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25 \title{Two parallel implementations of Ehrlich-Aberth algorithm for root-finding of polynomials on multiple GPUs with OpenMP and MPI}
27 \author{\IEEEauthorblockN{Kahina Ghidouche, Abderrahmane Sider }
28 \IEEEauthorblockA{Laboratoire LIMED\\
29 Faculté des sciences exactes\\
30 Université de Bejaia, 06000, Algeria\\
31 Email: \{kahina.ghidouche,ar.sider\}@univ-bejaia.dz}
33 \IEEEauthorblockN{Lilia Ziane Khodja, Raphaël Couturier}
34 \IEEEauthorblockA{FEMTO-ST Institute\\
35 University of Bourgogne Franche-Comte, France\\
36 Email: zianekhodja.lilia@gmail.com\\ raphael.couturier@univ-fcomte.fr}}
42 Finding roots of polynomials is a very important part of solving
43 real-life problems but it is not so easy for polynomials of high
44 degrees. In this paper, we present two different parallel algorithms
45 of the Ehrlich-Aberth method to find roots of sparse and fully defined
46 polynomials of high degrees. Both algorithms are based on CUDA
47 technology to be implemented on multi-GPU computing platforms but each
48 using different parallel paradigms: OpenMP or MPI. The experiments
49 show a quasi-linear speedup by using up-to 4 GPU devices compared to 1
50 GPU to find roots of polynomials of degree up-to 1.4
51 million. Moreover, other experiments show it is possible to find roots
52 of polynomials of degree up-to 5 millions.
56 root finding method, Ehrlich-Aberth method, GPU, MPI, OpenMP
59 \IEEEpeerreviewmaketitle
62 %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
63 %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
64 \section{Introduction}
67 Finding roots of polynomials of very high degrees arises in many complex problems of various domains such as algebra, biology or physics. A polynomial $p(x)$ in $\mathbb{C}$ in one variable $x$ is an algebraic expression in $x$ of the form:
69 p(x) = \displaystyle\sum^n_{i=0}{\alpha_ix^i},\alpha_n\neq 0,
71 where $\{\alpha_i\}_{0\leq i\leq n}$ are complex coefficients and $n$ is a high integer number. If $\alpha_n\neq0$ then $n$ is called the degree of the polynomial. The root-finding problem consists in finding the $n$ different values of the unknown variable $x$ for which $p(x)=0$. Such values are called roots of $p(x)$. Let $\{z_i\}_{1\leq i\leq n}$ be the roots of polynomial $p(x)$, then $p(x)$ can be written as :
73 p(x)=\alpha_n\displaystyle\prod_{i=1}^n(x-z_i), \alpha_n\neq 0.
76 Most of the numerical methods that deal with the polynomial root-finding problem are simultaneous methods, \textit{i.e.} the iterative methods to find simultaneous approximations of the $n$ polynomial roots. These methods start from the initial approximations of all $n$ polynomial roots and give a sequence of approximations that converge to the roots of the polynomial. Two examples of well-known simultaneous methods for root-finding problem of polynomials are Durand-Kerner method~\cite{Durand60,Kerner66} and Ehrlich-Aberth method~\cite{Ehrlich67,Aberth73}.
79 The convergence time of simultaneous methods drastically increases with the increasing of the polynomial's degree. The great challenge with simultaneous methods is to parallelize them and to improve their convergence. Many authors have proposed parallel simultaneous methods~\cite{Freeman89,Loizou83,Freemanall90,bini96,cs01:nj,Couturier02}, using several paradigms of parallelization (synchronous or asynchronous computations, mechanism of shared or distributed memory, etc). However, they have solved only polynomials not exceeding degrees of 20,000.
81 %The main problem of the simultaneous methods is that the necessary
82 %time needed for the convergence increases with the increasing of the
83 %polynomial's degree. Many authors have treated the problem of
84 %implementing simultaneous methods in
85 %parallel. Freeman~\cite{Freeman89} implemented and compared
86 %Durand-Kerner method, Ehrlich-Aberth method and another method of the
87 %fourth order of convergence proposed by Farmer and
88 %Loizou~\cite{Loizou83} on a 8-processor linear chain, for polynomials
89 %of degree up-to 8. The method of Farmer and Loizou~\cite{Loizou83}
90 %often diverges, but the first two methods (Durand-Kerner and
91 %Ehrlich-Aberth methods) have a speed-up equals to 5.5. Later, Freeman
92 %and Bane~\cite{Freemanall90} considered asynchronous algorithms in
93 %which each processor continues to update its approximations even
94 %though the latest values of other approximations $z^{k}_{i}$ have not
95 %been received from the other processors, in contrast with synchronous
96 %algorithms where it would wait those values before making a new
97 %iteration. Couturier and al.~\cite{cs01:nj} proposed two methods
98 %of parallelization for a shared memory architecture with OpenMP and
99 %for a distributed memory one with MPI. They are able to compute the
100 %roots of sparse polynomials of degree 10,000. The authors showed an interesting
101 %speedup that is 20 times as fast as the sequential implementation.
103 But the recent advent of the Compute Unified Device Architecture (CUDA)~\cite{CUDA15}, a parallel computing platform and a programming model invented by NVIDIA had revived parallel programming interest for this problem. Indeed, the computing power of GPUs (Graphics Processing Units) has exceeded that of traditional processors CPUs, which makes it very appealing to the research community to investigate new parallel implementations for a whole set of scientific problems in the reasonable hope to solve bigger instances of well known computationally demanding issues such as the one beforehand. However, CUDA adopts a totally new computing architecture to use the hardware resources provided by the GPU in order to offer a stronger computing ability to the massive data computing. Ghidouche et al.~\cite{Kahinall14} proposed an implementation of the Durand-Kerner method on a single GPU. Their main results showed that a parallel CUDA implementation is about 10 times faster than the sequential implementation on a single CPU for sparse polynomials of degree 48,000.
105 In this paper we propose the parallelization of Ehrlich-Aberth (EA) method which has a cubic convergence rate which is much better than the quadratic rate of the Durand-Kerner method which has already been investigated in \cite{Kahinall14}. In the other hand, EA is suitable to be implemented in parallel computers according to the data-parallel paradigm. In this model, computing elements carry computations on the data they are assigned and communicate with other computing elements in order to get fresh data or to synchronise. Classically, two parallel programming paradigms OpenMP and MPI are used to code such solutions. But in our case, computing elements are CUDA multi-GPU platforms. This architectural setting poses new programming challenges but offers also new opportunities to efficiently solve huge problems, otherwise considered intractable until recently. To the best of our knowledge, our CUDA-MPI and CUDA-OpenMP codes are the first implementations of EA method with multiple GPUs for finding roots of polynomials. Our major contributions include:
108 \item The parallel implementation of EA algorithm on a multi-GPU platform with a shared memory using OpenMP API. It is based on threads created from the same system process, such that each thread is attached to one GPU. In this case the communications between GPUs are done by OpenMP threads through shared memory.
109 \item The parallel implementation of EA algorithm on a
110 multi-GPU platform with a distributed memory using MPI API, such
111 that each GPU is attached and managed by a MPI process. The GPUs
112 exchange their data by message-passing communications. This approach is more used on clusters to solve very complex problems that are too large for traditional supercomputers, which are very expensive to build and run.
114 Our method is efficient to compute the roots of sparse and full
115 polynomials of degree up to 5 millions.
119 The paper is organized as follows. In Section~\ref{sec2} we present three different parallel programming models OpenMP, MPI and CUDA. In Section~\ref{sec3} we present the implementation of the Ehrlich-Aberth algorithm on a single GPU. In Section~\ref{sec4} we present the parallel implementations of the Ehrlich-Aberth algorithm on multiple GPUs using the OpenMP and MPI approaches. In section~\ref{sec5} we present our experiments and discuss them. Finally, Section~\ref{sec6} concludes this paper and gives some hints for future research directions in this topic.
122 %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
123 %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
125 \section{Parallel programming models}
127 Our objective consists in implementing a root-finding algorithm of polynomials on multiple GPUs. To this end, it is primordial to know how to manage CUDA contexts of different GPUs. A direct method for controlling the various GPUs is to use as many threads or processes as GPU devices. We investigate two parallel paradigms: OpenMP and MPI. In this case, the GPU indices are defined according to the identifiers of the OpenMP threads or the ranks of the MPI processes. In this section we present the parallel programming models: OpenMP, MPI and CUDA.
130 OpenMP (Open Multi-processing) is an application programming interface for parallel programming~\cite{openmp13}. It is a portable approach based on the multithreading designed for shared memory computers, where a master thread forks a number of slave threads which execute blocks of code in parallel. An OpenMP program alternates sequential regions and parallel regions of code, where the sequential regions are executed by the master thread and the parallel ones may be executed by multiple threads. During the execution of an OpenMP program the threads communicate their data (read and modified) in the shared memory. One advantage of OpenMP is the global view of the memory address space of an application. This allows relatively a fast development of parallel applications with easier maintenance. However, it is often difficult to get high rates of performances in large scale-applications.
133 MPI (Message Passing Interface) is a portable message passing style of the parallel programming designed especially for the distributed memory architectures~\cite{Peter96}. In most MPI implementations, a computation contains a fixed set of processes created at the initialization of the program in such way one process is created per processor. The processes synchronize their computations and communicate by sending/receiving messages to/from other processes. In this case, the data are explicitly exchanged by message passing while the data exchanges are implicit in a multithread programming model like OpenMP and Pthreads. However in the MPI programming model, the processes may either execute different programs referred to as multiple program multiple data (MPMD) or every process executes the same program (SPMD). The MPI approach is one of most used HPC programming model to solve large scale and complex applications.
136 CUDA (Compute Unified Device Architecture) is a parallel computing architecture developed by NVIDIA~\cite{CUDA15} for GPUs. It provides a high level GPGPU-based programming model to program GPUs for general purpose computations. The GPU is viewed as an accelerator such that data-parallel operations of a CUDA program running on a CPU are off-loaded onto GPU and executed by this later. The data-parallel operations executed by GPUs are called kernels. The same kernel is executed in parallel by a large number of threads organized in grids of thread blocks, such that each GPU multiprocessor executes one or more thread blocks in SIMD fashion (Single Instruction, Multiple Data) and in turn each core of the multiprocessor executes one or more threads within a block. Threads within a block can cooperate by sharing data through a fast shared memory and coordinate their execution through synchronization points. In contrast, within a grid of thread blocks, there is no synchronization at all between blocks. The GPU only works on data filled in the global memory and the final results of the kernel executions must be transferred out of the GPU. In the GPU, the global memory has lower bandwidth than the shared memory associated to each multiprocessor. Thus in the CUDA programming, it is necessary to design carefully the arrangement of the thread blocks in order to ensure low latency and a proper usage of the shared memory, and the global memory accesses should be minimized.
139 %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
140 %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
142 \section{The Ehrlich-Aberth algorithm on a GPU}
145 \subsection{The Ehrlich-Aberth method}
147 The Ehrlich-Aberth method is a simultaneous method~\cite{Aberth73} using the following iteration
150 z^{k+1}_{i}=z_{i}^{k}-\frac{\frac{p(z_{i}^{k})}{p'(z_{i}^{k})}}
151 {1-\frac{p(z_{i}^{k})}{p'(z_{i}^{k})}\sum_{j=1,j\neq i}^{j=n}{\frac{1}{(z_{i}^{k}-z_{j}^{k})}}}, i=1,\ldots,n
154 This method contains 4 steps. The first step consists in the
155 initializing the polynomial. The second step initializes the solution
156 vector $Z$ using the Guggenheimer method~\cite{Gugg86} to ensure that
157 initial roots are all distinct from each other. In step 3, the
158 iterative function based on the Newton's method~\cite{newt70} and
159 Weiestrass operator~\cite{Weierstrass03} is applied. In our case, the
160 Ehrlich-Aberth is applied as in~(\ref{Eq:EA1}). Iterations of the
161 Ehrlich-Aberth method will converge to the roots of the considered
162 polynomial. In order to stop the iterative function, a stop condition
163 is applied, this is the 4th step. This condition checks that all the
164 root modules are lower than a fixed value $\epsilon$.
167 \label{eq:Aberth-Conv-Cond}
168 \forall i\in[1,n],~\vert\frac{z_i^k-z_i^{k-1}}{z_i^k}\vert<\epsilon
171 \subsection{Improving Ehrlich-Aberth method}
172 With high degree polynomials, the Ehrlich-Aberth method suffers from floating point overflows due to the mantissa of floating points representations. This induces errors in the computation of $p(z)$ when $z$ is large.
174 In order to solve this problem, we propose to modify the iterative
175 function by using the logarithm and the exponential of a complex and
176 we propose a new version of the Ehrlich-Aberth method. This method
177 allows us to exceed the computation of the polynomials of degree
178 100,000 and to reach a degree up to more than 1,000,000. The reformulation of the iteration~(\ref{Eq:EA1}) of the Ehrlich-Aberth method with exponential and logarithm operators is defined as follows, for $i=1,\dots,n$:
182 z^{k+1}_i = z_i^k - \exp(\ln(p(z_i^k)) - \ln(p'(z^k_i)) - \ln(1-Q(z^k_i))),
189 Q(z^k_i) = \exp(\ln(p(z^k_i)) - \ln(p'(z^k_i)) + \ln(\sum_{i\neq j}^n\frac{1}{z^k_i-z^k_j})).
192 Using the logarithm and the exponential operators, we can replace any
193 multiplications and divisions with additions and
194 subtractions. Consequently, computations manipulate lower values in
195 absolute values~\cite{Karimall98}. In practice, the exponential and
196 logarithm mode is used when a root is outisde the circle unit represented by the radius $R$ evaluated in C language with:
199 R = exp(log(DBL\_MAX)/(2*n) );
201 where \verb=DBL_MAX= stands for the maximum representable
202 \verb=double= value and $n$ is the degree of the polynimal.
205 \subsection{The Ehrlich-Aberth parallel implementation on CUDA}
206 The code is organized as kernels which are parts of code that are run
207 on GPU devices. Algorithm~\ref{alg1-cuda} describes the CUDA
208 implementation of the Ehrlich-Aberth on a GPU. This algorithms starts
209 by initializing the polynomial and its derivative (line 1). The
210 initialization of the roots is performed (line 2). Data are transferred
211 from the CPU to the GPU (after allocation of the required memory on
212 the GPU) (line 3). Then at each iteration, if the error is greater
213 than a threshold, the following operations are performed. The previous
214 roots are saved using a kernel (line 5). Then the new roots with the
215 new iterations are computed using the EA method with a Gauss-Seidel
216 iteration mode in order to use the lastest updated roots (line
217 6). This improves the convergence. This kernel is, in practice, very
218 long since it performs all the operations with complex numbers with
219 the normal mode of the EA method but also with the
220 logarithm-exponential one. Then the error is computed with a final
221 kernel (line 7). Finally when the EA method has converged, the roots
222 are transferred from the GPU to the CPU.
224 \begin{algorithm}[htpb]
228 \caption{Finding roots of polynomials with the Ehrlich-Aberth method on a GPU}
229 \KwIn{ $\epsilon$ (tolerance threshold)}
230 \KwOut{$Z$ (solution vector of roots)}
231 Initialize the polynomial $P$ and its derivative $P'$\;
232 Set the initial values of vector $Z$\;
233 Copy $P$, $P'$ and $Z$ from CPU to GPU\;
234 \While{$error > \epsilon$}{
235 $Z^{prev}$ = KernelSave($Z$)\;
236 $Z$ = KernelUpdate($P,P',Z$)\;
237 $error$ = KernelComputeError($Z,Z^{prev}$)\;
239 Copy $Z$ from GPU to CPU\;
243 The development of this code is a rather long task, as the development
244 of corresponding kernels with CUDA is longer than on a CPU host. This
245 comes in particular from the fact that it is very difficult to debug
246 CUDA running threads like threads on a CPU host. In the following
247 section the GPU parallel implementation of Ehrlich-Aberth method with
248 OpenMP and MPI is presented.
254 \section{The Ehrlich-Aberth algorithm on multiple GPUs}
256 \subsection{An OpenMP-CUDA approach}
257 Our OpenMP-CUDA implementation of EA algorithm is based on the hybrid
258 OpenMP and CUDA programming model. This algorithm is presented in
259 Algorithm~\ref{alg2-cuda-openmp}. All the data are shared with OpenMP
260 among all the OpenMP threads. The shared data are the solution vector
261 $Z$, the polynomial to solve $P$, its derivative $P'$, and the error
262 vector $error$. The number of OpenMP threads is equal to the number of
263 GPUs, each OpenMP thread binds to one GPU, and it controls a part of
264 the shared memory. More precisely each OpenMP thread will be
265 responsible to update its owns part of the vector $Z$. This part is
266 called $Z_{loc}$ in the following. Then all GPUs will have a grid of
267 computation organized according to the device performance and the size
268 of data on which it runs the computation kernels.
270 To compute one iteration of the EA method each GPU performs the
271 followings steps. First roots are shared with OpenMP and the
272 computation of the local size for each GPU is performed (line 4). Each
273 thread starts by copying all the previous roots inside its GPU (line
274 5). At each iteration, the following operations are performed. First
275 the vector $Z$ is transferred from the CPU to the GPU (line 7). Each
276 GPU copies the previous roots (line 8) and it computes an iteration of
277 the EA method on its own roots (line 9). For that all the other roots
278 are used. The local error is computed on the new roots (line 10) and
279 the max of the local errors is computed on all OpenMP threads (lien 11). At
280 the end of an iteration, the updated roots are copied from the GPU to
281 the CPU (line 12) by directly updating its own roots in the shared
282 memory arrays containing all the roots.
286 \begin{algorithm}[htpb]
287 \label{alg2-cuda-openmp}
290 \caption{Finding roots of polynomials with the Ehrlich-Aberth method on multiple GPUs using OpenMP}
291 \KwIn{ $\epsilon$ (tolerance threshold)}
292 \KwOut{$Z$ (solution vector of roots)}
293 Initialize the polynomial $P$ and its derivative $P'$\;
294 Set the initial values of vector $Z$\;
295 Start of a parallel part with OpenMP ($Z$, $error$, $P$, $P'$ are shared variables)\;
296 Determine the local part of the OpenMP thread\;
297 Copy $P$, $P'$ from CPU to GPU\;
298 \While{$error > \epsilon$}{
299 Copy $Z$ from CPU to GPU\;
300 $Z^{prev}_{loc}$ = KernelSave($Z_{loc}$)\;
301 $Z_{loc}$ = KernelUpdate($P,P',Z$)\;
302 $error_{loc}$ = KernelComputeError($Z_{loc},Z^{prev}_{loc}$)\;
303 $error = max(error_{loc})$\;
304 Copy $Z_{loc}$ from GPU to $Z$ in CPU\;
312 \subsection{A MPI-CUDA approach}
313 Our parallel implementation of EA to find roots of polynomials using a
314 CUDA-MPI approach follows a similar approach to the one used in
315 CUDA-OpenMP. Each process is responsible to compute its own part of
316 roots using all the roots computed by other processors at the previous
317 iteration. The difference between both approaches lies in the way
318 processes communicate and exchange data. With MPI, processors need to
319 send and receive data explicitly. So in
320 Algorithm~\ref{alg2-cuda-mpi}, after the initialization all the
321 processors have the same $Z$ vector. Then they need to compute the
322 parameters used by the $MPI\_AlltoAll$ routines (line 4). In practice,
323 each processor needs to compute its offset and its local
324 size. Processors need to allocate memory on their GPU and need to copy
325 their data on the GPU (line 5). At the beginning of each iteration, a
326 processor starts by transferring the whole vector $Z$ from the CPU to the
327 GPU (line 7). Only the local part of $Z^{prev}$ is saved (line
328 8). After that, a processor is able to compute an updated version of
329 its own roots (line 9) with the EA method. The local error is computed
330 (line 10) and the global error using $MPI\_Reduce$ (line 11). Then
331 the local roots are transferred from the GPU memory to the CPU memory
332 (line 12) before being exchanged between all processors (line 13) in
333 order to give to all processors the last version of the roots (with
334 the MPI\_AlltoAll routine). If the convergence is not satisfied, an
335 new iteration is executed.
337 \begin{algorithm}[htpb]
338 \label{alg2-cuda-mpi}
341 \caption{Finding roots of polynomials with the Ehrlich-Aberth method on multiple GPUs using MPI}
343 \KwIn{ $\epsilon$ (tolerance threshold)}
345 \KwOut {$Z$ (solution vector of roots)}
348 Initialize the polynomial $P$ and its derivative $P'$\;
349 Set the initial values of vector $Z$\;
350 Determine the local part of the MPI process\;
351 Computation of the parameters for the $MPI\_AlltoAll$\;
352 Copy $P$, $P'$ from CPU to GPU\;
353 \While {$error > \epsilon$}{
354 Copy $Z$ from CPU to GPU\;
355 $Z^{prev}_{loc}$ = KernelSave($Z_{loc}$)\;
356 $Z_{loc}$ = KernelUpdate($P,P',Z$)\;
357 $error_{loc}$ = KernelComputeError($Z_{loc},Z^{prev}_{loc}$)\;
358 $error=MPI\_Reduce(error_{loc})$\;
359 Copy $Z_{loc}$ from GPU to CPU\;
360 $Z=MPI\_AlltoAll(Z_{loc})$\;
365 \section{Experiments}
367 We study two categories of polynomials: sparse polynomials and full polynomials.\\
368 {\it A sparse polynomial} is a polynomial for which only some coefficients are not null. In this paper, we consider sparse polynomials for which the roots are distributed on 2 distinct circles:
370 \forall \alpha_{1} \alpha_{2} \in \mathbb{C},\forall n_{1},n_{2} \in \mathbb{N}^{*}; p(z)= (z^{n_{1}}-\alpha_{1})(z^{n_{2}}-\alpha_{2})
371 \end{equation}\noindent
372 {\it A full polynomial} is, in contrast, a polynomial for which all the coefficients are not null. A full polynomial is defined by:
375 {\Large \forall \alpha_{i} \in \mathbb{C}, i\in \mathbb{N}; p(x)=\sum^{n}_{i=0} \alpha_{i}.x^{i}}
378 For our tests, 4 cards GPU Tesla Kepler K40 are used. In order to evaluate both the GPU and Multi-GPU approaches, we performed a set of experiments on a single GPU and multiple GPUs using OpenMP or MPI with the EA algorithm, for both sparse and full polynomials of different sizes. All experimental results obtained are performed with double precision float data and the convergence threshold of the EA method is set to $10^{-7}$. The initialization values of the vector solution of the methods are given by Guggenheimer method~\cite{Gugg86}.
380 \subsection{Evaluation of the multi-GPUs approaches}
381 Here we evaluate the performances of the CUDA-OpenMP and CUDA-MPI approaches of the EA algorithm on different GPU platforms composed each of 1, 2, 3 or 4 GPUs. In this experiments we report the experimental results of the EA algorithms to find roots of different sparse and full polynomials of high degrees ranging from 100,000 to 1,400,000. Figures~\ref{fig:01} and~\ref{fig:02} show the execution times to solve, respectively, sparse and full polynomials with the CUDA-OpenMP algorithm, and Figures~\ref{fig:03} and~\ref{fig:04} show those to solve, respectively, sparse and full polynomials with the CUDA-MPI algorithm.
383 All these figures show that the CUDA-OpenMP and CUDA-MPI approaches of the EA algorithm, compared to the single GPU version, are efficient and scale well with multiple GPUs. Both approaches allow us to solve sparse and full polynomials of very high degrees. Using 4 GPUs allows us to achieve a quasi-linear speedup.
387 \includegraphics[angle=-90,width=0.5\textwidth]{Sparse_omp}
388 \caption{Execution times in seconds of the Ehrlich-Aberth method to solve sparse polynomials on multiple GPUs with CUDA-OpenMP.}
394 \includegraphics[angle=-90,width=0.5\textwidth]{Full_omp}
395 \caption{Execution times in seconds of the Ehrlich-Aberth method to solve full polynomials on multiple GPUs with CUDA-OpenMP.}
401 \includegraphics[angle=-90,width=0.5\textwidth]{Sparse_mpi}
402 \caption{Execution times in seconds of the Ehrlich-Aberth method to solve sparse polynomials on multiple GPUs with CUDA-MPI.}
408 \includegraphics[angle=-90,width=0.5\textwidth]{Full_mpi}
409 \caption{Execution times in seconds of the Ehrlich-Aberth method for full polynomials on multiple GPUs with CUDA-MPI.}
414 \subsection{Comparison between the CUDA-OpenMP and the CUDA-MPI approaches}
415 In the previous section we saw that both approaches are very efficient to reduce the execution times to solve sparse and full polynomials. In this section we try to compare these two approaches. In this experiment three sparse polynomials and three full polynomials of degrees 200,000, 800,000 and 1,400,000 are investigated. Figures~\ref{fig:05} and~\ref{fig:06} show the comparison between CUDA-OpenMP and CUDA-MPI algorithms of the EA method to solve sparse and full polynomials, respectively.
419 \includegraphics[angle=-90,width=0.5\textwidth]{Sparse}
420 \caption{Execution times to solve sparse polynomials of three distinct degrees on multiple GPUs using OpenMP and MPI with the Ehrlich-Aberth method}
426 \includegraphics[angle=-90,width=0.5\textwidth]{Full}
427 \caption{Execution times to solve full polynomials of three distinct degrees on multiple GPUs using OpenMP and MPI with the Ehrlich-Aberth method}
431 In Figure~\ref{fig:05} there is one curve for CUDA-OpenMP and another one for CUDA-MPI. We can see that the results are quite similar between OpenMP and MPI for the polynomial degree of 200K. For the degree of 800K, the MPI version is a little bit slower than the OpenMP version but for the degree of 1,4 millions, there is a slight advantage for the MPI version. In Figure~\ref{fig:06}, we can see that when it comes to full polynomials, both approaches are almost equivalent.
434 \subsection{Solving sparse and full polynomials of the same degree on multiple GPUs}
435 In this experiment we compare the execution times of the EA algorithm according to the number of GPUs to solve sparse and full polynomials on multiple GPUs using OpenMP or MPI approaches. We chose three sparse and three full polynomials of degrees 200,000, 800,000 and 1,400,000. Figures~\ref{fig:07} and~\ref{fig:08} show the execution times to solve sparse and full polynomials of the same degrees with CUDA-OpenMP version and CUDA-MPI version, respectively.
439 \includegraphics[angle=-90,width=0.5\textwidth]{OMP}
440 \caption{Execution times to solve sparse and full polynomials of three distinct degrees on multiple GPUs using OpenMP.}
446 \includegraphics[angle=-90,width=0.5\textwidth]{MPI}
447 \caption{Execution times to solve sparse and full polynomials of three distinct degrees on multiple GPUs using MPI.}
451 In Figure ~\ref{fig:07} the execution times of the CUDA-OpenMP version to solve sparse polynomials are very low compared to those to solve full polynomials. With sparse polynomials the number of monomials is reduced, consequently the number of operations is reduced and the execution time decreases. Figure~\ref{fig:08} shows the impact of sparsity on the effectiveness of the CUDA-MPI approach. We can see that the impact follows the same pattern, a difference in execution times in favor of the sparse polynomials.
454 \subsection{Scalability of the EA method on multiple GPUs to solve very high degree polynomials}
455 These experiments report the execution times of the EA method for sparse and full polynomials of high degrees ranging from 1,000,000 to 5,000,000. In Figure~\ref{fig:09} we can see that both approaches (CUDA-OpenMP and CUDA-MPI) are scalable and can solve very high degree polynomials. In addition, with full polynomial as well as sparse ones, both approaches give very similar results.
459 \includegraphics[angle=-90,width=0.5\textwidth]{big}
460 \caption{Execution times in seconds of the Ehrlich-Aberth method to solve sparse and full polynomials of high degree on 4 GPUs for degrees ranging from 1M to 5M}
467 In this paper, we have presented parallel implementations of the Ehrlich-Aberth algorithm to solve full and sparse polynomials, on a single GPU with CUDA and on multiple GPUs using two parallel paradigms: shared memory with OpenMP and distributed memory with MPI. These architectures were addressed by a CUDA-OpenMP approach and CUDA-MPI approach, respectively. Experiments show that, using parallel programming model like (OpenMP or MPI), we can efficiently manage multiple graphics cards to solve the same problem and accelerate the parallel execution with 4 GPUs and solve a polynomial of degree up-to 5,000,000 four times faster than on single GPU.
469 Our next objective is to extend the model presented here with clusters of GPU nodes, with a three-level scheme: inter-node communications via MPI processes (distributed memory), management of multi-GPU nodes by OpenMP threads (shared memory).
472 \section*{Acknowledgment}
473 This paper is partially funded by the Labex ACTION program (contract
474 ANR-11-LABX-01-01). Computations have been performed on the supercomputer facilities of the Mésocentre de calcul de Franche-Comté. We also would like to thank Nvidia for hardware donation under CUDA Research Center 2014.
477 \bibliography{mybibfile}