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mirror of https://github.com/kidoman/embd synced 2024-12-22 04:40:04 +01:00

add documentation

This commit is contained in:
Karan Misra 2014-03-23 14:09:31 +05:30
parent a35692aabb
commit 0002d02c28
8 changed files with 117 additions and 8 deletions

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@ -1,3 +1,7 @@
// Digital IO support.
// This driver requires kernel version 3.8+ and should work uniformly
// across all supported devices.
package embd
import (

66
gpio.go
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@ -1,50 +1,84 @@
// GPIO support.
package embd
// The Direction type indicates the direction of a GPIO pin.
type Direction int
const (
// In represents read mode.
In Direction = iota
// Out represents write mode.
Out
)
const (
// Low represents 0.
Low int = iota
// High represents 1.
High
)
// DigitalPin implements access to a digital IO capable GPIO pin.
type DigitalPin interface {
// N returns the logical GPIO number.
N() int
// Write writes the provided value to the pin.
Write(val int) error
// Read reads the value from the pin.
Read() (int, error)
// SetDirection sets the direction of the pin (in/out).
SetDirection(dir Direction) error
// ActiveLow makes the pin active low. A low logical state is represented by
// a high state on the physical pin, and vice-versa.
ActiveLow(b bool) error
// PullUp pulls the pin up.
PullUp() error
// PullDown pulls the pin down.
PullDown() error
// Close releases the resources associated with the pin.
Close() error
}
// AnalogPin implements access to a analog IO capable GPIO pin.
type AnalogPin interface {
// N returns the logical GPIO number.
N() int
// Write writes the provided value to the pin.
Write(val int) error
// Read reads the value from the pin.
Read() (int, error)
// Close releases the resources associated with the pin.
Close() error
}
// GPIODriver implements a generic GPIO driver.
type GPIODriver interface {
// DigitalPin returns a pin capable of doing digital IO.
DigitalPin(key interface{}) (DigitalPin, error)
// AnalogPin returns a pin capable of doing analog IO.
AnalogPin(key interface{}) (AnalogPin, error)
// Close releases the resources associated with the driver.
Close() error
}
var gpioDriverInstance GPIODriver
// InitGPIO initializes the GPIO driver.
func InitGPIO() error {
desc, err := DescribeHost()
if err != nil {
@ -60,14 +94,18 @@ func InitGPIO() error {
return nil
}
// CloseGPIO releases resources associated with the GPIO driver.
func CloseGPIO() error {
return gpioDriverInstance.Close()
}
// NewDigitalPin returns a DigitalPin interface which allows control over
// the digital GPIO pin.
func NewDigitalPin(key interface{}) (DigitalPin, error) {
return gpioDriverInstance.DigitalPin(key)
}
// DigitalWrite writes val to the pin.
func DigitalWrite(key interface{}, val int) error {
pin, err := NewDigitalPin(key)
if err != nil {
@ -77,6 +115,7 @@ func DigitalWrite(key interface{}, val int) error {
return pin.Write(val)
}
// DigitalRead reads a value from the pin.
func DigitalRead(key interface{}) (int, error) {
pin, err := NewDigitalPin(key)
if err != nil {
@ -86,6 +125,7 @@ func DigitalRead(key interface{}) (int, error) {
return pin.Read()
}
// SetDirection sets the direction of the pin (in/out).
func SetDirection(key interface{}, dir Direction) error {
pin, err := NewDigitalPin(key)
if err != nil {
@ -95,6 +135,8 @@ func SetDirection(key interface{}, dir Direction) error {
return pin.SetDirection(dir)
}
// ActiveLow makes the pin active low. A low logical state is represented by
// a high state on the physical pin, and vice-versa.
func ActiveLow(key interface{}, b bool) error {
pin, err := NewDigitalPin(key)
if err != nil {
@ -104,10 +146,33 @@ func ActiveLow(key interface{}, b bool) error {
return pin.ActiveLow(b)
}
// PullUp pulls the pin up.
func PullUp(key interface{}) error {
pin, err := NewDigitalPin(key)
if err != nil {
return err
}
return pin.PullUp()
}
// PullDown pulls the pin down.
func PullDown(key interface{}) error {
pin, err := NewDigitalPin(key)
if err != nil {
return err
}
return pin.PullDown()
}
// NewAnalogPin returns a AnalogPin interface which allows control over
// the analog GPIO pin.
func NewAnalogPin(key interface{}) (AnalogPin, error) {
return gpioDriverInstance.AnalogPin(key)
}
// AnalogWrite writes the provided value to the pin.
func AnalogWrite(key interface{}, val int) error {
pin, err := NewAnalogPin(key)
if err != nil {
@ -117,6 +182,7 @@ func AnalogWrite(key interface{}, val int) error {
return pin.Write(val)
}
// AnalogWrite reads a value from the pin.
func AnalogRead(key interface{}) (int, error) {
pin, err := NewAnalogPin(key)
if err != nil {

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@ -1,3 +1,5 @@
// Generic GPIO driver.
package embd
import (

4
i2c.go
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@ -52,12 +52,12 @@ func InitI2C() error {
return nil
}
// CloseI2C gracefully closes the I2C driver.
// CloseI2C releases resources associated with the I2C driver.
func CloseI2C() error {
return i2cDriverInstance.Close()
}
// NewI2CBus returns a I2CBus corresponding to the provided address.
// NewI2CBus returns a I2CBus.
func NewI2CBus(l byte) I2CBus {
return i2cDriverInstance.Bus(l)
}

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@ -1,3 +1,5 @@
// Generic I2C driver.
package embd
import (

16
led.go
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@ -4,11 +4,16 @@ package embd
// The LED interface is used to control a led on the prototyping board.
type LED interface {
// On switches the LED on.
On() error
// Off switches the LED off.
Off() error
// Toggle toggles the LED.
Toggle() error
// Close releases resources associated with the LED.
Close() error
}
@ -38,18 +43,17 @@ func InitLED() error {
return nil
}
// CloseLED gracefully closes the LED driver.
// CloseLED releases resources associated with the LED driver.
func CloseLED() error {
return ledDriverInstance.Close()
}
// NewLED returns a LED interface which allows control over the LED
// represented by key.
// NewLED returns a LED interface which allows control over the LED.
func NewLED(key interface{}) (LED, error) {
return ledDriverInstance.LED(key)
}
// LEDOn switches the corresponding LED on.
// LEDOn switches the LED on.
func LEDOn(key interface{}) error {
led, err := NewLED(key)
if err != nil {
@ -59,7 +63,7 @@ func LEDOn(key interface{}) error {
return led.On()
}
// LEDOff switches the corresponding LED off.
// LEDOff switches the LED off.
func LEDOff(key interface{}) error {
led, err := NewLED(key)
if err != nil {
@ -69,7 +73,7 @@ func LEDOff(key interface{}) error {
return led.Off()
}
// LEDToggle toggles the corresponding LED.
// LEDToggle toggles the LED.
func LEDToggle(key interface{}) error {
led, err := NewLED(key)
if err != nil {

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@ -1,3 +1,5 @@
// Generic LED driver.
package embd
import (
@ -9,6 +11,7 @@ import (
"strings"
)
// LEDMap type represents a LED mapping for a host.
type LEDMap map[string][]string
type ledDriver struct {

28
pin.go
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@ -1,3 +1,5 @@
// Pin mapping support.
package embd
import (
@ -6,16 +8,32 @@ import (
)
const (
// CapNormal represents the digital IO capability.
CapNormal int = 1 << iota
// CapI2C represents pins with the I2C capability.
CapI2C
// CapUART represents pins with the UART capability.
CapUART
// CapSPI represents pins with the SPI capability.
CapSPI
// CapGPMS represents pins with the GPMC capability.
CapGPMC
// CapLCD represents pins used to carry LCD data.
CapLCD
// CapPWM represents pins with PWM capability.
CapPWM
// CapAnalog represents pins with analog IO capability.
CapAnalog
)
// PinDesc represents a pin descriptor.
type PinDesc struct {
ID string
Aliases []string
@ -25,8 +43,18 @@ type PinDesc struct {
AnalogLogical int
}
// PinMap type represents a collection of pin descriptors.
type PinMap []*PinDesc
// Lookup returns a pin descriptor matching the provided key and capability
// combination. This allows the same keys to be used across pins with differing
// capabilities. For example, it is perfectly fine to have:
//
// pin1: {Aliases: [10, GPIO10], Cap: CapNormal}
// pin2: {Aliases: [10, AIN0], Cap: CapAnalog}
//
// Searching for 10 with CapNormal will return pin1 and searching for
// 10 with CapAnalog will return pin2. This makes for a very pleasant to use API.
func (m PinMap) Lookup(k interface{}, cap int) (*PinDesc, bool) {
var ks string
switch key := k.(type) {