/****************************************************************************** * * Copyright (C) 2022-2023 Maxim Integrated Products, Inc. (now owned by * Analog Devices, Inc.), * Copyright (C) 2023-2024 Analog Devices, Inc. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * ******************************************************************************/ #include #include #include #include "mxc_device.h" #include "mxc_assert.h" #include "mxc_lock.h" #include "mxc_sys.h" #include "mxc_delay.h" #include "spi_reva1.h" #include "dma.h" /* **** Functions **** */ int MXC_SPI_Init(mxc_spi_regs_t *spi, int masterMode, int quadModeUsed, int numSlaves, unsigned ssPolarity, unsigned int hz) { uint8_t spi_num; spi_num = MXC_SPI_GET_IDX(spi); MXC_ASSERT(spi_num >= 0); if (numSlaves > MXC_SPI_SS_INSTANCES) { return E_BAD_PARAM; } // Check if frequency is too high if (hz > PeripheralClock) { return E_BAD_PARAM; } #ifndef MSDK_NO_GPIO_CLK_INIT // Configure GPIO for spi if (spi == MXC_SPI0) { MXC_SYS_ClockEnable(MXC_SYS_PERIPH_CLOCK_SPI0); MXC_SYS_Reset_Periph(MXC_SYS_RESET0_SPI0); MXC_GPIO_Config(&gpio_cfg_spi0); } else if (spi == MXC_SPI1) { MXC_SYS_ClockEnable(MXC_SYS_PERIPH_CLOCK_SPI1); MXC_SYS_Reset_Periph(MXC_SYS_RESET0_SPI1); MXC_GPIO_Config(&gpio_cfg_spi1); } else if (spi == MXC_SPI2) { MXC_SYS_ClockEnable(MXC_SYS_PERIPH_CLOCK_SPI2); MXC_SYS_Reset_Periph(MXC_SYS_RESET0_SPI2); MXC_GPIO_Config(&gpio_cfg_spi2); } else { return E_NO_DEVICE; } #endif // MSDK_NO_GPIO_CLK_INIT return MXC_SPI_RevA1_Init(spi, masterMode, quadModeUsed, numSlaves, ssPolarity, hz); } int MXC_SPI_Shutdown(mxc_spi_regs_t *spi) { int spi_num; spi_num = MXC_SPI_GET_IDX(spi); MXC_ASSERT(spi_num >= 0); MXC_SPI_RevA1_Shutdown(spi); if (spi == MXC_SPI0) { MXC_SYS_ClockDisable(MXC_SYS_PERIPH_CLOCK_SPI0); } else if (spi == MXC_SPI1) { MXC_SYS_ClockDisable(MXC_SYS_PERIPH_CLOCK_SPI1); } else if (spi == MXC_SPI2) { MXC_SYS_ClockDisable(MXC_SYS_PERIPH_CLOCK_SPI2); } else { return E_INVALID; } return E_NO_ERROR; } int MXC_SPI_ReadyForSleep(mxc_spi_regs_t *spi) { return MXC_SPI_RevA1_ReadyForSleep(spi); } int MXC_SPI_GetPeripheralClock(mxc_spi_regs_t *spi) { if (MXC_SPI_GET_IDX(spi) != -1) { return PeripheralClock; } else { return E_BAD_PARAM; } return E_NO_ERROR; } int MXC_SPI_SetFrequency(mxc_spi_regs_t *spi, unsigned int hz) { return MXC_SPI_RevA1_SetFrequency(spi, hz); } unsigned int MXC_SPI_GetFrequency(mxc_spi_regs_t *spi) { return MXC_SPI_RevA1_GetFrequency(spi); } int MXC_SPI_SetDataSize(mxc_spi_regs_t *spi, int dataSize) { return MXC_SPI_RevA1_SetDataSize(spi, dataSize); } int MXC_SPI_GetDataSize(mxc_spi_regs_t *spi) { return MXC_SPI_RevA1_GetDataSize(spi); } int MXC_SPI_SetSlave(mxc_spi_regs_t *spi, int ssIdx) { return MXC_SPI_RevA1_SetSlave(spi, ssIdx); } int MXC_SPI_GetSlave(mxc_spi_regs_t *spi) { return MXC_SPI_RevA1_GetSlave(spi); } int MXC_SPI_SetWidth(mxc_spi_regs_t *spi, mxc_spi_width_t spiWidth) { return MXC_SPI_RevA1_SetWidth(spi, spiWidth); } mxc_spi_width_t MXC_SPI_GetWidth(mxc_spi_regs_t *spi) { return MXC_SPI_RevA1_GetWidth(spi); } int MXC_SPI_SetMode(mxc_spi_regs_t *spi, mxc_spi_mode_t spiMode) { return MXC_SPI_RevA1_SetMode((mxc_spi_reva_regs_t *)spi, spiMode); } mxc_spi_mode_t MXC_SPI_GetMode(mxc_spi_regs_t *spi) { return MXC_SPI_RevA1_GetMode((mxc_spi_reva_regs_t *)spi); } int MXC_SPI_StartTransmission(mxc_spi_regs_t *spi) { return MXC_SPI_RevA1_StartTransmission(spi); } int MXC_SPI_GetActive(mxc_spi_regs_t *spi) { return MXC_SPI_RevA1_GetActive(spi); } int MXC_SPI_AbortTransmission(mxc_spi_regs_t *spi) { return MXC_SPI_RevA1_AbortTransmission(spi); } unsigned int MXC_SPI_ReadRXFIFO(mxc_spi_regs_t *spi, unsigned char *bytes, unsigned int len) { return MXC_SPI_RevA1_ReadRXFIFO(spi, bytes, len); } unsigned int MXC_SPI_GetRXFIFOAvailable(mxc_spi_regs_t *spi) { return MXC_SPI_RevA1_GetRXFIFOAvailable(spi); } unsigned int MXC_SPI_WriteTXFIFO(mxc_spi_regs_t *spi, unsigned char *bytes, unsigned int len) { return MXC_SPI_RevA1_WriteTXFIFO(spi, bytes, len); } unsigned int MXC_SPI_GetTXFIFOAvailable(mxc_spi_regs_t *spi) { return MXC_SPI_RevA1_GetTXFIFOAvailable(spi); } void MXC_SPI_ClearRXFIFO(mxc_spi_regs_t *spi) { MXC_SPI_RevA1_ClearRXFIFO(spi); } void MXC_SPI_ClearTXFIFO(mxc_spi_regs_t *spi) { MXC_SPI_RevA1_ClearTXFIFO(spi); } int MXC_SPI_SetRXThreshold(mxc_spi_regs_t *spi, unsigned int numBytes) { return MXC_SPI_RevA1_SetRXThreshold(spi, numBytes); } unsigned int MXC_SPI_GetRXThreshold(mxc_spi_regs_t *spi) { return MXC_SPI_RevA1_GetRXThreshold(spi); } int MXC_SPI_SetTXThreshold(mxc_spi_regs_t *spi, unsigned int numBytes) { return MXC_SPI_RevA1_SetTXThreshold(spi, numBytes); } unsigned int MXC_SPI_GetTXThreshold(mxc_spi_regs_t *spi) { return MXC_SPI_RevA1_GetTXThreshold(spi); } unsigned int MXC_SPI_GetFlags(mxc_spi_regs_t *spi) { return MXC_SPI_RevA1_GetFlags(spi); } void MXC_SPI_ClearFlags(mxc_spi_regs_t *spi) { MXC_SPI_RevA1_ClearFlags(spi); } void MXC_SPI_EnableInt(mxc_spi_regs_t *spi, unsigned int mask) { MXC_SPI_RevA1_EnableInt(spi, mask); } void MXC_SPI_DisableInt(mxc_spi_regs_t *spi, unsigned int mask) { MXC_SPI_RevA1_DisableInt(spi, mask); } int MXC_SPI_MasterTransaction(mxc_spi_req_t *req) { return MXC_SPI_RevA1_MasterTransaction(req); } int MXC_SPI_MasterTransactionAsync(mxc_spi_req_t *req) { return MXC_SPI_RevA1_MasterTransactionAsync(req); } int MXC_SPI_MasterTransactionDMA(mxc_spi_req_t *req) { int reqselTx = -1; int reqselRx = -1; int spi_num; spi_num = MXC_SPI_GET_IDX(req->spi); MXC_ASSERT(spi_num >= 0); if (req->txData != NULL) { switch (spi_num) { case 0: reqselTx = MXC_DMA_REQUEST_SPI0TX; break; case 1: reqselTx = MXC_DMA_REQUEST_SPI1TX; break; case 2: reqselTx = MXC_DMA_REQUEST_SPI2TX; break; case 3: reqselTx = MXC_DMA_REQUEST_SPI3TX; break; } } if (req->rxData != NULL) { switch (spi_num) { case 0: reqselRx = MXC_DMA_REQUEST_SPI0TX; break; case 1: reqselRx = MXC_DMA_REQUEST_SPI1TX; break; case 2: reqselRx = MXC_DMA_REQUEST_SPI2TX; break; case 3: reqselRx = MXC_DMA_REQUEST_SPI3TX; break; } } return MXC_SPI_RevA1_MasterTransactionDMA(req, reqselTx, reqselRx); } int MXC_SPI_SlaveTransaction(mxc_spi_req_t *req) { return MXC_SPI_RevA1_SlaveTransaction(req); } int MXC_SPI_SlaveTransactionAsync(mxc_spi_req_t *req) { return MXC_SPI_RevA1_SlaveTransactionAsync(req); } int MXC_SPI_SlaveTransactionDMA(mxc_spi_req_t *req) { int reqselTx = -1; int reqselRx = -1; int spi_num; spi_num = MXC_SPI_GET_IDX(req->spi); MXC_ASSERT(spi_num >= 0); if (req->txData != NULL) { switch (spi_num) { case 0: reqselTx = MXC_DMA_REQUEST_SPI0TX; break; case 1: reqselTx = MXC_DMA_REQUEST_SPI1TX; break; case 2: reqselTx = MXC_DMA_REQUEST_SPI2TX; break; case 3: reqselTx = MXC_DMA_REQUEST_SPI3TX; break; } } if (req->rxData != NULL) { switch (spi_num) { case 0: reqselRx = MXC_DMA_REQUEST_SPI0TX; break; case 1: reqselRx = MXC_DMA_REQUEST_SPI1TX; break; case 2: reqselRx = MXC_DMA_REQUEST_SPI2TX; break; case 3: reqselRx = MXC_DMA_REQUEST_SPI3TX; break; } } return MXC_SPI_RevA1_SlaveTransactionDMA(req, reqselTx, reqselRx); } int MXC_SPI_SetDefaultTXData(mxc_spi_regs_t *spi, unsigned int defaultTXData) { return MXC_SPI_RevA1_SetDefaultTXData(spi, defaultTXData); } void MXC_SPI_AbortAsync(mxc_spi_regs_t *spi) { MXC_SPI_RevA1_AbortAsync(spi); } void MXC_SPI_AsyncHandler(mxc_spi_regs_t *spi) { MXC_SPI_RevA1_AsyncHandler(spi); } void MXC_SPI_HWSSControl(mxc_spi_regs_t *spi, int state) { MXC_SPI_RevA1_HWSSControl((mxc_spi_reva_regs_t *)spi, state); }