mwifiex/mxm_wifiex/wlan_src/mlan/mlan_cfp.c

3725 lines
116 KiB
C
Raw Normal View History

/**
* @file mlan_cfp.c
*
* @brief This file contains WLAN client mode channel, frequency and power
* related code
*
*
* Copyright 2009-2021 NXP
*
* This software file (the File) is distributed by NXP
* under the terms of the GNU General Public License Version 2, June 1991
* (the License). You may use, redistribute and/or modify the File in
* accordance with the terms and conditions of the License, a copy of which
* is available by writing to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA or on the
* worldwide web at http://www.gnu.org/licenses/old-licenses/gpl-2.0.txt.
*
* THE FILE IS DISTRIBUTED AS-IS, WITHOUT WARRANTY OF ANY KIND, AND THE
* IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE
* ARE EXPRESSLY DISCLAIMED. The License provides additional details about
* this warranty disclaimer.
*
*/
/*************************************************************
* Change Log:
* 04/16/2009: initial version
************************************************************/
#include "mlan.h"
#include "mlan_util.h"
#include "mlan_fw.h"
#include "mlan_join.h"
#include "mlan_main.h"
/********************************************************
* Local Variables
********************************************************/
/** 100mW */
#define WLAN_TX_PWR_DEFAULT 20
/** 100mW */
#define WLAN_TX_PWR_00_DEFAULT 20
/** 100mW */
#define WLAN_TX_PWR_US_DEFAULT 20
/** 100mW */
#define WLAN_TX_PWR_JP_BG_DEFAULT 20
/** 200mW */
#define WLAN_TX_PWR_JP_A_DEFAULT 23
/** 100mW */
#define WLAN_TX_PWR_EMEA_DEFAULT 20
/** 2000mW */
#define WLAN_TX_PWR_CN_2000MW 33
/** 200mW */
#define WLAN_TX_PWR_200MW 23
/** 1000mW */
#define WLAN_TX_PWR_1000MW 30
/** 250mW */
#define WLAN_TX_PWR_250MW 24
/** Region code mapping */
typedef struct _country_code_mapping {
/** Region */
t_u8 country_code[COUNTRY_CODE_LEN];
/** Code for B/G CFP table */
t_u8 cfp_code_bg;
/** Code for A CFP table */
t_u8 cfp_code_a;
} country_code_mapping_t;
#define EU_CFP_CODE_BG 0x30
#define EU_CFP_CODE_A 0x30
/** Region code mapping table */
static country_code_mapping_t country_code_mapping[] = {
{"WW", 0x00, 0x00}, /* World */
{"US", 0x10, 0x10}, /* US FCC */
{"CA", 0x10, 0x20}, /* IC Canada */
{"SG", 0x10, 0x10}, /* Singapore */
{"EU", 0x30, 0x30}, /* ETSI */
{"AU", 0x30, 0x30}, /* Australia */
{"KR", 0x30, 0x30}, /* Republic Of Korea */
{"JP", 0xFF, 0x40}, /* Japan */
{"CN", 0x30, 0x50}, /* China */
{"BR", 0x01, 0x09}, /* Brazil */
{"RU", 0x30, 0x0f}, /* Russia */
{"IN", 0x10, 0x06}, /* India */
{"MY", 0x30, 0x06}, /* Malaysia */
{"NZ", 0x30, 0x30}, /* New Zeland */
{"MX", 0x10, 0x07}, /* Mexico */
};
/** Country code for ETSI */
static t_u8 eu_country_code_table[][COUNTRY_CODE_LEN] = {
"AL", "AD", "AT", "AU", "BY", "BE", "BA", "BG", "HR", "CY", "CZ", "DK",
"EE", "FI", "FR", "MK", "DE", "GR", "HU", "IS", "IE", "IT", "KR", "LV",
"LI", "LT", "LU", "MT", "MD", "MC", "ME", "NL", "NO", "PL", "RO", "RU",
"SM", "RS", "SI", "SK", "ES", "SE", "CH", "TR", "UA", "UK", "GB", "NZ"};
/**
* The structure for Channel-Frequency-Power table
*/
typedef struct _cfp_table {
/** Region or Code */
t_u8 code;
/** Frequency/Power */
chan_freq_power_t *cfp;
/** No of CFP flag */
int cfp_no;
} cfp_table_t;
/* Format { Channel, Frequency (MHz), MaxTxPower } */
/** Band : 'B/G', Region: World Wide Safe */
static chan_freq_power_t channel_freq_power_00_BG[] = {
{1, 2412, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x1c, 0, 0}},
{2, 2417, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x1c, 0, 0}},
{3, 2422, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x1c, 0, 0}},
{4, 2427, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x1c, 0, 0}},
{5, 2432, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x1c, 0, 0}},
{6, 2437, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x1c, 0, 0}},
{7, 2442, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x1c, 0, 0}},
{8, 2447, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x1c, 0, 0}},
{9, 2452, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x1c, 0, 0}},
{10, 2457, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x1c, 0, 0}},
{11, 2462, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x1c, 0, 0}},
{12, 2467, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x1d, 0, 0}},
{13, 2472, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x1d, 0, 0}}};
/* Format { Channel, Frequency (MHz), MaxTxPower } */
/** Band: 'B/G', Region: USA FCC/Canada IC */
static chan_freq_power_t channel_freq_power_US_BG[] = {
{1, 2412, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x1c, 0, 0}},
{2, 2417, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x1c, 0, 0}},
{3, 2422, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x1c, 0, 0}},
{4, 2427, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x1c, 0, 0}},
{5, 2432, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x1c, 0, 0}},
{6, 2437, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x1c, 0, 0}},
{7, 2442, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x1c, 0, 0}},
{8, 2447, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x1c, 0, 0}},
{9, 2452, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x1c, 0, 0}},
{10, 2457, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x1c, 0, 0}},
{11, 2462, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x1c, 0, 0}}};
/** Band: 'B/G', Region: Europe ETSI/China */
static chan_freq_power_t channel_freq_power_EU_BG[] = {
{1, 2412, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x1c, 0, 0}},
{2, 2417, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x1c, 0, 0}},
{3, 2422, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x1c, 0, 0}},
{4, 2427, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x1c, 0, 0}},
{5, 2432, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x1c, 0, 0}},
{6, 2437, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x1c, 0, 0}},
{7, 2442, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x1c, 0, 0}},
{8, 2447, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x1c, 0, 0}},
{9, 2452, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x1c, 0, 0}},
{10, 2457, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x1c, 0, 0}},
{11, 2462, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x1c, 0, 0}},
{12, 2467, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x1d, 0, 0}},
{13, 2472, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x1d, 0, 0}}};
/** Band: 'B/G', Region: Japan */
static chan_freq_power_t channel_freq_power_JPN41_BG[] = {
{1, 2412, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{2, 2417, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{3, 2422, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{4, 2427, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{5, 2432, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{6, 2437, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{7, 2442, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{8, 2447, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{9, 2452, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{10, 2457, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{11, 2462, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{12, 2467, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1d, 0, 0}},
{13, 2472, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1d, 0, 0}}};
/** Band: 'B/G', Region: Japan */
static chan_freq_power_t channel_freq_power_JPN40_BG[] = {
{14, 2484, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1d, 0, 0}}};
/** Band: 'B/G', Region: Japan */
static chan_freq_power_t channel_freq_power_JPNFE_BG[] = {
{1, 2412, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{2, 2417, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{3, 2422, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{4, 2427, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{5, 2432, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{6, 2437, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{7, 2442, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{8, 2447, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{9, 2452, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{10, 2457, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{11, 2462, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{12, 2467, WLAN_TX_PWR_JP_BG_DEFAULT, MTRUE, {0x1d, 0, 0}},
{13, 2472, WLAN_TX_PWR_JP_BG_DEFAULT, MTRUE, {0x1d, 0, 0}}};
/** Band : 'B/G', Region: Brazil */
static chan_freq_power_t channel_freq_power_BR_BG[] = {
{1, 2412, WLAN_TX_PWR_1000MW, MFALSE, {0x1c, 0, 0}},
{2, 2417, WLAN_TX_PWR_1000MW, MFALSE, {0x1c, 0, 0}},
{3, 2422, WLAN_TX_PWR_1000MW, MFALSE, {0x1c, 0, 0}},
{4, 2427, WLAN_TX_PWR_1000MW, MFALSE, {0x1c, 0, 0}},
{5, 2432, WLAN_TX_PWR_1000MW, MFALSE, {0x1c, 0, 0}},
{6, 2437, WLAN_TX_PWR_1000MW, MFALSE, {0x1c, 0, 0}},
{7, 2442, WLAN_TX_PWR_1000MW, MFALSE, {0x1c, 0, 0}},
{8, 2447, WLAN_TX_PWR_1000MW, MFALSE, {0x1c, 0, 0}},
{9, 2452, WLAN_TX_PWR_1000MW, MFALSE, {0x1c, 0, 0}},
{10, 2457, WLAN_TX_PWR_1000MW, MFALSE, {0x1c, 0, 0}},
{11, 2462, WLAN_TX_PWR_1000MW, MFALSE, {0x1c, 0, 0}},
{12, 2467, WLAN_TX_PWR_1000MW, MFALSE, {0x1d, 0, 0}},
{13, 2472, WLAN_TX_PWR_1000MW, MFALSE, {0x1d, 0, 0}}};
/** Band : 'B/G', Region: Special */
static chan_freq_power_t channel_freq_power_SPECIAL_BG[] = {
{1, 2412, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{2, 2417, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{3, 2422, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{4, 2427, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{5, 2432, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{6, 2437, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{7, 2442, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{8, 2447, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{9, 2452, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{10, 2457, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{11, 2462, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1c, 0, 0}},
{12, 2467, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1d, 0, 0}},
{13, 2472, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1d, 0, 0}},
{14, 2484, WLAN_TX_PWR_JP_BG_DEFAULT, MFALSE, {0x1d, 0, 0}}};
/**
* The 2.4GHz CFP tables
*/
static cfp_table_t cfp_table_BG[] = {
{
0x01, /* Brazil */
channel_freq_power_BR_BG,
NELEMENTS(channel_freq_power_BR_BG),
},
{
0x00, /* World FCC */
channel_freq_power_00_BG,
NELEMENTS(channel_freq_power_00_BG),
},
{
0x10, /* US FCC */
channel_freq_power_US_BG,
NELEMENTS(channel_freq_power_US_BG),
},
{
0x20, /* CANADA IC */
channel_freq_power_US_BG,
NELEMENTS(channel_freq_power_US_BG),
},
{
0x30, /* EU */
channel_freq_power_EU_BG,
NELEMENTS(channel_freq_power_EU_BG),
},
{
0x40, /* JAPAN */
channel_freq_power_JPN40_BG,
NELEMENTS(channel_freq_power_JPN40_BG),
},
{
0x41, /* JAPAN */
channel_freq_power_JPN41_BG,
NELEMENTS(channel_freq_power_JPN41_BG),
},
{
0x50, /* China */
channel_freq_power_EU_BG,
NELEMENTS(channel_freq_power_EU_BG),
},
{
0xfe, /* JAPAN */
channel_freq_power_JPNFE_BG,
NELEMENTS(channel_freq_power_JPNFE_BG),
},
{
0xff, /* Special */
channel_freq_power_SPECIAL_BG,
NELEMENTS(channel_freq_power_SPECIAL_BG),
},
/* Add new region here */
};
/** Number of the CFP tables for 2.4GHz */
#define MLAN_CFP_TABLE_SIZE_BG (NELEMENTS(cfp_table_BG))
/* Format { Channel, Frequency (MHz), MaxTxPower, DFS } */
/** Band: 'A', Region: World Wide Safe */
static chan_freq_power_t channel_freq_power_00_A[] = {
{36, 5180, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x10, 0, 0}},
{40, 5200, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x10, 0, 0}},
{44, 5220, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x10, 0, 0}},
{48, 5240, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x10, 0, 0}},
{52, 5260, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{56, 5280, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{60, 5300, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{64, 5320, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{100, 5500, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{104, 5520, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{108, 5540, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{112, 5560, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{116, 5580, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{120, 5600, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{124, 5620, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{128, 5640, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{132, 5660, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{136, 5680, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{140, 5700, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{144, 5720, WLAN_TX_PWR_00_DEFAULT, MTRUE, {0x13, 0, 0}},
{149, 5745, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x10, 0, 0}},
{153, 5765, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x10, 0, 0}},
{157, 5785, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x10, 0, 0}},
{161, 5805, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x10, 0, 0}},
{165, 5825, WLAN_TX_PWR_00_DEFAULT, MFALSE, {0x10, 0, 0}}};
/* Format { Channel, Frequency (MHz), MaxTxPower, DFS } */
/** Band: 'A', Region: USA FCC */
static chan_freq_power_t channel_freq_power_A[] = {
{36, 5180, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{40, 5200, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{44, 5220, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{48, 5240, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{52, 5260, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{56, 5280, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{60, 5300, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{64, 5320, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{100, 5500, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{104, 5520, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{108, 5540, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{112, 5560, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{116, 5580, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{120, 5600, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{124, 5620, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{128, 5640, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{132, 5660, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{136, 5680, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{140, 5700, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{144, 5720, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{149, 5745, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{153, 5765, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{157, 5785, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{161, 5805, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{165, 5825, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{169, 5845, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{173, 5865, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{177, 5885, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}}};
/** Band: 'A', Region: Canada IC */
static chan_freq_power_t channel_freq_power_CAN_A[] = {
{36, 5180, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{40, 5200, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{44, 5220, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{48, 5240, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{52, 5260, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{56, 5280, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{60, 5300, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{64, 5320, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{100, 5500, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{104, 5520, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{108, 5540, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{112, 5560, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{116, 5580, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{132, 5660, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{136, 5680, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{140, 5700, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{144, 5720, WLAN_TX_PWR_US_DEFAULT, MTRUE, {0x13, 0, 0}},
{149, 5745, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{153, 5765, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{157, 5785, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{161, 5805, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}},
{165, 5825, WLAN_TX_PWR_US_DEFAULT, MFALSE, {0x10, 0, 0}}};
/** Band: 'A', Region: Europe ETSI */
static chan_freq_power_t channel_freq_power_EU_A[] = {
{36, 5180, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{40, 5200, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{44, 5220, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{48, 5240, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{52, 5260, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{56, 5280, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{60, 5300, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{64, 5320, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{100, 5500, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{104, 5520, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{108, 5540, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{112, 5560, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{116, 5580, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{120, 5600, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{124, 5620, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{128, 5640, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{132, 5660, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{136, 5680, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{140, 5700, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{149, 5745, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{153, 5765, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{157, 5785, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{161, 5805, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{165, 5825, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}}};
/** Band: 'A', Region: Japan */
static chan_freq_power_t channel_freq_power_JPN_A[] = {
{36, 5180, WLAN_TX_PWR_JP_A_DEFAULT, MFALSE, {0x10, 0, 0}},
{40, 5200, WLAN_TX_PWR_JP_A_DEFAULT, MFALSE, {0x10, 0, 0}},
{44, 5220, WLAN_TX_PWR_JP_A_DEFAULT, MFALSE, {0x10, 0, 0}},
{48, 5240, WLAN_TX_PWR_JP_A_DEFAULT, MFALSE, {0x10, 0, 0}},
{52, 5260, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{56, 5280, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{60, 5300, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{64, 5320, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{100, 5500, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{104, 5520, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{108, 5540, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{112, 5560, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{116, 5580, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{120, 5600, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{124, 5620, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{128, 5640, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{132, 5660, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{136, 5680, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{140, 5700, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}},
{144, 5720, WLAN_TX_PWR_JP_A_DEFAULT, MTRUE, {0x13, 0, 0}}};
/** Band: 'A', Region: China */
static chan_freq_power_t channel_freq_power_CN_A[] = {
{36, 5180, WLAN_TX_PWR_200MW, MFALSE, {0x10, 0, 0}},
{40, 5200, WLAN_TX_PWR_200MW, MFALSE, {0x10, 0, 0}},
{44, 5220, WLAN_TX_PWR_200MW, MFALSE, {0x10, 0, 0}},
{48, 5240, WLAN_TX_PWR_200MW, MFALSE, {0x10, 0, 0}},
{52, 5260, WLAN_TX_PWR_200MW, MTRUE, {0x13, 0, 0}},
{56, 5280, WLAN_TX_PWR_200MW, MTRUE, {0x13, 0, 0}},
{60, 5300, WLAN_TX_PWR_200MW, MTRUE, {0x13, 0, 0}},
{64, 5320, WLAN_TX_PWR_200MW, MTRUE, {0x13, 0, 0}},
{149, 5745, WLAN_TX_PWR_CN_2000MW, MFALSE, {0x10, 0, 0}},
{153, 5765, WLAN_TX_PWR_CN_2000MW, MFALSE, {0x10, 0, 0}},
{157, 5785, WLAN_TX_PWR_CN_2000MW, MFALSE, {0x10, 0, 0}},
{161, 5805, WLAN_TX_PWR_CN_2000MW, MFALSE, {0x10, 0, 0}},
{165, 5825, WLAN_TX_PWR_CN_2000MW, MFALSE, {0x10, 0, 0}}};
/** Band: 'A', NULL */
static chan_freq_power_t channel_freq_power_NULL_A[] = {};
/** Band: 'A', Region: Spain/Austria/Brazil */
static chan_freq_power_t channel_freq_power_SPN2_A[] = {
{36, 5180, WLAN_TX_PWR_200MW, MFALSE, {0x10, 0, 0}},
{40, 5200, WLAN_TX_PWR_200MW, MFALSE, {0x10, 0, 0}},
{44, 5220, WLAN_TX_PWR_200MW, MFALSE, {0x10, 0, 0}},
{48, 5240, WLAN_TX_PWR_200MW, MFALSE, {0x10, 0, 0}},
{52, 5260, WLAN_TX_PWR_200MW, MTRUE, {0x13, 0, 0}},
{56, 5280, WLAN_TX_PWR_200MW, MTRUE, {0x13, 0, 0}},
{60, 5300, WLAN_TX_PWR_200MW, MTRUE, {0x13, 0, 0}},
{64, 5320, WLAN_TX_PWR_200MW, MTRUE, {0x13, 0, 0}}};
/** Band: 'A', Region: Brazil */
static chan_freq_power_t channel_freq_power_BR1_A[] = {
{100, 5500, WLAN_TX_PWR_250MW, MTRUE, {0x13, 0, 0}},
{104, 5520, WLAN_TX_PWR_250MW, MTRUE, {0x13, 0, 0}},
{108, 5540, WLAN_TX_PWR_250MW, MTRUE, {0x13, 0, 0}},
{112, 5560, WLAN_TX_PWR_250MW, MTRUE, {0x13, 0, 0}},
{116, 5580, WLAN_TX_PWR_250MW, MTRUE, {0x13, 0, 0}},
{120, 5600, WLAN_TX_PWR_250MW, MTRUE, {0x13, 0, 0}},
{124, 5620, WLAN_TX_PWR_250MW, MTRUE, {0x13, 0, 0}},
{128, 5640, WLAN_TX_PWR_250MW, MTRUE, {0x13, 0, 0}},
{132, 5660, WLAN_TX_PWR_250MW, MTRUE, {0x13, 0, 0}},
{136, 5680, WLAN_TX_PWR_250MW, MTRUE, {0x13, 0, 0}},
{140, 5700, WLAN_TX_PWR_250MW, MTRUE, {0x13, 0, 0}}};
/** Band: 'A', Region: Brazil */
static chan_freq_power_t channel_freq_power_BR2_A[] = {
{149, 5745, WLAN_TX_PWR_1000MW, MFALSE, {0x10, 0, 0}},
{153, 5765, WLAN_TX_PWR_1000MW, MFALSE, {0x10, 0, 0}},
{157, 5785, WLAN_TX_PWR_1000MW, MFALSE, {0x10, 0, 0}},
{161, 5805, WLAN_TX_PWR_1000MW, MFALSE, {0x10, 0, 0}},
{165, 5825, WLAN_TX_PWR_1000MW, MFALSE, {0x10, 0, 0}}};
/** Band: 'A', Region: Russia */
static chan_freq_power_t channel_freq_power_RU_A[] = {
{36, 5180, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{40, 5200, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{44, 5220, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{48, 5240, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{52, 5260, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{56, 5280, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{60, 5300, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{64, 5320, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{132, 5660, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{136, 5680, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{140, 5700, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{149, 5745, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{153, 5765, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{157, 5785, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{161, 5805, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}}};
/** Band: 'A', Region: Mexico */
static chan_freq_power_t channel_freq_power_MX_A[] = {
{36, 5180, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{40, 5200, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{44, 5220, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{48, 5240, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{52, 5260, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{56, 5280, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{60, 5300, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{64, 5320, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{100, 5500, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{104, 5520, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{108, 5540, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{112, 5560, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{116, 5580, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{132, 5660, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{136, 5680, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{140, 5700, WLAN_TX_PWR_EMEA_DEFAULT, MTRUE, {0x13, 0, 0}},
{149, 5745, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{153, 5765, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{157, 5785, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{161, 5805, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}},
{165, 5825, WLAN_TX_PWR_EMEA_DEFAULT, MFALSE, {0x10, 0, 0}}};
/** Band: 'A', Code: 1, Low band (5150-5250 MHz) channels */
static chan_freq_power_t channel_freq_power_low_band[] = {
{36, 5180, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{40, 5200, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{44, 5220, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{48, 5240, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}}};
/** Band: 'A', Code: 2, Lower middle band (5250-5350 MHz) channels */
static chan_freq_power_t channel_freq_power_lower_middle_band[] = {
{52, 5260, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{56, 5280, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{60, 5300, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{64, 5320, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}}};
/** Band: 'A', Code: 3, Upper middle band (5470-5725 MHz) channels */
static chan_freq_power_t channel_freq_power_upper_middle_band[] = {
{100, 5500, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{104, 5520, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{108, 5540, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{112, 5560, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{116, 5580, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{120, 5600, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{124, 5620, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{128, 5640, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{132, 5660, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{136, 5680, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}},
{140, 5700, WLAN_TX_PWR_DEFAULT, MTRUE, {0x13, 0, 0}}};
/** Band: 'A', Code: 4, High band (5725-5850 MHz) channels */
static chan_freq_power_t channel_freq_power_high_band[] = {
{149, 5745, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{153, 5765, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{157, 5785, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{161, 5805, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{165, 5825, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}}};
/** Band: 'A', Code: 5, Low band (5150-5250 MHz) and
* High band (5725-5850 MHz) channels
*/
static chan_freq_power_t channel_freq_power_low_high_band[] = {
{36, 5180, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{40, 5200, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{44, 5220, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{48, 5240, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{149, 5745, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{153, 5765, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{157, 5785, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{161, 5805, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{165, 5825, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}}};
/** Band: 'A', Code: 6, Low band (5150-5250 MHz) and
* mid low (5260-5320) and High band (5725-5850 MHz) channels
*/
static chan_freq_power_t channel_freq_power_low_middle_high_band[] = {
{36, 5180, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{40, 5200, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{44, 5220, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{48, 5240, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{52, 5260, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{56, 5280, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{60, 5300, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{64, 5320, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{149, 5745, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{153, 5765, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{157, 5785, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{161, 5805, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}},
{165, 5825, WLAN_TX_PWR_DEFAULT, MFALSE, {0x10, 0, 0}}};
/**
* The 5GHz CFP tables
*/
static cfp_table_t cfp_table_A[] = {
{0x1, /* Low band (5150-5250 MHz) channels */
channel_freq_power_low_band, NELEMENTS(channel_freq_power_low_band)},
{0x2, /* Lower middle band (5250-5350 MHz) channels */
channel_freq_power_lower_middle_band,
NELEMENTS(channel_freq_power_lower_middle_band)},
{0x3, /* Upper middle band (5470-5725 MHz) channels */
channel_freq_power_upper_middle_band,
NELEMENTS(channel_freq_power_upper_middle_band)},
{0x4, /* High band (5725-5850 MHz) channels */
channel_freq_power_high_band, NELEMENTS(channel_freq_power_high_band)},
{0x5, /* Low band (5150-5250 MHz) and
* High band (5725-5850 MHz) channels
*/
channel_freq_power_low_high_band,
NELEMENTS(channel_freq_power_low_high_band)},
{0x6, /* Low band (5150-5250 MHz)
* Mid band (5260-5320) and
* High band (5725-5850 MHz) channels
*/
channel_freq_power_low_middle_high_band,
NELEMENTS(channel_freq_power_low_middle_high_band)},
{
0x07, /* Mexico */
channel_freq_power_MX_A,
NELEMENTS(channel_freq_power_MX_A),
},
{
0x09, /* SPAIN/Austria/Brazil */
channel_freq_power_SPN2_A,
NELEMENTS(channel_freq_power_SPN2_A),
},
{
0x0c, /* Brazil */
channel_freq_power_BR1_A,
NELEMENTS(channel_freq_power_BR1_A),
},
{
0x0e, /* Brazil */
channel_freq_power_BR2_A,
NELEMENTS(channel_freq_power_BR2_A),
},
{
0x0f, /* Russia */
channel_freq_power_RU_A,
NELEMENTS(channel_freq_power_RU_A),
},
{
0x00, /* World */
channel_freq_power_00_A,
NELEMENTS(channel_freq_power_00_A),
},
{
0x10, /* US FCC */
channel_freq_power_A,
NELEMENTS(channel_freq_power_A),
},
{
0x20, /* CANADA IC */
channel_freq_power_CAN_A,
NELEMENTS(channel_freq_power_CAN_A),
},
{
0x30, /* EU */
channel_freq_power_EU_A,
NELEMENTS(channel_freq_power_EU_A),
},
{
0x40, /* JAPAN */
channel_freq_power_JPN_A,
NELEMENTS(channel_freq_power_JPN_A),
},
{
0x41, /* JAPAN */
channel_freq_power_JPN_A,
NELEMENTS(channel_freq_power_JPN_A),
},
{
0x50, /* China */
channel_freq_power_CN_A,
NELEMENTS(channel_freq_power_CN_A),
},
{
0xfe, /* JAPAN */
channel_freq_power_NULL_A,
NELEMENTS(channel_freq_power_NULL_A),
},
{
0xff, /* Special */
channel_freq_power_JPN_A,
NELEMENTS(channel_freq_power_JPN_A),
},
/* Add new region here */
};
/** Number of the CFP tables for 5GHz */
#define MLAN_CFP_TABLE_SIZE_A (NELEMENTS(cfp_table_A))
enum { RATEID_DBPSK1Mbps, //(0)
RATEID_DQPSK2Mbps, //(1)
RATEID_CCK5_5Mbps, //(2)
RATEID_CCK11Mbps, //(3)
RATEID_CCK22Mbps, //(4)
RATEID_OFDM6Mbps, //(5)
RATEID_OFDM9Mbps, //(6)
RATEID_OFDM12Mbps, //(7)
RATEID_OFDM18Mbps, //(8)
RATEID_OFDM24Mbps, //(9)
RATEID_OFDM36Mbps, //(10)
RATEID_OFDM48Mbps, //(11)
RATEID_OFDM54Mbps, //(12)
RATEID_OFDM72Mbps, //(13)
};
static const t_u8 rateUnit_500Kbps[] = {
(10 / 5), /* 1Mbps */
(20 / 5), /* 2Mbps */
(55 / 5), /* 5.5Mbps */
(110 / 5), /* 11Mbps */
(10 / 5), /* 22Mbps, intentionally set to 1Mbps
* because it's not available
*/
(60 / 5), /* 6Mbps */
(90 / 5), /* 9Mbps */
(120 / 5), /* 12Mbps */
(180 / 5), /* 18Mbps */
(240 / 5), /* 24Mbps */
(360 / 5), /* 36Mbps */
(480 / 5), /* 48Mbps */
(540 / 5), /* 54Mbps */
(60 / 5), /* 72Mbps, intentionally set to 6Mbps
* because it's not available
*/
};
typedef struct _rate_map {
/** Rate, in 0.5Mbps */
t_u32 rate;
/** Mrvl rate id, refer to RATEID_XXX in FW */
t_u32 id;
/** nss: 0-nss1, 1-nss2 */
t_u8 nss;
} rate_map;
/** If user configure to 1x1 or we found peer device only support 1x1,
* then we need skip the nss1 part when map to Mrvl rate.
*/
static const rate_map rate_map_table_2x2[] = {
/* LG <--> Mrvl rate idx */
{2, 0, 0}, // RATEID_DBPSK1Mbps
{4, 1, 0}, // RATEID_DQPSK2Mbps
{11, 2, 0}, // RATEID_CCK5_5Mbps
{22, 3, 0}, // RATEID_CCK11Mbps
{44, 4, 0}, // RATEID_CCK22Mbps
{12, 5, 0}, // RATEID_OFDM6Mbps
{18, 6, 0}, // RATEID_OFDM9Mbps
{24, 7, 0}, // RATEID_OFDM12Mbps
{36, 8, 0}, // RATEID_OFDM18Mbps
{48, 9, 0}, // RATEID_OFDM24Mbps
{72, 10, 0}, // RATEID_OFDM36Mbps
{96, 11, 0}, // RATEID_OFDM48Mbps
{108, 12, 0}, // RATEID_OFDM54Mbps
{144, 13, 0}, // RATEID_OFDM72Mbps
/* HT bw20 <--> Mrvl rate idx - nss2 */
{26, 22, 1}, // RATEID_MCS8_13Mbps
{52, 23, 1}, // RATEID_MCS9_26Mbps
{78, 24, 1}, // RATEID_MCS10_39Mbps
{104, 25, 1}, // RATEID_MCS11_52Mbps
{156, 26, 1}, // RATEID_MCS12_78Mbps
{208, 27, 1}, // RATEID_MCS13_104Mbps
{234, 28, 1}, // RATEID_MCS14_117Mbps
{260, 29, 1}, // RATEID_MCS15_130Mbps
/* HT bw20 <--> Mrvl rate idx - nss1 */
{13, 14, 0}, // RATEID_MCS0_6d5Mbps
{26, 15, 0}, // RATEID_MCS1_13Mbps
{39, 16, 0}, // RATEID_MCS2_19d5Mbps
{52, 17, 0}, // RATEID_MCS3_26Mbps
{78, 18, 0}, // RATEID_MCS4_39Mbps
{104, 19, 0}, // RATEID_MCS5_52Mbps
{117, 20, 0}, // RATEID_MCS6_58d5Mbps
{130, 21, 0}, // RATEID_MCS7_65Mbps
/* HT bw40<--> Mrvl rate idx - nss2 */
{54, 39, 1}, // RATEID_MCS8BW40_27Mbps
{108, 40, 1}, // RATEID_MCS9BW40_54Mbps
{162, 41, 1}, // RATEID_MCS10BW40_81Mbps
{216, 42, 1}, // RATEID_MCS11BW40_108Mbps
{324, 43, 1}, // RATEID_MCS12BW40_162Mbps
{432, 44, 1}, // RATEID_MCS13BW40_216Mbps
{486, 45, 1}, // RATEID_MCS14BW40_243Mbps
{540, 46, 1}, // RATEID_MCS15BW40_270Mbps
/* HT bw40<--> Mrvl rate idx - nss1 */
{12, 30, 0}, // RATEID_MCS32BW40_6Mbps
{27, 31, 0}, // RATEID_MCS0BW40_13d5Mbps
{54, 32, 0}, // RATEID_MCS1BW40_27Mbps
{81, 33, 0}, // RATEID_MCS2BW40_40d5Mbps
{108, 34, 0}, // RATEID_MCS3BW40_54Mbps
{162, 35, 0}, // RATEID_MCS4BW40_81Mbps
{216, 36, 0}, // RATEID_MCS5BW40_108Mbps
{243, 37, 0}, // RATEID_MCS6BW40_121d5Mbps
{270, 38, 0}, // RATEID_MCS7BW40_135Mbps
/* VHT bw20<--> Mrvl rate idx - nss2 */
{26, 57, 1}, // RATEID_VHT_MCS0_2SS_BW20 13 Mbps
{52, 58, 1}, // RATEID_VHT_MCS1_2SS_BW20 26 Mbps
{78, 59, 1}, // RATEID_VHT_MCS2_2SS_BW20 39 Mbps
{104, 60, 1}, // RATEID_VHT_MCS3_2SS_BW20 52 Mbps
{156, 61, 1}, // RATEID_VHT_MCS4_2SS_BW20 78 Mbps
{208, 62, 1}, // RATEID_VHT_MCS5_2SS_BW20 104 Mbps
{234, 63, 1}, // RATEID_VHT_MCS6_2SS_BW20 117 Mbps
{260, 64, 1}, // RATEID_VHT_MCS7_2SS_BW20 130 Mbps
{312, 65, 1}, // RATEID_VHT_MCS8_2SS_BW20 156 Mbps
{0, 66, 1}, // RATEID_VHT_MCS9_2SS_BW20 173.3 Mbps(INVALID)
/* VHT bw20<--> Mrvl rate idx - nss1 */
{13, 47, 0}, // RATEID_VHT_MCS0_1SS_BW20 6.5 Mbps
{26, 48, 0}, // RATEID_VHT_MCS1_1SS_BW20 13 Mbps
{39, 49, 0}, // RATEID_VHT_MCS2_1SS_BW20 19.5 Mbps
{52, 50, 0}, // RATEID_VHT_MCS3_1SS_BW20 26 Mbps
{78, 51, 0}, // RATEID_VHT_MCS4_1SS_BW20 39 Mbps
{104, 52, 0}, // RATEID_VHT_MCS5_1SS_BW20 52 Mbps
{117, 53, 0}, // RATEID_VHT_MCS6_1SS_BW20 58.5 Mbps
{130, 54, 0}, // RATEID_VHT_MCS7_1SS_BW20 65 Mbps
{156, 55, 0}, // RATEID_VHT_MCS8_1SS_BW20 78 Mbps
{0, 56, 0}, // RATEID_VHT_MCS9_1SS_BW20 86.7 Mbps(INVALID)
/* VHT bw40<--> Mrvl rate idx - nss2 */
{54, 77, 1}, // RATEID_VHT_MCS0_2SS_BW40 27 Mbps
{108, 78, 1}, // RATEID_VHT_MCS1_2SS_BW40 54 Mbps
{162, 79, 1}, // RATEID_VHT_MCS2_2SS_BW40 81 Mbps
{216, 80, 1}, // RATEID_VHT_MCS3_2SS_BW40 108 Mbps
{324, 81, 1}, // RATEID_VHT_MCS4_2SS_BW40 162 Mbps
{432, 82, 1}, // RATEID_VHT_MCS5_2SS_BW40 216 Mbps
{486, 83, 1}, // RATEID_VHT_MCS6_2SS_BW40 243 Mbps
{540, 84, 1}, // RATEID_VHT_MCS7_2SS_BW40 270 Mbps
{648, 85, 1}, // RATEID_VHT_MCS8_2SS_BW40 324 Mbps
{720, 86, 1}, // RATEID_VHT_MCS9_2SS_BW40 360 Mbps
/* VHT bw40<--> Mrvl rate idx - nss1 */
{27, 67, 0}, // RATEID_VHT_MCS0_1SS_BW40 13.5 Mbps
{54, 68, 0}, // RATEID_VHT_MCS1_1SS_BW40 27 Mbps
{81, 69, 0}, // RATEID_VHT_MCS2_1SS_BW40 40.5 Mbps
{108, 70, 0}, // RATEID_VHT_MCS3_1SS_BW40 54 Mbps
{162, 71, 0}, // RATEID_VHT_MCS4_1SS_BW40 81 Mbps
{216, 72, 0}, // RATEID_VHT_MCS5_1SS_BW40 108 Mbps
{243, 73, 0}, // RATEID_VHT_MCS6_1SS_BW40 121.5 Mbps
{270, 74, 0}, // RATEID_VHT_MCS7_1SS_BW40 135 Mbps
{324, 75, 0}, // RATEID_VHT_MCS8_1SS_BW40 162 Mbps
{360, 76, 0}, // RATEID_VHT_MCS9_1SS_BW40 180 Mbps
/* VHT bw80<--> Mrvl rate idx - nss2 */
{117, 97, 1}, // RATEID_VHT_MCS0_2SS_BW80 58.5 Mbps
{234, 98, 1}, // RATEID_VHT_MCS1_2SS_BW80 117 Mbps
{350, 99, 1}, // RATEID_VHT_MCS2_2SS_BW80 175 Mbps
{468, 100, 1}, // RATEID_VHT_MCS3_2SS_BW80 234 Mbps
{702, 101, 1}, // RATEID_VHT_MCS4_2SS_BW80 351 Mbps
{936, 102, 1}, // RATEID_VHT_MCS5_2SS_BW80 468 Mbps
{1053, 103, 1}, // RATEID_VHT_MCS6_2SS_BW80 526.5 Mbps
{1170, 104, 1}, // RATEID_VHT_MCS7_2SS_BW80 585 Mbps
{1404, 105, 1}, // RATEID_VHT_MCS8_2SS_BW80 702 Mbps
{1560, 106, 1}, // RATEID_VHT_MCS9_2SS_BW80 780 Mbps
/* VHT bw80<--> Mrvl rate idx - nss1 */
{58, 87, 0}, // RATEID_VHT_MCS0_1SS_BW80 29.3 Mbps, 29.3x2 could
// correspond to 58
{59, 87, 0}, // RATEID_VHT_MCS0_1SS_BW80 29.3 Mbps, 29.3*2 could
// correspond to 59 too
{117, 88, 0}, // RATEID_VHT_MCS1_1SS_BW80 58.5 Mbps
{175, 89, 0}, // RATEID_VHT_MCS2_1SS_BW80 87.8 Mbps, 87.8x2 could
// correspond to 175
{176, 89, 0}, // RATEID_VHT_MCS2_1SS_BW80 87.8 Mbps, 87.8x2 could
// correspond to 176 too
{234, 90, 0}, // RATEID_VHT_MCS3_1SS_BW80 117 Mbps
{351, 91, 0}, // RATEID_VHT_MCS4_1SS_BW80 175.5 Mbps
{468, 92, 0}, // RATEID_VHT_MCS5_1SS_BW80 234 Mbps
{526, 93, 0}, // RATEID_VHT_MCS6_1SS_BW80 263.3 Mbps, 263.3x2 could
// correspond to 526
{527, 93, 0}, // RATEID_VHT_MCS6_1SS_BW80 263.3 Mbps, 263.3x2 could
// correspond to 527 too
{585, 94, 0}, // RATEID_VHT_MCS7_1SS_BW80 292.5 Mbps
{702, 95, 0}, // RATEID_VHT_MCS8_1SS_BW80 351 Mbps
{780, 96, 0}, // RATEID_VHT_MCS9_1SS_BW80 390 Mbps
};
/** rate_map_table_1x1 is based on rate_map_table_2x2 and remove nss2 part.
* For the chip who only support 1x1, Mrvl rate idx define is different with 2x2
* in FW We need redefine a bitrate to Mrvl rate idx table for 1x1 chip.
*/
static const rate_map rate_map_table_1x1[] = {
/* LG <--> Mrvl rate idx */
{2, 0, 0}, // RATEID_DBPSK1Mbps
{4, 1, 0}, // RATEID_DQPSK2Mbps
{11, 2, 0}, // RATEID_CCK5_5Mbps
{22, 3, 0}, // RATEID_CCK11Mbps
{44, 4, 0}, // RATEID_CCK22Mbps
{12, 5, 0}, // RATEID_OFDM6Mbps
{18, 6, 0}, // RATEID_OFDM9Mbps
{24, 7, 0}, // RATEID_OFDM12Mbps
{36, 8, 0}, // RATEID_OFDM18Mbps
{48, 9, 0}, // RATEID_OFDM24Mbps
{72, 10, 0}, // RATEID_OFDM36Mbps
{96, 11, 0}, // RATEID_OFDM48Mbps
{108, 12, 0}, // RATEID_OFDM54Mbps
{144, 13, 0}, // RATEID_OFDM72Mbps
/* HT bw20 <--> Mrvl rate idx */
{13, 14, 0}, // RATEID_MCS0_6d5Mbps
{26, 15, 0}, // RATEID_MCS1_13Mbps
{39, 16, 0}, // RATEID_MCS2_19d5Mbps
{52, 17, 0}, // RATEID_MCS3_26Mbps
{78, 18, 0}, // RATEID_MCS4_39Mbps
{104, 19, 0}, // RATEID_MCS5_52Mbps
{117, 20, 0}, // RATEID_MCS6_58d5Mbps
{130, 21, 0}, // RATEID_MCS7_65Mbps
/* HT bw40<--> Mrvl rate idx */
{12, 22, 0}, // RATEID_MCS32BW40_6Mbps, for 1x1 start from 22
{27, 23, 0}, // RATEID_MCS0BW40_13d5Mbps
{54, 24, 0}, // RATEID_MCS1BW40_27Mbps
{81, 25, 0}, // RATEID_MCS2BW40_40d5Mbps
{108, 26, 0}, // RATEID_MCS3BW40_54Mbps
{162, 27, 0}, // RATEID_MCS4BW40_81Mbps
{216, 28, 0}, // RATEID_MCS5BW40_108Mbps
{243, 29, 0}, // RATEID_MCS6BW40_121d5Mbps
{270, 30, 0}, // RATEID_MCS7BW40_135Mbps
/* VHT bw20<--> Mrvl rate idx */
{13, 31, 0}, // RATEID_VHT_MCS0_1SS_BW20 6.5 Mbps
{26, 32, 0}, // RATEID_VHT_MCS1_1SS_BW20 13 Mbps
{39, 33, 0}, // RATEID_VHT_MCS2_1SS_BW20 19.5 Mbps
{52, 34, 0}, // RATEID_VHT_MCS3_1SS_BW20 26 Mbps
{78, 35, 0}, // RATEID_VHT_MCS4_1SS_BW20 39 Mbps
{104, 36, 0}, // RATEID_VHT_MCS5_1SS_BW20 52 Mbps
{117, 37, 0}, // RATEID_VHT_MCS6_1SS_BW20 58.5 Mbps
{130, 38, 0}, // RATEID_VHT_MCS7_1SS_BW20 65 Mbps
{156, 39, 0}, // RATEID_VHT_MCS8_1SS_BW20 78 Mbps
{0, 40, 0}, // RATEID_VHT_MCS9_1SS_BW20 86.7 Mbps(INVALID)
/* VHT bw40<--> Mrvl rate idx */
{27, 41, 0}, // RATEID_VHT_MCS0_1SS_BW40 13.5 Mbps
{54, 42, 0}, // RATEID_VHT_MCS1_1SS_BW40 27 Mbps
{81, 43, 0}, // RATEID_VHT_MCS2_1SS_BW40 40.5 Mbps
{108, 44, 0}, // RATEID_VHT_MCS3_1SS_BW40 54 Mbps
{162, 45, 0}, // RATEID_VHT_MCS4_1SS_BW40 81 Mbps
{216, 46, 0}, // RATEID_VHT_MCS5_1SS_BW40 108 Mbps
{243, 47, 0}, // RATEID_VHT_MCS6_1SS_BW40 121.5 Mbps
{270, 48, 0}, // RATEID_VHT_MCS7_1SS_BW40 135 Mbps
{324, 49, 0}, // RATEID_VHT_MCS8_1SS_BW40 162 Mbps
{360, 50, 0}, // RATEID_VHT_MCS9_1SS_BW40 180 Mbps
/* VHT bw80<--> Mrvl rate idx */
{58, 51, 0}, // RATEID_VHT_MCS0_1SS_BW80 29.3 Mbps, 29.3x2 could
// correspond to 58
{59, 51, 0}, // RATEID_VHT_MCS0_1SS_BW80 29.3 Mbps, 29.3x2 could
// correspond to 59 too
{117, 52, 0}, // RATEID_VHT_MCS1_1SS_BW80 58.5 Mbps
{175, 53, 0}, // RATEID_VHT_MCS2_1SS_BW80 87.8 Mbps, 87.8x2 could
// correspond to 175
{176, 53, 0}, // RATEID_VHT_MCS2_1SS_BW80 87.8 Mbps, 87.8x2 could
// correspond to 176 too
{234, 54, 0}, // RATEID_VHT_MCS3_1SS_BW80 117 Mbps
{351, 55, 0}, // RATEID_VHT_MCS4_1SS_BW80 175.5 Mbps
{468, 56, 0}, // RATEID_VHT_MCS5_1SS_BW80 234 Mbps
{526, 57, 0}, // RATEID_VHT_MCS6_1SS_BW80 263.3 Mbps, 263.3x2 could
// correspond to 526
{527, 57, 0}, // RATEID_VHT_MCS6_1SS_BW80 263.3 Mbps, 263.3x2 could
// correspond to 527 too
{585, 58, 0}, // RATEID_VHT_MCS7_1SS_BW80 292.5 Mbps
{702, 59, 0}, // RATEID_VHT_MCS8_1SS_BW80 351 Mbps
{780, 60, 0}, // RATEID_VHT_MCS9_1SS_BW80 390 Mbps
};
/********************************************************
* Global Variables
********************************************************/
/**
* The table to keep region code
*/
t_u16 region_code_index[MRVDRV_MAX_REGION_CODE] = {0x00, 0x10, 0x20, 0x30, 0x40,
0x41, 0x50, 0xfe, 0xff};
/** The table to keep CFP code for BG */
t_u16 cfp_code_index_bg[MRVDRV_MAX_CFP_CODE_BG] = {};
/** The table to keep CFP code for A */
t_u16 cfp_code_index_a[MRVDRV_MAX_CFP_CODE_A] = {0x1, 0x2, 0x3, 0x4, 0x5};
/**
* The rates supported for ad-hoc B mode
*/
t_u8 AdhocRates_B[B_SUPPORTED_RATES] = {0x82, 0x84, 0x8b, 0x96, 0};
/**
* The rates supported for ad-hoc G mode
*/
t_u8 AdhocRates_G[G_SUPPORTED_RATES] = {0x8c, 0x12, 0x98, 0x24, 0xb0,
0x48, 0x60, 0x6c, 0x00};
/**
* The rates supported for ad-hoc BG mode
*/
t_u8 AdhocRates_BG[BG_SUPPORTED_RATES] = {0x82, 0x84, 0x8b, 0x96, 0x0c,
0x12, 0x18, 0x24, 0x30, 0x48,
0x60, 0x6c, 0x00};
/**
* The rates supported in A mode for ad-hoc
*/
t_u8 AdhocRates_A[A_SUPPORTED_RATES] = {0x8c, 0x12, 0x98, 0x24, 0xb0,
0x48, 0x60, 0x6c, 0x00};
/**
* The rates supported in A mode (used for BAND_A)
*/
t_u8 SupportedRates_A[A_SUPPORTED_RATES] = {0x0c, 0x12, 0x18, 0x24, 0xb0,
0x48, 0x60, 0x6c, 0x00};
/**
* The rates supported by the card
*/
static t_u16 WlanDataRates[WLAN_SUPPORTED_RATES_EXT] = {
0x02, 0x04, 0x0B, 0x16, 0x00, 0x0C, 0x12, 0x18, 0x24, 0x30, 0x48,
0x60, 0x6C, 0x90, 0x0D, 0x1A, 0x27, 0x34, 0x4E, 0x68, 0x75, 0x82,
0x0C, 0x1B, 0x36, 0x51, 0x6C, 0xA2, 0xD8, 0xF3, 0x10E, 0x00};
/**
* The rates supported in B mode
*/
t_u8 SupportedRates_B[B_SUPPORTED_RATES] = {0x02, 0x04, 0x0b, 0x16, 0x00};
/**
* The rates supported in G mode (BAND_G, BAND_G|BAND_GN)
*/
t_u8 SupportedRates_G[G_SUPPORTED_RATES] = {0x0c, 0x12, 0x18, 0x24, 0x30,
0x48, 0x60, 0x6c, 0x00};
/**
* The rates supported in BG mode (BAND_B|BAND_G, BAND_B|BAND_G|BAND_GN)
*/
t_u8 SupportedRates_BG[BG_SUPPORTED_RATES] = {0x02, 0x04, 0x0b, 0x0c, 0x12,
0x16, 0x18, 0x24, 0x30, 0x48,
0x60, 0x6c, 0x00};
/**
* The rates supported in N mode
*/
t_u8 SupportedRates_N[N_SUPPORTED_RATES] = {0x02, 0x04, 0};
#define MCS_NUM_AX 12
// for MCS0/MCS1/MCS3/MCS4 have 4 additional DCM=1 value
// note: the value in the table is 2 multiplier of the actual rate
static t_u16 ax_mcs_rate_nss1[12][MCS_NUM_AX + 4] = {
{0x90, 0x48, 0x120, 0x90, 0x1B0, 0x240, 0x120, 0x360, 0x1B0, 0x481,
0x511, 0x5A1, 0x6C1, 0x781, 0x871, 0x962}, /*SG 160M*/
{0x88, 0x44, 0x110, 0x88, 0x198, 0x220, 0x110, 0x330, 0x198, 0x440,
0x4C9, 0x551, 0x661, 0x716, 0x7F9, 0x8DC}, /*MG 160M*/
{0x7A, 0x3D, 0xF5, 0x7A, 0x16F, 0x1EA, 0xF5, 0x2DF, 0x16F, 0x3D4, 0x44E,
0x4C9, 0x5BE, 0x661, 0x72D, 0x7F9}, /*LG 160M*/
{0x48, 0x24, 0x90, 0x48, 0xD8, 0x120, 0x90, 0x1B0, 0xD8, 0x240, 0x288,
0x2D0, 0x360, 0x3C0, 0x438, 0x4B0}, /*SG 80M*/
{0x44, 0x22, 0x88, 0x44, 0xCC, 0x110, 0x88, 0x198, 0xCC, 0x220, 0x264,
0x2A8, 0x330, 0x38B, 0x3FC, 0x46E}, /*MG 80M*/
{0x3D, 0x1E, 0x7A, 0x3D, 0xB7, 0xF5, 0x7A, 0x16F, 0xB7, 0x1EA, 0x227,
0x264, 0x2DF, 0x330, 0x396, 0x3FC}, /*LG 80M*/
{0x22, 0x11, 0x44, 0x22, 0x67, 0x89, 0x44, 0xCE, 0x67, 0x113, 0x135,
0x158, 0x19D, 0x1CA, 0x204, 0x23D}, /*SG 40M*/
{0x20, 0x10, 0x41, 0x20, 0x61, 0x82, 0x41, 0xC3, 0x61, 0x104, 0x124,
0x145, 0x186, 0x1B1, 0x1E7, 0x21D}, /*MG 40M*/
{0x1D, 0xE, 0x3A, 0x1D, 0x57, 0x75, 0x3A, 0xAF, 0x57, 0xEA, 0x107,
0x124, 0x15F, 0x186, 0x1B6, 0x1E7}, /*LG 40M*/
{0x11, 0x8, 0x22, 0x11, 0x33, 0x44, 0x22, 0x67, 0x33, 0x89, 0x9A, 0xAC,
0xCE, 0xE5, 0x102, 0x11E}, /*SG 20M*/
{0x10, 0x8, 0x20, 0x10, 0x30, 0x41, 0x20, 0x61, 0x30, 0x82, 0x92, 0xA2,
0xC3, 0xD8, 0xF3, 0x10E}, /*MG 20M*/
{0xE, 0x7, 0x1D, 0xE, 0x2B, 0x3A, 0x1D, 0x57, 0x2B, 0x75, 0x83, 0x92,
0xAF, 0xC3, 0xDB, 0xF3} /*LG 20M*/
};
#if 0
// note: the value in the table is 2 multiplier of the actual rate
t_u16 ax_tone_ru_rate_nss1[9][MCS_NUM_AX + 4] = {
{0x8, 0x4, 0xF, 0x8, 0x17, 0x1E, 0xF, 0x2D, 0x17, 0x3C, 0x44, 0x4B,
0x5A, 0x64, 0x71, 0x7D}, /*SG 106-tone*/
{0x7, 0x4, 0xF, 0x7, 0x16, 0x1D, 0xF, 0x2B, 0x16, 0x39, 0x40, 0x47,
0x55, 0x5F, 0x6B, 0x76}, /*MG 106-tone*/
{0x7, 0x3, 0xD, 0x6, 0x14, 0x1A, 0xD, 0x27, 0x14, 0x33, 0x3A, 0x40,
0x4D, 0x55, 0x60, 0x6B}, /*LG 106-tone*/
{0x4, 0x2, 0x7, 0x4, 0xB, 0xF, 0x7, 0x16, 0xB, 0x1D, 0x20, 0x22, 0x2B,
0x2F, 0x35, 0x3B}, /*SG 52-tone*/
{0x4, 0x2, 0x7, 0x4, 0xA, 0xE, 0x7, 0x14, 0xA, 0x1B, 0x1E, 0x22, 0x28,
0x2D, 0x32, 0x38}, /*MG 52-tone*/
{0x3, 0x2, 0x6, 0x3, 0x9, 0xC, 0x6, 0x12, 0x9, 0x18, 0x1B, 0x1E, 0x24,
0x28, 0x2D, 0x32}, /*LG 52-tone*/
{0x2, 0x1, 0x4, 0x2, 0x6, 0x7, 0x4, 0xB, 0x5, 0xE, 0x10, 0x12, 0x15,
0x18, 0x1A, 0x1D}, /*SG 26-tone*/
{0x2, 0x1, 0x4, 0x2, 0x5, 0x6, 0x4, 0xA, 0x5, 0xD, 0xF, 0x11, 0x14,
0x16, 0x19, 0x1C}, /*MG 26-tone*/
{0x2, 0x1, 0x3, 0x2, 0x5, 0x6, 0x3, 0x9, 0x4, 0xC, 0xE, 0xF, 0x12, 0x14,
0x17, 0x19} /*LG 26-tone*/
};
#endif
// note: the value in the table is 2 multiplier of the actual rate
static t_u16 ax_mcs_rate_nss2[12][MCS_NUM_AX + 4] = {
{0x120, 0x90, 0x240, 0x120, 0x360, 0x481, 0x240, 0x61C, 0x360, 0x901,
0xA22, 0xB42, 0xD82, 0xF03, 0x10E3, 0x12C3}, /*SG 160M*/
{0x110, 0x88, 0x220, 0x110, 0x330, 0x440, 0x220, 0x661, 0x330, 0x881,
0x992, 0xAA2, 0xCAC, 0xE2D, 0xFF3, 0x11B9}, /*MG 160M*/
{0xF5, 0x7A, 0x1EA, 0xF5, 0x2DF, 0x3D4, 0x1EA, 0x5BE, 0x2DF, 0x7A8,
0x1134, 0x992, 0xB7C, 0xCC2, 0xE5B, 0xFF3}, /*LG 160M*/
{0x90, 0x48, 0x120, 0x90, 0x1B0, 0x240, 0x120, 0x360, 0x1B0, 0x481,
0x511, 0x5A1, 0x6C1, 0x781, 0x871, 0x962}, /*SG 80M*/
{0x88, 0x44, 0x110, 0x88, 0x198, 0x220, 0x110, 0x330, 0x198, 0x440,
0x4C9, 0x551, 0x661, 0x716, 0x7F9, 0x8DC}, /*MG 80M*/
{0x7A, 0x3D, 0xF5, 0x7A, 0x16F, 0x1EA, 0xF5, 0x2DF, 0x16F, 0x3D4, 0x44E,
0x4C9, 0x5BE, 0x661, 0x72D, 0x7F9}, /*LG 80M*/
{0x44, 0x22, 0x89, 0x44, 0xCE, 0x113, 0x89, 0x19D, 0xCE, 0x226, 0x26B,
0x2B0, 0x339, 0x395, 0x408, 0x47B}, /*SG 40M*/
{0x41, 0x20, 0x82, 0x41, 0xC3, 0x104, 0x82, 0x186, 0xC3, 0x208, 0x249,
0x28A, 0x30C, 0x362, 0x3CE, 0x43B}, /*MG 40M*/
{0x3A, 0x1D, 0x75, 0x3A, 0xAF, 0xEA, 0x75, 0x15F, 0xAF, 0x1D4, 0x20E,
0x249, 0x2BE, 0x30C, 0x36D, 0x3CF}, /*LG 40M*/
{0x22, 0x11, 0x44, 0x22, 0x67, 0x89, 0x44, 0xCE, 0x67, 0x113, 0x135,
0x158, 0x19D, 0x1CA, 0x204, 0x23D}, /*SG 20M*/
{0x20, 0x10, 0x41, 0x20, 0x61, 0x82, 0x41, 0xC3, 0x61, 0x104, 0x124,
0x145, 0x186, 0x1B1, 0x1E7, 0x21D}, /*MG 20M*/
{0x1D, 0xE, 0x3A, 0x1D, 0x57, 0x75, 0x3A, 0xAF, 0x57, 0xEA, 0x107,
0x124, 0x15F, 0x186, 0x1B6, 0x1E7} /*LG 20M*/
};
#if 0
// note: the value in the table is 2 multiplier of the actual rate
t_u16 ax_tone_ru_rate_nss2[9][MCS_NUM_AX + 4] = {
{0xF, 0x8, 0x1E, 0xF, 0x2D, 0x3C, 0x1E, 0x5A, 0x2D, 0x78, 0x87, 0x96,
0xB4, 0xC8, 0xE1, 0xFA}, /*SG 106-tone*/
{0xE, 0x7, 0x1D, 0xE, 0x2B, 0x39, 0x1D, 0x55, 0x2B, 0x72, 0x80, 0x8E,
0xAA, 0xBD, 0xD5, 0xED}, /*MG 106-tone*/
{0xD, 0x7, 0x1A, 0xD, 0x27, 0x33, 0x1A, 0x4D, 0x27, 0x66, 0x73, 0x80,
0x99, 0xAA, 0xC0, 0xD5}, /*LG 106-tone*/
{0x7, 0x4, 0xF, 0x7, 0x16, 0x1D, 0xF, 0x2A, 0x16, 0x39, 0x40, 0x47,
0x55, 0x5F, 0x6A, 0x76}, /*SG 52-tone*/
{0x7, 0x4, 0xE, 0x7, 0x14, 0x1B, 0xE, 0x28, 0x14, 0x36, 0x3C, 0x43,
0x50, 0x59, 0x64, 0x70}, /*MG 52-tone*/
{0x6, 0x3, 0xC, 0x6, 0x12, 0x18, 0xC, 0x24, 0x12, 0x30, 0x36, 0x3C,
0x48, 0x50, 0x5A, 0x64}, /*LG 52-tone*/
{0x4, 0x2, 0x7, 0x4, 0xB, 0xF, 0x7, 0x16, 0xB, 0x1D, 0x20, 0x22, 0x2B,
0x2F, 0x35, 0x3B}, /*SG 26-tone*/
{0x4, 0x2, 0x7, 0x4, 0xA, 0xE, 0x7, 0x14, 0xA, 0x1B, 0x1E, 0x22, 0x28,
0x2D, 0x32, 0x38}, /*MG 26-tone*/
{0x3, 0x2, 0x6, 0x3, 0x9, 0xC, 0x6, 0x12, 0x9, 0x18, 0x1B, 0x1E, 0x24,
0x28, 0x2D, 0x32} /*LG 26-tone*/
};
#endif
/********************************************************
* Local Functions
********************************************************/
/**
* @brief Find a character in a string.
*
* @param pmadapter A pointer to mlan_adapter structure
* @param s A pointer to string
* @param c Character to be located
* @param n The length of string
*
* @return A pointer to the first occurrence of c in string, or MNULL if
* c is not found.
*/
static void *wlan_memchr(pmlan_adapter pmadapter, void *s, int c, int n)
{
const t_u8 *p = (t_u8 *)s;
ENTER();
while (n--) {
if ((t_u8)c == *p++) {
LEAVE();
return (void *)(p - 1);
}
}
LEAVE();
return MNULL;
}
/**
* @brief This function finds the CFP in
* cfp_table_BG/A based on region/code and band parameter.
*
* @param pmadapter A pointer to mlan_adapter structure
* @param region The region code
* @param band The band
* @param cfp_no A pointer to CFP number
*
* @return A pointer to CFP
*/
static chan_freq_power_t *wlan_get_region_cfp_table(pmlan_adapter pmadapter,
t_u8 region, t_u8 band,
int *cfp_no)
{
t_u32 i;
t_u8 cfp_bg, cfp_a;
ENTER();
cfp_bg = cfp_a = region;
if (!region) {
/* Invalid region code, use CFP code */
cfp_bg = pmadapter->cfp_code_bg;
cfp_a = pmadapter->cfp_code_a;
}
if (band & (BAND_B | BAND_G | BAND_GN | BAND_GAC)) {
/* Return the FW cfp table for requested region code, if
* available. If region is not forced and the requested region
* code is different, simply return the corresponding
* pre-defined table.
*/
if (pmadapter->otp_region && pmadapter->cfp_otp_bg) {
if (pmadapter->otp_region->force_reg ||
(cfp_bg ==
(t_u8)pmadapter->otp_region->region_code)) {
*cfp_no = pmadapter->tx_power_table_bg_rows;
LEAVE();
return pmadapter->cfp_otp_bg;
}
}
for (i = 0; i < MLAN_CFP_TABLE_SIZE_BG; i++) {
PRINTM(MINFO, "cfp_table_BG[%d].code=%d\n", i,
cfp_table_BG[i].code);
/* Check if region/code matches for BG bands */
if (cfp_table_BG[i].code == cfp_bg) {
/* Select by band */
*cfp_no = cfp_table_BG[i].cfp_no;
LEAVE();
return cfp_table_BG[i].cfp;
}
}
}
if (band & (BAND_A | BAND_AN | BAND_AAC)) {
/* Return the FW cfp table for requested region code */
if (pmadapter->otp_region && pmadapter->cfp_otp_a) {
if (pmadapter->otp_region->force_reg ||
(cfp_a ==
(t_u8)pmadapter->otp_region->region_code)) {
*cfp_no = pmadapter->tx_power_table_a_rows;
LEAVE();
return pmadapter->cfp_otp_a;
}
}
for (i = 0; i < MLAN_CFP_TABLE_SIZE_A; i++) {
PRINTM(MINFO, "cfp_table_A[%d].code=%d\n", i,
cfp_table_A[i].code);
/* Check if region/code matches for A bands */
if (cfp_table_A[i].code == cfp_a) {
/* Select by band */
*cfp_no = cfp_table_A[i].cfp_no;
LEAVE();
return cfp_table_A[i].cfp;
}
}
}
if (!region)
PRINTM(MERROR, "Error Band[0x%x] or code[BG:%#x, A:%#x]\n",
band, cfp_bg, cfp_a);
else
PRINTM(MERROR, "Error Band[0x%x] or region[%#x]\n", band,
region);
LEAVE();
return MNULL;
}
/**
* @brief This function copies dynamic CFP elements from one table to another.
* Only copy elements where channel numbers match.
*
* @param pmadapter A pointer to mlan_adapter structure
* @param cfp Destination table
* @param num_cfp Number of elements in dest table
* @param cfp_src Source table
* @param num_cfp_src Number of elements in source table
*/
static t_void wlan_cfp_copy_dynamic(pmlan_adapter pmadapter,
chan_freq_power_t *cfp, t_u8 num_cfp,
chan_freq_power_t *cfp_src,
t_u8 num_cfp_src)
{
int i, j;
ENTER();
if (cfp == cfp_src) {
LEAVE();
return;
}
/* first clear dest dynamic blacklisted entries */
/* do not clear the flags */
for (i = 0; i < num_cfp; i++) {
cfp[i].dynamic.blacklist = MFALSE;
}
/* copy dynamic blacklisted entries from source where channels match */
if (cfp_src) {
for (i = 0; i < num_cfp; i++)
for (j = 0; j < num_cfp_src; j++)
if (cfp[i].channel == cfp_src[j].channel) {
cfp[i].dynamic.blacklist =
cfp_src[j].dynamic.blacklist;
break;
}
}
LEAVE();
}
/********************************************************
* Global Functions
********************************************************/
/**
* @brief This function converts region string to integer code
*
* @param pmadapter A pointer to mlan_adapter structure
* @param country_code Country string
* @param cfp_bg Pointer to buffer
* @param cfp_a Pointer to buffer
*
* @return MLAN_STATUS_SUCCESS or MLAN_STATUS_FAILURE
*/
mlan_status wlan_misc_country_2_cfp_table_code(pmlan_adapter pmadapter,
t_u8 *country_code, t_u8 *cfp_bg,
t_u8 *cfp_a)
{
t_u8 i;
ENTER();
if (pmadapter->otp_region) {
if (!memcmp(pmadapter, pmadapter->otp_region->country_code,
country_code, COUNTRY_CODE_LEN - 1)) {
if (pmadapter->cfp_otp_bg)
*cfp_bg = pmadapter->otp_region->region_code;
if (pmadapter->cfp_otp_a)
*cfp_a = pmadapter->otp_region->region_code;
LEAVE();
return MLAN_STATUS_SUCCESS;
}
}
/* Look for code in mapping table */
for (i = 0; i < NELEMENTS(country_code_mapping); i++) {
if (!memcmp(pmadapter, country_code_mapping[i].country_code,
country_code, COUNTRY_CODE_LEN - 1)) {
*cfp_bg = country_code_mapping[i].cfp_code_bg;
*cfp_a = country_code_mapping[i].cfp_code_a;
LEAVE();
return MLAN_STATUS_SUCCESS;
}
}
/* If still not found, look for code in EU country code table */
for (i = 0; i < NELEMENTS(eu_country_code_table); i++) {
if (!memcmp(pmadapter, eu_country_code_table[i], country_code,
COUNTRY_CODE_LEN - 1)) {
*cfp_bg = EU_CFP_CODE_BG;
*cfp_a = EU_CFP_CODE_A;
LEAVE();
return MLAN_STATUS_SUCCESS;
}
}
LEAVE();
return MLAN_STATUS_FAILURE;
}
/**
* @brief This function finds if given country code is in EU table
*
* @param pmadapter A pointer to mlan_adapter structure
* @param country_code Country string
*
* @return MTRUE or MFALSE
*/
t_bool wlan_is_etsi_country(pmlan_adapter pmadapter, t_u8 *country_code)
{
t_u8 i;
ENTER();
/* Look for code in EU country code table */
for (i = 0; i < NELEMENTS(eu_country_code_table); i++) {
if (!memcmp(pmadapter, eu_country_code_table[i], country_code,
COUNTRY_CODE_LEN - 1)) {
LEAVE();
return MTRUE;
}
}
LEAVE();
return MFALSE;
}
/**
* @brief This function adjust the antenna index
*
* V16_FW_API: Bit0: ant A, Bit 1:ant B, Bit0 & Bit 1: A+B
* 8887: case1: 0 - 2.4G ant A, 1- 2.4G antB, 2-- 5G ant C
* case2: 0 - 2.4G ant A, 1- 2.4G antB, 0x80- 5G antA, 0x81-5G ant B
* @param priv A pointer to mlan_private structure
* @param prx_pd A pointer to the RxPD structure
*
* @return MLAN_STATUS_SUCCESS or MLAN_STATUS_FAILURE
*/
t_u8 wlan_adjust_antenna(pmlan_private priv, RxPD *prx_pd)
{
t_u8 antenna = prx_pd->antenna;
#if defined(SD8887) || defined(SD8987)
t_u32 rx_channel = (prx_pd->rx_info & RXPD_CHAN_MASK) >> 5;
#endif
if (prx_pd->antenna == 0xff)
return 0;
if (priv->adapter->pcard_info->v16_fw_api) {
if ((antenna & MBIT(0)) && (antenna & MBIT(1)))
antenna = 2;
else if (antenna & MBIT(1))
antenna = 1;
else if (antenna & MBIT(0))
antenna = 0;
}
#if defined(SD8887) || defined(SD8987)
#define ANTENNA_OFFSET 2
if (MFALSE
#ifdef SD8887
|| IS_SD8887(priv->adapter->card_type)
#endif
#ifdef SD8987
|| IS_SD8987(priv->adapter->card_type)
#endif
) {
if ((priv->adapter->antinfo & ANT_DIVERSITY_2G) &&
(priv->adapter->antinfo & ANT_DIVERSITY_5G)) {
#define MAX_2G_CHAN 14
if (rx_channel > MAX_2G_CHAN)
antenna += ANTENNA_OFFSET;
}
}
#endif
return antenna;
}
/**
* @brief This function adjust the rate index
*
* @param priv A pointer to mlan_private structure
* @param rx_rate rx rate
* @param rate_info rate info
* @return rate index
*/
t_u16 wlan_adjust_data_rate(mlan_private *priv, t_u8 rx_rate, t_u8 rate_info)
{
t_u16 rate_index = 0;
t_u8 bw = 0;
t_u8 nss = 0;
t_bool sgi_enable = 0;
t_u8 gi = 0;
#define MAX_MCS_NUM_AX 12
#define MAX_MCS_NUM_SUPP 16
#define MAX_MCS_NUM_AC 10
#define RATE_INDEX_MCS0 12
bw = (rate_info & 0xC) >> 2;
sgi_enable = (rate_info & 0x10) >> 4;
if ((rate_info & 0x3) == 0) {
rate_index = (rx_rate > MLAN_RATE_INDEX_OFDM0) ? rx_rate - 1 :
rx_rate;
} else if ((rate_info & 0x03) == 1) {
rate_index = RATE_INDEX_MCS0 +
MAX_MCS_NUM_SUPP * 2 * sgi_enable +
MAX_MCS_NUM_SUPP * bw + rx_rate;
} else if ((rate_info & 0x3) == 2) {
if (IS_STREAM_2X2(priv->adapter->feature_control))
nss = rx_rate >> 4; // 0:NSS1, 1:NSS2
rate_index = RATE_INDEX_MCS0 + MAX_MCS_NUM_SUPP * 4 +
MAX_MCS_NUM_AC * 6 * sgi_enable +
MAX_MCS_NUM_AC * 2 * bw + MAX_MCS_NUM_AC * nss +
(rx_rate & 0x0f);
} else if ((rate_info & 0x3) == 3) {
gi = (rate_info & 0x10) >> 4 | (rate_info & 0x80) >> 6;
if (IS_STREAM_2X2(priv->adapter->feature_control))
nss = rx_rate >> 4; // 0:NSS1, 1:NSS2
rate_index = RATE_INDEX_MCS0 + MAX_MCS_NUM_SUPP * 4 +
MAX_MCS_NUM_AC * 12 + MAX_MCS_NUM_AX * 6 * gi +
MAX_MCS_NUM_AX * 2 * bw + MAX_MCS_NUM_AX * nss +
(rx_rate & 0x0f);
}
return rate_index;
}
#ifdef STA_SUPPORT
#endif /* STA_SUPPORT */
/**
* @brief convert TX rate_info from v14 to v15+ FW rate_info
*
* @param v14_rate_info v14 rate info
*
* @return v15+ rate info
*/
t_u8 wlan_convert_v14_tx_rate_info(pmlan_private pmpriv, t_u8 v14_rate_info)
{
t_u8 rate_info = 0;
if (!pmpriv->adapter->pcard_info->v14_fw_api) {
PRINTM(MERROR, "%s: Not convert for this is not V14 FW\n",
__func__);
return v14_rate_info;
}
rate_info = v14_rate_info & 0x01;
/* band */
rate_info |= (v14_rate_info & MBIT(1)) << 1;
/* short GI */
rate_info |= (v14_rate_info & MBIT(2)) << 2;
return rate_info;
}
/**
* @brief convert RX rate_info from v14 to v15+ FW rate_info
*
* @param v14_rate_info v14 rate info
*
* @return v15+ rate info
*/
t_u8 wlan_convert_v14_rx_rate_info(pmlan_private pmpriv, t_u8 v14_rate_info)
{
t_u8 rate_info = 0;
t_u8 mode = 0;
t_u8 bw = 0;
t_u8 sgi = 0;
if (!pmpriv->adapter->pcard_info->v14_fw_api) {
PRINTM(MERROR, "%s: Not convert for this is not V14 FW\n",
__func__);
return v14_rate_info;
}
mode = v14_rate_info & MBIT(0);
bw = v14_rate_info & MBIT(1);
sgi = (v14_rate_info & 0x04) >> 2;
rate_info = (mode & 0x01) | ((bw & 0x01) << 2) | ((sgi & 0x01) << 4);
return rate_info;
}
/**
* @brief Use index to get the data rate
*
* @param pmadapter A pointer to mlan_adapter structure
* @param index The index of data rate
* @param tx_rate_info Tx rate info
* @param ext_rate_info Extend tx rate info
*
* @return Data rate or 0
*/
t_u32 wlan_index_to_data_rate(pmlan_adapter pmadapter, t_u8 index,
t_u8 tx_rate_info, t_u8 ext_rate_info)
{
#define MCS_NUM_SUPP 16
t_u16 mcs_rate[4][MCS_NUM_SUPP] = {
{0x1b, 0x36, 0x51, 0x6c, 0xa2, 0xd8, 0xf3, 0x10e, 0x36, 0x6c,
0xa2, 0xd8, 0x144, 0x1b0, 0x1e6, 0x21c}, /*LG 40M*/
{0x1e, 0x3c, 0x5a, 0x78, 0xb4, 0xf0, 0x10e, 0x12c, 0x3c, 0x78,
0xb4, 0xf0, 0x168, 0x1e0, 0x21c, 0x258}, /*SG 40M */
{0x0d, 0x1a, 0x27, 0x34, 0x4e, 0x68, 0x75, 0x82, 0x1a, 0x34,
0x4e, 0x68, 0x9c, 0xd0, 0xea, 0x104}, /*LG 20M */
{0x0e, 0x1c, 0x2b, 0x39, 0x56, 0x73, 0x82, 0x90, 0x1c, 0x39,
0x56, 0x73, 0xad, 0xe7, 0x104, 0x120}}; /*SG 20M */
#define MCS_NUM_AC 10
/* NSS 1. note: the value in the table is 2 multiplier of the actual
* rate in other words, it is in the unit of 500 Kbs
*/
t_u16 ac_mcs_rate_nss1[8][MCS_NUM_AC] = {
{0x75, 0xEA, 0x15F, 0x1D4, 0x2BE, 0x3A8, 0x41D, 0x492, 0x57C,
0x618}, /* LG 160M*/
{0x82, 0x104, 0x186, 0x208, 0x30C, 0x410, 0x492, 0x514, 0x618,
0x6C6}, /* SG 160M*/
{0x3B, 0x75, 0xB0, 0xEA, 0x15F, 0x1D4, 0x20F, 0x249, 0x2BE,
0x30C}, /* LG 80M */
{0x41, 0x82, 0xC3, 0x104, 0x186, 0x208, 0x249, 0x28A, 0x30C,
0x363}, /* SG 80M */
{0x1B, 0x36, 0x51, 0x6C, 0xA2, 0xD8, 0xF3, 0x10E, 0x144,
0x168}, /* LG 40M */
{0x1E, 0x3C, 0x5A, 0x78, 0xB4, 0xF0, 0x10E, 0x12C, 0x168,
0x190}, /* SG 40M */
{0xD, 0x1A, 0x27, 0x34, 0x4E, 0x68, 0x75, 0x82, 0x9C,
0x00}, /* LG 20M */
{0xF, 0x1D, 0x2C, 0x3A, 0x57, 0x74, 0x82, 0x91, 0xAE,
0x00}, /* SG 20M */
};
/* NSS 2. note: the value in the table is 2 multiplier of the actual
* rate
*/
t_u16 ac_mcs_rate_nss2[8][MCS_NUM_AC] = {
{0xEA, 0x1D4, 0x2BE, 0x3A8, 0x57C, 0x750, 0x83A, 0x924, 0xAF8,
0xC30}, /*LG 160M*/
{0x104, 0x208, 0x30C, 0x410, 0x618, 0x820, 0x924, 0xA28, 0xC30,
0xD8B}, /*SG 160M*/
{0x75, 0xEA, 0x15F, 0x1D4, 0x2BE, 0x3A8, 0x41D, 0x492, 0x57C,
0x618}, /*LG 80M*/
{0x82, 0x104, 0x186, 0x208, 0x30C, 0x410, 0x492, 0x514, 0x618,
0x6C6}, /*SG 80M*/
{0x36, 0x6C, 0xA2, 0xD8, 0x144, 0x1B0, 0x1E6, 0x21C, 0x288,
0x2D0}, /*LG 40M*/
{0x3C, 0x78, 0xB4, 0xF0, 0x168, 0x1E0, 0x21C, 0x258, 0x2D0,
0x320}, /*SG 40M*/
{0x1A, 0x34, 0x4A, 0x68, 0x9C, 0xD0, 0xEA, 0x104, 0x138,
0x00}, /*LG 20M*/
{0x1D, 0x3A, 0x57, 0x74, 0xAE, 0xE6, 0x104, 0x121, 0x15B,
0x00}, /*SG 20M*/
};
t_u32 rate = 0;
t_u8 mcs_index = 0;
t_u8 he_dcm = 0;
// t_u8 he_tone = 0;
t_u8 stbc = 0;
t_u8 bw = 0;
t_u8 gi = 0;
ENTER();
PRINTM(MINFO, "%s:index=%d, tx_rate_info=%d, ext_rate_info=%d\n",
__func__, index, tx_rate_info, ext_rate_info);
if ((tx_rate_info & 0x3) == MLAN_RATE_FORMAT_VHT) {
/* VHT rate */
mcs_index = index & 0xF;
if (mcs_index > 9)
mcs_index = 9;
/* 20M: bw=0, 40M: bw=1, 80M: bw=2, 160M: bw=3 */
bw = (tx_rate_info & 0xC) >> 2;
/* LGI: gi =0, SGI: gi = 1 */
gi = (tx_rate_info & 0x10) >> 4;
if ((index >> 4) == 1) {
/* NSS = 2 */
rate = ac_mcs_rate_nss2[2 * (3 - bw) + gi][mcs_index];
} else
/* NSS = 1 */
rate = ac_mcs_rate_nss1[2 * (3 - bw) + gi][mcs_index];
} else
if ((tx_rate_info & 0x3) == MLAN_RATE_FORMAT_HE) {
/* VHT rate */
mcs_index = index & 0xF;
he_dcm = ext_rate_info & MBIT(0);
if (mcs_index > MCS_NUM_AX - 1)
mcs_index = MCS_NUM_AX - 1;
/* 20M: bw=0, 40M: bw=1, 80M: bw=2, 160M: bw=3 */
bw = (tx_rate_info & (MBIT(3) | MBIT(2))) >> 2;
/* BIT7:BIT4 0:0= 0.8us,0:1= 0.8us, 1:0=1.6us, 1:1=3.2us or
* 0.8us
*/
gi = (tx_rate_info & MBIT(4)) >> 4 |
(tx_rate_info & MBIT(7)) >> 6;
/* STBC: BIT5 in tx rate info */
stbc = (tx_rate_info & MBIT(5)) >> 5;
if (gi > 3) {
PRINTM(MERROR, "Invalid gi value");
return 0;
}
if ((gi == 3) && stbc && he_dcm) {
gi = 0;
stbc = 0;
he_dcm = 0;
}
/* map to gi 0:0.8us,1:1.6us 2:3.2us*/
if (gi > 0)
gi = gi - 1;
//#ifdef ENABLE_802_11AX
// TODO: hardcode he_tone here, wait for FW value ready.
// he_tone = 4;
// he_tone = (ext_rate_info & 0xE) >> 1;
//#endif
if ((index >> 4) == 1) {
switch (mcs_index) {
case 0:
case 1:
// #if 0
// if (he_tone < 3) {
// rate =
//ax_tone_ru_rate_nss2[3*(2-he_tone)+gi][mcs_index*2
//+ he_dcm];
// } else {
// #endif
rate = ax_mcs_rate_nss2[3 * (3 - bw) + gi]
[mcs_index * 2 + he_dcm];
break;
case 2:
// #if 0
// if (he_tone < 3) {
// rate =
//ax_tone_ru_rate_nss2[3*(2-he_tone)+gi][mcs_index*2];
// } else {
// #endif
rate = ax_mcs_rate_nss2[3 * (3 - bw) + gi]
[mcs_index * 2];
break;
case 3:
case 4:
// #if 0
// if (he_tone < 3) {
// rate =
//ax_tone_ru_rate_nss2[3*(2-he_tone)+gi][mcs_index*2
//- 1 + he_dcm];
// } else {
// #endif
rate = ax_mcs_rate_nss2[3 * (3 - bw) + gi]
[mcs_index * 2 - 1 +
he_dcm];
break;
default:
// #if 0
// if (he_tone < 3) {
// rate =
//ax_tone_ru_rate_nss2[3*(2-he_tone)+gi][mcs_index
//+ 4];
// } else {
// #endif
rate = ax_mcs_rate_nss2[3 * (3 - bw) + gi]
[mcs_index + 4];
break;
}
} else {
switch (mcs_index) {
case 0:
case 1:
// #if 0
// if (he_tone < 3) {
// rate =
//ax_tone_ru_rate_nss1[3*(2-he_tone)+gi][mcs_index*2
//+ he_dcm];
// } else {
// #endif
rate = ax_mcs_rate_nss1[3 * (3 - bw) + gi]
[mcs_index * 2 + he_dcm];
break;
case 2:
// #if 0
// if (he_tone < 3) {
// rate =
//ax_tone_ru_rate_nss1[3*(2-he_tone)+gi][mcs_index*2];
// } else {
// #endif
rate = ax_mcs_rate_nss1[3 * (3 - bw) + gi]
[mcs_index * 2];
break;
case 3:
case 4:
// #if 0
// if (he_tone < 3) {
// rate =
//ax_tone_ru_rate_nss1[3*(2-he_tone)+gi][mcs_index*2
//- 1 + he_dcm];
// } else {
// #endif
rate = ax_mcs_rate_nss1[3 * (3 - bw) + gi]
[mcs_index * 2 - 1 +
he_dcm];
break;
default:
// #if 0
// if (he_tone < 3) {
// rate =
//ax_tone_ru_rate_nss1[3*(2-he_tone)+gi][mcs_index
//+ 4];
// } else {
// #endif
rate = ax_mcs_rate_nss1[3 * (3 - bw) + gi]
[mcs_index + 4];
break;
}
}
} else if ((tx_rate_info & 0x3) == MLAN_RATE_FORMAT_HT) {
/* HT rate */
/* 20M: bw=0, 40M: bw=1 */
bw = (tx_rate_info & 0xC) >> 2;
/* LGI: gi =0, SGI: gi = 1 */
gi = (tx_rate_info & 0x10) >> 4;
if (index == MLAN_RATE_BITMAP_MCS0) {
if (gi == 1)
rate = 0x0D; /* MCS 32 SGI rate */
else
rate = 0x0C; /* MCS 32 LGI rate */
} else if (index < MCS_NUM_SUPP) {
if (bw <= 1)
rate = mcs_rate[2 * (1 - bw) + gi][index];
else
rate = WlanDataRates[0];
} else
rate = WlanDataRates[0];
} else {
/* 11n non HT rates */
if (index >= WLAN_SUPPORTED_RATES_EXT)
index = 0;
rate = WlanDataRates[index];
}
LEAVE();
return rate;
}
/**
* @brief Use rate to get the index
*
* @param pmadapter A pointer to mlan_adapter structure
* @param rate Data rate
*
* @return Index or 0
*/
t_u8 wlan_data_rate_to_index(pmlan_adapter pmadapter, t_u32 rate)
{
t_u16 *ptr;
ENTER();
if (rate) {
ptr = wlan_memchr(pmadapter, WlanDataRates, (t_u8)rate,
sizeof(WlanDataRates));
if (ptr) {
LEAVE();
return (t_u8)(ptr - WlanDataRates);
}
}
LEAVE();
return 0;
}
/**
* @brief Get active data rates
*
* @param pmpriv A pointer to mlan_private structure
* @param bss_mode The specified BSS mode (Infra/IBSS)
* @param config_bands The specified band configuration
* @param rates The buf to return the active rates
*
* @return The number of Rates
*/
t_u32 wlan_get_active_data_rates(mlan_private *pmpriv, t_u32 bss_mode,
t_u16 config_bands, WLAN_802_11_RATES rates)
{
t_u32 k;
ENTER();
if (pmpriv->media_connected != MTRUE) {
k = wlan_get_supported_rates(pmpriv, bss_mode, config_bands,
rates);
} else {
k = wlan_copy_rates(rates, 0,
pmpriv->curr_bss_params.data_rates,
pmpriv->curr_bss_params.num_of_rates);
}
LEAVE();
return k;
}
#ifdef STA_SUPPORT
/**
* @brief This function search through all the regions cfp table to find the
* channel, if the channel is found then gets the MIN txpower of the channel
* present in all the regions.
*
* @param pmpriv A pointer to mlan_private structure
* @param channel Channel number.
*
* @return The Tx power
*/
t_u8 wlan_get_txpwr_of_chan_from_cfp(mlan_private *pmpriv, t_u8 channel)
{
t_u8 i = 0;
t_u8 j = 0;
t_u8 tx_power = 0;
t_u32 cfp_no;
chan_freq_power_t *cfp = MNULL;
chan_freq_power_t *cfp_a = MNULL;
t_u32 cfp_no_a;
ENTER();
for (i = 0; i < MLAN_CFP_TABLE_SIZE_BG; i++) {
/* Get CFP */
cfp = cfp_table_BG[i].cfp;
cfp_no = cfp_table_BG[i].cfp_no;
/* Find matching channel and get Tx power */
for (j = 0; j < cfp_no; j++) {
if ((cfp + j)->channel == channel) {
if (tx_power != 0)
tx_power = MIN(tx_power,
(cfp + j)->max_tx_power);
else
tx_power =
(t_u8)(cfp + j)->max_tx_power;
break;
}
}
}
for (i = 0; i < MLAN_CFP_TABLE_SIZE_A; i++) {
/* Get CFP */
cfp_a = cfp_table_A[i].cfp;
cfp_no_a = cfp_table_A[i].cfp_no;
for (j = 0; j < cfp_no_a; j++) {
if ((cfp_a + j)->channel == channel) {
if (tx_power != 0)
tx_power =
MIN(tx_power,
(cfp_a + j)->max_tx_power);
else
tx_power = (t_u8)(
(cfp_a + j)->max_tx_power);
break;
}
}
}
LEAVE();
return tx_power;
}
/**
* @brief Get the channel frequency power info for a specific channel
*
* @param pmadapter A pointer to mlan_adapter structure
* @param band It can be BAND_A, BAND_G or BAND_B
* @param channel The channel to search for
* @param region_channel A pointer to region_chan_t structure
*
* @return A pointer to chan_freq_power_t structure or
* MNULL if not found.
*/
chan_freq_power_t *
wlan_get_cfp_by_band_and_channel(pmlan_adapter pmadapter, t_u8 band,
t_u16 channel, region_chan_t *region_channel)
{
region_chan_t *rc;
chan_freq_power_t *cfp = MNULL;
int i, j;
ENTER();
for (j = 0; !cfp && (j < MAX_REGION_CHANNEL_NUM); j++) {
rc = &region_channel[j];
if (!rc->valid || !rc->pcfp)
continue;
switch (rc->band) {
case BAND_A:
switch (band) {
case BAND_AN:
case BAND_A | BAND_AN:
case BAND_A | BAND_AN | BAND_AAC:
/* Fall Through */
case BAND_A: /* Matching BAND_A */
break;
default:
continue;
}
break;
case BAND_B:
case BAND_G:
switch (band) {
case BAND_GN:
case BAND_B | BAND_G | BAND_GN:
case BAND_G | BAND_GN:
case BAND_GN | BAND_GAC:
case BAND_B | BAND_G | BAND_GN | BAND_GAC:
case BAND_G | BAND_GN | BAND_GAC:
case BAND_B | BAND_G:
/* Fall Through */
case BAND_B: /* Matching BAND_B/G */
/* Fall Through */
case BAND_G:
/* Fall Through */
case 0:
break;
default:
continue;
}
break;
default:
continue;
}
if (channel == FIRST_VALID_CHANNEL)
cfp = &rc->pcfp[0];
else {
for (i = 0; i < rc->num_cfp; i++) {
if (rc->pcfp[i].channel == channel) {
cfp = &rc->pcfp[i];
break;
}
}
}
}
if (!cfp && channel)
PRINTM(MCMND, "%s: can not find cfp by band %d & channel %d\n",
__func__, band, channel);
LEAVE();
return cfp;
}
/**
* @brief Find the channel frequency power info for a specific channel
*
* @param pmadapter A pointer to mlan_adapter structure
* @param band It can be BAND_A, BAND_G or BAND_B
* @param channel The channel to search for
*
* @return A pointer to chan_freq_power_t structure or MNULL if not
* found.
*/
chan_freq_power_t *wlan_find_cfp_by_band_and_channel(mlan_adapter *pmadapter,
t_u8 band, t_u16 channel)
{
chan_freq_power_t *cfp = MNULL;
ENTER();
/* Any station(s) with 11D enabled */
if (wlan_count_priv_cond(pmadapter, wlan_11d_is_enabled,
wlan_is_station) > 0)
cfp = wlan_get_cfp_by_band_and_channel(
pmadapter, band, channel, pmadapter->universal_channel);
else
cfp = wlan_get_cfp_by_band_and_channel(
pmadapter, band, channel, pmadapter->region_channel);
LEAVE();
return cfp;
}
/**
* @brief Find the channel frequency power info for a specific frequency
*
* @param pmadapter A pointer to mlan_adapter structure
* @param band It can be BAND_A, BAND_G or BAND_B
* @param freq The frequency to search for
*
* @return Pointer to chan_freq_power_t structure; MNULL if not found
*/
chan_freq_power_t *wlan_find_cfp_by_band_and_freq(mlan_adapter *pmadapter,
t_u8 band, t_u32 freq)
{
chan_freq_power_t *cfp = MNULL;
region_chan_t *rc;
int i, j;
ENTER();
for (j = 0; !cfp && (j < MAX_REGION_CHANNEL_NUM); j++) {
rc = &pmadapter->region_channel[j];
/* Any station(s) with 11D enabled */
if (wlan_count_priv_cond(pmadapter, wlan_11d_is_enabled,
wlan_is_station) > 0)
rc = &pmadapter->universal_channel[j];
if (!rc->valid || !rc->pcfp)
continue;
switch (rc->band) {
case BAND_A:
switch (band) {
case BAND_AN:
case BAND_A | BAND_AN:
case BAND_A | BAND_AN | BAND_AAC:
/* Fall Through */
case BAND_A: /* Matching BAND_A */
break;
default:
continue;
}
break;
case BAND_B:
case BAND_G:
switch (band) {
case BAND_GN:
case BAND_B | BAND_G | BAND_GN:
case BAND_G | BAND_GN:
case BAND_GN | BAND_GAC:
case BAND_B | BAND_G | BAND_GN | BAND_GAC:
case BAND_G | BAND_GN | BAND_GAC:
case BAND_B | BAND_G:
/* Fall Through */
case BAND_B:
/* Fall Through */
case BAND_G:
/* Fall Through */
case 0:
break;
default:
continue;
}
break;
default:
continue;
}
for (i = 0; i < rc->num_cfp; i++) {
if (rc->pcfp[i].freq == freq) {
cfp = &rc->pcfp[i];
break;
}
}
}
if (!cfp && freq)
PRINTM(MERROR, "%s: cannot find cfp by band %d & freq %d\n",
__func__, band, freq);
LEAVE();
return cfp;
}
#endif /* STA_SUPPORT */
/**
* @brief Check if Rate Auto
*
* @param pmpriv A pointer to mlan_private structure
*
* @return MTRUE or MFALSE
*/
t_u8 wlan_is_rate_auto(mlan_private *pmpriv)
{
t_u32 i;
int rate_num = 0;
ENTER();
for (i = 0; i < NELEMENTS(pmpriv->bitmap_rates); i++)
if (pmpriv->bitmap_rates[i])
rate_num++;
LEAVE();
if (rate_num > 1)
return MTRUE;
else
return MFALSE;
}
/**
* @brief Covert Rate Bitmap to Rate index
*
* @param pmadapter Pointer to mlan_adapter structure
* @param rate_bitmap Pointer to rate bitmap
* @param size Size of the bitmap array
*
* @return Rate index
*/
int wlan_get_rate_index(pmlan_adapter pmadapter, t_u16 *rate_bitmap, int size)
{
int i;
ENTER();
for (i = 0; i < size * 8; i++) {
if (rate_bitmap[i / 16] & (1 << (i % 16))) {
LEAVE();
return i;
}
}
LEAVE();
return -1;
}
/**
* @brief Get supported data rates
*
* @param pmpriv A pointer to mlan_private structure
* @param bss_mode The specified BSS mode (Infra/IBSS)
* @param config_bands The specified band configuration
* @param rates The buf to return the supported rates
*
* @return The number of Rates
*/
t_u32 wlan_get_supported_rates(mlan_private *pmpriv, t_u32 bss_mode,
t_u16 config_bands, WLAN_802_11_RATES rates)
{
t_u32 k = 0;
ENTER();
if (bss_mode == MLAN_BSS_MODE_INFRA) {
/* Infra. mode */
switch (config_bands) {
case (t_u8)BAND_B:
PRINTM(MINFO, "Infra Band=%d SupportedRates_B\n",
config_bands);
k = wlan_copy_rates(rates, k, SupportedRates_B,
sizeof(SupportedRates_B));
break;
case (t_u8)BAND_G:
case BAND_G | BAND_GN:
case BAND_G | BAND_GN | BAND_GAC:
case BAND_G | BAND_GN | BAND_GAC | BAND_GAX:
PRINTM(MINFO, "Infra band=%d SupportedRates_G\n",
config_bands);
k = wlan_copy_rates(rates, k, SupportedRates_G,
sizeof(SupportedRates_G));
break;
case BAND_B | BAND_G:
case BAND_A | BAND_B | BAND_G:
case BAND_A | BAND_B:
case BAND_A | BAND_B | BAND_G | BAND_GN:
case BAND_A | BAND_B | BAND_G | BAND_GN | BAND_AN:
case BAND_A | BAND_B | BAND_G | BAND_GN | BAND_AN | BAND_AAC:
case BAND_A | BAND_B | BAND_G | BAND_GN | BAND_AN | BAND_AAC |
BAND_GAC:
case BAND_A | BAND_B | BAND_G | BAND_GN | BAND_AN | BAND_AAC |
BAND_AAX:
case BAND_A | BAND_B | BAND_G | BAND_GN | BAND_AN | BAND_AAC |
BAND_GAC | BAND_AAX | BAND_GAX:
case BAND_B | BAND_G | BAND_GN:
case BAND_B | BAND_G | BAND_GN | BAND_GAC:
case BAND_B | BAND_G | BAND_GN | BAND_GAC | BAND_GAX:
PRINTM(MINFO, "Infra band=%d SupportedRates_BG\n",
config_bands);
#ifdef WIFI_DIRECT_SUPPORT
if (pmpriv->bss_type == MLAN_BSS_TYPE_WIFIDIRECT)
k = wlan_copy_rates(rates, k, SupportedRates_G,
sizeof(SupportedRates_G));
else
k = wlan_copy_rates(rates, k, SupportedRates_BG,
sizeof(SupportedRates_BG));
#else
k = wlan_copy_rates(rates, k, SupportedRates_BG,
sizeof(SupportedRates_BG));
#endif
break;
case BAND_A:
case BAND_A | BAND_G:
PRINTM(MINFO, "Infra band=%d SupportedRates_A\n",
config_bands);
k = wlan_copy_rates(rates, k, SupportedRates_A,
sizeof(SupportedRates_A));
break;
case BAND_AN:
case BAND_A | BAND_AN:
case BAND_A | BAND_G | BAND_AN | BAND_GN:
case BAND_A | BAND_AN | BAND_AAC:
case BAND_A | BAND_G | BAND_AN | BAND_GN | BAND_AAC:
case BAND_A | BAND_AN | BAND_AAC | BAND_AAX:
case BAND_A | BAND_G | BAND_AN | BAND_GN | BAND_AAC | BAND_AAX:
PRINTM(MINFO, "Infra band=%d SupportedRates_A\n",
config_bands);
k = wlan_copy_rates(rates, k, SupportedRates_A,
sizeof(SupportedRates_A));
break;
case BAND_GN:
case BAND_GN | BAND_GAC:
case BAND_GN | BAND_GAC | BAND_GAX:
PRINTM(MINFO, "Infra band=%d SupportedRates_N\n",
config_bands);
k = wlan_copy_rates(rates, k, SupportedRates_N,
sizeof(SupportedRates_N));
break;
}
} else {
/* Ad-hoc mode */
switch (config_bands) {
case (t_u8)BAND_B:
PRINTM(MINFO, "Band: Adhoc B\n");
k = wlan_copy_rates(rates, k, AdhocRates_B,
sizeof(AdhocRates_B));
break;
case (t_u8)BAND_G:
PRINTM(MINFO, "Band: Adhoc G only\n");
k = wlan_copy_rates(rates, k, AdhocRates_G,
sizeof(AdhocRates_G));
break;
case BAND_B | BAND_G:
PRINTM(MINFO, "Band: Adhoc BG\n");
k = wlan_copy_rates(rates, k, AdhocRates_BG,
sizeof(AdhocRates_BG));
break;
case BAND_A:
case BAND_A | BAND_AN | BAND_AAC:
case BAND_A | BAND_AN | BAND_AAC | BAND_AAX:
PRINTM(MINFO, "Band: Adhoc A\n");
k = wlan_copy_rates(rates, k, AdhocRates_A,
sizeof(AdhocRates_A));
break;
}
}
LEAVE();
return k;
}
#define COUNTRY_ID_US 0
#define COUNTRY_ID_JP 1
#define COUNTRY_ID_CN 2
#define COUNTRY_ID_EU 3
typedef struct _oper_bw_chan {
/*non-global operating class*/
t_u8 oper_class;
/*global operating class*/
t_u8 global_oper_class;
/*bandwidth 0-20M 1-40M 2-80M 3-160M*/
t_u8 bandwidth;
/*channel list*/
t_u8 channel_list[13];
} oper_bw_chan;
/** oper class table for US*/
static oper_bw_chan oper_bw_chan_us[] = {
/** non-Global oper class, global oper class, bandwidth, channel list*/
{1, 115, 0, {36, 40, 44, 48}},
{2, 118, 0, {52, 56, 60, 64}},
{3, 124, 0, {149, 153, 157, 161}},
{4,
121,
0,
{100, 104, 108, 112, 116, 120, 124, 128, 132, 136, 140, 144}},
{5, 125, 0, {149, 153, 157, 161, 165}},
{12, 81, 0, {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11}},
{22, 116, 1, {36, 44}},
{23, 119, 1, {52, 60}},
{24, 122, 1, {100, 108, 116, 124, 132, 140}},
{25, 126, 1, {149, 157}},
{26, 126, 1, {149, 157}},
{27, 117, 1, {40, 48}},
{28, 120, 1, {56, 64}},
{29, 123, 1, {104, 112, 120, 128, 136, 144}},
{30, 127, 1, {153, 161}},
{31, 127, 1, {153, 161}},
{32, 83, 1, {1, 2, 3, 4, 5, 6, 7}},
{33, 84, 1, {5, 6, 7, 8, 9, 10, 11}},
{128, 128, 2, {42, 58, 106, 122, 138, 155}},
{129, 129, 3, {50, 114}},
{130, 130, 2, {42, 58, 106, 122, 138, 155}},
};
/** oper class table for EU*/
static oper_bw_chan oper_bw_chan_eu[] = {
/** non-global oper class,global oper class, bandwidth, channel list*/
{1, 115, 0, {36, 40, 44, 48}},
{2, 118, 0, {52, 56, 60, 64}},
{3, 121, 0, {100, 104, 108, 112, 116, 120, 124, 128, 132, 136, 140}},
{4, 81, 0, {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13}},
{5, 116, 1, {36, 44}},
{6, 119, 1, {52, 60}},
{7, 122, 1, {100, 108, 116, 124, 132}},
{8, 117, 1, {40, 48}},
{9, 120, 1, {56, 64}},
{10, 123, 1, {104, 112, 120, 128, 136}},
{11, 83, 1, {1, 2, 3, 4, 5, 6, 7, 8, 9}},
{12, 84, 1, {5, 6, 7, 8, 9, 10, 11, 12, 13}},
{17, 125, 0, {149, 153, 157, 161, 165, 169}},
{128, 128, 2, {42, 58, 106, 122, 138, 155}},
{129, 129, 3, {50, 114}},
{130, 130, 2, {42, 58, 106, 122, 138, 155}},
};
/** oper class table for Japan*/
static oper_bw_chan oper_bw_chan_jp[] = {
/** non-Global oper class,global oper class, bandwidth, channel list*/
{1, 115, 0, {34, 38, 42, 46, 36, 40, 44, 48}},
{30, 81, 0, {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13}},
{31, 82, 0, {14}},
{32, 118, 0, {52, 56, 60, 64}},
{33, 118, 0, {52, 56, 60, 64}},
{34, 121, 0, {100, 104, 108, 112, 116, 120, 124, 128, 132, 136, 140}},
{35, 121, 0, {100, 104, 108, 112, 116, 120, 124, 128, 132, 136, 140}},
{36, 116, 1, {36, 44}},
{37, 119, 1, {52, 60}},
{38, 119, 1, {52, 60}},
{39, 122, 1, {100, 108, 116, 124, 132}},
{40, 122, 1, {100, 108, 116, 124, 132}},
{41, 117, 1, {40, 48}},
{42, 120, 1, {56, 64}},
{43, 120, 1, {56, 64}},
{44, 123, 1, {104, 112, 120, 128, 136}},
{45, 123, 1, {104, 112, 120, 128, 136}},
{56, 83, 1, {1, 2, 3, 4, 5, 6, 7, 8, 9}},
{57, 84, 1, {5, 6, 7, 8, 9, 10, 11, 12, 13}},
{58, 121, 0, {100, 104, 108, 112, 116, 120, 124, 128, 132, 136, 140}},
{128, 128, 2, {42, 58, 106, 122, 138, 155}},
{129, 129, 3, {50, 114}},
{130, 130, 2, {42, 58, 106, 122, 138, 155}},
};
/** oper class table for China*/
static oper_bw_chan oper_bw_chan_cn[] = {
/** non-Global oper class,global oper class, bandwidth, channel list*/
{1, 115, 0, {36, 40, 44, 48}},
{2, 118, 0, {52, 56, 60, 64}},
{3, 125, 0, {149, 153, 157, 161, 165}},
{4, 116, 1, {36, 44}},
{5, 119, 1, {52, 60}},
{6, 126, 1, {149, 157}},
{7, 81, 0, {1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13}},
{8, 83, 0, {1, 2, 3, 4, 5, 6, 7, 8, 9}},
{9, 84, 1, {5, 6, 7, 8, 9, 10, 11, 12, 13}},
{128, 128, 2, {42, 58, 106, 122, 138, 155}},
{129, 129, 3, {50, 114}},
{130, 130, 2, {42, 58, 106, 122, 138, 155}},
};
/**
* @brief Get non-global operaing class table according to country
*
* @param pmpriv A pointer to mlan_private structure
* @param arraysize A pointer to table size
*
* @return A pointer to oper_bw_chan
*/
static oper_bw_chan *wlan_get_nonglobal_operclass_table(mlan_private *pmpriv,
int *arraysize)
{
t_u8 country_code[][COUNTRY_CODE_LEN] = {"US", "JP", "CN"};
int country_id = 0;
oper_bw_chan *poper_bw_chan = MNULL;
ENTER();
for (country_id = 0; country_id < 3; country_id++)
if (!memcmp(pmpriv->adapter, pmpriv->adapter->country_code,
country_code[country_id], COUNTRY_CODE_LEN - 1))
break;
if (country_id >= 3)
country_id = COUNTRY_ID_US; /*Set default to US*/
if (wlan_is_etsi_country(pmpriv->adapter,
pmpriv->adapter->country_code))
country_id = COUNTRY_ID_EU; /** Country in EU */
switch (country_id) {
case COUNTRY_ID_US:
poper_bw_chan = oper_bw_chan_us;
*arraysize = sizeof(oper_bw_chan_us);
break;
case COUNTRY_ID_JP:
poper_bw_chan = oper_bw_chan_jp;
*arraysize = sizeof(oper_bw_chan_jp);
break;
case COUNTRY_ID_CN:
poper_bw_chan = oper_bw_chan_cn;
*arraysize = sizeof(oper_bw_chan_cn);
break;
case COUNTRY_ID_EU:
poper_bw_chan = oper_bw_chan_eu;
*arraysize = sizeof(oper_bw_chan_eu);
break;
default:
PRINTM(MERROR, "Country not support!\n");
break;
}
LEAVE();
return poper_bw_chan;
}
/**
* @brief Check validation of given channel and oper class
*
* @param pmpriv A pointer to mlan_private structure
* @param channel Channel number
* @param oper_class operating class
*
* @return MLAN_STATUS_PENDING --success, otherwise fail
*/
mlan_status wlan_check_operclass_validation(mlan_private *pmpriv, t_u8 channel,
t_u8 oper_class)
{
int arraysize = 0, i = 0, channum = 0;
oper_bw_chan *poper_bw_chan = MNULL;
t_u8 center_freq_idx = 0;
t_u8 center_freqs[] = {42, 50, 58, 106, 114, 122, 138, 155};
ENTER();
for (i = 0; i < (int)sizeof(center_freqs); i++) {
if (channel == center_freqs[i]) {
PRINTM(MERROR, "Invalid channel number %d!\n", channel);
LEAVE();
return MLAN_STATUS_FAILURE;
}
}
if (oper_class <= 0 || oper_class > 130) {
PRINTM(MERROR, "Invalid operating class!\n");
LEAVE();
return MLAN_STATUS_FAILURE;
}
if (oper_class >= 128) {
center_freq_idx = wlan_get_center_freq_idx(
pmpriv, BAND_AAC, channel, CHANNEL_BW_80MHZ);
channel = center_freq_idx;
}
poper_bw_chan = wlan_get_nonglobal_operclass_table(pmpriv, &arraysize);
if (!poper_bw_chan) {
PRINTM(MCMND, "Operating class table do not find!\n");
LEAVE();
return MLAN_STATUS_FAILURE;
}
for (i = 0; i < (int)(arraysize / sizeof(oper_bw_chan)); i++) {
if (poper_bw_chan[i].oper_class == oper_class ||
poper_bw_chan[i].global_oper_class == oper_class) {
for (channum = 0;
channum <
(int)sizeof(poper_bw_chan[i].channel_list);
channum++) {
if (poper_bw_chan[i].channel_list[channum] &&
poper_bw_chan[i].channel_list[channum] ==
channel) {
LEAVE();
return MLAN_STATUS_SUCCESS;
}
}
}
}
PRINTM(MCMND, "Operating class %d do not match channel %d!\n",
oper_class, channel);
LEAVE();
return MLAN_STATUS_FAILURE;
}
/**
* @brief Get current operating class from channel and bandwidth
*
* @param pmpriv A pointer to mlan_private structure
* @param channel Channel number
* @param bw Bandwidth
* @param oper_class A pointer to current operating class
*
* @return MLAN_STATUS_PENDING --success, otherwise fail
*/
mlan_status wlan_get_curr_oper_class(mlan_private *pmpriv, t_u8 channel,
t_u8 bw, t_u8 *oper_class)
{
oper_bw_chan *poper_bw_chan = MNULL;
t_u8 center_freq_idx = 0;
t_u8 center_freqs[] = {42, 50, 58, 106, 114, 122, 138, 155};
int i = 0, arraysize = 0, channum = 0;
ENTER();
poper_bw_chan = wlan_get_nonglobal_operclass_table(pmpriv, &arraysize);
if (!poper_bw_chan) {
PRINTM(MCMND, "Operating class table do not find!\n");
LEAVE();
return MLAN_STATUS_FAILURE;
}
for (i = 0; i < (int)sizeof(center_freqs); i++) {
if (channel == center_freqs[i]) {
PRINTM(MERROR, "Invalid channel number %d!\n", channel);
LEAVE();
return MLAN_STATUS_FAILURE;
}
}
if (bw == BW_80MHZ) {
center_freq_idx = wlan_get_center_freq_idx(
pmpriv, BAND_AAC, channel, CHANNEL_BW_80MHZ);
channel = center_freq_idx;
}
for (i = 0; i < (int)(arraysize / sizeof(oper_bw_chan)); i++) {
if (poper_bw_chan[i].bandwidth == bw) {
for (channum = 0;
channum <
(int)(sizeof(poper_bw_chan[i].channel_list));
channum++) {
if (poper_bw_chan[i].channel_list[channum] &&
poper_bw_chan[i].channel_list[channum] ==
channel) {
*oper_class =
poper_bw_chan[i].oper_class;
return MLAN_STATUS_SUCCESS;
}
}
}
}
PRINTM(MCMND, "Operating class not find!\n");
LEAVE();
return MLAN_STATUS_FAILURE;
}
/**
* @brief Add Supported operating classes IE
*
* @param pmpriv A pointer to mlan_private structure
* @param pptlv_out A pointer to TLV to fill in
* @param curr_oper_class Current operating class
*
* @return Length
*/
int wlan_add_supported_oper_class_ie(mlan_private *pmpriv, t_u8 **pptlv_out,
t_u8 curr_oper_class)
{
t_u8 oper_class_us[] = {1, 2, 3, 4, 5, 12, 22, 23, 24, 25, 26,
27, 28, 29, 30, 31, 32, 33, 128, 129, 130};
t_u8 oper_class_eu[] = {1, 2, 3, 4, 5, 6, 7, 8,
9, 10, 11, 12, 17, 128, 129, 130};
t_u8 oper_class_jp[] = {1, 30, 31, 32, 33, 34, 35, 36,
37, 38, 39, 40, 41, 42, 43, 44,
45, 56, 57, 58, 128, 129, 130};
t_u8 oper_class_cn[] = {1, 2, 3, 4, 5, 6, 7, 8, 9, 128, 129, 130};
t_u8 country_code[][COUNTRY_CODE_LEN] = {"US", "JP", "CN"};
int country_id = 0, ret = 0;
MrvlIETypes_SuppOperClass_t *poper_class = MNULL;
ENTER();
for (country_id = 0; country_id < 3; country_id++)
if (!memcmp(pmpriv->adapter, pmpriv->adapter->country_code,
country_code[country_id], COUNTRY_CODE_LEN - 1))
break;
if (country_id >= 3)
country_id = COUNTRY_ID_US; /*Set default to US*/
if (wlan_is_etsi_country(pmpriv->adapter,
pmpriv->adapter->country_code))
country_id = COUNTRY_ID_EU; /** Country in EU */
poper_class = (MrvlIETypes_SuppOperClass_t *)*pptlv_out;
memset(pmpriv->adapter, poper_class, 0,
sizeof(MrvlIETypes_SuppOperClass_t));
poper_class->header.type = wlan_cpu_to_le16(REGULATORY_CLASS);
if (country_id == COUNTRY_ID_US) {
poper_class->header.len = sizeof(oper_class_us);
memcpy_ext(pmpriv->adapter, &poper_class->oper_class,
oper_class_us, sizeof(oper_class_us),
poper_class->header.len);
} else if (country_id == COUNTRY_ID_JP) {
poper_class->header.len = sizeof(oper_class_jp);
memcpy_ext(pmpriv->adapter, &poper_class->oper_class,
oper_class_jp, sizeof(oper_class_jp),
poper_class->header.len);
} else if (country_id == COUNTRY_ID_CN) {
poper_class->header.len = sizeof(oper_class_cn);
memcpy_ext(pmpriv->adapter, &poper_class->oper_class,
oper_class_cn, sizeof(oper_class_cn),
poper_class->header.len);
} else if (country_id == COUNTRY_ID_EU) {
poper_class->header.len = sizeof(oper_class_eu);
memcpy_ext(pmpriv->adapter, &poper_class->oper_class,
oper_class_eu, sizeof(oper_class_eu),
poper_class->header.len);
}
poper_class->current_oper_class = curr_oper_class;
poper_class->header.len += sizeof(poper_class->current_oper_class);
DBG_HEXDUMP(MCMD_D, "Operating class", (t_u8 *)poper_class,
sizeof(MrvlIEtypesHeader_t) + poper_class->header.len);
ret = sizeof(MrvlIEtypesHeader_t) + poper_class->header.len;
*pptlv_out += ret;
poper_class->header.len = wlan_cpu_to_le16(poper_class->header.len);
LEAVE();
return ret;
}
/**
* @brief This function sets region table.
*
* @param pmpriv A pointer to mlan_private structure
* @param region The region code
* @param band The band
*
* @return MLAN_STATUS_SUCCESS or MLAN_STATUS_FAILURE
*/
mlan_status wlan_set_regiontable(mlan_private *pmpriv, t_u8 region, t_u8 band)
{
mlan_adapter *pmadapter = pmpriv->adapter;
int i = 0, j;
chan_freq_power_t *cfp;
int cfp_no;
region_chan_t region_chan_old[MAX_REGION_CHANNEL_NUM];
t_u8 cfp_code_bg = region;
t_u8 cfp_code_a = region;
ENTER();
memcpy_ext(pmadapter, region_chan_old, pmadapter->region_channel,
sizeof(pmadapter->region_channel), sizeof(region_chan_old));
memset(pmadapter, pmadapter->region_channel, 0,
sizeof(pmadapter->region_channel));
if (band & (BAND_B | BAND_G | BAND_GN)) {
if (pmadapter->cfp_code_bg)
cfp_code_bg = pmadapter->cfp_code_bg;
PRINTM(MCMND, "%s: 2.4G 0x%x\n", __func__, cfp_code_bg);
cfp = wlan_get_region_cfp_table(pmadapter, cfp_code_bg,
BAND_G | BAND_B | BAND_GN,
&cfp_no);
if (cfp) {
pmadapter->region_channel[i].num_cfp = (t_u8)cfp_no;
pmadapter->region_channel[i].pcfp = cfp;
} else {
PRINTM(MERROR, "wrong region code %#x in Band B-G\n",
region);
LEAVE();
return MLAN_STATUS_FAILURE;
}
pmadapter->region_channel[i].valid = MTRUE;
pmadapter->region_channel[i].region = region;
if (band & BAND_GN)
pmadapter->region_channel[i].band = BAND_G;
else
pmadapter->region_channel[i].band =
(band & BAND_G) ? BAND_G : BAND_B;
for (j = 0; j < MAX_REGION_CHANNEL_NUM; j++) {
if (region_chan_old[j].band & (BAND_B | BAND_G))
break;
}
if ((j < MAX_REGION_CHANNEL_NUM) &&
(region_chan_old[j].valid == MTRUE)) {
wlan_cfp_copy_dynamic(pmadapter, cfp, cfp_no,
region_chan_old[j].pcfp,
region_chan_old[j].num_cfp);
} else if (cfp) {
wlan_cfp_copy_dynamic(pmadapter, cfp, cfp_no, MNULL, 0);
}
i++;
}
if (band & (BAND_A | BAND_AN | BAND_AAC)) {
if (pmadapter->cfp_code_bg)
cfp_code_a = pmadapter->cfp_code_a;
PRINTM(MCMND, "%s: 5G 0x%x\n", __func__, cfp_code_a);
cfp = wlan_get_region_cfp_table(pmadapter, cfp_code_a, BAND_A,
&cfp_no);
if (cfp) {
pmadapter->region_channel[i].num_cfp = (t_u8)cfp_no;
pmadapter->region_channel[i].pcfp = cfp;
} else {
PRINTM(MERROR, "wrong region code %#x in Band A\n",
region);
LEAVE();
return MLAN_STATUS_FAILURE;
}
pmadapter->region_channel[i].valid = MTRUE;
pmadapter->region_channel[i].region = region;
pmadapter->region_channel[i].band = BAND_A;
for (j = 0; j < MAX_REGION_CHANNEL_NUM; j++) {
if (region_chan_old[j].band & BAND_A)
break;
}
if ((j < MAX_REGION_CHANNEL_NUM) && region_chan_old[j].valid) {
wlan_cfp_copy_dynamic(pmadapter, cfp, cfp_no,
region_chan_old[j].pcfp,
region_chan_old[j].num_cfp);
} else if (cfp) {
wlan_cfp_copy_dynamic(pmadapter, cfp, cfp_no, MNULL, 0);
}
}
LEAVE();
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Get if radar detection is enabled or not on a certain channel
*
* @param priv Private driver information structure
* @param chnl Channel to determine radar detection requirements
*
* @return
* - MTRUE if radar detection is required
* - MFALSE otherwise
*/
t_bool wlan_get_cfp_radar_detect(mlan_private *priv, t_u8 chnl)
{
int i, j;
t_bool required = MFALSE;
chan_freq_power_t *pcfp = MNULL;
ENTER();
/*get the cfp table first*/
for (i = 0; i < MAX_REGION_CHANNEL_NUM; i++) {
if (priv->adapter->region_channel[i].band == BAND_A) {
pcfp = priv->adapter->region_channel[i].pcfp;
break;
}
}
if (!pcfp) {
/* This means operation in BAND-A is not support, we can
* just return false here, it's harmless
*/
goto done;
}
/*get the radar detection requirements according to chan num*/
for (j = 0; j < priv->adapter->region_channel[i].num_cfp; j++) {
if (pcfp[j].channel == chnl) {
required = pcfp[j].passive_scan_or_radar_detect;
break;
}
}
done:
LEAVE();
return required;
}
/**
* @brief Get if scan type is passive or not on a certain channel for b/g band
*
* @param priv Private driver information structure
* @param chnl Channel to determine scan type
*
* @return
* - MTRUE if scan type is passive
* - MFALSE otherwise
*/
t_bool wlan_bg_scan_type_is_passive(mlan_private *priv, t_u8 chnl)
{
int i, j;
t_bool passive = MFALSE;
chan_freq_power_t *pcfp = MNULL;
ENTER();
/*get the cfp table first*/
for (i = 0; i < MAX_REGION_CHANNEL_NUM; i++) {
if (priv->adapter->region_channel[i].band & (BAND_B | BAND_G)) {
pcfp = priv->adapter->region_channel[i].pcfp;
break;
}
}
if (!pcfp) {
/*This means operation in BAND-B or BAND_G is not support, we
* can just return false here
*/
goto done;
}
/*get the bg scan type according to chan num*/
for (j = 0; j < priv->adapter->region_channel[i].num_cfp; j++) {
if (pcfp[j].channel == chnl) {
passive = pcfp[j].passive_scan_or_radar_detect;
break;
}
}
done:
LEAVE();
return passive;
}
/**
* @brief Get if a channel is NO_IR (passive) or not
*
* @param priv Private driver information structure
* @param band Band to check
* @param chan Channel to check
*
* @return
* - MTRUE if channel is passive
* - MFALSE otherwise
*/
t_bool wlan_is_chan_passive(mlan_private *priv, t_u8 band, t_u8 chan)
{
int i, j;
t_bool passive = MFALSE;
chan_freq_power_t *pcfp = MNULL;
ENTER();
/* get the cfp table first */
for (i = 0; i < MAX_REGION_CHANNEL_NUM; i++) {
if (priv->adapter->region_channel[i].band & band) {
pcfp = priv->adapter->region_channel[i].pcfp;
break;
}
}
if (pcfp) {
/* check table according to chan num */
for (j = 0; j < priv->adapter->region_channel[i].num_cfp; j++) {
if (pcfp[j].channel == chan) {
if (pcfp[j].dynamic.flags & NXP_CHANNEL_PASSIVE)
passive = MTRUE;
break;
}
}
}
LEAVE();
return passive;
}
/**
* @brief Get if a channel is disabled or not
*
* @param priv Private driver information structure
* @param band Band to check
* @param chan Channel to check
*
* @return
* - MTRUE if channel is disabled
* - MFALSE otherwise
*/
t_bool wlan_is_chan_disabled(mlan_private *priv, t_u8 band, t_u8 chan)
{
int i, j;
t_bool disabled = MFALSE;
chan_freq_power_t *pcfp = MNULL;
ENTER();
/* get the cfp table first */
for (i = 0; i < MAX_REGION_CHANNEL_NUM; i++) {
if (priv->adapter->region_channel[i].band & band) {
pcfp = priv->adapter->region_channel[i].pcfp;
break;
}
}
if (pcfp) {
/* check table according to chan num */
for (j = 0; j < priv->adapter->region_channel[i].num_cfp; j++) {
if (pcfp[j].channel == chan) {
if (pcfp[j].dynamic.flags &
NXP_CHANNEL_DISABLED)
disabled = MTRUE;
break;
}
}
}
LEAVE();
return disabled;
}
/**
* @brief Get if a channel is blacklisted or not
*
* @param priv Private driver information structure
* @param band Band to check
* @param chan Channel to check
*
* @return
* - MTRUE if channel is blacklisted
* - MFALSE otherwise
*/
t_bool wlan_is_chan_blacklisted(mlan_private *priv, t_u8 band, t_u8 chan)
{
int i, j;
t_bool blacklist = MFALSE;
chan_freq_power_t *pcfp = MNULL;
ENTER();
/*get the cfp table first*/
for (i = 0; i < MAX_REGION_CHANNEL_NUM; i++) {
if (priv->adapter->region_channel[i].band & band) {
pcfp = priv->adapter->region_channel[i].pcfp;
break;
}
}
if (pcfp) {
/*check table according to chan num*/
for (j = 0; j < priv->adapter->region_channel[i].num_cfp; j++) {
if (pcfp[j].channel == chan) {
blacklist = pcfp[j].dynamic.blacklist;
break;
}
}
}
LEAVE();
return blacklist;
}
/**
* @brief Set a channel as blacklisted or not
*
* @param priv Private driver information structure
* @param band Band to check
* @param chan Channel to check
* @param bl Blacklist if MTRUE
*
* @return
* - MTRUE if channel setting is updated
* - MFALSE otherwise
*/
t_bool wlan_set_chan_blacklist(mlan_private *priv, t_u8 band, t_u8 chan,
t_bool bl)
{
int i, j;
t_bool set_bl = MFALSE;
chan_freq_power_t *pcfp = MNULL;
ENTER();
/*get the cfp table first*/
for (i = 0; i < MAX_REGION_CHANNEL_NUM; i++) {
if (priv->adapter->region_channel[i].band & band) {
pcfp = priv->adapter->region_channel[i].pcfp;
break;
}
}
if (pcfp) {
/*check table according to chan num*/
for (j = 0; j < priv->adapter->region_channel[i].num_cfp; j++) {
if (pcfp[j].channel == chan) {
pcfp[j].dynamic.blacklist = bl;
set_bl = MTRUE;
break;
}
}
}
LEAVE();
return set_bl;
}
/**
* @brief Convert rateid in IEEE format to MRVL format
*
* @param priv Private driver information structure
* @param IeeeMacRate Rate in terms of IEEE format
* @param pmbuf A pointer to packet buffer
*
* @return
* Rate ID in terms of MRVL format
*/
t_u8 wlan_ieee_rateid_to_mrvl_rateid(mlan_private *priv, t_u16 IeeeMacRate,
t_u8 *dst_mac)
{
/* Set default rate ID to RATEID_DBPSK1Mbps */
t_u8 mrvlRATEID = 0;
const rate_map *rate_tbl = rate_map_table_1x1;
t_u32 cnt = sizeof(rate_map_table_1x1) / sizeof(rate_map);
t_u8 skip_nss2 = MTRUE;
t_u32 i = 0;
IEEEtypes_HTCap_t *htcap = MNULL;
t_u8 tx_mcs_supp = GET_TXMCSSUPP(priv->usr_dev_mcs_support);
#ifdef UAP_SUPPORT
psta_node sta_ptr = MNULL;
#endif
ENTER();
if (priv->adapter->hw_dev_mcs_support == HT_STREAM_MODE_2X2) {
rate_tbl = rate_map_table_2x2;
cnt = sizeof(rate_map_table_2x2) / sizeof(rate_map);
}
#ifdef UAP_SUPPORT
if (priv->bss_role == MLAN_BSS_ROLE_UAP) {
if (!dst_mac) {
LEAVE();
return mrvlRATEID;
}
sta_ptr = (sta_node *)util_peek_list(
priv->adapter->pmoal_handle, &priv->sta_list,
priv->adapter->callbacks.moal_spin_lock,
priv->adapter->callbacks.moal_spin_unlock);
if (!sta_ptr) {
LEAVE();
return mrvlRATEID;
}
while (sta_ptr != (sta_node *)&priv->sta_list) {
if (memcmp(priv->adapter, dst_mac, sta_ptr->mac_addr,
MLAN_MAC_ADDR_LENGTH)) {
htcap = &(sta_ptr->HTcap);
break;
}
sta_ptr = sta_ptr->pnext;
}
}
#endif
#ifdef STA_SUPPORT
if (priv->bss_role == MLAN_BSS_ROLE_STA)
htcap = priv->curr_bss_params.bss_descriptor.pht_cap;
#endif
if (htcap) {
/* If user configure tx to 2x2 and peer device rx is 2x2 */
if (tx_mcs_supp >= 2 && htcap->ht_cap.supported_mcs_set[1])
skip_nss2 = MFALSE;
}
for (i = 0; i < cnt; i++) {
if (rate_tbl[i].nss && skip_nss2)
continue;
if (rate_tbl[i].rate == IeeeMacRate) {
mrvlRATEID = rate_tbl[i].id;
break;
}
}
return mrvlRATEID;
}
/**
* @brief Convert rateid in MRVL format to IEEE format
*
* @param IeeeMacRate Rate in terms of MRVL format
*
* @return
* Rate ID in terms of IEEE format
*/
t_u8 wlan_mrvl_rateid_to_ieee_rateid(t_u8 rate)
{
return rateUnit_500Kbps[rate];
}
/**
* @brief sort cfp otp table
*
* @param pmapdater a pointer to mlan_adapter structure
*
* @return
* None
*/
static void wlan_sort_cfp_otp_table(mlan_adapter *pmadapter)
{
t_u8 c, d;
chan_freq_power_t *ch1;
chan_freq_power_t *ch2;
chan_freq_power_t swap;
if (pmadapter->tx_power_table_a_rows <= 1)
return;
for (c = 0; c < pmadapter->tx_power_table_a_rows - 1; c++) {
for (d = 0; d < pmadapter->tx_power_table_a_rows - c - 1; d++) {
ch1 = (chan_freq_power_t *)(pmadapter->cfp_otp_a + d);
ch2 = (chan_freq_power_t *)(pmadapter->cfp_otp_a + d +
1);
if (ch1->channel > ch2->channel) {
memcpy_ext(pmadapter, &swap, ch1,
sizeof(chan_freq_power_t),
sizeof(chan_freq_power_t));
memcpy_ext(pmadapter, ch1, ch2,
sizeof(chan_freq_power_t),
sizeof(chan_freq_power_t));
memcpy_ext(pmadapter, ch2, &swap,
sizeof(chan_freq_power_t),
sizeof(chan_freq_power_t));
}
}
}
}
/**
* @brief Update CFP tables and power tables from FW
*
* @param priv Private driver information structure
* @param buf Pointer to the buffer holding TLV data
* from 0x242 command response.
* @param buf_left bufsize
*
* @return
* None
*/
void wlan_add_fw_cfp_tables(pmlan_private pmpriv, t_u8 *buf, t_u16 buf_left)
{
mlan_adapter *pmadapter = pmpriv->adapter;
mlan_callbacks *pcb = (mlan_callbacks *)&pmadapter->callbacks;
MrvlIEtypesHeader_t *head;
t_u16 tlv;
t_u16 tlv_buf_len;
t_u16 tlv_buf_left;
t_u16 i;
int k = 0, rows, cols;
t_u16 max_tx_pwr_bg = WLAN_TX_PWR_DEFAULT;
t_u16 max_tx_pwr_a = WLAN_TX_PWR_DEFAULT;
t_u8 *tlv_buf;
t_u8 *data;
t_u8 *tmp;
mlan_status ret;
ENTER();
if (!buf) {
PRINTM(MERROR, "CFP table update failed!\n");
goto out;
}
if (pmadapter->otp_region) {
memset(pmadapter, pmadapter->region_channel, 0,
sizeof(pmadapter->region_channel));
wlan_free_fw_cfp_tables(pmadapter);
}
pmadapter->tx_power_table_bg_rows = FW_CFP_TABLE_MAX_ROWS_BG;
pmadapter->tx_power_table_bg_cols = FW_CFP_TABLE_MAX_COLS_BG;
pmadapter->tx_power_table_a_rows = FW_CFP_TABLE_MAX_ROWS_A;
pmadapter->tx_power_table_a_cols = FW_CFP_TABLE_MAX_COLS_A;
tlv_buf = (t_u8 *)buf;
tlv_buf_left = buf_left;
while (tlv_buf_left >= sizeof(*head)) {
head = (MrvlIEtypesHeader_t *)tlv_buf;
tlv = wlan_le16_to_cpu(head->type);
tlv_buf_len = wlan_le16_to_cpu(head->len);
if (tlv_buf_left < (sizeof(*head) + tlv_buf_len))
break;
data = (t_u8 *)head + sizeof(*head);
switch (tlv) {
case TLV_TYPE_REGION_INFO:
/* Skip adding fw region info if it already exists or
* if this TLV has no set data
*/
if (*data == 0)
break;
if (pmadapter->otp_region)
break;
ret = pcb->moal_malloc(pmadapter->pmoal_handle,
sizeof(otp_region_info_t),
MLAN_MEM_DEF,
(t_u8 **)&pmadapter->otp_region);
if (ret != MLAN_STATUS_SUCCESS ||
!pmadapter->otp_region) {
PRINTM(MERROR,
"Memory allocation for the otp region info struct failed!\n");
break;
}
/* Save region info values from OTP in the otp_region
* structure
*/
memcpy_ext(pmadapter, pmadapter->otp_region, data,
sizeof(otp_region_info_t),
sizeof(otp_region_info_t));
data += sizeof(otp_region_info_t);
/* Get pre-defined cfp tables corresponding to the
* region code in OTP
*/
for (i = 0; i < MLAN_CFP_TABLE_SIZE_BG; i++) {
if (cfp_table_BG[i].code ==
pmadapter->otp_region->region_code) {
max_tx_pwr_bg = (cfp_table_BG[i].cfp)
->max_tx_power;
break;
}
}
for (i = 0; i < MLAN_CFP_TABLE_SIZE_A; i++) {
if (cfp_table_A[i].code ==
pmadapter->otp_region->region_code) {
max_tx_pwr_a = (cfp_table_A[i].cfp)
->max_tx_power;
break;
}
}
/* Update the region code and the country code in
* pmadapter
*/
pmadapter->region_code =
pmadapter->otp_region->region_code;
pmadapter->country_code[0] =
pmadapter->otp_region->country_code[0];
pmadapter->country_code[1] =
pmadapter->otp_region->country_code[1];
pmadapter->country_code[2] = '\0';
pmadapter->domain_reg.country_code[0] =
pmadapter->otp_region->country_code[0];
pmadapter->domain_reg.country_code[1] =
pmadapter->otp_region->country_code[1];
pmadapter->domain_reg.country_code[2] = '\0';
PRINTM(MCMND, "OTP region: region_code=%d %c%c\n",
pmadapter->otp_region->region_code,
pmadapter->country_code[0],
pmadapter->country_code[1]);
pmadapter->cfp_code_bg =
pmadapter->otp_region->region_code;
pmadapter->cfp_code_a =
pmadapter->otp_region->region_code;
break;
case TLV_TYPE_CHAN_ATTR_CFG:
/* Skip adding fw cfp tables if they already exist or
* if this TLV has no set data
*/
if (*data == 0)
break;
if (pmadapter->cfp_otp_bg || pmadapter->cfp_otp_a) {
break;
}
ret = pcb->moal_malloc(
pmadapter->pmoal_handle,
pmadapter->tx_power_table_bg_rows *
sizeof(chan_freq_power_t),
MLAN_MEM_DEF, (t_u8 **)&pmadapter->cfp_otp_bg);
if (ret != MLAN_STATUS_SUCCESS ||
!pmadapter->cfp_otp_bg) {
PRINTM(MERROR,
"Memory allocation for storing otp bg table data failed!\n");
break;
}
/* Save channel usability flags from OTP data in the fw
* cfp bg table and set frequency and max_tx_power
* values
*/
for (i = 0; i < pmadapter->tx_power_table_bg_rows;
i++) {
(pmadapter->cfp_otp_bg + i)->channel = *data;
if (*data == 14)
(pmadapter->cfp_otp_bg + i)->freq =
2484;
else
(pmadapter->cfp_otp_bg + i)->freq =
2412 + 5 * (*data - 1);
(pmadapter->cfp_otp_bg + i)->max_tx_power =
max_tx_pwr_bg;
data++;
(pmadapter->cfp_otp_bg + i)->dynamic.flags =
*data;
if (*data & NXP_CHANNEL_DFS)
(pmadapter->cfp_otp_bg + i)
->passive_scan_or_radar_detect =
MTRUE;
PRINTM(MCMD_D,
"OTP Region (BG): chan=%d flags=0x%x\n",
(pmadapter->cfp_otp_bg + i)->channel,
(pmadapter->cfp_otp_bg + i)
->dynamic.flags);
data++;
}
ret = pcb->moal_malloc(
pmadapter->pmoal_handle,
pmadapter->tx_power_table_a_rows *
sizeof(chan_freq_power_t),
MLAN_MEM_DEF, (t_u8 **)&pmadapter->cfp_otp_a);
if (ret != MLAN_STATUS_SUCCESS ||
!pmadapter->cfp_otp_a) {
PRINTM(MERROR,
"Memory allocation for storing otp a table data failed!\n");
break;
}
/* Save channel usability flags from OTP data in the fw
* cfp a table and set frequency and max_tx_power values
*/
for (i = 0; i < pmadapter->tx_power_table_a_rows; i++) {
(pmadapter->cfp_otp_a + i)->channel = *data;
if (*data < 183)
/* 5GHz channels */
(pmadapter->cfp_otp_a + i)->freq =
5035 + 5 * (*data - 7);
else
/* 4GHz channels */
(pmadapter->cfp_otp_a + i)->freq =
4915 + 5 * (*data - 183);
(pmadapter->cfp_otp_a + i)->max_tx_power =
max_tx_pwr_a;
data++;
(pmadapter->cfp_otp_a + i)->dynamic.flags =
*data;
if (*data & NXP_CHANNEL_DFS)
(pmadapter->cfp_otp_a + i)
->passive_scan_or_radar_detect =
MTRUE;
PRINTM(MCMD_D,
"OTP Region (A): chan=%d flags=0x%x\n",
(pmadapter->cfp_otp_a + i)->channel,
(pmadapter->cfp_otp_a + i)
->dynamic.flags);
data++;
}
break;
case TLV_TYPE_POWER_TABLE:
/* Skip adding fw power tables if this TLV has no data
* or if they already exists but force reg rule is set
* in the otp
*/
if (*data == 0)
break;
if (pmadapter->otp_region &&
pmadapter->otp_region->force_reg &&
pmadapter->tx_power_table_bg)
break;
/* Save the tlv data in power tables for band BG and A
*/
tmp = data;
i = 0;
while ((i <
pmadapter->tx_power_table_bg_rows *
pmadapter->tx_power_table_bg_cols) &&
(i < tlv_buf_len) && (*tmp != 36)) {
i++;
tmp++;
}
if (!pmadapter->tx_power_table_bg) {
ret = pcb->moal_malloc(
pmadapter->pmoal_handle, i,
MLAN_MEM_DEF,
(t_u8 **)&pmadapter->tx_power_table_bg);
if (ret != MLAN_STATUS_SUCCESS ||
!pmadapter->tx_power_table_bg) {
PRINTM(MERROR,
"Memory allocation for the BG-band power table failed!\n");
break;
}
}
memcpy_ext(pmadapter, pmadapter->tx_power_table_bg,
data, i, i);
pmadapter->tx_power_table_bg_size = i;
data += i;
i = 0;
while ((i < pmadapter->tx_power_table_a_rows *
pmadapter->tx_power_table_a_cols) &&
(i < (tlv_buf_len -
pmadapter->tx_power_table_bg_size))) {
i++;
}
if (!pmadapter->tx_power_table_a) {
ret = pcb->moal_malloc(
pmadapter->pmoal_handle, i,
MLAN_MEM_DEF,
(t_u8 **)&pmadapter->tx_power_table_a);
if (ret != MLAN_STATUS_SUCCESS ||
!pmadapter->tx_power_table_a) {
PRINTM(MERROR,
"Memory allocation for the A-band power table failed!\n");
break;
}
}
memcpy_ext(pmadapter, pmadapter->tx_power_table_a, data,
i, i);
pmadapter->tx_power_table_a_size = i;
break;
case TLV_TYPE_POWER_TABLE_ATTR:
pmadapter->tx_power_table_bg_rows =
((power_table_attr_t *)data)->rows_2g;
pmadapter->tx_power_table_bg_cols =
((power_table_attr_t *)data)->cols_2g;
pmadapter->tx_power_table_a_rows =
((power_table_attr_t *)data)->rows_5g;
pmadapter->tx_power_table_a_cols =
((power_table_attr_t *)data)->cols_5g;
PRINTM(MCMD_D, "OTP region: bg_row=%d, a_row=%d\n",
pmadapter->tx_power_table_bg_rows,
pmadapter->tx_power_table_a_rows);
break;
default:
break;
}
tlv_buf += (sizeof(*head) + tlv_buf_len);
tlv_buf_left -= (sizeof(*head) + tlv_buf_len);
}
if (!pmadapter->cfp_otp_bg || !pmadapter->tx_power_table_bg)
goto out;
/* Set remaining flags for BG */
rows = pmadapter->tx_power_table_bg_rows;
cols = pmadapter->tx_power_table_bg_cols;
for (i = 0; i < rows; i++) {
k = (i * cols) + 1;
if ((pmadapter->cfp_otp_bg + i)->dynamic.flags &
NXP_CHANNEL_DISABLED)
continue;
if (pmadapter->tx_power_table_bg[k + MOD_CCK] == 0)
(pmadapter->cfp_otp_bg + i)->dynamic.flags |=
NXP_CHANNEL_NO_CCK;
if (pmadapter->tx_power_table_bg[k + MOD_OFDM_PSK] == 0 &&
pmadapter->tx_power_table_bg[k + MOD_OFDM_QAM16] == 0 &&
pmadapter->tx_power_table_bg[k + MOD_OFDM_QAM64] == 0) {
(pmadapter->cfp_otp_bg + i)->dynamic.flags |=
NXP_CHANNEL_NO_OFDM;
}
}
if (pmadapter->cfp_otp_a)
wlan_sort_cfp_otp_table(pmadapter);
out:
LEAVE();
}
/**
* @brief This function deallocates otp cfp and power tables memory.
*
* @param pmadapter A pointer to mlan_adapter structure
*/
void wlan_free_fw_cfp_tables(mlan_adapter *pmadapter)
{
pmlan_callbacks pcb;
ENTER();
pcb = &pmadapter->callbacks;
if (pmadapter->otp_region)
pcb->moal_mfree(pmadapter->pmoal_handle,
(t_u8 *)pmadapter->otp_region);
if (pmadapter->cfp_otp_bg)
pcb->moal_mfree(pmadapter->pmoal_handle,
(t_u8 *)pmadapter->cfp_otp_bg);
if (pmadapter->tx_power_table_bg)
pcb->moal_mfree(pmadapter->pmoal_handle,
(t_u8 *)pmadapter->tx_power_table_bg);
pmadapter->otp_region = MNULL;
pmadapter->cfp_otp_bg = MNULL;
pmadapter->tx_power_table_bg = MNULL;
pmadapter->tx_power_table_bg_size = 0;
if (pmadapter->cfp_otp_a)
pcb->moal_mfree(pmadapter->pmoal_handle,
(t_u8 *)pmadapter->cfp_otp_a);
if (pmadapter->tx_power_table_a)
pcb->moal_mfree(pmadapter->pmoal_handle,
(t_u8 *)pmadapter->tx_power_table_a);
pmadapter->cfp_otp_a = MNULL;
pmadapter->tx_power_table_a = MNULL;
pmadapter->tx_power_table_a_size = 0;
LEAVE();
}
/**
* @brief Get DFS chan list
*
* @param pmadapter Pointer to mlan_adapter
* @param pioctl_req Pointer to mlan_ioctl_req
*
* @return MLAN_STATUS_SUCCESS or MLAN_STATUS_FAILURE
*/
mlan_status wlan_get_cfp_table(pmlan_adapter pmadapter,
pmlan_ioctl_req pioctl_req)
{
mlan_ds_misc_cfg *ds_misc_cfg = MNULL;
mlan_status ret = MLAN_STATUS_FAILURE;
chan_freq_power_t *cfp = MNULL;
t_u32 cfp_no = 0;
ENTER();
if (pioctl_req) {
ds_misc_cfg = (mlan_ds_misc_cfg *)pioctl_req->pbuf;
if (pioctl_req->action == MLAN_ACT_GET) {
cfp = wlan_get_region_cfp_table(
pmadapter, pmadapter->region_code,
ds_misc_cfg->param.cfp.band, &cfp_no);
if (cfp) {
ds_misc_cfg->param.cfp.num_chan = cfp_no;
memcpy_ext(pmadapter,
ds_misc_cfg->param.cfp.cfp_tbl, cfp,
cfp_no * sizeof(chan_freq_power_t),
cfp_no * sizeof(chan_freq_power_t));
}
ret = MLAN_STATUS_SUCCESS;
}
}
LEAVE();
return ret;
}
/**
* @brief Get power tables and cfp tables for set region code
* into the IOCTL request buffer
*
* @param pmadapter Private mlan adapter structure
* @param pioctl_req Pointer to the IOCTL request structure
*
* @return success, otherwise fail
*
*/
mlan_status wlan_get_cfpinfo(pmlan_adapter pmadapter,
pmlan_ioctl_req pioctl_req)
{
chan_freq_power_t *cfp_bg = MNULL;
t_u32 cfp_no_bg = 0;
chan_freq_power_t *cfp_a = MNULL;
t_u32 cfp_no_a = 0;
t_u8 cfp_code_a = pmadapter->region_code;
t_u8 cfp_code_bg = pmadapter->region_code;
t_u32 len = 0, size = 0;
t_u8 *req_buf, *tmp;
mlan_status ret = MLAN_STATUS_SUCCESS;
ENTER();
if (!pioctl_req || !pioctl_req->pbuf) {
PRINTM(MERROR, "MLAN IOCTL information is not present!\n");
ret = MLAN_STATUS_FAILURE;
goto out;
}
/* Calculate the total response size required to return region,
* country codes, cfp tables and power tables
*/
size = sizeof(pmadapter->country_code) + sizeof(pmadapter->region_code);
/* Add size to store region, country and environment codes */
size += sizeof(t_u32);
if (pmadapter->cfp_code_bg)
cfp_code_bg = pmadapter->cfp_code_bg;
/* Get cfp table and its size corresponding to the region code */
cfp_bg = wlan_get_region_cfp_table(pmadapter, cfp_code_bg,
BAND_G | BAND_B, &cfp_no_bg);
size += cfp_no_bg * sizeof(chan_freq_power_t);
if (pmadapter->cfp_code_a)
cfp_code_a = pmadapter->cfp_code_a;
cfp_a = wlan_get_region_cfp_table(pmadapter, cfp_code_a, BAND_A,
&cfp_no_a);
size += cfp_no_a * sizeof(chan_freq_power_t);
if (pmadapter->otp_region)
size += sizeof(pmadapter->otp_region->environment);
/* Get power table size */
if (pmadapter->tx_power_table_bg) {
size += pmadapter->tx_power_table_bg_size;
/* Add size to store table size, rows and cols */
size += 3 * sizeof(t_u32);
}
if (pmadapter->tx_power_table_a) {
size += pmadapter->tx_power_table_a_size;
size += 3 * sizeof(t_u32);
}
/* Check information buffer length of MLAN IOCTL */
if (pioctl_req->buf_len < size) {
PRINTM(MWARN,
"MLAN IOCTL information buffer length is too short.\n");
pioctl_req->buf_len_needed = size;
pioctl_req->status_code = MLAN_ERROR_INVALID_PARAMETER;
ret = MLAN_STATUS_RESOURCE;
goto out;
}
/* Copy the total size of region code, country code and environment
* in first four bytes of the IOCTL request buffer and then copy
* codes respectively in following bytes
*/
req_buf = (t_u8 *)pioctl_req->pbuf;
size = sizeof(pmadapter->country_code) + sizeof(pmadapter->region_code);
if (pmadapter->otp_region)
size += sizeof(pmadapter->otp_region->environment);
tmp = (t_u8 *)&size;
memcpy_ext(pmadapter, req_buf, tmp, sizeof(size), sizeof(size));
len += sizeof(size);
memcpy_ext(pmadapter, req_buf + len, &pmadapter->region_code,
sizeof(pmadapter->region_code),
sizeof(pmadapter->region_code));
len += sizeof(pmadapter->region_code);
memcpy_ext(pmadapter, req_buf + len, &pmadapter->country_code,
sizeof(pmadapter->country_code),
sizeof(pmadapter->country_code));
len += sizeof(pmadapter->country_code);
if (pmadapter->otp_region) {
memcpy_ext(pmadapter, req_buf + len,
&pmadapter->otp_region->environment,
sizeof(pmadapter->otp_region->environment),
sizeof(pmadapter->otp_region->environment));
len += sizeof(pmadapter->otp_region->environment);
}
/* copy the cfp table size followed by the entire table */
if (!cfp_bg)
goto out;
size = cfp_no_bg * sizeof(chan_freq_power_t);
memcpy_ext(pmadapter, req_buf + len, tmp, sizeof(size), sizeof(size));
len += sizeof(size);
memcpy_ext(pmadapter, req_buf + len, cfp_bg, size, size);
len += size;
if (!cfp_a)
goto out;
size = cfp_no_a * sizeof(chan_freq_power_t);
memcpy_ext(pmadapter, req_buf + len, tmp, sizeof(size), sizeof(size));
len += sizeof(size);
memcpy_ext(pmadapter, req_buf + len, cfp_a, size, size);
len += size;
/* Copy the size of the power table, number of rows, number of cols
* and the entire power table
*/
if (!pmadapter->tx_power_table_bg)
goto out;
size = pmadapter->tx_power_table_bg_size;
memcpy_ext(pmadapter, req_buf + len, tmp, sizeof(size), sizeof(size));
len += sizeof(size);
/* No. of rows */
size = pmadapter->tx_power_table_bg_rows;
memcpy_ext(pmadapter, req_buf + len, tmp, sizeof(size), sizeof(size));
len += sizeof(size);
/* No. of cols */
size = pmadapter->tx_power_table_bg_size /
pmadapter->tx_power_table_bg_rows;
memcpy_ext(pmadapter, req_buf + len, tmp, sizeof(size), sizeof(size));
len += sizeof(size);
memcpy_ext(pmadapter, req_buf + len, pmadapter->tx_power_table_bg,
pmadapter->tx_power_table_bg_size,
pmadapter->tx_power_table_bg_size);
len += pmadapter->tx_power_table_bg_size;
if (!pmadapter->tx_power_table_a)
goto out;
size = pmadapter->tx_power_table_a_size;
memcpy_ext(pmadapter, req_buf + len, tmp, sizeof(size), sizeof(size));
len += sizeof(size);
/* No. of rows */
size = pmadapter->tx_power_table_a_rows;
memcpy_ext(pmadapter, req_buf + len, tmp, sizeof(size), sizeof(size));
len += sizeof(size);
/* No. of cols */
size = pmadapter->tx_power_table_a_size /
pmadapter->tx_power_table_a_rows;
memcpy_ext(pmadapter, req_buf + len, tmp, sizeof(size), sizeof(size));
len += sizeof(size);
memcpy_ext(pmadapter, req_buf + len, pmadapter->tx_power_table_a,
pmadapter->tx_power_table_a_size,
pmadapter->tx_power_table_a_size);
len += pmadapter->tx_power_table_a_size;
out:
if (pioctl_req)
pioctl_req->data_read_written = len;
LEAVE();
return ret;
}