#include "zeus/Math.hpp" #include "ANIM.hpp" #define DUMP_KEYS 0 namespace DataSpec { namespace DNAANIM { size_t ComputeBitstreamSize(size_t keyFrameCount, const std::vector& channels) { size_t bitsPerKeyFrame = 0; for (const Channel& chan : channels) { switch (chan.type) { case Channel::Type::Rotation: bitsPerKeyFrame += 1; case Channel::Type::Translation: case Channel::Type::Scale: bitsPerKeyFrame += chan.q[0]; bitsPerKeyFrame += chan.q[1]; bitsPerKeyFrame += chan.q[2]; break; case Channel::Type::KfHead: bitsPerKeyFrame += 1; break; case Channel::Type::RotationMP3: bitsPerKeyFrame += chan.q[0]; bitsPerKeyFrame += chan.q[1]; bitsPerKeyFrame += chan.q[2]; bitsPerKeyFrame += chan.q[3]; break; default: break; } } return (bitsPerKeyFrame * keyFrameCount + 31) / 32 * 4; } static inline QuantizedRot QuantizeRotation(const Value& quat, atUint32 div) { float q = M_PIF / 2.0f / float(div); return { { atInt16(std::asin(quat.v4.vec[1]) / q), atInt16(std::asin(quat.v4.vec[2]) / q), atInt16(std::asin(quat.v4.vec[3]) / q), }, (quat.v4.vec[0] < 0.f) ? true : false }; } static inline Value DequantizeRotation(const QuantizedRot& v, atUint32 div) { float q = M_PIF / 2.0f / float(div); Value retval = { 0.0f, std::sin(v.v[0] * q), std::sin(v.v[1] * q), std::sin(v.v[2] * q), }; retval.v4.vec[0] = std::sqrt(std::max((1.0f - (retval.v4.vec[1] * retval.v4.vec[1] + retval.v4.vec[2] * retval.v4.vec[2] + retval.v4.vec[3] * retval.v4.vec[3])), 0.0f)); retval.v4.vec[0] = v.w ? -retval.v4.vec[0] : retval.v4.vec[0]; return retval; } static inline Value DequantizeRotation_3(const QuantizedRot& v, atUint32 div) { float q = 1.0f / float(div); Value retval = { 0.0f, v.v[0] * q, v.v[1] * q, v.v[2] * q, }; retval.v4.vec[0] = std::sqrt(std::max((1.0f - (retval.v4.vec[1] * retval.v4.vec[1] + retval.v4.vec[2] * retval.v4.vec[2] + retval.v4.vec[3] * retval.v4.vec[3])), 0.0f)); retval.v4.vec[0] = v.w ? -retval.v4.vec[0] : retval.v4.vec[0]; return retval; } bool BitstreamReader::dequantizeBit(const atUint8* data) { atUint32 byteCur = (m_bitCur / 32) * 4; atUint32 bitRem = m_bitCur % 32; /* Fill 32 bit buffer with region containing bits */ /* Make them least significant */ atUint32 tempBuf = hecl::SBig(*reinterpret_cast(data + byteCur)) >> bitRem; /* That's it */ m_bitCur += 1; return tempBuf & 0x1; } atInt16 BitstreamReader::dequantize(const atUint8* data, atUint8 q) { atUint32 byteCur = (m_bitCur / 32) * 4; atUint32 bitRem = m_bitCur % 32; /* Fill 32 bit buffer with region containing bits */ /* Make them least significant */ atUint32 tempBuf = hecl::SBig(*reinterpret_cast(data + byteCur)) >> bitRem; /* If this shift underflows the value, buffer the next 32 bits */ /* And tack onto shifted buffer */ if ((bitRem + q) > 32) { atUint32 tempBuf2 = hecl::SBig(*reinterpret_cast(data + byteCur + 4)); tempBuf |= (tempBuf2 << (32 - bitRem)); } /* Mask it */ atUint32 mask = (1 << q) - 1; tempBuf &= mask; /* Sign extend */ atUint32 sign = (tempBuf >> (q - 1)) & 0x1; if (sign) tempBuf |= ~0 << q; /* Return delta value */ m_bitCur += q; return atInt32(tempBuf); } std::vector> BitstreamReader::read(const atUint8* data, size_t keyFrameCount, const std::vector& channels, atUint32 rotDiv, float transMult) { m_bitCur = 0; std::vector> chanKeys; std::vector chanAccum; chanKeys.reserve(channels.size()); chanAccum.reserve(channels.size()); for (const Channel& chan : channels) { chanAccum.push_back(chan.i); chanKeys.emplace_back(); std::vector& keys = chanKeys.back(); keys.reserve(keyFrameCount); switch (chan.type) { case Channel::Type::Rotation: { QuantizedRot qr = {{chan.i[0], chan.i[1], chan.i[2]}, false}; keys.emplace_back(DequantizeRotation(qr, rotDiv)); break; } case Channel::Type::Translation: { keys.push_back({chan.i[0] * transMult, chan.i[1] * transMult, chan.i[2] * transMult}); break; } case Channel::Type::Scale: { keys.push_back({chan.i[0] / float(rotDiv), chan.i[1] / float(rotDiv), chan.i[2] / float(rotDiv)}); break; } case Channel::Type::KfHead: { break; } case Channel::Type::RotationMP3: { QuantizedRot qr = {{chan.i[1], chan.i[2], chan.i[3]}, bool(chan.i[0] & 0x1)}; keys.emplace_back(DequantizeRotation_3(qr, rotDiv)); break; } default: break; } } for (size_t f=0 ; femplace_back(DequantizeRotation(qr, rotDiv)); #if DUMP_KEYS fprintf(stderr, "%d R: %d %d %d %d\t", chan.id, wBit, p[0], p[1], p[2]); #endif break; } case Channel::Type::Translation: { atInt16 val1 = dequantize(data, chan.q[0]); p[0] += val1; atInt16 val2 = dequantize(data, chan.q[1]); p[1] += val2; atInt16 val3 = dequantize(data, chan.q[2]); p[2] += val3; kit->push_back({p[0] * transMult, p[1] * transMult, p[2] * transMult}); #if DUMP_KEYS fprintf(stderr, "%d T: %d %d %d\t", chan.id, p[0], p[1], p[2]); #endif break; } case Channel::Type::Scale: { p[0] += dequantize(data, chan.q[0]); p[1] += dequantize(data, chan.q[1]); p[2] += dequantize(data, chan.q[2]); kit->push_back({p[0] / float(rotDiv), p[1] / float(rotDiv), p[2] / float(rotDiv)}); #if DUMP_KEYS fprintf(stderr, "%d S: %d %d %d\t", chan.id, p[0], p[1], p[2]); #endif break; } case Channel::Type::KfHead: { bool aBit = dequantizeBit(data); break; } case Channel::Type::RotationMP3: { atInt16 val1 = dequantize(data, chan.q[0]); p[0] += val1; atInt16 val2 = dequantize(data, chan.q[1]); p[1] += val2; atInt16 val3 = dequantize(data, chan.q[2]); p[2] += val3; atInt16 val4 = dequantize(data, chan.q[3]); p[3] += val4; QuantizedRot qr = {{p[1], p[2], p[3]}, bool(p[0] & 0x1)}; kit->emplace_back(DequantizeRotation_3(qr, rotDiv)); break; } default: break; } ++kit; ++ait; } #if DUMP_KEYS fprintf(stderr, "\n"); #endif } return chanKeys; } void BitstreamWriter::quantizeBit(atUint8* data, bool val) { atUint32 byteCur = (m_bitCur / 32) * 4; atUint32 bitRem = m_bitCur % 32; /* Fill 32 bit buffer with region containing bits */ /* Make them least significant */ *(atUint32*)(data + byteCur) = hecl::SBig(hecl::SBig(*(atUint32*)(data + byteCur)) | (val << bitRem)); m_bitCur += 1; } void BitstreamWriter::quantize(atUint8* data, atUint8 q, atInt16 val) { atUint32 byteCur = (m_bitCur / 32) * 4; atUint32 bitRem = m_bitCur % 32; atUint32 masked = val & ((1 << q) - 1); /* Fill 32 bit buffer with region containing bits */ /* Make them least significant */ *(atUint32*)(data + byteCur) = hecl::SBig(hecl::SBig(*(atUint32*)(data + byteCur)) | (masked << bitRem)); /* If this shift underflows the value, buffer the next 32 bits */ /* And tack onto shifted buffer */ if ((bitRem + q) > 32) { *(atUint32*)(data + byteCur + 4) = hecl::SBig(hecl::SBig(*(atUint32*)(data + byteCur + 4)) | (masked >> (32 - bitRem))); } m_bitCur += q; } std::unique_ptr BitstreamWriter::write(const std::vector>& chanKeys, size_t keyFrameCount, std::vector& channels, atUint32& rotDivOut, float& transMultOut, size_t& sizeOut) { m_bitCur = 0; rotDivOut = 32767; /* Normalized range of values */ /* Pre-pass to calculate translation multiplier */ float maxTransDiff = 0.0f; auto kit = chanKeys.begin(); for (Channel& chan : channels) { switch (chan.type) { case Channel::Type::Translation: { const Value* last = &(*kit)[0]; for (auto it=kit->begin() + 1; it != kit->end(); ++it) { const Value* current = &*it; maxTransDiff = std::max(maxTransDiff, current->v3.vec[0] - last->v3.vec[0]); maxTransDiff = std::max(maxTransDiff, current->v3.vec[1] - last->v3.vec[1]); maxTransDiff = std::max(maxTransDiff, current->v3.vec[2] - last->v3.vec[2]); last = current; } break; } default: break; } ++kit; } transMultOut = maxTransDiff / 32767; /* Output channel inits */ kit = chanKeys.begin(); for (Channel& chan : channels) { chan.q[0] = 1; chan.q[1] = 1; chan.q[2] = 1; switch (chan.type) { case Channel::Type::Rotation: { QuantizedRot qr = QuantizeRotation((*kit)[0], rotDivOut); chan.i = qr.v; break; } case Channel::Type::Translation: { chan.i = {atInt16((*kit)[0].v3.vec[0] / transMultOut), atInt16((*kit)[0].v3.vec[1] / transMultOut), atInt16((*kit)[0].v3.vec[2] / transMultOut)}; break; } case Channel::Type::Scale: { chan.i = {atInt16((*kit)[0].v3.vec[0] * rotDivOut), atInt16((*kit)[0].v3.vec[1] * rotDivOut), atInt16((*kit)[0].v3.vec[2] * rotDivOut)}; break; } default: break; } ++kit; } /* Pre-pass to analyze quantization factors for channels */ kit = chanKeys.begin(); for (Channel& chan : channels) { switch (chan.type) { case Channel::Type::Rotation: { QuantizedRot qrLast = QuantizeRotation((*kit)[0], rotDivOut); for (auto it=kit->begin() + 1; it != kit->end(); ++it) { QuantizedRot qrCur = QuantizeRotation(*it, rotDivOut); chan.q[0] = std::max(chan.q[0], atUint8(ceilf(log2f(qrCur.v[0] - qrLast.v[0])))); chan.q[1] = std::max(chan.q[1], atUint8(ceilf(log2f(qrCur.v[1] - qrLast.v[1])))); chan.q[2] = std::max(chan.q[2], atUint8(ceilf(log2f(qrCur.v[2] - qrLast.v[2])))); qrLast = qrCur; } break; } case Channel::Type::Translation: { QuantizedValue last = {atInt16((*kit)[0].v3.vec[0] / transMultOut), atInt16((*kit)[0].v3.vec[1] / transMultOut), atInt16((*kit)[0].v3.vec[2] / transMultOut)}; for (auto it=kit->begin() + 1; it != kit->end(); ++it) { QuantizedValue cur = {atInt16(it->v3.vec[0] / transMultOut), atInt16(it->v3.vec[1] / transMultOut), atInt16(it->v3.vec[2] / transMultOut)}; chan.q[0] = std::max(chan.q[0], atUint8(ceilf(log2f(cur[0] - last[0])))); chan.q[1] = std::max(chan.q[1], atUint8(ceilf(log2f(cur[1] - last[1])))); chan.q[2] = std::max(chan.q[2], atUint8(ceilf(log2f(cur[2] - last[2])))); last = cur; } break; } case Channel::Type::Scale: { QuantizedValue last = {atInt16((*kit)[0].v3.vec[0] * rotDivOut), atInt16((*kit)[0].v3.vec[1] * rotDivOut), atInt16((*kit)[0].v3.vec[2] * rotDivOut)}; for (auto it=kit->begin() + 1; it != kit->end(); ++it) { QuantizedValue cur = {atInt16(it->v3.vec[0] * rotDivOut), atInt16(it->v3.vec[1] * rotDivOut), atInt16(it->v3.vec[2] * rotDivOut)}; chan.q[0] = std::max(chan.q[0], atUint8(ceilf(log2f(cur[0] - last[0])))); chan.q[1] = std::max(chan.q[1], atUint8(ceilf(log2f(cur[1] - last[1])))); chan.q[2] = std::max(chan.q[2], atUint8(ceilf(log2f(cur[2] - last[2])))); last = cur; } break; } default: break; } ++kit; } /* Generate Bitstream */ sizeOut = ComputeBitstreamSize(keyFrameCount, channels); atUint8* newData = new atUint8[sizeOut]; for (size_t f=0 ; fbegin() + 1; it != kit->end(); ++it) { QuantizedRot qrCur = QuantizeRotation(*it, rotDivOut); quantizeBit(newData, qrCur.w); quantize(newData, chan.q[0], qrCur.v[0] - qrLast.v[0]); quantize(newData, chan.q[1], qrCur.v[1] - qrLast.v[1]); quantize(newData, chan.q[2], qrCur.v[2] - qrLast.v[2]); qrLast = qrCur; } break; } case Channel::Type::Translation: { QuantizedValue last = {atInt16((*kit)[0].v3.vec[0] / transMultOut), atInt16((*kit)[0].v3.vec[1] / transMultOut), atInt16((*kit)[0].v3.vec[2] / transMultOut)}; for (auto it=kit->begin() + 1; it != kit->end(); ++it) { QuantizedValue cur = {atInt16(it->v3.vec[0] / transMultOut), atInt16(it->v3.vec[1] / transMultOut), atInt16(it->v3.vec[2] / transMultOut)}; quantize(newData, chan.q[0], cur[0] - last[0]); quantize(newData, chan.q[1], cur[1] - last[1]); quantize(newData, chan.q[2], cur[2] - last[2]); last = cur; } break; } case Channel::Type::Scale: { QuantizedValue last = {atInt16((*kit)[0].v3.vec[0] * rotDivOut), atInt16((*kit)[0].v3.vec[1] * rotDivOut), atInt16((*kit)[0].v3.vec[2] * rotDivOut)}; for (auto it=kit->begin() + 1; it != kit->end(); ++it) { QuantizedValue cur = {atInt16(it->v3.vec[0] * rotDivOut), atInt16(it->v3.vec[1] * rotDivOut), atInt16(it->v3.vec[2] * rotDivOut)}; quantize(newData, chan.q[0], cur[0] - last[0]); quantize(newData, chan.q[1], cur[1] - last[1]); quantize(newData, chan.q[2], cur[2] - last[2]); last = cur; } break; } default: break; } ++kit; } } return std::unique_ptr(newData); } } }