drivers/hwmon/m_adcproc.c - kernel/msm - Gitiles

 /* Copyright (c) 2010-2011, The Linux Foundation. All rights reserved.
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License version 2 and
  * only version 2 as published by the Free Software Foundation.
  *
  * This program is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  * GNU General Public License for more details.
  */

 #include <linux/kernel.h>

 #include <linux/msm_adc.h>

 #define KELVINMIL_DEGMIL	273160

 static const struct adc_map_pt adcmap_batttherm[] = {
 	{2020,	-30},
 	{1923,	-20},
 	{1796,	-10},
 	{1640,	  0},
 	{1459,	 10},
 	{1260,	 20},
 	{1159,	 25},
 	{1059,	 30},
 	{871,	 40},
 	{706,	 50},
 	{567,	 60},
 	{453,	 70},
 	{364,	 80}
 };

 static const struct adc_map_pt adcmap_msmtherm[] = {
 	{2150,	-30},
 	{2107,	-20},
 	{2037,	-10},
 	{1929,	  0},
 	{1776,	 10},
 	{1579,	 20},
 	{1467,	 25},
 	{1349,	 30},
 	{1108,	 40},
 	{878,	 50},
 	{677,	 60},
 	{513,	 70},
 	{385,	 80},
 	{287,	 90},
 	{215,	100},
 	{186,	110},
 	{107,	120}
 };

 static const struct adc_map_pt adcmap_ntcg104ef104fb[] = {
 	{696483,	-40960},
 	{649148,	-39936},
 	{605368,	-38912},
 	{564809,	-37888},
 	{527215,	-36864},
 	{492322,	-35840},
 	{460007,	-34816},
 	{429982,	-33792},
 	{402099,	-32768},
 	{376192,	-31744},
 	{352075,	-30720},
 	{329714,	-29696},
 	{308876,	-28672},
 	{289480,	-27648},
 	{271417,	-26624},
 	{254574,	-25600},
 	{238903,	-24576},
 	{224276,	-23552},
 	{210631,	-22528},
 	{197896,	-21504},
 	{186007,	-20480},
 	{174899,	-19456},
 	{164521,	-18432},
 	{154818,	-17408},
 	{145744,	-16384},
 	{137265,	-15360},
 	{129307,	-14336},
 	{121866,	-13312},
 	{114896,	-12288},
 	{108365,	-11264},
 	{102252,	-10240},
 	{96499,		-9216},
 	{91111,		-8192},
 	{86055,		-7168},
 	{81308,		-6144},
 	{76857,		-5120},
 	{72660,		-4096},
 	{68722,		-3072},
 	{65020,		-2048},
 	{61538,		-1024},
 	{58261,		0},
 	{55177,		1024},
 	{52274,		2048},
 	{49538,		3072},
 	{46962,		4096},
 	{44531,		5120},
 	{42243,		6144},
 	{40083,		7168},
 	{38045,		8192},
 	{36122,		9216},
 	{34308,		10240},
 	{32592,		11264},
 	{30972,		12288},
 	{29442,		13312},
 	{27995,		14336},
 	{26624,		15360},
 	{25333,		16384},
 	{24109,		17408},
 	{22951,		18432},
 	{21854,		19456},
 	{20807,		20480},
 	{19831,		21504},
 	{18899,		22528},
 	{18016,		23552},
 	{17178,		24576},
 	{16384,		25600},
 	{15631,		26624},
 	{14916,		27648},
 	{14237,		28672},
 	{13593,		29696},
 	{12976,		30720},
 	{12400,		31744},
 	{11848,		32768},
 	{11324,		33792},
 	{10825,		34816},
 	{10354,		35840},
 	{9900,		36864},
 	{9471,		37888},
 	{9062,		38912},
 	{8674,		39936},
 	{8306,		40960},
 	{7951,		41984},
 	{7616,		43008},
 	{7296,		44032},
 	{6991,		45056},
 	{6701,		46080},
 	{6424,		47104},
 	{6160,		48128},
 	{5908,		49152},
 	{5667,		50176},
 	{5439,		51200},
 	{5219,		52224},
 	{5010,		53248},
 	{4810,		54272},
 	{4619,		55296},
 	{4440,		56320},
 	{4263,		57344},
 	{4097,		58368},
 	{3938,		59392},
 	{3785,		60416},
 	{3637,		61440},
 	{3501,		62464},
 	{3368,		63488},
 	{3240,		64512},
 	{3118,		65536},
 	{2998,		66560},
 	{2889,		67584},
 	{2782,		68608},
 	{2680,		69632},
 	{2581,		70656},
 	{2490,		71680},
 	{2397,		72704},
 	{2310,		73728},
 	{2227,		74752},
 	{2147,		75776},
 	{2064,		76800},
 	{1998,		77824},
 	{1927,		78848},
 	{1860,		79872},
 	{1795,		80896},
 	{1736,		81920},
 	{1673,		82944},
 	{1615,		83968},
 	{1560,		84992},
 	{1507,		86016},
 	{1456,		87040},
 	{1407,		88064},
 	{1360,		89088},
 	{1314,		90112},
 	{1271,		91136},
 	{1228,		92160},
 	{1189,		93184},
 	{1150,		94208},
 	{1112,		95232},
 	{1076,		96256},
 	{1042,		97280},
 	{1008,		98304},
 	{976,		99328},
 	{945,		100352},
 	{915,		101376},
 	{886,		102400},
 	{859,		103424},
 	{832,		104448},
 	{807,		105472},
 	{782,		106496},
 	{756,		107520},
 	{735,		108544},
 	{712,		109568},
 	{691,		110592},
 	{670,		111616},
 	{650,		112640},
 	{631,		113664},
 	{612,		114688},
 	{594,		115712},
 	{577,		116736},
 	{560,		117760},
 	{544,		118784},
 	{528,		119808},
 	{513,		120832},
 	{498,		121856},
 	{483,		122880},
 	{470,		123904},
 	{457,		124928},
 	{444,		125952},
 	{431,		126976},
 	{419,		128000}
 };

 static int32_t
 	adc_map_linear(const struct adc_map_pt *pts,
 		uint32_t tablesize, int32_t input, int64_t *output)
 {
 	bool descending = 1;
 	uint32_t i = 0;

 	if ((pts == NULL) || (output == NULL))
 		return -EINVAL;

 	/* Check if table is descending or ascending */
 	if (tablesize > 1) {
 		if (pts[0].x < pts[1].x)
 			descending = 0;
 	}

 	while (i < tablesize) {
 		if ((descending == 1) && (pts[i].x < input)) {
 			/* table entry is less than measured
 				value and table is descending, stop */
 			break;
 		} else if ((descending == 0) &&
 				(pts[i].x > input)) {
 			/* table entry is greater than measured
 				value and table is ascending, stop */
 			break;
 		} else
 			i++;
 	}

 	if (i == 0)
 		*output = pts[0].y;
 	else if (i == tablesize)
 		*output = pts[tablesize-1].y;
 	else {
 	/* result is between search_index and search_index-1 */
 	/* interpolate linearly */
 	*output = (((int32_t) ((pts[i].y - pts[i-1].y)*
 			(input - pts[i-1].x))/
 			(pts[i].x - pts[i-1].x))+
 			pts[i-1].y);
 	}

 	return 0;
 }

 int32_t scale_default(int32_t adc_code,
 				const struct adc_properties *adc_properties,
 				const struct chan_properties *chan_properties,
 				struct adc_chan_result *adc_chan_result)
 {
 	bool negative_rawfromoffset = 0;
 	int32_t rawfromoffset = adc_code - chan_properties->adc_graph->offset;

 	if (!chan_properties->gain_numerator ||
 		!chan_properties->gain_denominator)
 		return -EINVAL;

 	adc_chan_result->adc_code = adc_code;
 	if (rawfromoffset < 0) {
 		if (adc_properties->bipolar) {
 			rawfromoffset = (rawfromoffset ^ -1) +  1;
 			negative_rawfromoffset = 1;
 		} else
 			rawfromoffset = 0;
 	}

 	if (rawfromoffset >= 1 << adc_properties->bitresolution)
 		rawfromoffset = (1 << adc_properties->bitresolution) - 1;

 	adc_chan_result->measurement = (int64_t)rawfromoffset*
 					chan_properties->adc_graph->dx*
 					chan_properties->gain_denominator;

 	/* do_div only perform positive integer division! */
 	do_div(adc_chan_result->measurement, chan_properties->adc_graph->dy*
 					chan_properties->gain_numerator);

 	if (negative_rawfromoffset)
 		adc_chan_result->measurement =
 		(adc_chan_result->measurement ^ -1) + 1;

 	/* Note: adc_chan_result->measurement is in the unit of
 	 * adc_properties.adc_reference. For generic channel processing,
 	 * channel measurement is a scale/ratio relative to the adc
 	 * reference input */
 	adc_chan_result->physical = (int32_t) adc_chan_result->measurement;

 	return 0;
 }

 int32_t scale_batt_therm(int32_t adc_code,
 				const struct adc_properties *adc_properties,
 				const struct chan_properties *chan_properties,
 				struct adc_chan_result *adc_chan_result)
 {
 	scale_default(adc_code, adc_properties, chan_properties,
 			adc_chan_result);
 	/* convert mV ---> degC using the table */
 	return adc_map_linear(
 			adcmap_batttherm,
 			sizeof(adcmap_batttherm)/sizeof(adcmap_batttherm[0]),
 			adc_chan_result->physical,
 			&adc_chan_result->physical);
 }

 int32_t scale_msm_therm(int32_t adc_code,
 		const struct adc_properties *adc_properties,
 		const struct chan_properties *chan_properties,
 		struct adc_chan_result *adc_chan_result)
 {
 	scale_default(adc_code, adc_properties, chan_properties,
 			adc_chan_result);
 	/* convert mV ---> degC using the table */
 	return adc_map_linear(
 			adcmap_msmtherm,
 			sizeof(adcmap_msmtherm)/sizeof(adcmap_msmtherm[0]),
 			adc_chan_result->physical,
 			&adc_chan_result->physical);
 }

 int32_t scale_pmic_therm(int32_t adc_code,
 				const struct adc_properties *adc_properties,
 				const struct chan_properties *chan_properties,
 				struct adc_chan_result *adc_chan_result)
 {
 	/* 2mV/K */
 	int32_t rawfromoffset = adc_code - chan_properties->adc_graph->offset;

 	if (!chan_properties->gain_numerator ||
 		!chan_properties->gain_denominator)
 		return -EINVAL;

 	adc_chan_result->adc_code = adc_code;
 	if (rawfromoffset > 0) {
 		if (rawfromoffset >= 1 << adc_properties->bitresolution)
 			rawfromoffset = (1 << adc_properties->bitresolution)
 									- 1;
 		adc_chan_result->measurement = (int64_t)rawfromoffset*
 					chan_properties->adc_graph->dx*
 					chan_properties->gain_denominator*1000;
 		do_div(adc_chan_result->measurement,
 			chan_properties->adc_graph->dy*
 			chan_properties->gain_numerator*2);
 	} else {
 		adc_chan_result->measurement = 0;
 	}
 	/* Note: adc_chan_result->measurement is in the unit of
 		adc_properties.adc_reference */
 	adc_chan_result->physical = (int32_t)adc_chan_result->measurement;
 	/* Change to .001 deg C */
 	adc_chan_result->physical -= KELVINMIL_DEGMIL;
 	adc_chan_result->measurement <<= 1;

 	return 0;
 }

 /* Scales the ADC code to 0.001 degrees C using the map
  * table for the XO thermistor.
  */
 int32_t tdkntcgtherm(int32_t adc_code,
 			const struct adc_properties *adc_properties,
 			const struct chan_properties *chan_properties,
 			struct adc_chan_result *adc_chan_result)
 {
 	int32_t offset = chan_properties->adc_graph->offset,
 		dy = chan_properties->adc_graph->dy,
 		dx = chan_properties->adc_graph->dx,
 		fullscale_calibrated_adc_code;

 	uint32_t rt_r25;
 	uint32_t num1, num2, denom;

 	adc_chan_result->adc_code = adc_code;
 	fullscale_calibrated_adc_code = dy + offset;
 	/* The above is a short cut in math that would reduce a lot of
 	   computation whereas the below expression
 		(adc_properties->adc_reference*dy+dx*offset+(dx>>1))/dx
 	   is a more generic formula when the 2 reference voltages are
 	   different than 0 and full scale voltage. */

 	if ((dy == 0) || (dx == 0) ||
 			(offset >= fullscale_calibrated_adc_code)) {
 		return -EINVAL;
 	} else {
 		if (adc_code >= fullscale_calibrated_adc_code) {
 			rt_r25 = (uint32_t)-1;
 		} else if (adc_code <= offset) {
 			rt_r25 = 0;
 		} else {
 	/* The formula used is (adc_code of current reading - offset)/
 	 * (the calibrated fullscale adc code - adc_code of current reading).
 	 * For this channel, at this time, chan_properties->gain_numerator =
 	 * chan_properties->gain_denominator = 1, so no need to incorporate
 	 * into the formula even though we could and multiply/divide by 1
 	 * which yields the same result but expensive on computation. */
 		num1 = (adc_code - offset) << 14;
 		num2 = (fullscale_calibrated_adc_code - adc_code) >> 1;
 		denom = fullscale_calibrated_adc_code - adc_code;

 			if ((int)denom <= 0)
 				rt_r25 = 0x7FFFFFFF;
 			else
 				rt_r25 = (num1 + num2) / denom;
 		}

 		if (rt_r25 > 0x7FFFFFFF)
 			rt_r25 = 0x7FFFFFFF;

 		adc_map_linear(adcmap_ntcg104ef104fb,
 		sizeof(adcmap_ntcg104ef104fb)/sizeof(adcmap_ntcg104ef104fb[0]),
 		(int32_t)rt_r25, &adc_chan_result->physical);
 	}

 	return 0;
 }

 int32_t scale_xtern_chgr_cur(int32_t adc_code,
 			const struct adc_properties *adc_properties,
 			const struct chan_properties *chan_properties,
 			struct adc_chan_result *adc_chan_result)
 {
 	int32_t rawfromoffset = adc_code - chan_properties->adc_graph->offset;

 	if (!chan_properties->gain_numerator ||
 		!chan_properties->gain_denominator)
 		return -EINVAL;

 	adc_chan_result->adc_code = adc_code;
 	if (rawfromoffset > 0) {
 		if (rawfromoffset >= 1 << adc_properties->bitresolution)
 			rawfromoffset = (1 << adc_properties->bitresolution)
 									- 1;
 		adc_chan_result->measurement = ((int64_t)rawfromoffset * 5)*
 						chan_properties->adc_graph->dx*
 					chan_properties->gain_denominator;
 		do_div(adc_chan_result->measurement,
 					chan_properties->adc_graph->dy*
 					chan_properties->gain_numerator);
 	} else {
 		adc_chan_result->measurement = 0;
 	}
 	adc_chan_result->physical = (int32_t) adc_chan_result->measurement;

 	return 0;
 }
	/* Copyright (c) 2010-2011, The Linux Foundation. All rights reserved.
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License version 2 and
	* only version 2 as published by the Free Software Foundation.
	*
	* This program is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	* GNU General Public License for more details.
	*/

	#include <linux/kernel.h>

	#include <linux/msm_adc.h>

	#define KELVINMIL_DEGMIL 273160

	static const struct adc_map_pt adcmap_batttherm[] = {
	{2020, -30},
	{1923, -20},
	{1796, -10},
	{1640, 0},
	{1459, 10},
	{1260, 20},
	{1159, 25},
	{1059, 30},
	{871, 40},
	{706, 50},
	{567, 60},
	{453, 70},
	{364, 80}
	};

	static const struct adc_map_pt adcmap_msmtherm[] = {
	{2150, -30},
	{2107, -20},
	{2037, -10},
	{1929, 0},
	{1776, 10},
	{1579, 20},
	{1467, 25},
	{1349, 30},
	{1108, 40},
	{878, 50},
	{677, 60},
	{513, 70},
	{385, 80},
	{287, 90},
	{215, 100},
	{186, 110},
	{107, 120}
	};

	static const struct adc_map_pt adcmap_ntcg104ef104fb[] = {
	{696483, -40960},
	{649148, -39936},
	{605368, -38912},
	{564809, -37888},
	{527215, -36864},
	{492322, -35840},
	{460007, -34816},
	{429982, -33792},
	{402099, -32768},
	{376192, -31744},
	{352075, -30720},
	{329714, -29696},
	{308876, -28672},
	{289480, -27648},
	{271417, -26624},
	{254574, -25600},
	{238903, -24576},
	{224276, -23552},
	{210631, -22528},
	{197896, -21504},
	{186007, -20480},
	{174899, -19456},
	{164521, -18432},
	{154818, -17408},
	{145744, -16384},
	{137265, -15360},
	{129307, -14336},
	{121866, -13312},
	{114896, -12288},
	{108365, -11264},
	{102252, -10240},
	{96499, -9216},
	{91111, -8192},
	{86055, -7168},
	{81308, -6144},
	{76857, -5120},
	{72660, -4096},
	{68722, -3072},
	{65020, -2048},
	{61538, -1024},
	{58261, 0},
	{55177, 1024},
	{52274, 2048},
	{49538, 3072},
	{46962, 4096},
	{44531, 5120},
	{42243, 6144},
	{40083, 7168},
	{38045, 8192},
	{36122, 9216},
	{34308, 10240},
	{32592, 11264},
	{30972, 12288},
	{29442, 13312},
	{27995, 14336},
	{26624, 15360},
	{25333, 16384},
	{24109, 17408},
	{22951, 18432},
	{21854, 19456},
	{20807, 20480},
	{19831, 21504},
	{18899, 22528},
	{18016, 23552},
	{17178, 24576},
	{16384, 25600},
	{15631, 26624},
	{14916, 27648},
	{14237, 28672},
	{13593, 29696},
	{12976, 30720},
	{12400, 31744},
	{11848, 32768},
	{11324, 33792},
	{10825, 34816},
	{10354, 35840},
	{9900, 36864},
	{9471, 37888},
	{9062, 38912},
	{8674, 39936},
	{8306, 40960},
	{7951, 41984},
	{7616, 43008},
	{7296, 44032},
	{6991, 45056},
	{6701, 46080},
	{6424, 47104},
	{6160, 48128},
	{5908, 49152},
	{5667, 50176},
	{5439, 51200},
	{5219, 52224},
	{5010, 53248},
	{4810, 54272},
	{4619, 55296},
	{4440, 56320},
	{4263, 57344},
	{4097, 58368},
	{3938, 59392},
	{3785, 60416},
	{3637, 61440},
	{3501, 62464},
	{3368, 63488},
	{3240, 64512},
	{3118, 65536},
	{2998, 66560},
	{2889, 67584},
	{2782, 68608},
	{2680, 69632},
	{2581, 70656},
	{2490, 71680},
	{2397, 72704},
	{2310, 73728},
	{2227, 74752},
	{2147, 75776},
	{2064, 76800},
	{1998, 77824},
	{1927, 78848},
	{1860, 79872},
	{1795, 80896},
	{1736, 81920},
	{1673, 82944},
	{1615, 83968},
	{1560, 84992},
	{1507, 86016},
	{1456, 87040},
	{1407, 88064},
	{1360, 89088},
	{1314, 90112},
	{1271, 91136},
	{1228, 92160},
	{1189, 93184},
	{1150, 94208},
	{1112, 95232},
	{1076, 96256},
	{1042, 97280},
	{1008, 98304},
	{976, 99328},
	{945, 100352},
	{915, 101376},
	{886, 102400},
	{859, 103424},
	{832, 104448},
	{807, 105472},
	{782, 106496},
	{756, 107520},
	{735, 108544},
	{712, 109568},
	{691, 110592},
	{670, 111616},
	{650, 112640},
	{631, 113664},
	{612, 114688},
	{594, 115712},
	{577, 116736},
	{560, 117760},
	{544, 118784},
	{528, 119808},
	{513, 120832},
	{498, 121856},
	{483, 122880},
	{470, 123904},
	{457, 124928},
	{444, 125952},
	{431, 126976},
	{419, 128000}
	};

	static int32_t
	adc_map_linear(const struct adc_map_pt *pts,
	uint32_t tablesize, int32_t input, int64_t *output)
	{
	bool descending = 1;
	uint32_t i = 0;

	if ((pts == NULL) \|\| (output == NULL))
	return -EINVAL;

	/* Check if table is descending or ascending */
	if (tablesize > 1) {
	if (pts[0].x < pts[1].x)
	descending = 0;
	}

	while (i < tablesize) {
	if ((descending == 1) && (pts[i].x < input)) {
	/* table entry is less than measured
	value and table is descending, stop */
	break;
	} else if ((descending == 0) &&
	(pts[i].x > input)) {
	/* table entry is greater than measured
	value and table is ascending, stop */
	break;
	} else
	i++;
	}

	if (i == 0)
	*output = pts[0].y;
	else if (i == tablesize)
	*output = pts[tablesize-1].y;
	else {
	/* result is between search_index and search_index-1 */
	/* interpolate linearly */
	output = (((int32_t) ((pts[i].y - pts[i-1].y)
	(input - pts[i-1].x))/
	(pts[i].x - pts[i-1].x))+
	pts[i-1].y);
	}

	return 0;
	}

	int32_t scale_default(int32_t adc_code,
	const struct adc_properties *adc_properties,
	const struct chan_properties *chan_properties,
	struct adc_chan_result *adc_chan_result)
	{
	bool negative_rawfromoffset = 0;
	int32_t rawfromoffset = adc_code - chan_properties->adc_graph->offset;

	if (!chan_properties->gain_numerator \|\|
	!chan_properties->gain_denominator)
	return -EINVAL;

	adc_chan_result->adc_code = adc_code;
	if (rawfromoffset < 0) {
	if (adc_properties->bipolar) {
	rawfromoffset = (rawfromoffset ^ -1) + 1;
	negative_rawfromoffset = 1;
	} else
	rawfromoffset = 0;
	}

	if (rawfromoffset >= 1 << adc_properties->bitresolution)
	rawfromoffset = (1 << adc_properties->bitresolution) - 1;

	adc_chan_result->measurement = (int64_t)rawfromoffset*
	chan_properties->adc_graph->dx*
	chan_properties->gain_denominator;

	/* do_div only perform positive integer division! */
	do_div(adc_chan_result->measurement, chan_properties->adc_graph->dy*
	chan_properties->gain_numerator);

	if (negative_rawfromoffset)
	adc_chan_result->measurement =
	(adc_chan_result->measurement ^ -1) + 1;

	/* Note: adc_chan_result->measurement is in the unit of
	* adc_properties.adc_reference. For generic channel processing,
	* channel measurement is a scale/ratio relative to the adc
	* reference input */
	adc_chan_result->physical = (int32_t) adc_chan_result->measurement;

	return 0;
	}

	int32_t scale_batt_therm(int32_t adc_code,
	const struct adc_properties *adc_properties,
	const struct chan_properties *chan_properties,
	struct adc_chan_result *adc_chan_result)
	{
	scale_default(adc_code, adc_properties, chan_properties,
	adc_chan_result);
	/* convert mV ---> degC using the table */
	return adc_map_linear(
	adcmap_batttherm,
	sizeof(adcmap_batttherm)/sizeof(adcmap_batttherm[0]),
	adc_chan_result->physical,
	&adc_chan_result->physical);
	}

	int32_t scale_msm_therm(int32_t adc_code,
	const struct adc_properties *adc_properties,
	const struct chan_properties *chan_properties,
	struct adc_chan_result *adc_chan_result)
	{
	scale_default(adc_code, adc_properties, chan_properties,
	adc_chan_result);
	/* convert mV ---> degC using the table */
	return adc_map_linear(
	adcmap_msmtherm,
	sizeof(adcmap_msmtherm)/sizeof(adcmap_msmtherm[0]),
	adc_chan_result->physical,
	&adc_chan_result->physical);
	}

	int32_t scale_pmic_therm(int32_t adc_code,
	const struct adc_properties *adc_properties,
	const struct chan_properties *chan_properties,
	struct adc_chan_result *adc_chan_result)
	{
	/* 2mV/K */
	int32_t rawfromoffset = adc_code - chan_properties->adc_graph->offset;

	if (!chan_properties->gain_numerator \|\|
	!chan_properties->gain_denominator)
	return -EINVAL;

	adc_chan_result->adc_code = adc_code;
	if (rawfromoffset > 0) {
	if (rawfromoffset >= 1 << adc_properties->bitresolution)
	rawfromoffset = (1 << adc_properties->bitresolution)
	- 1;
	adc_chan_result->measurement = (int64_t)rawfromoffset*
	chan_properties->adc_graph->dx*
	chan_properties->gain_denominator*1000;
	do_div(adc_chan_result->measurement,
	chan_properties->adc_graph->dy*
	chan_properties->gain_numerator*2);
	} else {
	adc_chan_result->measurement = 0;
	}
	/* Note: adc_chan_result->measurement is in the unit of
	adc_properties.adc_reference */
	adc_chan_result->physical = (int32_t)adc_chan_result->measurement;
	/* Change to .001 deg C */
	adc_chan_result->physical -= KELVINMIL_DEGMIL;
	adc_chan_result->measurement <<= 1;

	return 0;
	}

	/* Scales the ADC code to 0.001 degrees C using the map
	* table for the XO thermistor.
	*/
	int32_t tdkntcgtherm(int32_t adc_code,
	const struct adc_properties *adc_properties,
	const struct chan_properties *chan_properties,
	struct adc_chan_result *adc_chan_result)
	{
	int32_t offset = chan_properties->adc_graph->offset,
	dy = chan_properties->adc_graph->dy,
	dx = chan_properties->adc_graph->dx,
	fullscale_calibrated_adc_code;

	uint32_t rt_r25;
	uint32_t num1, num2, denom;

	adc_chan_result->adc_code = adc_code;
	fullscale_calibrated_adc_code = dy + offset;
	/* The above is a short cut in math that would reduce a lot of
	computation whereas the below expression
	(adc_properties->adc_referencedy+dxoffset+(dx>>1))/dx
	is a more generic formula when the 2 reference voltages are
	different than 0 and full scale voltage. */

	if ((dy == 0) \|\| (dx == 0) \|\|
	(offset >= fullscale_calibrated_adc_code)) {
	return -EINVAL;
	} else {
	if (adc_code >= fullscale_calibrated_adc_code) {
	rt_r25 = (uint32_t)-1;
	} else if (adc_code <= offset) {
	rt_r25 = 0;
	} else {
	/* The formula used is (adc_code of current reading - offset)/
	* (the calibrated fullscale adc code - adc_code of current reading).
	* For this channel, at this time, chan_properties->gain_numerator =
	* chan_properties->gain_denominator = 1, so no need to incorporate
	* into the formula even though we could and multiply/divide by 1
	* which yields the same result but expensive on computation. */
	num1 = (adc_code - offset) << 14;
	num2 = (fullscale_calibrated_adc_code - adc_code) >> 1;
	denom = fullscale_calibrated_adc_code - adc_code;

	if ((int)denom <= 0)
	rt_r25 = 0x7FFFFFFF;
	else
	rt_r25 = (num1 + num2) / denom;
	}

	if (rt_r25 > 0x7FFFFFFF)
	rt_r25 = 0x7FFFFFFF;

	adc_map_linear(adcmap_ntcg104ef104fb,
	sizeof(adcmap_ntcg104ef104fb)/sizeof(adcmap_ntcg104ef104fb[0]),
	(int32_t)rt_r25, &adc_chan_result->physical);
	}

	return 0;
	}

	int32_t scale_xtern_chgr_cur(int32_t adc_code,
	const struct adc_properties *adc_properties,
	const struct chan_properties *chan_properties,
	struct adc_chan_result *adc_chan_result)
	{
	int32_t rawfromoffset = adc_code - chan_properties->adc_graph->offset;

	if (!chan_properties->gain_numerator \|\|
	!chan_properties->gain_denominator)
	return -EINVAL;

	adc_chan_result->adc_code = adc_code;
	if (rawfromoffset > 0) {
	if (rawfromoffset >= 1 << adc_properties->bitresolution)
	rawfromoffset = (1 << adc_properties->bitresolution)
	- 1;
	adc_chan_result->measurement = ((int64_t)rawfromoffset * 5)*
	chan_properties->adc_graph->dx*
	chan_properties->gain_denominator;
	do_div(adc_chan_result->measurement,
	chan_properties->adc_graph->dy*
	chan_properties->gain_numerator);
	} else {
	adc_chan_result->measurement = 0;
	}
	adc_chan_result->physical = (int32_t) adc_chan_result->measurement;

	return 0;
	}