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https://github.com/jakcron/nstool
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Add support for CompressedRomFs
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parent
cd1e589216
commit
9088f285d8
4 changed files with 292 additions and 1 deletions
2
deps/libnintendo-hac
vendored
2
deps/libnintendo-hac
vendored
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@ -1 +1 @@
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Subproject commit b1b57ad02653c08638dcacbf6566a47ae366b4e1
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Subproject commit 5dd09615784de624ee8c14032869d30170b58fec
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193
src/CompressedArchiveIFile.cpp
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193
src/CompressedArchiveIFile.cpp
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#include "CompressedArchiveIFile.h"
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#include <fnd/lz4.h>
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#include <iostream>
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CompressedArchiveIFile::CompressedArchiveIFile(const fnd::SharedPtr<fnd::IFile>& base_file, size_t compression_meta_offset) :
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mFile(base_file),
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mCompEntries(),
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mLogicalFileSize(0),
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mCacheCapacity(nn::hac::compression::kRomfsBlockSize),
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mCurrentCacheDataSize(0),
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mCache(std::shared_ptr<byte_t>(new byte_t[mCacheCapacity])),
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mScratch(std::shared_ptr<byte_t>(new byte_t[mCacheCapacity]))
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{
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// determine and check the compression metadata size
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size_t compression_meta_size = (*mFile)->size() - compression_meta_offset;
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if (compression_meta_size % sizeof(nn::hac::sCompressionEntry))
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{
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fnd::Exception(kModuleName, "Invalid compression meta size");
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}
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// import raw metadata
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std::shared_ptr<byte_t> entries_raw = std::shared_ptr<byte_t>(new byte_t[compression_meta_size]);
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(*mFile)->read(entries_raw.get(), compression_meta_offset, compression_meta_size);
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// process metadata entries
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nn::hac::sCompressionEntry* entries = (nn::hac::sCompressionEntry*)entries_raw.get();
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for (size_t idx = 0, num = compression_meta_size / sizeof(nn::hac::sCompressionEntry); idx < num; idx++)
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{
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if (idx == 0)
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{
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if (entries[idx].physical_offset.get() != 0x0)
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throw fnd::Exception(kModuleName, "Entry 0 had a non-zero physical offset");
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if (entries[idx].virtual_offset.get() != 0x0)
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throw fnd::Exception(kModuleName, "Entry 0 had a non-zero virtual offset");
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}
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else
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{
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if (entries[idx].physical_offset.get() != align(entries[idx - 1].physical_offset.get() + entries[idx - 1].physical_size.get(), nn::hac::compression::kRomfsBlockAlign))
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throw fnd::Exception(kModuleName, "Entry was not physically aligned with previous entry");
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if (entries[idx].virtual_offset.get() <= entries[idx - 1].virtual_offset.get())
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throw fnd::Exception(kModuleName, "Entry was not virtually aligned with previous entry");
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// set previous entry virtual_size = this->virtual_offset - prev->virtual_offset;
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mCompEntries[mCompEntries.size() - 1].virtual_size = entries[idx].virtual_offset.get() - mCompEntries[mCompEntries.size() - 1].virtual_offset;
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}
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if (entries[idx].physical_size.get() > nn::hac::compression::kRomfsBlockSize)
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throw fnd::Exception(kModuleName, "Entry physical size was too large");
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switch ((nn::hac::compression::CompressionType)entries[idx].compression_type)
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{
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case (nn::hac::compression::CompressionType::None):
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case (nn::hac::compression::CompressionType::Lz4):
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break;
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default:
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throw fnd::Exception(kModuleName, "Unsupported CompressionType");
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}
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mCompEntries.push_back({(nn::hac::compression::CompressionType)entries[idx].compression_type, entries[idx].virtual_offset.get(), 0, entries[idx].physical_offset.get(), entries[idx].physical_size.get()});
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}
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// determine logical file size and final entry size
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importEntryDataToCache(mCompEntries.size() - 1);
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mCompEntries[mCurrentEntryIndex].virtual_size = mCurrentCacheDataSize;
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mLogicalFileSize = mCompEntries[mCurrentEntryIndex].virtual_offset + mCompEntries[mCurrentEntryIndex].virtual_size;
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/*
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for (auto itr = mCompEntries.begin(); itr != mCompEntries.end(); itr++)
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{
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std::cout << "entry " << std::endl;
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std::cout << " type: " << (uint32_t)itr->compression_type << std::endl;
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std::cout << " phys_addr: 0x" << std::hex << itr->physical_offset << std::endl;
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std::cout << " phys_size: 0x" << std::hex << itr->physical_size << std::endl;
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std::cout << " virt_addr: 0x" << std::hex << itr->virtual_offset << std::endl;
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std::cout << " virt_size: 0x" << std::hex << itr->virtual_size << std::endl;
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}
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std::cout << "logical size: 0x" << std::hex << mLogicalFileSize << std::endl;
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*/
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}
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size_t CompressedArchiveIFile::size()
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{
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return mLogicalFileSize;
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}
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void CompressedArchiveIFile::seek(size_t offset)
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{
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mLogicalOffset = std::min<size_t>(offset, mLogicalFileSize);
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}
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void CompressedArchiveIFile::read(byte_t* out, size_t len)
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{
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// limit len to the end of the logical file
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len = std::min<size_t>(len, mLogicalFileSize - mLogicalOffset);
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for (size_t pos = 0, entry_index = getEntryIndexForLogicalOffset(mLogicalOffset); pos < len; entry_index++)
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{
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importEntryDataToCache(entry_index);
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// write padding if required
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if (mCompEntries[entry_index].virtual_size > mCurrentCacheDataSize)
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{
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memset(mCache.get() + mCurrentCacheDataSize, 0, mCompEntries[entry_index].virtual_size - mCurrentCacheDataSize);
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}
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// determine
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size_t read_offset = mLogicalOffset - (size_t)mCompEntries[entry_index].virtual_offset;
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size_t read_size = std::min<size_t>(len, (size_t)mCompEntries[entry_index].virtual_size - read_offset);
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memcpy(out + pos, mCache.get() + read_offset, read_size);
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pos += read_size;
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mLogicalOffset += read_size;
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}
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}
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void CompressedArchiveIFile::read(byte_t* out, size_t offset, size_t len)
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{
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seek(offset);
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read(out, len);
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}
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void CompressedArchiveIFile::write(const byte_t* out, size_t len)
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{
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throw fnd::Exception(kModuleName, "write() not supported");
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}
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void CompressedArchiveIFile::write(const byte_t* out, size_t offset, size_t len)
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{
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throw fnd::Exception(kModuleName, "write() not supported");
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}
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void CompressedArchiveIFile::importEntryDataToCache(size_t entry_index)
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{
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// return if entry already imported
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if (mCurrentEntryIndex == entry_index && mCurrentCacheDataSize != 0)
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return;
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// save index
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mCurrentEntryIndex = entry_index;
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// reference entry
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CompressionEntry& entry = mCompEntries[mCurrentEntryIndex];
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if (entry.compression_type == nn::hac::compression::CompressionType::None)
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{
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(*mFile)->read(mCache.get(), entry.physical_offset, entry.physical_size);
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mCurrentCacheDataSize = entry.physical_size;
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}
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else if (entry.compression_type == nn::hac::compression::CompressionType::Lz4)
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{
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(*mFile)->read(mScratch.get(), entry.physical_offset, entry.physical_size);
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mCurrentCacheDataSize = 0;
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fnd::lz4::decompressData(mScratch.get(), entry.physical_size, mCache.get(), mCacheCapacity, mCurrentCacheDataSize);
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if (mCurrentCacheDataSize == 0)
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{
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throw fnd::Exception(kModuleName, "Decompression of final block failed");
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}
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}
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}
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size_t CompressedArchiveIFile::getEntryIndexForLogicalOffset(size_t logical_offset)
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{
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// rule out bad offset
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if (logical_offset > mLogicalFileSize)
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throw fnd::Exception(kModuleName, "illegal logical offset");
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size_t entry_index = 0;
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// try the current comp entry
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if (mCompEntries[mCurrentEntryIndex].virtual_offset <= logical_offset && \
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mCompEntries[mCurrentEntryIndex].virtual_offset + mCompEntries[mCurrentEntryIndex].virtual_size >= logical_offset)
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{
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entry_index = mCurrentEntryIndex;
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}
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else
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{
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for (size_t index = 0; index < mCompEntries.size(); index++)
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{
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if (mCompEntries[index].virtual_offset <= logical_offset && \
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mCompEntries[index].virtual_offset + mCompEntries[index].virtual_size >= logical_offset)
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{
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entry_index = index;
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}
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}
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}
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return entry_index;
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}
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51
src/CompressedArchiveIFile.h
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51
src/CompressedArchiveIFile.h
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#pragma once
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#include <sstream>
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#include <fnd/IFile.h>
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#include <fnd/SharedPtr.h>
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#include <memory>
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#include <vector>
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#include <nn/hac/define/compression.h>
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class CompressedArchiveIFile : public fnd::IFile
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{
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public:
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CompressedArchiveIFile(const fnd::SharedPtr<fnd::IFile>& file, size_t compression_meta_offset);
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size_t size();
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void seek(size_t offset);
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void read(byte_t* out, size_t len);
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void read(byte_t* out, size_t offset, size_t len);
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void write(const byte_t* out, size_t len);
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void write(const byte_t* out, size_t offset, size_t len);
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private:
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const std::string kModuleName = "CompressedArchiveIFile";
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std::stringstream mErrorSs;
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struct CompressionEntry
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{
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nn::hac::compression::CompressionType compression_type;
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uint64_t virtual_offset;
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uint32_t virtual_size;
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uint64_t physical_offset;
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uint32_t physical_size;
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};
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// raw data
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fnd::SharedPtr<fnd::IFile> mFile;
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// compression metadata
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std::vector<CompressionEntry> mCompEntries;
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size_t mLogicalFileSize;
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size_t mLogicalOffset;
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// cached decompressed entry
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size_t mCacheCapacity; // capacity
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size_t mCurrentEntryIndex; // index of entry currently associated with the cache
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uint32_t mCurrentCacheDataSize; // size of data currently in cache
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std::shared_ptr<byte_t> mCache; // where decompressed data resides
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std::shared_ptr<byte_t> mScratch; // same size as cache, but is used for storing data pre-compression
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// this will import entry to cache
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void importEntryDataToCache(size_t entry_index);
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size_t getEntryIndexForLogicalOffset(size_t logical_offset);
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};
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@ -3,6 +3,7 @@
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#include <fnd/SimpleTextOutput.h>
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#include <fnd/SimpleFile.h>
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#include <fnd/io.h>
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#include "CompressedArchiveIFile.h"
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#include "RomfsProcess.h"
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RomfsProcess::RomfsProcess() :
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throw fnd::Exception(kModuleName, "Invalid ROMFS Header");
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}
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// check for romfs compression
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size_t physical_size = (*mFile)->size();
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size_t logical_size = mHdr.sections[nn::hac::romfs::FILE_NODE_TABLE].offset.get() + mHdr.sections[nn::hac::romfs::FILE_NODE_TABLE].size.get();
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// if logical size is greater than the physical size, check for compression meta footer
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if (logical_size > physical_size)
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{
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// initial and final entries
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nn::hac::sCompressionEntry entry[2];
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(*mFile)->read((byte_t*)&entry[1], physical_size - sizeof(nn::hac::sCompressionEntry), sizeof(nn::hac::sCompressionEntry));
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// the final compression entry should be for the romfs footer, for which the logical offset is detailed in the romfs header
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// the compression is always enabled for non-header compression entries
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if (entry[1].virtual_offset.get() != mHdr.sections[nn::hac::romfs::DIR_HASHMAP_TABLE].offset.get() || \
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entry[1].compression_type != (byte_t)nn::hac::compression::CompressionType::Lz4)
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{
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throw fnd::Exception(kModuleName, "RomFs appears corrupted (bad final compression entry)");
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}
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// the first compression entry follows the physical placement of the final data chunk (specified in the final compression entry)
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size_t first_entry_offset = align(entry[1].physical_offset.get() + entry[1].physical_size.get(), nn::hac::compression::kRomfsBlockAlign);
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// quick check to make sure the offset at least before the last entry offset
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if (first_entry_offset >= (physical_size - sizeof(nn::hac::sCompressionEntry)))
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{
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throw fnd::Exception(kModuleName, "RomFs appears corrupted (bad final compression entry)");
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}
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// read the first compression entry
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(*mFile)->read((byte_t*)&entry[0], first_entry_offset, sizeof(nn::hac::sCompressionEntry));
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// validate first compression entry
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// this should be the same for all compressed romfs
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if (entry[0].virtual_offset.get() != 0x0 || \
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entry[0].physical_offset.get() != 0x0 || \
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entry[0].physical_size.get() != 0x200 || \
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entry[0].compression_type != (byte_t)nn::hac::compression::CompressionType::None)
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{
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throw fnd::Exception(kModuleName, "RomFs appears corrupted (bad first compression entry)");
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}
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// wrap mFile in a class to transparantly decompress the image.
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mFile = new CompressedArchiveIFile(mFile, first_entry_offset);
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}
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// read directory nodes
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mDirNodes.alloc(mHdr.sections[nn::hac::romfs::DIR_NODE_TABLE].size.get());
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(*mFile)->read(mDirNodes.data(), mHdr.sections[nn::hac::romfs::DIR_NODE_TABLE].offset.get(), mDirNodes.size());
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