hwmon: (ntc_thermistor) Optimize and fix build warning

The following build warning is seen in some configurations:

drivers/hwmon/ntc_thermistor.c: In function 'ntc_show_temp':
drivers/hwmon/ntc_thermistor.c:293: warning: 'temp' may be used uninitialized in this function

Fix the problem by re-arranging the code to overload return values with error
codes, and by avoiding error returns whenever possible.

Specifically,

Simplify lookup_comp() to not return an error. Instead, return i_low == i_high
if there is an exact match, or if the ohm value is outside the lookup table
range.

Modify get_temp_mC() to not return an error. Since it only returns an error
after lookup_comp() returned an error, this is quite straightforward after above
change.

Separate ntc_thermistor_read() into a function to read the resistor value (which
can return an error), and the call to get_temp_mC() which doesn't. Call the
functions directly from ntc_show_temp().

Code was tested using a test program, comparing the result of the old and new
versions of get_temp_mC() for resistor values between 0 and 2,000,000 ohm.

As a side effect, this patch reduces code size by approximately 400 bytes on
x86_64.

Signed-off-by: Guenter Roeck <guenter.roeck@ericsson.com>
Cc: Donggeun Kim <dg77.kim@samsung.com>
Reviewed-by: Robert Coulson <robert.coulson@ericsson.com>
This commit is contained in:
Guenter Roeck 2012-04-22 20:58:51 -07:00
parent 425d247680
commit dbe43a6276

View File

@ -134,8 +134,7 @@ static inline u64 div64_u64_safe(u64 dividend, u64 divisor)
return div64_u64(dividend, divisor); return div64_u64(dividend, divisor);
} }
static unsigned int get_ohm_of_thermistor(struct ntc_data *data, static int get_ohm_of_thermistor(struct ntc_data *data, unsigned int uV)
unsigned int uV)
{ {
struct ntc_thermistor_platform_data *pdata = data->pdata; struct ntc_thermistor_platform_data *pdata = data->pdata;
u64 mV = uV / 1000; u64 mV = uV / 1000;
@ -146,12 +145,12 @@ static unsigned int get_ohm_of_thermistor(struct ntc_data *data,
if (mV == 0) { if (mV == 0) {
if (pdata->connect == NTC_CONNECTED_POSITIVE) if (pdata->connect == NTC_CONNECTED_POSITIVE)
return UINT_MAX; return INT_MAX;
return 0; return 0;
} }
if (mV >= pmV) if (mV >= pmV)
return (pdata->connect == NTC_CONNECTED_POSITIVE) ? return (pdata->connect == NTC_CONNECTED_POSITIVE) ?
0 : UINT_MAX; 0 : INT_MAX;
if (pdata->connect == NTC_CONNECTED_POSITIVE && puO == 0) if (pdata->connect == NTC_CONNECTED_POSITIVE && puO == 0)
N = div64_u64_safe(pdO * (pmV - mV), mV); N = div64_u64_safe(pdO * (pmV - mV), mV);
@ -163,113 +162,109 @@ static unsigned int get_ohm_of_thermistor(struct ntc_data *data,
else else
N = div64_u64_safe(pdO * puO * mV, pdO * (pmV - mV) - puO * mV); N = div64_u64_safe(pdO * puO * mV, pdO * (pmV - mV) - puO * mV);
return (unsigned int) N; if (N > INT_MAX)
N = INT_MAX;
return N;
} }
static int lookup_comp(struct ntc_data *data, static void lookup_comp(struct ntc_data *data, unsigned int ohm,
unsigned int ohm, int *i_low, int *i_high) int *i_low, int *i_high)
{ {
int start, end, mid = -1; int start, end, mid;
/*
* Handle special cases: Resistance is higher than or equal to
* resistance in first table entry, or resistance is lower or equal
* to resistance in last table entry.
* In these cases, return i_low == i_high, either pointing to the
* beginning or to the end of the table depending on the condition.
*/
if (ohm >= data->comp[0].ohm) {
*i_low = 0;
*i_high = 0;
return;
}
if (ohm <= data->comp[data->n_comp - 1].ohm) {
*i_low = data->n_comp - 1;
*i_high = data->n_comp - 1;
return;
}
/* Do a binary search on compensation table */ /* Do a binary search on compensation table */
start = 0; start = 0;
end = data->n_comp; end = data->n_comp;
while (start < end) {
while (end > start) {
mid = start + (end - start) / 2; mid = start + (end - start) / 2;
if (data->comp[mid].ohm < ohm) /*
* start <= mid < end
* data->comp[start].ohm > ohm >= data->comp[end].ohm
*
* We could check for "ohm == data->comp[mid].ohm" here, but
* that is a quite unlikely condition, and we would have to
* check again after updating start. Check it at the end instead
* for simplicity.
*/
if (ohm >= data->comp[mid].ohm) {
end = mid; end = mid;
else if (data->comp[mid].ohm > ohm) } else {
start = mid + 1; start = mid + 1;
else /*
break; * ohm >= data->comp[start].ohm might be true here,
} * since we set start to mid + 1. In that case, we are
* done. We could keep going, but the condition is quite
if (mid == 0) { * likely to occur, so it is worth checking for it.
if (data->comp[mid].ohm > ohm) { */
*i_high = mid; if (ohm >= data->comp[start].ohm)
*i_low = mid + 1; end = start;
return 0;
} else {
*i_low = mid;
*i_high = -1;
return -EINVAL;
} }
/*
* start <= end
* data->comp[start].ohm >= ohm >= data->comp[end].ohm
*/
} }
if (mid == (data->n_comp - 1)) { /*
if (data->comp[mid].ohm <= ohm) { * start == end
*i_low = mid; * ohm >= data->comp[end].ohm
*i_high = mid - 1; */
return 0; *i_low = end;
} else { if (ohm == data->comp[end].ohm)
*i_low = -1; *i_high = end;
*i_high = mid; else
return -EINVAL; *i_high = end - 1;
}
}
if (data->comp[mid].ohm <= ohm) {
*i_low = mid;
*i_high = mid - 1;
} else {
*i_low = mid + 1;
*i_high = mid;
}
return 0;
} }
static int get_temp_mC(struct ntc_data *data, unsigned int ohm, int *temp) static int get_temp_mC(struct ntc_data *data, unsigned int ohm)
{ {
int low, high; int low, high;
int ret; int temp;
ret = lookup_comp(data, ohm, &low, &high); lookup_comp(data, ohm, &low, &high);
if (ret) { if (low == high) {
/* Unable to use linear approximation */ /* Unable to use linear approximation */
if (low != -1) temp = data->comp[low].temp_C * 1000;
*temp = data->comp[low].temp_C * 1000;
else if (high != -1)
*temp = data->comp[high].temp_C * 1000;
else
return ret;
} else { } else {
*temp = data->comp[low].temp_C * 1000 + temp = data->comp[low].temp_C * 1000 +
((data->comp[high].temp_C - data->comp[low].temp_C) * ((data->comp[high].temp_C - data->comp[low].temp_C) *
1000 * ((int)ohm - (int)data->comp[low].ohm)) / 1000 * ((int)ohm - (int)data->comp[low].ohm)) /
((int)data->comp[high].ohm - (int)data->comp[low].ohm); ((int)data->comp[high].ohm - (int)data->comp[low].ohm);
} }
return temp;
return 0;
} }
static int ntc_thermistor_read(struct ntc_data *data, int *temp) static int ntc_thermistor_get_ohm(struct ntc_data *data)
{ {
int ret; int read_uV;
int read_ohm, read_uV;
unsigned int ohm = 0;
if (data->pdata->read_ohm) { if (data->pdata->read_ohm)
read_ohm = data->pdata->read_ohm(); return data->pdata->read_ohm();
if (read_ohm < 0)
return read_ohm;
ohm = (unsigned int)read_ohm;
}
if (data->pdata->read_uV) { if (data->pdata->read_uV) {
read_uV = data->pdata->read_uV(); read_uV = data->pdata->read_uV();
if (read_uV < 0) if (read_uV < 0)
return read_uV; return read_uV;
ohm = get_ohm_of_thermistor(data, (unsigned int)read_uV); return get_ohm_of_thermistor(data, read_uV);
} }
return -EINVAL;
ret = get_temp_mC(data, ohm, temp);
if (ret) {
dev_dbg(data->dev, "Sensor reading function not available.\n");
return ret;
}
return 0;
} }
static ssize_t ntc_show_name(struct device *dev, static ssize_t ntc_show_name(struct device *dev,
@ -290,12 +285,13 @@ static ssize_t ntc_show_temp(struct device *dev,
struct device_attribute *attr, char *buf) struct device_attribute *attr, char *buf)
{ {
struct ntc_data *data = dev_get_drvdata(dev); struct ntc_data *data = dev_get_drvdata(dev);
int temp, ret; int ohm;
ret = ntc_thermistor_read(data, &temp); ohm = ntc_thermistor_get_ohm(data);
if (ret) if (ohm < 0)
return ret; return ohm;
return sprintf(buf, "%d\n", temp);
return sprintf(buf, "%d\n", get_temp_mC(data, ohm));
} }
static SENSOR_DEVICE_ATTR(temp1_type, S_IRUGO, ntc_show_type, NULL, 0); static SENSOR_DEVICE_ATTR(temp1_type, S_IRUGO, ntc_show_type, NULL, 0);