SPI library for ESP32 which use DMA buffer to send/receive transactions
This is the SPI library to send/receive large transaction with DMA. Please use ESP32SPISlave for the simple SPI Slave mode without DMA.
- support DMA buffer (more than 64 byte transfer is available)
- support both SPI Master and Slave mode based on ESP32's SPI Master Driver and SPI Slave Driver
- Master has two ways to send/receive transactions
transfer()
to send/receive transaction one by onequeue()
andyield()
to send/receive multiple transactions at once (more efficient thantransfer()
many times)
- Slave has two ways to receive/send transactions
wait()
to receive/send transaction one by onequeue()
andyield()
to receive/send multiple transactions at once (more efficient thanwait()
many times)
- Various configurations based on driver APIs
IDE | ESP32 Board Version |
---|---|
Arduino IDE | >= 2.0.0 |
PlatformIO | Currently (<= 3.4.0 ) NOT Supported |
- There is known issue that last 4 bytes are missing if DMA is used with SPI Slave
- you need to send 4 bytes more to send all required bytes to ESP32 SPI Slave with DMA
- There is also a known issue that received data is bit shifted depending on the SPI mode
- Please try SPI mode 0 for this issue
- But SPI mode 1 or 3 is required based on the official doc
- Please use this library and SPI modes for your own risk
#include <ESP32DMASPIMaster.h>
ESP32DMASPI::Master master;
static const uint32_t BUFFER_SIZE = 8192;
uint8_t* spi_master_tx_buf;
uint8_t* spi_master_rx_buf;
void setup() {
// to use DMA buffer, use these methods to allocate buffer
spi_master_tx_buf = master.allocDMABuffer(BUFFER_SIZE);
spi_master_rx_buf = master.allocDMABuffer(BUFFER_SIZE);
// set buffer data...
master.setDataMode(SPI_MODE0); // default: SPI_MODE0
master.setFrequency(4000000); // default: 8MHz (too fast for bread board...)
master.setMaxTransferSize(BUFFER_SIZE); // default: 4092 bytes
// begin() after setting
master.begin(); // HSPI (CS: 15, CLK: 14, MOSI: 13, MISO: 12) -> default
// VSPI (CS: 5, CLK: 18, MOSI: 23, MISO: 19)
}
void loop() {
// start and wait to complete transaction
master.transfer(spi_master_tx_buf, spi_master_rx_buf, BUFFER_SIZE);
// do something with received data if you want
}
#include <ESP32DMASPISlave.h>
ESP32DMASPI::Slave slave;
static const uint32_t BUFFER_SIZE = 8192;
uint8_t* spi_slave_tx_buf;
uint8_t* spi_slave_rx_buf;
void setup() {
// to use DMA buffer, use these methods to allocate buffer
spi_slave_tx_buf = slave.allocDMABuffer(BUFFER_SIZE);
spi_slave_rx_buf = slave.allocDMABuffer(BUFFER_SIZE);
// set buffer data...
// slave device configuration
slave.setDataMode(SPI_MODE0);
slave.setMaxTransferSize(BUFFER_SIZE);
// begin() after setting
slave.begin(); // HSPI = CS: 15, CLK: 14, MOSI: 13, MISO: 12 -> default
// VSPI (CS: 5, CLK: 18, MOSI: 23, MISO: 19)
}
void loop() {
// if there is no transaction in queue, add transaction
if (slave.remained() == 0) {
slave.queue(spi_slave_rx_buf, spi_slave_tx_buf, BUFFER_SIZE);
}
// if transaction has completed from master,
// available() returns size of results of transaction,
// and buffer is automatically updated
while (slave.available()) {
// do something with received data: spi_slave_rx_buf
slave.pop();
}
}
// use HSPI or VSPI with default pin assignment
// VSPI (CS: 5, CLK: 18, MOSI: 23, MISO: 19)
// HSPI (CS: 15, CLK: 14, MOSI: 13, MISO: 12) -> default
bool begin(const uint8_t spi_bus = HSPI);
// use HSPI or VSPI with your own pin assignment
bool begin(const uint8_t spi_bus, const int8_t sck, const int8_t miso, const int8_t mosi, const int8_t ss);
bool end();
// DMA requires the memory allocated with this method
uint8_t* allocDMABuffer(const size_t n);
// execute transaction and wait for transmission one by one
size_t transfer(const uint8_t* tx_buf, const size_t size);
size_t transfer(const uint8_t* tx_buf, uint8_t* rx_buf, const size_t size);
size_t transfer(const uint16_t cmd, const uint64_t addr, const uint8_t* tx_buf, const size_t size);
size_t transfer(const uint16_t cmd, const uint64_t addr, const uint8_t* tx_buf, uint8_t* rx_buf, const size_t size);
size_t transfer(const uint8_t command_bits, const uint8_t address_bits, const uint16_t cmd, const uint64_t addr, const uint8_t* tx_buf, uint8_t* rx_buf, const size_t size);
size_t transfer(const uint8_t command_bits, const uint8_t address_bits, const uint8_t dummy_bits, const uint32_t flags, const uint16_t cmd, const uint64_t addr, const uint8_t* tx_buf, uint8_t* rx_buf, const size_t size);
// queueing transaction and execute simultaneously
// wait (blocking) and timeout occurs if queue is full with transaction
// (but designed not to queue transaction more than queue_size, so there is no timeout argument)
bool queue(const uint8_t* tx_buf, const size_t size);
bool queue(const uint8_t* tx_buf, uint8_t* rx_buf, const size_t size);
bool queue(const uint16_t cmd, const uint64_t addr, const uint8_t* tx_buf, const size_t size);
bool queue(const uint16_t cmd, const uint64_t addr, const uint8_t* tx_buf, uint8_t* rx_buf, const size_t size);
bool queue(const uint8_t command_bits, const uint8_t address_bits, const uint16_t cmd, const uint64_t addr, const uint8_t* tx_buf, uint8_t* rx_buf, const size_t size);
bool queue(const uint8_t command_bits, const uint8_t address_bits, const uint8_t dummy_bits, const uint32_t flags, const uint16_t cmd, const uint64_t addr, const uint8_t* tx_buf, uint8_t* rx_buf, const size_t size);
void yield();
// ===== Main Configurations =====
// set these optional parameters before begin() if you want
void setDataMode(const uint8_t m); // SPI_MODE0, 1, 2, 3
void setFrequency(const size_t f); // up to 80 MHz
void setMaxTransferSize(const size_t n);
// ===== Optional Configurations =====
// set these optional parameters before begin() if you want
void setCommandBits(const uint8_t n); // 0-16
void setAddressBits(const uint8_t n); // 0-64
void setDummyBits(const uint8_t n);
void setDutyCyclePos(const uint8_t n); // 128 for 50%
void setSpiMode(const uint8_t m); // SPI_MODE0, 1, 2, 3
void setCsEnaPostTrans(const uint8_t n);
void setClockSpeedHz(const size_t f); // up to 80 MHz
void setInputDelayNs(const int n);
void setDeviceFlags(const uint32_t flags); // OR of SPI_DEVICE_* flags
void setQueueSize(const size_t n); // default: 3
void setPreCb(const transaction_cb_t pre_cb);
void setPostCb(const transaction_cb_t post_cb);
void setDMAChannel(const uint8_t c); // default: auto
// use HSPI or VSPI with default pin assignment
// VSPI (CS: 5, CLK: 18, MOSI: 23, MISO: 19)
// HSPI (CS: 15, CLK: 14, MOSI: 13, MISO: 12) -> default
bool begin(const uint8_t spi_bus = HSPI);
// use HSPI or VSPI with your own pin assignment
bool begin(const uint8_t spi_bus, const int8_t sck, const int8_t miso, const int8_t mosi, const int8_t ss);
bool end();
// DMA requires the memory allocated with this method
uint8_t* allocDMABuffer(const size_t s);
// wait for transaction one by one
bool wait(uint8_t* rx_buf, const size_t size); // no data to master
bool wait(uint8_t* rx_buf, const uint8_t* tx_buf, const size_t size);
// queueing transaction
// wait (blocking) and timeout occurs if queue is full with transaction
// (but designed not to queue transaction more than queue_size, so there is no timeout argument)
bool queue(uint8_t* rx_buf, const size_t size); // no data to master
bool queue(uint8_t* rx_buf, const uint8_t* tx_buf, const size_t size);
// wait until all queued transaction will be done by master
// if yield is finished, all the buffer is updated to latest
void yield();
// transaction result info
size_t available() const; // size of completed (received) transaction results
size_t remained() const; // size of queued (not completed) transactions
uint32_t size() const; // size of the received bytes of the oldest queued transaction result
void pop(); // pop the oldest transaction result
// ===== Main Configurations =====
// set these optional parameters before begin() if you want
void setDataMode(const uint8_t m);
void setMaxTransferSize(const int n);
// ===== Optional Configurations =====
void setSlaveFlags(const uint32_t flags); // OR of SPI_SLAVE_* flags
void setQueueSize(const int n);
void setSpiMode(const uint8_t m);
void setDMAChannel(const uint8_t c); // default: auto
#define SPI_DEVICE_TXBIT_LSBFIRST (1<<0) ///< Transmit command/address/data LSB first instead of the default MSB first
#define SPI_DEVICE_RXBIT_LSBFIRST (1<<1) ///< Receive data LSB first instead of the default MSB first
#define SPI_DEVICE_BIT_LSBFIRST (SPI_DEVICE_TXBIT_LSBFIRST|SPI_DEVICE_RXBIT_LSBFIRST) ///< Transmit and receive LSB first
#define SPI_DEVICE_3WIRE (1<<2) ///< Use MOSI (=spid) for both sending and receiving data
#define SPI_DEVICE_POSITIVE_CS (1<<3) ///< Make CS positive during a transaction instead of negative
#define SPI_DEVICE_HALFDUPLEX (1<<4) ///< Transmit data before receiving it, instead of simultaneously
#define SPI_DEVICE_CLK_AS_CS (1<<5) ///< Output clock on CS line if CS is active
/** There are timing issue when reading at high frequency (the frequency is related to whether iomux pins are used, valid time after slave sees the clock).
* - In half-duplex mode, the driver automatically inserts dummy bits before reading phase to fix the timing issue. Set this flag to disable this feature.
* - In full-duplex mode, however, the hardware cannot use dummy bits, so there is no way to prevent data being read from getting corrupted.
* Set this flag to confirm that you're going to work with output only, or read without dummy bits at your own risk.
*/
#define SPI_DEVICE_NO_DUMMY (1<<6)
#define SPI_DEVICE_DDRCLK (1<<7)
#define SPI_SLAVE_TXBIT_LSBFIRST (1<<0) ///< Transmit command/address/data LSB first instead of the default MSB first
#define SPI_SLAVE_RXBIT_LSBFIRST (1<<1) ///< Receive data LSB first instead of the default MSB first
#define SPI_SLAVE_BIT_LSBFIRST (SPI_SLAVE_TXBIT_LSBFIRST|SPI_SLAVE_RXBIT_LSBFIRST) ///< Transmit and receive LSB first
As mentioned above, in short, there are two restrictions/issues for SPI with DMA buffer.
- RX buffer and host transfer length should be aligned to 4 bytes (length must be multiples of 4 bytes)
- Correct transfer requires SPI mode 1 and 3; otherwise Slave -> Master data corrupt (maybe MSB of the first byte)
To avoid 2nd issue, I set setDutyCyclePos(96)
in examples but it's a workaround and not a good solution. In addition, SPI Mode 1 and 3 do not work correctly with the current configuration if esp32-arduino
version > 1.0.4
. Also, in the example of esp-idf, SPI mode 1 is used... I hope someone sends PR for a better solution (configuration) someday!
Please refer here for more information and configure your slave by yourself.
- ESP-IDF Programming Guide / API Reference / SPI Master Driver
- ESP-IDF Programming Guide / API Reference / SPI Slave Driver
MIT