/* * Copyright (c) 2016 BayLibre, SAS * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT st_stm32_spi #define LOG_LEVEL CONFIG_SPI_LOG_LEVEL #include LOG_MODULE_REGISTER(spi_ll_stm32); #include #include #include #include #include #include #include #ifdef CONFIG_SPI_STM32_DMA #include #include #endif #include #include #include #include "spi_ll_stm32.h" #define DEV_CFG(dev) \ (const struct spi_stm32_config * const)(dev->config) #define DEV_DATA(dev) \ (struct spi_stm32_data * const)(dev->data) /* * Check for SPI_SR_FRE to determine support for TI mode frame format * error flag, because STM32F1 SoCs do not support it and STM32CUBE * for F1 family defines an unused LL_SPI_SR_FRE. */ #if defined(CONFIG_SOC_SERIES_STM32MP1X) || \ defined(CONFIG_SOC_SERIES_STM32H7X) #define SPI_STM32_ERR_MSK (LL_SPI_SR_UDR | LL_SPI_SR_CRCE | LL_SPI_SR_MODF | \ LL_SPI_SR_OVR | LL_SPI_SR_TIFRE) #else #if defined(LL_SPI_SR_UDR) #define SPI_STM32_ERR_MSK (LL_SPI_SR_UDR | LL_SPI_SR_CRCERR | LL_SPI_SR_MODF | \ LL_SPI_SR_OVR | LL_SPI_SR_FRE) #elif defined(SPI_SR_FRE) #define SPI_STM32_ERR_MSK (LL_SPI_SR_CRCERR | LL_SPI_SR_MODF | \ LL_SPI_SR_OVR | LL_SPI_SR_FRE) #else #define SPI_STM32_ERR_MSK (LL_SPI_SR_CRCERR | LL_SPI_SR_MODF | LL_SPI_SR_OVR) #endif #endif /* CONFIG_SOC_SERIES_STM32MP1X */ #ifdef CONFIG_SPI_STM32_DMA /* dummy value used for transferring NOP when tx buf is null * and use as dummy sink for when rx buf is null */ uint32_t dummy_rx_tx_buffer; /* This function is executed in the interrupt context */ static void dma_callback(const struct device *dev, void *arg, uint32_t channel, int status) { /* arg directly holds the spi device */ struct spi_stm32_data *data = arg; if (status != 0) { LOG_ERR("DMA callback error with channel %d.", channel); data->status_flags |= SPI_STM32_DMA_ERROR_FLAG; } else { /* identify the origin of this callback */ if (channel == data->dma_tx.channel) { /* this part of the transfer ends */ data->status_flags |= SPI_STM32_DMA_TX_DONE_FLAG; } else if (channel == data->dma_rx.channel) { /* this part of the transfer ends */ data->status_flags |= SPI_STM32_DMA_RX_DONE_FLAG; } else { LOG_ERR("DMA callback channel %d is not valid.", channel); data->status_flags |= SPI_STM32_DMA_ERROR_FLAG; } } k_sem_give(&data->status_sem); } static int spi_stm32_dma_tx_load(const struct device *dev, const uint8_t *buf, size_t len) { const struct spi_stm32_config *cfg = DEV_CFG(dev); struct spi_stm32_data *data = DEV_DATA(dev); struct dma_block_config *blk_cfg; int ret; /* remember active TX DMA channel (used in callback) */ struct stream *stream = &data->dma_tx; blk_cfg = &stream->dma_blk_cfg; /* prepare the block for this TX DMA channel */ memset(blk_cfg, 0, sizeof(struct dma_block_config)); blk_cfg->block_size = len; /* tx direction has memory as source and periph as dest. */ if (buf == NULL) { dummy_rx_tx_buffer = 0; /* if tx buff is null, then sends NOP on the line. */ blk_cfg->source_address = (uint32_t)&dummy_rx_tx_buffer; blk_cfg->source_addr_adj = DMA_ADDR_ADJ_NO_CHANGE; } else { blk_cfg->source_address = (uint32_t)buf; if (data->dma_tx.src_addr_increment) { blk_cfg->source_addr_adj = DMA_ADDR_ADJ_INCREMENT; } else { blk_cfg->source_addr_adj = DMA_ADDR_ADJ_NO_CHANGE; } } blk_cfg->dest_address = (uint32_t)LL_SPI_DMA_GetRegAddr(cfg->spi); /* fifo mode NOT USED there */ if (data->dma_tx.dst_addr_increment) { blk_cfg->dest_addr_adj = DMA_ADDR_ADJ_INCREMENT; } else { blk_cfg->dest_addr_adj = DMA_ADDR_ADJ_NO_CHANGE; } /* give the fifo mode from the DT */ blk_cfg->fifo_mode_control = data->dma_tx.fifo_threshold; /* direction is given by the DT */ stream->dma_cfg.head_block = blk_cfg; /* give the client dev as arg, as the callback comes from the dma */ stream->dma_cfg.user_data = data; /* pass our client origin to the dma: data->dma_tx.dma_channel */ ret = dma_config(data->dma_tx.dma_dev, data->dma_tx.channel, &stream->dma_cfg); /* the channel is the actual stream from 0 */ if (ret != 0) { return ret; } /* gives the request ID to the dma mux */ return dma_start(data->dma_tx.dma_dev, data->dma_tx.channel); } static int spi_stm32_dma_rx_load(const struct device *dev, uint8_t *buf, size_t len) { const struct spi_stm32_config *cfg = DEV_CFG(dev); struct spi_stm32_data *data = DEV_DATA(dev); struct dma_block_config *blk_cfg; int ret; /* retrieve active RX DMA channel (used in callback) */ struct stream *stream = &data->dma_rx; blk_cfg = &stream->dma_blk_cfg; /* prepare the block for this RX DMA channel */ memset(blk_cfg, 0, sizeof(struct dma_block_config)); blk_cfg->block_size = len; /* rx direction has periph as source and mem as dest. */ if (buf == NULL) { /* if rx buff is null, then write data to dummy address. */ blk_cfg->dest_address = (uint32_t)&dummy_rx_tx_buffer; blk_cfg->dest_addr_adj = DMA_ADDR_ADJ_NO_CHANGE; } else { blk_cfg->dest_address = (uint32_t)buf; if (data->dma_rx.dst_addr_increment) { blk_cfg->dest_addr_adj = DMA_ADDR_ADJ_INCREMENT; } else { blk_cfg->dest_addr_adj = DMA_ADDR_ADJ_NO_CHANGE; } } blk_cfg->source_address = (uint32_t)LL_SPI_DMA_GetRegAddr(cfg->spi); if (data->dma_rx.src_addr_increment) { blk_cfg->source_addr_adj = DMA_ADDR_ADJ_INCREMENT; } else { blk_cfg->source_addr_adj = DMA_ADDR_ADJ_NO_CHANGE; } /* give the fifo mode from the DT */ blk_cfg->fifo_mode_control = data->dma_rx.fifo_threshold; /* direction is given by the DT */ stream->dma_cfg.head_block = blk_cfg; stream->dma_cfg.user_data = data; /* pass our client origin to the dma: data->dma_rx.channel */ ret = dma_config(data->dma_rx.dma_dev, data->dma_rx.channel, &stream->dma_cfg); /* the channel is the actual stream from 0 */ if (ret != 0) { return ret; } /* gives the request ID to the dma mux */ return dma_start(data->dma_rx.dma_dev, data->dma_rx.channel); } static int spi_dma_move_buffers(const struct device *dev, size_t len) { struct spi_stm32_data *data = DEV_DATA(dev); int ret; size_t dma_segment_len; dma_segment_len = len / data->dma_rx.dma_cfg.dest_data_size; ret = spi_stm32_dma_rx_load(dev, data->ctx.rx_buf, dma_segment_len); if (ret != 0) { return ret; } dma_segment_len = len / data->dma_tx.dma_cfg.source_data_size; ret = spi_stm32_dma_tx_load(dev, data->ctx.tx_buf, dma_segment_len); return ret; } #endif /* CONFIG_SPI_STM32_DMA */ /* Value to shift out when no application data needs transmitting. */ #define SPI_STM32_TX_NOP 0x00 static bool spi_stm32_transfer_ongoing(struct spi_stm32_data *data) { return spi_context_tx_on(&data->ctx) || spi_context_rx_on(&data->ctx); } static int spi_stm32_get_err(SPI_TypeDef *spi) { uint32_t sr = LL_SPI_ReadReg(spi, SR); if (sr & SPI_STM32_ERR_MSK) { LOG_ERR("%s: err=%d", __func__, sr & (uint32_t)SPI_STM32_ERR_MSK); /* OVR error must be explicitly cleared */ if (LL_SPI_IsActiveFlag_OVR(spi)) { LL_SPI_ClearFlag_OVR(spi); } return -EIO; } return 0; } /* Shift a SPI frame as master. */ static void spi_stm32_shift_m(SPI_TypeDef *spi, struct spi_stm32_data *data) { uint16_t tx_frame = SPI_STM32_TX_NOP; uint16_t rx_frame; while (!ll_func_tx_is_empty(spi)) { /* NOP */ } #if defined(CONFIG_SOC_SERIES_STM32MP1X) || \ defined(CONFIG_SOC_SERIES_STM32H7X) /* With the STM32MP1 and the STM32H7, if the device is the SPI master, * we need to enable the start of the transfer with * LL_SPI_StartMasterTransfer(spi) */ if (LL_SPI_GetMode(spi) == LL_SPI_MODE_MASTER) { LL_SPI_StartMasterTransfer(spi); while (!LL_SPI_IsActiveMasterTransfer(spi)) { /* NOP */ } } #endif if (SPI_WORD_SIZE_GET(data->ctx.config->operation) == 8) { if (spi_context_tx_buf_on(&data->ctx)) { tx_frame = UNALIGNED_GET((uint8_t *)(data->ctx.tx_buf)); } LL_SPI_TransmitData8(spi, tx_frame); /* The update is ignored if TX is off. */ spi_context_update_tx(&data->ctx, 1, 1); } else { if (spi_context_tx_buf_on(&data->ctx)) { tx_frame = UNALIGNED_GET((uint16_t *)(data->ctx.tx_buf)); } LL_SPI_TransmitData16(spi, tx_frame); /* The update is ignored if TX is off. */ spi_context_update_tx(&data->ctx, 2, 1); } while (!ll_func_rx_is_not_empty(spi)) { /* NOP */ } if (SPI_WORD_SIZE_GET(data->ctx.config->operation) == 8) { rx_frame = LL_SPI_ReceiveData8(spi); if (spi_context_rx_buf_on(&data->ctx)) { UNALIGNED_PUT(rx_frame, (uint8_t *)data->ctx.rx_buf); } spi_context_update_rx(&data->ctx, 1, 1); } else { rx_frame = LL_SPI_ReceiveData16(spi); if (spi_context_rx_buf_on(&data->ctx)) { UNALIGNED_PUT(rx_frame, (uint16_t *)data->ctx.rx_buf); } spi_context_update_rx(&data->ctx, 2, 1); } } /* Shift a SPI frame as slave. */ static void spi_stm32_shift_s(SPI_TypeDef *spi, struct spi_stm32_data *data) { if (ll_func_tx_is_empty(spi) && spi_context_tx_on(&data->ctx)) { uint16_t tx_frame; if (SPI_WORD_SIZE_GET(data->ctx.config->operation) == 8) { tx_frame = UNALIGNED_GET((uint8_t *)(data->ctx.tx_buf)); LL_SPI_TransmitData8(spi, tx_frame); spi_context_update_tx(&data->ctx, 1, 1); } else { tx_frame = UNALIGNED_GET((uint16_t *)(data->ctx.tx_buf)); LL_SPI_TransmitData16(spi, tx_frame); spi_context_update_tx(&data->ctx, 2, 1); } } else { ll_func_disable_int_tx_empty(spi); } if (ll_func_rx_is_not_empty(spi) && spi_context_rx_buf_on(&data->ctx)) { uint16_t rx_frame; if (SPI_WORD_SIZE_GET(data->ctx.config->operation) == 8) { rx_frame = LL_SPI_ReceiveData8(spi); UNALIGNED_PUT(rx_frame, (uint8_t *)data->ctx.rx_buf); spi_context_update_rx(&data->ctx, 1, 1); } else { rx_frame = LL_SPI_ReceiveData16(spi); UNALIGNED_PUT(rx_frame, (uint16_t *)data->ctx.rx_buf); spi_context_update_rx(&data->ctx, 2, 1); } } } /* * Without a FIFO, we can only shift out one frame's worth of SPI * data, and read the response back. * * TODO: support 16-bit data frames. */ static int spi_stm32_shift_frames(SPI_TypeDef *spi, struct spi_stm32_data *data) { uint16_t operation = data->ctx.config->operation; if (SPI_OP_MODE_GET(operation) == SPI_OP_MODE_MASTER) { spi_stm32_shift_m(spi, data); } else { spi_stm32_shift_s(spi, data); } return spi_stm32_get_err(spi); } static void spi_stm32_cs_control(const struct device *dev, bool on) { struct spi_stm32_data *data = dev->data; spi_context_cs_control(&data->ctx, on); #if DT_HAS_COMPAT_STATUS_OKAY(st_stm32_spi_subghz) const struct spi_stm32_config *cfg = dev->config; if (cfg->use_subghzspi_nss) { if (on) { LL_PWR_SelectSUBGHZSPI_NSS(); } else { LL_PWR_UnselectSUBGHZSPI_NSS(); } } #endif } static void spi_stm32_complete(const struct device *dev, int status) { const struct spi_stm32_config *cfg = dev->config; SPI_TypeDef *spi = cfg->spi; #ifdef CONFIG_SPI_STM32_INTERRUPT struct spi_stm32_data *data = dev->data; ll_func_disable_int_tx_empty(spi); ll_func_disable_int_rx_not_empty(spi); ll_func_disable_int_errors(spi); #endif spi_stm32_cs_control(dev, false); #if DT_HAS_COMPAT_STATUS_OKAY(st_stm32_spi_fifo) /* Flush RX buffer */ while (ll_func_rx_is_not_empty(spi)) { (void) LL_SPI_ReceiveData8(spi); } #endif if (LL_SPI_GetMode(spi) == LL_SPI_MODE_MASTER) { while (ll_func_spi_is_busy(spi)) { /* NOP */ } } /* BSY flag is cleared when MODF flag is raised */ if (LL_SPI_IsActiveFlag_MODF(spi)) { LL_SPI_ClearFlag_MODF(spi); } ll_func_disable_spi(spi); #ifdef CONFIG_SPI_STM32_INTERRUPT spi_context_complete(&data->ctx, status); #endif } #ifdef CONFIG_SPI_STM32_INTERRUPT static void spi_stm32_isr(const struct device *dev) { const struct spi_stm32_config *cfg = dev->config; struct spi_stm32_data *data = dev->data; SPI_TypeDef *spi = cfg->spi; int err; err = spi_stm32_get_err(spi); if (err) { spi_stm32_complete(dev, err); return; } if (spi_stm32_transfer_ongoing(data)) { err = spi_stm32_shift_frames(spi, data); } if (err || !spi_stm32_transfer_ongoing(data)) { spi_stm32_complete(dev, err); } } #endif static int spi_stm32_configure(const struct device *dev, const struct spi_config *config) { const struct spi_stm32_config *cfg = DEV_CFG(dev); struct spi_stm32_data *data = DEV_DATA(dev); const uint32_t scaler[] = { LL_SPI_BAUDRATEPRESCALER_DIV2, LL_SPI_BAUDRATEPRESCALER_DIV4, LL_SPI_BAUDRATEPRESCALER_DIV8, LL_SPI_BAUDRATEPRESCALER_DIV16, LL_SPI_BAUDRATEPRESCALER_DIV32, LL_SPI_BAUDRATEPRESCALER_DIV64, LL_SPI_BAUDRATEPRESCALER_DIV128, LL_SPI_BAUDRATEPRESCALER_DIV256 }; SPI_TypeDef *spi = cfg->spi; uint32_t clock; int br; if (spi_context_configured(&data->ctx, config)) { /* Nothing to do */ return 0; } if ((SPI_WORD_SIZE_GET(config->operation) != 8) && (SPI_WORD_SIZE_GET(config->operation) != 16)) { return -ENOTSUP; } if (clock_control_get_rate(DEVICE_DT_GET(STM32_CLOCK_CONTROL_NODE), (clock_control_subsys_t) &cfg->pclken, &clock) < 0) { LOG_ERR("Failed call clock_control_get_rate"); return -EIO; } for (br = 1 ; br <= ARRAY_SIZE(scaler) ; ++br) { uint32_t clk = clock >> br; if (clk <= config->frequency) { break; } } if (br > ARRAY_SIZE(scaler)) { LOG_ERR("Unsupported frequency %uHz, max %uHz, min %uHz", config->frequency, clock >> 1, clock >> ARRAY_SIZE(scaler)); return -EINVAL; } LL_SPI_Disable(spi); LL_SPI_SetBaudRatePrescaler(spi, scaler[br - 1]); if (SPI_MODE_GET(config->operation) & SPI_MODE_CPOL) { LL_SPI_SetClockPolarity(spi, LL_SPI_POLARITY_HIGH); } else { LL_SPI_SetClockPolarity(spi, LL_SPI_POLARITY_LOW); } if (SPI_MODE_GET(config->operation) & SPI_MODE_CPHA) { LL_SPI_SetClockPhase(spi, LL_SPI_PHASE_2EDGE); } else { LL_SPI_SetClockPhase(spi, LL_SPI_PHASE_1EDGE); } LL_SPI_SetTransferDirection(spi, LL_SPI_FULL_DUPLEX); if (config->operation & SPI_TRANSFER_LSB) { LL_SPI_SetTransferBitOrder(spi, LL_SPI_LSB_FIRST); } else { LL_SPI_SetTransferBitOrder(spi, LL_SPI_MSB_FIRST); } LL_SPI_DisableCRC(spi); if (config->cs || !IS_ENABLED(CONFIG_SPI_STM32_USE_HW_SS)) { #if defined(CONFIG_SOC_SERIES_STM32MP1X) || \ defined(CONFIG_SOC_SERIES_STM32H7X) if (SPI_OP_MODE_GET(config->operation) == SPI_OP_MODE_MASTER) { if (LL_SPI_GetNSSPolarity(spi) == LL_SPI_NSS_POLARITY_LOW) LL_SPI_SetInternalSSLevel(spi, LL_SPI_SS_LEVEL_HIGH); } #endif LL_SPI_SetNSSMode(spi, LL_SPI_NSS_SOFT); } else { if (config->operation & SPI_OP_MODE_SLAVE) { LL_SPI_SetNSSMode(spi, LL_SPI_NSS_HARD_INPUT); } else { LL_SPI_SetNSSMode(spi, LL_SPI_NSS_HARD_OUTPUT); } } if (config->operation & SPI_OP_MODE_SLAVE) { LL_SPI_SetMode(spi, LL_SPI_MODE_SLAVE); } else { LL_SPI_SetMode(spi, LL_SPI_MODE_MASTER); } if (SPI_WORD_SIZE_GET(config->operation) == 8) { LL_SPI_SetDataWidth(spi, LL_SPI_DATAWIDTH_8BIT); } else { LL_SPI_SetDataWidth(spi, LL_SPI_DATAWIDTH_16BIT); } #if DT_HAS_COMPAT_STATUS_OKAY(st_stm32_spi_fifo) ll_func_set_fifo_threshold_8bit(spi); #endif #if !defined(CONFIG_SOC_SERIES_STM32F1X) \ && (!defined(CONFIG_SOC_SERIES_STM32L1X) || defined(SPI_CR2_FRF)) LL_SPI_SetStandard(spi, LL_SPI_PROTOCOL_MOTOROLA); #endif /* At this point, it's mandatory to set this on the context! */ data->ctx.config = config; spi_context_cs_configure(&data->ctx); LOG_DBG("Installed config %p: freq %uHz (div = %u)," " mode %u/%u/%u, slave %u", config, clock >> br, 1 << br, (SPI_MODE_GET(config->operation) & SPI_MODE_CPOL) ? 1 : 0, (SPI_MODE_GET(config->operation) & SPI_MODE_CPHA) ? 1 : 0, (SPI_MODE_GET(config->operation) & SPI_MODE_LOOP) ? 1 : 0, config->slave); return 0; } static int spi_stm32_release(const struct device *dev, const struct spi_config *config) { struct spi_stm32_data *data = DEV_DATA(dev); spi_context_unlock_unconditionally(&data->ctx); return 0; } static int transceive(const struct device *dev, const struct spi_config *config, const struct spi_buf_set *tx_bufs, const struct spi_buf_set *rx_bufs, bool asynchronous, struct k_poll_signal *signal) { const struct spi_stm32_config *cfg = DEV_CFG(dev); struct spi_stm32_data *data = DEV_DATA(dev); SPI_TypeDef *spi = cfg->spi; int ret; if (!tx_bufs && !rx_bufs) { return 0; } #ifndef CONFIG_SPI_STM32_INTERRUPT if (asynchronous) { return -ENOTSUP; } #endif spi_context_lock(&data->ctx, asynchronous, signal, config); ret = spi_stm32_configure(dev, config); if (ret) { goto end; } /* Set buffers info */ spi_context_buffers_setup(&data->ctx, tx_bufs, rx_bufs, 1); #if DT_HAS_COMPAT_STATUS_OKAY(st_stm32_spi_fifo) /* Flush RX buffer */ while (ll_func_rx_is_not_empty(spi)) { (void) LL_SPI_ReceiveData8(spi); } #endif LL_SPI_Enable(spi); /* This is turned off in spi_stm32_complete(). */ spi_stm32_cs_control(dev, true); #ifdef CONFIG_SPI_STM32_INTERRUPT ll_func_enable_int_errors(spi); if (rx_bufs) { ll_func_enable_int_rx_not_empty(spi); } ll_func_enable_int_tx_empty(spi); ret = spi_context_wait_for_completion(&data->ctx); #else do { ret = spi_stm32_shift_frames(spi, data); } while (!ret && spi_stm32_transfer_ongoing(data)); spi_stm32_complete(dev, ret); #ifdef CONFIG_SPI_SLAVE if (spi_context_is_slave(&data->ctx) && !ret) { ret = data->ctx.recv_frames; } #endif /* CONFIG_SPI_SLAVE */ #endif end: spi_context_release(&data->ctx, ret); return ret; } #ifdef CONFIG_SPI_STM32_DMA static int wait_dma_rx_tx_done(const struct device *dev) { struct spi_stm32_data *data = DEV_DATA(dev); int res = -1; while (1) { res = k_sem_take(&data->status_sem, K_MSEC(1000)); if (res != 0) { return res; } if (data->status_flags & SPI_STM32_DMA_ERROR_FLAG) { return -EIO; } if (data->status_flags & SPI_STM32_DMA_DONE_FLAG) { return 0; } } return res; } static int transceive_dma(const struct device *dev, const struct spi_config *config, const struct spi_buf_set *tx_bufs, const struct spi_buf_set *rx_bufs, bool asynchronous, struct k_poll_signal *signal) { const struct spi_stm32_config *cfg = DEV_CFG(dev); struct spi_stm32_data *data = DEV_DATA(dev); SPI_TypeDef *spi = cfg->spi; int ret; if (!tx_bufs && !rx_bufs) { return 0; } if (asynchronous) { return -ENOTSUP; } spi_context_lock(&data->ctx, asynchronous, signal, config); k_sem_reset(&data->status_sem); ret = spi_stm32_configure(dev, config); if (ret) { goto end; } /* Set buffers info */ spi_context_buffers_setup(&data->ctx, tx_bufs, rx_bufs, 1); LL_SPI_Enable(spi); /* This is turned off in spi_stm32_complete(). */ spi_stm32_cs_control(dev, true); while (data->ctx.rx_len > 0 || data->ctx.tx_len > 0) { size_t dma_len; if (data->ctx.rx_len == 0) { dma_len = data->ctx.tx_len; } else if (data->ctx.tx_len == 0) { dma_len = data->ctx.rx_len; } else { dma_len = MIN(data->ctx.tx_len, data->ctx.rx_len); } data->status_flags = 0; ret = spi_dma_move_buffers(dev, dma_len); if (ret != 0) { break; } LL_SPI_EnableDMAReq_RX(spi); LL_SPI_EnableDMAReq_TX(spi); ret = wait_dma_rx_tx_done(dev); if (ret != 0) { break; } #ifdef SPI_SR_FTLVL while (LL_SPI_GetTxFIFOLevel(spi) > 0) { } #endif /* wait until TX buffer is really empty */ while (LL_SPI_IsActiveFlag_TXE(spi) == 0) { } /* wait until hardware is really ready */ while (LL_SPI_IsActiveFlag_BSY(spi) == 1) { } LL_SPI_DisableDMAReq_TX(spi); LL_SPI_DisableDMAReq_RX(spi); spi_context_update_tx(&data->ctx, 1, dma_len); spi_context_update_rx(&data->ctx, 1, dma_len); } LL_SPI_Disable(spi); LL_SPI_DisableDMAReq_TX(spi); LL_SPI_DisableDMAReq_RX(spi); dma_stop(data->dma_rx.dma_dev, data->dma_rx.channel); dma_stop(data->dma_tx.dma_dev, data->dma_tx.channel); spi_stm32_complete(dev, ret); end: spi_context_release(&data->ctx, ret); return ret; } #endif /* CONFIG_SPI_STM32_DMA */ static int spi_stm32_transceive(const struct device *dev, const struct spi_config *config, const struct spi_buf_set *tx_bufs, const struct spi_buf_set *rx_bufs) { #ifdef CONFIG_SPI_STM32_DMA struct spi_stm32_data *data = DEV_DATA(dev); if ((data->dma_tx.dma_dev != NULL) && (data->dma_rx.dma_dev != NULL)) { return transceive_dma(dev, config, tx_bufs, rx_bufs, false, NULL); } #endif /* CONFIG_SPI_STM32_DMA */ return transceive(dev, config, tx_bufs, rx_bufs, false, NULL); } #ifdef CONFIG_SPI_ASYNC static int spi_stm32_transceive_async(const struct device *dev, const struct spi_config *config, const struct spi_buf_set *tx_bufs, const struct spi_buf_set *rx_bufs, struct k_poll_signal *async) { return transceive(dev, config, tx_bufs, rx_bufs, true, async); } #endif /* CONFIG_SPI_ASYNC */ static const struct spi_driver_api api_funcs = { .transceive = spi_stm32_transceive, #ifdef CONFIG_SPI_ASYNC .transceive_async = spi_stm32_transceive_async, #endif .release = spi_stm32_release, }; static int spi_stm32_init(const struct device *dev) { struct spi_stm32_data *data __attribute__((unused)) = dev->data; const struct spi_stm32_config *cfg = dev->config; int err; if (clock_control_on(DEVICE_DT_GET(STM32_CLOCK_CONTROL_NODE), (clock_control_subsys_t) &cfg->pclken) != 0) { LOG_ERR("Could not enable SPI clock"); return -EIO; } /* Configure dt provided device signals when available */ err = stm32_dt_pinctrl_configure(cfg->pinctrl_list, cfg->pinctrl_list_size, (uint32_t)cfg->spi); if (err < 0) { LOG_ERR("SPI pinctrl setup failed (%d)", err); return err; } #ifdef CONFIG_SPI_STM32_INTERRUPT cfg->irq_config(dev); #endif #ifdef CONFIG_SPI_STM32_DMA if ((data->dma_rx.dma_dev != NULL) && !device_is_ready(data->dma_rx.dma_dev)) { LOG_ERR("%s device not ready", data->dma_rx.dma_dev->name); return -ENODEV; } if ((data->dma_tx.dma_dev != NULL) && !device_is_ready(data->dma_tx.dma_dev)) { LOG_ERR("%s device not ready", data->dma_tx.dma_dev->name); return -ENODEV; } #endif /* CONFIG_SPI_STM32_DMA */ spi_context_unlock_unconditionally(&data->ctx); return 0; } #ifdef CONFIG_SPI_STM32_INTERRUPT #define STM32_SPI_IRQ_HANDLER_DECL(id) \ static void spi_stm32_irq_config_func_##id(const struct device *dev) #define STM32_SPI_IRQ_HANDLER_FUNC(id) \ .irq_config = spi_stm32_irq_config_func_##id, #define STM32_SPI_IRQ_HANDLER(id) \ static void spi_stm32_irq_config_func_##id(const struct device *dev) \ { \ IRQ_CONNECT(DT_INST_IRQN(id), \ DT_INST_IRQ(id, priority), \ spi_stm32_isr, DEVICE_DT_INST_GET(id), 0); \ irq_enable(DT_INST_IRQN(id)); \ } #else #define STM32_SPI_IRQ_HANDLER_DECL(id) #define STM32_SPI_IRQ_HANDLER_FUNC(id) #define STM32_SPI_IRQ_HANDLER(id) #endif #define SPI_DMA_CHANNEL_INIT(index, dir, dir_cap, src_dev, dest_dev) \ .dma_dev = DEVICE_DT_GET(STM32_DMA_CTLR(index, dir)), \ .channel = DT_INST_DMAS_CELL_BY_NAME(index, dir, channel), \ .dma_cfg = { \ .dma_slot = STM32_DMA_SLOT(index, dir, slot),\ .channel_direction = STM32_DMA_CONFIG_DIRECTION( \ STM32_DMA_CHANNEL_CONFIG(index, dir)), \ .source_data_size = STM32_DMA_CONFIG_##src_dev##_DATA_SIZE( \ STM32_DMA_CHANNEL_CONFIG(index, dir)), \ .dest_data_size = STM32_DMA_CONFIG_##dest_dev##_DATA_SIZE( \ STM32_DMA_CHANNEL_CONFIG(index, dir)), \ .source_burst_length = 1, /* SINGLE transfer */ \ .dest_burst_length = 1, /* SINGLE transfer */ \ .channel_priority = STM32_DMA_CONFIG_PRIORITY( \ STM32_DMA_CHANNEL_CONFIG(index, dir)),\ .dma_callback = dma_callback, \ .block_count = 2, \ }, \ .src_addr_increment = STM32_DMA_CONFIG_##src_dev##_ADDR_INC( \ STM32_DMA_CHANNEL_CONFIG(index, dir)), \ .dst_addr_increment = STM32_DMA_CONFIG_##dest_dev##_ADDR_INC( \ STM32_DMA_CHANNEL_CONFIG(index, dir)), \ .fifo_threshold = STM32_DMA_FEATURES_FIFO_THRESHOLD( \ STM32_DMA_FEATURES(index, dir)), \ #if CONFIG_SPI_STM32_DMA #define SPI_DMA_CHANNEL(id, dir, DIR, src, dest) \ .dma_##dir = { \ COND_CODE_1(DT_INST_DMAS_HAS_NAME(id, dir), \ (SPI_DMA_CHANNEL_INIT(id, dir, DIR, src, dest)),\ (NULL)) \ }, #define SPI_DMA_STATUS_SEM(id) \ .status_sem = Z_SEM_INITIALIZER( \ spi_stm32_dev_data_##id.status_sem, 0, 1), #else #define SPI_DMA_CHANNEL(id, dir, DIR, src, dest) #define SPI_DMA_STATUS_SEM(id) #endif #if DT_HAS_COMPAT_STATUS_OKAY(st_stm32_spi_subghz) #define STM32_SPI_USE_SUBGHZSPI_NSS_CONFIG(id) \ .use_subghzspi_nss = DT_INST_PROP_OR( \ id, use_subghzspi_nss, false), #else #define STM32_SPI_USE_SUBGHZSPI_NSS_CONFIG(id) #endif #define STM32_SPI_INIT(id) \ STM32_SPI_IRQ_HANDLER_DECL(id); \ \ static const struct soc_gpio_pinctrl spi_pins_##id[] = \ ST_STM32_DT_INST_PINCTRL(id, 0); \ \ static const struct spi_stm32_config spi_stm32_cfg_##id = { \ .spi = (SPI_TypeDef *) DT_INST_REG_ADDR(id), \ .pclken = { \ .enr = DT_INST_CLOCKS_CELL(id, bits), \ .bus = DT_INST_CLOCKS_CELL(id, bus) \ }, \ .pinctrl_list = spi_pins_##id, \ .pinctrl_list_size = ARRAY_SIZE(spi_pins_##id), \ STM32_SPI_IRQ_HANDLER_FUNC(id) \ STM32_SPI_USE_SUBGHZSPI_NSS_CONFIG(id) \ }; \ \ static struct spi_stm32_data spi_stm32_dev_data_##id = { \ SPI_CONTEXT_INIT_LOCK(spi_stm32_dev_data_##id, ctx), \ SPI_CONTEXT_INIT_SYNC(spi_stm32_dev_data_##id, ctx), \ SPI_DMA_CHANNEL(id, rx, RX, PERIPHERAL, MEMORY) \ SPI_DMA_CHANNEL(id, tx, TX, MEMORY, PERIPHERAL) \ SPI_DMA_STATUS_SEM(id) \ }; \ \ DEVICE_DT_INST_DEFINE(id, &spi_stm32_init, NULL, \ &spi_stm32_dev_data_##id, &spi_stm32_cfg_##id, \ POST_KERNEL, CONFIG_SPI_INIT_PRIORITY, \ &api_funcs); \ \ STM32_SPI_IRQ_HANDLER(id) DT_INST_FOREACH_STATUS_OKAY(STM32_SPI_INIT)