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One of the promises of side-effect free, referentially transparent functional programming is that such code can be extensively optimized. To quote Wikipedia:

Immutability of data can, in many cases, lead to execution efficiency, by allowing the compiler to make assumptions that are unsafe in an imperative language, thus increasi*emphasized text*ng opportunities for inline expansion.

I'd like to see examples where a functional language compiler outperforms an imperative one by producing a better optimized code.

Edit: I tried to give a specific scenario, but apparently it wasn't a good idea. So I'll try to explain it in a different way.

Programmers translate ideas (algorithms) into languages that machines can understand. At the same time, one of the most important aspects of the translation is that also humans can understand the resulting code. Unfortunately, in many cases there is a trade-off: A concise, readable code suffers from slow performance and needs to be manually optimized. This is error-prone, time consuming, and it makes the code less readable (up to totally unreadable).

The foundations of functional languages, such as immutability and referential transparency, allow compilers to perform extensive optimizations, which could replace manual optimization of code and free programmers from this trade-off. I'm looking for examples of ideas (algorithms) and their implementations, such that:

  1. the (functional) implementation is close to the original idea and is easy to understand,
  2. it is extensively optimized by the compiler of the language, and
  3. it is hard (or impossible) to write similarly efficient code in an imperative language without manual optimizations that reduce its conciseness and readability.

I apologize if it is a bit vague, but I hope the idea is clear. I don't want to give unnecessary restrictions on the answers. I'm open to suggestions if someone knows how to express it better.

My interest isn't just theoretical. I'd like to use such examples (among other things) to motivate students to get interested in functional programming.

At first, I wasn't satisfied by a few examples suggested in the comments. On second thoughts I take my objections back, those are good examples. Please feel free to expand them to full answers so that people can comment and vote for them.


(One class of such examples will be most likely parallelized code, which can take advantage of multiple CPU cores. Often in functional languages this can be done easily without sacrificing code simplicity (like in Haskell by adding par or pseq in appropriate places). I' be interested in such examples too, but also in other, non-parallel ones.)

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You might be interested in Neil Mitchell's paper on super compilation. –  Thomas M. DuBuisson Jan 16 '13 at 12:16
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Ref.trans. and lazy optimize (from O(n log n) to O(n)) function min = head . sort –  josejuan Jan 16 '13 at 12:18
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A great question and people vote to close it. What the hell is wrong with this world?! –  Nikita Volkov Jan 16 '13 at 14:39
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@NikitaVolkov it should be closed because 1) the premise "suppose we have an algorithm A and implement it in an imperative language such as C/C++/Java and also in a functional language such as Haskell" is nonsensical, and 2) it's not clear what would actually qualify as an example; if non-sensical algorithm A runs faster in C++ but less fast in Java, does that count? What about my homegrown brainfuck compiler that I wrote in whitespace? –  jberryman Jan 16 '13 at 15:53
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@NikitaVolkov as Don suggests, you're not going to be comparing the same algorithm. For instance quicksort is an imperative algorithm for sorting "in-place". You could implement that in haskell, but you wouldn't be learning anything about referential transparency and efficiency. Or you could implement the usual sort-of-analogous functional flavor of quicksort and compare the two, but then you'd learn nothing because the algorithms really are completely different semantically. –  jberryman Jan 16 '13 at 17:42
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4 Answers

There are cases where the same algorithm will optimize better in a pure context. Specifically, stream fusion allows an algorithm that consists of a sequence of loops that may be of widely varying form: maps, filters, folds, unfolds, to be composed into a single loop.

The equivalent optimization in a conventional imperative setting, with mutable data in loops, would have to achieve a full effect analysis, which no one does.

So at least for the class of algorithms that are implemented as pipelines of ana- and catamorphisms on sequences, you can guarantee optimization results that are not possible in an imperative setting.

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What about memoization? I believe there are plenty of opportunities to utilize that in pure code. –  Nikita Volkov Jan 16 '13 at 14:41
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@NikitaVolkov: Memoization is easy to add, the difficult part is deciding when it will actually help instead of just wasting lots of memory. –  C. A. McCann Jan 16 '13 at 16:38
    
@C.A.McCann You have to admit that "lots" is quite a questionable measure, especially with the amounts of available memory these days. Anyway, so does it imply that there are no memoization-based optimizations nor plans to implement any in GHC? Just curious. –  Nikita Volkov Jan 16 '13 at 17:12
    
@NikitaVolkov, automatic memoization optimizations are hard to get right because you don't know where it is helpful to put them -- but Haskell programmers readily whip out a memoization library when one is needed, and then type memo somewhere in their code. Feels more like a "user-directed optimization" than coding to me (obviously you do have to understand the problem and Haskell's evaluation model to know where to put it though). –  luqui Jan 16 '13 at 18:52
    
This sorta begs the question of whether the two are the "same algorithm." The expressions look superficially similar, but they are certainly not doing anywhere close to the same thing to the data. –  tmyklebu Jan 17 '13 at 4:55
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A very recent paper Haskell beats C using generalised stream fusion by Geoff Mainland, Simon Peyton Jones, Simon Marlow, Roman Leshchinskiy (submitted to ICFP 2013) describes such an example. Abstract (with the interesting part in bold):

Stream fusion [6] is a powerful technique for automatically transforming high-level sequence-processing functions into efficient implementations. It has been used to great effect in Haskell libraries for manipulating byte arrays, Unicode text, and unboxed vectors. However, some operations, like vector append, still do not perform well within the standard stream fusion framework. Others, like SIMD computation using the SSE and AVX instructions available on modern x86 chips, do not seem to fit in the framework at all.

In this paper we introduce generalized stream fusion, which solves these issues. The key insight is to bundle together multiple stream representations, each tuned for a particular class of stream consumer. We also describe a stream representation suited for efficient computation with SSE instructions. Our ideas are implemented in modified versions of the GHC compiler and vector library. Benchmarks show that high-level Haskell code written using our compiler and libraries can produce code that is faster than both compiler- and hand-vectorized C.

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This is just a note, not an answer: the gcc has a pure attribute suggesting it can take account of purity; the obvious reasons are remarked on in the manual here.

I would think that 'static single assignment' imposes a form of purity -- see the links at http://lambda-the-ultimate.org/node/2860 or the wikipedia article.

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make and various build systems perform better for large projects by assuming that various build steps are referentially transparent; as such, they only need to rerun steps that have had their inputs change.

For small to medium sized changes, this can be a lot faster than building from scratch.

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While this is a good example in general, I'd say it doesn't give an answer to my question Examples where compiler-optimized functional code performs better than imperative code. –  Petr Pudlák Jan 30 '13 at 21:29
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