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5.2 KiB
Markdown
194 lines
No EOL
5.2 KiB
Markdown
---
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date: 2022-11-12 10:45:04-05:00
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draft: false
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math: true
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medium_enabled: true
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medium_post_id: edd1ef8ee314
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tags:
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- Scala
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- Functional Programming
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title: Corecursion, Unfold and Infinite Sequences
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---
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Recursion takes a large problem and breaks it down until it reaches some base cases. One popular example, is the factorial function.
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```scala
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def fact(x: Int): Int =
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if x == 0 then
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1
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else if x == 1 then
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1
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else
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x * fact(x - 1)
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```
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Though we can similarly arrive at the answer by starting at the base case `1` and multiplying until we reach `x`. This is called co-recursion.
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```
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1 * 2 * ... * x
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```
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`Unfold` allows us to create sequences given some initial state and a function that takes some state and produces a value for the sequence. For the factorial function, we want to keep track of in our state the last factorial computed and the current index. `(lastFact, currInd)`.
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Therefore, our initial state is `(1, 0)`.
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```scala
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val fact_seq = () => Iterator.unfold((1, 0))((x, y) => Some(
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x, // currFact
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(x * (y + 1), y + 1) // (nextFact, nextInd)
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))
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val fact = (x: Int) => fact_seq().take(x + 1).toList.last
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```
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Let's trace an execution of `fact(4)`.
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```
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fact(4)
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Iterator.unfold((1, 0))((x, y) => Some((x, (x * (y + 1), y + 1)))).take(5).toList.last
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States: (1, 0) -> (1, 1) -> (2, 2) -> (6, 3) -> (24, 4).....
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[1, 1, 2, 6, 24, ...].take(4).toList.last
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[1, 1, 2, 6, 24].last
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24
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```
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Now why is this useful when maybe the recursive version can seem cleaner? Co-recursion and in turn unfolding can help remove redundancies. Let's look at the Fibbonaci sequence for an example. The recursive version would be as follows:
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```scala
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def fib(n : Int): Int =
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if n == 0 then
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0
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else if n == 1 then
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1
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else
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fib(n - 1) + fib(n - 2)
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```
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Now let's trace through an execution of `fib(4)`
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```
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fib(4)
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fib(3) + fib(2)
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(fib(2) + fib(1)) + fib(2)
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((fib(1) + fib(0)) + fib(1)) + fib(2)
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((1 + fib(0)) + fib(1)) + fib(2)
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((1 + 0) + fib(1)) + fib(2)
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(1 + fib(1)) + fib(2)
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(1 + 1) + fib(2)
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2 + fib(2)
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2 + (fib(1) + fib(0))
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2 + (1 + fib(0))
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2 + (1 + 0)
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2 + 1
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3
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```
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Notice how there are many redundant calculations, for example `fib(2)` is evaluated twice separately in line 3 above.
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Now lets look at how `unfold` helps. For our state, we need to keep track of the last two evaluations. Therefore, we can represent our state as `(currentAnswer, nextAnswer)`.
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```scala
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val fib_seq = () => Iterator.unfold((0, 1))((x, y) => Some(x, (y, x + y)))
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val fib: (Int => Int) = (n) => fib_seq.take(n + 1).toList.last
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```
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Tracing through `fib(4)`
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```
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fib(4)
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Iterator.unfold((0, 1))((x, y) => Some(x,(y, x + y))).take(5).toList.last
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State: (0, 1) -> (1, 1) -> (1, 2) -> (2, 3) -> (3, 5)
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[0, 1, 1, 2, 3, ...].take(5).toList.last
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[0, 1, 1, 2, 3].last
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3
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```
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## Small Unfold Examples
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To get a better handle of `unfold`. Here are three examples:
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**(1) Build an iterator from start to infinity with a step size of `step`**
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Built-in way in Scala:
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```scala
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Iterator.from(start, step)
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```
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Using `unfold`
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```scala
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val fromStep: ((Int, Int) => Iterator[Int]) = (n, step) => Iterator.unfold(n)(x => Some((x, x + step)))
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```
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**(2) Build an infinite sequence of even numbers**
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Using from and map:
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```scala
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val evens = Iterator.from(0).filter(_ % 2 == 0)
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```
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Using `fromStep` in (1)
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```scala
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val evens = fromStep(0, 2)
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```
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Using `unfold`
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```scala
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val evens = Iterator.unfold(0)(x => Some((x, x + 2)))
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```
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**(3) Build a countdown from $n$ to $0$**
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Notice how the function within `unfold` needs to return an `Option`. If the returned option is `None` then the sequence is terminated.
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```scala
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val countdown = (n: Int) => Iterator.unfold(n)(x => if x == -1 then None else Some((x, x - 1)))
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```
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**(4) Repeat an element forever**
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For this example, we don't need to carry any state throughout hte computation.
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```scala
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val repeat: (Int => Iterator[Int]) = (n) => Iterator.unfold(None)(_ => Some(n, None))
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```
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## Recursive Sequences
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In the past, [I've written](/blog/haskellrealsequences/) about analyzing sequences from real analysis within Haskell. Within it, I was looking at the following sequence:
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$$
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f(1) = 1, f(2) = 2, f(n) = \frac{1}{2}(f(n - 2) + f(n - 1))
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$$
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The technique I described in that post is to build out the function `f` and then map it to the natural numbers. In Scala that would look like:
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```scala
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val f: (Int => Double) = n => if n == 1 then 1.0 else if n == 2 then 2.0 else 0.5 * (f(n - 2) + f(n - 1))
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val f_sequence = Iterator.from(1).map(f)
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```
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However as mentioned in prior in this post, this methodology is suboptimal since there will be many repeated computations.
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Corecursion and unfold comes to the rescue again. For recursive sequences, we can make the state the base cases `(1.0, 2.0)`.
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```scala
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val f_sequence = () => Iterator.unfold((1.0, 2.0))((x1, x2) => Some(
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x1,
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(x2, 0.5 * (x1 + x2))
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))
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```
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We can get a good guess at where this sequence converges by looking at the $100^{th}$ element.
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```scala
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f_sequence().take(100).toList.last
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// 1.6666666666666665
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```
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If you want to learn more about unfold or see a different take, then the following two blog posts helped me craft this one:
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https://blog.genuine.com/2020/07/scala-unfold/
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https://john.cs.olemiss.edu/~hcc/csci555/notes/FPS05/Laziness.html |