The problem involves the Scala PriorityQueue[Array[Int]] performance on large data set. The following operations are needed: enqueue, dequeue, and filter. Currently, my implementation is as follows:

For every element of type Array[Int], there is a complex evaluation function: (I'm not sure how to write it in a more efficient way, because it excludes the position 0)

```
def eval_fun(a : Array[Int]) =
if(a.size < 2) 3
else {
var ret = 0
var i = 1
while(i < a.size) {
if((a(i) & 0x3) == 1) ret += 1
else if((a(i) & 0x3) == 3) ret += 3
i += 1
}
ret / a.size
}
```

The ordering with a comparison function is based on the evaluation function: (*Reversed*, descendent order)

```
val arr_ord = new Ordering[Array[Int]] {
def compare(a : Array[Int], b : Array[Int]) = eval_fun(b) compare eval_fun(a) }
```

The PriorityQueue is defined as:

```
val pq: scala.collection.mutable.PriorityQueue[Array[Int]] = PriorityQueue()
```

Question:

- Is there a more elegant and efficient way to write such a evaluation function? I'm thinking of using fold, but fold cannot exclude the position 0.
- Is there a data structure to generate a priorityqueue with
**unique**elements? Applying filter operation after each enqueue operation is*not*efficient. - Is there a cache method to reduce the evaluation computation? Since when adding a new element to the queue, every element may need to be evaluated by eval_fun again, which is not necessary if evaluated value of every element can be cached. Also, I should mention that two distinct element may have the same evaluated value.
- Is there a more efficient data structure
*without*using generic type? Because if the size of elements reaches 10,000 and the size of size reaches 1,000, the performance is terribly slow.

Thanks you.