}
try_expose_me();
- // spawn smalltux below spawnpoint
- if (!player->is_big()) {
- player->move(player_pos + Vector(0,32));
- } else {
- player->move(player_pos);
- }
- // spawning tux in the ground would kill him
- if(!is_free_of_tiles(player->get_bbox())) {
- log_warning << "Tried spawning Tux in solid matter. Compensating." << std::endl;
- Vector npos = player->get_bbox().p1;
- npos.y-=32;
- player->move(npos);
+ // two-player hack: move other players to main player's position
+ // Maybe specify 2 spawnpoints in the level?
+ for(GameObjects::iterator i = gameobjects.begin();
+ i != gameobjects.end(); ++i) {
+ Player* p = dynamic_cast<Player*>(*i);
+ if (!p) continue;
+
+ // spawn smalltux below spawnpoint
+ if (!p->is_big()) {
+ p->move(player_pos + Vector(0,32));
+ } else {
+ p->move(player_pos);
+ }
+
+ // spawning tux in the ground would kill him
+ if(!is_free_of_tiles(p->get_bbox())) {
+ log_warning << "Tried spawning Tux in solid matter. Compensating." << std::endl;
+ Vector npos = p->get_bbox().p1;
+ npos.y-=32;
+ p->move(npos);
+ }
}
camera->reset(player->get_pos());
}
if(show_collrects) {
- Color col(0.2f, 0.2f, 0.2f, 0.7f);
+ Color color(1.0f, 0.0f, 0.0f, 0.75f);
for(MovingObjects::iterator i = moving_objects.begin();
i != moving_objects.end(); ++i) {
MovingObject* object = *i;
const Rectf& rect = object->get_bbox();
- context.draw_filled_rect(rect, col, LAYER_FOREGROUND1 + 10);
+ context.draw_filled_rect(rect, color, LAYER_FOREGROUND1 + 10);
}
}
/** r1 is supposed to be moving, r2 a solid object */
void check_collisions(collision::Constraints* constraints,
- const Vector& movement, const Rectf& r1, const Rectf& r2,
- GameObject* object = NULL, MovingObject* other = NULL, const Vector& addl_ground_movement = Vector(0,0))
+ const Vector& obj_movement, const Rectf& obj_rect, const Rectf& other_rect,
+ GameObject* object = NULL, MovingObject* other = NULL, const Vector& other_movement = Vector(0,0))
{
- if(!collision::intersects(r1, r2))
+ if(!collision::intersects(obj_rect, other_rect))
return;
MovingObject *moving_object = dynamic_cast<MovingObject*> (object);
return;
// calculate intersection
- float itop = r1.get_bottom() - r2.get_top();
- float ibottom = r2.get_bottom() - r1.get_top();
- float ileft = r1.get_right() - r2.get_left();
- float iright = r2.get_right() - r1.get_left();
+ float itop = obj_rect.get_bottom() - other_rect.get_top();
+ float ibottom = other_rect.get_bottom() - obj_rect.get_top();
+ float ileft = obj_rect.get_right() - other_rect.get_left();
+ float iright = other_rect.get_right() - obj_rect.get_left();
- if(fabsf(movement.y) > fabsf(movement.x)) {
+ if(fabsf(obj_movement.y) > fabsf(obj_movement.x)) {
if(ileft < SHIFT_DELTA) {
- constraints->constrain_right(r2.get_left());
+ constraints->constrain_right(other_rect.get_left(), other_movement.x);
return;
} else if(iright < SHIFT_DELTA) {
- constraints->constrain_left(r2.get_right());
+ constraints->constrain_left(other_rect.get_right(), other_movement.x);
return;
}
} else {
// shiftout bottom/top
if(itop < SHIFT_DELTA) {
- constraints->constrain_bottom(r2.get_top());
+ constraints->constrain_bottom(other_rect.get_top(), other_movement.y);
return;
} else if(ibottom < SHIFT_DELTA) {
- constraints->constrain_top(r2.get_bottom());
+ constraints->constrain_top(other_rect.get_bottom(), other_movement.y);
return;
}
}
- constraints->ground_movement += addl_ground_movement;
+ constraints->ground_movement += other_movement;
if(other != NULL) {
HitResponse response = other->collision(*object, dummy);
if(response == ABORT_MOVE)
float horiz_penetration = std::min(ileft, iright);
if(vert_penetration < horiz_penetration) {
if(itop < ibottom) {
- constraints->constrain_bottom(r2.get_top());
+ constraints->constrain_bottom(other_rect.get_top(), other_movement.y);
constraints->hit.bottom = true;
} else {
- constraints->constrain_top(r2.get_bottom());
+ constraints->constrain_top(other_rect.get_bottom(), other_movement.y);
constraints->hit.top = true;
}
} else {
if(ileft < iright) {
- constraints->constrain_right(r2.get_left());
+ constraints->constrain_right(other_rect.get_left(), other_movement.x);
constraints->hit.right = true;
} else {
- constraints->constrain_left(r2.get_right());
+ constraints->constrain_left(other_rect.get_right(), other_movement.x);
constraints->hit.left = true;
}
}
break;
// apply calculated horizontal constraints
- if(constraints.bottom < infinity) {
- float height = constraints.bottom - constraints.top;
+ if(constraints.get_position_bottom() < infinity) {
+ float height = constraints.get_height ();
if(height < oheight) {
// we're crushed, but ignore this for now, we'll get this again
// later if we're really crushed or things will solve itself when
// looking at the vertical constraints
}
- dest.p2.y = constraints.bottom - DELTA;
+ dest.p2.y = constraints.get_position_bottom() - DELTA;
dest.p1.y = dest.p2.y - oheight;
- } else if(constraints.top > -infinity) {
- dest.p1.y = constraints.top + DELTA;
+ } else if(constraints.get_position_top() > -infinity) {
+ dest.p1.y = constraints.get_position_top() + DELTA;
dest.p2.y = dest.p1.y + oheight;
}
}
break;
// apply calculated vertical constraints
- float width = constraints.right - constraints.left;
+ float width = constraints.get_width ();
if(width < infinity) {
if(width + SHIFT_DELTA < owidth) {
#if 0
printf("Object %p crushed horizontally... L:%f R:%f\n", &object,
- constraints.left, constraints.right);
+ constraints.get_position_left(), constraints.get_position_right());
#endif
CollisionHit h;
h.left = true;
h.crush = true;
object.collision_solid(h);
} else {
- float xmid = (constraints.left + constraints.right) / 2;
+ float xmid = constraints.get_x_midpoint ();
dest.p1.x = xmid - owidth/2;
dest.p2.x = xmid + owidth/2;
}
- } else if(constraints.right < infinity) {
- dest.p2.x = constraints.right - DELTA;
+ } else if(constraints.get_position_right() < infinity) {
+ dest.p2.x = constraints.get_position_right() - DELTA;
dest.p1.x = dest.p2.x - owidth;
- } else if(constraints.left > -infinity) {
- dest.p1.x = constraints.left + DELTA;
+ } else if(constraints.get_position_left() > -infinity) {
+ dest.p1.x = constraints.get_position_left() + DELTA;
dest.p2.x = dest.p1.x + owidth;
}
}
// an extra pass to make sure we're not crushed horizontally
constraints = Constraints();
collision_static(&constraints, movement, dest, object);
- if(constraints.bottom < infinity) {
- float height = constraints.bottom - constraints.top;
+ if(constraints.get_position_bottom() < infinity) {
+ float height = constraints.get_height ();
if(height + SHIFT_DELTA < oheight) {
#if 0
printf("Object %p crushed vertically...\n", &object);
return gravity;
}
+Player*
+Sector::get_nearest_player (const Vector& pos)
+{
+ Player *nearest_player = NULL;
+ float nearest_dist = std::numeric_limits<float>::max();
+
+ std::vector<Player*> players = Sector::current()->get_players();
+ for (std::vector<Player*>::iterator playerIter = players.begin();
+ playerIter != players.end();
+ ++playerIter)
+ {
+ Player *this_player = *playerIter;
+ if (this_player->is_dying() || this_player->is_dead())
+ continue;
+
+ float this_dist = this_player->get_bbox ().distance(pos);
+
+ if (this_dist < nearest_dist) {
+ nearest_player = this_player;
+ nearest_dist = this_dist;
+ }
+ }
+
+ return nearest_player;
+} /* Player *get_nearest_player */
+
+std::vector<MovingObject*>
+Sector::get_nearby_objects (const Vector& center, float max_distance)
+{
+ std::vector<MovingObject*> ret;
+ std::vector<Player*> players = Sector::current()->get_players();
+
+ for (size_t i = 0; i < players.size (); i++) {
+ float distance = players[i]->get_bbox ().distance (center);
+ if (distance <= max_distance)
+ ret.push_back (players[i]);
+ }
+
+ for (size_t i = 0; i < moving_objects.size (); i++) {
+ float distance = moving_objects[i]->get_bbox ().distance (center);
+ if (distance <= max_distance)
+ ret.push_back (moving_objects[i]);
+ }
+
+ return (ret);
+}
+
+/* vim: set sw=2 sts=2 et : */
/* EOF */