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# Manual Reference Pages  -  MATH::GMPQ (3)

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### NAME

```

Math::GMPq - perl interface to the GMP librarys rational (mpq) functions.

```

### DEPENDENCIES

```

This module needs the GMP C library - available from:
http://gmplib.org.

```

### DESCRIPTION

```

A bigrational module utilising the Gnu MP (GMP) library.
Basically this module simply wraps all of the mpq
(rational number) functions provided by that library.
The documentation below extensively plagiarises the GMP
documentation (which can be found at http://gmplib.org).
See also the Math::GMPq test suite for examples of usage.

IMPORTANT:
If your perl was built with -Duse64bitint you need to assign
all integers larger than 52-bit in a use integer; block.
Failure to do so can result in the creation of the variable as
an NV (rather than an IV) - with a resultant loss of precision.

```

### SYNOPSIS

```

use Math::GMPq qw(:mpq);

my \$str = 123542/4; # numerator = 123542
# denominator = 4
my \$base = 10;

# Create the Math::GMPq object
my \$bn1 = Rmpq_init(); # Value set to 0/1

# Assign a value.
Rmpq_set_str(\$str, \$base);

# Remove any factors common to both numerator and
# denominator so that gcd(numerator, denominator) == 1.
Rmpq_canonicalize(\$bn1);

# or just use the new() function:
my \$rational = Math::GMPq->new(1234/1179);

# Perform some operations, either by using function calls
# or by utilising operator overloading ... see FUNCTIONS
# below.

.
.

# print out the value held by \$bn1 (in octal):
print Rmpq_get_str(\$bn1, 8), "\n"; # prints 170513/2

# print out the value held by \$bn1 (in decimal) with:
print Rmpq_get_str(\$bn1, 10), "\n"; # prints 61771/2.
# or, courtesy of operator loading, simply with:
print \$bn1, "\n"; # again prints 61771/2.

# print out the value held by \$bn1 (in base 29)
# using the (alternative) Rmpq_out_str()
# function. (This function doesnt print a newline.)
Rmpq_out_str(\$bn1, 29);

```

### MEMORY MANAGEMENT

```

Objects created with Rmpq_create_init() have been
blessed into package Math::GMPq. They will
therefore be automatically cleaned up by the
DESTROY() function whenever they go out of scope.

If you wish, you can create unblessed objects
with Rmpq_init_nobless().
It will then be up to you to clean up the memory
associated with these objects by calling
Rmpq_clear(\$op), for each object.
Alternatively the objects will be cleaned up
when the script ends.
I dont know why you would want to create unblessed
objects - the point is you can if you want to :-)

```

### FUNCTIONS

```

See the GMP documentation at http://gmplib.org.

These next 3 functions are demonstrated above:
\$rop   = Rmpq_init();
\$rop   = Rmpq_set_strl(\$str, \$base); # 1 < \$base < 63
\$str = Rmpq_get_str(\$op, \$base); # 1 < \$base < 37

The following functions are simply wrappers around a GMP
function of the same name. eg. Rmpq_swap() is a wrapper around
mpq_swap() which is fully documented in the GMP manual at
http://gmplib.org.

"\$rop", "\$op1", "\$op2", etc. are simply  Math::GMPq objects -
the return value of Rmpq_init or Rmpq_init_nobless
functions. They are in fact references to GMP structures.
The "\$rop" argument(s) contain the result(s) of the calculation
being done, the "\$op" argument(s) being the input(s) into that
calculation.
Generally, \$rop, \$op1, \$op2, etc. can be the same perl variable,
though usually they will be distinct perl variables referencing
distinct GMP structures.
Eg. something like Rmpq_add(\$r1, \$r1, \$r1),
where \$r1 *is* the same reference to the same GMP structure,
would add \$r1 to itself and store the result in \$r1. Think of it
as \$r1 += \$r1. Otoh, Rmpq_add(\$r1, \$r2, \$r3), where each of the
arguments is a different reference to a different GMP structure
would add \$r2 to \$r3 and store the result in \$r1. Think of it as
\$r1 = \$r2 + \$r3. Mostly, the first argument is the argument that
stores the result and subsequent arguments provide the input values.
Exceptions to this can be found in some of the functions that
actually return a value.
Like I say, see the GMP manual for details. I hope its
intuitively obvious or quickly becomes so. Also see the test
suite that comes with the distro for some examples of usage.

"\$ui" means any integer that will fit into a C unsigned long int.

"\$si" means any integer that will fit into a C signed long int.

"\$double" means any number (not necessarily integer) that will fit
into a C double.

"\$bool" means a value (usually a signed long int) in which
the only interest is whether it evaluates as true or false.

"\$str" simply means a string of symbols that represent a number,
eg "1234567890987654321234567/7".
Valid bases for GMP numbers are 2 to 62 (inclusive).

############

CANONICALIZE

Rmpq_canonicalize(\$op);
Remove any factors that are common to the numerator and
denominator of \$op, and make the denominator positive.

##########

INITIALIZE

Normally, a variable should be initialized once only or at least be
cleared, using `Rmpq_clear, between initializations.
DESTROY (which calls Rmpq_clear) is automatically called on
blessed objects whenever they go out of scope.

See the section MEMORY MANAGEMENT (above).

\$rop = Math::GMPq::new();
\$rop = Math::GMPq->new();
\$rop = new Math::GMPq();
\$rop = Rmpq_init();
\$rop = Rmpq_init_nobless();
Initialize \$rop and set it to 0/1.

####################

ASSIGNMENT FUNCTIONS

Rmpq_set(\$rop, \$op);
Rmpq_set_z(\$rop, \$z); # \$z is a Math::GMPz object
Set \$rop to value contained in 2nd arg.

Rmpq_set_ui(\$rop, \$ui1, \$ui2);
Rmpq_set_si(\$rop, \$si1, \$si2);
Set \$rop to 2nd arg / 3rd arg.

Rmpq_set_str(\$rop, \$str, \$base);
Set \$rop from \$str in the given base \$base. The string can be
an integer like "41" or a fraction like "41/152".  The fraction
must be in canonical form, or if not then `Rmpq_canonicalize
must be called. The numerator and optional denominator are
parsed the same as in `Rmpz_set_str. \$base can vary from 2 to
62, or if \$base is 0 then the leading characters are used: `0x
for hex, `0 for octal, or decimal otherwise.  Note that this
is done separately for the numerator and denominator, so for
instance `0xEF/100 is 239/100, whereas `0xEF/0x100 is 239/256.

Rmpq_swap(\$rop1, \$rop2);
Swap the values.

####################

COMBINED INITIALIZATION AND ASSIGNMENT

NOTE: Do NOT use these functions if \$rop has already
been initialised. Instead use the Rmpq_set* functions
in Assignment Functions (above)

First read the section MEMORY MANAGEMENT (above).

\$rop = Math::GMPq->new(\$arg);
\$rop = Math::GMPq::new(\$arg);
\$rop = new Math::GMPq(\$arg);
Returns a Math::GMPq object with the value of \$arg.
\$arg can be either an integer (signed integer, unsigned
integer) or a string that represents a numeric value. If \$arg is a
string, an optional additional argument that specifies the base of
the number can be supplied to new(). If base is 0 (or not supplied)
then the leading characters of the string are used: 0x or 0X for
hex, 0b or 0B for binary, 0 for octal, or decimal otherwise. Note
that this is done separately for the numerator and denominator, so
for instance 0xEF/100 is 239/100, whereas 0xEF/0x100 is 239/256.
Legal values for the base are 0 and 2..62.

####################

RATIONAL CONVERSIONS

\$double = Rmpq_get_d(\$op);
Convert \$op to a double.

Rmpq_set_d(\$rop, \$double);
Rmpq_set_f(\$rop, \$f); # \$f is a Math::GnumMPf object
Set \$rop to the value of the 2nd arg, without rounding.

\$str = Rmpq_get_str(\$op, \$base);
Convert \$op to a string of digits in base \$base. The base may
vary from 2 to 36.  The string will be of the form `num/den,
or if the denominator is 1 then just `num.

###################

RATIONAL ARITHMETIC

Rmpq_add(\$rop, \$op1, \$op2);
\$rop = \$op1 + \$op2.

Rmpq_sub(\$rop, \$op1, \$op2);
\$rop = \$op1 - \$op2.

Rmpq_mul(\$rop, \$op1, \$op2);
\$rop = \$op1 * \$op2.

Rmpq_mul_2exp(\$rop, \$op, \$ui);
\$rop = \$op * (2 ** \$ui).

Rmpq_div(\$rop, \$op1, \$op2);
\$rop = \$op1 / \$op2.

Rmpq_div_2exp(\$rop, \$op, \$ui);
\$rop = \$op / (2 ** \$ui).

Rmpq_neg(\$rop, \$op);
\$rop = -\$op.

Rmpq_abs(\$rop, \$op);
\$rop = abs(\$op).

Rmpq_inv(\$rop, \$op);
\$rop = 1 / \$op.

##########################

APPLYING INTEGER FUNCTIONS

Rmpq_numref(\$z, \$op); # \$z is a Math::GMPz object
Rmpq_denref(\$z, \$op); # \$z is a Math::GMPz object
Set \$rop to the numerator and denominator of \$op, respectively.

Rmpq_get_num(\$z, \$op); # \$z is a Math::GMPz oblect
Rmpq_get_den(\$z, \$op); # \$z is a Math::GMPz oblect
Rmpq_set_num(\$rop, \$z); # \$z is a Math::GMPz oblect
Rmpq_set_den(\$rop, \$z); # \$z is a Math::GMPz oblect
Get or set the numerator or denominator of a rational
Direct use of `Rmpq_numref or `Rmpq_denref is
recommended instead of these functions.

###################

COMPARING RATIONALS

\$si = Rmpq_cmp(\$op1, \$op2);
Compare \$op1 and \$op2.  Return a positive value if \$op1 > \$op2,
zero if \$op1 = \$op2, and a negative value if \$op1 < \$op2.
To determine if two rationals are equal, `Rmpq_equal is
faster than `Rmpq_cmp.

\$si = Rmpq_cmp_ui(\$op, \$ui, \$ui);
\$si1 = Rmpq_cmp_si(\$op, \$si2, \$ui);
Compare \$op1 and 2nd arg/3rd arg.  Return a positive value if
\$op1 > 2nd arg/3rd arg, zero if \$op1 = 2nd arg/3rd arg,
and a negative value if \$op1 < 2nd arg/3rd arg.
2nd and 3rd args are allowed to have common factors.
Note that the 3rd (NOT 2nd) arg is unsigned. If you want
to compare \$op with 2/-3, make sure that 2nd arg is
-2 and 3rd arg is 3.

\$si = Rmpq_sgn(\$op);
Return +1 if \$op>0, 0 if \$op=0, and -1 if \$op<0.

\$bool = Rmpq_equal(\$op1, \$op2); # faster than Rmpq_cmp()
Return non-zero if \$op1 and \$op2 are equal, zero if they
are non-equal.  Although `Rmpq_cmp can be used for the
same purpose, this function is much faster.

\$si = Rmpq_cmp_z(\$op, \$z);# \$z is Math::GMPz or Math::GMP object
Return a positive value if \$op > \$z.
Return zero if \$op == \$z.
Return a negative value if \$op < \$z.

################

I/O of RATIONALS

\$bytes_written = Rmpq_out_str([\$prefix,] \$op, \$base [, \$suffix]);
BEST TO USE TRmpq_out_str INSTEAD.
Output \$op to STDOUT, as a string of digits in base \$base.
The base may vary from 2 to 36. Output is in the form `num/den
or if the denominator is 1 then just `num. Return the number
of bytes written, or if an error occurred, return 0.
The optional first and last arguments (\$prefix and \$suffix) are
strings that will be prepended/appended to the mpq_out_str
output.  \$bytes_written does not include the bytes contained in
\$prefix and \$suffix.

\$bytes_written = TRmpq_out_str([\$prefix,] \$stream, \$base, \$op, [, \$suffix]);
As for Rmpq_out_str, except that theres the capability to print
to somewhere other than STDOUT. Note that the order of the args
is different (to match the order of the mpq_out_str args).
To print to STDERR:
TRmpq_out_str(*stderr, \$base, \$digits, \$op);
To print to an open filehandle (lets call it FH):
TRmpq_out_str(\*FH, \$base, \$digits, \$op);

\$bytes_read = Rmpq_inp_str(\$rop, \$base);
BEST TO USE TRmpq_inp_str INSTEAD.
Read a string of digits from STDIN and convert them to a rational
in \$rop.  Any initial white-space characters are read and
discarded.  Return the number of characters read (including white
space), or 0 if a rational could not be read.
The input can be a fraction like `17/63 or just an integer like
`123.  Reading stops at the first character not in this form, and
white space is not permitted within the string.  If the input
might not be in canonical form, then `mpq_canonicalize must be
called. \$base can be between 2 and 36, or can be 0 in which case the
leading characters of the string determine the base, `0x or `0X
for hexadecimal, `0 for octal, or decimal otherwise.  The leading
characters are examined separately for the numerator and
denominator of a fraction, so for instance `0x10/11 is 16/11,
whereas `0x10/0x11 is 16/17.

\$bytes_read = TRmpq_inp_str(\$rop, \$stream, \$base);
As for Rmpq_inp_str, except that theres the capability to read
from somewhere other than STDIN.
To read from STDIN:
TRmpq_inp_str(\$rop, *stdin, \$base);
To read from an open filehandle (lets call it FH):
TRmpq_inp_str(\$rop, \*FH, \$base);

#######################

RANDOM NUMBER FUNCTIONS

\$state = qgmp_randinit_default();
This is the Math::GMPq interface to the gmp library function
gmp_randinit_default.
\$state is blessed into package Math::GMPq::Random and will be
automatically cleaned up when it goes out of scope.
Initialize \$state with a default algorithm. This will be a
compromise between speed and randomness, and is recommended for
applications with no special requirements. Currently this is
the gmp_randinit_mt function (Mersenne Twister algorithm).

\$state = qgmp_randinit_mt();
This is the Math::GMPq interface to the gmp library function
gmp_randinit_mt.
Currently identical to fgmp_randinit_default().

\$state = qgmp_randinit_lc_2exp(\$mpz, \$ui, \$m2exp);
This is the Math::GMPq interface to the gmp library function
gmp_randinit_lc_2exp. \$mpz is a Math::GMP or Math::GMPz object,
so one of those modules is required in order to make use of this
function.
\$state is blessed into package Math::GMPq::Random and will be
automatically cleaned up when it goes out of scope.
Initialize \$state with a linear congruential algorithm
X = (\$mpz*X + \$ui) mod (2 ** \$m2exp). The low bits of X in this
algorithm are not very random. The least significant bit will have a
period no more than 2, and the second bit no more than 4, etc. For
this reason only the high half of each X is actually used.
When a random number of more than m2exp/2 bits is to be generated,
multiple iterations of the recurrence are used and the results
concatenated.

\$state = qgmp_randinit_lc_2exp_size(\$ui);
This is the Math::GMPq interface to the gmp library function
gmp_randinit_lc_2exp_size.
\$state is blessed into package Math::GMPf::Random and will be
automatically cleaned up when it goes out of scope.
Initialize state for a linear congruential algorithm as per
gmp_randinit_lc_2exp. a, c and m2exp are selected from a table,
chosen so that \$ui bits (or more) of each X will be used,
ie. m2exp/2 >= \$ui.
If \$ui is bigger than the table data provides then the function fails
and dies with an appropriate error message. The maximum value for \$ui
currently supported is 128.

\$state2 = qgmp_randinit_set(\$state1);
This is the Math::GMPq interface to the gmp library function
gmp_randinit_set.
\$state2 is blessed into package Math::GMPf::Random and will be
automatically cleaned up when it goes out of scope.
Initialize \$state2 with a copy of the algorithm and state from
\$state1.

\$state = qgmp_randinit_default_nobless();
\$state = qgmp_randinit_mt_nobless();
\$state = qgmp_randinit_lc_2exp_nobless(\$mpz, \$ui, \$m2exp);
\$state2 = qgmp_randinit_set_nobless(\$state1);
As for the above comparable function, but \$state is not blessed into
any package. (Generally not useful - but theyre available if you
want them.)

qgmp_randseed(\$state, \$mpz); # \$mpz is a Math::GMPz or Math::GMP object
qgmp_randseed_ui(\$state, \$ui);
These are the Math::GMPz interfaces to the gmp library functions
gmp_randseed and gmp_randseed_ui.
Seed an initialised (but not yet seeded) \$state with \$mpz/\$ui.
Either Math::GMP or Math::GMPz is required for gmp_randseed.

\$ui = qgmp_urandomb_ui(\$state, \$bits);
This is the Math::GMPq interface to the gmp library function
gmp_urandomb_ui.
Return a uniformly distributed random number of \$bits bits, ie. in
the range 0 to 2 ** (\$bits - 1) inclusive. \$bits must be less than or
equal to the number of bits in an unsigned long.

\$ui2 = qgmp_urandomm_ui(\$state, \$ui1);
This is the Math::GMPq interface to the gmp library function
gmp_urandomm_ui.
Return a uniformly distributed random number in the range 0 to
\$ui1 - 1, inclusive.

qgmp_randclear(\$state);
Destroys \$state, as also does Math::GMPq::Random::DESTROY - two
identical functions.
Use only if \$state is an unblessed object - ie if it was initialised
using one of the qgmp_randinit*_nobless functions.

####################

OPERATOR OVERLOADING

Overloading occurs with numbers, strings,Math::GMPq objects and, to a
limited extent, Math::GMP or Math::GMPz objects (iff the gmp library is
version 6.1.0 or later) and Math::MPFR objects (iff version 3.13 or
later of Math::MPFR has been installed).
Strings are first converted to Math::GMPq objects, then canonicalized.
See the Rmpq_set_str documentation (above) in the section "ASSIGNMENT
FUNCTIONS" regarding permissible string formats.
The following operators are overloaded:

+ - * /
+= -= *= /= ++ --
== != !
< <= > >= <=>
= "" abs

Atempting to use the overloaded operators with objects that
have been blessed into some package other than Math::GMPq
or Math::MPFR (limited applications) will not work.
Math::MPFR objects can be used only with +, -, *, /
and ** operators, and will work only if Math::MPFR is at
version 3.13 or later - in which case the operation will
return a Math::MPFR object.
Math::GMP or Math::GMPz objects can be used only with the
comparison operators ( == != < <= > >= <=> ), and only if Math::GMPq
has been built against gmp-6.1.0 or later.
In those situations where the overload subroutine operates on 2
perl variables, then obviously one of those perl variables is
a Math::GMPq object. To determine the value of the other variable
the subroutine works through the following steps (in order),
using the first value it finds, or croaking if it gets
to step 6:

1. If the variable is an unsigned long then that value is used.
The variable is considered to be an unsigned long if
(perl 5.8 and later) the UOK flag is set or if (perl 5.6)
SvIsUV() returns true.

2. If the variable is a signed long int, then that value is used.
The variable is considered to be a signed long int if the
IOK flag is set. (In the case of perls built with
-Duse64bitint, the variable is treated as a signed long long
int if the IOK flag is set.)

3. If the variable is a double, then that value is used. The
variable is considered to be a double if the NOK flag is set.

4. If the variable is a string (ie the POK flag is set) then the
value of that string is used. Octal strings must begin with
0, hex strings must begin with either 0x or 0X -
otherwise the string is assumed to be decimal. If the POK
flag is set, but the string is not a valid base 8, 10, or 16
number, the subroutine croaks with an appropriate error
message. If the string is of the form numerator/denominator,
then the bases of the numerator and the denominator are
assessed individually. ie 0xa123/ff is not a valid number
(because ff is not a valid base 10 number). That needs to
be rewritten as 0xa123/0xff.

5. If the variable is a Math::GMPq object (or, for operators
specified above, a Math::MPFR/Math::GMP/Math::GMPz object)
then the value of that object is used.

6. If none of the above is true, then the second variable is
deemed to be of an invalid type. The subroutine croaks with
an appropriate error message.

##############

MISCELLANEOUS

\$bool = Rmpq_integer_p(\$op);
Returns true if \$op is an integer (ie denominator of \$op is 1).
Else returns false. The mpq_integer_p function is not
implemented in gmp.

#####

OTHER

\$GMP_version = Math::GMPq::gmp_v;
Returns the version of the GMP library (eg 4.1.3) being used by
Math::GMPq. The function is not exportable.

\$GMP_cc = Math::GMPq::__GMP_CC;
\$GMP_cflags = Math::GMPq::__GMP_CFLAGS;
If Math::GMPq has been built against gmp-4.2.3 or later,
returns respectively the CC and CFLAGS settings that were used
to compile the gmp library against which Math::GMPq was built.
(Values are as specified in the gmp.h that was used to build
Math::GMPq.)
Returns undef if Math::GMPq has been built against an earlier
version of the gmp library.
(These functions are in @EXPORT_OK and are therefore exportable
by request. They are not listed under the ":mpq" tag.)

\$major = Math::GMPq::__GNU_MP_VERSION;
\$minor = Math::GMPq::__GNU_MP_VERSION_MINOR;
\$patchlevel = Math::GMPq::__GNU_MP_VERSION_PATCHLEVEL;
Returns respectively the major, minor, and patchlevel numbers
for the GMP library version used to build Math::GMPq. Values are
as specified in the gmp.h that was used to build Math::GMPq.
(These functions are in @EXPORT_OK and are therefore exportable
by request. They are not listed under the ":mpq" tag.)

################

FORMATTED OUTPUT

NOTE: The format specification can be found at:
http://gmplib.org/manual/Formatted-Output-Strings.html#Formatted-Output-Strings
However, the use of * to take an extra variable for width and
precision is not allowed in this implementation. Instead, it is
necessary to interpolate the variable into the format string - ie,
instead of:
Rmpq_printf("%*Zd\n", \$width, \$mpz);
we need:
Rmpq_printf("%\${width}Zd\n", \$mpz);

\$si = Rmpq_printf(\$format_string, \$var);

This function changed with the release of Math-GMPq-0.27.
Now (unlike the GMP counterpart), it is limited to taking 2
arguments - the format string, and the variable to be formatted.
That is, you can format only one variable at a time.
If there is no variable to be formatted, then the final arg
can be omitted - a suitable dummy arg will be passed to the XS
code for you. ie the following will work:
Rmpq_printf("hello world\n");
Returns the number of characters written, or -1 if an error
occurred.

\$si = Rmpq_fprintf(\$fh, \$format_string, \$var);

This function (unlike the GMP counterpart) is limited to taking
3 arguments - the filehandle, the format string, the variable
to be formatted. That is, you can format only one variable at a time.
If there is no variable to be formatted, then the final arg
can be omitted - a suitable dummy arg will be passed to the XS
code for you. ie the following will work:
Rmpq_fprintf(\$fh, "hello world\n");
Other than that, the rules outlined above wrt Rmpq_printf apply.
Returns the number of characters written, or -1 if an error
occurred.

\$si = Rmpq_sprintf(\$buffer, \$format_string, \$var, \$buflen);

This function (unlike the GMP counterpart) is limited to taking
4 arguments - the buffer, the format string,  the variable to be
formatted and the size of the buffer. If there is no variable to
be formatted, then the third arg can be omitted - a suitable
dummy arg will be passed to the XS code for you. ie the following
will work:
Rmpf_sprintf(\$buffer, "hello world", 12);
\$buffer must be large enough to accommodate the formatted string.
The formatted string is placed in \$buffer.
Returns the number of characters written, or -1 if an error
occurred.

\$si = Rmpq_snprintf(\$buffer, \$bytes, \$format_string, \$var, \$buflen);

Form a null-terminated string in \$buffer. No more than \$bytes
bytes will be written. To get the full output, \$bytes must be
enough for the string and null-terminator. \$buffer must be large
enough to accommodate the string and null-terminator, and is
truncated to the length of that string (and null-terminator).
The return value is the total number of characters which ought
to have been produced, excluding the terminating null.
If \$si >= \$bytes then the actual output has been truncated to
the first \$bytes-1 characters, and a null appended.
This function (unlike the GMP counterpart) is limited to taking
5 arguments - the buffer, the maximum number of bytes to be
returned, the format string, the variable to be formatted and
the size of the buffer.
If there is no variable to be formatted, then the 4th arg can
be omitted - a suitable dummy arg will be passed to the XS code
for you. ie the following will work:
Rmpf_snprintf(\$buffer, 6, "hello world", 12);

################
################

```

### BUGS

```

You can get segfaults if you pass the wrong type of
argument to the functions - so if you get a segfault, the
first thing to do is to check that the argument types
you have supplied are appropriate.

```

### LICENSE

```

This program is free software; you may redistribute it and/or
modify it under the same terms as Perl itself.
Copyright 2006-2011, 2013-16, Sisyphus

```

### AUTHOR

```

Sisyphus <sisyphus at(@) cpan dot (.) org>

```
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