/* * BattleAI.cpp, part of VCMI engine * * Authors: listed in file AUTHORS in main folder * * License: GNU General Public License v2.0 or later * Full text of license available in license.txt file, in main folder * */ #include "StdInc.h" #include "BattleExchangeVariant.h" #include "../../lib/CStack.h" AttackerValue::AttackerValue() { value = 0; isRetalitated = false; } MoveTarget::MoveTarget() : positions() { score = EvaluationResult::INEFFECTIVE_SCORE; } int64_t BattleExchangeVariant::trackAttack(const AttackPossibility & ap, HypotheticBattle & state) { auto affectedUnits = ap.affectedUnits; affectedUnits.push_back(ap.attackerState); for(auto affectedUnit : affectedUnits) { auto unitToUpdate = state.getForUpdate(affectedUnit->unitId()); unitToUpdate->health = affectedUnit->health; unitToUpdate->shots = affectedUnit->shots; unitToUpdate->counterAttacks = affectedUnit->counterAttacks; unitToUpdate->movedThisRound = affectedUnit->movedThisRound; } auto attackValue = ap.attackValue(); dpsScore += attackValue; #if BATTLE_TRACE_LEVEL>=1 logAi->trace( "%s -> %s, ap attack, %s, dps: %lld, score: %lld", ap.attack.attacker->getDescription(), ap.attack.defender->getDescription(), ap.attack.shooting ? "shot" : "mellee", ap.damageDealt, attackValue); #endif return attackValue; } int64_t BattleExchangeVariant::trackAttack( std::shared_ptr attacker, std::shared_ptr defender, bool shooting, bool isOurAttack, const CBattleInfoCallback & cb, bool evaluateOnly) { const std::string cachingStringBlocksRetaliation = "type_BLOCKS_RETALIATION"; static const auto selectorBlocksRetaliation = Selector::type()(Bonus::BLOCKS_RETALIATION); const bool counterAttacksBlocked = attacker->hasBonus(selectorBlocksRetaliation, cachingStringBlocksRetaliation); TDmgRange retaliation; BattleAttackInfo bai(attacker.get(), defender.get(), shooting); if(shooting) { bai.attackerPos.setXY(8, 5); } auto attack = cb.battleEstimateDamage(bai, &retaliation); int64_t attackDamage = (attack.first + attack.second) / 2; int64_t defenderDamageReduce = AttackPossibility::calculateDamageReduce(attacker.get(), defender.get(), attackDamage, cb); int64_t attackerDamageReduce = 0; if(!evaluateOnly) { #if BATTLE_TRACE_LEVEL>=1 logAi->trace( "%s -> %s, normal attack, %s, dps: %lld, %lld", attacker->getDescription(), defender->getDescription(), shooting ? "shot" : "mellee", attackDamage, defenderDamageReduce); #endif if(isOurAttack) { dpsScore += defenderDamageReduce; attackerValue[attacker->unitId()].value += defenderDamageReduce; } else dpsScore -= defenderDamageReduce; defender->damage(attackDamage); attacker->afterAttack(shooting, false); } if(defender->alive() && defender->ableToRetaliate() && !counterAttacksBlocked && !shooting) { if(retaliation.second != 0) { auto retaliationDamage = (retaliation.first + retaliation.second) / 2; attackerDamageReduce = AttackPossibility::calculateDamageReduce(defender.get(), attacker.get(), retaliationDamage, cb); if(!evaluateOnly) { #if BATTLE_TRACE_LEVEL>=1 logAi->trace( "%s -> %s, retaliation, dps: %lld, %lld", defender->getDescription(), attacker->getDescription(), retaliationDamage, attackerDamageReduce); #endif if(isOurAttack) { dpsScore -= attackerDamageReduce; attackerValue[attacker->unitId()].isRetalitated = true; } else { dpsScore += attackerDamageReduce; attackerValue[defender->unitId()].value += attackerDamageReduce; } attacker->damage(retaliationDamage); defender->afterAttack(false, true); } } } auto score = defenderDamageReduce - attackerDamageReduce; #if BATTLE_TRACE_LEVEL>=1 if(!score) { logAi->trace("Attack has zero score d:%lld a:%lld", defenderDamageReduce, attackerDamageReduce); } #endif return score; } EvaluationResult BattleExchangeEvaluator::findBestTarget(const battle::Unit * activeStack, PotentialTargets & targets, HypotheticBattle & hb) { EvaluationResult result(targets.bestAction()); updateReachabilityMap(hb); for(auto & ap : targets.possibleAttacks) { int64_t score = calculateExchange(ap, targets, hb); if(score > result.score) { result.score = score; result.bestAttack = ap; } } if(!activeStack->waited()) { #if BATTLE_TRACE_LEVEL>=1 logAi->trace("Evaluating waited attack for %s", activeStack->getDescription()); #endif hb.getForUpdate(activeStack->unitId())->waiting = true; hb.getForUpdate(activeStack->unitId())->waitedThisTurn = true; updateReachabilityMap(hb); for(auto & ap : targets.possibleAttacks) { int64_t score = calculateExchange(ap, targets, hb); if(score > result.score) { result.score = score; result.bestAttack = ap; result.wait = true; } } } return result; } MoveTarget BattleExchangeEvaluator::findMoveTowardsUnreachable(const battle::Unit * activeStack, PotentialTargets & targets, HypotheticBattle & hb) { MoveTarget result; BattleExchangeVariant ev; if(targets.unreachableEnemies.empty()) return result; updateReachabilityMap(hb); auto dists = cb->getReachability(activeStack); auto speed = activeStack->Speed(); for(const battle::Unit * enemy : targets.unreachableEnemies) { int64_t stackScore = EvaluationResult::INEFFECTIVE_SCORE; std::vector adjacentStacks = getAdjacentUnits(enemy); auto closestStack = *vstd::minElementByFun(adjacentStacks, [&](const battle::Unit * u) -> int64_t { return dists.distToNearestNeighbour(activeStack, u) * 100000 - activeStack->getTotalHealth(); }); auto distance = dists.distToNearestNeighbour(activeStack, closestStack); if(distance >= GameConstants::BFIELD_SIZE) continue; if(distance <= speed) continue; auto turnsToRich = (distance - 1) / speed + 1; auto hexes = closestStack->getSurroundingHexes(); for(auto hex : hexes) { auto bai = BattleAttackInfo(activeStack, closestStack, cb->battleCanShoot(activeStack)); auto attack = AttackPossibility::evaluate(bai, hex, hb); attack.shootersBlockedDmg = 0; // we do not want to count on it, it is not for sure auto score = calculateExchange(attack, targets, hb) / turnsToRich; if(result.score < score) { result.score = score; result.positions = closestStack->getAttackableHexes(activeStack); } } } return result; } std::vector BattleExchangeEvaluator::getAdjacentUnits(const battle::Unit * blockerUnit) { std::queue queue; std::vector checkedStacks; queue.push(blockerUnit); while(!queue.empty()) { auto stack = queue.front(); queue.pop(); checkedStacks.push_back(stack); auto hexes = stack->getSurroundingHexes(); for(auto hex : hexes) { auto neighbor = cb->battleGetStackByPos(hex); if(neighbor && neighbor->unitSide() == stack->unitSide() && !vstd::contains(checkedStacks, neighbor)) { queue.push(neighbor); checkedStacks.push_back(neighbor); } } } return checkedStacks; } std::vector BattleExchangeEvaluator::getExchangeUnits( const AttackPossibility & ap, PotentialTargets & targets, HypotheticBattle & hb) { auto hexes = ap.attack.defender->getHexes(); if(!ap.attack.shooting) hexes.push_back(ap.from); std::vector exchangeUnits; std::vector allReachableUnits; for(auto hex : hexes) { vstd::concatenate(allReachableUnits, reachabilityMap[hex]); } vstd::removeDuplicates(allReachableUnits); auto copy = allReachableUnits; for(auto unit : copy) { for(auto adjacentUnit : getAdjacentUnits(unit)) { auto unitWithBonuses = hb.battleGetUnitByID(adjacentUnit->unitId()); if(vstd::contains(targets.unreachableEnemies, adjacentUnit) && !vstd::contains(allReachableUnits, unitWithBonuses)) { allReachableUnits.push_back(unitWithBonuses); } } } vstd::removeDuplicates(allReachableUnits); if(!vstd::contains(allReachableUnits, ap.attack.attacker)) { allReachableUnits.push_back(ap.attack.attacker); } if(allReachableUnits.size() < 2) { #if BATTLE_TRACE_LEVEL>=1 logAi->trace("Reachability map contains only %d stacks", allReachableUnits.size()); #endif return exchangeUnits; } for(int turn = 0; turn < turnOrder.size(); turn++) { for(auto unit : turnOrder[turn]) { if(vstd::contains(allReachableUnits, unit)) exchangeUnits.push_back(unit); } } return exchangeUnits; } int64_t BattleExchangeEvaluator::calculateExchange( const AttackPossibility & ap, PotentialTargets & targets, HypotheticBattle & hb) { #if BATTLE_TRACE_LEVEL>=1 logAi->trace("Battle exchange at %lld", ap.attack.shooting ? ap.dest : ap.from); #endif std::vector ourStacks; std::vector enemyStacks; enemyStacks.push_back(ap.attack.defender); std::vector exchangeUnits = getExchangeUnits(ap, targets, hb); if(exchangeUnits.empty()) { return 0; } HypotheticBattle exchangeBattle(env.get(), cb); BattleExchangeVariant v; auto melleeAttackers = ourStacks; vstd::removeDuplicates(melleeAttackers); vstd::erase_if(melleeAttackers, [&](const battle::Unit * u) -> bool { return !cb->battleCanShoot(u); }); for(auto unit : exchangeUnits) { bool isOur = cb->battleMatchOwner(ap.attack.attacker, unit, true); auto & attackerQueue = isOur ? ourStacks : enemyStacks; if(!vstd::contains(attackerQueue, unit)) { attackerQueue.push_back(unit); } } bool canUseAp = true; for(auto activeUnit : exchangeUnits) { bool isOur = cb->battleMatchOwner(ap.attack.attacker, activeUnit, true); battle::Units & attackerQueue = isOur ? ourStacks : enemyStacks; battle::Units & oppositeQueue = isOur ? enemyStacks : ourStacks; auto attacker = exchangeBattle.getForUpdate(activeUnit->unitId()); if(!attacker->alive()) { #if BATTLE_TRACE_LEVEL>=1 logAi->trace( "Attacker is dead"); #endif continue; } auto targetUnit = ap.attack.defender; if(!isOur || !exchangeBattle.getForUpdate(targetUnit->unitId())->alive()) { auto estimateAttack = [&](const battle::Unit * u) -> int64_t { auto stackWithBonuses = exchangeBattle.getForUpdate(u->unitId()); auto score = v.trackAttack( attacker, stackWithBonuses, exchangeBattle.battleCanShoot(stackWithBonuses.get()), isOur, *cb, true); #if BATTLE_TRACE_LEVEL>=1 logAi->trace("Best target selector %s->%s score = %lld", attacker->getDescription(), u->getDescription(), score); #endif return score; }; if(!oppositeQueue.empty()) { targetUnit = *vstd::maxElementByFun(oppositeQueue, estimateAttack); } else { auto reachable = exchangeBattle.battleGetUnitsIf([&](const battle::Unit * u) -> bool { if(!u->alive() || u->unitSide() == attacker->unitSide()) return false; return vstd::contains_if(reachabilityMap[u->getPosition()], [&](const battle::Unit * other) -> bool { return attacker->unitId() == other->unitId(); }); }); if(!reachable.empty()) { targetUnit = *vstd::maxElementByFun(reachable, estimateAttack); } else { #if BATTLE_TRACE_LEVEL>=1 logAi->trace("Battle queue is empty and no reachable enemy."); #endif continue; } } } auto defender = exchangeBattle.getForUpdate(targetUnit->unitId()); auto shooting = cb->battleCanShoot(attacker.get()); const int totalAttacks = attacker->getTotalAttacks(shooting); if(canUseAp && activeUnit == ap.attack.attacker && targetUnit == ap.attack.defender) { v.trackAttack(ap, exchangeBattle); } else { for(int i = 0; i < totalAttacks; i++) { v.trackAttack(attacker, defender, shooting, isOur, exchangeBattle); if(!attacker->alive() || !defender->alive()) break; } } canUseAp = false; vstd::erase_if(attackerQueue, [&](const battle::Unit * u) -> bool { return !exchangeBattle.getForUpdate(u->unitId())->alive(); }); vstd::erase_if(oppositeQueue, [&](const battle::Unit * u) -> bool { return !exchangeBattle.getForUpdate(u->unitId())->alive(); }); } // avoid blocking path for stronger stack by weaker stack // the method checks if all stacks can be placed around enemy v.adjustPositions(melleeAttackers, ap, reachabilityMap); #if BATTLE_TRACE_LEVEL>=1 logAi->trace("Exchange score: %lld", v.getScore()); #endif return v.getScore(); } void BattleExchangeVariant::adjustPositions( std::vector attackers, const AttackPossibility & ap, std::map & reachabilityMap) { auto hexes = ap.attack.defender->getSurroundingHexes(); boost::sort(attackers, [&](const battle::Unit * u1, const battle::Unit * u2) -> bool { if(attackerValue[u1->unitId()].isRetalitated && !attackerValue[u2->unitId()].isRetalitated) return true; if(attackerValue[u2->unitId()].isRetalitated && !attackerValue[u1->unitId()].isRetalitated) return false; return attackerValue[u1->unitId()].value > attackerValue[u2->unitId()].value; }); if(!ap.attack.shooting) { vstd::erase_if_present(hexes, ap.from); vstd::erase_if_present(hexes, ap.attack.attacker->occupiedHex(ap.attack.attackerPos)); } int64_t notRealizedDamage = 0; for(auto unit : attackers) { if(unit->unitId() == ap.attack.attacker->unitId()) continue; if(!vstd::contains_if(hexes, [&](BattleHex h) -> bool { return vstd::contains(reachabilityMap[h], unit); })) { notRealizedDamage += attackerValue[unit->unitId()].value; continue; } auto desiredPosition = vstd::minElementByFun(hexes, [&](BattleHex h) -> int64_t { auto score = vstd::contains(reachabilityMap[h], unit) ? reachabilityMap[h].size() : 0; if(unit->doubleWide()) { auto backHex = unit->occupiedHex(h); if(vstd::contains(hexes, backHex)) score += reachabilityMap[backHex].size(); } return score; }); hexes.erase(desiredPosition); } if(notRealizedDamage > ap.attackValue() && notRealizedDamage > attackerValue[ap.attack.attacker->unitId()].value) { dpsScore = EvaluationResult::INEFFECTIVE_SCORE; } } void BattleExchangeEvaluator::updateReachabilityMap(HypotheticBattle & hb) { const int TURN_DEPTH = 2; turnOrder.clear(); hb.battleGetTurnOrder(turnOrder, std::numeric_limits::max(), TURN_DEPTH); reachabilityMap.clear(); for(int turn = 0; turn < turnOrder.size(); turn++) { auto & turnQueue = turnOrder[turn]; HypotheticBattle turnBattle(env.get(), cb); for(const battle::Unit * unit : turnQueue) { if(turnBattle.battleCanShoot(unit)) { for(BattleHex hex = BattleHex::TOP_LEFT; hex.isValid(); hex = hex + 1) { reachabilityMap[hex].push_back(unit); } continue; } auto unitReachability = turnBattle.getReachability(unit); for(BattleHex hex = BattleHex::TOP_LEFT; hex.isValid(); hex = hex + 1) { bool reachable = unitReachability.distances[hex] <= unit->Speed(turn); if(!reachable && unitReachability.accessibility[hex] == EAccessibility::ALIVE_STACK) { const battle::Unit * hexStack = cb->battleGetUnitByPos(hex); if(hexStack && cb->battleMatchOwner(unit, hexStack, false)) { for(BattleHex neighbor : hex.neighbouringTiles()) { reachable = unitReachability.distances[neighbor] <= unit->Speed(turn); if(reachable) break; } } } if(reachable) { reachabilityMap[hex].push_back(unit); } } } } } // avoid blocking path for stronger stack by weaker stack bool BattleExchangeEvaluator::checkPositionBlocksOurStacks(HypotheticBattle & hb, const battle::Unit * activeUnit, BattleHex position) { const int BLOCKING_THRESHOLD = 70; const int BLOCKING_OWN_ATTACK_PENALTY = 100; const int BLOCKING_OWN_MOVE_PENALTY = 1; float blockingScore = 0; auto activeUnitDamage = activeUnit->getMinDamage(hb.battleCanShoot(activeUnit)) * activeUnit->getCount(); for(int turn = 0; turn < turnOrder.size(); turn++) { auto & turnQueue = turnOrder[turn]; HypotheticBattle turnBattle(env.get(), cb); auto unitToUpdate = turnBattle.getForUpdate(activeUnit->unitId()); unitToUpdate->setPosition(position); for(const battle::Unit * unit : turnQueue) { if(unit->unitId() == unitToUpdate->unitId() || cb->battleMatchOwner(unit, activeUnit, false)) continue; auto blockedUnitDamage = unit->getMinDamage(hb.battleCanShoot(unit)) * unit->getCount(); auto ratio = blockedUnitDamage / (blockedUnitDamage + activeUnitDamage); auto unitReachability = turnBattle.getReachability(unit); for(BattleHex hex = BattleHex::TOP_LEFT; hex.isValid(); hex = hex + 1) { bool enemyUnit = false; bool reachable = unitReachability.distances[hex] <= unit->Speed(turn); if(!reachable && unitReachability.accessibility[hex] == EAccessibility::ALIVE_STACK) { const battle::Unit * hexStack = turnBattle.battleGetUnitByPos(hex); if(hexStack && cb->battleMatchOwner(unit, hexStack, false)) { enemyUnit = true; for(BattleHex neighbor : hex.neighbouringTiles()) { reachable = unitReachability.distances[neighbor] <= unit->Speed(turn); if(reachable) break; } } } if(!reachable && vstd::contains(reachabilityMap[hex], unit)) { blockingScore += ratio * (enemyUnit ? BLOCKING_OWN_ATTACK_PENALTY : BLOCKING_OWN_MOVE_PENALTY); } } } } #if BATTLE_TRACE_LEVEL>=1 logAi->trace("Position %d, blocking score %f", position.hex, blockingScore); #endif return blockingScore > BLOCKING_THRESHOLD; }