Is there a way to iterate over a range of integers?

Go's range can iterate over maps and slices, but I was wondering if there is a way to iterate over a range of numbers, something like this:

``````for i := range [1..10] {
fmt.Println(i)
}
``````

Or is there a way to represent range of integers in Go like how Ruby does with the class Range?

From Go 1.22 (expected release February 2024), you will be able to write:

``````for i := range 10 {
fmt.Println(i+1)
}
``````

(ranging over an integer in Go iterates from 0 to one less than that integer).

For versions of Go before 1.22, the idiomatic approach is to write a for loop like this.

``````for i := 1; i <= 10; i++ {
fmt.Println(i)
}
``````
• I don't think most people would call this three-expression version more simple than what @Vishnu wrote. Only perhaps after years and years of C or Java indoctrination ;-) Commented Jun 28, 2014 at 21:06
• IMO the point is that you are always going to have this three-expression version of the for loop (i.e. you can do a lot more with it, the syntax from the OP is only good for that more restricted case of a number range, so in any language you're going to want this extended version) and it sufficiently accomplishes the same task, and isn't remarkably different anyway, so why have to learn/remember another syntax. If you are coding on a large and complex project you have enough to worry about already without having to fight the compiler about various syntaxes for something as simple as a loop. Commented Apr 5, 2015 at 19:43
• @ThomasAhle especially considering C++ is officially adding notation for_each(x,y) inspired by the boost template library Commented Feb 8, 2017 at 2:02
• @BradPeabody this is actually a matter of preference. Python does not have the 3-expression loop and works fine. Many consider the for-each syntax a lot less error-prone and there is nothing intrinsically inefficient about it. Commented Jun 17, 2017 at 3:17
• @PaulHankin That entirely depends upon whether you view coding as a science or as a religion. Rob is unfortunately mistaken and then defensively power-tripping here, and you are blindly channeling his hand-it-down. For your own engineering benefit, don't dismiss that changing the value of `i` within Rob's loop causes it to self-destruct, whereas the range approach is immune. And, "DRY" is a universally accepted language-design principle, and you can see `i` 3 times in Rob's loop! Anyway, now look at me repeating myself. I'd treat each upvote of the first comment as a polite downvote. Commented Jan 18, 2018 at 23:21

It was suggested by Mark Mishyn to use slice but there is no reason to create array with `make` and use in `for` returned slice of it when array created via literal can be used and it's shorter

``````for i := range [5]int{} {
fmt.Println(i)
}
``````
• If you're not going to use the variable you can also omit the left side and use `for range [5]int{} {` Commented May 4, 2018 at 3:07
• Drawback is that `5` here is a literal and cannot be determined at run-time. Commented Jul 25, 2018 at 14:44
• Is it faster or comparable to normal three expressions for loop? Commented Jul 29, 2018 at 18:56
• @AmitTripathi yes, it's comparable, execution time is almost the same for billions of iterations. Commented Mar 27, 2019 at 15:58
• Looks nice, but does that use `O(n)` memory though?
– Ian
Commented Nov 30, 2022 at 22:24

Here is a program to compare the two ways suggested so far

``````import (
"fmt"

)

func p(i int) {
fmt.Println(i)
}

func plain() {
for i := 0; i < 10; i++ {
p(i)
}
}

func with_iter() {
for i := range iter.N(10) {
p(i)
}
}

func main() {
plain()
with_iter()
}
``````

Compile like this to generate disassembly

``````go build -gcflags -S iter.go
``````

Here is plain (I've removed the non instructions from the listing)

setup

``````0035 (/home/ncw/Go/iter.go:14) MOVQ    \$0,AX
0036 (/home/ncw/Go/iter.go:14) JMP     ,38
``````

loop

``````0037 (/home/ncw/Go/iter.go:14) INCQ    ,AX
0038 (/home/ncw/Go/iter.go:14) CMPQ    AX,\$10
0039 (/home/ncw/Go/iter.go:14) JGE     \$0,45
0040 (/home/ncw/Go/iter.go:15) MOVQ    AX,i+-8(SP)
0041 (/home/ncw/Go/iter.go:15) MOVQ    AX,(SP)
0042 (/home/ncw/Go/iter.go:15) CALL    ,p+0(SB)
0043 (/home/ncw/Go/iter.go:15) MOVQ    i+-8(SP),AX
0044 (/home/ncw/Go/iter.go:14) JMP     ,37
0045 (/home/ncw/Go/iter.go:17) RET     ,
``````

And here is with_iter

setup

``````0052 (/home/ncw/Go/iter.go:20) MOVQ    \$10,AX
0053 (/home/ncw/Go/iter.go:20) MOVQ    \$0,~r0+-24(SP)
0054 (/home/ncw/Go/iter.go:20) MOVQ    \$0,~r0+-16(SP)
0055 (/home/ncw/Go/iter.go:20) MOVQ    \$0,~r0+-8(SP)
0056 (/home/ncw/Go/iter.go:20) MOVQ    \$type.[]struct {}+0(SB),(SP)
0057 (/home/ncw/Go/iter.go:20) MOVQ    AX,8(SP)
0058 (/home/ncw/Go/iter.go:20) MOVQ    AX,16(SP)
0059 (/home/ncw/Go/iter.go:20) PCDATA  \$0,\$48
0060 (/home/ncw/Go/iter.go:20) CALL    ,runtime.makeslice+0(SB)
0061 (/home/ncw/Go/iter.go:20) PCDATA  \$0,\$-1
0062 (/home/ncw/Go/iter.go:20) MOVQ    24(SP),DX
0063 (/home/ncw/Go/iter.go:20) MOVQ    32(SP),CX
0064 (/home/ncw/Go/iter.go:20) MOVQ    40(SP),AX
0065 (/home/ncw/Go/iter.go:20) MOVQ    DX,~r0+-24(SP)
0066 (/home/ncw/Go/iter.go:20) MOVQ    CX,~r0+-16(SP)
0067 (/home/ncw/Go/iter.go:20) MOVQ    AX,~r0+-8(SP)
0068 (/home/ncw/Go/iter.go:20) MOVQ    \$0,AX
0069 (/home/ncw/Go/iter.go:20) LEAQ    ~r0+-24(SP),BX
0070 (/home/ncw/Go/iter.go:20) MOVQ    8(BX),BP
0071 (/home/ncw/Go/iter.go:20) MOVQ    BP,autotmp_0006+-32(SP)
0072 (/home/ncw/Go/iter.go:20) JMP     ,74
``````

loop

``````0073 (/home/ncw/Go/iter.go:20) INCQ    ,AX
0074 (/home/ncw/Go/iter.go:20) MOVQ    autotmp_0006+-32(SP),BP
0075 (/home/ncw/Go/iter.go:20) CMPQ    AX,BP
0076 (/home/ncw/Go/iter.go:20) JGE     \$0,82
0077 (/home/ncw/Go/iter.go:20) MOVQ    AX,autotmp_0005+-40(SP)
0078 (/home/ncw/Go/iter.go:21) MOVQ    AX,(SP)
0079 (/home/ncw/Go/iter.go:21) CALL    ,p+0(SB)
0080 (/home/ncw/Go/iter.go:21) MOVQ    autotmp_0005+-40(SP),AX
0081 (/home/ncw/Go/iter.go:20) JMP     ,73
0082 (/home/ncw/Go/iter.go:23) RET     ,
``````

So you can see that the iter solution is considerably more expensive even though it is fully inlined in the setup phase. In the loop phase there is an extra instruction in the loop, but it isn't too bad.

I'd use the simple for loop.

• I can't "see that the iter solution is considerably more expensive." Your method of counting Go pseudo-assembler instructions is flawed. Run a benchmark. Commented Feb 22, 2014 at 18:27
• One solution calls `runtime.makeslice` and the other doesn't - I don't need a benchmark to know that is going to be a lot slower! Commented Feb 22, 2014 at 18:45
• Yes `runtime.makeslice` is clever enough not to allocate any memory if you ask for zero size allocation. However the above still calls it, and according to your benchmark does take 10nS longer on my machine. Commented Feb 23, 2014 at 10:48
• this reminds of people suggesting to use C over C++ for performance reasons Commented Jan 18, 2018 at 10:50
• Debating the runtime performance of nanosecond CPU operations, while common in Goland, seems silly to me. I'd consider that a very distant last consideration, after readability. Even if CPU performance were relevant, the contents of the for loop will almost always swamp whatever differences incurred by the loop itself. Commented Jan 30, 2019 at 19:50

iter is a very small package that just provides a syntantically different way to iterate over integers.

``````for i := range iter.N(4) {
fmt.Println(i)
}
``````

Rob Pike (an author of Go) has criticized it:

It seems that almost every time someone comes up with a way to avoid doing something like a for loop the idiomatic way, because it feels too long or cumbersome, the result is almost always more keystrokes than the thing that is supposedly shorter. [...] That's leaving aside all the crazy overhead these "improvements" bring.

• Pike's critique is simplistic in that it only addresses the keystrokes rather than the mental overhead of constantly redeclaring ranges. Also, with most modern editors, the `iter` version actually uses fewer keystrokes because `range` and `iter` will autocomplete. Commented Apr 3, 2017 at 19:04
• @lang2, `for` loops are not a first class citizen of Unix like they are in go. Besides, unlike `for`, `seq` streams to standard output a sequence of numbers. Whether or not to iterate over them is up to the consumer. Though `for i in \$(seq 1 10); do ... done ` is common in Shell, it's only one way to do a for loop, which is itself only one way to consume the output of `seq`, albeit a very common one. Commented Nov 13, 2017 at 23:13
• Also, Pike simply doesn't consider the fact that a compile (given the language specs included a range syntax for this use case) could be build in a way to just treat `i in range(10)` exactly like `i := 0; i < 10; i++`. Commented Sep 13, 2019 at 20:22
• FYI: “This package [the ‘iter’ package] was intended to be an educational joke when it was released in 2014. People didn’t get the joke part and started depending on it. That’s fine, I guess. (This is the Internet.) But it’s kinda weird. It’s one line, and not even idiomatic Go style.” Commented Sep 6, 2021 at 18:05

Here's a benchmark to compare a Go `for` statement with a ForClause and a Go `range` statement using the `iter` package.

`iter_test.go`

``````package main

import (
"testing"

)

const loops = 1e6

func BenchmarkForClause(b *testing.B) {
b.ReportAllocs()
j := 0
for i := 0; i < b.N; i++ {
for j = 0; j < loops; j++ {
j = j
}
}
_ = j
}

func BenchmarkRangeIter(b *testing.B) {
b.ReportAllocs()
j := 0
for i := 0; i < b.N; i++ {
for j = range iter.N(loops) {
j = j
}
}
_ = j
}

// It does not cause any allocations.
func N(n int) []struct{} {
return make([]struct{}, n)
}

func BenchmarkIterAllocs(b *testing.B) {
b.ReportAllocs()
var n []struct{}
for i := 0; i < b.N; i++ {
n = iter.N(loops)
}
_ = n
}
``````

Output:

``````\$ go test -bench=. -run=.
testing: warning: no tests to run
PASS
BenchmarkForClause      2000       1260356 ns/op           0 B/op          0 allocs/op
BenchmarkRangeIter      2000       1257312 ns/op           0 B/op          0 allocs/op
BenchmarkIterAllocs 20000000            82.2 ns/op         0 B/op          0 allocs/op
ok      so/test 7.026s
\$
``````
• If you set loops to 10 then retry the benchmark you'll see a marked difference. On my machine the ForClause takes 5.6 ns whereas the Iter takes 15.4 ns, so calling the allocator (even though it is clever enough not to allocate anything) still costs 10ns and a whole heap of extra I-cache busting code. Commented Feb 23, 2014 at 10:46
• I would be interested to see your benchmarks and critiques for the package I created and referenced in my answer. Commented Apr 3, 2017 at 18:58

If you want to just iterate over a range w/o using and indices or anything else, this code sample worked just fine for me. No extra declaration needed, no `_`. Haven't checked the performance, though.

``````for range [N]int{} {
// Body...
}
``````

P.S. The very first day in GoLang. Please, do critique if it's a wrong approach.

• N must be constant: for range [5]int{} {} Commented Aug 30, 2021 at 1:16

While I commiserate with your concern about lacking this language feature, you're probably just going to want to use a normal `for` loop. And you'll probably be more okay with that than you think as you write more Go code.

I wrote this iter package — which is backed by a simple, idiomatic `for` loop that returns values over a `chan int` — in an attempt to improve on the design found in https://github.com/bradfitz/iter, which has been pointed out to have caching and performance issues, as well as a clever, but strange and unintuitive implementation. My own version operates the same way:

``````package main

import (
"fmt"
"github.com/drgrib/iter"
)

func main() {
for i := range iter.N(10) {
fmt.Println(i)
}
}
``````

However, benchmarking revealed that the use of a channel was a very expensive option. The comparison of the 3 methods, which can be run from `iter_test.go` in my package using

``````go test -bench=. -run=.
``````

quantifies just how poor its performance is

``````BenchmarkForMany-4                   5000       329956 ns/op           0 B/op          0 allocs/op
BenchmarkDrgribIterMany-4               5    229904527 ns/op         195 B/op          1 allocs/op
BenchmarkBradfitzIterMany-4          5000       337952 ns/op           0 B/op          0 allocs/op

BenchmarkFor10-4                500000000         3.27 ns/op           0 B/op          0 allocs/op
BenchmarkDrgribIter10-4            500000      2907 ns/op             96 B/op          1 allocs/op
BenchmarkBradfitzIter10-4       100000000        12.1 ns/op            0 B/op          0 allocs/op
``````

In the process, this benchmark also shows how the `bradfitz` solution underperforms in comparison to the built-in `for` clause for a loop size of `10`.

In short, there appears to be no way discovered so far to duplicate the performance of the built-in `for` clause while providing a simple syntax for `[0,n)` like the one found in Python and Ruby.

Which is a shame because it would probably be easy for the Go team to add a simple rule to the compiler to change a line like

``````for i := range 10 {
fmt.Println(i)
}
``````

to the same machine code as `for i := 0; i < 10; i++`.

However, to be fair, after writing my own `iter.N` (but before benchmarking it), I went back through a recently written program to see all the places I could use it. There actually weren't many. There was only one spot, in a non-vital section of my code, where I could get by without the more complete, default `for` clause.

So while it may look like this is a huge disappointment for the language in principle, you may find — like I did — that you actually don't really need it in practice. Like Rob Pike is known to say for generics, you might not actually miss this feature as much as you think you will.

Go 1.22

Starting from 1.22 (February 2024) you will be able to rewrite for loops from zero to N by simply ranging over an integer. Therefore:

``````for i := 0; i < 5; i++ {
fmt.Println(i)
}
``````

Becomes:

``````for i := range 5 {
fmt.Println(i)
}
``````

You can now find it mentioned in the language specification within the For-range section:

The expression on the right in the "range" clause is called the range expression, its core type must be [one of the usual cases], or an integer.

And:

For an integer value `n`, the iteration values 0 through n-1 are produced in increasing order, with the same type as `n`. If n <= 0, the loop does not run any iterations.

Note that ranging over an integer allows only one iteration variable. Clearly the idiom `i, v := range` isn't necessary here.

This new language feature covers only ranges in the form [0,N) — i.e. from zero to N excluded. For everything else you must still write the full three-clause loop.

I have written a package in Golang which mimic the Python's range function:

``````package main

import (
"fmt"

)

func main() {
// sequence: 0-9
for v := range iter.N(10) {
fmt.Printf("%d ", v)
}
fmt.Println()
// output: 0 1 2 3 4 5 6 7 8 9

// sequence: 5-9
for v := range iter.N(5, 10) {
fmt.Printf("%d ", v)
}
fmt.Println()
// output: 5 6 7 8 9

// sequence: 1-9, increment by 2
for v := range iter.N(5, 10, 2) {
fmt.Printf("%d ", v)
}
fmt.Println()
// output: 5 7 9

// sequence: a-e
for v := range iter.L('a', 'e') {
fmt.Printf("%s ", string(v))
}
fmt.Println()
// output: a b c d e
}

``````

Note: I have written for fun! Btw, sometimes it may be helpful

Here is a compact, dynamic version that doesn't depend on `iter` (but works similarly):

``````package main

import (
"fmt"
)

// N is an alias for an unallocated struct
func N(size int) []struct{} {
return make([]struct{}, size)
}

func main() {
size := 1000
for i := range N(size) {
fmt.Println(i)
}
}

``````

With some tweaks `size` could be of type `uint64` (if needed) but that's the gist.

``````for i := range 10 {
fmt.Println(i)
}
``````

this case also is Valid ( when you do not need counter variable(index))

``````for range 10 {
doSomething()
}
``````

You can also check out github.com/wushilin/stream

It is a lazy stream like concept of java.util.stream.

``````// It doesn't really allocate the 10 elements.
stream1 := stream.Range(0, 10)

// Print each element.
stream1.Each(print)

// Add 3 to each element, but it is a lazy add.
// You only add when consume the stream
stream2 := stream1.Map(func(i int) int {
return i + 3
})

// Well, this consumes the stream => return sum of stream2.
stream2.Reduce(func(i, j int) int {
return i + j
})

// Create stream with 5 elements
stream3 := stream.Of(1, 2, 3, 4, 5)

// Create stream from array
stream4 := stream.FromArray(arrayInput)

// Filter stream3, keep only elements that is bigger than 2,
// and return the Sum, which is 12
stream3.Filter(func(i int) bool {
return i > 2
}).Sum()
``````

Hope this helps

The problem is not the range, the problem is how the end of slice is calculated. with a fixed number `10` the simple `for` loop is ok but with a calculated `size` like `bfl.Size()` you get a function-call on every iteration. A simple `range` over `int32` would help because this evaluate the `bfl.Size()` only once.

``````type BFLT PerfServer
func (this *BFLT) Call() {
bfl := MqBufferLCreateTLS(0)
}
this.SendSTART()
// size := bfl.Size()
for i := int32(0); i < bfl.Size() /* size */; i++ {
this.SendU(bfl.IndexGet(i))
}
this.SendRETURN()
}
``````

As answered by others, this is currently not supported in the language. Idiomatic way of Go is to use a for loop.

However, there is a recent proposal by RSC that extends the range to iterate over integers.

If n is an integer type, then `for x := range n { ... }` would be completely equivalent to for `x := T(0); x < n; x++ { ... }`, where T is the type of n (assuming x is not modified in the loop body).

I'm optimistic that this proposal will make it into the language.

``````package main

import "fmt"

func main() {

nums := []int{2, 3, 4}
for _, num := range nums {
fmt.Println(num, sum)
}
}
``````
• Add some context to your code to help future readers better understand its meaning. Commented Jul 26, 2018 at 3:15
• what is this? sum is not defined. Commented Nov 6, 2018 at 18:12