In polymake, there is two kinds of objects. A Big Object models a complex mathematical concept, like a Polytope or a SimplicialComplex, while a small object is an instance of one of the many data types commonly used in computer science, like Integers, Matrices, Sets or Maps. A big object consists of a collection of other objects (big or small) describing it, called properties, and functions to compute more properties from the ones already known, called production rules.
To find out the type of an object $c
, enter
print $c->type->full_name;
To get a more detailed explanation of the polymake
object model and properties, check out the scripting guide.
You can save polymake objects to disc, as explained here.
Each (big) object has a list of properties of various types. When an object is 'born' it comes with an initial list of properties, and all other properties will be derived from those. Let's look at example from the polytope
application. The following creates a 3-dimensional cube:
> $c=cube(3);
To find out what the initial set of properties is, use the list_properties
method. It returns an array of strings. The extra code is just there to print this list nicely.
> print join(", ", $c->list_properties); CONE_AMBIENT_DIM, CONE_DIM, FACETS, AFFINE_HULL, VERTICES_IN_FACETS, BOUNDED
To see what a property contains, use the →
syntax:
> print $c->FACETS; 1 1 0 0 1 -1 0 0 1 0 1 0 1 0 -1 0 1 0 0 1 1 0 0 -1 1 1 0 0 1 -1 0 0 1 0 1 0 1 0 -1 0 1 0 0 1 1 0 0 -1
You can also get the content of all properties using the properties
method:
> $c->properties; name: c type: Polytope<Rational> description: cube of dimension 3 CONE_AMBIENT_DIM 4 CONE_DIM 4 FACETS 1 1 0 0 1 -1 0 0 1 0 1 0 1 0 -1 0 1 0 0 1 1 0 0 -1 AFFINE_HULL VERTICES_IN_FACETS {0 2 4 6} {1 3 5 7} {0 1 4 5} {2 3 6 7} {0 1 2 3} {4 5 6 7} BOUNDED true CONE_AMBIENT_DIM 4 CONE_DIM 4 FACETS 1 1 0 0 1 -1 0 0 1 0 1 0 1 0 -1 0 1 0 0 1 1 0 0 -1 AFFINE_HULL VERTICES_IN_FACETS {0 2 4 6} {1 3 5 7} {0 1 4 5} {2 3 6 7} {0 1 2 3} {4 5 6 7} BOUNDED 1
The object is changed if we ask for a property which has not been computed before.
> print $c->VERTICES; 1 -1 -1 -1 1 1 -1 -1 1 -1 1 -1 1 1 1 -1 1 -1 -1 1 1 1 -1 1 1 -1 1 1 1 1 1 1 > print join(", ", $c->list_properties); CONE_AMBIENT_DIM, CONE_DIM, FACETS, AFFINE_HULL, VERTICES_IN_FACETS, BOUNDED, FEASIBLE, POINTED, N_VERTICES, N_FACETS, VERTICES, LINEALITY_SPACE
The property VERTICES
was added, but a few others were computed on the way, too. polymake
applied a sequence of production rules that add new properties to the object that can be computed from the properties the object already posesses.
What properties can be computed for a given object depends on the set of rules defined for it. Here is a short sequence of commands which lets you find out.
> $t=$c->type; > print join(", ", sorted_uniq(sort { $a cmp $b } map { keys %{$_->properties} } $t, @{$t->super})); AFFINE_HULL, ALTSHULER_DET, BALANCE, BALANCED, BOUNDARY_LATTICE_POINTS, BOUNDED, CANONICAL, CD_INDEX_COEFFICIENTS, CENTERED, CENTERED_ZONOTOPE, CENTRALLY_SYMMETRIC, CENTROID, CHIROTOPE, CIRCUITS, COCIRCUITS, COCIRCUIT_EQUATIONS, COCUBICAL, COCUBICALITY, COMBINATORIAL_DIM, COMPLEXITY, COMPRESSED, CONE_AMBIENT_DIM, CONE_DIM, CS_PERMUTATION, CUBICAL, CUBICALITY, CUBICAL_H_VECTOR, DEGREE_ONE_GENERATORS, DUAL_BOUNDED_H_VECTOR, DUAL_GRAPH, DUAL_H_VECTOR, EDGE_ORIENTABLE, EDGE_ORIENTATION, EHRHART_POLYNOMIAL_COEFF, EQUATIONS, EXCESS_RAY_DEGREE, EXCESS_VERTEX_DEGREE, F2_VECTOR, FACETS, FACETS_THRU_INPUT_RAYS, FACETS_THRU_POINTS, FACETS_THRU_RAYS, FACETS_THRU_VERTICES, FACET_SIZES, FACET_VERTEX_LATTICE_DISTANCES, FACET_WIDTH, FACET_WIDTHS, FACE_SIMPLICITY, FAR_FACE, FAR_HYPERPLANE, FATNESS, FEASIBLE, FLAG_VECTOR, FOLDABLE_COCIRCUIT_EQUATIONS, FOLDABLE_MAX_SIGNATURE_UPPER_BOUND, FTR_CYCLIC_NORMAL, FTV_CYCLIC_NORMAL, FULL_DIM, F_VECTOR, FacetPerm, FacetPerm.pure, GALE_TRANSFORM, GALE_VERTICES, GORENSTEIN, GORENSTEIN_CONE, GORENSTEIN_INDEX, GORENSTEIN_VECTOR, GRAPH, GROEBNER_BASIS, GROUP, G_VECTOR, HASSE_DIAGRAM, HILBERT_BASIS_GENERATORS, HILBERT_SERIES, HOMOGENEOUS, H_STAR_VECTOR, H_VECTOR, INEQUALITIES, INEQUALITIES_THRU_RAYS, INEQUALITIES_THRU_VERTICES, INPUT_LINEALITY, INPUT_RAYS, INPUT_RAYS_IN_FACETS, INPUT_RAY_LABELS, INTERIOR_LATTICE_POINTS, INTERIOR_RIDGE_SIMPLICES, LATTICE, LATTICE_BASIS, LATTICE_CODEGREE, LATTICE_DEGREE, LATTICE_EMPTY, LATTICE_POINTS_GENERATORS, LATTICE_VOLUME, LATTICE_WIDTH, LATTICE_WIDTH_DIRECTION, LINEALITY_DIM, LINEALITY_SPACE, LINEAR_SPAN, LP, MAHLER_VOLUME, MAX_INTERIOR_SIMPLICES, MILP, MINIMAL_NON_FACES, MINIMAL_VERTEX_ANGLE, MINKOWSKI_CONE, MOEBIUS_STRIP_EDGES, MOEBIUS_STRIP_QUADS, MONOID_GRADING, NEIGHBORLINESS, NEIGHBORLY, NEIGHBOR_RAYS_CYCLIC_NORMAL, NEIGHBOR_VERTICES_CYCLIC_NORMAL, NORMAL, N_01POINTS, N_BOUNDARY_LATTICE_POINTS, N_BOUNDED_VERTICES, N_FACETS, N_HILBERT_BASIS, N_INPUT_RAYS, N_INTERIOR_LATTICE_POINTS, N_LATTICE_POINTS, N_POINTS, N_RAYS, N_RAY_FACET_INC, N_VERTEX_FACET_INC, N_VERTICES, ONE_RAY, ONE_VERTEX, POINTED, POINTS, POINTS_IN_FACETS, POINT_LABELS, POLAR_SMOOTH, QUOTIENT_SPACE, Q_GORENSTEIN_CONE, Q_GORENSTEIN_CONE_INDEX, RAYS, RAYS_IN_FACETS, RAYS_IN_INEQUALITIES, RAYS_IN_RIDGES, RAY_LABELS, RAY_SEPARATORS, RAY_SIZES, REFLEXIVE, RELATIVE_VOLUME, REL_INT_POINT, RIF_CYCLIC_NORMAL, SCHLEGEL_DIAGRAM, SIMPLE, SIMPLEXITY_LOWER_BOUND, SIMPLE_POLYHEDRON, SIMPLICIAL, SIMPLICIALITY, SIMPLICIAL_CONE, SIMPLICITY, SMOOTH, SMOOTH_CONE, SPECIAL_FACETS, SPLITS, SPLIT_COMPATIBILITY_GRAPH, SQUARED_RELATIVE_VOLUMES, STEINER_POINT, STEINER_POINTS, SUBRIDGE_SIZES, TERMINAL, TILING_LATTICE, TOWARDS_FAR_FACE, TRIANGULATION, TRIANGULATION_INT, TWO_FACE_SIZES, UNBOUNDED_FACETS, VALID_POINT, VERTEX_BARYCENTER, VERTEX_LABELS, VERTEX_NORMALS, VERTEX_SIZES, VERTICES, VERTICES_IN_FACETS, VERTICES_IN_INEQUALITIES, VERTICES_IN_RIDGES, VERY_AMPLE, VIF_CYCLIC_NORMAL, VOLUME, VertexPerm, VertexPerm.pure, WEAKLY_CENTERED, ZONOTOPE_INPUT_POINTS
Instead of showing the (lengthy) enumeration have a look at the documentation for a complete list of properties known for objects of the application polytope
.
You may wonder what sequence of rules led to the computation of a property you request. There usually are several mathematical ways to compute a property. polymake
uses a nice scheduling algorithm to find the most efficient procedure, and you can look at what it returns.
Suppose we want to see which sequence of rules leads to the computation of the F_VECTOR.
> $schedule=$c->get_schedule("F_VECTOR"); > print join("\n", $schedule->list); LINEALITY_DIM : LINEALITY_SPACE COMBINATORIAL_DIM : CONE_DIM, LINEALITY_DIM precondition : COMBINATORIAL_DIM ( F_VECTOR : N_FACETS, N_RAYS, COMBINATORIAL_DIM ) F_VECTOR : N_FACETS, N_RAYS, COMBINATORIAL_DIM
So if you ask for the f-vector, polymake
will first compute the dimension of the lineality space from the basis of the lineality space, then compute the combinatorial dimension from the lineality and cone dimensions, and then compute the f-vector from the number of facets, number of rays, and combinatorial dimension of the polytope. Applying the schedule to the object yields the same as asking for the property right away:
> $schedule->apply($c); > print join(", ", $c->list_properties); CONE_AMBIENT_DIM, CONE_DIM, FACETS, AFFINE_HULL, VERTICES_IN_FACETS, BOUNDED, FEASIBLE, POINTED, N_VERTICES, N_FACETS, VERTICES, LINEALITY_SPACE, LINEALITY_DIM, COMBINATORIAL_DIM, F_VECTOR
As you can see, the things polymake
needed to compute in order to get to the f-vector are stored in the object as well, so you don't have to recompute them later.
If you're interested, read more about rule scheduling in the scripting guide and the article on writing rules yourself.