The Viewperf data sets are basically GL API traces that are recorded from CAD applications, then replayed in the Viewperf framework.
The primary problem with these traces is they blindly use features and OpenGL extensions that were supported by the OpenGL driver when the trace was recorded, but there’s no checks to see if those features are supported by the driver when playing back the traces with Viewperf.
These issues have been reported to the SPEC organization in the hope that they’ll be fixed in the future.
Some of the Viewperf 11 tests use a lot of memory. At least 2GB of RAM is recommended.
Catia-03 test 2¶
This test creates over 38000 vertex buffer objects. On some systems this can exceed the maximum number of buffer allocations. Mesa generates GL_OUT_OF_MEMORY errors in this situation, but Viewperf does no error checking and continues. When this happens, some drawing commands become no-ops. This can also eventually lead to a segfault either in Viewperf or the Mesa driver.
Catia-03 tests 3, 4, 8¶
When Mesa tries to compile the vertex/fragment programs it generates errors (which Viewperf ignores). Subsequent drawing calls become no-ops and the rendering is incorrect.
sw-02 tests 1, 2, 4, 6¶
These tests depend on the GL_NV_primitive_restart extension.
If the Mesa driver doesn’t support this extension the rendering will be incorrect and the test will fail.
Also, the color of the line drawings in test 2 seem to appear in a random color. This is probably due to some uninitialized state somewhere.
sw-02 test 6¶
The lines drawn in this test appear in a random color. That’s because texture mapping is enabled when the lines are drawn, but no texture image is defined (glTexImage2D() is called with pixels=NULL). Since GL says the contents of the texture image are undefined in that situation, we get a random color.
Lightwave-01 test 3¶
This test uses a number of mipmapped textures, but the textures are incomplete because the last/smallest mipmap level (1 x 1 pixel) is never specified.
A trace captured with API trace shows this sequences of calls like this:
2504 glBindTexture(target = GL_TEXTURE_2D, texture = 55) 2505 glTexImage2D(target = GL_TEXTURE_2D, level = 0, internalformat = GL_RGBA, width = 512, height = 512, border = 0, format = GL_RGB, type = GL_UNSIGNED_SHORT, pixels = blob(1572864)) 2506 glTexImage2D(target = GL_TEXTURE_2D, level = 1, internalformat = GL_RGBA, width = 256, height = 256, border = 0, format = GL_RGB, type = GL_UNSIGNED_SHORT, pixels = blob(393216)) 2507 glTexImage2D(target = GL_TEXTURE_2D, level = 2, internalformat = GL_RGBA, width = 128, height = 128, border = 0, format = GL_RGB, type = GL_UNSIGNED_SHORT, pixels = blob(98304)) [...] 2512 glTexImage2D(target = GL_TEXTURE_2D, level = 7, internalformat = GL_RGBA, width = 4, height = 4, border = 0, format = GL_RGB, type = GL_UNSIGNED_SHORT, pixels = blob(96)) 2513 glTexImage2D(target = GL_TEXTURE_2D, level = 8, internalformat = GL_RGBA, width = 2, height = 2, border = 0, format = GL_RGB, type = GL_UNSIGNED_SHORT, pixels = blob(24)) 2514 glTexParameteri(target = GL_TEXTURE_2D, pname = GL_TEXTURE_MIN_FILTER, param = GL_LINEAR_MIPMAP_LINEAR) 2515 glTexParameteri(target = GL_TEXTURE_2D, pname = GL_TEXTURE_WRAP_S, param = GL_REPEAT) 2516 glTexParameteri(target = GL_TEXTURE_2D, pname = GL_TEXTURE_WRAP_T, param = GL_REPEAT) 2517 glTexParameteri(target = GL_TEXTURE_2D, pname = GL_TEXTURE_MAG_FILTER, param = GL_NEAREST)
Note that one would expect call 2514 to be glTexImage(level=9, width=1, height=1) but it’s not there.
The minification filter is GL_LINEAR_MIPMAP_LINEAR and the texture’s GL_TEXTURE_MAX_LEVEL is 1000 (the default) so a full mipmap is expected.
Later, these incomplete textures are bound before drawing calls. According to the GL specification, if a fragment program or fragment shader is being used, the sampler should return (0,0,0,1) (“black”) when sampling from an incomplete texture. This is what Mesa does and the resulting rendering is darker than it should be.
It appears that NVIDIA’s driver (and possibly AMD’s driver) detects this case and returns (1,1,1,1) (white) which causes the rendering to appear brighter and match the reference image (however, AMD’s rendering is much brighter than NVIDIA’s).
If the fallback texture created in _mesa_get_fallback_texture() is initialized to be full white instead of full black the rendering appears correct. However, we have no plans to implement this work-around in Mesa.
Maya-03 test 2¶
This test makes some unusual calls to glRotate. For example:
glRotate(50, 50, 50, 1); glRotate(100, 100, 100, 1); glRotate(52, 52, 52, 1);
These unusual values lead to invalid modelview matrices. For example, the last glRotate command above produces this matrix with Mesa:
1.08536e+24 2.55321e-23 -0.000160389 0 5.96937e-25 1.08536e+24 103408 0 103408 -0.000160389 1.74755e+09 0 0 0 0 nan
and with NVIDIA’s OpenGL:
1.4013e-45 0 -nan 0 0 1.4013e-45 1.4013e-45 0 1.4013e-45 -nan 1.4013e-45 0 0 0 0 1.4013e-45
This causes the object in question to be drawn in a strange orientation and with a semi-random color (between white and black) since GL_FOG is enabled.
Proe-05 test 1¶
This uses depth testing but there’s two problems:
The glXChooseFBConfig() call doesn’t request a depth buffer
The test never calls glClear(GL_DEPTH_BUFFER_BIT) to initialize the depth buffer
If the chosen visual does not have a depth buffer, you’ll see the wireframe car model but it won’t be rendered correctly.
If (by luck) the chosen visual has a depth buffer, its initial contents will be undefined so you may or may not see parts of the model.
Interestingly, with NVIDIA’s driver most visuals happen to have a depth buffer and apparently the contents are initialized to 1.0 by default so this test just happens to work with their drivers.
Finally, even if a depth buffer was requested and the glClear(GL_COLOR_BUFFER_BIT) calls were changed to glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT) the problem still wouldn’t be fixed because GL_DEPTH_WRITEMASK=GL_FALSE when glClear is called so clearing the depth buffer would be a no-op anyway.
Proe-05 test 6¶
This test draws an engine model with a two-pass algorithm. The first pass is drawn with polygon stipple enabled. The second pass is drawn without polygon stipple but with blending and GL_DEPTH_FUNC=GL_LEQUAL. If either of the two passes happen to use a software fallback of some sort, the Z values of fragments may be different between the two passes. This leads to incorrect rendering.
For example, the VMware SVGA gallium driver uses a special semi-fallback path for drawing with polygon stipple. Since the two passes are rendered with different vertex transformation implementations, the rendering doesn’t appear as expected. Setting the SVGA_FORCE_SWTNL environment variable to 1 will force the driver to use the software vertex path all the time and clears up this issue.
According to the OpenGL invariance rules, there’s no guarantee that the pixels produced by these two rendering states will match. To achieve invariance, both passes should enable polygon stipple and blending with appropriate patterns/modes to ensure the same fragments are produced in both passes.
Note that Viewperf 12 only runs on 64-bit Windows 7 or later.
One of the catia tests calls wglGetProcAddress() to get some GL_EXT_direct_state_access functions (such as glBindMultiTextureEXT) and some GL_NV_half_float functions (such as glMultiTexCoord3hNV). If the extension/function is not supported, wglGetProcAddress() can return NULL. Unfortunately, Viewperf doesn’t check for null pointers and crashes when it later tries to use the pointer.
Another catia test uses OpenGL 3.1’s primitive restart feature. But when Viewperf creates an OpenGL context, it doesn’t request version 3.1 If the driver returns version 3.0 or earlier all the calls related to primitive restart generate an OpenGL error. Some of the rendering is then incorrect.
This test creates a 3D luminance texture of size 1K x 1K x 1K. If the OpenGL driver/device doesn’t support a texture of this size the glTexImage3D() call will fail with GL_INVALID_VALUE or GL_OUT_OF_MEMORY and all that’s rendered is plain white polygons. Ideally, the test would use a proxy texture to determine the max 3D texture size. But it does not do that.
This test generates many GL_INVALID_OPERATION errors in its calls to glUniform(). Causes include:
Trying to set float uniforms with glUniformi()
Trying to set float uniforms with glUniform3f()
Trying to set matrix uniforms with glUniform() instead of glUniformMatrix().
Apparently, the indexes returned by glGetUniformLocation() were hard-coded into the application trace when it was created. Since different implementations of glGetUniformLocation() may return different values for any given uniform name, subsequent calls to glUniform() will be invalid since they refer to the wrong uniform variables. This causes many OpenGL errors and leads to incorrect rendering.
This test uses a single GLSL fragment shader which contains a GLSL 1.20
array initializer statement, but it neglects to specify
at the top of the shader code. So, the shader does not compile and all
that’s rendered is plain white polygons.
Also, the test tries to create a very large 3D texture that may exceed the device driver’s limit. When this happens, the glTexImage3D call fails and all that’s rendered is a white box.
This is actually a DX11 test based on Autodesk’s Showcase product. As such, it won’t run with Mesa.