SpiDevice Class

Definition

Represents a device connected through the SPI bus.

public ref class SpiDevice sealed : IClosable
/// [Windows.Foundation.Metadata.ContractVersion(Windows.Devices.DevicesLowLevelContract, 65536)]
/// [Windows.Foundation.Metadata.MarshalingBehavior(Windows.Foundation.Metadata.MarshalingType.Agile)]
class SpiDevice final : IClosable
[Windows.Foundation.Metadata.ContractVersion(typeof(Windows.Devices.DevicesLowLevelContract), 65536)]
[Windows.Foundation.Metadata.MarshalingBehavior(Windows.Foundation.Metadata.MarshalingType.Agile)]
public sealed class SpiDevice : System.IDisposable
Public NotInheritable Class SpiDevice
Implements IDisposable
Inheritance
Object Platform::Object IInspectable SpiDevice
Attributes
Implements

Windows requirements

Device family
Windows IoT Extension SDK (introduced in 10.0.10240.0)
API contract
Windows.Devices.DevicesLowLevelContract (introduced in v1.0)

Examples

The following sample illustrates the basic functionality of this and other SPI APIs by showing how to open an SPI bus by friendly name using the default connection settings.

// Arduino SPIDigialPot example: http://arduino.cc/en/Tutorial/SPIDigitalPot 
// using digital potentiometer AD5206 the 50kohm variance 
async void Digipot_AD5206() 
{ 
    // Get a device selector query that will select buses with SP10 
    // property set on them (we expect only 1 SP10 bus at the end) 
    var spi0Aqs = SpiDevice.GetDeviceSelector("SPI0"); 
    // Find all buses using the AQS query formed above 
    var devicesInfo = await DeviceInformation.FindAllAsync(spi0Aqs); 

    // Construct time settings beforehand which can't be changed 
    // once a SPI device is created 
    const Int32 DigipotChipSelectLine = 0; 
    var settings = new SpiConnectionSettings(DigipotChipSelectLine); 

    // Ask the SPI bus to open a device with the connection settings 
    // provided. Once we go out of scope, the device will be released 
    using (var spiDev = await SpiDevice.FromIdAsync(devicesInfo[0].Id, settings)) 
    { 

        // data[0] is the channel address 
        // data[1] is the resistance step (0 - 255) 
        // 0 is max digipot resistance, and 255 is no resistance 
        byte[] data = { 0x0, 0x0 }; 

        // Go over the 6 channels of the digipot 
        for (byte channel = 0; channel < 6; ++channel) 
        { 
            data[0] = channel; 

            // Step the resistance on this channel from max to min 
            for (byte r = 0; r <= 255; ++r) 
            { 
                data[1] = r; 
                spiDev.Write(data); 
                await Task.Delay(100); 
            } 

            // Step the resistance on this channel from min to max 
            for (byte r = 255; r >= 0; --r) 
            { 
                data[1] = r; 
                spiDev.Write(data); 
                await Task.Delay(100); 
            } 
        } 
    } 
} 

The following sample shows how to use this and other SPI APIs to initialize an SPI device with non-default connection settings. It does so by reading the light-intensity from an analog Photocell connected to an 8-channel 10-bit ADC108S102 A/D Converter.

// Knowing that an SPI bus with 'spiBusId' exist, and has the ADC connected 
// on 'chipSelectLine', read a digital sample from some sensor wired to 'channel' 
async Task<int> AnalogRead_ADC108S102(string spiBusId, Int32 chipSelectLine, byte channel) 
{ 
    var settings = new SpiConnectionSettings(chipSelectLine); 

    // The defaults (4MHz, 8-bit, Mode0) will not work here according 
    // to the datasheet. 
    // e.g The datasheet specifies a clock freq range (8MHz - 16MHz) 
    settings.ClockFrequency = 8000000; 
    // CPOL=1, CPHA=1 
    settings.Mode = SpiMode.Mode3; 
    // Conversion happens on a 16-bit frame 
    settings.DataBitLength = 16; 
    // The ADC108S102 has 8 input analog channels, where each can be 
    // connected to a specific analog sensor and each sensor is 
    // used by a different application independently 
    // The IO requests to the SPI bus are implicitly synchronized 
    // by the driver model, plus that the ADC configuration is per 
    // 1 sampling read 
    settings.SharingMode = SpiSharingMode.Shared; 

    // Ask the SPI bus to open a shared device with the connection settings 
    // provided. 
    using (var spiDev = await SpiDevice.FromIdAsync(spiBusId, settings)) 
    { 
        if (spiDev == null) 
            return -1; 

        // Set up control register to get a conversion on a specific 
        // channel address 
        byte[] write16bitData = { (byte)(channel << 3), 0 }; 
        byte[] read16bitData = new byte[2]; 
        // The transfer is guaranteed to be atomic according to SpbCx model 
        spiDev.TransferFullDuplex(write16bitData, read16bitData); 

        ushort result = BitConverter.ToUInt16(read16bitData, 0); 
        // Get rid of the 2 LSB zeros and mask the 10-bit sampled value 
        return (int)((result >> 2) & 0x3ff); 
    } 
} 

Properties

ConnectionSettings

Gets the connection settings for the device.

DeviceId

Gets the unique ID associated with the device.

Methods

Close()

Closes the connection to the device.

Dispose()

Performs application-defined tasks associated with freeing, releasing, or resetting unmanaged resources.

FromIdAsync(String, SpiConnectionSettings)

Opens a device with the connection settings provided.

GetBusInfo(String)

Retrieves the info about a certain bus.

GetDeviceSelector()

Gets all the SPI buses found on the system.

GetDeviceSelector(String)

Gets all the SPI buses found on the system that match the input parameter.

Read(Byte[])

Reads from the connected device.

TransferFullDuplex(Byte[], Byte[])

Transfer data using a full duplex communication system. Full duplex allows both the host and the peripheral to communicate simultaneously.

For definitions of host and peripheral, see Windows.Devices.Spi namespace.

TransferSequential(Byte[], Byte[])

Transfer data sequentially to the device.

Write(Byte[])

Writes to the connected device.

Applies to

See also