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Diff for /OpenXM/src/asir-doc/parts/asir.texi between version 1.6 and 1.9

version 1.6, 2002/09/03 01:50:57 version 1.9, 2003/11/27 12:08:58
Line 1 
Line 1 
 @comment $OpenXM: OpenXM/src/asir-doc/parts/asir.texi,v 1.5 2000/09/23 07:53:24 noro Exp $  @comment $OpenXM: OpenXM/src/asir-doc/parts/asir.texi,v 1.8 2003/10/21 09:17:57 takayama Exp $
 \BJP  \BJP
 @node $B%f!<%68@8l(B Asir,,, Top  @node $B%f!<%68@8l(B Asir,,, Top
 @chapter $B%f!<%68@8l(B Asir  @chapter $B%f!<%68@8l(B Asir
Line 258  comprehensible than use of structure like C programs.
Line 258  comprehensible than use of structure like C programs.
 * $B$5$^$6$^$J<0(B::  * $B$5$^$6$^$J<0(B::
 * $B%W%j%W%m%;%C%5(B::  * $B%W%j%W%m%;%C%5(B::
 * $B%*%W%7%g%s;XDj(B::  * $B%*%W%7%g%s;XDj(B::
   * $B%b%8%e!<%k(B::
 \E  \E
 \BEG  \BEG
 * User defined functions::  * User defined functions::
Line 272  comprehensible than use of structure like C programs.
Line 273  comprehensible than use of structure like C programs.
 * various expressions::  * various expressions::
 * preprocessor::  * preprocessor::
 * option::  * option::
   * module::
 \E  \E
 @end menu  @end menu
   
Line 347  def c(N)
Line 349  def c(N)
         @}          @}
     return A;      return A;
 @}  @}
   
   @tex
   /* $A+B$ */
   @end tex
   
   def add(A,B)
   "add two numbers."
   @{
       return A+B;
   @}
 @end example  @end example
   
 @noindent  @noindent
Line 359  In the second example, @code{c(N)} returns a vector, s
Line 371  In the second example, @code{c(N)} returns a vector, s
 @code{N+1}.  @code{A[I]} is a vector of length @code{I+1}, and  @code{N+1}.  @code{A[I]} is a vector of length @code{I+1}, and
 each element is again a vector which contains  each element is again a vector which contains
 \E  \E
   
   @noindent
   \BJP
   3 $B$DL\$NNc$G$O(B, $B0z?tJB$S$N$"$H$KJ8;zNs$,CV$+$l$F$$$k$,!"$3$l$O(B
   Emacs-Lisp $B$N4X?tDj5A$KN`;w$N5!G=$G!"%X%k%WMQ$NJ8;zNs$G$"$k!#(B
   $B$3$NNc$N>l9g!"(B@code{help(add)} $B$K$h$C$F$3$NJ8;zNs$,=PNO$5$l$k!#(B
   \E
   
   @table @t
   \JP @item $B;2>H(B
   \EG @item References
   @fref{help}.
   @end table
   
 @iftex  @iftex
 @tex  @tex
 ${_I}C_J$  ${_I}C_J$
Line 890  infinite loop.
Line 916  infinite loop.
   
 @example  @example
 \JP for ( $B<0JB$S(B-1; $B<0(B; $B<0JB$S(B-2 ) $BJ8(B  \JP for ( $B<0JB$S(B-1; $B<0(B; $B<0JB$S(B-2 ) $BJ8(B
 \EG for ( expression list-1; expression; expression list-2 ) statement  \EG for ( expr list-1; expr; expr list-2 ) statement
 @end example  @end example
   
 \JP $B$G(B, $B$3$l$O(B  \JP $B$G(B, $B$3$l$O(B
Line 905  while ( $B<0(B ) @{
Line 931  while ( $B<0(B ) @{
 @}  @}
 \E  \E
 \BEG  \BEG
 expression list-1 (transformed into a sequence of simple statement)  expr list-1 (transformed into a sequence of simple statement)
 while ( expression ) @{  while ( expr ) @{
     statement      statement
     expression list-2 (transformed into a sequence of simple statement)      expr list-2 (transformed into a sequence of simple statement)
 @}  @}
 \E  \E
 @end example  @end example
Line 1137  There are special assignments combined with arithmetic
Line 1163  There are special assignments combined with arithmetic
   
 @example  @example
 \JP A = 2  A *= 3 ($B$3$l$O(B A = A*3 $B$HF1$8(B; $B$=$NB>$N1i;;;R$bF1MM(B)  \JP A = 2  A *= 3 ($B$3$l$O(B A = A*3 $B$HF1$8(B; $B$=$NB>$N1i;;;R$bF1MM(B)
 \EG A = 2  A *= 3 (the same as A = A*3; The other combination are alike.)  \EG A = 2  A *= 3 (the same as A = A*3; The others are alike.)
 @end example  @end example
 @item  @item
 \JP $BH!?t8F$S=P$7(B  \JP $BH!?t8F$S=P$7(B
Line 1163  A--  $BCM$O85$N(B A $B$NCM(B, A = A-1
Line 1189  A--  $BCM$O85$N(B A $B$NCM(B, A = A-1
 \BEG  \BEG
 A++  the expression value is the previous value of A, and A = A+1  A++  the expression value is the previous value of A, and A = A+1
 A--  the expression value is the previous value of A, and A = A-1  A--  the expression value is the previous value of A, and A = A-1
 ++A  A = A+1, and the expression value is the value after increment of A  ++A  A = A+1, and the value is the one after increment of A
 --A  A = A-1, and the expression value is the value after decrement of A  --A  A = A-1, and the value is the one after decrement of A
 \E  \E
 @end example  @end example
   
Line 1355  After @samp{|} one can append any number of options se
Line 1381  After @samp{|} one can append any number of options se
 @end example  @end example
   
   
   \BJP
   @node $B%b%8%e!<%k(B,,, $B%f!<%6Dj5AH!?t$N=q$-J}(B
   @subsection $B%b%8%e!<%k(B
   \E
   \BEG
   @node module,,, Writing user defined functions
   @subsection module
   \E
   
   \BJP
   $B%i%$%V%i%j$GDj5A$5$l$F$$$k4X?t(B, $BJQ?t$r%+%W%;%k2=$9$k;EAH$_$,(B
   $B%b%8%e!<%k(B (module) $B$G$"$k(B.
   $B$O$8$a$K%b%8%e!<%k$rMQ$$$?%W%m%0%i%`$NNc$r$"$2$h$&(B.
   \E
   \BEG
   Function names and variables in a library may be
   encapsulated by module.
   Let us see an example of using module
   \E
   
   @example
   module stack;
   
   static Sp $
   Sp = 0$
   static Ssize$
   Ssize = 100$
   static Stack $
   Stack = newvect(Ssize)$
   localf push $
   localf pop $
   
   def push(A) @{
     if (Sp >= Ssize) @{print("Warning: Stack overflow\nDiscard the top"); pop();@}
     Stack[Sp] = A;
     Sp++;
   @}
   def pop() @{
     local A;
     if (Sp <= 0) @{print("Stack underflow"); return 0;@}
     Sp--;
     A = Stack[Sp];
     return A;
   @}
   endmodule;
   
   def demo() @{
     stack.push(1);
     stack.push(2);
     print(stack.pop());
     print(stack.pop());
   @}
   @end example
   
   \BJP
   $B%b%8%e!<%k$O(B @code{module} $B%b%8%e!<%kL>(B  $B!A(B @code{endmodule}$B$G0O$`(B.
   $B%b%8%e!<%k$NCf$@$1$G;H$&Bg0hJQ?t$O(B @code{static} $B$G@k8@$9$k(B.
   $B$3$NJQ?t$O%b%8%e!<%k$N30$+$i$O;2>H$b$G$-$J$$$7JQ99$b$G$-$J$$(B.
   $B%b%8%e!<%k$N30$NBg0hJQ?t$O(B @code{extern} $B$G@k8@$9$k(B.
   \E
   \BEG
   Module is encapsulated by the sentences
   @code{module} module name
   and
   @code{endmodule}.
   A variable of a module is declared with the key word @code{static}.
   The static variables cannot be refered nor changed out of the module,
   but it can be refered and changed in any functions in the module.
   A global variable which can be refered and changed at any place
   is declared with the key word @code{extern}.
   \E
   
   \BJP
   $B%b%8%e!<%kFbIt$GDj5A$9$k4X?t$O(B @code{localf} $B$rMQ$$$F@k8@$7$J$$$H$$$1$J$$(B.
   $B>e$NNc$G$O(B @code{push} $B$H(B @code{pop} $B$r@k8@$7$F$$$k(B.
   $B$3$N@k8@$OI,?\$G$"$k(B.
   \E
   \BEG
   Any function defined in a module must be declared forward
   with the keyword @code{localf}.
   In the example above, @code{push} and @code{pop} are declared.
   This declaration is necessary.
   \E
   
   \BJP
   $B%b%8%e!<%k(B @code{moduleName} $B$GDj5A$5$l$?4X?t(B @code{functionName} $B$r(B
   $B%b%8%e!<%k$N30$+$i8F$V$K$O(B
        @code{moduleName.functionName($B0z?t(B1, $B0z?t(B2, ... )}
   $B$J$k7A<0$G$h$V(B.
   $B%b%8%e!<%k$NCf$+$i$O(B, $B4X?tL>$N$_$G$h$$(B.
   $B<!$NNc$G$O(B, $B%b%8%e!<%k$N30$+$i%b%8%e!<%k(B @code{stack} $B$GDj5A$5$l$?4X?t(B @code{push},
   @code{pop} $B$r8F$s$G$$$k(B.
   \E
   \BEG
   A function @code{functionName} defined in a module @code{moduleName}
   can be called by the expression
   @code{moduleName.functioName(arg1, arg2, ...)}
   out of the module.
   Inside the module, @code{moduleName.} is not necessary.
   In the example below, the functions @code{push} and @code{pop} defined
   in the module @code{stack} are called out of the module.
   \E
   
   @example
    stack.push(2);
    print( stack.pop() );
    2
   @end example
   
   \BJP
   $B%b%8%e!<%k$GMQ$$$k4X?tL>$O6I=jE*$G$"$k(B.
   $B$D$^$j%b%8%e!<%k$N30$dJL$N%b%8%e!<%k$GDj5A$5$l$F$$$k4X?tL>$HF1$8L>A0$,(B
   $BMxMQ$G$-$k(B.
   \E
   \BEG
   Any function name defined in a module is local.
   In other words, the same function name may be used out of the module
   to define a different function.
   \E
   
   \BJP
   $B%b%8%e!<%k5!G=$OBg5,LO%i%$%V%i%j$N3+H/$rA[Dj$7$F$$$k(B.
   $B%i%$%V%i%j$rI,MW$K1~$8$FJ,3d%m!<%I$9$k$K$O(B, $B4X?t(B @code{module_definedp} $B$rMQ$$$k$N$,(B
   $BJXMx$G$"$k(B.
   $B%G%^%s%I%m!<%I$O$?$H$($P<!$N$h$&$K9T$J$($PNI$$(B.
   \E
   \BEG
   The module structure of asir is introduced to develop large libraries.
   In order to load libraries on demand, the command @code{module_definedp}
   will be useful.
   The below is an example of demand loading.
   \E
   
   @example
   if (!module_definep("stack")) load("stack.rr") $
   @end example
   
   \BJP
   asir $B$G$O6I=jJQ?t$N@k8@$OITMW$G$"$C$?(B.
   $B$7$+$7%b%8%e!<%k(B stack $B$NNc$r8+$l$PJ,$+$k$h$&$K(B, @code{local A;} $B$J$k7A<0$G(B
   $B6I=jJQ?t$r@k8@$G$-$k(B.
   $B%-!<%o!<%I(B @code{local} $B$rMQ$$$k$H(B, $B@k8@5!G=$,M-8z$H$J$k(B.
   $B@k8@5!G=$rM-8z$K$9$k$H(B, $B@k8@$5$l$F$J$$JQ?t$O%m!<%I$NCJ3,$G(B
   $B%(%i!<$r5/$3$9(B.
   $BJQ?tL>$N%?%$%W%_%9$K$h$kM=4|$7$J$$%H%i%V%k$rKI$0$K$O(B,
   $B@k8@5!G=$rM-8z$K$7$F%W%m%0%i%`$9$k$N$,$h$$(B.
   \E
   \BEG
   It is not necessary to declare local variables in asir.
   As you see in the example of the stack module,
   we may declare local variables by the key word @code{local}.
   Once this key word is used, asir requires to declare all the
   variables.
   In order to avoid some troubles to develop a large libraries,
   it is recommended to use @code{local} declarations.
   \E
   
   \BJP
   $B%b%8%e!<%kFb$N4X?t$r$=$N%b%8%e!<%k$,Dj5A$5$l$kA0$K(B
   $B8F$S=P$9$h$&$J4X?t$r=q$/$H$-$K$O(B, $B$=$N4X?t$NA0$G%b%8%e!<%k$r<!$N$h$&$K(B
   $B%W%m%H%?%$%W@k8@$7$F$*$/I,MW$,$"$k(B.
   \E
   \BEG
   When we need to call a function in a module before the module is defined,
   we must make a prototype declaration as the example below.
   \E
   
   @example
   /* Prototype declaration of the module stack */
   module stack;
   localf push $
   localf pop $
   endmodule;
   
   def demo() @{
     print("----------------");
     stack.push(1);
     print(stack.pop());
     print("---------------");
   @}
   
   module stack;
     /* The body of the module stack */
   endmodule;
   @end example
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