1 // SPDX-License-Identifier: GPL-2.0
3 * Thermal sensor driver for Allwinner SOC
4 * Copyright (C) 2019 Yangtao Li
6 * Based on the work of Icenowy Zheng <icenowy@aosc.io>
7 * Based on the work of Ondrej Jirman <megous@megous.com>
8 * Based on the work of Josef Gajdusek <atx@atx.name>
11 #include <linux/clk.h>
12 #include <linux/device.h>
13 #include <linux/interrupt.h>
14 #include <linux/module.h>
15 #include <linux/nvmem-consumer.h>
16 #include <linux/of_device.h>
17 #include <linux/platform_device.h>
18 #include <linux/regmap.h>
19 #include <linux/reset.h>
20 #include <linux/slab.h>
21 #include <linux/thermal.h>
23 #include "thermal_hwmon.h"
25 #define MAX_SENSOR_NUM 4
27 #define FT_TEMP_MASK GENMASK(11, 0)
28 #define TEMP_CALIB_MASK GENMASK(11, 0)
29 #define CALIBRATE_DEFAULT 0x800
31 #define SUN8I_THS_CTRL0 0x00
32 #define SUN8I_THS_CTRL2 0x40
33 #define SUN8I_THS_IC 0x44
34 #define SUN8I_THS_IS 0x48
35 #define SUN8I_THS_MFC 0x70
36 #define SUN8I_THS_TEMP_CALIB 0x74
37 #define SUN8I_THS_TEMP_DATA 0x80
39 #define SUN50I_THS_CTRL0 0x00
40 #define SUN50I_H6_THS_ENABLE 0x04
41 #define SUN50I_H6_THS_PC 0x08
42 #define SUN50I_H6_THS_DIC 0x10
43 #define SUN50I_H6_THS_DIS 0x20
44 #define SUN50I_H6_THS_MFC 0x30
45 #define SUN50I_H6_THS_TEMP_CALIB 0xa0
46 #define SUN50I_H6_THS_TEMP_DATA 0xc0
48 #define SUN8I_THS_CTRL0_T_ACQ0(x) (GENMASK(15, 0) & (x))
49 #define SUN8I_THS_CTRL2_T_ACQ1(x) ((GENMASK(15, 0) & (x)) << 16)
50 #define SUN8I_THS_DATA_IRQ_STS(x) BIT(x + 8)
52 #define SUN50I_THS_CTRL0_T_ACQ(x) ((GENMASK(15, 0) & (x)) << 16)
53 #define SUN50I_THS_FILTER_EN BIT(2)
54 #define SUN50I_THS_FILTER_TYPE(x) (GENMASK(1, 0) & (x))
55 #define SUN50I_H6_THS_PC_TEMP_PERIOD(x) ((GENMASK(19, 0) & (x)) << 12)
56 #define SUN50I_H6_THS_DATA_IRQ_STS(x) BIT(x)
58 /* millidegree celsius */
61 struct ths_device *tmdev;
62 struct thermal_zone_device *tzd;
66 struct ths_thermal_chip {
68 bool has_bus_clk_reset;
74 int (*calibrate)(struct ths_device *tmdev,
75 u16 *caldata, int callen);
76 int (*init)(struct ths_device *tmdev);
77 int (*irq_ack)(struct ths_device *tmdev);
78 int (*calc_temp)(struct ths_device *tmdev,
83 const struct ths_thermal_chip *chip;
85 struct regmap *regmap;
86 struct reset_control *reset;
89 struct tsensor sensor[MAX_SENSOR_NUM];
92 /* Temp Unit: millidegree Celsius */
93 static int sun8i_ths_calc_temp(struct ths_device *tmdev,
96 return tmdev->chip->offset - (reg * tmdev->chip->scale / 10);
99 static int sun50i_h5_calc_temp(struct ths_device *tmdev,
103 return -1191 * reg / 10 + 223000;
105 return -1452 * reg / 10 + 259000;
107 return -1590 * reg / 10 + 276000;
110 static int sun8i_ths_get_temp(void *data, int *temp)
112 struct tsensor *s = data;
113 struct ths_device *tmdev = s->tmdev;
116 regmap_read(tmdev->regmap, tmdev->chip->temp_data_base +
119 /* ths have no data yet */
123 *temp = tmdev->chip->calc_temp(tmdev, s->id, val);
125 * According to the original sdk, there are some platforms(rarely)
126 * that add a fixed offset value after calculating the temperature
127 * value. We can't simply put it on the formula for calculating the
128 * temperature above, because the formula for calculating the
129 * temperature above is also used when the sensor is calibrated. If
130 * do this, the correct calibration formula is hard to know.
132 *temp += tmdev->chip->ft_deviation;
137 static const struct thermal_zone_of_device_ops ths_ops = {
138 .get_temp = sun8i_ths_get_temp,
141 static const struct regmap_config config = {
146 .max_register = 0xfc,
149 static int sun8i_h3_irq_ack(struct ths_device *tmdev)
151 int i, state, ret = 0;
153 regmap_read(tmdev->regmap, SUN8I_THS_IS, &state);
155 for (i = 0; i < tmdev->chip->sensor_num; i++) {
156 if (state & SUN8I_THS_DATA_IRQ_STS(i)) {
157 regmap_write(tmdev->regmap, SUN8I_THS_IS,
158 SUN8I_THS_DATA_IRQ_STS(i));
166 static int sun50i_h6_irq_ack(struct ths_device *tmdev)
168 int i, state, ret = 0;
170 regmap_read(tmdev->regmap, SUN50I_H6_THS_DIS, &state);
172 for (i = 0; i < tmdev->chip->sensor_num; i++) {
173 if (state & SUN50I_H6_THS_DATA_IRQ_STS(i)) {
174 regmap_write(tmdev->regmap, SUN50I_H6_THS_DIS,
175 SUN50I_H6_THS_DATA_IRQ_STS(i));
183 static irqreturn_t sun8i_irq_thread(int irq, void *data)
185 struct ths_device *tmdev = data;
188 state = tmdev->chip->irq_ack(tmdev);
190 for (i = 0; i < tmdev->chip->sensor_num; i++) {
192 thermal_zone_device_update(tmdev->sensor[i].tzd,
193 THERMAL_EVENT_UNSPECIFIED);
199 static int sun8i_h3_ths_calibrate(struct ths_device *tmdev,
200 u16 *caldata, int callen)
204 if (!caldata[0] || callen < 2 * tmdev->chip->sensor_num)
207 for (i = 0; i < tmdev->chip->sensor_num; i++) {
208 int offset = (i % 2) << 4;
210 regmap_update_bits(tmdev->regmap,
211 SUN8I_THS_TEMP_CALIB + (4 * (i >> 1)),
213 caldata[i] << offset);
219 static int sun50i_h6_ths_calibrate(struct ths_device *tmdev,
220 u16 *caldata, int callen)
222 struct device *dev = tmdev->dev;
225 if (!caldata[0] || callen < 2 + 2 * tmdev->chip->sensor_num)
232 * +-------+-------+-------+
233 * |temp| |sensor0|sensor1|
234 * +-------+-------+-------+
236 * The calibration data on the H6 is the ambient temperature and
237 * sensor values that are filled during the factory test stage.
239 * The unit of stored FT temperature is 0.1 degreee celusis.
241 * We need to calculate a delta between measured and caluclated
242 * register values and this will become a calibration offset.
244 ft_temp = (caldata[0] & FT_TEMP_MASK) * 100;
246 for (i = 0; i < tmdev->chip->sensor_num; i++) {
247 int sensor_reg = caldata[i + 1] & TEMP_CALIB_MASK;
249 int sensor_temp = tmdev->chip->calc_temp(tmdev, i, sensor_reg);
252 * Calibration data is CALIBRATE_DEFAULT - (calculated
253 * temperature from sensor reading at factory temperature
254 * minus actual factory temperature) * 14.88 (scale from
255 * temperature to register values)
257 cdata = CALIBRATE_DEFAULT -
258 ((sensor_temp - ft_temp) * 10 / tmdev->chip->scale);
259 if (cdata & ~TEMP_CALIB_MASK) {
261 * Calibration value more than 12-bit, but calibration
262 * register is 12-bit. In this case, ths hardware can
263 * still work without calibration, although the data
264 * won't be so accurate.
266 dev_warn(dev, "sensor%d is not calibrated.\n", i);
270 offset = (i % 2) * 16;
271 regmap_update_bits(tmdev->regmap,
272 SUN50I_H6_THS_TEMP_CALIB + (i / 2 * 4),
280 static int sun8i_ths_calibrate(struct ths_device *tmdev)
282 struct nvmem_cell *calcell;
283 struct device *dev = tmdev->dev;
288 calcell = devm_nvmem_cell_get(dev, "calibration");
289 if (IS_ERR(calcell)) {
290 if (PTR_ERR(calcell) == -EPROBE_DEFER)
291 return -EPROBE_DEFER;
293 * Even if the external calibration data stored in sid is
294 * not accessible, the THS hardware can still work, although
295 * the data won't be so accurate.
297 * The default value of calibration register is 0x800 for
298 * every sensor, and the calibration value is usually 0x7xx
299 * or 0x8xx, so they won't be away from the default value
302 * So here we do not return error if the calibartion data is
303 * not available, except the probe needs deferring.
308 caldata = nvmem_cell_read(calcell, &callen);
309 if (IS_ERR(caldata)) {
310 ret = PTR_ERR(caldata);
314 tmdev->chip->calibrate(tmdev, caldata, callen);
321 static void sun8i_ths_reset_control_assert(void *data)
323 reset_control_assert(data);
326 static int sun8i_ths_resource_init(struct ths_device *tmdev)
328 struct device *dev = tmdev->dev;
329 struct platform_device *pdev = to_platform_device(dev);
333 base = devm_platform_ioremap_resource(pdev, 0);
335 return PTR_ERR(base);
337 tmdev->regmap = devm_regmap_init_mmio(dev, base, &config);
338 if (IS_ERR(tmdev->regmap))
339 return PTR_ERR(tmdev->regmap);
341 if (tmdev->chip->has_bus_clk_reset) {
342 tmdev->reset = devm_reset_control_get(dev, NULL);
343 if (IS_ERR(tmdev->reset))
344 return PTR_ERR(tmdev->reset);
346 ret = reset_control_deassert(tmdev->reset);
350 ret = devm_add_action_or_reset(dev, sun8i_ths_reset_control_assert,
355 tmdev->bus_clk = devm_clk_get_enabled(&pdev->dev, "bus");
356 if (IS_ERR(tmdev->bus_clk))
357 return PTR_ERR(tmdev->bus_clk);
360 if (tmdev->chip->has_mod_clk) {
361 tmdev->mod_clk = devm_clk_get_enabled(&pdev->dev, "mod");
362 if (IS_ERR(tmdev->mod_clk))
363 return PTR_ERR(tmdev->mod_clk);
366 ret = clk_set_rate(tmdev->mod_clk, 24000000);
370 ret = sun8i_ths_calibrate(tmdev);
377 static int sun8i_h3_thermal_init(struct ths_device *tmdev)
381 /* average over 4 samples */
382 regmap_write(tmdev->regmap, SUN8I_THS_MFC,
383 SUN50I_THS_FILTER_EN |
384 SUN50I_THS_FILTER_TYPE(1));
390 * x = period * clkin / 4096 / filter_samples - 1
393 val = GENMASK(7 + tmdev->chip->sensor_num, 8);
394 regmap_write(tmdev->regmap, SUN8I_THS_IC,
395 SUN50I_H6_THS_PC_TEMP_PERIOD(365) | val);
400 * x = T_acq * clkin - 1
403 regmap_write(tmdev->regmap, SUN8I_THS_CTRL0,
404 SUN8I_THS_CTRL0_T_ACQ0(479));
405 val = GENMASK(tmdev->chip->sensor_num - 1, 0);
406 regmap_write(tmdev->regmap, SUN8I_THS_CTRL2,
407 SUN8I_THS_CTRL2_T_ACQ1(479) | val);
413 * Without this undocummented value, the returned temperatures would
414 * be higher than real ones by about 20C.
416 #define SUN50I_H6_CTRL0_UNK 0x0000002f
418 static int sun50i_h6_thermal_init(struct ths_device *tmdev)
426 * x = T_acq * clkin - 1
429 regmap_write(tmdev->regmap, SUN50I_THS_CTRL0,
430 SUN50I_H6_CTRL0_UNK | SUN50I_THS_CTRL0_T_ACQ(479));
431 /* average over 4 samples */
432 regmap_write(tmdev->regmap, SUN50I_H6_THS_MFC,
433 SUN50I_THS_FILTER_EN |
434 SUN50I_THS_FILTER_TYPE(1));
440 * x = period * clkin / 4096 / filter_samples - 1
443 regmap_write(tmdev->regmap, SUN50I_H6_THS_PC,
444 SUN50I_H6_THS_PC_TEMP_PERIOD(365));
446 val = GENMASK(tmdev->chip->sensor_num - 1, 0);
447 regmap_write(tmdev->regmap, SUN50I_H6_THS_ENABLE, val);
448 /* thermal data interrupt enable */
449 val = GENMASK(tmdev->chip->sensor_num - 1, 0);
450 regmap_write(tmdev->regmap, SUN50I_H6_THS_DIC, val);
455 static int sun8i_ths_register(struct ths_device *tmdev)
459 for (i = 0; i < tmdev->chip->sensor_num; i++) {
460 tmdev->sensor[i].tmdev = tmdev;
461 tmdev->sensor[i].id = i;
462 tmdev->sensor[i].tzd =
463 devm_thermal_zone_of_sensor_register(tmdev->dev,
467 if (IS_ERR(tmdev->sensor[i].tzd))
468 return PTR_ERR(tmdev->sensor[i].tzd);
470 if (devm_thermal_add_hwmon_sysfs(tmdev->sensor[i].tzd))
472 "Failed to add hwmon sysfs attributes\n");
478 static int sun8i_ths_probe(struct platform_device *pdev)
480 struct ths_device *tmdev;
481 struct device *dev = &pdev->dev;
484 tmdev = devm_kzalloc(dev, sizeof(*tmdev), GFP_KERNEL);
489 tmdev->chip = of_device_get_match_data(&pdev->dev);
493 platform_set_drvdata(pdev, tmdev);
495 ret = sun8i_ths_resource_init(tmdev);
499 irq = platform_get_irq(pdev, 0);
503 ret = tmdev->chip->init(tmdev);
507 ret = sun8i_ths_register(tmdev);
512 * Avoid entering the interrupt handler, the thermal device is not
513 * registered yet, we deffer the registration of the interrupt to
516 ret = devm_request_threaded_irq(dev, irq, NULL,
518 IRQF_ONESHOT, "ths", tmdev);
525 static const struct ths_thermal_chip sun8i_a83t_ths = {
529 .temp_data_base = SUN8I_THS_TEMP_DATA,
530 .calibrate = sun8i_h3_ths_calibrate,
531 .init = sun8i_h3_thermal_init,
532 .irq_ack = sun8i_h3_irq_ack,
533 .calc_temp = sun8i_ths_calc_temp,
536 static const struct ths_thermal_chip sun8i_h3_ths = {
541 .has_bus_clk_reset = true,
542 .temp_data_base = SUN8I_THS_TEMP_DATA,
543 .calibrate = sun8i_h3_ths_calibrate,
544 .init = sun8i_h3_thermal_init,
545 .irq_ack = sun8i_h3_irq_ack,
546 .calc_temp = sun8i_ths_calc_temp,
549 static const struct ths_thermal_chip sun8i_r40_ths = {
554 .has_bus_clk_reset = true,
555 .temp_data_base = SUN8I_THS_TEMP_DATA,
556 .calibrate = sun8i_h3_ths_calibrate,
557 .init = sun8i_h3_thermal_init,
558 .irq_ack = sun8i_h3_irq_ack,
559 .calc_temp = sun8i_ths_calc_temp,
562 static const struct ths_thermal_chip sun50i_a64_ths = {
567 .has_bus_clk_reset = true,
568 .temp_data_base = SUN8I_THS_TEMP_DATA,
569 .calibrate = sun8i_h3_ths_calibrate,
570 .init = sun8i_h3_thermal_init,
571 .irq_ack = sun8i_h3_irq_ack,
572 .calc_temp = sun8i_ths_calc_temp,
575 static const struct ths_thermal_chip sun50i_a100_ths = {
577 .has_bus_clk_reset = true,
578 .ft_deviation = 8000,
581 .temp_data_base = SUN50I_H6_THS_TEMP_DATA,
582 .calibrate = sun50i_h6_ths_calibrate,
583 .init = sun50i_h6_thermal_init,
584 .irq_ack = sun50i_h6_irq_ack,
585 .calc_temp = sun8i_ths_calc_temp,
588 static const struct ths_thermal_chip sun50i_h5_ths = {
591 .has_bus_clk_reset = true,
592 .temp_data_base = SUN8I_THS_TEMP_DATA,
593 .calibrate = sun8i_h3_ths_calibrate,
594 .init = sun8i_h3_thermal_init,
595 .irq_ack = sun8i_h3_irq_ack,
596 .calc_temp = sun50i_h5_calc_temp,
599 static const struct ths_thermal_chip sun50i_h6_ths = {
601 .has_bus_clk_reset = true,
602 .ft_deviation = 7000,
605 .temp_data_base = SUN50I_H6_THS_TEMP_DATA,
606 .calibrate = sun50i_h6_ths_calibrate,
607 .init = sun50i_h6_thermal_init,
608 .irq_ack = sun50i_h6_irq_ack,
609 .calc_temp = sun8i_ths_calc_temp,
612 static const struct of_device_id of_ths_match[] = {
613 { .compatible = "allwinner,sun8i-a83t-ths", .data = &sun8i_a83t_ths },
614 { .compatible = "allwinner,sun8i-h3-ths", .data = &sun8i_h3_ths },
615 { .compatible = "allwinner,sun8i-r40-ths", .data = &sun8i_r40_ths },
616 { .compatible = "allwinner,sun50i-a64-ths", .data = &sun50i_a64_ths },
617 { .compatible = "allwinner,sun50i-a100-ths", .data = &sun50i_a100_ths },
618 { .compatible = "allwinner,sun50i-h5-ths", .data = &sun50i_h5_ths },
619 { .compatible = "allwinner,sun50i-h6-ths", .data = &sun50i_h6_ths },
622 MODULE_DEVICE_TABLE(of, of_ths_match);
624 static struct platform_driver ths_driver = {
625 .probe = sun8i_ths_probe,
627 .name = "sun8i-thermal",
628 .of_match_table = of_ths_match,
631 module_platform_driver(ths_driver);
633 MODULE_DESCRIPTION("Thermal sensor driver for Allwinner SOC");
634 MODULE_LICENSE("GPL v2");