This is the historically first application, and the largest one. It deals with convex pointed polyhedra. It allows to define a polyhedron either as a convex hull of a point set, an intersection of halfspaces, or as an incidence matrix without any embedding. Then you can ask for a plenty of its (especially combinatorial) properties, construct new polyhedra by modifying it, or study the behavior of the objective functions. There is a wide range of visualization methods for polyhedra, even for dimensions > 4 and purely combinatorial descriptions, including interfaces to interactive geometry viewers (such as JavaView or geomview), generating PostScript drawings and povray scene files.
imports from:
uses:
AffineLattice
:
a lattice that is displaced from the origin, i.e., a set of the form x + L, where x is a non-zero vector and L a (linear) lattice
LinearProgram
:
A linear program specified by a linear or abstract objective function
MixedIntegerLinearProgram
:
A mixed integer linear program specified by a linear or abstract objective function
PointConfiguration
:
The POINTS
of an object of type PointConfiguration encode a not necessarily convex finite point set. The difference to a parent VectorConfiguration
is that the points have homogeneous coordinates, i.e. they will be normalized to have first coordinate 1 without warning.
Polytope
:
Not necessarily bounded convex polyhedron, i.e., the feasible region of a linear program. Nonetheless, the name “Polytope” is used for two reasons: Firstly, as far as the combinatorics is concerned we always deal with polytopes; see the description of VERTICES_IN_FACETS
for details. Note that a pointed polyhedron is projectively equivalent to a polytope. The second reason is historical. We use homogeneous coordinates, which is why Polytope is derived from Cone
.
PropagatedPolytope
:
Polytope propagation means to define a polytope inductively by assigning vectors to arcs of a directed graph. At each node of such a graph a polytope arises as the joint convex hull of the polytopes at the translated sources of the inward pointing arcs. For details see
> Joswig: Polytope Propagation on Graphs.
> Chapter 6 in Pachter/Sturmfels: Algebraic Statistics for Computational Biology, Cambridge 2005. ** ''[[.:polytope:QuotientSpace |QuotientSpace]]'':\\ A topological quotient space obtained from a ''[[.:polytope:Polytope |Polytope]]'' by identifying faces. This object will sit inside the polytope. ** ''[[.:polytope:SchlegelDiagram |SchlegelDiagram]]'':\\ A Schlegel diagram of a polytope. ** ''[[.:polytope:SymmetrizedCocircuitEquations |SymmetrizedCocircuitEquations]]'':\\ ** ''[[.:polytope:VectorConfiguration |VectorConfiguration]]'':\\ An object of type VectorConfiguration deals with properties of row vectors, assembled into an n x d matrix called ''[[.:polytope:VectorConfiguration#VECTORS |VECTORS]]''. The entries of these row vectors are interpreted as non-homogeneous coordinates. In particular, the coordinates of a VECTOR will *NOT* be normalized to have a leading 1. ** ''[[.:polytope:Visual_Cone |Visual::Cone]]'':\\ Visualization of a Cone as a graph (if 1d), or as a solid object (if 2d or 3d) ** ''[[.:polytope:Visual_Gale |Visual::Gale]]'':\\ A gale diagram prepared for drawing. ** ''[[.:polytope:Visual_PointConfiguration |Visual::PointConfiguration]]'':\\ Visualization of the point configuration. ** ''[[.:polytope:Visual_Polytope |Visual::Polytope]]'':\\ Visualization of a polytope as a graph (if 1d), or as a solid object (if 2d or 3d), or as a Schlegel diagram (4d). ** ''[[.:polytope:Visual_PolytopeGraph |Visual::PolytopeGraph]]'':\\ Visualization of the graph of a polyhedron. ** ''[[.:polytope:Visual_PolytopeLattice |Visual::PolytopeLattice]]'':\\ Visualization of the ''[[.:polytope:Polytope#HASSE_DIAGRAM |HASSE_DIAGRAM]]'' of a polyhedron as a multi-layer graph.. ** ''[[.:polytope:Visual_SchlegelDiagram |Visual::SchlegelDiagram]]'':\\ Visualization of the Schlegel diagram of a polytope. ** ''[[.:polytope:VoronoiPolyhedron |VoronoiPolyhedron]]'':\\ For a finite set of ''[[.:polytope:VoronoiPolyhedron#SITES |SITES]]'' //S// the Voronoi region of each site is the set of points closest (with respect to Euclidean distance) to the given site. All Voronoi regions (and their faces) form a polyhedral complex which is a vertical projection of the boundary complex of an unbounded polyhedron P(S). This way VoronoiPolyhedron becomes a derived class from [[]].
Combinatorial functions.
circuits2matrix(Set<Pair<Set<Int>,Set<Int>>> co)
Convert CIRCUITS
or COCIRCUITS
to a 0/+1/-1 matrix, with one row for each circuit/cocircuit, and as many columns as there are VECTORs/POINTS.
cocircuit_equation_of_ridge(Cone C, Set rho)
The cocircuit equations of a cone C corresponding to some interior ridge rho with respect to a list of interior simplices symmetries of the cone are NOT taken into account
cocircuit_equations(Cone C, Array<Set> interior_ridge_simplices, Array<Set> interior_simplices)
A matrix whose rows contain the cocircuit equations of a cone C with respect to a list of interior ridge simplices symmetries of the cone are NOT taken into account
codegree<Scalar>(Cone P)
Calculate the codegree of a cone or polytope P. This is the maximal positive integer c such that every subset of size < c lies in a common facet of conv P. Moreover, the relation degree(P) + codegree(P) = dim(P) + 1 holds.
codegree<Scalar>(PointConfiguration P)
Calculate the codegree of a point configuration P. This is the maximal positive integer c such that every subset of size < c lies in a common facet of conv P. Moreover, the relation degree(P) + codegree(P) = dim(P) + 1 holds.
Scalar
: the underlying number type,
contraction(VectorConfiguration C, Int v)
Contract a vector configuration C along a specified vector v.
Int
v
: index of the vector to contract
degree<Scalar>(PointConfiguration P)
Calculate the degree of a cone, polytope or point configuration P. This is the maximal dimension of an interior face of P, where an interior face is a subset of the points of P whose convex hull does not lie on the boundary of P. Moreover, the relation degree(P) + codegree(P) = dim(P) + 1 holds.
Scalar
: the underlying number type,
PointConfiguration
P
: (or Cone or Polytope)
To find the degree of the 3-cube, type
> print degree(cube(3)); 3
deletion(VectorConfiguration C, Int v)
Delete a specified vector v from a vector configuration C.
Int
v
: index of the vector to delete
describe(Polytope P)
Provide a basic combinatorial description (unless there exists one already). Only the options extended and matchthenet (for 3-polytopes) can trigger any computation.
Polytope
P
: source object
Bool
extended
Bool
matchthenet
String
language
> print describe(cube(3)); cube of dimension 3
> $P = new Polytope(POINTS=>cube(3)->VERTICES); print describe($P); polytope with POINTS, CONE_AMBIENT_DIM
> $P = new Polytope(POINTS=>cube(3)->VERTICES); print describe($P, extended=>1, language=>"de"); einfaches 3-Polytop im 3-Raum mit f-Vektor 8 12 6
> $P = new Polytope(POINTS=>cube(3)->VERTICES); print describe($P, matchthenet=>1); { "en": "A simple polytope with 8 vertices, 12 edges and 6 facets.", "de": "Ein einfaches Polytop mit 8 Ecken, 12 Kanten und 6 Seiten."}
Functions based on graph isomorphisms.
congruent(Polytope P1, Polytope P2)
Check whether two given polytopes P1 and P2 are congruent, i.e. whether there is an affine isomorphism between them that is induced by a (possibly scaled) orthogonal matrix. Returns the scale factor, or 0 if the polytopes are not congruent. We are using the reduction of the congruence problem (for arbitrary point sets) to the graph isomorphism problem due to:
> Akutsu, T.: On determining the congruence of point sets in `d` dimensions.
> Comput. Geom. Theory Appl. 9, 247--256 (1998), no. 4 ? Parameters: :: ''[[.:polytope:Polytope |Polytope]]'' ''P1'': the first polytope :: ''[[.:polytope:Polytope |Polytope]]'' ''P2'': the second polytope ? Returns: :''Scalar'' ? Example: :: Let's first consider an isosceles triangle and its image of the reflection in the origin: :: <code perl> > $t = simplex(2);
> $tr = simplex(2,-1); </code>
Those two are congruent:
> print congruent($t,$tr); 1
If we scale one of them, we get a factor:
> print congruent(scale($t,2),$tr); 4
But if we instead take a triangle that is not isosceles, we get a negative result.
> $tn = new Polytope(VERTICES => [[1,0,0],[1,2,0],[1,0,1]]); > print congruent($t,$tn); 0
equal_polyhedra(Polytope P1, Polytope P2)
Polytope
P1
: the first polytope
Polytope
P2
: the second polytope
Bool
verbose
: Prints information on the difference between P1 and P2 if they are not equal.
> $p = new Polytope(VERTICES => [[1,-1,-1],[1,1,-1],[1,-1,1],[1,1,1]]); > print equal_polyhedra($p,cube(2)); true
To see why two polytopes are unequal, try this:
> print equal_polyhedra($p,simplex(2),verbose => 1); Inequality 1 -1 -1 not satisfied by point 1 1 1. false
find_facet_vertex_permutations(Cone P1, Cone P2)
Find the permutations of facets and vertices which maps the cone or polyhedron P1 to P2. The facet permutation is the first component, the vertex permutation is the second component of the return value. Only the combinatorial isomorphism is considered.
included_polyhedra(Polytope P1, Polytope P2)
Polytope
P1
: the first polytope
Polytope
P2
: the second polytope
Bool
verbose
: Prints information on the difference between P1 and P2 if none is included in the other.
> print included_polyhedra(simplex(3),cube(3)); true
To see in what way the two polytopes differ, try this:
> $p = new Polytope(VERTICES => [[1,-1,-1],[1,1,-1],[1,-1,1],[1,1,1]]); > print included_polyhedra($p,simplex(2),verbose => 1); Inequality 0 1 0 not satisfied by point 1 -1 -1. false
isomorphic(Cone P1, Cone P2)
Check whether the face lattices of two cones or polytopes are isomorphic. The problem is reduced to graph isomorphism of the vertex-facet incidence graphs.
Cone
P1
: the first cone/polytope
Cone
P2
: the second cone/polytope
The following compares the standard 2-cube with a polygon generated as the convex hull of five points. The return value is true since both polygons are quadrangles.
> $p = new Polytope(POINTS=>[[1,-1,-1],[1,1,-1],[1,-1,1],[1,1,1],[1,0,0]]); > print isomorphic(cube(2),$p); true
lattice_isomorphic_smooth_polytopes(Polytope P1, Polytope P2)
Tests whether two smooth lattice polytopes are lattice equivalent by comparing lattice distances between vertices and facets.
These functions are for checking the consistency of some properties.
check_inc(Matrix points, Matrix hyperplanes, String sign, Bool verbose)
Check coordinate data. For each pair of vectors from two given matrices their inner product must satisfy the given relation.
Matrix
points
Matrix
hyperplanes
String
sign
: composed of one or two characters from [-+0], representing the allowed domain of the vector inner products.
Bool
verbose
: print all products violating the required relation
Let's check which vertices of the square lie in its zeroth facet:
> $H = cube(2)->FACETS->minor([0],All); > print check_inc(cube(2)->VERTICES,$H,'0',1); <1,0> ( 1 1 -1 ) * [ 1 1 0 ] == 2 <3,0> ( 1 1 1 ) * [ 1 1 0 ] == 2 #points==4, #hyperplanes==1, -:0, 0:2, +:2, total:4 false
Thus, the first and third vertex don't lie on the hyperplane defined by the facet but on the positive side of it, and the remaining two lie on the hyperplane.
check_poly(IncidenceMatrix VIF)
Try to check whether a given vertex-facet incidence matrix VIF defines a polytope. Note that a successful certification by check_poly is not sufficient to determine whether an incidence matrix actually defines a polytope. Think of it as a plausibility check.
IncidenceMatrix
VIF
Bool
dual
: transposes the incidence matrix
Bool
verbose
: prints information about the check.
validate_moebius_strip(Polytope P)
Validates the output of the client edge_orientable
, in particular it checks whether the MOEBIUS_STRIP_EDGES form a Moebius strip with parallel opposite edges. Prints a message to stdout.
Polytope
P
: the given polytope
validate_moebius_strip_quads(Polytope P)
Checks whether the MOEBIUS_STRIP_QUADS form a Moebius strip with parallel opposite edges. Prints a message to stdout and returns the MOEBIUS_STRIP_EDGES if the answer is affirmative.
The following functions allow for the conversion of the coordinate type of cones and polytopes.
affine_float_coords(Polytope P)
Dehomogenize the vertex coordinates and convert them to Float
building_set_ycoord_2_zcoord(Map<Set<Int>,Scalar> The)
Convert the y-coordinate representation of a generalized permutahedron given via a building set into the z-coordinate representation. See 6, 7, 8 of Postnikov, A. (2009) “Permutohedra, Associahedra, and Beyond,” International Mathematics Research Notices, Vol. 2009, No. 6, pp. 1026–1106 Advance Access publication January 7, 2009 doi:10.1093/imrn/rnn153# @tparam Scalar
convert_to<Coord>(Cone c)
Creates a new Cone object with different coordinate type target coordinate type Coord must be specified in angle brackets e.g. $new_cone = convert_to<Coord>($cone)
convert_to<Coord>(Polytope P)
provide a Polytope object with desired coordinate type
This contains functions for data conversions and type casts.
plantri_list(Int number, String options)
Convert the output of plantri program into polymake Polytope object. Returns an Array of combinatorial types of simplicial 3-polytopes (or their duals).
Int
number
: of vertices
String
options
: (not affecting the output format) as described in the plantri manual
Combinatorial types of simplicial 3-polytopes with 6 vertices.
> $A = plantri_list(6); > print $A->size(); 2
Distribution of vertex degrees of the first polytope in that list.
> print histogram($A->[0]->VERTEX_DEGREES); {(3 2) (4 2) (5 2)}
Simple 3-polytopes with seven facets.
> $B = plantri_list(7,"-d"); > print $B->size(); 5
> print $B->[0]->F_VECTOR; 10 15 7
Tight spans and their connections to polyhedral geometry
metric_cone(Int n)
Computes the metric cone on for points. The triangle inequalities define the facets. The number of rays are known for n ⇐ 8. See Deza and Dutour-Sikiric (2018), doi:10.1016/j.jsc.2016.01.009
metric_polytope(Int n)
Computes the metric polytope on for points. This is the metric cone bounded by one inequality per triplet of points. The number of vertices are known for n ⇐ 8. See Deza and Dutour-Sikiric (2018), doi:10.1016/j.jsc.2016.01.009
tight_span_envelope(SubdivisionOfPoints sd)
Computes the envelope for a given subdivision of points.
Bool
extended
: If True, the envelope of the extended tight span is computed.
These functions capture geometric information of the object. Geometric properties depend on geometric information of the object, like, e.g., vertices or facets.
all_steiner_points(Polytope P)
Compute the Steiner points of all faces of a polyhedron P using a randomized approximation of the angles. P must be BOUNDED
.
center_distance(Polytope p)
Compute the mean or median distance of the VERTICES
to the VERTEX_BARYCENTER
.
circuit_completions(Matrix L, Matrix R)
Given two matrices L (n x d) and R (m x d) such that (L/R) has rank r, select all (r+1-n)-subsets C of rows of R such that (L,S) or (S,L) is a circuit. Optionally, if d > r, a basis H for the orthogonal span of the affine hull of (L/R) may be given.
Matrix
L
Matrix
R
Matrix
H
Divide the vertex set of the 3-cube into a body diagonal L and six remaining vertices R. To find the subsets of R that complete L to a circuit, type
> $c = cube(3); > $L = $c->VERTICES->minor([0,7],All); > $R = $c->VERTICES->minor([1,2,3,4,5,6],All); > print circuit_completions($L,$R); {0 1 3} {2 4 5}
containing_normal_cone(Cone P, Vector q)
Return the vertices of the face of P whose normal cone contains a point q.
containing_outer_cone(Polytope P, Vector q)
Return the vertices of the face of P whose outer cone contains a point q.
dihedral_angle(Vector<Scalar> H1, Vector<Scalar> H2)
Compute the dihedral angle between two (oriented) affine or linear hyperplanes.
Vector<Scalar>
H1
: : first hyperplane
Vector<Scalar>
H2
: : second hyperplane
Bool
deg
: output in degrees rather than radians, default is false
Bool
cone
: hyperplanes seen as linear hyperplanes, default is false
> $H1 = new Vector(1,5,5); > $H2 = new Vector(1,-5,5); > print dihedral_angle($H1,$H2,deg=>1); 90
gelfand_tsetlin_counting<Scalar>(Vector<Scalar> lambda)
Compute the volume of the Gelfand-Tsetlin polytope associated to the vector lambda. See Postnikov: Permutohedra, associahedra, and beyond, IMRN (2009); doi:10.1093/imrn/rnn153 Theorem 15.1. Note that this volume is the volume of the polytope in its embedding space, in case that all entries of lambda are different.
Scalar
Vector<Scalar>
lambda
: Vector encoding a descending sequence of numbers.
Bool
lattice
: The same formula may be used to count lattice points, default=false
Scalar
Illustrating the differences between the volumes for the sequence (6,4,2,1)
> $lambda = new Vector(6,4,2,1); > $pgt = gelfand_tsetlin($lambda,projected=>1); > $gt = gelfand_tsetlin($lambda,projected=>0); > print $gt->VOLUME; 0
> print $gt->FULL_DIM; false
> print $pgt->VOLUME; 20
> print $pgt->FULL_DIM; true
> print gelfand_tsetlin_counting($lambda); 20
> print $gt->N_LATTICE_POINTS; 360
> print gelfand_tsetlin_counting($lambda, lattice_points=>1); 360
gelfand_tsetlin_diagrams<Scalar>(Vector<Scalar> lambda)
Turn points from a Gelfand-Tsetlin polytope into triangular arrays. See Postnikov: Permutohedra, associahedra, and beyond, IMRN (2009); doi:10.1093/imrn/rnn153 Theorem 15.1. Note that we assume the points to come with a homogenizing coordinate.
Scalar
Vector<Scalar>
lambda
: Vector encoding a descending sequence of numbers.
Small example with tree lattice points
> $lambda = new Vector(3,2,2); > $gt = gelfand_tsetlin($lambda,projected=>0); > print $gt->N_LATTICE_POINTS; 3
> print $gt->LATTICE_POINTS; 1 3 2 2 2 2 2 1 3 2 2 3 2 2 1 3 2 2 3 2 3
> print gelfand_tsetlin_diagrams($gt->LATTICE_POINTS); <3 2 2 2 2 0 2 0 0 > <3 2 2 3 2 0 2 0 0 > <3 2 2 3 2 0 3 0 0 >
induced_lattice_basis(Polytope p)
Returns a basis of the affine lattice spanned by the vertices
integer_points_bbox(Polytope<Scalar> P)
Enumerate all integer points in the given polytope by searching a bounding box.
maximal_ball(Polytope<Rational> P)
Finds for a given rational Polytope P the maximal ball B(r,c) which is contained in P. Here r is the radius of the maximal ball and c is it center. Since is can happen, that r is not a rational number or c is not a rational, does this function only work for polytopes for which in the norm of each can be written as QuadraticExtension to the same root.
> $S = simplex(2); > print maximal_ball($S); 1-1/2r2 <1 1-1/2r2 1-1/2r2>
minimal_vertex_angle(Polytope P)
Computes the minimal angle between two vertices of the input polytope P.
normaliz_compute(Cone C)
Compute degree one elements, Hilbert basis or Hilbert series of a cone C with libnormaliz Hilbert series and Hilbert h-vector depend on the given grading and will not work unless C is HOMOGENEOUS
or a MONOID_GRADING
is set
Cone
C
Bool
from_facets
: supply facets instead of rays to normaliz
Bool
degree_one_generators
: compute the generators of degree one, i.e. lattice points of the polytope
Bool
hilbert_basis
: compute Hilbert basis of the cone C
Bool
h_star_vector
: compute Hilbert h-vector of the cone C
Bool
hilbert_series
: compute Hilbert series of the monoid
Bool
ehrhart_quasi_polynomial
: compute Ehrhart quasi polynomial of a polytope
Bool
facets
: compute support hyperplanes (=FACETS,LINEAR_SPAN)
Bool
rays
: compute extreme rays (=RAYS)
Bool
dual_algorithm
: use the dual algorithm by Pottier
Bool
skip_long
: do not try to use long coordinates first
Bool
verbose
: libnormaliz debug output
occluding_cone(Cone P, Set F)
For a face F of a cone or polytope P, return the polyhedral cone C such that taking the convex hull of P and any point in C destroys the face F
optimal_contains(Polytope P_in, Polytope P_out)
Finds for a given inner Polytope P_in and a given outer Polytope P_out a maximal a scalar s and a vector t, such that P_in scaled with s and shifted by t is a subset of P_out.
print_face_lattice(IncidenceMatrix VIF, Bool dual)
Write the face lattice of a vertex-facet incidence matrix VIF to stdout. If dual is set true the face lattice of the dual is printed.
IncidenceMatrix
VIF
Bool
dual
To get a nice representation of the squares face lattice, do this:
> print_face_lattice(cube(2)->VERTICES_IN_FACETS); FACE_LATTICE [ -1 : 4 ] {{0 1} {0 2} {1 3} {2 3}} [ -2 : 4 ] {{0} {1} {2} {3}}
separable(Vector q, Cone P)
Checks whether there exists a hyperplane separating a given point q from a polytope/cone P by solving a suitable LP. If true, q is a vertex of the polytope defined by q and the vertices of P. To get the separating hyperplane, use separating_hyperplane. Works without knowing the facets of P!
Vector
q
: the vertex (candidate) which is to be separated from P
Cone
P
: the polytope/cone from which q is to be separated
Bool
strong
: Test for strong separability. default: true
> $q = cube(2)->VERTICES->row(0); > print separable(cube(2), $q, strong=>0); true
simple_polytope_vertices_rs(Polytope<Scalar> P, Vector<Scalar> min_vertex)
Use reverse search method to find the vertices of a polyhedron. While applying this method, also collect the directed graph of cost optimization with respect to a (optionally) provided objective. If no objective is provided, one will be selected that cuts of ONE_VERTEX
The input polytope must be SIMPLE
and POINTED
, these properties are not checked by the algorithm.
steiner_point(Polytope P)
Compute the Steiner point of a polyhedron P using a randomized approximation of the angles.
violations(Cone P, Vector q)
Check which relations, if any, are violated by a point.
Cone
P
Vector
q
String
section
: Which section of P to test against q
Int
violating_criterion
: has the options: +1 (positive values violate; this is the default), 0 (*non*zero values violate), -1 (negative values violate)
This calculates and prints the violated equations defining a square with the origin as its center and side length 2 with respect to a certain point:
> $p = cube(2); > $v = new Vector([1,2,2]); > $S = violations($p,$v); > print $S; {1 3}
visible_face_indices(Cone P, Vector q)
Return the indices (in the HASSE_DIAGRAM) of all faces that are visible from a point q.
visible_facet_indices(Cone P, Vector q)
Return the indices of all facets that are visible from a point q.
zonotope_tiling_lattice(Polytope P)
Calculates a generating set for a tiling lattice for P, i.e., a lattice L such that P + L tiles the affine span of P.
Polytope
P
: the zonotope
Bool
lattice_origin_is_vertex
: true if the origin of the tiling lattice should be a vertex of P; default false, ie, the origin will be the barycenter of P
This determines a tiling lattice for a parallelogram with the origin as its vertex barycenter and prints it base vectors:
> $M = new Matrix([[1,1,0],[1,1,1]]); > $p = zonotope($M); > $A = zonotope_tiling_lattice($p); > print $A->BASIS; 0 -1 -1 0 0 1
These functions capture information that depends on the lattice structure of the cone. polymake always works with the integer lattice.
smooth_vertices
Return the indices of all bounded and simple vertices where the edge-directions form a lattice basis.
> print smooth_vertices(cube(2, 2/3)); {0 1 2 3}
These functions provide tools from linear, integer and dicrete optimization. In particular, linear programs are defined here.
ball_lifting_lp(GeometricSimplicialComplex c, Int facet_index, Rational conv_eps)
Computes the inequalities and the linear objective for an LP to lift a simplicial d-ball embedded starshaped in Rd.
core_point_algo(Polytope p, Rational optLPvalue)
Algorithm to solve highly symmetric integer linear programs (ILP). It is required that the group of the ILP induces the alternating or symmetric group on the set of coordinate directions. The linear objective function is the vector (0,1,1,..,1).
core_point_algo_Rote(Polytope p, Rational optLPvalue)
Version of core_point_algo with improved running time (according to a suggestion by G. Rote). The core_point_algo is an algorithm to solve highly symmetric integer linear programs (ILP). It is required that the group of the ILP induces the alternating or symmetric group on the set of coordinate directions. The linear objective function is the vector (0,1,1,..,1).
find_transitive_lp_sol(Matrix Inequalities)
Algorithm to solve symmetric linear programs (LP) of the form max ctx , c=(0,1,1,..,1) subject to the inequality system given by Inequalities. It is required that the symmetry group of the LP acts transitively on the coordinate directions.
Matrix
Inequalities
: the inequalities describing the feasible region
Consider the LP described by the facets of the 3-cube:
> @sol=find_transitive_lp_sol(cube(3)->FACETS); > print $_, "\n" for @sol; 1 1 1 1 3 true true
The optimal solution is [1,1,1,1], its value under c is 3, and the LP is feasible and bounded in direction of c.
inner_point(Matrix points)
Compute a true inner point of a convex hull of the given set of points.
lp2poly<Scalar>(String file, Vector testvec, String prefix)
Read a linear programming problem given in LP-Format or MILP-Format (as used by cplex & Co.) and convert it to a polytope object with an added LP property or MILP property
Scalar
: coordinate type of the resulting polytope; default is Rational
.
String
file
: filename of a linear programming problem in LP-Format
Vector
testvec
: If present, after reading in each line of the LP it is checked whether testvec fulfills it
String
prefix
: If testvec is present, all variables in the LP file are assumed to have the form $prefix$i
Bool
create_lp
: Create an LP property regardless of the format of the given file. If the file has MILP-Format, the created LP property will have an attachment INTEGER_VARIABLES
Polytope<Scalar>
mps2poly<Scalar>(String file, String prefix, Bool use_lazy)
Read a linear problem or mixed integer problem from in MPS-Format (as used by Gurobi and other linear problem solvers) and convert it to a polytope object with one or multiple added LP property or MILP property. This interface has some limitations since the MPS-Format offer a wide range of functionalities, which are not all compatible with polymake right now.
Scalar
: coordinate type of the resulting polytope; default is rational
String
file
: filename of a linear programming problem in MPS-Format
String
prefix
: If prefix is present, all variables in the LP file are assumed to have the form $prefix$i
Bool
use_lazy
: Also use the lazy constrains if they are given to build the polytope.
poly2lp(Polytope P, LinearProgram LP, Bool maximize, String file)
Convert a polymake description of a polyhedron to LP format (as used by CPLEX and other linear problem solvers) and write it to standard output or to a file. If LP comes with an attachment 'INTEGER_VARIABLES' (of type Array<Bool>), the output will contain an additional section 'GENERAL', allowing for IP computations in CPLEX. If the polytope is already known to be infeasible, the function will throw a runtime error. Alternatively one can also provide a MILP, instead of a LP with 'INTEGER_VARIABLES' attachment.
Polytope
P
LinearProgram
LP
: default value: P→LP
Bool
maximize
: produces a maximization problem; default value: 0 (minimize)
String
file
: default value: standard output
poly2mps(Polytope P, LinearProgram LP, Set<Int> br, String file)
Convert a polymake description of a polyhedron to MPS format (as used by Gurobi and other linear problem solvers) and write it to standard output or to a file. If LP comes with an attachment 'INTEGER_VARIABLES' (of type Array<Bool>), the output will contain markers for them. You can give the indices rows, which are just variable bounds (x_i>=b_i or x_i⇐b_i), as a Set. If you do so, the will be in this way. If the polytope is already known to be infeasible, the function will throw a runtime error. Alternatively one can also provide a MILP, instead of a LP with 'INTEGER_VARIABLES' attachment.
Polytope
P
LinearProgram
LP
: default value: P→LP
String
file
: default value: standard output
poly2porta(Polytope<Rational> p, String file)
take a rational polytope and write a porta input file (.ieq or .poi)
porta2poly(String file)
Read an .ieq or .poi file (porta input) or .poi.ieq or .ieq.poi (porta output) and convert it to a polytope object
String
file
: filename of a porta file (.ieq or .poi)
print_constraints(Cone<Scalar> C)
Write the FACETS
/ INEQUALITIES
and the LINEAR_SPAN
/ EQUATIONS
(if present) of a polytope P or cone C in a readable way. COORDINATE_LABELS
are adopted if present.
Cone<Scalar>
C
: the given polytope or cone
The following prints the facet inequalities of the square, changing the labels.
> print_constraints(cube(2),ineq_labels=>['zero','one','two','three']); Facets: zero: x1 >= -1 one: -x1 >= -1 two: x2 >= -1 three: -x2 >= -1
rand_aof(Polytope P, Int start)
Produce a random abstract objective function on a given simple polytope P. It is assumed that the boundary complex of the dual polytope is extendibly shellable. If, during the computation, it turns out that a certain partial shelling cannot be extended, then this is given instead of an abstract objective function. It is possible (but not required) to specify the index of the starting vertex start.
random_edge_epl(Graph<Directed> G)
Computes a vector containing the expected path length to the maximum for each vertex of a directed graph G. The random edge pivot rule is applied.
separating_hyperplane(Vector q, Matrix points)
Computes (the normal vector of) a hyperplane which separates a given point q from points via solving a suitable LP. The scalar product of the normal vector of the separating hyperplane and a point in points is greater or equal than 0 (same behavior as for facets!). If q is not a vertex of P=conv(points,q), the function throws an infeasible exception. Works without knowing the facets of P!
Vector
q
: the vertex (candidate) which is to be separated from points
Matrix
points
: the points from which q is to be separated
The following stores the result in the List @r and then prints the answer and a description of the hyperplane separating the zeroth vertex of the square from the others.
> $q = cube(2)->VERTICES->row(0); > $points = cube(2)->VERTICES->minor(sequence(1,3),All); > print separating_hyperplane($q,$points); 0 1/2 1/2
separating_hyperplane(Polytope p1, Polytope p2)
Computes (the normal vector of) a hyperplane which separates two given polytopes p1 and p2 if possible. Works by solving a linear program, not by facet enumeration.
Polytope
p1
: the first polytope, will be on the positive side of the separating hyperplane
Polytope
p2
: the second polytope
Bool
strong
: If this is set to true, the resulting hyperplane will be strongly separating, i.e. it won't touch either of the polytopes. If such a plane does not exist, an exception will be thrown. default: true
totally_dual_integral(Matrix inequalities)
Checks if a given system of inequalities is totally dual integral or not. The inequalities should describe a full dimensional polyhedron
vertex_colors(Polytope P, LinearProgram LP)
Calculate RGB-color-values for each vertex depending on a linear or abstract objective function. Maximal and minimal affine vertices are colored as specified. Far vertices (= rays) orthogonal to the linear function normal vector are white. The colors for other affine vertices are linearly interpolated in the HSV color model. If the objective function is linear and the corresponding LP problem is unbounded, then the affine vertices that would become optimal after the removal of the rays are painted pale.
Polytope
P
RGB
min
: the minimal RGB value
RGB
max
: the maximal RGB value
This calculates a vertex coloring with respect to a linear program. For a better visualization, we also set the vertex thickness to 2.
> $p = cube(3); > $p->LP(LINEAR_OBJECTIVE=>[0,1,2,3]); > $v = vertex_colors($p,$p->LP); > $p->VISUAL(VertexColor=>$v,VertexThickness=>2);
write_foldable_max_signature_ilp(Polytope P, String outfile_name)
construct a linear program whose optimal value is an upper bound for the algebraic signature of a triangulation of P. This is the absolute value of the difference of normalized volumes of black minus white simplices (counting only those with odd normalized volume) in a triangulation of P whose dual graph is bipartite. If P has a GROUP, it will be used to construct the linear program.
Polytope
P
String
outfile_name
For the 0/1 2-cube without a GROUP, the foldable max signature lp is computed as follows:
> write_foldable_max_signature_ilp(cube(2,0)); MINIMIZE obj: +1 x1 -1 x2 +1 x3 -1 x4 +1 x5 -1 x6 +1 x7 -1 x8 Subject To ie0: +1 x1 >= 0 ie1: +1 x2 >= 0 ie2: +1 x3 >= 0 ie3: +1 x4 >= 0 ie4: +1 x5 >= 0 ie5: +1 x6 >= 0 ie6: +1 x7 >= 0 ie7: +1 x8 >= 0 ie8: -1 x1 -1 x2 >= -1 ie9: -1 x3 -1 x4 >= -1 ie10: -1 x5 -1 x6 >= -1 ie11: -1 x7 -1 x8 >= -1 eq0: -1 x4 +1 x5 = 0 eq1: +1 x3 -1 x6 = 0 eq2: -1 x2 +1 x7 = 0 eq3: +1 x1 -1 x8 = 0 eq4: +1 x1 +1 x2 +1 x3 +1 x4 +1 x5 +1 x6 +1 x7 +1 x8 = 2 BOUNDS x1 free x2 free x3 free x4 free x5 free x6 free x7 free x8 free GENERAL x1 x2 x3 x4 x5 x6 x7 x8 END
There are eight variables, one for each possible black or white maximal interior simplex. The optimal value of this LP is zero, because any triangulation has exactly one black and one white simplex of odd normalized volume. Notice that the objective function becomes empty for cube(2), because in the +1/-1 cube, each simplex has even volume.
For the 0/1 3-cube, we use a GROUP property:
> write_foldable_max_signature_ilp(cube(3,0,group=>1)); MINIMIZE obj: +1 x1 -1 x2 +1 x3 -1 x4 +1 x5 -1 x6 Subject To ie0: +1 x1 >= 0 ie1: +1 x2 >= 0 ie2: +1 x3 >= 0 ie3: +1 x4 >= 0 ie4: +1 x5 >= 0 ie5: +1 x6 >= 0 ie6: +1 x7 >= 0 ie7: +1 x8 >= 0 ie8: -1 x1 -1 x2 >= -8 ie9: -1 x3 -1 x4 >= -24 ie10: -1 x5 -1 x6 >= -24 ie11: -1 x7 -1 x8 >= -2 eq0: +2 x3 -2 x4 +2 x5 -2 x6 = 0 eq1: -2 x3 +2 x4 -2 x5 +2 x6 = 0 eq2: -6 x2 +6 x5 +24 x7 = 0 eq3: -6 x1 +6 x6 +24 x8 = 0 eq4: +1 x1 +1 x2 +1 x3 +1 x4 +1 x5 +1 x6 +2 x7 +2 x8 = 6 BOUNDS x1 free x2 free x3 free x4 free x5 free x6 free x7 free x8 free GENERAL x1 x2 x3 x4 x5 x6 x7 x8 END
There are again 8 variables, but now they correspond to the black and white representatives of the four symmetry classes of maximal interior simplices. The optimal value of this linear program is 4, because the most imbalanced triangulation is the one with 5 simplices, in which the volume of the big interior simplex is even and doesn't get counted in the objective function.
write_simplexity_ilp(Polytope P)
construct a linear program whose optimal value is a lower bound for the minimal number of simplices in a triangulation of P.
Polytope
P
String
outfile_name
: . If the string is '-' (as is the default), the linear program is printed to STDOUT.
To print the linear program for the 2-dimensional cube, write
> write_simplexity_ilp(cube(2)); MINIMIZE obj: +1 x1 +1 x2 +1 x3 +1 x4 Subject To ie0: +1 x1 >= 0 ie1: +1 x2 >= 0 ie2: +1 x3 >= 0 ie3: +1 x4 >= 0 eq0: +4 x1 +4 x2 +4 x3 +4 x4 = 8 eq1: -1 x2 +1 x3 = 0 eq2: -1 x1 +1 x4 = 0 BOUNDS x1 free x2 free x3 free x4 free GENERAL x1 x2 x3 x4 END
write_simplexity_ilp_with_angles(Polytope P, String outfile_name)
construct a linear program whose optimal value is a lower bound for the minimal number of simplices in a triangulation of P, and that takes into account the angle constraint around codimension 2 faces. The first set of variables correspond to possible maximal internal simplices, the second set to the simplices of codimension 2. See the source file polytope/src/symmetrized_codim_2_angle_sums.cc for details.
Polytope
P
String
outfile_name
To print the linear program for the 2-dimensional cube, write
> write_simplexity_ilp_with_angles(cube(2)); MINIMIZE obj: +1 x1 +1 x2 +1 x3 +1 x4 Subject To ie0: +1 x1 >= 0 ie1: +1 x2 >= 0 ie2: +1 x3 >= 0 ie3: +1 x4 >= 0 ie4: +1 x5 >= 0 ie5: +1 x6 >= 0 ie6: +1 x7 >= 0 ie7: +1 x8 >= 0 eq0: -1 x2 +1 x3 = 0 eq1: -1 x1 +1 x4 = 0 eq2: +0.5 x1 +0.25 x2 +0.2500000000000001 x3 -0.5 x5 = 0 eq3: +0.25 x1 +0.5 x3 +0.2500000000000001 x4 -0.5 x6 = 0 eq4: +0.25 x1 +0.5 x2 +0.2500000000000001 x4 -0.5 x7 = 0 eq5: +0.25 x2 +0.2500000000000001 x3 +0.5 x4 -0.5 x8 = 0 eq6: +1 x5 = 1 eq7: +1 x6 = 1 eq8: +1 x7 = 1 eq9: +1 x8 = 1 eq10: +4 x1 +4 x2 +4 x3 +4 x4 = 8 BOUNDS x1 free x2 free x3 free x4 free x5 free x6 free x7 free x8 free GENERAL x1 x2 x3 x4 x5 x6 x7 x8 END
write_symmetrized_simplexity_ilp(Polytope P, Set<Int> isotypic_components, String outfile_name)
construct a linear program whose optimal value is a lower bound for the minimal number of simplices in a triangulation of P. The symmetry group of P is taken into account, in that the variables in the linear program are projections of the indicator variables of the maximal interior simplices to a given direct sum of isotypic components of the symmetry group of P acting on these simplices.
Polytope
P
String
outfile_name
: . Setting this to '-' (as is the default) prints the LP to stdout.
For the 3-cube, the symmetrized LP for isotypic component 0 reads as follows:
> write_symmetrized_simplexity_ilp(cube(3,group=>1)); MINIMIZE obj: +1 x1 +1 x2 +1 x3 +1 x4 Subject To ie0: +1 x1 >= 0 ie1: +1 x2 >= 0 ie2: +1 x3 >= 0 ie3: +1 x4 >= 0 eq0: +8 x1 +8 x2 +8 x3 +16 x4 = 48 eq1: -6 x1 +6 x3 +24 x4 = 0 BOUNDS x1 free x2 free x3 free x4 free GENERAL x1 x2 x3 x4 END
The interpretation is as follows: The variables x1,…,x4 correspond to the representatives of interior simplices:
> print cube(3,group=>1)->GROUP->REPRESENTATIVE_MAX_INTERIOR_SIMPLICES; {0 1 2 4} {0 1 2 5} {0 1 2 7} {0 3 5 6}
The solution (x1,x2,x3,x4) = (4,0,0,1) of the LP says that in a minimal triangulation of the 3-cube, there are 4 simplices in the same symmetry class as {0,1,2,4}, and one in the class of {0,3,5,6}.
Various constructions of cones.
inner_cone(Cone p, Set<Int> F)
Computes the inner cone of p at a face F (or a vertex v).
Cone
p
Bool
outer
: Make it point outside the polytope? Default value is 0 (= point inside)
Bool
attach
: Attach the cone to F? Default 0 (ie, return the cone inside the hyperplane at infinity)
To compute the inner cone at a vertex of the 3-cube, do this:
> $c = inner_cone(cube(3), 1); > print $c->RAYS; -1 0 0 0 1 0 0 0 1
To compute the inner cone along an edge of the 3-cube, and make it point outside the polytope, do this:
> print inner_cone(cube(3), [0,1], outer=>1)->RAYS; 0 0 -1 0 -1 0
If you want to attach the cone to the polytope, specify the corresponding option:
> print normal_cone(cube(3), [0,1], attach=>1)->RAYS; 1 -1 -1 -1 1 1 -1 -1 0 0 1 0 0 0 0 1
normal_cone(PointConfiguration p, Set<Int> F)
Computes the normal cone of p at a face F (or vertex v). By default this is the inner normal cone.
Bool
outer
: Calculate outer normal cone? Default value is 0 (= inner)
Bool
attach
: Attach the cone to F? Default 0 (ie, return the cone inside the hyperplane at infinity)
To compute the outer normal cone of a doubled 2-cube, do this:
> $v = cube(2)->VERTICES; > $p = new PointConfiguration(POINTS=>($v/$v)); > print normal_cone($p, 4, outer=>1)->RAYS; 0 -1 -1 0
normal_cone(Cone p, Set<Int> F)
Computes the normal cone of p at a face F (or a vertex v). By default this is the inner normal cone.
Cone
p
Bool
outer
: Calculate outer normal cone? Default value is 0 (= inner)
Bool
attach
: Attach the cone to F? Default 0 (ie, return the cone inside the hyperplane at infinity)
To compute the outer normal cone at a vertex of the 3-cube, do this:
> $c = normal_cone(cube(3), 0, outer=>1); > print $c->RAYS; -1 0 0 0 -1 0 0 0 -1
To compute the outer normal cone along an edge of the 3-cube, do this:
> print normal_cone(cube(3), [0,1], outer=>1)->RAYS; 0 -1 0 0 0 -1
If you want to attach the cone to the polytope, specify the corresponding option:
> print normal_cone(cube(3), [0,1], outer=>1, attach=>1)->RAYS; 1 -1 -1 -1 1 1 -1 -1 0 0 -1 0 0 0 0 -1
recession_cone(Polytope<Scalar> P)
retuns the recession cone (tail cone, characteristic cone) of a polytope
subcone(Cone C)
Make a subcone from a cone.
Cone
C
: the input cone
Bool
no_labels
: Do not create RAY_LABELS
. default: 0
Constructing a point configuration, either from scratch or from existing objects.
minkowski_sum(PointConfiguration P1, PointConfiguration P2)
Produces the Minkowski sum of P1 and P2.
> $P1 = new PointConfiguration(POINTS=>simplex(2)->VERTICES); > $P2 = new PointConfiguration(POINTS=>[[1,1,1],[1,-1,1],[1,1,-1],[1,-1,-1],[1,0,0]]); > $m = minkowski_sum($P1,$P2); > print $m->POINTS; 1 1 1 1 -1 1 1 1 -1 1 -1 -1 1 0 0 1 2 1 1 0 1 1 2 -1 1 0 -1 1 1 0 1 1 2 1 -1 2 1 1 0 1 -1 0 1 0 1
minkowski_sum(Scalar lambda, PointConfiguration P1, Scalar mu, PointConfiguration P2)
Produces the polytope lambda*P1+mu*P2, where * and + are scalar multiplication and Minkowski addition, respectively.
Scalar
lambda
Scalar
mu
> $P1 = new PointConfiguration(POINTS=>simplex(2)->VERTICES); > $P2 = new PointConfiguration(POINTS=>[[1,1,1],[1,-1,1],[1,1,-1],[1,-1,-1],[1,0,0]]); > $m = minkowski_sum(1,$P1,3,$P2); > print $m->POINTS; 1 3 3 1 -3 3 1 3 -3 1 -3 -3 1 0 0 1 4 3 1 -2 3 1 4 -3 1 -2 -3 1 1 0 1 3 4 1 -3 4 1 3 -2 1 -3 -2 1 0 1
Polytope constructions which take graphs as input.
chain_polytope(PartiallyOrderedSet L, Bool is_extended)
Chain polytope of a poset. See Stanley, Discr Comput Geom 1 (1986).
Bool
is_extended
: interpret input as extended poset and ignore top and bottom node
flow_polytope<Scalar>(GraphAdjacency<Directed> G, EdgeMap<Directed,Scalar> Arc_Bounds, Int source, Int sink)
Produces the flow polytope of a directed Graph G=(V,E) with a given source and sink. The flow polytope has the following outer description: forall v in V-{source, sink}: sum_{e in E going into v} x_e
sum_{e in E going into source} x_e
sum_{e in E going into sink} x_e
forall e in E: x_e ⇐ given bound on edge e
flow_polytope<Scalar>(Graph<Directed> G, Array<Scalar> Arc_Bounds, Int source, Int sink)
Produces the flow polytope of a directed Graph G=(V,E) with a given source and sink. The flow polytope has the following outer description: forall v in V-{source, sink}: sum_{e in E going into v} x_e
sum_{e in E going into source} x_e
sum_{e in E going into sink} x_e
forall e in E: x_e ⇐ given bound on edge e
fractional_matching_polytope(Graph G)
Matching polytope of an undirected graph.
Graph
G
order_polytope(PartiallyOrderedSet L, Bool is_extended)
Order polytope of a poset. See Stanley, Discr Comput Geom 1 (1986).
Bool
is_extended
: interpret input as extended poset and ignore top and bottom node
tutte_lifting(Graph G)
Let G be a 3-connected planar graph. If the corresponding polytope contains a triangular facet (ie. the graph contains a non- separating cycle of length 3), the client produces a realization in R3.
Graph
G
weighted_digraph_polyhedron(Matrix encoding)
Weighted digraph polyhedron of a directed graph with a weight function as studied in Joswig, Loho: Weighted digraph polyhedra and tropical cones, LAA (2016). The graph and the weight function are combined into a matrix.
Matrix
encoding
: weighted digraph
This digraph has two nodes and a single arc (with weight 2).
> $enc = new Matrix([[0,2],["inf",0]]); > $Q = weighted_digraph_polyhedron($enc); > print $Q->FACETS; 2 -1 1 1 0 0
These are the one defining inequality and the trivial inequality, which contains the far face.
Polytope constructions which take other big objects as input.
billera_lee(Vector<Integer> H)
Produces a simplicial polytope whose H-vector is the given input vector. The G-vector coming from the given vector must be an M-sequence. This is an implementation of the algorithm described in the paper “A Proof of the Sufficiency of McMullen’s Conditions of Simplicial Convex Polytopes” by Louis Billera and Carl Lee, DOI: 10.1016/0097-3165(81)90058-3
> $p = billera_lee([1,5,15,15,5,1]); > print $p->H_VECTOR; 1 5 15 15 5 1
An important way of constructing polytopes is to modify an already existing polytope. Actually, these functions don't alter the input polytope (it is forbidden in polymake), but create a new polytope object. Many functions can at your choice either calculate the vertex or facet coordinates, or constrain themselves on the purely combinatorial description of the resulting polytope.
bipyramid(Polytope P, Scalar z, Scalar z_prime)
Make a bipyramid over a pointed polyhedron. The bipyramid is the convex hull of the input polyhedron P and two points (v, z), (v, z_prime) on both sides of the affine span of P. For bounded polyhedra, the apex projections v to the affine span of P coincide with the vertex barycenter of P.
Polytope
P
Scalar
z
: distance between the vertex barycenter and the first apex, default value is 1.
Scalar
z_prime
: distance between the vertex barycenter and the second apex, default value is -z.
Bool
no_coordinates
: : don't compute the coordinates, purely combinatorial description is produced.
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytope. default: 0 label the new vertices with “Apex” and “Apex'”.
Here's a way to construct the 3-dimensional cross polytope:
> $p = bipyramid(bipyramid(cube(1))); > print equal_polyhedra($p,cross(3)); true
blending(Polytope P1, Int v1, Polytope P2, Int v2)
Compute the blending of two polyhedra at simple vertices. This is a slightly less standard construction. A vertex is simple if its vertex figure is a simplex. Moving a vertex v of a bounded polytope to infinity yields an unbounded polyhedron with all edges through v becoming mutually parallel rays. Do this to both input polytopes P1 and P2 at simple vertices v1 and v2, respectively. Up to an affine transformation one can assume that the orthogonal projections of P1 and P2 in direction v1 and v2, respectively, are mutually congruent. Any bijection b from the set of edges through v1 to the edges through v2 uniquely defines a way of glueing the unbounded polyhedra to obtain a new bounded polytope, the blending with respect to b. The bijection is specified as a permutation of indices 0 1 2 etc. The default permutation is the identity. The number of vertices of the blending is the sum of the numbers of vertices of the input polytopes minus 2. The number of facets is the sum of the numbers of facets of the input polytopes minus the dimension. The resulting polytope is described only combinatorially.
Polytope
P1
Int
v1
: the index of the first vertex
Polytope
P2
Int
v2
: the index of the second vertex
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytopes. default: 0
The following gives the smallest EVEN
3-polytope which is not a zonotope.
> $c = cube(3); $bc = blending($c,0,$c,0); > print $bc->EVEN true
> print $bc->F_VECTOR 14 21 9
cayley_embedding(Polytope P_0, Polytope P_1, Scalar t_0, Scalar t_1)
Create a Cayley embedding of two polytopes (one of them must be pointed). The vertices of the first polytope P_0 get embedded to (t_0,0) and the vertices of the second polytope P_1 to (0,t_1). Default values are t_0=t_1=1.
Polytope
P_0
: the first polytope
Polytope
P_1
: the second polytope
Scalar
t_0
: the extra coordinate for the vertices of P_0
Scalar
t_1
: the extra coordinate for the vertices of P_1
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytope. default: 0
cayley_embedding(Array<Polytope> A)
Create a Cayley embedding of an array (P1,…,Pm) of polytopes. All polytopes must have the same dimension, at least one of them must be pointed, and all must be defined over the same number type. Each vertex v of the i-th polytope is embedded to v|t_i e_i, where t_i is the i-th entry of the optional array t.
Array<Scalar>
factors
: array of scaling factors for the Cayley embedding; defaults to the all-1 vector
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytope. default: 0
cayley_polytope(Array<Polytope> P_Array)
Construct the cayley polytope of a set of pointed lattice polytopes contained in P_Array which is the convex hull of P1×e1, …, Pk×ek where e1, …,ek are the standard unit vectors in Rk. In this representation the last k coordinates always add up to 1. The option proj projects onto the complement of the last coordinate.
Bool
proj
cell_from_subdivision(Polytope P, Int cell)
Extract the given cell of the subdivision of a polyhedron and write it as a new polyhedron.
Polytope
P
Int
cell
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytope. default: 0
First we create a nice subdivision for our favourite 2-polytope, the square:
> $p = cube(2); > $p->POLYTOPAL_SUBDIVISION(MAXIMAL_CELLS=>[[0,1,3],[1,2,3]]);
Then we extract the [1,2,3]-cell, copying the vertex labels.
> $c = cell_from_subdivision($p,1); > print $c->VERTICES; 1 1 -1 1 -1 1 1 1 1
> print $c->VERTEX_LABELS; 1 2 3
cells_from_subdivision(Polytope<Scalar> P, Set<Int> cells)
Extract the given cells of the subdivision of a polyhedron and create a new polyhedron that has as vertices the vertices of the cells.
Polytope<Scalar>
P
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytope. default: 0
Polytope<Scalar>
First we create a nice subdivision for a small polytope:
> $p = new Polytope(VERTICES=>[[1,0,0],[1,0,1],[1,1,0],[1,1,1],[1,3/2,1/2]]); > $p->POLYTOPAL_SUBDIVISION(MAXIMAL_CELLS=>[[0,1,3],[1,2,3],[2,3,4]]);
Then we create the polytope that has as vertices the vertices from cell 1 and 2, while keeping their labels.
> $c = cells_from_subdivision($p,[1,2]); > print $c->VERTICES; 1 0 1 1 1 0 1 1 1 1 3/2 1/2
> print $c->VERTEX_LABELS; 1 2 3 4
conv(Array<Polytope> P_Array)
Construct a new polyhedron as the convex hull of the polyhedra given in P_Array.
> $p = conv([cube(2,1,0),cube(2,6,5)]); > print $p->VERTICES; 1 0 0 1 1 0 1 0 1 1 6 5 1 5 6 1 6 6
conway(Polytope P, String operations)
Applies a sequence of Conway operations to the polytope P (from left to right)
Polytope
P
String
operations
: 'd': conway operation dual 'a': conway operation ambo 'k': conway operation kis 's': conway operation snub 'g': conway operation gyro 'n': conway operation needle 'z': conway operation zip 'j': conway operation join 't': conway operation truncate 'e': conway operation expand 'o': conway operation ortho 'm': conway operation meta 'b': conway operation bevel
> $s = simplex(3); > $as = conway($s, "a"); > print isomorphic(octahedron(),$as); true
> $ss = conway($s, "s"); > print isomorphic(icosahedron(),$ss); true
> $mjzkab_s = conway($s, "mjzkab"); > print $mjzkab_s->F_VECTOR; 5184 7776 2594
conway_CG(Polytope P, Int k, Int l)
Perform the Coxeter-Goldberg (CG) construction with the given simplicial 3-polytope P and the nonnegative integer parameters k,l where k>l. If P is an icosahedron, then this construction yields a dual Goldberg polyhedron. The Goldberg polyhedra and their duals are used by Kaspar and Klug to give the first classification of viral capsids. For more on CG constrution, see Chapter 6 of Deza, M. and Sikiric, M. and Shtogrin, M. (2015) “Geometric Structure of Chemistry-Relevant Graphs,” In Forum for Interdisciplinary Mathematics, Vol 1, Springer, https://doi.org/10.1007/978-81-322-2449-5 For more on viral capsids, see Caspar, D.L. and Klug, A. (1962) “Physical principles in the construction of regular viruses” In Cold Spring Harbor symposia on quantitative biology, vol. 27, pp. 1-24, https://doi.org/10.1101/sqb.1962.027.001.005
conway_ambo(Polytope P)
Produces Ambo of a 3-polytope (Conway notation 'a')
conway_dual(Polytope P)
Produces dual of a 3-polytope (Conway notation 'd')
Polytope
P
conway_gyro(Polytope P)
Produces Gyro of a 3-polytope (Conway notation 'g')
Polytope
P
conway_kis(Polytope P)
Produces Kis of a 3-polytope (Conway notation 'k')
Polytope
P
conway_needle(Polytope P)
Produces Needle of a 3-polytope (Conway notation 'n')
Polytope
P
conway_propeller(Polytope P)
Produces Propeller of a 3-polytope (Conway notation 'p')
Polytope
P
conway_seed()
Produces Conway Seed (3-cube) (Conway notation 'S')
conway_snub(Polytope P)
Produces Snub of a 3-polytope (Conway notation 's')
dual_linear_program(Polytope P, Bool maximize)
Produces the dual linear program for a given linear program of the form min {cx | Ax >= b, Bx = d}. Here (A,b) are given by the FACETS (or the INEQAULITIES), and (B,d) are given by the AFFINE_HULL (or by the EQUATIONS) of the polytope P, while the objective function c comes from an LP subobject.
edge_middle(Polytope P)
Produce the convex hull of all edge middle points of some polytope P. The polytope must be BOUNDED
.
Polytope
P
face(Cone P, Set S)
For a given set S of rays compute the smallest face F of a cone P containing them all; see also face_pair.
Cone
P
Set
S
Bool
no_coordinates
: don't copy the coordinates, produce purely combinatorial description.
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytope. default: 0
To create a cone from the vertices of the zeroth facet of the 3-cube, type this:
> $p = face(cube(3),[0,1]);
facet(Cone P, Int facet)
Extract the given facet of a polyhedron and write it as a new polyhedron.
Cone
P
Int
facet
Bool
no_coordinates
: don't copy the coordinates, produce purely combinatorial description.
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytope. default: 0
To create a cone from the vertices of the zeroth facet of the 3-cube, type this:
> $p = facet(cube(3),0);
facet_to_infinity(Polytope P, Int i)
Make an affine transformation such that the i-th facet is transformed to infinity
free_sum(Polytope P1, Polytope P2)
Construct a new polyhedron as the free sum of two given bounded ones.
Polytope
P1
Polytope
P2
Bool
force_centered
: if the input polytopes must be centered. Defaults to true.
Bool
no_coordinates
: produces a pure combinatorial description. Defaults to false.
> $p = free_sum(cube(2),cube(2)); > print $p->VERTICES; 1 -1 -1 0 0 1 1 -1 0 0 1 -1 1 0 0 1 1 1 0 0 1 0 0 -1 -1 1 0 0 1 -1 1 0 0 -1 1 1 0 0 1 1
free_sum_decomposition(Polytope P)
Decompose a given polytope into the free sum of smaller ones
Polytope
P
free_sum_decomposition_indices(Polytope P)
Decompose a given polytope into the free sum of smaller ones, and return the vertex indices of the summands
gc_closure(Polytope P)
Computes the Gomory-Chvátal closure of a full dimensional polyhedron. See Schrijver, Theory of Linear and Integer programming (Wiley 1986), §23.1.
Polytope
P
integer_hull(Polytope P)
Produces the integer hull of a polyhedron
intersection(Cone C …)
Construct a new polyhedron or cone as the intersection of given polyhedra and/or cones. Works only if all CONE_AMBIENT_DIM
values are equal. If the input contains both cones and polytopes, the output will be a polytope.
join_polytopes(Polytope P1, Polytope P2)
Construct a new polyhedron as the join of two given bounded ones.
Polytope
P1
Polytope
P2
Bool
no_coordinates
: produces a pure combinatorial description.
Bool
group
: Compute the canonical group induced by the groups on P1 and P2 Throws an exception if the GROUPs of the input polytopes are not provided. default 0
To join two squares, use this:
> $p = join_polytopes(cube(2),cube(2)); > print $p->VERTICES; 1 -1 -1 -1 0 0 1 1 -1 -1 0 0 1 -1 1 -1 0 0 1 1 1 -1 0 0 1 0 0 1 -1 -1 1 0 0 1 1 -1 1 0 0 1 -1 1 1 0 0 1 1 1
lattice_bipyramid(Polytope P, Vector v, Vector v_prime, Rational z, Rational z_prime)
Make a lattice bipyramid over a polyhedron. The bipyramid is the convex hull of the input polyhedron P and two points (v, z), (v_prime, z_prime) on both sides of the affine span of P.
Polytope
P
Vector
v
: basis point for the first apex
Vector
v_prime
: basis for the second apex If v_prime is omitted, v will be used for both apices. If both v and v_prime are omitted, it tries to find two vertices which don't lie in a common facet. If no such vertices can be found or P is a simplex, it uses an interior lattice point as both v and v_prime.
Rational
z
: height for the first apex, default value is 1
Rational
z_prime
: height for the second apex, default value is -z
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytope. default: 0 label the new vertices with “Apex” and “Apex'”.
To create the bipyramid over a square and keep the vertex labels, do this:
> $p = lattice_bipyramid(cube(2),new Vector(1,0,0)); > print $p->VERTICES; 1 -1 -1 0 1 1 -1 0 1 -1 1 0 1 1 1 0 1 0 0 1 1 0 0 -1
> print $p->VERTEX_LABELS; 0 1 2 3 Apex Apex'
lattice_pyramid(Polytope P, Rational z, Vector v)
Make a lattice pyramid over a polyhedron. The pyramid is the convex hull of the input polyhedron P and a point v outside the affine span of P.
Polytope
P
Rational
z
: the height for the apex (v,z), default value is 1.
Vector
v
: the lattice point to use as apex, default is the first vertex of P.
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytope. default: 0 label the new top vertex with “Apex”.
To create the pyramid of height 5 over a square and keep the vertex labels, do this:
> $p = lattice_pyramid(cube(2),5,new Vector(1,0,0)); > print $p->VERTICES; 1 -1 -1 0 1 1 -1 0 1 -1 1 0 1 1 1 0 1 0 0 5
> print $p->VERTEX_LABELS; 0 1 2 3 Apex
lawrence(Cone P)
Create the Lawrence polytope $ Lambda(P) $ corresponding to P. $ Lambda(P) $ has the property that $ Gale( Lambda(P) ) = Gale(P) union -Gale(P) $.
Cone
P
: an input cone or polytope
make_totally_dual_integral(Polytope P)
Computes a polyhedron with an totally dual integral inequality formulation of a full dimensional polyhedron. See Schrijver, Theory of Linear and Integer programming (Wiley 1986), §22.3.
Polytope
P
mapping_polytope(Polytope P1, Polytope P2)
Construct a new polytope as the mapping polytope of two polytopes P1 and P2. The mapping polytope is the set of all affine maps from Rp to Rq, that map P1 into P2. Mapping polytopes are also called Hom-polytopes; cf. Bogart, Contois & Gubeladze, doi:10.1007/s00209-012-1053-5. The label of a new facet corresponding to v1 and h1 will have the form “v1*h1”.
Polytope
P1
Polytope
P2
Bool
no_labels
: Do not assign FACET_LABELS
. default: 0
Let us look at the mapping polytope of the unit interval and the standard unimodular triangle.
> $I=simplex(1); $T=simplex(2); $Hom_IT=mapping_polytope($I,$T);
The dimension equals (dim I + 1) * dim T.
> print $Hom_IT->DIM 4
> print rows_labeled($Hom_IT->FACETS,$Hom_IT->FACET_LABELS); v0*F0:1 -1 0 -1 0 v0*F1:0 1 0 0 0 v0*F2:0 0 0 1 0 v1*F0:1 -1 -1 -1 -1 v1*F1:0 1 1 0 0 v1*F2:0 0 0 1 1
> print $Hom_IT->N_VERTICES; 9
This is how to turn, e.g., the first vertex into a linear map.
> $v=$Hom_IT->VERTICES->[0]; > $M=new Matrix([$v->slice([1..2]),$v->slice([3..4])]); > print $I->VERTICES * transpose($M); 0 0 0 1
The above are coordinates in R^2, without the homogenization commonly used in polymake.
minkowski_sum(Polytope P1, Polytope P2)
Produces the Minkowski sum of P1 and P2.
minkowski_sum(Scalar lambda, Polytope P1, Scalar mu, Polytope P2)
Produces the polytope lambda*P1+mu*P2, where * and + are scalar multiplication and Minkowski addition, respectively.
Scalar
lambda
Polytope
P1
Scalar
mu
Polytope
P2
The following stores the minkowski sum of a scaled square and a triangle in the variable $p and then prints its vertices.
> $p = minkowski_sum(2,cube(2),1,simplex(2)); > print $p->VERTICES; 1 -2 -2 1 3 -2 1 -2 3 1 3 2 1 2 3
minkowski_sum_fukuda(Array<Polytope> summands)
Computes the (VERTICES
of the) Minkowski sum of a list of polytopes using the algorithm by Fukuda described in
> Komei Fukuda, From the zonotope construction to the Minkowski addition of convex polytopes, J. Symbolic Comput., 38(4):1261-1272, 2004.
> $p = minkowski_sum_fukuda([cube(2),simplex(2),cross(2)]); > print $p->VERTICES; 1 3 -1 1 3 1 1 -1 -2 1 1 3 1 -1 3 1 2 -2 1 -2 2 1 -2 -1
mixed_integer_hull(Polytope P, Array<Int> int_coords)
Produces the mixed integer hull of a polyhedron
Polytope
P
pointed_part(Polytope P)
Produces the pointed part of a polyhedron
prism(Polytope P, Scalar z1, Scalar z2)
Make a prism over a pointed polyhedron. The prism is the product of the input polytope P and the interval [z1, z2].
Polytope
P
: the input polytope
Scalar
z1
: the left endpoint of the interval; default value: -1
Scalar
z2
: the right endpoint of the interval; default value: -z1
Bool
group
: Compute the canonical group induced by the group on P with an extra generator swapping the upper and lower copy. throws an exception if GROUP of P is not provided. default 0
Bool
no_coordinates
: only combinatorial information is handled
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytope. default: 0 the bottom facet vertices get the labels from the original polytope; the labels of their clones in the top facet get a tick (') appended.
The following saves the prism over the square and the interval [-2,2] to the variable $p, and then prints a nice representation of its vertices.
> $p = prism(cube(2),-2); > print rows_labeled($p->VERTICES,$p->VERTEX_LABELS); 0:1 -1 -1 -2 1:1 1 -1 -2 2:1 -1 1 -2 3:1 1 1 -2 0':1 -1 -1 2 1':1 1 -1 2 2':1 -1 1 2 3':1 1 1 2
product(Polytope P1, Polytope P2)
Construct a new polytope as the product of two given polytopes P1 and P2. As little additional properties of the input polytopes as possible are computed. You can control this behaviour using the option flags.
Polytope
P1
Polytope
P2
Bool
no_coordinates
: only combinatorial information is handled
Bool
no_vertices
: do not compute vertices
Bool
no_facets
: do not compute facets
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytopes, if present. the label of a new vertex corresponding to v1 ⊕ v2 will have the form LABEL_1*LABEL_2. default: 0
Bool
group
: Compute the canonical group of the product, as induced by the groups on FACETS of VERTICES of P1 and P2. If neither FACETS_ACTION nor VERTICES_ACTION of the GROUPs of the input polytopes are provided, an exception is thrown. default 0
The following builds the product of a square and an interval, without computing vertices of neither the input nor the output polytopes.
> $p = product(cube(2),cube(1), no_vertices=>1);
project_full(Cone P)
Orthogonally project a polyhedron to a coordinate subspace such that redundant columns are omitted, i.e., the projection becomes full-dimensional without changing the combinatorial type. The client scans for all coordinate sections and produces proper output from each. If a description in terms of inequalities is found, the client performs Fourier-Motzkin elimination unless the nofm option is set. Setting the nofm option is useful if the corank of the projection is large; in this case the number of inequalities produced grows quickly.
Cone
P
Bool
nofm
: suppresses Fourier-Motzkin elimination
Bool
no_labels
: Do not copy VERTEX_LABELS
to the projection. default: 0
projection(Cone P, Array<Int> indices)
Orthogonally project a pointed polyhedron to a coordinate subspace. The subspace the polyhedron P is projected on is given by indices in the set indices. The option revert inverts the coordinate list. The client scans for all coordinate sections and produces proper output from each. If a description in terms of inequalities is found, the client performs Fourier-Motzkin elimination unless the nofm option is set. Setting the nofm option is useful if the corank of the projection is large; in this case the number of inequalities produced grows quickly.
Cone
P
Bool
revert
: inverts the coordinate list
Bool
nofm
: suppresses Fourier-Motzkin elimination
project the 3-cube along the first coordinate, i.e. to the subspace spanned by the second and third coordinate:
> $p = projection(cube(3),[1],revert=>1); > print $p->VERTICES; 1 1 -1 1 1 1 1 -1 1 1 -1 -1
projection_preimage(Array<Cone> P_Array)
Construct a new polyhedron that projects to a given array of polyhedra. If the n polyhedra are d_1, d_2, …, d_n-dimensional and all have m vertices, the resulting polyhedron is (d_1+…+d_n)-dimensional, has m vertices, and the projection to the i-th d_i coordinates gives the i-th input polyhedron.
> $p = projection_preimage(cube(2),cube(2)); > print $p->VERTICES; 1 -1 -1 -1 -1 1 1 -1 1 -1 1 -1 1 -1 1 1 1 1 1 1
pyramid(Polytope P, Scalar z)
Make a pyramid over a polyhedron. The pyramid is the convex hull of the input polyhedron P and a point v outside the affine span of P. For bounded polyhedra, the projection of v to the affine span of P coincides with the vertex barycenter of P.
Polytope
P
Scalar
z
: is the distance between the vertex barycenter and v, default value is 1.
Bool
group
: compute the group induced by the GROUP of P and leaving the apex fixed. throws an exception if GROUP of P is not provided. default 0
Bool
no_coordinates
: don't compute new coordinates, produce purely combinatorial description.
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytope. default: 0 label the new top vertex with “Apex”.
The following saves the pyramid of height 2 over the square to the variable $p. The vertices are relabeled.
> $p = pyramid(cube(2),2);
To print the vertices and vertex labels of the newly generated pyramid, do this:
> print $p->VERTICES; 1 -1 -1 0 1 1 -1 0 1 -1 1 0 1 1 1 0 1 0 0 2
> print $p->VERTEX_LABELS; 0 1 2 3 Apex
rand_inner_points(Polytope P, Int n)
Produce a polytope with n random points from the input polytope P. Each generated point is a convex linear combination of the input vertices with uniformly distributed random coefficients. Thus, the output points can't in general be expected to be distributed uniformly within the input polytope; cf. unirand
for this. The polytope must be BOUNDED
.
rand_vert(Matrix V, Int n)
Selects n random vertices from the set of vertices V. This can be used to produce random polytopes which are neither simple nor simplicial as follows: First produce a simple polytope (for instance at random, by using rand_sphere, rand, or unirand). Then use this client to choose among the vertices at random. Generalizes random 0/1-polytopes.
spherize(Polytope P)
stack(Polytope P, Set<Int> stack_facets)
Stack a (simplicial or cubical) polytope over one or more of its facets. For each facet of the polytope P specified in stack_facets, the barycenter of its vertices is lifted along the normal vector of the facet. In the simplicial case, this point is directly added to the vertex set, thus building a pyramid over the facet. In the cubical case, this pyramid is truncated by a hyperplane parallel to the original facet at its half height. This way, the property of being simplicial or cubical is preserved in both cases. The option lift controls the exact coordinates of the new vertices. It should be a rational number between 0 and 1, which expresses the ratio of the distance between the new vertex and the stacked facet, to the maximal possible distance. When lift=0, the new vertex would lie on the original facet. lift=1 corresponds to the opposite extremal case, where the new vertex hit the hyperplane of some neighbor facet. As an additional restriction, the new vertex can't lie further from the facet as the vertex barycenter of the whole polytope. Alternatively, the option noc (no coordinates) can be specified to produce a pure combinatorial description of the resulting polytope.
Polytope
P
Rational
lift
: controls the exact coordinates of the new vertices; rational number between 0 and 1; default value: 1/2
Bool
no_coordinates
: produces a pure combinatorial description (in contrast to lift)
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytope. default: 0 New vertices get labels 'f(FACET_LABEL)' in the simplicial case, and 'f(FACET_LABEL)-NEIGHBOR_VERTEX_LABEL' in the cubical case.
To generate a cubical polytope by stacking all facets of the 3-cube to height 1/4, do this:
> $p = stack(cube(3),All,lift=>1/4);
stellar_all_faces(Polytope P, Int d)
Perform a stellar subdivision of all proper faces, starting with the facets. Parameter d specifies the lowest dimension of the faces to be divided. It can also be negative, then treated as the co-dimension. Default is 1, that is, the edges of the polytope.
stellar_indep_faces(Polytope P, Array<Set<Int>> in_faces)
Perform a stellar subdivision of the faces in_faces of a polyhedron P. The faces must have the following property: The open vertex stars of any pair of faces must be disjoint.
Polytope
P
: , must be bounded
tensor(Polytope P1, Polytope P2)
Construct a new polytope as the convex hull of the tensor products of the vertices of two polytopes P1 and P2. Unbounded polyhedra are not allowed. Does depend on the vertex coordinates of the input.
truncation(Polytope P, Set<Int> trunc_vertices)
Cut off one or more vertices of a polyhedron. The exact location of the cutting hyperplane(s) can be controlled by the option cutoff, a rational number between 0 and 1. When cutoff=0, the hyperplane would go through the chosen vertex, thus cutting off nothing. When cutoff=1, the hyperplane touches the nearest neighbor vertex of a polyhedron. Alternatively, the option no_coordinates can be specified to produce a pure combinatorial description of the resulting polytope, which corresponds to the cutoff factor 1/2.
Polytope
P
Scalar
cutoff
: controls the exact location of the cutting hyperplane(s); rational number between 0 and 1; default value: 1/2
Bool
no_coordinates
: produces a pure combinatorial description (in contrast to cutoff)
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytope. default: 0 New vertices get labels of the form 'LABEL1-LABEL2', where LABEL1 is the original label of the truncated vertex, and LABEL2 is the original label of its neighbor.
To truncate the second vertex of the square at 1/4, try this:
> $p = truncation(cube(2),2,cutoff=>1/4); > print $p->VERTICES; 1 -1 -1 1 1 -1 1 1 1 1 -1 1/2 1 -1/2 1
unirand(Polytope P, Int n)
Produce a polytope with n random points that are uniformly distributed within the given polytope P. P must be bounded and full-dimensional.
Polytope
P
Int
n
: the number of random points
Bool
boundary
: forces the points to lie on the boundary of the given polytope
Int
seed
: controls the outcome of the random number generator; fixing a seed number guarantees the same outcome.
This produces a polytope as the convex hull of 5 random points in the square with the origin as its center and side length 2:
> $p = unirand(cube(2),5);
This produces a polytope as the convex hull of 5 random points on the boundary of the square with the origin as its center and side length 2:
> $p = unirand(cube(2),5,boundary=>1);
vertex_figure(Polytope p, Int n)
Construct the vertex figure of the vertex n of a polyhedron. The vertex figure is dual to a facet of the dual polytope.
Polytope
p
Int
n
: number of the chosen vertex
Scalar
cutoff
: controls the exact location of the cutting hyperplane. It should lie between 0 and 1. Value 0 would let the hyperplane go through the chosen vertex, thus degenerating the vertex figure to a single point. Value 1 would let the hyperplane touch the nearest neighbor vertex of a polyhedron. Default value is 1/2.
Bool
no_coordinates
: skip the coordinates computation, producing a pure combinatorial description.
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytope. default: 0 by default, the labels are produced from the corresponding neighbor vertices of the original polytope.
This produces a vertex figure of one vertex of a 3-dimensional cube with the origin as its center and side length 2. The result is a 2-simplex.
> $p = vertex_figure(cube(3),5); > print $p->VERTICES; 1 1 -1 0 1 0 -1 1 1 1 0 1
wedge(Polytope P, Int facet, Rational z, Rational z_prime)
Make a wedge from a polytope over the given facet. The polytope must be bounded. The inclination of the bottom and top side facet is controlled by z and z_prime, which are heights of the projection of the old vertex barycenter on the bottom and top side facet respectively.
Polytope
P
: , must be bounded
Int
facet
: the `cutting edge'.
Rational
z
: default value is 0.
Rational
z_prime
: default value is -z, or 1 if z==0.
Bool
no_coordinates
: don't compute coordinates, pure combinatorial description is produced.
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytopes. default: 0 By default, the vertices get labelled as follows: The bottom facet vertices obtain the labels from the original polytope; the labels of their clones in the top facet get a tick (') appended.
This produces the wedge from a square (over the facet 0), which yields a prism over a triangle:
> $p = wedge(cube(2),0); > print $p->VERTICES; 1 -1 -1 0 1 1 -1 0 1 -1 1 0 1 1 1 0 1 1 -1 2 1 1 1 2
wreath(Polytope P1, Polytope P2)
Construct a new polytope as the wreath product of two input polytopes P1, P2. P1 and P2 have to be BOUNDED
.
Polytope
P1
Polytope
P2
Bool
dual
: invokes the computation of the dual wreath product
Bool
no_labels
: Do not copy VERTEX_LABELS
from the original polytopes. default: 0 the label of a new vertex corresponding to v1 ⊕ v2 will have the form LABEL_1*LABEL_2.
With these clients you can create polytopes belonging to various parameterized families which occur frequently in polytope theory, as well as several kinds of random polytopes. Regular polytopes and their friends are listed separately.
SIM_body<Scalar>(Vector<Scalar> alpha)
Produce an n-dimensional SIM-body as generalized permutahedron in (n+1)-space. SIM-bodies are defined in the article “Duality and Optimality of Auctions for Uniform Distributions” by Yiannis Giannakopoulos and Elias Koutsoupias, but the input needs to be descending instead of ascending, as used in “Generalized Permutahedra and Optimal Auctions” by Michael Joswig, Max Klimm and Sylvain Spitz.
Scalar
Vector<Scalar>
alpha
: Vector with the parameters (a1,…,an) s.t. a1 >= … >= an >= 0.
To produce a 2-dimensional SIM-body, use for example the following code. Note that the polytope lives in 3-space, so we project it down to 2-space by eliminating the last coordinate.
> $p = SIM_body(new Vector(sequence(3,1))); > $s = new Polytope(POINTS=>$p->VERTICES->minor(All,~[$p->CONE_DIM]));
associahedron(Int d)
Produce a d-dimensional associahedron (or Stasheff polytope). We use the facet description given in Ziegler's book on polytopes, section 9.2.
binary_markov_graph(Array<Bool> observation)
Defines a very simple graph for a polytope propagation related to a Hidden Markov Model. The propagated polytope is always a polygon. For a detailed description see
> M. Joswig: Polytope propagation, in: Algebraic statistics and computational biology
> by L. Pachter and B. Sturmfels (eds.), Cambridge, 2005. ? Parameters: :: ''[[.:common#Array |Array]]<[[.:common#Bool |Bool]]>'' ''observation'' ? Returns: :''[[.:polytope:PropagatedPolytope |PropagatedPolytope]]'' ? **''binary_markov_graph([[.:common#String |String]] observation)''** :: ? Parameters: :: ''[[.:common#String |String]]'' ''observation'': encoded as a string of "0" and "1".
birkhoff(Int n, Bool even)
Constructs the Birkhoff polytope of dimension n2. It is the polytope of nxn stochastic matrices (encoded as n2 row vectors), thus matrices with non-negative entries whose row and column entries sum up to one. Its vertices are the permutation matrices.
cyclic(Int d, Int n)
Produce a d-dimensional cyclic polytope with n points. Prototypical example of a neighborly polytope. Combinatorics completely known due to Gale's evenness criterion. Coordinates are chosen on the (spherical) moment curve at integer steps from start, or 0 if unspecified. If spherical is true the vertices lie on the sphere with center (1/2,0,…,0) and radius 1/2. In this case (the necessarily positive) parameter start defaults to 1.
Int
d
: the dimension
Int
n
: the number of points
Int
start
: defaults to 0 (or to 1 if spherical)
Bool
spherical
: defaults to false
To create the 2-dimensional cyclic polytope with 6 points on the sphere, starting at 3:
> $p = cyclic(2,6,start=>3,spherical=>1); > print $p->VERTICES; 1 1/10 3/10 1 1/17 4/17 1 1/26 5/26 1 1/37 6/37 1 1/50 7/50 1 1/65 8/65
cyclic_caratheodory(Int d, Int n)
Produce a d-dimensional cyclic polytope with n points. Prototypical example of a neighborly polytope. Combinatorics completely known due to Gale's evenness criterion. Coordinates are chosen on the trigonometric moment curve. For cyclic polytopes from other curves, see cyclic
.
Int
d
: the dimension. Required to be even.
Int
n
: the number of points
Bool
group
: add a symmetry group description. If 0 (default), the return type is Polytope<Rational>, else Polytope<Float> so that the matrices corresponding to the symmetry action may be approximated
delpezzo(Int d, Scalar scale)
Produce a d-dimensional del-Pezzo polytope, which is the convex hull of the cross polytope together with the all-ones and minus all-ones vector. All coordinates are +/- scale or 0.
dwarfed_product_polygons(Int d, Int s)
Produce a d-dimensional dwarfed product of polygons of size s.
explicit_zonotope(Matrix zones)
Produce the POINTS of a zonotope as the iterated Minkowski sum of all intervals [-x,x], where x ranges over the rows of the input matrix zones.
Matrix
zones
: the input vectors
Bool
rows_are_points
: the rows of the input matrix represent affine points(true, default) or linear vectors(false)
> $M = new Matrix([1,1],[1,-1]); > $p = explicit_zonotope($M,rows_are_points=>0); > print $p->VERTICES; 1 2 0 1 0 -2 1 0 2 1 -2 0
fano_simplex(Int d)
Produce a Fano d-simplex.
fractional_knapsack(Vector<Rational> b)
Produce a knapsack polytope defined by one linear inequality (and non-negativity constraints).
For the inequality 2x_1 + 3x_2 + 5x_3 ⇐ 10 we compute the facets of the corresponding knapsack polytope (i.e., the integer hull of the fractional knapsack polytope).
> $K = fractional_knapsack([10,-2,-3,-5]); > print $K->FACETS; 10 -2 -3 -5 0 1 0 0 0 0 1 0 0 0 0 1
> $IK = integer_hull($K); > print $IK->FACETS; 0 1 0 0 6 -1 -2 -3 5 -1 -3/2 -5/2 0 0 1 0 0 0 0 1
gelfand_tsetlin<Scalar>(Vector<Scalar> lambda)
Produce a Gelfand-Tsetlin polytope for a given sequence. See Postnikov: Permutohedra, associahedra, and beyond, IMRN (2009); doi:10.1093/imrn/rnn153 Theorem 15.1.
Scalar
Vector<Scalar>
lambda
: Vector encoding a descending sequence of numbers.
Bool
projected
: Omit the redundant first row of equations to reduce dimension, default=false
Create the Gelfand-Tsetlin polytope for the sequence (6,4,2,1)
> $lambda = new Vector(6,4,2,1); > $pgt = gelfand_tsetlin($lambda,projected=>1); > $gt = gelfand_tsetlin($lambda,projected=>0); > print $gt->LATTICE_VOLUME; 14400
> print $pgt->LATTICE_VOLUME; 14400
generalized_permutahedron<Scalar>(Int d, Map<Set<Int>,Scalar> z)
Produce a generalized permutahedron via zI height function. See Postnikov: Permutohedra, associahedra, and beyond, IMRN (2009); doi:10.1093/imrn/rnn153 Note that opposed to Postnikov's paper, polymake starts counting at zero.
Scalar
Int
d
: The dimension
Map<Set<Int>,Scalar>
z
: Values of the height functions for the different 0/1-directions, i.e. for h = height({1,2,4}) we have the inequality x1 + x2 + x4 >= h. The height value for the set containing all coordinates from 0 to d-1 is interpreted as equality. If any value is missing, it will be skipped. Also it is not checked, if the values are consistent for a height function.
To create a generalized permutahedron in 3-space use
> $m = new Map<Set,Rational>; > $m->{new Set(0)} = 0; > $m->{new Set(1)} = 0; > $m->{new Set(2)} = 0; > $m->{new Set(0,1)} = 1/4; > $m->{new Set(0,2)} = 1/4; > $m->{new Set(1,2)} = 1/4; > $m->{new Set(0,1,2)} = 1; > $p = generalized_permutahedron(3,$m);
goldfarb(Int d, Scalar e, Scalar g)
Produces a d-dimensional Goldfarb cube if e<1/2 and g⇐e/4. The Goldfarb cube is a combinatorial cube and yields a bad example for the Simplex Algorithm using the Shadow Vertex Pivoting Strategy. Here we use the description as a deformed product due to Amenta and Ziegler. For e<1/2 and g=0 we obtain the Klee-Minty cubes.
Int
d
: the dimension
Scalar
e
Scalar
g
goldfarb_sit(Int d, Scalar eps, Scalar delta)
Produces a d-dimensional variation of the Klee-Minty cube if eps<1/2 and delta⇐1/2. This Klee-Minty cube is scaled in direction x_(d-i) by (eps*delta)^i. This cube is a combinatorial cube and yields a bad example for the Simplex Algorithm using the 'steepest edge' Pivoting Strategy. Here we use a scaled description of the construction of Goldfarb and Sit.
Int
d
: the dimension
Scalar
eps
Scalar
delta
hypersimplex(Int k, Int d)
Produce the hypersimplex $ Δ(k,d) $, that is the the convex hull of all 0/1-vector in $ R^d $ with exactly k 1s. Note that the output is never full-dimensional.
Int
k
: number of 1s
Int
d
: ambient dimension
Bool
group
Bool
no_vertices
: do not compute vertices
Bool
no_facets
: do not compute facets
Bool
no_vif
: do not compute vertices in facets
This creates the hypersimplex in dimension 4 with vertices with exactly two 1-entries and computes its symmetry group:
> $h = hypersimplex(2,4,group=>1);
hypertruncated_cube<Scalar>(Int d, Scalar k, Scalar lambda)
Produce a d-dimensional hypertruncated cube. With symmetric linear objective function (0,1,1,…,1).
k_cyclic(Int n, Vector s)
Produce a (rounded) 2*k-dimensional k-cyclic polytope with n points, where k is the length of the input vector s. Special cases are the bicyclic (k=2) and tricyclic (k=3) polytopes. Only possible in even dimensions. The parameters s_i can be specified as integer, floating-point, or rational numbers. The coordinates of the i-th point are taken as follows:
> cos(s_1 * 2πi/n),
> sin(s_1 * 2πi/n), > ... > cos(s_k * 2πi/n), > sin(s_k * 2πi/n) .. Warning: Some of the k-cyclic polytopes are not simplicial. Since the components are rounded, this function might output a polytope which is not a k-cyclic polytope! More information can be found in the following references: > P. Schuchert: "Matroid-Polytope und Einbettungen kombinatorischer Mannigfaltigkeiten", > PhD thesis, TU Darmstadt, 1995. .. > Z. Smilansky: "Bi-cyclic 4-polytopes", > Isr. J. Math. 70, 1990, 82-92 ? Parameters: :: ''[[.:common#Int |Int]]'' ''n'': the number of points :: ''[[.:common#Vector |Vector]]'' ''s'': s=(s_1,...,s_k) ? Returns: :''[[.:polytope:Polytope |Polytope]]'' ? Example: :: To produce a (not exactly) regular pentagon, type this: :: <code perl> > $p = k_cyclic(5,[1]);
</code>
klee_minty_cube(Int d, Scalar e)
Produces a d-dimensional Klee-Minty-cube if e<1/2. Uses the goldfarb
client with g=0.
Int
d
: the dimension
Scalar
e
lecture_hall_simplex(Int d)
Produce a lecture hall d-simplex.
long_and_winding(Int r)
Produce polytope in dimension 2r with 3r+2 facets such that the total curvature of the central path is at least Omega(2^r); see Allamigeon, Benchimol, Gaubert and Joswig, SIAM J. Appl. Algebra Geom. (2018). See also perturbed_long_and_winding
.
Int
r
: defining parameter
Rational
eval_ratio
: parameter for evaluating the puiseux rational functions
Int
eval_exp
: to evaluate at eval_ratio^eval_exp, default: 1
Float
eval_float
: parameter for evaluating the puiseux rational functions
This yields a 4-polytope over the field of Puiseux fractions.
> $p = long_and_winding(2);
This yields a rational 4-polytope with the same combinatorics.
> $p = long_and_winding(2,eval_ratio=>2);
max_GC_rank(Int d)
Produce a d-dimensional polytope of maximal Gomory-Chvatal rank $ Omega( d/log(d) ) $ , integrally infeasible. With symmetric linear objective function (0,1,1..,1). Construction due to Pokutta and Schulz.
Int
d
: the dimension
multiplex(Int d, Int n)
Produce a combinatorial description of a multiplex with parameters d and n. This yields a self-dual d-dimensional polytope with n+1 vertices. They are introduced by
> T. Bisztriczky,
> On a class of generalized simplices, Mathematika 43:27-285, 1996, .. see also > M.M. Bayer, A.M. Bruening, and J.D. Stewart, > A combinatorial study of multiplexes and ordinary polytopes, > Discrete Comput. Geom. 27(1):49--63, 2002. ? Parameters: :: ''[[.:common#Int |Int]]'' ''d'': the dimension :: ''[[.:common#Int |Int]]'' ''n'' ? Returns: :''[[.:polytope:Polytope |Polytope]]''
n_gon(Int n, Rational r, Rational alpha_0)
Produce a regular n-gon. All vertices lie on a circle of radius r. The radius defaults to 1.
Int
n
: the number of vertices
Rational
r
: the radius (defaults to 1)
Rational
alpha_0
: the initial angle divided by pi (defaults to 0)
Bool
group
To store the regular pentagon in the variable $p and calculate its symmetry group, do this:
> $p = n_gon(5,group=>1); > print $p->GROUP->RAYS_ACTION->GENERATORS; 0 4 3 2 1 1 2 3 4 0
neighborly_cubical(Int d, Int n)
Produce the combinatorial description of a neighborly cubical polytope. The facets are labelled in oriented matroid notation as in the cubical Gale evenness criterion.
> See Joswig and Ziegler, Discr. Comput. Geom. 24:315-344 (2000).
newton(Polynomial p)
Produce the Newton polytope of a polynomial p.
Create the newton polytope of 1+x^2+y like so:
perles_irrational_8_polytope()
Create an 8-dimensional polytope without rational realizations due to Perles See Grünbaum, Convex polytopes, 2nd ed., Springer (2003), p.94f
permutahedron(Int d)
Produce a d-dimensional permutahedron. The vertices correspond to the elements of the symmetric group of degree d+1.
perturbed_long_and_winding(Int r)
Produce polytope in dimension 2r with 3r+2 facets such that the total curvature of the central path is at least Omega(2^r). This is a perturbed version of long_and_winding
, which yields simple polytopes.
Int
r
: defining parameter
Rational
eval_ratio
: parameter for evaluating the puiseux rational functions
Int
eval_exp
: to evaluate at eval_ratio^eval_exp, default: 1
Float
eval_float
: parameter for evaluating the puiseux rational functions
This yields a simple 4-polytope over the field of Puiseux fractions.
> $p = perturbed_long_and_winding(2);
pile(Vector<Int> sizes)
Produce a (d+1)-dimensional polytope from a pile of cubes. Start with a d-dimensional pile of cubes. Take a generic convex function to lift this polytopal complex to the boundary of a (d+1)-polytope.
pitman_stanley<Scalar>(Vector<Scalar> y)
Produce a Pitman-Stanley polytope of dimension n-1. See Pitman and Stanley, Discrete Comput Geom 27 (2002); doi:10.1007/s00454-002-2776-6
pseudo_delpezzo(Int d, Scalar scale)
Produce a d-dimensional del-Pezzo polytope, which is the convex hull of the cross polytope together with the all-ones vector. All coordinates are +/- scale or 0.
rand01(Int d, Int n)
Produce a d-dimensional 0/1-polytope with n random vertices. Uniform distribution.
rand_box(Int d, Int n, Int b)
Computes the convex hull of n points sampled uniformly at random from the integer points in the cube [0,b]d.
rand_cyclic(Int d, Int n)
Computes a random instance of a cyclic polytope of dimension d on n vertices by randomly generating a Gale diagram whose cocircuits have alternating signs.
rand_metric<Scalar>(Int n)
Produce an n-point metric with random distances. The values are uniformily distributed in [1,2].
rand_metric_int<Scalar>(Int n)
Produce an n-point metric with random distances. The values are uniformily distributed in [1,2].
rand_normal(Int d, Int n)
Produce a rational d-dimensional polytope from n random points approximately normally distributed in the unit ball.
rand_sphere<Num>(Int d, Int n)
Produce a rational d-dimensional polytope with n random vertices approximately uniformly distributed on the unit sphere.
Num
: can be AccurateFloat (the default) or Rational With AccurateFloat
the distribution should be closer to uniform, but the vertices will not exactly be on the sphere. With Rational
the vertices are guaranteed to be on the unit sphere, at the expense of both uniformity and log-height of points.
Int
d
: the dimension of sphere
Int
n
: the number of random vertices
Int
seed
: controls the outcome of the random number generator; fixing a seed number guarantees the same outcome.
Int
precision
: Number of bits for MPFR sphere approximation
rss_associahedron(Int l)
Produce a polytope of constrained expansions in dimension l according to
> Rote, Santos, and Streinu: Expansive motions and the polytope of pointed pseudo-triangulations.
> Discrete and computational geometry, 699--736, Algorithms Combin., 25, Springer, Berlin, 2003. ? Parameters: :: ''[[.:common#Int |Int]]'' ''l'': ambient dimension ? Returns: :''[[.:polytope:Polytope |Polytope]]''
signed_permutahedron(Int d)
Produce a d-dimensional signed permutahedron.
simplex(Int d, Scalar scale)
Produce the standard d-simplex. Combinatorially equivalent to a regular polytope corresponding to the Coxeter group of type Ad-1. Optionally, the simplex can be scaled by the parameter scale.
Int
d
: the dimension
Scalar
scale
: default value: 1
Bool
group
To print the vertices (in homogeneous coordinates) of the standard 2-simplex, i.e. a right-angled isoceles triangle, type this:
> print simplex(2)->VERTICES; (3) (0 1) 1 1 0 1 0 1
The first row vector is sparse and encodes the origin.
To create a 3-simplex and also calculate its symmetry group, type this:
> simplex(3, group=>1);
stable_set(Graph G)
Produces the stable set polytope from an undirected graph G=(V,E). The stable set Polytope has the following inequalities: x_i + x_j ⇐ 1 forall {i,j} in E x_i >= 0 forall i in V x_i ⇐ 1 forall i in V with deg(i)=0
Graph
G
transportation(Vector r, Vector c)
Produce the transportation polytope from two vectors r of length m and c of length n, i.e. all positive m×n Matrizes with row sums equal to r and column sums equal to c.
zonotope(Matrix<Scalar> M)
Create a zonotope from a matrix whose rows are input points or vectors. This method merely defines a Polytope object with the property ZONOTOPE_INPUT_POINTS
.
Matrix<Scalar>
M
: input points or vectors
Bool
rows_are_points
: true if M are points instead of vectors; default true
Bool
centered
: true if output should be centered; default true
Polytope<Scalar>
The following produces a parallelogram with the origin as its vertex barycenter:
> $M = new Matrix([[1,1,0],[1,1,1]]); > $p = zonotope($M); > print $p->VERTICES; 1 0 -1/2 1 0 1/2 1 -1 -1/2 1 1 1/2
The following produces a parallelogram with the origin being a vertex (not centered case):
> $M = new Matrix([[1,1,0],[1,1,1]]); > $p = zonotope($M,centered=>0); > print $p->VERTICES; 1 1 0 1 0 0 1 1 1 1 2 1
zonotope_vertices_fukuda(Matrix M)
Create the vertices of a zonotope from a matrix whose rows are input points or vectors.
Matrix
M
Bool
centered_zonotope
: default 1
The following stores the vertices of a parallelogram with the origin as its vertex barycenter and prints them:
> $M = new Matrix([[1,1,0],[1,1,1]]); > print zonotope_vertices_fukuda($M); 1 0 -1/2 1 0 1/2 1 -1 -1/2 1 1 1/2
A way of constructing vector configurations is to modify an already existing vector configuration.
free_sum(VectorConfiguration P1, VectorConfiguration P2)
Construct the free sum of two vector configurations.
project_full<Scalar>(VectorConfiguration P)
Orthogonally project a vector configuration to a coordinate subspace such that redundant columns are omitted, i.e., the projection becomes full-dimensional without changing the combinatorial type.
Scalar
: coordinate type
Bool
no_labels
: Do not copy VERTEX_LABELS
to the projection. default: 0
project_out<Scalar>(VectorConfiguration V, Matrix B)
Project a vector configuration V along the subspace with the given basis B. The result is still expressed in the original ambient basis. If V is a PointConfiguration and the first column of B is zero, the result is a PointConfiguration, else a VectorConfiguration.
Scalar
: coordinate type
Matrix
B
: a matrix whose rows contain the basis of the space to be projected out
project_out<Scalar>(Cone C, Matrix B)
Project a Cone C along the subspace with the given basis B The result is still expressed in the original ambient basis. If V is a Polytope and the first column of B is zero, the result is a Polytope, else a Cone.
project_to<Scalar>(VectorConfiguration V, Matrix B)
Project a vector configuration V to the subspace with a given basis B and express the result in that basis. A boolean flag make_affine (by default undef) determines whether the resulting coordinates acquire an extra leading '1'. The return type is a VectorConfiguration, unless (i) P is a PointConfiguration, (ii) the first column of B is zero, (iii) make_affine is not 0, in which case it is a PointConfiguration. The return type depends on the input: (1) If V is a VectorConfiguration, the result is also a VectorConfiguration. (2a) If V is a PointConfiguration and all rows in B start with a 0, the result is a PointConfiguration. If, furthermore, make_affine is undef, it is set to 1. (2b) If V is a PointConfiguration and some row of B has a non-zero first entry, the result is a VectorConfiguration. The reasoning here is that B having a zero first column or not influences the hyperplane at infinity.
project_to<Scalar>(Cone C, Matrix B)
Project a Polytope or Cone to the subspace with a given basis, and express the result in that basis A boolean flag make_affine (by default undef) determines whether the resulting coordinates acquire an extra leading '1'. The return type is a Cone, unless (i) P is a Polytope, (ii) the first column of B is zero, (iii) make_affine is not 0, in which case it is a Polytope. If make_affine is undef and (ii) is true, make_affine is set to 1. The reasoning here is that B having a zero first column or not influences the hyperplane at infinity.
projection<Scalar>(VectorConfiguration P, Array<Int> indices)
Orthogonally project a vector configuration to a coordinate subspace. The subspace the VectorConfiguration P is projected on is given by indices in the set indices. The option revert inverts the coordinate list.
Scalar
: coordinate type
Bool
revert
: inverts the coordinate list
projection_preimage<Scalar>(Array<VectorConfiguration> P_Array)
Construct a new vector configuration that projects to a given array of vector configurations If the n vector configurations are d_1, d_2, …, d_n-dimensional and all have m vectors, the resulting vector configuration is (d_1+…+d_n)-dimensional, has m vectors, and the projection to the i-th d_i coordinates gives the i-th input vector configuration.
Scalar
: coordinate type
Array<VectorConfiguration>
P_Array
Functions producing big objects which are not contained in application polytope.
coxeter_group(String type)
Produces the Coxeter group of type type. The Dynkin diagrams of the different types can be found in the description of the clients simple_roots_type_*.
String
type
: the type of the Coxeter group
crosscut_complex(Polytope p)
Produce the crosscut complex of the boundary of a polytope.
Polytope
p
Bool
geometric_realization
: create a GeometricSimplicialComplex
; default is true
This includes the Platonic solids and their generalizations into two directions. In dimension 3 there are the Archimedean, Catalan and Johnson solids. In higher dimensions there are the simplices, the cubes, the cross polytopes and three other regular 4-polytopes.
archimedean_solid(String s)
Create Archimedean solid of the given name. Some polytopes are realized with floating point numbers and thus not exact; Vertex-facet-incidences are correct in all cases.
String
s
: the name of the desired Archimedean solid
To show the mirror image of the snub cube use:
> scale(archimedean_solid('snub_cube'),-1)->VISUAL;
archimedean_solid(Int n)
Create Archimedean solid number n, where 1 ⇐ n ⇐ 13. Some polytopes are realized with floating point numbers and thus not exact; Vertex-facet-incidences are correct in all cases.
Int
n
: the index of the desired Archimedean solid
catalan_solid(String s)
Create Catalan solid of the given name. Some polytopes are realized with floating point numbers and thus not exact; Vertex-facet-incidences are correct in all cases.
String
s
: the name of the desired Catalan solid
catalan_solid(Int n)
Create Catalan solid number n, where 1 ⇐ n ⇐ 13. Some polytopes are realized with floating point numbers and thus not exact; Vertex-facet-incidences are correct in all cases.
Int
n
: the index of the desired Catalan solid
cross<Scalar>(Int d, Scalar scale)
Produce a d-dimensional cross polytope. Regular polytope corresponding to the Coxeter group of type Bd-1 = Cd-1. All coordinates are +/- scale or 0.
Scalar
: Coordinate type of the resulting polytope. Unless specified explicitly, deduced from the type of bound values, defaults to Rational.
Int
d
: the dimension
Scalar
scale
: the absolute value of each non-zero vertex coordinate. Needs to be positive. The default value is 1.
Bool
group
: add a symmetry group description to the resulting polytope
Bool
character_table
: add the character table to the symmetry group description, if 0<d<7; default 1
Polytope<Scalar>
To create the 3-dimensional cross polytope, type
> $p = cross(3);
Check out it's vertices and volume:
> print $p->VERTICES; 1 1 0 0 1 -1 0 0 1 0 1 0 1 0 -1 0 1 0 0 1 1 0 0 -1
> print cross(3)->VOLUME; 4/3
If you rather had a bigger one, type
> $p_scaled = cross(3,2); > print $p_scaled->VOLUME; 32/3
To also calculate the symmetry group, do this:
> $p = cross(3,group=>1);
You can then print the generators of this group like this:
> print $p->GROUP->RAYS_ACTION->GENERATORS; 1 0 2 3 4 5 2 3 0 1 4 5 0 1 4 5 2 3
cube<Scalar>(Int d, Scalar x_up, Scalar x_low)
Produce a d-dimensional cube. Regular polytope corresponding to the Coxeter group of type Bd-1 = Cd-1. The bounding hyperplanes are xi ⇐ x_up and xi >= x_low.
Scalar
: Coordinate type of the resulting polytope. Unless specified explicitly, deduced from the type of bound values, defaults to Rational.
Int
d
: the dimension
Scalar
x_up
: upper bound in each dimension
Scalar
x_low
: lower bound in each dimension
Bool
group
: add a symmetry group description to the resulting polytope
Bool
character_table
: add the character table to the symmetry group description, if 0<d<7; default 1
Polytope<Scalar>
This yields a +/-1 cube of dimension 3 and stores it in the variable $c.
> $c = cube(3);
This stores a standard unit cube of dimension 3 in the variable $c.
> $c = cube(3,0);
This prints the area of a square with side length 4 translated to have its vertex barycenter at [5,5]:
> print cube(2,7,3)->VOLUME; 16
cuboctahedron()
Create cuboctahedron. An Archimedean solid.
dodecahedron()
Create exact regular dodecahedron in Q(sqrt{5}). A Platonic solid.
icosahedron()
Create exact regular icosahedron in Q(sqrt{5}). A Platonic solid.
icosidodecahedron()
Create exact icosidodecahedron in Q(sqrt{5}). An Archimedean solid.
johnson_solid(Int n)
Create Johnson solid number n, where 1 ⇐ n ⇐ 92. A Johnson solid is a 3-polytope all of whose facets are regular polygons. Some are realized with floating point numbers and thus not exact; yet VERTICES_IN_FACETS
is correct in all cases.
Int
n
: the index of the desired Johnson polytope
johnson_solid(String s)
Create Johnson solid with the given name. A Johnson solid is a 3-polytope all of whose facets are regular polygons. Some are realized with floating point numbers and thus not exact; yet VERTICES_IN_FACETS
is correct in all cases.
String
s
: the name of the desired Johnson polytope
octahedron()
Produce a regular octahedron, which is the same as the 3-dimensional cross polytope.
platonic_solid(String s)
Create Platonic solid of the given name.
String
s
: the name of the desired Platonic solid
platonic_solid(Int n)
Create Platonic solid number n, where 1 ⇐ n ⇐ 5.
Int
n
: the index of the desired Platonic solid
reduced(Rational t, Rational x, Rational s, Rational h, Rational r)
Produce a 3-dimensional reduced polytope (for suitably chosen parameters). That is, a polytope of constant width which does not properly contain a subpolytope of the same width. Construction due to Bernardo González Merino, Thomas Jahn, Alexandr Polyanskii and Gerd Wachsmuth, arXiv:1701.08629
regular_120_cell()
Create exact regular 120-cell in Q(sqrt{5}).
regular_24_cell()
Create regular 24-cell.
regular_600_cell()
Create exact regular 600-cell in Q(sqrt{5}).
regular_simplex(Int d)
Produce a regular d-simplex embedded in R^d with edge length sqrt(2).
Int
d
: the dimension
Bool
group
To print the vertices (in homogeneous coordinates) of the regular 2-simplex, i.e. an equilateral triangle, type this:
> print regular_simplex(2)->VERTICES; 1 1 0 1 0 1 1 1/2-1/2r3 1/2-1/2r3
The polytopes cordinate type is QuadraticExtension<Rational>
, thus numbers that can be represented as a + b*sqrt© with Rational numbers a, b and c. The last row vectors entries thus represent the number $ 1/2 * ( 1 - sqrt(3) ) $.
To store a regular 3-simplex in the variable $s and also calculate its symmetry group, type this:
> $s = regular_simplex(3, group=>1);
You can then print the groups generators like so:
> print $s->GROUP->RAYS_ACTION->GENERATORS; 1 0 2 3 3 0 1 2
rhombicosidodecahedron()
Create exact rhombicosidodecahedron in Q(sqrt{5}). An Archimedean solid.
rhombicuboctahedron()
Create rhombicuboctahedron. An Archimedean solid.
root_system(String type)
Produce the root systems of the Coxeter arrangement of a given type The roots lie at infinity to facilitate reflecting in them.
String
type
: the type of the Coxeter arrangement, for example A4 or E8
simple_roots_type_A(Int index)
Produce the simple roots of the Coxeter arrangement of type A Indices are taken w.r.t. the Dynkin diagram 0 —- 1 —- … —- n-1 Note that the roots lie at infinity to facilitate reflecting in them, and are normalized to length sqrt{2}.
Int
index
: of the arrangement (3, 4, etc)
simple_roots_type_B(Int index)
Produce the simple roots of the Coxeter arrangement of type B Indices are taken w.r.t. the Dynkin diagram 0 —- 1 —- … —- n-2 –(4)–> n-1 Note that the roots lie at infinity to facilitate reflecting in them, and are normalized to length sqrt{2}.
Int
index
: of the arrangement (3, 4, etc)
simple_roots_type_C(Int index)
Produce the simple roots of the Coxeter arrangement of type C Indices are taken w.r.t. the Dynkin diagram 0 —- 1 —- … —- n-2 ←-(4)– n-1 Note that the roots lie at infinity to facilitate reflecting in them, and are normalized to length sqrt{2}.
Int
index
: of the arrangement (3, 4, etc)
simple_roots_type_D(Int index)
Produce the simple roots of the Coxeter arrangement of type D Indices are taken w.r.t. the Dynkin diagram n-2 / 0 - 1 - … - n-3 # n-1 Note that the roots lie at infinity to facilitate reflecting in them, and are normalized to length sqrt{2}.
Int
index
: of the arrangement (3, 4, etc)
simple_roots_type_E6()
Produce the simple roots of the Coxeter arrangement of type E6 Indices are taken w.r.t. the Dynkin diagram 3 | | 0 —- 1 —- 2 —- 4 —- 5 Note that the roots lie at infinity to facilitate reflecting in them.
simple_roots_type_E7()
Produce the simple roots of the Coxeter arrangement of type E7 Indices are taken w.r.t. the Dynkin diagram 4 | | 0 —- 1 —- 2 —- 3 —- 5 —- 6 Note that the roots lie at infinity to facilitate reflecting in them.
simple_roots_type_E8()
Produce the simple roots of the Coxeter arrangement of type E8 Indices are taken w.r.t. the Dynkin diagram 5 | | 0 —- 1 —- 2 —- 3 —- 4 —- 6 —- 7 Note that the roots lie at infinity to facilitate reflecting in them.
simple_roots_type_F4()
Produce the simple roots of the Coxeter arrangement of type F4 Indices are taken w.r.t. the Dynkin diagram 0 —- 1 –(4)–> 2 —- 3
simple_roots_type_G2()
Produce the simple roots of the Coxeter arrangement of type G2 Indices are taken w.r.t. the Dynkin diagram 0 ←-(6)– 1
simple_roots_type_H3()
Produce the simple roots of the Coxeter arrangement of type H3 Indices are taken w.r.t. the Dynkin diagram 0 –(5)– 1 —- 2 Note that the roots lie at infinity to facilitate reflecting in them, and are normalized to length 2
simple_roots_type_H4()
Produce the simple roots of the Coxeter arrangement of type H4 Indices are taken w.r.t. the Dynkin diagram 0 –(5)– 1 —- 2 —- 3 Note that the roots lie at infinity to facilitate reflecting in them, and are normalized to length sqrt{2}
tetrahedron()
Create regular tetrahedron. A Platonic solid.
truncated_cube()
Create truncated cube. An Archimedean solid.
truncated_cuboctahedron()
Create truncated cuboctahedron. An Archimedean solid. This is actually a misnomer. The actual truncation of a cuboctahedron is normally equivalent to this construction, but has two different edge lengths. This construction has regular 2-faces.
truncated_dodecahedron()
Create exact truncated dodecahedron in Q(sqrt{5}). An Archimedean solid.
truncated_icosahedron()
Create exact truncated icosahedron in Q(sqrt{5}). An Archimedean solid. Also known as the soccer ball.
truncated_icosidodecahedron()
Create exact truncated icosidodecahedron in Q(sqrt{5}). An Archimedean solid.
truncated_octahedron()
Create truncated octahedron. An Archimedean solid. Also known as the 3-permutahedron.
wythoff(String type, Set rings)
Produce the orbit polytope of a point under a Coxeter arrangement with exact coordinates, possibly in a qudratic extension field of the rationals
String
type
: single letter followed by rank representing the type of the arrangement
Set
rings
: indices of the hyperplanes corresponding to simple roots of the arrangement that the initial point should NOT lie on. You may specify just an integer or a perl array ref like [0,1] or [0..2].
Bool
lattice
: Should the vertices of the orbit polytope be chosen to lie on the corresponding root lattice? default 0, which means that the vertices will instead be chosen to lie as symmetrically as possible.
Topologic cell complexes defined as quotients over polytopes modulo a discrete group.
cs_quotient(Polytope P)
For a centrally symmetric polytope, divide out the central symmetry, i.e, identify diametrically opposite faces.
cylinder_2()
Return a 2-dimensional cylinder obtained by identifying two opposite sides of a square.
To obtain a topological space homeomorphic to a cylinder, type
> $p = cylinder_2(); > print $p->QUOTIENT_SPACE->IDENTIFICATION_ACTION->GENERATORS; 2 3 0 1
> print $p->QUOTIENT_SPACE->IDENTIFICATION_ACTION->ORBITS; {0 2} {1 3}
Thus, vertices 0,2 and vertices 1,3 are identified.
> print $p->QUOTIENT_SPACE->FACES; {{0} {1}} {{0 1} {0 2} {1 3}} {{0 1 2 3}}
Thus, after identification two vertices, three edges, and one two-dimensional face remain:
> print $p->QUOTIENT_SPACE->F_VECTOR; 2 3 1
davis_manifold()
Return the 4-dimensional hyperbolic manifold obtained by Michael Davis
quarter_turn_manifold()
Return the 3-dimensional Euclidean manifold obtained by identifying opposite faces of a 3-dimensional cube by a quarter turn. After identification, two classes of vertices remain.
To obtain a topological space homeomorphic to the quarter turn manifold, type
> $p = quarter_turn_manifold(); > print $p->QUOTIENT_SPACE->IDENTIFICATION_ACTION->GENERATORS; 5 7 4 6 2 0 3 1 6 2 1 5 7 3 0 4
To see which vertices are identified, type
> print $p->QUOTIENT_SPACE->IDENTIFICATION_ACTION->ORBITS; {0 3 5 6} {1 2 4 7}
Thus, two classes of vertices remain, with 0 and 1 being representatives. To see the faces remaining after identification, type
> print $p->QUOTIENT_SPACE->FACES; {{0} {1}} {{0 1} {0 2} {0 4} {0 7}} {{0 1 2 3} {0 1 4 5} {0 1 6 7}} {{0 1 2 3 4 5 6 7}}
> print $p->QUOTIENT_SPACE->F_VECTOR; 2 4 3 1
write_quotient_space_simplexity_ilp
outputs a linear program whose optimal value is a lower bound for the number of simplices necessary to triangulate the polytope in such a way that its symmetries respect the triangulation of the boundary.
These functions capture information of the object that is concerned with the action of permutation groups.
cocircuit_equations_support_reps(Matrix<Scalar> points, Array<Array<Int>> gens, Array<SetType> rirs, Array<SetType> rmis)
write the indices of the representatives of the support of the cocircuit equations to a file
combinatorial_symmetries(Polytope p)
Compute the combinatorial symmetries (i.e., automorphisms of the face lattice) of a given polytope p. They are stored in terms of a GROUP.VERTICES_ACTION and a GROUP.FACETS_ACTION property in p, and the GROUP.VERTICES_ACTION is also returned.
Polytope
p
To get the vertex symmetry group of the square and print its generators, type the following:
> print combinatorial_symmetries(cube(2))->GENERATORS; 2 3 0 1 1 0 2 3
> $p = cube(2); combinatorial_symmetries($p); > print $p->GROUP->VERTICES_ACTION->GENERATORS; 0 2 1 3 1 0 3 2
> print $p->GROUP->FACETS_ACTION->GENERATORS; 2 3 0 1 1 0 2 3
combinatorial_symmetrized_cocircuit_equations(Cone P, Set<Int> comps)
calculate a sparse representation of the cocircuit equations corresponding to a direct sum of isotypic components
Cone
P
combinatorial_symmetrized_cocircuit_equations(Cone P, Array<SetType> rirs, Array<SetType> rmis, Set<Int> comps)
calculate the projection of the cocircuit equations to a direct sum of isotypic components and represent it combinatorially
isotypic_configuration(Polytope P, Int i)
Given a polytope that has a matrix group acting on it, return the projections of the vertices to the i-th isotypic component C_i. If the input is a group with a permutation action a, regard a as acting on the unit basis vectors of the ambient space and return the projection of the unit basis vectors to the i-th isotypic component.
Polytope
P
: a polytope with a matrix action, or a group::Group g with a permutation action
Int
i
: the index of the desired isotypic component
Consider the symmetry group of the cyclic polytope c(4,10) in the Carathéodory realization.
> $p = cyclic_caratheodory(4,10,group=>1);
For i=4, we obtain a 10-gon:
> print isotypic_configuration($p,4)->POINTS; 1 1 0 1 0.8090169944 0.5877852523 1 0.3090169944 0.9510565163 1 -0.3090169944 0.9510565163 1 -0.8090169944 0.5877852523 1 -1 0 1 -0.8090169944 -0.5877852523 1 -0.3090169944 -0.9510565163 1 0.3090169944 -0.9510565163 1 0.8090169944 -0.5877852523
Similarly, for i=5 we get two copies of a pentagon.
lattice_automorphisms_smooth_polytope(Polytope P)
Returns a generating set for the lattice automorphism group of a smooth polytope P by comparing lattice distances between vertices and facets.
linear_symmetries(Matrix M)
Compute the linear symmetries of the rows of a rational matrix M. This is an implementation of the algorithm described in the paper “Computing symmetry groups of polyhedra” LMS J. Comput. Math. 17 (1) (2004) by By David Bremner, Mathieu Dutour Sikiri'{c}, Dmitrii V. Pasechnik, Thomas Rehn and Achill Sch“{u}rmann.
linear_symmetries(Cone C)
CREDIT sympol\n\n Use sympol to compute the linear symmetries of
The action of the symmetry group is stored inside the parent object. In the case of cones, sympol might compute only a subset of the linear symmetry group. Sympol, and therefore this function, can only handle rational objects.
nestedOPGraph(Vector gen_point, Matrix points, Matrix lattice_points, Group group, Bool verbose)
Constructs the NOP-graph of an orbit polytope. It is used by the rule for the NOP_GRAPH
.
orbit_polytope(Vector input_point, PermutationAction a)
Constructs the orbit polytope of a given point input_point with respect to a given group action a.
Vector
input_point
: the basis point of the orbit polytope
PermutationAction
a
: the action of a permutation group on the coordinates of the ambient space
The orbit polytope of a set of points A in affine d-space is the convex hull of the images of A under the action of a group G on the affine space. polymake implements several variations of this concept. The most basic one is the convex hull of the orbit of a single point under a set of coordinate permutations. For example, consider the cyclic group C_6 that acts on 6-dimensional space by cyclically permuting the coordinates. This action is represented in polymake by group::cyclic_group(6)→PERMUTATION_ACTION. To compute the convex hull of cyclic shifts of the vector v = [1,6,0,5,-5,0,-5] in homogeneous coordinates, type
> $p = orbit_polytope(new Vector([1,6,0,5,-5,0,-5]), group::cyclic_group(6)->PERMUTATION_ACTION);
After this assignment, the orbit polytope is still in implicit form, and the only properties that are defined reside in GROUP→COORDINATE_ACTION:
> print $p->GROUP->COORDINATE_ACTION->properties(); type: PermutationAction<Int, Rational> as Polytope<Rational>::GROUP::COORDINATE_ACTION GENERATORS 1 2 3 4 5 0 INPUT_RAYS_GENERATORS 1 6 0 5 -5 0 -5
To calculate the vertices of the orbit polytope explicitly, say
> print $p->VERTICES; 1 -5 0 -5 6 0 5 1 -5 6 0 5 -5 0 1 0 -5 6 0 5 -5 1 0 5 -5 0 -5 6 1 5 -5 0 -5 6 0 1 6 0 5 -5 0 -5
orbit_polytope(Matrix input_points, PermutationAction a)
Constructs the orbit polytope of a given set of points input_points with respect to a given group action a.
Matrix
input_points
: the basis points of the orbit polytope
PermutationAction
a
: the action of a permutation group on the coordinates of the ambient space
To find the orbit of more than one point under a PermutationAction on the coordinates, say
> $p = orbit_polytope(new Matrix([ [1,6,0,5,-5,0,-5], [1,1,2,3,4,5,6] ]), new group::PermutationAction(GENERATORS=>[ [1,2,3,4,5,0] ])); > print $p->VERTICES; 1 -5 0 -5 6 0 5 1 -5 6 0 5 -5 0 1 0 -5 6 0 5 -5 1 0 5 -5 0 -5 6 1 5 -5 0 -5 6 0 1 6 0 5 -5 0 -5 1 1 2 3 4 5 6 1 2 3 4 5 6 1 1 3 4 5 6 1 2 1 4 5 6 1 2 3 1 5 6 1 2 3 4 1 6 1 2 3 4 5
orbit_polytope(Vector input_point, Group g)
Constructs the orbit polytope of a given point input_point with respect to a given group action a.
Vector
input_point
: the basis point of the orbit polytope
Group
g
: a group with a PERMUTATION_ACTION that acts on the coordinates of the ambient space
As a convenience function, you can also directly specify a group::Group that contains a PERMUTATION_ACTION:
> $p = orbit_polytope(new Vector([1,6,0,5,-5,0,-5]), group::cyclic_group(6));
Up to now, the orbit polytope is still in implicit form. To calculate the vertices explicitly, say
> print $p->VERTICES; 1 -5 0 -5 6 0 5 1 -5 6 0 5 -5 0 1 0 -5 6 0 5 -5 1 0 5 -5 0 -5 6 1 5 -5 0 -5 6 0 1 6 0 5 -5 0 -5
orbit_polytope(Matrix input_points, Group g)
Constructs the orbit polytope of a given set of points input_points with respect to a given group action a.
Matrix
input_points
: the basis points of the orbit polytope
Group
g
: a group with a PERMUTATION_ACTION that acts on the coordinates of the ambient space
As a convenience function, you can also directly specify a group::Group that contains a PERMUTATION_ACTION:
> $p = orbit_polytope(new Matrix([ [1,6,0,5,-5,0,-5], [1,1,2,3,4,5,6] ]), group::cyclic_group(6)); > print $p->VERTICES; 1 -5 0 -5 6 0 5 1 -5 6 0 5 -5 0 1 0 -5 6 0 5 -5 1 0 5 -5 0 -5 6 1 5 -5 0 -5 6 0 1 6 0 5 -5 0 -5 1 1 2 3 4 5 6 1 2 3 4 5 6 1 1 3 4 5 6 1 2 1 4 5 6 1 2 3 1 5 6 1 2 3 4 1 6 1 2 3 4 5
orbit_polytope(Matrix input_points, Array<Array<Int>> gens)
Constructs the orbit polytope of a given set of points input_points with respect to a given set of generators gens.
Matrix
input_points
: the basis point of the orbit polytope
This is a variation where several points are given as the row of a matrix, and the permutation action on coordinates is given by explicitly listing the generators. In this example, the matrix has just one row, and there is just one generator.
> print orbit_polytope(new Matrix([ [1,6,0,5,-5,0,-5] ]), [ [1,2,3,4,5,0] ])->VERTICES; 1 -5 0 -5 6 0 5 1 -5 6 0 5 -5 0 1 0 -5 6 0 5 -5 1 0 5 -5 0 -5 6 1 5 -5 0 -5 6 0 1 6 0 5 -5 0 -5
orbit_polytope<Scalar>(Vector input_point, MatrixActionOnVectors a)
Constructs the orbit polytope of a given point input_point with respect to a given matrix group action a.
Scalar
: S the underlying number type
Vector
input_point
: the generating point of the orbit polytope
MatrixActionOnVectors
a
: the action of a matrix group on the coordinates of the ambient space
polymake also supports orbit polytopes under the action of a group by matrices. To find the orbit of a point in the plane under the symmetry group of the square, say
> $p = orbit_polytope(new Vector([1,2,1]), cube(2, group=>1)->GROUP->MATRIX_ACTION); > print $p->VERTICES; 1 -2 -1 1 -2 1 1 -1 -2 1 -1 2 1 1 -2 1 1 2 1 2 -1 1 2 1
orbit_polytope<Scalar>(Matrix<Scalar> input_points, MatrixActionOnVectors<Scalar> a)
Constructs the orbit polytope of a given set of points input_points with respect to a given matrix group action a.
Scalar
: S the underlying number type
Matrix<Scalar>
input_points
: the generating points of the orbit polytope
MatrixActionOnVectors<Scalar>
a
: the action of a matrix group on the coordinates of the ambient space
To find the orbit of more than one point in the plane under the symmetry group of the square, say
> $p = orbit_polytope(new Matrix([ [1,2,1], [1,5/2,0] ]), cube(2, group=>1)->GROUP->MATRIX_ACTION); > print $p->VERTICES; 1 -2 -1 1 -2 1 1 -1 -2 1 -1 2 1 1 -2 1 1 2 1 2 -1 1 2 1 1 -5/2 0 1 0 -5/2 1 0 5/2 1 5/2 0
ortho_project(Polytope p)
Projects a symmetric polytope in R4 cap H1,k to R3. (See also the polymake extension 'tropmat' by S. Horn.)
Polytope
p
: the symmetric polytope to be projected
projective_symmetries(Cone C)
Find the group of projective automorphisms of a Cone C. This is a group of all permutations on the rays of the cone (not necessarily there representatives), such that there is a invertible matrix A with A*Ray = Ray_sigma for all rays of the cone. This is an implementation of the algorithm described in the paper “Computing symmetry groups of polyhedra” LMS J. Comput. Math. 17 (1) (2004) by By David Bremner, Mathieu Dutour Sikiri'{c}, Dmitrii V. Pasechnik, Thomas Rehn and Achill Sch”{u}rmann.
representation_conversion_up_to_symmetry(Cone c)
Computes the dual description of a polytope up to its linear symmetry group.
Cone
c
: the cone (or polytope) whose dual description is to be computed, equipped with a GROUP
Bool
v_to_h
: 1 (default) if converting V to H, false if converting H to V
String
method
: specifies sympol's method of ray computation via 'lrs' (default), 'cdd', 'beneath_beyond', 'ppl'
symmetrized_cocircuit_equations<Scalar>(Cone P, Set<Int> comps)
calculate the projection of the cocircuit equations to a direct sum of isotypic components
truncated_orbit_polytope(Polytope P, Scalar eps)
Gives an implicit representation of the all-vertex truncation of an orbit polytope P, in which all vertices are cut off by hyperplanes at distance eps. The input polytope P must have a GROUP.COORDINATE_ACTION. The output is a polytope with a GROUP.COORDINATE_ACTION equipped with INEQUALITIES_GENERATORS.
Polytope
P
: the input polytope
Scalar
eps
: scaled distance by which the vertices of the orbit polytope are to be cut off
These functions take a realized polytope and produce a new one by applying a suitable affine or projective transformation in order to obtain some special coordinate description but preserve the combinatorial type. For example, before you can polarize an arbitrary polyhedron, it must be transformed to a combinatorially equivalent bounded polytope with the origin as a relatively interior point. It is achieved with the sequence orthantify
- bound
- center
- polarize
.
ambient_lattice_normalization(Polytope p)
Transform to a full-dimensional polytope while preserving the ambient lattice Z^n
Polytope
p
: the input polytope,
Bool
store_transform
: store the reverse transformation as an attachement
Consider a line segment embedded in 2-space containing three lattice points:
> $p = new Polytope(VERTICES=>[[1,0,0],[1,2,2]]); > print ambient_lattice_normalization($p)->VERTICES; 1 0 1 2
The ambient lattice of the projection equals the intersection of the affine hull of $p with Z^2.
Another line segment containing only two lattice points:
> $p = new Polytope(VERTICES=>[[1,0,0],[1,1,2]]); > $P = ambient_lattice_normalization($p,store_transform=>1); > print $P->VERTICES; 1 0 1 1
To get the transformation, do the following:
> $M = $P->get_attachment('REVERSE_LATTICE_PROJECTION'); > print $M; 1 0 0 0 1 2
> print $P->VERTICES * $M; 1 0 0 1 1 2
bound(Polytope P)
Make a positive polyhedron bounded. Apply a projective linear transformation to a polyhedron mapping the far hyperplane to the hyperplane spanned by the unit vectors. The origin (1,0,…,0) is fixed. The input polyhedron should be POSITIVE
; i.e. no negative coordinates.
Polytope
P
: a positive polyhedron
Observe the transformation of a simple unbounded 2-polyhedron:
> $P = new Polytope(VERTICES=>[[1,0,0],[0,1,1],[0,0,1]]); > print bound($P)->VERTICES; 1 0 0 1 1/2 1/2 1 0 1
As you can see, the far points are mapped to the hyperplane spanned by (1,1,0) and (1,0,1).
center(Polytope P)
Make a polyhedron centered. Apply a linear transformation to a polyhedron P such that a relatively interior point (preferably the vertex barycenter) is moved to the origin (1,0,…,0).
Polytope
P
Consider this triangle not containing the origin:
> $P = new Polytope(VERTICES => [[1,1,1],[1,2,1],[1,1,2]]); > $origin = new Vector([1,0,0]); > print $P->contains_in_interior($origin); false
To create a translate that contains the origin, do this:
> $PC = center($P); > print $PC->contains_in_interior($origin); true
This is what happened to the vertices:
> print $PC->VERTICES; 1 -1/3 -1/3 1 2/3 -1/3 1 -1/3 2/3
There also exists a property to check whether a polytope is centered:
> print $PC->CENTERED; true
orthantify(Polytope P, Int v)
Make a polyhedron POSITIVE
. Apply an affine transformation to a polyhedron such that the vertex v is mapped to the origin (1,0,…,0) and as many facets through this vertex as possible are mapped to the bounding facets of the first orthant.
orthonormal_col_basis(Matrix M)
Return an orthonormal column basis of the input matrix.
Matrix
M
: the input matrix
orthonormal_row_basis(Matrix M)
Return an orthonormal row basis of the input matrix.
Matrix
M
: the input matrix
polarize(Cone C)
This method takes either a polytope (1.) or a cone (2.) as input. 1. Given a bounded, centered, not necessarily full-dimensional polytope P, produce its polar with respect to the standard Euclidean scalar product. 2. Given a cone C produce its dual with respect to the standard Euclidean scalar product, i.e. all the vectors that evaluate positively on C. Note that the definition of the polar has changed after version 2.10: the polar is reflected in the origin to conform with cone polarization If P is not full-dimensional, the output will contain lineality orthogonal to the affine span of P. In particular, polarize() of a pointed polytope will always produce a full-dimensional polytope. If you want to compute the polar inside the affine hull you may use the pointed_part
client afterwards.
Cone
C
Bool
no_coordinates
: only combinatorial information is handled
To save the polar of the square in the variable $p and then print its vertices, do this:
> $p = polarize(cube(2)); > print $p->VERTICES; 1 1 0 1 -1 0 1 0 1 1 0 -1
To dualize the cone over a hexagon and print its rays, do this:
> $c = new Cone(INPUT_RAYS=>[[1,0,0],[1,1,0],[1,2,1],[1,2,2],[1,1,2],[1,0,1]]); > $cd = polarize($c); > print $cd->RAYS; 1 -1 1 0 0 1 0 1 0 1 1 -1 1 0 -1/2 1 -1/2 0
porta_dual
Dual transformation via porta. Computes vertices and lineality space from inequalities and equations.
porta_primal
Primal transformation via porta. Computes facets and affine hull from vertices or points.
revert(Polytope P)
Apply a reverse transformation to a given polyhedron P. All transformation clients keep track of the polytope's history. They write or update the attachment REVERSE_TRANSFORMATION. Applying revert to the transformed polytope reconstructs the original polytope.
Polytope
P
: a (transformed) polytope
The following translates the square and then reverts the transformation:
> $v = new Vector(1,2); > $p = translate(cube(2),$v); > print $p->VERTICES; 1 0 1 1 2 1 1 0 3 1 2 3
> $q = revert($p); > print $q->VERTICES; 1 -1 -1 1 1 -1 1 -1 1 1 1 1
scale(Polytope P, Scalar factor, Bool store)
Scale a polyhedron P by a given scaling parameter factor.
Polytope
P
: the polyhedron to be scaled
Scalar
factor
: the scaling factor
Bool
store
: stores the reverse transformation as an attachment (REVERSE_TRANSFORMATION); default value: 1.
To scale the square by 23, do this:
> $p = scale(cube(2),23); > print $p->VERTICES; 1 -23 -23 1 23 -23 1 -23 23 1 23 23
The transformation matrix is stored in an attachment:
> print $p->get_attachment('REVERSE_TRANSFORMATION'); 1 0 0 0 1/23 0 0 0 1/23
To reverse the transformation, you can use the revert function.
> $q = revert($p); > print $q->VERTICES; 1 -1 -1 1 1 -1 1 -1 1 1 1 1
transform(Polytope P, Matrix trans, Bool store)
Transform a polyhedron P according to the linear transformation trans.
Polytope
P
: the polyhedron to be transformed
Matrix
trans
: the transformation matrix
Bool
store
: stores the reverse transformation as an attachment (REVERSE_TRANSFORMATION); default value: 1.
This translates the square by (23,23) and stores the transformation:
> $M = new Matrix([1,23,23],[0,1,0],[0,0,1]); > $p = transform(cube(2),$M,1); > print $p->VERTICES; 1 22 22 1 24 22 1 22 24 1 24 24
To retrieve the attached transformation, use this:
> print $p->get_attachment('REVERSE_TRANSFORMATION'); 1 -23 -23 0 1 0 0 0 1
Check out the revert function to learn how to undo the transformation. It might be more comfortable to use the translate function to achieve the same result.
translate(Polytope P, Vector trans, Bool store)
Translate a polyhedron P by a given translation vector trans.
Polytope
P
: the polyhedron to be translated
Vector
trans
: the translation vector
Bool
store
: stores the reverse transformation as an attachment (REVERSE_TRANSFORMATION); default value: 1.
This translates the square by (23,23) and stores the transformation:
> $t = new Vector(23,23); > $p = translate(cube(2),$t); > print $p->VERTICES; 1 22 22 1 24 22 1 22 24 1 24 24
To retrieve the attached transformation, use this:
> print $p->get_attachment('REVERSE_TRANSFORMATION'); 1 -23 -23 0 1 0 0 0 1
Check out the revert function to learn how to undo the transformation.
vertex_lattice_normalization(Polytope p)
Transform to a full-dimensional polytope while preserving the lattice spanned by vertices induced lattice of new vertices = Z^dim
These functions collect information about triangulations and other subdivisions of the object and properties usually computed from such, as the volume.
barycentric_subdivision(Cone c)
Create a simplicial complex as a barycentric subdivision of a given cone or polytope. Each vertex in the new complex corresponds to a face in the old complex.
Cone
c
: input cone or polytope
Bool
no_labels
: Do not generate VERTEX_LABELS
from the faces of the original cone. default: 0
Bool
geometric_realization
: create a GeometricSimplicialComplex
; default is true
chirotope(Matrix M)
Compute the chirotope of a point configuration given as the rows of a matrix.
Matrix
M
: The rows are the points
coherency_index(Polytope p1, Polytope p2, Matrix points, Vector w1, Vector w2)
DOC_FIXME: Incomprehensible description! Computes the coherency index of w1 w.r.t. w2
coherency_index(Matrix points, Vector w1, Vector w2)
DOC_FIXME: Incomprehensible description! Computes the coherency index of w1 w.r.t. w2
coherency_index(Polytope p1, Polytope p2)
DOC_FIXME: Erroneous description! w1 is not a parameter here! Computes the coherency index of p1 w.r.t. p2
common_refinement(Matrix points, IncidenceMatrix sub1, IncidenceMatrix sub2, Int dim)
Computes the common refinement of two subdivisions of points. It is assumed that there exists a common refinement of the two subdivisions.
Matrix
points
IncidenceMatrix
sub1
: first subdivision
IncidenceMatrix
sub2
: second subdivision
Int
dim
: dimension of the point configuration
A simple 2-dimensional set of points:
> $points = new Matrix<Rational>([[1,0,0],[1,1,0],[1,0,1],[1,1,1],[1,2,1]]);
Two different subdivisions…
> $sub1 = new IncidenceMatrix([[0,1,2],[1,2,3,4]]); > $sub2 = new IncidenceMatrix([[1,3,4],[0,1,2,3]]);
…and their common refinement:
> print common_refinement($points,$sub1,$sub2,2); {0 1 2} {1 3 4} {1 2 3}
common_refinement(Polytope p1, Polytope p2)
Computes the common refinement of two subdivisions of the same polytope p1, p2. It is assumed that there exists a common refinement of the two subdivisions. It is not checked if p1 and p2 are indeed the same!
delaunay_triangulation(VoronoiPolyhedron V)
Compute the Delaunay triangulation of the given SITES
of a VoronoiPolyhedron V. If the sites are not in general position, the non-triangular facets of the Delaunay subdivision are triangulated (by applying the beneath-beyond algorithm).
> $VD = new VoronoiPolyhedron(SITES=>[[1,1,1],[1,0,1],[1,-1,1],[1,1,-1],[1,0,-1],[1,-1,-1]]); > $D = delaunay_triangulation($VD); > print $D; {0 1 3} {1 3 4} {1 2 4} {2 4 5}
fiber_polytope(PointConfiguration pc, PointConfiguration pc)
Computes the fiber polytope of a projection of point configurations P→Q via the GKZ secondary configuration.
PointConfiguration
pc
: (or Polytope) source point configuration or polytope
PointConfiguration
pc
: target point configuration
fiber_polytope(PointConfiguration pc, Polytope pc)
Computes the fiber polytope of a projection of point configurations P→Q via the GKZ secondary configuration.
PointConfiguration
pc
: (or Polytope) source point configuration or polytope
Polytope
pc
: target polytope
fiber_polytope(PointConfiguration P, Matrix pi)
Computes the fiber polytope of a projection of point configurations P -pi→ Q via the GKZ secondary configuration.
PointConfiguration
P
: (or Polytope) source point configuration or polytope
Matrix
pi
: the projection acting on P
foldable_max_signature_ilp(Int d, Matrix points, Rational volume, SparseMatrix cocircuit_equations)
Set up an ILP whose MAXIMAL_VALUE is the maximal signature of a foldable triangulation of a polytope, point configuration or quotient manifold
Int
d
: the dimension of the input polytope, point configuration or quotient manifold
Matrix
points
: the input points or vertices
Rational
volume
: the volume of the convex hull
SparseMatrix
cocircuit_equations
: the matrix of cocircuit equations
foldable_max_signature_upper_bound(Int d, Matrix points, Rational volume, SparseMatrix cocircuit_equations)
Calculate the LP relaxation upper bound to the maximal signature of a foldable triangulation of polytope, point configuration or quotient manifold
Int
d
: the dimension of the input polytope, point configuration or quotient manifold
Matrix
points
: the input points or vertices
Rational
volume
: the volume of the convex hull
SparseMatrix
cocircuit_equations
: the matrix of cocircuit equations
interior_and_boundary_ridges(Polytope P)
Find the (d-1)-dimensional simplices in the interior and in the boundary of a d-dimensional polytope or cone
is_regular(Matrix points, Array<Set<Int>> subdiv)
For a given subdivision subdiv of points tests if the subdivision is regular and if yes computes a weight vector inducing this subdivsion. The output is a pair of Bool and the weight vector. Options can be used to ensure properties of the resulting vector. The default is having 0 on all vertices of the first face of subdiv.
Matrix
points
: in homogeneous coordinates
Matrix<Scalar>
equations
: system of linear equation the cone is cut with.
Int
lift_face_to_zero
: gives only lifting functions lifting all vertices of the designated face to 0
A regular subdivision of the square, with the first cell lifted to zero:
> $points = cube(2)->VERTICES; > print is_regular($points,[[0,1,3],[1,2,3]],lift_to_zero=>[0,1,3]); 1 <0 0 1 0>
is_subdivision(Matrix points, Array<Set<Int>> faces)
Matrix
points
Two potential subdivisions of the square without inner points:
> $points = cube(2)->VERTICES; > print is_subdivision($points,[[0,1,3],[1,2,3]],interior_points=>[ ]); true
> print is_subdivision($points,[[0,1,2],[1,2]],interior_points=>[ ]); false
Three points in RR^1
> $points = new Matrix([[1,0],[1,1],[1,2]]); > print is_subdivision($points, [[0,2]]); true
> print is_subdivision($points, [[0,1]]); false
iterated_barycentric_subdivision(Cone c, Int n)
Create a simplicial complex as an iterated barycentric subdivision of a given cone or polytope.
Cone
c
: input cone or polytope
Int
n
: how many times to subdivide
Bool
no_labels
: Do not generate VERTEX_LABELS
from the faces of the original cone. default: 0
Bool
geometric_realization
: create a GeometricSimplicialComplex
; default is false
max_interior_simplices(Polytope P)
Find the maximal interior simplices of a polytope P. Symmetries of P are NOT taken into account.
max_interior_simplices(PointConfiguration P)
find the maximal interior simplices of a point configuration Symmetries of the configuration are NOT taken into account.
PointConfiguration
P
: the input point configuration
To calculate the maximal interior simplices of a point configuration, type
> $p=new PointConfiguration(POINTS=>[[1,0,0],[1,1,0],[1,0,1],[1,1,1],[1,1/2,1/2]]); > print max_interior_simplices($p); {0 1 2} {0 1 3} {0 1 4} {0 2 3} {0 2 4} {1 2 3} {1 3 4} {2 3 4}
mixed_volume(Polytope<Scalar> P1, Polytope<Scalar> P2, Polytope<Scalar> Pn)
Produces the normalized mixed volume of polytopes P1,P2,…,Pn. It does so by producing a (pseudo-)random lift function. If by bad luck the function is not generic, an error message might be displayed.
n_fine_triangulations(Matrix M, Bool optimization)
Calculates the number of fine triangulations of a planar point configuration. This can be space intensive. Victor Alvarez, Raimund Seidel: A Simple Aggregative Algorithm for Counting Triangulations of Planar Point Sets and Related Problems. In Proc. of the 29th Symposium on Computational Geometry (SoCG '13), pages 1-8, Rio de Janeiro, Brazil, 2013
placing_triangulation(Matrix Points)
Compute the placing triangulation of the given point set using the beneath-beyond algorithm.
Matrix
Points
: the given point set
Bool
non_redundant
: whether it's already known that Points are non-redundant
To compute the placing triangulation of the square (of whose vertices we know that they're non-redundant), do this:
> $t = placing_triangulation(cube(2)->VERTICES, non_redundant=>1); > print $t; {0 1 2} {1 2 3}
points2metric(Matrix points)
Define a metric by restricting the Euclidean distance function to a given set of points. Due to floating point computations (sqrt is used) the metric defined may not be exact. If the option max or l1 is set to true the max-norm or l1-norm is used instead (with exact computation).
poly2metric(Polytope P)
Define a metric by restricting the Euclidean distance function to the vertex set of a given polytope P. Due to floating point computations (sqrt is used) the metric defined may not be exact. If the option max or l1 is set to true the max-norm or l1-norm is used instead (with exact computation).
positive_circuits(Polytope or, Set<Int> S)
returns all sets of points that form a circuit with the given list of points
Polytope
or
: PointConfiguration P
quotient_space_simplexity_ilp(Int d, Matrix V, Scalar volume, SparseMatrix cocircuit_equations)
Set up an LP whose MINIMAL_VALUE is a lower bound for the minimal number of simplices needed to triangulate a polytope, point configuration or quotient manifold
Int
d
: the dimension of the input polytope, point configuration or quotient manifold
Matrix
V
: the input points or vertices
Scalar
volume
: the volume of the convex hull
SparseMatrix
cocircuit_equations
: the matrix of cocircuit equations
String
filename
: a name for a file in .lp format to store the linear program
quotient_space_simplexity_lower_bound(Int d, Matrix V, Scalar volume, SparseMatrix cocircuit_equations)
Calculate a lower bound for the minimal number of simplices needed to triangulate a polytope, point configuration or quotient manifold
Int
d
: the dimension of the input polytope, point configuration or quotient manifold
Matrix
V
: the input points or vertices
Scalar
volume
: the volume of the convex hull
SparseMatrix
cocircuit_equations
: the matrix of cocircuit equations
regular_subdivision(Matrix points, Vector weights)
Compute a regular subdivision of the polytope obtained by lifting points to weights and taking the lower complex of the resulting polytope. If the weight is generic the output is a triangulation.
regularity_lp(Matrix points, Array<Set<Int>> subdiv)
For a given subdivision subdiv of points determines a LinearProgram to decide whether the subdivision is regular. The output a Polytope with an attached LP. Options can be used to ensure properties of the resulting LP. The default is having 0 on all vertices of the first face of subdiv.
Matrix
points
: in homogeneous coordinates
Matrix<Scalar>
equations
: system of linear equation the cone is cut with.
Int
lift_face_to_zero
: gives only lifting functions lifting all vertices of the designated face to 0
Scalar
epsilon
: minimum distance from all inequalities
Polytope<Scalar>
secondary_configuration(PointConfiguration pc)
Computes the point configuration of GKZ vectors of a point configuration via its chirotope using topcom or mptopcom.
PointConfiguration
pc
: input point configuration
The following PointConfiguration
is called the “mother of all examples (moae)”. It has two non-regular triangulations, which can be seen when comparing the number of points of the output configuration with the number of vertices of the convex hull of the output configuration.
> $moae = new PointConfiguration(POINTS=>[[1,4,0,0],[1,0,4,0],[1,0,0,4],[1,2,1,1],[1,1,2,1],[1,1,1,2]]); > $moae = project_full($moae); > $SC_moae = secondary_configuration($moae); > print $SC_moae -> N_POINTS; 18
> print $SC_moae -> CONVEX_HULL -> N_VERTICES; 16
secondary_configuration(Polytope pc)
Computes the point configuration of GKZ vectors of a point configuration via its chirotope using topcom or mptopcom.
secondary_polytope(PointConfiguration pc)
Computes the GKZ secondary polytope of a point configuration via its using topcom or mptopcom.
PointConfiguration
pc
: input point configuration
The following PointConfiguration
is called the “mother of all examples (moae)”. It has two non-regular triangulations, which can be seen when comparing the number of points in the secondary configuration with the number of vertices of the secondary polytope.
> $moae = new PointConfiguration(POINTS => [[1,4,0,0],[1,0,4,0],[1,0,0,4],[1,2,1,1],[1,1,2,1],[1,1,1,2]]); > $moae = project_full($moae); > $SC_moae = secondary_configuration($moae); > $SP_moae = secondary_polytope($moae); > print $SC_moae -> N_POINTS; 18
> print $SP_moae -> N_VERTICES; 16
secondary_polytope(Polytope pc)
Computes the GKZ secondary polytope of a point configuration via its using topcom or mptopcom.
simplexity_ilp(Int d, Matrix points, Array<Set> MIS, Scalar volume, SparseMatrix cocircuit_equations)
Set up an ILP whose MINIMAL_VALUE is the minimal number of simplices needed to triangulate a polytope, point configuration or quotient manifold
Int
d
: the dimension of the input polytope, point configuration or quotient manifold
Matrix
points
: the input points or vertices
Scalar
volume
: the volume of the convex hull
SparseMatrix
cocircuit_equations
: the matrix of cocircuit equations
simplexity_ilp_with_angles(Int d, Matrix V, Matrix F, IncidenceMatrix VIF, IncidenceMatrix VIR, Array<Array<Int>> gens, Array<Set> MIS, Scalar volume, SparseMatrix cocircuit_equations)
Set up an ILP whose MINIMAL_VALUE is the minimal number of simplices needed to triangulate a polytope, point configuration or quotient manifold
Int
d
: the dimension of the input polytope, point configuration or quotient manifold
Matrix
V
: the input points or vertices
Matrix
F
: the facets of the input polytope
IncidenceMatrix
VIF
: the vertices-in-facets incidence matrix
IncidenceMatrix
VIR
: the vertices-in-ridges incidence matrix
Scalar
volume
: the volume of the convex hull
SparseMatrix
cocircuit_equations
: the matrix of cocircuit equations
simplexity_lower_bound(Int d, Matrix points, Scalar volume, SparseMatrix cocircuit_equations)
Calculate the LP relaxation lower bound for the minimal number of simplices needed to triangulate a polytope, point configuration or quotient manifold
Int
d
: the dimension of the input polytope, point configuration or quotient manifold
Matrix
points
: the input points or vertices
Scalar
volume
: the volume of the convex hull
SparseMatrix
cocircuit_equations
: the matrix of cocircuit equations
split_compatibility_graph(Matrix splits, Polytope P)
DOC_FIXME: Incomprehensible description! Computes the compatibility graph among the splits of a polytope P.
split_polyhedron(Polytope P)
Computes the split polyhedron of a full-dimensional polyhdron P.
Polytope
P
splits(Matrix V, Graph G, Matrix F, Int dimension)
Computes the SPLITS of a polytope. The splits are normalized by dividing by the first non-zero entry. If the polytope is not fulldimensional the first entries are set to zero unless coords are specified.
splits_in_subdivision(Matrix vertices, Array<Set<Int>> subdivision, Matrix splits)
Tests which of the splits of a polyhedron are coarsenings of the given subdivision.
staircase_weight(Int k, Int l)
Gives a weight vector for the staircase triangulation of the product of a k-1- and an l-1-dimensional simplex.
Int
k
: the number of vertices of the first simplex
Int
l
: the number of vertices of the second simplex
The following creates the staircase triangulation of the product of the 2- and the 1-simplex.
> $w = staircase_weight(3,2); > $p = product(simplex(2),simplex(1)); > $p->POLYTOPAL_SUBDIVISION(WEIGHTS=>$w); > print $p->POLYTOPAL_SUBDIVISION->MAXIMAL_CELLS; {0 2 4 5} {0 2 3 5} {0 1 3 5}
symmetrized_foldable_max_signature_ilp(Int d, Matrix points, Rational volume, Array<Array<Int>> generators, SparseMatrix symmetrized_foldable_cocircuit_equations)
Set up an ILP whose MAXIMAL_VALUE is the maximal signature of a foldable triangulation of a polytope, point configuration or quotient manifold
Int
d
: the dimension of the input polytope, point configuration or quotient manifold
Matrix
points
: the input points or vertices
Rational
volume
: the volume of the convex hull
SparseMatrix
symmetrized_foldable_cocircuit_equations
: the matrix of symmetrized cocircuit equations
symmetrized_foldable_max_signature_upper_bound(Int d, Matrix points, Rational volume, SparseMatrix cocircuit_equations)
Calculate the LP relaxation upper bound to the maximal signature of a foldable triangulation of polytope, point configuration or quotient manifold
Int
d
: the dimension of the input polytope, point configuration or quotient manifold
Matrix
points
: the input points or vertices
Rational
volume
: the volume of the convex hull
SparseMatrix
cocircuit_equations
: the matrix of cocircuit equations
topcom_all_triangulations(PointConfiguration pc)
Computes all triangulations of a point configuration via its chirotope.
PointConfiguration
pc
: input point configuration
topcom_fine_and_connected_triangulations(PointConfiguration pc)
Computes all fine triangulations of a point configuration that are connected by bistellar flips to a fine seed triangulation. The triangulations are computed via the chirotope. If the input point configuration or polytope has a symmetry group, only fine triangulations up to symmetry will be computed.
PointConfiguration
pc
: or Polytope p input point configuration or polytope
topcom_fine_and_regular_triangulations(PointConfiguration pc)
Computes all fine and regular triangulations of a point configuration.
PointConfiguration
pc
: or Polytope p input point configuration or polytope
topcom_fine_triangulations(PointConfiguration pc)
Computes all fine triangulations (sometimes called “full”) of a chirotope. The triangulations are computed via the chirotope. If the input point configuration or polytope has a symmetry group, only fine triangulations up to symmetry will be computed.
PointConfiguration
pc
: or Polytope p input point configuration or polytope
topcom_input_format(Cone P)
This converts a polytope, cone or point configuration into a format that topcom understands
Cone
P
: (or PointConfiguration)
To convert a 2-cube without symmetries into topcom format, type
> print topcom_input_format(cube(2)); [[1,-1,-1],[1,1,-1],[1,-1,1],[1,1,1]] []
If you also want the symmetry group, you can type
> print topcom_input_format(cube(2,group=>1)); [[1,-1,-1],[1,1,-1],[1,-1,1],[1,1,1]] [[1,0,3,2],[0,2,1,3]]
topcom_regular_and_connected_triangulations(PointConfiguration pc)
Computes all triangulations of a point configuration that are connected by bistellar flips to the regular triangulations. The triangulations are computed via the chirotope. If the input point configuration or polytope has a symmetry group, only triangulations up to symmetry will be computed.
PointConfiguration
pc
: or Polytope p input point configuration or polytope
topcom_regular_triangulations(PointConfiguration pc)
Computes all regular triangulations of a point configuration.
PointConfiguration
pc
: or Polytope p input point configuration or polytope
universal_polytope<Scalar>(PointConfiguration<Scalar> PC)
Calculate the universal polytope of a point configuration A. It is a 0/1 polytope with one vertex for every triangulation of A. Each coordinate of the ambient space corresponds to a simplex in the configuration.
Scalar
: the underlying number type
PointConfiguration<Scalar>
PC
: the point configuration
To calculate the universal polytope of a point configuration, type
> $p=new PointConfiguration(POINTS=>[[1,0,0],[1,1,0],[1,0,1],[1,1,1],[1,1/2,1/2]]); > print universal_polytope($p)->VERTICES; 1 0 1 0 1 0 0 0 0 1 1 0 0 0 0 1 0 0 1 0 0 1 0 1 0 1 1
Notice how the first vertex corresponds to the triangulation using all points, and the other ones to the triangulations that don't use the inner point.
universal_polytope(Polytope P)
Calculate the universal polytope U(P) of an input polytope P. If P has n vertices and dimension d, then U(P) is a 0/1-polytope in dimension binomial(n,d+1) whose vertices correspond to the full triangulations of P. Each coordinate of a particular vertex v indicates the presence or absence of a particular simplex in the triangulation corresponding to v, and the order of the simplices (and hence the interpretation of each coordinate of v) is the one given by the property MAX_INTERIOR_SIMPLICES. Because the number of triangulations of P is typically very large, the polytope U(P) is not constructed by enumerating triangulations, but instead in the inequality description afforded by the cocircuit equations, a volume equality, and non-negativity constraints for the coordinates.
Polytope
P
: the input polytope
Since the 2-dimensional cube (i.e., the square) has just two triangulations, its universal polytope is a segment embedded in dimension binomial(4,3) = 4. The cocircuit equations read as follows:
> print universal_polytope(cube(2))->EQUATIONS; -8 4 4 4 4 (5) (2 -1) (3 1) (5) (1 -1) (4 1)
universal_polytope(Polytope P, Array<Set> reps, SparseMatrix cocircuit_equations)
Calculate the universal polytope of a polytope, point configuration or quotient manifold
Polytope
P
: the input polytope
SparseMatrix
cocircuit_equations
: the matrix of cocircuit equations
These functions are for visualization.
bounding_box_facets(Matrix V)
Produces boundary facets describing a box shaped polytope that contains all bounded vertices in V.
Matrix
V
: vertices that should be in the box
Scalar
offset
: the minimum offset between a bounding box facet and its nearest bounded vertex
Scalar
surplus_k
: size of the bounding box relative to the box spanned by V (added to offset)
Bool
fulldim
: keeps the bounding box full dimensional even if the bounded vertices do not span the whole space and offset is zero. Useful for visualizations of Voronoi diagrams that do not have enough vertices. Default value is 0.
Bool
make_cube
bounding_facets(Matrix H, Matrix V)
A function that turns a giving H-description into one that can be used as bounding facets for a given set of vertices.
Matrix
H
: H-description of some bounded polytope P
Matrix
V
: vertices of which the bounded ones will be contained in P
Scalar
offset
: the minimum euclidean distance between a hyperplane and a bounded vertex. Default is 0
Scalar
surplus_k
: factor multiplied with $ max(<f,v> | v in V) - min(<f,v> | v in V) $ to describe the minimum offset relative to the extents of V in f direction (added to offset)
Bool
transform
: instead of simply shifting the facets. For P simplicial/(and simple?) this should produce the same as the LP and can be turned off. Default is true
Bool
fulldim
: keep P full dimensional. Default is false
Bool
return_nonredundant
: (shifted) hyperplanes only. If transform is true there will be no check. Regardless of this variable. Default is true
vlabels(Matrix vertices, Bool wo_zero)
Creates vertex labels for visualization from the vertices of the polytope. The parameter wo_zero decides whether the entry at position 0 (homogenizing coordinate) is omitted (1) or included (0) in the label string.“
Special purpose functions.
edge_orientable(Polytope P)
Checks whether a 2-cubical polytope P is edge-orientable (in the sense of Hetyei), that means that there exits an orientation of the edges such that for each 2-face the opposite edges point in the same direction. It produces the certificates EDGE_ORIENTATION
if the polytope is edge-orientable, or MOEBIUS_STRIP_EDGES
otherwise. In the latter case, the output can be checked with the client validate_moebius_strip
.
Polytope
P
: the given 2-cubical polytope
face_pair(Cone P, Set S)
For a given set S of rays compute the smallest face F of a cone P containing them all; see also face.
lawrence_matrix(Matrix M)
Matrix
M
: Create the Lawrence matrix $ Lambda(M) $ corresponding to M. If M has n rows and d columns, then Lambda(M) equals ( M I_n ) ( 0_{n,d} I_n ).
m_sequence(Vector<Int> h)
Test if the given vector is an M-sequence.
The h-vector of a simplicial or simple polytope is an M-sequence.
> print m_sequence(cyclic(7,23)->H_VECTOR); true
matroid_indices_of_hypersimplex_vertices()
For a given matroid return the bases as a subset of the vertices of the hypersimplex
Matroid
m
: the matroid
pseudopower(Integer l, Int i)
Compute the i-th pseudopower of l, commonly denoted l^<i>. See “A Proof of the Sufficiency of McMullen’s Conditions of Simplicial Convex Polytopes” by Louis Billera and Carl Lee, DOI: 10.1016/0097-3165(81)90058-3, for the definition.
wronski_center_ideal(Matrix<Int> L, Vector<Int> lambda)
Returns a system of polynomials which is necessary to check if degeneration avoids center of projection: compute eliminant e(s); this must not have a zero in (0,1)
wronski_polynomial(Matrix<Int> M, Vector<Int> lambda, Array<Rational> coeff, Rational s)
Returns a Wronski polynomial of a FOLDABLE
triangulation of a lattice polytope
Rational
s
: additional Parameter in the polynomial
SimplicialComplex
triangulation
: The triangulation of the pointset corresponding to the lifting function
wronski_system(Matrix<Int> M, Vector<Int> lambda, Array<Array<Rational>> coeff_array, Rational s)
Returns a Wronski system of a FOLDABLE
triangulation of a lattice polytope
Rational
s
: additional Parameter in the polynomial
SimplicialComplex
triangulation
: The triangulation of the pointset corresponding to the lifting function