📄 bsp.c
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/*
*********************************************************************************************************
* LED OFF
*
* Description : This function is used to control any or all the LEDs on the board.
*
* Arguments : led is the number of the LED to turn OFF
* 0 indicates that you want ALL the LEDs to be OFF
* 1 turns OFF LED1 on the board
* .
* .
* 16 turns OFF LED16 on the board
*********************************************************************************************************
*/
void LED_Off (CPU_INT08U led)
{
#if __VER__ == 420
switch (led) {
case 0:
IOCLR0 = 1 << 21;
break;
case 1:
IOCLR0 = 1 << 21;
break;
}
#else
switch (led) {
case 0:
IO0CLR = 1 << 21;
break;
case 1:
IO0CLR = 1 << 21;
break;
}
#endif
}
/*
*********************************************************************************************************
* LED TOGGLE
*
* Description : This function is used to toggle any or all the LEDs on the board.
*
* Arguments : led is the number of the LED to control
* 0 indicates that you want to toggle ALL the LEDs
* 1 toggles LED1 on the board
* .
* .
* 16 toggles LED16 on the board
*********************************************************************************************************
*/
void LED_Toggle (CPU_INT08U led)
{
CPU_INT32U are_on;
CPU_INT32U are_off;
#if __VER__ == 420
switch (led) {
case 0:
are_off = IOPIN0 ^ (1 << 21);
are_on = ~IOPIN0 ^ (1 << 21);
IOCLR0 = are_on;
IOSET0 = are_off;
break;
case 1:
if (IOPIN0 & (1 << 21)) {
IOCLR0 = 1 << 21;
} else {
IOSET0 = 1 << 21;
}
break;
}
#else
switch (led) {
case 0:
are_off = IO0PIN ^ (1 << 21);
are_on = ~IO0PIN ^ (1 << 21);
IO0CLR = are_on;
IO0SET = are_off;
break;
case 1:
if (IO0PIN & (1 << 21)) {
IO0CLR = 1 << 21;
} else {
IO0SET = 1 << 21;
}
break;
}
#endif
}
/*
*********************************************************************************************************
* INITIALIZE TIMER FOR uC/OS-View
*
* Description : This function is called to by uC/OS-View to initialize the free running timer that is
* used to make time measurements.
*
* Arguments : none
*
* Returns ; none
*
* Note(s) : This function is EMPTY because the timer is initialized elsewhere.
*********************************************************************************************************
*/
#if OS_VIEW_MODULE > 0
void OSView_TmrInit (void)
{
/* TIMER #1 Initialization */
T1TCR = 0; /* Disable timer 1. */
T1PC = 0; /* Prescaler is set to no division. */
T1TCR = 1; /* Enable timer 1 */
}
#endif
/*
*********************************************************************************************************
* READ TIMER FOR uC/OS-View
*
* Description : This function is called to read the current counts of a 32 bit free running timer.
*
* Timer #0 of the LPC2000 is used. This is an UP-timer.
*
* Arguments : none
*
* Returns ; The 32 bit counts of the timer assuming the timer (MUST be an UP counter).
*********************************************************************************************************
*/
#if OS_VIEW_MODULE > 0
INT32U OSView_TmrRd (void)
{
return ((CPU_INT32U)T1TC);
}
#endif
/*
*********************************************************************************************************
* TICKER INITIALIZATION
*
* Description : This function is called to initialize uC/OS-II's tick source (typically a timer generating
* interrupts every 1 to 100 mS).
*
* Arguments : none
*
* Note(s) : 1) The timer is setup for output compare mode BUT 'MUST' also 'freerun' so that the timer
* count goes from 0x00000000 to 0xFFFFFFFF to ALSO be able to read the free running count.
* The reason this is needed is because we use the free-running count in uC/OS-View.
*********************************************************************************************************
*/
static void Tmr_TickInit (void)
{
CPU_INT32U peripheral_clk_freq;
/* VIC TIMER #0 Initialization */
VICIntSelect &= ~(1 << VIC_TIMER0); /* Enable interrupts */
VICVectAddr2 = (CPU_INT32U)Tmr_TickISR_Handler; /* Set the vector address */
VICVectCntl2 = 0x20 | VIC_TIMER0; /* Enable vectored interrupts */
VICIntEnable = (1 << VIC_TIMER0); /* Enable Interrupts */
peripheral_clk_freq = BSP_CPU_ClkFreqPeripheral();
Tmr_ReloadCnts = peripheral_clk_freq / OS_TICKS_PER_SEC;
T0TCR = 0; /* Disable timer 0. */
T0PC = 0; /* Prescaler is set to no division. */
T0MR0 = Tmr_ReloadCnts;
T0MCR = 3; /* Interrupt on MR0 (reset TC) */
T0CCR = 0; /* Capture is disabled. */
T0EMR = 0; /* No external match output. */
T0TCR = 1; /* Enable timer 0 */
}
/*
*********************************************************************************************************
* TIMER #0 IRQ HANDLER
*
* Description : This function handles the timer interrupt that is used to generate TICKs for uC/OS-II.
*
* Arguments : none
*
* Note(s) : 1) The timer is 'reloaded' with the count at compare + the time for the next interrupt.
* Since we are using 'unsigned' integer math, overflows are irrelevant.
*********************************************************************************************************
*/
void Tmr_TickISR_Handler (void)
{
T0IR = 0xFF; /* Clear timer #0 interrupt */
/* Reload 'relative' to current interrupt time */
VICVectAddr = 0;
OSTimeTick(); /* Call uC/OS-II's OSTimeTick() */
}
/*
*********************************************************************************************************
* Vectored Interrupt Controller
*********************************************************************************************************
*/
static void VIC_Init (void)
{
VICIntEnClear = 0xFFFFFFFF; /* Disable ALL interrupts */
VICProtection = 0; /* Setup interrupt controller */
VICVectAddr1 = (CPU_INT32U)VIC_DummyWDT; /* Set the vector address */
VICVectAddr2 = (CPU_INT32U)VIC_DummyTIMER0;
VICVectAddr3 = (CPU_INT32U)VIC_DummyTIMER1;
VICVectAddr4 = (CPU_INT32U)VIC_DummyUART0;
VICVectAddr5 = (CPU_INT32U)VIC_DummyUART1;
VICVectAddr6 = (CPU_INT32U)VIC_DummyPWM0;
VICVectAddr7 = (CPU_INT32U)VIC_DummyI2C;
VICVectAddr8 = (CPU_INT32U)VIC_DummySPI;
VICVectAddr9 = (CPU_INT32U)VIC_DummyRTC;
VICVectAddr10 = (CPU_INT32U)VIC_DummyEINT0;
VICVectAddr11 = (CPU_INT32U)VIC_DummyEINT1;
VICVectAddr12 = (CPU_INT32U)VIC_DummyEINT2;
}
static void VIC_Dummy (void)
{
while (1) {
(void)VIC_SpuriousInt;
}
}
static void VIC_DummyWDT (void)
{
VIC_SpuriousInt = VIC_WDT;
VIC_Dummy();
}
static void VIC_DummyTIMER0 (void)
{
VIC_SpuriousInt = VIC_TIMER0;
VIC_Dummy();
}
static void VIC_DummyTIMER1 (void)
{
VIC_SpuriousInt = VIC_TIMER1;
VIC_Dummy();
}
static void VIC_DummyUART0 (void)
{
VIC_SpuriousInt = VIC_UART0;
VIC_Dummy();
}
static void VIC_DummyUART1 (void)
{
VIC_SpuriousInt = VIC_UART1;
VIC_Dummy();
}
static void VIC_DummyPWM0 (void)
{
VIC_SpuriousInt = VIC_UART1;
VIC_Dummy();
}
static void VIC_DummyI2C (void)
{
VIC_SpuriousInt = VIC_I2C;
VIC_Dummy();
}
static void VIC_DummySPI (void)
{
VIC_SpuriousInt = VIC_SPI;
VIC_Dummy();
}
static void VIC_DummyRTC (void)
{
VIC_SpuriousInt = VIC_RTC;
VIC_Dummy();
}
static void VIC_DummyEINT0 (void)
{
VIC_SpuriousInt = VIC_EINT0;
VIC_Dummy();
}
static void VIC_DummyEINT1 (void)
{
VIC_SpuriousInt = VIC_EINT1;
VIC_Dummy();
}
static void VIC_DummyEINT2 (void)
{
VIC_SpuriousInt = VIC_EINT2;
VIC_Dummy();
}
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