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nxdumptool/include/data_transfer_task.hpp
Pablo Curiel 9525f37e51 [ci skip] Add DataTransfer* classes.
Adds the DataTransferTask and DataTransferProgressDisplay classes, which use repurposed logic from the DownloadTask and EtaProgressDisplay classes, respectively. The EtaProgressDisplay class and EtaProgressInfo struct have been removed.

Other changes include:

* DownloadTask: heavily simplified logic by using DataTransferTask as the base class.

* DumpOptionsFrame: implement some additional/experimental changes.

* OptionsTab: update logic to use the new DataTransferProgressDisplay class.
2024-04-15 01:53:43 +02:00

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9.9 KiB
C++

/*
* data_transfer_task.hpp
*
* Copyright (c) 2020-2024, DarkMatterCore <pabloacurielz@gmail.com>.
*
* This file is part of nxdumptool (https://github.com/DarkMatterCore/nxdumptool).
*
* nxdumptool is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* nxdumptool is distributed in the hope that 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 <https://www.gnu.org/licenses/>.
*/
#pragma once
#ifndef __DATA_TRANSFER_TASK_HPP__
#define __DATA_TRANSFER_TASK_HPP__
#include <borealis.hpp>
#include "core/nxdt_utils.h"
#include "async_task.hpp"
namespace nxdt::tasks
{
/* Used to hold data transfer progress info. */
typedef struct {
size_t total_size; ///< Total size for the data transfer process.
size_t xfer_size; ///< Number of bytes transferred thus far.
int percentage; ///< Progress percentage.
double speed; ///< Current speed expressed in bytes per second.
std::string eta; ///< Formatted ETA string.
} DataTransferProgress;
/* Custom event type used to push data transfer progress updates. */
typedef brls::Event<const DataTransferProgress&> DataTransferProgressEvent;
/* Class template to asynchronously transfer data on a background thread. */
/* Automatically allocates and registers a RepeatingTask on its own, which is started along with the actual task when AsyncTask::execute() is called. */
/* This internal RepeatingTask is guaranteed to work on the UI thread, and it is also automatically unregistered on object destruction. */
/* Progress updates are pushed through a DataTransferProgressEvent. Make sure to register all event listeners before executing the task. */
template<typename Result, typename... Params>
class DataTransferTask: public AsyncTask<DataTransferProgress, Result, Params...>
{
private:
/* Handles task progress updates on the calling thread. */
class Handler: public brls::RepeatingTask
{
private:
bool finished = false;
DataTransferTask<Result, Params...>* task = nullptr;
protected:
void run(retro_time_t current_time) override final
{
brls::RepeatingTask::run(current_time);
if (this->task && !this->finished) this->finished = this->task->loopCallback();
}
public:
Handler(retro_time_t interval, DataTransferTask<Result, Params...>* task) : brls::RepeatingTask(interval), task(task) { }
ALWAYS_INLINE bool IsFinished(void)
{
return this->finished;
}
};
typedef std::chrono::time_point<std::chrono::steady_clock> SteadyTimePoint;
static constexpr auto &CurrentSteadyTimePoint = std::chrono::steady_clock::now;
DataTransferProgressEvent progress_event{};
Handler *task_handler = nullptr;
SteadyTimePoint start_time{}, prev_time{}, end_time{};
size_t prev_xfer_size = 0;
protected:
/* Set class as non-copyable and non-moveable. */
NON_COPYABLE(DataTransferTask);
NON_MOVEABLE(DataTransferTask);
/* Make the background function overridable. */
virtual Result doInBackground(const Params&... params) override = 0;
/* Runs on the calling thread. */
void onCancelled(const Result& result) override final
{
NX_IGNORE_ARG(result);
/* Set end time. */
this->end_time = CurrentSteadyTimePoint();
/* Pause task handler. */
this->task_handler->pause();
/* Unset long running process state. */
utilsSetLongRunningProcessState(false);
}
/* Runs on the calling thread. */
void onPostExecute(const Result& result) override final
{
NX_IGNORE_ARG(result);
/* Set end time. */
this->end_time = CurrentSteadyTimePoint();
/* Fire task handler immediately to get the last result from AsyncTask::loopCallback(), then pause it. */
this->task_handler->fireNow();
this->task_handler->pause();
/* Update progress one last time. */
this->onProgressUpdate(this->getProgress());
/* Unset long running process state. */
utilsSetLongRunningProcessState(false);
}
/* Runs on the calling thread. */
void onPreExecute(void) override final
{
/* Set long running process state. */
utilsSetLongRunningProcessState(true);
/* Start task handler. */
this->task_handler->start();
/* Set start time. */
this->start_time = this->prev_time = CurrentSteadyTimePoint();
}
/* Runs on the calling thread. */
void onProgressUpdate(const DataTransferProgress& progress) override final
{
AsyncTaskStatus status = this->getStatus();
/* Return immediately if there has been no progress at all, or if it the task has been cancelled. */
bool proceed = (progress.xfer_size > prev_xfer_size || (progress.xfer_size == prev_xfer_size && (!progress.total_size || progress.xfer_size >= progress.total_size)));
if (!proceed || this->isCancelled()) return;
/* Calculate time difference between the last progress update and the current one. */
/* Return immediately if it's less than 1 second, but only if this isn't the last chunk; or if we don't know the total size and the task is still running . */
SteadyTimePoint cur_time = std::chrono::steady_clock::now();
double diff_time = std::chrono::duration<double>(cur_time - this->prev_time).count();
if (diff_time < 1.0 && ((progress.total_size && progress.xfer_size < progress.total_size) || status == AsyncTaskStatus::RUNNING)) return;
/* Calculate transferred data size difference between the last progress update and the current one. */
double diff_xfer_size = static_cast<double>(progress.xfer_size - prev_xfer_size);
/* Calculate transfer speed in bytes per second. */
double speed = (diff_xfer_size / diff_time);
/* Fill struct. */
DataTransferProgress new_progress = progress;
new_progress.speed = speed;
if (progress.total_size)
{
/* Calculate remaining data size and ETA if we know the total size. */
double remaining = static_cast<double>(progress.total_size - progress.xfer_size);
double eta = (remaining / speed);
new_progress.eta = fmt::format("{:02.0F}H{:02.0F}M{:02.0F}S", std::fmod(eta, 86400.0) / 3600.0, std::fmod(eta, 3600.0) / 60.0, std::fmod(eta, 60.0));
} else {
/* No total size means no ETA calculation, sadly. */
new_progress.eta = "";
}
/* Set total size if we don't know it and if this is the final chunk. */
if (!new_progress.total_size && status == AsyncTaskStatus::FINISHED)
{
new_progress.total_size = new_progress.xfer_size;
new_progress.percentage = 100;
}
/* Update class variables. */
this->prev_time = cur_time;
this->prev_xfer_size = progress.xfer_size;
/* Send updated progress to all listeners. */
this->progress_event.fire(new_progress);
}
public:
DataTransferTask(void)
{
/* Create task handler. */
this->task_handler = new Handler(DATA_TRANSFER_TASK_INTERVAL, this);
}
~DataTransferTask(void)
{
/* Stop task handler. Borealis' task manager will take care of deleting it. */
this->task_handler->stop();
/* Unregister all event listeners. */
this->progress_event.unsubscribeAll();
}
/* Returns the last result from AsyncTask::loopCallback(). Runs on the calling thread. */
ALWAYS_INLINE bool IsFinished(void)
{
return this->task_handler->IsFinished();
}
/* Returns the task duration expressed in seconds. */
/* If the task hasn't finished yet, it returns the number of seconds that have passed since the task was started. */
ALWAYS_INLINE double GetDuration(void)
{
return std::chrono::duration<double>(this->IsFinished() ? (this->end_time - this->start_time) : (CurrentSteadyTimePoint() - this->start_time)).count();
}
ALWAYS_INLINE DataTransferProgressEvent::Subscription RegisterListener(DataTransferProgressEvent::Callback cb)
{
return this->progress_event.subscribe(cb);
}
ALWAYS_INLINE void UnregisterListener(DataTransferProgressEvent::Subscription subscription)
{
this->progress_event.unsubscribe(subscription);
}
};
}
#endif /* __DATA_TRANSFER_TASK_HPP__ */