2020-06-13 02:09:42 +08:00
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Viewperf Issues
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===============
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This page lists known issues with `SPEC Viewperf
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11 <https://www.spec.org/gwpg/gpc.static/vp11info.html>`__ and `SPEC
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Viewperf 12 <https://www.spec.org/gwpg/gpc.static/vp12info.html>`__ when
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running on Mesa-based drivers.
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The Viewperf data sets are basically GL API traces that are recorded
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from CAD applications, then replayed in the Viewperf framework.
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The primary problem with these traces is they blindly use features and
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OpenGL extensions that were supported by the OpenGL driver when the
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trace was recorded, but there's no checks to see if those features are
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supported by the driver when playing back the traces with Viewperf.
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These issues have been reported to the SPEC organization in the hope
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that they'll be fixed in the future.
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Viewperf 11
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-----------
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Some of the Viewperf 11 tests use a lot of memory. At least 2GB of RAM
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is recommended.
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Catia-03 test 2
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~~~~~~~~~~~~~~~
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This test creates over 38000 vertex buffer objects. On some systems this
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can exceed the maximum number of buffer allocations. Mesa generates
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GL_OUT_OF_MEMORY errors in this situation, but Viewperf does no error
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checking and continues. When this happens, some drawing commands become
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no-ops. This can also eventually lead to a segfault either in Viewperf
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or the Mesa driver.
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Catia-03 tests 3, 4, 8
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~~~~~~~~~~~~~~~~~~~~~~
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These tests use features of the
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`GL_NV_fragment_program2 <https://www.opengl.org/registry/specs/NV/fragment_program2.txt>`__
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and
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`GL_NV_vertex_program3 <https://www.opengl.org/registry/specs/NV/vertex_program3.txt>`__
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extensions without checking if the driver supports them.
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When Mesa tries to compile the vertex/fragment programs it generates
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errors (which Viewperf ignores). Subsequent drawing calls become no-ops
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and the rendering is incorrect.
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sw-02 tests 1, 2, 4, 6
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~~~~~~~~~~~~~~~~~~~~~~
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These tests depend on the
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`GL_NV_primitive_restart <https://www.opengl.org/registry/specs/NV/primitive_restart.txt>`__
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extension.
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If the Mesa driver doesn't support this extension the rendering will be
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incorrect and the test will fail.
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Also, the color of the line drawings in test 2 seem to appear in a
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random color. This is probably due to some uninitialized state
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somewhere.
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sw-02 test 6
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~~~~~~~~~~~~
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The lines drawn in this test appear in a random color. That's because
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texture mapping is enabled when the lines are drawn, but no texture
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image is defined (glTexImage2D() is called with pixels=NULL). Since GL
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says the contents of the texture image are undefined in that situation,
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we get a random color.
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Lightwave-01 test 3
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~~~~~~~~~~~~~~~~~~~
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This test uses a number of mipmapped textures, but the textures are
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incomplete because the last/smallest mipmap level (1 x 1 pixel) is never
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specified.
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A trace captured with `API
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trace <https://github.com/apitrace/apitrace>`__ shows this sequences of
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calls like this:
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::
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2504 glBindTexture(target = GL_TEXTURE_2D, texture = 55)
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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))
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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))
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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))
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[...]
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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))
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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))
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2514 glTexParameteri(target = GL_TEXTURE_2D, pname = GL_TEXTURE_MIN_FILTER, param = GL_LINEAR_MIPMAP_LINEAR)
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2515 glTexParameteri(target = GL_TEXTURE_2D, pname = GL_TEXTURE_WRAP_S, param = GL_REPEAT)
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2516 glTexParameteri(target = GL_TEXTURE_2D, pname = GL_TEXTURE_WRAP_T, param = GL_REPEAT)
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2517 glTexParameteri(target = GL_TEXTURE_2D, pname = GL_TEXTURE_MAG_FILTER, param = GL_NEAREST)
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Note that one would expect call 2514 to be glTexImage(level=9, width=1,
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height=1) but it's not there.
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The minification filter is GL_LINEAR_MIPMAP_LINEAR and the texture's
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GL_TEXTURE_MAX_LEVEL is 1000 (the default) so a full mipmap is expected.
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Later, these incomplete textures are bound before drawing calls.
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According to the GL specification, if a fragment program or fragment
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shader is being used, the sampler should return (0,0,0,1) ("black") when
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sampling from an incomplete texture. This is what Mesa does and the
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resulting rendering is darker than it should be.
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It appears that NVIDIA's driver (and possibly AMD's driver) detects this
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case and returns (1,1,1,1) (white) which causes the rendering to appear
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brighter and match the reference image (however, AMD's rendering is
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*much* brighter than NVIDIA's).
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If the fallback texture created in \_mesa_get_fallback_texture() is
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initialized to be full white instead of full black the rendering appears
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correct. However, we have no plans to implement this work-around in
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Mesa.
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Maya-03 test 2
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~~~~~~~~~~~~~~
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This test makes some unusual calls to glRotate. For example:
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2021-04-15 22:08:52 +08:00
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.. code-block:: c
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glRotate(50, 50, 50, 1);
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glRotate(100, 100, 100, 1);
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glRotate(52, 52, 52, 1);
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These unusual values lead to invalid modelview matrices. For example,
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the last glRotate command above produces this matrix with Mesa:
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2021-04-15 22:23:34 +08:00
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.. math::
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2021-04-15 22:23:34 +08:00
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\begin{matrix}
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1.08536 \times 10^{24} & 2.55321 \times 10^{-23} & -0.000160389 & 0\\
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5.96937 \times 10^{25} & 1.08536 \times 10^{24} & 103408 & 0\\
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103408 & -0.000160389 & 1.74755\times 10^{9} & 0\\
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0 & 0 & 0 & nan
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\end{matrix}
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and with NVIDIA's OpenGL:
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2021-04-15 22:23:34 +08:00
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.. math::
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2021-04-15 22:23:34 +08:00
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\begin{matrix}
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1.4013 \times 10^{-45} & 0 & -nan & 0\\
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0 & 1.4013 \times 10^{-45} & 1.4013 \times 10^{-45} & 0\\
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1.4013 \times 10^{-45} & -nan & 1.4013 \times 10^{-45} & 0\\
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0 & 0 & 0 & 1.4013 \times 10^{-45}
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\end{matrix}
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2020-06-13 02:09:42 +08:00
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This causes the object in question to be drawn in a strange orientation
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and with a semi-random color (between white and black) since GL_FOG is
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enabled.
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Proe-05 test 1
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~~~~~~~~~~~~~~
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This uses depth testing but there's two problems:
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#. The glXChooseFBConfig() call doesn't request a depth buffer
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#. The test never calls glClear(GL_DEPTH_BUFFER_BIT) to initialize the
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depth buffer
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If the chosen visual does not have a depth buffer, you'll see the
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wireframe car model but it won't be rendered correctly.
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If (by luck) the chosen visual has a depth buffer, its initial contents
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will be undefined so you may or may not see parts of the model.
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Interestingly, with NVIDIA's driver most visuals happen to have a depth
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buffer and apparently the contents are initialized to 1.0 by default so
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this test just happens to work with their drivers.
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Finally, even if a depth buffer was requested and the
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glClear(GL_COLOR_BUFFER_BIT) calls were changed to
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glClear(GL_COLOR_BUFFER_BIT \| GL_DEPTH_BUFFER_BIT) the problem still
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wouldn't be fixed because GL_DEPTH_WRITEMASK=GL_FALSE when glClear is
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called so clearing the depth buffer would be a no-op anyway.
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Proe-05 test 6
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~~~~~~~~~~~~~~
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This test draws an engine model with a two-pass algorithm. The first
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pass is drawn with polygon stipple enabled. The second pass is drawn
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without polygon stipple but with blending and GL_DEPTH_FUNC=GL_LEQUAL.
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If either of the two passes happen to use a software fallback of some
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sort, the Z values of fragments may be different between the two passes.
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This leads to incorrect rendering.
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2020-09-28 19:49:20 +08:00
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For example, the VMware SVGA Gallium driver uses a special semi-fallback
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path for drawing with polygon stipple. Since the two passes are rendered
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with different vertex transformation implementations, the rendering
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doesn't appear as expected. Setting the SVGA_FORCE_SWTNL environment
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variable to 1 will force the driver to use the software vertex path all
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the time and clears up this issue.
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According to the OpenGL invariance rules, there's no guarantee that the
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pixels produced by these two rendering states will match. To achieve
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invariance, both passes should enable polygon stipple and blending with
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appropriate patterns/modes to ensure the same fragments are produced in
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both passes.
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Viewperf 12
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-----------
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Note that Viewperf 12 only runs on 64-bit Windows 7 or later.
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catia-04
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~~~~~~~~
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One of the catia tests calls wglGetProcAddress() to get some
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GL_EXT_direct_state_access functions (such as glBindMultiTextureEXT) and
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some GL_NV_half_float functions (such as glMultiTexCoord3hNV). If the
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extension/function is not supported, wglGetProcAddress() can return
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NULL. Unfortunately, Viewperf doesn't check for null pointers and
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crashes when it later tries to use the pointer.
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Another catia test uses OpenGL 3.1's primitive restart feature. But when
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Viewperf creates an OpenGL context, it doesn't request version 3.1 If
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the driver returns version 3.0 or earlier all the calls related to
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primitive restart generate an OpenGL error. Some of the rendering is
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then incorrect.
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energy-01
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~~~~~~~~~
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This test creates a 3D luminance texture of size 1K x 1K x 1K. If the
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OpenGL driver/device doesn't support a texture of this size the
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glTexImage3D() call will fail with GL_INVALID_VALUE or GL_OUT_OF_MEMORY
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and all that's rendered is plain white polygons. Ideally, the test would
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use a proxy texture to determine the max 3D texture size. But it does
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not do that.
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maya-04
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~~~~~~~
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This test generates many GL_INVALID_OPERATION errors in its calls to
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glUniform(). Causes include:
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- Trying to set float uniforms with glUniformi()
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- Trying to set float uniforms with glUniform3f()
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- Trying to set matrix uniforms with glUniform() instead of
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glUniformMatrix().
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Apparently, the indexes returned by glGetUniformLocation() were
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hard-coded into the application trace when it was created. Since
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different implementations of glGetUniformLocation() may return different
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values for any given uniform name, subsequent calls to glUniform() will
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be invalid since they refer to the wrong uniform variables. This causes
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many OpenGL errors and leads to incorrect rendering.
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medical-01
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~~~~~~~~~~
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This test uses a single GLSL fragment shader which contains a GLSL 1.20
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array initializer statement, but it neglects to specify ``#version 120``
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at the top of the shader code. So, the shader does not compile and all
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that's rendered is plain white polygons.
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Also, the test tries to create a very large 3D texture that may exceed
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the device driver's limit. When this happens, the glTexImage3D call
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fails and all that's rendered is a white box.
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showcase-01
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~~~~~~~~~~~
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This is actually a DX11 test based on Autodesk's Showcase product. As
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such, it won't run with Mesa.
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