/* * 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 "BattleEvaluator.h" #include "BattleExchangeVariant.h" #include "StackWithBonuses.h" #include "EnemyInfo.h" #include "tbb/parallel_for.h" #include "../../lib/CStopWatch.h" #include "../../lib/CThreadHelper.h" #include "../../lib/mapObjects/CGTownInstance.h" #include "../../lib/entities/building/TownFortifications.h" #include "../../lib/spells/CSpellHandler.h" #include "../../lib/spells/ISpellMechanics.h" #include "../../lib/battle/BattleStateInfoForRetreat.h" #include "../../lib/battle/CObstacleInstance.h" #include "../../lib/battle/BattleAction.h" #include "../../lib/CRandomGenerator.h" // TODO: remove // Eventually only IBattleInfoCallback and battle::Unit should be used, // CUnitState should be private and CStack should be removed completely #include "../../lib/CStack.h" #define LOGL(text) print(text) #define LOGFL(text, formattingEl) print(boost::str(boost::format(text) % formattingEl)) enum class SpellTypes { ADVENTURE, BATTLE, OTHER }; SpellTypes spellType(const CSpell * spell) { if(!spell->isCombat() || spell->isCreatureAbility()) return SpellTypes::OTHER; if(spell->isOffensive() || spell->hasEffects() || spell->hasBattleEffects()) return SpellTypes::BATTLE; return SpellTypes::OTHER; } BattleEvaluator::BattleEvaluator( std::shared_ptr env, std::shared_ptr cb, const battle::Unit * activeStack, PlayerColor playerID, BattleID battleID, BattleSide side, float strengthRatio, int simulationTurnsCount) :scoreEvaluator(cb->getBattle(battleID), env, strengthRatio, simulationTurnsCount), cachedAttack(), playerID(playerID), side(side), env(env), cb(cb), strengthRatio(strengthRatio), battleID(battleID), simulationTurnsCount(simulationTurnsCount) { hb = std::make_shared(env.get(), cb->getBattle(battleID)); damageCache.buildDamageCache(hb, side); targets = std::make_unique(activeStack, damageCache, hb); } BattleEvaluator::BattleEvaluator( std::shared_ptr env, std::shared_ptr cb, std::shared_ptr hb, DamageCache & damageCache, const battle::Unit * activeStack, PlayerColor playerID, BattleID battleID, BattleSide side, float strengthRatio, int simulationTurnsCount) :scoreEvaluator(cb->getBattle(battleID), env, strengthRatio, simulationTurnsCount), cachedAttack(), playerID(playerID), side(side), env(env), cb(cb), hb(hb), damageCache(damageCache), strengthRatio(strengthRatio), battleID(battleID), simulationTurnsCount(simulationTurnsCount) { targets = std::make_unique(activeStack, damageCache, hb); } std::vector BattleEvaluator::getBrokenWallMoatHexes() const { std::vector result; for(EWallPart wallPart : { EWallPart::BOTTOM_WALL, EWallPart::BELOW_GATE, EWallPart::OVER_GATE, EWallPart::UPPER_WALL }) { auto state = cb->getBattle(battleID)->battleGetWallState(wallPart); if(state != EWallState::DESTROYED) continue; auto wallHex = cb->getBattle(battleID)->wallPartToBattleHex(wallPart); auto moatHex = wallHex.cloneInDirection(BattleHex::LEFT); result.push_back(moatHex); moatHex = moatHex.cloneInDirection(BattleHex::LEFT); auto obstaclesSecondRow = cb->getBattle(battleID)->battleGetAllObstaclesOnPos(moatHex, false); for(auto obstacle : obstaclesSecondRow) { if(obstacle->obstacleType == CObstacleInstance::EObstacleType::MOAT) { result.push_back(moatHex); break; } } } return result; } std::optional BattleEvaluator::findBestCreatureSpell(const CStack *stack) { //TODO: faerie dragon type spell should be selected by server SpellID creatureSpellToCast = cb->getBattle(battleID)->getRandomCastedSpell(CRandomGenerator::getDefault(), stack); if(stack->canCast() && creatureSpellToCast != SpellID::NONE) { const CSpell * spell = creatureSpellToCast.toSpell(); if(spell->canBeCast(cb->getBattle(battleID).get(), spells::Mode::CREATURE_ACTIVE, stack)) { std::vector possibleCasts; spells::BattleCast temp(cb->getBattle(battleID).get(), stack, spells::Mode::CREATURE_ACTIVE, spell); for(auto & target : temp.findPotentialTargets()) { PossibleSpellcast ps; ps.dest = target; ps.spell = spell; evaluateCreatureSpellcast(stack, ps); possibleCasts.push_back(ps); } std::sort(possibleCasts.begin(), possibleCasts.end(), [&](const PossibleSpellcast & lhs, const PossibleSpellcast & rhs) { return lhs.value > rhs.value; }); if(!possibleCasts.empty() && possibleCasts.front().value > 0) { return possibleCasts.front(); } } } return std::nullopt; } BattleAction BattleEvaluator::selectStackAction(const CStack * stack) { #if BATTLE_TRACE_LEVEL >= 1 logAi->trace("Select stack action"); #endif //evaluate casting spell for spellcasting stack std::optional bestSpellcast = findBestCreatureSpell(stack); auto moveTarget = scoreEvaluator.findMoveTowardsUnreachable(stack, *targets, damageCache, hb); float score = EvaluationResult::INEFFECTIVE_SCORE; if(targets->possibleAttacks.empty() && bestSpellcast.has_value()) { activeActionMade = true; return BattleAction::makeCreatureSpellcast(stack, bestSpellcast->dest, bestSpellcast->spell->id); } if(!targets->possibleAttacks.empty()) { #if BATTLE_TRACE_LEVEL>=1 logAi->trace("Evaluating attack for %s", stack->getDescription()); #endif auto evaluationResult = scoreEvaluator.findBestTarget(stack, *targets, damageCache, hb); auto & bestAttack = evaluationResult.bestAttack; cachedAttack.ap = bestAttack; cachedAttack.score = evaluationResult.score; cachedAttack.turn = 0; cachedAttack.waited = evaluationResult.wait; //TODO: consider more complex spellcast evaluation, f.e. because "re-retaliation" during enemy move in same turn for melee attack etc. if(bestSpellcast.has_value() && bestSpellcast->value > bestAttack.damageDiff()) { // return because spellcast value is damage dealt and score is dps reduce activeActionMade = true; return BattleAction::makeCreatureSpellcast(stack, bestSpellcast->dest, bestSpellcast->spell->id); } if(evaluationResult.score > score) { score = evaluationResult.score; logAi->debug("BattleAI: %s -> %s x %d, from %d curpos %d dist %d speed %d: +%2f -%2f = %2f", bestAttack.attackerState->unitType()->getJsonKey(), bestAttack.affectedUnits[0]->unitType()->getJsonKey(), bestAttack.affectedUnits[0]->getCount(), (int)bestAttack.from, (int)bestAttack.attack.attacker->getPosition().hex, bestAttack.attack.chargeDistance, bestAttack.attack.attacker->getMovementRange(0), bestAttack.defenderDamageReduce, bestAttack.attackerDamageReduce, score ); if (moveTarget.score <= score) { if(evaluationResult.wait) { return BattleAction::makeWait(stack); } else if(bestAttack.attack.shooting) { activeActionMade = true; return BattleAction::makeShotAttack(stack, bestAttack.attack.defender); } else { if(bestAttack.collateralDamageReduce && bestAttack.collateralDamageReduce >= bestAttack.defenderDamageReduce / 2 && score < 0) { return BattleAction::makeDefend(stack); } auto enemyMellee = hb->getUnitsIf([this](const battle::Unit * u) -> bool { return u->unitSide() == BattleSide::ATTACKER && !hb->battleCanShoot(u); }); bool isTargetOutsideFort = bestAttack.dest.getY() < GameConstants::BFIELD_WIDTH - 4; bool siegeDefense = stack->unitSide() == BattleSide::DEFENDER && !bestAttack.attack.shooting && hb->battleGetFortifications().hasMoat && !enemyMellee.empty() && isTargetOutsideFort; if(siegeDefense) { logAi->trace("Evaluating exchange at %d self-defense", stack->getPosition().hex); BattleAttackInfo bai(stack, stack, 0, false); AttackPossibility apDefend(stack->getPosition(), stack->getPosition(), bai); float defenseValue = scoreEvaluator.evaluateExchange(apDefend, 0, *targets, damageCache, hb); if((defenseValue > score && score <= 0) || (defenseValue > 2 * score && score > 0)) { return BattleAction::makeDefend(stack); } } activeActionMade = true; return BattleAction::makeMeleeAttack(stack, bestAttack.attack.defenderPos, bestAttack.from); } } } } //ThreatMap threatsToUs(stack); // These lines may be useful but they are't used in the code. if(moveTarget.score > score) { score = moveTarget.score; cachedAttack.ap = moveTarget.cachedAttack; cachedAttack.score = score; cachedAttack.turn = moveTarget.turnsToRich; if(stack->waited()) { logAi->debug( "Moving %s towards hex %s[%d], score: %2f", stack->getDescription(), moveTarget.cachedAttack->attack.defender->getDescription(), moveTarget.cachedAttack->attack.defender->getPosition().hex, moveTarget.score); return goTowardsNearest(stack, moveTarget.positions, *targets); } else { cachedAttack.waited = true; return BattleAction::makeWait(stack); } } if(score <= EvaluationResult::INEFFECTIVE_SCORE && !stack->hasBonusOfType(BonusType::FLYING) && stack->unitSide() == BattleSide::ATTACKER && cb->getBattle(battleID)->battleGetFortifications().hasMoat) { auto brokenWallMoat = getBrokenWallMoatHexes(); if(brokenWallMoat.size()) { activeActionMade = true; if(stack->doubleWide() && vstd::contains(brokenWallMoat, stack->getPosition())) return BattleAction::makeMove(stack, stack->getPosition().cloneInDirection(BattleHex::RIGHT)); else return goTowardsNearest(stack, brokenWallMoat, *targets); } } return stack->waited() ? BattleAction::makeDefend(stack) : BattleAction::makeWait(stack); } uint64_t timeElapsed(std::chrono::time_point start) { auto end = std::chrono::high_resolution_clock::now(); return std::chrono::duration_cast(end - start).count(); } BattleAction BattleEvaluator::moveOrAttack(const CStack * stack, BattleHex hex, const PotentialTargets & targets) { auto additionalScore = 0; std::optional attackOnTheWay; for(auto & target : targets.possibleAttacks) { if(!target.attack.shooting && target.from == hex && target.attackValue() > additionalScore) { additionalScore = target.attackValue(); attackOnTheWay = target; } } if(attackOnTheWay) { activeActionMade = true; return BattleAction::makeMeleeAttack(stack, attackOnTheWay->attack.defender->getPosition(), attackOnTheWay->from); } else { if(stack->position == hex) return BattleAction::makeDefend(stack); else return BattleAction::makeMove(stack, hex); } } BattleAction BattleEvaluator::goTowardsNearest(const CStack * stack, std::vector hexes, const PotentialTargets & targets) { auto reachability = cb->getBattle(battleID)->getReachability(stack); auto avHexes = cb->getBattle(battleID)->battleGetAvailableHexes(reachability, stack, false); if(!avHexes.size() || !hexes.size()) //we are blocked or dest is blocked { return BattleAction::makeDefend(stack); } std::vector targetHexes = hexes; vstd::erase_if(targetHexes, [](const BattleHex & hex) { return !hex.isValid(); }); std::sort(targetHexes.begin(), targetHexes.end(), [&](BattleHex h1, BattleHex h2) -> bool { return reachability.distances[h1] < reachability.distances[h2]; }); BattleHex bestNeighbor = targetHexes.front(); if(reachability.distances[bestNeighbor] > GameConstants::BFIELD_SIZE) { logAi->trace("No richable hexes."); return BattleAction::makeDefend(stack); } // this turn for(auto hex : targetHexes) { if(vstd::contains(avHexes, hex)) { return moveOrAttack(stack, hex, targets); } if(stack->coversPos(hex)) { logAi->warn("Warning: already standing on neighbouring hex!"); //We shouldn't even be here... return BattleAction::makeDefend(stack); } } // not this turn scoreEvaluator.updateReachabilityMap(hb); if(stack->hasBonusOfType(BonusType::FLYING)) { std::set obstacleHexes; auto insertAffected = [](const CObstacleInstance & spellObst, std::set obstacleHexes) { auto affectedHexes = spellObst.getAffectedTiles(); obstacleHexes.insert(affectedHexes.cbegin(), affectedHexes.cend()); }; const auto & obstacles = hb->battleGetAllObstacles(); for (const auto & obst: obstacles) { if(obst->triggersEffects()) { auto triggerAbility = VLC->spells()->getById(obst->getTrigger()); auto triggerIsNegative = triggerAbility->isNegative() || triggerAbility->isDamage(); if(triggerIsNegative) insertAffected(*obst, obstacleHexes); } } // Flying stack doesn't go hex by hex, so we can't backtrack using predecessors. // We just check all available hexes and pick the one closest to the target. auto nearestAvailableHex = vstd::minElementByFun(avHexes, [&](BattleHex hex) -> int { const int NEGATIVE_OBSTACLE_PENALTY = 100; // avoid landing on negative obstacle (moat, fire wall, etc) const int BLOCKED_STACK_PENALTY = 100; // avoid landing on moat auto distance = BattleHex::getDistance(bestNeighbor, hex); if(vstd::contains(obstacleHexes, hex)) distance += NEGATIVE_OBSTACLE_PENALTY; return scoreEvaluator.checkPositionBlocksOurStacks(*hb, stack, hex) ? BLOCKED_STACK_PENALTY + distance : distance; }); return moveOrAttack(stack, *nearestAvailableHex, targets); } else { BattleHex currentDest = bestNeighbor; while(true) { if(!currentDest.isValid()) { return BattleAction::makeDefend(stack); } if(vstd::contains(avHexes, currentDest) && !scoreEvaluator.checkPositionBlocksOurStacks(*hb, stack, currentDest)) { return moveOrAttack(stack, currentDest, targets); } currentDest = reachability.predecessors[currentDest]; } } logAi->error("We should either detect that hexes are unreachable or make a move!"); return BattleAction::makeDefend(stack); } bool BattleEvaluator::canCastSpell() { auto hero = cb->getBattle(battleID)->battleGetMyHero(); if(!hero) return false; return cb->getBattle(battleID)->battleCanCastSpell(hero, spells::Mode::HERO) == ESpellCastProblem::OK; } bool BattleEvaluator::attemptCastingSpell(const CStack * activeStack) { auto hero = cb->getBattle(battleID)->battleGetMyHero(); if(!hero) return false; LOGL("Casting spells sounds like fun. Let's see..."); //Get all spells we can cast std::vector possibleSpells; for (auto const & s : VLC->spellh->objects) if (s->canBeCast(cb->getBattle(battleID).get(), spells::Mode::HERO, hero)) possibleSpells.push_back(s.get()); LOGFL("I can cast %d spells.", possibleSpells.size()); vstd::erase_if(possibleSpells, [](const CSpell *s) { return spellType(s) != SpellTypes::BATTLE; }); LOGFL("I know how %d of them works.", possibleSpells.size()); //Get possible spell-target pairs std::vector possibleCasts; for(auto spell : possibleSpells) { spells::BattleCast temp(cb->getBattle(battleID).get(), hero, spells::Mode::HERO, spell); const bool FAST = true; for(auto & target : temp.findPotentialTargets(FAST)) { PossibleSpellcast ps; ps.dest = target; ps.spell = spell; possibleCasts.push_back(ps); } } LOGFL("Found %d spell-target combinations.", possibleCasts.size()); if(possibleCasts.empty()) return false; using ValueMap = PossibleSpellcast::ValueMap; auto evaluateQueue = [&](ValueMap & values, const std::vector & queue, std::shared_ptr state, size_t minTurnSpan, bool * enemyHadTurnOut) -> bool { bool firstRound = true; bool enemyHadTurn = false; size_t ourTurnSpan = 0; bool stop = false; for(auto & round : queue) { if(!firstRound) state->nextRound(); for(auto unit : round) { if(!vstd::contains(values, unit->unitId())) values[unit->unitId()] = 0; if(!unit->alive()) continue; if(state->battleGetOwner(unit) != playerID) { enemyHadTurn = true; if(!firstRound || state->battleCastSpells(unit->unitSide()) == 0) { //enemy could counter our spell at this point //anyway, we do not know what enemy will do //just stop evaluation stop = true; break; } } else if(!enemyHadTurn) { ourTurnSpan++; } state->nextTurn(unit->unitId()); PotentialTargets potentialTargets(unit, damageCache, state); if(!potentialTargets.possibleAttacks.empty()) { AttackPossibility attackPossibility = potentialTargets.bestAction(); auto stackWithBonuses = state->getForUpdate(unit->unitId()); *stackWithBonuses = *attackPossibility.attackerState; if(attackPossibility.defenderDamageReduce > 0) { stackWithBonuses->removeUnitBonus(Bonus::UntilAttack); stackWithBonuses->removeUnitBonus(Bonus::UntilOwnAttack); } if(attackPossibility.attackerDamageReduce > 0) stackWithBonuses->removeUnitBonus(Bonus::UntilBeingAttacked); for(auto affected : attackPossibility.affectedUnits) { stackWithBonuses = state->getForUpdate(affected->unitId()); *stackWithBonuses = *affected; if(attackPossibility.defenderDamageReduce > 0) stackWithBonuses->removeUnitBonus(Bonus::UntilBeingAttacked); if(attackPossibility.attackerDamageReduce > 0 && attackPossibility.attack.defender->unitId() == affected->unitId()) stackWithBonuses->removeUnitBonus(Bonus::UntilAttack); } } auto bav = potentialTargets.bestActionValue(); //best action is from effective owner`s point if view, we need to convert to our point if view if(state->battleGetOwner(unit) != playerID) bav = -bav; values[unit->unitId()] += bav; } firstRound = false; if(stop) break; } if(enemyHadTurnOut) *enemyHadTurnOut = enemyHadTurn; return ourTurnSpan >= minTurnSpan; }; ValueMap valueOfStack; ValueMap healthOfStack; TStacks all = cb->getBattle(battleID)->battleGetAllStacks(false); size_t ourRemainingTurns = 0; for(auto unit : all) { healthOfStack[unit->unitId()] = unit->getAvailableHealth(); valueOfStack[unit->unitId()] = 0; if(cb->getBattle(battleID)->battleGetOwner(unit) == playerID && unit->canMove() && !unit->moved()) ourRemainingTurns++; } LOGFL("I have %d turns left in this round", ourRemainingTurns); const bool castNow = ourRemainingTurns <= 1; if(castNow) print("I should try to cast a spell now"); else print("I could wait better moment to cast a spell"); auto amount = all.size(); std::vector turnOrder; cb->getBattle(battleID)->battleGetTurnOrder(turnOrder, amount, 2); //no more than 1 turn after current, each unit at least once { bool enemyHadTurn = false; auto state = std::make_shared(env.get(), cb->getBattle(battleID)); evaluateQueue(valueOfStack, turnOrder, state, 0, &enemyHadTurn); if(!enemyHadTurn) { auto battleIsFinishedOpt = state->battleIsFinished(); if(battleIsFinishedOpt) { print("No need to cast a spell. Battle will finish soon."); return false; } } } CStopWatch timer; #if BATTLE_TRACE_LEVEL >= 1 tbb::blocked_range r(0, possibleCasts.size()); #else tbb::parallel_for(tbb::blocked_range(0, possibleCasts.size()), [&](const tbb::blocked_range & r) { #endif for(auto i = r.begin(); i != r.end(); i++) { auto & ps = possibleCasts[i]; #if BATTLE_TRACE_LEVEL >= 1 if(ps.dest.empty()) logAi->trace("Evaluating %s", ps.spell->getNameTranslated()); else { auto psFirst = ps.dest.front(); auto strWhere = psFirst.unitValue ? psFirst.unitValue->getDescription() : std::to_string(psFirst.hexValue.hex); logAi->trace("Evaluating %s at %s", ps.spell->getNameTranslated(), strWhere); } #endif auto state = std::make_shared(env.get(), cb->getBattle(battleID)); spells::BattleCast cast(state.get(), hero, spells::Mode::HERO, ps.spell); cast.castEval(state->getServerCallback(), ps.dest); auto allUnits = state->battleGetUnitsIf([](const battle::Unit * u) -> bool { return true; }); auto needFullEval = vstd::contains_if(allUnits, [&](const battle::Unit * u) -> bool { auto original = cb->getBattle(battleID)->battleGetUnitByID(u->unitId()); return !original || u->getMovementRange() != original->getMovementRange(); }); DamageCache safeCopy = damageCache; DamageCache innerCache(&safeCopy); innerCache.buildDamageCache(state, side); if(cachedAttack.ap && cachedAttack.waited) { state->makeWait(activeStack); } if(needFullEval || !cachedAttack.ap) { #if BATTLE_TRACE_LEVEL >= 1 logAi->trace("Full evaluation is started due to stack speed affected."); #endif PotentialTargets innerTargets(activeStack, innerCache, state); BattleExchangeEvaluator innerEvaluator(state, env, strengthRatio, simulationTurnsCount); innerEvaluator.updateReachabilityMap(state); auto moveTarget = innerEvaluator.findMoveTowardsUnreachable(activeStack, innerTargets, innerCache, state); if(!innerTargets.possibleAttacks.empty()) { auto newStackAction = innerEvaluator.findBestTarget(activeStack, innerTargets, innerCache, state); ps.value = std::max(moveTarget.score, newStackAction.score); } else { ps.value = moveTarget.score; } } else { auto updatedAttacker = state->getForUpdate(cachedAttack.ap->attack.attacker->unitId()); auto updatedDefender = state->getForUpdate(cachedAttack.ap->attack.defender->unitId()); auto updatedBai = BattleAttackInfo( updatedAttacker.get(), updatedDefender.get(), cachedAttack.ap->attack.chargeDistance, cachedAttack.ap->attack.shooting); auto updatedAttack = AttackPossibility::evaluate(updatedBai, cachedAttack.ap->from, innerCache, state); ps.value = scoreEvaluator.evaluateExchange(updatedAttack, cachedAttack.turn, *targets, innerCache, state); } for(const auto & unit : allUnits) { if(!unit->isValidTarget(true)) continue; auto newHealth = unit->getAvailableHealth(); auto oldHealth = vstd::find_or(healthOfStack, unit->unitId(), 0); // old health value may not exist for newly summoned units if(oldHealth != newHealth) { auto damage = std::abs(oldHealth - newHealth); auto originalDefender = cb->getBattle(battleID)->battleGetUnitByID(unit->unitId()); auto dpsReduce = AttackPossibility::calculateDamageReduce( nullptr, originalDefender && originalDefender->alive() ? originalDefender : unit, damage, innerCache, state); auto ourUnit = unit->unitSide() == side ? 1 : -1; auto goodEffect = newHealth > oldHealth ? 1 : -1; if(ourUnit * goodEffect == 1) { auto isMagical = state->getForUpdate(unit->unitId())->summoned || unit->isClone() || unit->isGhost(); if(ourUnit && goodEffect && isMagical) continue; ps.value += dpsReduce * scoreEvaluator.getPositiveEffectMultiplier(); } else // discourage AI making collateral damage with spells ps.value -= 4 * dpsReduce * scoreEvaluator.getNegativeEffectMultiplier(); #if BATTLE_TRACE_LEVEL >= 1 logAi->trace( "Spell affects %s (%d), dps: %2f", unit->creatureId().toCreature()->getNameSingularTranslated(), unit->getCount(), dpsReduce); #endif } } #if BATTLE_TRACE_LEVEL >= 1 logAi->trace("Total score: %2f", ps.value); #endif } #if BATTLE_TRACE_LEVEL == 0 }); #endif LOGFL("Evaluation took %d ms", timer.getDiff()); auto castToPerform = *vstd::maxElementByFun(possibleCasts, [](const PossibleSpellcast & ps) -> float { return ps.value; }); if(castToPerform.value > cachedAttack.score && !vstd::isAlmostEqual(castToPerform.value, cachedAttack.score)) { LOGFL("Best spell is %s (value %d). Will cast.", castToPerform.spell->getNameTranslated() % castToPerform.value); BattleAction spellcast; spellcast.actionType = EActionType::HERO_SPELL; spellcast.spell = castToPerform.spell->id; spellcast.setTarget(castToPerform.dest); spellcast.side = side; spellcast.stackNumber = -1; cb->battleMakeSpellAction(battleID, spellcast); activeActionMade = true; return true; } LOGFL("Best spell is %s. But it is actually useless (value %d).", castToPerform.spell->getNameTranslated() % castToPerform.value); return false; } //Below method works only for offensive spells void BattleEvaluator::evaluateCreatureSpellcast(const CStack * stack, PossibleSpellcast & ps) { using ValueMap = PossibleSpellcast::ValueMap; RNGStub rngStub; HypotheticBattle state(env.get(), cb->getBattle(battleID)); TStacks all = cb->getBattle(battleID)->battleGetAllStacks(false); ValueMap healthOfStack; ValueMap newHealthOfStack; for(auto unit : all) { healthOfStack[unit->unitId()] = unit->getAvailableHealth(); } spells::BattleCast cast(&state, stack, spells::Mode::CREATURE_ACTIVE, ps.spell); cast.castEval(state.getServerCallback(), ps.dest); for(auto unit : all) { auto unitId = unit->unitId(); auto localUnit = state.battleGetUnitByID(unitId); newHealthOfStack[unitId] = localUnit->getAvailableHealth(); } int64_t totalGain = 0; for(auto unit : all) { auto unitId = unit->unitId(); auto localUnit = state.battleGetUnitByID(unitId); auto healthDiff = newHealthOfStack[unitId] - healthOfStack[unitId]; if(localUnit->unitOwner() != cb->getBattle(battleID)->getPlayerID()) healthDiff = -healthDiff; if(healthDiff < 0) { ps.value = -1; return; //do not damage own units at all } totalGain += healthDiff; } ps.value = totalGain; } void BattleEvaluator::print(const std::string & text) const { logAi->trace("%s Battle AI[%p]: %s", playerID.toString(), this, text); }