godot/servers/physics/body_sw.cpp
Rémi Verschelde 93ab45b6b5 Style: Fix whole-line commented code
They do not play well with clang-format which aligns the `//` part
with the rest of the code block, thus producing badly indented commented code.
2017-01-14 14:52:23 +01:00

826 lines
20 KiB
C++

/*************************************************************************/
/* body_sw.cpp */
/*************************************************************************/
/* This file is part of: */
/* GODOT ENGINE */
/* http://www.godotengine.org */
/*************************************************************************/
/* Copyright (c) 2007-2017 Juan Linietsky, Ariel Manzur. */
/* */
/* 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.*/
/* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */
/* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */
/* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */
/* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */
/*************************************************************************/
#include "body_sw.h"
#include "space_sw.h"
#include "area_sw.h"
void BodySW::_update_inertia() {
if (get_space() && !inertia_update_list.in_list())
get_space()->body_add_to_inertia_update_list(&inertia_update_list);
}
void BodySW::_update_transform_dependant() {
center_of_mass = get_transform().basis.xform(center_of_mass_local);
principal_inertia_axes = get_transform().basis * principal_inertia_axes_local;
// update inertia tensor
Basis tb = principal_inertia_axes;
Basis tbt = tb.transposed();
tb.scale(_inv_inertia);
_inv_inertia_tensor = tb * tbt;
}
void BodySW::update_inertias() {
//update shapes and motions
switch(mode) {
case PhysicsServer::BODY_MODE_RIGID: {
//update tensor for all shapes, not the best way but should be somehow OK. (inspired from bullet)
float total_area=0;
for (int i=0;i<get_shape_count();i++) {
total_area+=get_shape_area(i);
}
// We have to recompute the center of mass
center_of_mass_local.zero();
for (int i=0; i<get_shape_count(); i++) {
float area=get_shape_area(i);
float mass = area * this->mass / total_area;
// NOTE: we assume that the shape origin is also its center of mass
center_of_mass_local += mass * get_shape_transform(i).origin;
}
center_of_mass_local /= mass;
// Recompute the inertia tensor
Basis inertia_tensor;
inertia_tensor.set_zero();
for (int i=0;i<get_shape_count();i++) {
const ShapeSW* shape=get_shape(i);
float area=get_shape_area(i);
float mass = area * this->mass / total_area;
Basis shape_inertia_tensor=shape->get_moment_of_inertia(mass).to_diagonal_matrix();
Transform shape_transform=get_shape_transform(i);
Basis shape_basis = shape_transform.basis.orthonormalized();
// NOTE: we don't take the scale of collision shapes into account when computing the inertia tensor!
shape_inertia_tensor = shape_basis * shape_inertia_tensor * shape_basis.transposed();
Vector3 shape_origin = shape_transform.origin - center_of_mass_local;
inertia_tensor += shape_inertia_tensor + (Basis()*shape_origin.dot(shape_origin)-shape_origin.outer(shape_origin))*mass;
}
// Compute the principal axes of inertia
principal_inertia_axes_local = inertia_tensor.diagonalize().transposed();
_inv_inertia = inertia_tensor.get_main_diagonal().inverse();
if (mass)
_inv_mass=1.0/mass;
else
_inv_mass=0;
} break;
case PhysicsServer::BODY_MODE_KINEMATIC:
case PhysicsServer::BODY_MODE_STATIC: {
_inv_inertia_tensor.set_zero();
_inv_mass=0;
} break;
case PhysicsServer::BODY_MODE_CHARACTER: {
_inv_inertia_tensor.set_zero();
_inv_mass=1.0/mass;
} break;
}
//_update_shapes();
_update_transform_dependant();
}
void BodySW::set_active(bool p_active) {
if (active==p_active)
return;
active=p_active;
if (!p_active) {
if (get_space())
get_space()->body_remove_from_active_list(&active_list);
} else {
if (mode==PhysicsServer::BODY_MODE_STATIC)
return; //static bodies can't become active
if (get_space())
get_space()->body_add_to_active_list(&active_list);
//still_time=0;
}
/*
if (!space)
return;
for(int i=0;i<get_shape_count();i++) {
Shape &s=shapes[i];
if (s.bpid>0) {
get_space()->get_broadphase()->set_active(s.bpid,active);
}
}
*/
}
void BodySW::set_param(PhysicsServer::BodyParameter p_param, float p_value) {
switch(p_param) {
case PhysicsServer::BODY_PARAM_BOUNCE: {
bounce=p_value;
} break;
case PhysicsServer::BODY_PARAM_FRICTION: {
friction=p_value;
} break;
case PhysicsServer::BODY_PARAM_MASS: {
ERR_FAIL_COND(p_value<=0);
mass=p_value;
_update_inertia();
} break;
case PhysicsServer::BODY_PARAM_GRAVITY_SCALE: {
gravity_scale=p_value;
} break;
case PhysicsServer::BODY_PARAM_LINEAR_DAMP: {
linear_damp=p_value;
} break;
case PhysicsServer::BODY_PARAM_ANGULAR_DAMP: {
angular_damp=p_value;
} break;
default:{}
}
}
float BodySW::get_param(PhysicsServer::BodyParameter p_param) const {
switch(p_param) {
case PhysicsServer::BODY_PARAM_BOUNCE: {
return bounce;
} break;
case PhysicsServer::BODY_PARAM_FRICTION: {
return friction;
} break;
case PhysicsServer::BODY_PARAM_MASS: {
return mass;
} break;
case PhysicsServer::BODY_PARAM_GRAVITY_SCALE: {
return gravity_scale;
} break;
case PhysicsServer::BODY_PARAM_LINEAR_DAMP: {
return linear_damp;
} break;
case PhysicsServer::BODY_PARAM_ANGULAR_DAMP: {
return angular_damp;
} break;
default:{}
}
return 0;
}
void BodySW::set_mode(PhysicsServer::BodyMode p_mode) {
PhysicsServer::BodyMode prev=mode;
mode=p_mode;
switch(p_mode) {
//CLEAR UP EVERYTHING IN CASE IT NOT WORKS!
case PhysicsServer::BODY_MODE_STATIC:
case PhysicsServer::BODY_MODE_KINEMATIC: {
_set_inv_transform(get_transform().affine_inverse());
_inv_mass=0;
_set_static(p_mode==PhysicsServer::BODY_MODE_STATIC);
//set_active(p_mode==PhysicsServer::BODY_MODE_KINEMATIC);
set_active(p_mode==PhysicsServer::BODY_MODE_KINEMATIC && contacts.size());
linear_velocity=Vector3();
angular_velocity=Vector3();
if (mode==PhysicsServer::BODY_MODE_KINEMATIC && prev!=mode) {
first_time_kinematic=true;
}
} break;
case PhysicsServer::BODY_MODE_RIGID: {
_inv_mass=mass>0?(1.0/mass):0;
_set_static(false);
} break;
case PhysicsServer::BODY_MODE_CHARACTER: {
_inv_mass=mass>0?(1.0/mass):0;
_set_static(false);
} break;
}
_update_inertia();
/*
if (get_space())
_update_queries();
*/
}
PhysicsServer::BodyMode BodySW::get_mode() const {
return mode;
}
void BodySW::_shapes_changed() {
_update_inertia();
}
void BodySW::set_state(PhysicsServer::BodyState p_state, const Variant& p_variant) {
switch(p_state) {
case PhysicsServer::BODY_STATE_TRANSFORM: {
if (mode==PhysicsServer::BODY_MODE_KINEMATIC) {
new_transform=p_variant;
//wakeup_neighbours();
set_active(true);
if (first_time_kinematic) {
_set_transform(p_variant);
_set_inv_transform(get_transform().affine_inverse());
first_time_kinematic=false;
}
} else if (mode==PhysicsServer::BODY_MODE_STATIC) {
_set_transform(p_variant);
_set_inv_transform(get_transform().affine_inverse());
wakeup_neighbours();
} else {
Transform t = p_variant;
t.orthonormalize();
new_transform=get_transform(); //used as old to compute motion
if (new_transform==t)
break;
_set_transform(t);
_set_inv_transform(get_transform().inverse());
}
wakeup();
} break;
case PhysicsServer::BODY_STATE_LINEAR_VELOCITY: {
/*
if (mode==PhysicsServer::BODY_MODE_STATIC)
break;
*/
linear_velocity=p_variant;
wakeup();
} break;
case PhysicsServer::BODY_STATE_ANGULAR_VELOCITY: {
/*
if (mode!=PhysicsServer::BODY_MODE_RIGID)
break;
*/
angular_velocity=p_variant;
wakeup();
} break;
case PhysicsServer::BODY_STATE_SLEEPING: {
//?
if (mode==PhysicsServer::BODY_MODE_STATIC || mode==PhysicsServer::BODY_MODE_KINEMATIC)
break;
bool do_sleep=p_variant;
if (do_sleep) {
linear_velocity=Vector3();
//biased_linear_velocity=Vector3();
angular_velocity=Vector3();
//biased_angular_velocity=Vector3();
set_active(false);
} else {
if (mode!=PhysicsServer::BODY_MODE_STATIC)
set_active(true);
}
} break;
case PhysicsServer::BODY_STATE_CAN_SLEEP: {
can_sleep=p_variant;
if (mode==PhysicsServer::BODY_MODE_RIGID && !active && !can_sleep)
set_active(true);
} break;
}
}
Variant BodySW::get_state(PhysicsServer::BodyState p_state) const {
switch(p_state) {
case PhysicsServer::BODY_STATE_TRANSFORM: {
return get_transform();
} break;
case PhysicsServer::BODY_STATE_LINEAR_VELOCITY: {
return linear_velocity;
} break;
case PhysicsServer::BODY_STATE_ANGULAR_VELOCITY: {
return angular_velocity;
} break;
case PhysicsServer::BODY_STATE_SLEEPING: {
return !is_active();
} break;
case PhysicsServer::BODY_STATE_CAN_SLEEP: {
return can_sleep;
} break;
}
return Variant();
}
void BodySW::set_space(SpaceSW *p_space){
if (get_space()) {
if (inertia_update_list.in_list())
get_space()->body_remove_from_inertia_update_list(&inertia_update_list);
if (active_list.in_list())
get_space()->body_remove_from_active_list(&active_list);
if (direct_state_query_list.in_list())
get_space()->body_remove_from_state_query_list(&direct_state_query_list);
}
_set_space(p_space);
if (get_space()) {
_update_inertia();
if (active)
get_space()->body_add_to_active_list(&active_list);
/*
_update_queries();
if (is_active()) {
active=false;
set_active(true);
}
*/
}
first_integration=true;
}
void BodySW::_compute_area_gravity_and_dampenings(const AreaSW *p_area) {
if (p_area->is_gravity_point()) {
if(p_area->get_gravity_distance_scale() > 0) {
Vector3 v = p_area->get_transform().xform(p_area->get_gravity_vector()) - get_transform().get_origin();
gravity += v.normalized() * (p_area->get_gravity() / Math::pow(v.length() * p_area->get_gravity_distance_scale()+1, 2) );
} else {
gravity += (p_area->get_transform().xform(p_area->get_gravity_vector()) - get_transform().get_origin()).normalized() * p_area->get_gravity();
}
} else {
gravity += p_area->get_gravity_vector() * p_area->get_gravity();
}
area_linear_damp += p_area->get_linear_damp();
area_angular_damp += p_area->get_angular_damp();
}
void BodySW::integrate_forces(real_t p_step) {
if (mode==PhysicsServer::BODY_MODE_STATIC)
return;
AreaSW *def_area = get_space()->get_default_area();
// AreaSW *damp_area = def_area;
ERR_FAIL_COND(!def_area);
int ac = areas.size();
bool stopped = false;
gravity = Vector3(0,0,0);
area_linear_damp = 0;
area_angular_damp = 0;
if (ac) {
areas.sort();
const AreaCMP *aa = &areas[0];
// damp_area = aa[ac-1].area;
for(int i=ac-1;i>=0 && !stopped;i--) {
PhysicsServer::AreaSpaceOverrideMode mode=aa[i].area->get_space_override_mode();
switch (mode) {
case PhysicsServer::AREA_SPACE_OVERRIDE_COMBINE:
case PhysicsServer::AREA_SPACE_OVERRIDE_COMBINE_REPLACE: {
_compute_area_gravity_and_dampenings(aa[i].area);
stopped = mode==PhysicsServer::AREA_SPACE_OVERRIDE_COMBINE_REPLACE;
} break;
case PhysicsServer::AREA_SPACE_OVERRIDE_REPLACE:
case PhysicsServer::AREA_SPACE_OVERRIDE_REPLACE_COMBINE: {
gravity = Vector3(0,0,0);
area_angular_damp = 0;
area_linear_damp = 0;
_compute_area_gravity_and_dampenings(aa[i].area);
stopped = mode==PhysicsServer::AREA_SPACE_OVERRIDE_REPLACE;
} break;
default: {}
}
}
}
if( !stopped ) {
_compute_area_gravity_and_dampenings(def_area);
}
gravity*=gravity_scale;
// If less than 0, override dampenings with that of the Body
if (angular_damp>=0)
area_angular_damp=angular_damp;
/*
else
area_angular_damp=damp_area->get_angular_damp();
*/
if (linear_damp>=0)
area_linear_damp=linear_damp;
/*
else
area_linear_damp=damp_area->get_linear_damp();
*/
Vector3 motion;
bool do_motion=false;
if (mode==PhysicsServer::BODY_MODE_KINEMATIC) {
//compute motion, angular and etc. velocities from prev transform
linear_velocity = (new_transform.origin - get_transform().origin)/p_step;
//compute a FAKE angular velocity, not so easy
Basis rot=new_transform.basis.orthonormalized().transposed() * get_transform().basis.orthonormalized();
Vector3 axis;
float angle;
rot.get_axis_and_angle(axis,angle);
axis.normalize();
angular_velocity=axis.normalized() * (angle/p_step);
motion = new_transform.origin - get_transform().origin;
do_motion=true;
} else {
if (!omit_force_integration && !first_integration) {
//overriden by direct state query
Vector3 force=gravity*mass;
force+=applied_force;
Vector3 torque=applied_torque;
real_t damp = 1.0 - p_step * area_linear_damp;
if (damp<0) // reached zero in the given time
damp=0;
real_t angular_damp = 1.0 - p_step * area_angular_damp;
if (angular_damp<0) // reached zero in the given time
angular_damp=0;
linear_velocity*=damp;
angular_velocity*=angular_damp;
linear_velocity+=_inv_mass * force * p_step;
angular_velocity+=_inv_inertia_tensor.xform(torque)*p_step;
}
if (continuous_cd) {
motion=linear_velocity*p_step;
do_motion=true;
}
}
applied_force=Vector3();
applied_torque=Vector3();
first_integration=false;
//motion=linear_velocity*p_step;
biased_angular_velocity=Vector3();
biased_linear_velocity=Vector3();
if (do_motion) {//shapes temporarily extend for raycast
_update_shapes_with_motion(motion);
}
def_area=NULL; // clear the area, so it is set in the next frame
contact_count=0;
}
void BodySW::integrate_velocities(real_t p_step) {
if (mode==PhysicsServer::BODY_MODE_STATIC)
return;
if (fi_callback)
get_space()->body_add_to_state_query_list(&direct_state_query_list);
if (mode==PhysicsServer::BODY_MODE_KINEMATIC) {
_set_transform(new_transform,false);
_set_inv_transform(new_transform.affine_inverse());
if (contacts.size()==0 && linear_velocity==Vector3() && angular_velocity==Vector3())
set_active(false); //stopped moving, deactivate
return;
}
//apply axis lock
if (axis_lock!=PhysicsServer::BODY_AXIS_LOCK_DISABLED) {
int axis=axis_lock-1;
for(int i=0;i<3;i++) {
if (i==axis) {
linear_velocity[i]=0;
biased_linear_velocity[i]=0;
} else {
angular_velocity[i]=0;
biased_angular_velocity[i]=0;
}
}
}
Vector3 total_angular_velocity = angular_velocity+biased_angular_velocity;
float ang_vel = total_angular_velocity.length();
Transform transform = get_transform();
if (ang_vel!=0.0) {
Vector3 ang_vel_axis = total_angular_velocity / ang_vel;
Basis rot( ang_vel_axis, -ang_vel*p_step );
Basis identity3(1, 0, 0, 0, 1, 0, 0, 0, 1);
transform.origin += ((identity3 - rot) * transform.basis).xform(center_of_mass_local);
transform.basis = rot * transform.basis;
transform.orthonormalize();
}
Vector3 total_linear_velocity=linear_velocity+biased_linear_velocity;
/*for(int i=0;i<3;i++) {
if (axis_lock&(1<<i)) {
transform.origin[i]=0.0;
}
}*/
transform.origin+=total_linear_velocity * p_step;
_set_transform(transform);
_set_inv_transform(get_transform().inverse());
_update_transform_dependant();
/*
if (fi_callback) {
get_space()->body_add_to_state_query_list(&direct_state_query_list);
*/
}
/*
void BodySW::simulate_motion(const Transform& p_xform,real_t p_step) {
Transform inv_xform = p_xform.affine_inverse();
if (!get_space()) {
_set_transform(p_xform);
_set_inv_transform(inv_xform);
return;
}
//compute a FAKE linear velocity - this is easy
linear_velocity=(p_xform.origin - get_transform().origin)/p_step;
//compute a FAKE angular velocity, not so easy
Matrix3 rot=get_transform().basis.orthonormalized().transposed() * p_xform.basis.orthonormalized();
Vector3 axis;
float angle;
rot.get_axis_and_angle(axis,angle);
axis.normalize();
angular_velocity=axis.normalized() * (angle/p_step);
linear_velocity = (p_xform.origin - get_transform().origin)/p_step;
if (!direct_state_query_list.in_list())// - callalways, so lv and av are cleared && (state_query || direct_state_query))
get_space()->body_add_to_state_query_list(&direct_state_query_list);
simulated_motion=true;
_set_transform(p_xform);
}
*/
void BodySW::wakeup_neighbours() {
for(Map<ConstraintSW*,int>::Element *E=constraint_map.front();E;E=E->next()) {
const ConstraintSW *c=E->key();
BodySW **n = c->get_body_ptr();
int bc=c->get_body_count();
for(int i=0;i<bc;i++) {
if (i==E->get())
continue;
BodySW *b = n[i];
if (b->mode!=PhysicsServer::BODY_MODE_RIGID)
continue;
if (!b->is_active())
b->set_active(true);
}
}
}
void BodySW::call_queries() {
if (fi_callback) {
PhysicsDirectBodyStateSW *dbs = PhysicsDirectBodyStateSW::singleton;
dbs->body=this;
Variant v=dbs;
Object *obj = ObjectDB::get_instance(fi_callback->id);
if (!obj) {
set_force_integration_callback(0,StringName());
} else {
const Variant *vp[2]={&v,&fi_callback->udata};
Variant::CallError ce;
int argc=(fi_callback->udata.get_type()==Variant::NIL)?1:2;
obj->call(fi_callback->method,vp,argc,ce);
}
}
}
bool BodySW::sleep_test(real_t p_step) {
if (mode==PhysicsServer::BODY_MODE_STATIC || mode==PhysicsServer::BODY_MODE_KINEMATIC)
return true; //
else if (mode==PhysicsServer::BODY_MODE_CHARACTER)
return !active; // characters don't sleep unless asked to sleep
else if (!can_sleep)
return false;
if (Math::abs(angular_velocity.length())<get_space()->get_body_angular_velocity_sleep_treshold() && Math::abs(linear_velocity.length_squared()) < get_space()->get_body_linear_velocity_sleep_treshold()*get_space()->get_body_linear_velocity_sleep_treshold()) {
still_time+=p_step;
return still_time > get_space()->get_body_time_to_sleep();
} else {
still_time=0; //maybe this should be set to 0 on set_active?
return false;
}
}
void BodySW::set_force_integration_callback(ObjectID p_id,const StringName& p_method,const Variant& p_udata) {
if (fi_callback) {
memdelete(fi_callback);
fi_callback=NULL;
}
if (p_id!=0) {
fi_callback=memnew(ForceIntegrationCallback);
fi_callback->id=p_id;
fi_callback->method=p_method;
fi_callback->udata=p_udata;
}
}
BodySW::BodySW() : CollisionObjectSW(TYPE_BODY), active_list(this), inertia_update_list(this), direct_state_query_list(this) {
mode=PhysicsServer::BODY_MODE_RIGID;
active=true;
mass=1;
//_inv_inertia=Transform();
_inv_mass=1;
bounce=0;
friction=1;
omit_force_integration=false;
//applied_torque=0;
island_step=0;
island_next=NULL;
island_list_next=NULL;
first_time_kinematic=false;
first_integration=false;
_set_static(false);
contact_count=0;
gravity_scale=1.0;
area_angular_damp=0;
area_linear_damp=0;
still_time=0;
continuous_cd=false;
can_sleep=false;
fi_callback=NULL;
axis_lock=PhysicsServer::BODY_AXIS_LOCK_DISABLED;
}
BodySW::~BodySW() {
if (fi_callback)
memdelete(fi_callback);
}
PhysicsDirectBodyStateSW *PhysicsDirectBodyStateSW::singleton=NULL;
PhysicsDirectSpaceState* PhysicsDirectBodyStateSW::get_space_state() {
return body->get_space()->get_direct_state();
}