OpenCL, Vulkan, Sycl

How does OpenCL relates to vulkan ? I understand that OpenCL is higher level and abstracts the devices, but does ( or could ) it uses Vulkan internally ?

They're not related to each other at all.

Well, they do technically use the same intermediate shader language, but Vulkan forbids the Kernel execution model, and OpenCL forbids the Shader execution model. Because of that, you can't just take a shader meant for OpenCL and stick it in Vulkan, or vice-versa.

Vulkan is advertised as both a compute and graphics api, however I found very little resources for the compute part - why is that ?

Because the Khronos Group likes misleading marketing blurbs.

Vulkan is no more of a compute API than OpenGL. It may have Compute Shaders, but they're limited in functionality. The kind of stuff you can do in an OpenCL compute operation is just not available through OpenGL/Vulkan CS's.

Vulkan CS's, like OpenGL's CS's, are intended to be used for one thing: to support graphics operations. To do frustum culling, build indirect graphics commands, manipulate particle systems, and other such things. CS's operate at the same numerical precision as graphical shaders.

Vulkan has a performance advantages over OpenGL. Is the same true for Vulkan vs OpenCl?

The performance of a compute system is based primarily on the quality of its implementation. It's not OpenCL that's slow; it's your OpenCL implementation that's slower than it possibly could be.

Vulkan CS's are no different in this regard. The performance will be based on the maturity of the drivers.

Also, there's the fact that, again, there's a lot of stuff you can do in an OpenCL compute operation that you cannot do in a Vulkan CS.

Does SYCL uses OpenCL internally or could it use vulkan ?

From the Khronos Group:

SYCL (pronounced ‘sickle’) is a royalty-free, cross-platform abstraction layer that builds on the underlying concepts, portability and efficiency of OpenCL...

So yes, it's built on top of OpenCL.


How does OpenCL relates to vulkan ?

They both can pipeline a separable work from host to gpu and gpu to host using queues to reduce communication overhead using multiple threads. Directx-opengl cannot?

  • OpenCL: Initial release August 28, 2009. Broader hardware support. Pointers allowed but only to be used in device. You can use local memory shared between threads. Much easier to start a hello world. Has api overhead for commands unless they are device-side queued. You can choose implicit multi-device synchronization or explicit management. Bugs are mostly fixed for 1.2 but I don't know about version 2.0.

  • Vulkan: Initial release 16 February 2016(but progress from 2014). Narrower hardware support. Can SPIR-V handle pointers? Maybe not? No local-memory option? Hard to start hello world. Less api overhead. Can you choose implicit multi-device management? Still buggy for Dota-2 game and some other games. Using both graphics and compute pipeline at the same time can hide even more latency.

if opencl had vulkan in it, then it has been hidden from public for 7-9 years. If they could add it, why didn't they do it for opengl?(maybe because of pressure by physx/cuda?)

Vulkan is advertised as both a compute and graphics api, however I found very little resources for the compute part - why is that ?

It needs more time, just like opencl.

You can check info aboout compute shaders here:

https://www.khronos.org/registry/vulkan/specs/1.0/xhtml/vkspec.html#fundamentals-floatingpoint

Here is an example of particle system managed by compute shaders:

https://github.com/SaschaWillems/Vulkan/tree/master/computeparticles

below that, there are raytracers and image processing examples too.

Vulkan has a performance advantages over OpenGL. Is the same true for Vulkan vs OpenCl?

  • Vulkan doesn't need to synchronize for another API. Its about command buffers synchronization between commandqueues.
  • OpenCL needs to synchronize with opengl or directx (or vulkan?) before using a shared buffer(cl-gl or dx-cl interop buffers). This has an overhead and you need to hide it using buffer swapping and pipelining. If no shared buffer exists, it can run concurrently on modern hardware with opengl or directx.

OpenCL is sadly notorious to being slower than CUDA

It was, but now its mature and challenges cuda, especially with much wider hardware support from all gaming gpus to fpgas using version 2.1, such as in future Intel can put an fpga into a Core i3 and enable it for (soft-x86 core ip) many-core cpu model closing the gap between a gpu performance and a cpu to upgrade its cpu-physx gaming experience or simply let an opencl physics implementation shape it and use at least %90 die-area instead of a soft-core's %10-%20 effectively used area.

With same price, AMD gpus can compute faster on opencl and with same compute power Intel igpus draw less power. (edit: except when algorithms are sensitive to cache performance where Nvidia has upperhand)

Besides, I wrote a SGEMM opencl kernel and run on a HD7870 at 1.1 Tflops and checked internet then saw a SGEMM henchmark on a GTX680 for same performance using a popular title on CUDA!(price ratio of gtx680/hd7870 was 2). (edit: Nvidia's cc3.0 doesn't use L1 cache when reading global arrays and my kernel was purely local/shared memory + some registers "tiled")

Does SYCL uses OpenCL internally or could it use vulkan ? Or does it use neither and instead relies on low level, vendor specific apis to be implemented ?

Here,

https://www.khronos.org/assets/uploads/developers/library/2015-iwocl/Khronos-SYCL-May15.pdf

says

Provides methods for dealing with targets that do not have OpenCL(yet!)

A fallback CPU implementation is debuggable!

so it can fall back to a pure threaded version(similar to java's aparapi).

Can access OpenCL objects from SYCL objects Can construct SYCL objects from OpenCL object

Interop with OpenGL remains in SYCL - Uses the same structures/types

it uses opencl(maybe not directly, but with an upgraded driver communication?), it develops parallel to opencl but can fallback to threads.

from the smallest OpenCL 1.2 embedded device to the most advanced OpenCL 2.2 accelerators