#include "nod/IDiscIO.hpp" #include "nod/IFileIO.hpp" #include "nod/Util.hpp" #include "nod/aes.hpp" #include #include namespace nod { /* * NFS is the image format used to distribute Wii VC games for the Wii U. * It is an LBA format similar to WBFS but adds its own encryption layer. * It logically stores a standard Wii disc image with partitions. */ class DiscIONFS : public IDiscIO { struct DiscIONFSShared { std::vector> files; struct NFSHead { uint32_t magic; // EGGS uint32_t version; uint32_t unknown[2]; // Signature, UUID? uint32_t lbaRangeCount; struct { uint32_t startBlock; uint32_t numBlocks; } lbaRanges[61]; uint32_t endMagic; // SGGE } nfsHead; uint8_t key[16]; uint32_t calculateNumFiles() const { uint32_t totalSectorCount = 0; for (uint32_t i = 0; i < nfsHead.lbaRangeCount; ++i) { const auto& range = nfsHead.lbaRanges[i]; totalSectorCount += range.numBlocks; } return (uint64_t(totalSectorCount) * uint64_t(0x8000) + (uint64_t(0x200) + uint64_t(0xF9FFFFF))) / uint64_t(0xFA00000); } struct FBO { uint32_t file, block, offset; }; FBO logicalToFBO(uint64_t offset) const { auto sectorAndRemBytes = std::lldiv(offset, 0x8000); /* 32768 bytes per block */ uint32_t i, physicalBlock; for (i = 0, physicalBlock = 0; i < nfsHead.lbaRangeCount; ++i) { const auto& range = nfsHead.lbaRanges[i]; if (sectorAndRemBytes.quot >= range.startBlock && sectorAndRemBytes.quot - range.startBlock < range.numBlocks) { sectorAndRemBytes.quot = physicalBlock + (sectorAndRemBytes.quot - range.startBlock); break; } physicalBlock += range.numBlocks; } /* This offset has no physical mapping, read zeroes */ if (i == nfsHead.lbaRangeCount) return {UINT32_MAX, UINT32_MAX, UINT32_MAX}; auto fileAndRemBlocks = std::lldiv(sectorAndRemBytes.quot, 8000); /* 8000 blocks per file */ return {uint32_t(fileAndRemBlocks.quot), uint32_t(fileAndRemBlocks.rem), uint32_t(sectorAndRemBytes.rem)}; } DiscIONFSShared(SystemStringView fpin, bool& err) { /* Validate file path format */ using SignedSize = std::make_signed::type; const auto dotPos = SignedSize(fpin.rfind('.')); const auto slashPos = SignedSize(fpin.rfind("/\\")); if (fpin.size() <= 4 || dotPos == -1 || dotPos <= slashPos || fpin.compare(slashPos + 1, 4, "hif_") || fpin.compare(dotPos, fpin.size() - dotPos, ".nfs")) { LogModule.report(logvisor::Error, fmt("'{}' must begin with 'hif_' and end with '.nfs' to be accepted as an NFS image"), fpin); err = true; return; } /* Load key file */ const SystemString dir(fpin.begin(), fpin.begin() + slashPos + 1); auto keyFile = NewFileIO(dir + "../code/htk.bin")->beginReadStream(); if (!keyFile) keyFile = NewFileIO(dir + "htk.bin")->beginReadStream(); if (!keyFile) { LogModule.report(logvisor::Error, fmt("Unable to open '{}../code/htk.bin' or '{}htk.bin'"), dir, dir); err = true; return; } if (keyFile->read(key, 16) != 16) { LogModule.report(logvisor::Error, fmt("Unable to read from '{}../code/htk.bin' or '{}htk.bin'"), dir, dir); err = true; return; } /* Load header from first file */ const SystemString firstPath = fmt::format(fmt("{}hif_{:06}.nfs"), dir, 0); files.push_back(NewFileIO(firstPath)); auto rs = files.back()->beginReadStream(); if (!rs) { LogModule.report(logvisor::Error, fmt("'{}' does not exist"), firstPath); err = true; return; } if (rs->read(&nfsHead, 0x200) != 0x200) { LogModule.report(logvisor::Error, fmt("Unable to read header from '{}'"), firstPath); err = true; return; } if (std::memcmp(&nfsHead.magic, "EGGS", 4)) { LogModule.report(logvisor::Error, fmt("Invalid magic in '{}'"), firstPath); err = true; return; } nfsHead.lbaRangeCount = SBig(nfsHead.lbaRangeCount); for (uint32_t i = 0; i < nfsHead.lbaRangeCount; ++i) { auto& range = nfsHead.lbaRanges[i]; range.startBlock = SBig(range.startBlock); range.numBlocks = SBig(range.numBlocks); } /* Ensure remaining files exist */ const uint32_t numFiles = calculateNumFiles(); files.reserve(numFiles); for (uint32_t i = 1; i < numFiles; ++i) { SystemString path = fmt::format(fmt("{}hif_{:06}.nfs"), dir, i); files.push_back(NewFileIO(path)); if (!files.back()->exists()) { LogModule.report(logvisor::Error, fmt("'{}' does not exist"), path); err = true; return; } } } }; std::shared_ptr m_shared; public: DiscIONFS(SystemStringView fpin, bool& err) : m_shared(std::make_shared(fpin, err)) {} class ReadStream : public IReadStream { friend class DiscIONFS; std::shared_ptr m_shared; std::unique_ptr m_rs; std::unique_ptr m_aes; /* Physical address - all UINT32_MAX indicates logical zero block */ DiscIONFSShared::FBO m_physAddr; /* Logical address */ uint64_t m_offset; /* Active file stream and its offset as set in the system. * Block is typically one ahead of the presently decrypted block. */ uint32_t m_curFile = UINT32_MAX; uint32_t m_curBlock = UINT32_MAX; ReadStream(std::shared_ptr shared, uint64_t offset, bool& err) : m_shared(std::move(shared)), m_aes(NewAES()), m_physAddr({UINT32_MAX, UINT32_MAX, UINT32_MAX}), m_offset(offset) { m_aes->setKey(m_shared->key); setNewLogicalAddr(offset); } uint8_t m_encBuf[0x8000] = {}; uint8_t m_decBuf[0x8000] = {}; void setCurFile(uint32_t curFile) { if (curFile >= m_shared->files.size()) { LogModule.report(logvisor::Error, fmt("Out of bounds NFS file access")); return; } m_curFile = curFile; m_curBlock = UINT32_MAX; m_rs = m_shared->files[m_curFile]->beginReadStream(); } void setCurBlock(uint32_t curBlock) { m_curBlock = curBlock; m_rs->seek(m_curBlock * 0x8000 + 0x200); } void setNewPhysicalAddr(DiscIONFSShared::FBO physAddr) { /* If we're just changing the offset, nothing else needs to be done */ if (m_physAddr.file == physAddr.file && m_physAddr.block == physAddr.block) { m_physAddr.offset = physAddr.offset; return; } m_physAddr = physAddr; /* Set logical zero block */ if (m_physAddr.file == UINT32_MAX) { memset(m_decBuf, 0, 0x8000); return; } /* Make necessary file and block current with system */ if (m_physAddr.file != m_curFile) setCurFile(m_physAddr.file); if (m_physAddr.block != m_curBlock) setCurBlock(m_physAddr.block); /* Read block, handling 0x200 overlap case */ if (m_physAddr.block == 7999) { m_rs->read(m_encBuf, 0x7E00); setCurFile(m_curFile + 1); m_rs->read(m_encBuf + 0x7E00, 0x200); m_curBlock = 0; } else { m_rs->read(m_encBuf, 0x8000); ++m_curBlock; } /* Decrypt */ const uint32_t ivBuf[] = {0, 0, 0, SBig(m_physAddr.block)}; m_aes->decrypt((const uint8_t*)ivBuf, m_encBuf, m_decBuf, 0x8000); } void setNewLogicalAddr(uint64_t addr) { setNewPhysicalAddr(m_shared->logicalToFBO(m_offset)); } public: uint64_t read(void* buf, uint64_t length) override { uint64_t rem = length; uint8_t* dst = (uint8_t*)buf; /* Perform reads on block boundaries */ while (rem) { uint64_t readSize = rem; uint32_t blockOffset = (m_physAddr.offset == UINT32_MAX) ? 0 : m_physAddr.offset; if (readSize + blockOffset > 0x8000) readSize = 0x8000 - blockOffset; memmove(dst, m_decBuf + blockOffset, readSize); dst += readSize; rem -= readSize; m_offset += readSize; setNewLogicalAddr(m_offset); } return dst - (uint8_t*)buf; } uint64_t position() const override { return m_offset; } 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; setNewLogicalAddr(m_offset); } }; std::unique_ptr beginReadStream(uint64_t offset) const override { bool err = false; auto ret = std::unique_ptr(new ReadStream(m_shared, offset, err)); if (err) return {}; return ret; } std::unique_ptr beginWriteStream(uint64_t offset) const override { return {}; } bool hasWiiCrypto() const override { return false; } }; std::unique_ptr NewDiscIONFS(SystemStringView path) { bool err = false; auto ret = std::make_unique(path, err); if (err) return {}; return ret; } }