public void PopMin_1Node_CorrectNode()
{
var fh = new FibonacciHeap <int>();
fh.Push(7);
var actual = fh.PopMin();
Assert.Multiple(() =>
{
Assert.AreEqual(7, actual);
Assert.Throws <HeapEmptyException>(() => fh.PopMin());
});
}
public void PopMin_2Nodes_CorrectNode()
{
var fh = new FibonacciHeap <int>();
fh.Push(7);
fh.Push(6);
var first = fh.PopMin();
var second = fh.PopMin();
Assert.Multiple(() =>
{
Assert.AreEqual(6, first);
Assert.AreEqual(7, second);
Assert.Throws <HeapEmptyException>(() => fh.PopMin());
});
}
public void ProcessIntArray(int[] sequence)
{
var fh = new FibonacciHeap <int>();
foreach (var s in sequence)
{
if (s < 0)
{
var val = fh.PopMin();
Assert.AreEqual(System.Math.Abs(s), val);
}
else
{
fh.Push(s);
}
}
Assert.Throws <HeapEmptyException>(() => fh.PopMin());
}
public void PopMin_5Nodes_CorrectNode()
{
var fh = new FibonacciHeap <int>();
fh.Push(7);
fh.Push(6);
fh.Push(5);
fh.Push(8);
fh.Push(4);
fh.Push(2);
fh.Push(1);
fh.Push(3);
var first = fh.PopMin();
var second = fh.PopMin();
var third = fh.PopMin();
var fourth = fh.PopMin();
var fifth = fh.PopMin();
var sixth = fh.PopMin();
var seven = fh.PopMin();
var eigth = fh.PopMin();
Assert.Multiple(() =>
{
Assert.AreEqual(1, first);
Assert.AreEqual(2, second);
Assert.AreEqual(3, third);
Assert.AreEqual(4, fourth);
Assert.AreEqual(5, fifth);
Assert.AreEqual(6, sixth);
Assert.AreEqual(7, seven);
Assert.AreEqual(8, eigth);
Assert.Throws <HeapEmptyException>(() => fh.PopMin());
});
}
public void Count_MultipleValuesPushedAndPopped_CorrectCount(int[] sequence)
{
var fh = new FibonacciHeap <int>();
var count = 0;
foreach (var value in sequence)
{
if (value < 0)
{
var val = fh.PopMin();
Assert.AreEqual(--count, fh.Count);
}
else
{
fh.Push(value);
count++;
}
}
}
public static FibonacciHeap <int> ProcessIntArray(int[] sequence)
{
var fh = new FibonacciHeap <int>();
foreach (var s in sequence)
{
if (s < 0)
{
var val = fh.PopMin();
Assert.AreEqual(System.Math.Abs(s), val);
}
else
{
fh.Push(s);
}
}
return(fh);
}
public void FibonacciHeap_ShouldOrderLargeDataset()
{
var random = new Random(123);
var numbers = Enumerable
.Range(0, 8)
.Select(_ => random.Next(1, 1000000))
.Distinct()
.ToList();
var heap = new FibonacciHeap <int>();
foreach (var i in numbers)
{
heap.Push(i);
}
foreach (var i in numbers.OrderBy(n => n))
{
Assert.AreEqual(i, heap.PopMin());
}
}
public void PopMin_EmptyHeap_Exception()
{
var fh = new FibonacciHeap <int>();
Assert.Throws <HeapEmptyException>(() => fh.PopMin());
}
public void FibonacciHeap_ShouldPerform()
{
var stringBuilder = new System.Text.StringBuilder();
stringBuilder.AppendLine();
var mod = 4;
var random = new Random(123);
var numbers = Enumerable
.Range(0, 200000)
.Select(_ => random.Next(1, 1000000))
.Distinct()
.ToList();
var baselineTimer = Stopwatch.StartNew();
var queueB = new BaselinePriorityQueue <int>();
for (var i = 0; i < numbers.Count; i++)
{
queueB.Push(numbers[i]);
if (i % mod == 0)
{
queueB.PopMin();
}
}
baselineTimer.Stop();
var queueElapsed = baselineTimer.ElapsedMilliseconds;
var heapTimer = Stopwatch.StartNew();
var heap = new FibonacciHeap <int>();
for (var i = 0; i < numbers.Count; i++)
{
heap.Push(numbers[i]);
if (i % mod == 0)
{
heap.PopMin();
}
}
heapTimer.Stop();
var heapElapsed = heapTimer.ElapsedMilliseconds;
stringBuilder.AppendLine($"Heap: {numbers.Count} processed in {heapElapsed}ms");
// timer = Stopwatch.StartNew();
// var list = new List<int>();
// for (var i = 0; i < numbers.Count; i++)
// {
// list.Add(numbers[i]);
// if (i % mod == 0) {
// list.Remove(list.Min());
// }
// }
// timer.Stop();
// stringBuilder.AppendLine($"List: {numbers.Count} processed in {timer.ElapsedMilliseconds}ms");
var variance = ((double)heapElapsed / (double)queueElapsed) * (double)100;
stringBuilder.AppendLine($"Queue: {numbers.Count} processed in {queueElapsed}ms");
stringBuilder.AppendLine();
stringBuilder.AppendLine($"variance {heapElapsed - queueElapsed}ms ({Math.Round(variance, 2)}%)");
stringBuilder.AppendLine();
Console.WriteLine(stringBuilder.ToString());
// Assert.Less(heapElapsed, queueElapsed);
}
