linux_dsm_epyc7002/drivers/thermal/qcom/tsens-v1.c
Amit Kucheria 0aef1ee5af drivers: thermal: tsens: De-constify struct tsens_features
struct tsens_features is currently initialized as part of platform data
at compile-time and not modifiable. We now have some usecases in feature
detection across IP versions where it is more flexible to update the
features after probing registers.

Remove const qualifier from tsens_features and the encapsulating
tsens_plat_data.

Signed-off-by: Amit Kucheria <amit.kucheria@linaro.org>
Reviewed-by: Stephen Boyd <swboyd@chromium.org>
Signed-off-by: Daniel Lezcano <daniel.lezcano@linaro.org>
Link: https://lore.kernel.org/r/2919a72220470366ae11e0bb5330a4ea39838f71.1584015867.git.amit.kucheria@linaro.org
2020-03-20 12:17:48 +01:00

391 lines
13 KiB
C

// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (c) 2019, Linaro Limited
*/
#include <linux/bitops.h>
#include <linux/regmap.h>
#include <linux/delay.h>
#include <linux/slab.h>
#include "tsens.h"
/* ----- SROT ------ */
#define SROT_HW_VER_OFF 0x0000
#define SROT_CTRL_OFF 0x0004
/* ----- TM ------ */
#define TM_INT_EN_OFF 0x0000
#define TM_Sn_UPPER_LOWER_STATUS_CTRL_OFF 0x0004
#define TM_Sn_STATUS_OFF 0x0044
#define TM_TRDY_OFF 0x0084
#define TM_HIGH_LOW_INT_STATUS_OFF 0x0088
#define TM_HIGH_LOW_Sn_INT_THRESHOLD_OFF 0x0090
/* eeprom layout data for msm8956/76 (v1) */
#define MSM8976_BASE0_MASK 0xff
#define MSM8976_BASE1_MASK 0xff
#define MSM8976_BASE1_SHIFT 8
#define MSM8976_S0_P1_MASK 0x3f00
#define MSM8976_S1_P1_MASK 0x3f00000
#define MSM8976_S2_P1_MASK 0x3f
#define MSM8976_S3_P1_MASK 0x3f000
#define MSM8976_S4_P1_MASK 0x3f00
#define MSM8976_S5_P1_MASK 0x3f00000
#define MSM8976_S6_P1_MASK 0x3f
#define MSM8976_S7_P1_MASK 0x3f000
#define MSM8976_S8_P1_MASK 0x1f8
#define MSM8976_S9_P1_MASK 0x1f8000
#define MSM8976_S10_P1_MASK 0xf8000000
#define MSM8976_S10_P1_MASK_1 0x1
#define MSM8976_S0_P2_MASK 0xfc000
#define MSM8976_S1_P2_MASK 0xfc000000
#define MSM8976_S2_P2_MASK 0xfc0
#define MSM8976_S3_P2_MASK 0xfc0000
#define MSM8976_S4_P2_MASK 0xfc000
#define MSM8976_S5_P2_MASK 0xfc000000
#define MSM8976_S6_P2_MASK 0xfc0
#define MSM8976_S7_P2_MASK 0xfc0000
#define MSM8976_S8_P2_MASK 0x7e00
#define MSM8976_S9_P2_MASK 0x7e00000
#define MSM8976_S10_P2_MASK 0x7e
#define MSM8976_S0_P1_SHIFT 8
#define MSM8976_S1_P1_SHIFT 20
#define MSM8976_S2_P1_SHIFT 0
#define MSM8976_S3_P1_SHIFT 12
#define MSM8976_S4_P1_SHIFT 8
#define MSM8976_S5_P1_SHIFT 20
#define MSM8976_S6_P1_SHIFT 0
#define MSM8976_S7_P1_SHIFT 12
#define MSM8976_S8_P1_SHIFT 3
#define MSM8976_S9_P1_SHIFT 15
#define MSM8976_S10_P1_SHIFT 27
#define MSM8976_S10_P1_SHIFT_1 0
#define MSM8976_S0_P2_SHIFT 14
#define MSM8976_S1_P2_SHIFT 26
#define MSM8976_S2_P2_SHIFT 6
#define MSM8976_S3_P2_SHIFT 18
#define MSM8976_S4_P2_SHIFT 14
#define MSM8976_S5_P2_SHIFT 26
#define MSM8976_S6_P2_SHIFT 6
#define MSM8976_S7_P2_SHIFT 18
#define MSM8976_S8_P2_SHIFT 9
#define MSM8976_S9_P2_SHIFT 21
#define MSM8976_S10_P2_SHIFT 1
#define MSM8976_CAL_SEL_MASK 0x3
#define MSM8976_CAL_DEGC_PT1 30
#define MSM8976_CAL_DEGC_PT2 120
#define MSM8976_SLOPE_FACTOR 1000
#define MSM8976_SLOPE_DEFAULT 3200
/* eeprom layout data for qcs404/405 (v1) */
#define BASE0_MASK 0x000007f8
#define BASE1_MASK 0x0007f800
#define BASE0_SHIFT 3
#define BASE1_SHIFT 11
#define S0_P1_MASK 0x0000003f
#define S1_P1_MASK 0x0003f000
#define S2_P1_MASK 0x3f000000
#define S3_P1_MASK 0x000003f0
#define S4_P1_MASK 0x003f0000
#define S5_P1_MASK 0x0000003f
#define S6_P1_MASK 0x0003f000
#define S7_P1_MASK 0x3f000000
#define S8_P1_MASK 0x000003f0
#define S9_P1_MASK 0x003f0000
#define S0_P2_MASK 0x00000fc0
#define S1_P2_MASK 0x00fc0000
#define S2_P2_MASK_1_0 0xc0000000
#define S2_P2_MASK_5_2 0x0000000f
#define S3_P2_MASK 0x0000fc00
#define S4_P2_MASK 0x0fc00000
#define S5_P2_MASK 0x00000fc0
#define S6_P2_MASK 0x00fc0000
#define S7_P2_MASK_1_0 0xc0000000
#define S7_P2_MASK_5_2 0x0000000f
#define S8_P2_MASK 0x0000fc00
#define S9_P2_MASK 0x0fc00000
#define S0_P1_SHIFT 0
#define S0_P2_SHIFT 6
#define S1_P1_SHIFT 12
#define S1_P2_SHIFT 18
#define S2_P1_SHIFT 24
#define S2_P2_SHIFT_1_0 30
#define S2_P2_SHIFT_5_2 0
#define S3_P1_SHIFT 4
#define S3_P2_SHIFT 10
#define S4_P1_SHIFT 16
#define S4_P2_SHIFT 22
#define S5_P1_SHIFT 0
#define S5_P2_SHIFT 6
#define S6_P1_SHIFT 12
#define S6_P2_SHIFT 18
#define S7_P1_SHIFT 24
#define S7_P2_SHIFT_1_0 30
#define S7_P2_SHIFT_5_2 0
#define S8_P1_SHIFT 4
#define S8_P2_SHIFT 10
#define S9_P1_SHIFT 16
#define S9_P2_SHIFT 22
#define CAL_SEL_MASK 7
#define CAL_SEL_SHIFT 0
static void compute_intercept_slope_8976(struct tsens_priv *priv,
u32 *p1, u32 *p2, u32 mode)
{
int i;
priv->sensor[0].slope = 3313;
priv->sensor[1].slope = 3275;
priv->sensor[2].slope = 3320;
priv->sensor[3].slope = 3246;
priv->sensor[4].slope = 3279;
priv->sensor[5].slope = 3257;
priv->sensor[6].slope = 3234;
priv->sensor[7].slope = 3269;
priv->sensor[8].slope = 3255;
priv->sensor[9].slope = 3239;
priv->sensor[10].slope = 3286;
for (i = 0; i < priv->num_sensors; i++) {
priv->sensor[i].offset = (p1[i] * MSM8976_SLOPE_FACTOR) -
(MSM8976_CAL_DEGC_PT1 *
priv->sensor[i].slope);
}
}
static int calibrate_v1(struct tsens_priv *priv)
{
u32 base0 = 0, base1 = 0;
u32 p1[10], p2[10];
u32 mode = 0, lsb = 0, msb = 0;
u32 *qfprom_cdata;
int i;
qfprom_cdata = (u32 *)qfprom_read(priv->dev, "calib");
if (IS_ERR(qfprom_cdata))
return PTR_ERR(qfprom_cdata);
mode = (qfprom_cdata[4] & CAL_SEL_MASK) >> CAL_SEL_SHIFT;
dev_dbg(priv->dev, "calibration mode is %d\n", mode);
switch (mode) {
case TWO_PT_CALIB:
base1 = (qfprom_cdata[4] & BASE1_MASK) >> BASE1_SHIFT;
p2[0] = (qfprom_cdata[0] & S0_P2_MASK) >> S0_P2_SHIFT;
p2[1] = (qfprom_cdata[0] & S1_P2_MASK) >> S1_P2_SHIFT;
/* This value is split over two registers, 2 bits and 4 bits */
lsb = (qfprom_cdata[0] & S2_P2_MASK_1_0) >> S2_P2_SHIFT_1_0;
msb = (qfprom_cdata[1] & S2_P2_MASK_5_2) >> S2_P2_SHIFT_5_2;
p2[2] = msb << 2 | lsb;
p2[3] = (qfprom_cdata[1] & S3_P2_MASK) >> S3_P2_SHIFT;
p2[4] = (qfprom_cdata[1] & S4_P2_MASK) >> S4_P2_SHIFT;
p2[5] = (qfprom_cdata[2] & S5_P2_MASK) >> S5_P2_SHIFT;
p2[6] = (qfprom_cdata[2] & S6_P2_MASK) >> S6_P2_SHIFT;
/* This value is split over two registers, 2 bits and 4 bits */
lsb = (qfprom_cdata[2] & S7_P2_MASK_1_0) >> S7_P2_SHIFT_1_0;
msb = (qfprom_cdata[3] & S7_P2_MASK_5_2) >> S7_P2_SHIFT_5_2;
p2[7] = msb << 2 | lsb;
p2[8] = (qfprom_cdata[3] & S8_P2_MASK) >> S8_P2_SHIFT;
p2[9] = (qfprom_cdata[3] & S9_P2_MASK) >> S9_P2_SHIFT;
for (i = 0; i < priv->num_sensors; i++)
p2[i] = ((base1 + p2[i]) << 2);
/* Fall through */
case ONE_PT_CALIB2:
base0 = (qfprom_cdata[4] & BASE0_MASK) >> BASE0_SHIFT;
p1[0] = (qfprom_cdata[0] & S0_P1_MASK) >> S0_P1_SHIFT;
p1[1] = (qfprom_cdata[0] & S1_P1_MASK) >> S1_P1_SHIFT;
p1[2] = (qfprom_cdata[0] & S2_P1_MASK) >> S2_P1_SHIFT;
p1[3] = (qfprom_cdata[1] & S3_P1_MASK) >> S3_P1_SHIFT;
p1[4] = (qfprom_cdata[1] & S4_P1_MASK) >> S4_P1_SHIFT;
p1[5] = (qfprom_cdata[2] & S5_P1_MASK) >> S5_P1_SHIFT;
p1[6] = (qfprom_cdata[2] & S6_P1_MASK) >> S6_P1_SHIFT;
p1[7] = (qfprom_cdata[2] & S7_P1_MASK) >> S7_P1_SHIFT;
p1[8] = (qfprom_cdata[3] & S8_P1_MASK) >> S8_P1_SHIFT;
p1[9] = (qfprom_cdata[3] & S9_P1_MASK) >> S9_P1_SHIFT;
for (i = 0; i < priv->num_sensors; i++)
p1[i] = (((base0) + p1[i]) << 2);
break;
default:
for (i = 0; i < priv->num_sensors; i++) {
p1[i] = 500;
p2[i] = 780;
}
break;
}
compute_intercept_slope(priv, p1, p2, mode);
kfree(qfprom_cdata);
return 0;
}
static int calibrate_8976(struct tsens_priv *priv)
{
int base0 = 0, base1 = 0, i;
u32 p1[11], p2[11];
int mode = 0, tmp = 0;
u32 *qfprom_cdata;
qfprom_cdata = (u32 *)qfprom_read(priv->dev, "calib");
if (IS_ERR(qfprom_cdata))
return PTR_ERR(qfprom_cdata);
mode = (qfprom_cdata[4] & MSM8976_CAL_SEL_MASK);
dev_dbg(priv->dev, "calibration mode is %d\n", mode);
switch (mode) {
case TWO_PT_CALIB:
base1 = (qfprom_cdata[2] & MSM8976_BASE1_MASK) >> MSM8976_BASE1_SHIFT;
p2[0] = (qfprom_cdata[0] & MSM8976_S0_P2_MASK) >> MSM8976_S0_P2_SHIFT;
p2[1] = (qfprom_cdata[0] & MSM8976_S1_P2_MASK) >> MSM8976_S1_P2_SHIFT;
p2[2] = (qfprom_cdata[1] & MSM8976_S2_P2_MASK) >> MSM8976_S2_P2_SHIFT;
p2[3] = (qfprom_cdata[1] & MSM8976_S3_P2_MASK) >> MSM8976_S3_P2_SHIFT;
p2[4] = (qfprom_cdata[2] & MSM8976_S4_P2_MASK) >> MSM8976_S4_P2_SHIFT;
p2[5] = (qfprom_cdata[2] & MSM8976_S5_P2_MASK) >> MSM8976_S5_P2_SHIFT;
p2[6] = (qfprom_cdata[3] & MSM8976_S6_P2_MASK) >> MSM8976_S6_P2_SHIFT;
p2[7] = (qfprom_cdata[3] & MSM8976_S7_P2_MASK) >> MSM8976_S7_P2_SHIFT;
p2[8] = (qfprom_cdata[4] & MSM8976_S8_P2_MASK) >> MSM8976_S8_P2_SHIFT;
p2[9] = (qfprom_cdata[4] & MSM8976_S9_P2_MASK) >> MSM8976_S9_P2_SHIFT;
p2[10] = (qfprom_cdata[5] & MSM8976_S10_P2_MASK) >> MSM8976_S10_P2_SHIFT;
for (i = 0; i < priv->num_sensors; i++)
p2[i] = ((base1 + p2[i]) << 2);
/* Fall through */
case ONE_PT_CALIB2:
base0 = qfprom_cdata[0] & MSM8976_BASE0_MASK;
p1[0] = (qfprom_cdata[0] & MSM8976_S0_P1_MASK) >> MSM8976_S0_P1_SHIFT;
p1[1] = (qfprom_cdata[0] & MSM8976_S1_P1_MASK) >> MSM8976_S1_P1_SHIFT;
p1[2] = (qfprom_cdata[1] & MSM8976_S2_P1_MASK) >> MSM8976_S2_P1_SHIFT;
p1[3] = (qfprom_cdata[1] & MSM8976_S3_P1_MASK) >> MSM8976_S3_P1_SHIFT;
p1[4] = (qfprom_cdata[2] & MSM8976_S4_P1_MASK) >> MSM8976_S4_P1_SHIFT;
p1[5] = (qfprom_cdata[2] & MSM8976_S5_P1_MASK) >> MSM8976_S5_P1_SHIFT;
p1[6] = (qfprom_cdata[3] & MSM8976_S6_P1_MASK) >> MSM8976_S6_P1_SHIFT;
p1[7] = (qfprom_cdata[3] & MSM8976_S7_P1_MASK) >> MSM8976_S7_P1_SHIFT;
p1[8] = (qfprom_cdata[4] & MSM8976_S8_P1_MASK) >> MSM8976_S8_P1_SHIFT;
p1[9] = (qfprom_cdata[4] & MSM8976_S9_P1_MASK) >> MSM8976_S9_P1_SHIFT;
p1[10] = (qfprom_cdata[4] & MSM8976_S10_P1_MASK) >> MSM8976_S10_P1_SHIFT;
tmp = (qfprom_cdata[5] & MSM8976_S10_P1_MASK_1) << MSM8976_S10_P1_SHIFT_1;
p1[10] |= tmp;
for (i = 0; i < priv->num_sensors; i++)
p1[i] = (((base0) + p1[i]) << 2);
break;
default:
for (i = 0; i < priv->num_sensors; i++) {
p1[i] = 500;
p2[i] = 780;
}
break;
}
compute_intercept_slope_8976(priv, p1, p2, mode);
kfree(qfprom_cdata);
return 0;
}
/* v1.x: msm8956,8976,qcs404,405 */
static struct tsens_features tsens_v1_feat = {
.ver_major = VER_1_X,
.crit_int = 0,
.adc = 1,
.srot_split = 1,
.max_sensors = 11,
};
static const struct reg_field tsens_v1_regfields[MAX_REGFIELDS] = {
/* ----- SROT ------ */
/* VERSION */
[VER_MAJOR] = REG_FIELD(SROT_HW_VER_OFF, 28, 31),
[VER_MINOR] = REG_FIELD(SROT_HW_VER_OFF, 16, 27),
[VER_STEP] = REG_FIELD(SROT_HW_VER_OFF, 0, 15),
/* CTRL_OFFSET */
[TSENS_EN] = REG_FIELD(SROT_CTRL_OFF, 0, 0),
[TSENS_SW_RST] = REG_FIELD(SROT_CTRL_OFF, 1, 1),
[SENSOR_EN] = REG_FIELD(SROT_CTRL_OFF, 3, 13),
/* ----- TM ------ */
/* INTERRUPT ENABLE */
[INT_EN] = REG_FIELD(TM_INT_EN_OFF, 0, 0),
/* UPPER/LOWER TEMPERATURE THRESHOLDS */
REG_FIELD_FOR_EACH_SENSOR11(LOW_THRESH, TM_Sn_UPPER_LOWER_STATUS_CTRL_OFF, 0, 9),
REG_FIELD_FOR_EACH_SENSOR11(UP_THRESH, TM_Sn_UPPER_LOWER_STATUS_CTRL_OFF, 10, 19),
/* UPPER/LOWER INTERRUPTS [CLEAR/STATUS] */
REG_FIELD_FOR_EACH_SENSOR11(LOW_INT_CLEAR, TM_Sn_UPPER_LOWER_STATUS_CTRL_OFF, 20, 20),
REG_FIELD_FOR_EACH_SENSOR11(UP_INT_CLEAR, TM_Sn_UPPER_LOWER_STATUS_CTRL_OFF, 21, 21),
[LOW_INT_STATUS_0] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 0, 0),
[LOW_INT_STATUS_1] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 1, 1),
[LOW_INT_STATUS_2] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 2, 2),
[LOW_INT_STATUS_3] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 3, 3),
[LOW_INT_STATUS_4] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 4, 4),
[LOW_INT_STATUS_5] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 5, 5),
[LOW_INT_STATUS_6] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 6, 6),
[LOW_INT_STATUS_7] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 7, 7),
[UP_INT_STATUS_0] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 8, 8),
[UP_INT_STATUS_1] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 9, 9),
[UP_INT_STATUS_2] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 10, 10),
[UP_INT_STATUS_3] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 11, 11),
[UP_INT_STATUS_4] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 12, 12),
[UP_INT_STATUS_5] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 13, 13),
[UP_INT_STATUS_6] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 14, 14),
[UP_INT_STATUS_7] = REG_FIELD(TM_HIGH_LOW_INT_STATUS_OFF, 15, 15),
/* NO CRITICAL INTERRUPT SUPPORT on v1 */
/* Sn_STATUS */
REG_FIELD_FOR_EACH_SENSOR11(LAST_TEMP, TM_Sn_STATUS_OFF, 0, 9),
REG_FIELD_FOR_EACH_SENSOR11(VALID, TM_Sn_STATUS_OFF, 14, 14),
/* xxx_STATUS bits: 1 == threshold violated */
REG_FIELD_FOR_EACH_SENSOR11(MIN_STATUS, TM_Sn_STATUS_OFF, 10, 10),
REG_FIELD_FOR_EACH_SENSOR11(LOWER_STATUS, TM_Sn_STATUS_OFF, 11, 11),
REG_FIELD_FOR_EACH_SENSOR11(UPPER_STATUS, TM_Sn_STATUS_OFF, 12, 12),
/* No CRITICAL field on v1.x */
REG_FIELD_FOR_EACH_SENSOR11(MAX_STATUS, TM_Sn_STATUS_OFF, 13, 13),
/* TRDY: 1=ready, 0=in progress */
[TRDY] = REG_FIELD(TM_TRDY_OFF, 0, 0),
};
static const struct tsens_ops ops_generic_v1 = {
.init = init_common,
.calibrate = calibrate_v1,
.get_temp = get_temp_tsens_valid,
};
struct tsens_plat_data data_tsens_v1 = {
.ops = &ops_generic_v1,
.feat = &tsens_v1_feat,
.fields = tsens_v1_regfields,
};
static const struct tsens_ops ops_8976 = {
.init = init_common,
.calibrate = calibrate_8976,
.get_temp = get_temp_tsens_valid,
};
/* Valid for both MSM8956 and MSM8976. Sensor ID 3 is unused. */
struct tsens_plat_data data_8976 = {
.num_sensors = 11,
.ops = &ops_8976,
.hw_ids = (unsigned int[]){0, 1, 2, 4, 5, 6, 7, 8, 9, 10},
.feat = &tsens_v1_feat,
.fields = tsens_v1_regfields,
};