liquidhaskell-0.9.8.1: src/Data/ByteString/Lazy/Char8_LHAssumptions.hs
{-# OPTIONS_GHC -fplugin=LiquidHaskellBoot #-}
{-# OPTIONS_GHC -Wno-unused-imports #-}
module Data.ByteString.Lazy.Char8_LHAssumptions where
import Data.ByteString.Lazy hiding (hGetNonBlocking, scanl)
import Data.ByteString.Lazy.Char8
import Data.ByteString.Lazy_LHAssumptions()
{-@
assume Data.ByteString.Lazy.Char8.last :: { bs : Data.ByteString.Lazy.ByteString | 1 <= bllen bs } -> GHC.Types.Char
assume Data.ByteString.Lazy.Char8.singleton
:: GHC.Types.Char -> { bs : Data.ByteString.Lazy.ByteString | bllen bs == 1 }
assume Data.ByteString.Lazy.Char8.pack
:: w8s : [GHC.Types.Char]
-> { bs : Data.ByteString.Lazy.ByteString | bllen bs == len w8s }
assume Data.ByteString.Lazy.Char8.unpack
:: bs : Data.ByteString.Lazy.ByteString
-> { w8s : [GHC.Types.Char] | len w8s == bllen bs }
assume Data.ByteString.Lazy.Char8.cons
:: GHC.Types.Char
-> i : Data.ByteString.Lazy.ByteString
-> { o : Data.ByteString.Lazy.ByteString | bllen o == bllen i + 1 }
assume Data.ByteString.Lazy.Char8.snoc
:: i : Data.ByteString.Lazy.ByteString
-> GHC.Types.Char
-> { o : Data.ByteString.Lazy.ByteString | bllen o == bllen i + 1 }
assume Data.ByteString.Lazy.Char8.head
:: { bs : Data.ByteString.Lazy.ByteString | 1 <= bllen bs }
-> GHC.Types.Char
assume Data.ByteString.Lazy.Char8.uncons
:: i : Data.ByteString.Lazy.ByteString
-> Maybe (GHC.Types.Char, { o : Data.ByteString.Lazy.ByteString | bllen o == bllen i - 1 })
assume Data.ByteString.Lazy.Char8.unsnoc
:: i : Data.ByteString.Lazy.ByteString
-> Maybe ({ o : Data.ByteString.Lazy.ByteString | bllen o == bllen i - 1 }, GHC.Types.Char)
assume Data.ByteString.Lazy.Char8.map
:: (GHC.Types.Char -> GHC.Types.Char)
-> i : Data.ByteString.Lazy.ByteString
-> { o : Data.ByteString.Lazy.ByteString | bllen o == bllen i }
assume Data.ByteString.Lazy.Char8.intersperse
:: GHC.Types.Char
-> i : Data.ByteString.Lazy.ByteString
-> { o : Data.ByteString.Lazy.ByteString | (bllen i == 0 <=> bllen o == 0) && (1 <= bllen i <=> bllen o == 2 * bllen i - 1) }
assume Data.ByteString.Lazy.Char8.foldl1
:: (GHC.Types.Char -> GHC.Types.Char -> GHC.Types.Char)
-> { bs : Data.ByteString.Lazy.ByteString | 1 <= bllen bs }
-> GHC.Types.Char
assume Data.ByteString.Lazy.Char8.foldl1'
:: (GHC.Types.Char -> GHC.Types.Char -> GHC.Types.Char)
-> { bs : Data.ByteString.Lazy.ByteString | 1 <= bllen bs }
-> GHC.Types.Char
assume Data.ByteString.Lazy.Char8.foldr1
:: (GHC.Types.Char -> GHC.Types.Char -> GHC.Types.Char)
-> { bs : Data.ByteString.Lazy.ByteString | 1 <= bllen bs }
-> GHC.Types.Char
assume Data.ByteString.Lazy.Char8.concatMap
:: (GHC.Types.Char -> Data.ByteString.Lazy.ByteString)
-> i : Data.ByteString.Lazy.ByteString
-> { o : Data.ByteString.Lazy.ByteString | bllen i == 0 ==> bllen o == 0 }
assume Data.ByteString.Lazy.Char8.any :: (GHC.Types.Char -> GHC.Types.Bool)
-> bs : Data.ByteString.Lazy.ByteString
-> { b : GHC.Types.Bool | bllen bs == 0 ==> not b }
assume Data.ByteString.Lazy.Char8.all :: (GHC.Types.Char -> GHC.Types.Bool)
-> bs : Data.ByteString.Lazy.ByteString
-> { b : GHC.Types.Bool | bllen bs == 0 ==> b }
assume Data.ByteString.Lazy.Char8.maximum :: { bs : Data.ByteString.Lazy.ByteString | 1 <= bllen bs } -> GHC.Types.Char
assume Data.ByteString.Lazy.Char8.minimum :: { bs : Data.ByteString.Lazy.ByteString | 1 <= bllen bs } -> GHC.Types.Char
assume Data.ByteString.Lazy.Char8.scanl
:: (GHC.Types.Char -> GHC.Types.Char -> GHC.Types.Char)
-> GHC.Types.Char
-> i : Data.ByteString.Lazy.ByteString
-> { o : Data.ByteString.Lazy.ByteString | bllen o == bllen i }
assume Data.ByteString.Lazy.Char8.scanl1
:: (GHC.Types.Char -> GHC.Types.Char -> GHC.Types.Char)
-> i : { i : Data.ByteString.Lazy.ByteString | 1 <= bllen i }
-> { o : Data.ByteString.Lazy.ByteString | bllen o == bllen i }
assume Data.ByteString.Lazy.Char8.scanr
:: (GHC.Types.Char -> GHC.Types.Char -> GHC.Types.Char)
-> GHC.Types.Char
-> i : Data.ByteString.Lazy.ByteString
-> { o : Data.ByteString.Lazy.ByteString | bllen o == bllen i }
assume Data.ByteString.Lazy.Char8.scanr1
:: (GHC.Types.Char -> GHC.Types.Char -> GHC.Types.Char)
-> i : { i : Data.ByteString.Lazy.ByteString | 1 <= bllen i }
-> { o : Data.ByteString.Lazy.ByteString | bllen o == bllen i }
assume Data.ByteString.Lazy.Char8.mapAccumL
:: (acc -> GHC.Types.Char -> (acc, GHC.Types.Char))
-> acc
-> i : Data.ByteString.Lazy.ByteString
-> (acc, { o : Data.ByteString.Lazy.ByteString | bllen o == bllen i })
assume Data.ByteString.Lazy.Char8.mapAccumR
:: (acc -> GHC.Types.Char -> (acc, GHC.Types.Char))
-> acc
-> i : Data.ByteString.Lazy.ByteString
-> (acc, { o : Data.ByteString.Lazy.ByteString | bllen o == bllen i })
assume Data.ByteString.Lazy.Char8.replicate
:: n : Int64
-> GHC.Types.Char
-> { bs : Data.ByteString.Lazy.ByteString | bllen bs == n }
assume Data.ByteString.Lazy.Char8.takeWhile
:: (GHC.Types.Char -> GHC.Types.Bool)
-> i : Data.ByteString.Lazy.ByteString
-> { o : Data.ByteString.Lazy.ByteString | bllen o <= bllen i }
assume Data.ByteString.Lazy.Char8.dropWhile
:: (GHC.Types.Char -> GHC.Types.Bool)
-> i : Data.ByteString.Lazy.ByteString
-> { o : Data.ByteString.Lazy.ByteString | bllen o <= bllen i }
assume Data.ByteString.Lazy.Char8.span
:: (GHC.Types.Char -> GHC.Types.Bool)
-> i : Data.ByteString.Lazy.ByteString
-> ( { l : Data.ByteString.Lazy.ByteString | bllen l <= bllen i }
, { r : Data.ByteString.Lazy.ByteString | bllen r <= bllen i }
)
assume Data.ByteString.Lazy.Char8.break
:: (GHC.Types.Char -> GHC.Types.Bool)
-> i : Data.ByteString.Lazy.ByteString
-> ( { l : Data.ByteString.Lazy.ByteString | bllen l <= bllen i }
, { r : Data.ByteString.Lazy.ByteString | bllen r <= bllen i }
)
assume Data.ByteString.Lazy.Char8.groupBy
:: (GHC.Types.Char -> GHC.Types.Char -> GHC.Types.Bool)
-> i : Data.ByteString.Lazy.ByteString
-> [{ o : Data.ByteString.Lazy.ByteString | 1 <= bllen o && bllen o <= bllen i }]
assume Data.ByteString.Lazy.Char8.split
:: GHC.Types.Char
-> i : Data.ByteString.Lazy.ByteString
-> [{ o : Data.ByteString.Lazy.ByteString | bllen o <= bllen i }]
assume Data.ByteString.Lazy.Char8.splitWith
:: (GHC.Types.Char -> GHC.Types.Bool)
-> i : Data.ByteString.Lazy.ByteString
-> [{ o : Data.ByteString.Lazy.ByteString | bllen o <= bllen i }]
assume Data.ByteString.Lazy.Char8.lines
:: i : Data.ByteString.Lazy.ByteString
-> [{ o : Data.ByteString.Lazy.ByteString | bllen o <= bllen i }]
assume Data.ByteString.Lazy.Char8.words
:: i : Data.ByteString.Lazy.ByteString
-> [{ o : Data.ByteString.Lazy.ByteString | bllen o <= bllen i }]
assume Data.ByteString.Lazy.Char8.unlines
:: is : [Data.ByteString.Lazy.ByteString]
-> { o : Data.ByteString.Lazy.ByteString | (len is == 0 <=> bllen o == 0) && bllen o >= len is }
assume Data.ByteString.Lazy.Char8.unwords
:: is : [Data.ByteString.Lazy.ByteString]
-> { o : Data.ByteString.Lazy.ByteString | (len is == 0 ==> bllen o == 0) && (1 <= len is ==> bllen o >= len is - 1) }
assume Data.ByteString.Lazy.Char8.elem
:: GHC.Types.Char
-> bs : Data.ByteString.Lazy.ByteString
-> { b : GHC.Types.Bool | bllen bs == 0 ==> not b }
assume Data.ByteString.Lazy.Char8.notElem
:: GHC.Types.Char
-> bs : Data.ByteString.Lazy.ByteString
-> { b : GHC.Types.Bool | bllen bs == 0 ==> b }
assume Data.ByteString.Lazy.Char8.find
:: (GHC.Types.Char -> GHC.Types.Bool)
-> bs : Data.ByteString.Lazy.ByteString
-> Maybe { w8 : GHC.Types.Char | bllen bs /= 0 }
assume Data.ByteString.Lazy.Char8.filter
:: (GHC.Types.Char -> GHC.Types.Bool)
-> i : Data.ByteString.Lazy.ByteString
-> { o : Data.ByteString.Lazy.ByteString | bllen o <= bllen i }
assume Data.ByteString.Lazy.Char8.index
:: bs : Data.ByteString.Lazy.ByteString
-> { n : Int64 | 0 <= n && n < bllen bs }
-> GHC.Types.Char
assume Data.ByteString.Lazy.Char8.elemIndex
:: GHC.Types.Char
-> bs : Data.ByteString.Lazy.ByteString
-> Maybe { n : Int64 | 0 <= n && n < bllen bs }
assume Data.ByteString.Lazy.Char8.elemIndices
:: GHC.Types.Char
-> bs : Data.ByteString.Lazy.ByteString
-> [{ n : Int64 | 0 <= n && n < bllen bs }]
assume Data.ByteString.Lazy.Char8.findIndex
:: (GHC.Types.Char -> GHC.Types.Bool)
-> bs : Data.ByteString.Lazy.ByteString
-> Maybe { n : Int64 | 0 <= n && n < bllen bs }
assume Data.ByteString.Lazy.Char8.findIndices
:: (GHC.Types.Char -> GHC.Types.Bool)
-> bs : Data.ByteString.Lazy.ByteString
-> [{ n : Int64 | 0 <= n && n < bllen bs }]
assume Data.ByteString.Lazy.Char8.count
:: GHC.Types.Char
-> bs : Data.ByteString.Lazy.ByteString
-> { n : Int64 | 0 <= n && n < bllen bs }
assume Data.ByteString.Lazy.Char8.zip
:: l : Data.ByteString.Lazy.ByteString
-> r : Data.ByteString.Lazy.ByteString
-> { o : [(GHC.Types.Char, GHC.Types.Char)] | len o <= bllen l && len o <= bllen r }
assume Data.ByteString.Lazy.Char8.zipWith
:: (GHC.Types.Char -> GHC.Types.Char -> a)
-> l : Data.ByteString.Lazy.ByteString
-> r : Data.ByteString.Lazy.ByteString
-> { o : [a] | len o <= bllen l && len o <= bllen r }
assume Data.ByteString.Lazy.Char8.unzip
:: i : [(GHC.Types.Char, GHC.Types.Char)]
-> ( { l : Data.ByteString.Lazy.ByteString | bllen l == len i }
, { r : Data.ByteString.Lazy.ByteString | bllen r == len i }
)
assume Data.ByteString.Lazy.ReadInt.readInt
:: i : Data.ByteString.Lazy.ByteString
-> Maybe { p : (Int, { o : Data.ByteString.Lazy.ByteString | bllen o < bllen i}) | bllen i /= 0 }
assume Data.ByteString.Lazy.ReadNat.readInteger
:: i : Data.ByteString.Lazy.ByteString
-> Maybe { p : (Integer, { o : Data.ByteString.Lazy.ByteString | bllen o < bllen i}) | bllen i /= 0 }
@-}