+
+void Hair::set_transform(Mat4 &xform)
+{
+ this->xform = xform;
+}
+
+void Hair::update(float dt)
+{
+ for(size_t i = 0; i < hair.size(); i++) {
+ /* in local space */
+ Vec3 hair_end = hair[i].spawn_pt + hair[i].spawn_dir * hair_length;
+ Vec3 anchor = xform * hair_end;
+
+ Vec3 force = (anchor - hair[i].pos) * K_ANC;
+
+ Vec3 accel = force; /* mass 1 */
+ hair[i].velocity += ((-hair[i].velocity * DAMPING) + accel) * dt;
+ Vec3 new_pos = hair[i].pos + hair[i].velocity * dt;
+
+ /* collision detection with the head */
+ Vec3 normal = xform.upper3x3() * hair[i].spawn_dir;
+ Vec3 root = xform * hair[i].spawn_pt;
+ Vec3 dir = new_pos - root;
+
+ normal.normalize();
+
+ /* angle that will cause the hair to be rendered inside the head */
+ float d = dot(dir, normal);
+ if(d < 0) {
+ new_pos += -d * normal;
+ }
+
+ hair[i].pos = handle_collision(new_pos);
+
+ dbg_force = force;
+ }
+}
+
+void Hair::add_collider(CollSphere *cobj) {
+ colliders.push_back(cobj);
+}
+
+Vec3 Hair::handle_collision(const Vec3 &v) const
+{
+ /* if we transform the center and the radius of the collider sphere
+ * we might end up with a spheroid, so better just multiply the
+ * position with the inverse transform before check for collisions :*/
+
+ Vec3 new_v = inverse(xform) * v;
+
+ for(size_t i=0; i<colliders.size(); i++) {
+ if(colliders[i]->contains(new_v)) {
+ new_v = colliders[i]->project_surf(new_v);
+ }
+ }
+ return xform * new_v;
+}