Some completely unscientific benchmarking first:
All programmes have been compiled with the default optimisation level (-O3 for gcc, -O2 for GHC) and run with
time ./prog > outfile
As a baseline, the C programme took 1.07s to produce a ~76MB (78888897 bytes) file, roughly 70MB/s throughput.
- The "naive" Haskell programme (
forM [1 .. 10000000] $ \j -> putStrLn (show j)) took 8.64s, about 8.8MB/s.
- The same with
forM_ instead of
forM took 5.64s, about 13.5MB/s.
ByteString version from dflemstr's answer took 9.13s, about 8.3MB/s.
Text version from dflemstr's answer took 5.64s, about 13.5MB/s.
Vector version from the question took 5.54s, about 13.7MB/s.
main = mapM_ (C.putStrLn . C.pack . show) $ [1 :: Int .. 10000000], where
Data.ByteString.Char8, took 4.25s, about 17.9MB/s.
putStr . unlines . map show $ [1 :: Int .. 10000000] took 3.06s, about 24.8MB/s.
A manual loop,
main = putStr $ go 1
go :: Int -> String
| i > 10000000 = ""
| otherwise = shows i . showChar '\n' $ go (i+1)
took 2.32s, about 32.75MB/s.
main = putStrLn $ replicate 78888896 'a' took 1.15s, about 66MB/s.
main = C.putStrLn $ C.replicate 78888896 'a' where
Data.ByteString.Char8, took 0.143s, about 530MB/s, roughly the same figures for lazy
What can we learn from that?
First, don't use
mapM unless you really want to collect the results. Performancewise, that sucks.
ByteString output can be very fast (10.), but if the construction of the
ByteString to output is slow (3.), you end up with slower code than the naive
What's so terrible about 3.? Well, all the involved
Strings are very short. So you get a list of
Chunk "1234567" Empty
and between any two such, a
Chunk "\n" Empty is put, then the resulting list is concatenated, which means all these
Emptys are tossed away when a
... (Chunk "1234567" (Chunk "\n" (Chunk "1234568" (...)))) is built. That's a lot of wasteful construct-deconstruct-reconstruct going on. Speed comparable to that of the
Text and the fixed "naive"
String version can be achieved by
packing to strict
ByteStrings and using
Data.List.intersperse for the newlines). Better performance, slightly better than 6., can be obtained by eliminating the costly singletons. If you glue the newlines to the
\k -> shows k "\n" instead of
show, the concatenation has to deal with half as many slightly longer
ByteStrings, which pays off.
I'm not familiar enough with the internals of either text or vector to offer more than a semi-educated guess concerning the reasons for the observed performance, so I'll leave them out. Suffice it to say that the performance gain is marginal at best compared to the fixed naive
Now, 6. shows that
ByteString output is faster than
String output, enough that in this case the additional work of
packing is more than compensated. However, don't be fooled by that to believe that is always so. If the
Strings to pack are long, the packing can take more time than the
But ten million invocations of
putStrLn, be it the
String or the
ByteString version, take a lot of time. It's faster to grab the
Handle just once and construct the output
String in non-IO code.
unlines already does well, but we still suffer from the construction of the list
map show [1 .. 10^7]. Unfortunately, the compiler didn't manage to eliminate that (but it eliminated
[1 .. 10^7], that's already pretty good). So let's do it ourselves, leading to 8. That's not too terrible, but still takes more than twice as long as the C programme.
One can make a faster Haskell programme by going low-level and directly filling
ByteStrings without going through
show, but I don't know if the C speed is reachable. Anyway, that low-level code isn't very pretty, so I'll spare you what I have, but sometimes one has to get one's hands dirty if speed matters.