// Copyright (c) 2015, Emir Pasic. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package binaryheap import ( "math/rand" "strings" "testing" ) func TestBinaryHeapPush(t *testing.T) { heap := NewWithIntComparator() if actualValue := heap.Empty(); actualValue != true { t.Errorf("Got %v expected %v", actualValue, true) } heap.Push(3) // [3] heap.Push(2) // [2,3] heap.Push(1) // [1,3,2](2 swapped with 1, hence last) if actualValue := heap.Values(); actualValue[0].(int) != 1 || actualValue[1].(int) != 3 || actualValue[2].(int) != 2 { t.Errorf("Got %v expected %v", actualValue, "[1,2,3]") } if actualValue := heap.Empty(); actualValue != false { t.Errorf("Got %v expected %v", actualValue, false) } if actualValue := heap.Size(); actualValue != 3 { t.Errorf("Got %v expected %v", actualValue, 3) } if actualValue, ok := heap.Peek(); actualValue != 1 || !ok { t.Errorf("Got %v expected %v", actualValue, 1) } } func TestBinaryHeapPushBulk(t *testing.T) { heap := NewWithIntComparator() heap.Push(15, 20, 3, 1, 2) if actualValue := heap.Values(); actualValue[0].(int) != 1 || actualValue[1].(int) != 2 || actualValue[2].(int) != 3 { t.Errorf("Got %v expected %v", actualValue, "[1,2,3]") } if actualValue, ok := heap.Pop(); actualValue != 1 || !ok { t.Errorf("Got %v expected %v", actualValue, 1) } } func TestBinaryHeapPop(t *testing.T) { heap := NewWithIntComparator() if actualValue := heap.Empty(); actualValue != true { t.Errorf("Got %v expected %v", actualValue, true) } heap.Push(3) // [3] heap.Push(2) // [2,3] heap.Push(1) // [1,3,2](2 swapped with 1, hence last) heap.Pop() // [3,2] if actualValue, ok := heap.Peek(); actualValue != 2 || !ok { t.Errorf("Got %v expected %v", actualValue, 2) } if actualValue, ok := heap.Pop(); actualValue != 2 || !ok { t.Errorf("Got %v expected %v", actualValue, 2) } if actualValue, ok := heap.Pop(); actualValue != 3 || !ok { t.Errorf("Got %v expected %v", actualValue, 3) } if actualValue, ok := heap.Pop(); actualValue != nil || ok { t.Errorf("Got %v expected %v", actualValue, nil) } if actualValue := heap.Empty(); actualValue != true { t.Errorf("Got %v expected %v", actualValue, true) } if actualValue := heap.Values(); len(actualValue) != 0 { t.Errorf("Got %v expected %v", actualValue, "[]") } } func TestBinaryHeapRandom(t *testing.T) { heap := NewWithIntComparator() rand.Seed(3) for i := 0; i < 10000; i++ { r := int(rand.Int31n(30)) heap.Push(r) } prev, _ := heap.Pop() for !heap.Empty() { curr, _ := heap.Pop() if prev.(int) > curr.(int) { t.Errorf("Heap property invalidated. prev: %v current: %v", prev, curr) } prev = curr } } func TestBinaryHeapIteratorOnEmpty(t *testing.T) { heap := NewWithIntComparator() it := heap.Iterator() for it.Next() { t.Errorf("Shouldn't iterate on empty heap") } } func TestBinaryHeapIteratorNext(t *testing.T) { heap := NewWithIntComparator() heap.Push(3) // [3] heap.Push(2) // [2,3] heap.Push(1) // [1,3,2](2 swapped with 1, hence last) it := heap.Iterator() count := 0 for it.Next() { count++ index := it.Index() value := it.Value() switch index { case 0: if actualValue, expectedValue := value, 1; actualValue != expectedValue { t.Errorf("Got %v expected %v", actualValue, expectedValue) } case 1: if actualValue, expectedValue := value, 3; actualValue != expectedValue { t.Errorf("Got %v expected %v", actualValue, expectedValue) } case 2: if actualValue, expectedValue := value, 2; actualValue != expectedValue { t.Errorf("Got %v expected %v", actualValue, expectedValue) } default: t.Errorf("Too many") } if actualValue, expectedValue := index, count-1; actualValue != expectedValue { t.Errorf("Got %v expected %v", actualValue, expectedValue) } } if actualValue, expectedValue := count, 3; actualValue != expectedValue { t.Errorf("Got %v expected %v", actualValue, expectedValue) } } func TestBinaryHeapIteratorPrev(t *testing.T) { heap := NewWithIntComparator() heap.Push(3) // [3] heap.Push(2) // [2,3] heap.Push(1) // [1,3,2](2 swapped with 1, hence last) it := heap.Iterator() for it.Next() { } count := 0 for it.Prev() { count++ index := it.Index() value := it.Value() switch index { case 0: if actualValue, expectedValue := value, 1; actualValue != expectedValue { t.Errorf("Got %v expected %v", actualValue, expectedValue) } case 1: if actualValue, expectedValue := value, 3; actualValue != expectedValue { t.Errorf("Got %v expected %v", actualValue, expectedValue) } case 2: if actualValue, expectedValue := value, 2; actualValue != expectedValue { t.Errorf("Got %v expected %v", actualValue, expectedValue) } default: t.Errorf("Too many") } if actualValue, expectedValue := index, 3-count; actualValue != expectedValue { t.Errorf("Got %v expected %v", actualValue, expectedValue) } } if actualValue, expectedValue := count, 3; actualValue != expectedValue { t.Errorf("Got %v expected %v", actualValue, expectedValue) } } func TestBinaryHeapIteratorBegin(t *testing.T) { heap := NewWithIntComparator() it := heap.Iterator() it.Begin() heap.Push(2) heap.Push(3) heap.Push(1) for it.Next() { } it.Begin() it.Next() if index, value := it.Index(), it.Value(); index != 0 || value != 1 { t.Errorf("Got %v,%v expected %v,%v", index, value, 0, 1) } } func TestBinaryHeapIteratorEnd(t *testing.T) { heap := NewWithIntComparator() it := heap.Iterator() if index := it.Index(); index != -1 { t.Errorf("Got %v expected %v", index, -1) } it.End() if index := it.Index(); index != 0 { t.Errorf("Got %v expected %v", index, 0) } heap.Push(3) // [3] heap.Push(2) // [2,3] heap.Push(1) // [1,3,2](2 swapped with 1, hence last) it.End() if index := it.Index(); index != heap.Size() { t.Errorf("Got %v expected %v", index, heap.Size()) } it.Prev() if index, value := it.Index(), it.Value(); index != heap.Size()-1 || value != 2 { t.Errorf("Got %v,%v expected %v,%v", index, value, heap.Size()-1, 2) } } func TestBinaryHeapIteratorFirst(t *testing.T) { heap := NewWithIntComparator() it := heap.Iterator() if actualValue, expectedValue := it.First(), false; actualValue != expectedValue { t.Errorf("Got %v expected %v", actualValue, expectedValue) } heap.Push(3) // [3] heap.Push(2) // [2,3] heap.Push(1) // [1,3,2](2 swapped with 1, hence last) if actualValue, expectedValue := it.First(), true; actualValue != expectedValue { t.Errorf("Got %v expected %v", actualValue, expectedValue) } if index, value := it.Index(), it.Value(); index != 0 || value != 1 { t.Errorf("Got %v,%v expected %v,%v", index, value, 0, 1) } } func TestBinaryHeapIteratorLast(t *testing.T) { tree := NewWithIntComparator() it := tree.Iterator() if actualValue, expectedValue := it.Last(), false; actualValue != expectedValue { t.Errorf("Got %v expected %v", actualValue, expectedValue) } tree.Push(2) tree.Push(3) tree.Push(1) // [1,3,2](2 swapped with 1, hence last) if actualValue, expectedValue := it.Last(), true; actualValue != expectedValue { t.Errorf("Got %v expected %v", actualValue, expectedValue) } if index, value := it.Index(), it.Value(); index != 2 || value != 2 { t.Errorf("Got %v,%v expected %v,%v", index, value, 2, 2) } } func TestBinaryHeapIteratorNextTo(t *testing.T) { // Sample seek function, i.e. string starting with "b" seek := func(index int, value interface{}) bool { return strings.HasSuffix(value.(string), "b") } // NextTo (empty) { tree := NewWithStringComparator() it := tree.Iterator() for it.NextTo(seek) { t.Errorf("Shouldn't iterate on empty list") } } // NextTo (not found) { tree := NewWithStringComparator() tree.Push("xx") tree.Push("yy") it := tree.Iterator() for it.NextTo(seek) { t.Errorf("Shouldn't iterate on empty list") } } // NextTo (found) { tree := NewWithStringComparator() tree.Push("aa") tree.Push("bb") tree.Push("cc") it := tree.Iterator() it.Begin() if !it.NextTo(seek) { t.Errorf("Shouldn't iterate on empty list") } if index, value := it.Index(), it.Value(); index != 1 || value.(string) != "bb" { t.Errorf("Got %v,%v expected %v,%v", index, value, 1, "bb") } if !it.Next() { t.Errorf("Should go to first element") } if index, value := it.Index(), it.Value(); index != 2 || value.(string) != "cc" { t.Errorf("Got %v,%v expected %v,%v", index, value, 2, "cc") } if it.Next() { t.Errorf("Should not go past last element") } } } func TestBinaryHeapIteratorPrevTo(t *testing.T) { // Sample seek function, i.e. string starting with "b" seek := func(index int, value interface{}) bool { return strings.HasSuffix(value.(string), "b") } // PrevTo (empty) { tree := NewWithStringComparator() it := tree.Iterator() it.End() for it.PrevTo(seek) { t.Errorf("Shouldn't iterate on empty list") } } // PrevTo (not found) { tree := NewWithStringComparator() tree.Push("xx") tree.Push("yy") it := tree.Iterator() it.End() for it.PrevTo(seek) { t.Errorf("Shouldn't iterate on empty list") } } // PrevTo (found) { tree := NewWithStringComparator() tree.Push("aa") tree.Push("bb") tree.Push("cc") it := tree.Iterator() it.End() if !it.PrevTo(seek) { t.Errorf("Shouldn't iterate on empty list") } if index, value := it.Index(), it.Value(); index != 1 || value.(string) != "bb" { t.Errorf("Got %v,%v expected %v,%v", index, value, 1, "bb") } if !it.Prev() { t.Errorf("Should go to first element") } if index, value := it.Index(), it.Value(); index != 0 || value.(string) != "aa" { t.Errorf("Got %v,%v expected %v,%v", index, value, 0, "aa") } if it.Prev() { t.Errorf("Should not go before first element") } } } func TestBinaryHeapSerialization(t *testing.T) { heap := NewWithStringComparator() heap.Push("c") // ["c"] heap.Push("b") // ["b","c"] heap.Push("a") // ["a","c","b"]("b" swapped with "a", hence last) var err error assert := func() { if actualValue := heap.Values(); actualValue[0].(string) != "a" || actualValue[1].(string) != "c" || actualValue[2].(string) != "b" { t.Errorf("Got %v expected %v", actualValue, "[1,3,2]") } if actualValue := heap.Size(); actualValue != 3 { t.Errorf("Got %v expected %v", actualValue, 3) } if actualValue, ok := heap.Peek(); actualValue != "a" || !ok { t.Errorf("Got %v expected %v", actualValue, "a") } if err != nil { t.Errorf("Got error %v", err) } } assert() json, err := heap.ToJSON() assert() err = heap.FromJSON(json) assert() } func benchmarkPush(b *testing.B, heap *Heap, size int) { for i := 0; i < b.N; i++ { for n := 0; n < size; n++ { heap.Push(n) } } } func benchmarkPop(b *testing.B, heap *Heap, size int) { for i := 0; i < b.N; i++ { for n := 0; n < size; n++ { heap.Pop() } } } func BenchmarkBinaryHeapPop100(b *testing.B) { b.StopTimer() size := 100 heap := NewWithIntComparator() for n := 0; n < size; n++ { heap.Push(n) } b.StartTimer() benchmarkPop(b, heap, size) } func BenchmarkBinaryHeapPop1000(b *testing.B) { b.StopTimer() size := 1000 heap := NewWithIntComparator() for n := 0; n < size; n++ { heap.Push(n) } b.StartTimer() benchmarkPop(b, heap, size) } func BenchmarkBinaryHeapPop10000(b *testing.B) { b.StopTimer() size := 10000 heap := NewWithIntComparator() for n := 0; n < size; n++ { heap.Push(n) } b.StartTimer() benchmarkPop(b, heap, size) } func BenchmarkBinaryHeapPop100000(b *testing.B) { b.StopTimer() size := 100000 heap := NewWithIntComparator() for n := 0; n < size; n++ { heap.Push(n) } b.StartTimer() benchmarkPop(b, heap, size) } func BenchmarkBinaryHeapPush100(b *testing.B) { b.StopTimer() size := 100 heap := NewWithIntComparator() b.StartTimer() benchmarkPush(b, heap, size) } func BenchmarkBinaryHeapPush1000(b *testing.B) { b.StopTimer() size := 1000 heap := NewWithIntComparator() for n := 0; n < size; n++ { heap.Push(n) } b.StartTimer() benchmarkPush(b, heap, size) } func BenchmarkBinaryHeapPush10000(b *testing.B) { b.StopTimer() size := 10000 heap := NewWithIntComparator() for n := 0; n < size; n++ { heap.Push(n) } b.StartTimer() benchmarkPush(b, heap, size) } func BenchmarkBinaryHeapPush100000(b *testing.B) { b.StopTimer() size := 100000 heap := NewWithIntComparator() for n := 0; n < size; n++ { heap.Push(n) } b.StartTimer() benchmarkPush(b, heap, size) }