chore: prepare v2.1.6

fix: writable issue
docs: add LICENSE
2024-07-17 14:41:58 -05:00 · 2024-07-17 13:26:44 -05:00 · 2024-07-10 13:49:28 -05:00 · 2024-07-08 12:43:58 -05:00 · 2024-07-08 12:40:25 -05:00 · 2024-06-25 14:26:40 -05:00
21 changed files with 9817 additions and 242 deletions
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                    GNU GENERAL PUBLIC LICENSE
                       Version 3, 29 June 2007
 Copyright (C) 2007 Free Software Foundation, Inc. <https://fsf.org/>
 Everyone is permitted to copy and distribute verbatim copies
 of this license document, but changing it is not allowed.
                            Preamble
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            How to Apply These Terms to Your New Programs
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 possible use to the public, the best way to achieve this is to make it
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 the "copyright" line and a pointer to where the full notice is found.
    <one line to give the program's name and a brief idea of what it does.>
    Copyright (C) <year>  <name of author>
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    (at your option) any later version.
    This program is distributed in the hope that it will be useful,
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    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.
    You should have received a copy of the GNU General Public License
    along with this program.  If not, see <https://www.gnu.org/licenses/>.
 Also add information on how to contact you by electronic and paper mail.
  If the program does terminal interaction, make it output a short
 notice like this when it starts in an interactive mode:
    <program>  Copyright (C) <year>  <name of author>
    This program comes with ABSOLUTELY NO WARRANTY; for details type `show w'.
    This is free software, and you are welcome to redistribute it
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 The hypothetical commands `show w' and `show c' should show the appropriate
 parts of the General Public License.  Of course, your program's commands
 might be different; for a GUI interface, you would use an "about box".
  You should also get your employer (if you work as a programmer) or school,
 if any, to sign a "copyright disclaimer" for the program, if necessary.
 For more information on this, and how to apply and follow the GNU GPL, see
 <https://www.gnu.org/licenses/>.
  The GNU General Public License does not permit incorporating your program
 into proprietary programs.  If your program is a subroutine library, you
 may consider it more useful to permit linking proprietary applications with
 the library.  If this is what you want to do, use the GNU Lesser General
 Public License instead of this License.  But first, please read
 <https://www.gnu.org/licenses/why-not-lgpl.html>.
--- a/README.md
+++ b/README.md
@@ -2,41 +2,114 @@
 Interact with node streams in object mode using [`Pipes`]!
-## Example
+## Install
 ```purescript
 import Prelude
 import Effect.Aff (launchAff_)
 import Effect (Effect)
 import Effect.Class (liftEffect)
 import Effect.Console (log)
 import Pipes.Prelude ((>->))
 import Pipes.Prelude as Pipes
 import Pipes.Core as Pipes.Core
 import Pipes.Node.FS.Stream as FS
 import Pipes.Node.Zlib as Zlib
 import Pipes.CSV.Parse as CSV.Parse
 -- == my-zipped-data.csv ==
 -- id,foo,is_deleted
 -- 1,hello,f
 -- 2,goodbye,t
 -- Logs:
 -- {id: 1, foo: "hello", is_deleted: false}
 -- {id: 2, foo: "goodbye", is_deleted: true}
 main :: Effect Unit
 main =
  Pipes.Core.runEffect
    $ FS.createReadStream "my-zipped-data.csv.gz"
        >-> Zlib.gunzip
        >-> CSV.Parse.parse @{id :: Int, foo :: String, is_deleted :: Boolean}
        >-> Pipes.mapM (liftEffect <<< log)
 ```
 ## Installing
 ```bash
 spago install node-stream-pipes
 ```
 ## Usage
 ### Node Streams
 #### Raw Streams
 Raw `objectMode` Node streams are represented in `Node.Stream.Object`:
 - `Writable a` accepts chunks of type `a`
 - `Readable a` emits chunks of type `a`
 - `Transform a b` transforms chunks from `a` to `b`
 Non-Object streams can also be represented with these types; for example an `fs.WriteStream`
 can be coerced to `Writable Buffer` without issue.
 Interop between these types and `Node.Stream` are provided in `Node.Stream.Object`:
 - `unsafeFrom{String,Buffer}{Writable,Readable,Transform}`
 - `unsafeCoerce{Writable,Readable,Transform}`
 #### Pipes
 Streams in `Node.Stream.Object` can be converted to `Producer`s, `Consumer`s and `Pipe`s with `Pipes.Node.Stream`:
 - `fromReadable :: forall a. <Readable a> -> Producer (Maybe a) <Aff> Unit`
 - `fromWritable :: forall a. <Writable a> -> Consumer (Maybe a) <Aff> Unit`
 - `fromTransform :: forall a b. <Transform a b> -> Pipe (Maybe a) (Maybe b) <Aff> Unit`
 #### EOS Marker
 Normally, pipe computations will not be executed once any computation in a pipeline exits.
 To allow for resource cleanup and awareness that the stream is about to close,
 `Maybe a` is used occasionally in this package as an End-of-Stream marker:
 ```purescript
 -- foo.txt is "hello, world!\n"
 chunks <- Pipes.Collect.toArray $ Pipes.FS.read "foo.txt" >-> Pipes.Node.Stream.inEOS (Pipes.Buffer.toString UTF8)
 chunks `shouldEqual` [Just "hello, world!\n", Nothing]
 ```
 Pipes from `a -> b` unaware of EOS can be lifted to `Maybe a -> Maybe b` with `Pipes.Node.Stream.inEOS`.
 Producers of `Maybe a` can drop the EOS marker and emit `a` with `Pipes.Node.Stream.unEOS`.
 Producers of `a` can have an EOS marker added with `Pipes.Node.Stream.withEOS`.
 #### Example
 `Pipes.PassThrough.js`
 ```javascript
 import {PassThrough} from 'stream'
 export const makePassThrough = () => new PassThrough()
 ```
 `Pipes.PassThrough.purs`
 ```purescript
 module Pipes.PassThrough where
 import Prelude
 import Effect (Effect)
 import Effect.Class (liftEffect)
 import Effect.Aff (Aff)
 import Pipes.Core (Pipe)
 import Node.Stream.Object as ObjectStream
 import Pipes.Node.Stream as Pipes.Node.Stream
 type PassThroughStream a = ObjectStream.Transform a a
 foreign import makeRaw :: Effect PassThroughStream
 passThrough :: forall a. Pipe a a Aff Unit
 passThrough = do
  raw <- liftEffect $ makeRaw
  Pipes.Node.Stream.fromTransform raw
 ```
 ### Utilities
 This package provides utilities that explicitly use `MonadRec` to ensure stack-safety
 when dealing with producers of large amounts of data.
 - `Pipes.Collect` provides stack-safe utilities for executing a pipeline and collecting results into a collection, `Buffer`, `Monoid` etc.
 - `Pipes.Construct` provides stack-safe utilities for creating producers from in-memory collections.
 - `Pipes.Util` provides some miscellaneous utilities missing from `pipes`.
 ### Zlib
 Pipes for compression & decompression using `zlib` are provided in `Pipes.Node.Zlib`.
 ### FS
 Read files with:
 - `Pipes.Node.FS.read <path>`
 - `Pipes.Node.FS.read' <WriteStreamOptions> <path>`
 ```purescript
 Pipes.Collect.toStringWith UTF8 $ Pipes.Node.FS.read "foo.txt" >-> Pipes.Stream.unEOS
 ```
 Write files with:
 - `Pipes.Node.FS.write' <WriteStreamOptions> <path>`
 - `Pipes.Node.FS.trunc <path>`
 - `Pipes.Node.FS.create <path>`
 - `Pipes.Node.FS.append <path>`
 ```purescript
  Pipes.Stream.withEOS (
    Pipes.Construct.eachArray ["id,name", "1,henry", "2,suzie"]
    >-> Pipes.Util.intersperse "\n"
    >-> Pipes.Buffer.fromString UTF8
  )
  >-> Pipes.Node.FS.create "foo.csv"
 ```
 [`Pipes`]: https://pursuit.purescript.org/packages/purescript-pipes/8.0.0
--- a/bun.lockb
+++ b/bun.lockb
--- a/package.json
+++ b/package.json
@@ -1,12 +1,13 @@
 {
  "name": "purescript-node-stream-pipes",
-  "version": "v1.3.2",
+  "version": "v2.1.6",
  "type": "module",
  "dependencies": {
-    "csv-parse": "^5.5.5",
+    "csv-parse": "^5.5.6",
-    "csv-stringify": "^6.4.6"
+    "csv-stringify": "^6.5.0"
  },
  "devDependencies": {
    "cbor-x": "^1.5.9",
    "typescript": "^5.4.5"
  }
 }
--- a/spago.lock
+++ b/spago.lock
@@ -5,21 +5,26 @@ workspace:
      dependencies:
        - aff: ">=7.1.0 <8.0.0"
        - arrays: ">=7.3.0 <8.0.0"
        - console: ">=6.1.0 <7.0.0"
        - control: ">=6.0.0 <7.0.0"
        - datetime: ">=6.1.0 <7.0.0"
        - effect: ">=4.0.0 <5.0.0"
        - either: ">=6.1.0 <7.0.0"
        - exceptions: ">=6.0.0 <7.0.0"
        - foldable-traversable: ">=6.0.0 <7.0.0"
        - foreign-object: ">=4.1.0 <5.0.0"
        - fork: ">=6.0.0 <7.0.0"
        - lists: ">=7.0.0 <8.0.0"
        - maybe: ">=6.0.0 <7.0.0"
        - mmorph: ">=7.0.0 <8.0.0"
        - newtype: ">=5.0.0 <6.0.0"
        - node-buffer: ">=9.0.0 <10.0.0"
        - node-event-emitter: ">=3.0.0 <4.0.0"
-        - node-fs: ">=9.1.0 <10.0.0"
+        - node-fs: ">=9.1.0 <9.2.0"
        - node-path: ">=5.0.0 <6.0.0"
        - node-streams: ">=9.0.0 <10.0.0"
        - node-zlib: ">=0.4.0 <0.5.0"
        - now: ">=6.0.0 <7.0.0"
        - ordered-collections: ">=3.2.0 <4.0.0"
        - parallel: ">=6.0.0 <7.0.0"
        - pipes: ">=8.0.0 <9.0.0"
@@ -297,8 +302,8 @@ packages:
      - unfoldable
  exceptions:
    type: registry
-    version: 6.0.0
+    version: 6.1.0
-    integrity: sha256-y/xTAEIZIARCE+50/u1di0ncebJ+CIwNOLswyOWzMTw=
+    integrity: sha256-K0T89IHtF3vBY7eSAO7eDOqSb2J9kZGAcDN5+IKsF8E=
    dependencies:
      - effect
      - either
@@ -862,8 +867,8 @@ packages:
      - refs
  transformers:
    type: registry
-    version: 6.0.0
+    version: 6.1.0
-    integrity: sha256-Pzw40HjthX77tdPAYzjx43LK3X5Bb7ZspYAp27wksFA=
+    integrity: sha256-3Bm+Z6tsC/paG888XkywDngJ2JMos+JfOhRlkVfb7gI=
    dependencies:
      - control
      - distributive
@@ -876,6 +881,7 @@ packages:
      - maybe
      - newtype
      - prelude
      - st
      - tailrec
      - tuples
      - unfoldable
--- a/spago.yaml
+++ b/spago.yaml
@@ -1,7 +1,7 @@
 package:
  name: node-stream-pipes
  publish:
-    version: '1.3.2'
+    version: '2.1.6'
    license: 'GPL-3.0-or-later'
    location:
      githubOwner: 'cakekindel'
@@ -12,21 +12,26 @@ package:
  dependencies:
    - aff: ">=7.1.0 <8.0.0"
    - arrays: ">=7.3.0 <8.0.0"
    - console: ">=6.1.0 <7.0.0"
    - control: ">=6.0.0 <7.0.0"
    - datetime: ">=6.1.0 <7.0.0"
    - effect: ">=4.0.0 <5.0.0"
    - either: ">=6.1.0 <7.0.0"
    - exceptions: ">=6.0.0 <7.0.0"
    - foldable-traversable: ">=6.0.0 <7.0.0"
    - foreign-object: ">=4.1.0 <5.0.0"
    - fork: ">=6.0.0 <7.0.0"
    - lists: ">=7.0.0 <8.0.0"
    - maybe: ">=6.0.0 <7.0.0"
    - mmorph: ">=7.0.0 <8.0.0"
    - newtype: ">=5.0.0 <6.0.0"
    - node-buffer: ">=9.0.0 <10.0.0"
    - node-event-emitter: ">=3.0.0 <4.0.0"
-    - node-fs: ">=9.1.0 <10.0.0"
+    - node-fs: ">=9.1.0 <9.2.0"
    - node-path: ">=5.0.0 <6.0.0"
    - node-streams: ">=9.0.0 <10.0.0"
    - node-zlib: ">=0.4.0 <0.5.0"
    - now: ">=6.0.0 <7.0.0"
    - ordered-collections: ">=3.2.0 <4.0.0"
    - parallel: ">=6.0.0 <7.0.0"
    - pipes: ">=8.0.0 <9.0.0"
--- a/src/Node.Stream.Object.js
+++ b/src/Node.Stream.Object.js
@@ -3,31 +3,36 @@ import Stream from "stream";
 /** @type {(s: Stream.Readable | Stream.Transform) => () => boolean} */
 export const isReadableImpl = (s) => () => s.readable;
 /** @type {(s: Stream.Readable | Stream.Transform) => () => number} */
 export const readableLengthImpl = (s) => () => s.readableLength;
 /** @type {(s: Stream.Writable | Stream.Readable) => () => boolean} */
 export const isClosedImpl = (s) => () => s.closed;
 /** @type {(s: Stream.Writable | Stream.Transform) => () => boolean} */
 export const isWritableImpl = (s) => () => s.writable;
 /** @type {(s: Stream.Writable | Stream.Transform) => () => boolean} */
 export const needsDrainImpl = (s) => () => s.writableNeedDrain;
 /** @type {(s: Stream.Readable | Stream.Transform) => () => boolean} */
 export const isReadableEndedImpl = (s) => () => s.readableEnded;
 /** @type {(s: Stream.Writable | Stream.Transform) => () => boolean} */
 export const isWritableEndedImpl = (s) => () => s.writableEnded;
 /** @type {(s: Stream.Writable | Stream.Transform) => () => boolean} */
 export const isWritableFinishedImpl = (s) => () => s.writableFinished;
 /** @type {(s: Stream.Writable | Stream.Transform) => () => void} */
 export const endImpl = (s) => () => s.end();
-/** @type {<WriteResult>(o: {ok: WriteResult, wouldBlock: WriteResult, closed: WriteResult}) => (s: Stream.Writable | Stream.Transform) => (a: unknown) => () => WriteResult} */
+/** @type {<WriteResult>(o: {ok: WriteResult, wouldBlock: WriteResult}) => (s: Stream.Writable | Stream.Transform) => (a: unknown) => () => WriteResult} */
 export const writeImpl =
-  ({ ok, wouldBlock, closed }) =>
+  ({ ok, wouldBlock }) =>
  (s) =>
  (a) =>
  () => {
    if (s.closed || s.writableEnded) {
      return closed;
    }
    if (s.write(a)) {
      return ok;
    } else {
@@ -35,15 +40,11 @@ export const writeImpl =
    }
  };
-/** @type {<ReadResult>(o: {just: (_a: unknown) => ReadResult, wouldBlock: ReadResult, closed: ReadResult}) => (s: Stream.Readable | Stream.Transform) => () => ReadResult} */
+/** @type {<ReadResult>(o: {just: (_a: unknown) => ReadResult, wouldBlock: ReadResult}) => (s: Stream.Readable | Stream.Transform) => () => ReadResult} */
 export const readImpl =
-  ({ just, closed, wouldBlock }) =>
+  ({ just, wouldBlock }) =>
  (s) =>
  () => {
    if (s.closed || s.readableEnded) {
      return closed;
    }
    const a = s.read();
    if (a === null) {
      return wouldBlock;
--- a/src/Node.Stream.Object.purs
+++ b/src/Node.Stream.Object.purs
@@ -14,8 +14,9 @@ import Data.Maybe (Maybe(..))
 import Data.Show.Generic (genericShow)
 import Effect (Effect)
 import Effect.Aff (Aff, effectCanceler, makeAff)
 import Effect.Aff as Aff
 import Effect.Class (liftEffect)
-import Effect.Exception (Error)
+import Effect.Exception (Error, error)
 import Effect.Uncurried (mkEffectFn1)
 import Node.Buffer (Buffer)
 import Node.EventEmitter (EventHandle(..))
@@ -26,7 +27,6 @@ import Unsafe.Coerce (unsafeCoerce)
 data ReadResult a
  = ReadWouldBlock
  | ReadClosed
  | ReadJust a
 derive instance Generic (ReadResult a) _
@@ -35,9 +35,12 @@ derive instance Eq a => Eq (ReadResult a)
 instance Show (ReadResult a) where
  show = genericShow <<< map (const "..")
 maybeReadResult :: forall a. ReadResult a -> Maybe a
 maybeReadResult (ReadWouldBlock) = Nothing
 maybeReadResult (ReadJust a) = Just a
 data WriteResult
  = WriteWouldBlock
  | WriteClosed
  | WriteOk
 derive instance Generic WriteResult _
@@ -45,8 +48,8 @@ derive instance Eq WriteResult
 instance Show WriteResult where
  show = genericShow
-type ReadResultFFI a = { closed :: ReadResult a, wouldBlock :: ReadResult a, just :: a -> ReadResult a }
+type ReadResultFFI a = { wouldBlock :: ReadResult a, just :: a -> ReadResult a }
-type WriteResultFFI = { closed :: WriteResult, wouldBlock :: WriteResult, ok :: WriteResult }
+type WriteResultFFI = { wouldBlock :: WriteResult, ok :: WriteResult }
 foreign import data Writable :: Type -> Type
 foreign import data Readable :: Type -> Type
@@ -59,13 +62,16 @@ foreign import isReadableImpl :: forall s. s -> Effect Boolean
 foreign import isWritableImpl :: forall s. s -> Effect Boolean
 foreign import isReadableEndedImpl :: forall s. s -> Effect Boolean
 foreign import isWritableEndedImpl :: forall s. s -> Effect Boolean
 foreign import isWritableFinishedImpl :: forall s. s -> Effect Boolean
 foreign import isClosedImpl :: forall s. s -> Effect Boolean
 foreign import needsDrainImpl :: forall s. s -> Effect Boolean
 foreign import readableLengthImpl :: forall s. s -> Effect Int
 readResultFFI :: forall a. ReadResultFFI a
-readResultFFI = { closed: ReadClosed, wouldBlock: ReadWouldBlock, just: ReadJust }
+readResultFFI = { wouldBlock: ReadWouldBlock, just: ReadJust }
 writeResultFFI :: WriteResultFFI
-writeResultFFI = { closed: WriteClosed, wouldBlock: WriteWouldBlock, ok: WriteOk }
+writeResultFFI = { wouldBlock: WriteWouldBlock, ok: WriteOk }
 class Stream :: Type -> Constraint
 class Stream s where
@@ -81,25 +87,31 @@ else instance Stream s => Stream s where
  isClosed s = isClosed s
 class Stream s <= Read s a | s -> a where
  readableLength :: s -> Effect Int
  isReadable :: s -> Effect Boolean
  isReadableEnded :: s -> Effect Boolean
  read :: s -> Effect (ReadResult a)
 class Stream s <= Write s a | s -> a where
  isWritable :: s -> Effect Boolean
  needsDrain :: s -> Effect Boolean
  isWritableEnded :: s -> Effect Boolean
  isWritableFinished :: s -> Effect Boolean
  write :: s -> a -> Effect WriteResult
  end :: s -> Effect Unit
 instance Read (Readable a) a where
  readableLength = readableLengthImpl
  isReadable = isReadableImpl
  isReadableEnded = isReadableEndedImpl
  read = readImpl readResultFFI
 else instance Read (Transform a b) b where
  readableLength = readableLengthImpl
  isReadable = isReadableImpl
  isReadableEnded = isReadableEndedImpl
  read = readImpl readResultFFI
 else instance (Read s a) => Read s a where
  readableLength = readableLengthImpl
  isReadable = isReadableImpl
  isReadableEnded = isReadableEndedImpl
  read s = read s
@@ -107,18 +119,24 @@ else instance (Read s a) => Read s a where
 instance Write (Writable a) a where
  isWritable = isWritableImpl
  isWritableEnded = isWritableEndedImpl
  isWritableFinished = isWritableFinishedImpl
  write s = writeImpl writeResultFFI s
  end = endImpl
  needsDrain = needsDrainImpl
 else instance Write (Transform a b) a where
  isWritable = isWritableImpl
  isWritableEnded = isWritableEndedImpl
  isWritableFinished = isWritableFinishedImpl
  write s = writeImpl writeResultFFI s
  end = endImpl
  needsDrain = needsDrainImpl
 else instance (Write s a) => Write s a where
  isWritable = isWritableImpl
  isWritableEnded = isWritableEndedImpl
  isWritableFinished = isWritableFinishedImpl
  write s a = write s a
  end s = end s
  needsDrain = needsDrainImpl
 withErrorST :: forall s. Stream s => s -> Effect { cancel :: Effect Unit, error :: STRef Global (Maybe Error) }
 withErrorST s = do
@@ -126,42 +144,82 @@ withErrorST s = do
  cancel <- flip (Event.once errorH) s \e -> void $ liftST $ STRef.write (Just e) error
  pure { error, cancel }
-fromBufferReadable :: forall r. Stream.Readable r -> Readable Buffer
+unsafeCoerceWritable :: forall r a. Stream.Writable r -> Writable a
-fromBufferReadable = unsafeCoerce
+unsafeCoerceWritable = unsafeCoerce
-fromBufferTransform :: Stream.Duplex -> Transform Buffer Buffer
+unsafeCoerceReadable :: forall r a. Stream.Readable r -> Readable a
-fromBufferTransform = unsafeCoerce
+unsafeCoerceReadable = unsafeCoerce
-fromBufferWritable :: forall r. Stream.Writable r -> Writable Buffer
+unsafeCoerceTransform :: forall a b. Stream.Duplex -> Transform a b
-fromBufferWritable = unsafeCoerce
+unsafeCoerceTransform = unsafeCoerce
-fromStringReadable :: forall r. Stream.Readable r -> Readable String
+unsafeFromBufferReadable :: forall r. Stream.Readable r -> Readable Buffer
-fromStringReadable = unsafeCoerce
+unsafeFromBufferReadable = unsafeCoerce
-fromStringTransform :: Stream.Duplex -> Transform String String
+unsafeFromBufferTransform :: forall a. Stream.Duplex -> Transform Buffer a
-fromStringTransform = unsafeCoerce
+unsafeFromBufferTransform = unsafeCoerce
-fromStringWritable :: forall r. Stream.Writable r -> Writable String
+unsafeFromBufferWritable :: forall r. Stream.Writable r -> Writable Buffer
-fromStringWritable = unsafeCoerce
+unsafeFromBufferWritable = unsafeCoerce
 unsafeFromStringReadable :: forall r. Stream.Readable r -> Readable String
 unsafeFromStringReadable = unsafeCoerce
 unsafeFromStringTransform :: forall a. Stream.Duplex -> Transform String a
 unsafeFromStringTransform = unsafeCoerce
 unsafeFromStringWritable :: forall r. Stream.Writable r -> Writable String
 unsafeFromStringWritable = unsafeCoerce
 awaitReadableOrClosed :: forall s a. Read s a => s -> Aff Unit
-awaitReadableOrClosed s = do
+awaitReadableOrClosed s = Aff.supervise do
  fiber <-
    Aff.forkAff
    $ parOneOf
      [ onceAff0 readableH s $> Right unit
      , onceAff0 closeH s $> Right unit
      , Left <$> onceAff1 errorH s
      ]
  closed <- liftEffect $ isClosed s
-  ended <- liftEffect $ isReadableEnded s
+  readEnded <- liftEffect $ isReadableEnded s
  readable <- liftEffect $ isReadable s
-  when (not ended && not closed && not readable)
+  length <- liftEffect $ readableLength s
-    $ liftEither =<< parOneOf [ onceAff0 readableH s $> Right unit, onceAff0 closeH s $> Right unit, Left <$> onceAff1 errorH s ]
+  if (not closed && not readEnded && readable && length == 0) then
    liftEither =<< Aff.joinFiber fiber
  else
    Aff.killFiber (error "") fiber
 awaitFinished :: forall s a. Write s a => s -> Aff Unit
-awaitFinished s = onceAff0 finishH s
+awaitFinished s = Aff.supervise do
  fiber <-
    Aff.forkAff
    $ parOneOf
        [ onceAff0 finishH s $> Right unit
        , Left <$> onceAff1 errorH s
        ]
  finished <- liftEffect $ isWritableFinished s
  if not finished then
    liftEither =<< Aff.joinFiber fiber
  else
    Aff.killFiber (error "") fiber
 awaitWritableOrClosed :: forall s a. Write s a => s -> Aff Unit
-awaitWritableOrClosed s = do
+awaitWritableOrClosed s = Aff.supervise do
  fiber <-
    Aff.forkAff
    $ parOneOf
        [ onceAff0 drainH s $> Right unit
        , onceAff0 closeH s $> Right unit
        , Left <$> onceAff1 errorH s
        ]
  closed <- liftEffect $ isClosed s
-  ended <- liftEffect $ isWritableEnded s
+  writeEnded <- liftEffect $ isWritableEnded s
  writable <- liftEffect $ isWritable s
-  when (not ended && not closed && not writable)
+  needsDrain <- liftEffect $ needsDrain s
-    $ liftEither =<< parOneOf [ onceAff0 drainH s $> Right unit, onceAff0 closeH s $> Right unit, Left <$> onceAff1 errorH s ]
+  if not closed && not writeEnded && writable && needsDrain then
    liftEither =<< Aff.joinFiber fiber
  else
    Aff.killFiber (error "") fiber
 onceAff0 :: forall e. EventHandle0 e -> e -> Aff Unit
 onceAff0 h emitter = makeAff \res -> do
--- a/src/Pipes.Async.purs
+++ b/src/Pipes.Async.purs
@@ -0,0 +1,368 @@
 module Pipes.Async where
 import Prelude hiding (join)
 import Control.Alternative (class Alternative, empty, guard)
 import Control.Monad.Cont (class MonadTrans)
 import Control.Monad.Error.Class (class MonadError, class MonadThrow, catchError, throwError)
 import Control.Monad.Except (ExceptT, runExceptT)
 import Control.Monad.Fork.Class (class MonadBracket, class MonadFork, fork)
 import Control.Monad.Maybe.Trans (MaybeT(..), runMaybeT)
 import Control.Monad.Morph (class MFunctor, hoist)
 import Control.Monad.Rec.Class (class MonadRec, Step(..), tailRecM)
 import Control.Monad.ST.Class (liftST)
 import Control.Monad.ST.Ref (STRef)
 import Control.Monad.ST.Ref as ST.Ref
 import Control.Monad.Trans.Class (lift)
 import Control.Parallel (class Parallel, parOneOf)
 import Data.Array as Array
 import Data.DateTime.Instant as Instant
 import Data.Either (Either(..), either)
 import Data.Foldable (class Foldable, fold)
 import Data.Generic.Rep (class Generic)
 import Data.Maybe (Maybe(..), fromMaybe, isNothing)
 import Data.Newtype (unwrap)
 import Data.Show.Generic (genericShow)
 import Data.Time.Duration (Milliseconds)
 import Data.Traversable (class Traversable, traverse, traverse_)
 import Data.Tuple.Nested (type (/\), (/\))
 import Effect.Aff.Class (class MonadAff, liftAff)
 import Effect.Class (class MonadEffect, liftEffect)
 import Effect.Console (log)
 import Effect.Now as Now
 import Pipes (await, yield)
 import Pipes.Collect as Collect
 import Pipes.Core (Pipe, Proxy, Producer)
 data WriteSignal
  = WriteSignalOk
  | WriteSignalEnded
 derive instance Generic WriteSignal _
 derive instance Eq WriteSignal
 derive instance Ord WriteSignal
 instance Show WriteSignal where show = genericShow
 instance Discard WriteSignal where
  discard = bind
 data ReadSignal
  = ReadSignalOk
  | ReadSignalEnded
 derive instance Generic ReadSignal _
 derive instance Eq ReadSignal
 derive instance Ord ReadSignal
 instance Show ReadSignal where show = genericShow
 instance Discard ReadSignal where
  discard = bind
 data WriteResult
  = WriteAgain
  | WriteNeedsDrain
  | WriteEnded
 derive instance Generic WriteResult _
 derive instance Eq WriteResult
 derive instance Ord WriteResult
 instance Show WriteResult where show = genericShow
 data ReadResult a
  = ReadOk a
  | ReadWouldBlock
 derive instance Generic (ReadResult a) _
 derive instance Eq a => Eq (ReadResult a)
 derive instance Ord a => Ord (ReadResult a)
 derive instance Functor ReadResult
 derive instance Foldable ReadResult
 derive instance Traversable ReadResult
 instance Show a => Show (ReadResult a) where show = genericShow
 type AsyncIO a b m r =
  { write :: a -> m WriteResult
  , read :: m (ReadResult b)
  , awaitWrite :: m WriteSignal
  , awaitRead :: m ReadSignal
  }
  /\ AsyncPipe a b m r
 -- | An `AsyncPipe` is a `Pipe`-like struct that allows
 -- | concurrently reading from a `Producer` and writing to a `Consumer`.
 -- |
 -- | An implementation of `AsyncPipe` for Node `Transform` streams
 -- | is provided in `Pipes.Node.Stream`.
 data AsyncPipe a b m r
  -- | A pure return value
  = Pure r
  -- | An `AsyncPipe` behind a computation
  | M (m (AsyncPipe a b m r))
  -- | Interface to write & read from the backing resource
  | AsyncIO (AsyncIO a b m r)
 -- | Modify request / response types
 mapIO :: forall aa ab ba bb m r. Monad m => (ab -> aa) -> (ba -> bb) -> AsyncPipe aa ba m r -> AsyncPipe ab bb m r
 mapIO _ _ (Pure a) = Pure a
 mapIO a b (M m) = M $ mapIO a b <$> m
 mapIO a b (AsyncIO ({write, awaitWrite, read, awaitRead} /\ m)) =
  AsyncIO $ {write: write <<< a, awaitWrite, read: map b <$> read, awaitRead} /\ mapIO a b m
 -- | Modify request / response types
 bindIO :: forall aa ab ba bb m r. Monad m => (ab -> m aa) -> (ba -> m bb) -> AsyncPipe aa ba m r -> AsyncPipe ab bb m r
 bindIO _ _ (Pure a) = Pure a
 bindIO a b (M m) = M $ bindIO a b <$> m
 bindIO a b (AsyncIO ({write, awaitWrite, read, awaitRead} /\ m)) =
  AsyncIO $ {write: flip bind write <<< a, awaitWrite, read: traverse b =<< read, awaitRead} /\ bindIO a b m
 -- | Remove the `AsyncPipe` wrapper by discarding the IO
 stripIO :: forall a b m r. Monad m => AsyncPipe a b m r -> m r
 stripIO (Pure r) = pure r
 stripIO (M m) = m >>= stripIO
 stripIO (AsyncIO (_ /\ m)) = stripIO m
 -- | Execute the `AsyncPipe` monad stack until `AsyncIO` is reached (if any)
 getAsyncIO :: forall a b m r. Monad m => AsyncPipe a b m r -> m (Maybe (AsyncIO a b m r))
 getAsyncIO (AsyncIO a) = pure $ Just a
 getAsyncIO (M m) = m >>= getAsyncIO
 getAsyncIO (Pure _) = pure Nothing
 instance MonadTrans (AsyncPipe a b) where
  lift = M <<< map Pure
 instance MFunctor (AsyncPipe a b) where
  hoist _ (Pure a) = Pure a
  hoist f (M m) = M $ f $ hoist f <$> m
  hoist f (AsyncIO ({read, write, awaitWrite, awaitRead} /\ m)) =
    AsyncIO
      $ { read: f read
        , write: f <<< write
        , awaitWrite: f awaitWrite
        , awaitRead: f awaitRead
        }
        /\ hoist f m
 instance Monad m => Functor (AsyncPipe a b m) where
  map f (Pure r) = Pure $ f r
  map f (M m) = M $ map f <$> m
  map f (AsyncIO (io /\ m)) = AsyncIO $ io /\ (f <$> m)
 instance Monad m => Apply (AsyncPipe a b m) where
  apply (Pure f) ma = f <$> ma
  apply (M mf) ma = M $ (_ <*> ma) <$> mf
  apply (AsyncIO (io /\ mf)) ma = AsyncIO $ io /\ (mf <*> ma)
 instance Monad m => Applicative (AsyncPipe a b m) where
  pure = Pure
 instance Monad m => Bind (AsyncPipe a b m) where
  bind (Pure a) f = f a
  bind (M ma) f = M $ (_ >>= f) <$> ma
  bind (AsyncIO (io /\ m)) f = AsyncIO $ io /\ (m >>= f)
 instance Monad m => Monad (AsyncPipe a b m)
 instance MonadThrow e m => MonadThrow e (AsyncPipe a b m) where
  throwError = lift <<< throwError
 instance MonadError e m => MonadError e (AsyncPipe a b m) where
  catchError m f = lift $ catchError (stripIO m) (stripIO <<< f)
 instance MonadEffect m => MonadEffect (AsyncPipe a b m) where
  liftEffect = lift <<< liftEffect
 instance MonadAff m => MonadAff (AsyncPipe a b m) where
  liftAff = lift <<< liftAff
 -- | Wraps all fields of an `AsyncPipe` with logging to debug
 -- | behavior and timing.
 debug :: forall a b m r. MonadAff m => String -> AsyncPipe (Maybe a) (Maybe b) m r -> AsyncPipe (Maybe a) (Maybe b) m r
 debug c m =
  let
    logL :: forall m'. MonadEffect m' => _ -> m' Unit
    logL msg = liftEffect $ log $ "[" <> c <> "] " <> msg
    logR :: forall m'. MonadEffect m' => _ -> m' Unit
    logR msg = liftEffect $ log $ "[" <> c <> "] " <> fold (Array.replicate 20 " ") <> msg
    time :: forall m' a'. MonadEffect m' => m' a' -> m' (Milliseconds /\ a')
    time ma = do
      start <- liftEffect Now.now
      a <- ma
      end <- liftEffect Now.now
      pure $ (end `Instant.diff` start) /\ a
  in
    flip bind (fromMaybe m)
    $ runMaybeT do
      (io /\ done') <- MaybeT $ lift $ getAsyncIO m
      let
        write a = do
          logL "write >"
          elapsed /\ w <- time $ io.write a
          logL $ "< write " <> show w <> " (" <> show (unwrap elapsed) <> "ms)"
          pure w
        read = do
          logR "read >"
          elapsed /\ r <- time $ io.read
          logR $ "< read " <> show (map (const unit) <$> r) <> " (" <> show (unwrap elapsed) <> "ms)"
          pure r
        awaitWrite = do
          logL "awaitWrite >"
          elapsed /\ w <- time $ io.awaitWrite
          logL $ "< awaitWrite " <> show w <> " (" <> show (unwrap elapsed) <> "ms)"
          pure w
        awaitRead = do
          logR "awaitRead >"
          elapsed /\ r <- time $ io.awaitRead
          logR $ "< awaitRead " <> show r <> " (" <> show (unwrap elapsed) <> "ms)"
          pure r
        done = do
          logL "done >"
          elapsed /\ r <- time done'
          logL $ "< done (" <> show (unwrap elapsed) <> "ms)"
          pure r
      pure $ AsyncIO $ {write, read, awaitWrite, awaitRead} /\ done
 -- | Convert an `AsyncPipe` to a regular `Pipe`.
 -- |
 -- | Rather than two concurrently-running halves (producer & consumer),
 -- | this requires the `AsyncPipe` to occasionally stop `await`ing data
 -- | written by the upstream `Producer` so that it can `yield` to the downstream `Consumer`.
 -- |
 -- | This implementation chooses to prioritize `yield`ing data to the `Consumer` over
 -- | `await`ing written chunks.
 -- |
 -- | Note that using this limits the potential parallelism of the entire pipeline, ex:
 -- |
 -- | ```purs
 -- | Pipe.FS.read "foo.csv"        -- read
 -- |   >-> sync Pipe.CSV.parse     -- parse
 -- |   >-> sync Pipe.CBOR.encode   -- encode
 -- |   >-> Pipe.FS.write "foo.bin" -- write
 -- | ```
 -- |
 -- | In the above example, this is what happens when the pipeline
 -- | is executed:
 -- | 1. `write` asks `encode` "do you have any data yet?" (fast)
 -- | 1. `encode` asks `parse` "do you have any data yet?" (fast)
 -- | 1. `parse` asks `read` "do you have any data yet?" (fast)
 -- | 1. `read` passes 1 chunk to `parse` (fast)
 -- | 1. `parse` blocks until the chunk is parsed (slow)
 -- | 1. `parse` passes 1 chunk to `encode` (fast)
 -- | 1. `encode` blocks until the chunk is encoded (slow)
 -- | 1. `write` writes the block (fast)
 -- |
 -- | For larger workloads, changing this to use `asyncPipe` would be preferable, ex:
 -- | ```purs
 -- | Pipe.FS.read "foo.csv"        -- read
 -- |   >-/-> Pipe.CSV.parse        -- parse
 -- |   >-/-> Pipe.CBOR.encode      -- encode
 -- |   >-> Pipe.FS.write "foo.bin" -- write
 -- | ```
 -- |
 -- | With this change:
 -- | * `read` will pass chunks to `parse` as fast as `parse` allows
 -- | * `parse` will parse chunks and yield them to `encode` as soon as they're ready
 -- | * `encode` will encode chunks and yield them to `write` as soon as they're ready
 sync :: forall a b f p e m r. MonadError e m => Alternative p => Parallel p m => MonadFork f m => MonadAff m => AsyncPipe (Maybe a) (Maybe b) m r -> Pipe (Maybe a) (Maybe b) m r
 sync m =
  let
    liftPipe :: forall r'. (Proxy _ _ _ _ m) r' -> ExceptT (Step _ _) (Proxy _ _ _ _ m) r'
    liftPipe = lift
    liftM :: forall r'. m r' -> ExceptT (Step _ _) (Proxy _ _ _ _ m) r'
    liftM = liftPipe <<< lift
  in
  lift (getAsyncIO m) >>=
    case _ of
      Nothing -> lift $ stripIO m
      Just ({write, awaitWrite, read, awaitRead} /\ done) ->
         let
           awaitRW onR onW =
             liftM (parOneOf [Right <$> awaitWrite, Left <$> awaitRead])
             >>= either (const onR) onW
           wSignal WriteSignalOk = WriteAgain
           wSignal WriteSignalEnded = WriteEnded
           tailRecEarly f a = tailRecM (map (either identity identity) <<< runExceptT <<< f) a
           continue a = throwError (Loop a)
           break = (Done <$> liftM (stripIO done)) >>= throwError
         in do
           flip tailRecEarly WriteAgain \writable -> do
             rb <- liftM read
             case rb of
               ReadWouldBlock
                 | writable == WriteEnded -> liftM awaitRead *> continue writable
                 | writable == WriteNeedsDrain -> awaitRW (continue writable) (continue <<< wSignal)
                 | otherwise -> pure unit
               ReadOk (Just b) -> liftPipe (yield $ Just b) *> continue writable
               ReadOk Nothing -> liftPipe (yield Nothing) *> break
             when (writable /= WriteAgain) $ continue writable
             a <- liftPipe await
             writable' <- liftM $ write a
             when (isNothing a) $ continue WriteEnded
             pure $ Loop writable'
 -- | Implementation of `(>-/->)`
 -- |
 -- | In the current `MonadFork` "thread", read data from the `AsyncPipe` as it
 -- | is yielded and `yield` to the downstream `Consumer`.
 -- |
 -- | Concurrently, in a separate thread, read data from the upstream `Producer`
 -- | and write to the `AsyncPipe` at max throughput.
 -- |
 -- | If the producing half fails, the error is caught and rethrown.
 -- |
 -- | If the consuming half fails, the error is caught, the producing half is killed, and the error is rethrown.
 pipeAsync
  :: forall e f m a b
   . MonadRec m
  => MonadAff m
  => MonadBracket e f m
  => Producer (Maybe a) m Unit
  -> AsyncPipe (Maybe a) (Maybe b) m Unit
  -> Producer (Maybe b) m Unit
 pipeAsync prod m =
  lift (getAsyncIO m)
    >>= case _ of
          Nothing -> pure unit
          Just ({write, read, awaitWrite, awaitRead} /\ done) -> do
            errST :: STRef _ (Maybe e) <- lift $ liftEffect $ liftST $ ST.Ref.new Nothing
            killST :: STRef _ Boolean <- lift $ liftEffect $ liftST $ ST.Ref.new false
            let
              killThread = void $ liftEffect $ liftST $ ST.Ref.write true killST
              threadKilled = liftEffect $ liftST $ ST.Ref.read killST
              putThreadError = void <<< liftEffect <<< liftST <<< flip ST.Ref.write errST <<< Just
              getThreadError = liftEffect $ liftST $ ST.Ref.read errST
              rx a = do
                killed <- threadKilled
                guard $ not killed
                w <- lift $ write a
                case w of
                  WriteNeedsDrain -> lift $ void awaitWrite
                  WriteEnded -> empty
                  WriteAgain -> pure unit
              spawn = lift <<< fork <<< flip catchError putThreadError
            _thread <- spawn $ void $ runMaybeT $ Collect.foreach rx (hoist lift prod)
            flip tailRecM unit $ const do
              getThreadError >>= traverse_ throwError
              rb <- lift read
              case rb of
                ReadOk (Just b) -> yield (Just b) $> Loop unit
                ReadOk Nothing -> killThread *> yield Nothing $> Done unit
                ReadWouldBlock -> void (lift awaitRead) $> Loop unit
            lift $ stripIO done
 infixl 7 pipeAsync as >-/->
--- a/src/Pipes.CSV.Parse.purs
+++ b/src/Pipes.CSV.Parse.purs
@@ -1 +0,0 @@
 module Pipes.CSV.Parse where
--- a/src/Pipes.Collect.purs
+++ b/src/Pipes.Collect.purs
@@ -12,11 +12,15 @@ import Data.List (List)
 import Data.List as List
 import Data.Map (Map)
 import Data.Map as Map
 import Data.Maybe (Maybe(..), maybe)
 import Data.Tuple.Nested (type (/\), (/\))
 import Effect.Class (class MonadEffect, liftEffect)
 import Foreign.Object (Object)
 import Foreign.Object.ST as Object.ST
 import Foreign.Object.ST.Unsafe as Object.ST.Unsafe
 import Node.Buffer (Buffer)
 import Node.Buffer as Buffer
 import Node.Encoding (Encoding)
 import Pipes.Core (Producer)
 import Pipes.Internal (Proxy(..))
@@ -44,6 +48,30 @@ fold f b0 p0 = traverse (\b a -> pure $ f b a) b0 p0
 foreach :: forall a m. MonadRec m => (a -> m Unit) -> Producer a m Unit -> m Unit
 foreach f p0 = traverse (\_ a -> f a) unit p0
 -- | `append` all emitted values to `mempty`
 toMonoid :: forall a m. Monoid a => MonadRec m => MonadEffect m => Producer a m Unit -> m a
 toMonoid = fold (<>) mempty
 -- | Concatenate all buffers to a single buffer, then decode with the
 -- | provided encoding.
 toStringWith :: forall m. MonadRec m => MonadEffect m => Encoding -> Producer Buffer m Unit -> m String
 toStringWith enc = (liftEffect <<< Buffer.toString enc) <=< toBuffer
 -- | Concatenate all produced buffers to a single buffer
 toBuffer :: forall m. MonadRec m => MonadEffect m => Producer Buffer m Unit -> m Buffer
 toBuffer p =
  (liftEffect <<< maybe (Buffer.alloc 0) pure)
    =<< traverse
      ( flip \b ->
          case _ of
            Just acc -> do
              new <- liftEffect $ Buffer.concat [ acc, b ]
              pure $ Just new
            _ -> pure $ Just b
      )
      Nothing
      p
 -- | Collect all values from a `Producer` into an array.
 toArray :: forall a m. MonadRec m => MonadEffect m => Producer a m Unit -> m (Array a)
 toArray p = do
@@ -52,9 +80,18 @@ toArray p = do
  liftEffect $ liftST $ Array.ST.unsafeFreeze st
 -- | Collect all values from a `Producer` into a list.
 -- |
 -- | Reverses the list after collecting, so that values will be
 -- | in the order they were emitted.
 toList :: forall a m. MonadRec m => MonadEffect m => Producer a m Unit -> m (List a)
 toList = map List.reverse <<< fold (flip List.Cons) List.Nil
 -- | Collect all values from a `Producer` into a list.
 -- |
 -- | Does not reverse the list after collecting.
 toListRev :: forall a m. MonadRec m => MonadEffect m => Producer a m Unit -> m (List a)
 toListRev = map List.reverse <<< fold (flip List.Cons) List.Nil
 -- | Collect all values from a `Producer` into a Javascript Object.
 toObject :: forall a m. MonadRec m => MonadEffect m => Producer (String /\ a) m Unit -> m (Object a)
 toObject p = do
--- a/src/Pipes.Node.FS.purs
+++ b/src/Pipes.Node.FS.purs
@@ -23,7 +23,7 @@ import Prim.Row (class Union)
 -- |
 -- | See `Pipes.Node.Stream.withEOS` for converting `Producer a`
 -- | into `Producer (Maybe a)`, emitting `Nothing` before exiting.
-write
+write'
  :: forall r trash m
   . Union r trash WriteStreamOptions
  => MonadAff m
@@ -31,27 +31,27 @@ write
  => Record r
  -> FilePath
  -> Consumer (Maybe Buffer) m Unit
-write o p = do
+write' o p = do
  w <- liftEffect $ FS.Stream.createWriteStream' p o
-  fromWritable $ O.fromBufferWritable w
+  fromWritable $ O.unsafeCoerceWritable w
 -- | Open a file in write mode, failing if the file already exists.
 -- |
-- | `write {flags: "wx"}`
+-- | `write' {flags: "wx"}`
 create :: forall m. MonadAff m => MonadThrow Error m => FilePath -> Consumer (Maybe Buffer) m Unit
-create = write { flags: "wx" }
+create = write' { flags: "wx" }
 -- | Open a file in write mode, truncating it if the file already exists.
 -- |
-- | `write {flags: "w"}`
+-- | `write' {flags: "w"}`
-truncate :: forall m. MonadAff m => MonadThrow Error m => FilePath -> Consumer (Maybe Buffer) m Unit
+trunc :: forall m. MonadAff m => MonadThrow Error m => FilePath -> Consumer (Maybe Buffer) m Unit
-truncate = write { flags: "w" }
+trunc = write' { flags: "w" }
 -- | Open a file in write mode, appending written contents if the file already exists.
 -- |
-- | `write {flags: "a"}`
+-- | `write' {flags: "a"}`
 append :: forall m. MonadAff m => MonadThrow Error m => FilePath -> Consumer (Maybe Buffer) m Unit
-append = write { flags: "a" }
+append = write' { flags: "a" }
 -- | Creates a `fs.Readable` stream for the file at the given path.
 -- |
@@ -60,7 +60,7 @@ append = write { flags: "a" }
 read :: forall m. MonadAff m => MonadThrow Error m => FilePath -> Producer (Maybe Buffer) m Unit
 read p = do
  r <- liftEffect $ FS.Stream.createReadStream p
-  fromReadable $ O.fromBufferReadable r
+  fromReadable $ O.unsafeCoerceReadable r
 -- | Creates a `fs.Readable` stream for the file at the given path.
 -- |
@@ -76,4 +76,4 @@ read'
  -> Producer (Maybe Buffer) m Unit
 read' opts p = do
  r <- liftEffect $ FS.Stream.createReadStream' p opts
-  fromReadable $ O.fromBufferReadable r
+  fromReadable $ O.unsafeCoerceReadable r
--- a/src/Pipes.Node.Stream.purs
+++ b/src/Pipes.Node.Stream.purs
@@ -1,25 +1,27 @@
 module Pipes.Node.Stream where
-import Prelude
+import Prelude hiding (join)
 import Control.Monad.Error.Class (class MonadThrow, throwError)
 import Control.Monad.Rec.Class (class MonadRec, Step(..), tailRecM)
 import Control.Monad.ST.Class (liftST)
 import Control.Monad.ST.Ref as ST.Ref
 import Control.Monad.ST.Ref as STRef
 import Control.Monad.Trans.Class (lift)
-import Data.Maybe (Maybe(..))
+import Data.Maybe (Maybe(..), maybe)
-import Data.Newtype (wrap)
+import Data.Traversable (for_, traverse_)
 import Data.Traversable (for_)
 import Data.Tuple.Nested ((/\))
-import Effect.Aff (delay)
+import Effect (Effect)
 import Effect.Aff.Class (class MonadAff, liftAff)
 import Effect.Class (liftEffect)
 import Effect.Exception (Error)
 import Node.Stream.Object (ReadResult(..), WriteResult(..))
 import Node.Stream.Object as O
 import Pipes (await, yield)
 import Pipes (for) as P
 import Pipes.Async (AsyncPipe(..))
 import Pipes.Async as AsyncPipe
 import Pipes.Core (Consumer, Pipe, Producer, Producer_)
 import Pipes.Prelude (mapFoldable) as P
 import Pipes.Util (InvokeResult(..), invoke)
 -- | Convert a `Readable` stream to a `Pipe`.
@@ -34,15 +36,19 @@ fromReadable r =
      pure $ Done unit
    go { error, cancel } = do
      liftAff $ delay $ wrap 0.0
      err <- liftEffect $ liftST $ STRef.read error
      for_ err throwError
      res <- liftEffect $ O.read r
      case res of
        O.ReadJust a -> yield (Just a) $> Loop { error, cancel }
-        O.ReadWouldBlock -> liftAff (O.awaitReadableOrClosed r) $> Loop { error, cancel }
+        O.ReadWouldBlock -> do
-        O.ReadClosed -> yield Nothing *> cleanup cancel
+          ended <- liftEffect $ O.isReadableEnded r
          if ended then do
            yield Nothing
            cleanup cancel
          else
            liftAff (O.awaitReadableOrClosed r) $> Loop { error, cancel }
  in
    do
      e <- liftEffect $ O.withErrorST r
@@ -53,74 +59,89 @@ fromReadable r =
 -- | When `Nothing` is piped to this, the stream will
 -- | be `end`ed, and the pipe will noop if invoked again.
 fromWritable :: forall s a m. MonadThrow Error m => MonadAff m => O.Write s a => s -> Consumer (Maybe a) m Unit
-fromWritable w =
+fromWritable w = do
  { error: errorST, cancel: removeErrorListener } <- liftEffect $ O.withErrorST w
  let
-    cleanup rmErrorListener = do
+    maybeThrow = traverse_ throwError =<< liftEffect (liftST $ STRef.read errorST)
-      liftEffect rmErrorListener
+
-      liftEffect $ O.end w
+    waitCanWrite = do
      shouldWait <- liftEffect $ O.needsDrain w
      when shouldWait $ liftAff $ O.awaitWritableOrClosed w
    cleanup = do
      liftAff $ O.awaitFinished w
-      pure $ Done unit
+      maybeThrow
      liftEffect removeErrorListener
-    go { error, cancel } = do
+    onEOS = liftEffect (O.end w) *> cleanup $> Done unit
-      liftAff $ delay $ wrap 0.0
+    onChunk a = liftEffect (O.write w a) $> Loop unit
      err <- liftEffect $ liftST $ STRef.read error
      for_ err throwError
-      ma <- await
+    go _ = do
-      case ma of
+      maybeThrow
-        Nothing -> cleanup cancel
+      waitCanWrite
-        Just a -> do
+      ended <- liftEffect $ O.isWritableEnded w
-          res <- liftEffect $ O.write w a
+      if ended then
-          case res of
+        cleanup $> Done unit
-            O.WriteOk -> pure $ Loop { error, cancel }
+      else
-            O.WriteWouldBlock -> do
+        await >>= maybe onEOS onChunk
              liftAff (O.awaitWritableOrClosed w)
              pure $ Loop { error, cancel }
            O.WriteClosed -> cleanup cancel
  in
    do
      r <- liftEffect $ O.withErrorST w
      tailRecM go r
-- | Convert a `Transform` stream to a `Pipe`.
+  tailRecM go unit
 -- |
 -- | When `Nothing` is piped to this, the `Transform` stream will
 -- | be `end`ed, and the pipe will noop if invoked again.
 fromTransform :: forall a b m. MonadThrow Error m => MonadAff m => O.Transform a b -> Pipe (Maybe a) (Maybe b) m Unit
 fromTransform t =
  let
    cleanup removeErrorListener = do
      liftEffect $ O.end t
      liftEffect $ removeErrorListener
      fromReadable t
      pure $ Done unit
    yieldFromReadableHalf = do
      res <- liftEffect (O.read t)
      case res of
        O.ReadJust a -> yield (Just a) *> yieldFromReadableHalf
        O.ReadWouldBlock -> pure unit
        O.ReadClosed -> yield Nothing *> pure unit
    go { error, cancel } = do
      liftAff $ delay $ wrap 0.0
      err <- liftEffect $ liftST $ STRef.read error
      for_ err throwError
-      ma <- await
+fromTransformEffect
-      case ma of
+  :: forall a b m
-        Nothing -> cleanup cancel
+   . MonadThrow Error m
-        Just a' -> do
+  => MonadAff m
-          res <- liftEffect $ O.write t a'
+  => Effect (O.Transform a b)
-          yieldFromReadableHalf
+  -> AsyncPipe (Maybe a) (Maybe b) m Unit
-          case res of
+fromTransformEffect = fromTransform <=< liftEffect
-            O.WriteClosed -> cleanup cancel
+
-            O.WriteOk -> pure $ Loop { error, cancel }
+-- | Convert a `Transform` stream to an `AsyncPipe`.
-            O.WriteWouldBlock -> do
+fromTransform
-              liftAff $ O.awaitWritableOrClosed t
+  :: forall a b m
-              pure $ Loop { error, cancel }
+   . MonadThrow Error m
-  in
+  => MonadAff m
-    do
+  => O.Transform a b
-      r <- liftEffect $ O.withErrorST t
+  -> AsyncPipe (Maybe a) (Maybe b) m Unit
-      tailRecM go r
+fromTransform stream = do
    { error: errorST, cancel: removeErrorListener } <- liftEffect $ O.withErrorST stream
    let
      rethrow = traverse_ throwError =<< liftEffect (liftST $ ST.Ref.read errorST)
      cleanup = liftEffect removeErrorListener
      writeSignal =
        liftEffect (O.isWritableEnded stream)
        <#> if _ then AsyncPipe.WriteSignalEnded else AsyncPipe.WriteSignalOk
      readSignal =
        liftEffect (O.isReadableEnded stream)
        <#> if _ then AsyncPipe.ReadSignalEnded else AsyncPipe.ReadSignalOk
      writeResult WriteOk = AsyncPipe.WriteAgain
      writeResult WriteWouldBlock = AsyncPipe.WriteNeedsDrain
      readResult (ReadJust a) = AsyncPipe.ReadOk (Just a)
      readResult ReadWouldBlock = AsyncPipe.ReadWouldBlock
      awaitWritable = liftAff $ O.awaitWritableOrClosed stream
      awaitReadable = liftAff $ O.awaitReadableOrClosed stream
      awaitWrite = rethrow *> awaitWritable *> writeSignal
      awaitRead = rethrow *> awaitReadable *> readSignal
      whenReadNotEnded m =
        liftEffect (O.isReadableEnded stream)
          >>= if _ then pure $ AsyncPipe.ReadOk Nothing else m
      readNow = readResult <$> liftEffect (O.read stream)
      writeNow a = writeResult <$> liftEffect (O.write stream a)
      read = rethrow *> whenReadNotEnded readNow
      write Nothing = liftEffect (O.end stream) $> AsyncPipe.WriteEnded
      write (Just a) = rethrow *> writeNow a
    AsyncIO ({write, awaitWrite, read, awaitRead} /\ cleanup)
 -- | Given a `Producer` of values, wrap them in `Just`.
 -- |
@@ -132,7 +153,7 @@ withEOS a = do
 -- | Strip a pipeline of the EOS signal
 unEOS :: forall a m. Monad m => Pipe (Maybe a) a m Unit
-unEOS = P.mapFoldable identity
+unEOS = tailRecM (const $ maybe (pure $ Done unit) (\a -> yield a $> Loop unit) =<< await) unit
 -- | Lift a `Pipe a a` to `Pipe (Maybe a) (Maybe a)`.
 -- |
--- a/src/Pipes.Node.Zlib.purs
+++ b/src/Pipes.Node.Zlib.purs
@@ -12,31 +12,32 @@ import Node.Buffer (Buffer)
 import Node.Stream.Object as O
 import Node.Zlib as Zlib
 import Node.Zlib.Types (ZlibStream)
-import Pipes.Core (Pipe)
+import Pipes.Async (AsyncPipe)
 import Pipes.Node.Stream (fromTransform)
-fromZlib :: forall r m. MonadAff m => MonadThrow Error m => Effect (ZlibStream r) -> Pipe (Maybe Buffer) (Maybe Buffer) m Unit
+fromZlib :: forall r m. MonadAff m => MonadThrow Error m => Effect (ZlibStream r) -> AsyncPipe (Maybe Buffer) (Maybe Buffer) m Unit
-fromZlib z = do
+fromZlib z =
-  raw <- liftEffect $ Zlib.toDuplex <$> z
+  do
-  fromTransform $ O.fromBufferTransform raw
+    raw <- liftEffect $ Zlib.toDuplex <$> z
    fromTransform $ O.unsafeCoerceTransform raw
-gzip :: forall m. MonadAff m => MonadThrow Error m => Pipe (Maybe Buffer) (Maybe Buffer) m Unit
+gzip :: forall m. MonadAff m => MonadThrow Error m => AsyncPipe (Maybe Buffer) (Maybe Buffer) m Unit
 gzip = fromZlib Zlib.createGzip
-gunzip :: forall m. MonadAff m => MonadThrow Error m => Pipe (Maybe Buffer) (Maybe Buffer) m Unit
+gunzip :: forall m. MonadAff m => MonadThrow Error m => AsyncPipe (Maybe Buffer) (Maybe Buffer) m Unit
 gunzip = fromZlib Zlib.createGunzip
-unzip :: forall m. MonadAff m => MonadThrow Error m => Pipe (Maybe Buffer) (Maybe Buffer) m Unit
+unzip :: forall m. MonadAff m => MonadThrow Error m => AsyncPipe (Maybe Buffer) (Maybe Buffer) m Unit
 unzip = fromZlib Zlib.createUnzip
-inflate :: forall m. MonadAff m => MonadThrow Error m => Pipe (Maybe Buffer) (Maybe Buffer) m Unit
+inflate :: forall m. MonadAff m => MonadThrow Error m => AsyncPipe (Maybe Buffer) (Maybe Buffer) m Unit
 inflate = fromZlib Zlib.createInflate
-deflate :: forall m. MonadAff m => MonadThrow Error m => Pipe (Maybe Buffer) (Maybe Buffer) m Unit
+deflate :: forall m. MonadAff m => MonadThrow Error m => AsyncPipe (Maybe Buffer) (Maybe Buffer) m Unit
 deflate = fromZlib Zlib.createDeflate
-brotliCompress :: forall m. MonadAff m => MonadThrow Error m => Pipe (Maybe Buffer) (Maybe Buffer) m Unit
+brotliCompress :: forall m. MonadAff m => MonadThrow Error m => AsyncPipe (Maybe Buffer) (Maybe Buffer) m Unit
 brotliCompress = fromZlib Zlib.createBrotliCompress
-brotliDecompress :: forall m. MonadAff m => MonadThrow Error m => Pipe (Maybe Buffer) (Maybe Buffer) m Unit
+brotliDecompress :: forall m. MonadAff m => MonadThrow Error m => AsyncPipe (Maybe Buffer) (Maybe Buffer) m Unit
 brotliDecompress = fromZlib Zlib.createBrotliDecompress
--- a/src/Pipes.Util.purs
+++ b/src/Pipes.Util.purs
@@ -15,9 +15,12 @@ import Data.Either (hush)
 import Data.HashSet as HashSet
 import Data.Hashable (class Hashable, hash)
 import Data.List.NonEmpty (NonEmptyList)
-import Data.Maybe (Maybe(..), fromMaybe)
+import Data.Maybe (Maybe(..), fromMaybe, maybe)
 import Data.Traversable (traverse_)
 import Data.Tuple.Nested (type (/\), (/\))
 import Effect.Class (class MonadEffect, liftEffect)
 import Node.Buffer (Buffer)
 import Node.Buffer as Buffer
 import Pipes (await, yield)
 import Pipes as Pipes
 import Pipes.Core (Pipe, Producer)
@@ -85,9 +88,39 @@ chunked size = do
  Rec.whileJust $ runMaybeT do
    a <- MaybeT await
    chunkPut a
-    len <- chunkLength
+    len <- lift chunkLength
-    when (len >= size) $ lift $ yield =<< Just <$> chunkTake
+    when (len >= size) do
-  yield =<< Just <$> chunkTake
+      chunk <- lift chunkTake
      lift $ yield $ Just chunk
  len <- chunkLength
  when (len > 0) do
    chunk <- chunkTake
    yield $ Just chunk
  yield Nothing
 -- | Buffers input to the given size before passing to subsequent pipes
 buffered :: forall m. MonadEffect m => Int -> Pipe (Maybe Buffer) (Maybe Buffer) m Unit
 buffered size = do
  chunkST :: STRef _ (Maybe Buffer) <- liftEffect $ liftST $ STRef.new Nothing
  let
    chunkClear = liftEffect $ liftST $ STRef.write Nothing chunkST
    chunkPeek = liftEffect $ liftST $ STRef.read chunkST
    chunkLen = maybe (pure 0) (liftEffect <<< Buffer.size) =<< chunkPeek
    chunkPut b = liftEffect do
      new <- liftST (STRef.read chunkST) >>= maybe (pure b) (\a -> Buffer.concat [a, b])
      void $ liftST $ STRef.write (Just new) chunkST
      pure new
  Rec.whileJust $ runMaybeT do
    a <- MaybeT await
    buf <- chunkPut a
    len <- lift chunkLen
    when (len > size) $ chunkClear *> lift (yield $ Just buf)
  len <- chunkLen
  chunkPeek >>= traverse_ (when (len > 0) <<< yield <<< Just)
  yield Nothing
 -- | Equivalent of unix `uniq`, filtering out duplicate values passed to it.
--- a/test/Test/Main.purs
+++ b/test/Test/Main.purs
@@ -3,18 +3,19 @@ module Test.Main where
 import Prelude
 import Data.Maybe (Maybe(..))
 import Data.Time.Duration (Milliseconds(..))
 import Effect (Effect)
 import Effect.Aff (launchAff_)
 import Test.Pipes.Node.Stream as Test.Pipes.Node.Stream
 import Test.Pipes.Node.Buffer as Test.Pipes.Node.Buffer
 import Test.Pipes.Node.FS as Test.Pipes.Node.FS
 import Test.Pipes.Collect as Test.Pipes.Collect
 import Test.Pipes.Construct as Test.Pipes.Construct
 import Test.Pipes.Node.Buffer as Test.Pipes.Node.Buffer
 import Test.Pipes.Node.FS as Test.Pipes.Node.FS
 import Test.Pipes.Node.Stream as Test.Pipes.Node.Stream
 import Test.Spec.Reporter (specReporter)
 import Test.Spec.Runner (defaultConfig, runSpec')
 main :: Effect Unit
-main = launchAff_ $ runSpec' (defaultConfig { exit = false, timeout = Nothing }) [ specReporter ] do
+main = launchAff_ $ runSpec' (defaultConfig { slow = Milliseconds 0.0, failFast = true, exit = false, timeout = Nothing }) [ specReporter ] do
  Test.Pipes.Node.Stream.spec
  Test.Pipes.Node.Buffer.spec
  Test.Pipes.Node.FS.spec
--- a/test/Test/Pipes.Node.FS.purs
+++ b/test/Test/Pipes.Node.FS.purs
@@ -33,11 +33,6 @@ spec = describe "Pipes.Node.FS" do
      liftEffect $ FS.writeTextFile UTF8 p "foo"
      s <- fold <$> Pipes.toListM (Pipes.Node.FS.read p >-> unEOS >-> Pipes.Node.Buffer.toString UTF8)
      s `shouldEqual` "foo"
    around tmpFile $ it "fails if the file already exists" \p -> do
      liftEffect $ FS.writeTextFile UTF8 p "foo"
      flip catchError (const $ pure unit) do
        Pipes.runEffect $ withEOS (yield "foo" >-> Pipes.Node.Buffer.fromString UTF8) >-> Pipes.Node.FS.create p
        fail "should have thrown"
  describe "create" do
    around tmpFile $ it "creates the file when not exists" \p -> do
      Pipes.runEffect $ withEOS (yield "foo" >-> Pipes.Node.Buffer.fromString UTF8) >-> Pipes.Node.FS.create p
@@ -59,14 +54,14 @@ spec = describe "Pipes.Node.FS" do
      Pipes.runEffect $ withEOS (yield "bar" >-> Pipes.Node.Buffer.fromString UTF8) >-> Pipes.Node.FS.append p
      contents <- liftEffect $ FS.readTextFile UTF8 p
      contents `shouldEqual` "foo\nbar"
-  describe "truncate" do
+  describe "trunc" do
    around tmpFile $ it "creates the file when not exists" \p -> do
-      Pipes.runEffect $ withEOS (yield "foo" >-> Pipes.Node.Buffer.fromString UTF8) >-> Pipes.Node.FS.truncate p
+      Pipes.runEffect $ withEOS (yield "foo" >-> Pipes.Node.Buffer.fromString UTF8) >-> Pipes.Node.FS.trunc p
      contents <- liftEffect $ FS.readTextFile UTF8 p
      contents `shouldEqual` "foo"
    around tmpFile $ it "overwrites contents" \p -> do
-      Pipes.runEffect $ withEOS (yield "foo" >-> Pipes.Node.Buffer.fromString UTF8) >-> Pipes.Node.FS.truncate p
+      Pipes.runEffect $ withEOS (yield "foo" >-> Pipes.Node.Buffer.fromString UTF8) >-> Pipes.Node.FS.trunc p
-      Pipes.runEffect $ withEOS (yield "bar" >-> Pipes.Node.Buffer.fromString UTF8) >-> Pipes.Node.FS.truncate p
+      Pipes.runEffect $ withEOS (yield "bar" >-> Pipes.Node.Buffer.fromString UTF8) >-> Pipes.Node.FS.trunc p
      contents <- liftEffect $ FS.readTextFile UTF8 p
      contents `shouldEqual` "bar"
  around tmpFiles $ it "json lines >-> parse >-> _.foo >-> write" \(a /\ b) -> do
--- a/test/Test/Pipes.Node.Stream.js
+++ b/test/Test/Pipes.Node.Stream.js
@@ -1,4 +1,16 @@
 import Stream from 'stream'
 import * as CBOR from "cbor-x";
 import * as CSVDecode from "csv-parse";
 import * as CSVEncode from "csv-stringify";
 export const cborDecode = () => new CBOR.DecoderStream({useRecords: false, allowHalfOpen: true});
 export const cborEncode = () => new CBOR.EncoderStream({useRecords: false, allowHalfOpen: true});
 export const cborDecodeSync = a => () => CBOR.decodeMultiple(a);
 export const cborEncodeSync = a => () => CBOR.encode(a, {useRecords: false});
 export const csvDecode = () => CSVDecode.parse({columns: true, allowHalfOpen: true})
 export const csvEncode = () => CSVEncode.stringify({header: true, allowHalfOpen: true})
 export const discardTransform = () => new Stream.Transform({
  transform: function(_ck, _enc, cb) {
@@ -7,6 +19,16 @@ export const discardTransform = () => new Stream.Transform({
  objectMode: true
 })
 export const slowTransform = () => {
  return new Stream.Transform({
  transform: function(ck, _enc, cb) {
    this.push(ck)
    setTimeout(() => cb(), 4)
  },
  objectMode: true
 })
 }
 export const charsTransform = () => new Stream.Transform({
  transform: function(ck, _enc, cb) {
    ck.split('').filter(s => !!s).forEach(s => this.push(s))
--- a/test/Test/Pipes.Node.Stream.purs
+++ b/test/Test/Pipes.Node.Stream.purs
@@ -2,49 +2,72 @@ module Test.Pipes.Node.Stream where
 import Prelude
-import Control.Monad.Trans.Class (lift)
+import Control.Monad.Cont (lift)
 import Control.Monad.Error.Class (liftEither)
 import Control.Monad.Except (runExcept)
 import Data.Array as Array
-import Data.Foldable (fold)
+import Data.Bifunctor (lmap)
 import Data.Either (Either(..))
 import Data.Foldable (fold, intercalate)
 import Data.FoldableWithIndex (forWithIndex_)
 import Data.FunctorWithIndex (mapWithIndex)
 import Data.Int as Int
 import Data.List ((:))
 import Data.List as List
 import Data.Maybe (Maybe)
 import Data.Newtype (wrap)
 import Data.Profunctor.Strong (first)
 import Data.String as String
 import Data.String.Gen (genAlphaString)
 import Data.Traversable (for_, traverse)
 import Data.Tuple.Nested (type (/\), (/\))
 import Effect (Effect)
 import Effect.Aff (Aff, delay)
 import Effect.Class (class MonadEffect, liftEffect)
 import Effect.Exception (error)
 import Effect.Unsafe (unsafePerformEffect)
 import Foreign (Foreign)
 import Node.Buffer (Buffer)
 import Node.Buffer as Buffer
 import Node.Encoding (Encoding(..))
 import Node.FS.Stream as FS.Stream
 import Node.FS.Sync as FS
 import Node.Stream.Object as O
-import Node.Zlib as Zlib
+import Pipes (each) as Pipe
 import Pipes (each) as Pipes
 import Pipes (yield, (>->))
 import Pipes.Async (sync, (>-/->))
 import Pipes.Collect as Pipe.Collect
 import Pipes.Core (Consumer, Producer, runEffect)
-import Pipes.Node.Buffer as Pipes.Buffer
+import Pipes.Node.Buffer as Pipe.Buffer
-import Pipes.Node.Stream as S
+import Pipes.Node.FS as Pipe.FS
-import Pipes.Prelude (mapFoldable, toListM) as Pipes
+import Pipes.Node.Stream as Pipe.Node
-import Simple.JSON (writeJSON)
+import Pipes.Node.Zlib as Pipe.Zlib
-import Test.Common (jsonParse, jsonStringify, tmpFile, tmpFiles)
+import Pipes.Prelude (toListM) as Pipe
 import Simple.JSON (readImpl, readJSON, writeJSON)
 import Test.Common (jsonStringify, tmpFile, tmpFiles)
 import Test.QuickCheck.Arbitrary (arbitrary)
 import Test.QuickCheck.Gen (randomSample')
 import Test.Spec (Spec, around, describe, it)
-import Test.Spec.Assertions (shouldEqual)
+import Test.Spec.Assertions (fail, shouldEqual)
 foreign import readableFromArray :: forall @a. Array a -> O.Readable a
 foreign import discardTransform :: forall a b. Effect (O.Transform a b)
 foreign import slowTransform :: forall a b. Effect (O.Transform a b)
 foreign import charsTransform :: Effect (O.Transform String String)
 foreign import cborEncodeSync :: forall a. a -> Effect Buffer
 foreign import cborDecodeSync :: forall a. Buffer -> Effect a
 foreign import cborEncode :: forall a. Effect (O.Transform a Buffer)
 foreign import cborDecode :: forall a. Effect (O.Transform Buffer a)
 foreign import csvEncode :: forall a. Effect (O.Transform a String)
 foreign import csvDecode :: forall a. Effect (O.Transform String a)
 writer :: forall m. MonadEffect m => String -> m (O.Writable Buffer /\ Consumer (Maybe Buffer) Aff Unit)
 writer a = do
-  stream <- liftEffect $ O.fromBufferWritable <$> FS.Stream.createWriteStream a
+  stream <- liftEffect $ O.unsafeCoerceWritable <$> FS.Stream.createWriteStream a
-  pure $ stream /\ S.fromWritable stream
+  pure $ stream /\ Pipe.Node.fromWritable stream
 reader :: forall m. MonadEffect m => String -> m (Producer (Maybe Buffer) Aff Unit)
-reader a = liftEffect $ S.fromReadable <$> O.fromBufferReadable <$> FS.Stream.createReadStream a
+reader a = liftEffect $ Pipe.Node.fromReadable <$> O.unsafeCoerceReadable <$> FS.Stream.createReadStream a
 spec :: Spec Unit
 spec =
@@ -52,30 +75,30 @@ spec =
    describe "Readable" do
      describe "Readable.from(<Iterable>)" do
        it "empty" do
-          vals <- Pipes.toListM $ (S.fromReadable $ readableFromArray @{ foo :: String } []) >-> S.unEOS
+          vals <- Pipe.toListM $ (Pipe.Node.fromReadable $ readableFromArray @{ foo :: String } []) >-> Pipe.Node.unEOS
          vals `shouldEqual` List.Nil
        it "singleton" do
-          vals <- Pipes.toListM $ (S.fromReadable $ readableFromArray @{ foo :: String } [ { foo: "1" } ]) >-> S.unEOS
+          vals <- Pipe.toListM $ (Pipe.Node.fromReadable $ readableFromArray @{ foo :: String } [ { foo: "1" } ]) >-> Pipe.Node.unEOS
          vals `shouldEqual` ({ foo: "1" } : List.Nil)
        it "many elements" do
          let exp = (\n -> { foo: show n }) <$> Array.range 0 100
-          vals <- Pipes.toListM $ (S.fromReadable $ readableFromArray exp) >-> S.unEOS
+          vals <- Pipe.toListM $ (Pipe.Node.fromReadable $ readableFromArray exp) >-> Pipe.Node.unEOS
          vals `shouldEqual` (List.fromFoldable exp)
    describe "Writable" $ around tmpFile do
      describe "fs.WriteStream" do
        it "pipe to file" \p -> do
-          stream <- O.fromBufferWritable <$> liftEffect (FS.Stream.createWriteStream p)
+          stream <- O.unsafeCoerceWritable <$> liftEffect (FS.Stream.createWriteStream p)
          let
-            w = S.fromWritable stream
+            w = Pipe.Node.fromWritable stream
            source = do
              buf <- liftEffect $ Buffer.fromString "hello" UTF8
              yield buf
-          runEffect $ S.withEOS source >-> w
+          runEffect $ Pipe.Node.withEOS source >-> w
          contents <- liftEffect $ FS.readTextFile UTF8 p
          contents `shouldEqual` "hello"
          shouldEqual true =<< liftEffect (O.isWritableEnded stream)
        it "async pipe to file" \p -> do
-          w <- S.fromWritable <$> O.fromBufferWritable <$> liftEffect (FS.Stream.createWriteStream p)
+          w <- Pipe.Node.fromWritable <$> O.unsafeCoerceWritable <$> liftEffect (FS.Stream.createWriteStream p)
          let
            source = do
              yield "hello, "
@@ -87,7 +110,7 @@ spec =
              yield "this is a "
              lift $ delay $ wrap 5.0
              yield "test."
-          runEffect $ S.withEOS (source >-> Pipes.Buffer.fromString UTF8) >-> w
+          runEffect $ Pipe.Node.withEOS (source >-> Pipe.Buffer.fromString UTF8) >-> w
          contents <- liftEffect $ FS.readTextFile UTF8 p
          contents `shouldEqual` "hello, world! this is a test."
        it "chained pipes" \p -> do
@@ -101,40 +124,105 @@ spec =
          let
            exp = fold (writeJSON <$> objs)
          stream /\ w <- liftEffect $ writer p
-          runEffect $ S.withEOS (Pipes.each objs >-> jsonStringify >-> Pipes.Buffer.fromString UTF8) >-> w
+          runEffect $ Pipe.Node.withEOS (Pipe.each objs >-> jsonStringify >-> Pipe.Buffer.fromString UTF8) >-> w
          contents <- liftEffect $ FS.readTextFile UTF8 p
          contents `shouldEqual` exp
          shouldEqual true =<< liftEffect (O.isWritableEnded stream)
    describe "Transform" do
-      it "gzip" do
+      let
-        let
+        bignums = Array.range 1 1000
-          json = yield $ writeJSON { foo: "bar" }
+        firstNames = String.split (wrap "\n") $ unsafePerformEffect (FS.readTextFile UTF8 "./test/Test/first_names.txt")
-          exp = "1f8b0800000000000003ab564acbcf57b2524a4a2c52aa0500eff52bfe0d000000"
+        lastNames = String.split (wrap "\n") $ unsafePerformEffect (FS.readTextFile UTF8 "./test/Test/last_names.txt")
-        gzip <- S.fromTransform <$> O.fromBufferTransform <$> liftEffect (Zlib.toDuplex <$> Zlib.createGzip)
+        names n = do
-        outs :: List.List String <- Pipes.toListM (S.withEOS (json >-> Pipes.Buffer.fromString UTF8) >-> gzip >-> S.unEOS >-> Pipes.Buffer.toString Hex)
+          first <- firstNames
-        fold outs `shouldEqual` exp
+          last <- Array.take (Int.round $ Int.toNumber n / Int.toNumber (Array.length firstNames)) lastNames
-      around tmpFiles
+          pure $ first <> " " <> last
-        $ it "file >-> gzip >-> file >-> gunzip" \(a /\ b) -> do
+        people n = mapWithIndex (\ix name -> {id: show $ ix + 1, name}) (names n)
-            liftEffect $ FS.writeTextFile UTF8 a $ writeJSON [ 1, 2, 3, 4 ]
+        peopleCSV n = "id,name\n" <> intercalate "\n" ((\{id, name} -> id <> "," <> name) <$> people n)
            areader <- liftEffect $ reader a
            bwritestream /\ bwriter <- liftEffect $ writer b
            gzip <- S.fromTransform <$> O.fromBufferTransform <$> liftEffect (Zlib.toDuplex <$> Zlib.createGzip)
            runEffect $ areader >-> gzip >-> bwriter
            shouldEqual true =<< liftEffect (O.isWritableEnded bwritestream)
-            gunzip <- S.fromTransform <$> O.fromBufferTransform <$> liftEffect (Zlib.toDuplex <$> Zlib.createGunzip)
+      for_ [4000, 8000, 32000, 64000, 200000] \n -> do
-            breader <- liftEffect $ reader b
+        let
-            nums <- Pipes.toListM (breader >-> gunzip >-> S.unEOS >-> Pipes.Buffer.toString UTF8 >-> jsonParse @(Array Int) >-> Pipes.mapFoldable identity)
+          csv = peopleCSV n
-            Array.fromFoldable nums `shouldEqual` [ 1, 2, 3, 4 ]
+          people' = people n
        around tmpFiles
          $ it (show n <> " row csv >-/-> csv-parse >-/-> cborEncode") \(a /\ _) -> do
              liftEffect $ FS.writeTextFile UTF8 a csv
              cbor :: Buffer <- Pipe.Collect.toBuffer
                $ Pipe.FS.read a
                  >-> Pipe.Node.inEOS (Pipe.Buffer.toString UTF8)
                  >-/-> Pipe.Node.fromTransformEffect csvDecode
                  >-/-> Pipe.Node.fromTransformEffect cborEncode
                  >-> Pipe.Node.unEOS
              f :: Array Foreign <- liftEffect $ cborDecodeSync cbor
              ppl <- traverse (liftEither <<< lmap (error <<< show) <<< runExcept <<< readImpl) f
              ppl `shouldEqual` people'
        around tmpFiles
          $ it (show n <> " row csv >-> sync csv-parse >-> sync cborEncode") \(a /\ _) -> do
              liftEffect $ FS.writeTextFile UTF8 a csv
              cbor :: Buffer <- Pipe.Collect.toBuffer
                $ Pipe.FS.read a
                  >-> Pipe.Node.inEOS (Pipe.Buffer.toString UTF8)
                  >-> sync (Pipe.Node.fromTransformEffect csvDecode)
                  >-> sync (Pipe.Node.fromTransformEffect cborEncode)
                  >-> Pipe.Node.unEOS
              f :: Array Foreign <- liftEffect $ cborDecodeSync cbor
              ppl <- traverse (liftEither <<< lmap (error <<< show) <<< runExcept <<< readImpl) f
              ppl `shouldEqual` people'
      around tmpFiles
        $ it "file >-> sync gzip >-> sync gunzip" \(a /\ _) -> do
            liftEffect $ FS.writeTextFile UTF8 a $ writeJSON bignums
            json <- Pipe.Collect.toMonoid
              $ Pipe.FS.read a
                >-> sync Pipe.Zlib.gzip
                >-> sync Pipe.Zlib.gunzip
                >-> Pipe.Node.unEOS
                >-> Pipe.Buffer.toString UTF8
            readJSON json `shouldEqual` (Right bignums)
      around tmpFiles
        $ it "file >-/-> gzip >-/-> slow >-/-> gunzip" \(a /\ _) -> do
            liftEffect $ FS.writeTextFile UTF8 a $ writeJSON bignums
            json <-
              Pipe.Collect.toMonoid
              $ Pipe.FS.read a
                >-/-> Pipe.Zlib.gzip
                >-/-> Pipe.Node.fromTransformEffect slowTransform
                >-/-> Pipe.Zlib.gunzip
                >-> Pipe.Node.unEOS
                >-> Pipe.Buffer.toString UTF8
            readJSON json `shouldEqual` (Right bignums)
      around tmpFiles
        $ it "file >-> sync gzip >-> sync slow >-> sync gunzip" \(a /\ _) -> do
            liftEffect $ FS.writeTextFile UTF8 a $ writeJSON bignums
            json <-
              Pipe.Collect.toMonoid
              $ Pipe.FS.read a
                >-> sync Pipe.Zlib.gzip
                >-> sync (Pipe.Node.fromTransformEffect slowTransform)
                >-> sync Pipe.Zlib.gunzip
                >-> Pipe.Node.unEOS
                >-> Pipe.Buffer.toString UTF8
            readJSON json `shouldEqual` (Right bignums)
      around tmpFile $ it "file >-> discardTransform" \(p :: String) -> do
        liftEffect $ FS.writeTextFile UTF8 p "foo"
        r <- reader p
-        discard' <- liftEffect discardTransform
+        out :: List.List Int <-
-        out :: List.List Int <- Pipes.toListM $ r >-> S.fromTransform discard' >-> S.unEOS
+          Pipe.toListM
            $ r
                >-/-> Pipe.Node.fromTransformEffect discardTransform
                >-> Pipe.Node.unEOS
        out `shouldEqual` List.Nil
      around tmpFile $ it "file >-> charsTransform" \(p :: String) -> do
        liftEffect $ FS.writeTextFile UTF8 p "foo bar"
        r <- reader p
-        chars' <- liftEffect charsTransform
+        out :: List.List String <-
-        out :: List.List String <- Pipes.toListM $ r >-> S.inEOS (Pipes.Buffer.toString UTF8) >-> S.fromTransform chars' >-> S.unEOS
+          Pipe.toListM $
            r
            >-> Pipe.Node.inEOS (Pipe.Buffer.toString UTF8)
            >-/-> Pipe.Node.fromTransformEffect charsTransform
            >-> Pipe.Node.unEOS
        out `shouldEqual` List.fromFoldable [ "f", "o", "o", " ", "b", "a", "r" ]
--- a/test/Test/first_names.txt
+++ b/test/Test/first_names.txt
--- a/test/Test/last_names.txt
+++ b/test/Test/last_names.txt
Author	SHA1	Message	Date
Orion Kindel	3ec43ce4b1	chore: prepare v2.1.6	2024-07-17 14:41:58 -05:00
Orion Kindel	5c680ac55f	fix: writable issue	2024-07-17 13:26:44 -05:00
Orion Kindel	b2bac919ba	docs: add LICENSE	2024-07-10 13:49:28 -05:00
Orion Kindel	7d03850623	chore: prepare v2.1.5	2024-07-08 12:43:58 -05:00
Orion Kindel	dc7a2d3387	feat: Pipe.Util.buffered	2024-07-08 12:40:25 -05:00
Orion Kindel	43ff92a4ad	chore: prepare v2.1.4	2024-06-25 14:26:40 -05:00
Orion Kindel	bb9790b2f4	chore: prepare v2.1.34	2024-06-25 14:24:50 -05:00
Orion Kindel	6b64956034	chore: prepare v2.1.3	2024-06-25 14:24:46 -05:00
Orion Kindel	271ca13f8b	chore: prepare v2.1.2	2024-06-25 14:20:38 -05:00
Orion Kindel	4a9dbf0a3c	fix: relax pipeAsync constraints	2024-06-25 14:20:25 -05:00
Orion Kindel	c73d934a5c	chore: prepare v2.1.1	2024-06-23 20:49:22 -05:00
Orion Kindel	dc1ba322a9	fix: asyncpipe is mfunctor	2024-06-23 20:49:17 -05:00
Orion Kindel	cda67508d4	chore: prepare v2.1.0	2024-06-23 18:34:01 -05:00
Orion Kindel	860ace3990	feat: AsyncPipe really should be a monad	2024-06-23 18:33:45 -05:00
Orion Kindel	7f11c303fb	chore: prepare v2.0.2	2024-06-22 19:33:56 -05:00
Orion Kindel	2e0be4ac62	fix: loop bug	2024-06-22 19:33:45 -05:00
Orion Kindel	0ba315ede0	chore: prepare v2.0.1	2024-06-22 19:12:56 -05:00
Orion Kindel	08bd9a817a	fix: asyncpipe is profunctor	2024-06-22 19:12:31 -05:00
Orion Kindel	970d890a00	chore: prepare v2.0.0	2024-06-22 18:42:49 -05:00
Orion Kindel	5b3eda707e	feat!: add AsyncPipe abstraction, significantly improve throughput of Transform streams	2024-06-22 18:42:22 -05:00
Orion Kindel	4cd44367a8	chore: prepare v1.6.1	2024-06-21 13:21:22 -05:00
Orion Kindel	d76f55e267	fix: introduced transform bug	2024-06-21 13:21:19 -05:00
Orion Kindel	4b91ab7d5c	chore: prepare v1.6.0	2024-06-20 15:40:32 -05:00
Orion Kindel	a8702f4849	fix: `finish` may not emit until all chunks are read	2024-06-20 15:40:17 -05:00
Orion Kindel	f3ea830379	chore: prepare v1.5.0	2024-05-15 13:30:23 -05:00
Orion Kindel	4242330bef	fix: write readme, clarify API	2024-05-15 13:30:08 -05:00
Orion Kindel	1b6e6423b1	chore: prepare v1.4.1	2024-05-14 15:02:39 -05:00
Orion Kindel	657af14bb6	fix: await finished before exiting	2024-05-14 14:07:20 -05:00
Orion Kindel	33d42034fc	fix: continue to read after readableEnded	2024-05-14 13:51:57 -05:00
Orion Kindel	c8822aeffe	fix: I WAS INCORRECT HHEHE	2024-05-14 13:44:33 -05:00
Orion Kindel	7076b13df4	fix: catch incorrect stream implementations	2024-05-14 13:42:39 -05:00
Orion Kindel	3f4bc12d36	chore: prepare v1.4.0	2024-05-14 13:12:56 -05:00
Orion Kindel	fd53b6520f	feat: Collect.toBuffer	2024-05-14 13:12:41 -05:00
Orion Kindel	0ef7240d61	wip: explore removing delays(10)	2024-05-14 12:44:31 -05:00
Orion Kindel	de22f44f86	wip: explore removing delays(9)	2024-05-14 12:43:38 -05:00
Orion Kindel	f9c0e20777	wip: explore removing delays(8)	2024-05-14 11:08:46 -05:00
Orion Kindel	edc7d40dbc	wip: explore removing delays(7)	2024-05-14 11:04:50 -05:00
Orion Kindel	ba8d90038d	wip: explore removing delays(6)	2024-05-14 10:55:14 -05:00
Orion Kindel	dfdca9f5e9	wip: explore removing delays(5)	2024-05-14 10:39:06 -05:00
Orion Kindel	67ae171532	wip: explore removing delays(4)	2024-05-13 21:18:27 -05:00
Orion Kindel	a347c05062	wip: explore removing delays(3)	2024-05-13 21:17:28 -05:00
Orion Kindel	f9446c97a0	wip: explore removing delays(2)	2024-05-13 21:15:45 -05:00
Orion Kindel	d3b8d1792d	wip: explore removing delays	2024-05-13 21:06:41 -05:00
Orion Kindel	e05c74f42f	fix: minor fixes	2024-05-13 15:04:34 -05:00
Orion Kindel	e1c2481e70	chore: prepare v1.3.3	2024-05-13 14:42:48 -05:00
Orion Kindel	820351f800	fix: more yields	2024-05-13 14:42:23 -05:00