commit | 6f40c27fb2ea106c14f90ebbe05ffb57644715ff | [log] [tgz] |
---|---|---|
author | Kevin Moore <kevmoo@google.com> | Wed Sep 20 20:40:44 2017 -0700 |
committer | Kevin Moore <kevmoo@google.com> | Wed Sep 20 20:40:44 2017 -0700 |
tree | f507c9e5fd9969fda29c6e9eead5e346c9900b33 | |
parent | e48f815c1f6ac00a21f5669b83c28ce5a19b6ce9 [diff] |
dartfmt
The pool package exposes a Pool
class which makes it easy to manage a limited pool of resources.
The easiest way to use a pool is by calling withResource
. This runs a callback and returns its result, but only once there aren't too many other callbacks currently running.
// Create a Pool that will only allocate 10 resources at once. After 30 seconds // of inactivity with all resources checked out, the pool will throw an error. final pool = new Pool(10, timeout: new Duration(seconds: 30)); Future<String> readFile(String path) { // Since the call to [File.readAsString] is within [withResource], no more // than ten files will be open at once. return pool.withResource(() => new File(path).readAsString()); }
For more fine-grained control, the user can also explicitly request generic PoolResource
objects that can later be released back into the pool. This is what withResource
does under the covers: requests a resource, then releases it once the callback completes.
Pool
ensures that only a limited number of resources are allocated at once. It‘s the caller’s responsibility to ensure that the corresponding physical resource is only consumed when a PoolResource
is allocated.
class PooledFile implements RandomAccessFile { final RandomAccessFile _file; final PoolResource _resource; static Future<PooledFile> open(String path) { return pool.request().then((resource) { return new File(path).open().then((file) { return new PooledFile._(file, resource); }); }); } PooledFile(this._file, this._resource); // ... Future<RandomAccessFile> close() { return _file.close.then((_) { _resource.release(); return this; }); } }