SPI Slave driver ================= Overview -------- The ESP32 has four SPI peripheral devices, called SPI0, SPI1, HSPI and VSPI. SPI0 is entirely dedicated to the flash cache the ESP32 uses to map the SPI flash device it is connected to into memory. SPI1 is connected to the same hardware lines as SPI0 and is used to write to the flash chip. HSPI and VSPI are free to use, and with the spi_slave driver, these can be used as a SPI slave, driven from a connected SPI master. The spi_slave driver ^^^^^^^^^^^^^^^^^^^^^ The spi_slave driver allows using the HSPI and/or VSPI peripheral as a full-duplex SPI slave. It can send/receive transactions within 64 bytes, or make use of DMA to send/receive transactions longer than that. However, there are some `known issues `_ when the DMA is enabled. Terminology ^^^^^^^^^^^ The spi_slave driver uses the following terms: * Host: The SPI peripheral inside the ESP32 initiating the SPI transmissions. One of HSPI or VSPI. * Bus: The SPI bus, common to all SPI devices connected to a master. In general the bus consists of the miso, mosi, sclk and optionally quadwp and quadhd signals. The SPI slaves are connected to these signals in parallel. Each SPI slave is also connected to one CS signal. - miso - Also known as q, this is the output of the serial stream from the ESP32 to the SPI master - mosi - Also known as d, this is the output of the serial stream from the SPI master to the ESP32 - sclk - Clock signal. Each data bit is clocked out or in on the positive or negative edge of this signal - cs - Chip Select. An active Chip Select delineates a single transaction to/from a slave. * Transaction: One instance of CS going active, data transfer from and to a master happening, and CS going inactive again. Transactions are atomic, as in they will never be interrupted by another transaction. SPI transactions ^^^^^^^^^^^^^^^^ A full-duplex SPI transaction starts with the master pulling CS low. After this happens, the master starts sending out clock pulses on the CLK line: every clock pulse causes a data bit to be shifted from the master to the slave on the MOSI line and vice versa on the MISO line. At the end of the transaction, the master makes CS high again. .. note:: The SPI slave peripheral relies on the control of software very much. The master shouldn't start a transaction when the slave hasn't prepared for it. Using one more GPIO as the handshake signal to sync is a good idea. For more details, see :ref:`transaction_interval`. GPIO matrix and IOMUX ^^^^^^^^^^^^^^^^^^^^^ Most peripheral signals in ESP32 can connect directly to a specific GPIO, which is called its IOMUX pin. When a peripheral signal is routed to a pin other than its IOMUX pin, ESP32 uses the less direct GPIO matrix to make this connection. If the driver is configured with all SPI signals set to their specific IOMUX pins (or left unconnected), it will bypass the GPIO matrix. If any SPI signal is configured to a pin other than its IOMUx pin, the driver will automatically route all the signals via the GPIO Matrix. The GPIO matrix samples all signals at 80MHz and sends them between the GPIO and the peripheral. When the GPIO matrix is used, setup time of MISO is more easily violated, since the output delay of MISO signal is increased. .. note:: More details about influence of output delay on the maximum clock frequency, see :ref:`timing_considerations` below. IOMUX pins for SPI controllers are as below: +----------+------+------+ | Pin Name | HSPI | VSPI | + +------+------+ | | GPIO Number | +==========+======+======+ | CS0* | 15 | 5 | +----------+------+------+ | SCLK | 14 | 18 | +----------+------+------+ | MISO | 12 | 19 | +----------+------+------+ | MOSI | 13 | 23 | +----------+------+------+ | QUADWP | 2 | 22 | +----------+------+------+ | QUADHD | 4 | 21 | +----------+------+------+ note * Only the first device attaching to the bus can use CS0 pin. Using the spi_slave driver ^^^^^^^^^^^^^^^^^^^^^^^^^^^ - Initialize a SPI peripheral as a slave by calling ``spi_slave_initialize``. Make sure to set the correct IO pins in the ``bus_config`` struct. Take care to set signals that are not needed to -1. A DMA channel (either 1 or 2) must be given if transactions will be larger than 32 bytes, if not the dma_chan parameter may be 0. - To set up a transaction, fill one or more spi_transaction_t structure with any transaction parameters you need. Either queue all transactions by calling ``spi_slave_queue_trans``, later quering the result using ``spi_slave_get_trans_result``, or handle all requests synchroneously by feeding them into ``spi_slave_transmit``. The latter two functions will block until the master has initiated and finished a transaction, causing the queued data to be sent and received. - Optional: to unload the SPI slave driver, call ``spi_slave_free``. Transaction data and master/slave length mismatches ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Normally, data to be transferred to or from a device will be read from or written to a chunk of memory indicated by the ``rx_buffer`` and ``tx_buffer`` members of the transaction structure. The SPI driver may decide to use DMA for transfers, so these buffers should be allocated in DMA-capable memory using ``pvPortMallocCaps(size, MALLOC_CAP_DMA)``. The amount of data written to the buffers is limited by the ``length`` member of the transaction structure: the driver will never read/write more data than indicated there. The ``length`` cannot define the actual length of the SPI transaction; this is determined by the master as it drives the clock and CS lines. The actual length transferred can be read from the ``trans_len`` member of the ``spi_slave_transaction_t`` structure after transaction. In case the length of the transmission is larger than the buffer length, only the start of the transmission will be sent and received, and the ``trans_len`` is set to ``length`` instead of the actual length. It's recommended to set ``length`` longer than the maximum length expected if the ``trans_len`` is required. In case the transmission length is shorter than the buffer length, only data up to the length of the buffer will be exchanged. Warning: Due to a design peculiarity in the ESP32, if the amount of bytes sent by the master or the length of the transmission queues in the slave driver, in bytes, is not both larger than eight and dividable by four, the SPI hardware can fail to write the last one to seven bytes to the receive buffer. Speed and Timing considerations ------------------------------- .. _transaction_interval: Transaction interval ^^^^^^^^^^^^^^^^^^^^ The SPI slave is designed as s general purpose device controlled by the CPU. Different from dedicated devices, CPU-based SPI slave doesn't have too much pre-defined registers. All transactions should be triggered by the CPU, which means the response speed would not be real-time, and there'll always be noticeable intervals between transfers. During the transaction intervals, the device is not prepared for transactions, the response is not meaningful at all. It is suggested to use :cpp:func:`spi_slave_queue_trans` with :cpp:func:`spi_slave_get_trans_result` to shorten the interval to half the case when using :cpp:func:`spi_slave_transmit`. The master should always wait for the slave to be ready to start new transactions. Suggested way is to use a gpio by the slave to indicate whether it's ready. The example is in :example:`peripherals/spi_slave`. SCLK frequency requirement ^^^^^^^^^^^^^^^^^^^^^^^^^^ The spi slave is designed to work under 10MHz or lower. The clock and data cannot be recognized or received correctly if the clock is too fast or doesn't have a 50% duty cycle. Moreover, there are more requirements if the data meets the timing requirement: - Read (MOSI): Given that the MOSI is valid right at the launch edge, the slave can read data correctly. Luckily, it's usually the case for most masters. - Write (MISO): To meet the requirement that MISO is stable before the next latch edge of SPI clock, the output delay of MISO signal should be shorter than half a clock. The output delay and frequency limitation (given that the clock is balanced) of different cases are as below : +-------------+---------------------------+------------------------+ | | Output delay of MISO (ns) | Freq. limit (MHZ) | +=============+===========================+========================+ | IOMUX | 43.75 | <11.4 | +-------------+---------------------------+------------------------+ | GPIO matrix | 68.75 | <7.2 | +-------------+---------------------------+------------------------+ Note: 1. Random error will happen if the frequency exactly equals the limitation 2. The clock uncertainty between master and slave (12.5ns) is included. 3. The output delay is measured under ideal case (free of load). When the loading of MISO pin is too heavy, the output delay will be longer, and the maximum allowed frequency will be lower. There is an exceptions: The frequency is allowed to be higher if the master has more toleration for the MISO setup time, e.g. latch data at the next edge than expected, or configurable latching time. .. _spi_dma_known_issues: Restrictions and Known issues ------------------------------- 1. If the DMA is enabled, the rx buffer should be WORD aligned, i.e. Start from the boundary of 32-bit and have length of multiples of 4 bytes. Or the DMA may write incorrectly or out of the boundary.The driver will check for this. Also, master should write lengths which are a multiple of 4 bytes. Data longer than that will be discarded. 2. Furthurmore, the DMA requires a spi mode 1/3 timing. When using spi mode 0/2, the MISO signal has to output half a clock earlier to meet the timing. The new timing is as below: .. image:: /../_static/spi_slave_miso_dma.png The hold time after the latch edge is 68.75ns (when GPIO matrix is bypassed), no longer half a SPI clock. The master should sample immediately at the latch edge, or communicate in mode 1/3. Or just initial the spi slave without DMA. Application Example ------------------- Slave/master communication: :example:`peripherals/spi_slave`. API Reference ------------- .. include:: /_build/inc/spi_slave.inc