ack/lang/pc/test/machar.p

{ $Id$ }

procedure machar (var ibeta , it , irnd , ngrd , machep , negep , iexp,
  minexp , maxexp : integer ; var eps , epsneg , xmin , xmax : real ) ;
var trapped:boolean;

procedure encaps(procedure p; procedure q(i:integer)); extern;
procedure trap(i:integer); extern;

procedure catch(i:integer);
const underflo=5;
begin if i=underflo then trapped:=true else trap(i) end;

procedure work;
var


{     This subroutine is intended to determine the characteristics
      of the floating-point arithmetic system that are specified
      below.  The first three are determined according to an
      algorithm due to M. Malcolm, CACM 15 (1972), pp. 949-951,
      incorporating some, but not all, of the improvements
      suggested by M. Gentleman and S. Marovich, CACM 17 (1974),
      pp. 276-277.  The version given here is for single precision.

      Latest revision - October 1, 1976.

      Author - W. J. Cody
               Argonne National Laboratory

      Revised for Pascal - R. A. Freak
                           University of Tasmania
                           Hobart
                           Tasmania

      ibeta    is the radix of the floating-point representation
      it       is the number of base ibeta digits in the floating-point
                  significand
      irnd     =  0 if the arithmetic chops,
                  1 if the arithmetic rounds
      ngrd     =  0 if  irnd=1, or if  irnd=0  and only  it  base ibeta
                    digits participate in the post normalization shift
                    of the floating-point significand in multiplication
                  1 if  irnd=0  and more than  it  base  ibeta  digits
                    participate in the post normalization shift of the
                    floating-point significand in multiplication
      machep   is the exponent on the smallest positive floating-point
                  number  eps such that  1.0+eps <> 1.0
      negeps   is the exponent on the smallest positive fl. pt. no.
                  negeps such that  1.0-negeps <> 1.0, except that
                  negeps is bounded below by  it-3
      iexp     is the number of bits (decimal places if ibeta = 10)
                  reserved for the representation of the exponent of
                  a floating-point number
      minexp   is the exponent of the smallest positive fl. pt. no.
                  xmin
      maxexp   is the exponent of the largest finite floating-point
                  number  xmax
      eps      is the smallest positive floating-point number such
                  that  1.0+eps <> 1.0. in particular,
                  eps = ibeta**machep
      epsneg   is the smallest positive floating-point number such
                  that  1.0-eps <> 1.0  (except that the exponent
                  negeps is bounded below by it-3).  in particular
                  epsneg = ibeta**negep
      xmin     is the smallest positive floating-point number.  in
                  particular,  xmin = ibeta ** minexp
      xmax     is the largest finite floating-point number.  in
                  particular   xmax = (1.0-epsneg) * ibeta ** maxexp
                  note - on some machines  xmax  will be only the
                  second, or perhaps third, largest number, being
                  too small by 1 or 2 units in the last digit of
                  the significand.

                                                                    }

   i , iz , j , k , mx : integer ;
   a , b , beta , betain , betam1 , one , y , z , zero : real ;

begin
   irnd := 1 ;
   one := ( irnd );
   a := one + one ;
   b := a ;
   zero := 0.0 ;
{
      determine ibeta,beta ala Malcolm
                                                                    }
   while ( ( ( a + one ) - a ) - one = zero ) do begin
      a := a + a ;
   end ;
   while ( ( a + b ) - a = zero ) do begin
      b := b + b ;
   end ;
   ibeta := trunc ( ( a + b ) - a );
   beta := ( ibeta );
   betam1 := beta - one ;
{
      determine irnd,ngrd,it
                                                                    }
   if ( ( a + betam1 ) - a = zero ) then irnd := 0 ;
   it := 0 ;
   a := one ;
   repeat begin
      it := it + 1 ;
      a := a * beta ;
   end until ( ( ( a + one ) - a ) - one <> zero ) ;
{
      determine negep, epsneg
                                                                    }
   negep := it + 3 ;
   a := one ;

   for i := 1 to negep do begin
      a := a / beta ;
   end ;

   while ( ( one - a ) - one = zero ) do begin
      a := a * beta ;
      negep := negep - 1 ;
   end ;
   negep := - negep ;
   epsneg := a ;
{
      determine machep, eps
                                                                    }
   machep := negep ;
   while ( ( one + a ) - one = zero ) do begin
      a := a * beta ;
      machep := machep + 1 ;
   end ;
   eps := a ;
{
      determine ngrd
                                                                    }
   ngrd := 0 ;
   if(( irnd = 0) and((( one + eps) * one - one) <> zero)) then
   ngrd := 1 ;
{
      determine iexp, minexp, xmin

      loop to determine largest i such that
          (1/beta) ** (2**(i))
      does not underflow
      exit from loop is signall by an underflow
                                                                    }
   i := 0 ;
   betain := one / beta ;
   z := betain ;
   trapped:=false;
   repeat begin
      y := z ;
      z := y * y ;
{
      check for underflow
                                                                    }
      i := i + 1 ;
   end until trapped;
   i := i - 1;
   k := 1 ;
{
      determine k such that (1/beta)**k does not underflow

      first set k = 2 ** i
                                                                    }

   for j := 1 to i do begin
      k := k + k ;
   end ;

   iexp := i + 1 ;
   mx := k + k ;
   if ( ibeta = 10 ) then begin
{
      for decimal machines only                                     }
      iexp := 2 ;
      iz := ibeta ;
      while ( k >= iz ) do begin
         iz := iz * ibeta ;
         iexp := iexp + 1 ;
      end ;
      mx := iz + iz - 1 ;
   end;
   trapped:=false;
   repeat begin
{
      loop to construct xmin
      exit from loop is signalled by an underflow
                                                                    }
      xmin := y ;
      y := y * betain ;
      k := k + 1 ;
   end until trapped;
   k := k - 1;
   minexp := - k ;
{  determine maxexp, xmax
                                                                    }
   if ( ( mx <= k + k - 3 ) and ( ibeta <> 10 ) ) then begin
      mx := mx + mx ;
      iexp := iexp + 1 ;
   end;
   maxexp := mx + minexp ;
{  adjust for machines with implicit leading
   bit in binary significand and machines with
   radix point at extreme right of significand
                                                                    }
   i := maxexp + minexp ;
   if ( ( ibeta = 2 ) and ( i = 0 ) ) then maxexp := maxexp - 1 ;
   if ( i > 20 ) then maxexp := maxexp - 3 ;
   xmax := one - epsneg ;
   if ( xmax * one <> xmax ) then xmax := one - beta * epsneg ;
   xmax := ( xmax * betain * betain * betain ) / xmin ;
   i := maxexp + minexp + 3 ;
   if  ( i > 0 ) then begin

      for j := 1 to i do begin
         xmax := xmax * beta ;
      end ;
   end;

end;

begin
  trapped:=false;
  encaps(work,catch);
end;
Header --> Id 1994-06-24 14:02:31 +00:00			`{ $Id$ }`
added rcsid 1984-07-12 14:07:14 +00:00
Initial revision 1984-07-12 13:50:44 +00:00			`procedure machar (var ibeta , it , irnd , ngrd , machep , negep , iexp,`
			`minexp , maxexp : integer ; var eps , epsneg , xmin , xmax : real ) ;`
			`var trapped:boolean;`

			`procedure encaps(procedure p; procedure q(i:integer)); extern;`
			`procedure trap(i:integer); extern;`

			`procedure catch(i:integer);`
			`const underflo=5;`
			`begin if i=underflo then trapped:=true else trap(i) end;`

			`procedure work;`
			`var`


			`{ This subroutine is intended to determine the characteristics`
			`of the floating-point arithmetic system that are specified`
			`below. The first three are determined according to an`
			`algorithm due to M. Malcolm, CACM 15 (1972), pp. 949-951,`
			`incorporating some, but not all, of the improvements`
			`suggested by M. Gentleman and S. Marovich, CACM 17 (1974),`
			`pp. 276-277. The version given here is for single precision.`

			`Latest revision - October 1, 1976.`

			`Author - W. J. Cody`
			`Argonne National Laboratory`

			`Revised for Pascal - R. A. Freak`
			`University of Tasmania`
			`Hobart`
			`Tasmania`

			`ibeta is the radix of the floating-point representation`
			`it is the number of base ibeta digits in the floating-point`
			`significand`
			`irnd = 0 if the arithmetic chops,`
			`1 if the arithmetic rounds`
			`ngrd = 0 if irnd=1, or if irnd=0 and only it base ibeta`
			`digits participate in the post normalization shift`
			`of the floating-point significand in multiplication`
			`1 if irnd=0 and more than it base ibeta digits`
			`participate in the post normalization shift of the`
			`floating-point significand in multiplication`
			`machep is the exponent on the smallest positive floating-point`
			`number eps such that 1.0+eps <> 1.0`
			`negeps is the exponent on the smallest positive fl. pt. no.`
			`negeps such that 1.0-negeps <> 1.0, except that`
			`negeps is bounded below by it-3`
			`iexp is the number of bits (decimal places if ibeta = 10)`
			`reserved for the representation of the exponent of`
			`a floating-point number`
			`minexp is the exponent of the smallest positive fl. pt. no.`
			`xmin`
			`maxexp is the exponent of the largest finite floating-point`
			`number xmax`
			`eps is the smallest positive floating-point number such`
			`that 1.0+eps <> 1.0. in particular,`
			`eps = ibeta**machep`
			`epsneg is the smallest positive floating-point number such`
			`that 1.0-eps <> 1.0 (except that the exponent`
			`negeps is bounded below by it-3). in particular`
			`epsneg = ibeta**negep`
			`xmin is the smallest positive floating-point number. in`
			`particular, xmin = ibeta ** minexp`
			`xmax is the largest finite floating-point number. in`
			`particular xmax = (1.0-epsneg) * ibeta ** maxexp`
			`note - on some machines xmax will be only the`
			`second, or perhaps third, largest number, being`
			`too small by 1 or 2 units in the last digit of`
			`the significand.`

			`}`

			`i , iz , j , k , mx : integer ;`
			`a , b , beta , betain , betam1 , one , y , z , zero : real ;`

			`begin`
			`irnd := 1 ;`
			`one := ( irnd );`
			`a := one + one ;`
			`b := a ;`
			`zero := 0.0 ;`
			`{`
			`determine ibeta,beta ala Malcolm`
			`}`
			`while ( ( ( a + one ) - a ) - one = zero ) do begin`
			`a := a + a ;`
			`end ;`
			`while ( ( a + b ) - a = zero ) do begin`
			`b := b + b ;`
			`end ;`
			`ibeta := trunc ( ( a + b ) - a );`
			`beta := ( ibeta );`
			`betam1 := beta - one ;`
			`{`
			`determine irnd,ngrd,it`
			`}`
			`if ( ( a + betam1 ) - a = zero ) then irnd := 0 ;`
			`it := 0 ;`
			`a := one ;`
			`repeat begin`
			`it := it + 1 ;`
			`a := a * beta ;`
			`end until ( ( ( a + one ) - a ) - one <> zero ) ;`
			`{`
			`determine negep, epsneg`
			`}`
			`negep := it + 3 ;`
			`a := one ;`

			`for i := 1 to negep do begin`
			`a := a / beta ;`
			`end ;`

			`while ( ( one - a ) - one = zero ) do begin`
			`a := a * beta ;`
			`negep := negep - 1 ;`
			`end ;`
			`negep := - negep ;`
			`epsneg := a ;`
			`{`
			`determine machep, eps`
			`}`
			`machep := negep ;`
			`while ( ( one + a ) - one = zero ) do begin`
			`a := a * beta ;`
			`machep := machep + 1 ;`
			`end ;`
			`eps := a ;`
			`{`
			`determine ngrd`
			`}`
			`ngrd := 0 ;`
			`if(( irnd = 0) and((( one + eps) * one - one) <> zero)) then`
			`ngrd := 1 ;`
			`{`
			`determine iexp, minexp, xmin`

			`loop to determine largest i such that`
			`(1/beta) (2(i))`
			`does not underflow`
			`exit from loop is signall by an underflow`
			`}`
			`i := 0 ;`
			`betain := one / beta ;`
			`z := betain ;`
			`trapped:=false;`
			`repeat begin`
			`y := z ;`
			`z := y * y ;`
			`{`
			`check for underflow`
			`}`
			`i := i + 1 ;`
			`end until trapped;`
			`i := i - 1;`
			`k := 1 ;`
			`{`
			`determine k such that (1/beta)**k does not underflow`

			`first set k = 2 ** i`
			`}`

			`for j := 1 to i do begin`
			`k := k + k ;`
			`end ;`

			`iexp := i + 1 ;`
			`mx := k + k ;`
			`if ( ibeta = 10 ) then begin`
			`{`
			`for decimal machines only }`
			`iexp := 2 ;`
			`iz := ibeta ;`
			`while ( k >= iz ) do begin`
			`iz := iz * ibeta ;`
			`iexp := iexp + 1 ;`
			`end ;`
			`mx := iz + iz - 1 ;`
			`end;`
			`trapped:=false;`
			`repeat begin`
			`{`
			`loop to construct xmin`
			`exit from loop is signalled by an underflow`
			`}`
			`xmin := y ;`
			`y := y * betain ;`
			`k := k + 1 ;`
			`end until trapped;`
			`k := k - 1;`
			`minexp := - k ;`
			`{ determine maxexp, xmax`
			`}`
			`if ( ( mx <= k + k - 3 ) and ( ibeta <> 10 ) ) then begin`
			`mx := mx + mx ;`
			`iexp := iexp + 1 ;`
			`end;`
			`maxexp := mx + minexp ;`
			`{ adjust for machines with implicit leading`
			`bit in binary significand and machines with`
			`radix point at extreme right of significand`
			`}`
			`i := maxexp + minexp ;`
			`if ( ( ibeta = 2 ) and ( i = 0 ) ) then maxexp := maxexp - 1 ;`
			`if ( i > 20 ) then maxexp := maxexp - 3 ;`
			`xmax := one - epsneg ;`
			`if ( xmax * one <> xmax ) then xmax := one - beta * epsneg ;`
			`xmax := ( xmax * betain * betain * betain ) / xmin ;`
			`i := maxexp + minexp + 3 ;`
			`if ( i > 0 ) then begin`

			`for j := 1 to i do begin`
			`xmax := xmax * beta ;`
			`end ;`
			`end;`

			`end;`

			`begin`
			`trapped:=false;`
			`encaps(work,catch);`
			`end;`