示例#1
0
int main (int numargs, char ** args)
{
    DFHack::ContextManager DFMgr("Memory.xml");
    DFHack::Context *DF = DFMgr.getSingleContext();
    DFHack::Process * p;
    try
    {
        DF->Attach();
    }
    catch (exception& e)
    {
        cerr << e.what() << endl;
        #ifndef LINUX_BUILD
            cin.ignore();
        #endif
        return 1;
    }
    p = DF->getProcess();
    string check = "";
    if(numargs == 2)
        check = args[1];

    DFHack::Creatures * Creatures = DF->getCreatures();
    Materials = DF->getMaterials();
    DFHack::Translation * Tran = DF->getTranslation();

    uint32_t numCreatures;
    if(!Creatures->Start(numCreatures))
    {
        cerr << "Can't get creatures" << endl;
        #ifndef LINUX_BUILD
            cin.ignore();
        #endif
        return 1;
    }
    if(!numCreatures)
    {
        cerr << "No creatures to print" << endl;
        #ifndef LINUX_BUILD
            cin.ignore();
        #endif
        return 1;
    }
    mem = DF->getMemoryInfo();

    if(!Materials->ReadInorganicMaterials())
    {
        cerr << "Can't get the inorganics types." << endl;
        return 1;
    }
    if(!Materials->ReadCreatureTypesEx())
    {
        cerr << "Can't get the creature types." << endl;
        return 1; 
    }
    if(!Tran->Start())
    {
        cerr << "Can't get name tables" << endl;
        return 1;
    }
    vector<uint32_t> addrs;
    //DF.InitViewAndCursor();
    for(uint32_t i = 0; i < numCreatures; i++)
    {
        DFHack::t_creature temp;
        unsigned int current_job;
        unsigned int mat_start;
        unsigned int mat_end;
        unsigned int j,k;
        unsigned int matptr;

        Creatures->ReadCreature(i,temp);
        if(temp.mood>=0)
        {
            current_job = p->readDWord(temp.origin + 0x390);
            if(current_job == 0)
                continue;
            mat_start = p->readDWord(current_job + 0xa4 + 4*3);
            mat_end = p->readDWord(current_job + 0xa4 + 4*4);
            for(j=mat_start;j<mat_end;j+=4)
            {
                matptr = p->readDWord(j);
                for(k=0;k<4;k++)
                    printf("%.4X ", p->readWord(matptr + k*2));
                for(k=0;k<3;k++)
                    printf("%.8X ", p->readDWord(matptr + k*4 + 0x8));
                for(k=0;k<2;k++)
                    printf("%.4X ", p->readWord(matptr + k*2 + 0x14));
                for(k=0;k<3;k++)
                    printf("%.8X ", p->readDWord(matptr + k*4 + 0x18));
                for(k=0;k<4;k++)
                    printf("%.2X ", p->readByte(matptr + k + 0x24));
                for(k=0;k<6;k++)
                    printf("%.8X ", p->readDWord(matptr + k*4 + 0x28));
                for(k=0;k<4;k++)
                    printf("%.2X ", p->readByte(matptr + k + 0x40));
                for(k=0;k<9;k++)
                    printf("%.8X ", p->readDWord(matptr + k*4 + 0x44));
                printf(" [%p]\n", matptr);
            }
        }
    }
    Creatures->Finish();
    DF->Detach();
    return 0;
}
示例#2
0
int main ( int argc, char** argv )
{
    DFHack::memory_info *mem;
    DFHack::Process *proc;
    uint32_t creature_pregnancy_offset;
    
    //bool femaleonly = 0;
    bool showcreatures = 0;
    int maxpreg = 1000; // random start value, since its not required and im not sure how to set it to infinity
    list<string> s_creatures;
    
    // parse input, handle this nice and neat before we get to the connecting
    argstream as(argc,argv);
    as // >>option('f',"female",femaleonly,"Impregnate females only")
        >>option('s',"show",showcreatures,"Show creature list (read only)")
        >>parameter('m',"max",maxpreg,"The maximum limit of pregnancies ", false)
        >>values<string>(back_inserter(s_creatures), "any number of creatures")
        >>help();
        
    // make the creature list unique
    s_creatures.unique();
    
    if (!as.isOk())
    {
        cout << as.errorLog();
        return(0);
    }
    else if (as.helpRequested())
    {
        cout<<as.usage()<<endl;
        return(1);
    }
    else if(showcreatures==1)
    {
    }
    else if (s_creatures.size() == 0 && showcreatures != 1)
    {
        cout << as.usage() << endl << "---------------------------------------" << endl;
        cout << "Creature list empty, assuming CATs" << endl;
        s_creatures.push_back("CAT");
    }

    DFHack::ContextManager DFMgr("Memory.xml");
    DFHack::Context *DF;
    try
    {
        DF = DFMgr.getSingleContext();
        DF->Attach();
    }
    catch (exception& e)
    {
        cerr << e.what() << endl;
        #ifndef LINUX_BUILD
            cin.ignore();
        #endif
        return 1;
    }

    proc = DF->getProcess();
    mem = DF->getMemoryInfo();
    DFHack::Materials *Mats = DF->getMaterials();
    DFHack::Creatures *Cre = DF->getCreatures();
    creature_pregnancy_offset = mem->getOffset("creature_pregnancy");

    if(!Mats->ReadCreatureTypesEx())
    {
        cerr << "Can't get the creature types." << endl;
        #ifndef LINUX_BUILD
            cin.ignore();
        #endif
        return 1;
    }

    uint32_t numCreatures;
    if(!Cre->Start(numCreatures))
    {
        cerr << "Can't get creatures" << endl;
        #ifndef LINUX_BUILD
            cin.ignore();
        #endif
        return 1;
    }

    int totalcount=0;
    int totalchanged=0;
    string sextype;

    // shows all the creatures and returns.

    int maxlength = 0;
    map<string, vector <t_creature> > male_counts;
    map<string, vector <t_creature> > female_counts;
    
    // classify
    for(uint32_t i =0;i < numCreatures;i++)
    {
        DFHack::t_creature creature;
        Cre->ReadCreature(i,creature);
        DFHack::t_creaturetype & crt = Mats->raceEx[creature.race];
        string castename = crt.castes[creature.sex].rawname;
        if(castename == "FEMALE")
        {
            female_counts[Mats->raceEx[creature.race].rawname].push_back(creature);
            male_counts[Mats->raceEx[creature.race].rawname].size();
        }
        else // male, other, etc.
        {
            male_counts[Mats->raceEx[creature.race].rawname].push_back(creature);
            female_counts[Mats->raceEx[creature.race].rawname].size(); //auto initialize the females as well
        }
    }
    
    // print (optional)
    if (showcreatures == 1)
    {
        cout << "Type\t\tMale #\tFemale #" << endl;
        for(map<string, vector <t_creature> >::iterator it1 = male_counts.begin();it1!=male_counts.end();it1++)
        {
            cout << it1->first << "\t\t" << it1->second.size() << "\t" << female_counts[it1->first].size() << endl;
        }
    }
    
    // process
    for (list<string>::iterator it = s_creatures.begin(); it != s_creatures.end(); ++it)
    {
        std::string clinput = *it;
        std::transform(clinput.begin(), clinput.end(), clinput.begin(), ::toupper);
        vector <t_creature> &females = female_counts[clinput];
        uint32_t sz_fem = females.size();
        totalcount += sz_fem;
        for(uint32_t i = 0; i < sz_fem && totalchanged != maxpreg; i++)
        {
            t_creature & female = females[i];
            uint32_t preg_timer = proc->readDWord(female.origin + creature_pregnancy_offset);
            if(preg_timer != 0)
            {
                proc->writeDWord(female.origin + creature_pregnancy_offset, rand() % 100 + 1);
                totalchanged++;
            }
        }
    }

    cout << totalchanged << " pregnancies accelerated. Total creatures checked: " << totalcount << "." << endl;
    Cre->Finish();
    DF->Detach();
    #ifndef LINUX_BUILD
        cout << "Done. Press any key to continue" << endl;
        cin.ignore();
    #endif
    return 0;
}