/*
* DangerHitMapAnalyzer.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 "ObjectClusterizer.h"
#include "../Goals/ExecuteHeroChain.h"
#include "../AIGateway.h"
#include "../Engine/Nullkiller.h"
namespace NKAI
{
void ObjectCluster::addObject(const CGObjectInstance * obj, const AIPath & path, float priority)
{
ClusterObjects::accessor info;
objects.insert(info, ClusterObjects::value_type(obj->id, ClusterObjectInfo()));
if(info->second.priority < priority)
{
info->second.priority = priority;
info->second.movementCost = path.movementCost() - path.firstNode().cost;
info->second.danger = path.targetObjectDanger;
info->second.turn = path.turn();
}
}
const CGObjectInstance * ObjectCluster::calculateCenter(const CPlayerSpecificInfoCallback * cb) const
{
auto tile = int3(0);
float priority = 0;
for(auto & pair : objects)
{
auto newPoint = cb->getObj(pair.first)->visitablePos();
float newPriority = std::pow(pair.second.priority, 4); // lets make high priority targets more weghtful
int3 direction = newPoint - tile;
float priorityRatio = newPriority / (priority + newPriority);
tile += direction * priorityRatio;
priority += newPriority;
}
auto closestPair = *vstd::minElementByFun(objects, [&](const std::pair<ObjectInstanceID, ClusterObjectInfo> & pair) -> int
{
return cb->getObj(pair.first)->visitablePos().dist2dSQ(tile);
});
return cb->getObj(closestPair.first);
}
std::vector<const CGObjectInstance *> ObjectCluster::getObjects(const CPlayerSpecificInfoCallback * cb) const
{
std::vector<const CGObjectInstance *> result;
for(auto & pair : objects)
{
result.push_back(cb->getObj(pair.first));
}
return result;
}
std::vector<const CGObjectInstance *> ObjectClusterizer::getNearbyObjects() const
{
return nearObjects.getObjects(ai->cb.get());
}
std::vector<const CGObjectInstance *> ObjectClusterizer::getFarObjects() const
{
return farObjects.getObjects(ai->cb.get());
}
std::vector<std::shared_ptr<ObjectCluster>> ObjectClusterizer::getLockedClusters() const
{
std::vector<std::shared_ptr<ObjectCluster>> result;
for(auto & pair : blockedObjects)
{
result.push_back(pair.second);
}
return result;
}
std::optional<const CGObjectInstance *> ObjectClusterizer::getBlocker(const AIPathNodeInfo & node) const
{
std::vector<const CGObjectInstance *> blockers = {};
if(node.layer == EPathfindingLayer::LAND || node.layer == EPathfindingLayer::SAIL)
{
auto guardPos = ai->cb->getGuardingCreaturePosition(node.coord);
blockers = ai->cb->getVisitableObjs(node.coord);
if(guardPos.valid())
{
auto guard = ai->cb->getTopObj(ai->cb->getGuardingCreaturePosition(node.coord));
if(guard)
{
blockers.insert(blockers.begin(), guard);
}
}
}
if(node.specialAction && node.actionIsBlocked)
{
auto blockerObject = node.specialAction->targetObject();
if(blockerObject)
{
blockers.insert(blockers.begin(), blockerObject);
}
}
if(blockers.empty())
return std::optional< const CGObjectInstance *>();
auto blocker = blockers.front();
if(isObjectPassable(ai, blocker))
return std::optional< const CGObjectInstance *>();
if(blocker->ID == Obj::GARRISON
|| blocker->ID == Obj::GARRISON2)
{
if(dynamic_cast<const CArmedInstance *>(blocker)->getArmyStrength() == 0)
return std::optional< const CGObjectInstance *>();
else
return blocker;
}
if(blocker->ID == Obj::MONSTER
|| blocker->ID == Obj::BORDERGUARD
|| blocker->ID == Obj::BORDER_GATE
|| blocker->ID == Obj::SHIPYARD
|| (blocker->ID == Obj::QUEST_GUARD && node.actionIsBlocked))
{
return blocker;
}
return std::optional< const CGObjectInstance *>();
}
const CGObjectInstance * ObjectClusterizer::getBlocker(const AIPath & path) const
{
for(auto node = path.nodes.rbegin(); node != path.nodes.rend(); node++)
{
auto blocker = getBlocker(*node);
if(blocker)
return *blocker;
}
return nullptr;
}
void ObjectClusterizer::invalidate(ObjectInstanceID id)
{
nearObjects.objects.erase(id);
farObjects.objects.erase(id);
invalidated.push_back(id);
for(auto & c : blockedObjects)
{
c.second->objects.erase(id);
}
}
void ObjectClusterizer::validateObjects()
{
std::vector<ObjectInstanceID> toRemove;
auto scanRemovedObjects = [this, &toRemove](const ObjectCluster & cluster)
{
for(auto & pair : cluster.objects)
{
if(!ai->cb->getObj(pair.first, false))
toRemove.push_back(pair.first);
}
};
scanRemovedObjects(nearObjects);
scanRemovedObjects(farObjects);
for(auto & pair : blockedObjects)
{
if(!ai->cb->getObj(pair.first, false) || pair.second->objects.empty())
toRemove.push_back(pair.first);
else
scanRemovedObjects(*pair.second);
}
vstd::removeDuplicates(toRemove);
for(auto id : toRemove)
{
onObjectRemoved(id);
}
}
void ObjectClusterizer::onObjectRemoved(ObjectInstanceID id)
{
invalidate(id);
vstd::erase_if_present(invalidated, id);
NKAI::ClusterMap::accessor cluster;
if(blockedObjects.find(cluster, id))
{
for(auto & unlocked : cluster->second->objects)
{
invalidated.push_back(unlocked.first);
}
blockedObjects.erase(cluster);
}
}
bool ObjectClusterizer::shouldVisitObject(const CGObjectInstance * obj) const
{
if(isObjectRemovable(obj))
{
return true;
}
const int3 pos = obj->visitablePos();
if((obj->ID != Obj::CREATURE_GENERATOR1 && vstd::contains(ai->memory->alreadyVisited, obj))
|| obj->wasVisited(ai->playerID))
{
return false;
}
auto playerRelations = ai->cb->getPlayerRelations(ai->playerID, obj->tempOwner);
if(playerRelations != PlayerRelations::ENEMIES && !isWeeklyRevisitable(ai, obj))
{
return false;
}
//it may be hero visiting this obj
//we don't try visiting object on which allied or owned hero stands
// -> it will just trigger exchange windows and AI will be confused that obj behind doesn't get visited
const CGObjectInstance * topObj = ai->cb->getTopObj(pos);
if(!topObj)
return false; // partly visible obj but its visitable pos is not visible.
if(topObj->ID == Obj::HERO && ai->cb->getPlayerRelations(ai->playerID, topObj->tempOwner) != PlayerRelations::ENEMIES)
return false;
else
return true; //all of the following is met
}
Obj ObjectClusterizer::IgnoredObjectTypes[] = {
Obj::BOAT,
Obj::EYE_OF_MAGI,
Obj::MONOLITH_ONE_WAY_ENTRANCE,
Obj::MONOLITH_ONE_WAY_EXIT,
Obj::MONOLITH_TWO_WAY,
Obj::SUBTERRANEAN_GATE,
Obj::WHIRLPOOL,
Obj::BUOY,
Obj::SIGN,
Obj::GARRISON,
Obj::MONSTER,
Obj::GARRISON2,
Obj::BORDERGUARD,
Obj::QUEST_GUARD,
Obj::BORDER_GATE,
Obj::REDWOOD_OBSERVATORY,
Obj::CARTOGRAPHER,
Obj::PILLAR_OF_FIRE
};
void ObjectClusterizer::clusterize()
{
if(isUpToDate)
{
validateObjects();
}
if(isUpToDate && invalidated.empty())
return;
auto start = std::chrono::high_resolution_clock::now();
logAi->debug("Begin object clusterization");
std::vector<const CGObjectInstance *> objs;
if(isUpToDate)
{
for(auto id : invalidated)
{
auto obj = cb->getObj(id, false);
if(obj)
{
objs.push_back(obj);
}
}
invalidated.clear();
}
else
{
nearObjects.reset();
farObjects.reset();
blockedObjects.clear();
invalidated.clear();
objs = std::vector<const CGObjectInstance *>(
ai->memory->visitableObjs.begin(),
ai->memory->visitableObjs.end());
}
#if NKAI_TRACE_LEVEL == 0
tbb::parallel_for(tbb::blocked_range<size_t>(0, objs.size()), [&](const tbb::blocked_range<size_t> & r) {
#else
tbb::blocked_range<size_t> r(0, objs.size());
#endif
auto priorityEvaluator = ai->priorityEvaluators->acquire();
auto heroes = ai->cb->getHeroesInfo();
std::vector<AIPath> pathCache;
for(int i = r.begin(); i != r.end(); i++)
{
clusterizeObject(objs[i], priorityEvaluator.get(), pathCache, heroes);
}
#if NKAI_TRACE_LEVEL == 0
});
#endif
logAi->trace("Near objects count: %i", nearObjects.objects.size());
logAi->trace("Far objects count: %i", farObjects.objects.size());
for(auto pair : blockedObjects)
{
auto blocker = cb->getObj(pair.first);
logAi->trace("Cluster %s %s count: %i", blocker->getObjectName(), blocker->visitablePos().toString(), pair.second->objects.size());
#if NKAI_TRACE_LEVEL >= 1
for(auto obj : pair.second->getObjects(ai->cb.get()))
{
logAi->trace("Object %s %s", obj->getObjectName(), obj->visitablePos().toString());
}
#endif
}
isUpToDate = true;
logAi->trace("Clusterization complete in %ld", timeElapsed(start));
}
void ObjectClusterizer::clusterizeObject(
const CGObjectInstance * obj,
PriorityEvaluator * priorityEvaluator,
std::vector<AIPath> & pathCache,
std::vector<const CGHeroInstance *> & heroes)
{
if(!shouldVisitObject(obj))
{
#if NKAI_TRACE_LEVEL >= 2
logAi->trace("Skip object %s%s.", obj->getObjectName(), obj->visitablePos().toString());
#endif
return;
}
#if NKAI_TRACE_LEVEL >= 2
logAi->trace("Check object %s%s.", obj->getObjectName(), obj->visitablePos().toString());
#endif
if(ai->isObjectGraphAllowed())
{
ai->pathfinder->calculateQuickPathsWithBlocker(pathCache, heroes, obj->visitablePos());
}
else
ai->pathfinder->calculatePathInfo(pathCache, obj->visitablePos(), false);
if(pathCache.empty())
{
#if NKAI_TRACE_LEVEL >= 2
logAi->trace("No paths found.");
#endif
return;
}
std::sort(pathCache.begin(), pathCache.end(), [](const AIPath & p1, const AIPath & p2) -> bool
{
return p1.movementCost() < p2.movementCost();
});
if(vstd::contains(IgnoredObjectTypes, obj->ID))
{
farObjects.addObject(obj, pathCache.front(), 0);
#if NKAI_TRACE_LEVEL >= 2
logAi->trace("Object ignored. Moved to far objects with path %s", pathCache.front().toString());
#endif
return;
}
std::set<const CGHeroInstance *> heroesProcessed;
for(auto & path : pathCache)
{
#if NKAI_TRACE_LEVEL >= 2
logAi->trace("Checking path %s", path.toString());
#endif
if(ai->heroManager->getHeroRole(path.targetHero) == HeroRole::SCOUT)
{
if(path.movementCost() > 2.0f)
{
#if NKAI_TRACE_LEVEL >= 2
logAi->trace("Path is too far %f", path.movementCost());
#endif
continue;
}
}
else if(path.movementCost() > 4.0f && obj->ID != Obj::TOWN)
{
auto strategicalValue = valueEvaluator.getStrategicalValue(obj);
if(strategicalValue < 0.3f)
{
#if NKAI_TRACE_LEVEL >= 2
logAi->trace("Object value is too low %f", strategicalValue);
#endif
continue;
}
}
if(!shouldVisit(ai, path.targetHero, obj))
{
#if NKAI_TRACE_LEVEL >= 2
logAi->trace("Hero %s does not need to visit %s", path.targetHero->getObjectName(), obj->getObjectName());
#endif
continue;
}
if(path.nodes.size() > 1)
{
auto blocker = getBlocker(path);
if(blocker)
{
if(vstd::contains(heroesProcessed, path.targetHero))
{
#if NKAI_TRACE_LEVEL >= 2
logAi->trace("Hero %s is already processed.", path.targetHero->getObjectName());
#endif
continue;
}
heroesProcessed.insert(path.targetHero);
float priority = priorityEvaluator->evaluate(Goals::sptr(Goals::ExecuteHeroChain(path, obj)));
if(ai->settings->isUseFuzzy() && priority < MIN_PRIORITY)
continue;
else if (priority <= 0)
continue;
ClusterMap::accessor cluster;
blockedObjects.insert(
cluster,
ClusterMap::value_type(blocker->id, std::make_shared<ObjectCluster>(blocker)));
cluster->second->addObject(obj, path, priority);
#if NKAI_TRACE_LEVEL >= 2
logAi->trace("Path added to cluster %s%s", blocker->getObjectName(), blocker->visitablePos().toString());
#endif
continue;
}
}
heroesProcessed.insert(path.targetHero);
float priority = priorityEvaluator->evaluate(Goals::sptr(Goals::ExecuteHeroChain(path, obj)));
if (ai->settings->isUseFuzzy() && priority < MIN_PRIORITY)
continue;
else if (priority <= 0)
continue;
bool interestingObject = path.turn() <= 2 || priority > 0.5f;
if(interestingObject)
{
nearObjects.addObject(obj, path, priority);
}
else
{
farObjects.addObject(obj, path, priority);
}
#if NKAI_TRACE_LEVEL >= 2
logAi->trace("Path %s added to %s objects. Turn: %d, priority: %f",
path.toString(),
interestingObject ? "near" : "far",
path.turn(),
priority);
#endif
}
}
}