Source code for flatsurf.geometry.homology

r"""
Absolute and relative (simplicial) homology of surfaces.

EXAMPLES:

The absolute homology of the regular octagon::

    sage: from flatsurf import translation_surfaces, SimplicialHomology
    sage: S = translation_surfaces.regular_octagon()
    sage: H = SimplicialHomology(S)

A basis of homology, with generators written as (sums of) oriented edges::

    sage: H.gens()
    (B[(0, 1)], B[(0, 2)], B[(0, 3)], B[(0, 0)])

The absolute homology of the unfolding of the (3, 4, 13) triangle::

    sage: from flatsurf import Polygon, similarity_surfaces
    sage: P = Polygon(angles=[3, 4, 13])
    sage: S = similarity_surfaces.billiard(P).minimal_cover(cover_type="translation")
    sage: S.genus()
    8
    sage: H = SimplicialHomology(S)
    sage: len(H.gens())
    16

Relative homology, relative to the singularities of the surface::

    sage: S = S.erase_marked_points()  # optional: pyflatsurf  # random output due to deprecation warnings
    sage: H1 = SimplicialHomology(S, relative=S.vertices())  # optional: pyflatsurf
    sage: len(H1.gens())  # optional: pyflatsurf
    17

We can also form relative `H_0` and `H_2`, though they are not overly
interesting of course::

    sage: H0 = SimplicialHomology(S, relative=S.vertices(), k=0)
    sage: len(H0.gens())
    0

    sage: H2 = SimplicialHomology(S, relative=S.vertices(), k=2)
    sage: len(H2.gens())
    1

We create the homology class corresponding to the core curve of a cylinder (the
interface here is terrible at the moment, see
https://github.com/flatsurf/sage-flatsurf/issues/166)::

    sage: from flatsurf import Polygon, similarity_surfaces, SimplicialHomology, GL2ROrbitClosure

    sage: P = Polygon(angles=[3, 4, 13])
    sage: S = similarity_surfaces.billiard(P).minimal_cover(cover_type="translation").triangulate().codomain()

    sage: from flatsurf.geometry.pyflatsurf.conversion import FlatTriangulationConversion  # optional: pyflatsurf
    sage: conversion = FlatTriangulationConversion.to_pyflatsurf(S)  # optional: pyflatsurf
    sage: T = conversion.codomain()  # optional: pyflatsurf
    sage: O = GL2ROrbitClosure(T)  # optional: pyflatsurf

    sage: D = O.decomposition((13, 37))  # optional: pyflatsurf
    sage: cylinder = D.cylinders()[0]  # optional: pyflatsurf

    sage: H = SimplicialHomology(S)
    sage: core = sum(int(str(chain[edge])) * H(conversion.section(edge.positive())) for segment in cylinder.right() for chain in [segment.saddleConnection().chain()] for edge in T.edges())  # optional: pyflatsurf
    sage: core  # optional: pyflatsurf  # random output, the chosen generators vary between operating systems
    972725347814111665129717*B[((0, -1/2*c0, -1/2*c0^2 + 3/2), 2)] + 587352809047576581321682*B[((0, -1/2*c0^2 + 1, -1/2*c0^3 + 3/2*c0), 2)] + 60771110563809382932401*B[((0, -1/2*c0^2 + 1, 1/2*c0^3 - 3/2*c0), 2)] ...

"""

######################################################################
#  This file is part of sage-flatsurf.
#
#        Copyright (C) 2022-2024 Julian Rüth
#                           2023 Julien Boulanger
#
#  sage-flatsurf is free software: you can redistribute it and/or modify
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from typing import List, Tuple

from sage.structure.parent import Parent
from sage.structure.element import Element
from sage.categories.morphism import Morphism
from sage.misc.cachefunc import cached_method

from flatsurf.geometry.morphism import MorphismSpace


[docs] class SimplicialHomologyClass(Element): r""" An element of a homology group. INPUT: - ``parent`` -- a :class:`SimplicialHomology` - ``chain`` -- an element of the :meth:`SimplicialHomologyGroup.chain_module`. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: S = translation_surfaces.regular_octagon() sage: H0 = SimplicialHomology(S, k=0) sage: g0 = H0.gens()[0] sage: g0 B[Vertex 0 of polygon 0] sage: H1 = SimplicialHomology(S, k=1) sage: g1 = H1.gens()[0] sage: g1 B[(0, 1)] sage: H2 = SimplicialHomology(S, k=2) sage: g2 = H2.gens()[0] sage: g2 B[0] TESTS:: sage: from flatsurf.geometry.homology import SimplicialHomologyClass sage: isinstance(g0, SimplicialHomologyClass) True sage: isinstance(g1, SimplicialHomologyClass) True sage: isinstance(g2, SimplicialHomologyClass) True """ def __init__(self, parent, chain): super().__init__(parent) self._chain = chain
[docs] def algebraic_intersection(self, other): r""" Return the algebraic intersection of this class of a closed curve with ``other``. INPUT: - ``other`` - a :class:`SimplicialHomologyClass` in the same homology EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: S = translation_surfaces.regular_octagon() sage: H = SimplicialHomology(S) sage: H((0, 0)).algebraic_intersection(H((0, 1))) 1 sage: a = H((0, 1)) sage: b = 3 * H((0, 0)) + 5 * H((0, 2)) - 2 * H((0, 4)) sage: a.algebraic_intersection(b) 0 sage: a = 2 * H((0, 0)) + H((0, 1)) + 3 * H((0, 2)) + H((0, 3)) + H((0, 4)) + H((0, 5)) + H((0, 7)) sage: b = H((0, 0)) + 2 * H((0, 1)) + H((0, 2)) + H((0, 3)) + 2 * H((0, 4)) + 3 * H((0, 5)) + 4 * H((0, 6)) + 3 * H((0, 7)) sage: a.algebraic_intersection(b) -6 sage: S = translation_surfaces.cathedral(1, 4) sage: H = SimplicialHomology(S) sage: a = H((0, 3)) sage: b = H((2, 1)) sage: a.algebraic_intersection(b) 0 sage: a = H((0, 3)) sage: b = H((3, 4)) + 3 * H((0, 3)) + 2 * H((0, 0)) - H((1, 7)) + 7 * H((2, 1)) - 2 * H((2, 2)) sage: a.algebraic_intersection(b) 2 """ if not self.parent().is_absolute(): raise NotImplementedError( "algebraic intersection only available for absolute homology classes" ) other = self.parent()(other) if self.parent().degree() != 1: raise NotImplementedError( "algebraic intersections only available for homology in degree 1" ) intersection = 0 multiplicities = dict(self._chain) other_multiplicities = dict(other._chain) for vertex in self.parent().surface().vertices(): counter = 0 other_counter = 0 for edge in [edge for (edge, _) in vertex.edges_ccw()[::2]]: opposite_edge = self.parent().surface().opposite_edge(*edge) counter += multiplicities.get(edge, 0) intersection += counter * other_multiplicities.get(edge, 0) intersection -= counter * other_multiplicities.get(opposite_edge, 0) counter -= multiplicities.get(opposite_edge, 0) other_counter += other_multiplicities.get(edge, 0) other_counter -= other_multiplicities.get(opposite_edge, 0) if counter: raise TypeError("homology class does not correspond to a closed curve") if other_counter: raise ValueError("homology class does not correspond to a closed curve") return intersection
def _acted_upon_(self, c, self_on_left=None): r""" Return this homology class scaled by ``c``. INPUT: - ``c`` -- an element of the base ring of scalars EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: 3 * H.gens()[0] 3*B[(0, 1)] sage: H.gens()[0] * 0 0 """ del self_on_left # parameter intentionally ignored, the side does not matter return self.parent()(c * self._chain)
[docs] @cached_method def coefficients(self): r""" Return the coefficients of this element in terms of the generators of homology. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H.gens()[0].coefficients() (1, 0) sage: H.gens()[1].coefficients() (0, 1) """ _, _, to_homology = self.parent()._homology() return tuple(to_homology(self._chain))
def _richcmp_(self, other, op): r""" Return how this class compares to ``other`` with respect to the binary relation ``op``. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H.gens()[0] == H.gens()[0] True sage: H.gens()[0] == H.gens()[1] False """ from sage.structure.richcmp import op_EQ, op_NE if op == op_NE: return not self._richcmp_(other, op_EQ) if op == op_EQ: if self is other: return True if self.parent() != other.parent(): return False return self.coefficients() == other.coefficients() return super()._richcmp_(other, op) def __hash__(self): r""" Return a hash value of this class that is compatible with :meth:`_richcmp_`. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: hash(H.gens()[0]) == hash(H.gens()[0]) True """ return hash(self.coefficients()) def _repr_(self): r""" Return a printable representation of this class. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H.gens()[0] B[(0, 1)] """ return repr(self._chain)
[docs] def coefficient(self, gen): r""" Return the multiplicity of this class at a generator of homology. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: a,b = H.gens() sage: a.coefficient(a) 1 sage: a.coefficient(b) 0 TESTS:: sage: a.coefficient(a + b) Traceback (most recent call last): ... ValueError: gen must be a generator not B[(0, 0)] + B[(0, 1)] """ coefficients = gen.coefficients() indexes = [i for (i, c) in enumerate(coefficients) if c] if len(indexes) != 1 or coefficients[indexes[0]] != 1: raise ValueError(f"gen must be a generator not {gen}") index = indexes[0] return self.coefficients()[index]
def _add_(self, other): r""" Return the formal sum of this class and ``other``. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: a, b = H.gens() sage: a + b B[(0, 0)] + B[(0, 1)] """ return self.parent()(self._chain + other._chain) def _sub_(self, other): r""" Return the formal difference of this class and ``other``. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: a, b = H.gens() sage: a - b -B[(0, 0)] + B[(0, 1)] """ return self.parent()(self._chain - other._chain) def _neg_(self): r""" Return the negative of this homology class. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: a, b = H.gens() sage: a + b B[(0, 0)] + B[(0, 1)] sage: -(a + b) -B[(0, 0)] - B[(0, 1)] """ return self.parent()(-self._chain)
[docs] def surface(self): r""" Return the surface on which this homology class in defined. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: h = H.gens()[0] sage: h.surface() Translation Surface in H_1(0) built from a square """ return self.parent().surface()
def __bool__(self): r""" Return whether this class is non-trivial. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: h = H.gens()[0] sage: bool(h) True sage: bool(h-h) False """ return bool(self._chain)
[docs] class SimplicialHomologyGroup(Parent): r""" The ``k``-th simplicial homology group of the ``surface`` with ``coefficients``. .. NOTE: This method should not be called directly since it leads to problems with pickling and uniqueness. Instead use :meth:`SimplicialHomology` or :meth:`homology` on a surface. INPUT: - ``surface`` -- a finite type surface without boundary - ``k`` -- an integer - ``coefficients`` -- a ring - ``relative`` -- a subset of points of the ``surface`` - ``implementation`` -- a string; the algorithm used to compute the homology, only ``"generic"`` is supported at the moment which uses the generic homology machinery of SageMath. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology, MutableOrientedSimilaritySurface sage: T = translation_surfaces.square_torus() Surfaces must be immutable to compute their homology:: sage: T = MutableOrientedSimilaritySurface.from_surface(T) sage: SimplicialHomology(T) Traceback (most recent call last): ... ValueError: surface must be immutable to compute homology :: sage: T.set_immutable() sage: SimplicialHomology(T) H₁(Translation Surface in H_1(0) built from a square) TESTS:: sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T, implementation="generic") sage: TestSuite(H).run() """ Element = SimplicialHomologyClass def __init__(self, surface, k, coefficients, relative, implementation, category): Parent.__init__(self, base=coefficients, category=category) if surface.is_mutable(): raise TypeError("surface must be immutable") from sage.all import ZZ if k not in ZZ: raise TypeError("k must be an integer") from sage.categories.all import Rings if coefficients not in Rings(): # pyright: ignore[reportCallIssue] raise TypeError("coefficients must be a ring") if relative: for point in relative: if point not in surface.vertices(): raise NotImplementedError( "can only compute homology relative to a subset of the vertices" ) if implementation == "generic": if not surface.is_finite_type(): raise NotImplementedError( "homology only implemented for surfaces with finitely many polygons" ) if surface.is_with_boundary(): raise NotImplementedError( "homology only implemented for surfaces without boundary" ) else: raise NotImplementedError( "cannot compute homology with this implementation yet" ) self._surface = surface self._k = k self._coefficients = coefficients self._relative = relative self._implementation = implementation
[docs] def is_absolute(self): r""" Return whether this is absolute homology (and not relative to some set of points.) EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H.is_absolute() True """ return not self._relative
[docs] def some_elements(self): r""" Return some typical homology classes (for testing.) EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H.some_elements() [0, B[(0, 1)], B[(0, 0)]] """ return [self.zero()] + list(self.gens())
[docs] def surface(self): r""" Return the surface of which this is the homology. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H.surface() == T True """ return self._surface
[docs] @cached_method def chain_module(self): r""" Return the free module of simplicial chains of the surface i.e., formal sums of simplicies, e.g., formal sums of edges of the surface. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H.chain_module() Free module generated by {(0, 1), (0, 0)} over Integer Ring """ from sage.all import FreeModule return FreeModule(self._coefficients, self.simplices())
[docs] @cached_method def simplices(self): r""" Return the simplices that form the generators of :meth:`chain_module`. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() In dimension 1, this is the set of edges:: sage: H = SimplicialHomology(T) sage: H.simplices() ((0, 1), (0, 0)) In dimension 0, this is the set of vertices:: sage: H = SimplicialHomology(T, k=0) sage: H.simplices() (Vertex 0 of polygon 0,) In dimension 2, this is the set of polygons:: sage: H = SimplicialHomology(T, k=2) sage: H.simplices() (0,) In all other dimensions, there are no simplices:: sage: H = SimplicialHomology(T, k=12) sage: H.simplices() () """ if self._k == 0: return tuple( vertex for vertex in self._surface.vertices() if vertex not in self._relative ) if self._k == 1: simplices = set() for edge in self._surface.edges(): if self._surface.opposite_edge(*edge) not in simplices: simplices.add(edge) return tuple(simplices) if self._k == 2: return tuple(self._surface.labels()) return ()
[docs] @cached_method def change(self, k=None): r""" Return this homology but in dimension ``k``. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H H₁(Translation Surface in H_1(0) built from a square) sage: H.change(k=0) H₀(Translation Surface in H_1(0) built from a square) """ return SimplicialHomology( surface=self._surface, k=k if k is not None else self._k, coefficients=self._coefficients, relative=self._relative, implementation=self._implementation, category=self.category(), )
[docs] def boundary(self, chain): r""" Return the boundary of ``chain`` as an element of the :meth:`chain_module` in lower dimension. INPUT: - ``chain`` -- an element of :meth:`chain_module` EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() :: sage: H = SimplicialHomology(T, k=0) sage: c = H.chain_module().an_element(); c 2*B[Vertex 0 of polygon 0] sage: H.boundary(c) 0 :: sage: H = SimplicialHomology(T, k=1) sage: c = H.chain_module().an_element(); c 2*B[(0, 0)] + 2*B[(0, 1)] sage: H.boundary(c) 0 :: sage: H = SimplicialHomology(T, k=2) sage: c = H.chain_module().an_element(); c 2*B[0] sage: H.boundary(c) 0 """ chain = self.chain_module()(chain) if self._k == 1: C0 = self.change(k=0).chain_module() def to_C0(point): if point in self._relative: return C0.zero() return C0(point) boundary = C0.zero() for edge, coefficient in chain: boundary += coefficient * to_C0( self._surface.point(*self._surface.opposite_edge(*edge)) ) boundary -= coefficient * to_C0(self._surface.point(*edge)) return boundary if self._k == 2: C1 = self.change(k=1).chain_module() boundary = C1.zero() for face, coefficient in chain: for edge in range(len(self._surface.polygon(face).edges())): if (face, edge) in C1.indices(): boundary += coefficient * C1((face, edge)) else: boundary -= coefficient * C1( self._surface.opposite_edge(face, edge) ) return boundary return self.change(k=self._k - 1).chain_module().zero()
@cached_method def _chain_complex(self): r""" Return the chain complex of vector spaces that is implementing this homology (if the ``"generic"`` implementation has been selected.) EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H._chain_complex() Chain complex with at most 3 nonzero terms over Integer Ring :: sage: H = SimplicialHomology(T, relative=T.vertices()) sage: H._chain_complex() Chain complex with at most 2 nonzero terms over Integer Ring """ def boundary(dimension, chain): boundary = self.change(k=dimension).boundary(chain) coefficients = boundary.dense_coefficient_list( self.change(k=dimension - 1).chain_module().indices() ) return coefficients from sage.all import ChainComplex, matrix return ChainComplex( { dimension: matrix( [ boundary(dimension, simplex) for simplex in self.change(k=dimension).chain_module().basis() ] ).transpose() for dimension in range(3) }, base_ring=self._coefficients, degree=-1, )
[docs] def zero(self) -> SimplicialHomologyClass: r""" Return the zero homology class. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H.zero() 0 """ return self(self.chain_module().zero())
@cached_method def _homology(self): r""" Return the free module isomorphic to homology, a lift from that module to the chain module, and an inverse (modulo boundaries.) EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H._homology() (Finitely generated module V/W over Integer Ring with invariants (0, 0), Generic morphism: From: Finitely generated module V/W over Integer Ring with invariants (0, 0) To: Free module generated by {(0, 1), (0, 0)} over Integer Ring, Generic morphism: From: Free module generated by {(0, 1), (0, 0)} over Integer Ring To: Finitely generated module V/W over Integer Ring with invariants (0, 0)) """ if self._implementation == "generic": C = self._chain_complex() cycles = C.differential(self._k).transpose().kernel() boundaries = C.differential(self._k + 1).transpose().image() homology = cycles.quotient(boundaries) F = self.chain_module() from sage.all import vector from_homology = homology.module_morphism( function=lambda x: F.from_vector(vector(list(x.lift().lift()))), codomain=F, ) def _to_homology(x): multiplicities = x.dense_coefficient_list(order=F.get_order()) try: cycle = cycles(multiplicities) except TypeError: if multiplicities not in cycles: raise ValueError( "chain is not a cycle so it has no representation in homology" ) raise return homology(cycle) to_homology = F.module_morphism(function=_to_homology, codomain=homology) for gen in homology.gens(): assert to_homology(from_homology(gen)) == gen return homology, from_homology, to_homology raise NotImplementedError( "cannot compute homology with this implementation yet" ) def _test_homology(self, **options): r""" Test that :meth:`_homology` computes homology correctly. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H._test_homology() """ tester = self._tester(**options) homology, from_homology, to_homology = self._homology() chains = self.chain_module() tester.assertEqual(homology, to_homology.codomain()) tester.assertEqual(homology, from_homology.domain()) tester.assertEqual(chains, to_homology.domain()) tester.assertEqual(chains, from_homology.codomain()) for gen in homology.gens(): tester.assertEqual(to_homology(from_homology(gen)), gen) def _repr_(self): r""" Return a printable representation of this homology. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H H₁(Translation Surface in H_1(0) built from a square) """ k = self._k if k == 0: k = "₀" elif k == 1: k = "₁" elif k == 2: k = "₂" else: k = f"_{k}" H_k = f"H{k}" X = repr(self.surface()) if not self.is_absolute(): X = f"{X}, {set(self._relative)}" from sage.all import ZZ if self._coefficients is not ZZ: sep = ";" X = f"{X}{sep} {self._coefficients}" return f"{H_k}({X})" def _element_constructor_(self, x): r""" Return ``x`` as an element of this homology. TESTS:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) :: sage: H(0) 0 sage: H(None) 0 :: sage: H((0, 0)) B[(0, 0)] sage: H((0, 2)) -B[(0, 0)] :: sage: H = SimplicialHomology(T, 0) sage: H(H.chain_module().gens()[0]) B[Vertex 0 of polygon 0] sage: H = SimplicialHomology(T, 1) sage: H(H.chain_module().gens()[0]) B[(0, 1)] sage: H = SimplicialHomology(T, 2) sage: H(H.chain_module().gens()[0]) B[0] """ if x == 0 or x is None: return self.element_class(self, self.chain_module().zero()) if self._k == 1 and isinstance(x, tuple) and len(x) == 2: sgn = 1 if x not in self.simplices(): x = self.surface().opposite_edge(*x) sgn = -1 assert x in self.simplices() return sgn * self.element_class(self, self.chain_module()(x)) if x.parent() is self.chain_module(): return self.element_class(self, x) raise NotImplementedError("cannot convert this element to a homology class yet")
[docs] @cached_method def gens(self) -> Tuple[SimplicialHomologyClass, ...]: r""" Return generators of homology. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() :: sage: H = SimplicialHomology(T) sage: H.gens() (B[(0, 1)], B[(0, 0)]) :: sage: H = SimplicialHomology(T, 0) sage: H.gens() (B[Vertex 0 of polygon 0],) :: sage: H = SimplicialHomology(T, 2) sage: H.gens() (B[0],) """ if self._k < 0 or self._k > 2: return () homology, from_homology, _ = self._homology() return tuple(self(from_homology(g)) for g in homology.gens())
[docs] def ngens(self): r""" Return the Betti number of this homology. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: T = translation_surfaces.square_torus() sage: H = T.homology() sage: H.ngens() 2 """ return len(self.gens())
[docs] def degree(self): r""" Return the degree `k` for this homology `H_k`. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H.degree() 1 """ return self._k
[docs] def symplectic_basis(self) -> List[SimplicialHomologyClass]: r""" Return a symplectic basis of generators of this homology group. A symplectic basis is a basis of the form `(e_1, \ldots, e_n, f_1, \ldots, f_n)` such that for the :meth:`SimplicialHomologyClass.algebraic_intersection`, `e_i \cdot e_j = f_i \cdot f_j = 0` and `e_i \cdot f_j = \delta_{ij}` for all `i` and `j`. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() :: sage: H = SimplicialHomology(T) sage: H.symplectic_basis() [B[(0, 0)], B[(0, 1)]] """ from sage.all import matrix E = matrix( self.base_ring(), [[g.algebraic_intersection(h) for h in self.gens()] for g in self.gens()], ) from sage.categories.all import Fields if self.base_ring() in Fields: from sage.matrix.symplectic_basis import symplectic_basis_over_field F, C = symplectic_basis_over_field(E) else: from sage.matrix.symplectic_basis import symplectic_basis_over_ZZ F, C = symplectic_basis_over_ZZ(E) if any(entry not in [-1, 0, 1] for row in F for entry in row): raise NotImplementedError( "cannot determine symplectic basis for this homology group over this ring yet" ) return [ sum(c * g for (c, g) in zip(row, self.gens())) for row in C ] # pyright: ignore
def _test_symplectic_basis(self, **options): r""" Verify that :meth:`symplectic_basis` has been implemented correctly. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: H._test_symplectic_basis() """ tester = self._tester(**options) basis = self.symplectic_basis() n = len(basis) tester.assertEqual(len(self.gens()), n) tester.assertEqual(n % 2, 0) A = basis[: n // 2] B = basis[n // 2 :] for i, a in enumerate(A): for j, b in enumerate(B): tester.assertEqual(a.algebraic_intersection(b), i == j) for a in A: for aa in A: tester.assertEqual(a.algebraic_intersection(aa), 0) for b in B: for bb in B: tester.assertEqual(b.algebraic_intersection(bb), 0)
[docs] def hom(self, f, codomain=None): r""" Return the homomorphism of homology induced by ``f``. INPUT: - ``f`` -- a morphism of surfaces or a matrix - ``codomain`` -- the simplicial homology this morphism maps into EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 2], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: g = H.hom(f) sage: g.matrix() # optional: pyflatsurf [1 0] [2 1] sage: H.gens() (B[(0, 1)], B[(0, 0)]) sage: [g(h) for h in H.gens()] # optional: pyflatsurf [2*B[(0, 0)] + B[(0, 1)], B[(0, 0)]] """ from flatsurf.geometry.veech_group import SurfaceMorphism from sage.matrix.matrix0 import Matrix from sage.all import Hom if isinstance(f, SurfaceMorphism): if codomain is None: codomain = f.codomain().homology() if codomain.surface() is not f.codomain(): raise ValueError("codomain must be codomain of morphism or None") if f.domain() is self.surface(): parent = Hom(self, codomain) return parent.__make_element_class__( SimplicialHomologyMorphism_induced )(parent, f) elif isinstance(f, Matrix): if codomain is None: if f.is_square(): codomain = self if codomain is None: raise NotImplementedError("cannot deduce codomain from this matrix") if f.ncols() != self.ngens(): raise ValueError( "matrix must have one column for each generator of homology" ) if f.nrows() != codomain.ngens(): raise ValueError( "matrix must have one row for each generator of the codomain" ) parent = Hom(self, codomain) return parent.__make_element_class__(SimplicialHomologyMorphism_matrix)( parent, f ) raise NotImplementedError( "cannot create a morphism in homology from this data yet" )
def _Hom_(self, Y, category=None): r""" Return the space of morphisms from this homology to ``Y``. k EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: H = S.homology() sage: End(H) Endomorphisms of H₁(Translation Surface in H_1(0) built from a square) """ if isinstance(Y, SimplicialHomologyGroup): return SimplicialHomologyMorphismSpace(self, Y, category=category) return super()._Hom_(Y, category=category) def __eq__(self, other): r""" Return whether this homology is indistinguishable from ``other``. .. NOTE:: We cannot rely on the builtin `==` by ``id`` since we need to detect homologies over equal but distinct surfaces to be equal. See :meth:`homology` for ideas on how to fix this. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: T = translation_surfaces.square_torus() sage: HH = SimplicialHomology(T) sage: H == HH True """ if not isinstance(other, SimplicialHomologyGroup): return False return ( self._surface == other._surface and self._coefficients == other._coefficients and self._relative == other._relative and self._implementation == other._implementation and self.category() == other.category() ) def __hash__(self): r""" Return a hash value for this homology that is compatible with :meth:`__eq__`. EXAMPLES:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: H = SimplicialHomology(T) sage: T = translation_surfaces.square_torus() sage: HH = SimplicialHomology(T) sage: hash(H) == hash(HH) True """ return hash( ( self._surface, self._coefficients, self._relative, self._implementation, self.category(), ) )
[docs] class SimplicialHomologyMorphismSpace(MorphismSpace): r""" The space of homomorphisms from the homology ``domain`` to ``codomain``. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 0], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: g = H.hom(f) sage: G = g.parent() Since these are homomorphisms in homology, they preserve the linear structure of the homology:: sage: g.category() Category of endsets of modules over Integer Ring TESTS:: sage: from flatsurf.geometry.homology import SimplicialHomologyMorphismSpace sage: isinstance(G, SimplicialHomologyMorphismSpace) True sage: TestSuite(G).run() """ def __init__(self, domain, codomain, category=None): from sage.all import Hom super().__init__( domain, codomain, category=category or Hom(domain, codomain).homset_category(), )
[docs] def an_element(self): r""" Return some homomorphism in homology. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: T = translation_surfaces.mcmullen_L(1, 1, 1, 1) sage: End(S.homology()).an_element() Generic endomorphism of H₁(Translation Surface in H_1(0) built from a square) Defn: [1 0] [0 1] sage: Hom(S.homology(), T.homology()).an_element() Generic morphism: From: H₁(Translation Surface in H_1(0) built from a square) To: H₁(Translation Surface in H_2(2) built from 3 squares) Defn: [0 0] [0 0] [0 0] [0 0] """ if self.domain() is self.codomain(): return self.identity() return self.zero()
[docs] def identity(self): r""" Return the identity homomorphism in this space (if it exists.) EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: T = translation_surfaces.mcmullen_L(1, 1, 1, 1) sage: End(S.homology()).identity() Generic endomorphism of H₁(Translation Surface in H_1(0) built from a square) Defn: [1 0] [0 1] """ if self.is_endomorphism_set(): from sage.all import identity_matrix matrix = identity_matrix( self.codomain().base_ring(), self.domain().ngens(), sparse=True ) return self.__make_element_class__(SimplicialHomologyMorphism_matrix)( self, matrix ) return super().identity()
[docs] def zero(self): r""" Return the zero homomorphism. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: End(S.homology()).zero() Generic endomorphism of H₁(Translation Surface in H_1(0) built from a square) Defn: [0 0] [0 0] """ from sage.all import zero_matrix return self.domain().hom( zero_matrix( self.codomain().base_ring(), nrows=self.codomain().ngens(), ncols=self.domain().ngens(), sparse=True, ), codomain=self.codomain(), )
[docs] def base_ring(self): r""" Return the ring over which these homomorphisms are defined. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: End(S.homology()).base_ring() Integer Ring """ if self.domain().base_ring() is self.codomain().base_ring(): return self.domain().base_ring() return super().base_ring()
def __reduce__(self): r""" Return a picklable version of this space. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: H = End(S.homology()).base_ring() sage: loads(dumps(H)) == H True """ return SimplicialHomologyMorphismSpace, ( self.domain(), self.codomain(), self.homset_category(), ) def __repr__(self): r""" Return a printable representation of this space of homomorphisms. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: H = End(S.homology()) sage: H Endomorphisms of H₁(Translation Surface in H_1(0) built from a square) """ if self.domain() == self.codomain(): return f"Endomorphisms of {self.domain()!r}" return f"Homomorphisms from {self.domain()!r} to {self.codomain()!r}"
[docs] class SimplicialHomologyMorphism_base(Morphism): r""" Base class for all homomorphisms in homology. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 0], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: g = H.hom(f) TESTS:: sage: from flatsurf.geometry.homology import SimplicialHomologyMorphism_base sage: isinstance(g, SimplicialHomologyMorphism_base) True sage: TestSuite(g).run() # optional: pyflatsurf """
[docs] @cached_method def matrix(self): r""" Return the matrix describing this homomorphism on the generators of homology (as a multiplication from the left.) EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.mcmullen_L(1, 1, 1, 1) sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 2], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: H.gens() (B[(0, 1)], B[(0, 0)], B[(1, 1)], B[(2, 0)]) sage: g = H.hom(f) sage: g.matrix() # optional: pyflatsurf [1 0 0 0] [1 1 2 0] [0 0 1 0] [1 0 0 1] """ from sage.all import matrix return matrix( [list(self(gen).coefficients()) for gen in self.domain().gens()] ).transpose()
def _add_(self, other): r""" Return the pointwise sum of this morphism and ``other``. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.mcmullen_L(1, 1, 1, 1) sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 2], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: g = H.hom(f) sage: h = End(H).one() sage: g + h # optional: pyflatsurf Generic endomorphism of H₁(Translation Surface in H_2(2) built from 3 squares) Defn: [2 0 0 0] [1 2 2 0] [0 0 2 0] [1 0 0 2] """ return self.domain().hom( self.matrix() + other.matrix(), codomain=self.codomain() ) def _acted_upon_(self, x, self_on_left): r""" Return the morphism given by pointwise multiplying with ``x``. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.mcmullen_L(1, 1, 1, 1) sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 2], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: g = H.hom(f) sage: (2**1234567 * g).matrix().trace() == 2**1234569 # optional: pyflatsurf True """ return self.domain().hom(x * self.matrix()) def _neg_(self): r""" Return the pointwise negative of this homomorphism. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.mcmullen_L(1, 1, 1, 1) sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 2], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: g = H.hom(f) sage: -g # optional: pyflatsurf Generic endomorphism of H₁(Translation Surface in H_2(2) built from 3 squares) Defn: [-1 0 0 0] [-1 -1 -2 0] [ 0 0 -1 0] [-1 0 0 -1] """ return self.domain().hom(-self.matrix(), codomain=self.codomain()) def _composition(self, other): r""" Return the composition of this homomorphism and ``other``. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.mcmullen_L(1, 1, 1, 1) sage: T = translation_surfaces.mcmullen_L(1, 1, 1, 2) sage: U = translation_surfaces.mcmullen_L(1, 1, 1, 3) sage: f = S.homology().hom(2 * identity_matrix(4), codomain=T.homology()) sage: g = T.homology().hom(3 * identity_matrix(4), codomain=U.homology()) sage: g * f Generic morphism: From: H₁(Translation Surface in H_2(2) built from 3 squares) To: H₁(Translation Surface in H_2(2) built from 2 squares and a rectangle) Defn: [6 0 0 0] [0 6 0 0] [0 0 6 0] [0 0 0 6] """ return other.domain().hom( self.matrix() * other.matrix(), codomain=self.codomain() ) def __bool__(self): r""" Return whether this is not the homommorphism that is zero everywhere. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.mcmullen_L(1, 1, 1, 1) sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 2], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: g = H.hom(f) sage: bool(g) # optional: pyflatsurf True sage: bool(g.parent().zero()) False """ return bool(self.matrix())
[docs] class SimplicialHomologyMorphism_matrix(SimplicialHomologyMorphism_base): r""" A homomorphism of homology that is given by a matrix that describes the homomorphism on the generators. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.mcmullen_L(1, 1, 1, 1) sage: T = translation_surfaces.square_torus() sage: f = S.homology().hom(matrix([[1, 2, 3, 4], [5, 6, 7, 8]]), codomain=T.homology()) sage: f Generic morphism: From: H₁(Translation Surface in H_2(2) built from 3 squares) To: H₁(Translation Surface in H_1(0) built from a square) Defn: [1 2 3 4] [5 6 7 8] TESTS:: sage: from flatsurf.geometry.homology import SimplicialHomologyMorphism_matrix sage: isinstance(f, SimplicialHomologyMorphism_matrix) True sage: TestSuite(f).run() """ def __init__(self, parent, matrix): super().__init__(parent) if matrix.is_mutable(): from sage.all import matrix as copy matrix = copy(matrix) matrix.set_immutable() self._matrix = matrix def _call_(self, g): r""" Return the image of ``g`` under this homomorphism. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.mcmullen_L(1, 1, 1, 1) sage: T = translation_surfaces.square_torus() sage: f = S.homology().hom(matrix([[1, 2, 3, 4], [5, 6, 7, 8]]), codomain=T.homology()) sage: [f(gen) for gen in S.homology().gens()] [5*B[(0, 0)] + B[(0, 1)], 6*B[(0, 0)] + 2*B[(0, 1)], 7*B[(0, 0)] + 3*B[(0, 1)], 8*B[(0, 0)] + 4*B[(0, 1)]] """ from sage.all import vector image = self._matrix * vector(g.coefficients()) homology, to_chain, to_homology = self.codomain()._homology() image = sum( coefficient * gen for (coefficient, gen) in zip(image, homology.gens()) ) return self.codomain()(to_chain(image)) def __eq__(self, other): r""" Return whether this morphism is indistinguishable from ``other``. .. NOTE:: We cannot override ``_richcmp_`` since our non-uniqueness of surfaces breaks the coercion framework in SageMath. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.mcmullen_L(1, 1, 1, 1) sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 2], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: g = H.hom(f) sage: h = H.hom(g.matrix()) # optional: pyflatsurf sage: h == h # optional: pyflatsurf True Note that this determines whether two morphisms are indistinguishable, not whether they are pointwise the same:: sage: h == g # optional: pyflatsurf False """ if not isinstance(other, SimplicialHomologyMorphism_matrix): return False return self.parent() == other.parent() and self._matrix == other._matrix def __hash__(self): r""" Return a hash value for this morphism that is compatible with :meth:`__eq__`. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.mcmullen_L(1, 1, 1, 1) sage: f = End(S.homology()).one() sage: g = End(S.homology()).one() sage: hash(f) == hash(g) True """ return hash((self.parent(), self._matrix)) def _repr_defn(self): r""" Helper method for :meth:`_repr_`. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.mcmullen_L(1, 1, 1, 1) sage: f = End(S.homology()).one() sage: f Generic endomorphism of H₁(Translation Surface in H_2(2) built from 3 squares) Defn: [1 0 0 0] [0 1 0 0] [0 0 1 0] [0 0 0 1] """ return repr(self._matrix)
[docs] class SimplicialHomologyMorphism_induced(SimplicialHomologyMorphism_base): r""" A homomorphism of homology induced by a morphism of surfaces. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 2], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: g = H.hom(f) TESTS:: sage: from flatsurf.geometry.homology import SimplicialHomologyMorphism_induced sage: isinstance(g, SimplicialHomologyMorphism_induced) True sage: TestSuite(g).run() # optional: pyflatsurf """ def __init__(self, parent, morphism): super().__init__(parent) self._morphism = morphism def _call_(self, x): r""" Return the image of the homology class ``x`` under this morphism. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 2], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: g = H.hom(f) sage: H.gens() (B[(0, 1)], B[(0, 0)]) sage: [g(h) for h in H.gens()] # optional: pyflatsurf [2*B[(0, 0)] + B[(0, 1)], B[(0, 0)]] """ return self._morphism._image_homology(x, codomain=self.codomain()) def _repr_type(self): r""" Helper method for :meth:`_repr_` to produce a printable representation of this homomorphism. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 2], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: g = H.hom(f) sage: g._repr_type() 'Induced' """ return "Induced" def _repr_defn(self): r""" Helper method for :meth:`_repr_` to produce a printable representation of this homomorphism. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 2], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: g = H.hom(f) sage: print(g._repr_defn()) Induced by Affine endomorphism of Translation Surface in H_1(0) built from a square Defn: Lift of linear action given by [1 2] [0 1] """ return f"Induced by {self._morphism!r}" def __eq__(self, other): r""" Return whether this morphism is indistinguishable from ``other``. .. NOTE:: We cannot override ``_richcmp_`` since our non-uniqueness of surfaces breaks the coercion framework in SageMath. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 2], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: g = H.hom(f) sage: h = H.hom(f) sage: g == h True Note that this does not compare homomorphisms pointwise:: sage: h = H.hom(g.matrix()) # optional: pyflatsurf sage: g == h # optional: pyflatsurf False """ if not isinstance(other, SimplicialHomologyMorphism_induced): return False return self.parent() == other.parent() and self._morphism == other._morphism def __hash__(self): r""" Return a hash value for this homomorphism that is compatible with :meth:`__eq__`. EXAMPLES:: sage: from flatsurf import translation_surfaces sage: S = translation_surfaces.square_torus() sage: A = S.affine_automorphism_group() sage: M = matrix([[1, 2], [0, 1]]) sage: f = A.derivative().section()(M, check=False) sage: from flatsurf import SimplicialHomology sage: H = SimplicialHomology(S) sage: g = H.hom(f) sage: h = H.hom(f) sage: hash(g) == hash(h) True """ return hash((self.parent(), self._morphism))
[docs] def SimplicialHomology( surface, k=1, coefficients=None, relative=None, implementation="generic", category=None, ): r""" Return the ``k``-th simplicial homology group of ``surface``. INPUT: - ``surface`` -- a surface - ``k`` -- an integer (default: ``1``) - ``coefficients`` -- a ring (default: the integer ring); consider the homology with coefficients in this ring - ``relative`` -- a set (default: the empty set); if non-empty, then relative homology with respect to this set is constructed. - ``implementation`` -- a string (default: ``"generic"``); the algorithm used to compute the homology groups. Currently only ``"generic"`` is supported, i.e., the groups are computed with the generic homology machinery from SageMath. - ``category`` -- a category; if not specified, a category for the homology group is chosen automatically depending on ``coefficients``. TESTS: Homology is unique and cached:: sage: from flatsurf import translation_surfaces, SimplicialHomology sage: T = translation_surfaces.square_torus() sage: SimplicialHomology(T) is SimplicialHomology(T) True """ return surface.homology(k, coefficients, relative, implementation, category)