version 1.2, 2001/09/23 08:31:18 |
version 1.5, 2001/09/29 08:33:41 |
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%% $OpenXM: OpenXM/doc/ascm2001p/ohp.tex,v 1.1 2001/09/20 09:27:56 takayama Exp $ |
%% $OpenXM: OpenXM/doc/ascm2001p/ohp.tex,v 1.4 2001/09/25 02:28:27 takayama Exp $ |
\documentclass{slides} |
\documentclass{slides} |
%%\documentclass[12pt]{article} |
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\usepackage{color} |
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{\color{green} Design and Implementation of OpenXM-RFC 100 and 101} |
{\color{green} Design and Implementation of OpenXM-RFC 100 and 101} |
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\noindent |
\noindent |
M.Maekawa, M.Noro, K.Ohara, N.Takayama, Y.Tamura \\ |
M.Maekawa ($BA0(B $B@n(B $B!!(B $B>-(B $B=((B), \\ M.Noro ($BLn(B $BO$(B $B!!(B $B@5(B $B9T(B), \\ |
\htmladdnormallink{http://www.openxm.org}{http://www.openxm.org} |
K.Ohara ($B>.(B $B86(B $B!!(B $B8y(B $BG$(B), \\ N.Takayama ($B9b(B $B;3(B $B!!(B $B?.(B $B5#(B), \\ |
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Y.Tamura ($BED(B $BB<(B $B!!(B $B63(B $B;N(B)\\ |
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\htmladdnormallink{{\color{red}http://www.openxm.org}}{{\color{red}http://www.openxm.org}} |
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\newpage |
\newpage |
\noindent |
\noindent |
{\color{red} 1. Architecture} \\ |
{\color{red} 1. Architecture} \\ |
Line 21 Two main applications of the project \\ |
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Line 24 Two main applications of the project \\ |
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\begin{enumerate} |
\begin{enumerate} |
\item Providing an environment for interactive distributed computation. |
\item Providing an environment for interactive distributed computation. |
{\color{blue} Risa/Asir} |
{\color{blue} Risa/Asir} |
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(computer algebra system for general purpose, |
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open source (c) Fujitsu, \\ |
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http://www.openxm.org, \\ |
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http://risa.cs.ehime-u.ac.jp, \\ |
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http://www.math.kobe-u.ac.jp/Asir/asir.html) |
\item e-Bateman project |
\item e-Bateman project |
(Electronic version of higher transcendental functions of the 21st century)\\ |
(Electronic version of higher transcendental functions of the 21st century)\\ |
1st step: Generate and verify hypergeometric function identities. |
1st step: Generate and verify hypergeometric function identities. |
Line 36 OpenXM-RFC 100 \\ |
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Line 44 OpenXM-RFC 100 \\ |
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OpenXM {\color{red} stackmachine}. |
OpenXM {\color{red} stackmachine}. |
\item execute\_string |
\item execute\_string |
\begin{verbatim} |
\begin{verbatim} |
P = ox_launch(0,"ox_asir"); |
Pid = ox_launch(0,"ox_asir"); |
ox_execute_string(Pid," poly_factor(x^10-1);"); |
ox_execute_string(Pid," poly_factor(x^10-1);"); |
\end{verbatim} |
\end{verbatim} |
\end{enumerate} |
\end{enumerate} |
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\end{picture} |
\end{picture} |
\newpage |
\newpage |
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\noindent{\color{red} 4. Easy to try and evaluate distributed algorithms} \\ |
\noindent |
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{\color{red} 4. e-Bateman project} (Electronic mathematical formula book)\\ |
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First Step: \\ |
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Gauss Hypergeometric function: |
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$$ {\color{blue} F(a,b,c;x)} = \sum_{n=1}^\infty |
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\frac{(a)_n (b)_n}{(1)_n (c)_n} x^n |
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$$ |
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where |
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$$ (a)_n = a(a+1) \cdots (a+n-1). $$ |
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{\color{green} |
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$$ \log (1+x) = x F(1,1,2;-x) $$ |
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$$ \arcsin x = x F(1/2,1/2,3/2;x^2) $$ |
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} |
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\noindent |
\noindent |
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Appell's $F_1$: |
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$$ {\color{blue} F_1(a,b,b',c;x,y)} = \sum_{m,n=1}^\infty |
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\frac{(a)_{m+n} (b)_m (b')_n}{(c)_{m+n}(1)_m (1)_n} x^m y^n. |
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$$ |
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\newpage |
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Mathematical formula book, e.g., |
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Erdelyi: {\color{green} Higher Transcendental Functions} \\ |
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{\color{blue} Formula (type A)}\\ |
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The solution space of the ordinary differential equation |
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$$ x(1-x) \frac{d^2f}{dx^2} -\left( c-(a+b+1)x \right) \frac{df}{dx} - a b f = 0$$ |
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is spanned by |
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$$ F(a,b,c;x) = {\color{red}1} + O(x), \ |
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x^{1-c} F(a,b,c;x) = {\color{red}x^{1-c}}+O(x^{2-c}))$$ |
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when $c \not\in {\bf Z}$. \\ |
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{\color{blue} Formula (type B)}\\ |
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\begin{eqnarray*} |
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&\ & F(a_1, a_2, b_2;z) \, F(-a_1,-a_2,2-b_2;z) \\ |
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&+& \frac{z}{e_2}\, F'(a_1, a_2, b_2;z) \, F(-a_1,-a_2,2-b_2;z) \\ |
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&-& \frac{z}{e_2}\, F(a_1, a_2, b_2;z) \, F'(-a_1,-a_2,2-b_2;z) \\ |
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&-& \frac{a_1+a_2-e_2}{a_1 a_2 e_2}z^2\, |
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F'(a_1, a_2, b_2;z)\,F'(-a_1,-a_2,2-b_2;z) \\ |
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&=& 1 |
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\end{eqnarray*} |
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where $e_2 = b_2-1$ and $a_1, a_2, e_2, e_2-a_2 \not\in {\bf Z}$. \\ |
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(generalization of $\sin^2 x + \cos^2 x =1$.) |
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\noindent |
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Project in progress: \\ |
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We are trying to generate or verify type A formulas and type B formulas |
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for {\color{blue} GKZ hypergeometric systems}. |
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\begin{tabular}{|c|c|c|} |
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\hline |
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& type A & type B \\ \hline |
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Algorithm & {\color{red} OK} (SST book) & in progress \\ \hline |
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Implementation & partially done & NO \\ \hline |
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\end{tabular} |
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\noindent |
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Our ox servers |
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{\tt ox\_asir}, {\tt ox\_sm1}, {\tt ox\_tigers}, {\tt ox\_gnuplot}, |
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{\tt ox\_mathematica}, {\tt OpenMathproxy} (JavaClasses), {\tt ox\_m2} |
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are used to generate, verify and present formulas of type A |
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for GKZ hypergeometric systems. |
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\newpage |
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\noindent{\color{red} 5. Easy to try and evaluate distributed algorithms} \\ |
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\noindent |
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{\color{green} Example 1} \\ |
Theorem (Cantor-Zassenhaus) \\ |
Theorem (Cantor-Zassenhaus) \\ |
Let $f_1$ and $f_2$ be degree $d$ polynomials in $F_q[x]$. |
Let $f_1$ and $f_2$ be degree $d$ irreducible polynomials in $F_q[x]$. |
For a random degree $2d-1$ polynomial $g \in F_q[x]$, |
For a random degree $2d-1$ polynomial $g \in F_q[x]$, |
the chance of |
the chance of |
$$ GCD(g^{(q^d-1)/2}-1,f_1 f_2) = f_1 \,\mbox{or}\, f_2 $$ |
$$ GCD(g^{(q^d-1)/2}-1,f_1 f_2) = f_1 \,\mbox{or}\, f_2 $$ |
Line 142 $$ \frac{1}{2}-\frac{1}{(2q)^d}. $$ |
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Line 214 $$ \frac{1}{2}-\frac{1}{(2q)^d}. $$ |
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\begin{picture}(20,14)(0,0) |
\begin{picture}(20,14)(0,0) |
\put(7,12){\framebox(4,1.5){client}} |
\put(7,12){\framebox(4,1.5){client}} |
\put(2,6){\framebox(4,1.5){server}} |
\put(2,6){\framebox(4,1.5){server}} |
\put(7,6){\framebox(4,1.5){server}} |
%%\put(7,6){\framebox(4,1.5){server}} |
\put(12,6){\framebox(4,1.5){server}} |
\put(12,6){\framebox(4,1.5){server}} |
\put(0,0){\framebox(4,1.5){server}} |
\put(0,0){\framebox(4,1.5){server}} |
\put(5,0){\framebox(4,1.5){server}} |
\put(5,0){\framebox(4,1.5){server}} |
\put(13.5,0){\framebox(4,1.5){server}} |
\put(13.5,0){\framebox(4,1.5){server}} |
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\put(9,12){\vector(-1,-1){4.3}} |
\put(9,12){\vector(-1,-1){4.3}} |
\put(9,12){\vector(0,-1){4.3}} |
%%\put(9,12){\vector(0,-1){4.3}} |
\put(9,12){\vector(1,-1){4.3}} |
\put(9,12){\vector(1,-1){4.3}} |
\put(4,6){\vector(-1,-2){2.2}} |
\put(4,6){\vector(-1,-2){2.2}} |
\put(4,6){\vector(1,-2){2.2}} |
\put(4,6){\vector(1,-2){2.2}} |
Line 195 def c_z(F,E,Level) |
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Line 267 def c_z(F,E,Level) |
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} |
} |
\end{verbatim} |
\end{verbatim} |
\newpage |
\newpage |
\noindent |
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{\color{red} 5. e-Bateman project} \\ |
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First Step: \\ |
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Gauss Hypergeometric function: |
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$$ {\color{blue} F(a,b,c;x)} = \sum_{n=1}^\infty |
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\frac{(a)_n (b)_n}{(1)_n}{(c)_n} x^n |
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$$ |
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where |
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$$ (a)_n = a(a+1) \cdots (a+n-1). $$ |
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$$ \log (1+x) = x F(1,1,2;-x) $$ |
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$$ \arcsin x = x F(1/2,1/2,3/2;x^2) $$ |
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\noindent |
\epsfxsize=17cm |
Appell's $F_1$: |
\epsffile{cz.ps} |
$$ {\color{blue} F_1(a,b,b',c;x,y)} = \sum_{m,n=1}^\infty |
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\frac{(a)_{m+n} (b)_m (b')_n}{(c)_{m+n}(1)_m (1)_n} x^m y^n. |
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$$ |
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\newpage |
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Mathematical formula book, e.g., |
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Erdelyi: {\color{green} Higher Transcendental Functions} \\ |
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{\color{blue} Formula (type A)}\\ |
|
The solution space of the ordinary differential equation |
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$$ x(1-x) \frac{d^2f}{dx^2} -\left( c-(a+b+1)x \right) \frac{df}{dx} - a b f = 0$$ |
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is spanned by |
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$$ F(a,b,c;x) , \ x^{1-c} F(a,b,c;x) $$ |
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when $c \not\in {\bf Z}$. \\ |
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{\color{blue} Formula (type B)}\\ |
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\begin{eqnarray*} |
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&\ & F(a_1, a_2, b_2;z) \, F(-a_1,-a_2,2-b_2;z) \\ |
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&+& \frac{z}{e_2}\, F'(a_1, a_2, b_2;z) \, F(-a_1,-a_2,2-b_2;z) \\ |
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&-& \frac{z}{e_2}\, F(a_1, a_2, b_2;z) \, F'(-a_1,-a_2,2-b_2;z) \\ |
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&-& \frac{a_1+a_2-e_2}{a_1 a_2 e_2}z^2\, |
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F'(a_1, a_2, b_2;z)\,F'(-a_1,-a_2,2-b_2;z) \\ |
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&=& 1 |
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\end{eqnarray*} |
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where $e_2 = b_2-1$ and $a_1, a_2, e_2, e_2-a_2 \not\in {\bf Z}$. \\ |
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(generalization of $\sin^2 x + \cos^2 x =1$.) |
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\noindent |
\noindent |
Project in progress: \\ |
{\color{blue} Performance of parallel CZ algorithm} \\ |
We are trying to generate or verify type A formulas and type B formulas |
$d=1$, $k=200$ : product of $200$ linear forms. \\ |
for {\color{blue} GKZ hypergeometric systems}. |
$d=2$, $k=50$ : product of $50$ irreducible degree $2$ polynomials. \\ |
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\begin{tabular}{|c|c|c|} |
\newpage |
\hline |
{\color{green} Example 2} \\ |
& type A & type B \\ \hline |
Shoup's algorithm to multiply polynomials. \\ |
Algorithm & {\color{red} OK} (SST book) & in progress \\ \hline |
{\color{green} Example 3} \\ |
Implementation & partially done & NO \\ \hline |
Competitive Gr\"obner basis computation. \\ |
\end{tabular} |
\newpage |
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\noindent |
\noindent |
Our ox servers |
{\color{green} Example 3. Competitive Gr\"obner Basis Computation} |
{\tt ox\_asir}, {\tt ox\_sm1}, {\tt ox\_tigers}, {\tt ox\_gnuplot}, |
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{\tt ox\_mathematica}, {\tt OMproxy} (JavaClasses), {\tt ox\_m2} |
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are used to generate, verify and present formulas of type A |
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for GKZ hypergeometric systems. |
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\newpage |
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\noindent |
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{\color{green} Competitive Gr\"obner Basis Computation} |
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\begin{verbatim} |
\begin{verbatim} |
extern Proc1,Proc2$ |
extern Proc1,Proc2$ |
Proc1 = -1$ Proc2 = -1$ |
Proc1 = -1$ Proc2 = -1$ |