// SPDX-License-Identifier: GPL-2.0 #include "command_divelist.h" #include "core/divelist.h" #include "core/display.h" // for amount_selected #include "core/qthelper.h" #include "core/selection.h" #include "core/subsurface-qt/divelistnotifier.h" #include "qt-models/filtermodels.h" #include "../profile-widget/profilewidget2.h" #include "core/divefilter.h" #include namespace Command { // This helper function removes a dive, takes ownership of the dive and adds it to a DiveToAdd structure. // If the trip the dive belongs to becomes empty, it is removed and added to the tripsToAdd vector. // It is crucial that dives are added in reverse order of deletion, so that the indices are correctly // set and that the trips are added before they are used! DiveToAdd DiveListBase::removeDive(struct dive *d, std::vector &tripsToAdd) { // If the dive was the current dive, reset the current dive. The calling // command is responsible of finding a new dive. if (d == current_dive) current_dive = nullptr; // remove dive from trip and site - if this is the last dive in the trip // remove the whole trip. DiveToAdd res; res.trip = unregister_dive_from_trip(d); if (d->dive_site) diveSiteCountChanged(d->dive_site); res.site = unregister_dive_from_dive_site(d); if (res.trip && res.trip->dives.nr == 0) { remove_trip(res.trip, &trip_table); // Remove trip from backend tripsToAdd.emplace_back(res.trip); // Take ownership of trip } int idx = get_divenr(d); if (idx < 0) qWarning("Deletion of unknown dive!"); if (!d->hidden_by_filter) --shown_dives; res.dive.reset(unregister_dive(idx)); // Remove dive from backend return res; } void DiveListBase::diveSiteCountChanged(struct dive_site *ds) { if (std::find(sitesCountChanged.begin(), sitesCountChanged.end(), ds) == sitesCountChanged.end()) sitesCountChanged.push_back(ds); } // This helper function adds a dive and returns ownership to the backend. It may also add a dive trip. // It is crucial that dives are added in reverse order of deletion (see comment above)! // Returns pointer to added dive (which is owned by the backend!) dive *DiveListBase::addDive(DiveToAdd &d) { if (d.trip) add_dive_to_trip(d.dive.get(), d.trip); if (d.site) { add_dive_to_dive_site(d.dive.get(), d.site); diveSiteCountChanged(d.site); } dive *res = d.dive.release(); // Give up ownership of dive // When we add dives, we start in hidden-by-filter status. Once all // dives have been added, their status will be updated. res->hidden_by_filter = true; int idx = dive_table_get_insertion_index(&dive_table, res); add_to_dive_table(&dive_table, idx, res); // Return ownership to backend invalidate_dive_cache(res); // Ensure that dive is written in git_save() return res; } // Some signals are sent in batches per trip. To avoid writing the same loop // twice, this template takes a vector of trip / dive pairs, sorts it // by trip and then calls a function-object with trip and a QVector of dives in that trip. // The dives are sorted by the dive_less_than() function defined in the core. // Input parameters: // - dives: a vector of trip,dive pairs, which will be sorted and processed in batches by trip. // - action: a function object, taking a trip-pointer and a QVector of dives, which will be called for each batch. template void processByTrip(std::vector> &dives, Function action) { // Sort lexicographically by trip then according to the dive_less_than() function. std::sort(dives.begin(), dives.end(), [](const std::pair &e1, const std::pair &e2) { return e1.first == e2.first ? dive_less_than(e1.second, e2.second) : e1.first < e2.first; }); // Then, process the dives in batches by trip size_t i, j; // Begin and end of batch for (i = 0; i < dives.size(); i = j) { dive_trip *trip = dives[i].first; for (j = i + 1; j < dives.size() && dives[j].first == trip; ++j) ; // pass // Copy dives into a QVector. Some sort of "range_view" would be ideal, but Qt doesn't work this way. QVector divesInTrip(j - i); for (size_t k = i; k < j; ++k) divesInTrip[k - i] = dives[k].second; // Finally, emit the signal action(trip, divesInTrip); } } // This helper function calls removeDive() on a list of dives to be removed and // returns a vector of corresponding DiveToAdd objects, which can later be readded. // Moreover, a vector of deleted trips is returned, if trips became empty. // The passed in vector is cleared. DivesAndTripsToAdd DiveListBase::removeDives(DivesAndSitesToRemove &divesAndSitesToDelete) { std::vector divesToAdd; std::vector tripsToAdd; std::vector sitesToAdd; divesToAdd.reserve(divesAndSitesToDelete.dives.size()); sitesToAdd.reserve(divesAndSitesToDelete.sites.size()); // Remember old number of shown dives int oldShown = shown_dives; // Make sure that the dive list is sorted. The added dives will be sent in a signal // and the recipients assume that the dives are sorted the same way as they are // in the core list. std::sort(divesAndSitesToDelete.dives.begin(), divesAndSitesToDelete.dives.end(), dive_less_than); for (dive *d: divesAndSitesToDelete.dives) divesToAdd.push_back(removeDive(d, tripsToAdd)); divesAndSitesToDelete.dives.clear(); for (dive_site *ds: divesAndSitesToDelete.sites) { int idx = unregister_dive_site(ds); sitesToAdd.emplace_back(ds); emit diveListNotifier.diveSiteDeleted(ds, idx); } divesAndSitesToDelete.sites.clear(); // We send one dives-deleted signal per trip (see comments in divelistnotifier.h). // Therefore, collect all dives in an array and sort by trip. std::vector> dives; dives.reserve(divesToAdd.size()); for (const DiveToAdd &entry: divesToAdd) dives.push_back({ entry.trip, entry.dive.get() }); // Send signals. processByTrip(dives, [&](dive_trip *trip, const QVector &divesInTrip) { // Check if this trip is supposed to be deleted, by checking if it was marked as "add it". bool deleteTrip = trip && std::find_if(tripsToAdd.begin(), tripsToAdd.end(), [trip](const OwningTripPtr &ptr) { return ptr.get() == trip; }) != tripsToAdd.end(); emit diveListNotifier.divesDeleted(trip, deleteTrip, divesInTrip); }); if (oldShown != shown_dives) emit diveListNotifier.numShownChanged(); return { std::move(divesToAdd), std::move(tripsToAdd), std::move(sitesToAdd) }; } // This helper function is the counterpart fo removeDives(): it calls addDive() on a list // of dives to be (re)added and returns a vector of the added dives. It does this in reverse // order, so that trips are created appropriately and indexing is correct. // The passed in vector is cleared. DivesAndSitesToRemove DiveListBase::addDives(DivesAndTripsToAdd &toAdd) { std::vector res; std::vector sites; std::vector> dives; res.resize(toAdd.dives.size()); sites.reserve(toAdd.sites.size()); dives.reserve(toAdd.sites.size()); // Make sure that the dive list is sorted. The added dives will be sent in a signal // and the recipients assume that the dives are sorted the same way as they are // in the core list. std::sort(toAdd.dives.begin(), toAdd.dives.end(), [](const DiveToAdd &d, const DiveToAdd &d2) { return dive_less_than(d.dive.get(), d2.dive.get()); }); // Now, add the dives // Note: the idiomatic STL-way would be std::transform, but let's use a loop since // that is closer to classical C-style. auto it2 = res.rbegin(); QVector divesToFilter; divesToFilter.reserve(toAdd.dives.size()); for (auto it = toAdd.dives.rbegin(); it != toAdd.dives.rend(); ++it, ++it2) { *it2 = addDive(*it); dives.push_back({ (*it2)->divetrip, *it2 }); divesToFilter.push_back(*it2); } toAdd.dives.clear(); ShownChange change = DiveFilter::instance()->update(divesToFilter); // If the dives belong to new trips, add these as well. // Remember the pointers so that we can later check if a trip was newly added std::vector addedTrips; addedTrips.reserve(toAdd.trips.size()); for (OwningTripPtr &trip: toAdd.trips) { addedTrips.push_back(trip.get()); insert_trip(trip.release(), &trip_table); // Return ownership to backend } toAdd.trips.clear(); // Finally, add any necessary dive sites for (OwningDiveSitePtr &ds: toAdd.sites) { sites.push_back(ds.get()); int idx = register_dive_site(ds.release()); // Return ownership to backend emit diveListNotifier.diveSiteAdded(sites.back(), idx); } toAdd.sites.clear(); // Send signals by trip. processByTrip(dives, [&](dive_trip *trip, const QVector &divesInTrip) { // Now, let's check if this trip is supposed to be created, by checking if it was marked as "add it". bool createTrip = trip && std::find(addedTrips.begin(), addedTrips.end(), trip) != addedTrips.end(); // Finally, emit the signal emit diveListNotifier.divesAdded(trip, createTrip, divesInTrip); }); if (!change.newShown.empty() || !change.newHidden.empty()) emit diveListNotifier.numShownChanged(); return { res, sites }; } // This helper function renumbers dives according to an array of id/number pairs. // The old numbers are stored in the array, thus calling this function twice has no effect. static void renumberDives(QVector> &divesToRenumber) { QVector dives; dives.reserve(divesToRenumber.size()); for (auto &pair: divesToRenumber) { dive *d = pair.first; if (!d) continue; std::swap(d->number, pair.second); dives.push_back(d); invalidate_dive_cache(d); } // Send signals. emit diveListNotifier.divesChanged(dives, DiveField::NR); } // This helper function moves a dive to a trip. The old trip is recorded in the // passed-in structure. This means that calling the function twice on the same // object is a no-op concerning the dive. If the old trip was deleted from the // core, an owning pointer to the removed trip is returned, otherwise a null pointer. static OwningTripPtr moveDiveToTrip(DiveToTrip &diveToTrip) { // Firstly, check if we move to the same trip and bail if this is a no-op. if (diveToTrip.trip == diveToTrip.dive->divetrip) return {}; // Remove from old trip OwningTripPtr res; // Remove dive from trip - if this is the last dive in the trip, remove the whole trip. dive_trip *trip = unregister_dive_from_trip(diveToTrip.dive); if (trip && trip->dives.nr == 0) { remove_trip(trip, &trip_table); // Remove trip from backend res.reset(trip); } // Store old trip and get new trip we should associate this dive with std::swap(trip, diveToTrip.trip); if (trip) add_dive_to_trip(diveToTrip.dive, trip); invalidate_dive_cache(diveToTrip.dive); // Ensure that dive is written in git_save() return res; } // This helper function moves a set of dives between trips using the // moveDiveToTrip function. Before doing so, it adds the necessary trips to // the core. Trips that are removed from the core because they are empty // are recorded in the passed in struct. The vectors of trips and dives // are reversed. Thus, calling the function twice on the same object is // a no-op. static void moveDivesBetweenTrips(DivesToTrip &dives) { // We collect an array of created trips so that we can instruct // the model to create a new entry std::vector createdTrips; createdTrips.reserve(dives.tripsToAdd.size()); // First, bring back the trip(s) for (OwningTripPtr &trip: dives.tripsToAdd) { dive_trip *t = trip.release(); // Give up ownership createdTrips.push_back(t); insert_trip(t, &trip_table); // Return ownership to backend } dives.tripsToAdd.clear(); for (DiveToTrip &dive: dives.divesToMove) { OwningTripPtr tripToAdd = moveDiveToTrip(dive); // register trips that we'll have to readd if (tripToAdd) dives.tripsToAdd.push_back(std::move(tripToAdd)); } // We send one signal per from-trip/to-trip pair. // First, collect all dives in a struct and sort by from-trip/to-trip. struct DiveMoved { dive_trip *from; dive_trip *to; dive *d; }; std::vector divesMoved; divesMoved.reserve(dives.divesToMove.size()); for (const DiveToTrip &entry: dives.divesToMove) divesMoved.push_back({ entry.trip, entry.dive->divetrip, entry.dive }); // Sort lexicographically by from-trip, to-trip and by start-time. // Use std::tie() for lexicographical sorting. std::sort(divesMoved.begin(), divesMoved.end(), [] ( const DiveMoved &d1, const DiveMoved &d2) { return std::tie(d1.from, d1.to, d1.d->when) < std::tie(d2.from, d2.to, d2.d->when); }); // Now, process the dives in batches by trip // TODO: this is a bit different from the cases above, so we don't use the processByTrip template, // but repeat the loop here. We might think about generalizing the template, if more of such // "special cases" appear. size_t i, j; // Begin and end of batch for (i = 0; i < divesMoved.size(); i = j) { dive_trip *from = divesMoved[i].from; dive_trip *to = divesMoved[i].to; for (j = i + 1; j < divesMoved.size() && divesMoved[j].from == from && divesMoved[j].to == to; ++j) ; // pass // Copy dives into a QVector. Some sort of "range_view" would be ideal, but Qt doesn't work this way. QVector divesInTrip(j - i); for (size_t k = i; k < j; ++k) divesInTrip[k - i] = divesMoved[k].d; // Check if the from-trip was deleted: If yes, it was recorded in the tripsToAdd structure. // Only set the flag if this is that last time this trip is featured. bool deleteFrom = from && std::find_if(divesMoved.begin() + j, divesMoved.end(), // Is this the last occurence of "from"? [from](const DiveMoved &entry) { return entry.from == from; }) == divesMoved.end() && std::find_if(dives.tripsToAdd.begin(), dives.tripsToAdd.end(), // Is "from" in tripsToAdd? [from](const OwningTripPtr &trip) { return trip.get() == from; }) != dives.tripsToAdd.end(); // Check if the to-trip has to be created. For this purpose, we saved an array of trips to be created. bool createTo = false; if (to) { // Check if the element is there... auto it = std::find(createdTrips.begin(), createdTrips.end(), to); // ...if it is - remove it as we don't want the model to create the trip twice! if (it != createdTrips.end()) { createTo = true; // erase/remove would be more performant, but this is irrelevant in the big scheme of things. createdTrips.erase(it); } } // Finally, emit the signal emit diveListNotifier.divesMovedBetweenTrips(from, to, deleteFrom, createTo, divesInTrip); } // Reverse the tripsToAdd and the divesToAdd, so that on undo/redo the operations // will be performed in reverse order. std::reverse(dives.tripsToAdd.begin(), dives.tripsToAdd.end()); std::reverse(dives.divesToMove.begin(), dives.divesToMove.end()); } void DiveListBase::initWork() { } void DiveListBase::finishWork() { for (dive_site *ds: sitesCountChanged) emit diveListNotifier.diveSiteDiveCountChanged(ds); } void DiveListBase::undo() { auto marker = diveListNotifier.enterCommand(); initWork(); undoit(); finishWork(); } void DiveListBase::redo() { auto marker = diveListNotifier.enterCommand(); initWork(); redoit(); finishWork(); } AddDive::AddDive(dive *d, bool autogroup, bool newNumber) { setText(Command::Base::tr("add dive")); // By convention, d is a pointer to "displayed dive" or a temporary variable and can be overwritten. d->maxdepth.mm = 0; d->dc.maxdepth.mm = 0; fixup_dive(d); // this only matters if undoit were called before redoit currentDive = nullptr; // Get an owning pointer to a moved dive. OwningDivePtr divePtr(move_dive(d)); divePtr->selected = false; // If we clone a planned dive, it might have been selected. // We have to clear the flag, as selections will be managed // on dive-addition. // If we alloc a new-trip for autogrouping, get an owning pointer to it. OwningTripPtr allocTrip; dive_trip *trip = divePtr->divetrip; dive_site *site = divePtr->dive_site; // We have to delete the pointers to trip and site, because this would prevent the core from adding to the // trip or site and we would get the count-of-dives in the trip or site wrong. Yes, that's all horribly subtle! divePtr->divetrip = nullptr; divePtr->dive_site = nullptr; if (!trip && autogroup) { bool alloc; trip = get_trip_for_new_dive(divePtr.get(), &alloc); if (alloc) allocTrip.reset(trip); } int idx = dive_table_get_insertion_index(&dive_table, divePtr.get()); if (newNumber) divePtr->number = get_dive_nr_at_idx(idx); divesToAdd.dives.push_back({ std::move(divePtr), trip, site }); if (allocTrip) divesToAdd.trips.push_back(std::move(allocTrip)); } bool AddDive::workToBeDone() { return true; } void AddDive::redoit() { // Remember selection so that we can undo it selection = getDiveSelection(); currentDive = current_dive; divesAndSitesToRemove = addDives(divesToAdd); sort_trip_table(&trip_table); // Though unlikely, adding a dive may reorder trips // Select the newly added dive setSelection(divesAndSitesToRemove.dives, divesAndSitesToRemove.dives[0]); } void AddDive::undoit() { // Simply remove the dive that was previously added... divesToAdd = removeDives(divesAndSitesToRemove); sort_trip_table(&trip_table); // Though unlikely, removing a dive may reorder trips // ...and restore the selection setSelection(selection, currentDive); } ImportDives::ImportDives(struct dive_table *dives, struct trip_table *trips, struct dive_site_table *sites, int flags, const QString &source) { setText(Command::Base::tr("import %n dive(s) from %1", "", dives->nr).arg(source)); // this only matters if undoit were called before redoit currentDive = nullptr; struct dive_table dives_to_add = empty_dive_table; struct dive_table dives_to_remove = empty_dive_table; struct trip_table trips_to_add = empty_trip_table; struct dive_site_table sites_to_add = empty_dive_site_table; process_imported_dives(dives, trips, sites, flags, &dives_to_add, &dives_to_remove, &trips_to_add, &sites_to_add); // Add trips to the divesToAdd.trips structure divesToAdd.trips.reserve(trips_to_add.nr); for (int i = 0; i < trips_to_add.nr; ++i) divesToAdd.trips.emplace_back(trips_to_add.trips[i]); // Add sites to the divesToAdd.sites structure divesToAdd.sites.reserve(sites_to_add.nr); for (int i = 0; i < sites_to_add.nr; ++i) divesToAdd.sites.emplace_back(sites_to_add.dive_sites[i]); // Add dives to the divesToAdd.dives structure divesToAdd.dives.reserve(dives_to_add.nr); for (int i = 0; i < dives_to_add.nr; ++i) { OwningDivePtr divePtr(dives_to_add.dives[i]); divePtr->selected = false; // See above in AddDive::AddDive() dive_trip *trip = divePtr->divetrip; divePtr->divetrip = nullptr; // See above in AddDive::AddDive() dive_site *site = divePtr->dive_site; divePtr->dive_site = nullptr; // See above in AddDive::AddDive() divesToAdd.dives.push_back({ std::move(divePtr), trip, site }); } // Add dive to be deleted to the divesToRemove structure divesAndSitesToRemove.dives.reserve(dives_to_remove.nr); for (int i = 0; i < dives_to_remove.nr; ++i) divesAndSitesToRemove.dives.push_back(dives_to_remove.dives[i]); } bool ImportDives::workToBeDone() { return !divesToAdd.dives.empty(); } void ImportDives::redoit() { // Remember selection so that we can undo it currentDive = current_dive; // Add new dives and sites DivesAndSitesToRemove divesAndSitesToRemoveNew = addDives(divesToAdd); // Remove old dives and sites divesToAdd = removeDives(divesAndSitesToRemove); // Select the newly added dives setSelection(divesAndSitesToRemoveNew.dives, divesAndSitesToRemoveNew.dives.back()); // Remember dives and sites to remove divesAndSitesToRemove = std::move(divesAndSitesToRemoveNew); } void ImportDives::undoit() { // Add new dives and sites DivesAndSitesToRemove divesAndSitesToRemoveNew = addDives(divesToAdd); // Remove old dives and sites divesToAdd = removeDives(divesAndSitesToRemove); // Remember dives and sites to remove divesAndSitesToRemove = std::move(divesAndSitesToRemoveNew); // ...and restore the selection setSelection(selection, currentDive); } DeleteDive::DeleteDive(const QVector &divesToDeleteIn) { divesToDelete.dives = std::vector(divesToDeleteIn.begin(), divesToDeleteIn.end()); setText(QStringLiteral("%1 [%2]").arg(Command::Base::tr("delete %n dive(s)", "", divesToDelete.dives.size())).arg(getListOfDives(divesToDelete.dives))); } bool DeleteDive::workToBeDone() { return !divesToDelete.dives.empty(); } void DeleteDive::undoit() { divesToDelete = addDives(divesToAdd); sort_trip_table(&trip_table); // Though unlikely, removing a dive may reorder trips // Select all re-added dives and make the first one current dive *currentDive = !divesToDelete.dives.empty() ? divesToDelete.dives[0] : nullptr; setSelection(divesToDelete.dives, currentDive); } void DeleteDive::redoit() { divesToAdd = removeDives(divesToDelete); sort_trip_table(&trip_table); // Though unlikely, adding a dive may reorder trips // Deselect all dives and select dive that was close to the first deleted dive dive *newCurrent = nullptr; if (!divesToAdd.dives.empty()) { timestamp_t when = divesToAdd.dives[0].dive->when; newCurrent = find_next_visible_dive(when); } select_single_dive(newCurrent); } ShiftTime::ShiftTime(std::vector changedDives, int amount) : diveList(changedDives), timeChanged(amount) { setText(QStringLiteral("%1 [%2]").arg(Command::Base::tr("shift time of %n dives", "", changedDives.size())).arg(getListOfDives(changedDives))); } void ShiftTime::redoit() { std::vector trips; for (dive *d: diveList) { d->when += timeChanged; if (d->divetrip && std::find(trips.begin(), trips.end(), d->divetrip) == trips.end()) trips.push_back(d->divetrip); } // Changing times may have unsorted the dive and trip tables sort_dive_table(&dive_table); sort_trip_table(&trip_table); for (dive_trip *trip: trips) sort_dive_table(&trip->dives); // Keep the trip-table in order // Send signals QVector dives = QVector::fromStdVector(diveList); emit diveListNotifier.divesTimeChanged(timeChanged, dives); emit diveListNotifier.divesChanged(dives, DiveField::DATETIME); // Select the changed dives setSelection(diveList, diveList[0]); // Negate the time-shift so that the next call does the reverse timeChanged = -timeChanged; } bool ShiftTime::workToBeDone() { return !diveList.empty(); } void ShiftTime::undoit() { // Same as redoit(), since after redoit() we reversed the timeOffset redoit(); } RenumberDives::RenumberDives(const QVector> &divesToRenumberIn) : divesToRenumber(divesToRenumberIn) { std::vector dives; dives.reserve(divesToRenumber.length()); for (QPairdivePlusNumber: divesToRenumber) dives.push_back(divePlusNumber.first); setText(QStringLiteral("%1 [%2]").arg(Command::Base::tr("renumber %n dive(s)", "", divesToRenumber.count())).arg(getListOfDives(dives))); } void RenumberDives::undoit() { renumberDives(divesToRenumber); // Select the changed dives std::vector dives; dives.reserve(divesToRenumber.size()); for (const QPair &item: divesToRenumber) dives.push_back(item.first); setSelection(dives, dives[0]); } bool RenumberDives::workToBeDone() { return !divesToRenumber.isEmpty(); } void RenumberDives::redoit() { // Redo and undo do the same thing! undoit(); } bool TripBase::workToBeDone() { return !divesToMove.divesToMove.empty(); } void TripBase::redoit() { moveDivesBetweenTrips(divesToMove); sort_trip_table(&trip_table); // Though unlikely, moving dives may reorder trips // Select the moved dives std::vector dives; dives.reserve(divesToMove.divesToMove.size()); for (const DiveToTrip &item: divesToMove.divesToMove) dives.push_back(item.dive); setSelection(dives, dives[0]); } void TripBase::undoit() { // Redo and undo do the same thing! redoit(); } RemoveDivesFromTrip::RemoveDivesFromTrip(const QVector &divesToRemove) { setText(QStringLiteral("%1 [%2]").arg(Command::Base::tr("remove %n dive(s) from trip", "", divesToRemove.size())).arg(getListOfDives(divesToRemove))); divesToMove.divesToMove.reserve(divesToRemove.size()); for (dive *d: divesToRemove) { // If a user manually removes a dive from a trip, don't autogroup this dive. // The flag will not be reset on undo, but that should be acceptable. d->notrip = true; divesToMove.divesToMove.push_back( {d, nullptr} ); } } RemoveAutogenTrips::RemoveAutogenTrips() { setText(Command::Base::tr("remove autogenerated trips")); // TODO: don't touch core-innards directly int i; struct dive *dive; for_each_dive(i, dive) { if (dive->divetrip && dive->divetrip->autogen) divesToMove.divesToMove.push_back( {dive, nullptr} ); } } AddDivesToTrip::AddDivesToTrip(const QVector &divesToAddIn, dive_trip *trip) { setText(QStringLiteral("%1 [%2]").arg(Command::Base::tr("add %n dives to trip", "", divesToAddIn.size())).arg(getListOfDives(divesToAddIn))); for (dive *d: divesToAddIn) divesToMove.divesToMove.push_back( {d, trip} ); } CreateTrip::CreateTrip(const QVector &divesToAddIn) { setText(Command::Base::tr("create trip")); if (divesToAddIn.isEmpty()) return; dive_trip *trip = create_trip_from_dive(divesToAddIn[0]); divesToMove.tripsToAdd.emplace_back(trip); for (dive *d: divesToAddIn) divesToMove.divesToMove.push_back( {d, trip} ); } AutogroupDives::AutogroupDives() { setText(Command::Base::tr("autogroup dives")); dive_trip *trip; bool alloc; int from, to; for(int i = 0; (trip = get_dives_to_autogroup(&dive_table, i, &from, &to, &alloc)) != NULL; i = to) { // If this is an allocated trip, take ownership if (alloc) divesToMove.tripsToAdd.emplace_back(trip); for (int j = from; j < to; ++j) divesToMove.divesToMove.push_back( { get_dive(j), trip } ); } } MergeTrips::MergeTrips(dive_trip *trip1, dive_trip *trip2) { if (trip1 == trip2) return; dive_trip *newTrip = combine_trips(trip1, trip2); divesToMove.tripsToAdd.emplace_back(newTrip); for (int i = 0; i < trip1->dives.nr; ++i) divesToMove.divesToMove.push_back( { trip1->dives.dives[i], newTrip } ); for (int i = 0; i < trip2->dives.nr; ++i) divesToMove.divesToMove.push_back( { trip2->dives.dives[i], newTrip } ); } // std::array is the same as struct *dive[2], with the fundamental // difference that it can be returned from functions. Thus, this constructor // can be chained with the result of a function. SplitDivesBase::SplitDivesBase(dive *d, std::array newDives) { // If either of the new dives is null, simply return. Empty arrays indicate that nothing is to be done. if (!newDives[0] || !newDives[1]) return; // Currently, the core code selects the dive -> this is not what we want, as // we manually manage the selection post-command. // TODO: Reset selection in core. newDives[0]->selected = false; newDives[1]->selected = false; // The new dives will be registered to the dive site using the site member // of the DiveToAdd structure. For this to work, we must set the dive's // dive_site member to null. Yes, that's subtle! newDives[0]->dive_site = nullptr; newDives[1]->dive_site = nullptr; diveToSplit.dives.push_back(d); splitDives.dives.resize(2); splitDives.dives[0].dive.reset(newDives[0]); splitDives.dives[0].trip = d->divetrip; splitDives.dives[0].site = d->dive_site; splitDives.dives[1].dive.reset(newDives[1]); splitDives.dives[1].trip = d->divetrip; splitDives.dives[1].site = d->dive_site; } bool SplitDivesBase::workToBeDone() { return !diveToSplit.dives.empty(); } void SplitDivesBase::redoit() { divesToUnsplit = addDives(splitDives); unsplitDive = removeDives(diveToSplit); // Select split dives and make first dive current setSelection(divesToUnsplit.dives, divesToUnsplit.dives[0]); } void SplitDivesBase::undoit() { // Note: reverse order with respect to redoit() diveToSplit = addDives(unsplitDive); splitDives = removeDives(divesToUnsplit); // Select unsplit dive and make it current setSelection(diveToSplit.dives, diveToSplit.dives[0] ); } static std::array doSplitDives(const dive *d, duration_t time) { // Split the dive dive *new1, *new2; if (time.seconds < 0) split_dive(d, &new1, &new2); else split_dive_at_time(d, time, &new1, &new2); return { new1, new2 }; } SplitDives::SplitDives(dive *d, duration_t time) : SplitDivesBase(d, doSplitDives(d, time)) { setText(Command::Base::tr("split dive")); } static std::array splitDiveComputer(const dive *d, int dc_num) { // Refuse to do anything if the dive has only one dive computer. // Yes, this should have been checked by the UI, but let's just make sure. if (!d->dc.next) return { nullptr, nullptr}; dive *new1, *new2; split_divecomputer(d, dc_num, &new1, &new2); return { new1, new2 }; } SplitDiveComputer::SplitDiveComputer(dive *d, int dc_num) : SplitDivesBase(d, splitDiveComputer(d, dc_num)) { setText(Command::Base::tr("split dive computer")); } DiveComputerBase::DiveComputerBase(dive *old_dive, dive *new_dive, int dc_nr_after_in) : dc_nr_before(dc_number), dc_nr_after(dc_nr_after_in) { if (!new_dive) return; diveToRemove.dives.push_back(old_dive); // Currently, the core code selects the dive -> this is not what we want, as // we manually manage the selection post-command. // TODO: Reset selection in core. new_dive->selected = false; // Reset references to trip and site in the new dive, as the undo command // will add the dive to the trip and site. new_dive->divetrip = nullptr; new_dive->dive_site = nullptr; diveToAdd.dives.resize(1); diveToAdd.dives[0].dive.reset(new_dive); diveToAdd.dives[0].trip = old_dive->divetrip; diveToAdd.dives[0].site = old_dive->dive_site; } bool DiveComputerBase::workToBeDone() { return !diveToRemove.dives.empty() || !diveToAdd.dives.empty(); } void DiveComputerBase::redoit() { DivesAndSitesToRemove addedDive = addDives(diveToAdd); diveToAdd = removeDives(diveToRemove); diveToRemove = std::move(addedDive); dc_number = dc_nr_after; // Select added dive and make it current. // This automatically replots the profile. setSelection(diveToRemove.dives, diveToRemove.dives[0]); std::swap(dc_nr_before, dc_nr_after); } void DiveComputerBase::undoit() { // Undo and redo do the same redoit(); } MoveDiveComputerToFront::MoveDiveComputerToFront(dive *d, int dc_num) : DiveComputerBase(d, make_first_dc(d, dc_num), 0) { setText(Command::Base::tr("move dive computer to front")); } DeleteDiveComputer::DeleteDiveComputer(dive *d, int dc_num) : DiveComputerBase(d, clone_delete_divecomputer(d, dc_num), std::min(count_divecomputers(d) - 1, dc_num)) { setText(Command::Base::tr("delete dive computer")); } MergeDives::MergeDives(const QVector &dives) { setText(Command::Base::tr("merge dive")); // Just a safety check - if there's not two or more dives - do nothing // The caller should have made sure that this doesn't happen. if (dives.count() < 2) { qWarning("Merging less than two dives"); return; } dive_trip *preferred_trip; dive_site *preferred_site; OwningDivePtr d(merge_dives(dives[0], dives[1], dives[1]->when - dives[0]->when, false, &preferred_trip, &preferred_site)); // Currently, the core code selects the dive -> this is not what we want, as // we manually manage the selection post-command. // TODO: Remove selection code from core. d->selected = false; // Set the preferred dive trip, so that for subsequent merges the better trip can be selected d->divetrip = preferred_trip; for (int i = 2; i < dives.count(); ++i) { d.reset(merge_dives(d.get(), dives[i], dives[i]->when - d->when, false, &preferred_trip, &preferred_site)); // Set the preferred dive trip and site, so that for subsequent merges the better trip and site can be selected d->divetrip = preferred_trip; d->dive_site = preferred_site; } // We got our preferred trip and site, so now the references can be deleted from the newly generated dive d->divetrip = nullptr; d->dive_site = nullptr; // The merged dive gets the number of the first dive with a non-zero number for (const dive *dive: dives) { if (dive->number) { d->number = dive->number; break; } } // We will only renumber the remaining dives if the joined dives are consecutive. // Otherwise all bets are off concerning what the user wanted and doing nothing seems // like the best option. int idx = get_divenr(dives[0]); int num = dives.count(); if (idx < 0 || idx + num > dive_table.nr) { // It was the callers responsibility to pass only known dives. // Something is seriously wrong - give up. qWarning("Merging unknown dives"); return; } // std::equal compares two ranges. The parameters are (begin_range1, end_range1, begin_range2). // Here, we can compare C-arrays, because QVector guarantees contiguous storage. if (std::equal(&dives[0], &dives[0] + num, &dive_table.dives[idx]) && dives[0]->number && dives.last()->number && dives[0]->number < dives.last()->number) { // We have a consecutive set of dives. Rename all following dives according to the // number of erased dives. This considers that there might be missing numbers. // Comment copied from core/divelist.c: // So if you had a dive list 1 3 6 7 8, and you // merge 1 and 3, the resulting numbered list will // be 1 4 5 6, because we assume that there were // some missing dives (originally dives 4 and 5), // that now will still be missing (dives 2 and 3 // in the renumbered world). // // Obviously the normal case is that everything is // consecutive, and the difference will be 1, so the // above example is not supposed to be normal. int diff = dives.last()->number - dives[0]->number; divesToRenumber.reserve(dive_table.nr - idx - num); int previousnr = dives[0]->number; for (int i = idx + num; i < dive_table.nr; ++i) { int newnr = dive_table.dives[i]->number - diff; // Stop renumbering if stuff isn't in order (see also core/divelist.c) if (newnr <= previousnr) break; divesToRenumber.append(QPair(dive_table.dives[i], newnr)); previousnr = newnr; } } mergedDive.dives.resize(1); mergedDive.dives[0].dive = std::move(d); mergedDive.dives[0].trip = preferred_trip; mergedDive.dives[0].site = preferred_site; divesToMerge.dives = std::vector(dives.begin(), dives.end()); } bool MergeDives::workToBeDone() { return !mergedDive.dives.empty(); } void MergeDives::redoit() { renumberDives(divesToRenumber); diveToUnmerge = addDives(mergedDive); unmergedDives = removeDives(divesToMerge); // Select merged dive and make it current setSelection(diveToUnmerge.dives, diveToUnmerge.dives[0]); } void MergeDives::undoit() { divesToMerge = addDives(unmergedDives); mergedDive = removeDives(diveToUnmerge); renumberDives(divesToRenumber); // Select unmerged dives and make first one current setSelection(divesToMerge.dives, divesToMerge.dives[0]); } } // namespace Command