typedef struct {
uint16_t target, pwm;
int16_t err_sum;
- unsigned char mode, state, probe_steps;
+ unsigned char mode, state;
+ union {
+ unsigned char probe_steady, mode_changed;
+ };
uint16_t mode_pwm[N_PWMLED_MODES];
int16_t err_sums[N_PWMLED_MODES];
} pwmled_t;
#define PWMLED2_TESTING_WITH_350MA_LED
#define SENSE_MOHM 33 /* 0.033 Ohm */
-#define MA_MOHM_GAIN_TO_ADC(ma, mohm, gain) (\
- ((unsigned long)(ma))*(mohm) /* voltage at sensing resistor in uV */ \
- /(1100000UL/gain/1024UL) /* voltage of ADC reading == 1 */ \
-)
+/*
+ * Voltage in uV at ADC reading == 1 is 1100/gain/1024
+ * ADC module returns sum of 1 << PWMLED_ADC_SHIFT measurements
+ * Voltage in uV measured is current in mA * sense resistance in mOhm
+ */
+#define MA_GAIN_TO_ADC(ma, gain) ((uint16_t) \
+ ((uint32_t)(ma) \
+ * (SENSE_MOHM) \
+ * (1 << (PWMLED_ADC_SHIFT)) \
+ * 1024 \
+ / (1100000/(gain))))
static uint16_t adc_max[N_PWMLEDS] = {
- MA_MOHM_GAIN_TO_ADC( 400, SENSE_MOHM, 20),
- MA_MOHM_GAIN_TO_ADC( 30, SENSE_MOHM, 20),
-#ifdef PWMLED2_TESTING_WITH_350MA_LED
- MA_MOHM_GAIN_TO_ADC( 400, SENSE_MOHM, 1)
+#ifdef TESTING_FW
+ MA_GAIN_TO_ADC( 400, 20),
+ MA_GAIN_TO_ADC( 30, 20),
+ MA_GAIN_TO_ADC( 800, 1)
#else
- MA_MOHM_GAIN_TO_ADC(2500, SENSE_MOHM, 1)
+ MA_GAIN_TO_ADC( 900, 20),
+ MA_GAIN_TO_ADC( 30, 20),
+ MA_GAIN_TO_ADC(2500, 1)
#endif
};
static uint16_t adc_vals[N_PWMLEDS*N_PWMLED_MODES] = {
+#ifdef TESTING_FW
/* pwmled0 */
- MA_MOHM_GAIN_TO_ADC( 20, SENSE_MOHM, 20),
- MA_MOHM_GAIN_TO_ADC( 50, SENSE_MOHM, 20),
- MA_MOHM_GAIN_TO_ADC( 100, SENSE_MOHM, 20),
- MA_MOHM_GAIN_TO_ADC( 350, SENSE_MOHM, 20),
+ MA_GAIN_TO_ADC( 50, 20),
+ MA_GAIN_TO_ADC( 100, 20),
+ MA_GAIN_TO_ADC( 200, 20),
+ MA_GAIN_TO_ADC( 300, 20),
/* pwmled1 */
- 16, 32, 64, 112,
-#if 0
- MA_MOHM_GAIN_TO_ADC( 5, SENSE_MOHM, 20),
- MA_MOHM_GAIN_TO_ADC( 12, SENSE_MOHM, 20),
- MA_MOHM_GAIN_TO_ADC( 16, SENSE_MOHM, 20),
- MA_MOHM_GAIN_TO_ADC( 20, SENSE_MOHM, 20),
-#endif
+ MA_GAIN_TO_ADC( 5, 20),
+ MA_GAIN_TO_ADC( 10, 20),
+ MA_GAIN_TO_ADC( 15, 20),
+ MA_GAIN_TO_ADC( 20, 20),
/* pwmled2 */
- 24, 32, 40, 48
-#if 0
-#ifdef PWMLED2_TESTING_WITH_350MA_LED
- MA_MOHM_GAIN_TO_ADC( 100, SENSE_MOHM, 1),
- MA_MOHM_GAIN_TO_ADC( 140, SENSE_MOHM, 1),
- MA_MOHM_GAIN_TO_ADC( 250, SENSE_MOHM, 1),
- MA_MOHM_GAIN_TO_ADC( 350, SENSE_MOHM, 1),
+ MA_GAIN_TO_ADC( 50, 1),
+ MA_GAIN_TO_ADC( 100, 1),
+ MA_GAIN_TO_ADC( 150, 1),
+ MA_GAIN_TO_ADC( 200, 1)
#else
- MA_MOHM_GAIN_TO_ADC( 150, SENSE_MOHM, 1),
- MA_MOHM_GAIN_TO_ADC( 350, SENSE_MOHM, 1),
- MA_MOHM_GAIN_TO_ADC( 700, SENSE_MOHM, 1),
- MA_MOHM_GAIN_TO_ADC(2400, SENSE_MOHM, 1),
-#endif
+ /* pwmled0 */
+ MA_GAIN_TO_ADC( 100, 20),
+ MA_GAIN_TO_ADC( 300, 20),
+ MA_GAIN_TO_ADC( 700, 20),
+ MA_GAIN_TO_ADC( 800, 20),
+ /* pwmled1 */
+ MA_GAIN_TO_ADC( 5, 20),
+ MA_GAIN_TO_ADC( 10, 20),
+ MA_GAIN_TO_ADC( 18, 20),
+ MA_GAIN_TO_ADC( 23, 20),
+ /* pwmled2 */
+ MA_GAIN_TO_ADC( 200, 1),
+ MA_GAIN_TO_ADC( 400, 1),
+ MA_GAIN_TO_ADC( 800, 1),
+ MA_GAIN_TO_ADC(1500, 1)
#endif
};
led->pwm = 0;
led->mode = 1;
led->state = ST_PROBING;
- led->probe_steps = 0;
+ led->probe_steady = 0;
for (j = 0; j < N_PWMLED_MODES; j++) {
led->mode_pwm[j] = 0;
led->state = ST_ON;
led->pwm = led->mode_pwm[mode - 1];
led->err_sum = led->err_sums[mode - 1];
+ led->mode_changed = 1;
pwm_set(n, led->pwm);
} else {
led->state = ST_OFF;
}
}
+#define PWMLED_PROBE_STEADY_COUNT 10
+
+static inline unsigned char pwmled_probed_ok(unsigned char n, uint16_t old_pwm)
+{
+ pwmled_t *led = pwmleds + n;
+
+ if (led->pwm == old_pwm) {
+ if (led->probe_steady < PWMLED_PROBE_STEADY_COUNT)
+ led->probe_steady++;
+ } else {
+ led->probe_steady = 0;
+ }
+
+ if (led->probe_steady < PWMLED_PROBE_STEADY_COUNT
+ && old_pwm <= led->pwm)
+ return 0;
+
+ // probed OK
+ led->mode_pwm[led->mode - 1] = led->pwm;
+ led->err_sums[led->mode - 1] = 0;
+
+ // next mode to probe?
+ if (led->mode < N_PWMLED_MODES) {
+ led->probe_steady = 0;
+ led->err_sum = 0;
+
+ led->mode++;
+ led->target = adc_vals[n*N_PWMLED_MODES+led->mode-1];
+
+ return 0;
+ } else {
+ unsigned char i;
+
+ led->state = ST_OFF;
+ pwm_off(n);
+
+ log_byte(0xF0);
+ log_byte(n);
+ log_word(jiffies);
+
+ for (i = 0; i < N_PWMLED_MODES; i++)
+ log_word(led->mode_pwm[i]);
+
+ log_flush();
+
+ pattern_reload();
+
+ return 1;
+ }
+}
+
+static inline void pwmled_err(unsigned char n)
+{
+ pwmleds[n].state = ST_DISABLED;
+ pwm_off(n);
+
+ log_byte(0xF1);
+ log_byte(n);
+ log_word(jiffies);
+ log_flush();
+}
+
+
void pwmled_adc(unsigned char n, uint16_t adcval)
{
pwmled_t *led = pwmleds + n;
if (!ST_IS_ON(led->state))
return;
+ if (led->state == ST_ON && led->mode_changed) {
+ led->mode_changed--;
+ return;
+ }
// FIXME: test for maximum adcval value (adc_max[n])
old_pwm = led->pwm;
sum -= led->pwm << shift;
led->err_sum = sum;
- if (led->state == ST_PROBING) {
- if (led->pwm == old_pwm) {
- if (led->probe_steps < 10)
- led->probe_steps++;
- } else {
- led->probe_steps = 0;
- }
-
- if (led->probe_steps >= 10 || old_pwm > led->pwm) {
-
- led->mode_pwm[led->mode - 1] = led->pwm;
-
- if (led->mode < N_PWMLED_MODES) {
- led->probe_steps = 0;
- led->err_sum = 0;
-
- led->mode++;
- led->target = adc_vals[n*N_PWMLED_MODES+led->mode-1];
- } else {
- unsigned char i;
-
- led->state = ST_OFF;
-
- log_byte(0xF0);
- log_byte(n);
- log_word(jiffies);
-
- for (i = 0; i < N_PWMLED_MODES; i++)
- log_word(led->mode_pwm[i]);
-
- log_flush();
- }
- }
+ if (led->pwm >= PWM_MAX
+ || (n == 1 && led->pwm > PWM_MAX/4 && adcval < 0x08)) {
+ pwmled_err(n);
+ return;
}
+ if (led->state == ST_PROBING)
+ if (pwmled_probed_ok(n, old_pwm))
+ return;
+
if (led->pwm == old_pwm)
return;
- if (led->pwm > (PWM_MAX << PWM_STEP_SHIFT)/2) {
- pwm_off(n);
- led->state = ST_DISABLED;
- log_byte(0xF1);
- log_byte(n);
- log_word(jiffies);
- log_flush();
- }
-
pwm_set(n, led->pwm);
}