 0, phy_idx, 0); } } #if 0 u32 halbb_read_rf_reg_8852b_a(struct bb_info *bb, enum rf_path path, u32 reg_addr, u32 bit_mask) { u8 path_tmp=0; u32 i = 0, j = 0, readback_value = INVALID_RF_DATA, r_reg = 0; bool is_r_busy = true, is_w_busy = true, is_r_done = false; BB_DBG(bb, DBG_PHY_CONFIG, "<====== %s ======>\n", __func__); /*==== Error handling ====*/ while (is_w_busy || is_r_busy) { is_w_busy = (bool)halbb_get_reg(bb, 0x174c, BIT(24)); is_r_busy = (bool)halbb_get_reg(bb, 0x174c, BIT(25)); halbb_delay_us(bb, 1); /*BB_WARNING("[%s] is_w_busy = %d, is_r_busy = %d\n", __func__, is_w_busy, is_r_busy);*/ i++; if (i > 30) break; } if (is_w_busy || is_r_busy) { BB_WARNING("[%s] is_w_busy = (%d), is_r_busy = (%d)\n", __func__, is_w_busy, is_r_busy); return INVALID_RF_DATA; } if (path > RF_PATH_B) { BB_WARNING("[%s] Unsupported path (%d)\n", __func__, path); return INVALID_RF_DATA; } /*==== Calculate offset ====*/ path_tmp = (u8)path & 0x7; reg_addr &= 0xff; /*==== RF register only has 20bits ====*/ bit_mask &= RFREGOFFSETMASK; r_reg = (path_tmp << 8 | reg_addr) & 0x7ff; halbb_set_reg(bb, 0x378, 0x7ff, r_reg); halbb_delay_us(bb, 2); /*==== Read RF register ====*/ while (!is_r_done) { is_r_done = (bool)halbb_get_reg(bb, 0x174c, BIT(26)); halbb_delay_us(bb, 1); j++; if (j > 30) break; } if (is_r_done) { readback_value = halbb_get_reg(bb, 0x174c, bit_mask); } else { BB_WARNING("[%s] is_r_done = (%d)\n", __func__, is_r_done); return INVALID_RF_DATA; } BB_DBG(bb, DBG_PHY_CONFIG, "A die RF-%d 0x%x = 0x%x, bit mask = 0x%x, i=%x, j =%x\n", path_tmp, reg_addr, readback_value, bit_mask,i,j); return readback_value; } u32 halbb_read_rf_reg_8852b_d(struct bb_info *bb, enum rf_path path, u32 reg_addr, u32 bit_mask) { u32 readback_value = 0, direct_addr = 0; u32 offset_read_rf[2] = {0xe000, 0xf000}; BB_DBG(bb, DBG_PHY_CONFIG, "<====== %s ======>\n", __func__); /*==== Error handling ====*/ if (path > RF_PATH_B) { BB_WARNING("[%s] Unsupported path (%d)\n", __func__, path); return INVALID_RF_DATA; } /*==== Calculate offset ====*/ reg_addr &= 0xff; direct_addr = offset_read_rf[path] + (reg_addr << 2); /*==== RF register only has 20bits ====*/ bit_mask &= RFREGOFFSETMASK; /*==== Read RF register directly ====*/ readback_value = halbb_get_reg(bb, direct_addr, bit_mask); BB_DBG(bb, DBG_PHY_CONFIG, "D die RF-%d 0x100%x = 0x%x, bit mask = 0x%x\n", path, reg_addr, readback_value, bit_mask); return readback_value; } u32 halbb_read_rf_reg_8852b(struct bb_info *bb, enum rf_path path, u32 reg_addr, u32 bit_mask) { u32 readback_value = INVALID_RF_DATA; enum rtw_dv_sel ad_sel = (enum rtw_dv_sel)((reg_addr & 0x10000) >> 16); BB_DBG(bb, DBG_PHY_CONFIG, "<====== %s ======>\n", __func__); /*==== Error handling ====*/ if (path > RF_PATH_B) { BB_WARNING("[%s] Unsupported path (%d)\n", __func__, path); return INVALID_RF_DATA; } if (ad_sel == DAV) { readback_value = halbb_read_rf_reg_8852b_a(bb, path, reg_addr, bit_mask); /*BB_DBG(bb, DBG_PHY_CONFIG, "A-die RF-%d 0x%x = 0x%x, bit mask = 0x%x\n", path, reg_addr, readback_value, bit_mask);*/ } else if (ad_sel == DDV) { readback_value = halbb_read_rf_reg_8852b_d(bb, path, reg_addr, bit_mask); /*BB_DBG(bb, DBG_PHY_CONFIG, "D-die RF-%d 0x%x = 0x%x, bit mask = 0x%x\n", path, reg_addr, readback_value, bit_mask);*/ } else { BB_DBG(bb, DBG_PHY_CONFIG, "Fail Read RF RF-%d 0x%x = 0x%x, bit mask = 0x%x\n", path, reg_addr, readback_value, bit_mask); return INVALID_RF_DATA; } return readback_value; } bool halbb_write_rf_reg_8852b_a(struct bb_info *bb, enum rf_path path, u32 reg_addr, u32 bit_mask, u32 data) { u8 path_tmp = 0, b_msk_en = 0, bit_shift = 0; u32 i =0, w_reg = 0; bool is_r_busy = true, is_w_busy = true; BB_DBG(bb, DBG_PHY_CONFIG, "<====== %s ======>\n", __func__); /*==== Error handling ====*/ while (is_w_busy || is_r_busy) { is_w_busy = (bool)halbb_get_reg(bb, 0x174c, BIT(24)); is_r_busy = (bool)halbb_get_reg(bb, 0x174c, BIT(25)); halbb_delay_us(bb, 1); /*BB_WARNING("[%s] is_w_busy = %d, is_r_busy = %d\n", __func__, is_w_busy, is_r_busy);*/ i++; if (i > 30) break; } if (is_w_busy || is_r_busy) { BB_WARNING("[%s] is_w_busy = (%d), is_r_busy = (%d)\n", __func__, is_w_busy, is_r_busy); return false; } if (path > RF_PATH_B) { BB_WARNING("[%s] Unsupported path (%d)\n", __func__, path); return false; } /*==== Calculate offset ====*/ path_tmp = (u8)path & 0x7; reg_addr &= 0xff; /*==== RF register only has 20bits ====*/ data &= RFREGOFFSETMASK; bit_mask &= RFREGOFFSETMASK; /*==== Check if mask needed ====*/ if (bit_mask != RFREGOFFSETMASK) { b_msk_en = 1; halbb_set_reg(bb, 0x374, RFREGOFFSETMASK, bit_mask); for (bit_shift = 0; bit_shift <= 19; bit_shift++) { if ((bit_mask >> bit_shift) & 0x1) break; } data = (data << bit_shift) & RFREGOFFSETMASK; } w_reg = b_msk_en << 31 | path_tmp << 28 | reg_addr << 20 | data; /*==== Write RF register ====*/ halbb_set_reg(bb, 0x370, MASKDWORD, w_reg); //halbb_delay_us(bb, 5); BB_DBG(bb, DBG_PHY_CONFIG, "A die RF-%d 0x%x = 0x%x , bit mask = 0x%x, i=%x\n", path_tmp, reg_addr, data, bit_mask,i); return true; } bool halbb_write_rf_reg_8852b_d(struct bb_info *bb, enum rf_path path, u32 reg_addr, u32 bit_mask, u32 data) { u32 direct_addr = 0; u32 offset_write_rf[2] = {0xe000, 0xf000}; BB_DBG(bb, DBG_PHY_CONFIG, "<====== %s ======>\n", __func__); /*==== Error handling ====*/ if (path > RF_PATH_B) { BB_WARNING("[%s] Unsupported path (%d)\n", __func__, path); return false; } /*==== Calculate offset ====*/ reg_addr &= 0xff; direct_addr = offset_write_rf[path] + (reg_addr << 2); /*==== RF register only has 20bits ====*/ bit_mask &= RFREGOFFSETMASK; /*==== Write RF register directly ====*/ halbb_set_reg(bb, direct_addr, bit_mask, data); halbb_delay_us(bb, 1); BB_DBG(bb, DBG_PHY_CONFIG, "D die RF-%d 0x%x = 0x%x , bit mask = 0x%x\n", path, reg_addr, data, bit_mask); return true; } bool halbb_write_rf_reg_8852b(struct bb_info *bb, enum rf_path path, u32 reg_addr, u32 bit_mask, u32 data) { u8 path_tmp = 0, b_msk_en = 0; u32 w_reg = 0; bool rpt = true; enum rtw_dv_sel ad_sel = (enum rtw_dv_sel)((reg_addr & 0x10000) >> 16); BB_DBG(bb, DBG_PHY_CONFIG, "<====== %s ======>\n", __func__); /*==== Error handling ====*/ if (path > RF_PATH_B) { BB_WARNING("[%s] Unsupported path (%d)\n", __func__, path); return false; } if (ad_sel == DAV) { rpt = halbb_write_rf_reg_8852b_a(bb, path, reg_addr, bit_mask, data); /*BB_DBG(bb, DBG_PHY_CONFIG, "A-die RF-%d 0x%x = 0x%x , bit mask = 0x%x\n", path, reg_addr, data, bit_mask);*/ } else if (ad_sel == DDV) { rpt = halbb_write_rf_reg_8852b_d(bb, path, reg_addr, bit_mask, data); /*BB_DBG(bb, DBG_PHY_CONFIG, "D-die RF-%d 0x%x = 0x%x , bit mask = 0x%x\n", path, reg_addr, data, bit_mask);*/ } else { rpt = false; BB_DBG(bb, DBG_PHY_CONFIG, "Fail Write RF-%d 0x%x = 0x%x , bit mask = 0x%x\n", path, reg_addr, data, bit_mask); } return rpt; } #endif void halbb_fwofld_5m_mask_8852b(struct bb_info *bb, u8 pri_ch, enum channel_width bw, enum phl_phy_idx phy_idx) { bool mask_5m_low = false; bool mask_5m_en = false; switch (bw) { case CHANNEL_WIDTH_40: /* Prich=1 : Mask 5M High Prich=2 : Mask 5M Low */ mask_5m_en = true; mask_5m_low = pri_ch == 2 ? true : false; break; case CHANNEL_WIDTH_80: /* Prich=3 : Mask 5M High Prich=4 : Mask 5M Low Else : Mask 5M Disable */ mask_5m_en = ((pri_ch == 3) || (pri_ch == 4)) ? true : false; mask_5m_low = pri_ch == 4 ? true : false; break; default: mask_5m_en = false; break; } BB_DBG(bb, DBG_PHY_CONFIG, "[5M Mask] pri_ch = %d, bw = %d", pri_ch, bw); if (!mask_5m_en) { halbb_fw_set_reg(bb, 0x46f8, BIT(12), 0x0, 0); halbb_fw_set_reg(bb, 0x47b8, BIT(12), 0x0, 0); halbb_fw_set_reg_cmn(bb, 0x4440, BIT(31), 0x0, phy_idx, 0); } else { if (mask_5m_low) { halbb_fw_set_reg(bb, 0x46f8, 0x3f, 0x4, 0); halbb_fw_set_reg(bb, 0x46f8, BIT(12), 0x1, 0); halbb_fw_set_reg(bb, 0x46f8, BIT(8), 0x0, 0); halbb_fw_set_reg(bb, 0x46f8, BIT(6), 0x1, 0); halbb_fw_set_reg(bb, 0x47b8, 0x3f, 0x4, 0); halbb_fw_set_reg(bb, 0x47b8, BIT(12), 0x1, 0); halbb_fw_set_reg(bb, 0x47b8, BIT(8), 0x0, 0); halbb_fw_set_reg(bb, 0x47b8, BIT(6), 0x1, 0); } else { halbb_fw_set_reg(bb, 0x46f8, 0x3f, 0x4, 0); halbb_fw_set_reg(bb, 0x46f8, BIT(12), 0x1, 0); halbb_fw_set_reg(bb, 0x46f8, BIT(8), 0x1, 0); halbb_fw_set_reg(bb, 0x46f8, BIT(6), 0x0, 0); halbb_fw_set_reg(bb, 0x47b8, 0x3f, 0x4, 0); halbb_fw_set_reg(bb, 0x47b8, BIT(12), 0x1, 0); halbb_fw_set_reg(bb, 0x47b8, BIT(8), 0x1, 0); halbb_fw_set_reg(bb, 0x47b8, BIT(6), 0x0, 0); } halbb_fw_set_reg_cmn(bb, 0x4440, BIT(31), 0x1, phy_idx, 0); } } u8 halbb_fwofld_sco_mapping_8852b(struct bb_info *bb, u8 central_ch) { /*=== SCO compensate : (BIT(0) << 18) / central_ch ===*/ if (central_ch == 1) /*=== 2G ===*/ return 109; else if (central_ch >= 2 && central_ch <= 6) return 108; else if (central_ch >= 7 && central_ch <= 10) return 107; else if (central_ch >= 11 && central_ch <= 14) return 106; else if (central_ch == 36 || central_ch == 38) return 51; else if (central_ch >= 40 && central_ch <= 58) return 50; else if (central_ch >= 60 && central_ch <= 64) return 49; else if (central_ch == 100 || central_ch == 102) return 48; else if (central_ch >= 104 && central_ch <= 126) return 47; else if (central_ch >= 128 && central_ch <= 151) return 46; else if (central_ch >= 153 && central_ch <= 177) return 45; else return 0; } bool halbb_fwofld_ctrl_sco_cck_8852b(struct bb_info *bb, u8 pri_ch) { u32 sco_barker_threshold[14] = {0x1cfea, 0x1d0e1, 0x1d1d7, 0x1d2cd, 0x1d3c3, 0x1d4b9, 0x1d5b0, 0x1d6a6, 0x1d79c, 0x1d892, 0x1d988, 0x1da7f, 0x1db75, 0x1ddc4}; u32 sco_cck_threshold[14] = {0x27de3, 0x27f35, 0x28088, 0x281da, 0x2832d, 0x2847f, 0x285d2, 0x28724, 0x28877, 0x289c9, 0x28b1c, 0x28c6e, 0x28dc1, 0x290ed}; if (pri_ch > 14) { BB_DBG(bb, DBG_PHY_CONFIG, "[CCK SCO Fail]"); return false; } halbb_fw_set_reg(bb, 0x23b0, 0x7ffff, sco_barker_threshold[pri_ch - 1], 0); halbb_fw_set_reg(bb, 0x23b4, 0x7ffff, sco_cck_threshold[pri_ch - 1], 0); BB_DBG(bb, DBG_PHY_CONFIG, "[CCK SCO Success]"); return true; } void halbb_fwofld_ctrl_btg_8852b(struct bb_info *bb, bool btg) { struct rtw_phl_com_t *phl = bb->phl_com; struct dev_cap_t *dev = &phl->dev_cap; BB_DBG(bb, DBG_PHY_CONFIG, "<====== %s ======>\n", __func__); if(bb->hal_com->band[0].cur_chandef.band != BAND_ON_24G) return; if (btg) { // Path A halbb_fw_set_reg(bb, 0x4738, BIT(19), 0x1, 0); halbb_fw_set_reg(bb, 0x4738, BIT(22), 0x0, 0); // Path B halbb_fw_set_reg(bb, 0x4AA4, BIT(19), 0x1, 0); halbb_fw_set_reg(bb, 0x4AA4, BIT(22), 0x1, 0); BB_DBG(bb, DBG_PHY_CONFIG, "[BT] Apply BTG Setting\n"); // Apply Grant BT by TMAC Setting halbb_fw_set_reg(bb, 0x980, 0x1e0000, 0x0, 0); BB_DBG(bb, DBG_PHY_CONFIG, "[BT] Apply Grant BT by TMAC Setting\n"); // Add BT share halbb_fw_set_reg(bb, 0x49C4, BIT(14), 0x1, 0); halbb_fw_set_reg(bb, 0x49C0, 0x3c00000, 0x2, 0); /* To avoid abnormal 1R CCA without BT, set rtl only 0xc6c[21] = 0x1 */ halbb_fw_set_reg(bb, 0x4420, BIT(31), 0x1, 0); halbb_fw_set_reg(bb, 0xc6c, BIT(21), 0x1, 0); } else { // Path A halbb_fw_set_reg(bb, 0x4738, BIT(19), 0x0, 0); halbb_fw_set_reg(bb, 0x4738, BIT(22), 0x0, 0); // Path B halbb_fw_set_reg(bb, 0x4AA4, BIT(19), 0x0, 0); halbb_fw_set_reg(bb, 0x4AA4, BIT(22), 0x0, 0); BB_DBG(bb, DBG_PHY_CONFIG, "[BT] Disable BTG Setting\n"); // Ignore Grant BT by PMAC Setting halbb_fw_set_reg(bb, 0x980, 0x1e0000, 0x0, 0); BB_DBG(bb, DBG_PHY_CONFIG, "[BT] Ignore Grant BT by PMAC Setting\n"); // Reset BT share halbb_fw_set_reg(bb, 0x49C4, BIT(14), 0x0, 0); halbb_fw_set_reg(bb, 0x49C0, 0x3c00000, 0x0, 0); /* To avoid abnormal 1R CCA without BT, set rtl only 0xc6c[21] = 0x1 */ halbb_fw_set_reg(bb, 0x4420, BIT(31), 0x1, 0); halbb_fw_set_reg(bb, 0xc6c, BIT(21), 0x0, 0); } } void halbb_fwofld_ctrl_btc_preagc_8852b(struct bb_info *bb, bool bt_en) { BB_DBG(bb, DBG_PHY_CONFIG, "<====== %s ======>\n", __func__); if (bt_en) { // DFIR Corner halbb_fw_set_reg(bb, 0x46D0, BIT(1) | BIT(0), 0x3, 0); halbb_fw_set_reg(bb, 0x4790, BIT(1) | BIT(0), 0x3, 0); // LNA Backoff at Normal halbb_fw_set_reg(bb, 0x46a0, 0x3f, 0x8, 0); halbb_fw_set_reg(bb, 0x49f4, 0x3f, 0x8, 0); // LNA, TIA, ADC backoff at BT TX halbb_fw_set_reg(bb, 0x4ae4, 0xffffff, 0x78899e, 0); halbb_fw_set_reg(bb, 0x4aec, 0xffffff, 0x78899e, 0); } else { // DFIR Corner halbb_fw_set_reg(bb, 0x46D0, BIT(1) | BIT(0), 0x0, 0); halbb_fw_set_reg(bb, 0x4790, BIT(1) | BIT(0), 0x0, 0); // LNA Backoff at Normal halbb_fw_set_reg(bb, 0x46a0, 0x3f, 0x1e, 0); halbb_fw_set_reg(bb, 0x49f4, 0x3f, 0x1e, 0); // LNA, TIA, ADC backoff at BT TX halbb_fw_set_reg(bb, 0x4ae4, 0xffffff, 0x4d34d2, 0); halbb_fw_set_reg(bb, 0x4aec, 0xffffff, 0x4d34d2, 0); } } bool halbb_fwofld_bw_setting_8852b(struct bb_info *bb, enum channel_width bw, enum rf_path path) { u32 rf_reg18 = 0; u32 adc_sel[2] = {0xC0EC, 0xC1EC}; u32 wbadc_sel[2] = {0xC0E4, 0xC1E4}; //rf_reg18 = halbb_read_rf_reg_8852b(bb, path, 0x18, RFREGOFFSETMASK); /*==== [Error handling] ====*/ //if (rf_reg18 == INVALID_RF_DATA) { // BB_WARNING("Invalid RF_0x18 for Path-%d\n", path); // return false; //} //rf_reg18 &= ~(BIT(11) | BIT(10)); /*==== [Switch bandwidth] ====*/ switch (bw) { case CHANNEL_WIDTH_5: case CHANNEL_WIDTH_10: case CHANNEL_WIDTH_20: if (bw == CHANNEL_WIDTH_5) { /*ADC clock = 20M & WB ADC clock = 40M for BW5 */ halbb_fw_set_reg(bb, adc_sel[path], 0x6000, 0x1, 0); halbb_fw_set_reg(bb, wbadc_sel[path], 0x30, 0x0, 0); } else if (bw == CHANNEL_WIDTH_10) { /*ADC clock = 40M & WB ADC clock = 80M for BW10 */ halbb_fw_set_reg(bb, adc_sel[path], 0x6000, 0x2, 0); halbb_fw_set_reg(bb, wbadc_sel[path], 0x30, 0x1, 0); } else if (bw == CHANNEL_WIDTH_20) { /*ADC clock = 80M & WB ADC clock = 160M for BW20 */ halbb_fw_set_reg(bb, adc_sel[path], 0x6000, 0x0, 0); halbb_fw_set_reg(bb, wbadc_sel[path], 0x30, 0x2, 0); } break; case CHANNEL_WIDTH_40: /*ADC clock = 80M & WB ADC clock = 160M for BW40 */ halbb_fw_set_reg(bb, adc_sel[path], 0x6000, 0x0, 0); halbb_fw_set_reg(bb, wbadc_sel[path], 0x30, 0x2, 0); break; case CHANNEL_WIDTH_80: /*ADC clock = 160M & WB ADC clock = 160M for BW40 */ halbb_fw_set_reg(bb, adc_sel[path], 0x6000, 0x0, 0); halbb_fw_set_reg(bb, wbadc_sel[path], 0x30, 0x2, 0); break; default: BB_WARNING("Fail to set ADC\n"); } BB_DBG(bb, DBG_PHY_CONFIG, "[Success][bw_setting] ADC setting for Path-%d\n", path); return true; } bool halbb_fwofld_ctrl_bw_8852b(struct bb_info *bb, u8 pri_ch, enum channel_width bw, enum phl_phy_idx phy_idx) { BB_DBG(bb, DBG_PHY_CONFIG, "<====== %s ======>\n", __func__); if (bb->is_disable_phy_api) { BB_DBG(bb, DBG_PHY_CONFIG, "[%s] Disable PHY API\n", __func__); return true; } /*==== Error handling ====*/ if (bw >= CHANNEL_WIDTH_MAX || (bw == CHANNEL_WIDTH_40 && pri_ch > 2) || (bw == CHANNEL_WIDTH_80 && pri_ch > 4)) { BB_WARNING("Fail to switch bw(bw:%d, pri ch:%d)\n", bw, pri_ch); return false; } /*==== Switch bandwidth ====*/ switch (bw) { case CHANNEL_WIDTH_5: case CHANNEL_WIDTH_10: case CHANNEL_WIDTH_20: if (bw == CHANNEL_WIDTH_5) { /*RF_BW:[31:30]=0x0 */ halbb_fw_set_reg_cmn(bb, 0x49C0, 0xC0000000, 0x0, phy_idx, 0); /*small BW:[13:12]=0x1 */ halbb_fw_set_reg_cmn(bb, 0x49C4, 0x3000, 0x1, phy_idx, 0); /*Pri ch:[11:8]=0x0 */ halbb_fw_set_reg_cmn(bb, 0x49C4, 0xf00, 0x0, phy_idx, 0); } else if (bw == CHANNEL_WIDTH_10) { /*RF_BW:[31:30]=0x0 */ halbb_fw_set_reg_cmn(bb, 0x49C0, 0xC0000000, 0x0, phy_idx, 0); /*small BW:[13:12]=0x2 */ halbb_fw_set_reg_cmn(bb, 0x49C4, 0x3000, 0x2, phy_idx, 0); /*Pri ch:[11:8]=0x0 */ halbb_fw_set_reg_cmn(bb, 0x49C4, 0xf00, 0x0, phy_idx, 0); } else if (bw == CHANNEL_WIDTH_20) { /*RF_BW:[31:30]=0x0 */ halbb_fw_set_reg_cmn(bb, 0x49C0, 0xC0000000, 0x0, phy_idx, 0); /*small BW:[13:12]=0x0 */ halbb_fw_set_reg_cmn(bb, 0x49C4, 0x3000, 0x0, phy_idx, 0); /*Pri ch:[11:8]=0x0 */ halbb_fw_set_reg_cmn(bb, 0x49C4, 0xf00, 0x0, phy_idx, 0); } break; case CHANNEL_WIDTH_40: /*RF_BW:[31:30]=0x1 */ halbb_fw_set_reg_cmn(bb, 0x49C0, 0xC0000000, 0x1, phy_idx, 0); /*small BW:[13:12]=0x0 */ halbb_fw_set_reg_cmn(bb, 0x49C4, 0x3000, 0x0, phy_idx, 0); /*Pri ch:[11:8] */ halbb_fw_set_reg_cmn(bb, 0x49C4, 0xf00, pri_ch, phy_idx, 0); /*CCK primary channel */ if (pri_ch == 1) halbb_fw_set_reg(bb, 0x237c, BIT(0), 1, 0); else halbb_fw_set_reg(bb, 0x237c, BIT(0), 0, 0); break; case CHANNEL_WIDTH_80: /*RF_BW:[31:30]=0x2 */ halbb_fw_set_reg_cmn(bb, 0x49C0, 0xC0000000, 0x2, phy_idx, 0); /*small BW:[13:12]=0x0 */ halbb_fw_set_reg_cmn(bb, 0x49C4, 0x3000, 0x0, phy_idx, 0); /*Pri ch:[11:8] */ halbb_fw_set_reg_cmn(bb, 0x49C4, 0xf00, pri_ch, phy_idx, 0); break; default: BB_WARNING("Fail to switch bw (bw:%d, pri ch:%d)\n", bw, pri_ch); } /*============== [Path A] ==============*/ halbb_fwofld_bw_setting_8852b(bb, bw, RF_PATH_A); /*============== [Path B] ==============*/ halbb_fwofld_bw_setting_8852b(bb, bw, RF_PATH_B); BB_DBG(bb, DBG_PHY_CONFIG, "[Switch BW Success] BW: %d for PHY%d\n", bw, phy_idx); return true; } bool halbb_fwofld_ch_setting_8852b(struct bb_info *bb, u8 central_ch, enum rf_path path, bool *is_2g_ch) { u32 rf_reg18 = 0; //*is_2g_ch = (central_ch <= 14) ? true : false; //RF_18 R/W already move to RF API BB_DBG(bb, DBG_PHY_CONFIG, "[Success][ch_setting] CH: %d for Path-%d\n", central_ch, path); return true; } bool halbb_fwofld_ctrl_ch_8852b(struct bb_info *bb, u8 central_ch, enum band_type band, enum phl_phy_idx phy_idx) { u8 sco_comp; bool is_2g_ch; BB_DBG(bb, DBG_PHY_CONFIG, "<====== %s ======>\n", __func__); if (bb->is_disable_phy_api) { BB_DBG(bb, DBG_PHY_CONFIG, "[%s] Disable PHY API\n", __func__); return true; } /*==== Error handling ====*/ if (band != BAND_ON_6G) { if ((central_ch > 14 && central_ch < 36) || (central_ch > 64 && central_ch < 100) || (central_ch > 144 && central_ch < 149) || central_ch > 177 || central_ch== 0) { BB_WARNING("Invalid CH:%d for PHY%d\n", central_ch, phy_idx); return false; } } else { if (central_ch > 253) { BB_WARNING("Invalid 6G CH:%d for PHY%d\n", central_ch, phy_idx); return false; } } is_2g_ch = (band == BAND_ON_24G) ? true : false; /*============== [Path A] ==============*/ //halbb_ch_setting_8852b(bb, central_ch, RF_PATH_A, &is_2g_ch); //------------- [Mode Sel - Path A] ------------// if (is_2g_ch) halbb_fw_set_reg_cmn(bb, 0x4738, BIT(17), 1, phy_idx, 0); else halbb_fw_set_reg_cmn(bb, 0x4738, BIT(17), 0, phy_idx, 0); /*============== [Path B] ==============*/ //halbb_ch_setting_8852b(bb, central_ch, RF_PATH_B, &is_2g_ch); //------------- [Mode Sel - Path B] ------------// if (is_2g_ch) halbb_fw_set_reg_cmn(bb, 0x4AA4, BIT(17), 1, phy_idx, 0); else halbb_fw_set_reg_cmn(bb, 0x4AA4, BIT(17), 0, phy_idx, 0); /*==== [SCO compensate fc setting] ====*/ sco_comp = halbb_fwofld_sco_mapping_8852b(bb, central_ch); halbb_fw_set_reg_cmn(bb, 0x49C0, 0x7f, sco_comp, phy_idx, 0); /* === CCK Parameters === */ if (band != BAND_ON_6G) { if (central_ch == 14) { halbb_fw_set_reg(bb, 0x2300, 0xffffff, 0x3b13ff, 0); halbb_fw_set_reg(bb, 0x2304, 0xffffff, 0x1c42de, 0); halbb_fw_set_reg(bb, 0x2308, 0xffffff, 0xfdb0ad, 0); halbb_fw_set_reg(bb, 0x230c, 0xffffff, 0xf60f6e, 0); halbb_fw_set_reg(bb, 0x2310, 0xffffff, 0xfd8f92, 0); halbb_fw_set_reg(bb, 0x2314, 0xffffff, 0x2d011, 0); halbb_fw_set_reg(bb, 0x2318, 0xffffff, 0x1c02c, 0); halbb_fw_set_reg(bb, 0x231c, 0xffffff, 0xfff00a, 0); } else { halbb_fw_set_reg(bb, 0x2300, 0xffffff, 0x3d23ff, 0); halbb_fw_set_reg(bb, 0x2304, 0xffffff, 0x29b354, 0); halbb_fw_set_reg(bb, 0x2308, 0xffffff, 0xfc1c8, 0); halbb_fw_set_reg(bb, 0x230c, 0xffffff, 0xfdb053, 0); halbb_fw_set_reg(bb, 0x2310, 0xffffff, 0xf86f9a, 0); halbb_fw_set_reg(bb, 0x2314, 0xffffff, 0xfaef92, 0); halbb_fw_set_reg(bb, 0x2318, 0xffffff, 0xfe5fcc, 0); halbb_fw_set_reg(bb, 0x231c, 0xffffff, 0xffdff5, 0); } /* === Set Gain Error === */ halbb_fwofld_set_gain_error_8852b(bb, central_ch); /* === Set Efuse === */ halbb_fwofld_set_efuse_8852b(bb, central_ch, HW_PHY_0); /* === Set RXSC RPL Comp === */ halbb_fwofld_set_rxsc_rpl_comp_8852b(bb, central_ch); } /* === Set Ch idx report in phy-sts === */ halbb_fw_set_reg_cmn(bb, 0x0734, 0x0ff0000, central_ch, phy_idx, 0); bb->bb_ch_i.rf_central_ch_cfg = central_ch; BB_DBG(bb, DBG_PHY_CONFIG, "[Switch CH Success] CH: %d for PHY%d\n", central_ch, phy_idx); return true; } void halbb_fwofld_ctrl_cck_en_8852b(struct bb_info *bb, bool cck_en, enum phl_phy_idx phy_idx) { if (cck_en) { //halbb_set_reg(bb, 0x2300, BIT(27), 0); halbb_fw_set_reg(bb, 0x700, BIT(5), 1, 0); halbb_fw_set_reg(bb, 0x2344, BIT(31), 0, 0); } else { //halbb_set_reg(bb, 0x2300, BIT(27), 1); halbb_fw_set_reg(bb, 0x700, BIT(5), 0, 0); halbb_fw_set_reg(bb, 0x2344, BIT(31), 1, 0); } BB_DBG(bb, DBG_PHY_CONFIG, "[CCK Enable for PHY%d]\n", phy_idx); } bool halbb_fwofld_ctrl_bw_ch_8852b(struct bb_info *bb, u8 pri_ch, u8 central_ch, enum channel_width bw, enum band_type band, enum phl_phy_idx phy_idx) { bool rpt = true; bool cck_en = false; u8 pri_ch_idx = 0; bool is_2g_ch; is_2g_ch = (band == BAND_ON_24G) ? true : false; /*==== [Set pri_ch idx] ====*/ if (central_ch <= 14) { #ifdef BANDEDGE_FILTER_CFG_FOR_ULOFDMA /*==== [UL-OFDMA 2x 1p6 Tx WA] ====*/ halbb_fw_set_reg(bb, 0x4498, BIT(30), 1, 0); #endif // === 2G === // switch (bw) { case CHANNEL_WIDTH_20: break; case CHANNEL_WIDTH_40: pri_ch_idx = pri_ch > central_ch ? 1 : 2; break; default: break; } /*==== [CCK SCO Compesate] ====*/ rpt &= halbb_fwofld_ctrl_sco_cck_8852b(bb, pri_ch); cck_en = true; } else { // === 5G === // switch (bw) { case CHANNEL_WIDTH_20: #ifdef BANDEDGE_FILTER_CFG_FOR_ULOFDMA /*==== [UL-OFDMA 2x 1p6 Tx WA] ====*/ halbb_fw_set_reg(bb, 0x4498, BIT(30), 1, 0); #endif break; case CHANNEL_WIDTH_40: case CHANNEL_WIDTH_80: if (pri_ch > central_ch) pri_ch_idx = (pri_ch - central_ch) >> 1; else pri_ch_idx = ((central_ch - pri_ch) >> 1) + 1; #ifdef BANDEDGE_FILTER_CFG_FOR_ULOFDMA /*==== [UL-OFDMA 2x 1p6 Tx WA] ====*/ halbb_fw_set_reg(bb, 0x4498, BIT(30), 0, 0); #endif break; default: break; } cck_en = false; } /*==== [Switch CH] ====*/ rpt &= halbb_fwofld_ctrl_ch_8852b(bb, central_ch, band, phy_idx); /*==== [Switch BW] ====*/ rpt &= halbb_fwofld_ctrl_bw_8852b(bb, pri_ch_idx, bw, phy_idx); /*==== [CCK Enable / Disable] ====*/ halbb_fwofld_ctrl_cck_en_8852b(bb, cck_en, phy_idx); /*==== [Spur elimination] ====*/ //TBD /*==== [BTG Ctrl] ====*/ if (is_2g_ch && ((bb->rx_path == RF_PATH_B) || (bb->rx_path == RF_PATH_AB))){ halbb_fwofld_ctrl_btg_8852b(bb, true); } else if (is_2g_ch && (bb->rx_path == RF_PATH_A)) { halbb_fwofld_ctrl_btg_8852b(bb, false); } else { // Path A halbb_fw_set_reg(bb, 0x4738, BIT(19), 0x0, 0); halbb_fw_set_reg(bb, 0x4738, BIT(22), 0x0, 0); // Path B halbb_fw_set_reg(bb, 0x4AA4, BIT(19), 0x0, 0); halbb_fw_set_reg(bb, 0x4AA4, BIT(22), 0x0, 0); // Ignore Grant BT by PMAC Setting halbb_fw_set_reg(bb, 0x980, 0x1e0000, 0xf, 0); // Reset BT share halbb_fw_set_reg(bb, 0x49C4, BIT(14), 0x0, 0); halbb_fw_set_reg(bb, 0x49C0, 0x3c00000, 0x0, 0); /* To avoid abnormal 1R CCA without BT, set rtl only 0xc6c[21] = 0x1 */ halbb_fw_set_reg(bb, 0x4420, BIT(31), 0x0, 0); halbb_fw_set_reg(bb, 0xc6c, BIT(21), 0x0, 0); } /* Dynamic 5M Mask Setting */ halbb_fwofld_5m_mask_8852b(bb, pri_ch, bw, phy_idx); /*==== [BB reset] ====*/ halbb_fwofld_bb_reset_all_8852b(bb, phy_idx); return rpt; } void halbb_fwofld_set_efuse_8852b(struct bb_info *bb, u8 central_ch, enum phl_phy_idx phy_idx) { u8 band; u8 gain_val = 0; s32 hidden_efuse = 0, normal_efuse = 0, normal_efuse_cck = 0; s32 tmp = 0; u8 path = 0; u32 gain_err_addr[2] = {0x4ACC, 0x4AD8}; //Wait for Bcut Def BB_DBG(bb, DBG_PHY_CONFIG, "<====== %s ======>\n", __func__); // 2G Band: (0) // 5G Band: (1):Low, (2): Mid, (3):High if (central_ch >= 0 && central_ch <= 14) band = 0; else if (central_ch >= 36 && central_ch <= 64) band = 1; else if (central_ch >= 100 && central_ch <= 144) band = 2; else if (central_ch >= 149 && central_ch <= 177) band = 3; else band = 0; // === [Set hidden efuse] === // if (bb->bb_efuse_i.hidden_efuse_check) { for (path = RF_PATH_A; path < BB_PATH_MAX_8852B; path++) { gain_val = bb->bb_efuse_i.gain_cs[path][band] << 2; halbb_fw_set_reg(bb, gain_err_addr[path], 0xff, gain_val, 0); } BB_DBG(bb, DBG_PHY_CONFIG, "[Efuse] Hidden efuse dynamic setting!!\n"); } else { BB_DBG(bb, DBG_PHY_CONFIG, "[Efuse] Values of hidden efuse are all 0xff, bypass dynamic setting!!\n"); } // === [Set normal efuse] === // if (bb->bb_efuse_i.normal_efuse_check) { if ((bb->rx_path == RF_PATH_A) || (bb->rx_path == RF_PATH_AB)) { normal_efuse = bb->bb_efuse_i.gain_offset[RF_PATH_A][band + 1]; normal_efuse_cck = bb->bb_efuse_i.gain_offset[RF_PATH_A][0]; } else if (bb->rx_path == RF_PATH_B) { normal_efuse = bb->bb_efuse_i.gain_offset[RF_PATH_B][band + 1]; normal_efuse_cck = bb->bb_efuse_i.gain_offset[RF_PATH_B][0]; } normal_efuse *= (-1); normal_efuse_cck *= (-1); // OFDM normal efuse // r_1_rpl_bias_comp tmp = (normal_efuse << 4) + bb->bb_efuse_i.efuse_ofst; halbb_fw_set_reg_cmn(bb, 0x49B0, 0xff, (tmp & 0xff), phy_idx, 0); // r_tb_rssi_bias_comp tmp = (normal_efuse << 4) + bb->bb_efuse_i.efuse_ofst_tb; halbb_fw_set_reg_cmn(bb, 0x4A00, 0xff, (tmp & 0xff), phy_idx, 0); // CCK normal efuse if (band == 0) { tmp = (normal_efuse_cck << 3) + (bb->bb_efuse_i.efuse_ofst >>1); halbb_fw_set_reg(bb, 0x23ac, 0x7f, (tmp & 0x7f), 0); } BB_DBG(bb, DBG_PHY_CONFIG, "[Efuse] Normal efuse dynamic setting!!\n"); } else { BB_DBG(bb, DBG_PHY_CONFIG, "[Efuse] Values of normal efuse are all 0xff, bypass dynamic setting!!\n"); } } void halbb_fwofld_set_gain_error_8852b(struct bb_info *bb, u8 central_ch) { struct bb_gain_info *gain = &bb->bb_gain_i; u8 band; u8 path = 0, lna_idx = 0, tia_idx = 0; s32 tmp = 0; u32 lna_gain_g[BB_PATH_MAX_8852B][7] = {{0x4678, 0x4678, 0x467C, 0x467C, 0x467C, 0x467C, 0x4680}, {0x475C, 0x475C, 0x4760, 0x4760, 0x4760, 0x4760, 0x4764}}; u32 lna_gain_a[BB_PATH_MAX_8852B][7] = {{0x45DC, 0x45DC, 0x4660, 0x4660, 0x4660, 0x4660, 0x4664}, {0x4740, 0x4740, 0x4744, 0x4744, 0x4744, 0x4744, 0x4748}}; u32 lna_gain_mask[7] = {0x00ff0000, 0xff000000, 0x000000ff, 0x0000ff00, 0x00ff0000, 0xff000000, 0x000000ff}; u32 tia_gain_g[BB_PATH_MAX_8852B][2] = {{0x4680, 0x4680}, {0x4764, 0x4764}}; u32 tia_gain_a[BB_PATH_MAX_8852B][2] = {{0x4664, 0x4664}, {0x4748, 0x4748}}; u32 tia_gain_mask[2] = {0x00ff0000, 0xff000000}; BB_DBG(bb, DBG_PHY_CONFIG, "<====== %s ======>\n", __func__); // 2G Band: (0) // 5G Band: (1):Low, (2): Mid, (3):High if (central_ch >= 0 && central_ch <= 14) band = 0; else if (central_ch >= 36 && central_ch <= 64) band = 1; else if (central_ch >= 100 && central_ch <= 144) band = 2; else if (central_ch >= 149 && central_ch <= 177) band = 3; else band = 0; for (path = RF_PATH_A; path < BB_PATH_MAX_8852B; path++) { for (lna_idx = 0; lna_idx < 7; lna_idx++) { if (central_ch >= 0 && central_ch <= 14) { tmp = gain->lna_gain[band][path][lna_idx]; halbb_fw_set_reg(bb, lna_gain_g[path][lna_idx], lna_gain_mask[lna_idx], tmp, 0); } else { tmp = gain->lna_gain[band][path][lna_idx]; halbb_fw_set_reg(bb, lna_gain_a[path][lna_idx], lna_gain_mask[lna_idx], tmp, 0); } } for (tia_idx = 0; tia_idx < 2; tia_idx++) { if (central_ch >= 0 && central_ch <= 14) { tmp = gain->tia_gain[band][path][tia_idx]; halbb_fw_set_reg(bb, tia_gain_g[path][tia_idx], tia_gain_mask[tia_idx], tmp, 0); } else { tmp = gain->tia_gain[band][path][tia_idx]; halbb_fw_set_reg(bb, tia_gain_a[path][tia_idx], tia_gain_mask[tia_idx], tmp, 0); } } } } void halbb_fwofld_set_rxsc_rpl_comp_8852b(struct bb_info *bb, u8 central_ch) { struct bb_gain_info *gain = &bb->bb_gain_i; u8 band; u8 path = 0; u8 i = 0; u8 rxsc = 0; s8 ofst = 0; s8 bw20_avg = 0; s8 bw40_avg = 0, bw40_avg_1 = 0, bw40_avg_2 = 0; s8 bw80_avg = 0; s8 bw80_avg_1 = 0, bw80_avg_2 = 0, bw80_avg_3 = 0, bw80_avg_4 = 0; s8 bw80_avg_9 = 0, bw80_avg_10 = 0; u32 tmp_val1 = 0, tmp_val2 = 0, tmp_val3 = 0; BB_DBG(bb, DBG_PHY_CONFIG, "<====== %s ======>\n", __func__); if (central_ch >= 0 && central_ch <= 14) { band = 0; } else if (central_ch >= 36 && central_ch <= 64) { band = 1; } else if (central_ch >= 100 && central_ch <= 144) { band = 2; } else if (central_ch >= 149 && central_ch <= 177) { band = 3; } else { band = 0; } //20M RPL bw20_avg = (gain->rpl_ofst_20[band][RF_PATH_A] + gain->rpl_ofst_20[band][RF_PATH_B]) >> 1; tmp_val1 |= (((u32)bw20_avg & 0xff) << 8); //40M RPL bw40_avg = (gain->rpl_ofst_40[band][RF_PATH_A][0] + gain->rpl_ofst_40[band][RF_PATH_B][0]) >> 1; tmp_val1 |= (((u32)bw40_avg & 0xff) << 16); bw40_avg_1 = (gain->rpl_ofst_40[band][RF_PATH_A][1] + gain->rpl_ofst_40[band][RF_PATH_B][1]) >> 1; tmp_val1 |= (((u32)bw40_avg_1 & 0xff) << 24); bw40_avg_2 = (gain->rpl_ofst_40[band][RF_PATH_A][2] + gain->rpl_ofst_40[band][RF_PATH_B][2]) >> 1; tmp_val2 |= ((u32)bw40_avg_2 & 0xff); //80M RPL bw80_avg = (gain->rpl_ofst_80[band][RF_PATH_A][0] + gain->rpl_ofst_80[band][RF_PATH_B][0]) >> 1; tmp_val2 |= ((u32)(bw80_avg & 0xff) << 8); bw80_avg_1 = (gain->rpl_ofst_80[band][RF_PATH_A][1] + gain->rpl_ofst_80[band][RF_PATH_B][1]) >> 1; tmp_val2 |= (((u32)bw80_avg_1 & 0xff) << 16); bw80_avg_10 = (gain->rpl_ofst_80[band][RF_PATH_A][10] + gain->rpl_ofst_80[band][RF_PATH_B][10]) >> 1; tmp_val2 |= (((u32)bw80_avg_10 & 0xff) << 24); bw80_avg_2 = (gain->rpl_ofst_80[band][RF_PATH_A][2] + gain->rpl_ofst_80[band][RF_PATH_B][2]) >> 1; tmp_val3 |= ((u32)bw80_avg_2 & 0xff); bw80_avg_3 = (gain->rpl_ofst_80[band][RF_PATH_A][3] + gain->rpl_ofst_80[band][RF_PATH_B][3]) >> 1; tmp_val3 |= (((u32)bw80_avg_3 & 0xff) << 8); bw80_avg_4 = (gain->rpl_ofst_80[band][RF_PATH_A][4] + gain->rpl_ofst_80[band][RF_PATH_B][4]) >> 1; tmp_val3 |= (((u32)bw80_avg_4 & 0xff) << 16); bw80_avg_9 = (gain->rpl_ofst_80[band][RF_PATH_A][9] + gain->rpl_ofst_80[band][RF_PATH_B][9]) >> 1; tmp_val3 |= (((u32)bw80_avg_9 & 0xff) << 24); BB_DBG(bb, DBG_PHY_CONFIG, "[20M RPL] gain ofst = 0x%2x\n", bw20_avg&0xff); BB_DBG(bb, DBG_PHY_CONFIG, "[40M RPL] gain ofst = 0x%2x, 0x%2x, 0x%2x\n", bw40_avg&0xff, bw40_avg_1&0xff, bw40_avg_2&0xff); BB_DBG(bb, DBG_PHY_CONFIG, "[80M RPL] gain ofst = 0x%2x, 0x%2x, 0x%2x, 0x%2x, 0x%2x, 0x%2x, 0x%2x\n", bw80_avg&0xff,bw80_avg_1&0xff,bw80_avg_2&0xff,bw80_avg_3&0xff,bw80_avg_4&0xff,bw80_avg_9&0xff,bw80_avg_10&0xff); BB_DBG(bb, DBG_PHY_CONFIG, "tmp1 = 0x%x, tmp2 = 0x%x, tmp3 = 0x%x\n", tmp_val1, tmp_val2, tmp_val3); halbb_fw_set_reg(bb, 0x49b0, 0xffffff00, tmp_val1 >> 8, 0); halbb_fw_set_reg(bb, 0x4a00, 0xffffff00, tmp_val1 >> 8, 0); halbb_fw_set_reg(bb, 0x49b4, MASKDWORD, tmp_val2, 0); halbb_fw_set_reg(bb, 0x4a04, MASKDWORD, tmp_val2, 0); halbb_fw_set_reg(bb, 0x49b8, MASKDWORD, tmp_val3, 0); halbb_fw_set_reg(bb, 0x4a08, MASKDWORD, tmp_val3, 0); } #endif #endif