particle-boron
Constants
const (
P0_00 Pin = 0
P0_01 Pin = 1
P0_02 Pin = 2
P0_03 Pin = 3
P0_04 Pin = 4
P0_05 Pin = 5
P0_06 Pin = 6
P0_07 Pin = 7
P0_08 Pin = 8
P0_09 Pin = 9
P0_10 Pin = 10
P0_11 Pin = 11
P0_12 Pin = 12
P0_13 Pin = 13
P0_14 Pin = 14
P0_15 Pin = 15
P0_16 Pin = 16
P0_17 Pin = 17
P0_18 Pin = 18
P0_19 Pin = 19
P0_20 Pin = 20
P0_21 Pin = 21
P0_22 Pin = 22
P0_23 Pin = 23
P0_24 Pin = 24
P0_25 Pin = 25
P0_26 Pin = 26
P0_27 Pin = 27
P0_28 Pin = 28
P0_29 Pin = 29
P0_30 Pin = 30
P0_31 Pin = 31
P1_00 Pin = 32
P1_01 Pin = 33
P1_02 Pin = 34
P1_03 Pin = 35
P1_04 Pin = 36
P1_05 Pin = 37
P1_06 Pin = 38
P1_07 Pin = 39
P1_08 Pin = 40
P1_09 Pin = 41
P1_10 Pin = 42
P1_11 Pin = 43
P1_12 Pin = 44
P1_13 Pin = 45
P1_14 Pin = 46
P1_15 Pin = 47
)
Hardware pins
const HasLowFrequencyCrystal = true
const (
A0 Pin = 3
A1 Pin = 4
A2 Pin = 28
A3 Pin = 29
A4 Pin = 30
A5 Pin = 31
D0 Pin = 26 // Also SDA
D1 Pin = 27 // Also SCL
D2 Pin = 33
D3 Pin = 34
D4 Pin = 40
D5 Pin = 42
D6 Pin = 43
D7 Pin = 44 // Also LED
D8 Pin = 35
D9 Pin = 6 // Also TX
D10 Pin = 8 // Also RX
D11 Pin = 46 // Also SDI
D12 Pin = 45 // Also SDO
D13 Pin = 47 // Also SCK
)
GPIOs
const (
LED Pin = 44
LED_GREEN Pin = 14
LED_RED Pin = 13
LED_BLUE Pin = 15
)
LEDs
const (
UART_TX_PIN Pin = 6
UART_RX_PIN Pin = 8
)
const (
SDA_PIN Pin = 26
SCL_PIN Pin = 27
// Internal I2C with MAX17043 (Fuel gauge) and BQ24195 (Power management) chips on it
SDA1_PIN Pin = 24
SCL1_PIN Pin = 41
INT1_PIN Pin = 5
)
I2C pins
const (
SPI0_SCK_PIN Pin = 47
SPI0_SDO_PIN Pin = 45
SPI0_SDI_PIN Pin = 46
)
SPI pins
const (
SPI1_SCK_PIN Pin = 19
SPI1_SDO_PIN Pin = 20
SPI1_SDI_PIN Pin = 21
SPI1_CS_PIN Pin = 17
SPI1_WP_PIN Pin = 22
SPI1_HOLD_PIN Pin = 23
)
Internal 4MB SPI Flash
const (
SARA_TXD_PIN Pin = 37
SARA_RXD_PIN Pin = 36
SARA_CTS_PIN Pin = 38
SARA_RTS_PIN Pin = 39
SARA_RESET_PIN Pin = 12
SARA_POWER_ON_PIN Pin = 16
SARA_BUFF_EN_PIN Pin = 25
SARA_VINT_PIN Pin = 2
)
u-blox SARA coprocessor
const (
MODE_BUTTON_PIN Pin = 11
ANTENNA_SEL_PIN Pin = 7 // Low: chip antenna, High: External uFL
NFC1_PIN Pin = 9
NFC2_PIN Pin = 10
)
Other peripherals
const (
TWI_FREQ_100KHZ = 100000
TWI_FREQ_400KHZ = 400000
)
TWI_FREQ is the I2C bus speed. Normally either 100 kHz, or 400 kHz for high-speed bus.
Deprecated: use 100 * machine.KHz or 400 * machine.KHz instead.
const (
// I2CReceive indicates target has received a message from the controller.
I2CReceive I2CTargetEvent = iota
// I2CRequest indicates the controller is expecting a message from the target.
I2CRequest
// I2CFinish indicates the controller has ended the transaction.
//
// I2C controllers can chain multiple receive/request messages without
// relinquishing the bus by doing 'restarts'. I2CFinish indicates the
// bus has been relinquished by an I2C 'stop'.
I2CFinish
)
const (
// I2CModeController represents an I2C peripheral in controller mode.
I2CModeController I2CMode = iota
// I2CModeTarget represents an I2C peripheral in target mode.
I2CModeTarget
)
const Device = deviceName
Device is the running program’s chip name, such as “ATSAMD51J19A” or “nrf52840”. It is not the same as the CPU name.
The constant is some hardcoded default value if the program does not target a particular chip but instead runs in WebAssembly for example.
const (
KHz = 1000
MHz = 1000_000
GHz = 1000_000_000
)
Generic constants.
const NoPin = Pin(0xff)
NoPin explicitly indicates “not a pin”. Use this pin if you want to leave one of the pins in a peripheral unconfigured (if supported by the hardware).
const (
PinInput PinMode = (nrf.GPIO_PIN_CNF_DIR_Input << nrf.GPIO_PIN_CNF_DIR_Pos) | (nrf.GPIO_PIN_CNF_INPUT_Connect << nrf.GPIO_PIN_CNF_INPUT_Pos)
PinInputPullup PinMode = PinInput | (nrf.GPIO_PIN_CNF_PULL_Pullup << nrf.GPIO_PIN_CNF_PULL_Pos)
PinInputPulldown PinMode = PinInput | (nrf.GPIO_PIN_CNF_PULL_Pulldown << nrf.GPIO_PIN_CNF_PULL_Pos)
PinOutput PinMode = (nrf.GPIO_PIN_CNF_DIR_Output << nrf.GPIO_PIN_CNF_DIR_Pos) | (nrf.GPIO_PIN_CNF_INPUT_Connect << nrf.GPIO_PIN_CNF_INPUT_Pos)
)
const (
PinRising PinChange = nrf.GPIOTE_CONFIG_POLARITY_LoToHi
PinFalling PinChange = nrf.GPIOTE_CONFIG_POLARITY_HiToLo
PinToggle PinChange = nrf.GPIOTE_CONFIG_POLARITY_Toggle
)
Pin change interrupt constants for SetInterrupt.
const (
// WatchdogMaxTimeout in milliseconds (approx 36h)
WatchdogMaxTimeout = (0xffffffff * 1000) / 32768
)
const (
Mode0 = 0
Mode1 = 1
Mode2 = 2
Mode3 = 3
)
SPI phase and polarity configs CPOL and CPHA
const (
// ParityNone means to not use any parity checking. This is
// the most common setting.
ParityNone UARTParity = iota
// ParityEven means to expect that the total number of 1 bits sent
// should be an even number.
ParityEven
// ParityOdd means to expect that the total number of 1 bits sent
// should be an odd number.
ParityOdd
)
Variables
var (
DefaultUART = UART0
)
UART
var (
ErrTimeoutRNG = errors.New("machine: RNG Timeout")
ErrClockRNG = errors.New("machine: RNG Clock Error")
ErrSeedRNG = errors.New("machine: RNG Seed Error")
ErrInvalidInputPin = errors.New("machine: invalid input pin")
ErrInvalidOutputPin = errors.New("machine: invalid output pin")
ErrInvalidClockPin = errors.New("machine: invalid clock pin")
ErrInvalidDataPin = errors.New("machine: invalid data pin")
ErrNoPinChangeChannel = errors.New("machine: no channel available for pin interrupt")
)
var (
// UART0 is the hardware UART on the NRF SoC.
_UART0 = UART{Buffer: NewRingBuffer()}
UART0 = &_UART0
)
UART
var Flash flashBlockDevice
var (
PWM0 = &PWM{PWM: nrf.PWM0}
PWM1 = &PWM{PWM: nrf.PWM1}
PWM2 = &PWM{PWM: nrf.PWM2}
PWM3 = &PWM{PWM: nrf.PWM3}
)
PWM
var (
I2C0 = &I2C{Bus: nrf.TWIM0, BusT: nrf.TWIS0}
I2C1 = &I2C{Bus: nrf.TWIM1, BusT: nrf.TWIS1}
)
There are 2 I2C interfaces on the NRF.
var (
Watchdog = &watchdogImpl{}
)
var (
SPI0 = SPI{Bus: nrf.SPIM0, buf: new([1]byte)}
SPI1 = SPI{Bus: nrf.SPIM1, buf: new([1]byte)}
SPI2 = SPI{Bus: nrf.SPIM2, buf: new([1]byte)}
)
There are 3 SPI interfaces on the NRF528xx.
var (
ErrPWMPeriodTooLong = errors.New("pwm: period too long")
)
var Serial = DefaultUART
Serial is implemented via the default (usually the first) UART on the chip.
var (
ErrTxInvalidSliceSize = errors.New("SPI write and read slices must be same size")
errSPIInvalidMachineConfig = errors.New("SPI port was not configured properly by the machine")
)
var (
USBDev = &USBDevice{}
USBCDC Serialer
)
var (
ErrUSBReadTimeout = errors.New("USB read timeout")
ErrUSBBytesRead = errors.New("USB invalid number of bytes read")
ErrUSBBytesWritten = errors.New("USB invalid number of bytes written")
)
func CPUFrequency
func CPUFrequency() uint32
func CPUReset
func CPUReset()
CPUReset performs a hard system reset.
func ConfigureUSBEndpoint
func ConfigureUSBEndpoint(desc descriptor.Descriptor, epSettings []usb.EndpointConfig, setup []usb.SetupConfig)
func DeviceID
func DeviceID() []byte
DeviceID returns an identifier that is unique within a particular chipset.
The identity is one burnt into the MCU itself, or the flash chip at time of manufacture.
It’s possible that two different vendors may allocate the same DeviceID, so callers should take this into account if needing to generate a globally unique id.
The length of the hardware ID is vendor-specific, but 8 bytes (64 bits) is common.
func EnableCDC
func EnableCDC(txHandler func(), rxHandler func([]byte), setupHandler func(usb.Setup) bool)
func EnterBootloader
func EnterBootloader()
EnterBootloader resets the chip into the serial bootloader.
func EnterOTABootloader
func EnterOTABootloader()
EnterOTABootloader resets the chip into the bootloader so that it can be flashed via an OTA update
func EnterSerialBootloader
func EnterSerialBootloader()
EnterSerialBootloader resets the chip into the serial bootloader. After reset, it can be flashed using serial/nrfutil.
func EnterUF2Bootloader
func EnterUF2Bootloader()
EnterUF2Bootloader resets the chip into the UF2 bootloader. After reset, it can be flashed via nrfutil or by copying a UF2 file to the mass storage device
func FlashDataEnd
func FlashDataEnd() uintptr
Return the end of the writable flash area. Usually this is the address one past the end of the on-chip flash.
func FlashDataStart
func FlashDataStart() uintptr
Return the start of the writable flash area, aligned on a page boundary. This is usually just after the program and static data.
func GetRNG
func GetRNG() (ret uint32, err error)
GetRNG returns 32 bits of non-deterministic random data based on internal thermal noise. According to Nordic’s documentation, the random output is suitable for cryptographic purposes.
func InitADC
func InitADC()
InitADC initializes the registers needed for ADC.
func InitSerial
func InitSerial()
func NewRingBuffer
func NewRingBuffer() *RingBuffer
NewRingBuffer returns a new ring buffer.
func ReadTemperature
func ReadTemperature() int32
ReadTemperature reads the silicon die temperature of the chip. The return value is in milli-celsius.
func ReceiveUSBControlPacket
func ReceiveUSBControlPacket() ([cdcLineInfoSize]byte, error)
func SendUSBInPacket
func SendUSBInPacket(ep uint32, data []byte) bool
SendUSBInPacket sends a packet for USBHID (interrupt in / bulk in).
func SendZlp
func SendZlp()
type ADC
type ADC struct {
Pin Pin
}
func (ADC) Configure
func (a ADC) Configure(config ADCConfig)
Configure configures an ADC pin to be able to read analog data.
func (ADC) Get
func (a ADC) Get() uint16
Get returns the current value of a ADC pin in the range 0..0xffff.
type ADCConfig
type ADCConfig struct {
Reference uint32 // analog reference voltage (AREF) in millivolts
Resolution uint32 // number of bits for a single conversion (e.g., 8, 10, 12)
Samples uint32 // number of samples for a single conversion (e.g., 4, 8, 16, 32)
SampleTime uint32 // sample time, in microseconds (µs)
}
ADCConfig holds ADC configuration parameters. If left unspecified, the zero value of each parameter will use the peripheral’s default settings.
type BlockDevice
type BlockDevice interface {
// ReadAt reads the given number of bytes from the block device.
io.ReaderAt
// WriteAt writes the given number of bytes to the block device.
io.WriterAt
// Size returns the number of bytes in this block device.
Size() int64
// WriteBlockSize returns the block size in which data can be written to
// memory. It can be used by a client to optimize writes, non-aligned writes
// should always work correctly.
WriteBlockSize() int64
// EraseBlockSize returns the smallest erasable area on this particular chip
// in bytes. This is used for the block size in EraseBlocks.
// It must be a power of two, and may be as small as 1. A typical size is 4096.
EraseBlockSize() int64
// EraseBlocks erases the given number of blocks. An implementation may
// transparently coalesce ranges of blocks into larger bundles if the chip
// supports this. The start and len parameters are in block numbers, use
// EraseBlockSize to map addresses to blocks.
EraseBlocks(start, len int64) error
}
BlockDevice is the raw device that is meant to store flash data.
type I2C
type I2C struct {
Bus *nrf.TWIM_Type // Called Bus to align with Bus field in nrf51
BusT *nrf.TWIS_Type
mode I2CMode
}
I2C on the NRF528xx.
func (*I2C) Configure
func (i2c *I2C) Configure(config I2CConfig) error
Configure is intended to setup the I2C interface.
func (*I2C) Listen
func (i2c *I2C) Listen(addr uint8) error
Listen starts listening for I2C requests sent to specified address
addr is the address to listen to
func (*I2C) ReadRegister
func (i2c *I2C) ReadRegister(address uint8, register uint8, data []byte) error
ReadRegister transmits the register, restarts the connection as a read operation, and reads the response.
Many I2C-compatible devices are organized in terms of registers. This method is a shortcut to easily read such registers. Also, it only works for devices with 7-bit addresses, which is the vast majority.
func (*I2C) Reply
func (i2c *I2C) Reply(buf []byte) error
Reply supplies the response data the controller.
func (*I2C) SetBaudRate
func (i2c *I2C) SetBaudRate(br uint32) error
SetBaudRate sets the I2C frequency. It has the side effect of also enabling the I2C hardware if disabled beforehand.
func (*I2C) Tx
func (i2c *I2C) Tx(addr uint16, w, r []byte) (err error)
Tx does a single I2C transaction at the specified address (when in controller mode).
It clocks out the given address, writes the bytes in w, reads back len(r) bytes and stores them in r, and generates a stop condition on the bus.
func (*I2C) WaitForEvent
func (i2c *I2C) WaitForEvent(buf []byte) (evt I2CTargetEvent, count int, err error)
WaitForEvent blocks the current go-routine until an I2C event is received (when in Target mode).
The passed buffer will be populated for receive events, with the number of bytes received returned in count. For other event types, buf is not modified and a count of zero is returned.
For request events, the caller MUST call Reply
to avoid hanging the i2c bus indefinitely.
func (*I2C) WriteRegister
func (i2c *I2C) WriteRegister(address uint8, register uint8, data []byte) error
WriteRegister transmits first the register and then the data to the peripheral device.
Many I2C-compatible devices are organized in terms of registers. This method is a shortcut to easily write to such registers. Also, it only works for devices with 7-bit addresses, which is the vast majority.
type I2CConfig
type I2CConfig struct {
Frequency uint32
SCL Pin
SDA Pin
Mode I2CMode
}
I2CConfig is used to store config info for I2C.
type I2CMode
type I2CMode int
I2CMode determines if an I2C peripheral is in Controller or Target mode.
type I2CTargetEvent
type I2CTargetEvent uint8
I2CTargetEvent reflects events on the I2C bus
type NullSerial
type NullSerial struct {
}
NullSerial is a serial version of /dev/null (or null router): it drops everything that is written to it.
func (NullSerial) Buffered
func (ns NullSerial) Buffered() int
Buffered returns how many bytes are buffered in the UART. It always returns 0 as there are no bytes to read.
func (NullSerial) Configure
func (ns NullSerial) Configure(config UARTConfig) error
Configure does nothing: the null serial has no configuration.
func (NullSerial) ReadByte
func (ns NullSerial) ReadByte() (byte, error)
ReadByte always returns an error because there aren’t any bytes to read.
func (NullSerial) Write
func (ns NullSerial) Write(p []byte) (n int, err error)
Write is a no-op: none of the data is being written and it will not return an error.
func (NullSerial) WriteByte
func (ns NullSerial) WriteByte(b byte) error
WriteByte is a no-op: the null serial doesn’t write bytes.
type PDM
type PDM struct {
device *nrf.PDM_Type
defaultBuffer int16
}
PDM represents a PDM device
func (*PDM) Configure
func (pdm *PDM) Configure(config PDMConfig) error
Configure is intended to set up the PDM interface prior to use.
func (*PDM) Read
func (pdm *PDM) Read(buf []int16) (uint32, error)
Read stores a set of samples in the given target buffer.
type PDMConfig
type PDMConfig struct {
Stereo bool
DIN Pin
CLK Pin
}
type PWM
type PWM struct {
PWM *nrf.PWM_Type
channelValues [4]volatile.Register16
}
PWM is one PWM peripheral, which consists of a counter and multiple output channels (that can be connected to actual pins). You can set the frequency using SetPeriod, but only for all the channels in this PWM peripheral at once.
func (*PWM) Channel
func (pwm *PWM) Channel(pin Pin) (uint8, error)
Channel returns a PWM channel for the given pin.
func (*PWM) Configure
func (pwm *PWM) Configure(config PWMConfig) error
Configure enables and configures this PWM. On the nRF52 series, the maximum period is around 0.26s.
func (*PWM) Set
func (pwm *PWM) Set(channel uint8, value uint32)
Set updates the channel value. This is used to control the channel duty cycle. For example, to set it to a 25% duty cycle, use:
ch.Set(ch.Top() / 4)
ch.Set(0) will set the output to low and ch.Set(ch.Top()) will set the output to high, assuming the output isn’t inverted.
func (*PWM) SetInverting
func (pwm *PWM) SetInverting(channel uint8, inverting bool)
SetInverting sets whether to invert the output of this channel. Without inverting, a 25% duty cycle would mean the output is high for 25% of the time and low for the rest. Inverting flips the output as if a NOT gate was placed at the output, meaning that the output would be 25% low and 75% high with a duty cycle of 25%.
func (*PWM) SetPeriod
func (pwm *PWM) SetPeriod(period uint64) error
SetPeriod updates the period of this PWM peripheral. To set a particular frequency, use the following formula:
period = 1e9 / frequency
If you use a period of 0, a period that works well for LEDs will be picked.
SetPeriod will not change the prescaler, but also won’t change the current value in any of the channels. This means that you may need to update the value for the particular channel.
Note that you cannot pick any arbitrary period after the PWM peripheral has been configured. If you want to switch between frequencies, pick the lowest frequency (longest period) once when calling Configure and adjust the frequency here as needed.
func (*PWM) Top
func (pwm *PWM) Top() uint32
Top returns the current counter top, for use in duty cycle calculation. It will only change with a call to Configure or SetPeriod, otherwise it is constant.
The value returned here is hardware dependent. In general, it’s best to treat it as an opaque value that can be divided by some number and passed to pwm.Set (see pwm.Set for more information).
type PWMConfig
type PWMConfig struct {
// PWM period in nanosecond. Leaving this zero will pick a reasonable period
// value for use with LEDs.
// If you want to configure a frequency instead of a period, you can use the
// following formula to calculate a period from a frequency:
//
// period = 1e9 / frequency
//
Period uint64
}
PWMConfig allows setting some configuration while configuring a PWM peripheral. A zero PWMConfig is ready to use for simple applications such as dimming LEDs.
type Pin
type Pin uint8
Pin is a single pin on a chip, which may be connected to other hardware devices. It can either be used directly as GPIO pin or it can be used in other peripherals like ADC, I2C, etc.
func (Pin) Configure
func (p Pin) Configure(config PinConfig)
Configure this pin with the given configuration.
func (Pin) Get
func (p Pin) Get() bool
Get returns the current value of a GPIO pin when the pin is configured as an input or as an output.
func (Pin) High
func (p Pin) High()
High sets this GPIO pin to high, assuming it has been configured as an output pin. It is hardware dependent (and often undefined) what happens if you set a pin to high that is not configured as an output pin.
func (Pin) Low
func (p Pin) Low()
Low sets this GPIO pin to low, assuming it has been configured as an output pin. It is hardware dependent (and often undefined) what happens if you set a pin to low that is not configured as an output pin.
func (Pin) PortMaskClear
func (p Pin) PortMaskClear() (*uint32, uint32)
Return the register and mask to disable a given port. This can be used to implement bit-banged drivers.
func (Pin) PortMaskSet
func (p Pin) PortMaskSet() (*uint32, uint32)
Return the register and mask to enable a given GPIO pin. This can be used to implement bit-banged drivers.
func (Pin) Set
func (p Pin) Set(high bool)
Set the pin to high or low. Warning: only use this on an output pin!
func (Pin) SetInterrupt
func (p Pin) SetInterrupt(change PinChange, callback func(Pin)) error
SetInterrupt sets an interrupt to be executed when a particular pin changes state. The pin should already be configured as an input, including a pull up or down if no external pull is provided.
This call will replace a previously set callback on this pin. You can pass a nil func to unset the pin change interrupt. If you do so, the change parameter is ignored and can be set to any value (such as 0).
type PinChange
type PinChange uint8
type PinConfig
type PinConfig struct {
Mode PinMode
}
type PinMode
type PinMode uint8
PinMode sets the direction and pull mode of the pin. For example, PinOutput sets the pin as an output and PinInputPullup sets the pin as an input with a pull-up.
type RingBuffer
type RingBuffer struct {
rxbuffer [bufferSize]volatile.Register8
head volatile.Register8
tail volatile.Register8
}
RingBuffer is ring buffer implementation inspired by post at https://www.embeddedrelated.com/showthread/comp.arch.embedded/77084-1.php
func (*RingBuffer) Clear
func (rb *RingBuffer) Clear()
Clear resets the head and tail pointer to zero.
func (*RingBuffer) Get
func (rb *RingBuffer) Get() (byte, bool)
Get returns a byte from the buffer. If the buffer is empty, the method will return a false as the second value.
func (*RingBuffer) Put
func (rb *RingBuffer) Put(val byte) bool
Put stores a byte in the buffer. If the buffer is already full, the method will return false.
func (*RingBuffer) Used
func (rb *RingBuffer) Used() uint8
Used returns how many bytes in buffer have been used.
type SPI
type SPI struct {
Bus *nrf.SPIM_Type
buf *[1]byte // 1-byte buffer for the Transfer method
}
SPI on the NRF.
func (SPI) Configure
func (spi SPI) Configure(config SPIConfig) error
Configure is intended to setup the SPI interface.
func (SPI) Transfer
func (spi SPI) Transfer(w byte) (byte, error)
Transfer writes/reads a single byte using the SPI interface.
func (SPI) Tx
func (spi SPI) Tx(w, r []byte) error
Tx handles read/write operation for SPI interface. Since SPI is a syncronous write/read interface, there must always be the same number of bytes written as bytes read. Therefore, if the number of bytes don’t match it will be padded until they fit: if len(w) > len(r) the extra bytes received will be dropped and if len(w) < len(r) extra 0 bytes will be sent.
type SPIConfig
type SPIConfig struct {
Frequency uint32
SCK Pin
SDO Pin
SDI Pin
LSBFirst bool
Mode uint8
}
SPIConfig is used to store config info for SPI.
type Serialer
type Serialer interface {
WriteByte(c byte) error
Write(data []byte) (n int, err error)
Configure(config UARTConfig) error
Buffered() int
ReadByte() (byte, error)
DTR() bool
RTS() bool
}
type UART
type UART struct {
Buffer *RingBuffer
}
UART on the NRF.
func (*UART) Buffered
func (uart *UART) Buffered() int
Buffered returns the number of bytes currently stored in the RX buffer.
func (*UART) Configure
func (uart *UART) Configure(config UARTConfig)
Configure the UART.
func (*UART) Read
func (uart *UART) Read(data []byte) (n int, err error)
Read from the RX buffer.
func (*UART) ReadByte
func (uart *UART) ReadByte() (byte, error)
ReadByte reads a single byte from the RX buffer. If there is no data in the buffer, returns an error.
func (*UART) Receive
func (uart *UART) Receive(data byte)
Receive handles adding data to the UART’s data buffer. Usually called by the IRQ handler for a machine.
func (*UART) SetBaudRate
func (uart *UART) SetBaudRate(br uint32)
SetBaudRate sets the communication speed for the UART.
func (*UART) Write
func (uart *UART) Write(data []byte) (n int, err error)
Write data over the UART’s Tx. This function blocks until the data is finished being sent.
func (*UART) WriteByte
func (uart *UART) WriteByte(c byte) error
WriteByte writes a byte of data over the UART’s Tx. This function blocks until the data is finished being sent.
type UARTConfig
type UARTConfig struct {
BaudRate uint32
TX Pin
RX Pin
RTS Pin
CTS Pin
}
UARTConfig is a struct with which a UART (or similar object) can be configured. The baud rate is usually respected, but TX and RX may be ignored depending on the chip and the type of object.
type UARTParity
type UARTParity uint8
UARTParity is the parity setting to be used for UART communication.
type USBDevice
type USBDevice struct {
initcomplete bool
InitEndpointComplete bool
}
func (*USBDevice) Configure
func (dev *USBDevice) Configure(config UARTConfig)
Configure the USB peripheral. The config is here for compatibility with the UART interface.
type WatchdogConfig
type WatchdogConfig struct {
// The timeout (in milliseconds) before the watchdog fires.
//
// If the requested timeout exceeds `MaxTimeout` it will be rounded
// down.
TimeoutMillis uint32
}
WatchdogConfig holds configuration for the watchdog timer.