Before reporting, please skim through the known issues below.
Report any issues on github, always including the following information:
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operating system name and version
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OpenGL/D3D driver name and version
These are issues that the developers are already aware of, but for which there is no immediate plan to address them, because either:
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they stem from architectural limitations that are difficult to overcome and/or time-consuming;
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they are corners cases that are thought to be of very little practical use;
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merely lack of time/opportunity.
That said, feel free to file an issue and/or send an email to the mailing list if:
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you want discuss the rationale, propose your ideas on how to address it, or volunteer to work on it;
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a known issue is important for you and you would like to see it addressed sooner rather than later.
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Fake calls may be emitted in the trace, in order to provide complete information for retracing. The typical case is OpenGL vertex arrays in user memory (as opposed to VBOs): where glXxxPointer calls will be deferred, glInterleavedArrays will be decomposed, etc.
This should not affect the rendered output, but it may use different paths in the OpenGL driver, exercising different paths and with different performance characteristics.
There is no way to distinguish the fake calls from those actually made by the application yet.
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Huge traces will be generated for applications that make extensive use of immediate mode drawing (ie., glBegin/glEnd), use vertex/element arrays in user memory, or generate a lot of dynamic vertex data per frame. This is because large quantities of (often redundant) data will be recorded over and over; and although the traces are compressed, the compression algorithms used aim a good performance/compression balance, hence fail to identify and remove the redundancy at this scale.
However, this should not be a problem for modern OpenGL applications that make an efficient use of VBOs and vertex shaders.
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On MacOSX, the internal OpenGL calls done by GLU are not traced yet.
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Replaying can take substantially more CPU due to the overhead of reading the trace file from disk.
However, the overhead should not be significant for modern 3D applications that do efficient use of VBOs and vertex shaders. The communication between CPU to GPU can easily be a bottleneck on the powerful discrete GPUs of nowadays, and trace overhead tend to be propotional so it is not a coincidence that applications that are optimized for modern GPUs will also be traced and replayed efficiently.
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glretrace needs to infer window sizes from glViewport calls, because calls that create/resize windows happen outside of OpenGL and are not traced. Therefore window will be missing if the application relies on the default viewport instead of explicitly invoking glViewport; or it will to too big if the window is shrunk. Most apps call glViewport before rendering.
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OS specific OpenGL APIs (WGL, GLX, CGL, etc), are not retraced literally, but instead partially emulated. This is by design, to allow traces to be retraced on any OS, as the focus is on the OS-independent parts of OpenGL API.
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There is no guarantee that the same visual that was used on tracing will be used for retracing OpenGL. Actually currently, glretrace will always choose a standard 32bit RGBA, 24bit depth, 8bit alpha, double buffer visual. Unless overridden on command line.
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OpenGL context sharing is not fully respected -- all contexts are assumed to share state. This is by far the most common case though.
- Not all types of arguments can be edited.
Issues should be preferably filed on github to facilitate collaborative development and for future reference.
Access to applications source code is not required -- binaries are sufficient.
If the bug happens with a proprietary application, and you don't want to publicly release the application and/or any data collected from it, then alternatively you can provide the necessary application and/or data via e-mail, to jose dot r dot fonseca at gmail dot com.
If it is not technically/legally feasible for you to provide application and/or data at all, then you must be either:
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develop and provide a test application, stripped-down of all proprietary/confidential data, but that can reproduce the issue;
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be willing/able to do the investigation of the issue, namely to identify the root cause of the issue (e.g., which OpenGL call is not properly handled and why), using all necessary tools (such as debuggers).
Failure to do so will render the apitrace authors powerless to address the issue.
github issue tracker doesn't support attachments.
Please attach long logs to https://gist.github.com/ and paste the URL into the issue description.
For big attachments, such as traces, please upload them temporarily to a web server you control, or use a file upload service such as Google Drive or Dropbox and paste the URL into the issue description.
Trace files are only slightly compressed (for performance reasons). You can further reduce their size when attaching/uploading by compressing with XZ or 7-Zip.
For bugs that happen while tracing (e.g., crashes while tracing the application, or incorrect traces) please:
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provide information on how to obtain the application;
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describe how you were using it when the issue happened.
For bugs on retracing (e.g. crashes when retracing the application, incorrect inconsistent rendering, or viewing with the GUI) please:
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provide the trace file;
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describe the results you got, and what results you were expecting.
Please rebuild apitrace with debugging information, by passing
-DCMAKE_BUILD_TYPE=Debug to cmake, or editing its value in CMakeCache.txt
and rebuilding.
To obtain a stack back-trace, run the application with gdb from a terminal:
$ gdb --args application arg1 arg2 ...
(gdb) run
...
(gdb) bt
...
(gdb) quit
To trace an application inside GDB invoke apitrace as:
apitrace trace --verbose --debug application arg1 ...
See also more detailed and Distro specific instructions:
Before you can debug you must first enable developer mode on the machine if you haven't done so before:
sudo /usr/sbin/DevToolsSecurity --enable
To trace an application inside LLDB and obtain a stack backtrace invoke apitrace as:
$ apitrace trace --verbose --debug application arg1 ...
...
(lldb) bt
...
(lldb) quit
See: