As I said in a comment on the question, I believe the OP's approach is optimal. That's given the fully general problem in which the input is a seqable of arbitrary numbers.
However, if the requirement were added that the input should be a collection of longs (or doubles; other primitives are fine too, as long as we're not mixing integers with floating-point numbers), a loop
/ recur
based solution could be made to be significantly faster by taking advantage of primitive arithmetic:
(defn max-subarray-prim [xs]
(loop [xs (seq xs) here 0 so-far 0]
(if xs
(let [x (long (first xs))
new-here (max 0 (+ here x))]
(recur (next xs) new-here (max new-here so-far)))
so-far)))
This is actually quite readable to my eye, though I do prefer reduce
where there is no particular reason to use loop
/ recur
. The hope now is that loop
's ability to keep here
and so-far
unboxed throughout the loop's execution will make enough of a difference performance-wise.
To benchmark this, I generated a vector of 100000 random integers from the range -50000, ..., 49999:
(def xs (vec (repeatedly 100000 #(- (rand-int 100000) 50000))))
Sanity check (max-subarray-orig
refers to the OP's implementation):
(= (max-subarray-orig xs) (max-subarray-prim xs))
;= true
Criterium benchmarks:
(do (c/bench (max-subarray-orig xs))
(flush)
(c/bench (max-subarray-prim xs)))
WARNING: Final GC required 3.8238570080506156 % of runtime
Evaluation count : 11460 in 60 samples of 191 calls.
Execution time mean : 5.295551 ms
Execution time std-deviation : 97.329399 µs
Execution time lower quantile : 5.106146 ms ( 2.5%)
Execution time upper quantile : 5.456003 ms (97.5%)
Overhead used : 2.038603 ns
Evaluation count : 28560 in 60 samples of 476 calls.
Execution time mean : 2.121256 ms
Execution time std-deviation : 42.014943 µs
Execution time lower quantile : 2.045558 ms ( 2.5%)
Execution time upper quantile : 2.206587 ms (97.5%)
Overhead used : 2.038603 ns
Found 5 outliers in 60 samples (8.3333 %)
low-severe 1 (1.6667 %)
low-mild 4 (6.6667 %)
Variance from outliers : 7.8724 % Variance is slightly inflated by outliers
So that's a jump from ~5.29 ms to ~2.12 ms per call.
peek
in place oflast
,peek
being much more efficient with vectors (O(1) in contrast tolast
's O(n)) and equally clear to my eye in terms of intent; if you findlast
clearer, though, it's completely fine on a vector of size 2.