% $OpenXM: OpenXM/doc/ascm2001/homogeneous-network.tex,v 1.3 2001/03/07 08:12:56 noro Exp $
\subsection{Distributed computation with homogeneous servers}
\label{section:homog}
One of the aims of OpenXM is a parallel speedup by a distributed computation
with homogeneous servers. As the current specification of OpenXM does
not include communication between servers, one cannot expect
the maximal parallel speedup. However it is possible to execute
several types of distributed computation as follows.
\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. The will be proposed as OpenXM-RFC-102 in future.
We note that preliminary experiments shows the collective operations
works 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.
The following Risa/Asir function computes a Gr\"obner basis by
starting the computations simultaneously from the homogenized input and
the input itself. 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}
\subsubsection{Nesting of client-server communication}
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
client-server communication.
\begin{figure}
\label{tree}
\begin{center}
\begin{picture}(200,140)(0,0)
\put(70,120){\framebox(40,15){client}}
\put(20,60){\framebox(40,15){server}}
\put(70,60){\framebox(40,15){server}}
\put(120,60){\framebox(40,15){server}}
\put(0,0){\framebox(40,15){server}}
\put(50,0){\framebox(40,15){server}}
\put(135,0){\framebox(40,15){server}}
\put(90,120){\vector(-1,-1){43}}
\put(90,120){\vector(0,-1){43}}
\put(90,120){\vector(1,-1){43}}
\put(40,60){\vector(-1,-2){22}}
\put(40,60){\vector(1,-2){22}}
\put(140,60){\vector(1,-3){14}}
\end{picture}
\caption{Tree-like structure of client-server communication}
\end{center}
\end{figure}
Such a computational model is useful for parallel implementation of
algorithms whose task can be divided into subtasks recursively. A
typical example is {\it quicksort}, where an array to be sorted is
partitioned into two sub-arrays and the algorithm is applied to each
sub-array. In each level of recursion, two subtasks are generated
and one can ask other OpenXM servers to execute them. Though
this makes little contribution to the efficiency, it is worth
to show that such an attempt is very easy under OpenXM.
Here is an Asir program.
A predefined constant {\tt LevelMax} determines
whether new servers are launched or whole subtasks are done on the server.
\begin{verbatim}
#define LevelMax 2
extern Proc1, Proc2;
Proc1 = -1$ Proc2 = -1$
/* sort [A[P],...,A[Q]] by quicksort */
def quickSort(A,P,Q,Level) {
if (Q-P < 1) return A;
Mp = idiv(P+Q,2); M = A[Mp]; B = P; E = Q;
while (1) {
while (A[B] < M) B++;
while (A[E] > M && B <= E) E--;
if (B >= E) break;
else { T = A[B]; A[B] = A[E]; A[E] = T; E--; }
}
if (E < P) E = P;
if (Level < LevelMax) {
/* launch new servers if necessary */
if (Proc1 == -1) Proc1 = ox_launch(0);
if (Proc2 == -1) Proc2 = ox_launch(0);
/* send the requests to the servers */
ox_rpc(Proc1,"quickSort",A,P,E,Level+1);
ox_rpc(Proc2,"quickSort",A,E+1,Q,Level+1);
if (E-P < Q-E) {
A1 = ox_pop_local(Proc1);
A2 = ox_pop_local(Proc2);
}else{
A2 = ox_pop_local(Proc2);
A1 = ox_pop_local(Proc1);
}
for (I=P; I<=E; I++) A[I] = A1[I];
for (I=E+1; I<=Q; I++) A[I] = A2[I];
return(A);
}else{
/* everything is done on this server */
quickSort(A,P,E,Level+1);
quickSort(A,E+1,Q,Level+1);
return(A);
}
}
\end{verbatim}
Another example is a parallelization of the Cantor-Zassenhaus
algorithm for polynomial factorization over finite fields. Its
fundamental structure is similar to that of quicksort. By choosing a
random polynomial, a polynomial is divided into two sub-factors with
some probability. Then each subfactor is factorized recursively. In
the following program, one of the two sub-factors generated on a server
is sent to another server and the other subfactor is factorized on the server
itself.
\begin{verbatim}
/* factorization of F */
/* E = degree of irreducible factors in F */
def c_z(F,E,Level)
{
V = var(F); N = deg(F,V);
if ( N == E ) return [F];
M = field_order_ff(); K = idiv(N,E); L = [F];
while ( 1 ) {
W = monic_randpoly_ff(2*E,V);
T = generic_pwrmod_ff(W,F,idiv(M^E-1,2));
if ( !(W = T-1) ) continue;
G = ugcd(F,W);
if ( deg(G,V) && deg(G,V) < N ) {
if ( Level >= LevelMax ) {
/* everything is done on this server */
L1 = c_z(G,E,Level+1);
L2 = c_z(sdiv(F,G),E,Level+1);
} else {
/* launch a server if necessary */
if ( Proc1 < 0 ) Proc1 = ox_launch();
/* send a request with Level = Level+1 */
/* ox_c_z is a wrapper of c_z on the server */
ox_cmo_rpc(Proc1,"ox_c_z",lmptop(G),E,
setmod_ff(),Level+1);
/* the rest is done on this server */
L2 = c_z(sdiv(F,G),E,Level+1);
L1 = map(simp_ff,ox_pop_cmo(Proc1));
}
return append(L1,L2);
}
}
}
\end{verbatim}
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