bool AIHints::HintSaysDontAttack(GameObserver* observer,MTGCardInstance * card)
{
TargetChooserFactory tfc(observer);
TargetChooser * hintTc = NULL;
for(unsigned int i = 0; i < hints.size();i++)
{
if (hints[i]->mCombatAttackTip.size())
{
hintTc = tfc.createTargetChooser(hints[i]->mCombatAttackTip,card);
if(hintTc && hintTc->canTarget(card,true))
{
SAFE_DELETE(hintTc);
return true;
}
SAFE_DELETE(hintTc);
}
}
return false;
}
void ActionStack::Update(float dt)
{
//This is a hack to avoid updating the stack while tuto messages are being shown
//Ideally, the tuto messages should be moved to a layer above this one
//No need for Tuto when no human in game
if (getCurrentTutorial() && (observer->players[0]->isHuman() || observer->players[1]->isHuman() ) )
return;
askIfWishesToInterrupt = NULL;
//modal = 0;
TargetChooser * tc = observer->getCurrentTargetChooser();
int newState = observer->getCurrentGamePhase();
currentState = newState;
if (!tc)
checked = 0;
//Select Stack's display mode
if (mode == ACTIONSTACK_STANDARD && tc && !checked)
{
checked = 1;
for (size_t i = 0; i < mObjects.size(); i++)
{
Interruptible * current = (Interruptible *) mObjects[i];
if (tc->canTarget(current))
{
if (mCurr < (int) mObjects.size() && mObjects[mCurr])
mObjects[mCurr]->Leaving(JGE_BTN_UP);
current->display = 1;
mCurr = i;
mObjects[mCurr]->Entering();
mode = ACTIONSTACK_TARGET;
modal = 1;
}
else
{
current->display = 0;
}
}
if (mode != ACTIONSTACK_TARGET)
{
}
}
else if (mode == ACTIONSTACK_TARGET && !tc)
{
mode = ACTIONSTACK_STANDARD;
checked = 0;
}
if (mode == ACTIONSTACK_STANDARD)
{
modal = 0;
if (getLatest(NOT_RESOLVED) && !tc)
{
Interruptible * currentSpell = (Interruptible *)getLatest(NOT_RESOLVED);
MTGCardInstance * card = currentSpell->source;
if(card && card->has(Constants::SPLITSECOND))
{
resolve();
}
else
{
int currentPlayerId = 0;
int otherPlayerId = 1;
if (observer->currentlyActing() != observer->players[0])
{
currentPlayerId = 1;
otherPlayerId = 0;
}
if (interruptDecision[currentPlayerId] == NOT_DECIDED)
{
askIfWishesToInterrupt = observer->players[currentPlayerId];
observer->isInterrupting = observer->players[currentPlayerId];
modal = 1;
}
else if (interruptDecision[currentPlayerId] == INTERRUPT)
{
observer->isInterrupting = observer->players[currentPlayerId];
}
else
{
if (interruptDecision[otherPlayerId] == NOT_DECIDED)
{
askIfWishesToInterrupt = observer->players[otherPlayerId];
observer->isInterrupting = observer->players[otherPlayerId];
modal = 1;
}
else if (interruptDecision[otherPlayerId] == INTERRUPT)
{
observer->isInterrupting = observer->players[otherPlayerId];
}
else
{
resolve();
}
}
}
}
}
else if (mode == ACTIONSTACK_TARGET)
{
GuiLayer::Update(dt);
}
if (askIfWishesToInterrupt)
{
// WALDORF - added code to use a game option setting to determine how
// long the Interrupt timer should be. If it is set to zero (0), the
// game will wait for ever for the user to make a selection.
if (options[Options::INTERRUPT_SECONDS].number > 0)
{
int extraTime = 0;
//extraTime is a multiplier, it counts the number of unresolved stack actions
//then is used to extend the time you have to interupt.
//this prevents you from "running out of time" while deciding.
//before this int was added, it was possible to run out of time if you had 10 stack actions
//and set the timer to 4 secs. BUG FIX //http://code.google.com/p/wagic/issues/detail?id=464
extraTime = count(0, NOT_RESOLVED, 0);
if (extraTime == 0)
extraTime = 1;//we never want this int to be 0.
if (timer < 0)
timer = static_cast<float>(options[Options::INTERRUPT_SECONDS].number * extraTime);
timer -= dt;
if (timer < 0)
cancelInterruptOffer();
}
}
}
WEvent * REDrawReplacement::replace(WEvent *event)
{
if (!event) return event;
WEventDraw * e = dynamic_cast<WEventDraw*> (event);
if (!e) return event;
if (DrawerOfCard != e->player) return event;
if(!replacementAbility) return event;
//check for dredge
TargetChooserFactory tf(e->player->getObserver());
TargetChooser * tcb = NULL;
tcb = tf.createTargetChooser("dredgeable",source->source);
tcb->targetter = NULL;
if(tcb->validTargetsExist())
{
if(e->player == DrawerOfCard && e->player == source->source->controller())
{
SAFE_DELETE(tcb);
return event;
}
}
SAFE_DELETE(tcb);
vector<MTGAbility*>selection;
//look for other draw replacement effects
list<ReplacementEffect *>::iterator it;
GameObserver * game = source->source->getObserver();
if(replacementAbility->source->controller() == DrawerOfCard)
for (it = game->replacementEffects->modifiers.begin(); it != game->replacementEffects->modifiers.end(); it++)
{
if(REDrawReplacement * DR = dynamic_cast<REDrawReplacement *>(*it))
{
MTGAbility * otherA = NULL;
if(DR->DrawerOfCard == e->player)
{
if(DR->replacementAbility->oneShot)
selection.push_back(DR->replacementAbility->clone());
else
{
otherA = NEW GenericAddToGame(game, game->mLayers->actionLayer()->getMaxId(), source->source,NULL,DR->replacementAbility->clone());
selection.push_back(otherA);
}
}
}
}
for(int j = 0; j < e->nb_cards; j++)
{
if(e->player != DrawerOfCard || selection.size() < 2)
{
MTGAbility * toResolve = replacementAbility->clone();
if(replacementAbility->oneShot)
toResolve->resolve();
else
toResolve->addToGame();
}
else
{
MTGAbility * menuChoice = NEW MenuAbility(game, 1, source->source, source->source,true,selection,NULL,"Choose Draw Replacement");
menuChoice->addToGame();
}
}
delete event;
event = NULL;
return event;
}
//if it's not part of a combo or there is more to gather, then return false
bool AIHints::canWeCombo(GameObserver* observer,MTGCardInstance * card,AIPlayerBaka * Ai)
{
TargetChooserFactory tfc(observer);
TargetChooser * hintTc = NULL;
bool gotCombo = false;
int comboPartsHold = 0;
int comboPartsUntil = 0;
int comboPartsRestriction = 0;
for(unsigned int i = 0; i < hints.size();i++)
{
comboPartsHold = 0;
comboPartsUntil = 0;
comboPartsRestriction = 0;
if(gotCombo)
return gotCombo;//because more then one might be possible at any time.
if (hints[i]->hold.size())
{
for(unsigned int hPart = 0; hPart < hints[i]->hold.size(); hPart++)
{
hintTc = tfc.createTargetChooser(hints[i]->hold[hPart],card);
int TcCheck = hintTc->countValidTargets();
if(hintTc && TcCheck >= hintTc->maxtargets)
{
comboPartsHold +=1;
}
SAFE_DELETE(hintTc);
}
}
if (hints[i]->until.size())
{
for(unsigned int hPart = 0; hPart < hints[i]->until.size(); hPart++)
{
hintTc = tfc.createTargetChooser(hints[i]->until[hPart],card);
int TcCheck = hintTc->countValidTargets();
if(hintTc && TcCheck >= hintTc->maxtargets)
{
comboPartsUntil +=1;
}
SAFE_DELETE(hintTc);
}
}
if (hints[i]->restrict.size())
{
for(unsigned int hPart = 0; hPart < hints[i]->restrict.size(); hPart++)
{
AbilityFactory af(observer);
int checkCond = af.parseCastRestrictions(card,card->controller(),hints[i]->restrict[hPart]);
if(checkCond >= 1)
{
comboPartsRestriction +=1;
}
}
}
if( comboPartsUntil >= int(hints[i]->until.size()) && comboPartsHold >= int(hints[i]->hold.size()) && comboPartsRestriction >= int(hints[i]->restrict.size()) && hints[i]->combos.size() )
{
ManaCost * needed = ManaCost::parseManaCost(hints[i]->manaNeeded, NULL, card);
if(Ai->canPayManaCost(card,needed).size()||!needed->getConvertedCost())
{
gotCombo = true;
Ai->comboHint = hints[i];//set the combo we are doing.
}
SAFE_DELETE(needed);
}
}
return gotCombo;
}
bool AIHints::HintSaysItsForCombo(GameObserver* observer,MTGCardInstance * card)
{
TargetChooserFactory tfc(observer);
TargetChooser * hintTc = NULL;
bool forCombo = false;
for(unsigned int i = 0; i < hints.size();i++)
{
if (hints[i]->combos.size())
{
//time to find the parts and condiations of the combo.
string part = "";
if(!hints[i]->partOfCombo.size() && hints[i]->combos.size())
{
for(unsigned int cPart = 0; cPart < hints[i]->combos.size(); cPart++)
{
//here we disect the different parts of a given combo
part = hints[i]->combos[cPart];
hints[i]->partOfCombo = split(part,'^');
for(unsigned int dPart = 0; dPart < hints[i]->partOfCombo.size(); dPart++)
{
vector<string>asTc;
asTc = parseBetween(hints[i]->partOfCombo[dPart],"hold(",")");
if(asTc.size())
{
hints[i]->hold.push_back(asTc[1]);
asTc.clear();
}
asTc = parseBetween(hints[i]->partOfCombo[dPart],"until(",")");
if(asTc.size())
{
hints[i]->until.push_back(asTc[1]);
asTc.clear();
}
asTc = parseBetween(hints[i]->partOfCombo[dPart],"restriction{","}");
if(asTc.size())
{
hints[i]->restrict.push_back(asTc[1]);
asTc.clear();
}
asTc = parseBetween(hints[i]->partOfCombo[dPart],"cast(",")");
if(asTc.size())
{
hints[i]->cardTargets[asTc[1]] = parseBetween(hints[i]->partOfCombo[dPart],"targeting(",")")[1];
}
asTc = parseBetween(hints[i]->partOfCombo[dPart],"totalmananeeded(",")");
if(asTc.size())
{
hints[i]->manaNeeded = asTc[1];
asTc.clear();
}
}
}
}//we collect the peices of a combo on first run.
for(unsigned int hPart = 0; hPart < hints[i]->hold.size(); hPart++)
{
hintTc = tfc.createTargetChooser(hints[i]->hold[hPart],card);
if(hintTc && hintTc->canTarget(card,true) && hintTc->countValidTargets() <= hintTc->maxtargets)
{
forCombo = true;
}
SAFE_DELETE(hintTc);
}
}
}
return forCombo;//return forCombo that way all hints that are combos are predisected.
}
