descriptive
Self-describing consumers/parsers
Haddocks
There are a variety of Haskell libraries which are implementable
through a common interface: self-describing parsers:
- A formlet is a self-describing parser.
- A regular old text parser can be self-describing.
- A command-line options parser is a self-describing parser.
- A MUD command set is a self-describing parser.
- A JSON API can be a self-describing parser.
Consumption is done in this data type:
data Consumer s d a
To make a consumer, this combinator is used:
consumer :: (s -> (Description d,s))
-> (s -> (Either (Description d) a,s))
-> Consumer s d a
The first argument generates a description based on some state. The
state is determined by whatever use-case you have. The second argument
parses from the state, which could be a stream of bytes, a list of
strings, a Map, a Vector, etc. You may or may not decide to modify the
state during generation of the description and during parsing.
To use a consumer or describe what it does, these are used:
consume :: Consumer s d a -> s -> (Either (Description d) a,s)
describe :: Consumer s d a -> s -> (Description d,s)
A description is like this:
data Description a
= Unit !a
| Bounded !Integer !Bound !(Description a)
| And !(Description a) !(Description a)
| Sequence [Description a]
| Wrap a (Description a)
| None
deriving (Show)
You configure the a
for your use-case, but the rest is generatable
by the library. Afterwards, you can make your own pretty printing
function, which may be to generate an HTML form, to generate a
commandline --help
screen, a man page, API docs for your JSON
parser, a text parsing grammar, etc. For example:
describeParser :: Consumer [Char] Text Demo -> Text
describeForm :: Consumer (Map Text Text) (Html ()) Login -> Html ()
describeArgs :: Consumer [Text] CmdArgs MyApp -> CmdArgs
See below for some examples of this library.
Parsing characters
See Descriptive.Char
.
λ> describe (many (char 'k') <> string "abc") mempty
(And (Bounded 0 UnlimitedBound (Unit "k"))
(Sequence [Unit "a",Sequence [Unit "b",Sequence [Unit "c",Sequence []]]])
,"")
λ> consume (many (char 'k') <> string "abc") "kkkabc"
(Right "kkkabc","")
λ> consume (many (char 'k') <> string "abc") "kkkab"
(Left (Unit "a character"),"")
λ> consume (many (char 'k') <> string "abc") "kkkabj"
(Left (Unit "c"),"")
See Descriptive.Form
.
λ> describe ((,) <$> input "username" <*> input "password") mempty
(And (Unit (Input "username")) (Unit (Input "password")),fromList [])
λ> consume ((,) <$>
input "username" <*>
input "password")
(M.fromList [("username","chrisdone"),("password","god")])
(Right ("chrisdone","god")
,fromList [("password","god"),("username","chrisdone")])
Conditions on two inputs:
login = validate "confirmed password (entered the same twice)"
(\(x,y) ->
if x == y
then Just y
else Nothing)
((,) <$>
input "password" <*>
input "password2")
λ> describe login mempty
(Wrap (Constraint "confirmed password (entered the same twice)")
(And (Unit (Input "password"))
(Unit (Input "password2")))
,fromList [])
λ> consume login (M.fromList [("password2","gob"),("password","gob")])
(Right "gob",fromList [("password","gob"),("password2","gob")])
See Descriptive.Formlet
.
λ> describe ((,) <$> indexed <*> indexed)
(FormletState mempty 0)
(And (Unit (Index 0))
(Unit (Index 1))
,FormletState {formletMap = fromList []
,formletIndex = 2})
λ> consume ((,) <$> indexed <*> indexed)
(FormletState (M.fromList [(0,"chrisdone"),(1,"god")]) 0)
(Right ("chrisdone","god")
,FormletState {formletMap =
fromList [(0,"chrisdone"),(1,"god")]
,formletIndex = 2})
λ> consume ((,) <$> indexed <*> indexed)
(FormletState (M.fromList [(0,"chrisdone")]) 0)
(Left (Unit (Index 1))
,FormletState {formletMap =
fromList [(0,"chrisdone")]
,formletIndex = 2})
Parsing command-line options
See Descriptive.Options
.
server =
((,,,) <$>
constant "start" <*>
anyString "SERVER_NAME" <*>
flag "dev" "Enable dev mode?" <*>
arg "port" "Port to listen on")
λ> describe server []
(And (And (And (Unit (Constant "start"))
(Unit (AnyString "SERVER_NAME")))
(Unit (Flag "dev" "Enable dev mode?")))
(Unit (Arg "port" "Port to listen on"))
,[])
λ> consume server ["start","any","--port","1234","-fdev"]
(Right ("start","any",True,"1234"),[])
λ> consume server ["start","any","--port","1234"]
(Right ("start","any",False,"1234"),[])
λ> consume server ["start","any"]
(Left (Unit (Arg "port" "Port to listen on")),[])
Self-documenting JSON parser
See Descriptive.JSON
.
-- | Submit a URL to reddit.
data Submission =
Submission {submissionToken :: !Integer
,submissionTitle :: !Text
,submissionComment :: !Text
,submissionSubreddit :: !Integer}
deriving (Show)
submission :: Consumer Value Doc Submission
submission =
obj "Submission"
(Submission
<$> key "token" (integer "Submission token; see the API docs")
<*> key "title" (string "Submission title")
<*> key "comment" (string "Submission comment")
<*> key "subreddit" (integer "The ID of the subreddit"))
sample :: Value
sample =
toJSON (object
["token" .= 123
,"title" .= "Some title"
,"comment" .= "This is good"
,"subreddit" .= 234214])
badsample :: Value
badsample =
toJSON (object
["token" .= 123
,"title" .= "Some title"
,"comment" .= 123
,"subreddit" .= 234214])
λ> describe submission (toJSON ())
(Wrap (Struct "Submission")
(And (And (And (Wrap (Key "token")
(Unit (Integer "Submission token; see the API docs")))
(Wrap (Key "title")
(Unit (Text "Submission title"))))
(Wrap (Key "comment")
(Unit (Text "Submission comment"))))
(Wrap (Key "subreddit")
(Unit (Integer "The ID of the subreddit"))))
,Array (fromList []))
λ> consume submission sample
(Right (Submission {submissionToken = 123
,submissionTitle = "Some title"
,submissionComment = "This is good"
,submissionSubreddit = 234214})
,Object (fromList [("token",Number 123.0)
,("subreddit",Number 234214.0)
,("title",String "Some title")
,("comment",String "This is good")]))
λ> consume submission badsample
(Left (Wrap (Struct "Submission")
(Wrap (Key "comment")
(Unit (Text "Submission comment"))))
,Object (fromList [("token",Number 123.0)
,("subreddit",Number 234214.0)
,("title",String "Some title")
,("comment",Number 123.0)]))
The bad sample yields an informative message that:
- The error is in the Submission object.
- The key "comment".
- The type of that key should be a String and it should be a
Submission comment (or whatever invariants you'd like to mention).
Parsing Attempto Controlled English for MUD commands
TBA. Will use
this package.
With ACE you can parse into:
parsed complV "<distrans-verb> a <noun> <prep> a <noun>" ==
Right (ComplVDisV (DistransitiveV "<distrans-verb>")
(ComplNP (NPCoordUnmarked (UnmarkedNPCoord anoun Nothing)))
(ComplPP (PP (Preposition "<prep>")
(NPCoordUnmarked (UnmarkedNPCoord anoun Nothing)))))
Which I can then further parse with descriptive
to yield
descriptions like:
<verb-phrase> [<noun-phrase> ..]
Or similar. Which would be handy for a MUD so that a user can write:
Put the sword on the table.
Producing questions and consuming the answers in Haskell
TBA. Will be a generalization of
this type.
It is a library which I am working on in parallel which will ask the
user questions and then validate the answers. Current output is like
this:
λ> describe (greaterThan 4 (integerExpr (parse id expr exercise)))
an integer greater than 4
λ> eval (greaterThan 4 (integerExpr (parse id expr exercise))) $(someHaskell "x = 1")
Left expected an expression, but got a declaration
λ> eval (greaterThan 4 (integerExpr (parse id expr exercise))) $(someHaskell "x")
Left expected an integer, but got an expression
λ> eval (greaterThan 4 (integerExpr (parse id expr exercise))) $(someHaskell "3")
Left expected an integer greater than 4
λ> eval (greaterThan 4 (integerExpr (parse id expr exercise))) $(someHaskell "5")
Right 5
This is also couples description with validation, but I will probably
rewrite it with this descriptive
library.