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blender-archive/source/blender/blenlib/tests/BLI_mesh_intersect_test.cc

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File headers: SPDX License migration Use a shorter/simpler license convention, stops the header taking so much space. Follow the SPDX license specification: https://spdx.org/licenses - C/C++/objc/objc++ - Python - Shell Scripts - CMake, GNUmakefile While most of the source tree has been included - `./extern/` was left out. - `./intern/cycles` & `./intern/atomic` are also excluded because they use different header conventions. doc/license/SPDX-license-identifiers.txt has been added to list SPDX all used identifiers. See P2788 for the script that automated these edits. Reviewed By: brecht, mont29, sergey Ref D14069
2022-02-11 09:07:11 +11:00
/* SPDX-License-Identifier: Apache-2.0 */
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
#include "testing/testing.h"
#include <algorithm>
#include <fstream>
#include <iostream>
#include "PIL_time.h"
#include "BLI_array.hh"
#include "BLI_math_mpq.hh"
BLI: Refactor vector types & functions to use templates This patch implements the vector types (i.e:`float2`) by making heavy usage of templating. All vector functions are now outside of the vector classes (inside the `blender::math` namespace) and are not vector size dependent for the most part. In the ongoing effort to make shaders less GL centric, we are aiming to share more code between GLSL and C++ to avoid code duplication. ####Motivations: - We are aiming to share UBO and SSBO structures between GLSL and C++. This means we will use many of the existing vector types and others we currently don't have (uintX, intX). All these variations were asking for many more code duplication. - Deduplicate existing code which is duplicated for each vector size. - We also want to share small functions. Which means that vector functions should be static and not in the class namespace. - Reduce friction to use these types in new projects due to their incompleteness. - The current state of the `BLI_(float|double|mpq)(2|3|4).hh` is a bit of a let down. Most clases are incomplete, out of sync with each others with different codestyles, and some functions that should be static are not (i.e: `float3::reflect()`). ####Upsides: - Still support `.x, .y, .z, .w` for readability. - Compact, readable and easilly extendable. - All of the vector functions are available for all the vectors types and can be restricted to certain types. Also template specialization let us define exception for special class (like mpq). - With optimization ON, the compiler unroll the loops and performance is the same. ####Downsides: - Might impact debugability. Though I would arge that the bugs are rarelly caused by the vector class itself (since the operations are quite trivial) but by the type conversions. - Might impact compile time. I did not saw a significant impact since the usage is not really widespread. - Functions needs to be rewritten to support arbitrary vector length. For instance, one can't call `len_squared_v3v3` in `math::length_squared()` and call it a day. - Type cast does not work with the template version of the `math::` vector functions. Meaning you need to manually cast `float *` and `(float *)[3]` to `float3` for the function calls. i.e: `math::distance_squared(float3(nearest.co), positions[i]);` - Some parts might loose in readability: `float3::dot(v1.normalized(), v2.normalized())` becoming `math::dot(math::normalize(v1), math::normalize(v2))` But I propose, when appropriate, to use `using namespace blender::math;` on function local or file scope to increase readability. `dot(normalize(v1), normalize(v2))` ####Consideration: - Include back `.length()` method. It is quite handy and is more C++ oriented. - I considered the GLM library as a candidate for replacement. It felt like too much for what we need and would be difficult to extend / modify to our needs. - I used Macros to reduce code in operators declaration and potential copy paste bugs. This could reduce debugability and could be reverted. - This touches `delaunay_2d.cc` and the intersection code. I would like to know @howardt opinion on the matter. - The `noexcept` on the copy constructor of `mpq(2|3)` is being removed. But according to @JacquesLucke it is not a real problem for now. I would like to give a huge thanks to @JacquesLucke who helped during this and pushed me to reduce the duplication further. Reviewed By: brecht, sergey, JacquesLucke Differential Revision: https://developer.blender.org/D13791
2022-01-12 12:57:07 +01:00
#include "BLI_math_vec_mpq_types.hh"
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
#include "BLI_mesh_intersect.hh"
#include "BLI_task.h"
#include "BLI_vector.hh"
#define DO_REGULAR_TESTS 1
#define DO_PERF_TESTS 0
Fix to previous commit to allow building without WITH_GMP.
2020-08-28 11:43:56 -04:00
#ifdef WITH_GMP
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
namespace blender::meshintersect::tests {
constexpr bool DO_OBJ = false;
/* Build and hold an IMesh from a string spec. Also hold and own resources used by IMesh. */
class IMeshBuilder {
public:
IMesh imesh;
IMeshArena arena;
/* "Edge orig" indices are an encoding of <input face#, position in face of start of edge>. */
static constexpr int MAX_FACE_LEN = 1000; /* Used for forming "orig edge" indices only. */
static int edge_index(int face_index, int facepos)
{
return face_index * MAX_FACE_LEN + facepos;
}
static std::pair<int, int> face_and_pos_for_edge_index(int e_index)
{
return std::pair<int, int>(e_index / MAX_FACE_LEN, e_index % MAX_FACE_LEN);
}
Cleanup: spelling in comments Use <pre>..</pre> for pseudo-code.
2022-03-17 10:04:45 +11:00
/**
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
* Spec should have form:
Cleanup: spelling in comments Use <pre>..</pre> for pseudo-code.
2022-03-17 10:04:45 +11:00
* <pre>
* #verts #faces
* mpq_class mpq_class mpq_clas [#verts lines]
* int int int ... [#faces lines; indices into verts for given face]
* </pre>
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
*/
IMeshBuilder(const char *spec)
{
std::istringstream ss(spec);
std::string line;
getline(ss, line);
std::istringstream hdrss(line);
int nv, nf;
hdrss >> nv >> nf;
if (nv == 0 || nf == 0) {
return;
}
arena.reserve(nv, nf);
Vector<const Vert *> verts;
Vector<Face *> faces;
bool spec_ok = true;
int v_index = 0;
while (v_index < nv && spec_ok && getline(ss, line)) {
std::istringstream iss(line);
mpq_class p0;
mpq_class p1;
mpq_class p2;
iss >> p0 >> p1 >> p2;
spec_ok = !iss.fail();
if (spec_ok) {
verts.append(arena.add_or_find_vert(mpq3(p0, p1, p2), v_index));
}
++v_index;
}
if (v_index != nv) {
spec_ok = false;
}
int f_index = 0;
while (f_index < nf && spec_ok && getline(ss, line)) {
std::istringstream fss(line);
Vector<const Vert *> face_verts;
Vector<int> edge_orig;
int fpos = 0;
while (spec_ok && fss >> v_index) {
if (v_index < 0 || v_index >= nv) {
spec_ok = false;
continue;
}
face_verts.append(verts[v_index]);
edge_orig.append(edge_index(f_index, fpos));
++fpos;
}
if (fpos < 3) {
spec_ok = false;
}
if (spec_ok) {
Face *facep = arena.add_face(face_verts, f_index, edge_orig);
faces.append(facep);
}
++f_index;
}
if (f_index != nf) {
spec_ok = false;
}
if (!spec_ok) {
std::cout << "Bad spec: " << spec;
return;
}
imesh = IMesh(faces);
}
};
/* Return a const Face * in mesh with verts equal to v0, v1, and v2, in
* some cyclic order; return nullptr if not found.
*/
static const Face *find_tri_with_verts(const IMesh &mesh,
const Vert *v0,
const Vert *v1,
const Vert *v2)
{
Face f_arg({v0, v1, v2}, 0, NO_INDEX);
for (const Face *f : mesh.faces()) {
if (f->cyclic_equal(f_arg)) {
return f;
}
}
return nullptr;
}
/* How many instances of a triangle with v0, v1, v2 are in the mesh? */
static int count_tris_with_verts(const IMesh &mesh, const Vert *v0, const Vert *v1, const Vert *v2)
{
Face f_arg({v0, v1, v2}, 0, NO_INDEX);
int ans = 0;
for (const Face *f : mesh.faces()) {
if (f->cyclic_equal(f_arg)) {
++ans;
}
}
return ans;
}
/* What is the starting position, if any, of the edge (v0, v1), in either order, in f? -1 if none.
*/
static int find_edge_pos_in_tri(const Vert *v0, const Vert *v1, const Face *f)
{
for (int pos : f->index_range()) {
int nextpos = f->next_pos(pos);
if (((*f)[pos] == v0 && (*f)[nextpos] == v1) || ((*f)[pos] == v1 && (*f)[nextpos] == v0)) {
return static_cast<int>(pos);
}
}
return -1;
}
Cleanup: clang-format
2020-08-28 10:04:26 -06:00
# if DO_REGULAR_TESTS
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
TEST(mesh_intersect, Mesh)
{
Vector<const Vert *> verts;
Vector<Face *> faces;
IMeshArena arena;
verts.append(arena.add_or_find_vert(mpq3(0, 0, 1), 0));
verts.append(arena.add_or_find_vert(mpq3(1, 0, 1), 1));
verts.append(arena.add_or_find_vert(mpq3(0.5, 1, 1), 2));
faces.append(arena.add_face(verts, 0, {10, 11, 12}));
IMesh mesh(faces);
const Face *f = mesh.face(0);
EXPECT_TRUE(f->is_tri());
}
Fix T89330 Exact Boolean fails on a simple model. The problem was an optimization I put in to triangulate quads. It was wrong if the quad, after projecting onto a 2d plane, was not convex. Handling quads the same as other faces fixes the bug. Unfortunately, this will slow down Exact Boolean when the input has many quads (the usual case, of course). Will attempt to fix that with a later change, but for now, this at least restores correctness.
2021-06-26 17:49:52 -04:00
TEST(mesh_intersect, TriangulateTri)
{
const char *spec = R"(3 1
0 0 0
1 0 0
1/2 1 0
0 1 2
)";
IMeshBuilder mb(spec);
IMesh im_tri = triangulate_polymesh(mb.imesh, &mb.arena);
EXPECT_EQ(im_tri.faces().size(), 1);
}
TEST(mesh_intersect, TriangulateQuad)
{
const char *spec = R"(4 1
0 0 0
1 0 0
1 1 0
0 1 0
0 1 2 3
)";
IMeshBuilder mb(spec);
IMesh im_tri = triangulate_polymesh(mb.imesh, &mb.arena);
EXPECT_EQ(im_tri.faces().size(), 2);
}
TEST(mesh_intersect, TriangulatePentagon)
{
const char *spec = R"(5 1
0 0 0
1 0 0
1 1 0
1/2 2 0
0 1 0
0 1 2 3 4
)";
IMeshBuilder mb(spec);
IMesh im_tri = triangulate_polymesh(mb.imesh, &mb.arena);
EXPECT_EQ(im_tri.faces().size(), 3);
if (DO_OBJ) {
write_obj_mesh(im_tri, "pentagon");
}
}
TEST(mesh_intersect, TriangulateTwoFaces)
{
const char *spec = R"(7 2
461/250 -343/125 103/1000
-3/40 -453/200 -97/500
237/100 -321/200 -727/500
451/1000 -563/500 -1751/1000
12/125 -2297/1000 -181/1000
12/125 -411/200 -493/1000
1959/1000 -2297/1000 -493/1000
1 3 2 0 6 5 4
6 0 1 4
)";
IMeshBuilder mb(spec);
IMesh im_tri = triangulate_polymesh(mb.imesh, &mb.arena);
EXPECT_EQ(im_tri.faces().size(), 7);
if (DO_OBJ) {
write_obj_mesh(im_tri, "twofaces");
}
}
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
TEST(mesh_intersect, OneTri)
{
const char *spec = R"(3 1
0 0 0
1 0 0
1/2 1 0
0 1 2
)";
IMeshBuilder mb(spec);
IMesh imesh = trimesh_self_intersect(mb.imesh, &mb.arena);
imesh.populate_vert();
EXPECT_EQ(imesh.vert_size(), 3);
EXPECT_EQ(imesh.face_size(), 1);
const Face &f_in = *mb.imesh.face(0);
const Face &f_out = *imesh.face(0);
EXPECT_EQ(f_in.orig, f_out.orig);
for (int i = 0; i < 3; ++i) {
EXPECT_EQ(f_in[i], f_out[i]);
EXPECT_EQ(f_in.edge_orig[i], f_out.edge_orig[i]);
}
}
TEST(mesh_intersect, TriTri)
{
const char *spec = R"(6 2
0 0 0
4 0 0
0 4 0
1 0 0
2 0 0
1 1 0
0 1 2
3 4 5
)";
/* Second triangle is smaller and congruent to first, resting on same base, partway along. */
IMeshBuilder mb(spec);
IMesh out = trimesh_self_intersect(mb.imesh, &mb.arena);
out.populate_vert();
EXPECT_EQ(out.vert_size(), 6);
EXPECT_EQ(out.face_size(), 6);
if (out.vert_size() == 6 && out.face_size() == 6) {
const Vert *v0 = mb.arena.find_vert(mpq3(0, 0, 0));
const Vert *v1 = mb.arena.find_vert(mpq3(4, 0, 0));
const Vert *v2 = mb.arena.find_vert(mpq3(0, 4, 0));
const Vert *v3 = mb.arena.find_vert(mpq3(1, 0, 0));
const Vert *v4 = mb.arena.find_vert(mpq3(2, 0, 0));
const Vert *v5 = mb.arena.find_vert(mpq3(1, 1, 0));
EXPECT_TRUE(v0 != nullptr && v1 != nullptr && v2 != nullptr);
EXPECT_TRUE(v3 != nullptr && v4 != nullptr && v5 != nullptr);
if (v0 != nullptr && v1 != nullptr && v2 != nullptr && v3 != nullptr && v4 != nullptr &&
v5 != nullptr) {
EXPECT_EQ(v0->orig, 0);
EXPECT_EQ(v1->orig, 1);
const Face *f0 = find_tri_with_verts(out, v4, v1, v5);
const Face *f1 = find_tri_with_verts(out, v3, v4, v5);
const Face *f2 = find_tri_with_verts(out, v0, v3, v5);
const Face *f3 = find_tri_with_verts(out, v0, v5, v2);
const Face *f4 = find_tri_with_verts(out, v5, v1, v2);
EXPECT_TRUE(f0 != nullptr && f1 != nullptr && f2 != nullptr && f3 != nullptr &&
f4 != nullptr);
/* For boolean to work right, there need to be two copies of the smaller triangle in the
* output. */
EXPECT_EQ(count_tris_with_verts(out, v3, v4, v5), 2);
if (f0 != nullptr && f1 != nullptr && f2 != nullptr && f3 != nullptr && f4 != nullptr) {
EXPECT_EQ(f0->orig, 0);
EXPECT_TRUE(f1->orig == 0 || f1->orig == 1);
EXPECT_EQ(f2->orig, 0);
EXPECT_EQ(f3->orig, 0);
EXPECT_EQ(f4->orig, 0);
}
int e03 = find_edge_pos_in_tri(v0, v3, f2);
int e34 = find_edge_pos_in_tri(v3, v4, f1);
int e45 = find_edge_pos_in_tri(v4, v5, f1);
int e05 = find_edge_pos_in_tri(v0, v5, f3);
int e15 = find_edge_pos_in_tri(v1, v5, f0);
EXPECT_TRUE(e03 != -1 && e34 != -1 && e45 != -1 && e05 != -1 && e15 != -1);
if (e03 != -1 && e34 != -1 && e45 != -1 && e05 != -1 && e15 != -1) {
EXPECT_EQ(f2->edge_orig[e03], 0);
EXPECT_TRUE(f1->edge_orig[e34] == 0 ||
f1->edge_orig[e34] == 1 * IMeshBuilder::MAX_FACE_LEN);
EXPECT_EQ(f1->edge_orig[e45], 1 * IMeshBuilder::MAX_FACE_LEN + 1);
EXPECT_EQ(f3->edge_orig[e05], NO_INDEX);
EXPECT_EQ(f0->edge_orig[e15], NO_INDEX);
}
}
}
if (DO_OBJ) {
write_obj_mesh(out, "tritri");
}
}
TEST(mesh_intersect, TriTriReversed)
{
/* Like TriTri but with triangles of opposite orientation.
* This matters because projection to 2D will now need reversed triangles. */
const char *spec = R"(6 2
0 0 0
4 0 0
0 4 0
1 0 0
2 0 0
1 1 0
0 2 1
3 5 4
)";
IMeshBuilder mb(spec);
IMesh out = trimesh_self_intersect(mb.imesh, &mb.arena);
out.populate_vert();
EXPECT_EQ(out.vert_size(), 6);
EXPECT_EQ(out.face_size(), 6);
if (out.vert_size() == 6 && out.face_size() == 6) {
const Vert *v0 = mb.arena.find_vert(mpq3(0, 0, 0));
const Vert *v1 = mb.arena.find_vert(mpq3(4, 0, 0));
const Vert *v2 = mb.arena.find_vert(mpq3(0, 4, 0));
const Vert *v3 = mb.arena.find_vert(mpq3(1, 0, 0));
const Vert *v4 = mb.arena.find_vert(mpq3(2, 0, 0));
const Vert *v5 = mb.arena.find_vert(mpq3(1, 1, 0));
EXPECT_TRUE(v0 != nullptr && v1 != nullptr && v2 != nullptr);
EXPECT_TRUE(v3 != nullptr && v4 != nullptr && v5 != nullptr);
if (v0 != nullptr && v1 != nullptr && v2 != nullptr && v3 != nullptr && v4 != nullptr &&
v5 != nullptr) {
EXPECT_EQ(v0->orig, 0);
EXPECT_EQ(v1->orig, 1);
const Face *f0 = find_tri_with_verts(out, v4, v5, v1);
const Face *f1 = find_tri_with_verts(out, v3, v5, v4);
const Face *f2 = find_tri_with_verts(out, v0, v5, v3);
const Face *f3 = find_tri_with_verts(out, v0, v2, v5);
const Face *f4 = find_tri_with_verts(out, v5, v2, v1);
EXPECT_TRUE(f0 != nullptr && f1 != nullptr && f2 != nullptr && f3 != nullptr &&
f4 != nullptr);
/* For boolean to work right, there need to be two copies of the smaller triangle in the
* output. */
EXPECT_EQ(count_tris_with_verts(out, v3, v5, v4), 2);
if (f0 != nullptr && f1 != nullptr && f2 != nullptr && f3 != nullptr && f4 != nullptr) {
EXPECT_EQ(f0->orig, 0);
EXPECT_TRUE(f1->orig == 0 || f1->orig == 1);
EXPECT_EQ(f2->orig, 0);
EXPECT_EQ(f3->orig, 0);
EXPECT_EQ(f4->orig, 0);
}
int e03 = find_edge_pos_in_tri(v0, v3, f2);
int e34 = find_edge_pos_in_tri(v3, v4, f1);
int e45 = find_edge_pos_in_tri(v4, v5, f1);
int e05 = find_edge_pos_in_tri(v0, v5, f3);
int e15 = find_edge_pos_in_tri(v1, v5, f0);
EXPECT_TRUE(e03 != -1 && e34 != -1 && e45 != -1 && e05 != -1 && e15 != -1);
if (e03 != -1 && e34 != -1 && e45 != -1 && e05 != -1 && e15 != -1) {
EXPECT_EQ(f2->edge_orig[e03], 2);
EXPECT_TRUE(f1->edge_orig[e34] == 2 ||
f1->edge_orig[e34] == 1 * IMeshBuilder::MAX_FACE_LEN + 2);
EXPECT_EQ(f1->edge_orig[e45], 1 * IMeshBuilder::MAX_FACE_LEN + 1);
EXPECT_EQ(f3->edge_orig[e05], NO_INDEX);
EXPECT_EQ(f0->edge_orig[e15], NO_INDEX);
}
}
}
if (DO_OBJ) {
write_obj_mesh(out, "tritrirev");
}
}
TEST(mesh_intersect, TwoTris)
{
Array<mpq3> verts = {
mpq3(1, 1, 1), mpq3(1, 4, 1), mpq3(1, 1, 4), /* T0 */
mpq3(2, 2, 2), mpq3(-3, 3, 2), mpq3(-4, 1, 3), /* T1 */
mpq3(2, 2, 2), mpq3(-3, 3, 2), mpq3(0, 3, 5), /* T2 */
mpq3(2, 2, 2), mpq3(-3, 3, 2), mpq3(0, 3, 3), /* T3 */
mpq3(1, 0, 0), mpq3(2, 4, 1), mpq3(-3, 2, 2), /* T4 */
mpq3(0, 2, 1), mpq3(-2, 3, 3), mpq3(0, 1, 3), /* T5 */
mpq3(1.5, 2, 0.5), mpq3(-2, 3, 3), mpq3(0, 1, 3), /* T6 */
mpq3(1, 0, 0), mpq3(-2, 3, 3), mpq3(0, 1, 3), /* T7 */
mpq3(1, 0, 0), mpq3(-3, 2, 2), mpq3(0, 1, 3), /* T8 */
mpq3(1, 0, 0), mpq3(-1, 1, 1), mpq3(0, 1, 3), /* T9 */
mpq3(3, -1, -1), mpq3(-1, 1, 1), mpq3(0, 1, 3), /* T10 */
mpq3(0, 0.5, 0.5), mpq3(-1, 1, 1), mpq3(0, 1, 3), /* T11 */
mpq3(2, 1, 1), mpq3(3, 5, 2), mpq3(-2, 3, 3), /* T12 */
mpq3(2, 1, 1), mpq3(3, 5, 2), mpq3(-2, 3, 4), /* T13 */
mpq3(2, 2, 5), mpq3(-3, 3, 5), mpq3(0, 3, 10), /* T14 */
mpq3(0, 0, 0), mpq3(4, 4, 0), mpq3(-4, 2, 4), /* T15 */
mpq3(0, 1.5, 1), mpq3(1, 2.5, 1), mpq3(-1, 2, 2), /* T16 */
mpq3(3, 0, -2), mpq3(7, 4, -2), mpq3(-1, 2, 2), /* T17 */
mpq3(3, 0, -2), mpq3(3, 6, 2), mpq3(-1, 2, 2), /* T18 */
mpq3(7, 4, -2), mpq3(3, 6, 2), mpq3(-1, 2, 2), /* T19 */
mpq3(5, 2, -2), mpq3(1, 4, 2), mpq3(-3, 0, 2), /* T20 */
mpq3(2, 2, 0), mpq3(1, 4, 2), mpq3(-3, 0, 2), /* T21 */
mpq3(0, 0, 0), mpq3(4, 4, 0), mpq3(-3, 0, 2), /* T22 */
mpq3(0, 0, 0), mpq3(4, 4, 0), mpq3(-1, 2, 2), /* T23 */
mpq3(2, 2, 0), mpq3(4, 4, 0), mpq3(0, 3, 2), /* T24 */
mpq3(0, 0, 0), mpq3(-4, 2, 4), mpq3(4, 4, 0), /* T25 */
};
struct two_tri_test_spec {
int t0;
int t1;
int nv_out;
int nf_out;
};
Array<two_tri_test_spec> test_tris = Span<two_tri_test_spec>{
{0, 1, 8, 8}, /* 0: T1 pierces T0 inside at (1,11/6,13/6) and (1,11/5,2). */
{0, 2, 8, 8}, /* 1: T2 intersects T0 inside (1,11/5,2) and edge (1,7/3,8/3). */
{0, 3, 8, 7}, /* 2: T3 intersects T0 (1,11/5,2) and edge-edge (1,5/2,5/2). */
{4, 5, 6, 4}, /* 3: T5 touches T4 inside (0,2,1). */
{4, 6, 6, 3}, /* 4: T6 touches T4 on edge (3/2,2/1/2). */
{4, 7, 5, 2}, /* 5: T7 touches T4 on vert (1,0,0). */
{4, 8, 4, 2}, /* 6: T8 shared edge with T4 (1,0,0)(-3,2,2). */
{4, 9, 5, 3}, /* 7: T9 edge (1,0,0)(-1,1,1) is subset of T4 edge. */
{4, 10, 6, 4}, /* 8: T10 edge overlaps T4 edge with seg (-1,1,0)(1,0,0). */
{4, 11, 6, 4}, /* 9: T11 edge (-1,1,1)(0,1/2,1/2) inside T4 edge. */
{4, 12, 6, 2}, /* 10: parallel planes, not intersecting. */
{4, 13, 6, 2}, /* 11: non-parallel planes, not intersecting, all one side. */
Cleanup: spelling in comments
2021-09-23 22:06:49 +10:00
{0, 14, 6, 2}, /* 12: non-parallel planes, not intersecting, alternate sides. */
/* Following are all co-planar cases. */
Cleanup: consistent use of tags: NOTE/TODO/FIXME/XXX Also use doxy style function reference `#` prefix chars when referencing identifiers.
2021-07-03 23:08:40 +10:00
{15, 16, 6, 8}, /* 13: T16 inside T15. NOTE: dup'd tri is expected. */
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
{15, 17, 8, 8}, /* 14: T17 intersects one edge of T15 at (1,1,0)(3,3,0). */
{15, 18, 10, 12}, /* 15: T18 intersects T15 at (1,1,0)(3,3,0)(3,15/4,1/2)(0,3,2). */
{15, 19, 8, 10}, /* 16: T19 intersects T15 at (3,3,0)(0,3,2). */
{15, 20, 12, 14}, /* 17: T20 intersects T15 on three edges, six intersects. */
{15, 21, 10, 11}, /* 18: T21 intersects T15 on three edges, touching one. */
{15, 22, 5, 4}, /* 19: T22 shares edge T15, one other outside. */
{15, 23, 4, 4}, /* 20: T23 shares edge T15, one other outside. */
{15, 24, 5, 4}, /* 21: T24 shares two edges with T15. */
{15, 25, 3, 2}, /* 22: T25 same T15, reverse orientation. */
};
static int perms[6][3] = {{0, 1, 2}, {0, 2, 1}, {1, 0, 2}, {1, 2, 0}, {2, 0, 1}, {2, 1, 0}};
const int do_only_test = -1; /* Make this negative to do all tests. */
for (int test = 0; test < test_tris.size(); ++test) {
if (do_only_test >= 0 && test != do_only_test) {
continue;
}
int tri1_index = test_tris[test].t0;
int tri2_index = test_tris[test].t1;
int co1_i = 3 * tri1_index;
int co2_i = 3 * tri2_index;
const bool verbose = false;
if (verbose) {
std::cout << "\nTest " << test << ": T" << tri1_index << " intersect T" << tri2_index
<< "\n";
}
const bool do_all_perms = true;
const int perm_limit = do_all_perms ? 3 : 1;
for (int i = 0; i < perm_limit; ++i) {
for (int j = 0; j < perm_limit; ++j) {
if (do_all_perms && verbose) {
std::cout << "\nperms " << i << " " << j << "\n";
}
IMeshArena arena;
arena.reserve(2 * 3, 2);
Array<const Vert *> f0_verts(3);
Array<const Vert *> f1_verts(3);
for (int k = 0; k < 3; ++k) {
f0_verts[k] = arena.add_or_find_vert(verts[co1_i + perms[i][k]], k);
}
for (int k = 0; k < 3; ++k) {
f1_verts[k] = arena.add_or_find_vert(verts[co2_i + perms[i][k]], k + 3);
}
Face *f0 = arena.add_face(f0_verts, 0, {0, 1, 2});
Face *f1 = arena.add_face(f1_verts, 1, {3, 4, 5});
IMesh in_mesh({f0, f1});
IMesh out_mesh = trimesh_self_intersect(in_mesh, &arena);
out_mesh.populate_vert();
EXPECT_EQ(out_mesh.vert_size(), test_tris[test].nv_out);
EXPECT_EQ(out_mesh.face_size(), test_tris[test].nf_out);
bool constexpr dump_input = true;
if (DO_OBJ && i == 0 && j == 0) {
if (dump_input) {
std::string name = "test_tt_in" + std::to_string(test);
write_obj_mesh(in_mesh, name);
}
std::string name = "test_tt" + std::to_string(test);
write_obj_mesh(out_mesh, name);
}
}
}
}
}
TEST(mesh_intersect, OverlapCluster)
{
/* Chain of 5 overlapping coplanar tris.
* Ordered so that clustering will make two separate clusters
* that it will have to merge into one cluster with everything. */
const char *spec = R"(15 5
0 0 0
1 0 0
1/2 1 0
1/2 0 0
3/2 0 0
1 1 0
1 0 0
2 0 0
3/2 1 0
3/2 0 0
5/2 0 0
2 1 0
2 0 0
3 0 0
5/2 1 0
0 1 2
3 4 5
9 10 11
12 13 14
6 7 8
)";
IMeshBuilder mb(spec);
IMesh out = trimesh_self_intersect(mb.imesh, &mb.arena);
out.populate_vert();
EXPECT_EQ(out.vert_size(), 16);
EXPECT_EQ(out.face_size(), 18);
if (DO_OBJ) {
write_obj_mesh(out, "overlapcluster");
}
}
TEST(mesh_intersect, TriCornerCross1)
{
/* A corner formed by 3 tris, and a 4th crossing two of them. */
const char *spec = R"(12 4
0 0 0
1 0 0
0 0 1
0 0 0
0 1 0
0 0 1
0 0 0
1 0 0
0 1 0
1 1 1/2
1 -2 1/2
-2 1 1/2
0 1 2
3 4 5
6 7 8
9 10 11
)";
IMeshBuilder mb(spec);
IMesh out = trimesh_self_intersect(mb.imesh, &mb.arena);
out.populate_vert();
EXPECT_EQ(out.vert_size(), 10);
EXPECT_EQ(out.face_size(), 14);
if (DO_OBJ) {
write_obj_mesh(out, "test_tc_1");
}
}
TEST(mesh_intersect, TriCornerCross2)
{
/* A corner formed by 3 tris, and a 4th coplanar with base. */
const char *spec = R"(12 4
0 0 0
1 0 0
0 0 1
0 0 0
0 1 0
0 0 1
0 0 0
1 0 0
0 1 0
1 1 0
1 -2 0
-2 1 0
0 1 2
3 4 5
6 7 8
9 10 11
)";
IMeshBuilder mb(spec);
IMesh out = trimesh_self_intersect(mb.imesh, &mb.arena);
out.populate_vert();
EXPECT_EQ(out.vert_size(), 7);
EXPECT_EQ(out.face_size(), 8);
if (DO_OBJ) {
write_obj_mesh(out, "test_tc_2");
}
}
TEST(mesh_intersect, TriCornerCross3)
{
/* A corner formed by 3 tris, and a 4th crossing all 3. */
const char *spec = R"(12 4
0 0 0
1 0 0
0 0 1
0 0 0
0 1 0
0 0 1
0 0 0
1 0 0
0 1 0
3/2 -1/2 -1/4
-1/2 3/2 -1/4
-1/2 -1/2 3/4
0 1 2
3 4 5
6 7 8
9 10 11
)";
IMeshBuilder mb(spec);
IMesh out = trimesh_self_intersect(mb.imesh, &mb.arena);
out.populate_vert();
EXPECT_EQ(out.vert_size(), 10);
EXPECT_EQ(out.face_size(), 16);
if (DO_OBJ) {
write_obj_mesh(out, "test_tc_3");
}
}
TEST(mesh_intersect, TetTet)
{
const char *spec = R"(8 8
0 0 0
2 0 0
1 2 0
1 1 2
0 0 1
2 0 1
1 2 1
1 1 3
0 1 2
0 3 1
1 3 2
2 3 0
4 5 6
4 7 5
5 7 6
6 7 4
)";
IMeshBuilder mb(spec);
IMesh out = trimesh_self_intersect(mb.imesh, &mb.arena);
out.populate_vert();
EXPECT_EQ(out.vert_size(), 11);
EXPECT_EQ(out.face_size(), 20);
/* Expect there to be a triangle with these three verts, oriented this way, with original face 1.
*/
const Vert *v1 = mb.arena.find_vert(mpq3(2, 0, 0));
const Vert *v8 = mb.arena.find_vert(mpq3(0.5, 0.5, 1));
const Vert *v9 = mb.arena.find_vert(mpq3(1.5, 0.5, 1));
Speedups for new boolean. Better hash function for verts. The existing hash function didn't work well with Set's method of masking to the lower bits, because many verts have zeros in the lower bits. Also, replaced VectorSet with Set for Vert deduping.
2020-11-23 19:30:40 -05:00
EXPECT_TRUE(v1 && v8 && v9);
if (v1 && v8 && v9) {
const Face *f = mb.arena.find_face({v1, v8, v9});
EXPECT_NE(f, nullptr);
if (f != nullptr) {
EXPECT_EQ(f->orig, 1);
int v1pos = f->vert[0] == v1 ? 0 : (f->vert[1] == v1 ? 1 : 2);
EXPECT_EQ(f->edge_orig[v1pos], NO_INDEX);
EXPECT_EQ(f->edge_orig[(v1pos + 1) % 3], NO_INDEX);
EXPECT_EQ(f->edge_orig[(v1pos + 2) % 3], 1001);
EXPECT_EQ(f->is_intersect[v1pos], false);
EXPECT_EQ(f->is_intersect[(v1pos + 1) % 3], true);
EXPECT_EQ(f->is_intersect[(v1pos + 2) % 3], false);
}
}
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
if (DO_OBJ) {
write_obj_mesh(out, "test_tc_3");
}
}
TEST(mesh_intersect, CubeCubeStep)
{
const char *spec = R"(16 24
0 -1 0
0 -1 2
0 1 0
0 1 2
2 -1 0
2 -1 2
2 1 0
2 1 2
-1 -1 -1
-1 -1 1
-1 1 -1
-1 1 1
1 -1 -1
1 -1 1
1 1 -1
1 1 1
0 1 3
0 3 2
2 3 7
2 7 6
6 7 5
6 5 4
4 5 1
4 1 0
2 6 4
2 4 0
7 3 1
7 1 5
8 9 11
8 11 10
10 11 15
10 15 14
14 15 13
14 13 12
12 13 9
12 9 8
10 14 12
10 12 8
15 11 9
15 9 13
)";
IMeshBuilder mb(spec);
IMesh out = trimesh_self_intersect(mb.imesh, &mb.arena);
out.populate_vert();
EXPECT_EQ(out.vert_size(), 22);
EXPECT_EQ(out.face_size(), 56);
if (DO_OBJ) {
write_obj_mesh(out, "test_cubecubestep");
}
IMeshBuilder mb2(spec);
IMesh out2 = trimesh_nary_intersect(
mb2.imesh, 2, [](int t) { return t < 12 ? 0 : 1; }, false, &mb2.arena);
out2.populate_vert();
EXPECT_EQ(out2.vert_size(), 22);
EXPECT_EQ(out2.face_size(), 56);
if (DO_OBJ) {
write_obj_mesh(out2, "test_cubecubestep_nary");
}
}
New boolean: Fix second example in T79404. The code to detect non-trivial coplanar intersection sometimes falsely said there wasn't one. This caused some coplanar intersections to be missed. Also added a test for this case.
2020-09-04 20:59:36 -04:00
TEST(mesh_intersect, RectCross)
{
const char *spec = R"(8 4
3/2 0 1
-3/2 0 1
-3/2 0 -1
3/2 0 -1
1 0 -5
-1 0 -5
1 0 5
-1 0 5
1 0 3
1 3 2
5 4 6
5 6 7
)";
IMeshBuilder mb(spec);
IMesh out = trimesh_self_intersect(mb.imesh, &mb.arena);
out.populate_vert();
EXPECT_EQ(out.vert_size(), 17);
EXPECT_EQ(out.face_size(), 28);
if (DO_OBJ) {
write_obj_mesh(out, "test_rectcross");
}
}
Cleanup: clang-format
2020-08-28 10:04:26 -06:00
# endif
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
Cleanup: clang-format
2020-08-28 10:04:26 -06:00
# if DO_PERF_TESTS
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
static void get_sphere_params(
int nrings, int nsegs, bool triangulate, int *r_num_verts, int *r_num_faces)
{
*r_num_verts = nsegs * (nrings - 1) + 2;
if (triangulate) {
*r_num_faces = 2 * nsegs + 2 * nsegs * (nrings - 2);
}
else {
*r_num_faces = nsegs * nrings;
}
}
static void fill_sphere_data(int nrings,
int nsegs,
const double3 &center,
double radius,
bool triangulate,
MutableSpan<Face *> face,
int vid_start,
int fid_start,
IMeshArena *arena)
{
int num_verts;
int num_faces;
get_sphere_params(nrings, nsegs, triangulate, &num_verts, &num_faces);
BLI_assert(num_faces == face.size());
Array<const Vert *> vert(num_verts);
const bool nrings_even = (nrings % 2 == 0);
int half_nrings = nrings / 2;
const bool nsegs_even = (nsegs % 2) == 0;
const bool nsegs_four_divisible = (nsegs % 4 == 0);
int half_nsegs = nrings;
int quarter_nsegs = half_nsegs / 2;
double delta_phi = 2 * M_PI / nsegs;
double delta_theta = M_PI / nrings;
int fid = fid_start;
int vid = vid_start;
auto vert_index_fn = [nrings, num_verts](int seg, int ring) {
if (ring == 0) { /* Top vert. */
return num_verts - 2;
}
if (ring == nrings) { /* Bottom vert. */
return num_verts - 1;
}
return seg * (nrings - 1) + (ring - 1);
};
auto face_index_fn = [nrings](int seg, int ring) { return seg * nrings + ring; };
auto tri_index_fn = [nrings, nsegs](int seg, int ring, int tri) {
if (ring == 0) {
return seg;
}
if (ring < nrings - 1) {
return nsegs + 2 * (ring - 1) * nsegs + 2 * seg + tri;
}
return nsegs + 2 * (nrings - 2) * nsegs + seg;
};
Array<int> eid = {0, 0, 0, 0}; /* Don't care about edge ids. */
/*
Cleanup: code comments punctuation / spacing
2021-07-23 16:56:00 +10:00
* (x, y, z) is given from inclination theta and azimuth phi,
* where: `0 <= theta <= pi; 0 <= phi <= 2pi`.
* `x = radius * sin(theta) cos(phi)`
* `y = radius * sin(theta) sin(phi)`
* `z = radius * cos(theta)`
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
*/
for (int s = 0; s < nsegs; ++s) {
double phi = s * delta_phi;
double sin_phi;
double cos_phi;
/* Avoid use of trig functions for pi/2 divisible angles. */
if (s == 0) {
/* phi = 0. */
sin_phi = 0.0;
cos_phi = 1.0;
}
else if (nsegs_even && s == half_nsegs) {
/* phi = pi. */
sin_phi = 0.0;
cos_phi = -1.0;
}
else if (nsegs_four_divisible && s == quarter_nsegs) {
/* phi = pi/2. */
sin_phi = 1.0;
cos_phi = 0.0;
}
else if (nsegs_four_divisible && s == 3 * quarter_nsegs) {
/* phi = 3pi/2. */
sin_phi = -1.0;
cos_phi = 0.0;
}
else {
sin_phi = sin(phi);
cos_phi = cos(phi);
}
for (int r = 1; r < nrings; ++r) {
double theta = r * delta_theta;
double r_sin_theta;
double r_cos_theta;
if (nrings_even && r == half_nrings) {
/* theta = pi/2. */
r_sin_theta = radius;
r_cos_theta = 0.0;
}
else {
r_sin_theta = radius * sin(theta);
r_cos_theta = radius * cos(theta);
}
double x = r_sin_theta * cos_phi + center[0];
double y = r_sin_theta * sin_phi + center[1];
double z = r_cos_theta + center[2];
const Vert *v = arena->add_or_find_vert(mpq3(x, y, z), vid++);
vert[vert_index_fn(s, r)] = v;
}
}
const Vert *vtop = arena->add_or_find_vert(mpq3(center[0], center[1], center[2] + radius),
vid++);
const Vert *vbot = arena->add_or_find_vert(mpq3(center[0], center[1], center[2] - radius),
vid++);
vert[vert_index_fn(0, 0)] = vtop;
vert[vert_index_fn(0, nrings)] = vbot;
for (int s = 0; s < nsegs; ++s) {
int snext = (s + 1) % nsegs;
for (int r = 0; r < nrings; ++r) {
int rnext = r + 1;
int i0 = vert_index_fn(s, r);
int i1 = vert_index_fn(s, rnext);
int i2 = vert_index_fn(snext, rnext);
int i3 = vert_index_fn(snext, r);
Face *f;
Face *f2 = nullptr;
if (r == 0) {
f = arena->add_face({vert[i0], vert[i1], vert[i2]}, fid++, eid);
}
else if (r == nrings - 1) {
f = arena->add_face({vert[i0], vert[i1], vert[i3]}, fid++, eid);
}
else {
if (triangulate) {
f = arena->add_face({vert[i0], vert[i1], vert[i2]}, fid++, eid);
f2 = arena->add_face({vert[i2], vert[i3], vert[i0]}, fid++, eid);
}
else {
f = arena->add_face({vert[i0], vert[i1], vert[i2], vert[i3]}, fid++, eid);
}
}
if (triangulate) {
int f_index = tri_index_fn(s, r, 0);
face[f_index] = f;
if (r != 0 && r != nrings - 1) {
int f_index2 = tri_index_fn(s, r, 1);
face[f_index2] = f2;
}
}
else {
int f_index = face_index_fn(s, r);
face[f_index] = f;
}
}
}
}
static void spheresphere_test(int nrings, double y_offset, bool use_self)
{
Cleanup: spelling in comments
2021-09-23 22:06:49 +10:00
/* Make two UV-spheres with nrings rings ad 2*nrings segments. */
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
if (nrings < 2) {
return;
}
BLI_task_scheduler_init(); /* Without this, no parallelism. */
double time_start = PIL_check_seconds_timer();
IMeshArena arena;
int nsegs = 2 * nrings;
int num_sphere_verts;
int num_sphere_tris;
get_sphere_params(nrings, nsegs, true, &num_sphere_verts, &num_sphere_tris);
Array<Face *> tris(2 * num_sphere_tris);
Speedups for new boolean. Better hash function for verts. The existing hash function didn't work well with Set's method of masking to the lower bits, because many verts have zeros in the lower bits. Also, replaced VectorSet with Set for Vert deduping.
2020-11-23 19:30:40 -05:00
arena.reserve(6 * num_sphere_verts / 2, 8 * num_sphere_tris);
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
double3 center1(0.0, 0.0, 0.0);
fill_sphere_data(nrings,
nsegs,
center1,
1.0,
true,
MutableSpan<Face *>(tris.begin(), num_sphere_tris),
0,
0,
&arena);
double3 center2(0.0, y_offset, 0.0);
fill_sphere_data(nrings,
nsegs,
center2,
1.0,
true,
MutableSpan<Face *>(tris.begin() + num_sphere_tris, num_sphere_tris),
num_sphere_verts,
num_sphere_verts,
&arena);
IMesh mesh(tris);
double time_create = PIL_check_seconds_timer();
// write_obj_mesh(mesh, "spheresphere_in");
IMesh out;
if (use_self) {
out = trimesh_self_intersect(mesh, &arena);
}
else {
int nf = num_sphere_tris;
out = trimesh_nary_intersect(
mesh, 2, [nf](int t) { return t < nf ? 0 : 1; }, false, &arena);
}
double time_intersect = PIL_check_seconds_timer();
std::cout << "Create time: " << time_create - time_start << "\n";
std::cout << "Intersect time: " << time_intersect - time_create << "\n";
std::cout << "Total time: " << time_intersect - time_start << "\n";
if (DO_OBJ) {
write_obj_mesh(out, "spheresphere");
}
BLI_task_scheduler_exit();
}
static void get_grid_params(
int x_subdiv, int y_subdiv, bool triangulate, int *r_num_verts, int *r_num_faces)
{
*r_num_verts = x_subdiv * y_subdiv;
if (triangulate) {
*r_num_faces = 2 * (x_subdiv - 1) * (y_subdiv - 1);
}
else {
*r_num_faces = (x_subdiv - 1) * (y_subdiv - 1);
}
}
static void fill_grid_data(int x_subdiv,
int y_subdiv,
bool triangulate,
double size,
const double3 &center,
Fix T82301, exact boolean fail on cube with bump. The code for determining coplanar clusters had a bug where it would miss some triangles. The fix for now is to just put triangles in the cluster if their bounding boxes overlap. This works but maybe makes clusters bigger then they have to be. I'll follow this commit with work on making the CDT routine faster when using exact arithmetic. Also removed a lot of unused code, and added some new intersect performance tests.
2020-11-07 09:02:58 -05:00
double rot_deg,
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
MutableSpan<Face *> face,
int vid_start,
int fid_start,
IMeshArena *arena)
{
if (x_subdiv <= 1 || y_subdiv <= 1) {
return;
}
int num_verts;
int num_faces;
get_grid_params(x_subdiv, y_subdiv, triangulate, &num_verts, &num_faces);
BLI_assert(face.size() == num_faces);
Array<const Vert *> vert(num_verts);
auto vert_index_fn = [x_subdiv](int ix, int iy) { return iy * x_subdiv + ix; };
auto face_index_fn = [x_subdiv](int ix, int iy) { return iy * (x_subdiv - 1) + ix; };
auto tri_index_fn = [x_subdiv](int ix, int iy, int tri) {
return 2 * iy * (x_subdiv - 1) + 2 * ix + tri;
};
Array<int> eid = {0, 0, 0, 0}; /* Don't care about edge ids. */
double r = size / 2.0;
double delta_x = size / (x_subdiv - 1);
double delta_y = size / (y_subdiv - 1);
int vid = vid_start;
Fix T82301, exact boolean fail on cube with bump. The code for determining coplanar clusters had a bug where it would miss some triangles. The fix for now is to just put triangles in the cluster if their bounding boxes overlap. This works but maybe makes clusters bigger then they have to be. I'll follow this commit with work on making the CDT routine faster when using exact arithmetic. Also removed a lot of unused code, and added some new intersect performance tests.
2020-11-07 09:02:58 -05:00
double cos_rot = cosf(rot_deg * M_PI / 180.0);
double sin_rot = sinf(rot_deg * M_PI / 180.0);
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
for (int iy = 0; iy < y_subdiv; ++iy) {
Fix T82301, exact boolean fail on cube with bump. The code for determining coplanar clusters had a bug where it would miss some triangles. The fix for now is to just put triangles in the cluster if their bounding boxes overlap. This works but maybe makes clusters bigger then they have to be. I'll follow this commit with work on making the CDT routine faster when using exact arithmetic. Also removed a lot of unused code, and added some new intersect performance tests.
2020-11-07 09:02:58 -05:00
double yy = iy * delta_y - r;
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
for (int ix = 0; ix < x_subdiv; ++ix) {
Fix T82301, exact boolean fail on cube with bump. The code for determining coplanar clusters had a bug where it would miss some triangles. The fix for now is to just put triangles in the cluster if their bounding boxes overlap. This works but maybe makes clusters bigger then they have to be. I'll follow this commit with work on making the CDT routine faster when using exact arithmetic. Also removed a lot of unused code, and added some new intersect performance tests.
2020-11-07 09:02:58 -05:00
double xx = ix * delta_x - r;
double x = center[0] + xx;
double y = center[1] + yy;
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
double z = center[2];
Fix T82301, exact boolean fail on cube with bump. The code for determining coplanar clusters had a bug where it would miss some triangles. The fix for now is to just put triangles in the cluster if their bounding boxes overlap. This works but maybe makes clusters bigger then they have to be. I'll follow this commit with work on making the CDT routine faster when using exact arithmetic. Also removed a lot of unused code, and added some new intersect performance tests.
2020-11-07 09:02:58 -05:00
if (rot_deg != 0.0) {
x = center[0] + xx * cos_rot - yy * sin_rot;
y = center[1] + xx * sin_rot + yy * cos_rot;
}
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
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const Vert *v = arena->add_or_find_vert(mpq3(x, y, z), vid++);
vert[vert_index_fn(ix, iy)] = v;
}
}
int fid = fid_start;
for (int iy = 0; iy < y_subdiv - 1; ++iy) {
for (int ix = 0; ix < x_subdiv - 1; ++ix) {
int i0 = vert_index_fn(ix, iy);
int i1 = vert_index_fn(ix, iy + 1);
int i2 = vert_index_fn(ix + 1, iy + 1);
int i3 = vert_index_fn(ix + 1, iy);
if (triangulate) {
Face *f = arena->add_face({vert[i0], vert[i1], vert[i2]}, fid++, eid);
Face *f2 = arena->add_face({vert[i2], vert[i3], vert[i0]}, fid++, eid);
face[tri_index_fn(ix, iy, 0)] = f;
face[tri_index_fn(ix, iy, 1)] = f2;
}
else {
Face *f = arena->add_face({vert[i0], vert[i1], vert[i2], vert[i3]}, fid++, eid);
face[face_index_fn(ix, iy)] = f;
}
}
}
}
static void spheregrid_test(int nrings, int grid_level, double z_offset, bool use_self)
{
Cleanup: spelling
2020-09-02 09:58:26 +10:00
/* Make a uv-sphere and a grid.
* The sphere is radius 1, has `nrings` rings and `2 * nrings` segments,
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
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* and is centered at (0,0,z_offset).
Cleanup: spelling
2020-09-02 09:58:26 +10:00
* The plane is 4x4, has `2 ** grid_level` subdivisions x and y,
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
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* and is centered at the origin. */
if (nrings < 2 || grid_level < 1) {
return;
}
BLI_task_scheduler_init(); /* Without this, no parallelism. */
double time_start = PIL_check_seconds_timer();
IMeshArena arena;
int num_sphere_verts;
int num_sphere_tris;
int nsegs = 2 * nrings;
int num_grid_verts;
int num_grid_tris;
int subdivs = 1 << grid_level;
get_sphere_params(nrings, nsegs, true, &num_sphere_verts, &num_sphere_tris);
get_grid_params(subdivs, subdivs, true, &num_grid_verts, &num_grid_tris);
Array<Face *> tris(num_sphere_tris + num_grid_tris);
Speedups for new boolean. Better hash function for verts. The existing hash function didn't work well with Set's method of masking to the lower bits, because many verts have zeros in the lower bits. Also, replaced VectorSet with Set for Vert deduping.
2020-11-23 19:30:40 -05:00
arena.reserve(3 * (num_sphere_verts + num_grid_verts) / 2,
4 * (num_sphere_tris + num_grid_tris));
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
double3 center(0.0, 0.0, z_offset);
fill_sphere_data(nrings,
nsegs,
center,
1.0,
true,
MutableSpan<Face *>(tris.begin(), num_sphere_tris),
0,
0,
&arena);
fill_grid_data(subdivs,
subdivs,
true,
4.0,
double3(0, 0, 0),
Fix T82301, exact boolean fail on cube with bump. The code for determining coplanar clusters had a bug where it would miss some triangles. The fix for now is to just put triangles in the cluster if their bounding boxes overlap. This works but maybe makes clusters bigger then they have to be. I'll follow this commit with work on making the CDT routine faster when using exact arithmetic. Also removed a lot of unused code, and added some new intersect performance tests.
2020-11-07 09:02:58 -05:00
0.0,
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
MutableSpan<Face *>(tris.begin() + num_sphere_tris, num_grid_tris),
num_sphere_verts,
num_sphere_tris,
&arena);
IMesh mesh(tris);
double time_create = PIL_check_seconds_timer();
// write_obj_mesh(mesh, "spheregrid_in");
IMesh out;
if (use_self) {
out = trimesh_self_intersect(mesh, &arena);
}
else {
int nf = num_sphere_tris;
out = trimesh_nary_intersect(
mesh, 2, [nf](int t) { return t < nf ? 0 : 1; }, false, &arena);
}
double time_intersect = PIL_check_seconds_timer();
std::cout << "Create time: " << time_create - time_start << "\n";
std::cout << "Intersect time: " << time_intersect - time_create << "\n";
std::cout << "Total time: " << time_intersect - time_start << "\n";
if (DO_OBJ) {
write_obj_mesh(out, "spheregrid");
}
BLI_task_scheduler_exit();
}
Fix T82301, exact boolean fail on cube with bump. The code for determining coplanar clusters had a bug where it would miss some triangles. The fix for now is to just put triangles in the cluster if their bounding boxes overlap. This works but maybe makes clusters bigger then they have to be. I'll follow this commit with work on making the CDT routine faster when using exact arithmetic. Also removed a lot of unused code, and added some new intersect performance tests.
2020-11-07 09:02:58 -05:00
static void gridgrid_test(int x_level_1,
int y_level_1,
int x_level_2,
int y_level_2,
double x_off,
double y_off,
double rot_deg,
bool use_self)
{
/* Make two grids, each 4x4, with given subdivision levels in x and y,
* and the second offset from the first by x_off, y_off, and rotated by rot_deg degrees. */
BLI_task_scheduler_init(); /* Without this, no parallelism. */
double time_start = PIL_check_seconds_timer();
IMeshArena arena;
int x_subdivs_1 = 1 << x_level_1;
int y_subdivs_1 = 1 << y_level_1;
int x_subdivs_2 = 1 << x_level_2;
int y_subdivs_2 = 1 << y_level_2;
int num_grid_verts_1;
int num_grid_verts_2;
int num_grid_tris_1;
int num_grid_tris_2;
get_grid_params(x_subdivs_1, y_subdivs_1, true, &num_grid_verts_1, &num_grid_tris_1);
get_grid_params(x_subdivs_2, y_subdivs_2, true, &num_grid_verts_2, &num_grid_tris_2);
Array<Face *> tris(num_grid_tris_1 + num_grid_tris_2);
Speedups for new boolean. Better hash function for verts. The existing hash function didn't work well with Set's method of masking to the lower bits, because many verts have zeros in the lower bits. Also, replaced VectorSet with Set for Vert deduping.
2020-11-23 19:30:40 -05:00
arena.reserve(3 * (num_grid_verts_1 + num_grid_verts_2) / 2,
4 * (num_grid_tris_1 + num_grid_tris_2));
Fix T82301, exact boolean fail on cube with bump. The code for determining coplanar clusters had a bug where it would miss some triangles. The fix for now is to just put triangles in the cluster if their bounding boxes overlap. This works but maybe makes clusters bigger then they have to be. I'll follow this commit with work on making the CDT routine faster when using exact arithmetic. Also removed a lot of unused code, and added some new intersect performance tests.
2020-11-07 09:02:58 -05:00
fill_grid_data(x_subdivs_1,
y_subdivs_1,
true,
4.0,
double3(0, 0, 0),
0.0,
MutableSpan<Face *>(tris.begin(), num_grid_tris_1),
0,
0,
&arena);
fill_grid_data(x_subdivs_2,
y_subdivs_2,
true,
4.0,
double3(x_off, y_off, 0),
rot_deg,
MutableSpan<Face *>(tris.begin() + num_grid_tris_1, num_grid_tris_2),
num_grid_verts_1,
num_grid_tris_1,
&arena);
IMesh mesh(tris);
double time_create = PIL_check_seconds_timer();
// write_obj_mesh(mesh, "gridgrid_in");
IMesh out;
if (use_self) {
out = trimesh_self_intersect(mesh, &arena);
}
else {
int nf = num_grid_tris_1;
out = trimesh_nary_intersect(
mesh, 2, [nf](int t) { return t < nf ? 0 : 1; }, false, &arena);
}
double time_intersect = PIL_check_seconds_timer();
std::cout << "Create time: " << time_create - time_start << "\n";
std::cout << "Intersect time: " << time_intersect - time_create << "\n";
std::cout << "Total time: " << time_intersect - time_start << "\n";
if (DO_OBJ) {
write_obj_mesh(out, "gridgrid");
}
BLI_task_scheduler_exit();
}
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
TEST(mesh_intersect_perf, SphereSphere)
{
New Boolean: performance improvement. Avoided cost of searching for coplanar clusters in many cases.
2020-08-29 17:48:01 -04:00
spheresphere_test(512, 0.5, false);
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
}
Fix T82301, exact boolean fail on cube with bump. The code for determining coplanar clusters had a bug where it would miss some triangles. The fix for now is to just put triangles in the cluster if their bounding boxes overlap. This works but maybe makes clusters bigger then they have to be. I'll follow this commit with work on making the CDT routine faster when using exact arithmetic. Also removed a lot of unused code, and added some new intersect performance tests.
2020-11-07 09:02:58 -05:00
TEST(mesh_intersect_perf, SphereSphereSelf)
{
spheresphere_test(64, 0.5, true);
}
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
TEST(mesh_intersect_perf, SphereGrid)
{
New Boolean: performance improvement. Avoided cost of searching for coplanar clusters in many cases.
2020-08-29 17:48:01 -04:00
spheregrid_test(512, 4, 0.1, false);
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
}
Fix T82301, exact boolean fail on cube with bump. The code for determining coplanar clusters had a bug where it would miss some triangles. The fix for now is to just put triangles in the cluster if their bounding boxes overlap. This works but maybe makes clusters bigger then they have to be. I'll follow this commit with work on making the CDT routine faster when using exact arithmetic. Also removed a lot of unused code, and added some new intersect performance tests.
2020-11-07 09:02:58 -05:00
TEST(mesh_intersect_perf, SphereGridSelf)
{
spheregrid_test(64, 4, 0.1, true);
}
TEST(mesh_intersect_perf, GridGrid)
{
gridgrid_test(8, 2, 4, 2, 0.1, 0.1, 0.0, false);
}
TEST(mesh_intersect_perf, GridGridTilt)
{
gridgrid_test(8, 2, 4, 2, 0.0, 0.0, 1.0, false);
}
Cleanup: clang-format
2020-08-28 10:04:26 -06:00
# endif
Merge newboolean branch into master. This is for design task T67744, Boolean Redesign. It adds a choice of solver to the Boolean modifier and the Intersect (Boolean) and Intersect (Knife) tools. The 'Fast' choice is the current Bmesh boolean. The new 'Exact' choice is a more advanced algorithm that supports overlapping geometry and uses more robust calculations, but is slower than the Fast choice. The default with this commit is set to 'Exact'. We can decide before the 2.91 release whether or not this is the right choice, but this choice now will get us more testing and feedback on the new code.
2020-08-28 10:56:44 -04:00
} // namespace blender::meshintersect::tests
Fix to previous commit to allow building without WITH_GMP.
2020-08-28 11:43:56 -04:00
#endif
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