# Go Tour Exercise: Equivalent Binary Trees

I am trying to solve equivalent binary trees exercise on go tour. Here is what I did;

``````package main

import "tour/tree"
import "fmt"

// Walk walks the tree t sending all values
// from the tree to the channel ch.
func WalkRecurse(t *tree.Tree, ch chan int) {
if t.Left != nil {
Walk(t.Left, ch)
}
ch <- t.Value
if t.Right != nil {
Walk(t.Right,ch)
}

}

func Walk(t *tree.Tree, ch chan int) {
WalkRecurse(t, ch)
close(ch)
}

// Same determines whether the trees
// t1 and t2 contain the same values.
func Same(t1, t2 *tree.Tree) bool {
ch1 := make(chan int)
ch2 := make(chan int)
go Walk(t1, ch1)
go Walk(t2, ch2)
for k := range ch1{
select {
case g := <-ch2:
if k != g {
return false
}
default:
break
}
}
return true
}

func main() {
fmt.Println(Same(tree.New(1), tree.New(1)))
fmt.Println(Same(tree.New(1), tree.New(2)))
}
``````

However, I couldn't find out how to signal if any no more elements left in trees. I can't use `close(ch)` on `Walk()` because it makes the channel close before all values are sent (because of recursion.) Can anyone lend me a hand here?

-
I've read that like six times and still don't understand. Why do you need to signal that there are no more elements left in the tree? – FrankieTheKneeMan Sep 1 '12 at 0:57
@FrankieTheKneeMan To break out the infinite for loop. Currently, for loop only finishes if any of the elements are different. – yasar Sep 1 '12 at 0:59
Right, because it hangs on a channel. – FrankieTheKneeMan Sep 1 '12 at 1:01
@FrankieTheKneeMan Yes, how do I make so that it won't hang on channel? – yasar Sep 1 '12 at 1:03
@yasar11732 You just need to remove the `default` case, have a look at my proposed solution here (Also, I use a Walk function similar to the one presented here) – tokou Jul 27 '13 at 9:45

You could use close() if your Walk function doesn't recurse on itself. i.e. Walk would just do:

``````func Walk(t *tree.Tree, ch chan int) {
walkRecurse(t, ch)
close(ch)
}
``````

Where walkRecurseis more or less your current Walk function, but recursing on walkRecurse. (or you rewrite Walk to be iterative - which, granted, is more hazzle) With this approach, your Same() function have to learn that the channels was closed, which is done with the channel receive of the form

``````k,ok1 := <-ch
g,ok2 := <-ch
``````

And take proper action when `ok1` and `ok2` are different, or when they're both `false`

Another way, but probably not in the spirit of the exercise, is to count the number of nodes in the tree:

``````func Same(t1, t2 *tree.Tree) bool {
countT1 := countTreeNodes(t1)
countT2 := countTreeNodes(t2)
if countT1!= countT2 {
return false
}
ch1:=make(chan int)
ch2:=make(chan int)
go Walk(t1, ch1)
go Walk(t2, ch2)
for i:=0; i<countT1; i++ {
if <-ch1 != <-ch2 {
return false
}
}

return true
}
``````

You'l have to implement the countTreeNodes()function, which should count the number of nodes in a *Tree

-
I have updated code in my question. I am getting `panic: runtime error: send on closed channel` – yasar Sep 1 '12 at 1:18
@yasar11732 Your WalkRecurse body have to call WalkRecurse, not Walk – nos Sep 1 '12 at 1:19
I don't think that counting the number of nodes is the best solution. You'd need to have two passes on each tree. You can see my proposed one-pass-solution here – tokou Jul 27 '13 at 9:43

An elegant solution using closure was presented in the golang-nuts group,

``````func Walk(t *tree.Tree, ch chan int) {
defer close(ch)  // <- closes the channel when this function returns
var walk func(t *tree.Tree)
walk = func(t *tree.Tree) {
if t == nil { return }
walk(t.Left)
ch <- t.Value
walk(t.Right)
}
walk(t)
}
``````
-
nice one, upvote :) – Nemoden Dec 9 '14 at 15:56
Can anyone explain why only an in-order traversal (as opposed to pre and post-order) works here? – Michael Aug 27 at 19:53
It's implicit in the problem definition that you're comparing whether two binary search trees contain the same multiset of elements, and while an in-order of a BST will give you the elements in sorted order, the same is not true of any other traversal. E.g. the tree ¹\₂ has preorder 12 while the tree ₁/² has preorder 21, despite that both contain the same elements. – daveagp Sep 11 at 21:57
Also this is maybe just me being grumpy, but I don't know if this is much more elegant than having a second recursive helper function, but I applaud the idiomatic use of defer. – daveagp Sep 11 at 21:58
Nice answer, but why "defer close(ch)", why not simply write close(ch) as the last statement of the function? That seems to work fine as well. – marczoid Nov 12 at 13:03

This is my solution. It properly checks for differences in the length of the two sequences.

``````package main

import "fmt"

func Walk(t *tree.Tree, ch chan int) {
var walker func (t *tree.Tree)
walker = func (t *tree.Tree) {
if t.Left != nil {
walker(t.Left)
}
ch <- t.Value
if t.Right != nil {
walker(t.Right)
}
}
walker(t)
close(ch)
}

func Same(t1, t2 *tree.Tree) bool {
chana := make (chan int)
chanb := make (chan int)

go Walk(t1, chana)
go Walk(t2, chanb)

for {
n1, ok1 := <-chana
n2, ok2 := <-chanb
if n1 != n2 || ok1 != ok2 {
return false
}
if (!ok1) {
break
}
}
return true;
}
``````
-

Here's the solution I came up with :

``````func Walker(t *tree.Tree, ch chan int){
if t==nil {return}
Walker(t.Left,ch)
ch<-t.Value
Walker(t.Right,ch)
}

func Walk(t *tree.Tree, ch chan int){
Walker(t,ch)
close(ch)
}

func Same(t1, t2 *tree.Tree) bool{
ch:=make(chan int)
dh:=make(chan int)
go Walk(t1,ch)
go Walk(t2,dh)

for i:=range ch {
j,ok:=<-dh
if(i!=j||!ok)  {return false}
}

return true
}
``````
-
in your solution function Same ensures `ch` is closed (`for i := range ch`), but `dh` could still be open, so, to make sure `dh` has as many elements as `ch` after the for statement, check if `dh` closed too: `_,ok := <-dh; return !ok` – Nemoden Dec 9 '14 at 15:54

You got it almost right, there's no need to use the `select` statement because you will go through the `default` case too often, here's my solution that works without needing to count the number of nodes in the tress:

``````func Same(t1, t2 *tree.Tree) bool {
ch1, ch2 := make(chan int), make(chan int)
go Walk(t1, ch1)
go Walk(t2, ch2)
for i := range ch1 {
j, more := <-ch2
if more {
if i != j { return false }
} else { return false }
}

return true
}
``````
-
Your solution isn't correct. If ch2 has more elements than ch1, then it will return true. You should check at the end if ch2 has more elements – Marco Jan 18 '14 at 21:50

Here's the full solution using ideas here and from the Google Group thread

``````package main

import "fmt"

// Walk walks the tree t sending all values
// from the tree to the channel ch.
func Walk(t *tree.Tree, ch chan int) {
var walker func(t *tree.Tree)
walker = func (t *tree.Tree) {
if (t == nil) {
return
}
walker(t.Left)
ch <- t.Value
walker(t.Right)
}
walker(t)
close(ch)
}

// Same determines whether the trees
// t1 and t2 contain the same values.
func Same(t1, t2 *tree.Tree) bool {
ch1, ch2 := make(chan int), make(chan int)

go Walk(t1, ch1)
go Walk(t2, ch2)

for {
v1,ok1 := <- ch1
v2,ok2 := <- ch2

if v1 != v2 || ok1 != ok2 {
return false
}

if !ok1 {
break
}
}

return true
}

func main() {
fmt.Println("1 and 1 same: ", Same(tree.New(1), tree.New(1)))
fmt.Println("1 and 2 same: ", Same(tree.New(1), tree.New(2)))

}
``````
-

You should avoid to let opened channels unattended or a thread can be waiting forever and never ending.

``````package main

import "fmt"

func WalkRecurse(t *tree.Tree, ch chan int) {
if t == nil {
return
}

WalkRecurse(t.Left, ch)
ch <- t.Value
WalkRecurse(t.Right, ch)
}

// Walk walks the tree t sending all values
// from the tree to the channel ch.
func Walk(t *tree.Tree, ch chan int) {
WalkRecurse(t, ch)
close(ch)
}

// Same determines whether the trees
// t1 and t2 contain the same values.
func Same(t1, t2 *tree.Tree) bool {
var ch1, ch2 chan int = make(chan int), make(chan int)
go Walk(t1, ch1)
go Walk(t2, ch2)

ret := true
for {
v1, ok1 := <- ch1
v2, ok2 := <- ch2

if ok1 != ok2 {
ret = false
}
if ok1 && (v1 != v2) {
ret = false
}
if !ok1 && !ok2 {
break
}
}

return ret
}

func main() {
ch := make(chan int)
go Walk(tree.New(1), ch)
for v := range ch {
fmt.Print(v, " ")
}
fmt.Println()

fmt.Println(Same(tree.New(1), tree.New(1)))
fmt.Println(Same(tree.New(1), tree.New(2)))
}
``````
-