PKGBUILD/vendor/periph.io/x/periph/host/sysfs/gpio.go
2018-12-07 20:42:30 +01:00

516 lines
12 KiB
Go

// Copyright 2016 The Periph Authors. All rights reserved.
// Use of this source code is governed under the Apache License, Version 2.0
// that can be found in the LICENSE file.
package sysfs
import (
"errors"
"fmt"
"io"
"os"
"path/filepath"
"strconv"
"sync"
"time"
"periph.io/x/periph"
"periph.io/x/periph/conn"
"periph.io/x/periph/conn/gpio"
"periph.io/x/periph/conn/gpio/gpioreg"
"periph.io/x/periph/conn/physic"
"periph.io/x/periph/conn/pin"
"periph.io/x/periph/host/fs"
)
// Pins is all the pins exported by GPIO sysfs.
//
// Some CPU architectures have the pin numbers start at 0 and use consecutive
// pin numbers but this is not the case for all CPU architectures, some
// have gaps in the pin numbering.
//
// This global variable is initialized once at driver initialization and isn't
// mutated afterward. Do not modify it.
var Pins map[int]*Pin
// Pin represents one GPIO pin as found by sysfs.
type Pin struct {
number int
name string
root string // Something like /sys/class/gpio/gpio%d/
mu sync.Mutex
err error // If open() failed
direction direction // Cache of the last known direction
edge gpio.Edge // Cache of the last edge used.
fDirection fileIO // handle to /sys/class/gpio/gpio*/direction; never closed
fEdge fileIO // handle to /sys/class/gpio/gpio*/edge; never closed
fValue fileIO // handle to /sys/class/gpio/gpio*/value; never closed
event fs.Event // Initialized once
buf [4]byte // scratch buffer for Function(), Read() and Out()
}
// String implements conn.Resource.
func (p *Pin) String() string {
return p.name
}
// Halt implements conn.Resource.
//
// It stops edge detection if enabled.
func (p *Pin) Halt() error {
p.mu.Lock()
defer p.mu.Unlock()
return p.haltEdge()
}
// Name implements pin.Pin.
func (p *Pin) Name() string {
return p.name
}
// Number implements pin.Pin.
func (p *Pin) Number() int {
return p.number
}
// Function implements pin.Pin.
func (p *Pin) Function() string {
return string(p.Func())
}
// Func implements pin.PinFunc.
func (p *Pin) Func() pin.Func {
p.mu.Lock()
defer p.mu.Unlock()
// TODO(maruel): There's an internal bug which causes p.direction to be
// invalid (!?) Need to figure it out ASAP.
if err := p.open(); err != nil {
return pin.Func("ERR")
}
if _, err := seekRead(p.fDirection, p.buf[:]); err != nil {
return pin.Func("ERR")
}
if p.buf[0] == 'i' && p.buf[1] == 'n' {
p.direction = dIn
} else if p.buf[0] == 'o' && p.buf[1] == 'u' && p.buf[2] == 't' {
p.direction = dOut
}
if p.direction == dIn {
if p.Read() {
return gpio.IN_HIGH
}
return gpio.IN_LOW
} else if p.direction == dOut {
if p.Read() {
return gpio.OUT_HIGH
}
return gpio.OUT_LOW
}
return pin.Func("ERR")
}
// SupportedFuncs implements pin.PinFunc.
func (p *Pin) SupportedFuncs() []pin.Func {
return []pin.Func{gpio.IN, gpio.OUT}
}
// SetFunc implements pin.PinFunc.
func (p *Pin) SetFunc(f pin.Func) error {
switch f {
case gpio.IN:
return p.In(gpio.PullNoChange, gpio.NoEdge)
case gpio.OUT_HIGH:
return p.Out(gpio.High)
case gpio.OUT, gpio.OUT_LOW:
return p.Out(gpio.Low)
default:
return p.wrap(errors.New("unsupported function"))
}
}
// In implements gpio.PinIn.
func (p *Pin) In(pull gpio.Pull, edge gpio.Edge) error {
if pull != gpio.PullNoChange && pull != gpio.Float {
return p.wrap(errors.New("doesn't support pull-up/pull-down"))
}
p.mu.Lock()
defer p.mu.Unlock()
if p.direction != dIn {
if err := p.open(); err != nil {
return p.wrap(err)
}
if err := seekWrite(p.fDirection, bIn); err != nil {
return p.wrap(err)
}
p.direction = dIn
}
// Always push none to help accumulated flush edges. This is not fool proof
// but it seems to help.
if p.fEdge != nil {
if err := seekWrite(p.fEdge, bNone); err != nil {
return p.wrap(err)
}
}
// Assume that when the pin was switched, the driver doesn't recall if edge
// triggering was enabled.
if edge != gpio.NoEdge {
if p.fEdge == nil {
var err error
p.fEdge, err = fileIOOpen(p.root+"edge", os.O_RDWR)
if err != nil {
return p.wrap(err)
}
if err = p.event.MakeEvent(p.fValue.Fd()); err != nil {
_ = p.fEdge.Close()
p.fEdge = nil
return p.wrap(err)
}
}
// Always reset the edge detection mode to none after starting the epoll
// otherwise edges are not always delivered, as observed on an Allwinner A20
// running kernel 4.14.14.
if err := seekWrite(p.fEdge, bNone); err != nil {
return p.wrap(err)
}
var b []byte
switch edge {
case gpio.RisingEdge:
b = bRising
case gpio.FallingEdge:
b = bFalling
case gpio.BothEdges:
b = bBoth
}
if err := seekWrite(p.fEdge, b); err != nil {
return p.wrap(err)
}
}
p.edge = edge
// This helps to remove accumulated edges but this is not 100% sufficient.
// Most of the time the interrupts are handled promptly enough that this loop
// flushes the accumulated interrupt.
// Sometimes the kernel may have accumulated interrupts that haven't been
// processed for a long time, it can easily be >300µs even on a quite idle
// CPU. In this case, the loop below is not sufficient, since the interrupt
// will happen afterward "out of the blue".
if edge != gpio.NoEdge {
p.WaitForEdge(0)
}
return nil
}
// Read implements gpio.PinIn.
func (p *Pin) Read() gpio.Level {
// There's no lock here.
if p.fValue == nil {
return gpio.Low
}
if _, err := seekRead(p.fValue, p.buf[:]); err != nil {
// Error.
return gpio.Low
}
if p.buf[0] == '0' {
return gpio.Low
}
if p.buf[0] == '1' {
return gpio.High
}
// Error.
return gpio.Low
}
// WaitForEdge implements gpio.PinIn.
func (p *Pin) WaitForEdge(timeout time.Duration) bool {
// Run lockless, as the normal use is to call in a busy loop.
var ms int
if timeout == -1 {
ms = -1
} else {
ms = int(timeout / time.Millisecond)
}
start := time.Now()
for {
if nr, err := p.event.Wait(ms); err != nil {
return false
} else if nr == 1 {
// TODO(maruel): According to pigpio, the correct way to consume the
// interrupt is to call Seek().
return true
}
// A signal occurred.
if timeout != -1 {
ms = int((timeout - time.Since(start)) / time.Millisecond)
}
if ms <= 0 {
return false
}
}
}
// Pull implements gpio.PinIn.
//
// It returns gpio.PullNoChange since gpio sysfs has no support for input pull
// resistor.
func (p *Pin) Pull() gpio.Pull {
return gpio.PullNoChange
}
// DefaultPull implements gpio.PinIn.
//
// It returns gpio.PullNoChange since gpio sysfs has no support for input pull
// resistor.
func (p *Pin) DefaultPull() gpio.Pull {
return gpio.PullNoChange
}
// Out implements gpio.PinOut.
func (p *Pin) Out(l gpio.Level) error {
p.mu.Lock()
defer p.mu.Unlock()
if p.direction != dOut {
if err := p.open(); err != nil {
return p.wrap(err)
}
if err := p.haltEdge(); err != nil {
return err
}
// "To ensure glitch free operation, values "low" and "high" may be written
// to configure the GPIO as an output with that initial value."
var d []byte
if l == gpio.Low {
d = bLow
} else {
d = bHigh
}
if err := seekWrite(p.fDirection, d); err != nil {
return p.wrap(err)
}
p.direction = dOut
return nil
}
if l == gpio.Low {
p.buf[0] = '0'
} else {
p.buf[0] = '1'
}
if err := seekWrite(p.fValue, p.buf[:1]); err != nil {
return p.wrap(err)
}
return nil
}
// PWM implements gpio.PinOut.
//
// This is not supported on sysfs.
func (p *Pin) PWM(gpio.Duty, physic.Frequency) error {
return p.wrap(errors.New("pwm is not supported via sysfs"))
}
//
// open opens the gpio sysfs handle to /value and /direction.
//
// lock must be held.
func (p *Pin) open() error {
if p.fDirection != nil || p.err != nil {
return p.err
}
if drvGPIO.exportHandle == nil {
return errors.New("sysfs gpio is not initialized")
}
var err error
_, err = drvGPIO.exportHandle.Write([]byte(strconv.Itoa(p.number)))
if err != nil && !isErrBusy(err) {
p.err = err
if os.IsPermission(p.err) {
return fmt.Errorf("need more access, try as root or setup udev rules: %v", p.err)
}
return p.err
}
// There's a race condition where the file may be created but udev is still
// running the Raspbian udev rule to make it readable to the current user.
// It's simpler to just loop a little as if /export is accessible, it doesn't
// make sense that gpioN/value doesn't become accessible eventually.
timeout := 5 * time.Second
for start := time.Now(); time.Since(start) < timeout; {
p.fValue, err = fileIOOpen(p.root+"value", os.O_RDWR)
// The virtual file creation is synchronous when writing to /export for
// udev rule execution is asynchronous.
if err == nil {
break
}
if !os.IsPermission(err) {
p.err = err
break
}
}
if p.err != nil {
return p.err
}
p.fDirection, err = fileIOOpen(p.root+"direction", os.O_RDWR)
if err != nil {
p.err = err
_ = p.fValue.Close()
p.fValue = nil
}
return p.err
}
// haltEdge stops any on-going edge detection.
func (p *Pin) haltEdge() error {
if p.edge != gpio.NoEdge {
if err := seekWrite(p.fEdge, bNone); err != nil {
return p.wrap(err)
}
p.edge = gpio.NoEdge
// This is still important to remove an accumulated edge.
p.WaitForEdge(0)
}
return nil
}
func (p *Pin) wrap(err error) error {
return fmt.Errorf("sysfs-gpio (%s): %v", p, err)
}
//
type direction int
const (
dUnknown direction = 0
dIn direction = 1
dOut direction = 2
)
var (
bIn = []byte("in")
bLow = []byte("low")
bHigh = []byte("high")
bNone = []byte("none")
bRising = []byte("rising")
bFalling = []byte("falling")
bBoth = []byte("both")
)
// readInt reads a pseudo-file (sysfs) that is known to contain an integer and
// returns the parsed number.
func readInt(path string) (int, error) {
f, err := fileIOOpen(path, os.O_RDONLY)
if err != nil {
return 0, err
}
defer f.Close()
var b [24]byte
n, err := f.Read(b[:])
if err != nil {
return 0, err
}
raw := b[:n]
if len(raw) == 0 || raw[len(raw)-1] != '\n' {
return 0, errors.New("invalid value")
}
return strconv.Atoi(string(raw[:len(raw)-1]))
}
// driverGPIO implements periph.Driver.
type driverGPIO struct {
exportHandle io.Writer // handle to /sys/class/gpio/export
}
func (d *driverGPIO) String() string {
return "sysfs-gpio"
}
func (d *driverGPIO) Prerequisites() []string {
return nil
}
func (d *driverGPIO) After() []string {
return nil
}
// Init initializes GPIO sysfs handling code.
//
// Uses gpio sysfs as described at
// https://www.kernel.org/doc/Documentation/gpio/sysfs.txt
//
// GPIO sysfs is often the only way to do edge triggered interrupts. Doing this
// requires cooperation from a driver in the kernel.
//
// The main drawback of GPIO sysfs is that it doesn't expose internal pull
// resistor and it is much slower than using memory mapped hardware registers.
func (d *driverGPIO) Init() (bool, error) {
items, err := filepath.Glob("/sys/class/gpio/gpiochip*")
if err != nil {
return true, err
}
if len(items) == 0 {
return false, errors.New("no GPIO pin found")
}
// There are hosts that use non-continuous pin numbering so use a map instead
// of an array.
Pins = map[int]*Pin{}
for _, item := range items {
if err := d.parseGPIOChip(item + "/"); err != nil {
return true, err
}
}
drvGPIO.exportHandle, err = fileIOOpen("/sys/class/gpio/export", os.O_WRONLY)
if os.IsPermission(err) {
return true, fmt.Errorf("need more access, try as root or setup udev rules: %v", err)
}
return true, err
}
func (d *driverGPIO) parseGPIOChip(path string) error {
base, err := readInt(path + "base")
if err != nil {
return err
}
number, err := readInt(path + "ngpio")
if err != nil {
return err
}
// TODO(maruel): The chip driver may lie and lists GPIO pins that cannot be
// exported. The only way to know about it is to export it before opening.
for i := base; i < base+number; i++ {
if _, ok := Pins[i]; ok {
return fmt.Errorf("found two pins with number %d", i)
}
p := &Pin{
number: i,
name: fmt.Sprintf("GPIO%d", i),
root: fmt.Sprintf("/sys/class/gpio/gpio%d/", i),
}
Pins[i] = p
if err := gpioreg.Register(p); err != nil {
return err
}
// If there is a CPU memory mapped gpio pin with the same number, the
// driver has to unregister this pin and map its own after.
if err := gpioreg.RegisterAlias(strconv.Itoa(i), p.name); err != nil {
return err
}
}
return nil
}
func init() {
if isLinux {
periph.MustRegister(&drvGPIO)
}
}
var drvGPIO driverGPIO
var _ conn.Resource = &Pin{}
var _ gpio.PinIn = &Pin{}
var _ gpio.PinOut = &Pin{}
var _ gpio.PinIO = &Pin{}
var _ pin.PinFunc = &Pin{}