#define SPI_RX_SLOW BIT(11) /* receive with 1 wire slow */
#define SPI_RX_DUAL BIT(12) /* receive with 2 wires */
#define SPI_RX_QUAD BIT(13) /* receive with 4 wires */
+#define SPI_TX_OCTAL BIT(14) /* transmit with 8 wires */
+#define SPI_RX_OCTAL BIT(15) /* receive with 8 wires */
/* Header byte that marks the start of the message */
#define SPI_PREAMBLE_END_BYTE 0xec
#endif /* CONFIG_DM_SPI */
/**
+ * enum spi_clock_phase - indicates the clock phase to use for SPI (CPHA)
+ *
+ * @SPI_CLOCK_PHASE_FIRST: Data sampled on the first phase
+ * @SPI_CLOCK_PHASE_SECOND: Data sampled on the second phase
+ */
+enum spi_clock_phase {
+ SPI_CLOCK_PHASE_FIRST,
+ SPI_CLOCK_PHASE_SECOND,
+};
+
+/**
+ * enum spi_wire_mode - indicates the number of wires used for SPI
+ *
+ * @SPI_4_WIRE_MODE: Normal bidirectional mode with MOSI and MISO
+ * @SPI_3_WIRE_MODE: Unidirectional version with a single data line SISO
+ */
+enum spi_wire_mode {
+ SPI_4_WIRE_MODE,
+ SPI_3_WIRE_MODE,
+};
+
+/**
+ * enum spi_polarity - indicates the polarity of the SPI bus (CPOL)
+ *
+ * @SPI_POLARITY_LOW: Clock is low in idle state
+ * @SPI_POLARITY_HIGH: Clock is high in idle state
+ */
+enum spi_polarity {
+ SPI_POLARITY_LOW,
+ SPI_POLARITY_HIGH,
+};
+
+/**
* struct spi_slave - Representation of a SPI slave
*
* For driver model this is the per-child data used by the SPI bus. It can
};
/**
- * Initialization, must be called once on start up.
- *
- * TODO: I don't think we really need this.
- */
-void spi_init(void);
-
-/**
* spi_do_alloc_slave - Allocate a new SPI slave (internal)
*
* Allocate and zero all fields in the spi slave, and set the bus/chip
int spi_set_wordlen(struct spi_slave *slave, unsigned int wordlen);
/**
- * SPI transfer
+ * SPI transfer (optional if mem_ops is used)
*
* This writes "bitlen" bits out the SPI MOSI port and simultaneously clocks
* "bitlen" bits in the SPI MISO port. That's just the way SPI works.
int spi_xfer(struct spi_slave *slave, unsigned int bitlen, const void *dout,
void *din, unsigned long flags);
+/**
+ * spi_write_then_read - SPI synchronous write followed by read
+ *
+ * This performs a half duplex transaction in which the first transaction
+ * is to send the opcode and if the length of buf is non-zero then it start
+ * the second transaction as tx or rx based on the need from respective slave.
+ *
+ * @slave: The SPI slave device with which opcode/data will be exchanged
+ * @opcode: opcode used for specific transfer
+ * @n_opcode: size of opcode, in bytes
+ * @txbuf: buffer into which data to be written
+ * @rxbuf: buffer into which data will be read
+ * @n_buf: size of buf (whether it's [tx|rx]buf), in bytes
+ *
+ * Returns: 0 on success, not 0 on failure
+ */
+int spi_write_then_read(struct spi_slave *slave, const u8 *opcode,
+ size_t n_opcode, const u8 *txbuf, u8 *rxbuf,
+ size_t n_buf);
+
/* Copy memory mapped data */
void spi_flash_copy_mmap(void *data, void *offset, size_t len);
* @cs: The chip select (0..n-1)
* @info: Returns information about the chip select, if valid.
* On entry info->dev is NULL
- * @return 0 if OK (and @info is set up), -ENODEV if the chip select
+ * @return 0 if OK (and @info is set up), -EINVAL if the chip select
* is invalid, other -ve value on error
*/
int (*cs_info)(struct udevice *bus, uint cs, struct spi_cs_info *info);
+
+ /**
+ * get_mmap() - Get memory-mapped SPI
+ *
+ * @dev: The SPI flash slave device
+ * @map_basep: Returns base memory address for mapped SPI
+ * @map_sizep: Returns size of mapped SPI
+ * @offsetp: Returns start offset of SPI flash where the map works
+ * correctly (offsets before this are not visible)
+ * @return 0 if OK, -EFAULT if memory mapping is not available
+ */
+ int (*get_mmap)(struct udevice *dev, ulong *map_basep,
+ uint *map_sizep, uint *offsetp);
};
struct dm_spi_emul_ops {
* device and slave device.
*
* If no such slave exists, and drv_name is not NULL, then a new slave device
- * is automatically bound on this chip select.
+ * is automatically bound on this chip select with requested speed and mode.
*
- * Ths new slave device is probed ready for use with the given speed and mode.
+ * Ths new slave device is probed ready for use with the speed and mode
+ * from platdata when available or the requested values.
*
* @busnum: SPI bus number
* @cs: Chip select to look for
- * @speed: SPI speed to use for this slave
- * @mode: SPI mode to use for this slave
+ * @speed: SPI speed to use for this slave when not available in platdata
+ * @mode: SPI mode to use for this slave when not available in platdata
* @drv_name: Name of driver to attach to this chip select
* @dev_name: Name of the new device thus created
* @busp: Returns bus device
* @bus: SPI bus to search
* @cs: Chip select to look for
* @devp: Returns the slave device if found
- * @return 0 if found, -ENODEV on error
+ * @return 0 if found, -EINVAL if cs is invalid, -ENODEV if no device attached,
+ * other -ve value on error
*/
int spi_find_chip_select(struct udevice *bus, int cs, struct udevice **devp);
int dm_spi_xfer(struct udevice *dev, unsigned int bitlen,
const void *dout, void *din, unsigned long flags);
+/**
+ * spi_get_mmap() - Get memory-mapped SPI
+ *
+ * @dev: SPI slave device to check
+ * @map_basep: Returns base memory address for mapped SPI
+ * @map_sizep: Returns size of mapped SPI
+ * @offsetp: Returns start offset of SPI flash where the map works
+ * correctly (offsets before this are not visible)
+ * @return 0 if OK, -ENOSYS if no operation, -EFAULT if memory mapping is not
+ * available
+ */
+int dm_spi_get_mmap(struct udevice *dev, ulong *map_basep, uint *map_sizep,
+ uint *offsetp);
+
/* Access the operations for a SPI device */
#define spi_get_ops(dev) ((struct dm_spi_ops *)(dev)->driver->ops)
#define spi_emul_get_ops(dev) ((struct dm_spi_emul_ops *)(dev)->driver->ops)