using System;
using System.Collections;
using System.Collections.Generic;
namespace Mirror
{
public class SyncSet<T> : SyncObject, ISet<T>
{
public delegate void SyncSetChanged(Operation op, T item);
protected readonly ISet<T> objects;
public int Count => objects.Count;
public bool IsReadOnly { get; private set; }
public event SyncSetChanged Callback;
public enum Operation : byte
{
OP_ADD,
OP_CLEAR,
OP_REMOVE
}
struct Change
{
internal Operation operation;
internal T item;
}
// list of changes.
// -> insert/delete/clear is only ONE change
// -> changing the same slot 10x caues 10 changes.
// -> note that this grows until next sync(!)
// TODO Dictionary<key, change> to avoid ever growing changes / redundant changes!
readonly List<Change> changes = new List<Change>();
// how many changes we need to ignore
// this is needed because when we initialize the list,
// we might later receive changes that have already been applied
// so we need to skip them
int changesAhead;
public SyncSet(ISet<T> objects)
{
this.objects = objects;
}
public override void Reset()
{
IsReadOnly = false;
changes.Clear();
changesAhead = 0;
objects.Clear();
}
// throw away all the changes
// this should be called after a successful sync
public override void ClearChanges() => changes.Clear();
void AddOperation(Operation op, T item)
{
if (IsReadOnly)
{
throw new InvalidOperationException("SyncSets can only be modified at the server");
}
Change change = new Change
{
operation = op,
item = item
};
if (IsRecording())
{
changes.Add(change);
OnDirty?.Invoke();
}
Callback?.Invoke(op, item);
}
void AddOperation(Operation op) => AddOperation(op, default);
public override void OnSerializeAll(NetworkWriter writer)
{
// if init, write the full list content
writer.WriteUInt((uint)objects.Count);
foreach (T obj in objects)
{
writer.Write(obj);
}
// all changes have been applied already
// thus the client will need to skip all the pending changes
// or they would be applied again.
// So we write how many changes are pending
writer.WriteUInt((uint)changes.Count);
}
public override void OnSerializeDelta(NetworkWriter writer)
{
// write all the queued up changes
writer.WriteUInt((uint)changes.Count);
for (int i = 0; i < changes.Count; i++)
{
Change change = changes[i];
writer.WriteByte((byte)change.operation);
switch (change.operation)
{
case Operation.OP_ADD:
writer.Write(change.item);
break;
case Operation.OP_CLEAR:
break;
case Operation.OP_REMOVE:
writer.Write(change.item);
break;
}
}
}
public override void OnDeserializeAll(NetworkReader reader)
{
// This list can now only be modified by synchronization
IsReadOnly = true;
// if init, write the full list content
int count = (int)reader.ReadUInt();
objects.Clear();
changes.Clear();
for (int i = 0; i < count; i++)
{
T obj = reader.Read<T>();
objects.Add(obj);
}
// We will need to skip all these changes
// the next time the list is synchronized
// because they have already been applied
changesAhead = (int)reader.ReadUInt();
}
public override void OnDeserializeDelta(NetworkReader reader)
{
// This list can now only be modified by synchronization
IsReadOnly = true;
int changesCount = (int)reader.ReadUInt();
for (int i = 0; i < changesCount; i++)
{
Operation operation = (Operation)reader.ReadByte();
// apply the operation only if it is a new change
// that we have not applied yet
bool apply = changesAhead == 0;
T item = default;
switch (operation)
{
case Operation.OP_ADD:
item = reader.Read<T>();
if (apply)
{
objects.Add(item);
}
break;
case Operation.OP_CLEAR:
if (apply)
{
objects.Clear();
}
break;
case Operation.OP_REMOVE:
item = reader.Read<T>();
if (apply)
{
objects.Remove(item);
}
break;
}
if (apply)
{
Callback?.Invoke(operation, item);
}
// we just skipped this change
else
{
changesAhead--;
}
}
}
public bool Add(T item)
{
if (objects.Add(item))
{
AddOperation(Operation.OP_ADD, item);
return true;
}
return false;
}
void ICollection<T>.Add(T item)
{
if (objects.Add(item))
{
AddOperation(Operation.OP_ADD, item);
}
}
public void Clear()
{
objects.Clear();
AddOperation(Operation.OP_CLEAR);
}
public bool Contains(T item) => objects.Contains(item);
public void CopyTo(T[] array, int index) => objects.CopyTo(array, index);
public bool Remove(T item)
{
if (objects.Remove(item))
{
AddOperation(Operation.OP_REMOVE, item);
return true;
}
return false;
}
public IEnumerator<T> GetEnumerator() => objects.GetEnumerator();
IEnumerator IEnumerable.GetEnumerator() => GetEnumerator();
public void ExceptWith(IEnumerable<T> other)
{
if (other == this)
{
Clear();
return;
}
// remove every element in other from this
foreach (T element in other)
{
Remove(element);
}
}
public void IntersectWith(IEnumerable<T> other)
{
if (other is ISet<T> otherSet)
{
IntersectWithSet(otherSet);
}
else
{
HashSet<T> otherAsSet = new HashSet<T>(other);
IntersectWithSet(otherAsSet);
}
}
void IntersectWithSet(ISet<T> otherSet)
{
List<T> elements = new List<T>(objects);
foreach (T element in elements)
{
if (!otherSet.Contains(element))
{
Remove(element);
}
}
}
public bool IsProperSubsetOf(IEnumerable<T> other) => objects.IsProperSubsetOf(other);
public bool IsProperSupersetOf(IEnumerable<T> other) => objects.IsProperSupersetOf(other);
public bool IsSubsetOf(IEnumerable<T> other) => objects.IsSubsetOf(other);
public bool IsSupersetOf(IEnumerable<T> other) => objects.IsSupersetOf(other);
public bool Overlaps(IEnumerable<T> other) => objects.Overlaps(other);
public bool SetEquals(IEnumerable<T> other) => objects.SetEquals(other);
// custom implementation so we can do our own Clear/Add/Remove for delta
public void SymmetricExceptWith(IEnumerable<T> other)
{
if (other == this)
{
Clear();
}
else
{
foreach (T element in other)
{
if (!Remove(element))
{
Add(element);
}
}
}
}
// custom implementation so we can do our own Clear/Add/Remove for delta
public void UnionWith(IEnumerable<T> other)
{
if (other != this)
{
foreach (T element in other)
{
Add(element);
}
}
}
}
public class SyncHashSet<T> : SyncSet<T>
{
public SyncHashSet() : this(EqualityComparer<T>.Default) {}
public SyncHashSet(IEqualityComparer<T> comparer) : base(new HashSet<T>(comparer ?? EqualityComparer<T>.Default)) {}
// allocation free enumerator
public new HashSet<T>.Enumerator GetEnumerator() => ((HashSet<T>)objects).GetEnumerator();
}
public class SyncSortedSet<T> : SyncSet<T>
{
public SyncSortedSet() : this(Comparer<T>.Default) {}
public SyncSortedSet(IComparer<T> comparer) : base(new SortedSet<T>(comparer ?? Comparer<T>.Default)) {}
// allocation free enumerator
public new SortedSet<T>.Enumerator GetEnumerator() => ((SortedSet<T>)objects).GetEnumerator();
}
}