subsurface/qt-models/diveplannermodel.cpp
Berthold Stoeger 601861ef5e planner: split DivePlannerPointsModel::removePoints() in two
Split the function in one external version, that updates the
dive profile and cylinders and one internal version, that
does no recalculations. In the latter case, the caller is
responsible for updating the dive.

Thus, the recalculation flag-clearing can be removed from
removeDeco().

Signed-off-by: Berthold Stoeger <bstoeger@mail.tuwien.ac.at>
2021-04-02 13:53:23 -07:00

1340 lines
37 KiB
C++

// SPDX-License-Identifier: GPL-2.0
#include "diveplannermodel.h"
#include "core/divelist.h"
#include "core/subsurface-string.h"
#include "qt-models/cylindermodel.h"
#include "core/planner.h"
#include "qt-models/models.h"
#include "core/device.h"
#include "core/qthelper.h"
#include "core/sample.h"
#include "core/settings/qPrefDivePlanner.h"
#include "core/settings/qPrefUnit.h"
#if !defined(SUBSURFACE_TESTING)
#include "commands/command.h"
#endif // !SUBSURFACE_TESTING
#include "core/gettextfromc.h"
#include "core/deco.h"
#include <QApplication>
#include <QTextDocument>
#include <QtConcurrent>
#define VARIATIONS_IN_BACKGROUND 1
#define UNIT_FACTOR ((prefs.units.length == units::METERS) ? 1000.0 / 60.0 : feet_to_mm(1.0) / 60.0)
CylindersModel *DivePlannerPointsModel::cylindersModel()
{
return &cylinders;
}
void DivePlannerPointsModel::removePoints(const QVector<int> &rows)
{
if (!rows.count())
return;
QVector<int> v2 = rows;
std::sort(v2.begin(), v2.end());
for (int i = v2.count() - 1; i >= 0; i--) {
beginRemoveRows(QModelIndex(), v2[i], v2[i]);
divepoints.erase(divepoints.begin() + v2[i]);
endRemoveRows();
}
}
void DivePlannerPointsModel::removeSelectedPoints(const QVector<int> &rows)
{
removePoints(rows);
updateDiveProfile();
emitDataChanged();
cylinders.updateTrashIcon();
}
void DivePlannerPointsModel::createSimpleDive(struct dive *dIn)
{
// clean out the dive and give it an id and the correct dc model
d = dIn;
clear_dive(d);
d->id = dive_getUniqID();
d->when = QDateTime::currentMSecsSinceEpoch() / 1000L + gettimezoneoffset() + 3600;
d->dc.model = strdup("planned dive"); // don't translate! this is stored in the XML file
clear();
setupCylinders();
setupStartTime();
// initialize the start time in the plan
diveplan.when = dateTimeToTimestamp(startTime);
d->when = diveplan.when;
// Use gas from the first cylinder
int cylinderid = 0;
// If we're in drop_stone_mode, don't add a first point.
// It will be added implicitly.
if (!prefs.drop_stone_mode)
addStop(M_OR_FT(15, 45), 1 * 60, cylinderid, 0, true, UNDEF_COMP_TYPE);
addStop(M_OR_FT(15, 45), 20 * 60, 0, 0, true, UNDEF_COMP_TYPE);
if (!isPlanner()) {
addStop(M_OR_FT(5, 15), 42 * 60, 0, cylinderid, true, UNDEF_COMP_TYPE);
addStop(M_OR_FT(5, 15), 45 * 60, 0, cylinderid, true, UNDEF_COMP_TYPE);
}
updateDiveProfile();
GasSelectionModel::instance()->repopulate();
DiveTypeSelectionModel::instance()->repopulate();
}
void DivePlannerPointsModel::setupStartTime()
{
// if the latest dive is in the future, then start an hour after it ends
// otherwise start an hour from now
startTime = QDateTime::currentDateTimeUtc().addSecs(3600 + gettimezoneoffset());
if (dive_table.nr) {
struct dive *d = get_dive(dive_table.nr - 1);
time_t ends = dive_endtime(d);
time_t diff = ends - dateTimeToTimestamp(startTime);
if (diff > 0) {
startTime = startTime.addSecs(diff + 3600);
}
}
}
void DivePlannerPointsModel::loadFromDive(dive *dIn)
{
d = dIn;
int depthsum = 0;
int samplecount = 0;
o2pressure_t last_sp;
bool oldRec = recalc;
struct divecomputer *dc = &(d->dc);
const struct event *evd = NULL;
enum divemode_t current_divemode = UNDEF_COMP_TYPE;
recalc = false;
cylinders.updateDive(d);
duration_t lasttime = { 0 };
duration_t lastrecordedtime = {};
duration_t newtime = {};
clear();
free_dps(&diveplan);
diveplan.when = d->when;
// is this a "new" dive where we marked manually entered samples?
// if yes then the first sample should be marked
// if it is we only add the manually entered samples as waypoints to the diveplan
// otherwise we have to add all of them
bool hasMarkedSamples = false;
if (dc->samples)
hasMarkedSamples = dc->sample[0].manually_entered;
else
fake_dc(dc);
// if this dive has more than 100 samples (so it is probably a logged dive),
// average samples so we end up with a total of 100 samples.
int plansamples = dc->samples <= 100 ? dc->samples : 100;
int j = 0;
int cylinderid = 0;
last_sp.mbar = 0;
for (int i = 0; i < plansamples - 1; i++) {
if (dc->last_manual_time.seconds && dc->last_manual_time.seconds > 120 && lasttime.seconds >= dc->last_manual_time.seconds)
break;
while (j * plansamples <= i * dc->samples) {
const sample &s = dc->sample[j];
const sample &prev = dc->sample[j-1];
if (s.time.seconds != 0 && (!hasMarkedSamples || s.manually_entered)) {
depthsum += s.depth.mm;
last_sp = prev.setpoint;
++samplecount;
newtime = s.time;
}
j++;
}
if (samplecount) {
cylinderid = get_cylinderid_at_time(d, dc, lasttime);
duration_t nexttime = newtime;
++nexttime.seconds;
if (newtime.seconds - lastrecordedtime.seconds > 10 || cylinderid == get_cylinderid_at_time(d, dc, nexttime)) {
if (newtime.seconds == lastrecordedtime.seconds)
newtime.seconds += 10;
current_divemode = get_current_divemode(dc, newtime.seconds - 1, &evd, &current_divemode);
addStop(depthsum / samplecount, newtime.seconds, cylinderid, last_sp.mbar, true, current_divemode);
lastrecordedtime = newtime;
}
lasttime = newtime;
depthsum = 0;
samplecount = 0;
}
}
// make sure we get the last point right so the duration is correct
current_divemode = get_current_divemode(dc, d->dc.duration.seconds, &evd, &current_divemode);
if (!hasMarkedSamples && !dc->last_manual_time.seconds)
addStop(0, d->dc.duration.seconds,cylinderid, last_sp.mbar, true, current_divemode);
recalc = oldRec;
DiveTypeSelectionModel::instance()->repopulate();
preserved_until = d->duration;
updateDiveProfile();
emitDataChanged();
}
// copy the tanks from the current dive, or the default cylinder
// or an unknown cylinder
// setup the cylinder widget accordingly
void DivePlannerPointsModel::setupCylinders()
{
clear_cylinder_table(&d->cylinders);
if (mode == PLAN && current_dive) {
// take the displayed cylinders from the selected dive as starting point
copy_used_cylinders(current_dive, d, !prefs.display_unused_tanks);
reset_cylinders(d, true);
if (d->cylinders.nr > 0) {
cylinders.updateDive(d);
return; // We have at least one cylinder
}
}
if (!empty_string(prefs.default_cylinder)) {
cylinder_t cyl = empty_cylinder;
fill_default_cylinder(d, &cyl);
cyl.start = cyl.type.workingpressure;
add_cylinder(&d->cylinders, 0, cyl);
} else {
cylinder_t cyl = empty_cylinder;
// roughly an AL80
cyl.type.description = copy_qstring(tr("unknown"));
cyl.type.size.mliter = 11100;
cyl.type.workingpressure.mbar = 207000;
add_cylinder(&d->cylinders, 0, cyl);
}
reset_cylinders(d, false);
cylinders.updateDive(d);
}
// Update the dive's maximum depth. Returns true if max. depth changed
bool DivePlannerPointsModel::updateMaxDepth()
{
int prevMaxDepth = d->maxdepth.mm;
d->maxdepth.mm = 0;
for (int i = 0; i < rowCount(); i++) {
divedatapoint p = at(i);
if (p.depth.mm > d->maxdepth.mm)
d->maxdepth.mm = p.depth.mm;
}
return d->maxdepth.mm != prevMaxDepth;
}
void DivePlannerPointsModel::removeDeco()
{
QVector<int> computedPoints;
for (int i = 0; i < rowCount(); i++) {
if (!at(i).entered)
computedPoints.push_back(i);
}
removePoints(computedPoints);
}
void DivePlannerPointsModel::addCylinder_clicked()
{
cylinders.add();
}
void DivePlannerPointsModel::setPlanMode(Mode m)
{
mode = m;
// the planner may reset our GF settings that are used to show deco
// reset them to what's in the preferences
if (m != PLAN) {
set_gf(prefs.gflow, prefs.gfhigh);
set_vpmb_conservatism(prefs.vpmb_conservatism);
}
}
bool DivePlannerPointsModel::isPlanner() const
{
return mode == PLAN;
}
int DivePlannerPointsModel::columnCount(const QModelIndex&) const
{
return COLUMNS; // to disable CCSETPOINT subtract one
}
QVariant DivePlannerPointsModel::data(const QModelIndex &index, int role) const
{
divedatapoint p = divepoints.at(index.row());
if (role == Qt::DisplayRole || role == Qt::EditRole) {
switch (index.column()) {
case CCSETPOINT:
return (double)p.setpoint / 1000;
case DEPTH:
return (int) lrint(get_depth_units(p.depth.mm, NULL, NULL));
case RUNTIME:
return p.time / 60;
case DURATION:
if (index.row())
return (p.time - divepoints.at(index.row() - 1).time) / 60;
else
return p.time / 60;
case DIVEMODE:
return gettextFromC::tr(divemode_text_ui[p.divemode]);
case GAS:
/* Check if we have the same gasmix two or more times
* If yes return more verbose string */
int same_gas = same_gasmix_cylinder(get_cylinder(d, p.cylinderid), p.cylinderid, d, true);
if (same_gas == -1)
return get_gas_string(get_cylinder(d, p.cylinderid)->gasmix);
else
return get_gas_string(get_cylinder(d, p.cylinderid)->gasmix) +
QString(" (%1 %2 ").arg(tr("cyl.")).arg(p.cylinderid + 1) +
get_cylinder(d, p.cylinderid)->type.description + ")";
}
} else if (role == Qt::DecorationRole) {
switch (index.column()) {
case REMOVE:
if (rowCount() > 1)
return p.entered ? trashIcon() : QVariant();
else
return trashForbiddenIcon();
}
} else if (role == Qt::SizeHintRole) {
switch (index.column()) {
case REMOVE:
if (rowCount() > 1)
return p.entered ? trashIcon().size() : QVariant();
else
return trashForbiddenIcon().size();
}
} else if (role == Qt::FontRole) {
if (divepoints.at(index.row()).entered) {
return defaultModelFont();
} else {
QFont font = defaultModelFont();
font.setBold(true);
return font;
}
}
return QVariant();
}
bool DivePlannerPointsModel::setData(const QModelIndex &index, const QVariant &value, int role)
{
int i, shift;
if (role == Qt::EditRole) {
divedatapoint &p = divepoints[index.row()];
switch (index.column()) {
case DEPTH:
if (value.toInt() >= 0) {
p.depth = units_to_depth(value.toInt());
if (updateMaxDepth())
cylinders.updateBestMixes();
}
break;
case RUNTIME: {
int secs = value.toInt() * 60;
i = index.row();
int duration = secs;
if (i)
duration -= divepoints[i-1].time;
// Make sure segments have a minimal duration
if (duration <= 0)
secs += 10 - duration;
p.time = secs;
while (++i < divepoints.size())
if (divepoints[i].time < divepoints[i - 1].time + 10)
divepoints[i].time = divepoints[i - 1].time + 10;
break;
}
case DURATION: {
int secs = value.toInt() * 60;
if (!secs)
secs = 10;
i = index.row();
if (i)
shift = divepoints[i].time - divepoints[i - 1].time - secs;
else
shift = divepoints[i].time - secs;
while (i < divepoints.size())
divepoints[i++].time -= shift;
break;
}
case CCSETPOINT: {
int po2 = 0;
QByteArray gasv = value.toByteArray();
if (validate_po2(gasv.data(), &po2))
p.setpoint = po2;
break;
}
case GAS:
if (value.toInt() >= 0)
p.cylinderid = value.toInt();
/* Did we change the start (dp 0) cylinder to another cylinderid than 0? */
if (value.toInt() != 0 && index.row() == 0)
cylinders.moveAtFirst(value.toInt());
cylinders.updateTrashIcon();
break;
case DIVEMODE:
if (value.toInt() < FREEDIVE) {
p.divemode = (enum divemode_t) value.toInt();
p.setpoint = p.divemode == CCR ? prefs.defaultsetpoint : 0;
}
if (index.row() == 0)
d->dc.divemode = (enum divemode_t) value.toInt();
break;
}
editStop(index.row(), p);
}
return QAbstractItemModel::setData(index, value, role);
}
void DivePlannerPointsModel::gasChange(const QModelIndex &index, int newcylinderid)
{
int i = index.row(), oldcylinderid = divepoints[i].cylinderid;
while (i < rowCount() && oldcylinderid == divepoints[i].cylinderid)
divepoints[i++].cylinderid = newcylinderid;
emitDataChanged();
}
void DivePlannerPointsModel::cylinderRenumber(int mapping[])
{
for (int i = 0; i < rowCount(); i++) {
if (mapping[divepoints[i].cylinderid] >= 0)
divepoints[i].cylinderid = mapping[divepoints[i].cylinderid];
}
emitDataChanged();
}
QVariant DivePlannerPointsModel::headerData(int section, Qt::Orientation orientation, int role) const
{
if (role == Qt::DisplayRole && orientation == Qt::Horizontal) {
switch (section) {
case DEPTH:
return tr("Final depth");
case RUNTIME:
return tr("Run time");
case DURATION:
return tr("Duration");
case GAS:
return tr("Used gas");
case CCSETPOINT:
return tr("CC setpoint");
case DIVEMODE:
return tr("Dive mode");
}
} else if (role == Qt::FontRole) {
return defaultModelFont();
}
return QVariant();
}
Qt::ItemFlags DivePlannerPointsModel::flags(const QModelIndex &index) const
{
if (index.column() != REMOVE)
return QAbstractItemModel::flags(index) | Qt::ItemIsEditable;
else
return QAbstractItemModel::flags(index);
}
int DivePlannerPointsModel::rowCount(const QModelIndex&) const
{
return divepoints.count();
}
DivePlannerPointsModel::DivePlannerPointsModel(QObject *parent) : QAbstractTableModel(parent),
d(nullptr),
cylinders(true),
mode(NOTHING),
recalc(true)
{
memset(&diveplan, 0, sizeof(diveplan));
startTime.setTimeSpec(Qt::UTC);
// use a Qt-connection to send the variations text across thread boundary (in case we
// are calculating the variations in a background thread).
connect(this, &DivePlannerPointsModel::variationsComputed, this, &DivePlannerPointsModel::computeVariationsDone);
}
DivePlannerPointsModel *DivePlannerPointsModel::instance()
{
static DivePlannerPointsModel self;
return &self;
}
void DivePlannerPointsModel::emitDataChanged()
{
emit dataChanged(createIndex(0, 0), createIndex(rowCount() - 1, COLUMNS - 1));
}
void DivePlannerPointsModel::setBottomSac(double sac)
{
// mobile delivers the same value as desktop when using
// units:METERS
// however when using units:CUFT mobile deliver 0-300 which
// are really 0.00 - 3.00 so start be correcting that
#ifdef SUBSURFACE_MOBILE
if (qPrefUnits::volume() == units::CUFT)
sac /= 100; // cuft without decimals (0 - 300)
#endif
diveplan.bottomsac = units_to_sac(sac);
qPrefDivePlanner::set_bottomsac(diveplan.bottomsac);
emitDataChanged();
}
void DivePlannerPointsModel::setDecoSac(double sac)
{
// mobile delivers the same value as desktop when using
// units:METERS
// however when using units:CUFT mobile deliver 0-300 which
// are really 0.00 - 3.00 so start be correcting that
#ifdef SUBSURFACE_MOBILE
if (qPrefUnits::volume() == units::CUFT)
sac /= 100; // cuft without decimals (0 - 300)
#endif
diveplan.decosac = units_to_sac(sac);
qPrefDivePlanner::set_decosac(diveplan.decosac);
emitDataChanged();
}
void DivePlannerPointsModel::setSacFactor(double factor)
{
// sacfactor is normal x.y (one decimal), however mobile
// delivers 0 - 100 so adjust that to 0.0 - 10.0, to have
// the same value as desktop
#ifdef SUBSURFACE_MOBILE
factor /= 10.0;
#endif
qPrefDivePlanner::set_sacfactor((int) round(factor * 100));
emitDataChanged();
}
void DivePlannerPointsModel::setProblemSolvingTime(int minutes)
{
qPrefDivePlanner::set_problemsolvingtime(minutes);
emitDataChanged();
}
void DivePlannerPointsModel::setGFHigh(const int gfhigh)
{
if (diveplan.gfhigh != gfhigh) {
diveplan.gfhigh = gfhigh;
emitDataChanged();
}
}
void DivePlannerPointsModel::setGFLow(const int gflow)
{
if (diveplan.gflow != gflow) {
diveplan.gflow = gflow;
emitDataChanged();
}
}
void DivePlannerPointsModel::setRebreatherMode(int mode)
{
int i;
d->dc.divemode = (divemode_t) mode;
for (i = 0; i < rowCount(); i++) {
divepoints[i].setpoint = mode == CCR ? prefs.defaultsetpoint : 0;
divepoints[i].divemode = (enum divemode_t) mode;
}
emitDataChanged();
}
void DivePlannerPointsModel::setVpmbConservatism(int level)
{
if (diveplan.vpmb_conservatism != level) {
diveplan.vpmb_conservatism = level;
emitDataChanged();
}
}
void DivePlannerPointsModel::setSurfacePressure(int pressure)
{
diveplan.surface_pressure = pressure;
emitDataChanged();
}
void DivePlannerPointsModel::setSalinity(int salinity)
{
diveplan.salinity = salinity;
emitDataChanged();
}
int DivePlannerPointsModel::getSurfacePressure() const
{
return diveplan.surface_pressure;
}
void DivePlannerPointsModel::setLastStop6m(bool value)
{
qPrefDivePlanner::set_last_stop(value);
emitDataChanged();
}
void DivePlannerPointsModel::setAscrate75Display(int rate)
{
qPrefDivePlanner::set_ascrate75(lrint(rate * UNIT_FACTOR));
emitDataChanged();
}
int DivePlannerPointsModel::ascrate75Display() const
{
return lrint((float)prefs.ascrate75 / UNIT_FACTOR);
}
void DivePlannerPointsModel::setAscrate50Display(int rate)
{
qPrefDivePlanner::set_ascrate50(lrint(rate * UNIT_FACTOR));
emitDataChanged();
}
int DivePlannerPointsModel::ascrate50Display() const
{
return lrint((float)prefs.ascrate50 / UNIT_FACTOR);
}
void DivePlannerPointsModel::setAscratestopsDisplay(int rate)
{
qPrefDivePlanner::set_ascratestops(lrint(rate * UNIT_FACTOR));
emitDataChanged();
}
int DivePlannerPointsModel::ascratestopsDisplay() const
{
return lrint((float)prefs.ascratestops / UNIT_FACTOR);
}
void DivePlannerPointsModel::setAscratelast6mDisplay(int rate)
{
qPrefDivePlanner::set_ascratelast6m(lrint(rate * UNIT_FACTOR));
emitDataChanged();
}
int DivePlannerPointsModel::ascratelast6mDisplay() const
{
return lrint((float)prefs.ascratelast6m / UNIT_FACTOR);
}
void DivePlannerPointsModel::setDescrateDisplay(int rate)
{
qPrefDivePlanner::set_descrate(lrint(rate * UNIT_FACTOR));
emitDataChanged();
}
int DivePlannerPointsModel::descrateDisplay() const
{
return lrint((float)prefs.descrate / UNIT_FACTOR);
}
void DivePlannerPointsModel::setVerbatim(bool value)
{
qPrefDivePlanner::set_verbatim_plan(value);
emitDataChanged();
}
void DivePlannerPointsModel::setDisplayRuntime(bool value)
{
qPrefDivePlanner::set_display_runtime(value);
emitDataChanged();
}
void DivePlannerPointsModel::setDisplayDuration(bool value)
{
qPrefDivePlanner::set_display_duration(value);
emitDataChanged();
}
void DivePlannerPointsModel::setDisplayTransitions(bool value)
{
qPrefDivePlanner::set_display_transitions(value);
emitDataChanged();
}
void DivePlannerPointsModel::setDisplayVariations(bool value)
{
qPrefDivePlanner::set_display_variations(value);
emitDataChanged();
}
void DivePlannerPointsModel::setDecoMode(int mode)
{
qPrefDivePlanner::set_planner_deco_mode(deco_mode(mode));
emit recreationChanged(mode == int(prefs.planner_deco_mode));
emitDataChanged();
}
void DivePlannerPointsModel::setSafetyStop(bool value)
{
qPrefDivePlanner::set_safetystop(value);
emitDataChanged();
}
void DivePlannerPointsModel::setReserveGas(int reserve)
{
if (prefs.units.pressure == units::BAR)
qPrefDivePlanner::set_reserve_gas(reserve * 1000);
else
qPrefDivePlanner::set_reserve_gas(psi_to_mbar(reserve));
emitDataChanged();
}
void DivePlannerPointsModel::setDropStoneMode(bool value)
{
qPrefDivePlanner::set_drop_stone_mode(value);
if (prefs.drop_stone_mode) {
/* Remove the first entry if we enable drop_stone_mode */
if (rowCount() >= 2) {
beginRemoveRows(QModelIndex(), 0, 0);
divepoints.remove(0);
endRemoveRows();
}
} else {
/* Add a first entry if we disable drop_stone_mode */
beginInsertRows(QModelIndex(), 0, 0);
/* Copy the first current point */
divedatapoint p = divepoints.at(0);
p.time = p.depth.mm / prefs.descrate;
divepoints.push_front(p);
endInsertRows();
}
emitDataChanged();
}
void DivePlannerPointsModel::setSwitchAtReqStop(bool value)
{
qPrefDivePlanner::set_switch_at_req_stop(value);
emitDataChanged();
}
void DivePlannerPointsModel::setMinSwitchDuration(int duration)
{
qPrefDivePlanner::set_min_switch_duration(duration * 60);
emitDataChanged();
}
void DivePlannerPointsModel::setSurfaceSegment(int duration)
{
qPrefDivePlanner::set_surface_segment(duration * 60);
emitDataChanged();
}
void DivePlannerPointsModel::setStartDate(const QDate &date)
{
startTime.setDate(date);
diveplan.when = dateTimeToTimestamp(startTime);
d->when = diveplan.when;
emitDataChanged();
}
void DivePlannerPointsModel::setStartTime(const QTime &t)
{
startTime.setTime(t);
diveplan.when = dateTimeToTimestamp(startTime);
d->when = diveplan.when;
emitDataChanged();
}
bool divePointsLessThan(const divedatapoint &p1, const divedatapoint &p2)
{
return p1.time < p2.time;
}
int DivePlannerPointsModel::lastEnteredPoint() const
{
for (int i = divepoints.count() - 1; i >= 0; i--)
if (divepoints.at(i).entered)
return i;
return -1;
}
void DivePlannerPointsModel::addDefaultStop()
{
addStop(0, 0, -1, 0, true, UNDEF_COMP_TYPE);
}
void DivePlannerPointsModel::addStop(int milimeters, int seconds)
{
addStop(milimeters, seconds, -1, 0, true, UNDEF_COMP_TYPE);
updateDiveProfile();
}
// cylinderid_in == -1 means same gas as before.
// divemode == UNDEF_COMP_TYPE means determine from previous point.
int DivePlannerPointsModel::addStop(int milimeters, int seconds, int cylinderid_in, int ccpoint, bool entered, enum divemode_t divemode)
{
int cylinderid = 0;
bool usePrevious = false;
if (cylinderid_in >= 0)
cylinderid = cylinderid_in;
else
usePrevious = true;
if (recalc)
removeDeco();
int row = divepoints.count();
if (seconds == 0 && milimeters == 0 && row != 0) {
/* this is only possible if the user clicked on the 'plus' sign on the DivePoints Table */
const divedatapoint t = divepoints.at(lastEnteredPoint());
milimeters = t.depth.mm;
seconds = t.time + 600; // 10 minutes.
cylinderid = t.cylinderid;
ccpoint = t.setpoint;
} else if (seconds == 0 && milimeters == 0 && row == 0) {
milimeters = M_OR_FT(5, 15); // 5m / 15ft
seconds = 600; // 10 min
// Default to the first cylinder
cylinderid = 0;
}
// check if there's already a new stop before this one:
for (int i = 0; i < row; i++) {
const divedatapoint &dp = divepoints.at(i);
if (dp.time == seconds) {
row = i;
beginRemoveRows(QModelIndex(), row, row);
divepoints.remove(row);
endRemoveRows();
break;
}
if (dp.time > seconds) {
row = i;
break;
}
}
// Previous, actually means next as we are typically subdiving a segment and the gas for
// the segment is determined by the waypoint at the end.
if (usePrevious) {
if (row < divepoints.count()) {
cylinderid = divepoints.at(row).cylinderid;
if (divemode == UNDEF_COMP_TYPE)
divemode = divepoints.at(row).divemode;
ccpoint = divepoints.at(row).setpoint;
} else if (row > 0) {
cylinderid = divepoints.at(row - 1).cylinderid;
if (divemode == UNDEF_COMP_TYPE)
divemode = divepoints.at(row - 1).divemode;
ccpoint = divepoints.at(row -1).setpoint;
}
}
if (divemode == UNDEF_COMP_TYPE)
divemode = d->dc.divemode;
// add the new stop
beginInsertRows(QModelIndex(), row, row);
divedatapoint point;
point.depth.mm = milimeters;
point.time = seconds;
point.cylinderid = cylinderid;
point.setpoint = ccpoint;
point.entered = entered;
point.divemode = divemode;
point.next = NULL;
divepoints.insert(divepoints.begin() + row, point);
endInsertRows();
return row;
}
void DivePlannerPointsModel::editStop(int row, divedatapoint newData)
{
if (row < 0 || row >= divepoints.count())
return;
// Refuse to move to 0, since that has special meaning.
if (newData.time <= 0)
return;
/*
* When moving divepoints rigorously, we might end up with index
* out of range, thus returning the last one instead.
*/
int old_first_cylid = divepoints[0].cylinderid;
// Refuse creation of two points with the same time stamp.
// Note: "time" is moved in the positive direction to avoid
// time becoming zero or, worse, negative.
while (std::any_of(divepoints.begin(), divepoints.begin() + row,
[t = newData.time] (const divedatapoint &data)
{ return data.time == t; }))
newData.time += 10;
while (std::any_of(divepoints.begin() + row + 1, divepoints.end(),
[t = newData.time] (const divedatapoint &data)
{ return data.time == t; }))
newData.time += 10;
// Is it ok to change data first and then move the rows?
divepoints[row] = newData;
// If the time changed, the item might have to be moved. Oh joy.
int newRow = row;
while (newRow + 1 < divepoints.count() && divepoints[newRow + 1].time < divepoints[row].time)
++newRow;
if (newRow != row) {
++newRow; // Move one past item with smaller time stamp
} else {
// If we didn't move forward, try moving backwards
while (newRow > 0 && divepoints[newRow - 1].time > divepoints[row].time)
--newRow;
}
if (newRow != row && newRow != row + 1) {
beginMoveRows(QModelIndex(), row, row, QModelIndex(), newRow);
moveInVector(divepoints, row, row + 1, newRow);
endMoveRows();
// Account for moving the row backwards in the array.
row = newRow > row ? newRow - 1 : newRow;
}
if (updateMaxDepth())
cylinders.updateBestMixes();
if (divepoints[0].cylinderid != old_first_cylid)
cylinders.moveAtFirst(divepoints[0].cylinderid);
updateDiveProfile();
emit dataChanged(createIndex(row, 0), createIndex(row, COLUMNS - 1));
}
divedatapoint DivePlannerPointsModel::at(int row) const
{
/*
* When moving divepoints rigorously, we might end up with index
* out of range, thus returning the last one instead.
*/
if (row >= divepoints.count())
return divepoints.at(divepoints.count() - 1);
return divepoints.at(row);
}
void DivePlannerPointsModel::remove(const QModelIndex &index)
{
if (index.column() != REMOVE || rowCount() == 1)
return;
divedatapoint dp = at(index.row());
if (!dp.entered)
return;
int old_first_cylid = divepoints[0].cylinderid;
/* TODO: this seems so wrong.
* We can't do this here if we plan to use QML on mobile
* as mobile has no ControlModifier.
* The correct thing to do is to create a new method
* remove method that will pass the first and last index of the
* removed rows, and remove those in a go.
*/
int i;
int rows = rowCount();
if (QApplication::keyboardModifiers() & Qt::ControlModifier) {
preserved_until.seconds = divepoints.at(index.row()).time;
beginRemoveRows(QModelIndex(), index.row(), rows - 1);
for (i = rows - 1; i >= index.row(); i--)
divepoints.remove(i);
} else {
if (index.row() == rows -1)
preserved_until.seconds = divepoints.at(rows - 1).time;
beginRemoveRows(QModelIndex(), index.row(), index.row());
divepoints.remove(index.row());
}
endRemoveRows();
cylinders.updateTrashIcon();
if (divepoints[0].cylinderid != old_first_cylid)
cylinders.moveAtFirst(divepoints[0].cylinderid);
updateDiveProfile();
emitDataChanged();
}
struct diveplan &DivePlannerPointsModel::getDiveplan()
{
return diveplan;
}
void DivePlannerPointsModel::cancelPlan()
{
/* TODO:
* This check shouldn't be here - this is the interface responsability.
* as soon as the interface thinks that it could cancel the plan, this should be
* called.
*/
/*
if (mode == PLAN && rowCount()) {
if (QMessageBox::warning(MainWindow::instance(), TITLE_OR_TEXT(tr("Discard the plan?"),
tr("You are about to discard your plan.")),
QMessageBox::Discard | QMessageBox::Cancel, QMessageBox::Discard) != QMessageBox::Discard) {
return;
}
}
*/
setPlanMode(NOTHING);
free_dps(&diveplan);
emit planCanceled();
}
DivePlannerPointsModel::Mode DivePlannerPointsModel::currentMode() const
{
return mode;
}
bool DivePlannerPointsModel::tankInUse(int cylinderid) const
{
for (int j = 0; j < rowCount(); j++) {
const divedatapoint &p = divepoints[j];
if (p.time == 0) // special entries that hold the available gases
continue;
if (!p.entered) // removing deco gases is ok
continue;
if (p.cylinderid == cylinderid) // tank is in use
return true;
}
return false;
}
void DivePlannerPointsModel::clear()
{
bool oldrec = std::exchange(recalc, false);
beginResetModel();
divepoints.clear();
endResetModel();
cylinders.clear();
preserved_until.seconds = 0;
recalc = oldrec;
}
void DivePlannerPointsModel::createTemporaryPlan()
{
// Get the user-input and calculate the dive info
free_dps(&diveplan);
int lastIndex = -1;
for (int i = 0; i < rowCount(); i++) {
divedatapoint p = at(i);
int deltaT = lastIndex != -1 ? p.time - at(lastIndex).time : p.time;
lastIndex = i;
if (i == 0 && mode == PLAN && prefs.drop_stone_mode) {
/* Okay, we add a first segment where we go down to depth */
plan_add_segment(&diveplan, p.depth.mm / prefs.descrate, p.depth.mm, p.cylinderid, p.setpoint, true, p.divemode);
deltaT -= p.depth.mm / prefs.descrate;
}
if (p.entered)
plan_add_segment(&diveplan, deltaT, p.depth.mm, p.cylinderid, p.setpoint, true, p.divemode);
}
struct divedatapoint *dp = NULL;
for (int i = 0; i < d->cylinders.nr; i++) {
cylinder_t *cyl = get_cylinder(d, i);
if (cyl->depth.mm && cyl->cylinder_use != NOT_USED) {
dp = create_dp(0, cyl->depth.mm, i, 0);
if (diveplan.dp) {
dp->next = diveplan.dp;
diveplan.dp = dp;
} else {
dp->next = NULL;
diveplan.dp = dp;
}
}
}
#if DEBUG_PLAN
dump_plan(&diveplan);
#endif
}
void DivePlannerPointsModel::updateDiveProfile()
{
createTemporaryPlan();
if (diveplan_empty(&diveplan))
return;
struct deco_state *cache = NULL;
struct decostop stoptable[60];
struct deco_state plan_deco_state;
struct diveplan *plan_copy;
memset(&plan_deco_state, 0, sizeof(struct deco_state));
plan(&plan_deco_state, &diveplan, d, DECOTIMESTEP, stoptable, &cache, isPlanner(), false);
updateMaxDepth();
plan_copy = (struct diveplan *)malloc(sizeof(struct diveplan));
lock_planner();
cloneDiveplan(&diveplan, plan_copy);
unlock_planner();
#ifdef VARIATIONS_IN_BACKGROUND
// Since we're calling computeVariations asynchronously and plan_deco_state is allocated
// on the stack, it must be copied and freed by the worker-thread.
struct deco_state *plan_deco_state_copy = new deco_state(plan_deco_state);
QtConcurrent::run(this, &DivePlannerPointsModel::computeVariationsFreeDeco, plan_copy, plan_deco_state_copy);
#else
computeVariations(plan_copy, &plan_deco_state);
#endif
final_deco_state = plan_deco_state;
emit calculatedPlanNotes(QString(d->notes));
// throw away the cache
free(cache);
#if DEBUG_PLAN
save_dive(stderr, d);
dump_plan(&diveplan);
#endif
}
void DivePlannerPointsModel::deleteTemporaryPlan()
{
free_dps(&diveplan);
}
void DivePlannerPointsModel::savePlan()
{
createPlan(false);
}
void DivePlannerPointsModel::saveDuplicatePlan()
{
createPlan(true);
}
struct divedatapoint *DivePlannerPointsModel::cloneDiveplan(struct diveplan *plan_src, struct diveplan *plan_copy)
{
divedatapoint *src, *last_segment;
divedatapoint **dp;
src = plan_src->dp;
*plan_copy = *plan_src;
dp = &plan_copy->dp;
while (src && (!src->time || src->entered)) {
*dp = (struct divedatapoint *)malloc(sizeof(struct divedatapoint));
**dp = *src;
dp = &(*dp)->next;
src = src->next;
}
(*dp) = NULL;
last_segment = plan_copy->dp;
while (last_segment && last_segment->next && last_segment->next->next)
last_segment = last_segment->next;
return last_segment;
}
int DivePlannerPointsModel::analyzeVariations(struct decostop *min, struct decostop *mid, struct decostop *max, const char *unit)
{
int minsum = 0;
int midsum = 0;
int maxsum = 0;
int leftsum = 0;
int rightsum = 0;
while (min->depth) {
minsum += min->time;
++min;
}
while (mid->depth) {
midsum += mid->time;
++mid;
}
while (max->depth) {
maxsum += max->time;
++max;
}
leftsum = midsum - minsum;
rightsum = maxsum - midsum;
#ifdef DEBUG_STOPVAR
printf("Total + %d:%02d/%s +- %d s/%s\n\n", FRACTION((leftsum + rightsum) / 2, 60), unit,
(rightsum - leftsum) / 2, unit);
#else
Q_UNUSED(unit)
#endif
return (leftsum + rightsum) / 2;
}
void DivePlannerPointsModel::computeVariationsFreeDeco(struct diveplan *original_plan, struct deco_state *previous_ds)
{
computeVariations(original_plan, previous_ds);
delete previous_ds;
}
void DivePlannerPointsModel::computeVariations(struct diveplan *original_plan, const struct deco_state *previous_ds)
{
// nothing to do unless there's an original plan
if (!original_plan)
return;
struct dive *dive = alloc_dive();
copy_dive(d, dive);
struct decostop original[60], deeper[60], shallower[60], shorter[60], longer[60];
struct deco_state *cache = NULL, *save = NULL;
struct diveplan plan_copy;
struct divedatapoint *last_segment;
struct deco_state ds = *previous_ds;
if (isPlanner() && prefs.display_variations && decoMode(true) != RECREATIONAL) {
int my_instance = ++instanceCounter;
cache_deco_state(&ds, &save);
duration_t delta_time = { .seconds = 60 };
QString time_units = tr("min");
depth_t delta_depth;
QString depth_units;
if (prefs.units.length == units::METERS) {
delta_depth.mm = 1000; // 1m
depth_units = tr("m");
} else {
delta_depth.mm = feet_to_mm(1.0); // 1ft
depth_units = tr("ft");
}
last_segment = cloneDiveplan(original_plan, &plan_copy);
if (!last_segment)
goto finish;
if (my_instance != instanceCounter)
goto finish;
plan(&ds, &plan_copy, dive, 1, original, &cache, true, false);
free_dps(&plan_copy);
restore_deco_state(save, &ds, false);
last_segment = cloneDiveplan(original_plan, &plan_copy);
last_segment->depth.mm += delta_depth.mm;
last_segment->next->depth.mm += delta_depth.mm;
if (my_instance != instanceCounter)
goto finish;
plan(&ds, &plan_copy, dive, 1, deeper, &cache, true, false);
free_dps(&plan_copy);
restore_deco_state(save, &ds, false);
last_segment = cloneDiveplan(original_plan, &plan_copy);
last_segment->depth.mm -= delta_depth.mm;
last_segment->next->depth.mm -= delta_depth.mm;
if (my_instance != instanceCounter)
goto finish;
plan(&ds, &plan_copy, dive, 1, shallower, &cache, true, false);
free_dps(&plan_copy);
restore_deco_state(save, &ds, false);
last_segment = cloneDiveplan(original_plan, &plan_copy);
last_segment->next->time += delta_time.seconds;
if (my_instance != instanceCounter)
goto finish;
plan(&ds, &plan_copy, dive, 1, longer, &cache, true, false);
free_dps(&plan_copy);
restore_deco_state(save, &ds, false);
last_segment = cloneDiveplan(original_plan, &plan_copy);
last_segment->next->time -= delta_time.seconds;
if (my_instance != instanceCounter)
goto finish;
plan(&ds, &plan_copy, dive, 1, shorter, &cache, true, false);
free_dps(&plan_copy);
restore_deco_state(save, &ds, false);
char buf[200];
sprintf(buf, ", %s: + %d:%02d /%s + %d:%02d /min", qPrintable(tr("Stop times")),
FRACTION(analyzeVariations(shallower, original, deeper, qPrintable(depth_units)), 60), qPrintable(depth_units),
FRACTION(analyzeVariations(shorter, original, longer, qPrintable(time_units)), 60));
// By using a signal, we can transport the variations to the main thread.
emit variationsComputed(QString(buf));
#ifdef DEBUG_STOPVAR
printf("\n\n");
#endif
}
finish:
free_dps(original_plan);
free(original_plan);
free(save);
free(cache);
free(dive);
}
void DivePlannerPointsModel::computeVariationsDone(QString variations)
{
QString notes = QString(d->notes);
free(d->notes);
d->notes = copy_qstring(notes.replace("VARIATIONS", variations));
emit calculatedPlanNotes(QString(d->notes));
}
void DivePlannerPointsModel::createPlan(bool replanCopy)
{
// Ok, so, here the diveplan creates a dive
struct deco_state *cache = NULL;
removeDeco();
createTemporaryPlan();
//TODO: C-based function here?
struct decostop stoptable[60];
plan(&ds_after_previous_dives, &diveplan, d, DECOTIMESTEP, stoptable, &cache, isPlanner(), true);
struct diveplan *plan_copy;
plan_copy = (struct diveplan *)malloc(sizeof(struct diveplan));
lock_planner();
cloneDiveplan(&diveplan, plan_copy);
unlock_planner();
computeVariations(plan_copy, &ds_after_previous_dives);
free(cache);
// Fixup planner notes.
if (current_dive && d->id == current_dive->id) {
// Try to identify old planner output and remove only this part
// Treat user provided text as plain text.
QTextDocument notesDocument;
notesDocument.setHtml(current_dive->notes);
QString oldnotes(notesDocument.toPlainText());
QString disclaimer = get_planner_disclaimer();
int disclaimerMid = disclaimer.indexOf("%s");
QString disclaimerBegin, disclaimerEnd;
if (disclaimerMid >= 0) {
disclaimerBegin = disclaimer.left(disclaimerMid);
disclaimerEnd = disclaimer.mid(disclaimerMid + 2);
} else {
disclaimerBegin = disclaimer;
}
int disclaimerPositionStart = oldnotes.indexOf(disclaimerBegin);
if (disclaimerPositionStart >= 0) {
if (oldnotes.indexOf(disclaimerEnd, disclaimerPositionStart) >= 0) {
// We found a disclaimer according to the current locale.
// Remove the disclaimer and anything after the disclaimer, because
// that's supposedly the old planner notes.
oldnotes = oldnotes.left(disclaimerPositionStart);
}
}
// Deal with line breaks
oldnotes.replace("\n", "<br>");
oldnotes.append(d->notes);
d->notes = copy_qstring(oldnotes);
// If we save as new create a copy of the dive here
}
setPlanMode(NOTHING);
planCreated(); // This signal will exit the profile from planner state. This must be *before* adding the dive,
// so that the Undo-commands update the display accordingly (see condition in updateDiveInfo().
// Now, add or modify the dive.
if (!current_dive || d->id != current_dive->id) {
// we were planning a new dive, not re-planning an existing one
d->divetrip = nullptr; // Should not be necessary, just in case!
#if !defined(SUBSURFACE_TESTING)
Command::addDive(d, autogroup, true);
#endif // !SUBSURFACE_TESTING
} else {
copy_events_until(current_dive, d, preserved_until.seconds);
if (replanCopy) {
// we were planning an old dive and save as a new dive
d->id = dive_getUniqID(); // Things will break horribly if we create dives with the same id.
#if !defined(SUBSURFACE_TESTING)
Command::addDive(d, false, false);
#endif // !SUBSURFACE_TESTING
} else {
// we were planning an old dive and rewrite the plan
#if !defined(SUBSURFACE_TESTING)
Command::replanDive(d);
#endif // !SUBSURFACE_TESTING
}
}
// Remove and clean the diveplan, so we don't delete
// the dive by mistake.
free_dps(&diveplan);
}