- doc/users/ for ready-to-use tools.
- doc/apps/ to use
periphas a library. The complete API documentation, including examples, is at.
- doc/drivers/ to expand the list of supported hardware.
periph includes many ready-to-use tools! See doc/users/ for more info on configuring the host and using the included tools.
go get github.com/google/periph/cmd/...
periph-info
headers-listFor application developers, periph provides OS-independent bus
interfacing. The following gets the current temperature, barometric pressure and
relative humidity using a bme280:
package main
import (
"fmt"
"log"
"github.com/google/periph/devices"
"github.com/google/periph/devices/bme280"
"github.com/google/periph/host"
)
func main() {
// Load all the drivers:
if _, err := host.Init(); err != nil {
log.Fatal(err)
}
// Open a handle to the first available I²C bus. It could be via a FT232H
// over USB or an I²C bus exposed on the host's headers, it doesn't matter.
bus, err := i2c.New(-1)
if err != nil {
log.Fatal(err)
}
defer bus.Close()
// Open a handle to a bme280 connected on the I²C bus using default settings:
dev, err := bme280.NewI2C(bus, nil)
if err != nil {
log.Fatal(err)
}
defer dev.Close()
// Read temperature from the sensor:
var env devices.Environment
if err = dev.Sense(&env); err != nil {
log.Fatal(err)
}
fmt.Printf("%8s %10s %9s\n", env.Temperature, env.Pressure, env.Humidity)
}See doc/apps/SAMPLES.md for more examples.
periph provides an extensible driver registry and common bus interfaces which
are explained in more details at doc/drivers/. periph is
designed to work well with drivers living in external repositories so you are
not required to fork the periph repository to load out-of-tree drivers for
your platform.
We gladly accept contributions from device driver developers via GitHub pull requests, as long as the author has signed the Google Contributor License. Please see doc/drivers/CONTRIBUTING.md for more details.
- Optimize for simplicity, correctness and usability in that order.
- e.g. everything, interfaces and structs, uses strict typing, there's no
interface{}in sight.
- e.g. everything, interfaces and structs, uses strict typing, there's no
- OS agnostic. Clear separation of interfaces in conn/,
enablers in host/ and device drivers in devices/.
- e.g. no devfs or sysfs path in sight.
- e.g. conditional compilation enables only the relevant drivers to be loaded on each platform.
- ... yet doesn't get in the way of platform specific code.
- e.g. A user can use statically typed global variables rpi.P1_3, bcm283x.GPIO2 or bcm283x.I2C1_SDA to refer to the exact same pin when I²C bus #1 is enabled on a Raspberry Pi.
- The user can chose to optimize for performance instead of usability.
- e.g. apa102.Dev exposes both high level draw.Image to draw an image and low level io.Writer to write raw RGB 24 bits pixels. The user chooses.
- Use a divide and conquer approach. Each component has exactly one
responsibility.
- e.g. instead of having a driver per "platform", there's a driver per "component": one for the CPU, one for the board headers, one for each bus and sensor, etc.
- Extensible via a driver
registry.
- e.g. a user can inject a custom driver to expose more pins, headers, etc. A USB device (like an FT232H) can expose headers in addition to the headers found on the host.
- The drivers must use the fastest possible implementation.
The main author is Marc-Antoine Ruel. The full list is in AUTHORS and CONTRIBUTORS.
This is not an official Google product (experimental or otherwise), it is just code that happens to be owned by Google.
This project is not affiliated with the Go project.