metaforce/DataSpec/DNAMP1/ANIM.hpp

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#ifndef _DNAMP1_ANIM_HPP_
#define _DNAMP1_ANIM_HPP_
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#include "BlenderConnection.hpp"
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#include "DNAMP1.hpp"
#include "../DNACommon/ANIM.hpp"
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#include "DataSpec/DNACommon/RigInverter.hpp"
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#include "CINF.hpp"
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namespace DataSpec
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{
namespace DNAMP1
{
struct ANIM : BigDNA
{
Delete expl;
struct IANIM : BigDNA
{
Delete expl;
atUint32 m_version;
IANIM(atUint32 version) : m_version(version) {}
std::vector<std::pair<atUint32, bool>> bones;
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std::vector<atUint32> frames;
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std::vector<DNAANIM::Channel> channels;
std::vector<std::vector<DNAANIM::Value>> chanKeys;
float mainInterval = 0.0;
UniqueID32 evnt;
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void sendANIMToBlender(hecl::BlenderConnection::PyOutStream&, const DNAANIM::RigInverter<CINF>& rig) const;
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};
struct ANIM0 : IANIM
{
DECL_EXPLICIT_DNA
ANIM0() : IANIM(0) {}
struct Header : BigDNA
{
DECL_DNA
Value<float> duration;
Value<atUint32> unk0;
Value<float> interval;
Value<atUint32> unk1;
Value<atUint32> keyCount;
Value<atUint32> unk2;
Value<atUint32> boneSlotCount;
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};
};
struct ANIM2 : IANIM
{
DECL_EXPLICIT_DNA
ANIM2(bool pc) : IANIM(pc ? 3 : 2) {}
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struct Header : BigDNA
{
DECL_DNA
Value<atUint32> scratchSize;
UniqueID32 evnt;
Value<atUint32> unk0 = 1;
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Value<float> duration;
Value<float> interval;
Value<atUint32> rootBoneId = 3;
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Value<atUint32> looping = 0;
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Value<atUint32> rotDiv;
Value<float> translationMult;
Value<atUint32> boneChannelCount;
Value<atUint32> unk3;
Value<atUint32> keyBitmapBitCount;
};
struct ChannelDesc : BigDNA
{
Delete expl;
Value<atUint32> id = 0;
Value<atUint16> keyCount1 = 0;
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Value<atInt16> initRX = 0;
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Value<atUint8> qRX = 0;
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Value<atInt16> initRY = 0;
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Value<atUint8> qRY = 0;
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Value<atInt16> initRZ = 0;
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Value<atUint8> qRZ = 0;
Value<atUint16> keyCount2 = 0;
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Value<atInt16> initTX = 0;
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Value<atUint8> qTX = 0;
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Value<atInt16> initTY = 0;
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Value<atUint8> qTY = 0;
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Value<atInt16> initTZ = 0;
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Value<atUint8> qTZ = 0;
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void read(athena::io::IStreamReader& reader)
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{
id = reader.readUint32Big();
keyCount1 = reader.readUint16Big();
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initRX = reader.readInt16Big();
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qRX = reader.readUByte();
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initRY = reader.readInt16Big();
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qRY = reader.readUByte();
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initRZ = reader.readInt16Big();
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qRZ = reader.readUByte();
keyCount2 = reader.readUint16Big();
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if (keyCount2)
{
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initTX = reader.readInt16Big();
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qTX = reader.readUByte();
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initTY = reader.readInt16Big();
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qTY = reader.readUByte();
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initTZ = reader.readInt16Big();
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qTZ = reader.readUByte();
}
}
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void write(athena::io::IStreamWriter& writer) const
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{
writer.writeUint32Big(id);
writer.writeUint16Big(keyCount1);
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writer.writeInt16Big(initRX);
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writer.writeUByte(qRX);
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writer.writeInt16Big(initRY);
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writer.writeUByte(qRY);
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writer.writeInt16Big(initRZ);
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writer.writeUByte(qRZ);
writer.writeUint16Big(keyCount2);
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if (keyCount2)
{
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writer.writeInt16Big(initTX);
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writer.writeUByte(qTX);
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writer.writeInt16Big(initTY);
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writer.writeUByte(qTY);
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writer.writeInt16Big(initTZ);
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writer.writeUByte(qTZ);
}
}
size_t binarySize(size_t __isz) const
{
__isz += 17;
if (keyCount2)
__isz += 9;
return __isz;
}
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};
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struct ChannelDescPC : BigDNA
{
Delete expl;
Value<atUint32> id = 0;
Value<atUint32> keyCount1 = 0;
Value<atUint32> QinitRX = 0;
Value<atUint32> QinitRY = 0;
Value<atUint32> QinitRZ = 0;
Value<atUint32> keyCount2 = 0;
Value<atUint32> QinitTX = 0;
Value<atUint32> QinitTY = 0;
Value<atUint32> QinitTZ = 0;
void read(athena::io::IStreamReader& reader)
{
id = reader.readUint32Big();
keyCount1 = reader.readUint32Big();
QinitRX = reader.readUint32Big();
QinitRY = reader.readUint32Big();
QinitRZ = reader.readUint32Big();
keyCount2 = reader.readUint32Big();
if (keyCount2)
{
QinitTX = reader.readUint32Big();
QinitTY = reader.readUint32Big();
QinitTZ = reader.readUint32Big();
}
}
void write(athena::io::IStreamWriter& writer) const
{
writer.writeUint32Big(id);
writer.writeUint32Big(keyCount1);
writer.writeUint32Big(QinitRX);
writer.writeUint32Big(QinitRY);
writer.writeUint32Big(QinitRZ);
writer.writeUint32Big(keyCount2);
if (keyCount2)
{
writer.writeUint32Big(QinitTX);
writer.writeUint32Big(QinitTY);
writer.writeUint32Big(QinitTZ);
}
}
size_t binarySize(size_t __isz) const
{
__isz += 24;
if (keyCount2)
__isz += 12;
return __isz;
}
};
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};
std::unique_ptr<IANIM> m_anim;
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void read(athena::io::IStreamReader& reader)
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{
atUint32 version = reader.readUint32Big();
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switch (version)
{
case 0:
m_anim.reset(new struct ANIM0);
m_anim->read(reader);
break;
case 2:
m_anim.reset(new struct ANIM2(false));
m_anim->read(reader);
break;
case 3:
m_anim.reset(new struct ANIM2(true));
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m_anim->read(reader);
break;
default:
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Log.report(logvisor::Error, "unrecognized ANIM version");
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break;
}
}
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void write(athena::io::IStreamWriter& writer) const
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{
writer.writeUint32Big(m_anim->m_version);
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m_anim->write(writer);
}
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size_t binarySize(size_t __isz) const
{
return m_anim->binarySize(__isz + 4);
}
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void sendANIMToBlender(hecl::BlenderConnection::PyOutStream& os, const DNAANIM::RigInverter<CINF>& rig, bool) const
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{
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m_anim->sendANIMToBlender(os, rig);
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}
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using BlenderAction = hecl::BlenderConnection::DataStream::Actor::Action;
ANIM() = default;
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ANIM(const BlenderAction& act,
const std::unordered_map<std::string, atInt32>& idMap,
const DNAANIM::RigInverter<CINF>& rig,
bool pc);
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};
}
}
#endif // _DNAMP1_ANIM_HPP_