Go Functions

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Revision as of 18:00, 5 September 2023 by Ovidiu (talk | contribs)
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Internal

Overview

A function is a block of instructions, grouped together, and that optionally have a name.

Functions exist for code reusability reasons: the function is declared once and then can be invoked any number of times. The functions can be reused from within the project, or from other projects, if the function is declared as part of a package that is imported in the project that needs to use the function.

Function exist for abstraction reasons: they hide details into a compact "packaging" and improve the understandably of the code.

Declaration

A statical function declaration starts with the func keyword followed by the function name and a mandatory parentheses pair. Note that functions can also be created dynamically.

func <function_name>([parameters]) [(return_declaration)] {
  // body
  [return [return_values]]
}
func someFunction(color string, size int) (float64, error) {
  //
  // body
  //

  var result float64
  var err error

  // ...

  return result, err
}

Parameters

The parentheses optionally enclose function parameters. A function may not have any parameters, but in this situation, the parentheses must still be provided. The parameters, when exist, are vehicles for the input data the function needs to operate on. The parameter declaration syntax consists in a set of variables listed after the function name, between parentheses. Parameters become local variables to the function, scoped to the function body.

...(<par_name_1> <type>, <par_name_2> <type>, ...)

Example:

func blue(x int, s string) {
  ...
}

If there are multiple parameters of the same type, they can be provided as a comma separated list postfixed by the type:

func blue(x, y int, s string) {
  ...
}

Also see:

Variables, Parameters, Arguments

Return Declaration

The function output must have a type (or types), which are listed in the function declaration after the parameter list.

func ...(...) <return-type> {
 ...
}

If the function has more than one return values, their types must be enclosed in parentheses.

func ...(...) (<return-type-1>, <return-type-2>, ....) {
 ...
}

Function Body

Parameters are local variables visible inside the function body.

Go functions allow new local variables to be declared, inside the function, with the short variable declaration. The short variable declaration is not allowed anywhere else, except a function body.

The function returns its output value(s) with the return keyword:

{
   ...
  return someVar
}

More than one values can be returned at the same time, and such a function can be used with the multi-value short variable declaration form.

{
  ...
  return someVar1, someVar2
}

Invocation

All functions, except main() must be invoked explicitly from the program to execute.

A function is invoked, or called, by specifying the function name, mandatory followed by open parentheses, optionally followed by arguments, if the function has parameters, then mandatory followed by closing parenthesis.

result, err := someFunction("blue", 3)

Arguments

The arguments consist of the data supplied to the function as part of the invocation.

Pass by Value vs. Pass by Reference vs. Pass by Pointer

"Call by value vs. call by reference" describes how arguments are passed to parameters during a function call. When the function is invoked, arguments are passed to the function and the values of those arguments are bound to the function's parameters.

In Go, arguments are always passed by value. Arguments are copied to parameters, on the function's call stack. The data that function uses is a copy of the original. This approach promotes encapsulation: the function cannot modify the original data. The called function cannot changed the variables inside the calling function. The approach also comes at the cost of the argument copy time, which for large pieces of data, can be non-trivial. Arrays are also passed by value, their data is always copied, and for large arrays this can be a problem. This is the reason array should not be used directly, but slices should be used instead.

The alternative to pass by value is pass by reference (or by pointer). Go does not have a built-in pass by reference mechanism, but pass by pointer can be manually implemented, by passing the pointer to a variable to a function.

func passByPointerExample(i *int) {
   *i = *i + 1
}

func callerFunction() {
   x := 2
   passByPointerExample(&x)
   fmt.Println(x) // will print 3
}

main()

All programs in Go must have a main() function, where the program execution starts. The main() function must be declared in the main package.

You never call this function. When a program is executed, the main() gets called automatically.

Variadic Functions

Variadic function are functions with a variable number of arguments. It is syntactically specified in the function definition using an elipsis ... that precedes the type. Inside the function, the parameter is treated like a slice.

func SomeVariadicFunc(s string, i ...int) {
  ...
  for _, v := range i {
     ...
  }
}

When invoked, such a variadic function can get a list of arguments, separated by commas:

SomeVariadicFunc("blue", 3, 5, 7, 11, 13, 17)

An equivalent invocation uses a slice and the ellipsis ... to allow using the slice as argument:

si := []int{3, 5, 7, 11, 13, 17}
SomeVariadicFunc("blue", si...)

Deferred Function Calls

Go syntax allows specifying that a function invocation should be deferred after the function that invokes it finishes executing. This behavior is achieved using the defer keyword. This mechanism is usually used to clean things up after the enclosing function completes, close files, etc.

It is important to remember is that the deferred function arguments will be evaluated when the defer statement is executed, NOT when the deferred function is executed.

The following example prints:

EnclosingFunction 30
DeferredFunction 20

The example prints "EnclosingFunction 11" first because even if fmt.Println("EnclosingFunction", i) statement is executed last in EnclosingFunction(), DeferredFunction() is executed after EnclosingFunction() completes.

The example prints "DeferredFunction 20" last because first because DeferredFunction() is executed after EnclosingFunction() completes. However the integer value is the result of the argument evaluation at the time the defer statement is executed (10 + 10), and not at the time DeferredFunction() is executed, when it should have been 10 + 20 + 10 = 40.

func EnclosingFunction() {
  i := 10
  defer DeferredFunction(i + 10)
  i += 20
  fmt.Println("EnclosingFunction", i)
}

func DeferredFunction(i int) {
  fmt.Println("DeferredFunction", i)
}

func main() {
  EnclosingFunction()
}

Built-in Functions

Built-in functions are available by default, without importing any package. Their names are predeclared function identifiers. They give access to Go's internal data structures. Their semantics depends on the arguments.

append() cap() close() complex() copy()
delete() imag() len() make() new()
panic() print() println() real() recover()

Length and Capacity

https://golang.org/ref/spec#Length_and_capacity

len()

len() returns string length, array length, slice length and map size.

cap()

cap() returns slice capacity.

Complex Number Manipulation

complex() real() imag()

make()

https://golang.org/ref/spec#Making_slices_maps_and_channels

make(() is a built-in function that can be used to initialize slices, maps and channels.

TO DO: Continue to Distribute These Built-in Functions

Allocation: new()

Appending to and copying slices: append(), copy()

Deletion of map elements delete()

Handling panics panic(), recover()

Functions as First-Class Values

Go implements features of a functional programming style. Function are treated as first-class value, which means functions are treated like any other type. Variables can be declared to be of a function type. Function instances can be created dynamically at runtime, as opposite to declaring them statically in the program with the func keyword. Functions can be passed as arguments into a function invocation and they can be returned as values of a function invocation. Functions can be stored into a data structure.

Declaring a Function Variable

The variable name acts as an alias, another name for the function.

var <var_name> <func_type>

A function type is declared using the following syntax:

func(<parameter_1_type, parameter_2_type, ...) (return_1_type, return_2_type, ...)

Example:

func SomeFunction(s string, i int) (int, error) {
  ...
}

...

var f func(string, int) (int, error)
f = SomeFunction
f("10", 20)

Passing a Function as Argument into a Function

func <func_name>(<func_var> <func_type_declaration>, ...) ... {
  ...
}

Example:

func Invoker(f func(string) int, s string) int {
  result := f(s)
  return result
}

func SomeFunction(s string) int {
  i, _ := strconv.Atoi(s)
  return i
}

...

result := Invoker(SomeFunction, "10") 
...

Anonymous Functions (Lambdas)

These are lambdas.

In the example for Passing a Function as Argument into a Function, we can simply create the function passed as argument on the fly, without giving it a name:

result := Invoker(func(s string) int {
  i, _ := strconv.Atoi(s)
  return i
}, "10")

Returning Function as Result of Function Invocations

func FunctionMaker() func(int) int {
  // we are creating an anonymous function
  f := func(i int) int {
      return i + 1
  }
  return f
}

Environment of a Function

The concept of environment of a function is important for understanding closures.

The environment of a function is the set of all names that are accessible from inside the function. Variables are a subset of those names. Given that Go is lexically scoped, the environment of a function includes the names defined locally in the function's own block and the enclosing blocks. A variable's scope is a somewhat similar concept, and scope and environment are some times used interchangeably when it comes to functions, but they are technically not the same. Functions have environments, variables have scope.

Closures

A closure is a function and its environment, which, as described in the Environment of a Function section, includes all the names declared within the function and all its enclosing blocks.

When a function is passed as an argument, the environment goes along with the function. When the function passed as argument is executed, the function has access to its original environment.

In the following example, we show that passing a function of an argument it passes the closure of the function: the function and its environment. The anonymous function that is passed as argument has access to its own localVar local variable, the functionMakerVar, declared in the block that also defines the anonymous function, and the package-level packageLevelVar. When the anonymous function is invoked from within FunctionInvoker(), whose environment does not have access to functionMakerVar variable, the anonymous function still has access to all the variables it had access to while declared, and returns 10 (the argument) + 20 (localVar in the anonymous function) + 30 (functionMakerVar variable in the FunctionMaker() block) + 40 (packageLevelVar) = 100:

...

var packageLevelVar int = 40

func FunctionMaker() func(int) int {
  functionMakerVar := 30
  f := func(i int) int {
    localVar := 20
    return i + localVar + functionMakerVar + packageLevelVar
  }
  return f
}

func FunctionInvoker(f func(int) int, arg int) int {
  return f(arg)
}

func main() {
  f := FunctionMaker()
  r := FunctionInvoker(f, 10)
  fmt.Println(r) // will print 100
}

Elements of Style

Strive to write your functions so it enhances the understandability of your code. A code is understandable if, when you are in the position to find a feature, you can find it quickly. In general, you should be able to answer fast to question of type "Where is the code that does something?"

Avoid global variables. Without global variables, data is local to function.

Name functions and variables meaningfully. You don't want the names to be too long. "If you want to work with people, naming is really important".

Limit the number of parameters. A large number of parameter is a symptom of bad functional cohesion.

Functional cohesion: a function should perform only one operation.

Functional complexity: don't make function too complex: lines of code, control-flow complexity.

To reduce control-flow complexity, separate conditionals in different functions.

Methods and Support for Object Orientation

Object Oriented Programming in Go | Methods

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Built-in functions for type conversions.


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