-- | -- Module : Cryptol.Eval.Concrete -- Copyright : (c) 2013-2020 Galois, Inc. -- License : BSD3 -- Maintainer : cryptol@galois.com -- Stability : provisional -- Portability : portable {-# LANGUAGE BangPatterns #-} {-# LANGUAGE BlockArguments #-} {-# LANGUAGE LambdaCase #-} {-# LANGUAGE NamedFieldPuns #-} {-# LANGUAGE OverloadedStrings #-} {-# LANGUAGE PatternGuards #-} {-# LANGUAGE Rank2Types #-} {-# LANGUAGE RecordWildCards #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE TupleSections #-} {-# LANGUAGE TypeFamilies #-} {-# LANGUAGE ViewPatterns #-} module Cryptol.Eval.Concrete ( module Cryptol.Backend.Concrete , Value , primTable , toExpr ) where import Control.Monad (guard, zipWithM, foldM, mzero) import Data.Bits (Bits(..)) import Data.Ratio(numerator,denominator) import Data.Word(Word32, Word64) import MonadLib( ChoiceT, findOne, lift ) import qualified LibBF as FP import qualified Cryptol.F2 as F2 import qualified Data.Map.Strict as Map import Data.Map(Map) import Cryptol.TypeCheck.Solver.InfNat (Nat'(..)) import Cryptol.Backend import Cryptol.Backend.Concrete import Cryptol.Backend.FloatHelpers import Cryptol.Backend.Monad import Cryptol.Eval.Generic hiding (logicShift) import Cryptol.Eval.Prims import Cryptol.Eval.Type import Cryptol.Eval.Value import qualified Cryptol.SHA as SHA import qualified Cryptol.AES as AES import qualified Cryptol.PrimeEC as PrimeEC import Cryptol.ModuleSystem.Name import Cryptol.TypeCheck.AST as AST import Cryptol.Utils.Panic (panic) import Cryptol.Utils.Ident (PrimIdent,prelPrim,floatPrim,suiteBPrim,primeECPrim) import Cryptol.Utils.PP import Cryptol.Utils.RecordMap type Value = GenValue Concrete -- Value to Expression conversion ---------------------------------------------- -- | Given an expected type, returns an expression that evaluates to -- this value, if we can determine it. toExpr :: PrimMap -> TValue -> Value -> Eval (Maybe AST.Expr) toExpr prims t0 v0 = findOne (go t0 v0) where prim n = ePrim prims (prelPrim n) go :: TValue -> Value -> ChoiceT Eval Expr go ty val = case (ty,val) of (TVRec tfs, VRecord vfs) -> do -- NB, vfs first argument to keep their display order res <- zipRecordsM (\_lbl v t -> go t =<< lift v) vfs tfs case res of Left _ -> mismatch -- different fields Right efs -> pure (ERec efs) (TVNewtype nt ts tfs, VRecord vfs) -> do -- NB, vfs first argument to keep their display order res <- zipRecordsM (\_lbl v t -> go t =<< lift v) vfs tfs case res of Left _ -> mismatch -- different fields Right efs -> let f = foldl (\x t -> ETApp x (tNumValTy t)) (EVar (ntName nt)) ts in pure (EApp f (ERec efs)) (TVTuple ts, VTuple tvs) -> do guard (length ts == length tvs) ETuple <$> (zipWithM go ts =<< lift (sequence tvs)) (TVBit, VBit b) -> pure (prim (if b then "True" else "False")) (TVInteger, VInteger i) -> pure $ ETApp (ETApp (prim "number") (tNum i)) tInteger (TVIntMod n, VInteger i) -> pure $ ETApp (ETApp (prim "number") (tNum i)) (tIntMod (tNum n)) (TVRational, VRational (SRational n d)) -> do let n' = ETApp (ETApp (prim "number") (tNum n)) tInteger let d' = ETApp (ETApp (prim "number") (tNum d)) tInteger pure $ EApp (EApp (prim "ratio") n') d' (TVFloat e p, VFloat i) -> pure (floatToExpr prims (tNum e) (tNum p) (bfValue i)) (TVSeq _ b, VSeq n svs) -> do ses <- traverse (go b) =<< lift (sequence (enumerateSeqMap n svs)) pure $ EList ses (tValTy b) (TVSeq n TVBit, VWord _ wval) -> do BV _ v <- lift (asWordVal Concrete =<< wval) pure $ ETApp (ETApp (prim "number") (tNum v)) (tWord (tNum n)) (_,VStream{}) -> mzero (_,VFun{}) -> mzero (_,VPoly{}) -> mzero (_,VNumPoly{}) -> mzero _ -> mismatch where mismatch :: forall a. ChoiceT Eval a mismatch = do doc <- lift (ppValue Concrete defaultPPOpts val) panic "Cryptol.Eval.Concrete.toExpr" ["type mismatch:" , pretty (tValTy ty) , render doc ] floatToExpr :: PrimMap -> AST.Type -> AST.Type -> FP.BigFloat -> AST.Expr floatToExpr prims eT pT f = case FP.bfToRep f of FP.BFNaN -> mkP "fpNaN" FP.BFRep sign num -> case (sign,num) of (FP.Pos, FP.Zero) -> mkP "fpPosZero" (FP.Neg, FP.Zero) -> mkP "fpNegZero" (FP.Pos, FP.Inf) -> mkP "fpPosInf" (FP.Neg, FP.Inf) -> mkP "fpNegInf" (_, FP.Num m e) -> let r = toRational m * (2 ^^ e) in EProofApp $ ePrim prims (prelPrim "fraction") `ETApp` tNum (numerator r) `ETApp` tNum (denominator r) `ETApp` tNum (0 :: Int) `ETApp` tFloat eT pT where mkP n = EProofApp $ ePrim prims (floatPrim n) `ETApp` eT `ETApp` pT -- Primitives ------------------------------------------------------------------ primTable :: IO EvalOpts -> Map PrimIdent (Prim Concrete) primTable getEOpts = let sym = Concrete in Map.union (genericPrimTable sym getEOpts) $ Map.union (genericFloatTable sym) $ Map.union suiteBPrims $ Map.union primeECPrims $ Map.fromList $ map (\(n, v) -> (prelPrim n, v)) [ (">>$" , {-# SCC "Prelude::(>>$)" #-} sshrV) -- Shifts and rotates , ("<<" , {-# SCC "Prelude::(<<)" #-} logicShift shiftLW shiftLS) , (">>" , {-# SCC "Prelude::(>>)" #-} logicShift shiftRW shiftRS) , ("<<<" , {-# SCC "Prelude::(<<<)" #-} logicShift rotateLW rotateLS) , (">>>" , {-# SCC "Prelude::(>>>)" #-} logicShift rotateRW rotateRS) -- Indexing and updates , ("@" , {-# SCC "Prelude::(@)" #-} indexPrim sym indexFront_int indexFront_bits indexFront) , ("!" , {-# SCC "Prelude::(!)" #-} indexPrim sym indexBack_int indexBack_bits indexBack) , ("update" , {-# SCC "Prelude::update" #-} updatePrim sym updateFront_word updateFront) , ("updateEnd" , {-# SCC "Prelude::updateEnd" #-} updatePrim sym updateBack_word updateBack) , ("pmult", PFinPoly \u -> PFinPoly \v -> PWordFun \(BV _ x) -> PWordFun \(BV _ y) -> PPrim let z = if u <= v then F2.pmult (fromInteger (u+1)) x y else F2.pmult (fromInteger (v+1)) y x in return . VWord (1+u+v) . pure . WordVal . mkBv (1+u+v) $! z) , ("pmod", PFinPoly \_u -> PFinPoly \v -> PWordFun \(BV w x) -> PWordFun \(BV _ m) -> PPrim do assertSideCondition sym (m /= 0) DivideByZero return . VWord v . pure . WordVal . mkBv v $! F2.pmod (fromInteger w) x m) , ("pdiv", PFinPoly \_u -> PFinPoly \_v -> PWordFun \(BV w x) -> PWordFun \(BV _ m) -> PPrim do assertSideCondition sym (m /= 0) DivideByZero return . VWord w . pure . WordVal . mkBv w $! F2.pdiv (fromInteger w) x m) ] primeECPrims :: Map.Map PrimIdent (Prim Concrete) primeECPrims = Map.fromList $ map (\(n,v) -> (primeECPrim n, v)) [ ("ec_double", {-# SCC "PrimeEC::ec_double" #-} PFinPoly \p -> PFun \s -> PPrim do s' <- toProjectivePoint =<< s let r = PrimeEC.ec_double (PrimeEC.primeModulus p) s' fromProjectivePoint $! r) , ("ec_add_nonzero", {-# SCC "PrimeEC::ec_add_nonzero" #-} PFinPoly \p -> PFun \s -> PFun \t -> PPrim do s' <- toProjectivePoint =<< s t' <- toProjectivePoint =<< t let r = PrimeEC.ec_add_nonzero (PrimeEC.primeModulus p) s' t' fromProjectivePoint $! r) , ("ec_mult", {-# SCC "PrimeEC::ec_mult" #-} PFinPoly \p -> PFun \d -> PFun \s -> PPrim do d' <- fromVInteger <$> d s' <- toProjectivePoint =<< s let r = PrimeEC.ec_mult (PrimeEC.primeModulus p) d' s' fromProjectivePoint $! r) , ("ec_twin_mult", {-# SCC "PrimeEC::ec_twin_mult" #-} PFinPoly \p -> PFun \d0 -> PFun \s -> PFun \d1 -> PFun \t -> PPrim do d0' <- fromVInteger <$> d0 s' <- toProjectivePoint =<< s d1' <- fromVInteger <$> d1 t' <- toProjectivePoint =<< t let r = PrimeEC.ec_twin_mult (PrimeEC.primeModulus p) d0' s' d1' t' fromProjectivePoint $! r) ] toProjectivePoint :: Value -> Eval PrimeEC.ProjectivePoint toProjectivePoint v = PrimeEC.ProjectivePoint <$> f "x" <*> f "y" <*> f "z" where f nm = PrimeEC.integerToBigNat . fromVInteger <$> lookupRecord nm v fromProjectivePoint :: PrimeEC.ProjectivePoint -> Eval Value fromProjectivePoint (PrimeEC.ProjectivePoint x y z) = pure . VRecord . recordFromFields $ [("x", f x), ("y", f y), ("z", f z)] where f i = pure (VInteger (PrimeEC.bigNatToInteger i)) suiteBPrims :: Map.Map PrimIdent (Prim Concrete) suiteBPrims = Map.fromList $ map (\(n, v) -> (suiteBPrim n, v)) [ ("processSHA2_224", {-# SCC "SuiteB::processSHA2_224" #-} PFinPoly \n -> PFun \xs -> PPrim do blks <- enumerateSeqMap n . fromVSeq <$> xs (SHA.SHA256S w0 w1 w2 w3 w4 w5 w6 _) <- foldM (\st blk -> seq st (SHA.processSHA256Block st <$> (toSHA256Block =<< blk))) SHA.initialSHA224State blks let f :: Word32 -> Eval Value f = pure . VWord 32 . pure . WordVal . BV 32 . toInteger zs = finiteSeqMap (map f [w0,w1,w2,w3,w4,w5,w6]) seq zs (pure (VSeq 7 zs))) , ("processSHA2_256", {-# SCC "SuiteB::processSHA2_256" #-} PFinPoly \n -> PFun \xs -> PPrim do blks <- enumerateSeqMap n . fromVSeq <$> xs (SHA.SHA256S w0 w1 w2 w3 w4 w5 w6 w7) <- foldM (\st blk -> seq st (SHA.processSHA256Block st <$> (toSHA256Block =<< blk))) SHA.initialSHA256State blks let f :: Word32 -> Eval Value f = pure . VWord 32 . pure . WordVal . BV 32 . toInteger zs = finiteSeqMap (map f [w0,w1,w2,w3,w4,w5,w6,w7]) seq zs (pure (VSeq 8 zs))) , ("processSHA2_384", {-# SCC "SuiteB::processSHA2_384" #-} PFinPoly \n -> PFun \xs -> PPrim do blks <- enumerateSeqMap n . fromVSeq <$> xs (SHA.SHA512S w0 w1 w2 w3 w4 w5 _ _) <- foldM (\st blk -> seq st (SHA.processSHA512Block st <$> (toSHA512Block =<< blk))) SHA.initialSHA384State blks let f :: Word64 -> Eval Value f = pure . VWord 64 . pure . WordVal . BV 64 . toInteger zs = finiteSeqMap (map f [w0,w1,w2,w3,w4,w5]) seq zs (pure (VSeq 6 zs))) , ("processSHA2_512", {-# SCC "SuiteB::processSHA2_512" #-} PFinPoly \n -> PFun \xs -> PPrim do blks <- enumerateSeqMap n . fromVSeq <$> xs (SHA.SHA512S w0 w1 w2 w3 w4 w5 w6 w7) <- foldM (\st blk -> seq st (SHA.processSHA512Block st <$> (toSHA512Block =<< blk))) SHA.initialSHA512State blks let f :: Word64 -> Eval Value f = pure . VWord 64 . pure . WordVal . BV 64 . toInteger zs = finiteSeqMap (map f [w0,w1,w2,w3,w4,w5,w6,w7]) seq zs (pure (VSeq 8 zs))) , ("AESKeyExpand", {-# SCC "SuiteB::AESKeyExpand" #-} PFinPoly \k -> PFun \seed -> PPrim do ss <- fromVSeq <$> seed let toWord :: Integer -> Eval Word32 toWord i = fromInteger. bvVal <$> (fromVWord Concrete "AESInfKeyExpand" =<< lookupSeqMap ss i) let fromWord :: Word32 -> Eval Value fromWord = pure . VWord 32 . pure . WordVal . BV 32 . toInteger kws <- mapM toWord [0 .. k-1] let ws = AES.keyExpansionWords k kws let len = 4*(k+7) pure (VSeq len (finiteSeqMap (map fromWord ws)))) , ("AESInvMixColumns", {-# SCC "SuiteB::AESInvMixColumns" #-} PFun \st -> PPrim do ss <- fromVSeq <$> st let toWord :: Integer -> Eval Word32 toWord i = fromInteger. bvVal <$> (fromVWord Concrete "AESInvMixColumns" =<< lookupSeqMap ss i) let fromWord :: Word32 -> Eval Value fromWord = pure . VWord 32 . pure . WordVal . BV 32 . toInteger ws <- mapM toWord [0,1,2,3] let ws' = AES.invMixColumns ws pure . VSeq 4 . finiteSeqMap . map fromWord $ ws') , ("AESEncRound", {-# SCC "SuiteB::AESEncRound" #-} PFun \st -> PPrim do ss <- fromVSeq <$> st let toWord :: Integer -> Eval Word32 toWord i = fromInteger. bvVal <$> (fromVWord Concrete "AESEncRound" =<< lookupSeqMap ss i) let fromWord :: Word32 -> Eval Value fromWord = pure . VWord 32 . pure . WordVal . BV 32 . toInteger ws <- mapM toWord [0,1,2,3] let ws' = AES.aesRound ws pure . VSeq 4 . finiteSeqMap . map fromWord $ ws') , ("AESEncFinalRound", {-# SCC "SuiteB::AESEncFinalRound" #-} PFun \st -> PPrim do ss <- fromVSeq <$> st let toWord :: Integer -> Eval Word32 toWord i = fromInteger. bvVal <$> (fromVWord Concrete "AESEncFinalRound" =<< lookupSeqMap ss i) let fromWord :: Word32 -> Eval Value fromWord = pure . VWord 32 . pure . WordVal . BV 32 . toInteger ws <- mapM toWord [0,1,2,3] let ws' = AES.aesFinalRound ws pure . VSeq 4 . finiteSeqMap . map fromWord $ ws') , ("AESDecRound", {-# SCC "SuiteB::AESDecRound" #-} PFun \st -> PPrim do ss <- fromVSeq <$> st let toWord :: Integer -> Eval Word32 toWord i = fromInteger. bvVal <$> (fromVWord Concrete "AESDecRound" =<< lookupSeqMap ss i) let fromWord :: Word32 -> Eval Value fromWord = pure . VWord 32 . pure . WordVal . BV 32 . toInteger ws <- mapM toWord [0,1,2,3] let ws' = AES.aesInvRound ws pure . VSeq 4 . finiteSeqMap . map fromWord $ ws') , ("AESDecFinalRound", {-# SCC "SuiteB::AESDecFinalRound" #-} PFun \st -> PPrim do ss <- fromVSeq <$> st let toWord :: Integer -> Eval Word32 toWord i = fromInteger. bvVal <$> (fromVWord Concrete "AESDecFinalRound" =<< lookupSeqMap ss i) let fromWord :: Word32 -> Eval Value fromWord = pure . VWord 32 . pure . WordVal . BV 32 . toInteger ws <- mapM toWord [0,1,2,3] let ws' = AES.aesInvFinalRound ws pure . VSeq 4 . finiteSeqMap . map fromWord $ ws') ] toSHA256Block :: Value -> Eval SHA.SHA256Block toSHA256Block blk = do let ws = fromVSeq blk let toWord i = fromInteger . bvVal <$> (fromVWord Concrete "toSHA256Block" =<< lookupSeqMap ws i) SHA.SHA256Block <$> (toWord 0) <*> (toWord 1) <*> (toWord 2) <*> (toWord 3) <*> (toWord 4) <*> (toWord 5) <*> (toWord 6) <*> (toWord 7) <*> (toWord 8) <*> (toWord 9) <*> (toWord 10) <*> (toWord 11) <*> (toWord 12) <*> (toWord 13) <*> (toWord 14) <*> (toWord 15) toSHA512Block :: Value -> Eval SHA.SHA512Block toSHA512Block blk = do let ws = fromVSeq blk let toWord i = fromInteger . bvVal <$> (fromVWord Concrete "toSHA512Block" =<< lookupSeqMap ws i) SHA.SHA512Block <$> (toWord 0) <*> (toWord 1) <*> (toWord 2) <*> (toWord 3) <*> (toWord 4) <*> (toWord 5) <*> (toWord 6) <*> (toWord 7) <*> (toWord 8) <*> (toWord 9) <*> (toWord 10) <*> (toWord 11) <*> (toWord 12) <*> (toWord 13) <*> (toWord 14) <*> (toWord 15) -------------------------------------------------------------------------------- sshrV :: Prim Concrete sshrV = PNumPoly \_n -> PTyPoly \ix -> PWordFun \(BV w x) -> PFun \y -> PPrim do idx <- y >>= asIndex Concrete ">>$" ix >>= \case Left idx -> pure idx Right wv -> bvVal <$> asWordVal Concrete wv return $ VWord w $ pure $ WordVal $ mkBv w $ signedShiftRW w x idx logicShift :: (Integer -> Integer -> Integer -> Integer) -- ^ The function may assume its arguments are masked. -- It is responsible for masking its result if needed. -> (Nat' -> TValue -> SeqMap Concrete -> Integer -> SeqMap Concrete) -> Prim Concrete logicShift opW opS = PNumPoly \a -> PTyPoly \_ix -> PTyPoly \c -> PFun \l -> PFun \r -> PPrim do i <- r >>= \case VInteger i -> pure i VWord _ wval -> bvVal <$> (asWordVal Concrete =<< wval) _ -> evalPanic "logicShift" ["not an index"] l >>= \case VWord w wv -> return $ VWord w $ wv >>= \case WordVal (BV _ x) -> return $ WordVal (BV w (opW w x i)) LargeBitsVal n xs -> return $ LargeBitsVal n $ opS (Nat n) c xs i _ -> mkSeq a c <$> (opS a c <$> (fromSeq "logicShift" =<< l) <*> return i) -- Left shift for words. shiftLW :: Integer -> Integer -> Integer -> Integer shiftLW w ival by | by < 0 = shiftRW w ival (negate by) | by >= w = 0 | by > toInteger (maxBound :: Int) = panic "shiftLW" ["Shift amount too large", show by] | otherwise = mask w (shiftL ival (fromInteger by)) -- Right shift for words shiftRW :: Integer -> Integer -> Integer -> Integer shiftRW w ival by | by < 0 = shiftLW w ival (negate by) | by >= w = 0 | by > toInteger (maxBound :: Int) = panic "shiftRW" ["Shift amount too large", show by] | otherwise = shiftR ival (fromInteger by) -- signed right shift for words signedShiftRW :: Integer -> Integer -> Integer -> Integer signedShiftRW w ival by | by < 0 = shiftLW w ival (negate by) | otherwise = let by' = min w by in if by' > toInteger (maxBound :: Int) then panic "signedShiftRW" ["Shift amount too large", show by] else shiftR (signedValue w ival) (fromInteger by') shiftLS :: Nat' -> TValue -> SeqMap Concrete -> Integer -> SeqMap Concrete shiftLS w ety vs by | by < 0 = shiftRS w ety vs (negate by) shiftLS w ety vs by = IndexSeqMap $ \i -> case w of Nat len | i+by < len -> lookupSeqMap vs (i+by) | i < len -> zeroV Concrete ety | otherwise -> evalPanic "shiftLS" ["Index out of bounds"] Inf -> lookupSeqMap vs (i+by) shiftRS :: Nat' -> TValue -> SeqMap Concrete -> Integer -> SeqMap Concrete shiftRS w ety vs by | by < 0 = shiftLS w ety vs (negate by) shiftRS w ety vs by = IndexSeqMap $ \i -> case w of Nat len | i >= by -> lookupSeqMap vs (i-by) | i < len -> zeroV Concrete ety | otherwise -> evalPanic "shiftLS" ["Index out of bounds"] Inf | i >= by -> lookupSeqMap vs (i-by) | otherwise -> zeroV Concrete ety -- XXX integer doesn't implement rotateL, as there's no bit bound rotateLW :: Integer -> Integer -> Integer -> Integer rotateLW 0 i _ = i rotateLW w i by = mask w $ (i `shiftL` b) .|. (i `shiftR` (fromInteger w - b)) where b = fromInteger (by `mod` w) rotateLS :: Nat' -> TValue -> SeqMap Concrete -> Integer -> SeqMap Concrete rotateLS w _ vs by = IndexSeqMap $ \i -> case w of Nat len -> lookupSeqMap vs ((by + i) `mod` len) _ -> panic "Cryptol.Eval.Prim.rotateLS" [ "unexpected infinite sequence" ] -- XXX integer doesn't implement rotateR, as there's no bit bound rotateRW :: Integer -> Integer -> Integer -> Integer rotateRW 0 i _ = i rotateRW w i by = mask w $ (i `shiftR` b) .|. (i `shiftL` (fromInteger w - b)) where b = fromInteger (by `mod` w) rotateRS :: Nat' -> TValue -> SeqMap Concrete -> Integer -> SeqMap Concrete rotateRS w _ vs by = IndexSeqMap $ \i -> case w of Nat len -> lookupSeqMap vs ((len - by + i) `mod` len) _ -> panic "Cryptol.Eval.Prim.rotateRS" [ "unexpected infinite sequence" ] -- Sequence Primitives --------------------------------------------------------- indexFront :: Nat' -> TValue -> SeqMap Concrete -> TValue -> BV -> Eval Value indexFront _mblen _a vs _ix (bvVal -> ix) = lookupSeqMap vs ix indexFront_bits :: Nat' -> TValue -> SeqMap Concrete -> TValue -> [Bool] -> Eval Value indexFront_bits mblen a vs ix bs = indexFront mblen a vs ix =<< packWord Concrete bs indexFront_int :: Nat' -> TValue -> SeqMap Concrete -> TValue -> Integer -> Eval Value indexFront_int _mblen _a vs _ix idx = lookupSeqMap vs idx indexBack :: Nat' -> TValue -> SeqMap Concrete -> TValue -> BV -> Eval Value indexBack mblen a vs ix (bvVal -> idx) = indexBack_int mblen a vs ix idx indexBack_bits :: Nat' -> TValue -> SeqMap Concrete -> TValue -> [Bool] -> Eval Value indexBack_bits mblen a vs ix bs = indexBack mblen a vs ix =<< packWord Concrete bs indexBack_int :: Nat' -> TValue -> SeqMap Concrete -> TValue -> Integer -> Eval Value indexBack_int mblen _a vs _ix idx = case mblen of Nat len -> lookupSeqMap vs (len - idx - 1) Inf -> evalPanic "indexBack" ["unexpected infinite sequence"] updateFront :: Nat' {- ^ length of the sequence -} -> TValue {- ^ type of values in the sequence -} -> SeqMap Concrete {- ^ sequence to update -} -> Either Integer (WordValue Concrete) {- ^ index -} -> Eval Value {- ^ new value at index -} -> Eval (SeqMap Concrete) updateFront _len _eltTy vs (Left idx) val = do return $ updateSeqMap vs idx val updateFront _len _eltTy vs (Right w) val = do idx <- bvVal <$> asWordVal Concrete w return $ updateSeqMap vs idx val updateFront_word :: Nat' {- ^ length of the sequence -} -> TValue {- ^ type of values in the sequence -} -> WordValue Concrete {- ^ bit sequence to update -} -> Either Integer (WordValue Concrete) {- ^ index -} -> Eval Value {- ^ new value at index -} -> Eval (WordValue Concrete) updateFront_word _len _eltTy bs (Left idx) val = do updateWordValue Concrete bs idx (fromVBit <$> val) updateFront_word _len _eltTy bs (Right w) val = do idx <- bvVal <$> asWordVal Concrete w updateWordValue Concrete bs idx (fromVBit <$> val) updateBack :: Nat' {- ^ length of the sequence -} -> TValue {- ^ type of values in the sequence -} -> SeqMap Concrete {- ^ sequence to update -} -> Either Integer (WordValue Concrete) {- ^ index -} -> Eval Value {- ^ new value at index -} -> Eval (SeqMap Concrete) updateBack Inf _eltTy _vs _w _val = evalPanic "Unexpected infinite sequence in updateEnd" [] updateBack (Nat n) _eltTy vs (Left idx) val = do return $ updateSeqMap vs (n - idx - 1) val updateBack (Nat n) _eltTy vs (Right w) val = do idx <- bvVal <$> asWordVal Concrete w return $ updateSeqMap vs (n - idx - 1) val updateBack_word :: Nat' {- ^ length of the sequence -} -> TValue {- ^ type of values in the sequence -} -> WordValue Concrete {- ^ bit sequence to update -} -> Either Integer (WordValue Concrete) {- ^ index -} -> Eval Value {- ^ new value at index -} -> Eval (WordValue Concrete) updateBack_word Inf _eltTy _bs _w _val = evalPanic "Unexpected infinite sequence in updateEnd" [] updateBack_word (Nat n) _eltTy bs (Left idx) val = do updateWordValue Concrete bs (n - idx - 1) (fromVBit <$> val) updateBack_word (Nat n) _eltTy bs (Right w) val = do idx <- bvVal <$> asWordVal Concrete w updateWordValue Concrete bs (n - idx - 1) (fromVBit <$> val)