1
1
mirror of https://github.com/namibia/awesome-cheatsheets.git synced 2024-11-24 21:57:38 +00:00
awesome-cheatsheets/languages/golang.md
yogesnsamy b885d645fe
Update golang.md
Use propercase in renaming the function in the `Testing` example
2021-09-17 10:57:51 +08:00

16 KiB

Golang

Summary

Hello World

package main

import "fmt"

func main() {
    fmt.Println("Hello Gophers!")
}

Return to Summary


Go CLI Commands

# Compile & Run code
$ go run [file.go]

# Compile
$ go build [file.go]
# Running compiled file
$ ./hello

# Test packages
$ go test [folder]

# Install packages/modules
$ go install [package]

# List installed packages/modules
$ go list

# Update packages/modules
$ go fix

# Format package sources
$ go fmt

# See package documentation
$ go doc [package]

# Add dependencies and install
$ go get [module]

# See Go environment variables
$ go env

# See version
$ go version

Return to Summary


Go Modules

  • Go projects are called modules
  • Each module has multiple packages
  • Each package should has a scoped functionality. Packages talk to each other to compose the code
  • A module needs at least one package, the main
  • The package main needs a entry function called main
# Create Module
$ go mod init [name]

Tip: By convention, modules names has the follow structure:

domain.com/user/module/package

Example: github.com/spf13/cobra


Return to Summary

Basic Types

Type Set of Values Values
bool boolean true/false
string array of characters needs to be inside ""
int integers 32 or 64 bit integer
int8 8-bit integers [ -128, 128 ]
int16 16-bit integers [ -32768, 32767]
int32 32-bit integers [ -2147483648, 2147483647]
int64 64-bit integers [ -9223372036854775808, 9223372036854775807 ]
uint8 8-bit unsigned integers [ 0, 255 ]
uint16 16-bit unsigned integers [ 0, 65535 ]
uint32 32-bit unsigned integers [ 0, 4294967295 ]
uint64 64-bit unsigned integers [ 0, 18446744073709551615 ]
float32 32-bit float
float64 64-bit float
complex64 32-bit float with real and imaginary parts
complex128 64-bit float with real and imaginary parts
byte sets of bits alias for uint8
rune Unicode characters alias for int32

Return to Summary


Variables

// Declaration
var value int

// Initialization
value = 10

// Declaration + Initialization + Type inference
var isActive = true

// Short declaration (only inside functions)
text := "Hello"

// Multi declaration
var i, j, k = 1, 2, 3

// Variable not initialized = Zero values
// Numeric: 0
// Boolean: false
// String: ""
// Special value: nil (same as null)

var number int // 0
var text string // ""
var boolean bool // false

// Type conversions
// T(v) converts v to type T

i := 1.234 // float
int(i) // 1

// Constants
const pi = 3.1415

Operators

Return to Summary

Arithmetic Operators

Symbol Operation Valid Types
+ Sum integers, floats, complex values, strings
- Difference integers, floats, complex values
* Product integers, floats, complex values
/ Quotient integers, floats, complex values
% Remainder integers
& Bitwise AND integers
` ` Bitwise OR
^ Bitwise XOR integers
&^ Bit clear (AND NOT) integers
<< Left shift integer << unsigned integer
>> Right shift integer >> unsigned integer

Comparison Operators

Symbol Operation
== Equal
!= Not equal
< Less
<= Less or equal
> Greater
>= Greater or equal

Logical Operators

Symbol Operation
&& Conditional AND
`
! NOT

Return to Summary


Conditional Statements

// If / Else
i := 1

if i > 0 {
    // Condition is True! i is greater than zero
} else {
    // Condition is False! i is lower or equal to zero
}

// Else if
i := 1

if i > 0 {
    // Condition is True! i is greater than zero
} else if i > 0 && i < 2 {
    // Condition is True! i greater than zero and lower than two
} else if i > 1 && i < 4 {
    // Condition is True! i greater than one and lower than four
} else {
    // None of the above conditions is True, so it falls here
}

// If with short statements
i := 2.567

if j := int(i); j == 2 {
    // Condition is True! j, the integer value of i, is equal to two
} else {
    // Condition is False! j, the integer value of i, is not equal to two
}

// Switch
text := 'hey'

switch text {
    case 'hey':
        // 'Hello!'
    case 'bye':
        // 'Byee'
    default:
        // 'Ok'
}

// Switch without condition
value := 5

switch {
    case value < 2:
        // 'Hello!'
    case value >= 2 && value < 6:
        // 'Byee'
    default:
        // 'Ok'
}

Return to Summary


Loops

// Golang only has the for loop
for i := 0; i < 10; i++ {
    // i
}

// The first and third parameters are ommitable
// For as a while
i := 0;

for i < 10 {
    i++
}

// Forever loop
for {

}

Return to Summary


Arrays

// Declaration with specified size
var array [3]string
array[0] = "Hello"
array[1] = "Golang"
array[2] = "World"

// Declaration and Initialization
values := [5]int{1, 2, 3, 4, 5}

// Slices: A subarray that acts as a reference of an array
// Determining min and max
values[1:3] // {2, 3, 4}

// Determining only max will use min = 0
values[:2] // {1, 2, 3}

// Determining only min will use max = last element
values[3:] // {3, 4}

// Length: number of elements that a slice contains
len(values) // 5

// Capacity: number of elements that a slice can contain
values = values[:1]
len(values) // 2
cap(values) // 5

// Slice literal
slice := []bool{true, true, false}

// make function: create a slice with length and capacity
slice := make([]int, 5, 6) // make(type, len, cap)

// Append new element to slice
slice := []int{ 1, 2 }
slice = append(slice, 3)
slice // { 1, 2, 3 }
slice = append(slice, 3, 2, 1)
slice // { 1, 2, 3, 3, 2, 1 }

// For range: iterate over a slice
slice := string["W", "o", "w"]

for i, value := range slice {
    i // 0, then 1, then 2
    value // "W", then "o", then "w"
}

// Skip index or value

for i := range slice {
    i // 0, then 1, then 2
}

for _, value := range slice {
   value // "W", then "o", then "w"
}

Return to Summary


Functions

// Functions acts as a scoped block of code
func sayHello() {
    // Hello World!
}
sayHello() // Hello World!

// Functions can take zero or more parameters, as so return zero or more parameters
func sum(x int, y int) int {
    return x + y
}
sum(3, 7) // 10

// Returned values can be named and be used inside the function
func doubleAndTriple(x int) (double, triple int) {
    double = x * 2
    triple = x * 3
    return
}
d, t := doubleAndTriple(5)
// d = 10
// t = 15

// Skipping one of the returned values
_, t := doubleAndTriple(3)
// t = 9

// Functions can defer commands. Defered commands are
// runned in a stack order after the execution and
// returning of a function
var aux = 0

func switchValuesAndDouble(x, y int) {
    aux = x
    defer aux = 0 // cleaning variable to post use
    x = y * 2
    y = aux * 2
}

a, b = 2, 5
switchValuesAndDouble(2, 5)

// a = 10
// b = 4
// aux = 0

// Functions can be handled as values and be anonymous functions
func calc(fn func(int, int) int) int {
    return fn(2, 6)
}

func sum(x, y int) int {
    return x + y
}

func mult(x, y int) int {
    return x * y
}

calc(sum) // 8
calc(mult) // 12
calc(
    func(x, y int) int {
		return x / y
    }
) // 3

// Function closures: a function that returns a function
// that remembers the original context
func calc() func(int) int {
    value := 0
    return func(x int) int {
        value += x
        return value
    }
}

calculator := calc()
calculator(3) // 3
calculator(45) // 48
calculator(12) // 60

Return to Summary


Structs

Structs are a way to arrange data in specific formats.

// Declaring a struct
type Person struct {
    Name string
    Age int
}

// Initializing
person := Person{"John", 34}
person.Name // "John"
person.Age // 34

person2 := Person{Age: 20}
person2.Name // ""
person2.Age // 20

person3 := Person{}
person3.Name // ""
person3.Age // 0

Return to Summary


Maps

Maps are data structures that holds values assigneds to a key.

// Declaring a map
var cities map[string]string

// Initializing
cities = make(map[string]string)
cities // nil

// Insert
cities["NY"] = "EUA"

// Retrieve
newYork = cities["NY"]
newYork // "EUA"

// Delete
delete(cities, "NY")

// Check if a key is setted
value, ok := cities["NY"]
ok // false
value // ""

Return to Summary


Pointers

Pointers are a direct reference to a memory address that some variable or value is being stored.

// Pointers has *T type
var value int
var pointer *int

// Point to a variable memory address with &
value = 3
pointer = &value

pointer // 3
pointer = 20
pointer // 20
pointer += 5
pointer // 25

// Pointers to structs can access the attributes
type Struct struct {
    X int
}

s := Struct{3}
pointer := &s

s.X // 3

Obs: Unlike C, Go doesn't have pointer arithmetics.

Return to Summary


Methods and Interfaces

Go doesn't have classes. But you can implement methods, interfaces and almost everything contained in OOP, but in what gophers call "Go Way"

type Dog struct {
    Name string
}

func (dog *Dog) bark() string {
    return dog.Name + " is barking!"
}

dog := Dog{"Rex"}
dog.bark() // Rex is barking!

Interfaces are implicitly implemented. You don't need to inform that your struct are correctly implementing a interface if it already has all methods with the same name of the interface. All structs implement the interface{} interface. This empty interface means the same as any.

// Car implements Vehicle interface
type Vehicle interface {
    Accelerate()
}

type Car struct {

}

func (car *Car) Accelerate() {
    return "Car is moving on ground"
}

Return to Summary


Errors

Go doesn't support throw, try, catch and other common error handling structures. Here, we use error package to build possible errors as a returning parameter in functions

import "errors"

// Function that contain a logic that can cause a possible exception flow 
func firstLetter(text string) (string, error) {
    if len(text) < 1 {
        return nil, errors.New("Parameter text is empty")
    }
    return string(text[0]), nil
}

a, errorA := firstLetter("Wow")
a // "W"
errorA // nil

b, errorB := firstLetter("")
b // nil
errorB // Error("Parameter text is empty")

Return to Summary


Testing

Go has a built-in library to unit testing. In a separate file you insert tests for functionalities of a file and run go test package to run all tests of the actual package or go test path to run a specific test file.

// main.go
func Sum(x, y int) int {
    return x + y
}

// main_test.go
import ( 
    "testing"
    "reflect"
)

func TestSum(t *testing.T) {
    x, y := 2, 4
    expected := 2 + 4

    if !reflect.DeepEqual(Sum(x, y), expected) {
        t.Fatalf("Function Sum not working as expected")
    }
}

Return to Summary


Concurrency

One of the main parts that make Go attractive is its form to handle with concurrency. Different than parallelism, where tasks can be separated in many cores that the machine processor have, in concurrency we have routines that are more lightweight than threads and can run asynchronously, with memory sharing and in a single core.

// Consider a common function, but that function can delay itself because some processing
func show(from string) {
	for i := 0; i < 3; i++ {
		fmt.Printf("%s : %d\n", from, i)
	}
}

// In a blocking way...
func main() {
	show("blocking1")
	show("blocking2")

	fmt.Println("done")
}
/*  blocking1: 0
    blocking1: 1
    blocking1: 2
    blocking2: 0
    blocking2: 1
    blocking2: 2
    done 
*/

// Go routines are a function (either declared previously or anonymous) called with the keyword go
func main() {
	go show("routine1")
	go show("routine2")

	go func() {
		fmt.Println("going")
	}()

	time.Sleep(time.Second)

	fmt.Println("done")
}

/*  Obs: The result will depends of what processes first
    routine2: 0
    routine2: 1
    routine2: 2
    going
    routine1: 0
    routine1: 1
    routine1: 2
    done
*/

// Routines can share data with channels
// Channels are queues that store data between multiple routines
msgs := make(chan string)

go func(channel chan string) {
    channel <- "ping"
}(msgs)

go func(channel chan string) {
    channel <- "pong"
}(msgs)

fmt.Println(<-msgs) // pong
fmt.Println(<-msgs) // ping

// Channels can be bufferized. Buffered channels will accept a limited number of values and when someone try to put belong their limit, it will throw and error
numbers := make(chan int, 2)

msgs<-0
msgs<-1
msgs<-2

// fatal error: all goroutines are asleep - deadlock!

// Channels can be passed as parameter where the routine can only send or receive
numbers := make(chan int)

go func(sender chan<- int) {
    sender <- 10
}(numbers)

go func(receiver <-chan int) {
    fmt.Println(<-receiver) // 10
}(numbers)

time.Sleep(time.Second)

// When working with multiple channels, the select can provide a control to execute code accordingly of what channel has bring a message
c1 := make(chan string)
c2 := make(chan string)

select {
case msg1 := <-c1:
    fmt.Println("received", msg1)
case msg2 := <-c2:
    fmt.Println("received", msg2)
default:
    fmt.Println("no messages")
}

go func() {
    time.Sleep(1 * time.Second)
    c1 <- "channel1 : one"
}()
go func() {
    time.Sleep(2 * time.Second)
    c2 <- "channel2 : one"
}()

for i := 0; i < 2; i++ {
    select {
    case msg1 := <-c1:
        fmt.Println("received", msg1)
    case msg2 := <-c2:
        fmt.Println("received", msg2)
    }
}

/*
    no messages
    received channel1: one
    received channel2: one
*/

// Channels can be closed and iterated
channel := make(chan int, 5)

for i := 0; i < 5; i++ {
    channel <- i
}

close(channel)

for value := range channel {
    fmt.Println(value)
}

/*
    0
    1
    2
    3
    4
*/

Return to Summary


Package fmt

import "fmt"

fmt.Print("Hello World") // Print in console
fmt.Println("Hello World") // Print and add a new line in end
fmt.Printf("%s is %d years old", "John", 32) // Print with formatting
fmt.Errorf("User %d not found", 123) // Print a formatted error

Return to Summary