/* * This file is part of OpenTTD. * OpenTTD 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 2. * OpenTTD 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 OpenTTD. If not, see . */ /** @file tracerestrict.cpp Main file for Trace Restrict */ #include "stdafx.h" #include "tracerestrict.h" #include "train.h" #include "core/bitmath_func.hpp" #include "core/container_func.hpp" #include "core/pool_func.hpp" #include "command_func.h" #include "company_func.h" #include "viewport_func.h" #include "window_func.h" #include "order_base.h" #include "cargotype.h" #include "group.h" #include "string_func.h" #include "pathfinder/yapf/yapf_cache.h" #include "scope_info.h" #include "vehicle_func.h" #include "date_func.h" #include "3rdparty/cpp-btree/btree_map.h" #include #include #include "safeguards.h" /** @file * * Trace Restrict Data Storage Model Notes: * * Signals may have 0, 1 or 2 trace restrict programs attached to them, * up to one for each track. Two-way signals share the same program. * * The mapping between signals and programs is defined in terms of * TraceRestrictRefId to TraceRestrictProgramID, * where TraceRestrictRefId is formed of the tile index and track, * and TraceRestrictProgramID is an index into the program pool. * * If one or more mappings exist for a given signal tile, bit 12 of M3 will be set to 1. * This is updated whenever mappings are added/removed for that tile. This is to avoid * needing to do a mapping lookup for the common case where there is no trace restrict * program mapping for the given tile. * * Programs in the program pool are refcounted based on the number of mappings which exist. * When this falls to 0, the program is deleted from the pool. * If a program has a refcount greater than 1, it is a shared program. * * In all cases, an empty program is evaluated the same as the absence of a program. * Therefore it is not necessary to store mappings to empty unshared programs. * Any editing action which would otherwise result in a mapping to an empty program * which has no other references, instead removes the mapping. * This is not done for shared programs as this would delete the shared aspect whenever * the program became empty. * * Special case: In the case where an empty program with refcount 2 has one of its * mappings removed, the other mapping is left pointing to an empty unshared program. * This other mapping is then removed by performing a linear search of the mappings, * and removing the reference to that program ID. */ TraceRestrictProgramPool _tracerestrictprogram_pool("TraceRestrictProgram"); INSTANTIATE_POOL_METHODS(TraceRestrictProgram) TraceRestrictSlotPool _tracerestrictslot_pool("TraceRestrictSlot"); INSTANTIATE_POOL_METHODS(TraceRestrictSlot) TraceRestrictCounterPool _tracerestrictcounter_pool("TraceRestrictCounter"); INSTANTIATE_POOL_METHODS(TraceRestrictCounter) /** * TraceRestrictRefId --> TraceRestrictProgramID (Pool ID) mapping * The indirection is mainly to enable shared programs * TODO: use a more efficient container/indirection mechanism */ TraceRestrictMapping _tracerestrictprogram_mapping; /** * List of pre-defined pathfinder penalty values * This is indexed by TraceRestrictPathfinderPenaltyPresetIndex */ const uint16_t _tracerestrict_pathfinder_penalty_preset_values[] = { 500, 2000, 8000, }; static_assert(lengthof(_tracerestrict_pathfinder_penalty_preset_values) == TRPPPI_END); /** * This should be used when all pools have been or are immediately about to be also cleared * Calling this at other times will leave dangling refcounts */ void ClearTraceRestrictMapping() { _tracerestrictprogram_mapping.clear(); } /** * Flags used for the program execution condition stack * Each 'if' pushes onto the stack * Each 'end if' pops from the stack * Elif/orif/else may modify the stack top */ enum TraceRestrictCondStackFlags { TRCSF_DONE_IF = 1<<0, ///< The if/elif/else is "done", future elif/else branches will not be executed TRCSF_SEEN_ELSE = 1<<1, ///< An else branch has been seen already, error if another is seen afterwards TRCSF_ACTIVE = 1<<2, ///< The condition is currently active TRCSF_PARENT_INACTIVE = 1<<3, ///< The parent condition is not active, thus this condition is also not active }; DECLARE_ENUM_AS_BIT_SET(TraceRestrictCondStackFlags) /** * Helper function to handle condition stack manipulatoin */ static void HandleCondition(std::vector &condstack, TraceRestrictCondFlags condflags, bool value) { if (condflags & TRCF_OR) { assert(!condstack.empty()); if (condstack.back() & TRCSF_ACTIVE) { // leave TRCSF_ACTIVE set return; } } if (condflags & (TRCF_OR | TRCF_ELSE)) { assert(!condstack.empty()); if (condstack.back() & (TRCSF_DONE_IF | TRCSF_PARENT_INACTIVE)) { condstack.back() &= ~TRCSF_ACTIVE; return; } } else { if (!condstack.empty() && !(condstack.back() & TRCSF_ACTIVE)) { //this is a 'nested if', the 'parent if' is not active condstack.push_back(TRCSF_PARENT_INACTIVE); return; } condstack.push_back(static_cast(0)); } if (value) { condstack.back() |= TRCSF_DONE_IF | TRCSF_ACTIVE; } else { condstack.back() &= ~TRCSF_ACTIVE; } } /** * Integer condition testing * Test value op condvalue */ static bool TestCondition(int value, TraceRestrictCondOp condop, int condvalue) { switch (condop) { case TRCO_IS: return value == condvalue; case TRCO_ISNOT: return value != condvalue; case TRCO_LT: return value < condvalue; case TRCO_LTE: return value <= condvalue; case TRCO_GT: return value > condvalue; case TRCO_GTE: return value >= condvalue; default: NOT_REACHED(); return false; } } /** * Binary condition testing helper function */ static bool TestBinaryConditionCommon(TraceRestrictItem item, bool input) { switch (GetTraceRestrictCondOp(item)) { case TRCO_IS: return input; case TRCO_ISNOT: return !input; default: NOT_REACHED(); return false; } } /** * Test order condition * @p order may be nullptr */ static bool TestOrderCondition(const Order *order, TraceRestrictItem item) { bool result = false; if (order) { DestinationID condvalue = GetTraceRestrictValue(item); switch (static_cast(GetTraceRestrictAuxField(item))) { case TROCAF_STATION: result = (order->IsType(OT_GOTO_STATION) || order->IsType(OT_LOADING_ADVANCE)) && order->GetDestination() == condvalue; break; case TROCAF_WAYPOINT: result = order->IsType(OT_GOTO_WAYPOINT) && order->GetDestination() == condvalue; break; case TROCAF_DEPOT: result = order->IsType(OT_GOTO_DEPOT) && order->GetDestination() == condvalue; break; default: NOT_REACHED(); } } return TestBinaryConditionCommon(item, result); } /** * Test station condition */ static bool TestStationCondition(StationID station, TraceRestrictItem item) { bool result = (GetTraceRestrictAuxField(item) == TROCAF_STATION) && (station == GetTraceRestrictValue(item)); return TestBinaryConditionCommon(item, result); } /** * Execute program on train and store results in out * @p v may not be nullptr * @p out should be zero-initialised */ void TraceRestrictProgram::Execute(const Train* v, const TraceRestrictProgramInput &input, TraceRestrictProgramResult& out) const { /* static to avoid needing to re-alloc/resize on each execution */ static std::vector condstack; condstack.clear(); /* Only for use with TRPISP_PBS_RES_END_ACQ_DRY and TRPAUF_PBS_RES_END_SIMULATE */ static TraceRestrictSlotTemporaryState pbs_res_end_acq_dry_slot_temporary_state; byte have_previous_signal = 0; TileIndex previous_signal_tile[3]; size_t size = this->items.size(); for (size_t i = 0; i < size; i++) { TraceRestrictItem item = this->items[i]; TraceRestrictItemType type = GetTraceRestrictType(item); if (IsTraceRestrictConditional(item)) { TraceRestrictCondFlags condflags = GetTraceRestrictCondFlags(item); TraceRestrictCondOp condop = GetTraceRestrictCondOp(item); if (type == TRIT_COND_ENDIF) { assert(!condstack.empty()); if (condflags & TRCF_ELSE) { // else assert(!(condstack.back() & TRCSF_SEEN_ELSE)); HandleCondition(condstack, condflags, true); condstack.back() |= TRCSF_SEEN_ELSE; } else { // end if condstack.pop_back(); } } else { uint16_t condvalue = GetTraceRestrictValue(item); bool result = false; switch(type) { case TRIT_COND_UNDEFINED: result = false; break; case TRIT_COND_TRAIN_LENGTH: result = TestCondition(CeilDiv(v->gcache.cached_total_length, TILE_SIZE), condop, condvalue); break; case TRIT_COND_MAX_SPEED: result = TestCondition(v->GetDisplayMaxSpeed(), condop, condvalue); break; case TRIT_COND_CURRENT_ORDER: result = TestOrderCondition(&(v->current_order), item); break; case TRIT_COND_NEXT_ORDER: { if (v->orders == nullptr) break; if (v->orders->GetNumOrders() == 0) break; const Order *current_order = v->GetOrder(v->cur_real_order_index); for (const Order *order = v->orders->GetNext(current_order); order != current_order; order = v->orders->GetNext(order)) { if (order->IsGotoOrder()) { result = TestOrderCondition(order, item); break; } } break; } case TRIT_COND_LAST_STATION: result = TestStationCondition(v->last_station_visited, item); break; case TRIT_COND_CARGO: { bool have_cargo = false; for (const Vehicle *v_iter = v; v_iter != nullptr; v_iter = v_iter->Next()) { if (v_iter->cargo_type == GetTraceRestrictValue(item) && v_iter->cargo_cap > 0) { have_cargo = true; break; } } result = TestBinaryConditionCommon(item, have_cargo); break; } case TRIT_COND_ENTRY_DIRECTION: { bool direction_match; switch (GetTraceRestrictValue(item)) { case TRNTSV_NE: case TRNTSV_SE: case TRNTSV_SW: case TRNTSV_NW: direction_match = (static_cast(GetTraceRestrictValue(item)) == TrackdirToExitdir(ReverseTrackdir(input.trackdir))); break; case TRDTSV_FRONT: direction_match = (IsTileType(input.tile, MP_RAILWAY) && HasSignalOnTrackdir(input.tile, input.trackdir)) || IsTileType(input.tile, MP_TUNNELBRIDGE); break; case TRDTSV_BACK: direction_match = IsTileType(input.tile, MP_RAILWAY) && !HasSignalOnTrackdir(input.tile, input.trackdir); break; case TRDTSV_TUNBRIDGE_ENTER: direction_match = IsTunnelBridgeSignalSimulationEntranceTile(input.tile) && TrackdirEntersTunnelBridge(input.tile, input.trackdir); break; case TRDTSV_TUNBRIDGE_EXIT: direction_match = IsTunnelBridgeSignalSimulationExitTile(input.tile) && TrackdirExitsTunnelBridge(input.tile, input.trackdir); break; default: NOT_REACHED(); break; } result = TestBinaryConditionCommon(item, direction_match); break; } case TRIT_COND_PBS_ENTRY_SIGNAL: { // TRIT_COND_PBS_ENTRY_SIGNAL value type uses the next slot i++; TraceRestrictPBSEntrySignalAuxField mode = static_cast(GetTraceRestrictAuxField(item)); assert(mode == TRPESAF_VEH_POS || mode == TRPESAF_RES_END || mode == TRPESAF_RES_END_TILE); uint32_t signal_tile = this->items[i]; if (!HasBit(have_previous_signal, mode)) { if (input.previous_signal_callback) { previous_signal_tile[mode] = input.previous_signal_callback(v, input.previous_signal_ptr, mode); } else { previous_signal_tile[mode] = INVALID_TILE; } SetBit(have_previous_signal, mode); } bool match = (signal_tile != INVALID_TILE) && (previous_signal_tile[mode] == signal_tile); result = TestBinaryConditionCommon(item, match); break; } case TRIT_COND_TRAIN_GROUP: { result = TestBinaryConditionCommon(item, GroupIsInGroup(v->group_id, GetTraceRestrictValue(item))); break; } case TRIT_COND_TRAIN_IN_SLOT: { const TraceRestrictSlot *slot = TraceRestrictSlot::GetIfValid(GetTraceRestrictValue(item)); result = TestBinaryConditionCommon(item, slot != nullptr && slot->IsOccupant(v->index)); break; } case TRIT_COND_SLOT_OCCUPANCY: { // TRIT_COND_SLOT_OCCUPANCY value type uses the next slot i++; uint32_t value = this->items[i]; const TraceRestrictSlot *slot = TraceRestrictSlot::GetIfValid(GetTraceRestrictValue(item)); switch (static_cast(GetTraceRestrictAuxField(item))) { case TRSOCAF_OCCUPANTS: result = TestCondition(slot != nullptr ? (uint)slot->occupants.size() : 0, condop, value); break; case TRSOCAF_REMAINING: result = TestCondition(slot != nullptr ? slot->max_occupancy - (uint)slot->occupants.size() : 0, condop, value); break; default: NOT_REACHED(); break; } break; } case TRIT_COND_PHYS_PROP: { switch (static_cast(GetTraceRestrictAuxField(item))) { case TRPPCAF_WEIGHT: result = TestCondition(v->gcache.cached_weight, condop, condvalue); break; case TRPPCAF_POWER: result = TestCondition(v->gcache.cached_power, condop, condvalue); break; case TRPPCAF_MAX_TE: result = TestCondition(v->gcache.cached_max_te / 1000, condop, condvalue); break; default: NOT_REACHED(); break; } break; } case TRIT_COND_PHYS_RATIO: { switch (static_cast(GetTraceRestrictAuxField(item))) { case TRPPRCAF_POWER_WEIGHT: result = TestCondition(std::min(UINT16_MAX, (100 * v->gcache.cached_power) / std::max(1, v->gcache.cached_weight)), condop, condvalue); break; case TRPPRCAF_MAX_TE_WEIGHT: result = TestCondition(std::min(UINT16_MAX, (v->gcache.cached_max_te / 10) / std::max(1, v->gcache.cached_weight)), condop, condvalue); break; default: NOT_REACHED(); break; } break; } case TRIT_COND_TRAIN_OWNER: { result = TestBinaryConditionCommon(item, v->owner == condvalue); break; } case TRIT_COND_TRAIN_STATUS: { bool has_status = false; switch (static_cast(GetTraceRestrictValue(item))) { case TRTSVF_EMPTY: has_status = true; for (const Vehicle *v_iter = v; v_iter != nullptr; v_iter = v_iter->Next()) { if (v_iter->cargo.StoredCount() > 0) { has_status = false; break; } } break; case TRTSVF_FULL: has_status = true; for (const Vehicle *v_iter = v; v_iter != nullptr; v_iter = v_iter->Next()) { if (v_iter->cargo.StoredCount() < v_iter->cargo_cap) { has_status = false; break; } } break; case TRTSVF_BROKEN_DOWN: has_status = v->flags & VRF_IS_BROKEN; break; case TRTSVF_NEEDS_REPAIR: has_status = v->critical_breakdown_count > 0; break; case TRTSVF_REVERSING: has_status = v->reverse_distance > 0 || HasBit(v->flags, VRF_REVERSING); break; case TRTSVF_HEADING_TO_STATION_WAYPOINT: has_status = v->current_order.IsType(OT_GOTO_STATION) || v->current_order.IsType(OT_GOTO_WAYPOINT); break; case TRTSVF_HEADING_TO_DEPOT: has_status = v->current_order.IsType(OT_GOTO_DEPOT); break; case TRTSVF_LOADING: { extern const Order *_choose_train_track_saved_current_order; const Order *o = (_choose_train_track_saved_current_order != nullptr) ? _choose_train_track_saved_current_order : &(v->current_order); has_status = o->IsType(OT_LOADING) || o->IsType(OT_LOADING_ADVANCE); break; } case TRTSVF_WAITING: has_status = v->current_order.IsType(OT_WAITING); break; case TRTSVF_LOST: has_status = HasBit(v->vehicle_flags, VF_PATHFINDER_LOST); break; case TRTSVF_REQUIRES_SERVICE: has_status = v->NeedsServicing(); break; case TRTSVF_STOPPING_AT_STATION_WAYPOINT: switch (v->current_order.GetType()) { case OT_GOTO_STATION: case OT_GOTO_WAYPOINT: case OT_LOADING_ADVANCE: has_status = v->current_order.ShouldStopAtStation(v, v->current_order.GetDestination(), v->current_order.IsType(OT_GOTO_WAYPOINT)); break; default: has_status = false; break; } break; } result = TestBinaryConditionCommon(item, has_status); break; } case TRIT_COND_LOAD_PERCENT: { result = TestCondition(CalcPercentVehicleFilled(v, nullptr), condop, condvalue); break; } case TRIT_COND_COUNTER_VALUE: { // TRVT_COUNTER_INDEX_INT value type uses the next slot i++; uint32_t value = this->items[i]; const TraceRestrictCounter *ctr = TraceRestrictCounter::GetIfValid(GetTraceRestrictValue(item)); result = TestCondition(ctr != nullptr ? ctr->value : 0, condop, value); break; } case TRIT_COND_TIME_DATE_VALUE: { // TRVT_TIME_DATE_INT value type uses the next slot i++; uint32_t value = this->items[i]; result = TestCondition(GetTraceRestrictTimeDateValue(static_cast(GetTraceRestrictValue(item))), condop, value); break; } case TRIT_COND_RESERVED_TILES: { uint tiles_ahead = 0; if (v->lookahead != nullptr) { tiles_ahead = std::max(0, v->lookahead->reservation_end_position - v->lookahead->current_position) / TILE_SIZE; } result = TestCondition(tiles_ahead, condop, condvalue); break; } case TRIT_COND_CATEGORY: { switch (static_cast(GetTraceRestrictAuxField(item))) { case TRCCAF_ENGINE_CLASS: { EngineClass ec = (EngineClass)condvalue; result = (GetTraceRestrictCondOp(item) != TRCO_IS); for (const Train *u = v; u != nullptr; u = u->Next()) { /* Check if engine class present */ if (u->IsEngine() && RailVehInfo(u->engine_type)->engclass == ec) { result = !result; break; } } break; } default: NOT_REACHED(); break; } break; } case TRIT_COND_TARGET_DIRECTION: { const Order *o = nullptr; switch (static_cast(GetTraceRestrictAuxField(item))) { case TRTDCAF_CURRENT_ORDER: o = &(v->current_order); break; case TRTDCAF_NEXT_ORDER: if (v->orders == nullptr) break; if (v->orders->GetNumOrders() == 0) break; const Order *current_order = v->GetOrder(v->cur_real_order_index); for (const Order *order = v->orders->GetNext(current_order); order != current_order; order = v->orders->GetNext(order)) { if (order->IsGotoOrder()) { o = order; break; } } break; } if (o == nullptr) break; TileIndex target = o->GetLocation(v, true); if (target == INVALID_TILE) break; switch (condvalue) { case DIAGDIR_NE: result = TestBinaryConditionCommon(item, TileX(target) < TileX(input.tile)); break; case DIAGDIR_SE: result = TestBinaryConditionCommon(item, TileY(target) > TileY(input.tile)); break; case DIAGDIR_SW: result = TestBinaryConditionCommon(item, TileX(target) > TileX(input.tile)); break; case DIAGDIR_NW: result = TestBinaryConditionCommon(item, TileY(target) < TileY(input.tile)); break; } break; } case TRIT_COND_RESERVATION_THROUGH: { // TRIT_COND_RESERVATION_THROUGH value type uses the next slot i++; uint32_t test_tile = this->items[i]; result = TestBinaryConditionCommon(item, TrainReservationPassesThroughTile(v, test_tile)); break; } default: NOT_REACHED(); } HandleCondition(condstack, condflags, result); } } else { if (condstack.empty() || condstack.back() & TRCSF_ACTIVE) { switch(type) { case TRIT_PF_DENY: if (GetTraceRestrictValue(item)) { out.flags &= ~TRPRF_DENY; } else { out.flags |= TRPRF_DENY; } break; case TRIT_PF_PENALTY: switch (static_cast(GetTraceRestrictAuxField(item))) { case TRPPAF_VALUE: out.penalty += GetTraceRestrictValue(item); break; case TRPPAF_PRESET: { uint16_t index = GetTraceRestrictValue(item); assert(index < TRPPPI_END); out.penalty += _tracerestrict_pathfinder_penalty_preset_values[index]; break; } default: NOT_REACHED(); } break; case TRIT_RESERVE_THROUGH: if (GetTraceRestrictValue(item)) { out.flags &= ~TRPRF_RESERVE_THROUGH; } else { out.flags |= TRPRF_RESERVE_THROUGH; } break; case TRIT_LONG_RESERVE: switch (static_cast(GetTraceRestrictValue(item))) { case TRLRVF_LONG_RESERVE: out.flags |= TRPRF_LONG_RESERVE; break; case TRLRVF_CANCEL_LONG_RESERVE: out.flags &= ~TRPRF_LONG_RESERVE; break; case TRLRVF_LONG_RESERVE_UNLESS_STOPPING: if (!(input.input_flags & TRPIF_PASSED_STOP)) { out.flags |= TRPRF_LONG_RESERVE; } break; default: NOT_REACHED(); break; } break; case TRIT_WAIT_AT_PBS: switch (static_cast(GetTraceRestrictValue(item))) { case TRWAPVF_WAIT_AT_PBS: out.flags |= TRPRF_WAIT_AT_PBS; break; case TRWAPVF_CANCEL_WAIT_AT_PBS: out.flags &= ~TRPRF_WAIT_AT_PBS; break; case TRWAPVF_PBS_RES_END_WAIT: out.flags |= TRPRF_PBS_RES_END_WAIT; break; case TRWAPVF_CANCEL_PBS_RES_END_WAIT: out.flags &= ~TRPRF_PBS_RES_END_WAIT; break; default: NOT_REACHED(); break; } break; case TRIT_SLOT: { if (!input.permitted_slot_operations) break; TraceRestrictSlot *slot = TraceRestrictSlot::GetIfValid(GetTraceRestrictValue(item)); if (slot == nullptr || slot->vehicle_type != v->type) break; switch (static_cast(GetTraceRestrictCombinedAuxCondOpField(item))) { case TRSCOF_ACQUIRE_WAIT: if (input.permitted_slot_operations & TRPISP_ACQUIRE) { if (!slot->Occupy(v)) out.flags |= TRPRF_WAIT_AT_PBS; } else if (input.permitted_slot_operations & TRPISP_ACQUIRE_TEMP_STATE) { if (!slot->OccupyUsingTemporaryState(v->index, TraceRestrictSlotTemporaryState::GetCurrent())) out.flags |= TRPRF_WAIT_AT_PBS; } break; case TRSCOF_ACQUIRE_TRY: if (input.permitted_slot_operations & TRPISP_ACQUIRE) { slot->Occupy(v); } else if (input.permitted_slot_operations & TRPISP_ACQUIRE_TEMP_STATE) { slot->OccupyUsingTemporaryState(v->index, TraceRestrictSlotTemporaryState::GetCurrent()); } break; case TRSCOF_RELEASE_ON_RESERVE: if (input.permitted_slot_operations & TRPISP_ACQUIRE) { slot->Vacate(v); } else if (input.permitted_slot_operations & TRPISP_ACQUIRE_TEMP_STATE) { slot->VacateUsingTemporaryState(v->index, TraceRestrictSlotTemporaryState::GetCurrent()); } break; case TRSCOF_RELEASE_BACK: if (input.permitted_slot_operations & TRPISP_RELEASE_BACK) slot->Vacate(v); break; case TRSCOF_RELEASE_FRONT: if (input.permitted_slot_operations & TRPISP_RELEASE_FRONT) slot->Vacate(v); break; case TRSCOF_PBS_RES_END_ACQ_WAIT: if (input.permitted_slot_operations & TRPISP_PBS_RES_END_ACQUIRE) { if (!slot->Occupy(v)) out.flags |= TRPRF_PBS_RES_END_WAIT; } else if (input.permitted_slot_operations & TRPISP_PBS_RES_END_ACQ_DRY) { if (this->actions_used_flags & TRPAUF_PBS_RES_END_SIMULATE) { if (!slot->OccupyUsingTemporaryState(v->index, &pbs_res_end_acq_dry_slot_temporary_state)) out.flags |= TRPRF_PBS_RES_END_WAIT; } else { if (!slot->OccupyDryRun(v->index)) out.flags |= TRPRF_PBS_RES_END_WAIT; } } break; case TRSCOF_PBS_RES_END_ACQ_TRY: if (input.permitted_slot_operations & TRPISP_PBS_RES_END_ACQUIRE) { slot->Occupy(v); } else if ((input.permitted_slot_operations & TRPISP_PBS_RES_END_ACQ_DRY) && (this->actions_used_flags & TRPAUF_PBS_RES_END_SIMULATE)) { slot->OccupyUsingTemporaryState(v->index, &pbs_res_end_acq_dry_slot_temporary_state); } break; case TRSCOF_PBS_RES_END_RELEASE: if (input.permitted_slot_operations & TRPISP_PBS_RES_END_ACQUIRE) { slot->Vacate(v); } else if ((input.permitted_slot_operations & TRPISP_PBS_RES_END_ACQ_DRY) && (this->actions_used_flags & TRPAUF_PBS_RES_END_SIMULATE)) { slot->VacateUsingTemporaryState(v->index, &pbs_res_end_acq_dry_slot_temporary_state); } break; default: NOT_REACHED(); break; } break; } case TRIT_REVERSE: switch (static_cast(GetTraceRestrictValue(item))) { case TRRVF_REVERSE: out.flags |= TRPRF_REVERSE; break; case TRRVF_CANCEL_REVERSE: out.flags &= ~TRPRF_REVERSE; break; default: NOT_REACHED(); break; } break; case TRIT_SPEED_RESTRICTION: { out.speed_restriction = GetTraceRestrictValue(item); out.flags |= TRPRF_SPEED_RESTRICTION_SET; break; } case TRIT_NEWS_CONTROL: switch (static_cast(GetTraceRestrictValue(item))) { case TRNCF_TRAIN_NOT_STUCK: out.flags |= TRPRF_TRAIN_NOT_STUCK; break; case TRNCF_CANCEL_TRAIN_NOT_STUCK: out.flags &= ~TRPRF_TRAIN_NOT_STUCK; break; default: NOT_REACHED(); break; } break; case TRIT_COUNTER: { // TRVT_COUNTER_INDEX_INT value type uses the next slot i++; uint32_t value = this->items[i]; if (!(input.permitted_slot_operations & TRPISP_CHANGE_COUNTER)) break; TraceRestrictCounter *ctr = TraceRestrictCounter::GetIfValid(GetTraceRestrictValue(item)); if (ctr == nullptr) break; ctr->ApplyUpdate(static_cast(GetTraceRestrictCondOp(item)), value); break; } case TRIT_PF_PENALTY_CONTROL: switch (static_cast(GetTraceRestrictValue(item))) { case TRPPCF_NO_PBS_BACK_PENALTY: out.flags |= TRPRF_NO_PBS_BACK_PENALTY; break; case TRPPCF_CANCEL_NO_PBS_BACK_PENALTY: out.flags &= ~TRPRF_NO_PBS_BACK_PENALTY; break; default: NOT_REACHED(); break; } break; case TRIT_SPEED_ADAPTATION_CONTROL: switch (static_cast(GetTraceRestrictValue(item))) { case TRSACF_SPEED_ADAPT_EXEMPT: out.flags |= TRPRF_SPEED_ADAPT_EXEMPT; out.flags &= ~TRPRF_RM_SPEED_ADAPT_EXEMPT; break; case TRSACF_REMOVE_SPEED_ADAPT_EXEMPT: out.flags &= ~TRPRF_SPEED_ADAPT_EXEMPT; out.flags |= TRPRF_RM_SPEED_ADAPT_EXEMPT; break; default: NOT_REACHED(); break; } break; case TRIT_SIGNAL_MODE_CONTROL: switch (static_cast(GetTraceRestrictValue(item))) { case TRSMCF_NORMAL_ASPECT: out.flags |= TRPRF_SIGNAL_MODE_NORMAL; out.flags &= ~TRPRF_SIGNAL_MODE_SHUNT; break; case TRSMCF_SHUNT_ASPECT: out.flags &= ~TRPRF_SIGNAL_MODE_NORMAL; out.flags |= TRPRF_SIGNAL_MODE_SHUNT; break; default: NOT_REACHED(); break; } break; default: NOT_REACHED(); } } else { if (IsTraceRestrictDoubleItem(type)) i++; } } } if ((input.permitted_slot_operations & TRPISP_PBS_RES_END_ACQ_DRY) && (this->actions_used_flags & TRPAUF_PBS_RES_END_SIMULATE)) { pbs_res_end_acq_dry_slot_temporary_state.RevertTemporaryChanges(v->index); } assert(condstack.empty()); } void TraceRestrictProgram::ClearRefIds() { if (this->refcount > 4) free(this->ref_ids.ptr_ref_ids.buffer); } /** * Increment ref count, only use when creating a mapping */ void TraceRestrictProgram::IncrementRefCount(TraceRestrictRefId ref_id) { if (this->refcount >= 4) { if (this->refcount == 4) { /* Transition from inline to allocated mode */ TraceRestrictRefId *ptr = MallocT(8); MemCpyT(ptr, this->ref_ids.inline_ref_ids, 4); this->ref_ids.ptr_ref_ids.buffer = ptr; this->ref_ids.ptr_ref_ids.elem_capacity = 8; } else if (this->refcount == this->ref_ids.ptr_ref_ids.elem_capacity) { // grow buffer this->ref_ids.ptr_ref_ids.elem_capacity *= 2; this->ref_ids.ptr_ref_ids.buffer = ReallocT(this->ref_ids.ptr_ref_ids.buffer, this->ref_ids.ptr_ref_ids.elem_capacity); } this->ref_ids.ptr_ref_ids.buffer[this->refcount] = ref_id; } else { this->ref_ids.inline_ref_ids[this->refcount] = ref_id; } this->refcount++; } /** * Decrement ref count, only use when removing a mapping */ void TraceRestrictProgram::DecrementRefCount(TraceRestrictRefId ref_id) { assert(this->refcount > 0); if (this->refcount >= 2) { TraceRestrictRefId *data = this->GetRefIdsPtr(); for (uint i = 0; i < this->refcount - 1; i++) { if (data[i] == ref_id) { data[i] = data[this->refcount - 1]; break; } } } this->refcount--; if (this->refcount == 4) { /* Transition from allocated to inline mode */ TraceRestrictRefId *ptr = this->ref_ids.ptr_ref_ids.buffer; MemCpyT(this->ref_ids.inline_ref_ids, ptr, 4); free(ptr); } if (this->refcount == 0) { extern const TraceRestrictProgram *_viewport_highlight_tracerestrict_program; if (_viewport_highlight_tracerestrict_program == this) { _viewport_highlight_tracerestrict_program = nullptr; InvalidateWindowClassesData(WC_TRACE_RESTRICT); } delete this; } } /** * Validate a instruction list * Returns successful result if program seems OK * This only validates that conditional nesting is correct, * and that all instructions have a known type, at present */ CommandCost TraceRestrictProgram::Validate(const std::vector &items, TraceRestrictProgramActionsUsedFlags &actions_used_flags) { // static to avoid needing to re-alloc/resize on each execution static std::vector condstack; condstack.clear(); actions_used_flags = TRPAUF_NONE; static std::vector pbs_res_end_released_slots; pbs_res_end_released_slots.clear(); static std::vector pbs_res_end_acquired_slots; pbs_res_end_acquired_slots.clear(); size_t size = items.size(); for (size_t i = 0; i < size; i++) { TraceRestrictItem item = items[i]; TraceRestrictItemType type = GetTraceRestrictType(item); auto validation_error = [i](StringID str) -> CommandCost { CommandCost result(str); result.SetResultData((uint)i); return result; }; auto unknown_instruction = [&]() { return validation_error(STR_TRACE_RESTRICT_ERROR_VALIDATE_UNKNOWN_INSTRUCTION); }; // check multi-word instructions if (IsTraceRestrictDoubleItem(item)) { i++; if (i >= size) { return validation_error(STR_TRACE_RESTRICT_ERROR_OFFSET_TOO_LARGE); // instruction ran off end } } if (IsTraceRestrictConditional(item)) { TraceRestrictCondFlags condflags = GetTraceRestrictCondFlags(item); if (type == TRIT_COND_ENDIF) { if (condstack.empty()) { return validation_error(STR_TRACE_RESTRICT_ERROR_VALIDATE_NO_IF); // else/endif with no starting if } if (condflags & TRCF_ELSE) { // else if (condstack.back() & TRCSF_SEEN_ELSE) { return validation_error(STR_TRACE_RESTRICT_ERROR_VALIDATE_DUP_ELSE); // Two else clauses } HandleCondition(condstack, condflags, true); condstack.back() |= TRCSF_SEEN_ELSE; } else { // end if condstack.pop_back(); } } else { if (condflags & (TRCF_OR | TRCF_ELSE)) { // elif/orif if (condstack.empty()) { return validation_error(STR_TRACE_RESTRICT_ERROR_VALIDATE_ELIF_NO_IF); // Pre-empt assertions in HandleCondition } if (condstack.back() & TRCSF_SEEN_ELSE) { return validation_error(STR_TRACE_RESTRICT_ERROR_VALIDATE_DUP_ELSE); // else clause followed by elif/orif } } HandleCondition(condstack, condflags, true); } const TraceRestrictCondOp condop = GetTraceRestrictCondOp(item); auto invalid_condition = [&]() -> bool { switch (condop) { case TRCO_IS: case TRCO_ISNOT: case TRCO_LT: case TRCO_LTE: case TRCO_GT: case TRCO_GTE: return false; default: return true; } }; auto invalid_binary_condition = [&]() -> bool { switch (condop) { case TRCO_IS: case TRCO_ISNOT: return false; default: return true; } }; auto invalid_order_condition = [&]() -> bool { if (invalid_binary_condition()) return true; switch (static_cast(GetTraceRestrictAuxField(item))) { case TROCAF_STATION: case TROCAF_WAYPOINT: case TROCAF_DEPOT: return false; default: return true; } }; /* Validation action instruction */ switch (GetTraceRestrictType(item)) { case TRIT_COND_ENDIF: case TRIT_COND_UNDEFINED: break; case TRIT_COND_TRAIN_LENGTH: case TRIT_COND_MAX_SPEED: case TRIT_COND_LOAD_PERCENT: case TRIT_COND_COUNTER_VALUE: case TRIT_COND_RESERVED_TILES: if (invalid_condition()) return unknown_instruction(); break; case TRIT_COND_CARGO: case TRIT_COND_TRAIN_GROUP: case TRIT_COND_TRAIN_IN_SLOT: case TRIT_COND_TRAIN_OWNER: case TRIT_COND_RESERVATION_THROUGH: if (invalid_binary_condition()) return unknown_instruction(); break; case TRIT_COND_CURRENT_ORDER: case TRIT_COND_NEXT_ORDER: case TRIT_COND_LAST_STATION: if (invalid_order_condition()) return unknown_instruction(); break; case TRIT_COND_ENTRY_DIRECTION: if (invalid_binary_condition()) return unknown_instruction(); switch (GetTraceRestrictValue(item)) { case TRNTSV_NE: case TRNTSV_SE: case TRNTSV_SW: case TRNTSV_NW: case TRDTSV_FRONT: case TRDTSV_BACK: case TRDTSV_TUNBRIDGE_ENTER: case TRDTSV_TUNBRIDGE_EXIT: break; default: return unknown_instruction(); } break; case TRIT_COND_PBS_ENTRY_SIGNAL: if (invalid_binary_condition()) return unknown_instruction(); switch (static_cast(GetTraceRestrictAuxField(item))) { case TRPESAF_VEH_POS: case TRPESAF_RES_END: case TRPESAF_RES_END_TILE: break; default: return unknown_instruction(); } break; case TRIT_COND_PHYS_PROP: if (invalid_condition()) return unknown_instruction(); switch (static_cast(GetTraceRestrictAuxField(item))) { case TRPPCAF_WEIGHT: case TRPPCAF_POWER: case TRPPCAF_MAX_TE: break; default: return unknown_instruction(); } break; case TRIT_COND_PHYS_RATIO: if (invalid_condition()) return unknown_instruction(); switch (static_cast(GetTraceRestrictAuxField(item))) { case TRPPRCAF_POWER_WEIGHT: case TRPPRCAF_MAX_TE_WEIGHT: break; default: return unknown_instruction(); } break; case TRIT_COND_TIME_DATE_VALUE: if (invalid_condition()) return unknown_instruction(); switch (static_cast(GetTraceRestrictValue(item))) { case TRTDVF_MINUTE: case TRTDVF_HOUR: case TRTDVF_HOUR_MINUTE: case TRTDVF_DAY: case TRTDVF_MONTH: break; default: return unknown_instruction(); } break; case TRIT_COND_CATEGORY: if (invalid_binary_condition()) return unknown_instruction(); switch (static_cast(GetTraceRestrictAuxField(item))) { case TRCCAF_ENGINE_CLASS: break; default: return unknown_instruction(); } break; case TRIT_COND_TARGET_DIRECTION: if (invalid_binary_condition()) return unknown_instruction(); switch (static_cast(GetTraceRestrictAuxField(item))) { case TRTDCAF_CURRENT_ORDER: case TRTDCAF_NEXT_ORDER: break; default: return unknown_instruction(); } switch (GetTraceRestrictValue(item)) { case DIAGDIR_NE: case DIAGDIR_SE: case DIAGDIR_SW: case DIAGDIR_NW: break; default: return unknown_instruction(); } break; case TRIT_COND_TRAIN_STATUS: if (invalid_binary_condition()) return unknown_instruction(); switch (static_cast(GetTraceRestrictValue(item))) { case TRTSVF_EMPTY: case TRTSVF_FULL: case TRTSVF_BROKEN_DOWN: case TRTSVF_NEEDS_REPAIR: case TRTSVF_REVERSING: case TRTSVF_HEADING_TO_STATION_WAYPOINT: case TRTSVF_HEADING_TO_DEPOT: case TRTSVF_LOADING: case TRTSVF_WAITING: case TRTSVF_LOST: case TRTSVF_REQUIRES_SERVICE: case TRTSVF_STOPPING_AT_STATION_WAYPOINT: break; default: return unknown_instruction(); } break; case TRIT_COND_SLOT_OCCUPANCY: if (invalid_condition()) return unknown_instruction(); switch (static_cast(GetTraceRestrictAuxField(item))) { case TRSOCAF_OCCUPANTS: case TRSOCAF_REMAINING: break; default: return unknown_instruction(); } break; default: return unknown_instruction(); } /* Determine actions_used_flags */ switch (GetTraceRestrictType(item)) { case TRIT_COND_ENDIF: case TRIT_COND_UNDEFINED: case TRIT_COND_TRAIN_LENGTH: case TRIT_COND_MAX_SPEED: case TRIT_COND_CARGO: case TRIT_COND_ENTRY_DIRECTION: case TRIT_COND_PBS_ENTRY_SIGNAL: case TRIT_COND_TRAIN_GROUP: case TRIT_COND_PHYS_PROP: case TRIT_COND_PHYS_RATIO: case TRIT_COND_TRAIN_OWNER: case TRIT_COND_LOAD_PERCENT: case TRIT_COND_COUNTER_VALUE: case TRIT_COND_TIME_DATE_VALUE: case TRIT_COND_RESERVED_TILES: case TRIT_COND_CATEGORY: case TRIT_COND_RESERVATION_THROUGH: break; case TRIT_COND_CURRENT_ORDER: case TRIT_COND_NEXT_ORDER: case TRIT_COND_LAST_STATION: case TRIT_COND_TARGET_DIRECTION: actions_used_flags |= TRPAUF_ORDER_CONDITIONALS; break; case TRIT_COND_TRAIN_STATUS: switch (static_cast(GetTraceRestrictValue(item))) { case TRTSVF_HEADING_TO_STATION_WAYPOINT: case TRTSVF_HEADING_TO_DEPOT: case TRTSVF_LOADING: case TRTSVF_WAITING: case TRTSVF_STOPPING_AT_STATION_WAYPOINT: actions_used_flags |= TRPAUF_ORDER_CONDITIONALS; break; default: break; } break; case TRIT_COND_TRAIN_IN_SLOT: case TRIT_COND_SLOT_OCCUPANCY: actions_used_flags |= TRPAUF_SLOT_CONDITIONALS; if (find_index(pbs_res_end_released_slots, GetTraceRestrictValue(item)) >= 0 || find_index(pbs_res_end_acquired_slots, GetTraceRestrictValue(item)) >= 0) { actions_used_flags |= TRPAUF_PBS_RES_END_SIMULATE; } break; default: /* Validation has already been done, above */ NOT_REACHED(); } } else { switch (GetTraceRestrictType(item)) { case TRIT_PF_DENY: actions_used_flags |= TRPAUF_PF; break; case TRIT_PF_PENALTY: actions_used_flags |= TRPAUF_PF; switch (static_cast(GetTraceRestrictAuxField(item))) { case TRPPAF_VALUE: break; case TRPPAF_PRESET: if (GetTraceRestrictValue(item) >= TRPPPI_END) return unknown_instruction(); break; default: return unknown_instruction(); } break; case TRIT_RESERVE_THROUGH: actions_used_flags |= TRPAUF_RESERVE_THROUGH; if (GetTraceRestrictValue(item)) { actions_used_flags &= ~TRPAUF_RESERVE_THROUGH_ALWAYS; } else if (condstack.empty()) { actions_used_flags |= TRPAUF_RESERVE_THROUGH_ALWAYS; } break; case TRIT_LONG_RESERVE: actions_used_flags |= TRPAUF_LONG_RESERVE; break; case TRIT_WAIT_AT_PBS: switch (static_cast(GetTraceRestrictValue(item))) { case TRWAPVF_WAIT_AT_PBS: case TRWAPVF_CANCEL_WAIT_AT_PBS: actions_used_flags |= TRPAUF_WAIT_AT_PBS; break; case TRWAPVF_PBS_RES_END_WAIT: case TRWAPVF_CANCEL_PBS_RES_END_WAIT: actions_used_flags |= TRPAUF_PBS_RES_END_WAIT; break; default: return unknown_instruction(); } break; case TRIT_SLOT: switch (static_cast(GetTraceRestrictCombinedAuxCondOpField(item))) { case TRSCOF_ACQUIRE_WAIT: actions_used_flags |= TRPAUF_SLOT_ACQUIRE | TRPAUF_SLOT_CONDITIONALS | TRPAUF_WAIT_AT_PBS; break; case TRSCOF_ACQUIRE_TRY: actions_used_flags |= TRPAUF_SLOT_ACQUIRE; break; case TRSCOF_RELEASE_ON_RESERVE: actions_used_flags |= TRPAUF_SLOT_ACQUIRE; break; case TRSCOF_RELEASE_BACK: actions_used_flags |= TRPAUF_SLOT_RELEASE_BACK; break; case TRSCOF_RELEASE_FRONT: actions_used_flags |= TRPAUF_SLOT_RELEASE_FRONT; break; case TRSCOF_PBS_RES_END_ACQ_WAIT: actions_used_flags |= TRPAUF_PBS_RES_END_SLOT | TRPAUF_PBS_RES_END_WAIT | TRPAUF_SLOT_CONDITIONALS ; if (find_index(pbs_res_end_released_slots, GetTraceRestrictValue(item)) >= 0) actions_used_flags |= TRPAUF_PBS_RES_END_SIMULATE; include(pbs_res_end_acquired_slots, GetTraceRestrictValue(item)); break; case TRSCOF_PBS_RES_END_ACQ_TRY: actions_used_flags |= TRPAUF_PBS_RES_END_SLOT; if (find_index(pbs_res_end_released_slots, GetTraceRestrictValue(item)) >= 0) actions_used_flags |= TRPAUF_PBS_RES_END_SIMULATE; include(pbs_res_end_acquired_slots, GetTraceRestrictValue(item)); break; case TRSCOF_PBS_RES_END_RELEASE: actions_used_flags |= TRPAUF_PBS_RES_END_SLOT; include(pbs_res_end_released_slots, GetTraceRestrictValue(item)); break; default: return unknown_instruction(); } break; case TRIT_REVERSE: switch (static_cast(GetTraceRestrictValue(item))) { case TRRVF_REVERSE: actions_used_flags |= TRPAUF_REVERSE; break; case TRRVF_CANCEL_REVERSE: if (condstack.empty()) actions_used_flags &= ~TRPAUF_REVERSE; break; default: return unknown_instruction(); } break; case TRIT_SPEED_RESTRICTION: actions_used_flags |= TRPAUF_SPEED_RESTRICTION; break; case TRIT_NEWS_CONTROL: actions_used_flags |= TRPAUF_TRAIN_NOT_STUCK; switch (static_cast(GetTraceRestrictValue(item))) { case TRNCF_TRAIN_NOT_STUCK: case TRNCF_CANCEL_TRAIN_NOT_STUCK: break; default: return unknown_instruction(); } break; case TRIT_COUNTER: actions_used_flags |= TRPAUF_CHANGE_COUNTER; switch (static_cast(GetTraceRestrictCondOp(item))) { case TRCCOF_INCREASE: case TRCCOF_DECREASE: case TRCCOF_SET: break; default: return unknown_instruction(); } break; case TRIT_PF_PENALTY_CONTROL: actions_used_flags |= TRPAUF_NO_PBS_BACK_PENALTY; switch (static_cast(GetTraceRestrictValue(item))) { case TRPPCF_NO_PBS_BACK_PENALTY: case TRPPCF_CANCEL_NO_PBS_BACK_PENALTY: break; default: return unknown_instruction(); } break; case TRIT_SPEED_ADAPTATION_CONTROL: actions_used_flags |= TRPAUF_SPEED_ADAPTATION; switch (static_cast(GetTraceRestrictValue(item))) { case TRSACF_SPEED_ADAPT_EXEMPT: case TRSACF_REMOVE_SPEED_ADAPT_EXEMPT: break; default: return unknown_instruction(); } break; case TRIT_SIGNAL_MODE_CONTROL: actions_used_flags |= TRPAUF_CMB_SIGNAL_MODE_CTRL; switch (static_cast(GetTraceRestrictValue(item))) { case TRSMCF_NORMAL_ASPECT: case TRSMCF_SHUNT_ASPECT: break; default: return unknown_instruction(); } break; default: return unknown_instruction(); } } } if (!condstack.empty()) { return_cmd_error(STR_TRACE_RESTRICT_ERROR_VALIDATE_END_CONDSTACK); } return CommandCost(); } /** * Convert an instruction index into an item array index */ size_t TraceRestrictProgram::InstructionOffsetToArrayOffset(const std::vector &items, size_t offset) { size_t output_offset = 0; size_t size = items.size(); for (size_t i = 0; i < offset && output_offset < size; i++, output_offset++) { if (IsTraceRestrictDoubleItem(items[output_offset])) { output_offset++; } } return output_offset; } /** * Convert an item array index into an instruction index */ size_t TraceRestrictProgram::ArrayOffsetToInstructionOffset(const std::vector &items, size_t offset) { size_t output_offset = 0; for (size_t i = 0; i < offset; i++, output_offset++) { if (IsTraceRestrictDoubleItem(items[i])) { i++; } } return output_offset; } /** * Set the value and aux field of @p item, as per the value type in @p value_type */ void SetTraceRestrictValueDefault(TraceRestrictItem &item, TraceRestrictValueType value_type) { switch (value_type) { case TRVT_NONE: case TRVT_INT: case TRVT_DENY: case TRVT_SPEED: case TRVT_TILE_INDEX: case TRVT_TILE_INDEX_THROUGH: case TRVT_RESERVE_THROUGH: case TRVT_LONG_RESERVE: case TRVT_WEIGHT: case TRVT_POWER: case TRVT_FORCE: case TRVT_POWER_WEIGHT_RATIO: case TRVT_FORCE_WEIGHT_RATIO: case TRVT_WAIT_AT_PBS: case TRVT_TRAIN_STATUS: case TRVT_REVERSE: case TRVT_PERCENT: case TRVT_NEWS_CONTROL: case TRVT_TIME_DATE_INT: case TRVT_ENGINE_CLASS: case TRVT_PF_PENALTY_CONTROL: case TRVT_SPEED_ADAPTATION_CONTROL: case TRVT_SIGNAL_MODE_CONTROL: case TRVT_ORDER_TARGET_DIAGDIR: SetTraceRestrictValue(item, 0); if (!IsTraceRestrictTypeAuxSubtype(GetTraceRestrictType(item))) { SetTraceRestrictAuxField(item, 0); } break; case TRVT_ORDER: SetTraceRestrictValue(item, INVALID_STATION); SetTraceRestrictAuxField(item, TROCAF_STATION); break; case TRVT_CARGO_ID: assert(_standard_cargo_mask != 0); SetTraceRestrictValue(item, FindFirstBit(_standard_cargo_mask)); SetTraceRestrictAuxField(item, 0); break; case TRVT_DIRECTION: SetTraceRestrictValue(item, TRDTSV_FRONT); SetTraceRestrictAuxField(item, 0); break; case TRVT_PF_PENALTY: SetTraceRestrictValue(item, TRPPPI_SMALL); SetTraceRestrictAuxField(item, TRPPAF_PRESET); break; case TRVT_GROUP_INDEX: SetTraceRestrictValue(item, INVALID_GROUP); SetTraceRestrictAuxField(item, 0); break; case TRVT_OWNER: SetTraceRestrictValue(item, INVALID_OWNER); SetTraceRestrictAuxField(item, 0); break; case TRVT_SLOT_INDEX: SetTraceRestrictValue(item, INVALID_TRACE_RESTRICT_SLOT_ID); SetTraceRestrictAuxField(item, 0); break; case TRVT_SLOT_INDEX_INT: SetTraceRestrictValue(item, INVALID_TRACE_RESTRICT_SLOT_ID); break; case TRVT_COUNTER_INDEX_INT: SetTraceRestrictValue(item, INVALID_TRACE_RESTRICT_COUNTER_ID); break; default: NOT_REACHED(); break; } } /** * Set the type field of a TraceRestrictItem, and resets any other fields which are no longer valid/meaningful to sensible defaults */ void SetTraceRestrictTypeAndNormalise(TraceRestrictItem &item, TraceRestrictItemType type, uint8_t aux_data) { if (item != 0) { assert(GetTraceRestrictType(item) != TRIT_NULL); assert(IsTraceRestrictConditional(item) == IsTraceRestrictTypeConditional(type)); } assert(type != TRIT_NULL); TraceRestrictTypePropertySet old_properties = GetTraceRestrictTypeProperties(item); SetTraceRestrictType(item, type); if (IsTraceRestrictTypeAuxSubtype(type)) { SetTraceRestrictAuxField(item, aux_data); } else { assert(aux_data == 0); } TraceRestrictTypePropertySet new_properties = GetTraceRestrictTypeProperties(item); if (old_properties.cond_type != new_properties.cond_type || old_properties.value_type != new_properties.value_type) { SetTraceRestrictCondOp(item, TRCO_IS); SetTraceRestrictValueDefault(item, new_properties.value_type); } if (new_properties.value_type == TRVT_SLOT_INDEX || new_properties.value_type == TRVT_SLOT_INDEX_INT) { if (!IsTraceRestrictTypeNonMatchingVehicleTypeSlot(GetTraceRestrictType(item))) { const TraceRestrictSlot *slot = TraceRestrictSlot::GetIfValid(GetTraceRestrictValue(item)); if (slot != nullptr && slot->vehicle_type != VEH_TRAIN) SetTraceRestrictValue(item, INVALID_TRACE_RESTRICT_SLOT_ID); } } if (GetTraceRestrictType(item) == TRIT_COND_LAST_STATION && GetTraceRestrictAuxField(item) != TROCAF_STATION) { // if changing type from another order type to last visited station, reset value if not currently a station SetTraceRestrictValueDefault(item, TRVT_ORDER); } } /** * Sets the "signal has a trace restrict mapping" bit * This looks for mappings with that tile index */ void TraceRestrictSetIsSignalRestrictedBit(TileIndex t) { // First mapping for this tile, or later TraceRestrictMapping::iterator lower_bound = _tracerestrictprogram_mapping.lower_bound(MakeTraceRestrictRefId(t, static_cast(0))); bool found = (lower_bound != _tracerestrictprogram_mapping.end()) && (GetTraceRestrictRefIdTileIndex(lower_bound->first) == t); // If iterators are the same, there are no mappings for this tile switch (GetTileType(t)) { case MP_RAILWAY: SetRestrictedSignal(t, found); break; case MP_TUNNELBRIDGE: SetTunnelBridgeRestrictedSignal(t, found); break; default: NOT_REACHED(); } } /** * Create a new program mapping to an existing program * If a mapping already exists, it is removed */ void TraceRestrictCreateProgramMapping(TraceRestrictRefId ref, TraceRestrictProgram *prog) { std::pair insert_result = _tracerestrictprogram_mapping.insert(std::make_pair(ref, TraceRestrictMappingItem(prog->index))); if (!insert_result.second) { // value was not inserted, there is an existing mapping // unref the existing mapping before updating it _tracerestrictprogram_pool.Get(insert_result.first->second.program_id)->DecrementRefCount(ref); insert_result.first->second = prog->index; } prog->IncrementRefCount(ref); TileIndex tile = GetTraceRestrictRefIdTileIndex(ref); Track track = GetTraceRestrictRefIdTrack(ref); TraceRestrictSetIsSignalRestrictedBit(tile); MarkTileDirtyByTile(tile, VMDF_NOT_MAP_MODE); YapfNotifyTrackLayoutChange(tile, track); } /** * Remove a program mapping * @return true if a mapping was actually removed */ bool TraceRestrictRemoveProgramMapping(TraceRestrictRefId ref) { TraceRestrictMapping::iterator iter = _tracerestrictprogram_mapping.find(ref); if (iter != _tracerestrictprogram_mapping.end()) { // Found TraceRestrictProgram *prog = _tracerestrictprogram_pool.Get(iter->second.program_id); bool update_reserve_through = (prog->actions_used_flags & TRPAUF_RESERVE_THROUGH_ALWAYS); // check to see if another mapping needs to be removed as well // do this before decrementing the refcount bool remove_other_mapping = prog->refcount == 2 && prog->items.empty(); prog->DecrementRefCount(ref); _tracerestrictprogram_mapping.erase(iter); TileIndex tile = GetTraceRestrictRefIdTileIndex(ref); Track track = GetTraceRestrictRefIdTrack(ref); TraceRestrictSetIsSignalRestrictedBit(tile); MarkTileDirtyByTile(tile, VMDF_NOT_MAP_MODE); YapfNotifyTrackLayoutChange(tile, track); if (remove_other_mapping) { TraceRestrictRemoveProgramMapping(const_cast(prog)->GetRefIdsPtr()[0]); } if (update_reserve_through && IsTileType(tile, MP_RAILWAY)) { UpdateSignalReserveThroughBit(tile, track, true); } return true; } else { return false; } } void TraceRestrictCheckRefreshSignals(const TraceRestrictProgram *prog, size_t old_size, TraceRestrictProgramActionsUsedFlags old_actions_used_flags) { if (((old_actions_used_flags ^ prog->actions_used_flags) & TRPAUF_RESERVE_THROUGH_ALWAYS)) { const TraceRestrictRefId *data = prog->GetRefIdsPtr(); for (uint i = 0; i < prog->refcount; i++) { TileIndex tile = GetTraceRestrictRefIdTileIndex(data[i]); Track track = GetTraceRestrictRefIdTrack(data[i]); if (IsTileType(tile, MP_RAILWAY)) UpdateSignalReserveThroughBit(tile, track, true); } } if (IsHeadless()) return; if (!((old_actions_used_flags ^ prog->actions_used_flags) & (TRPAUF_RESERVE_THROUGH_ALWAYS | TRPAUF_REVERSE))) return; if (old_size == 0 && prog->refcount == 1) return; // Program is new, no need to refresh again const TraceRestrictRefId *data = prog->GetRefIdsPtr(); for (uint i = 0; i < prog->refcount; i++) { MarkTileDirtyByTile(GetTraceRestrictRefIdTileIndex(data[i]), VMDF_NOT_MAP_MODE); } } void TraceRestrictCheckRefreshSingleSignal(const TraceRestrictProgram *prog, TraceRestrictRefId ref, TraceRestrictProgramActionsUsedFlags old_actions_used_flags) { if (((old_actions_used_flags ^ prog->actions_used_flags) & TRPAUF_RESERVE_THROUGH_ALWAYS)) { TileIndex tile = GetTraceRestrictRefIdTileIndex(ref); Track track = GetTraceRestrictRefIdTrack(ref); if (IsTileType(tile, MP_RAILWAY)) UpdateSignalReserveThroughBit(tile, track, true); } } /** * Gets the signal program for the tile ref @p ref * An empty program will be constructed if none exists, and @p create_new is true, unless the pool is full */ TraceRestrictProgram *GetTraceRestrictProgram(TraceRestrictRefId ref, bool create_new) { // Optimise for lookup, creating doesn't have to be that fast TraceRestrictMapping::iterator iter = _tracerestrictprogram_mapping.find(ref); if (iter != _tracerestrictprogram_mapping.end()) { // Found return _tracerestrictprogram_pool.Get(iter->second.program_id); } else if (create_new) { // Not found // Create new pool item if (!TraceRestrictProgram::CanAllocateItem()) { return nullptr; } TraceRestrictProgram *prog = new TraceRestrictProgram(); // Create new mapping to pool item TraceRestrictCreateProgramMapping(ref, prog); return prog; } else { return nullptr; } } /** * Gets the first signal program for the given tile * This is for debug/display purposes only */ TraceRestrictProgram *GetFirstTraceRestrictProgramOnTile(TileIndex t) { // First mapping for this tile, or later TraceRestrictMapping::iterator lower_bound = _tracerestrictprogram_mapping.lower_bound(MakeTraceRestrictRefId(t, static_cast(0))); if ((lower_bound != _tracerestrictprogram_mapping.end()) && (GetTraceRestrictRefIdTileIndex(lower_bound->first) == t)) { return _tracerestrictprogram_pool.Get(lower_bound->second.program_id); } return nullptr; } /** * Notify that a signal is being removed * Remove any trace restrict mappings associated with it */ void TraceRestrictNotifySignalRemoval(TileIndex tile, Track track) { TraceRestrictRefId ref = MakeTraceRestrictRefId(tile, track); bool removed = TraceRestrictRemoveProgramMapping(ref); CloseWindowById(WC_TRACE_RESTRICT, ref); if (removed) InvalidateWindowClassesData(WC_TRACE_RESTRICT); } /** * Helper function to perform parameter bit-packing and call DoCommandP, for instruction modification actions */ void TraceRestrictDoCommandP(TileIndex tile, Track track, TraceRestrictDoCommandType type, uint32_t offset, uint32_t value, StringID error_msg) { uint32_t p1 = 0; SB(p1, 0, 3, track); SB(p1, 3, 5, type); assert(offset < (1 << 16)); SB(p1, 8, 16, offset); DoCommandP(tile, p1, value, CMD_PROGRAM_TRACERESTRICT_SIGNAL | CMD_MSG(error_msg)); } /** * Check whether a tile/track pair contains a usable signal */ static CommandCost TraceRestrictCheckTileIsUsable(TileIndex tile, Track track) { // Check that there actually is a signal here switch (GetTileType(tile)) { case MP_RAILWAY: if (!IsPlainRailTile(tile) || !HasTrack(tile, track)) { return_cmd_error(STR_ERROR_THERE_IS_NO_RAILROAD_TRACK); } if (!HasSignalOnTrack(tile, track)) { return_cmd_error(STR_ERROR_THERE_ARE_NO_SIGNALS); } break; case MP_TUNNELBRIDGE: if (!IsRailTunnelBridgeTile(tile) || !HasBit(GetTunnelBridgeTrackBits(tile), track)) { return_cmd_error(STR_ERROR_THERE_IS_NO_RAILROAD_TRACK); } if (!IsTunnelBridgeWithSignalSimulation(tile) || !IsTrackAcrossTunnelBridge(tile, track)) { return_cmd_error(STR_ERROR_THERE_ARE_NO_SIGNALS); } break; default: return_cmd_error(STR_ERROR_THERE_IS_NO_RAILROAD_TRACK); } // Check tile ownership, do this afterwards to avoid tripping up on house/industry tiles CommandCost ret = CheckTileOwnership(tile); if (ret.Failed()) { return ret; } return CommandCost(); } /** * Returns an appropriate default value for the second item of a dual-item instruction * @p item is the first item of the instruction */ static uint32_t GetDualInstructionInitialValue(TraceRestrictItem item) { switch (GetTraceRestrictType(item)) { case TRIT_COND_PBS_ENTRY_SIGNAL: case TRIT_COND_RESERVATION_THROUGH: return INVALID_TILE; case TRIT_COND_SLOT_OCCUPANCY: case TRIT_COND_COUNTER_VALUE: case TRIT_COND_TIME_DATE_VALUE: return 0; case TRIT_COUNTER: return 1; default: NOT_REACHED(); } } template T InstructionIteratorNext(T iter) { return IsTraceRestrictDoubleItem(*iter) ? iter + 2 : iter + 1; } template void InstructionIteratorAdvance(T &iter) { iter = InstructionIteratorNext(iter); } CommandCost TraceRestrictProgramRemoveItemAt(std::vector &items, uint32_t offset, bool shallow_mode) { TraceRestrictItem old_item = *TraceRestrictProgram::InstructionAt(items, offset); if (IsTraceRestrictConditional(old_item) && GetTraceRestrictCondFlags(old_item) != TRCF_OR) { bool remove_whole_block = false; if (GetTraceRestrictCondFlags(old_item) == 0) { if (GetTraceRestrictType(old_item) == TRIT_COND_ENDIF) { // this is an end if, can't remove these return_cmd_error(STR_TRACE_RESTRICT_ERROR_CAN_T_REMOVE_ENDIF); } else { // this is an opening if remove_whole_block = true; } } uint32_t recursion_depth = 1; std::vector::iterator remove_start = TraceRestrictProgram::InstructionAt(items, offset); std::vector::iterator remove_end = InstructionIteratorNext(remove_start); // iterate until matching end block found for (; remove_end != items.end(); InstructionIteratorAdvance(remove_end)) { TraceRestrictItem current_item = *remove_end; if (IsTraceRestrictConditional(current_item)) { if (GetTraceRestrictCondFlags(current_item) == 0) { if (GetTraceRestrictType(current_item) == TRIT_COND_ENDIF) { // this is an end if recursion_depth--; if (recursion_depth == 0) { if (remove_whole_block) { if (shallow_mode) { // must erase endif first, as it is later in the vector items.erase(remove_end, InstructionIteratorNext(remove_end)); } else { // inclusively remove up to here InstructionIteratorAdvance(remove_end); } break; } else { // exclusively remove up to here break; } } } else { // this is an opening if recursion_depth++; } } else { // this is an else/or type block if (recursion_depth == 1 && !remove_whole_block) { // exclusively remove up to here recursion_depth = 0; break; } if (recursion_depth == 1 && remove_whole_block && shallow_mode) { // shallow-removing whole if block, and it contains an else/or if, bail out return_cmd_error(STR_TRACE_RESTRICT_ERROR_CAN_T_SHALLOW_REMOVE_IF_ELIF); } } } } if (recursion_depth != 0) return CMD_ERROR; // ran off the end if (shallow_mode) { items.erase(remove_start, InstructionIteratorNext(remove_start)); } else { items.erase(remove_start, remove_end); } } else { std::vector::iterator remove_start = TraceRestrictProgram::InstructionAt(items, offset); std::vector::iterator remove_end = InstructionIteratorNext(remove_start); items.erase(remove_start, remove_end); } return CommandCost(); } static CommandCost AdvanceItemEndIteratorForBlock(const std::vector &items, const std::vector::iterator &move_start, std::vector::iterator &move_end, bool allow_elif) { TraceRestrictItem old_item = *move_start; if (IsTraceRestrictConditional(old_item)) { if (GetTraceRestrictType(old_item) == TRIT_COND_ENDIF) { // this is an else or end if, can't move these return CMD_ERROR; } if (GetTraceRestrictCondFlags(old_item) != 0) { if (allow_elif) { uint32_t recursion_depth = 0; for (; move_end != items.end(); InstructionIteratorAdvance(move_end)) { TraceRestrictItem current_item = *move_end; if (IsTraceRestrictConditional(current_item)) { if (GetTraceRestrictCondFlags(current_item) == 0) { if (GetTraceRestrictType(current_item) == TRIT_COND_ENDIF) { // this is an end if if (recursion_depth == 0) break; recursion_depth--; } else { // this is an opening if recursion_depth++; } } else if (recursion_depth == 0) { // next elif/orif break; } } } return CommandCost(); } // can't move or/else blocks return CMD_ERROR; } uint32_t recursion_depth = 1; // iterate until matching end block found for (; move_end != items.end(); InstructionIteratorAdvance(move_end)) { TraceRestrictItem current_item = *move_end; if (IsTraceRestrictConditional(current_item)) { if (GetTraceRestrictCondFlags(current_item) == 0) { if (GetTraceRestrictType(current_item) == TRIT_COND_ENDIF) { // this is an end if recursion_depth--; if (recursion_depth == 0) { // inclusively remove up to here InstructionIteratorAdvance(move_end); break; } } else { // this is an opening if recursion_depth++; } } } } if (recursion_depth != 0) return CMD_ERROR; // ran off the end } return CommandCost(); } CommandCost TraceRestrictProgramMoveItemAt(std::vector &items, uint32_t &offset, bool up, bool shallow_mode) { std::vector::iterator move_start = TraceRestrictProgram::InstructionAt(items, offset); std::vector::iterator move_end = InstructionIteratorNext(move_start); if (!shallow_mode) { CommandCost res = AdvanceItemEndIteratorForBlock(items, move_start, move_end, false); if (res.Failed()) return CommandCost(STR_TRACE_RESTRICT_ERROR_CAN_T_MOVE_ITEM); } if (up) { if (move_start == items.begin()) return_cmd_error(STR_TRACE_RESTRICT_ERROR_CAN_T_MOVE_ITEM); std::rotate(TraceRestrictProgram::InstructionAt(items, offset - 1), move_start, move_end); offset--; } else { if (move_end == items.end()) return_cmd_error(STR_TRACE_RESTRICT_ERROR_CAN_T_MOVE_ITEM); std::rotate(move_start, move_end, InstructionIteratorNext(move_end)); offset++; } return CommandCost(); } CommandCost TraceRestrictProgramDuplicateItemAt(std::vector &items, uint32_t offset) { std::vector::iterator dup_start = TraceRestrictProgram::InstructionAt(items, offset); std::vector::iterator dup_end = InstructionIteratorNext(dup_start); CommandCost res = AdvanceItemEndIteratorForBlock(items, dup_start, dup_end, true); if (res.Failed()) return CommandCost(STR_TRACE_RESTRICT_ERROR_CAN_T_DUPLICATE_ITEM); std::vector new_items; new_items.reserve(items.size() + (dup_end - dup_start)); new_items.insert(new_items.end(), items.begin(), dup_end); new_items.insert(new_items.end(), dup_start, dup_end); new_items.insert(new_items.end(), dup_end, items.end()); items = std::move(new_items); return CommandCost(); } bool TraceRestrictProgramDuplicateItemAtDryRun(const std::vector &items, uint32_t offset) { std::vector::iterator dup_start = TraceRestrictProgram::InstructionAt(const_cast &>(items), offset); std::vector::iterator dup_end = InstructionIteratorNext(dup_start); CommandCost res = AdvanceItemEndIteratorForBlock(items, dup_start, dup_end, true); return res.Succeeded(); } /** * The main command for editing a signal tracerestrict program. * @param tile The tile which contains the signal. * @param flags Internal command handler stuff. * Below apply for instruction modification actions only * @param p1 Bitstuffed items * @param p2 Item, for insert and modify operations. Flags for instruction move operations * @return the cost of this operation (which is free), or an error */ CommandCost CmdProgramSignalTraceRestrict(TileIndex tile, DoCommandFlag flags, uint32_t p1, uint32_t p2, const char *text) { TraceRestrictDoCommandType type = static_cast(GB(p1, 3, 5)); if (type >= TRDCT_PROG_COPY) { return CmdProgramSignalTraceRestrictProgMgmt(tile, flags, p1, p2, text); } Track track = static_cast(GB(p1, 0, 3)); uint32_t offset = GB(p1, 8, 16); TraceRestrictItem item = static_cast(p2); CommandCost ret = TraceRestrictCheckTileIsUsable(tile, track); if (ret.Failed()) { return ret; } bool can_make_new = (type == TRDCT_INSERT_ITEM) && (flags & DC_EXEC); bool need_existing = (type != TRDCT_INSERT_ITEM); TraceRestrictProgram *prog = GetTraceRestrictProgram(MakeTraceRestrictRefId(tile, track), can_make_new); if (need_existing && !prog) { return_cmd_error(STR_TRACE_RESTRICT_ERROR_NO_PROGRAM); } uint32_t offset_limit_exclusive = ((type == TRDCT_INSERT_ITEM) ? 1 : 0); if (prog) offset_limit_exclusive += (uint)prog->items.size(); if (offset >= offset_limit_exclusive) { return_cmd_error(STR_TRACE_RESTRICT_ERROR_OFFSET_TOO_LARGE); } // copy program std::vector items; if (prog) items = prog->items; switch (type) { case TRDCT_INSERT_ITEM: items.insert(TraceRestrictProgram::InstructionAt(items, offset), item); if (IsTraceRestrictConditional(item) && GetTraceRestrictCondFlags(item) == 0 && GetTraceRestrictType(item) != TRIT_COND_ENDIF) { // this is an opening if block, insert a corresponding end if TraceRestrictItem endif_item = 0; SetTraceRestrictType(endif_item, TRIT_COND_ENDIF); items.insert(TraceRestrictProgram::InstructionAt(items, offset) + 1, endif_item); } else if (IsTraceRestrictDoubleItem(item)) { items.insert(TraceRestrictProgram::InstructionAt(items, offset) + 1, GetDualInstructionInitialValue(item)); } break; case TRDCT_MODIFY_ITEM: { std::vector::iterator old_item = TraceRestrictProgram::InstructionAt(items, offset); if (IsTraceRestrictConditional(*old_item) != IsTraceRestrictConditional(item)) { return_cmd_error(STR_TRACE_RESTRICT_ERROR_CAN_T_CHANGE_CONDITIONALITY); } const TraceRestrictItem old_item_value = *old_item; bool old_is_dual = IsTraceRestrictDoubleItem(old_item_value); bool new_is_dual = IsTraceRestrictDoubleItem(item); *old_item = item; if (old_is_dual && !new_is_dual) { items.erase(old_item + 1); } else if (!old_is_dual && new_is_dual) { items.insert(old_item + 1, GetDualInstructionInitialValue(item)); } else if (old_is_dual && new_is_dual && GetTraceRestrictType(old_item_value) != GetTraceRestrictType(item)) { *(old_item + 1) = GetDualInstructionInitialValue(item); } break; } case TRDCT_MODIFY_DUAL_ITEM: { std::vector::iterator old_item = TraceRestrictProgram::InstructionAt(items, offset); if (!IsTraceRestrictDoubleItem(*old_item)) { return CMD_ERROR; } *(old_item + 1) = p2; break; } case TRDCT_REMOVE_ITEM: case TRDCT_SHALLOW_REMOVE_ITEM: { CommandCost res = TraceRestrictProgramRemoveItemAt(items, offset, type == TRDCT_SHALLOW_REMOVE_ITEM); if (res.Failed()) return res; break; } case TRDCT_MOVE_ITEM: { CommandCost res = TraceRestrictProgramMoveItemAt(items, offset, p2 & 1, p2 & 2); if (res.Failed()) return res; break; } case TRDCT_DUPLICATE_ITEM: { CommandCost res = TraceRestrictProgramDuplicateItemAt(items, offset); if (res.Failed()) return res; break; } default: return CMD_ERROR; } TraceRestrictProgramActionsUsedFlags actions_used_flags; CommandCost validation_result = TraceRestrictProgram::Validate(items, actions_used_flags); if (validation_result.Failed()) { return validation_result; } if (flags & DC_EXEC) { assert(prog); size_t old_size = prog->items.size(); TraceRestrictProgramActionsUsedFlags old_actions_used_flags = prog->actions_used_flags; // move in modified program prog->items.swap(items); prog->actions_used_flags = actions_used_flags; if (prog->items.size() == 0 && prog->refcount == 1) { // program is empty, and this tile is the only reference to it // so delete it, as it's redundant TraceRestrictCheckRefreshSingleSignal(prog, MakeTraceRestrictRefId(tile, track), old_actions_used_flags); TraceRestrictRemoveProgramMapping(MakeTraceRestrictRefId(tile, track)); } else { TraceRestrictCheckRefreshSignals(prog, old_size, old_actions_used_flags); } // update windows InvalidateWindowClassesData(WC_TRACE_RESTRICT); } return CommandCost(); } /** * Helper function to perform parameter bit-packing and call DoCommandP, for program management actions */ void TraceRestrictProgMgmtWithSourceDoCommandP(TileIndex tile, Track track, TraceRestrictDoCommandType type, TileIndex source_tile, Track source_track, StringID error_msg) { uint32_t p1 = 0; SB(p1, 0, 3, track); SB(p1, 3, 5, type); SB(p1, 8, 3, source_track); DoCommandP(tile, p1, source_tile, CMD_PROGRAM_TRACERESTRICT_SIGNAL | CMD_MSG(error_msg)); } /** * Sub command for copy/share/unshare operations on signal tracerestrict programs. * @param tile The tile which contains the signal. * @param flags Internal command handler stuff. * @param p1 Bitstuffed items * @param p2 Source tile, for share/copy operations * @return the cost of this operation (which is free), or an error */ CommandCost CmdProgramSignalTraceRestrictProgMgmt(TileIndex tile, DoCommandFlag flags, uint32_t p1, uint32_t p2, const char *text) { TraceRestrictDoCommandType type = static_cast(GB(p1, 3, 5)); Track track = static_cast(GB(p1, 0, 3)); Track source_track = static_cast(GB(p1, 8, 3)); TileIndex source_tile = static_cast(p2); TraceRestrictRefId self = MakeTraceRestrictRefId(tile, track); TraceRestrictRefId source = MakeTraceRestrictRefId(source_tile, source_track); assert(type >= TRDCT_PROG_COPY); CommandCost ret = TraceRestrictCheckTileIsUsable(tile, track); if (ret.Failed()) { return ret; } if (type == TRDCT_PROG_SHARE || type == TRDCT_PROG_SHARE_IF_UNMAPPED || type == TRDCT_PROG_COPY) { if (self == source) { return_cmd_error(STR_TRACE_RESTRICT_ERROR_SOURCE_SAME_AS_TARGET); } } if (type == TRDCT_PROG_SHARE || type == TRDCT_PROG_SHARE_IF_UNMAPPED || type == TRDCT_PROG_COPY || type == TRDCT_PROG_COPY_APPEND) { ret = TraceRestrictCheckTileIsUsable(source_tile, source_track); if (ret.Failed()) { return ret; } } if (type == TRDCT_PROG_SHARE_IF_UNMAPPED && GetTraceRestrictProgram(self, false) != nullptr) { return_cmd_error(STR_TRACE_RESTRICT_ERROR_TARGET_ALREADY_HAS_PROGRAM); } if (type != TRDCT_PROG_RESET && !TraceRestrictProgram::CanAllocateItem()) { return CMD_ERROR; } if (!(flags & DC_EXEC)) { return CommandCost(); } switch (type) { case TRDCT_PROG_COPY: { TraceRestrictRemoveProgramMapping(self); TraceRestrictProgram *source_prog = GetTraceRestrictProgram(source, false); if (source_prog && !source_prog->items.empty()) { TraceRestrictProgram *prog = GetTraceRestrictProgram(self, true); if (!prog) { // allocation failed return CMD_ERROR; } prog->items = source_prog->items; // copy prog->Validate(); TraceRestrictCheckRefreshSignals(prog, 0, TRPAUF_NONE); } break; } case TRDCT_PROG_COPY_APPEND: { TraceRestrictProgram *source_prog = GetTraceRestrictProgram(source, false); if (source_prog && !source_prog->items.empty()) { TraceRestrictProgram *prog = GetTraceRestrictProgram(self, true); if (!prog) { // allocation failed return CMD_ERROR; } size_t old_size = prog->items.size(); TraceRestrictProgramActionsUsedFlags old_actions_used_flags = prog->actions_used_flags; prog->items.reserve(prog->items.size() + source_prog->items.size()); // this is in case prog == source_prog prog->items.insert(prog->items.end(), source_prog->items.begin(), source_prog->items.end()); // append prog->Validate(); TraceRestrictCheckRefreshSignals(prog, old_size, old_actions_used_flags); } break; } case TRDCT_PROG_SHARE: case TRDCT_PROG_SHARE_IF_UNMAPPED: { TraceRestrictRemoveProgramMapping(self); TraceRestrictProgram *source_prog = GetTraceRestrictProgram(source, true); if (!source_prog) { // allocation failed return CMD_ERROR; } TraceRestrictCreateProgramMapping(self, source_prog); TraceRestrictCheckRefreshSingleSignal(source_prog, self, TRPAUF_NONE); break; } case TRDCT_PROG_UNSHARE: { std::vector items; TraceRestrictProgram *prog = GetTraceRestrictProgram(self, false); if (prog) { // copy program into temporary items = prog->items; } // remove old program TraceRestrictRemoveProgramMapping(self); if (items.size()) { // if prog is non-empty, create new program and move temporary in TraceRestrictProgram *new_prog = GetTraceRestrictProgram(self, true); if (!new_prog) { // allocation failed return CMD_ERROR; } new_prog->items.swap(items); new_prog->Validate(); TraceRestrictCheckRefreshSingleSignal(new_prog, self, TRPAUF_NONE); } break; } case TRDCT_PROG_RESET: { TraceRestrictRemoveProgramMapping(self); break; } default: return CMD_ERROR; } // update windows InvalidateWindowClassesData(WC_TRACE_RESTRICT); return CommandCost(); } int GetTraceRestrictTimeDateValue(TraceRestrictTimeDateValueField type) { const TickMinutes now = _settings_game.game_time.NowInTickMinutes(); switch (type) { case TRTDVF_MINUTE: return now.ClockMinute(); case TRTDVF_HOUR: return now.ClockHour(); case TRTDVF_HOUR_MINUTE: return now.ClockHHMM(); case TRTDVF_DAY: return CalTime::CurDay(); case TRTDVF_MONTH: return CalTime::CurMonth() + 1; default: return 0; } } int GetTraceRestrictTimeDateValueFromStateTicks(TraceRestrictTimeDateValueField type, StateTicks state_ticks) { const TickMinutes minutes = _settings_game.game_time.ToTickMinutes(state_ticks); switch (type) { case TRTDVF_MINUTE: return minutes.ClockMinute(); case TRTDVF_HOUR: return minutes.ClockHour(); case TRTDVF_HOUR_MINUTE: return minutes.ClockHHMM(); case TRTDVF_DAY: { CalTime::YearMonthDay ymd = CalTime::ConvertDateToYMD(StateTicksToCalendarDate(state_ticks)); return ymd.day; } case TRTDVF_MONTH: { CalTime::YearMonthDay ymd = CalTime::ConvertDateToYMD(StateTicksToCalendarDate(state_ticks)); return ymd.month + 1; } default: return 0; } } /** * This is called when a station, waypoint or depot is about to be deleted * Scan program pool and change any references to it to the invalid station ID, to avoid dangling references */ void TraceRestrictRemoveDestinationID(TraceRestrictOrderCondAuxField type, uint16_t index) { for (TraceRestrictProgram *prog : TraceRestrictProgram::Iterate()) { for (size_t i = 0; i < prog->items.size(); i++) { TraceRestrictItem &item = prog->items[i]; // note this is a reference, if (GetTraceRestrictType(item) == TRIT_COND_CURRENT_ORDER || GetTraceRestrictType(item) == TRIT_COND_NEXT_ORDER || GetTraceRestrictType(item) == TRIT_COND_LAST_STATION) { if (GetTraceRestrictAuxField(item) == type && GetTraceRestrictValue(item) == index) { SetTraceRestrictValueDefault(item, TRVT_ORDER); // this updates the instruction in-place } } if (IsTraceRestrictDoubleItem(item)) i++; } } // update windows InvalidateWindowClassesData(WC_TRACE_RESTRICT); } /** * This is called when a group is about to be deleted * Scan program pool and change any references to it to the invalid group ID, to avoid dangling references */ void TraceRestrictRemoveGroupID(GroupID index) { for (TraceRestrictProgram *prog : TraceRestrictProgram::Iterate()) { for (size_t i = 0; i < prog->items.size(); i++) { TraceRestrictItem &item = prog->items[i]; // note this is a reference, if (GetTraceRestrictType(item) == TRIT_COND_TRAIN_GROUP && GetTraceRestrictValue(item) == index) { SetTraceRestrictValueDefault(item, TRVT_GROUP_INDEX); // this updates the instruction in-place } if (IsTraceRestrictDoubleItem(item)) i++; } } // update windows InvalidateWindowClassesData(WC_TRACE_RESTRICT); } /** * This is called when a company is about to be deleted or taken over * Scan program pool and change any references to it to the new company ID, to avoid dangling references * Change owner and/or delete slots */ void TraceRestrictUpdateCompanyID(CompanyID old_company, CompanyID new_company) { for (TraceRestrictProgram *prog : TraceRestrictProgram::Iterate()) { for (size_t i = 0; i < prog->items.size(); i++) { TraceRestrictItem &item = prog->items[i]; // note this is a reference, if (GetTraceRestrictType(item) == TRIT_COND_TRAIN_OWNER) { if (GetTraceRestrictValue(item) == old_company) { SetTraceRestrictValue(item, new_company); // this updates the instruction in-place } } if (IsTraceRestrictDoubleItem(item)) i++; } } for (TraceRestrictSlot *slot : TraceRestrictSlot::Iterate()) { if (slot->owner != old_company) continue; if (new_company == INVALID_OWNER) { TraceRestrictRemoveSlotID(slot->index); delete slot; } else { slot->owner = new_company; } } for (TraceRestrictCounter *ctr : TraceRestrictCounter::Iterate()) { if (ctr->owner != old_company) continue; if (new_company == INVALID_OWNER) { TraceRestrictRemoveCounterID(ctr->index); delete ctr; } else { ctr->owner = new_company; } } // update windows InvalidateWindowClassesData(WC_TRACE_RESTRICT); InvalidateWindowClassesData(WC_TRACE_RESTRICT_SLOTS); InvalidateWindowClassesData(WC_TRACE_RESTRICT_COUNTERS); } static btree::btree_multimap slot_vehicle_index; /** * Add vehicle to occupants if possible and not already an occupant * @param v Vehicle * @param force Add the vehicle even if the slot is at/over capacity * @return whether vehicle is now an occupant */ bool TraceRestrictSlot::Occupy(const Vehicle *v, bool force) { if (this->IsOccupant(v->index)) return true; if (this->occupants.size() >= this->max_occupancy && !force) return false; this->occupants.push_back(v->index); this->AddIndex(v); this->UpdateSignals(); return true; } /** * Dry-run adding vehicle ID to occupants if possible and not already an occupant * @param id Vehicle ID * @return whether vehicle ID would be an occupant */ bool TraceRestrictSlot::OccupyDryRun(VehicleID id) { if (this->IsOccupant(id)) return true; if (this->occupants.size() >= this->max_occupancy) return false; return true; } /** * Add vehicle ID to occupants if possible and not already an occupant, record any changes in the temporary state to be reverted later * @param id Vehicle ID * @param state Temporary state * @return whether vehicle ID is now an occupant */ bool TraceRestrictSlot::OccupyUsingTemporaryState(VehicleID id, TraceRestrictSlotTemporaryState *state) { if (this->IsOccupant(id)) return true; if (this->occupants.size() >= this->max_occupancy) return false; this->occupants.push_back(id); if (find_index(state->veh_temporarily_removed, this->index) < 0) { include(state->veh_temporarily_added, this->index); } return true; } /** * Remove vehicle from occupants * @param v Vehicle */ void TraceRestrictSlot::Vacate(const Vehicle *v) { if (container_unordered_remove(this->occupants, v->index)) { this->DeIndex(v->index, v); this->UpdateSignals(); } } /** * Remove vehicle ID from occupants, record any changes in the temporary state to be reverted later * @param id Vehicle ID * @param state Temporary state */ void TraceRestrictSlot::VacateUsingTemporaryState(VehicleID id, TraceRestrictSlotTemporaryState *state) { if (container_unordered_remove(this->occupants, id)) { if (find_index(state->veh_temporarily_added, this->index) < 0) { include(state->veh_temporarily_removed, this->index); } } } /** Remove all occupants */ void TraceRestrictSlot::Clear() { for (VehicleID id : this->occupants) { this->DeIndex(id, nullptr); } this->occupants.clear(); } void TraceRestrictSlot::UpdateSignals() { for (SignalReference sr : this->progsig_dependants) { AddTrackToSignalBuffer(sr.tile, sr.track, GetTileOwner(sr.tile)); UpdateSignalsInBuffer(); } } /** * Add vehicle to vehicle slot index * @param v Vehicle pointer */ void TraceRestrictSlot::AddIndex(const Vehicle *v) { slot_vehicle_index.insert({ v->index, this->index }); SetBit(const_cast(v)->vehicle_flags, VF_HAVE_SLOT); SetWindowDirty(WC_VEHICLE_DETAILS, v->index); InvalidateWindowClassesData(WC_TRACE_RESTRICT_SLOTS); } /** * Remove vehicle from vehicle slot index * @param id Vehicle ID * @param v Vehicle pointer (optional) or nullptr */ void TraceRestrictSlot::DeIndex(VehicleID id, const Vehicle *v) { auto start = slot_vehicle_index.lower_bound(id); for (auto it = start; it != slot_vehicle_index.end() && it->first == id; ++it) { if (it->second == this->index) { bool is_first_in_range = (it == start); auto next = slot_vehicle_index.erase(it); if (is_first_in_range && (next == slot_vehicle_index.end() || next->first != id)) { /* Only one item, which we've just erased, clear the vehicle flag */ if (v == nullptr) v = Vehicle::Get(id); ClrBit(const_cast(v)->vehicle_flags, VF_HAVE_SLOT); } break; } } SetWindowDirty(WC_VEHICLE_DETAILS, id); InvalidateWindowClassesData(WC_TRACE_RESTRICT_SLOTS); } /** Rebuild slot vehicle index after loading */ void TraceRestrictSlot::RebuildVehicleIndex() { slot_vehicle_index.clear(); for (const TraceRestrictSlot *slot : TraceRestrictSlot::Iterate()) { for (VehicleID id : slot->occupants) { slot_vehicle_index.insert({ id, slot->index }); } } } bool TraceRestrictSlot::ValidateVehicleIndex() { btree::btree_multimap saved_slot_vehicle_index = std::move(slot_vehicle_index); RebuildVehicleIndex(); bool ok = multimaps_equalivalent(saved_slot_vehicle_index, slot_vehicle_index); slot_vehicle_index = std::move(saved_slot_vehicle_index); return ok; } void TraceRestrictSlot::ValidateSlotOccupants(std::function log) { char cclog_buffer[1024]; #define CCLOG(...) { \ seprintf(cclog_buffer, lastof(cclog_buffer), __VA_ARGS__); \ DEBUG(desync, 0, "%s", cclog_buffer); \ if (log) log(cclog_buffer); \ } for (const TraceRestrictSlot *slot : TraceRestrictSlot::Iterate()) { for (VehicleID id : slot->occupants) { const Vehicle *v = Vehicle::GetIfValid(id); if (v) { if (v->type != slot->vehicle_type) CCLOG("Slot %u (%s) has wrong vehicle type (%u, %u): %s", slot->index, slot->name.c_str(), v->type, slot->vehicle_type, scope_dumper().VehicleInfo(v)); if (!v->IsPrimaryVehicle()) CCLOG("Slot %u (%s) has non-primary vehicle: %s", slot->index, slot->name.c_str(), scope_dumper().VehicleInfo(v)); if (!HasBit(v->vehicle_flags, VF_HAVE_SLOT)) CCLOG("Slot %u (%s) has vehicle without VF_HAVE_SLOT: %s", slot->index, slot->name.c_str(), scope_dumper().VehicleInfo(v)); } else { CCLOG("Slot %u (%s) has non-existent vehicle ID: %u", slot->index, slot->name.c_str(), id); } } } #undef CCLOG } /** Slot pool is about to be cleared */ void TraceRestrictSlot::PreCleanPool() { slot_vehicle_index.clear(); } std::vector TraceRestrictSlotTemporaryState::change_stack; /** Revert any temporary changes */ void TraceRestrictSlotTemporaryState::RevertTemporaryChanges(VehicleID veh) { for (TraceRestrictSlotID id : this->veh_temporarily_added) { TraceRestrictSlot *slot = TraceRestrictSlot::Get(id); container_unordered_remove(slot->occupants, veh); } for (TraceRestrictSlotID id : this->veh_temporarily_removed) { TraceRestrictSlot *slot = TraceRestrictSlot::Get(id); include(slot->occupants, veh); } this->veh_temporarily_added.clear(); this->veh_temporarily_removed.clear(); } /** Apply any temporary changes */ void TraceRestrictSlotTemporaryState::ApplyTemporaryChanges(const Vehicle *v) { VehicleID veh = v->index; for (TraceRestrictSlotID id : this->veh_temporarily_added) { TraceRestrictSlot *slot = TraceRestrictSlot::Get(id); if (slot->IsOccupant(veh)) { slot->AddIndex(v); slot->UpdateSignals(); } } for (TraceRestrictSlotID id : this->veh_temporarily_removed) { TraceRestrictSlot *slot = TraceRestrictSlot::Get(id); if (!slot->IsOccupant(veh)) { slot->DeIndex(v->index, v); slot->UpdateSignals(); } } this->veh_temporarily_added.clear(); this->veh_temporarily_removed.clear(); } /** Apply any temporary changes to a parent temporary state */ void TraceRestrictSlotTemporaryState::ApplyTemporaryChangesToParent(VehicleID veh, TraceRestrictSlotTemporaryState *parent) { for (TraceRestrictSlotID id : this->veh_temporarily_added) { if (find_index(parent->veh_temporarily_removed, id) < 0) { include(parent->veh_temporarily_added, id); } } for (TraceRestrictSlotID id : this->veh_temporarily_removed) { if (find_index(parent->veh_temporarily_added, id) < 0) { include(parent->veh_temporarily_removed, id); } } this->veh_temporarily_added.clear(); this->veh_temporarily_removed.clear(); } /** Pop from change stack and apply any temporary changes (to the parent temporary state if present) */ void TraceRestrictSlotTemporaryState::PopFromChangeStackApplyTemporaryChanges(const Vehicle *v) { assert(this->change_stack.back() == this); this->change_stack.pop_back(); this->is_active = false; if (this->change_stack.empty()) { this->ApplyTemporaryChanges(v); } else { this->ApplyTemporaryChangesToParent(v->index, this->change_stack.back()); } } /** Remove vehicle ID from all slot occupants */ void TraceRestrictRemoveVehicleFromAllSlots(VehicleID vehicle_id) { const auto start = slot_vehicle_index.lower_bound(vehicle_id); auto it = start; for (; it != slot_vehicle_index.end() && it->first == vehicle_id; ++it) { auto slot = TraceRestrictSlot::Get(it->second); container_unordered_remove(slot->occupants, vehicle_id); slot->UpdateSignals(); } const bool anything_to_erase = (start != it); slot_vehicle_index.erase(start, it); if (anything_to_erase) InvalidateWindowClassesData(WC_TRACE_RESTRICT_SLOTS); } /** Replace all instance of a vehicle ID with another, in all slot occupants */ void TraceRestrictTransferVehicleOccupantInAllSlots(VehicleID from, VehicleID to) { std::vector slots; const auto start = slot_vehicle_index.lower_bound(from); auto it = start; for (; it != slot_vehicle_index.end() && it->first == from; ++it) { slots.push_back(it->second); } slot_vehicle_index.erase(start, it); for (TraceRestrictSlotID slot_id : slots) { TraceRestrictSlot *slot = TraceRestrictSlot::Get(slot_id); for (VehicleID &id : slot->occupants) { if (id == from) { id = to; slot_vehicle_index.insert({ to, slot_id }); } } } if (!slots.empty()) InvalidateWindowClassesData(WC_TRACE_RESTRICT_SLOTS); } /** Get list of slots occupied by a vehicle ID */ void TraceRestrictGetVehicleSlots(VehicleID id, std::vector &out) { for (auto it = slot_vehicle_index.lower_bound(id); it != slot_vehicle_index.end() && it->first == id; ++it) { out.push_back(it->second); } } /** * This is called when a slot is about to be deleted * Scan program pool and change any references to it to the invalid group ID, to avoid dangling references * Scan order list and change any references to it to the invalid group ID, to avoid dangling slot condition references */ void TraceRestrictRemoveSlotID(TraceRestrictSlotID index) { for (TraceRestrictProgram *prog : TraceRestrictProgram::Iterate()) { for (size_t i = 0; i < prog->items.size(); i++) { TraceRestrictItem &item = prog->items[i]; // note this is a reference, if ((GetTraceRestrictType(item) == TRIT_SLOT || GetTraceRestrictType(item) == TRIT_COND_TRAIN_IN_SLOT) && GetTraceRestrictValue(item) == index) { SetTraceRestrictValueDefault(item, TRVT_SLOT_INDEX); // this updates the instruction in-place } if ((GetTraceRestrictType(item) == TRIT_COND_SLOT_OCCUPANCY) && GetTraceRestrictValue(item) == index) { SetTraceRestrictValueDefault(item, TRVT_SLOT_INDEX_INT); // this updates the instruction in-place } if (IsTraceRestrictDoubleItem(item)) i++; } } bool changed_order = false; for (Order *o : Order::Iterate()) { if (o->IsType(OT_CONDITIONAL) && (o->GetConditionVariable() == OCV_SLOT_OCCUPANCY || o->GetConditionVariable() == OCV_VEH_IN_SLOT) && o->GetXData() == index) { o->GetXDataRef() = INVALID_TRACE_RESTRICT_SLOT_ID; changed_order = true; } if (o->IsType(OT_SLOT) && o->GetDestination() == index) { o->SetDestination(INVALID_TRACE_RESTRICT_SLOT_ID); changed_order = true; } } // update windows InvalidateWindowClassesData(WC_TRACE_RESTRICT); if (changed_order) { InvalidateWindowClassesData(WC_VEHICLE_ORDERS); InvalidateWindowClassesData(WC_VEHICLE_TIMETABLE); } for (SignalReference sr : TraceRestrictSlot::Get(index)->progsig_dependants) { if (IsProgrammableSignal(GetSignalType(sr.tile, sr.track))) { extern void RemoveProgramSlotDependencies(TraceRestrictSlotID slot_being_removed, SignalReference signal_to_update); RemoveProgramSlotDependencies(index, sr); } } } static bool IsUniqueSlotName(const char *name) { for (const TraceRestrictSlot *slot : TraceRestrictSlot::Iterate()) { if (slot->name == name) return false; } return true; } /** * Create a new slot. * @param tile unused * @param flags type of operation * @param p1 bitstuffed elements * - p2 = (bit 0 - 2) - vehicle type * @param p2 unused * @param text new slot name * @return the cost of this operation or an error */ CommandCost CmdCreateTraceRestrictSlot(TileIndex tile, DoCommandFlag flags, uint32_t p1, uint32_t p2, const char *text) { if (!TraceRestrictSlot::CanAllocateItem()) return CMD_ERROR; if (StrEmpty(text)) return CMD_ERROR; VehicleType vehtype = Extract(p1); if (vehtype >= VEH_COMPANY_END) return CMD_ERROR; size_t length = Utf8StringLength(text); if (length <= 0) return CMD_ERROR; if (length >= MAX_LENGTH_TRACE_RESTRICT_SLOT_NAME_CHARS) return CMD_ERROR; if (!IsUniqueSlotName(text)) return_cmd_error(STR_ERROR_NAME_MUST_BE_UNIQUE); if (flags & DC_EXEC) { TraceRestrictSlot *slot = new TraceRestrictSlot(_current_company, vehtype); slot->name = text; // update windows InvalidateWindowClassesData(WC_TRACE_RESTRICT); InvalidateWindowClassesData(WC_TRACE_RESTRICT_SLOTS); } return CommandCost(); } /** * Deletes a slot. * @param tile unused * @param flags type of operation * @param p1 index of array group * - p1 bit 0-15 : Slot ID * @param p2 unused * @param text unused * @return the cost of this operation or an error */ CommandCost CmdDeleteTraceRestrictSlot(TileIndex tile, DoCommandFlag flags, uint32_t p1, uint32_t p2, const char *text) { TraceRestrictSlot *slot = TraceRestrictSlot::GetIfValid(p1); if (slot == nullptr || slot->owner != _current_company) return CMD_ERROR; if (flags & DC_EXEC) { /* notify tracerestrict that group is about to be deleted */ TraceRestrictRemoveSlotID(slot->index); delete slot; InvalidateWindowClassesData(WC_TRACE_RESTRICT); InvalidateWindowClassesData(WC_TRACE_RESTRICT_SLOTS); InvalidateWindowClassesData(WC_VEHICLE_ORDERS); } return CommandCost(); } /** * Alter a slot * @param tile unused * @param flags type of operation * @param p1 index of array group * - p1 bit 0-15 : GroupID * - p1 bit 16: 0 - Rename group * 1 - Change max occupancy * @param p2 new max occupancy * @param text the new name * @return the cost of this operation or an error */ CommandCost CmdAlterTraceRestrictSlot(TileIndex tile, DoCommandFlag flags, uint32_t p1, uint32_t p2, const char *text) { TraceRestrictSlot *slot = TraceRestrictSlot::GetIfValid(GB(p1, 0, 16)); if (slot == nullptr || slot->owner != _current_company) return CMD_ERROR; if (!HasBit(p1, 16)) { /* Rename slot */ if (StrEmpty(text)) return CMD_ERROR; size_t length = Utf8StringLength(text); if (length <= 0) return CMD_ERROR; if (length >= MAX_LENGTH_TRACE_RESTRICT_SLOT_NAME_CHARS) return CMD_ERROR; if (!IsUniqueSlotName(text)) return_cmd_error(STR_ERROR_NAME_MUST_BE_UNIQUE); if (flags & DC_EXEC) { slot->name = text; } } else { /* Change max occupancy */ if (flags & DC_EXEC) { slot->max_occupancy = p2; slot->UpdateSignals(); } } if (flags & DC_EXEC) { // update windows InvalidateWindowClassesData(WC_TRACE_RESTRICT); InvalidateWindowClassesData(WC_TRACE_RESTRICT_SLOTS); InvalidateWindowClassesData(WC_VEHICLE_ORDERS); InvalidateWindowClassesData(WC_SIGNAL_PROGRAM); } return CommandCost(); } /** * Add a vehicle to a slot * @param tile unused * @param flags type of operation * @param p1 index of array group * - p1 bit 0-15 : GroupID * @param p2 index of vehicle * - p2 bit 0-19 : VehicleID * @param text unused * @return the cost of this operation or an error */ CommandCost CmdAddVehicleTraceRestrictSlot(TileIndex tile, DoCommandFlag flags, uint32_t p1, uint32_t p2, const char *text) { TraceRestrictSlot *slot = TraceRestrictSlot::GetIfValid(p1); Vehicle *v = Vehicle::GetIfValid(p2); if (slot == nullptr || slot->owner != _current_company) return CMD_ERROR; if (v == nullptr || v->owner != _current_company) return CMD_ERROR; if (v->type != slot->vehicle_type || !v->IsPrimaryVehicle()) return CMD_ERROR; if (flags & DC_EXEC) { slot->Occupy(v, true); } return CommandCost(); } /** * Remove a vehicle from a slot * @param tile unused * @param flags type of operation * @param p1 index of array group * - p1 bit 0-15 : GroupID * @param p2 index of vehicle * - p2 bit 0-19 : VehicleID * @param text unused * @return the cost of this operation or an error */ CommandCost CmdRemoveVehicleTraceRestrictSlot(TileIndex tile, DoCommandFlag flags, uint32_t p1, uint32_t p2, const char *text) { TraceRestrictSlot *slot = TraceRestrictSlot::GetIfValid(p1); Vehicle *v = Vehicle::GetIfValid(p2); if (slot == nullptr || slot->owner != _current_company) return CMD_ERROR; if (v == nullptr) return CMD_ERROR; // permit removing vehicles of other owners from your own slot if (flags & DC_EXEC) { slot->Vacate(v); } return CommandCost(); } void TraceRestrictCounter::UpdateValue(int32_t new_value) { new_value = std::max(0, new_value); if (new_value != this->value) { this->value = new_value; InvalidateWindowClassesData(WC_TRACE_RESTRICT_COUNTERS); for (SignalReference sr : this->progsig_dependants) { AddTrackToSignalBuffer(sr.tile, sr.track, GetTileOwner(sr.tile)); UpdateSignalsInBuffer(); } } } int32_t TraceRestrictCounter::ApplyValue(int32_t current, TraceRestrictCounterCondOpField op, int32_t value) { switch (op) { case TRCCOF_INCREASE: return std::max(0, current + value); case TRCCOF_DECREASE: return std::max(0, current - value); case TRCCOF_SET: return std::max(0, value); default: NOT_REACHED(); break; } } static bool IsUniqueCounterName(const char *name) { for (const TraceRestrictCounter *ctr : TraceRestrictCounter::Iterate()) { if (ctr->name == name) return false; } return true; } /** * This is called when a counter is about to be deleted * Scan program pool and change any references to it to the invalid counter ID, to avoid dangling references */ void TraceRestrictRemoveCounterID(TraceRestrictCounterID index) { for (TraceRestrictProgram *prog : TraceRestrictProgram::Iterate()) { for (size_t i = 0; i < prog->items.size(); i++) { TraceRestrictItem &item = prog->items[i]; // note this is a reference, if ((GetTraceRestrictType(item) == TRIT_COUNTER || GetTraceRestrictType(item) == TRIT_COND_COUNTER_VALUE) && GetTraceRestrictValue(item) == index) { SetTraceRestrictValueDefault(item, TRVT_COUNTER_INDEX_INT); // this updates the instruction in-place } if (IsTraceRestrictDoubleItem(item)) i++; } } bool changed_order = false; for (Order *o : Order::Iterate()) { if (o->IsType(OT_CONDITIONAL) && (o->GetConditionVariable() == OCV_COUNTER_VALUE) && GB(o->GetXData(), 16, 16) == index) { SB(o->GetXDataRef(), 16, 16, INVALID_TRACE_RESTRICT_COUNTER_ID); changed_order = true; } if (o->IsType(OT_COUNTER) && o->GetDestination() == index) { o->SetDestination(INVALID_TRACE_RESTRICT_COUNTER_ID); changed_order = true; } } // update windows InvalidateWindowClassesData(WC_TRACE_RESTRICT); if (changed_order) { InvalidateWindowClassesData(WC_VEHICLE_ORDERS); InvalidateWindowClassesData(WC_VEHICLE_TIMETABLE); } for (SignalReference sr : TraceRestrictCounter::Get(index)->progsig_dependants) { if (IsProgrammableSignal(GetSignalType(sr.tile, sr.track))) { extern void RemoveProgramCounterDependencies(TraceRestrictCounterID ctr_being_removed, SignalReference signal_to_update); RemoveProgramCounterDependencies(index, sr); } } } /** * Create a new counter. * @param tile unused * @param flags type of operation * @param p1 unused * @param p2 unused * @param text new counter name * @return the cost of this operation or an error */ CommandCost CmdCreateTraceRestrictCounter(TileIndex tile, DoCommandFlag flags, uint32_t p1, uint32_t p2, const char *text) { if (!TraceRestrictCounter::CanAllocateItem()) return CMD_ERROR; if (StrEmpty(text)) return CMD_ERROR; size_t length = Utf8StringLength(text); if (length <= 0) return CMD_ERROR; if (length >= MAX_LENGTH_TRACE_RESTRICT_SLOT_NAME_CHARS) return CMD_ERROR; if (!IsUniqueCounterName(text)) return_cmd_error(STR_ERROR_NAME_MUST_BE_UNIQUE); if (flags & DC_EXEC) { TraceRestrictCounter *ctr = new TraceRestrictCounter(_current_company); ctr->name = text; // update windows InvalidateWindowClassesData(WC_TRACE_RESTRICT); InvalidateWindowClassesData(WC_TRACE_RESTRICT_COUNTERS); } return CommandCost(); } /** * Deletes a counter. * @param tile unused * @param flags type of operation * @param p1 index of array group * - p1 bit 0-15 : Counter ID * @param p2 unused * @param text unused * @return the cost of this operation or an error */ CommandCost CmdDeleteTraceRestrictCounter(TileIndex tile, DoCommandFlag flags, uint32_t p1, uint32_t p2, const char *text) { TraceRestrictCounter *ctr = TraceRestrictCounter::GetIfValid(p1); if (ctr == nullptr || ctr->owner != _current_company) return CMD_ERROR; if (flags & DC_EXEC) { /* notify tracerestrict that counter is about to be deleted */ TraceRestrictRemoveCounterID(ctr->index); delete ctr; InvalidateWindowClassesData(WC_TRACE_RESTRICT); InvalidateWindowClassesData(WC_TRACE_RESTRICT_COUNTERS); InvalidateWindowClassesData(WC_VEHICLE_ORDERS); } return CommandCost(); } /** * Alter a counter * @param tile unused * @param flags type of operation * @param p1 index of array counter * - p1 bit 0-15 : Counter ID * - p1 bit 16: 0 - Rename counter * 1 - Change value * @param p2 new value * @param text the new name * @return the cost of this operation or an error */ CommandCost CmdAlterTraceRestrictCounter(TileIndex tile, DoCommandFlag flags, uint32_t p1, uint32_t p2, const char *text) { TraceRestrictCounter *ctr = TraceRestrictCounter::GetIfValid(GB(p1, 0, 16)); if (ctr == nullptr || ctr->owner != _current_company) return CMD_ERROR; if (!HasBit(p1, 16)) { /* Rename counter */ if (StrEmpty(text)) return CMD_ERROR; size_t length = Utf8StringLength(text); if (length <= 0) return CMD_ERROR; if (length >= MAX_LENGTH_TRACE_RESTRICT_SLOT_NAME_CHARS) return CMD_ERROR; if (!IsUniqueCounterName(text)) return_cmd_error(STR_ERROR_NAME_MUST_BE_UNIQUE); if (flags & DC_EXEC) { ctr->name = text; } } else { /* Change value */ if (flags & DC_EXEC) { ctr->UpdateValue(p2); } } if (flags & DC_EXEC) { // update windows InvalidateWindowClassesData(WC_TRACE_RESTRICT); InvalidateWindowClassesData(WC_TRACE_RESTRICT_COUNTERS); InvalidateWindowClassesData(WC_VEHICLE_ORDERS); InvalidateWindowClassesData(WC_SIGNAL_PROGRAM); } return CommandCost(); }