nstool/src/NcaProcess.cpp
2021-10-16 15:41:45 +08:00

627 lines
No EOL
22 KiB
C++

#include "NcaProcess.h"
#include "MetaProcess.h"
//mak#include <memory>
#include <tc/crypto/detail/BlockUtilImpl.h>
#include <nn/hac/ContentArchiveUtil.h>
#include <nn/hac/AesKeygen.h>
#include <nn/hac/HierarchicalSha256Stream.h>
#include <nn/hac/HierarchicalIntegrityStream.h>
#include <nn/hac/PartitionFsMetaGenerator.h>
#include <nn/hac/RomFsMetaGenerator.h>
#include <nn/hac/CombinedFsMetaGenerator.h>
nstool::NcaProcess::NcaProcess() :
mModuleName("nstool::NcaProcess"),
mFile(),
mCliOutputMode(true, false, false, false),
mVerify(false),
mFileSystem(),
mFsProcess()
{
}
void nstool::NcaProcess::process()
{
// import header
importHeader();
// determine keys
generateNcaBodyEncryptionKeys();
// import/generate fs header data
generatePartitionConfiguration();
// validate signatures
if (mVerify)
validateNcaSignatures();
// display header
if (mCliOutputMode.show_basic_info)
displayHeader();
// process partition
processPartitions();
}
void nstool::NcaProcess::setInputFile(const std::shared_ptr<tc::io::IStream>& file)
{
mFile = file;
}
void nstool::NcaProcess::setKeyCfg(const KeyBag& keycfg)
{
mKeyCfg = keycfg;
}
void nstool::NcaProcess::setCliOutputMode(CliOutputMode type)
{
mCliOutputMode = type;
}
void nstool::NcaProcess::setVerifyMode(bool verify)
{
mVerify = verify;
}
void nstool::NcaProcess::setShowFsTree(bool show_fs_tree)
{
mFsProcess.setShowFsTree(show_fs_tree);
}
void nstool::NcaProcess::setFsRootLabel(const std::string& root_label)
{
mFsProcess.setFsRootLabel(root_label);
}
void nstool::NcaProcess::setExtractJobs(const std::vector<nstool::ExtractJob>& extract_jobs)
{
mFsProcess.setExtractJobs(extract_jobs);
}
const std::shared_ptr<tc::io::IStorage>& nstool::NcaProcess::getFileSystem() const
{
return mFileSystem;
}
void nstool::NcaProcess::importHeader()
{
if (mFile == nullptr)
{
throw tc::Exception(mModuleName, "No file reader set.");
}
if (mFile->canRead() == false || mFile->canSeek() == false)
{
throw tc::NotSupportedException(mModuleName, "Input stream requires read/seek permissions.");
}
// read header block
if (mFile->length() < tc::io::IOUtil::castSizeToInt64(sizeof(nn::hac::sContentArchiveHeaderBlock)))
{
throw tc::Exception(mModuleName, "Corrupt NCA: File too small.");
}
mFile->seek(0, tc::io::SeekOrigin::Begin);
mFile->read((byte_t*)(&mHdrBlock), sizeof(nn::hac::sContentArchiveHeaderBlock));
// decrypt header block
if (mKeyCfg.nca_header_key.isNull())
{
throw tc::Exception(mModuleName, "Failed to decrypt NCA header. (nca_header_key could not be loaded)");
}
nn::hac::ContentArchiveUtil::decryptContentArchiveHeader((byte_t*)&mHdrBlock, (byte_t*)&mHdrBlock, mKeyCfg.nca_header_key.get());
// generate header hash
tc::crypto::GenerateSha256Hash(mHdrHash.data(), (byte_t*)&mHdrBlock.header, sizeof(nn::hac::sContentArchiveHeader));
// proccess main header
mHdr.fromBytes((byte_t*)&mHdrBlock.header, sizeof(nn::hac::sContentArchiveHeader));
}
void nstool::NcaProcess::generateNcaBodyEncryptionKeys()
{
// create zeros key
KeyBag::aes128_key_t zero_aesctr_key;
memset(zero_aesctr_key.data(), 0, zero_aesctr_key.size());
// get key data from header
byte_t masterkey_rev = nn::hac::ContentArchiveUtil::getMasterKeyRevisionFromKeyGeneration(mHdr.getKeyGeneration());
byte_t keak_index = mHdr.getKeyAreaEncryptionKeyIndex();
// process key area
sKeys::sKeyAreaKey kak;
for (size_t i = 0; i < mHdr.getKeyArea().size(); i++)
{
if (mHdr.getKeyArea()[i] != zero_aesctr_key)
{
kak.index = (byte_t)i;
kak.enc = mHdr.getKeyArea()[i];
kak.decrypted = false;
// key[0-3]
if (i < 4 && mKeyCfg.nca_key_area_encryption_key[keak_index].find(masterkey_rev) != mKeyCfg.nca_key_area_encryption_key[keak_index].end())
{
kak.decrypted = true;
nn::hac::AesKeygen::generateKey(kak.dec.data(), kak.enc.data(), mKeyCfg.nca_key_area_encryption_key[keak_index][masterkey_rev].data());
}
// key[KEY_AESCTR_HW]
else if (i == nn::hac::nca::KEY_AESCTR_HW && mKeyCfg.nca_key_area_encryption_key_hw[keak_index].find(masterkey_rev) != mKeyCfg.nca_key_area_encryption_key_hw[keak_index].end())
{
kak.decrypted = true;
nn::hac::AesKeygen::generateKey(kak.dec.data(), kak.enc.data(), mKeyCfg.nca_key_area_encryption_key_hw[keak_index][masterkey_rev].data());
}
else
{
kak.decrypted = false;
}
mContentKey.kak_list.push_back(kak);
}
}
// clear content key
mContentKey.aes_ctr = tc::Optional<nn::hac::detail::aes128_key_t>();
// if this has a rights id, the key needs to be sourced from a ticket
if (mHdr.hasRightsId() == true)
{
KeyBag::aes128_key_t tmp_key;
if (mKeyCfg.external_content_keys.find(mHdr.getRightsId()) != mKeyCfg.external_content_keys.end())
{
mContentKey.aes_ctr = mKeyCfg.external_content_keys[mHdr.getRightsId()];
}
else if (mKeyCfg.fallback_content_key.isSet())
{
mContentKey.aes_ctr = mKeyCfg.fallback_content_key.get();
}
else if (mKeyCfg.fallback_enc_content_key.isSet())
{
tmp_key = mKeyCfg.fallback_enc_content_key.get();
if (mKeyCfg.etik_common_key.find(masterkey_rev) != mKeyCfg.etik_common_key.end())
{
nn::hac::AesKeygen::generateKey(tmp_key.data(), tmp_key.data(), mKeyCfg.etik_common_key[masterkey_rev].data());
mContentKey.aes_ctr = tmp_key;
}
}
}
// otherwise used decrypt key area
else
{
for (size_t i = 0; i < mContentKey.kak_list.size(); i++)
{
if (mContentKey.kak_list[i].index == nn::hac::nca::KEY_AESCTR && mContentKey.kak_list[i].decrypted)
{
mContentKey.aes_ctr = mContentKey.kak_list[i].dec;
}
}
}
// if the keys weren't generated, check if the keys were supplied by the user
if (mContentKey.aes_ctr.isNull())
{
if (mKeyCfg.fallback_content_key.isSet())
{
mContentKey.aes_ctr = mKeyCfg.fallback_content_key.get();
}
}
if (mCliOutputMode.show_keydata)
{
if (mContentKey.aes_ctr.isSet())
{
fmt::print("[NCA Content Key]\n");
fmt::print(" AES-CTR Key: {:s}\n", tc::cli::FormatUtil::formatBytesAsString(mContentKey.aes_ctr.get().data(), mContentKey.aes_ctr.get().size(), true, ":"));
}
}
}
void nstool::NcaProcess::generatePartitionConfiguration()
{
for (size_t i = 0; i < mHdr.getPartitionEntryList().size(); i++)
{
// get reference to relevant structures
const nn::hac::ContentArchiveHeader::sPartitionEntry& partition = mHdr.getPartitionEntryList()[i];
nn::hac::sContentArchiveFsHeader& fs_header = mHdrBlock.fs_header[partition.header_index];
// output structure
sPartitionInfo& info = mPartitions[partition.header_index];
// validate header hash
nn::hac::detail::sha256_hash_t fs_header_hash;
tc::crypto::GenerateSha256Hash(fs_header_hash.data(), (const byte_t*)&mHdrBlock.fs_header[partition.header_index], sizeof(nn::hac::sContentArchiveFsHeader));
if (fs_header_hash != partition.fs_header_hash)
{
throw tc::Exception(mModuleName, fmt::format("NCA FS Header [{:d}] Hash: FAIL", partition.header_index));
}
if (fs_header.version.unwrap() != nn::hac::nca::kDefaultFsHeaderVersion)
{
throw tc::Exception(mModuleName, fmt::format("NCA FS Header [{:d}] Version({:d}): UNSUPPORTED", partition.header_index, fs_header.version.unwrap()));
}
// setup AES-CTR
nn::hac::ContentArchiveUtil::getNcaPartitionAesCtr(&fs_header, info.aes_ctr.data());
// save partition configinfo
info.offset = partition.offset;
info.size = partition.size;
info.format_type = (nn::hac::nca::FormatType)fs_header.format_type;
info.hash_type = (nn::hac::nca::HashType)fs_header.hash_type;
info.enc_type = (nn::hac::nca::EncryptionType)fs_header.encryption_type;
if (info.hash_type == nn::hac::nca::HashType::HierarchicalSha256)
{
info.hierarchicalsha256_hdr.fromBytes(fs_header.hash_info.data(), fs_header.hash_info.size());
/*
nn::hac::HierarchicalSha256Header hdr;
// import raw data
hdr.fromBytes(fs_header.hash_info.data(), fs_header.hash_info.size());
for (size_t i = 0; i < hdr.getLayerInfo().size(); i++)
{
nn::hac::HierarchicalValidatedStream::StreamInfo::LayerInfo layer;
layer.offset = hdr.getLayerInfo()[i].offset;
layer.size = hdr.getLayerInfo()[i].size;
layer.block_size = hdr.getHashBlockSize();
if (i + 1 == hdr.getLayerInfo().size())
{
info.hashed_stream_info.data_layer_info = layer;
}
else
{
info.hashed_stream_info.hash_layer_info.push_back(layer);
}
}
info.hashed_stream_info.master_hash_data = tc::ByteData(hdr.getMasterHash().data(), hdr.getMasterHash().size());
info.hashed_stream_info.align_partial_block_to_blocksize = false;
*/
}
else if (info.hash_type == nn::hac::nca::HashType::HierarchicalIntegrity)
{
info.hierarchicalintegrity_hdr.fromBytes(fs_header.hash_info.data(), fs_header.hash_info.size());
/*
// info.hash_tree_meta.importData(fs_header.hash_info, nn::hac::nca::kHashInfoLen, LayeredIntegrityMetadata::HASH_TYPE_INTEGRITY);
nn::hac::HierarchicalIntegrityHeader hdr;
hdr.fromBytes(fs_header.hash_info.data(), fs_header.hash_info.size());
for (size_t i = 0; i < hdr.getLayerInfo().size(); i++)
{
nn::hac::HierarchicalValidatedStream::StreamInfo::LayerInfo layer;
layer.offset = hdr.getLayerInfo()[i].offset;
layer.size = hdr.getLayerInfo()[i].size;
layer.block_size = (1 << hdr.getLayerInfo()[i].block_size);
if (i + 1 == hdr.getLayerInfo().size())
{
info.hashed_stream_info.data_layer_info = layer;
}
else
{
info.hashed_stream_info.hash_layer_info.push_back(layer);
}
}
info.hashed_stream_info.master_hash_data = tc::ByteData(hdr.getMasterHashList().size() * sizeof(nn::hac::detail::sha256_hash_t));
for (size_t i = 0; i < hdr.getMasterHashList().size(); i++)
{
((nn::hac::detail::sha256_hash_t*)info.hashed_stream_info.master_hash_data.data())[i] = hdr.getMasterHashList()[i];
}
info.hashed_stream_info.align_partial_block_to_blocksize = false;
*/
}
// create reader
try
{
// create reader based on encryption type0
if (info.enc_type == nn::hac::nca::EncryptionType::None)
{
info.reader = std::make_shared<tc::io::SubStream>(tc::io::SubStream(mFile, info.offset, info.size));
}
else if (info.enc_type == nn::hac::nca::EncryptionType::AesCtr)
{
if (mContentKey.aes_ctr.isNull())
throw tc::Exception(mModuleName, "AES-CTR Key was not determined");
//info.reader = new fnd::OffsetAdjustedIFile(new fnd::AesCtrWrappedIFile(mFile, mContentKey.aes_ctr.get(), info.aes_ctr), info.offset, info.size);
info.reader = std::make_shared<tc::crypto::Aes128CtrEncryptedStream>(tc::crypto::Aes128CtrEncryptedStream(mFile, mContentKey.aes_ctr.get(), info.aes_ctr));
info.reader = std::make_shared<tc::io::SubStream>(tc::io::SubStream(info.reader, info.offset, info.size));
}
else if (info.enc_type == nn::hac::nca::EncryptionType::AesXts || info.enc_type == nn::hac::nca::EncryptionType::AesCtrEx)
{
throw tc::Exception(mModuleName, fmt::format("EncryptionType({:s}): UNSUPPORTED", nn::hac::ContentArchiveUtil::getEncryptionTypeAsString(info.enc_type)));
}
else
{
throw tc::Exception(mModuleName, fmt::format("EncryptionType({:s}): UNKNOWN", nn::hac::ContentArchiveUtil::getEncryptionTypeAsString(info.enc_type)));
}
// filter out unrecognised hash types, and hash based readers
switch (info.hash_type)
{
case (nn::hac::nca::HashType::None):
break;
case (nn::hac::nca::HashType::HierarchicalSha256):
info.reader = std::make_shared<nn::hac::HierarchicalSha256Stream>(nn::hac::HierarchicalSha256Stream(info.reader, info.hierarchicalsha256_hdr));
break;
case (nn::hac::nca::HashType::HierarchicalIntegrity):
info.reader = std::make_shared<nn::hac::HierarchicalIntegrityStream>(nn::hac::HierarchicalIntegrityStream(info.reader, info.hierarchicalintegrity_hdr));
break;
default:
throw tc::Exception(mModuleName, fmt::format("HashType({:s}): UNKNOWN", nn::hac::ContentArchiveUtil::getHashTypeAsString(info.hash_type)));
}
// filter out unrecognised format types
switch (info.format_type)
{
case (nn::hac::nca::FormatType::PartitionFs):
info.fs_meta = nn::hac::PartitionFsMetaGenerator(info.reader);
info.fs_reader = std::make_shared<tc::io::VirtualFileSystem>(tc::io::VirtualFileSystem(info.fs_meta));
break;
case (nn::hac::nca::FormatType::RomFs):
info.fs_meta = nn::hac::RomFsMetaGenerator(info.reader);
info.fs_reader = std::make_shared<tc::io::VirtualFileSystem>(tc::io::VirtualFileSystem(info.fs_meta));
break;
default:
throw tc::Exception(mModuleName, fmt::format("FormatType({:s}): UNKNOWN", nn::hac::ContentArchiveUtil::getFormatTypeAsString(info.format_type)));
}
}
catch (const tc::Exception& e)
{
info.fail_reason = std::string(e.error());
}
}
}
void nstool::NcaProcess::validateNcaSignatures()
{
// validate signature[0]
if (mKeyCfg.nca_header_sign0_key.find(mHdr.getSignatureKeyGeneration()) != mKeyCfg.nca_header_sign0_key.end())
{
if (tc::crypto::VerifyRsa2048PssSha256(mHdrBlock.signature_main.data(), mHdrHash.data(), mKeyCfg.nca_header_sign0_key[mHdr.getSignatureKeyGeneration()]) == false)
{
fmt::print("[WARNING] NCA Header Main Signature: FAIL\n");
}
}
else
{
fmt::print("[WARNING] NCA Header Main Signature: FAIL (could not load header key)\n");
}
// validate signature[1]
if (mHdr.getContentType() == nn::hac::nca::ContentType::Program)
{
try {
if (mPartitions[nn::hac::nca::PARTITION_CODE].format_type == nn::hac::nca::FormatType::PartitionFs)
{
if (mPartitions[nn::hac::nca::PARTITION_CODE].fs_reader != nullptr)
{
std::shared_ptr<tc::io::IStream> npdm_file;
try {
mPartitions[nn::hac::nca::PARTITION_CODE].fs_reader->openFile(tc::io::Path(kNpdmExefsPath), tc::io::FileMode::Open, tc::io::FileAccess::Read, npdm_file);
}
catch (tc::io::FileNotFoundException&) {
throw tc::Exception(fmt::format("\"{:s}\" not present in ExeFs", kNpdmExefsPath));
}
MetaProcess npdm;
npdm.setInputFile(npdm_file);
npdm.setKeyCfg(mKeyCfg);
npdm.setVerifyMode(true);
npdm.setCliOutputMode(CliOutputMode(false, false, false, false));
npdm.process();
if (tc::crypto::VerifyRsa2048PssSha256(mHdrBlock.signature_acid.data(), mHdrHash.data(), npdm.getMeta().getAccessControlInfoDesc().getContentArchiveHeaderSignature2Key()) == false)
{
throw tc::Exception("Bad signature");
}
}
else
{
throw tc::Exception("ExeFs was not mounted");
}
}
else
{
throw tc::Exception("No ExeFs partition");
}
}
catch (tc::Exception& e) {
fmt::print("[WARNING] NCA Header ACID Signature: FAIL ({:s})\n", e.error());
}
}
}
void nstool::NcaProcess::displayHeader()
{
fmt::print("[NCA Header]\n");
fmt::print(" Format Type: {:s}\n", nn::hac::ContentArchiveUtil::getFormatHeaderVersionAsString((nn::hac::nca::HeaderFormatVersion)mHdr.getFormatVersion()));
fmt::print(" Dist. Type: {:s}\n", nn::hac::ContentArchiveUtil::getDistributionTypeAsString(mHdr.getDistributionType()));
fmt::print(" Content Type: {:s}\n", nn::hac::ContentArchiveUtil::getContentTypeAsString(mHdr.getContentType()));
fmt::print(" Key Generation: {:d}\n", mHdr.getKeyGeneration());
fmt::print(" Sig. Generation: {:d}\n", mHdr.getSignatureKeyGeneration());
fmt::print(" Kaek Index: {:s} ({:d})\n", nn::hac::ContentArchiveUtil::getKeyAreaEncryptionKeyIndexAsString((nn::hac::nca::KeyAreaEncryptionKeyIndex)mHdr.getKeyAreaEncryptionKeyIndex()), mHdr.getKeyAreaEncryptionKeyIndex());
fmt::print(" Size: 0x{:x}\n", mHdr.getContentSize());
fmt::print(" ProgID: 0x{:016x}\n", mHdr.getProgramId());
fmt::print(" Content Index: {:d}\n", mHdr.getContentIndex());
fmt::print(" SdkAddon Ver.: {:s} (v{:d})\n", nn::hac::ContentArchiveUtil::getSdkAddonVersionAsString(mHdr.getSdkAddonVersion()), mHdr.getSdkAddonVersion());
if (mHdr.hasRightsId())
{
fmt::print(" RightsId: {:s}\n", tc::cli::FormatUtil::formatBytesAsString(mHdr.getRightsId().data(), mHdr.getRightsId().size(), true, ""));
}
if (mContentKey.kak_list.size() > 0 && mCliOutputMode.show_keydata)
{
fmt::print(" Key Area:\n");
fmt::print(" <--------------------------------------------------------------------------------------------------------->\n");
fmt::print(" | IDX | ENCRYPTED KEY | DECRYPTED KEY |\n");
fmt::print(" |-----|-------------------------------------------------|-------------------------------------------------|\n");
for (size_t i = 0; i < mContentKey.kak_list.size(); i++)
{
fmt::print(" | {:3d} | {:s} | ", mContentKey.kak_list[i].index, tc::cli::FormatUtil::formatBytesAsString(mContentKey.kak_list[i].enc.data(), mContentKey.kak_list[i].enc.size(), true, ":"));
if (mContentKey.kak_list[i].decrypted)
fmt::print("{:s}", tc::cli::FormatUtil::formatBytesAsString(mContentKey.kak_list[i].dec.data(), mContentKey.kak_list[i].dec.size(), true, ":"));
else
fmt::print("<unable to decrypt> ");
fmt::print(" |\n");
}
fmt::print(" <--------------------------------------------------------------------------------------------------------->\n");
}
if (mCliOutputMode.show_layout)
{
fmt::print(" Partitions:\n");
for (size_t i = 0; i < mHdr.getPartitionEntryList().size(); i++)
{
uint32_t index = mHdr.getPartitionEntryList()[i].header_index;
sPartitionInfo& info = mPartitions[index];
if (info.size == 0) continue;
fmt::print(" {:d}:\n", index);
fmt::print(" Offset: 0x{:x}\n", info.offset);
fmt::print(" Size: 0x{:x}\n", info.size);
fmt::print(" Format Type: {:s}\n", nn::hac::ContentArchiveUtil::getFormatTypeAsString(info.format_type));
fmt::print(" Hash Type: {:s}\n", nn::hac::ContentArchiveUtil::getHashTypeAsString(info.hash_type));
fmt::print(" Enc. Type: {:s}\n", nn::hac::ContentArchiveUtil::getEncryptionTypeAsString(info.enc_type));
if (info.enc_type == nn::hac::nca::EncryptionType::AesCtr)
{
nn::hac::detail::aes_iv_t aes_ctr;
memcpy(aes_ctr.data(), info.aes_ctr.data(), aes_ctr.size());
tc::crypto::detail::incr_counter<16>(aes_ctr.data(), info.offset>>4);
fmt::print(" AesCtr Counter:\n");
fmt::print(" {:s}\n", tc::cli::FormatUtil::formatBytesAsString(aes_ctr.data(), aes_ctr.size(), true, ":"));
}
if (info.hash_type == nn::hac::nca::HashType::HierarchicalIntegrity)
{
auto hash_hdr = info.hierarchicalintegrity_hdr;
fmt::print(" HierarchicalIntegrity Header:\n");
for (size_t j = 0; j < hash_hdr.getLayerInfo().size(); j++)
{
if (j+1 == hash_hdr.getLayerInfo().size())
{
fmt::print(" Data Layer:\n");
}
else
{
fmt::print(" Hash Layer {:d}:\n", j);
}
fmt::print(" Offset: 0x{:x}\n", hash_hdr.getLayerInfo()[j].offset);
fmt::print(" Size: 0x{:x}\n", hash_hdr.getLayerInfo()[j].size);
fmt::print(" BlockSize: 0x{:x}\n", hash_hdr.getLayerInfo()[j].block_size);
}
for (size_t j = 0; j < hash_hdr.getMasterHashList().size(); j++)
{
fmt::print(" Master Hash {:d}:\n", j);
fmt::print(" {:s}\n", tc::cli::FormatUtil::formatBytesAsString(hash_hdr.getMasterHashList()[j].data(), 0x10, true, ":"));
fmt::print(" {:s}\n", tc::cli::FormatUtil::formatBytesAsString(hash_hdr.getMasterHashList()[j].data()+0x10, 0x10, true, ":"));
}
}
else if (info.hash_type == nn::hac::nca::HashType::HierarchicalSha256)
{
auto hash_hdr = info.hierarchicalsha256_hdr;
fmt::print(" HierarchicalSha256 Header:\n");
fmt::print(" Master Hash:\n");
fmt::print(" {:s}\n", tc::cli::FormatUtil::formatBytesAsString(hash_hdr.getMasterHash().data(), 0x10, true, ":"));
fmt::print(" {:s}\n", tc::cli::FormatUtil::formatBytesAsString(hash_hdr.getMasterHash().data()+0x10, 0x10, true, ":"));
fmt::print(" HashBlockSize: 0x{:x}\n", hash_hdr.getHashBlockSize());
for (size_t j = 0; j < hash_hdr.getLayerInfo().size(); j++)
{
if (j+1 == hash_hdr.getLayerInfo().size())
{
fmt::print(" Data Layer:\n");
}
else
{
fmt::print(" Hash Layer {:d}:\n", j);
}
fmt::print(" Offset: 0x{:x}\n", hash_hdr.getLayerInfo()[j].offset);
fmt::print(" Size: 0x{:x}\n", hash_hdr.getLayerInfo()[j].size);
}
}
}
}
}
void nstool::NcaProcess::processPartitions()
{
std::vector<nn::hac::CombinedFsMetaGenerator::MountPointInfo> mount_points;
for (size_t i = 0; i < mHdr.getPartitionEntryList().size(); i++)
{
uint32_t index = mHdr.getPartitionEntryList()[i].header_index;
struct sPartitionInfo& partition = mPartitions[index];
// if the reader is null, skip
if (partition.fs_reader == nullptr)
{
fmt::print("[WARNING] NCA Partition {:d} not readable.", index);
if (partition.fail_reason.empty() == false)
{
fmt::print(" ({:s})", partition.fail_reason);
}
fmt::print("\n");
continue;
}
std::string mount_point_name;
/*
if (mHdr.getContentType() == nn::hac::nca::ContentType::Program)
{
mount_point_name = nn::hac::ContentArchiveUtil::getProgramContentParititionIndexAsString((nn::hac::nca::ProgramContentPartitionIndex)index);
}
else
*/
{
mount_point_name = fmt::format("{:d}", index);
}
mount_points.push_back( { mount_point_name, partition.fs_meta } );
}
tc::io::VirtualFileSystem::FileSystemMeta fs_meta = nn::hac::CombinedFsMetaGenerator(mount_points);
std::shared_ptr<tc::io::IStorage> nca_fs = std::make_shared<tc::io::VirtualFileSystem>(tc::io::VirtualFileSystem(fs_meta));
mFsProcess.setInputFileSystem(nca_fs);
mFsProcess.setFsFormatName("ContentArchive");
mFsProcess.setFsProperties({
fmt::format("DirNum: {:d}", fs_meta.dir_entries.size()-1),
fmt::format("FileNum: {:d}", fs_meta.file_entries.size()-1)
});
mFsProcess.setFsRootLabel(getContentTypeForMountStr(mHdr.getContentType()));
mFsProcess.process();
}
std::string nstool::NcaProcess::getContentTypeForMountStr(nn::hac::nca::ContentType cont_type) const
{
std::string str;
switch (cont_type)
{
case (nn::hac::nca::ContentType::Program):
str = "program";
break;
case (nn::hac::nca::ContentType::Meta):
str = "meta";
break;
case (nn::hac::nca::ContentType::Control):
str = "control";
break;
case (nn::hac::nca::ContentType::Manual):
str = "manual";
break;
case (nn::hac::nca::ContentType::Data):
str = "data";
break;
case (nn::hac::nca::ContentType::PublicData):
str = "publicdata";
break;
default:
str = "";
break;
}
return str;
}