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From what I understand (correct me if I am wrong), the OpenGL api converts the function calls written by the programmer in the source code into the specific gpu driver calls of our graphic card. Then, the gpu driver is able to really send instructions and data to the graphic card through some hardware interface like PCIe, AGP or PCI.

My question is, does openGL knows how to interact with different graphic cards because there are basically only 3 types of physical connections (PCIe, AGP and PCI)?

I think it is not that simple, because I always read that different graphic cards have different drivers, so a driver is not just a way to use the physical interfaces, but it serves also the purpose to have graphic cards able to perform different types of commands (which are vendor specific).

I just do not get the big picture.

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1 Answer 1

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This is a copy of my answer to the question "How does OpenGL work at the lowest level?" (the question has been marked for deletion, so I add some redundancy here).

This question is almost impossible to answer because OpenGL by itself is just a front end API, and as long as an implementations adheres to the specification and the outcome conforms to this it can be done any way you like.

The question may have been: How does an OpenGL driver work on the lowest level. Now this is again impossible to answer in general, as a driver is closely tied to some piece of hardware, which may again do things however the developer designed it.

So the question should have been: "How does it look on average behind the scenes of OpenGL and the graphics system?". Let's look at this from the bottom up:

  1. At the lowest level there's some graphics device. Nowadays these are GPUs which provide a set of registers controlling their operation (which registers exactly is device dependent) have some program memory for shaders, bulk memory for input data (vertices, textures, etc.) and an I/O channel to the rest of the system over which it recieves/sends data and command streams.

  2. The graphics driver keeps track of the GPUs state and all the resources application programs that make use of the GPU. Also it is responsible for conversion or any other processing the data sent by applications (convert textures into the pixelformat supported by the GPU, compile shaders in the machine code of the GPU). Furthermore it provides some abstract, driver dependent interface to application programs.

  3. Then there's the driver dependent OpenGL client library/driver. On Windows this gets loaded by proxy through opengl32.dll, on Unix systems this resides in two places:

    • X11 GLX module and driver dependent GLX driver
    • and /usr/lib/libGL.so may contain some driver dependent stuff for direct rendering

    On MacOS X this happens to be the "OpenGL Framework".

    It is this part that translates OpenGL calls how you do it into calls to the driver specific functions in the part of the driver described in (2).

  4. Finally the actual OpenGL API library, opengl32.dll in Windows, and on Unix /usr/lib/libGL.so; this mostly just passes down the commands to the OpenGL implementation proper.

How the actual communication happens can not be generalized:

In Unix the 3<->4 connection may happen either over Sockets (yes, it may, and does go over network if you want to) or through Shared Memory. In Windows the interface library and the driver client are both loaded into the process address space, so that's no so much communication but simple function calls and variable/pointer passing. In MacOS X this is similar to Windows, only that there's no separation between OpenGL interface and driver client (that's the reason why MacOS X is so slow to keep up with new OpenGL versions, it always requires a full operating system upgrade to deliver the new framework).

Communication betwen 3<->2 may go through ioctl, read/write, or through mapping some memory into process address space and configuring the MMU to trigger some driver code whenever changes to that memory are done. This is quite similar on any operating system since you always have to cross the kernel/userland boundary: Ultimately you go through some syscall.

Communication between system and GPU happen through the periphial bus and the access methods it defines, so PCI, AGP, PCI-E, etc, which work through Port-I/O, Memory Mapped I/O, DMA, IRQs.

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To summarize in a few words... Every graphic card vendor has to supply their buyers with a gui driver (otherwise the card would be useless) AND (if they wish, but it is probably a standard the facto) a specific OpenGL(and I guess directX also at this point) driver. The high level opengl api will basically map every function call with his low level opengl counterpart (like you say in 4). Am I right? –  Kami Dec 12 '13 at 20:12
@Max: Correct except that the driver also contians the high level OpenGL API implementation. The "opengl32.dll" you link against in Windows just offers some kind of "slots" which the actual GPU driver (the so called ICD) fills. In Linux, FreeBSD and Solaris (to this day) the libGL.so which provides the OpenGL API is part of the driver package. However Linux is due for a new OpenGL ABI (not to confuse with API) which provides a similar facade libGL.so into which the driver hooks its stuff. –  datenwolf Dec 12 '13 at 20:53

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