metaforce/DataSpec/DNACommon/ParticleCommon.cpp

785 lines
18 KiB
C++

#include "ParticleCommon.hpp"
namespace Retro
{
namespace DNAParticle
{
void RealElementFactory::read(Athena::io::YAMLDocReader& r)
{
if (r.enterSubRecord("LFTW"))
{
m_elem.reset(new struct RELifetimeTween);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CNST"))
{
m_elem.reset(new struct REConstant);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CHAN"))
{
m_elem.reset(new struct RETimeChain);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("ADD_"))
{
m_elem.reset(new struct REAdd);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CLMP"))
{
m_elem.reset(new struct REClamp);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("KEYE"))
{
m_elem.reset(new struct REKeyframeEmitter);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("IRND"))
{
m_elem.reset(new struct REInitialRandom);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("KEYP"))
{
m_elem.reset(new struct REKeyframeEmitter);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("RAND"))
{
m_elem.reset(new struct RERandom);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("MULT"))
{
m_elem.reset(new struct REMultiply);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("PULS"))
{
m_elem.reset(new struct REPulse);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("SCAL"))
{
m_elem.reset(new struct RETimeScale);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("RLPT"))
{
m_elem.reset(new struct RELifetimePercent);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("SINE"))
{
m_elem.reset(new struct RESineWave);
m_elem->read(r);
r.leaveSubRecord();
}
else
m_elem.reset();
}
void RealElementFactory::write(Athena::io::YAMLDocWriter& w) const
{
if (m_elem)
{
w.enterSubRecord(m_elem->ClassName());
m_elem->write(w);
w.leaveSubRecord();
}
}
size_t RealElementFactory::binarySize(size_t __isz) const
{
if (m_elem)
return m_elem->binarySize(__isz + 4);
else
return __isz + 4;
}
void RealElementFactory::read(Athena::io::IStreamReader& r)
{
uint32_t clsId;
r.readBytesToBuf(&clsId, 4);
switch (clsId)
{
case SBIG('LFTW'):
m_elem.reset(new struct RELifetimeTween);
break;
case SBIG('CNST'):
m_elem.reset(new struct REConstant);
break;
case SBIG('CHAN'):
m_elem.reset(new struct RETimeChain);
break;
case SBIG('ADD_'):
m_elem.reset(new struct REAdd);
break;
case SBIG('CLMP'):
m_elem.reset(new struct REClamp);
break;
case SBIG('KEYE'):
case SBIG('KEYP'):
m_elem.reset(new struct REKeyframeEmitter);
break;
case SBIG('IRND'):
m_elem.reset(new struct REInitialRandom);
break;
case SBIG('RAND'):
m_elem.reset(new struct RERandom);
break;
case SBIG('MULT'):
m_elem.reset(new struct REMultiply);
break;
case SBIG('PULS'):
m_elem.reset(new struct REPulse);
break;
case SBIG('SCAL'):
m_elem.reset(new struct RETimeScale);
break;
case SBIG('RLPT'):
m_elem.reset(new struct RELifetimePercent);
break;
case SBIG('SINE'):
m_elem.reset(new struct RESineWave);
break;
default:
m_elem.reset();
return;
}
m_elem->read(r);
}
void RealElementFactory::write(Athena::io::IStreamWriter& w) const
{
if (m_elem)
{
w.writeBytes((atInt8*)m_elem->ClassName(), 4);
m_elem->write(w);
}
else
w.writeBytes((atInt8*)"NONE", 4);
}
void IntElementFactory::read(Athena::io::YAMLDocReader& r)
{
if (r.enterSubRecord("KEYE"))
{
m_elem.reset(new struct IEKeyframeEmitter);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("DETH"))
{
m_elem.reset(new struct IEDeath);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CLMP"))
{
m_elem.reset(new struct IEClamp);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CHAN"))
{
m_elem.reset(new struct IETimeChain);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("ADD_"))
{
m_elem.reset(new struct IEAdd);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CNST"))
{
m_elem.reset(new struct IEConstant);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("IMPL"))
{
m_elem.reset(new struct IEImpulse);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("ILPT"))
{
m_elem.reset(new struct IELifetimePercent);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("IRND"))
{
m_elem.reset(new struct IEInitialRandom);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("PULS"))
{
m_elem.reset(new struct IEPulse);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("MULT"))
{
m_elem.reset(new struct IEMultiply);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("KEYP"))
{
m_elem.reset(new struct IEKeyframeEmitter);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("SPAH"))
{
m_elem.reset(new struct IESampleAndHold);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("RAND"))
{
m_elem.reset(new struct IERandom);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("TSCL"))
{
m_elem.reset(new struct IETimeScale);
m_elem->read(r);
r.leaveSubRecord();
}
else
m_elem.reset();
}
void IntElementFactory::write(Athena::io::YAMLDocWriter& w) const
{
if (m_elem)
{
w.enterSubRecord(m_elem->ClassName());
m_elem->write(w);
w.leaveSubRecord();
}
}
size_t IntElementFactory::binarySize(size_t __isz) const
{
if (m_elem)
return m_elem->binarySize(__isz + 4);
else
return __isz + 4;
}
void IntElementFactory::read(Athena::io::IStreamReader& r)
{
uint32_t clsId;
r.readBytesToBuf(&clsId, 4);
switch (clsId)
{
case SBIG('KEYE'):
case SBIG('KEYP'):
m_elem.reset(new struct IEKeyframeEmitter);
break;
case SBIG('DETH'):
m_elem.reset(new struct IEDeath);
break;
case SBIG('CLMP'):
m_elem.reset(new struct IEClamp);
break;
case SBIG('CHAN'):
m_elem.reset(new struct IETimeChain);
break;
case SBIG('ADD_'):
m_elem.reset(new struct IEAdd);
break;
case SBIG('CNST'):
m_elem.reset(new struct IEConstant);
break;
case SBIG('IMPL'):
m_elem.reset(new struct IEImpulse);
break;
case SBIG('ILPT'):
m_elem.reset(new struct IELifetimePercent);
break;
case SBIG('IRND'):
m_elem.reset(new struct IEInitialRandom);
break;
case SBIG('PULS'):
m_elem.reset(new struct IEPulse);
break;
case SBIG('MULT'):
m_elem.reset(new struct IEMultiply);
break;
case SBIG('SPAH'):
m_elem.reset(new struct IESampleAndHold);
break;
case SBIG('RAND'):
m_elem.reset(new struct IERandom);
break;
case SBIG('TSCL'):
m_elem.reset(new struct IETimeScale);
break;
default:
m_elem.reset();
return;
}
m_elem->read(r);
}
void IntElementFactory::write(Athena::io::IStreamWriter& w) const
{
if (m_elem)
{
w.writeBytes((atInt8*)m_elem->ClassName(), 4);
m_elem->write(w);
}
else
w.writeBytes((atInt8*)"NONE", 4);
}
void VectorElementFactory::read(Athena::io::YAMLDocReader& r)
{
if (r.enterSubRecord("CONE"))
{
m_elem.reset(new struct VECone);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CHAN"))
{
m_elem.reset(new struct VETimeChain);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("ANGC"))
{
m_elem.reset(new struct VEAngleCone);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("ADD_"))
{
m_elem.reset(new struct VEAdd);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CCLU"))
{
m_elem.reset(new struct VECircleCluster);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CNST"))
{
m_elem.reset(new struct VEConstant);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CIRC"))
{
m_elem.reset(new struct VECircle);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("KEYE"))
{
m_elem.reset(new struct VEKeyframeEmitter);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("KEYP"))
{
m_elem.reset(new struct VEKeyframeEmitter);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("MULT"))
{
m_elem.reset(new struct VEMultiply);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("RTOV"))
{
m_elem.reset(new struct VERealToVector);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("PULS"))
{
m_elem.reset(new struct VEPulse);
m_elem->read(r);
r.leaveSubRecord();
}
else
m_elem.reset();
}
void VectorElementFactory::write(Athena::io::YAMLDocWriter& w) const
{
if (m_elem)
{
w.enterSubRecord(m_elem->ClassName());
m_elem->write(w);
w.leaveSubRecord();
}
}
size_t VectorElementFactory::binarySize(size_t __isz) const
{
if (m_elem)
return m_elem->binarySize(__isz + 4);
else
return __isz + 4;
}
void VectorElementFactory::read(Athena::io::IStreamReader& r)
{
uint32_t clsId;
r.readBytesToBuf(&clsId, 4);
switch (clsId)
{
case SBIG('CONE'):
m_elem.reset(new struct VECone);
break;
case SBIG('CHAN'):
m_elem.reset(new struct VETimeChain);
break;
case SBIG('ANGC'):
m_elem.reset(new struct VEAngleCone);
break;
case SBIG('ADD_'):
m_elem.reset(new struct VEAdd);
break;
case SBIG('CCLU'):
m_elem.reset(new struct VECircleCluster);
break;
case SBIG('CNST'):
m_elem.reset(new struct VEConstant);
break;
case SBIG('CIRC'):
m_elem.reset(new struct VECircle);
break;
case SBIG('KEYE'):
case SBIG('KEYP'):
m_elem.reset(new struct VEKeyframeEmitter);
break;
case SBIG('MULT'):
m_elem.reset(new struct VEMultiply);
break;
case SBIG('RTOV'):
m_elem.reset(new struct VERealToVector);
break;
case SBIG('PULS'):
m_elem.reset(new struct VEPulse);
break;
default:
m_elem.reset();
return;
}
m_elem->read(r);
}
void VectorElementFactory::write(Athena::io::IStreamWriter& w) const
{
if (m_elem)
{
w.writeBytes((atInt8*)m_elem->ClassName(), 4);
m_elem->write(w);
}
else
w.writeBytes((atInt8*)"NONE", 4);
}
void ColorElementFactory::read(Athena::io::YAMLDocReader& r)
{
if (r.enterSubRecord("KEYE"))
{
m_elem.reset(new struct CEKeyframeEmitter);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CNST"))
{
m_elem.reset(new struct CEConstant);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CHAN"))
{
m_elem.reset(new struct CETimeChain);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CFDE"))
{
m_elem.reset(new struct CEFadeEnd);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("FADE"))
{
m_elem.reset(new struct CEFade);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("KEYP"))
{
m_elem.reset(new struct CEKeyframeEmitter);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("PULS"))
{
m_elem.reset(new struct CEPulse);
m_elem->read(r);
r.leaveSubRecord();
}
else
m_elem.reset();
}
void ColorElementFactory::write(Athena::io::YAMLDocWriter& w) const
{
if (m_elem)
{
w.enterSubRecord(m_elem->ClassName());
m_elem->write(w);
w.leaveSubRecord();
}
}
size_t ColorElementFactory::binarySize(size_t __isz) const
{
if (m_elem)
return m_elem->binarySize(__isz + 4);
else
return __isz + 4;
}
void ColorElementFactory::read(Athena::io::IStreamReader& r)
{
uint32_t clsId;
r.readBytesToBuf(&clsId, 4);
switch (clsId)
{
case SBIG('KEYE'):
case SBIG('KEYP'):
m_elem.reset(new struct CEKeyframeEmitter);
break;
case SBIG('CNST'):
m_elem.reset(new struct CEConstant);
break;
case SBIG('CHAN'):
m_elem.reset(new struct CETimeChain);
break;
case SBIG('CFDE'):
m_elem.reset(new struct CEFadeEnd);
break;
case SBIG('FADE'):
m_elem.reset(new struct CEFade);
break;
case SBIG('PULS'):
m_elem.reset(new struct CEPulse);
break;
default:
m_elem.reset();
return;
}
m_elem->read(r);
}
void ColorElementFactory::write(Athena::io::IStreamWriter& w) const
{
if (m_elem)
{
w.writeBytes((atInt8*)m_elem->ClassName(), 4);
m_elem->write(w);
}
else
w.writeBytes((atInt8*)"NONE", 4);
}
void ModVectorElementFactory::read(Athena::io::YAMLDocReader& r)
{
if (r.enterSubRecord("IMPL"))
{
m_elem.reset(new struct MVEImplosion);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("EMPL"))
{
m_elem.reset(new struct MVEExponentialImplosion);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CHAN"))
{
m_elem.reset(new struct MVETimeChain);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("BNCE"))
{
m_elem.reset(new struct MVEBounce);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("CNST"))
{
m_elem.reset(new struct MVEConstant);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("GRAV"))
{
m_elem.reset(new struct MVEGravity);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("EXPL"))
{
m_elem.reset(new struct MVEExplode);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("SPOS"))
{
m_elem.reset(new struct MVESetPosition);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("LMPL"))
{
m_elem.reset(new struct MVELinearImplosion);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("PULS"))
{
m_elem.reset(new struct MVEPulse);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("WIND"))
{
m_elem.reset(new struct MVEWind);
m_elem->read(r);
r.leaveSubRecord();
}
else if (r.enterSubRecord("SWRL"))
{
m_elem.reset(new struct MVESwirl);
m_elem->read(r);
r.leaveSubRecord();
}
else
m_elem.reset();
}
void ModVectorElementFactory::write(Athena::io::YAMLDocWriter& w) const
{
if (m_elem)
{
w.enterSubRecord(m_elem->ClassName());
m_elem->write(w);
w.leaveSubRecord();
}
}
size_t ModVectorElementFactory::binarySize(size_t __isz) const
{
if (m_elem)
return m_elem->binarySize(__isz + 4);
else
return __isz + 4;
}
void ModVectorElementFactory::read(Athena::io::IStreamReader& r)
{
uint32_t clsId;
r.readBytesToBuf(&clsId, 4);
switch (clsId)
{
case SBIG('IMPL'):
m_elem.reset(new struct MVEImplosion);
break;
case SBIG('EMPL'):
m_elem.reset(new struct MVEExponentialImplosion);
break;
case SBIG('CHAN'):
m_elem.reset(new struct MVETimeChain);
break;
case SBIG('BNCE'):
m_elem.reset(new struct MVEBounce);
break;
case SBIG('CNST'):
m_elem.reset(new struct MVEConstant);
break;
case SBIG('GRAV'):
m_elem.reset(new struct MVEGravity);
break;
case SBIG('EXPL'):
m_elem.reset(new struct MVEExplode);
break;
case SBIG('SPOS'):
m_elem.reset(new struct MVESetPosition);
break;
case SBIG('LMPL'):
m_elem.reset(new struct MVELinearImplosion);
break;
case SBIG('PULS'):
m_elem.reset(new struct MVEPulse);
break;
case SBIG('WIND'):
m_elem.reset(new struct MVEWind);
break;
case SBIG('SWRL'):
m_elem.reset(new struct MVESwirl);
break;
default:
m_elem.reset();
return;
}
m_elem->read(r);
}
void ModVectorElementFactory::write(Athena::io::IStreamWriter& w) const
{
if (m_elem)
{
w.writeBytes((atInt8*)m_elem->ClassName(), 4);
m_elem->write(w);
}
else
w.writeBytes((atInt8*)"NONE", 4);
}
}
}