ef2-sdk/dlls/game/bspline.cpp

940 lines
18 KiB
C++
Raw Permalink Normal View History

2003-11-05 00:00:00 +00:00
//-----------------------------------------------------------------------------
//
// $Logfile:: /EF2/Code/DLLs/game/bspline.cpp $
// $Revision:: 12 $
// $Author:: Singlis $
// $Date:: 9/26/03 2:35p $
//
// Copyright (C) 1998 by Ritual Entertainment, Inc.
// All rights reserved.
//
// This source is may not be distributed and/or modified without
// expressly written permission by Ritual Entertainment, Inc.
//
// DESCRIPTION:
// Uniform non-rational bspline class.
//
#include "_pch_cpp.h"
#include "bspline.h"
void BSpline::Set( const Vector *control_points_, int num_control_points_, splinetype_t type )
{
int i;
SetType( type );
has_orientation = false;
if ( control_points )
{
delete [] control_points;
control_points = NULL;
}
num_control_points = num_control_points_;
if ( num_control_points )
{
control_points = new BSplineControlPoint[ num_control_points ];
assert( control_points );
for( i = 0; i < num_control_points; i++ )
{
control_points[ i ].Set( control_points_[ i ] );
}
}
}
void BSpline::Set( const Vector *control_points_, const Vector *control_orients_, const float *control_speeds_,
int num_control_points_, splinetype_t type )
{
int i;
SetType( type );
has_orientation = true;
if ( control_points )
{
delete [] control_points;
control_points = NULL;
}
num_control_points = num_control_points_;
if ( num_control_points )
{
control_points = new BSplineControlPoint[ num_control_points ];
assert( control_points );
for( i = 0; i < num_control_points; i++ )
{
control_points[ i ].Set( control_points_[ i ], control_orients_[ i ], control_speeds_[ i ] );
}
}
}
void BSpline::Clear( void )
{
if( control_points )
{
delete [] control_points;
control_points = NULL;
}
num_control_points = 0;
has_orientation = false;
}
inline float BSpline::EvalNormal( float u, Vector& pos, Vector& orient )
{
int segment_id;
float B[ 4 ];
float tmp;
float u_2;
float u_3;
Vector ang;
float roll;
float speed;
segment_id = ( int )u;
if ( segment_id < 0 )
{
segment_id = 0;
}
if ( segment_id > ( num_control_points - 4 ) )
{
segment_id = num_control_points - 4;
}
u -= ( float )segment_id;
u_2 = u * u;
u_3 = u * u_2;
tmp = 1.0f - u;
B[ 0 ] = ( tmp * tmp * tmp ) * ( 1.0f / 6.0f );
B[ 1 ] = ( ( 3.0f * u_3 ) - ( 6.0f * u_2 ) + 4.0f ) * ( 1.0f / 6.0f );
B[ 2 ] = ( ( -3.0f * u_3 ) + ( 3.0f * u_2 ) + ( 3.0f * u ) + 1 ) * ( 1.0f / 6.0f );
B[ 3 ] = u_3 * ( 1.0f / 6.0f );
pos =
( *control_points[ 0 + segment_id ].GetPosition() * B[ 0 ] ) +
( *control_points[ 1 + segment_id ].GetPosition() * B[ 1 ] ) +
( *control_points[ 2 + segment_id ].GetPosition() * B[ 2 ] ) +
( *control_points[ 3 + segment_id ].GetPosition() * B[ 3 ] );
ang =
( *control_points[ 0 + segment_id ].GetOrientation() * B[ 0 ] ) +
( *control_points[ 1 + segment_id ].GetOrientation() * B[ 1 ] ) +
( *control_points[ 2 + segment_id ].GetOrientation() * B[ 2 ] ) +
( *control_points[ 3 + segment_id ].GetOrientation() * B[ 3 ] );
roll =
( *control_points[ 0 + segment_id ].GetRoll() * B[ 0 ] ) +
( *control_points[ 1 + segment_id ].GetRoll() * B[ 1 ] ) +
( *control_points[ 2 + segment_id ].GetRoll() * B[ 2 ] ) +
( *control_points[ 3 + segment_id ].GetRoll() * B[ 3 ] );
speed =
( *control_points[ 0 + segment_id ].GetSpeed() * B[ 0 ] ) +
( *control_points[ 1 + segment_id ].GetSpeed() * B[ 1 ] ) +
( *control_points[ 2 + segment_id ].GetSpeed() * B[ 2 ] ) +
( *control_points[ 3 + segment_id ].GetSpeed() * B[ 3 ] );
orient = ang.toAngles();
orient[ ROLL ] = roll;
return speed;
}
inline float BSpline::EvalLoop( float t, Vector& pos, Vector& orient )
{
Vector retval;
Vector ang;
float speed;
float roll;
int segment_id;
int next_id;
float B[ 4 ];
float tmp;
float u;
float u_2;
float u_3;
int i;
int j;
segment_id = ( int )floor( t );
u = t - floor( t );
segment_id %= num_control_points;
if ( segment_id < 0 )
{
segment_id += num_control_points;
}
u_2 = u * u;
u_3 = u * u_2;
tmp = 1.0f - u;
B[ 0 ] = ( tmp * tmp * tmp ) * ( 1.0f / 6.0f );
B[ 1 ] = ( ( 3.0f * u_3 ) - ( 6.0f * u_2 ) + 4.0f ) * ( 1.0f / 6.0f );
B[ 2 ] = ( ( -3.0f * u_3 ) + ( 3.0f * u_2 ) + ( 3.0f * u ) + 1 ) * ( 1.0f / 6.0f );
B[ 3 ] = u_3 * ( 1.0f / 6.0f );
speed = 0;
roll = 0;
for( i = 0, j = segment_id; i < 4; i++, j++ )
{
if ( j >= num_control_points )
{
j -= ( num_control_points - loop_control_point );
}
retval += *control_points[ j ].GetPosition() * B[ i ];
ang += *control_points[ j ].GetOrientation() * B[ i ];
speed += *control_points[ j ].GetSpeed() * B[ i ];
roll += *control_points[ j ].GetRoll() * B[ i ];
}
pos = retval;
next_id = segment_id + 1;
if ( next_id >= num_control_points )
{
next_id -= ( num_control_points - loop_control_point );
}
orient = ang.toAngles();
orient[ ROLL ] = roll;
return speed;
}
inline float BSpline::EvalClamp( float t, Vector& pos, Vector& orient )
{
Vector retval;
Vector ang;
int segment_id;
int next_id;
float B[ 4 ];
float tmp;
float u;
float u_2;
float u_3;
int i;
int j;
float speed;
float roll;
segment_id = ( int )floor( t );
u = t - floor( t );
u_2 = u * u;
u_3 = u * u_2;
tmp = 1.0f - u;
B[ 0 ] = ( tmp * tmp * tmp ) * ( 1.0f / 6.0f );
B[ 1 ] = ( ( 3.0f * u_3 ) - ( 6.0f * u_2 ) + 4.0f ) * ( 1.0f / 6.0f );
B[ 2 ] = ( ( -3.0f * u_3 ) + ( 3.0f * u_2 ) + ( 3.0f * u ) + 1 ) * ( 1.0f / 6.0f );
B[ 3 ] = u_3 * ( 1.0f / 6.0f );
speed = 0.0f;
roll = 0.0f;
for( i = 0; i < 4; i++, segment_id++ )
{
j = segment_id;
if ( j < 0 )
{
j = 0;
}
else if ( j >= num_control_points )
{
j = num_control_points - 1;
}
retval += *control_points[ j ].GetPosition() * B[ i ];
ang += *control_points[ j ].GetOrientation() * B[ i ];
speed += *control_points[ j ].GetSpeed() * B[ i ];
roll += *control_points[ j ].GetRoll() * B[ i ];
}
pos = retval;
next_id = segment_id + 1;
if ( segment_id < 0 )
{
segment_id = 0;
}
if ( segment_id >= num_control_points )
{
segment_id = num_control_points - 1;
}
if ( next_id < 0 )
{
next_id = 0;
}
if ( next_id >= num_control_points )
{
next_id = num_control_points - 1;
}
orient = ang.toAngles();
orient[ ROLL ] = roll;
return speed;
}
Vector BSpline::Eval( float u )
{
Vector pos;
Vector orient;
switch( curvetype )
{
default:
case SPLINE_NORMAL :
EvalNormal( u, pos, orient );
break;
case SPLINE_CLAMP:
EvalClamp( u, pos, orient );
break;
case SPLINE_LOOP:
if ( u < 0.0f )
{
EvalClamp( u, pos, orient );
}
else
{
EvalLoop( u, pos, orient );
}
break;
}
return pos;
}
float BSpline::Eval( float u, Vector &pos, Vector &orient )
{
switch( curvetype )
{
default:
case SPLINE_NORMAL :
return EvalNormal( u, pos, orient );
break;
case SPLINE_CLAMP:
return EvalClamp( u, pos, orient );
break;
case SPLINE_LOOP:
if ( u < 0.0f )
{
return EvalClamp( u, pos, orient );
}
else
{
return EvalLoop( u, pos, orient );
}
break;
}
}
void BSpline::DrawControlSegments( void )
{
int i;
G_BeginLine();
for( i = 0; i < num_control_points; i++ )
{
G_Vertex( *control_points[ i ].GetPosition() );
}
G_EndLine();
}
void BSpline::DrawCurve( int num_subdivisions )
{
float u;
float du;
if ( !num_control_points )
{
return;
}
du = 1.0f / ( float )num_subdivisions;
G_BeginLine();
for( u = -2.0f; u <= ( float )num_control_points; u += du )
{
G_Vertex( ( Vector )Eval( u ) );
}
G_EndLine();
}
void BSpline::DrawCurve( const Vector &offset, int num_subdivisions )
{
float u;
float du;
du = 1.0f / ( float )num_subdivisions;
G_BeginLine();
for( u = -2.0f; u <= ( float )num_control_points; u += du )
{
G_Vertex( offset + ( Vector )Eval( u ) );
}
G_EndLine();
}
void BSpline::AppendControlPoint( const Vector& new_control_point )
{
BSplineControlPoint *old_control_points;
int i;
old_control_points = control_points;
num_control_points++;
control_points = new BSplineControlPoint[num_control_points];
assert( control_points );
if ( old_control_points )
{
for( i = 0; i < ( num_control_points - 1 ) ; i++ )
{
control_points[ i ] = old_control_points[ i ];
}
delete [] old_control_points;
}
control_points[ num_control_points - 1 ].Set( new_control_point );
}
void BSpline::AppendControlPoint( const Vector& new_control_point, const float& speed )
{
BSplineControlPoint *old_control_points;
int i;
old_control_points = control_points;
num_control_points++;
control_points = new BSplineControlPoint[num_control_points];
assert( control_points );
if ( old_control_points )
{
for( i = 0; i < ( num_control_points - 1 ); i++ )
{
control_points[ i ] = old_control_points[ i ];
}
delete [] old_control_points;
}
control_points[ num_control_points - 1 ].Set( new_control_point, speed );
}
void BSpline::AppendControlPoint( const Vector& new_control_point, const Vector& new_control_orient,
const float& new_control_speed )
{
BSplineControlPoint *old_control_points;
int i;
has_orientation = true;
old_control_points = control_points;
num_control_points++;
control_points = new BSplineControlPoint[num_control_points];
assert( control_points );
if ( old_control_points )
{
for( i = 0; i < ( num_control_points - 1 ) ; i++ )
{
control_points[ i ] = old_control_points[ i ];
}
delete [] old_control_points;
}
control_points[ num_control_points - 1 ].Set( new_control_point, new_control_orient, new_control_speed );
}
void BSpline::SetLoopPoint( const Vector& pos )
{
int i;
for( i = 0; i < num_control_points; i++ )
{
if ( pos == *control_points[ i ].GetPosition() )
{
loop_control_point = i;
break;
}
}
}
int BSpline::PickControlPoint( const Vector& window_point, float pick_size )
{
int i;
float closest_dist_2;
int closest_index;
float dist_2;
Vector delta;
closest_index = -1;
closest_dist_2 = 1000000.0f;
for( i = 0; i < num_control_points; i++ )
{
delta = window_point - *control_points[ i ].GetPosition();
dist_2 = delta * delta;
if ( dist_2 < closest_dist_2 )
{
closest_dist_2 = dist_2;
closest_index = i;
}
}
if ( pick_size * pick_size >= closest_dist_2 )
{
return closest_index;
}
else
{
return -1;
}
}
Event EV_SplinePath_Create
(
"SplinePath_create",
EV_SCRIPTONLY,
NULL,
NULL,
"Creates the spline path from the target list."
);
Event EV_SplinePath_Loop
(
"loopSpline",
EV_SCRIPTONLY,
"s",
"loop_name",
"Sets the loop name."
);
Event EV_SplinePath_Speed
(
"speed",
EV_DEFAULT,
"f",
"speed",
"Sets the path speed."
);
Event EV_SplinePath_SetTriggerTarget
(
"triggertarget",
EV_SCRIPTONLY,
"s",
"target",
"Sets the trigger target."
);
Event EV_SplinePath_SetThread
(
"thread",
EV_SCRIPTONLY,
"s",
"thread",
"Sets the thread."
);
Event EV_SplinePath_SetWatch
(
"watch",
EV_SCRIPTONLY,
"s",
"watchEntity",
"Sets the entity to watch at this node."
);
Event EV_SplinePath_SetFov
(
"fov",
EV_CONSOLE,
"f",
"cameraFOV",
"Sets the fov at this node."
);
Event EV_SplinePath_SetFadeTime
(
"fadetime",
EV_SCRIPTONLY,
"f",
"fadeTime",
"Sets the fadetime at this node."
);
Event EV_SplinePath_MoveSpline
(
"movespline",
EV_SCRIPTONLY,
"v",
"new_position",
"Sets the new position of the spline."
);
Event EV_SplinePath_OffsetSpline
(
"offsetspline",
EV_SCRIPTONLY,
"v",
"offset",
"Offsets the position of the spline."
);
Event EV_SplinePath_TurnSpline
(
"turnspline",
EV_SCRIPTONLY,
"v",
"angle_offset",
"Turns the spline."
);
/*QUAKED info_splinepath (0 0 .5) (-8 -8 -8) (8 8 8) x x x x x x x LADYBUG
Spline Path Node
"angles" camera will use that orientation
"loop" set a loop node
"triggertarget" when node is reached fire these targets
"thread" fire this thread when node is reached
"speed" speed multiplier for this segment, normally each\
segment will take 1 second to traverse, use 2 for double speed\
and 0.5 for half speed
*/
CLASS_DECLARATION( Entity, SplinePath, "info_splinepath" )
{
{ &EV_SplinePath_Create, &SplinePath::CreatePath },
{ &EV_SplinePath_Loop, &SplinePath::SetLoop },
{ &EV_SplinePath_Speed, &SplinePath::SetSpeed },
{ &EV_SplinePath_SetTriggerTarget, &SplinePath::SetTriggerTarget },
{ &EV_SplinePath_SetThread, &SplinePath::SetThread },
{ &EV_SplinePath_SetWatch, &SplinePath::SetWatch },
{ &EV_SplinePath_SetFov, &SplinePath::SetFov },
{ &EV_SplinePath_SetFadeTime, &SplinePath::SetFadeTime },
{ &EV_SplinePath_MoveSpline, &SplinePath::MoveSpline },
{ &EV_SplinePath_OffsetSpline, &SplinePath::OffsetSpline },
{ &EV_SplinePath_TurnSpline, &SplinePath::TurnSpline },
{ NULL, NULL }
};
SplinePath::SplinePath()
{
owner = this;
next = NULL;
loop = NULL;
speed = 1;
doWatch = false;
watchEnt = "";
fov = 0;
fadeTime = -1;
setMoveType( MOVETYPE_NONE );
setSolidType( SOLID_NOT );
hideModel();
if ( !LoadingSavegame )
{
PostEvent( EV_SplinePath_Create, FRAMETIME );
}
}
SplinePath::~SplinePath()
{
// disconnect from the chain
if ( owner != this )
{
owner->SetNext( next );
}
else if ( next )
{
next->SetPrev( NULL );
next = NULL;
}
assert( owner == this );
assert( next == NULL );
}
void SplinePath::SetLoop( Event *ev )
{
loop_name = ev->GetString( 1 );
}
void SplinePath::SetSpeed( Event *ev )
{
speed = ev->GetFloat( 1 );
}
void SplinePath::SetTriggerTarget( Event *ev )
{
SetTriggerTarget( ev->GetString( 1 ) );
}
void SplinePath::SetThread( Event *ev )
{
SetThread( ev->GetString( 1 ) );
}
void SplinePath::CreatePath( Event *ev )
{
const char *target;
Entity *ent;
// Make the path from the targetlist.
target = Target();
if ( target[ 0 ] )
{
ent = G_FindTarget( NULL, target );
if ( ent )
{
assert( next == NULL );
next = ( SplinePath * )ent;
next->owner = this;
}
else
{
gi.Error( ERR_DROP, "SplinePath::CreatePath: target %s not found\n", target );
}
}
if ( loop_name.length() )
{
ent = G_FindTarget( NULL, loop_name.c_str() );
if ( ent )
{
loop = ( SplinePath * )ent;
}
}
}
SplinePath *SplinePath::GetNext( void )
{
return next;
}
SplinePath *SplinePath::GetPrev( void )
{
if ( owner == this )
{
return NULL;
}
return owner;
}
void SplinePath::SetNext( SplinePath *node )
{
if ( next )
{
// remove ourselves from the chain
next->owner = next;
}
next = node;
if ( next )
{
// disconnect next from it's previous node
if ( next->owner != next )
{
next->owner->next = NULL;
}
next->owner = this;
}
}
void SplinePath::SetPrev( SplinePath *node )
{
if ( owner != this )
{
owner->next = NULL;
}
if ( node && ( node != this ) )
{
// safely remove the node from its chain
if ( node->next )
{
node->next->owner = node->next;
}
node->next = this;
owner = node;
}
else
{
owner = this;
}
}
SplinePath *SplinePath::GetLoop( void )
{
return loop;
}
void SplinePath::SetWatch( const char *name )
{
if ( watchEnt != name )
{
watchEnt = name;
if ( watchEnt.length() )
{
doWatch = true;
}
else
{
doWatch = false;
}
}
}
void SplinePath::SetWatch( Event *ev )
{
SetWatch( ev->GetString( 1 ) );
}
void SplinePath::NoWatch( void )
{
doWatch = true;
watchEnt = "none";
}
str SplinePath::GetWatch( void )
{
return watchEnt;
}
void SplinePath::SetFov( float newFov )
{
fov = newFov;
}
void SplinePath::SetFov( Event *ev )
{
fov = ev->GetFloat( 1 );
}
float SplinePath::GetFov( void )
{
return fov;
}
void SplinePath::SetFadeTime( float newFadeTime )
{
fadeTime = newFadeTime;
}
void SplinePath::SetFadeTime( Event *ev )
{
fadeTime = ev->GetFloat( 1 );
}
float SplinePath::GetFadeTime( void )
{
return fadeTime;
}
void SplinePath::MoveSpline( Event *ev )
{
Vector new_position;
Vector offset;
Event *new_event;
// Get the new position for this spline node
new_position = ev->GetVector( 1 );
// Get the offset to move the entire spline
offset = new_position - origin;
// Move the entire spline
new_event = new Event( EV_SplinePath_OffsetSpline );
new_event->AddVector( offset );
ProcessEvent( new_event );
}
void SplinePath::OffsetSpline( Event *ev )
{
Vector offset;
const char *target;
Entity *ent;
offset = ev->GetVector( 1 );
target = Target();
setOrigin( origin + offset );
if ( !target || !target[ 0 ] )
return;
ent = G_FindTarget( NULL, target );
if ( !ent )
return;
while ( ent && ( ent != this ) )
{
ent->setOrigin( ent->origin + offset );
target = ent->Target();
if ( !target || !target[ 0 ] )
break;
ent = G_FindTarget( NULL, target );
}
}
void SplinePath::TurnSpline( Event *ev )
{
Vector new_angles;
Vector angles_diff;
float axis[3][3];
const char *target;
Entity *ent;
Vector offset;
Vector transformed_origin;
new_angles = ev->GetVector( 1 );
angles_diff = new_angles - angles;
AnglesToAxis( angles_diff, axis );
setAngles( new_angles );
target = Target();
if ( !target || !target[ 0 ] )
return;
ent = G_FindTarget( NULL, target );
if ( !ent )
return;
while ( ent && ( ent != this ) )
{
offset = ent->origin - origin;
MatrixTransformVector( offset, axis, transformed_origin );
transformed_origin += origin;
ent->setOrigin( transformed_origin );
target = ent->Target();
if ( !target || !target[ 0 ] )
break;
ent = G_FindTarget( NULL, target );
}
}