Math::Vector::Real - Real vector arithmetic in Perl
use Math::Vector::Real; my $v = V(1.1, 2.0, 3.1, -4.0, -12.0); my $u = V(2.0, 0.0, 0.0, 1.0, 0.3); printf "abs(%s) = %d\n", $v, abs($b); my $dot = $u * $v; my $sub = $u - $v; # etc...
A simple pure perl module to manipulate vectors of any dimension.
The function V
, always exported by the module, allows one to create new vectors:
my $v = V(0, 1, 3, -1);
Vectors are represented as blessed array references. It is allowed to manipulate the arrays directly as far as only real numbers are inserted (well, actually, integers are also allowed because from a mathematical point of view, integers are a subset of the real numbers).
Example:
my $v = V(0.0, 1.0); # extending the 2D vector to 3D: push @$v, 0.0; # setting some component value: $v->[0] = 23;
Vectors can be used in mathematical expressions:
my $u = V(3, 3, 0); $p = $u * $v; # dot product $f = 1.4 * $u + $v; # scalar product and vector addition $c = $u x $v; # cross product, only defined for 3D vectors # etc.
The currently supported operations are:
+ * / - (both unary and binary) x (cross product for 3D vectors) += -= *= /= x= == != "" (stringfication) abs (returns the norm) atan2 (returns the angle between two vectors)
That, AFAIK, are all the operations that can be applied to vectors.
When an array reference is used in an operation involving a vector, it is automatically upgraded to a vector. For instance:
my $v = V(1, 2); $v += [0, 2];
Besides the common mathematical operations described above, the following methods are available from the package.
Note that all these methods are non destructive returning new objects with the result.
Equivalent to V(@components)
.
Returns the zero vector of the given dimension.
Returns a vector of the given dimension with all its components set to $size
.
Returns a unitary vector of the given dimension parallel to the axis with index $ix
(0-based).
For instance:
Math::Vector::Real->axis_versor(5, 3); # V(0, 0, 0, 1, 0) Math::Vector::Real->axis_versor(2, 0); # V(1, 0)
Returns the canonical base for the vector space of the given dimension.
Returns the versor for the given vector.
It is equivalent to:
$u = $v / abs($v);
Returns the result of wrapping the given vector in the box (hyper-cube) defined by $w
.
Long description:
Given the vector W
and the canonical base U1, U2, ...Un
such that W = w1*U1 + w2*U2 +...+ wn*Un
. For every component wi
we can consider the infinite set of affine hyperplanes perpendicular to Ui
such that they contain the point j * wi * Ui
being j
an integer number.
The combination of all the hyperplanes defined by every component define a grid that divides the space into an infinite set of affine hypercubes. Every hypercube can be identified by its lower corner indexes j1, j2, ..., jN
or its lower corner point j1*w1*U1 + j2*w2*U2 +...+ jn*wn*Un
.
Given the vector V
, wrapping it by W
is equivalent to finding where it lays relative to the lower corner point of the hypercube inside the grid containing it:
Wrapped = V - (j1*w1*U1 + j2*w2*U2 +...+ jn*wn*Un) such that ji*wi <= vi < (ji+1)*wi
Returns the maximum of the absolute values of the vector components.
Returns the minimum of the absolute values of the vector components.
Returns the norm of the vector squared.
Returns the distance between the two vectors.
Returns the distance between the two vectors squared.
Returns the two corners of the axis-aligned minimum bounding box (or hyperrectangle) for the given vectors.
In scalar context returns the difference between the two corners (the box diagonal vector).
Returns the vector nearest to $v
from the axis-aligned minimum box bounding the given set of vectors.
For instance, given a point $v
and an axis-aligned rectangle defined by two opposite corners ($c0
and $c1
), this method can be used to find the point nearest to $v
from inside the rectangle:
my $n = $v->nearest_in_box($c0, $c1);
Note that if $v
lays inside the box, the nearest point is $v
itself. Otherwise it will be a point from the box hyper-surface.
Calculates the square of the minimal distance between the vector $v
and the minimal axis-aligned box containing all the vectors ($w0, $w1, ...)
.
Calculates the square of the maximum distance between the vector $v
and the minimal axis-aligned box containing all the vectors ($w0, $w1, ...)
.
Returns the square of the maximum distance between any two points belonging respectively to the boxes defined by ($a0, $a1)
and ($b0, $b1)
.
Equivalent to $v = $u
but without allocating a new object.
Note that this method is destructive.
Returns the index of the vector component with the maximum size.
Given the set of vectors formed by $v
and all its reflections around the axis-aligned hyperplanes, this method returns the one lying on the first orthant.
See also [http://en.wikipedia.org/wiki/Reflection_%28mathematics%29|reflection] and [http://en.wikipedia.org/wiki/Orthant|orthant].
Decompose the given vector $u
in two vectors: one parallel to $v
and another normal.
In scalar context returns the normal vector.
Returns the sum of all the given vectors.
Returns a base for the subspace complementary to the one defined by the base @v.
The vectors on @v must be linearly independent. Otherwise a division by zero error may pop up or probably due to rounding errors, just a wrong result may be generated.
Returns a set of vectors forming an orthonormal base for the hyperplane normal to $v.
In scalar context returns just some unitary vector normal to $v.
Note that this two expressions are equivalent:
@b = $v->normal_base; @b = Math::Vector::Real->complementary_base($v);
Given a 3D vector, returns a list of 3 vectors forming an orthonormal base where $i has the same direction as the given vector $v
and $k = $i x $j
.
Returns the vectors @u
rotated around the vector $v
an angle $angle
in radians in anticlockwise direction.
See http://en.wikipedia.org/wiki/Rotation_operator_(vector_space).
Selects from the list of given vectors those that lay inside the n-ball determined by the given radius and center ($radius
and $center
respectively).
Passing the zero vector to some methods (i.e. versor
, decompose
, normal_base
, etc.) is not acceptable. In those cases, the module will croak with an "Illegal division by zero" error.
atan2
is an exceptional case that will return 0 when any of its arguments is the zero vector (for consistency with the atan2
builtin operating over real numbers).
In any case note that, in practice, rounding errors frequently cause the check for the zero vector to fail resulting in numerical instabilities.
The correct way to handle this problem is to introduce in your code checks of this kind:
if ($v->norm2 < $epsilon2) { croak "$v is too small"; }
Or even better, reorder the operations to minimize the chance of instabilities if the algorithm allows it.
The module Math::Vector::Real::XS reimplements most of the methods available from this module in XS. When it is installed, Math::Vector::Real
when automatically load and use it.
Math::Vector::Real::Random extends this module with random vector generation methods.
There are other vector manipulation packages in CPAN (Math::Vec, Math::VectorReal, Math::Vector), but they can only handle 3 dimensional vectors.
In order to report bugs you can send me and email to the address that appears below or use the CPAN RT bug-tracking system available at http://rt.cpan.org.
The source for the development version of the module is hosted at GitHub: https://github.com/salva/p5-Math-Vector-Real.
If you like this module and you're feeling generous, take a look at my wishlist: http://amzn.com/w/1WU1P6IR5QZ42
Copyright (C) 2009-2012, 2014 by Salvador Fandiño (sfandino@yahoo.com)
This library is free software; you can redistribute it and/or modify it under the same terms as Perl itself, either Perl version 5.10.0 or, at your option, any later version of Perl 5 you may have available.