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I have this implementation of the sieve of Eratosthenes in Clojure:

(defn sieve [n]
  (loop [last-tried 2 sift (range 2 (inc n))]
      (or (nil? last-tried) (> last-tried n))
      (let [filtered (filter #(or (= % last-tried) (< 0 (rem % last-tried))) sift)]
        (let [next-to-try (first (filter #(> % last-tried) filtered))]
        (recur next-to-try filtered))))))

For larger n (like 20000) it ends with stack overflow. Why doesn't tail call elimination work here? How to fix it?

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As a side note, but this is not the sieve of Eratosthenes. SoE performs no remainder operations, just addition and "crossing out". See cs.hmc.edu/~oneill/papers/Sieve-JFP.pdf for an extended discussion (it's a great read!); for a beautiful "incremental" SoE implementation in Clojure by Christophe Grand, see clj-me.cgrand.net/2009/07/30/… (it's also the fastest version I've seen so far). –  Michał Marczyk Jun 5 '10 at 14:18
@Michał Marczyk thanks. I would say that "crossing out" is equivalent of "filtering", and "addition" in this algorithm is equivalent of "multiplication" and consequently "remainder". –  Konrad Garus Jun 5 '10 at 14:32
Not really. The result is, of course, the same, but the algorithmic complexity is wildly different. –  Michał Marczyk Jun 5 '10 at 14:33

3 Answers 3

up vote 10 down vote accepted

Problem: filter does lazy evaluation, so each new level of filtering hangs around on the call stack.

Fix: Change (filter ...) to (doall (filter ...)).

See the explanation here.

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If you look at the backtrace

 (sieve 200000)
 (catch java.lang.StackOverflowError e
  (.printStackTrace e)))

it looks like this:

at clojure.lang.LazySeq.sval(LazySeq.java:42)
at clojure.lang.LazySeq.seq(LazySeq.java:56)
at clojure.lang.RT.seq(RT.java:440)
at clojure.core$seq__4176.invoke(core.clj:103)
at clojure.core$filter__5033$fn__5035.invoke(core.clj:1751)
at clojure.lang.LazySeq.sval(LazySeq.java:42)
at clojure.lang.LazySeq.seq(LazySeq.java:56)

It's too many filters that's causing the overflow, not the loop.

Unfortunately, I don't see an obvious solution for this.

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The clue was in the LazySeq. Clojures implementation of Laziness has a few gotchas this being one of them. –  Jeremy Wall Jun 6 '10 at 4:40

I second Michal Marczyk's comment about checking out cgrande's beautiful incremental SoE. I did some really primitive benchmarks and put them up at http://clojure.roboloco.net/?p=100, for those curious about lazy prime generator performance.

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