volatile char shutterLagTest(char key, char first)
{
// static uint8_t cable;
uint16_t start_lag, end_lag;
if(first)
{
// cable = 0;
lcd.cls();
menu.setTitle(TEXT("Shutter Lag Test"));
menu.setBar(TEXT("Test 1"), TEXT("Test 2 "));
lcd.update();
}
if(key == FL_KEY || key == FR_KEY)
{
lcd.eraseBox(10, 18, 80, 38);
lcd.writeString(10, 18, TEXT("Result:"));
ENABLE_SHUTTER;
ENABLE_MIRROR;
ENABLE_AUX_PORT;
_delay_ms(100);
if(key == FR_KEY)
{
MIRROR_UP;
_delay_ms(1000);
}
SHUTTER_OPEN;
clock.tare();
while(!AUX_INPUT1)
{
if(clock.eventMs() >= 1000)
break;
}
start_lag = (uint16_t)clock.eventMs();
_delay_ms(50);
SHUTTER_CLOSE;
clock.tare();
while(AUX_INPUT1)
{
if(clock.eventMs() > 1000)
break;
}
end_lag = (uint16_t)clock.eventMs();
lcd.writeNumber(56, 18, start_lag, 'U', 'L');
lcd.writeNumber(56, 28, end_lag, 'U', 'L');
lcd.update();
}
if(key == LEFT_KEY)
return FN_CANCEL;
return FN_CONTINUE;
}
char shutter::run()
{
char cancel = 0;
static uint8_t enter, photos, exps, run_state = RUN_DELAY, old_state = 255;
static uint32_t last_photo_ms;
if(MIRROR_IS_DOWN)
{
CHECK_CABLE;
}
if(!running)
{
if(enter) cancel = 1; else return 0;
}
uint16_t value;
if(enter == 0) // Initialize variables and setup I/O pins
{
enter = 1;
run_state = RUN_DELAY;
clock.tare();
photos = 0;
exps = 0;
ENABLE_MIRROR;
ENABLE_SHUTTER;
MIRROR_DOWN;
SHUTTER_CLOSE;
}
/////// RUNNING PROCEDURE ///////
if(run_state == RUN_DELAY)
{
#ifdef DEBUG
if(old_state != run_state)
{
if(conf.devMode)
{
debug("State: RUN_DELAY");
debug_nl();
}
old_state = run_state;
}
#endif
if(((unsigned long) clock.event_ms / 1000) > current.Delay)
{
clock.tare();
clock.reset();
last_photo_ms = 0;
run_state = RUN_PHOTO;
}
else
{
if(((unsigned long) clock.event_ms / 1000) + settings_mirror_up_time >= current.Delay)
{
// Mirror Up //
half();
}
if((settings_warn_time > 0) && (((unsigned long) clock.event_ms / 1000) + settings_warn_time >= current.Delay))
{
// Flash Light //
_delay_ms(50);
}
}
}
if(run_state == RUN_PHOTO)
{
#ifdef DEBUG
if(old_state != run_state)
{
if(conf.devMode)
{
debug("State: RUN_PHOTO");
debug_nl();
}
old_state = run_state;
}
#endif
if(current.Exp > 0 || (current.Mode & RAMP))
{
clock.tare();
run_state = RUN_BULB;
}
else
{
exps++;
bulb = false;
full();
_delay_ms(50);
off();
_delay_ms(50);
if(current.Gap <= settings_mirror_up_time) half(); // Mirror Up //
run_state = RUN_NEXT;
}
}
if(run_state == RUN_BULB)
{
#ifdef DEBUG
if(old_state != run_state)
{
if(conf.devMode)
{
debug("State: RUN_BULB");
debug_nl();
}
old_state = run_state;
}
#endif
bulb = true;
full();
static uint8_t calc = true;
static uint16_t bulb_length, exp;
if(calc)
{
calc = false;
exp = current.Exp * 100;
if(current.Mode & RAMP)
{
float key1, key2, key3, key4;
char found = 0;
uint8_t i;
// Bulb ramp algorithm goes here
for(i = 1; i <= current.Keyframes; i++)
{
if(clock.Seconds() <= current.Key[i - 1])
{
found = 1;
key1 = (float) current.Bulb[i > 1 ? i - 2 : i - 1] * 100;
key2 = (float) current.Bulb[i - 1] * 100;
key3 = (float) current.Bulb[i] * 100;
key4 = (float) current.Bulb[i < current.Keyframes ? i + 1 : i] * 100;
break;
}
}
if(found)
{
exp = (uint16_t) curve(key1, key2, key3, key4, ((float)clock.Seconds() - (i > 1 ? (float)current.Key[i - 2] : 0.0) ) / ((float)current.Key[i - 1] - (i > 1 ? (float)current.Key[i - 2] : 0.0)) );
}
else
{
exp = current.Bulb[current.Keyframes] * 100;
}
bulb_length = exp;
if(conf.devMode)
{
debug("Seconds: ");
debug((uint16_t) clock.Seconds());
debug_nl();
debug("Ramp: ");
debug(bulb_length);
if(found) debug(" (calculated)");
debug_nl();
}
}
if(current.Mode & HDR)
{
uint16_t tmp = exps - (current.Exps >> 1);
bulb_length = (tmp < 32768) ? exp * (1 << tmp) : exp / (1 << (0 - tmp));
if(conf.devMode)
{
debug("exps - (current.Exps >> 1): ");
if(tmp < 32768)
{
debug(tmp);
}
else
{
debug("-");
debug(0 - tmp);
}
debug_nl();
debug("Bulb: ");
debug(bulb_length);
debug_nl();
}
}
if((current.Mode & (HDR | RAMP)) == 0)
{
if(conf.devMode)
{
debug("***Using exp");
debug_nl();
}
bulb_length = exp;
}
}
if(((unsigned long) clock.eventMs()) >= bulb_length )
{
calc = true;
exps++;
off();
_delay_ms(50);
if(current.Gap <= settings_mirror_up_time) half(); // Mirror Up //
run_state = RUN_NEXT;
}
}
volatile char motionTrigger(char key, char first)
{
uint8_t i;
uint16_t val;
static uint16_t lv[3];
static uint8_t threshold = 2;
if(key == LEFT_KEY)
{
if(threshold > 0) threshold--;
first = 1;
}
if(key == RIGHT_KEY)
{
if(threshold < 4) threshold++;
first = 1;
}
if(first)
{
sleepOk = 0;
clock.tare();
lcd.cls();
menu.setTitle(TEXT("Motion Sensor"));
menu.setBar(TEXT("RETURN"), BLANK_STR);
lcd.drawLine(10, 22, 84-10, 22);
lcd.drawLine(11, 21, 11, 23);
lcd.drawLine(84-11, 21, 84-11, 23);
lcd.drawLine(12, 20, 12, 24);
lcd.drawLine(84-12, 20, 84-12, 24);
lcd.drawLine(13, 20, 13, 24);
lcd.drawLine(84-13, 20, 84-13, 24);
lcd.setPixel(42, 21);
lcd.setPixel(42+10, 21);
lcd.setPixel(42-10, 21);
lcd.setPixel(42+20, 21);
lcd.setPixel(42-20, 21);
i = threshold * 10;
lcd.drawLine(42-3-20+i, 16, 42+3-20+i, 16);
lcd.drawLine(42-2-20+i, 17, 42+2-20+i, 17);
lcd.drawLine(42-1-20+i, 18, 42+1-20+i, 18);
lcd.setPixel(42-20+i, 19);
lcd.writeStringTiny(19, 25, TEXT("SENSITIVITY"));
lcd.update();
lcd.backlight(0);
hardware_flashlight(0);
_delay_ms(50);
for(i = 0; i < 3; i++)
{
lv[i] = (uint16_t)hardware_readLight(i);
}
}
uint8_t thres = 4 - threshold + 2;
if((4 - threshold) > 2) thres += ((4 - threshold) - 1) * 2;
for(i = 0; i < 3; i++)
{
val = (uint16_t)hardware_readLight(i);
if(clock.eventMs() > 1000 && val > thres && (val < (lv[i] - thres) || val > (lv[i] + thres)))
{
clock.tare();
shutter_capture();
}
lv[i] = val;
}
if(key == FL_KEY)
{
sleepOk = 1;
lcd.backlight(255);
return FN_CANCEL;
}
return FN_CONTINUE;
}
