The emission of vertex attributes corresponding to dvec3 and dvec4 vertex shader input variables was not correct when the <size> passed to the VertexAttribL* commands was <= 2. This was because we were using the vertex array size when emitting vertices to decide if we uploaded a 64-bit floating point attribute as 1 slot (128-bits) for sizes 1 and 2, or 2 slots (256-bits) for sizes 3 and 4. This caused problems when mapping the input variables to registers because, for deciding which registers contain the values uploaded for a certain variable, we use the size and type given to the variable in the shader, so we will be assigning 256-bits to dvec3/4 variables, even if we only uploaded 128-bits for them, which happened when the vertex array size was <= 2. The patch uses the shader information to only emit as 128-bits those 64-bit floating point variables that were declared as double or dvec2 in the vertex shader. Dvec3 and dvec4 variables will be always uploaded as 256-bits, independently of the <size> given to the VertexAttribL* command. From the ARB_vertex_attrib_64bit specification: "For the 64-bit double precision types listed in Table X.1, no default attribute values are provided if the values of the vertex attribute variable are specified with fewer components than required for the attribute variable. For example, the fourth component of a variable of type dvec4 will be undefined if specified using VertexAttribL3dv or using a vertex array specified with VertexAttribLPointer and a size of three." We are filling these unspecified components with zeros, which coincidentally is also what the GL44-CTS.vertex_attrib_binding.basic-inputL-case1 expects. v2: Do not use bitcount (Kenneth Graunke) Fixes: GL44-CTS.vertex_attrib_binding.basic-inputL-case1 test Bugzilla: https://bugs.freedesktop.org/show_bug.cgi?id=97287 Reviewed-by: Kenneth Graunke <kenneth@whitecape.org> |
||
---|---|---|
bin | ||
docs | ||
doxygen | ||
include | ||
m4 | ||
scons | ||
scripts | ||
src | ||
.dir-locals.el | ||
.editorconfig | ||
.gitattributes | ||
.gitignore | ||
.mailmap | ||
.travis.yml | ||
Android.common.mk | ||
Android.mk | ||
CleanSpec.mk | ||
Makefile.am | ||
REVIEWERS | ||
SConstruct | ||
VERSION | ||
appveyor.yml | ||
autogen.sh | ||
common.py | ||
configure.ac | ||
install-gallium-links.mk | ||
install-lib-links.mk |
docs/README.WIN32
File: docs/README.WIN32 Last updated: 21 June 2013 Quick Start ----- ----- Windows drivers are build with SCons. Makefiles or Visual Studio projects are no longer shipped or supported. Run scons libgl-gdi to build gallium based GDI driver. This will work both with MSVS or Mingw. Windows Drivers ------- ------- At this time, only the gallium GDI driver is known to work. Source code also exists in the tree for other drivers in src/mesa/drivers/windows, but the status of this code is unknown. Recipe ------ Building on windows requires several open-source packages. These are steps that work as of this writing. - install python 2.7 - install scons (latest) - install mingw, flex, and bison - install pywin32 from here: http://www.lfd.uci.edu/~gohlke/pythonlibs get pywin32-218.4.win-amd64-py2.7.exe - install git - download mesa from git see http://www.mesa3d.org/repository.html - run scons General ------- After building, you can copy the above DLL files to a place in your PATH such as $SystemRoot/SYSTEM32. If you don't like putting things in a system directory, place them in the same directory as the executable(s). Be careful about accidentially overwriting files of the same name in the SYSTEM32 directory. The DLL files are built so that the external entry points use the stdcall calling convention. Static LIB files are not built. The LIB files that are built with are the linker import files associated with the DLL files. The si-glu sources are used to build the GLU libs. This was done mainly to get the better tessellator code. If you have a Windows-related build problem or question, please post to the mesa-dev or mesa-users list.