Documentation ¶
Overview ¶
Package board defines the interfaces that typically live on a single-board computer such as a Raspberry Pi.
Besides the board itself, some other interfaces it defines are analog pins and digital interrupts. For more information, see the board component docs.
Package board contains a gRPC based board client.
Package board contains a gRPC based Board service server.
Index ¶
- Constants
- Variables
- func CreateStatus(ctx context.Context, b Board) (*pb.Status, error)
- func Named(name string) resource.Name
- func NamesFromRobot(r robot.Robot) []string
- func NewRPCServiceServer(coll resource.APIResourceCollection[Board]) interface{}
- func ValidatePWMDutyCycle(dutyCyclePct float64) (float64, error)
- type Analog
- type AnalogReaderConfig
- type AnalogValue
- type Board
- type DigitalInterrupt
- type DigitalInterruptConfig
- type GPIOPin
- type I2CConfig
- type SPIConfig
- type Tick
Constants ¶
const SubtypeName = "board"
SubtypeName is a constant that identifies the component resource API string "board".
Variables ¶
var API = resource.APINamespaceRDK.WithComponentType(SubtypeName)
API is a variable that identifies the component resource API.
Functions ¶
func CreateStatus ¶
CreateStatus constructs a new up to date status from the given board. The operation can take time and be expensive, so it can be cancelled by the given context.
func NamesFromRobot ¶
NamesFromRobot is a helper for getting all board names from the given Robot.
func NewRPCServiceServer ¶ added in v0.2.36
func NewRPCServiceServer(coll resource.APIResourceCollection[Board]) interface{}
NewRPCServiceServer constructs an board gRPC service server. It is intentionally untyped to prevent use outside of tests.
func ValidatePWMDutyCycle ¶ added in v0.39.0
ValidatePWMDutyCycle makes sure the value passed in is a believable duty cycle value. It returns the preferred duty cycle value if it is, and an error if it is not.
Types ¶
type Analog ¶ added in v0.26.0
type Analog interface { // Read reads off the current value. Read(ctx context.Context, extra map[string]interface{}) (AnalogValue, error) // Write writes a value to the analog pin. Write(ctx context.Context, value int, extra map[string]interface{}) error }
An Analog represents an analog pin that resides on a board.
Read example:
myBoard, err := board.FromRobot(robot, "my_board") // Get the analog pin "my_example_analog". analog, err := myBoard.AnalogByName("my_example_analog") // Get the value of the analog signal "my_example_analog" has most recently measured. reading, err := analog.Read(context.Background(), nil) readingValue := reading.Value stepSize := reading.StepSize
Write example:
myBoard, err := board.FromRobot(robot, "my_board") // Get the Analog pin "my_example_analog". analog, err := myBoard.AnalogByName("my_example_analog") // Set the pin to value 48. err := analog.Write(context.Background(), 48, nil)
type AnalogReaderConfig ¶ added in v0.11.0
type AnalogReaderConfig struct { Name string `json:"name"` Pin string `json:"pin"` AverageOverMillis int `json:"average_over_ms,omitempty"` SamplesPerSecond int `json:"samples_per_sec,omitempty"` }
AnalogReaderConfig describes the configuration of an analog reader on a board.
func (*AnalogReaderConfig) Validate ¶ added in v0.11.0
func (config *AnalogReaderConfig) Validate(path string) error
Validate ensures all parts of the config are valid.
type AnalogValue ¶ added in v0.28.0
AnalogValue contains all info about the analog reading. Value represents the reading in bits. Min and Max represent the range of raw analog values. StepSize is the precision per bit of the reading.
type Board ¶
type Board interface { resource.Resource // AnalogByName returns an analog pin by name. AnalogByName(name string) (Analog, error) // DigitalInterruptByName returns a digital interrupt by name. DigitalInterruptByName(name string) (DigitalInterrupt, error) // GPIOPinByName returns a GPIOPin by name. GPIOPinByName(name string) (GPIOPin, error) // AnalogNames returns the names of all known analog pins. AnalogNames() []string // DigitalInterruptNames returns the names of all known digital interrupts. DigitalInterruptNames() []string // SetPowerMode sets the board to the given power mode. If // provided, the board will exit the given power mode after // the specified duration. SetPowerMode(ctx context.Context, mode pb.PowerMode, duration *time.Duration) error // StreamTicks starts a stream of digital interrupt ticks. StreamTicks(ctx context.Context, interrupts []DigitalInterrupt, ch chan Tick, extra map[string]interface{}) error }
A Board represents a physical general purpose board that contains various components such as analogs, and digital interrupts. For more information, see the board component docs.
AnalogByName example:
myBoard, err := board.FromRobot(robot, "my_board") // Get the Analog pin "my_example_analog". analog, err := myBoard.AnalogByName("my_example_analog")
DigitalInterruptByName example:
myBoard, err := board.FromRobot(robot, "my_board") // Get the DigitalInterrupt "my_example_digital_interrupt". interrupt, err := myBoard.DigitalInterruptByName("my_example_digital_interrupt")
GPIOPinByName example:
myBoard, err := board.FromRobot(robot, "my_board") // Get the GPIOPin with pin number 15. pin, err := myBoard.GPIOPinByName("15")
SetPowerMode example:
myBoard, err := board.FromRobot(robot, "my_board") Set the power mode of the board to OFFLINE_DEEP. myBoard.SetPowerMode(context.Background(), boardpb.PowerMode_POWER_MODE_OFFLINE_DEEP, nil)
StreamTicks example:
myBoard, err := board.FromRobot(robot, "my_board") // Make a channel to stream ticks ticksChan := make(chan board.Tick) interrupts := []*DigitalInterrupt{} if di8, err := myBoard.DigitalInterruptByName("8"); err == nil { interrupts = append(interrupts, di8) } if di11, err := myBoard.DigitalInterruptByName("11"); err == nil { interrupts = append(interrupts, di11) } err = myBoard.StreamTicks(context.Background(), interrupts, ticksChan, nil)
func FromDependencies ¶
func FromDependencies(deps resource.Dependencies, name string) (Board, error)
FromDependencies is a helper for getting the named board from a collection of dependencies.
type DigitalInterrupt ¶
type DigitalInterrupt interface { // Name returns the name of the interrupt. Name() string // Value returns the current value of the interrupt which is // based on the type of interrupt. Value(ctx context.Context, extra map[string]interface{}) (int64, error) }
A DigitalInterrupt represents a configured interrupt on the board that when interrupted, calls the added callbacks.
Value example:
myBoard, err := board.FromRobot(robot, "my_board") // Get the DigitalInterrupt "my_example_digital_interrupt". interrupt, err := myBoard.DigitalInterruptByName("my_example_digital_interrupt") // Get the amount of times this DigitalInterrupt has ticked. count, err := interrupt.Value(context.Background(), nil)
type DigitalInterruptConfig ¶
DigitalInterruptConfig describes the configuration of digital interrupt for a board.
func (*DigitalInterruptConfig) Validate ¶
func (config *DigitalInterruptConfig) Validate(path string) error
Validate ensures all parts of the config are valid.
type GPIOPin ¶
type GPIOPin interface { // Set sets the pin to either low or high. Set(ctx context.Context, high bool, extra map[string]interface{}) error // Get gets the high/low state of the pin. Get(ctx context.Context, extra map[string]interface{}) (bool, error) // PWM gets the pin's given duty cycle. PWM(ctx context.Context, extra map[string]interface{}) (float64, error) // SetPWM sets the pin to the given duty cycle. SetPWM(ctx context.Context, dutyCyclePct float64, extra map[string]interface{}) error // PWMFreq gets the PWM frequency of the pin. PWMFreq(ctx context.Context, extra map[string]interface{}) (uint, error) // SetPWMFreq sets the given pin to the given PWM frequency. For Raspberry Pis, // 0 will use a default PWM frequency of 800. SetPWMFreq(ctx context.Context, freqHz uint, extra map[string]interface{}) error }
A GPIOPin represents an individual GPIO pin on a board.
Set example:
myBoard, err := board.FromRobot(robot, "my_board") // Get the GPIOPin with pin number 15. pin, err := myBoard.GPIOPinByName("15") // Set the pin to high. err := pin.Set(context.Background(), "true", nil)
Get example:
myBoard, err := board.FromRobot(robot, "my_board") // Get the GPIOPin with pin number 15. pin, err := myBoard.GPIOPinByName("15") // Get if it is true or false that the state of the pin is high. high := pin.Get(context.Background(), nil)
PWM example:
myBoard, err := board.FromRobot(robot, "my_board") // Get the GPIOPin with pin number 15. pin, err := myBoard.GPIOPinByName("15") // Returns the duty cycle. duty_cycle := pin.PWM(context.Background(), nil)
SetPWM example:
myBoard, err := board.FromRobot(robot, "my_board") // Get the GPIOPin with pin number 15. pin, err := myBoard.GPIOPinByName("15") // Set the duty cycle to .6, meaning that this pin will be in the high state for 60% of the duration of the PWM interval period. err := pin.SetPWM(context.Background(), .6, nil)
PWMFreq example:
myBoard, err := board.FromRobot(robot, "my_board") // Get the GPIOPin with pin number 15. pin, err := myBoard.GPIOPinByName("15") // Get the PWM frequency of this pin. freqHz, err := pin.PWMFreq(context.Background(), nil)
SetPWMFreq example:
myBoard, err := board.FromRobot(robot, "my_board") // Get the GPIOPin with pin number 15. pin, err := myBoard.GPIOPinByName("15") // Set the PWM frequency of this pin to 1600 Hz. high := pin.SetPWMFreq(context.Background(), 1600, nil)
type SPIConfig ¶
type SPIConfig struct { Name string `json:"name"` BusSelect string `json:"bus_select"` // "0" or "1" are common on single board computers }
SPIConfig enumerates a specific, shareable SPI bus.
type Tick ¶ added in v0.2.19
Tick represents a signal received by an interrupt pin. This signal is communicated via registered channel to the various drivers. Depending on board implementation there may be a wraparound in timestamp values past 4294967295000 nanoseconds (~72 minutes) if the value was originally in microseconds as a 32-bit integer. The timestamp in nanoseconds of the tick SHOULD ONLY BE USED FOR CALCULATING THE TIME ELAPSED BETWEEN CONSECUTIVE TICKS AND NOT AS AN ABSOLUTE TIMESTAMP.
Source Files ¶
Directories ¶
Path | Synopsis |
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Package beaglebone implements a beaglebone based board.
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Package beaglebone implements a beaglebone based board. |
Package customlinux implements a board running Linux.
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Package customlinux implements a board running Linux. |
Package esp32 exists for the sole purpose of exposing the esp32 as a micro-rdk configuration in app.viam.com The ESP32 is supported by the micro-rdk only (https://github.com/viamrobotics/micro-rdk)
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Package esp32 exists for the sole purpose of exposing the esp32 as a micro-rdk configuration in app.viam.com The ESP32 is supported by the micro-rdk only (https://github.com/viamrobotics/micro-rdk) |
Package fake implements a fake board.
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Package fake implements a fake board. |
Package genericlinux implements a Linux-based board making heavy use of sysfs (https://en.wikipedia.org/wiki/Sysfs).
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Package genericlinux implements a Linux-based board making heavy use of sysfs (https://en.wikipedia.org/wiki/Sysfs). |
buses
Package buses is for I2C and SPI boards that run Linux.
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Package buses is for I2C and SPI boards that run Linux. |
hat
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pca9685
Package pca9685 implements a PCA9685 HAT.
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Package pca9685 implements a PCA9685 HAT. |
Package jetson implements a jetson-based board.
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Package jetson implements a jetson-based board. |
Package mcp3008helper is shared code for hooking an MCP3008 ADC up to a board.
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Package mcp3008helper is shared code for hooking an MCP3008 ADC up to a board. |
Package numato is for numato IO boards.
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Package numato is for numato IO boards. |
Package odroid implements a odroid based board.
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Package odroid implements a odroid based board. |
Package orangepi implements a orangepi based board.
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Package orangepi implements a orangepi based board. |
Package pi5 implements a raspberry pi 5 board.
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Package pi5 implements a raspberry pi 5 board. |
Package pinwrappers implements interfaces that wrap the basic board interface and return types, and expands them with new methods and interfaces for the built in board models.
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Package pinwrappers implements interfaces that wrap the basic board interface and return types, and expands them with new methods and interfaces for the built in board models. |
Package register registers all relevant Boards and also API specific functions
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Package register registers all relevant Boards and also API specific functions |
Package ti implements a ti based board.
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Package ti implements a ti based board. |
Package upboard implements an Intel based board.
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Package upboard implements an Intel based board. |