#include "task.h"
#include "adc_random.h"
-#define AUTO_OFF_COUNT 150 /* 5 mins on*/
-#define AUTO_ON_COUNT 300 /* 10 mins off */
+//#define AUTO_OFF_COUNT 150 /* 5 mins on*/
+//#define AUTO_ON_COUNT 300 /* 10 mins off */
//#define AUTO_OFF_COUNT 450 /* 15 mins on*/
//#define AUTO_ON_COUNT 1350 /* 45 mins off */
//#define AUTO_OFF_COUNT 600 /* 20 mins on*/
//#define AUTO_ON_COUNT 1200 /* 40 mins off */
//#define AUTO_OFF_COUNT 450 /* 2 hours on*/
//#define AUTO_ON_COUNT 1350 /* 22 hours off */
-//#define AUTO_OFF_COUNT 9000U /* 5 hrs in 2 sec units */
-//#define AUTO_ON_COUNT 34200U /* 19 hrs in 2 sec units */
+#define AUTO_OFF_COUNT 9000U /* 5 hrs in 2 sec units */
+#define AUTO_ON_COUNT 34200U /* 19 hrs in 2 sec units */
#define dbgpin_init() do { \
/* Set RA2 as output low */ \
RA2 = 0; \
#define dbgpin_low() (RA2 = 0)
#define dbgpin_toggle() (RA2 = (LATA2 == 0) ? 1 : 0)
+#define cfg_write(mode, color) do { \
+ eeprom_write(CFG_MODE_ADDR, (mode)); \
+ eeprom_write(CFG_COLOR_ADDR, (color)); \
+ } while (0)
+
+#define cfg_read(mode, color) do { \
+ unsigned char tmp; \
+ tmp = eeprom_read(CFG_MODE_ADDR); \
+ mode = (tmp < MODE_COUNT) ? tmp : MODE_SOLID; \
+ tmp = eeprom_read(CFG_COLOR_ADDR); \
+ color = (tmp < COLOR_COUNT) ? tmp : 0; \
+ } while (0)
+
enum {
/* Operating modes */
MODE_SOLID = 0, /* Cycle through colors[][] before next mode */
//MODE_CANDLE,
- MODE_FADE, /* Auto cycle through colors */
+ MODE_CYCLE, /* Auto cycle through colors */
MODE_PARTY, /* Random yet fast incolor and fade */
MODE_COUNT,
BRIGHT_MIN = 1, /* ... by min and max. */
BRIGHT_INIT = 42, /* later, get from eeprom */
STD_FADE = 16, /* Fade time in 32.768 ms units */
- STD_INCOLOR = 29491, /* Time in color when MODE_FADE, in 32.768 ms units */
+ STD_INCOLOR = 29491, /* Time in color when MODE_CYCLE, in 32.768 ms units */
PARTY_MIN = 8, /* Min party fade and incolor units */
PARTY_RANGE = 8, /* Party fade/incolor range mask for rand() */
/* ... see start_fade() */
+ CFG_MODE_ADDR = 0, /* EEPROM address of mode variable */
+ CFG_COLOR_ADDR, /* EEPROM address of color variable */
+ CFG_DELAY = 92, /* 3 seconds in 32.768 msec units */
};
typedef struct {
bit bright_up;
signed char pbHeldCount;
-/* Return the constrained brightness level for use in computing RGB values */
-unsigned char bright_get()
-{
- if (bright > BRIGHT_MAX)
- return BRIGHT_MAX;
- else if (bright < BRIGHT_MIN)
- return BRIGHT_MIN;
- else
- return bright;
-}
-
-/* RGB values will not illuminate the LED */
-unsigned char led_get(unsigned value)
+/* Combine LED color value and brightness level to generate an RGB value.
+ * bright will be BRIGHT_MIN...BRIGHT_MAX
+ *
+ * @param value 0...1023 (6 bit color, left shifted 4 bits, for 10 bits)
+ * @param b brightness value BRIGHT_MIN...BRIGHT_MAX
+ * @return An RGB drive value, 0...255
+ */
+unsigned char led_get(int value, signed char b)
{
- value = (value * bright_get()) >> 8;
-#ifdef CEIL256
- if (value && value < 0x26)
- return 0x26;
-#else
- if (value && value < 4)
- return 4;
-#endif
- return value;
+ return (unsigned long)value * b / 4 / BRIGHT_MAX;
}
-/* Set the LEDs using both color and brightness values. */
+/* Set the LEDs using color values and current brightness. */
void leds_set()
{
- rgb_set(led_get((red).value),
- led_get((grn).value), led_get((blu).value),
- led_get((wht).value));
+ signed char b;
+
+ if (bright > BRIGHT_MAX)
+ b = BRIGHT_MAX;
+ else if (bright < BRIGHT_MIN)
+ b = BRIGHT_MIN;
+ else
+ b = bright;
+ rgb_set(led_get((red).value, b), led_get((grn).value, b),
+ led_get((blu).value, b), led_get((wht).value, b));
}
void start_fade()
{
- /* RGB PWM values are 8 bits, but computations are done in 15
- * (leaving room for a sign bit), so leds_set() uses >>7 to convert
- * to PWM values.
+ /* RGB PWM values are 8 bits. Color values are 12 bits. See led_get()
+ * for the conversion of color values and brightness to RGB values.
*/
int newr, newg, newb, neww;
if (mode == MODE_PARTY) {
color = rand() % COLOR_COUNT;
fade_steps = PARTY_MIN + (rand() % PARTY_RANGE);
- } else if (mode == MODE_FADE) {
+ } else if (mode == MODE_CYCLE) {
if (++color == COLOR_COUNT)
color = 0;
}
void turnOff()
{
/* Event on to off, either by switch or auto-off timer */
+ tmr_stop(TMR_CFG);
tmr_stop(TMR_INCOLOR);
tmr_stop(TMR_FADE);
rgb_off();
void pb_clicked()
{
if (on) {
+ unsigned char omode = mode;
+
if (mode == MODE_SOLID) {
if (++color == COLOR_COUNT) {
color = 0;
mode = 0;
color = 0;
}
+ if (mode != omode || mode == MODE_SOLID)
+ tmr_start(TMR_CFG, CFG_DELAY);
start_fade();
}
}
blu.value += blu.remainder;
wht.value += wht.remainder;
tmr_stop(TMR_FADE);
- if (mode == MODE_FADE)
+ if (mode == MODE_CYCLE)
tmr_start(TMR_INCOLOR, STD_INCOLOR);
else if (mode == MODE_PARTY)
tmr_start(TMR_INCOLOR, PARTY_MIN + (rand() % PARTY_RANGE));
}
}
-void config_read()
-{
- /* Read configuration fields from eeprom, notably current mode and
- * brightness level.
- */
- /* FIXME: implement this */
-}
-
void user_boot()
{
dbgpin_high();
srand((adc_random() << 8) + adc_random());
- config_read();
+ cfg_read(mode, color);
rs_task();
}
case TASK_TMR32: /* auto on/off event */
auto_offon_task();
break;
+ case TASK_CFG: /* Save config to EEPROM event */
+ cfg_write(mode, color);
+ break;
}
}
}