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I just started learning Clojure. One of the first things I noticed is that there are no loops. That's OK, I can recur. So let's look at this function (from Practical Clojure):

(defn add-up
  "Adds up numbers from 1 to n"
  ([n] (add-up n 0 0))
  ([n i sum] 
    (if (< n i)
      sum
      (recur n (+ 1 i) (+ i sum)))))

To achieve the same function in Javascript, we use a loop like so:

function addup (n) {
  var sum = 0;
  for(var i = n; i > 0; i--) {
    sum += i;
  }
  return sum;
}

When timed, the results look like:

input size: 10,000,000
clojure: 818 ms
nodejs: 160 ms

input size: 55,000,000
clojure: 4051 ms
nodejs: 754 ms

input size: 100,000,000
clojure: 7390 ms
nodejs: 1351 ms

I then proceeded to try the classic fib (after reading this):

in clojure:

(defn fib
  "Fib"
  [n]
  (if (<= n 1) 1
      (+ (fib (- n 1)) (fib (- n 2)))))

in js:

function fib (n) {
  if (n <= 1) return 1;
  return fib(n-1) + fib(n-2);
}

Again, the performance has quite some difference.

fib of 39
clojure: 9092 ms
nodejs: 3484 ms

fib of 40
clojure: 14728 ms
nodejs: 5615 ms

fib of 41
clojure: 23611 ms
nodejs: 9079 ms

Note I'm using (time (fib 40)) in clojure so it's ignoring the bootup time for JVM. These are ran on a MacBook Air (1.86 Ghz Intel Core 2 Duo).

So what's causing Clojure to be slow here? And why do people say that "Clojure is fast"?

Thanks in advance and Please, no flame wars.

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10  
That's an awful way to compute Fibonacci numbers in any language :-) –  Pointy Jun 2 '11 at 15:53
2  
Hehe. True. Just for the sake of comparison. –  esjd Jun 2 '11 at 16:07
1  
I think I gave a pretty definitive answer, any reason to not mark it as so? –  dnolen Jun 3 '11 at 3:11
    
Yep! You got it, dnolen. Thanks a lot :) –  esjd Jun 3 '11 at 16:27

7 Answers 7

up vote 39 down vote accepted
(set! *unchecked-math* true)

(defn add-up ^long [^long n]
  (loop [n n i 0 sum 0]
    (if (< n i)
      sum
      (recur n (inc i) (+ i sum)))))

(defn fib ^long [^long n]
  (if (<= n 1) 1
      (+ (fib (dec n)) (fib (- n 2)))))

(comment
  ;; ~130ms
  (dotimes [_ 10]
    (time
     (add-up 1e8)))

  ;; ~1180ms
  (dotimes [_ 10]
    (time
     (fib 41)))
  )

All numbers from 2.66ghz i7 Macbook Pro OS X 10.7 JDK 7 64bit

As you can see Node.js is trounced. This is with 1.3.0 alphas, but you can achieve the same thing in 1.2.0 if you know what you're doing.

On my machine Node.js 0.4.8 for addup 1e8 was ~990ms, for fib 41 ~7600ms.

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2  
I don't understand your result times ... –  jcolebrand Jun 2 '11 at 17:45
    
Did you benchmark node.js on your machine? –  Raynos Jun 2 '11 at 17:47
    
@Raynos: updated w/ Node.js times on my machine. –  dnolen Jun 2 '11 at 18:06
6  
Mind listing the times like the OP does? –  DTrejo Jun 2 '11 at 18:14
    
@DTrejo: why? for both addup and fib you see the pretty much the exact same rate of change in Clojure and Node.js for the change in input size –  dnolen Jun 2 '11 at 18:22

I'd actually expect Clojure to be significantly faster than Javascript if you optimise your code for performance.

Clojure will statically compile to fairly optimised Java bytecode whenever you give enough static type information (i.e. type hints or casts to primitive types). So in theory at least, you ought to be able to get pretty close to pure Java speed, which is itself pretty close to native code performance.

So let's prove it!

In this case, you have several issues that are causing the Clojure code to run slow:

  • Clojure supports arbitrary-precision arithmetic by default, so any arithmetic operations are automatically checked for overflow and if necessary numbers are promoted to BigIntegers etc. This extra checking adds a small amount of overhead which is usually negligible, but can show up if you run arithmetic operations in a tight loop like this. The easy way to fix this in Clojure 1.2 is to use the unchecked-* functions (this is a bit inelegant, but will be much improved in Clojure 1.3)
  • Unless you tell it otherwise, Clojure behaves dynamically and boxes function arguments. Hence I suspect your code is creating and boxing a lot of Integers/Longs. The way to remove this for your loop variables is to use primitive type hints and use constructs like loop/recur.
  • Likewise, the n is boxed, which means that the <= function call cannot be optimised to use primitive arithmetic. You can avoid this by casting n into a long primitive with a local let.
  • (time (some-function)) is also an unreliable way to benchmark in Clojure because it won't necessarily allow JIT compilation optimisations to kick in. You often need to run (some-function) a few times first so that the JIT has a chance to do its work.

My suggestion for the optimised Clojure version of add-up would therefore be something more like:

(defn add-up
  "Adds up numbers from 1 to n"
  [n]
  (let [n2 (long n)]                                    ; unbox loop limit
    (loop [i (long 1)                                   ; use "loop" for primitives
          acc (long 0)]                                 ; cast to primitive
      (if (<= i n2)                                     ; use unboxed loop limit
        (recur (unchecked-inc i) (unchecked-add acc i)) ; use unchecked maths
        acc))))

And a better way to time it is as follows (to allow JIT compilation to happen):

(defn f [] (add-up 10000000))
(do 
  (dotimes [i 10] (f)) 
  (time (f)))

If I do the above, I get 6 ms for the Clojure solution in Clojure 1.2. Which is something like 15-20x faster than the Node.js code and maybe 80-100x faster than your original Clojure version.

Incidentally, this is also about as fast as I can get this loop to go in pure Java so I doubt that it would be possible to improve this much in any JVM language. It also puts us at about 2 machine cycles per iteration... so it's probably not far from native machine code speed either!

(sorry not able to benchmark against Node.js on my machine, but it's a 3.3 GHz core i7 980X for anyone interested)

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A high-level comment. Node.js and Clojure have completely different models for attaining scalability and eventually making software run fast.

Clojure achieves scalability through multi-core parallelism. If you build your Clojure programs correctly, you can divvy up your computational work (via pmap, etc.) to ultimately run in parallel on separate cores.

Node.js is not parallel. Rather its key insight is that scalability (usually in a web application environment) is I/O bound. So Node.js and Google V8 technology attain scalability via many asynchronous I/O callbacks.

Theoretically, I would expect Clojure to beat Node.js in areas easily parallelizable. Fibonacci would fall in this category and would beat Node.js if given enough cores. And Node.js would be better for server-side applications that make many requests to the file system or network.

In conclusion, I do not think this may be a very good benchmark for comparing Clojure versus Node.js.

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17  
In my experience Clojure + Evented I/O (via say Netty) is just as fast or faster than Node.js. Node.js has no purely technical merit IMHO - it's just a matter of taste - more people know JS, so they'd rather write their server in JS. –  dnolen Jun 2 '11 at 19:10

Couple of hints, assuming you're using clojure 1.2

  • repeating the (time ...) tests is likely to gain higher speeds in clojure, because of JIT optimizations kicking in.
  • (inc i) is - a little - faster than (+ i 1)
  • the unchecked-* functions are also faster (sometimes MUCH faster) than their checked variants. Assuming you don't need to exceed the limit of longs or doubles, using unchecked-add, unchecked-int etc could be a lot faster.
  • read up on type declarations; in some cases, they can also improve speed substantially.

Clojure 1.3 is generally faster with numerics than 1.2, but it's still under development.

The following is about 20 times faster than your version, and it can still be improved by modifying the algorithm (counting down, like the js version does, instead of up saves a binding).

(defn add-up-faster
  "Adds up numbers from 1 to n"
  ([n] (add-up-faster n 0 0))
  ([^long n ^long i ^long sum] 
    (if (< n i)
      sum
      (recur n (unchecked-inc i) (unchecked-add i sum)))))
share|improve this answer
    
I find call the unchecked variants less elegant then setting the unchecked-math flag around the critical loops. –  dnolen Jun 2 '11 at 16:19
    
@dnolen: I agree, but it does sort of help indicate the critical sections, and in this case, I think it shows more clearly what's going on "under the hood". By the way, isn't unchecked-math the default in the latest 1.3 alphas? –  Joost Diepenmaat Jun 2 '11 at 16:23
1  
No unchecked-math means no error on overflow. By default in 1.3.0 primitives flow through arithmetic operations, but if they overflow you'll hit a hard error - a good thing. Using unchecked-math gives a 8-10% speed boost for loss of safety. –  dnolen Jun 2 '11 at 16:33
    
@dnolen - agree with all you say apart from that "loss of safety" is somewhat dependent on your point of view - if you recognise that you are dealing with 64-bit signed integers then unchecked long maths is perfectly "safe", it's just maths defined on a set that is different from the mathematical definition of integers. You're effectively just doing all your maths in modulo arithmetic..... –  mikera Jun 2 '11 at 18:54

Not directly related to optimization problem at hand but your Fib can be easily sped up:

(defn fib
  "Fib"
  [n]
  (if (<= n 1) 1
      (+ (fib (- n 1)) (fib (- n 2)))))

change to:

(def fib (memoize (fn
  [n]
  (if (<= n 1) 1
      (+ (fib (- n 1)) (fib (- n 2)))))))

Works much faster (from 13000 ms for fib 38 on core i5 - why is my computer slower than dualcores? - to 0.2 ms). In essence it isn't much different than an iterative solution - though it does allow you to express the problem in a recursive fashion for the price of some memory.

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This is a more appropriate node.js way to handle this:

Number.prototype.triangle = function() {
    return this * (this + 1) /2;
}

var start = new Date();
var result = 100000000 .triangle();
var elapsed = new Date() - start;
console.log('Answer is', result, ' in ', elapsed, 'ms');

yielding:

$ node triangle.js
Answer is 5000000050000000  in  0 ms
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2  
zero? damn! Will node.js make my CPU infinite speed, too? –  gtrak Nov 1 '13 at 17:58

Playing around, you can get some pretty good performance for fib as well using something like the below:

(defn fib [^long n]
  (if (< n 2) 
   n
   (loop [i 2 l '(1 1)]
   (if (= i n)
    (first l)
     (recur 
      (inc i) 
      (cons 
       (+' (first l) (second l)) 
        l))))))


(dotimes [_ 10]
 (time
  (fib 51)))
; on old MB air, late 2010
; "Elapsed time: 0.010661 msecs"
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