-{-# LANGUAGE TemplateHaskell, QuasiQuotes #-}
+{-# LANGUAGE TemplateHaskell #-}
-{-| TemplateHaskell helper for HTools.
+{-| TemplateHaskell helper for Ganeti Haskell code.
As TemplateHaskell require that splices be defined in a separate
module, we combine all the TemplateHaskell functionality that HTools
{-
-Copyright (C) 2011 Google Inc.
+Copyright (C) 2011, 2012 Google Inc.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
, declareIADT
, makeJSONInstance
, genOpID
+ , genAllOpIDs
, genOpCode
- , noDefault
, genStrOfOp
, genStrOfKey
, genLuxiOp
+ , Field
+ , simpleField
+ , defaultField
+ , optionalField
+ , renameField
+ , customField
+ , timeStampFields
+ , uuidFields
+ , serialFields
+ , tagsFields
+ , TagSet
+ , buildObject
+ , buildObjectSerialisation
+ , buildParam
+ , DictObject(..)
+ , genException
+ , excErrMsg
) where
-import Control.Monad (liftM, liftM2)
+import Control.Monad (liftM)
import Data.Char
import Data.List
+import Data.Maybe (fromMaybe)
+import qualified Data.Set as Set
import Language.Haskell.TH
import qualified Text.JSON as JSON
+import Text.JSON.Pretty (pp_value)
+
+-- * Exported types
+
+-- | Class of objects that can be converted to 'JSObject'
+-- lists-format.
+class DictObject a where
+ toDict :: a -> [(String, JSON.JSValue)]
+
+-- | Serialised field data type.
+data Field = Field { fieldName :: String
+ , fieldType :: Q Type
+ , fieldRead :: Maybe (Q Exp)
+ , fieldShow :: Maybe (Q Exp)
+ , fieldDefault :: Maybe (Q Exp)
+ , fieldConstr :: Maybe String
+ , fieldIsOptional :: Bool
+ }
+
+-- | Generates a simple field.
+simpleField :: String -> Q Type -> Field
+simpleField fname ftype =
+ Field { fieldName = fname
+ , fieldType = ftype
+ , fieldRead = Nothing
+ , fieldShow = Nothing
+ , fieldDefault = Nothing
+ , fieldConstr = Nothing
+ , fieldIsOptional = False
+ }
+
+-- | Sets the renamed constructor field.
+renameField :: String -> Field -> Field
+renameField constrName field = field { fieldConstr = Just constrName }
+
+-- | Sets the default value on a field (makes it optional with a
+-- default value).
+defaultField :: Q Exp -> Field -> Field
+defaultField defval field = field { fieldDefault = Just defval }
+
+-- | Marks a field optional (turning its base type into a Maybe).
+optionalField :: Field -> Field
+optionalField field = field { fieldIsOptional = True }
+
+-- | Sets custom functions on a field.
+customField :: Name -- ^ The name of the read function
+ -> Name -- ^ The name of the show function
+ -> Field -- ^ The original field
+ -> Field -- ^ Updated field
+customField readfn showfn field =
+ field { fieldRead = Just (varE readfn), fieldShow = Just (varE showfn) }
+
+-- | Computes the record name for a given field, based on either the
+-- string value in the JSON serialisation or the custom named if any
+-- exists.
+fieldRecordName :: Field -> String
+fieldRecordName (Field { fieldName = name, fieldConstr = alias }) =
+ fromMaybe (camelCase name) alias
+
+-- | Computes the preferred variable name to use for the value of this
+-- field. If the field has a specific constructor name, then we use a
+-- first-letter-lowercased version of that; otherwise, we simply use
+-- the field name. See also 'fieldRecordName'.
+fieldVariable :: Field -> String
+fieldVariable f =
+ case (fieldConstr f) of
+ Just name -> ensureLower name
+ _ -> map (\c -> if c == '-' then '_' else c) $ fieldName f
+
+actualFieldType :: Field -> Q Type
+actualFieldType f | fieldIsOptional f = [t| Maybe $t |]
+ | otherwise = t
+ where t = fieldType f
+
+checkNonOptDef :: (Monad m) => Field -> m ()
+checkNonOptDef (Field { fieldIsOptional = True, fieldName = name }) =
+ fail $ "Optional field " ++ name ++ " used in parameter declaration"
+checkNonOptDef (Field { fieldDefault = (Just _), fieldName = name }) =
+ fail $ "Default field " ++ name ++ " used in parameter declaration"
+checkNonOptDef _ = return ()
+
+-- | Produces the expression that will de-serialise a given
+-- field. Since some custom parsing functions might need to use the
+-- entire object, we do take and pass the object to any custom read
+-- functions.
+loadFn :: Field -- ^ The field definition
+ -> Q Exp -- ^ The value of the field as existing in the JSON message
+ -> Q Exp -- ^ The entire object in JSON object format
+ -> Q Exp -- ^ Resulting expression
+loadFn (Field { fieldRead = Just readfn }) expr o = [| $expr >>= $readfn $o |]
+loadFn _ expr _ = expr
+
+-- * Common field declarations
+
+-- | Timestamp fields description.
+timeStampFields :: [Field]
+timeStampFields =
+ [ defaultField [| 0::Double |] $ simpleField "ctime" [t| Double |]
+ , defaultField [| 0::Double |] $ simpleField "mtime" [t| Double |]
+ ]
+
+-- | Serial number fields description.
+serialFields :: [Field]
+serialFields =
+ [ renameField "Serial" $ simpleField "serial_no" [t| Int |] ]
+
+-- | UUID fields description.
+uuidFields :: [Field]
+uuidFields = [ simpleField "uuid" [t| String |] ]
+
+-- | Tag set type alias.
+type TagSet = Set.Set String
+
+-- | Tag field description.
+tagsFields :: [Field]
+tagsFields = [ defaultField [| Set.empty |] $
+ simpleField "tags" [t| TagSet |] ]
+
+-- * Internal types
+
+-- | A simple field, in constrast to the customisable 'Field' type.
+type SimpleField = (String, Q Type)
+
+-- | A definition for a single constructor for a simple object.
+type SimpleConstructor = (String, [SimpleField])
+
+-- | A definition for ADTs with simple fields.
+type SimpleObject = [SimpleConstructor]
-- * Helper functions
ensureLower [] = []
ensureLower (x:xs) = toLower x:xs
+-- | Ensure first letter is uppercase.
+--
+-- Used to convert constructor name to component
+ensureUpper :: String -> String
+ensureUpper [] = []
+ensureUpper (x:xs) = toUpper x:xs
+
-- | Helper for quoted expressions.
varNameE :: String -> Q Exp
varNameE = varE . mkName
fromRawName :: String -> Name
fromRawName = mkName . (++ "FromRaw") . ensureLower
--- | Converts a name to it's varE/litE representations.
---
+-- | Converts a name to it's varE\/litE representations.
reprE :: Either String Name -> Q Exp
reprE = either stringE varE
appFn f x | f == VarE 'id = x
| otherwise = AppE f x
+-- | Builds a field for a normal constructor.
+buildConsField :: Q Type -> StrictTypeQ
+buildConsField ftype = do
+ ftype' <- ftype
+ return (NotStrict, ftype')
+
+-- | Builds a constructor based on a simple definition (not field-based).
+buildSimpleCons :: Name -> SimpleObject -> Q Dec
+buildSimpleCons tname cons = do
+ decl_d <- mapM (\(cname, fields) -> do
+ fields' <- mapM (buildConsField . snd) fields
+ return $ NormalC (mkName cname) fields') cons
+ return $ DataD [] tname [] decl_d [''Show, ''Read, ''Eq]
+
+-- | Generate the save function for a given type.
+genSaveSimpleObj :: Name -- ^ Object type
+ -> String -- ^ Function name
+ -> SimpleObject -- ^ Object definition
+ -> (SimpleConstructor -> Q Clause) -- ^ Constructor save fn
+ -> Q (Dec, Dec)
+genSaveSimpleObj tname sname opdefs fn = do
+ let sigt = AppT (AppT ArrowT (ConT tname)) (ConT ''JSON.JSValue)
+ fname = mkName sname
+ cclauses <- mapM fn opdefs
+ return $ (SigD fname sigt, FunD fname cclauses)
+
-- * Template code for simple raw type-equivalent ADTs
-- | Generates a data type declaration.
-- @
genToRaw :: Name -> Name -> Name -> [(String, Either String Name)] -> Q [Dec]
genToRaw traw fname tname constructors = do
- sigt <- [t| $(conT tname) -> $(conT traw) |]
+ let sigt = AppT (AppT ArrowT (ConT tname)) (ConT traw)
-- the body clauses, matching on the constructor and returning the
-- raw value
clauses <- mapM (\(c, v) -> clause [recP (mkName c) []]
--
-- * /name/FromRaw, which (monadically) converts from a raw type to the type
--
--- Note that this is basically just a custom show/read instance,
+-- Note that this is basically just a custom show\/read instance,
-- nothing else.
declareADT :: Name -> String -> [(String, Name)] -> Q [Dec]
declareADT traw sname cons = do
-- @
--
-- in an instance JSON /name/ declaration
-genShowJSON :: String -> Q [Dec]
-genShowJSON name = [d| showJSON = JSON.showJSON . $(varE (toRawName name)) |]
+genShowJSON :: String -> Q Dec
+genShowJSON name = do
+ body <- [| JSON.showJSON . $(varE (toRawName name)) |]
+ return $ FunD (mkName "showJSON") [Clause [] (NormalB body) []]
-- | Creates the readJSON member of a JSON instance declaration.
--
JSON.Ok s' -> $(varE (fromRawName name)) s'
JSON.Error e ->
JSON.Error $ "Can't parse raw value for type " ++
- $(stringE name) ++ ": " ++ e
+ $(stringE name) ++ ": " ++ e ++ " from " ++
+ show $(varE s)
|]
return $ FunD (mkName "readJSON") [Clause [VarP s] (NormalB body) []]
let base = nameBase name
showJ <- genShowJSON base
readJ <- genReadJSON base
- return [InstanceD [] (AppT (ConT ''JSON.JSON) (ConT name)) (readJ:showJ)]
+ return [InstanceD [] (AppT (ConT ''JSON.JSON) (ConT name)) [readJ,showJ]]
-- * Template code for opcodes
deCamelCase =
intercalate "_" . map (map toUpper) . groupBy (\_ b -> not $ isUpper b)
+-- | Transform an underscore_name into a CamelCase one.
+camelCase :: String -> String
+camelCase = concatMap (ensureUpper . drop 1) .
+ groupBy (\_ b -> b /= '_' && b /= '-') . ('_':)
+
-- | Computes the name of a given constructor.
constructorName :: Con -> Q Name
constructorName (NormalC name _) = return name
constructorName (RecC name _) = return name
constructorName x = fail $ "Unhandled constructor " ++ show x
+-- | Extract all constructor names from a given type.
+reifyConsNames :: Name -> Q [String]
+reifyConsNames name = do
+ reify_result <- reify name
+ case reify_result of
+ TyConI (DataD _ _ _ cons _) -> mapM (liftM nameBase . constructorName) cons
+ o -> fail $ "Unhandled name passed to reifyConsNames, expected\
+ \ type constructor but got '" ++ show o ++ "'"
+
-- | Builds the generic constructor-to-string function.
--
-- This generates a simple function of the following form:
-- fname (ConStructorTwo {}) = trans_fun("ConStructorTwo")
-- @
--
--- This builds a custom list of name/string pairs and then uses
--- 'genToRaw' to actually generate the function
+-- This builds a custom list of name\/string pairs and then uses
+-- 'genToRaw' to actually generate the function.
genConstrToStr :: (String -> String) -> Name -> String -> Q [Dec]
genConstrToStr trans_fun name fname = do
- TyConI (DataD _ _ _ cons _) <- reify name
- cnames <- mapM (liftM nameBase . constructorName) cons
+ cnames <- reifyConsNames name
let svalues = map (Left . trans_fun) cnames
genToRaw ''String (mkName fname) name $ zip cnames svalues
genOpID :: Name -> String -> Q [Dec]
genOpID = genConstrToStr deCamelCase
+-- | Builds a list with all defined constructor names for a type.
+--
+-- @
+-- vstr :: String
+-- vstr = [...]
+-- @
+--
+-- Where the actual values of the string are the constructor names
+-- mapped via @trans_fun@.
+genAllConstr :: (String -> String) -> Name -> String -> Q [Dec]
+genAllConstr trans_fun name vstr = do
+ cnames <- reifyConsNames name
+ let svalues = sort $ map trans_fun cnames
+ vname = mkName vstr
+ sig = SigD vname (AppT ListT (ConT ''String))
+ body = NormalB (ListE (map (LitE . StringL) svalues))
+ return $ [sig, ValD (VarP vname) body []]
+
+-- | Generates a list of all defined opcode IDs.
+genAllOpIDs :: Name -> String -> Q [Dec]
+genAllOpIDs = genAllConstr deCamelCase
+
-- | OpCode parameter (field) type.
type OpParam = (String, Q Type, Q Exp)
-- datatype and the JSON serialisation out of it. We can't use a
-- generic serialisation since we need to be compatible with Ganeti's
-- own, so we have a few quirks to work around.
---
--- There are three things to be defined for each parameter:
---
--- * name
---
--- * type; if this is 'Maybe', will only be serialised if it's a
--- 'Just' value
---
--- * default; if missing, won't raise an exception, but will instead
--- use the default
---
genOpCode :: String -- ^ Type name to use
- -> [(String, [OpParam])] -- ^ Constructor name and parameters
+ -> [(String, [Field])] -- ^ Constructor name and parameters
-> Q [Dec]
genOpCode name cons = do
decl_d <- mapM (\(cname, fields) -> do
-- we only need the type of the field, without Q
- fields' <- mapM (\(_, qt, _) ->
- qt >>= \t -> return (NotStrict, t))
- fields
- return $ NormalC (mkName cname) fields')
+ fields' <- mapM actualFieldType fields
+ let fields'' = zip (repeat NotStrict) fields'
+ return $ NormalC (mkName cname) fields'')
cons
let declD = DataD [] (mkName name) [] decl_d [''Show, ''Read, ''Eq]
isOptional (AppT (ConT dt) _) | dt == ''Maybe = True
isOptional _ = False
--- | Generates the \"save\" expression for a single opcode parameter.
---
--- There is only one special handling mode: if the parameter is of
--- 'Maybe' type, then we only save it if it's a 'Just' value,
--- otherwise we skip it.
-saveField :: Name -- ^ The name of variable that contains the value
- -> OpParam -- ^ Parameter definition
- -> Q Exp
-saveField fvar (fname, qt, _) = do
- t <- qt
- let fnexp = stringE fname
- fvare = varE fvar
- (if isOptional t
- then [| case $fvare of
- Just v' -> [( $fnexp, $showJSONE v')]
- Nothing -> []
- |]
- else [| [( $fnexp, $showJSONE $fvare )] |])
-
-- | Generates the \"save\" clause for an entire opcode constructor.
--
-- This matches the opcode with variables named the same as the
-- constructor fields (just so that the spliced in code looks nicer),
--- and passes those name plus the parameter definition to 'saveField'.
+-- and passes those name plus the parameter definition to 'saveObjectField'.
saveConstructor :: String -- ^ The constructor name
- -> [OpParam] -- ^ The parameter definitions for this
+ -> [Field] -- ^ The parameter definitions for this
-- constructor
-> Q Clause -- ^ Resulting clause
saveConstructor sname fields = do
let cname = mkName sname
- let fnames = map (\(n, _, _) -> mkName n) fields
+ fnames <- mapM (newName . fieldVariable) fields
let pat = conP cname (map varP fnames)
- let felems = map (uncurry saveField) (zip fnames fields)
+ let felems = map (uncurry saveObjectField) (zip fnames fields)
-- now build the OP_ID serialisation
opid = [| [( $(stringE "OP_ID"),
- $showJSONE $(stringE . deCamelCase $ sname) )] |]
+ JSON.showJSON $(stringE . deCamelCase $ sname) )] |]
flist = listE (opid:felems)
-- and finally convert all this to a json object
flist' = [| $(varNameE "makeObj") (concat $flist) |]
--
-- This builds a per-constructor match clause that contains the
-- respective constructor-serialisation code.
-genSaveOpCode :: [(String, [OpParam])] -> Q (Dec, Dec)
+genSaveOpCode :: [(String, [Field])] -> Q (Dec, Dec)
genSaveOpCode opdefs = do
cclauses <- mapM (uncurry saveConstructor) opdefs
let fname = mkName "saveOpCode"
sigt <- [t| $(conT (mkName "OpCode")) -> JSON.JSValue |]
return $ (SigD fname sigt, FunD fname cclauses)
--- | Generates the \"load\" field for a single parameter.
---
--- There is custom handling, depending on how the parameter is
--- specified. For a 'Maybe' type parameter, we allow that it is not
--- present (via 'Utils.maybeFromObj'). Otherwise, if there is a
--- default value, we allow the parameter to be abset, and finally if
--- there is no default value, we require its presence.
-loadField :: OpParam -> Q (Name, Stmt)
-loadField (fname, qt, qdefa) = do
- let fvar = mkName fname
- t <- qt
- defa <- qdefa
- -- these are used in all patterns below
- let objvar = varNameE "o"
- objfield = stringE fname
- bexp <- if isOptional t
- then [| $((varNameE "maybeFromObj")) $objvar $objfield |]
- else case defa of
- AppE (ConE dt) defval | dt == 'Just ->
- -- but has a default value
- [| $(varNameE "fromObjWithDefault")
- $objvar $objfield $(return defval) |]
- ConE dt | dt == 'Nothing ->
- [| $(varNameE "fromObj") $objvar $objfield |]
- s -> fail $ "Invalid default value " ++ show s ++
- ", expecting either 'Nothing' or a 'Just defval'"
- return (fvar, BindS (VarP fvar) bexp)
-
-loadConstructor :: String -> [OpParam] -> Q Exp
+-- | Generates load code for a single constructor of the opcode data type.
+loadConstructor :: String -> [Field] -> Q Exp
loadConstructor sname fields = do
let name = mkName sname
- fbinds <- mapM loadField fields
+ fbinds <- mapM loadObjectField fields
let (fnames, fstmts) = unzip fbinds
let cval = foldl (\accu fn -> AppE accu (VarE fn)) (ConE name) fnames
fstmts' = fstmts ++ [NoBindS (AppE (VarE 'return) cval)]
return $ DoE fstmts'
-genLoadOpCode :: [(String, [OpParam])] -> Q (Dec, Dec)
+-- | Generates the loadOpCode function.
+genLoadOpCode :: [(String, [Field])] -> Q (Dec, Dec)
genLoadOpCode opdefs = do
let fname = mkName "loadOpCode"
arg1 = mkName "v"
sigt <- [t| JSON.JSValue -> JSON.Result $(conT (mkName "OpCode")) |]
return $ (SigD fname sigt, FunD fname [Clause [VarP arg1] (NormalB body) []])
--- | No default type.
-noDefault :: Q Exp
-noDefault = conE 'Nothing
-
-- * Template code for luxi
-- | Constructor-to-string for LuxiOp.
genStrOfKey :: Name -> String -> Q [Dec]
genStrOfKey = genConstrToStr ensureLower
--- | LuxiOp parameter type.
-type LuxiParam = (String, Q Type, Q Exp)
-
-- | Generates the LuxiOp data type.
--
-- This takes a Luxi operation definition and builds both the
-- We can't use anything less generic, because the way different
-- operations are serialized differs on both parameter- and top-level.
--
--- There are three things to be defined for each parameter:
+-- There are two things to be defined for each parameter:
--
-- * name
--
-- * type
--
--- * operation; this is the operation performed on the parameter before
--- serialization
---
-genLuxiOp :: String -> [(String, [LuxiParam])] -> Q [Dec]
+genLuxiOp :: String -> SimpleObject -> Q [Dec]
genLuxiOp name cons = do
- decl_d <- mapM (\(cname, fields) -> do
- fields' <- mapM (\(_, qt, _) ->
- qt >>= \t -> return (NotStrict, t))
- fields
- return $ NormalC (mkName cname) fields')
- cons
- let declD = DataD [] (mkName name) [] decl_d [''Show, ''Read]
- (savesig, savefn) <- genSaveLuxiOp cons
- return [declD, savesig, savefn]
+ let tname = mkName name
+ declD <- buildSimpleCons tname cons
+ (savesig, savefn) <- genSaveSimpleObj tname "opToArgs"
+ cons saveLuxiConstructor
+ req_defs <- declareSADT "LuxiReq" .
+ map (\(str, _) -> ("Req" ++ str, mkName ("luxiReq" ++ str))) $
+ cons
+ return $ [declD, savesig, savefn] ++ req_defs
-- | Generates the \"save\" expression for a single luxi parameter.
-saveLuxiField :: Name -> LuxiParam -> Q Exp
-saveLuxiField fvar (_, qt, fn) =
- [| JSON.showJSON ( $(liftM2 appFn fn $ varE fvar) ) |]
+saveLuxiField :: Name -> SimpleField -> Q Exp
+saveLuxiField fvar (_, qt) =
+ [| JSON.showJSON $(varE fvar) |]
-- | Generates the \"save\" clause for entire LuxiOp constructor.
-saveLuxiConstructor :: (String, [LuxiParam]) -> Q Clause
+saveLuxiConstructor :: SimpleConstructor -> Q Clause
saveLuxiConstructor (sname, fields) = do
let cname = mkName sname
- fnames = map (\(nm, _, _) -> mkName nm) fields
+ fnames = map (mkName . fst) fields
pat = conP cname (map varP fnames)
flist = map (uncurry saveLuxiField) (zip fnames fields)
finval = if null flist
else [| JSON.showJSON $(listE flist) |]
clause [pat] (normalB finval) []
--- | Generates the main save LuxiOp function.
-genSaveLuxiOp :: [(String, [LuxiParam])]-> Q (Dec, Dec)
-genSaveLuxiOp opdefs = do
- sigt <- [t| $(conT (mkName "LuxiOp")) -> JSON.JSValue |]
- let fname = mkName "opToArgs"
- cclauses <- mapM saveLuxiConstructor opdefs
- return $ (SigD fname sigt, FunD fname cclauses)
+-- * "Objects" functionality
+
+-- | Extract the field's declaration from a Field structure.
+fieldTypeInfo :: String -> Field -> Q (Name, Strict, Type)
+fieldTypeInfo field_pfx fd = do
+ t <- actualFieldType fd
+ let n = mkName . (field_pfx ++) . fieldRecordName $ fd
+ return (n, NotStrict, t)
+
+-- | Build an object declaration.
+buildObject :: String -> String -> [Field] -> Q [Dec]
+buildObject sname field_pfx fields = do
+ let name = mkName sname
+ fields_d <- mapM (fieldTypeInfo field_pfx) fields
+ let decl_d = RecC name fields_d
+ let declD = DataD [] name [] [decl_d] [''Show, ''Read, ''Eq]
+ ser_decls <- buildObjectSerialisation sname fields
+ return $ declD:ser_decls
+
+-- | Generates an object definition: data type and its JSON instance.
+buildObjectSerialisation :: String -> [Field] -> Q [Dec]
+buildObjectSerialisation sname fields = do
+ let name = mkName sname
+ savedecls <- genSaveObject saveObjectField sname fields
+ (loadsig, loadfn) <- genLoadObject loadObjectField sname fields
+ shjson <- objectShowJSON sname
+ rdjson <- objectReadJSON sname
+ let instdecl = InstanceD [] (AppT (ConT ''JSON.JSON) (ConT name))
+ [rdjson, shjson]
+ return $ savedecls ++ [loadsig, loadfn, instdecl]
+
+-- | The toDict function name for a given type.
+toDictName :: String -> Name
+toDictName sname = mkName ("toDict" ++ sname)
+
+-- | Generates the save object functionality.
+genSaveObject :: (Name -> Field -> Q Exp)
+ -> String -> [Field] -> Q [Dec]
+genSaveObject save_fn sname fields = do
+ let name = mkName sname
+ fnames <- mapM (newName . fieldVariable) fields
+ let pat = conP name (map varP fnames)
+ let tdname = toDictName sname
+ tdsigt <- [t| $(conT name) -> [(String, JSON.JSValue)] |]
+
+ let felems = map (uncurry save_fn) (zip fnames fields)
+ flist = listE felems
+ -- and finally convert all this to a json object
+ tdlist = [| concat $flist |]
+ iname = mkName "i"
+ tclause <- clause [pat] (normalB tdlist) []
+ cclause <- [| $(varNameE "makeObj") . $(varE tdname) |]
+ let fname = mkName ("save" ++ sname)
+ sigt <- [t| $(conT name) -> JSON.JSValue |]
+ return [SigD tdname tdsigt, FunD tdname [tclause],
+ SigD fname sigt, ValD (VarP fname) (NormalB cclause) []]
+
+-- | Generates the code for saving an object's field, handling the
+-- various types of fields that we have.
+saveObjectField :: Name -> Field -> Q Exp
+saveObjectField fvar field
+ | fisOptional = [| case $(varE fvar) of
+ Nothing -> []
+ Just v -> [( $nameE, JSON.showJSON v)]
+ |]
+ | otherwise = case fieldShow field of
+ Nothing -> [| [( $nameE, JSON.showJSON $fvarE)] |]
+ Just fn -> [| let (actual, extra) = $fn $fvarE
+ in extra ++ [( $nameE, JSON.showJSON actual)]
+ |]
+ where fisOptional = fieldIsOptional field
+ nameE = stringE (fieldName field)
+ fvarE = varE fvar
+
+-- | Generates the showJSON clause for a given object name.
+objectShowJSON :: String -> Q Dec
+objectShowJSON name = do
+ body <- [| JSON.showJSON . $(varE . mkName $ "save" ++ name) |]
+ return $ FunD (mkName "showJSON") [Clause [] (NormalB body) []]
+
+-- | Generates the load object functionality.
+genLoadObject :: (Field -> Q (Name, Stmt))
+ -> String -> [Field] -> Q (Dec, Dec)
+genLoadObject load_fn sname fields = do
+ let name = mkName sname
+ funname = mkName $ "load" ++ sname
+ arg1 = mkName "v"
+ objname = mkName "o"
+ opid = mkName "op_id"
+ st1 <- bindS (varP objname) [| liftM JSON.fromJSObject
+ (JSON.readJSON $(varE arg1)) |]
+ fbinds <- mapM load_fn fields
+ let (fnames, fstmts) = unzip fbinds
+ let cval = foldl (\accu fn -> AppE accu (VarE fn)) (ConE name) fnames
+ fstmts' = st1:fstmts ++ [NoBindS (AppE (VarE 'return) cval)]
+ sigt <- [t| JSON.JSValue -> JSON.Result $(conT name) |]
+ return $ (SigD funname sigt,
+ FunD funname [Clause [VarP arg1] (NormalB (DoE fstmts')) []])
+
+-- | Generates code for loading an object's field.
+loadObjectField :: Field -> Q (Name, Stmt)
+loadObjectField field = do
+ let name = fieldVariable field
+ fvar <- newName name
+ -- these are used in all patterns below
+ let objvar = varNameE "o"
+ objfield = stringE (fieldName field)
+ loadexp =
+ if fieldIsOptional field
+ then [| $(varNameE "maybeFromObj") $objvar $objfield |]
+ else case fieldDefault field of
+ Just defv ->
+ [| $(varNameE "fromObjWithDefault") $objvar
+ $objfield $defv |]
+ Nothing -> [| $(varNameE "fromObj") $objvar $objfield |]
+ bexp <- loadFn field loadexp objvar
+
+ return (fvar, BindS (VarP fvar) bexp)
+
+-- | Builds the readJSON instance for a given object name.
+objectReadJSON :: String -> Q Dec
+objectReadJSON name = do
+ let s = mkName "s"
+ body <- [| case JSON.readJSON $(varE s) of
+ JSON.Ok s' -> $(varE .mkName $ "load" ++ name) s'
+ JSON.Error e ->
+ JSON.Error $ "Can't parse value for type " ++
+ $(stringE name) ++ ": " ++ e
+ |]
+ return $ FunD (mkName "readJSON") [Clause [VarP s] (NormalB body) []]
+
+-- * Inheritable parameter tables implementation
+
+-- | Compute parameter type names.
+paramTypeNames :: String -> (String, String)
+paramTypeNames root = ("Filled" ++ root ++ "Params",
+ "Partial" ++ root ++ "Params")
+
+-- | Compute information about the type of a parameter field.
+paramFieldTypeInfo :: String -> Field -> Q (Name, Strict, Type)
+paramFieldTypeInfo field_pfx fd = do
+ t <- actualFieldType fd
+ let n = mkName . (++ "P") . (field_pfx ++) .
+ fieldRecordName $ fd
+ return (n, NotStrict, AppT (ConT ''Maybe) t)
+
+-- | Build a parameter declaration.
+--
+-- This function builds two different data structures: a /filled/ one,
+-- in which all fields are required, and a /partial/ one, in which all
+-- fields are optional. Due to the current record syntax issues, the
+-- fields need to be named differrently for the two structures, so the
+-- partial ones get a /P/ suffix.
+buildParam :: String -> String -> [Field] -> Q [Dec]
+buildParam sname field_pfx fields = do
+ let (sname_f, sname_p) = paramTypeNames sname
+ name_f = mkName sname_f
+ name_p = mkName sname_p
+ fields_f <- mapM (fieldTypeInfo field_pfx) fields
+ fields_p <- mapM (paramFieldTypeInfo field_pfx) fields
+ let decl_f = RecC name_f fields_f
+ decl_p = RecC name_p fields_p
+ let declF = DataD [] name_f [] [decl_f] [''Show, ''Read, ''Eq]
+ declP = DataD [] name_p [] [decl_p] [''Show, ''Read, ''Eq]
+ ser_decls_f <- buildObjectSerialisation sname_f fields
+ ser_decls_p <- buildPParamSerialisation sname_p fields
+ fill_decls <- fillParam sname field_pfx fields
+ return $ [declF, declP] ++ ser_decls_f ++ ser_decls_p ++ fill_decls ++
+ buildParamAllFields sname fields ++
+ buildDictObjectInst name_f sname_f
+
+-- | Builds a list of all fields of a parameter.
+buildParamAllFields :: String -> [Field] -> [Dec]
+buildParamAllFields sname fields =
+ let vname = mkName ("all" ++ sname ++ "ParamFields")
+ sig = SigD vname (AppT ListT (ConT ''String))
+ val = ListE $ map (LitE . StringL . fieldName) fields
+ in [sig, ValD (VarP vname) (NormalB val) []]
+
+-- | Builds the 'DictObject' instance for a filled parameter.
+buildDictObjectInst :: Name -> String -> [Dec]
+buildDictObjectInst name sname =
+ [InstanceD [] (AppT (ConT ''DictObject) (ConT name))
+ [ValD (VarP 'toDict) (NormalB (VarE (toDictName sname))) []]]
+
+-- | Generates the serialisation for a partial parameter.
+buildPParamSerialisation :: String -> [Field] -> Q [Dec]
+buildPParamSerialisation sname fields = do
+ let name = mkName sname
+ savedecls <- genSaveObject savePParamField sname fields
+ (loadsig, loadfn) <- genLoadObject loadPParamField sname fields
+ shjson <- objectShowJSON sname
+ rdjson <- objectReadJSON sname
+ let instdecl = InstanceD [] (AppT (ConT ''JSON.JSON) (ConT name))
+ [rdjson, shjson]
+ return $ savedecls ++ [loadsig, loadfn, instdecl]
+
+-- | Generates code to save an optional parameter field.
+savePParamField :: Name -> Field -> Q Exp
+savePParamField fvar field = do
+ checkNonOptDef field
+ let actualVal = mkName "v"
+ normalexpr <- saveObjectField actualVal field
+ -- we have to construct the block here manually, because we can't
+ -- splice-in-splice
+ return $ CaseE (VarE fvar) [ Match (ConP 'Nothing [])
+ (NormalB (ConE '[])) []
+ , Match (ConP 'Just [VarP actualVal])
+ (NormalB normalexpr) []
+ ]
+
+-- | Generates code to load an optional parameter field.
+loadPParamField :: Field -> Q (Name, Stmt)
+loadPParamField field = do
+ checkNonOptDef field
+ let name = fieldName field
+ fvar <- newName name
+ -- these are used in all patterns below
+ let objvar = varNameE "o"
+ objfield = stringE name
+ loadexp = [| $(varNameE "maybeFromObj") $objvar $objfield |]
+ bexp <- loadFn field loadexp objvar
+ return (fvar, BindS (VarP fvar) bexp)
+
+-- | Builds a simple declaration of type @n_x = fromMaybe f_x p_x@.
+buildFromMaybe :: String -> Q Dec
+buildFromMaybe fname =
+ valD (varP (mkName $ "n_" ++ fname))
+ (normalB [| $(varNameE "fromMaybe")
+ $(varNameE $ "f_" ++ fname)
+ $(varNameE $ "p_" ++ fname) |]) []
+
+-- | Builds a function that executes the filling of partial parameter
+-- from a full copy (similar to Python's fillDict).
+fillParam :: String -> String -> [Field] -> Q [Dec]
+fillParam sname field_pfx fields = do
+ let fnames = map (\fd -> field_pfx ++ fieldRecordName fd) fields
+ (sname_f, sname_p) = paramTypeNames sname
+ oname_f = "fobj"
+ oname_p = "pobj"
+ name_f = mkName sname_f
+ name_p = mkName sname_p
+ fun_name = mkName $ "fill" ++ sname ++ "Params"
+ le_full = ValD (ConP name_f (map (VarP . mkName . ("f_" ++)) fnames))
+ (NormalB . VarE . mkName $ oname_f) []
+ le_part = ValD (ConP name_p (map (VarP . mkName . ("p_" ++)) fnames))
+ (NormalB . VarE . mkName $ oname_p) []
+ obj_new = foldl (\accu vname -> AppE accu (VarE vname)) (ConE name_f)
+ $ map (mkName . ("n_" ++)) fnames
+ le_new <- mapM buildFromMaybe fnames
+ funt <- [t| $(conT name_f) -> $(conT name_p) -> $(conT name_f) |]
+ let sig = SigD fun_name funt
+ fclause = Clause [VarP (mkName oname_f), VarP (mkName oname_p)]
+ (NormalB $ LetE (le_full:le_part:le_new) obj_new) []
+ fun = FunD fun_name [fclause]
+ return [sig, fun]
+
+-- * Template code for exceptions
+
+-- | Exception simple error message field.
+excErrMsg :: (String, Q Type)
+excErrMsg = ("errMsg", [t| String |])
+
+-- | Builds an exception type definition.
+genException :: String -- ^ Name of new type
+ -> SimpleObject -- ^ Constructor name and parameters
+ -> Q [Dec]
+genException name cons = do
+ let tname = mkName name
+ declD <- buildSimpleCons tname cons
+ (savesig, savefn) <- genSaveSimpleObj tname ("save" ++ name) cons $
+ uncurry saveExcCons
+ (loadsig, loadfn) <- genLoadExc tname ("load" ++ name) cons
+ return [declD, loadsig, loadfn, savesig, savefn]
+
+-- | Generates the \"save\" clause for an entire exception constructor.
+--
+-- This matches the exception with variables named the same as the
+-- constructor fields (just so that the spliced in code looks nicer),
+-- and calls showJSON on it.
+saveExcCons :: String -- ^ The constructor name
+ -> [SimpleField] -- ^ The parameter definitions for this
+ -- constructor
+ -> Q Clause -- ^ Resulting clause
+saveExcCons sname fields = do
+ let cname = mkName sname
+ fnames <- mapM (newName . fst) fields
+ let pat = conP cname (map varP fnames)
+ felems = if null fnames
+ then conE '() -- otherwise, empty list has no type
+ else listE $ map (\f -> [| JSON.showJSON $(varE f) |]) fnames
+ let tup = tupE [ litE (stringL sname), felems ]
+ clause [pat] (normalB [| JSON.showJSON $tup |]) []
+
+-- | Generates load code for a single constructor of an exception.
+--
+-- Generates the code (if there's only one argument, we will use a
+-- list, not a tuple:
+--
+-- @
+-- do
+-- (x1, x2, ...) <- readJSON args
+-- return $ Cons x1 x2 ...
+-- @
+loadExcConstructor :: Name -> String -> [SimpleField] -> Q Exp
+loadExcConstructor inname sname fields = do
+ let name = mkName sname
+ f_names <- mapM (newName . fst) fields
+ let read_args = AppE (VarE 'JSON.readJSON) (VarE inname)
+ let binds = case f_names of
+ [x] -> BindS (ListP [VarP x])
+ _ -> BindS (TupP (map VarP f_names))
+ cval = foldl (\accu fn -> AppE accu (VarE fn)) (ConE name) f_names
+ return $ DoE [binds read_args, NoBindS (AppE (VarE 'return) cval)]
+
+{-| Generates the loadException function.
+
+This generates a quite complicated function, along the lines of:
+
+@
+loadFn (JSArray [JSString name, args]) = case name of
+ "A1" -> do
+ (x1, x2, ...) <- readJSON args
+ return $ A1 x1 x2 ...
+ "a2" -> ...
+ s -> fail $ "Unknown exception" ++ s
+loadFn v = fail $ "Expected array but got " ++ show v
+@
+-}
+genLoadExc :: Name -> String -> SimpleObject -> Q (Dec, Dec)
+genLoadExc tname sname opdefs = do
+ let fname = mkName sname
+ exc_name <- newName "name"
+ exc_args <- newName "args"
+ exc_else <- newName "s"
+ arg_else <- newName "v"
+ fails <- [| fail $ "Unknown exception '" ++ $(varE exc_else) ++ "'" |]
+ -- default match for unknown exception name
+ let defmatch = Match (VarP exc_else) (NormalB fails) []
+ -- the match results (per-constructor blocks)
+ str_matches <-
+ mapM (\(s, params) -> do
+ body_exp <- loadExcConstructor exc_args s params
+ return $ Match (LitP (StringL s)) (NormalB body_exp) [])
+ opdefs
+ -- the first function clause; we can't use [| |] due to TH
+ -- limitations, so we have to build the AST by hand
+ let clause1 = Clause [ConP 'JSON.JSArray
+ [ListP [ConP 'JSON.JSString [VarP exc_name],
+ VarP exc_args]]]
+ (NormalB (CaseE (AppE (VarE 'JSON.fromJSString)
+ (VarE exc_name))
+ (str_matches ++ [defmatch]))) []
+ -- the fail expression for the second function clause
+ fail_type <- [| fail $ "Invalid exception: expected '(string, [args])' " ++
+ " but got " ++ show (pp_value $(varE arg_else)) ++ "'"
+ |]
+ -- the second function clause
+ let clause2 = Clause [VarP arg_else] (NormalB fail_type) []
+ sigt <- [t| JSON.JSValue -> JSON.Result $(conT tname) |]
+ return $ (SigD fname sigt, FunD fname [clause1, clause2])