//
// Created by WolverinDEV on 04/05/2020.
//
#include <cassert>
#include <event2/event.h>
#include <log/LogUtils.h>
#include <random>
#include "./LocalFileProvider.h"
#include "./LocalFileTransfer.h"
#include <experimental/filesystem>
namespace fs = std::experimental::filesystem;
using namespace ts::server::file;
using namespace ts::server::file::transfer;
Buffer* transfer::allocate_buffer(size_t size) {
auto total_size = sizeof(Buffer) + size;
auto buffer = (Buffer*) malloc(total_size);
new (buffer) Buffer{};
buffer->capacity = size;
buffer->ref_count = 1;
return buffer;
}
Buffer* transfer::ref_buffer(Buffer *buffer) {
buffer->ref_count++;
return buffer;
}
void transfer::deref_buffer(Buffer *buffer) {
if(--buffer->ref_count == 0) {
buffer->~Buffer();
free(buffer);
}
}
FileClient::~FileClient() {
this->flush_network_buffer();
this->flush_disk_buffer();
assert(!this->disk_buffer.buffer_head);
assert(!this->network_buffer.buffer_head);
assert(!this->file.file_descriptor);
assert(!this->file.currently_processing);
assert(!this->file.next_client);
assert(!this->networking.event_read);
assert(!this->networking.event_write);
assert(this->state == STATE_DISCONNECTED);
memtrack::freed<FileClient>(this);
}
LocalFileTransfer::LocalFileTransfer(filesystem::LocalFileSystem *fs) : file_system_{fs} {}
LocalFileTransfer::~LocalFileTransfer() = default;
bool LocalFileTransfer::start() {
(void) this->start_client_worker();
{
auto start_result = this->start_disk_io();
switch (start_result) {
case DiskIOStartResult::SUCCESS:
break;
case DiskIOStartResult::OUT_OF_MEMORY:
logError(LOG_FT, "Failed to start disk worker (Out of memory)");
goto error_exit_disk;
default:
logError(LOG_FT, "Failed to start disk worker ({})", (int) start_result);
goto error_exit_disk;
}
}
{
auto start_result = this->start_networking();
switch (start_result) {
case NetworkingStartResult::SUCCESS:
break;
case NetworkingStartResult::OUT_OF_MEMORY:
logError(LOG_FT, "Failed to start networking (Out of memory)");
goto error_exit_network;
default:
logError(LOG_FT, "Failed to start networking ({})", (int) start_result);
goto error_exit_network;
}
}
return true;
error_exit_network:
this->shutdown_networking();
error_exit_disk:
this->shutdown_disk_io();
this->shutdown_client_worker();
return false;
}
void LocalFileTransfer::stop() {
this->shutdown_networking();
this->shutdown_disk_io();
this->shutdown_client_worker();
}
std::shared_ptr<ExecuteResponse<TransferInitError, std::shared_ptr<Transfer>>>
LocalFileTransfer::initialize_icon_transfer(Transfer::Direction direction, const std::shared_ptr<VirtualFileServer> &server, const TransferInfo &info) {
return this->initialize_transfer(direction, server, 0, Transfer::TARGET_TYPE_ICON, info);
}
std::shared_ptr<ExecuteResponse<TransferInitError, std::shared_ptr<Transfer>>>
LocalFileTransfer::initialize_avatar_transfer(Transfer::Direction direction, const std::shared_ptr<VirtualFileServer> &server, const TransferInfo &info) {
return this->initialize_transfer(direction, server, 0, Transfer::TARGET_TYPE_AVATAR, info);
}
std::shared_ptr<ExecuteResponse<TransferInitError, std::shared_ptr<Transfer>>>
LocalFileTransfer::initialize_channel_transfer(Transfer::Direction direction, const std::shared_ptr<VirtualFileServer> &server, ChannelId cid, const TransferInfo &info) {
return this->initialize_transfer(direction, server, cid, Transfer::TARGET_TYPE_CHANNEL_FILE, info);
}
std::shared_ptr<ExecuteResponse<TransferInitError, std::shared_ptr<Transfer>>> LocalFileTransfer::initialize_transfer(
Transfer::Direction direction, const std::shared_ptr<VirtualFileServer> &server, ChannelId cid,
Transfer::TargetType ttype,
const TransferInfo &info) {
auto response = this->create_execute_response<TransferInitError, std::shared_ptr<Transfer>>();
std::lock_guard clock{this->transfer_create_mutex};
if(info.max_concurrent_transfers > 0) {
std::unique_lock tlock{this->transfers_mutex};
{
auto transfers = std::count_if(this->transfers_.begin(), this->transfers_.end(), [&](const std::shared_ptr<FileClient>& client) {
return client->transfer && client->transfer->client_unique_id == info.client_unique_id && client->state < FileClient::STATE_FLUSHING;
});
transfers += std::count_if(this->pending_transfers.begin(), this->pending_transfers.end(), [&](const std::shared_ptr<Transfer>& transfer) {
return transfer->client_unique_id == info.client_unique_id;
});
if(transfers >= info.max_concurrent_transfers) {
response->emplace_fail(TransferInitError::CLIENT_TOO_MANY_TRANSFERS, std::to_string(transfers));
return response;
}
}
{
auto server_transfers = this->pending_transfers.size();
server_transfers += std::count_if(this->transfers_.begin(), this->transfers_.end(), [&](const std::shared_ptr<FileClient>& client) {
return client->transfer;
});
if(server_transfers >= this->max_concurrent_transfers) {
response->emplace_fail(TransferInitError::SERVER_TOO_MANY_TRANSFERS, std::to_string(server_transfers));
return response;
}
}
}
auto transfer = std::make_shared<Transfer>();
transfer->server_transfer_id = server->generate_transfer_id();
transfer->server = server;
transfer->channel_id = cid;
transfer->target_type = ttype;
transfer->direction = direction;
transfer->client_id = 0; /* must be provided externally */
transfer->client_transfer_id = 0; /* must be provided externally */
transfer->server_addresses.reserve(this->network.bindings.size());
for(auto& binding : this->network.bindings) {
if(!binding->file_descriptor) continue;
transfer->server_addresses.emplace_back(Transfer::Address{binding->hostname, net::port(binding->address)});
}
transfer->target_file_path = info.file_path;
transfer->file_offset = info.file_offset;
transfer->expected_file_size = info.expected_file_size;
transfer->max_bandwidth = info.max_bandwidth;
transfer->client_unique_id = info.client_unique_id;
transfer->client_id = info.client_id;
constexpr static std::string_view kTokenCharacters{"abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ0123456789"};
transfer->transfer_key.resize(TRANSFER_KEY_LENGTH);
for(auto& c : transfer->transfer_key) {
c = kTokenCharacters[transfer_random_token_generator() % kTokenCharacters.length()];
}
transfer->transfer_key[0] = (char) 'r'; /* (114) */ /* a non valid SSL header type to indicate that we're using a file transfer key and not doing a SSL handshake */
transfer->transfer_key[1] = (char) 'a'; /* ( 97) */
transfer->transfer_key[2] = (char) 'w'; /* (119) */
transfer->initialized_timestamp = std::chrono::system_clock::now();
{
std::string absolute_path{};
switch (transfer->target_type) {
case Transfer::TARGET_TYPE_AVATAR:
absolute_path = this->file_system_->absolute_avatar_path(transfer->server, transfer->target_file_path);
break;
case Transfer::TARGET_TYPE_ICON:
absolute_path = this->file_system_->absolute_icon_path(transfer->server, transfer->target_file_path);
break;
case Transfer::TARGET_TYPE_CHANNEL_FILE:
absolute_path = this->file_system_->absolute_channel_path(transfer->server, transfer->channel_id, transfer->target_file_path);
break;
case Transfer::TARGET_TYPE_UNKNOWN:
default:
response->emplace_fail(TransferInitError::INVALID_FILE_TYPE, "");
return response;
}
transfer->absolute_file_path = absolute_path;
const auto root_path_length = this->file_system_->root_path().size();
if(root_path_length < absolute_path.size())
transfer->relative_file_path = absolute_path.substr(root_path_length);
else
transfer->relative_file_path = "error";
transfer->file_name = fs::u8path(absolute_path).filename();
}
if(direction == Transfer::DIRECTION_DOWNLOAD) {
auto path = fs::u8path(transfer->absolute_file_path);
std::error_code error{};
if(!fs::exists(path, error)) {
response->emplace_fail(TransferInitError::FILE_DOES_NOT_EXISTS, "");
return response;
} else if(error) {
logWarning(LOG_FT, "Failed to check for file at {}: {}. Assuming it does not exists.", transfer->absolute_file_path, error.value(), error.message());
response->emplace_fail(TransferInitError::FILE_DOES_NOT_EXISTS, "");
return response;
}
auto status = fs::status(path, error);
if(error) {
logWarning(LOG_FT, "Failed to status for file at {}: {}. Ignoring file transfer.", transfer->absolute_file_path, error.value(), error.message());
response->emplace_fail(TransferInitError::IO_ERROR, "stat");
return response;
}
if(status.type() != fs::file_type::regular) {
response->emplace_fail(TransferInitError::FILE_IS_NOT_A_FILE, "");
return response;
}
transfer->expected_file_size = fs::file_size(path, error);
if(error) {
logWarning(LOG_FT, "Failed to get file size for file at {}: {}. Ignoring file transfer.", transfer->absolute_file_path, error.value(), error.message());
response->emplace_fail(TransferInitError::IO_ERROR, "file_size");
return response;
}
if(info.download_client_quota_limit > 0 && info.download_client_quota_limit <= transfer->expected_file_size) {
response->emplace_fail(TransferInitError::CLIENT_QUOTA_EXCEEDED, "");
return response;
}
if(info.download_server_quota_limit > 0 && info.download_server_quota_limit <= transfer->expected_file_size) {
response->emplace_fail(TransferInitError::SERVER_QUOTA_EXCEEDED, "");
return response;
}
}
{
std::lock_guard tlock{this->transfers_mutex};
this->pending_transfers.push_back(transfer);
}
switch (transfer->target_type) {
case Transfer::TARGET_TYPE_AVATAR:
logMessage(LOG_FT, "Initialized avatar transfer for avatar \"{}\" ({} bytes, transferring {} bytes).", transfer->target_file_path, transfer->expected_file_size, transfer->expected_file_size - transfer->file_offset);
break;
case Transfer::TARGET_TYPE_ICON:
logMessage(LOG_FT, "Initialized icon transfer for icon \"{}\" ({} bytes, transferring {} bytes).",
transfer->target_file_path, transfer->expected_file_size, transfer->expected_file_size - transfer->file_offset);
break;
case Transfer::TARGET_TYPE_CHANNEL_FILE:
logMessage(LOG_FT, "Initialized channel transfer for file \"{}/{}\" ({} bytes, transferring {} bytes).",
transfer->channel_id, transfer->target_file_path, transfer->expected_file_size, transfer->expected_file_size - transfer->file_offset);
break;
case Transfer::TARGET_TYPE_UNKNOWN:
default:
response->emplace_fail(TransferInitError::INVALID_FILE_TYPE, "");
return response;
}
if(auto callback{this->callback_transfer_registered}; callback)
callback(transfer);
response->emplace_success(std::move(transfer));
return response;
}
std::shared_ptr<ExecuteResponse<TransferActionError>> LocalFileTransfer::stop_transfer(const std::shared_ptr<VirtualFileServer>& server, transfer_id id, bool flush) {
auto response = this->create_execute_response<TransferActionError>();
std::shared_ptr<Transfer> transfer{};
std::shared_ptr<FileClient> connected_transfer{};
{
std::lock_guard tlock{this->transfers_mutex};
auto ct_it = std::find_if(this->transfers_.begin(), this->transfers_.end(), [&](const std::shared_ptr<FileClient>& t) {
return t->transfer && t->transfer->server_transfer_id == id && t->transfer->server == server;
});
if(ct_it != this->transfers_.end())
connected_transfer = *ct_it;
else {
auto t_it = std::find_if(this->pending_transfers.begin(), this->pending_transfers.end(), [&](const std::shared_ptr<Transfer>& t) {
return t->server_transfer_id == id && t->server == server;
});
if(t_it != this->pending_transfers.end()) {
transfer = *t_it;
this->pending_transfers.erase(t_it);
}
}
}
if(!transfer) {
if(connected_transfer)
transfer = connected_transfer->transfer;
else {
response->emplace_fail(TransferActionError{TransferActionError::UNKNOWN_TRANSFER, ""});
return response;
}
}
if(connected_transfer) {
this->invoke_aborted_callback(connected_transfer, { TransferError::USER_REQUEST, "" });
logMessage(LOG_FT, "{} Stopping transfer due to an user request.", connected_transfer->log_prefix());
std::unique_lock slock{connected_transfer->state_mutex};
this->disconnect_client(connected_transfer, slock, flush);
} else {
this->invoke_aborted_callback(transfer, { TransferError::USER_REQUEST, "" });
logMessage(LOG_FT, "Removing pending file transfer for id {}", id);
}
response->emplace_success();
return response;
}
inline void apply_transfer_info(const std::shared_ptr<Transfer>& transfer, ActiveFileTransfer& info) {
info.server_transfer_id = transfer->server_transfer_id;
info.client_transfer_id = transfer->client_transfer_id;
info.direction = transfer->direction;
info.client_id = transfer->client_id;
info.client_unique_id = transfer->client_unique_id;
info.file_path = transfer->relative_file_path;
info.file_name = transfer->file_name;
info.expected_size = transfer->expected_file_size;
}
std::shared_ptr<ExecuteResponse<TransferListError, std::vector<ActiveFileTransfer>>> LocalFileTransfer::list_transfer() {
std::vector<ActiveFileTransfer> transfer_infos{};
auto response = this->create_execute_response<TransferListError, std::vector<ActiveFileTransfer>>();
std::unique_lock tlock{this->transfers_mutex};
auto awaiting_transfers = this->pending_transfers;
auto running_transfers = this->transfers_;
tlock.unlock();
transfer_infos.reserve(awaiting_transfers.size() + running_transfers.size());
for(const auto& transfer : awaiting_transfers) {
ActiveFileTransfer info{};
apply_transfer_info(transfer, info);
info.size_done = transfer->file_offset;
info.status = ActiveFileTransfer::NOT_STARTED;
info.runtime = std::chrono::milliseconds{0};
info.average_speed = 0;
info.current_speed = 0;
transfer_infos.push_back(info);
}
for(const auto& client : running_transfers) {
auto transfer = client->transfer;
if(!transfer) continue;
ActiveFileTransfer info{};
apply_transfer_info(transfer, info);
info.size_done = transfer->file_offset + client->statistics.file_transferred.total_bytes;
info.status = ActiveFileTransfer::RUNNING;
info.runtime = std::chrono::floor<std::chrono::milliseconds>(std::chrono::system_clock::now() - client->timings.key_received);
info.average_speed = client->statistics.file_transferred.average_bandwidth();
info.current_speed = client->statistics.file_transferred.current_bandwidth();
transfer_infos.push_back(info);
}
response->emplace_success(std::move(transfer_infos));
return response;
}