/*
* AIUtility.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 "AIUtility.h"
#include "VCAI.h"
#include "FuzzyHelper.h"
#include "../../lib/UnlockGuard.h"
#include "../../lib/CConfigHandler.h"
#include "../../lib/CHeroHandler.h"
#include "../../lib/mapObjects/CBank.h"
#include "../../lib/mapObjects/CGTownInstance.h"
#include "../../lib/mapObjects/CQuest.h"
#include "../../lib/mapping/CMapDefines.h"
extern boost::thread_specific_ptr<CCallback> cb;
extern boost::thread_specific_ptr<VCAI> ai;
extern FuzzyHelper * fh;
//extern static const int3 dirs[8];
const CGObjectInstance * ObjectIdRef::operator->() const
{
return cb->getObj(id, false);
}
ObjectIdRef::operator const CGObjectInstance *() const
{
return cb->getObj(id, false);
}
ObjectIdRef::operator bool() const
{
return cb->getObj(id, false);
}
ObjectIdRef::ObjectIdRef(ObjectInstanceID _id)
: id(_id)
{
}
ObjectIdRef::ObjectIdRef(const CGObjectInstance * obj)
: id(obj->id)
{
}
bool ObjectIdRef::operator<(const ObjectIdRef & rhs) const
{
return id < rhs.id;
}
HeroPtr::HeroPtr(const CGHeroInstance * H)
{
if(!H)
{
//init from nullptr should equal to default init
*this = HeroPtr();
return;
}
h = H;
name = h->name;
hid = H->id;
// infosCount[ai->playerID][hid]++;
}
HeroPtr::HeroPtr()
{
h = nullptr;
hid = ObjectInstanceID();
}
HeroPtr::~HeroPtr()
{
// if(hid >= 0)
// infosCount[ai->playerID][hid]--;
}
bool HeroPtr::operator<(const HeroPtr & rhs) const
{
return hid < rhs.hid;
}
const CGHeroInstance * HeroPtr::get(bool doWeExpectNull) const
{
//TODO? check if these all assertions every time we get info about hero affect efficiency
//
//behave terribly when attempting unauthorized access to hero that is not ours (or was lost)
assert(doWeExpectNull || h);
if(h)
{
auto obj = cb->getObj(hid);
const bool owned = obj && obj->tempOwner == ai->playerID;
if(doWeExpectNull && !owned)
{
return nullptr;
}
else
{
assert(obj);
assert(owned);
}
}
return h;
}
const CGHeroInstance * HeroPtr::operator->() const
{
return get();
}
bool HeroPtr::validAndSet() const
{
return get(true);
}
const CGHeroInstance * HeroPtr::operator*() const
{
return get();
}
bool HeroPtr::operator==(const HeroPtr & rhs) const
{
return h == rhs.get(true);
}
void foreach_tile_pos(std::function<void(const int3 & pos)> foo)
{
// some micro-optimizations since this function gets called a LOT
// callback pointer is thread-specific and slow to retrieve -> read map size only once
int3 mapSize = cb->getMapSize();
for(int i = 0; i < mapSize.x; i++)
{
for(int j = 0; j < mapSize.y; j++)
{
for(int k = 0; k < mapSize.z; k++)
foo(int3(i, j, k));
}
}
}
void foreach_tile_pos(CCallback * cbp, std::function<void(CCallback * cbp, const int3 & pos)> foo)
{
int3 mapSize = cbp->getMapSize();
for(int i = 0; i < mapSize.x; i++)
{
for(int j = 0; j < mapSize.y; j++)
{
for(int k = 0; k < mapSize.z; k++)
foo(cbp, int3(i, j, k));
}
}
}
void foreach_neighbour(const int3 & pos, std::function<void(const int3 & pos)> foo)
{
CCallback * cbp = cb.get(); // avoid costly retrieval of thread-specific pointer
for(const int3 & dir : int3::getDirs())
{
const int3 n = pos + dir;
if(cbp->isInTheMap(n))
foo(pos + dir);
}
}
void foreach_neighbour(CCallback * cbp, const int3 & pos, std::function<void(CCallback * cbp, const int3 & pos)> foo)
{
for(const int3 & dir : int3::getDirs())
{
const int3 n = pos + dir;
if(cbp->isInTheMap(n))
foo(cbp, pos + dir);
}
}
bool CDistanceSorter::operator()(const CGObjectInstance * lhs, const CGObjectInstance * rhs) const
{
const CGPathNode * ln = ai->myCb->getPathsInfo(hero)->getPathInfo(lhs->visitablePos());
const CGPathNode * rn = ai->myCb->getPathsInfo(hero)->getPathInfo(rhs->visitablePos());
if(ln->turns != rn->turns)
return ln->turns < rn->turns;
return (ln->moveRemains > rn->moveRemains);
}
bool compareMovement(HeroPtr lhs, HeroPtr rhs)
{
return lhs->movement > rhs->movement;
}
ui64 evaluateDanger(crint3 tile)
{
const TerrainTile * t = cb->getTile(tile, false);
if(!t) //we can know about guard but can't check its tile (the edge of fow)
return 190000000; //MUCH
ui64 objectDanger = 0;
ui64 guardDanger = 0;
auto visObjs = cb->getVisitableObjs(tile);
if(visObjs.size())
objectDanger = evaluateDanger(visObjs.back());
int3 guardPos = cb->getGuardingCreaturePosition(tile);
if(guardPos.x >= 0 && guardPos != tile)
guardDanger = evaluateDanger(guardPos);
//TODO mozna odwiedzic blockvis nie ruszajac straznika
return std::max(objectDanger, guardDanger);
}
ui64 evaluateDanger(crint3 tile, const CGHeroInstance * visitor)
{
const TerrainTile * t = cb->getTile(tile, false);
if(!t) //we can know about guard but can't check its tile (the edge of fow)
return 190000000; //MUCH
ui64 objectDanger = 0;
ui64 guardDanger = 0;
auto visitableObjects = cb->getVisitableObjs(tile);
// in some scenarios hero happens to be "under" the object (eg town). Then we consider ONLY the hero.
if(vstd::contains_if(visitableObjects, objWithID<Obj::HERO>))
{
vstd::erase_if(visitableObjects, [](const CGObjectInstance * obj)
{
return !objWithID<Obj::HERO>(obj);
});
}
if(const CGObjectInstance * dangerousObject = vstd::backOrNull(visitableObjects))
{
objectDanger = evaluateDanger(dangerousObject); //unguarded objects can also be dangerous or unhandled
if(objectDanger)
{
//TODO: don't downcast objects AI shouldn't know about!
auto armedObj = dynamic_cast<const CArmedInstance *>(dangerousObject);
if(armedObj)
{
float tacticalAdvantage = fh->tacticalAdvantageEngine.getTacticalAdvantage(visitor, armedObj);
objectDanger *= tacticalAdvantage; //this line tends to go infinite for allied towns (?)
}
}
if(dangerousObject->ID == Obj::SUBTERRANEAN_GATE)
{
//check guard on the other side of the gate
auto it = ai->knownSubterraneanGates.find(dangerousObject);
if(it != ai->knownSubterraneanGates.end())
{
auto guards = cb->getGuardingCreatures(it->second->visitablePos());
for(auto cre : guards)
{
vstd::amax(guardDanger, evaluateDanger(cre) * fh->tacticalAdvantageEngine.getTacticalAdvantage(visitor, dynamic_cast<const CArmedInstance *>(cre)));
}
}
}
}
auto guards = cb->getGuardingCreatures(tile);
for(auto cre : guards)
{
vstd::amax(guardDanger, evaluateDanger(cre) * fh->tacticalAdvantageEngine.getTacticalAdvantage(visitor, dynamic_cast<const CArmedInstance *>(cre))); //we are interested in strongest monster around
}
//TODO mozna odwiedzic blockvis nie ruszajac straznika
return std::max(objectDanger, guardDanger);
}
ui64 evaluateDanger(const CGObjectInstance * obj)
{
if(obj->tempOwner < PlayerColor::PLAYER_LIMIT && cb->getPlayerRelations(obj->tempOwner, ai->playerID) != PlayerRelations::ENEMIES) //owned or allied objects don't pose any threat
return 0;
switch(obj->ID)
{
case Obj::HERO:
{
InfoAboutHero iah;
cb->getHeroInfo(obj, iah);
return iah.army.getStrength();
}
case Obj::TOWN:
case Obj::GARRISON:
case Obj::GARRISON2:
{
InfoAboutTown iat;
cb->getTownInfo(obj, iat);
return iat.army.getStrength();
}
case Obj::MONSTER:
{
//TODO!!!!!!!!
const CGCreature * cre = dynamic_cast<const CGCreature *>(obj);
return cre->getArmyStrength();
}
case Obj::CREATURE_GENERATOR1:
case Obj::CREATURE_GENERATOR4:
{
const CGDwelling * d = dynamic_cast<const CGDwelling *>(obj);
return d->getArmyStrength();
}
case Obj::MINE:
case Obj::ABANDONED_MINE:
{
const CArmedInstance * a = dynamic_cast<const CArmedInstance *>(obj);
return a->getArmyStrength();
}
case Obj::CRYPT: //crypt
case Obj::CREATURE_BANK: //crebank
case Obj::DRAGON_UTOPIA:
case Obj::SHIPWRECK: //shipwreck
case Obj::DERELICT_SHIP: //derelict ship
// case Obj::PYRAMID:
return fh->estimateBankDanger(dynamic_cast<const CBank *>(obj));
case Obj::PYRAMID:
{
if(obj->subID == 0)
return fh->estimateBankDanger(dynamic_cast<const CBank *>(obj));
else
return 0;
}
default:
return 0;
}
}
bool compareDanger(const CGObjectInstance * lhs, const CGObjectInstance * rhs)
{
return evaluateDanger(lhs) < evaluateDanger(rhs);
}
bool isSafeToVisit(HeroPtr h, crint3 tile)
{
return isSafeToVisit(h, evaluateDanger(tile));
}
bool isSafeToVisit(HeroPtr h, uint64_t dangerStrength)
{
const ui64 heroStrength = h->getTotalStrength();
if(dangerStrength)
{
if(heroStrength / SAFE_ATTACK_CONSTANT > dangerStrength)
{
return true;
}
else
{
return false;
}
}
return true; //there's no danger
}
bool isObjectRemovable(const CGObjectInstance * obj)
{
//FIXME: move logic to object property!
switch (obj->ID)
{
case Obj::MONSTER:
case Obj::RESOURCE:
case Obj::CAMPFIRE:
case Obj::TREASURE_CHEST:
case Obj::ARTIFACT:
case Obj::BORDERGUARD:
return true;
break;
default:
return false;
break;
}
}
bool canBeEmbarkmentPoint(const TerrainTile * t, bool fromWater)
{
// TODO: Such information should be provided by pathfinder
// Tile must be free or with unoccupied boat
if(!t->blocked)
{
return true;
}
else if(!fromWater) // do not try to board when in water sector
{
if(t->visitableObjects.size() == 1 && t->topVisitableId() == Obj::BOAT)
return true;
}
return false;
}
int3 whereToExplore(HeroPtr h)
{
TimeCheck tc("where to explore");
int radius = h->getSightRadius();
int3 hpos = h->visitablePos();
//look for nearby objs -> visit them if they're close enouh
const int DIST_LIMIT = 3;
const int MP_LIMIT = DIST_LIMIT * 150; // aproximate cost of diagonal movement
std::vector<const CGObjectInstance *> nearbyVisitableObjs;
for(int x = hpos.x - DIST_LIMIT; x <= hpos.x + DIST_LIMIT; ++x) //get only local objects instead of all possible objects on the map
{
for(int y = hpos.y - DIST_LIMIT; y <= hpos.y + DIST_LIMIT; ++y)
{
for(auto obj : cb->getVisitableObjs(int3(x, y, hpos.z), false))
{
if(ai->isGoodForVisit(obj, h, MP_LIMIT))
{
nearbyVisitableObjs.push_back(obj);
}
}
}
}
vstd::removeDuplicates(nearbyVisitableObjs); //one object may occupy multiple tiles
boost::sort(nearbyVisitableObjs, CDistanceSorter(h.get()));
if(nearbyVisitableObjs.size())
return nearbyVisitableObjs.back()->visitablePos();
try //check if nearby tiles allow us to reveal anything - this is quick
{
return ai->explorationBestNeighbour(hpos, radius, h);
}
catch(cannotFulfillGoalException & e)
{
//perform exhaustive search
return ai->explorationNewPoint(h);
}
}
bool isBlockedBorderGate(int3 tileToHit) //TODO: is that function needed? should be handled by pathfinder
{
if(cb->getTile(tileToHit)->topVisitableId() != Obj::BORDER_GATE)
return false;
auto gate = dynamic_cast<const CGKeys *>(cb->getTile(tileToHit)->topVisitableObj());
return !gate->passableFor(ai->playerID);
}
bool isBlockVisitObj(const int3 & pos)
{
if(auto obj = cb->getTopObj(pos))
{
if(obj->blockVisit) //we can't stand on that object
return true;
}
return false;
}
bool hasReachableNeighbor(const int3 &pos, HeroPtr hero, CCallback * cbp)
{
for(crint3 dir : int3::getDirs())
{
int3 tile = pos + dir;
if(cbp->isInTheMap(tile) && cbp->getPathsInfo(hero.get())->getPathInfo(tile)->reachable())
{
return true;
}
}
return false;
}
int howManyTilesWillBeDiscovered(const int3 & pos, int radious, CCallback * cbp, HeroPtr hero)
{
int ret = 0;
for(int x = pos.x - radious; x <= pos.x + radious; x++)
{
for(int y = pos.y - radious; y <= pos.y + radious; y++)
{
int3 npos = int3(x, y, pos.z);
if(cbp->isInTheMap(npos) && pos.dist2d(npos) - 0.5 < radious && !cbp->isVisible(npos))
{
if(hasReachableNeighbor(npos, hero, cbp))
ret++;
}
}
}
return ret;
}
void getVisibleNeighbours(const std::vector<int3> & tiles, std::vector<int3> & out)
{
for(const int3 & tile : tiles)
{
foreach_neighbour(tile, [&](int3 neighbour)
{
if(cb->isVisible(neighbour))
out.push_back(neighbour);
});
}
}
creInfo infoFromDC(const dwellingContent & dc)
{
creInfo ci;
ci.count = dc.first;
ci.creID = dc.second.size() ? dc.second.back() : CreatureID(-1); //should never be accessed
if (ci.creID != -1)
{
ci.cre = VLC->creh->creatures[ci.creID];
ci.level = ci.cre->level; //this is cretaure tier, while tryRealize expects dwelling level. Ignore.
}
else
{
ci.cre = nullptr;
ci.level = 0;
}
return ci;
}
ui64 howManyReinforcementsCanBuy(HeroPtr h, const CGDwelling * t)
{
ui64 aivalue = 0;
int freeHeroSlots = GameConstants::ARMY_SIZE - h->stacksCount();
for(auto const dc : t->creatures)
{
creInfo ci = infoFromDC(dc);
if(ci.count && ci.creID != -1) //valid creature at this level
{
//can be merged with another stack?
SlotID dst = h->getSlotFor(ci.creID);
if(!h->hasStackAtSlot(dst)) //need another new slot for this stack
{
if(!freeHeroSlots) //no more place for stacks
continue;
else
freeHeroSlots--; //new slot will be occupied
}
//we found matching occupied or free slot
aivalue += ci.count * ci.cre->AIValue;
}
}
return aivalue;
}
ui64 howManyReinforcementsCanGet(HeroPtr h, const CGTownInstance * t)
{
ui64 ret = 0;
int freeHeroSlots = GameConstants::ARMY_SIZE - h->stacksCount();
std::vector<const CStackInstance *> toMove;
for(auto const slot : t->Slots())
{
//can be merged woth another stack?
SlotID dst = h->getSlotFor(slot.second->getCreatureID());
if(h->hasStackAtSlot(dst))
ret += t->getPower(slot.first);
else
toMove.push_back(slot.second);
}
boost::sort(toMove, [](const CStackInstance * lhs, const CStackInstance * rhs)
{
return lhs->getPower() < rhs->getPower();
});
for(auto & stack : boost::adaptors::reverse(toMove))
{
if(freeHeroSlots)
{
ret += stack->getPower();
freeHeroSlots--;
}
else
break;
}
return ret;
}
bool compareHeroStrength(HeroPtr h1, HeroPtr h2)
{
return h1->getTotalStrength() < h2->getTotalStrength();
}
bool compareArmyStrength(const CArmedInstance * a1, const CArmedInstance * a2)
{
return a1->getArmyStrength() < a2->getArmyStrength();
}
bool compareArtifacts(const CArtifactInstance * a1, const CArtifactInstance * a2)
{
auto art1 = a1->artType;
auto art2 = a2->artType;
if(art1->price == art2->price)
return art1->valOfBonuses(Bonus::PRIMARY_SKILL) > art2->valOfBonuses(Bonus::PRIMARY_SKILL);
else if(art1->price > art2->price)
return true;
else
return false;
}
uint32_t distanceToTile(const CGHeroInstance * hero, int3 pos)
{
auto pathInfo = cb->getPathsInfo(hero)->getPathInfo(pos);
uint32_t totalMovementPoints = pathInfo->turns * hero->maxMovePoints(true) + hero->movement;
if(totalMovementPoints < pathInfo->moveRemains) // should not be but who knows
return 0;
return totalMovementPoints - pathInfo->moveRemains;
}