/* Minetest Copyright (C) 2013 celeron55, Perttu Ahola This program is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include "collision.h" #include #include "mapblock.h" #include "map.h" #include "nodedef.h" #include "gamedef.h" #ifndef SERVER #include "client/clientenvironment.h" #include "client/localplayer.h" #endif #include "serverenvironment.h" #include "server/serveractiveobject.h" #include "util/timetaker.h" #include "profiler.h" struct NearbyCollisionInfo { NearbyCollisionInfo(bool is_ul, bool is_obj, int bouncy, const v3s16 &pos, const aabb3f &box) : is_unloaded(is_ul), is_object(is_obj), bouncy(bouncy), position(pos), box(box) {} bool is_unloaded; bool is_step_up = false; bool is_object; int bouncy; v3s16 position; aabb3f box; }; // Helper function: // Checks for collision of a moving aabbox with a static aabbox // Returns -1 if no collision, 0 if X collision, 1 if Y collision, 2 if Z collision // The time after which the collision occurs is stored in dtime. CollisionAxis axisAlignedCollision( const aabb3f &staticbox, const aabb3f &movingbox, const v3f &speed, f32 *dtime) { //TimeTaker tt("axisAlignedCollision"); aabb3f relbox( movingbox.MaxEdge.X - movingbox.MinEdge.X + staticbox.MaxEdge.X - staticbox.MinEdge.X, // sum of the widths movingbox.MaxEdge.Y - movingbox.MinEdge.Y + staticbox.MaxEdge.Y - staticbox.MinEdge.Y, movingbox.MaxEdge.Z - movingbox.MinEdge.Z + staticbox.MaxEdge.Z - staticbox.MinEdge.Z, std::max(movingbox.MaxEdge.X, staticbox.MaxEdge.X) - std::min(movingbox.MinEdge.X, staticbox.MinEdge.X), //outer bounding 'box' dimensions std::max(movingbox.MaxEdge.Y, staticbox.MaxEdge.Y) - std::min(movingbox.MinEdge.Y, staticbox.MinEdge.Y), std::max(movingbox.MaxEdge.Z, staticbox.MaxEdge.Z) - std::min(movingbox.MinEdge.Z, staticbox.MinEdge.Z) ); const f32 dtime_max = *dtime; const f32 inner_margin = -1.5f; f32 distance; f32 time; if (speed.X) { distance = relbox.MaxEdge.X - relbox.MinEdge.X; *dtime = distance >= 0 ? std::abs(distance / speed.X) : -std::abs(distance / speed.X); time = std::max(*dtime, 0.0f); if (distance > inner_margin) { if (*dtime <= dtime_max) { if ((speed.X > 0 && staticbox.MaxEdge.X > movingbox.MaxEdge.X) || (speed.X < 0 && staticbox.MinEdge.X < movingbox.MinEdge.X)) { if ( (std::max(movingbox.MaxEdge.Y + speed.Y * time, staticbox.MaxEdge.Y) - std::min(movingbox.MinEdge.Y + speed.Y * time, staticbox.MinEdge.Y) - relbox.MinEdge.Y < 0) && (std::max(movingbox.MaxEdge.Z + speed.Z * time, staticbox.MaxEdge.Z) - std::min(movingbox.MinEdge.Z + speed.Z * time, staticbox.MinEdge.Z) - relbox.MinEdge.Z < 0) ) return COLLISION_AXIS_X; } } else { return COLLISION_AXIS_NONE; } } } // NO else if here if (speed.Y) { distance = relbox.MaxEdge.Y - relbox.MinEdge.Y; *dtime = distance >= 0 ? std::abs(distance / speed.Y) : -std::abs(distance / speed.Y); time = std::max(*dtime, 0.0f); if (distance > inner_margin) { if (*dtime <= dtime_max) { if ((speed.Y > 0 && staticbox.MaxEdge.Y > movingbox.MaxEdge.Y) || (speed.Y < 0 && staticbox.MinEdge.Y < movingbox.MinEdge.Y)) { if ( (std::max(movingbox.MaxEdge.X + speed.X * time, staticbox.MaxEdge.X) - std::min(movingbox.MinEdge.X + speed.X * time, staticbox.MinEdge.X) - relbox.MinEdge.X < 0) && (std::max(movingbox.MaxEdge.Z + speed.Z * time, staticbox.MaxEdge.Z) - std::min(movingbox.MinEdge.Z + speed.Z * time, staticbox.MinEdge.Z) - relbox.MinEdge.Z < 0) ) return COLLISION_AXIS_Y; } } else { return COLLISION_AXIS_NONE; } } } // NO else if here if (speed.Z) { distance = relbox.MaxEdge.Z - relbox.MinEdge.Z; *dtime = distance >= 0 ? std::abs(distance / speed.Z) : -std::abs(distance / speed.Z); time = std::max(*dtime, 0.0f); if (distance > inner_margin) { if (*dtime <= dtime_max) { if ((speed.Z > 0 && staticbox.MaxEdge.Z > movingbox.MaxEdge.Z) || (speed.Z < 0 && staticbox.MinEdge.Z < movingbox.MinEdge.Z)) { if ( (std::max(movingbox.MaxEdge.X + speed.X * time, staticbox.MaxEdge.X) - std::min(movingbox.MinEdge.X + speed.X * time, staticbox.MinEdge.X) - relbox.MinEdge.X < 0) && (std::max(movingbox.MaxEdge.Y + speed.Y * time, staticbox.MaxEdge.Y) - std::min(movingbox.MinEdge.Y + speed.Y * time, staticbox.MinEdge.Y) - relbox.MinEdge.Y < 0) ) return COLLISION_AXIS_Z; } } } } return COLLISION_AXIS_NONE; } // Helper function: // Checks if moving the movingbox up by the given distance would hit a ceiling. bool wouldCollideWithCeiling( const std::vector &cinfo, const aabb3f &movingbox, f32 y_increase, f32 d) { //TimeTaker tt("wouldCollideWithCeiling"); assert(y_increase >= 0); // pre-condition for (const auto &it : cinfo) { const aabb3f &staticbox = it.box; if ((movingbox.MaxEdge.Y - d <= staticbox.MinEdge.Y) && (movingbox.MaxEdge.Y + y_increase > staticbox.MinEdge.Y) && (movingbox.MinEdge.X < staticbox.MaxEdge.X) && (movingbox.MaxEdge.X > staticbox.MinEdge.X) && (movingbox.MinEdge.Z < staticbox.MaxEdge.Z) && (movingbox.MaxEdge.Z > staticbox.MinEdge.Z)) return true; } return false; } static inline void getNeighborConnectingFace(const v3s16 &p, const NodeDefManager *nodedef, Map *map, MapNode n, int v, int *neighbors) { MapNode n2 = map->getNode(p); if (nodedef->nodeboxConnects(n, n2, v)) *neighbors |= v; } collisionMoveResult collisionMoveSimple(Environment *env, IGameDef *gamedef, f32 pos_max_d, const aabb3f &box_0, f32 stepheight, f32 dtime, v3f *pos_f, v3f *speed_f, v3f accel_f, ActiveObject *self, bool collideWithObjects) { static bool time_notification_done = false; Map *map = &env->getMap(); ScopeProfiler sp(g_profiler, "collisionMoveSimple()", SPT_AVG); collisionMoveResult result; /* Calculate new velocity */ if (dtime > 0.5f) { if (!time_notification_done) { time_notification_done = true; infostream << "collisionMoveSimple: maximum step interval exceeded," " lost movement details!"<getLength() == 0) return result; // Limit speed for avoiding hangs speed_f->Y = rangelim(speed_f->Y, -5000, 5000); speed_f->X = rangelim(speed_f->X, -5000, 5000); speed_f->Z = rangelim(speed_f->Z, -5000, 5000); /* Collect node boxes in movement range */ std::vector cinfo; { //TimeTaker tt2("collisionMoveSimple collect boxes"); ScopeProfiler sp2(g_profiler, "collisionMoveSimple(): collect boxes", SPT_AVG); v3f newpos_f = *pos_f + *speed_f * dtime; v3f minpos_f( MYMIN(pos_f->X, newpos_f.X), MYMIN(pos_f->Y, newpos_f.Y) + 0.01f * BS, // bias rounding, player often at +/-n.5 MYMIN(pos_f->Z, newpos_f.Z) ); v3f maxpos_f( MYMAX(pos_f->X, newpos_f.X), MYMAX(pos_f->Y, newpos_f.Y), MYMAX(pos_f->Z, newpos_f.Z) ); v3s16 min = floatToInt(minpos_f + box_0.MinEdge, BS) - v3s16(1, 1, 1); v3s16 max = floatToInt(maxpos_f + box_0.MaxEdge, BS) + v3s16(1, 1, 1); bool any_position_valid = false; v3s16 p; for (p.X = min.X; p.X <= max.X; p.X++) for (p.Y = min.Y; p.Y <= max.Y; p.Y++) for (p.Z = min.Z; p.Z <= max.Z; p.Z++) { bool is_position_valid; MapNode n = map->getNode(p, &is_position_valid); if (is_position_valid && n.getContent() != CONTENT_IGNORE) { // Object collides into walkable nodes any_position_valid = true; const NodeDefManager *nodedef = gamedef->getNodeDefManager(); const ContentFeatures &f = nodedef->get(n); if (!f.walkable) continue; int n_bouncy_value = itemgroup_get(f.groups, "bouncy"); int neighbors = 0; if (f.drawtype == NDT_NODEBOX && f.node_box.type == NODEBOX_CONNECTED) { v3s16 p2 = p; p2.Y++; getNeighborConnectingFace(p2, nodedef, map, n, 1, &neighbors); p2 = p; p2.Y--; getNeighborConnectingFace(p2, nodedef, map, n, 2, &neighbors); p2 = p; p2.Z--; getNeighborConnectingFace(p2, nodedef, map, n, 4, &neighbors); p2 = p; p2.X--; getNeighborConnectingFace(p2, nodedef, map, n, 8, &neighbors); p2 = p; p2.Z++; getNeighborConnectingFace(p2, nodedef, map, n, 16, &neighbors); p2 = p; p2.X++; getNeighborConnectingFace(p2, nodedef, map, n, 32, &neighbors); } std::vector nodeboxes; n.getCollisionBoxes(gamedef->ndef(), &nodeboxes, neighbors); // Calculate float position only once v3f posf = intToFloat(p, BS); for (auto box : nodeboxes) { box.MinEdge += posf; box.MaxEdge += posf; cinfo.emplace_back(false, false, n_bouncy_value, p, box); } } else { // Collide with unloaded nodes (position invalid) and loaded // CONTENT_IGNORE nodes (position valid) aabb3f box = getNodeBox(p, BS); cinfo.emplace_back(true, false, 0, p, box); } } // Do not move if world has not loaded yet, since custom node boxes // are not available for collision detection. // This also intentionally occurs in the case of the object being positioned // solely on loaded CONTENT_IGNORE nodes, no matter where they come from. if (!any_position_valid) { *speed_f = v3f(0, 0, 0); return result; } } // tt2 if(collideWithObjects) { /* add object boxes to cinfo */ std::vector objects; #ifndef SERVER ClientEnvironment *c_env = dynamic_cast(env); if (c_env != 0) { // Calculate distance by speed, add own extent and 1.5m of tolerance f32 distance = speed_f->getLength() * dtime + box_0.getExtent().getLength() + 1.5f * BS; std::vector clientobjects; c_env->getActiveObjects(*pos_f, distance, clientobjects); for (auto &clientobject : clientobjects) { // Do collide with everything but itself and the parent CAO if (!self || (self != clientobject.obj && self != clientobject.obj->getParent())) { objects.push_back((ActiveObject*) clientobject.obj); } } } else #endif { ServerEnvironment *s_env = dynamic_cast(env); if (s_env != NULL) { // Calculate distance by speed, add own extent and 1.5m of tolerance f32 distance = speed_f->getLength() * dtime + box_0.getExtent().getLength() + 1.5f * BS; // search for objects which are not us, or we are not its parent // we directly use the callback to populate the result to prevent // a useless result loop here auto include_obj_cb = [self, &objects] (ServerActiveObject *obj) { if (!self || (self != obj && self != obj->getParent())) { objects.push_back((ActiveObject *)obj); } return false; }; std::vector s_objects; s_env->getObjectsInsideRadius(s_objects, *pos_f, distance, include_obj_cb); } } for (std::vector::const_iterator iter = objects.begin(); iter != objects.end(); ++iter) { ActiveObject *object = *iter; if (object) { aabb3f object_collisionbox; if (object->getCollisionBox(&object_collisionbox) && object->collideWithObjects()) { cinfo.emplace_back(false, true, 0, v3s16(), object_collisionbox); } } } #ifndef SERVER if (self && c_env) { LocalPlayer *lplayer = c_env->getLocalPlayer(); if (lplayer->getParent() == nullptr) { aabb3f lplayer_collisionbox = lplayer->getCollisionbox(); v3f lplayer_pos = lplayer->getPosition(); lplayer_collisionbox.MinEdge += lplayer_pos; lplayer_collisionbox.MaxEdge += lplayer_pos; cinfo.emplace_back(false, true, 0, v3s16(), lplayer_collisionbox); } } #endif } //tt3 /* Collision detection */ f32 d = 0.0f; int loopcount = 0; while(dtime > BS * 1e-10f) { // Avoid infinite loop loopcount++; if (loopcount >= 100) { warningstream << "collisionMoveSimple: Loop count exceeded, aborting to avoid infiniite loop" << std::endl; break; } aabb3f movingbox = box_0; movingbox.MinEdge += *pos_f; movingbox.MaxEdge += *pos_f; CollisionAxis nearest_collided = COLLISION_AXIS_NONE; f32 nearest_dtime = dtime; int nearest_boxindex = -1; /* Go through every nodebox, find nearest collision */ for (u32 boxindex = 0; boxindex < cinfo.size(); boxindex++) { const NearbyCollisionInfo &box_info = cinfo[boxindex]; // Ignore if already stepped up this nodebox. if (box_info.is_step_up) continue; // Find nearest collision of the two boxes (raytracing-like) f32 dtime_tmp = nearest_dtime; CollisionAxis collided = axisAlignedCollision(box_info.box, movingbox, *speed_f, &dtime_tmp); if (collided == -1 || dtime_tmp >= nearest_dtime) continue; nearest_dtime = dtime_tmp; nearest_collided = collided; nearest_boxindex = boxindex; } if (nearest_collided == COLLISION_AXIS_NONE) { // No collision with any collision box. *pos_f += *speed_f * dtime; dtime = 0; // Set to 0 to avoid "infinite" loop due to small FP numbers } else { // Otherwise, a collision occurred. NearbyCollisionInfo &nearest_info = cinfo[nearest_boxindex]; const aabb3f& cbox = nearest_info.box; //movingbox except moved to the horizontal position it would be after step up aabb3f stepbox = movingbox; stepbox.MinEdge.X += speed_f->X * dtime; stepbox.MinEdge.Z += speed_f->Z * dtime; stepbox.MaxEdge.X += speed_f->X * dtime; stepbox.MaxEdge.Z += speed_f->Z * dtime; // Check for stairs. bool step_up = (nearest_collided != COLLISION_AXIS_Y) && // must not be Y direction (movingbox.MinEdge.Y < cbox.MaxEdge.Y) && (movingbox.MinEdge.Y + stepheight > cbox.MaxEdge.Y) && (!wouldCollideWithCeiling(cinfo, stepbox, cbox.MaxEdge.Y - movingbox.MinEdge.Y, d)); // Get bounce multiplier float bounce = -(float)nearest_info.bouncy / 100.0f; // Move to the point of collision and reduce dtime by nearest_dtime if (nearest_dtime < 0) { // Handle negative nearest_dtime if (!step_up) { if (nearest_collided == COLLISION_AXIS_X) pos_f->X += speed_f->X * nearest_dtime; if (nearest_collided == COLLISION_AXIS_Y) pos_f->Y += speed_f->Y * nearest_dtime; if (nearest_collided == COLLISION_AXIS_Z) pos_f->Z += speed_f->Z * nearest_dtime; } } else { *pos_f += *speed_f * nearest_dtime; dtime -= nearest_dtime; } bool is_collision = true; if (nearest_info.is_unloaded) is_collision = false; CollisionInfo info; if (nearest_info.is_object) info.type = COLLISION_OBJECT; else info.type = COLLISION_NODE; info.node_p = nearest_info.position; info.old_speed = *speed_f; info.plane = nearest_collided; // Set the speed component that caused the collision to zero if (step_up) { // Special case: Handle stairs nearest_info.is_step_up = true; is_collision = false; } else if (nearest_collided == COLLISION_AXIS_X) { if (fabs(speed_f->X) > BS * 3) speed_f->X *= bounce; else speed_f->X = 0; result.collides = true; } else if (nearest_collided == COLLISION_AXIS_Y) { if(fabs(speed_f->Y) > BS * 3) speed_f->Y *= bounce; else speed_f->Y = 0; result.collides = true; } else if (nearest_collided == COLLISION_AXIS_Z) { if (fabs(speed_f->Z) > BS * 3) speed_f->Z *= bounce; else speed_f->Z = 0; result.collides = true; } info.new_speed = *speed_f; if (info.new_speed.getDistanceFrom(info.old_speed) < 0.1f * BS) is_collision = false; if (is_collision) { info.axis = nearest_collided; result.collisions.push_back(info); } } } /* Final touches: Check if standing on ground, step up stairs. */ aabb3f box = box_0; box.MinEdge += *pos_f; box.MaxEdge += *pos_f; for (const auto &box_info : cinfo) { const aabb3f &cbox = box_info.box; /* See if the object is touching ground. Object touches ground if object's minimum Y is near node's maximum Y and object's X-Z-area overlaps with the node's X-Z-area. */ if (cbox.MaxEdge.X - d > box.MinEdge.X && cbox.MinEdge.X + d < box.MaxEdge.X && cbox.MaxEdge.Z - d > box.MinEdge.Z && cbox.MinEdge.Z + d < box.MaxEdge.Z) { if (box_info.is_step_up) { pos_f->Y += cbox.MaxEdge.Y - box.MinEdge.Y; box = box_0; box.MinEdge += *pos_f; box.MaxEdge += *pos_f; } if (std::fabs(cbox.MaxEdge.Y - box.MinEdge.Y) < 0.05f) { result.touching_ground = true; if (box_info.is_object) result.standing_on_object = true; } } } return result; }