/* * Copyright (c) 2018 SiFive Inc. * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT sifive_spi0 #define LOG_LEVEL CONFIG_SPI_LOG_LEVEL #include LOG_MODULE_REGISTER(spi_sifive); #include "spi_sifive.h" #include #include /* Helper Functions */ static ALWAYS_INLINE void sys_set_mask(mem_addr_t addr, uint32_t mask, uint32_t value) { uint32_t temp = sys_read32(addr); temp &= ~(mask); temp |= value; sys_write32(temp, addr); } static int spi_config(const struct device *dev, uint32_t frequency, uint16_t operation) { uint32_t div; uint32_t fmt_len; if (operation & SPI_HALF_DUPLEX) { return -ENOTSUP; } if (SPI_OP_MODE_GET(operation) != SPI_OP_MODE_MASTER) { return -ENOTSUP; } if (operation & SPI_MODE_LOOP) { return -ENOTSUP; } /* Set the SPI frequency */ div = (SPI_CFG(dev)->f_sys / (frequency * 2U)) - 1; sys_write32((SF_SCKDIV_DIV_MASK & div), SPI_REG(dev, REG_SCKDIV)); /* Set the polarity */ if (operation & SPI_MODE_CPOL) { /* If CPOL is set, then SCK idles at logical 1 */ sys_set_bit(SPI_REG(dev, REG_SCKMODE), SF_SCKMODE_POL); } else { /* SCK idles at logical 0 */ sys_clear_bit(SPI_REG(dev, REG_SCKMODE), SF_SCKMODE_POL); } /* Set the phase */ if (operation & SPI_MODE_CPHA) { /* * If CPHA is set, then data is sampled * on the trailing SCK edge */ sys_set_bit(SPI_REG(dev, REG_SCKMODE), SF_SCKMODE_PHA); } else { /* Data is sampled on the leading SCK edge */ sys_clear_bit(SPI_REG(dev, REG_SCKMODE), SF_SCKMODE_PHA); } /* Get the frame length */ fmt_len = SPI_WORD_SIZE_GET(operation); if (fmt_len > SF_FMT_LEN_MASK) { return -ENOTSUP; } /* Set the frame length */ fmt_len = fmt_len << SF_FMT_LEN; fmt_len &= SF_FMT_LEN_MASK; sys_set_mask(SPI_REG(dev, REG_FMT), SF_FMT_LEN_MASK, fmt_len); if (IS_ENABLED(CONFIG_SPI_EXTENDED_MODES) && (operation & SPI_LINES_MASK) != SPI_LINES_SINGLE) { return -ENOTSUP; } /* Set single line operation */ sys_set_mask(SPI_REG(dev, REG_FMT), SF_FMT_PROTO_MASK, SF_FMT_PROTO_SINGLE); /* Set the endianness */ if (operation & SPI_TRANSFER_LSB) { sys_set_bit(SPI_REG(dev, REG_FMT), SF_FMT_ENDIAN); } else { sys_clear_bit(SPI_REG(dev, REG_FMT), SF_FMT_ENDIAN); } return 0; } static ALWAYS_INLINE bool spi_sifive_send_available(const struct device *dev) { return !(sys_read32(SPI_REG(dev, REG_TXDATA)) & SF_TXDATA_FULL); } static ALWAYS_INLINE void spi_sifive_send(const struct device *dev, uint8_t frame) { sys_write32((uint32_t) frame, SPI_REG(dev, REG_TXDATA)); } static ALWAYS_INLINE bool spi_sifive_recv(const struct device *dev, uint8_t *val) { uint32_t reg = sys_read32(SPI_REG(dev, REG_RXDATA)); if (reg & SF_RXDATA_EMPTY) { return false; } *val = (uint8_t) reg; return true; } static void spi_sifive_xfer(const struct device *dev, const bool hw_cs_control) { struct spi_context *ctx = &SPI_DATA(dev)->ctx; uint8_t txd, rxd; int queued_frames = 0; while (spi_context_tx_on(ctx) || spi_context_rx_on(ctx) || queued_frames > 0) { bool send = false; /* As long as frames remain to be sent, attempt to queue them on Tx FIFO. If * the FIFO is full then another attempt will be made next pass. If Rx length * > Tx length then queue dummy Tx in order to read the requested Rx data. */ if (spi_context_tx_buf_on(ctx)) { send = true; txd = *ctx->tx_buf; } else if (queued_frames == 0) { /* Implies spi_context_rx_on(). */ send = true; txd = 0U; } if (send && spi_sifive_send_available(dev)) { spi_sifive_send(dev, txd); queued_frames++; spi_context_update_tx(ctx, 1, 1); } if (queued_frames > 0 && spi_sifive_recv(dev, &rxd)) { if (spi_context_rx_buf_on(ctx)) { *ctx->rx_buf = rxd; } queued_frames--; spi_context_update_rx(ctx, 1, 1); } } /* Deassert the CS line */ if (!hw_cs_control) { spi_context_cs_control(&SPI_DATA(dev)->ctx, false); } else { sys_write32(SF_CSMODE_OFF, SPI_REG(dev, REG_CSMODE)); } spi_context_complete(ctx, dev, 0); } /* API Functions */ static int spi_sifive_init(const struct device *dev) { int err; #ifdef CONFIG_PINCTRL struct spi_sifive_cfg *cfg = (struct spi_sifive_cfg *)dev->config; #endif /* Disable SPI Flash mode */ sys_clear_bit(SPI_REG(dev, REG_FCTRL), SF_FCTRL_EN); err = spi_context_cs_configure_all(&SPI_DATA(dev)->ctx); if (err < 0) { return err; } #ifdef CONFIG_PINCTRL err = pinctrl_apply_state(cfg->pcfg, PINCTRL_STATE_DEFAULT); if (err < 0) { return err; } #endif /* Make sure the context is unlocked */ spi_context_unlock_unconditionally(&SPI_DATA(dev)->ctx); return 0; } static int spi_sifive_transceive(const struct device *dev, const struct spi_config *config, const struct spi_buf_set *tx_bufs, const struct spi_buf_set *rx_bufs) { int rc = 0; bool hw_cs_control = false; /* Lock the SPI Context */ spi_context_lock(&SPI_DATA(dev)->ctx, false, NULL, NULL, config); /* Configure the SPI bus */ SPI_DATA(dev)->ctx.config = config; /* * If the chip select configuration is not present, we'll ask the * SPI peripheral itself to control the CS line */ if (!spi_cs_is_gpio(config)) { hw_cs_control = true; } if (!hw_cs_control) { /* * If the user has requested manual GPIO control, ask the * context for control and disable HW control */ sys_write32(SF_CSMODE_OFF, SPI_REG(dev, REG_CSMODE)); } else { /* * Tell the hardware to control the requested CS pin. * NOTE: * For the SPI peripheral, the pin number is not the * GPIO pin, but the index into the list of available * CS lines for the SPI peripheral. */ sys_write32(config->slave, SPI_REG(dev, REG_CSID)); sys_write32(SF_CSMODE_OFF, SPI_REG(dev, REG_CSMODE)); } rc = spi_config(dev, config->frequency, config->operation); if (rc < 0) { spi_context_release(&SPI_DATA(dev)->ctx, rc); return rc; } spi_context_buffers_setup(&SPI_DATA(dev)->ctx, tx_bufs, rx_bufs, 1); /* Assert the CS line */ if (!hw_cs_control) { spi_context_cs_control(&SPI_DATA(dev)->ctx, true); } else { sys_write32(SF_CSMODE_HOLD, SPI_REG(dev, REG_CSMODE)); } /* Perform transfer */ spi_sifive_xfer(dev, hw_cs_control); rc = spi_context_wait_for_completion(&SPI_DATA(dev)->ctx); spi_context_release(&SPI_DATA(dev)->ctx, rc); return rc; } static int spi_sifive_release(const struct device *dev, const struct spi_config *config) { spi_context_unlock_unconditionally(&SPI_DATA(dev)->ctx); return 0; } /* Device Instantiation */ static const struct spi_driver_api spi_sifive_api = { .transceive = spi_sifive_transceive, .release = spi_sifive_release, }; #define SPI_INIT(n) \ PINCTRL_DT_INST_DEFINE(n); \ static struct spi_sifive_data spi_sifive_data_##n = { \ SPI_CONTEXT_INIT_LOCK(spi_sifive_data_##n, ctx), \ SPI_CONTEXT_INIT_SYNC(spi_sifive_data_##n, ctx), \ SPI_CONTEXT_CS_GPIOS_INITIALIZE(DT_DRV_INST(n), ctx) \ }; \ static struct spi_sifive_cfg spi_sifive_cfg_##n = { \ .base = DT_INST_REG_ADDR_BY_NAME(n, control), \ .f_sys = SIFIVE_PERIPHERAL_CLOCK_FREQUENCY, \ .pcfg = PINCTRL_DT_INST_DEV_CONFIG_GET(n), \ }; \ DEVICE_DT_INST_DEFINE(n, \ spi_sifive_init, \ NULL, \ &spi_sifive_data_##n, \ &spi_sifive_cfg_##n, \ POST_KERNEL, \ CONFIG_SPI_INIT_PRIORITY, \ &spi_sifive_api); DT_INST_FOREACH_STATUS_OKAY(SPI_INIT)