winery
winery is a serialisation library focusing on performance, compactness
and compatibility. The primary feature is that metadata (types, field names,
etc) are packed into one schema.
A number of formats, like JSON and CBOR, attach metadata for each value:
[{"id": 0, "name": "Alice"}, {"id": 1, "name": "Bob"}]
In contrast, winery stores them separately, eliminating redundancy while
guaranteeing well-typedness:
0402 0402 0269 6410 046e 616d 6514 [{ id :: Integer, name :: Text }]
0200 0541 6c69 6365 0103 426f 62 [(0, "Alice"), (1, "Bob")]
Unlike other libraries that don't preserve metadata (e.g. binary
, cereal
, store
) at all, winery also
allows readers to decode values regardless of the current implementation.
Interface
The interface is simple; serialise
encodes a value with its schema, and
deserialise
decodes a ByteString using the schema in it.
class Serialise a where
schema :: Serialise a => proxy a -> Schema
serialise :: Serialise a => a -> B.ByteString
deserialise :: Serialise a => B.ByteString -> Either WineryException a
It's also possible to serialise schemata and data separately. serialiseSchema
encodes a schema and its version number into a ByteString, and
serialiseOnly
serialises a value without a schema.
serialiseSchema :: Schema -> B.ByteString
serialiseOnly :: Serialise a => a -> B.ByteString
In order to decode data generated this way, pass the result of deserialiseSchema
to getDecoder
. Finally run evalDecoder
to deserialise them.
deserialiseSchema :: B.ByteString -> Either WineryException Schema
getDecoder :: Serialise a => Schema -> Either WineryException (Decoder a)
evalDecoder :: Decoder a -> B.ByteString -> a
Deriving an instance
The recommended way to create an instance of Serialise
is to use DerivingVia
.
deriving Generic
deriving Serialise via WineryRecord Foo
for single-constructor records, or just
deriving Generic
deriving Serialise via WineryVariant Foo
for any ADT. The former explicitly describes field names in the schema, and the
latter does constructor names.
If you want to customise one of the methods, you can use bundleVia
to supply the rest of definitions.
instance Serialise Foo where
bundleSerialise = bundleVia WineryRecord
extractor = buildExtractor $ Foo
<$> extractField "foo"
<*> extractField "bar"
Backward compatibility
If the representation is not the same as the current version (i.e. the schema
is different), the data cannot be decoded directly. This is where extractors
come in.
Extractor
parses a schema and returns a function which gives a value back from
a Term
.
You can build an extractor using combinators such as extractField
, extractConstructor
, etc.
buildExtractor
$ ("None", \() -> Nothing)
`extractConstructor` ("Some", Just)
`extractConstructor` extractVoid
:: Extractor (Maybe a)
If you want to customise the extractor, the pair of gvariantExtractors
and buildVariantExtractors
is handy.
gvariantExtractors :: (GSerialiseVariant (Rep a), Generic a) => HM.HashMap T.Text (Extractor a)
buildVariantExtractor :: (Generic a, Typeable a) => HM.HashMap T.Text (Extractor a) -> Extractor a
Extractor
is Alternative, meaning that multiple extractors (such as a default
generic implementation and fallback plans) can be combined into one.
Altering an instance for a record type is a little bit tricky.
HKD can represent a record where each field is Subextractor
instead of the orignal type.
The barbies-th allows us to derive it from a plain declaration.
import Barbies.Bare
import Barbies.TH
declareBareB [d|
data HRecB = HRec
{ baz :: !Int
, qux :: !Text
}
|]
type HRec = HRecB Bare Identity
Obtain a record of extractors using bextractors :: forall b. (AllB Serialise b, ...) => b Subextractor
, update it as necessary,
then build an extractor for an entire record by buildRecordExtractor
.
instance Serialise HRec where
bundleSerialise = bundleVia WineryRecord
extractor = fmap bstrip $ buildRecordExtractor bextractors
{ qux = extractField "qux" <|> extractField "oldQux" }
More generic instance (for covered types) can be defined as below:
instance (Typeable h, AllBF Serialise h (HRecB Covered)) => Serialise (HRecB Covered h) where
bundleSerialise = bundleVia Barbie
extractor = buildRecordExtractorF bextractorsF
{ qux = Compose $ extractField "qux" <|> extractField "oldQux" }
Pretty-printing
Term
can be deserialised from any winery data. It can be pretty-printed using the Pretty
instance:
{ bar: "hello"
, baz: 3.141592653589793
, foo: Just 42
}
You can use the winery
command-line tool to inspect values.
$ winery '.[:10] | .first_name .last_name' benchmarks/data.winery
Shane Plett
Mata Snead
Levon Sammes
Irina Gourlay
Brooks Titlow
Antons Culleton
Regine Emerton
Starlin Laying
Orv Kempshall
Elizabeth Joseff
Cathee Eberz
At the moment, the following queries are supported:
.
return itself
.[]
enumerate all the elements in a list
.[i]
get the i-th element
.[i:j]
enumerate i-th to j-th items
.N
n-th element of a product
.foo
Get a field named foo
F | G
compose queries (left to right)
A useful library should also be fast. Benchmarking encoding/decoding of the
following datatype.
data Gender = Male | Female
data TestRec = TestRec
{ id_ :: !Int
, first_name :: !Text
, last_name :: !Text
, email :: !Text
, gender :: !Gender
, num :: !Int
, latitude :: !Double
, longitude :: !Double
}
Here's the result:
|
encode 1 |
encode 1000 |
decode |
length |
winery |
0.28 μs |
0.26 ms |
0.81 ms |
58662 |
cereal |
0.82 μs |
0.78 ms |
0.90 ms |
91709 |
binary |
1.7 μs |
1.7 ms |
2.0 ms |
125709 |
serialise |
0.61 μs |
0.50 ms |
1.4 ms |
65437 |
store |
54 ns |
56 μs |
0.13 ms |
126410 |
aeson |
9.9 μs |
9.7 ms |
17 ms |
160558 |