e5d2406b1d
fix(spi_master): allow to use cs_ena_pretrans in full duplex mode without… See merge request idf/esp-idf!2576
429 lines
21 KiB
ReStructuredText
429 lines
21 KiB
ReStructuredText
SPI Master driver
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=================
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Overview
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--------
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The ESP32 has four SPI peripheral devices, called SPI0, SPI1, HSPI and VSPI. SPI0 is entirely dedicated to
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the flash cache the ESP32 uses to map the SPI flash device it is connected to into memory. SPI1 is
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connected to the same hardware lines as SPI0 and is used to write to the flash chip. HSPI and VSPI
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are free to use. SPI1, HSPI and VSPI all have three chip select lines, allowing them to drive up to
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three SPI devices each as a master.
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The spi_master driver
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^^^^^^^^^^^^^^^^^^^^^
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The spi_master driver allows easy communicating with SPI slave devices, even in a multithreaded environment.
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It fully transparently handles DMA transfers to read and write data and automatically takes care of
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multiplexing between different SPI slaves on the same master
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Terminology
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^^^^^^^^^^^
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The spi_master driver uses the following terms:
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* Host: The SPI peripheral inside the ESP32 initiating the SPI transmissions. One of SPI, HSPI or VSPI. (For
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now, only HSPI or VSPI are actually supported in the driver; it will support all 3 peripherals
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somewhere in the future.)
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* Bus: The SPI bus, common to all SPI devices connected to one host. In general the bus consists of the
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miso, mosi, sclk and optionally quadwp and quadhd signals. The SPI slaves are connected to these
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signals in parallel.
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- miso - Also known as q, this is the input of the serial stream into the ESP32
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- mosi - Also known as d, this is the output of the serial stream from the ESP32
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- sclk - Clock signal. Each data bit is clocked out or in on the positive or negative edge of this signal
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- quadwp - Write Protect signal. Only used for 4-bit (qio/qout) transactions.
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- quadhd - Hold signal. Only used for 4-bit (qio/qout) transactions.
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* Device: A SPI slave. Each SPI slave has its own chip select (CS) line, which is made active when
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a transmission to/from the SPI slave occurs.
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* Transaction: One instance of CS going active, data transfer from and/or to a device happening, and
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CS going inactive again. Transactions are atomic, as in they will never be interrupted by another
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transaction.
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SPI transactions
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^^^^^^^^^^^^^^^^
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A transaction on the SPI bus consists of five phases, any of which may be skipped:
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* The command phase. In this phase, a command (0-16 bit) is clocked out.
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* The address phase. In this phase, an address (0-64 bit) is clocked out.
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* The write phase. The master sends data to the slave.
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* The dummy phase. The phase is configurable, used to meet the timing requirements.
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* The read phase. The slave sends data to the master.
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In full duplex mode, the read and write phases are combined, and the SPI host reads and
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writes data simultaneously. The total transaction length is decided by
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``command_bits + address_bits + trans_conf.length``, while the ``trans_conf.rx_length``
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only determins length of data received into the buffer.
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While in half duplex mode, the host have independent write and read phases. The length of write phase and read phase are
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decided by ``trans_conf.length`` and ``trans_conf.rx_length`` respectively.
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The command and address phase are optional in that not every SPI device will need to be sent a command
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and/or address. This is reflected in the device configuration: when the ``command_bits`` or ``address_bits``
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fields are set to zero, no command or address phase is done.
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Something similar is true for the read and write phase: not every transaction needs both data to be written
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as well as data to be read. When ``rx_buffer`` is NULL (and SPI_USE_RXDATA) is not set) the read phase
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is skipped. When ``tx_buffer`` is NULL (and SPI_USE_TXDATA) is not set) the write phase is skipped.
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GPIO matrix and IOMUX
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^^^^^^^^^^^^^^^^^^^^^^^^^^^
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Most peripheral signals in ESP32 can connect directly to a specific GPIO, which is called its IOMUX pin. When a
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peripheral signal is routed to a pin other than its IOMUX pin, ESP32 uses the less direct GPIO matrix to make this
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connection.
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If the driver is configured with all SPI signals set to their specific IOMUX pins (or left unconnected), it will bypass
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the GPIO matrix. If any SPI signal is configured to a pin other than its IOMUx pin, the driver will automatically route
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all the signals via the GPIO Matrix. The GPIO matrix samples all signals at 80MHz and sends them between the GPIO and
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the peripheral.
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When the GPIO matrix is used, signals faster than 40MHz cannot propagate and the setup time of MISO is more easily
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violated, since the input delay of MISO signal is increased. The maximum clock frequency with GPIO Matrix is 40MHz
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or less, whereas using all IOMUX pins allows 80MHz.
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.. note:: More details about influence of input delay on the maximum clock frequency, see :ref:`timing_considerations` below.
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IOMUX pins for SPI controllers are as below:
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+----------+------+------+
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| Pin Name | HSPI | VSPI |
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+ +------+------+
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| | GPIO Number |
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+==========+======+======+
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| CS0* | 15 | 5 |
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+----------+------+------+
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| SCLK | 14 | 18 |
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+----------+------+------+
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| MISO | 12 | 19 |
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+----------+------+------+
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| MOSI | 13 | 23 |
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+----------+------+------+
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| QUADWP | 2 | 22 |
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+----------+------+------+
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| QUADHD | 4 | 21 |
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+----------+------+------+
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note * Only the first device attaching to the bus can use CS0 pin.
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Using the spi_master driver
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^^^^^^^^^^^^^^^^^^^^^^^^^^^
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- Initialize a SPI bus by calling ``spi_bus_initialize``. Make sure to set the correct IO pins in
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the ``bus_config`` struct. Take care to set signals that are not needed to -1.
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- Tell the driver about a SPI slave device connected to the bus by calling spi_bus_add_device.
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Make sure to configure any timing requirements the device has in the ``dev_config`` structure.
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You should now have a handle for the device, to be used when sending it a transaction.
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- To interact with the device, fill one or more spi_transaction_t structure with any transaction
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parameters you need. Either queue all transactions by calling ``spi_device_queue_trans``, later
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quering the result using ``spi_device_get_trans_result``, or handle all requests synchroneously
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by feeding them into ``spi_device_transmit``.
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- Optional: to unload the driver for a device, call ``spi_bus_remove_device`` with the device
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handle as an argument
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- Optional: to remove the driver for a bus, make sure no more drivers are attached and call
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``spi_bus_free``.
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Command and address phases
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^^^^^^^^^^^^^^^^^^^^^^^^^^
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During the command and address phases, ``cmd`` and ``addr`` field in the
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``spi_transaction_t`` struct are sent to the bus, while nothing is read at the
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same time. The default length of command and address phase are set in the
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``spi_device_interface_config_t`` and by ``spi_bus_add_device``. When the the
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flag ``SPI_TRANS_VARIABLE_CMD`` and ``SPI_TRANS_VARIABLE_ADDR`` are not set in
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the ``spi_transaction_t``,the driver automatically set the length of these
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phases to the default value as set when the device is initialized respectively.
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If the length of command and address phases needs to be variable, declare a
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``spi_transaction_ext_t`` descriptor, set the flag ``SPI_TRANS_VARIABLE_CMD``
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or/and ``SPI_TRANS_VARIABLE_ADDR`` in the ``flags`` of ``base`` member and
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configure the rest part of ``base`` as usual. Then the length of each phases
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will be ``command_bits`` and ``address_bits`` set in the ``spi_transaction_ext_t``.
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Write and read phases
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^^^^^^^^^^^^^^^^^^^^^
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Normally, data to be transferred to or from a device will be read from or written to a chunk of memory
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indicated by the ``rx_buffer`` and ``tx_buffer`` members of the transaction structure.
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When DMA is enabled for transfers, these buffers are highly recommended to meet the requirements as below:
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1. allocated in DMA-capable memory using ``pvPortMallocCaps(size, MALLOC_CAP_DMA)``;
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2. 32-bit aligned (start from the boundary and have length of multiples of 4 bytes).
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If these requirements are not satisfied, efficiency of the transaction will suffer due to the allocation and
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memcpy of temporary buffers.
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.. note:: Half duplex transactions with both read and write phases are not supported when using DMA. See
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:ref:`spi_known_issues` for details and workarounds.
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Tips
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""""
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1. Transactions with small amount of data:
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Sometimes, the amount of data is very small making it less than optimal allocating a separate buffer
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for it. If the data to be transferred is 32 bits or less, it can be stored in the transaction struct
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itself. For transmitted data, use the ``tx_data`` member for this and set the ``SPI_USE_TXDATA`` flag
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on the transmission. For received data, use ``rx_data`` and set ``SPI_USE_RXDATA``. In both cases, do
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not touch the ``tx_buffer`` or ``rx_buffer`` members, because they use the same memory locations
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as ``tx_data`` and ``rx_data``.
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2. Transactions with integers other than uint8_t
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The SPI peripheral reads and writes the memory byte-by-byte. By default,
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the SPI works at MSB first mode, each bytes are sent or received from the
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MSB to the LSB. However, if you want to send data with length which is
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not multiples of 8 bits, unused bits are sent.
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E.g. you write ``uint8_t data = 0x15`` (00010101B), and set length to
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only 5 bits, the sent data is ``00010B`` rather than expected ``10101B``.
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Moreover, ESP32 is a little-endian chip whose lowest byte is stored at
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the very beginning address for uint16_t and uint32_t variables. Hence if
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a uint16_t is stored in the memory, it's bit 7 is first sent, then bit 6
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to 0, then comes its bit 15 to bit 8.
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To send data other than uint8_t arrays, macros ``SPI_SWAP_DATA_TX`` is
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provided to shift your data to the MSB and swap the MSB to the lowest
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address; while ``SPI_SWAP_DATA_RX`` can be used to swap received data
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from the MSB to it's correct place.
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Speed and Timing Considerations
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-------------------------------
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Transferring speed
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^^^^^^^^^^^^^^^^^^
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There're two factors limiting the transferring speed: (1) The transaction interval, (2) The SPI clock frequency used.
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When large transactions are used, the clock frequency determines the transferring speed; while the interval effects the
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speed a lot if small transactions are used.
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1. Transaction interval: The interval mainly comes from the cost of FreeRTOS queues and the time switching between
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tasks and the ISR. It also takes time for the software to setup spi peripheral registers as well as copy data to
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FIFOs, or setup DMA links. Depending on whether the DMA is used, the interval of an one-byte transaction is around
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25us typically.
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1. The CPU is blocked and switched to other tasks when the
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transaction is in flight. This save the cpu time but increase the interval.
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2. When the DMA is enabled, it needs about 2us per transaction to setup the linked list. When the master is
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transferring, it automatically read data from the linked list. If the DMA is not enabled,
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CPU has to write/read each byte to/from the FIFO by itself. Usually this is faster than 2us, but the
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transaction length is limited to 32 bytes for both write and read.
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Typical transaction interval with one byte data is as below:
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+--------+------------------+
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| | Transaction Time |
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+========+==================+
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| | Typical (us) |
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+--------+------------------+
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| DMA | 24 |
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+--------+------------------+
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| No DMA | 22 |
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+--------+------------------+
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2. SPI clock frequency: Each byte transferred takes 8 times of the clock period *8/fspi*. If the clock frequency is
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too high, some functions may be limited to use. See :ref:`timing_considerations`.
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For a normal transaction, the overall cost is *20+8n/Fspi[MHz]* [us] for n bytes tranferred
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in one transaction. Hence the transferring speed is : *n/(20+8n/Fspi)*. Example of transferring speed under 8MHz
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clock speed:
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+-----------+----------------------+--------------------+------------+-------------+
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| Frequency | Transaction Interval | Transaction Length | Total Time | Total Speed |
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| | | | | |
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| (MHz) | (us) | (bytes) | (us) | (kBps) |
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+===========+======================+====================+============+=============+
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| 8 | 25 | 1 | 26 | 38.5 |
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+-----------+----------------------+--------------------+------------+-------------+
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| 8 | 25 | 8 | 33 | 242.4 |
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+-----------+----------------------+--------------------+------------+-------------+
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| 8 | 25 | 16 | 41 | 490.2 |
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+-----------+----------------------+--------------------+------------+-------------+
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| 8 | 25 | 64 | 89 | 719.1 |
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+-----------+----------------------+--------------------+------------+-------------+
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| 8 | 25 | 128 | 153 | 836.6 |
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+-----------+----------------------+--------------------+------------+-------------+
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When the length of transaction is short, the cost of transaction interval is really high. Please try to squash data
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into one transaction if possible to get higher transfer speed.
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.. _timing_considerations:
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Timing considerations
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^^^^^^^^^^^^^^^^^^^^^
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As shown in the figure below, there is a delay on the MISO signal after SCLK
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launch edge and before it's latched by the internal register. As a result,
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the MISO pin setup time is the limiting factor for SPI clock speed. When the
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delay is too large, setup slack is < 0 and the setup timing requirement is
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violated, leads to the failure of reading correctly.
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.. image:: /../_static/spi_miso.png
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.. wavedrom don't support rendering pdflatex till now(1.3.1), so we use the png here
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.. image:: /../_static/miso_timing_waveform.png
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The maximum frequency allowed is related to the *input delay* (maximum valid
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time after SCLK on the MISO bus), as well as the usage of GPIO matrix. The
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maximum frequency allowed is reduced to about 33~77% (related to existing
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*input delay*) when the GPIO matrix is used. To work at higher frequency, you
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have to use the IOMUX pins or the *dummy bit workaround*. You can get the
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maximum reading frequency of the master by ``spi_get_freq_limit``.
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.. _dummy_bit_workaround:
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**Dummy bit workaround:** We can insert dummy clocks (during which the host does not read data) before the read phase
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actually begins. The slave still sees the dummy clocks and gives out data, but the host does not read until the read
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phase. This compensates the lack of setup time of MISO required by the host, allowing the host reading at higher
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frequency.
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In the ideal case (the slave is so fast that the input delay is shorter than an apb clock, 12.5ns), the maximum
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frequency host can read (or read and write) under different conditions is as below:
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+-------------+-------------+------------+-----------------------------+
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| Frequency Limit (MHz) | Dummy Bits | Comments |
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+-------------+-------------+ Used + +
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| GPIO matrix | IOMUX pins | By Driver | |
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+=============+=============+============+=============================+
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| 26.6 | 80 | No | |
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+-------------+-------------+------------+-----------------------------+
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| 40 | -- | Yes | Half Duplex, no DMA allowed |
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+-------------+-------------+------------+-----------------------------+
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And if the host only writes, the *dummy bit workaround* is not used and the frequency limit is as below:
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+-------------------+------------------+
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| GPIO matrix (MHz) | IOMUX pins (MHz) |
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+===================+==================+
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| 40 | 80 |
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+-------------------+------------------+
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The spi master driver can work even if the *input delay* in the ``spi_device_interface_config_t`` is set to 0.
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However, setting a accurate value helps to: (1) calculate the frequency limit in full duplex mode, and (2) compensate
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the timing correctly by dummy bits in half duplex mode. You may find the maximum data valid time after the launch edge
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of SPI clocks in the AC characteristics chapter of the device specifications, or measure the time on a oscilloscope or
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logic analyzer.
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.. wavedrom don't support rendering pdflatex till now(1.3.1), so we use the png here
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.. image:: /../_static/miso_timing_waveform_async.png
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As shown in the figure above, the input delay is usually:
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*[input delay] = [sample delay] + [slave output delay]*
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1. The sample delay is the maximum random delay due to the
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asynchronization of SCLK and peripheral clock of the slave. It's usually
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1 slave peripheral clock if the clock is asynchronize with SCLK, or 0 if
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the slave just use the SCLK to latch the SCLK and launch MISO data. e.g.
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for ESP32 slaves, the delay is 12.5ns (1 apb clock), while it is reduced
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to 0 if the slave is in the same chip as the master.
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2. The slave output delay is the time for the MOSI to be stable after the
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launch edge. e.g. for ESP32 slaves, the output delay is 37.5ns (3 apb
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clocks) when IOMUX pins in the slave is used, or 62.5ns (5 apb clocks) if
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through the GPIO matrix.
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Some typical delays are shown in the following table:
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+--------------------+------------------+
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| Device | Input delay (ns) |
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+====================+==================+
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| Ideal device | 0 |
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+--------------------+------------------+
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| ESP32 slave IOMUX* | 50 |
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+--------------------+------------------+
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| ESP32 slave GPIO* | 75 |
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+--------------------+------------------+
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| ESP32 slave is on an independent |
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| chip, 12.5ns sample delay included. |
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+---------------------------------------+
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The MISO path delay(tv), consists of slave *input delay* and master *GPIO matrix delay*, finally determines the
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frequency limit, above which the full duplex mode will not work, or dummy bits are used in the half duplex mode. The
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frequency limit is:
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*Freq limit[MHz] = 80 / (floor(MISO delay[ns]/12.5) + 1)*
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The figure below shows the relations of frequency limit against the input delay. 2 extra apb clocks should be counted
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into the MISO delay if the GPIO matrix in the master is used.
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.. image:: /../_static/spi_master_freq_tv.png
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Corresponding frequency limit for different devices with different *input delay* are shown in the following
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table:
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+--------+------------------+----------------------+-------------------+
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| Master | Input delay (ns) | MISO path delay (ns) | Freq. limit (MHz) |
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+========+==================+======================+===================+
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| IOMUX | 0 | 0 | 80 |
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+ (0ns) +------------------+----------------------+-------------------+
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| | 50 | 50 | 16 |
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+ +------------------+----------------------+-------------------+
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| | 75 | 75 | 11.43 |
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+--------+------------------+----------------------+-------------------+
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| GPIO | 0 | 25 | 26.67 |
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+ (25ns) +------------------+----------------------+-------------------+
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| | 50 | 75 | 11.43 |
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+ +------------------+----------------------+-------------------+
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| | 75 | 100 | 8.89 |
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+--------+------------------+----------------------+-------------------+
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Thread Safety
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-------------
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The SPI driver API is thread safe when multiple SPI devices on the same bus are accessed from different tasks. However, the driver is not thread safe if the same SPI device is accessed from multiple tasks.
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In this case, it is recommended to either refactor your application so only a single task accesses each SPI device, or to add mutex locking around access of the shared device.
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.. _spi_known_issues:
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Known Issues
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------------
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1. Half duplex mode is not compatible with DMA when both writing and reading phases exist.
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If such transactions are required, you have to use one of the alternative solutions:
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1. use full-duplex mode instead.
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2. disable the DMA by setting the last parameter to 0 in bus initialization function just as below:
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``ret=spi_bus_initialize(VSPI_HOST, &buscfg, 0);``
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this may prohibit you from transmitting and receiving data longer than 32 bytes.
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3. try to use command and address field to replace the write phase.
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2. Full duplex mode is not compatible with the *dummy bit workaround*, hence the frequency is limited. See :ref:`dummy
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bit speed-up workaround <dummy_bit_workaround>`.
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3. ``cs_ena_pretrans`` is not compatible with command, address phases in full duplex mode.
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Application Example
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-------------------
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Display graphics on the 320x240 LCD of WROVER-Kits: :example:`peripherals/spi_master`.
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API Reference - SPI Common
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--------------------------
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.. include:: /_build/inc/spi_common.inc
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API Reference - SPI Master
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--------------------------
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.. include:: /_build/inc/spi_master.inc
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