metaforce/Runtime/Character/CAnimSource.cpp

219 lines
9.0 KiB
C++
Raw Permalink Normal View History

#include "Runtime/Character/CAnimSource.hpp"
#include <algorithm>
#include "Runtime/Character/CAnimPOIData.hpp"
#include "Runtime/Character/CSegId.hpp"
#include "Runtime/Character/CSegIdList.hpp"
#include "Runtime/Character/CSegStatementSet.hpp"
2016-04-11 23:35:37 +00:00
2021-04-10 08:42:06 +00:00
namespace metaforce {
2016-04-11 23:35:37 +00:00
static constexpr float ClampZeroToOne(float in) { return std::clamp(in, 0.0f, 1.0f); }
2016-04-11 23:35:37 +00:00
2018-12-08 05:30:43 +00:00
u32 RotationAndOffsetStorage::DataSizeInBytes(u32 rotPerFrame, u32 transPerFrame, u32 frameCount) {
return (transPerFrame * 12 + rotPerFrame * 16) * frameCount;
2016-04-11 23:35:37 +00:00
}
void RotationAndOffsetStorage::CopyRotationsAndOffsets(const std::vector<zeus::CQuaternion>& rots,
2018-12-08 05:30:43 +00:00
const std::vector<zeus::CVector3f>& offs, u32 frameCount,
float* arrOut) {
std::vector<zeus::CQuaternion>::const_iterator rit = rots.cbegin();
std::vector<zeus::CVector3f>::const_iterator oit = offs.cbegin();
u32 rotsPerFrame = rots.size() / frameCount;
u32 offsPerFrame = offs.size() / frameCount;
for (u32 i = 0; i < frameCount; ++i) {
for (u32 j = 0; j < rotsPerFrame; ++j) {
const zeus::CQuaternion& rot = *rit++;
arrOut[0] = rot.w();
arrOut[1] = rot.x();
arrOut[2] = rot.y();
arrOut[3] = rot.z();
arrOut += 4;
2016-04-11 23:35:37 +00:00
}
2018-12-08 05:30:43 +00:00
for (u32 j = 0; j < offsPerFrame; ++j) {
const zeus::CVector3f& off = *oit++;
arrOut[0] = off.x();
arrOut[1] = off.y();
arrOut[2] = off.z();
arrOut += 3;
2016-04-11 23:35:37 +00:00
}
2018-12-08 05:30:43 +00:00
}
}
std::unique_ptr<float[]> RotationAndOffsetStorage::GetRotationsAndOffsets(const std::vector<zeus::CQuaternion>& rots,
const std::vector<zeus::CVector3f>& offs,
u32 frameCount) {
u32 size = DataSizeInBytes(rots.size() / frameCount, offs.size() / frameCount, frameCount);
std::unique_ptr<float[]> ret(new float[(size / 4 + 1) * 4]);
CopyRotationsAndOffsets(rots, offs, frameCount, ret.get());
return ret;
}
RotationAndOffsetStorage::CRotationAndOffsetVectors::CRotationAndOffsetVectors(CInputStream& in) {
const u32 quatCount = in.readUint32Big();
2018-12-08 05:30:43 +00:00
x0_rotations.reserve(quatCount);
for (u32 i = 0; i < quatCount; ++i) {
x0_rotations.emplace_back().readBig(in);
2018-12-08 05:30:43 +00:00
}
const u32 vecCount = in.readUint32Big();
2018-12-08 05:30:43 +00:00
x10_offsets.reserve(vecCount);
for (u32 i = 0; i < vecCount; ++i) {
x10_offsets.emplace_back().readBig(in);
2018-12-08 05:30:43 +00:00
}
}
u32 RotationAndOffsetStorage::GetFrameSizeInBytes() const { return (x10_transPerFrame * 12 + xc_rotPerFrame * 16); }
RotationAndOffsetStorage::RotationAndOffsetStorage(const CRotationAndOffsetVectors& vectors, u32 frameCount) {
x0_storage = GetRotationsAndOffsets(vectors.x0_rotations, vectors.x10_offsets, frameCount);
x8_frameCount = frameCount;
xc_rotPerFrame = vectors.x0_rotations.size() / frameCount;
x10_transPerFrame = vectors.x10_offsets.size() / frameCount;
}
static std::vector<u8> ReadIndexTable(CInputStream& in) {
std::vector<u8> ret;
u32 count = in.readUint32Big();
ret.reserve(count);
for (u32 i = 0; i < count; ++i)
ret.push_back(in.readUByte());
return ret;
}
void CAnimSource::CalcAverageVelocity() {
u8 rootIdx = x20_rotationChannels[3];
u8 rootTransIdx = x30_translationChannels[rootIdx];
float accum = 0.f;
const u32 floatsPerFrame = x40_data.x10_transPerFrame * 3 + x40_data.xc_rotPerFrame * 4;
const u32 rotFloatsPerFrame = x40_data.xc_rotPerFrame * 4;
for (u32 i = 1; i < x10_frameCount; ++i) {
const float* frameDataA = &x40_data.x0_storage[(i - 1) * floatsPerFrame + rotFloatsPerFrame + rootTransIdx * 3];
const float* frameDataB = &x40_data.x0_storage[i * floatsPerFrame + rotFloatsPerFrame + rootTransIdx * 3];
zeus::CVector3f vecA(frameDataA[0], frameDataA[1], frameDataA[2]);
zeus::CVector3f vecB(frameDataB[0], frameDataB[1], frameDataB[2]);
float frameVel = (vecB - vecA).magnitude();
if (frameVel > 0.00001f)
accum += frameVel;
}
x60_averageVelocity = accum / x0_duration.GetSeconds();
2016-04-11 23:35:37 +00:00
}
2018-12-08 05:30:43 +00:00
CAnimSource::CAnimSource(CInputStream& in, IObjectStore& store)
: x0_duration(in)
, x8_interval(in)
, x10_frameCount(in.readUint32Big())
, x1c_rootBone(in)
, x20_rotationChannels(ReadIndexTable(in))
, x30_translationChannels(ReadIndexTable(in))
, x40_data(RotationAndOffsetStorage::CRotationAndOffsetVectors(in), x10_frameCount)
, x54_evntId(in.readUint32Big()) {
if (x54_evntId.IsValid()) {
x58_evntData = store.GetObj({SBIG('EVNT'), x54_evntId});
x58_evntData.GetObj();
}
CalcAverageVelocity();
}
void CAnimSource::GetSegStatementSet(const CSegIdList& list, CSegStatementSet& set, const CCharAnimTime& time) const {
const auto frameIdx = u32(time / x8_interval);
2018-12-08 05:30:43 +00:00
float remTime = time.GetSeconds() - frameIdx * x8_interval.GetSeconds();
if (std::fabs(remTime) < 0.00001f) {
2018-12-08 05:30:43 +00:00
remTime = 0.f;
}
const float t = ClampZeroToOne(remTime / x8_interval.GetSeconds());
2018-12-08 05:30:43 +00:00
const u32 floatsPerFrame = x40_data.x10_transPerFrame * 3 + x40_data.xc_rotPerFrame * 4;
const u32 rotFloatsPerFrame = x40_data.xc_rotPerFrame * 4;
for (const CSegId& id : list.GetList()) {
const u8 rotIdx = x20_rotationChannels[id];
2018-12-08 05:30:43 +00:00
if (rotIdx != 0xff) {
const float* frameDataA = &x40_data.x0_storage[frameIdx * floatsPerFrame + rotIdx * 4];
const float* frameDataB = &x40_data.x0_storage[(frameIdx + 1) * floatsPerFrame + rotIdx * 4];
const zeus::CQuaternion quatA(frameDataA[0], frameDataA[1], frameDataA[2], frameDataA[3]);
const zeus::CQuaternion quatB(frameDataB[0], frameDataB[1], frameDataB[2], frameDataB[3]);
set[id].x0_rotation = zeus::CQuaternion::slerp(quatA, quatB, t);
2018-12-08 05:30:43 +00:00
const u8 transIdx = x30_translationChannels[rotIdx];
2018-12-08 05:30:43 +00:00
if (transIdx != 0xff) {
const float* frameVecDataA = &x40_data.x0_storage[frameIdx * floatsPerFrame + rotFloatsPerFrame + transIdx * 3];
const float* frameVecDataB =
2018-12-08 05:30:43 +00:00
&x40_data.x0_storage[(frameIdx - 1) * floatsPerFrame + rotFloatsPerFrame + transIdx * 3];
const zeus::CVector3f vecA(frameVecDataA[0], frameVecDataA[1], frameVecDataA[2]);
const zeus::CVector3f vecB(frameVecDataB[0], frameVecDataB[1], frameVecDataB[2]);
set[id].x10_offset = zeus::CVector3f::lerp(vecA, vecB, t);
set[id].x1c_hasOffset = true;
2018-12-08 05:30:43 +00:00
}
2016-04-11 23:35:37 +00:00
}
2018-12-08 05:30:43 +00:00
}
2016-04-11 23:35:37 +00:00
}
2018-12-08 05:30:43 +00:00
const std::vector<CSoundPOINode>& CAnimSource::GetSoundPOIStream() const { return x58_evntData->GetSoundPOIStream(); }
const std::vector<CParticlePOINode>& CAnimSource::GetParticlePOIStream() const {
return x58_evntData->GetParticlePOIStream();
2016-04-11 23:35:37 +00:00
}
2018-12-08 05:30:43 +00:00
const std::vector<CInt32POINode>& CAnimSource::GetInt32POIStream() const { return x58_evntData->GetInt32POIStream(); }
const std::vector<CBoolPOINode>& CAnimSource::GetBoolPOIStream() const { return x58_evntData->GetBoolPOIStream(); }
zeus::CQuaternion CAnimSource::GetRotation(const CSegId& seg, const CCharAnimTime& time) const {
u8 rotIdx = x20_rotationChannels[seg];
if (rotIdx != 0xff) {
2016-04-11 23:35:37 +00:00
u32 frameIdx = unsigned(time / x8_interval);
2017-07-10 04:55:51 +00:00
float remTime = time.GetSeconds() - frameIdx * x8_interval.GetSeconds();
2016-04-11 23:35:37 +00:00
if (std::fabs(remTime) < 0.00001f)
2018-12-08 05:30:43 +00:00
remTime = 0.f;
2017-07-10 04:55:51 +00:00
float t = ClampZeroToOne(remTime / x8_interval.GetSeconds());
2016-04-11 23:35:37 +00:00
2018-12-08 05:30:43 +00:00
const u32 floatsPerFrame = x40_data.x10_transPerFrame * 3 + x40_data.xc_rotPerFrame * 4;
const float* frameDataA = &x40_data.x0_storage[frameIdx * floatsPerFrame + rotIdx * 4];
const float* frameDataB = &x40_data.x0_storage[(frameIdx + 1) * floatsPerFrame + rotIdx * 4];
2016-04-11 23:35:37 +00:00
2018-12-08 05:30:43 +00:00
zeus::CQuaternion quatA(frameDataA[0], frameDataA[1], frameDataA[2], frameDataA[3]);
zeus::CQuaternion quatB(frameDataB[0], frameDataB[1], frameDataB[2], frameDataB[3]);
return zeus::CQuaternion::slerp(quatA, quatB, t);
} else {
return {};
}
2016-04-11 23:35:37 +00:00
}
2018-12-08 05:30:43 +00:00
zeus::CVector3f CAnimSource::GetOffset(const CSegId& seg, const CCharAnimTime& time) const {
u8 rotIdx = x20_rotationChannels[seg];
if (rotIdx != 0xff) {
u8 transIdx = x30_translationChannels[rotIdx];
if (transIdx == 0xff)
return {};
2016-04-11 23:35:37 +00:00
2018-12-08 05:30:43 +00:00
u32 frameIdx = unsigned(time / x8_interval);
float remTime = time.GetSeconds() - frameIdx * x8_interval.GetSeconds();
if (std::fabs(remTime) < 0.00001f)
remTime = 0.f;
float t = ClampZeroToOne(remTime / x8_interval.GetSeconds());
2016-04-11 23:35:37 +00:00
2018-12-08 05:30:43 +00:00
const u32 floatsPerFrame = x40_data.x10_transPerFrame * 3 + x40_data.xc_rotPerFrame * 4;
const u32 rotFloatsPerFrame = x40_data.xc_rotPerFrame * 4;
const float* frameDataA = &x40_data.x0_storage[frameIdx * floatsPerFrame + rotFloatsPerFrame + transIdx * 3];
const float* frameDataB = &x40_data.x0_storage[(frameIdx - 1) * floatsPerFrame + rotFloatsPerFrame + transIdx * 3];
zeus::CVector3f vecA(frameDataA[0], frameDataA[1], frameDataA[2]);
zeus::CVector3f vecB(frameDataB[0], frameDataB[1], frameDataB[2]);
return zeus::CVector3f::lerp(vecA, vecB, t);
} else {
return {};
}
2016-04-11 23:35:37 +00:00
}
2018-12-08 05:30:43 +00:00
bool CAnimSource::HasOffset(const CSegId& seg) const {
u8 rotIdx = x20_rotationChannels[seg];
if (rotIdx == 0xff)
return false;
u8 transIdx = x30_translationChannels[rotIdx];
return transIdx != 0xff;
2016-04-11 23:35:37 +00:00
}
2021-04-10 08:42:06 +00:00
} // namespace metaforce