-{-# LANGUAGE PackageImports #-}
-
module CLasH.VHDL.Generate where
-- Standard modules
-import qualified Control.Monad as Monad
+import qualified Data.List as List
import qualified Data.Map as Map
+import qualified Control.Monad as Monad
import qualified Maybe
import qualified Data.Either as Either
-import qualified Control.Monad.Trans.State as State
-import qualified "transformers" Control.Monad.Identity as Identity
-import Data.Accessor
-import Data.Accessor.MonadState as MonadState
-import Debug.Trace
+import qualified Data.Accessor.Monad.Trans.State as MonadState
--- ForSyDe
+-- VHDL Imports
import qualified Language.VHDL.AST as AST
-- GHC API
-import CoreSyn
-import Type
+import qualified CoreSyn
+import qualified Type
import qualified Var
+import qualified Id
import qualified IdInfo
import qualified Literal
import qualified Name
import qualified TyCon
-- Local imports
+import CLasH.Translator.TranslatorTypes
import CLasH.VHDL.Constants
import CLasH.VHDL.VHDLTypes
import CLasH.VHDL.VHDLTools
+import CLasH.Utils
import CLasH.Utils.Core.CoreTools
import CLasH.Utils.Pretty
+import qualified CLasH.Normalize as Normalize
+
+-----------------------------------------------------------------------------
+-- Functions to generate VHDL for user-defined functions.
+-----------------------------------------------------------------------------
+
+-- | Create an entity for a given function
+getEntity ::
+ CoreSyn.CoreBndr
+ -> TranslatorSession Entity -- ^ The resulting entity
+
+getEntity fname = makeCached fname tsEntities $ do
+ expr <- Normalize.getNormalized fname
+ -- Split the normalized expression
+ let (args, binds, res) = Normalize.splitNormalized expr
+ -- Generate ports for all non-empty types
+ args' <- catMaybesM $ mapM mkMap args
+ -- TODO: Handle Nothing
+ res' <- mkMap res
+ count <- MonadState.get tsEntityCounter
+ let vhdl_id = mkVHDLBasicId $ varToString fname ++ "Component_" ++ show count
+ MonadState.set tsEntityCounter (count + 1)
+ let ent_decl = createEntityAST vhdl_id args' res'
+ let signature = Entity vhdl_id args' res' ent_decl
+ return signature
+ where
+ mkMap ::
+ --[(SignalId, SignalInfo)]
+ CoreSyn.CoreBndr
+ -> TranslatorSession (Maybe Port)
+ mkMap = (\bndr ->
+ let
+ --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 = varToVHDLId bndr
+ ty = Var.varType bndr
+ error_msg = "\nVHDL.createEntity.mkMap: Can not create entity: " ++ pprString fname ++ "\nbecause no type can be created for port: " ++ pprString bndr
+ in do
+ type_mark_maybe <- MonadState.lift tsType $ vhdlTy error_msg ty
+ case type_mark_maybe of
+ Just type_mark -> return $ Just (id, type_mark)
+ Nothing -> return Nothing
+ )
+
+-- | Create the VHDL AST for an entity
+createEntityAST ::
+ AST.VHDLId -- ^ The name of the function
+ -> [Port] -- ^ The entity's arguments
+ -> Maybe Port -- ^ The entity's result
+ -> AST.EntityDec -- ^ The entity with the ent_decl filled in as well
+
+createEntityAST vhdl_id args res =
+ AST.EntityDec vhdl_id ports
+ where
+ -- Create a basic Id, since VHDL doesn't grok filenames with extended Ids.
+ ports = map (mkIfaceSigDec AST.In) args
+ ++ (Maybe.maybeToList res_port)
+ ++ [clk_port,resetn_port]
+ -- Add a clk port if we have state
+ clk_port = AST.IfaceSigDec clockId AST.In std_logicTM
+ resetn_port = AST.IfaceSigDec resetId AST.In std_logicTM
+ res_port = fmap (mkIfaceSigDec AST.Out) res
+
+-- | Create a port declaration
+mkIfaceSigDec ::
+ AST.Mode -- ^ The mode for the port (In / Out)
+ -> Port -- ^ The id and type for the port
+ -> AST.IfaceSigDec -- ^ The resulting port declaration
+
+mkIfaceSigDec mode (id, ty) = AST.IfaceSigDec id mode ty
+
+-- | Create an architecture for a given function
+getArchitecture ::
+ CoreSyn.CoreBndr -- ^ The function to get an architecture for
+ -> TranslatorSession (Architecture, [CoreSyn.CoreBndr])
+ -- ^ The architecture for this function
+
+getArchitecture fname = makeCached fname tsArchitectures $ do
+ expr <- Normalize.getNormalized fname
+ -- Split the normalized expression
+ let (args, binds, res) = Normalize.splitNormalized expr
+
+ -- Get the entity for this function
+ signature <- getEntity fname
+ let entity_id = ent_id signature
+
+ -- 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
+ -- Process each bind, resulting in info about state variables and concurrent
+ -- statements.
+ (state_vars, sms) <- Monad.mapAndUnzipM dobind binds
+ let (in_state_maybes, out_state_maybes) = unzip state_vars
+ let (statementss, used_entitiess) = unzip sms
+ -- Get initial state, if it's there
+ initSmap <- MonadState.get tsInitStates
+ let init_state = Map.lookup fname initSmap
+ -- Create a state proc, if needed
+ (state_proc, resbndr) <- case (Maybe.catMaybes in_state_maybes, Maybe.catMaybes out_state_maybes, init_state) of
+ ([in_state], [out_state], Nothing) -> do
+ nonEmpty <- hasNonEmptyType in_state
+ if nonEmpty
+ then error ("No initial state defined for: " ++ show fname)
+ else return ([],[])
+ ([in_state], [out_state], Just resetval) -> do
+ nonEmpty <- hasNonEmptyType in_state
+ if nonEmpty
+ then mkStateProcSm (in_state, out_state, resetval)
+ else error ("Initial state defined for function with only substate: " ++ show fname)
+ ([], [], Just _) -> error $ "Initial state defined for state-less function: " ++ show fname
+ ([], [], Nothing) -> return ([],[])
+ (ins, outs, res) -> error $ "Weird use of state in " ++ show fname ++ ". In: " ++ show ins ++ " Out: " ++ show outs
+ -- Join the create statements and the (optional) state_proc
+ let statements = concat statementss ++ state_proc
+ -- Create the architecture
+ let arch = AST.ArchBody (mkVHDLBasicId "structural") (AST.NSimple entity_id) (map AST.BDISD sig_decs) statements
+ let used_entities = (concat used_entitiess) ++ resbndr
+ return (arch, used_entities)
+ where
+ dobind :: (CoreSyn.CoreBndr, CoreSyn.CoreExpr) -- ^ The bind to process
+ -> TranslatorSession ((Maybe CoreSyn.CoreBndr, Maybe CoreSyn.CoreBndr), ([AST.ConcSm], [CoreSyn.CoreBndr]))
+ -- ^ ((Input state variable, output state variable), (statements, used entities))
+ -- newtype unpacking is just a cast
+ dobind (bndr, unpacked@(CoreSyn.Cast packed coercion))
+ | hasStateType packed && not (hasStateType unpacked)
+ = return ((Just bndr, Nothing), ([], []))
+ -- With simplCore, newtype packing is just a cast
+ dobind (bndr, packed@(CoreSyn.Cast unpacked@(CoreSyn.Var state) coercion))
+ | hasStateType packed && not (hasStateType unpacked)
+ = return ((Nothing, Just state), ([], []))
+ -- Without simplCore, newtype packing uses a data constructor
+ dobind (bndr, (CoreSyn.App (CoreSyn.App (CoreSyn.Var con) (CoreSyn.Type _)) (CoreSyn.Var state)))
+ | isStateCon con
+ = return ((Nothing, Just state), ([], []))
+ -- Anything else is handled by mkConcSm
+ dobind bind = do
+ sms <- mkConcSm bind
+ return ((Nothing, Nothing), sms)
+
+mkStateProcSm ::
+ (CoreSyn.CoreBndr, CoreSyn.CoreBndr, CoreSyn.CoreBndr) -- ^ The current state, new state and reset variables
+ -> TranslatorSession ([AST.ConcSm], [CoreSyn.CoreBndr]) -- ^ The resulting statements
+mkStateProcSm (old, new, res) = do
+ let error_msg = "\nVHDL.mkSigDec: Can not make signal declaration for type: \n" ++ pprString res
+ type_mark_old_maybe <- MonadState.lift tsType $ vhdlTy error_msg (Var.varType old)
+ let type_mark_old = Maybe.fromMaybe
+ (error $ "\nGenerate.mkStateProcSm: empty type for state? Type: " ++ pprString (Var.varType old))
+ type_mark_old_maybe
+ type_mark_res_maybe <- MonadState.lift tsType $ vhdlTy error_msg (Var.varType res)
+ let type_mark_res' = Maybe.fromMaybe
+ (error $ "\nGenerate.mkStateProcSm: empty type for initial state? Type: " ++ pprString (Var.varType res))
+ type_mark_res_maybe
+ let type_mark_res = if type_mark_old == type_mark_res' then
+ type_mark_res'
+ else
+ error $ "Initial state has different type than state type, state type: " ++ show type_mark_old ++ ", init type: " ++ show type_mark_res'
+ let resvalid = mkVHDLExtId $ varToString res ++ "val"
+ let resvaldec = AST.BDISD $ AST.SigDec resvalid type_mark_res Nothing
+ let reswform = AST.Wform [AST.WformElem (AST.PrimName $ AST.NSimple resvalid) Nothing]
+ let res_assign = AST.SigAssign (varToVHDLName old) reswform
+ let blocklabel = mkVHDLBasicId "state"
+ let statelabel = mkVHDLBasicId "stateupdate"
+ let rising_edge = AST.NSimple $ mkVHDLBasicId "rising_edge"
+ let wform = AST.Wform [AST.WformElem (AST.PrimName $ varToVHDLName new) Nothing]
+ let clk_assign = AST.SigAssign (varToVHDLName old) wform
+ let rising_edge_clk = AST.PrimFCall $ AST.FCall rising_edge [Nothing AST.:=>: (AST.ADName $ AST.NSimple clockId)]
+ let resetn_is_low = (AST.PrimName $ AST.NSimple resetId) AST.:=: (AST.PrimLit "'0'")
+ signature <- getEntity res
+ let entity_id = ent_id signature
+ let reslabel = "resetval_" ++ ((prettyShow . varToVHDLName) res)
+ let portmaps = mkAssocElems [] (AST.NSimple resvalid) signature
+ let reset_statement = mkComponentInst reslabel entity_id portmaps
+ let clk_statement = [AST.ElseIf rising_edge_clk [clk_assign]]
+ let statement = AST.IfSm resetn_is_low [res_assign] clk_statement Nothing
+ let stateupdate = AST.CSPSm $ AST.ProcSm statelabel [clockId,resetId,resvalid] [statement]
+ let block = AST.CSBSm $ AST.BlockSm blocklabel [] (AST.PMapAspect []) [resvaldec] [reset_statement,stateupdate]
+ return ([block],[res])
+
+-- | Transforms a core binding into a VHDL concurrent statement
+mkConcSm ::
+ (CoreSyn.CoreBndr, CoreSyn.CoreExpr) -- ^ The binding to process
+ -> TranslatorSession ([AST.ConcSm], [CoreSyn.CoreBndr])
+ -- ^ The corresponding VHDL concurrent statements and entities
+ -- instantiated.
+
+
+-- Ignore Cast expressions, they should not longer have any meaning as long as
+-- the type works out. Throw away state repacking
+mkConcSm (bndr, to@(CoreSyn.Cast from ty))
+ | hasStateType to && hasStateType from
+ = return ([],[])
+mkConcSm (bndr, CoreSyn.Cast expr ty) = mkConcSm (bndr, expr)
+
+-- Simple a = b assignments are just like applications, but without arguments.
+-- We can't just generate an unconditional assignment here, since b might be a
+-- top level binding (e.g., a function with no arguments).
+mkConcSm (bndr, CoreSyn.Var v) =
+ genApplication (Left bndr) v []
+
+mkConcSm (bndr, app@(CoreSyn.App _ _))= do
+ let (CoreSyn.Var f, args) = CoreSyn.collectArgs app
+ let valargs = get_val_args (Var.varType f) args
+ genApplication (Left bndr) f (map Left valargs)
+
+-- A single alt case must be a selector. This means the scrutinee is a simple
+-- variable, the alternative is a dataalt with a single non-wild binder that
+-- is also returned.
+mkConcSm (bndr, expr@(CoreSyn.Case (CoreSyn.Var scrut) b ty [alt]))
+ -- Don't generate VHDL for substate extraction
+ | hasStateType bndr = return ([], [])
+ | otherwise =
+ case alt of
+ (CoreSyn.DataAlt dc, bndrs, (CoreSyn.Var sel_bndr)) -> do
+ nonemptysel <- hasNonEmptyType sel_bndr
+ if nonemptysel
+ then do
+ bndrs' <- Monad.filterM hasNonEmptyType bndrs
+ case List.elemIndex sel_bndr bndrs' of
+ Just i -> do
+ htypeScrt <- MonadState.lift tsType $ mkHTypeEither (Var.varType scrut)
+ htypeBndr <- MonadState.lift tsType $ mkHTypeEither (Var.varType bndr)
+ case htypeScrt == htypeBndr of
+ True -> do
+ let sel_name = varToVHDLName scrut
+ let sel_expr = AST.PrimName sel_name
+ return ([mkUncondAssign (Left bndr) sel_expr], [])
+ otherwise ->
+ case htypeScrt of
+ Right (AggrType _ _) -> do
+ labels <- MonadState.lift tsType $ getFieldLabels (Id.idType scrut)
+ let label = labels!!i
+ let sel_name = mkSelectedName (varToVHDLName scrut) label
+ let sel_expr = AST.PrimName sel_name
+ return ([mkUncondAssign (Left bndr) sel_expr], [])
+ _ -> do -- error $ "DIE!"
+ let sel_name = varToVHDLName scrut
+ let sel_expr = AST.PrimName sel_name
+ return ([mkUncondAssign (Left bndr) sel_expr], [])
+ Nothing -> error $ "\nVHDL.mkConcSM: Not in normal form: Not a selector case: result is not one of the binders\n" ++ (pprString expr)
+ else
+ -- A selector case that selects a state value, ignore it.
+ return ([], [])
+
+ _ -> error $ "\nVHDL.mkConcSM: Not in normal form: Not a selector case:\n" ++ (pprString expr)
+
+-- 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, (CoreSyn.Case (CoreSyn.Var scrut) b ty [(_, _, CoreSyn.Var false), (con, _, CoreSyn.Var true)])) = do
+-- scrut' <- MonadState.lift tsType $ varToVHDLExpr scrut
+-- altcon <- MonadState.lift tsType $ altconToVHDLExpr con
+-- let cond_expr = scrut' AST.:=: altcon
+-- true_expr <- MonadState.lift tsType $ varToVHDLExpr true
+-- false_expr <- MonadState.lift tsType $ varToVHDLExpr false
+-- return ([mkCondAssign (Left bndr) cond_expr true_expr false_expr], [])
+mkConcSm (bndr, (CoreSyn.Case (CoreSyn.Var scrut) _ _ (alt:alts))) = do --error "\nVHDL.mkConcSm: Not in normal form: Case statement with more than two alternatives"
+ scrut' <- MonadState.lift tsType $ varToVHDLExpr scrut
+ -- Omit first condition, which is the default
+ altcons <- MonadState.lift tsType $ mapM (altconToVHDLExpr . (\(con,_,_) -> con)) alts
+ let cond_exprs = map (\x -> scrut' AST.:=: x) altcons
+ -- Rotate expressions to the left, so that the expression related to the default case is the last
+ exprs <- MonadState.lift tsType $ mapM (varToVHDLExpr . (\(_,_,CoreSyn.Var expr) -> expr)) (alts ++ [alt])
+ return ([mkAltsAssign (Left bndr) cond_exprs exprs], [])
+
+mkConcSm (_, CoreSyn.Case _ _ _ _) = error "\nVHDL.mkConcSm: Not in normal form: Case statement has does not have a simple variable as scrutinee"
+mkConcSm (bndr, expr) = error $ "\nVHDL.mkConcSM: Unsupported binding in let expression: " ++ pprString bndr ++ " = " ++ pprString expr
-----------------------------------------------------------------------------
-- Functions to generate VHDL for builtin functions
-- | A function to wrap a builder-like function that expects its arguments to
-- be expressions.
genExprArgs wrap dst func args = do
- args' <- eitherCoreOrExprArgs args
+ args' <- argsToVHDLExprs args
wrap dst func args'
-eitherCoreOrExprArgs :: [Either CoreSyn.CoreExpr AST.Expr] -> VHDLSession [AST.Expr]
-eitherCoreOrExprArgs args = mapM (Either.either ((MonadState.lift vsType) . varToVHDLExpr . exprToVar) return) args
+-- | Turn the all lefts into VHDL Expressions.
+argsToVHDLExprs :: [Either CoreSyn.CoreExpr AST.Expr] -> TranslatorSession [AST.Expr]
+argsToVHDLExprs = catMaybesM . (mapM argToVHDLExpr)
+
+argToVHDLExpr :: Either CoreSyn.CoreExpr AST.Expr -> TranslatorSession (Maybe AST.Expr)
+argToVHDLExpr (Left expr) = MonadState.lift tsType $ do
+ let errmsg = "Generate.argToVHDLExpr: Using non-representable type? Should not happen!"
+ ty_maybe <- vhdlTy errmsg expr
+ case ty_maybe of
+ Just _ -> do
+ vhdl_expr <- varToVHDLExpr $ exprToVar expr
+ return $ Just vhdl_expr
+ Nothing -> return Nothing
+
+argToVHDLExpr (Right expr) = return $ Just expr
+
+-- A function to wrap a builder-like function that generates no component
+-- instantiations
+genNoInsts ::
+ (dst -> func -> args -> TranslatorSession [AST.ConcSm])
+ -> (dst -> func -> args -> TranslatorSession ([AST.ConcSm], [CoreSyn.CoreBndr]))
+genNoInsts wrap dst func args = do
+ concsms <- wrap dst func args
+ return (concsms, [])
-- | A function to wrap a builder-like function that expects its arguments to
-- be variables.
-- | A function to wrap a builder-like function that expects its arguments to
-- be Literals
genLitArgs ::
- (dst -> func -> [Literal.Literal] -> res)
- -> (dst -> func -> [Either CoreSyn.CoreExpr AST.Expr] -> res)
-genLitArgs wrap dst func args = wrap dst func args'
- where
- args' = map exprToLit litargs
- -- FIXME: Check if we were passed an CoreSyn.App
- litargs = concat (map getLiterals exprargs)
- (exprargs, []) = Either.partitionEithers args
+ (dst -> func -> [Literal.Literal] -> TranslatorSession [AST.ConcSm])
+ -> (dst -> func -> [Either CoreSyn.CoreExpr AST.Expr] -> TranslatorSession [AST.ConcSm])
+genLitArgs wrap dst func args = do
+ hscenv <- MonadState.lift tsType $ MonadState.get tsHscEnv
+ let (exprargs, []) = Either.partitionEithers args
+ -- FIXME: Check if we were passed an CoreSyn.App
+ let litargs = concatMap (getLiterals hscenv) exprargs
+ let args' = map exprToLit litargs
+ wrap dst func args'
-- | A function to wrap a builder-like function that produces an expression
-- and expects it to be assigned to the destination.
genExprRes ::
- ((Either CoreSyn.CoreBndr AST.VHDLName) -> func -> [arg] -> VHDLSession AST.Expr)
- -> ((Either CoreSyn.CoreBndr AST.VHDLName) -> func -> [arg] -> VHDLSession [AST.ConcSm])
+ ((Either CoreSyn.CoreBndr AST.VHDLName) -> func -> [arg] -> TranslatorSession AST.Expr)
+ -> ((Either CoreSyn.CoreBndr AST.VHDLName) -> func -> [arg] -> TranslatorSession [AST.ConcSm])
genExprRes wrap dst func args = do
expr <- wrap dst func args
- return $ [mkUncondAssign dst expr]
+ return [mkUncondAssign dst expr]
-- | Generate a binary operator application. The first argument should be a
-- constructor from the AST.Expr type, e.g. AST.And.
genOperator2 :: (AST.Expr -> AST.Expr -> AST.Expr) -> BuiltinBuilder
-genOperator2 op = genExprArgs $ genExprRes (genOperator2' op)
-genOperator2' :: (AST.Expr -> AST.Expr -> AST.Expr) -> dst -> CoreSyn.CoreBndr -> [AST.Expr] -> VHDLSession AST.Expr
+genOperator2 op = genNoInsts $ genExprArgs $ genExprRes (genOperator2' op)
+genOperator2' :: (AST.Expr -> AST.Expr -> AST.Expr) -> dst -> CoreSyn.CoreBndr -> [AST.Expr] -> TranslatorSession AST.Expr
genOperator2' op _ f [arg1, arg2] = return $ op arg1 arg2
-- | Generate a unary operator application
genOperator1 :: (AST.Expr -> AST.Expr) -> BuiltinBuilder
-genOperator1 op = genExprArgs $ genExprRes (genOperator1' op)
-genOperator1' :: (AST.Expr -> AST.Expr) -> dst -> CoreSyn.CoreBndr -> [AST.Expr] -> VHDLSession AST.Expr
+genOperator1 op = genNoInsts $ genExprArgs $ genExprRes (genOperator1' op)
+genOperator1' :: (AST.Expr -> AST.Expr) -> dst -> CoreSyn.CoreBndr -> [AST.Expr] -> TranslatorSession AST.Expr
genOperator1' op _ f [arg] = return $ op arg
-- | Generate a unary operator application
genNegation :: BuiltinBuilder
-genNegation = genVarArgs $ genExprRes genNegation'
-genNegation' :: dst -> CoreSyn.CoreBndr -> [Var.Var] -> VHDLSession AST.Expr
+genNegation = genNoInsts $ genVarArgs $ genExprRes genNegation'
+genNegation' :: dst -> CoreSyn.CoreBndr -> [Var.Var] -> TranslatorSession AST.Expr
genNegation' _ f [arg] = do
- arg1 <- MonadState.lift vsType $ varToVHDLExpr arg
+ arg1 <- MonadState.lift tsType $ varToVHDLExpr arg
let ty = Var.varType arg
let (tycon, args) = Type.splitTyConApp ty
let name = Name.getOccString (TyCon.tyConName tycon)
case name of
"SizedInt" -> return $ AST.Neg arg1
- otherwise -> error $ "\nGenerate.genNegation': Negation allowed for type: " ++ show name
+ otherwise -> error $ "\nGenerate.genNegation': Negation not allowed for type: " ++ show name
-- | Generate a function call from the destination binder, function name and a
-- list of expressions (its arguments)
genFCall :: Bool -> BuiltinBuilder
-genFCall switch = genExprArgs $ genExprRes (genFCall' switch)
-genFCall' :: Bool -> Either CoreSyn.CoreBndr AST.VHDLName -> CoreSyn.CoreBndr -> [AST.Expr] -> VHDLSession AST.Expr
+genFCall switch = genNoInsts $ genExprArgs $ genExprRes (genFCall' switch)
+genFCall' :: Bool -> Either CoreSyn.CoreBndr AST.VHDLName -> CoreSyn.CoreBndr -> [AST.Expr] -> TranslatorSession AST.Expr
genFCall' switch (Left res) f args = do
let fname = varToString f
let el_ty = if switch then (Var.varType res) else ((tfvec_elem . Var.varType) res)
- id <- MonadState.lift vsType $ vectorFunId el_ty fname
+ id <- MonadState.lift tsType $ vectorFunId el_ty fname
return $ AST.PrimFCall $ AST.FCall (AST.NSimple id) $
map (\exp -> Nothing AST.:=>: AST.ADExpr exp) args
genFCall' _ (Right name) _ _ = error $ "\nGenerate.genFCall': Cannot generate builtin function call assigned to a VHDLName: " ++ show name
genFromSizedWord :: BuiltinBuilder
-genFromSizedWord = genExprArgs $ genExprRes genFromSizedWord'
-genFromSizedWord' :: Either CoreSyn.CoreBndr AST.VHDLName -> CoreSyn.CoreBndr -> [AST.Expr] -> VHDLSession AST.Expr
-genFromSizedWord' (Left res) f args = do
- let fname = varToString f
- return $ AST.PrimFCall $ AST.FCall (AST.NSimple (mkVHDLBasicId toIntegerId)) $
- map (\exp -> Nothing AST.:=>: AST.ADExpr exp) args
+genFromSizedWord = genNoInsts $ genExprArgs genFromSizedWord'
+genFromSizedWord' :: Either CoreSyn.CoreBndr AST.VHDLName -> CoreSyn.CoreBndr -> [AST.Expr] -> TranslatorSession [AST.ConcSm]
+genFromSizedWord' (Left res) f args@[arg] =
+ return [mkUncondAssign (Left res) arg]
+ -- let fname = varToString f
+ -- return $ AST.PrimFCall $ AST.FCall (AST.NSimple (mkVHDLBasicId toIntegerId)) $
+ -- map (\exp -> Nothing AST.:=>: AST.ADExpr exp) args
genFromSizedWord' (Right name) _ _ = error $ "\nGenerate.genFromSizedWord': Cannot generate builtin function call assigned to a VHDLName: " ++ show name
genResize :: BuiltinBuilder
-genResize = genExprArgs $ genExprRes genResize'
-genResize' :: Either CoreSyn.CoreBndr AST.VHDLName -> CoreSyn.CoreBndr -> [AST.Expr] -> VHDLSession AST.Expr
+genResize = genNoInsts $ genExprArgs $ genExprRes genResize'
+genResize' :: Either CoreSyn.CoreBndr AST.VHDLName -> CoreSyn.CoreBndr -> [AST.Expr] -> TranslatorSession AST.Expr
genResize' (Left res) f [arg] = do {
; let { ty = Var.varType res
; (tycon, args) = Type.splitTyConApp ty
; name = Name.getOccString (TyCon.tyConName tycon)
} ;
; len <- case name of
- "SizedInt" -> MonadState.lift vsType $ tfp_to_int (sized_int_len_ty ty)
- "SizedWord" -> MonadState.lift vsType $ tfp_to_int (sized_word_len_ty ty)
+ "SizedInt" -> MonadState.lift tsType $ tfp_to_int (sized_int_len_ty ty)
+ "SizedWord" -> MonadState.lift tsType $ tfp_to_int (sized_word_len_ty ty)
; return $ AST.PrimFCall $ AST.FCall (AST.NSimple (mkVHDLBasicId resizeId))
[Nothing AST.:=>: AST.ADExpr arg, Nothing AST.:=>: AST.ADExpr( AST.PrimLit (show len))]
}
genResize' (Right name) _ _ = error $ "\nGenerate.genFromSizedWord': Cannot generate builtin function call assigned to a VHDLName: " ++ show name
+genTimes :: BuiltinBuilder
+genTimes = genNoInsts $ genExprArgs $ genExprRes genTimes'
+genTimes' :: Either CoreSyn.CoreBndr AST.VHDLName -> CoreSyn.CoreBndr -> [AST.Expr] -> TranslatorSession AST.Expr
+genTimes' (Left res) f [arg1,arg2] = do {
+ ; let { ty = Var.varType res
+ ; (tycon, args) = Type.splitTyConApp ty
+ ; name = Name.getOccString (TyCon.tyConName tycon)
+ } ;
+ ; len <- case name of
+ "SizedInt" -> MonadState.lift tsType $ tfp_to_int (sized_int_len_ty ty)
+ "SizedWord" -> MonadState.lift tsType $ tfp_to_int (sized_word_len_ty ty)
+ "RangedWord" -> do { ubound <- MonadState.lift tsType $ tfp_to_int (ranged_word_bound_ty ty)
+ ; let bitsize = floor (logBase 2 (fromInteger (toInteger ubound)))
+ ; return bitsize
+ }
+ ; return $ AST.PrimFCall $ AST.FCall (AST.NSimple (mkVHDLBasicId resizeId))
+ [Nothing AST.:=>: AST.ADExpr (arg1 AST.:*: arg2), Nothing AST.:=>: AST.ADExpr( AST.PrimLit (show len))]
+ }
+genTimes' (Right name) _ _ = error $ "\nGenerate.genTimes': Cannot generate builtin function call assigned to a VHDLName: " ++ show name
+
-- FIXME: I'm calling genLitArgs which is very specific function,
-- which needs to be fixed as well
genFromInteger :: BuiltinBuilder
-genFromInteger = genLitArgs $ genExprRes genFromInteger'
-genFromInteger' :: Either CoreSyn.CoreBndr AST.VHDLName -> CoreSyn.CoreBndr -> [Literal.Literal] -> VHDLSession AST.Expr
+genFromInteger = genNoInsts $ genLitArgs $ genExprRes genFromInteger'
+genFromInteger' :: Either CoreSyn.CoreBndr AST.VHDLName -> CoreSyn.CoreBndr -> [Literal.Literal] -> TranslatorSession AST.Expr
genFromInteger' (Left res) f lits = do {
; let { ty = Var.varType res
; (tycon, args) = Type.splitTyConApp ty
; name = Name.getOccString (TyCon.tyConName tycon)
} ;
; len <- case name of
- "SizedInt" -> MonadState.lift vsType $ tfp_to_int (sized_int_len_ty ty)
- "SizedWord" -> MonadState.lift vsType $ tfp_to_int (sized_word_len_ty ty)
- ; let fname = case name of "SizedInt" -> toSignedId ; "SizedWord" -> toUnsignedId
- ; return $ AST.PrimFCall $ AST.FCall (AST.NSimple (mkVHDLBasicId fname))
+ "SizedInt" -> MonadState.lift tsType $ tfp_to_int (sized_int_len_ty ty)
+ "SizedWord" -> MonadState.lift tsType $ tfp_to_int (sized_word_len_ty ty)
+ "RangedWord" -> do {
+ ; bound <- MonadState.lift tsType $ tfp_to_int (ranged_word_bound_ty ty)
+ ; return $ floor (logBase 2 (fromInteger (toInteger (bound)))) + 1
+ }
+ ; let fname = case name of "SizedInt" -> toSignedId ; "SizedWord" -> toUnsignedId ; "RangedWord" -> toUnsignedId
+ ; return $ AST.PrimFCall $ AST.FCall (AST.NSimple (mkVHDLBasicId fname))
[Nothing AST.:=>: AST.ADExpr (AST.PrimLit (show (last lits))), Nothing AST.:=>: AST.ADExpr( AST.PrimLit (show len))]
+
}
genFromInteger' (Right name) _ _ = error $ "\nGenerate.genFromInteger': Cannot generate builtin function call assigned to a VHDLName: " ++ show name
+genSizedInt :: BuiltinBuilder
+genSizedInt = genFromInteger
+
+{-
+-- | Generate a Builder for the builtin datacon TFVec
+genTFVec :: BuiltinBuilder
+genTFVec (Left res) f [Left (CoreSyn.Let (CoreSyn.Rec letBinders) letRes)] = do {
+ -- Generate Assignments for all the binders
+ ; letAssigns <- mapM genBinderAssign letBinders
+ -- Generate assignments for the result (which might be another let binding)
+ ; (resBinders,resAssignments) <- genResAssign letRes
+ -- Get all the Assigned binders
+ ; let assignedBinders = Maybe.catMaybes (map fst letAssigns)
+ -- Make signal names for all the assigned binders
+ ; sigs <- mapM (\x -> MonadState.lift tsType $ varToVHDLExpr x) (assignedBinders ++ resBinders)
+ -- Assign all the signals to the resulting vector
+ ; let { vecsigns = mkAggregateSignal sigs
+ ; vecassign = mkUncondAssign (Left res) vecsigns
+ } ;
+ -- Generate all the signal declaration for the assigned binders
+ ; sig_dec_maybes <- mapM mkSigDec (assignedBinders ++ resBinders)
+ ; let { sig_decs = map (AST.BDISD) (Maybe.catMaybes $ sig_dec_maybes)
+ -- Setup the VHDL Block
+ ; block_label = mkVHDLExtId ("TFVec_" ++ show (varToString res))
+ ; block = AST.BlockSm block_label [] (AST.PMapAspect []) sig_decs ((concat (map snd letAssigns)) ++ resAssignments ++ [vecassign])
+ } ;
+ -- Return the block statement coressponding to the TFVec literal
+ ; return $ [AST.CSBSm block]
+ }
+ where
+ genBinderAssign :: (CoreSyn.CoreBndr, CoreSyn.CoreExpr) -> TranslatorSession (Maybe CoreSyn.CoreBndr, [AST.ConcSm])
+ -- For now we only translate applications
+ genBinderAssign (bndr, app@(CoreSyn.App _ _)) = do
+ let (CoreSyn.Var f, args) = CoreSyn.collectArgs app
+ let valargs = get_val_args (Var.varType f) args
+ apps <- genApplication (Left bndr) f (map Left valargs)
+ return (Just bndr, apps)
+ genBinderAssign _ = return (Nothing,[])
+ genResAssign :: CoreSyn.CoreExpr -> TranslatorSession ([CoreSyn.CoreBndr], [AST.ConcSm])
+ genResAssign app@(CoreSyn.App _ letexpr) = do
+ case letexpr of
+ (CoreSyn.Let (CoreSyn.Rec letbndrs) letres) -> do
+ letapps <- mapM genBinderAssign letbndrs
+ let bndrs = Maybe.catMaybes (map fst letapps)
+ let app = (map snd letapps)
+ (vars, apps) <- genResAssign letres
+ return ((bndrs ++ vars),((concat app) ++ apps))
+ otherwise -> return ([],[])
+ genResAssign _ = return ([],[])
+
+genTFVec (Left res) f [Left app@(CoreSyn.App _ _)] = do {
+ ; let { elems = reduceCoreListToHsList app
+ -- Make signal names for all the binders
+ ; binders = map (\expr -> case expr of
+ (CoreSyn.Var b) -> b
+ otherwise -> error $ "\nGenerate.genTFVec: Cannot generate TFVec: "
+ ++ show res ++ ", with elems:\n" ++ show elems ++ "\n" ++ pprString elems) elems
+ } ;
+ ; sigs <- mapM (\x -> MonadState.lift tsType $ varToVHDLExpr x) binders
+ -- Assign all the signals to the resulting vector
+ ; let { vecsigns = mkAggregateSignal sigs
+ ; vecassign = mkUncondAssign (Left res) vecsigns
+ -- Setup the VHDL Block
+ ; block_label = mkVHDLExtId ("TFVec_" ++ show (varToString res))
+ ; block = AST.BlockSm block_label [] (AST.PMapAspect []) [] [vecassign]
+ } ;
+ -- Return the block statement coressponding to the TFVec literal
+ ; return $ [AST.CSBSm block]
+ }
+
+genTFVec (Left name) _ [Left xs] = error $ "\nGenerate.genTFVec: Cannot generate TFVec: " ++ show name ++ ", with elems:\n" ++ show xs ++ "\n" ++ pprString xs
+genTFVec (Right name) _ _ = error $ "\nGenerate.genTFVec: Cannot generate TFVec assigned to VHDLName: " ++ show name
+-}
-- | Generate a generate statement for the builtin function "map"
genMap :: BuiltinBuilder
-genMap (Left res) f [Left mapped_f, Left (Var arg)] = do {
+genMap (Left res) f [Left mapped_f, Left (CoreSyn.Var arg)] = do {
-- mapped_f must be a CoreExpr (since we can't represent functions as VHDL
-- expressions). arg must be a CoreExpr (and should be a CoreSyn.Var), since
-- we must index it (which we couldn't if it was a VHDL Expr, since only
-- VHDLNames can be indexed).
-- Setup the generate scheme
- ; len <- MonadState.lift vsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) res
+ ; len <- MonadState.lift tsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) res
-- TODO: Use something better than varToString
; let { label = mkVHDLExtId ("mapVector" ++ (varToString res))
; n_id = mkVHDLBasicId "n"
; (CoreSyn.Var real_f, already_mapped_args) = CoreSyn.collectArgs mapped_f
; valargs = get_val_args (Var.varType real_f) already_mapped_args
} ;
- ; app_concsms <- genApplication (Right resname) real_f (map Left valargs ++ [Right argexpr])
+ ; (app_concsms, used) <- genApplication (Right resname) real_f (map Left valargs ++ [Right argexpr])
-- Return the generate statement
- ; return [AST.CSGSm $ AST.GenerateSm label genScheme [] app_concsms]
+ ; return ([AST.CSGSm $ AST.GenerateSm label genScheme [] app_concsms], used)
}
genMap' (Right name) _ _ = error $ "\nGenerate.genMap': Cannot generate map function call assigned to a VHDLName: " ++ show name
genZipWith :: BuiltinBuilder
-genZipWith = genVarArgs genZipWith'
-genZipWith' :: (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> VHDLSession [AST.ConcSm]
-genZipWith' (Left res) f args@[zipped_f, arg1, arg2] = do {
+genZipWith (Left res) f args@[Left zipped_f, Left (CoreSyn.Var arg1), Left (CoreSyn.Var arg2)] = do {
-- Setup the generate scheme
- ; len <- MonadState.lift vsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) res
+ ; len <- MonadState.lift tsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) res
-- TODO: Use something better than varToString
; let { label = mkVHDLExtId ("zipWithVector" ++ (varToString res))
; n_id = mkVHDLBasicId "n"
-- Create the content of the generate statement: Applying the zipped_f to
-- each of the elements in arg1 and arg2, storing to each element in res
; resname = mkIndexedName (varToVHDLName res) n_expr
+ ; (CoreSyn.Var real_f, already_mapped_args) = CoreSyn.collectArgs zipped_f
+ ; valargs = get_val_args (Var.varType real_f) already_mapped_args
; argexpr1 = vhdlNameToVHDLExpr $ mkIndexedName (varToVHDLName arg1) n_expr
; argexpr2 = vhdlNameToVHDLExpr $ mkIndexedName (varToVHDLName arg2) n_expr
} ;
- ; app_concsms <- genApplication (Right resname) zipped_f [Right argexpr1, Right argexpr2]
+ ; (app_concsms, used) <- genApplication (Right resname) real_f (map Left valargs ++ [Right argexpr1, Right argexpr2])
-- Return the generate functions
- ; return [AST.CSGSm $ AST.GenerateSm label genScheme [] app_concsms]
+ ; return ([AST.CSGSm $ AST.GenerateSm label genScheme [] app_concsms], used)
}
genFoldl :: BuiltinBuilder
genFold :: Bool -> BuiltinBuilder
genFold left = genVarArgs (genFold' left)
-genFold' :: Bool -> (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> VHDLSession [AST.ConcSm]
+genFold' :: Bool -> (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> TranslatorSession ([AST.ConcSm], [CoreSyn.CoreBndr])
genFold' left res f args@[folded_f , start ,vec]= do
- len <- MonadState.lift vsType $ tfp_to_int $ (tfvec_len_ty (Var.varType vec))
+ len <- MonadState.lift tsType $ tfp_to_int (tfvec_len_ty (Var.varType vec))
genFold'' len left res f args
-genFold'' :: Int -> Bool -> (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> VHDLSession [AST.ConcSm]
+genFold'' :: Int -> Bool -> (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> TranslatorSession ([AST.ConcSm], [CoreSyn.CoreBndr])
-- Special case for an empty input vector, just assign start to res
genFold'' len left (Left res) _ [_, start, vec] | len == 0 = do
- arg <- MonadState.lift vsType $ varToVHDLExpr start
- return [mkUncondAssign (Left res) arg]
+ arg <- MonadState.lift tsType $ varToVHDLExpr start
+ return ([mkUncondAssign (Left res) arg], [])
genFold'' len left (Left res) f [folded_f, start, vec] = do
-- The vector length
- --len <- MonadState.lift vsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) vec
+ --len <- MonadState.lift tsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) vec
-- An expression for len-1
let len_min_expr = (AST.PrimLit $ show (len-1))
-- evec is (TFVec n), so it still needs an element type
- let (nvec, _) = splitAppTy (Var.varType vec)
+ let (nvec, _) = Type.splitAppTy (Var.varType vec)
-- Put the type of the start value in nvec, this will be the type of our
-- temporary vector
let tmp_ty = Type.mkAppTy nvec (Var.varType start)
let error_msg = "\nGenerate.genFold': Can not construct temp vector for element type: " ++ pprString tmp_ty
- tmp_vhdl_ty <- MonadState.lift vsType $ vhdl_ty error_msg tmp_ty
+ -- TODO: Handle Nothing
+ Just tmp_vhdl_ty <- MonadState.lift tsType $ vhdlTy error_msg tmp_ty
-- Setup the generate scheme
let gen_label = mkVHDLExtId ("foldlVector" ++ (varToString vec))
let block_label = mkVHDLExtId ("foldlVector" ++ (varToString res))
-- Make the intermediate vector
let tmp_dec = AST.BDISD $ AST.SigDec tmp_id tmp_vhdl_ty Nothing
-- Create the generate statement
- cells <- sequence [genFirstCell, genOtherCell]
+ cells' <- sequence [genFirstCell, genOtherCell]
+ let (cells, useds) = unzip cells'
let gen_sm = AST.GenerateSm gen_label gen_scheme [] (map AST.CSGSm cells)
-- Assign tmp[len-1] or tmp[0] to res
let out_assign = mkUncondAssign (Left res) $ vhdlNameToVHDLExpr (if left then
(mkIndexedName tmp_name (AST.PrimLit $ show (len-1))) else
(mkIndexedName tmp_name (AST.PrimLit "0")))
let block = AST.BlockSm block_label [] (AST.PMapAspect []) [tmp_dec] [AST.CSGSm gen_sm, out_assign]
- return [AST.CSBSm block]
+ return ([AST.CSBSm block], concat useds)
where
-- An id for the counter
n_id = mkVHDLBasicId "n"
tmp_id = mkVHDLBasicId "tmp"
tmp_name = AST.NSimple tmp_id
-- Generate parts of the fold
- genFirstCell, genOtherCell :: VHDLSession AST.GenerateSm
+ genFirstCell, genOtherCell :: TranslatorSession (AST.GenerateSm, [CoreSyn.CoreBndr])
genFirstCell = do
- len <- MonadState.lift vsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) vec
+ len <- MonadState.lift tsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) vec
let cond_label = mkVHDLExtId "firstcell"
-- if n == 0 or n == len-1
let cond_scheme = AST.IfGn $ n_cur AST.:=: (if left then (AST.PrimLit "0")
-- Output to tmp[current n]
let resname = mkIndexedName tmp_name n_cur
-- Input from start
- argexpr1 <- MonadState.lift vsType $ varToVHDLExpr start
+ argexpr1 <- MonadState.lift tsType $ varToVHDLExpr start
-- Input from vec[current n]
let argexpr2 = vhdlNameToVHDLExpr $ mkIndexedName (varToVHDLName vec) n_cur
- app_concsms <- genApplication (Right resname) folded_f ( if left then
+ (app_concsms, used) <- genApplication (Right resname) folded_f ( if left then
[Right argexpr1, Right argexpr2]
else
[Right argexpr2, Right argexpr1]
)
-- Return the conditional generate part
- return $ AST.GenerateSm cond_label cond_scheme [] app_concsms
+ return (AST.GenerateSm cond_label cond_scheme [] app_concsms, used)
genOtherCell = do
- len <- MonadState.lift vsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) vec
+ len <- MonadState.lift tsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) vec
let cond_label = mkVHDLExtId "othercell"
-- if n > 0 or n < len-1
let cond_scheme = AST.IfGn $ n_cur AST.:/=: (if left then (AST.PrimLit "0")
let argexpr1 = vhdlNameToVHDLExpr $ mkIndexedName tmp_name n_prev
-- Input from vec[current n]
let argexpr2 = vhdlNameToVHDLExpr $ mkIndexedName (varToVHDLName vec) n_cur
- app_concsms <- genApplication (Right resname) folded_f ( if left then
+ (app_concsms, used) <- genApplication (Right resname) folded_f ( if left then
[Right argexpr1, Right argexpr2]
else
[Right argexpr2, Right argexpr1]
)
-- Return the conditional generate part
- return $ AST.GenerateSm cond_label cond_scheme [] app_concsms
+ return (AST.GenerateSm cond_label cond_scheme [] app_concsms, used)
-- | Generate a generate statement for the builtin function "zip"
genZip :: BuiltinBuilder
-genZip = genVarArgs genZip'
-genZip' :: (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> VHDLSession [AST.ConcSm]
+genZip = genNoInsts $ genVarArgs genZip'
+genZip' :: (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> TranslatorSession [AST.ConcSm]
genZip' (Left res) f args@[arg1, arg2] = do {
-- Setup the generate scheme
- ; len <- MonadState.lift vsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) res
+ ; len <- MonadState.lift tsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) res
-- TODO: Use something better than varToString
; let { label = mkVHDLExtId ("zipVector" ++ (varToString res))
; n_id = mkVHDLBasicId "n"
; argexpr1 = vhdlNameToVHDLExpr $ mkIndexedName (varToVHDLName arg1) n_expr
; argexpr2 = vhdlNameToVHDLExpr $ mkIndexedName (varToVHDLName arg2) n_expr
} ;
- ; labels <- MonadState.lift vsType $ getFieldLabels (tfvec_elem (Var.varType res))
+ ; labels <- MonadState.lift tsType $ getFieldLabels (tfvec_elem (Var.varType res))
; let { resnameA = mkSelectedName resname' (labels!!0)
; resnameB = mkSelectedName resname' (labels!!1)
; resA_assign = mkUncondAssign (Right resnameA) argexpr1
-- Return the generate functions
; return [AST.CSGSm $ AST.GenerateSm label genScheme [] [resA_assign,resB_assign]]
}
-
--- | Generate a generate statement for the builtin function "unzip"
-genUnzip :: BuiltinBuilder
-genUnzip = genVarArgs genUnzip'
-genUnzip' :: (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> VHDLSession [AST.ConcSm]
-genUnzip' (Left res) f args@[arg] = do {
- -- Setup the generate scheme
- ; len <- MonadState.lift vsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) arg
- -- TODO: Use something better than varToString
- ; let { label = mkVHDLExtId ("unzipVector" ++ (varToString res))
- ; n_id = mkVHDLBasicId "n"
- ; n_expr = idToVHDLExpr n_id
- ; range = AST.ToRange (AST.PrimLit "0") (AST.PrimLit $ show (len-1))
- ; genScheme = AST.ForGn n_id range
- ; resname' = varToVHDLName res
- ; argexpr' = mkIndexedName (varToVHDLName arg) n_expr
+
+-- | Generate a generate statement for the builtin function "fst"
+genFst :: BuiltinBuilder
+genFst = genNoInsts $ genVarArgs genFst'
+genFst' :: (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> TranslatorSession [AST.ConcSm]
+genFst' (Left res) f args@[arg] = do {
+ ; labels <- MonadState.lift tsType $ getFieldLabels (Var.varType arg)
+ ; let { argexpr' = varToVHDLName arg
+ ; argexprA = vhdlNameToVHDLExpr $ mkSelectedName argexpr' (labels!!0)
+ ; assign = mkUncondAssign (Left res) argexprA
} ;
- ; reslabels <- MonadState.lift vsType $ getFieldLabels (Var.varType res)
- ; arglabels <- MonadState.lift vsType $ getFieldLabels (tfvec_elem (Var.varType arg))
- ; let { resnameA = mkIndexedName (mkSelectedName resname' (reslabels!!0)) n_expr
- ; resnameB = mkIndexedName (mkSelectedName resname' (reslabels!!1)) n_expr
- ; argexprA = vhdlNameToVHDLExpr $ mkSelectedName argexpr' (arglabels!!0)
- ; argexprB = vhdlNameToVHDLExpr $ mkSelectedName argexpr' (arglabels!!1)
- ; resA_assign = mkUncondAssign (Right resnameA) argexprA
- ; resB_assign = mkUncondAssign (Right resnameB) argexprB
+ -- Return the generate functions
+ ; return [assign]
+ }
+
+-- | Generate a generate statement for the builtin function "snd"
+genSnd :: BuiltinBuilder
+genSnd = genNoInsts $ genVarArgs genSnd'
+genSnd' :: (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> TranslatorSession [AST.ConcSm]
+genSnd' (Left res) f args@[arg] = do {
+ ; labels <- MonadState.lift tsType $ getFieldLabels (Var.varType arg)
+ ; let { argexpr' = varToVHDLName arg
+ ; argexprB = vhdlNameToVHDLExpr $ mkSelectedName argexpr' (labels!!1)
+ ; assign = mkUncondAssign (Left res) argexprB
} ;
-- Return the generate functions
- ; return [AST.CSGSm $ AST.GenerateSm label genScheme [] [resA_assign,resB_assign]]
+ ; return [assign]
}
+
+-- | Generate a generate statement for the builtin function "unzip"
+genUnzip :: BuiltinBuilder
+genUnzip = genNoInsts $ genVarArgs genUnzip'
+genUnzip' :: (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> TranslatorSession [AST.ConcSm]
+genUnzip' (Left res) f args@[arg] = do
+ let error_msg = "\nGenerate.genUnzip: Cannot generate unzip call: " ++ pprString res ++ " = " ++ pprString f ++ " " ++ pprString arg
+ htype <- MonadState.lift tsType $ mkHType error_msg (Var.varType arg)
+ -- Prepare a unconditional assignment, for the case when either part
+ -- of the unzip is a state variable, which will disappear in the
+ -- resulting VHDL, making the the unzip no longer required.
+ case htype of
+ -- A normal vector containing two-tuples
+ VecType _ (AggrType _ [_, _]) -> do {
+ -- Setup the generate scheme
+ ; len <- MonadState.lift tsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) arg
+ -- TODO: Use something better than varToString
+ ; let { label = mkVHDLExtId ("unzipVector" ++ (varToString res))
+ ; n_id = mkVHDLBasicId "n"
+ ; n_expr = idToVHDLExpr n_id
+ ; range = AST.ToRange (AST.PrimLit "0") (AST.PrimLit $ show (len-1))
+ ; genScheme = AST.ForGn n_id range
+ ; resname' = varToVHDLName res
+ ; argexpr' = mkIndexedName (varToVHDLName arg) n_expr
+ } ;
+ ; reslabels <- MonadState.lift tsType $ getFieldLabels (Var.varType res)
+ ; arglabels <- MonadState.lift tsType $ getFieldLabels (tfvec_elem (Var.varType arg))
+ ; let { resnameA = mkIndexedName (mkSelectedName resname' (reslabels!!0)) n_expr
+ ; resnameB = mkIndexedName (mkSelectedName resname' (reslabels!!1)) n_expr
+ ; argexprA = vhdlNameToVHDLExpr $ mkSelectedName argexpr' (arglabels!!0)
+ ; argexprB = vhdlNameToVHDLExpr $ mkSelectedName argexpr' (arglabels!!1)
+ ; resA_assign = mkUncondAssign (Right resnameA) argexprA
+ ; resB_assign = mkUncondAssign (Right resnameB) argexprB
+ } ;
+ -- Return the generate functions
+ ; return [AST.CSGSm $ AST.GenerateSm label genScheme [] [resA_assign,resB_assign]]
+ }
+ -- Both elements of the tuple were state, so they've disappeared. No
+ -- need to do anything
+ VecType _ (AggrType _ []) -> return []
+ -- A vector containing aggregates with more than two elements?
+ VecType _ (AggrType _ _) -> error $ "Unzipping a value that is not a vector of two-tuples? Value: " ++ pprString arg ++ "\nType: " ++ pprString (Var.varType arg)
+ -- One of the elements of the tuple was state, so there won't be a
+ -- tuple (record) in the VHDL output. We can just do a plain
+ -- assignment, then.
+ VecType _ _ -> do
+ argexpr <- MonadState.lift tsType $ varToVHDLExpr arg
+ return [mkUncondAssign (Left res) argexpr]
+ _ -> error $ "Unzipping a value that is not a vector? Value: " ++ pprString arg ++ "\nType: " ++ pprString (Var.varType arg) ++ "\nhtype: " ++ show htype
genCopy :: BuiltinBuilder
-genCopy = genVarArgs genCopy'
-genCopy' :: (Either CoreSyn.CoreBndr AST.VHDLName ) -> CoreSyn.CoreBndr -> [Var.Var] -> VHDLSession [AST.ConcSm]
+genCopy = genNoInsts $ genVarArgs genCopy'
+genCopy' :: (Either CoreSyn.CoreBndr AST.VHDLName ) -> CoreSyn.CoreBndr -> [Var.Var] -> TranslatorSession [AST.ConcSm]
genCopy' (Left res) f args@[arg] =
let
resExpr = AST.Aggregate [AST.ElemAssoc (Just AST.Others)
- (AST.PrimName $ (varToVHDLName arg))]
+ (AST.PrimName (varToVHDLName arg))]
out_assign = mkUncondAssign (Left res) resExpr
in
return [out_assign]
genConcat :: BuiltinBuilder
-genConcat = genVarArgs genConcat'
-genConcat' :: (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> VHDLSession [AST.ConcSm]
+genConcat = genNoInsts $ genVarArgs genConcat'
+genConcat' :: (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> TranslatorSession [AST.ConcSm]
genConcat' (Left res) f args@[arg] = do {
-- Setup the generate scheme
- ; len1 <- MonadState.lift vsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) arg
- ; let (_, nvec) = splitAppTy (Var.varType arg)
- ; len2 <- MonadState.lift vsType $ tfp_to_int $ tfvec_len_ty nvec
+ ; len1 <- MonadState.lift tsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) arg
+ ; let (_, nvec) = Type.splitAppTy (Var.varType arg)
+ ; len2 <- MonadState.lift tsType $ tfp_to_int $ tfvec_len_ty nvec
-- TODO: Use something better than varToString
; let { label = mkVHDLExtId ("concatVector" ++ (varToString res))
; n_id = mkVHDLBasicId "n"
genIterateOrGenerate :: Bool -> BuiltinBuilder
genIterateOrGenerate iter = genVarArgs (genIterateOrGenerate' iter)
-genIterateOrGenerate' :: Bool -> (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> VHDLSession [AST.ConcSm]
+genIterateOrGenerate' :: Bool -> (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> TranslatorSession ([AST.ConcSm], [CoreSyn.CoreBndr])
genIterateOrGenerate' iter (Left res) f args = do
- len <- MonadState.lift vsType $ tfp_to_int ((tfvec_len_ty . Var.varType) res)
+ len <- MonadState.lift tsType $ tfp_to_int ((tfvec_len_ty . Var.varType) res)
genIterateOrGenerate'' len iter (Left res) f args
-genIterateOrGenerate'' :: Int -> Bool -> (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> VHDLSession [AST.ConcSm]
+genIterateOrGenerate'' :: Int -> Bool -> (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> TranslatorSession ([AST.ConcSm], [CoreSyn.CoreBndr])
-- Special case for an empty input vector, just assign start to res
-genIterateOrGenerate'' len iter (Left res) _ [app_f, start] | len == 0 = return [mkUncondAssign (Left res) (AST.PrimLit "\"\"")]
+genIterateOrGenerate'' len iter (Left res) _ [app_f, start] | len == 0 = return ([mkUncondAssign (Left res) (AST.PrimLit "\"\"")], [])
genIterateOrGenerate'' len iter (Left res) f [app_f, start] = do
-- The vector length
- -- len <- MonadState.lift vsType $ tfp_to_int ((tfvec_len_ty . Var.varType) res)
+ -- len <- MonadState.lift tsType $ tfp_to_int ((tfvec_len_ty . Var.varType) res)
-- An expression for len-1
let len_min_expr = (AST.PrimLit $ show (len-1))
-- -- evec is (TFVec n), so it still needs an element type
-- -- temporary vector
let tmp_ty = Var.varType res
let error_msg = "\nGenerate.genFold': Can not construct temp vector for element type: " ++ pprString tmp_ty
- tmp_vhdl_ty <- MonadState.lift vsType $ vhdl_ty error_msg tmp_ty
+ -- TODO: Handle Nothing
+ Just tmp_vhdl_ty <- MonadState.lift tsType $ vhdlTy error_msg tmp_ty
-- Setup the generate scheme
let gen_label = mkVHDLExtId ("iterateVector" ++ (varToString start))
let block_label = mkVHDLExtId ("iterateVector" ++ (varToString res))
-- Make the intermediate vector
let tmp_dec = AST.BDISD $ AST.SigDec tmp_id tmp_vhdl_ty Nothing
-- Create the generate statement
- cells <- sequence [genFirstCell, genOtherCell]
+ cells' <- sequence [genFirstCell, genOtherCell]
+ let (cells, useds) = unzip cells'
let gen_sm = AST.GenerateSm gen_label gen_scheme [] (map AST.CSGSm cells)
-- Assign tmp[len-1] or tmp[0] to res
let out_assign = mkUncondAssign (Left res) $ vhdlNameToVHDLExpr tmp_name
let block = AST.BlockSm block_label [] (AST.PMapAspect []) [tmp_dec] [AST.CSGSm gen_sm, out_assign]
- return [AST.CSBSm block]
+ return ([AST.CSBSm block], concat useds)
where
-- An id for the counter
n_id = mkVHDLBasicId "n"
tmp_id = mkVHDLBasicId "tmp"
tmp_name = AST.NSimple tmp_id
-- Generate parts of the fold
- genFirstCell, genOtherCell :: VHDLSession AST.GenerateSm
+ genFirstCell, genOtherCell :: TranslatorSession (AST.GenerateSm, [CoreSyn.CoreBndr])
genFirstCell = do
let cond_label = mkVHDLExtId "firstcell"
-- if n == 0 or n == len-1
-- Output to tmp[current n]
let resname = mkIndexedName tmp_name n_cur
-- Input from start
- argexpr <- MonadState.lift vsType $ varToVHDLExpr start
+ argexpr <- MonadState.lift tsType $ varToVHDLExpr start
let startassign = mkUncondAssign (Right resname) argexpr
- app_concsms <- genApplication (Right resname) app_f [Right argexpr]
+ (app_concsms, used) <- genApplication (Right resname) app_f [Right argexpr]
-- Return the conditional generate part
- return $ AST.GenerateSm cond_label cond_scheme [] (if iter then
+ let gensm = AST.GenerateSm cond_label cond_scheme [] (if iter then
[startassign]
else
app_concsms
)
+ return (gensm, used)
genOtherCell = do
let cond_label = mkVHDLExtId "othercell"
let resname = mkIndexedName tmp_name n_cur
-- Input from tmp[previous n]
let argexpr = vhdlNameToVHDLExpr $ mkIndexedName tmp_name n_prev
- app_concsms <- genApplication (Right resname) app_f [Right argexpr]
+ (app_concsms, used) <- genApplication (Right resname) app_f [Right argexpr]
-- Return the conditional generate part
- return $ AST.GenerateSm cond_label cond_scheme [] app_concsms
+ return (AST.GenerateSm cond_label cond_scheme [] app_concsms, used)
+genBlockRAM :: BuiltinBuilder
+genBlockRAM = genNoInsts $ genExprArgs genBlockRAM'
+genBlockRAM' :: (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [AST.Expr] -> TranslatorSession [AST.ConcSm]
+genBlockRAM' (Left res) f args@[data_in,rdaddr,wraddr,wrenable] = do
+ -- Get the ram type
+ let (tup,data_out) = Type.splitAppTy (Var.varType res)
+ let (tup',ramvec) = Type.splitAppTy tup
+ let Just realram = Type.coreView ramvec
+ let Just (tycon, types) = Type.splitTyConApp_maybe realram
+ Just ram_vhdl_ty <- MonadState.lift tsType $ vhdlTy "wtf" (head types)
+ -- Make the intermediate vector
+ let ram_dec = AST.BDISD $ AST.SigDec ram_id ram_vhdl_ty Nothing
+ -- Get the data_out name
+ -- reslabels <- MonadState.lift tsType $ getFieldLabels (Var.varType res)
+ let resname = varToVHDLName res
+ -- let resname = mkSelectedName resname' (reslabels!!0)
+ let rdaddr_int = genExprFCall (mkVHDLBasicId toIntegerId) rdaddr
+ let argexpr = vhdlNameToVHDLExpr $ mkIndexedName (AST.NSimple ram_id) rdaddr_int
+ let assign = mkUncondAssign (Right resname) argexpr
+ let block_label = mkVHDLExtId ("blockRAM" ++ (varToString res))
+ let block = AST.BlockSm block_label [] (AST.PMapAspect []) [ram_dec] [assign, mkUpdateProcSm]
+ return [AST.CSBSm block]
+ where
+ ram_id = mkVHDLBasicId "ram"
+ mkUpdateProcSm :: AST.ConcSm
+ mkUpdateProcSm = AST.CSPSm $ AST.ProcSm proclabel [clockId] [statement]
+ where
+ proclabel = mkVHDLBasicId "updateRAM"
+ rising_edge = mkVHDLBasicId "rising_edge"
+ wraddr_int = genExprFCall (mkVHDLBasicId toIntegerId) wraddr
+ ramloc = mkIndexedName (AST.NSimple ram_id) wraddr_int
+ wform = AST.Wform [AST.WformElem data_in Nothing]
+ ramassign = AST.SigAssign ramloc wform
+ rising_edge_clk = genExprFCall rising_edge (AST.PrimName $ AST.NSimple clockId)
+ statement = AST.IfSm (AST.And rising_edge_clk wrenable) [ramassign] [] Nothing
+
+genSplit :: BuiltinBuilder
+genSplit = genNoInsts $ genVarArgs genSplit'
+
+genSplit' :: (Either CoreSyn.CoreBndr AST.VHDLName) -> CoreSyn.CoreBndr -> [Var.Var] -> TranslatorSession [AST.ConcSm]
+genSplit' (Left res) f args@[vecIn] = do {
+ ; labels <- MonadState.lift tsType $ getFieldLabels (Var.varType res)
+ ; len <- MonadState.lift tsType $ tfp_to_int $ (tfvec_len_ty . Var.varType) vecIn
+ ; let { block_label = mkVHDLExtId ("split" ++ (varToString vecIn))
+ ; halflen = round ((fromIntegral len) / 2)
+ ; rangeL = vecSlice (AST.PrimLit "0") (AST.PrimLit $ show (halflen - 1))
+ ; rangeR = vecSlice (AST.PrimLit $ show halflen) (AST.PrimLit $ show (len - 1))
+ ; resname = varToVHDLName res
+ ; resnameL = mkSelectedName resname (labels!!0)
+ ; resnameR = mkSelectedName resname (labels!!1)
+ ; argexprL = vhdlNameToVHDLExpr rangeL
+ ; argexprR = vhdlNameToVHDLExpr rangeR
+ ; out_assignL = mkUncondAssign (Right resnameL) argexprL
+ ; out_assignR = mkUncondAssign (Right resnameR) argexprR
+ ; block = AST.BlockSm block_label [] (AST.PMapAspect []) [] [out_assignL, out_assignR]
+ }
+ ; return [AST.CSBSm block]
+ }
+ where
+ vecSlice init last = AST.NSlice (AST.SliceName (varToVHDLName res)
+ (AST.ToRange init last))
-----------------------------------------------------------------------------
-- Function to generate VHDL for applications
-----------------------------------------------------------------------------
(Either CoreSyn.CoreBndr AST.VHDLName) -- ^ Where to store the result?
-> CoreSyn.CoreBndr -- ^ The function to apply
-> [Either CoreSyn.CoreExpr AST.Expr] -- ^ The arguments to apply
- -> VHDLSession [AST.ConcSm] -- ^ The resulting concurrent statements
+ -> TranslatorSession ([AST.ConcSm], [CoreSyn.CoreBndr])
+ -- ^ The corresponding VHDL concurrent statements and entities
+ -- instantiated.
genApplication dst f args = do
- case Var.isGlobalId f of
- False -> 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.
- case (Map.lookup f signatures) of
- Just signature -> do
- args' <- eitherCoreOrExprArgs args
- -- We have a signature, this is a top level binding. Generate a
- -- component instantiation.
- let entity_id = ent_id signature
- -- TODO: Using show here isn't really pretty, but we'll need some
- -- unique-ish value...
- let label = "comp_ins_" ++ (either show prettyShow) dst
- let portmaps = mkAssocElems args' ((either varToVHDLName id) dst) signature
- return [mkComponentInst label entity_id portmaps]
- Nothing -> do
- -- No signature, so this must be a local variable reference. It
- -- should have a representable type (and thus, no arguments) and a
- -- signal should be generated for it. Just generate an
- -- unconditional assignment here.
- f' <- MonadState.lift vsType $ varToVHDLExpr f
- return $ [mkUncondAssign dst f']
- True ->
- case Var.idDetails f of
- IdInfo.DataConWorkId dc -> case dst of
- -- It's a datacon. Create a record from its arguments.
- Left bndr -> do
- -- We have the bndr, so we can get at the type
- labels <- MonadState.lift vsType $ getFieldLabels (Var.varType bndr)
- args' <- eitherCoreOrExprArgs args
- return $ zipWith mkassign labels $ args'
- where
- mkassign :: AST.VHDLId -> AST.Expr -> AST.ConcSm
- mkassign label arg =
- let sel_name = mkSelectedName ((either varToVHDLName id) dst) label in
- mkUncondAssign (Right sel_name) arg
- Right _ -> error $ "\nGenerate.genApplication: Can't generate dataconstructor application without an original binder"
- IdInfo.VanillaId -> do
- -- It's a global value imported from elsewhere. These can be builtin
- -- functions. Look up the function name in the name table and execute
- -- the associated builder if there is any and the argument count matches
- -- (this should always be the case if it typechecks, but just to be
- -- sure...).
- case (Map.lookup (varToString f) globalNameTable) of
- Just (arg_count, builder) ->
- if length args == arg_count then
- builder dst f args
- else
- error $ "\nGenerate.genApplication(VanillaGlobal): Incorrect number of arguments to builtin function: " ++ pprString f ++ " Args: " ++ show args
- Nothing -> error $ "\nGenerate.genApplication(VanillaGlobal): Using function from another module that is not a known builtin: " ++ pprString f
- IdInfo.ClassOpId cls -> do
- -- FIXME: Not looking for what instance this class op is called for
- -- Is quite stupid of course.
- case (Map.lookup (varToString f) globalNameTable) of
- Just (arg_count, builder) ->
- if length args == arg_count then
- builder dst f args
- else
- error $ "\nGenerate.genApplication(ClassOpId): Incorrect number of arguments to builtin function: " ++ pprString f ++ " Args: " ++ show args
- Nothing -> error $ "\nGenerate.genApplication(ClassOpId): Using function from another module that is not a known builtin: " ++ pprString f
- details -> error $ "\nGenerate.genApplication: Calling unsupported function " ++ pprString f ++ " with GlobalIdDetails " ++ pprString details
-
+ nonemptydst <- case dst of
+ Left bndr -> hasNonEmptyType bndr
+ Right _ -> return True
+ if nonemptydst
+ then
+ if Var.isGlobalId f then
+ case Var.idDetails f of
+ IdInfo.DataConWorkId dc -> case dst of
+ -- It's a datacon. Create a record from its arguments.
+ Left bndr -> do
+ -- We have the bndr, so we can get at the type
+ htype <- MonadState.lift tsType $ mkHTypeEither (Var.varType bndr)
+ let argsNostate = filter (\x -> not (either hasStateType (\x -> False) x)) args
+ case argsNostate of
+ [arg] -> do
+ [arg'] <- argsToVHDLExprs [arg]
+ return ([mkUncondAssign dst arg'], [])
+ otherwise ->
+ case htype of
+ Right (AggrType _ _) -> do
+ labels <- MonadState.lift tsType $ getFieldLabels (Var.varType bndr)
+ args' <- argsToVHDLExprs argsNostate
+ return (zipWith mkassign labels args', [])
+ where
+ mkassign :: AST.VHDLId -> AST.Expr -> AST.ConcSm
+ mkassign label arg =
+ let sel_name = mkSelectedName ((either varToVHDLName id) dst) label in
+ mkUncondAssign (Right sel_name) arg
+ _ -> do -- error $ "DIE!"
+ args' <- argsToVHDLExprs argsNostate
+ return ([mkUncondAssign dst (head args')], [])
+ Right _ -> error "\nGenerate.genApplication(DataConWorkId): Can't generate dataconstructor application without an original binder"
+ IdInfo.DataConWrapId dc -> case dst of
+ -- It's a datacon. Create a record from its arguments.
+ Left bndr ->
+ case (Map.lookup (varToString f) globalNameTable) of
+ Just (arg_count, builder) ->
+ if length args == arg_count then
+ builder dst f args
+ else
+ error $ "\nGenerate.genApplication(DataConWrapId): Incorrect number of arguments to builtin function: " ++ pprString f ++ " Args: " ++ show args
+ Nothing -> error $ "\nGenerate.genApplication(DataConWrapId): Can't generate dataconwrapper: " ++ (show dc)
+ Right _ -> error "\nGenerate.genApplication(DataConWrapId): Can't generate dataconwrapper application without an original binder"
+ IdInfo.VanillaId ->
+ -- It's a global value imported from elsewhere. These can be builtin
+ -- functions. Look up the function name in the name table and execute
+ -- the associated builder if there is any and the argument count matches
+ -- (this should always be the case if it typechecks, but just to be
+ -- sure...).
+ case (Map.lookup (varToString f) globalNameTable) of
+ Just (arg_count, builder) ->
+ if length args == arg_count then
+ builder dst f args
+ else
+ error $ "\nGenerate.genApplication(VanillaId): Incorrect number of arguments to builtin function: " ++ pprString f ++ " Args: " ++ show args
+ Nothing -> do
+ top <- isTopLevelBinder f
+ if top then
+ do
+ -- Local binder that references a top level binding. Generate a
+ -- component instantiation.
+ signature <- getEntity f
+ args' <- argsToVHDLExprs args
+ let entity_id = ent_id signature
+ -- TODO: Using show here isn't really pretty, but we'll need some
+ -- unique-ish value...
+ let label = "comp_ins_" ++ (either show prettyShow) dst
+ let portmaps = mkAssocElems args' ((either varToVHDLName id) dst) signature
+ return ([mkComponentInst label entity_id portmaps], [f])
+ else
+ -- Not a top level binder, so this must be a local variable reference.
+ -- It should have a representable type (and thus, no arguments) and a
+ -- signal should be generated for it. Just generate an unconditional
+ -- assignment here.
+ -- FIXME : I DONT KNOW IF THE ABOVE COMMENT HOLDS HERE, SO FOR NOW JUST ERROR!
+ -- f' <- MonadState.lift tsType $ varToVHDLExpr f
+ -- return $ ([mkUncondAssign dst f'], [])
+ do errtype <- case dst of
+ Left bndr -> do
+ htype <- MonadState.lift tsType $ mkHTypeEither (Var.varType bndr)
+ return (show htype)
+ Right vhd -> return $ show vhd
+ error ("\nGenerate.genApplication(VanillaId): Using function from another module that is not a known builtin: " ++ (pprString f) ++ "::" ++ errtype)
+ IdInfo.ClassOpId cls ->
+ -- FIXME: Not looking for what instance this class op is called for
+ -- Is quite stupid of course.
+ case (Map.lookup (varToString f) globalNameTable) of
+ Just (arg_count, builder) ->
+ if length args == arg_count then
+ builder dst f args
+ else
+ error $ "\nGenerate.genApplication(ClassOpId): Incorrect number of arguments to builtin function: " ++ pprString f ++ " Args: " ++ show args
+ Nothing -> error $ "\nGenerate.genApplication(ClassOpId): Using function from another module that is not a known builtin: " ++ pprString f
+ details -> error $ "\nGenerate.genApplication: Calling unsupported function " ++ pprString f ++ " with GlobalIdDetails " ++ pprString details
+ else do
+ top <- isTopLevelBinder f
+ if top then
+ do
+ -- Local binder that references a top level binding. Generate a
+ -- component instantiation.
+ signature <- getEntity f
+ args' <- argsToVHDLExprs args
+ let entity_id = ent_id signature
+ -- TODO: Using show here isn't really pretty, but we'll need some
+ -- unique-ish value...
+ let label = "comp_ins_" ++ (either (prettyShow . varToVHDLName) prettyShow) dst
+ let portmaps = mkAssocElems args' ((either varToVHDLName id) dst) signature
+ return ([mkComponentInst label entity_id portmaps], [f])
+ else
+ -- Not a top level binder, so this must be a local variable reference.
+ -- It should have a representable type (and thus, no arguments) and a
+ -- signal should be generated for it. Just generate an unconditional
+ -- assignment here.
+ do f' <- MonadState.lift tsType $ varToVHDLExpr f
+ return ([mkUncondAssign dst f'], [])
+ else -- Destination has empty type, don't generate anything
+ return ([], [])
-----------------------------------------------------------------------------
-- Functions to generate functions dealing with vectors.
-----------------------------------------------------------------------------
vectorFunId :: Type.Type -> String -> TypeSession AST.VHDLId
vectorFunId el_ty fname = do
let error_msg = "\nGenerate.vectorFunId: Can not construct vector function for element: " ++ pprString el_ty
- elemTM <- vhdl_ty error_msg el_ty
+ -- TODO: Handle the Nothing case?
+ elemTM_maybe <- vhdlTy error_msg el_ty
+ let elemTM = Maybe.fromMaybe
+ (error $ "\nGenerate.vectorFunId: Cannot generate vector function \"" ++ fname ++ "\" for the empty type \"" ++ (pprString el_ty) ++ "\"")
+ elemTM_maybe
-- TODO: This should not be duplicated from mk_vector_ty. Probably but it in
-- the VHDLState or something.
let vectorTM = mkVHDLExtId $ "vector_" ++ (AST.fromVHDLId elemTM)
- typefuns <- getA vsTypeFuns
- case Map.lookup (OrdType el_ty, fname) typefuns of
+ typefuns <- MonadState.get tsTypeFuns
+ el_htype <- mkHType error_msg el_ty
+ case Map.lookup (UVecType el_htype, fname) typefuns of
-- Function already generated, just return it
Just (id, _) -> return id
-- Function not generated yet, generate it
let functions = genUnconsVectorFuns elemTM vectorTM
case lookup fname functions of
Just body -> do
- modA vsTypeFuns $ Map.insert (OrdType el_ty, fname) (function_id, (fst body))
+ MonadState.modify tsTypeFuns $ Map.insert (UVecType el_htype, fname) (function_id, (fst body))
mapM_ (vectorFunId el_ty) (snd body)
return function_id
Nothing -> error $ "\nGenerate.vectorFunId: I don't know how to generate vector function " ++ fname
-> [(String, (AST.SubProgBody, [String]))]
genUnconsVectorFuns elemTM vectorTM =
[ (exId, (AST.SubProgBody exSpec [] [exExpr],[]))
- , (replaceId, (AST.SubProgBody replaceSpec [AST.SPVD replaceVar] [replaceExpr,replaceRet],[]))
+ , (replaceId, (AST.SubProgBody replaceSpec [AST.SPVD replaceVar] [replaceExpr1,replaceExpr2,replaceRet],[]))
, (lastId, (AST.SubProgBody lastSpec [] [lastExpr],[]))
, (initId, (AST.SubProgBody initSpec [AST.SPVD initVar] [initExpr, initRet],[]))
- , (takeId, (AST.SubProgBody takeSpec [AST.SPVD takeVar] [takeExpr, takeRet],[]))
+ , (minimumId, (AST.SubProgBody minimumSpec [] [minimumExpr],[]))
+ , (takeId, (AST.SubProgBody takeSpec [AST.SPVD takeVar] [takeExpr, takeRet],[minimumId]))
, (dropId, (AST.SubProgBody dropSpec [AST.SPVD dropVar] [dropExpr, dropRet],[]))
, (plusgtId, (AST.SubProgBody plusgtSpec [AST.SPVD plusgtVar] [plusgtExpr, plusgtRet],[]))
- , (emptyId, (AST.SubProgBody emptySpec [AST.SPCD emptyVar] [emptyExpr],[]))
+ , (emptyId, (AST.SubProgBody emptySpec [AST.SPVD emptyVar] [emptyExpr],[]))
, (singletonId, (AST.SubProgBody singletonSpec [AST.SPVD singletonVar] [singletonRet],[]))
, (copynId, (AST.SubProgBody copynSpec [AST.SPVD copynVar] [copynExpr],[]))
, (selId, (AST.SubProgBody selSpec [AST.SPVD selVar] [selFor, selRet],[]))
vec1Par = AST.unsafeVHDLBasicId "vec1"
vec2Par = AST.unsafeVHDLBasicId "vec2"
nPar = AST.unsafeVHDLBasicId "n"
+ leftPar = AST.unsafeVHDLBasicId "nLeft"
+ rightPar = AST.unsafeVHDLBasicId "nRight"
iId = AST.unsafeVHDLBasicId "i"
iPar = iId
aPar = AST.unsafeVHDLBasicId "a"
fPar = AST.unsafeVHDLBasicId "f"
sPar = AST.unsafeVHDLBasicId "s"
- resId = AST.unsafeVHDLBasicId "res"
+ resId = AST.unsafeVHDLBasicId "res"
exSpec = AST.Function (mkVHDLExtId exId) [AST.IfaceVarDec vecPar vectorTM,
- AST.IfaceVarDec ixPar naturalTM] elemTM
+ AST.IfaceVarDec ixPar unsignedTM] elemTM
exExpr = AST.ReturnSm (Just $ AST.PrimName $ AST.NIndexed
- (AST.IndexedName (AST.NSimple vecPar) [AST.PrimName $
- AST.NSimple ixPar]))
+ (AST.IndexedName (AST.NSimple vecPar) [genExprFCall (mkVHDLBasicId toIntegerId) (AST.PrimName $ AST.NSimple ixPar)]))
replaceSpec = AST.Function (mkVHDLExtId replaceId) [ AST.IfaceVarDec vecPar vectorTM
- , AST.IfaceVarDec iPar naturalTM
+ , AST.IfaceVarDec iPar unsignedTM
, AST.IfaceVarDec aPar elemTM
] vectorTM
-- variable res : fsvec_x (0 to vec'length-1);
(AST.PrimLit "1")) ]))
Nothing
-- res AST.:= vec(0 to i-1) & a & vec(i+1 to length'vec-1)
- replaceExpr = AST.NSimple resId AST.:=
- (vecSlice (AST.PrimLit "0") (AST.PrimName (AST.NSimple iPar) AST.:-: AST.PrimLit "1") AST.:&:
- AST.PrimName (AST.NSimple aPar) AST.:&:
- vecSlice (AST.PrimName (AST.NSimple iPar) AST.:+: AST.PrimLit "1")
- ((AST.PrimName (AST.NAttribute $
- AST.AttribName (AST.NSimple vecPar) (AST.NSimple $ mkVHDLBasicId lengthId) Nothing))
- AST.:-: AST.PrimLit "1"))
+ replaceExpr1 = AST.NSimple resId AST.:= AST.PrimName (AST.NSimple vecPar)
+ replaceExpr2 = AST.NIndexed (AST.IndexedName (AST.NSimple resId) [genExprFCall (mkVHDLBasicId toIntegerId) (AST.PrimName $ AST.NSimple iPar)]) AST.:= AST.PrimName (AST.NSimple aPar)
replaceRet = AST.ReturnSm (Just $ AST.PrimName $ AST.NSimple resId)
vecSlice init last = AST.PrimName (AST.NSlice
(AST.SliceName
(AST.ToRange init last)))
lastSpec = AST.Function (mkVHDLExtId lastId) [AST.IfaceVarDec vecPar vectorTM] elemTM
-- return vec(vec'length-1);
- lastExpr = AST.ReturnSm (Just $ (AST.PrimName $ AST.NIndexed (AST.IndexedName
+ lastExpr = AST.ReturnSm (Just (AST.PrimName $ AST.NIndexed (AST.IndexedName
(AST.NSimple vecPar)
[AST.PrimName (AST.NAttribute $
AST.AttribName (AST.NSimple vecPar) (AST.NSimple $ mkVHDLBasicId lengthId) Nothing)
AST.AttribName (AST.NSimple vecPar) (AST.NSimple $ mkVHDLBasicId lengthId) Nothing)
AST.:-: AST.PrimLit "2"))
initRet = AST.ReturnSm (Just $ AST.PrimName $ AST.NSimple resId)
+ minimumSpec = AST.Function (mkVHDLExtId minimumId) [AST.IfaceVarDec leftPar naturalTM,
+ AST.IfaceVarDec rightPar naturalTM ] naturalTM
+ minimumExpr = AST.IfSm ((AST.PrimName $ AST.NSimple leftPar) AST.:<: (AST.PrimName $ AST.NSimple rightPar))
+ [AST.ReturnSm (Just $ AST.PrimName $ AST.NSimple leftPar)]
+ []
+ (Just $ AST.Else [minimumExprRet])
+ where minimumExprRet = AST.ReturnSm (Just $ AST.PrimName $ AST.NSimple rightPar)
takeSpec = AST.Function (mkVHDLExtId takeId) [AST.IfaceVarDec nPar naturalTM,
AST.IfaceVarDec vecPar vectorTM ] vectorTM
- -- variable res : fsvec_x (0 to n-1);
+ -- variable res : fsvec_x (0 to (minimum (n,vec'length))-1);
+ minLength = AST.PrimFCall $ AST.FCall (AST.NSimple (mkVHDLExtId minimumId))
+ [Nothing AST.:=>: AST.ADExpr (AST.PrimName $ AST.NSimple nPar)
+ ,Nothing AST.:=>: AST.ADExpr (AST.PrimName (AST.NAttribute $
+ AST.AttribName (AST.NSimple vecPar) (AST.NSimple $ mkVHDLBasicId lengthId) Nothing))]
takeVar =
AST.VarDec resId
(AST.SubtypeIn vectorTM
(Just $ AST.ConstraintIndex $ AST.IndexConstraint
[AST.ToRange (AST.PrimLit "0")
- ((AST.PrimName (AST.NSimple nPar)) AST.:-:
+ (minLength AST.:-:
(AST.PrimLit "1")) ]))
Nothing
-- res AST.:= vec(0 to n-1)
takeExpr = AST.NSimple resId AST.:=
- (vecSlice (AST.PrimLit "1")
- (AST.PrimName (AST.NSimple $ nPar) AST.:-: AST.PrimLit "1"))
+ (vecSlice (AST.PrimLit "0")
+ (minLength AST.:-: AST.PrimLit "1"))
takeRet = AST.ReturnSm (Just $ AST.PrimName $ AST.NSimple resId)
dropSpec = AST.Function (mkVHDLExtId dropId) [AST.IfaceVarDec nPar naturalTM,
AST.IfaceVarDec vecPar vectorTM ] vectorTM
plusgtRet = AST.ReturnSm (Just $ AST.PrimName $ AST.NSimple resId)
emptySpec = AST.Function (mkVHDLExtId emptyId) [] vectorTM
emptyVar =
- AST.ConstDec resId
- (AST.SubtypeIn vectorTM Nothing)
- (Just $ AST.PrimLit "\"\"")
+ AST.VarDec resId
+ (AST.SubtypeIn vectorTM
+ (Just $ AST.ConstraintIndex $ AST.IndexConstraint
+ [AST.ToRange (AST.PrimLit "0") (AST.PrimLit "-1")]))
+ Nothing
emptyExpr = AST.ReturnSm (Just $ AST.PrimName (AST.NSimple resId))
singletonSpec = AST.Function (mkVHDLExtId singletonId) [AST.IfaceVarDec aPar elemTM ]
vectorTM
-- for i res'range loop
-- res(i) := vec(f+i*s);
-- end loop;
- selFor = AST.ForSM iId (AST.AttribRange $ AST.AttribName (AST.NSimple resId) (AST.NSimple $ rangeId) Nothing) [selAssign]
+ selFor = AST.ForSM iId (AST.AttribRange $ AST.AttribName (AST.NSimple resId) (AST.NSimple rangeId) Nothing) [selAssign]
-- res(i) := vec(f+i*s);
selAssign = let origExp = AST.PrimName (AST.NSimple fPar) AST.:+:
(AST.PrimName (AST.NSimple iId) AST.:*:
-- res(vec'length-i-1) := vec(i);
-- end loop;
reverseFor =
- AST.ForSM iId (AST.AttribRange $ AST.AttribName (AST.NSimple resId) (AST.NSimple $ rangeId) Nothing) [reverseAssign]
+ AST.ForSM iId (AST.AttribRange $ AST.AttribName (AST.NSimple resId) (AST.NSimple rangeId) Nothing) [reverseAssign]
-- res(vec'length-i-1) := vec(i);
reverseAssign = AST.NIndexed (AST.IndexedName (AST.NSimple resId) [destExp]) AST.:=
(AST.PrimName $ AST.NIndexed (AST.IndexedName (AST.NSimple vecPar)
-- A table of builtin functions
-----------------------------------------------------------------------------
+-- A function that generates VHDL for a builtin function
+type BuiltinBuilder =
+ (Either CoreSyn.CoreBndr AST.VHDLName) -- ^ The destination signal and it's original type
+ -> CoreSyn.CoreBndr -- ^ The function called
+ -> [Either CoreSyn.CoreExpr AST.Expr] -- ^ The value arguments passed (excluding type and
+ -- dictionary arguments).
+ -> TranslatorSession ([AST.ConcSm], [CoreSyn.CoreBndr])
+ -- ^ The corresponding VHDL concurrent statements and entities
+ -- instantiated.
+
+-- A map of a builtin function to VHDL function builder
+type NameTable = Map.Map String (Int, BuiltinBuilder )
+
-- | The builtin functions we support. Maps a name to an argument count and a
-- builder function.
globalNameTable :: NameTable
globalNameTable = Map.fromList
- [ (exId , (2, genFCall False ) )
+ [ (exId , (2, genFCall True ) )
, (replaceId , (3, genFCall False ) )
, (headId , (1, genFCall True ) )
, (lastId , (1, genFCall True ) )
, (hwandId , (2, genOperator2 AST.And ) )
, (hworId , (2, genOperator2 AST.Or ) )
, (hwnotId , (1, genOperator1 AST.Not ) )
+ , (equalityId , (2, genOperator2 (AST.:=:) ) )
+ , (inEqualityId , (2, genOperator2 (AST.:/=:) ) )
+ , (ltId , (2, genOperator2 (AST.:<:) ) )
+ , (lteqId , (2, genOperator2 (AST.:<=:) ) )
+ , (gtId , (2, genOperator2 (AST.:>:) ) )
+ , (gteqId , (2, genOperator2 (AST.:>=:) ) )
+ , (boolOrId , (2, genOperator2 AST.Or ) )
+ , (boolAndId , (2, genOperator2 AST.And ) )
+ , (boolNot , (1, genOperator1 AST.Not ) )
, (plusId , (2, genOperator2 (AST.:+:) ) )
- , (timesId , (2, genOperator2 (AST.:*:) ) )
+ , (timesId , (2, genTimes ) )
, (negateId , (1, genNegation ) )
, (minusId , (2, genOperator2 (AST.:-:) ) )
, (fromSizedWordId , (1, genFromSizedWord ) )
, (fromIntegerId , (1, genFromInteger ) )
- , (resizeId , (1, genResize ) )
+ , (resizeWordId , (1, genResize ) )
+ , (resizeIntId , (1, genResize ) )
+ , (sizedIntId , (1, genSizedInt ) )
+ , (smallIntegerId , (1, genFromInteger ) )
+ , (fstId , (1, genFst ) )
+ , (sndId , (1, genSnd ) )
+ , (blockRAMId , (5, genBlockRAM ) )
+ , (splitId , (1, genSplit ) )
+ --, (tfvecId , (1, genTFVec ) )
+ , (minimumId , (2, error "\nFunction name: \"minimum\" is used internally, use another name"))
]