@@ -65,26 +65,29 @@
#define TSC_MAX_NUM 5
-/* Structure for thermal temperature calculation */
-struct equation_coefs {
- int a1;
- int b1;
- int a2;
- int b2;
-};
-
struct rcar_gen3_thermal_priv;
struct rcar_thermal_info {
- int ths_tj_1;
+ int scale;
+ int adj_below;
+ int adj_above;
void (*read_fuses)(struct rcar_gen3_thermal_priv *priv);
};
+struct equation_set_coef {
+ int a;
+ int b;
+};
+
struct rcar_gen3_thermal_tsc {
struct rcar_gen3_thermal_priv *priv;
void __iomem *base;
struct thermal_zone_device *zone;
- struct equation_coefs coef;
+ /* Different coefficients are used depending on a threshold. */
+ struct {
+ struct equation_set_coef below;
+ struct equation_set_coef above;
+ } coef;
int thcode[3];
};
@@ -112,90 +115,75 @@ static inline void rcar_gen3_thermal_write(struct rcar_gen3_thermal_tsc *tsc,
/*
* Linear approximation for temperature
*
- * [reg] = [temp] * a + b => [temp] = ([reg] - b) / a
+ * [temp] = ((thadj - [reg]) * a) / b + adj
+ * [reg] = thadj - ([temp] - adj) * b / a
*
* The constants a and b are calculated using two triplets of int values PTAT
* and THCODE. PTAT and THCODE can either be read from hardware or use hard
- * coded values from driver. The formula to calculate a and b are taken from
- * BSP and sparsely documented and understood.
+ * coded values from the driver. The formula to calculate a and b are taken from
+ * the datasheet. Different calculations are needed for a and b depending on
+ * if the input variables ([temp] or [reg]) are above or below a threshold. The
+ * threshold is also calculated from PTAT and THCODE using formulas from the
+ * datasheet.
+ *
+ * The constant thadj is one of the THCODE values, which one to use depends on
+ * the threshold and input value.
*
- * Examining the linear formula and the formula used to calculate constants a
- * and b while knowing that the span for PTAT and THCODE values are between
- * 0x000 and 0xfff the largest integer possible is 0xfff * 0xfff == 0xffe001.
- * Integer also needs to be signed so that leaves 7 bits for binary
- * fixed point scaling.
+ * The constants adj is taken verbatim from the datasheet. Two values exists,
+ * which one to use depends on the input value and the calculated threshold.
+ * Furthermore different SoC models supported by the driver have different sets
+ * of values. The values for each model are stored in the device match data.
*/
-#define FIXPT_SHIFT 7
-#define FIXPT_INT(_x) ((_x) << FIXPT_SHIFT)
-#define INT_FIXPT(_x) ((_x) >> FIXPT_SHIFT)
-#define FIXPT_DIV(_a, _b) DIV_ROUND_CLOSEST(((_a) << FIXPT_SHIFT), (_b))
-#define FIXPT_TO_MCELSIUS(_x) ((_x) * 1000 >> FIXPT_SHIFT)
-
-#define RCAR3_THERMAL_GRAN 500 /* mili Celsius */
-
-/* no idea where these constants come from */
-#define TJ_3 -41
-
static void rcar_gen3_thermal_shared_coefs(struct rcar_gen3_thermal_priv *priv)
{
- int tj1 = priv->info->ths_tj_1;
-
- priv->tj_t = (FIXPT_INT((priv->ptat[1] - priv->ptat[2]) * (tj1 - TJ_3))
- / (priv->ptat[0] - priv->ptat[2])) + FIXPT_INT(TJ_3);
+ priv->tj_t =
+ DIV_ROUND_CLOSEST((priv->ptat[1] - priv->ptat[2]) * priv->info->scale,
+ priv->ptat[0] - priv->ptat[2])
+ + priv->info->adj_below;
}
-
static void rcar_gen3_thermal_tsc_coefs(struct rcar_gen3_thermal_priv *priv,
struct rcar_gen3_thermal_tsc *tsc)
{
- int tj1 = priv->info->ths_tj_1;
-
- /* TODO: Find documentation and document constant calculation formula */
-
- /*
- * Division is not scaled in BSP and if scaled it might overflow
- * the dividend (4095 * 4095 << 14 > INT_MAX) so keep it unscaled
- */
- tsc->coef.a1 = FIXPT_DIV(FIXPT_INT(tsc->thcode[1] - tsc->thcode[2]),
- priv->tj_t - FIXPT_INT(TJ_3));
- tsc->coef.b1 = FIXPT_INT(tsc->thcode[2]) - tsc->coef.a1 * TJ_3;
-
- tsc->coef.a2 = FIXPT_DIV(FIXPT_INT(tsc->thcode[1] - tsc->thcode[0]),
- priv->tj_t - FIXPT_INT(tj1));
- tsc->coef.b2 = FIXPT_INT(tsc->thcode[0]) - tsc->coef.a2 * tj1;
-}
-
-static int rcar_gen3_thermal_round(int temp)
-{
- int result, round_offs;
+ tsc->coef.below.a = priv->info->scale * (priv->ptat[2] - priv->ptat[1]);
+ tsc->coef.above.a = priv->info->scale * (priv->ptat[0] - priv->ptat[1]);
- round_offs = temp >= 0 ? RCAR3_THERMAL_GRAN / 2 :
- -RCAR3_THERMAL_GRAN / 2;
- result = (temp + round_offs) / RCAR3_THERMAL_GRAN;
- return result * RCAR3_THERMAL_GRAN;
+ tsc->coef.below.b = (priv->ptat[2] - priv->ptat[0]) * (tsc->thcode[2] - tsc->thcode[1]);
+ tsc->coef.above.b = (priv->ptat[0] - priv->ptat[2]) * (tsc->thcode[1] - tsc->thcode[0]);
}
static int rcar_gen3_thermal_get_temp(struct thermal_zone_device *tz, int *temp)
{
struct rcar_gen3_thermal_tsc *tsc = thermal_zone_device_priv(tz);
- int mcelsius, val;
- int reg;
+ struct rcar_gen3_thermal_priv *priv = tsc->priv;
+ const struct equation_set_coef *coef;
+ int adj, decicelsius, reg, thcode;
/* Read register and convert to mili Celsius */
reg = rcar_gen3_thermal_read(tsc, REG_GEN3_TEMP) & CTEMP_MASK;
- if (reg <= tsc->thcode[1])
- val = FIXPT_DIV(FIXPT_INT(reg) - tsc->coef.b1,
- tsc->coef.a1);
- else
- val = FIXPT_DIV(FIXPT_INT(reg) - tsc->coef.b2,
- tsc->coef.a2);
- mcelsius = FIXPT_TO_MCELSIUS(val);
+ if (reg < tsc->thcode[1]) {
+ adj = priv->info->adj_below;
+ coef = &tsc->coef.below;
+ thcode = tsc->thcode[2];
+ } else {
+ adj = priv->info->adj_above;
+ coef = &tsc->coef.above;
+ thcode = tsc->thcode[0];
+ }
+
+ /*
+ * The dividend can't be grown as it might overflow, instead shorten the
+ * divisor to convert to decidegree Celsius. If we convert after the
+ * division precision is lost as we will scale up from whole degrees
+ * Celsius.
+ */
+ decicelsius = DIV_ROUND_CLOSEST(coef->a * (thcode - reg), coef->b / 10);
/* Guaranteed operating range is -40C to 125C. */
- /* Round value to device granularity setting */
- *temp = rcar_gen3_thermal_round(mcelsius);
+ /* Reporting is done in millidegree Celsius */
+ *temp = decicelsius * 100 + adj * 1000;
return 0;
}
@@ -204,15 +192,21 @@ static int rcar_gen3_thermal_mcelsius_to_temp(struct rcar_gen3_thermal_tsc *tsc,
int mcelsius)
{
struct rcar_gen3_thermal_priv *priv = tsc->priv;
- int celsius, val;
+ const struct equation_set_coef *coef;
+ int adj, celsius, thcode;
celsius = DIV_ROUND_CLOSEST(mcelsius, 1000);
- if (celsius <= INT_FIXPT(priv->tj_t))
- val = celsius * tsc->coef.a1 + tsc->coef.b1;
- else
- val = celsius * tsc->coef.a2 + tsc->coef.b2;
+ if (celsius < priv->tj_t) {
+ coef = &tsc->coef.below;
+ adj = priv->info->adj_below;
+ thcode = tsc->thcode[2];
+ } else {
+ coef = &tsc->coef.above;
+ adj = priv->info->adj_above;
+ thcode = tsc->thcode[0];
+ }
- return INT_FIXPT(val);
+ return thcode - DIV_ROUND_CLOSEST((celsius - adj) * coef->b, coef->a);
}
static int rcar_gen3_thermal_set_trips(struct thermal_zone_device *tz, int low, int high)
@@ -377,17 +371,23 @@ static void rcar_gen3_thermal_init(struct rcar_gen3_thermal_priv *priv,
}
static const struct rcar_thermal_info rcar_m3w_thermal_info = {
- .ths_tj_1 = 116,
+ .scale = 157,
+ .adj_below = -41,
+ .adj_above = 116,
.read_fuses = rcar_gen3_thermal_read_fuses_gen3,
};
static const struct rcar_thermal_info rcar_gen3_thermal_info = {
- .ths_tj_1 = 126,
+ .scale = 167,
+ .adj_below = -41,
+ .adj_above = 126,
.read_fuses = rcar_gen3_thermal_read_fuses_gen3,
};
static const struct rcar_thermal_info rcar_gen4_thermal_info = {
- .ths_tj_1 = 126,
+ .scale = 167,
+ .adj_below = -41,
+ .adj_above = 126,
.read_fuses = rcar_gen3_thermal_read_fuses_gen4,
};