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It was the first major revision to OpenGL since the creation of OpenGL 1.0 in 1992. Some benefits of using GLSL are: Cross-platform compatibility on multiple operating systems, including Linux, macOS and Windows. The ability to write shaders that can be used on any hardware vendor's graphics card that supports the OpenGL Shading Language.
GLSL 1.5, Geometry Shader, Multi-sampled textures [53] 3.3 March 11, 2010 GLSL 3.30, Backports as much function as possible from the OpenGL 4.0 specification 4.0 March 11, 2010 GLSL 4.00, Tessellation on GPU, shaders with 64-bit precision [54] 4.1 July 26, 2010 GLSL 4.10, Developer-friendly debug outputs [a], compatibility with OpenGL ES 2.0 ...
The unified shader model uses the same hardware resources for both vertex and fragment processing. In the field of 3D computer graphics, the unified shader model (known in Direct3D 10 as "Shader Model 4.0") refers to a form of shader hardware in a graphical processing unit (GPU) where all of the shader stages in the rendering pipeline (geometry, vertex, pixel, etc.) have the same capabilities.
2020-05-27: Mesa 20.1 released NIR vectorisation support and shared virtual memory support for OpenCL in Clover 2020-11-30: Mesa 20.3 full support of OpenCL 1.2 in Clover [41] 2021-03-11: Mesa 21.0 initial support of "D3D12“: Direct 3D 12 for WSL2 in Windows 10 with OpenGL 3.3+, ARM Freedreno: OpenGL 3.3+
OpenGL for Embedded Systems (OpenGL ES or GLES) is a subset of the OpenGL computer graphics rendering application programming interface (API) for rendering 2D and 3D computer graphics such as those used by video games, typically hardware-accelerated using a graphics processing unit (GPU). It is designed for embedded systems like smartphones ...
Historically the number of ROPs, texture mapping units (TMUs), and shader processing units/stream processors have been equal. However, from 2004, several GPUs have decoupled these areas to allow optimum transistor allocation for application workload and available memory performance. As the trend continues, it is expected that graphics ...
Shader Model 2.0b — Radeon X700-X850 shader model, DirectX 9.0b. Shader Model 3.0 — Radeon X1000 and GeForce 6, DirectX 9.0c. Shader Model 4.0 — Radeon HD 2000 and GeForce 8, DirectX 10. Shader Model 4.1 — Radeon HD 3000 and GeForce 200, DirectX 10.1. Shader Model 5.0 — Radeon HD 5000 and GeForce 400, DirectX 11.
It is a direct representation of the intermediate shader bytecode which is passed to the graphics driver for execution. The shader assembly language cannot be directly used to program unified Shader Model 4.0, 4.1, 5.0, and 5.1, although it retains its function as a representation of the intermediate bytecode for debug purposes. [6]