4.34. SPI
4.34.2. Description
There are three main functions in the SPI API:
SPI function to transmit data: used to transmit data without DMA, blocking
SPI function to transmit and receive data: used to transmit and receive data without DMA, blocking
SPI function to transmit and receive data with DMA: used to transmit and receive data with DMA, non-blocking
Three other functions are available:
SPI function to receive data with DMA as a slave device: used to send a dummy byte without DMA, blocking
SPI wrapper function for FRAM: wrapper function used in the FRAM module, works without DMA, blocking
SPI function to receive data with DMA as a slave device: used to configure an SPI interface as a slave device receiving data over SPI, non blocking.
1/**
2 * @brief Transmits data on SPI without DMA.
3 * @details This function can be used to send and receive data via SPI. SPI
4 * communication is performed in blocking mode and chip select is
5 * set/reset automatically.
6 * @param pSpiInterface pointer to SPI interface configuration
7 * @param pTxBuff pointer to data that is transmitted by the SPI interface
8 * @param frameLength number of bytes to be transmitted by the SPI interface
9 * @return status of the SPI transfer
10 */
11extern STD_RETURN_TYPE_e SPI_TransmitData(SPI_INTERFACE_CONFIG_s *pSpiInterface, uint16 *pTxBuff, uint32 frameLength);
1/**
2 * @brief Transmits and receives data on SPI without DMA.
3 * @details This function can be used to send and receive data via SPI. SPI
4 * communication is performed in blocking mode and chip select is
5 * set/reset automatically.
6 * @param pSpiInterface pointer to SPI interface configuration
7 * @param pTxBuff pointer to data that is transmitted by the SPI interface
8 * @param pRxBuff pointer to data that is received by the SPI interface
9 * @param frameLength number of bytes to be transmitted by the SPI interface
10 * @return status of the SPI transfer
11 */
12extern STD_RETURN_TYPE_e SPI_TransmitReceiveData(
13 SPI_INTERFACE_CONFIG_s *pSpiInterface,
14 uint16 *pTxBuff,
15 uint16 *pRxBuff,
16 uint32 frameLength);
1/**
2 * @brief Transmits and receives data on SPI with DMA.
3 * @details This function can be used to send and receive data via SPI. SPI
4 * communication is performed in blocking mode and chip select is
5 * set/reset automatically..
6 * @param pSpiInterface pointer to SPI interface configuration
7 * @param pTxBuff pointer to data that is transmitted by the SPI interface
8 * @param pRxBuff pointer to data that is received by the SPI interface
9 * @param frameLength number of bytes to be transmitted by the SPI interface
10 * @return status of the SPI transfer
11 */
12extern STD_RETURN_TYPE_e SPI_TransmitReceiveDataDma(
13 SPI_INTERFACE_CONFIG_s *pSpiInterface,
14 uint16_t *pTxBuff,
15 uint16_t *pRxBuff,
16 uint32_t frameLength);
1/**
2 * @brief Sends a dummy byte to wake up the SPI interface.
3 *
4 * @param pSpiInterface pointer to SPI interface configuration
5 * @param delay delay to wait after dummy byte transfer
6 *
7 * @return status of the SPI transfer
8 */
9extern STD_RETURN_TYPE_e SPI_TransmitDummyByte(SPI_INTERFACE_CONFIG_s *pSpiInterface, uint32_t delay);
1/**
2 * @brief Transmits and receives data on SPI without DMA, wrappe for FRAM
3 * @details This function can be used to send and receive data via SPI. SPI
4 * communication is performed in blocking mode and chip select is
5 * set/reset automatically.
6 * It does not drive the Chip Select (neither hardware nor software)
7 * as this is done directly in the FRAM functions.
8 * @param pSpiInterface pointer to SPI interface configuration
9 * @param pTxBuff pointer to data that is transmitted by the SPI interface
10 * @param pRxBuff pointer to data that is received by the SPI interface
11 * @param frameLength number of bytes to be transmitted by the SPI interface
12 * @return status of the SPI transfer
13 */
14extern void SPI_FramTransmitReceiveData(
15 SPI_INTERFACE_CONFIG_s *pSpiInterface,
16 uint16 *pTxBuff,
17 uint16 *pRxBuff,
18 uint32 frameLength);
1/**
2 * @brief Transmits and receives data on SPI with DMA.
3 * @details This function can be used to send and receive data via SPI. SPI
4 * communication is performed in blocking mode and chip select is
5 * set/reset automatically..
6 * @param pSpiInterface pointer to SPI interface configuration
7 * @param pTxBuff pointer to data that is transmitted by the SPI interface
8 * @param pRxBuff pointer to data that is received by the SPI interface
9 * @param frameLength number of bytes to be transmitted by the SPI interface
10 * @return status of the SPI transfer
11 */
12extern STD_RETURN_TYPE_e SPI_SlaveSetReceiveDataDma(
13 SPI_INTERFACE_CONFIG_s *pSpiInterface,
14 uint16_t *pTxBuff,
15 uint16_t *pRxBuff,
16 uint32_t frameLength);
To configure an SPI interface, a structure of the type Configuration for the SPI interface must be used. One important parameter is the type of the Chip Select pin, to be chosen within the enum Type of Chip Select used. Available possibilities:
Hardware Chip Select
Software Chip Select
Warning
Currently the DMA functions presented above can only be used with a hardware Chip Select.
1/** configuration of the SPI interface */
2typedef struct {
3 spiDAT1_t *pConfig;
4 spiBASE_t *pNode;
5 volatile uint32_t *pGioPort;
6 uint32_t csPin;
7 SPI_CHIP_SELECT_TYPE_e csType;
8} SPI_INTERFACE_CONFIG_s;
1/** type of chip select for spi */
2typedef enum {
3 SPI_CHIP_SELECT_HARDWARE,
4 SPI_CHIP_SELECT_SOFTWARE,
5} SPI_CHIP_SELECT_TYPE_e;
Warning
The DMA transmit/receive function works only to transmit 3 words and more. To transmit 1 or 2 words, the function without DMA must be used.
The register SPIDAT1
is used to transmit data. It is made out of two bit
groups:
bits 0 to 15, containing the data to send (up to 16 bits)
bits 16 to 31, containing the configuration to be used for the SPI transmission
When using DMA, only the data group is written, so the configuration is not
taken into account.
This is problematic, as the configuration contains among other the hardware
Chip Select pin to use.
Another issue is that very often SPI transmissions require the Chip Select pin
to be held active.
To realize this, the field CSHOLD
in the configuration group must be written
with 1, except for the last word sent, where it must be written with 0.
To overcome these issues, the first word and the last word are written to the
SPIDAT1
register without DMA. This way the configuration group is written
with the first word.
When DMA writes the subsequent words, the configuration group remains
untouched.
When the last word is written, the CSHOLD
bit is set to 0.
If this was not done, the Chip Select pin would remains active after the
transmission.
This is the reason why DMA can only be used when transmitting 3 words or more.