dust3d/thirdparty/carve-1.4.0/include/carve/polyhedron_impl.hpp

// Begin License:
// Copyright (C) 2006-2008 Tobias Sargeant (tobias.sargeant@gmail.com).
// All rights reserved.
//
// This file is part of the Carve CSG Library (http://carve-csg.com/)
//
// This file may be used under the terms of the GNU General Public
// License version 2.0 as published by the Free Software Foundation
// and appearing in the file LICENSE.GPL2 included in the packaging of
// this file.
//
// This file is provided "AS IS" with NO WARRANTY OF ANY KIND,
// INCLUDING THE WARRANTIES OF DESIGN, MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE.
// End:


#pragma once

#include <carve/timing.hpp>

#include <assert.h>
#include <list>

namespace carve {
  namespace poly {


    template<typename order_t>
    struct VPtrSort {
      order_t &order;

      VPtrSort(order_t &_order) : order(_order) {}
      bool operator()(carve::poly::Polyhedron::vertex_t const *a,
                      carve::poly::Polyhedron::vertex_t const *b) const {
        return order(a->v, b->v);
      }
    };

    template<typename order_t>
    bool Geometry<3>::orderVertices(order_t order) {
      static carve::TimingName FUNC_NAME("Geometry<3>::orderVertices()");
      carve::TimingBlock block(FUNC_NAME);

      std::vector<vertex_t *> vptr;
      std::vector<vertex_t *> vmap;
      std::vector<vertex_t> vout;
      const size_t N = vertices.size();

      vptr.reserve(N);
      vout.reserve(N);
      vmap.resize(N);

      for (size_t i = 0; i != N; ++i) {
        vptr.push_back(&vertices[i]);
      }
      std::sort(vptr.begin(), vptr.end(), VPtrSort<order_t>(order));

      for (size_t i = 0; i != N; ++i) {
        vout.push_back(*vptr[i]);
        vmap[vertexToIndex_fast(vptr[i])] = &vout[i];
      }

      for (size_t i = 0; i < faces.size(); ++i) {
        face_t &f = faces[i];
        for (size_t j = 0; j < f.nVertices(); ++j) {
          f.vertex(j) = vmap[vertexToIndex_fast(f.vertex(j))];
        }
      }
      for (size_t i = 0; i < edges.size(); ++i) {
        edges[i].v1 = vmap[vertexToIndex_fast(edges[i].v1)];
        edges[i].v2 = vmap[vertexToIndex_fast(edges[i].v2)];
      }

      vout.swap(vertices);

      return true;
    }


    template<typename T>
    int Geometry<3>::_faceNeighbourhood(const face_t *f, int depth, T *result) const {
      if (depth < 0 || f->is_tagged()) return 0;

      f->tag();
      *(*result)++ = f;

      int r = 1;
      for (size_t i = 0; i < f->edges.size(); ++i) {
        const std::vector<const face_t *> &edge_faces = connectivity.edge_to_face[edgeToIndex_fast(f->edges[i])];
        const face_t *f2 = connectedFace(f, f->edges[i]);
        if (f2) {
          r += _faceNeighbourhood(f2, depth - 1, (*result));
        }
      }
      return r;
    }


    template<typename T>
    int Geometry<3>::faceNeighbourhood(const face_t *f, int depth, T result) const {
      tagable::tag_begin();

      return _faceNeighbourhood(f, depth, &result);
    }


    template<typename T>
    int Geometry<3>::faceNeighbourhood(const edge_t *e, int m_id, int depth, T result) const {
      tagable::tag_begin();

      int r = 0;
      const std::vector<const face_t *> &edge_faces = connectivity.edge_to_face[edgeToIndex_fast(e)];
      for (size_t i = 0; i < edge_faces.size(); ++i) {
        const face_t *f = edge_faces[i];
        if (f && f->manifold_id == m_id) { r += _faceNeighbourhood(f, depth, &result); }
      }
      return r;
    }


    template<typename T>
    int Geometry<3>::faceNeighbourhood(const vertex_t *v, int m_id, int depth, T result) const {
      tagable::tag_begin();

      int r = 0;
      const std::vector<const face_t *> &vertex_faces = connectivity.vertex_to_face[vertexToIndex_fast(v)];
      for (size_t i = 0; i < vertex_faces.size(); ++i) {
        const face_t *f = vertex_faces[i];
        if (f && f->manifold_id == m_id) { r += _faceNeighbourhood(f, depth, &result); }
      }
      return r;
    }


    // accessing connectivity information.
    template<typename T>
    int Geometry<3>::vertexToEdges(const vertex_t *v, T result) const {
      const std::vector<const edge_t *> &e = connectivity.vertex_to_edge[vertexToIndex_fast(v)];
      std::copy(e.begin(), e.end(), result);
      return e.size();
    }


    template<typename T>
    int Geometry<3>::vertexToFaces(const vertex_t *v, T result) const {
      const std::vector<const face_t *> &vertex_faces = connectivity.vertex_to_face[vertexToIndex_fast(v)];
      int c = 0;
      for (size_t i = 0; i < vertex_faces.size(); ++i) {
        *result++ = vertex_faces[i]; ++c;
      }
      return c;
    }


    template<typename T>
    int Geometry<3>::edgeToFaces(const edge_t *e, T result) const {
      const std::vector<const face_t *> &edge_faces = connectivity.edge_to_face[edgeToIndex_fast(e)];
      int c = 0;
      for (size_t i = 0; i < edge_faces.size(); ++i) {
        if (edge_faces[i] != NULL) { *result++ = edge_faces[i]; ++c; }
      }
      return c;
    }


    inline const Geometry<3>::face_t *Geometry<3>::connectedFace(const face_t *f, const edge_t *e) const {
      const std::vector<const face_t *> &edge_faces = connectivity.edge_to_face[edgeToIndex_fast(e)];
      for (size_t i = 0; i < (edge_faces.size() & ~1U); i++) {
        if (edge_faces[i] == f) return edge_faces[i^1];
      }
      return NULL;
    }


    inline void Polyhedron::invert(int m_id) {
      std::vector<bool> selected_manifolds(manifold_is_closed.size(), false);
      if (m_id >=0 && (unsigned)m_id < selected_manifolds.size()) selected_manifolds[m_id] = true;
      invert(selected_manifolds);
    }


    inline void Polyhedron::invert() {
      invertAll();
    }


    inline bool Polyhedron::edgeOnManifold(const edge_t *e, int m_id) const {
      const std::vector<const face_t *> &edge_faces = connectivity.edge_to_face[edgeToIndex_fast(e)];

      for (size_t i = 0; i < edge_faces.size(); ++i) {
        if (edge_faces[i] && edge_faces[i]->manifold_id == m_id) return true;
      }
      return false;
    }

    inline bool Polyhedron::vertexOnManifold(const vertex_t *v, int m_id) const {
      const std::vector<const face_t *> &f = connectivity.vertex_to_face[vertexToIndex_fast(v)];

      for (size_t i = 0; i < f.size(); ++i) {
        if (f[i]->manifold_id == m_id) return true;
      }
      return false;
    }


    template<typename T>
    int Polyhedron::edgeManifolds(const edge_t *e, T result) const {
      const std::vector<const face_t *> &edge_faces = connectivity.edge_to_face[edgeToIndex_fast(e)];

      for (size_t i = 0; i < (edge_faces.size() & ~1U); i += 2) {
        const face_t *f1 = edge_faces[i];
        const face_t *f2 = edge_faces[i+1];
        assert (f1 || f2);
        if (f1)
          *result++ = f1->manifold_id;
        else if (f2)
          *result++ = f2->manifold_id;
      }
      return edge_faces.size() >> 1;
    }


    template<typename T>
    int Polyhedron::vertexManifolds(const vertex_t *v, T result) const {
      const std::vector<const face_t *> &f = connectivity.vertex_to_face[vertexToIndex_fast(v)];
      std::set<int> em;

      for (size_t i = 0; i < f.size(); ++i) {
        em.insert(f[i]->manifold_id);
      }

      std::copy(em.begin(), em.end(), result);
      return em.size();
    }


    template<typename T>
    void Polyhedron::transform(const T &xform) {
      for (size_t i = 0; i < vertices.size(); i++) {
        vertices[i].v = xform(vertices[i].v);
      }
      faceRecalc();
      init();
    }


    inline size_t Polyhedron::manifoldCount() const {
      return manifold_is_closed.size();
    }


    inline bool Polyhedron::hasOpenManifolds() const {
      for (size_t i = 0; i < manifold_is_closed.size(); ++i) {
        if (!manifold_is_closed[i]) return true;
      }
      return false;
    }


    inline std::ostream &operator<<(std::ostream &o, const Polyhedron &p) {
      p.print(o);
      return o;
    }


  }
}
Add carve library to support better mesh boolean operations 2018-03-17 09:21:17 +00:00			`// Begin License:`
			`// Copyright (C) 2006-2008 Tobias Sargeant (tobias.sargeant@gmail.com).`
			`// All rights reserved.`
			`//`
			`// This file is part of the Carve CSG Library (http://carve-csg.com/)`
			`//`
			`// This file may be used under the terms of the GNU General Public`
			`// License version 2.0 as published by the Free Software Foundation`
			`// and appearing in the file LICENSE.GPL2 included in the packaging of`
			`// this file.`
			`//`
			`// This file is provided "AS IS" with NO WARRANTY OF ANY KIND,`
			`// INCLUDING THE WARRANTIES OF DESIGN, MERCHANTABILITY AND FITNESS FOR`
			`// A PARTICULAR PURPOSE.`
			`// End:`


			`#pragma once`

			`#include <carve/timing.hpp>`

			`#include <assert.h>`
			`#include <list>`

			`namespace carve {`
			`namespace poly {`



			`template<typename order_t>`
			`struct VPtrSort {`
			`order_t &order;`

			`VPtrSort(order_t &_order) : order(_order) {}`
			`bool operator()(carve::poly::Polyhedron::vertex_t const *a,`
			`carve::poly::Polyhedron::vertex_t const *b) const {`
			`return order(a->v, b->v);`
			`}`
			`};`

			`template<typename order_t>`
			`bool Geometry<3>::orderVertices(order_t order) {`
			`static carve::TimingName FUNC_NAME("Geometry<3>::orderVertices()");`
			`carve::TimingBlock block(FUNC_NAME);`

			`std::vector<vertex_t *> vptr;`
			`std::vector<vertex_t *> vmap;`
			`std::vector<vertex_t> vout;`
			`const size_t N = vertices.size();`

			`vptr.reserve(N);`
			`vout.reserve(N);`
			`vmap.resize(N);`

			`for (size_t i = 0; i != N; ++i) {`
			`vptr.push_back(&vertices[i]);`
			`}`
			`std::sort(vptr.begin(), vptr.end(), VPtrSort<order_t>(order));`

			`for (size_t i = 0; i != N; ++i) {`
			`vout.push_back(*vptr[i]);`
			`vmap[vertexToIndex_fast(vptr[i])] = &vout[i];`
			`}`

			`for (size_t i = 0; i < faces.size(); ++i) {`
			`face_t &f = faces[i];`
			`for (size_t j = 0; j < f.nVertices(); ++j) {`
			`f.vertex(j) = vmap[vertexToIndex_fast(f.vertex(j))];`
			`}`
			`}`
			`for (size_t i = 0; i < edges.size(); ++i) {`
			`edges[i].v1 = vmap[vertexToIndex_fast(edges[i].v1)];`
			`edges[i].v2 = vmap[vertexToIndex_fast(edges[i].v2)];`
			`}`

			`vout.swap(vertices);`

			`return true;`
			`}`



			`template<typename T>`
			`int Geometry<3>::_faceNeighbourhood(const face_t f, int depth, T result) const {`
			`if (depth < 0 \|\| f->is_tagged()) return 0;`

			`f->tag();`
			`(result)++ = f;`

			`int r = 1;`
			`for (size_t i = 0; i < f->edges.size(); ++i) {`
			`const std::vector<const face_t *> &edge_faces = connectivity.edge_to_face[edgeToIndex_fast(f->edges[i])];`
			`const face_t *f2 = connectedFace(f, f->edges[i]);`
			`if (f2) {`
			`r += _faceNeighbourhood(f2, depth - 1, (*result));`
			`}`
			`}`
			`return r;`
			`}`



			`template<typename T>`
			`int Geometry<3>::faceNeighbourhood(const face_t *f, int depth, T result) const {`
			`tagable::tag_begin();`

			`return _faceNeighbourhood(f, depth, &result);`
			`}`



			`template<typename T>`
			`int Geometry<3>::faceNeighbourhood(const edge_t *e, int m_id, int depth, T result) const {`
			`tagable::tag_begin();`

			`int r = 0;`
			`const std::vector<const face_t *> &edge_faces = connectivity.edge_to_face[edgeToIndex_fast(e)];`
			`for (size_t i = 0; i < edge_faces.size(); ++i) {`
			`const face_t *f = edge_faces[i];`
			`if (f && f->manifold_id == m_id) { r += _faceNeighbourhood(f, depth, &result); }`
			`}`
			`return r;`
			`}`



			`template<typename T>`
			`int Geometry<3>::faceNeighbourhood(const vertex_t *v, int m_id, int depth, T result) const {`
			`tagable::tag_begin();`

			`int r = 0;`
			`const std::vector<const face_t *> &vertex_faces = connectivity.vertex_to_face[vertexToIndex_fast(v)];`
			`for (size_t i = 0; i < vertex_faces.size(); ++i) {`
			`const face_t *f = vertex_faces[i];`
			`if (f && f->manifold_id == m_id) { r += _faceNeighbourhood(f, depth, &result); }`
			`}`
			`return r;`
			`}`



			`// accessing connectivity information.`
			`template<typename T>`
			`int Geometry<3>::vertexToEdges(const vertex_t *v, T result) const {`
			`const std::vector<const edge_t *> &e = connectivity.vertex_to_edge[vertexToIndex_fast(v)];`
			`std::copy(e.begin(), e.end(), result);`
			`return e.size();`
			`}`



			`template<typename T>`
			`int Geometry<3>::vertexToFaces(const vertex_t *v, T result) const {`
			`const std::vector<const face_t *> &vertex_faces = connectivity.vertex_to_face[vertexToIndex_fast(v)];`
			`int c = 0;`
			`for (size_t i = 0; i < vertex_faces.size(); ++i) {`
			`*result++ = vertex_faces[i]; ++c;`
			`}`
			`return c;`
			`}`



			`template<typename T>`
			`int Geometry<3>::edgeToFaces(const edge_t *e, T result) const {`
			`const std::vector<const face_t *> &edge_faces = connectivity.edge_to_face[edgeToIndex_fast(e)];`
			`int c = 0;`
			`for (size_t i = 0; i < edge_faces.size(); ++i) {`
			`if (edge_faces[i] != NULL) { *result++ = edge_faces[i]; ++c; }`
			`}`
			`return c;`
			`}`



			`inline const Geometry<3>::face_t Geometry<3>::connectedFace(const face_t f, const edge_t *e) const {`
			`const std::vector<const face_t *> &edge_faces = connectivity.edge_to_face[edgeToIndex_fast(e)];`
			`for (size_t i = 0; i < (edge_faces.size() & ~1U); i++) {`
			`if (edge_faces[i] == f) return edge_faces[i^1];`
			`}`
			`return NULL;`
			`}`



			`inline void Polyhedron::invert(int m_id) {`
			`std::vector<bool> selected_manifolds(manifold_is_closed.size(), false);`
			`if (m_id >=0 && (unsigned)m_id < selected_manifolds.size()) selected_manifolds[m_id] = true;`
			`invert(selected_manifolds);`
			`}`



			`inline void Polyhedron::invert() {`
			`invertAll();`
			`}`



			`inline bool Polyhedron::edgeOnManifold(const edge_t *e, int m_id) const {`
			`const std::vector<const face_t *> &edge_faces = connectivity.edge_to_face[edgeToIndex_fast(e)];`

			`for (size_t i = 0; i < edge_faces.size(); ++i) {`
			`if (edge_faces[i] && edge_faces[i]->manifold_id == m_id) return true;`
			`}`
			`return false;`
			`}`

			`inline bool Polyhedron::vertexOnManifold(const vertex_t *v, int m_id) const {`
			`const std::vector<const face_t *> &f = connectivity.vertex_to_face[vertexToIndex_fast(v)];`

			`for (size_t i = 0; i < f.size(); ++i) {`
			`if (f[i]->manifold_id == m_id) return true;`
			`}`
			`return false;`
			`}`



			`template<typename T>`
			`int Polyhedron::edgeManifolds(const edge_t *e, T result) const {`
			`const std::vector<const face_t *> &edge_faces = connectivity.edge_to_face[edgeToIndex_fast(e)];`

			`for (size_t i = 0; i < (edge_faces.size() & ~1U); i += 2) {`
			`const face_t *f1 = edge_faces[i];`
			`const face_t *f2 = edge_faces[i+1];`
			`assert (f1 \|\| f2);`
			`if (f1)`
			`*result++ = f1->manifold_id;`
			`else if (f2)`
			`*result++ = f2->manifold_id;`
			`}`
			`return edge_faces.size() >> 1;`
			`}`



			`template<typename T>`
			`int Polyhedron::vertexManifolds(const vertex_t *v, T result) const {`
			`const std::vector<const face_t *> &f = connectivity.vertex_to_face[vertexToIndex_fast(v)];`
			`std::set<int> em;`

			`for (size_t i = 0; i < f.size(); ++i) {`
			`em.insert(f[i]->manifold_id);`
			`}`

			`std::copy(em.begin(), em.end(), result);`
			`return em.size();`
			`}`



			`template<typename T>`
			`void Polyhedron::transform(const T &xform) {`
			`for (size_t i = 0; i < vertices.size(); i++) {`
			`vertices[i].v = xform(vertices[i].v);`
			`}`
			`faceRecalc();`
			`init();`
			`}`



			`inline size_t Polyhedron::manifoldCount() const {`
			`return manifold_is_closed.size();`
			`}`



			`inline bool Polyhedron::hasOpenManifolds() const {`
			`for (size_t i = 0; i < manifold_is_closed.size(); ++i) {`
			`if (!manifold_is_closed[i]) return true;`
			`}`
			`return false;`
			`}`



			`inline std::ostream &operator<<(std::ostream &o, const Polyhedron &p) {`
			`p.print(o);`
			`return o;`
			`}`



			`}`
			`}`