#include "link.h" #include #include #include #include #include Link::Link(End a, End b, float l) : ends {{std::move(a), std::move(b)}}, length {l} { } LinkCurve::LinkCurve(GlobalPosition3D c, RelativeDistance r, Arc a) : centreBase {c}, radius {r}, arc {std::move(a)} { } bool operator<(const GlobalPosition3D & a, const GlobalPosition3D & b) { // NOLINTNEXTLINE(hicpp-use-nullptr,modernize-use-nullptr) return std::tie(a.x, a.y, a.z) < std::tie(b.x, b.y, b.z); } bool operator<(const Node & a, const Node & b) { return a.pos < b.pos; } Location LinkStraight::positionAt(RelativeDistance dist, unsigned char start) const { const auto es {std::make_pair(ends[start].node.get(), ends[1 - start].node.get())}; const RelativePosition3D diff {es.second->pos - es.first->pos}; const auto dir {glm::normalize(diff)}; return Location {es.first->pos + (vehiclePositionOffset() + dir * dist), {vector_pitch(dir), vector_yaw(dir), 0}}; } bool LinkStraight::intersectRay(const Ray & ray) const { return ray.passesCloseToEdges( std::array {GlobalPosition3D {ends.front().node->pos}, GlobalPosition3D {ends.back().node->pos}}, 1000); } Location LinkCurve::positionAt(float dist, unsigned char start) const { static constexpr std::array dirOffset {half_pi, -half_pi}; const auto frac {dist / length}; const auto es {std::make_pair(ends[start].node.get(), ends[1 - start].node.get())}; const auto as {std::make_pair(arc[start], arc[1 - start])}; const auto ang {as.first + ((as.second - as.first) * frac)}; const auto relPos {(sincos(ang) || 0.F) * radius}; const auto relClimb {vehiclePositionOffset() + RelativePosition3D {0, 0, static_cast(es.first->pos.z - centreBase.z) + (static_cast(es.second->pos.z - es.first->pos.z) * frac)}}; const auto pitch {vector_pitch(difference(es.second->pos, es.first->pos) / length)}; return Location {GlobalPosition3D(relPos + relClimb) + centreBase, {pitch, normalize(ang + dirOffset[start]), 0}}; } bool LinkCurve::intersectRay(const Ray & ray) const { const auto & e0p {ends[0].node->pos}; const auto & e1p {ends[1].node->pos}; const auto slength = round_frac(length / 2.F, 5.F); const auto segs = std::round(15.F * slength / std::pow(radius, 0.7F)); const auto step {glm::vec<2, RelativeDistance> {arc.length(), e1p.z - e0p.z} / segs}; auto segCount = static_cast(std::lround(segs)) + 1; std::vector points; points.reserve(segCount); for (std::remove_const_t swing = {arc.first, centreBase.z - e0p.z}; segCount; swing += step, --segCount) { points.emplace_back(centreBase + ((sincos(swing.x) * radius) || swing.y)); } return ray.passesCloseToEdges(points, 1.F); }