bool Chunk::Intersection(
const Ray &ray,
const glm::mat4 &M,
- int *blkid,
- float *dist,
- glm::vec3 *normal) const {
- { // rough check
- if (!blank::Intersection(ray, Bounds(), M)) {
- return false;
- }
- }
-
- if (!blkid && !dist && !normal) {
- return true;
- }
-
+ int &blkid,
+ float &dist,
+ glm::vec3 &normal
+) const {
// TODO: should be possible to heavily optimize this
int id = 0;
- int closest_id = -1;
- float closest_dist = std::numeric_limits<float>::infinity();
- glm::vec3 closest_normal(0, 1, 0);
+ blkid = -1;
+ dist = std::numeric_limits<float>::infinity();
for (int z = 0; z < Depth(); ++z) {
for (int y = 0; y < Height(); ++y) {
for (int x = 0; x < Width(); ++x, ++id) {
}
float cur_dist;
glm::vec3 cur_norm;
- Block::Pos pos(float(x) + 0.5f, float(y) + 0.5f, float(z) + 0.5f);
- if (Type(blocks[id]).shape->Intersects(ray, glm::translate(M, pos), cur_dist, cur_norm)) {
- if (cur_dist < closest_dist) {
- closest_id = id;
- closest_dist = cur_dist;
- closest_normal = cur_norm;
+ if (Type(blocks[id]).shape->Intersects(ray, M * ToTransform(id), cur_dist, cur_norm)) {
+ if (cur_dist < dist) {
+ blkid = id;
+ dist = cur_dist;
+ normal = cur_norm;
}
}
}
}
}
- if (closest_id < 0) {
+ if (blkid < 0) {
return false;
+ } else {
+ normal = glm::vec3(BlockAt(blkid).Transform() * glm::vec4(normal, 0.0f));
+ return true;
}
-
- if (blkid) {
- *blkid = closest_id;
- }
- if (dist) {
- *dist = closest_dist;
- }
- if (normal) {
- *normal = closest_normal;
- }
- return true;
}
void Chunk::Position(const Pos &pos) {
if (Obstructed(i)) continue;
const BlockType &type = Type(blocks[i]);
- type.FillModel(buf, ToCoords(i), vtx_counter);
+ type.FillModel(buf, ToTransform(i), vtx_counter);
vtx_counter += type.shape->VertexCount();
}
const BlockType &left = Type(blocks[idx - 1]);
if (!left.fill.right) return false;
- const BlockType &top = Type(blocks[idx + Width()]);
- if (!top.fill.bottom) return false;
+ const BlockType &up = Type(blocks[idx + Width()]);
+ if (!up.fill.down) return false;
- const BlockType &bottom = Type(blocks[idx - Width()]);
- if (!bottom.fill.top) return false;
+ const BlockType &down = Type(blocks[idx - Width()]);
+ if (!down.fill.up) return false;
const BlockType &front = Type(blocks[idx + Width() * Height()]);
if (!front.fill.back) return false;
return true;
}
+glm::mat4 Chunk::ToTransform(int idx) const {
+ return glm::translate(glm::mat4(1.0f), ToCoords(idx)) * blocks[idx].Transform();
+}
+
ChunkLoader::ChunkLoader(const BlockTypeRegistry ®, const Generator &gen)
: base(0, 0, 0)
loaded.emplace_back(reg);
loaded.back().Position(pos);
gen(loaded.back());
+
+ // orientation testing
+ // for (int i = 0; i < Block::FACE_COUNT; ++i) {
+ // for (int j = 0; j < Block::TURN_COUNT; ++j) {
+ // loaded.back().BlockAt(512 * j + 2 * i) = Block(3 * (j + 1), Block::Face(i), Block::Turn(j));
+ // }
+ // }
+ // loaded.back().Invalidate();
+ // loaded.back().CheckUpdate();
} else {
to_generate.emplace_back(pos);
}