stevegt/learn.go

## learn.go
// Single line comment
/* Multi-
   line comment */

// A package clause starts every source file.
// Main is a special name declaring an executable rather than a library.
package main

// Import declaration declares library packages referenced in this file.
import (
	"fmt"       // A package in the Go standard library.
	"io/ioutil" // Implements some I/O utility functions.
	m "math"    // Math library with local alias m.
	"net/http"  // Yes, a web server!
	"strconv"   // String conversions.
)

// A function definition.  Main is special.  It is the entry point for the
// executable program.  Love it or hate it, Go uses brace brackets.
func main() {
	// Println outputs a line to stdout.
	// Qualify it with the package name, fmt.
	fmt.Println("Hello world!")

	// Call another function within this package.
	beyondHello()
}

// Functions have parameters in parentheses.
// If there are no parameters, empty parentheses are still required.
func beyondHello() {
	var x int // Variable declaration. Variables must be declared before use.
	x = 3     // Variable assignment.
	// "Short" declarations use := to infer the type, declare, and assign.
	y := 4
	sum, prod := learnMultiple(x, y)        // Function returns two values.
	fmt.Println("sum:", sum, "prod:", prod) // Simple output.
	learnTypes()                            // < y minutes, learn more!
}

// Functions can have parameters and (multiple!) return values.
func learnMultiple(x, y int) (sum, prod int) {
	return x + y, x * y // Return two values.
}

// Some built-in types and literals.
func learnTypes() {
	// Short declaration usually gives you what you want.
	s := "Learn Go!" // string type.

	s2 := `A "raw" string literal
can include line breaks.` // Same string type.

	// Non-ASCII literal.  Go source is UTF-8.
	g := 'Σ' // rune type, an alias for uint32, holds a unicode code point.

	f := 3.14195 // float64, an IEEE-754 64-bit floating point number.
	c := 3 + 4i  // complex128, represented internally with two float64's.

	// Var syntax with an initializers.
	var u uint = 7 // Unsigned, but implementation dependent size as with int.
	var pi float32 = 22. / 7

	// Conversion syntax with a short declaration.
	n := byte('\n') // byte is an alias for uint8.

	// Arrays have size fixed at compile time.
	var a4 [4]int           // An array of 4 ints, initialized to all 0.
	a3 := [...]int{3, 1, 5} // An array of 3 ints, initialized as shown.

	// Slices have dynamic size.  Arrays and slices each have advantages
	// but use cases for slices are much more common.
	s3 := []int{4, 5, 9}    // Compare to a3.  No ellipsis here.
	s4 := make([]int, 4)    // Allocates slice of 4 ints, initialized to all 0.
	var d2 [][]float64      // Declaration only, nothing allocated here.
	bs := []byte("a slice") // Type conversion syntax.

	p, q := learnMemory() // Declares p, q to be type pointer to int.
	fmt.Println(*p, *q)   // * follows a pointer.  This prints two ints.

	// Maps are a dynamically growable associative array type, like the
	// hash or dictionary types of some other languages.
	m := map[string]int{"three": 3, "four": 4}
	m["one"] = 1

	// Unused variables are an error in Go.
	// The underbar lets you "use" a variable but discard its value.
	_, _, _, _, _, _, _, _, _ = s2, g, f, u, pi, n, a3, s4, bs
	// Output of course counts as using a variable.
	fmt.Println(s, c, a4, s3, d2, m)

	learnFlowControl() // Back in the flow.
}

// It is possible, unlike in many other languages for functions in go
// to have named return values.
// Assigning a name to the type being returned in the function declaration line
// allows us to easily return from multiple points in a function as well as to
// only use the return keyword, without anything further.
func learnNamedReturns(x, y int) (z int) {
	z = x * y
	return // z is implicit here, because we named it earlier.
}

// Go is fully garbage collected.  It has pointers but no pointer arithmetic.
// You can make a mistake with a nil pointer, but not by incrementing a pointer.
func learnMemory() (p, q *int) {
	// Named return values p and q have type pointer to int.
	p = new(int) // Built-in function new allocates memory.
	// The allocated int is initialized to 0, p is no longer nil.
	s := make([]int, 20) // Allocate 20 ints as a single block of memory.
	s[3] = 7             // Assign one of them.
	r := -2              // Declare another local variable.
	return &s[3], &r     // & takes the address of an object.
}

func expensiveComputation() float64 {
	return m.Exp(10)
}

func learnFlowControl() {
	// If statements require brace brackets, and do not require parens.
	if true {
		fmt.Println("told ya")
	}
	// Formatting is standardized by the command line command "go fmt."
	if false {
		// Pout.
	} else {
		// Gloat.
	}
	// Use switch in preference to chained if statements.
	x := 42.0
	switch x {
	case 0:
	case 1:
	case 42:
		// Cases don't "fall through".
	case 43:
		// Unreached.
	}
	// Like if, for doesn't use parens either.
	// Variables declared in for and if are local to their scope.
	for x := 0; x < 3; x++ { // ++ is a statement.
		fmt.Println("iteration", x)
	}
	// x == 42 here.

	// For is the only loop statement in Go, but it has alternate forms.
	for { // Infinite loop.
		break    // Just kidding.
		continue // Unreached.
	}
	// As with for, := in an if statement means to declare and assign
	// y first, then test y > x.
	if y := expensiveComputation(); y > x {
		x = y
	}
	// Function literals are closures.
	xBig := func() bool {
		return x > 10000 // References x declared above switch statement.
	}
	fmt.Println("xBig:", xBig()) // true (we last assigned e^10 to x).
	x = 1.3e3                    // This makes x == 1300
	fmt.Println("xBig:", xBig()) // false now.

	// What's more is function literals may be defined and called inline,
	// acting as an argument to function, as long as:
	// a) function literal is called immediately (),
	// b) result type matches expected type of argument.
	fmt.Println("Add + double two numbers: ",
		func(a, b int) int {
			return (a + b) * 2
		}(10, 2)) // Called with args 10 and 2
	// => Add + double two numbers:  24

	// When you need it, you'll love it.
	goto love
love:

	learnFunctionFactory() // func returning func is fun(3)(3)
	learnDefer()      // A quick detour to an important keyword.
	learnInterfaces() // Good stuff coming up!
}

func learnFunctionFactory() {
	// Next two are equivalent, with second being more practical
	fmt.Println(sentenceFactory("summer")("A beautiful", "day!"))

	d := sentenceFactory("summer")
	fmt.Println(d("A beautiful", "day!"))
	fmt.Println(d("A lazy", "afternoon!"))
}

// Decorators are common in other languages. Same can be done in Go
// with function literals that accept arguments.
func sentenceFactory(mystring string) func(before, after string) string {
	return func(before, after string) string {
		return fmt.Sprintf("%s %s %s", before, mystring, after) // new string
	}
}

func learnDefer() (ok bool) {
	// Deferred statements are executed just before the function returns.
	defer fmt.Println("deferred statements execute in reverse (LIFO) order.")
	defer fmt.Println("\nThis line is being printed first because")
	// Defer is commonly used to close a file, so the function closing the
	// file stays close to the function opening the file.
	return true
}

// Define Stringer as an interface type with one method, String.
type Stringer interface {
	String() string
}

// Define pair as a struct with two fields, ints named x and y.
type pair struct {
	x, y int
}

// Define a method on type pair.  Pair now implements Stringer.
func (p pair) String() string { // p is called the "receiver"
	// Sprintf is another public function in package fmt.
	// Dot syntax references fields of p.
	return fmt.Sprintf("(%d, %d)", p.x, p.y)
}

func learnInterfaces() {
	// Brace syntax is a "struct literal."  It evaluates to an initialized
	// struct.  The := syntax declares and initializes p to this struct.
	p := pair{3, 4}
	fmt.Println(p.String()) // Call String method of p, of type pair.
	var i Stringer          // Declare i of interface type Stringer.
	i = p                   // Valid because pair implements Stringer
	// Call String method of i, of type Stringer.  Output same as above.
	fmt.Println(i.String())

	// Functions in the fmt package call the String method to ask an object
	// for a printable representation of itself.
	fmt.Println(p) // Output same as above. Println calls String method.
	fmt.Println(i) // Output same as above.

	learnVariadicParams("great", "learning", "here!")
}

// Functions can have variadic parameters.
func learnVariadicParams(myStrings ...interface{}) {
	// Iterate each value of the variadic.
	// The underbar here is ignoring the index argument of the array.
	for _, param := range myStrings {
		fmt.Println("param:", param)
	}

	// Pass variadic value as a variadic parameter.
	fmt.Println("params:", fmt.Sprintln(myStrings...))

	learnErrorHandling()
}

func learnErrorHandling() {
	// ", ok" idiom used to tell if something worked or not.
	m := map[int]string{3: "three", 4: "four"}
	if x, ok := m[1]; !ok { // ok will be false because 1 is not in the map.
		fmt.Println("no one there")
	} else {
		fmt.Print(x) // x would be the value, if it were in the map.
	}
	// An error value communicates not just "ok" but more about the problem.
	if _, err := strconv.Atoi("non-int"); err != nil { // _ discards value
		// prints 'strconv.ParseInt: parsing "non-int": invalid syntax'
		fmt.Println(err)
	}
	// We'll revisit interfaces a little later.  Meanwhile,
	learnConcurrency()
}

// c is a channel, a concurrency-safe communication object.
func inc(i int, c chan int) {
	c <- i + 1 // <- is the "send" operator when a channel appears on the left.
}

// We'll use inc to increment some numbers concurrently.
func learnConcurrency() {
	// Same make function used earlier to make a slice.  Make allocates and
	// initializes slices, maps, and channels.
	c := make(chan int)
	// Start three concurrent goroutines.  Numbers will be incremented
	// concurrently, perhaps in parallel if the machine is capable and
	// properly configured.  All three send to the same channel.
	go inc(0, c) // go is a statement that starts a new goroutine.
	go inc(10, c)
	go inc(-805, c)
	// Read three results from the channel and print them out.
	// There is no telling in what order the results will arrive!
	fmt.Println(<-c, <-c, <-c) // channel on right, <- is "receive" operator.

	cs := make(chan string)       // Another channel, this one handles strings.
	ccs := make(chan chan string) // A channel of string channels.
	go func() { c <- 84 }()       // Start a new goroutine just to send a value.
	go func() { cs <- "wordy" }() // Again, for cs this time.
	// Select has syntax like a switch statement but each case involves
	// a channel operation.  It selects a case at random out of the cases
	// that are ready to communicate.
	select {
	case i := <-c: // The value received can be assigned to a variable,
		fmt.Printf("it's a %T", i)
	case <-cs: // or the value received can be discarded.
		fmt.Println("it's a string")
	case <-ccs: // Empty channel, not ready for communication.
		fmt.Println("didn't happen.")
	}
	// At this point a value was taken from either c or cs.  One of the two
	// goroutines started above has completed, the other will remain blocked.

	learnWebProgramming() // Go does it. You want to do it too.
}

// A single function from package http starts a web server.
func learnWebProgramming() {

	// First parameter of ListenAndServe is TCP address to listen to.
	// Second parameter is an interface, specifically http.Handler.
	go func() {
		err := http.ListenAndServe(":8080", pair{})
		fmt.Println(err) // don't ignore errors
	}()

	requestServer()
}

// Make pair an http.Handler by implementing its only method, ServeHTTP.
func (p pair) ServeHTTP(w http.ResponseWriter, r *http.Request) {
	// Serve data with a method of http.ResponseWriter.
	w.Write([]byte("You learned Go in Y minutes!"))
}

func requestServer() {
	resp, err := http.Get("http://localhost:8080")
	fmt.Println(err)
	defer resp.Body.Close()
	body, err := ioutil.ReadAll(resp.Body)
	fmt.Printf("\nWebserver said: `%s`", string(body))
}
	// Single line comment
	/* Multi-
	line comment */

	// A package clause starts every source file.
	// Main is a special name declaring an executable rather than a library.
	package main

	// Import declaration declares library packages referenced in this file.
	import (
	"fmt" // A package in the Go standard library.
	"io/ioutil" // Implements some I/O utility functions.
	m "math" // Math library with local alias m.
	"net/http" // Yes, a web server!
	"strconv" // String conversions.
	)

	// A function definition. Main is special. It is the entry point for the
	// executable program. Love it or hate it, Go uses brace brackets.
	func main() {
	// Println outputs a line to stdout.
	// Qualify it with the package name, fmt.
	fmt.Println("Hello world!")

	// Call another function within this package.
	beyondHello()
	}

	// Functions have parameters in parentheses.
	// If there are no parameters, empty parentheses are still required.
	func beyondHello() {
	var x int // Variable declaration. Variables must be declared before use.
	x = 3 // Variable assignment.
	// "Short" declarations use := to infer the type, declare, and assign.
	y := 4
	sum, prod := learnMultiple(x, y) // Function returns two values.
	fmt.Println("sum:", sum, "prod:", prod) // Simple output.
	learnTypes() // < y minutes, learn more!
	}

	// Functions can have parameters and (multiple!) return values.
	func learnMultiple(x, y int) (sum, prod int) {
	return x + y, x * y // Return two values.
	}

	// Some built-in types and literals.
	func learnTypes() {
	// Short declaration usually gives you what you want.
	s := "Learn Go!" // string type.

	s2 := `A "raw" string literal
	can include line breaks.` // Same string type.

	// Non-ASCII literal. Go source is UTF-8.
	g := 'Σ' // rune type, an alias for uint32, holds a unicode code point.

	f := 3.14195 // float64, an IEEE-754 64-bit floating point number.
	c := 3 + 4i // complex128, represented internally with two float64's.

	// Var syntax with an initializers.
	var u uint = 7 // Unsigned, but implementation dependent size as with int.
	var pi float32 = 22. / 7

	// Conversion syntax with a short declaration.
	n := byte('\n') // byte is an alias for uint8.

	// Arrays have size fixed at compile time.
	var a4 [4]int // An array of 4 ints, initialized to all 0.
	a3 := [...]int{3, 1, 5} // An array of 3 ints, initialized as shown.

	// Slices have dynamic size. Arrays and slices each have advantages
	// but use cases for slices are much more common.
	s3 := []int{4, 5, 9} // Compare to a3. No ellipsis here.
	s4 := make([]int, 4) // Allocates slice of 4 ints, initialized to all 0.
	var d2 [][]float64 // Declaration only, nothing allocated here.
	bs := []byte("a slice") // Type conversion syntax.

	p, q := learnMemory() // Declares p, q to be type pointer to int.
	fmt.Println(p, q) // * follows a pointer. This prints two ints.

	// Maps are a dynamically growable associative array type, like the
	// hash or dictionary types of some other languages.
	m := map[string]int{"three": 3, "four": 4}
	m["one"] = 1

	// Unused variables are an error in Go.
	// The underbar lets you "use" a variable but discard its value.
	_, _, _, _, _, _, _, _, _ = s2, g, f, u, pi, n, a3, s4, bs
	// Output of course counts as using a variable.
	fmt.Println(s, c, a4, s3, d2, m)

	learnFlowControl() // Back in the flow.
	}

	// It is possible, unlike in many other languages for functions in go
	// to have named return values.
	// Assigning a name to the type being returned in the function declaration line
	// allows us to easily return from multiple points in a function as well as to
	// only use the return keyword, without anything further.
	func learnNamedReturns(x, y int) (z int) {
	z = x * y
	return // z is implicit here, because we named it earlier.
	}

	// Go is fully garbage collected. It has pointers but no pointer arithmetic.
	// You can make a mistake with a nil pointer, but not by incrementing a pointer.
	func learnMemory() (p, q *int) {
	// Named return values p and q have type pointer to int.
	p = new(int) // Built-in function new allocates memory.
	// The allocated int is initialized to 0, p is no longer nil.
	s := make([]int, 20) // Allocate 20 ints as a single block of memory.
	s[3] = 7 // Assign one of them.
	r := -2 // Declare another local variable.
	return &s[3], &r // & takes the address of an object.
	}

	func expensiveComputation() float64 {
	return m.Exp(10)
	}

	func learnFlowControl() {
	// If statements require brace brackets, and do not require parens.
	if true {
	fmt.Println("told ya")
	}
	// Formatting is standardized by the command line command "go fmt."
	if false {
	// Pout.
	} else {
	// Gloat.
	}
	// Use switch in preference to chained if statements.
	x := 42.0
	switch x {
	case 0:
	case 1:
	case 42:
	// Cases don't "fall through".
	case 43:
	// Unreached.
	}
	// Like if, for doesn't use parens either.
	// Variables declared in for and if are local to their scope.
	for x := 0; x < 3; x++ { // ++ is a statement.
	fmt.Println("iteration", x)
	}
	// x == 42 here.

	// For is the only loop statement in Go, but it has alternate forms.
	for { // Infinite loop.
	break // Just kidding.
	continue // Unreached.
	}
	// As with for, := in an if statement means to declare and assign
	// y first, then test y > x.
	if y := expensiveComputation(); y > x {
	x = y
	}
	// Function literals are closures.
	xBig := func() bool {
	return x > 10000 // References x declared above switch statement.
	}
	fmt.Println("xBig:", xBig()) // true (we last assigned e^10 to x).
	x = 1.3e3 // This makes x == 1300
	fmt.Println("xBig:", xBig()) // false now.

	// What's more is function literals may be defined and called inline,
	// acting as an argument to function, as long as:
	// a) function literal is called immediately (),
	// b) result type matches expected type of argument.
	fmt.Println("Add + double two numbers: ",
	func(a, b int) int {
	return (a + b) * 2
	}(10, 2)) // Called with args 10 and 2
	// => Add + double two numbers: 24

	// When you need it, you'll love it.
	goto love
	love:

	learnFunctionFactory() // func returning func is fun(3)(3)
	learnDefer() // A quick detour to an important keyword.
	learnInterfaces() // Good stuff coming up!
	}

	func learnFunctionFactory() {
	// Next two are equivalent, with second being more practical
	fmt.Println(sentenceFactory("summer")("A beautiful", "day!"))

	d := sentenceFactory("summer")
	fmt.Println(d("A beautiful", "day!"))
	fmt.Println(d("A lazy", "afternoon!"))
	}

	// Decorators are common in other languages. Same can be done in Go
	// with function literals that accept arguments.
	func sentenceFactory(mystring string) func(before, after string) string {
	return func(before, after string) string {
	return fmt.Sprintf("%s %s %s", before, mystring, after) // new string
	}
	}

	func learnDefer() (ok bool) {
	// Deferred statements are executed just before the function returns.
	defer fmt.Println("deferred statements execute in reverse (LIFO) order.")
	defer fmt.Println("\nThis line is being printed first because")
	// Defer is commonly used to close a file, so the function closing the
	// file stays close to the function opening the file.
	return true
	}

	// Define Stringer as an interface type with one method, String.
	type Stringer interface {
	String() string
	}

	// Define pair as a struct with two fields, ints named x and y.
	type pair struct {
	x, y int
	}

	// Define a method on type pair. Pair now implements Stringer.
	func (p pair) String() string { // p is called the "receiver"
	// Sprintf is another public function in package fmt.
	// Dot syntax references fields of p.
	return fmt.Sprintf("(%d, %d)", p.x, p.y)
	}

	func learnInterfaces() {
	// Brace syntax is a "struct literal." It evaluates to an initialized
	// struct. The := syntax declares and initializes p to this struct.
	p := pair{3, 4}
	fmt.Println(p.String()) // Call String method of p, of type pair.
	var i Stringer // Declare i of interface type Stringer.
	i = p // Valid because pair implements Stringer
	// Call String method of i, of type Stringer. Output same as above.
	fmt.Println(i.String())

	// Functions in the fmt package call the String method to ask an object
	// for a printable representation of itself.
	fmt.Println(p) // Output same as above. Println calls String method.
	fmt.Println(i) // Output same as above.

	learnVariadicParams("great", "learning", "here!")
	}

	// Functions can have variadic parameters.
	func learnVariadicParams(myStrings ...interface{}) {
	// Iterate each value of the variadic.
	// The underbar here is ignoring the index argument of the array.
	for _, param := range myStrings {
	fmt.Println("param:", param)
	}

	// Pass variadic value as a variadic parameter.
	fmt.Println("params:", fmt.Sprintln(myStrings...))

	learnErrorHandling()
	}

	func learnErrorHandling() {
	// ", ok" idiom used to tell if something worked or not.
	m := map[int]string{3: "three", 4: "four"}
	if x, ok := m[1]; !ok { // ok will be false because 1 is not in the map.
	fmt.Println("no one there")
	} else {
	fmt.Print(x) // x would be the value, if it were in the map.
	}
	// An error value communicates not just "ok" but more about the problem.
	if _, err := strconv.Atoi("non-int"); err != nil { // _ discards value
	// prints 'strconv.ParseInt: parsing "non-int": invalid syntax'
	fmt.Println(err)
	}
	// We'll revisit interfaces a little later. Meanwhile,
	learnConcurrency()
	}

	// c is a channel, a concurrency-safe communication object.
	func inc(i int, c chan int) {
	c <- i + 1 // <- is the "send" operator when a channel appears on the left.
	}

	// We'll use inc to increment some numbers concurrently.
	func learnConcurrency() {
	// Same make function used earlier to make a slice. Make allocates and
	// initializes slices, maps, and channels.
	c := make(chan int)
	// Start three concurrent goroutines. Numbers will be incremented
	// concurrently, perhaps in parallel if the machine is capable and
	// properly configured. All three send to the same channel.
	go inc(0, c) // go is a statement that starts a new goroutine.
	go inc(10, c)
	go inc(-805, c)
	// Read three results from the channel and print them out.
	// There is no telling in what order the results will arrive!
	fmt.Println(<-c, <-c, <-c) // channel on right, <- is "receive" operator.

	cs := make(chan string) // Another channel, this one handles strings.
	ccs := make(chan chan string) // A channel of string channels.
	go func() { c <- 84 }() // Start a new goroutine just to send a value.
	go func() { cs <- "wordy" }() // Again, for cs this time.
	// Select has syntax like a switch statement but each case involves
	// a channel operation. It selects a case at random out of the cases
	// that are ready to communicate.
	select {
	case i := <-c: // The value received can be assigned to a variable,
	fmt.Printf("it's a %T", i)
	case <-cs: // or the value received can be discarded.
	fmt.Println("it's a string")
	case <-ccs: // Empty channel, not ready for communication.
	fmt.Println("didn't happen.")
	}
	// At this point a value was taken from either c or cs. One of the two
	// goroutines started above has completed, the other will remain blocked.

	learnWebProgramming() // Go does it. You want to do it too.
	}

	// A single function from package http starts a web server.
	func learnWebProgramming() {

	// First parameter of ListenAndServe is TCP address to listen to.
	// Second parameter is an interface, specifically http.Handler.
	go func() {
	err := http.ListenAndServe(":8080", pair{})
	fmt.Println(err) // don't ignore errors
	}()

	requestServer()
	}

	// Make pair an http.Handler by implementing its only method, ServeHTTP.
	func (p pair) ServeHTTP(w http.ResponseWriter, r *http.Request) {
	// Serve data with a method of http.ResponseWriter.
	w.Write([]byte("You learned Go in Y minutes!"))
	}

	func requestServer() {
	resp, err := http.Get("http://localhost:8080")
	fmt.Println(err)
	defer resp.Body.Close()
	body, err := ioutil.ReadAll(resp.Body)
	fmt.Printf("\nWebserver said: `%s`", string(body))
	}