static volatile uint16_t handlerEvents = 0;
static uint16_t clockTick = 0;
static Hal_Handler handlerTab[NUM_HANDLERS];
+static uint32_t gpioCount[3];
+static bool timerActive[3] = {false, false, false};
+static uint16_t timerPoint[3];
+/* -------- INTERNAL FUNCTIONS -------- */
+
+static void gpioHandler(uint8_t id) {
+ uint8_t i;
+ uint16_t now, left;
+
+ if (timerActive[id])
+ return;
+ timerActive[id] = true;
+ now = TA1R;
+ timerPoint[id] = now + ACLK_TICKS_PER_SECOND; // One second ahead
+ left = ACLK_TICKS_PER_SECOND;
+ for (i = 0; i < 3; i++)
+ if (timerActive[i] && (timerPoint[i] - now) < left) {
+ left = timerPoint[i] - now;
+ }
+ TA1CCR0 = now + left;
+ TA1CCTL0 = CCIE;
+}
+
+static void tickHandler(uint16_t clock) {
+ uint8_t i;
+
+ for (i = 0; i < 3; i++)
+ if (timerActive[i] && timerPoint[i] == clock) {
+ uint32_t count = Hal_gpioCount(i);
+
+ if (count) {
+ ; // update timer; call jitter handler
+ } else {
+ ; // clear timer; call app gpio handler
+ }
+ }
+ // if all timers are unset, disable ticker.
+}
+
+static void postEvent(uint8_t handlerId) {
+ uint8_t key = Em_Hal_lock();
+ handlerEvents |= 1 << handlerId;
+ Em_Hal_unlock(key);
+}
/* -------- APP-HAL INTERFACE -------- */
Hal_delay(100);
(P1IFG &= ~mask, P1IE |= mask);
}
+ handlerTab[TICK_HANDLER_ID] = tickHandler;
}
void Hal_connected(void) {
uint8_t id;
for (id = 0, mask = 0x1; id < NUM_HANDLERS; id++, mask <<= 1) {
if ((events & mask) && handlerTab[id]) {
- handlerTab[id](id);
+ if (id == TICK_HANDLER_ID)
+ handlerTab[id](TA1R);
+ else
+ handlerTab[id](id);
}
}
}
else { // await more events
- SLEEP();
+ SLEEP(); // this also enables interrupts
}
}
}
RED_LED_TOGGLE();
}
-void Hal_tickStart(uint16_t msecs, Hal_Handler handler) {
+uint16_t Hal_tickStart(uint16_t msecs, void (*handler)(uint16_t clock)) {
handlerTab[TICK_HANDLER_ID] = handler;
- clockTick = (ACLK_TICKS_PER_SECOND * msecs) / 1000;
- TA1CCR0 = TA1R + clockTick; // Set the CCR0 interrupt for msecs from now.
+ uint16_t clockTick = (ACLK_TICKS_PER_SECOND * msecs) / 1000;
+ uint16_t then = TA1R + clockTick;
+ TA1CCR0 = then; // Set the CCR0 interrupt for msecs from now.
TA1CCTL0 = CCIE; // Enable the CCR0 interrupt
+ return then;
}
void Hal_tickStop(void) {
TA1CCTL0 = 0;
}
+uint32_t Hal_gpioCount(uint8_t id) {
+ DINT();
+ uint32_t count = gpioCount[id];
+ gpioCount[id] = 0;
+ EINT();
+ return count;
+}
+
/* -------- SRT-HAL INTERFACE -------- */
uint8_t Em_Hal_lock(void) {
UART_WATCH_ENABLE();
}
-
-/* -------- INTERNAL FUNCTIONS -------- */
-
-static void gpioHandler(uint8_t id) {
- uint16_t mask = BIT3 << id;
-
- Hal_delay(GPIO_DEBOUNCE_MSECS);
- if (GPIO_LOW(mask) && appGpioHandler)
- appGpioHandler(id);
- GPIO_ENABLE(mask);
-}
-
-static void postEvent(uint8_t handlerId) {
- uint8_t key = Em_Hal_lock();
- handlerEvents |= 1 << handlerId;
- Em_Hal_unlock(key);
-}
-
/* -------- INTERRUPT SERVICE ROUTINES -------- */
#ifdef __GNUC__
for (id = 0, mask = BIT3; id < 3; id++, mask <<= 1)
if (GPIO_FIRED(mask)) {
+ gpioCount[id]++;
postEvent(id);
- GPIO_DISABLE(mask);
}
WAKEUP();
}
* tickHandler - the address of the user's tick handler that will be called
*
* Returns:
- * None
+ * Future clock when handler will be called
*
* Side Effects:
* tickhandler called by the idle loop
*
**/
-extern void Hal_tickStart(uint16_t msecs, Hal_Handler Handler);
+extern uint16_t Hal_tickStart(uint16_t msecs, void (*handler)(uint16_t clock));
extern void Hal_tickStop(void);
+/**
+ * --------- Hal_gpioCount ---------
+ *
+ * Returns the number of interrups encounted on gpio `id`
+ *
+ * Inputs:
+ * id if the gpio (0-2 for gpio 3-5)
+ *
+ * Returns:
+ * Counted interrupts
+ *
+ * Side Effects:
+ * Resets the accumulator (counting restarts from zero).
+ *
+ **/
+extern uint32_t Hal_gpioCount(uint8_t id);
+
#ifdef __cplusplus
}
#endif
projects / pulsecounter.git / commitdiff