algebraeon_geometry/simplexes/simplicial_complex.rs
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use std::collections::{HashMap, HashSet};
use super::*;
#[derive(Clone)]
pub struct SCSpxInfo<
FS: OrderedRingStructure + FieldStructure,
SP: Borrow<AffineSpace<FS>> + Clone,
T: Eq + Clone,
> {
inv_bdry: HashSet<Simplex<FS, SP>>,
label: T,
}
impl<
FS: OrderedRingStructure + FieldStructure,
SP: Borrow<AffineSpace<FS>> + Clone,
T: Eq + Clone,
> std::fmt::Debug for SCSpxInfo<FS, SP, T>
{
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
f.debug_struct("SCSpxInfo")
.field("inv_bdry", &self.inv_bdry)
.finish()
}
}
#[derive(Clone)]
pub struct LabelledSimplicialComplex<
FS: OrderedRingStructure + FieldStructure,
SP: Borrow<AffineSpace<FS>> + Clone,
T: Eq + Clone,
> {
ambient_space: SP,
simplexes: HashMap<Simplex<FS, SP>, SCSpxInfo<FS, SP, T>>,
}
pub type SimplicialComplex<FS, SP> = LabelledSimplicialComplex<FS, SP, ()>;
impl<
FS: OrderedRingStructure + FieldStructure,
SP: Borrow<AffineSpace<FS>> + Clone,
T: Eq + Clone,
> std::fmt::Debug for LabelledSimplicialComplex<FS, SP, T>
{
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
f.debug_struct("SimplicialComplex")
.field("simplexes", &self.simplexes)
.finish()
}
}
impl<
FS: OrderedRingStructure + FieldStructure,
SP: Borrow<AffineSpace<FS>> + Clone,
T: Eq + Clone,
> LabelledSimplexCollection<FS, SP, T> for LabelledSimplicialComplex<FS, SP, T>
where
FS::Set: Hash,
{
type WithLabel<S: Eq + Clone> = LabelledSimplicialComplex<FS, SP, S>;
type SubsetType = LabelledPartialSimplicialComplex<FS, SP, T>;
fn new_labelled(
ambient_space: SP,
simplexes: HashMap<Simplex<FS, SP>, T>,
) -> Result<Self, &'static str> {
for simplex in simplexes.keys() {
assert_eq!(simplex.ambient_space().borrow(), ambient_space.borrow());
if simplex.points().len() == 0 {
return Err("Simplicial complex musn't contain the null simplex");
}
}
let mut simplexes = simplexes
.into_iter()
.map(|(spx, label)| {
(
spx,
SCSpxInfo {
inv_bdry: HashSet::new(),
label,
},
)
})
.collect::<HashMap<_, _>>();
for simplex in simplexes.keys().map(|s| s.clone()).collect::<Vec<_>>() {
for bdry_spx in simplex.proper_sub_simplices_not_null() {
match simplexes.get_mut(&bdry_spx) {
Some(entry) => {
entry.inv_bdry.insert(simplex.clone());
}
None => {
return Err("Simplicial complex must be closed under taking boundaries");
}
}
}
}
Ok(Self {
ambient_space,
simplexes,
})
}
fn new_labelled_unchecked(ambient_space: SP, simplexes: HashMap<Simplex<FS, SP>, T>) -> Self {
Self::new_labelled(ambient_space, simplexes).unwrap()
}
fn ambient_space(&self) -> SP {
self.ambient_space.clone()
}
fn labelled_simplexes(&self) -> HashMap<&Simplex<FS, SP>, &T> {
self.simplexes
.iter()
.map(|(spx, info)| (spx, &info.label))
.collect()
}
fn into_labelled_simplexes(self) -> HashMap<Simplex<FS, SP>, T> {
self.simplexes
.into_iter()
.map(|(spx, info)| (spx, info.label))
.collect()
}
fn into_partial_simplicial_complex(self) -> LabelledPartialSimplicialComplex<FS, SP, T> {
LabelledPartialSimplicialComplex::new_labelled_unchecked(
self.ambient_space,
self.simplexes
.into_iter()
.map(|(spx, info)| (spx, info.label))
.collect(),
)
}
}
impl<
FS: OrderedRingStructure + FieldStructure,
SP: Borrow<AffineSpace<FS>> + Clone,
T: Eq + Clone,
> LabelledSimplicialComplex<FS, SP, T>
where
FS::Set: Hash,
{
fn check(&self) {
let mut inv_bdry_map = HashMap::new();
for spx in self.simplexes.keys() {
inv_bdry_map.insert(spx.clone(), HashSet::new());
}
for (spx, _info) in &self.simplexes {
for bdry_spx in spx.proper_sub_simplices_not_null() {
assert!(self.simplexes.contains_key(&bdry_spx));
inv_bdry_map.get_mut(&bdry_spx).unwrap().insert(spx.clone());
}
}
for (spx, info) in &self.simplexes {
assert_eq!(&info.inv_bdry, inv_bdry_map.get(spx).unwrap());
}
//check that every pair of distinct simplexes intersect in the empty set
LabelledSimplicialDisjointUnion::new_labelled_unchecked(
self.ambient_space(),
self.simplexes
.iter()
.map(|(spx, info)| (spx.clone(), info.label.clone()))
.collect(),
)
.check();
}
}
impl<FS: OrderedRingStructure + FieldStructure, SP: Borrow<AffineSpace<FS>> + Clone>
SimplicialComplex<FS, SP>
where
FS::Set: Hash,
{
pub fn interior_and_boundary(
&self,
) -> LabelledSimplicialComplex<FS, SP, InteriorBoundaryLabel> {
/*
let n be the dimension of the space self is living in
- every simplex of rank n is part of the interior
- a simplex of rank n-1 is the facet of at most 2 simplices of rank n, and is part of the interior if and only if it is the facet of exactly 2 simplices of rank n
- a simplex of rank less or equal to n-2 is part of the interior iff it is in the boundary of some strictly higher rank simplex AND every strictly higher rank simplex containing it as part of the boundary is part of the interior
*/
let n = self.ambient_space().borrow().affine_dimension();
let mut simplexes = HashMap::new();
let mut all = self.simplexes.keys().cloned().collect::<Vec<_>>();
all.sort_unstable_by_key(|s| std::cmp::Reverse(s.n())); //so that we process largest rank first
for simplex in all {
let r = simplex.n();
if r == n {
//rank n simplex is always part of the interior
simplexes.insert(simplex, InteriorBoundaryLabel::Interior);
} else {
let inv_bdry = &self.simplexes.get(&simplex).unwrap().inv_bdry;
if r == n - 1 {
//rank n-1 simplex is part of the boundary of at most 2 rank n simplices
//it is part of the boundary of the simplicial complex iff it is the boundary of exactly 2
match inv_bdry.len() {
0 | 1 => {
simplexes.insert(simplex, InteriorBoundaryLabel::Boundary);
}
2 => {
simplexes.insert(simplex, InteriorBoundaryLabel::Interior);
}
_ => panic!(
"rank n-1 simplex should be in the boundary of at most 2 rank n simplices"
),
}
} else {
//rank < n-1 simplex is part of the interior iff it is part of the boundary of at least one simplex and every such simplex is part of the interior
debug_assert!(r < n - 1);
if inv_bdry.is_empty() {
simplexes.insert(simplex, InteriorBoundaryLabel::Boundary);
} else {
if inv_bdry
.iter()
.all(|b| simplexes.get(b).unwrap() == &InteriorBoundaryLabel::Interior)
{
simplexes.insert(simplex, InteriorBoundaryLabel::Interior);
} else {
simplexes.insert(simplex, InteriorBoundaryLabel::Boundary);
}
}
}
}
}
LabelledSimplicialComplex::new_labelled(self.ambient_space(), simplexes).unwrap()
}
pub fn interior(&self) -> PartialSimplicialComplex<FS, SP> {
self.interior_and_boundary()
.subset_by_label(&InteriorBoundaryLabel::Interior)
}
pub fn boundary(&self) -> SimplicialComplex<FS, SP> {
self.interior_and_boundary()
.subset_by_label(&InteriorBoundaryLabel::Boundary)
.try_as_simplicial_complex()
.unwrap()
}
}
/*
Input:
A list of oriented simplicies which join to form a closed region of space
with negative side inside and positive side outside which join
Output:
Figure out whether the region can be filled in by fanning out from some point
If it can't: return None
If it can: return the simplicies to use to fill in the interior region
*/
fn simplify_in_region<
FS: OrderedRingStructure + FieldStructure,
SP: Borrow<AffineSpace<FS>> + Clone,
>(
space: SP,
boundary_facets: Vec<OrientedSimplex<FS, SP>>,
) -> Option<Vec<Simplex<FS, SP>>>
where
FS::Set: Hash,
{
for spx in &boundary_facets {
debug_assert_eq!(spx.ambient_space().borrow(), space.borrow());
}
let mut boundary_points: HashMap<Vector<FS, SP>, Vec<usize>> = HashMap::new();
for (idx, spx) in boundary_facets.iter().enumerate() {
for pt in spx.simplex().points() {
if boundary_points.contains_key(pt) {
boundary_points.get_mut(pt).unwrap().push(idx);
} else {
boundary_points.insert(pt.clone(), vec![idx]);
}
}
}
for (boundary_point, adjacent_facets) in boundary_points {
let mut nonadjacent_facets = (0..boundary_facets.len()).collect::<HashSet<_>>();
for idx in &adjacent_facets {
nonadjacent_facets.remove(idx);
}
if nonadjacent_facets.iter().all(|idx| {
match boundary_facets[*idx].classify_point(&boundary_point) {
OrientationSide::Positive => false,
OrientationSide::Neutral => false,
OrientationSide::Negative => true,
}
}) {
let mut nonadjacent_simplexes = HashSet::new();
for idx in nonadjacent_facets {
for spx in boundary_facets[idx].simplex().sub_simplices_not_null() {
nonadjacent_simplexes.insert(spx);
}
}
for idx in adjacent_facets {
for spx in boundary_facets[idx].simplex().sub_simplices_not_null() {
nonadjacent_simplexes.remove(&spx);
}
}
let filler = nonadjacent_simplexes
.into_iter()
.map(|spx| {
let mut points = spx.points().clone();
points.push(boundary_point.clone());
Simplex::new(spx.ambient_space().clone(), points).unwrap()
})
.collect();
return Some(filler);
}
}
None
}
impl<
FS: OrderedRingStructure + FieldStructure,
SP: Borrow<AffineSpace<FS>> + Clone,
T: Eq + Clone,
> LabelledSimplicialComplex<FS, SP, T>
where
FS::Set: Hash,
{
pub fn simplify(mut self) -> Self {
//go through each point
//compute its star
//enter the affine subspace spanned by its star
//compute its link as oriented simplices
//if point is part of the link then no simplification can be made, so move on
//check whether any point of the link is in the interior with respect to every boundary of the link
//if such a point exists, it can be used to fill in the star in a simpler way by fanning out
let mut pts_todo = HashSet::new();
for simplex in self.simplexes.keys() {
for pt in simplex.points() {
pts_todo.insert(pt.clone());
}
}
while !pts_todo.is_empty() {
let pt = {
let mut pts_todo_iter = pts_todo.into_iter();
let pt = pts_todo_iter.next().unwrap();
pts_todo = pts_todo_iter.collect();
pt
};
let pt_spx = Simplex::new(self.ambient_space(), vec![pt.clone()]).unwrap();
let (star, link) = {
let mut star = self.simplexes.get(&pt_spx).unwrap().inv_bdry.clone();
star.insert(pt_spx.clone());
let mut nbd = HashSet::new();
for spx in &star {
for bdry in spx.sub_simplices_not_null() {
nbd.insert(bdry);
}
}
let mut link = nbd.clone();
for spx in &star {
link.remove(spx);
}
debug_assert_eq!(star.len() + link.len(), nbd.len());
for link_spx in &link {
debug_assert!(self.simplexes.contains_key(&link_spx));
}
(star, link)
};
let link_points = {
let mut link_points: Vec<Vector<FS, SP>> = vec![];
for spx in &link {
for p in spx.points() {
link_points.push(p.clone());
}
}
link_points
};
let nbd_points = {
let mut nbd_points = link_points.clone();
nbd_points.push(pt.clone());
nbd_points
};
let nbd_affine_subspace = EmbeddedAffineSubspace::new_affine_span_linearly_dependent(
self.ambient_space(),
nbd_points.iter().collect(),
);
let nbd_points_img = nbd_points
.iter()
.map(|pt| nbd_affine_subspace.unembed_point(pt).unwrap())
.collect::<Vec<_>>();
let pt_img = nbd_affine_subspace.unembed_point(&pt).unwrap();
let pt_img_spx =
Simplex::new(nbd_affine_subspace.embedded_space(), vec![pt_img.clone()]).unwrap();
let star_img = star
.iter()
.map(|s| nbd_affine_subspace.unembed_simplex(s).unwrap())
.collect::<HashSet<_>>();
let link_img = link
.iter()
.map(|s| nbd_affine_subspace.unembed_simplex(s).unwrap())
.collect::<HashSet<_>>();
let nbd = LabelledSimplicialComplex::<FS, AffineSpace<FS>, T>::new(
nbd_affine_subspace.embedded_space(),
{
let mut simplexes = HashSet::new();
simplexes.extend(star_img.clone());
simplexes.extend(link_img.clone());
simplexes
},
)
.unwrap();
let nbd_interior = nbd.interior().into_simplexes();
if !nbd_interior.contains(&pt_img_spx) {
/*
pt is on the boundary of nbd and nbd looks something like this
l l l
+----------+
/ \\__ \
l / \ \__ s \ l
/ s \ \__ \
/ \ \__ \
+---------+---------+
r b p b r
where
p = point
b = boundary = intersection of star and ndb.boundary
r = rim = closure of boundary minus boundary
l = semilink = link minus rim
s = semistar = star minus boundary
so the idea here is
simplify the boundary by filling in the rim to replace the boundary
then simplify the rest by filling in the new boundary and the link to replace the star
*/
let boundary_img = star_img
.iter()
.filter(|spx| !nbd_interior.contains(&spx))
.collect::<HashSet<_>>();
let boundary = boundary_img
.iter()
.map(|spx| nbd_affine_subspace.embed_simplex(spx))
.collect::<Vec<_>>();
let semistar = {
let mut semistar = star.clone();
for spx in &boundary {
semistar.remove(spx);
}
semistar
};
debug_assert_eq!(boundary.len() + semistar.len(), star.len());
if let (Some(boundary_label), Some(semistar_label)) = (
self.common_label(boundary.iter()).cloned(),
self.common_label(semistar.iter()).cloned(),
) {
let mut boundary_img_points = HashSet::new();
for spx in &boundary_img {
for p in spx.points() {
boundary_img_points.insert(p);
}
}
let nbd_boundary_affine_subspace =
EmbeddedAffineSubspace::new_affine_span_linearly_dependent(
nbd_affine_subspace.embedded_space(),
boundary_img_points.into_iter().collect(),
);
debug_assert!(
nbd_boundary_affine_subspace
.embedded_space()
.affine_dimension()
<= nbd_affine_subspace.embedded_space().affine_dimension()
);
if nbd_boundary_affine_subspace
.embedded_space()
.affine_dimension()
+ 1
== nbd_affine_subspace.embedded_space().affine_dimension()
{
let ref_point_img = {
let mut ref_point_img = None;
for pt in &nbd_points_img {
if nbd_boundary_affine_subspace.unembed_point(pt).is_none() {
ref_point_img = Some(pt.clone());
break;
}
}
ref_point_img.unwrap()
};
let oriented_hyperplane = OrientedSimplex::new_with_negative_point(
nbd_boundary_affine_subspace.ambient_space(),
nbd_boundary_affine_subspace.get_embedding_points().clone(),
&ref_point_img,
)
.unwrap();
for pt in &nbd_points_img {
debug_assert!(
oriented_hyperplane.classify_point(pt) != OrientationSide::Positive
);
}
let rim_img = {
let mut rim_img = HashSet::new();
for spx in &boundary_img {
for bspx in spx.sub_simplices_not_null() {
rim_img.insert(bspx);
}
}
for spx in &boundary_img {
rim_img.remove(spx);
}
rim_img
};
let pt_img_img =
nbd_boundary_affine_subspace.unembed_point(&pt_img).unwrap();
let rim_img_img = rim_img
.iter()
.map(|spx| {
OrientedSimplex::new_with_negative_point(
nbd_boundary_affine_subspace.embedded_space(),
nbd_boundary_affine_subspace
.unembed_simplex(spx)
.unwrap()
.points()
.clone(),
&pt_img_img,
)
.unwrap()
})
.collect::<Vec<_>>();
if let Some(new_boundary_img_img) = simplify_in_region(
nbd_boundary_affine_subspace.embedded_space(),
rim_img_img,
) {
let new_boundary_img = new_boundary_img_img
.iter()
.map(|spx| nbd_boundary_affine_subspace.embed_simplex(spx))
.collect::<Vec<_>>();
let sphere_img = {
let mut sphere_img = vec![];
for spx in &new_boundary_img {
if spx.n() + 1
== nbd_affine_subspace.embedded_space().affine_dimension()
{
sphere_img.push(
OrientedSimplex::new_with_negative_point(
nbd_affine_subspace.embedded_space(),
spx.points().clone(),
&ref_point_img,
)
.unwrap(),
);
}
}
for spx in &link_img {
if spx.n() + 1
== nbd_affine_subspace.embedded_space().affine_dimension()
{
sphere_img.push(
OrientedSimplex::new_with_negative_point(
nbd_affine_subspace.embedded_space(),
spx.points().clone(),
&pt_img,
)
.unwrap(),
);
}
}
sphere_img
};
if let Some(new_star_img) =
simplify_in_region(nbd_affine_subspace.embedded_space(), sphere_img)
{
self.remove_simplexes_unchecked(star.into_iter().collect());
self.add_simplexes_unchecked(
new_boundary_img
.into_iter()
.map(|spx_img| nbd_affine_subspace.embed_simplex(&spx_img))
.collect(),
&boundary_label,
);
self.add_simplexes_unchecked(
new_star_img
.into_iter()
.map(|spx_img| nbd_affine_subspace.embed_simplex(&spx_img))
.collect(),
&semistar_label,
);
pts_todo.extend(link_points);
}
}
}
}
} else {
/*
pt is in the interior and nbd looks something like
l
+---------+
/ \ / \
l / \ s / \ l
/ s \ / s \
/ \ / \
+---------p---------+
\ / \ /
\ s / \ s /
l \ / s \ / l
\ / \ /
+---------+
l
where
p = point
s = star
l = link
*/
if let Some(star_label) = self.common_label(star.iter()).cloned() {
let boundary = link_img
.iter()
.filter(|spx| {
let n = spx.n();
let a = nbd_affine_subspace.embedded_space().affine_dimension();
if n >= a {
unreachable!()
} else if n + 1 == a {
true
} else {
debug_assert!(n + 1 < a);
false
}
})
.map(|spx| {
OrientedSimplex::new_with_negative_point(
nbd_affine_subspace.embedded_space(),
spx.points().clone(),
&pt_img,
)
.unwrap()
})
.collect();
if let Some(new_star_img) =
simplify_in_region(nbd_affine_subspace.embedded_space(), boundary)
{
self.remove_simplexes_unchecked(star.into_iter().collect());
self.add_simplexes_unchecked(
new_star_img
.into_iter()
.map(|spx_img| nbd_affine_subspace.embed_simplex(&spx_img))
.collect(),
&star_label,
);
pts_todo.extend(link_points);
}
}
}
}
#[cfg(debug_assertions)]
self.check();
self
}
// #[deprecated]
// pub fn frick(self) -> LabelledSimplicialComplex<FS, SP, usize> {
// let mut count = 0;
// LabelledSimplicialComplex::new_labelled(
// self.ambient_space().clone(),
// self.simplexes
// .iter()
// .map(|(spx, _)| {
// count += 1;
// (spx.clone(), count)
// })
// .collect(),
// )
// .unwrap()
// }
//remove simplexes and remove them from the inverse boundary of any others
//self may not be in a valid state after this operation
fn remove_simplexes_unchecked(&mut self, simplexes: Vec<Simplex<FS, SP>>) {
for spx in &simplexes {
for bdry_spx in spx.proper_sub_simplices_not_null() {
match self.simplexes.get_mut(&bdry_spx) {
Some(info) => {
info.inv_bdry.remove(spx);
}
None => {}
}
}
}
for spx in &simplexes {
self.simplexes.remove(spx);
}
}
fn remove_simplexes(&mut self, simplexes: Vec<Simplex<FS, SP>>) {
self.remove_simplexes_unchecked(simplexes);
#[cfg(debug_assertions)]
self.check();
}
//add the given simplexes and add them to the inverse boundary map on anything on their boundaries
//must be added together to cover the case where there are mutual boundary relations
//self may not be in a valid state after this operation
fn add_simplexes_unchecked(&mut self, simplexes: Vec<Simplex<FS, SP>>, label: &T) {
for spx in &simplexes {
self.simplexes.insert(
spx.clone(),
SCSpxInfo {
inv_bdry: HashSet::new(),
label: label.clone(),
},
);
}
for spx in &simplexes {
for bdry_spx in spx.proper_sub_simplices_not_null() {
self.simplexes
.get_mut(&bdry_spx)
.unwrap()
.inv_bdry
.insert(spx.clone());
}
}
}
fn add_simplexes(&mut self, simplexes: Vec<Simplex<FS, SP>>, label: &T) {
self.add_simplexes_unchecked(simplexes, label);
#[cfg(debug_assertions)]
self.check();
}
}