/*
-Minetest-c55
-Copyright (C) 2010 celeron55, Perttu Ahola <celeron55@gmail.com>
+Minetest
+Copyright (C) 2013 celeron55, Perttu Ahola <celeron55@gmail.com>
This program is free software; you can redistribute it and/or modify
-it under the terms of the GNU General Public License as published by
-the Free Software Foundation; either version 2 of the License, or
+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 General Public License for more details.
+GNU Lesser General Public License for more details.
-You should have received a copy of the GNU General Public License along
+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 "mapblock.h"
#include "map.h"
+#include "nodedef.h"
+#include "gamedef.h"
+#include "log.h"
+#include "environment.h"
+#include "serverobject.h"
+#include <vector>
+#include <set>
+#include "util/timetaker.h"
+#include "profiler.h"
-collisionMoveResult collisionMoveSimple(Map *map, f32 pos_max_d,
- const core::aabbox3d<f32> &box_0,
- f32 dtime, v3f &pos_f, v3f &speed_f)
+// float error is 10 - 9.96875 = 0.03125
+//#define COLL_ZERO 0.032 // broken unit tests
+#define COLL_ZERO 0
+
+// 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.
+int axisAlignedCollision(
+ const aabb3f &staticbox, const aabb3f &movingbox,
+ const v3f &speed, f32 d, f32 *dtime)
{
+ //TimeTaker tt("axisAlignedCollision");
+
+ f32 xsize = (staticbox.MaxEdge.X - staticbox.MinEdge.X) - COLL_ZERO; // reduce box size for solve collision stuck (flying sand)
+ f32 ysize = (staticbox.MaxEdge.Y - staticbox.MinEdge.Y); // - COLL_ZERO; // Y - no sense for falling, but maybe try later
+ f32 zsize = (staticbox.MaxEdge.Z - staticbox.MinEdge.Z) - COLL_ZERO;
+
+ aabb3f relbox(
+ movingbox.MinEdge.X - staticbox.MinEdge.X,
+ movingbox.MinEdge.Y - staticbox.MinEdge.Y,
+ movingbox.MinEdge.Z - staticbox.MinEdge.Z,
+ movingbox.MaxEdge.X - staticbox.MinEdge.X,
+ movingbox.MaxEdge.Y - staticbox.MinEdge.Y,
+ movingbox.MaxEdge.Z - staticbox.MinEdge.Z
+ );
+
+ if(speed.X > 0) // Check for collision with X- plane
+ {
+ if (relbox.MaxEdge.X <= d) {
+ *dtime = -relbox.MaxEdge.X / speed.X;
+ if ((relbox.MinEdge.Y + speed.Y * (*dtime) < ysize) &&
+ (relbox.MaxEdge.Y + speed.Y * (*dtime) > COLL_ZERO) &&
+ (relbox.MinEdge.Z + speed.Z * (*dtime) < zsize) &&
+ (relbox.MaxEdge.Z + speed.Z * (*dtime) > COLL_ZERO))
+ return 0;
+ }
+ else if(relbox.MinEdge.X > xsize)
+ {
+ return -1;
+ }
+ }
+ else if(speed.X < 0) // Check for collision with X+ plane
+ {
+ if (relbox.MinEdge.X >= xsize - d) {
+ *dtime = (xsize - relbox.MinEdge.X) / speed.X;
+ if ((relbox.MinEdge.Y + speed.Y * (*dtime) < ysize) &&
+ (relbox.MaxEdge.Y + speed.Y * (*dtime) > COLL_ZERO) &&
+ (relbox.MinEdge.Z + speed.Z * (*dtime) < zsize) &&
+ (relbox.MaxEdge.Z + speed.Z * (*dtime) > COLL_ZERO))
+ return 0;
+ }
+ else if(relbox.MaxEdge.X < 0)
+ {
+ return -1;
+ }
+ }
+
+ // NO else if here
+
+ if(speed.Y > 0) // Check for collision with Y- plane
+ {
+ if (relbox.MaxEdge.Y <= d) {
+ *dtime = -relbox.MaxEdge.Y / speed.Y;
+ if ((relbox.MinEdge.X + speed.X * (*dtime) < xsize) &&
+ (relbox.MaxEdge.X + speed.X * (*dtime) > COLL_ZERO) &&
+ (relbox.MinEdge.Z + speed.Z * (*dtime) < zsize) &&
+ (relbox.MaxEdge.Z + speed.Z * (*dtime) > COLL_ZERO))
+ return 1;
+ }
+ else if(relbox.MinEdge.Y > ysize)
+ {
+ return -1;
+ }
+ }
+ else if(speed.Y < 0) // Check for collision with Y+ plane
+ {
+ if (relbox.MinEdge.Y >= ysize - d) {
+ *dtime = (ysize - relbox.MinEdge.Y) / speed.Y;
+ if ((relbox.MinEdge.X + speed.X * (*dtime) < xsize) &&
+ (relbox.MaxEdge.X + speed.X * (*dtime) > COLL_ZERO) &&
+ (relbox.MinEdge.Z + speed.Z * (*dtime) < zsize) &&
+ (relbox.MaxEdge.Z + speed.Z * (*dtime) > COLL_ZERO))
+ return 1;
+ }
+ else if(relbox.MaxEdge.Y < 0)
+ {
+ return -1;
+ }
+ }
+
+ // NO else if here
+
+ if(speed.Z > 0) // Check for collision with Z- plane
+ {
+ if (relbox.MaxEdge.Z <= d) {
+ *dtime = -relbox.MaxEdge.Z / speed.Z;
+ if ((relbox.MinEdge.X + speed.X * (*dtime) < xsize) &&
+ (relbox.MaxEdge.X + speed.X * (*dtime) > COLL_ZERO) &&
+ (relbox.MinEdge.Y + speed.Y * (*dtime) < ysize) &&
+ (relbox.MaxEdge.Y + speed.Y * (*dtime) > COLL_ZERO))
+ return 2;
+ }
+ //else if(relbox.MinEdge.Z > zsize)
+ //{
+ // return -1;
+ //}
+ }
+ else if(speed.Z < 0) // Check for collision with Z+ plane
+ {
+ if (relbox.MinEdge.Z >= zsize - d) {
+ *dtime = (zsize - relbox.MinEdge.Z) / speed.Z;
+ if ((relbox.MinEdge.X + speed.X * (*dtime) < xsize) &&
+ (relbox.MaxEdge.X + speed.X * (*dtime) > COLL_ZERO) &&
+ (relbox.MinEdge.Y + speed.Y * (*dtime) < ysize) &&
+ (relbox.MaxEdge.Y + speed.Y * (*dtime) > COLL_ZERO))
+ return 2;
+ }
+ //else if(relbox.MaxEdge.Z < 0)
+ //{
+ // return -1;
+ //}
+ }
+
+ return -1;
+}
+
+// Helper function:
+// Checks if moving the movingbox up by the given distance would hit a ceiling.
+bool wouldCollideWithCeiling(
+ const std::vector<aabb3f> &staticboxes,
+ const aabb3f &movingbox,
+ f32 y_increase, f32 d)
+{
+ //TimeTaker tt("wouldCollideWithCeiling");
+
+ assert(y_increase >= 0); // pre-condition
+
+ for(std::vector<aabb3f>::const_iterator
+ i = staticboxes.begin();
+ i != staticboxes.end(); ++i)
+ {
+ const aabb3f& staticbox = *i;
+ 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;
+}
+
+
+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();
+ //TimeTaker tt("collisionMoveSimple");
+ ScopeProfiler sp(g_profiler, "collisionMoveSimple avg", SPT_AVG);
+
collisionMoveResult result;
- v3f oldpos_f = pos_f;
- v3s16 oldpos_i = floatToInt(oldpos_f, BS);
+ /*
+ Calculate new velocity
+ */
+ if (dtime > 0.5) {
+ if (!time_notification_done) {
+ time_notification_done = true;
+ infostream << "collisionMoveSimple: maximum step interval exceeded,"
+ " lost movement details!"<<std::endl;
+ }
+ dtime = 0.5;
+ } else {
+ time_notification_done = false;
+ }
+ *speed_f += accel_f * dtime;
+
+ // If there is no speed, there are no collisions
+ if (speed_f->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);
/*
- Calculate new position
+ Collect node boxes in movement range
*/
- pos_f += speed_f * dtime;
+ std::vector<aabb3f> cboxes;
+ std::vector<bool> is_unloaded;
+ std::vector<bool> is_step_up;
+ std::vector<bool> is_object;
+ std::vector<int> bouncy_values;
+ std::vector<v3s16> node_positions;
+ {
+ //TimeTaker tt2("collisionMoveSimple collect boxes");
+ ScopeProfiler sp(g_profiler, "collisionMoveSimple collect boxes avg", SPT_AVG);
+
+ v3s16 oldpos_i = floatToInt(*pos_f, BS);
+ v3s16 newpos_i = floatToInt(*pos_f + *speed_f * dtime, BS);
+ s16 min_x = MYMIN(oldpos_i.X, newpos_i.X) + (box_0.MinEdge.X / BS) - 1;
+ s16 min_y = MYMIN(oldpos_i.Y, newpos_i.Y) + (box_0.MinEdge.Y / BS) - 1;
+ s16 min_z = MYMIN(oldpos_i.Z, newpos_i.Z) + (box_0.MinEdge.Z / BS) - 1;
+ s16 max_x = MYMAX(oldpos_i.X, newpos_i.X) + (box_0.MaxEdge.X / BS) + 1;
+ s16 max_y = MYMAX(oldpos_i.Y, newpos_i.Y) + (box_0.MaxEdge.Y / BS) + 1;
+ s16 max_z = MYMAX(oldpos_i.Z, newpos_i.Z) + (box_0.MaxEdge.Z / BS) + 1;
+
+ bool any_position_valid = false;
+
+ // The order is important here, must be y first
+ for(s16 y = max_y; y >= min_y; y--)
+ for(s16 x = min_x; x <= max_x; x++)
+ for(s16 z = min_z; z <= max_z; z++)
+ {
+ v3s16 p(x,y,z);
+
+ bool is_position_valid;
+ MapNode n = map->getNodeNoEx(p, &is_position_valid);
+
+ if (is_position_valid) {
+ // Object collides into walkable nodes
+
+ any_position_valid = true;
+ const ContentFeatures &f = gamedef->getNodeDefManager()->get(n);
+ if(f.walkable == false)
+ continue;
+ int n_bouncy_value = itemgroup_get(f.groups, "bouncy");
+
+ std::vector<aabb3f> nodeboxes = n.getCollisionBoxes(gamedef->ndef());
+ for(std::vector<aabb3f>::iterator
+ i = nodeboxes.begin();
+ i != nodeboxes.end(); ++i)
+ {
+ aabb3f box = *i;
+ box.MinEdge += v3f(x, y, z)*BS;
+ box.MaxEdge += v3f(x, y, z)*BS;
+ cboxes.push_back(box);
+ is_unloaded.push_back(false);
+ is_step_up.push_back(false);
+ bouncy_values.push_back(n_bouncy_value);
+ node_positions.push_back(p);
+ is_object.push_back(false);
+ }
+ }
+ else {
+ // Collide with unloaded nodes
+ aabb3f box = getNodeBox(p, BS);
+ cboxes.push_back(box);
+ is_unloaded.push_back(true);
+ is_step_up.push_back(false);
+ bouncy_values.push_back(0);
+ node_positions.push_back(p);
+ is_object.push_back(false);
+ }
+ }
+
+ // Do not move if world has not loaded yet, since custom node boxes
+ // are not available for collision detection.
+ if (!any_position_valid)
+ return result;
+
+ } // tt2
+
+ if(collideWithObjects)
+ {
+ ScopeProfiler sp(g_profiler, "collisionMoveSimple objects avg", SPT_AVG);
+ //TimeTaker tt3("collisionMoveSimple collect object boxes");
+
+ /* add object boxes to cboxes */
+
+ std::vector<ActiveObject*> objects;
+#ifndef SERVER
+ ClientEnvironment *c_env = dynamic_cast<ClientEnvironment*>(env);
+ if (c_env != 0) {
+ f32 distance = speed_f->getLength();
+ std::vector<DistanceSortedActiveObject> clientobjects;
+ c_env->getActiveObjects(*pos_f, distance * 1.5, clientobjects);
+ for (size_t i=0; i < clientobjects.size(); i++) {
+ if ((self == 0) || (self != clientobjects[i].obj)) {
+ objects.push_back((ActiveObject*)clientobjects[i].obj);
+ }
+ }
+ }
+ else
+#endif
+ {
+ ServerEnvironment *s_env = dynamic_cast<ServerEnvironment*>(env);
+ if (s_env != 0) {
+ f32 distance = speed_f->getLength();
+ std::vector<u16> s_objects;
+ s_env->getObjectsInsideRadius(s_objects, *pos_f, distance * 1.5);
+ for (std::vector<u16>::iterator iter = s_objects.begin(); iter != s_objects.end(); ++iter) {
+ ServerActiveObject *current = s_env->getActiveObject(*iter);
+ if ((self == 0) || (self != current)) {
+ objects.push_back((ActiveObject*)current);
+ }
+ }
+ }
+ }
+
+ for (std::vector<ActiveObject*>::const_iterator iter = objects.begin();
+ iter != objects.end(); ++iter) {
+ ActiveObject *object = *iter;
+
+ if (object != NULL) {
+ aabb3f object_collisionbox;
+ if (object->getCollisionBox(&object_collisionbox) &&
+ object->collideWithObjects()) {
+ cboxes.push_back(object_collisionbox);
+ is_unloaded.push_back(false);
+ is_step_up.push_back(false);
+ bouncy_values.push_back(0);
+ node_positions.push_back(v3s16(0,0,0));
+ is_object.push_back(true);
+ }
+ }
+ }
+ } //tt3
+
+ assert(cboxes.size() == is_unloaded.size()); // post-condition
+ assert(cboxes.size() == is_step_up.size()); // post-condition
+ assert(cboxes.size() == bouncy_values.size()); // post-condition
+ assert(cboxes.size() == node_positions.size()); // post-condition
+ assert(cboxes.size() == is_object.size()); // post-condition
/*
Collision detection
*/
-
- // position in nodes
- v3s16 pos_i = floatToInt(pos_f, BS);
-
+
/*
Collision uncertainty radius
Make it a bit larger than the maximum distance of movement
//f32 d = 0.15*BS;
// This should always apply, otherwise there are glitches
- assert(d > pos_max_d);
-
- /*
- Calculate collision box
- */
- core::aabbox3d<f32> box = box_0;
- box.MaxEdge += pos_f;
- box.MinEdge += pos_f;
- core::aabbox3d<f32> oldbox = box_0;
- oldbox.MaxEdge += oldpos_f;
- oldbox.MinEdge += oldpos_f;
+ assert(d > pos_max_d); // invariant
- /*
- If the object lies on a walkable node, this is set to true.
- */
- result.touching_ground = false;
-
- /*
- Go through every node around the object
- TODO: Calculate the range of nodes that need to be checked
- */
- for(s16 y = oldpos_i.Y - 1; y <= oldpos_i.Y + 2; y++)
- for(s16 z = oldpos_i.Z - 1; z <= oldpos_i.Z + 1; z++)
- for(s16 x = oldpos_i.X - 1; x <= oldpos_i.X + 1; x++)
- {
- try{
- // Object collides into walkable nodes
- if(content_walkable(map->getNode(v3s16(x,y,z)).d) == false)
- continue;
- }
- catch(InvalidPositionException &e)
- {
- // Doing nothing here will block the object from
- // walking over map borders
+ int loopcount = 0;
+
+ while(dtime > BS * 1e-10) {
+ //TimeTaker tt3("collisionMoveSimple dtime loop");
+ ScopeProfiler sp(g_profiler, "collisionMoveSimple dtime loop avg", SPT_AVG);
+
+ // Avoid infinite loop
+ loopcount++;
+ if (loopcount >= 100) {
+ warningstream << "collisionMoveSimple: Loop count exceeded, aborting to avoid infiniite loop" << std::endl;
+ break;
}
- core::aabbox3d<f32> nodebox = getNodeBox(v3s16(x,y,z), BS);
-
- /*
- See if the object is touching ground.
+ aabb3f movingbox = box_0;
+ movingbox.MinEdge += *pos_f;
+ movingbox.MaxEdge += *pos_f;
- 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.
+ int nearest_collided = -1;
+ f32 nearest_dtime = dtime;
+ int nearest_boxindex = -1;
- Use 0.15*BS so that it is easier to get on a node.
- */
- if(
- //fabs(nodebox.MaxEdge.Y-box.MinEdge.Y) < d
- fabs(nodebox.MaxEdge.Y-box.MinEdge.Y) < 0.15*BS
- && nodebox.MaxEdge.X-d > box.MinEdge.X
- && nodebox.MinEdge.X+d < box.MaxEdge.X
- && nodebox.MaxEdge.Z-d > box.MinEdge.Z
- && nodebox.MinEdge.Z+d < box.MaxEdge.Z
- ){
- result.touching_ground = true;
- }
-
- // If object doesn't intersect with node, ignore node.
- if(box.intersectsWithBox(nodebox) == false)
- continue;
-
/*
- Go through every axis
+ Go through every nodebox, find nearest collision
*/
- v3f dirs[3] = {
- v3f(0,0,1), // back-front
- v3f(0,1,0), // top-bottom
- v3f(1,0,0), // right-left
- };
- for(u16 i=0; i<3; i++)
- {
- /*
- Calculate values along the axis
- */
- f32 nodemax = nodebox.MaxEdge.dotProduct(dirs[i]);
- f32 nodemin = nodebox.MinEdge.dotProduct(dirs[i]);
- f32 objectmax = box.MaxEdge.dotProduct(dirs[i]);
- f32 objectmin = box.MinEdge.dotProduct(dirs[i]);
- f32 objectmax_old = oldbox.MaxEdge.dotProduct(dirs[i]);
- f32 objectmin_old = oldbox.MinEdge.dotProduct(dirs[i]);
-
- /*
- Check collision for the axis.
- Collision happens when object is going through a surface.
- */
- bool negative_axis_collides =
- (nodemax > objectmin && nodemax <= objectmin_old + d
- && speed_f.dotProduct(dirs[i]) < 0);
- bool positive_axis_collides =
- (nodemin < objectmax && nodemin >= objectmax_old - d
- && speed_f.dotProduct(dirs[i]) > 0);
- bool main_axis_collides =
- negative_axis_collides || positive_axis_collides;
-
- /*
- Check overlap of object and node in other axes
- */
- bool other_axes_overlap = true;
- for(u16 j=0; j<3; j++)
- {
- if(j == i)
- continue;
- f32 nodemax = nodebox.MaxEdge.dotProduct(dirs[j]);
- f32 nodemin = nodebox.MinEdge.dotProduct(dirs[j]);
- f32 objectmax = box.MaxEdge.dotProduct(dirs[j]);
- f32 objectmin = box.MinEdge.dotProduct(dirs[j]);
- if(!(nodemax - d > objectmin && nodemin + d < objectmax))
- {
- other_axes_overlap = false;
- break;
+ for (u32 boxindex = 0; boxindex < cboxes.size(); boxindex++) {
+ // Find nearest collision of the two boxes (raytracing-like)
+ f32 dtime_tmp;
+ int collided = axisAlignedCollision(
+ cboxes[boxindex], movingbox, *speed_f, d, &dtime_tmp);
+
+ // Ignore if already stepped up this nodebox.
+ if (is_step_up[boxindex]) {
+ pos_f->Y += (cboxes[boxindex].MaxEdge.Y - movingbox.MinEdge.Y);
+ continue;
+ }
+
+ if (collided == -1 || dtime_tmp >= nearest_dtime)
+ continue;
+
+ nearest_dtime = dtime_tmp;
+ nearest_collided = collided;
+ nearest_boxindex = boxindex;
+ }
+
+ if (nearest_collided == -1) {
+ // 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.
+
+ const aabb3f& cbox = cboxes[nearest_boxindex];
+ // Check for stairs.
+ bool step_up = (nearest_collided != 1) && // must not be Y direction
+ (movingbox.MinEdge.Y < cbox.MaxEdge.Y) &&
+ (movingbox.MinEdge.Y + stepheight > cbox.MaxEdge.Y) &&
+ (!wouldCollideWithCeiling(cboxes, movingbox,
+ cbox.MaxEdge.Y - movingbox.MinEdge.Y,
+ d));
+
+ // Get bounce multiplier
+ bool bouncy = (bouncy_values[nearest_boxindex] >= 1);
+ float bounce = -(float)bouncy_values[nearest_boxindex] / 100.0;
+
+ // Move to the point of collision and reduce dtime by nearest_dtime
+ if (nearest_dtime < 0) {
+ // Handle negative nearest_dtime (can be caused by the d allowance)
+ if (!step_up) {
+ if (nearest_collided == 0)
+ pos_f->X += speed_f->X * nearest_dtime;
+ if (nearest_collided == 1)
+ pos_f->Y += speed_f->Y * nearest_dtime;
+ if (nearest_collided == 2)
+ pos_f->Z += speed_f->Z * nearest_dtime;
}
+ } else {
+ *pos_f += *speed_f * nearest_dtime;
+ dtime -= nearest_dtime;
}
-
- /*
- If this is a collision, revert the pos_f in the main
- direction.
- */
- if(other_axes_overlap && main_axis_collides)
- {
- speed_f -= speed_f.dotProduct(dirs[i]) * dirs[i];
- pos_f -= pos_f.dotProduct(dirs[i]) * dirs[i];
- pos_f += oldpos_f.dotProduct(dirs[i]) * dirs[i];
+
+ bool is_collision = true;
+ if (is_unloaded[nearest_boxindex])
+ is_collision = false;
+
+ CollisionInfo info;
+ if (is_object[nearest_boxindex]) {
+ info.type = COLLISION_OBJECT;
+ result.standing_on_object = true;
+ } else {
+ info.type = COLLISION_NODE;
+ }
+
+ info.node_p = node_positions[nearest_boxindex];
+ info.bouncy = bouncy;
+ info.old_speed = *speed_f;
+
+ // Set the speed component that caused the collision to zero
+ if (step_up) {
+ // Special case: Handle stairs
+ is_step_up[nearest_boxindex] = true;
+ is_collision = false;
+ } else if(nearest_collided == 0) { // X
+ if (fabs(speed_f->X) > BS * 3)
+ speed_f->X *= bounce;
+ else
+ speed_f->X = 0;
+ result.collides = true;
+ result.collides_xz = true;
+ } else if(nearest_collided == 1) { // Y
+ if (fabs(speed_f->Y) > BS * 3) {
+ speed_f->Y *= bounce;
+ } else {
+ speed_f->Y = 0;
+ result.touching_ground = true;
+ }
+ result.collides = true;
+ } else if(nearest_collided == 2) { // Z
+ if (fabs(speed_f->Z) > BS * 3)
+ speed_f->Z *= bounce;
+ else
+ speed_f->Z = 0;
+ result.collides = true;
+ result.collides_xz = true;
+ }
+
+ info.new_speed = *speed_f;
+ if (info.new_speed.getDistanceFrom(info.old_speed) < 0.1 * BS)
+ is_collision = false;
+
+ if (is_collision) {
+ result.collisions.push_back(info);
}
-
}
- } // xyz
-
+ }
+
return result;
}
-
-