package skiplist import ( "bytes" "fmt" "math/rand" "strconv" "testing" ) const ( maxN = 10000 ) func TestInsertAndFind(t *testing.T) { k0 := []byte("0") var list *SkipList var listPointer *SkipList listPointer.Insert(k0) if _, ok := listPointer.Find(k0); ok { t.Fail() } list = New() if _, ok := list.Find(k0); ok { t.Fail() } if !list.IsEmpty() { t.Fail() } // Test at the beginning of the list. for i := 0; i < maxN; i++ { key := []byte(strconv.Itoa(maxN-i)) list.Insert(key) } for i := 0; i < maxN; i++ { key := []byte(strconv.Itoa(maxN-i)) if _, ok := list.Find(key); !ok { t.Fail() } } list = New() // Test at the end of the list. for i := 0; i < maxN; i++ { key := []byte(strconv.Itoa(i)) list.Insert(key) } for i := 0; i < maxN; i++ { key := []byte(strconv.Itoa(i)) if _, ok := list.Find(key); !ok { t.Fail() } } list = New() // Test at random positions in the list. rList := rand.Perm(maxN) for _, e := range rList { key := []byte(strconv.Itoa(e)) println("insert", e) list.Insert(key) } for _, e := range rList { key := []byte(strconv.Itoa(e)) println("find", e) if _, ok := list.Find(key); !ok { t.Fail() } } println("print list") list.println() } func Element(x int) []byte { return []byte(strconv.Itoa(x)) } func TestDelete(t *testing.T) { k0 := []byte("0") var list *SkipList // Delete on empty list list.Delete(k0) list = New() list.Delete(k0) if !list.IsEmpty() { t.Fail() } list.Insert(k0) list.Delete(k0) if !list.IsEmpty() { t.Fail() } // Delete elements at the beginning of the list. for i := 0; i < maxN; i++ { list.Insert(Element(i)) } for i := 0; i < maxN; i++ { list.Delete(Element(i)) } if !list.IsEmpty() { t.Fail() } list = New() // Delete elements at the end of the list. for i := 0; i < maxN; i++ { list.Insert(Element(i)) } for i := 0; i < maxN; i++ { list.Delete(Element(maxN - i - 1)) } if !list.IsEmpty() { t.Fail() } list = New() // Delete elements at random positions in the list. rList := rand.Perm(maxN) for _, e := range rList { list.Insert(Element(e)) } for _, e := range rList { list.Delete(Element(e)) } if !list.IsEmpty() { t.Fail() } } func TestNext(t *testing.T) { list := New() for i := 0; i < maxN; i++ { list.Insert(Element(i)) } smallest := list.GetSmallestNode() largest := list.GetLargestNode() lastNode := smallest node := lastNode for node != largest { node = list.Next(node) // Must always be incrementing here! if bytes.Compare(node.Values[0], lastNode.Values[0]) <= 0 { t.Fail() } // Next.Prev must always point to itself! if list.Next(list.Prev(node)) != node { t.Fail() } lastNode = node } if list.Next(largest) != smallest { t.Fail() } } func TestPrev(t *testing.T) { list := New() for i := 0; i < maxN; i++ { list.Insert(Element(i)) } smallest := list.GetSmallestNode() largest := list.GetLargestNode() lastNode := largest node := lastNode for node != smallest { node = list.Prev(node) // Must always be incrementing here! if bytes.Compare(node.Values[0], lastNode.Values[0]) >= 0 { t.Fail() } // Next.Prev must always point to itself! if list.Prev(list.Next(node)) != node { t.Fail() } lastNode = node } if list.Prev(smallest) != largest { t.Fail() } } func TestGetNodeCount(t *testing.T) { list := New() for i := 0; i < maxN; i++ { list.Insert(Element(i)) } if list.GetNodeCount() != maxN { t.Fail() } } func TestFindGreaterOrEqual(t *testing.T) { maxNumber := maxN * 100 var list *SkipList var listPointer *SkipList // Test on empty list. if _, ok := listPointer.FindGreaterOrEqual(Element(0)); ok { t.Fail() } list = New() for i := 0; i < maxN; i++ { list.Insert(Element(rand.Intn(maxNumber))) } for i := 0; i < maxN; i++ { key := Element(rand.Intn(maxNumber)) if v, ok := list.FindGreaterOrEqual(key); ok { // if f is v should be bigger than the element before if bytes.Compare(v.Prev.Key, key) >= 0 { fmt.Printf("PrevV: %s\n key: %s\n\n", string(v.Prev.Key), string(key)) t.Fail() } // v should be bigger or equal to f // If we compare directly, we get an equal key with a difference on the 10th decimal point, which fails. if bytes.Compare(v.Values[0], key) < 0 { fmt.Printf("v: %s\n key: %s\n\n", string(v.Values[0]), string(key)) t.Fail() } } else { lastV := list.GetLargestNode().GetValue() // It is OK, to fail, as long as f is bigger than the last element. if bytes.Compare(key, lastV) <= 0 { fmt.Printf("lastV: %s\n key: %s\n\n", string(lastV), string(key)) t.Fail() } } } }