Difference between revisions of "Performance/Strings"
DonStewart (talk | contribs) (Use fps if your strings are 1G or bigger) |
(Change Data.FastPackedString do Data.ByteString) |
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{{Performance infobox}} |
{{Performance infobox}} |
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| + | [[Category:Performance|Strings]] |
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==Strings== |
==Strings== |
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number of options: |
number of options: |
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| ⚫ | |||
| − | * The standard Data.PackedString type |
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| ⚫ | |||
* Unboxed arrays of Word8 or Char |
* Unboxed arrays of Word8 or Char |
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* Ptrs to foreign malloced Word8 buffers |
* Ptrs to foreign malloced Word8 buffers |
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| Line 14: | Line 14: | ||
Char types, in that they provide the usual list-like operations. |
Char types, in that they provide the usual list-like operations. |
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| − | Some interesting results for |
+ | Some interesting results for Data.ByteString are documented |
[http://www.cse.unsw.edu.au/~dons/code/fps/README here]. In particular, |
[http://www.cse.unsw.edu.au/~dons/code/fps/README here]. In particular, |
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it compares FPS against the existing PackedString and [Char] functions, |
it compares FPS against the existing PackedString and [Char] functions, |
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| − | and is used successfully with 1 |
+ | and is used successfully with 1 terabyte strings. |
==Example== |
==Example== |
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completes in a fairly quick 0.2s. Still, we can do better. |
completes in a fairly quick 0.2s. Still, we can do better. |
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| − | === Attempt 2 : |
+ | === Attempt 2 : Data.ByteString === |
| − | Using [http://www.cse.unsw.edu.au/~dons/fps.html |
+ | Using [http://www.cse.unsw.edu.au/~dons/fps.html ByteString], we get: |
<haskell> |
<haskell> |
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| − | import qualified Data. |
+ | import qualified Data.ByteString as B |
import IO |
import IO |
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| − | main = |
+ | main = B.readFile "/usr/share/dict/words" >>= B.putStr . last . B.lines |
</haskell> |
</haskell> |
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<haskell> |
<haskell> |
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| − | import qualified Data. |
+ | import qualified Data.ByteString as P |
| + | import Maybe |
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import IO |
import IO |
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| − | main = |
+ | main = P.readFile "/usr/share/dict/words" >>= P.putStrLn . snd . fromJust . P.breakLast '\n' |
| − | putChar '\n' |
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</haskell> |
</haskell> |
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Runs in 0.013s |
Runs in 0.013s |
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| + | |||
| + | === Related work === |
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| + | |||
| + | An extended tutorial on using PackedStrings/ByteStrings for high performance string manipulating code is [[Wc|here]]. |
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| + | |||
| + | [http://groups.google.com/group/fa.haskell/browse_thread/thread/4133fa71ce97eb0e/fef34d1c3943bbe0#fef34d1c3943bbe0 A discussion] of the fastest way to parse a file of numbers, comparing various approaches using ByteStrings. |
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Revision as of 15:59, 31 August 2009
| Haskell Performance Resource
Constructs: Techniques: |
Strings
Sometimes the cost of representing strings as lists of Char can be too much. In this case, you can instead use packed strings. There are a number of options:
- One of the packed string libraries, for example Data.ByteString
- Unboxed arrays of Word8 or Char
- Ptrs to foreign malloced Word8 buffers
The packed string libraries have the benefit over arrays of Word8 or Char types, in that they provide the usual list-like operations.
Some interesting results for Data.ByteString are documented here. In particular, it compares FPS against the existing PackedString and [Char] functions, and is used successfully with 1 terabyte strings.
Example
Pete Chown asked the question:
I want to read a text file. As an example, let's use /usr/share/dict/words and try to print out the last line of the file.
The python version completes in around 0.05s.
Attempt 1 : [Char]
import System.IO
main = readFile "/usr/share/dict/words" >>= putStrLn.last.lines
Run in hugs, this program took several seconds to complete. Problem: interpreted (solution, use a Haskell compiler). Compiled, the program completes in a fairly quick 0.2s. Still, we can do better.
Attempt 2 : Data.ByteString
Using ByteString, we get:
import qualified Data.ByteString as B
import IO
main = B.readFile "/usr/share/dict/words" >>= B.putStr . last . B.lines
Runs in 0.063s
Attempt 3 : No Lists
Avoid splitting the file into lists at all, and just keep a single buffer (as a C programmer would perhaps do):
import qualified Data.ByteString as P
import Maybe
import IO
main = P.readFile "/usr/share/dict/words" >>= P.putStrLn . snd . fromJust . P.breakLast '\n'
Runs in 0.013s
Related work
An extended tutorial on using PackedStrings/ByteStrings for high performance string manipulating code is here.
A discussion of the fastest way to parse a file of numbers, comparing various approaches using ByteStrings.