X-Git-Url: https://bilbo.iut-bm.univ-fcomte.fr/and/gitweb/book_gpu.git/blobdiff_plain/f69f75dd5354fe34ad3b1360af061a8f1aebb9aa..f947c46397ce66a0f014e5e11653f0d34b3b7d50:/BookGPU/Chapters/chapter2/ch2.tex?ds=sidebyside diff --git a/BookGPU/Chapters/chapter2/ch2.tex b/BookGPU/Chapters/chapter2/ch2.tex index b06e9be..bff6d44 100755 --- a/BookGPU/Chapters/chapter2/ch2.tex +++ b/BookGPU/Chapters/chapter2/ch2.tex @@ -9,7 +9,7 @@ In this chapter we give some simple examples on CUDA programming. The goal is not to provide an exhaustive presentation of all the functionalities of CUDA but rather giving some basic elements. Of course, readers that do not know CUDA are -invited to read other books that are specialized on CUDA programming. +invited to read other books that are specialized on CUDA programming (for example: \cite{Sanders:2010:CEI}). \section{First example} @@ -17,7 +17,7 @@ invited to read other books that are specialized on CUDA programming. This first example is intented to show how to build a very simple example with CUDA. The goal of this example is to performed the sum of two arrays and putting the result into a third array. A cuda program consists in a C code -which calls CUDA kernels that are executed on a GPU. +which calls CUDA kernels that are executed on a GPU. The listing of this code is in Listing~\ref{ch2:lst:ex1} As GPUs have their own memory, the first step consists in allocating memory on @@ -41,5 +41,29 @@ parameter is set to \texttt{cudaMemcpyHostToDevice}. The first parameter of the function is the destination array, the second is the source array and the third is the number of elements to copy (exprimed in bytes). -\putbib[biblio] +Now the GPU contains the data needed to perform the addition. In sequential such +addition is achieved out with a loop on all the elements. With a GPU, it is +possible to perform the addition of all elements of the arrays in parallel (if +the number of blocks and threads per blocks is sufficient). In +Listing\ref{ch2:lst:ex1} at the beginning, a simple kernel, +called \texttt{addition} is defined to compute in parallel the summation of the +two arrays. With CUDA, a kernel starts with the keyword \texttt{\_\_global\_\_} +which indicates that this kernel can be call from the C code. The first +instruction in this kernel is used to computed the \texttt{tid} which +representes the thread index. This thread index is computed according to the +values of the block index (it is a variable of CUDA +called \texttt{blockIdx}\index{CUDA~keywords!blockIdx}). Blocks of threads can +be decomposed into 1 dimension, 2 dimensions or 3 dimensions. According to the +dimension of data manipulated, the appropriate dimension can be useful. In our +example, only one dimension is used. Then using notation \texttt{.x} we can +access to the first dimension (\texttt{.y} and \texttt{.z} allow respectively to +access to the second and third dimension). The +variable \texttt{blockDim}\index{CUDA~keywords!blockDim} gives the size of each +block. + + + +\lstinputlisting[label=ch2:lst:ex1,caption=A simple example]{Chapters/chapter2/ex1.cu} + +\putbib[Chapters/chapter2/biblio]