rtt-f030/bsp/lpc824/Libraries/peri_driver/spi/spi_8xx.c

551 lines
15 KiB
C

/*
* @brief LPC8xx SPI driver
*
* @note
* Copyright(C) NXP Semiconductors, 2012
* All rights reserved.
*
* @par
* Software that is described herein is for illustrative purposes only
* which provides customers with programming information regarding the
* LPC products. This software is supplied "AS IS" without any warranties of
* any kind, and NXP Semiconductors and its licenser disclaim any and
* all warranties, express or implied, including all implied warranties of
* merchantability, fitness for a particular purpose and non-infringement of
* intellectual property rights. NXP Semiconductors assumes no responsibility
* or liability for the use of the software, conveys no license or rights under any
* patent, copyright, mask work right, or any other intellectual property rights in
* or to any products. NXP Semiconductors reserves the right to make changes
* in the software without notification. NXP Semiconductors also makes no
* representation or warranty that such application will be suitable for the
* specified use without further testing or modification.
*
* @par
* Permission to use, copy, modify, and distribute this software and its
* documentation is hereby granted, under NXP Semiconductors' and its
* licensor's relevant copyrights in the software, without fee, provided that it
* is used in conjunction with NXP Semiconductors microcontrollers. This
* copyright, permission, and disclaimer notice must appear in all copies of
* this code.
*/
#include "chip.h"
/*****************************************************************************
* Private types/enumerations/variables
****************************************************************************/
static volatile bool xmitOn;
static volatile bool deasserted;
/*****************************************************************************
* Public types/enumerations/variables
****************************************************************************/
/*****************************************************************************
* Private functions
****************************************************************************/
STATIC void SPI_Send_Data_RxIgnore(LPC_SPI_T *pSPI,
SPI_DATA_SETUP_T *pXfSetup)
{
if (pXfSetup->TxCnt == (pXfSetup->Length - 1)) {
Chip_SPI_SendLastFrame_RxIgnore(pSPI, pXfSetup->pTx[pXfSetup->TxCnt], pXfSetup->DataSize);
}
else {
Chip_SPI_SendMidFrame(pSPI, pXfSetup->pTx[pXfSetup->TxCnt]);
}
pXfSetup->TxCnt++;
}
STATIC void SPI_Send_Data(LPC_SPI_T *pSPI,
SPI_DATA_SETUP_T *pXfSetup)
{
if (pXfSetup->TxCnt == (pXfSetup->Length - 1)) {
Chip_SPI_SendLastFrame(pSPI, pXfSetup->pTx[pXfSetup->TxCnt], pXfSetup->DataSize);
}
else {
Chip_SPI_SendMidFrame(pSPI, pXfSetup->pTx[pXfSetup->TxCnt]);
}
pXfSetup->TxCnt++;
}
STATIC void SPI_Send_Dummy(LPC_SPI_T *pSPI,
SPI_DATA_SETUP_T *pXfSetup)
{
if (pXfSetup->RxCnt == (pXfSetup->Length - 1)) {
Chip_SPI_SendLastFrame(pSPI, 0x55, pXfSetup->DataSize);
}
else {
Chip_SPI_SendMidFrame(pSPI, 0x55);
}
}
STATIC void SPI_Receive_Data(LPC_SPI_T *pSPI,
SPI_DATA_SETUP_T *pXfSetup)
{
pXfSetup->pRx[pXfSetup->RxCnt] = Chip_SPI_ReceiveFrame(pSPI);
pXfSetup->RxCnt++;
}
/* Determine SSEL associated with the current data value */
STATIC uint8_t Chip_SPIS_FindSSEL(LPC_SPI_T *pSPI, uint32_t data)
{
int i;
uint8_t ssel = 0;
for (i = 0; i <= 3; i++) {
if ((data & SPI_RXDAT_RXSSELNUM_INACTIVE(i)) == 0) {
/* Signal is active on low */
ssel = (uint8_t) i;
}
}
return ssel;
}
/*****************************************************************************
* Public functions
****************************************************************************/
/* Calculate the Clock Rate Divider for SPI Peripheral */
uint32_t Chip_SPI_CalClkRateDivider(LPC_SPI_T *pSPI, uint32_t bitRate)
{
uint32_t SPIClk;
uint32_t DivVal = 1;
/* Get SPI clock rate */
SPIClk = Chip_Clock_GetSystemClockRate(); /*The peripheral clock for both SPIs is the system clock*/
DivVal = SPIClk / bitRate;
return DivVal;
}
/* Configure SPI Delay parameters */
void Chip_SPI_DelayConfig(LPC_SPI_T *pSPI, SPI_DELAY_CONFIG_T *pConfig)
{
uint32_t delayValue = SPI_DLY_PRE_DELAY(pConfig->PreDelay) |
SPI_DLY_POST_DELAY(pConfig->PostDelay) |
SPI_DLY_FRAME_DELAY(pConfig->FrameDelay);
if (pConfig->TransferDelay) {
delayValue |= SPI_DLY_TRANSFER_DELAY(pConfig->TransferDelay - 1);
}
pSPI->DLY = delayValue;
}
/* Disable/Enable Interrupt */
void Chip_SPI_Int_Cmd(LPC_SPI_T *pSPI, uint32_t IntMask, FunctionalState NewState)
{
if (NewState == ENABLE) {
pSPI->INTENSET = IntMask;
}
else {
pSPI->INTENCLR = IntMask;
}
}
/*Send and Receive SPI Data */
uint32_t Chip_SPI_RWFrames_Blocking(LPC_SPI_T *pSPI, SPI_DATA_SETUP_T *pXfSetup)
{
uint32_t Status;
/* Clear status */
Chip_SPI_ClearStatus(pSPI, SPI_STAT_CLR_RXOV | SPI_STAT_CLR_TXUR | SPI_STAT_CLR_SSA | SPI_STAT_CLR_SSD);
Chip_SPI_SetControlInfo(pSPI, pXfSetup->DataSize, SPI_TXCTL_ASSERT_SSEL | SPI_TXCTL_EOF);
pXfSetup->TxCnt = pXfSetup->RxCnt = 0;
while ((pXfSetup->TxCnt < pXfSetup->Length) ||
(pXfSetup->RxCnt < pXfSetup->Length)) {
Status = Chip_SPI_GetStatus(pSPI);
/* In case of TxReady */
if ((Status & SPI_STAT_TXRDY) && (pXfSetup->TxCnt < pXfSetup->Length)) {
SPI_Send_Data(pSPI, pXfSetup);
}
/*In case of Rx ready */
if ((Status & SPI_STAT_RXRDY) && (pXfSetup->RxCnt < pXfSetup->Length)) {
SPI_Receive_Data(pSPI, pXfSetup);
}
}
/* Check error */
if (Chip_SPI_GetStatus(pSPI) & (SPI_STAT_CLR_RXOV | SPI_STAT_CLR_TXUR)) {
return 0;
}
return pXfSetup->TxCnt;
}
uint32_t Chip_SPI_WriteFrames_Blocking(LPC_SPI_T *pSPI, SPI_DATA_SETUP_T *pXfSetup)
{
/* Clear status */
Chip_SPI_ClearStatus(pSPI, SPI_STAT_CLR_RXOV | SPI_STAT_CLR_TXUR | SPI_STAT_CLR_SSA | SPI_STAT_CLR_SSD);
Chip_SPI_SetControlInfo(pSPI, pXfSetup->DataSize, SPI_TXCTL_ASSERT_SSEL | SPI_TXCTL_EOF | SPI_TXCTL_RXIGNORE);
pXfSetup->TxCnt = pXfSetup->RxCnt = 0;
while (pXfSetup->TxCnt < pXfSetup->Length) {
/* Wait for TxReady */
while (!(Chip_SPI_GetStatus(pSPI) & SPI_STAT_TXRDY)) {}
SPI_Send_Data_RxIgnore(pSPI, pXfSetup);
}
/* Make sure the last frame sent completely*/
while (!(Chip_SPI_GetStatus(pSPI) & SPI_STAT_SSD)) {}
Chip_SPI_ClearStatus(pSPI, SPI_STAT_CLR_SSD);
/* Check overrun error */
if (Chip_SPI_GetStatus(pSPI) & SPI_STAT_CLR_TXUR) {
return 0;
}
return pXfSetup->TxCnt;
}
uint32_t Chip_SPI_ReadFrames_Blocking(LPC_SPI_T *pSPI, SPI_DATA_SETUP_T *pXfSetup)
{
/* Clear status */
Chip_SPI_ClearStatus(pSPI, SPI_STAT_CLR_RXOV | SPI_STAT_CLR_TXUR | SPI_STAT_CLR_SSA | SPI_STAT_CLR_SSD);
Chip_SPI_SetControlInfo(pSPI, pXfSetup->DataSize, SPI_TXCTL_ASSERT_SSEL | SPI_TXCTL_EOF);
pXfSetup->TxCnt = pXfSetup->RxCnt = 0;
while (pXfSetup->RxCnt < pXfSetup->Length) {
/* Wait for TxReady */
while (!(Chip_SPI_GetStatus(pSPI) & SPI_STAT_TXRDY)) {}
SPI_Send_Dummy(pSPI, pXfSetup);
/* Wait for receive data */
while (!(Chip_SPI_GetStatus(pSPI) & SPI_STAT_RXRDY)) {}
SPI_Receive_Data(pSPI, pXfSetup);
}
/* Check overrun error */
if (Chip_SPI_GetStatus(pSPI) & (SPI_STAT_CLR_RXOV | SPI_STAT_CLR_TXUR)) {
return 0;
}
return pXfSetup->RxCnt;
}
/* SPI Interrupt Read/Write with 8-bit frame width */
Status Chip_SPI_Int_RWFrames(LPC_SPI_T *pSPI, SPI_DATA_SETUP_T *pXfSetup)
{
uint32_t Status;
Status = Chip_SPI_GetStatus(pSPI);
/* Check error in INTSTAT register */
if (Status & (SPI_STAT_RXOV | SPI_STAT_TXUR)) {
return ERROR;
}
if (pXfSetup->TxCnt == 0) {
Chip_SPI_SetControlInfo(pSPI, pXfSetup->DataSize, SPI_TXCTL_ASSERT_SSEL | SPI_TXCTL_EOF);
}
if (pXfSetup->pRx == NULL) {
if ((Status & SPI_STAT_TXRDY) && (pXfSetup->TxCnt < pXfSetup->Length)) {
SPI_Send_Data_RxIgnore(pSPI, pXfSetup);
}
}
else {
/* check if Tx ready */
if ((Status & SPI_STAT_TXRDY) && (pXfSetup->TxCnt < pXfSetup->Length)) {
SPI_Send_Data(pSPI, pXfSetup);
}
/* check if RX FIFO contains data */
if ((Status & SPI_STAT_RXRDY) && (pXfSetup->RxCnt < pXfSetup->Length)) {
SPI_Receive_Data(pSPI, pXfSetup);
}
}
return SUCCESS;
}
/* Get SPI master bit rate */
uint32_t Chip_SPIM_GetClockRate(LPC_SPI_T *pSPI)
{
return Chip_Clock_GetSystemClockRate() / ((pSPI->DIV & ~SPI_DIV_RESERVED) + 1);
}
/* Set SPI master bit rate */
uint32_t Chip_SPIM_SetClockRate(LPC_SPI_T *pSPI, uint32_t rate)
{
uint32_t baseClock, div;
/* Get peripheral base clock rate */
baseClock = Chip_Clock_GetSystemClockRate();
/* Compute divider */
div = baseClock / rate;
/* Limit values */
if (div == 0) {
div = 1;
}
else if (div > 0x10000) {
div = 0x10000;
}
pSPI->DIV = div - 1;
return Chip_SPIM_GetClockRate(pSPI);
}
/* Configure SPI Delay parameters */
void Chip_SPIM_DelayConfig(LPC_SPI_T *pSPI, SPIM_DELAY_CONFIG_T *pConfig)
{
pSPI->DLY = (SPI_DLY_PRE_DELAY(pConfig->PreDelay) |
SPI_DLY_POST_DELAY(pConfig->PostDelay) |
SPI_DLY_FRAME_DELAY(pConfig->FrameDelay) |
SPI_DLY_TRANSFER_DELAY(pConfig->TransferDelay - 1));
}
/* Assert a SPI select */
void Chip_SPIM_AssertSSEL(LPC_SPI_T *pSPI, uint8_t sselNum)
{
uint32_t reg;
reg = pSPI->TXCTRL & SPI_TXDATCTL_CTRLMASK;
/* Assert a SSEL line by driving it low */
reg &= ~SPI_TXDATCTL_DEASSERTNUM_SSEL(sselNum);
pSPI->TXCTRL = reg;
}
/* Deassert a SPI select */
void Chip_SPIM_DeAssertSSEL(LPC_SPI_T *pSPI, uint8_t sselNum)
{
uint32_t reg;
reg = pSPI->TXCTRL & SPI_TXDATCTL_CTRLMASK;
pSPI->TXCTRL = reg | SPI_TXDATCTL_DEASSERTNUM_SSEL(sselNum);
}
/* SPI master transfer state change handler */
void Chip_SPIM_XferHandler(LPC_SPI_T *pSPI, SPIM_XFER_T *xfer)
{
uint32_t data;
uint8_t flen;
/* Get length of a receive value */
flen = ((pSPI->TXCTRL & ~SPI_TXCTRL_RESERVED) >> 24) & 0xF;
/* Master asserts slave */
if ((Chip_SPI_GetStatus(pSPI) & SPI_STAT_SSA) != 0) {
Chip_SPI_ClearStatus(pSPI, SPI_STAT_SSA);
/* SSEL assertion callback */
xfer->pCB->masterXferCSAssert(xfer);
}
/* Slave de-assertion */
if ((Chip_SPI_GetStatus(pSPI) & SPI_STAT_SSD) != 0) {
Chip_SPI_ClearStatus(pSPI, SPI_STAT_SSD);
/* If transmitter disabled and deassert happens, the transfer is done */
if (xmitOn == false) {
xfer->pCB->mMasterXferDone(xfer);
}
}
/* Transmit data? */
while (((Chip_SPI_GetStatus(pSPI) & SPI_STAT_TXRDY) != 0) && (xmitOn == true)) {
if ((xfer->txCount == 1) && (xfer->terminate)) {
/* Transfer is done, this will be last data */
Chip_SPIM_ForceEndOfTransfer(pSPI);
xmitOn = false;
}
else if (xfer->txCount == 0) {
/* Request a new buffer first */
xfer->pCB->masterXferSend(xfer);
}
if (xfer->txCount > 0) {
/* Send 0 if ignoring transmit */
if (xfer->pTXData8 == NULL) {
data = 0;
}
else {
/* Copy buffer to data */
if (flen > 8) {
data = (uint32_t) *xfer->pTXData16;
xfer->pTXData16++;
}
else {
data = (uint32_t) *xfer->pTXData8;
xfer->pTXData8++;
}
xfer->dataTXferred++;
}
Chip_SPI_WriteTXData(pSPI, data);
xfer->txCount--;
}
}
/* Data received? */
while ((Chip_SPI_GetStatus(pSPI) & SPI_STAT_RXRDY) != 0) {
/* Get raw data and status */
data = Chip_SPI_ReadRawRXFifo(pSPI);
/* Only copy data when not ignoring receive */
if (xfer->pRXData8 != NULL) {
/* Enough size in current buffers? */
if (xfer->rxCount == 0) {
/* Request a new buffer first */
xfer->pCB->masterXferRecv(xfer);
}
/* Copy data to buffer */
if (xfer->rxCount > 0) {
if (flen > 8) {
*xfer->pRXData16 = (uint16_t) (data & 0xFFFF);
xfer->pRXData16++;
}
else {
*xfer->pRXData8 = (uint8_t) (data & 0xFF);
xfer->pRXData8++;
}
xfer->dataRXferred++;
xfer->rxCount--;
}
}
}
}
/* Start non-blocking SPI master transfer */
void Chip_SPIM_Xfer(LPC_SPI_T *pSPI, SPIM_XFER_T *xfer)
{
/* Setup SPI master select, data length, EOT/EOF timing, and RX data ignore */
pSPI->TXCTRL = xfer->options | SPI_TXDATCTL_DEASSERT_ALL;
Chip_SPIM_AssertSSEL(pSPI, xfer->sselNum);
/* Clear initial transfer states */
xfer->dataRXferred = xfer->dataTXferred = 0;
/* Call main handler to start transfer */
xmitOn = true;
Chip_SPIM_XferHandler(pSPI, xfer);
}
/* Perform blocking SPI master transfer */
void Chip_SPIM_XferBlocking(LPC_SPI_T *pSPI, SPIM_XFER_T *xfer)
{
/* Start trasnfer */
Chip_SPIM_Xfer(pSPI, xfer);
/* Wait for termination */
while (xmitOn == true) {
Chip_SPIM_XferHandler(pSPI, xfer);
}
}
/* SPI slave transfer state change handler */
uint32_t Chip_SPIS_XferHandler(LPC_SPI_T *pSPI, SPIS_XFER_T *xfer)
{
uint32_t staterr, data;
uint8_t flen;
/* Get length of a receive value */
flen = ((pSPI->TXCTRL & ~SPI_TXCTRL_RESERVED) >> 24) & 0xF;
/* Get errors for later, we'll continue even if errors occur, but we notify
caller on return */
staterr = Chip_SPI_GetStatus(pSPI) & (SPI_STAT_RXOV | SPI_STAT_TXUR);
if (staterr != 0) {
Chip_SPI_ClearStatus(pSPI, staterr);
}
/* Slave assertion */
if ((Chip_SPI_GetStatus(pSPI) & SPI_STAT_SSA) != 0) {
Chip_SPI_ClearStatus(pSPI, SPI_STAT_SSA);
/* Determine SPI select. Read the data FIFO to get the slave number. Data
should not be in the receive FIFO yet, only the statuses */
xfer->sselNum = Chip_SPIS_FindSSEL(pSPI, Chip_SPI_ReadRawRXFifo(pSPI));
/* SSEL assertion callback */
xfer->pCB->slaveXferCSAssert(xfer);
}
/* Slave de-assertion */
if ((Chip_SPI_GetStatus(pSPI) & SPI_STAT_SSD) != 0) {
Chip_SPI_ClearStatus(pSPI, SPI_STAT_SSD);
deasserted = true;
xfer->pCB->slaveXferCSDeAssert(xfer);
}
/* Transmit data? */
while ((Chip_SPI_GetStatus(pSPI) & SPI_STAT_TXRDY) != 0) {
if (xfer->txCount == 0) {
/* Request a new buffer first */
xfer->pCB->slaveXferSend(xfer);
}
/* Send 0 on empty buffer or count */
if ((xfer->txCount == 0) || (xfer->pTXData8 == NULL)) {
data = 0;
}
else {
/* Copy buffer to data */
if (flen > 8) {
data = (uint32_t) *xfer->pTXData16;
xfer->pTXData16++;
}
else {
data = (uint32_t) *xfer->pTXData8;
xfer->pTXData8++;
}
xfer->dataTXferred++;
xfer->txCount--;
}
Chip_SPI_WriteTXData(pSPI, data);
}
/* Data received? */
while ((Chip_SPI_GetStatus(pSPI) & SPI_STAT_RXRDY) != 0) {
/* Get raw data and status */
data = Chip_SPI_ReadRawRXFifo(pSPI);
/* Only copy data when not ignoring receive */
if (xfer->pRXData8 != NULL) {
/* Enough size in current buffers? */
if (xfer->rxCount == 0) {
/* Request a new buffer first */
xfer->pCB->slaveXferRecv(xfer);
}
/* Copy data to buffer */
if (flen > 8) {
*xfer->pRXData16 = (uint16_t) (data & 0xFFFF);
xfer->pRXData16++;
}
else {
*xfer->pRXData8 = (uint8_t) (data & 0xFF);
xfer->pRXData8++;
}
xfer->dataRXferred++;
xfer->rxCount--;
}
}
return staterr;
}
/* SPI slave transfer blocking function */
uint32_t Chip_SPIS_XferBlocking(LPC_SPI_T *pSPI, SPIS_XFER_T *xfer)
{
uint32_t status = 0;
/* Wait forever until deassertion event */
deasserted = false;
while ((!deasserted) && (status == 0)) {
status = Chip_SPIS_XferHandler(pSPI, xfer);
}
return status;
}