using MultiversalDiplomacy.Adjudicate.Decision; using MultiversalDiplomacy.Adjudicate.Logging; using MultiversalDiplomacy.Model; using MultiversalDiplomacy.Orders; namespace MultiversalDiplomacy.Adjudicate; /// /// Adjudicator for the movement phase. /// public class MovementPhaseAdjudicator : IPhaseAdjudicator { public static IPhaseAdjudicator Instance { get; } = new MovementPhaseAdjudicator(ConsoleLogger.Instance); private IAdjudicatorLogger logger { get; } public MovementPhaseAdjudicator(IAdjudicatorLogger logger) { this.logger = logger; } public List ValidateOrders(World world, List orders) { // The basic workflow of this function will be to look for invalid orders, remove these // from the working set of orders, and then perform one final check for duplicate orders // at the end. This is to comply with DATC 4.D.3's requirement that a unit that receives // a legal and an illegal order follows the legal order rather than holding. List validationResults = new List(); // Invalidate any orders that aren't a legal type for this phase and remove them from the // working set. AdjudicatorHelpers.InvalidateWrongTypes( new List { typeof(HoldOrder), typeof(MoveOrder), typeof(ConvoyOrder), typeof(SupportHoldOrder), typeof(SupportMoveOrder) }, ref orders, ref validationResults); // Invalidate any orders by a power that were given to another power's units and remove // them from the working set. AdjudicatorHelpers.InvalidateWrongPower(orders, ref orders, ref validationResults); // Since all the order types in this phase are UnitOrders, downcast to get the Unit. List unitOrders = orders.Cast().ToList(); // Invalidate any order given to a unit in the past. AdjudicatorHelpers.InvalidateIfNotMatching( order => !world.Timelines.GetFutures(order.Unit.Season).Any(), ValidationReason.IneligibleForOrder, ref unitOrders, ref validationResults); /*************** * HOLD ORDERS * ***************/ // Hold orders are always valid. List holdOrders = unitOrders.OfType().ToList(); /*************** * MOVE ORDERS * ***************/ // Move order validity is far more complicated, due to multiversal time travel and convoys. List moveOrders = unitOrders.OfType().ToList(); // Trivial check: armies cannot move to water and fleets cannot move to land. AdjudicatorHelpers.InvalidateIfNotMatching( order => (order.Unit.Type == UnitType.Army && order.Location.Type == LocationType.Land) || (order.Unit.Type == UnitType.Fleet && order.Location.Type == LocationType.Water), ValidationReason.IllegalDestinationType, ref moveOrders, ref validationResults); // Trivial check: a unit cannot move to where it already is. AdjudicatorHelpers.InvalidateIfNotMatching( order => !(order.Location.Key == order.Unit.Location && order.Season == order.Unit.Season), ValidationReason.DestinationMatchesOrigin, ref moveOrders, ref validationResults); // If the unit is moving to a valid destination that isn't where it already is, then the // move order is valid if there is a path from the origin to the destination. In the easy // case, the destination is directly adjacent to the origin with respect to the map, the // turn, and the timeline. These moves are valid. Any other move must be checked for // potential validity as a convoy move. ILookup moveOrdersByAdjacency = moveOrders .ToLookup(order => // Map adjacency world.Map.GetLocation(order.Unit).Adjacents.Contains(order.Location) // Turn adjacency && Math.Abs(order.Unit.Season.Turn - order.Season.Turn) <= 1 // Timeline adjacency && world.Timelines.InAdjacentTimeline(order.Unit.Season, order.Season)); List adjacentMoveOrders = moveOrdersByAdjacency[true].ToList(); List nonAdjacentMoveOrders = moveOrdersByAdjacency[false].ToList(); // Only armies can move to non-adjacent destinations, since fleets cannot be convoyed. AdjudicatorHelpers.InvalidateIfNotMatching( order => order.Unit.Type == UnitType.Army, ValidationReason.UnreachableDestination, ref nonAdjacentMoveOrders, ref validationResults); // For all remaining convoyable move orders, check if there is a path between the origin // and the destination. AdjudicatorHelpers.InvalidateIfNotMatching( order => PathFinder.ConvoyPathExists(world, order), ValidationReason.UnreachableDestination, ref nonAdjacentMoveOrders, ref validationResults); /***************** * CONVOY ORDERS * *****************/ // A convoy order must be to a fleet and target an army. List convoyOrders = unitOrders.OfType().ToList(); AdjudicatorHelpers.InvalidateIfNotMatching( order => order.Unit.Type == UnitType.Fleet && order.Target.Type == UnitType.Army, ValidationReason.InvalidOrderTypeForUnit, ref convoyOrders, ref validationResults); // A convoy for an illegal move is illegal, which means all the move validity checks // now need to be repeated for the convoy target. // Trivial check: cannot convoy to non-coastal province. AdjudicatorHelpers.InvalidateIfNotMatching( order => order.Location.Type == LocationType.Land && order.Province.Locations.Any(loc => loc.Type == LocationType.Water), ValidationReason.IllegalDestinationType, ref convoyOrders, ref validationResults); // Trivial check: cannot convoy a unit to its own location AdjudicatorHelpers.InvalidateIfNotMatching( order => !( order.Location.Key == order.Target.Location && order.Season == order.Target.Season), ValidationReason.DestinationMatchesOrigin, ref convoyOrders, ref validationResults); // By definition, the move enabled by a convoy order is a convoyable move order, so it // should be checked for a convoy path. AdjudicatorHelpers.InvalidateIfNotMatching( order => PathFinder.ConvoyPathExists(world, order), ValidationReason.UnreachableDestination, ref convoyOrders, ref validationResults); /*********************** * SUPPORT-HOLD ORDERS * ***********************/ // Support-hold orders are typically valid if the supporting unit can move to the // destination. List supportHoldOrders = unitOrders.OfType().ToList(); // Support-hold orders are invalid if the unit supports itself. AdjudicatorHelpers.InvalidateIfNotMatching( order => order.Unit != order.Target, ValidationReason.NoSelfSupport, ref supportHoldOrders, ref validationResults); // Support-hold orders are invalid if the supporting unit couldn't move to the destination // without a convoy. This is the same direct adjacency calculation as above, except that // the supporting unit only needs to be able to move to the *province*, even if the target // is holding in a location within that province that the supporting unit couldn't move to. // The reverse is not true: a unit cannot support another province if that province is only // reachable from a different location in the unit's province. AdjudicatorHelpers.InvalidateIfNotMatching( order => // Map adjacency with respect to province world.Map.GetLocation(order.Unit).Adjacents.Any( adjLocation => adjLocation.Province == world.Map.GetLocation(order.Target).Province) // Turn adjacency && Math.Abs(order.Unit.Season.Turn - order.Target.Season.Turn) <= 1 // Timeline adjacency && world.Timelines.InAdjacentTimeline(order.Unit.Season, order.Target.Season), ValidationReason.UnreachableSupport, ref supportHoldOrders, ref validationResults); /*********************** * SUPPORT-MOVE ORDERS * ***********************/ // Support-move orders, like support-hold orders, are typically valid if the supporting // unit can move to the destination. List supportMoveOrders = unitOrders.OfType().ToList(); // Support-move orders are invalid if the unit supports a move to any location in its own // province. AdjudicatorHelpers.InvalidateIfNotMatching( order => world.Map.GetLocation(order.Unit).Province != order.Province, ValidationReason.NoSupportMoveAgainstSelf, ref supportMoveOrders, ref validationResults); // Support-move orders, like support-hold orders, are valid only if the supporting unit // can reach the destination *province* of the move, even if the destination *location* // is unreachable (DATC 6.B.4). The same is not true of reachability from another location // in the supporting unit's province (DATC 6.B.5). AdjudicatorHelpers.InvalidateIfNotMatching( order => // Map adjacency with respect to province world.Map.GetLocation(order.Unit).Adjacents.Any( adjLocation => adjLocation.Province == order.Province) // Turn adjacency && Math.Abs(order.Unit.Season.Turn - order.Season.Turn) <= 1 // Timeline adjacency && world.Timelines.InAdjacentTimeline(order.Unit.Season, order.Season), ValidationReason.UnreachableSupport, ref supportMoveOrders, ref validationResults); // One more edge case: support-move orders by a fleet for an army are illegal if that army // requires a convoy and the supporting fleet is a part of the only convoy path (DATC // 6.D.31). // TODO: support convoy path check with "as if this fleet were missing" // Collect the valid orders together unitOrders = holdOrders.Cast() .Concat(adjacentMoveOrders) .Concat(nonAdjacentMoveOrders) .Concat(convoyOrders) .Concat(supportHoldOrders) .Concat(supportMoveOrders) .ToList(); // DATC 4.D.3 prefers that multiple orders to the same unit in the same order set be // replaced by a hold order. Since this function only takes one combined list of orders, // it is assumed that the caller has combined the order sets from all powers in a way that // is compliant with DATC 4.D.1-2. If there are still duplicate orders in the input, they // were not addressed by 4.D.1-2 and will be handled according to 4.D.3, i.e. replaced with // hold orders. Note that this happens last, after all other invalidations have been // applied in order to comply with what 4.D.3 specifies about illegal orders. List duplicateOrderedUnits = unitOrders .GroupBy(o => o.Unit) .Where(orderGroup => orderGroup.Count() > 1) .Select(orderGroup => orderGroup.Key) .ToList(); List duplicateOrders = unitOrders .Where(o => duplicateOrderedUnits.Contains(o.Unit)) .ToList(); List validOrders = unitOrders.Except(duplicateOrders).ToList(); validationResults = validationResults .Concat(duplicateOrders.Select(o => o.Invalidate(ValidationReason.DuplicateOrders))) .Concat(validOrders.Select(o => o.Validate(ValidationReason.Valid))) .ToList(); // Finally, add implicit hold orders for units without legal orders. List allOrderableUnits = world.Units .Where(unit => !world.Timelines.GetFutures(unit.Season).Any()) .ToList(); HashSet orderedUnits = validOrders.Select(order => order.Unit).ToHashSet(); List unorderedUnits = allOrderableUnits .Where(unit => !orderedUnits.Contains(unit)) .ToList(); List implicitHolds = unorderedUnits .Select(unit => new HoldOrder(unit.Power, unit)) .ToList(); validationResults = validationResults .Concat(implicitHolds.Select(o => o.Validate(ValidationReason.Valid))) .ToList(); return validationResults; } public List AdjudicateOrders(World world, List orders) { logger.Log(0, "Beginning adjudication"); // Define all adjudication decisions to be made. MovementDecisions decisions = new(world, orders); // Adjudicate all decisions. bool progress = false; int loopNum = 1; do { logger.Log(1, "Beginning loop {0}", loopNum++); progress = false; foreach (AdjudicationDecision decision in decisions.Values) { // This will noop without progress if the decision is already resolved progress |= ResolveDecision(decision, world, decisions, depth: 2); } } while (progress && decisions.Values.Any(decision => !decision.Resolved)); if (decisions.Values.Any(d => !d.Resolved)) { throw new ApplicationException("Some orders not resolved!"); } logger.Log(0, "Completed adjudication"); return decisions.Values.ToList(); } public World UpdateWorld(World world, List decisions) { logger.Log(0, "Updating world"); Dictionary moves = decisions .OfType() .ToDictionary(dm => dm.Order); Dictionary dislodges = decisions .OfType() .ToDictionary(dm => dm.Order.Unit); // All moves to a particular season in a single phase result in the same future. Keep a // record of when a future season has been created. Dictionary createdFutures = []; List createdUnits = []; List retreats = []; Timelines newTimelines = world.Timelines; // Populate createdFutures with the timeline fork decisions logger.Log(1, "Processing AdvanceTimeline decisions"); foreach (AdvanceTimeline advanceTimeline in decisions.OfType()) { logger.Log(2, "{0} = {1}", advanceTimeline, advanceTimeline.Outcome?.ToString() ?? "?"); if (advanceTimeline.Outcome == true) { // A timeline that doesn't have a future yet simply continues. Otherwise, it forks. newTimelines = newTimelines.WithNewSeason(advanceTimeline.Season, out var newFuture); createdFutures[advanceTimeline.Season] = newFuture; } } // Successful move orders result in the unit moving to the destination and creating a new // future, while unsuccessful move orders are processed the same way as non-move orders. logger.Log(1, "Processing successful moves"); foreach (DoesMove doesMove in moves.Values) { logger.Log(2, "{0} = {1}", doesMove, doesMove.Outcome?.ToString() ?? "?"); Season moveSeason = doesMove.Order.Season; if (doesMove.Outcome == true && createdFutures.TryGetValue(moveSeason, out Season future)) { Unit next = doesMove.Order.Unit.Next(doesMove.Order.Location.Key, future); logger.Log(3, "Advancing unit to {0}", next); createdUnits.Add(next); } } // Process unsuccessful moves, all holds, and all supports. logger.Log(1, "Processing stationary orders"); foreach (IsDislodged isDislodged in decisions.OfType()) { UnitOrder order = isDislodged.Order; // Skip the move orders that were processed above. if (order is MoveOrder move && moves[move].Outcome == true) { continue; } logger.Log(2, "{0} = {1}", isDislodged, isDislodged.Outcome?.ToString() ?? "?"); if (!createdFutures.ContainsKey(order.Unit.Season)) { logger.Log(3, "Skipping order because no future was created"); continue; } Season future = createdFutures[order.Unit.Season]; if (isDislodged.Outcome == false) { // Non-dislodged units continue into the future. Unit next = order.Unit.Next(world.Map.GetLocation(order.Unit).Key, future); logger.Log(3, "Advancing unit to {0}", next); createdUnits.Add(next); } else { // Create a retreat for each dislodged unit. // TODO check valid retreats and disbands logger.Log(3, "Creating retreat for {0}", order.Unit); var validRetreats = world.Map.GetLocation(order.Unit).Adjacents .Select(loc => (future, loc)) .ToList(); RetreatingUnit retreat = new(order.Unit, validRetreats); retreats.Add(retreat); } } // Record the adjudication results to the season's order history Dictionary newHistory = []; foreach (UnitOrder unitOrder in decisions.OfType().Select(d => d.Order)) { newHistory.Ensure(unitOrder.Unit.Season.Key, () => new([], [], [])); OrderHistory history = newHistory[unitOrder.Unit.Season.Key]; // TODO does this add every order to every season?? history.Orders.Add(unitOrder); history.IsDislodgedOutcomes[unitOrder.Unit.Key] = dislodges[unitOrder.Unit].Outcome == true; if (unitOrder is MoveOrder moveOrder) { history.DoesMoveOutcomes[moveOrder.Unit.Key] = moves[moveOrder].Outcome == true; } } // Log the new order history foreach ((string season, OrderHistory history) in newHistory) { string verb = world.OrderHistory.ContainsKey(season) ? "Updating" : "Adding"; logger.Log(1, "{0} history for {1}", verb, season); foreach (UnitOrder order in history.Orders) { logger.Log(2, "{0}", order); } } IEnumerable> updatedHistory = world.OrderHistory .Where(kvp => !newHistory.ContainsKey(kvp.Key)) .Concat(newHistory); // TODO provide more structured information about order outcomes World updated = world.Update( units: world.Units.Concat(createdUnits), retreats: retreats, orders: updatedHistory, timelines: newTimelines); logger.Log(0, "Completed update"); return updated; } private bool LoggedUpdate(BinaryAdjudicationDecision decision, bool outcome, int depth, string message) { bool updated = decision.Update(outcome); if (updated) { logger.Log(depth, "{0}: {1}", outcome, message); } return updated; } private bool LoggedUpdate(NumericAdjudicationDecision decision, int min, int max, int depth, string message) { bool updated = decision.Update(min, max); if (updated) { logger.Log(depth, "{0}, {1}: {2}", min, max, message); } return updated; } /// /// Attempt to resolve an adjudication decision. /// /// /// If any adjudication was further determined, returns true. If nothing was further determined, returns false. /// private bool ResolveDecision( AdjudicationDecision decision, World world, MovementDecisions decisions, int depth) { logger.Log(depth, "ResolveDecision({0})", decision); return decision.Resolved ? false : decision switch { AdvanceTimeline d => ResolveAdvanceTimeline(d, world, decisions, depth + 1), IsDislodged d => ResolveIsUnitDislodged(d, world, decisions, depth + 1), HasPath d => ResolveDoesMoveHavePath(d, world, decisions, depth + 1), GivesSupport d => ResolveIsSupportGiven(d, world, decisions, depth + 1), HoldStrength d => ResolveHoldStrength(d, world, decisions, depth + 1), AttackStrength d => ResolveAttackStrength(d, world, decisions, depth + 1), DefendStrength d => ResolveDefendStrength(d, world, decisions, depth + 1), PreventStrength d => ResolvePreventStrength(d, world, decisions, depth + 1), DoesMove d => ResolveDoesUnitMove(d, world, decisions, depth + 1), _ => throw new NotSupportedException($"Unknown decision type: {decision.GetType()}") }; } private bool ResolveAdvanceTimeline( AdvanceTimeline decision, World world, MovementDecisions decisions, int depth) { logger.Log(depth, "AdvanceTimeline({0})", decision.Season); bool progress = false; // A season at the head of a timeline always advances. if (!world.Timelines.GetFutures(decision.Season).Any()) { progress |= LoggedUpdate(decision, true, depth, "A timeline head always advances"); return progress; } // The season target of a new (i.e. not previously adjudicated) and successful move always advances. IEnumerable newIncomingMoves = decision.Orders .OfType() .Where(order => order.Season == decision.Season && !world.OrderHistory[order.Season.Key].DoesMoveOutcomes.ContainsKey(order.Unit.Key)); foreach (MoveOrder moveOrder in newIncomingMoves) { DoesMove doesMove = decisions.DoesMove[moveOrder]; progress |= ResolveDecision(doesMove, world, decisions, depth + 1); if (doesMove.Outcome == true) { progress |= LoggedUpdate(decision, true, depth, $"Advanced by {doesMove.Order}"); return progress; } } // Seasons not at the head of a timeline advance if the outcome of a battle is changed. // The outcome of a battle is changed if: // 1. The outcome of a dislodge decision is changed, // 2. The outcome of an intra-timeline move decision is changed, or // 3. The outcome of an inter-timeline move decision with that season as the destination is changed. OrderHistory history = world.OrderHistory[decision.Season.Key]; bool anyUnresolved = false; foreach (UnitOrder order in decision.Orders) { // TODO these aren't timeline-specific IsDislodged dislodged = decisions.IsDislodged[order.Unit]; progress |= ResolveDecision(dislodged, world, decisions, depth + 1); if (history.IsDislodgedOutcomes.TryGetValue(order.Unit.Key, out bool previous) && dislodged.Resolved && dislodged.Outcome != previous) { progress |= LoggedUpdate( decision, true, depth, $"History changed for {order.Unit}: dislodge {previous} => {dislodged.Outcome}"); return progress; } anyUnresolved |= !dislodged.Resolved; if (order is MoveOrder moveOrder) { DoesMove moves = decisions.DoesMove[moveOrder]; progress |= ResolveDecision(moves, world, decisions, depth + 1); if (history.DoesMoveOutcomes.TryGetValue(moveOrder.Unit.Key, out bool previousMove) && moves.Resolved && moves.Outcome != previousMove) if (moves.Resolved && moves.Outcome != previousMove) { progress |= LoggedUpdate( decision, true, depth, $"History changed for {order}: moves {previousMove} => {moves.Outcome}"); return progress; } anyUnresolved |= !moves.Resolved; } } if (!anyUnresolved) { progress |= LoggedUpdate(decision, false, depth, "No resolved changes to history"); } return progress; } private bool ResolveIsUnitDislodged( IsDislodged decision, World world, MovementDecisions decisions, int depth) { logger.Log(depth, "IsUnitDislodged({0})", decision.Order.Unit); bool progress = false; // If this unit was ordered to move and is doing so successfully, it cannot be dislodged // even if another unit will successfully move into the province. if (decision.Order is MoveOrder moveOrder) { DoesMove move = decisions.DoesMove[moveOrder]; progress |= ResolveDecision(move, world, decisions, depth + 1); // If this unit received a move order and the move is successful, it cannot be // dislodged. if (move.Outcome == true) { progress |= LoggedUpdate(decision, false, depth, "Unit successfully moves"); return progress; } // If the move is undecided, then the dislodge decision is undecidable until then. if (move.Outcome == null) { return progress; } } // If this unit isn't moving from its current province, then it is dislodged if another // unit has a successful move into its province, and it is not dislodged if every unit that // could move into its province fails to do so. bool potentialDislodger = false; foreach (MoveOrder dislodger in decision.Incoming) { DoesMove move = decisions.DoesMove[dislodger]; progress |= ResolveDecision(move, world, decisions, depth + 1); // If at least one invader will move, this unit is dislodged. if (move.Outcome == true) { progress |= LoggedUpdate(decision, true, depth, "Invading unit successfully moves"); return progress; } // If the invader could potentially move, the dislodge decision can't be resolved to // false. if (move.Outcome != false) { potentialDislodger = true; } } if (!potentialDislodger) { progress |= LoggedUpdate(decision, false, depth, "No invader can move"); } return progress; } private bool ResolveDoesMoveHavePath( HasPath decision, World world, MovementDecisions decisions, int depth) { logger.Log(depth, "DoesMoveHavePath({0})", decision.Order); bool progress= false; // If the origin and destination are adjacent, then there is a path. if (// Map adjacency world.Map.GetLocation(decision.Order.Unit).Adjacents.Contains(decision.Order.Location) // Turn adjacency && Math.Abs(decision.Order.Unit.Season.Turn - decision.Order.Season.Turn) <= 1 // Timeline adjacency && world.Timelines.InAdjacentTimeline(decision.Order.Unit.Season, decision.Order.Season)) { bool update = LoggedUpdate(decision, true, depth, "Adjacent move"); return progress | update; } // If the origin and destination are not adjacent, then the decision resolves to whether // there is a path of convoying fleets that (1) have matching orders and (2) are not // dislodged. // The adjudicator should have received a validated set of orders, so any illegal move // with no possible convoy path should have been invalidated. throw new NotImplementedException(); // TODO } private bool ResolveIsSupportGiven( GivesSupport decision, World world, MovementDecisions decisions, int depth) { logger.Log(depth, "IsSupportGiven({0})", decision.Order); bool progress = false; // Support is cut when a unit moves into the supporting unit's province with nonzero // attack strength. Support is given when there is known to be no such unit. bool potentialNonzeroAttack = false; foreach (MoveOrder cut in decision.Cuts) { AttackStrength attack = decisions.AttackStrength[cut]; progress |= ResolveDecision(attack, world, decisions, depth + 1); // If at least one attack has a nonzero minimum, the support decision can be resolved // to false. if (attack.MinValue > 0) { progress |= LoggedUpdate(decision, false, depth, "An attacker has nonzero attack strength"); return progress; } // If at least one attack has a nonzero maximum, the support decision can't be resolved // to true. if (attack.MaxValue > 0) { potentialNonzeroAttack = true; } } // Support is also cut if the unit is dislodged. IsDislodged dislodge = decisions.IsDislodged[decision.Order.Unit]; progress |= ResolveDecision(dislodge, world, decisions, depth + 1); if (dislodge.Outcome == true) { progress |= LoggedUpdate(decision, false, depth, "Unit dislodged"); return progress; } // If no attack has potentially nonzero attack strength, and the dislodge decision is // resolved to false, then the support is given. if (!potentialNonzeroAttack && dislodge.Outcome == false) { progress |= LoggedUpdate(decision, true, depth, "No successful attack or dislodge"); return progress; } // Otherwise, the support remains undecided. return progress; } private bool ResolveHoldStrength( HoldStrength decision, World world, MovementDecisions decisions, int depth) { logger.Log(depth, "HoldStrength({0})", decision.Province); bool progress = false; // If no unit is in the province, the hold strength is zero. if (decision.Order == null) { progress |= LoggedUpdate(decision, 0, 0, depth, "No unit in the province"); return progress; } // If a unit with a move order is in the province, the strength depends on the move success. if (decision.Order is MoveOrder move) { DoesMove moves = decisions.DoesMove[move]; progress |= ResolveDecision(moves, world, decisions, depth + 1); progress |= LoggedUpdate( decision, min: moves.Outcome != false ? 0 : 1, max: moves.Outcome == true ? 0 : 1, depth, "Updated based on unit's move success"); return progress; } // If a unit without a move order is in the province, add up the supports. else { int min = 1; int max = 1; foreach (SupportHoldOrder support in decision.Supports) { GivesSupport givesSupport = decisions.GivesSupport[support]; progress |= ResolveDecision(givesSupport, world, decisions, depth + 1); if (givesSupport.Outcome == true) min += 1; if (givesSupport.Outcome != false) max += 1; } progress |= LoggedUpdate(decision, min, max, depth, "Updated based on unit's supports"); return progress; } } private bool ResolveAttackStrength( AttackStrength decision, World world, MovementDecisions decisions, int depth) { logger.Log(depth, "AttackStrength({0})", decision.Order); bool progress = false; // If there is no path, the attack strength is zero. var hasPath = decisions.HasPath[decision.Order]; progress |= ResolveDecision(hasPath, world, decisions, depth + 1); if (hasPath.Outcome == false) { progress |= LoggedUpdate(decision, 0, 0, depth, "No path"); return progress; } // If there is a head to head battle, a unit at the destination that isn't moving away, or // a unit at the destination that will fail to move away, then the attacking unit will have // to dislodge it. UnitOrder? destOrder = decisions.HoldStrength[(decision.Order.Location.Province.Name, decision.Order.Season.Key)].Order; DoesMove? destMoveAway = destOrder is MoveOrder moveAway ? decisions.DoesMove[moveAway] : null; if (destMoveAway != null) { progress |= ResolveDecision(destMoveAway, world, decisions, depth + 1); } if (// In any case here, there will have to be a unit at the destination with an order, // which means that destOrder will have to be populated. Including this in the if //condition lets the compiler know it won't be null in the if block. destOrder != null && (// Is head to head decision.OpposingMove != null // Is not moving away || destMoveAway == null // Is failing to move away || destMoveAway.Outcome == false)) { string destPower = destOrder.Unit.Power; if (decision.Order.Unit.Power == destPower) { // Cannot dislodge own unit. progress |= LoggedUpdate(decision, 0, 0, depth, "Cannot dislodge own unit"); return progress; } else { // Supports won't help to dislodge units of the same power as the support. int min = 1; int max = 1; foreach (SupportMoveOrder support in decision.Supports) { if (support.Unit.Power == destPower) continue; GivesSupport givesSupport = decisions.GivesSupport[support]; progress |= ResolveDecision(givesSupport, world, decisions, depth + 1); if (givesSupport.Outcome == true) min += 1; if (givesSupport.Outcome != false) max += 1; } progress |= LoggedUpdate(decision, min, max, depth, "Updated with supports from other powers"); return progress; } } else if (destMoveAway != null && destMoveAway.Outcome == null) { // If the unit at the destination has an undecided move order, then the minimum tracks // the case where it doesn't move and the attack strength is mitigated by supports not // helping to dislodge units of the same power as the support. The maximum tracks the // case where it does move and the attack strength is unmitigated. string destPower = destMoveAway.Order.Unit.Power; int min = 1; int max = 1; foreach (SupportMoveOrder support in decision.Supports) { GivesSupport givesSupport = decisions.GivesSupport[support]; progress |= ResolveDecision(givesSupport, world, decisions, depth + 1); if (support.Unit.Power != destPower && givesSupport.Outcome == true) min += 1; if (givesSupport.Outcome != false) max += 1; } // Force min to zero in case of an attempt to disloge a unit of the same power. if (decision.Order.Unit.Power == destPower) min = 0; progress |= LoggedUpdate(decision, min, max, depth, "Updated with supports"); return progress; } else { // If the unit at the destination is going somewhere else, then attack strength // includes all supports from all powers. int min = 1; int max = 1; foreach (SupportMoveOrder support in decision.Supports) { GivesSupport givesSupport = decisions.GivesSupport[support]; progress |= ResolveDecision(givesSupport, world, decisions, depth + 1); if (givesSupport.Outcome == true) min += 1; if (givesSupport.Outcome != false) max += 1; } progress |= LoggedUpdate(decision, min, max, depth, "Updated with supports from all powers"); return progress; } } private bool ResolveDefendStrength( DefendStrength decision, World world, MovementDecisions decisions, int depth) { logger.Log(depth, "DefendStrength({0})", decision.Order); bool progress = false; // The defend strength is equal to one plus, at least, the number of known successful // supports, and at most, also the unresolved supports were they to resolve to successes. int min = 1; int max = 1; foreach (SupportMoveOrder support in decision.Supports) { GivesSupport givesSupport = decisions.GivesSupport[support]; progress |= ResolveDecision(givesSupport, world, decisions, depth + 1); if (givesSupport.Outcome == true) min += 1; if (givesSupport.Outcome != false) max += 1; } progress |= LoggedUpdate(decision, min, max, depth, "Updated based on unit's supports"); return progress; } private bool ResolvePreventStrength( PreventStrength decision, World world, MovementDecisions decisions, int depth) { logger.Log(depth, "PreventStrength({0})", decision.Order); bool progress = false; // If there is no path, the prevent strength is zero. var hasPath = decisions.HasPath[decision.Order]; progress |= ResolveDecision(hasPath, world, decisions, depth + 1); if (hasPath.Outcome == false) { progress |= LoggedUpdate(decision, 0, 0, depth, "No path to prevent"); return progress; } // If there's a head to head battle and the opposing unit succeeds in moving, the prevent // strength is zero. if (decision.OpposingMove != null && decisions.DoesMove[decision.OpposingMove].Outcome == true) { progress |= LoggedUpdate(decision, 0, 0, depth, "Cannot prevent in lost head-to-head"); return progress; } // In all other cases, the prevent strength is equal to one plus, at least, the number of // known successful supports, and at most, also the unresolved supports were they to // resolve to successes. int min = 1; int max = 1; foreach (SupportMoveOrder support in decision.Supports) { GivesSupport givesSupport = decisions.GivesSupport[support]; progress |= ResolveDecision(givesSupport, world, decisions, depth + 1); if (givesSupport.Outcome == true) min += 1; if (givesSupport.Outcome != false) max += 1; } // The minimum stays at zero if the path or head to head move decisions are unresolved, as // they may resolve to one of the conditions above that forces the prevent strength to zero. if (!hasPath.Resolved || (decision.OpposingMove != null && !decisions.DoesMove[decision.OpposingMove].Resolved)) { min = 0; } progress |= LoggedUpdate(decision, min, max, depth, "Updated based on unit's supports"); return progress; } private bool ResolveDoesUnitMove( DoesMove decision, World world, MovementDecisions decisions, int depth) { logger.Log(depth, "DoesUnitMove({0})", decision.Order); bool progress = false; // Resolve the move's attack strength. AttackStrength attack = decisions.AttackStrength[decision.Order]; progress |= ResolveDecision(attack, world, decisions, depth + 1); // In a head to head battle, the threshold for the attack strength to beat is the opposing // defend strength. Outside a head to head battle, the threshold is the destination's hold // strength. NumericAdjudicationDecision defense = decision.OpposingMove != null ? decisions.DefendStrength[decision.OpposingMove] : decisions.HoldStrength[(decision.Order.Location.Province.Name, decision.Order.Season.Key)]; progress |= ResolveDecision(defense, world, decisions, depth + 1); // If the attack doesn't beat the defense, resolve the move to false. if (attack.MaxValue <= defense.MinValue) { progress |= LoggedUpdate(decision, false, depth, "Attack can't beat defense"); return progress; } // Check if a competing move will prevent this one. bool beatsAllCompetingMoves = true; foreach (MoveOrder order in decision.Competing) { PreventStrength prevent = decisions.PreventStrength[order]; progress |= ResolveDecision(prevent, world, decisions, depth + 1); // If attack doesn't beat the prevent, resolve the move to false. if (attack.MaxValue <= prevent.MinValue) { progress |= LoggedUpdate(decision, false, depth, "Attack can't beat prevent"); return progress; } // If the attack doesn't beat the prevent, it can't resolve to true. if (attack.MinValue <= prevent.MaxValue) { beatsAllCompetingMoves = false; } } // If the attack didn't resolve to false because the defense or a prevent beat it, then // attempt to resolve it to true based on whether it beat the defense and all prevents. progress |= LoggedUpdate( decision, attack.MinValue > defense.MaxValue && beatsAllCompetingMoves, depth, "Updated based on competing moves"); return progress; } }