ar9003_eeprom.c 62.7 KB
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/*
 * Copyright (c) 2010 Atheros Communications Inc.
 *
 * Permission to use, copy, modify, and/or distribute this software for any
 * purpose with or without fee is hereby granted, provided that the above
 * copyright notice and this permission notice appear in all copies.
 *
 * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
 * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
 * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
 * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
 * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
 * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
 * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
 */

#include "hw.h"
#include "ar9003_phy.h"
#include "ar9003_eeprom.h"

#define COMP_HDR_LEN 4
#define COMP_CKSUM_LEN 2

#define AR_CH0_TOP (0x00016288)
#define AR_CH0_TOP_XPABIASLVL (0x3)
#define AR_CH0_TOP_XPABIASLVL_S (8)

#define AR_CH0_THERM (0x00016290)
#define AR_CH0_THERM_SPARE (0x3f)
#define AR_CH0_THERM_SPARE_S (0)

#define AR_SWITCH_TABLE_COM_ALL (0xffff)
#define AR_SWITCH_TABLE_COM_ALL_S (0)

#define AR_SWITCH_TABLE_COM2_ALL (0xffffff)
#define AR_SWITCH_TABLE_COM2_ALL_S (0)

#define AR_SWITCH_TABLE_ALL (0xfff)
#define AR_SWITCH_TABLE_ALL_S (0)

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#define LE16(x) __constant_cpu_to_le16(x)
#define LE32(x) __constant_cpu_to_le32(x)

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/* Local defines to distinguish between extension and control CTL's */
#define EXT_ADDITIVE (0x8000)
#define CTL_11A_EXT (CTL_11A | EXT_ADDITIVE)
#define CTL_11G_EXT (CTL_11G | EXT_ADDITIVE)
#define CTL_11B_EXT (CTL_11B | EXT_ADDITIVE)
#define REDUCE_SCALED_POWER_BY_TWO_CHAIN     6  /* 10*log10(2)*2 */
#define REDUCE_SCALED_POWER_BY_THREE_CHAIN   9  /* 10*log10(3)*2 */
#define PWRINCR_3_TO_1_CHAIN      9             /* 10*log(3)*2 */
#define PWRINCR_3_TO_2_CHAIN      3             /* floor(10*log(3/2)*2) */
#define PWRINCR_2_TO_1_CHAIN      6             /* 10*log(2)*2 */

#define SUB_NUM_CTL_MODES_AT_5G_40 2    /* excluding HT40, EXT-OFDM */
#define SUB_NUM_CTL_MODES_AT_2G_40 3    /* excluding HT40, EXT-OFDM, EXT-CCK */

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static const struct ar9300_eeprom ar9300_default = {
	.eepromVersion = 2,
	.templateVersion = 2,
	.macAddr = {1, 2, 3, 4, 5, 6},
	.custData = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
		     0, 0, 0, 0, 0, 0, 0, 0, 0, 0},
	.baseEepHeader = {
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		.regDmn = { LE16(0), LE16(0x1f) },
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		.txrxMask =  0x77, /* 4 bits tx and 4 bits rx */
		.opCapFlags = {
			.opFlags = AR9300_OPFLAGS_11G | AR9300_OPFLAGS_11A,
			.eepMisc = 0,
		},
		.rfSilent = 0,
		.blueToothOptions = 0,
		.deviceCap = 0,
		.deviceType = 5, /* takes lower byte in eeprom location */
		.pwrTableOffset = AR9300_PWR_TABLE_OFFSET,
		.params_for_tuning_caps = {0, 0},
		.featureEnable = 0x0c,
		 /*
		  * bit0 - enable tx temp comp - disabled
		  * bit1 - enable tx volt comp - disabled
		  * bit2 - enable fastClock - enabled
		  * bit3 - enable doubling - enabled
		  * bit4 - enable internal regulator - disabled
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		  * bit5 - enable pa predistortion - disabled
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		  */
		.miscConfiguration = 0, /* bit0 - turn down drivestrength */
		.eepromWriteEnableGpio = 3,
		.wlanDisableGpio = 0,
		.wlanLedGpio = 8,
		.rxBandSelectGpio = 0xff,
		.txrxgain = 0,
		.swreg = 0,
	 },
	.modalHeader2G = {
	/* ar9300_modal_eep_header  2g */
		/* 4 idle,t1,t2,b(4 bits per setting) */
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		.antCtrlCommon = LE32(0x110),
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		/* 4 ra1l1, ra2l1, ra1l2, ra2l2, ra12 */
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		.antCtrlCommon2 = LE32(0x22222),
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		/*
		 * antCtrlChain[AR9300_MAX_CHAINS]; 6 idle, t, r,
		 * rx1, rx12, b (2 bits each)
		 */
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		.antCtrlChain = { LE16(0x150), LE16(0x150), LE16(0x150) },
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		/*
		 * xatten1DB[AR9300_MAX_CHAINS];  3 xatten1_db
		 * for ar9280 (0xa20c/b20c 5:0)
		 */
		.xatten1DB = {0, 0, 0},

		/*
		 * xatten1Margin[AR9300_MAX_CHAINS]; 3 xatten1_margin
		 * for ar9280 (0xa20c/b20c 16:12
		 */
		.xatten1Margin = {0, 0, 0},
		.tempSlope = 36,
		.voltSlope = 0,

		/*
		 * spurChans[OSPREY_EEPROM_MODAL_SPURS]; spur
		 * channels in usual fbin coding format
		 */
		.spurChans = {0, 0, 0, 0, 0},

		/*
		 * noiseFloorThreshCh[AR9300_MAX_CHAINS]; 3 Check
		 * if the register is per chain
		 */
		.noiseFloorThreshCh = {-1, 0, 0},
		.ob = {1, 1, 1},/* 3 chain */
		.db_stage2 = {1, 1, 1}, /* 3 chain  */
		.db_stage3 = {0, 0, 0},
		.db_stage4 = {0, 0, 0},
		.xpaBiasLvl = 0,
		.txFrameToDataStart = 0x0e,
		.txFrameToPaOn = 0x0e,
		.txClip = 3, /* 4 bits tx_clip, 4 bits dac_scale_cck */
		.antennaGain = 0,
		.switchSettling = 0x2c,
		.adcDesiredSize = -30,
		.txEndToXpaOff = 0,
		.txEndToRxOn = 0x2,
		.txFrameToXpaOn = 0xe,
		.thresh62 = 28,
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		.papdRateMaskHt20 = LE32(0x80c080),
		.papdRateMaskHt40 = LE32(0x80c080),
		.futureModal = {
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			0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
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			0, 0, 0, 0, 0, 0, 0, 0
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		},
	 },
	.calFreqPier2G = {
		FREQ2FBIN(2412, 1),
		FREQ2FBIN(2437, 1),
		FREQ2FBIN(2472, 1),
	 },
	/* ar9300_cal_data_per_freq_op_loop 2g */
	.calPierData2G = {
		{ {0, 0, 0, 0, 0, 0}, {0, 0, 0, 0, 0, 0}, {0, 0, 0, 0, 0, 0} },
		{ {0, 0, 0, 0, 0, 0}, {0, 0, 0, 0, 0, 0}, {0, 0, 0, 0, 0, 0} },
		{ {0, 0, 0, 0, 0, 0}, {0, 0, 0, 0, 0, 0}, {0, 0, 0, 0, 0, 0} },
	 },
	.calTarget_freqbin_Cck = {
		FREQ2FBIN(2412, 1),
		FREQ2FBIN(2484, 1),
	 },
	.calTarget_freqbin_2G = {
		FREQ2FBIN(2412, 1),
		FREQ2FBIN(2437, 1),
		FREQ2FBIN(2472, 1)
	 },
	.calTarget_freqbin_2GHT20 = {
		FREQ2FBIN(2412, 1),
		FREQ2FBIN(2437, 1),
		FREQ2FBIN(2472, 1)
	 },
	.calTarget_freqbin_2GHT40 = {
		FREQ2FBIN(2412, 1),
		FREQ2FBIN(2437, 1),
		FREQ2FBIN(2472, 1)
	 },
	.calTargetPowerCck = {
		 /* 1L-5L,5S,11L,11S */
		 { {36, 36, 36, 36} },
		 { {36, 36, 36, 36} },
	},
	.calTargetPower2G = {
		 /* 6-24,36,48,54 */
		 { {32, 32, 28, 24} },
		 { {32, 32, 28, 24} },
		 { {32, 32, 28, 24} },
	},
	.calTargetPower2GHT20 = {
		{ {32, 32, 32, 32, 28, 20, 32, 32, 28, 20, 32, 32, 28, 20} },
		{ {32, 32, 32, 32, 28, 20, 32, 32, 28, 20, 32, 32, 28, 20} },
		{ {32, 32, 32, 32, 28, 20, 32, 32, 28, 20, 32, 32, 28, 20} },
	},
	.calTargetPower2GHT40 = {
		{ {32, 32, 32, 32, 28, 20, 32, 32, 28, 20, 32, 32, 28, 20} },
		{ {32, 32, 32, 32, 28, 20, 32, 32, 28, 20, 32, 32, 28, 20} },
		{ {32, 32, 32, 32, 28, 20, 32, 32, 28, 20, 32, 32, 28, 20} },
	},
	.ctlIndex_2G =  {
		0x11, 0x12, 0x15, 0x17, 0x41, 0x42,
		0x45, 0x47, 0x31, 0x32, 0x35, 0x37,
	},
	.ctl_freqbin_2G = {
		{
			FREQ2FBIN(2412, 1),
			FREQ2FBIN(2417, 1),
			FREQ2FBIN(2457, 1),
			FREQ2FBIN(2462, 1)
		},
		{
			FREQ2FBIN(2412, 1),
			FREQ2FBIN(2417, 1),
			FREQ2FBIN(2462, 1),
			0xFF,
		},

		{
			FREQ2FBIN(2412, 1),
			FREQ2FBIN(2417, 1),
			FREQ2FBIN(2462, 1),
			0xFF,
		},
		{
			FREQ2FBIN(2422, 1),
			FREQ2FBIN(2427, 1),
			FREQ2FBIN(2447, 1),
			FREQ2FBIN(2452, 1)
		},

		{
			/* Data[4].ctlEdges[0].bChannel */ FREQ2FBIN(2412, 1),
			/* Data[4].ctlEdges[1].bChannel */ FREQ2FBIN(2417, 1),
			/* Data[4].ctlEdges[2].bChannel */ FREQ2FBIN(2472, 1),
			/* Data[4].ctlEdges[3].bChannel */ FREQ2FBIN(2484, 1),
		},

		{
			/* Data[5].ctlEdges[0].bChannel */ FREQ2FBIN(2412, 1),
			/* Data[5].ctlEdges[1].bChannel */ FREQ2FBIN(2417, 1),
			/* Data[5].ctlEdges[2].bChannel */ FREQ2FBIN(2472, 1),
			0,
		},

		{
			/* Data[6].ctlEdges[0].bChannel */ FREQ2FBIN(2412, 1),
			/* Data[6].ctlEdges[1].bChannel */ FREQ2FBIN(2417, 1),
			FREQ2FBIN(2472, 1),
			0,
		},

		{
			/* Data[7].ctlEdges[0].bChannel */ FREQ2FBIN(2422, 1),
			/* Data[7].ctlEdges[1].bChannel */ FREQ2FBIN(2427, 1),
			/* Data[7].ctlEdges[2].bChannel */ FREQ2FBIN(2447, 1),
			/* Data[7].ctlEdges[3].bChannel */ FREQ2FBIN(2462, 1),
		},

		{
			/* Data[8].ctlEdges[0].bChannel */ FREQ2FBIN(2412, 1),
			/* Data[8].ctlEdges[1].bChannel */ FREQ2FBIN(2417, 1),
			/* Data[8].ctlEdges[2].bChannel */ FREQ2FBIN(2472, 1),
		},

		{
			/* Data[9].ctlEdges[0].bChannel */ FREQ2FBIN(2412, 1),
			/* Data[9].ctlEdges[1].bChannel */ FREQ2FBIN(2417, 1),
			/* Data[9].ctlEdges[2].bChannel */ FREQ2FBIN(2472, 1),
			0
		},

		{
			/* Data[10].ctlEdges[0].bChannel */ FREQ2FBIN(2412, 1),
			/* Data[10].ctlEdges[1].bChannel */ FREQ2FBIN(2417, 1),
			/* Data[10].ctlEdges[2].bChannel */ FREQ2FBIN(2472, 1),
			0
		},

		{
			/* Data[11].ctlEdges[0].bChannel */ FREQ2FBIN(2422, 1),
			/* Data[11].ctlEdges[1].bChannel */ FREQ2FBIN(2427, 1),
			/* Data[11].ctlEdges[2].bChannel */ FREQ2FBIN(2447, 1),
			/* Data[11].ctlEdges[3].bChannel */
			FREQ2FBIN(2462, 1),
		}
	 },
	.ctlPowerData_2G = {
		 { { {60, 0}, {60, 1}, {60, 0}, {60, 0} } },
		 { { {60, 0}, {60, 1}, {60, 0}, {60, 0} } },
		 { { {60, 1}, {60, 0}, {60, 0}, {60, 1} } },

		 { { {60, 1}, {60, 0}, {0, 0}, {0, 0} } },
		 { { {60, 0}, {60, 1}, {60, 0}, {60, 0} } },
		 { { {60, 0}, {60, 1}, {60, 0}, {60, 0} } },

		 { { {60, 0}, {60, 1}, {60, 1}, {60, 0} } },
		 { { {60, 0}, {60, 1}, {60, 0}, {60, 0} } },
		 { { {60, 0}, {60, 1}, {60, 0}, {60, 0} } },

		 { { {60, 0}, {60, 1}, {60, 0}, {60, 0} } },
		 { { {60, 0}, {60, 1}, {60, 1}, {60, 1} } },
	 },
	.modalHeader5G = {
		/* 4 idle,t1,t2,b (4 bits per setting) */
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		.antCtrlCommon = LE32(0x110),
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		/* 4 ra1l1, ra2l1, ra1l2,ra2l2,ra12 */
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		.antCtrlCommon2 = LE32(0x22222),
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		 /* antCtrlChain 6 idle, t,r,rx1,rx12,b (2 bits each) */
		.antCtrlChain = {
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			LE16(0x000), LE16(0x000), LE16(0x000),
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		},
		 /* xatten1DB 3 xatten1_db for AR9280 (0xa20c/b20c 5:0) */
		.xatten1DB = {0, 0, 0},

		/*
		 * xatten1Margin[AR9300_MAX_CHAINS]; 3 xatten1_margin
		 * for merlin (0xa20c/b20c 16:12
		 */
		.xatten1Margin = {0, 0, 0},
		.tempSlope = 68,
		.voltSlope = 0,
		/* spurChans spur channels in usual fbin coding format */
		.spurChans = {0, 0, 0, 0, 0},
		/* noiseFloorThreshCh Check if the register is per chain */
		.noiseFloorThreshCh = {-1, 0, 0},
		.ob = {3, 3, 3}, /* 3 chain */
		.db_stage2 = {3, 3, 3}, /* 3 chain */
		.db_stage3 = {3, 3, 3}, /* doesn't exist for 2G */
		.db_stage4 = {3, 3, 3},	 /* don't exist for 2G */
		.xpaBiasLvl = 0,
		.txFrameToDataStart = 0x0e,
		.txFrameToPaOn = 0x0e,
		.txClip = 3, /* 4 bits tx_clip, 4 bits dac_scale_cck */
		.antennaGain = 0,
		.switchSettling = 0x2d,
		.adcDesiredSize = -30,
		.txEndToXpaOff = 0,
		.txEndToRxOn = 0x2,
		.txFrameToXpaOn = 0xe,
		.thresh62 = 28,
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		.papdRateMaskHt20 = LE32(0xf0e0e0),
		.papdRateMaskHt40 = LE32(0xf0e0e0),
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		.futureModal = {
			0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
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			0, 0, 0, 0, 0, 0, 0, 0
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		},
	 },
	.calFreqPier5G = {
		FREQ2FBIN(5180, 0),
		FREQ2FBIN(5220, 0),
		FREQ2FBIN(5320, 0),
		FREQ2FBIN(5400, 0),
		FREQ2FBIN(5500, 0),
		FREQ2FBIN(5600, 0),
		FREQ2FBIN(5725, 0),
		FREQ2FBIN(5825, 0)
	},
	.calPierData5G = {
			{
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
			},
			{
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
			},
			{
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
				{0, 0, 0, 0, 0},
			},

	},
	.calTarget_freqbin_5G = {
		FREQ2FBIN(5180, 0),
		FREQ2FBIN(5220, 0),
		FREQ2FBIN(5320, 0),
		FREQ2FBIN(5400, 0),
		FREQ2FBIN(5500, 0),
		FREQ2FBIN(5600, 0),
		FREQ2FBIN(5725, 0),
		FREQ2FBIN(5825, 0)
	},
	.calTarget_freqbin_5GHT20 = {
		FREQ2FBIN(5180, 0),
		FREQ2FBIN(5240, 0),
		FREQ2FBIN(5320, 0),
		FREQ2FBIN(5500, 0),
		FREQ2FBIN(5700, 0),
		FREQ2FBIN(5745, 0),
		FREQ2FBIN(5725, 0),
		FREQ2FBIN(5825, 0)
	},
	.calTarget_freqbin_5GHT40 = {
		FREQ2FBIN(5180, 0),
		FREQ2FBIN(5240, 0),
		FREQ2FBIN(5320, 0),
		FREQ2FBIN(5500, 0),
		FREQ2FBIN(5700, 0),
		FREQ2FBIN(5745, 0),
		FREQ2FBIN(5725, 0),
		FREQ2FBIN(5825, 0)
	 },
	.calTargetPower5G = {
		/* 6-24,36,48,54 */
		{ {20, 20, 20, 10} },
		{ {20, 20, 20, 10} },
		{ {20, 20, 20, 10} },
		{ {20, 20, 20, 10} },
		{ {20, 20, 20, 10} },
		{ {20, 20, 20, 10} },
		{ {20, 20, 20, 10} },
		{ {20, 20, 20, 10} },
	 },
	.calTargetPower5GHT20 = {
		/*
		 * 0_8_16,1-3_9-11_17-19,
		 * 4,5,6,7,12,13,14,15,20,21,22,23
		 */
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
	 },
	.calTargetPower5GHT40 =  {
		/*
		 * 0_8_16,1-3_9-11_17-19,
		 * 4,5,6,7,12,13,14,15,20,21,22,23
		 */
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
		{ {20, 20, 10, 10, 0, 0, 10, 10, 0, 0, 10, 10, 0, 0} },
	 },
	.ctlIndex_5G =  {
		0x10, 0x16, 0x18, 0x40, 0x46,
		0x48, 0x30, 0x36, 0x38
	},
	.ctl_freqbin_5G =  {
		{
			/* Data[0].ctlEdges[0].bChannel */ FREQ2FBIN(5180, 0),
			/* Data[0].ctlEdges[1].bChannel */ FREQ2FBIN(5260, 0),
			/* Data[0].ctlEdges[2].bChannel */ FREQ2FBIN(5280, 0),
			/* Data[0].ctlEdges[3].bChannel */ FREQ2FBIN(5500, 0),
			/* Data[0].ctlEdges[4].bChannel */ FREQ2FBIN(5600, 0),
			/* Data[0].ctlEdges[5].bChannel */ FREQ2FBIN(5700, 0),
			/* Data[0].ctlEdges[6].bChannel */ FREQ2FBIN(5745, 0),
			/* Data[0].ctlEdges[7].bChannel */ FREQ2FBIN(5825, 0)
		},
		{
			/* Data[1].ctlEdges[0].bChannel */ FREQ2FBIN(5180, 0),
			/* Data[1].ctlEdges[1].bChannel */ FREQ2FBIN(5260, 0),
			/* Data[1].ctlEdges[2].bChannel */ FREQ2FBIN(5280, 0),
			/* Data[1].ctlEdges[3].bChannel */ FREQ2FBIN(5500, 0),
			/* Data[1].ctlEdges[4].bChannel */ FREQ2FBIN(5520, 0),
			/* Data[1].ctlEdges[5].bChannel */ FREQ2FBIN(5700, 0),
			/* Data[1].ctlEdges[6].bChannel */ FREQ2FBIN(5745, 0),
			/* Data[1].ctlEdges[7].bChannel */ FREQ2FBIN(5825, 0)
		},

		{
			/* Data[2].ctlEdges[0].bChannel */ FREQ2FBIN(5190, 0),
			/* Data[2].ctlEdges[1].bChannel */ FREQ2FBIN(5230, 0),
			/* Data[2].ctlEdges[2].bChannel */ FREQ2FBIN(5270, 0),
			/* Data[2].ctlEdges[3].bChannel */ FREQ2FBIN(5310, 0),
			/* Data[2].ctlEdges[4].bChannel */ FREQ2FBIN(5510, 0),
			/* Data[2].ctlEdges[5].bChannel */ FREQ2FBIN(5550, 0),
			/* Data[2].ctlEdges[6].bChannel */ FREQ2FBIN(5670, 0),
			/* Data[2].ctlEdges[7].bChannel */ FREQ2FBIN(5755, 0)
		},

		{
			/* Data[3].ctlEdges[0].bChannel */ FREQ2FBIN(5180, 0),
			/* Data[3].ctlEdges[1].bChannel */ FREQ2FBIN(5200, 0),
			/* Data[3].ctlEdges[2].bChannel */ FREQ2FBIN(5260, 0),
			/* Data[3].ctlEdges[3].bChannel */ FREQ2FBIN(5320, 0),
			/* Data[3].ctlEdges[4].bChannel */ FREQ2FBIN(5500, 0),
			/* Data[3].ctlEdges[5].bChannel */ FREQ2FBIN(5700, 0),
			/* Data[3].ctlEdges[6].bChannel */ 0xFF,
			/* Data[3].ctlEdges[7].bChannel */ 0xFF,
		},

		{
			/* Data[4].ctlEdges[0].bChannel */ FREQ2FBIN(5180, 0),
			/* Data[4].ctlEdges[1].bChannel */ FREQ2FBIN(5260, 0),
			/* Data[4].ctlEdges[2].bChannel */ FREQ2FBIN(5500, 0),
			/* Data[4].ctlEdges[3].bChannel */ FREQ2FBIN(5700, 0),
			/* Data[4].ctlEdges[4].bChannel */ 0xFF,
			/* Data[4].ctlEdges[5].bChannel */ 0xFF,
			/* Data[4].ctlEdges[6].bChannel */ 0xFF,
			/* Data[4].ctlEdges[7].bChannel */ 0xFF,
		},

		{
			/* Data[5].ctlEdges[0].bChannel */ FREQ2FBIN(5190, 0),
			/* Data[5].ctlEdges[1].bChannel */ FREQ2FBIN(5270, 0),
			/* Data[5].ctlEdges[2].bChannel */ FREQ2FBIN(5310, 0),
			/* Data[5].ctlEdges[3].bChannel */ FREQ2FBIN(5510, 0),
			/* Data[5].ctlEdges[4].bChannel */ FREQ2FBIN(5590, 0),
			/* Data[5].ctlEdges[5].bChannel */ FREQ2FBIN(5670, 0),
			/* Data[5].ctlEdges[6].bChannel */ 0xFF,
			/* Data[5].ctlEdges[7].bChannel */ 0xFF
		},

		{
			/* Data[6].ctlEdges[0].bChannel */ FREQ2FBIN(5180, 0),
			/* Data[6].ctlEdges[1].bChannel */ FREQ2FBIN(5200, 0),
			/* Data[6].ctlEdges[2].bChannel */ FREQ2FBIN(5220, 0),
			/* Data[6].ctlEdges[3].bChannel */ FREQ2FBIN(5260, 0),
			/* Data[6].ctlEdges[4].bChannel */ FREQ2FBIN(5500, 0),
			/* Data[6].ctlEdges[5].bChannel */ FREQ2FBIN(5600, 0),
			/* Data[6].ctlEdges[6].bChannel */ FREQ2FBIN(5700, 0),
			/* Data[6].ctlEdges[7].bChannel */ FREQ2FBIN(5745, 0)
		},

		{
			/* Data[7].ctlEdges[0].bChannel */ FREQ2FBIN(5180, 0),
			/* Data[7].ctlEdges[1].bChannel */ FREQ2FBIN(5260, 0),
			/* Data[7].ctlEdges[2].bChannel */ FREQ2FBIN(5320, 0),
			/* Data[7].ctlEdges[3].bChannel */ FREQ2FBIN(5500, 0),
			/* Data[7].ctlEdges[4].bChannel */ FREQ2FBIN(5560, 0),
			/* Data[7].ctlEdges[5].bChannel */ FREQ2FBIN(5700, 0),
			/* Data[7].ctlEdges[6].bChannel */ FREQ2FBIN(5745, 0),
			/* Data[7].ctlEdges[7].bChannel */ FREQ2FBIN(5825, 0)
		},

		{
			/* Data[8].ctlEdges[0].bChannel */ FREQ2FBIN(5190, 0),
			/* Data[8].ctlEdges[1].bChannel */ FREQ2FBIN(5230, 0),
			/* Data[8].ctlEdges[2].bChannel */ FREQ2FBIN(5270, 0),
			/* Data[8].ctlEdges[3].bChannel */ FREQ2FBIN(5510, 0),
			/* Data[8].ctlEdges[4].bChannel */ FREQ2FBIN(5550, 0),
			/* Data[8].ctlEdges[5].bChannel */ FREQ2FBIN(5670, 0),
			/* Data[8].ctlEdges[6].bChannel */ FREQ2FBIN(5755, 0),
			/* Data[8].ctlEdges[7].bChannel */ FREQ2FBIN(5795, 0)
		}
	 },
	.ctlPowerData_5G = {
		{
			{
				{60, 1}, {60, 1}, {60, 1}, {60, 1},
				{60, 1}, {60, 1}, {60, 1}, {60, 0},
			}
		},
		{
			{
				{60, 1}, {60, 1}, {60, 1}, {60, 1},
				{60, 1}, {60, 1}, {60, 1}, {60, 0},
			}
		},
		{
			{
				{60, 0}, {60, 1}, {60, 0}, {60, 1},
				{60, 1}, {60, 1}, {60, 1}, {60, 1},
			}
		},
		{
			{
				{60, 0}, {60, 1}, {60, 1}, {60, 0},
				{60, 1}, {60, 0}, {60, 0}, {60, 0},
			}
		},
		{
			{
				{60, 1}, {60, 1}, {60, 1}, {60, 0},
				{60, 0}, {60, 0}, {60, 0}, {60, 0},
			}
		},
		{
			{
				{60, 1}, {60, 1}, {60, 1}, {60, 1},
				{60, 1}, {60, 0}, {60, 0}, {60, 0},
			}
		},
		{
			{
				{60, 1}, {60, 1}, {60, 1}, {60, 1},
				{60, 1}, {60, 1}, {60, 1}, {60, 1},
			}
		},
		{
			{
				{60, 1}, {60, 1}, {60, 0}, {60, 1},
				{60, 1}, {60, 1}, {60, 1}, {60, 0},
			}
		},
		{
			{
				{60, 1}, {60, 0}, {60, 1}, {60, 1},
				{60, 1}, {60, 1}, {60, 0}, {60, 1},
			}
		},
	 }
};

626 627 628 629 630 631 632 633
static u16 ath9k_hw_fbin2freq(u8 fbin, bool is2GHz)
{
	if (fbin == AR9300_BCHAN_UNUSED)
		return fbin;

	return (u16) ((is2GHz) ? (2300 + fbin) : (4800 + 5 * fbin));
}

634 635 636 637 638 639 640 641 642 643 644 645 646 647 648 649 650 651 652
static int ath9k_hw_ar9300_check_eeprom(struct ath_hw *ah)
{
	return 0;
}

static u32 ath9k_hw_ar9300_get_eeprom(struct ath_hw *ah,
				      enum eeprom_param param)
{
	struct ar9300_eeprom *eep = &ah->eeprom.ar9300_eep;
	struct ar9300_base_eep_hdr *pBase = &eep->baseEepHeader;

	switch (param) {
	case EEP_MAC_LSW:
		return eep->macAddr[0] << 8 | eep->macAddr[1];
	case EEP_MAC_MID:
		return eep->macAddr[2] << 8 | eep->macAddr[3];
	case EEP_MAC_MSW:
		return eep->macAddr[4] << 8 | eep->macAddr[5];
	case EEP_REG_0:
653
		return le16_to_cpu(pBase->regDmn[0]);
654
	case EEP_REG_1:
655
		return le16_to_cpu(pBase->regDmn[1]);
656 657 658 659 660 661 662 663 664 665 666 667 668 669 670 671 672
	case EEP_OP_CAP:
		return pBase->deviceCap;
	case EEP_OP_MODE:
		return pBase->opCapFlags.opFlags;
	case EEP_RF_SILENT:
		return pBase->rfSilent;
	case EEP_TX_MASK:
		return (pBase->txrxMask >> 4) & 0xf;
	case EEP_RX_MASK:
		return pBase->txrxMask & 0xf;
	case EEP_DRIVE_STRENGTH:
#define AR9300_EEP_BASE_DRIV_STRENGTH	0x1
		return pBase->miscConfiguration & AR9300_EEP_BASE_DRIV_STRENGTH;
	case EEP_INTERNAL_REGULATOR:
		/* Bit 4 is internal regulator flag */
		return (pBase->featureEnable & 0x10) >> 4;
	case EEP_SWREG:
673
		return le32_to_cpu(pBase->swreg);
674 675
	case EEP_PAPRD:
		return !!(pBase->featureEnable & BIT(5));
676 677 678 679 680
	default:
		return 0;
	}
}

681 682
static bool ar9300_eeprom_read_byte(struct ath_common *common, int address,
				    u8 *buffer)
683
{
684
	u16 val;
685

686 687
	if (unlikely(!ath9k_hw_nvram_read(common, address / 2, &val)))
		return false;
688

689 690 691
	*buffer = (val >> (8 * (address % 2))) & 0xff;
	return true;
}
692

693 694 695 696
static bool ar9300_eeprom_read_word(struct ath_common *common, int address,
				    u8 *buffer)
{
	u16 val;
697

698 699
	if (unlikely(!ath9k_hw_nvram_read(common, address / 2, &val)))
		return false;
700

701 702
	buffer[0] = val >> 8;
	buffer[1] = val & 0xff;
703

704
	return true;
705 706
}

707 708
static bool ar9300_read_eeprom(struct ath_hw *ah, int address, u8 *buffer,
			       int count)
709 710
{
	struct ath_common *common = ath9k_hw_common(ah);
711
	int i;
712

713
	if ((address < 0) || ((address + count) / 2 > AR9300_EEPROM_SIZE - 1)) {
714 715 716 717 718
		ath_print(common, ATH_DBG_EEPROM,
			  "eeprom address not in range\n");
		return false;
	}

719 720 721 722 723 724 725 726 727 728
	/*
	 * Since we're reading the bytes in reverse order from a little-endian
	 * word stream, an even address means we only use the lower half of
	 * the 16-bit word at that address
	 */
	if (address % 2 == 0) {
		if (!ar9300_eeprom_read_byte(common, address--, buffer++))
			goto error;

		count--;
729 730
	}

731 732 733
	for (i = 0; i < count / 2; i++) {
		if (!ar9300_eeprom_read_word(common, address, buffer))
			goto error;
734

735 736 737 738 739 740 741
		address -= 2;
		buffer += 2;
	}

	if (count % 2)
		if (!ar9300_eeprom_read_byte(common, address, buffer))
			goto error;
742 743

	return true;
744 745 746 747 748

error:
	ath_print(common, ATH_DBG_EEPROM,
		  "unable to read eeprom region at offset %d\n", address);
	return false;
749 750 751 752 753 754 755 756 757 758 759 760 761 762 763 764 765 766 767 768 769 770 771 772 773 774 775 776 777 778 779 780 781 782 783 784 785 786 787 788 789 790 791 792 793 794 795 796 797 798 799
}

static void ar9300_comp_hdr_unpack(u8 *best, int *code, int *reference,
				   int *length, int *major, int *minor)
{
	unsigned long value[4];

	value[0] = best[0];
	value[1] = best[1];
	value[2] = best[2];
	value[3] = best[3];
	*code = ((value[0] >> 5) & 0x0007);
	*reference = (value[0] & 0x001f) | ((value[1] >> 2) & 0x0020);
	*length = ((value[1] << 4) & 0x07f0) | ((value[2] >> 4) & 0x000f);
	*major = (value[2] & 0x000f);
	*minor = (value[3] & 0x00ff);
}

static u16 ar9300_comp_cksum(u8 *data, int dsize)
{
	int it, checksum = 0;

	for (it = 0; it < dsize; it++) {
		checksum += data[it];
		checksum &= 0xffff;
	}

	return checksum;
}

static bool ar9300_uncompress_block(struct ath_hw *ah,
				    u8 *mptr,
				    int mdataSize,
				    u8 *block,
				    int size)
{
	int it;
	int spot;
	int offset;
	int length;
	struct ath_common *common = ath9k_hw_common(ah);

	spot = 0;

	for (it = 0; it < size; it += (length+2)) {
		offset = block[it];
		offset &= 0xff;
		spot += offset;
		length = block[it+1];
		length &= 0xff;

800
		if (length > 0 && spot >= 0 && spot+length <= mdataSize) {
801 802 803 804 805 806 807 808 809 810 811 812 813 814 815 816 817 818 819 820 821 822 823 824 825 826 827 828 829 830 831 832 833 834 835 836 837 838 839 840 841 842 843 844 845 846 847 848 849 850 851 852 853 854 855 856 857 858 859 860 861 862 863 864 865 866 867 868 869 870 871 872 873 874 875 876 877 878 879 880 881 882 883 884 885 886 887 888 889 890 891 892 893 894 895 896 897 898 899 900 901 902 903 904 905 906 907 908 909 910 911 912 913 914 915 916 917 918 919 920 921 922 923 924 925 926 927 928 929 930 931 932 933 934 935 936 937 938 939 940 941 942 943 944 945 946 947 948
			ath_print(common, ATH_DBG_EEPROM,
				  "Restore at %d: spot=%d "
				  "offset=%d length=%d\n",
				   it, spot, offset, length);
			memcpy(&mptr[spot], &block[it+2], length);
			spot += length;
		} else if (length > 0) {
			ath_print(common, ATH_DBG_EEPROM,
				  "Bad restore at %d: spot=%d "
				  "offset=%d length=%d\n",
				  it, spot, offset, length);
			return false;
		}
	}
	return true;
}

static int ar9300_compress_decision(struct ath_hw *ah,
				    int it,
				    int code,
				    int reference,
				    u8 *mptr,
				    u8 *word, int length, int mdata_size)
{
	struct ath_common *common = ath9k_hw_common(ah);
	u8 *dptr;

	switch (code) {
	case _CompressNone:
		if (length != mdata_size) {
			ath_print(common, ATH_DBG_EEPROM,
				  "EEPROM structure size mismatch"
				  "memory=%d eeprom=%d\n", mdata_size, length);
			return -1;
		}
		memcpy(mptr, (u8 *) (word + COMP_HDR_LEN), length);
		ath_print(common, ATH_DBG_EEPROM, "restored eeprom %d:"
			  " uncompressed, length %d\n", it, length);
		break;
	case _CompressBlock:
		if (reference == 0) {
			dptr = mptr;
		} else {
			if (reference != 2) {
				ath_print(common, ATH_DBG_EEPROM,
					  "cant find reference eeprom"
					  "struct %d\n", reference);
				return -1;
			}
			memcpy(mptr, &ar9300_default, mdata_size);
		}
		ath_print(common, ATH_DBG_EEPROM,
			  "restore eeprom %d: block, reference %d,"
			  " length %d\n", it, reference, length);
		ar9300_uncompress_block(ah, mptr, mdata_size,
					(u8 *) (word + COMP_HDR_LEN), length);
		break;
	default:
		ath_print(common, ATH_DBG_EEPROM, "unknown compression"
			  " code %d\n", code);
		return -1;
	}
	return 0;
}

/*
 * Read the configuration data from the eeprom.
 * The data can be put in any specified memory buffer.
 *
 * Returns -1 on error.
 * Returns address of next memory location on success.
 */
static int ar9300_eeprom_restore_internal(struct ath_hw *ah,
					  u8 *mptr, int mdata_size)
{
#define MDEFAULT 15
#define MSTATE 100
	int cptr;
	u8 *word;
	int code;
	int reference, length, major, minor;
	int osize;
	int it;
	u16 checksum, mchecksum;
	struct ath_common *common = ath9k_hw_common(ah);

	word = kzalloc(2048, GFP_KERNEL);
	if (!word)
		return -1;

	memcpy(mptr, &ar9300_default, mdata_size);

	cptr = AR9300_BASE_ADDR;
	for (it = 0; it < MSTATE; it++) {
		if (!ar9300_read_eeprom(ah, cptr, word, COMP_HDR_LEN))
			goto fail;

		if ((word[0] == 0 && word[1] == 0 && word[2] == 0 &&
		     word[3] == 0) || (word[0] == 0xff && word[1] == 0xff
				       && word[2] == 0xff && word[3] == 0xff))
			break;

		ar9300_comp_hdr_unpack(word, &code, &reference,
				       &length, &major, &minor);
		ath_print(common, ATH_DBG_EEPROM,
			  "Found block at %x: code=%d ref=%d"
			  "length=%d major=%d minor=%d\n", cptr, code,
			  reference, length, major, minor);
		if (length >= 1024) {
			ath_print(common, ATH_DBG_EEPROM,
				  "Skipping bad header\n");
			cptr -= COMP_HDR_LEN;
			continue;
		}

		osize = length;
		ar9300_read_eeprom(ah, cptr, word,
				   COMP_HDR_LEN + osize + COMP_CKSUM_LEN);
		checksum = ar9300_comp_cksum(&word[COMP_HDR_LEN], length);
		mchecksum = word[COMP_HDR_LEN + osize] |
		    (word[COMP_HDR_LEN + osize + 1] << 8);
		ath_print(common, ATH_DBG_EEPROM,
			  "checksum %x %x\n", checksum, mchecksum);
		if (checksum == mchecksum) {
			ar9300_compress_decision(ah, it, code, reference, mptr,
						 word, length, mdata_size);
		} else {
			ath_print(common, ATH_DBG_EEPROM,
				  "skipping block with bad checksum\n");
		}
		cptr -= (COMP_HDR_LEN + osize + COMP_CKSUM_LEN);
	}

	kfree(word);
	return cptr;

fail:
	kfree(word);
	return -1;
}

/*
 * Restore the configuration structure by reading the eeprom.
 * This function destroys any existing in-memory structure
 * content.
 */
static bool ath9k_hw_ar9300_fill_eeprom(struct ath_hw *ah)
{
949
	u8 *mptr = (u8 *) &ah->eeprom.ar9300_eep;
950

951 952 953
	if (ar9300_eeprom_restore_internal(ah, mptr,
			sizeof(struct ar9300_eeprom)) < 0)
		return false;
954

955
	return true;
956 957 958 959 960 961 962 963 964 965 966 967 968 969 970
}

/* XXX: review hardware docs */
static int ath9k_hw_ar9300_get_eeprom_ver(struct ath_hw *ah)
{
	return ah->eeprom.ar9300_eep.eepromVersion;
}

/* XXX: could be read from the eepromVersion, not sure yet */
static int ath9k_hw_ar9300_get_eeprom_rev(struct ath_hw *ah)
{
	return 0;
}

static u8 ath9k_hw_ar9300_get_num_ant_config(struct ath_hw *ah,
971
					     enum ath9k_hal_freq_band freq_band)
972 973 974 975
{
	return 1;
}

976
static u32 ath9k_hw_ar9300_get_eeprom_antenna_cfg(struct ath_hw *ah,
977 978 979 980 981 982 983 984 985 986 987 988 989 990 991 992 993 994 995 996 997 998 999 1000 1001 1002
						  struct ath9k_channel *chan)
{
	return -EINVAL;
}

static s32 ar9003_hw_xpa_bias_level_get(struct ath_hw *ah, bool is2ghz)
{
	struct ar9300_eeprom *eep = &ah->eeprom.ar9300_eep;

	if (is2ghz)
		return eep->modalHeader2G.xpaBiasLvl;
	else
		return eep->modalHeader5G.xpaBiasLvl;
}

static void ar9003_hw_xpa_bias_level_apply(struct ath_hw *ah, bool is2ghz)
{
	int bias = ar9003_hw_xpa_bias_level_get(ah, is2ghz);
	REG_RMW_FIELD(ah, AR_CH0_TOP, AR_CH0_TOP_XPABIASLVL, (bias & 0x3));
	REG_RMW_FIELD(ah, AR_CH0_THERM, AR_CH0_THERM_SPARE,
		      ((bias >> 2) & 0x3));
}

static u32 ar9003_hw_ant_ctrl_common_get(struct ath_hw *ah, bool is2ghz)
{
	struct ar9300_eeprom *eep = &ah->eeprom.ar9300_eep;
1003
	__le32 val;
1004 1005

	if (is2ghz)
1006
		val = eep->modalHeader2G.antCtrlCommon;
1007
	else
1008 1009
		val = eep->modalHeader5G.antCtrlCommon;
	return le32_to_cpu(val);
1010 1011 1012 1013 1014
}

static u32 ar9003_hw_ant_ctrl_common_2_get(struct ath_hw *ah, bool is2ghz)
{
	struct ar9300_eeprom *eep = &ah->eeprom.ar9300_eep;
1015
	__le32 val;
1016 1017

	if (is2ghz)
1018
		val = eep->modalHeader2G.antCtrlCommon2;
1019
	else
1020 1021
		val = eep->modalHeader5G.antCtrlCommon2;
	return le32_to_cpu(val);
1022 1023 1024 1025 1026 1027 1028
}

static u16 ar9003_hw_ant_ctrl_chain_get(struct ath_hw *ah,
					int chain,
					bool is2ghz)
{
	struct ar9300_eeprom *eep = &ah->eeprom.ar9300_eep;
1029
	__le16 val = 0;
1030 1031 1032

	if (chain >= 0 && chain < AR9300_MAX_CHAINS) {
		if (is2ghz)
1033
			val = eep->modalHeader2G.antCtrlChain[chain];
1034
		else
1035
			val = eep->modalHeader5G.antCtrlChain[chain];
1036 1037
	}

1038
	return le16_to_cpu(val);
1039 1040 1041 1042 1043 1044 1045 1046 1047 1048 1049 1050 1051 1052 1053 1054 1055 1056 1057 1058 1059 1060 1061 1062 1063 1064 1065 1066 1067 1068 1069 1070 1071 1072 1073 1074 1075 1076 1077 1078 1079 1080 1081 1082 1083 1084 1085 1086 1087 1088 1089 1090 1091 1092 1093 1094 1095 1096 1097 1098 1099 1100 1101 1102 1103 1104 1105 1106 1107 1108 1109 1110 1111 1112 1113 1114 1115 1116 1117 1118 1119 1120 1121 1122 1123 1124 1125 1126 1127 1128 1129 1130 1131 1132 1133 1134 1135 1136 1137 1138 1139 1140 1141 1142 1143 1144 1145 1146 1147 1148 1149 1150 1151 1152 1153 1154 1155 1156 1157 1158 1159 1160 1161 1162 1163 1164 1165 1166 1167 1168 1169 1170 1171 1172 1173 1174 1175 1176 1177 1178 1179 1180 1181 1182 1183 1184 1185 1186 1187 1188 1189 1190 1191 1192 1193 1194 1195 1196 1197 1198 1199 1200 1201 1202 1203 1204 1205 1206 1207 1208 1209 1210 1211 1212
}

static void ar9003_hw_ant_ctrl_apply(struct ath_hw *ah, bool is2ghz)
{
	u32 value = ar9003_hw_ant_ctrl_common_get(ah, is2ghz);
	REG_RMW_FIELD(ah, AR_PHY_SWITCH_COM, AR_SWITCH_TABLE_COM_ALL, value);

	value = ar9003_hw_ant_ctrl_common_2_get(ah, is2ghz);
	REG_RMW_FIELD(ah, AR_PHY_SWITCH_COM_2, AR_SWITCH_TABLE_COM2_ALL, value);

	value = ar9003_hw_ant_ctrl_chain_get(ah, 0, is2ghz);
	REG_RMW_FIELD(ah, AR_PHY_SWITCH_CHAIN_0, AR_SWITCH_TABLE_ALL, value);

	value = ar9003_hw_ant_ctrl_chain_get(ah, 1, is2ghz);
	REG_RMW_FIELD(ah, AR_PHY_SWITCH_CHAIN_1, AR_SWITCH_TABLE_ALL, value);

	value = ar9003_hw_ant_ctrl_chain_get(ah, 2, is2ghz);
	REG_RMW_FIELD(ah, AR_PHY_SWITCH_CHAIN_2, AR_SWITCH_TABLE_ALL, value);
}

static void ar9003_hw_drive_strength_apply(struct ath_hw *ah)
{
	int drive_strength;
	unsigned long reg;

	drive_strength = ath9k_hw_ar9300_get_eeprom(ah, EEP_DRIVE_STRENGTH);

	if (!drive_strength)
		return;

	reg = REG_READ(ah, AR_PHY_65NM_CH0_BIAS1);
	reg &= ~0x00ffffc0;
	reg |= 0x5 << 21;
	reg |= 0x5 << 18;
	reg |= 0x5 << 15;
	reg |= 0x5 << 12;
	reg |= 0x5 << 9;
	reg |= 0x5 << 6;
	REG_WRITE(ah, AR_PHY_65NM_CH0_BIAS1, reg);

	reg = REG_READ(ah, AR_PHY_65NM_CH0_BIAS2);
	reg &= ~0xffffffe0;
	reg |= 0x5 << 29;
	reg |= 0x5 << 26;
	reg |= 0x5 << 23;
	reg |= 0x5 << 20;
	reg |= 0x5 << 17;
	reg |= 0x5 << 14;
	reg |= 0x5 << 11;
	reg |= 0x5 << 8;
	reg |= 0x5 << 5;
	REG_WRITE(ah, AR_PHY_65NM_CH0_BIAS2, reg);

	reg = REG_READ(ah, AR_PHY_65NM_CH0_BIAS4);
	reg &= ~0xff800000;
	reg |= 0x5 << 29;
	reg |= 0x5 << 26;
	reg |= 0x5 << 23;
	REG_WRITE(ah, AR_PHY_65NM_CH0_BIAS4, reg);
}

static void ar9003_hw_internal_regulator_apply(struct ath_hw *ah)
{
	int internal_regulator =
		ath9k_hw_ar9300_get_eeprom(ah, EEP_INTERNAL_REGULATOR);

	if (internal_regulator) {
		/* Internal regulator is ON. Write swreg register. */
		int swreg = ath9k_hw_ar9300_get_eeprom(ah, EEP_SWREG);
		REG_WRITE(ah, AR_RTC_REG_CONTROL1,
		REG_READ(ah, AR_RTC_REG_CONTROL1) &
			 (~AR_RTC_REG_CONTROL1_SWREG_PROGRAM));
		REG_WRITE(ah, AR_RTC_REG_CONTROL0, swreg);
		/* Set REG_CONTROL1.SWREG_PROGRAM */
		REG_WRITE(ah, AR_RTC_REG_CONTROL1,
			  REG_READ(ah,
				   AR_RTC_REG_CONTROL1) |
				   AR_RTC_REG_CONTROL1_SWREG_PROGRAM);
	} else {
		REG_WRITE(ah, AR_RTC_SLEEP_CLK,
			  (REG_READ(ah,
				    AR_RTC_SLEEP_CLK) |
				    AR_RTC_FORCE_SWREG_PRD));
	}
}

static void ath9k_hw_ar9300_set_board_values(struct ath_hw *ah,
					     struct ath9k_channel *chan)
{
	ar9003_hw_xpa_bias_level_apply(ah, IS_CHAN_2GHZ(chan));
	ar9003_hw_ant_ctrl_apply(ah, IS_CHAN_2GHZ(chan));
	ar9003_hw_drive_strength_apply(ah);
	ar9003_hw_internal_regulator_apply(ah);
}

static void ath9k_hw_ar9300_set_addac(struct ath_hw *ah,
				      struct ath9k_channel *chan)
{
}

/*
 * Returns the interpolated y value corresponding to the specified x value
 * from the np ordered pairs of data (px,py).
 * The pairs do not have to be in any order.
 * If the specified x value is less than any of the px,
 * the returned y value is equal to the py for the lowest px.
 * If the specified x value is greater than any of the px,
 * the returned y value is equal to the py for the highest px.
 */
static int ar9003_hw_power_interpolate(int32_t x,
				       int32_t *px, int32_t *py, u_int16_t np)
{
	int ip = 0;
	int lx = 0, ly = 0, lhave = 0;
	int hx = 0, hy = 0, hhave = 0;
	int dx = 0;
	int y = 0;

	lhave = 0;
	hhave = 0;

	/* identify best lower and higher x calibration measurement */
	for (ip = 0; ip < np; ip++) {
		dx = x - px[ip];

		/* this measurement is higher than our desired x */
		if (dx <= 0) {
			if (!hhave || dx > (x - hx)) {
				/* new best higher x measurement */
				hx = px[ip];
				hy = py[ip];
				hhave = 1;
			}
		}
		/* this measurement is lower than our desired x */
		if (dx >= 0) {
			if (!lhave || dx < (x - lx)) {
				/* new best lower x measurement */
				lx = px[ip];
				ly = py[ip];
				lhave = 1;
			}
		}
	}

	/* the low x is good */
	if (lhave) {
		/* so is the high x */
		if (hhave) {
			/* they're the same, so just pick one */
			if (hx == lx)
				y = ly;
			else	/* interpolate  */
				y = ly + (((x - lx) * (hy - ly)) / (hx - lx));
		} else		/* only low is good, use it */
			y = ly;
	} else if (hhave)	/* only high is good, use it */
		y = hy;
	else /* nothing is good,this should never happen unless np=0, ???? */
		y = -(1 << 30);
	return y;
}

static u8 ar9003_hw_eeprom_get_tgt_pwr(struct ath_hw *ah,
				       u16 rateIndex, u16 freq, bool is2GHz)
{
	u16 numPiers, i;
	s32 targetPowerArray[AR9300_NUM_5G_20_TARGET_POWERS];
	s32 freqArray[AR9300_NUM_5G_20_TARGET_POWERS];
	struct ar9300_eeprom *eep = &ah->eeprom.ar9300_eep;
	struct cal_tgt_pow_legacy *pEepromTargetPwr;
	u8 *pFreqBin;

	if (is2GHz) {
1213
		numPiers = AR9300_NUM_2G_20_TARGET_POWERS;
1214 1215 1216 1217 1218 1219 1220 1221 1222 1223 1224 1225 1226 1227 1228 1229 1230 1231 1232 1233 1234 1235 1236 1237 1238 1239 1240 1241 1242 1243 1244 1245 1246 1247 1248
		pEepromTargetPwr = eep->calTargetPower2G;
		pFreqBin = eep->calTarget_freqbin_2G;
	} else {
		numPiers = AR9300_NUM_5G_20_TARGET_POWERS;
		pEepromTargetPwr = eep->calTargetPower5G;
		pFreqBin = eep->calTarget_freqbin_5G;
	}

	/*
	 * create array of channels and targetpower from
	 * targetpower piers stored on eeprom
	 */
	for (i = 0; i < numPiers; i++) {
		freqArray[i] = FBIN2FREQ(pFreqBin[i], is2GHz);
		targetPowerArray[i] = pEepromTargetPwr[i].tPow2x[rateIndex];
	}

	/* interpolate to get target power for given frequency */
	return (u8) ar9003_hw_power_interpolate((s32) freq,
						 freqArray,
						 targetPowerArray, numPiers);
}

static u8 ar9003_hw_eeprom_get_ht20_tgt_pwr(struct ath_hw *ah,
					    u16 rateIndex,
					    u16 freq, bool is2GHz)
{
	u16 numPiers, i;
	s32 targetPowerArray[AR9300_NUM_5G_20_TARGET_POWERS];
	s32 freqArray[AR9300_NUM_5G_20_TARGET_POWERS];
	struct ar9300_eeprom *eep = &ah->eeprom.ar9300_eep;
	struct cal_tgt_pow_ht *pEepromTargetPwr;
	u8 *pFreqBin;

	if (is2GHz) {
1249
		numPiers = AR9300_NUM_2G_20_TARGET_POWERS;
1250 1251 1252 1253 1254 1255 1256 1257 1258 1259 1260 1261 1262 1263 1264 1265 1266 1267 1268 1269 1270 1271 1272 1273 1274 1275 1276 1277 1278 1279 1280 1281 1282 1283 1284 1285 1286 1287 1288 1289 1290 1291 1292 1293 1294 1295 1296 1297 1298 1299 1300 1301 1302 1303 1304 1305 1306 1307 1308 1309 1310 1311 1312 1313 1314 1315 1316 1317 1318 1319 1320 1321 1322 1323 1324 1325 1326 1327 1328 1329 1330 1331 1332 1333 1334 1335 1336 1337 1338 1339 1340 1341 1342 1343 1344 1345 1346 1347 1348 1349 1350 1351 1352 1353 1354 1355 1356 1357 1358 1359 1360 1361 1362 1363 1364 1365 1366 1367 1368 1369 1370 1371 1372 1373 1374 1375 1376 1377 1378 1379 1380 1381 1382 1383 1384 1385 1386 1387 1388 1389 1390 1391 1392 1393 1394 1395 1396 1397 1398 1399 1400 1401 1402 1403 1404 1405 1406 1407 1408 1409 1410 1411 1412 1413 1414 1415 1416 1417 1418 1419 1420 1421 1422 1423 1424 1425 1426 1427 1428 1429 1430 1431 1432 1433 1434 1435 1436 1437 1438 1439 1440 1441
		pEepromTargetPwr = eep->calTargetPower2GHT20;
		pFreqBin = eep->calTarget_freqbin_2GHT20;
	} else {
		numPiers = AR9300_NUM_5G_20_TARGET_POWERS;
		pEepromTargetPwr = eep->calTargetPower5GHT20;
		pFreqBin = eep->calTarget_freqbin_5GHT20;
	}

	/*
	 * create array of channels and targetpower
	 * from targetpower piers stored on eeprom
	 */
	for (i = 0; i < numPiers; i++) {
		freqArray[i] = FBIN2FREQ(pFreqBin[i], is2GHz);
		targetPowerArray[i] = pEepromTargetPwr[i].tPow2x[rateIndex];
	}

	/* interpolate to get target power for given frequency */
	return (u8) ar9003_hw_power_interpolate((s32) freq,
						 freqArray,
						 targetPowerArray, numPiers);
}

static u8 ar9003_hw_eeprom_get_ht40_tgt_pwr(struct ath_hw *ah,
					    u16 rateIndex,
					    u16 freq, bool is2GHz)
{
	u16 numPiers, i;
	s32 targetPowerArray[AR9300_NUM_5G_40_TARGET_POWERS];
	s32 freqArray[AR9300_NUM_5G_40_TARGET_POWERS];
	struct ar9300_eeprom *eep = &ah->eeprom.ar9300_eep;
	struct cal_tgt_pow_ht *pEepromTargetPwr;
	u8 *pFreqBin;

	if (is2GHz) {
		numPiers = AR9300_NUM_2G_40_TARGET_POWERS;
		pEepromTargetPwr = eep->calTargetPower2GHT40;
		pFreqBin = eep->calTarget_freqbin_2GHT40;
	} else {
		numPiers = AR9300_NUM_5G_40_TARGET_POWERS;
		pEepromTargetPwr = eep->calTargetPower5GHT40;
		pFreqBin = eep->calTarget_freqbin_5GHT40;
	}

	/*
	 * create array of channels and targetpower from
	 * targetpower piers stored on eeprom
	 */
	for (i = 0; i < numPiers; i++) {
		freqArray[i] = FBIN2FREQ(pFreqBin[i], is2GHz);
		targetPowerArray[i] = pEepromTargetPwr[i].tPow2x[rateIndex];
	}

	/* interpolate to get target power for given frequency */
	return (u8) ar9003_hw_power_interpolate((s32) freq,
						 freqArray,
						 targetPowerArray, numPiers);
}

static u8 ar9003_hw_eeprom_get_cck_tgt_pwr(struct ath_hw *ah,
					   u16 rateIndex, u16 freq)
{
	u16 numPiers = AR9300_NUM_2G_CCK_TARGET_POWERS, i;
	s32 targetPowerArray[AR9300_NUM_2G_CCK_TARGET_POWERS];
	s32 freqArray[AR9300_NUM_2G_CCK_TARGET_POWERS];
	struct ar9300_eeprom *eep = &ah->eeprom.ar9300_eep;
	struct cal_tgt_pow_legacy *pEepromTargetPwr = eep->calTargetPowerCck;
	u8 *pFreqBin = eep->calTarget_freqbin_Cck;

	/*
	 * create array of channels and targetpower from
	 * targetpower piers stored on eeprom
	 */
	for (i = 0; i < numPiers; i++) {
		freqArray[i] = FBIN2FREQ(pFreqBin[i], 1);
		targetPowerArray[i] = pEepromTargetPwr[i].tPow2x[rateIndex];
	}

	/* interpolate to get target power for given frequency */
	return (u8) ar9003_hw_power_interpolate((s32) freq,
						 freqArray,
						 targetPowerArray, numPiers);
}

/* Set tx power registers to array of values passed in */
static int ar9003_hw_tx_power_regwrite(struct ath_hw *ah, u8 * pPwrArray)
{
#define POW_SM(_r, _s)     (((_r) & 0x3f) << (_s))
	/* make sure forced gain is not set */
	REG_WRITE(ah, 0xa458, 0);

	/* Write the OFDM power per rate set */

	/* 6 (LSB), 9, 12, 18 (MSB) */
	REG_WRITE(ah, 0xa3c0,
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_6_24], 24) |
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_6_24], 16) |
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_6_24], 8) |
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_6_24], 0));

	/* 24 (LSB), 36, 48, 54 (MSB) */
	REG_WRITE(ah, 0xa3c4,
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_54], 24) |
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_48], 16) |
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_36], 8) |
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_6_24], 0));

	/* Write the CCK power per rate set */

	/* 1L (LSB), reserved, 2L, 2S (MSB) */
	REG_WRITE(ah, 0xa3c8,
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_1L_5L], 24) |
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_1L_5L], 16) |
		  /* POW_SM(txPowerTimes2,  8) | this is reserved for AR9003 */
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_1L_5L], 0));

	/* 5.5L (LSB), 5.5S, 11L, 11S (MSB) */
	REG_WRITE(ah, 0xa3cc,
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_11S], 24) |
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_11L], 16) |
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_5S], 8) |
		  POW_SM(pPwrArray[ALL_TARGET_LEGACY_1L_5L], 0)
	    );

	/* Write the HT20 power per rate set */

	/* 0/8/16 (LSB), 1-3/9-11/17-19, 4, 5 (MSB) */
	REG_WRITE(ah, 0xa3d0,
		  POW_SM(pPwrArray[ALL_TARGET_HT20_5], 24) |
		  POW_SM(pPwrArray[ALL_TARGET_HT20_4], 16) |
		  POW_SM(pPwrArray[ALL_TARGET_HT20_1_3_9_11_17_19], 8) |
		  POW_SM(pPwrArray[ALL_TARGET_HT20_0_8_16], 0)
	    );

	/* 6 (LSB), 7, 12, 13 (MSB) */
	REG_WRITE(ah, 0xa3d4,
		  POW_SM(pPwrArray[ALL_TARGET_HT20_13], 24) |
		  POW_SM(pPwrArray[ALL_TARGET_HT20_12], 16) |
		  POW_SM(pPwrArray[ALL_TARGET_HT20_7], 8) |
		  POW_SM(pPwrArray[ALL_TARGET_HT20_6], 0)
	    );

	/* 14 (LSB), 15, 20, 21 */
	REG_WRITE(ah, 0xa3e4,
		  POW_SM(pPwrArray[ALL_TARGET_HT20_21], 24) |
		  POW_SM(pPwrArray[ALL_TARGET_HT20_20], 16) |
		  POW_SM(pPwrArray[ALL_TARGET_HT20_15], 8) |
		  POW_SM(pPwrArray[ALL_TARGET_HT20_14], 0)
	    );

	/* Mixed HT20 and HT40 rates */

	/* HT20 22 (LSB), HT20 23, HT40 22, HT40 23 (MSB) */
	REG_WRITE(ah, 0xa3e8,
		  POW_SM(pPwrArray[ALL_TARGET_HT40_23], 24) |
		  POW_SM(pPwrArray[ALL_TARGET_HT40_22], 16) |
		  POW_SM(pPwrArray[ALL_TARGET_HT20_23], 8) |
		  POW_SM(pPwrArray[ALL_TARGET_HT20_22], 0)
	    );

	/*
	 * Write the HT40 power per rate set
	 * correct PAR difference between HT40 and HT20/LEGACY
	 * 0/8/16 (LSB), 1-3/9-11/17-19, 4, 5 (MSB)
	 */
	REG_WRITE(ah, 0xa3d8,
		  POW_SM(pPwrArray[ALL_TARGET_HT40_5], 24) |
		  POW_SM(pPwrArray[ALL_TARGET_HT40_4], 16) |
		  POW_SM(pPwrArray[ALL_TARGET_HT40_1_3_9_11_17_19], 8) |
		  POW_SM(pPwrArray[ALL_TARGET_HT40_0_8_16], 0)
	    );

	/* 6 (LSB), 7, 12, 13 (MSB) */
	REG_WRITE(ah, 0xa3dc,
		  POW_SM(pPwrArray[ALL_TARGET_HT40_13], 24) |
		  POW_SM(pPwrArray[ALL_TARGET_HT40_12], 16) |
		  POW_SM(pPwrArray[ALL_TARGET_HT40_7], 8) |
		  POW_SM(pPwrArray[ALL_TARGET_HT40_6], 0)
	    );

	/* 14 (LSB), 15, 20, 21 */
	REG_WRITE(ah, 0xa3ec,
		  POW_SM(pPwrArray[ALL_TARGET_HT40_21], 24) |
		  POW_SM(pPwrArray[ALL_TARGET_HT40_20], 16) |
		  POW_SM(pPwrArray[ALL_TARGET_HT40_15], 8) |
		  POW_SM(pPwrArray[ALL_TARGET_HT40_14], 0)
	    );

	return 0;
#undef POW_SM
}

1442 1443
static void ar9003_hw_set_target_power_eeprom(struct ath_hw *ah, u16 freq,
					      u8 *targetPowerValT2)
1444 1445 1446 1447 1448 1449 1450 1451 1452 1453 1454 1455 1456 1457 1458 1459 1460 1461 1462 1463 1464 1465 1466 1467 1468 1469 1470 1471 1472 1473 1474 1475 1476 1477 1478 1479 1480 1481 1482 1483 1484 1485 1486 1487 1488 1489 1490 1491 1492 1493 1494 1495 1496 1497 1498 1499 1500 1501 1502 1503 1504 1505 1506 1507 1508 1509 1510 1511 1512 1513 1514 1515 1516 1517 1518 1519 1520 1521 1522 1523 1524 1525 1526 1527 1528 1529 1530 1531 1532 1533 1534 1535 1536 1537 1538 1539 1540 1541 1542 1543 1544 1545 1546 1547 1548 1549 1550 1551 1552 1553 1554 1555 1556 1557 1558 1559 1560 1561 1562 1563 1564 1565 1566 1567 1568 1569 1570 1571 1572 1573 1574 1575 1576 1577 1578 1579 1580 1581 1582 1583 1584 1585 1586 1587 1588 1589 1590 1591 1592 1593 1594 1595 1596 1597 1598 1599 1600 1601 1602 1603 1604 1605 1606 1607 1608 1609 1610 1611 1612 1613 1614 1615 1616 1617 1618 1619 1620 1621 1622 1623 1624 1625 1626 1627 1628 1629 1630 1631 1632 1633 1634 1635 1636 1637 1638 1639 1640 1641 1642 1643 1644 1645 1646 1647 1648 1649 1650 1651 1652 1653 1654 1655 1656 1657 1658 1659 1660 1661 1662 1663 1664 1665 1666 1667 1668 1669 1670 1671 1672 1673 1674 1675 1676 1677 1678 1679 1680 1681 1682 1683 1684 1685 1686 1687 1688 1689 1690 1691 1692 1693 1694 1695 1696 1697 1698 1699 1700 1701 1702 1703 1704 1705 1706 1707 1708 1709 1710 1711 1712 1713 1714 1715 1716 1717 1718 1719 1720 1721 1722 1723 1724 1725 1726 1727 1728 1729 1730 1731 1732 1733 1734 1735 1736 1737 1738 1739 1740 1741 1742 1743 1744 1745 1746 1747 1748 1749 1750 1751 1752 1753 1754 1755 1756 1757 1758 1759 1760 1761 1762 1763 1764 1765 1766 1767 1768 1769 1770 1771 1772 1773 1774 1775 1776 1777 1778 1779 1780 1781 1782 1783 1784 1785 1786 1787 1788 1789 1790 1791 1792 1793 1794 1795 1796 1797 1798 1799 1800 1801 1802 1803 1804 1805 1806 1807 1808 1809 1810 1811 1812 1813 1814 1815 1816 1817 1818 1819 1820
{
	/* XXX: hard code for now, need to get from eeprom struct */
	u8 ht40PowerIncForPdadc = 0;
	bool is2GHz = false;
	unsigned int i = 0;
	struct ath_common *common = ath9k_hw_common(ah);

	if (freq < 4000)
		is2GHz = true;

	targetPowerValT2[ALL_TARGET_LEGACY_6_24] =
	    ar9003_hw_eeprom_get_tgt_pwr(ah, LEGACY_TARGET_RATE_6_24, freq,
					 is2GHz);
	targetPowerValT2[ALL_TARGET_LEGACY_36] =
	    ar9003_hw_eeprom_get_tgt_pwr(ah, LEGACY_TARGET_RATE_36, freq,
					 is2GHz);
	targetPowerValT2[ALL_TARGET_LEGACY_48] =
	    ar9003_hw_eeprom_get_tgt_pwr(ah, LEGACY_TARGET_RATE_48, freq,
					 is2GHz);
	targetPowerValT2[ALL_TARGET_LEGACY_54] =
	    ar9003_hw_eeprom_get_tgt_pwr(ah, LEGACY_TARGET_RATE_54, freq,
					 is2GHz);
	targetPowerValT2[ALL_TARGET_LEGACY_1L_5L] =
	    ar9003_hw_eeprom_get_cck_tgt_pwr(ah, LEGACY_TARGET_RATE_1L_5L,
					     freq);
	targetPowerValT2[ALL_TARGET_LEGACY_5S] =
	    ar9003_hw_eeprom_get_cck_tgt_pwr(ah, LEGACY_TARGET_RATE_5S, freq);
	targetPowerValT2[ALL_TARGET_LEGACY_11L] =
	    ar9003_hw_eeprom_get_cck_tgt_pwr(ah, LEGACY_TARGET_RATE_11L, freq);
	targetPowerValT2[ALL_TARGET_LEGACY_11S] =
	    ar9003_hw_eeprom_get_cck_tgt_pwr(ah, LEGACY_TARGET_RATE_11S, freq);
	targetPowerValT2[ALL_TARGET_HT20_0_8_16] =
	    ar9003_hw_eeprom_get_ht20_tgt_pwr(ah, HT_TARGET_RATE_0_8_16, freq,
					      is2GHz);
	targetPowerValT2[ALL_TARGET_HT20_1_3_9_11_17_19] =
	    ar9003_hw_eeprom_get_ht20_tgt_pwr(ah, HT_TARGET_RATE_1_3_9_11_17_19,
					      freq, is2GHz);
	targetPowerValT2[ALL_TARGET_HT20_4] =
	    ar9003_hw_eeprom_get_ht20_tgt_pwr(ah, HT_TARGET_RATE_4, freq,
					      is2GHz);
	targetPowerValT2[ALL_TARGET_HT20_5] =
	    ar9003_hw_eeprom_get_ht20_tgt_pwr(ah, HT_TARGET_RATE_5, freq,
					      is2GHz);
	targetPowerValT2[ALL_TARGET_HT20_6] =
	    ar9003_hw_eeprom_get_ht20_tgt_pwr(ah, HT_TARGET_RATE_6, freq,
					      is2GHz);
	targetPowerValT2[ALL_TARGET_HT20_7] =
	    ar9003_hw_eeprom_get_ht20_tgt_pwr(ah, HT_TARGET_RATE_7, freq,
					      is2GHz);
	targetPowerValT2[ALL_TARGET_HT20_12] =
	    ar9003_hw_eeprom_get_ht20_tgt_pwr(ah, HT_TARGET_RATE_12, freq,
					      is2GHz);
	targetPowerValT2[ALL_TARGET_HT20_13] =
	    ar9003_hw_eeprom_get_ht20_tgt_pwr(ah, HT_TARGET_RATE_13, freq,
					      is2GHz);
	targetPowerValT2[ALL_TARGET_HT20_14] =
	    ar9003_hw_eeprom_get_ht20_tgt_pwr(ah, HT_TARGET_RATE_14, freq,
					      is2GHz);
	targetPowerValT2[ALL_TARGET_HT20_15] =
	    ar9003_hw_eeprom_get_ht20_tgt_pwr(ah, HT_TARGET_RATE_15, freq,
					      is2GHz);
	targetPowerValT2[ALL_TARGET_HT20_20] =
	    ar9003_hw_eeprom_get_ht20_tgt_pwr(ah, HT_TARGET_RATE_20, freq,
					      is2GHz);
	targetPowerValT2[ALL_TARGET_HT20_21] =
	    ar9003_hw_eeprom_get_ht20_tgt_pwr(ah, HT_TARGET_RATE_21, freq,
					      is2GHz);
	targetPowerValT2[ALL_TARGET_HT20_22] =
	    ar9003_hw_eeprom_get_ht20_tgt_pwr(ah, HT_TARGET_RATE_22, freq,
					      is2GHz);
	targetPowerValT2[ALL_TARGET_HT20_23] =
	    ar9003_hw_eeprom_get_ht20_tgt_pwr(ah, HT_TARGET_RATE_23, freq,
					      is2GHz);
	targetPowerValT2[ALL_TARGET_HT40_0_8_16] =
	    ar9003_hw_eeprom_get_ht40_tgt_pwr(ah, HT_TARGET_RATE_0_8_16, freq,
					      is2GHz) + ht40PowerIncForPdadc;
	targetPowerValT2[ALL_TARGET_HT40_1_3_9_11_17_19] =
	    ar9003_hw_eeprom_get_ht40_tgt_pwr(ah, HT_TARGET_RATE_1_3_9_11_17_19,
					      freq,
					      is2GHz) + ht40PowerIncForPdadc;
	targetPowerValT2[ALL_TARGET_HT40_4] =
	    ar9003_hw_eeprom_get_ht40_tgt_pwr(ah, HT_TARGET_RATE_4, freq,
					      is2GHz) + ht40PowerIncForPdadc;
	targetPowerValT2[ALL_TARGET_HT40_5] =
	    ar9003_hw_eeprom_get_ht40_tgt_pwr(ah, HT_TARGET_RATE_5, freq,
					      is2GHz) + ht40PowerIncForPdadc;
	targetPowerValT2[ALL_TARGET_HT40_6] =
	    ar9003_hw_eeprom_get_ht40_tgt_pwr(ah, HT_TARGET_RATE_6, freq,
					      is2GHz) + ht40PowerIncForPdadc;
	targetPowerValT2[ALL_TARGET_HT40_7] =
	    ar9003_hw_eeprom_get_ht40_tgt_pwr(ah, HT_TARGET_RATE_7, freq,
					      is2GHz) + ht40PowerIncForPdadc;
	targetPowerValT2[ALL_TARGET_HT40_12] =
	    ar9003_hw_eeprom_get_ht40_tgt_pwr(ah, HT_TARGET_RATE_12, freq,
					      is2GHz) + ht40PowerIncForPdadc;
	targetPowerValT2[ALL_TARGET_HT40_13] =
	    ar9003_hw_eeprom_get_ht40_tgt_pwr(ah, HT_TARGET_RATE_13, freq,
					      is2GHz) + ht40PowerIncForPdadc;
	targetPowerValT2[ALL_TARGET_HT40_14] =
	    ar9003_hw_eeprom_get_ht40_tgt_pwr(ah, HT_TARGET_RATE_14, freq,
					      is2GHz) + ht40PowerIncForPdadc;
	targetPowerValT2[ALL_TARGET_HT40_15] =
	    ar9003_hw_eeprom_get_ht40_tgt_pwr(ah, HT_TARGET_RATE_15, freq,
					      is2GHz) + ht40PowerIncForPdadc;
	targetPowerValT2[ALL_TARGET_HT40_20] =
	    ar9003_hw_eeprom_get_ht40_tgt_pwr(ah, HT_TARGET_RATE_20, freq,
					      is2GHz) + ht40PowerIncForPdadc;
	targetPowerValT2[ALL_TARGET_HT40_21] =
	    ar9003_hw_eeprom_get_ht40_tgt_pwr(ah, HT_TARGET_RATE_21, freq,
					      is2GHz) + ht40PowerIncForPdadc;
	targetPowerValT2[ALL_TARGET_HT40_22] =
	    ar9003_hw_eeprom_get_ht40_tgt_pwr(ah, HT_TARGET_RATE_22, freq,
					      is2GHz) + ht40PowerIncForPdadc;
	targetPowerValT2[ALL_TARGET_HT40_23] =
	    ar9003_hw_eeprom_get_ht40_tgt_pwr(ah, HT_TARGET_RATE_23, freq,
					      is2GHz) + ht40PowerIncForPdadc;

	while (i < ar9300RateSize) {
		ath_print(common, ATH_DBG_EEPROM,
			  "TPC[%02d] 0x%08x ", i, targetPowerValT2[i]);
		i++;

		ath_print(common, ATH_DBG_EEPROM,
			  "TPC[%02d] 0x%08x ", i, targetPowerValT2[i]);
		i++;

		ath_print(common, ATH_DBG_EEPROM,
			  "TPC[%02d] 0x%08x ", i, targetPowerValT2[i]);
		i++;

		ath_print(common, ATH_DBG_EEPROM,
			  "TPC[%02d] 0x%08x\n", i, targetPowerValT2[i]);
		i++;
	}
}

static int ar9003_hw_cal_pier_get(struct ath_hw *ah,
				  int mode,
				  int ipier,
				  int ichain,
				  int *pfrequency,
				  int *pcorrection,
				  int *ptemperature, int *pvoltage)
{
	u8 *pCalPier;
	struct ar9300_cal_data_per_freq_op_loop *pCalPierStruct;
	int is2GHz;
	struct ar9300_eeprom *eep = &ah->eeprom.ar9300_eep;
	struct ath_common *common = ath9k_hw_common(ah);

	if (ichain >= AR9300_MAX_CHAINS) {
		ath_print(common, ATH_DBG_EEPROM,
			  "Invalid chain index, must be less than %d\n",
			  AR9300_MAX_CHAINS);
		return -1;
	}

	if (mode) {		/* 5GHz */
		if (ipier >= AR9300_NUM_5G_CAL_PIERS) {
			ath_print(common, ATH_DBG_EEPROM,
				  "Invalid 5GHz cal pier index, must "
				  "be less than %d\n",
				  AR9300_NUM_5G_CAL_PIERS);
			return -1;
		}
		pCalPier = &(eep->calFreqPier5G[ipier]);
		pCalPierStruct = &(eep->calPierData5G[ichain][ipier]);
		is2GHz = 0;
	} else {
		if (ipier >= AR9300_NUM_2G_CAL_PIERS) {
			ath_print(common, ATH_DBG_EEPROM,
				  "Invalid 2GHz cal pier index, must "
				  "be less than %d\n", AR9300_NUM_2G_CAL_PIERS);
			return -1;
		}

		pCalPier = &(eep->calFreqPier2G[ipier]);
		pCalPierStruct = &(eep->calPierData2G[ichain][ipier]);
		is2GHz = 1;
	}

	*pfrequency = FBIN2FREQ(*pCalPier, is2GHz);
	*pcorrection = pCalPierStruct->refPower;
	*ptemperature = pCalPierStruct->tempMeas;
	*pvoltage = pCalPierStruct->voltMeas;

	return 0;
}

static int ar9003_hw_power_control_override(struct ath_hw *ah,
					    int frequency,
					    int *correction,
					    int *voltage, int *temperature)
{
	int tempSlope = 0;
	struct ar9300_eeprom *eep = &ah->eeprom.ar9300_eep;

	REG_RMW(ah, AR_PHY_TPC_11_B0,
		(correction[0] << AR_PHY_TPC_OLPC_GAIN_DELTA_S),
		AR_PHY_TPC_OLPC_GAIN_DELTA);
	REG_RMW(ah, AR_PHY_TPC_11_B1,
		(correction[1] << AR_PHY_TPC_OLPC_GAIN_DELTA_S),
		AR_PHY_TPC_OLPC_GAIN_DELTA);
	REG_RMW(ah, AR_PHY_TPC_11_B2,
		(correction[2] << AR_PHY_TPC_OLPC_GAIN_DELTA_S),
		AR_PHY_TPC_OLPC_GAIN_DELTA);

	/* enable open loop power control on chip */
	REG_RMW(ah, AR_PHY_TPC_6_B0,
		(3 << AR_PHY_TPC_6_ERROR_EST_MODE_S),
		AR_PHY_TPC_6_ERROR_EST_MODE);
	REG_RMW(ah, AR_PHY_TPC_6_B1,
		(3 << AR_PHY_TPC_6_ERROR_EST_MODE_S),
		AR_PHY_TPC_6_ERROR_EST_MODE);
	REG_RMW(ah, AR_PHY_TPC_6_B2,
		(3 << AR_PHY_TPC_6_ERROR_EST_MODE_S),
		AR_PHY_TPC_6_ERROR_EST_MODE);

	/*
	 * enable temperature compensation
	 * Need to use register names
	 */
	if (frequency < 4000)
		tempSlope = eep->modalHeader2G.tempSlope;
	else
		tempSlope = eep->modalHeader5G.tempSlope;

	REG_RMW_FIELD(ah, AR_PHY_TPC_19, AR_PHY_TPC_19_ALPHA_THERM, tempSlope);
	REG_RMW_FIELD(ah, AR_PHY_TPC_18, AR_PHY_TPC_18_THERM_CAL_VALUE,
		      temperature[0]);

	return 0;
}

/* Apply the recorded correction values. */
static int ar9003_hw_calibration_apply(struct ath_hw *ah, int frequency)
{
	int ichain, ipier, npier;
	int mode;
	int lfrequency[AR9300_MAX_CHAINS],
	    lcorrection[AR9300_MAX_CHAINS],
	    ltemperature[AR9300_MAX_CHAINS], lvoltage[AR9300_MAX_CHAINS];
	int hfrequency[AR9300_MAX_CHAINS],
	    hcorrection[AR9300_MAX_CHAINS],
	    htemperature[AR9300_MAX_CHAINS], hvoltage[AR9300_MAX_CHAINS];
	int fdiff;
	int correction[AR9300_MAX_CHAINS],
	    voltage[AR9300_MAX_CHAINS], temperature[AR9300_MAX_CHAINS];
	int pfrequency, pcorrection, ptemperature, pvoltage;
	struct ath_common *common = ath9k_hw_common(ah);

	mode = (frequency >= 4000);
	if (mode)
		npier = AR9300_NUM_5G_CAL_PIERS;
	else
		npier = AR9300_NUM_2G_CAL_PIERS;

	for (ichain = 0; ichain < AR9300_MAX_CHAINS; ichain++) {
		lfrequency[ichain] = 0;
		hfrequency[ichain] = 100000;
	}
	/* identify best lower and higher frequency calibration measurement */
	for (ichain = 0; ichain < AR9300_MAX_CHAINS; ichain++) {
		for (ipier = 0; ipier < npier; ipier++) {
			if (!ar9003_hw_cal_pier_get(ah, mode, ipier, ichain,
						    &pfrequency, &pcorrection,
						    &ptemperature, &pvoltage)) {
				fdiff = frequency - pfrequency;

				/*
				 * this measurement is higher than
				 * our desired frequency
				 */
				if (fdiff <= 0) {
					if (hfrequency[ichain] <= 0 ||
					    hfrequency[ichain] >= 100000 ||
					    fdiff >
					    (frequency - hfrequency[ichain])) {
						/*
						 * new best higher
						 * frequency measurement
						 */
						hfrequency[ichain] = pfrequency;
						hcorrection[ichain] =
						    pcorrection;
						htemperature[ichain] =
						    ptemperature;
						hvoltage[ichain] = pvoltage;
					}
				}
				if (fdiff >= 0) {
					if (lfrequency[ichain] <= 0
					    || fdiff <
					    (frequency - lfrequency[ichain])) {
						/*
						 * new best lower
						 * frequency measurement
						 */
						lfrequency[ichain] = pfrequency;
						lcorrection[ichain] =
						    pcorrection;
						ltemperature[ichain] =
						    ptemperature;
						lvoltage[ichain] = pvoltage;
					}
				}
			}
		}
	}

	/* interpolate  */
	for (ichain = 0; ichain < AR9300_MAX_CHAINS; ichain++) {
		ath_print(common, ATH_DBG_EEPROM,
			  "ch=%d f=%d low=%d %d h=%d %d\n",
			  ichain, frequency, lfrequency[ichain],
			  lcorrection[ichain], hfrequency[ichain],
			  hcorrection[ichain]);
		/* they're the same, so just pick one */
		if (hfrequency[ichain] == lfrequency[ichain]) {
			correction[ichain] = lcorrection[ichain];
			voltage[ichain] = lvoltage[ichain];
			temperature[ichain] = ltemperature[ichain];
		}
		/* the low frequency is good */
		else if (frequency - lfrequency[ichain] < 1000) {
			/* so is the high frequency, interpolate */
			if (hfrequency[ichain] - frequency < 1000) {

				correction[ichain] = lcorrection[ichain] +
				    (((frequency - lfrequency[ichain]) *
				      (hcorrection[ichain] -
				       lcorrection[ichain])) /
				     (hfrequency[ichain] - lfrequency[ichain]));

				temperature[ichain] = ltemperature[ichain] +
				    (((frequency - lfrequency[ichain]) *
				      (htemperature[ichain] -
				       ltemperature[ichain])) /
				     (hfrequency[ichain] - lfrequency[ichain]));

				voltage[ichain] =
				    lvoltage[ichain] +
				    (((frequency -
				       lfrequency[ichain]) * (hvoltage[ichain] -
							      lvoltage[ichain]))
				     / (hfrequency[ichain] -
					lfrequency[ichain]));
			}
			/* only low is good, use it */
			else {
				correction[ichain] = lcorrection[ichain];
				temperature[ichain] = ltemperature[ichain];
				voltage[ichain] = lvoltage[ichain];
			}
		}
		/* only high is good, use it */
		else if (hfrequency[ichain] - frequency < 1000) {
			correction[ichain] = hcorrection[ichain];
			temperature[ichain] = htemperature[ichain];
			voltage[ichain] = hvoltage[ichain];
		} else {	/* nothing is good, presume 0???? */
			correction[ichain] = 0;
			temperature[ichain] = 0;
			voltage[ichain] = 0;
		}
	}

	ar9003_hw_power_control_override(ah, frequency, correction, voltage,
					 temperature);

	ath_print(common, ATH_DBG_EEPROM,
		  "for frequency=%d, calibration correction = %d %d %d\n",
		  frequency, correction[0], correction[1], correction[2]);

	return 0;
}

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static u16 ar9003_hw_get_direct_edge_power(struct ar9300_eeprom *eep,
					   int idx,
					   int edge,
					   bool is2GHz)
{
	struct cal_ctl_data_2g *ctl_2g = eep->ctlPowerData_2G;
	struct cal_ctl_data_5g *ctl_5g = eep->ctlPowerData_5G;

	if (is2GHz)
		return ctl_2g[idx].ctlEdges[edge].tPower;
	else
		return ctl_5g[idx].ctlEdges[edge].tPower;
}

static u16 ar9003_hw_get_indirect_edge_power(struct ar9300_eeprom *eep,
					     int idx,
					     unsigned int edge,
					     u16 freq,
					     bool is2GHz)
{
	struct cal_ctl_data_2g *ctl_2g = eep->ctlPowerData_2G;
	struct cal_ctl_data_5g *ctl_5g = eep->ctlPowerData_5G;

	u8 *ctl_freqbin = is2GHz ?
		&eep->ctl_freqbin_2G[idx][0] :
		&eep->ctl_freqbin_5G[idx][0];

	if (is2GHz) {
		if (ath9k_hw_fbin2freq(ctl_freqbin[edge - 1], 1) < freq &&
		    ctl_2g[idx].ctlEdges[edge - 1].flag)
			return ctl_2g[idx].ctlEdges[edge - 1].tPower;
	} else {
		if (ath9k_hw_fbin2freq(ctl_freqbin[edge - 1], 0) < freq &&
		    ctl_5g[idx].ctlEdges[edge - 1].flag)
			return ctl_5g[idx].ctlEdges[edge - 1].tPower;
	}

	return AR9300_MAX_RATE_POWER;
}

/*
 * Find the maximum conformance test limit for the given channel and CTL info
 */
static u16 ar9003_hw_get_max_edge_power(struct ar9300_eeprom *eep,
					u16 freq, int idx, bool is2GHz)
{
	u16 twiceMaxEdgePower = AR9300_MAX_RATE_POWER;
	u8 *ctl_freqbin = is2GHz ?
		&eep->ctl_freqbin_2G[idx][0] :
		&eep->ctl_freqbin_5G[idx][0];
	u16 num_edges = is2GHz ?
		AR9300_NUM_BAND_EDGES_2G : AR9300_NUM_BAND_EDGES_5G;
	unsigned int edge;

	/* Get the edge power */
	for (edge = 0;
	     (edge < num_edges) && (ctl_freqbin[edge] != AR9300_BCHAN_UNUSED);
	     edge++) {
		/*
		 * If there's an exact channel match or an inband flag set
		 * on the lower channel use the given rdEdgePower
		 */
		if (freq == ath9k_hw_fbin2freq(ctl_freqbin[edge], is2GHz)) {
			twiceMaxEdgePower =
				ar9003_hw_get_direct_edge_power(eep, idx,
								edge, is2GHz);
			break;
		} else if ((edge > 0) &&
			   (freq < ath9k_hw_fbin2freq(ctl_freqbin[edge],
						      is2GHz))) {
			twiceMaxEdgePower =
				ar9003_hw_get_indirect_edge_power(eep, idx,
								  edge, freq,
								  is2GHz);
			/*
			 * Leave loop - no more affecting edges possible in
			 * this monotonic increasing list
			 */
			break;
		}
	}
	return twiceMaxEdgePower;
}

static void ar9003_hw_set_power_per_rate_table(struct ath_hw *ah,
					       struct ath9k_channel *chan,
					       u8 *pPwrArray, u16 cfgCtl,
					       u8 twiceAntennaReduction,
					       u8 twiceMaxRegulatoryPower,
					       u16 powerLimit)
{
	struct ath_regulatory *regulatory = ath9k_hw_regulatory(ah);
	struct ath_common *common = ath9k_hw_common(ah);
	struct ar9300_eeprom *pEepData = &ah->eeprom.ar9300_eep;
	u16 twiceMaxEdgePower = AR9300_MAX_RATE_POWER;
	static const u16 tpScaleReductionTable[5] = {
		0, 3, 6, 9, AR9300_MAX_RATE_POWER
	};
	int i;
	int16_t  twiceLargestAntenna;
	u16 scaledPower = 0, minCtlPower, maxRegAllowedPower;
	u16 ctlModesFor11a[] = {
		CTL_11A, CTL_5GHT20, CTL_11A_EXT, CTL_5GHT40
	};
	u16 ctlModesFor11g[] = {
		CTL_11B, CTL_11G, CTL_2GHT20, CTL_11B_EXT,
		CTL_11G_EXT, CTL_2GHT40
	};
	u16 numCtlModes, *pCtlMode, ctlMode, freq;
	struct chan_centers centers;
	u8 *ctlIndex;
	u8 ctlNum;
	u16 twiceMinEdgePower;
	bool is2ghz = IS_CHAN_2GHZ(chan);

	ath9k_hw_get_channel_centers(ah, chan, &centers);

	/* Compute TxPower reduction due to Antenna Gain */
	if (is2ghz)
		twiceLargestAntenna = pEepData->modalHeader2G.antennaGain;
	else
		twiceLargestAntenna = pEepData->modalHeader5G.antennaGain;

	twiceLargestAntenna = (int16_t)min((twiceAntennaReduction) -
				twiceLargestAntenna, 0);

	/*
	 * scaledPower is the minimum of the user input power level
	 * and the regulatory allowed power level
	 */
	maxRegAllowedPower = twiceMaxRegulatoryPower + twiceLargestAntenna;

	if (regulatory->tp_scale != ATH9K_TP_SCALE_MAX) {
		maxRegAllowedPower -=
			(tpScaleReductionTable[(regulatory->tp_scale)] * 2);
	}

	scaledPower = min(powerLimit, maxRegAllowedPower);

	/*
	 * Reduce scaled Power by number of chains active to get
	 * to per chain tx power level
	 */
	switch (ar5416_get_ntxchains(ah->txchainmask)) {
	case 1:
		break;
	case 2:
		scaledPower -= REDUCE_SCALED_POWER_BY_TWO_CHAIN;
		break;
	case 3:
		scaledPower -= REDUCE_SCALED_POWER_BY_THREE_CHAIN;
		break;
	}

	scaledPower = max((u16)0, scaledPower);

	/*
	 * Get target powers from EEPROM - our baseline for TX Power
	 */
	if (is2ghz) {
		/* Setup for CTL modes */
		/* CTL_11B, CTL_11G, CTL_2GHT20 */
		numCtlModes =
			ARRAY_SIZE(ctlModesFor11g) -
				   SUB_NUM_CTL_MODES_AT_2G_40;
		pCtlMode = ctlModesFor11g;
		if (IS_CHAN_HT40(chan))
			/* All 2G CTL's */
			numCtlModes = ARRAY_SIZE(ctlModesFor11g);
	} else {
		/* Setup for CTL modes */
		/* CTL_11A, CTL_5GHT20 */
		numCtlModes = ARRAY_SIZE(ctlModesFor11a) -
					 SUB_NUM_CTL_MODES_AT_5G_40;
		pCtlMode = ctlModesFor11a;
		if (IS_CHAN_HT40(chan))
			/* All 5G CTL's */
			numCtlModes = ARRAY_SIZE(ctlModesFor11a);
	}

	/*
	 * For MIMO, need to apply regulatory caps individually across
	 * dynamically running modes: CCK, OFDM, HT20, HT40
	 *
	 * The outer loop walks through each possible applicable runtime mode.
	 * The inner loop walks through each ctlIndex entry in EEPROM.
	 * The ctl value is encoded as [7:4] == test group, [3:0] == test mode.
	 */
	for (ctlMode = 0; ctlMode < numCtlModes; ctlMode++) {
		bool isHt40CtlMode = (pCtlMode[ctlMode] == CTL_5GHT40) ||
			(pCtlMode[ctlMode] == CTL_2GHT40);
		if (isHt40CtlMode)
			freq = centers.synth_center;
		else if (pCtlMode[ctlMode] & EXT_ADDITIVE)
			freq = centers.ext_center;
		else
			freq = centers.ctl_center;

		ath_print(common, ATH_DBG_REGULATORY,
			  "LOOP-Mode ctlMode %d < %d, isHt40CtlMode %d, "
			  "EXT_ADDITIVE %d\n",
			  ctlMode, numCtlModes, isHt40CtlMode,
			  (pCtlMode[ctlMode] & EXT_ADDITIVE));

		/* walk through each CTL index stored in EEPROM */
		if (is2ghz) {
			ctlIndex = pEepData->ctlIndex_2G;
			ctlNum = AR9300_NUM_CTLS_2G;
		} else {
			ctlIndex = pEepData->ctlIndex_5G;
			ctlNum = AR9300_NUM_CTLS_5G;
		}

		for (i = 0; (i < ctlNum) && ctlIndex[i]; i++) {
			ath_print(common, ATH_DBG_REGULATORY,
				  "LOOP-Ctlidx %d: cfgCtl 0x%2.2x "
				  "pCtlMode 0x%2.2x ctlIndex 0x%2.2x "
				  "chan %dn",
				  i, cfgCtl, pCtlMode[ctlMode], ctlIndex[i],
				  chan->channel);

				/*
				 * compare test group from regulatory
				 * channel list with test mode from pCtlMode
				 * list
				 */
				if ((((cfgCtl & ~CTL_MODE_M) |
				       (pCtlMode[ctlMode] & CTL_MODE_M)) ==
					ctlIndex[i]) ||
				    (((cfgCtl & ~CTL_MODE_M) |
				       (pCtlMode[ctlMode] & CTL_MODE_M)) ==
				     ((ctlIndex[i] & CTL_MODE_M) |
				       SD_NO_CTL))) {
					twiceMinEdgePower =
					  ar9003_hw_get_max_edge_power(pEepData,
								       freq, i,
								       is2ghz);

					if ((cfgCtl & ~CTL_MODE_M) == SD_NO_CTL)
						/*
						 * Find the minimum of all CTL
						 * edge powers that apply to
						 * this channel
						 */
						twiceMaxEdgePower =
							min(twiceMaxEdgePower,
							    twiceMinEdgePower);
						else {
							/* specific */
							twiceMaxEdgePower =
							  twiceMinEdgePower;
							break;
						}
				}
			}

			minCtlPower = (u8)min(twiceMaxEdgePower, scaledPower);

			ath_print(common, ATH_DBG_REGULATORY,
				  "SEL-Min ctlMode %d pCtlMode %d 2xMaxEdge %d "
				  "sP %d minCtlPwr %d\n",
				  ctlMode, pCtlMode[ctlMode], twiceMaxEdgePower,
				  scaledPower, minCtlPower);

			/* Apply ctl mode to correct target power set */
			switch (pCtlMode[ctlMode]) {
			case CTL_11B:
				for (i = ALL_TARGET_LEGACY_1L_5L;
				     i <= ALL_TARGET_LEGACY_11S; i++)
					pPwrArray[i] =
					  (u8)min((u16)pPwrArray[i],
						  minCtlPower);
				break;
			case CTL_11A:
			case CTL_11G:
				for (i = ALL_TARGET_LEGACY_6_24;
				     i <= ALL_TARGET_LEGACY_54; i++)
					pPwrArray[i] =
					  (u8)min((u16)pPwrArray[i],
						  minCtlPower);
				break;
			case CTL_5GHT20:
			case CTL_2GHT20:
				for (i = ALL_TARGET_HT20_0_8_16;
				     i <= ALL_TARGET_HT20_21; i++)
					pPwrArray[i] =
					  (u8)min((u16)pPwrArray[i],
						  minCtlPower);
				pPwrArray[ALL_TARGET_HT20_22] =
				  (u8)min((u16)pPwrArray[ALL_TARGET_HT20_22],
					  minCtlPower);
				pPwrArray[ALL_TARGET_HT20_23] =
				  (u8)min((u16)pPwrArray[ALL_TARGET_HT20_23],
					   minCtlPower);
				break;
			case CTL_5GHT40:
			case CTL_2GHT40:
				for (i = ALL_TARGET_HT40_0_8_16;
				     i <= ALL_TARGET_HT40_23; i++)
					pPwrArray[i] =
					  (u8)min((u16)pPwrArray[i],
						  minCtlPower);
				break;
			default:
			    break;
			}
	} /* end ctl mode checking */
}

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static void ath9k_hw_ar9300_set_txpower(struct ath_hw *ah,
					struct ath9k_channel *chan, u16 cfgCtl,
					u8 twiceAntennaReduction,
					u8 twiceMaxRegulatoryPower,
					u8 powerLimit)
{
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	struct ath_common *common = ath9k_hw_common(ah);
	u8 targetPowerValT2[ar9300RateSize];
	unsigned int i = 0;

	ar9003_hw_set_target_power_eeprom(ah, chan->channel, targetPowerValT2);
	ar9003_hw_set_power_per_rate_table(ah, chan,
					   targetPowerValT2, cfgCtl,
					   twiceAntennaReduction,
					   twiceMaxRegulatoryPower,
					   powerLimit);

	while (i < ar9300RateSize) {
		ath_print(common, ATH_DBG_EEPROM,
			  "TPC[%02d] 0x%08x ", i, targetPowerValT2[i]);
		i++;
		ath_print(common, ATH_DBG_EEPROM,
			  "TPC[%02d] 0x%08x ", i, targetPowerValT2[i]);
		i++;
		ath_print(common, ATH_DBG_EEPROM,
			  "TPC[%02d] 0x%08x ", i, targetPowerValT2[i]);
		i++;
		ath_print(common, ATH_DBG_EEPROM,
			  "TPC[%02d] 0x%08x\n\n", i, targetPowerValT2[i]);
		i++;
	}

	/* Write target power array to registers */
	ar9003_hw_tx_power_regwrite(ah, targetPowerValT2);

	/*
	 * This is the TX power we send back to driver core,
	 * and it can use to pass to userspace to display our
	 * currently configured TX power setting.
	 *
	 * Since power is rate dependent, use one of the indices
	 * from the AR9300_Rates enum to select an entry from
	 * targetPowerValT2[] to report. Currently returns the
	 * power for HT40 MCS 0, HT20 MCS 0, or OFDM 6 Mbps
	 * as CCK power is less interesting (?).
	 */
	i = ALL_TARGET_LEGACY_6_24; /* legacy */
	if (IS_CHAN_HT40(chan))
		i = ALL_TARGET_HT40_0_8_16; /* ht40 */
	else if (IS_CHAN_HT20(chan))
		i = ALL_TARGET_HT20_0_8_16; /* ht20 */

	ah->txpower_limit = targetPowerValT2[i];

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	ar9003_hw_calibration_apply(ah, chan->channel);
}

static u16 ath9k_hw_ar9300_get_spur_channel(struct ath_hw *ah,
					    u16 i, bool is2GHz)
{
	return AR_NO_SPUR;
}

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s32 ar9003_hw_get_tx_gain_idx(struct ath_hw *ah)
{
	struct ar9300_eeprom *eep = &ah->eeprom.ar9300_eep;

	return (eep->baseEepHeader.txrxgain >> 4) & 0xf; /* bits 7:4 */
}

s32 ar9003_hw_get_rx_gain_idx(struct ath_hw *ah)
{
	struct ar9300_eeprom *eep = &ah->eeprom.ar9300_eep;

	return (eep->baseEepHeader.txrxgain) & 0xf; /* bits 3:0 */
}

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const struct eeprom_ops eep_ar9300_ops = {
	.check_eeprom = ath9k_hw_ar9300_check_eeprom,
	.get_eeprom = ath9k_hw_ar9300_get_eeprom,
	.fill_eeprom = ath9k_hw_ar9300_fill_eeprom,
	.get_eeprom_ver = ath9k_hw_ar9300_get_eeprom_ver,
	.get_eeprom_rev = ath9k_hw_ar9300_get_eeprom_rev,
	.get_num_ant_config = ath9k_hw_ar9300_get_num_ant_config,
	.get_eeprom_antenna_cfg = ath9k_hw_ar9300_get_eeprom_antenna_cfg,
	.set_board_values = ath9k_hw_ar9300_set_board_values,
	.set_addac = ath9k_hw_ar9300_set_addac,
	.set_txpower = ath9k_hw_ar9300_set_txpower,
	.get_spur_channel = ath9k_hw_ar9300_get_spur_channel
};