GPU Computing (CUDA C)

Tutorial
Title:	Introduction to GPU Computing
Provider:	HPC.NRW
Contact:	tutorials@hpc.nrw
Type:	Multi-part video
Topic Area:	GPU computing
License:	CC-BY-SA
Syllabus
1. Introduction
2. Several Ways to SAXPY: CUDA C/C++
3. Several Ways to SAXPY: OpenMP
4. Several Ways to SAXPY: Julia
5. Several Ways to SAXPY: NUMBA

This video discusses the SAXPY via NVIDIA CUDA C/C++.

1. Which features does CUDA add to C/C++?

2. What is a kernel?

3. How do you flag a function to be a kernel?

4. Let's say you coded your kernel function called "MyKernel". How do you run it?

5. Inside your kernel function, how do you distribute your data over the threads?

1. For which kind of program can we expect improvements with GPUs?

2. What does GPU stands for?

3. Why do we expect an overhead in the GPU timings?

	MyKernel()
	CUDA.run(NoBlocks, NoThreads, MyKernel())
	<<<NoBlocks, NoThreads>>>MyKernel()
	__global(NoBlocks, NoThreads)__ MyKernel()

	You don't have to, CUDA does that automatically for you.
	Each thread has has an index attached to it, which is addressed via threadIdx.x
	If you use array-element-wise operations (like y.=a.*x.+b ), this is managed by the NVIDIA preprocessor.
	You flag a line to be parallelized via keywords, e.g.: __device__ y=a*x+b

	The data must be copied to an extra device first and has to be transferred back later
	A GPU core is "weaker" than a CPU core
	For "small" problems like the SAXPY, the whole power of a GPU is rarely used
	All of the above

Contents

	It's a flag you can set to automatically parallelize any function.
	It's the part of your code that is run on the GPU.
	It's a new CUDA function that activates the GPU.

	serial programs
	parallel programs

	graphics processing unit
	grand powerful unit