/** * @file xmc_spi.h * @date 2016-05-20 * * @cond ********************************************************************************************************************* * XMClib v2.1.16 - XMC Peripheral Driver Library * * Copyright (c) 2015-2017, Infineon Technologies AG * All rights reserved. * * Redistribution and use in source and binary forms, with or without modification,are permitted provided that the * following conditions are met: * * Redistributions of source code must retain the above copyright notice, this list of conditions and the following * disclaimer. * * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following * disclaimer in the documentation and/or other materials provided with the distribution. * * Neither the name of the copyright holders nor the names of its contributors may be used to endorse or promote * products derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, * INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS 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. * * To improve the quality of the software, users are encouraged to share modifications, enhancements or bug fixes with * Infineon Technologies AG dave@infineon.com). ********************************************************************************************************************* * * Change History * -------------- * * 2015-02-20: * - Initial * * 2015-05-20: * - Documentation improved
* - Added XMC_SPI_CH_SetSlaveSelectDelay(), XMC_SPI_CH_TriggerServiceRequest() and * XMC_SPI_CH_SelectInterruptNodePointer()
* - Added XMC_SPI_CH_SetInterwordDelaySCLK()
* * 2015-06-20: * - Removed version macros and declaration of GetDriverVersion API
* * 2015-08-24: * - Added APIs for enabling/disabling delay compensation XMC_SPI_CH_DisableDelayCompensation() and * XMC_SPI_CH_EnableDelayCompensation()
* * 2015-08-27: * - Added APIs for external input for BRG configuration:XMC_SPI_CH_ConfigExternalInputSignalToBRG()
* * 2015-09-01: * - Modified XMC_SPI_CH_SetInputSource() for avoiding complete DXCR register overwriting.
* - Modified XMC_SPI_CH_EVENT_t enum for supporting XMC_SPI_CH_EnableEvent() and XMC_SPI_CH_DisableEvent() * for supporting multiple events configuration
* * 2015-09-08: * - Adding API for configuring the receiving clock phase in the slave:XMC_SPI_CH_DataLatchedInTrailingEdge() and XMC_SPI_CH_DataLatchedInLeadingEdge()
* * 2016-04-10: * - Added an API for configuring the transmit mode:XMC_SPI_CH_SetTransmitMode()
* * 2016-05-20: * - Added XMC_SPI_CH_EnableDataTransmission() and XMC_SPI_CH_DisableDataTransmission() * * @endcond * */ #ifndef XMC_SPI_H #define XMC_SPI_H /********************************************************************************************************************** * HEADER FILES *********************************************************************************************************************/ #include "xmc_usic.h" /** * @addtogroup XMClib XMC Peripheral Library * @{ */ /** * @addtogroup SPI * @brief Synchronous serial channel driver for SPI-like communication. * * The SPI driver uses Universal Serial Interface Channel(USIC) module. * The USIC module supports multiple data lines for SPI communication. \n * -# Full duplex communication with 2 separate lines for transmission and reception. * -# Half duplex communication with 1 common line shared for transmission and reception. * -# Dual mode communication with 2 common lines shared for transmission and reception. * -# Quad mode communication with 4 common lines shared for transmission and reception.

* * SPI driver provides structures, enumerations and APIs for configuring the USIC channel for SPI communication * and also for data transaction.
* SPI driver features: * -# Configuration structure XMC_SPI_CH_CONFIG_t and SPI initialization function XMC_SPI_CH_Init() * -# Allows configuration of protocol word and frame length using XMC_SPI_CH_SetWordLength(), XMC_SPI_CH_SetFrameLength() * -# Allows manipulation of data frame at runtime using XMC_SPI_CH_EnableSOF(), XMC_SPI_CH_EnableEOF(), XMC_SPI_CH_EnableSlaveSelect(), XMC_SPI_CH_DisableSlaveSelect() * -# Provides APIs for transmitting data and receiving data using XMC_SPI_CH_Transmit(), XMC_SPI_CH_Receive(), XMC_SPI_CH_GetReceivedData() * -# Allows configuration of shift clock using XMC_SPI_CH_ConfigureShiftClockOutput() * -# Provides enumeration of SPI protocol events using @ref XMC_SPI_CH_STATUS_FLAG_t * @{ */ /*********************************************************************************************************************** * MACROS **********************************************************************************************************************/ #if defined(USIC0) #define XMC_SPI0_CH0 XMC_USIC0_CH0 /**< SPI0 channel 0 base address */ #define XMC_SPI0_CH1 XMC_USIC0_CH1 /**< SPI0 channel 1 base address */ #endif #if defined(USIC1) #define XMC_SPI1_CH0 XMC_USIC1_CH0 /**< SPI1 channel 0 base address */ #define XMC_SPI1_CH1 XMC_USIC1_CH1 /**< SPI1 channel 1 base address */ #endif #if defined(USIC2) #define XMC_SPI2_CH0 XMC_USIC2_CH0 /**< SPI2 channel 0 base address */ #define XMC_SPI2_CH1 XMC_USIC2_CH1 /**< SPI2 channel 1 base address */ #endif /*********************************************************************************************************************** * ENUMS ***********************************************************************************************************************/ /** * Defines return status of SPI driver APIs */ typedef enum XMC_SPI_CH_STATUS { XMC_SPI_CH_STATUS_OK, /**< Status of the Module: OK */ XMC_SPI_CH_STATUS_ERROR, /**< Status of the Module: ERROR */ XMC_SPI_CH_STATUS_BUSY /**< The Module is busy */ } XMC_SPI_CH_STATUS_t; /** * Defines the SPI bus mode */ typedef enum XMC_SPI_CH_BUS_MODE { XMC_SPI_CH_BUS_MODE_MASTER, /**< SPI Master */ XMC_SPI_CH_BUS_MODE_SLAVE /**< SPI Slave */ } XMC_SPI_CH_BUS_MODE_t; /** * Defines the Polarity of the slave select signals SELO[7:0] in relation to the master slave select signal MSLS. */ typedef enum XMC_SPI_CH_SLAVE_SEL_MSLS_INV { XMC_SPI_CH_SLAVE_SEL_SAME_AS_MSLS = 0x0UL, /**< The SELO outputs have the same polarity as the MSLS signal (active high) */ XMC_SPI_CH_SLAVE_SEL_INV_TO_MSLS = 0x1UL << USIC_CH_PCR_SSCMode_SELINV_Pos /**< The SELO outputs have the inverted polarity to the MSLS signal (active low)*/ } XMC_SPI_CH_SLAVE_SEL_MSLS_INV_t; /** * Defines the Polarity of the data inputs. */ typedef enum XMC_SPI_CH_DATA_POLARITY { XMC_SPI_CH_DATA_POLARITY_DIRECT = 0x0UL, /**< The polarity of the data line is not inverted */ XMC_SPI_CH_DATA_POLARITY_INVERT = 0x1UL << USIC_CH_DX2CR_DPOL_Pos /**< The polarity of the data line is inverted */ } XMC_SPI_CH_DATA_POLARITY_t; /** * Defines Slave Select lines */ typedef enum XMC_SPI_CH_SLAVE_SELECT { XMC_SPI_CH_SLAVE_SELECT_0 = 1UL << USIC_CH_PCR_SSCMode_SELO_Pos, /**< Slave Select line 0 */ XMC_SPI_CH_SLAVE_SELECT_1 = 2UL << USIC_CH_PCR_SSCMode_SELO_Pos, /**< Slave Select line 1 */ XMC_SPI_CH_SLAVE_SELECT_2 = 4UL << USIC_CH_PCR_SSCMode_SELO_Pos, /**< Slave Select line 2 */ XMC_SPI_CH_SLAVE_SELECT_3 = 8UL << USIC_CH_PCR_SSCMode_SELO_Pos, /**< Slave Select line 3 */ XMC_SPI_CH_SLAVE_SELECT_4 = 16UL << USIC_CH_PCR_SSCMode_SELO_Pos, /**< Slave Select line 4 */ XMC_SPI_CH_SLAVE_SELECT_5 = 32UL << USIC_CH_PCR_SSCMode_SELO_Pos, /**< Slave Select line 5 */ XMC_SPI_CH_SLAVE_SELECT_6 = 64UL << USIC_CH_PCR_SSCMode_SELO_Pos, /**< Slave Select line 6 */ XMC_SPI_CH_SLAVE_SELECT_7 = 128UL << USIC_CH_PCR_SSCMode_SELO_Pos /**< Slave Select line 7 */ } XMC_SPI_CH_SLAVE_SELECT_t; /** * Defines SPI specific events */ typedef enum XMC_SPI_CH_EVENT { XMC_SPI_CH_EVENT_RECEIVE_START = USIC_CH_CCR_RSIEN_Msk, /**< Receive start event */ XMC_SPI_CH_EVENT_DATA_LOST = USIC_CH_CCR_DLIEN_Msk, /**< Data lost event */ XMC_SPI_CH_EVENT_TRANSMIT_SHIFT = USIC_CH_CCR_TSIEN_Msk, /**< Transmit shift event */ XMC_SPI_CH_EVENT_TRANSMIT_BUFFER = USIC_CH_CCR_TBIEN_Msk, /**< Transmit buffer event */ XMC_SPI_CH_EVENT_STANDARD_RECEIVE = USIC_CH_CCR_RIEN_Msk, /**< Receive event */ XMC_SPI_CH_EVENT_ALTERNATIVE_RECEIVE = USIC_CH_CCR_AIEN_Msk, /**< Alternate receive event */ XMC_SPI_CH_EVENT_BAUD_RATE_GENERATOR = USIC_CH_CCR_BRGIEN_Msk, /**< Baudrate generator event */ XMC_SPI_CH_EVENT_PARITY_ERROR = USIC_CH_PCR_SSCMode_PARIEN_Msk >> 13U, /**< Parity error event */ XMC_SPI_CH_EVENT_MSLS_CHANGE = USIC_CH_PCR_SSCMode_MSLSIEN_Msk >> 13U, /**< Master slave select(MSLS) output transition event*/ XMC_SPI_CH_EVENT_DX2TIEN_ACTIVATED = USIC_CH_PCR_SSCMode_DX2TIEN_Msk >> 13U /**< Slave select input signal transition event*/ } XMC_SPI_CH_EVENT_t; /** * Defines SPI event status */ typedef enum XMC_SPI_CH_STATUS_FLAG { XMC_SPI_CH_STATUS_FLAG_MSLS = USIC_CH_PSR_SSCMode_MSLS_Msk, /**< Status of Master slave select(MSLS) signal */ XMC_SPI_CH_STATUS_FLAG_DX2S = USIC_CH_PSR_SSCMode_DX2S_Msk, /**< Status of slave select input(DX2) signal*/ XMC_SPI_CH_STATUS_FLAG_MSLS_EVENT_DETECTED = USIC_CH_PSR_SSCMode_MSLSEV_Msk, /**< Status for master slave select output signal transition*/ XMC_SPI_CH_STATUS_FLAG_DX2T_EVENT_DETECTED = USIC_CH_PSR_SSCMode_DX2TEV_Msk, /**< Status for slave select input signal transition */ XMC_SPI_CH_STATUS_FLAG_PARITY_ERROR_EVENT_DETECTED = USIC_CH_PSR_SSCMode_PARERR_Msk, /**< Indicates status of the parity error */ XMC_SPI_CH_STATUS_FLAG_RECEIVER_START_INDICATION = USIC_CH_PSR_SSCMode_RSIF_Msk, /**< Status for receive start event */ XMC_SPI_CH_STATUS_FLAG_DATA_LOST_INDICATION = USIC_CH_PSR_SSCMode_DLIF_Msk, /**< Status for data lost event*/ XMC_SPI_CH_STATUS_FLAG_TRANSMIT_SHIFT_INDICATION = USIC_CH_PSR_SSCMode_TSIF_Msk, /**< Status for transmit shift event */ XMC_SPI_CH_STATUS_FLAG_TRANSMIT_BUFFER_INDICATION = USIC_CH_PSR_SSCMode_TBIF_Msk, /**< Status for transmit buffer event */ XMC_SPI_CH_STATUS_FLAG_RECEIVE_INDICATION = USIC_CH_PSR_SSCMode_RIF_Msk, /**< Status for receive event */ XMC_SPI_CH_STATUS_FLAG_ALTERNATIVE_RECEIVE_INDICATION = USIC_CH_PSR_SSCMode_AIF_Msk, /**< Status for alternative receive event */ XMC_SPI_CH_STATUS_FLAG_BAUD_RATE_GENERATOR_INDICATION = USIC_CH_PSR_SSCMode_BRGIF_Msk/**< Status for baud rate generation error event */ } XMC_SPI_CH_STATUS_FLAG_t; /** * Defines input frequency sources for slave select signal delay configuration. */ typedef enum XMC_SPI_CH_INPUT_FREQ_SLAVE_SELECT_DELAY { XMC_SPI_CH_INPUT_FREQ_SLAVE_SELECT_DELAY_FPDIV = 0x0UL, /**< Output of PDIV divider: FPDIV */ XMC_SPI_CH_INPUT_FREQ_SLAVE_SELECT_DELAY_FPPP = 0x1UL << USIC_CH_PCR_SSCMode_CTQSEL1_Pos, /**< Peripheral clock: FPPP */ XMC_SPI_CH_INPUT_FREQ_SLAVE_SELECT_DELAY_FSCLK = 0x2UL << USIC_CH_PCR_SSCMode_CTQSEL1_Pos, /**< Shift clock: FSCLK */ XMC_SPI_CH_INPUT_FREQ_SLAVE_SELECT_DELAY_FMCLK = 0x3UL << USIC_CH_PCR_SSCMode_CTQSEL1_Pos /**< Master clock: FMCLK */ } XMC_SPI_CH_INPUT_FREQ_SLAVE_SELECT_DELAY_t; /** * Define data and clock input stages */ typedef enum XMC_SPI_CH_INPUT { XMC_SPI_CH_INPUT_DIN0 = 0UL, /**< Data input stage 0 */ XMC_SPI_CH_INPUT_SLAVE_SCLKIN = 1UL, /**< Clock input stage */ XMC_SPI_CH_INPUT_SLAVE_SELIN = 2UL, /**< Slave select input stage */ XMC_SPI_CH_INPUT_DIN1 = 3UL, /**< Data input stage 1 */ XMC_SPI_CH_INPUT_DIN2 = 4UL, /**< Data input stage 2 */ XMC_SPI_CH_INPUT_DIN3 = 5UL /**< Data input stage 3 */ } XMC_SPI_CH_INPUT_t; /** * Define SPI data transfer mode */ typedef enum XMC_SPI_CH_MODE { XMC_SPI_CH_MODE_STANDARD = 0UL, /**< SPI standard full duplex mode */ XMC_SPI_CH_MODE_STANDARD_HALFDUPLEX = 4UL, /**< SPI standard half duplex mode */ XMC_SPI_CH_MODE_DUAL= 6UL, /**< SPI half duplex mode with dual data lines */ XMC_SPI_CH_MODE_QUAD= 7UL /**< SPI half duplex mode with quad data lines */ } XMC_SPI_CH_MODE_t; /** * SPI Baudrate Generator shift clock passive level */ typedef enum XMC_SPI_CH_BRG_SHIFT_CLOCK_PASSIVE_LEVEL { /**< Passive clock level 0, delay disabled */ XMC_SPI_CH_BRG_SHIFT_CLOCK_PASSIVE_LEVEL_0_DELAY_DISABLED = XMC_USIC_CH_BRG_SHIFT_CLOCK_PASSIVE_LEVEL_0_DELAY_DISABLED, /**< Passive clock level 1, delay disabled */ XMC_SPI_CH_BRG_SHIFT_CLOCK_PASSIVE_LEVEL_1_DELAY_DISABLED = XMC_USIC_CH_BRG_SHIFT_CLOCK_PASSIVE_LEVEL_1_DELAY_DISABLED, /**< Passive clock level 0, delay enabled */ XMC_SPI_CH_BRG_SHIFT_CLOCK_PASSIVE_LEVEL_0_DELAY_ENABLED = XMC_USIC_CH_BRG_SHIFT_CLOCK_PASSIVE_LEVEL_0_DELAY_ENABLED, /**< Passive clock level 1, delay enabled */ XMC_SPI_CH_BRG_SHIFT_CLOCK_PASSIVE_LEVEL_1_DELAY_ENABLED = XMC_USIC_CH_BRG_SHIFT_CLOCK_PASSIVE_LEVEL_1_DELAY_ENABLED } XMC_SPI_CH_BRG_SHIFT_CLOCK_PASSIVE_LEVEL_t; /** * SPI Baudrate Generator shift clock output */ typedef enum XMC_SPI_CH_BRG_SHIFT_CLOCK_OUTPUT { XMC_SPI_CH_BRG_SHIFT_CLOCK_OUTPUT_SCLK = XMC_USIC_CH_BRG_SHIFT_CLOCK_OUTPUT_SCLK, /**< Baudrate Generator shift clock output: SCLK*/ XMC_SPI_CH_BRG_SHIFT_CLOCK_OUTPUT_DX1 = XMC_USIC_CH_BRG_SHIFT_CLOCK_OUTPUT_DX1 /**< Clock obtained as input from master: DX1*/ } XMC_SPI_CH_BRG_SHIFT_CLOCK_OUTPUT_t; /** * SPI channel interrupt node pointers */ typedef enum XMC_SPI_CH_INTERRUPT_NODE_POINTER { XMC_SPI_CH_INTERRUPT_NODE_POINTER_TRANSMIT_SHIFT = XMC_USIC_CH_INTERRUPT_NODE_POINTER_TRANSMIT_SHIFT, /**< Node pointer for transmit shift interrupt */ XMC_SPI_CH_INTERRUPT_NODE_POINTER_TRANSMIT_BUFFER = XMC_USIC_CH_INTERRUPT_NODE_POINTER_TRANSMIT_BUFFER, /**< Node pointer for transmit buffer interrupt */ XMC_SPI_CH_INTERRUPT_NODE_POINTER_RECEIVE = XMC_USIC_CH_INTERRUPT_NODE_POINTER_RECEIVE, /**< Node pointer for receive interrupt */ XMC_SPI_CH_INTERRUPT_NODE_POINTER_ALTERNATE_RECEIVE = XMC_USIC_CH_INTERRUPT_NODE_POINTER_ALTERNATE_RECEIVE, /**< Node pointer for alternate receive interrupt */ XMC_SPI_CH_INTERRUPT_NODE_POINTER_PROTOCOL = XMC_USIC_CH_INTERRUPT_NODE_POINTER_PROTOCOL /**< Node pointer for protocol related interrupts */ } XMC_SPI_CH_INTERRUPT_NODE_POINTER_t; /********************************************************************************************************************** * DATA STRUCTURES **********************************************************************************************************************/ /** * Structure for initializing SPI channel. */ typedef struct XMC_SPI_CH_CONFIG { uint32_t baudrate; /**< Module baud rate for communication */ XMC_SPI_CH_BUS_MODE_t bus_mode; /**< Bus mode: Master/Slave */ XMC_SPI_CH_SLAVE_SEL_MSLS_INV_t selo_inversion; /**< Enable inversion of Slave select signal relative to the internal MSLS signal */ XMC_USIC_CH_PARITY_MODE_t parity_mode; /**< Enable parity check for transmit and received data */ } XMC_SPI_CH_CONFIG_t; /********************************************************************************************************************** * API PROTOTYPES *********************************************************************************************************************/ #ifdef __cplusplus extern "C" { #endif /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param config pointer to constant SPI channel configuration data structure.\n * Refer data structure @ref XMC_SPI_CH_CONFIG_t for detail. * * @return None * * \parDescription:
* Initializes the selected SPI \a channel with the \a config structure.\n\n * Enable SPI channel by calling XMC_USIC_CH_Enable() and then configures * * And if master mode is selected, * */ void XMC_SPI_CH_Init(XMC_USIC_CH_t *const channel, const XMC_SPI_CH_CONFIG_t *const config); /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription:
* Set the selected USIC channel to operate in SPI mode, by setting CCR.MODE bits.\n\n * It should be executed after XMC_SPI_CH_Init() during initialization. By invoking XMC_SPI_CH_Stop(), the MODE is set * to IDLE state. Call XMC_SPI_CH_Start() to set the SPI mode again, as needed later in the program. * * \parRelated APIs:
* XMC_SPI_CH_Init(), XMC_SPI_CH_Stop() */ __STATIC_INLINE void XMC_SPI_CH_Start(XMC_USIC_CH_t *const channel) { /* USIC channel in SPI mode */ XMC_USIC_CH_SetMode(channel, XMC_USIC_CH_OPERATING_MODE_SPI); } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return XMC_SPI_CH_STATUS_t Status of the SPI driver after the request for stopping is processed. \n * XMC_SPI_CH_STATUS_OK- If the USIC channel is successfully put to IDLE mode. \n * XMC_SPI_CH_STATUS_BUSY- If the USIC channel is busy transmitting data. * * \parDescription:
* Set the selected SPI channel to IDLE mode, by clearing CCR.MODE bits.\n\n * After calling XMC_SPI_CH_Stop, channel is IDLE mode. So no communication is supported. XMC_SPI_CH_Start() has to be * invoked to start the communication again. * * \parRelated APIs:
* XMC_SPI_CH_Start() */ XMC_SPI_CH_STATUS_t XMC_SPI_CH_Stop(XMC_USIC_CH_t *const channel); /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param rate Bus speed in bits per second * * @return XMC_SPI_CH_STATUS_t Status of the SPI driver after the request for setting baudrate is processed. \n * XMC_SPI_CH_STATUS_OK- If the baudrate is successfully changed. \n * XMC_SPI_CH_STATUS_ERROR- If the new baudrate value is out of range. * * \parDescription:
* Sets the bus speed in bits per second * * \parRelated APIs:
* XMC_SPI_CH_Init(), XMC_SPI_CH_Stop() */ XMC_SPI_CH_STATUS_t XMC_SPI_CH_SetBaudrate(XMC_USIC_CH_t *const channel, const uint32_t rate); /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param slave Slave select signal.\n * Refer @ref XMC_SPI_CH_SLAVE_SELECT_t for valid values. * * @return None * * \parDescription:
* Enable the selected slave signal by setting PCR.SELO bits.\n\n * Each slave is connected with one slave select signal. This is not configured in XMC_SPI_CH_Init(). Invoke * XMC_SPI_CH_EnableSlaveSelect() with required \a slave to to start the communication. After finishing the * communication XMC_SPI_CH_DisableSlaveSelect() can be invoked to disable the slaves. * * \parRelated APIs:
* XMC_SPI_CH_DisableSlaveSelect() */ void XMC_SPI_CH_EnableSlaveSelect(XMC_USIC_CH_t *const channel, const XMC_SPI_CH_SLAVE_SELECT_t slave); /** * @param channel A constant ponter to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription:
* Disable all the slave signals by clearing PCR.SELO bits.\n\n * XMC_SPI_CH_EnableSlaveSelect() has to be invoked to start the communication with the desired slave again. * * \parRelated APIs:
* XMC_SPI_CH_EnableSlaveSelect() */ void XMC_SPI_CH_DisableSlaveSelect(XMC_USIC_CH_t *const channel); /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param mode Communication mode of the SPI, based on this mode TCI(Transmit control information)is updated.\n * Refer @ref XMC_SPI_CH_MODE_t for valid values. * * @return None * * \parDescription:
* In Dual and Quad modes, hardware port control(CCR.HPCEN) mode is enabled. \n\n * By enabling this the direction of the data pin is updated by hardware itself. Before transmitting the data set the * mode to ensure the proper communication. * * \parRelated APIs:
* XMC_SPI_CH_Transmit() */ __STATIC_INLINE void XMC_SPI_CH_SetTransmitMode(XMC_USIC_CH_t *const channel, const XMC_SPI_CH_MODE_t mode) { channel->CCR = (channel->CCR & (uint32_t)(~USIC_CH_CCR_HPCEN_Msk)) | (((uint32_t) mode << USIC_CH_CCR_HPCEN_Pos) & (uint32_t)USIC_CH_CCR_HPCEN_Msk); } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param data Data to be transmitted * @param mode Communication mode of the SPI, based on this mode TCI(Transmit control information)is updated.\n * Refer @ref XMC_SPI_CH_MODE_t for valid values. * * @return None * * \parDescription:
* Puts the data into FIFO, if FIFO mode is enabled or else into standard buffer, by setting the proper mode.\n\n * In Dual and Quad modes, hardware port control(CCR.HPCEN) mode is enabled. By enabling this the direction of the data * pin is updated by hardware itself. TCI(Transmit Control Information) allows dynamic control of both the data shift mode * and pin direction during data transfers by writing to SCTR.DSM and SCTR.HPCDIR bit fields. To support this auto * update, TCSR.HPCMD(Hardware Port control) will be enabled during the initialization using XMC_SPI_CH_Init() for all modes. * * * \parRelated APIs:
* XMC_SPI_CH_Receive() */ void XMC_SPI_CH_Transmit(XMC_USIC_CH_t *const channel, const uint16_t data, const XMC_SPI_CH_MODE_t mode); /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param mode Communication mode of the SPI, based on this mode TCI(Transmit control information)is updated.\n * Refer @ref XMC_SPI_CH_MODE_t for valid values. * * @return None * * \parDescription:
* Transmits a dummy data(FFFFH) to provide clock for slave and receives the data from the slave.\n\n * XMC_SPI_CH_Receive() receives the data and places it into buffer based on the FIFO selection. After reception of data * XMC_SPI_CH_GetReceivedData() can be invoked to read the data from the buffers. * * \parRelated APIs:
* XMC_SPI_CH_GetReceivedDaa() */ __STATIC_INLINE void XMC_SPI_CH_Receive(XMC_USIC_CH_t *const channel, const XMC_SPI_CH_MODE_t mode) { /* Transmit dummy data */ XMC_SPI_CH_Transmit(channel, (uint16_t)0xffffU, (XMC_SPI_CH_MODE_t)((uint16_t)mode & 0xfffbU)); } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return uint16_t Data read from the receive buffer. * * \parDescription:
* Reads data from the receive buffer based on the FIFO selection.\n\n * Invocation of XMC_SPI_CH_Receive() receives the data and place it into receive buffer. After receiving the data * XMC_SPI_CH_GetReceivedData() can be used to read the data from the buffer. * * \parRelated APIs:
* XMC_SPI_CH_Receive() */ uint16_t XMC_SPI_CH_GetReceivedData(XMC_USIC_CH_t *const channel); /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription:
* Set the order of data transfer from LSB to MSB, by clearing SCTR.SDIR bit.\n\n * This is typically based on the slave settings. Invoke XMC_SPI_CH_SetBitOrderLsbFirst() to set direction as needed in * the program. * * \parRelated APIs:
* XMC_SPI_CH_SetBitOrderMsbFirst() */ __STATIC_INLINE void XMC_SPI_CH_SetBitOrderLsbFirst(XMC_USIC_CH_t *const channel) { channel->SCTR &= (uint32_t)~USIC_CH_SCTR_SDIR_Msk; } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription:
* Set the order of data transfer from MSB to LSB, by setting SCTR.SDIR bit.\n\n * This is typically based on the slave settings. This is not set during XMC_SPI_CH_Init(). * Invoke XMC_SPI_CH_SetBitOrderMsbFirst() to set direction as needed in the program. * * \parRelated APIs:
* XMC_SPI_CH_SetBitOrderLsbFirst() */ __STATIC_INLINE void XMC_SPI_CH_SetBitOrderMsbFirst(XMC_USIC_CH_t *const channel) { channel->SCTR |= (uint32_t)USIC_CH_SCTR_SDIR_Msk; } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param event Protocol events which have to be enabled. * Refer @ XMC_SPI_CH_EVENT_t for valid values. OR combinations of these enum items can be used * as input. * * @return None * * \parDescription:
* Enables the SPI protocol specific events, by configuring PCR register.\n\n * Events can be enabled as needed using XMC_SPI_CH_EnableEvent(). * XMC_SPI_CH_DisableEvent() can be used to disable the events. * * \parRelated APIs:
* XMC_SPI_CH_DisableEvent() */ void XMC_SPI_CH_EnableEvent(XMC_USIC_CH_t *const channel, const uint32_t event); /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param event Protocol events which have to be disabled. * Refer @ XMC_SPI_CH_EVENT_t for valid values. OR combinations of these enum item can be used * as input. * * @return None * * \parDescription:
* Disables the SPI protocol specific events, by configuring PCR register.\n\n * After disabling the events, XMC_SPI_CH_EnableEvent() has to be invoked to re-enable the events. * * \parRelated APIs:
* XMC_SPI_CH_EnableEvent() */ void XMC_SPI_CH_DisableEvent(XMC_USIC_CH_t *const channel, const uint32_t event); /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return uint32_t Status of SPI protocol events. * * \parDescription:
* Returns the status of the events, by reading PSR register.\n\n * This indicates the status of the all the events, for SPI communication. * * \parRelated APIs:
* XMC_SPI_CH_ClearStatusFlag() */ __STATIC_INLINE uint32_t XMC_SPI_CH_GetStatusFlag(XMC_USIC_CH_t *const channel) { return channel->PSR_SSCMode; } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param flag Protocol event status to be cleared for detection of next occurence. * Refer @ XMC_SPI_CH_STATUS_FLAG_t for valid values. OR combinations of these enum item can be used * as input. * @return None * * \parDescription:
* Clears the events specified, by setting PSCR register.\n\n * During communication the events occurred have to be cleared to detect their next occurence.\n * e.g: During transmission Transmit buffer event occurs to indicating data word transfer has started. This * event has to be cleared after transmission of each data word. Otherwise next event cannot be recognized. * * \parRelated APIs:
* XMC_SPI_CH_GetStatusFlag() */ __STATIC_INLINE void XMC_SPI_CH_ClearStatusFlag(XMC_USIC_CH_t *const channel, const uint32_t flag) { channel->PSCR |= flag; } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription:
* Enables the generation of Master clock by setting PCR.MCLK bit.\n\n * This clock can be used as a clock reference for external devices. This is not enabled during initialization in * XMC_SPI_CH_Init(). Invoke XMC_SPI_CH_EnableMasterClock() to enable as needed in the program, or if it is disabled by * XMC_SPI_CH_DisableMasterClock(). * * \parRelated APIs:
* XMC_SPI_CH_DisableMasterClock() */ __STATIC_INLINE void XMC_SPI_CH_EnableMasterClock(XMC_USIC_CH_t *const channel) { channel->PCR_SSCMode |= (uint32_t)USIC_CH_PCR_SSCMode_MCLK_Msk; } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription:
* Disables the generation of Master clock by clearing PCR.MCLK bit.\n\n * This clock can be enabled by invoking XMC_SPI_CH_EnableMasterClock() as needed in the program. * * \parRelated APIs:
* XMC_SPI_CH_EnableMasterClock() */ __STATIC_INLINE void XMC_SPI_CH_DisableMasterClock(XMC_USIC_CH_t *const channel) { channel->PCR_SSCMode &= (uint32_t)~USIC_CH_PCR_SSCMode_MCLK_Msk; } #ifdef USIC_CH_PCR_SSCMode_SLPHSEL_Msk /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription:
* Data bits are shifted out with the leading edge of the shift clock signal and latched in with the trailing edge. * * \parRelated APIs:
* XMC_SPI_CH_DataLatchedInLeadingEdge() */ __STATIC_INLINE void XMC_SPI_CH_DataLatchedInTrailingEdge(XMC_USIC_CH_t *const channel) { channel->PCR_SSCMode &= (uint32_t)~USIC_CH_PCR_SSCMode_SLPHSEL_Msk; } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription:
* The first data bit is shifted out when the data shift unit receives a low to high transition from the DX2 * stage. Subsequent bits are shifted out with the trailing edge of the shift clock signal. Data bits are * always latched in with the leading edge. * * \parRelated APIs:
* XMC_SPI_CH_DataLatchedInTrailingEdge() */ __STATIC_INLINE void XMC_SPI_CH_DataLatchedInLeadingEdge(XMC_USIC_CH_t *const channel) { channel->PCR_SSCMode |= USIC_CH_PCR_SSCMode_SLPHSEL_Msk; } #endif /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription:
* Enables the delay after each word, by setting PCR.TIWEN bit.\n\n * The inter word delay starts at the end of last SCLK cycle of data word. During this time no clock pulses are * generated and MSLS signal stays active. If inter word delay is not enabled, last data bit of a data word is directly * followed by the first data bit of the next data word. This is not enabled in XMC_SPI_CH_Init(). To enable * XMC_SPI_CH_EnableInterwordDelay() has to be invoked as needed in the program. And can be disabled by invoking * XMC_SPI_CH_DisableInterwordDelay(). * * \parRelated APIs:
* XMC_SPI_CH_DisableInterwordDelay() */ __STATIC_INLINE void XMC_SPI_CH_EnableInterwordDelay(XMC_USIC_CH_t *const channel) { channel->PCR_SSCMode |= (uint32_t)USIC_CH_PCR_SSCMode_TIWEN_Msk; } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription:
* Disables the delay after after each word, by clearing PCR.TIWEN bit.\n\n * So the last data bit of a data word is directly followed by the first data bit of the next data word. If needed can * be enabled by invoking XMC_SPI_CH_EnableInterwordDelay(). * * \parRelated APIs:
* XMC_SPI_CH_EnableInterwordDelay() */ __STATIC_INLINE void XMC_SPI_CH_DisableInterwordDelay(XMC_USIC_CH_t *const channel) { channel->PCR_SSCMode &= (uint32_t)~USIC_CH_PCR_SSCMode_TIWEN_Msk; } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param tinterword_delay_ns delay in terms of nano seconds. * * @return None * * \parDescription:
* Configures the inter word delay by setting PCR.PCTQ1, PCR.DCTQ1 bit fields.\n\n * The inter word delay is dependent on the peripheral clock. The maximum possible value is calculated by using the * below formula\n * Maximum inter word delay = ((1 + PCTQ1_max)(1 + DCTQ1_max)) / peripheral clock\n * where PCTQ1_max = 3 and DCTQ1_max = 31\n * After configuring the inter word delay, this has to be enabled by invoking XMC_SPI_CH_EnableInterwordDelay(). * * \parRelated APIs:
* XMC_SPI_CH_EnableInterwordDelay(),XMC_SPI_CH_SetInterwordDelaySCLK() */ void XMC_SPI_CH_SetInterwordDelay(XMC_USIC_CH_t *const channel,uint32_t tinterword_delay_ns); /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param sclk_period in terms of clk cycles. * * @return None * * \parDescription:
* Configures the inter word delay by setting PCR.DCTQ1 bit fields.\n\n * This delay is dependent on the peripheral clock. The maximum possible value supported by this API * is 32 clock cycles. * After configuring the inter word delay, this has to be enabled by invoking XMC_SPI_CH_EnableInterwordDelay(). * * \parRelated APIs:
* XMC_SPI_CH_EnableInterwordDelay(),XMC_SPI_CH_EnableInterwordDelay() */ __STATIC_INLINE void XMC_SPI_CH_SetInterwordDelaySCLK(XMC_USIC_CH_t *const channel,uint32_t sclk_period) { channel->PCR_SSCMode = (uint32_t)((channel->PCR_SSCMode) & (~(USIC_CH_PCR_SSCMode_DCTQ1_Msk | USIC_CH_PCR_SSCMode_PCTQ1_Msk | USIC_CH_PCR_SSCMode_CTQSEL1_Msk))) | (((sclk_period - 1U) << USIC_CH_PCR_SSCMode_DCTQ1_Pos) | (0x02U << USIC_CH_PCR_SSCMode_CTQSEL1_Pos)); } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param sclk_period delay in terms of sclk clock cycles. * * @return None * * \parDescription:
* Configures the leading/trailing delay by setting BRG.DCTQ bit field.\n\n * This delay is dependent on the peripheral clock. The maximum possible value supported by this API * is 30 clock cycles. * */ __STATIC_INLINE void XMC_SPI_CH_SetSlaveSelectDelay(XMC_USIC_CH_t *const channel,uint32_t sclk_period) { channel->BRG = (channel->BRG & ~(USIC_CH_BRG_DCTQ_Msk | USIC_CH_BRG_PCTQ_Msk)) | (((sclk_period - 1U) << USIC_CH_BRG_DCTQ_Pos) | (0x01U << USIC_CH_BRG_PCTQ_Pos)); } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription:
* * Configure to keep MSLS(Slave select signal) active even after finishing the current data frame, * by setting PCR.FEM bit.\n\n * This is typically used during the transmission of multi-data word frames, where there is possibility of delay in * delivering the data. Frame end mode is enabled in XMC_SPI_CH_Init() during initialization. To disable * XMC_SPI_CH_DisableFEM() can be invoked as needed in the program. * * \parRelated APIs:
* XMC_SPI_CH_DisableFEM() */ __STATIC_INLINE void XMC_SPI_CH_EnableFEM(XMC_USIC_CH_t *const channel) { channel->PCR_SSCMode |= (uint32_t)USIC_CH_PCR_SSCMode_FEM_Msk; } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription:
* Configure to disable the MSLS(Slave select signal) if the current data frame is considered as finished, * by setting PCR.FEM bit.\n\n * * When the last bit of a data word has been sent out and the transmit buffer TBUF does not contain new data, is * considered as frame is ended and MSLS(Slave select signal) is disabled. * * \parRelated APIs:
* XMC_SPI_CH_EnableFEM() */ __STATIC_INLINE void XMC_SPI_CH_DisableFEM(XMC_USIC_CH_t *const channel) { channel->PCR_SSCMode &= (uint32_t)~USIC_CH_PCR_SSCMode_FEM_Msk; } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param passive_level polarity and delay of the selected shift clock.\n * Refer @ref XMC_SPI_CH_BRG_SHIFT_CLOCK_PASSIVE_LEVEL_t for valid inputs. * @param clock_output shift clock source.\n * Refer @ref XMC_SPI_CH_BRG_SHIFT_CLOCK_OUTPUT_t for valid inputs. * * @return None * * \parDescription:
* Configures the shift clock source with the selected polarity and delay by setting BRG.SCLKOSEL and BRG.SCLKCFG.\n\n * In Master mode operation, shift clock is generated by the internal baud rate generator. This SCLK is made available * for external slave devices by SCLKOUT signal.\n * In Slave mode, the signal is received from the external master. So the DX1(input) stage has to be connected to input.\n * The shift clock output(SCLKOUT) signal polarity can be set relative to SCLK, with the delay of half the shift clock * period. These settings are applicable only in master mode. */ __STATIC_INLINE void XMC_SPI_CH_ConfigureShiftClockOutput(XMC_USIC_CH_t *const channel, const XMC_SPI_CH_BRG_SHIFT_CLOCK_PASSIVE_LEVEL_t passive_level, const XMC_SPI_CH_BRG_SHIFT_CLOCK_OUTPUT_t clock_output) { XMC_USIC_CH_ConfigureShiftClockOutput(channel, (XMC_USIC_CH_BRG_SHIFT_CLOCK_PASSIVE_LEVEL_t)passive_level, (XMC_USIC_CH_BRG_SHIFT_CLOCK_OUTPUT_t)clock_output); } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param word_length Number of bits to be configured for a data word. \n * \b Range: 1 to 16. * * @return None * * \parDescription
* Defines the data word length.\n\n * Sets the number of bits to represent a data word. Frame length should be a multiple of word length. * * \parRelated APIs:
* XMC_SPI_CH_SetFrameLength() */ __STATIC_INLINE void XMC_SPI_CH_SetWordLength(XMC_USIC_CH_t *const channel, const uint8_t word_length) { XMC_USIC_CH_SetWordLength(channel, word_length); } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param frame_length Number of bits in a frame. \n * \b Range: 1 to 64. If the value 64 is configured, then the frame does not * automatically end. User should explicitly end the frame. * * @return None * * \parDescription
* Define the data frame length.\n\n * Set the number of bits to be serially transmitted in a frame. * The frame length should be multiples of word length. If the value is set to 64, the frame does not * automatically end. Use XMC_SPI_CH_DisableSlaveSelect() to end the frame after all the data * is transmitted. * * \parRelated APIs:
* XMC_USIC_CH_SetWordLength(), XMC_USIC_CH_EnableFrameLengthControl(), XMC_SPI_CH_DisableSlaveSelect() */ __STATIC_INLINE void XMC_SPI_CH_SetFrameLength(XMC_USIC_CH_t *const channel, const uint8_t frame_length) { XMC_USIC_CH_SetFrameLength(channel, frame_length); } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription
* Configure the handling of start of frame through software, by setting TCSR.SOF bit.\n\n * This can be used if the software handles the TBUF data without FIFO. If SOF is set, a valid content of the TBUF is * considered as first word of a new frame by finishing the currently running frame. For software handling of SOF bit, * it is recommended to configure TCSR.WLEMD as 0. This is not configured during initialization. XMC_SPI_CH_EnableSOF() * can be called as needed in the program and can be disabled by XMC_SPI_CH_DisableSOF(). * * \parRelated APIs:
* XMC_SPI_CH_DisableSOF() */ __STATIC_INLINE void XMC_SPI_CH_EnableSOF(XMC_USIC_CH_t *const channel) { channel->TCSR |= (uint32_t)USIC_CH_TCSR_SOF_Msk; } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription
* Set the control of the handling start of frame through hardware, by clearing TCSR.SOF bit.\n\n * Typically this can be disabled, where the transmission control is done by the hardware. * * \parRelated APIs:
* XMC_SPI_CH_EnableSOF() */ __STATIC_INLINE void XMC_SPI_CH_DisableSOF(XMC_USIC_CH_t *const channel) { channel->TCSR &= (uint32_t)~USIC_CH_TCSR_SOF_Msk; } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription
* Configure the handling of end of frame through software, by setting TCSR.EOF bit.\n\n * This can be used if the software handles the TBUF data without FIFO. If EOF is set, a valid content of the TBUF is * considered as last word of a frame. After transfer of the last word, MSLS signal becomes inactive. For software * handling of EOF bit, it is recommended to configure TCSR.WLEMD as 0. \n * \b Note: The API should be called before putting the last data word of the frame to TBUF. * * \parRelated APIs:
* XMC_SPI_CH_DisableEOF() */ __STATIC_INLINE void XMC_SPI_CH_EnableEOF(XMC_USIC_CH_t *const channel) { channel->TCSR |= (uint32_t)USIC_CH_TCSR_EOF_Msk; } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription
* Configure the handling of end of frame through hardware, by clearing TCSR.EOF bit.\n\n * Typically this can be disabled, where the transmission control is done by the hardware. * * \parRelated APIs:
* XMC_SPI_CH_EnableEOF() */ __STATIC_INLINE void XMC_SPI_CH_DisableEOF(XMC_USIC_CH_t *const channel) { channel->TCSR &= (uint32_t)~USIC_CH_TCSR_EOF_Msk; } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param input SPI channel input stage.\n * Refer @ref XMC_SPI_CH_INPUT_t for valid values * @param source Input source select for the input stage. * Range : [0 to 7] * * @return None * * \parDescription
* Selects the data source for SPI input stage, by configuring DXCR.DSEL bits.\n\n * Selects the input data signal source among DXnA, DXnB.. DXnG for the input stage. The API can be used for all the * input stages like DX0CR, DX1CR etc. This is not done during initialization. This has to be configured before starting * the SPI communication. */ __STATIC_INLINE void XMC_SPI_CH_SetInputSource(XMC_USIC_CH_t *const channel, const XMC_SPI_CH_INPUT_t input, const uint8_t source) { channel->DXCR[input] = (uint32_t)(channel->DXCR[input] & (~USIC_CH_DX0CR_DSEN_Msk)) | USIC_CH_DX0CR_INSW_Msk; XMC_USIC_CH_SetInputSource(channel, (XMC_USIC_CH_INPUT_t)input, source); } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param selo_inversion Polarity of the slave select signal relative to the MSLS signal.\n * Refer @ref XMC_SPI_CH_SLAVE_SEL_MSLS_INV_t for valid values * * @return None * * \parDescription
* Set the polarity of the slave select signal, by configuring PCR.SELINV bit.\n\n * Normally MSLS signal is active low level signal. SO based on the slave inversion has to be applied. This is configured * in XMC_SPI_CH_Init() during initialization. Invoke XMC_SPI_CH_SetSlaveSelectPolarity() with desired settings as * needed later in the program. */ __STATIC_INLINE void XMC_SPI_CH_SetSlaveSelectPolarity(XMC_USIC_CH_t *const channel, const XMC_SPI_CH_SLAVE_SEL_MSLS_INV_t selo_inversion) { /* Configuration of Protocol Control Register */ channel->PCR_SSCMode = (uint32_t)((channel->PCR_SSCMode & (~USIC_CH_PCR_SSCMode_SELINV_Msk)) | (uint32_t)selo_inversion); } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param input SPI channel input stage.\n * Refer @ref XMC_SPI_CH_INPUT_t for valid inputs. * * @return None * * \parDescription
* Enables the polarity inversion of input data signal, by setting DXyCR.DPOL(where y = \a input).\n\n * This is not set in XMC_SPI_CH_Init(). Invoke XMC_SPI_CH_EnableInputInversion() as needed later in the program. To * disable the inversion XMC_SPI_CH_DisableInputInversion() can be invoked. * * \parRelated APIs:
* XMC_SPI_CH_DisableInputInversion() */ __STATIC_INLINE void XMC_SPI_CH_EnableInputInversion(XMC_USIC_CH_t *const channel, const XMC_SPI_CH_INPUT_t input) { XMC_USIC_CH_EnableInputInversion(channel, (XMC_USIC_CH_INPUT_t)input); } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param input SPI channel input stage.\n * Refer @ref XMC_SPI_CH_INPUT_t for valid inputs. * * @return None * * \parDescription
* Disables the polarity inversion of input data signal, by clearing DXyCR.DPOL(where y = \a input).\n\n * Resets the input data polarity. Invoke XMC_SPI_CH_EnableInputInversion() to apply inversion. * * \parRelated APIs:
* XMC_SPI_CH_EnableInputInversion() */ __STATIC_INLINE void XMC_SPI_CH_DisableInputInversion(XMC_USIC_CH_t *const channel, const XMC_SPI_CH_INPUT_t input) { XMC_USIC_CH_DisableInputInversion(channel, (XMC_USIC_CH_INPUT_t)input); } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * @param service_request Service request number. Range: [0 to 5] * * @return None * * \parDescription
* Sets the interrupt node for SPI channel events.\n\n * For an event to generate interrupt, node pointer should be configured with service request(SR0, SR1..SR5). * The NVIC node gets linked to the interrupt event by doing so. This is not configured in XMC_SPI_CH_Init() during * initialization. * * \parNote::
* 1. NVIC node should be separately enabled to generate the interrupt. * * \parRelated APIs:
* XMC_USIC_CH_EnableEvent() */ __STATIC_INLINE void XMC_SPI_CH_SetInterruptNodePointer(XMC_USIC_CH_t *const channel, const uint8_t service_request) { XMC_USIC_CH_SetInterruptNodePointer(channel, XMC_USIC_CH_INTERRUPT_NODE_POINTER_PROTOCOL, (uint32_t)service_request); } /** * @param channel Pointer to USIC channel handler of type @ref XMC_USIC_CH_t \n * \b Range: @ref XMC_SPI0_CH0, @ref XMC_SPI0_CH1,@ref XMC_SPI1_CH0,@ref XMC_SPI1_CH1,@ref XMC_SPI2_CH0,@ref XMC_SPI2_CH1 @note Availability of SPI1 and SPI2 depends on device selection * @param interrupt_node Interrupt node pointer to be configured. \n * \b Range: @ref XMC_SPI_CH_INTERRUPT_NODE_POINTER_TRANSMIT_SHIFT, * @ref XMC_SPI_CH_INTERRUPT_NODE_POINTER_TRANSMIT_BUFFER etc. * @param service_request Service request number.\n * \b Range: 0 to 5. * @return None * * \parDescription
* Sets the interrupt node for USIC channel events. \n\n * For an event to generate interrupt, node pointer should be configured with service request(SR0, SR1..SR5). * The NVIC node gets linked to the interrupt event by doing so.
* Note: NVIC node should be separately enabled to generate the interrupt. * * \parRelated APIs:
* XMC_SPI_CH_EnableEvent() \n\n\n */ __STATIC_INLINE void XMC_SPI_CH_SelectInterruptNodePointer(XMC_USIC_CH_t *const channel, const XMC_SPI_CH_INTERRUPT_NODE_POINTER_t interrupt_node, const uint32_t service_request) { XMC_USIC_CH_SetInterruptNodePointer(channel, (XMC_USIC_CH_INTERRUPT_NODE_POINTER_t)interrupt_node, (uint32_t)service_request); } /** * @param channel Pointer to USIC channel handler of type @ref XMC_USIC_CH_t \n * \b Range: @ref XMC_SPI0_CH0, @ref XMC_SPI0_CH1,@ref XMC_SPI1_CH0,@ref XMC_SPI1_CH1,@ref XMC_SPI2_CH0,@ref XMC_SPI2_CH1 @note Availability of SPI1 and SPI2 depends on device selection * @param service_request_line service request number of the event to be triggered. \n * \b Range: 0 to 5. * @return None * * \parDescription
* Trigger a SPI interrupt service request.\n\n * When the SPI service request is triggered, the NVIC interrupt associated with it will be * generated if enabled. * * \parRelated APIs:
* XMC_SPI_CH_SelectInterruptNodePointer() \n\n\n */ __STATIC_INLINE void XMC_SPI_CH_TriggerServiceRequest(XMC_USIC_CH_t *const channel, const uint32_t service_request_line) { XMC_USIC_CH_TriggerServiceRequest(channel, (uint32_t)service_request_line); } /** * @param channel Pointer to USIC channel handler of type @ref XMC_USIC_CH_t \n * \b Range: @ref XMC_SPI0_CH0, @ref XMC_SPI0_CH1,@ref XMC_SPI1_CH0,@ref XMC_SPI1_CH1,@ref XMC_SPI2_CH0,@ref XMC_SPI2_CH1 @note Availability of SPI1 and SPI2 depends on device selection * @return None * * \parDescription
* Enables delay compensation. \n\n * * Delay compensation can be applied to the receive path. * \parRelated APIs:
* XMC_SPI_CH_DisableDelayCompensation()\n\n\n */ __STATIC_INLINE void XMC_SPI_CH_EnableDelayCompensation(XMC_USIC_CH_t *const channel) { XMC_USIC_CH_EnableDelayCompensation(channel); } /** * @param channel Pointer to USIC channel handler of type @ref XMC_USIC_CH_t \n * \b Range: @ref XMC_SPI0_CH0, @ref XMC_SPI0_CH1,@ref XMC_SPI1_CH0,@ref XMC_SPI1_CH1,@ref XMC_SPI2_CH0,@ref XMC_SPI2_CH1 @note Availability of SPI1 and SPI2 depends on device selection * @return None * * \parDescription
* Disables delay compensation.. \n\n * * \parRelated APIs:
* XMC_SPI_CH_EnableDelayCompensation()\n\n\n */ __STATIC_INLINE void XMC_SPI_CH_DisableDelayCompensation(XMC_USIC_CH_t *const channel) { XMC_USIC_CH_DisableDelayCompensation(channel); } /** * @param channel Pointer to USIC channel handler of type @ref XMC_USIC_CH_t \n * \b Range: @ref XMC_SPI0_CH0, @ref XMC_SPI0_CH1,@ref XMC_SPI1_CH0,@ref XMC_SPI1_CH1,@ref XMC_SPI2_CH0,@ref XMC_SPI2_CH1 @note Availability of SPI1 and SPI2 depends on device selection * @param pdiv Desired divider for the external frequency input. \b Range: minimum value = 1, maximum value = 1024 \n * @param combination_mode USIC channel input combination mode \n * * @return None * * \parDescription
* Enables the external frequency input for the Baudrate Generator and configures the divider, oversampling and * the combination mode of the USIC channel. \n\n * * \parRelated APIs:
* XMC_USIC_CH_SetBRGInputClockSource(), XMC_USIC_CH_SetInputTriggerCombinationMode() \n\n\n */ __STATIC_INLINE void XMC_SPI_CH_ConfigExternalInputSignalToBRG(XMC_USIC_CH_t *const channel, const uint16_t pdiv, const XMC_USIC_CH_INPUT_COMBINATION_MODE_t combination_mode) { XMC_USIC_CH_ConfigExternalInputSignalToBRG(channel,pdiv,2U,combination_mode); } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription
* The SELOx lines (with x = 1-7) can be used as addresses for an external address * decoder to increase the number of external slave devices. */ __STATIC_INLINE void XMC_SPI_CH_EnableSlaveSelectCodedMode(XMC_USIC_CH_t *const channel) { /* Configuration of Protocol Control Register */ channel->PCR_SSCMode = (uint32_t)(channel->PCR_SSCMode & (~USIC_CH_PCR_SSCMode_SELCTR_Msk)); } /** * @param channel A constant pointer to XMC_USIC_CH_t, pointing to the USIC channel base address. * * @return None * * \parDescription
* Each SELOx line (with x = 0-7) can be directly connected to an external slave device. */ __STATIC_INLINE void XMC_SPI_CH_DisableSlaveSelectCodedMode(XMC_USIC_CH_t *const channel) { /* Configuration of Protocol Control Register */ channel->PCR_SSCMode |= (uint32_t)USIC_CH_PCR_SSCMode_SELCTR_Msk; } /** * @param channel Constant pointer to USIC channel handle of type @ref XMC_USIC_CH_t \n * \b Range: @ref XMC_SPI0_CH0, @ref XMC_SPI0_CH1,@ref XMC_SPI1_CH0,@ref XMC_SPI1_CH1,@ref XMC_SPI2_CH0,@ref XMC_SPI2_CH1 @note Availability of SPI1 and SPI2 depends on device selection * @return None * * \parDescription
* Enable data transmission.\n\n * Use this function in combination with XMC_SPI_CH_DisableDataTransmission() to fill the FIFO and send the FIFO content without gaps in the transmission. * FIFO is filled using XMC_USIC_CH_TXFIFO_PutData(). * @note If you need more control over the start of transmission use XMC_USIC_CH_SetStartTransmisionMode() * * \parRelated APIs:
* XMC_SPI_CH_DisableDataTransmission()\n\n\n */ __STATIC_INLINE void XMC_SPI_CH_EnableDataTransmission(XMC_USIC_CH_t *const channel) { XMC_USIC_CH_SetStartTransmisionMode(channel, XMC_USIC_CH_START_TRANSMISION_ON_TDV); } /** * @param channel Constant pointer to USIC channel handle of type @ref XMC_USIC_CH_t \n * \b Range: @ref XMC_SPI0_CH0, @ref XMC_SPI0_CH1,@ref XMC_SPI1_CH0,@ref XMC_SPI1_CH1,@ref XMC_SPI2_CH0,@ref XMC_SPI2_CH1 @note Availability of SPI1 and SPI2 depends on device selection * @return None * * \parDescription
* Disable data transmission.\n\n * Use this function in combination with XMC_SPI_CH_EnableDataTransmission() to fill the FIFO and send the FIFO content without gaps in the transmission. * FIFO is filled using XMC_USIC_CH_TXFIFO_PutData(). * * \parRelated APIs:
* XMC_SPI_CH_EnableDataTransmission()\n\n\n */ __STATIC_INLINE void XMC_SPI_CH_DisableDataTransmission(XMC_USIC_CH_t *const channel) { XMC_USIC_CH_SetStartTransmisionMode(channel, XMC_USIC_CH_START_TRANSMISION_DISABLED); } #ifdef __cplusplus } #endif /** * @} */ /** * @} */ #endif