Pari(3) User Contributed Perl Documentation Pari(3)NAMEMath::Pari - Perl interface to PARI.
SYNOPSIS
use Math::Pari;
$a = PARI 2;
print $a**10000;
or
use Math::Pariqw(Mod);
$a = Mod(3,5);
print $a**10000;
DESCRIPTION
This package is a Perl interface to famous library PARI for
numerical/scientific/number-theoretic calculations. It allows use of
most PARI functions as Perl functions, and (almost) seamless merging of
PARI and Perl data. In what follows we suppose prior knowledge of what
PARI is (see ftp://megrez.math.u-bordeaux.fr/pub/pari
<ftp://megrez.math.u-bordeaux.fr/pub/pari>, or Math::libPARI).
EXPORTed functions
DEFAULT
By default the package exports functions PARI(), PARIcol(),
PARIvar(), PARImat() and PARImat_tr() which convert their
argument(s) to a PARI object. (In fact PARI() is just an alias for
"new Math::Pari"). The function PARI() accepts following data as
its arguments
One integer Is converted to a PARI integer.
One float Is converted to a PARI float.
One string Is executed as a PARI expresion (so should not
contain whitespace).
PARI object Is passed unchanged.
Reference to a Perl array
Each element is converted using the same rules,
PARI vector-row with these elements is returned.
Several of above The same as with a reference to array.
Conflicts of rules in PARI()
In deciding what rule of the above to apply the preference is given
to the uppermost choice of those available now. If none matches,
then the string rule is used. So PARI(1) returns integer,
"PARI(1.)" returns float, "PARI("1")" evaluates 1 as a PARI
expression (well, the result is the same as PARI(1), only slower).
Note that for Perl these data are synonimous, since Perl freely
converts between integers, float and strings. However, to PARI()
only what the argument is now is important. If $v is 1 in the Perl
world, "PARI($v)" may convert it to an integer, float, or to the
result of evaluating the PARI program 1 (all depending on how $v
was created and accessed in Perl).
This is a fundamental limitation of creating an interface between
two systems, both with polymorphic objects, but with subtly
different semantic of the flavors of these objects. In reality,
however, this is rarely a problem.
PARIcol(), PARImat() and PARImat_tr()PARIcol() behaves in the same way as PARI() unless given several
arguments. In the latter case it returns a vector-column instead of
a vector-row.
PARImat() constructs a matrix out of the given arguments. It will
work if PARI() will construct a vector of vectors given the same
arguments. The internal vectors become columns of the matrix.
PARImat_tr() behaves similarly, but the internal vectors become
rows of the matrix.
Since PARI matrices are similar to vector-rows of vector-columns,
PARImat() is quickier, but PARImat_tr() better corresponds to the
PARI input and output forms of matrices:
print PARImat [[1,2], [3,4]]; # prints [1,3;2,4]
print PARImat_tr [[1,2], [3,4]]; # prints [1,2;3,4]
"use" with arguments
If arguments are specified in the "use Math::Pari" directive, the
PARI functions appearing as arguments are exported in the caller
context. In this case the function PARI() and friends is not
exported, so if you need them, you should include them into export
list explicitely, or include ":DEFAULT" tag:
use Math::Pari qw(factorint PARI);
use Math::Pari qw(:DEFAULT factorint);
or simply do it in two steps
use Math::Pari;
use Math::Pari 'factorint';
The other tags recognized are ":PARI", ":all", "prec=NUMBER",
number tags (e.g., ":4"), overloaded constants tags (":int",
":float", ":hex") and section names tags. The number tags export
functions from the PARI library from the given class (except for
":PARI", which exports all of the classes). Tag ":all" exports all
of the exportable symbols and ":PARI".
Giving "?" command to "gp" (PARI calculator) lists the following
classes:
1: Standard monadic or dyadic OPERATORS
2: CONVERSIONS and similar elementary functions
3: TRANSCENDENTAL functions
4: NUMBER THEORETICAL functions
5: Functions related to ELLIPTIC CURVES
6: Functions related to general NUMBER FIELDS
7: POLYNOMIALS and power series
8: Vectors, matrices, LINEAR ALGEBRA and sets
9: SUMS, products, integrals and similar functions
10: GRAPHIC functions
11: PROGRAMMING under GP
One can use section names instead of number tags. Recognized names
are
:standard :conversions :transcendental :number :elliptic
:fields :polynomials :vectors :sums :graphic :programming
One can get the list of all of the functions accessible by
"Math::Pari", or the accessible functions from the given section
using listPari() function.
Starting from version 5.005 of Perl, three constant-overload tags
are supported: ":int", ":float", ":hex". If used, all the
integer/float/hex-or-octal-or-binary literals in Perl will be
automatically converted to became PARI objects. For example,
use Math::Pari ':int';
print 2**1000;
is equivalent to
print PARI(2)**PARI(1000);
(The support for this Perl feature is buggy before the Perl version
5.005_57 - unless Perl uses mymalloc options; you can check for
this with "perl -V:usemymalloc".) Note also that (at least with
some versions of Perl) one should enable ':float' for conversion of
long integer literals (Perl may consider them as floats, since they
won't fit into Perl integers); note that it is PARI which
determines which PARI subtype is assigned to each such literal:
use Math::Pari ':float', 'type_name';
print type_name 22222222222222222222222;
prints "t_INT".
Available functions
Directly accessible from Perl
This package supports all the functions from the PARI library with a
signature which can be recognized by Math::Pari. This means that when
you update the PARI library, the newly added functions will we
available without any change to this package; only a recompile is
needed. In fact no recompile will be needed if you link libPARI
dynamically (you need to modify the Makefile manually to do this).
You can "reach" unsupported functions via going directly to PARI parser
using the string flavor of PARI() function, as in
3 + PARI('O(x^17)');
For some "unreachable" functions there is a special wrapper functions,
such as "O(variable,power)").
The following functions are specific to GP calculator, thus are not
available to Math::Pari in any way:
default error extern input print print1 printp printp1
printtex quit read system whatnow write write1 writetex
whatnow() function is useless, since Math::Pari does not support the
"compatibility" mode (with older PARI library). The functionality of
print(), write() and variants is available via automatic string
translation, and pari_print() function and its variants (see "Printout
functions").
default() is the only important function with functionality not
supported by the current interface. Note however, that four most
important default() actions are supported by allocatemem(),
setprimelimit(), setprecision() and setseriesprecision() functions.
(When called without arguments, these functions return the current
values.)
allocatemem($bytes) should not be called from inside Math::Pari
functions (such as forprimes()).
Arguments
Arguments to PARI functions are automatically converted to "long" or a
PARI object depending on the signature of the actual library function.
The arguments are forced into the given type, so even if "gp" rejects
your code similar to
func(2.5); # func() takes a long in C
arguing that a particular argument should be of "type T_INT" (i.e., a
Pari integer), the corresponding code will work in "Math::Pari", since
2.5 is silently converted to "long", per the function signature.
Return values
PARI functions return a PARI object or a Perl's integer depending on
what the actual library function returns.
Additional functions
Some PARI functions are available in "gp" (i.e., in "PARI" calculator)
via infix notation only. In "Math::Pari" these functions are available
in functional notations too. Some other convenience functions are also
made available.
Infix, prefix and postfix operations
are available under names
gneg, gadd, gsub, gmul, gdiv, gdivent, gmod, gpui,
gle, gge, glt, ggt, geq, gne, gegal, gor, gand,
gcmp, gcmp0, gcmp1, gcmp_1.
"gdivent" means euclidean quotient, "gpui" is power, "gegal"
checks whether two objects are equal, "gcmp" is applicable to two
real numbers only, "gcmp0", "gcmp1", "gcmp_1" compare with 0, 1
and -1 correspondingly (see PARI user manual for details, or
Math::libPARI). Note that all these functions are more readily
available via operator overloading, so instead of
gadd(gneg($x), $y)
one can write
-$x+$y
(as far as overloading may be triggered, see overload, so we
assume that at least one of $x or $y is a PARI object).
Conversion functions
pari2iv, pari2nv, pari2num, pari2pv, pari2bool
convert a PARI object to an integer, float, integer/float
(whatever is better), string, and a boolean value correspondingly.
Most the time you do not need these functions due to automatic
conversions.
Printout functions
pari_print, pari_pprint, pari_texprint
perform the same conversions to strings as their PARI
counterparts, but do not print the result. The difference of
pari_print() with pari2pv() is the number of significant digits
they output, and whitespace in the output. pari2pv(), which is
intended for "computer-readable strings", outputs as many digits
as is supported by the current precision of the number; while
pari_print(), which targets human-readable strings, takes into
account the currently specified output precision too.
Constant functions
Some mathematical constants appear as function without arguments
in PARI. These functions are available in Math::Pari too. If you
export them as in
use Math::Pari qw(:DEFAULT Pi I Euler);
they can be used as barewords in your program:
$x = Pi ** Euler;
Low-level functions
For convenience of low-level PARI programmers some low-level
functions are made available as well (all except type_name() and
changevalue() are not exportable):
typ($x)
lg($x)
lgef($x)
lgefint($x)
longword($x, $n)
type_name($x)
changevalue($name,$newvalue)
Here longword($x,$n) returns $n-th word in the memory
representation of $x (including non-code words). type_name()
differs from the PARI function type(): type() returns a PARI
object, while type_name() returns a Perl string. (PARI objects of
string type behave very non-intuitive w.r.t. string comparison
functions; remember that they are compared using lex() to the
results of evaluation of other argument of comparison!)
The function listPari($number) outputs a list of names of PARI
functions in the section $number. Use listPari(-1) to get the
list across all of the sections.
Uncompatible functions
O
Since implementing "O(7**6)" would be very tedious, we provide a
two-argument form "O(7,6)" instead (meaning the same as "O(7^6)"
in PARI). Note that with polynomials there is no problem like
this one, both "O($x,6)" and "O($x**6)" work.
ifact(n)
integer factorial functions, available from "gp" as "n!".
Looping functions
PARI has a big collection of functions which loops over some set. Such
a function takes two special arguments: loop variable, and the code to
execute in the loop.
The code can be either a string (which contains PARI code to execute -
thus should not contain whitespace), or a Perl code reference. The
loop variable can be a string giving the name of PARI variable (as in
fordiv(28, 'j', 'a=a+j+j^2');
or
$j= 'j';
fordiv(28, $j, 'a=a+j+j^2');
), a PARI monomial (as in
$j = PARI 'j';
fordiv(28, $j, sub { $a += $j + $j**2 });
), or a "delayed Math::Pari variable" (as in
$j = PARIvar 'j';
fordiv(28, $j, 'a=a+j+j^2');
). If none of these applies, as in
my $j; # Have this in a separate statement
fordiv(28, $j, sub { $a += $j + $j**2 });
then during the execution of the "sub", Math::Pari would autogenerate a
PARI variable, and would put its value in $j; this value of $j is
temporary only, the old contents of $j is restored when fordiv()
returns.
Note that since you have no control over this name, you will not be
able to use this variable from your PARI code; e.g.,
$j = 7.8;
fordiv(28, $j, 'a=a+j+j^2');
will not make "j" mirror $j (unless you explicitely set up "j" to be a
no-argument PARI function mirroring $j, see "Accessing Perl functions
from PARI code").
Caveats. There are 2 flavors of the "code" arguments (string/"sub"),
and 4 types of the "variable" arguments
(string/monomial/"PARIvar"/other). However, not all 8 combinations
make sense. As we already explained, an "other" variable cannot work
with a "string" code.
Useless musing alert! Do not read the rest of this section! Do not use
"string" variables with "sub" code, and do not ask why!
Additionally, the following code will not do what you expect
$x = 0;
$j = PARI 'j';
fordiv(28, 'j', sub { $x += $j } ); # Use $j as a loop variable!
since the PARI function "fordiv" localizes the PARI variable "j" inside
the loop, but $j will still reference the old value; the old value is a
monomial, not the index of the loop (which is an integer each time
"sub" is called). The simplest workaround is not to use the above
syntax (i.e., not mixing literal loop variable with Perl loop code,
just using $j as the second argument to "fordiv" is enough):
$x = 0;
$j = PARI 'j';
fordiv(28, $j, sub { $x += $j } );
Alternately, one can make a delayed variable $j which will always
reference the same thing "j" references in PARI now by using "PARIvar"
constructor
$x = 0;
$j = PARIvar 'j';
fordiv(28, 'j', sub { $x += $j } );
(This problem is similar to
$ref = \$_; # $$ref is going to be old value even after
# localizing $_ in Perl's grep/map
not accessing localized values of $_ in the plain Perl.)
Another possible quirk is that
fordiv(28, my $j, sub { $a += $j + $j**2 });
will not work too - by a different reason. "my" declarations change
the meaning of $j only after the end of the current statement; thus $j
inside "sub" will access a different variable $j (typically a non-
lexical, global variable $j) than one you declared on this line.
Accessing Perl functions from PARI code
Use the same name inside PARI code:
sub counter { $i += shift; }
$i = 145;
PARI 'k=5' ;
fordiv(28, 'j', 'k=k+counter(j)');
print PARI('k'), "\n";
prints
984
Due to a difference in the semantic of variable-number-of-parameters-
functions between PARI and Perl, if the Perl subroutine takes a
variable number of arguments (via "@" in the prototype or a missing
prototype), up to 6 arguments are supported when this function is
called from PARI. If called from PARI with fewer arguments, the rest
of arguments will be set to be integers "PARI 0".
Note also that no direct import of Perl variables is available yet (but
you can write a function wrapper for this):
sub getv () {$v}
There is an unsupported (and undocumented ;-) function for explicitely
importing Perl functions into PARI, possibly with a different name, and
possibly with explicitely specifying number of arguments.
PARI objects
Functions from PARI library may take as arguments and/or return values
the objects of C type "GEN". In Perl these data are encapsulated into
special kind of Perl variables: PARI objects. You can check for a
variable $obj to be a PARI object using
ref $obj and $obj->isa('Math::Pari');
Most the time you do not need this due to automatic conversions and
overloading.
PARI monomials and Perl barewords
If very lazy, one can code in Perl the same way one does it in PARI.
Variables in PARI are denoted by barewords, as in "x", and in the
default configuration (no warnings, no strict) Perl allows the same -
up to some extent. Do not do this, since there are many surprising
problems.
Some bareletters denote Perl operators, like "q", "x", "y", "s". This
can lead to errors in Perl parsing your expression. E.g.,
print sin(tan(t))-tan(sin(t))-asin(atan(t))+atan(asin(t));
may parse OK after "use Math::Pari qw(sin tan asin atan)". Why?
After importing, the word "sin" will denote the PARI function sin(),
not Perl operator sin(). The difference is subtle: the PARI function
implicitly forces its arguments to be converted PARI objects; it gets
't' as the argument, which is a string, thus is converted to what "t"
denotes in PARI - a monomial. While the Perl operator sin() grants
overloading (i.e., it will call PARI function sin() if the argument is
a PARI object), it does not force its argument; given 't' as argument,
it converts it to what sin() understands, a float (producing 0.), so
will give 0. as the answer.
However
print sin(tan(y))-tan(sin(y))-asin(atan(y))+atan(asin(y));
would not compile. You should avoid lower-case barewords used as PARI
variables, e.g., do
$y = PARI 'y';
print sin(tan($y))-tan(sin($y))-asin(atan($y))+atan(asin($y));
to get
-1/18*y^9+26/4725*y^11-41/1296*y^13+328721/16372125*y^15+O(y^16)
(BTW, it is a very good exercise to get the leading term by hand).
Well, the same advice again: do not use barewords anywhere in your
program!
Overloading and automatic conversion
Whenever an arithmetic operation includes at least one PARI object, the
other arguments are converted to a PARI object and the corresponding
PARI library functions is used to implement the operation. Currently
the following arithmetic operations are overloaded:
unary -
+ - * / % ** abs cos sin exp log sqrt
<< >>
<= == => < > != <=>
le eq ge lt gt ne cmp
| & ^ ~
Numeric comparison operations are converted to "gcmp" and friends,
string comparisons compare in lexicographical order using "lex".
Additionally, whenever a PARI object appears in a situation that
requires integer, numeric, boolean or string data, it is converted to
the corresponding type. Boolean conversion is subject to usual PARI
pitfalls related to imprecise zeros (see documentation of "gcmp0" in
PARI reference).
For details on overloading, see overload.
Note that a check for equality is subject to same pitfalls as in PARI
due to imprecise values. PARI may also refuse to compare data of
different types for equality if it thinks this may lead to
counterintuitive results.
Note also that in PARI the numeric ordering is not defined for some
types of PARI objects. For string comparison operations we use PARI-
lexicographical ordering.
PREREQUISITES
Perl
In the versions of perl earlier than 5.003 overloading used a different
interface, so you may need to convert "use overload" line to %OVERLOAD,
or, better, upgrade.
PARI
Starting from version 2.0, this module comes without a PARI library
included.
For the source of PARI library see
ftp://megrez.math.u-bordeaux.fr/pub/pari <ftp://megrez.math.u-
bordeaux.fr/pub/pari>.
Perl vs. PARI: different syntax
Note that the PARI notations should be used in the string arguments to
PARI() function, while the Perl notations should be used otherwise.
"^" Power is denoted by "**" in Perl.
"\" and "\/"
There are no such operators in Perl, use the word forms
"gdivent(x,y)" and "gdivround(x,y)" instead.
"~" There is no postfix "~" Perl operator. Use mattranspose() instead.
"'" There is no postfix "'" Perl operator. Use deriv() instead.
"!" There is no postfix "!" Perl operator. Use factorial()/ifact()
instead (returning a real or an integer correspondingly).
big integers
Perl converts big literal integers to doubles if they could not be
put into C integers (the particular flavor can be found in the
output of "perl -V" in newer version of Perl, look for
"ivtype"/"ivsize"). If you want to input such an integer, use
while ($x < PARI('12345678901234567890')) ...
instead of
while ($x < 12345678901234567890) ...
Why? Because conversion to double leads to precision loss
(typically above 1e15, see perlnumber), and you will get something
like 12345678901234567168 otherwise.
Starting from version 5.005 of Perl, if the tag ":int" is used on
the 'use Math::Pari' line, all of the integer literals in Perl will
be automatically converted to became PARI objects. E.g.,
use Math::Pari ':int';
print 2**1000;
is equivalent to
print PARI(2)**PARI(1000);
Similarly, large integer literals do not lose precision.
This directive is lexically scoped. There is a similar tag ":hex"
which affects hexadecimal, octal and binary constants. One may
also need to use tag ":float" for auto-conversion of large integer
literals which Perl considers as floating point literals (see
""use" with arguments" for details).
doubles
Doubles in Perl are typically of precision approximately 15 digits
(see perlnumber). When you use them as arguments to PARI
functions, they are converted to PARI real variables, and due to
intermediate 15-digits-to-binary conversion of Perl variables the
result may be different than with the PARI many-digits-to-binary
conversion. E.g., "PARI(0.01)" and "PARI('0.01')" differ at 19-th
place, as
setprecision(38);
print pari_print(0.01), "\n",
pari_print('0.01'), "\n";
shows.
Note that setprecision() changes the output format of pari_print()
and friends, as well as the default internal precision. The
generic PARI===>string conversion does not take into account the
output format, thus
setprecision(38);
print PARI(0.01), "\n",
PARI('0.01'), "\n",
pari_print(0.01), "\n";
will print all the lines with different number of digits after the
point: the first one with 22, since the double 0.01 was converted
to a low-precision PARI object, the second one with 41, since
internal form for precision 38 requires that many digits for
representation, and the last one with 39 to have 38 significant
digits.
Starting from version 5.005 of Perl, if the tag ":float" is used on
the "use Math::Pari" line, all the float literals in Perl will be
automatically converted to became PARI objects. E.g.,
use Math::Pari ':float';
print atan(1.);
is equivalent to
print atan(PARI('1.'));
Similarly, large float literals do not lose precision.
This directive is lexically scoped.
array base
Arrays are 1-based in PARI, are 0-based in Perl. So while array
access is possible in Perl, you need to use different indices:
$nf = PARI 'nf'; # assume that PARI variable nf contains a number field
$a = PARI('nf[7]');
$b = $nf->[6];
Now $a and $b contain the same value.
matrices
Note that "PARImat([[...],...,[...])" constructor creates a matrix
with specified columns, while in PARI the command "[1,2,3;4,5,6]"
creates a matrix with specified rows. Use a convenience function
PARImat_tr() which will transpose a matrix created by PARImat() to
use the same order of elements as in PARI.
builtin perl functions
Some PARI functions, like "length" and "eval", are Perl
(semi-)reserved words. To reach these functions, one should either
import them:
use Math::Pari qw(length eval);
or call them with prefix (like &length) or the full name (like
"Math::Pari::length").
High-resolution graphics
If you have Term::Gnuplot Perl module installed, you may use high-
resolution graphic primitives of PARI. Before the usage you need to
establish a link between Math::Pari and Term::Gnuplot by calling
link_gnuplot(). You can change the output filehandle by calling
set_plot_fh(), and output terminal by calling plotterm(), as in
use Math::Pari qw(:graphic asin);
open FH, '>out.tex' or die;
link_gnuplot(); # automatically loads Term::Gnuplot
set_plot_fh(\*FH);
plotterm('emtex');
ploth($x, .5, .999, sub {asin $x});
close FH or die;
libPARI documentation
libPARI documentation is included, see Math::libPARI. It is converted
from Chapter 3 of PARI/GP documentation by the gphelp script of
GP/PARI.
ENVIRONMENT
No environment variables are used.
BUGS
· A few of PARI functions are available indirectly only.
· Using overloading constants with the Perl versions below 5.005_57
could lead to segfaults (at least without "-D usemymalloc"), as
in:
use Math::Pari ':int';
for ( $i = 0; $i < 10 ; $i++ ) { print "$i\n" }
· It may be possible that conversion of a Perl value which has both
the integer slot and the floating slot set may create a PARI
integer, even if the actual value is not an integer.
· problems with refcounting of array elements and Mod().
Workaround: make the modulus live longer than the result of Mod().
Until Perl version 5.6.1, one should exercise a special care so
that the modulus goes out of scope on a different statement than
the result:
{ my $modulus = 125;
{ my $res = Mod(34, $modulus);
print $res;
}
$fake = 1; # A (fake) statement here is required
}
Here $res is destructed before the "$fake = 1" statement, $modulus
is destructed before the first statement after the provided block.
However, if you remove the "$fake = 1" statement, both these
variables are destructed on the first statement after the provided
block (and in a wrong order!).
In 5.6.1 declaring $modulus before $res is all that is needed to
circumvent the same problem:
{ my $modulus = 125;
my $res = Mod(34, $modulus);
print $res;
} # destruction will happen in a correct order.
Access to array elements may result in similar problems. Hard to
fix since in PARI the data is not refcounted.
· Legacy implementations of dynalinking require the code of DLL to
be compiled to be "position independent" code (PIC). This slows
down the execution, while allowing sharing the loaded copy of the
DLL between different processes. [On contemeporary architectures
the same effect is allowed without the position-independent hack.]
Currently, PARI assembler files are not position-independent.
When compiled for the dynamic linking on legacy systems, this
creates a DLL which cannot be shared between processes. Some
legacy systems are reported to recognize this situation, and load
the DLL as a non-shared module. However, there may be systems
(are there?) on which this can cause some "problems".
Summary: if the dynaloading on your system requires some kind of
"-fPIC" flag, using "assembler" compiles (anything but
"machine=none") *may* force you to do a static build (i.e.,
creation of a custom Perl executable with
perl Makefile.PL static
make perl
make test_static
).
INITIALIZATION
When Math::Pari is loaded, it examines variables $Math::Pari::initmem
and $Math::Pari::initprimes. They specify up to which number the
initial list of primes should be precalculated, and how large should be
the arena for PARI calculations (in bytes). (These values have safe
defaults.)
Since setting these values before loading requires either a "BEGIN"
block, or postponing the loading ("use" vs. "require"), it may be more
convenient to set them via Math::PariInit:
use Math::PariInit qw( primes=12000000 stack=1e8 );
"use Math::PariInit" also accepts arbitrary Math::Pari import
directives, see Math::PariInit.
These values may be changed at runtime too, via allocatemem() and
setprimelimit(), with performance penalties for
recalculation/reallocation.
AUTHOR
Ilya Zakharevich, ilyaz@cpan.org
perl v5.14.0 2010-09-11 Pari(3)