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/***************************************************************************
* Copyright (C) 2007 - 2013 by Andreas Theofilu *
* andreas@theosys.at *
* *
* This program 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 version 3 of the License. *
* *
* This program 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, write to the *
* Free Software Foundation, Inc., *
* 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. *
***************************************************************************/
#include "config.h"
#include "managefile.h"
#include "sportwatcherwidget.h"
#include "settingswidget.h"
#include "progresswidget.h"
#include "wmsbase.h"
#include "coordinateswidget.h"
#include "shapewidget.h"
#include <string.h>
#include <iostream>
#include <kfiledialog.h>
#include <kmessagebox.h>
#include <KConfig>
#include <klocale.h>
#include <k3listview.h>
#include <kaboutdata.h>
#include <kaboutapplicationdialog.h>
#include <kinputdialog.h>
#include <kglobalsettings.h>
#include <kcombobox.h>
#include <qapplication.h>
#include <qstring.h>
#include <qdatetime.h>
#include <qtoolbutton.h>
#include <qcursor.h>
#include <qregexp.h>
#include <QMouseEvent>
#include <QRect>
#include <QRegion>
#include <KIcon>
#include <QPrintDialog>
#include <QPrinter>
#if defined HAVE_GDAL
#include <gdal/ogr_spatialref.h>
#include <gdal/ogrsf_frmts.h>
#include <gdal/gdalwarper.h>
#include <gdal/ogrsf_frmts.h>
#include "GDALError.h"
#endif
#include "garmin.h"
#include "transform.h"
#if defined HAVE_MAPNIK
#include "render.h"
#endif
using std::cout;
using std::cerr;
using std::clog;
using std::endl;
typedef struct
{
double lon;
double lat;
} posn_type;
#if defined HAVE_GDAL
typedef struct ERRMSG
{
char msg[4096];
ERRMSG *next;
} ERRMSG;
ERRMSG *firstError;
#endif
sportwatcherWidget::sportwatcherWidget(QWidget *parent)
{
ui_sportwatcherWidgetBase.setupUi(this);
#if defined HAVE_GDAL
mFactor = 10; // Factor to calculate square pixels
firstError = 0;
#endif
mama = parent;
gmn = 0;
min_hr = max_hr = avg_hr = 0;
min_height = max_height = 0.0;
max_time = 0;
zfactor = 0;
mapLap = 0;
mapPan = QRect(0, 0, 0, 0);
stateHand = stateFlag = stateGlas = false;
oldTransX = oldTransY = 0.0;
lmbPressed = 0;
DIRTY = true;
curTab = ui_sportwatcherWidgetBase.tabView->currentIndex();
tabDirt0 = tabDirt1 = tabDirt2 = tabDirt3 = true;
ActivePrint = false; // true if we are printing on paper
kl = new KLocale(QString("kdesktop"), 0);
// Load the config parameters
KConfig cfg(QString("sportwatcher.rc"), KConfig::SimpleConfig);
KConfigGroup ic(&cfg, "SportWatcher");
lower1 = ic.readEntry("lower1", 0);
lower2 = ic.readEntry("lower2", 0);
lower3 = ic.readEntry("lower3", 0);
upper1 = ic.readEntry("upper1", 0);
upper2 = ic.readEntry("upper2", 0);
upper3 = ic.readEntry("upper3", 0);
MaxHr = ic.readEntry("maxHr", 180);
restHr = ic.readEntry("restHr", 60);
vo2max = ic.readEntry("vo2max", 50);
weight = ic.readEntry("weight", 70);
sampleTime = ic.readEntry("seconds", 15);
Serial = ic.readEntry("Serial", false);
Forerunner = ic.readEntry("Forerunner", false);
Contour = ic.readEntry("Contour", false);
Device = ic.readEntry("Device", "/dev/ttyUSB0");
Data = ic.readEntry("Data", QDir::home().absolutePath() + "/.sportwatcher");
HRM = ic.readEntry("HRM", QDir::home().absolutePath() + "/polar");
MAP = ic.readEntry("MAP", QDir::home().absolutePath() + "/.sportwatcher/track.wms");
Units = ic.readEntry("Units", 0);
MapType = ic.readEntry("MapType", 7);
#ifdef HAVE_GDAL
// set our own error handler here
CPLSetErrorHandler((CPLErrorHandler)spwErrorHandler);
#endif
}
sportwatcherWidget::~sportwatcherWidget()
{
destroy();
delete kl;
#ifdef HAVE_GDAL
// destroy the error handler here
CPLSetErrorHandler(NULL);
#endif
}
void sportwatcherWidget::destroy()
{
if(gmn)
garmin_free_data(gmn);
gmn = 0;
oldTransX = oldTransY = 0.0;
}
void sportwatcherWidget::Initialize()
{
// Set some widget settings
ui_sportwatcherWidgetBase.btHand->setIcon(KIcon("hand"));
ui_sportwatcherWidgetBase.btGlas->setIcon(KIcon("glas"));
ui_sportwatcherWidgetBase.btGlasMinus->setIcon(KIcon("glas_minus"));
ui_sportwatcherWidgetBase.btGlasPlus->setIcon(KIcon("glas_plus"));
ui_sportwatcherWidgetBase.btFlag->setIcon(KIcon("flag"));
ui_sportwatcherWidgetBase.btFullscreen->setIcon(KIcon("fullscreen"));
if(curTab != 0)
{
ui_sportwatcherWidgetBase.tabView->setCurrentIndex(0);
curTab = ui_sportwatcherWidgetBase.tabView->currentIndex();
}
// btHand->setToggleButton(true);
// btGlas->setToggleButton(true);
// Fill the activities
getActivities();
#if defined HAVE_GDAL
// Initialize the GDAL
GDALAllRegister();
poDataset = 0;
#endif
}
QTreeWidgetItem *sportwatcherWidget::findElement(QTreeWidget *wdg, const QString &val)
{
QTreeWidgetItem *item, *child, *subchild;
if(!wdg)
return 0;
for(int a = 0; a < wdg->topLevelItemCount(); a++)
{
if(!(item = wdg->topLevelItem(a)))
continue;
for(int j = 0; j < item->childCount(); j++)
{
if(!(child = item->child(j)))
continue;
if(child->data(0, Qt::UserRole).toString() == val)
return child;
for(int i = 0; i < child->childCount(); i++)
{
if(!(subchild = child->child(i)))
continue;
if(subchild->data(0, Qt::UserRole).toString() == val)
return subchild;
}
}
}
return 0;
}
/*
* Search for a directory named .sportwatcher in the home directory of
* the user and search for *.gmn files. Open the files and read the header
* to find the basic data of activities. Then add the information into
* the activities KListView.
*/
void sportwatcherWidget::getActivities()
{
QString path, txt;
QDir mdir, dir = QDir::home();
QStringList years, months;
QTreeWidgetItem *running, *biking, *other, *year_run, *year_bike, *year_other;
QTreeWidgetItem *el;
QList<QTreeWidgetItem *> item;
int i, j;
int y_run, y_bike, y_other;
RUN_NODE *rn;
LAP *lap;
if(Data.isEmpty())
{
path = dir.homePath();
path.append("/.sportwatcher");
}
else
path = Data;
dir.setPath(path);
dir.refresh();
if(!dir.exists())
{
dir.mkdir(path);
return;
}
destroy();
if(!ui_sportwatcherWidgetBase.liActivities)
{
KMessageBox::error(this, i18n("Error initializing some widgets of main window!"));
return;
}
ui_sportwatcherWidgetBase.liActivities->clear();
ui_sportwatcherWidgetBase.liActivities->setSortingEnabled(false);
ui_sportwatcherWidgetBase.liActivities->setColumnCount(1);
running = new QTreeWidgetItem(ui_sportwatcherWidgetBase.liActivities);
biking = new QTreeWidgetItem(ui_sportwatcherWidgetBase.liActivities);
other = new QTreeWidgetItem(ui_sportwatcherWidgetBase.liActivities);
if(!other || !biking || !running)
{
KMessageBox::error(this, i18n("Not enough memory to initilize application!"));
return;
}
running->setFlags(Qt::ItemIsSelectable | Qt::ItemIsEnabled);
biking->setFlags(Qt::ItemIsSelectable | Qt::ItemIsEnabled);
other->setFlags(Qt::ItemIsSelectable | Qt::ItemIsEnabled);
running->setText(0, i18n("Running"));
biking->setText(0, i18n("Biking"));
other->setText(0, i18n("Others"));
KIcon fld(QString("history"));
running->setIcon(0, fld);
biking->setIcon(0, fld);
other->setIcon(0, fld);
running->setStatusTip(0, i18n("\"Running\" activities."));
biking->setStatusTip(0, i18n("\"Biking\" activities."));
other->setStatusTip(0, i18n("\"Other\" and \"Multisport\" activities."));
dir.cd(path);
dir.setFilter(QDir::Dirs | QDir::NoSymLinks);
dir.setSorting(QDir::Name);
dir.refresh();
QFileInfoList list = dir.entryInfoList();
if(!list.size())
return;
for(i = 0; i < list.size(); i++) // Years
{
QFileInfo fileInfo = list.at(i);
if(fileInfo.fileName() == QString(".") || fileInfo.fileName() == QString(".."))
continue;
years += fileInfo.absoluteFilePath();
}
for(i = 0; i < years.size(); ++i)
{
if(months.size() > 0)
months.clear();
dir.setPath(years.at(i));
dir.refresh();
list = dir.entryInfoList();
if(!list.size())
continue;
for(j = 0; j < list.size(); j++) // Months
{
QFileInfo fileInfo = list.at(j);
if(fileInfo.fileName() == QString(".") || fileInfo.fileName() == QString(".."))
continue;
months += fileInfo.absoluteFilePath();
}
for(j = 0; j < months.size(); ++j)
{
mdir.setPath(months.at(j));
mdir.cd(months.at(j));
mdir.setFilter(QDir::Files | QDir::NoSymLinks);
mdir.setSorting(QDir::Name);
mdir.setNameFilters(QStringList("*.gmn"));
mdir.refresh();
list = mdir.entryInfoList();
if(!list.size())
continue;
for(int a = 0; a < list.size(); a++) // Files
{
QFileInfo fileInfo = list.at(a);
files += fileInfo.absoluteFilePath();
}
}
}
y_run = y_bike = y_other = 0;
year_run = year_bike = year_other = 0;
// Open every file and read its head
for(i = 0; i < files.size(); ++i)
{
QTreeWidgetItem *yr, *yb, *yo;
if(findElement(ui_sportwatcherWidgetBase.liActivities, files.at(i)))
continue;
spw.destroy();
if(spw.setFileName(files.at(i).toAscii().constData()) == -1)
return;
if(gmn)
{
garmin_free_data(gmn);
gmn = 0;
}
if(!(gmn = spw.readFile()))
continue;
ds.destroy();
ds.garmin_print_data(gmn);
rn = ds.getRunNode();
if(!rn)
return;
lap = ds.getLap(rn->run->first_lap_index);
if(!lap)
return;
const QDateTime *qt = garmin_dtime(lap->start_time);
// By default set the name of the session to the date and time
// it was recorded.
QString idx = kl->formatDateTime(*qt, KLocale::ShortDate, true);
QString stTip = kl->formatDateTime(*qt, KLocale::LongDate, true);
// If we have a custom name for this session, set it.
if(strlen(rn->run->workout.name) > 1 && strlen(rn->run->workout.name) < 16 && isalpha(rn->run->workout.name[0]))
idx = QString(rn->run->workout.name);
switch(rn->run->sport_type)
{
case D1000_running:
yr = findElement(ui_sportwatcherWidgetBase.liActivities, QString("run_%1").arg(qt->date().year()));
if(!yr && qt->date().year() != y_run)
{
year_run = new QTreeWidgetItem(running, running, QTreeWidgetItem::Type);
y_run = qt->date().year();
year_run->setText(0, QString("%1").arg(y_run));
year_run->setData(0, Qt::UserRole, QString("run_%1").arg(y_run));
year_run->setIcon(0, KIcon(QString("today")));
year_run->setFlags(Qt::ItemIsEnabled | Qt::ItemIsSelectable);
}
else
year_run = yr;
el = new QTreeWidgetItem(year_run, year_run, QTreeWidgetItem::Type);
el->setText(0, idx);
el->setData(0, Qt::UserRole, files.at(i));
el->setIcon(0, KIcon(QString("spw-running")));
el->setStatusTip(0, stTip);
el->setToolTip(0, stTip);
el->setFlags(Qt::ItemIsEnabled | Qt::ItemIsSelectable);
break;
case D1000_biking:
yb = findElement(ui_sportwatcherWidgetBase.liActivities, QString("bike_%1").arg(qt->date().year()));
if(!yb && qt->date().year() != y_bike)
{
year_bike = new QTreeWidgetItem(biking, biking, QTreeWidgetItem::Type);
y_bike = qt->date().year();
year_bike->setText(0, QString("%1").arg(y_bike));
year_bike->setData(0, Qt::UserRole, QString("bike_%1").arg(y_bike));
year_bike->setIcon(0, KIcon(QString("today")));
year_bike->setFlags(Qt::ItemIsEnabled | Qt::ItemIsSelectable);
}
else
year_bike = yb;
el = new QTreeWidgetItem(year_bike, year_bike, QTreeWidgetItem::Type);
el->setText(0, idx);
el->setData(0, Qt::UserRole, files.at(i));
el->setStatusTip(0, stTip);
el->setToolTip(0, stTip);
el->setIcon(0, KIcon(QString("bike")));
el->setFlags(Qt::ItemIsEnabled | Qt::ItemIsSelectable);
break;
case D1000_other:
default:
yo = findElement(ui_sportwatcherWidgetBase.liActivities, QString("other_%1").arg(qt->date().year()));
if(!yo && qt->date().year() != y_other)
{
year_other = new QTreeWidgetItem(other, other, QTreeWidgetItem::Type);
y_other = qt->date().year();
year_other->setText(0, QString("%1").arg(y_other));
year_other->setData(0, Qt::UserRole, QString("other_%1").arg(y_other));
year_other->setIcon(0, KIcon(QString("today")));
year_other->setFlags(Qt::ItemIsEnabled | Qt::ItemIsSelectable);
}
else
year_other = yo;
el = new QTreeWidgetItem(year_other, year_other, QTreeWidgetItem::Type);
el->setText(0, idx);
el->setData(0, Qt::UserRole, files.at(i));
el->setStatusTip(0, stTip);
el->setToolTip(0, stTip);
el->setIcon(0, KIcon(QString("other")));
el->setFlags(Qt::ItemIsEnabled | Qt::ItemIsSelectable);
}
delete qt;
}
ui_sportwatcherWidgetBase.liActivities->setItemExpanded(running, true);
if(year_run)
ui_sportwatcherWidgetBase.liActivities->setItemExpanded(year_run, true);
if(gmn)
garmin_free_data(gmn);
gmn = 0;
}
/*$SPECIALIZATION$*/
void sportwatcherWidget::btFullscreenSlot()
{
oldTransX = oldTransY = 0.0;
mapPan.setCoords(0, 0, 0, 0);
DIRTY = true;
showTrack(0);
DIRTY = false;
}
void sportwatcherWidget::btGlasMinusSlot()
{
bool sh = stateHand;
stateHand = false;
DIRTY = true;
showTrack(zfactor - 1000);
DIRTY = false;
stateHand = sh;
}
void sportwatcherWidget::btGlasPlusSlot()
{
bool sh = stateHand;
stateHand = false;
DIRTY = true;
showTrack(zfactor + 1000);
DIRTY = false;
stateHand = sh;
}
void sportwatcherWidget::btHandSlot()
{
QCursor cs;
if(stateGlas)
{
stateGlas = false;
ui_sportwatcherWidgetBase.btGlas->toggle();
}
stateHand = (stateHand) ? false : true;
if(stateHand)
cs.setShape(Qt::PointingHandCursor);
else
cs.setShape(Qt::ArrowCursor);
ui_sportwatcherWidgetBase.imgMap->setCursor(cs);
}
void sportwatcherWidget::btGlasSlot()
{
QCursor cs;
if(stateHand)
{
stateHand = false;
ui_sportwatcherWidgetBase.btHand->toggle();
}
stateGlas = (stateGlas) ? false : true;
if(stateGlas)
cs.setShape(Qt::ForbiddenCursor);
else
cs.setShape(Qt::ArrowCursor);
ui_sportwatcherWidgetBase.imgMap->setCursor(cs);
}
void sportwatcherWidget::btFlagSlot()
{
}
void sportwatcherWidget::liLapsSlot(Q3ListViewItem *item)
{
QString sl;
int l;
int idx;
RUN_NODE *rn;
LAP *lap;
if(!item)
return;
DIRTY = true;
sl = item->text(0).mid(4, 3);
l = sl.toInt();
if(l <= 0)
{
// Show the whole map and track
showTrack(zfactor, mapPan, 0);
// Don't mark any lap. Just display normal.
showCurves(0);
return;
}
rn = ds.getRunNode();
idx = rn->run->first_lap_index;
lap = ds.getLap(idx + l - 1);
// Show the part of the track, corresponding to the selected lap
showTrack(zfactor, mapPan, lap);
// Mark the selected lap
showCurves(lap);
DIRTY = false;
}
void sportwatcherWidget::liActivitiesSlot(QTreeWidgetItem *item, int)
{
if(!item)
return;
spw.destroy();
if(spw.setFileName(item->data(0, Qt::UserRole).toString().toAscii().constData()) == -1)
return;
if(gmn)
garmin_free_data(gmn);
gmn = spw.readFile();
zfactor = 0;
// Make sure, the currently not visible tabs will be redrawn as soon
// as they are visible.
switch(curTab)
{
case 0: tabDirt1 = tabDirt2 = tabDirt3 = true; break;
case 1: tabDirt0 = tabDirt2 = tabDirt3 = true; break;
case 2: tabDirt0 = tabDirt1 = tabDirt3 = true; break;
case 3: tabDirt0 = tabDirt1 = tabDirt2 = true; break;
}
// Display the just loaded sport session
DIRTY = true;
showLaps();
showTrack();
showCurves();
if(curTab == 2)
{
showThreeCurve();
tabDirt2 = false;
}
DIRTY = false;
}
/*
* The following function is called, when the user clicks the print button.
* It then prints the currently loaded activity. First the laps and on a
* seperate page the map, heart rate, elevation and speed.
*
* The function uses the already existing function showTrack() to draw an
* optional map and the track on it. It uses the function showThreeCurve()
* to draw the heart rate, elevation and speed. Only the laps are drawn
* directly in this function.
*/
void sportwatcherWidget::filePrint()
{
QPrinter printer(QPrinter::HighResolution);
QDateTime dt;
QTime t, st;
QDateTime *qt;
QRectF rect;
QString qs_name, qs_distance, qs_etime, qs_avgpace, qs_avgspeed, qs_maxspeed;
QString qs_calories, qs_avghr, qs_maxhr, qs_avgcadence, qs_ascent, qs_descent;
QString qs_totdist, hv0;
LAP *lap;
POINT *point;
RUN_NODE *rakt, *rn;
int laps, i, anz, cad, page, firstPage, lastPage;
qreal extMil[4];
double sum_dsc, old_asc, old_dsc;
double totdist, lineH, aktLine;
bool printed = false;
if(!gmn)
{
KMessageBox::error(this, i18n("You must select an activity first!"));
return;
}
printer.setCreator(QString("SportWatcher"));
printer.setDocName(QString("SportWatcher_%1").arg(QString(VERSION)));
QPrintDialog printDialog(&printer, this);
if(!printDialog.exec() == QDialog::Accepted)
return;
if(!(rn = ds.getRunNode()))
return;
// We dont care about page margins of a printer. Instead we assume
// a frame from about 20mm arround the page. European paper size is
// A4 (210x297mm) and the output is optimized for this.
totdist = 0;
extMil[0] = 20.0;
extMil[1] = 20.0;
extMil[2] = 210.0 - 20.0;
extMil[3] = 279.0 - 20.0;
lineH = 4.5; // The height of a line with 10pt letters
page = 1; // The page number
firstPage = printer.fromPage();
lastPage = printer.toPage();
if(!printArea.begin(&printer))
{
KMessageBox::error(this, i18n("Error initializing printer! Printing is currently not available!"));
return;
}
ActivePrint = true;
rakt = rn;
QApplication::setOverrideCursor(QCursor(Qt::WaitCursor));
while(rakt)
{
// Check for a supported run type
if(rakt->run->type == data_D1000 || rakt->run->type == data_D1009 ||
rakt->run->type == data_D1010)
{
int ahr;
double distance, speed, mspeed;
QDate dat;
printArea.setFont(QFont(QString("Helvetica"), 12, QFont::Bold, false));
rect.setCoords(milToPixel(extMil[0], printer),
milToPixel(extMil[1], printer, true),
milToPixel(extMil[0] + 170, printer),
milToPixel(extMil[1] + 7.0, printer, true));
printArea.setPen(QPen(QBrush(QColor("black")), (qreal)milToPixel(0.5, printer, false)));
if((lastPage > 0 && page >= firstPage && page <= lastPage) ||
(lastPage == 0 && firstPage == 0))
{
printArea.drawRect(rect);
printed = true;
}
if(!(lap = ds.getLap(rakt->run->first_lap_index)))
{
ActivePrint = false;
QApplication::restoreOverrideCursor();
return;
}
if(strlen(rn->run->workout.name) > 1 && strlen(rn->run->workout.name) < 16 && isalpha(rn->run->workout.name[0]))
hv0 = QString(rakt->run->workout.name);
else
{
qt = garmin_dtime(lap->start_time);
hv0 = kl->formatDate(qt->date(), KLocale::ShortDate) + " ";
hv0.append(qt->toString("hh:mm:ss"));
delete qt;
}
// Set the name depending on the sport type
// This is used on the tab "Summary"
switch(rakt->run->sport_type)
{
case D1000_running: qs_name = i18n("Running: "); break;
case D1000_biking: qs_name = i18n("Biking: "); break;
case D1000_other: qs_name = i18n("Other: "); break;
default:
qs_name = i18n("Unknown: ");
}
// Print the headline inside the frame
if((lastPage > 0 && page >= firstPage && page <= lastPage) ||
(lastPage == 0 && firstPage == 0))
{
printArea.drawText(rect, Qt::AlignHCenter, QString("%1%2").arg(qs_name).arg(hv0));
// Print the headline of the table
printArea.setFont(QFont(QString("Helvetica"), 10, QFont::Bold, false));
rect.setCoords(milToPixel(extMil[0], printer), milToPixel(extMil[1] + 10, printer, true), milToPixel(extMil[0] + 35, printer), milToPixel(extMil[0] + 10 + lineH, printer, true));
printArea.drawText(rect, Qt::AlignHCenter, i18n("Lap"));
rect.setCoords(milToPixel(extMil[0] + 35, printer), milToPixel(extMil[1] + 10, printer, true), milToPixel(extMil[0] + 60, printer), milToPixel(extMil[0] + 10 + lineH, printer, true));
printArea.drawText(rect, Qt::AlignHCenter, i18n("Distance"));
rect.setCoords(milToPixel(extMil[0] + 60, printer), milToPixel(extMil[1] + 10, printer, true), milToPixel(extMil[0] + 85, printer), milToPixel(extMil[0] + 10 + lineH, printer, true));
printArea.drawText(rect, Qt::AlignHCenter, i18n("Time"));
rect.setCoords(milToPixel(extMil[0] + 85, printer), milToPixel(extMil[1] + 10, printer, true), milToPixel(extMil[0] + 122, printer), milToPixel(extMil[0] + 10 + lineH, printer, true));
printArea.drawText(rect, Qt::AlignHCenter, i18n("Speed"));
rect.setCoords(milToPixel(extMil[0] + 122, printer), milToPixel(extMil[1] + 10, printer, true), milToPixel(extMil[0] + 147, printer), milToPixel(extMil[0] + 10 + lineH, printer, true));
printArea.drawText(rect, Qt::AlignHCenter, i18n("Heart rate"));
rect.setCoords(milToPixel(extMil[0] + 147, printer), milToPixel(extMil[1] + 10, printer, true), milToPixel(extMil[0] + 170, printer), milToPixel(extMil[0] + 10 + lineH, printer, true));
printArea.drawText(rect, Qt::AlignHCenter, i18n("Cadence"));
aktLine = extMil[1] + 10.0 + lineH;
printArea.drawLine(milToPixel(extMil[0], printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 170, printer), milToPixel(aktLine, printer, true));
aktLine += 1.0;
printed = true;
}
else
{
aktLine = extMil[1] + 10.0 + lineH;
aktLine += 1.0;
}
// Prepare to print the first line
qt = garmin_dtime(lap->start_time);
StartTime = *qt;
st = qt->time();
dat = qt->date();
delete qt;
qt = 0;
// Find the last track
if(!(point = ds.getLastPoint()))
{
QApplication::restoreOverrideCursor();
KMessageBox::error(this, i18n("Error getting the last messure point!"));
ActivePrint = false;
return;
}
qt = garmin_dtime(point->time);
t = qt->time();
t.setHMS(0, 0, 0);
t = t.addSecs(ds.getTotalTime());
qt->setDate(dat);
qt->setTime(t);
qs_name = kl->formatDate(dat, KLocale::ShortDate);
qs_name.append(" ");
qs_name.append(kl->formatTime(st, true));
max_time = ds.getTotalTime();
qs_etime = QString(qt->toString("hh:mm:ss.zzz"));
distance = 0.0;
mspeed = 0;
ahr = 0;
anz = 0;
cad = 0;
sum_dsc = old_asc = old_dsc = 0;
// Find out the total distance, calories, maximum speed,
// maximum heart rate and the average heart rate. Get this
// values from the lap summary the watch made.
for(i = rakt->run->first_lap_index; (unsigned int)i <= rakt->run->last_lap_index; i++)
{
if((lap = ds.getLap(i)) == NULL)
continue;
distance += lap->total_distance;
if(lap->avg_cadence != 0xff)
cad += lap->avg_cadence;
ahr += lap->avg_heart_rate;
anz++;
if(lap->max_speed > mspeed)
mspeed = lap->max_speed;
}
total_distance = distance = ds.getTotalDistance();
if(Units == 1) // Statute?
qs_distance.sprintf("%.2f ft", distance / 0.304);
else
qs_distance.sprintf("%.2f m", distance);
if(distance > 0)
{
QTime tt = qt->time();
long secs = (double)(tt.hour() * 3600 + tt.minute() * 60 + tt.second()) / 100.0;
if(Units == 0)
secs = secs * (1000.0 / distance * 100.0);
else
secs = secs * (1609.344 / distance * 100.0);
int h = secs / 3600;
int m = (secs - (h * 3600)) / 60;
int s = secs - ((h * 3600) + (m * 60));
t = QTime(h, m, s, 0);
qs_avgpace = QString(" ") + kl->formatTime(t, true);
if(Units == 0)
qs_avgpace.append(QString(" /km"));
else
qs_avgpace.append(QString(" /mi"));
}
if(Units == 1) // Statute?
speed = distance / ds.getTotalTime() * 3.6 / 1.609344;
else
speed = distance / ds.getTotalTime() * 3.6;
qs_avgspeed.sprintf("%.2f %s", speed, (Units == 1) ? "mph" : "km/h");
qs_maxspeed.sprintf("%.2f %s", (Units == 1) ? mspeed * 3.6 / 1.609344 : mspeed * 3.6, (Units == 1) ? "mph" : "km/h");
qs_avghr.sprintf("%d bpm", ahr / anz);
if(cad > 0)
qs_avgcadence.sprintf("%d", cad / anz);
// Print out the summary line and draw twi thin lines underneath
if((lastPage > 0 && page >= firstPage && page <= lastPage) ||
(lastPage == 0 && firstPage == 0))
{
printArea.setFont(QFont(QString("Helvetica"), 10, QFont::Normal, false));
rect.setCoords(milToPixel(extMil[0], printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 35, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignLeft, qs_name);
rect.setCoords(milToPixel(extMil[0] + 35, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 60, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignRight, kl->formatNumber(qs_distance, false));
rect.setCoords(milToPixel(extMil[0] + 60, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 85, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignRight, qs_etime);
rect.setCoords(milToPixel(extMil[0] + 85, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 122, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignRight, kl->formatNumber(qs_avgspeed, false));
rect.setCoords(milToPixel(extMil[0] + 122, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 147, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignRight, qs_avghr);
rect.setCoords(milToPixel(extMil[0] + 147, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 170, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignRight, qs_avgcadence);
aktLine += (lineH + (lineH / 3.0));
printArea.setPen(QPen(QBrush(QColor("black")), milToPixel(0.1, printer, false)));
printArea.drawLine(milToPixel(extMil[0], printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 170, printer), milToPixel(aktLine, printer, true));
printArea.drawLine(milToPixel(extMil[0], printer), milToPixel(aktLine + 0.5, printer, true), milToPixel(extMil[0] + 170, printer), milToPixel(aktLine + 0.5, printer, true));
aktLine += (lineH / 3.0);
printed = true;
}
else
{
aktLine += (lineH + (lineH / 3.0));
aktLine += (lineH / 3.0);
}
delete qt;
/* Get the laps. */
laps = 1;
for(i = rakt->run->first_lap_index; (unsigned int)i <= rakt->run->last_lap_index; i++)
{
double spd;
char *un;
if((lap = ds.getLap(i)) == NULL)
continue;
qt = garmin_dtime(lap->start_time);
qs_name.sprintf("Lap %03d - ", laps);
qs_name.append(kl->formatTime(qt->time(), true));
qs_distance.sprintf("%.2f %s", (Units == 1) ? lap->total_distance / 0.304 : lap->total_distance, (Units == 1) ? "ft" : "m");
totdist += (Units == 1) ? lap->total_distance / 0.304 : lap->total_distance;
qs_totdist.sprintf("%2.f %s", totdist, (Units == 1) ? "ft" : "m");
t = QTime(0, 0, 0, 0);
t = t.addMSecs(lap->total_time * 10);
qs_etime = t.toString("hh:mm:ss.zzz");
spd = lap->total_distance / (lap->total_time / 100.0);
delete qt;
qt = 0;
if(Units == 0)
{
un = (char *)"km/h";
spd *= 3.6;
}
else
{
spd *= 3.6 / 1.609344;
un = (char *)"mph";
}
qs_avgspeed.sprintf("%.2f %s", spd, un);
if(lap->total_distance > 0 && lap->total_time != 0)
{
double fact;
if(Units == 0)
fact = 1000.0; // 1 km
else
fact = 1609.344; // 1 mile in meters
long secs = (double)lap->total_time / 10000.0 * (fact / lap->total_distance * 100.0);
int h = secs / 3600;
int m = (secs - (h * 3600)) / 60;
int s = secs - ((h * 3600) + (m * 60));
t = QTime(h, m, s, 0);
qs_avgpace = kl->formatTime(t, true);
if(Units == 0)
qs_avgpace.append(QString(" /km"));
else
qs_avgpace.append(QString(" /mi"));
}
qs_avghr.sprintf("%d bpm", lap->avg_heart_rate);
if(lap->avg_cadence != 0xff)
qs_avgcadence.sprintf("%d", lap->avg_cadence);
// Draw a new detail line
if((lastPage > 0 && page >= firstPage && page <= lastPage) ||
(lastPage == 0 && firstPage == 0))
{
rect.setCoords(milToPixel(extMil[0], printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 35, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignLeft, qs_name);
rect.setCoords(milToPixel(extMil[0] + 35, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 60, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignRight, kl->formatNumber(qs_distance, false));
rect.setCoords(milToPixel(extMil[0] + 60, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 85, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignRight, qs_etime);
rect.setCoords(milToPixel(extMil[0] + 85, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 122, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignRight, kl->formatNumber(qs_avgspeed, false));
rect.setCoords(milToPixel(extMil[0] + 122, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 147, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignRight, qs_avghr);
rect.setCoords(milToPixel(extMil[0] + 147, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 170, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignRight, qs_avgcadence);
printed = true;
}
aktLine += lineH;
if(aktLine >= extMil[3]) // Print on the next page
{
aktLine = extMil[3] + 10.0;
if((lastPage > 0 && page >= firstPage && page <= lastPage) ||
(lastPage == 0 && firstPage == 0))
{
printArea.setFont(QFont(QString("Helvetica"), 8, QFont::Normal, false));
rect.setCoords(milToPixel(extMil[0], printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 170, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignRight, i18n("Page %1").arg(page));
aktLine = extMil[1];
printed = true;
}
else
aktLine = extMil[1];
if(printed)
printer.newPage();
page++;
// Print the headline of the table
if((lastPage > 0 && page >= firstPage && page <= lastPage) ||
(lastPage == 0 && firstPage == 0))
{
printArea.setFont(QFont(QString("Helvetica"), 10, QFont::Bold, false));
rect.setCoords(milToPixel(extMil[0], printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 35, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignHCenter, i18n("Lap"));
rect.setCoords(milToPixel(extMil[0] + 35, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 60, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignHCenter, i18n("Distance"));
rect.setCoords(milToPixel(extMil[0] + 60, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 85, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignHCenter, i18n("Time"));
rect.setCoords(milToPixel(extMil[0] + 85, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 122, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignHCenter, i18n("Speed"));
rect.setCoords(milToPixel(extMil[0] + 122, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 147, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignHCenter, i18n("Heart rate"));
rect.setCoords(milToPixel(extMil[0] + 147, printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 170, printer), milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignHCenter, i18n("Cadence"));
aktLine += lineH;
printArea.setPen(QPen(QBrush(QColor("black")), milToPixel(0.5, printer, false)));
printArea.drawLine(milToPixel(extMil[0], printer), milToPixel(aktLine, printer, true), milToPixel(extMil[0] + 170, printer), milToPixel(aktLine, printer, true));
aktLine += 1.0;
printed = true;
}
else
{
aktLine += lineH;
aktLine += 1.0;
}
printArea.setFont(QFont(QString("Helvetica"), 10, QFont::Normal, false));
}
delete qt;
laps++;
}
aktLine = extMil[3] + 10.0;
if((lastPage > 0 && page >= firstPage && page <= lastPage) ||
(lastPage == 0 && firstPage == 0))
{
printArea.setFont(QFont(QString("Helvetica"), 8, QFont::Normal, false));
rect.setCoords(milToPixel(extMil[0], printer),
milToPixel(aktLine, printer, true),
milToPixel(extMil[0] + 170, printer),
milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignRight, i18n("Page %1").arg(page));
printed = true;
}
aktLine = extMil[1];
page++;
if(printed && (page <= lastPage || lastPage == 0))
printer.newPage();
if((lastPage > 0 && (page < firstPage || page > lastPage)))
break;
// Draw the map on top of a new page
// Use 1/3 of the available height for the map
qreal resFact = 8; // The factor to calculate the resolution for pixmaps
int width = (int)(milToPixel(170, printer) / resFact);
int height = (int)(milToPixel(extMil[3] - extMil[1], printer, true) / resFact);
pmPrMap = QPixmap(width, height / 3); // 1/3 of page height
DIRTY = true;
int ct = curTab;
curTab = 1;
QApplication::restoreOverrideCursor();
showTrack();
QApplication::setOverrideCursor(QCursor(Qt::WaitCursor));
DIRTY = false;
curTab = ct;
printArea.drawPixmap(milToPixel(extMil[0], printer),
milToPixel(extMil[1], printer),
pmPrMap.scaled((int)milToPixel(170, printer),
(int)milToPixel(extMil[3] - extMil[1], printer, true) / 3,
Qt::IgnoreAspectRatio, Qt::SmoothTransformation));
// Put a frame around the map
rect.setCoords(milToPixel(extMil[0], printer), milToPixel(extMil[1], printer, true),
milToPixel(extMil[0] + 170, printer),
milToPixel(extMil[1], printer, true) + (milToPixel(extMil[3] - extMil[1], printer, true) / 3));
printArea.setPen(QPen(QBrush(QColor("black")), milToPixel(0.2, printer)));
printArea.drawRect(rect);
aktLine = (extMil[3] - extMil[1]) / 3.0 + extMil[1] + lineH;
// Draw the heart rate diagram
rect.setCoords(milToPixel(extMil[0], printer),
milToPixel(aktLine, printer, true),
milToPixel(extMil[2], printer),
milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignLeft, i18n("Heart rate:"));
aktLine += lineH;
qreal pixHeight = (extMil[3] - aktLine) / 3.0 - lineH * 2.0;
int realH = (int)milToPixel(pixHeight, printer, true);
height = realH / (int)resFact;
showThreeCurve(width, height); // Calculate the curves
printArea.drawPixmap(milToPixel(extMil[0], printer),
milToPixel(aktLine, printer, true),
prHR.scaled((int)milToPixel(170, printer),
realH, Qt::IgnoreAspectRatio, Qt::SmoothTransformation));
rect.setCoords(milToPixel(extMil[0], printer), milToPixel(aktLine, printer, true),
milToPixel(extMil[0] + 170, printer),
milToPixel(aktLine + pixHeight, printer, true));
printArea.drawRect(rect);
aktLine += pixHeight + lineH;
// Draw the elevation diagram
rect.setCoords(milToPixel(extMil[0], printer),
milToPixel(aktLine, printer, true),
milToPixel(extMil[2], printer),
milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignLeft, i18n("Elevation:"));
aktLine += lineH;
printArea.drawPixmap(milToPixel(extMil[0], printer),
milToPixel(aktLine, printer, true),
prElevation.scaled((int)milToPixel(170, printer),
realH, Qt::IgnoreAspectRatio, Qt::SmoothTransformation));
rect.setCoords(milToPixel(extMil[0], printer), milToPixel(aktLine, printer, true),
milToPixel(extMil[0] + 170, printer),
milToPixel(aktLine + pixHeight, printer, true));
printArea.drawRect(rect);
aktLine += pixHeight + lineH;
// Draw the speed diagram
rect.setCoords(milToPixel(extMil[0], printer),
milToPixel(aktLine, printer, true),
milToPixel(extMil[2], printer),
milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignLeft, i18n("Speed:"));
aktLine += lineH;
printArea.drawPixmap(milToPixel(extMil[0], printer),
milToPixel(aktLine, printer, true),
prSpeed.scaled((int)milToPixel(170, printer),
realH, Qt::IgnoreAspectRatio, Qt::SmoothTransformation));
rect.setCoords(milToPixel(extMil[0], printer), milToPixel(aktLine, printer, true),
milToPixel(extMil[0] + 170, printer),
milToPixel(aktLine + pixHeight, printer, true));
printArea.drawRect(rect);
// Print the page number at the right bottom of the page
aktLine = extMil[3] + 10.0;
printArea.setFont(QFont(QString("Helvetica"), 8, QFont::Normal, false));
rect.setCoords(milToPixel(extMil[0], printer),
milToPixel(aktLine, printer, true),
milToPixel(extMil[0] + 170, printer),
milToPixel(aktLine + lineH, printer, true));
printArea.drawText(rect, Qt::AlignRight, i18n("Page %1").arg(page));
}
rakt = rakt->next;
}
printArea.end();
// Mark printing as done
ActivePrint = false;
QApplication::restoreOverrideCursor();
}
qreal sportwatcherWidget::milToPixel(qreal dist, QPrinter &pr, bool dir)
{
QSizeF r = pr.paperSize(QPrinter::DevicePixel);
QSizeF m = pr.paperSize(QPrinter::Millimeter);
if(!dir) // width
return r.width() / m.width() * dist;
else
return r.height() / m.height() * dist;
}
/*
* This function allows the user to choose a file name, where we save the
* actual lap in Garmins own TCX format. This format is simply a XML-file.
* For details about the schema of this file look at
* http://developer.garmin.com/schemas/tcx/v2/
*/
void sportwatcherWidget::fileSaveAs()
{
QString fname;
QFile fn;
QString buffer;
RUN_NODE *rn, *rakt;
LAP *lap;
POINT *point;
int indent, i;
QDateTime *qt;
KUrl sDir("~/");
QRegExp rx("(\\.tcx|\\.gpx|\\.osm)$");
if(!gmn)
{
KMessageBox::error(this, i18n("Currently no activity is selected!"));
return;
}
rx.setPatternSyntax(QRegExp::RegExp);
fname = KFileDialog::getSaveFileName(sDir, QString("*.tcx|Garmin Training Center (*.tcx)\n*.gpx|GPS Excange Format (*.gpx)\n*.osm|OpenStreetMap (*.osm)"), this, QString("SportWatcher"));
if(fname.isEmpty())
return;
if(rx.indexIn(fname) < 0)
{
KMessageBox::error(this, i18n("The file %1 has no valid file extension!").arg(fname));
return;
}
fn.setFileName(fname);
if(fn.exists())
{
if(KMessageBox::questionYesNo(this, i18n("Do you really want to overwrite this file?")) == KMessageBox::No)
return;
}
rx.setPattern("*.gpx");
rx.setPatternSyntax(QRegExp::Wildcard);
if(rx.exactMatch(fname)) // Should we create a *.gpx file?
{
sportwatcherWidget::saveGPX(fname);
return;
}
rx.setPattern("*.osm");
rx.setPatternSyntax(QRegExp::Wildcard);
if(rx.exactMatch(fname)) // Should we create a *.osm file?
{
sportwatcherWidget::saveOSM(fname);
return;
}
// No, we create a *.tcx file!
indent = 0;
rn = ds.getRunNode();
lap = ds.getLap(rn->run->first_lap_index);
if((point = ds.getPoint(lap->start_time)) == 0)
{
KMessageBox::error(this, i18n("No data to save!"));
return;
}
if(!fn.open(QIODevice::ReadWrite | QIODevice::Truncate))
{
KMessageBox::error(this, i18n("Error creating file %1!\nPlease check permissions").arg(fname));
return;
}
buffer = QString("<?xml version=\"1.0\" encoding=\"UTF-8\" standalone=\"no\" ?>\n");
buffer.append("<TrainingCenterDatabase xmlns=\"http://www.garmin.com/xmlschemas/TrainingCenterDatabase/v2\" ");
buffer.append("xmlns:xsi=\"http://www.w3.org/2001/XMLSchema-instance\" ");
buffer.append("xsi:schemaLocation=\"http://www.garmin.com/xmlschemas/TrainingCenterDatabase/v2 ");
buffer.append("http://www.garmin.com/xmlschemas/TrainingCenterDatabasev2.xsd\">\n\n");
writeTag(fn, buffer, indent);
buffer = QString("<folders/>\n\n");
writeTag(fn, buffer, indent);
// Open a course
QFileInfo finfo(fname);
buffer = QString("<Courses>\n <Course>\n <name>%1</name>\n").arg(QFileInfo(finfo).baseName());
writeTag(fn, buffer, indent);
indent = 2;
rakt = rn;
while(rakt)
{
if(rakt->run->type != data_D1000 && rakt->run->type != data_D1009 &&
rakt->run->type != data_D1010)
{
rakt = rakt->next;
continue;
}
for(i = rakt->run->first_lap_index; (unsigned int)i <= rakt->run->last_lap_index; i++)
{
if((lap = ds.getLap(i)) == NULL)
continue;
// Write the information of the lap
writeTag(fn, QString("<Lap>\n"), indent);
indent++;
buffer.sprintf("<TotalTimeSeconds>%f</TotalTimeSeconds>\n", (double)lap->total_time / 100.0);
writeTag(fn, buffer, indent);
qt = garmin_dtime(lap->start_time);
buffer = QString("<StartTime>%1</StartTime>\n").arg(qt->toString("yyyy-MM-ddThh:mm:ssZ"));
writeTag(fn, buffer, indent);
buffer.sprintf("<DistanceMeters>%f</DistanceMeters>\n", lap->total_distance);
writeTag(fn, buffer, indent);
writeTag(fn, QString("<BeginPosition>\n"), indent);
indent++;
buffer.sprintf("<LatitudeDegrees>%f</LatitudeDegrees>\n", SEMI2DEG(lap->begin.lat));
writeTag(fn, buffer, indent);
buffer.sprintf("<LongitudeDegrees>%f</LongitudeDegrees>\n", SEMI2DEG(lap->begin.lon));
writeTag(fn, buffer, indent);
indent--;
writeTag(fn, QString("</BeginPosition>\n"), indent);
writeTag(fn, QString("<EndPosition>\n"), indent);
indent++;
buffer.sprintf("<LatitudeDegrees>%f</LatitudeDegrees>\n", SEMI2DEG(lap->end.lat));
writeTag(fn, buffer, indent);
buffer.sprintf("<LongitudeDegrees>%f</LongitudeDegrees>\n", SEMI2DEG(lap->end.lon));
writeTag(fn, buffer, indent);
indent--;
writeTag(fn, QString("</EndPosition>\n"), indent);
writeTag(fn, QString("<AverageHeartRateBpm xsi:type=\"HeartRateInBeatsPerMinute_t\">\n"), indent);
indent++;
buffer.sprintf("<Value>%d</Value>\n", lap->avg_heart_rate);
writeTag(fn, buffer, indent);
indent--;
writeTag(fn, QString("</AverageHeartRateBpm>\n"), indent);
writeTag(fn, QString("<MaximumHeartRateBpm xsi:type=\"HeartRateInBeatsPerMinute_t\">\n"), indent);
indent++;
buffer.sprintf("<Value>%d</Value>\n", lap->max_heart_rate);
writeTag(fn, buffer, indent);
indent--;
writeTag(fn, QString("</MaximumHeartRateBpm>\n"), indent);
if(lap->avg_cadence < 255)
{
buffer.sprintf("<AverageCadence>%d</AverageCadence>\n", lap->avg_cadence);
writeTag(fn, buffer, indent);
buffer.sprintf("<Cadence>%d</Cadence>\n", lap->avg_cadence);
writeTag(fn, buffer, indent);
}
buffer = QString("<Intensity>%1</Intensity>\n").arg((!lap->intensity) ? "Active" : "Resting");
writeTag(fn, buffer, indent);
buffer.sprintf("<Calories>%d</Calories>\n", lap->calories);
writeTag(fn, buffer, indent);
buffer.sprintf("<MaximumSpeed>%f</MaximumSpeed>\n", lap->max_speed);
writeTag(fn, buffer, indent);
indent--;
writeTag(fn, QString("</Lap>\n"), indent);
point = ds.getPoint(lap->start_time);
writeTag(fn, QString("<Track>\n"), indent);
indent++;
while(point)
{
if(point->time > (lap->start_time + (lap->total_time / 100)))
break;
writeTag(fn, QString("<Trackpoint>\n"), indent);
indent++;
qt = garmin_dtime(point->time);
buffer = QString("<Time>%1</Time>\n").arg(qt->toString("yyyy-MM-ddThh:mm:ssZ"));
writeTag(fn, buffer, indent);
delete qt;
writeTag(fn, QString("<Position>\n"), indent);
indent++;
buffer.sprintf("<LatitudeDegrees>%f</LatitudeDegrees>\n", SEMI2DEG(point->posn.lat));
writeTag(fn, buffer, indent);
buffer.sprintf("<LongitudeDegrees>%f</LongitudeDegrees>\n", SEMI2DEG(point->posn.lon));
writeTag(fn, buffer, indent);
indent--;
writeTag(fn, QString("</Position>\n"), indent);
if(point->alt < 20000.0)
{
buffer.sprintf("<AltitudeMeters>%f</AltitudeMeters>\n", point->alt);
writeTag(fn, buffer, indent);
}
buffer.sprintf("<DistanceMeters>%f</DistanceMeters>\n", point->distance);
writeTag(fn, buffer, indent);
if(point->heart_rate > 0 && point->heart_rate < 250)
{
writeTag(fn, QString("<HeartRateBpm xsi:type=\"HeartRateInBeatsPerMinute_t\">\n"), indent);
indent++;
buffer.sprintf("<Value>%d</Value>\n", point->heart_rate);
writeTag(fn, buffer, indent);
indent--;
writeTag(fn, QString("</HeartRateBpm>\n"), indent);
}
if(point->cadence < 0xff)
{
buffer.sprintf("<Cadence>%d</Cadence>\n", point->cadence);
writeTag(fn, buffer, indent);
}
buffer.sprintf("<SensorState>%s</SensorState>\n", (!point->sensor) ? "Absent" : "Present");
writeTag(fn, buffer, indent);
indent--;
writeTag(fn, QString("</Trackpoint>\n"), indent);
point = ds.getPoint(point->time + 1);
}
indent--;
writeTag(fn, QString("</Track>\n"), indent);
}
indent--;
writeTag(fn, QString("</Course>\n"), indent);
indent--;
writeTag(fn, QString("</Courses>\n"), indent);
rakt = rakt->next;
}
// Write information about device
// Here my personal signature is written :-)
writeTag(fn, QString("<Author xsi:type=\"Application_t\">\n"), indent);
indent++;
writeTag(fn, QString("<Name>SportWatcher</Name>\n"), indent);
writeTag(fn, QString("<Build>\n"), indent);
indent++;
writeTag(fn, QString("<Version>\n"), indent);
indent++;
writeTag(fn, QString("<VersionMajor>0</VersionMajor>\n"), indent);
writeTag(fn, QString("<VersionMinor>1</VersionMinor>\n"), indent);
writeTag(fn, QString("<BuildMajor>0</BuildMajor>\n"), indent);
writeTag(fn, QString("<BuildMinor>0</BuildMinor>\n"), indent);
indent--;
writeTag(fn, QString("</Version>\n"), indent);
writeTag(fn, QString("<Type>Beta</Type>\n"), indent);
writeTag(fn, QString("<Time>Jan 31 2008, 00:00:00</Time>\n"), indent);
writeTag(fn, QString("<Builder>theosys</Builder>\n"), indent);
indent--;
writeTag(fn, QString("</Build>\n"), indent);
writeTag(fn, QString("<LangID>EN</LangID>\n"), indent);
writeTag(fn, QString("<PartNumber>000-00000-00</PartNumber>\n"), indent);
indent--;
writeTag(fn, QString("</Author>\n"), indent);
writeTag(fn, QString("</TrainingCenterDatabase>\n"), indent);
fn.close();
KMessageBox::information(this, i18n("File ") + fname + i18n(" was written successfully."));
}
void sportwatcherWidget::fileSave()
{
KMessageBox::information(this, i18n("This function is currently not implemented!"));
}
void sportwatcherWidget::saveGPX(const QString &fn)
{
QFile qf;
QString buffer;
RUN_NODE *rn, *rakt;
LAP *lap;
POINT *point;
int indent;
unsigned int i;
QDateTime *qt;
double minLat, minLon, maxLat, maxLon;
indent = 0;
rn = ds.getRunNode();
lap = ds.getLap(rn->run->first_lap_index);
if((point = ds.getPoint(lap->start_time)) == 0)
{
KMessageBox::error(this, i18n("No data to save!"));
return;
}
qf.setFileName(fn);
if(!qf.open(QIODevice::ReadWrite | QIODevice::Truncate))
{
KMessageBox::error(this, i18n("Error creating file %1!\nPlease check permissions").arg(fn));
return;
}
buffer = QString("<?xml version='1.0' encoding='UTF-8'?>\n");
buffer.append("<gpx version=\"1.1\" creator=\"TheoSys SportWatcher\" xmlns=\"http://www.topografix.com/GPX/1/1\">\n");
buffer.append(" <metadata>\n");
indent = 0;
writeTag(qf, buffer, indent);
// Find the edges of our coordinates
// We need this information in the header (metadata)
rakt = rn;
minLat = -90.0;
minLon = -180.0;
maxLat = 90.0;
maxLon = 180.0;
while(rakt)
{
if(rakt->run->type != data_D1000 && rakt->run->type != data_D1009 &&
rakt->run->type != data_D1010)
{
rakt = rakt->next;
continue;
}
i = rakt->run->first_lap_index;
// get the first lap
if((lap = ds.getLap(i)) == NULL)
continue;
i = 0;
// iterate the points associated with the laps
while((point = ds.getPoint(i)) != 0)
{
if(point->posn.lat == 0x7fffffff || point->posn.lon == 0x7fffffff)
{
i = point->time + 1;
continue;
}
if(SEMI2DEG(point->posn.lat) > minLat)
minLat = SEMI2DEG(point->posn.lat);
if(SEMI2DEG(point->posn.lat) < maxLat)
maxLat = SEMI2DEG(point->posn.lat);
if(SEMI2DEG(point->posn.lon) > minLon)
minLon = SEMI2DEG(point->posn.lon);
if(SEMI2DEG(point->posn.lon) < maxLon)
maxLon = SEMI2DEG(point->posn.lon);
i = point->time + 1;
}
rakt = rakt->next;
}
buffer.sprintf(" <bounds minlat=\"%f\" minlon=\"%f\" maxlat=\"%f\" maxlon=\"%f\" />\n",
maxLat, minLon, minLat, maxLon);
buffer.append(" </metadata>\n");
buffer.append(" <trk>\n");
buffer.append(" <trkseg>\n");
writeTag(qf, buffer, indent);
indent = 3;
rn = ds.getRunNode();
lap = ds.getLap(rn->run->first_lap_index);
i = 0;
while((point = ds.getPoint(i)) != 0)
{
if(point->posn.lat == 0x7fffffff || point->posn.lon == 0x7fffffff)
{
i = point->time + 1;
continue;
}
buffer.sprintf("<trkpt lat=\"%f\" lon=\"%f\">\n",
SEMI2DEG(point->posn.lat), SEMI2DEG(point->posn.lon));
writeTag(qf, buffer, indent);
indent++;
buffer.sprintf("<ele>%f</ele>\n", point->alt);
writeTag(qf, buffer, indent);
qt = garmin_dtime(point->time);
buffer = QString("<Time>%1</Time>\n").arg(qt->toString("yyyy-MM-ddThh:mm:ssZ"));
writeTag(qf, buffer, indent);
indent--;
writeTag(qf, QString("</trkpt>\n"), indent);
i = point->time + 1;
}
indent = 0;
buffer = QString(" </trkseg>\n");
buffer.append(" </trk>\n");
buffer.append("</gpx>\n");
writeTag(qf, buffer, indent);
qf.close();
KMessageBox::information(this, i18n("File ") + fn + i18n(" was written successfully."));
}
void sportwatcherWidget::saveOSM(const QString &fn)
{
QFile qf;
QString buffer;
RUN_NODE *rn, *rakt;
LAP *lap;
POINT *point;
int indent, id, j;
unsigned int i;
double minLat, minLon, maxLat, maxLon;
QDateTime *qt;
indent = 0;
rn = ds.getRunNode();
lap = ds.getLap(rn->run->first_lap_index);
if((point = ds.getPoint(lap->start_time)) == 0)
{
KMessageBox::error(this, i18n("No data to save!"));
return;
}
qf.setFileName(fn);
if(!qf.open(QIODevice::ReadWrite | QIODevice::Truncate))
{
KMessageBox::error(this, i18n("Error creating file %1!\nPlease check permissions").arg(fn));
return;
}
buffer = QString("<?xml version='1.0' encoding='UTF-8'?>\n");
buffer.append("<osm version=\"0.5\" generator=\"TheoSys SportWatcher\">\n");
indent = 0;
writeTag(qf, buffer, indent);
// Find the edges of our coordinates
// We need this information in the header (metadata)
rakt = rn;
minLat = -90.0;
minLon = -180.0;
maxLat = 90.0;
maxLon = 180.0;
while(rakt)
{
if(rakt->run->type != data_D1000 && rakt->run->type != data_D1009 &&
rakt->run->type != data_D1010)
{
rakt = rakt->next;
continue;
}
i = rakt->run->first_lap_index;
// get the first lap
if((lap = ds.getLap(i)) == NULL)
continue;
i = 0;
// iterate the points associated with the laps
while((point = ds.getPoint(i)) != 0)
{
if(point->posn.lat == 0x7fffffff || point->posn.lon == 0x7fffffff)
{
i = point->time + 1;
continue;
}
if(SEMI2DEG(point->posn.lat) > minLat)
minLat = SEMI2DEG(point->posn.lat);
if(SEMI2DEG(point->posn.lat) < maxLat)
maxLat = SEMI2DEG(point->posn.lat);
if(SEMI2DEG(point->posn.lon) > minLon)
minLon = SEMI2DEG(point->posn.lon);
if(SEMI2DEG(point->posn.lon) < maxLon)
maxLon = SEMI2DEG(point->posn.lon);
i = point->time + 1;
}
rakt = rakt->next;
}
buffer.sprintf(" <bound box='%f,%f,%f,%f' origin='http://www.openstreetmap.org/api/0.5' />\n",
maxLat, minLon, minLat, maxLon);
writeTag(qf, buffer, indent);
indent = 1;
rn = ds.getRunNode();
lap = ds.getLap(rn->run->first_lap_index);
i = 0;
id = -1;
while((point = ds.getPoint(i)) != 0)
{
if(point->posn.lat == 0x7fffffff || point->posn.lon == 0x7fffffff)
{
i = point->time + 1;
continue;
}
buffer.sprintf("<node id='%d' action='modify' visible='true' lat=\"%f\" lon=\"%f\">\n",
id, SEMI2DEG(point->posn.lat), SEMI2DEG(point->posn.lon));
writeTag(qf, buffer, indent);
indent++;
buffer = QString("<tag k='created_by' v='TheoSys Sportwatcher' />\n");
writeTag(qf, buffer, indent);
buffer = QString("<tag k='highway' v='tertiary' />\n");
writeTag(qf, buffer, indent);
indent--;
writeTag(qf, QString("</node>\n"), indent);
id--;
i = point->time + 1;
}
qt = garmin_dtime(lap->start_time);
buffer.sprintf("<way id='%d' action='modify' visible='true' timestamp='%s'>\n",
id, QString(qt->toString("yyyy-MM-ddThh:mm:ssZ")).toAscii().data());
writeTag(qf, buffer, indent);
indent++;
for(j = -1; j > id; j--)
{
buffer.sprintf("<nd ref='%d' />\n", j);
writeTag(qf, buffer, indent);
}
indent--;
writeTag(qf, QString("</way>\n"), indent);
indent = 0;
writeTag(qf, QString("</osm>\n"), indent);
qf.close();
KMessageBox::information(this, i18n("File %1 was written successfully.").arg(fn));
}
void sportwatcherWidget::fileOpen()
{
QString fname = KFileDialog::getOpenFileName(Data, QString("*.gmn"), this, QString("SportWatcher"));
int m;
if(fname.isEmpty())
return;
spw.destroy();
if(spw.setFileName(fname.toAscii().data()) == -1)
return;
if(gmn)
garmin_free_data(gmn);
gmn = spw.readFile();
zfactor = 0;
if((m = garmin_count_error()) > 0)
{
int i, key = -1;
for(i = 0; i < m; i++)
KMessageBox::error(this, QString(garmin_get_next_error(&key)));
garmin_clear_errors();
return;
}
DIRTY = true;
tabDirt0 = tabDirt1 = tabDirt2 = tabDirt3 = true;
showLaps();
showTrack();
showCurves();
if(curTab == 2)
{
showThreeCurve();
tabDirt2 = false;
}
tabDirt0 = tabDirt3 = false;
DIRTY = false;
}
/**
* This function is called from the XML parser in "gmn_import"
* whenever an activity is complete.
* Necessary because there may be more than one activity in a history
* file.
*/
void sportwatcherWidget::saveImported(void *gd)
{
gmn_import import;
QString tgfile, fld, px;
RUN_NODE *rn;
LAP *lap;
garmin_data *g = (garmin_data *)gd;
QFileInfo datei;
QPixmap qpx;
QList<QTreeWidgetItem *>item;
QTreeWidgetItem *el, *it;
if(!g)
{
std::cerr << "sportwatcherWidget::saveImported: Empty data! Nothing was saved!" << std::endl;
return;
}
// Find the filename;
// It consists of the date and the time.
// We need this information to set the correct path to store the file.
tgfile = Data; // The base path
rn = ds.getRunNode();
lap = ds.getLap(rn->run->first_lap_index);
QDateTime *qt = garmin_dtime(lap->start_time);
tgfile.append(qt->toString("/yyyy")); // year is a folder
tgfile.append(qt->toString("/MM")); // month is a folder
tgfile.append(qt->toString("/yyyyMMddThhmmss")); // The file name
tgfile.append(".gmn"); // Extension of file name
datei.setFile(tgfile);
std:cerr << "sportwatcherWidget::saveImported:Saving to file " << datei.absoluteFilePath().toAscii().data() << std::endl;
// save the data to a real file, but only if it doesn't exist allready.
garmin_save_all(g, datei.fileName().toAscii().data(), datei.absolutePath().toAscii().data(), 0);
// in case the item is already in the list on the left side, we
// only highlight the item.
item = ui_sportwatcherWidgetBase.liActivities->findItems(tgfile, Qt::MatchExactly);
if(item.size() > 0)
{
ui_sportwatcherWidgetBase.liActivities->setItemSelected(item.at(0), true);
ui_sportwatcherWidgetBase.liActivities->setCurrentItem(item.at(0));
return;
}
// insert everything into the list on the left side
switch(rn->run->sport_type)
{
case D1000_running:
fld = i18n("Running");
px = QString("spw-running");
break;
case D1000_biking:
fld = i18n("Biking");
px = QString("bike");
break;
default:
fld = i18n("Others");
px = QString("other");
}
// Do we have allready so items in the list?
item = ui_sportwatcherWidgetBase.liActivities->findItems(fld, Qt::MatchExactly);
if(item.size() > 0)
{
el = new QTreeWidgetItem(item.at(0));
el->setText(0, kl->formatDateTime(*qt, KLocale::ShortDate, true));
el->setData(0, Qt::UserRole, tgfile);
el->setIcon(0, KIcon(px));
}
else // no, this is the first item. (shouldn't be!)
{
it = new QTreeWidgetItem(ui_sportwatcherWidgetBase.liActivities);
it->setText(0, fld);
it->setIcon(0, KIcon(QString("history")));
el = new QTreeWidgetItem(item.at(0));
el->setText(0, kl->formatDateTime(*qt, KLocale::ShortDate, true));
el->setData(0, Qt::UserRole, tgfile);
el->setIcon(0, KIcon(px));
}
}
void sportwatcherWidget::fileImport()
{
QString fname = KFileDialog::getOpenFileName(QString("~/"), QString("*.tcx"), this, QString("SportWatcher"));
gmn_import import;
int m;
QString tgfile, fld, px;
QPixmap qpx;
QFileInfo datei;
QList<QTreeWidgetItem *>item;
QTreeWidgetItem *el, *it;
LAP *lap;
RUN_NODE *rn;
if(fname.isEmpty())
return;
import.connectCallback(this);
import.setFile(fname);
if((m = import.import()) != 0)
{
KMessageBox::error(this, QString(import.getError(m)));
return;
}
if(gmn)
{
garmin_free_data(gmn);
gmn = 0;
}
if(!(gmn = import.getGarminData()))
return;
DIRTY = true;
tabDirt0 = tabDirt1 = tabDirt2 = tabDirt3 = true;
showLaps();
showTrack();
showCurves();
if(curTab == 2)
{
showThreeCurve();
tabDirt2 = false;
}
tabDirt0 = tabDirt3 = false;
DIRTY = false;
// Find the filename;
// It consists of the date and the time.
// We need this information to set the correct path to store the file.
tgfile = Data; // The base path
rn = ds.getRunNode();
lap = ds.getLap(rn->run->first_lap_index);
QDateTime *qt = garmin_dtime(lap->start_time);
tgfile.append(qt->toString("/yyyy")); // year is a folder
tgfile.append(qt->toString("/MM")); // month is a folder
tgfile.append(qt->toString("/yyyyMMddThhmmss")); // The file name
tgfile.append(".gmn"); // Extension of file name
datei.setFile(tgfile);
std:cerr << "sportwatcherWidget::fileImport:Saving to file " << datei.absoluteFilePath().toAscii().data() << std::endl;
// save the data to a real file, but only if it doesn't exist allready.
garmin_save_all(gmn, datei.fileName().toAscii().data(), datei.absolutePath().toAscii().data(), 0);
// in case the item is already in the list on the left side, we
// only highlight the item.
item = ui_sportwatcherWidgetBase.liActivities->findItems(tgfile, Qt::MatchExactly);
if(item.size() > 0)
{
ui_sportwatcherWidgetBase.liActivities->setItemSelected(item.at(0), true);
ui_sportwatcherWidgetBase.liActivities->setCurrentItem(item.at(0));
return;
}
// insert everything into the list on the left side
switch(rn->run->sport_type)
{
case D1000_running:
fld = i18n("Running");
px = QString("spw-running");
break;
case D1000_biking:
fld = i18n("Biking");
px = QString("bike");
break;
default:
fld = i18n("Others");
px = QString("other");
}
// Do we have allready so items in the list?
item = ui_sportwatcherWidgetBase.liActivities->findItems(fld, Qt::MatchExactly);
if(item.size() > 0)
{
el = new QTreeWidgetItem(item.at(0));
el->setText(0, kl->formatDateTime(*qt, KLocale::ShortDate, true));
el->setData(0, Qt::UserRole, tgfile);
el->setIcon(0, KIcon(px));
}
else // no, this is the first item. (shouldn't be!)
{
it = new QTreeWidgetItem(ui_sportwatcherWidgetBase.liActivities);
it->setText(0, fld);
it->setIcon(0, KIcon(QString("history")));
el = new QTreeWidgetItem(item.at(0));
el->setText(0, kl->formatDateTime(*qt, KLocale::ShortDate, true));
el->setData(0, Qt::UserRole, tgfile);
el->setIcon(0, KIcon(px));
}
}
/*
* Display a small dialog to rename the currently loaded session.
*/
void sportwatcherWidget::editRename()
{
bool ok;
QString name, inhalt;
QList<QTreeWidgetItem *> item;
QTreeWidgetItem *lvItem;
QFileInfo datei;
RUN_NODE *rn;
LAP *lap;
garmin_list *list;
D1009 *n;
if(!gmn)
{
KMessageBox::error(this, i18n("There is no session selected!"));
return;
}
rn = ds.getRunNode();
item = ui_sportwatcherWidgetBase.liActivities->selectedItems();
lvItem = item.first();
if(!isdigit(rn->run->workout.name[0]))
inhalt = lvItem->text(0);
else
inhalt.clear();
name = KInputDialog::getText(i18n("Rename session"), i18n("Session name"),
inhalt, &ok, this, (QValidator *)0, QString("Nxxxxxxxxxxxxxx"),
i18n("Enter a new name for the currently selected activity."));
if(!ok)
return;
if(name.length() <= 1)
{
lap = ds.getLap(rn->run->first_lap_index);
const QDateTime *qt = garmin_dtime(lap->start_time);
QString idx = kl->formatDateTime(*qt, KLocale::ShortDate, true);
lvItem->setText(0, idx);
datei.setFile(lvItem->data(0, Qt::UserRole).toString());
garmin_save_all(gmn, datei.fileName().toAscii().data(), datei.absolutePath().toAscii().data(), 1);
delete qt;
return;
}
strncpy(rn->run->workout.name, name.toAscii().data(), 16);
if(gmn->type != data_Dlist)
{
KMessageBox::error(this, i18n("editRename: Unexpected structure type %1 found!").arg(gmn->type));
return;
}
list = (garmin_list *)gmn->data;
if(list->head->data->type != data_D1009) // This should be the run node
{
KMessageBox::error(this, i18n("editRename: The run node was not found!"));
return;
}
n = (D1009 *)list->head->data->data;
strncpy(n->workout.name, rn->run->workout.name, 15);
lvItem->setText(0, name);
datei.setFile(lvItem->data(0, Qt::UserRole).toString());
garmin_save_all(gmn, datei.fileName().toAscii().data(), datei.absolutePath().toAscii().data(), 1);
}
void sportwatcherWidget::fileNew()
{
progressWidget *dlg = new progressWidget(this);
dlg->show();
if(!dlg->Download())
{
int m, key;
key = -1;
for(m = 0; m < garmin_count_error(); m++)
KMessageBox::error(this, QString(garmin_get_next_error(&key)));
}
else
getActivities();
garmin_clear_errors();
delete dlg;
}
/*
* This function is called, when the user clicks at the menu point
* "Save Heart Rate".
* First, a file dialog box is displayed, where the user can choose a
* directory and a file name to save the heart rate.
* If the file could successfully be created, the heart rate is saved
* in the "HRM"-format. This is the native format Polar uses to store
* heart rate data. I've choosen this format, because it's popular and
* used by many other software too.
*/
void sportwatcherWidget::extrasSaveHR()
{
QString fname, str1, str2;
QFile fdfile;
QDateTime *qt, *oldqt;
QDate dat;
QTime t;
QDir dir = QDir::home();
char hv0[256];
RUN_NODE *rn;
LAP *lap, *alap;
POINT *point;
int samples, smp, seconds, anz, nsec, samsec;
int avgHeart, minHeart, maxHeart, aktHeart;
int secRange1, secRange2, secRange3, secAbove, secBeyond;
if(!gmn)
{
KMessageBox::information(this, i18n("There is no activity open"));
return;
}
if(HRM.isEmpty())
str1 = dir.path();
else
str1 = HRM;
str1 += "/" + StartTime.toString("yyyyMMddThhmmss.zzz.hrm");
fname = KFileDialog::getSaveFileName(str1, QString("*.hrm"), this, QString("SportWatcher"));
if(fname.isEmpty())
return;
fdfile.setFileName(fname);
if(fdfile.exists())
{
if(KMessageBox::questionYesNo(this, i18n("Do you really want to overwrite this file?")) == KMessageBox::No)
return;
}
if(!fdfile.open(QIODevice::ReadWrite | QIODevice::Truncate))
{
KMessageBox::error(this, i18n("Error creating a file!\nPlease check permissions."));
return;
}
rn = ds.getRunNode();
lap = ds.getLap(rn->run->first_lap_index);
t = StartTime.time();
dat = StartTime.date();
if((point = ds.getPoint(lap->start_time)) == 0)
{
fdfile.close();
return;
}
strcpy(hv0, "[Params]\n");
write(fdfile.handle(), &hv0[0], strlen(hv0));
str1 = dat.toString("yyyyMMdd");
str2 = t.toString("hh:mm:ss.z");
sprintf(hv0, "Version=106\nMonitor=11\nSMode=000000000\nDate=%s\nStartTime=%s\n",
str1.toAscii().data(), str2.toAscii().data());
write(fdfile.handle(), &hv0[0], strlen(hv0));
t.setHMS(0, 0, 0);
t = t.addSecs(max_time);
str2 = t.toString("hh:mm:ss.z");
switch(sampleTime)
{
case 0: samsec = 5; break;
case 1: samsec = 15; break;
case 2: samsec = 30; break;
case 3: samsec = 60; break;
default:
samsec = 15;
}
sprintf(hv0, "Length=%s\nInterval=%d\nUpper1=%d\nLower1=%d\nUpper2=%d\n",
str2.toAscii().data(), samsec, upper1, lower1, upper2);
write(fdfile.handle(), &hv0[0], strlen(hv0));
sprintf(hv0, "Lower2=%d\nUpper3=%d\nLower3=%d\nTimer1=00:00:00.0\n",
lower2, upper3, lower3);
write(fdfile.handle(), &hv0[0], strlen(hv0));
strcpy(hv0, "Timer2=00:00:00.0\nTimer3=00:00:00.0\nActiveLimit=0\n");
write(fdfile.handle(), &hv0[0], strlen(hv0));
sprintf(hv0, "MaxHR=%d\nRestHR=%d\nStartDelay=0\nVO2max=%d\nWeight=%d\n\n",
MaxHr, restHr, vo2max, weight);
write(fdfile.handle(), &hv0[0], strlen(hv0));
// Write the intervall times. One block for every lap
secRange1 = secRange2 = secRange3 = secAbove = secBeyond = 0;
strcpy(hv0, "[IntTimes]\n");
write(fdfile.handle(), &hv0[0], strlen(hv0));
t.setHMS(0, 0, 0);
for(unsigned int i = rn->run->first_lap_index; i < rn->run->last_lap_index; i++)
{
alap = ds.getLap(i);
point = ds.getPoint(alap->start_time);
oldqt = garmin_dtime(point->time);
avgHeart = minHeart = maxHeart = aktHeart = 0;
anz = 0;
unsigned long lastTime = point->time;
int totSec = 0;
while(point)
{
if(point->time > (alap->start_time + (alap->total_time / 100)))
break;
if(point->heart_rate > 0)
{
avgHeart += point->heart_rate;
nsec = point->time - lastTime;
totSec += nsec;
if(minHeart == 0 || minHeart > point->heart_rate)
minHeart = point->heart_rate;
if(maxHeart < point->heart_rate)
maxHeart = point->heart_rate;
if(aktHeart == 0 && totSec >= samsec)
aktHeart = avgHeart / (anz + 1);
if(point->heart_rate < lower1)
secBeyond += nsec;
else if(point->heart_rate < lower2)
secRange1 += nsec;
else if(point->heart_rate < lower3)
secRange2 += nsec;
else if(point->heart_rate < upper3)
secRange3 += nsec;
else
secAbove += nsec;
lastTime = point->time;
anz++;
}
point = ds.getPoint(point->time + 1);
}
t = t.addSecs(alap->total_time / 100);
str1 = t.toString("hh:mm:ss.z");
if(anz > 0)
avgHeart = avgHeart / anz;
else
avgHeart = 0;
sprintf(hv0, "%s\t %d\t %d\t %d\t %d\n",
str1.toAscii().data(), aktHeart, minHeart, avgHeart, maxHeart);
write(fdfile.handle(), &hv0[0], strlen(hv0));
strcpy(hv0, "32\t 0\t 0\t 0\t 0\t 0\n");
write(fdfile.handle(), &hv0[0], strlen(hv0));
strcpy(hv0, "0\t 0\t 0\t 0\t 0\n");
write(fdfile.handle(), &hv0[0], strlen(hv0));
sprintf(hv0, "0\t %d\t 0\t 0\t 0\t 0\n", (int)alap->total_distance);
write(fdfile.handle(), &hv0[0], strlen(hv0));
strcpy(hv0, "0\t 0\t 0\t 0\t 0\t 0\n");
write(fdfile.handle(), &hv0[0], strlen(hv0));
}
strcpy(hv0, "\n[IntNotes]\n\n[ExtraData]\n\n");
write(fdfile.handle(), &hv0[0], strlen(hv0));
strcpy(hv0, "[Summary-123]\n");
write(fdfile.handle(), &hv0[0], strlen(hv0)); // Time limits 1
smp = max_time - secBeyond - secRange1 - secRange2 - secRange3 - secAbove;
sprintf(hv0, "%lu\t %u\t %u\t %u\t %u\n",
max_time, secRange1, secRange2 + secRange3,
secAbove + secBeyond, smp);
write(fdfile.handle(), &hv0[0], strlen(hv0)); // limits 1
sprintf(hv0, "%d\t %d\t %d\t %d\n",
MaxHr, upper1, lower1, restHr);
write(fdfile.handle(), &hv0[0], strlen(hv0)); // Time limits 1
sprintf(hv0, "%lu\t %u\t %u\t %u\t %u\n",
max_time, secRange2, secRange1 + secRange3,
secAbove + secBeyond, smp);
write(fdfile.handle(), &hv0[0], strlen(hv0)); // limits 2
sprintf(hv0, "%d\t %d\t %d\t %d\n",
MaxHr, upper2, lower2, restHr);
write(fdfile.handle(), &hv0[0], strlen(hv0)); // Time limits 2
sprintf(hv0, "%lu\t %u\t %u\t %u\t %u\n",
max_time, secRange3, secRange1 + secRange2,
secAbove + secBeyond, smp);
write(fdfile.handle(), &hv0[0], strlen(hv0)); // limits 3
sprintf(hv0, "%d\t %d\t %d\t %d\n",
MaxHr, upper3, lower3, restHr);
write(fdfile.handle(), &hv0[0], strlen(hv0)); // Time limits 3
samples = max_time / samsec;
sprintf(hv0, "0\t %u\n\n", samples); // samples
write(fdfile.handle(), &hv0[0], strlen(hv0));
strcpy(hv0, "[Summary-TH]\n");
write(fdfile.handle(), &hv0[0], strlen(hv0));
sprintf(hv0, "%lu\t 0\t %lu\t %d\t %d\t 0\n", max_time, max_time - max_hr - restHr, max_hr, restHr);
write(fdfile.handle(), &hv0[0], strlen(hv0));
sprintf(hv0, "%d\t %d\t %d\t %d\n", MaxHr, upper3, lower1, restHr);
write(fdfile.handle(), &hv0[0], strlen(hv0));
sprintf(hv0, "0\t %u\n\n", samples); // samples
write(fdfile.handle(), &hv0[0], strlen(hv0));
sprintf(hv0, "[HRZones]\n%d\n%d\n%d\n%d\n%d\n%d\n0\n0\n0\n0\n0\n\n",
MaxHr, upper3, upper2, upper1, lower1, restHr);
write(fdfile.handle(), &hv0[0], strlen(hv0));
strcpy(hv0, "[HRData]\n");
write(fdfile.handle(), &hv0[0], strlen(hv0));
smp = 0; // average heart rate of 15 seconds
seconds = 0;
anz = 0;
nsec = samsec;
oldqt = garmin_dtime(lap->start_time);
qt = 0;
point = ds.getPoint(lap->start_time);
while(point)
{
if(seconds >= nsec)
{
if(anz > 0)
{
sprintf(hv0, "%d\n", smp / anz);
write(fdfile.handle(), &hv0[0], strlen(hv0));
}
if(smp > 0 && seconds >= (nsec + samsec))
{
if(anz <= 0)
anz = 0;
for(int x = nsec; x < seconds; x += samsec)
{
sprintf(hv0, "%d\n", smp / anz);
write(fdfile.handle(), &hv0[0], strlen(hv0));
nsec += samsec;
}
}
anz = 0;
smp = 0;
nsec += samsec;
}
qt = garmin_dtime(point->time);
seconds += oldqt->secsTo(*qt);
if(point->heart_rate > 0)
{
smp += point->heart_rate;
anz++;
}
delete oldqt;
oldqt = qt;
point = ds.getPoint(point->time + 1);
}
fdfile.close();
KMessageBox::information(this, i18n("File successfully written."));
}
void sportwatcherWidget::extrasSettings()
{
settingsWidget *dlg = new settingsWidget(this);
if(dlg->exec() == QDialog::Accepted)
{
KConfig cfg(QString("sportwatcher.rc"), KConfig::SimpleConfig);
KConfigGroup ic(&cfg, "SportWatcher");
lower1 = ic.readEntry("lower1", 0);
lower2 = ic.readEntry("lower2", 0);
lower3 = ic.readEntry("lower3", 0);
upper1 = ic.readEntry("upper1", 0);
upper2 = ic.readEntry("upper2", 0);
upper3 = ic.readEntry("upper3", 0);
MaxHr = ic.readEntry("maxHr", 0);
restHr = ic.readEntry("restHr", 0);
vo2max = ic.readEntry("vo2max", 0);
weight = ic.readEntry("weight", 0);
sampleTime = ic.readEntry("seconds", 1);
Serial = ic.readEntry("Serial", false);
Contour = ic.readEntry("Contour", false);
Device = ic.readEntry("Device", QString("/dev/ttyUSB0"));
Forerunner = ic.readEntry("Forerunner", false);
Data = ic.readEntry("Data", QString("/"));
HRM = ic.readEntry("HRM", QString("/"));
MAP = ic.readEntry("MAP", QString("/"));
Units = ic.readEntry("Units", 0);
MapType = ic.readEntry("MapType", 0);
}
delete dlg;
}
void sportwatcherWidget::extrasWMSSettings()
{
#if defined HAVE_GDAL
if(MapType == MPT_BMP || MapType == MPT_GIF || MapType == MPT_PNG ||
MapType == MPT_TIF)
{
coordinatesWidget *idlg = new coordinatesWidget(this);
idlg->exec();
delete idlg;
return;
}
if(MapType == MPT_WMS)
{
wmsbase *dlg = new wmsbase(this);
dlg->exec();
delete dlg;
}
#if defined HAVE_MAPNIK
if(MapType == MPT_SHP || MapType == MPT_OSM)
{
shapeWidget *dlg = new shapeWidget(this);
if(MapType == MPT_SHP)
dlg->setMapType(shapeWidget::MAP_SHAPE);
else
dlg->setMapType(shapeWidget::MAP_OSM);
dlg->exec();
delete dlg;
}
#else
KMessageBox::detailedSorry(this,
i18n("This function was disabled at compile time because of missing Mapnik!"),
i18n("SportWatcher needs Mapnik 0.6 or newer, to enable this function.\n") +
i18n("If you like this to be working, install Mapnik and recompile the source."));
#endif
if(MapType != MPT_WMS && MapType != MPT_SHP && MapType != MPT_OSM)
{
KMessageBox::detailedSorry(this,
i18n("You have not choosen a WMS tag file or shape file directory!"),
i18n("This dialog is especialy to set map specific parameters. ") +
i18n("Therefore this dialog is temporary disabled. It will be ") +
i18n("available again, as soon as you choose \"WMS server\" or ") +
i18n("Shape file as your map type."));
return;
}
#else
KMessageBox::detailedSorry(this,
i18n("This function was disabled at compile time because of missing GDAL v1.x.x!"),
i18n("Sportwatcher needs GDAL v1.5.x or newer, to enable this function.\n") +
i18n("If you like this to be working, install GDAL and recompile the source!"));
#endif
}
/*
* Functions to fill in the boxes of the main mask.
*/
void sportwatcherWidget::showLaps()
{
QString qs_name, qs_distance, qs_etime, qs_avgpace, qs_avgspeed, qs_maxspeed;
QString qs_calories, qs_avghr, qs_maxhr, qs_avgcadence, qs_ascent, qs_descent;
QString qs_totdist;
QDateTime dt;
QTime t, st;
QDateTime *qt;
LAP *lap;
POINT *point;
RUN_NODE *rakt, *rn;
int laps, i, anz, men, cad;
double alt_asc, alt_dsc, sum_asc, sum_dsc, old_asc, old_dsc;
double totdist;
bool pause;
if(!DIRTY)
return;
if(!gmn)
return;
if(gmn->type == data_Dnil)
{
KMessageBox::error(this, i18n("No data found!"));
return;
}
if(gmn->type != data_Dlist) /* List of data */
{
KMessageBox::error(this, i18n("Found unexpected data type %1!").arg(gmn->type));
return;
}
ds.destroy();
min_hr = max_hr = avg_hr = 0;
min_height = max_height = 0.0;
min_speed = max_speed = 0.0;
totdist = 0.0;
// Tab Summary
ui_sportwatcherWidgetBase.liLaps->clear();
ui_sportwatcherWidgetBase.liLaps->setAllColumnsShowFocus(true);
// Tab Laps
ui_sportwatcherWidgetBase.twLaps->clear();
ds.garmin_print_data(gmn);
if(!(rn = ds.getRunNode()))
return;
rakt = rn;
// Tab Summary
ui_sportwatcherWidgetBase.liLaps->setRootIsDecorated(true);
for(i = 1; i < 12; i++)
ui_sportwatcherWidgetBase.liLaps->setColumnAlignment(i, Qt::AlignRight);
// Tab Laps
ui_sportwatcherWidgetBase.edTotalDistance->clear();
ui_sportwatcherWidgetBase.edTotalTime->clear();
ui_sportwatcherWidgetBase.edAvgSpeed->clear();
ui_sportwatcherWidgetBase.edTotalHeight->clear();
ui_sportwatcherWidgetBase.edAvgHR->clear();
ui_sportwatcherWidgetBase.edLapNumber->clear();
qs_name = qs_distance = qs_etime = qs_avgpace = qs_avgspeed = qs_maxspeed = QString("");
qs_calories = qs_avghr = qs_maxhr = qs_avgcadence = qs_ascent = qs_descent = QString("");
men = 0;
cad = 0;
// The main loop.
// If a supported run type is detected, it will be processed.
while(rakt)
{
// Check for a supported run type
if(rakt->run->type == data_D1000 || rakt->run->type == data_D1009 ||
rakt->run->type == data_D1010)
{
int cal, ahr, mhr;
double distance, speed, mspeed;
QDate dat;
// Set the name depending on the sport type
// This is used on the tab "Summary"
switch(rakt->run->sport_type)
{
case D1000_running: qs_name = i18n("Running: "); break;
case D1000_biking: qs_name = i18n("Biking: "); break;
case D1000_other: qs_name = i18n("Other: "); break;
default:
qs_name = i18n("Unknown: ");
}
if(!(lap = ds.getLap(rakt->run->first_lap_index)))
return;
qt = garmin_dtime(lap->start_time);
StartTime = *qt;
st = qt->time();
dat = qt->date();
delete qt;
qt = 0;
// Find the last track;
// It is possible to delete laps directly on the watch,
// so we can't be sure the last lap is really the last one.
// Tracks are not deleted and the last track contains the
// summuraries we need.
if(!(point = ds.getLastPoint()))
{
KMessageBox::error(this, i18n("Error getting the last messure point!"));
return;
}
qt = garmin_dtime(point->time);
t = qt->time();
t.setHMS(0, 0, 0);
t = t.addSecs(ds.getTotalTime());
qt->setDate(dat);
qt->setTime(t);
qs_name.append(kl->formatDate(dat, KLocale::ShortDate));
qs_name.append(" ");
qs_name.append(kl->formatTime(st, true));
max_time = ds.getTotalTime();
qs_etime = QString(qt->toString("hh:mm:ss.zzz"));
distance = 0.0;
cal = 0;
mspeed = 0;
ahr = mhr = 0;
anz = 0;
cad = 0;
sum_asc = sum_dsc = old_asc = old_dsc = 0;
// Find out the total distance, calories, maximum speed,
// maximum heart rate and the average heart rate. Get this
// values from the lap summary the watch made.
for(i = rakt->run->first_lap_index; (unsigned int)i <= rakt->run->last_lap_index; i++)
{
if((lap = ds.getLap(i)) == NULL)
continue;
distance += lap->total_distance;
cal += lap->calories;
if(lap->avg_cadence != 0xff)
cad += lap->avg_cadence;
ahr += lap->avg_heart_rate;
anz++;
if(lap->max_speed > mspeed)
mspeed = lap->max_speed;
if(lap->max_heart_rate > mhr)
mhr = lap->max_heart_rate;
}
total_distance = distance = ds.getTotalDistance();
if(Units == 1) // Statute?
qs_distance.sprintf("%.2f ft", distance / 0.304);
else
qs_distance.sprintf("%.2f m", distance);
if(distance > 0)
{
QTime tt = qt->time();
long secs = (double)(tt.hour() * 3600 + tt.minute() * 60 + tt.second()) / 100.0;
if(Units == 0)
secs = secs * (1000.0 / distance * 100.0);
else
secs = secs * (1609.344 / distance * 100.0);
int h = secs / 3600;
int m = (secs - (h * 3600)) / 60;
int s = secs - ((h * 3600) + (m * 60));
t = QTime(h, m, s, 0);
qs_avgpace = QString(" ") + kl->formatTime(t, true);
if(Units == 0)
qs_avgpace.append(QString(" /km"));
else
qs_avgpace.append(QString(" /mi"));
}
if(Units == 1) // Statute?
speed = distance / ds.getTotalTime() * 3.6 / 1.609344;
else
speed = distance / ds.getTotalTime() * 3.6;
qs_avgspeed.sprintf("%.2f %s", speed, (Units == 1) ? "mph" : "km/h");
qs_maxspeed.sprintf("%.2f %s", (Units == 1) ? mspeed * 3.6 / 1.609344 : mspeed * 3.6, (Units == 1) ? "mph" : "km/h");
qs_calories.sprintf("%d", cal);
qs_avghr.sprintf("%d bpm", ahr / anz);
qs_maxhr.sprintf("%d bpm", mhr);
if(cad > 0)
qs_avgcadence.sprintf("%d", cad / anz);
// Add the summary line columns to the tab "Summary"
K3ListViewItem *element = new K3ListViewItem(ui_sportwatcherWidgetBase.liLaps,
qs_name, kl->formatNumber(qs_distance, false),
qs_etime, qs_avgpace, kl->formatNumber(qs_avgspeed, false),
kl->formatNumber(qs_maxspeed, false), qs_calories, qs_avghr);
element->setText(8, qs_maxhr);
element->setText(9, qs_avgcadence);
element->setText(10, kl->formatNumber(qs_ascent, false));
element->setText(11, kl->formatNumber(qs_descent, false));
element->sortChildItems(0, false);
element->setOpen(true);
element->setPixmap(0, KIcon(QString("activity")).pixmap(16));
ui_sportwatcherWidgetBase.liLaps->insertItem(element);
// Add some of the summaries to the fields on the tab "Lap details"
ui_sportwatcherWidgetBase.edTotalDistance->setAlignment(Qt::AlignRight);
ui_sportwatcherWidgetBase.edTotalDistance->insert(kl->formatNumber(qs_distance, false));
ui_sportwatcherWidgetBase.edTotalTime->setAlignment(Qt::AlignRight);
ui_sportwatcherWidgetBase.edTotalTime->insert(qs_etime);
ui_sportwatcherWidgetBase.edAvgSpeed->setAlignment(Qt::AlignRight);
ui_sportwatcherWidgetBase.edAvgSpeed->insert(kl->formatNumber(qs_avgspeed, false));
ui_sportwatcherWidgetBase.edTotalHeight->setAlignment(Qt::AlignRight);
ui_sportwatcherWidgetBase.edTotalHeight->insert(kl->formatNumber(qs_ascent, false));
ui_sportwatcherWidgetBase.edAvgHR->setAlignment(Qt::AlignRight);
ui_sportwatcherWidgetBase.edAvgHR->insert(qs_avghr);
delete qt;
/* Get the laps. */
laps = 1;
for(i = rakt->run->first_lap_index; (unsigned int)i <= rakt->run->last_lap_index; i++)
{
double spd;
char *un;
if((lap = ds.getLap(i)) == NULL)
continue;
qt = garmin_dtime(lap->start_time);
qs_name.sprintf("Lap %03d - ", laps);
qs_name.append(kl->formatTime(qt->time(), true));
qs_distance.sprintf("%.2f %s", (Units == 1) ? lap->total_distance / 0.304 : lap->total_distance, (Units == 1) ? "ft" : "m");
totdist += (Units == 1) ? lap->total_distance / 0.304 : lap->total_distance;
qs_totdist.sprintf("%2.f %s", totdist, (Units == 1) ? "ft" : "m");
t = QTime(0, 0, 0, 0);
t = t.addMSecs(lap->total_time * 10);
qs_etime = t.toString("hh:mm:ss.zzz");
spd = lap->total_distance / (lap->total_time / 100.0);
delete qt;
qt = 0;
if(Units == 0)
{
un = (char *)"km/h";
spd *= 3.6;
}
else
{
spd *= 3.6 / 1.609344;
un = (char *)"mph";
}
qs_avgspeed.sprintf("%.2f %s", spd, un);
qs_maxspeed.sprintf("%.2f %s", (Units == 1) ? lap->max_speed * 3.6 / 1.609344 : lap->max_speed * 3.6, un);
qs_calories.sprintf("%d", lap->calories);
if(lap->total_distance > 0 && lap->total_time != 0)
{
double fact;
if(Units == 0)
fact = 1000.0; // 1 km
else
fact = 1609.344; // 1 mile in meters
long secs = (double)lap->total_time / 10000.0 * (fact / lap->total_distance * 100.0);
int h = secs / 3600;
int m = (secs - (h * 3600)) / 60;
int s = secs - ((h * 3600) + (m * 60));
t = QTime(h, m, s, 0);
qs_avgpace = kl->formatTime(t, true);
if(Units == 0)
qs_avgpace.append(QString(" /km"));
else
qs_avgpace.append(QString(" /mi"));
}
qs_avghr.sprintf("%d bpm", lap->avg_heart_rate);
qs_maxhr.sprintf("%d bpm", lap->max_heart_rate);
anz = 0;
alt_asc = alt_dsc = 0;
// Add a new detail line to the tab "Lap details"
QTreeWidgetItem * trdetail = new QTreeWidgetItem(ui_sportwatcherWidgetBase.twLaps);
if((point = ds.getPoint(lap->start_time)) != 0)
{
if(point->alt < 20000)
{
alt_dsc = alt_asc = point->alt;
if(old_asc == 0)
old_asc = alt_asc;
if(old_dsc == 0)
old_dsc = alt_dsc;
}
else
alt_dsc = alt_asc = 0;
POINT *oldPoint = 0;
double sc, dist, speed;
unsigned long t1, t2;
t1 = t2 = 0;
pause = false;
bool ignore = false;
while(point)
{
if(point->time > (lap->start_time + (lap->total_time / 100)))
break;
QTreeWidgetItem *child = new QTreeWidgetItem(trdetail);
qt = garmin_dtime(point->time);
child->setText(0, kl->formatTime(qt->time(), true));
child->setTextAlignment(0, Qt::AlignRight);
child->setText(8, QString("%1 %2").arg(kl->formatNumber((double)point->heart_rate, 0)).arg(" bpm"));
child->setTextAlignment(8, Qt::AlignRight);
if(point->cadence < 0xff)
{
child->setText(10, kl->formatNumber((double)point->cadence, 0));
child->setTextAlignment(10, Qt::AlignRight);
}
if(point->alt < 20000)
{
double alt = (Units == 0) ? (double)point->alt : (double)point->alt / 0.304;
child->setText(11, QString("%1 %2").arg(kl->formatNumber(alt, 2)).arg((Units == 0) ? QString(" m") : QString(" ft")));
child->setTextAlignment(11, Qt::AlignRight);
}
if(!oldPoint)
oldPoint = point;
if(point->alt > alt_asc && point->alt < 20000)
{
alt_asc = point->alt;
if(alt_dsc == 0)
alt_dsc = point->alt;
}
if(point->alt < alt_dsc)
alt_dsc = point->alt;
// save the min and max values. We need this information to
// build the graphics.
if(point->heart_rate > max_hr && point->heart_rate < 250)
max_hr = point->heart_rate;
if((min_hr == 0 && point->heart_rate > 0 && point->heart_rate < 250)
|| (point->heart_rate > 0 && point->heart_rate < min_hr))
min_hr = point->heart_rate;
if(point->alt < 20000 && max_height < point->alt)
max_height = point->alt;
if(point->alt < 20000 && (min_height == 0.0 || min_height > point->alt))
min_height = point->alt;
// Calculate speed of current track
if(!pause && point->distance > 1.0e10)
{
t1 = point->time;
pause = true;
ignore = true;
}
else if(pause)
{
t2 = point->time;
pause = false;
point = ds.getPoint(point->time + 1);
continue;
}
if(!ignore && !pause)
{
sc = point->time - oldPoint->time;
dist = point->distance - oldPoint->distance;
child->setText(1, QString("%1 %2").arg(kl->formatNumber((Units == 0) ? (double)dist : (double)dist / 0.304, 2)).arg((Units == 0) ? QString(" m") : QString(" ft")));
child->setTextAlignment(1, Qt::AlignRight);
if(t2 > t1)
sc -= t2 - t1;
if(sc > 0.0)
{
speed = (dist / sc) * 3.6;
if(speed > lap->max_speed * 3.6)
speed = lap->max_speed * 3.6;
}
else
speed = 0.0;
if(Units == 1)
speed /= 1.609344;
child->setText(5, QString("%1 %2").arg(kl->formatNumber(speed, 2)).arg((Units == 0) ? QString(" Km/h") : QString(" mi/h")));
child->setTextAlignment(5, Qt::AlignRight);
if(speed > 0.0 && speed < 400.0 && max_speed < speed)
max_speed = speed;
if(speed > 0.0 && (min_speed == 0.0 || min_speed > speed))
min_speed = speed;
oldPoint = point;
}
if(!pause && ignore)
ignore = false;
if(point->heart_rate > 0 && point->heart_rate < 250)
{
avg_hr += point->heart_rate;
men++;
}
point = ds.getPoint(point->time + 1);
}
if(old_asc < alt_asc)
sum_asc += (alt_asc - old_asc);
if(old_dsc > alt_dsc)
sum_dsc += (old_dsc - alt_dsc);
old_asc = alt_asc;
old_dsc = alt_dsc;
qs_ascent.sprintf("%.2f %s", (Units == 1) ? (alt_asc / 0.304) : alt_asc, (Units == 1) ? "ft" : "m");
qs_descent.sprintf("%.2f %s", (Units == 1) ? (alt_dsc / 0.304) : alt_dsc, (Units == 1) ? "ft" : "m");
}
if(lap->avg_cadence != 0xff)
qs_avgcadence.sprintf("%d", lap->avg_cadence);
// Add a new detail line to the tab "Summary"
K3ListViewItem *edetail = new K3ListViewItem(element, qs_name,
kl->formatNumber(qs_distance, false),
qs_etime, qs_avgpace, kl->formatNumber(qs_avgspeed, false),
kl->formatNumber(qs_maxspeed, false), qs_calories, qs_avghr);
edetail->setText(8, qs_maxhr);
edetail->setText(9, qs_avgcadence);
edetail->setText(10, kl->formatNumber(qs_ascent, false));
edetail->setText(11, kl->formatNumber(qs_descent, false));
edetail->setPixmap(0, KIcon(QString("history")).pixmap(16));
QPixmap qpx = KIcon(QString("other")).pixmap(16);
trdetail->setText(0, qs_etime);
trdetail->setTextAlignment(0, Qt::AlignRight);
trdetail->setText(1, kl->formatNumber(qs_distance));
trdetail->setTextAlignment(1, Qt::AlignRight);
trdetail->setText(2, kl->formatNumber(qs_totdist));
trdetail->setTextAlignment(2, Qt::AlignRight);
trdetail->setText(4, qs_avgpace);
trdetail->setTextAlignment(4, Qt::AlignRight);
trdetail->setText(5, kl->formatNumber(qs_avgspeed, false));
trdetail->setTextAlignment(5, Qt::AlignRight);
trdetail->setText(6, kl->formatNumber(qs_maxspeed, false));
trdetail->setTextAlignment(6, Qt::AlignRight);
trdetail->setText(7, qs_calories);
trdetail->setTextAlignment(7, Qt::AlignRight);
trdetail->setText(8, qs_avghr);
trdetail->setTextAlignment(8, Qt::AlignRight);
trdetail->setText(9, qs_maxhr);
trdetail->setTextAlignment(9, Qt::AlignRight);
trdetail->setText(10, qs_avgcadence);
trdetail->setTextAlignment(10, Qt::AlignRight);
trdetail->setText(11, kl->formatNumber(qs_ascent, false));
trdetail->setTextAlignment(11, Qt::AlignRight);
switch(rakt->run->sport_type)
{
case D1000_running:
edetail->setPixmap(0, KIcon(QString("spw-running")).pixmap(16));
break;
case D1000_biking:
edetail->setPixmap(0, KIcon(QString("bike")).pixmap(16));
break;
case D1000_other:
edetail->setPixmap(0, qpx);
break;
default:
edetail->setPixmap(0, qpx);
}
ui_sportwatcherWidgetBase.liLaps->clearSelection();
element->insertItem(edetail);
delete qt;
laps++;
}
qs_ascent.sprintf("%.2f %s", (Units == 1) ? sum_asc / 0.304 : sum_asc, (Units == 1) ? "ft" : "m");
qs_descent.sprintf("%.2f %s", (Units == 1) ? sum_dsc / 0.304 : sum_dsc, (Units == 1) ? "ft" : "m");
element->setText(10, qs_ascent);
element->setText(11, qs_descent);
qs_ascent.sprintf("%s %s", (Units == 1) ? kl->formatNumber(ds.getAscend() / 0.304, 2).toAscii().data() : kl->formatNumber(ds.getAscend(), 2).toAscii().data(), (Units == 1) ? "ft" : "m");
ui_sportwatcherWidgetBase.edTotalHeight->clear();
ui_sportwatcherWidgetBase.edTotalHeight->insert(qs_ascent);
ui_sportwatcherWidgetBase.edLapNumber->setAlignment(Qt::AlignRight);
ui_sportwatcherWidgetBase.edLapNumber->insert(kl->formatNumber((double)laps, 0));
}
rakt = rakt->next;
}
if(men > 0)
avg_hr /= men;
else
min_hr = max_hr = avg_hr = 0;
}
void sportwatcherWidget::showTrack()
{
showTrack(0, QRect(0, 0, 0, 0), 0);
}
void sportwatcherWidget::showTrack(int zoom)
{
showTrack(zoom, mapPan, mapLap);
}
void sportwatcherWidget::showTrack(int zoom, const QRect &pan, LAP *lap)
{
int width, height;
double x1, y1, x2, y2;
int a, top, left, panX, panY;
uint32 i;
double coordW, coordH, tick;
double meterW, dist, fact;
QPainter paint;
posn_type posNW, posSE, posLXY, posRXY;
POINT *point;
bool Fgeo = false;
bool Data = false;
#if defined HAVE_GDAL
QString fName = MAP;
//double adfGeoTransform[6];
GDALDataset *poDataset = 0;
GDALRasterBand *poBand = 0;
unsigned char *pafScanline = 0;
unsigned char *pafScanlineRed = 0;
unsigned char *pafScanlineGreen = 0;
unsigned char *pafScanlineBlue = 0;
unsigned char *pafScanlineAlpha = 0;
int nXSize, nYSize;
int xOff, yOff;
double oriLeftLon, oriLeftLat, oriRightLon, oriRightLat;
#endif
if(!DIRTY || curTab == 2 || curTab == 3)
return;
if(!gmn)
return;
QApplication::setOverrideCursor(QCursor(Qt::WaitCursor));
if(zoom != zfactor)
zfactor = zoom;
if(mapLap != lap)
mapLap = lap;
y2 = x2 = 0;
#if defined HAVE_GDAL
nXSize = nYSize = 0;
KConfig cfg(QString("sportwatcher.rc"), KConfig::SimpleConfig);
KConfigGroup wms(&cfg, "WMS");
bool square = wms.readEntry("Square", false);
int CorrX = wms.readEntry("CorrX", 0);
int CorrY = wms.readEntry("CorrY", 0);
KConfigGroup ic(&cfg, "ImageCoords");
oriLeftLon = ic.readEntry("LeftLon", 0.0);
oriLeftLat = ic.readEntry("LeftLat", 0.0);
oriRightLon = ic.readEntry("RightLon", 0.0);
oriRightLat = ic.readEntry("RightLat", 0.0);
// int isrs = ic.readEntry("SRS", 0);
#endif
if(curTab == 0 && !ActivePrint)
{
width = ui_sportwatcherWidgetBase.imgMap->width() - 2;
height = ui_sportwatcherWidgetBase.imgMap->height();
}
else if(ActivePrint)
{
width = pmPrMap.width();
height = pmPrMap.height();
}
else
{
width = ui_sportwatcherWidgetBase.grMap->width() - 2;
height = ui_sportwatcherWidgetBase.grMap->height();
}
#if defined HAVE_GDAL
if(MapType == MPT_WMS && square)
pmMap = QPixmap(width / (int)mFactor * (int)mFactor, height / (int)mFactor * (int)mFactor);
else
pmMap = QPixmap(width, height);
#else
pmMap = QPixmap(width, height);
#endif
if(pmMap.isNull())
return;
// Here we begin do draw something
paint.begin(&pmMap);
panX = panY = 0;
if(stateHand && mapPan != pan)
{
mapPan = pan;
panX = mapPan.right() - mapPan.left();
panY = mapPan.bottom() - mapPan.top();
oldTransX += (double)panX;
oldTransY += (double)panY;
}
memset(&posNW, 0, sizeof(posn_type));
memset(&posSE, 0, sizeof(posn_type));
posSE.lat = 90.0;
posSE.lon = 180.0;
posNW.lat = -90.0;
posNW.lon = -180.0;
/*
* Find out the corners of our track (NW, NE, SE, SW)
*/
if(mapLap)
i = mapLap->start_time;
else
i = 0;
while((point = ds.getPoint(i)) != 0)
{
if(mapLap && point->time > (mapLap->start_time + (mapLap->total_time / 100)))
break;
if(point->posn.lat == 0x7fffffff || point->posn.lon == 0x7fffffff)
{
i = point->time + 1;
continue;
}
if(SEMI2DEG(point->posn.lat) > posNW.lat)
posNW.lat = SEMI2DEG(point->posn.lat);
if(SEMI2DEG(point->posn.lat) < posSE.lat)
posSE.lat = SEMI2DEG(point->posn.lat);
if(SEMI2DEG(point->posn.lon) > posNW.lon)
posNW.lon = SEMI2DEG(point->posn.lon);
if(SEMI2DEG(point->posn.lon) < posSE.lon)
posSE.lon = SEMI2DEG(point->posn.lon);
i = point->time + 1;
Data = true;
}
coordW = (posNW.lon > posSE.lon) ? posNW.lon - posSE.lon : posSE.lon - posNW.lon;
coordH = (posNW.lat > posSE.lat) ? posNW.lat - posSE.lat : posSE.lat - posNW.lat;
meterW = ds.earth_distance(posNW.lat, posNW.lon, posNW.lat, posSE.lon);
// define the ticks to translate the GPS coordinates into pixels.
// The track should be centered and we have to calculate the
// rectangular within we draw the track.
if(coordW < coordH)
{
tick = (double)width / coordW + (double)zoom;
if((tick * coordH) > height)
tick = (double)height / coordH + (double)zoom;
}
else
{
tick = (double)height / coordH + (double)zoom;
if((tick * coordW) > width)
tick = (double)width / coordW + (double)zoom;
}
left = width - (width - tick * coordW) / 2;
top = (height - tick * coordH) / 2;
a = tick * coordW;
if(Units == 0)
dist = meterW / a; // Meters
else
dist = meterW * 1.609344 / a; // 1/1000 mile (5.28 feet)
#if defined HAVE_GDAL
geoRect.llat = 0.0;
geoRect.llon = 0.0;
geoRect.rlat = 0.0;
geoRect.rlon = 0.0;
geoRect.width = width;
geoRect.height = height;
/*
* If we have a map file, we try to read it and if successfull,
* we should get a map painted.
*
* Currently only WMS-Server is supported, allthough GDAL allows
* several other formats too.
*/
if(!MAP.isEmpty() && Data)
{
bool writeTag = true;
double mtx, mty;
double vx, vy;
xOff = yOff = 0;
posRXY.lon = posNW.lon + (width - left + oldTransX) / tick;
posLXY.lat = posNW.lat + (top + oldTransY) / tick;
posLXY.lon = posSE.lon - (left - a - oldTransX) / tick;
posRXY.lat = posSE.lat - (height - top - (tick * coordH) - oldTransY) / tick;
geoRect.llat = posLXY.lat;
geoRect.llon = posLXY.lon;
geoRect.rlat = posRXY.lat;
geoRect.rlon = posRXY.lon;
// width and height of map in meters
mtx = ds.earth_distance(posRXY.lat, posRXY.lon, posRXY.lat, posLXY.lon);
mty = ds.earth_distance(posRXY.lat, posRXY.lon, posLXY.lat, posRXY.lon);
// factor to correct the map, in case we use a WMS server
if(MapType == MPT_WMS)
{
vx = (posRXY.lon - posLXY.lon) / mtx * CorrX;
vy = (posRXY.lat - posLXY.lat) / mty * CorrY;
posRXY.lon += vx;
posRXY.lat += vy;
posLXY.lon += vx;
posLXY.lat += vy;
}
/*
* Write a control file for GDAL, if we use a WMS server.
* Warp an image if we use PNG or BMP or GIF.
* Warp a region if we use TIFF
*/
if(MapType == MPT_WMS)
writeTag = writeWMSTag(posLXY.lon, posLXY.lat, posRXY.lon, posRXY.lat, width, height);
if(MapType == MPT_GIF || MapType == MPT_BMP || MapType == MPT_PNG ||
MapType == MPT_SGI || MapType == MPT_TIF)
writeTag = warpImage(MAP, &fName);
if(writeTag)
{
if(MapType != MPT_SHP && (poDataset = (GDALDataset *)GDALOpen(fName.toAscii().constData(), GA_ReadOnly)) != NULL)
{
QPixmap bild;
int nRasterCount = poDataset->GetRasterCount();
int nXBlock, nYBlock;
GDALColorTable *pCT, *pCTb, *pCTr, *pCTg, *pCTa;
int bGotMin, bGotMax;
int tTypeLen; //, tColorEntrys;
GDALDataType tRasterType;
double adfMinMax[2];
pCT = pCTb = pCTr = pCTg = pCTa = 0;
tTypeLen = 0;
pafScanlineRed = pafScanlineGreen = pafScanlineBlue = pafScanlineAlpha = 0;
Fgeo = true;
/*
* Read every raster band.
*
* If we get 3 raster bands, the image is a 24 bit image.
* If we get 4 raster bands, the image is probably a 24 bit
* image with an alpha channel. Currently the alpha channel
* is ignored!
* If we have 1 raster band, the image is 8 bit monochrom.
* Otherwise the image is undefined and the results are also.
*/
for(a = 1; a <= nRasterCount; a++)
{
if(!Fgeo)
break;
if(!(poBand = poDataset->GetRasterBand(a)))
{
paint.end();
return;
}
poBand->GetBlockSize(&nXBlock, &nYBlock);
nXSize = poBand->GetXSize();
nYSize = poBand->GetYSize();
tRasterType = poBand->GetRasterDataType();
tTypeLen = GDALGetDataTypeSize(tRasterType) / 8; // We need Bytes not Bits!
// tColor = poBand->GetColorInterpretation();
adfMinMax[0] = poBand->GetMinimum(&bGotMin);
adfMinMax[1] = poBand->GetMaximum(&bGotMax);
if(!(bGotMin && bGotMax))
GDALComputeRasterMinMax((GDALRasterBandH)poBand, TRUE, adfMinMax);
// if((pCT = poBand->GetColorTable()) != NULL)
// tColorEntrys = poBand->GetColorTable()->GetColorEntryCount();
switch(a)
{
case 1: pafScanlineRed = new unsigned char[tTypeLen * nXSize * nYSize]; pafScanline = pafScanlineRed; pCTr = pCT; break;
case 2: pafScanlineGreen = new unsigned char[tTypeLen * nXSize * nYSize]; pafScanline = pafScanlineGreen; pCTg = pCT; break;
case 3: pafScanlineBlue = new unsigned char[tTypeLen * nXSize * nYSize]; pafScanline = pafScanlineBlue; pCTb = pCT; break;
case 4: pafScanlineAlpha = new unsigned char[tTypeLen * nXSize * nYSize]; pafScanline = pafScanlineAlpha; pCTa = pCT; break;
}
if(!pafScanline)
{
paint.end();
KMessageBox::error(this, i18n("Not enough memory for a raster operation!"));
return;
}
memset(pafScanline, 0, tTypeLen * nXSize * nYSize);
/*
* Get the image (from the server) and put the tiles together.
*
* The function reads only one raster band. This is,
* because the function is called for every raster band and
* every raster band is stored into a separate array.
*/
if(poBand->RasterIO(GF_Read, 0, 0, nXSize, nYSize, pafScanline, nXSize, nYSize, tRasterType, 0, 0) == CE_Failure)
{
paint.end();
KMessageBox::error(this, i18n("Error reading a raster band!"));
paint.begin(&pmMap);
Fgeo = false;
break;
}
else
Fgeo = true;
}
/*
* Only if Fgeo is TRUE, we've read successfully all raster
* bands. Now we have to put the bands together to get
* an image.
*/
if(Fgeo)
{
unsigned char *pCombinedBytes = new unsigned char[(tTypeLen * nXSize * nYSize * nRasterCount)];
unsigned char *ptr_dest, *ptr_src;
int j;
ptr_dest = ptr_src = 0;
/*
* We need two nested loops to set the pixels in the wanted
* order.
*/
for(a = 0, j = 0; a < (nXSize * nYSize * nRasterCount); a += nRasterCount, j++)
{
int k = a;
for(int m = nRasterCount - 1; m >= 0; m--, k++)
{
unsigned char *pBytes = 0;
switch(m)
{
case 3: pBytes = pafScanlineAlpha; pCT = pCTa; break;
case 2: pBytes = pafScanlineBlue; pCT = pCTb; break;
case 1: pBytes = pafScanlineGreen; pCT = pCTg; break;
default: pBytes = pafScanlineRed; pCT = pCTr;
}
ptr_dest = pCombinedBytes + k;
unsigned char b = pBytes[j];
/*
* If we have a color table, the pixels are pointers
* to the color table. We need to convert them into
* 24 bit pixels plus an optional alpha channel.
*/
if(pCT != NULL)
{
GDALColorEntry ce;
unsigned int c = (unsigned int)b;
c = pCT->GetColorEntryAsRGB(c, &ce);
if(m == 0) c = ce.c1;
if(m == 1) c = ce.c2;
if(m == 2) c = ce.c3;
if(m == 3) c = ce.c4;
b = (unsigned char)c;
}
ptr_src = &b;
memcpy(ptr_dest, ptr_src, 1);
}
}
x1 = y1 = 0;
/*
* The following loop is QT specific! It sets the pixels
* of the raw image, pixel by pixel. This may be slow, but
* everything else didn't work :-(
*
* FIXME: We need a more effective routine to put the
* raw image into QT's "painter" class.
*/
for(a = 0; a < (nXSize * nYSize * nRasterCount); a += nRasterCount)
{
if(x1 < width && y1 < height)
{
if(nRasterCount == 3)
paint.setPen(QPen(QColor((int)pCombinedBytes[a + 2], (int)pCombinedBytes[a + 1], (int)pCombinedBytes[a]), Qt::SolidLine));
else if(nRasterCount > 3)
paint.setPen(QPen(QColor(qRgba((int)pCombinedBytes[a + 3], (int)pCombinedBytes[a + 2], (int)pCombinedBytes[a + 1], (int)pCombinedBytes[a])), Qt::SolidLine));
else if(nRasterCount == 2)
paint.setPen(QPen(QColor((int)pCombinedBytes[a + 1], (int)pCombinedBytes[a], (int)pCombinedBytes[a + 1]), Qt::SolidLine));
else if(nRasterCount == 1)
paint.setPen(QPen(QColor((int)pCombinedBytes[a], (int)pCombinedBytes[a], (int)pCombinedBytes[a]), Qt::SolidLine));
paint.drawPoint(x1, y1);
}
x1++;
if(x1 >= nXSize)
{
x1 = 0;
y1++;
}
}
delete pCombinedBytes;
pCombinedBytes = 0;
}
if(pafScanlineRed)
delete pafScanlineRed;
if(pafScanlineGreen)
delete pafScanlineGreen;
if(pafScanlineBlue)
delete pafScanlineBlue;
if(pafScanlineAlpha)
delete pafScanlineAlpha;
GDALClose(poDataset);
poDataset = 0;
if(MAP != fName)
unlink(fName.toAscii().data());
}
#if defined HAVE_MAPNIK
else if(MapType == MPT_SHP)
{
QDir shpd(MAP, QString("*.shp"));
if(shpd.count() < 1)
{
KMessageBox::error(this, i18n("There is no shape file in directory %1").arg(MAP));
Fgeo = false;
}
else
{
SRender rd;
QColor bg(220, 220, 220); // background color
if(curTab == 0 && !ActivePrint)
rd.setDrawArea(ui_sportwatcherWidgetBase.imgMap->width(), ui_sportwatcherWidgetBase.imgMap->height());
else if(!ActivePrint)
rd.setDrawArea(ui_sportwatcherWidgetBase.grMap->width(), ui_sportwatcherWidgetBase.grMap->height());
else if(ActivePrint)
rd.setDrawArea(pmPrMap.width(), pmPrMap.height());
rd.setMapType(SRender::MAP_SHAPE);
if(rd.getMap(posLXY.lon, posLXY.lat, posRXY.lon, posRXY.lat))
{
paint.fillRect(0, 0, width + 2, height + 2, bg);
paint.drawPixmap(0, 0, rd.pixmap());
Fgeo = true;
}
else
Fgeo = false;
}
}
else if(MapType == MPT_OSM)
{
QFileInfo osmf(MAP);
if(!osmf.exists())
{
KMessageBox::error(this, i18n("The OSM file %1 does not exist!").arg(MAP));
Fgeo = false;
}
else
{
SRender rd;
QColor bg(220, 220, 220); // background color
if(curTab == 0 && !ActivePrint)
rd.setDrawArea(ui_sportwatcherWidgetBase.imgMap->width(), ui_sportwatcherWidgetBase.imgMap->height());
else if(!ActivePrint)
rd.setDrawArea(ui_sportwatcherWidgetBase.grMap->width(), ui_sportwatcherWidgetBase.grMap->height());
else if(ActivePrint)
rd.setDrawArea(pmPrMap.width(), pmPrMap.height());
rd.setMapType(SRender::MAP_OSM);
if(rd.getMap(posLXY.lon, posLXY.lat, posRXY.lon, posRXY.lat))
{
paint.fillRect(0, 0, width + 2, height + 2, bg);
paint.drawPixmap(0, 0, rd.pixmap());
Fgeo = true;
}
else
Fgeo = false;
}
}
#endif // HAVE_MAPNIK
else
{
KMessageBox::error(this, i18n("Error opening map file!"));
Fgeo = false;
}
}
}
#endif // HAVE_GDAL
/*
* Here we come to draw the track. It will be drawn over the previous
* created map image.
*/
// Colors and fonts
QColor background(220, 220, 220); // background color
QColor red(255, 0, 0); // mile marker
QColor black(0, 0, 0); // Text, center of track
// QColor yellow(255, 255, 0);
QColor yellow(0x00cf, 0x00ff, 0x0000); // color of track
QFont fntNormal("Helvetica");
fntNormal.setPixelSize(10);
fntNormal.setStyleHint(QFont::Helvetica);
QPen dot(red, 4, Qt::SolidLine);
QPen line(black, 2, Qt::SolidLine);
QPen yline(yellow, 4, Qt::SolidLine);
// Fill background with background colors, if there is no map.
if(!Fgeo)
paint.fillRect(0, 0, width + 2, height + 2, background);
if(Units == 0)
fact = 1000.0;
else
fact = 1609.344;
paint.setPen(line);
paint.drawLine(10, height - 9, 10, height - 4);
paint.drawLine(10, height - 4, 10 + (fact / dist), height - 4);
paint.drawLine(10 + (fact / dist), height - 9, 10 + (fact / dist), height - 4);
paint.setFont(fntNormal);
if(Units == 0)
paint.drawText(10, height - 10, QString("1000 m"));
else
paint.drawText(10, height - 10, QString("5280 ft"));
// Draw track
if(mapLap)
i = mapLap->start_time;
else
i = 0;
x1 = y1 = 0.0;
bool wStart = false;
while((point = ds.getPoint(i)) != 0)
{
if(mapLap && point->time > (mapLap->start_time + (mapLap->total_time / 100)))
break;
if(point->posn.lat == 0x7fffffff || point->posn.lon == 0x7fffffff)
{
i = point->time + 1;
continue;
}
x2 = (left + ((posNW.lon - SEMI2DEG(point->posn.lon)) * tick * -1)) + oldTransX;
y2 = (top + ((posNW.lat - SEMI2DEG(point->posn.lat)) * tick)) + oldTransY;
if(!wStart && x1 != 0.0 && y1 != 0.0)
{
// Load the start symbol
QPixmap qpx(KIcon(QString("wstart")).pixmap(16));
// Find the angle of the track and turn the symbol accordingly
// we use Pythagoras to calculate the triangle
double xl = (x1 < x2) ? x2 - x1 : x1 - x2;
double yl = (y1 < y2) ? y2 - y1 : y1 - y2;
double da = fmin(xl, yl);
double db = fmax(xl, yl);
double zl = sqrt(pow(da, 2) + pow(db, 2));
double angle = (asin(da / zl) / M_PIl) * 180.0;
angle = (angle > 45.0) ? 90.0 - angle : angle;
// cout << "Winkel: " << angle << " ---- X: " << xl << ", Y: " << yl << ", Z: " << zl << ", Point (x1,y1,x2,y2): " << x1 << ", " << y1 << ", " << x2 << ", " << y2 << endl;
if(x1 < x2 && y1 < y2) // right, down
angle = 90.0 + angle;
else if(x1 > x2 && y1 < y2) // left, down
angle = 270.0 - angle;
else if(x1 > x2 && y1 > y2) // left, up
angle = 270.0 + angle;
else // right, up
angle = 90.0 - angle;
// cout << "Realer Winkel: " << angle << endl;
// Set the center of the symbol
paint.save();
paint.translate(x1, y1);
// rotate the symbol
paint.rotate(angle);
paint.drawPixmap(-8, -8, qpx);
paint.restore();
wStart = true;
}
if(x1 == 0.0 && y1 == 0.0)
{
x1 = x2;
y1 = y2;
}
paint.setPen(yline);
paint.drawLine(x1, y1, x2, y2);
if((point->distance - dist) >= fact) // a dot at every 1000 meters or at 1 mile
{
paint.setPen(dot);
paint.drawEllipse(x2 - 2, y2 - 2, 3, 3);
dist = (int)(point->distance / fact) * fact;
}
paint.setPen(line);
paint.drawLine(x1, y1, x2, y2);
x1 = x2;
y1 = y2;
i = point->time + 1;
}
bool lastLap = false;
if(mapLap)
if(ds.getRunNode()->run->last_lap_index == mapLap->index)
lastLap = true;
if((!mapLap || lastLap) && wStart)
{
// load the end symbol
QPixmap qpx(KIcon(QString("wtarget")).pixmap(16));
paint.drawPixmap(x2, y2 - 16, qpx);
}
paint.end();
if(curTab == 0 && !ActivePrint)
ui_sportwatcherWidgetBase.imgMap->setPixmap(pmMap);
else if(ActivePrint)
pmPrMap = pmMap;
else
ui_sportwatcherWidgetBase.grMap->setPixmap(pmMap);
QApplication::restoreOverrideCursor();
}
void sportwatcherWidget::kcbCurveSlot(int)
{
DIRTY = true;
showCurves();
DIRTY = false;
}
void sportwatcherWidget::tabViewSlot(int tab)
{
curTab = tab;
if(tab == 0 && tabDirt0)
{
DIRTY = true;
showLaps();
showTrack();
showCurves();
DIRTY = false;
tabDirt0 = false;
}
else if(tab == 1 && tabDirt1)
{
DIRTY = true;
if(tabDirt0)
showLaps();
showTrack();
DIRTY = false;
tabDirt1 = false;
}
else if(tab == 2 && tabDirt2)
{
DIRTY = true;
if(tabDirt0)
showLaps();
setMouseTracking(true);
ui_sportwatcherWidgetBase.tabView->setMouseTracking(true);
ui_sportwatcherWidgetBase.grHR->setMouseTracking(true);
ui_sportwatcherWidgetBase.grElevation->setMouseTracking(true);
ui_sportwatcherWidgetBase.grSpeed->setMouseTracking(true);
showThreeCurve();
tabDirt2 = false;
DIRTY = false;
}
}
void sportwatcherWidget::showCurves()
{
showCurves(mapLap);
}
void sportwatcherWidget::showCurves(LAP *lap)
{
QPainter paint;
int width, height;
int i, secs, cuType;
int lineHeight, margin_left, margin_right, margin_bottom;
int x1, y1, x2, y2; // Coordinates
bool meter;
double maxHeight, minHeight, maxSpeed, minSpeed;
int maxHr, minHr, rh;
POINT *point;
RUN_NODE *rn;
LAP *lp;
double w_tick, h_tick; // Number of pixels one "tick" has;
// This depends on the width and height
// of the image.
// First we draw a grid based on the min and max
// values detected in the function showLap(). In case
// all values are 0, we exit here.
if(min_hr == 0 && max_hr == 0 && min_height == 0.0 && max_height == 0.0)
return;
if(!DIRTY || curTab != 0)
return;
// Look up, what curves we should draw
cuType = ui_sportwatcherWidgetBase.kcbCurveTypes->currentIndex();
// Get the dimensions of the available draw area
width = ui_sportwatcherWidgetBase.imgProfile->width() - 2;
height = ui_sportwatcherWidgetBase.imgProfile->height();
pmProfile = QPixmap(width, height);
paint.begin(&pmProfile);
// we need a somewhat bigger area to draw our curves than
// we have with the real min and max values.
if(max_height > 0.0)
{
double add = (max_height - min_height) / 100.0 * 5.0; // Percent
maxHeight = max_height + add;
minHeight = min_height - add;
if(minHeight < 0.0) // make sure, we are not too deep
minHeight = 0.0;
}
else
maxHeight = minHeight = 0.0;
if(max_speed > 0.0)
{
double add = (max_speed - min_speed) / 100.0 * 5.0; // Percent
maxSpeed = max_speed + add;
minSpeed = min_speed - add;
if(minSpeed < 0.0) // make sure, we are not too deep
minSpeed = 0.0;
}
else
maxSpeed = minSpeed = 0.0;
if(max_hr > 0)
{
maxHr = max_hr + 10;
minHr = min_hr - 10;
if(minHr < 0)
minHr = 0;
}
else
maxHr = minHr = 0;
// Define colors
QColor background(220, 220, 220); // Background of graphic
QColor mark(255, 255, 255); // Lines inside curve area
QColor hlight(180, 180, 180); // area of current lap
// hlight.setAlpha(128); // 50% transparent
QColor frame(0, 0, 0); // Text and borders
QColor barcol(151, 190, 13); // heart rate
QColor barcol2(190, 151, 13); // height over NN
QColor red(220, 128, 128); // speed
QColor blue(0, 0, 240);
QFont fntNormal("Helvetica");
// QFont fntBold("Helvetica", 10, QFont::Bold);
fntNormal.setPixelSize(10);
fntNormal.setStyleHint(QFont::Helvetica);
// fntBold.setPixelSize(10);
// fntBold.setStyleHint(QFont::Helvetica);
// Calculate ticks
margin_left = 52;
margin_right = 40;
margin_bottom = 12;
lineHeight = 10;
rh = height - margin_bottom - 1;
w_tick = (double)(width - (margin_left + margin_right)) / (max_time + ds.getPauseTime()); // 1 tick = 1 second
if(cuType == 1) // Speed and heart rate?
{
if((maxSpeed - minSpeed) > (double)(maxHr - minHr))
{
h_tick = (double)rh / (maxSpeed - minSpeed); // 1 tick = 1 km/h
meter = true;
}
else
{
h_tick = (double)rh / ((double)maxHr - (double)minHr); // 1 tick = 1 bpm
meter = false;
}
}
else if(cuType == 2) // Elevation and speed?
{
if((maxHeight - minHeight) > (double)(maxHr - minHr))
{
h_tick = (double)rh / (maxHeight - minHeight); // 1 tick = 1 meter
meter = true;
}
else
{
h_tick = (double)rh / (maxSpeed - minSpeed); // 1 tick = 1 km/h
meter = false;
}
}
else // Elevation and heart rate
{
if((maxHeight - minHeight) > (double)(maxHr - minHr))
{
h_tick = (double)rh / (maxHeight - minHeight); // 1 tick = 1 meter
meter = true;
}
else
{
h_tick = (double)rh / ((double)maxHr - (double)minHr); // 1 tick = 1 bpm
meter = false;
}
}
// Fill background with background colors
paint.fillRect(0, 0, width + 4, height + 4, background);
// Draw a grid with markers at every 10 minutes
paint.setPen(QPen(frame, 1, Qt::SolidLine));
// Bottom border line
x1 = margin_left;
y1 = height - margin_bottom;
x2 = width - margin_right;
y2 = y1;
paint.drawLine(x1, y1, x2, y2);
// Left border line
x1 = x2 = margin_left;
y1 = 2;
y2 = height - margin_bottom;
paint.drawLine(x1, y1, x2, y2);
// right border line
x1 = x2 = width - margin_right;
paint.drawLine(x1, y1, x2, y2);
// Draw some darker lines to show the laps, if we have one
// and, in case we have a given lap, we fill the area.
QDateTime *qt;
QTime zeit = StartTime.time();
rn = ds.getRunNode();
paint.setPen(QPen(hlight, 1, Qt::SolidLine));
for(i = rn->run->first_lap_index; (unsigned int)i <= rn->run->last_lap_index; i++)
{
if((lp = ds.getLap(i)) == NULL)
continue;
qt = garmin_dtime(lp->start_time);
secs = zeit.secsTo(qt->time());
delete qt;
x1 = secs * w_tick + margin_left + 1;
if(lap && lp->start_time == lap->start_time)
paint.fillRect(x1, 2, (int)((double)lap->total_time / 100.0 * w_tick), height - margin_bottom - 2, hlight);
else
paint.drawLine(x1, 2, x1, height - margin_bottom);
}
// Grid vertical
paint.setPen(QPen(frame, 1, Qt::SolidLine));
paint.setFont(fntNormal);
paint.drawText(margin_left - 20, height - lineHeight, 40, lineHeight, Qt::AlignCenter, QString("00:00"));
paint.save();
paint.rotate(270);
if(cuType == 1)
paint.setPen(QPen(red, 1, Qt::SolidLine));
else
paint.setPen(QPen(barcol, 1, Qt::SolidLine));
// Information on left side
if(cuType == 0)
paint.drawText((height + 4) * -1, 3, height - 2, lineHeight, Qt::AlignCenter, i18n("Elevation (%1)").arg((Units == 1) ? "ft" : "m"));
else if(cuType == 1)
paint.drawText((height + 4) * -1, 3, height - 2, lineHeight, Qt::AlignCenter, i18n("Speed (%1)").arg((Units == 1) ? "mph" : "km/h"));
else
paint.drawText((height + 4) * -1, 3, height - 2, lineHeight, Qt::AlignCenter, i18n("Elevation (%1)").arg((Units == 1) ? "ft" : "m"));
if(cuType == 2)
paint.setPen(QPen(red, 1, Qt::SolidLine));
else
paint.setPen(QPen(blue, 1, Qt::SolidLine));
// Information on right side
if(cuType < 2)
paint.drawText((height + 4) * -1, width - 1 - lineHeight, height - 2, lineHeight, Qt::AlignCenter, i18n("Heart Rate (bpm)"));
else
paint.drawText((height + 4) * -1, width - 1 - lineHeight, height - 2, lineHeight, Qt::AlignCenter, i18n("Speed (%1)").arg((Units == 1) ? "mph" : "km/h"));
paint.restore();
paint.setPen(QPen(mark, 1, Qt::SolidLine));
// Draw the time scale on the bottom of the graphic
for(i = 0; (unsigned int)i < (max_time + ds.getPauseTime()); i++)
{
if(i > 0 && !(i % 600)) // every 10 minutes
{
x1 = x2 = margin_left + w_tick * i;
if(x1 == (width - margin_right))
continue;
y1 = 2;
y2 = height - margin_bottom;
paint.drawLine(x1, y1, x2, y2);
QTime tm(0, 0, 0);
tm = tm.addSecs(i);
paint.setPen(QPen(frame, 1, Qt::SolidLine));
// paint.drawText(x1 - 25, height - lineHeight, 50, lineHeight, Qt::AlignCenter, tm.toString((i >= 3600) ? "hh:mm:ss" : "mm:ss"));
paint.drawText(x1 - 25, height - lineHeight, 50, lineHeight, Qt::AlignCenter, kl->formatTime(tm, (i >= 3600) ? true : false));
paint.setPen(QPen(mark, 1, Qt::SolidLine));
}
}
// This is the total time, with pauses included, at the lower right
// corner of the graphic.
QTime tm(0, 0, 0);
QString qs;
tm = tm.addSecs(max_time + ds.getPauseTime());
paint.setPen(QPen(frame, 1, Qt::SolidLine));
// paint.drawText(width - margin_right - 25, height - lineHeight, 50, lineHeight, Qt::AlignCenter, tm.toString((max_time >= 3600) ? "hh:mm:ss" : "mm:ss"));
paint.drawText(width - margin_right - 25, height - lineHeight, 50, lineHeight, Qt::AlignCenter, kl->formatTime(tm, (max_time >= 3600) ? true : false));
// Draw the minimal elevation, speed and/or heart rate
if(max_height > 0.0 || max_speed > 0.0)
{
// left side
if(cuType == 1)
{
paint.setPen(QPen(red, 1, Qt::SolidLine));
paint.drawText(12, height - margin_bottom - lineHeight / 2, margin_left - 14, lineHeight, Qt::AlignRight, qs.sprintf("%.0f", minSpeed));
}
else
{
paint.setPen(QPen(barcol, 1, Qt::SolidLine));
paint.drawText(12, height - margin_bottom - lineHeight / 2, margin_left - 14, lineHeight, Qt::AlignRight, qs.sprintf("%.0f", (Units == 1) ? minHeight / 0.304 : minHeight));
}
}
if(max_hr > 0 || max_speed > 0.0)
{
// right side
if(cuType == 2)
{
paint.setPen(QPen(red, 1, Qt::SolidLine));
paint.drawText(width - margin_right + 2, height - margin_bottom - lineHeight / 2, margin_right - 14, lineHeight, Qt::AlignLeft, qs.sprintf("%.0f", minSpeed));
}
else
{
paint.setPen(QPen(blue, 1, Qt::SolidLine));
paint.drawText(width - margin_right + 2, height - margin_bottom - lineHeight / 2, margin_right - 14, lineHeight, Qt::AlignLeft, qs.sprintf("%d", minHr));
}
}
paint.setPen(QPen(mark, 1, Qt::SolidLine));
// Grid horizontal
int factor = 0;
int target = 0;
if(cuType == 0) // Elevation and heart rate
{
factor = (meter) ? (maxHeight - minHeight) / (rh / 12) : (maxHr - minHr) / (rh / 12);
target = (meter) ? (int)(maxHeight - minHeight) : (maxHr - minHr);
}
else if(cuType == 1) // Speed and heart rate
{
factor = (meter) ? (maxSpeed - minSpeed) / (rh / 12) : (maxHr - minHr) / (rh / 12);
target = (meter) ? (int)(maxSpeed - minSpeed) : (maxHr - minHr);
}
else // Elevation and speed
{
factor = (meter) ? (maxHeight - minHeight) / (rh / 12) : (maxSpeed - minSpeed) / (rh / 12);
target = (meter) ? (int)(maxHeight - minHeight) : (int)(maxSpeed - minSpeed);
}
// To prevent a division by zero error, we check the <factor>
if(factor == 0)
factor = 1;
// Beside the horizontal part of the grid, we draw the scale on the
// left and the right side.
int oldy = height;
for(i = 0; i < target; i++)
{
if(i > 0 && !(i % factor))
{
x1 = margin_left + 1;
x2 = width - margin_right - 1;
y1 = y2 = rh - h_tick * i;
if(y1 < 12)
break;
paint.drawLine(x1, y1, x2, y2);
if(y1 < (oldy - lineHeight))
{
if(meter)
{
paint.setPen(QPen(barcol, 1, Qt::SolidLine));
// left side
if(cuType == 1)
{
paint.setPen(QPen(red, 1, Qt::SolidLine));
paint.drawText(12, y1 - lineHeight / 2, margin_left - 14, lineHeight, Qt::AlignRight, qs.sprintf("%.1f", minSpeed + i));
}
else
paint.drawText(12, y1 - lineHeight / 2, margin_left - 14, lineHeight, Qt::AlignRight, qs.sprintf("%.0f", (Units == 1) ? (minHeight + i) / 0.304 : minHeight + i));
// right side
if(maxHr > 0 && cuType != 2)
{
double hrscale = (double)(maxHr - minHr) / (double)target;
paint.setPen(QPen(blue, 1, Qt::SolidLine));
paint.drawText(width - margin_right + 2, y1 - lineHeight / 2, margin_right - 14, lineHeight, Qt::AlignLeft, qs.sprintf("%d", (int)((double)minHr + hrscale * (double)i)));
}
else
{
double spscale = (maxSpeed - minSpeed) / (double)target;
if(cuType == 2)
paint.setPen(QPen(red, 1, Qt::SolidLine));
else
paint.setPen(QPen(blue, 1, Qt::SolidLine));
paint.drawText(width - margin_right + 2, y1 - lineHeight / 2, margin_right - 14, lineHeight, Qt::AlignLeft, qs.sprintf("%.1f", (minSpeed + spscale * (double)i)));
}
}
else
{
// right side
if(cuType == 2)
{
paint.setPen(QPen(red, 1, Qt::SolidLine));
paint.drawText(width - margin_right + 2, y1 - lineHeight / 2, margin_right - 14, lineHeight, Qt::AlignLeft, qs.sprintf("%.1f", minSpeed + i));
}
else
{
paint.setPen(QPen(blue, 1, Qt::SolidLine));
paint.drawText(width - margin_right + 2, y1 - lineHeight / 2, margin_right - 14, lineHeight, Qt::AlignLeft, qs.sprintf("%d", minHr + i));
}
// left side
if((cuType == 0 || cuType == 2) && max_height > 0)
{
double hrscale = (maxHeight - minHeight) / (double)target;
paint.setPen(QPen(barcol, 1, Qt::SolidLine));
paint.drawText(12, y1 - lineHeight / 2, margin_left - 14, lineHeight, Qt::AlignRight, qs.sprintf("%.0f", minHeight + hrscale * (double)i));
}
else if(max_speed > 0 && cuType == 1)
{
double hrscale = (maxSpeed - minSpeed) / (double)target;
paint.setPen(QPen(red, 1, Qt::SolidLine));
paint.drawText(12, y1 - lineHeight / 2, margin_left - 14, lineHeight, Qt::AlignRight, qs.sprintf("%.1f", minSpeed + hrscale * (double)i));
}
}
paint.setPen(QPen(mark, 1, Qt::SolidLine));
oldy = y1;
}
}
}
// To make our graphics more beautiful, we draw lines for the
// heart rate limits and the average heart rate.
if(max_hr > 0 && cuType != 2)
{
int ay1, ay2, ay3, ay4, ay5;
x1 = margin_left + 1;
x2 = width - margin_right - 1;
if(meter)
{
double hrscale = rh / (double)(maxHr - minHr);
ay1 = (double)rh - (double)(lower1 - minHr) * hrscale;
ay2 = (double)rh - (double)(lower2 - minHr) * hrscale;
ay3 = (double)rh - (double)(lower3 - minHr) * hrscale;
ay4 = (double)rh - (double)(upper3 - minHr) * hrscale;
ay5 = (double)rh - (double)(avg_hr - minHr) * hrscale;
}
else
{
ay1 = (double)rh - (double)(lower1 - minHr) * h_tick;
ay2 = (double)rh - (double)(lower2 - minHr) * h_tick;
ay3 = (double)rh - (double)(lower3 - minHr) * h_tick;
ay4 = (double)rh - (double)(upper3 - minHr) * h_tick;
ay5 = (double)rh - (double)(avg_hr - minHr) * h_tick;
}
paint.setPen(QPen(barcol2, 1, Qt::DashLine)); // color for limits
if(lower1 > minHr && lower1 < maxHr)
paint.drawLine(x1, ay1, x2, ay1);
if(lower2 > minHr && lower2 < maxHr)
paint.drawLine(x1, ay2, x2, ay2);
if(lower3 > minHr && lower3 < maxHr)
paint.drawLine(x1, ay3, x2, ay3);
if(upper3 > minHr && upper3 < maxHr)
paint.drawLine(x1, ay4, x2, ay4);
paint.setPen(QPen(red, 1, Qt::DashDotLine)); // color for average heart rate
if(avg_hr > minHr && avg_hr < maxHr)
paint.drawLine(x1, ay5, x2, ay5);
}
// Now we have a grid and we've done the scaling.
// This is the point where we draw the curves itself.
// We use different colors to draw the lines:
//
// Green: Elevation
// Red: Speed
// Blue Heart Rate
//
x1 = x2 = y1 = y2 = 0;
int hy1, hy2, hx1, hx2;
int sy1, sy2, sx1, sx2;
hy1 = hy2 = hx1 = hx2 = 0;
sy1 = sy2 = sx1 = sx2 = 0;
int hEc = 0;
i = 0;
AVGHEIGHT *avgHakt, *avgHfirst, *avgHlast, *avgHeight = 0;
avgHfirst = avgHlast = 0;
// To even the surface lines, we store every altitude in the
// memory, by building a chain. Then, if the user has set in the
// settings (Contour == true), we will even the line by calculating
// the average of 10 messure points and setting every value to the
// average, who is up or down more than 2 meters from the average.
while((point = ds.getPoint(i)) != 0)
{
if(point->alt > 20000.0 || point->alt < -1000.0)
{
i++;
continue;
}
if(!avgHeight)
{
avgHeight = new AVGHEIGHT;
avgHeight->alt = point->alt;
avgHeight->pos = hEc;
avgHeight->prev = 0;
avgHeight->next = 0;
avgHakt = avgHeight;
avgHfirst = avgHeight;
}
else
{
avgHakt = new AVGHEIGHT;
avgHakt->alt = point->alt;
avgHakt->pos = hEc;
avgHakt->next = 0;
avgHakt->prev = avgHeight;
avgHeight->next = avgHakt;
avgHeight = avgHakt;
}
// FIXME: Currently we can not draw below 0 meters, because the
// base line is always 0!
if(avgHakt->alt < minHeight)
avgHakt->alt = minHeight;
hEc++;
i++;
}
avgHlast = avgHeight;
// If wanted, even the lines
if(Contour && hEc > 0 && cuType != 0)
{
double alt[100], avg, avg1, avg2, avg3, avg4;
int a, pos;
for(i = 0; i < (hEc + 100); i += 100)
{
avg = avg1 = avg2 = avg3 = avg4 = 0.0;
pos = 0;
for(a = 0; a < 100; a++)
{
alt[a] = getAvgAlt(avgHfirst, i + a);
avg += alt[a];
if(a < 25)
avg1 += alt[a];
else if(a < 50)
avg2 += alt[a];
else if(a < 75)
avg3 += alt[a];
else
avg4 += alt[a];
}
if((i + 100) >= hEc)
avg /= (double)(hEc - i) + 1.0;
else
avg /= 100.0;
for(a = 0; a < 100; a++)
{
if((avgHakt = getAvgPtr(avgHfirst, i + a)) != 0)
{
if((avgHakt->alt - avg) > 2 || (avgHakt->alt - avg) < -2)
avgHakt->alt = avg;
}
}
}
}
// plot the elevation, speed and/or heart rate. Depends on <cuType>)
i = 0;
int j = 0;
POINT *oldPoint = 0;
double speed = 0.0; // calculated speed
bool pause = false; // filter pause out of speed
unsigned long t1, t2;
t1 = t2 = 0;
while((point = ds.getPoint(i)) != 0)
{
if(!oldPoint)
oldPoint = point;
// calculate the y position based on the time
qt = garmin_dtime(point->time);
secs = zeit.secsTo(qt->time());
delete qt;
x2 = secs * w_tick + margin_left + 1;
hx2 = x2;
sx2 = x2;
if(x1 == 0)
x1 = x2;
if(hx1 == 0)
hx1 = hx2;
if(sx1 == 0)
sx1 = sx2;
// The speed is not very exact, because smallest time is
// one second. This allows a maximum error of 99 hundredths
// of a second, what is very close to one second. Because of
// this, speed seems to hop for every messure point. This
// looks ugly, but currently I don't know how to make it
// better.
if(cuType == 1 || cuType == 2) // Draw speed?
{
double dist;
double sc;
if(!pause && point->distance > 1.0e10)
{
pause = true;
t1 = point->time;
}
else if(pause)
{
pause = false;
t2 = point->time;
i += 2;
continue;
}
if(point->distance >= 0.1 && point->distance < 1.0e10)
{
dist = point->distance - oldPoint->distance;
sc = point->time - oldPoint->time;
LAP *runde = ds.getLapT(point->time);
if(t2 > t1)
{
sc -= t2 - t1;
if(sc <= 0.0)
sc = 1.0; // at least 1 second!
}
speed = (dist / sc) * 3.6;
if(runde && runde->max_speed > 0.0 && speed > (runde->max_speed * 3.6))
speed = runde->max_speed * 3.6;
if(Units == 1)
speed /= 1.609344;
if(speed < minSpeed || speed > 400.0)
speed = minSpeed;
if((meter && cuType == 1) || (!meter && cuType == 2))
y2 = (double)rh - (speed - minSpeed) * h_tick;
else
{
double hrscale = rh / (maxSpeed - minSpeed);
y2 = (double)rh - (speed - minSpeed) * hrscale;
}
if(y1 == 0)
y1 = y2;
paint.setPen(QPen(red, 1, Qt::SolidLine));
paint.drawLine(x1, y1, x2, y2);
y1 = y2;
x1 = x2;
t1 = t2 = 0;
oldPoint = point;
}
}
if(cuType == 0 || cuType == 2) // Draw elevation?
{
if(point->alt < 20000.0 && point->alt > -1000.0)
{
double alt = getAvgAlt(avgHfirst, j);
j++;
if(meter)
sy2 = (double)rh - (alt - minHeight) * h_tick;
else
{
double hrscale = rh / (maxHeight - minHeight);
sy2 = (double)rh - (alt - minHeight) * hrscale;
}
if(sy1 == 0)
sy1 = sy2;
paint.setPen(QPen(barcol, 1, Qt::SolidLine));
paint.drawLine(sx1, sy1, sx2, sy2);
sy1 = sy2;
sx1 = sx2;
}
}
if(point->heart_rate > 0 && cuType < 2) // Draw heart rate?
{
if(meter)
{
double hrscale = rh / (double)(maxHr - minHr);
hy2 = (double)rh - (double)(point->heart_rate - minHr) * hrscale;
}
else
hy2 = (double)rh - (double)(point->heart_rate - minHr) * h_tick;
if(hy1 == 0)
hy1 = hy2;
paint.setPen(QPen(blue, 1, Qt::SolidLine));
paint.drawLine(hx1, hy1, hx2, hy2);
hy1 = hy2;
hx1 = hx2;
}
i++;
}
paint.end();
ui_sportwatcherWidgetBase.imgProfile->setPixmap(pmProfile);
// free the chain of altitudes
avgHakt = avgHfirst;
while(avgHakt)
{
avgHeight = avgHakt->next;
delete avgHakt;
avgHakt = avgHeight;
}
DIRTY = false;
}
void sportwatcherWidget::showThreeCurve(int pw, int ph)
{
QPainter ptHR, ptElevation, ptSpeed;
int width, height, wdHR, htHR, wdElev, htElev, wdSpeed, htSpeed;
int i, secs;
int lineHeight, margin_left, margin_right, margin_bottom;
int x1, y1, x2, y2; // Coordinates
double maxHeight, minHeight, maxSpeed, minSpeed;
int maxHr, minHr, rh, rhHR, rhElev, rhSpeed;
POINT *point;
RUN_NODE *rn;
LAP *lp;
double wtiHR, htiHR, wtiElev, htiElev, wtiSpeed, htiSpeed;
double w_tick, h_tick; // Number of pixels one "tick" has;
// This depends on the width and height
// of the image.
// First we draw a grid based on the min and max
// values detected in the function showLap(). In case
// all values are 0, we exit here.
if(min_hr == 0 && max_hr == 0 && min_height == 0.0 && max_height == 0.0)
return;
if(!ActivePrint && (!DIRTY || curTab != 2))
return;
w_tick = h_tick = 0.0;
rh = 0;
width = height = 0;
// Get the dimensions of the available draw area
// First for heart rate
if(!ActivePrint)
{
wdHR = ui_sportwatcherWidgetBase.grHR->width() - 2;
htHR = ui_sportwatcherWidgetBase.grHR->height();
pmHR = QPixmap(wdHR, htHR);
// Then for elevation
wdElev = ui_sportwatcherWidgetBase.grElevation->width() - 2;
htElev = ui_sportwatcherWidgetBase.grElevation->height();
pmElevation = QPixmap(wdElev, htElev);
// And at last for speed
wdSpeed = ui_sportwatcherWidgetBase.grSpeed->width() - 2;
htSpeed = ui_sportwatcherWidgetBase.grSpeed->height();
pmSpeed = QPixmap(wdSpeed, htSpeed);
// Initialize QPainter
ptHR.begin(&pmHR);
ptElevation.begin(&pmElevation);
ptSpeed.begin(&pmSpeed);
}
else if(ActivePrint && pw > 0 && ph > 0)
{
wdHR = wdElev = wdSpeed = pw;
htHR = htElev = htSpeed = ph;
prHR = prElevation = prSpeed = QPixmap(pw, ph);
ptHR.begin(&prHR);
ptElevation.begin(&prElevation);
ptSpeed.begin(&prSpeed);
}
else
return;
// we need a somewhat bigger area to draw our curves than
// we have with the real min and max values.
if(max_height > 0.0)
{
double add = (max_height - min_height) / 100.0 * 5.0; // Percent
maxHeight = max_height + add;
minHeight = min_height - add;
if(minHeight < 0.0) // make sure, we are not too deep
minHeight = 0.0;
}
else
maxHeight = minHeight = 0.0;
if(max_speed > 0.0)
{
double add = (max_speed - min_speed) / 100.0 * 5.0; // Percent
maxSpeed = max_speed + add;
minSpeed = min_speed - add;
if(minSpeed < 0.0) // make sure, we are not too deep
minSpeed = 0.0;
}
else
maxSpeed = minSpeed = 0.0;
if(max_hr > 0)
{
maxHr = max_hr + 10;
minHr = min_hr - 10;
if(minHr < 0)
minHr = 0;
}
else
maxHr = minHr = 0;
// Define colors
QColor background(220, 220, 220); // Background of graphic
QColor mark(255, 255, 255); // Lines inside curve area
QColor hlight(180, 180, 180); // area of current lap
hlight.setAlpha(128); // 50% transparent
QColor frame(0, 0, 0); // Text and borders
QColor barcol(151, 190, 13); // heart rate
QColor barcol2(190, 151, 13); // height over NN
QColor red(220, 128, 128); // speed
QColor blue(0, 0, 240);
QFont fntNormal("Helvetica");
// QFont fntBold("Helvetica", 10, QFont::Bold);
fntNormal.setPixelSize(10);
fntNormal.setStyleHint(QFont::Helvetica);
// fntBold.setPixelSize(10);
// fntBold.setStyleHint(QFont::Helvetica);
// Calculate ticks
margin_left = 1;
margin_right = 40;
margin_bottom = 12;
lineHeight = 10;
// rh = height - margin_bottom - 1;
// Calculate the ticks for width and height for every draw area
for(i = 0; i < 3; i++)
{
if(i == 2) // Speed?
{
rhSpeed = htSpeed - margin_bottom - 1;
wtiSpeed = (double)(wdSpeed - (margin_left + margin_right)) / (max_time + ds.getPauseTime()); // 1 tick = 1 second
htiSpeed = (double)rhSpeed / (maxSpeed - minSpeed); // 1 tick = 1 km/h
}
else if(i == 1) // Elevation?
{
rhElev = htElev - margin_bottom - 1;
wtiElev = (double)(wdElev - (margin_left + margin_right)) / (max_time + ds.getPauseTime()); // 1 tick = 1 second
htiElev = (double)rhElev / (maxHeight - minHeight); // 1 tick = 1 meter
}
else // heart rate
{
rhHR = htHR - margin_bottom - 1;
wtiHR = (double)(wdHR - (margin_left + margin_right)) / (max_time + ds.getPauseTime()); // 1 tick = 1 second
htiHR = (double)rhHR / ((double)maxHr - (double)minHr); // 1 tick = 1 bpm
}
}
// Fill background with background colors
ptHR.fillRect(0, 0, wdHR + 4, htHR + 4, background);
ptElevation.fillRect(0, 0, wdElev + 4, htElev + 4, background);
ptSpeed.fillRect(0, 0, wdSpeed + 4, htSpeed + 4, background);
// Draw a grid with markers at every 10 minutes
ptHR.setPen(QPen(frame, 1, Qt::SolidLine));
ptElevation.setPen(QPen(frame, 1, Qt::SolidLine));
ptSpeed.setPen(QPen(frame, 1, Qt::SolidLine));
// Bottom border line
x1 = margin_left;
y1 = htHR - margin_bottom;
x2 = wdHR - margin_right;
y2 = y1;
ptHR.drawLine(x1, y1, x2, y2);
y1 = htElev - margin_bottom;
x2 = wdElev - margin_right;
y2 = y1;
ptElevation.drawLine(x1, y1, x2, y2);
y1 = htSpeed - margin_bottom;
x2 = wdSpeed - margin_right;
y2 = y1;
ptSpeed.drawLine(x1, y1, x2, y2);
// Left border line
x1 = x2 = margin_left;
y1 = 2;
y2 = htHR - margin_bottom;
ptHR.drawLine(x1, y1, x2, y2);
y2 = htElev - margin_bottom;
ptElevation.drawLine(x1, y1, x2, y2);
y2 = htSpeed - margin_bottom;
ptSpeed.drawLine(x1, y1, x2, y2);
// right border line
x1 = x2 = wdHR - margin_right;
ptHR.drawLine(x1, y1, x2, y2);
x1 = x2 = wdElev - margin_right;
ptElevation.drawLine(x1, y1, x2, y2);
x1 = x2 = wdSpeed - margin_right;
ptSpeed.drawLine(x1, y1, x2, y2);
// Draw some darker lines to show the laps, if we have one
QDateTime *qt;
QTime zeit = StartTime.time();
rn = ds.getRunNode();
ptHR.setPen(QPen(hlight, 1, Qt::SolidLine));
ptElevation.setPen(QPen(hlight, 1, Qt::SolidLine));
ptSpeed.setPen(QPen(hlight, 1, Qt::SolidLine));
for(i = rn->run->first_lap_index; (unsigned int)i <= rn->run->last_lap_index; i++)
{
if((lp = ds.getLap(i)) == NULL)
continue;
qt = garmin_dtime(lp->start_time);
secs = zeit.secsTo(qt->time());
delete qt;
// heart rate
x1 = secs * wtiHR + margin_left + 1;
ptHR.drawLine(x1, 2, x1, htHR - margin_bottom);
// Elevation
x1 = secs * wtiElev + margin_left + 1;
ptElevation.drawLine(x1, 2, x1, htElev - margin_bottom);
// Speed
x1 = secs * wtiSpeed + margin_left + 1;
ptSpeed.drawLine(x1, 2, x1, htSpeed - margin_bottom);
}
// Grid vertical
ptHR.setPen(QPen(frame, 1, Qt::SolidLine));
ptHR.setFont(fntNormal);
ptHR.drawText(margin_left, htHR - lineHeight, 40, lineHeight, Qt::AlignLeft, QString("0"));
ptElevation.setPen(QPen(frame, 1, Qt::SolidLine));
ptElevation.setFont(fntNormal);
ptElevation.drawText(margin_left, htElev - lineHeight, 40, lineHeight, Qt::AlignLeft, QString("0"));
ptSpeed.setPen(QPen(frame, 1, Qt::SolidLine));
ptSpeed.setFont(fntNormal);
ptSpeed.drawText(margin_left, htSpeed - lineHeight, 40, lineHeight, Qt::AlignLeft, QString("0"));
ptHR.save();
ptHR.rotate(270);
ptHR.setPen(QPen(blue, 1, Qt::SolidLine));
ptElevation.save();
ptElevation.rotate(270);
ptElevation.setPen(QPen(barcol, 1, Qt::SolidLine));
ptSpeed.save();
ptSpeed.rotate(270);
ptSpeed.setPen(QPen(red, 1, Qt::SolidLine));
// Information on right side
ptHR.drawText((htHR + 4) * -1, wdHR - 1 - lineHeight, htHR - 2, lineHeight, Qt::AlignCenter, i18n("Heart Rate (bpm)"));
ptElevation.drawText((htElev + 4) * -1, wdElev - 1 - lineHeight, htElev - 2, lineHeight, Qt::AlignCenter, i18n("Elevation (%1)").arg((Units == 1) ? "ft" : "m"));
ptSpeed.drawText((htSpeed + 4) * -1, wdSpeed - 1 - lineHeight, htSpeed - 2, lineHeight, Qt::AlignCenter, i18n("Speed (%1)").arg((Units == 1) ? "mph" : "km/h"));
// restore to normal
ptHR.restore();
ptHR.setPen(QPen(mark, 1, Qt::SolidLine));
ptElevation.restore();
ptElevation.setPen(QPen(mark, 1, Qt::SolidLine));
ptSpeed.restore();
ptSpeed.setPen(QPen(mark, 1, Qt::SolidLine));
// Draw the time scale on the bottom of the graphic
for(i = 0; (unsigned int)i < (max_time + ds.getPauseTime()); i++)
{
bool loop = false;
if(i > 0 && !(i % 600)) // every 10 minutes
{
for(int j = 0; j < 3; j++)
{
switch(j)
{
case 0: w_tick = wtiHR; width = wdHR; height = htHR; break;
case 1: w_tick = wtiElev; width = wdElev; height = htElev; break;
case 2: w_tick = wtiSpeed; width = wdSpeed; height = htSpeed; break;
}
x1 = x2 = margin_left + w_tick * i;
if(x1 == (width - margin_right - 25))
{
loop = true;
break;
}
y1 = 2;
y2 = height - margin_bottom;
QTime tm(0, 0, 0);
tm = tm.addSecs(i);
if(j == 0)
{
ptHR.drawLine(x1, y1, x2, y2);
ptHR.setPen(QPen(frame, 1, Qt::SolidLine));
ptHR.drawText(x1 - 25, height - lineHeight, 50, lineHeight, Qt::AlignCenter, kl->formatTime(tm, (i >= 3600) ? true : false));
ptHR.setPen(QPen(mark, 1, Qt::SolidLine));
}
else if(j == 1)
{
ptElevation.drawLine(x1, y1, x2, y2);
ptElevation.setPen(QPen(frame, 1, Qt::SolidLine));
ptElevation.drawText(x1 - 25, height - lineHeight, 50, lineHeight, Qt::AlignCenter, kl->formatTime(tm, (i >= 3600) ? true : false));
ptElevation.setPen(QPen(mark, 1, Qt::SolidLine));
}
else
{
ptSpeed.drawLine(x1, y1, x2, y2);
ptSpeed.setPen(QPen(frame, 1, Qt::SolidLine));
ptSpeed.drawText(x1 - 25, height - lineHeight, 50, lineHeight, Qt::AlignCenter, kl->formatTime(tm, (i >= 3600) ? true : false));
ptSpeed.setPen(QPen(mark, 1, Qt::SolidLine));
}
}
if(loop)
{
loop = false;
continue;
}
}
}
// This is the total time, with pauses included, at the lower right
// corner of the graphic.
QTime tm(0, 0, 0);
QString qs;
tm = tm.addSecs(max_time + ds.getPauseTime());
ptHR.setPen(QPen(frame, 1, Qt::SolidLine));
ptHR.drawText(wdHR - margin_right - 25, htHR - lineHeight, 50, lineHeight, Qt::AlignCenter, kl->formatTime(tm, (max_time >= 3600) ? true : false));
ptElevation.setPen(QPen(frame, 1, Qt::SolidLine));
ptElevation.drawText(wdElev - margin_right - 25, htElev - lineHeight, 50, lineHeight, Qt::AlignCenter, kl->formatTime(tm, (max_time >= 3600) ? true : false));
ptSpeed.setPen(QPen(frame, 1, Qt::SolidLine));
ptSpeed.drawText(wdSpeed - margin_right - 25, htSpeed - lineHeight, 50, lineHeight, Qt::AlignCenter, kl->formatTime(tm, (max_time >= 3600) ? true : false));
// Draw the minimal elevation, speed and heart rate
// Heart rate
ptHR.setPen(QPen(blue, 1, Qt::SolidLine));
ptHR.drawText(wdHR - margin_right + 2, htHR - margin_bottom - lineHeight / 2, margin_right - 14, lineHeight, Qt::AlignLeft, qs.sprintf("%d", minHr));
// Elevation
ptElevation.setPen(QPen(barcol, 1, Qt::SolidLine));
ptElevation.drawText(wdElev - margin_right + 2, htElev - margin_bottom - lineHeight / 2, margin_right - 14, lineHeight, Qt::AlignLeft, qs.sprintf("%.0f", (Units == 1) ? minHeight / 0.304 : minHeight));
// Speed
ptSpeed.setPen(QPen(red, 1, Qt::SolidLine));
ptSpeed.drawText(wdSpeed - margin_right + 2, htSpeed - margin_bottom - lineHeight / 2, margin_right - 14, lineHeight, Qt::AlignLeft, qs.sprintf("%.0f", minSpeed));
ptHR.setPen(QPen(mark, 1, Qt::SolidLine));
ptElevation.setPen(QPen(mark, 1, Qt::SolidLine));
ptSpeed.setPen(QPen(mark, 1, Qt::SolidLine));
// Grid horizontal
int factor = 0;
int target = 0;
for(int j = 0; j < 3; j++)
{
switch(j)
{
case 0: width = wdHR; height = htHR; w_tick = wtiHR; h_tick = htiHR; rh = rhHR;
factor = (maxHr - minHr) / (rhHR / 12);
target = (maxHr - minHr);
break;
case 1: width = wdElev; height = htElev; w_tick = wtiElev; h_tick = htiElev; rh = rhElev;
factor = (maxHeight - minHeight) / (rhElev / 12);
target = (int)(maxHeight - minHeight);
break;
case 2: width = wdSpeed; height = htSpeed; w_tick = wtiSpeed; h_tick = htiSpeed; rh = rhSpeed;
factor = (maxSpeed - minSpeed) / (rhSpeed / 12);
target = (int)(maxSpeed - minSpeed);
break;
}
// To prevent a division by zero error, we check the <factor>
if(factor == 0)
factor = 1;
// Beside the horizontal part of the grid, we draw the scale on the
// the right side too.
int oldy = height;
for(i = 0; i < target; i++)
{
if(i > 0 && !(i % factor))
{
x1 = margin_left + 1;
x2 = width - margin_right - 1;
y1 = y2 = rh - h_tick * i;
if(y1 < 12)
break;
switch(j)
{
case 0:
ptHR.drawLine(x1, y1, x2, y2);
ptHR.setPen(QPen(blue, 1, Qt::SolidLine));
ptHR.drawText(width - margin_right + 2, y1 - lineHeight / 2, margin_right - 14, lineHeight, Qt::AlignLeft, qs.sprintf("%d", minHr + i));
ptHR.setPen(QPen(mark, 1, Qt::SolidLine));
break;
case 1:
ptElevation.drawLine(x1, y1, x2, y2);
ptElevation.setPen(QPen(barcol, 1, Qt::SolidLine));
ptElevation.drawText(width - margin_right + 2, y1 - lineHeight / 2, margin_right - 14, lineHeight, Qt::AlignLeft, qs.sprintf("%.0f", (Units == 1) ? (minHeight + i) / 0.304 : minHeight + i));
ptElevation.setPen(QPen(mark, 1, Qt::SolidLine));
break;
case 2:
ptSpeed.drawLine(x1, y1, x2, y2);
ptSpeed.setPen(QPen(red, 1, Qt::SolidLine));
ptSpeed.drawText(width - margin_right + 2, y1 - lineHeight / 2, margin_right - 14, lineHeight, Qt::AlignLeft, qs.sprintf("%.1f", minSpeed + i));
ptSpeed.setPen(QPen(mark, 1, Qt::SolidLine));
break;
}
oldy = y1;
}
}
}
// To make our graphics more beautiful, we draw lines for the
// heart rate limits and the average heart rate.
if(max_hr > 0)
{
int ay1, ay2, ay3, ay4, ay5;
x1 = margin_left + 1;
x2 = wdHR - margin_right - 1;
ay1 = (double)rh - (double)(lower1 - minHr) * htiHR;
ay2 = (double)rh - (double)(lower2 - minHr) * htiHR;
ay3 = (double)rh - (double)(lower3 - minHr) * htiHR;
ay4 = (double)rh - (double)(upper3 - minHr) * htiHR;
ay5 = (double)rh - (double)(avg_hr - minHr) * htiHR;
ptHR.setPen(QPen(barcol2, 1, Qt::DashLine)); // color for limits
if(lower1 > minHr && lower1 < maxHr)
ptHR.drawLine(x1, ay1, x2, ay1);
if(lower2 > minHr && lower2 < maxHr)
ptHR.drawLine(x1, ay2, x2, ay2);
if(lower3 > minHr && lower3 < maxHr)
ptHR.drawLine(x1, ay3, x2, ay3);
if(upper3 > minHr && upper3 < maxHr)
ptHR.drawLine(x1, ay4, x2, ay4);
ptHR.setPen(QPen(red, 1, Qt::DashDotLine)); // color for average heart rate
if(avg_hr > minHr && avg_hr < maxHr)
ptHR.drawLine(x1, ay5, x2, ay5);
}
// Now we have a grid and we've done the scaling.
// This is the point where we draw the curves itself.
// We use different colors to draw the lines:
//
// Green: Elevation
// Red: Speed
// Blue Heart Rate
//
x1 = x2 = y1 = y2 = 0;
int hy1, hy2, hx1, hx2;
int sy1, sy2, sx1, sx2;
hy1 = hy2 = hx1 = hx2 = 0;
sy1 = sy2 = sx1 = sx2 = 0;
int hEc = 0;
i = 0;
AVGHEIGHT *avgHakt, *avgHfirst, *avgHlast, *avgHeight = 0;
avgHfirst = avgHlast = 0;
// To even the surface lines, we store every altitude in the
// memory, by building a chain. Then, if the user has set in the
// settings (Contour == true), we will even the line by calculating
// the average of 10 messure points and setting every value to the
// average, who is up or down more than 2 meters from the average.
while((point = ds.getPoint(i)) != 0)
{
if(point->alt > 20000.0 || point->alt < -1000.0)
{
i++;
continue;
}
if(!avgHeight)
{
avgHeight = new AVGHEIGHT;
avgHeight->alt = point->alt;
avgHeight->pos = hEc;
avgHeight->prev = 0;
avgHeight->next = 0;
avgHakt = avgHeight;
avgHfirst = avgHeight;
}
else
{
avgHakt = new AVGHEIGHT;
avgHakt->alt = point->alt;
avgHakt->pos = hEc;
avgHakt->next = 0;
avgHakt->prev = avgHeight;
avgHeight->next = avgHakt;
avgHeight = avgHakt;
}
// FIXME: Currently we can not draw below 0 meters, because the
// base line is always 0!
if(avgHakt->alt < minHeight)
avgHakt->alt = minHeight;
hEc++;
i++;
}
avgHlast = avgHeight;
// If wanted, even the lines
if(Contour && hEc > 0)
{
double alt[100], avg, avg1, avg2, avg3, avg4;
int a, pos;
for(i = 0; i < (hEc + 100); i += 100)
{
avg = avg1 = avg2 = avg3 = avg4 = 0.0;
pos = 0;
for(a = 0; a < 100; a++)
{
alt[a] = getAvgAlt(avgHfirst, i + a);
avg += alt[a];
if(a < 25)
avg1 += alt[a];
else if(a < 50)
avg2 += alt[a];
else if(a < 75)
avg3 += alt[a];
else
avg4 += alt[a];
}
if((i + 100) >= hEc)
avg /= (double)(hEc - i) + 1.0;
else
avg /= 100.0;
for(a = 0; a < 100; a++)
{
if((avgHakt = getAvgPtr(avgHfirst, i + a)) != 0)
{
if((avgHakt->alt - avg) > 2 || (avgHakt->alt - avg) < -2)
avgHakt->alt = avg;
}
}
}
}
// plot the elevation, speed and/or heart rate. Depends on <cuType>)
i = 0;
int j = 0;
POINT *oldPoint = 0;
double speed = 0.0; // calculated speed
bool pause = false; // filter pause out of speed
unsigned long t1, t2;
t1 = t2 = 0;
while((point = ds.getPoint(i)) != 0)
{
bool loop = false;
if(!oldPoint)
oldPoint = point;
// calculate the y position based on the time
qt = garmin_dtime(point->time);
secs = zeit.secsTo(qt->time());
delete qt;
for(int c = 0; c < 3; c++)
{
if(c == 0)
{
x2 = secs * wtiHR + margin_left + 1;
hx2 = x2;
sx2 = x2;
if(x1 == 0)
x1 = x2;
if(hx1 == 0)
hx1 = hx2;
if(sx1 == 0)
sx1 = sx2;
}
else if(c == 1)
{
x2 = secs * wtiElev + margin_left + 1;
hx2 = x2;
sx2 = x2;
if(x1 == 0)
x1 = x2;
if(hx1 == 0)
hx1 = hx2;
if(sx1 == 0)
sx1 = sx2;
}
else
{
x2 = secs * wtiSpeed + margin_left + 1;
hx2 = x2;
sx2 = x2;
if(x1 == 0)
x1 = x2;
if(hx1 == 0)
hx1 = hx2;
if(sx1 == 0)
sx1 = sx2;
}
// The speed is not very exact, because smallest time is
// one second. This allows a maximum error of 99 hundredths
// of a second, what is very close to one second. Because of
// this, speed seems to hop for every messure point. This
// looks ugly, but currently I don't know how to make it
// better.
if(c == 2) // Draw speed?
{
double dist;
double sc;
if(!pause && point->distance > 1.0e10)
{
pause = true;
t1 = point->time;
}
else if(pause)
{
pause = false;
t2 = point->time;
i += 2;
loop = true;
}
if(point->distance >= 0.1 && point->distance < 1.0e10)
{
dist = point->distance - oldPoint->distance;
sc = point->time - oldPoint->time;
LAP *runde = ds.getLapT(point->time);
if(t2 > t1)
{
sc -= t2 - t1;
if(sc <= 0.0)
sc = 1.0; // at least 1 second!
}
speed = (dist / sc) * 3.6;
if(runde && runde->max_speed > 0.0 && speed > (runde->max_speed * 3.6))
speed = runde->max_speed * 3.6;
if(Units == 1)
speed /= 1.609344;
if(speed < minSpeed || speed > 400.0)
speed = minSpeed;
y2 = (double)rh - (speed - minSpeed) * htiSpeed;
if(y1 == 0)
y1 = y2;
ptSpeed.setPen(QPen(red, 1, Qt::SolidLine));
ptSpeed.drawLine(x1, y1, x2, y2);
y1 = y2;
x1 = x2;
t1 = t2 = 0;
oldPoint = point;
}
}
if(c == 1) // Draw elevation?
{
if(point->alt < 20000.0 && point->alt > -1000.0)
{
double alt = getAvgAlt(avgHfirst, j);
j++;
sy2 = (double)rh - (alt - minHeight) * htiElev;
if(sy1 == 0)
sy1 = sy2;
ptElevation.setPen(QPen(barcol, 1, Qt::SolidLine));
ptElevation.drawLine(sx1, sy1, sx2, sy2);
sy1 = sy2;
sx1 = sx2;
}
}
if(point->heart_rate > 0 && c == 0) // Draw heart rate?
{
hy2 = (double)rh - (double)(point->heart_rate - minHr) * htiHR;
if(hy1 == 0)
hy1 = hy2;
ptHR.setPen(QPen(blue, 1, Qt::SolidLine));
ptHR.drawLine(hx1, hy1, hx2, hy2);
hy1 = hy2;
hx1 = hx2;
}
}
if(loop)
{
loop = false;
continue;
}
i++;
}
ptHR.end();
ptElevation.end();
ptSpeed.end();
if(!ActivePrint)
{
ui_sportwatcherWidgetBase.grHR->setPixmap(pmHR);
ui_sportwatcherWidgetBase.grElevation->setPixmap(pmElevation);
ui_sportwatcherWidgetBase.grSpeed->setPixmap(pmSpeed);
}
// free the chain of altitudes
avgHakt = avgHfirst;
while(avgHakt)
{
avgHeight = avgHakt->next;
delete avgHakt;
avgHakt = avgHeight;
}
DIRTY = false;
}
double sportwatcherWidget::getAvgAlt(AVGHEIGHT *avgHeight, int pos)
{
AVGHEIGHT *akt;
if(!avgHeight)
return 0.0;
akt = avgHeight;
while(akt)
{
if(akt->pos == pos)
return akt->alt;
akt = akt->next;
}
return 0.0;
}
AVGHEIGHT *sportwatcherWidget::getAvgPtr(AVGHEIGHT *avgHeight, int pos)
{
AVGHEIGHT *akt;
akt = avgHeight;
while(akt)
{
if(akt->pos == pos)
return akt;
akt = akt->next;
}
return 0;
}
void sportwatcherWidget::resizeEvent(QResizeEvent *e)
{
if(e->size() != e->oldSize())
DIRTY = true;
showTrack(zfactor);
showCurves();
tabDirt2 = true;
if(curTab == 2)
{
showThreeCurve();
tabDirt2 = false;
}
DIRTY = false;
}
void sportwatcherWidget::mouseMoveEvent(QMouseEvent *e)
{
QPoint pos(0, 0);
QPoint ev = ui_sportwatcherWidgetBase.imgMap->mapFrom(this, e->pos());
static QRect coord;
DIRTY = true;
if(curTab == 0)
{
if(!stateHand)
return;
if(ev.x() >= pos.x() &&
ev.y() >= pos.y() &&
ev.x() <= (pos.x() + ui_sportwatcherWidgetBase.imgMap->geometry().width()) &&
ev.y() <= (pos.y() + ui_sportwatcherWidgetBase.imgMap->geometry().height()))
{
if(lmbPressed == 1)
{
coord.setCoords(ev.x(), ev.y(), 0, 0);
lmbPressed = 0;
}
else
{
coord.setRight(ev.x());
coord.setBottom(ev.y());
}
if(lmbPressed == 2)
{
showTrack(zfactor, coord, mapLap);
lmbPressed = 0;
}
}
}
if(curTab == 2)
{
// look in which of the three QLabels the mouse is, if it is in
// one of them.
ev = ui_sportwatcherWidgetBase.grHR->mapFrom(this, e->pos());
if(ev.x() >= pos.x() &&
ev.y() >= pos.y() &&
ev.x() <= (pos.x() + ui_sportwatcherWidgetBase.grHR->geometry().width()) &&
ev.y() <= (pos.y() + ui_sportwatcherWidgetBase.grHR->geometry().height()))
{
drawGrHR(ev.x(), ev.y());
drawGrElev(ev.x(), -1);
drawGrSpeed(ev.x(), -1);
}
ev = ui_sportwatcherWidgetBase.grElevation->mapFrom(this, e->pos());
if(ev.x() >= pos.x() &&
ev.y() >= pos.y() &&
ev.x() <= (pos.x() + ui_sportwatcherWidgetBase.grElevation->geometry().width()) &&
ev.y() <= (pos.y() + ui_sportwatcherWidgetBase.grElevation->geometry().height()))
{
drawGrHR(ev.x(), -1);
drawGrElev(ev.x(), ev.y());
drawGrSpeed(ev.x(), -1);
}
ev = ui_sportwatcherWidgetBase.grSpeed->mapFrom(this, e->pos());
if(ev.x() >= pos.x() &&
ev.y() >= pos.y() &&
ev.x() <= (pos.x() + ui_sportwatcherWidgetBase.grSpeed->geometry().width()) &&
ev.y() <= (pos.y() + ui_sportwatcherWidgetBase.grSpeed->geometry().height()))
{
drawGrHR(ev.x(), -1);
drawGrElev(ev.x(), -1);
drawGrSpeed(ev.x(), ev.y());
}
}
DIRTY = false;
}
void sportwatcherWidget::mousePressEvent(QMouseEvent *e)
{
if(stateHand && e->button() == Qt::LeftButton)
lmbPressed = 1; // Left Mouse Button is pressed
else if(stateHand)
lmbPressed = 0; // Wrong button is pressed
if(stateGlas)
{
if(e->button() == Qt::LeftButton)
btGlasPlusSlot();
else if(e->button() == Qt::RightButton)
btGlasMinusSlot();
}
}
void sportwatcherWidget::mouseReleaseEvent(QMouseEvent *e)
{
if(stateHand && e->button() == Qt::LeftButton)
{
lmbPressed = 2; // Left Mouse Button was released
mouseMoveEvent(e);
}
}
/*
* Private functions to draw cross and/or a bar to reflect the mouse
* pointer on tab 2.
*/
void sportwatcherWidget::drawGrHR(int x, int y)
{
int width, height;
QPixmap pm = pmHR.copy(pmHR.rect());
QPainter paint;
width = ui_sportwatcherWidgetBase.grHR->width();
height = ui_sportwatcherWidgetBase.grHR->height();
ui_sportwatcherWidgetBase.grHR->setPixmap(pmHR);
if(x > (width - 40) || y > (height - 12) || x < 1)
{
ui_sportwatcherWidgetBase.grElevation->setPixmap(pmElevation);
ui_sportwatcherWidgetBase.grSpeed->setPixmap(pmSpeed);
return;
}
if(tabDirt2)
{
DIRTY = true;
showThreeCurve();
tabDirt2 = false;
DIRTY = false;
}
paint.begin(&pm);
QColor black(0, 0, 0);
black.setAlpha(128);
paint.setPen(QPen(black, 1, Qt::SolidLine));
// horizontal line, if y != -1
if(y >= 0)
paint.drawLine(2, y, width - 41, y);
// vertical line
paint.drawLine(x, 1, x, height - 13);
paint.end();
ui_sportwatcherWidgetBase.grHR->setPixmap(pm);
}
void sportwatcherWidget::drawGrElev(int x, int y)
{
int width, height;
QPixmap pm = pmElevation.copy(pmElevation.rect());
QPainter paint;
width = ui_sportwatcherWidgetBase.grElevation->width();
height = ui_sportwatcherWidgetBase.grElevation->height();
ui_sportwatcherWidgetBase.grElevation->setPixmap(pmElevation);
if(x > (width - 40) || y > (height - 12) || x < 1)
{
ui_sportwatcherWidgetBase.grHR->setPixmap(pmHR);
ui_sportwatcherWidgetBase.grSpeed->setPixmap(pmSpeed);
return;
}
if(tabDirt2)
{
DIRTY = true;
showThreeCurve();
tabDirt2 = false;
DIRTY = false;
}
paint.begin(&pm);
QColor black(0, 0, 0);
black.setAlpha(128);
paint.setPen(QPen(black, 1, Qt::SolidLine));
// horizontal line, if y != -1
if(y >= 0)
paint.drawLine(2, y, width - 41, y);
// vertical line
paint.drawLine(x, 1, x, height - 13);
paint.end();
ui_sportwatcherWidgetBase.grElevation->setPixmap(pm);
}
void sportwatcherWidget::drawGrSpeed(int x, int y)
{
int width, height;
QPixmap pm = pmSpeed.copy(pmSpeed.rect());
QPainter paint;
width = ui_sportwatcherWidgetBase.grSpeed->width();
height = ui_sportwatcherWidgetBase.grSpeed->height();
ui_sportwatcherWidgetBase.grSpeed->setPixmap(pmSpeed);
if(x > (width - 40) || y > (height - 12) || x < 1)
{
ui_sportwatcherWidgetBase.grHR->setPixmap(pmHR);
ui_sportwatcherWidgetBase.grElevation->setPixmap(pmElevation);
return;
}
if(tabDirt2)
{
DIRTY = true;
showThreeCurve();
tabDirt2 = false;
DIRTY = false;
}
paint.begin(&pm);
QColor black(0, 0, 0);
black.setAlpha(128);
paint.setPen(QPen(black, 1, Qt::SolidLine));
// horizontal line, if y != -1
if(y >= 0)
paint.drawLine(2, y, width - 41, y);
// vertical line
paint.drawLine(x, 1, x, height - 13);
paint.end();
ui_sportwatcherWidgetBase.grSpeed->setPixmap(pm);
}
/*
* Private functions to help decode the data
*/
QDateTime *sportwatcherWidget::garmin_dtime(uint32 t)
{
time_t tval;
struct tm tmval;
QTime ti;
QDate dt;
QDateTime *qt;
if(t == 0)
return new QDateTime(QDate(1900, 1, 1), QTime(0, 0, 0, 0));
tval = t + TIME_OFFSET;
localtime_r(&tval, &tmval);
qt = new QDateTime();
qt->setDate(QDate(tmval.tm_year + 1900, tmval.tm_mon + 1, tmval.tm_mday));
qt->setTime(QTime(tmval.tm_hour, tmval.tm_min, tmval.tm_sec, 0));
/* OK. Done. */
return qt;
}
bool sportwatcherWidget::writeTag(const QFile &fn, const QString &str, int indent)
{
QString qs;
char *p;
//QCString qcs;
int i;
if(indent > 0)
qs.fill(' ', indent * 3);
qs.append(str);
// qcs = qs.utf8();
// qstrcpy(p, qcs);
p = strdup(qs.toUtf8().data());
i = strlen(p);
if(write(fn.handle(), p, i) != i)
{
free(p);
return false;
}
free(p);
return true;
}
#if defined HAVE_GDAL
bool sportwatcherWidget::writeWMSTag(double llat, double llon, double rlat, double rlon, int width, int height)
{
QFile fl(MAP);
QString xml, s, srs, crs, styles, bSize, ext;
QDir dir = QDir::home();
QString path = dir.absolutePath();
int item, isrs;
double _llat, _llon, _rlat, _rlon;
bool offline, square;
if(!fl.open(QIODevice::ReadWrite | QIODevice::Truncate))
{
KMessageBox::error(this, i18n("Error opening or creating the WMS tag file!\nPlease check file name and/or permissions."));
return false;
}
KConfig cfg(QString("sportwatcher.rc"), KConfig::SimpleConfig);
KConfigGroup wms(&cfg, "WMS");
square = wms.readEntry("Square", false);
styles = wms.readEntry("Styles", QString(""));
xml = "<GDAL_WMS>\n";
xml += " <Service name=\"WMS\">\n";
xml += " <Version>1.1.1</Version>\n";
xml += " <ServerURL>" + wms.readEntry("ServerURL", "http://onearth.jpl.nasa.gov/wms.cgi") + "?</serverURL>\n";
isrs = wms.readEntry("SRS", 0);
_llon = llon;
_llat = llat;
_rlon = rlon;
_rlat = rlat;
offline = false;
switch(isrs)
{
case 0: srs = QString("EPSG:4326"); break;
case 1:
srs = QString("EPSG:31257");
offline = transCoords(&_llat, &_llon, &_rlat, &_rlon, 31257, width, height, square);
break;
case 2:
srs = QString("EPSG:31258");
offline = transCoords(&_llat, &_llon, &_rlat, &_rlon, 31258, width, height, square);
break;
case 3:
srs = QString("EPSG:31259");
offline = transCoords(&_llat, &_llon, &_rlat, &_rlon, 31259, width, height, square);
break;
case 4:
srs = QString("EPSG:31286");
offline = transCoords(&_llat, &_llon, &_rlat, &_rlon, 31286, width, height, square);
break;
case 5:
srs = QString("EPSG:31287");
offline = transCoords(&_llat, &_llon, &_rlat, &_rlon, 31287, width, height, square);
break;
case 6:
srs = QString("EPSG:31288");
offline = transCoords(&_llat, &_llon, &_rlat, &_rlon, 31288, width, height, square);
break;
case 7:
srs = QString("EPSG:900913");
offline = transCoords(&_llat, &_llon, &_rlat, &_rlon, 900913, width, height, square);
break;
case 8:
srs = QString("EPSG:3395");
offline = transCoords(&_llat, &_llon, &_rlat, &_rlon, 3395, width, height, square);
break;
default: srs = QString("EPSG:4326");
}
xml += " <SRS>" + srs + "</SRS>\n";
item = wms.readEntry("CRS", 0);
switch(item)
{
case 0: crs = QString("CRS:83"); break;
case 1: crs = QString("CRS:84"); break;
case 2: crs = QString("EPSG:4326"); break;
case 3: crs = QString("EPSG:31259"); break;
case 4: crs = QString("EPSG:31287"); break;
case 5: crs = QString("EPSG:900913"); break;
case 6: crs = QString("EPSG:3395"); break;
default: crs = QString("CRS:84"); break;
}
xml += " <CRS>" + crs + "</CRS>\n";
item = wms.readEntry("Image", 2);
xml += " <ImageFormat>image/";
switch(item)
{
case 0: xml += "gif"; ext = QString(".gif"); break;
case 1: xml += "jpeg"; ext = QString(".jpg"); break;
case 2: xml += "png"; ext = QString(".png"); break;
case 3: xml += "tiff"; ext = QString(".tif"); break;
default: xml += "png"; ext = QString(".png");
}
xml += "</ImageFormat>\n";
xml += " <Layers>" + wms.readEntry("Layer", QString("")) + "</Layers>\n";
if(!styles.isEmpty())
xml += " <Styles>" + styles + "</Styles>\n";
xml += " <BBoxOrder>xyXY</BBoxOrder>\n";
xml += " </Service>\n";
xml += " <DataWindow>\n";
s.sprintf("%f", _llat);
xml += " <UpperLeftX>" + s + "</UpperLeftX>\n";
s.sprintf("%f", _llon);
xml += " <UpperLeftY>" + s + "</UpperLeftY>\n";
s.sprintf("%f", _rlat);
xml += " <LowerRightX>" + s + "</LowerRightX>\n";
s.sprintf("%f", _rlon);
xml += " <LowerRightY>" + s + "</LowerRightY>\n";
s.sprintf("%d", width);
xml += " <SizeX>" + s + "</SizeX>\n";
s.sprintf("%d", height);
xml += " <SizeY>" + s + "</SizeY>\n";
xml += " </DataWindow>\n";
/* switch (isrs)
{
case 0: srs = QString("EPSG:4326"); break;
case 1: srs = QString("EPSG:31259"); break;
case 2: srs = QString("EPSG:31286"); break;
case 3: srs = QString("EPSG:31287"); break;
case 4: srs = QString("EPSG:31288"); break;
default: srs = QString("EPSG:4326");
}
*/
// srs = QString("EPSG:4326");
xml += " <Projection>" + crs + "</Projection>\n";
xml += " <BandsCount>" + wms.readEntry("Bands", QString("3")) + "</BandsCount>\n";
item = wms.readEntry("Tile", 2);
switch(item)
{
case 0: bSize = QString("64"); break;
case 1: bSize = QString("128"); break;
case 2: bSize = QString("256"); break;
case 3: bSize = QString("512"); break;
case 4: bSize = QString("1024"); break;
default: bSize = QString("256");
}
xml += " <BlockSizeX>" + bSize + "</BlockSizeX>\n";
xml += " <BlockSizeY>" + bSize + "</BlockSizeY>\n";
xml += " <OverviewCount>" + wms.readEntry("Overview", QString("10")) + "</OverviewCount>\n";
xml += " <Cache>\n";
xml += " <Path>" + path + "/.gdalwmscache" + "</Path>\n";
xml += " <Depth>" + wms.readEntry("Depth", QString("2")) + "</Depth>\n";
xml += " <Extension>" + ext + "</Extension>\n";
xml += " </Cache>\n";
QString off((wms.readEntry("Offline", false)) ? "true" : "false");
QString adv((wms.readEntry("Advice", false)) ? "true" : "false");
QString ver((wms.readEntry("Verify", true)) ? "true" : "false");
if(offline)
xml += " <OfflineMode>true</OfflineMode>\n";
else
xml += " <OfflineMode>" + off + "</OfflineMode>\n";
xml += " <AdviseRead>" + adv + "</AdviseRead>\n";
xml += " <VerifyAdviseRead>" + ver + "</VerifyAdviseRead>\n";
xml += "</GDAL_WMS>\n";
write(fl.handle(), xml.toAscii().data(), strlen(xml.toAscii().data()));
fl.close();
return true;
}
bool sportwatcherWidget::transCoords(double *x1, double *y1, double *x2, double *y2, int code, int width, int height, bool square)
{
OGRSpatialReference oSourceSRS, oTargetSRS;
OGRCoordinateTransformation *poCT;
oSourceSRS.SetWellKnownGeogCS("WGS84");
oTargetSRS.importFromEPSG(code);
poCT = OGRCreateCoordinateTransformation(&oSourceSRS, &oTargetSRS);
if(poCT == NULL || !poCT->Transform(1, x1, y1))
{
KMessageBox::error(this, i18n("Translation between coordinate systems failed!"));
if(poCT != NULL)
delete poCT;
return true;
}
if(poCT != NULL)
{
poCT->Transform(1, x2, y2);
delete poCT;
}
if(square)
{
double wdiff = (double)((long)(*x1 - *x2) / (width / 2 * 2) * (width / 2 * 2));
double hdiff = (double)((long)(*y2 - *y1) / (height / 2 * 2) * (height / 2 * 2));
*x2 = *x1 - wdiff; // * (double)mFactor;
*y2 = *y1 + hdiff; // * (double)mFactor;
// *x2 = *x1 - (double)((long)(wdiff / mFactor * mFactor));
// *y2 = *y1 - (double)((long)(hdiff / mFactor * mFactor));
/* wdiff = wdiff - (*x1 - *x2);
hdiff = hdiff - (*y2 - *y1);
*x1 -= wdiff / 2.0;
*x2 -= wdiff / 2.0;
*y1 += hdiff / 2.0;
*y2 += hdiff / 2.0; */
}
return false;
}
QString *sportwatcherWidget::getProjection(int isrs, QString *srs)
{
switch(isrs)
{
case 0: *srs = QString("EPSG:4326"); break;
case 1: *srs = QString("EPSG:31257"); break;
case 2: *srs = QString("EPSG:31258"); break;
case 3: *srs = QString("EPSG:31259"); break;
case 4: *srs = QString("EPSG:31286"); break;
case 5: *srs = QString("EPSG:31287"); break;
case 6: *srs = QString("EPSG:31288"); break;
default: *srs = QString("EPSG:4326");
}
return srs;
}
bool sportwatcherWidget::warpImage(QString fn, QString *fName)
{
GDALDatasetH hSrcDS, hDstDS;
GDALDataset *inSet, *outSet;
GDALDataType eDT;
GDALRasterBand *poBand;
GDALDriverH hDriver;
char hv0[256];
int nXSize, nYSize;
double adfGeoTransform[6];
double oriLeftLon, oriRightLon, oriLeftLat, oriRightLat;
// Loading the user set geo coords of our source image and
// load the projection used for that image
KConfig cfg(QString("sportwatcher.rc"), KConfig::SimpleConfig);
KConfigGroup ic(&cfg, "ImageCoords");
oriLeftLon = ic.readEntry("LeftLon", 0.0);
oriLeftLat = ic.readEntry("LeftLat", 0.0);
oriRightLon = ic.readEntry("RightLon", 0.0);
oriRightLat = ic.readEntry("RightLat", 0.0);
int isrs = ic.readEntry("SRS", 0);
// Create a temporary file name for our output file
strcpy(hv0, "/tmp/SportWatcherTIFFXXXXXX");
mkdtemp(&hv0[0]);
*fName = QString(hv0) + ".tif";
// Open input and output files.
if((hSrcDS = GDALOpen(fn.toAscii().data(), GA_ReadOnly)) == NULL)
{
KMessageBox::error(this, i18n("Error opening an image file!"));
return false;
}
inSet = (GDALDataset *)hSrcDS;
// Create output with same datatype as first input band.
poBand = inSet->GetRasterBand(1);
eDT = poBand->GetRasterDataType();
if((hDriver = GDALGetDriverByName("GTiff")) == NULL)
{
KMessageBox::error(this, i18n("Error loading the TIFF driver!"));
GDALClose(hSrcDS);
return false;
}
// Get dimensions of image and set transform data
int nRasterCount = inSet->GetRasterCount();
nXSize = inSet->GetRasterXSize();
nYSize = inSet->GetRasterYSize();
// cut the wanted region out of image
transform *tf = new transform(oriLeftLat, oriLeftLon, oriRightLat, oriRightLon);
tf->setDimensions(nXSize, nYSize);
if(!tf->cutImage(geoRect.llat, geoRect.llon, geoRect.rlat, geoRect.rlon, fn))
{
GDALClose(hSrcDS);
return false;
}
GDALClose(hSrcDS);
QString nfn = fn + "_tmp.png";
// repeat the part above and open the now cutted part of the image.
// Open input and output files.
if((hSrcDS = GDALOpen(nfn.toAscii().data(), GA_ReadOnly)) == NULL)
{
KMessageBox::error(this, i18n("Error opening an image file!"));
return false;
}
inSet = (GDALDataset *)hSrcDS;
// Create output with same datatype as first input band.
poBand = inSet->GetRasterBand(1);
eDT = poBand->GetRasterDataType();
if((hDriver = GDALGetDriverByName("GTiff")) == NULL)
{
KMessageBox::error(this, i18n("Error loading the TIFF driver!"));
GDALClose(hSrcDS);
return false;
}
// Get dimensions of image and set transform data
nRasterCount = inSet->GetRasterCount();
nXSize = inSet->GetRasterXSize();
nYSize = inSet->GetRasterYSize();
// Set the values needed to transform the image
OGRSpatialReference iSRS;
const char *iWKT;
switch(isrs)
{
case 0: iSRS.importFromEPSG(4326); break;
case 1: iSRS.importFromEPSG(31257); break;
case 2: iSRS.importFromEPSG(31258); break;
case 3: iSRS.importFromEPSG(31259); break;
case 4: iSRS.importFromEPSG(31286); break;
case 5: iSRS.importFromEPSG(31287); break;
case 6: iSRS.importFromEPSG(31288); break;
default: iSRS.importFromEPSG(4326);
}
iSRS.exportToWkt((char **)&iWKT);
if(inSet->SetProjection(iWKT) != CE_None)
{
KMessageBox::error(this, i18n("Error setting projection on source!"));
GDALClose(hSrcDS);
return false;
}
adfGeoTransform[0] = geoRect.llon;
adfGeoTransform[1] = (geoRect.rlon - geoRect.llon) / (double)nXSize;
adfGeoTransform[2] = 0.0;
adfGeoTransform[3] = geoRect.llat;
adfGeoTransform[4] = 0.0;
adfGeoTransform[5] = -1.0 * ((geoRect.llat - geoRect.rlat) / (double)nYSize);
if(inSet->SetGeoTransform(&adfGeoTransform[0]) != CE_None)
{
KMessageBox::error(this, i18n("Error setting geo transform data to source!"));
GDALClose(hSrcDS);
return false;
}
// Get Source coordinate system.
const char *pszSrcWKT, *pszDstWKT = NULL;
if((pszSrcWKT = GDALGetProjectionRef(hSrcDS)) == NULL)
{
KMessageBox::error(this, i18n("Error getting the projection reference"));
GDALClose(hSrcDS);
return false;
}
// Setup output coordinate system that is UTM ? WGS84.
OGRSpatialReference oSRS;
// oSRS.SetUTM( 0, TRUE );
oSRS.SetWellKnownGeogCS("WGS84");
oSRS.exportToWkt((char **)&pszDstWKT);
// Create the output file.
double adfDstGeoTransform[6];
adfDstGeoTransform[0] = geoRect.llon;
adfDstGeoTransform[1] = (geoRect.rlon - geoRect.llon) / (double)geoRect.width;
adfDstGeoTransform[2] = 0.0;
adfDstGeoTransform[3] = geoRect.llat;
adfDstGeoTransform[4] = 0.0;
adfDstGeoTransform[5] = -1.0 * ((geoRect.llat - geoRect.rlat) / (double)geoRect.height);
if((hDstDS = GDALCreate(hDriver, fName->toAscii().data(), geoRect.width, geoRect.height,
nRasterCount, eDT, NULL)) == NULL)
{
KMessageBox::error(this, i18n("Error creating a temporary image file! (%1)").arg(*fName));
GDALClose(hSrcDS);
return false;
}
outSet = (GDALDataset *)hDstDS;
for(int i = 0; i < nRasterCount; i++)
{
poBand = outSet->GetRasterBand(i + 1);
poBand->Fill(0.0);
}
if(outSet->SetProjection(pszDstWKT) != CE_None)
{
KMessageBox::error(this, i18n("Error setting projection on destination!"));
GDALClose(hDstDS);
GDALClose(hSrcDS);
unlink(fName->toAscii().data());
return false;
}
if(outSet->SetGeoTransform(&adfDstGeoTransform[0]) != CE_None)
{
KMessageBox::error(this, i18n("Error setting geo transform data to destination!"));
GDALClose(hDstDS);
GDALClose(hSrcDS);
unlink(fName->toAscii().data());
return false;
}
// Copy the color table, if required.
GDALColorTableH hCT;
for(int i = 0; i < nRasterCount; i++)
{
hCT = GDALGetRasterColorTable(inSet->GetRasterBand(i + 1));
if(hCT != NULL)
GDALSetRasterColorTable(outSet->GetRasterBand(i + 1), hCT);
}
// Setup warp options.
GDALWarpOptions *psWarpOptions = GDALCreateWarpOptions();
psWarpOptions->hSrcDS = hSrcDS;
psWarpOptions->hDstDS = hDstDS;
psWarpOptions->nBandCount = nRasterCount;
psWarpOptions->panSrcBands =
(int *) CPLMalloc(sizeof(int) * psWarpOptions->nBandCount);
psWarpOptions->panDstBands =
(int *) CPLMalloc(sizeof(int) * psWarpOptions->nBandCount);
for(int i = 0; i < nRasterCount; i++)
{
psWarpOptions->panSrcBands[i] = i + 1;
psWarpOptions->panDstBands[i] = i + 1;
}
// psWarpOptions->pfnProgress = GDALTermProgress;
// Establish reprojection transformer.
psWarpOptions->pTransformerArg =
GDALCreateGenImgProjTransformer(hSrcDS,
GDALGetProjectionRef(hSrcDS),
hDstDS,
GDALGetProjectionRef(hDstDS),
FALSE, 0.0, 1);
psWarpOptions->pfnTransformer = GDALGenImgProjTransform;
// Initialize and execute the warp operation.
GDALWarpOperation oOperation;
if(oOperation.Initialize(psWarpOptions) != CE_None)
{
KMessageBox::error(this, i18n("Error initializing warp operation!"));
GDALClose(hDstDS);
GDALClose(hSrcDS);
unlink(fName->toAscii().data());
return false;
}
oOperation.ChunkAndWarpMulti(0, 0, geoRect.width, geoRect.height);
GDALDestroyGenImgProjTransformer(psWarpOptions->pTransformerArg);
GDALDestroyWarpOptions(psWarpOptions);
GDALClose(hDstDS);
GDALClose(hSrcDS);
unlink(nfn.toAscii().data());
return true;
}
#endif
#ifdef HAVE_GDAL
void spwErrorHandler(CPLErr err, int num, const char *msg)
{
ERRMSG *akt;
char et[32], hv0[4096];
if(err == CE_None || !msg)
return;
if(err == CE_Fatal)
std::cerr << "ERROR " << num << ": " << msg << endl;
if(!firstError)
{
firstError = new ERRMSG;
memset(firstError, 0, sizeof(ERRMSG));
akt = firstError;
}
else
{
akt = firstError;
while(akt)
{
if(!akt->next)
break;
akt = akt->next;
}
akt->next = new ERRMSG;
akt = akt->next;
memset(akt, 0, sizeof(ERRMSG));
}
switch(err)
{
case CE_None: strcpy(et, "None"); break;
case CE_Debug: strcpy(et, "DEBUG"); break;
case CE_Warning: strcpy(et, "Warning"); break;
case CE_Failure: strcpy(et, "Failure"); break;
case CE_Fatal: strcpy(et, "Fatal"); break;
}
memset(hv0, 0, sizeof(hv0));
strncpy(hv0, msg, 4000);
sprintf(akt->msg, "ERROR TYPE %s - %d: %s", et, num, hv0);
}
void destroyErrors()
{
ERRMSG *akt;
if(!firstError)
return;
akt = firstError;
while(akt)
{
firstError = akt->next;
delete akt;
akt = firstError;
}
firstError = 0;
}
QString catGDALError()
{
QString err;
ERRMSG *akt = firstError;
while(akt)
{
err += QString(akt->msg) + "\n";
akt = akt->next;
}
destroyErrors();
return err;
}
#endif
#include "sportwatcherwidget.moc"