{-# LANGUAGE MagicHash, NoImplicitPrelude, BangPatterns, UnliftedFFITypes #-} ----------------------------------------------------------------------------- -- | -- Module : GHC.CString -- Copyright : (c) The University of Glasgow 2011 -- License : see libraries/ghc-prim/LICENSE -- -- Maintainer : cvs-ghc@haskell.org -- Stability : internal -- Portability : non-portable (GHC Extensions) -- -- GHC C strings definitions (previously in GHC.Base). -- Use GHC.Exts from the base package instead of importing this -- module directly. -- ----------------------------------------------------------------------------- module GHC.CString ( -- * Ascii variants unpackCString#, unpackAppendCString#, unpackFoldrCString#, cstringLength#, -- * Utf variants unpackCStringUtf8#, unpackAppendCStringUtf8#, unpackFoldrCStringUtf8#, -- * Other unpackNBytes#, ) where import GHC.Types hiding (One) import GHC.Prim {- Note [String literals in GHC] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ String literals get quite a bit of special handling in GHC. This Note summarises the moving parts. * Desugaring: see GHC.HsToCore.Match.Literal.dsLit, which in turn calls GHC.Core.Make.mkStringExprFS. The desugarer desugars the Haskell literal "foo" into Core GHC.CString.unpackCString# "foo"# where "foo"# is primitive string literal (of type Addr#). When the string cannot be encoded as a C string, we use UTF8: GHC.CString.unpackCStringUtf8# "foo"# * The library module ghc-prim:GHC.CString has a bunch of functions that work over primitive strings, including GHC.CString.unpackCString# * GHC.Core.Op.ConstantFold has some RULES that optimise certain string operations on literal strings. For example: + Constant folding the desugared form of ("foo" ++ "bar") into ("foobar") + Comparing strings + and more * GHC.Base has a number of regular rules for String literals. + a rule "eqString": (==) @String = eqString where GHC.Base.eqString :: String -> String -> Bool ConstantFold has a RULE for eqString on literals: eqString (Lit "foo"#) (Lit "bar"#) --> False This allows compile time evaluation of things like "foo" == "bar" + A bunch of rules to promote fusion: "unpack" [~1] forall a . unpackCString# a = build (unpackFoldrCString# a) "unpack-list" [1] forall a . unpackFoldrCString# a (:) [] = unpackCString# a "unpack-append" forall a n . unpackFoldrCString# a (:) n = unpackAppendCString# a n And UTF8 variants of these rules. * We allow primitive (unlifted) literal strings to be top-level bindings, breaking out usual rule. See GHC.Core Note [Core top-level string literals] * TODO: There is work on a special code-gen path for top-level boxed strings str :: [Char] str = unpackCString# "foo"# so that they can all share a common code pointer There is a WIP MR on gitlab for this: !3012 -} ----------------------------------------------------------------------------- -- Unpacking C strings ----------------------------------------------------------------------------- -- This code is needed for virtually all programs, since it's used for -- unpacking the strings of error messages. -- Used to be in GHC.Base, but was moved to ghc-prim because the new generics -- stuff uses Strings in the representation, so to give representations for -- ghc-prim types we need unpackCString# {- Note [Inlining unpackCString#] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ There's really no point in ever inlining things like unpackCString# as the loop doesn't specialise in an interesting way and we can't deforest the list constructors (we'd want to use unpackFoldrCString# for this). Moreover, it's pretty small, so there's a danger that it'll be inlined at every literal, which is a waste. Moreover, inlining early may interfere with a variety of rules that are supposed to match unpackCString#, * BuiltInRules in GHC.Core.Opt.ConstantFold; e.g. eqString (unpackCString# (Lit s1)) (unpackCString# (Lit s2) = s1 == s2 * unpacking rules; e.g. in GHC.Base, unpackCString# a = build (unpackFoldrCString# a) * stream fusion rules; e.g. in the `text` library, unstream (S.map safe (S.streamList (GHC.unpackCString# a))) = unpackCString# a Moreover, we want to make it CONLIKE, so that: * the rules in GHC.Core.Opt.ConstantFold will fire when the string is let-bound. E.g. the eqString rule in GHC.Core.Opt.ConstantFold eqString (unpackCString# (Lit s1)) (unpackCString# (Lit s2) = s1==s2 * exprIsConApp_maybe will see the string when we have let x = unpackCString# "foo"# ...(case x of algs)... All of this goes for unpackCStringUtf8# too. -} {- Note [Inlining of unpackFoldrCString] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Usually the unpack-list rule turns unpackFoldrCString# into unpackCString# It also has a BuiltInRule in PrelRules.hs: unpackFoldrCString# "foo" c (unpackFoldrCString# "baz" c n) = unpackFoldrCString# "foobaz" c n We use NOINLINE [0] on the grounds that, unlike unpackCString#, there *is* some point in inlining unpackFoldrCString#, because we get better code for the higher-order function call. This can cause a code size increase but it was minimal when looking at nofib. This is especially important for elem which then results in an allocation free loop. Note [unpackCString# iterating over addr] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ When unpacking unpackCString# and friends repeatedly return a cons cell containing: * The current character we just unpacked. * A thunk to unpack the rest of the string. In order to minimize the size of the thunk we do not index of the start of the string, offsetting into it, but instead increment the addr and always use offset 0#. This works since these two expressions will read from the same address. * `indexCharOffAddr# a i` * `indexCharOffAddr (a `plusAddr#` i) 0#` This way we avoid the need for the thunks to close over both the start of the string and the current offset, saving a word for each character unpacked. This has the additional advantage the we can guarantee that only the increment will happen in the loop. -} unpackCString# :: Addr# -> [Char] {-# NOINLINE CONLIKE unpackCString# #-} unpackCString# :: Addr# -> [Char] unpackCString# Addr# addr | Int# -> Bool isTrue# (Char# ch Char# -> Char# -> Int# `eqChar#` Char# '\0'#) = [] | Bool True = Char# -> Char C# Char# ch forall a. a -> [a] -> [a] : Addr# -> [Char] unpackCString# (Addr# addr Addr# -> Int# -> Addr# `plusAddr#` Int# 1#) where -- See Note [unpackCString# iterating over addr] !ch :: Char# ch = Addr# -> Int# -> Char# indexCharOffAddr# Addr# addr Int# 0# unpackAppendCString# :: Addr# -> [Char] -> [Char] {-# NOINLINE unpackAppendCString# #-} -- See the NOINLINE note on unpackCString# unpackAppendCString# :: Addr# -> [Char] -> [Char] unpackAppendCString# Addr# addr [Char] rest | Int# -> Bool isTrue# (Char# ch Char# -> Char# -> Int# `eqChar#` Char# '\0'#) = [Char] rest | Bool True = Char# -> Char C# Char# ch forall a. a -> [a] -> [a] : Addr# -> [Char] -> [Char] unpackAppendCString# (Addr# addr Addr# -> Int# -> Addr# `plusAddr#` Int# 1#) [Char] rest where -- See Note [unpackCString# iterating over addr] !ch :: Char# ch = Addr# -> Int# -> Char# indexCharOffAddr# Addr# addr Int# 0# -- Usually the unpack-list rule turns unpackFoldrCString# into unpackCString#. -- See Note [String literals in GHC] for more details. -- See [Inlining of unpackFoldrCString] {-# NOINLINE[0] unpackFoldrCString# #-} unpackFoldrCString# :: Addr# -> (Char -> a -> a) -> a -> a unpackFoldrCString# :: forall a. Addr# -> (Char -> a -> a) -> a -> a unpackFoldrCString# Addr# str Char -> a -> a f a z_init = Addr# -> a -> a go Addr# str a z_init where go :: Addr# -> a -> a go Addr# addr a z | Int# -> Bool isTrue# (Char# ch Char# -> Char# -> Int# `eqChar#` Char# '\0'#) = a z | Bool True = Char# -> Char C# Char# ch Char -> a -> a `f` Addr# -> a -> a go (Addr# addr Addr# -> Int# -> Addr# `plusAddr#` Int# 1#) a z where -- See Note [unpackCString# iterating over addr] !ch :: Char# ch = Addr# -> Int# -> Char# indexCharOffAddr# Addr# addr Int# 0# -- There's really no point in inlining this for the same reasons as -- unpackCString. See Note [Inlining unpackCString#] above for details. unpackCStringUtf8# :: Addr# -> [Char] {-# NOINLINE CONLIKE unpackCStringUtf8# #-} unpackCStringUtf8# :: Addr# -> [Char] unpackCStringUtf8# Addr# addr | Int# -> Bool isTrue# (Char# ch Char# -> Char# -> Int# `eqChar#` Char# '\0'# ) = [] | Bool True = let !byte_count :: Bytes byte_count = Char# -> Bytes getByteCount Char# ch !utf_ch :: Char# utf_ch = Bytes -> Char# -> Addr# -> Char# unpackUtf8Char# Bytes byte_count Char# ch Addr# addr !addr' :: Addr# addr' = Addr# addr Addr# -> Bytes -> Addr# `plusBytes` Bytes byte_count in Char# -> Char C# Char# utf_ch forall a. a -> [a] -> [a] : Addr# -> [Char] unpackCStringUtf8# Addr# addr' where -- See Note [unpackCString# iterating over addr] !ch :: Char# ch = Addr# -> Int# -> Char# indexCharOffAddr# Addr# addr Int# 0# unpackAppendCStringUtf8# :: Addr# -> [Char] -> [Char] {-# NOINLINE unpackAppendCStringUtf8# #-} -- See the NOINLINE note on unpackCString# unpackAppendCStringUtf8# :: Addr# -> [Char] -> [Char] unpackAppendCStringUtf8# Addr# addr [Char] rest | Int# -> Bool isTrue# (Char# ch Char# -> Char# -> Int# `eqChar#` Char# '\0'#) = [Char] rest | Bool True = let !byte_count :: Bytes byte_count = Char# -> Bytes getByteCount Char# ch !utf_ch :: Char# utf_ch = Bytes -> Char# -> Addr# -> Char# unpackUtf8Char# Bytes byte_count Char# ch Addr# addr !addr' :: Addr# addr' = (Addr# addr Addr# -> Bytes -> Addr# `plusBytes` Bytes byte_count) in Char# -> Char C# Char# utf_ch forall a. a -> [a] -> [a] : Addr# -> [Char] -> [Char] unpackAppendCStringUtf8# Addr# addr' [Char] rest where -- See Note [unpackCString# iterating over addr] !ch :: Char# ch = Addr# -> Int# -> Char# indexCharOffAddr# Addr# addr Int# 0# -- See Note [Inlining of unpackFoldrCString] {-# NOINLINE[0] unpackFoldrCStringUtf8# #-} unpackFoldrCStringUtf8# :: Addr# -> (Char -> a -> a) -> a -> a unpackFoldrCStringUtf8# :: forall a. Addr# -> (Char -> a -> a) -> a -> a unpackFoldrCStringUtf8# Addr# addr_init Char -> a -> a f a z_init = Addr# -> a -> a go Addr# addr_init a z_init where go :: Addr# -> a -> a go Addr# addr a z | Int# -> Bool isTrue# (Char# ch Char# -> Char# -> Int# `eqChar#` Char# '\0'#) = a z | Bool True = let !byte_count :: Bytes byte_count = Char# -> Bytes getByteCount Char# ch !utf_ch :: Char# utf_ch = Bytes -> Char# -> Addr# -> Char# unpackUtf8Char# Bytes byte_count Char# ch Addr# addr !addr' :: Addr# addr' = (Addr# addr Addr# -> Bytes -> Addr# `plusBytes` Bytes byte_count) in Char# -> Char C# Char# utf_ch Char -> a -> a `f` Addr# -> a -> a go Addr# addr' a z where -- See Note [unpackCString# iterating over addr] !ch :: Char# ch = Addr# -> Int# -> Char# indexCharOffAddr# Addr# addr Int# 0# -- There's really no point in inlining this for the same reasons as -- unpackCString. See Note [Inlining unpackCString#] above for details. unpackNBytes# :: Addr# -> Int# -> [Char] {-# NOINLINE unpackNBytes# #-} unpackNBytes# :: Addr# -> Int# -> [Char] unpackNBytes# Addr# _addr Int# 0# = [] unpackNBytes# Addr# addr Int# len# = [Char] -> Int# -> [Char] unpack [] (Int# len# Int# -> Int# -> Int# -# Int# 1#) where unpack :: [Char] -> Int# -> [Char] unpack :: [Char] -> Int# -> [Char] unpack [Char] acc Int# i# | Int# -> Bool isTrue# (Int# i# Int# -> Int# -> Int# <# Int# 0#) = [Char] acc | Bool True = case Addr# -> Int# -> Char# indexCharOffAddr# Addr# addr Int# i# of Char# ch -> [Char] -> Int# -> [Char] unpack (Char# -> Char C# Char# ch forall a. a -> [a] -> [a] : [Char] acc) (Int# i# Int# -> Int# -> Int# -# Int# 1#) -- The return type is not correct here. We really want CSize, -- but that type is defined in base. However, CSize should always -- match the size of a machine word (I hope), so this is probably -- alright on all platforms that GHC supports. foreign import ccall unsafe "strlen" c_strlen :: Addr# -> Int# -- | Compute the length of a NUL-terminated string. This address -- must refer to immutable memory. GHC includes a built-in rule for -- constant folding when the argument is a statically-known literal. -- That is, a core-to-core pass reduces the expression -- @cstringLength# "hello"#@ to the constant @5#@. cstringLength# :: Addr# -> Int# {-# INLINE[0] cstringLength# #-} cstringLength# :: Addr# -> Int# cstringLength# = Addr# -> Int# c_strlen ------------------------------ --- UTF8 decoding utilities ------------------------------ -- -- These functions make explicit the logic that was originally -- part of unpackCStringUtf8. Since we want the same support for ascii -- and non-ascii a variety of functions needs the same logic. Instead -- of C&P'in the decoding logic all over we have it here once, and then -- force GHC to inline it. -- -- All the overhead of the Bytes argument and calls goes away once all is -- said and done. And what remains is readable code in Haskell land and -- performant code in the resulting binary. data Bytes = One | Two | Three | Four {-# INLINE getByteCount #-} getByteCount :: Char# -> Bytes getByteCount :: Char# -> Bytes getByteCount Char# ch | Int# -> Bool isTrue# (Char# ch Char# -> Char# -> Int# `leChar#` Char# '\x7F'#) = Bytes One | Int# -> Bool isTrue# (Char# ch Char# -> Char# -> Int# `leChar#` Char# '\xDF'#) = Bytes Two | Int# -> Bool isTrue# (Char# ch Char# -> Char# -> Int# `leChar#` Char# '\xEF'#) = Bytes Three | Bool True = Bytes Four {-# INLINE plusBytes #-} plusBytes :: Addr# -> Bytes -> Addr# plusBytes :: Addr# -> Bytes -> Addr# plusBytes Addr# addr Bytes bytes = case Bytes bytes of Bytes One -> Addr# addr Addr# -> Int# -> Addr# `plusAddr#` Int# 1# Bytes Two -> Addr# addr Addr# -> Int# -> Addr# `plusAddr#` Int# 2# Bytes Three -> Addr# addr Addr# -> Int# -> Addr# `plusAddr#` Int# 3# Bytes Four -> Addr# addr Addr# -> Int# -> Addr# `plusAddr#` Int# 4# -- | Take the current address, read unicode char of the given size. -- We obviously want the number of bytes, but we have to read one -- byte to determine the number of bytes for the current codepoint -- so we might as well reuse it and avoid a read. -- -- Side Note: We don't dare to decode all 4 possibilities at once. -- Reading past the end of the addr might trigger an exception. -- For this reason we really have to check the width first and only -- decode after. {-# INLINE unpackUtf8Char# #-} unpackUtf8Char# :: Bytes -> Char# -> Addr# -> Char# unpackUtf8Char# :: Bytes -> Char# -> Addr# -> Char# unpackUtf8Char# Bytes bytes Char# ch Addr# addr = case Bytes bytes of Bytes One -> Char# ch Bytes Two -> (Int# -> Char# chr# (((Char# -> Int# ord# Char# ch Int# -> Int# -> Int# -# Int# 0xC0#) Int# -> Int# -> Int# `uncheckedIShiftL#` Int# 6#) Int# -> Int# -> Int# +# (Char# -> Int# ord# (Addr# -> Int# -> Char# indexCharOffAddr# (Addr# addr Addr# -> Int# -> Addr# `plusAddr#` Int# 1#) Int# 0#) Int# -> Int# -> Int# -# Int# 0x80#))) Bytes Three -> (Int# -> Char# chr# (((Char# -> Int# ord# Char# ch Int# -> Int# -> Int# -# Int# 0xE0#) Int# -> Int# -> Int# `uncheckedIShiftL#` Int# 12#) Int# -> Int# -> Int# +# ((Char# -> Int# ord# (Addr# -> Int# -> Char# indexCharOffAddr# (Addr# addr Addr# -> Int# -> Addr# `plusAddr#` Int# 1#) Int# 0#) Int# -> Int# -> Int# -# Int# 0x80#) Int# -> Int# -> Int# `uncheckedIShiftL#` Int# 6#) Int# -> Int# -> Int# +# (Char# -> Int# ord# (Addr# -> Int# -> Char# indexCharOffAddr# (Addr# addr Addr# -> Int# -> Addr# `plusAddr#` Int# 2#) Int# 0#) Int# -> Int# -> Int# -# Int# 0x80#))) Bytes Four -> (Int# -> Char# chr# (((Char# -> Int# ord# Char# ch Int# -> Int# -> Int# -# Int# 0xF0#) Int# -> Int# -> Int# `uncheckedIShiftL#` Int# 18#) Int# -> Int# -> Int# +# ((Char# -> Int# ord# (Addr# -> Int# -> Char# indexCharOffAddr# (Addr# addr Addr# -> Int# -> Addr# `plusAddr#` Int# 1#) Int# 0#) Int# -> Int# -> Int# -# Int# 0x80#) Int# -> Int# -> Int# `uncheckedIShiftL#` Int# 12#) Int# -> Int# -> Int# +# ((Char# -> Int# ord# (Addr# -> Int# -> Char# indexCharOffAddr# (Addr# addr Addr# -> Int# -> Addr# `plusAddr#` Int# 2#) Int# 0#) Int# -> Int# -> Int# -# Int# 0x80#) Int# -> Int# -> Int# `uncheckedIShiftL#` Int# 6#) Int# -> Int# -> Int# +# (Char# -> Int# ord# (Addr# -> Int# -> Char# indexCharOffAddr# (Addr# addr Addr# -> Int# -> Addr# `plusAddr#` Int# 3#) Int# 0#) Int# -> Int# -> Int# -# Int# 0x80#)))