rt-thread-official/bsp/lpc408x/Libraries/Drivers/source/lpc_ssp.c

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2014-01-02 18:30:13 +08:00
/**********************************************************************
* $Id$ lpc_ssp.c 2011-06-02
*//**
* @file lpc_ssp.c
* @brief Contains all functions support for SSP firmware library
* on LPC
* @version 1.0
* @date 02. June. 2011
* @author NXP MCU SW Application Team
*
* Copyright(C) 2011, NXP Semiconductor
* All rights reserved.
*
***********************************************************************
* Software that is described herein is for illustrative purposes only
* which provides customers with programming information regarding the
* products. This software is supplied "AS IS" without any warranties.
* NXP Semiconductors assumes no responsibility or liability for the
* use of the software, conveys no license or title under any patent,
* copyright, or mask work right to the product. NXP Semiconductors
* reserves the right to make changes in the software without
* notification. NXP Semiconductors also make no representation or
* warranty that such application will be suitable for the specified
* use without further testing or modification.
* Permission to use, copy, modify, and distribute this software and its
* documentation is hereby granted, under NXP Semiconductors'
* relevant copyright 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.
**********************************************************************/
/* Peripheral group ----------------------------------------------------------- */
/** @addtogroup SSP
* @{
*/
#ifdef __BUILD_WITH_EXAMPLE__
#include "lpc_libcfg.h"
#else
#include "lpc_libcfg_default.h"
#endif /* __BUILD_WITH_EXAMPLE__ */
#ifdef _SSP
/* Includes ------------------------------------------------------------------- */
#include "lpc_ssp.h"
#include "lpc_clkpwr.h"
/* Public Functions ----------------------------------------------------------- */
/** @addtogroup SSP_Public_Functions
* @{
*/
static void setSSPclock (LPC_SSP_TypeDef *SSPx, uint32_t target_clock);
/*********************************************************************//**
* @brief Setup clock rate for SSP device
* @param[in] SSPx SSP peripheral definition, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @param[in] target_clock : clock of SSP (Hz)
* @return None
***********************************************************************/
static void setSSPclock (LPC_SSP_TypeDef *SSPx, uint32_t target_clock)
{
uint32_t prescale, cr0_div, cmp_clk, ssp_clk;
ssp_clk = CLKPWR_GetCLK (CLKPWR_CLKTYPE_PER);
/* Find closest divider to get at or under the target frequency.
Use smallest prescale possible and rely on the divider to get
the closest target frequency */
cr0_div = 0;
cmp_clk = 0xFFFFFFFF;
prescale = 2;
while (cmp_clk > target_clock)
{
cmp_clk = ssp_clk / ((cr0_div + 1) * prescale);
if (cmp_clk > target_clock)
{
cr0_div++;
if (cr0_div > 0xFF)
{
cr0_div = 0;
prescale += 2;
}
}
}
/* Write computed prescaler and divider back to register */
SSPx->CR0 &= (~SSP_CR0_SCR(0xFF)) & SSP_CR0_BITMASK;
SSPx->CR0 |= (SSP_CR0_SCR(cr0_div)) & SSP_CR0_BITMASK;
SSPx->CPSR = prescale & SSP_CPSR_BITMASK;
}
/**
* @}
*/
/* Public Functions ----------------------------------------------------------- */
/** @addtogroup SSP_Public_Functions
* @{
*/
/********************************************************************//**
* @brief Initializes the SSPx peripheral according to the specified
* parameters in the SSP_ConfigStruct.
* @param[in] SSPx SSP peripheral selected, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @param[in] SSP_ConfigStruct Pointer to a SSP_CFG_Type structure
* that contains the configuration information for the
* specified SSP peripheral.
* @return None
*********************************************************************/
void SSP_Init(LPC_SSP_TypeDef *SSPx, SSP_CFG_Type *SSP_ConfigStruct)
{
uint32_t tmp;
if(SSPx == LPC_SSP0) {
/* Set up clock and power for SSP0 module */
CLKPWR_ConfigPPWR (CLKPWR_PCONP_PCSSP0, ENABLE);
} else if(SSPx == LPC_SSP1) {
/* Set up clock and power for SSP1 module */
CLKPWR_ConfigPPWR (CLKPWR_PCONP_PCSSP1, ENABLE);
} else if(SSPx == LPC_SSP2) {
/* Set up clock and power for SSP1 module */
CLKPWR_ConfigPPWR (CLKPWR_PCONP_PCSSP2, ENABLE);
} else {
return;
}
/* Configure SSP, interrupt is disable, LoopBack mode is disable,
* SSP is disable, Slave output is disable as default
*/
tmp = ((SSP_ConfigStruct->CPHA) | (SSP_ConfigStruct->CPOL) \
| (SSP_ConfigStruct->FrameFormat) | (SSP_ConfigStruct->Databit))
& SSP_CR0_BITMASK;
// write back to SSP control register
SSPx->CR0 = tmp;
tmp = SSP_ConfigStruct->Mode & SSP_CR1_BITMASK;
// Write back to CR1
SSPx->CR1 = tmp;
// Set clock rate for SSP peripheral
setSSPclock(SSPx, SSP_ConfigStruct->ClockRate);
}
/*********************************************************************//**
* @brief De-initializes the SSPx peripheral registers to their
* default reset values.
* @param[in] SSPx SSP peripheral selected, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @return None
**********************************************************************/
void SSP_DeInit(LPC_SSP_TypeDef* SSPx)
{
if (SSPx == LPC_SSP0){
/* Set up clock and power for SSP0 module */
CLKPWR_ConfigPPWR (CLKPWR_PCONP_PCSSP0, DISABLE);
} else if (SSPx == LPC_SSP1) {
/* Set up clock and power for SSP1 module */
CLKPWR_ConfigPPWR (CLKPWR_PCONP_PCSSP1, DISABLE);
} else if (SSPx == LPC_SSP2) {
/* Set up clock and power for SSP1 module */
CLKPWR_ConfigPPWR (CLKPWR_PCONP_PCSSP2, DISABLE);
}
}
/*****************************************************************************//**
* @brief Get data size bit selected
* @param[in] SSPx pointer to LPC_SSP_TypeDef structure, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @return Data size, could be:
* - SSP_DATABIT_4: 4 bit transfer
* - SSP_DATABIT_5: 5 bit transfer
* ...
* - SSP_DATABIT_16: 16 bit transfer
*******************************************************************************/
uint8_t SSP_GetDataSize(LPC_SSP_TypeDef* SSPx)
{
return (SSPx->CR0 & (0xF));
}
/*****************************************************************************//**
* @brief Fills each SSP_InitStruct member with its default value:
* - CPHA = SSP_CPHA_FIRST
* - CPOL = SSP_CPOL_HI
* - ClockRate = 1000000
* - Databit = SSP_DATABIT_8
* - Mode = SSP_MASTER_MODE
* - FrameFormat = SSP_FRAME_SSP
* @param[in] SSP_InitStruct Pointer to a SSP_CFG_Type structure
* which will be initialized.
* @return None
*******************************************************************************/
void SSP_ConfigStructInit(SSP_CFG_Type *SSP_InitStruct)
{
SSP_InitStruct->CPHA = SSP_CPHA_FIRST;
SSP_InitStruct->CPOL = SSP_CPOL_HI;
SSP_InitStruct->ClockRate = 1000000;
SSP_InitStruct->Databit = SSP_DATABIT_8;
SSP_InitStruct->Mode = SSP_MASTER_MODE;
SSP_InitStruct->FrameFormat = SSP_FRAME_SPI;
}
/*********************************************************************//**
* @brief Enable or disable SSP peripheral's operation
* @param[in] SSPx SSP peripheral, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @param[in] NewState New State of SSPx peripheral's operation
* @return none
**********************************************************************/
void SSP_Cmd(LPC_SSP_TypeDef* SSPx, FunctionalState NewState)
{
if (NewState == ENABLE)
{
SSPx->CR1 |= SSP_CR1_SSP_EN;
}
else
{
SSPx->CR1 &= (~SSP_CR1_SSP_EN) & SSP_CR1_BITMASK;
}
}
/*********************************************************************//**
* @brief Enable or disable Loop Back mode function in SSP peripheral
* @param[in] SSPx SSP peripheral selected, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @param[in] NewState New State of Loop Back mode, should be:
* - ENABLE: Enable this function
* - DISABLE: Disable this function
* @return None
**********************************************************************/
void SSP_LoopBackCmd(LPC_SSP_TypeDef* SSPx, FunctionalState NewState)
{
if (NewState == ENABLE)
{
SSPx->CR1 |= SSP_CR1_LBM_EN;
}
else
{
SSPx->CR1 &= (~SSP_CR1_LBM_EN) & SSP_CR1_BITMASK;
}
}
/*********************************************************************//**
* @brief Enable or disable Slave Output function in SSP peripheral
* @param[in] SSPx SSP peripheral selected, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @param[in] NewState New State of Slave Output function, should be:
* - ENABLE: Slave Output in normal operation
* - DISABLE: Slave Output is disabled. This blocks
* SSP controller from driving the transmit data
* line (MISO)
* Note: This function is available when SSP peripheral in Slave mode
* @return None
**********************************************************************/
void SSP_SlaveOutputCmd(LPC_SSP_TypeDef* SSPx, FunctionalState NewState)
{
if (NewState == ENABLE)
{
SSPx->CR1 &= (~SSP_CR1_SO_DISABLE) & SSP_CR1_BITMASK;
}
else
{
SSPx->CR1 |= SSP_CR1_SO_DISABLE;
}
}
/*********************************************************************//**
* @brief Transmit a single data through SSPx peripheral
* @param[in] SSPx SSP peripheral selected, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @param[in] Data Data to transmit (must be 16 or 8-bit long,
* this depend on SSP data bit number configured)
* @return none
**********************************************************************/
void SSP_SendData(LPC_SSP_TypeDef* SSPx, uint16_t Data)
{
SSPx->DR = SSP_DR_BITMASK(Data);
}
/*********************************************************************//**
* @brief Receive a single data from SSPx peripheral
* @param[in] SSPx SSP peripheral selected, should be
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @return Data received (16-bit long)
**********************************************************************/
uint16_t SSP_ReceiveData(LPC_SSP_TypeDef* SSPx)
{
return ((uint16_t) (SSP_DR_BITMASK(SSPx->DR)));
}
/*********************************************************************//**
* @brief SSP Read write data function
* @param[in] SSPx Pointer to SSP peripheral, should be
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @param[in] dataCfg Pointer to a SSP_DATA_SETUP_Type structure that
* contains specified information about transmit
* data configuration.
* @param[in] xfType Transfer type, should be:
* - SSP_TRANSFER_POLLING: Polling mode
* - SSP_TRANSFER_INTERRUPT: Interrupt mode
* @return Actual Data length has been transferred in polling mode.
* In interrupt mode, always return (0)
* Return (-1) if error.
* Note: This function can be used in both master and slave mode.
***********************************************************************/
int32_t SSP_ReadWrite (LPC_SSP_TypeDef *SSPx, SSP_DATA_SETUP_Type *dataCfg, \
SSP_TRANSFER_Type xfType)
{
uint8_t *rdata8;
uint8_t *wdata8;
uint16_t *rdata16;
uint16_t *wdata16;
uint32_t stat;
uint32_t tmp;
int32_t dataword;
dataCfg->rx_cnt = 0;
dataCfg->tx_cnt = 0;
dataCfg->status = 0;
/* Clear all remaining data in RX FIFO */
while (SSPx->SR & SSP_SR_RNE){
tmp = (uint32_t) SSP_ReceiveData(SSPx);
}
// Clear status
SSPx->ICR = SSP_ICR_BITMASK;
if(SSP_GetDataSize(SSPx)>SSP_DATABIT_8)
dataword = 1;
else dataword = 0;
// Polling mode ----------------------------------------------------------------------
if (xfType == SSP_TRANSFER_POLLING){
if (dataword == 0){
rdata8 = (uint8_t *)dataCfg->rx_data;
wdata8 = (uint8_t *)dataCfg->tx_data;
} else {
rdata16 = (uint16_t *)dataCfg->rx_data;
wdata16 = (uint16_t *)dataCfg->tx_data;
}
while ((dataCfg->tx_cnt < dataCfg->length) || (dataCfg->rx_cnt < dataCfg->length)){
if ((SSPx->SR & SSP_SR_TNF) && (dataCfg->tx_cnt < dataCfg->length)){
// Write data to buffer
if(dataCfg->tx_data == NULL){
if (dataword == 0){
SSP_SendData(SSPx, 0xFF);
dataCfg->tx_cnt++;
} else {
SSP_SendData(SSPx, 0xFFFF);
dataCfg->tx_cnt += 2;
}
} else {
if (dataword == 0){
SSP_SendData(SSPx, *wdata8);
wdata8++;
dataCfg->tx_cnt++;
} else {
SSP_SendData(SSPx, *wdata16);
wdata16++;
dataCfg->tx_cnt += 2;
}
}
}
// Check overrun error
if ((stat = SSPx->RIS) & SSP_RIS_ROR){
// save status and return
dataCfg->status = stat | SSP_STAT_ERROR;
return (-1);
}
// Check for any data available in RX FIFO
while ((SSPx->SR & SSP_SR_RNE) && (dataCfg->rx_cnt < dataCfg->length)){
// Read data from SSP data
tmp = SSP_ReceiveData(SSPx);
// Store data to destination
if (dataCfg->rx_data != NULL)
{
if (dataword == 0){
*(rdata8) = (uint8_t) tmp;
rdata8++;
} else {
*(rdata16) = (uint16_t) tmp;
rdata16++;
}
}
// Increase counter
if (dataword == 0){
dataCfg->rx_cnt++;
} else {
dataCfg->rx_cnt += 2;
}
}
}
// save status
dataCfg->status = SSP_STAT_DONE;
if (dataCfg->tx_data != NULL){
return dataCfg->tx_cnt;
} else if (dataCfg->rx_data != NULL){
return dataCfg->rx_cnt;
} else {
return (0);
}
}
// Interrupt mode ----------------------------------------------------------------------
else if (xfType == SSP_TRANSFER_INTERRUPT){
while ((SSPx->SR & SSP_SR_TNF) && (dataCfg->tx_cnt < dataCfg->length)){
// Write data to buffer
if(dataCfg->tx_data == NULL){
if (dataword == 0){
SSP_SendData(SSPx, 0xFF);
dataCfg->tx_cnt++;
} else {
SSP_SendData(SSPx, 0xFFFF);
dataCfg->tx_cnt += 2;
}
} else {
if (dataword == 0){
SSP_SendData(SSPx, (*(uint8_t *)((uint32_t)dataCfg->tx_data + dataCfg->tx_cnt)));
dataCfg->tx_cnt++;
} else {
SSP_SendData(SSPx, (*(uint16_t *)((uint32_t)dataCfg->tx_data + dataCfg->tx_cnt)));
dataCfg->tx_cnt += 2;
}
}
// Check error
if ((stat = SSPx->RIS) & SSP_RIS_ROR){
// save status and return
dataCfg->status = stat | SSP_STAT_ERROR;
return (-1);
}
// Check for any data available in RX FIFO
while ((SSPx->SR & SSP_SR_RNE) && (dataCfg->rx_cnt < dataCfg->length)){
// Read data from SSP data
tmp = SSP_ReceiveData(SSPx);
// Store data to destination
if (dataCfg->rx_data != NULL)
{
if (dataword == 0){
*(uint8_t *)((uint32_t)dataCfg->rx_data + dataCfg->rx_cnt) = (uint8_t) tmp;
} else {
*(uint16_t *)((uint32_t)dataCfg->rx_data + dataCfg->rx_cnt) = (uint16_t) tmp;
}
}
// Increase counter
if (dataword == 0){
dataCfg->rx_cnt++;
} else {
dataCfg->rx_cnt += 2;
}
}
}
// If there more data to sent or receive
if ((dataCfg->rx_cnt < dataCfg->length) || (dataCfg->tx_cnt < dataCfg->length)){
// Enable all interrupt
SSPx->IMSC = SSP_IMSC_BITMASK;
} else {
// Save status
dataCfg->status = SSP_STAT_DONE;
}
return (0);
}
return (-1);
}
/*********************************************************************//**
* @brief Checks whether the specified SSP status flag is set or not
* @param[in] SSPx SSP peripheral selected, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @param[in] FlagType Type of flag to check status, should be one
* of following:
* - SSP_STAT_TXFIFO_EMPTY: TX FIFO is empty
* - SSP_STAT_TXFIFO_NOTFULL: TX FIFO is not full
* - SSP_STAT_RXFIFO_NOTEMPTY: RX FIFO is not empty
* - SSP_STAT_RXFIFO_FULL: RX FIFO is full
* - SSP_STAT_BUSY: SSP peripheral is busy
* @return New State of specified SSP status flag
**********************************************************************/
FlagStatus SSP_GetStatus(LPC_SSP_TypeDef* SSPx, uint32_t FlagType)
{
return ((SSPx->SR & FlagType) ? SET : RESET);
}
/*********************************************************************//**
* @brief Enable or disable specified interrupt type in SSP peripheral
* @param[in] SSPx SSP peripheral selected, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @param[in] IntType Interrupt type in SSP peripheral, should be:
* - SSP_INTCFG_ROR: Receive Overrun interrupt
* - SSP_INTCFG_RT: Receive Time out interrupt
* - SSP_INTCFG_RX: RX FIFO is at least half full interrupt
* - SSP_INTCFG_TX: TX FIFO is at least half empty interrupt
* @param[in] NewState New State of specified interrupt type, should be:
* - ENABLE: Enable this interrupt type
* - DISABLE: Disable this interrupt type
* @return None
* Note: We can enable/disable multi-interrupt type by OR multi value
**********************************************************************/
void SSP_IntConfig(LPC_SSP_TypeDef *SSPx, uint32_t IntType, FunctionalState NewState)
{
if (NewState == ENABLE)
{
SSPx->IMSC |= IntType;
}
else
{
SSPx->IMSC &= (~IntType) & SSP_IMSC_BITMASK;
}
}
/*********************************************************************//**
* @brief Check whether the specified Raw interrupt status flag is
* set or not
* @param[in] SSPx SSP peripheral selected, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @param[in] RawIntType Raw Interrupt Type, should be:
* - SSP_INTSTAT_RAW_ROR: Receive Overrun interrupt
* - SSP_INTSTAT_RAW_RT: Receive Time out interrupt
* - SSP_INTSTAT_RAW_RX: RX FIFO is at least half full interrupt
* - SSP_INTSTAT_RAW_TX: TX FIFO is at least half empty interrupt
* @return New State of specified Raw interrupt status flag in SSP peripheral
* Note: Enabling/Disabling specified interrupt in SSP peripheral does not
* effect to Raw Interrupt Status flag.
**********************************************************************/
IntStatus SSP_GetRawIntStatus(LPC_SSP_TypeDef *SSPx, uint32_t RawIntType)
{
return ((SSPx->RIS & RawIntType) ? SET : RESET);
}
/*********************************************************************//**
* @brief Get Raw Interrupt Status register
* @param[in] SSPx SSP peripheral selected, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @return Raw Interrupt Status (RIS) register value
**********************************************************************/
uint32_t SSP_GetRawIntStatusReg(LPC_SSP_TypeDef *SSPx)
{
return (SSPx->RIS);
}
/*********************************************************************//**
* @brief Check whether the specified interrupt status flag is
* set or not
* @param[in] SSPx SSP peripheral selected, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @param[in] IntType Raw Interrupt Type, should be:
* - SSP_INTSTAT_ROR: Receive Overrun interrupt
* - SSP_INTSTAT_RT: Receive Time out interrupt
* - SSP_INTSTAT_RX: RX FIFO is at least half full interrupt
* - SSP_INTSTAT_TX: TX FIFO is at least half empty interrupt
* @return New State of specified interrupt status flag in SSP peripheral
* Note: Enabling/Disabling specified interrupt in SSP peripheral effects
* to Interrupt Status flag.
**********************************************************************/
IntStatus SSP_GetIntStatus (LPC_SSP_TypeDef *SSPx, uint32_t IntType)
{
return ((SSPx->MIS & IntType) ? SET :RESET);
}
/*********************************************************************//**
* @brief Clear specified interrupt pending in SSP peripheral
* @param[in] SSPx SSP peripheral selected, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @param[in] IntType Interrupt pending to clear, should be:
* - SSP_INTCLR_ROR: clears the "frame was received when
* RxFIFO was full" interrupt.
* - SSP_INTCLR_RT: clears the "Rx FIFO was not empty and
* has not been read for a timeout period" interrupt.
* @return None
**********************************************************************/
void SSP_ClearIntPending(LPC_SSP_TypeDef *SSPx, uint32_t IntType)
{
SSPx->ICR = IntType;
}
/*********************************************************************//**
* @brief Enable/Disable DMA function for SSP peripheral
* @param[in] SSPx SSP peripheral selected, should be:
* - LPC_SSP0: SSP0 peripheral
* - LPC_SSP1: SSP1 peripheral
* @param[in] DMAMode Type of DMA, should be:
* - SSP_DMA_TX: DMA for the transmit FIFO
* - SSP_DMA_RX: DMA for the Receive FIFO
* @param[in] NewState New State of DMA function on SSP peripheral,
* should be:
* - ENALBE: Enable this function
* - DISABLE: Disable this function
* @return None
**********************************************************************/
void SSP_DMACmd(LPC_SSP_TypeDef *SSPx, uint32_t DMAMode, FunctionalState NewState)
{
if (NewState == ENABLE)
{
SSPx->DMACR |= DMAMode;
}
else
{
SSPx->DMACR &= (~DMAMode) & SSP_DMA_BITMASK;
}
}
/**
* @}
*/
#endif /*_SSP*/
/**
* @}
*/
/* --------------------------------- End Of File ------------------------------ */