blender-archive/intern/cycles/subd/subd_dice.cpp

/*
 * Copyright 2011-2013 Blender Foundation
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

#include "render/camera.h"
#include "render/mesh.h"

#include "subd/subd_dice.h"
#include "subd/subd_patch.h"

CCL_NAMESPACE_BEGIN

/* EdgeDice Base */

EdgeDice::EdgeDice(const SubdParams &params_) : params(params_)
{
  mesh_P = NULL;
  mesh_N = NULL;
  vert_offset = 0;

  params.mesh->attributes.add(ATTR_STD_VERTEX_NORMAL);

  if (params.ptex) {
    params.mesh->attributes.add(ATTR_STD_PTEX_UV);
    params.mesh->attributes.add(ATTR_STD_PTEX_FACE_ID);
  }
}

void EdgeDice::reserve(int num_verts)
{
  Mesh *mesh = params.mesh;

  vert_offset = mesh->verts.size();
  tri_offset = mesh->num_triangles();

  /* todo: optimize so we can reserve in advance, this is like push_back_slow() */
  if (vert_offset + num_verts > mesh->verts.capacity()) {
    mesh->reserve_mesh(size_t((vert_offset + num_verts) * 1.2), mesh->num_triangles());
  }

  mesh->resize_mesh(vert_offset + num_verts, tri_offset);

  Attribute *attr_vN = mesh->attributes.add(ATTR_STD_VERTEX_NORMAL);

  mesh_P = mesh->verts.data();
  mesh_N = attr_vN->data_float3();
}

int EdgeDice::add_vert(Patch *patch, float2 uv)
{
  float3 P, N;

  patch->eval(&P, NULL, NULL, &N, uv.x, uv.y);

  assert(vert_offset < params.mesh->verts.size());

  mesh_P[vert_offset] = P;
  mesh_N[vert_offset] = N;
  params.mesh->vert_patch_uv[vert_offset] = make_float2(uv.x, uv.y);

  if (params.ptex) {
    Attribute *attr_ptex_uv = params.mesh->attributes.add(ATTR_STD_PTEX_UV);
    params.mesh->attributes.resize();

    float3 *ptex_uv = attr_ptex_uv->data_float3();
    ptex_uv[vert_offset] = make_float3(uv.x, uv.y, 0.0f);
  }

  params.mesh->num_subd_verts++;

  return vert_offset++;
}

void EdgeDice::add_triangle(Patch *patch, int v0, int v1, int v2)
{
  Mesh *mesh = params.mesh;

  /* todo: optimize so we can reserve in advance, this is like push_back_slow() */
  if (mesh->triangles.size() == mesh->triangles.capacity())
    mesh->reserve_mesh(mesh->verts.size(), size_t(max(mesh->num_triangles() + 1, 1) * 1.2));

  mesh->add_triangle(v0, v1, v2, patch->shader, true);
  params.mesh->triangle_patch[params.mesh->num_triangles() - 1] = patch->patch_index;

  if (params.ptex) {
    Attribute *attr_ptex_face_id = params.mesh->attributes.add(ATTR_STD_PTEX_FACE_ID);
    params.mesh->attributes.resize();

    float *ptex_face_id = attr_ptex_face_id->data_float();
    ptex_face_id[tri_offset] = (float)patch->ptex_face_id();
  }

  tri_offset++;
}

void EdgeDice::stitch_triangles(Patch *patch, vector<int> &outer, vector<int> &inner)
{
  if (inner.size() == 0 || outer.size() == 0)
    return;  // XXX avoid crashes for Mu or Mv == 1, missing polygons

  /* stitch together two arrays of verts with triangles. at each step,
   * we compare using the next verts on both sides, to find the split
   * direction with the smallest diagonal, and use that in order to keep
   * the triangle shape reasonable. */
  for (size_t i = 0, j = 0; i + 1 < inner.size() || j + 1 < outer.size();) {
    int v0, v1, v2;

    v0 = inner[i];
    v1 = outer[j];

    if (j + 1 == outer.size()) {
      v2 = inner[++i];
    }
    else if (i + 1 == inner.size()) {
      v2 = outer[++j];
    }
    else {
      /* length of diagonals */
      float len1 = len_squared(mesh_P[inner[i]] - mesh_P[outer[j + 1]]);
      float len2 = len_squared(mesh_P[outer[j]] - mesh_P[inner[i + 1]]);

      /* use smallest diagonal */
      if (len1 < len2)
        v2 = outer[++j];
      else
        v2 = inner[++i];
    }

    add_triangle(patch, v0, v1, v2);
  }
}

/* QuadDice */

QuadDice::QuadDice(const SubdParams &params_) : EdgeDice(params_)
{
}

void QuadDice::reserve(EdgeFactors &ef, int Mu, int Mv)
{
  /* XXX need to make this also work for edge factor 0 and 1 */
  int num_verts = (ef.tu0 + ef.tu1 + ef.tv0 + ef.tv1) + (Mu - 1) * (Mv - 1);
  EdgeDice::reserve(num_verts);
}

float2 QuadDice::map_uv(SubPatch &sub, float u, float v)
{
  /* map UV from subpatch to patch parametric coordinates */
  float2 d0 = interp(sub.P00, sub.P01, v);
  float2 d1 = interp(sub.P10, sub.P11, v);
  return interp(d0, d1, u);
}

float3 QuadDice::eval_projected(SubPatch &sub, float u, float v)
{
  float2 uv = map_uv(sub, u, v);
  float3 P;

  sub.patch->eval(&P, NULL, NULL, NULL, uv.x, uv.y);
  if (params.camera)
    P = transform_perspective(&params.camera->worldtoraster, P);

  return P;
}

int QuadDice::add_vert(SubPatch &sub, float u, float v)
{
  return EdgeDice::add_vert(sub.patch, map_uv(sub, u, v));
}

void QuadDice::add_side_u(SubPatch &sub,
                          vector<int> &outer,
                          vector<int> &inner,
                          int Mu,
                          int Mv,
                          int tu,
                          int side,
                          int offset)
{
  outer.clear();
  inner.clear();

  /* set verts on the edge of the patch */
  outer.push_back(offset + ((side) ? 2 : 0));

  for (int i = 1; i < tu; i++) {
    float u = i / (float)tu;
    float v = (side) ? 1.0f : 0.0f;

    outer.push_back(add_vert(sub, u, v));
  }

  outer.push_back(offset + ((side) ? 3 : 1));

  /* set verts on the edge of the inner grid */
  for (int i = 0; i < Mu - 1; i++) {
    int j = (side) ? Mv - 1 - 1 : 0;
    inner.push_back(offset + 4 + i + j * (Mu - 1));
  }
}

void QuadDice::add_side_v(SubPatch &sub,
                          vector<int> &outer,
                          vector<int> &inner,
                          int Mu,
                          int Mv,
                          int tv,
                          int side,
                          int offset)
{
  outer.clear();
  inner.clear();

  /* set verts on the edge of the patch */
  outer.push_back(offset + ((side) ? 1 : 0));

  for (int j = 1; j < tv; j++) {
    float u = (side) ? 1.0f : 0.0f;
    float v = j / (float)tv;

    outer.push_back(add_vert(sub, u, v));
  }

  outer.push_back(offset + ((side) ? 3 : 2));

  /* set verts on the edge of the inner grid */
  for (int j = 0; j < Mv - 1; j++) {
    int i = (side) ? Mu - 1 - 1 : 0;
    inner.push_back(offset + 4 + i + j * (Mu - 1));
  }
}

float QuadDice::quad_area(const float3 &a, const float3 &b, const float3 &c, const float3 &d)
{
  return triangle_area(a, b, d) + triangle_area(a, d, c);
}

float QuadDice::scale_factor(SubPatch &sub, EdgeFactors &ef, int Mu, int Mv)
{
  /* estimate area as 4x largest of 4 quads */
  float3 P[3][3];

  for (int i = 0; i < 3; i++)
    for (int j = 0; j < 3; j++)
      P[i][j] = eval_projected(sub, i * 0.5f, j * 0.5f);

  float A1 = quad_area(P[0][0], P[1][0], P[0][1], P[1][1]);
  float A2 = quad_area(P[1][0], P[2][0], P[1][1], P[2][1]);
  float A3 = quad_area(P[0][1], P[1][1], P[0][2], P[1][2]);
  float A4 = quad_area(P[1][1], P[2][1], P[1][2], P[2][2]);
  float Apatch = max(A1, max(A2, max(A3, A4))) * 4.0f;

  /* solve for scaling factor */
  float Atri = params.dicing_rate * params.dicing_rate * 0.5f;
  float Ntris = Apatch / Atri;

  // XXX does the -sqrt solution matter
  // XXX max(D, 0.0) is highly suspicious, need to test cases
  // where D goes negative
  float N = 0.5f * (Ntris - (ef.tu0 + ef.tu1 + ef.tv0 + ef.tv1));
  float D = 4.0f * N * Mu * Mv + (Mu + Mv) * (Mu + Mv);
  float S = (Mu + Mv + sqrtf(max(D, 0.0f))) / (2 * Mu * Mv);

  return S;
}

void QuadDice::add_corners(SubPatch &sub)
{
  /* add verts for patch corners */
  add_vert(sub, 0.0f, 0.0f);
  add_vert(sub, 1.0f, 0.0f);
  add_vert(sub, 0.0f, 1.0f);
  add_vert(sub, 1.0f, 1.0f);
}

void QuadDice::add_grid(SubPatch &sub, int Mu, int Mv, int offset)
{
  /* create inner grid */
  float du = 1.0f / (float)Mu;
  float dv = 1.0f / (float)Mv;

  for (int j = 1; j < Mv; j++) {
    for (int i = 1; i < Mu; i++) {
      float u = i * du;
      float v = j * dv;

      add_vert(sub, u, v);

      if (i < Mu - 1 && j < Mv - 1) {
        int i1 = offset + 4 + (i - 1) + (j - 1) * (Mu - 1);
        int i2 = offset + 4 + i + (j - 1) * (Mu - 1);
        int i3 = offset + 4 + i + j * (Mu - 1);
        int i4 = offset + 4 + (i - 1) + j * (Mu - 1);

        add_triangle(sub.patch, i1, i2, i3);
        add_triangle(sub.patch, i1, i3, i4);
      }
    }
  }
}

void QuadDice::dice(SubPatch &sub, EdgeFactors &ef)
{
  /* compute inner grid size with scale factor */
  int Mu = max(ef.tu0, ef.tu1);
  int Mv = max(ef.tv0, ef.tv1);

#if 0 /* Doesnt work very well, especially at grazing angles. */
  float S = scale_factor(sub, ef, Mu, Mv);
#else
  float S = 1.0f;
#endif

  Mu = max((int)ceil(S * Mu), 2);  // XXX handle 0 & 1?
  Mv = max((int)ceil(S * Mv), 2);  // XXX handle 0 & 1?

  /* reserve space for new verts */
  int offset = params.mesh->verts.size();
  reserve(ef, Mu, Mv);

  /* corners and inner grid */
  add_corners(sub);
  add_grid(sub, Mu, Mv, offset);

  /* bottom side */
  vector<int> outer, inner;

  add_side_u(sub, outer, inner, Mu, Mv, ef.tu0, 0, offset);
  stitch_triangles(sub.patch, outer, inner);

  /* top side */
  add_side_u(sub, outer, inner, Mu, Mv, ef.tu1, 1, offset);
  stitch_triangles(sub.patch, inner, outer);

  /* left side */
  add_side_v(sub, outer, inner, Mu, Mv, ef.tv0, 0, offset);
  stitch_triangles(sub.patch, inner, outer);

  /* right side */
  add_side_v(sub, outer, inner, Mu, Mv, ef.tv1, 1, offset);
  stitch_triangles(sub.patch, outer, inner);

  assert(vert_offset == params.mesh->verts.size());
}

CCL_NAMESPACE_END