#include "STRG.hpp" #include "DNAMP2.hpp" namespace Retro { namespace DNAMP2 { void STRG::_read(Athena::io::IStreamReader& reader) { atUint32 langCount = reader.readUint32Big(); atUint32 strCount = reader.readUint32Big(); std::vector readLangs; readLangs.reserve(langCount); for (atUint32 l=0 ; l nameTableBuf(new uint8_t[nameTableSz]); reader.readUBytesToBuf(nameTableBuf.get(), nameTableSz); struct NameIdxEntry { atUint32 nameOff; atUint32 strIdx; }* nameIndex = (NameIdxEntry*)nameTableBuf.get(); for (atUint32 n=0 ; n strs; reader.seek(strCount * 4); for (atUint32 s=0 ; s>& item : langs) langMap.emplace(item.first, &item.second); } void STRG::read(Athena::io::IStreamReader& reader) { atUint32 magic = reader.readUint32Big(); if (magic != 0x87654321) Log.report(LogVisor::Error, "invalid STRG magic"); atUint32 version = reader.readUint32Big(); if (version != 1) Log.report(LogVisor::Error, "invalid STRG version"); _read(reader); } void STRG::write(Athena::io::IStreamWriter& writer) const { writer.writeUint32Big(0x87654321); writer.writeUint32Big(1); writer.writeUint32Big(langs.size()); atUint32 strCount = STRG::count(); writer.writeUint32Big(strCount); atUint32 offset = 0; for (const std::pair>& lang : langs) { lang.first.write(writer); writer.writeUint32Big(offset); offset += strCount * 4 + 4; atUint32 langStrCount = lang.second.size(); atUint32 tableSz = strCount * 4; for (atUint32 s=0 ; s& name : names) nameTableSz += name.first.size() + 1; writer.writeUint32Big(names.size()); writer.writeUint32Big(nameTableSz); offset = names.size() * 8; for (const std::pair& name : names) { writer.writeUint32Big(offset); writer.writeInt32Big(name.second); offset += name.first.size() + 1; } for (const std::pair& name : names) writer.writeString(name.first); for (const std::pair>& lang : langs) { offset = strCount * 4; atUint32 langStrCount = lang.second.size(); for (atUint32 s=0 ; s& name : names) __isz += name.first.size() + 1; size_t strCount = STRG::count(); for (const std::pair>& lang : langs) { atUint32 langStrCount = lang.second.size(); __isz += strCount * 4; for (atUint32 s=0 ; sm_type == YAML_MAPPING_NODE) { for (const auto& lang : root->m_mapChildren) { if (!lang.first.compare("names")) continue; if (lang.first.size() != 4) { Log.report(LogVisor::Warning, "STRG language string '%s' must be exactly 4 characters; skipping", lang.first.c_str()); return; } if (lang.second->m_type != YAML_SEQUENCE_NODE) { Log.report(LogVisor::Warning, "STRG language string '%s' must contain a sequence; skipping", lang.first.c_str()); return; } for (const auto& str : lang.second->m_seqChildren) { if (str->m_type != YAML_SCALAR_NODE) { Log.report(LogVisor::Warning, "STRG language '%s' must contain all scalars; skipping", lang.first.c_str()); return; } } } } else { Log.report(LogVisor::Warning, "STRG must have a mapping root node; skipping"); return; } /* Read Pass */ langs.clear(); for (const auto& lang : root->m_mapChildren) { std::vector strs; for (const auto& str : lang.second->m_seqChildren) strs.emplace_back(HECL::UTF8ToWide(str->m_scalarString)); langs.emplace_back(FourCC(lang.first.c_str()), strs); } names.clear(); const Athena::io::YAMLNode* namesNode = root->findMapChild("names"); if (namesNode) for (const auto& item : namesNode->m_mapChildren) names[item.first] = Athena::io::NodeToVal(item.second.get()); langMap.clear(); langMap.reserve(langs.size()); for (std::pair>& item : langs) langMap.emplace(item.first, &item.second); } void STRG::toYAML(Athena::io::YAMLDocWriter& writer) const { for (const auto& lang : langs) { writer.enterSubVector(lang.first.toString().c_str()); for (const std::wstring& str : lang.second) writer.writeWString(nullptr, str); writer.leaveSubVector(); } if (names.size()) { writer.enterSubRecord("names"); for (const auto& name : names) { writer.enterSubRecord(name.first.c_str()); writer.writeInt32(nullptr, name.second); writer.leaveSubRecord(); } writer.leaveSubRecord(); } } const char* STRG::DNAType() { return "Retro::DNAMP2::STRG"; } } }