A Tour of GoExercise: Equivalent Binary Trees
There can be many different binary trees with the same sequence of values stored at the leaves. For example, here are two binary trees storing the sequence 1, 1, 2, 3, 5, 8, 13.
A function to check whether two binary trees store the same sequence is quite complex in most languages. We'll use Go's concurrency and channels to write a simple solution.
This example uses the tree
package, which defines the type:
type Tree struct {Left *TreeValue intRight *Tree}
1. Implement the Walk
function.
2. Test the Walk
function.
The function tree.New(k)
constructs a randomly-structured binary tree holding the values k
, 2k
, 3k
,
..., 10k
.
Create a new channel ch
and kick off the walker:
go Walk(tree.New(1), ch)
Then read and print 10 values from the channel. It should be the numbers 1, 2, 3, ..., 10.
3. Implement the Same
function using Walk
to determine whether t1
and t2
store
the same values.
4. Test the Same
function.
Same(tree.New(1), tree.New(1))
should return true, and Same(tree.New(1), tree.New(2))
should return false.
package mainimport "tour/tree"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) {if t.Left != nil {Walk(t.Left, ch)}ch <- t.Value if t.Right != nil {Walk(t.Right, 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)result := truefor i := 0; i < 10; i ++ {v1 := <- ch1v2 := <- ch2result = (v1 == v2)}return result}func main() {//ch := make(chan int)//go Walk(tree.New(1), ch)//for i := 0; i < 10; i ++ {//v := <- ch//fmt.Println(v)//}fmt.Println(Same(tree.New(1), tree.New(1)))fmt.Println(Same(tree.New(1), tree.New(2)))}