| version 1.1, 2001/06/19 07:32:58 |
version 1.7, 2001/06/20 05:42:47 |
|
|
| % $OpenXM$ |
% $OpenXM: OpenXM/doc/ascm2001p/homogeneous-network.tex,v 1.6 2001/06/20 03:18:21 noro Exp $ |
| |
|
| \subsection{Distributed computation with homogeneous servers} |
\subsection{Distributed computation with homogeneous servers} |
| \label{section:homog} |
\label{section:homog} |
| |
|
| One of the aims of OpenXM is a parallel speedup by a distributed computation |
One of the aims of OpenXM is a parallel speedup by a distributed computation |
| with homogeneous servers. As the current specification of OpenXM does |
with homogeneous servers. Let us see some examples. |
| not include communication between servers, one cannot expect |
%As the current specification of OpenXM does |
| the maximal parallel speedup. However it is possible to execute |
%not include communication between servers, one cannot expect |
| several types of distributed computation as follows. |
%the maximal parallel speedup. However it is possible to execute |
| |
%several types of distributed computation as follows. |
| |
|
| \subsubsection{Product of univariate polynomials} |
\subsubsection{Competitive distributed computation by various strategies} |
| |
|
| Shoup \cite{Shoup} showed that the product of univariate polynomials |
SINGULAR \cite{Singular} implements {\it MP} interface for distributed |
| with large degrees and large coefficients can be computed efficiently |
computation and a competitive Gr\"obner basis computation is |
| by FFT over small finite fields and Chinese remainder theorem, |
illustrated as an example of distributed computation by the MP interface. |
| which can be easily parallelized. |
Such a distributed computation is also possible on OpenXM. |
| % |
|
| %\begin{tabbing} |
|
| %Input :\= $f_1, f_2 \in {\bf Z}[x]$ such that $deg(f_1), deg(f_2) < 2^M$\\ |
|
| %Output : $f = f_1f_2$ \\ |
|
| %$P \leftarrow$ \= $\{m_1,\cdots,m_N\}$ where $m_i$ is an odd prime, \\ |
|
| %\> $2^{M+1}|m_i-1$ and $m=\prod m_i $ is sufficiently large. \\ |
|
| %Separate $P$ into disjoint subsets $P_1, \cdots, P_L$.\\ |
|
| %for \= $j=1$ to $L$ $M_j \leftarrow \prod_{m_i\in P_j} m_i$\\ |
|
| %Compute $F_j$ such that $F_j \equiv f_1f_2 \bmod M_j$\\ |
|
| %\> and $F_j \equiv 0 \bmod m/M_j$ in parallel.\\ |
|
| %\> (The product is computed by FFT.)\\ |
|
| %return $\phi_m(\sum F_j)$\\ |
|
| %(For $a \in {\bf Z}$, $\phi_m(a) \in (-m/2,m/2)$ and $\phi_m(a)\equiv a \bmod m$) |
|
| %\end{tabbing} |
|
| % |
|
| Figure \ref{speedup} |
|
| shows the speedup factor under the above distributed computation |
|
| on Risa/Asir. For each $n$, two polynomials of degree $n$ |
|
| with 3000bit coefficients are generated and the product is computed. |
|
| The machine is FUJITSU AP3000, |
|
| a cluster of Sun workstations connected with a high speed network |
|
| and MPI over the network is used to implement OpenXM. |
|
| \begin{figure}[htbp] |
|
| \epsfxsize=10cm |
|
| \epsffile{speedup.ps} |
|
| \caption{Speedup factor} |
|
| \label{speedup} |
|
| \end{figure} |
|
| If the number of servers is $L$ and the inputs are fixed, then the cost to |
|
| compute the products modulo some integers in parallel is $O(1/L)$, |
|
| whereas the cost |
|
| to send and receive polynomials is $O(L)$ if {\tt ox\_push\_cmo()} and |
|
| {\tt ox\_pop\_cmo()} are repeatedly applied on the client. |
|
| Therefore the speedup is limited and the upper bound of |
|
| the speedup factor depends on the ratio of |
|
| the computational cost and the communication cost for each unit operation. |
|
| Figure \ref{speedup} shows that |
|
| the speedup is satisfactory if the degree is large and $L$ |
|
| is not large, say, up to 10 under the above environment. |
|
| If OpenXM provides collective operations for broadcast and reduction |
|
| such as {\tt MPI\_Bcast} and {\tt MPI\_Reduce} respectively, the cost of |
|
| broadcasting the inputs and gathering the results on the servers |
|
| may be reduced to $O(\log_2L)$ |
|
| and we can expect better results in such a case. In order to implement |
|
| such operations we need new specifications for inter-sever communication |
|
| and the session management, which will be proposed as OpenXM-RFC 102. |
|
| We note that preliminary experiments show the collective operations |
|
| work well on OpenXM. |
|
| |
|
| %\subsubsection{Competitive distributed computation by various strategies} |
\begin{verbatim} |
| % |
extern Proc1,Proc2$ Proc1 = -1$ Proc2 = -1$ |
| %SINGULAR \cite{Singular} implements {\it MP} interface for distributed |
/* G:set of polys; V:list of variables */ |
| %computation and a competitive Gr\"obner basis computation is |
/* Mod: the Ground field GF(Mod); O:type of order */ |
| %illustrated as an example of distributed computation. |
def dgr(G,V,Mod,O) |
| %Such a distributed computation is also possible on OpenXM as follows: |
{ |
| % |
/* invoke servers if necessary */ |
| %The client creates two servers and it requests |
if ( Proc1 == -1 ) Proc1 = ox_launch(); |
| %Gr\"obner basis comutations from the homogenized input and the input itself |
if ( Proc2 == -1 ) Proc2 = ox_launch(); |
| %to the servers. |
P = [Proc1,Proc2]; |
| %The client watches the streams by {\tt ox\_select()} |
map(ox_reset,P); /* reset servers */ |
| %and the result which is returned first is taken. Then the remaining |
/* P0 executes Buchberger algorithm over GF(Mod) */ |
| %server is reset. |
ox_cmo_rpc(P[0],"dp_gr_mod_main",G,V,0,Mod,O); |
| % |
/* P1 executes F4 algorithm over GF(Mod) */ |
| %\begin{verbatim} |
ox_cmo_rpc(P[1],"dp_f4_mod_main",G,V,Mod,O); |
| %/* G:set of polys; V:list of variables */ |
map(ox_push_cmd,P,262); /* 262 = OX_popCMO */ |
| %/* O:type of order; P0,P1: id's of servers */ |
F = ox_select(P); /* wait for data */ |
| %def dgr(G,V,O,P0,P1) |
/* F[0] is a server's id which is ready */ |
| %{ |
R = ox_get(F[0]); |
| % P = [P0,P1]; /* server list */ |
if ( F[0] == P[0] ) { Win = "Buchberger"; Lose = P[1]; } |
| % map(ox_reset,P); /* reset servers */ |
else { Win = "F4"; Lose = P[0]; } |
| % /* P0 executes non-homogenized computation */ |
ox_reset(Lose); /* reset the loser */ |
| % ox_cmo_rpc(P0,"dp_gr_main",G,V,0,1,O); |
return [Win,R]; |
| % /* P1 executes homogenized computation */ |
} |
| % ox_cmo_rpc(P1,"dp_gr_main",G,V,1,1,O); |
\end{verbatim} |
| % map(ox_push_cmd,P,262); /* 262 = OX_popCMO */ |
In the above Asir program, the client creates two servers and it requests |
| % F = ox_select(P); /* wait for data */ |
Gr\"obner basis computations by the Buchberger algorithm |
| % /* F[0] is a server's id which is ready */ |
and the $F_4$ algorithm to the servers for the same input. |
| % R = ox_get(F[0]); |
The client watches the streams by {\tt ox\_select()} |
| % if ( F[0] == P0 ) { |
and the result which is returned first is taken. Then the remaining |
| % Win = "nonhomo"; Lose = P1; |
server is reset. |
| % } else { |
|
| % Win = "homo"; Lose = P0; |
|
| % } |
|
| % ox_reset(Lose); /* reset the loser */ |
|
| % return [Win,R]; |
|
| %} |
|
| %\end{verbatim} |
|
| |
|
| \subsubsection{Nesting of client-server communication} |
\subsubsection{Nesting of client-server communication} |
| |
|
| |
%%Prog: load ("dfff"); df_demo(); enter 100. |
| Under OpenXM-RFC 100 an OpenXM server can be a client of other servers. |
Under OpenXM-RFC 100 an OpenXM server can be a client of other servers. |
| Figure \ref{tree} illustrates a tree-like structure of an OpenXM |
Figure \ref{tree} illustrates a tree-like structure of an OpenXM |
| client-server communication. |
client-server communication. |
| |
|
| \begin{figure} |
\begin{figure} |
| \label{tree} |
\label{tree} |
| \begin{center} |
\begin{center} |
| \begin{picture}(200,140)(0,0) |
\begin{picture}(200,70)(0,0) |
| \put(70,120){\framebox(40,15){client}} |
\put(70,70){\framebox(40,15){client}} |
| \put(20,60){\framebox(40,15){server}} |
\put(20,30){\framebox(40,15){server}} |
| \put(70,60){\framebox(40,15){server}} |
\put(70,30){\framebox(40,15){server}} |
| \put(120,60){\framebox(40,15){server}} |
\put(120,30){\framebox(40,15){server}} |
| \put(0,0){\framebox(40,15){server}} |
\put(0,0){\framebox(40,15){server}} |
| \put(50,0){\framebox(40,15){server}} |
\put(50,0){\framebox(40,15){server}} |
| \put(135,0){\framebox(40,15){server}} |
\put(150,0){\framebox(40,15){server}} |
| |
|
| \put(90,120){\vector(-1,-1){43}} |
\put(90,70){\vector(-2,-1){43}} |
| \put(90,120){\vector(0,-1){43}} |
\put(90,70){\vector(0,-1){21}} |
| \put(90,120){\vector(1,-1){43}} |
\put(90,70){\vector(2,-1){43}} |
| \put(40,60){\vector(-1,-2){22}} |
\put(40,30){\vector(-2,-1){22}} |
| \put(40,60){\vector(1,-2){22}} |
\put(40,30){\vector(2,-1){22}} |
| \put(140,60){\vector(1,-3){14}} |
\put(140,30){\vector(2,-1){22}} |
| \end{picture} |
\end{picture} |
| \caption{Tree-like structure of client-server communication} |
\caption{Tree-like structure of client-server communication} |
| \end{center} |
\end{center} |
| \end{figure} |
\end{figure} |
| |
|
| Such a computational model is useful for parallel implementation of |
Such a computational model is useful for parallel implementation of |
| algorithms whose task can be divided into subtasks recursively. |
algorithms whose task can be divided into subtasks recursively. |
| |
|
| Line 186 algorithms whose task can be divided into subtasks rec |
|
| Line 131 algorithms whose task can be divided into subtasks rec |
|
| % } |
% } |
| %} |
%} |
| %\end{verbatim} |
%\end{verbatim} |
| |
% |
| A typical example is a parallelization of the Cantor-Zassenhaus |
A typical example is a parallelization of the Cantor-Zassenhaus |
| algorithm for polynomial factorization over finite fields. |
algorithm for polynomial factorization over finite fields, |
| which is a recursive algorithm. |
which is a recursive algorithm. |
| At each level of the recursion, a given polynomial can be |
At each level of the recursion, a given polynomial can be |
| divided into two non-trivial factors with some probability by using |
divided into two non-trivial factors with some probability by using |
|
|
| % if ( N == E ) return [F]; |
% if ( N == E ) return [F]; |
| % M = field_order_ff(); K = idiv(N,E); L = [F]; |
% M = field_order_ff(); K = idiv(N,E); L = [F]; |
| % while ( 1 ) { |
% while ( 1 ) { |
| % /* gererate a random polynomial */ |
% /* generate a random polynomial */ |
| % W = monic_randpoly_ff(2*E,V); |
% W = monic_randpoly_ff(2*E,V); |
| % /* compute a power of the random polynomial */ |
% /* compute a power of the random polynomial */ |
| % T = generic_pwrmod_ff(W,F,idiv(M^E-1,2)); |
% T = generic_pwrmod_ff(W,F,idiv(M^E-1,2)); |
|
|
| % |
% |
| % |
% |
| % |
% |
| |
|
| |
\subsubsection{Product of univariate polynomials} |
| |
|
| |
Shoup \cite{Shoup} showed that the product of univariate polynomials |
| |
with large degrees and large coefficients can be computed efficiently |
| |
by FFT over small finite fields and Chinese remainder theorem. |
| |
It can be easily parallelized: |
| |
|
| |
\begin{tabbing} |
| |
Input :\= $f_1, f_2 \in {\bf Z}[x]$ such that $deg(f_1), deg(f_2) < 2^M$\\ |
| |
Output : $f = f_1f_2$ \\ |
| |
$P \leftarrow$ \= $\{m_1,\cdots,m_N\}$ where $m_i$ is an odd prime, \\ |
| |
\> $2^{M+1}|m_i-1$ and $m=\prod m_i $ is sufficiently large. \\ |
| |
Separate $P$ into disjoint subsets $P_1, \cdots, P_L$.\\ |
| |
for \= $j=1$ to $L$ $M_j \leftarrow \prod_{m_i\in P_j} m_i$\\ |
| |
Compute $F_j$ such that $F_j \equiv f_1f_2 \bmod M_j$\\ |
| |
\> and $F_j \equiv 0 \bmod m/M_j$ in parallel.\\ |
| |
\> (The product is computed by FFT.)\\ |
| |
return $\phi_m(\sum F_j)$\\ |
| |
(For $a \in {\bf Z}$, $\phi_m(a) \in (-m/2,m/2)$ and $\phi_m(a)\equiv a \bmod m$) |
| |
\end{tabbing} |
| |
|
| |
Figure \ref{speedup} |
| |
shows the speedup factor under the above distributed computation |
| |
on Risa/Asir. For each $n$, two polynomials of degree $n$ |
| |
with 3000bit coefficients are generated and the product is computed. |
| |
The machine is FUJITSU AP3000, |
| |
a cluster of Sun workstations connected with a high speed network |
| |
and MPI over the network is used to implement OpenXM. |
| |
\begin{figure}[htbp] |
| |
\epsfxsize=8.5cm |
| |
\epsffile{speedup.ps} |
| |
\caption{Speedup factor} |
| |
\label{speedup} |
| |
\end{figure} |
| |
|
| |
If the number of servers is $L$ and the inputs are fixed, then the cost to |
| |
compute $F_j$ in parallel is $O(1/L)$, whereas the cost |
| |
to send and receive polynomials is $O(L)$ if {\tt ox\_push\_cmo()} and |
| |
{\tt ox\_pop\_cmo()} are repeatedly applied on the client. |
| |
Therefore the speedup is limited and the upper bound of |
| |
the speedup factor depends on the ratio of |
| |
the computational cost and the communication cost for each unit operation. |
| |
Figure \ref{speedup} shows that |
| |
the speedup is satisfactory if the degree is large and $L$ |
| |
is not large, say, up to 10 under the above environment. |
| |
If OpenXM provides collective operations for broadcast and reduction |
| |
such as {\tt MPI\_Bcast} and {\tt MPI\_Reduce} respectively, the cost of |
| |
sending $f_1$, $f_2$ and gathering $F_j$ may be reduced to $O(\log_2L)$ |
| |
and we can expect better results in such a case. In order to implement |
| |
such operations we need new specifications for inter-sever communication |
| |
and the session management, which will be proposed as OpenXM-RFC 102. |
| |
We note that preliminary experiments show the collective operations |
| |
work well on OpenXM. |
| |
|
| |
%\subsubsection{Competitive distributed computation by various strategies} |
| |
% |
| |
%SINGULAR \cite{Singular} implements {\it MP} interface for distributed |
| |
%computation and a competitive Gr\"obner basis computation is |
| |
%illustrated as an example of distributed computation. |
| |
%Such a distributed computation is also possible on OpenXM as follows: |
| |
% |
| |
%The client creates two servers and it requests |
| |
%Gr\"obner basis computations from the homogenized input and the input itself |
| |
%to the servers. |
| |
%The client watches the streams by {\tt ox\_select()} |
| |
%and the result which is returned first is taken. Then the remaining |
| |
%server is reset. |
| |
% |
| |
%\begin{verbatim} |
| |
%/* G:set of polys; V:list of variables */ |
| |
%/* O:type of order; P0,P1: id's of servers */ |
| |
%def dgr(G,V,O,P0,P1) |
| |
%{ |
| |
% P = [P0,P1]; /* server list */ |
| |
% map(ox_reset,P); /* reset servers */ |
| |
% /* P0 executes non-homogenized computation */ |
| |
% ox_cmo_rpc(P0,"dp_gr_main",G,V,0,1,O); |
| |
% /* P1 executes homogenized computation */ |
| |
% ox_cmo_rpc(P1,"dp_gr_main",G,V,1,1,O); |
| |
% map(ox_push_cmd,P,262); /* 262 = OX_popCMO */ |
| |
% F = ox_select(P); /* wait for data */ |
| |
% /* F[0] is a server's id which is ready */ |
| |
% R = ox_get(F[0]); |
| |
% if ( F[0] == P0 ) { |
| |
% Win = "nonhomo"; Lose = P1; |
| |
% } else { |
| |
% Win = "homo"; Lose = P0; |
| |
% } |
| |
% ox_reset(Lose); /* reset the loser */ |
| |
% return [Win,R]; |
| |
%} |
| |
%\end{verbatim} |
| |
|
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