#include "nod/DiscGCN.hpp" #include #include #include #include #include #include "nod/nod.hpp" #include "nod/Util.hpp" #include #define BUFFER_SZ 0x8000 namespace nod { class PartitionGCN : public IPartition { public: PartitionGCN(const DiscGCN& parent, uint64_t offset, bool& err) : IPartition(parent, PartitionKind::Data, false, offset) { /* GCN-specific header reads */ std::unique_ptr s = beginReadStream(0x0); if (!s) { err = true; return; } m_header.read(*s); m_bi2Header.read(*s); m_dolOff = m_header.m_dolOff; m_fstOff = m_header.m_fstOff; m_fstSz = m_header.m_fstSz; uint32_t vals[2]; s->seek(0x2440 + 0x14); s->read(vals, 8); m_apploaderSz = 32 + SBig(vals[0]) + SBig(vals[1]); /* Yay files!! */ parseFST(*s); /* Also make DOL header and size handy */ s->seek(m_dolOff); parseDOL(*s); } class PartReadStream : public IPartReadStream { const PartitionGCN& m_parent; std::unique_ptr m_dio; uint64_t m_offset; size_t m_curBlock = SIZE_MAX; uint8_t m_buf[BUFFER_SZ]; public: PartReadStream(const PartitionGCN& parent, uint64_t offset, bool& err) : m_parent(parent), m_offset(offset) { size_t block = m_offset / BUFFER_SZ; m_dio = m_parent.m_parent.getDiscIO().beginReadStream(block * BUFFER_SZ); if (!m_dio) { err = true; return; } m_dio->read(m_buf, BUFFER_SZ); m_curBlock = block; } void seek(int64_t offset, int whence) override { if (whence == SEEK_SET) m_offset = offset; else if (whence == SEEK_CUR) m_offset += offset; else return; size_t block = m_offset / BUFFER_SZ; if (block != m_curBlock) { m_dio->seek(block * BUFFER_SZ); m_dio->read(m_buf, BUFFER_SZ); m_curBlock = block; } } uint64_t position() const override { return m_offset; } uint64_t read(void* buf, uint64_t length) override { size_t block = m_offset / BUFFER_SZ; size_t cacheOffset = m_offset % BUFFER_SZ; uint64_t cacheSize; uint64_t rem = length; uint8_t* dst = (uint8_t*)buf; while (rem) { if (block != m_curBlock) { m_dio->read(m_buf, BUFFER_SZ); m_curBlock = block; } cacheSize = rem; if (cacheSize + cacheOffset > BUFFER_SZ) cacheSize = BUFFER_SZ - cacheOffset; memmove(dst, m_buf + cacheOffset, cacheSize); dst += cacheSize; rem -= cacheSize; cacheOffset = 0; ++block; } m_offset += length; return dst - (uint8_t*)buf; } }; std::unique_ptr beginReadStream(uint64_t offset) const override { bool err = false; auto ret = std::make_unique(*this, offset, err); if (err) { return nullptr; } return ret; } }; DiscGCN::DiscGCN(std::unique_ptr&& dio, bool& err) : DiscBase(std::move(dio), err) { if (err) return; /* One lone partition for GCN */ m_partitions.emplace_back(std::make_unique(*this, 0, err)); } DiscBuilderGCN DiscGCN::makeMergeBuilder(SystemStringView outPath, FProgress progressCB) { return DiscBuilderGCN(outPath, progressCB); } bool DiscGCN::extractDiscHeaderFiles(SystemStringView path, const ExtractionContext& ctx) const { return true; } class PartitionBuilderGCN : public DiscBuilderBase::PartitionBuilderBase { uint64_t m_curUser = 0x57058000; public: class PartWriteStream : public IPartWriteStream { const PartitionBuilderGCN& m_parent; uint64_t m_offset; std::unique_ptr m_fio; public: PartWriteStream(const PartitionBuilderGCN& parent, uint64_t offset, bool& err) : m_parent(parent), m_offset(offset) { m_fio = m_parent.m_parent.getFileIO().beginWriteStream(offset); if (!m_fio) err = true; } void close() override { m_fio.reset(); } uint64_t position() const override { return m_offset; } uint64_t write(const void* buf, uint64_t length) override { uint64_t len = m_fio->write(buf, length); m_offset += len; return len; } void seek(size_t off) { m_offset = off; m_fio = m_parent.m_parent.getFileIO().beginWriteStream(off); } }; PartitionBuilderGCN(DiscBuilderBase& parent) : DiscBuilderBase::PartitionBuilderBase(parent, PartitionKind::Data, false) {} uint64_t userAllocate(uint64_t reqSz, IPartWriteStream& ws) override { m_curUser -= reqSz; m_curUser &= 0xfffffffffffffff0; if (m_curUser < 0x30000) { LogModule.report(logvisor::Error, FMT_STRING("user area low mark reached")); return -1; } static_cast(ws).seek(m_curUser); return m_curUser; } uint32_t packOffset(uint64_t offset) const override { return offset; } std::unique_ptr beginWriteStream(uint64_t offset) override { bool err = false; auto ret = std::make_unique(*this, offset, err); if (err) { return nullptr; } return ret; } bool _build(const std::function& headerFunc, const std::function& bi2Func, const std::function& apploaderFunc) { std::unique_ptr ws = beginWriteStream(0x2440); if (!ws) return false; size_t xferSz = 0; if (!apploaderFunc(*ws, xferSz)) return false; size_t fstOff = ROUND_UP_32(xferSz); size_t fstSz = sizeof(FSTNode) * m_buildNodes.size(); for (size_t i = 0; i < fstOff - xferSz; ++i) ws->write("\xff", 1); fstOff += 0x2440; ws->write(m_buildNodes.data(), fstSz); for (const std::string& str : m_buildNames) ws->write(str.data(), str.size() + 1); fstSz += m_buildNameOff; fstSz = ROUND_UP_32(fstSz); if (fstOff + fstSz >= m_curUser) { LogModule.report(logvisor::Error, FMT_STRING("FST flows into user area (one or the other is too big)")); return false; } ws = beginWriteStream(0); if (!ws) return false; if (!headerFunc(*ws, m_dolOffset, fstOff, fstSz, m_curUser, 0x57058000 - m_curUser)) return false; if (!bi2Func(*ws)) return false; return true; } bool buildFromDirectory(SystemStringView dirIn) { std::unique_ptr ws = beginWriteStream(0); if (!ws) return false; bool result = DiscBuilderBase::PartitionBuilderBase::buildFromDirectory(*ws, dirIn); if (!result) return false; SystemString dirStr(dirIn); /* Check Apploader */ SystemString apploaderIn = dirStr + _SYS_STR("/sys/apploader.img"); Sstat apploaderStat; if (Stat(apploaderIn.c_str(), &apploaderStat)) { LogModule.report(logvisor::Error, FMT_STRING(_SYS_STR("unable to stat {}")), apploaderIn); return false; } /* Check Boot */ SystemString bootIn = dirStr + _SYS_STR("/sys/boot.bin"); Sstat bootStat; if (Stat(bootIn.c_str(), &bootStat)) { LogModule.report(logvisor::Error, FMT_STRING(_SYS_STR("unable to stat {}")), bootIn); return false; } /* Check BI2 */ SystemString bi2In = dirStr + _SYS_STR("/sys/bi2.bin"); Sstat bi2Stat; if (Stat(bi2In.c_str(), &bi2Stat)) { LogModule.report(logvisor::Error, FMT_STRING(_SYS_STR("unable to stat {}")), bi2In); return false; } return _build( [&bootIn](IPartWriteStream& ws, uint32_t dolOff, uint32_t fstOff, uint32_t fstSz, uint32_t userOff, uint32_t userSz) -> bool { std::unique_ptr rs = NewFileIO(bootIn.c_str())->beginReadStream(); if (!rs) return false; Header header; header.read(*rs); header.m_dolOff = dolOff; header.m_fstOff = fstOff; header.m_fstSz = fstSz; header.m_fstMaxSz = fstSz; header.m_userPosition = userOff; header.m_userSz = userSz; header.write(ws); return true; }, [&bi2In](IPartWriteStream& ws) -> bool { std::unique_ptr rs = NewFileIO(bi2In.c_str())->beginReadStream(); if (!rs) return false; BI2Header bi2; bi2.read(*rs); bi2.write(ws); return true; }, [this, &apploaderIn](IPartWriteStream& ws, size_t& xferSz) -> bool { std::unique_ptr rs = NewFileIO(apploaderIn.c_str())->beginReadStream(); if (!rs) return false; char buf[8192]; while (true) { size_t rdSz = rs->read(buf, 8192); if (!rdSz) break; ws.write(buf, rdSz); xferSz += rdSz; if (0x2440 + xferSz >= m_curUser) { LogModule.report(logvisor::Error, FMT_STRING("apploader flows into user area (one or the other is too big)")); return false; } m_parent.m_progressCB(m_parent.getProgressFactor(), apploaderIn, xferSz); } ++m_parent.m_progressIdx; return true; }); } bool mergeFromDirectory(const PartitionGCN* partIn, SystemStringView dirIn) { std::unique_ptr ws = beginWriteStream(0); if (!ws) return false; bool result = DiscBuilderBase::PartitionBuilderBase::mergeFromDirectory(*ws, partIn, dirIn); if (!result) return false; return _build( [partIn](IPartWriteStream& ws, uint32_t dolOff, uint32_t fstOff, uint32_t fstSz, uint32_t userOff, uint32_t userSz) -> bool { Header header = partIn->getHeader(); header.m_dolOff = dolOff; header.m_fstOff = fstOff; header.m_fstSz = fstSz; header.m_fstMaxSz = fstSz; header.m_userPosition = userOff; header.m_userSz = userSz; header.write(ws); return true; }, [partIn](IPartWriteStream& ws) -> bool { partIn->getBI2().write(ws); return true; }, [this, partIn](IPartWriteStream& ws, size_t& xferSz) -> bool { std::unique_ptr apploaderBuf = partIn->getApploaderBuf(); size_t apploaderSz = partIn->getApploaderSize(); SystemString apploaderName(_SYS_STR("")); ws.write(apploaderBuf.get(), apploaderSz); xferSz += apploaderSz; if (0x2440 + xferSz >= m_curUser) { LogModule.report(logvisor::Error, FMT_STRING("apploader flows into user area (one or the other is too big)")); return false; } m_parent.m_progressCB(m_parent.getProgressFactor(), apploaderName, xferSz); ++m_parent.m_progressIdx; return true; }); } }; EBuildResult DiscBuilderGCN::buildFromDirectory(SystemStringView dirIn) { if (!m_fileIO->beginWriteStream()) return EBuildResult::Failed; if (!CheckFreeSpace(m_outPath.c_str(), 0x57058000)) { LogModule.report(logvisor::Error, FMT_STRING(_SYS_STR("not enough free disk space for {}")), m_outPath); return EBuildResult::DiskFull; } m_progressCB(getProgressFactor(), _SYS_STR("Preallocating image"), -1); ++m_progressIdx; { auto ws = m_fileIO->beginWriteStream(0); if (!ws) return EBuildResult::Failed; char zeroBytes[1024] = {}; for (uint64_t i = 0; i < 0x57058000; i += 1024) ws->write(zeroBytes, 1024); } PartitionBuilderGCN& pb = static_cast(*m_partitions[0]); return pb.buildFromDirectory(dirIn) ? EBuildResult::Success : EBuildResult::Failed; } std::optional DiscBuilderGCN::CalculateTotalSizeRequired(SystemStringView dirIn) { std::optional sz = DiscBuilderBase::PartitionBuilderBase::CalculateTotalSizeBuild(dirIn, PartitionKind::Data, false); if (!sz) return sz; *sz += 0x30000; if (sz > 0x57058000) { LogModule.report(logvisor::Error, FMT_STRING(_SYS_STR("disc capacity exceeded [{} / {}]")), *sz, 0x57058000); return std::nullopt; } return sz; } DiscBuilderGCN::DiscBuilderGCN(SystemStringView outPath, FProgress progressCB) : DiscBuilderBase(outPath, 0x57058000, progressCB) { m_partitions.emplace_back(std::make_unique(*this)); } DiscMergerGCN::DiscMergerGCN(SystemStringView outPath, DiscGCN& sourceDisc, FProgress progressCB) : m_sourceDisc(sourceDisc), m_builder(sourceDisc.makeMergeBuilder(outPath, progressCB)) {} EBuildResult DiscMergerGCN::mergeFromDirectory(SystemStringView dirIn) { if (!m_builder.getFileIO().beginWriteStream()) return EBuildResult::Failed; if (!CheckFreeSpace(m_builder.m_outPath.c_str(), 0x57058000)) { LogModule.report(logvisor::Error, FMT_STRING(_SYS_STR("not enough free disk space for {}")), m_builder.m_outPath); return EBuildResult::DiskFull; } m_builder.m_progressCB(m_builder.getProgressFactor(), _SYS_STR("Preallocating image"), -1); ++m_builder.m_progressIdx; { auto ws = m_builder.m_fileIO->beginWriteStream(0); if (!ws) return EBuildResult::Failed; char zeroBytes[1024] = {}; for (uint64_t i = 0; i < 0x57058000; i += 1024) ws->write(zeroBytes, 1024); } PartitionBuilderGCN& pb = static_cast(*m_builder.m_partitions[0]); return pb.mergeFromDirectory(static_cast(m_sourceDisc.getDataPartition()), dirIn) ? EBuildResult::Success : EBuildResult::Failed; } std::optional DiscMergerGCN::CalculateTotalSizeRequired(DiscGCN& sourceDisc, SystemStringView dirIn) { std::optional sz = DiscBuilderBase::PartitionBuilderBase::CalculateTotalSizeMerge(sourceDisc.getDataPartition(), dirIn); if (!sz) return std::nullopt; *sz += 0x30000; if (sz > 0x57058000) { LogModule.report(logvisor::Error, FMT_STRING(_SYS_STR("disc capacity exceeded [{} / {}]")), *sz, 0x57058000); return std::nullopt; } return sz; } } // namespace nod