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Atmosphere/stratosphere/ams_mitm/source/sysupdater/sysupdater_service.cpp

524 lines
23 KiB
C++

/*
* Copyright (c) 2018-2020 Atmosphère-NX
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include <stratosphere.hpp>
#include "sysupdater_service.hpp"
#include "sysupdater_async_impl.hpp"
#include "sysupdater_fs_utils.hpp"
namespace ams::mitm::sysupdater {
namespace {
/* ExFat NCAs prior to 2.0.0 do not actually include the exfat driver, and don't boot. */
constexpr inline u32 MinimumVersionForExFatDriver = 65536;
bool IsExFatDriverSupported(const ncm::ContentMetaInfo &info) {
return info.version >= MinimumVersionForExFatDriver && ((info.attributes & ncm::ContentMetaAttribute_IncludesExFatDriver) != 0);
}
template<typename F>
Result ForEachFileInDirectory(const char *root_path, F f) {
/* Open the directory. */
fs::DirectoryHandle dir;
R_TRY(fs::OpenDirectory(std::addressof(dir), root_path, fs::OpenDirectoryMode_File));
ON_SCOPE_EXIT { fs::CloseDirectory(dir); };
while (true) {
/* Read the current entry. */
s64 count;
fs::DirectoryEntry entry;
R_TRY(fs::ReadDirectory(std::addressof(count), std::addressof(entry), dir, 1));
if (count == 0) {
break;
}
/* Invoke our handler on the entry. */
bool done;
R_TRY(f(std::addressof(done), entry));
R_SUCCEED_IF(done);
}
return ResultSuccess();
}
Result ConvertToFsCommonPath(char *dst, size_t dst_size, const char *package_root_path, const char *entry_path) {
char package_path[ams::fs::EntryNameLengthMax];
const size_t path_len = std::snprintf(package_path, sizeof(package_path), "%s%s", package_root_path, entry_path);
AMS_ABORT_UNLESS(path_len < ams::fs::EntryNameLengthMax);
return ams::fs::ConvertToFsCommonPath(dst, dst_size, package_path);
}
Result LoadContentMeta(ncm::AutoBuffer *out, const char *package_root_path, const fs::DirectoryEntry &entry) {
AMS_ABORT_UNLESS(PathView(entry.name).HasSuffix(".cnmt.nca"));
char path[ams::fs::EntryNameLengthMax];
R_TRY(ConvertToFsCommonPath(path, sizeof(path), package_root_path, entry.name));
return ncm::ReadContentMetaPath(out, path);
}
Result ReadContentMetaPath(ncm::AutoBuffer *out, const char *package_root, const ncm::ContentInfo &content_info) {
/* Get the .cnmt.nca path for the info. */
char cnmt_nca_name[ncm::ContentIdStringLength + 10];
ncm::GetStringFromContentId(cnmt_nca_name, sizeof(cnmt_nca_name), content_info.GetId());
std::memcpy(cnmt_nca_name + ncm::ContentIdStringLength, ".cnmt.nca", std::strlen(".cnmt.nca"));
cnmt_nca_name[sizeof(cnmt_nca_name) - 1] = '\x00';
/* Create a new path. */
ncm::Path content_path;
R_TRY(ConvertToFsCommonPath(content_path.str, sizeof(content_path.str), package_root, cnmt_nca_name));
/* Read the content meta path. */
return ncm::ReadContentMetaPath(out, content_path.str);
}
Result GetSystemUpdateUpdateContentInfoFromPackage(ncm::ContentInfo *out, const char *package_root) {
bool found_system_update = false;
/* Iterate over all files to find the system update meta. */
R_TRY(ForEachFileInDirectory(package_root, [&](bool *done, const fs::DirectoryEntry &entry) -> Result {
/* Don't early terminate by default. */
*done = false;
/* We have nothing to list if we're not looking at a meta. */
R_SUCCEED_IF(!PathView(entry.name).HasSuffix(".cnmt.nca"));
/* Read the content meta path, and build. */
ncm::AutoBuffer package_meta;
R_TRY(LoadContentMeta(std::addressof(package_meta), package_root, entry));
/* Create a reader. */
const auto reader = ncm::PackagedContentMetaReader(package_meta.Get(), package_meta.GetSize());
/* If we find a system update, we're potentially done. */
if (reader.GetHeader()->type == ncm::ContentMetaType::SystemUpdate) {
/* Try to parse a content id from the name. */
auto content_id = ncm::GetContentIdFromString(entry.name, sizeof(entry.name));
R_UNLESS(content_id, ncm::ResultInvalidPackageFormat());
/* We're done. */
*done = true;
found_system_update = true;
*out = ncm::ContentInfo::Make(*content_id, entry.file_size, ncm::ContentType::Meta);
}
return ResultSuccess();
}));
/* If we didn't find anything, error. */
R_UNLESS(found_system_update, ncm::ResultSystemUpdateNotFoundInPackage());
return ResultSuccess();
}
Result ValidateSystemUpdate(Result *out_result, Result *out_exfat_result, UpdateValidationInfo *out_info, const ncm::PackagedContentMetaReader &update_reader, const char *package_root) {
/* Clear output. */
*out_result = ResultSuccess();
*out_exfat_result = ResultSuccess();
/* We want to track all content the update requires. */
const size_t num_content_metas = update_reader.GetContentMetaCount();
bool content_meta_valid[num_content_metas] = {};
/* Allocate a buffer to use for validation. */
size_t data_buffer_size = 1_MB;
void *data_buffer;
do {
data_buffer = std::malloc(data_buffer_size);
if (data_buffer != nullptr) {
break;
}
data_buffer_size /= 2;
} while (data_buffer_size >= 16_KB);
R_UNLESS(data_buffer != nullptr, fs::ResultAllocationFailureInNew());
ON_SCOPE_EXIT { std::free(data_buffer); };
/* Declare helper for result validation. */
auto ValidateResult = [&] ALWAYS_INLINE_LAMBDA (Result result) -> Result {
*out_result = result;
return result;
};
/* Iterate over all files to find all content metas. */
R_TRY(ForEachFileInDirectory(package_root, [&](bool *done, const fs::DirectoryEntry &entry) -> Result {
/* Clear output. */
*out_info = {};
/* Don't early terminate by default. */
*done = false;
/* We have nothing to list if we're not looking at a meta. */
R_SUCCEED_IF(!PathView(entry.name).HasSuffix(".cnmt.nca"));
/* Read the content meta path, and build. */
ncm::AutoBuffer package_meta;
R_TRY(LoadContentMeta(std::addressof(package_meta), package_root, entry));
/* Create a reader. */
const auto reader = ncm::PackagedContentMetaReader(package_meta.Get(), package_meta.GetSize());
/* Get the key for the reader. */
const auto key = reader.GetKey();
/* Check if we need to validate this content. */
bool need_validate = false;
size_t validation_index = 0;
for (size_t i = 0; i < num_content_metas; ++i) {
if (update_reader.GetContentMetaInfo(i)->ToKey() == key) {
need_validate = true;
validation_index = i;
break;
}
}
/* If we don't need to validate, continue. */
R_SUCCEED_IF(!need_validate);
/* We're validating. */
out_info->invalid_key = key;
/* Validate all contents. */
for (size_t i = 0; i < reader.GetContentCount(); ++i) {
const auto *content_info = reader.GetContentInfo(i);
const auto &content_id = content_info->GetId();
const s64 content_size = content_info->info.GetSize();
out_info->invalid_content_id = content_id;
/* Get the content id string. */
auto content_id_str = ncm::GetContentIdString(content_id);
/* Open the file. */
fs::FileHandle file;
{
char path[fs::EntryNameLengthMax];
std::snprintf(path, sizeof(path), "%s%s%s", package_root, content_id_str.data, content_info->GetType() == ncm::ContentType::Meta ? ".cnmt.nca" : ".nca");
if (R_FAILED(ValidateResult(fs::OpenFile(std::addressof(file), path, ams::fs::OpenMode_Read)))) {
*done = true;
return ResultSuccess();
}
}
ON_SCOPE_EXIT { fs::CloseFile(file); };
/* Validate the file size is correct. */
s64 file_size;
if (R_FAILED(ValidateResult(fs::GetFileSize(std::addressof(file_size), file)))) {
*done = true;
return ResultSuccess();
}
if (file_size != content_size) {
*out_result = ncm::ResultInvalidContentHash();
*done = true;
return ResultSuccess();
}
/* Read and hash the file in chunks. */
crypto::Sha256Generator sha;
sha.Initialize();
s64 ofs = 0;
while (ofs < content_size) {
const size_t cur_size = std::min(static_cast<size_t>(content_size - ofs), data_buffer_size);
if (R_FAILED(ValidateResult(fs::ReadFile(file, ofs, data_buffer, cur_size)))) {
*done = true;
return ResultSuccess();
}
sha.Update(data_buffer, cur_size);
ofs += cur_size;
}
/* Get the hash. */
ncm::Digest calc_digest;
sha.GetHash(std::addressof(calc_digest), sizeof(calc_digest));
/* Validate the hash. */
if (std::memcmp(std::addressof(calc_digest), std::addressof(content_info->digest), sizeof(ncm::Digest)) != 0) {
*out_result = ncm::ResultInvalidContentHash();
*done = true;
return ResultSuccess();
}
}
/* Mark the relevant content as validated. */
content_meta_valid[validation_index] = true;
*out_info = {};
return ResultSuccess();
}));
/* If we're otherwise going to succeed, ensure that every content was found. */
if (R_SUCCEEDED(*out_result)) {
for (size_t i = 0; i < num_content_metas; ++i) {
if (!content_meta_valid[i]) {
const ncm::ContentMetaInfo *info = update_reader.GetContentMetaInfo(i);
*out_info = { .invalid_key = info->ToKey(), };
if (IsExFatDriverSupported(*info)) {
*out_exfat_result = fs::ResultPathNotFound();
/* Continue, in case there's a non-exFAT failure result. */
} else {
*out_result = fs::ResultPathNotFound();
break;
}
}
}
}
return ResultSuccess();
}
Result FormatUserPackagePath(ncm::Path *out, const ncm::Path &user_path) {
/* Ensure that the user path is valid. */
R_UNLESS(user_path.str[0] == '/', fs::ResultInvalidPath());
/* Print as @Sdcard:<user_path>/ */
std::snprintf(out->str, sizeof(out->str), "%s:%s/", ams::fs::impl::SdCardFileSystemMountName, user_path.str);
/* Normalize, if the user provided an ending / */
const size_t len = std::strlen(out->str);
if (out->str[len - 1] == '/' && out->str[len - 2] == '/') {
out->str[len - 1] = '\x00';
}
return ResultSuccess();
}
const char *GetFirmwareVariationSettingName(settings::system::PlatformRegion region) {
switch (region) {
case settings::system::PlatformRegion_Global: return "firmware_variation";
case settings::system::PlatformRegion_China: return "t_firmware_variation";
AMS_UNREACHABLE_DEFAULT_CASE();
}
}
ncm::FirmwareVariationId GetFirmwareVariationId() {
/* Get the firmware variation setting name. */
const char * const setting_name = GetFirmwareVariationSettingName(settings::system::GetPlatformRegion());
/* Retrieve the firmware variation id. */
ncm::FirmwareVariationId id = {};
settings::fwdbg::GetSettingsItemValue(std::addressof(id.value), sizeof(u8), "ns.systemupdate", setting_name);
return id;
}
}
Result SystemUpdateService::GetUpdateInformation(sf::Out<UpdateInformation> out, const ncm::Path &path) {
/* Adjust the path. */
ncm::Path package_root;
R_TRY(FormatUserPackagePath(std::addressof(package_root), path));
/* Create a new update information. */
UpdateInformation update_info = {};
/* Parse the update. */
{
/* Get the content info for the system update. */
ncm::ContentInfo content_info;
R_TRY(GetSystemUpdateUpdateContentInfoFromPackage(std::addressof(content_info), package_root.str));
/* Read the content meta. */
ncm::AutoBuffer content_meta_buffer;
R_TRY(ReadContentMetaPath(std::addressof(content_meta_buffer), package_root.str, content_info));
/* Create a reader. */
const auto reader = ncm::PackagedContentMetaReader(content_meta_buffer.Get(), content_meta_buffer.GetSize());
/* Get the version from the header. */
update_info.version = reader.GetHeader()->version;
/* Iterate over infos to find the system update info. */
for (size_t i = 0; i < reader.GetContentMetaCount(); ++i) {
const auto &meta_info = *reader.GetContentMetaInfo(i);
switch (meta_info.type) {
case ncm::ContentMetaType::BootImagePackage:
/* Detect exFAT support. */
update_info.exfat_supported |= IsExFatDriverSupported(meta_info);
break;
default:
break;
}
}
/* Default to no firmware variations. */
update_info.firmware_variation_count = 0;
/* Parse firmware variations if relevant. */
if (reader.GetExtendedDataSize() != 0) {
/* Get the actual firmware variation count. */
ncm::SystemUpdateMetaExtendedDataReader extended_data_reader(reader.GetExtendedData(), reader.GetExtendedDataSize());
update_info.firmware_variation_count = extended_data_reader.GetFirmwareVariationCount();
/* NOTE: Update this if Nintendo ever actually releases an update with this many variations? */
R_UNLESS(update_info.firmware_variation_count <= FirmwareVariationCountMax, ncm::ResultInvalidFirmwareVariation());
for (size_t i = 0; i < update_info.firmware_variation_count; ++i) {
update_info.firmware_variation_ids[i] = *extended_data_reader.GetFirmwareVariationId(i);
}
}
}
/* Set the parsed update info. */
out.SetValue(update_info);
return ResultSuccess();
}
Result SystemUpdateService::ValidateUpdate(sf::Out<Result> out_validate_result, sf::Out<Result> out_validate_exfat_result, sf::Out<UpdateValidationInfo> out_validate_info, const ncm::Path &path) {
/* Adjust the path. */
ncm::Path package_root;
R_TRY(FormatUserPackagePath(std::addressof(package_root), path));
/* Parse the update. */
{
/* Get the content info for the system update. */
ncm::ContentInfo content_info;
R_TRY(GetSystemUpdateUpdateContentInfoFromPackage(std::addressof(content_info), package_root.str));
/* Read the content meta. */
ncm::AutoBuffer content_meta_buffer;
R_TRY(ReadContentMetaPath(std::addressof(content_meta_buffer), package_root.str, content_info));
/* Create a reader. */
const auto reader = ncm::PackagedContentMetaReader(content_meta_buffer.Get(), content_meta_buffer.GetSize());
/* Validate the update. */
R_TRY(ValidateSystemUpdate(out_validate_result.GetPointer(), out_validate_exfat_result.GetPointer(), out_validate_info.GetPointer(), reader, package_root.str));
}
return ResultSuccess();
};
Result SystemUpdateService::SetupUpdate(sf::CopyHandle transfer_memory, u64 transfer_memory_size, const ncm::Path &path, bool exfat) {
return this->SetupUpdateImpl(transfer_memory.GetValue(), transfer_memory_size, path, exfat, GetFirmwareVariationId());
}
Result SystemUpdateService::SetupUpdateWithVariation(sf::CopyHandle transfer_memory, u64 transfer_memory_size, const ncm::Path &path, bool exfat, ncm::FirmwareVariationId firmware_variation_id) {
return this->SetupUpdateImpl(transfer_memory.GetValue(), transfer_memory_size, path, exfat, firmware_variation_id);
}
Result SystemUpdateService::RequestPrepareUpdate(sf::OutCopyHandle out_event_handle, sf::Out<std::shared_ptr<ns::impl::IAsyncResult>> out_async) {
/* Ensure the update is setup but not prepared. */
R_UNLESS(this->setup_update, ns::ResultCardUpdateNotSetup());
R_UNLESS(!this->requested_update, ns::ResultPrepareCardUpdateAlreadyRequested());
/* Create the async result. */
auto async_result = sf::MakeShared<ns::impl::IAsyncResult, AsyncPrepareSdCardUpdateImpl>(std::addressof(*this->update_task));
R_UNLESS(async_result != nullptr, ns::ResultOutOfMaxRunningTask());
/* Run the task. */
R_TRY(async_result->GetImpl().Run());
/* We prepared the task! */
this->requested_update = true;
out_event_handle.SetValue(async_result->GetImpl().GetEvent().GetReadableHandle());
out_async.SetValue(std::move(async_result));
return ResultSuccess();
}
Result SystemUpdateService::GetPrepareUpdateProgress(sf::Out<SystemUpdateProgress> out) {
/* Ensure the update is setup. */
R_UNLESS(this->setup_update, ns::ResultCardUpdateNotSetup());
/* Get the progress. */
auto install_progress = this->update_task->GetProgress();
out.SetValue({ .current_size = install_progress.installed_size, .total_size = install_progress.total_size });
return ResultSuccess();
}
Result SystemUpdateService::HasPreparedUpdate(sf::Out<bool> out) {
/* Ensure the update is setup. */
R_UNLESS(this->setup_update, ns::ResultCardUpdateNotSetup());
out.SetValue(this->update_task->GetProgress().state == ncm::InstallProgressState::Downloaded);
return ResultSuccess();
}
Result SystemUpdateService::ApplyPreparedUpdate() {
/* Ensure the update is setup. */
R_UNLESS(this->setup_update, ns::ResultCardUpdateNotSetup());
/* Ensure the update is prepared. */
R_UNLESS(this->update_task->GetProgress().state == ncm::InstallProgressState::Downloaded, ns::ResultCardUpdateNotPrepared());
/* Apply the task. */
R_TRY(this->apply_manager.ApplyPackageTask(std::addressof(*this->update_task)));
return ResultSuccess();
}
Result SystemUpdateService::SetupUpdateImpl(os::ManagedHandle transfer_memory, u64 transfer_memory_size, const ncm::Path &path, bool exfat, ncm::FirmwareVariationId firmware_variation_id) {
/* Ensure we don't already have an update set up. */
R_UNLESS(!this->setup_update, ns::ResultCardUpdateAlreadySetup());
/* Destroy any existing update tasks. */
nim::SystemUpdateTaskId id;
auto count = nim::ListSystemUpdateTask(std::addressof(id), 1);
if (count > 0) {
R_TRY(nim::DestroySystemUpdateTask(id));
}
/* Initialize the update task. */
R_TRY(InitializeUpdateTask(transfer_memory, transfer_memory_size, path, exfat, firmware_variation_id));
/* The update is now set up. */
this->setup_update = true;
return ResultSuccess();
}
Result SystemUpdateService::InitializeUpdateTask(os::ManagedHandle &transfer_memory_handle, u64 transfer_memory_size, const ncm::Path &path, bool exfat, ncm::FirmwareVariationId firmware_variation_id) {
/* Map the transfer memory. */
const size_t tmem_buffer_size = static_cast<size_t>(transfer_memory_size);
this->update_transfer_memory.emplace(tmem_buffer_size, transfer_memory_handle.Get(), true);
void *tmem_buffer;
R_TRY(this->update_transfer_memory->Map(std::addressof(tmem_buffer), os::MemoryPermission_None));
auto tmem_guard = SCOPE_GUARD {
this->update_transfer_memory->Unmap();
this->update_transfer_memory = std::nullopt;
};
/* Now that the memory is mapped, the input handle is managed and can be released. */
transfer_memory_handle.Detach();
/* Adjust the package root. */
ncm::Path package_root;
R_TRY(FormatUserPackagePath(std::addressof(package_root), path));
/* Ensure that we can create an update context. */
R_TRY(fs::EnsureDirectoryRecursively("@Sdcard:/atmosphere/update/"));
const char *context_path = "@Sdcard:/atmosphere/update/cup.ctx";
/* Create and initialize the update task. */
this->update_task.emplace();
R_TRY(this->update_task->Initialize(package_root.str, context_path, tmem_buffer, tmem_buffer_size, exfat, firmware_variation_id));
/* We successfully setup the update. */
tmem_guard.Cancel();
return ResultSuccess();
}
}