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13 years ago
# Stream
Stability: 2 - Unstable
A stream is an abstract interface implemented by various objects in
Node. For example a [request to an HTTP
server](http.html#http_http_incomingmessage) is a stream, as is
[stdout][]. Streams are readable, writable, or both. All streams are
instances of [EventEmitter][]
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You can load the Stream base classes by doing `require('stream')`.
There are base classes provided for [Readable][] streams, [Writable][]
streams, [Duplex][] streams, and [Transform][] streams.
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This document is split up into 3 sections. The first explains the
parts of the API that you need to be aware of to use streams in your
programs. If you never implement a streaming API yourself, you can
stop there.
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The second section explains the parts of the API that you need to use
if you implement your own custom streams yourself. The API is
designed to make this easy for you to do.
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The third section goes into more depth about how streams work,
including some of the internal mechanisms and functions that you
should probably not modify unless you definitely know what you are
doing.
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## API for Stream Consumers
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<!--type=misc-->
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Streams can be either [Readable][], [Writable][], or both ([Duplex][]).
All streams are EventEmitters, but they also have other custom methods
and properties depending on whether they are Readable, Writable, or
Duplex.
If a stream is both Readable and Writable, then it implements all of
the methods and events below. So, a [Duplex][] or [Transform][] stream is
fully described by this API, though their implementation may be
somewhat different.
It is not necessary to implement Stream interfaces in order to consume
streams in your programs. If you **are** implementing streaming
interfaces in your own program, please also refer to
[API for Stream Implementors][] below.
Almost all Node programs, no matter how simple, use Streams in some
way. Here is an example of using Streams in a Node program:
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```javascript
var http = require('http');
var server = http.createServer(function (req, res) {
// req is an http.IncomingMessage, which is a Readable Stream
// res is an http.ServerResponse, which is a Writable Stream
var body = '';
// we want to get the data as utf8 strings
// If you don't set an encoding, then you'll get Buffer objects
req.setEncoding('utf8');
// Readable streams emit 'data' events once a listener is added
req.on('data', function (chunk) {
body += chunk;
})
// the end event tells you that you have entire body
req.on('end', function () {
try {
var data = JSON.parse(body);
} catch (er) {
// uh oh! bad json!
res.statusCode = 400;
return res.end('error: ' + er.message);
}
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// write back something interesting to the user:
res.write(typeof data);
res.end();
})
})
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server.listen(1337);
// $ curl localhost:1337 -d '{}'
// object
// $ curl localhost:1337 -d '"foo"'
// string
// $ curl localhost:1337 -d 'not json'
// error: Unexpected token o
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```
### Class: stream.Readable
12 years ago
<!--type=class-->
The Readable stream interface is the abstraction for a *source* of
data that you are reading from. In other words, data comes *out* of a
Readable stream.
A Readable stream will not start emitting data until you indicate that
you are ready to receive it.
Readable streams have two "modes": a **flowing mode** and a **non-flowing
mode**. When in flowing mode, data is read from the underlying system
and provided to your program as fast as possible. In non-flowing
mode, you must explicitly call `stream.read()` to get chunks of data
out.
Examples of readable streams include:
* [http responses, on the client](http.html#http_http_incomingmessage)
* [http requests, on the server](http.html#http_http_incomingmessage)
* [fs read streams](fs.html#fs_class_fs_readstream)
* [zlib streams][]
* [crypto streams][]
* [tcp sockets][]
* [child process stdout and stderr][]
* [process.stdin][]
#### Event: 'readable'
When a chunk of data can be read from the stream, it will emit a
`'readable'` event.
In some cases, listening for a `'readable'` event will cause some data
to be read into the internal buffer from the underlying system, if it
hadn't already.
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```javascript
var readable = getReadableStreamSomehow();
readable.on('readable', function() {
// there is some data to read now
})
```
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Once the internal buffer is drained, a `readable` event will fire
again when more data is available.
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#### Event: 'data'
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* `chunk` {Buffer | String} The chunk of data.
If you attach a `data` event listener, then it will switch the stream
into flowing mode, and data will be passed to your handler as soon as
it is available.
If you just want to get all the data out of the stream as fast as
possible, this is the best way to do so.
```javascript
var readable = getReadableStreamSomehow();
readable.on('data', function(chunk) {
console.log('got %d bytes of data', chunk.length);
})
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```
#### Event: 'end'
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This event fires when no more data will be provided.
Note that the `end` event **will not fire** unless the data is
completely consumed. This can be done by switching into flowing mode,
or by calling `read()` repeatedly until you get to the end.
```javascript
var readable = getReadableStreamSomehow();
readable.on('data', function(chunk) {
console.log('got %d bytes of data', chunk.length);
})
readable.on('end', function() {
console.log('there will be no more data.');
});
```
#### Event: 'close'
Emitted when the underlying resource (for example, the backing file
descriptor) has been closed. Not all streams will emit this.
#### Event: 'error'
Emitted if there was an error receiving data.
#### readable.read([size])
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* `size` {Number} Optional argument to specify how much data to read.
* Return {String | Buffer | null}
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The `read()` method pulls some data out of the internal buffer and
returns it. If there is no data available, then it will return
`null`.
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If you pass in a `size` argument, then it will return that many
bytes. If `size` bytes are not available, then it will return `null`.
If you do not specify a `size` argument, then it will return all the
data in the internal buffer.
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This method should only be called in non-flowing mode. In
flowing-mode, this method is called automatically until the internal
buffer is drained.
```javascript
var readable = getReadableStreamSomehow();
readable.on('readable', function() {
var chunk;
while (null !== (chunk = readable.read())) {
console.log('got %d bytes of data', chunk.length);
}
});
```
#### readable.setEncoding(encoding)
* `encoding` {String} The encoding to use.
Call this function to cause the stream to return strings of the
specified encoding instead of Buffer objects. For example, if you do
`readable.setEncoding('utf8')`, then the output data will be
interpreted as UTF-8 data, and returned as strings. If you do
`readable.setEncoding('hex')`, then the data will be encoded in
hexadecimal string format.
This properly handles multi-byte characters that would otherwise be
potentially mangled if you simply pulled the Buffers directly and
called `buf.toString(encoding)` on them. If you want to read the data
as strings, always use this method.
```javascript
var readable = getReadableStreamSomehow();
readable.setEncoding('utf8');
readable.on('data', function(chunk) {
assert.equal(typeof chunk, 'string');
console.log('got %d characters of string data', chunk.length);
})
```
#### readable.resume()
This method will cause the readable stream to resume emitting `data`
events.
This method will switch the stream into flowing-mode. If you do *not*
want to consume the data from a stream, but you *do* want to get to
its `end` event, you can call `readable.resume()` to open the flow of
data.
```javascript
var readable = getReadableStreamSomehow();
readable.resume();
readable.on('end', function(chunk) {
console.log('got to the end, but did not read anything');
})
```
#### readable.pause()
This method will cause a stream in flowing-mode to stop emitting
`data` events. Any data that becomes available will remain in the
internal buffer.
This method is only relevant in flowing mode. When called on a
non-flowing stream, it will switch into flowing mode, but remain
paused.
```javascript
var readable = getReadableStreamSomehow();
readable.on('data', function(chunk) {
console.log('got %d bytes of data', chunk.length);
readable.pause();
console.log('there will be no more data for 1 second');
setTimeout(function() {
console.log('now data will start flowing again');
readable.resume();
}, 1000);
})
```
#### readable.pipe(destination, [options])
* `destination` {[Writable][] Stream} The destination for writing data
* `options` {Object} Pipe options
* `end` {Boolean} End the writer when the reader ends. Default = `true`
This method pulls all the data out of a readable stream, and writes it
to the supplied destination, automatically managing the flow so that
the destination is not overwhelmed by a fast readable stream.
Multiple destinations can be piped to safely.
```javascript
var readable = getReadableStreamSomehow();
var writable = fs.createWriteStream('file.txt');
// All the data from readable goes into 'file.txt'
readable.pipe(writable);
```
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This function returns the destination stream, so you can set up pipe
chains like so:
```javascript
var r = fs.createReadStream('file.txt');
var z = zlib.createGzip();
var w = fs.createWriteStream('file.txt.gz');
r.pipe(z).pipe(w);
```
For example, emulating the Unix `cat` command:
```javascript
process.stdin.pipe(process.stdout);
```
By default [`end()`][] is called on the destination when the source stream
emits `end`, so that `destination` is no longer writable. Pass `{ end:
false }` as `options` to keep the destination stream open.
stream: Fix unshift() race conditions Fix #5272 The consumption of a readable stream is a dance with 3 partners. 1. The specific stream Author (A) 2. The Stream Base class (B), and 3. The Consumer of the stream (C) When B calls the _read() method that A implements, it sets a &#39;reading&#39; flag, so that parallel calls to _read() can be avoided. When A calls stream.push(), B knows that it&#39;s safe to start calling _read() again. If the consumer C is some kind of parser that wants in some cases to pass the source stream off to some other party, but not before &#34;putting back&#34; some bit of previously consumed data (as in the case of Node&#39;s websocket http upgrade implementation). So, stream.unshift() will generally *never* be called by A, but *only* called by C. Prior to this patch, stream.unshift() *also* unset the state.reading flag, meaning that C could indicate the end of a read, and B would dutifully fire off another _read() call to A. This is inappropriate. In the case of fs streams, and other variably-laggy streams that don&#39;t tolerate overlapped _read() calls, this causes big problems. Also, calling stream.shift() after the &#39;end&#39; event did not raise any kind of error, but would cause very strange behavior indeed. Calling it after the EOF chunk was seen, but before the &#39;end&#39; event was fired would also cause weird behavior, and could lead to data being lost, since it would not emit another &#39;readable&#39; event. This change makes it so that: 1. stream.unshift() does *not* set state.reading = false 2. stream.unshift() is allowed up until the &#39;end&#39; event. 3. unshifting onto a EOF-encountered and zero-length (but not yet end-emitted) stream will defer the &#39;end&#39; event until the new data is consumed. 4. pushing onto a EOF-encountered stream is now an error. So, if you read(), you have that single tick to safely unshift() data back into the stream, even if the null chunk was pushed, and the length was 0.
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This keeps `writer` open so that "Goodbye" can be written at the
end.
```javascript
reader.pipe(writer, { end: false });
reader.on('end', function() {
writer.end('Goodbye\n');
});
```
Note that `process.stderr` and `process.stdout` are never closed until
the process exits, regardless of the specified options.
#### readable.unpipe([destination])
* `destination` {[Writable][] Stream} Optional specific stream to unpipe
This method will remove the hooks set up for a previous `pipe()` call.
If the destination is not specified, then all pipes are removed.
stream: Fix unshift() race conditions Fix #5272 The consumption of a readable stream is a dance with 3 partners. 1. The specific stream Author (A) 2. The Stream Base class (B), and 3. The Consumer of the stream (C) When B calls the _read() method that A implements, it sets a &#39;reading&#39; flag, so that parallel calls to _read() can be avoided. When A calls stream.push(), B knows that it&#39;s safe to start calling _read() again. If the consumer C is some kind of parser that wants in some cases to pass the source stream off to some other party, but not before &#34;putting back&#34; some bit of previously consumed data (as in the case of Node&#39;s websocket http upgrade implementation). So, stream.unshift() will generally *never* be called by A, but *only* called by C. Prior to this patch, stream.unshift() *also* unset the state.reading flag, meaning that C could indicate the end of a read, and B would dutifully fire off another _read() call to A. This is inappropriate. In the case of fs streams, and other variably-laggy streams that don&#39;t tolerate overlapped _read() calls, this causes big problems. Also, calling stream.shift() after the &#39;end&#39; event did not raise any kind of error, but would cause very strange behavior indeed. Calling it after the EOF chunk was seen, but before the &#39;end&#39; event was fired would also cause weird behavior, and could lead to data being lost, since it would not emit another &#39;readable&#39; event. This change makes it so that: 1. stream.unshift() does *not* set state.reading = false 2. stream.unshift() is allowed up until the &#39;end&#39; event. 3. unshifting onto a EOF-encountered and zero-length (but not yet end-emitted) stream will defer the &#39;end&#39; event until the new data is consumed. 4. pushing onto a EOF-encountered stream is now an error. So, if you read(), you have that single tick to safely unshift() data back into the stream, even if the null chunk was pushed, and the length was 0.
12 years ago
If the destination is specified, but no pipe is set up for it, then
this is a no-op.
```javascript
var readable = getReadableStreamSomehow();
var writable = fs.createWriteStream('file.txt');
// All the data from readable goes into 'file.txt',
// but only for the first second
readable.pipe(writable);
setTimeout(function() {
console.log('stop writing to file.txt');
readable.unpipe(writable);
console.log('manually close the file stream');
writable.end();
}, 1000);
```
#### readable.unshift(chunk)
* `chunk` {Buffer | String} Chunk of data to unshift onto the read queue
stream: Fix unshift() race conditions Fix #5272 The consumption of a readable stream is a dance with 3 partners. 1. The specific stream Author (A) 2. The Stream Base class (B), and 3. The Consumer of the stream (C) When B calls the _read() method that A implements, it sets a &#39;reading&#39; flag, so that parallel calls to _read() can be avoided. When A calls stream.push(), B knows that it&#39;s safe to start calling _read() again. If the consumer C is some kind of parser that wants in some cases to pass the source stream off to some other party, but not before &#34;putting back&#34; some bit of previously consumed data (as in the case of Node&#39;s websocket http upgrade implementation). So, stream.unshift() will generally *never* be called by A, but *only* called by C. Prior to this patch, stream.unshift() *also* unset the state.reading flag, meaning that C could indicate the end of a read, and B would dutifully fire off another _read() call to A. This is inappropriate. In the case of fs streams, and other variably-laggy streams that don&#39;t tolerate overlapped _read() calls, this causes big problems. Also, calling stream.shift() after the &#39;end&#39; event did not raise any kind of error, but would cause very strange behavior indeed. Calling it after the EOF chunk was seen, but before the &#39;end&#39; event was fired would also cause weird behavior, and could lead to data being lost, since it would not emit another &#39;readable&#39; event. This change makes it so that: 1. stream.unshift() does *not* set state.reading = false 2. stream.unshift() is allowed up until the &#39;end&#39; event. 3. unshifting onto a EOF-encountered and zero-length (but not yet end-emitted) stream will defer the &#39;end&#39; event until the new data is consumed. 4. pushing onto a EOF-encountered stream is now an error. So, if you read(), you have that single tick to safely unshift() data back into the stream, even if the null chunk was pushed, and the length was 0.
12 years ago
This is useful in certain cases where a stream is being consumed by a
parser, which needs to "un-consume" some data that it has
optimistically pulled out of the source, so that the stream can be
passed on to some other party.
If you find that you must often call `stream.unshift(chunk)` in your
programs, consider implementing a [Transform][] stream instead. (See API
for Stream Implementors, below.)
```javascript
// Pull off a header delimited by \n\n
// use unshift() if we get too much
// Call the callback with (error, header, stream)
var StringDecoder = require('string_decoder').StringDecoder;
function parseHeader(stream, callback) {
stream.on('error', callback);
stream.on('readable', onReadable);
var decoder = new StringDecoder('utf8');
var header = '';
function onReadable() {
var chunk;
while (null !== (chunk = stream.read())) {
var str = decoder.write(chunk);
if (str.match(/\n\n/)) {
// found the header boundary
var split = str.split(/\n\n/);
header += split.shift();
var remaining = split.join('\n\n');
var buf = new Buffer(remaining, 'utf8');
if (buf.length)
stream.unshift(buf);
stream.removeListener('error', callback);
stream.removeListener('readable', onReadable);
// now the body of the message can be read from the stream.
callback(null, header, stream);
} else {
// still reading the header.
header += str;
}
}
}
}
```
#### readable.wrap(stream)
* `stream` {Stream} An "old style" readable stream
Versions of Node prior to v0.10 had streams that did not implement the
entire Streams API as it is today. (See "Compatibility" below for
more information.)
If you are using an older Node library that emits `'data'` events and
has a `pause()` method that is advisory only, then you can use the
`wrap()` method to create a [Readable][] stream that uses the old stream
as its data source.
You will very rarely ever need to call this function, but it exists
as a convenience for interacting with old Node programs and libraries.
For example:
```javascript
var OldReader = require('./old-api-module.js').OldReader;
var oreader = new OldReader;
var Readable = require('stream').Readable;
var myReader = new Readable().wrap(oreader);
myReader.on('readable', function() {
myReader.read(); // etc.
});
```
### Class: stream.Writable
<!--type=class-->
The Writable stream interface is an abstraction for a *destination*
that you are writing data *to*.
Examples of writable streams include:
* [http requests, on the client](http.html#http_class_http_clientrequest)
* [http responses, on the server](http.html#http_class_http_serverresponse)
* [fs write streams](fs.html#fs_class_fs_writestream)
* [zlib streams][]
* [crypto streams][]
* [tcp sockets][]
* [child process stdin](child_process.html#child_process_child_stdin)
* [process.stdout][], [process.stderr][]
#### writable.write(chunk, [encoding], [callback])
* `chunk` {String | Buffer} The data to write
* `encoding` {String} The encoding, if `chunk` is a String
* `callback` {Function} Callback for when this chunk of data is flushed
* Returns: {Boolean} True if the data was handled completely.
This method writes some data to the underlying system, and calls the
supplied callback once the data has been fully handled.
The return value indicates if you should continue writing right now.
If the data had to be buffered internally, then it will return
`false`. Otherwise, it will return `true`.
This return value is strictly advisory. You MAY continue to write,
even if it returns `false`. However, writes will be buffered in
memory, so it is best not to do this excessively. Instead, wait for
the `drain` event before writing more data.
#### Event: 'drain'
If a [`writable.write(chunk)`][] call returns false, then the `drain`
event will indicate when it is appropriate to begin writing more data
to the stream.
```javascript
// Write the data to the supplied writable stream 1MM times.
// Be attentive to back-pressure.
function writeOneMillionTimes(writer, data, encoding, callback) {
var i = 1000000;
write();
function write() {
var ok = true;
do {
i -= 1;
if (i === 0) {
// last time!
writer.write(data, encoding, callback);
} else {
// see if we should continue, or wait
// don't pass the callback, because we're not done yet.
ok = writer.write(data, encoding);
}
} while (i > 0 && ok);
if (i > 0) {
// had to stop early!
// write some more once it drains
writer.once('drain', write);
}
}
}
```
#### writable.cork()
Forces buffering of all writes.
Buffered data will be flushed either at `.uncork()` or at `.end()` call.
#### writable.uncork()
Flush all data, buffered since `.cork()` call.
#### writable.end([chunk], [encoding], [callback])
* `chunk` {String | Buffer} Optional data to write
* `encoding` {String} The encoding, if `chunk` is a String
* `callback` {Function} Optional callback for when the stream is finished
Call this method when no more data will be written to the stream. If
supplied, the callback is attached as a listener on the `finish` event.
Calling [`write()`][] after calling [`end()`][] will raise an error.
```javascript
// write 'hello, ' and then end with 'world!'
http.createServer(function (req, res) {
res.write('hello, ');
res.end('world!');
// writing more now is not allowed!
});
```
#### Event: 'finish'
When the [`end()`][] method has been called, and all data has been flushed
to the underlying system, this event is emitted.
```javascript
var writer = getWritableStreamSomehow();
for (var i = 0; i < 100; i ++) {
writer.write('hello, #' + i + '!\n');
}
writer.end('this is the end\n');
write.on('finish', function() {
console.error('all writes are now complete.');
});
```
#### Event: 'pipe'
* `src` {[Readable][] Stream} source stream that is piping to this writable
This is emitted whenever the `pipe()` method is called on a readable
stream, adding this writable to its set of destinations.
```javascript
var writer = getWritableStreamSomehow();
var reader = getReadableStreamSomehow();
writer.on('pipe', function(src) {
console.error('something is piping into the writer');
assert.equal(src, reader);
});
reader.pipe(writer);
```
#### Event: 'unpipe'
* `src` {[Readable][] Stream} The source stream that [unpiped][] this writable
This is emitted whenever the [`unpipe()`][] method is called on a
readable stream, removing this writable from its set of destinations.
```javascript
var writer = getWritableStreamSomehow();
var reader = getReadableStreamSomehow();
writer.on('unpipe', function(src) {
console.error('something has stopped piping into the writer');
assert.equal(src, reader);
});
reader.pipe(writer);
reader.unpipe(writer);
```
### Class: stream.Duplex
Duplex streams are streams that implement both the [Readable][] and
[Writable][] interfaces. See above for usage.
Examples of Duplex streams include:
* [tcp sockets][]
* [zlib streams][]
* [crypto streams][]
### Class: stream.Transform
Transform streams are [Duplex][] streams where the output is in some way
computed from the input. They implement both the [Readable][] and
[Writable][] interfaces. See above for usage.
Examples of Transform streams include:
* [zlib streams][]
* [crypto streams][]
## API for Stream Implementors
<!--type=misc-->
To implement any sort of stream, the pattern is the same:
1. Extend the appropriate parent class in your own subclass. (The
[`util.inherits`][] method is particularly helpful for this.)
2. Call the appropriate parent class constructor in your constructor,
to be sure that the internal mechanisms are set up properly.
2. Implement one or more specific methods, as detailed below.
The class to extend and the method(s) to implement depend on the sort
of stream class you are writing:
<table>
<thead>
<tr>
<th>
<p>Use-case</p>
</th>
<th>
<p>Class</p>
</th>
<th>
<p>Method(s) to implement</p>
</th>
</tr>
</thead>
<tr>
<td>
<p>Reading only</p>
</td>
<td>
<p>[Readable](#stream_class_stream_readable_1)</p>
</td>
<td>
<p><code>[_read][]</code></p>
</td>
</tr>
<tr>
<td>
<p>Writing only</p>
</td>
<td>
<p>[Writable](#stream_class_stream_writable_1)</p>
</td>
<td>
<p><code>[_write][]</code></p>
</td>
</tr>
<tr>
<td>
<p>Reading and writing</p>
</td>
<td>
<p>[Duplex](#stream_class_stream_duplex_1)</p>
</td>
<td>
<p><code>[_read][]</code>, <code>[_write][]</code></p>
</td>
</tr>
<tr>
<td>
<p>Operate on written data, then read the result</p>
</td>
<td>
<p>[Transform](#stream_class_stream_transform_1)</p>
</td>
<td>
<p><code>_transform</code>, <code>_flush</code></p>
</td>
</tr>
</table>
In your implementation code, it is very important to never call the
methods described in [API for Stream Consumers][] above. Otherwise, you
can potentially cause adverse side effects in programs that consume
your streaming interfaces.
### Class: stream.Readable
<!--type=class-->
`stream.Readable` is an abstract class designed to be extended with an
underlying implementation of the [`_read(size)`][] method.
Please see above under [API for Stream Consumers][] for how to consume
streams in your programs. What follows is an explanation of how to
implement Readable streams in your programs.
#### Example: A Counting Stream
<!--type=example-->
This is a basic example of a Readable stream. It emits the numerals
from 1 to 1,000,000 in ascending order, and then ends.
```javascript
var Readable = require('stream').Readable;
var util = require('util');
util.inherits(Counter, Readable);
function Counter(opt) {
Readable.call(this, opt);
this._max = 1000000;
this._index = 1;
}
Counter.prototype._read = function() {
var i = this._index++;
if (i > this._max)
this.push(null);
else {
var str = '' + i;
var buf = new Buffer(str, 'ascii');
this.push(buf);
}
};
```
#### Example: SimpleProtocol v1 (Sub-optimal)
This is similar to the `parseHeader` function described above, but
implemented as a custom stream. Also, note that this implementation
does not convert the incoming data to a string.
However, this would be better implemented as a [Transform][] stream. See
below for a better implementation.
```javascript
// A parser for a simple data protocol.
// The "header" is a JSON object, followed by 2 \n characters, and
// then a message body.
//
stream: Fix unshift() race conditions Fix #5272 The consumption of a readable stream is a dance with 3 partners. 1. The specific stream Author (A) 2. The Stream Base class (B), and 3. The Consumer of the stream (C) When B calls the _read() method that A implements, it sets a &#39;reading&#39; flag, so that parallel calls to _read() can be avoided. When A calls stream.push(), B knows that it&#39;s safe to start calling _read() again. If the consumer C is some kind of parser that wants in some cases to pass the source stream off to some other party, but not before &#34;putting back&#34; some bit of previously consumed data (as in the case of Node&#39;s websocket http upgrade implementation). So, stream.unshift() will generally *never* be called by A, but *only* called by C. Prior to this patch, stream.unshift() *also* unset the state.reading flag, meaning that C could indicate the end of a read, and B would dutifully fire off another _read() call to A. This is inappropriate. In the case of fs streams, and other variably-laggy streams that don&#39;t tolerate overlapped _read() calls, this causes big problems. Also, calling stream.shift() after the &#39;end&#39; event did not raise any kind of error, but would cause very strange behavior indeed. Calling it after the EOF chunk was seen, but before the &#39;end&#39; event was fired would also cause weird behavior, and could lead to data being lost, since it would not emit another &#39;readable&#39; event. This change makes it so that: 1. stream.unshift() does *not* set state.reading = false 2. stream.unshift() is allowed up until the &#39;end&#39; event. 3. unshifting onto a EOF-encountered and zero-length (but not yet end-emitted) stream will defer the &#39;end&#39; event until the new data is consumed. 4. pushing onto a EOF-encountered stream is now an error. So, if you read(), you have that single tick to safely unshift() data back into the stream, even if the null chunk was pushed, and the length was 0.
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// NOTE: This can be done more simply as a Transform stream!
// Using Readable directly for this is sub-optimal. See the
// alternative example below under the Transform section.
var Readable = require('stream').Readable;
var util = require('util');
util.inherits(SimpleProtocol, Readable);
function SimpleProtocol(source, options) {
if (!(this instanceof SimpleProtocol))
return new SimpleProtocol(options);
Readable.call(this, options);
this._inBody = false;
this._sawFirstCr = false;
// source is a readable stream, such as a socket or file
this._source = source;
var self = this;
source.on('end', function() {
self.push(null);
});
// give it a kick whenever the source is readable
// read(0) will not consume any bytes
source.on('readable', function() {
self.read(0);
});
this._rawHeader = [];
this.header = null;
}
SimpleProtocol.prototype._read = function(n) {
if (!this._inBody) {
var chunk = this._source.read();
// if the source doesn't have data, we don't have data yet.
if (chunk === null)
return this.push('');
// check if the chunk has a \n\n
var split = -1;
for (var i = 0; i < chunk.length; i++) {
if (chunk[i] === 10) { // '\n'
if (this._sawFirstCr) {
split = i;
break;
} else {
this._sawFirstCr = true;
}
} else {
this._sawFirstCr = false;
}
}
if (split === -1) {
// still waiting for the \n\n
// stash the chunk, and try again.
this._rawHeader.push(chunk);
this.push('');
} else {
this._inBody = true;
var h = chunk.slice(0, split);
this._rawHeader.push(h);
var header = Buffer.concat(this._rawHeader).toString();
try {
this.header = JSON.parse(header);
} catch (er) {
this.emit('error', new Error('invalid simple protocol data'));
return;
}
// now, because we got some extra data, unshift the rest
// back into the read queue so that our consumer will see it.
var b = chunk.slice(split);
this.unshift(b);
// and let them know that we are done parsing the header.
this.emit('header', this.header);
}
} else {
// from there on, just provide the data to our consumer.
// careful not to push(null), since that would indicate EOF.
var chunk = this._source.read();
if (chunk) this.push(chunk);
}
};
// Usage:
// var parser = new SimpleProtocol(source);
// Now parser is a readable stream that will emit 'header'
// with the parsed header data.
```
#### new stream.Readable([options])
* `options` {Object}
* `highWaterMark` {Number} The maximum number of bytes to store in
the internal buffer before ceasing to read from the underlying
resource. Default=16kb
* `encoding` {String} If specified, then buffers will be decoded to
strings using the specified encoding. Default=null
* `objectMode` {Boolean} Whether this stream should behave
as a stream of objects. Meaning that stream.read(n) returns
a single value instead of a Buffer of size n
In classes that extend the Readable class, make sure to call the
Readable constructor so that the buffering settings can be properly
initialized.
#### readable.\_read(size)
* `size` {Number} Number of bytes to read asynchronously
Note: **Implement this function, but do NOT call it directly.**
This function should NOT be called directly. It should be implemented
by child classes, and only called by the internal Readable class
methods.
All Readable stream implementations must provide a `_read` method to
fetch data from the underlying resource.
This method is prefixed with an underscore because it is internal to
the class that defines it, and should not be called directly by user
programs. However, you **are** expected to override this method in
your own extension classes.
When data is available, put it into the read queue by calling
`readable.push(chunk)`. If `push` returns false, then you should stop
reading. When `_read` is called again, you should start pushing more
data.
The `size` argument is advisory. Implementations where a "read" is a
single call that returns data can use this to know how much data to
fetch. Implementations where that is not relevant, such as TCP or
TLS, may ignore this argument, and simply provide data whenever it
becomes available. There is no need, for example to "wait" until
`size` bytes are available before calling [`stream.push(chunk)`][].
#### readable.push(chunk, [encoding])
* `chunk` {Buffer | null | String} Chunk of data to push into the read queue
* `encoding` {String} Encoding of String chunks. Must be a valid
Buffer encoding, such as `'utf8'` or `'ascii'`
* return {Boolean} Whether or not more pushes should be performed
Note: **This function should be called by Readable implementors, NOT
by consumers of Readable streams.**
The `_read()` function will not be called again until at least one
`push(chunk)` call is made.
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The `Readable` class works by putting data into a read queue to be
pulled out later by calling the `read()` method when the `'readable'`
event fires.
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The `push()` method will explicitly insert some data into the read
queue. If it is called with `null` then it will signal the end of the
data (EOF).
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This API is designed to be as flexible as possible. For example,
you may be wrapping a lower-level source which has some sort of
pause/resume mechanism, and a data callback. In those cases, you
could wrap the low-level source object by doing something like this:
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```javascript
// source is an object with readStop() and readStart() methods,
// and an `ondata` member that gets called when it has data, and
// an `onend` member that gets called when the data is over.
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util.inherits(SourceWrapper, Readable);
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function SourceWrapper(options) {
Readable.call(this, options);
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this._source = getLowlevelSourceObject();
var self = this;
// Every time there's data, we push it into the internal buffer.
this._source.ondata = function(chunk) {
// if push() returns false, then we need to stop reading from source
if (!self.push(chunk))
self._source.readStop();
};
// When the source ends, we push the EOF-signalling `null` chunk
this._source.onend = function() {
self.push(null);
};
}
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// _read will be called when the stream wants to pull more data in
// the advisory size argument is ignored in this case.
SourceWrapper.prototype._read = function(size) {
this._source.readStart();
};
```
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### Class: stream.Writable
<!--type=class-->
`stream.Writable` is an abstract class designed to be extended with an
underlying implementation of the [`_write(chunk, encoding, callback)`][] method.
Please see above under [API for Stream Consumers][] for how to consume
writable streams in your programs. What follows is an explanation of
how to implement Writable streams in your programs.
#### new stream.Writable([options])
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* `options` {Object}
* `highWaterMark` {Number} Buffer level when [`write()`][] starts
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returning false. Default=16kb
* `decodeStrings` {Boolean} Whether or not to decode strings into
Buffers before passing them to [`_write()`][]. Default=true
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In classes that extend the Writable class, make sure to call the
constructor so that the buffering settings can be properly
initialized.
#### writable.\_write(chunk, encoding, callback)
* `chunk` {Buffer | String} The chunk to be written. Will always
be a buffer unless the `decodeStrings` option was set to `false`.
* `encoding` {String} If the chunk is a string, then this is the
encoding type. Ignore chunk is a buffer. Note that chunk will
**always** be a buffer unless the `decodeStrings` option is
explicitly set to `false`.
* `callback` {Function} Call this function (optionally with an error
argument) when you are done processing the supplied chunk.
All Writable stream implementations must provide a [`_write()`][]
method to send data to the underlying resource.
Note: **This function MUST NOT be called directly.** It should be
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implemented by child classes, and called by the internal Writable
class methods only.
Call the callback using the standard `callback(error)` pattern to
signal that the write completed successfully or with an error.
If the `decodeStrings` flag is set in the constructor options, then
`chunk` may be a string rather than a Buffer, and `encoding` will
indicate the sort of string that it is. This is to support
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implementations that have an optimized handling for certain string
data encodings. If you do not explicitly set the `decodeStrings`
option to `false`, then you can safely ignore the `encoding` argument,
and assume that `chunk` will always be a Buffer.
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This method is prefixed with an underscore because it is internal to
the class that defines it, and should not be called directly by user
programs. However, you **are** expected to override this method in
your own extension classes.
### writable.\_writev(chunks, callback)
* `chunks` {Array} The chunks to be written. Each chunk has following
format: `{ chunk: ..., encoding: ... }`.
* `callback` {Function} Call this function (optionally with an error
argument) when you are done processing the supplied chunks.
Note: **This function MUST NOT be called directly.** It may be
implemented by child classes, and called by the internal Writable
class methods only.
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This function is completely optional to implement. In most cases it is
unnecessary. If implemented, it will be called with all the chunks
that are buffered in the write queue.
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### Class: stream.Duplex
12 years ago
<!--type=class-->
A "duplex" stream is one that is both Readable and Writable, such as a
TCP socket connection.
Note that `stream.Duplex` is an abstract class designed to be extended
with an underlying implementation of the `_read(size)` and
[`_write(chunk, encoding, callback)`][] methods as you would with a
Readable or Writable stream class.
12 years ago
Since JavaScript doesn't have multiple prototypal inheritance, this
class prototypally inherits from Readable, and then parasitically from
Writable. It is thus up to the user to implement both the lowlevel
`_read(n)` method as well as the lowlevel
[`_write(chunk, encoding, callback)`][] method on extension duplex classes.
12 years ago
#### new stream.Duplex(options)
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* `options` {Object} Passed to both Writable and Readable
constructors. Also has the following fields:
* `allowHalfOpen` {Boolean} Default=true. If set to `false`, then
the stream will automatically end the readable side when the
writable side ends and vice versa.
In classes that extend the Duplex class, make sure to call the
constructor so that the buffering settings can be properly
initialized.
### Class: stream.Transform
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A "transform" stream is a duplex stream where the output is causally
connected in some way to the input, such as a [zlib][] stream or a
[crypto][] stream.
12 years ago
There is no requirement that the output be the same size as the input,
the same number of chunks, or arrive at the same time. For example, a
Hash stream will only ever have a single chunk of output which is
provided when the input is ended. A zlib stream will either produce
much smaller or much larger than its input.
Rather than implement the [`_read()`][] and [`_write()`][] methods, Transform
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classes must implement the `_transform()` method, and may optionally
also implement the `_flush()` method. (See below.)
#### new stream.Transform([options])
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* `options` {Object} Passed to both Writable and Readable
constructors.
In classes that extend the Transform class, make sure to call the
constructor so that the buffering settings can be properly
initialized.
#### transform.\_transform(chunk, encoding, callback)
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* `chunk` {Buffer | String} The chunk to be transformed. Will always
be a buffer unless the `decodeStrings` option was set to `false`.
* `encoding` {String} If the chunk is a string, then this is the
encoding type. (Ignore if `decodeStrings` chunk is a buffer.)
12 years ago
* `callback` {Function} Call this function (optionally with an error
argument) when you are done processing the supplied chunk.
Note: **This function MUST NOT be called directly.** It should be
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implemented by child classes, and called by the internal Transform
class methods only.
All Transform stream implementations must provide a `_transform`
method to accept input and produce output.
12 years ago
`_transform` should do whatever has to be done in this specific
Transform class, to handle the bytes being written, and pass them off
to the readable portion of the interface. Do asynchronous I/O,
process things, and so on.
Call `transform.push(outputChunk)` 0 or more times to generate output
from this input chunk, depending on how much data you want to output
as a result of this chunk.
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Call the callback function only when the current chunk is completely
consumed. Note that there may or may not be output as a result of any
particular input chunk.
12 years ago
This method is prefixed with an underscore because it is internal to
the class that defines it, and should not be called directly by user
programs. However, you **are** expected to override this method in
your own extension classes.
#### transform.\_flush(callback)
12 years ago
* `callback` {Function} Call this function (optionally with an error
argument) when you are done flushing any remaining data.
Note: **This function MUST NOT be called directly.** It MAY be implemented
12 years ago
by child classes, and if so, will be called by the internal Transform
class methods only.
12 years ago
In some cases, your transform operation may need to emit a bit more
data at the end of the stream. For example, a `Zlib` compression
stream will store up some internal state so that it can optimally
compress the output. At the end, however, it needs to do the best it
can with what is left, so that the data will be complete.
12 years ago
In those cases, you can implement a `_flush` method, which will be
called at the very end, after all the written data is consumed, but
before emitting `end` to signal the end of the readable side. Just
like with `_transform`, call `transform.push(chunk)` zero or more
times, as appropriate, and call `callback` when the flush operation is
complete.
12 years ago
This method is prefixed with an underscore because it is internal to
the class that defines it, and should not be called directly by user
programs. However, you **are** expected to override this method in
your own extension classes.
#### Example: `SimpleProtocol` parser v2
The example above of a simple protocol parser can be implemented
simply by using the higher level [Transform][] stream class, similar to
the `parseHeader` and `SimpleProtocol v1` examples above.
In this example, rather than providing the input as an argument, it
would be piped into the parser, which is a more idiomatic Node stream
approach.
```javascript
var util = require('util');
var Transform = require('stream').Transform);
util.inherits(SimpleProtocol, Transform);
function SimpleProtocol(options) {
if (!(this instanceof SimpleProtocol))
return new SimpleProtocol(options);
Transform.call(this, options);
this._inBody = false;
this._sawFirstCr = false;
this._rawHeader = [];
this.header = null;
}
SimpleProtocol.prototype._transform = function(chunk, encoding, done) {
if (!this._inBody) {
// check if the chunk has a \n\n
var split = -1;
for (var i = 0; i < chunk.length; i++) {
if (chunk[i] === 10) { // '\n'
if (this._sawFirstCr) {
split = i;
break;
} else {
this._sawFirstCr = true;
}
} else {
this._sawFirstCr = false;
}
}
if (split === -1) {
// still waiting for the \n\n
// stash the chunk, and try again.
this._rawHeader.push(chunk);
} else {
this._inBody = true;
var h = chunk.slice(0, split);
this._rawHeader.push(h);
var header = Buffer.concat(this._rawHeader).toString();
try {
this.header = JSON.parse(header);
} catch (er) {
this.emit('error', new Error('invalid simple protocol data'));
return;
}
// and let them know that we are done parsing the header.
this.emit('header', this.header);
// now, because we got some extra data, emit this first.
this.push(chunk.slice(split));
}
} else {
// from there on, just provide the data to our consumer as-is.
this.push(chunk);
}
done();
};
// Usage:
// var parser = new SimpleProtocol();
// source.pipe(parser)
// Now parser is a readable stream that will emit 'header'
// with the parsed header data.
```
### Class: stream.PassThrough
This is a trivial implementation of a [Transform][] stream that simply
12 years ago
passes the input bytes across to the output. Its purpose is mainly
for examples and testing, but there are occasionally use cases where
it can come in handy as a building block for novel sorts of streams.
## Streams: Under the Hood
<!--type=misc-->
### Buffering
<!--type=misc-->
Both Writable and Readable streams will buffer data on an internal
object called `_writableState.buffer` or `_readableState.buffer`,
respectively.
The amount of data that will potentially be buffered depends on the
`highWaterMark` option which is passed into the constructor.
Buffering in Readable streams happens when the implementation calls
[`stream.push(chunk)`][]. If the consumer of the Stream does not call
`stream.read()`, then the data will sit in the internal queue until it
is consumed.
Buffering in Writable streams happens when the user calls
[`stream.write(chunk)`][] repeatedly, even when `write()` returns `false`.
The purpose of streams, especially with the `pipe()` method, is to
limit the buffering of data to acceptable levels, so that sources and
destinations of varying speed will not overwhelm the available memory.
### `stream.read(0)`
There are some cases where you want to trigger a refresh of the
underlying readable stream mechanisms, without actually consuming any
data. In that case, you can call `stream.read(0)`, which will always
return null.
If the internal read buffer is below the `highWaterMark`, and the
stream is not currently reading, then calling `read(0)` will trigger
a low-level `_read` call.
There is almost never a need to do this. However, you will see some
cases in Node's internals where this is done, particularly in the
Readable stream class internals.
### `stream.push('')`
Pushing a zero-byte string or Buffer (when not in [Object mode][]) has an
interesting side effect. Because it *is* a call to
[`stream.push()`][], it will end the `reading` process. However, it
does *not* add any data to the readable buffer, so there's nothing for
a user to consume.
Very rarely, there are cases where you have no data to provide now,
but the consumer of your stream (or, perhaps, another bit of your own
code) will know when to check again, by calling `stream.read(0)`. In
those cases, you *may* call `stream.push('')`.
So far, the only use case for this functionality is in the
[tls.CryptoStream][] class, which is deprecated in Node v0.12. If you
find that you have to use `stream.push('')`, please consider another
approach, because it almost certainly indicates that something is
horribly wrong.
### Compatibility with Older Node Versions
<!--type=misc-->
In versions of Node prior to v0.10, the Readable stream interface was
simpler, but also less powerful and less useful.
* Rather than waiting for you to call the `read()` method, `'data'`
events would start emitting immediately. If you needed to do some
I/O to decide how to handle data, then you had to store the chunks
in some kind of buffer so that they would not be lost.
* The `pause()` method was advisory, rather than guaranteed. This
meant that you still had to be prepared to receive `'data'` events
even when the stream was in a paused state.
In Node v0.10, the Readable class described below was added. For
backwards compatibility with older Node programs, Readable streams
switch into "flowing mode" when a `'data'` event handler is added, or
when the `pause()` or `resume()` methods are called. The effect is
that, even if you are not using the new `read()` method and
`'readable'` event, you no longer have to worry about losing `'data'`
chunks.
Most programs will continue to function normally. However, this
introduces an edge case in the following conditions:
* No `'data'` event handler is added.
* The `pause()` and `resume()` methods are never called.
For example, consider the following code:
```javascript
// WARNING! BROKEN!
net.createServer(function(socket) {
// we add an 'end' method, but never consume the data
socket.on('end', function() {
// It will never get here.
socket.end('I got your message (but didnt read it)\n');
});
}).listen(1337);
```
In versions of node prior to v0.10, the incoming message data would be
simply discarded. However, in Node v0.10 and beyond, the socket will
remain paused forever.
The workaround in this situation is to call the `resume()` method to
trigger "old mode" behavior:
```javascript
// Workaround
net.createServer(function(socket) {
socket.on('end', function() {
socket.end('I got your message (but didnt read it)\n');
});
// start the flow of data, discarding it.
socket.resume();
}).listen(1337);
```
In addition to new Readable streams switching into flowing-mode, pre-v0.10
style streams can be wrapped in a Readable class using the `wrap()`
method.
### Object Mode
<!--type=misc-->
Normally, Streams operate on Strings and Buffers exclusively.
Streams that are in **object mode** can emit generic JavaScript values
other than Buffers and Strings.
A Readable stream in object mode will always return a single item from
a call to `stream.read(size)`, regardless of what the size argument
is.
A Writable stream in object mode will always ignore the `encoding`
argument to `stream.write(data, encoding)`.
The special value `null` still retains its special value for object
mode streams. That is, for object mode readable streams, `null` as a
return value from `stream.read()` indicates that there is no more
data, and [`stream.push(null)`][] will signal the end of stream data
(`EOF`).
No streams in Node core are object mode streams. This pattern is only
used by userland streaming libraries.
You should set `objectMode` in your stream child class constructor on
the options object. Setting `objectMode` mid-stream is not safe.
### State Objects
[Readable][] streams have a member object called `_readableState`.
[Writable][] streams have a member object called `_writableState`.
[Duplex][] streams have both.
**These objects should generally not be modified in child classes.**
However, if you have a Duplex or Transform stream that should be in
`objectMode` on the readable side, and not in `objectMode` on the
writable side, then you may do this in the constructor by setting the
flag explicitly on the appropriate state object.
```javascript
var util = require('util');
var StringDecoder = require('string_decoder').StringDecoder;
var Transform = require('stream').Transform;
util.inherits(JSONParseStream, Transform);
// Gets \n-delimited JSON string data, and emits the parsed objects
function JSONParseStream(options) {
if (!(this instanceof JSONParseStream))
return new JSONParseStream(options);
Transform.call(this, options);
this._writableState.objectMode = false;
this._readableState.objectMode = true;
this._buffer = '';
this._decoder = new StringDecoder('utf8');
}
JSONParseStream.prototype._transform = function(chunk, encoding, cb) {
this._buffer += this._decoder.write(chunk);
// split on newlines
var lines = this._buffer.split(/\r?\n/);
// keep the last partial line buffered
this._buffer = lines.pop();
for (var l = 0; l < lines.length; l++) {
var line = lines[l];
try {
var obj = JSON.parse(line);
} catch (er) {
this.emit('error', er);
return;
}
// push the parsed object out to the readable consumer
this.push(obj);
}
cb();
};
JSONParseStream.prototype._flush = function(cb) {
// Just handle any leftover
var rem = this._buffer.trim();
if (rem) {
try {
var obj = JSON.parse(rem);
} catch (er) {
this.emit('error', er);
return;
}
// push the parsed object out to the readable consumer
this.push(obj);
}
cb();
};
```
The state objects contain other useful information for debugging the
state of streams in your programs. It is safe to look at them, but
beyond setting option flags in the constructor, it is **not** safe to
modify them.
[EventEmitter]: events.html#events_class_events_eventemitter
[Object mode]: #stream_object_mode
[`stream.push(chunk)`]: #stream_readable_push_chunk_encoding
[`stream.push(null)`]: #stream_readable_push_chunk_encoding
[`stream.push()`]: #stream_readable_push_chunk_encoding
[`unpipe()`]: #stream_readable_unpipe_destination
[unpiped]: #stream_readable_unpipe_destination
[tcp sockets]: net.html#net_class_net_socket
[zlib streams]: zlib.html
[zlib]: zlib.html
[crypto streams]: crypto.html
[crypto]: crypto.html
[tls.CryptoStream]: tls.html#tls_class_cryptostream
[process.stdin]: process.html#process_process_stdin
[stdout]: process.html#process_process_stdout
[process.stdout]: process.html#process_process_stdout
[process.stderr]: process.html#process_process_stderr
[child process stdout and stderr]: child_process.html#child_process_child_stdout
[API for Stream Consumers]: #stream_api_for_stream_consumers
[API for Stream Implementors]: #stream_api_for_stream_implementors
[Readable]: #stream_class_stream_readable
[Writable]: #stream_class_stream_writable
[Duplex]: #stream_class_stream_duplex
[Transform]: #stream_class_stream_transform
[`_read(size)`]: #stream_readable_read_size_1
[`_read()`]: #stream_readable_read_size_1
[_read]: #stream_readable_read_size_1
[`writable.write(chunk)`]
[`write(chunk, encoding, callback)`]: #stream_writable_write_chunk_encoding_callback
[`write()`]: #stream_writable_write_chunk_encoding_callback
[`stream.write(chunk)`]: #stream_writable_write_chunk_encoding_callback
[`_write(chunk, encoding, callback)`]: #stream_writable_write_chunk_encoding_callback_1
[`_write()`]: #stream_writable_write_chunk_encoding_callback_1
[_write]: #stream_writable_write_chunk_encoding_callback_1
[`util.inherits`]: util.html#util_util_inherits_constructor_superconstructor
[`end()`]: #stream_writable_end_chunk_encoding_callback