d4708
/
source-engine
mirror of https://github.com/nillerusr/source-engine.git
1
0
Fork 0
Code Issues Projects Releases Wiki Activity
Modified source engine (2017) developed by valve and leaked in 2020. Not for commercial purporses
You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
175 Commits
25 Branches
6 Tags
221 MiB
Tree: 94916a20ce
Branches Tags
${ item.name }
Create tag ${ searchTerm }
Create branch ${ searchTerm }
from '94916a20ce'
${ noResults }
source-engine/public/interpolatortypes.cpp

506 lines
12 KiB
Raw Normal View History Unescape

1
5 years ago
//========= Copyright Valve Corporation, All rights reserved. ============//
//
// Purpose:
//
//=============================================================================
#include "basetypes.h"
#include "tier1/strtools.h"
#include "interpolatortypes.h"
#include "tier0/dbg.h"
#include "mathlib/mathlib.h"
// memdbgon must be the last include file in a .cpp file!!!
#include "tier0/memdbgon.h"
struct InterpolatorNameMap_t
{
int type;
char const *name;
char const *printname;
};
static InterpolatorNameMap_t g_InterpolatorNameMap[] =
{
{ INTERPOLATE_DEFAULT, "default", "Default" },
{ INTERPOLATE_CATMULL_ROM_NORMALIZEX, "catmullrom_normalize_x", "Catmull-Rom (Norm X)" },
{ INTERPOLATE_EASE_IN, "easein", "Ease In" },
{ INTERPOLATE_EASE_OUT, "easeout", "Ease Out" },
{ INTERPOLATE_EASE_INOUT, "easeinout", "Ease In/Out" },
{ INTERPOLATE_BSPLINE, "bspline", "B-Spline" },
{ INTERPOLATE_LINEAR_INTERP, "linear_interp", "Linear Interp." },
{ INTERPOLATE_KOCHANEK_BARTELS, "kochanek", "Kochanek-Bartels" },
{ INTERPOLATE_KOCHANEK_BARTELS_EARLY, "kochanek_early", "Kochanek-Bartels Early" },
{ INTERPOLATE_KOCHANEK_BARTELS_LATE, "kochanek_late", "Kochanek-Bartels Late" },
{ INTERPOLATE_SIMPLE_CUBIC, "simple_cubic", "Simple Cubic" },
{ INTERPOLATE_CATMULL_ROM, "catmullrom", "Catmull-Rom" },
{ INTERPOLATE_CATMULL_ROM_NORMALIZE, "catmullrom_normalize", "Catmull-Rom (Norm)" },
{ INTERPOLATE_CATMULL_ROM_TANGENT, "catmullrom_tangent", "Catmull-Rom (Tangent)" },
{ INTERPOLATE_EXPONENTIAL_DECAY, "exponential_decay", "Exponential Decay" },
{ INTERPOLATE_HOLD, "hold", "Hold" },
};
int Interpolator_InterpolatorForName( char const *name )
{
for ( int i = 0; i < NUM_INTERPOLATE_TYPES; ++i )
{
InterpolatorNameMap_t *slot = &g_InterpolatorNameMap[ i ];
if ( !Q_stricmp( name, slot->name ) )
return slot->type;
}
Assert( !"Interpolator_InterpolatorForName failed!!!" );
return INTERPOLATE_DEFAULT;
}
char const *Interpolator_NameForInterpolator( int type, bool printname )
{
int i = (int)type;
int c = ARRAYSIZE( g_InterpolatorNameMap );
if ( i < 0 || i >= c )
{
Assert( "!Interpolator_NameForInterpolator: bogus type!" );
// returns "unspecified!!!";
return printname ? g_InterpolatorNameMap[ 0 ].printname : g_InterpolatorNameMap[ 0 ].name;
}
return printname ? g_InterpolatorNameMap[ i ].printname : g_InterpolatorNameMap[ i ].name;
}
//-----------------------------------------------------------------------------
// Purpose:
//-----------------------------------------------------------------------------
struct CurveNameMap_t
{
int type;
int hotkey;
};
static CurveNameMap_t g_CurveNameMap[] =
{
{ CURVE_CATMULL_ROM_TO_CATMULL_ROM, '1' },
{ CURVE_EASE_IN_TO_EASE_OUT, '2' },
{ CURVE_EASE_IN_TO_EASE_IN, '3' },
{ CURVE_EASE_OUT_TO_EASE_OUT, '4' },
{ CURVE_BSPLINE_TO_BSPLINE, '5' },
{ CURVE_LINEAR_INTERP_TO_LINEAR_INTERP, '6' },
{ CURVE_KOCHANEK_BARTELS_TO_KOCHANEK_BARTELS, '7' },
{ CURVE_KOCHANEK_BARTELS_EARLY_TO_KOCHANEK_BARTELS_EARLY, '8' },
{ CURVE_KOCHANEK_BARTELS_LATE_TO_KOCHANEK_BARTELS_LATE, '9' },
{ CURVE_SIMPLE_CUBIC_TO_SIMPLE_CUBIC, '0' },
};
// Turn enum into string and vice versa
int Interpolator_CurveTypeForName( const char *name )
{
char sz[ 128 ];
Q_strncpy( sz, name, sizeof( sz ) );
int leftcurve = 0;
int rightcurve = 0;
int skip = Q_strlen( "curve_" );
if ( !Q_strnicmp( sz, "curve_", skip ) )
{
char *p = sz + skip;
char *second = Q_stristr( p, "_to_curve_" );
char save = *second;
*second = 0;
leftcurve = Interpolator_InterpolatorForName( p );
*second = save;
p = second + Q_strlen( "_to_curve_" );
rightcurve = Interpolator_InterpolatorForName( p );
}
return MAKE_CURVE_TYPE( leftcurve, rightcurve );
}
const char *Interpolator_NameForCurveType( int type, bool printname )
{
static char outname[ 256 ];
int leftside = GET_LEFT_CURVE( type );
int rightside = GET_RIGHT_CURVE( type );
if ( !printname )
{
Q_snprintf( outname, sizeof( outname ), "curve_%s_to_curve_%s",
Interpolator_NameForInterpolator( leftside, printname ),
Interpolator_NameForInterpolator( rightside, printname ) );
}
else
{
Q_snprintf( outname, sizeof( outname ), "%s <-> %s",
Interpolator_NameForInterpolator( leftside, printname ),
Interpolator_NameForInterpolator( rightside, printname ) );
}
return outname;
}
void Interpolator_CurveInterpolatorsForType( int type, int& inbound, int& outbound )
{
inbound = GET_LEFT_CURVE( type );
outbound = GET_RIGHT_CURVE( type );
}
int Interpolator_CurveTypeForHotkey( int key )
{
int c = ARRAYSIZE( g_CurveNameMap );
for ( int i = 0; i < c; ++i )
{
CurveNameMap_t *slot = &g_CurveNameMap[ i ];
if ( slot->hotkey == key )
return slot->type;
}
return -1;
}
void Interpolator_GetKochanekBartelsParams( int interpolationType, float& tension, float& bias, float& continuity )
{
switch ( interpolationType )
{
default:
tension = 0.0f;
bias = 0.0f;
continuity = 0.0f;
Assert( 0 );
break;
case INTERPOLATE_KOCHANEK_BARTELS:
tension = 0.77f;
bias = 0.0f;
continuity = 0.77f;
break;
case INTERPOLATE_KOCHANEK_BARTELS_EARLY:
tension = 0.77f;
bias = -1.0f;
continuity = 0.77f;
break;
case INTERPOLATE_KOCHANEK_BARTELS_LATE:
tension = 0.77f;
bias = 1.0f;
continuity = 0.77f;
break;
}
}
void Interpolator_CurveInterpolate( int interpolationType,
const Vector &vPre,
const Vector &vStart,
const Vector &vEnd,
const Vector &vNext,
float f,
Vector &vOut )
{
vOut.Init();
switch ( interpolationType )
{
default:
Warning( "Unknown interpolation type %d\n",
(int)interpolationType );
// break; // Fall through and use catmull_rom as default
case INTERPOLATE_DEFAULT:
case INTERPOLATE_CATMULL_ROM_NORMALIZEX:
Catmull_Rom_Spline_NormalizeX(
vPre,
vStart,
vEnd,
vNext,
f,
vOut );
break;
case INTERPOLATE_CATMULL_ROM:
Catmull_Rom_Spline(
vPre,
vStart,
vEnd,
vNext,
f,
vOut );
break;
case INTERPOLATE_CATMULL_ROM_NORMALIZE:
Catmull_Rom_Spline_Normalize(
vPre,
vStart,
vEnd,
vNext,
f,
vOut );
break;
case INTERPOLATE_CATMULL_ROM_TANGENT:
Catmull_Rom_Spline_Tangent(
vPre,
vStart,
vEnd,
vNext,
f,
vOut );
break;
case INTERPOLATE_EASE_IN:
{
f = sin( M_PI * f * 0.5f );
// Fixme, since this ignores vPre and vNext we could omit computing them aove
VectorLerp( vStart, vEnd, f, vOut );
}
break;
case INTERPOLATE_EASE_OUT:
{
f = 1.0f - sin( M_PI * f * 0.5f + 0.5f * M_PI );
// Fixme, since this ignores vPre and vNext we could omit computing them aove
VectorLerp( vStart, vEnd, f, vOut );
}
break;
case INTERPOLATE_EASE_INOUT:
{
f = SimpleSpline( f );
// Fixme, since this ignores vPre and vNext we could omit computing them aove
VectorLerp( vStart, vEnd, f, vOut );
}
break;
case INTERPOLATE_LINEAR_INTERP:
// Fixme, since this ignores vPre and vNext we could omit computing them aove
VectorLerp( vStart, vEnd, f, vOut );
break;
case INTERPOLATE_KOCHANEK_BARTELS:
case INTERPOLATE_KOCHANEK_BARTELS_EARLY:
case INTERPOLATE_KOCHANEK_BARTELS_LATE:
{
float t, b, c;
Interpolator_GetKochanekBartelsParams( interpolationType, t, b, c );
Kochanek_Bartels_Spline_NormalizeX
(
t, b, c,
vPre,
vStart,
vEnd,
vNext,
f,
vOut
);
}
break;
case INTERPOLATE_SIMPLE_CUBIC:
Cubic_Spline_NormalizeX(
vPre,
vStart,
vEnd,
vNext,
f,
vOut );
break;
case INTERPOLATE_BSPLINE:
BSpline(
vPre,
vStart,
vEnd,
vNext,
f,
vOut );
break;
case INTERPOLATE_EXPONENTIAL_DECAY:
{
float dt = vEnd.x - vStart.x;
if ( dt > 0.0f )
{
float val = 1.0f - ExponentialDecay( 0.001, dt, f * dt );
vOut.y = vStart.y + val * ( vEnd.y - vStart.y );
}
else
{
vOut.y = vStart.y;
}
}
break;
case INTERPOLATE_HOLD:
{
vOut.y = vStart.y;
}
break;
}
}
void Interpolator_CurveInterpolate_NonNormalized( int interpolationType,
const Vector &vPre,
const Vector &vStart,
const Vector &vEnd,
const Vector &vNext,
float f,
Vector &vOut )
{
vOut.Init();
switch ( interpolationType )
{
default:
Warning( "Unknown interpolation type %d\n",
(int)interpolationType );
// break; // Fall through and use catmull_rom as default
case INTERPOLATE_CATMULL_ROM_NORMALIZEX:
case INTERPOLATE_DEFAULT:
case INTERPOLATE_CATMULL_ROM:
case INTERPOLATE_CATMULL_ROM_NORMALIZE:
case INTERPOLATE_CATMULL_ROM_TANGENT:
Catmull_Rom_Spline(
vPre,
vStart,
vEnd,
vNext,
f,
vOut );
break;
case INTERPOLATE_EASE_IN:
{
f = sin( M_PI * f * 0.5f );
// Fixme, since this ignores vPre and vNext we could omit computing them aove
VectorLerp( vStart, vEnd, f, vOut );
}
break;
case INTERPOLATE_EASE_OUT:
{
f = 1.0f - sin( M_PI * f * 0.5f + 0.5f * M_PI );
// Fixme, since this ignores vPre and vNext we could omit computing them aove
VectorLerp( vStart, vEnd, f, vOut );
}
break;
case INTERPOLATE_EASE_INOUT:
{
f = SimpleSpline( f );
// Fixme, since this ignores vPre and vNext we could omit computing them aove
VectorLerp( vStart, vEnd, f, vOut );
}
break;
case INTERPOLATE_LINEAR_INTERP:
// Fixme, since this ignores vPre and vNext we could omit computing them aove
VectorLerp( vStart, vEnd, f, vOut );
break;
case INTERPOLATE_KOCHANEK_BARTELS:
case INTERPOLATE_KOCHANEK_BARTELS_EARLY:
case INTERPOLATE_KOCHANEK_BARTELS_LATE:
{
float t, b, c;
Interpolator_GetKochanekBartelsParams( interpolationType, t, b, c );
Kochanek_Bartels_Spline
(
t, b, c,
vPre,
vStart,
vEnd,
vNext,
f,
vOut
);
}
break;
case INTERPOLATE_SIMPLE_CUBIC:
Cubic_Spline(
vPre,
vStart,
vEnd,
vNext,
f,
vOut );
break;
case INTERPOLATE_BSPLINE:
BSpline(
vPre,
vStart,
vEnd,
vNext,
f,
vOut );
break;
case INTERPOLATE_EXPONENTIAL_DECAY:
{
float dt = vEnd.x - vStart.x;
if ( dt > 0.0f )
{
float val = 1.0f - ExponentialDecay( 0.001, dt, f * dt );
vOut.y = vStart.y + val * ( vEnd.y - vStart.y );
}
else
{
vOut.y = vStart.y;
}
}
break;
case INTERPOLATE_HOLD:
{
vOut.y = vStart.y;
}
break;
}
}
void Interpolator_CurveInterpolate_NonNormalized( int interpolationType,
const Quaternion &vPre,
const Quaternion &vStart,
const Quaternion &vEnd,
const Quaternion &vNext,
float f,
Quaternion &vOut )
{
vOut.Init();
switch ( interpolationType )
{
default:
Warning( "Unknown interpolation type %d\n",
(int)interpolationType );
// break; // Fall through and use catmull_rom as default
case INTERPOLATE_CATMULL_ROM_NORMALIZEX:
case INTERPOLATE_DEFAULT:
case INTERPOLATE_CATMULL_ROM:
case INTERPOLATE_CATMULL_ROM_NORMALIZE:
case INTERPOLATE_CATMULL_ROM_TANGENT:
case INTERPOLATE_KOCHANEK_BARTELS:
case INTERPOLATE_KOCHANEK_BARTELS_EARLY:
case INTERPOLATE_KOCHANEK_BARTELS_LATE:
case INTERPOLATE_SIMPLE_CUBIC:
case INTERPOLATE_BSPLINE:
// FIXME, since this ignores vPre and vNext we could omit computing them aove
QuaternionSlerp( vStart, vEnd, f, vOut );
break;
case INTERPOLATE_EASE_IN:
{
f = sin( M_PI * f * 0.5f );
// Fixme, since this ignores vPre and vNext we could omit computing them aove
QuaternionSlerp( vStart, vEnd, f, vOut );
}
break;
case INTERPOLATE_EASE_OUT:
{
f = 1.0f - sin( M_PI * f * 0.5f + 0.5f * M_PI );
// Fixme, since this ignores vPre and vNext we could omit computing them aove
QuaternionSlerp( vStart, vEnd, f, vOut );
}
break;
case INTERPOLATE_EASE_INOUT:
{
f = SimpleSpline( f );
// Fixme, since this ignores vPre and vNext we could omit computing them aove
QuaternionSlerp( vStart, vEnd, f, vOut );
}
break;
case INTERPOLATE_LINEAR_INTERP:
// Fixme, since this ignores vPre and vNext we could omit computing them aove
QuaternionSlerp( vStart, vEnd, f, vOut );
break;
case INTERPOLATE_EXPONENTIAL_DECAY:
vOut.Init();
break;
case INTERPOLATE_HOLD:
{
vOut = vStart;
}
break;
}
}