package fn import ( "math/rand" "reflect" "testing" "testing/quick" ) func GenList(r *rand.Rand) *List[uint32] { size := int(r.Uint32() >> 24) l := NewList[uint32]() for i := 0; i < size; i++ { l.PushBack(rand.Uint32()) } return l } func GetRandNode(l *List[uint32], r *rand.Rand) *Node[uint32] { if l.Len() == 0 { return nil } idx := r.Uint32() % uint32(l.Len()) n := l.Front() for i := 0; i < int(idx); i++ { n = n.Next() } return n } func TestPushLenIncrement(t *testing.T) { err := quick.Check( func(l *List[uint32], x uint32, front bool) bool { sz := l.Len() if front { l.PushFront(x) } else { l.PushBack(x) } sz2 := l.Len() return sz2 == sz+1 }, &quick.Config{ Values: func(vs []reflect.Value, r *rand.Rand) { vs[0] = reflect.ValueOf(GenList(r)) vs[1] = reflect.ValueOf(r.Uint32()) vs[2] = reflect.ValueOf(r.Uint32()%2 == 0) }, }, ) if err != nil { t.Fatal(err) } } func TestRemoveLenDecrement(t *testing.T) { err := quick.Check( func(l *List[uint32], n *Node[uint32]) bool { if l.Len() == 0 { return true } sz := l.Len() l.Remove(n) sz2 := l.Len() return sz2 == sz-1 }, &quick.Config{ Values: func(vs []reflect.Value, r *rand.Rand) { l := GenList(r) vs[0] = reflect.ValueOf(l) vs[1] = reflect.ValueOf(GetRandNode(l, r)) }, }, ) if err != nil { t.Fatal(err) } } func TestPushGetCongruence(t *testing.T) { err := quick.Check( func(l *List[uint32], x uint32, front bool) bool { if front { l.PushFront(x) return l.Front().Value == x } else { l.PushBack(x) return l.Back().Value == x } }, &quick.Config{ Values: func(vs []reflect.Value, r *rand.Rand) { vs[0] = reflect.ValueOf(GenList(r)) vs[1] = reflect.ValueOf(r.Uint32()) vs[2] = reflect.ValueOf(r.Uint32()%2 == 0) }, }, ) if err != nil { t.Fatal(err) } } func TestInsertBeforeFrontIdentity(t *testing.T) { err := quick.Check( func(l *List[uint32], x uint32) bool { if l == nil { return true } nodeX := l.InsertBefore(x, l.Front()) return nodeX == l.Front() }, &quick.Config{ Values: func(vs []reflect.Value, r *rand.Rand) { l := GenList(r) vs[0] = reflect.ValueOf(l) vs[1] = reflect.ValueOf(r.Uint32()) }, }, ) if err != nil { t.Fatal(err) } } func TestInsertAfterBackIdentity(t *testing.T) { err := quick.Check( func(l *List[uint32], x uint32) bool { if l == nil { return true } nodeX := l.InsertAfter(x, l.Back()) return nodeX == l.Back() }, &quick.Config{ Values: func(vs []reflect.Value, r *rand.Rand) { l := GenList(r) vs[0] = reflect.ValueOf(l) vs[1] = reflect.ValueOf(r.Uint32()) }, }, ) if err != nil { t.Fatal(err) } } func TestInsertBeforeNextIdentity(t *testing.T) { err := quick.Check( func(l *List[uint32], n *Node[uint32], x uint32) bool { if n == nil { return true } nodeX := l.InsertBefore(x, n) return nodeX.Next() == n }, &quick.Config{ Values: func(vs []reflect.Value, r *rand.Rand) { l := GenList(r) vs[0] = reflect.ValueOf(l) vs[1] = reflect.ValueOf(GetRandNode(l, r)) vs[2] = reflect.ValueOf(r.Uint32()) }, }, ) if err != nil { t.Fatal(err) } } func TestInsertAfterPrevIdentity(t *testing.T) { err := quick.Check( func(l *List[uint32], n *Node[uint32], x uint32) bool { if n == nil { return true } nodeX := l.InsertAfter(x, n) return nodeX.Prev() == n }, &quick.Config{ Values: func(vs []reflect.Value, r *rand.Rand) { l := GenList(r) vs[0] = reflect.ValueOf(l) vs[1] = reflect.ValueOf(GetRandNode(l, r)) vs[2] = reflect.ValueOf(r.Uint32()) }, }, ) if err != nil { t.Fatal(err) } } func TestMoveToFrontFrontIdentity(t *testing.T) { err := quick.Check( func(l *List[uint32], n *Node[uint32]) bool { if n == nil { return true } l.MoveToFront(n) return l.Front() == n }, &quick.Config{ Values: func(vs []reflect.Value, r *rand.Rand) { l := GenList(r) vs[0] = reflect.ValueOf(l) vs[1] = reflect.ValueOf(GetRandNode(l, r)) }, }, ) if err != nil { t.Fatal(err) } } func TestMoveToBackBackIdentity(t *testing.T) { err := quick.Check( func(l *List[uint32], n *Node[uint32]) bool { if n == nil { return true } l.MoveToBack(n) return l.Back() == n }, &quick.Config{ Values: func(vs []reflect.Value, r *rand.Rand) { l := GenList(r) vs[0] = reflect.ValueOf(l) vs[1] = reflect.ValueOf(GetRandNode(l, r)) }, }, ) if err != nil { t.Fatal(err) } } func TestMoveBeforeFrontIsFront(t *testing.T) { err := quick.Check( func(l *List[uint32], n *Node[uint32]) bool { if n == nil { return true } l.MoveBefore(n, l.Front()) return l.Front() == n }, &quick.Config{ Values: func(vs []reflect.Value, r *rand.Rand) { l := GenList(r) vs[0] = reflect.ValueOf(l) vs[1] = reflect.ValueOf(GetRandNode(l, r)) }, }, ) if err != nil { t.Fatal(err) } } func TestMoveAfterBackIsBack(t *testing.T) { err := quick.Check( func(l *List[uint32], n *Node[uint32]) bool { if n == nil { return true } l.MoveAfter(n, l.Back()) return l.Back() == n }, &quick.Config{ Values: func(vs []reflect.Value, r *rand.Rand) { l := GenList(r) vs[0] = reflect.ValueOf(l) vs[1] = reflect.ValueOf(GetRandNode(l, r)) }, }, ) if err != nil { t.Fatal(err) } } func TestMultiMoveErasure(t *testing.T) { err := quick.Check( func(l *List[uint32], n *Node[uint32], m *Node[uint32]) bool { if n == nil || m == nil || n == m { return true } l.MoveToFront(n) l.MoveToBack(n) l.MoveBefore(n, m) l.MoveAfter(n, m) return m.Next() == n }, &quick.Config{ Values: func(vs []reflect.Value, r *rand.Rand) { l := GenList(r) vs[0] = reflect.ValueOf(l) vs[1] = reflect.ValueOf(GetRandNode(l, r)) vs[2] = reflect.ValueOf(GetRandNode(l, r)) }, }, ) if err != nil { t.Fatal(err) } } func TestPushListSymmetry(t *testing.T) { copyList := func(l *List[uint32]) *List[uint32] { c := NewList[uint32]() for n := l.Front(); n != nil; n = n.Next() { c.PushBack(n.Value) } return c } err := quick.Check( func(l1 *List[uint32], l2 *List[uint32]) bool { if l1.Len() == 0 || l2.Len() == 0 { return true } l1Copy := copyList(l1) l2Copy := copyList(l2) l1.PushBackList(l2Copy) l2.PushFrontList(l1Copy) iter1 := l1.Front() iter2 := l2.Front() for i := 0; i < l1Copy.Len()+l2Copy.Len()-1; i++ { if iter1.Value != iter2.Value { return false } iter1 = iter1.Next() iter2 = iter2.Next() } return true }, &quick.Config{ Values: func(vs []reflect.Value, r *rand.Rand) { l := GenList(r) l2 := GenList(r) vs[0] = reflect.ValueOf(l) vs[1] = reflect.ValueOf(l2) }, }, ) if err != nil { t.Fatal(err) } } func TestIssue4103(t *testing.T) { l1 := NewList[int]() l1.PushBack(1) l1.PushBack(2) l2 := NewList[int]() l2.PushBack(3) l2.PushBack(4) e := l1.Front() l2.Remove(e) // l2 should not change because e is not an element of l2 if n := l2.Len(); n != 2 { t.Errorf("l2.Len() = %d, want 2", n) } l1.InsertBefore(8, e) if n := l1.Len(); n != 3 { t.Errorf("l1.Len() = %d, want 3", n) } } func TestIssue6349(t *testing.T) { l := NewList[int]() l.PushBack(1) l.PushBack(2) e := l.Front() l.Remove(e) if e.Value != 1 { t.Errorf("e.value = %d, want 1", e.Value) } if e.Next() != nil { t.Errorf("e.Next() != nil") } if e.Prev() != nil { t.Errorf("e.Prev() != nil") } } func checkListLen[V any](t *testing.T, l *List[V], length int) bool { if n := l.Len(); n != length { t.Errorf("l.Len() = %d, want %d", n, length) return false } return true } func checkListPointers[V any](t *testing.T, l *List[V], es []*Node[V]) { root := &l.root if !checkListLen(t, l, len(es)) { return } // zero length lists must be the zero value or properly initialized // (sentinel circle) if len(es) == 0 { if l.root.next != nil && l.root.next != root || l.root.prev != nil && l.root.prev != root { t.Errorf("l.root.next = %p, l.root.prev = %p;"+ "both should both be nil or %p", l.root.next, l.root.prev, root) } return } // len(es) > 0 // check internal and external prev/next connections for i, e := range es { prev := root Prev := (*Node[V])(nil) if i > 0 { prev = es[i-1] Prev = prev } if p := e.prev; p != prev { t.Errorf("elt[%d](%p).prev = %p, want %p", i, e, p, prev) } if p := e.Prev(); p != Prev { t.Errorf("elt[%d](%p).Prev() = %p, want %p", i, e, p, Prev) } next := root Next := (*Node[V])(nil) if i < len(es)-1 { next = es[i+1] Next = next } if n := e.next; n != next { t.Errorf("elt[%d](%p).next = %p, want %p", i, e, n, next) } if n := e.Next(); n != Next { t.Errorf("elt[%d](%p).Next() = %p, want %p", i, e, n, Next) } } } func TestList(t *testing.T) { l := NewList[int]() checkListPointers(t, l, []*Node[int]{}) // Single element list e := l.PushFront(5) checkListPointers(t, l, []*Node[int]{e}) l.MoveToFront(e) checkListPointers(t, l, []*Node[int]{e}) l.MoveToBack(e) checkListPointers(t, l, []*Node[int]{e}) l.Remove(e) checkListPointers(t, l, []*Node[int]{}) // Bigger list e2 := l.PushFront(2) e1 := l.PushFront(1) e3 := l.PushBack(3) e4 := l.PushBack(0) checkListPointers(t, l, []*Node[int]{e1, e2, e3, e4}) l.Remove(e2) checkListPointers(t, l, []*Node[int]{e1, e3, e4}) l.MoveToFront(e3) // move from middle checkListPointers(t, l, []*Node[int]{e3, e1, e4}) l.MoveToFront(e1) l.MoveToBack(e3) // move from middle checkListPointers(t, l, []*Node[int]{e1, e4, e3}) l.MoveToFront(e3) // move from back checkListPointers(t, l, []*Node[int]{e3, e1, e4}) l.MoveToFront(e3) // should be no-op checkListPointers(t, l, []*Node[int]{e3, e1, e4}) l.MoveToBack(e3) // move from front checkListPointers(t, l, []*Node[int]{e1, e4, e3}) l.MoveToBack(e3) // should be no-op checkListPointers(t, l, []*Node[int]{e1, e4, e3}) e2 = l.InsertBefore(2, e1) // insert before front checkListPointers(t, l, []*Node[int]{e2, e1, e4, e3}) l.Remove(e2) e2 = l.InsertBefore(2, e4) // insert before middle checkListPointers(t, l, []*Node[int]{e1, e2, e4, e3}) l.Remove(e2) e2 = l.InsertBefore(2, e3) // insert before back checkListPointers(t, l, []*Node[int]{e1, e4, e2, e3}) l.Remove(e2) e2 = l.InsertAfter(2, e1) // insert after front checkListPointers(t, l, []*Node[int]{e1, e2, e4, e3}) l.Remove(e2) e2 = l.InsertAfter(2, e4) // insert after middle checkListPointers(t, l, []*Node[int]{e1, e4, e2, e3}) l.Remove(e2) e2 = l.InsertAfter(2, e3) // insert after back checkListPointers(t, l, []*Node[int]{e1, e4, e3, e2}) l.Remove(e2) // Check standard iteration. sum := 0 for e := l.Front(); e != nil; e = e.Next() { sum += e.Value } if sum != 4 { t.Errorf("sum over l = %d, want 4", sum) } // Clear all elements by iterating var next *Node[int] for e := l.Front(); e != nil; e = next { next = e.Next() l.Remove(e) } checkListPointers(t, l, []*Node[int]{}) } func checkList[V comparable](t *testing.T, l *List[V], es []V) { if !checkListLen(t, l, len(es)) { return } i := 0 for e := l.Front(); e != nil; e = e.Next() { le := e.Value if le != es[i] { t.Errorf("elt[%d].Value = %v, want %v", i, le, es[i]) } i++ } } func TestExtending(t *testing.T) { l1 := NewList[int]() l2 := NewList[int]() l1.PushBack(1) l1.PushBack(2) l1.PushBack(3) l2.PushBack(4) l2.PushBack(5) l3 := NewList[int]() l3.PushBackList(l1) checkList(t, l3, []int{1, 2, 3}) l3.PushBackList(l2) checkList(t, l3, []int{1, 2, 3, 4, 5}) l3 = NewList[int]() l3.PushFrontList(l2) checkList(t, l3, []int{4, 5}) l3.PushFrontList(l1) checkList(t, l3, []int{1, 2, 3, 4, 5}) checkList(t, l1, []int{1, 2, 3}) checkList(t, l2, []int{4, 5}) l3 = NewList[int]() l3.PushBackList(l1) checkList(t, l3, []int{1, 2, 3}) l3.PushBackList(l3) checkList(t, l3, []int{1, 2, 3, 1, 2, 3}) l3 = NewList[int]() l3.PushFrontList(l1) checkList(t, l3, []int{1, 2, 3}) l3.PushFrontList(l3) checkList(t, l3, []int{1, 2, 3, 1, 2, 3}) l3 = NewList[int]() l1.PushBackList(l3) checkList(t, l1, []int{1, 2, 3}) l1.PushFrontList(l3) checkList(t, l1, []int{1, 2, 3}) } func TestRemove(t *testing.T) { l := NewList[int]() e1 := l.PushBack(1) e2 := l.PushBack(2) checkListPointers(t, l, []*Node[int]{e1, e2}) e := l.Front() l.Remove(e) checkListPointers(t, l, []*Node[int]{e2}) l.Remove(e) checkListPointers(t, l, []*Node[int]{e2}) } func TestMove(t *testing.T) { l := NewList[int]() e1 := l.PushBack(1) e2 := l.PushBack(2) e3 := l.PushBack(3) e4 := l.PushBack(4) l.MoveAfter(e3, e3) checkListPointers(t, l, []*Node[int]{e1, e2, e3, e4}) l.MoveBefore(e2, e2) checkListPointers(t, l, []*Node[int]{e1, e2, e3, e4}) l.MoveAfter(e3, e2) checkListPointers(t, l, []*Node[int]{e1, e2, e3, e4}) l.MoveBefore(e2, e3) checkListPointers(t, l, []*Node[int]{e1, e2, e3, e4}) l.MoveBefore(e2, e4) checkListPointers(t, l, []*Node[int]{e1, e3, e2, e4}) e2, e3 = e3, e2 l.MoveBefore(e4, e1) checkListPointers(t, l, []*Node[int]{e4, e1, e2, e3}) e1, e2, e3, e4 = e4, e1, e2, e3 l.MoveAfter(e4, e1) checkListPointers(t, l, []*Node[int]{e1, e4, e2, e3}) e2, e3, e4 = e4, e2, e3 l.MoveAfter(e2, e3) checkListPointers(t, l, []*Node[int]{e1, e3, e2, e4}) } // Test PushFront, PushBack, PushFrontList, PushBackList with uninitialized List func TestZeroList(t *testing.T) { var l1 = new(List[int]) l1.PushFront(1) checkList(t, l1, []int{1}) var l2 = new(List[int]) l2.PushBack(1) checkList(t, l2, []int{1}) var l3 = new(List[int]) l3.PushFrontList(l1) checkList(t, l3, []int{1}) var l4 = new(List[int]) l4.PushBackList(l2) checkList(t, l4, []int{1}) } // Test that a list l is not modified when calling InsertBefore with a mark // that is not an element of l. func TestInsertBeforeUnknownMark(t *testing.T) { var l List[int] l.PushBack(1) l.PushBack(2) l.PushBack(3) l.InsertBefore(1, new(Node[int])) checkList(t, &l, []int{1, 2, 3}) } // Test that a list l is not modified when calling InsertAfter with a mark that // is not an element of l. func TestInsertAfterUnknownMark(t *testing.T) { var l List[int] l.PushBack(1) l.PushBack(2) l.PushBack(3) l.InsertAfter(1, new(Node[int])) checkList(t, &l, []int{1, 2, 3}) } // Test that a list l is not modified when calling MoveAfter or MoveBefore with // a mark that is not an element of l. func TestMoveUnknownMark(t *testing.T) { var l1 List[int] e1 := l1.PushBack(1) var l2 List[int] e2 := l2.PushBack(2) l1.MoveAfter(e1, e2) checkList(t, &l1, []int{1}) checkList(t, &l2, []int{2}) l1.MoveBefore(e1, e2) checkList(t, &l1, []int{1}) checkList(t, &l2, []int{2}) }