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Markdown
770 lines
25 KiB
Markdown
# minipass
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A _very_ minimal implementation of a [PassThrough
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stream](https://nodejs.org/api/stream.html#stream_class_stream_passthrough)
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[It's very
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fast](https://docs.google.com/spreadsheets/d/1K_HR5oh3r80b8WVMWCPPjfuWXUgfkmhlX7FGI6JJ8tY/edit?usp=sharing)
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for objects, strings, and buffers.
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Supports `pipe()`ing (including multi-`pipe()` and backpressure
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transmission), buffering data until either a `data` event handler
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or `pipe()` is added (so you don't lose the first chunk), and
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most other cases where PassThrough is a good idea.
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There is a `read()` method, but it's much more efficient to
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consume data from this stream via `'data'` events or by calling
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`pipe()` into some other stream. Calling `read()` requires the
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buffer to be flattened in some cases, which requires copying
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memory.
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If you set `objectMode: true` in the options, then whatever is
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written will be emitted. Otherwise, it'll do a minimal amount of
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Buffer copying to ensure proper Streams semantics when `read(n)`
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is called.
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`objectMode` can also be set by doing `stream.objectMode = true`,
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or by writing any non-string/non-buffer data. `objectMode` cannot
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be set to false once it is set.
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This is not a `through` or `through2` stream. It doesn't
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transform the data, it just passes it right through. If you want
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to transform the data, extend the class, and override the
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`write()` method. Once you're done transforming the data however
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you want, call `super.write()` with the transform output.
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For some examples of streams that extend Minipass in various
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ways, check out:
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- [minizlib](http://npm.im/minizlib)
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- [fs-minipass](http://npm.im/fs-minipass)
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- [tar](http://npm.im/tar)
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- [minipass-collect](http://npm.im/minipass-collect)
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- [minipass-flush](http://npm.im/minipass-flush)
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- [minipass-pipeline](http://npm.im/minipass-pipeline)
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- [tap](http://npm.im/tap)
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- [tap-parser](http://npm.im/tap-parser)
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- [treport](http://npm.im/treport)
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- [minipass-fetch](http://npm.im/minipass-fetch)
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- [pacote](http://npm.im/pacote)
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- [make-fetch-happen](http://npm.im/make-fetch-happen)
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- [cacache](http://npm.im/cacache)
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- [ssri](http://npm.im/ssri)
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- [npm-registry-fetch](http://npm.im/npm-registry-fetch)
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- [minipass-json-stream](http://npm.im/minipass-json-stream)
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- [minipass-sized](http://npm.im/minipass-sized)
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## Differences from Node.js Streams
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There are several things that make Minipass streams different
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from (and in some ways superior to) Node.js core streams.
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Please read these caveats if you are familiar with node-core
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streams and intend to use Minipass streams in your programs.
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You can avoid most of these differences entirely (for a very
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small performance penalty) by setting `{async: true}` in the
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constructor options.
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### Timing
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Minipass streams are designed to support synchronous use-cases.
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Thus, data is emitted as soon as it is available, always. It is
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buffered until read, but no longer. Another way to look at it is
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that Minipass streams are exactly as synchronous as the logic
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that writes into them.
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This can be surprising if your code relies on
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`PassThrough.write()` always providing data on the next tick
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rather than the current one, or being able to call `resume()` and
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not have the entire buffer disappear immediately.
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However, without this synchronicity guarantee, there would be no
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way for Minipass to achieve the speeds it does, or support the
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synchronous use cases that it does. Simply put, waiting takes
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time.
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This non-deferring approach makes Minipass streams much easier to
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reason about, especially in the context of Promises and other
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flow-control mechanisms.
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Example:
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```js
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// hybrid module, either works
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import { Minipass } from 'minipass'
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// or:
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const { Minipass } = require('minipass')
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const stream = new Minipass()
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stream.on('data', () => console.log('data event'))
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console.log('before write')
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stream.write('hello')
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console.log('after write')
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// output:
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// before write
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// data event
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// after write
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```
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### Exception: Async Opt-In
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If you wish to have a Minipass stream with behavior that more
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closely mimics Node.js core streams, you can set the stream in
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async mode either by setting `async: true` in the constructor
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options, or by setting `stream.async = true` later on.
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```js
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// hybrid module, either works
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import { Minipass } from 'minipass'
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// or:
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const { Minipass } = require('minipass')
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const asyncStream = new Minipass({ async: true })
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asyncStream.on('data', () => console.log('data event'))
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console.log('before write')
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asyncStream.write('hello')
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console.log('after write')
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// output:
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// before write
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// after write
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// data event <-- this is deferred until the next tick
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```
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Switching _out_ of async mode is unsafe, as it could cause data
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corruption, and so is not enabled. Example:
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```js
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import { Minipass } from 'minipass'
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const stream = new Minipass({ encoding: 'utf8' })
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stream.on('data', chunk => console.log(chunk))
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stream.async = true
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console.log('before writes')
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stream.write('hello')
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setStreamSyncAgainSomehow(stream) // <-- this doesn't actually exist!
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stream.write('world')
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console.log('after writes')
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// hypothetical output would be:
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// before writes
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// world
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// after writes
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// hello
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// NOT GOOD!
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```
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To avoid this problem, once set into async mode, any attempt to
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make the stream sync again will be ignored.
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```js
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const { Minipass } = require('minipass')
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const stream = new Minipass({ encoding: 'utf8' })
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stream.on('data', chunk => console.log(chunk))
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stream.async = true
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console.log('before writes')
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stream.write('hello')
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stream.async = false // <-- no-op, stream already async
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stream.write('world')
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console.log('after writes')
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// actual output:
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// before writes
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// after writes
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// hello
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// world
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```
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### No High/Low Water Marks
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Node.js core streams will optimistically fill up a buffer,
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returning `true` on all writes until the limit is hit, even if
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the data has nowhere to go. Then, they will not attempt to draw
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more data in until the buffer size dips below a minimum value.
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Minipass streams are much simpler. The `write()` method will
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return `true` if the data has somewhere to go (which is to say,
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given the timing guarantees, that the data is already there by
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the time `write()` returns).
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If the data has nowhere to go, then `write()` returns false, and
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the data sits in a buffer, to be drained out immediately as soon
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as anyone consumes it.
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Since nothing is ever buffered unnecessarily, there is much less
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copying data, and less bookkeeping about buffer capacity levels.
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### Hazards of Buffering (or: Why Minipass Is So Fast)
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Since data written to a Minipass stream is immediately written
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all the way through the pipeline, and `write()` always returns
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true/false based on whether the data was fully flushed,
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backpressure is communicated immediately to the upstream caller.
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This minimizes buffering.
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Consider this case:
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```js
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const { PassThrough } = require('stream')
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const p1 = new PassThrough({ highWaterMark: 1024 })
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const p2 = new PassThrough({ highWaterMark: 1024 })
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const p3 = new PassThrough({ highWaterMark: 1024 })
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const p4 = new PassThrough({ highWaterMark: 1024 })
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p1.pipe(p2).pipe(p3).pipe(p4)
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p4.on('data', () => console.log('made it through'))
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// this returns false and buffers, then writes to p2 on next tick (1)
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// p2 returns false and buffers, pausing p1, then writes to p3 on next tick (2)
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// p3 returns false and buffers, pausing p2, then writes to p4 on next tick (3)
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// p4 returns false and buffers, pausing p3, then emits 'data' and 'drain'
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// on next tick (4)
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// p3 sees p4's 'drain' event, and calls resume(), emitting 'resume' and
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// 'drain' on next tick (5)
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// p2 sees p3's 'drain', calls resume(), emits 'resume' and 'drain' on next tick (6)
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// p1 sees p2's 'drain', calls resume(), emits 'resume' and 'drain' on next
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// tick (7)
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p1.write(Buffer.alloc(2048)) // returns false
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```
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Along the way, the data was buffered and deferred at each stage,
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and multiple event deferrals happened, for an unblocked pipeline
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where it was perfectly safe to write all the way through!
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Furthermore, setting a `highWaterMark` of `1024` might lead
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someone reading the code to think an advisory maximum of 1KiB is
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being set for the pipeline. However, the actual advisory
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buffering level is the _sum_ of `highWaterMark` values, since
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each one has its own bucket.
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Consider the Minipass case:
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```js
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const m1 = new Minipass()
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const m2 = new Minipass()
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const m3 = new Minipass()
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const m4 = new Minipass()
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m1.pipe(m2).pipe(m3).pipe(m4)
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m4.on('data', () => console.log('made it through'))
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// m1 is flowing, so it writes the data to m2 immediately
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// m2 is flowing, so it writes the data to m3 immediately
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// m3 is flowing, so it writes the data to m4 immediately
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// m4 is flowing, so it fires the 'data' event immediately, returns true
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// m4's write returned true, so m3 is still flowing, returns true
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// m3's write returned true, so m2 is still flowing, returns true
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// m2's write returned true, so m1 is still flowing, returns true
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// No event deferrals or buffering along the way!
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m1.write(Buffer.alloc(2048)) // returns true
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```
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It is extremely unlikely that you _don't_ want to buffer any data
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written, or _ever_ buffer data that can be flushed all the way
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through. Neither node-core streams nor Minipass ever fail to
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buffer written data, but node-core streams do a lot of
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unnecessary buffering and pausing.
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As always, the faster implementation is the one that does less
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stuff and waits less time to do it.
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### Immediately emit `end` for empty streams (when not paused)
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If a stream is not paused, and `end()` is called before writing
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any data into it, then it will emit `end` immediately.
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If you have logic that occurs on the `end` event which you don't
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want to potentially happen immediately (for example, closing file
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descriptors, moving on to the next entry in an archive parse
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stream, etc.) then be sure to call `stream.pause()` on creation,
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and then `stream.resume()` once you are ready to respond to the
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`end` event.
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However, this is _usually_ not a problem because:
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### Emit `end` When Asked
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One hazard of immediately emitting `'end'` is that you may not
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yet have had a chance to add a listener. In order to avoid this
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hazard, Minipass streams safely re-emit the `'end'` event if a
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new listener is added after `'end'` has been emitted.
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Ie, if you do `stream.on('end', someFunction)`, and the stream
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has already emitted `end`, then it will call the handler right
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away. (You can think of this somewhat like attaching a new
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`.then(fn)` to a previously-resolved Promise.)
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To prevent calling handlers multiple times who would not expect
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multiple ends to occur, all listeners are removed from the
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`'end'` event whenever it is emitted.
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### Emit `error` When Asked
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The most recent error object passed to the `'error'` event is
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stored on the stream. If a new `'error'` event handler is added,
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and an error was previously emitted, then the event handler will
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be called immediately (or on `process.nextTick` in the case of
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async streams).
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This makes it much more difficult to end up trying to interact
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with a broken stream, if the error handler is added after an
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error was previously emitted.
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### Impact of "immediate flow" on Tee-streams
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A "tee stream" is a stream piping to multiple destinations:
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```js
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const tee = new Minipass()
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t.pipe(dest1)
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t.pipe(dest2)
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t.write('foo') // goes to both destinations
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```
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Since Minipass streams _immediately_ process any pending data
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through the pipeline when a new pipe destination is added, this
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can have surprising effects, especially when a stream comes in
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from some other function and may or may not have data in its
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buffer.
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```js
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// WARNING! WILL LOSE DATA!
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const src = new Minipass()
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src.write('foo')
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src.pipe(dest1) // 'foo' chunk flows to dest1 immediately, and is gone
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src.pipe(dest2) // gets nothing!
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```
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One solution is to create a dedicated tee-stream junction that
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pipes to both locations, and then pipe to _that_ instead.
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```js
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// Safe example: tee to both places
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const src = new Minipass()
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src.write('foo')
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const tee = new Minipass()
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tee.pipe(dest1)
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tee.pipe(dest2)
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src.pipe(tee) // tee gets 'foo', pipes to both locations
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```
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The same caveat applies to `on('data')` event listeners. The
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first one added will _immediately_ receive all of the data,
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leaving nothing for the second:
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```js
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// WARNING! WILL LOSE DATA!
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const src = new Minipass()
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src.write('foo')
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src.on('data', handler1) // receives 'foo' right away
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src.on('data', handler2) // nothing to see here!
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```
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Using a dedicated tee-stream can be used in this case as well:
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```js
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// Safe example: tee to both data handlers
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const src = new Minipass()
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src.write('foo')
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const tee = new Minipass()
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tee.on('data', handler1)
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tee.on('data', handler2)
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src.pipe(tee)
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```
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All of the hazards in this section are avoided by setting `{
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async: true }` in the Minipass constructor, or by setting
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`stream.async = true` afterwards. Note that this does add some
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overhead, so should only be done in cases where you are willing
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to lose a bit of performance in order to avoid having to refactor
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program logic.
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## USAGE
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It's a stream! Use it like a stream and it'll most likely do what
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you want.
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```js
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import { Minipass } from 'minipass'
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const mp = new Minipass(options) // optional: { encoding, objectMode }
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mp.write('foo')
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mp.pipe(someOtherStream)
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mp.end('bar')
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```
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### OPTIONS
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- `encoding` How would you like the data coming _out_ of the
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stream to be encoded? Accepts any values that can be passed to
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`Buffer.toString()`.
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- `objectMode` Emit data exactly as it comes in. This will be
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flipped on by default if you write() something other than a
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string or Buffer at any point. Setting `objectMode: true` will
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prevent setting any encoding value.
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- `async` Defaults to `false`. Set to `true` to defer data
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emission until next tick. This reduces performance slightly,
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but makes Minipass streams use timing behavior closer to Node
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core streams. See [Timing](#timing) for more details.
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- `signal` An `AbortSignal` that will cause the stream to unhook
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itself from everything and become as inert as possible. Note
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that providing a `signal` parameter will make `'error'` events
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no longer throw if they are unhandled, but they will still be
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emitted to handlers if any are attached.
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### API
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Implements the user-facing portions of Node.js's `Readable` and
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`Writable` streams.
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### Methods
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- `write(chunk, [encoding], [callback])` - Put data in. (Note
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that, in the base Minipass class, the same data will come out.)
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Returns `false` if the stream will buffer the next write, or
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true if it's still in "flowing" mode.
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- `end([chunk, [encoding]], [callback])` - Signal that you have
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no more data to write. This will queue an `end` event to be
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fired when all the data has been consumed.
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- `setEncoding(encoding)` - Set the encoding for data coming of
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the stream. This can only be done once.
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- `pause()` - No more data for a while, please. This also
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prevents `end` from being emitted for empty streams until the
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stream is resumed.
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- `resume()` - Resume the stream. If there's data in the buffer,
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it is all discarded. Any buffered events are immediately
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emitted.
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- `pipe(dest)` - Send all output to the stream provided. When
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data is emitted, it is immediately written to any and all pipe
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destinations. (Or written on next tick in `async` mode.)
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- `unpipe(dest)` - Stop piping to the destination stream. This is
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immediate, meaning that any asynchronously queued data will
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_not_ make it to the destination when running in `async` mode.
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- `options.end` - Boolean, end the destination stream when the
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source stream ends. Default `true`.
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- `options.proxyErrors` - Boolean, proxy `error` events from
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the source stream to the destination stream. Note that errors
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are _not_ proxied after the pipeline terminates, either due
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to the source emitting `'end'` or manually unpiping with
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`src.unpipe(dest)`. Default `false`.
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- `on(ev, fn)`, `emit(ev, fn)` - Minipass streams are
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EventEmitters. Some events are given special treatment,
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however. (See below under "events".)
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- `promise()` - Returns a Promise that resolves when the stream
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emits `end`, or rejects if the stream emits `error`.
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- `collect()` - Return a Promise that resolves on `end` with an
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array containing each chunk of data that was emitted, or
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rejects if the stream emits `error`. Note that this consumes
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the stream data.
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- `concat()` - Same as `collect()`, but concatenates the data
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into a single Buffer object. Will reject the returned promise
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if the stream is in objectMode, or if it goes into objectMode
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by the end of the data.
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- `read(n)` - Consume `n` bytes of data out of the buffer. If `n`
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is not provided, then consume all of it. If `n` bytes are not
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available, then it returns null. **Note** consuming streams in
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this way is less efficient, and can lead to unnecessary Buffer
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copying.
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- `destroy([er])` - Destroy the stream. If an error is provided,
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then an `'error'` event is emitted. If the stream has a
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`close()` method, and has not emitted a `'close'` event yet,
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then `stream.close()` will be called. Any Promises returned by
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`.promise()`, `.collect()` or `.concat()` will be rejected.
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After being destroyed, writing to the stream will emit an
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error. No more data will be emitted if the stream is destroyed,
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even if it was previously buffered.
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### Properties
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- `bufferLength` Read-only. Total number of bytes buffered, or in
|
|
the case of objectMode, the total number of objects.
|
|
- `encoding` The encoding that has been set. (Setting this is
|
|
equivalent to calling `setEncoding(enc)` and has the same
|
|
prohibition against setting multiple times.)
|
|
- `flowing` Read-only. Boolean indicating whether a chunk written
|
|
to the stream will be immediately emitted.
|
|
- `emittedEnd` Read-only. Boolean indicating whether the end-ish
|
|
events (ie, `end`, `prefinish`, `finish`) have been emitted.
|
|
Note that listening on any end-ish event will immediateyl
|
|
re-emit it if it has already been emitted.
|
|
- `writable` Whether the stream is writable. Default `true`. Set
|
|
to `false` when `end()`
|
|
- `readable` Whether the stream is readable. Default `true`.
|
|
- `pipes` An array of Pipe objects referencing streams that this
|
|
stream is piping into.
|
|
- `destroyed` A getter that indicates whether the stream was
|
|
destroyed.
|
|
- `paused` True if the stream has been explicitly paused,
|
|
otherwise false.
|
|
- `objectMode` Indicates whether the stream is in `objectMode`.
|
|
Once set to `true`, it cannot be set to `false`.
|
|
- `aborted` Readonly property set when the `AbortSignal`
|
|
dispatches an `abort` event.
|
|
|
|
### Events
|
|
|
|
- `data` Emitted when there's data to read. Argument is the data
|
|
to read. This is never emitted while not flowing. If a listener
|
|
is attached, that will resume the stream.
|
|
- `end` Emitted when there's no more data to read. This will be
|
|
emitted immediately for empty streams when `end()` is called.
|
|
If a listener is attached, and `end` was already emitted, then
|
|
it will be emitted again. All listeners are removed when `end`
|
|
is emitted.
|
|
- `prefinish` An end-ish event that follows the same logic as
|
|
`end` and is emitted in the same conditions where `end` is
|
|
emitted. Emitted after `'end'`.
|
|
- `finish` An end-ish event that follows the same logic as `end`
|
|
and is emitted in the same conditions where `end` is emitted.
|
|
Emitted after `'prefinish'`.
|
|
- `close` An indication that an underlying resource has been
|
|
released. Minipass does not emit this event, but will defer it
|
|
until after `end` has been emitted, since it throws off some
|
|
stream libraries otherwise.
|
|
- `drain` Emitted when the internal buffer empties, and it is
|
|
again suitable to `write()` into the stream.
|
|
- `readable` Emitted when data is buffered and ready to be read
|
|
by a consumer.
|
|
- `resume` Emitted when stream changes state from buffering to
|
|
flowing mode. (Ie, when `resume` is called, `pipe` is called,
|
|
or a `data` event listener is added.)
|
|
|
|
### Static Methods
|
|
|
|
- `Minipass.isStream(stream)` Returns `true` if the argument is a
|
|
stream, and false otherwise. To be considered a stream, the
|
|
object must be either an instance of Minipass, or an
|
|
EventEmitter that has either a `pipe()` method, or both
|
|
`write()` and `end()` methods. (Pretty much any stream in
|
|
node-land will return `true` for this.)
|
|
|
|
## EXAMPLES
|
|
|
|
Here are some examples of things you can do with Minipass
|
|
streams.
|
|
|
|
### simple "are you done yet" promise
|
|
|
|
```js
|
|
mp.promise().then(
|
|
() => {
|
|
// stream is finished
|
|
},
|
|
er => {
|
|
// stream emitted an error
|
|
}
|
|
)
|
|
```
|
|
|
|
### collecting
|
|
|
|
```js
|
|
mp.collect().then(all => {
|
|
// all is an array of all the data emitted
|
|
// encoding is supported in this case, so
|
|
// so the result will be a collection of strings if
|
|
// an encoding is specified, or buffers/objects if not.
|
|
//
|
|
// In an async function, you may do
|
|
// const data = await stream.collect()
|
|
})
|
|
```
|
|
|
|
### collecting into a single blob
|
|
|
|
This is a bit slower because it concatenates the data into one
|
|
chunk for you, but if you're going to do it yourself anyway, it's
|
|
convenient this way:
|
|
|
|
```js
|
|
mp.concat().then(onebigchunk => {
|
|
// onebigchunk is a string if the stream
|
|
// had an encoding set, or a buffer otherwise.
|
|
})
|
|
```
|
|
|
|
### iteration
|
|
|
|
You can iterate over streams synchronously or asynchronously in
|
|
platforms that support it.
|
|
|
|
Synchronous iteration will end when the currently available data
|
|
is consumed, even if the `end` event has not been reached. In
|
|
string and buffer mode, the data is concatenated, so unless
|
|
multiple writes are occurring in the same tick as the `read()`,
|
|
sync iteration loops will generally only have a single iteration.
|
|
|
|
To consume chunks in this way exactly as they have been written,
|
|
with no flattening, create the stream with the `{ objectMode:
|
|
true }` option.
|
|
|
|
```js
|
|
const mp = new Minipass({ objectMode: true })
|
|
mp.write('a')
|
|
mp.write('b')
|
|
for (let letter of mp) {
|
|
console.log(letter) // a, b
|
|
}
|
|
mp.write('c')
|
|
mp.write('d')
|
|
for (let letter of mp) {
|
|
console.log(letter) // c, d
|
|
}
|
|
mp.write('e')
|
|
mp.end()
|
|
for (let letter of mp) {
|
|
console.log(letter) // e
|
|
}
|
|
for (let letter of mp) {
|
|
console.log(letter) // nothing
|
|
}
|
|
```
|
|
|
|
Asynchronous iteration will continue until the end event is reached,
|
|
consuming all of the data.
|
|
|
|
```js
|
|
const mp = new Minipass({ encoding: 'utf8' })
|
|
|
|
// some source of some data
|
|
let i = 5
|
|
const inter = setInterval(() => {
|
|
if (i-- > 0) mp.write(Buffer.from('foo\n', 'utf8'))
|
|
else {
|
|
mp.end()
|
|
clearInterval(inter)
|
|
}
|
|
}, 100)
|
|
|
|
// consume the data with asynchronous iteration
|
|
async function consume() {
|
|
for await (let chunk of mp) {
|
|
console.log(chunk)
|
|
}
|
|
return 'ok'
|
|
}
|
|
|
|
consume().then(res => console.log(res))
|
|
// logs `foo\n` 5 times, and then `ok`
|
|
```
|
|
|
|
### subclass that `console.log()`s everything written into it
|
|
|
|
```js
|
|
class Logger extends Minipass {
|
|
write(chunk, encoding, callback) {
|
|
console.log('WRITE', chunk, encoding)
|
|
return super.write(chunk, encoding, callback)
|
|
}
|
|
end(chunk, encoding, callback) {
|
|
console.log('END', chunk, encoding)
|
|
return super.end(chunk, encoding, callback)
|
|
}
|
|
}
|
|
|
|
someSource.pipe(new Logger()).pipe(someDest)
|
|
```
|
|
|
|
### same thing, but using an inline anonymous class
|
|
|
|
```js
|
|
// js classes are fun
|
|
someSource
|
|
.pipe(
|
|
new (class extends Minipass {
|
|
emit(ev, ...data) {
|
|
// let's also log events, because debugging some weird thing
|
|
console.log('EMIT', ev)
|
|
return super.emit(ev, ...data)
|
|
}
|
|
write(chunk, encoding, callback) {
|
|
console.log('WRITE', chunk, encoding)
|
|
return super.write(chunk, encoding, callback)
|
|
}
|
|
end(chunk, encoding, callback) {
|
|
console.log('END', chunk, encoding)
|
|
return super.end(chunk, encoding, callback)
|
|
}
|
|
})()
|
|
)
|
|
.pipe(someDest)
|
|
```
|
|
|
|
### subclass that defers 'end' for some reason
|
|
|
|
```js
|
|
class SlowEnd extends Minipass {
|
|
emit(ev, ...args) {
|
|
if (ev === 'end') {
|
|
console.log('going to end, hold on a sec')
|
|
setTimeout(() => {
|
|
console.log('ok, ready to end now')
|
|
super.emit('end', ...args)
|
|
}, 100)
|
|
} else {
|
|
return super.emit(ev, ...args)
|
|
}
|
|
}
|
|
}
|
|
```
|
|
|
|
### transform that creates newline-delimited JSON
|
|
|
|
```js
|
|
class NDJSONEncode extends Minipass {
|
|
write(obj, cb) {
|
|
try {
|
|
// JSON.stringify can throw, emit an error on that
|
|
return super.write(JSON.stringify(obj) + '\n', 'utf8', cb)
|
|
} catch (er) {
|
|
this.emit('error', er)
|
|
}
|
|
}
|
|
end(obj, cb) {
|
|
if (typeof obj === 'function') {
|
|
cb = obj
|
|
obj = undefined
|
|
}
|
|
if (obj !== undefined) {
|
|
this.write(obj)
|
|
}
|
|
return super.end(cb)
|
|
}
|
|
}
|
|
```
|
|
|
|
### transform that parses newline-delimited JSON
|
|
|
|
```js
|
|
class NDJSONDecode extends Minipass {
|
|
constructor (options) {
|
|
// always be in object mode, as far as Minipass is concerned
|
|
super({ objectMode: true })
|
|
this._jsonBuffer = ''
|
|
}
|
|
write (chunk, encoding, cb) {
|
|
if (typeof chunk === 'string' &&
|
|
typeof encoding === 'string' &&
|
|
encoding !== 'utf8') {
|
|
chunk = Buffer.from(chunk, encoding).toString()
|
|
} else if (Buffer.isBuffer(chunk)) {
|
|
chunk = chunk.toString()
|
|
}
|
|
if (typeof encoding === 'function') {
|
|
cb = encoding
|
|
}
|
|
const jsonData = (this._jsonBuffer + chunk).split('\n')
|
|
this._jsonBuffer = jsonData.pop()
|
|
for (let i = 0; i < jsonData.length; i++) {
|
|
try {
|
|
// JSON.parse can throw, emit an error on that
|
|
super.write(JSON.parse(jsonData[i]))
|
|
} catch (er) {
|
|
this.emit('error', er)
|
|
continue
|
|
}
|
|
}
|
|
if (cb)
|
|
cb()
|
|
}
|
|
}
|
|
```
|