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apitrace consists of a set of tools to:

• trace OpenGL, OpenGL ES, Direct3D, and DirectDraw APIs calls to a file;

• replay OpenGL and OpenGL ES calls from a file;

• inspect OpenGL state at any call while retracing;

• visualize and edit trace files.

See the apitrace homepage for more details.

# Obtaining apitrace

To obtain apitrace either download the latest binaries for your platform if available, or follow the instructions in INSTALL.markdown to build it yourself. On 64bits Linux and Windows platforms you'll need apitrace binaries that match the architecture (32bits or 64bits) of the application being traced.

# Basic usage

Run the application you want to trace as

apitrace trace --api API /path/to/application [args...]


and it will generate a trace named application.trace in the current directory. You can specify the written trace filename by passing the --output command line option.

Problems while tracing (e.g, if the application uses calls/parameters unsupported by apitrace) will be reported via stderr output on Unices. On Windows you'll need to run DebugView to view these messages.

Follow the "Tracing manually" instructions below if you cannot obtain a trace.

View the trace with

apitrace dump application.trace


Replay an OpenGL trace with

apitrace replay application.trace


Pass the --sb option to use a single buffered visual. Pass --help to apitrace replay for more options.

# Basic GUI usage

Start the GUI as

qapitrace application.trace


You can also tell the GUI to go directly to a specific call

qapitrace application.trace 12345


## Call sets

Several tools take CALLSET arguments, e.g:

apitrace dump --calls=CALLSET foo.trace
apitrace dump-images --calls=CALLSET foo.trace


The call syntax is very flexible. Here are a few examples:

• 4 one call

• 0,2,4,5 set of calls

• "0 2 4 5" set of calls (commas are optional and can be replaced with whitespace)

• 0-100/2 calls 1, 3, 5, ..., 99

• 0-1000/draw all draw calls between 0 and 1000

• 0-1000/fbo all fbo changes between calls 0 and 1000

• frame all calls at end of frames

• @foo.txt read call numbers from foo.txt, using the same syntax as above

## Tracing manually

### Linux

On 64 bits systems, you'll need to determine ether the application is 64 bits or 32 bits. This can be done by doing

file /path/to/application


But beware of wrapper shell scripts -- what matters is the architecture of the main process.

Run the GLX application you want to trace as

LD_PRELOAD=/path/to/apitrace/wrappers/glxtrace.so /path/to/application


and it will generate a trace named application.trace in the current directory. You can specify the written trace filename by setting the TRACE_FILE environment variable before running.

For EGL applications you will need to use egltrace.so instead of glxtrace.so.

The LD_PRELOAD mechanism should work with the majority applications. There are some applications (e.g., Unigine Heaven, Android GPU emulator, etc.), that have global function pointers with the same name as GL entrypoints, living in a shared object that wasn't linked with -Bsymbolic flag, so relocations to those globals function pointers get overwritten with the address to our wrapper library, and the application will segfault when trying to write to them. For these applications it is possible to trace by using glxtrace.so as an ordinary libGL.so and injecting it via LD_LIBRARY_PATH:

ln -s glxtrace.so wrappers/libGL.so
ln -s glxtrace.so wrappers/libGL.so.1
ln -s glxtrace.so wrappers/libGL.so.1.2
export LD_LIBRARY_PATH=/path/to/apitrace/wrappers:$LD_LIBRARY_PATH export TRACE_LIBGL=/path/to/real/libGL.so.1 /path/to/application  If you are an application developer, you can avoid this either by linking with -Bsymbolic flag, or by using some unique prefix for your function pointers. See the ld.so man page for more information about LD_PRELOAD and LD_LIBRARY_PATH environment flags. To trace the application inside gdb, invoke gdb as: gdb --ex 'set exec-wrapper env LD_PRELOAD=/path/to/glxtrace.so' --args /path/to/application  ### Android To trace standalone native OpenGL ES applications, use LD_PRELOAD=/path/to/egltrace.so /path/to/application like described in the previous section. To trace Java applications, refer to Dalvik.markdown. ### Mac OS X Run the application you want to trace as DYLD_LIBRARY_PATH=/path/to/apitrace/wrappers /path/to/application  Note that although Mac OS X has an LD_PRELOAD equivalent, DYLD_INSERT_LIBRARIES, it is mostly useless because it only works with DYLD_FORCE_FLAT_NAMESPACE=1 which breaks most applications. See the dyld man page for more details about these environment flags. ### Windows When tracing third-party applications, you can identify the target application's main executable, either by: • right clicking on the application's icon in the Start Menu, choose Properties, and see the Target field; • or by starting the application, run Windows Task Manager (taskmgr.exe), right click on the application name in the Applications tab, choose Go To Process, note the highlighted Image Name, and search it on C:\Program Files or C:\Program Files (x86). On 64 bits Windows, you'll need to determine ether the application is a 64 bits or 32 bits. 32 bits applications will have a *32 suffix in the Image Name column of the Processes tab of Windows Task Manager window. Copy the appropriate opengl32.dll, d3d8.dll, or d3d9.dll from the wrappers directory to the directory with the application you want to trace. Then run the application as usual. You can specify the written trace filename by setting the TRACE_FILE environment variable before running. For D3D10 and higher you really must use apitrace trace -a DXGI .... This is because D3D10-11 API span many DLLs which depend on each other, and once a DLL with a given name is loaded Windows will reuse it for LoadLibrary calls of the same name, causing internal calls to be traced erroneously. apitrace trace solves this issue by injecting a DLL dxgitrace.dll and patching all modules to hook only the APIs of interest. ## Emitting annotations to the trace From OpenGL applications you can embed annotations in the trace file through the GL_GREMEDY_string_marker and GL_GREMEDY_frame_terminator GL extensions. apitrace will advertise and intercept these GL extensions independently of the GL implementation. So all you have to do is to use these extensions when available. For example, if you use GLEW to dynamically detect and use GL extensions, you could easily accomplish this by doing: void foo() { if (GLEW_GREMEDY_string_marker) { glStringMarkerGREMEDY(0, __FUNCTION__ ": enter"); } ... if (GLEW_GREMEDY_string_marker) { glStringMarkerGREMEDY(0, __FUNCTION__ ": leave"); } }  This has the added advantage of working equally well with gDEBugger. From OpenGL ES applications you can embed annotations in the trace file through the GL_EXT_debug_marker extension. For Direct3D applications you can follow the standard procedure for adding user defined events to Visual Studio Graphics Debugger / PIX: • D3DPERF_BeginEvent, D3DPERF_EndEvent, and D3DPERF_SetMarker for D3D9 applications. • ID3DUserDefinedAnnotation::BeginEvent, ID3DUserDefinedAnnotation::EndEvent, and ID3DUserDefinedAnnotation::SetMarker for D3D11.1 applications. ## Dump GL state at a particular call You can get a dump of the bound GL state at call 12345 by doing: apitrace replay -D 12345 application.trace > 12345.json  This is precisely the mechanism the GUI obtains its own state. You can compare two state dumps by doing: apitrace diff-state 12345.json 67890.json  ## Comparing two traces side by side apitrace diff trace1.trace trace2.trace  This works only on Unices, and it will truncate the traces due to performance limitations. ## Recording a video with FFmpeg You can make a video of the output by doing apitrace dump-images -o - application.trace \ | ffmpeg -r 30 -f image2pipe -vcodec ppm -i pipe: -vcodec mpeg4 -y output.mp4  ## Trimming a trace You can make a smaller trace by doing: apitrace trim --callset 100-1000 -o trimed.trace applicated.trace  If you need precise control over which calls to trim you can specify the individual call numbers a plaintext file, as described in the 'Call sets' section above. ## Profiling a trace You can perform gpu and cpu profiling with the command line options: • --pgpu record gpu times for frames and draw calls. • --pcpu record cpu times for frames and draw calls. • --ppd record pixels drawn for each draw call. The results from this can then be read by hand or analysed with a script. scripts/profileshader.py will read the profile results and format them into a table which displays profiling results per shader. For example, to record all profiling data and utilise the per shader script: apitrace replay --pgpu --pcpu --ppd foo.trace | ./scripts/profileshader.py  # Advanced usage for OpenGL implementors There are several advanced usage examples meant for OpenGL implementors. ## Regression testing These are the steps to create a regression test-suite around apitrace: • obtain a trace • obtain reference snapshots, by doing on a reference system: mkdir /path/to/reference/snapshots/ apitrace dump-images -o /path/to/reference/snapshots/ application.trace  • prune the snapshots which are not interesting • to do a regression test, use apitrace diff-images: apitrace dump-images -o /path/to/test/snapshots/ application.trace apitrace diff-images --output summary.html /path/to/reference/snapshots/ /path/to/test/snapshots/  ## Automated git-bisection With tracecheck.py it is possible to automate git bisect and pinpoint the commit responsible for a regression. Below is an example of using tracecheck.py to bisect a regression in the Mesa-based Intel 965 driver. But the procedure could be applied to any GL driver hosted on a git repository. First, create a build script, named build-script.sh, containing: #!/bin/sh set -e export PATH=/usr/lib/ccache:$PATH
export CFLAGS='-g'
export CXXFLAGS='-g'
./autogen.sh --disable-egl --disable-gallium --disable-glut --disable-glu --disable-glw --with-dri-drivers=i965
make clean
make "$@"  It is important that builds are both robust, and efficient. Due to broken dependency discovery in Mesa's makefile system, it was necessary invoke make clean in every iteration step. ccache should be installed to avoid recompiling unchanged source files. Then do: cd /path/to/mesa export LIBGL_DEBUG=verbose export LD_LIBRARY_PATH=$PWD/lib
export LIBGL_DRIVERS_DIR=\$PWD/lib
git bisect start \
6491e9593d5cbc5644eb02593a2f562447efdcbb 71acbb54f49089b03d3498b6f88c1681d3f649ac \
-- src/mesa/drivers/dri/intel src/mesa/drivers/dri/i965/
git bisect run /path/to/tracecheck.py \
--precision-threshold 8.0 \
--build /path/to/build-script.sh \
--gl-renderer '.*Mesa.*Intel.*' \
--retrace=/path/to/glretrace \
-c /path/to/reference/snapshots/ \
topogun-1.06-orc-84k.trace


The trace-check.py script will skip automatically when there are build failures.

The --gl-renderer option will also cause a commit to be skipped if the GL_RENDERER is unexpected (e.g., when a software renderer or another GL driver is unintentionally loaded due to missing symbol in the DRI driver, or another runtime fault).

## Side by side retracing

In order to determine which draw call a regression first manifests one could generate snapshots for every draw call, using the -S option. That is, however, very inefficient for big traces with many draw calls.

A faster approach is to run both the bad and a good GL driver side-by-side. The latter can be either a previously known good build of the GL driver, or a reference software renderer.

This can be achieved with retracediff.py script, which invokes glretrace with different environments, allowing to choose the desired GL driver by manipulating variables such as LD_LIBRARY_PATH, LIBGL_DRIVERS_DIR, or TRACE_LIBGL.

For example, on Linux:

./scripts/retracediff.py \
--ref-env LD_LIBRARY_PATH=/path/to/reference/GL/implementation \
--retrace /path/to/glretrace \
--diff-prefix=/path/to/output/diffs \
application.trace


Or on Windows:

python scripts\retracediff.py --retrace \path\to\glretrace.exe --ref-env TRACE_LIBGL=\path\to\reference\opengl32.dll application.trace


qapitrace has rudimentary support for replaying traces on a remote target device. This can be useful, for example, when developing for an embedded system. The primary GUI will run on the local host, while any replays will be performed on the target device.

In order to target a remote device, use the command-line:

qapitrace --remote-target <HOST> <trace-file>


In order for this to work, the following must be available in the system configuration:

1. It must be possible for the current user to initiate an ssh session that has access to the target's window system. The command to be exectuted by qapitrace will be:

ssh <HOST> glretrace


For example, if the target device is using the X window system, one can test whether an ssh session has access to the target X server with:

ssh <HOST> xdpyinfo


If this command fails with something like "cannot open display" then the user will have to configure the target to set the DISPLAY environment variable, (for example, setting DISPLAY=:0 in the .bashrc file on the target or similar).

Also, note that if the ssh session requires a custom username, then this must be configured on the host side so that ssh can be initiated without a username.

For example, if you normally connect with ssh user@192.168.0.2 you could configure ~/.ssh/config on the host with a block such as:

Host target
HostName 192.168.0.2
User user


And after this you should be able to connect with ssh target so that you can also use qapitrace --remote-target target.

2. The target host must have a functional glretrace binary available

3. The target host must have access to at the same path in the filesystem as the path on the host system being passed to the qapitrace command line.

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