docs/html/tools/debugging/debugging-tracing.jd - LeafOS-Project/android_frameworks_base - Gitiles

 page.title=Profiling with Traceview and dmtracedump
 parent.title=Debugging
 parent.link=index.html
 @jd:body

  <div id="qv-wrapper">
     <div id="qv">
       <h2>In this document</h2>

       <ol>
         <li>
           <a href="#traceviewLayout">Traceview Layout</a>

           <ol>
             <li><a href="#timelinepanel">Timeline Panel</a></li>

             <li><a href="#profilepanel">Profile Panel</a></li>
           </ol>
         </li>

         <li><a href="#creatingtracefiles">Creating Trace Files</a></li>

         <li><a href="#copyingfiles">Copying Trace Files to a Host Machine</a></li>

         <li><a href="#runningtraceview">Viewing Trace Files in Traceview</a></li>

         <li><a href="#dmtracedump">Using dmtracedump</a></li>

         <li><a href="#knownissues">Traceview Known Issues</a></li>
       </ol>
     </div>
   </div>

   <p>Traceview is a graphical viewer for execution logs that you create by using the {@link
   android.os.Debug} class to log tracing information in your code. Traceview can help you debug
   your application and profile its performance.</p>

   <h2 id="traceviewLayout">Traceview Layout</h2>

   <p>When you have a trace log file (generated by adding tracing code to your application or by DDMS),
   you can load the log files in Traceview, which displays the log data in two panels:</p>

   <ul>
     <li>A <a href="#timelinepanel">timeline panel</a> -- describes when each thread and method
     started and stopped</li>

     <li>A <a href="#timelinepanel">profile panel</a> -- provides a summary of what happened inside
     a method</li>
   </ul>

   <p>The sections below provide addition information about the traceview output panes.</p>

   <h3 id="timelinepanel">Timeline Panel</h3>

   <p>Figure 1 shows a close up of the timeline panel. Each thread&rsquo;s execution is shown
   in its own row, with time increasing to the right. Each method is shown in another color (colors
   are reused in a round-robin fashion starting with the methods that have the most inclusive time).
   The thin lines underneath the first row show the extent (entry to exit) of all the calls to the
   selected method.</p>

   <img src="{@docRoot}images/traceview_timeline.png"
        alt="Traceview timeline panel"
        width="893"
        height="284" />
        <p class="img-caption"><strong>Figure 1.</strong> The Traceview Timeline Panel</p>

   <h3 id="profilepanel">Profile Panel</h3>

   <p>Figure 2 shows the profile pane, a summary of all the time spent
   in a method. The table shows both the inclusive and exclusive times (as well as the percentage of
   the total time). Exclusive time is the time spent in the method. Inclusive time is the time spent
   in the method plus the time spent in any called functions. We refer to calling methods as
   "parents" and called methods as "children." When a method is selected (by clicking on it), it
   expands to show the parents and children. Parents are shown with a purple background and children
   with a yellow background. The last column in the table shows the number of calls to this method
   plus the number of recursive calls. The last column shows the number of calls out of the total
   number of calls made to that method. In this view, we can see that there were 14 calls to
   <code>LoadListener.nativeFinished();</code> looking at the timeline panel shows that one of those calls took
   an unusually long time.</p>

   <img src="{@docRoot}images/traceview_profile.png"
        alt="Traceview profile panel."
        width="892"
        height="630" />
   <p class="img-caption"><strong>Figure 2.</strong> The Traceview Profile Panel</p>

   <h2 id="creatingtracefiles">Creating Trace Files</h2>

   <p>To use Traceview, you need to generate log files containing the trace information you want to
   analyze.</p>

   <p>There are two ways to generate trace logs:</p>
   <ul>
     <li>Include the {@link android.os.Debug} class in your code and call its
   methods such as {@link android.os.Debug#startMethodTracing()} and {@link
   android.os.Debug#stopMethodTracing()}, to start and stop logging of trace information to disk.
   This option is very precise because
   you can specify exactly where to start and stop logging trace data in your code.</li>
     <li>Use the method profiling feature of DDMS to generate trace logs. This option is less
     precise because you do not modify code, but rather specify when to start and stop logging with
     DDMS. Although you have less control on exactly where logging starts and stops,
     this option is useful if you don't have access to the application's code, or if you do
     not need precise log timing.
     </li>
   </ul>

   <p>Before you start generating trace logs, be aware of the following restrictions:</p>
   <ul>
     <li>If you are using the {@link android.os.Debug} class,
      your application must have permission to write to external storage
      ({@link android.Manifest.permission#READ_EXTERNAL_STORAGE}). </li>
     <li>If you are using DDMS:
       <ul>
         <li>Android 2.1 and earlier devices must
     have an SD card present and your application must have permission to write to the SD card.
         <li>Android 2.2 and later devices do not need an SD card. The trace log files are
     streamed directly to your development machine.</li>
       </ul>
     </li>
   </ul>

   <p>This document focuses on using the {@link android.os.Debug} class to generate trace data.  For more information on using DDMS
   to generate trace data, see <a href="ddms.html#profiling">Using the Dalvik Debug Monitor Server.</a>
   </p>

   <p>To create the trace files, include the {@link android.os.Debug} class and call one of the
   {@link android.os.Debug#startMethodTracing() startMethodTracing()} methods. In the call, you
   specify a base name for the trace files that the system generates. To stop tracing, call {@link
   android.os.Debug#stopMethodTracing() stopMethodTracing()}. These methods start and stop method
   tracing across the entire virtual machine. For example, you could call
   {@link android.os.Debug#startMethodTracing() startMethodTracing()} in
   your activity's {@link android.app.Activity#onCreate onCreate()} method, and call
   {@link android.os.Debug#stopMethodTracing() stopMethodTracing()} in that activity's
   {@link android.app.Activity#onDestroy()} method.</p>
   <pre>
     // start tracing to "/sdcard/calc.trace"
     Debug.startMethodTracing("calc");
     // ...
     // stop tracing
     Debug.stopMethodTracing();
 </pre>

   <p>When your application calls {@link android.os.Debug#startMethodTracing() startMethodTracing()},
   the system creates a file called
   <code>&lt;trace-base-name&gt;.trace</code>. This contains the binary method trace data and a
   mapping table with thread and method names.</p>

   <p>The system then begins buffering the generated trace data, until your application calls
   {@link android.os.Debug#stopMethodTracing() stopMethodTracing()}, at which time it writes
   the buffered data to the output file. If the system
   reaches the maximum buffer size before you call {@link android.os.Debug#stopMethodTracing()
   stopMethodTracing()}, the system stops tracing
   and sends a notification to the console.</p>

   <p>Interpreted code runs more slowly when profiling is enabled. Don't try to generate
   absolute timings from the profiler results (such as, "function X takes 2.5 seconds to run"). The
   times are only useful in relation to other profile output, so you can see if changes have made
   the code faster or slower relative to a previous profiling run.</p>

   <p>In Android 4.4 and later, you can use sample-based profiling to profile with less runtime
   performance impact. To enable sample profiling, call {@link
   android.os.Debug#startMethodTracingSampling(java.lang.String, int, int)
   startMethodTracingSampling()} with a specified sampling interval. The system will then gather
   samples periodically until tracing is stopped via {@link android.os.Debug#stopMethodTracing()
   stopMethodTracing()}.</p>

   <h2 id="copyingfiles">Copying Trace Files to a Host Machine</h2>

   <p>After your application has run and the system has created your trace files
   <code>&lt;trace-base-name&gt;.trace</code> on a device or emulator, you must copy those files to
   your development computer. You can use <code>adb pull</code> to copy the files. Here's an example
   that shows how to copy an example file, calc.trace, from the default location on the emulator to
   the /tmp directory on the emulator host machine:</p>
   <pre>
 adb pull /sdcard/calc.trace /tmp
 </pre>

   <h2 id="runningtraceview">Viewing Trace Files in Traceview</h2>

   <p>To run Traceview and view the trace files:</p>
   <ul>
     <li>start the
     <a href="{@docRoot}tools/help/monitor.html">Android Device Monitor</a>. </li>
     <li>In the Android Device Monitor tool bar, click <strong>DDMS</strong> and select a process. </li>
     <li>Click the <strong>Start Method Profiling</strong> icon to start method profiling. </li>
     <li>After the profiling is complete, click the <strong>Stop Method Profiling</strong> icon to
     display the traceview. </li>
    </ul>

   <p class="note"><strong>Note:</strong> If you are trying to view the trace logs of an application
   that is built with ProGuard enabled (release mode build), some method and member names might be obfuscated.
   You can use the Proguard <code>mapping.txt</code> file to figure out the original unobfuscated names. For more information
   on this file, see the <a href="{@docRoot}tools/help/proguard.html">Proguard</a> documentation.</p>

       <h2 id="dmtracedump">Using dmtracedump</h2>

       <p><code>dmtracedump</code> is a tool that gives you an alternate way of generating
       graphical call-stack diagrams from trace log files. The tool uses the Graphviz Dot utility to
       create the graphical output, so you need to install Graphviz before running dmtracedump.</p>

       <p>The dmtracedump tool generates the call stack data as a tree diagram, with each call
       represented as a node. It shows call flow (from parent node to child nodes) using arrows. The
       diagram below shows an example of dmtracedump output.</p>
       <img src=
       "{@docRoot}images/tracedump.png"
           width="485"
           height="401" />
        <p class="img-caption"><strong>Figure 3.</strong> Screenshot of dmtracedump</p>

       <p>For each node, dmtracedump shows <code>&lt;ref&gt;
       <em>callname</em> (&lt;inc-ms&gt;, &lt;exc-ms&gt;,&lt;numcalls&gt;)</code>, where</p>

       <ul>
         <li><code>&lt;ref&gt;</code> -- Call reference number, as used in trace logs</li>

         <li><code>&lt;inc-ms&gt;</code> -- Inclusive elapsed time (milliseconds spent in method,
         including all child methods)</li>

         <li><code>&lt;exc-ms&gt;</code> -- Exclusive elapsed time (milliseconds spent in method,
         not including any child methods)</li>

         <li><code>&lt;numcalls&gt;</code> -- Number of calls</li>
       </ul>

       <p>The usage for dmtracedump is:</p>
       <pre>
 dmtracedump [-ho] [-s sortable] [-d trace-base-name] [-g outfile] &lt;trace-base-name&gt;
 </pre>

       <p>The tool then loads trace log data from <code>&lt;trace-base-name&gt;.data</code> and
       <code>&lt;trace-base-name&gt;.key</code>. The table below lists the options for dmtracedump.</p>

       <table>
         <tr>
           <th>Option</th>

           <th>Description</th>
         </tr>

         <tr>
           <td><code>-d&nbsp;&lt;trace-base-name&gt;</code></td>

           <td>Diff with this trace name</td>
         </tr>

         <tr>
           <td><code>-g&nbsp;&lt;outfile&gt;</code></td>

           <td>Generate output to &lt;outfile&gt;</td>
         </tr>

         <tr>
           <td><code>-h</code></td>

           <td>Turn on HTML output</td>
         </tr>

         <tr>
           <td><code>-o</code></td>

           <td>Dump the trace file instead of profiling</td>
         </tr>

         <tr>
           <td><code>-d&nbsp;&lt;trace-base-name&gt;</code></td>

           <td>URL base to the location of the sortable javascript file</td>
         </tr>

         <tr>
           <td><code>-t&nbsp;&lt;percent&gt;</code></td>

           <td>Minimum threshold for including child nodes in the graph (child's inclusive time as a
           percentage of parent inclusive time). If this option is not used, the default threshold
           is 20%.</td>
         </tr>
       </table>


   <h2 id="knownissues">Traceview Known Issues</h2>

   <dl>
     <dt>Threads</dt>

     <dd>
       Traceview logging does not handle threads well, resulting in these two problems:

       <ol>
         <li>If a thread exits during profiling, the thread name is not emitted (fixed in Android 5.1
 	and later);</li>

         <li>The VM reuses thread IDs. If a thread stops and another starts, they may get the same
         ID.</li>
       </ol>
     </dd>

     </dl>
	page.title=Profiling with Traceview and dmtracedump
	parent.title=Debugging
	parent.link=index.html
	@jd:body

	<div id="qv-wrapper">
	<div id="qv">
	<h2>In this document</h2>

	<ol>
	<li>
	<a href="#traceviewLayout">Traceview Layout</a>

	<ol>
	<li><a href="#timelinepanel">Timeline Panel</a></li>

	<li><a href="#profilepanel">Profile Panel</a></li>
	</ol>
	</li>

	<li><a href="#creatingtracefiles">Creating Trace Files</a></li>

	<li><a href="#copyingfiles">Copying Trace Files to a Host Machine</a></li>

	<li><a href="#runningtraceview">Viewing Trace Files in Traceview</a></li>

	<li><a href="#dmtracedump">Using dmtracedump</a></li>

	<li><a href="#knownissues">Traceview Known Issues</a></li>
	</ol>
	</div>
	</div>

	<p>Traceview is a graphical viewer for execution logs that you create by using the {@link
	android.os.Debug} class to log tracing information in your code. Traceview can help you debug
	your application and profile its performance.</p>

	<h2 id="traceviewLayout">Traceview Layout</h2>

	<p>When you have a trace log file (generated by adding tracing code to your application or by DDMS),
	you can load the log files in Traceview, which displays the log data in two panels:</p>

	<ul>
	<li>A <a href="#timelinepanel">timeline panel</a> -- describes when each thread and method
	started and stopped</li>

	<li>A <a href="#timelinepanel">profile panel</a> -- provides a summary of what happened inside
	a method</li>
	</ul>

	<p>The sections below provide addition information about the traceview output panes.</p>

	<h3 id="timelinepanel">Timeline Panel</h3>

	<p>Figure 1 shows a close up of the timeline panel. Each thread’s execution is shown
	in its own row, with time increasing to the right. Each method is shown in another color (colors
	are reused in a round-robin fashion starting with the methods that have the most inclusive time).
	The thin lines underneath the first row show the extent (entry to exit) of all the calls to the
	selected method.</p>

	<img src="{@docRoot}images/traceview_timeline.png"
	alt="Traceview timeline panel"
	width="893"
	height="284" />
	<p class="img-caption"><strong>Figure 1.</strong> The Traceview Timeline Panel</p>

	<h3 id="profilepanel">Profile Panel</h3>

	<p>Figure 2 shows the profile pane, a summary of all the time spent
	in a method. The table shows both the inclusive and exclusive times (as well as the percentage of
	the total time). Exclusive time is the time spent in the method. Inclusive time is the time spent
	in the method plus the time spent in any called functions. We refer to calling methods as
	"parents" and called methods as "children." When a method is selected (by clicking on it), it
	expands to show the parents and children. Parents are shown with a purple background and children
	with a yellow background. The last column in the table shows the number of calls to this method
	plus the number of recursive calls. The last column shows the number of calls out of the total
	number of calls made to that method. In this view, we can see that there were 14 calls to
	<code>LoadListener.nativeFinished();</code> looking at the timeline panel shows that one of those calls took
	an unusually long time.</p>

	<img src="{@docRoot}images/traceview_profile.png"
	alt="Traceview profile panel."
	width="892"
	height="630" />
	<p class="img-caption"><strong>Figure 2.</strong> The Traceview Profile Panel</p>

	<h2 id="creatingtracefiles">Creating Trace Files</h2>

	<p>To use Traceview, you need to generate log files containing the trace information you want to
	analyze.</p>

	<p>There are two ways to generate trace logs:</p>
	<ul>
	<li>Include the {@link android.os.Debug} class in your code and call its
	methods such as {@link android.os.Debug#startMethodTracing()} and {@link
	android.os.Debug#stopMethodTracing()}, to start and stop logging of trace information to disk.
	This option is very precise because
	you can specify exactly where to start and stop logging trace data in your code.</li>
	<li>Use the method profiling feature of DDMS to generate trace logs. This option is less
	precise because you do not modify code, but rather specify when to start and stop logging with
	DDMS. Although you have less control on exactly where logging starts and stops,
	this option is useful if you don't have access to the application's code, or if you do
	not need precise log timing.
	</li>
	</ul>

	<p>Before you start generating trace logs, be aware of the following restrictions:</p>
	<ul>
	<li>If you are using the {@link android.os.Debug} class,
	your application must have permission to write to external storage
	({@link android.Manifest.permission#READ_EXTERNAL_STORAGE}). </li>
	<li>If you are using DDMS:
	<ul>
	<li>Android 2.1 and earlier devices must
	have an SD card present and your application must have permission to write to the SD card.
	<li>Android 2.2 and later devices do not need an SD card. The trace log files are
	streamed directly to your development machine.</li>
	</ul>
	</li>
	</ul>

	<p>This document focuses on using the {@link android.os.Debug} class to generate trace data. For more information on using DDMS
	to generate trace data, see <a href="ddms.html#profiling">Using the Dalvik Debug Monitor Server.</a>
	</p>

	<p>To create the trace files, include the {@link android.os.Debug} class and call one of the
	{@link android.os.Debug#startMethodTracing() startMethodTracing()} methods. In the call, you
	specify a base name for the trace files that the system generates. To stop tracing, call {@link
	android.os.Debug#stopMethodTracing() stopMethodTracing()}. These methods start and stop method
	tracing across the entire virtual machine. For example, you could call
	{@link android.os.Debug#startMethodTracing() startMethodTracing()} in
	your activity's {@link android.app.Activity#onCreate onCreate()} method, and call
	{@link android.os.Debug#stopMethodTracing() stopMethodTracing()} in that activity's
	{@link android.app.Activity#onDestroy()} method.</p>
	<pre>
	// start tracing to "/sdcard/calc.trace"
	Debug.startMethodTracing("calc");
	// ...
	// stop tracing
	Debug.stopMethodTracing();
	</pre>

	<p>When your application calls {@link android.os.Debug#startMethodTracing() startMethodTracing()},
	the system creates a file called
	<code><trace-base-name>.trace</code>. This contains the binary method trace data and a
	mapping table with thread and method names.</p>

	<p>The system then begins buffering the generated trace data, until your application calls
	{@link android.os.Debug#stopMethodTracing() stopMethodTracing()}, at which time it writes
	the buffered data to the output file. If the system
	reaches the maximum buffer size before you call {@link android.os.Debug#stopMethodTracing()
	stopMethodTracing()}, the system stops tracing
	and sends a notification to the console.</p>

	<p>Interpreted code runs more slowly when profiling is enabled. Don't try to generate
	absolute timings from the profiler results (such as, "function X takes 2.5 seconds to run"). The
	times are only useful in relation to other profile output, so you can see if changes have made
	the code faster or slower relative to a previous profiling run.</p>

	<p>In Android 4.4 and later, you can use sample-based profiling to profile with less runtime
	performance impact. To enable sample profiling, call {@link
	android.os.Debug#startMethodTracingSampling(java.lang.String, int, int)
	startMethodTracingSampling()} with a specified sampling interval. The system will then gather
	samples periodically until tracing is stopped via {@link android.os.Debug#stopMethodTracing()
	stopMethodTracing()}.</p>

	<h2 id="copyingfiles">Copying Trace Files to a Host Machine</h2>

	<p>After your application has run and the system has created your trace files
	<code><trace-base-name>.trace</code> on a device or emulator, you must copy those files to
	your development computer. You can use <code>adb pull</code> to copy the files. Here's an example
	that shows how to copy an example file, calc.trace, from the default location on the emulator to
	the /tmp directory on the emulator host machine:</p>
	<pre>
	adb pull /sdcard/calc.trace /tmp
	</pre>

	<h2 id="runningtraceview">Viewing Trace Files in Traceview</h2>

	<p>To run Traceview and view the trace files:</p>
	<ul>
	<li>start the
	<a href="{@docRoot}tools/help/monitor.html">Android Device Monitor</a>. </li>
	<li>In the Android Device Monitor tool bar, click <strong>DDMS</strong> and select a process. </li>
	<li>Click the <strong>Start Method Profiling</strong> icon to start method profiling. </li>
	<li>After the profiling is complete, click the <strong>Stop Method Profiling</strong> icon to
	display the traceview. </li>
	</ul>

	<p class="note"><strong>Note:</strong> If you are trying to view the trace logs of an application
	that is built with ProGuard enabled (release mode build), some method and member names might be obfuscated.
	You can use the Proguard <code>mapping.txt</code> file to figure out the original unobfuscated names. For more information
	on this file, see the <a href="{@docRoot}tools/help/proguard.html">Proguard</a> documentation.</p>

	<h2 id="dmtracedump">Using dmtracedump</h2>

	<p><code>dmtracedump</code> is a tool that gives you an alternate way of generating
	graphical call-stack diagrams from trace log files. The tool uses the Graphviz Dot utility to
	create the graphical output, so you need to install Graphviz before running dmtracedump.</p>

	<p>The dmtracedump tool generates the call stack data as a tree diagram, with each call
	represented as a node. It shows call flow (from parent node to child nodes) using arrows. The
	diagram below shows an example of dmtracedump output.</p>
	<img src=
	"{@docRoot}images/tracedump.png"
	width="485"
	height="401" />
	<p class="img-caption"><strong>Figure 3.</strong> Screenshot of dmtracedump</p>

	<p>For each node, dmtracedump shows <code><ref>
	<em>callname</em> (<inc-ms>, <exc-ms>,<numcalls>)</code>, where</p>

	<ul>
	<li><code><ref></code> -- Call reference number, as used in trace logs</li>

	<li><code><inc-ms></code> -- Inclusive elapsed time (milliseconds spent in method,
	including all child methods)</li>

	<li><code><exc-ms></code> -- Exclusive elapsed time (milliseconds spent in method,
	not including any child methods)</li>

	<li><code><numcalls></code> -- Number of calls</li>
	</ul>

	<p>The usage for dmtracedump is:</p>
	<pre>
	dmtracedump [-ho] [-s sortable] [-d trace-base-name] [-g outfile] <trace-base-name>
	</pre>

	<p>The tool then loads trace log data from <code><trace-base-name>.data</code> and
	<code><trace-base-name>.key</code>. The table below lists the options for dmtracedump.</p>

	<table>
	<tr>
	<th>Option</th>

	<th>Description</th>
	</tr>

	<tr>
	<td><code>-d <trace-base-name></code></td>

	<td>Diff with this trace name</td>
	</tr>

	<tr>
	<td><code>-g <outfile></code></td>

	<td>Generate output to <outfile></td>
	</tr>

	<tr>
	<td><code>-h</code></td>

	<td>Turn on HTML output</td>
	</tr>

	<tr>
	<td><code>-o</code></td>

	<td>Dump the trace file instead of profiling</td>
	</tr>

	<tr>
	<td><code>-d <trace-base-name></code></td>

	<td>URL base to the location of the sortable javascript file</td>
	</tr>

	<tr>
	<td><code>-t <percent></code></td>

	<td>Minimum threshold for including child nodes in the graph (child's inclusive time as a
	percentage of parent inclusive time). If this option is not used, the default threshold
	is 20%.</td>
	</tr>
	</table>



	<h2 id="knownissues">Traceview Known Issues</h2>

	<dl>
	<dt>Threads</dt>

	<dd>
	Traceview logging does not handle threads well, resulting in these two problems:

	<ol>
	<li>If a thread exits during profiling, the thread name is not emitted (fixed in Android 5.1
	and later);</li>

	<li>The VM reuses thread IDs. If a thread stops and another starts, they may get the same
	ID.</li>
	</ol>
	</dd>

	</dl>