#include "ParticleCommon.hpp" namespace DataSpec::DNAParticle { logvisor::Module LogModule("urde::DNAParticle"); template <> void REConstant::Enumerate(typename ReadYaml::StreamT& r) { val = r.readFloat(nullptr); } template <> void REConstant::Enumerate(typename WriteYaml::StreamT& w) { w.writeFloat(nullptr, val); } template <> void REConstant::Enumerate(typename BinarySize::StreamT& s) { s += 4; } template <> void REConstant::Enumerate(typename Read::StreamT& r) { val = r.readFloatBig(); } template <> void REConstant::Enumerate(typename Write::StreamT& w) { w.writeFloatBig(val); } template <> void IEConstant::Enumerate(typename ReadYaml::StreamT& r) { val = r.readUint32(nullptr); } template <> void IEConstant::Enumerate(typename WriteYaml::StreamT& w) { w.writeUint32(nullptr, val); } template <> void IEConstant::Enumerate(typename BinarySize::StreamT& s) { s += 4; } template <> void IEConstant::Enumerate(typename Read::StreamT& r) { val = r.readUint32Big(); } template <> void IEConstant::Enumerate(typename Write::StreamT& w) { w.writeUint32Big(val); } template <> void VEConstant::Enumerate(typename ReadYaml::StreamT& r) { size_t elemCount; if (auto v = r.enterSubVector(nullptr, elemCount)) { for (size_t i = 0; i < 3 && i < elemCount; ++i) { if (auto rec = r.enterSubRecord(nullptr)) comps[i].read(r); } } } template <> void VEConstant::Enumerate(typename WriteYaml::StreamT& w) { if (auto v = w.enterSubVector(nullptr)) for (int i = 0; i < 3; ++i) if (auto rec = w.enterSubRecord(nullptr)) comps[i].write(w); } template <> void VEConstant::Enumerate(typename BinarySize::StreamT& s) { comps[0].binarySize(s); comps[1].binarySize(s); comps[2].binarySize(s); } template <> void VEConstant::Enumerate(typename Read::StreamT& r) { comps[0].read(r); comps[1].read(r); comps[2].read(r); } template <> void VEConstant::Enumerate(typename Write::StreamT& w) { comps[0].write(w); comps[1].write(w); comps[2].write(w); } template <> void CEConstant::Enumerate(typename ReadYaml::StreamT& r) { for (int i = 0; i < 4; ++i) if (auto rec = r.enterSubRecord(nullptr)) comps[i].read(r); } template <> void CEConstant::Enumerate(typename WriteYaml::StreamT& w) { if (auto v = w.enterSubVector(nullptr)) for (int i = 0; i < 4; ++i) if (auto rec = w.enterSubRecord(nullptr)) comps[i].write(w); } template <> void CEConstant::Enumerate(typename BinarySize::StreamT& s) { comps[0].binarySize(s); comps[1].binarySize(s); comps[2].binarySize(s); comps[3].binarySize(s); } template <> void CEConstant::Enumerate(typename Read::StreamT& r) { comps[0].read(r); comps[1].read(r); comps[2].read(r); comps[3].read(r); } template <> void CEConstant::Enumerate(typename Write::StreamT& w) { comps[0].write(w); comps[1].write(w); comps[2].write(w); comps[3].write(w); } template <> void MVEConstant::Enumerate(typename ReadYaml::StreamT& r) { for (int i = 0; i < 3; ++i) if (auto rec = r.enterSubRecord(nullptr)) comps[i].read(r); } template <> void MVEConstant::Enumerate(typename WriteYaml::StreamT& w) { if (auto v = w.enterSubVector(nullptr)) for (int i = 0; i < 3; ++i) if (auto rec = w.enterSubRecord(nullptr)) comps[i].write(w); } template <> void MVEConstant::Enumerate(typename BinarySize::StreamT& s) { comps[0].binarySize(s); comps[1].binarySize(s); comps[2].binarySize(s); } template <> void MVEConstant::Enumerate(typename Read::StreamT& r) { comps[0].read(r); comps[1].read(r); comps[2].read(r); } template <> void MVEConstant::Enumerate(typename Write::StreamT& w) { comps[0].write(w); comps[1].write(w); comps[2].write(w); } template <> void RealElementFactory::Enumerate(typename ReadYaml::StreamT& r) { const auto& mapChildren = r.getCurNode()->m_mapChildren; if (mapChildren.empty()) { m_elem.reset(); return; } const auto& elem = mapChildren[0]; if (elem.first.size() < 4) LogModule.report(logvisor::Fatal, fmt("short FourCC in element '{}'"), elem.first); switch (*reinterpret_cast(elem.first.data())) { 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; case SBIG('ISWT'): m_elem.reset(new struct REInitialSwitch); break; case SBIG('CLTN'): m_elem.reset(new struct RECompareLessThan); break; case SBIG('CEQL'): m_elem.reset(new struct RECompareEquals); break; case SBIG('PAP1'): m_elem.reset(new struct REParticleAdvanceParam1); break; case SBIG('PAP2'): m_elem.reset(new struct REParticleAdvanceParam2); break; case SBIG('PAP3'): m_elem.reset(new struct REParticleAdvanceParam3); break; case SBIG('PAP4'): m_elem.reset(new struct REParticleAdvanceParam4); break; case SBIG('PAP5'): m_elem.reset(new struct REParticleAdvanceParam5); break; case SBIG('PAP6'): m_elem.reset(new struct REParticleAdvanceParam6); break; case SBIG('PAP7'): m_elem.reset(new struct REParticleAdvanceParam7); break; case SBIG('PAP8'): m_elem.reset(new struct REParticleAdvanceParam8); break; case SBIG('PSLL'): m_elem.reset(new struct REParticleSizeOrLineLength); break; case SBIG('PRLW'): m_elem.reset(new struct REParticleRotationOrLineWidth); break; case SBIG('SUB_'): m_elem.reset(new struct RESubtract); break; case SBIG('VMAG'): m_elem.reset(new struct REVectorMagnitude); break; case SBIG('VXTR'): m_elem.reset(new struct REVectorXToReal); break; case SBIG('VYTR'): m_elem.reset(new struct REVectorYToReal); break; case SBIG('VZTR'): m_elem.reset(new struct REVectorZToReal); break; case SBIG('CEXT'): m_elem.reset(new struct RECEXT); break; case SBIG('ITRL'): m_elem.reset(new struct REIntTimesReal); break; default: m_elem.reset(); return; } if (auto rec = r.enterSubRecord(elem.first.c_str())) m_elem->read(r); } template <> void RealElementFactory::Enumerate(typename WriteYaml::StreamT& w) { if (m_elem) if (auto rec = w.enterSubRecord(m_elem->ClassID())) m_elem->write(w); } template <> void RealElementFactory::Enumerate(typename BinarySize::StreamT& s) { s += 4; if (m_elem) m_elem->binarySize(s); } template <> void RealElementFactory::Enumerate(typename Read::StreamT& r) { DNAFourCC clsId; clsId.read(r); switch (clsId.toUint32()) { 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; case SBIG('ISWT'): m_elem.reset(new struct REInitialSwitch); break; case SBIG('CLTN'): m_elem.reset(new struct RECompareLessThan); break; case SBIG('CEQL'): m_elem.reset(new struct RECompareEquals); break; case SBIG('PAP1'): m_elem.reset(new struct REParticleAdvanceParam1); break; case SBIG('PAP2'): m_elem.reset(new struct REParticleAdvanceParam2); break; case SBIG('PAP3'): m_elem.reset(new struct REParticleAdvanceParam3); break; case SBIG('PAP4'): m_elem.reset(new struct REParticleAdvanceParam4); break; case SBIG('PAP5'): m_elem.reset(new struct REParticleAdvanceParam5); break; case SBIG('PAP6'): m_elem.reset(new struct REParticleAdvanceParam6); break; case SBIG('PAP7'): m_elem.reset(new struct REParticleAdvanceParam7); break; case SBIG('PAP8'): m_elem.reset(new struct REParticleAdvanceParam8); break; case SBIG('PSLL'): m_elem.reset(new struct REParticleSizeOrLineLength); break; case SBIG('PRLW'): m_elem.reset(new struct REParticleRotationOrLineWidth); break; case SBIG('SUB_'): m_elem.reset(new struct RESubtract); break; case SBIG('VMAG'): m_elem.reset(new struct REVectorMagnitude); break; case SBIG('VXTR'): m_elem.reset(new struct REVectorXToReal); break; case SBIG('VYTR'): m_elem.reset(new struct REVectorYToReal); break; case SBIG('VZTR'): m_elem.reset(new struct REVectorZToReal); break; case SBIG('CEXT'): m_elem.reset(new struct RECEXT); break; case SBIG('ITRL'): m_elem.reset(new struct REIntTimesReal); break; case SBIG('NONE'): m_elem.reset(); return; default: m_elem.reset(); LogModule.report(logvisor::Fatal, fmt("Unknown RealElement class {} @{}"), clsId, r.position()); return; } m_elem->read(r); } template <> void RealElementFactory::Enumerate(typename Write::StreamT& w) { if (m_elem) { w.writeBytes((atInt8*)m_elem->ClassID(), 4); m_elem->write(w); } else w.writeBytes((atInt8*)"NONE", 4); } template <> void IntElementFactory::Enumerate(typename ReadYaml::StreamT& r) { const auto& mapChildren = r.getCurNode()->m_mapChildren; if (mapChildren.empty()) { m_elem.reset(); return; } const auto& elem = mapChildren[0]; if (elem.first.size() < 4) LogModule.report(logvisor::Fatal, fmt("short FourCC in element '{}'"), elem.first); switch (*reinterpret_cast(elem.first.data())) { 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; case SBIG('GTCP'): m_elem.reset(new struct IEGTCP); break; case SBIG('MODU'): m_elem.reset(new struct IEModulo); break; case SBIG('SUB_'): m_elem.reset(new struct IESubtract); break; default: m_elem.reset(); return; } if (auto rec = r.enterSubRecord(elem.first.c_str())) m_elem->read(r); } template <> void IntElementFactory::Enumerate(typename WriteYaml::StreamT& w) { if (m_elem) if (auto rec = w.enterSubRecord(m_elem->ClassID())) m_elem->write(w); } template <> void IntElementFactory::Enumerate(typename BinarySize::StreamT& s) { s += 4; if (m_elem) m_elem->binarySize(s); } template <> void IntElementFactory::Enumerate(typename Read::StreamT& r) { DNAFourCC clsId; clsId.read(r); switch (clsId.toUint32()) { 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; case SBIG('GTCP'): m_elem.reset(new struct IEGTCP); break; case SBIG('MODU'): m_elem.reset(new struct IEModulo); break; case SBIG('SUB_'): m_elem.reset(new struct IESubtract); break; case SBIG('NONE'): m_elem.reset(); return; default: m_elem.reset(); LogModule.report(logvisor::Fatal, fmt("Unknown IntElement class {} @{}"), clsId, r.position()); return; } m_elem->read(r); } template <> void IntElementFactory::Enumerate(typename Write::StreamT& w) { if (m_elem) { w.writeBytes((atInt8*)m_elem->ClassID(), 4); m_elem->write(w); } else w.writeBytes((atInt8*)"NONE", 4); } template <> void VectorElementFactory::Enumerate(typename ReadYaml::StreamT& r) { const auto& mapChildren = r.getCurNode()->m_mapChildren; if (mapChildren.empty()) { m_elem.reset(); return; } const auto& elem = mapChildren[0]; if (elem.first.size() < 4) LogModule.report(logvisor::Fatal, fmt("short FourCC in element '{}'"), elem.first); switch (*reinterpret_cast(elem.first.data())) { 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; case SBIG('PVEL'): m_elem.reset(new struct VEParticleVelocity); break; case SBIG('SPOS'): m_elem.reset(new struct VESPOS); break; case SBIG('PLCO'): m_elem.reset(new struct VEPLCO); break; case SBIG('PLOC'): m_elem.reset(new struct VEPLOC); break; case SBIG('PSOR'): m_elem.reset(new struct VEPSOR); break; case SBIG('PSOF'): m_elem.reset(new struct VEPSOF); break; default: m_elem.reset(); return; } if (auto rec = r.enterSubRecord(elem.first.c_str())) m_elem->read(r); } template <> void VectorElementFactory::Enumerate(typename WriteYaml::StreamT& w) { if (m_elem) if (auto rec = w.enterSubRecord(m_elem->ClassID())) m_elem->write(w); } template <> void VectorElementFactory::Enumerate(typename BinarySize::StreamT& s) { s += 4; if (m_elem) m_elem->binarySize(s); } template <> void VectorElementFactory::Enumerate(typename Read::StreamT& r) { DNAFourCC clsId; clsId.read(r); switch (clsId.toUint32()) { 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; case SBIG('PVEL'): m_elem.reset(new struct VEParticleVelocity); break; case SBIG('SPOS'): m_elem.reset(new struct VESPOS); break; case SBIG('PLCO'): m_elem.reset(new struct VEPLCO); break; case SBIG('PLOC'): m_elem.reset(new struct VEPLOC); break; case SBIG('PSOR'): m_elem.reset(new struct VEPSOR); break; case SBIG('PSOF'): m_elem.reset(new struct VEPSOF); break; case SBIG('NONE'): m_elem.reset(); return; default: m_elem.reset(); LogModule.report(logvisor::Fatal, fmt("Unknown VectorElement class {} @{}"), clsId, r.position()); return; } m_elem->read(r); } template <> void VectorElementFactory::Enumerate(typename Write::StreamT& w) { if (m_elem) { w.writeBytes((atInt8*)m_elem->ClassID(), 4); m_elem->write(w); } else w.writeBytes((atInt8*)"NONE", 4); } template <> void ColorElementFactory::Enumerate(typename ReadYaml::StreamT& r) { const auto& mapChildren = r.getCurNode()->m_mapChildren; if (mapChildren.empty()) { m_elem.reset(); return; } const auto& elem = mapChildren[0]; if (elem.first.size() < 4) LogModule.report(logvisor::Fatal, fmt("short FourCC in element '{}'"), elem.first); switch (*reinterpret_cast(elem.first.data())) { 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; } if (auto rec = r.enterSubRecord(elem.first.c_str())) m_elem->read(r); } template <> void ColorElementFactory::Enumerate(typename WriteYaml::StreamT& w) { if (m_elem) if (auto rec = w.enterSubRecord(m_elem->ClassID())) m_elem->write(w); } template <> void ColorElementFactory::Enumerate(typename BinarySize::StreamT& s) { s += 4; if (m_elem) m_elem->binarySize(s); } template <> void ColorElementFactory::Enumerate(typename Read::StreamT& r) { DNAFourCC clsId; clsId.read(r); switch (clsId.toUint32()) { 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; case SBIG('NONE'): m_elem.reset(); return; default: m_elem.reset(); LogModule.report(logvisor::Fatal, fmt("Unknown ColorElement class {} @{}"), clsId, r.position()); return; } m_elem->read(r); } template <> void ColorElementFactory::Enumerate(typename Write::StreamT& w) { if (m_elem) { w.writeBytes((atInt8*)m_elem->ClassID(), 4); m_elem->write(w); } else w.writeBytes((atInt8*)"NONE", 4); } template <> void ModVectorElementFactory::Enumerate(typename ReadYaml::StreamT& r) { const auto& mapChildren = r.getCurNode()->m_mapChildren; if (mapChildren.empty()) { m_elem.reset(); return; } const auto& elem = mapChildren[0]; if (elem.first.size() < 4) LogModule.report(logvisor::Fatal, fmt("short FourCC in element '{}'"), elem.first); switch (*reinterpret_cast(elem.first.data())) { 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; } if (auto rec = r.enterSubRecord(elem.first.c_str())) m_elem->read(r); } template <> void ModVectorElementFactory::Enumerate(typename WriteYaml::StreamT& w) { if (m_elem) if (auto rec = w.enterSubRecord(m_elem->ClassID())) m_elem->write(w); } template <> void ModVectorElementFactory::Enumerate(typename BinarySize::StreamT& s) { s += 4; if (m_elem) m_elem->binarySize(s); } template <> void ModVectorElementFactory::Enumerate(typename Read::StreamT& r) { DNAFourCC clsId; clsId.read(r); switch (clsId.toUint32()) { 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; case SBIG('NONE'): m_elem.reset(); return; default: m_elem.reset(); LogModule.report(logvisor::Fatal, fmt("Unknown ModVectorElement class {} @{}"), clsId, r.position()); return; } m_elem->read(r); } template <> void ModVectorElementFactory::Enumerate(typename Write::StreamT& w) { if (m_elem) { w.writeBytes((atInt8*)m_elem->ClassID(), 4); m_elem->write(w); } else w.writeBytes((atInt8*)"NONE", 4); } template <> void EmitterElementFactory::Enumerate(typename ReadYaml::StreamT& r) { const auto& mapChildren = r.getCurNode()->m_mapChildren; if (mapChildren.empty()) { m_elem.reset(); return; } const auto& elem = mapChildren[0]; if (elem.first.size() < 4) LogModule.report(logvisor::Fatal, fmt("short FourCC in element '{}'"), elem.first); switch (*reinterpret_cast(elem.first.data())) { case SBIG('SETR'): m_elem.reset(new struct EESimpleEmitterTR); break; case SBIG('SEMR'): m_elem.reset(new struct EESimpleEmitter); break; case SBIG('SPHE'): m_elem.reset(new struct VESphere); break; case SBIG('ASPH'): m_elem.reset(new struct VEAngleSphere); break; default: m_elem.reset(); return; } if (auto rec = r.enterSubRecord(elem.first.c_str())) m_elem->read(r); } template <> void EmitterElementFactory::Enumerate(typename WriteYaml::StreamT& w) { if (m_elem) if (auto rec = w.enterSubRecord(m_elem->ClassID())) m_elem->write(w); } template <> void EmitterElementFactory::Enumerate(typename BinarySize::StreamT& s) { s += 4; if (m_elem) m_elem->binarySize(s); } template <> void EmitterElementFactory::Enumerate(typename Read::StreamT& r) { DNAFourCC clsId; clsId.read(r); switch (clsId.toUint32()) { case SBIG('SETR'): m_elem.reset(new struct EESimpleEmitterTR); break; case SBIG('SEMR'): m_elem.reset(new struct EESimpleEmitter); break; case SBIG('SPHE'): m_elem.reset(new struct VESphere); break; case SBIG('ASPH'): m_elem.reset(new struct VEAngleSphere); break; case SBIG('NONE'): m_elem.reset(); return; default: m_elem.reset(); LogModule.report(logvisor::Fatal, fmt("Unknown EmitterElement class {} @{}"), clsId, r.position()); return; } m_elem->read(r); } template <> void EmitterElementFactory::Enumerate(typename Write::StreamT& w) { if (m_elem) { w.writeBytes((atInt8*)m_elem->ClassID(), 4); m_elem->write(w); } else w.writeBytes((atInt8*)"NONE", 4); } template <> void BoolHelper::Enumerate(typename ReadYaml::StreamT& r) { value = r.readBool(nullptr); } template <> void BoolHelper::Enumerate(typename WriteYaml::StreamT& w) { w.writeBool(nullptr, value); } template <> void BoolHelper::Enumerate(typename BinarySize::StreamT& s) { s += 5; } template <> void BoolHelper::Enumerate(typename Read::StreamT& r) { uint32_t clsId; r.readBytesToBuf(&clsId, 4); if (clsId == SBIG('CNST')) value = r.readBool(); else value = false; } template <> void BoolHelper::Enumerate(typename Write::StreamT& w) { w.writeBytes((atInt8*)"CNST", 4); w.writeBool(value); } template <> void EESimpleEmitterTR::Enumerate(typename ReadYaml::StreamT& r) { position.m_elem.reset(); velocity.m_elem.reset(); if (auto rec = r.enterSubRecord("ILOC")) position.read(r); if (auto rec = r.enterSubRecord("IVEC")) velocity.read(r); } template <> void EESimpleEmitterTR::Enumerate(typename WriteYaml::StreamT& w) { if (auto rec = w.enterSubRecord("ILOC")) position.write(w); if (auto rec = w.enterSubRecord("IVEC")) velocity.write(w); } template <> void EESimpleEmitterTR::Enumerate(typename BinarySize::StreamT& s) { s += 8; position.binarySize(s); velocity.binarySize(s); } template <> void EESimpleEmitterTR::Enumerate(typename Read::StreamT& r) { position.m_elem.reset(); velocity.m_elem.reset(); uint32_t clsId; r.readBytesToBuf(&clsId, 4); if (clsId == SBIG('ILOC')) { position.read(r); r.readBytesToBuf(&clsId, 4); if (clsId == SBIG('IVEC')) velocity.read(r); } } template <> void EESimpleEmitterTR::Enumerate(typename Write::StreamT& w) { w.writeBytes((atInt8*)"ILOC", 4); position.write(w); w.writeBytes((atInt8*)"IVEC", 4); velocity.write(w); } template <> const char* UVEConstant::DNAType() { return "UVEConstant"; } template <> const char* UVEConstant::DNAType() { return "UVEConstant"; } template void UVEConstant::_read(typename ReadYaml::StreamT& r) { tex.clear(); if (auto rec = r.enterSubRecord("tex")) tex.read(r); } template void UVEConstant::_write(typename WriteYaml::StreamT& w) const { if (auto rec = w.enterSubRecord("tex")) tex.write(w); } template void UVEConstant::_binarySize(typename BinarySize::StreamT& _s) const { _s += 4; tex.binarySize(_s); } template void UVEConstant::_read(typename Read::StreamT& r) { tex.clear(); uint32_t clsId; r.readBytesToBuf(&clsId, 4); if (clsId == SBIG('CNST')) tex.read(r); } template void UVEConstant::_write(typename Write::StreamT& w) const { w.writeBytes((atInt8*)"CNST", 4); tex.write(w); } AT_SUBSPECIALIZE_DNA_YAML(UVEConstant) AT_SUBSPECIALIZE_DNA_YAML(UVEConstant) template struct UVEConstant; template struct UVEConstant; template <> const char* UVEAnimTexture::DNAType() { return "UVEAnimTexture"; } template <> const char* UVEAnimTexture::DNAType() { return "UVEAnimTexture"; } template void UVEAnimTexture::_read(typename ReadYaml::StreamT& r) { tex.clear(); if (auto rec = r.enterSubRecord("tex")) tex.read(r); if (auto rec = r.enterSubRecord("tileW")) tileW.read(r); if (auto rec = r.enterSubRecord("tileH")) tileH.read(r); if (auto rec = r.enterSubRecord("strideW")) strideW.read(r); if (auto rec = r.enterSubRecord("strideH")) strideH.read(r); if (auto rec = r.enterSubRecord("cycleFrames")) cycleFrames.read(r); if (auto rec = r.enterSubRecord("loop")) loop = r.readBool(nullptr); } template void UVEAnimTexture::_write(typename WriteYaml::StreamT& w) const { if (auto rec = w.enterSubRecord("tex")) tex.write(w); if (auto rec = w.enterSubRecord("tileW")) tileW.write(w); if (auto rec = w.enterSubRecord("tileH")) tileH.write(w); if (auto rec = w.enterSubRecord("strideW")) strideW.write(w); if (auto rec = w.enterSubRecord("strideH")) strideH.write(w); if (auto rec = w.enterSubRecord("cycleFrames")) cycleFrames.write(w); w.writeBool("loop", loop); } template void UVEAnimTexture::_binarySize(typename BinarySize::StreamT& _s) const { _s += 9; tex.binarySize(_s); tileW.binarySize(_s); tileH.binarySize(_s); strideW.binarySize(_s); strideH.binarySize(_s); cycleFrames.binarySize(_s); } template void UVEAnimTexture::_read(typename Read::StreamT& r) { tex.clear(); uint32_t clsId; r.readBytesToBuf(&clsId, 4); if (clsId == SBIG('CNST')) tex.read(r); tileW.read(r); tileH.read(r); strideW.read(r); strideH.read(r); cycleFrames.read(r); r.readBytesToBuf(&clsId, 4); if (clsId == SBIG('CNST')) loop = r.readBool(); } template void UVEAnimTexture::_write(typename Write::StreamT& w) const { w.writeBytes((atInt8*)"CNST", 4); tex.write(w); tileW.write(w); tileH.write(w); strideW.write(w); strideH.write(w); cycleFrames.write(w); w.writeBytes((atInt8*)"CNST", 4); w.writeBool(loop); } AT_SUBSPECIALIZE_DNA_YAML(UVEAnimTexture) AT_SUBSPECIALIZE_DNA_YAML(UVEAnimTexture) template struct UVEAnimTexture; template struct UVEAnimTexture; template <> const char* UVElementFactory::DNAType() { return "UVElementFactory"; } template <> const char* UVElementFactory::DNAType() { return "UVElementFactory"; } template void UVElementFactory::_read(typename Read::StreamT& r) { uint32_t clsId; r.readBytesToBuf(&clsId, 4); switch (clsId) { case SBIG('CNST'): m_elem.reset(new struct UVEConstant); break; case SBIG('ATEX'): m_elem.reset(new struct UVEAnimTexture); break; default: m_elem.reset(); return; } m_elem->read(r); } template void UVElementFactory::_write(typename Write::StreamT& w) const { if (m_elem) { w.writeBytes((atInt8*)m_elem->ClassID(), 4); m_elem->write(w); } else w.writeBytes((atInt8*)"NONE", 4); } template void UVElementFactory::_read(typename ReadYaml::StreamT& r) { if (auto rec = r.enterSubRecord("CNST")) { m_elem.reset(new struct UVEConstant); m_elem->read(r); } else if (auto rec = r.enterSubRecord("ATEX")) { m_elem.reset(new struct UVEAnimTexture); m_elem->read(r); } else m_elem.reset(); } template void UVElementFactory::_write(typename WriteYaml::StreamT& w) const { if (m_elem) if (auto rec = w.enterSubRecord(m_elem->ClassID())) m_elem->write(w); } template void UVElementFactory::_binarySize(typename BinarySize::StreamT& _s) const { if (m_elem) m_elem->binarySize(_s); _s += 4; } AT_SUBSPECIALIZE_DNA_YAML(UVElementFactory) AT_SUBSPECIALIZE_DNA_YAML(UVElementFactory) template struct UVElementFactory; template struct UVElementFactory; template <> const char* SpawnSystemKeyframeData::SpawnSystemKeyframeInfo::DNAType() { return "SpawnSystemKeyframeData::SpawnSystemKeyframeInfo"; } template <> const char* SpawnSystemKeyframeData::SpawnSystemKeyframeInfo::DNAType() { return "SpawnSystemKeyframeData::SpawnSystemKeyframeInfo"; } template template void SpawnSystemKeyframeData::SpawnSystemKeyframeInfo::Enumerate(typename Op::StreamT& s) { Do({"id"}, id, s); Do({"a"}, a, s); Do({"b"}, b, s); Do({"c"}, c, s); } template <> const char* SpawnSystemKeyframeData::DNAType() { return "SpawnSystemKeyframeData"; } template <> const char* SpawnSystemKeyframeData::DNAType() { return "SpawnSystemKeyframeData"; } template void SpawnSystemKeyframeData::_read(typename ReadYaml::StreamT& r) { if (auto rec = r.enterSubRecord("a")) a = r.readUint32(nullptr); if (auto rec = r.enterSubRecord("b")) b = r.readUint32(nullptr); if (auto rec = r.enterSubRecord("endFrame")) endFrame = r.readUint32(nullptr); if (auto rec = r.enterSubRecord("d")) d = r.readUint32(nullptr); spawns.clear(); size_t spawnCount; if (auto v = r.enterSubVector("spawns", spawnCount)) { spawns.reserve(spawnCount); for (const auto& child : r.getCurNode()->m_seqChildren) { (void)child; if (auto rec = r.enterSubRecord(nullptr)) { spawns.emplace_back(); spawns.back().first = r.readUint32("startFrame"); size_t systemCount; if (auto v = r.enterSubVector("systems", systemCount)) { spawns.back().second.reserve(systemCount); for (const auto& in : r.getCurNode()->m_seqChildren) { (void)in; spawns.back().second.emplace_back(); SpawnSystemKeyframeInfo& info = spawns.back().second.back(); if (auto rec = r.enterSubRecord(nullptr)) info.read(r); } } } } } } template void SpawnSystemKeyframeData::_write(typename WriteYaml::StreamT& w) const { if (spawns.empty()) return; w.writeUint32("a", a); w.writeUint32("b", b); w.writeUint32("endFrame", endFrame); w.writeUint32("d", d); if (auto v = w.enterSubVector("spawns")) { for (const auto& spawn : spawns) { if (auto rec = w.enterSubRecord(nullptr)) { w.writeUint32("startFrame", spawn.first); if (auto v = w.enterSubVector("systems")) for (const auto& info : spawn.second) if (auto rec = w.enterSubRecord(nullptr)) info.write(w); } } } } template void SpawnSystemKeyframeData::_binarySize(typename BinarySize::StreamT& s) const { s += 20; for (const auto& spawn : spawns) { s += 8; for (const auto& info : spawn.second) info.binarySize(s); } } template void SpawnSystemKeyframeData::_read(typename Read::StreamT& r) { uint32_t clsId; r.readBytesToBuf(&clsId, 4); if (clsId != SBIG('CNST')) return; a = r.readUint32Big(); b = r.readUint32Big(); endFrame = r.readUint32Big(); d = r.readUint32Big(); uint32_t count = r.readUint32Big(); spawns.clear(); spawns.reserve(count); for (size_t i = 0; i < count; ++i) { spawns.emplace_back(); spawns.back().first = r.readUint32Big(); uint32_t infoCount = r.readUint32Big(); spawns.back().second.reserve(infoCount); for (size_t j = 0; j < infoCount; ++j) { spawns.back().second.emplace_back(); spawns.back().second.back().read(r); } } } template void SpawnSystemKeyframeData::_write(typename Write::StreamT& w) const { if (spawns.empty()) { w.writeBytes((atInt8*)"NONE", 4); return; } w.writeBytes((atInt8*)"CNST", 4); w.writeUint32Big(a); w.writeUint32Big(b); w.writeUint32Big(endFrame); w.writeUint32Big(d); w.writeUint32Big(spawns.size()); for (const auto& spawn : spawns) { w.writeUint32Big(spawn.first); w.writeUint32Big(spawn.second.size()); for (const auto& info : spawn.second) info.write(w); } } AT_SUBSPECIALIZE_DNA_YAML(SpawnSystemKeyframeData) AT_SUBSPECIALIZE_DNA_YAML(SpawnSystemKeyframeData) template struct SpawnSystemKeyframeData; template struct SpawnSystemKeyframeData; template <> const char* ChildResourceFactory::DNAType() { return "ChildResourceFactory"; } template <> const char* ChildResourceFactory::DNAType() { return "ChildResourceFactory"; } template void ChildResourceFactory::_read(typename ReadYaml::StreamT& r) { id.clear(); if (auto rec = r.enterSubRecord("CNST")) id.read(r); } template void ChildResourceFactory::_write(typename WriteYaml::StreamT& w) const { if (id.isValid()) if (auto rec = w.enterSubRecord("CNST")) id.write(w); } template void ChildResourceFactory::_binarySize(typename BinarySize::StreamT& s) const { if (id.isValid()) id.binarySize(s); s += 4; } template void ChildResourceFactory::_read(typename Read::StreamT& r) { id.clear(); uint32_t clsId; r.readBytesToBuf(&clsId, 4); if (clsId == SBIG('CNST')) id.read(r); } template void ChildResourceFactory::_write(typename Write::StreamT& w) const { if (id.isValid()) { w.writeBytes((atInt8*)"CNST", 4); id.write(w); } else w.writeBytes((atInt8*)"NONE", 4); } AT_SUBSPECIALIZE_DNA_YAML(ChildResourceFactory) AT_SUBSPECIALIZE_DNA_YAML(ChildResourceFactory) template struct ChildResourceFactory; template struct ChildResourceFactory; } // namespace DataSpec::DNAParticle