# Best practice for shifting a sequence in a circular manner

I have to implement a kind of an array or sequence or list, which supports the cheapest way of circulated forwarding and back winding of elements. See this example:

``````Original sequence: 1 2 3 4 5

Forwarded once: 5 1 2 3 4
Forwarded twice: 4 5 1 2 3
``````

Same but opposite is for the back winding. What would be the cheapest and most Scala-style way of implementing this? In Java I could use LinkedList and it would do great... However, I could not find any definite answer for Scala.

Also, it also has to be easy to replace any given element by index, as in LinkedList.

UPDATE:

For the fastest, but not-so-idiomatic variant of algorithm (you know when you need it), refer to the answer of Petr Pudlák!!!

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this migth be usefull for you –  om-nom-nom Jan 16 '12 at 7:13
I think "barrel shifting" might be a more technical way to express your intent than "circulating"... –  fortran Jan 16 '12 at 9:47
@fortran I only know this term from the logic circuit. Thus it's a particular implementation. You're sure this applies to the operation of shifting? –  ziggystar Jan 16 '12 at 9:50
@ziggystar I think you are right, I might have confused the HW term for the circular shifting... Anyway, the verb should be shift, not circulate (that is what I found weird in the title). Cheers. –  fortran Jan 16 '12 at 9:58

A ring buffer is a pair of an `IndexedSeq` and an `Int` pointer into this sequence. I provide code for a immutable version. Note that not all methods that might be useful are implemented; like the mutators that change the content of the `IndexedSeq`.

With this implementation, shifting is just creating one new object. So it's pretty efficient.

### Example code

``````class RingBuffer[A](val index: Int, val data: IndexedSeq[A]) extends IndexedSeq[A] {
def shiftLeft = new RingBuffer((index + 1) % data.size, data)
def shiftRight = new RingBuffer((index + data.size - 1) % data.size, data)
def length = data.length
def apply(i: Int) = data((index + i) % data.size)
}

val rb = new RingBuffer(0, IndexedSeq(2,3,5,7,11))

println("plain: " + rb)
println("sl: " + rb.shiftLeft)
println("sr: " + rb.shiftRight)
``````

### Output

``````plain: Main(2, 3, 5, 7, 11)
sl: Main(3, 5, 7, 11, 2)
sr: Main(11, 2, 3, 5, 7)
``````
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Anyone knowing why the `println` shows the data structure as `Main`? I've run it as a script using the `scala` command. –  ziggystar Jan 16 '12 at 9:47
Method `stringPrefix` from `TraversableLike` defines prefix of collection as substring of class name between last `.` and first `\$`. I can't check now, but I think because of `scala` command class loading magic your class receives a name like `Main\$object\$\$iw\$\$iw\$RingBuffer` which gives prefix `Main`. Try this in REPL: `settings.unwrapStrings = false; class Foo; println(new Foo);` –  incrop Jan 16 '12 at 13:04
What version of scala are you using? In 2.9.0.1 in the REPL it prints as `plain: (2, 3, 5, 7, 11)`. You can get the correct prefix with `override def stringPrefix = "RingBuffer"`. –  Luigi Plinge Jan 16 '12 at 19:23
This is really cool because `data` is only needed exactly once in memory, all of the `RingBuffer`s can share the one copy (assuming immutability). –  Dan Burton Jan 16 '12 at 19:37
``````scala> val l = List(1,2,3,4,5)
l: List[Int] = List(1, 2, 3, 4, 5)

scala> val reorderings = Stream.continually(l.reverse).flatten.sliding(l.size).map(_.reverse)
reorderings: Iterator[scala.collection.immutable.Stream[Int]] = non-empty iterator

scala> reorderings.take(5).foreach(x => println(x.toList))
List(1, 2, 3, 4, 5)
List(5, 1, 2, 3, 4)
List(4, 5, 1, 2, 3)
List(3, 4, 5, 1, 2)
List(2, 3, 4, 5, 1)
``````
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Nice idea! Functional. Efficient? –  Peter Schmitz Jan 16 '12 at 11:35
I find the type of `reorderings` weird. An `Iterator` of `Stream`s? –  notan3xit Jan 16 '12 at 11:52

The way I solve Scala problems is solving them in Haskell first, and then translating. :)

``````reorderings xs = take len . map (take len) . tails . cycle \$ xs
where len = length xs
``````

This is the easiest way I could think of, which produces the list of all possible shifts, by "shifting left" repeatedly.

``````ghci> reorderings [1..5]
[[1,2,3,4,5],[2,3,4,5,1],[3,4,5,1,2],[4,5,1,2,3],[5,1,2,3,4]]
``````

The concept is relatively simple (for those comfortable with functional programming, that is). First, `cycle` the original list, producing an infinite stream from which to draw from. Next, break that stream into a stream of streams, where each subsequent stream has dropped the first element of the previous stream (`tails`). Next, limit each substream to the length of the original list (`map (take len)`). Finally, limit the stream of streams to the length of the original list, since there are only `len` possible reorderings (`take len`).

So let's do that in Scala now.

``````def reorderings[A](xs: List[A]):List[List[A]] = {
val len = xs.length
Stream.continually(xs).flatten // cycle
.tails
.map(_.take(len).toList)
.take(len)
.toList
}
``````

We just had to use a small workaround for `cycle` (not sure if Scala standard libs provide cycle, though I was pleasantly surprised to find they provide `tails`), and a few `toList`s (Haskell lists are lazy streams, while Scala's are strict), but other than that, it's exactly the same as the Haskell, and as far as I can tell, behaves exactly the same. You can almost think of Scala's `.` as behaving like Haskell's, except flowing the opposite way.

Also note this is very nearly the same as dhg's solution, except without the reverses, which (on the upside) makes it more efficient, but (on the downside) provides the cycles in "backwinding" order, rather than "forward" order.

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An interesting thought! Frankly speaking, I am trying to master FP now and my initial choices of languages to learn were Scala and Haskell and eventually, Clojure. What I know of Haskell so far also made me think that it is a good practice - to formulate a solution in it and then translate to Scala))) But I am yet far from being perfect in FP, so thanks for mentioning that parallel with an example. That will make me more conscious of it! –  noncom Jan 18 '12 at 8:14

I needed such an operation myself, here it is. Method `rotate` rotates the given indexed sequence (array) to the right (negative values shift to the left). The process is in-place, so no additional memory is required and the original array is modified.

It's not Scala-specific or functional at all, it's meant to be very fast.

``````import annotation.tailrec;
import scala.collection.mutable.IndexedSeq

// ...

@tailrec
def gcd(a: Int, b: Int): Int =
if (b == 0) a
else gcd(b, a % b);

@inline
def swap[A](a: IndexedSeq[A], idx: Int, value: A): A = {
val x = a(idx);
a(idx) = value;
return x;
}

/**
* Time complexity: O(a.size).
* Memory complexity: O(1).
*/
def rotate[A](a: IndexedSeq[A], shift: Int): Unit =
rotate(a, 0, a.size, shift);
def rotate[A](a: IndexedSeq[A], start: Int, end: Int, shift: Int): Unit = {
val len = end - start;
if (len == 0)
return;

var s = shift % len;
if (shift == 0)
return;
if (s < 0)
s = len + s;

val c = gcd(len, s);
var i = 0;
while (i < c) {
var k = i;
var x = a(start + len - s + k);
do {
x = swap(a, start + k, x);
k = (k + s) % len;
} while (k != i);
i = i + 1;
}
return;
}
``````
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Very nice, could come very handly at known places! Thank you :) –  noncom Apr 14 '13 at 18:41