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/*************************************************************************/
/* space_sw.cpp */
/*************************************************************************/
/* This file is part of: */
/* GODOT ENGINE */
/* http://www.godotengine.org */
/*************************************************************************/
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/* Copyright (c) 2007-2016 Juan Linietsky, Ariel Manzur. */
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/* */
/* Permission is hereby granted, free of charge, to any person obtaining */
/* a copy of this software and associated documentation files (the */
/* "Software"), to deal in the Software without restriction, including */
/* without limitation the rights to use, copy, modify, merge, publish, */
/* distribute, sublicense, and/or sell copies of the Software, and to */
/* permit persons to whom the Software is furnished to do so, subject to */
/* the following conditions: */
/* */
/* The above copyright notice and this permission notice shall be */
/* included in all copies or substantial portions of the Software. */
/* */
/* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */
/* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */
/* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.*/
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# include "globals.h"
# include "space_sw.h"
# include "collision_solver_sw.h"
# include "physics_server_sw.h"
_FORCE_INLINE_ static bool _match_object_type_query ( CollisionObjectSW * p_object , uint32_t p_layer_mask , uint32_t p_type_mask ) {
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if ( p_object - > get_type ( ) = = CollisionObjectSW : : TYPE_AREA )
return p_type_mask & PhysicsDirectSpaceState : : TYPE_MASK_AREA ;
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if ( ( p_object - > get_layer_mask ( ) & p_layer_mask ) = = 0 )
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return false ;
BodySW * body = static_cast < BodySW * > ( p_object ) ;
return ( 1 < < body - > get_mode ( ) ) & p_type_mask ;
}
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bool PhysicsDirectSpaceStateSW : : intersect_ray ( const Vector3 & p_from , const Vector3 & p_to , RayResult & r_result , const Set < RID > & p_exclude , uint32_t p_layer_mask , uint32_t p_object_type_mask , bool p_pick_ray ) {
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ERR_FAIL_COND_V ( space - > locked , false ) ;
Vector3 begin , end ;
Vector3 normal ;
begin = p_from ;
end = p_to ;
normal = ( end - begin ) . normalized ( ) ;
int amount = space - > broadphase - > cull_segment ( begin , end , space - > intersection_query_results , SpaceSW : : INTERSECTION_QUERY_MAX , space - > intersection_query_subindex_results ) ;
//todo, create another array tha references results, compute AABBs and check closest point to ray origin, sort, and stop evaluating results when beyond first collision
bool collided = false ;
Vector3 res_point , res_normal ;
int res_shape ;
const CollisionObjectSW * res_obj ;
real_t min_d = 1e10 ;
for ( int i = 0 ; i < amount ; i + + ) {
if ( ! _match_object_type_query ( space - > intersection_query_results [ i ] , p_layer_mask , p_object_type_mask ) )
continue ;
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if ( p_pick_ray & & ! ( static_cast < CollisionObjectSW * > ( space - > intersection_query_results [ i ] ) - > is_ray_pickable ( ) ) )
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continue ;
if ( p_exclude . has ( space - > intersection_query_results [ i ] - > get_self ( ) ) )
continue ;
const CollisionObjectSW * col_obj = space - > intersection_query_results [ i ] ;
int shape_idx = space - > intersection_query_subindex_results [ i ] ;
Transform inv_xform = col_obj - > get_shape_inv_transform ( shape_idx ) * col_obj - > get_inv_transform ( ) ;
Vector3 local_from = inv_xform . xform ( begin ) ;
Vector3 local_to = inv_xform . xform ( end ) ;
const ShapeSW * shape = col_obj - > get_shape ( shape_idx ) ;
Vector3 shape_point , shape_normal ;
if ( shape - > intersect_segment ( local_from , local_to , shape_point , shape_normal ) ) {
Transform xform = col_obj - > get_transform ( ) * col_obj - > get_shape_transform ( shape_idx ) ;
shape_point = xform . xform ( shape_point ) ;
real_t ld = normal . dot ( shape_point ) ;
if ( ld < min_d ) {
min_d = ld ;
res_point = shape_point ;
res_normal = inv_xform . basis . xform_inv ( shape_normal ) . normalized ( ) ;
res_shape = shape_idx ;
res_obj = col_obj ;
collided = true ;
}
}
}
if ( ! collided )
return false ;
r_result . collider_id = res_obj - > get_instance_id ( ) ;
if ( r_result . collider_id ! = 0 )
r_result . collider = ObjectDB : : get_instance ( r_result . collider_id ) ;
else
r_result . collider = NULL ;
r_result . normal = res_normal ;
r_result . position = res_point ;
r_result . rid = res_obj - > get_self ( ) ;
r_result . shape = res_shape ;
return true ;
}
int PhysicsDirectSpaceStateSW : : intersect_shape ( const RID & p_shape , const Transform & p_xform , float p_margin , ShapeResult * r_results , int p_result_max , const Set < RID > & p_exclude , uint32_t p_layer_mask , uint32_t p_object_type_mask ) {
if ( p_result_max < = 0 )
return 0 ;
ShapeSW * shape = static_cast < PhysicsServerSW * > ( PhysicsServer : : get_singleton ( ) ) - > shape_owner . get ( p_shape ) ;
ERR_FAIL_COND_V ( ! shape , 0 ) ;
AABB aabb = p_xform . xform ( shape - > get_aabb ( ) ) ;
int amount = space - > broadphase - > cull_aabb ( aabb , space - > intersection_query_results , SpaceSW : : INTERSECTION_QUERY_MAX , space - > intersection_query_subindex_results ) ;
int cc = 0 ;
//Transform ai = p_xform.affine_inverse();
for ( int i = 0 ; i < amount ; i + + ) {
if ( cc > = p_result_max )
break ;
if ( ! _match_object_type_query ( space - > intersection_query_results [ i ] , p_layer_mask , p_object_type_mask ) )
continue ;
//area cant be picked by ray (default)
if ( p_exclude . has ( space - > intersection_query_results [ i ] - > get_self ( ) ) )
continue ;
const CollisionObjectSW * col_obj = space - > intersection_query_results [ i ] ;
int shape_idx = space - > intersection_query_subindex_results [ i ] ;
if ( ! CollisionSolverSW : : solve_static ( shape , p_xform , col_obj - > get_shape ( shape_idx ) , col_obj - > get_transform ( ) * col_obj - > get_shape_transform ( shape_idx ) , NULL , NULL , NULL , p_margin , 0 ) )
continue ;
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if ( r_results ) {
r_results [ cc ] . collider_id = col_obj - > get_instance_id ( ) ;
if ( r_results [ cc ] . collider_id ! = 0 )
r_results [ cc ] . collider = ObjectDB : : get_instance ( r_results [ cc ] . collider_id ) ;
else
r_results [ cc ] . collider = NULL ;
r_results [ cc ] . rid = col_obj - > get_self ( ) ;
r_results [ cc ] . shape = shape_idx ;
}
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cc + + ;
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}
return cc ;
}
bool PhysicsDirectSpaceStateSW : : cast_motion ( const RID & p_shape , const Transform & p_xform , const Vector3 & p_motion , float p_margin , float & p_closest_safe , float & p_closest_unsafe , const Set < RID > & p_exclude , uint32_t p_layer_mask , uint32_t p_object_type_mask , ShapeRestInfo * r_info ) {
ShapeSW * shape = static_cast < PhysicsServerSW * > ( PhysicsServer : : get_singleton ( ) ) - > shape_owner . get ( p_shape ) ;
ERR_FAIL_COND_V ( ! shape , false ) ;
AABB aabb = p_xform . xform ( shape - > get_aabb ( ) ) ;
aabb = aabb . merge ( AABB ( aabb . pos + p_motion , aabb . size ) ) ; //motion
aabb = aabb . grow ( p_margin ) ;
//if (p_motion!=Vector3())
// print_line(p_motion);
int amount = space - > broadphase - > cull_aabb ( aabb , space - > intersection_query_results , SpaceSW : : INTERSECTION_QUERY_MAX , space - > intersection_query_subindex_results ) ;
float best_safe = 1 ;
float best_unsafe = 1 ;
Transform xform_inv = p_xform . affine_inverse ( ) ;
MotionShapeSW mshape ;
mshape . shape = shape ;
mshape . motion = xform_inv . basis . xform ( p_motion ) ;
bool best_first = true ;
Vector3 closest_A , closest_B ;
for ( int i = 0 ; i < amount ; i + + ) {
if ( ! _match_object_type_query ( space - > intersection_query_results [ i ] , p_layer_mask , p_object_type_mask ) )
continue ;
if ( p_exclude . has ( space - > intersection_query_results [ i ] - > get_self ( ) ) )
continue ; //ignore excluded
const CollisionObjectSW * col_obj = space - > intersection_query_results [ i ] ;
int shape_idx = space - > intersection_query_subindex_results [ i ] ;
Vector3 point_A , point_B ;
Vector3 sep_axis = p_motion . normalized ( ) ;
Transform col_obj_xform = col_obj - > get_transform ( ) * col_obj - > get_shape_transform ( shape_idx ) ;
//test initial overlap, does it collide if going all the way?
if ( CollisionSolverSW : : solve_distance ( & mshape , p_xform , col_obj - > get_shape ( shape_idx ) , col_obj_xform , point_A , point_B , aabb , & sep_axis ) ) {
//print_line("failed motion cast (no collision)");
continue ;
}
//test initial overlap
#if 0
if ( CollisionSolverSW : : solve_static ( shape , p_xform , col_obj - > get_shape ( shape_idx ) , col_obj_xform , NULL , NULL , & sep_axis ) ) {
print_line ( " failed initial cast (collision at begining) " ) ;
return false ;
}
# else
sep_axis = p_motion . normalized ( ) ;
if ( ! CollisionSolverSW : : solve_distance ( shape , p_xform , col_obj - > get_shape ( shape_idx ) , col_obj_xform , point_A , point_B , aabb , & sep_axis ) ) {
//print_line("failed motion cast (no collision)");
return false ;
}
# endif
//just do kinematic solving
float low = 0 ;
float hi = 1 ;
Vector3 mnormal = p_motion . normalized ( ) ;
for ( int i = 0 ; i < 8 ; i + + ) { //steps should be customizable..
float ofs = ( low + hi ) * 0.5 ;
Vector3 sep = mnormal ; //important optimization for this to work fast enough
mshape . motion = xform_inv . basis . xform ( p_motion * ofs ) ;
Vector3 lA , lB ;
bool collided = ! CollisionSolverSW : : solve_distance ( & mshape , p_xform , col_obj - > get_shape ( shape_idx ) , col_obj_xform , lA , lB , aabb , & sep ) ;
if ( collided ) {
//print_line(itos(i)+": "+rtos(ofs));
hi = ofs ;
} else {
point_A = lA ;
point_B = lB ;
low = ofs ;
}
}
if ( low < best_safe ) {
best_first = true ; //force reset
best_safe = low ;
best_unsafe = hi ;
}
if ( r_info & & ( best_first | | ( point_A . distance_squared_to ( point_B ) < closest_A . distance_squared_to ( closest_B ) & & low < = best_safe ) ) ) {
closest_A = point_A ;
closest_B = point_B ;
r_info - > collider_id = col_obj - > get_instance_id ( ) ;
r_info - > rid = col_obj - > get_self ( ) ;
r_info - > shape = shape_idx ;
r_info - > point = closest_B ;
r_info - > normal = ( closest_A - closest_B ) . normalized ( ) ;
best_first = false ;
if ( col_obj - > get_type ( ) = = CollisionObjectSW : : TYPE_BODY ) {
const BodySW * body = static_cast < const BodySW * > ( col_obj ) ;
r_info - > linear_velocity = body - > get_linear_velocity ( ) + ( body - > get_angular_velocity ( ) ) . cross ( body - > get_transform ( ) . origin - closest_B ) ;
}
}
}
p_closest_safe = best_safe ;
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p_closest_unsafe = best_unsafe ;
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return true ;
}
bool PhysicsDirectSpaceStateSW : : collide_shape ( RID p_shape , const Transform & p_shape_xform , float p_margin , Vector3 * r_results , int p_result_max , int & r_result_count , const Set < RID > & p_exclude , uint32_t p_layer_mask , uint32_t p_object_type_mask ) {
if ( p_result_max < = 0 )
return 0 ;
ShapeSW * shape = static_cast < PhysicsServerSW * > ( PhysicsServer : : get_singleton ( ) ) - > shape_owner . get ( p_shape ) ;
ERR_FAIL_COND_V ( ! shape , 0 ) ;
AABB aabb = p_shape_xform . xform ( shape - > get_aabb ( ) ) ;
aabb = aabb . grow ( p_margin ) ;
int amount = space - > broadphase - > cull_aabb ( aabb , space - > intersection_query_results , SpaceSW : : INTERSECTION_QUERY_MAX , space - > intersection_query_subindex_results ) ;
bool collided = false ;
r_result_count = 0 ;
PhysicsServerSW : : CollCbkData cbk ;
cbk . max = p_result_max ;
cbk . amount = 0 ;
cbk . ptr = r_results ;
CollisionSolverSW : : CallbackResult cbkres = NULL ;
PhysicsServerSW : : CollCbkData * cbkptr = NULL ;
if ( p_result_max > 0 ) {
cbkptr = & cbk ;
cbkres = PhysicsServerSW : : _shape_col_cbk ;
}
for ( int i = 0 ; i < amount ; i + + ) {
if ( ! _match_object_type_query ( space - > intersection_query_results [ i ] , p_layer_mask , p_object_type_mask ) )
continue ;
const CollisionObjectSW * col_obj = space - > intersection_query_results [ i ] ;
int shape_idx = space - > intersection_query_subindex_results [ i ] ;
if ( p_exclude . has ( col_obj - > get_self ( ) ) ) {
continue ;
}
//print_line("AGAINST: "+itos(col_obj->get_self().get_id())+":"+itos(shape_idx));
//print_line("THE ABBB: "+(col_obj->get_transform() * col_obj->get_shape_transform(shape_idx)).xform(col_obj->get_shape(shape_idx)->get_aabb()));
if ( CollisionSolverSW : : solve_static ( shape , p_shape_xform , col_obj - > get_shape ( shape_idx ) , col_obj - > get_transform ( ) * col_obj - > get_shape_transform ( shape_idx ) , cbkres , cbkptr , NULL , p_margin ) ) {
collided = true ;
}
}
r_result_count = cbk . amount ;
return collided ;
}
struct _RestCallbackData {
const CollisionObjectSW * object ;
const CollisionObjectSW * best_object ;
int shape ;
int best_shape ;
Vector3 best_contact ;
Vector3 best_normal ;
float best_len ;
} ;
static void _rest_cbk_result ( const Vector3 & p_point_A , const Vector3 & p_point_B , void * p_userdata ) {
_RestCallbackData * rd = ( _RestCallbackData * ) p_userdata ;
Vector3 contact_rel = p_point_B - p_point_A ;
float len = contact_rel . length ( ) ;
if ( len < = rd - > best_len )
return ;
rd - > best_len = len ;
rd - > best_contact = p_point_B ;
rd - > best_normal = contact_rel / len ;
rd - > best_object = rd - > object ;
rd - > best_shape = rd - > shape ;
}
bool PhysicsDirectSpaceStateSW : : rest_info ( RID p_shape , const Transform & p_shape_xform , float p_margin , ShapeRestInfo * r_info , const Set < RID > & p_exclude , uint32_t p_layer_mask , uint32_t p_object_type_mask ) {
ShapeSW * shape = static_cast < PhysicsServerSW * > ( PhysicsServer : : get_singleton ( ) ) - > shape_owner . get ( p_shape ) ;
ERR_FAIL_COND_V ( ! shape , 0 ) ;
AABB aabb = p_shape_xform . xform ( shape - > get_aabb ( ) ) ;
aabb = aabb . grow ( p_margin ) ;
int amount = space - > broadphase - > cull_aabb ( aabb , space - > intersection_query_results , SpaceSW : : INTERSECTION_QUERY_MAX , space - > intersection_query_subindex_results ) ;
_RestCallbackData rcd ;
rcd . best_len = 0 ;
rcd . best_object = NULL ;
rcd . best_shape = 0 ;
for ( int i = 0 ; i < amount ; i + + ) {
if ( ! _match_object_type_query ( space - > intersection_query_results [ i ] , p_layer_mask , p_object_type_mask ) )
continue ;
const CollisionObjectSW * col_obj = space - > intersection_query_results [ i ] ;
int shape_idx = space - > intersection_query_subindex_results [ i ] ;
if ( p_exclude . has ( col_obj - > get_self ( ) ) )
continue ;
rcd . object = col_obj ;
rcd . shape = shape_idx ;
bool sc = CollisionSolverSW : : solve_static ( shape , p_shape_xform , col_obj - > get_shape ( shape_idx ) , col_obj - > get_transform ( ) * col_obj - > get_shape_transform ( shape_idx ) , _rest_cbk_result , & rcd , NULL , p_margin ) ;
if ( ! sc )
continue ;
}
if ( rcd . best_len = = 0 )
return false ;
r_info - > collider_id = rcd . best_object - > get_instance_id ( ) ;
r_info - > shape = rcd . best_shape ;
r_info - > normal = rcd . best_normal ;
r_info - > point = rcd . best_contact ;
r_info - > rid = rcd . best_object - > get_self ( ) ;
if ( rcd . best_object - > get_type ( ) = = CollisionObjectSW : : TYPE_BODY ) {
const BodySW * body = static_cast < const BodySW * > ( rcd . best_object ) ;
r_info - > linear_velocity = body - > get_linear_velocity ( ) +
( body - > get_angular_velocity ( ) ) . cross ( body - > get_transform ( ) . origin - rcd . best_contact ) ; // * mPos);
} else {
r_info - > linear_velocity = Vector3 ( ) ;
}
return true ;
}
PhysicsDirectSpaceStateSW : : PhysicsDirectSpaceStateSW ( ) {
space = NULL ;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////
void * SpaceSW : : _broadphase_pair ( CollisionObjectSW * A , int p_subindex_A , CollisionObjectSW * B , int p_subindex_B , void * p_self ) {
CollisionObjectSW : : Type type_A = A - > get_type ( ) ;
CollisionObjectSW : : Type type_B = B - > get_type ( ) ;
if ( type_A > type_B ) {
SWAP ( A , B ) ;
SWAP ( p_subindex_A , p_subindex_B ) ;
SWAP ( type_A , type_B ) ;
}
SpaceSW * self = ( SpaceSW * ) p_self ;
self - > collision_pairs + + ;
if ( type_A = = CollisionObjectSW : : TYPE_AREA ) {
AreaSW * area = static_cast < AreaSW * > ( A ) ;
if ( type_B = = CollisionObjectSW : : TYPE_AREA ) {
AreaSW * area_b = static_cast < AreaSW * > ( B ) ;
Area2PairSW * area2_pair = memnew ( Area2PairSW ( area_b , p_subindex_B , area , p_subindex_A ) ) ;
return area2_pair ;
} else {
BodySW * body = static_cast < BodySW * > ( B ) ;
AreaPairSW * area_pair = memnew ( AreaPairSW ( body , p_subindex_B , area , p_subindex_A ) ) ;
return area_pair ;
}
} else {
BodyPairSW * b = memnew ( BodyPairSW ( ( BodySW * ) A , p_subindex_A , ( BodySW * ) B , p_subindex_B ) ) ;
return b ;
}
return NULL ;
}
void SpaceSW : : _broadphase_unpair ( CollisionObjectSW * A , int p_subindex_A , CollisionObjectSW * B , int p_subindex_B , void * p_data , void * p_self ) {
SpaceSW * self = ( SpaceSW * ) p_self ;
self - > collision_pairs - - ;
ConstraintSW * c = ( ConstraintSW * ) p_data ;
memdelete ( c ) ;
}
const SelfList < BodySW > : : List & SpaceSW : : get_active_body_list ( ) const {
return active_list ;
}
void SpaceSW : : body_add_to_active_list ( SelfList < BodySW > * p_body ) {
active_list . add ( p_body ) ;
}
void SpaceSW : : body_remove_from_active_list ( SelfList < BodySW > * p_body ) {
active_list . remove ( p_body ) ;
}
void SpaceSW : : body_add_to_inertia_update_list ( SelfList < BodySW > * p_body ) {
inertia_update_list . add ( p_body ) ;
}
void SpaceSW : : body_remove_from_inertia_update_list ( SelfList < BodySW > * p_body ) {
inertia_update_list . remove ( p_body ) ;
}
BroadPhaseSW * SpaceSW : : get_broadphase ( ) {
return broadphase ;
}
void SpaceSW : : add_object ( CollisionObjectSW * p_object ) {
ERR_FAIL_COND ( objects . has ( p_object ) ) ;
objects . insert ( p_object ) ;
}
void SpaceSW : : remove_object ( CollisionObjectSW * p_object ) {
ERR_FAIL_COND ( ! objects . has ( p_object ) ) ;
objects . erase ( p_object ) ;
}
const Set < CollisionObjectSW * > & SpaceSW : : get_objects ( ) const {
return objects ;
}
void SpaceSW : : body_add_to_state_query_list ( SelfList < BodySW > * p_body ) {
state_query_list . add ( p_body ) ;
}
void SpaceSW : : body_remove_from_state_query_list ( SelfList < BodySW > * p_body ) {
state_query_list . remove ( p_body ) ;
}
void SpaceSW : : area_add_to_monitor_query_list ( SelfList < AreaSW > * p_area ) {
monitor_query_list . add ( p_area ) ;
}
void SpaceSW : : area_remove_from_monitor_query_list ( SelfList < AreaSW > * p_area ) {
monitor_query_list . remove ( p_area ) ;
}
void SpaceSW : : area_add_to_moved_list ( SelfList < AreaSW > * p_area ) {
area_moved_list . add ( p_area ) ;
}
void SpaceSW : : area_remove_from_moved_list ( SelfList < AreaSW > * p_area ) {
area_moved_list . remove ( p_area ) ;
}
const SelfList < AreaSW > : : List & SpaceSW : : get_moved_area_list ( ) const {
return area_moved_list ;
}
void SpaceSW : : call_queries ( ) {
while ( state_query_list . first ( ) ) {
BodySW * b = state_query_list . first ( ) - > self ( ) ;
b - > call_queries ( ) ;
state_query_list . remove ( state_query_list . first ( ) ) ;
}
while ( monitor_query_list . first ( ) ) {
AreaSW * a = monitor_query_list . first ( ) - > self ( ) ;
a - > call_queries ( ) ;
monitor_query_list . remove ( monitor_query_list . first ( ) ) ;
}
}
void SpaceSW : : setup ( ) {
contact_debug_count = 0 ;
while ( inertia_update_list . first ( ) ) {
inertia_update_list . first ( ) - > self ( ) - > update_inertias ( ) ;
inertia_update_list . remove ( inertia_update_list . first ( ) ) ;
}
}
void SpaceSW : : update ( ) {
broadphase - > update ( ) ;
}
void SpaceSW : : set_param ( PhysicsServer : : SpaceParameter p_param , real_t p_value ) {
switch ( p_param ) {
case PhysicsServer : : SPACE_PARAM_CONTACT_RECYCLE_RADIUS : contact_recycle_radius = p_value ; break ;
case PhysicsServer : : SPACE_PARAM_CONTACT_MAX_SEPARATION : contact_max_separation = p_value ; break ;
case PhysicsServer : : SPACE_PARAM_BODY_MAX_ALLOWED_PENETRATION : contact_max_allowed_penetration = p_value ; break ;
case PhysicsServer : : SPACE_PARAM_BODY_LINEAR_VELOCITY_SLEEP_TRESHOLD : body_linear_velocity_sleep_threshold = p_value ; break ;
case PhysicsServer : : SPACE_PARAM_BODY_ANGULAR_VELOCITY_SLEEP_TRESHOLD : body_angular_velocity_sleep_threshold = p_value ; break ;
case PhysicsServer : : SPACE_PARAM_BODY_TIME_TO_SLEEP : body_time_to_sleep = p_value ; break ;
case PhysicsServer : : SPACE_PARAM_BODY_ANGULAR_VELOCITY_DAMP_RATIO : body_angular_velocity_damp_ratio = p_value ; break ;
case PhysicsServer : : SPACE_PARAM_CONSTRAINT_DEFAULT_BIAS : constraint_bias = p_value ; break ;
}
}
real_t SpaceSW : : get_param ( PhysicsServer : : SpaceParameter p_param ) const {
switch ( p_param ) {
case PhysicsServer : : SPACE_PARAM_CONTACT_RECYCLE_RADIUS : return contact_recycle_radius ;
case PhysicsServer : : SPACE_PARAM_CONTACT_MAX_SEPARATION : return contact_max_separation ;
case PhysicsServer : : SPACE_PARAM_BODY_MAX_ALLOWED_PENETRATION : return contact_max_allowed_penetration ;
case PhysicsServer : : SPACE_PARAM_BODY_LINEAR_VELOCITY_SLEEP_TRESHOLD : return body_linear_velocity_sleep_threshold ;
case PhysicsServer : : SPACE_PARAM_BODY_ANGULAR_VELOCITY_SLEEP_TRESHOLD : return body_angular_velocity_sleep_threshold ;
case PhysicsServer : : SPACE_PARAM_BODY_TIME_TO_SLEEP : return body_time_to_sleep ;
case PhysicsServer : : SPACE_PARAM_BODY_ANGULAR_VELOCITY_DAMP_RATIO : return body_angular_velocity_damp_ratio ;
case PhysicsServer : : SPACE_PARAM_CONSTRAINT_DEFAULT_BIAS : return constraint_bias ;
}
return 0 ;
}
void SpaceSW : : lock ( ) {
locked = true ;
}
void SpaceSW : : unlock ( ) {
locked = false ;
}
bool SpaceSW : : is_locked ( ) const {
return locked ;
}
PhysicsDirectSpaceStateSW * SpaceSW : : get_direct_state ( ) {
return direct_access ;
}
SpaceSW : : SpaceSW ( ) {
collision_pairs = 0 ;
active_objects = 0 ;
island_count = 0 ;
contact_debug_count = 0 ;
locked = false ;
contact_recycle_radius = 0.01 ;
contact_max_separation = 0.05 ;
contact_max_allowed_penetration = 0.01 ;
constraint_bias = 0.01 ;
body_linear_velocity_sleep_threshold = GLOBAL_DEF ( " physics/sleep_threshold_linear " , 0.1 ) ;
body_angular_velocity_sleep_threshold = GLOBAL_DEF ( " physics/sleep_threshold_angular " , ( 8.0 / 180.0 * Math_PI ) ) ;
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body_time_to_sleep = GLOBAL_DEF ( " physics/time_before_sleep " , 0.5 ) ;
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body_angular_velocity_damp_ratio = 10 ;
broadphase = BroadPhaseSW : : create_func ( ) ;
broadphase - > set_pair_callback ( _broadphase_pair , this ) ;
broadphase - > set_unpair_callback ( _broadphase_unpair , this ) ;
area = NULL ;
direct_access = memnew ( PhysicsDirectSpaceStateSW ) ;
direct_access - > space = this ;
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for ( int i = 0 ; i < ELAPSED_TIME_MAX ; i + + )
elapsed_time [ i ] = 0 ;
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}
SpaceSW : : ~ SpaceSW ( ) {
memdelete ( broadphase ) ;
memdelete ( direct_access ) ;
}