5 import qualified Data.List as List
6 import qualified Data.Map as Map
7 import qualified Control.Monad as Monad
8 import qualified Control.Arrow as Arrow
9 import qualified Data.Monoid as Monoid
13 import qualified ForSyDe.Backend.VHDL.AST as AST
18 import qualified OccName
21 import qualified TyCon
23 import qualified DataCon
24 import qualified CoreSubst
32 -----------------------------------------------------------------------------
33 -- Functions to generate concurrent statements
34 -----------------------------------------------------------------------------
36 -- Create an unconditional assignment statement
38 Either CoreBndr AST.VHDLName -- ^ The signal to assign to
39 -> AST.Expr -- ^ The expression to assign
40 -> AST.ConcSm -- ^ The resulting concurrent statement
41 mkUncondAssign dst expr = mkAssign dst Nothing expr
43 -- Create a conditional assignment statement
45 Either CoreBndr AST.VHDLName -- ^ The signal to assign to
46 -> AST.Expr -- ^ The condition
47 -> AST.Expr -- ^ The value when true
48 -> AST.Expr -- ^ The value when false
49 -> AST.ConcSm -- ^ The resulting concurrent statement
50 mkCondAssign dst cond true false = mkAssign dst (Just (cond, true)) false
52 -- Create a conditional or unconditional assignment statement
54 Either CoreBndr AST.VHDLName -> -- ^ The signal to assign to
55 Maybe (AST.Expr , AST.Expr) -> -- ^ Optionally, the condition to test for
56 -- and the value to assign when true.
57 AST.Expr -> -- ^ The value to assign when false or no condition
58 AST.ConcSm -- ^ The resulting concurrent statement
59 mkAssign dst cond false_expr =
61 -- I'm not 100% how this assignment AST works, but this gets us what we
63 whenelse = case cond of
64 Just (cond_expr, true_expr) ->
66 true_wform = AST.Wform [AST.WformElem true_expr Nothing]
68 [AST.WhenElse true_wform cond_expr]
70 false_wform = AST.Wform [AST.WformElem false_expr Nothing]
71 dst_name = case dst of
72 Left bndr -> AST.NSimple (varToVHDLId bndr)
74 assign = dst_name AST.:<==: (AST.ConWforms whenelse false_wform Nothing)
79 [AST.Expr] -- | The argument that are applied to function
80 -> AST.VHDLName -- | The binder in which to store the result
81 -> Entity -- | The entity to map against.
82 -> [AST.AssocElem] -- | The resulting port maps
83 mkAssocElems args res entity =
84 -- Create the actual AssocElems
85 Maybe.catMaybes $ zipWith mkAssocElem ports sigs
87 -- Turn the ports and signals from a map into a flat list. This works,
88 -- since the maps must have an identical form by definition. TODO: Check
90 arg_ports = ent_args entity
91 res_port = ent_res entity
92 -- Extract the id part from the (id, type) tuple
93 ports = map (Monad.liftM fst) (res_port : arg_ports)
94 -- Translate signal numbers into names
95 sigs = (vhdlNameToVHDLExpr res : args)
97 -- | Create an VHDL port -> signal association
98 mkAssocElem :: Maybe AST.VHDLId -> AST.Expr -> Maybe AST.AssocElem
99 mkAssocElem (Just port) signal = Just $ Just port AST.:=>: (AST.ADExpr signal)
100 mkAssocElem Nothing _ = Nothing
102 -- | Create an VHDL port -> signal association
103 mkAssocElemIndexed :: Maybe AST.VHDLId -> AST.VHDLId -> AST.VHDLId -> Maybe AST.AssocElem
104 mkAssocElemIndexed (Just port) signal index = Just $ Just port AST.:=>: (AST.ADName (AST.NIndexed (AST.IndexedName
105 (AST.NSimple signal) [AST.PrimName $ AST.NSimple index])))
106 mkAssocElemIndexed Nothing _ _ = Nothing
109 String -- ^ The portmap label
110 -> AST.VHDLId -- ^ The entity name
111 -> [AST.AssocElem] -- ^ The port assignments
113 mkComponentInst label entity_id portassigns = AST.CSISm compins
115 -- We always have a clock port, so no need to map it anywhere but here
116 clk_port = Maybe.fromJust $ mkAssocElem (Just $ mkVHDLExtId "clk") (idToVHDLExpr $ mkVHDLExtId "clk")
117 compins = AST.CompInsSm (mkVHDLExtId label) (AST.IUEntity (AST.NSimple entity_id)) (AST.PMapAspect (portassigns ++ [clk_port]))
119 -----------------------------------------------------------------------------
120 -- Functions to generate VHDL Exprs
121 -----------------------------------------------------------------------------
123 -- Turn a variable reference into a AST expression
124 varToVHDLExpr :: Var.Var -> AST.Expr
126 case Id.isDataConWorkId_maybe var of
127 Just dc -> dataconToVHDLExpr dc
128 -- This is a dataconstructor.
129 -- Not a datacon, just another signal. Perhaps we should check for
130 -- local/global here as well?
131 Nothing -> AST.PrimName $ AST.NSimple $ varToVHDLId var
133 -- Turn a VHDLName into an AST expression
134 vhdlNameToVHDLExpr = AST.PrimName
136 -- Turn a VHDL Id into an AST expression
137 idToVHDLExpr = vhdlNameToVHDLExpr . AST.NSimple
139 -- Turn a Core expression into an AST expression
140 exprToVHDLExpr = varToVHDLExpr . exprToVar
142 -- Turn a alternative constructor into an AST expression. For
143 -- dataconstructors, this is only the constructor itself, not any arguments it
144 -- has. Should not be called with a DEFAULT constructor.
145 altconToVHDLExpr :: CoreSyn.AltCon -> AST.Expr
146 altconToVHDLExpr (DataAlt dc) = dataconToVHDLExpr dc
148 altconToVHDLExpr (LitAlt _) = error "VHDL.conToVHDLExpr Literals not support in case alternatives yet"
149 altconToVHDLExpr DEFAULT = error "VHDL.conToVHDLExpr DEFAULT alternative should not occur here!"
151 -- Turn a datacon (without arguments!) into a VHDL expression.
152 dataconToVHDLExpr :: DataCon.DataCon -> AST.Expr
153 dataconToVHDLExpr dc = AST.PrimLit lit
155 tycon = DataCon.dataConTyCon dc
156 tyname = TyCon.tyConName tycon
157 dcname = DataCon.dataConName dc
158 lit = case Name.getOccString tyname of
159 -- TODO: Do something more robust than string matching
160 "Bit" -> case Name.getOccString dcname of "High" -> "'1'"; "Low" -> "'0'"
161 "Bool" -> case Name.getOccString dcname of "True" -> "true"; "False" -> "false"
163 -----------------------------------------------------------------------------
164 -- Functions dealing with names, variables and ids
165 -----------------------------------------------------------------------------
167 -- Creates a VHDL Id from a binder
171 varToVHDLId = mkVHDLExtId . varToString
173 -- Creates a VHDL Name from a binder
177 varToVHDLName = AST.NSimple . varToVHDLId
179 -- Extracts the binder name as a String
183 varToString = OccName.occNameString . Name.nameOccName . Var.varName
185 -- Get the string version a Var's unique
186 varToStringUniq :: Var.Var -> String
187 varToStringUniq = show . Var.varUnique
189 -- Extracts the string version of the name
190 nameToString :: Name.Name -> String
191 nameToString = OccName.occNameString . Name.nameOccName
193 -- Shortcut for Basic VHDL Ids.
194 -- Can only contain alphanumerics and underscores. The supplied string must be
195 -- a valid basic id, otherwise an error value is returned. This function is
196 -- not meant to be passed identifiers from a source file, use mkVHDLExtId for
198 mkVHDLBasicId :: String -> AST.VHDLId
200 AST.unsafeVHDLBasicId $ (strip_multiscore . strip_leading . strip_invalid) s
202 -- Strip invalid characters.
203 strip_invalid = filter (`elem` ['A'..'Z'] ++ ['a'..'z'] ++ ['0'..'9'] ++ "_.")
204 -- Strip leading numbers and underscores
205 strip_leading = dropWhile (`elem` ['0'..'9'] ++ "_")
206 -- Strip multiple adjacent underscores
207 strip_multiscore = concat . map (\cs ->
213 -- Shortcut for Extended VHDL Id's. These Id's can contain a lot more
214 -- different characters than basic ids, but can never be used to refer to
216 -- Use extended Ids for any values that are taken from the source file.
217 mkVHDLExtId :: String -> AST.VHDLId
219 AST.unsafeVHDLExtId $ strip_invalid s
221 -- Allowed characters, taken from ForSyde's mkVHDLExtId
222 allowed = ['A'..'Z'] ++ ['a'..'z'] ++ ['0'..'9'] ++ " \"#&\\'()*+,./:;<=>_|!$%@?[]^`{}~-"
223 strip_invalid = filter (`elem` allowed)
225 -- Create a record field selector that selects the given label from the record
226 -- stored in the given binder.
227 mkSelectedName :: AST.VHDLName -> AST.VHDLId -> AST.VHDLName
228 mkSelectedName name label =
229 AST.NSelected $ name AST.:.: (AST.SSimple label)
231 -----------------------------------------------------------------------------
232 -- Functions dealing with VHDL types
233 -----------------------------------------------------------------------------
235 -- | Maps the string name (OccName) of a type to the corresponding VHDL type,
236 -- for a few builtin types.
239 ("Bit", std_logicTM),
240 ("Bool", booleanTM) -- TysWiredIn.boolTy
243 -- Translate a Haskell type to a VHDL type, generating a new type if needed.
244 vhdl_ty :: Type.Type -> VHDLSession AST.TypeMark
246 typemap <- getA vsTypes
247 let builtin_ty = do -- See if this is a tycon and lookup its name
248 (tycon, args) <- Type.splitTyConApp_maybe ty
249 let name = Name.getOccString (TyCon.tyConName tycon)
250 Map.lookup name builtin_types
251 -- If not a builtin type, try the custom types
252 let existing_ty = (fmap fst) $ Map.lookup (OrdType ty) typemap
253 case Monoid.getFirst $ Monoid.mconcat (map Monoid.First [builtin_ty, existing_ty]) of
254 -- Found a type, return it
256 -- No type yet, try to construct it
258 newty_maybe <- (construct_vhdl_ty ty)
260 Just (ty_id, ty_def) -> do
261 -- TODO: Check name uniqueness
262 modA vsTypes (Map.insert (OrdType ty) (ty_id, ty_def))
264 Nothing -> error $ "Unsupported Haskell type: " ++ pprString ty
266 -- Construct a new VHDL type for the given Haskell type.
267 construct_vhdl_ty :: Type.Type -> VHDLSession (Maybe (AST.TypeMark, Either AST.TypeDef AST.SubtypeIn))
268 construct_vhdl_ty ty = do
269 case Type.splitTyConApp_maybe ty of
270 Just (tycon, args) -> do
271 let name = Name.getOccString (TyCon.tyConName tycon)
274 res <- mk_vector_ty (tfvec_len ty) (tfvec_elem ty)
275 return $ Just $ (Arrow.second Right) res
277 -- res <- mk_vector_ty (sized_word_len ty) ty
278 -- return $ Just $ (Arrow.second Left) res
280 res <- mk_natural_ty 0 (ranged_word_bound ty)
281 return $ Just $ (Arrow.second Right) res
282 -- Create a custom type from this tycon
283 otherwise -> mk_tycon_ty tycon args
284 Nothing -> return $ Nothing
286 -- | Create VHDL type for a custom tycon
287 mk_tycon_ty :: TyCon.TyCon -> [Type.Type] -> VHDLSession (Maybe (AST.TypeMark, Either AST.TypeDef AST.SubtypeIn))
288 mk_tycon_ty tycon args =
289 case TyCon.tyConDataCons tycon of
290 -- Not an algebraic type
291 [] -> error $ "Only custom algebraic types are supported: " ++ pprString tycon
293 let arg_tys = DataCon.dataConRepArgTys dc
294 -- TODO: CoreSubst docs say each Subs can be applied only once. Is this a
295 -- violation? Or does it only mean not to apply it again to the same
297 let real_arg_tys = map (CoreSubst.substTy subst) arg_tys
298 elem_tys <- mapM vhdl_ty real_arg_tys
299 let elems = zipWith AST.ElementDec recordlabels elem_tys
300 -- For a single construct datatype, build a record with one field for
302 -- TODO: Add argument type ids to this, to ensure uniqueness
303 -- TODO: Special handling for tuples?
304 let ty_id = mkVHDLExtId $ nameToString (TyCon.tyConName tycon)
305 let ty_def = AST.TDR $ AST.RecordTypeDef elems
306 return $ Just (ty_id, Left ty_def)
307 dcs -> error $ "Only single constructor datatypes supported: " ++ pprString tycon
309 -- Create a subst that instantiates all types passed to the tycon
310 -- TODO: I'm not 100% sure that this is the right way to do this. It seems
311 -- to work so far, though..
312 tyvars = TyCon.tyConTyVars tycon
313 subst = CoreSubst.extendTvSubstList CoreSubst.emptySubst (zip tyvars args)
314 -- Generate a bunch of labels for fields of a record
315 recordlabels = map (\c -> mkVHDLBasicId [c]) ['A'..'Z']
317 -- | Create a VHDL vector type
319 Int -- ^ The length of the vector
320 -> Type.Type -- ^ The Haskell element type of the Vector
321 -> VHDLSession (AST.TypeMark, AST.SubtypeIn) -- The typemark created.
323 mk_vector_ty len el_ty = do
324 elem_types_map <- getA vsElemTypes
325 el_ty_tm <- vhdl_ty el_ty
326 let ty_id = mkVHDLExtId $ "vector-"++ (AST.fromVHDLId el_ty_tm) ++ "-0_to_" ++ (show len)
327 let range = AST.ConstraintIndex $ AST.IndexConstraint [AST.ToRange (AST.PrimLit "0") (AST.PrimLit $ show (len - 1))]
328 let existing_elem_ty = (fmap fst) $ Map.lookup (OrdType el_ty) elem_types_map
329 case existing_elem_ty of
331 let ty_def = AST.SubtypeIn t (Just range)
332 return (ty_id, ty_def)
334 let vec_id = mkVHDLExtId $ "vector_" ++ (AST.fromVHDLId el_ty_tm)
335 let vec_def = AST.TDA $ AST.UnconsArrayDef [tfvec_indexTM] el_ty_tm
336 modA vsElemTypes (Map.insert (OrdType el_ty) (vec_id, vec_def))
337 --modA vsTypeFuns (Map.insert (OrdType el_ty) (genUnconsVectorFuns el_ty_tm vec_id))
338 let ty_def = AST.SubtypeIn vec_id (Just range)
339 return (ty_id, ty_def)
342 Int -- ^ The minimum bound (> 0)
343 -> Int -- ^ The maximum bound (> minimum bound)
344 -> VHDLSession (AST.TypeMark, AST.SubtypeIn) -- The typemark created.
345 mk_natural_ty min_bound max_bound = do
346 let ty_id = mkVHDLExtId $ "nat_" ++ (show min_bound) ++ "_to_" ++ (show max_bound)
347 let range = AST.ConstraintRange $ AST.SubTypeRange (AST.PrimLit $ (show min_bound)) (AST.PrimLit $ (show max_bound))
348 let ty_def = AST.SubtypeIn naturalTM (Just range)
349 return (ty_id, ty_def)
351 -- Finds the field labels for VHDL type generated for the given Core type,
352 -- which must result in a record type.
353 getFieldLabels :: Type.Type -> VHDLSession [AST.VHDLId]
354 getFieldLabels ty = do
355 -- Ensure that the type is generated (but throw away it's VHDLId)
357 -- Get the types map, lookup and unpack the VHDL TypeDef
358 types <- getA vsTypes
359 case Map.lookup (OrdType ty) types of
360 Just (_, Left (AST.TDR (AST.RecordTypeDef elems))) -> return $ map (\(AST.ElementDec id _) -> id) elems
361 _ -> error $ "VHDL.getFieldLabels Type not found or not a record type? This should not happen! Type: " ++ (show ty)