binary

Binary serialisation for Haskell values using lazy ByteStrings

https://github.com/kolmodin/binary

Version on this page:0.7.1.0
LTS Haskell 22.14:0.8.9.1
Stackage Nightly 2024-03-29:0.8.9.1
Latest on Hackage:0.10.0.0@rev:1

See all snapshots binary appears in

BSD-3-Clause licensed by Lennart Kolmodin
Maintained by Lennart Kolmodin, Don Stewart
This version can be pinned in stack with:binary-0.7.1.0@sha256:c5a93a43da9ba7917eab6cbb2780f5c9ca0bf8980b50e308f5135c57954a8758,3409

binary package

Efficient, pure binary serialisation using lazy ByteStrings.

The binary package provides Data.Binary, containing the Binary class, and associated methods, for serialising values to and from lazy ByteStrings. A key feature of binary is that the interface is both pure, and efficient. The binary package is portable to GHC and Hugs.

Installing binary from Hackage

binary is part of The Glasgow Haskell Compiler (GHC) and therefore if you have either GHC or The Haskell Platform installed, you already have binary.

More recent versions of binary than you might have installed may be available. You can use cabal-install to install a later version from Hackage.

$ cabal update
$ cabal install binary

Building binary

binary comes with both a test suite and a set of benchmarks. While developing, you probably want to enable both. Here’s how to get the latest version of the repository, configure and build.

$ git clone [email protected]:kolmodin/binary.git
$ cd binary
$ cabal update
$ cabal configure --enable-tests --enable-benchmarks
$ cabal build

Run the test suite.

$ cabal test

Using binary

First:

import Data.Binary

and then write an instance of Binary for the type you wish to serialise. An example doing exactly this can be found in the Data.Binary module. You can also use the Data.Binary.Builder module to efficiently build lazy bytestrings using the Builder monoid. Or, alternatively, the Data.Binary.Get and Data.Binary.Put to serialize/deserialize using the Get and Put monads.

More information in the haddock documentation.

Deriving binary instances

It is possible to mechanically derive new instances of Binary for your types, if they support the Data and Typeable classes. A script is provided in tools/derive. Here’s an example of its use.

$ cd binary 
$ cd tools/derive 

$ ghci -fglasgow-exts BinaryDerive.hs

*BinaryDerive> :l Example.hs 

*Main> deriveM (undefined :: Exp)

instance Binary Main.Exp where
  put (ExpOr a b) = putWord8 0 >> put a >> put b
  put (ExpAnd a b) = putWord8 1 >> put a >> put b
  put (ExpEq a b) = putWord8 2 >> put a >> put b
  put (ExpNEq a b) = putWord8 3 >> put a >> put b
  put (ExpAdd a b) = putWord8 4 >> put a >> put b
  put (ExpSub a b) = putWord8 5 >> put a >> put b
  put (ExpVar a) = putWord8 6 >> put a
  put (ExpInt a) = putWord8 7 >> put a
  get = do
    tag_ <- getWord8
    case tag_ of
      0 -> get >>= \a -> get >>= \b -> return (ExpOr a b)
      1 -> get >>= \a -> get >>= \b -> return (ExpAnd a b)
      2 -> get >>= \a -> get >>= \b -> return (ExpEq a b)
      3 -> get >>= \a -> get >>= \b -> return (ExpNEq a b)
      4 -> get >>= \a -> get >>= \b -> return (ExpAdd a b)
      5 -> get >>= \a -> get >>= \b -> return (ExpSub a b)
      6 -> get >>= \a -> return (ExpVar a)
      7 -> get >>= \a -> return (ExpInt a)
      _ -> fail "no decoding"

Contributors

  • Lennart Kolmodin
  • Duncan Coutts
  • Don Stewart
  • Spencer Janssen
  • David Himmelstrup
  • Björn Bringert
  • Ross Paterson
  • Einar Karttunen
  • John Meacham
  • Ulf Norell
  • Tomasz Zielonka
  • Stefan Karrmann
  • Bryan O’Sullivan
  • Bas van Dijk
  • Florian Weimer