**apitrace** consists of a set of tools to:
-* trace OpenGL, OpenGL ES, D3D9, D3D8, D3D7, and DDRAW APIs calls to a file;
+* trace OpenGL, OpenGL ES, Direct3D, and DirectDraw APIs calls to a file;
-* retrace OpenGL and OpenGL ES calls from 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](http://apitrace.github.io/) for more details.
+
+
+Obtaining **apitrace**
+======================
+
+To obtain apitrace either [download the latest
+binaries](http://apitrace.github.io/#download) 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
===========
[DebugView](http://technet.microsoft.com/en-us/sysinternals/bb896647) 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
- glretrace application.trace
+ apitrace replay application.trace
+
+Pass the `--sb` option to use a single buffered visual. Pass `--help` to
+`apitrace replay` for more options.
+
-Pass the `-sb` option to use a single buffered visual. Pass `--help` to
-glretrace 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
+
Advanced command line usage
===========================
Several tools take `CALLSET` arguments, e.g:
- apitrace dump --calls CALLSET foo.trace
- glretrace -S CALLSET foo.trace
+ 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
- * `1,2,4,5` set of calls
+ * `0,2,4,5` set of calls
- * `"1 2 4 5"` set of calls (commas are optional and can be replaced with whitespace)
+ * `"0 2 4 5"` set of calls (commas are optional and can be replaced with whitespace)
- * `1-100/2` calls 1, 3, 5, ..., 99
+ * `0-100/2` calls 1, 3, 5, ..., 99
- * `1-1000/draw` all draw calls between 1 and 1000
+ * `0-1000/draw` all draw calls between 0 and 1000
- * `1-1000/fbo` all fbo changes between calls 1 and 1000
+ * `0-1000/fbo` all fbo changes between calls 0 and 1000
* `frame` all calls at end of frames
### Linux ###
-Run the application you want to trace as
+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
+ 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.
-The `LD_PRELOAD` mechanism should work with most applications. There are some
-applications, e.g., Unigine Heaven, which 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 into
-`LD_LIBRARY_PATH`:
+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
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.
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
### Windows ###
-Copy `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.
+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
---------------------------------
extension.
-For Direct3D applications you can follow the same procedure used for
-[instrumenting an application for PIX](http://technet.microsoft.com/en-us/query/ee417250)
+For Direct3D applications you can follow the standard procedure for
+[adding user defined events to Visual Studio Graphics Debugger / PIX](http://msdn.microsoft.com/en-us/library/vstudio/hh873200.aspx):
+
+- `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:
- glretrace -D 12345 application.trace > 12345.json
+ apitrace replay -D 12345 application.trace > 12345.json
This is precisely the mechanism the GUI obtains its own state.
limitations.
-Recording a video with FFmpeg
------------------------------
+Recording a video with FFmpeg/Libav
+-----------------------------------
-You can make a video of the output by doing
+You can make a video of the output with FFmpeg by doing
- glretrace -s - application.trace \
+ apitrace dump-images -o - application.trace \
| ffmpeg -r 30 -f image2pipe -vcodec ppm -i pipe: -vcodec mpeg4 -y output.mp4
+or Libav (which replaces FFmpeg on recent Debian/Ubuntu distros) doing
+
+ apitrace dump-images -o - application.trace \
+ | avconv -r 30 -f image2pipe -vcodec ppm -i - -vcodec mpeg4 -y output.mp4
-Triming a trace
----------------
+Recording a video with gstreamer
+--------------------------------------
-You can make a smaller trace by doing:
+You can make a video of the output with gstreamer by doing
- apitrace trim --callset 100-1000 -o trimed.trace applicated.trace
+ glretrace --snapshot-format=RGB -s - smokinguns.trace | gst-launch-0.10 fdsrc blocksize=409600 ! queue \
+ ! videoparse format=rgb width=1920 height=1080 ! queue ! ffmpegcolorspace ! queue \
+ ! vaapiupload direct-rendering=0 ! queue ! vaapiencodeh264 ! filesink location=xxx.264
+
+Trimming a trace
+----------------
+
+You can truncate a trace by doing:
+
+ apitrace trim --exact --calls 0-12345 -o trimed.trace application.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.
+There is also experimental support for automatically trimming the calls
+necessary for a given frame or call:
+
+ apitrace trim --auto --calls=12345 -o trimed.trace application.trace
+ apitrace trim --auto --frames=12345 -o trimed.trace application.trace
+
+
+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
======================================
* obtain reference snapshots, by doing on a reference system:
mkdir /path/to/reference/snapshots/
- glretrace -s /path/to/reference/snapshots/ application.trace
+ apitrace dump-images -o /path/to/reference/snapshots/ application.trace
* prune the snapshots which are not interesting
-* to do a regression test, do:
-
- glretrace -c /path/to/reference/snapshots/ application.trace
+* to do a regression test, use `apitrace diff-images`:
- Alternatively, for a HTML summary, use `apitrace diff-images`:
-
- glretrace -s /path/to/test/snapshots/ application.trace
+ apitrace dump-images -o /path/to/test/snapshots/ application.trace
apitrace diff-images --output summary.html /path/to/reference/snapshots/ /path/to/test/snapshots/
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` or `LIBGL_DRIVERS_DIR`.
+manipulating variables such as `LD_LIBRARY_PATH`, `LIBGL_DRIVERS_DIR`, or
+`TRACE_LIBGL`.
-For example:
+For example, on Linux:
./scripts/retracediff.py \
--ref-env LD_LIBRARY_PATH=/path/to/reference/GL/implementation \
- -r ./glretrace \
+ --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
-Links
-=====
-
-About **apitrace**:
-
-* [Official mailing list](http://lists.freedesktop.org/mailman/listinfo/apitrace)
-* [Zack Rusin's blog introducing the GUI](http://zrusin.blogspot.com/2011/04/apitrace.html)
-
-* [Jose's Fonseca blog introducing the tool](http://jrfonseca.blogspot.com/2008/07/tracing-d3d-applications.html)
-
-
-Direct3D
---------
-
-Open-source:
-
-* [Proxy DLL](http://www.mikoweb.eu/index.php?node=21)
+Advanced GUI usage
+==================
- * [Intercept Calls to DirectX with a Proxy DLL](http://www.codeguru.com/cpp/g-m/directx/directx8/article.php/c11453/)
+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.
-* [Direct3D 9 API Interceptor](http://graphics.stanford.edu/~mdfisher/D3D9Interceptor.html)
+In order to target a remote device, use the command-line:
-Closed-source:
+ qapitrace --remote-target <HOST> <trace-file>
-* [Microsoft PIX](http://msdn.microsoft.com/en-us/library/ee417062.aspx)
+In order for this to work, the following must be available in the
+system configuration:
- * [D3DSpy](http://doc.51windows.net/Directx9_SDK/?url=/directx9_sdk/graphics/programmingguide/TutorialsAndSamplesAndToolsAndTips/Tools/D3DSpy.htm): the predecessor of PIX
+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:
-* [AMD GPU PerfStudio](http://developer.amd.com/gpu/PerfStudio/pages/APITraceWindow.aspx)
+ 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:
-OpenGL
-------
+ ssh <HOST> xdpyinfo
-Open-source:
+ 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).
-* [BuGLe](http://www.opengl.org/sdk/tools/BuGLe/)
+ 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.
-* [GLIntercept](http://code.google.com/p/glintercept/)
+ 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:
-* [tracy](https://gitorious.org/tracy): OpenGL ES and OpenVG trace, retrace, and state inspection
+ Host target
+ HostName 192.168.0.2
+ User user
-Closed-source:
+ And after this you should be able to connect with `ssh target` so
+ that you can also use `qapitrace --remote-target target`.
-* [gDEBugger](http://www.gremedy.com/products.php)
+2. The target host must have a functional glretrace binary available
-* [glslDevil](http://cumbia.informatik.uni-stuttgart.de/glsldevil/index.html)
+3. The target host must have access to <trace-file> at the same path
+ in the filesystem as the <trace-file> path on the host system being
+ passed to the qapitrace command line.
-* [AMD GPU PerfStudio](http://developer.amd.com/gpu/PerfStudio/pages/APITraceWindow.aspx)
+[![githalytics.com alpha](https://cruel-carlota.pagodabox.com/c1062ad633aa7a458e9d7520021307e4 "githalytics.com")](http://githalytics.com/apitrace/apitrace)