def fibSeq(n: Int): List[Int] = {
var ret = scala.collection.mutable.ListBuffer[Int](1, 2)
while (ret(ret.length - 1) < n) {
val temp = ret(ret.length - 1) + ret(ret.length - 2)
if (temp >= n) {
return ret.toList
}
ret += temp
}
ret.toList
}
So the above is my code to generate a Fibonacci sequence using Scala to a value n. I am wondering if there is a more elegant way to do this in Scala?
This is a bit more elegant:
val fibs: Stream[Int] = 0 #:: fibs.scanLeft(1)(_ + _)
With Streams you "take" a number of values, which you can then turn into a List:
scala> fibs take 10 toList
res42: List[Int] = List(0, 1, 1, 2, 3, 5, 8, 13, 21, 34)
Update: I've written a blog post which goes more detail regarding how this solution works, and why you end up with a Fibonacci sequence!
lazy keyword.
Apr 2, 2013 at 3:09
object or in the REPL, you don't. If it's within a method then you do need the lazy.
Apr 2, 2013 at 4:57
There are many ways to define the Fibonacci sequence, but my favorite is this one:
val fibs:Stream[Int] = 0 #:: 1 #:: (fibs zip fibs.tail).map{ t => t._1 + t._2 }
This creates a stream that is evaluated lazily when you want a specific Fibonacci number.
EDIT: First, as Luigi Plinge pointed out, the "lazy" at the beginning was unnecessary. Second, go look at his answer, he pretty much did the same thing only more elegantly.
(foo zip bar).map{ t => f(t._1, t._2) }. In Haskell it would be zipWith f foo bar, and in Racket, (map f foo bar)
Mar 26, 2012 at 3:48
(foo zip bar) map f if f expects a tuple and (foo zip bar) map f.tupled if f expects two parameters.
Mar 26, 2012 at 14:12
lazy val if it's defined as a local variable rather than an an object/class field. Because when it's a field the compiler translates fibs to this.fibs, so you can get away without the lazy. Meh. Probably best to keep it in for consistency.
Apr 16, 2012 at 17:55
Not as elegant as Streams, not lazy, but tailrecursive and handles BigInt (which is easy to do with Luigis scanLeft too, but not so with Tal's zip - maybe just for me).
@tailrec
def fib (cnt: Int, low: BigInt=0, high: BigInt=1, sofar: List[BigInt]=Nil): List[BigInt] = {
if (cnt == 0) (low :: sofar).reverse else fib (cnt - 1, high, low + high, low :: sofar) }
scala> fib (75)
res135: List[BigInt] = List(0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55, 89, 144, 233, 377, 610, 987, 1597, 2584, 4181, 6765, 10946, 17711, 28657, 46368, 75025, 121393, 196418, 317811, 514229, 832040, 1346269, 2178309, 3524578, 5702887, 9227465, 14930352, 24157817, 39088169, 63245986, 102334155, 165580141, 267914296, 433494437, 701408733, 1134903170, 1836311903, 2971215073, 4807526976, 7778742049, 12586269025, 20365011074, 32951280099, 53316291173, 86267571272, 139583862445, 225851433717, 365435296162, 591286729879, 956722026041, 1548008755920, 2504730781961, 4052739537881, 6557470319842, 10610209857723, 17167680177565, 27777890035288, 44945570212853, 72723460248141, 117669030460994, 190392490709135, 308061521170129, 498454011879264, 806515533049393, 1304969544928657, 2111485077978050)
def fib(n: Int, s: List[BigInt] = List(1, 0)): List[BigInt] = if (n <= 2) s.reverse else fib(n - 1, s(0) + s(1) :: s)
Mar 26, 2012 at 12:06
[Int] on the left hand side to [BigInt]! The Int literals on the right are implicitly converted.
Mar 29, 2012 at 3:57
My favorite version is:
def fibs(a: Int = 0, b: Int = 1): Stream[Int] = Stream.cons(a, fibs(b, a+b))
With the default values you can just call fibs() and get the infinite Stream.
I also think it's highly readable despite being a one liner.
If you just want the first n then you can use take like fibs() take n, and if you need it as a list fibs() take n toList.
Here's yet another approach again using *Stream*s on an intermediary tuples:
scala> val fibs = Stream.iterate( (0,1) ) { case (a,b)=>(b,a+b) }.map(_._1)
fibs: scala.collection.immutable.Stream[Int] = Stream(0, ?)
scala> fibs take 10 toList
res68: List[Int] = List(0, 1, 1, 2, 3, 5, 8, 13, 21, 34)
I find this implementation to be more legible:
def fibonacci: Stream[Int] = {
def loop(a: Int, b: Int): Stream[Int] = (a + b) #:: loop(b, b + a)
loop(0, 1)
}
def fib:Stream[Int] ={
def go(f0: Int, f1:Int): Stream[Int] = {
Stream.cons(f0,go(f1,f0+f1))
}
go(0,1)
}
