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+@code{(require 'modular)}
+@ftindex modular
+
+
+@defun mod x1 x2
+@defunx rem x1 x2
+
+These procedures implement the Common-Lisp functions of the same names.
+The real number @var{x2} must be non-zero.
+@code{mod} returns @code{(- @var{x1} (* @var{x2} (floor (/ @var{x1} @var{x2}))))}.
+@code{rem} returns @code{(- @var{x1} (* @var{x2} (truncate (/ @var{x1} @var{x2}))))}.
+
+If @var{x1} and @var{x2} are integers, then @code{mod} behaves like
+@code{modulo} and @code{rem} behaves like @code{remainder}.
+
+@format
+@t{(mod -90 360)                          @result{} 270
+(rem -90 180)                          @result{} -90
+
+(mod 540 360)                          @result{} 180
+(rem 540 360)                          @result{} 180
+
+(mod (* 5/2 pi) (* 2 pi))              @result{} 1.5707963267948965
+(rem (* -5/2 pi) (* 2 pi))             @result{} -1.5707963267948965
+}
+@end format
+@end defun
+
+@defun extended-euclid n1 n2
+
+Returns a list of 3 integers @code{(d x y)} such that d = gcd(@var{n1},
+@var{n2}) = @var{n1} * x + @var{n2} * y.
+@end defun
+
+@defun symmetric:modulus n
+
+Returns @code{(quotient (+ -1 n) -2)} for positive odd integer @var{n}.
+@end defun
+
+@defun modulus->integer modulus
+
+Returns the non-negative integer characteristic of the ring formed when
+@var{modulus} is used with @code{modular:} procedures.
+@end defun
+
+@defun modular:normalize modulus n
+
+Returns the integer @code{(modulo @var{n} (modulus->integer
+@var{modulus}))} in the representation specified by @var{modulus}.
+@end defun
+@noindent
+The rest of these functions assume normalized arguments; That is, the
+arguments are constrained by the following table:
+
+@noindent
+For all of these functions, if the first argument (@var{modulus}) is:
+@table @code
+@item positive?
+Work as before.  The result is between 0 and @var{modulus}.
+
+@item zero?
+The arguments are treated as integers.  An integer is returned.
+
+@item negative?
+The arguments and result are treated as members of the integers modulo
+@code{(+ 1 (* -2 @var{modulus}))}, but with @dfn{symmetric}
+@cindex symmetric
+representation; i.e. @code{(<= (- @var{modulus}) @var{n}
+@var{modulus})}.
+@end table
+
+@noindent
+If all the arguments are fixnums the computation will use only fixnums.
+
+
+@defun modular:invertable? modulus k
+
+Returns @code{#t} if there exists an integer n such that @var{k} * n
+@equiv{} 1 mod @var{modulus}, and @code{#f} otherwise.
+@end defun
+
+@defun modular:invert modulus n2
+
+Returns an integer n such that 1 = (n * @var{n2}) mod @var{modulus}.  If
+@var{n2} has no inverse mod @var{modulus} an error is signaled.
+@end defun
+
+@defun modular:negate modulus n2
+
+Returns (@minus{}@var{n2}) mod @var{modulus}.
+@end defun
+
+@defun modular:+ modulus n2 n3
+
+Returns (@var{n2} + @var{n3}) mod @var{modulus}.
+@end defun
+
+@defun modular:- modulus n2 n3
+
+Returns (@var{n2} @minus{} @var{n3}) mod @var{modulus}.
+@end defun
+
+@defun modular:* modulus n2 n3
+
+Returns (@var{n2} * @var{n3}) mod @var{modulus}.
+
+The Scheme code for @code{modular:*} with negative @var{modulus} is
+not completed for fixnum-only implementations.
+@end defun
+
+@defun modular:expt modulus n2 n3
+
+Returns (@var{n2} ^ @var{n3}) mod @var{modulus}.
+@end defun