{-| Copyright : (C) 2016, University of Twente, 2017, QBayLogic, Google Inc. 2017-2019, Myrtle Software Ltd License : BSD2 (see the file LICENSE) Maintainer : Christiaan Baaij 'X': An exception for uninitialized values >>> show (errorX "undefined" :: Integer, 4 :: Int) "(*** Exception: X: undefined CallStack (from HasCallStack): ... >>> showX (errorX "undefined" :: Integer, 4 :: Int) "(X,4)" -} {-# LANGUAGE CPP #-} {-# LANGUAGE EmptyCase #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE GADTs #-} {-# LANGUAGE MultiParamTypeClasses #-} {-# LANGUAGE NoImplicitPrelude #-} {-# LANGUAGE StandaloneDeriving #-} {-# LANGUAGE TemplateHaskell #-} {-# LANGUAGE Trustworthy #-} {-# OPTIONS_GHC -Wno-orphans #-} module Clash.XException ( -- * 'X': An exception for uninitialized values XException(..), errorX, isX, hasX, maybeIsX, maybeHasX, fromJustX, undefined -- * Printing 'X' exceptions as \"X\" , ShowX (..), showsX, printX, showsPrecXWith -- * Strict evaluation , seqX, forceX, deepseqX, rwhnfX, defaultSeqX, hwSeqX -- * Structured undefined / deep evaluation with undefined values , NFDataX (rnfX, deepErrorX, hasUndefined, ensureSpine) ) where import Prelude hiding (undefined) import Clash.Annotations.Primitive (hasBlackBox) import Clash.CPP (maxTupleSize, fSuperStrict) import Clash.XException.TH import Control.Exception (Exception, catch, evaluate, throw) import Control.DeepSeq (NFData, rnf) import Data.Complex (Complex) import Data.Either (isLeft) import Data.Foldable (toList) import Data.Int (Int8, Int16, Int32, Int64) import Data.Ord (Down (Down)) import Data.Ratio (Ratio, numerator, denominator) import qualified Data.Semigroup as SG import qualified Data.Monoid as M import Data.Sequence (Seq(Empty, (:<|))) import Data.Word (Word8, Word16, Word32, Word64) import Foreign.C.Types (CUShort) import GHC.Exts (Char (C#), Double (D#), Float (F#), Int (I#), Word (W#)) import GHC.Generics import GHC.Natural (Natural) import GHC.Show (appPrec) import GHC.Stack (HasCallStack, callStack, prettyCallStack, withFrozenCallStack) import Numeric.Half (Half) import System.IO.Unsafe (unsafeDupablePerformIO) -- $setup -- >>> import Clash.Class.BitPack (pack) -- >>> import Clash.Sized.Vector (Vec) -- >>> import Clash.Sized.RTree (RTree) -- >>> :set -fplugin GHC.TypeLits.Normalise -- >>> :set -fplugin GHC.TypeLits.KnownNat.Solver -- | An exception representing an \"uninitialized\" value. newtype XException = XException String instance Show XException where show (XException s) = s instance Exception XException -- | Either 'seqX' or 'deepSeqX' depending on the value of the cabal flag -- '-fsuper-strict'. If enabled, 'defaultSeqX' will be 'deepseqX', otherwise -- 'seqX'. Flag defaults to /false/ and thus 'seqX'. defaultSeqX :: NFDataX a => a -> b -> b defaultSeqX = if fSuperStrict then deepseqX else seqX {-# INLINE defaultSeqX #-} infixr 0 `defaultSeqX` -- | Like 'error', but throwing an 'XException' instead of an 'ErrorCall' -- -- The 'ShowX' methods print these error-values as \"X\"; instead of error'ing -- out with an exception. errorX :: HasCallStack => String -> a errorX msg = throw (XException ("X: " ++ msg ++ "\n" ++ prettyCallStack callStack)) -- | Like 'seq', however, whereas 'seq' will always do: -- -- > seq _|_ b = _|_ -- -- 'seqX' will do: -- -- > seqX (XException msg) b = b -- > seqX _|_ b = _|_ seqX :: a -> b -> b seqX a b = unsafeDupablePerformIO (catch (evaluate a >> return b) (\(XException _) -> return b)) {-# NOINLINE seqX #-} infixr 0 `seqX` -- | Like 'seqX' in simulation, but will force its first argument to be rendered -- in HDL. This is useful for components that need to be rendered in hardware, -- but otherwise have no meaning in simulation. An example of such a component -- would be an ILA: a component monitoring an internal signal of a design. The -- output of such a component (typically a unit) can be passed as the first -- argument to 'hwSeqX' to ensure the ILA ends up in the generated HDL. -- -- __NB__: the result of 'hwSeqX' must (indirectly) be used at the very top of -- a design. If it's not, Clash will remove it like it does for any other unused -- circuit parts. -- -- __NB__: Make sure the blackbox for the component with zero-width results -- uses 'Clash.Netlist.BlackBox.Types.RenderVoid' hwSeqX :: a -> b -> b hwSeqX = seqX {-# NOINLINE hwSeqX #-} {-# ANN hwSeqX hasBlackBox #-} infixr 0 `hwSeqX` -- | Evaluate a value with given function, returning 'Nothing' if it throws -- 'XException'. -- -- > maybeX hasX 42 = Just 42 -- > maybeX hasX (XException msg) = Nothing -- > maybeX hasX (3, XException msg) = Nothing -- > maybeX hasX (3, _|_) = _|_ -- > maybeX hasX _|_ = _|_ -- > -- > maybeX isX 42 = Just 42 -- > maybeX isX (XException msg) = Nothing -- > maybeX isX (3, XException msg) = Just (3, XException msg) -- > maybeX isX (3, _|_) = Just (3, _|_) -- > maybeX isX _|_ = _|_ -- maybeX :: (a -> Either String a) -> a -> Maybe a maybeX f a = either (const Nothing) Just (f a) -- | Fully evaluate a value, returning 'Nothing' if it throws 'XException'. -- -- > maybeX 42 = Just 42 -- > maybeX (XException msg) = Nothing -- > maybeX (3, XException msg) = Nothing -- > maybeX (3, _|_) = _|_ -- > maybeX _|_ = _|_ -- maybeHasX :: NFData a => a -> Maybe a maybeHasX = maybeX hasX -- | Evaluate a value to WHNF, returning 'Nothing' if it throws 'XException'. -- -- > maybeIsX 42 = Just 42 -- > maybeIsX (XException msg) = Nothing -- > maybeIsX (3, XException msg) = Just (3, XException msg) -- > maybeIsX (3, _|_) = Just (3, _|_) -- > maybeIsX _|_ = _|_ maybeIsX :: a -> Maybe a maybeIsX = maybeX isX -- | Fully evaluate a value, returning @'Left' msg@ if it throws 'XException'. -- If you want to determine if a value contains undefined parts, use -- 'hasUndefined' instead. -- -- > hasX 42 = Right 42 -- > hasX (XException msg) = Left msg -- > hasX (3, XException msg) = Left msg -- > hasX (3, _|_) = _|_ -- > hasX _|_ = _|_ -- -- If a data structure contains multiple 'XException's, the "first" message is -- picked according to the implementation of 'rnf'. hasX :: NFData a => a -> Either String a hasX a = unsafeDupablePerformIO (catch (evaluate (rnf a) >> return (Right a)) (\(XException msg) -> return (Left msg))) {-# NOINLINE hasX #-} -- | Evaluate a value to WHNF, returning @'Left' msg@ if is a 'XException'. -- -- > isX 42 = Right 42 -- > isX (XException msg) = Left msg -- > isX (3, XException msg) = Right (3, XException msg) -- > isX (3, _|_) = (3, _|_) -- > isX _|_ = _|_ isX :: a -> Either String a isX a = unsafeDupablePerformIO (catch (evaluate a >> return (Right a)) (\(XException msg) -> return (Left msg))) {-# NOINLINE isX #-} showXWith :: (a -> ShowS) -> a -> ShowS showXWith f x = \s -> unsafeDupablePerformIO (catch (f <$> evaluate x <*> pure s) (\(XException _) -> return ('X': s))) -- | Use when you want to create a 'ShowX' instance where: -- -- - There is no 'Generic' instance for your data type -- - The 'Generic' derived ShowX method would traverse into the (hidden) -- implementation details of your data type, and you just want to show the -- entire value as \"X\". -- -- Can be used like: -- -- > data T = ... -- > -- > instance Show T where ... -- > -- > instance ShowX T where -- > showsPrecX = showsPrecXWith showsPrec showsPrecXWith :: (Int -> a -> ShowS) -> Int -> a -> ShowS showsPrecXWith f n = showXWith (f n) -- | Like 'shows', but values that normally throw an 'X' exception are -- converted to \"X\", instead of error'ing out with an exception. showsX :: ShowX a => a -> ShowS showsX = showsPrecX 0 -- | Like 'print', but values that normally throw an 'X' exception are -- converted to \"X\", instead of error'ing out with an exception printX :: ShowX a => a -> IO () printX x = putStrLn $ showX x -- | Like the 'Show' class, but values that normally throw an 'X' exception are -- converted to \"X\", instead of error'ing out with an exception. -- -- >>> show (errorX "undefined" :: Integer, 4 :: Int) -- "(*** Exception: X: undefined -- CallStack (from HasCallStack): -- ... -- >>> showX (errorX "undefined" :: Integer, 4 :: Int) -- "(X,4)" -- -- Can be derived using 'GHC.Generics': -- -- > {-# LANGUAGE DeriveGeneric, DeriveAnyClass #-} -- > -- > import Clash.Prelude -- > import GHC.Generics -- > -- > data T = MkTA Int | MkTB Bool -- > deriving (Show,Generic,ShowX) class ShowX a where -- | Like 'showsPrec', but values that normally throw an 'X' exception are -- converted to \"X\", instead of error'ing out with an exception. showsPrecX :: Int -> a -> ShowS -- | Like 'show', but values that normally throw an 'X' exception are -- converted to \"X\", instead of error'ing out with an exception. showX :: a -> String showX x = showsX x "" -- | Like 'showList', but values that normally throw an 'X' exception are -- converted to \"X\", instead of error'ing out with an exception. showListX :: [a] -> ShowS showListX ls s = showListX__ showsX ls s default showsPrecX :: (Generic a, GShowX (Rep a)) => Int -> a -> ShowS showsPrecX = genericShowsPrecX showListX__ :: (a -> ShowS) -> [a] -> ShowS showListX__ showx = showXWith go where go [] s = "[]" ++ s go (x:xs) s = '[' : showx x (showl xs) where showl [] = ']':s showl (y:ys) = ',' : showx y (showl ys) data ShowType = Rec -- Record | Tup -- Tuple | Pref -- Prefix | Inf String -- Infix genericShowsPrecX :: (Generic a, GShowX (Rep a)) => Int -> a -> ShowS genericShowsPrecX n = gshowsPrecX Pref n . from instance ShowX () instance {-# OVERLAPPABLE #-} ShowX a => ShowX [a] where showsPrecX _ = showListX instance ShowX Char where showsPrecX = showsPrecXWith showsPrec instance ShowX Bool instance ShowX Double where showsPrecX = showsPrecXWith showsPrec instance ShowX a => ShowX (Down a) where showsPrecX = showsPrecXWith showsPrecX instance (ShowX a, ShowX b) => ShowX (Either a b) instance ShowX Float where showsPrecX = showsPrecXWith showsPrec instance ShowX Int where showsPrecX = showsPrecXWith showsPrec instance ShowX Int8 where showsPrecX = showsPrecXWith showsPrec instance ShowX Int16 where showsPrecX = showsPrecXWith showsPrec instance ShowX Int32 where showsPrecX = showsPrecXWith showsPrec instance ShowX Int64 where showsPrecX = showsPrecXWith showsPrec instance ShowX Integer where showsPrecX = showsPrecXWith showsPrec instance ShowX Natural where showsPrecX = showsPrecXWith showsPrec instance ShowX a => ShowX (Seq a) where showsPrecX _ = showListX . toList instance ShowX Word where showsPrecX = showsPrecXWith showsPrec instance ShowX Word8 where showsPrecX = showsPrecXWith showsPrec instance ShowX Word16 where showsPrecX = showsPrecXWith showsPrec instance ShowX Word32 where showsPrecX = showsPrecXWith showsPrec instance ShowX Word64 where showsPrecX = showsPrecXWith showsPrec instance ShowX a => ShowX (Maybe a) instance ShowX a => ShowX (Ratio a) where showsPrecX = showsPrecXWith showsPrecX instance ShowX a => ShowX (Complex a) instance {-# OVERLAPPING #-} ShowX String where showsPrecX = showsPrecXWith showsPrec class GShowX f where gshowsPrecX :: ShowType -> Int -> f a -> ShowS isNullary :: f a -> Bool isNullary = error "generic showX (isNullary): unnecessary case" instance GShowX U1 where gshowsPrecX _ _ U1 = id isNullary _ = True instance (ShowX c) => GShowX (K1 i c) where gshowsPrecX _ n (K1 a) = showsPrecX n a isNullary _ = False instance (GShowX a, Constructor c) => GShowX (M1 C c a) where gshowsPrecX _ n c@(M1 x) = case fixity of Prefix -> showParen (n > appPrec && not (isNullary x)) ( (if conIsTuple c then id else showString (conName c)) . (if isNullary x || conIsTuple c then id else showString " ") . showBraces t (gshowsPrecX t appPrec x)) Infix _ m -> showParen (n > m) (showBraces t (gshowsPrecX t m x)) where fixity = conFixity c t = if conIsRecord c then Rec else case conIsTuple c of True -> Tup False -> case fixity of Prefix -> Pref Infix _ _ -> Inf (show (conName c)) showBraces :: ShowType -> ShowS -> ShowS showBraces Rec p = showChar '{' . p . showChar '}' showBraces Tup p = showChar '(' . p . showChar ')' showBraces Pref p = p showBraces (Inf _) p = p conIsTuple :: C1 c f p -> Bool conIsTuple y = tupleName (conName y) where tupleName ('(':',':_) = True tupleName _ = False instance (Selector s, GShowX a) => GShowX (M1 S s a) where gshowsPrecX t n s@(M1 x) | selName s == "" = gshowsPrecX t n x | otherwise = showString (selName s) . showString " = " . gshowsPrecX t 0 x isNullary (M1 x) = isNullary x instance (GShowX a) => GShowX (M1 D d a) where gshowsPrecX t = showsPrecXWith go where go n (M1 x) = gshowsPrecX t n x instance (GShowX a, GShowX b) => GShowX (a :+: b) where gshowsPrecX t n (L1 x) = gshowsPrecX t n x gshowsPrecX t n (R1 x) = gshowsPrecX t n x instance (GShowX a, GShowX b) => GShowX (a :*: b) where gshowsPrecX t@Rec n (a :*: b) = gshowsPrecX t n a . showString ", " . gshowsPrecX t n b gshowsPrecX t@(Inf s) n (a :*: b) = gshowsPrecX t n a . showString s . gshowsPrecX t n b gshowsPrecX t@Tup n (a :*: b) = gshowsPrecX t n a . showChar ',' . gshowsPrecX t n b gshowsPrecX t@Pref n (a :*: b) = gshowsPrecX t (n+1) a . showChar ' ' . gshowsPrecX t (n+1) b -- If we have a product then it is not a nullary constructor isNullary _ = False -- Unboxed types instance GShowX UChar where gshowsPrecX _ _ (UChar c) = showsPrec 0 (C# c) . showChar '#' instance GShowX UDouble where gshowsPrecX _ _ (UDouble d) = showsPrec 0 (D# d) . showString "##" instance GShowX UFloat where gshowsPrecX _ _ (UFloat f) = showsPrec 0 (F# f) . showChar '#' instance GShowX UInt where gshowsPrecX _ _ (UInt i) = showsPrec 0 (I# i) . showChar '#' instance GShowX UWord where gshowsPrecX _ _ (UWord w) = showsPrec 0 (W# w) . showString "##" -- | a variant of 'deepseqX' that is useful in some circumstances: -- -- > forceX x = x `deepseqX` x forceX :: NFDataX a => a -> a forceX x = x `deepseqX` x {-# INLINE forceX #-} -- | 'deepseqX': fully evaluates the first argument, before returning the -- second. Does not propagate 'XException's. deepseqX :: NFDataX a => a -> b -> b deepseqX a b = rnfX a `seq` b {-# NOINLINE deepseqX #-} infixr 0 `deepseqX` -- | Reduce to weak head normal form -- -- Equivalent to @\\x -> 'seqX' x ()@. -- -- Useful for defining 'NFDataX.rnfX' for types for which NF=WHNF holds. rwhnfX :: a -> () rwhnfX = (`seqX` ()) {-# INLINE rwhnfX #-} -- | Hidden internal type-class. Adds a generic implementation for the "NFData" -- part of 'NFDataX' class GNFDataX arity f where grnfX :: RnfArgs arity a -> f a -> () instance GNFDataX arity V1 where grnfX _ x = case x of {} data Zero data One data RnfArgs arity a where RnfArgs0 :: RnfArgs Zero a RnfArgs1 :: (a -> ()) -> RnfArgs One a instance GNFDataX arity U1 where grnfX _ u = if isLeft (isX u) then () else case u of U1 -> () instance NFDataX a => GNFDataX arity (K1 i a) where grnfX _ = rnfX . unK1 {-# INLINEABLE grnfX #-} instance GNFDataX arity a => GNFDataX arity (M1 i c a) where grnfX args a = -- Check for X needed to handle edge-case "data Void" if isLeft (isX a) then () else grnfX args (unM1 a) {-# INLINEABLE grnfX #-} instance (GNFDataX arity a, GNFDataX arity b) => GNFDataX arity (a :*: b) where grnfX args xy@(~(x :*: y)) = if isLeft (isX xy) then () else grnfX args x `seq` grnfX args y {-# INLINEABLE grnfX #-} instance (GNFDataX arity a, GNFDataX arity b) => GNFDataX arity (a :+: b) where grnfX args lrx = if isLeft (isX lrx) then () else case lrx of L1 x -> grnfX args x R1 x -> grnfX args x {-# INLINEABLE grnfX #-} instance GNFDataX One Par1 where grnfX (RnfArgs1 r) = r . unPar1 instance NFDataX1 f => GNFDataX One (Rec1 f) where grnfX (RnfArgs1 r) = liftRnfX r . unRec1 instance (NFDataX1 f, GNFDataX One g) => GNFDataX One (f :.: g) where grnfX args = liftRnfX (grnfX args) . unComp1 class GEnsureSpine f where gEnsureSpine :: f a -> f a instance GEnsureSpine U1 where gEnsureSpine _u = U1 instance NFDataX a => GEnsureSpine (K1 i a) where gEnsureSpine = K1 . ensureSpine . unK1 {-# INLINEABLE gEnsureSpine #-} instance GEnsureSpine a => GEnsureSpine (M1 i c a) where gEnsureSpine a = M1 (gEnsureSpine (unM1 a)) {-# INLINEABLE gEnsureSpine #-} instance (GEnsureSpine a, GEnsureSpine b) => GEnsureSpine (a :*: b) where gEnsureSpine ~(x :*: y) = gEnsureSpine x :*: gEnsureSpine y {-# INLINEABLE gEnsureSpine #-} instance (GEnsureSpine a, GEnsureSpine b) => GEnsureSpine (a :+: b) where gEnsureSpine lrx = case lrx of (L1 x) -> L1 (gEnsureSpine x) (R1 x) -> R1 (gEnsureSpine x) {-# INLINEABLE gEnsureSpine #-} instance GEnsureSpine V1 where gEnsureSpine _ = error "Unreachable code?" -- | A class of functors that can be fully evaluated, according to semantics -- of NFDataX. class NFDataX1 f where -- | 'liftRnfX' should reduce its argument to normal form (that is, fully -- evaluate all sub-components), given an argument to reduce @a@ arguments, -- and then return '()'. -- -- See 'rnfX' for the generic deriving. liftRnfX :: (a -> ()) -> f a -> () default liftRnfX :: (Generic1 f, GNFDataX One (Rep1 f)) => (a -> ()) -> f a -> () liftRnfX r = grnfX (RnfArgs1 r) . from1 class GHasUndefined f where gHasUndefined :: f a -> Bool instance GHasUndefined U1 where gHasUndefined u = if isLeft (isX u) then True else case u of U1 -> False instance NFDataX a => GHasUndefined (K1 i a) where gHasUndefined = hasUndefined . unK1 {-# INLINEABLE gHasUndefined #-} instance GHasUndefined a => GHasUndefined (M1 i c a) where gHasUndefined a = -- Check for X needed to handle edge-case "data Void" if isLeft (isX a) then True else gHasUndefined (unM1 a) {-# INLINEABLE gHasUndefined #-} instance (GHasUndefined a, GHasUndefined b) => GHasUndefined (a :*: b) where gHasUndefined xy@(~(x :*: y)) = if isLeft (isX xy) then True else gHasUndefined x || gHasUndefined y {-# INLINEABLE gHasUndefined #-} instance (GHasUndefined a, GHasUndefined b) => GHasUndefined (a :+: b) where gHasUndefined lrx = if isLeft (isX lrx) then True else case lrx of L1 x -> gHasUndefined x R1 x -> gHasUndefined x {-# INLINEABLE gHasUndefined #-} instance GHasUndefined V1 where gHasUndefined _ = error "Unreachable code?" -- | Class that houses functions dealing with /undefined/ values in Clash. See -- 'deepErrorX' and 'rnfX'. class NFDataX a where -- | Create a value where all the elements have an 'errorX', but the spine -- is defined. deepErrorX :: HasCallStack => String -> a default deepErrorX :: (HasCallStack, Generic a, GDeepErrorX (Rep a)) => String -> a deepErrorX = withFrozenCallStack $ to . gDeepErrorX -- | Determines whether any of parts of a given construct contain undefined -- parts. Note that a negative answer does not mean its bit representation -- is fully defined. For example: -- -- >>> m = Nothing :: Maybe Bool -- >>> hasUndefined m -- False -- >>> pack m -- 0. -- >>> hasUndefined (pack m) -- True -- hasUndefined :: a -> Bool default hasUndefined :: (Generic a, GHasUndefined (Rep a)) => a -> Bool hasUndefined = gHasUndefined . from -- | Create a value where at the very least the spine is defined. For example: -- -- >>> spined = ensureSpine (errorX "?" :: (Int, Int)) -- >>> case spined of (_, _) -> 'a' -- 'a' -- >>> fmap (const 'b') (ensureSpine undefined :: Vec 3 Int) -- <'b','b','b'> -- >>> fmap (const 'c') (ensureSpine undefined :: RTree 2 Int) -- <<'c','c'>,<'c','c'>> -- -- For users familiar with 'Clash.Sized.Vector.lazyV': this is the generalized -- version of it. ensureSpine :: a -> a default ensureSpine :: (Generic a, GEnsureSpine (Rep a)) => a -> a ensureSpine = to . gEnsureSpine . from -- | Evaluate a value to NF. As opposed to 'NFData's 'rnf', it does not bubble -- up 'XException's. rnfX :: a -> () default rnfX :: (Generic a, GNFDataX Zero (Rep a)) => a -> () rnfX = grnfX RnfArgs0 . from instance NFDataX () instance NFDataX b => NFDataX (a -> b) where deepErrorX = pure . deepErrorX rnfX = rwhnfX hasUndefined = error "hasUndefined on Undefined (a -> b): Not Yet Implemented" ensureSpine = id instance NFDataX a => NFDataX (Down a) where deepErrorX = Down . deepErrorX rnfX d@(~(Down x)) = if isLeft (isX d) then () else rnfX x hasUndefined d@(~(Down x))= if isLeft (isX d) then True else hasUndefined x ensureSpine ~(Down x) = Down (ensureSpine x) instance NFDataX Bool instance NFDataX a => NFDataX [a] instance (NFDataX a, NFDataX b) => NFDataX (Either a b) instance NFDataX a => NFDataX (Maybe a) instance NFDataX Char where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Double where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Float where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Int where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Int8 where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Int16 where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Int32 where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Int64 where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Integer where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Natural where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Word where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Word8 where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Word16 where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Word32 where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Word64 where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX CUShort where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX Half where deepErrorX = errorX rnfX = rwhnfX hasUndefined = isLeft . isX ensureSpine = id instance NFDataX a => NFDataX (Seq a) where deepErrorX = errorX rnfX s = if isLeft (isX s) then () else go s where go Empty = () go (x :<| xs) = rnfX x `seq` go xs ensureSpine = id hasUndefined s = if isLeft (isX s) then True else go s where go Empty = False go (x :<| xs) = hasUndefined x || hasUndefined xs instance NFDataX a => NFDataX (Ratio a) where deepErrorX = errorX rnfX r = rnfX (numerator r) `seq` rnfX (denominator r) hasUndefined r = isLeft (isX (numerator r)) || isLeft (isX (denominator r)) ensureSpine = id instance NFDataX a => NFDataX (Complex a) where deepErrorX = errorX instance (NFDataX a, NFDataX b) => NFDataX (SG.Arg a b) instance NFDataX (SG.All) instance NFDataX (SG.Any) instance NFDataX a => NFDataX (SG.Dual a) instance NFDataX a => NFDataX (SG.Endo a) instance NFDataX a => NFDataX (SG.First a) instance NFDataX a => NFDataX (SG.Last a) instance NFDataX a => NFDataX (SG.Max a) instance NFDataX a => NFDataX (SG.Min a) instance NFDataX a => NFDataX (SG.Option a) instance NFDataX a => NFDataX (SG.Product a) instance NFDataX a => NFDataX (SG.Sum a) instance NFDataX a => NFDataX (M.First a) instance NFDataX a => NFDataX (M.Last a) class GDeepErrorX f where gDeepErrorX :: HasCallStack => String -> f a instance GDeepErrorX V1 where gDeepErrorX = errorX instance GDeepErrorX U1 where gDeepErrorX = const U1 instance (GDeepErrorX a) => GDeepErrorX (M1 m d a) where gDeepErrorX e = M1 (gDeepErrorX e) instance (GDeepErrorX f, GDeepErrorX g) => GDeepErrorX (f :*: g) where gDeepErrorX e = gDeepErrorX e :*: gDeepErrorX e instance NFDataX c => GDeepErrorX (K1 i c) where gDeepErrorX e = K1 (deepErrorX e) instance GDeepErrorX (f :+: g) where gDeepErrorX = errorX mkShowXTupleInstances [2..maxTupleSize] mkNFDataXTupleInstances [2..maxTupleSize] undefined :: HasCallStack => a undefined = errorX "undefined" -- | Same as "Data.Maybe.fromJust", but returns a bottom/undefined value that -- other Clash constructs are aware of. fromJustX :: HasCallStack => Maybe a -> a fromJustX Nothing = errorX "isJustX: Nothing" fromJustX (Just a) = a