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I know that pointers in Go allow mutation of a function's arguments, but wouldn't it have been simpler if they adopted just references (with appropriate const or mutable qualifiers). Now we have pointers and for some built-in types like maps and channels implicit pass by reference.

Am I missing something or are pointers in Go just an unnecessary complication?

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Here's a question that may help clarify: stackoverflow.com/questions/795160/… There is a difference between passing references by value and passing truly by reference. –  R. Martinho Fernandes Dec 7 '09 at 22:59
Note: the question is about Java, but it applies here as well. –  R. Martinho Fernandes Dec 7 '09 at 23:00
"and for some built-in types like maps and channels implicit pass by reference." No, everything is pass-by-value in Go. Some types are (informally described as) reference types, since they have internal mutable state. –  newacct Dec 29 '12 at 2:47

5 Answers 5

References cannot be reassigned, while pointers can. This alone makes pointers useful in many situations where references could not be used.

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Go is designed to be a terse, minimalist language. It therefore started with just values and pointers. Later, by necessity, some reference types (slices, maps, and channels) were added.

The Go Programming Language : Language Design FAQ : Why are maps, slices, and channels references while arrays are values?

"There's a lot of history on that topic. Early on, maps and channels were syntactically pointers and it was impossible to declare or use a non-pointer instance. Also, we struggled with how arrays should work. Eventually we decided that the strict separation of pointers and values made the language harder to use. Introducing reference types, including slices to handle the reference form of arrays, resolved these issues. Reference types add some regrettable complexity to the language but they have a large effect on usability: Go became a more productive, comfortable language when they were introduced."

Fast compilation is a major design goal of the Go programming language; that has its costs. One of the casualties appears to be the ability to mark variables (except for basic compile time constants) and parameters as immutable. It's been requested, but turned down.

golang-nuts : go language. Some feedback and doubts.

"Adding const to the type system forces it to appear everywhere, and forces one to remove it everywhere if something changes. While there may be some benefit to marking objects immutable in some way, we don't think a const type qualifier is to way to go."

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FWIW, "reference types" in Go are also reassignable. They're more like implicit pointers? –  Matt Joiner May 24 '12 at 13:11
They are just special syntax for structs that contain a pointer (and length, capacity, ...). –  Mk12 Jul 15 '13 at 16:32

I really like example taken from http://www.golang-book.com/8

func zero(x int) {
    x = 0
func main() {
    x := 5
    fmt.Println(x) // x is still 5

as contrasted with

func zero(xPtr *int) {
    *xPtr = 0
func main() {
    x := 5
    fmt.Println(x) // x is 0
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Pointers are usefull for several reasons. Pointers allow control over memory layout (affects efficiency of CPU cache). In Go we can define a structure where all the members are in contiguous memory:

type Point struct {
  x, y int

type LineSegment struct {
  source, destination Point

In this case the Point structures are embedded within the LineSegment struct. But you can't always embed data directly. If you want to support structures such as binary trees or linked list, then you need to support some kind of pointer.

type TreeNode {
  value int
  left  *TreeNode
  right *TreeNode

Java, Python etc doesn't have this problem because it does not allow you to embed composite types, so there is no need to syntactically differentiate between embedding and pointing.

Issues with C# structs solved with Go pointers

A possible alternative to accomplish the same is to differentiate between struct and class as C# does. But that isn't without problems either. Because it forces you do always use value semantics even when that doesn't make sense.

E.g. say I have a contiguous array of 4x4 matricies used to represent nodes in a scene graph or something simular. I could to that in C#, but I couldn't switch between accessing it as value or pointer. If it was an array of points I would not want to use a pointer. E.g:

// In this case we want to copy points on computation
var points [1024]Point
var q Point = calcSomePoint()

for p in range points {
   result := dotProduct(p, q)

// We don't want to copy matricies each time we perform a computation because
// they are big, but we want them in contiguous memory
var matricies [1024]Matrix4x4
var n Matrix4x4 = caclSomeMatrix()

for m in range matricies {
   multiply(&n, &m)     // Avoid copying 2*4*4*8 = 256 bytes on each computation

So in C# you are always forced to send struct around by copying them. This can easily kill performance in a C# application which is why MS recommends structs no larger than 16 bytes. With Go, since it supports pointers you can chose exactly when you want to pass your structs around using pointers and when you want to copy them. This makes it easier for Go to work with large structs without killing performance.

Custom Memory Allocator

Using pointers you can also create your own pool allocator (this is very simplified with lots of checks removed to just show the principle):

type TreeNode {
  value int
  left  *TreeNode
  right *TreeNode

  nextFreeNode *TreeNode; // For memory allocation

var pool [1024]TreeNode
var firstFreeNode *TreeNode = &pool[0] 

func poolAlloc() *TreeNode {
    node := firstFreeNode
    firstFreeNode  = firstFreeNode.nextFreeNode
    return node

func freeNode(node *TreeNode) {
    node.nextFreeNode = firstFreeNode
    firstFreeNode = node

Swap two values

Pointers also allows you to implement swap. That is swapping the values of two variables:

func swap(a *int, b *int) {
   temp := *a
   *a = *b
   *b = temp


Java has never been able to fully replace C++ for systems programming at places such as Google, in part because performance can not be tuned to the same extend due to the lack of ability to control memory layout and usage (cache misses affect performance significantly). Go has aimed to replace C++ in many areas and thus needs to support pointers.

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"References cannot be reassigned, while pointers can. [...]" zildjohn01

Why not? Java example:

    String s = "foo";
    s = "bar";
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String s = "foo"; String p = s; s = "bar"; // p is still foo. –  Nick Johnson Dec 8 '09 at 15:55
Right, and you want to be able to do this instead? char* v = "foo"; char** s = &v; char** p = s; *s = "bar"; // *p == "bar" This is easy to simulate with references if your reference refers to a mutable thing, e.g. in Java: AtomicReference<String> ref1 = new AtomicReference<String>("foo"); AtomicReference<String> ref2 = ref1; ref1.set("bar"); assert "bar".equals(ref2.get()); So I still fail to see what pointers would offer you in Go. –  45g Dec 8 '09 at 16:45
references in go are not the same as references in Java. Java references are more like C++ pointers without the pointer arithmetics. –  hasenj Dec 21 '09 at 11:02
"references in go are not the same as references in Java." Well, the references they are proposing to don't exist in Go, so they are not "the same" or "not the same" as anything else. Almost certainly the "reference" they are proposing is equivalent to the "C++ reference", or "pass-by-reference", not the "reference" in Java, Python, etc. –  newacct Dec 29 '12 at 2:45

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