{-# LANGUAGE Trustworthy #-}
{-# LANGUAGE CPP
           , NoImplicitPrelude
           , RecordWildCards
           , BangPatterns
           , NondecreasingIndentation
           , MagicHash
           , LambdaCase
  #-}
{-# OPTIONS_GHC -Wno-unused-matches #-}
{-# OPTIONS_HADDOCK not-home #-}

-----------------------------------------------------------------------------
-- |
-- Module      :  GHC.IO.Text
-- Copyright   :  (c) The University of Glasgow, 1992-2008
-- License     :  see libraries/base/LICENSE
--
-- Maintainer  :  libraries@haskell.org
-- Stability   :  internal
-- Portability :  non-portable
--
-- String I\/O functions
--
-- /The API of this module is unstable and not meant to be consumed by the general public./
-- If you absolutely must depend on it, make sure to use a tight upper
-- bound, e.g., @base < 4.X@ rather than @base < 5@, because the interface can
-- change rapidly without much warning.
--
-----------------------------------------------------------------------------

module GHC.Internal.IO.Handle.Text (
        hWaitForInput, hGetChar, hGetLine, hGetContents, hPutChar, hPutStr,
        commitBuffer',       -- hack, see below
        hGetBuf, hGetBufSome, hGetBufNonBlocking, hPutBuf, hPutBufNonBlocking,
        memcpy, hPutStrLn, hGetContents',
    ) where

import GHC.Internal.IO
import GHC.Internal.IO.Buffer
import qualified GHC.Internal.IO.BufferedIO as Buffered
import GHC.Internal.IO.Exception
import GHC.Internal.Exception
import GHC.Internal.IO.Handle.Types
import GHC.Internal.IO.Handle.Internals
import qualified GHC.Internal.IO.Device as IODevice
import qualified GHC.Internal.IO.Device as RawIO

import GHC.Internal.Foreign.C.Types
import GHC.Internal.Foreign.Storable

import qualified GHC.Internal.Control.Exception as Exception
import GHC.Internal.System.IO.Error
import GHC.Internal.Data.Either (Either(..))
import GHC.Internal.Data.Maybe

import GHC.Internal.IORef
import GHC.Internal.Base
import GHC.Internal.Real
import GHC.Internal.Word
import GHC.Internal.Ptr
import GHC.Internal.Num
import GHC.Internal.Show
import GHC.Internal.List

-- ---------------------------------------------------------------------------
-- Simple input operations

-- If hWaitForInput finds anything in the Handle's buffer, it
-- immediately returns.  If not, it tries to read from the underlying
-- OS handle. Notice that for buffered Handles connected to terminals
-- this means waiting until a complete line is available.

-- | Computation 'hWaitForInput' @hdl t@
-- waits until input is available on handle @hdl@.
-- It returns 'True' as soon as input is available on @hdl@,
-- or 'False' if no input is available within @t@ milliseconds.  Note that
-- 'hWaitForInput' waits until one or more full /characters/ are available,
-- which means that it needs to do decoding, and hence may fail
-- with a decoding error.
--
-- If @t@ is less than zero, then @hWaitForInput@ waits indefinitely.
--
-- This operation may fail with:
--
--  * 'isEOFError' if the end of file has been reached.
--
--  * a decoding error, if the input begins with an invalid byte sequence
--    in this Handle's encoding.
--
-- NOTE for GHC users: unless you use the @-threaded@ flag,
-- @hWaitForInput hdl t@ where @t >= 0@ will block all other Haskell
-- threads for the duration of the call.  It behaves like a
-- @safe@ foreign call in this respect.
--

hWaitForInput :: Handle -> Int -> IO Bool
hWaitForInput :: Handle -> Int -> IO Bool
hWaitForInput Handle
h Int
msecs =
  String -> Handle -> (Handle__ -> IO Bool) -> IO Bool
forall a. String -> Handle -> (Handle__ -> IO a) -> IO a
wantReadableHandle_ String
"hWaitForInput" Handle
h ((Handle__ -> IO Bool) -> IO Bool)
-> (Handle__ -> IO Bool) -> IO Bool
forall a b. (a -> b) -> a -> b
$ \ handle_ :: Handle__
handle_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
..} -> do
  cbuf <- IORef (Buffer CharBufElem) -> IO (Buffer CharBufElem)
forall a. IORef a -> IO a
readIORef IORef (Buffer CharBufElem)
haCharBuffer

  if not (isEmptyBuffer cbuf) then return True else do

  if msecs < 0
        then do cbuf' <- readTextDevice handle_ cbuf
                writeIORef haCharBuffer cbuf'
                return True
        else do
               -- there might be bytes in the byte buffer waiting to be decoded
               cbuf' <- decodeByteBuf handle_ cbuf
               writeIORef haCharBuffer cbuf'

               if not (isEmptyBuffer cbuf') then return True else do

                r <- IODevice.ready haDevice False{-read-} msecs
                if r then do -- Call hLookAhead' to throw an EOF
                             -- exception if appropriate
                             _ <- hLookAhead_ handle_
                             return True
                     else return False
                -- XXX we should only return when there are full characters
                -- not when there are only bytes.  That would mean looping
                -- and re-running IODevice.ready if we don't have any full
                -- characters; but we don't know how long we've waited
                -- so far.

-- ---------------------------------------------------------------------------
-- hGetChar

-- | Computation 'hGetChar' @hdl@ reads a character from the file or
-- channel managed by @hdl@, blocking until a character is available.
--
-- This operation may fail with:
--
--  * 'isEOFError' if the end of file has been reached.

hGetChar :: Handle -> IO Char
hGetChar :: Handle -> IO CharBufElem
hGetChar Handle
handle =
  String -> Handle -> (Handle__ -> IO CharBufElem) -> IO CharBufElem
forall a. String -> Handle -> (Handle__ -> IO a) -> IO a
wantReadableHandle_ String
"hGetChar" Handle
handle ((Handle__ -> IO CharBufElem) -> IO CharBufElem)
-> (Handle__ -> IO CharBufElem) -> IO CharBufElem
forall a b. (a -> b) -> a -> b
$ \handle_ :: Handle__
handle_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} -> do

  -- buffering mode makes no difference: we just read whatever is available
  -- from the device (blocking only if there is nothing available), and then
  -- return the first character.
  -- See [note Buffered Reading] in GHC.Internal.IO.Handle.Types
  buf0 <- IORef (Buffer CharBufElem) -> IO (Buffer CharBufElem)
forall a. IORef a -> IO a
readIORef IORef (Buffer CharBufElem)
haCharBuffer

  buf1 <- if isEmptyBuffer buf0
             then readTextDevice handle_ buf0
             else return buf0

  (c1,i) <- readCharBuf (bufRaw buf1) (bufL buf1)
  let buf2 = Int -> Buffer CharBufElem -> Buffer CharBufElem
forall e. Int -> Buffer e -> Buffer e
bufferAdjustL Int
i Buffer CharBufElem
buf1

  if haInputNL == CRLF && c1 == '\r'
     then do
            mbuf3 <- if isEmptyBuffer buf2
                      then maybeFillReadBuffer handle_ buf2
                      else return (Just buf2)

            case mbuf3 of
               -- EOF, so just return the '\r' we have
               Maybe (Buffer CharBufElem)
Nothing -> do
                  IORef (Buffer CharBufElem) -> Buffer CharBufElem -> IO ()
forall a. IORef a -> a -> IO ()
writeIORef IORef (Buffer CharBufElem)
haCharBuffer Buffer CharBufElem
buf2
                  CharBufElem -> IO CharBufElem
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return CharBufElem
'\r'
               Just Buffer CharBufElem
buf3 -> do
                  (c2,i2) <- RawCharBuffer -> Int -> IO (CharBufElem, Int)
readCharBuf (Buffer CharBufElem -> RawCharBuffer
forall e. Buffer e -> RawBuffer e
bufRaw Buffer CharBufElem
buf2) (Buffer CharBufElem -> Int
forall e. Buffer e -> Int
bufL Buffer CharBufElem
buf2)
                  if c2 == '\n'
                     then do
                       writeIORef haCharBuffer (bufferAdjustL i2 buf3)
                       return '\n'
                     else do
                       -- not a \r\n sequence, so just return the \r
                       writeIORef haCharBuffer buf3
                       return '\r'
     else do
            writeIORef haCharBuffer buf2
            return c1

-- ---------------------------------------------------------------------------
-- hGetLine

-- | Computation 'hGetLine' @hdl@ reads a line from the file or
-- channel managed by @hdl@.
-- 'hGetLine' does not return the newline as part of the result.
--
-- A line is separated by the newline
-- set with 'GHC.Internal.System.IO.hSetNewlineMode' or 'nativeNewline' by default.
-- The read newline character(s) are not returned as part of the result.
--
-- If 'hGetLine' encounters end-of-file at any point while reading
-- in the middle of a line, it is treated as a line terminator and the (partial)
-- line is returned.
--
-- This operation may fail with:
--
--  * 'isEOFError' if the end of file is encountered when reading
--    the /first/ character of the line.
--
-- ==== __Examples__
--
-- >>> withFile "/home/user/foo" ReadMode hGetLine >>= putStrLn
-- this is the first line of the file :O
--
-- >>> withFile "/home/user/bar" ReadMode (replicateM 3 . hGetLine)
-- ["this is the first line","this is the second line","this is the third line"]
hGetLine :: Handle -> IO String
hGetLine :: Handle -> IO String
hGetLine Handle
h =
  String -> Handle -> (Handle__ -> IO String) -> IO String
forall a. String -> Handle -> (Handle__ -> IO a) -> IO a
wantReadableHandle_ String
"hGetLine" Handle
h ((Handle__ -> IO String) -> IO String)
-> (Handle__ -> IO String) -> IO String
forall a b. (a -> b) -> a -> b
$ \ Handle__
handle_ ->
    Handle__ -> IO String
hGetLineBuffered Handle__
handle_

hGetLineBuffered :: Handle__ -> IO String
hGetLineBuffered :: Handle__ -> IO String
hGetLineBuffered handle_ :: Handle__
handle_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} = do
  buf <- IORef (Buffer CharBufElem) -> IO (Buffer CharBufElem)
forall a. IORef a -> IO a
readIORef IORef (Buffer CharBufElem)
haCharBuffer
  hGetLineBufferedLoop handle_ buf []

hGetLineBufferedLoop :: Handle__
                     -> CharBuffer -> [String]
                     -> IO String
hGetLineBufferedLoop :: Handle__ -> Buffer CharBufElem -> [String] -> IO String
hGetLineBufferedLoop handle_ :: Handle__
handle_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..}
        buf :: Buffer CharBufElem
buf@Buffer{ bufL :: forall e. Buffer e -> Int
bufL=Int
r0, bufR :: forall e. Buffer e -> Int
bufR=Int
w, bufRaw :: forall e. Buffer e -> RawBuffer e
bufRaw=RawCharBuffer
raw0 } [String]
xss =
  let
        -- find the end-of-line character, if there is one
        loop :: RawCharBuffer -> Int -> IO (Bool, Int)
loop RawCharBuffer
raw Int
r
           | Int
r Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
w = (Bool, Int) -> IO (Bool, Int)
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return (Bool
False, Int
w)
           | Bool
otherwise =  do
                (c,r') <- RawCharBuffer -> Int -> IO (CharBufElem, Int)
readCharBuf RawCharBuffer
raw Int
r
                if c == '\n'
                   then return (True, r) -- NB. not r': don't include the '\n'
                   else loop raw r'
  in do
  (eol, off) <- RawCharBuffer -> Int -> IO (Bool, Int)
loop RawCharBuffer
raw0 Int
r0

  debugIO ("hGetLineBufferedLoop: r=" ++ show r0 ++ ", w=" ++ show w ++ ", off=" ++ show off)

  (xs,r') <- if haInputNL == CRLF
                then unpack_nl raw0 r0 off ""
                else do xs <- unpack raw0 r0 off ""
                        return (xs,off)

  -- if eol == True, then off is the offset of the '\n'
  -- otherwise off == w and the buffer is now empty.
  if eol -- r' == off
        then do writeIORef haCharBuffer (bufferAdjustL (off+1) buf)
                return (concat (reverse (xs:xss)))
        else do
             let buf1 = Int -> Buffer CharBufElem -> Buffer CharBufElem
forall e. Int -> Buffer e -> Buffer e
bufferAdjustL Int
r' Buffer CharBufElem
buf
             maybe_buf <- maybeFillReadBuffer handle_ buf1
             case maybe_buf of
                -- Nothing indicates we caught an EOF, and we may have a
                -- partial line to return.
                Maybe (Buffer CharBufElem)
Nothing -> do
                     -- we reached EOF.  There might be a lone \r left
                     -- in the buffer, so check for that and
                     -- append it to the line if necessary.
                     --
                     let pre :: String
pre = if Bool -> Bool
not (Buffer CharBufElem -> Bool
forall e. Buffer e -> Bool
isEmptyBuffer Buffer CharBufElem
buf1) then String
"\r" else String
""
                     IORef (Buffer CharBufElem) -> Buffer CharBufElem -> IO ()
forall a. IORef a -> a -> IO ()
writeIORef IORef (Buffer CharBufElem)
haCharBuffer Buffer CharBufElem
buf1{ bufL=0, bufR=0 }
                     let str :: String
str = [String] -> String
forall a. [[a]] -> [a]
concat ([String] -> [String]
forall a. [a] -> [a]
reverse (String
preString -> [String] -> [String]
forall a. a -> [a] -> [a]
:String
xsString -> [String] -> [String]
forall a. a -> [a] -> [a]
:[String]
xss))
                     if Bool -> Bool
not (String -> Bool
forall a. [a] -> Bool
null String
str)
                        then String -> IO String
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return String
str
                        else IO String
forall a. IO a
ioe_EOF
                Just Buffer CharBufElem
new_buf ->
                     Handle__ -> Buffer CharBufElem -> [String] -> IO String
hGetLineBufferedLoop Handle__
handle_ Buffer CharBufElem
new_buf (String
xsString -> [String] -> [String]
forall a. a -> [a] -> [a]
:[String]
xss)

maybeFillReadBuffer :: Handle__ -> CharBuffer -> IO (Maybe CharBuffer)
maybeFillReadBuffer :: Handle__ -> Buffer CharBufElem -> IO (Maybe (Buffer CharBufElem))
maybeFillReadBuffer Handle__
handle_ Buffer CharBufElem
buf
  = IO (Maybe (Buffer CharBufElem))
-> (IOError -> IO (Maybe (Buffer CharBufElem)))
-> IO (Maybe (Buffer CharBufElem))
forall e a. Exception e => IO a -> (e -> IO a) -> IO a
catchException
     (do buf' <- Handle__ -> Buffer CharBufElem -> IO (Buffer CharBufElem)
getSomeCharacters Handle__
handle_ Buffer CharBufElem
buf
         return (Just buf')
     )
     (\IOError
e -> do if IOError -> Bool
isEOFError IOError
e
                  then Maybe (Buffer CharBufElem) -> IO (Maybe (Buffer CharBufElem))
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Maybe (Buffer CharBufElem)
forall a. Maybe a
Nothing
                  else IOError -> IO (Maybe (Buffer CharBufElem))
forall a. IOError -> IO a
ioError IOError
e)

-- See GHC.Internal.IO.Buffer
#define CHARBUF_UTF32
-- #define CHARBUF_UTF16

-- NB. performance-critical code: eyeball the Core.
unpack :: RawCharBuffer -> Int -> Int -> [Char] -> IO [Char]
unpack :: RawCharBuffer -> Int -> Int -> String -> IO String
unpack !RawCharBuffer
buf !Int
r !Int
w String
acc0
 | Int
r Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
w    = String -> IO String
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return String
acc0
 | Bool
otherwise =
  RawCharBuffer -> (Ptr CharBufElem -> IO String) -> IO String
forall e a. RawBuffer e -> (Ptr e -> IO a) -> IO a
withRawBuffer RawCharBuffer
buf ((Ptr CharBufElem -> IO String) -> IO String)
-> (Ptr CharBufElem -> IO String) -> IO String
forall a b. (a -> b) -> a -> b
$ \Ptr CharBufElem
pbuf ->
    let
        unpackRB :: String -> Int -> IO String
unpackRB String
acc !Int
i
         | Int
i Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
< Int
r  = String -> IO String
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return String
acc
         | Bool
otherwise = do
              -- Here, we are rather careful to only put an *evaluated* character
              -- in the output string. Due to pointer tagging, this allows the consumer
              -- to avoid ping-ponging between the actual consumer code and the thunk code
#if defined(CHARBUF_UTF16)
              -- reverse-order decoding of UTF-16
              c2 <- peekElemOff pbuf i
              if (c2 < 0xdc00 || c2 > 0xdffff)
                 then unpackRB (unsafeChr (fromIntegral c2) : acc) (i-1)
                 else do c1 <- peekElemOff pbuf (i-1)
                         let c = (fromIntegral c1 - 0xd800) * 0x400 +
                                 (fromIntegral c2 - 0xdc00) + 0x10000
                         case desurrogatifyRoundtripCharacter (unsafeChr c) of
                           { C# c# -> unpackRB (C# c# : acc) (i-2) }
#else
              c <- Ptr CharBufElem -> Int -> IO CharBufElem
forall a. Storable a => Ptr a -> Int -> IO a
peekElemOff Ptr CharBufElem
pbuf Int
i
              unpackRB (c : acc) (i-1)
#endif
     in
     String -> Int -> IO String
unpackRB String
acc0 (Int
wInt -> Int -> Int
forall a. Num a => a -> a -> a
-Int
1)

-- NB. performance-critical code: eyeball the Core.
unpack_nl :: RawCharBuffer -> Int -> Int -> [Char] -> IO ([Char],Int)
unpack_nl :: RawCharBuffer -> Int -> Int -> String -> IO (String, Int)
unpack_nl !RawCharBuffer
buf !Int
r !Int
w String
acc0
 | Int
r Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
w    =  (String, Int) -> IO (String, Int)
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return (String
acc0, Int
0)
 | Bool
otherwise =
  RawCharBuffer
-> (Ptr CharBufElem -> IO (String, Int)) -> IO (String, Int)
forall e a. RawBuffer e -> (Ptr e -> IO a) -> IO a
withRawBuffer RawCharBuffer
buf ((Ptr CharBufElem -> IO (String, Int)) -> IO (String, Int))
-> (Ptr CharBufElem -> IO (String, Int)) -> IO (String, Int)
forall a b. (a -> b) -> a -> b
$ \Ptr CharBufElem
pbuf ->
    let
        unpackRB :: String -> Int -> IO String
unpackRB String
acc !Int
i
         | Int
i Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
< Int
r  = String -> IO String
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return String
acc
         | Bool
otherwise = do
              c <- Ptr CharBufElem -> Int -> IO CharBufElem
forall a. Storable a => Ptr a -> Int -> IO a
peekElemOff Ptr CharBufElem
pbuf Int
i
              if (c == '\n' && i > r)
                 then do
                   c1 <- peekElemOff pbuf (i-1)
                   if (c1 == '\r')
                      then unpackRB ('\n':acc) (i-2)
                      else unpackRB ('\n':acc) (i-1)
                 else
                   unpackRB (c : acc) (i-1)
     in do
     c <- Ptr CharBufElem -> Int -> IO CharBufElem
forall a. Storable a => Ptr a -> Int -> IO a
peekElemOff Ptr CharBufElem
pbuf (Int
wInt -> Int -> Int
forall a. Num a => a -> a -> a
-Int
1)
     if (c == '\r')
        then do
                -- If the last char is a '\r', we need to know whether or
                -- not it is followed by a '\n', so leave it in the buffer
                -- for now and just unpack the rest.
                str <- unpackRB acc0 (w-2)
                return (str, w-1)
        else do
                str <- unpackRB acc0 (w-1)
                return (str, w)

-- Note [#5536]
-- ~~~~~~~~~~~~
-- We originally had
--
--    let c' = desurrogatifyRoundtripCharacter c in
--    c' `seq` unpackRB (c':acc) (i-1)
--
-- but this resulted in Core like
--
--    case (case x <# y of True -> C# e1; False -> C# e2) of c
--      C# _ -> unpackRB (c:acc) (i-1)
--
-- which compiles into a continuation for the outer case, with each
-- branch of the inner case building a C# and then jumping to the
-- continuation.  We'd rather not have this extra jump, which makes
-- quite a difference to performance (see #5536) It turns out that
-- matching on the C# directly causes GHC to do the case-of-case,
-- giving much straighter code.

-- -----------------------------------------------------------------------------
-- hGetContents

-- hGetContents on a DuplexHandle only affects the read side: you can
-- carry on writing to it afterwards.

-- | Computation 'hGetContents' @hdl@ returns the list of characters
-- corresponding to the unread portion of the channel or file managed
-- by @hdl@, which is put into an intermediate state, /semi-closed/.
-- In this state, @hdl@ is effectively closed,
-- but items are read from @hdl@ on demand and accumulated in a special
-- list returned by 'hGetContents' @hdl@.
--
-- Any operation that fails because a handle is closed,
-- also fails if a handle is semi-closed.  The only exception is
-- 'GHC.Internal.System.IO.hClose'.  A semi-closed handle becomes closed:
--
--  * if 'GHC.Internal.System.IO.hClose' is applied to it;
--
--  * if an I\/O error occurs when reading an item from the handle;
--
--  * or once the entire contents of the handle has been read.
--
-- Once a semi-closed handle becomes closed, the contents of the
-- associated list becomes fixed.  The contents of this final list is
-- only partially specified: it will contain at least all the items of
-- the stream that were evaluated prior to the handle becoming closed.
--
-- Any I\/O errors encountered while a handle is semi-closed are simply
-- discarded.
--
-- This operation may fail with:
--
--  * 'isEOFError' if the end of file has been reached.

hGetContents :: Handle -> IO String
hGetContents :: Handle -> IO String
hGetContents Handle
handle =
   String
-> Handle -> (Handle__ -> IO (Handle__, String)) -> IO String
forall a.
String -> Handle -> (Handle__ -> IO (Handle__, a)) -> IO a
wantReadableHandle String
"hGetContents" Handle
handle ((Handle__ -> IO (Handle__, String)) -> IO String)
-> (Handle__ -> IO (Handle__, String)) -> IO String
forall a b. (a -> b) -> a -> b
$ \Handle__
handle_ -> do
      xs <- Handle -> IO String
lazyRead Handle
handle
      return (handle_{ haType=SemiClosedHandle}, xs )

-- Note that someone may close the semi-closed handle (or change its
-- buffering), so each time these lazy read functions are pulled on,
-- they have to check whether the handle has indeed been closed.

lazyRead :: Handle -> IO String
lazyRead :: Handle -> IO String
lazyRead Handle
handle =
   IO String -> IO String
forall a. IO a -> IO a
unsafeInterleaveIO (IO String -> IO String) -> IO String -> IO String
forall a b. (a -> b) -> a -> b
$
        String
-> Handle -> (Handle__ -> IO (Handle__, String)) -> IO String
forall a.
String -> Handle -> (Handle__ -> IO (Handle__, a)) -> IO a
withHandle String
"hGetContents" Handle
handle ((Handle__ -> IO (Handle__, String)) -> IO String)
-> (Handle__ -> IO (Handle__, String)) -> IO String
forall a b. (a -> b) -> a -> b
$ \ Handle__
handle_ -> do
        case Handle__ -> HandleType
haType Handle__
handle_ of
          HandleType
SemiClosedHandle -> Handle -> Handle__ -> IO (Handle__, String)
lazyReadBuffered Handle
handle Handle__
handle_
          HandleType
ClosedHandle
            -> IOError -> IO (Handle__, String)
forall a. (?callStack::CallStack) => IOError -> IO a
ioException
                  (Maybe Handle
-> IOErrorType
-> String
-> String
-> Maybe CInt
-> Maybe String
-> IOError
IOError (Handle -> Maybe Handle
forall a. a -> Maybe a
Just Handle
handle) IOErrorType
IllegalOperation String
"hGetContents"
                        String
"delayed read on closed handle" Maybe CInt
forall a. Maybe a
Nothing Maybe String
forall a. Maybe a
Nothing)
          HandleType
_ -> IOError -> IO (Handle__, String)
forall a. (?callStack::CallStack) => IOError -> IO a
ioException
                  (Maybe Handle
-> IOErrorType
-> String
-> String
-> Maybe CInt
-> Maybe String
-> IOError
IOError (Handle -> Maybe Handle
forall a. a -> Maybe a
Just Handle
handle) IOErrorType
IllegalOperation String
"hGetContents"
                        String
"illegal handle type" Maybe CInt
forall a. Maybe a
Nothing Maybe String
forall a. Maybe a
Nothing)

lazyReadBuffered :: Handle -> Handle__ -> IO (Handle__, [Char])
lazyReadBuffered :: Handle -> Handle__ -> IO (Handle__, String)
lazyReadBuffered Handle
h handle_ :: Handle__
handle_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} = do
   buf <- IORef (Buffer CharBufElem) -> IO (Buffer CharBufElem)
forall a. IORef a -> IO a
readIORef IORef (Buffer CharBufElem)
haCharBuffer
   Exception.catch
        (do
            buf'@Buffer{..} <- getSomeCharacters handle_ buf
            lazy_rest <- lazyRead h
            (s,r) <- if haInputNL == CRLF
                         then unpack_nl bufRaw bufL bufR lazy_rest
                         else do s <- unpack bufRaw bufL bufR lazy_rest
                                 return (s,bufR)
            writeIORef haCharBuffer (bufferAdjustL r buf')
            return (handle_, s)
        )
        (\IOError
e -> do (handle_', _) <- Handle__ -> IO (Handle__, Maybe SomeException)
hClose_help Handle__
handle_
                  debugIO ("hGetContents caught: " ++ show e)
                  -- We might have a \r cached in CRLF mode.  So we
                  -- need to check for that and return it:
                  let r = if IOError -> Bool
isEOFError IOError
e
                             then if Bool -> Bool
not (Buffer CharBufElem -> Bool
forall e. Buffer e -> Bool
isEmptyBuffer Buffer CharBufElem
buf)
                                     then String
"\r"
                                     else String
""
                             else
                                  IOError -> String
forall a e. (?callStack::CallStack, Exception e) => e -> a
throw (IOError -> String -> Handle -> IOError
augmentIOError IOError
e String
"hGetContents" Handle
h)

                  return (handle_', r)
        )

-- ensure we have some characters in the buffer
getSomeCharacters :: Handle__ -> CharBuffer -> IO CharBuffer
getSomeCharacters :: Handle__ -> Buffer CharBufElem -> IO (Buffer CharBufElem)
getSomeCharacters handle_ :: Handle__
handle_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} buf :: Buffer CharBufElem
buf@Buffer{Int
Word64
RawCharBuffer
BufferState
bufRaw :: forall e. Buffer e -> RawBuffer e
bufL :: forall e. Buffer e -> Int
bufR :: forall e. Buffer e -> Int
bufOffset :: forall e. Buffer e -> Word64
bufSize :: forall e. Buffer e -> Int
bufState :: forall e. Buffer e -> BufferState
bufRaw :: RawCharBuffer
bufState :: BufferState
bufSize :: Int
bufOffset :: Word64
bufL :: Int
bufR :: Int
..} =
  case Buffer CharBufElem -> Int
forall e. Buffer e -> Int
bufferElems Buffer CharBufElem
buf of

    -- buffer empty: read some more
    Int
0 -> Handle__ -> Buffer CharBufElem -> IO (Buffer CharBufElem)
readTextDevice Handle__
handle_ Buffer CharBufElem
buf

    -- if the buffer has a single '\r' in it and we're doing newline
    -- translation: read some more
    Int
1 | Newline
haInputNL Newline -> Newline -> Bool
forall a. Eq a => a -> a -> Bool
== Newline
CRLF -> do
      (c,_) <- RawCharBuffer -> Int -> IO (CharBufElem, Int)
readCharBuf RawCharBuffer
bufRaw Int
bufL
      if c == '\r'
      then do
        -- shuffle the '\r' to the beginning.  This is only safe
        -- if we're about to call readTextDevice, otherwise it
        -- would mess up flushCharBuffer.
        -- See [note Buffer Flushing], GHC.Internal.IO.Handle.Types
        _ <- writeCharBuf bufRaw 0 '\r'
        let buf' = Buffer CharBufElem
buf{ bufL=0, bufR=1 }
        readTextDevice handle_ buf'
      else
        return buf

    -- buffer has some chars in it already: just return it
    Int
_otherwise ->
      Buffer CharBufElem -> IO (Buffer CharBufElem)
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Buffer CharBufElem
buf

-- -----------------------------------------------------------------------------
-- hGetContents'

-- We read everything into a list of CharBuffer chunks, and convert it lazily
-- to a string, which minimizes memory usage.
-- In the worst case, space usage is at most that of the complete String,
-- as the chunks can be garbage collected progressively.
-- For streaming consumers, space usage is at most that of the list of chunks.

-- | The 'hGetContents'' operation reads all input on the given handle
-- before returning it as a 'String' and closing the handle.
--
-- @since base-4.15.0.0

hGetContents' :: Handle -> IO String
hGetContents' :: Handle -> IO String
hGetContents' Handle
handle = do
    es <- String
-> Handle
-> (Handle__ -> IO (Handle__, Either SomeException String))
-> IO (Either SomeException String)
forall a.
String -> Handle -> (Handle__ -> IO (Handle__, a)) -> IO a
wantReadableHandle String
"hGetContents'" Handle
handle (Handle -> Handle__ -> IO (Handle__, Either SomeException String)
strictRead Handle
handle)
    case es of
      Right String
s -> String -> IO String
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return String
s
      Left SomeException
e ->
          case SomeException -> Maybe IOError
forall e. Exception e => SomeException -> Maybe e
fromException SomeException
e of
            Just IOError
ioe -> IOError -> IO String
forall e a. (?callStack::CallStack, Exception e) => e -> IO a
throwIO (IOError -> String -> Handle -> IOError
augmentIOError IOError
ioe String
"hGetContents'" Handle
handle)
            Maybe IOError
Nothing -> SomeException -> IO String
forall e a. (?callStack::CallStack, Exception e) => e -> IO a
throwIO SomeException
e

strictRead :: Handle -> Handle__ -> IO (Handle__, Either SomeException String)
strictRead :: Handle -> Handle__ -> IO (Handle__, Either SomeException String)
strictRead Handle
h handle_ :: Handle__
handle_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} = do
    cbuf <- IORef (Buffer CharBufElem) -> IO (Buffer CharBufElem)
forall a. IORef a -> IO a
readIORef IORef (Buffer CharBufElem)
haCharBuffer
    cbufs <- strictReadLoop' handle_ [] cbuf
    (handle_', me) <- hClose_help handle_
    case me of
      Just SomeException
e -> (Handle__, Either SomeException String)
-> IO (Handle__, Either SomeException String)
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return (Handle__
handle_', SomeException -> Either SomeException String
forall a b. a -> Either a b
Left SomeException
e)
      Maybe SomeException
Nothing -> do
        s <- Newline -> [Buffer CharBufElem] -> String -> IO String
lazyBuffersToString Newline
haInputNL [Buffer CharBufElem]
cbufs String
""
        return (handle_', Right s)

strictReadLoop :: Handle__ -> [CharBuffer] -> CharBuffer -> IO [CharBuffer]
strictReadLoop :: Handle__
-> [Buffer CharBufElem]
-> Buffer CharBufElem
-> IO [Buffer CharBufElem]
strictReadLoop Handle__
handle_ [Buffer CharBufElem]
cbufs Buffer CharBufElem
cbuf0 = do
    mcbuf <- IO (Maybe (Buffer CharBufElem))
-> (IOError -> IO (Maybe (Buffer CharBufElem)))
-> IO (Maybe (Buffer CharBufElem))
forall e a. Exception e => IO a -> (e -> IO a) -> IO a
Exception.catch
        (do r <- Handle__ -> Buffer CharBufElem -> IO (Buffer CharBufElem)
readTextDevice Handle__
handle_ Buffer CharBufElem
cbuf0
            return (Just r))
        (\IOError
e -> if IOError -> Bool
isEOFError IOError
e
                  then Maybe (Buffer CharBufElem) -> IO (Maybe (Buffer CharBufElem))
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Maybe (Buffer CharBufElem)
forall a. Maybe a
Nothing
                  else IOError -> IO (Maybe (Buffer CharBufElem))
forall a e. (?callStack::CallStack, Exception e) => e -> a
throw IOError
e)
    case mcbuf of
      Maybe (Buffer CharBufElem)
Nothing -> [Buffer CharBufElem] -> IO [Buffer CharBufElem]
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return (Buffer CharBufElem
cbuf0 Buffer CharBufElem -> [Buffer CharBufElem] -> [Buffer CharBufElem]
forall a. a -> [a] -> [a]
: [Buffer CharBufElem]
cbufs)
      Just Buffer CharBufElem
cbuf1 -> Handle__
-> [Buffer CharBufElem]
-> Buffer CharBufElem
-> IO [Buffer CharBufElem]
strictReadLoop' Handle__
handle_ [Buffer CharBufElem]
cbufs Buffer CharBufElem
cbuf1

-- If 'cbuf' is full, allocate a new buffer.
strictReadLoop' :: Handle__ -> [CharBuffer] -> CharBuffer -> IO [CharBuffer]
strictReadLoop' :: Handle__
-> [Buffer CharBufElem]
-> Buffer CharBufElem
-> IO [Buffer CharBufElem]
strictReadLoop' Handle__
handle_ [Buffer CharBufElem]
cbufs Buffer CharBufElem
cbuf
    | Buffer CharBufElem -> Bool
forall e. Buffer e -> Bool
isFullCharBuffer Buffer CharBufElem
cbuf = do
        cbuf' <- Int -> BufferState -> IO (Buffer CharBufElem)
newCharBuffer Int
dEFAULT_CHAR_BUFFER_SIZE BufferState
ReadBuffer
        strictReadLoop handle_ (cbuf : cbufs) cbuf'
    | Bool
otherwise = Handle__
-> [Buffer CharBufElem]
-> Buffer CharBufElem
-> IO [Buffer CharBufElem]
strictReadLoop Handle__
handle_ [Buffer CharBufElem]
cbufs Buffer CharBufElem
cbuf

-- Lazily convert a list of buffers to a String. The buffers are
-- in reverse order: the first buffer is the end of the String.
lazyBuffersToString :: Newline -> [CharBuffer] -> String -> IO String
lazyBuffersToString :: Newline -> [Buffer CharBufElem] -> String -> IO String
lazyBuffersToString Newline
LF = [Buffer CharBufElem] -> String -> IO String
loop where
    loop :: [Buffer CharBufElem] -> String -> IO String
loop [] String
s = String -> IO String
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return String
s
    loop (Buffer{Int
Word64
RawCharBuffer
BufferState
bufRaw :: forall e. Buffer e -> RawBuffer e
bufL :: forall e. Buffer e -> Int
bufR :: forall e. Buffer e -> Int
bufOffset :: forall e. Buffer e -> Word64
bufSize :: forall e. Buffer e -> Int
bufState :: forall e. Buffer e -> BufferState
bufRaw :: RawCharBuffer
bufState :: BufferState
bufSize :: Int
bufOffset :: Word64
bufL :: Int
bufR :: Int
..} : [Buffer CharBufElem]
cbufs) String
s = do
        s' <- IO String -> IO String
forall a. IO a -> IO a
unsafeInterleaveIO (RawCharBuffer -> Int -> Int -> String -> IO String
unpack RawCharBuffer
bufRaw Int
bufL Int
bufR String
s)
        loop cbufs s'
lazyBuffersToString Newline
CRLF = CharBufElem -> [Buffer CharBufElem] -> String -> IO String
loop CharBufElem
'\0' where
    loop :: CharBufElem -> [Buffer CharBufElem] -> String -> IO String
loop CharBufElem
before [] String
s = String -> IO String
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return String
s
    loop CharBufElem
before (Buffer{Int
Word64
RawCharBuffer
BufferState
bufRaw :: forall e. Buffer e -> RawBuffer e
bufL :: forall e. Buffer e -> Int
bufR :: forall e. Buffer e -> Int
bufOffset :: forall e. Buffer e -> Word64
bufSize :: forall e. Buffer e -> Int
bufState :: forall e. Buffer e -> BufferState
bufRaw :: RawCharBuffer
bufState :: BufferState
bufSize :: Int
bufOffset :: Word64
bufL :: Int
bufR :: Int
..} : [Buffer CharBufElem]
cbufs) String
s
        | Int
bufL Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
bufR = CharBufElem -> [Buffer CharBufElem] -> String -> IO String
loop CharBufElem
before [Buffer CharBufElem]
cbufs String
s  -- skip empty buffers
        | Bool
otherwise = do
            -- When a CRLF is broken across two buffers, we already have a newline
            -- from decoding the LF, so we ignore the CR in the current buffer.
            s1 <- if CharBufElem
before CharBufElem -> CharBufElem -> Bool
forall a. Eq a => a -> a -> Bool
== CharBufElem
'\n'
                     then String -> IO String
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return String
s
                     else do
                       -- We restore trailing CR not followed by LF.
                       c <- RawCharBuffer -> Int -> IO CharBufElem
peekCharBuf RawCharBuffer
bufRaw (Int
bufR Int -> Int -> Int
forall a. Num a => a -> a -> a
- Int
1)
                       if c == '\r'
                          then return ('\r' : s)
                          else return s
            s2 <- unsafeInterleaveIO (do
                (s2, _) <- unpack_nl bufRaw bufL bufR s1
                return s2)
            c0 <- peekCharBuf bufRaw bufL
            loop c0 cbufs s2

-- ---------------------------------------------------------------------------
-- hPutChar

-- | Computation 'hPutChar' @hdl ch@ writes the character @ch@ to the
-- file or channel managed by @hdl@.  Characters may be buffered if
-- buffering is enabled for @hdl@.
--
-- This operation may fail with:
--
--  * 'isFullError' if the device is full; or
--
--  * 'isPermissionError' if another system resource limit would be exceeded.

hPutChar :: Handle -> Char -> IO ()
hPutChar :: Handle -> CharBufElem -> IO ()
hPutChar Handle
handle !CharBufElem
c =
    String -> Handle -> (Handle__ -> IO ()) -> IO ()
forall a. String -> Handle -> (Handle__ -> IO a) -> IO a
wantWritableHandle String
"hPutChar" Handle
handle ((Handle__ -> IO ()) -> IO ()) -> (Handle__ -> IO ()) -> IO ()
forall a b. (a -> b) -> a -> b
$ \ Handle__
handle_  ->
      Handle__ -> CharBufElem -> IO ()
hPutcBuffered Handle__
handle_ CharBufElem
c

hPutcBuffered :: Handle__ -> Char -> IO ()
hPutcBuffered :: Handle__ -> CharBufElem -> IO ()
hPutcBuffered handle_ :: Handle__
handle_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} CharBufElem
c = do
  buf <- IORef (Buffer CharBufElem) -> IO (Buffer CharBufElem)
forall a. IORef a -> IO a
readIORef IORef (Buffer CharBufElem)
haCharBuffer
  if c == '\n'
     then do buf1 <- if haOutputNL == CRLF
                     then do
                       buf1 <- putc buf '\r'
                       putc buf1 '\n'
                     else
                       putc buf '\n'
             writeCharBuffer handle_ buf1
             when isLine $ flushByteWriteBuffer handle_
      else do
          buf1 <- putc buf c
          writeCharBuffer handle_ buf1
          return ()
  where
    isLine :: Bool
isLine = case BufferMode
haBufferMode of
                BufferMode
LineBuffering -> Bool
True
                BufferMode
_             -> Bool
False

    putc :: Buffer CharBufElem -> CharBufElem -> IO (Buffer CharBufElem)
putc buf :: Buffer CharBufElem
buf@Buffer{ bufRaw :: forall e. Buffer e -> RawBuffer e
bufRaw=RawCharBuffer
raw, bufR :: forall e. Buffer e -> Int
bufR=Int
w } CharBufElem
c' = do
       String -> IO ()
debugIO (String
"putc: " String -> String -> String
forall a. [a] -> [a] -> [a]
++ Buffer CharBufElem -> String
forall a. Buffer a -> String
summaryBuffer Buffer CharBufElem
buf)
       w'  <- RawCharBuffer -> Int -> CharBufElem -> IO Int
writeCharBuf RawCharBuffer
raw Int
w CharBufElem
c'
       return buf{ bufR = w' }

-- ---------------------------------------------------------------------------
-- hPutStr

-- We go to some trouble to avoid keeping the handle locked while we're
-- evaluating the string argument to hPutStr, in case doing so triggers another
-- I/O operation on the same handle which would lead to deadlock.  The classic
-- case is
--
--              putStr (trace "hello" "world")
--
-- so the basic scheme is this:
--
--      * copy the string into a fresh buffer,
--      * "commit" the buffer to the handle.
--
-- Committing may involve simply copying the contents of the new
-- buffer into the handle's buffer, flushing one or both buffers, or
-- maybe just swapping the buffers over (if the handle's buffer was
-- empty).  See commitBuffer below.

-- | Computation 'hPutStr' @hdl s@ writes the string
-- @s@ to the file or channel managed by @hdl@.
--
-- This operation may fail with:
--
--  * 'isFullError' if the device is full; or
--
--  * 'isPermissionError' if another system resource limit would be exceeded.

hPutStr :: Handle -> String -> IO ()
hPutStr :: Handle -> String -> IO ()
hPutStr Handle
handle String
str = Handle -> String -> Bool -> IO ()
hPutStr' Handle
handle String
str Bool
False

-- | The same as 'hPutStr', but adds a newline character.
hPutStrLn :: Handle -> String -> IO ()
hPutStrLn :: Handle -> String -> IO ()
hPutStrLn Handle
handle String
str = Handle -> String -> Bool -> IO ()
hPutStr' Handle
handle String
str Bool
True

{-# NOINLINE hPutStr' #-}
hPutStr' :: Handle -> String -> Bool -> IO ()
hPutStr' :: Handle -> String -> Bool -> IO ()
hPutStr' Handle
handle String
str Bool
add_nl =
  -- An optimisation: hPutStr' takes an additional "add_nl" boolean parameter to
  -- implement hPutStrLn efficiently. When LineBuffering or BlockBuffering modes
  -- are enabled, it performs the encoding of the string and of the new-line
  -- character(s) in the same loop, directly flushing buffers appropriately at
  -- the end if LineBuffering mode is used.
  do
    (buffer_mode, nl) <-
         String
-> Handle
-> (Handle__ -> IO ((BufferMode, Buffer CharBufElem), Newline))
-> IO ((BufferMode, Buffer CharBufElem), Newline)
forall a. String -> Handle -> (Handle__ -> IO a) -> IO a
wantWritableHandle String
"hPutStr" Handle
handle ((Handle__ -> IO ((BufferMode, Buffer CharBufElem), Newline))
 -> IO ((BufferMode, Buffer CharBufElem), Newline))
-> (Handle__ -> IO ((BufferMode, Buffer CharBufElem), Newline))
-> IO ((BufferMode, Buffer CharBufElem), Newline)
forall a b. (a -> b) -> a -> b
$ \Handle__
h_ -> do
                       bmode <- Handle__ -> IO (BufferMode, Buffer CharBufElem)
getSpareBuffer Handle__
h_
                       return (bmode, haOutputNL h_)

    case buffer_mode of
       (BufferMode
NoBuffering, Buffer CharBufElem
_) -> do
            Handle -> String -> IO ()
hPutChars Handle
handle String
str        -- v. slow, but we don't care
            Bool -> IO () -> IO ()
forall (f :: * -> *). Applicative f => Bool -> f () -> f ()
when Bool
add_nl (IO () -> IO ()) -> IO () -> IO ()
forall a b. (a -> b) -> a -> b
$ Handle -> CharBufElem -> IO ()
hPutChar Handle
handle CharBufElem
'\n'
       (BufferMode
LineBuffering, Buffer CharBufElem
buf) ->
            Handle
-> Bool -> Bool -> Newline -> Buffer CharBufElem -> String -> IO ()
writeBlocks Handle
handle Bool
True  Bool
add_nl Newline
nl Buffer CharBufElem
buf String
str
       (BlockBuffering Maybe Int
_, Buffer CharBufElem
buf) ->
            Handle
-> Bool -> Bool -> Newline -> Buffer CharBufElem -> String -> IO ()
writeBlocks Handle
handle Bool
False Bool
add_nl Newline
nl Buffer CharBufElem
buf String
str

hPutChars :: Handle -> [Char] -> IO ()
hPutChars :: Handle -> String -> IO ()
hPutChars Handle
_      [] = () -> IO ()
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return ()
hPutChars Handle
handle (CharBufElem
c:String
cs) = Handle -> CharBufElem -> IO ()
hPutChar Handle
handle CharBufElem
c IO () -> IO () -> IO ()
forall a b. IO a -> IO b -> IO b
forall (m :: * -> *) a b. Monad m => m a -> m b -> m b
>> Handle -> String -> IO ()
hPutChars Handle
handle String
cs

-- Buffer offset is always zero.
getSpareBuffer :: Handle__ -> IO (BufferMode, CharBuffer)
getSpareBuffer :: Handle__ -> IO (BufferMode, Buffer CharBufElem)
getSpareBuffer Handle__{haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haCharBuffer=IORef (Buffer CharBufElem)
ref, haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haBuffers=IORef (BufferList CharBufElem)
spare_ref, haBufferMode :: Handle__ -> BufferMode
haBufferMode=BufferMode
mode} =
   case BufferMode
mode of
     BufferMode
NoBuffering -> (BufferMode, Buffer CharBufElem)
-> IO (BufferMode, Buffer CharBufElem)
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return (BufferMode
mode, String -> Buffer CharBufElem
forall a. String -> a
errorWithoutStackTrace String
"no buffer!")
     BufferMode
_ -> do
          bufs <- IORef (BufferList CharBufElem) -> IO (BufferList CharBufElem)
forall a. IORef a -> IO a
readIORef IORef (BufferList CharBufElem)
spare_ref
          buf  <- readIORef ref
          case bufs of
            BufferListCons RawCharBuffer
b BufferList CharBufElem
rest -> do
                IORef (BufferList CharBufElem) -> BufferList CharBufElem -> IO ()
forall a. IORef a -> a -> IO ()
writeIORef IORef (BufferList CharBufElem)
spare_ref BufferList CharBufElem
rest
                (BufferMode, Buffer CharBufElem)
-> IO (BufferMode, Buffer CharBufElem)
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return ( BufferMode
mode, RawCharBuffer -> Int -> BufferState -> Buffer CharBufElem
forall e. RawBuffer e -> Int -> BufferState -> Buffer e
emptyBuffer RawCharBuffer
b (Buffer CharBufElem -> Int
forall e. Buffer e -> Int
bufSize Buffer CharBufElem
buf) BufferState
WriteBuffer)
            BufferList CharBufElem
BufferListNil -> do
                new_buf <- Int -> BufferState -> IO (Buffer CharBufElem)
newCharBuffer (Buffer CharBufElem -> Int
forall e. Buffer e -> Int
bufSize Buffer CharBufElem
buf) BufferState
WriteBuffer
                return (mode, new_buf)


-- NB. performance-critical code: eyeball the Core.
writeBlocks :: Handle -> Bool -> Bool -> Newline -> Buffer CharBufElem -> String -> IO ()
writeBlocks :: Handle
-> Bool -> Bool -> Newline -> Buffer CharBufElem -> String -> IO ()
writeBlocks Handle
hdl Bool
line_buffered Bool
add_nl Newline
nl
            buf :: Buffer CharBufElem
buf@Buffer{ bufRaw :: forall e. Buffer e -> RawBuffer e
bufRaw=RawCharBuffer
raw, bufSize :: forall e. Buffer e -> Int
bufSize=Int
len } String
s = Int -> String -> IO ()
shoveString Int
0 String
s
  where
   {-# INLINE new_line #-} -- we don't want to allocate a closure for it
   new_line :: Int -> IO Int
new_line !Int
n = do
     n1 <- case Newline
nl of
            Newline
CRLF -> RawCharBuffer -> Int -> CharBufElem -> IO Int
writeCharBuf RawCharBuffer
raw Int
n CharBufElem
'\r'
            Newline
_    -> Int -> IO Int
forall a. a -> IO a
forall (f :: * -> *) a. Applicative f => a -> f a
pure Int
n
     n2 <- writeCharBuf raw n1 '\n'
     if line_buffered
        then do
          -- end of line, so write and flush
          commitBuffer hdl raw len n2 True{-flush-} False
          pure 0
        else
          pure n2

   shoveString :: Int -> String -> IO ()
shoveString !Int
n = \case
    [] -> if Bool
add_nl
            then do
              n' <- Int -> IO Int
new_line Int
n
              commitBuffer hdl raw len n' False{-no flush-} True{-release-}
            else
              Handle -> RawCharBuffer -> Int -> Int -> Bool -> Bool -> IO ()
commitBuffer Handle
hdl RawCharBuffer
raw Int
len Int
n Bool
False{-no flush-} Bool
True{-release-}

    -- n+1 so we have enough room to write '\r\n' if necessary
    String
cs | Int
n Int -> Int -> Int
forall a. Num a => a -> a -> a
+ Int
1 Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
>= Int
len -> do
        Handle -> RawCharBuffer -> Int -> Int -> Bool -> Bool -> IO ()
commitBuffer Handle
hdl RawCharBuffer
raw Int
len Int
n Bool
False{-flush-} Bool
False
        Int -> String -> IO ()
shoveString Int
0 String
cs

    (CharBufElem
'\n':String
cs) -> do
        n' <- Int -> IO Int
new_line Int
n
        shoveString n' cs

    (CharBufElem
c:String
cs) -> do
        n' <- RawCharBuffer -> Int -> CharBufElem -> IO Int
writeCharBuf RawCharBuffer
raw Int
n CharBufElem
c
        shoveString n' cs

-- -----------------------------------------------------------------------------
-- commitBuffer handle buf sz count flush release
--
-- Write the contents of the buffer 'buf' ('sz' bytes long, containing
-- 'count' bytes of data) to handle (handle must be block or line buffered).
commitBuffer :: Handle                       -- handle to commit to
             -> RawCharBuffer -> Int         -- address and size (in bytes) of buffer
             -> Int                          -- number of bytes of data in buffer
             -> Bool                         -- True <=> flush the handle afterward
             -> Bool                         -- release the buffer?
             -> IO ()
commitBuffer :: Handle -> RawCharBuffer -> Int -> Int -> Bool -> Bool -> IO ()
commitBuffer Handle
hdl !RawCharBuffer
raw !Int
sz !Int
count Bool
flush Bool
release =
  String -> Handle -> (Handle__ -> IO ()) -> IO ()
forall a. String -> Handle -> (Handle__ -> IO a) -> IO a
wantWritableHandle String
"commitBuffer" Handle
hdl ((Handle__ -> IO ()) -> IO ()) -> (Handle__ -> IO ()) -> IO ()
forall a b. (a -> b) -> a -> b
$ \h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} -> do
    let debugMsg :: String
debugMsg = (String
"commitBuffer: sz=" String -> String -> String
forall a. [a] -> [a] -> [a]
++ Int -> String
forall a. Show a => a -> String
show Int
sz String -> String -> String
forall a. [a] -> [a] -> [a]
++ String
", count=" String -> String -> String
forall a. [a] -> [a] -> [a]
++ Int -> String
forall a. Show a => a -> String
show Int
count
                    String -> String -> String
forall a. [a] -> [a] -> [a]
++ String
", flush=" String -> String -> String
forall a. [a] -> [a] -> [a]
++ Bool -> String
forall a. Show a => a -> String
show Bool
flush String -> String -> String
forall a. [a] -> [a] -> [a]
++ String
", release=" String -> String -> String
forall a. [a] -> [a] -> [a]
++ Bool -> String
forall a. Show a => a -> String
show Bool
release
                    String -> String -> String
forall a. [a] -> [a] -> [a]
++ String
", handle=" String -> String -> String
forall a. [a] -> [a] -> [a]
++ Handle -> String
forall a. Show a => a -> String
show Handle
hdl)
    String -> IO ()
debugIO String
debugMsg
      -- Offset taken from handle
    Handle__ -> Buffer CharBufElem -> IO ()
writeCharBuffer Handle__
h_ Buffer{ bufRaw :: RawCharBuffer
bufRaw=RawCharBuffer
raw, bufState :: BufferState
bufState=BufferState
WriteBuffer, bufOffset :: Word64
bufOffset=Word64
0,
                               bufL :: Int
bufL=Int
0, bufR :: Int
bufR=Int
count, bufSize :: Int
bufSize=Int
sz }
    Bool -> IO () -> IO ()
forall (f :: * -> *). Applicative f => Bool -> f () -> f ()
when Bool
flush (IO () -> IO ()) -> IO () -> IO ()
forall a b. (a -> b) -> a -> b
$ Handle__ -> IO ()
flushByteWriteBuffer Handle__
h_
    -- release the buffer if necessary
    Bool -> IO () -> IO ()
forall (f :: * -> *). Applicative f => Bool -> f () -> f ()
when Bool
release (IO () -> IO ()) -> IO () -> IO ()
forall a b. (a -> b) -> a -> b
$ do
      -- find size of current buffer
      old_buf@Buffer{ bufSize=size } <- IORef (Buffer CharBufElem) -> IO (Buffer CharBufElem)
forall a. IORef a -> IO a
readIORef IORef (Buffer CharBufElem)
haCharBuffer
      when (sz == size) $ do
        spare_bufs <- readIORef haBuffers
        writeIORef haBuffers (BufferListCons raw spare_bufs)
    -- bb <- readIORef haByteBuffer
    -- debugIO ("commitBuffer: buffer=" ++ summaryBuffer bb ++ ", handle=" ++ show hdl)

-- backwards compatibility; the text package uses this
commitBuffer' :: RawCharBuffer -> Int -> Int -> Bool -> Bool -> Handle__
              -> IO CharBuffer
commitBuffer' :: RawCharBuffer
-> Int
-> Int
-> Bool
-> Bool
-> Handle__
-> IO (Buffer CharBufElem)
commitBuffer' RawCharBuffer
raw sz :: Int
sz@(I# Int#
_) count :: Int
count@(I# Int#
_) Bool
flush Bool
release h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..}
   = do
      String -> IO ()
debugIO (String
"commitBuffer: sz=" String -> String -> String
forall a. [a] -> [a] -> [a]
++ Int -> String
forall a. Show a => a -> String
show Int
sz String -> String -> String
forall a. [a] -> [a] -> [a]
++ String
", count=" String -> String -> String
forall a. [a] -> [a] -> [a]
++ Int -> String
forall a. Show a => a -> String
show Int
count
            String -> String -> String
forall a. [a] -> [a] -> [a]
++ String
", flush=" String -> String -> String
forall a. [a] -> [a] -> [a]
++ Bool -> String
forall a. Show a => a -> String
show Bool
flush String -> String -> String
forall a. [a] -> [a] -> [a]
++ String
", release=" String -> String -> String
forall a. [a] -> [a] -> [a]
++ Bool -> String
forall a. Show a => a -> String
show Bool
release)

      let this_buf :: Buffer CharBufElem
this_buf = Buffer{ bufRaw :: RawCharBuffer
bufRaw=RawCharBuffer
raw, bufState :: BufferState
bufState=BufferState
WriteBuffer,
                             bufL :: Int
bufL=Int
0, bufR :: Int
bufR=Int
count, bufSize :: Int
bufSize=Int
sz, bufOffset :: Word64
bufOffset=Word64
0 }

      Handle__ -> Buffer CharBufElem -> IO ()
writeCharBuffer Handle__
h_ Buffer CharBufElem
this_buf

      Bool -> IO () -> IO ()
forall (f :: * -> *). Applicative f => Bool -> f () -> f ()
when Bool
flush (IO () -> IO ()) -> IO () -> IO ()
forall a b. (a -> b) -> a -> b
$ Handle__ -> IO ()
flushByteWriteBuffer Handle__
h_

      -- release the buffer if necessary
      Bool -> IO () -> IO ()
forall (f :: * -> *). Applicative f => Bool -> f () -> f ()
when Bool
release (IO () -> IO ()) -> IO () -> IO ()
forall a b. (a -> b) -> a -> b
$ do
          -- find size of current buffer
          old_buf@Buffer{ bufSize=size } <- IORef (Buffer CharBufElem) -> IO (Buffer CharBufElem)
forall a. IORef a -> IO a
readIORef IORef (Buffer CharBufElem)
haCharBuffer
          when (sz == size) $ do
               spare_bufs <- readIORef haBuffers
               writeIORef haBuffers (BufferListCons raw spare_bufs)

      Buffer CharBufElem -> IO (Buffer CharBufElem)
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Buffer CharBufElem
this_buf

-- ---------------------------------------------------------------------------
-- Reading/writing sequences of bytes.

-- ---------------------------------------------------------------------------
-- hPutBuf

-- | 'hPutBuf' @hdl buf count@ writes @count@ 8-bit bytes from the
-- buffer @buf@ to the handle @hdl@.  It returns ().
--
-- 'hPutBuf' ignores any text encoding that applies to the 'Handle',
-- writing the bytes directly to the underlying file or device.
--
-- 'hPutBuf' ignores the prevailing 'System.IO.TextEncoding' and
-- 'NewlineMode' on the 'Handle', and writes bytes directly.
--
-- This operation may fail with:
--
--  * 'ResourceVanished' if the handle is a pipe or socket, and the
--    reading end is closed.  (If this is a POSIX system, and the program
--    has not asked to ignore SIGPIPE, then a SIGPIPE may be delivered
--    instead, whose default action is to terminate the program).

hPutBuf :: Handle                       -- handle to write to
        -> Ptr a                        -- address of buffer
        -> Int                          -- number of bytes of data in buffer
        -> IO ()
hPutBuf :: forall a. Handle -> Ptr a -> Int -> IO ()
hPutBuf Handle
h Ptr a
ptr Int
count = do _ <- Handle -> Ptr a -> Int -> Bool -> IO Int
forall a. Handle -> Ptr a -> Int -> Bool -> IO Int
hPutBuf' Handle
h Ptr a
ptr Int
count Bool
True
                         return ()

hPutBufNonBlocking
        :: Handle                       -- handle to write to
        -> Ptr a                        -- address of buffer
        -> Int                          -- number of bytes of data in buffer
        -> IO Int                       -- returns: number of bytes written
hPutBufNonBlocking :: forall a. Handle -> Ptr a -> Int -> IO Int
hPutBufNonBlocking Handle
h Ptr a
ptr Int
count = Handle -> Ptr a -> Int -> Bool -> IO Int
forall a. Handle -> Ptr a -> Int -> Bool -> IO Int
hPutBuf' Handle
h Ptr a
ptr Int
count Bool
False

hPutBuf':: Handle                       -- handle to write to
        -> Ptr a                        -- address of buffer
        -> Int                          -- number of bytes of data in buffer
        -> Bool                         -- allow blocking?
        -> IO Int
hPutBuf' :: forall a. Handle -> Ptr a -> Int -> Bool -> IO Int
hPutBuf' Handle
handle Ptr a
ptr Int
count Bool
can_block
  | Int
count Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
0 = Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Int
0
  | Int
count Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
<  Int
0 = Handle -> String -> Int -> IO Int
forall a. Handle -> String -> Int -> IO a
illegalBufferSize Handle
handle String
"hPutBuf" Int
count
  | Bool
otherwise =
    String -> Handle -> (Handle__ -> IO Int) -> IO Int
forall a. String -> Handle -> (Handle__ -> IO a) -> IO a
wantWritableHandle String
"hPutBuf" Handle
handle ((Handle__ -> IO Int) -> IO Int) -> (Handle__ -> IO Int) -> IO Int
forall a b. (a -> b) -> a -> b
$
      \ h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} -> do
          String -> IO ()
debugIO (String
"hPutBuf count=" String -> String -> String
forall a. [a] -> [a] -> [a]
++ Int -> String
forall a. Show a => a -> String
show Int
count)

          r <- Handle__ -> Ptr Word8 -> Int -> Bool -> IO Int
bufWrite Handle__
h_ (Ptr a -> Ptr Word8
forall a b. Ptr a -> Ptr b
castPtr Ptr a
ptr) Int
count Bool
can_block

          -- we must flush if this Handle is set to NoBuffering.  If
          -- it is set to LineBuffering, be conservative and flush
          -- anyway (we didn't check for newlines in the data).
          case haBufferMode of
             BlockBuffering Maybe Int
_      -> () -> IO ()
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return ()
             BufferMode
_line_or_no_buffering -> Handle__ -> IO ()
flushWriteBuffer Handle__
h_
          return r

-- TODO: Possible optimisation:
--       If we know that `w + count > size`, we should write both the
--       handle buffer and the `ptr` in a single `writev()` syscall.
bufWrite :: Handle__-> Ptr Word8 -> Int -> Bool -> IO Int
bufWrite :: Handle__ -> Ptr Word8 -> Int -> Bool -> IO Int
bufWrite h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} Ptr Word8
ptr !Int
count Bool
can_block = do
  -- Get buffer to determine size and free space in buffer
  old_buf@Buffer{ bufR=w, bufSize=size }
      <- IORef (Buffer Word8) -> IO (Buffer Word8)
forall a. IORef a -> IO a
readIORef IORef (Buffer Word8)
haByteBuffer

  -- There's no need to buffer if the incoming data is larger than
  -- the handle buffer (`count >= size`).
  -- Check if we can try to buffer the given chunk of data.
  b <- if (count < size && count <= size - w)
        then bufferChunk h_ old_buf ptr count
        else do
          -- The given data does not fit into the buffer.
          -- Either because it's too large for the buffer
          -- or the buffer is too full. Either way we need
          -- to flush the buffered data first.
          flushed_buf <- flushByteWriteBufferGiven h_ old_buf
          if count < size
              -- The data is small enough to be buffered.
              then bufferChunk h_ flushed_buf ptr count
              else do
                let offset = Buffer Word8 -> Word64
forall e. Buffer e -> Word64
bufOffset Buffer Word8
flushed_buf
                !bytes <- if can_block
                            then writeChunk            h_ (castPtr ptr) offset count
                            else writeChunkNonBlocking h_ (castPtr ptr) offset count
                -- Update buffer with actual bytes written.
                writeIORef haByteBuffer $! bufferAddOffset bytes flushed_buf
                return bytes
  debugIO "hPutBuf: done"
  return b

-- Flush the given buffer via the handle, return the flushed buffer
flushByteWriteBufferGiven :: Handle__ -> Buffer Word8 -> IO (Buffer Word8)
flushByteWriteBufferGiven :: Handle__ -> Buffer Word8 -> IO (Buffer Word8)
flushByteWriteBufferGiven h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} Buffer Word8
bbuf =
  if (Bool -> Bool
not (Buffer Word8 -> Bool
forall e. Buffer e -> Bool
isEmptyBuffer Buffer Word8
bbuf))
    then do
      bbuf' <- dev -> Buffer Word8 -> IO (Buffer Word8)
forall dev.
BufferedIO dev =>
dev -> Buffer Word8 -> IO (Buffer Word8)
Buffered.flushWriteBuffer dev
haDevice Buffer Word8
bbuf
      debugIO ("flushByteWriteBufferGiven: bbuf=" ++ summaryBuffer bbuf')
      writeIORef haByteBuffer bbuf'
      return bbuf'
    else
      Buffer Word8 -> IO (Buffer Word8)
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Buffer Word8
bbuf

-- Fill buffer and return bytes buffered/written.
-- Flushes buffer if it's full after adding the data.
bufferChunk :: Handle__ -> Buffer Word8 -> Ptr Word8 -> Int -> IO Int
bufferChunk :: Handle__ -> Buffer Word8 -> Ptr Word8 -> Int -> IO Int
bufferChunk h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} old_buf :: Buffer Word8
old_buf@Buffer{ bufRaw :: forall e. Buffer e -> RawBuffer e
bufRaw=RawBuffer Word8
raw, bufR :: forall e. Buffer e -> Int
bufR=Int
w, bufSize :: forall e. Buffer e -> Int
bufSize=Int
size } Ptr Word8
ptr !Int
count = do
    String -> IO ()
debugIO (String
"hPutBuf: copying to buffer, w=" String -> String -> String
forall a. [a] -> [a] -> [a]
++ Int -> String
forall a. Show a => a -> String
show Int
w)
    RawBuffer Word8 -> Int -> Ptr Word8 -> Int -> IO ()
forall e. RawBuffer e -> Int -> Ptr e -> Int -> IO ()
copyToRawBuffer RawBuffer Word8
raw Int
w Ptr Word8
ptr Int
count
    let copied_buf :: Buffer Word8
copied_buf = Buffer Word8
old_buf{ bufR = w + count }
    -- If the write filled the buffer completely, we need to flush,
    -- to maintain the "INVARIANTS on Buffers" from
    -- GHC.Internal.IO.Buffer.checkBuffer: "a write buffer is never full".
    if Buffer Word8 -> Bool
forall e. Buffer e -> Bool
isFullBuffer Buffer Word8
copied_buf
      then do
        -- TODO: we should do a non-blocking flush here
        String -> IO ()
debugIO String
"hPutBuf: flushing full buffer after writing"
        _ <- Handle__ -> Buffer Word8 -> IO (Buffer Word8)
flushByteWriteBufferGiven Handle__
h_ Buffer Word8
copied_buf
        return ()
      else
        IORef (Buffer Word8) -> Buffer Word8 -> IO ()
forall a. IORef a -> a -> IO ()
writeIORef IORef (Buffer Word8)
haByteBuffer Buffer Word8
copied_buf
    Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Int
count

writeChunk :: Handle__ -> Ptr Word8 -> Word64 -> Int -> IO Int
writeChunk :: Handle__ -> Ptr Word8 -> Word64 -> Int -> IO Int
writeChunk h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} Ptr Word8
ptr Word64
offset Int
bytes
  = do dev -> Ptr Word8 -> Word64 -> Int -> IO ()
forall a. RawIO a => a -> Ptr Word8 -> Word64 -> Int -> IO ()
RawIO.write dev
haDevice Ptr Word8
ptr Word64
offset Int
bytes
       Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Int
bytes

writeChunkNonBlocking :: Handle__ -> Ptr Word8 -> Word64 -> Int -> IO Int
writeChunkNonBlocking :: Handle__ -> Ptr Word8 -> Word64 -> Int -> IO Int
writeChunkNonBlocking h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} Ptr Word8
ptr Word64
offset Int
bytes
  = dev -> Ptr Word8 -> Word64 -> Int -> IO Int
forall a. RawIO a => a -> Ptr Word8 -> Word64 -> Int -> IO Int
RawIO.writeNonBlocking dev
haDevice Ptr Word8
ptr Word64
offset Int
bytes

-- ---------------------------------------------------------------------------
-- hGetBuf

-- | 'hGetBuf' @hdl buf count@ reads data from the handle @hdl@
-- into the buffer @buf@ until either EOF is reached or
-- @count@ 8-bit bytes have been read.
-- It returns the number of bytes actually read.  This may be zero if
-- EOF was reached before any data was read (or if @count@ is zero).
--
-- 'hGetBuf' never raises an EOF exception, instead it returns a value
-- smaller than @count@.
--
-- If the handle is a pipe or socket, and the writing end
-- is closed, 'hGetBuf' will behave as if EOF was reached.
--
-- 'hGetBuf' ignores the prevailing 'System.IO.TextEncoding' and 'NewlineMode'
-- on the 'Handle', and reads bytes directly.

hGetBuf :: Handle -> Ptr a -> Int -> IO Int
hGetBuf :: forall a. Handle -> Ptr a -> Int -> IO Int
hGetBuf Handle
h !Ptr a
ptr Int
count
  | Int
count Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
0 = Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Int
0
  | Int
count Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
<  Int
0 = Handle -> String -> Int -> IO Int
forall a. Handle -> String -> Int -> IO a
illegalBufferSize Handle
h String
"hGetBuf" Int
count
  | Bool
otherwise =
      String -> Handle -> (Handle__ -> IO Int) -> IO Int
forall a. String -> Handle -> (Handle__ -> IO a) -> IO a
wantReadableHandle_ String
"hGetBuf" Handle
h ((Handle__ -> IO Int) -> IO Int) -> (Handle__ -> IO Int) -> IO Int
forall a b. (a -> b) -> a -> b
$ \ h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} -> do
          String -> IO ()
debugIO (String -> IO ()) -> String -> IO ()
forall a b. (a -> b) -> a -> b
$ String
":: hGetBuf - " String -> String -> String
forall a. [a] -> [a] -> [a]
++ Handle -> String
forall a. Show a => a -> String
show Handle
h String -> String -> String
forall a. [a] -> [a] -> [a]
++ String
" - " String -> String -> String
forall a. [a] -> [a] -> [a]
++ Int -> String
forall a. Show a => a -> String
show Int
count
          Handle__ -> IO ()
flushCharReadBuffer Handle__
h_
          buf@Buffer{ bufRaw=raw, bufR=w, bufL=r, bufSize=sz }
            <- IORef (Buffer Word8) -> IO (Buffer Word8)
forall a. IORef a -> IO a
readIORef IORef (Buffer Word8)
haByteBuffer
          debugIO ("hGetBuf: " ++ summaryBuffer buf)
          res <- if isEmptyBuffer buf
                    then bufReadEmpty    h_ buf (castPtr ptr) 0 count
                    else bufReadNonEmpty h_ buf (castPtr ptr) 0 count
          debugIO "** hGetBuf done."
          return res

-- small reads go through the buffer, large reads are satisfied by
-- taking data first from the buffer and then direct from the file
-- descriptor.

bufReadNonEmpty :: Handle__ -> Buffer Word8 -> Ptr Word8 -> Int -> Int -> IO Int
bufReadNonEmpty :: Handle__ -> Buffer Word8 -> Ptr Word8 -> Int -> Int -> IO Int
bufReadNonEmpty h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..}
                -- w for width, r for ... read ptr?
                buf :: Buffer Word8
buf@Buffer{ bufRaw :: forall e. Buffer e -> RawBuffer e
bufRaw=RawBuffer Word8
raw, bufR :: forall e. Buffer e -> Int
bufR=Int
w, bufL :: forall e. Buffer e -> Int
bufL=Int
r, bufSize :: forall e. Buffer e -> Int
bufSize=Int
sz }
                Ptr Word8
ptr !Int
so_far !Int
count
 = do
        String -> IO ()
debugIO String
":: bufReadNonEmpty"
        -- We use < instead of <= because for count == avail
        -- we need to reset bufL and bufR to zero.
        -- See also: INVARIANTS on Buffers
        let avail :: Int
avail = Int
w Int -> Int -> Int
forall a. Num a => a -> a -> a
- Int
r
        if (Int
count Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
< Int
avail)
           then do
                Ptr Word8 -> RawBuffer Word8 -> Int -> Int -> IO ()
forall e. Ptr e -> RawBuffer e -> Int -> Int -> IO ()
copyFromRawBuffer Ptr Word8
ptr RawBuffer Word8
raw Int
r Int
count
                IORef (Buffer Word8) -> Buffer Word8 -> IO ()
forall a. IORef a -> a -> IO ()
writeIORef IORef (Buffer Word8)
haByteBuffer Buffer Word8
buf{ bufL = r + count }
                Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return (Int
so_far Int -> Int -> Int
forall a. Num a => a -> a -> a
+ Int
count)
           else do

        Ptr Word8 -> RawBuffer Word8 -> Int -> Int -> IO ()
forall e. Ptr e -> RawBuffer e -> Int -> Int -> IO ()
copyFromRawBuffer Ptr Word8
ptr RawBuffer Word8
raw Int
r Int
avail
        let buf' :: Buffer Word8
buf' = Buffer Word8
buf{ bufR=0, bufL=0 }
        IORef (Buffer Word8) -> Buffer Word8 -> IO ()
forall a. IORef a -> a -> IO ()
writeIORef IORef (Buffer Word8)
haByteBuffer Buffer Word8
buf'
        let remaining :: Int
remaining = Int
count Int -> Int -> Int
forall a. Num a => a -> a -> a
- Int
avail
            so_far' :: Int
so_far' = Int
so_far Int -> Int -> Int
forall a. Num a => a -> a -> a
+ Int
avail
            ptr' :: Ptr b
ptr' = Ptr Word8
ptr Ptr Word8 -> Int -> Ptr b
forall a b. Ptr a -> Int -> Ptr b
`plusPtr` Int
avail

        String -> IO ()
debugIO (String
"bufReadNonEmpty: " String -> String -> String
forall a. [a] -> [a] -> [a]
++ Buffer Word8 -> String
forall a. Buffer a -> String
summaryBuffer Buffer Word8
buf' String -> String -> String
forall a. [a] -> [a] -> [a]
++ String
" s:" String -> String -> String
forall a. [a] -> [a] -> [a]
++ Int -> String
forall a. Show a => a -> String
show Int
so_far' String -> String -> String
forall a. [a] -> [a] -> [a]
++ String
" r:" String -> String -> String
forall a. [a] -> [a] -> [a]
++ Int -> String
forall a. Show a => a -> String
show Int
remaining)
        b <- if Int
remaining Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
0
           then Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Int
so_far'
           else Handle__ -> Buffer Word8 -> Ptr Word8 -> Int -> Int -> IO Int
bufReadEmpty Handle__
h_ Buffer Word8
buf' Ptr Word8
forall {b}. Ptr b
ptr' Int
so_far' Int
remaining
        debugIO ":: bufReadNonEmpty - done"
        return b

-- We want to read more data, but the buffer is empty. (buffL == buffR == 0)
-- See also Note [INVARIANTS on Buffers] in Buffer.hs
bufReadEmpty :: Handle__ -> Buffer Word8 -> Ptr Word8 -> Int -> Int -> IO Int
bufReadEmpty :: Handle__ -> Buffer Word8 -> Ptr Word8 -> Int -> Int -> IO Int
bufReadEmpty h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..}
             buf :: Buffer Word8
buf@Buffer{ bufRaw :: forall e. Buffer e -> RawBuffer e
bufRaw=RawBuffer Word8
raw, bufR :: forall e. Buffer e -> Int
bufR=Int
w, bufL :: forall e. Buffer e -> Int
bufL=Int
_r, bufSize :: forall e. Buffer e -> Int
bufSize=Int
sz, bufOffset :: forall e. Buffer e -> Word64
bufOffset=Word64
bff }
             Ptr Word8
ptr Int
so_far Int
count
 | Int
count Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
> Int
sz
 = do
        bytes_read <- dev -> Int -> Word64 -> Int -> IO Int
forall dev. RawIO dev => dev -> Int -> Word64 -> Int -> IO Int
loop dev
haDevice Int
0 Word64
bff Int
count
        -- bytes_read includes so_far (content that was in the buffer)
        -- but that is already accounted for in the old offset, so don't
        -- count it twice.
        let buf1 = Int -> Buffer Word8 -> Buffer Word8
forall e. Int -> Buffer e -> Buffer e
bufferAddOffset (Int -> Int
forall a b. (Integral a, Num b) => a -> b
fromIntegral (Int -> Int) -> Int -> Int
forall a b. (a -> b) -> a -> b
$ Int
bytes_read Int -> Int -> Int
forall a. Num a => a -> a -> a
- Int
so_far) Buffer Word8
buf
        writeIORef haByteBuffer buf1
        debugIO ("bufReadEmpty1.1: " ++ summaryBuffer buf1 ++ " read:" ++ show bytes_read)
        return bytes_read
 | Bool
otherwise = do
        (r,buf') <- dev -> Buffer Word8 -> IO (Int, Buffer Word8)
forall dev.
BufferedIO dev =>
dev -> Buffer Word8 -> IO (Int, Buffer Word8)
Buffered.fillReadBuffer dev
haDevice Buffer Word8
buf
        writeIORef haByteBuffer buf'
        if r == 0 -- end of file reached
            then return so_far
            else bufReadNonEmpty h_ buf' ptr so_far count
 where
  -- Read @bytes@ byte into ptr. Repeating the read until either zero
  -- bytes where read, or we are done reading.
  loop :: RawIO.RawIO dev => dev -> Int -> Word64 -> Int -> IO Int
  loop :: forall dev. RawIO dev => dev -> Int -> Word64 -> Int -> IO Int
loop dev
dev Int
delta Word64
off Int
bytes | Int
bytes Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
<= Int
0 = Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return (Int
so_far Int -> Int -> Int
forall a. Num a => a -> a -> a
+ Int
delta)
  loop dev
dev Int
delta Word64
off Int
bytes = do
    r <- dev -> Ptr Word8 -> Word64 -> Int -> IO Int
forall a. RawIO a => a -> Ptr Word8 -> Word64 -> Int -> IO Int
RawIO.read dev
dev (Ptr Word8
ptr Ptr Word8 -> Int -> Ptr Word8
forall a b. Ptr a -> Int -> Ptr b
`plusPtr` Int
delta) Word64
off Int
bytes
    debugIO $ show ptr ++ " - loop read@" ++ show delta ++ ": " ++ show r
    debugIO $ "next:" ++ show (delta + r) ++ " - left:" ++ show (bytes - r)
    if r == 0
        then return (so_far + delta)
        else loop dev (delta + r) (off + fromIntegral r) (bytes - r)

-- ---------------------------------------------------------------------------
-- hGetBufSome

-- | 'hGetBufSome' @hdl buf count@ reads data from the handle @hdl@
-- into the buffer @buf@.  If there is any data available to read,
-- then 'hGetBufSome' returns it immediately; it only blocks if there
-- is no data to be read.
--
-- It returns the number of bytes actually read.  This may be zero if
-- EOF was reached before any data was read (or if @count@ is zero).
--
-- 'hGetBufSome' never raises an EOF exception, instead it returns a value
-- smaller than @count@.
--
-- If the handle is a pipe or socket, and the writing end
-- is closed, 'hGetBufSome' will behave as if EOF was reached.
--
-- 'hGetBufSome' ignores the prevailing 'System.IO.TextEncoding' and
-- 'NewlineMode' on the 'Handle', and reads bytes directly.

hGetBufSome :: Handle -> Ptr a -> Int -> IO Int
hGetBufSome :: forall a. Handle -> Ptr a -> Int -> IO Int
hGetBufSome Handle
h !Ptr a
ptr Int
count
  | Int
count Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
0 = Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Int
0
  | Int
count Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
<  Int
0 = Handle -> String -> Int -> IO Int
forall a. Handle -> String -> Int -> IO a
illegalBufferSize Handle
h String
"hGetBufSome" Int
count
  | Bool
otherwise =
      String -> Handle -> (Handle__ -> IO Int) -> IO Int
forall a. String -> Handle -> (Handle__ -> IO a) -> IO a
wantReadableHandle_ String
"hGetBufSome" Handle
h ((Handle__ -> IO Int) -> IO Int) -> (Handle__ -> IO Int) -> IO Int
forall a b. (a -> b) -> a -> b
$ \ h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} -> do
         Handle__ -> IO ()
flushCharReadBuffer Handle__
h_
         buf@Buffer{ bufSize=sz, bufOffset=offset } <- IORef (Buffer Word8) -> IO (Buffer Word8)
forall a. IORef a -> IO a
readIORef IORef (Buffer Word8)
haByteBuffer
         if isEmptyBuffer buf
            then case count > sz of  -- large read? optimize it with a little special case:
                    Bool
True -> do bytes <- dev -> Ptr Word8 -> Word64 -> Int -> IO Int
forall a. RawIO a => a -> Ptr Word8 -> Word64 -> Int -> IO Int
RawIO.read dev
haDevice (Ptr a -> Ptr Word8
forall a b. Ptr a -> Ptr b
castPtr Ptr a
ptr) Word64
offset Int
count
                               -- Update buffer with actual bytes written.
                               writeIORef haByteBuffer $! bufferAddOffset bytes buf
                               return bytes
                    Bool
_ -> do (r,buf') <- dev -> Buffer Word8 -> IO (Int, Buffer Word8)
forall dev.
BufferedIO dev =>
dev -> Buffer Word8 -> IO (Int, Buffer Word8)
Buffered.fillReadBuffer dev
haDevice Buffer Word8
buf
                            if r == 0
                               then return 0
                               else do writeIORef haByteBuffer buf'
                                       bufReadNBNonEmpty h_ buf' (castPtr ptr) 0 (min r count)
                                        -- new count is  (min r count), so
                                        -- that bufReadNBNonEmpty will not
                                        -- issue another read.
            else
              let count' = Int -> Int -> Int
forall a. Ord a => a -> a -> a
min Int
count (Buffer Word8 -> Int
forall e. Buffer e -> Int
bufferElems Buffer Word8
buf)
              in bufReadNBNonEmpty h_ buf (castPtr ptr) 0 count'

-- | 'hGetBufNonBlocking' @hdl buf count@ reads data from the handle @hdl@
-- into the buffer @buf@ until either EOF is reached, or
-- @count@ 8-bit bytes have been read, or there is no more data available
-- to read immediately.
--
-- 'hGetBufNonBlocking' is identical to 'hGetBuf', except that it will
-- never block waiting for data to become available, instead it returns
-- only whatever data is available.  To wait for data to arrive before
-- calling 'hGetBufNonBlocking', use 'hWaitForInput'.
--
-- If the handle is a pipe or socket, and the writing end
-- is closed, 'hGetBufNonBlocking' will behave as if EOF was reached.
--
-- 'hGetBufNonBlocking' ignores the prevailing 'System.IO.TextEncoding' and
-- 'NewlineMode' on the 'Handle', and reads bytes directly.
--
-- NOTE: on Windows, this function does not work correctly; it
-- behaves identically to 'hGetBuf'.

hGetBufNonBlocking :: Handle -> Ptr a -> Int -> IO Int
hGetBufNonBlocking :: forall a. Handle -> Ptr a -> Int -> IO Int
hGetBufNonBlocking Handle
h !Ptr a
ptr Int
count
  | Int
count Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
0 = Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Int
0
  | Int
count Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
<  Int
0 = Handle -> String -> Int -> IO Int
forall a. Handle -> String -> Int -> IO a
illegalBufferSize Handle
h String
"hGetBufNonBlocking" Int
count
  | Bool
otherwise =
      String -> Handle -> (Handle__ -> IO Int) -> IO Int
forall a. String -> Handle -> (Handle__ -> IO a) -> IO a
wantReadableHandle_ String
"hGetBufNonBlocking" Handle
h ((Handle__ -> IO Int) -> IO Int) -> (Handle__ -> IO Int) -> IO Int
forall a b. (a -> b) -> a -> b
$ \ h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..} -> do
         Handle__ -> IO ()
flushCharReadBuffer Handle__
h_
         buf@Buffer{ bufRaw=raw, bufR=w, bufL=r, bufSize=sz }
            <- IORef (Buffer Word8) -> IO (Buffer Word8)
forall a. IORef a -> IO a
readIORef IORef (Buffer Word8)
haByteBuffer
         if isEmptyBuffer buf
            then bufReadNBEmpty    h_ buf (castPtr ptr) 0 count
            else bufReadNBNonEmpty h_ buf (castPtr ptr) 0 count

bufReadNBEmpty :: Handle__ -> Buffer Word8 -> Ptr Word8 -> Int -> Int -> IO Int
bufReadNBEmpty :: Handle__ -> Buffer Word8 -> Ptr Word8 -> Int -> Int -> IO Int
bufReadNBEmpty   h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..}
                 buf :: Buffer Word8
buf@Buffer{ bufRaw :: forall e. Buffer e -> RawBuffer e
bufRaw=RawBuffer Word8
raw, bufR :: forall e. Buffer e -> Int
bufR=Int
w, bufL :: forall e. Buffer e -> Int
bufL=Int
_r, bufSize :: forall e. Buffer e -> Int
bufSize=Int
sz
                           , bufOffset :: forall e. Buffer e -> Word64
bufOffset=Word64
offset }
                 Ptr Word8
ptr Int
so_far Int
count
  | Int
count Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
> Int
sz = do
       m <- dev -> Ptr Word8 -> Word64 -> Int -> IO (Maybe Int)
forall a.
RawIO a =>
a -> Ptr Word8 -> Word64 -> Int -> IO (Maybe Int)
RawIO.readNonBlocking dev
haDevice Ptr Word8
ptr Word64
offset Int
count
       case m of
         Maybe Int
Nothing -> Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Int
so_far
         Just Int
n  -> do -- Update buffer with actual bytes written.
                       IORef (Buffer Word8) -> Buffer Word8 -> IO ()
forall a. IORef a -> a -> IO ()
writeIORef IORef (Buffer Word8)
haByteBuffer (Buffer Word8 -> IO ()) -> Buffer Word8 -> IO ()
forall a b. (a -> b) -> a -> b
$! Int -> Buffer Word8 -> Buffer Word8
forall e. Int -> Buffer e -> Buffer e
bufferAddOffset Int
n Buffer Word8
buf
                       Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return (Int
so_far Int -> Int -> Int
forall a. Num a => a -> a -> a
+ Int
n)

 | Bool
otherwise = do
    --  buf <- readIORef haByteBuffer
     (r,buf') <- dev -> Buffer Word8 -> IO (Maybe Int, Buffer Word8)
forall dev.
BufferedIO dev =>
dev -> Buffer Word8 -> IO (Maybe Int, Buffer Word8)
Buffered.fillReadBuffer0 dev
haDevice Buffer Word8
buf
     case r of
       Maybe Int
Nothing -> Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Int
so_far
       Just Int
0  -> Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Int
so_far
       Just Int
r'  -> do
         IORef (Buffer Word8) -> Buffer Word8 -> IO ()
forall a. IORef a -> a -> IO ()
writeIORef IORef (Buffer Word8)
haByteBuffer Buffer Word8
buf'
         Handle__ -> Buffer Word8 -> Ptr Word8 -> Int -> Int -> IO Int
bufReadNBNonEmpty Handle__
h_ Buffer Word8
buf' Ptr Word8
ptr Int
so_far (Int -> Int -> Int
forall a. Ord a => a -> a -> a
min Int
count Int
r')
                          -- NOTE: new count is    min count r'
                          -- so we will just copy the contents of the
                          -- buffer in the recursive call, and not
                          -- loop again.


bufReadNBNonEmpty :: Handle__ -> Buffer Word8 -> Ptr Word8 -> Int -> Int -> IO Int
bufReadNBNonEmpty :: Handle__ -> Buffer Word8 -> Ptr Word8 -> Int -> Int -> IO Int
bufReadNBNonEmpty h_ :: Handle__
h_@Handle__{dev
Maybe (MVar Handle__)
Maybe TextEncoding
Maybe (TextEncoder enc_state)
Maybe (TextDecoder dec_state)
IORef (dec_state, Buffer Word8)
IORef (Buffer CharBufElem)
IORef (Buffer Word8)
IORef (BufferList CharBufElem)
Newline
BufferMode
HandleType
haOtherSide :: Handle__ -> Maybe (MVar Handle__)
haOutputNL :: Handle__ -> Newline
haInputNL :: Handle__ -> Newline
haCodec :: Handle__ -> Maybe TextEncoding
haDecoder :: ()
haEncoder :: ()
haBuffers :: Handle__ -> IORef (BufferList CharBufElem)
haCharBuffer :: Handle__ -> IORef (Buffer CharBufElem)
haLastDecode :: ()
haBufferMode :: Handle__ -> BufferMode
haByteBuffer :: Handle__ -> IORef (Buffer Word8)
haType :: Handle__ -> HandleType
haDevice :: ()
haDevice :: dev
haType :: HandleType
haByteBuffer :: IORef (Buffer Word8)
haBufferMode :: BufferMode
haLastDecode :: IORef (dec_state, Buffer Word8)
haCharBuffer :: IORef (Buffer CharBufElem)
haBuffers :: IORef (BufferList CharBufElem)
haEncoder :: Maybe (TextEncoder enc_state)
haDecoder :: Maybe (TextDecoder dec_state)
haCodec :: Maybe TextEncoding
haInputNL :: Newline
haOutputNL :: Newline
haOtherSide :: Maybe (MVar Handle__)
..}
                  buf :: Buffer Word8
buf@Buffer{ bufRaw :: forall e. Buffer e -> RawBuffer e
bufRaw=RawBuffer Word8
raw, bufR :: forall e. Buffer e -> Int
bufR=Int
w, bufL :: forall e. Buffer e -> Int
bufL=Int
r, bufSize :: forall e. Buffer e -> Int
bufSize=Int
sz }
                  Ptr Word8
ptr Int
so_far Int
count
  = do
        let avail :: Int
avail = Int
w Int -> Int -> Int
forall a. Num a => a -> a -> a
- Int
r
        -- We use < instead of <= because for count == avail
        -- we need to reset bufL and bufR to zero.
        -- See also [INVARIANTS on Buffers] in Buffer.hs
        if (Int
count Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
< Int
avail)
           then do
                Ptr Word8 -> RawBuffer Word8 -> Int -> Int -> IO ()
forall e. Ptr e -> RawBuffer e -> Int -> Int -> IO ()
copyFromRawBuffer Ptr Word8
ptr RawBuffer Word8
raw Int
r Int
count
                IORef (Buffer Word8) -> Buffer Word8 -> IO ()
forall a. IORef a -> a -> IO ()
writeIORef IORef (Buffer Word8)
haByteBuffer Buffer Word8
buf{ bufL = r + count }
                Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return (Int
so_far Int -> Int -> Int
forall a. Num a => a -> a -> a
+ Int
count)
           else do

        Ptr Word8 -> RawBuffer Word8 -> Int -> Int -> IO ()
forall e. Ptr e -> RawBuffer e -> Int -> Int -> IO ()
copyFromRawBuffer Ptr Word8
ptr RawBuffer Word8
raw Int
r Int
avail
        let buf' :: Buffer Word8
buf' = Buffer Word8
buf{ bufR=0, bufL=0 }
        IORef (Buffer Word8) -> Buffer Word8 -> IO ()
forall a. IORef a -> a -> IO ()
writeIORef IORef (Buffer Word8)
haByteBuffer Buffer Word8
buf'
        let remaining :: Int
remaining = Int
count Int -> Int -> Int
forall a. Num a => a -> a -> a
- Int
avail
            so_far' :: Int
so_far' = Int
so_far Int -> Int -> Int
forall a. Num a => a -> a -> a
+ Int
avail
            ptr' :: Ptr b
ptr' = Ptr Word8
ptr Ptr Word8 -> Int -> Ptr b
forall a b. Ptr a -> Int -> Ptr b
`plusPtr` Int
avail

        if Int
remaining Int -> Int -> Bool
forall a. Eq a => a -> a -> Bool
== Int
0
           then Int -> IO Int
forall a. a -> IO a
forall (m :: * -> *) a. Monad m => a -> m a
return Int
so_far'
           else Handle__ -> Buffer Word8 -> Ptr Word8 -> Int -> Int -> IO Int
bufReadNBEmpty Handle__
h_ Buffer Word8
buf' Ptr Word8
forall {b}. Ptr b
ptr' Int
so_far' Int
remaining

-- ---------------------------------------------------------------------------
-- memcpy wrappers

copyToRawBuffer :: RawBuffer e -> Int -> Ptr e -> Int -> IO ()
copyToRawBuffer :: forall e. RawBuffer e -> Int -> Ptr e -> Int -> IO ()
copyToRawBuffer RawBuffer e
raw Int
off Ptr e
ptr Int
bytes =
 RawBuffer e -> (Ptr e -> IO ()) -> IO ()
forall e a. RawBuffer e -> (Ptr e -> IO a) -> IO a
withRawBuffer RawBuffer e
raw ((Ptr e -> IO ()) -> IO ()) -> (Ptr e -> IO ()) -> IO ()
forall a b. (a -> b) -> a -> b
$ \Ptr e
praw ->
   do _ <- Ptr e -> Ptr e -> CSize -> IO (Ptr ())
forall a. Ptr a -> Ptr a -> CSize -> IO (Ptr ())
memcpy (Ptr e
praw Ptr e -> Int -> Ptr e
forall a b. Ptr a -> Int -> Ptr b
`plusPtr` Int
off) Ptr e
ptr (Int -> CSize
forall a b. (Integral a, Num b) => a -> b
fromIntegral Int
bytes)
      return ()

copyFromRawBuffer :: Ptr e -> RawBuffer e -> Int -> Int -> IO ()
copyFromRawBuffer :: forall e. Ptr e -> RawBuffer e -> Int -> Int -> IO ()
copyFromRawBuffer Ptr e
ptr RawBuffer e
raw Int
off Int
bytes =
 RawBuffer e -> (Ptr e -> IO ()) -> IO ()
forall e a. RawBuffer e -> (Ptr e -> IO a) -> IO a
withRawBuffer RawBuffer e
raw ((Ptr e -> IO ()) -> IO ()) -> (Ptr e -> IO ()) -> IO ()
forall a b. (a -> b) -> a -> b
$ \Ptr e
praw ->
   do _ <- Ptr e -> Ptr e -> CSize -> IO (Ptr ())
forall a. Ptr a -> Ptr a -> CSize -> IO (Ptr ())
memcpy Ptr e
ptr (Ptr e
praw Ptr e -> Int -> Ptr e
forall a b. Ptr a -> Int -> Ptr b
`plusPtr` Int
off) (Int -> CSize
forall a b. (Integral a, Num b) => a -> b
fromIntegral Int
bytes)
      return ()

foreign import ccall unsafe "memcpy"
   memcpy :: Ptr a -> Ptr a -> CSize -> IO (Ptr ())

-----------------------------------------------------------------------------
-- Internal Utils

illegalBufferSize :: Handle -> String -> Int -> IO a
illegalBufferSize :: forall a. Handle -> String -> Int -> IO a
illegalBufferSize Handle
handle String
fn Int
sz =
        IOError -> IO a
forall a. (?callStack::CallStack) => IOError -> IO a
ioException (Maybe Handle
-> IOErrorType
-> String
-> String
-> Maybe CInt
-> Maybe String
-> IOError
IOError (Handle -> Maybe Handle
forall a. a -> Maybe a
Just Handle
handle)
                            IOErrorType
InvalidArgument  String
fn
                            (String
"illegal buffer size " String -> String -> String
forall a. [a] -> [a] -> [a]
++ Int -> Int -> String -> String
forall a. Show a => Int -> a -> String -> String
showsPrec Int
9 Int
sz [])
                            Maybe CInt
forall a. Maybe a
Nothing Maybe String
forall a. Maybe a
Nothing)