+-- | Something that defines a signal
+data SigDef =
+ -- | A flattened function application
+ FApp {
+ appFunc :: HsFunction,
+ appArgs :: [SignalMap],
+ appRes :: SignalMap
+ }
+ -- | A conditional signal definition
+ | CondDef {
+ cond :: SignalId,
+ high :: SignalId,
+ low :: SignalId,
+ condRes :: SignalId
+ }
+ -- | Unconditional signal definition
+ | UncondDef {
+ defSrc :: Either SignalId SignalExpr,
+ defDst :: SignalId
+ } deriving (Show, Eq)
+
+-- | Is the given SigDef a FApp?
+is_FApp :: SigDef -> Bool
+is_FApp d = case d of
+ (FApp _ _ _) -> True
+ _ -> False
+
+-- | Which signals are used by the given SigDef?
+sigDefUses :: SigDef -> [SignalId]
+sigDefUses (UncondDef (Left id) _) = [id]
+sigDefUses (UncondDef (Right expr) _) = sigExprUses expr
+sigDefUses (CondDef cond true false _) = [cond, true, false]
+sigDefUses (FApp _ args _) = concat $ map Foldable.toList args
+
+-- | An expression on signals
+data SignalExpr =
+ EqLit SignalId String -- ^ Is the given signal equal to the given (VHDL) literal
+ | Literal String (Maybe Type.Type)-- ^ A literal value, with an optional type to cast to
+ | Eq SignalId SignalId -- ^ A comparison between to signals
+ deriving (Show, Eq)
+
+-- Instantiate Eq for Type, so we can derive Eq for SignalExpr.
+instance Eq Type.Type where
+ (==) = Type.coreEqType
+
+-- | Which signals are used by the given SignalExpr?
+sigExprUses :: SignalExpr -> [SignalId]
+sigExprUses (EqLit id _) = [id]
+sigExprUses (Literal _ _) = []
+sigExprUses (Eq a b) = [a, b]
+
+-- Returns the function used by the given SigDef, if any
+usedHsFunc :: SigDef -> Maybe HsFunction
+usedHsFunc (FApp hsfunc _ _) = Just hsfunc
+usedHsFunc _ = Nothing