378 lines
12 KiB
C++
378 lines
12 KiB
C++
#include <catch2/catch.hpp>
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#include <test_utils.hpp>
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#include <unordered_set>
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#include "libslic3r/Execution/ExecutionSeq.hpp"
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#include "libslic3r/SLA/SupportTreeUtils.hpp"
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#include "libslic3r/SLA/SupportTreeUtilsLegacy.hpp"
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// Test pair hash for 'nums' random number pairs.
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template <class I, class II> void test_pairhash()
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{
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const constexpr size_t nums = 1000;
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I A[nums] = {0}, B[nums] = {0};
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std::unordered_set<I> CH;
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std::unordered_map<II, std::pair<I, I>> ints;
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std::random_device rd;
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std::mt19937 gen(rd());
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const I Ibits = int(sizeof(I) * CHAR_BIT);
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const II IIbits = int(sizeof(II) * CHAR_BIT);
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int bits = IIbits / 2 < Ibits ? Ibits / 2 : Ibits;
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if (std::is_signed<I>::value) bits -= 1;
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const I Imin = 0;
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const I Imax = I(std::pow(2., bits) - 1);
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std::uniform_int_distribution<I> dis(Imin, Imax);
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for (size_t i = 0; i < nums;) {
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I a = dis(gen);
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if (CH.find(a) == CH.end()) { CH.insert(a); A[i] = a; ++i; }
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}
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for (size_t i = 0; i < nums;) {
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I b = dis(gen);
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if (CH.find(b) == CH.end()) { CH.insert(b); B[i] = b; ++i; }
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}
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for (size_t i = 0; i < nums; ++i) {
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I a = A[i], b = B[i];
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REQUIRE(a != b);
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II hash_ab = Slic3r::sla::pairhash<I, II>(a, b);
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II hash_ba = Slic3r::sla::pairhash<I, II>(b, a);
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REQUIRE(hash_ab == hash_ba);
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auto it = ints.find(hash_ab);
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if (it != ints.end()) {
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REQUIRE((
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(it->second.first == a && it->second.second == b) ||
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(it->second.first == b && it->second.second == a)
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));
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} else
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ints[hash_ab] = std::make_pair(a, b);
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}
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}
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TEST_CASE("Pillar pairhash should be unique", "[suptreeutils]") {
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test_pairhash<int, int>();
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test_pairhash<int, long>();
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test_pairhash<unsigned, unsigned>();
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test_pairhash<unsigned, unsigned long>();
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}
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static void eval_ground_conn(const Slic3r::sla::GroundConnection &conn,
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const Slic3r::sla::SupportableMesh &sm,
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const Slic3r::sla::Junction &j,
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double end_r,
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const std::string &stl_fname = "output.stl")
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{
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using namespace Slic3r;
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//#ifndef NDEBUG
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sla::SupportTreeBuilder builder;
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if (!conn)
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builder.add_junction(j);
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sla::build_ground_connection(builder, sm, conn);
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indexed_triangle_set mesh = *sm.emesh.get_triangle_mesh();
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its_merge(mesh, builder.merged_mesh());
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its_write_stl_ascii(stl_fname.c_str(), "stl_fname", mesh);
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//#endif
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REQUIRE(bool(conn));
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// The route should include the source and one avoidance junction.
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REQUIRE(conn.path.size() == 2);
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// Check if the radius increases with each node
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REQUIRE(conn.path.front().r < conn.path.back().r);
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REQUIRE(conn.path.back().r < conn.pillar_base->r_top);
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// The end radius and the pillar base's upper radius should match
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REQUIRE(conn.pillar_base->r_top == Approx(end_r));
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}
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TEST_CASE("Pillar search dumb case", "[suptreeutils]") {
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using namespace Slic3r;
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constexpr double FromR = 0.5;
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auto j = sla::Junction{Vec3d::Zero(), FromR};
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SECTION("with empty mesh") {
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sla::SupportableMesh sm{indexed_triangle_set{},
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sla::SupportPoints{},
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sla::SupportTreeConfig{}};
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constexpr double EndR = 1.;
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sla::GroundConnection conn =
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sla::deepsearch_ground_connection(ex_seq, sm, j, EndR, sla::DOWN);
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REQUIRE(conn);
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// REQUIRE(conn.path.size() == 1);
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REQUIRE(conn.pillar_base->pos.z() == Approx(ground_level(sm)));
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}
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SECTION("with zero R source and destination") {
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sla::SupportableMesh sm{indexed_triangle_set{},
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sla::SupportPoints{},
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sla::SupportTreeConfig{}};
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j.r = 0.;
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constexpr double EndR = 0.;
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sla::GroundConnection conn =
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sla::deepsearch_ground_connection(ex_seq, sm, j, EndR, sla::DOWN);
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REQUIRE(conn);
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// REQUIRE(conn.path.size() == 1);
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REQUIRE(conn.pillar_base->pos.z() == Approx(ground_level(sm)));
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REQUIRE(conn.pillar_base->r_top == Approx(0.));
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}
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SECTION("with zero init direction") {
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sla::SupportableMesh sm{indexed_triangle_set{},
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sla::SupportPoints{},
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sla::SupportTreeConfig{}};
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constexpr double EndR = 1.;
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Vec3d init_dir = Vec3d::Zero();
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sla::GroundConnection conn =
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sla::deepsearch_ground_connection(ex_seq, sm, j, EndR, init_dir);
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REQUIRE(conn);
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// REQUIRE(conn.path.size() == 1);
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REQUIRE(conn.pillar_base->pos.z() == Approx(ground_level(sm)));
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}
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}
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TEST_CASE("Avoid disk below junction", "[suptreeutils]")
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{
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// In this test there will be a disk mesh with some radius, centered at
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// (0, 0, 0) and above the disk, a junction from which the support pillar
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// should be routed. The algorithm needs to find an avoidance route.
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using namespace Slic3r;
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constexpr double FromRadius = .5;
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constexpr double EndRadius = 1.;
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constexpr double CylRadius = 4.;
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constexpr double CylHeight = 1.;
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sla::SupportTreeConfig cfg;
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indexed_triangle_set disk = its_make_cylinder(CylRadius, CylHeight);
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// 2.5 * CyRadius height should be enough to be able to insert a bridge
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// with 45 degree tilt above the disk.
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sla::Junction j{Vec3d{0., 0., 2.5 * CylRadius}, FromRadius};
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sla::SupportableMesh sm{disk, sla::SupportPoints{}, cfg};
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SECTION("with elevation") {
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sla::GroundConnection conn =
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sla::deepsearch_ground_connection(ex_tbb, sm, j, EndRadius, sla::DOWN);
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eval_ground_conn(conn, sm, j, EndRadius, "disk.stl");
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// Check if the avoidance junction is indeed outside of the disk barrier's
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// edge.
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auto p = conn.path.back().pos;
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double pR = std::sqrt(p.x() * p.x()) + std::sqrt(p.y() * p.y());
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REQUIRE(pR + FromRadius > CylRadius);
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}
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SECTION("without elevation") {
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sm.cfg.object_elevation_mm = 0.;
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sla::GroundConnection conn =
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sla::deepsearch_ground_connection(ex_tbb, sm, j, EndRadius, sla::DOWN);
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eval_ground_conn(conn, sm, j, EndRadius, "disk_ze.stl");
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// Check if the avoidance junction is indeed outside of the disk barrier's
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// edge.
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auto p = conn.path.back().pos;
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double pR = std::sqrt(p.x() * p.x()) + std::sqrt(p.y() * p.y());
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REQUIRE(pR + FromRadius > CylRadius);
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}
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}
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TEST_CASE("Avoid disk below junction with barrier on the side", "[suptreeutils]")
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{
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// In this test there will be a disk mesh with some radius, centered at
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// (0, 0, 0) and above the disk, a junction from which the support pillar
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// should be routed. The algorithm needs to find an avoidance route.
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using namespace Slic3r;
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constexpr double FromRadius = .5;
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constexpr double EndRadius = 1.;
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constexpr double CylRadius = 4.;
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constexpr double CylHeight = 1.;
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constexpr double JElevX = 2.5;
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sla::SupportTreeConfig cfg;
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indexed_triangle_set disk = its_make_cylinder(CylRadius, CylHeight);
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indexed_triangle_set wall = its_make_cube(1., 2 * CylRadius, JElevX * CylRadius);
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its_translate(wall, Vec3f{float(FromRadius), -float(CylRadius), 0.f});
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its_merge(disk, wall);
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// 2.5 * CyRadius height should be enough to be able to insert a bridge
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// with 45 degree tilt above the disk.
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sla::Junction j{Vec3d{0., 0., JElevX * CylRadius}, FromRadius};
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sla::SupportableMesh sm{disk, sla::SupportPoints{}, cfg};
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SECTION("with elevation") {
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sla::GroundConnection conn =
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sla::deepsearch_ground_connection(ex_seq, sm, j, EndRadius, sla::DOWN);
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eval_ground_conn(conn, sm, j, EndRadius, "disk_with_barrier.stl");
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// Check if the avoidance junction is indeed outside of the disk barrier's
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// edge.
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auto p = conn.path.back().pos;
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double pR = std::sqrt(p.x() * p.x()) + std::sqrt(p.y() * p.y());
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REQUIRE(pR + FromRadius > CylRadius);
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}
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SECTION("without elevation") {
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sm.cfg.object_elevation_mm = 0.;
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sla::GroundConnection conn =
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sla::deepsearch_ground_connection(ex_seq, sm, j, EndRadius, sla::DOWN);
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eval_ground_conn(conn, sm, j, EndRadius, "disk_with_barrier_ze.stl");
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// Check if the avoidance junction is indeed outside of the disk barrier's
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// edge.
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auto p = conn.path.back().pos;
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double pR = std::sqrt(p.x() * p.x()) + std::sqrt(p.y() * p.y());
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REQUIRE(pR + FromRadius > CylRadius);
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}
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}
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TEST_CASE("Find ground route just above ground", "[suptreeutils]") {
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using namespace Slic3r;
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sla::SupportTreeConfig cfg;
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cfg.object_elevation_mm = 0.;
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sla::Junction j{Vec3d{0., 0., 2. * cfg.head_back_radius_mm}, cfg.head_back_radius_mm};
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sla::SupportableMesh sm{{}, sla::SupportPoints{}, cfg};
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sla::GroundConnection conn =
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sla::deepsearch_ground_connection(ex_seq, sm, j, Geometry::spheric_to_dir(3 * PI/ 4, PI));
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REQUIRE(conn);
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REQUIRE(conn.pillar_base->pos.z() >= Approx(ground_level(sm)));
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}
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TEST_CASE("BranchingSupports::MergePointFinder", "[suptreeutils]") {
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using namespace Slic3r;
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SECTION("Identical points have the same merge point") {
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Vec3f a{0.f, 0.f, 0.f}, b = a;
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auto slope = float(PI / 4.);
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auto mergept = sla::find_merge_pt(a, b, slope);
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REQUIRE(bool(mergept));
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REQUIRE((*mergept - b).norm() < EPSILON);
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REQUIRE((*mergept - a).norm() < EPSILON);
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}
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// ^ Z
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// | a *
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// |
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// | b * <= mergept
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SECTION("Points at different heights have the lower point as mergepoint") {
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Vec3f a{0.f, 0.f, 0.f}, b = {0.f, 0.f, -1.f};
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auto slope = float(PI / 4.);
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auto mergept = sla::find_merge_pt(a, b, slope);
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REQUIRE(bool(mergept));
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REQUIRE((*mergept - b).squaredNorm() < 2 * EPSILON);
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}
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// -|---------> X
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// a b
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// * *
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// * <= mergept
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SECTION("Points at different X have mergept in the middle at lower Z") {
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Vec3f a{0.f, 0.f, 0.f}, b = {1.f, 0.f, 0.f};
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auto slope = float(PI / 4.);
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auto mergept = sla::find_merge_pt(a, b, slope);
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REQUIRE(bool(mergept));
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// Distance of mergept should be equal from both input points
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float D = std::abs((*mergept - b).squaredNorm() - (*mergept - a).squaredNorm());
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REQUIRE(D < EPSILON);
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REQUIRE(!sla::is_outside_support_cone(a, *mergept, slope));
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REQUIRE(!sla::is_outside_support_cone(b, *mergept, slope));
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}
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// -|---------> Y
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// a b
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// * *
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// * <= mergept
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SECTION("Points at different Y have mergept in the middle at lower Z") {
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Vec3f a{0.f, 0.f, 0.f}, b = {0.f, 1.f, 0.f};
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auto slope = float(PI / 4.);
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auto mergept = sla::find_merge_pt(a, b, slope);
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REQUIRE(bool(mergept));
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// Distance of mergept should be equal from both input points
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float D = std::abs((*mergept - b).squaredNorm() - (*mergept - a).squaredNorm());
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REQUIRE(D < EPSILON);
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REQUIRE(!sla::is_outside_support_cone(a, *mergept, slope));
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REQUIRE(!sla::is_outside_support_cone(b, *mergept, slope));
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}
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SECTION("Points separated by less than critical angle have the lower point as mergept") {
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Vec3f a{-1.f, -1.f, -1.f}, b = {-1.5f, -1.5f, -2.f};
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auto slope = float(PI / 4.);
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auto mergept = sla::find_merge_pt(a, b, slope);
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REQUIRE(bool(mergept));
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REQUIRE((*mergept - b).norm() < 2 * EPSILON);
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}
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// -|----------------------------> Y
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// a b
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// * * <= mergept *
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//
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SECTION("Points at same height have mergepoint in the middle if critical angle is zero ") {
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Vec3f a{-1.f, -1.f, -1.f}, b = {-1.5f, -1.5f, -1.f};
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auto slope = EPSILON;
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auto mergept = sla::find_merge_pt(a, b, slope);
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REQUIRE(bool(mergept));
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Vec3f middle = (b + a) / 2.;
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REQUIRE((*mergept - middle).norm() < 4 * EPSILON);
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}
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}
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