-\chapterauthor{Author Name1}{Affiliation text1}
-\chapterauthor{Author Name2}{Affiliation text2}
+\chapterauthor{Raphaël Couturier}{Femto-ST Institute, University of Franche-Comte}
-
-\chapter{Introduction to CUDA}
+\chapter{Introduction to Cuda}
\label{chapter2}
-\section{Introduction}\label{intro}
-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 (for example: \cite{Sanders:2010:CEI}).
+\section{Introduction}
+\label{ch2:intro}
+
+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 (for
+example: \cite{ch2:Sanders:2010:CEI}).
\section{First example}
+\label{ch2:1ex}
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. The listing of this code is in Listing~\ref{ch2:lst:ex1}
+Cuda. The goal of this example is to perform the sum of two arrays and
+put the result into a third array. A Cuda program consists in a C code
+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
-the GPU. A call to \texttt{cudaMalloc} allows to allocate memory on the GPU. The
-first parameter of this function is a pointer on a memory on the device
-(i.e. the GPU). In this example, \texttt{d\_} is added on each variable allocated
-on the GPU meaning this variable is on the GPU. The second parameter represents
-the size of the allocated variables, this size is in bits.
+the GPU. A call to \texttt{cudaMalloc}\index{Cuda~functions!cudaMalloc} allows
+to allocate memory on the GPU. The first parameter of this function is a pointer
+on a memory on the device (i.e. the GPU). In this example, \texttt{d\_} is added
+on each variable allocated on the GPU, meaning this variable is on the GPU. The
+second parameter represents the size of the allocated variables, this size is in
+bits.
In this example, we want to compare the execution time of the additions of two
arrays in CPU and GPU. So for both these operations, a timer is created to
-measure the time. CUDA proposes to manipulate timers quick easily. The first
-step is to create the timer, then to start it and at the end to stop it. For
-each of these operations a dedicated functions is used.
+measure the time. Cuda proposes to manipulate timers quite easily. The first
+step is to create the timer\index{Cuda~functions!timer}, then to start it and at
+the end to stop it. For each of these operations a dedicated functions is used.
-In order to compute the same sum with a GPU, the first step consits in
-transferring the data from the CPU (considered as the host with CUDA) to the GPU
-(considered as the device with CUDA). A call to \texttt{cudaMalloc} allows to
+In order to compute the same sum with a GPU, the first step consists in
+transferring the data from the CPU (considered as the host with Cuda) to the GPU
+(considered as the device with Cuda). A call to \texttt{cudaMemcpy} allows to
copy the content of an array allocated in the host to the device when the fourth
-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).
+parameter is set
+to \texttt{cudaMemcpyHostToDevice}\index{Cuda~functions!cudaMemcpy}. 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).
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
+possible to perform the addition of all elements of the two 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.
+two arrays. With Cuda, a kernel starts with the
+keyword \texttt{\_\_global\_\_} \index{Cuda~keywords!\_\_shared\_\_} which
+indicates that this kernel can be called from the C code. The first instruction
+in this kernel is used to compute the variable \texttt{tid} which represents the
+thread index. This thread index\index{thread index} is computed according to
+the values of the block index
+(called \texttt{blockIdx} \index{Cuda~keywords!blockIdx} in Cuda) and of the
+thread index (called \texttt{blockIdx}\index{Cuda~keywords!threadIdx} in
+Cuda). Blocks of threads and thread indexes 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}
+\section{Second example: using CUBLAS}
+\label{ch2:2ex}
+
+The Basic Linear Algebra Subprograms (BLAS) allows programmers to use efficient
+routines that are often required. Those routines are heavily used in many
+scientific applications and are very optimized for vector operations,
+matrix-vector operations and matrix-matrix
+operations~\cite{ch2:journals/ijhpca/Dongarra02}. Some of those operations seem
+to be easy to implement with Cuda. Nevertheless, as soon as a reduction is
+needed, implementing an efficient reduction routines with Cuda is far from being
+simple. Roughly speaking, a reduction operation\index{reduction~operation} is an
+operation which combines all the elements of an array and extract a number
+computed with all the elements. For example, a sum, a maximum or a dot product
+are reduction operations.
+
+In this second example, we consider that we have two vectors $A$ and $B$. First
+of all, we want to compute the sum of both vectors in a vector $C$. Then we want
+to compute the scalar product between $1/C$ and $1/A$. This is just an example
+which has no direct interest except to show how to program it with Cuda.
+
+Listing~\ref{ch2:lst:ex2} shows this example with Cuda. The first kernel for the
+addition of two arrays is exactly the same as the one described in the
+previous example.
+
+The kernel to compute the inverse of the elements of an array is very
+simple. For each thread index, the inverse of the array replaces the initial
+array.
+
+In the main function, the beginning is very similar to the one in the previous
+example. First, the number of elements is asked to the user. Then a call
+to \texttt{cublasCreate} allows to initialize the cublas library. It creates an
+handle. Then all the arrays are allocated in the host and the device, as in the
+previous example. Both arrays $A$ and $B$ are initialized. Then the CPU
+computation is performed and the time for this CPU computation is measured. In
+order to compute the same result on the GPU, first of all, data from the CPU
+need to be copied into the memory of the GPU. For that, it is possible to use
+cublas function \texttt{cublasSetVector}. This function several arguments. More
+precisely, the first argument represents the number of elements to transfer, the
+second arguments is the size of each elements, the third element represents the
+source of the array to transfer (in the GPU), the fourth is an offset between
+each element of the source (usually this value is set to 1), the fifth is the
+destination (in the GPU) and the last is an offset between each element of the
+destination. Then we call the kernel \texttt{addition} which computes the sum of
+all elements of arrays $A$ and $B$. The \texttt{inverse} kernel is called twice,
+once to inverse elements of array $C$ and once for $A$. Finally, we call the
+function \texttt{cublasDdot} which computes the dot product of two vectors. To
+use this routine, we must specify the handle initialized by Cuda, the number of
+elements to consider, then each vector is followed by the offset between every
+element. After the GPU computation, it is possible to check that both
+computation produce the same result.
+
+\lstinputlisting[label=ch2:lst:ex2,caption=A simple example with cublas]{Chapters/chapter2/ex2.cu}
+
+\section{Third example: matrix-matrix multiplication}
+\label{ch2:3ex}
+
+
+
+Matrix-matrix multiplication is an operation which is quite easy to parallelize
+with a GPU. If we consider that a matrix is represented using a two dimensional
+array, A[i][j] represents the the element of the $i^{th}$ row and of the
+$j^{th}$ column. In many case, it is easier to manipulate 1D array instead of 2D
+array. With Cuda, even if it is possible to manipulate 2D arrays, in the
+following we present an example based on 1D array. For sake of simplicity we
+consider we have a squared matrix of size \texttt{size}. So with a 1D
+array, \texttt{A[i*size+j]} allows us to access to the element of the $i^{th}$
+row and of the $j^{th}$ column.
+
+With a sequential programming, the matrix multiplication is performed using
+three loops. Supposing that $A$, $B$ represent two square matrices and that the
+result of the multiplication of $A \times B$ is $C$. The
+element \texttt{C[i*size+j]} is computed as follows:
+\begin{equation}
+C[i*size+j]=\sum_{k=0}^{size-1} A[i*size+k]*B[k*size+j];
+\end{equation}
+
+In Listing~\ref{ch2:lst:ex3}, in the CPU computation, this part of code is
+performed using 3 loops, one for $i$, one for $j$ and one for $k$. In order to
+perform the same computation on a GPU, a naive solution consists in considering
+that the matrix $C$ is split into 2 dimensional blocks. The size of each block
+must be chosen such as the number of threads per block is inferior to $1,024$.
+
+
+In Listing~\ref{ch2:lst:ex3}, we consider that a block contains 16 threads in
+each dimension, the variable \texttt{width} is used for that. The
+variable \texttt{nbTh} represents the number of threads per block. So to be able
+to compute the matrix-matrix product on a GPU, each block of threads is assigned
+to compute the result of the product for the elements of this block. The main
+part of the code is quite similar to the previous code. Arrays are allocated in
+the CPU and the GPU. Matrices $A$ and $B$ are randomly initialized. Then
+arrays are transfered inside the GPU memory with call to \texttt{cudaMemcpy}.
+So the first step for each thread of a block is to compute the corresponding row
+and column. With a 2 dimensional decomposition, \texttt{int i=
+blockIdx.y*blockDim.y+ threadIdx.y;} allows us to compute the corresponding line
+and \texttt{int j= blockIdx.x*blockDim.x+ threadIdx.x;} the corresponding
+column. Then each thread has to compute the sum of the product of the line of
+$A$ per the column of $B$. In order to use a register, the
+kernel \texttt{matmul} uses a variable called \texttt{sum} to compute the
+sum. Then the result is set into the matrix at the right place. The computation
+of CPU matrix-matrix multiplication is performed as described previously. A
+timer measures the time. In order to use 2 dimensional blocks, \texttt{dim3
+dimGrid(size/width,size/width);} allows us to create \texttt{size/width} blocks
+in each dimension. Likewise, \texttt{dim3 dimBlock(width,width);} is used to
+create \texttt{width} thread in each dimension. After that, the kernel for the
+matrix multiplication is called. At the end of the listing, the matrix $C$
+computed by the GPU is transfered back in the CPU and we check if both matrices
+C computed by the CPU and the GPU are identical with a precision of $10^{-4}$.
+
+
+On C2070M Tesla card, this code take $37.68$ms to perform the multiplication. On
+a Intel Xeon E31245 at $3.30$GHz, it takes $2465$ms without any parallelization
+(using only one core). Consequently the speed up between the CPU and GPU version
+is about $65$ which is very good regarding the difficulty of parallelizing this
+code.
+
+\lstinputlisting[label=ch2:lst:ex3,caption=simple Matrix-matrix multiplication with cuda]{Chapters/chapter2/ex3.cu}
+
+\section{Conclusion}
+In this chapter 3 simple Cuda examples have been presented. Those examples are
+quite simple and they cannot present all the possibilities of the Cuda
+programming. Interested readers are invited to consult Cuda programming
+introduction books if some issues regarding the Cuda programming is not clear.
+
\putbib[Chapters/chapter2/biblio]