#include "PAK.hpp" #include "DNAMP3.hpp" namespace DataSpec::DNAMP3 { const hecl::FourCC CMPD("CMPD"); template <> void PAK::Enumerate(athena::io::IStreamReader& reader) { m_header.read(reader); if (m_header.version != 2) Log.report(logvisor::Fatal, "unexpected PAK magic"); reader.seek(8, athena::Current); atUint32 strgSz = reader.readUint32Big(); reader.seek(4, athena::Current); atUint32 rshdSz = reader.readUint32Big(); reader.seek(44, athena::Current); atUint32 dataOffset = 128 + strgSz + rshdSz; atUint64 strgBase = reader.position(); atUint32 nameCount = reader.readUint32Big(); m_nameEntries.clear(); m_nameEntries.reserve(nameCount); for (atUint32 n = 0; n < nameCount; ++n) { m_nameEntries.emplace_back(); m_nameEntries.back().read(reader); } reader.seek(strgBase + strgSz, athena::Begin); atUint32 count = reader.readUint32Big(); m_entries.clear(); m_entries.reserve(count); m_firstEntries.clear(); m_firstEntries.reserve(count); std::vector entries; entries.reserve(count); for (atUint32 e = 0; e < count; ++e) { entries.emplace_back(); entries.back().read(reader); } for (atUint32 e = 0; e < count; ++e) { Entry& entry = entries[e]; entry.offset += dataOffset; auto search = m_entries.find(entry.id); if (search == m_entries.end()) { m_firstEntries.push_back(entry.id); m_entries[entry.id] = std::move(entry); } else { /* Find next MREA to record which area has dupes */ for (atUint32 e2 = e + 1; e2 < count; ++e2) { Entry& entry2 = entries[e2]; if (entry2.type != FOURCC('MREA')) continue; m_dupeMREAs.insert(entry2.id); break; } } } m_nameMap.clear(); m_nameMap.reserve(nameCount); for (NameEntry& entry : m_nameEntries) m_nameMap[entry.name] = entry.id; } template <> void PAK::Enumerate(athena::io::IStreamWriter& writer) { m_header.write(writer); DNAFourCC("STRG").write(writer); atUint32 strgSz = 4; for (const NameEntry& entry : m_nameEntries) strgSz += (atUint32)entry.name.size() + 13; atUint32 strgPad = ((strgSz + 63) & ~63) - strgSz; strgSz += strgPad; writer.writeUint32Big(strgSz); DNAFourCC("RSHD").write(writer); atUint32 rshdSz = 4 + 24 * m_entries.size(); atUint32 rshdPad = ((rshdSz + 63) & ~63) - rshdSz; rshdSz += rshdPad; writer.writeUint32Big(rshdSz); atUint32 dataOffset = 128 + strgSz + rshdSz; DNAFourCC("DATA").write(writer); atUint32 dataSz = 0; for (const auto& entry : m_entries) dataSz += (entry.second.size + 63) & ~63; atUint32 dataPad = ((dataSz + 63) & ~63) - dataSz; dataSz += dataPad; writer.writeUint32Big(dataSz); writer.seek(36, athena::Current); writer.writeUint32Big((atUint32)m_nameEntries.size()); for (const NameEntry& entry : m_nameEntries) entry.write(writer); writer.seek(strgPad, athena::Current); writer.writeUint32Big((atUint32)m_entries.size()); for (const auto& entry : m_entries) { Entry copy = entry.second; copy.offset -= dataOffset; copy.write(writer); } writer.seek(rshdPad, athena::Current); } template <> void PAK::Enumerate(size_t& __isz) { m_header.binarySize(__isz); size_t strgSz = 4; for (const NameEntry& entry : m_nameEntries) strgSz += entry.name.size() + 13; size_t strgPad = ((strgSz + 63) & ~63) - strgSz; size_t rshdSz = 4 + 24 * m_entries.size(); size_t rshdPad = ((rshdSz + 63) & ~63) - rshdSz; __isz += 60; __isz += 4; for (const NameEntry& entry : m_nameEntries) entry.binarySize(__isz); __isz += strgPad; __isz += 4; for (const auto& entry : m_entries) entry.second.binarySize(__isz); __isz += rshdPad; } std::unique_ptr PAK::Entry::getBuffer(const nod::Node& pak, atUint64& szOut) const { if (compressed) { std::unique_ptr strm = pak.beginReadStream(offset); struct { hecl::FourCC magic; atUint32 blockCount; } head; strm->read(&head, 8); if (head.magic != CMPD) { Log.report(logvisor::Error, "invalid CMPD block"); return std::unique_ptr(); } head.blockCount = hecl::SBig(head.blockCount); struct Block { atUint32 compSz; atUint32 decompSz; }; std::unique_ptr blocks(new Block[head.blockCount]); strm->read(blocks.get(), 8 * head.blockCount); atUint64 maxBlockSz = 0; atUint64 totalDecompSz = 0; for (atUint32 b = 0; b < head.blockCount; ++b) { Block& block = blocks[b]; block.compSz = hecl::SBig(block.compSz) & 0xffffff; block.decompSz = hecl::SBig(block.decompSz); if (block.compSz > maxBlockSz) maxBlockSz = block.compSz; totalDecompSz += block.decompSz; } std::unique_ptr compBuf(new atUint8[maxBlockSz]); atUint8* buf = new atUint8[totalDecompSz]; atUint8* bufCur = buf; for (atUint32 b = 0; b < head.blockCount; ++b) { Block& block = blocks[b]; atUint8* compBufCur = compBuf.get(); strm->read(compBufCur, block.compSz); if (block.compSz == block.decompSz) { memcpy(bufCur, compBufCur, block.decompSz); bufCur += block.decompSz; } else { atUint32 rem = block.decompSz; while (rem) { atUint16 chunkSz = hecl::SBig(*(atUint16*)compBufCur); compBufCur += 2; size_t dsz; lzokay::decompress(compBufCur, chunkSz, bufCur, rem, dsz); compBufCur += chunkSz; bufCur += dsz; rem -= dsz; } } } szOut = totalDecompSz; return std::unique_ptr(buf); } else { atUint8* buf = new atUint8[size]; pak.beginReadStream(offset)->read(buf, size); szOut = size; return std::unique_ptr(buf); } } const PAK::Entry* PAK::lookupEntry(const UniqueID64& id) const { auto result = m_entries.find(id); if (result != m_entries.end()) return &result->second; return nullptr; } const PAK::Entry* PAK::lookupEntry(std::string_view name) const { auto result = m_nameMap.find(name.data()); if (result != m_nameMap.end()) { auto result1 = m_entries.find(result->second); if (result1 != m_entries.end()) return &result1->second; } return nullptr; } std::string PAK::bestEntryName(const nod::Node& pakNode, const Entry& entry, bool& named) const { /* Prefer named entries first */ for (const NameEntry& nentry : m_nameEntries) if (nentry.id == entry.id) { named = true; return nentry.name; } /* Otherwise return ID format string */ named = false; return entry.type.toString() + '_' + entry.id.toString(); } } // namespace DataSpec::DNAMP3