import Data.Accessor
import qualified Data.Accessor.MonadState as MonadState
import Text.Regex.Posix
+import Debug.Trace
-- ForSyDe
import qualified ForSyDe.Backend.VHDL.AST as AST
-- GHC API
+import CoreSyn
import qualified Type
import qualified Name
+import qualified OccName
+import qualified Var
+import qualified Id
+import qualified IdInfo
import qualified TyCon
+import qualified TcType
+import qualified DataCon
+import qualified CoreSubst
+import qualified CoreUtils
import Outputable ( showSDoc, ppr )
-- Local imports
import HsValueMap
import Pretty
import CoreTools
+import Constants
+import Generate
+import GlobalNameTable
createDesignFiles ::
- FlatFuncMap
+ [(CoreSyn.CoreBndr, CoreSyn.CoreExpr)]
-> [(AST.VHDLId, AST.DesignFile)]
-createDesignFiles flatfuncmap =
- (mkVHDLBasicId "types", AST.DesignFile ieee_context [type_package]) :
+createDesignFiles binds =
+ (mkVHDLBasicId "types", AST.DesignFile ieee_context [type_package_dec, type_package_body]) :
map (Arrow.second $ AST.DesignFile full_context) units
where
- init_session = VHDLSession Map.empty builtin_funcs
+ init_session = VHDLSession Map.empty Map.empty Map.empty Map.empty globalNameTable
(units, final_session) =
- State.runState (createLibraryUnits flatfuncmap) init_session
- ty_decls = Map.elems (final_session ^. vsTypes)
+ State.runState (createLibraryUnits binds) init_session
+ tyfun_decls = Map.elems (final_session ^.vsTypeFuns)
+ ty_decls = map mktydecl $ Map.elems (final_session ^. vsTypes)
+ vec_decls = map (\(v_id, v_def) -> AST.PDITD $ AST.TypeDec v_id v_def) (Map.elems (final_session ^. vsElemTypes))
+ tfvec_index_decl = AST.PDISD $ AST.SubtypeDec tfvec_indexTM tfvec_index_def
+ tfvec_range = AST.ConstraintRange $ AST.SubTypeRange (AST.PrimLit "-1") (AST.PrimName $ AST.NAttribute $ AST.AttribName (AST.NSimple integerTM) highId Nothing)
+ tfvec_index_def = AST.SubtypeIn integerTM (Just tfvec_range)
ieee_context = [
AST.Library $ mkVHDLBasicId "IEEE",
mkUseAll ["IEEE", "std_logic_1164"],
full_context =
mkUseAll ["work", "types"]
: ieee_context
- type_package = AST.LUPackageDec $ AST.PackageDec (mkVHDLBasicId "types") (map (AST.PDITD . snd) ty_decls)
+ type_package_dec = AST.LUPackageDec $ AST.PackageDec (mkVHDLBasicId "types") ([tfvec_index_decl] ++ vec_decls ++ ty_decls ++ subProgSpecs)
+ type_package_body = AST.LUPackageBody $ AST.PackageBody typesId (concat tyfun_decls)
+ subProgSpecs = concat (map subProgSpec tyfun_decls)
+ subProgSpec = map (\(AST.SubProgBody spec _ _) -> AST.PDISS spec)
+ mktydecl :: (AST.VHDLId, Either AST.TypeDef AST.SubtypeIn) -> AST.PackageDecItem
+ mktydecl (ty_id, Left ty_def) = AST.PDITD $ AST.TypeDec ty_id ty_def
+ mktydecl (ty_id, Right ty_def) = AST.PDISD $ AST.SubtypeDec ty_id ty_def
-- Create a use foo.bar.all statement. Takes a list of components in the used
-- name. Must contain at least two components
select prefix s = AST.NSelected $ prefix AST.:.: (AST.SSimple $ mkVHDLBasicId s)
createLibraryUnits ::
- FlatFuncMap
+ [(CoreSyn.CoreBndr, CoreSyn.CoreExpr)]
-> VHDLState [(AST.VHDLId, [AST.LibraryUnit])]
-createLibraryUnits flatfuncmap = do
- let hsfuncs = Map.keys flatfuncmap
- let flatfuncs = Map.elems flatfuncmap
- entities <- Monad.zipWithM createEntity hsfuncs flatfuncs
- archs <- Monad.zipWithM createArchitecture hsfuncs flatfuncs
+createLibraryUnits binds = do
+ entities <- Monad.mapM createEntity binds
+ archs <- Monad.mapM createArchitecture binds
return $ zipWith
(\ent arch ->
let AST.EntityDec id _ = ent in
-- | Create an entity for a given function
createEntity ::
- HsFunction -- | The function signature
- -> FlatFunction -- | The FlatFunction
+ (CoreSyn.CoreBndr, CoreSyn.CoreExpr) -- | The function
-> VHDLState AST.EntityDec -- | The resulting entity
-createEntity hsfunc flatfunc = do
- let sigs = flat_sigs flatfunc
- let args = flat_args flatfunc
- let res = flat_res flatfunc
- args' <- Traversable.traverse (Traversable.traverse (mkMap sigs)) args
- res' <- Traversable.traverse (mkMap sigs) res
- let ent_decl' = createEntityAST hsfunc args' res'
+createEntity (fname, expr) = do
+ -- Strip off lambda's, these will be arguments
+ let (args, letexpr) = CoreSyn.collectBinders expr
+ args' <- Monad.mapM mkMap args
+ -- There must be a let at top level
+ let (CoreSyn.Let binds (CoreSyn.Var res)) = letexpr
+ res' <- mkMap res
+ let vhdl_id = mkVHDLBasicId $ bndrToString fname ++ "_" ++ varToStringUniq fname
+ let ent_decl' = createEntityAST vhdl_id args' res'
let AST.EntityDec entity_id _ = ent_decl'
let signature = Entity entity_id args' res'
- modA vsSignatures (Map.insert hsfunc signature)
+ modA vsSignatures (Map.insert fname signature)
return ent_decl'
where
- mkMap ::
- [(SignalId, SignalInfo)]
- -> SignalId
+ mkMap ::
+ --[(SignalId, SignalInfo)]
+ CoreSyn.CoreBndr
-> VHDLState VHDLSignalMapElement
-- We only need the vsTypes element from the state
- mkMap sigmap = MonadState.lift vsTypes . (\id ->
+ mkMap = (\bndr ->
let
- info = Maybe.fromMaybe
- (error $ "Signal not found in the name map? This should not happen!")
- (lookup id sigmap)
- nm = Maybe.fromMaybe
- (error $ "Signal not named? This should not happen!")
- (sigName info)
- ty = sigTy info
+ --info = Maybe.fromMaybe
+ -- (error $ "Signal not found in the name map? This should not happen!")
+ -- (lookup id sigmap)
+ -- Assume the bndr has a valid VHDL id already
+ id = bndrToVHDLId bndr
+ ty = Var.varType bndr
in
- if isPortSigUse $ sigUse info
+ if True -- isPortSigUse $ sigUse info
then do
type_mark <- vhdl_ty ty
- return $ Just (mkVHDLExtId nm, type_mark)
+ return $ Just (id, type_mark)
else
return $ Nothing
)
-- | Create the VHDL AST for an entity
createEntityAST ::
- HsFunction -- | The signature of the function we're working with
- -> [VHDLSignalMap] -- | The entity's arguments
- -> VHDLSignalMap -- | The entity's result
- -> AST.EntityDec -- | The entity with the ent_decl filled in as well
+ AST.VHDLId -- | The name of the function
+ -> [VHDLSignalMapElement] -- | The entity's arguments
+ -> VHDLSignalMapElement -- | The entity's result
+ -> AST.EntityDec -- | The entity with the ent_decl filled in as well
-createEntityAST hsfunc args res =
+createEntityAST vhdl_id args res =
AST.EntityDec vhdl_id ports
where
- vhdl_id = mkEntityId hsfunc
- ports = concatMap (mapToPorts AST.In) args
- ++ mapToPorts AST.Out res
- ++ clk_port
- mapToPorts :: AST.Mode -> VHDLSignalMap -> [AST.IfaceSigDec]
- mapToPorts mode m =
- Maybe.catMaybes $ map (mkIfaceSigDec mode) (Foldable.toList m)
+ -- Create a basic Id, since VHDL doesn't grok filenames with extended Ids.
+ ports = Maybe.catMaybes $
+ map (mkIfaceSigDec AST.In) args
+ ++ [mkIfaceSigDec AST.Out res]
+ ++ [clk_port]
-- Add a clk port if we have state
- clk_port = if hasState hsfunc
+ clk_port = if True -- hasState hsfunc
then
- [AST.IfaceSigDec (mkVHDLExtId "clk") AST.In VHDL.std_logic_ty]
+ Just $ AST.IfaceSigDec (mkVHDLExtId "clk") AST.In VHDL.std_logic_ty
else
- []
+ Nothing
-- | Create a port declaration
mkIfaceSigDec ::
-- | Create an architecture for a given function
createArchitecture ::
- HsFunction -- ^ The function signature
- -> FlatFunction -- ^ The FlatFunction
+ (CoreSyn.CoreBndr, CoreSyn.CoreExpr) -- ^ The function
-> VHDLState AST.ArchBody -- ^ The architecture for this function
-createArchitecture hsfunc flatfunc = do
+createArchitecture (fname, expr) = do
signaturemap <- getA vsSignatures
let signature = Maybe.fromMaybe
- (error $ "Generating architecture for function " ++ (prettyShow hsfunc) ++ "without signature? This should not happen!")
- (Map.lookup hsfunc signaturemap)
+ (error $ "Generating architecture for function " ++ (pprString fname) ++ "without signature? This should not happen!")
+ (Map.lookup fname signaturemap)
let entity_id = ent_id signature
- -- Create signal declarations for all internal and state signals
- sig_dec_maybes <- mapM (mkSigDec' . snd) sigs
+ -- Strip off lambda's, these will be arguments
+ let (args, letexpr) = CoreSyn.collectBinders expr
+ -- There must be a let at top level
+ let (CoreSyn.Let (CoreSyn.Rec binds) (Var res)) = letexpr
+
+ -- Create signal declarations for all binders in the let expression, except
+ -- for the output port (that will already have an output port declared in
+ -- the entity).
+ sig_dec_maybes <- mapM (mkSigDec' . fst) (filter ((/=res).fst) binds)
let sig_decs = Maybe.catMaybes $ sig_dec_maybes
- -- Create concurrent statements for all signal definitions
- let statements = zipWith (mkConcSm signaturemap sigs) defs [0..]
+
+ statementss <- Monad.mapM mkConcSm binds
+ let statements = concat statementss
return $ AST.ArchBody (mkVHDLBasicId "structural") (AST.NSimple entity_id) (map AST.BDISD sig_decs) (statements ++ procs')
where
- sigs = flat_sigs flatfunc
- args = flat_args flatfunc
- res = flat_res flatfunc
- defs = flat_defs flatfunc
- procs = map mkStateProcSm (makeStatePairs flatfunc)
+ procs = map mkStateProcSm [] -- (makeStatePairs flatfunc)
procs' = map AST.CSPSm procs
-- mkSigDec only uses vsTypes from the state
- mkSigDec' = MonadState.lift vsTypes . mkSigDec
+ mkSigDec' = mkSigDec
-- | Looks up all pairs of old state, new state signals, together with
-- the state id they represent.
rising_edge_clk = AST.PrimFCall $ AST.FCall rising_edge [Nothing AST.:=>: (AST.ADName $ AST.NSimple clk)]
statement = AST.IfSm rising_edge_clk [assign] [] Nothing
-mkSigDec :: SignalInfo -> TypeState (Maybe AST.SigDec)
-mkSigDec info =
- let use = sigUse info in
- if isInternalSigUse use || isStateSigUse use then do
- type_mark <- vhdl_ty ty
- return $ Just (AST.SigDec (getSignalId info) type_mark Nothing)
+mkSigDec :: CoreSyn.CoreBndr -> VHDLState (Maybe AST.SigDec)
+mkSigDec bndr =
+ if True then do --isInternalSigUse use || isStateSigUse use then do
+ type_mark <- vhdl_ty $ Var.varType bndr
+ return $ Just (AST.SigDec (bndrToVHDLId bndr) type_mark Nothing)
else
return Nothing
- where
- ty = sigTy info
-- | Creates a VHDL Id from a named SignalInfo. Errors out if the SignalInfo
-- is not named.
(error $ "Unnamed signal? This should not happen!")
(sigName info)
--- | Transforms a signal definition into a VHDL concurrent statement
+-- | Transforms a core binding into a VHDL concurrent statement
mkConcSm ::
- SignatureMap -- ^ The interfaces of functions in the session
- -> [(SignalId, SignalInfo)] -- ^ The signals in the current architecture
- -> SigDef -- ^ The signal definition
- -> Int -- ^ A number that will be unique for all
- -- concurrent statements in the architecture.
- -> AST.ConcSm -- ^ The corresponding VHDL component instantiation.
-
-mkConcSm signatures sigs (FApp hsfunc args res) num =
- let
- signature = Maybe.fromMaybe
- (error $ "Using function '" ++ (prettyShow hsfunc) ++ "' without signature? This should not happen!")
- (Map.lookup hsfunc signatures)
- entity_id = ent_id signature
- label = (AST.fromVHDLId entity_id) ++ "_" ++ (show num)
- -- Add a clk port if we have state
- clk_port = Maybe.fromJust $ mkAssocElem (Just $ mkVHDLExtId "clk") "clk"
- portmaps = mkAssocElems sigs args res signature ++ (if hasState hsfunc then [clk_port] else [])
- in
- AST.CSISm $ AST.CompInsSm (mkVHDLExtId label) (AST.IUEntity (AST.NSimple entity_id)) (AST.PMapAspect portmaps)
+ (CoreSyn.CoreBndr, CoreSyn.CoreExpr) -- ^ The binding to process
+ -> VHDLState [AST.ConcSm] -- ^ The corresponding VHDL component instantiations.
+
+
+-- Ignore Cast expressions, they should not longer have any meaning as long as
+-- the type works out.
+mkConcSm (bndr, Cast expr ty) = mkConcSm (bndr, expr)
+
+mkConcSm (bndr, app@(CoreSyn.App _ _))= do
+ let (CoreSyn.Var f, args) = CoreSyn.collectArgs app
+ let valargs' = filter isValArg args
+ let valargs = filter (\(CoreSyn.Var bndr) -> not (Id.isDictId bndr)) valargs'
+ case Var.globalIdVarDetails f of
+ IdInfo.DataConWorkId dc ->
+ -- It's a datacon. Create a record from its arguments.
+ -- First, filter out type args. TODO: Is this the best way to do this?
+ -- The types should already have been taken into acocunt when creating
+ -- the signal, so this should probably work...
+ --let valargs = filter isValArg args in
+ if all is_var valargs then do
+ labels <- getFieldLabels (CoreUtils.exprType app)
+ return $ zipWith mkassign labels valargs
+ else
+ error $ "VHDL.mkConcSm Not in normal form: One ore more complex arguments: " ++ pprString args
+ where
+ mkassign :: AST.VHDLId -> CoreExpr -> AST.ConcSm
+ mkassign label (Var arg) =
+ let sel_name = mkSelectedName bndr label in
+ mkUncondAssign (Right sel_name) (varToVHDLExpr arg)
+ IdInfo.VanillaGlobal -> do
+ -- It's a global value imported from elsewhere. These can be builtin
+ -- functions.
+ funSignatures <- getA vsNameTable
+ signatures <- getA vsSignatures
+ case (Map.lookup (bndrToString f) funSignatures) of
+ Just (arg_count, builder) ->
+ if length valargs == arg_count then
+ case builder of
+ Left funBuilder ->
+ let
+ sigs = map (bndrToString.varBndr) valargs
+ sigsNames = map (\signal -> (AST.PrimName (AST.NSimple (mkVHDLExtId signal)))) sigs
+ func = funBuilder sigsNames
+ src_wform = AST.Wform [AST.WformElem func Nothing]
+ dst_name = AST.NSimple (mkVHDLExtId (bndrToString bndr))
+ assign = dst_name AST.:<==: (AST.ConWforms [] src_wform Nothing)
+ in
+ return [AST.CSSASm assign]
+ Right genBuilder ->
+ let
+ sigs = map varBndr valargs
+ signature = Maybe.fromMaybe
+ (error $ "Using function '" ++ (bndrToString (head sigs)) ++ "' without signature? This should not happen!")
+ (Map.lookup (head sigs) signatures)
+ arg_names = map (mkVHDLExtId . bndrToString) (tail sigs)
+ dst_name = mkVHDLExtId (bndrToString bndr)
+ genSm = genBuilder 4 signature (arg_names ++ [dst_name])
+ in return [AST.CSGSm genSm]
+ else
+ error $ "VHDL.mkConcSm Incorrect number of arguments to builtin function: " ++ pprString f ++ " Args: " ++ pprString valargs
+ Nothing -> error $ "Using function from another module that is not a known builtin: " ++ pprString f
+ IdInfo.NotGlobalId -> do
+ signatures <- getA vsSignatures
+ -- This is a local id, so it should be a function whose definition we
+ -- have and which can be turned into a component instantiation.
+ let
+ signature = Maybe.fromMaybe
+ (error $ "Using function '" ++ (bndrToString f) ++ "' without signature? This should not happen!")
+ (Map.lookup f signatures)
+ entity_id = ent_id signature
+ label = "comp_ins_" ++ bndrToString bndr
+ -- Add a clk port if we have state
+ --clk_port = Maybe.fromJust $ mkAssocElem (Just $ mkVHDLExtId "clk") "clk"
+ clk_port = Maybe.fromJust $ mkAssocElem (Just $ mkVHDLExtId "clk") "clk"
+ --portmaps = mkAssocElems sigs args res signature ++ (if hasState hsfunc then [clk_port] else [])
+ portmaps = clk_port : mkAssocElems args bndr signature
+ in
+ return [AST.CSISm $ AST.CompInsSm (mkVHDLExtId label) (AST.IUEntity (AST.NSimple entity_id)) (AST.PMapAspect portmaps)]
+ details -> error $ "Calling unsupported function " ++ pprString f ++ " with GlobalIdDetails " ++ pprString details
+
+-- A single alt case must be a selector. This means thee scrutinee is a simple
+-- variable, the alternative is a dataalt with a single non-wild binder that
+-- is also returned.
+mkConcSm (bndr, expr@(Case (Var scrut) b ty [alt])) =
+ case alt of
+ (DataAlt dc, bndrs, (Var sel_bndr)) -> do
+ case List.elemIndex sel_bndr bndrs of
+ Just i -> do
+ labels <- getFieldLabels (Id.idType scrut)
+ let label = labels!!i
+ let sel_name = mkSelectedName scrut label
+ let sel_expr = AST.PrimName sel_name
+ return [mkUncondAssign (Left bndr) sel_expr]
+ Nothing -> error $ "VHDL.mkConcSM Not in normal form: Not a selector case:\n" ++ (pprString expr)
+
+ _ -> error $ "VHDL.mkConcSM Not in normal form: Not a selector case:\n" ++ (pprString expr)
-mkConcSm _ sigs (UncondDef src dst) _ =
+-- Multiple case alt are be conditional assignments and have only wild
+-- binders in the alts and only variables in the case values and a variable
+-- for a scrutinee. We check the constructor of the second alt, since the
+-- first is the default case, if there is any.
+mkConcSm (bndr, (Case (Var scrut) b ty [(_, _, Var false), (con, _, Var true)])) =
let
- src_expr = vhdl_expr src
- src_wform = AST.Wform [AST.WformElem src_expr Nothing]
- dst_name = AST.NSimple (getSignalId $ signalInfo sigs dst)
- assign = dst_name AST.:<==: (AST.ConWforms [] src_wform Nothing)
+ cond_expr = (varToVHDLExpr scrut) AST.:=: (conToVHDLExpr con)
+ true_expr = (varToVHDLExpr true)
+ false_expr = (varToVHDLExpr false)
+ in
+ return [mkCondAssign (Left bndr) cond_expr true_expr false_expr]
+mkConcSm (_, (Case (Var _) _ _ alts)) = error "VHDL.mkConcSm Not in normal form: Case statement with more than two alternatives"
+mkConcSm (_, Case _ _ _ _) = error "VHDL.mkConcSm Not in normal form: Case statement has does not have a simple variable as scrutinee"
+mkConcSm (bndr, expr) = error $ "VHDL.mkConcSM Unsupported binding in let expression: " ++ pprString bndr ++ " = " ++ pprString expr
+
+-- Create an unconditional assignment statement
+mkUncondAssign ::
+ Either CoreBndr AST.VHDLName -- ^ The signal to assign to
+ -> AST.Expr -- ^ The expression to assign
+ -> AST.ConcSm -- ^ The resulting concurrent statement
+mkUncondAssign dst expr = mkAssign dst Nothing expr
+
+-- Create a conditional assignment statement
+mkCondAssign ::
+ Either CoreBndr AST.VHDLName -- ^ The signal to assign to
+ -> AST.Expr -- ^ The condition
+ -> AST.Expr -- ^ The value when true
+ -> AST.Expr -- ^ The value when false
+ -> AST.ConcSm -- ^ The resulting concurrent statement
+mkCondAssign dst cond true false = mkAssign dst (Just (cond, true)) false
+
+-- Create a conditional or unconditional assignment statement
+mkAssign ::
+ Either CoreBndr AST.VHDLName -> -- ^ The signal to assign to
+ Maybe (AST.Expr , AST.Expr) -> -- ^ Optionally, the condition to test for
+ -- and the value to assign when true.
+ AST.Expr -> -- ^ The value to assign when false or no condition
+ AST.ConcSm -- ^ The resulting concurrent statement
+
+mkAssign dst cond false_expr =
+ let
+ -- I'm not 100% how this assignment AST works, but this gets us what we
+ -- want...
+ whenelse = case cond of
+ Just (cond_expr, true_expr) ->
+ let
+ true_wform = AST.Wform [AST.WformElem true_expr Nothing]
+ in
+ [AST.WhenElse true_wform cond_expr]
+ Nothing -> []
+ false_wform = AST.Wform [AST.WformElem false_expr Nothing]
+ dst_name = case dst of
+ Left bndr -> AST.NSimple (bndrToVHDLId bndr)
+ Right name -> name
+ assign = dst_name AST.:<==: (AST.ConWforms whenelse false_wform Nothing)
in
AST.CSSASm assign
+
+-- Create a record field selector that selects the given label from the record
+-- stored in the given binder.
+mkSelectedName :: CoreBndr -> AST.VHDLId -> AST.VHDLName
+mkSelectedName bndr label =
+ let
+ sel_prefix = AST.NSimple $ bndrToVHDLId bndr
+ sel_suffix = AST.SSimple $ label
+ in
+ AST.NSelected $ sel_prefix AST.:.: sel_suffix
+
+-- Finds the field labels for VHDL type generated for the given Core type,
+-- which must result in a record type.
+getFieldLabels :: Type.Type -> VHDLState [AST.VHDLId]
+getFieldLabels ty = do
+ -- Ensure that the type is generated (but throw away it's VHDLId)
+ vhdl_ty ty
+ -- Get the types map, lookup and unpack the VHDL TypeDef
+ types <- getA vsTypes
+ case Map.lookup (OrdType ty) types of
+ Just (_, Left (AST.TDR (AST.RecordTypeDef elems))) -> return $ map (\(AST.ElementDec id _) -> id) elems
+ _ -> error $ "VHDL.getFieldLabels Type not found or not a record type? This should not happen! Type: " ++ (show ty)
+
+-- Turn a variable reference into a AST expression
+varToVHDLExpr :: Var.Var -> AST.Expr
+varToVHDLExpr var = AST.PrimName $ AST.NSimple $ bndrToVHDLId var
+
+-- Turn a constructor into an AST expression. For dataconstructors, this is
+-- only the constructor itself, not any arguments it has. Should not be called
+-- with a DEFAULT constructor.
+conToVHDLExpr :: CoreSyn.AltCon -> AST.Expr
+conToVHDLExpr (DataAlt dc) = AST.PrimLit lit
+ where
+ tycon = DataCon.dataConTyCon dc
+ tyname = TyCon.tyConName tycon
+ dcname = DataCon.dataConName dc
+ lit = case Name.getOccString tyname of
+ -- TODO: Do something more robust than string matching
+ "Bit" -> case Name.getOccString dcname of "High" -> "'1'"; "Low" -> "'0'"
+ "Bool" -> case Name.getOccString dcname of "True" -> "true"; "False" -> "false"
+conToVHDLExpr (LitAlt _) = error "VHDL.conToVHDLExpr Literals not support in case alternatives yet"
+conToVHDLExpr DEFAULT = error "VHDL.conToVHDLExpr DEFAULT alternative should not occur here!"
+
+
+
+{-
+mkConcSm sigs (UncondDef src dst) _ = do
+ src_expr <- vhdl_expr src
+ let src_wform = AST.Wform [AST.WformElem src_expr Nothing]
+ let dst_name = AST.NSimple (getSignalId $ signalInfo sigs dst)
+ let assign = dst_name AST.:<==: (AST.ConWforms [] src_wform Nothing)
+ return $ AST.CSSASm assign
where
- vhdl_expr (Left id) = mkIdExpr sigs id
+ vhdl_expr (Left id) = return $ mkIdExpr sigs id
vhdl_expr (Right expr) =
case expr of
(EqLit id lit) ->
- (mkIdExpr sigs id) AST.:=: (AST.PrimLit lit)
- (Literal lit _) ->
- AST.PrimLit lit
+ return $ (mkIdExpr sigs id) AST.:=: (AST.PrimLit lit)
+ (Literal lit Nothing) ->
+ return $ AST.PrimLit lit
+ (Literal lit (Just ty)) -> do
+ -- Create a cast expression, which is just a function call using the
+ -- type name as the function name.
+ let litexpr = AST.PrimLit lit
+ ty_id <- vhdl_ty ty
+ let ty_name = AST.NSimple ty_id
+ let args = [Nothing AST.:=>: (AST.ADExpr litexpr)]
+ return $ AST.PrimFCall $ AST.FCall ty_name args
(Eq a b) ->
- (mkIdExpr sigs a) AST.:=: (mkIdExpr sigs b)
+ return $ (mkIdExpr sigs a) AST.:=: (mkIdExpr sigs b)
-mkConcSm _ sigs (CondDef cond true false dst) _ =
+mkConcSm sigs (CondDef cond true false dst) _ =
let
cond_expr = mkIdExpr sigs cond
true_expr = mkIdExpr sigs true
dst_name = AST.NSimple (getSignalId $ signalInfo sigs dst)
assign = dst_name AST.:<==: (AST.ConWforms [whenelse] false_wform Nothing)
in
- AST.CSSASm assign
-
+ return $ AST.CSSASm assign
+-}
-- | Turn a SignalId into a VHDL Expr
mkIdExpr :: [(SignalId, SignalInfo)] -> SignalId -> AST.Expr
mkIdExpr sigs id =
AST.PrimName src_name
mkAssocElems ::
- [(SignalId, SignalInfo)] -- | The signals in the current architecture
- -> [SignalMap] -- | The signals that are applied to function
- -> SignalMap -- | the signals in which to store the function result
+ [CoreSyn.CoreExpr] -- | The argument that are applied to function
+ -> CoreSyn.CoreBndr -- | The binder in which to store the result
-> Entity -- | The entity to map against.
-> [AST.AssocElem] -- | The resulting port maps
-mkAssocElems sigmap args res entity =
+mkAssocElems args res entity =
-- Create the actual AssocElems
Maybe.catMaybes $ zipWith mkAssocElem ports sigs
where
-- Turn the ports and signals from a map into a flat list. This works,
-- since the maps must have an identical form by definition. TODO: Check
-- the similar form?
- arg_ports = concat (map Foldable.toList (ent_args entity))
- res_ports = Foldable.toList (ent_res entity)
- arg_sigs = (concat (map Foldable.toList args))
- res_sigs = Foldable.toList res
+ arg_ports = ent_args entity
+ res_port = ent_res entity
-- Extract the id part from the (id, type) tuple
- ports = (map (fmap fst) (arg_ports ++ res_ports))
+ ports = map (Monad.liftM fst) (res_port : arg_ports)
-- Translate signal numbers into names
- sigs = (map (lookupSigName sigmap) (arg_sigs ++ res_sigs))
+ sigs = (bndrToString res : map (bndrToString.varBndr) args)
+
+-- Turns a Var CoreExpr into the Id inside it. Will of course only work for
+-- simple Var CoreExprs, not complexer ones.
+varBndr :: CoreSyn.CoreExpr -> Var.Id
+varBndr (CoreSyn.Var id) = id
-- | Look up a signal in the signal name map
lookupSigName :: [(SignalId, SignalInfo)] -> SignalId -> String
std_logic_ty = AST.unsafeVHDLBasicId "std_logic"
-- Translate a Haskell type to a VHDL type
-vhdl_ty :: Type.Type -> TypeState AST.TypeMark
+vhdl_ty :: Type.Type -> VHDLState AST.TypeMark
vhdl_ty ty = do
- typemap <- State.get
+ typemap <- getA vsTypes
let builtin_ty = do -- See if this is a tycon and lookup its name
(tycon, args) <- Type.splitTyConApp_maybe ty
let name = Name.getOccString (TyCon.tyConName tycon)
Just t -> return t
-- No type yet, try to construct it
Nothing -> do
- let new_ty = do
- -- Use the Maybe Monad for failing when one of these fails
- (tycon, args) <- Type.splitTyConApp_maybe ty
- let name = Name.getOccString (TyCon.tyConName tycon)
- case name of
- "FSVec" -> Just $ mk_vector_ty (fsvec_len ty) ty
- "SizedWord" -> Just $ mk_vector_ty (sized_word_len ty) ty
- otherwise -> Nothing
- -- Return new_ty when a new type was successfully created
- Maybe.fromMaybe
- (error $ "Unsupported Haskell type: " ++ (showSDoc $ ppr ty))
- new_ty
+ newty_maybe <- (construct_vhdl_ty ty)
+ case newty_maybe of
+ Just (ty_id, ty_def) -> do
+ -- TODO: Check name uniqueness
+ modA vsTypes (Map.insert (OrdType ty) (ty_id, ty_def))
+ return ty_id
+ Nothing -> error $ "Unsupported Haskell type: " ++ (showSDoc $ ppr ty)
+
+-- Construct a new VHDL type for the given Haskell type.
+construct_vhdl_ty :: Type.Type -> VHDLState (Maybe (AST.TypeMark, Either AST.TypeDef AST.SubtypeIn))
+construct_vhdl_ty ty = do
+ case Type.splitTyConApp_maybe ty of
+ Just (tycon, args) -> do
+ let name = Name.getOccString (TyCon.tyConName tycon)
+ case name of
+ "TFVec" -> do
+ res <- mk_vector_ty (tfvec_len ty) (tfvec_elem ty)
+ return $ Just $ (Arrow.second Right) res
+ -- "SizedWord" -> do
+ -- res <- mk_vector_ty (sized_word_len ty) ty
+ -- return $ Just $ (Arrow.second Left) res
+ "RangedWord" -> do
+ res <- mk_natural_ty 0 (ranged_word_bound ty)
+ return $ Just $ (Arrow.second Right) res
+ -- Create a custom type from this tycon
+ otherwise -> mk_tycon_ty tycon args
+ Nothing -> return $ Nothing
+
+-- | Create VHDL type for a custom tycon
+mk_tycon_ty :: TyCon.TyCon -> [Type.Type] -> VHDLState (Maybe (AST.TypeMark, Either AST.TypeDef AST.SubtypeIn))
+mk_tycon_ty tycon args =
+ case TyCon.tyConDataCons tycon of
+ -- Not an algebraic type
+ [] -> error $ "Only custom algebraic types are supported: " ++ (showSDoc $ ppr tycon)
+ [dc] -> do
+ let arg_tys = DataCon.dataConRepArgTys dc
+ -- TODO: CoreSubst docs say each Subs can be applied only once. Is this a
+ -- violation? Or does it only mean not to apply it again to the same
+ -- subject?
+ let real_arg_tys = map (CoreSubst.substTy subst) arg_tys
+ elem_tys <- mapM vhdl_ty real_arg_tys
+ let elems = zipWith AST.ElementDec recordlabels elem_tys
+ -- For a single construct datatype, build a record with one field for
+ -- each argument.
+ -- TODO: Add argument type ids to this, to ensure uniqueness
+ -- TODO: Special handling for tuples?
+ let ty_id = mkVHDLExtId $ nameToString (TyCon.tyConName tycon)
+ let ty_def = AST.TDR $ AST.RecordTypeDef elems
+ return $ Just (ty_id, Left ty_def)
+ dcs -> error $ "Only single constructor datatypes supported: " ++ (showSDoc $ ppr tycon)
+ where
+ -- Create a subst that instantiates all types passed to the tycon
+ -- TODO: I'm not 100% sure that this is the right way to do this. It seems
+ -- to work so far, though..
+ tyvars = TyCon.tyConTyVars tycon
+ subst = CoreSubst.extendTvSubstList CoreSubst.emptySubst (zip tyvars args)
-- | Create a VHDL vector type
mk_vector_ty ::
Int -- ^ The length of the vector
- -> Type.Type -- ^ The Haskell type to create a VHDL type for
- -> TypeState AST.TypeMark -- The typemark created.
-
-mk_vector_ty len ty = do
- -- Assume there is a single type argument
- let ty_id = mkVHDLExtId $ "vector_" ++ (show len)
- -- TODO: Use el_ty
- let range = AST.IndexConstraint [AST.ToRange (AST.PrimLit "0") (AST.PrimLit $ show (len - 1))]
- let ty_def = AST.TDA $ AST.ConsArrayDef range std_logic_ty
- let ty_dec = AST.TypeDec ty_id ty_def
- -- TODO: Check name uniqueness
- State.modify (Map.insert (OrdType ty) (ty_id, ty_dec))
- return ty_id
-
-
+ -> Type.Type -- ^ The Haskell element type of the Vector
+ -> VHDLState (AST.TypeMark, AST.SubtypeIn) -- The typemark created.
+
+mk_vector_ty len el_ty = do
+ elem_types_map <- getA vsElemTypes
+ el_ty_tm <- vhdl_ty el_ty
+ let ty_id = mkVHDLExtId $ "vector-"++ (AST.fromVHDLId el_ty_tm) ++ "-0_to_" ++ (show len)
+ let range = AST.ConstraintIndex $ AST.IndexConstraint [AST.ToRange (AST.PrimLit "0") (AST.PrimLit $ show (len - 1))]
+ let existing_elem_ty = (fmap fst) $ Map.lookup (OrdType el_ty) elem_types_map
+ case existing_elem_ty of
+ Just t -> do
+ let ty_def = AST.SubtypeIn t (Just range)
+ return (ty_id, ty_def)
+ Nothing -> do
+ let vec_id = mkVHDLExtId $ "vector_" ++ (AST.fromVHDLId el_ty_tm)
+ let vec_def = AST.TDA $ AST.UnconsArrayDef [tfvec_indexTM] el_ty_tm
+ modA vsElemTypes (Map.insert (OrdType el_ty) (vec_id, vec_def))
+ modA vsTypeFuns (Map.insert (OrdType el_ty) (genUnconsVectorFuns el_ty_tm vec_id))
+ let ty_def = AST.SubtypeIn vec_id (Just range)
+ return (ty_id, ty_def)
+
+mk_natural_ty ::
+ Int -- ^ The minimum bound (> 0)
+ -> Int -- ^ The maximum bound (> minimum bound)
+ -> VHDLState (AST.TypeMark, AST.SubtypeIn) -- The typemark created.
+mk_natural_ty min_bound max_bound = do
+ let ty_id = mkVHDLExtId $ "nat_" ++ (show min_bound) ++ "_to_" ++ (show max_bound)
+ let range = AST.ConstraintRange $ AST.SubTypeRange (AST.PrimLit $ (show min_bound)) (AST.PrimLit $ (show max_bound))
+ let ty_def = AST.SubtypeIn naturalTM (Just range)
+ return (ty_id, ty_def)
+
builtin_types =
Map.fromList [
("Bit", std_logic_ty),
allowed = ['A'..'Z'] ++ ['a'..'z'] ++ ['0'..'9'] ++ " \"#&\\'()*+,./:;<=>_|!$%@?[]^`{}~-"
strip_invalid = filter (`elem` allowed)
--- | A consise representation of a (set of) ports on a builtin function
-type PortMap = HsValueMap (String, AST.TypeMark)
--- | A consise representation of a builtin function
-data BuiltIn = BuiltIn String [PortMap] PortMap
-
--- | Translate a list of concise representation of builtin functions to a
--- SignatureMap
-mkBuiltins :: [BuiltIn] -> SignatureMap
-mkBuiltins = Map.fromList . map (\(BuiltIn name args res) ->
- (HsFunction name (map useAsPort args) (useAsPort res),
- Entity (VHDL.mkVHDLBasicId name) (map toVHDLSignalMap args) (toVHDLSignalMap res))
- )
-
-builtin_hsfuncs = Map.keys builtin_funcs
-builtin_funcs = mkBuiltins
- [
- BuiltIn "hwxor" [(Single ("a", VHDL.bit_ty)), (Single ("b", VHDL.bit_ty))] (Single ("o", VHDL.bit_ty)),
- BuiltIn "hwand" [(Single ("a", VHDL.bit_ty)), (Single ("b", VHDL.bit_ty))] (Single ("o", VHDL.bit_ty)),
- BuiltIn "hwor" [(Single ("a", VHDL.bit_ty)), (Single ("b", VHDL.bit_ty))] (Single ("o", VHDL.bit_ty)),
- BuiltIn "hwnot" [(Single ("a", VHDL.bit_ty))] (Single ("o", VHDL.bit_ty))
- ]
+-- Creates a VHDL Id from a binder
+bndrToVHDLId ::
+ CoreSyn.CoreBndr
+ -> AST.VHDLId
+
+bndrToVHDLId = mkVHDLExtId . OccName.occNameString . Name.nameOccName . Var.varName
+
+-- Extracts the binder name as a String
+bndrToString ::
+ CoreSyn.CoreBndr
+ -> String
+bndrToString = OccName.occNameString . Name.nameOccName . Var.varName
+
+-- Get the string version a Var's unique
+varToStringUniq = show . Var.varUnique
+
+-- Extracts the string version of the name
+nameToString :: Name.Name -> String
+nameToString = OccName.occNameString . Name.nameOccName
+
+recordlabels = map (\c -> mkVHDLBasicId [c]) ['A'..'Z']
-- | Map a port specification of a builtin function to a VHDL Signal to put in
-- a VHDLSignalMap
-toVHDLSignalMap :: HsValueMap (String, AST.TypeMark) -> VHDLSignalMap
-toVHDLSignalMap = fmap (\(name, ty) -> Just (mkVHDLBasicId name, ty))
+toVHDLSignalMapElement :: (String, AST.TypeMark) -> VHDLSignalMapElement
+toVHDLSignalMapElement (name, ty) = Just (mkVHDLBasicId name, ty)