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//* ----------------------------------------------------------------------------
//* ATMEL Microcontroller Software Support - ROUSSET -
//* ----------------------------------------------------------------------------
//* DISCLAIMER: THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR
//* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
//* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
//* DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR ANY DIRECT, INDIRECT,
//* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
//* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA,
//* OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
//* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
//* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
//* EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
//* ----------------------------------------------------------------------------
//* File Name : lib_AT91SAM7S64.h
//* Object : AT91SAM7S64 inlined functions
//* Generated : AT91 SW Application Group 08/30/2005 (15:52:59)
//*
#include <sys/types.h>
#include <include/AT91SAM7.h>
#include <include/lib_AT91SAM7.h>
//*----------------------------------------------------------------------------
//* \fn AT91F_AIC_ConfigureIt
//* \brief Interrupt Handler Initialization
//*----------------------------------------------------------------------------
unsigned int AT91F_AIC_ConfigureIt (
AT91PS_AIC pAic, // \arg pointer to the AIC registers
unsigned int irq_id, // \arg interrupt number to initialize
unsigned int priority, // \arg priority to give to the interrupt
unsigned int src_type, // \arg activation and sense of activation
void (*newHandler) () ) // \arg address of the interrupt handler
{
unsigned int oldHandler;
unsigned int mask ;
oldHandler = pAic->AIC_SVR[irq_id];
mask = 0x1 << irq_id ;
//* Disable the interrupt on the interrupt controller
pAic->AIC_IDCR = mask ;
//* Save the interrupt handler routine pointer and the interrupt priority
pAic->AIC_SVR[irq_id] = (unsigned int) newHandler ;
//* Store the Source Mode Register
pAic->AIC_SMR[irq_id] = src_type | priority ;
//* Clear the interrupt on the interrupt controller
pAic->AIC_ICCR = mask ;
return oldHandler;
}
//*----------------------------------------------------------------------------
//* \fn AT91F_AIC_SetExceptionVector
//* \brief Configure vector handler
//*----------------------------------------------------------------------------
unsigned int AT91F_AIC_SetExceptionVector (
unsigned int *pVector, // \arg pointer to the AIC registers
void (*Handler) () ) // \arg Interrupt Handler
{
unsigned int oldVector = *pVector;
if ((unsigned int) Handler == (unsigned int) AT91C_AIC_BRANCH_OPCODE)
*pVector = (unsigned int) AT91C_AIC_BRANCH_OPCODE;
else
*pVector = (((((unsigned int) Handler) - ((unsigned int) pVector) - 0x8) >> 2) & 0x00FFFFFF) | 0xEA000000;
return oldVector;
}
//*----------------------------------------------------------------------------
//* \fn AT91F_AIC_Open
//* \brief Set exception vectors and AIC registers to default values
//*----------------------------------------------------------------------------
void AT91F_AIC_Open(
AT91PS_AIC pAic, // \arg pointer to the AIC registers
void (*IrqHandler) (), // \arg Default IRQ vector exception
void (*FiqHandler) (), // \arg Default FIQ vector exception
void (*DefaultHandler) (), // \arg Default Handler set in ISR
void (*SpuriousHandler) (), // \arg Default Spurious Handler
unsigned int protectMode) // \arg Debug Control Register
{
int i;
// Disable all interrupts and set IVR to the default handler
for (i = 0; i < 32; ++i) {
AT91F_AIC_DisableIt(pAic, i);
AT91F_AIC_ConfigureIt(pAic, i, AT91C_AIC_PRIOR_LOWEST, AT91C_AIC_SRCTYPE_HIGH_LEVEL, DefaultHandler);
}
// Set the IRQ exception vector
AT91F_AIC_SetExceptionVector((unsigned int *) 0x18, IrqHandler);
// Set the Fast Interrupt exception vector
AT91F_AIC_SetExceptionVector((unsigned int *) 0x1C, FiqHandler);
pAic->AIC_SPU = (unsigned int) SpuriousHandler;
pAic->AIC_DCR = protectMode;
}
//*----------------------------------------------------------------------------
//* \fn AT91F_PDC_Open
//* \brief Open PDC: disable TX and RX reset transfer descriptors, re-enable RX and TX
//*----------------------------------------------------------------------------
void AT91F_PDC_Open(AT91PS_PDC pPDC) // \arg pointer to a PDC controller
{
//* Disable the RX and TX PDC transfer requests
AT91F_PDC_DisableRx(pPDC);
AT91F_PDC_DisableTx(pPDC);
//* Reset all Counter register Next buffer first
AT91F_PDC_SetNextTx(pPDC, NULL, 0);
AT91F_PDC_SetNextRx(pPDC, NULL, 0);
AT91F_PDC_SetTx(pPDC, NULL, 0);
AT91F_PDC_SetRx(pPDC, NULL, 0);
//* Enable the RX and TX PDC transfer requests
AT91F_PDC_EnableRx(pPDC);
AT91F_PDC_EnableTx(pPDC);
}
//*----------------------------------------------------------------------------
//* \fn AT91F_PDC_Close
//* \brief Close PDC: disable TX and RX reset transfer descriptors
//*----------------------------------------------------------------------------
void AT91F_PDC_Close(AT91PS_PDC pPDC) // \arg pointer to a PDC controller
{
//* Disable the RX and TX PDC transfer requests
AT91F_PDC_DisableRx(pPDC);
AT91F_PDC_DisableTx(pPDC);
//* Reset all Counter register Next buffer first
AT91F_PDC_SetNextTx(pPDC, NULL, 0);
AT91F_PDC_SetNextRx(pPDC, NULL, 0);
AT91F_PDC_SetTx(pPDC, NULL, 0);
AT91F_PDC_SetRx(pPDC, NULL, 0);
}
//*----------------------------------------------------------------------------
//* \fn AT91F_PDC_SendFrame
//* \brief Close PDC: disable TX and RX reset transfer descriptors
//*----------------------------------------------------------------------------
unsigned int AT91F_PDC_SendFrame(
AT91PS_PDC pPDC,
const unsigned char *pBuffer,
unsigned int szBuffer,
const unsigned char *pNextBuffer,
unsigned int szNextBuffer )
{
if (AT91F_PDC_IsTxEmpty(pPDC)) {
//* Buffer and next buffer can be initialized
AT91F_PDC_SetTx(pPDC, pBuffer, szBuffer);
AT91F_PDC_SetNextTx(pPDC, pNextBuffer, szNextBuffer);
return 2;
}
else if (AT91F_PDC_IsNextTxEmpty(pPDC)) {
//* Only one buffer can be initialized
AT91F_PDC_SetNextTx(pPDC, pBuffer, szBuffer);
return 1;
}
else {
//* All buffer are in use...
return 0;
}
}
//*----------------------------------------------------------------------------
//* \fn AT91F_PDC_ReceiveFrame
//* \brief Close PDC: disable TX and RX reset transfer descriptors
//*----------------------------------------------------------------------------
unsigned int AT91F_PDC_ReceiveFrame (
AT91PS_PDC pPDC,
unsigned char *pBuffer,
unsigned int szBuffer,
unsigned char *pNextBuffer,
unsigned int szNextBuffer )
{
if (AT91F_PDC_IsRxEmpty(pPDC)) {
//* Buffer and next buffer can be initialized
AT91F_PDC_SetRx(pPDC, pBuffer, szBuffer);
AT91F_PDC_SetNextRx(pPDC, pNextBuffer, szNextBuffer);
return 2;
}
else if (AT91F_PDC_IsNextRxEmpty(pPDC)) {
//* Only one buffer can be initialized
AT91F_PDC_SetNextRx(pPDC, pBuffer, szBuffer);
return 1;
}
else {
//* All buffer are in use...
return 0;
}
}
//*------------------------------------------------------------------------------
//* \fn AT91F_PMC_GetMasterClock
//* \brief Return master clock in Hz which correponds to processor clock for ARM7
//*------------------------------------------------------------------------------
unsigned int AT91F_PMC_GetMasterClock (
AT91PS_PMC pPMC, // \arg pointer to PMC controller
AT91PS_CKGR pCKGR, // \arg pointer to CKGR controller
unsigned int slowClock) // \arg slowClock in Hz
{
unsigned int reg = pPMC->PMC_MCKR;
unsigned int prescaler = (1 << ((reg & AT91C_PMC_PRES) >> 2));
unsigned int pllDivider, pllMultiplier;
switch (reg & AT91C_PMC_CSS) {
case AT91C_PMC_CSS_SLOW_CLK: // Slow clock selected
return slowClock / prescaler;
case AT91C_PMC_CSS_MAIN_CLK: // Main clock is selected
return AT91F_CKGR_GetMainClock(pCKGR, slowClock) / prescaler;
case AT91C_PMC_CSS_PLL_CLK: // PLLB clock is selected
reg = pCKGR->CKGR_PLLR;
pllDivider = (reg & AT91C_CKGR_DIV);
pllMultiplier = ((reg & AT91C_CKGR_MUL) >> 16) + 1;
return AT91F_CKGR_GetMainClock(pCKGR, slowClock) / pllDivider * pllMultiplier / prescaler;
}
return 0;
}
//*--------------------------------------------------------------------------------------
//* \fn AT91F_RTT_ReadValue()
//* \brief Read the RTT value
//*--------------------------------------------------------------------------------------
unsigned int AT91F_RTTReadValue(AT91PS_RTTC pRTTC)
{
register volatile unsigned int val1,val2;
do
{
val1 = pRTTC->RTTC_RTVR;
val2 = pRTTC->RTTC_RTVR;
}
while(val1 != val2);
return(val1);
}
//*----------------------------------------------------------------------------
//* \fn AT91F_SPI_Close
//* \brief Close SPI: disable IT disable transfert, close PDC
//*----------------------------------------------------------------------------
void AT91F_SPI_Close(AT91PS_SPI pSPI) // \arg pointer to a SPI controller
{
//* Reset all the Chip Select register
pSPI->SPI_CSR[0] = 0 ;
pSPI->SPI_CSR[1] = 0 ;
pSPI->SPI_CSR[2] = 0 ;
pSPI->SPI_CSR[3] = 0 ;
//* Reset the SPI mode
pSPI->SPI_MR = 0 ;
//* Disable all interrupts
pSPI->SPI_IDR = 0xFFFFFFFF ;
//* Abort the Peripheral Data Transfers
AT91F_PDC_Close((AT91PS_PDC) &(pSPI->SPI_RPR));
//* Disable receiver and transmitter and stop any activity immediately
pSPI->SPI_CR = AT91C_SPI_SPIDIS;
}
//*----------------------------------------------------------------------------
//* \fn AT91F_ADC_CfgTimings
//* \brief Configure the different necessary timings of the ADC controller
//*----------------------------------------------------------------------------
void AT91F_ADC_CfgTimings (
AT91PS_ADC pADC, // pointer to a ADC controller
unsigned int mck_clock, // in MHz
unsigned int adc_clock, // in MHz
unsigned int startup_time, // in us
unsigned int sample_and_hold_time) // in ns
{
unsigned int prescal,startup,shtim;
prescal = mck_clock/(2*adc_clock) - 1;
startup = adc_clock*startup_time/8 - 1;
shtim = adc_clock*sample_and_hold_time/1000 - 1;
//* Write to the MR register
pADC->ADC_MR = ( (prescal<<8) & AT91C_ADC_PRESCAL) | ( (startup<<16) & AT91C_ADC_STARTUP) | ( (shtim<<24) & AT91C_ADC_SHTIM);
}
//*----------------------------------------------------------------------------
//* \fn AT91F_SSC_SetBaudrate
//* \brief Set the baudrate according to the CPU clock
//*----------------------------------------------------------------------------
void AT91F_SSC_SetBaudrate (
AT91PS_SSC pSSC, // \arg pointer to a SSC controller
unsigned int mainClock, // \arg peripheral clock
unsigned int speed) // \arg SSC baudrate
{
unsigned int baud_value;
//* Define the baud rate divisor register
if (speed == 0)
baud_value = 0;
else
{
baud_value = (unsigned int) (mainClock * 10)/(2*speed);
if ((baud_value % 10) >= 5)
baud_value = (baud_value / 10) + 1;
else
baud_value /= 10;
}
pSSC->SSC_CMR = baud_value;
}
//*----------------------------------------------------------------------------
//* \fn AT91F_SSC_Configure
//* \brief Configure SSC
//*----------------------------------------------------------------------------
void AT91F_SSC_Configure (
AT91PS_SSC pSSC, // \arg pointer to a SSC controller
unsigned int syst_clock, // \arg System Clock Frequency
unsigned int baud_rate, // \arg Expected Baud Rate Frequency
unsigned int clock_rx, // \arg Receiver Clock Parameters
unsigned int mode_rx, // \arg mode Register to be programmed
unsigned int clock_tx, // \arg Transmitter Clock Parameters
unsigned int mode_tx) // \arg mode Register to be programmed
{
//* Disable interrupts
pSSC->SSC_IDR = (unsigned int) -1;
//* Reset receiver and transmitter
pSSC->SSC_CR = AT91C_SSC_SWRST | AT91C_SSC_RXDIS | AT91C_SSC_TXDIS ;
//* Define the Clock Mode Register
AT91F_SSC_SetBaudrate(pSSC, syst_clock, baud_rate);
//* Write the Receive Clock Mode Register
pSSC->SSC_RCMR = clock_rx;
//* Write the Transmit Clock Mode Register
pSSC->SSC_TCMR = clock_tx;
//* Write the Receive Frame Mode Register
pSSC->SSC_RFMR = mode_rx;
//* Write the Transmit Frame Mode Register
pSSC->SSC_TFMR = mode_tx;
//* Clear Transmit and Receive Counters
AT91F_PDC_Open((AT91PS_PDC) &(pSSC->SSC_RPR));
}
//*----------------------------------------------------------------------------
//* \fn AT91F_US_Configure
//* \brief Configure USART
//*----------------------------------------------------------------------------
void AT91F_US_Configure (
AT91PS_USART pUSART, // \arg pointer to a USART controller
unsigned int mainClock, // \arg peripheral clock
unsigned int mode , // \arg mode Register to be programmed
unsigned int baudRate , // \arg baudrate to be programmed
unsigned int timeguard ) // \arg timeguard to be programmed
{
//* Disable interrupts
pUSART->US_IDR = (unsigned int) -1;
//* Reset receiver and transmitter
pUSART->US_CR = AT91C_US_RSTRX | AT91C_US_RSTTX | AT91C_US_RXDIS | AT91C_US_TXDIS ;
//* Define the baud rate divisor register
AT91F_US_SetBaudrate(pUSART, mainClock, baudRate);
//* Write the Timeguard Register
AT91F_US_SetTimeguard(pUSART, timeguard);
//* Clear Transmit and Receive Counters
AT91F_PDC_Open((AT91PS_PDC) &(pUSART->US_RPR));
//* Define the USART mode
pUSART->US_MR = mode ;
}
//*----------------------------------------------------------------------------
//* \fn AT91F_US_Close
//* \brief Close USART: disable IT disable receiver and transmitter, close PDC
//*----------------------------------------------------------------------------
void AT91F_US_Close(AT91PS_USART pUSART) // \arg pointer to a USART controller
{
//* Reset the baud rate divisor register
pUSART->US_BRGR = 0 ;
//* Reset the USART mode
pUSART->US_MR = 0 ;
//* Reset the Timeguard Register
pUSART->US_TTGR = 0;
//* Disable all interrupts
pUSART->US_IDR = 0xFFFFFFFF ;
//* Abort the Peripheral Data Transfers
AT91F_PDC_Close((AT91PS_PDC) &(pUSART->US_RPR));
//* Disable receiver and transmitter and stop any activity immediately
pUSART->US_CR = AT91C_US_TXDIS | AT91C_US_RXDIS | AT91C_US_RSTTX | AT91C_US_RSTRX ;
}
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