docs/html/training/articles/perf-anr.jd - platform/frameworks/base - Git at Google

 page.title=Keeping Your App Responsive
 page.tags=threads,asynctask

 page.article=true
 @jd:body

 <div id="tb-wrapper">
 <div id="tb">

 <h2>In this document</h2>
 <ol class="nolist">
   <li><a href="#anr">What Triggers ANR?</a></li>
   <li><a href="#Avoiding">How to Avoid ANRs</a></li>
   <li><a href="#Reinforcing">Reinforcing Responsiveness</a></li>
 </ol>

 </div>
 </div>

 <div class="figure" style="width:280px">
 <img src="{@docRoot}images/anr.png" alt=""/>
 <p class="img-caption"><strong>Figure 1.</strong> An ANR dialog displayed to the user.</p>
 </div>

 <p>It's possible to write code that wins every performance test in the world,
 but still feels sluggish, hang or freeze for significant periods, or take too
 long to process input. The worst thing that can happen to your app's responsiveness
 is an "Application Not Responding" (ANR) dialog.</p>

 <p>In Android, the system guards against applications that are insufficiently
 responsive for a period of time by displaying a dialog that says your app has
 stopped responding, such as the dialog
 in Figure 1. At this point, your app has been unresponsive for a considerable
 period of time so the system offers the user an option to quit the app. It's critical
 to design responsiveness into your application so the system never displays
 an ANR dialog to the user. </p>

 <p>This document describes how the Android system determines whether an
 application is not responding and provides guidelines for ensuring that your
 application stays responsive. </p>


 <h2 id="anr">What Triggers ANR?</h2>

 <p>Generally, the system displays an ANR if an application cannot respond to
 user input. For example, if an  application blocks on some I/O operation
 (frequently a network access) on the UI thread so the system can't
 process incoming user input events. Or perhaps the app
 spends too much time building an elaborate in-memory
 structure or computing the next move in a game on the UI thread. It's always important to make
 sure these computations are efficient, but even the
 most efficient code still takes time to run.</p>

 <p>In any situation in which your app performs a potentially lengthy operation,
 <strong>you should not perform the work on the UI thread</strong>, but instead create a
 worker thread and do most of the work there. This keeps the UI thread (which drives the user
 interface event loop) running and prevents the system from concluding that your code
 has frozen. Because such threading usually is accomplished at the class
 level, you can think of responsiveness as a <em>class</em> problem. (Compare
 this with basic code performance, which is a <em>method</em>-level
 concern.)</p>

 <p>In Android, application responsiveness is monitored by the Activity Manager
 and Window Manager system services. Android will display the ANR dialog
 for a particular application when it detects one of the following
 conditions:</p>
 <ul>
     <li>No response to an input event (such as key press or screen touch events)
     within 5 seconds.</li>
     <li>A {@link android.content.BroadcastReceiver BroadcastReceiver}
     hasn't finished executing within 10 seconds.</li>
 </ul>


 <h2 id="Avoiding">How to Avoid ANRs</h2>

 <p>Android applications normally run entirely on a single thread by default
 the "UI thread" or "main thread").
 This means anything your application is doing in the UI thread that
 takes a long time to complete can trigger the ANR dialog because your
 application is not giving itself a chance to handle the input event or intent
 broadcasts.</p>

 <p>Therefore, any method that runs in the UI thread should do as little work
 as possible on that thread. In particular, activities should do as little as possible to set
 up in key life-cycle methods such as {@link android.app.Activity#onCreate onCreate()}
 and {@link android.app.Activity#onResume onResume()}.
 Potentially long running operations such as network
 or database operations, or computationally expensive calculations such as
 resizing bitmaps should be done in a worker thread (or in the case of databases
 operations, via an asynchronous request).</p>

 <p>The most effecive way to create a worker thread for longer
 operations is with the {@link android.os.AsyncTask}
 class. Simply extend {@link android.os.AsyncTask} and implement the
 {@link android.os.AsyncTask#doInBackground doInBackground()} method to perform the work.
 To post progress changes to the user, you can call
  {@link android.os.AsyncTask#publishProgress publishProgress()}, which invokes the
  {@link android.os.AsyncTask#onProgressUpdate onProgressUpdate()} callback method. From your
  implementation of {@link android.os.AsyncTask#onProgressUpdate onProgressUpdate()} (which
  runs on the UI thread), you can notify the user. For example:</p>

 <pre>
 private class DownloadFilesTask extends AsyncTask&lt;URL, Integer, Long> {
     // Do the long-running work in here
     protected Long doInBackground(URL... urls) {
         int count = urls.length;
         long totalSize = 0;
         for (int i = 0; i &lt; count; i++) {
             totalSize += Downloader.downloadFile(urls[i]);
             publishProgress((int) ((i / (float) count) * 100));
             // Escape early if cancel() is called
             if (isCancelled()) break;
         }
         return totalSize;
     }

     // This is called each time you call publishProgress()
     protected void onProgressUpdate(Integer... progress) {
         setProgressPercent(progress[0]);
     }

     // This is called when doInBackground() is finished
     protected void onPostExecute(Long result) {
         showNotification("Downloaded " + result + " bytes");
     }
 }
 </pre>

  <p>To execute this worker thread, simply create an instance and
  call {@link android.os.AsyncTask#execute execute()}:</p>

 <pre>
 new DownloadFilesTask().execute(url1, url2, url3);
 </pre>


 <p>Although it's more complicated than {@link android.os.AsyncTask}, you might want to instead
 create your own {@link java.lang.Thread} or {@link android.os.HandlerThread} class. If you do,
 you should set the thread priority to "background" priority by calling {@link
 android.os.Process#setThreadPriority Process.setThreadPriority()} and passing {@link
 android.os.Process#THREAD_PRIORITY_BACKGROUND}. If you don't set the thread to a lower priority
 this way, then the thread could still slow down your app because it operates at the same priority
 as the UI thread by default.</p>

 <p>If you implement {@link java.lang.Thread} or {@link android.os.HandlerThread},
 be sure that your UI thread does not block while waiting for the worker thread to
 complete&mdash;do not call {@link java.lang.Thread#wait Thread.wait()} or
 {@link java.lang.Thread#sleep Thread.sleep()}. Instead of blocking while waiting for a worker
 thread to complete, your main thread should provide a {@link
 android.os.Handler} for the other threads to post back to upon completion.
 Designing your application in this way will allow your app's UI thread to remain
 responsive to input and thus avoid ANR dialogs caused by the 5 second input
 event timeout.</p>

 <p>The specific constraint on {@link android.content.BroadcastReceiver} execution time
 emphasizes what broadcast receivers are meant to do:
 small, discrete amounts of work in the background such
 as saving a setting or registering a {@link android.app.Notification}. So as with other methods
 called in the UI thread, applications should avoid potentially long-running
 operations or calculations in a broadcast receiver. But instead of doing intensive
 tasks via worker threads, your
 application should start an {@link android.app.IntentService} if a
 potentially long running action needs to be taken in response to an intent
 broadcast.</p>

 <p class="note"><strong>Tip:</strong>
 You can use {@link android.os.StrictMode} to help find potentially
 long running operations such as network or database operations that
 you might accidentally be doing your main thread.</p>


 <h2 id="Reinforcing">Reinforce Responsiveness</h2>

 <p>Generally, 100 to 200ms is the threshold beyond which users will perceive
 slowness in an application. As such, here
 are some additional tips beyond what you should do to avoid ANR and
 make your application seem responsive to users:</p>

 <ul>
     <li>If your application is doing work in the background in response to
     user input, show that progress is being made (such as with a {@link
     android.widget.ProgressBar} in your UI).</li>

     <li>For games specifically, do calculations for moves in a worker
     thread.</li>

     <li>If your application has a time-consuming initial setup phase, consider
     showing a splash screen or rendering the main view as quickly as possible, indicate that
     loading is in progress and fill the information asynchronously. In either case, you should
     indicate somehow that progress is being made, lest the user perceive that
     the application is frozen.</li>

     <li>Use performance tools such as <a href="{@docRoot}tools/help/systrace.html">Systrace</a>
     and <a href="{@docRoot}tools/help/traceview.html">Traceview</a> to determine bottlenecks
     in your app's responsiveness.</li>
 </ul>
	page.title=Keeping Your App Responsive
	page.tags=threads,asynctask

	page.article=true
	@jd:body

	<div id="tb-wrapper">
	<div id="tb">

	<h2>In this document</h2>
	<ol class="nolist">
	<li><a href="#anr">What Triggers ANR?</a></li>
	<li><a href="#Avoiding">How to Avoid ANRs</a></li>
	<li><a href="#Reinforcing">Reinforcing Responsiveness</a></li>
	</ol>

	</div>
	</div>

	<div class="figure" style="width:280px">
	<img src="{@docRoot}images/anr.png" alt=""/>
	<p class="img-caption"><strong>Figure 1.</strong> An ANR dialog displayed to the user.</p>
	</div>

	<p>It's possible to write code that wins every performance test in the world,
	but still feels sluggish, hang or freeze for significant periods, or take too
	long to process input. The worst thing that can happen to your app's responsiveness
	is an "Application Not Responding" (ANR) dialog.</p>

	<p>In Android, the system guards against applications that are insufficiently
	responsive for a period of time by displaying a dialog that says your app has
	stopped responding, such as the dialog
	in Figure 1. At this point, your app has been unresponsive for a considerable
	period of time so the system offers the user an option to quit the app. It's critical
	to design responsiveness into your application so the system never displays
	an ANR dialog to the user. </p>

	<p>This document describes how the Android system determines whether an
	application is not responding and provides guidelines for ensuring that your
	application stays responsive. </p>


	<h2 id="anr">What Triggers ANR?</h2>

	<p>Generally, the system displays an ANR if an application cannot respond to
	user input. For example, if an application blocks on some I/O operation
	(frequently a network access) on the UI thread so the system can't
	process incoming user input events. Or perhaps the app
	spends too much time building an elaborate in-memory
	structure or computing the next move in a game on the UI thread. It's always important to make
	sure these computations are efficient, but even the
	most efficient code still takes time to run.</p>

	<p>In any situation in which your app performs a potentially lengthy operation,
	<strong>you should not perform the work on the UI thread</strong>, but instead create a
	worker thread and do most of the work there. This keeps the UI thread (which drives the user
	interface event loop) running and prevents the system from concluding that your code
	has frozen. Because such threading usually is accomplished at the class
	level, you can think of responsiveness as a <em>class</em> problem. (Compare
	this with basic code performance, which is a <em>method</em>-level
	concern.)</p>

	<p>In Android, application responsiveness is monitored by the Activity Manager
	and Window Manager system services. Android will display the ANR dialog
	for a particular application when it detects one of the following
	conditions:</p>
	<ul>
	<li>No response to an input event (such as key press or screen touch events)
	within 5 seconds.</li>
	<li>A {@link android.content.BroadcastReceiver BroadcastReceiver}
	hasn't finished executing within 10 seconds.</li>
	</ul>



	<h2 id="Avoiding">How to Avoid ANRs</h2>

	<p>Android applications normally run entirely on a single thread by default
	the "UI thread" or "main thread").
	This means anything your application is doing in the UI thread that
	takes a long time to complete can trigger the ANR dialog because your
	application is not giving itself a chance to handle the input event or intent
	broadcasts.</p>

	<p>Therefore, any method that runs in the UI thread should do as little work
	as possible on that thread. In particular, activities should do as little as possible to set
	up in key life-cycle methods such as {@link android.app.Activity#onCreate onCreate()}
	and {@link android.app.Activity#onResume onResume()}.
	Potentially long running operations such as network
	or database operations, or computationally expensive calculations such as
	resizing bitmaps should be done in a worker thread (or in the case of databases
	operations, via an asynchronous request).</p>

	<p>The most effecive way to create a worker thread for longer
	operations is with the {@link android.os.AsyncTask}
	class. Simply extend {@link android.os.AsyncTask} and implement the
	{@link android.os.AsyncTask#doInBackground doInBackground()} method to perform the work.
	To post progress changes to the user, you can call
	{@link android.os.AsyncTask#publishProgress publishProgress()}, which invokes the
	{@link android.os.AsyncTask#onProgressUpdate onProgressUpdate()} callback method. From your
	implementation of {@link android.os.AsyncTask#onProgressUpdate onProgressUpdate()} (which
	runs on the UI thread), you can notify the user. For example:</p>

	<pre>
	private class DownloadFilesTask extends AsyncTask<URL, Integer, Long> {
	// Do the long-running work in here
	protected Long doInBackground(URL... urls) {
	int count = urls.length;
	long totalSize = 0;
	for (int i = 0; i < count; i++) {
	totalSize += Downloader.downloadFile(urls[i]);
	publishProgress((int) ((i / (float) count) * 100));
	// Escape early if cancel() is called
	if (isCancelled()) break;
	}
	return totalSize;
	}

	// This is called each time you call publishProgress()
	protected void onProgressUpdate(Integer... progress) {
	setProgressPercent(progress[0]);
	}

	// This is called when doInBackground() is finished
	protected void onPostExecute(Long result) {
	showNotification("Downloaded " + result + " bytes");
	}
	}
	</pre>

	<p>To execute this worker thread, simply create an instance and
	call {@link android.os.AsyncTask#execute execute()}:</p>

	<pre>
	new DownloadFilesTask().execute(url1, url2, url3);
	</pre>


	<p>Although it's more complicated than {@link android.os.AsyncTask}, you might want to instead
	create your own {@link java.lang.Thread} or {@link android.os.HandlerThread} class. If you do,
	you should set the thread priority to "background" priority by calling {@link
	android.os.Process#setThreadPriority Process.setThreadPriority()} and passing {@link
	android.os.Process#THREAD_PRIORITY_BACKGROUND}. If you don't set the thread to a lower priority
	this way, then the thread could still slow down your app because it operates at the same priority
	as the UI thread by default.</p>

	<p>If you implement {@link java.lang.Thread} or {@link android.os.HandlerThread},
	be sure that your UI thread does not block while waiting for the worker thread to
	complete—do not call {@link java.lang.Thread#wait Thread.wait()} or
	{@link java.lang.Thread#sleep Thread.sleep()}. Instead of blocking while waiting for a worker
	thread to complete, your main thread should provide a {@link
	android.os.Handler} for the other threads to post back to upon completion.
	Designing your application in this way will allow your app's UI thread to remain
	responsive to input and thus avoid ANR dialogs caused by the 5 second input
	event timeout.</p>

	<p>The specific constraint on {@link android.content.BroadcastReceiver} execution time
	emphasizes what broadcast receivers are meant to do:
	small, discrete amounts of work in the background such
	as saving a setting or registering a {@link android.app.Notification}. So as with other methods
	called in the UI thread, applications should avoid potentially long-running
	operations or calculations in a broadcast receiver. But instead of doing intensive
	tasks via worker threads, your
	application should start an {@link android.app.IntentService} if a
	potentially long running action needs to be taken in response to an intent
	broadcast.</p>

	<p class="note"><strong>Tip:</strong>
	You can use {@link android.os.StrictMode} to help find potentially
	long running operations such as network or database operations that
	you might accidentally be doing your main thread.</p>



	<h2 id="Reinforcing">Reinforce Responsiveness</h2>

	<p>Generally, 100 to 200ms is the threshold beyond which users will perceive
	slowness in an application. As such, here
	are some additional tips beyond what you should do to avoid ANR and
	make your application seem responsive to users:</p>

	<ul>
	<li>If your application is doing work in the background in response to
	user input, show that progress is being made (such as with a {@link
	android.widget.ProgressBar} in your UI).</li>

	<li>For games specifically, do calculations for moves in a worker
	thread.</li>

	<li>If your application has a time-consuming initial setup phase, consider
	showing a splash screen or rendering the main view as quickly as possible, indicate that
	loading is in progress and fill the information asynchronously. In either case, you should
	indicate somehow that progress is being made, lest the user perceive that
	the application is frozen.</li>

	<li>Use performance tools such as <a href="{@docRoot}tools/help/systrace.html">Systrace</a>
	and <a href="{@docRoot}tools/help/traceview.html">Traceview</a> to determine bottlenecks
	in your app's responsiveness.</li>
	</ul>