int main(int argc, char *argv[])
{
/* initialize your non-curses data structures here */
signal(SIGINT, finish); /* arrange interrupts to terminate */
setlocale(LC_ALL,"");
initscr(); /* initialize the curses library */
keypad(stdscr, TRUE); /* enable keyboard mapping */
nonl(); /* tell curses not to do NL->CR/NL on output */
cbreak(); /* take input chars one at a time, no wait for \n */
noecho(); /* don't echo input */
//nodelay(stdscr, true);
keypad(stdscr, TRUE);
scrollok(stdscr, TRUE);
if (has_colors())
{
start_color();
/*
* Simple color assignment, often all we need.
*/
init_pair(COLOR_BLACK, COLOR_BLACK, COLOR_BLACK);
init_pair(COLOR_GREEN, COLOR_GREEN, COLOR_BLACK);
init_pair(COLOR_RED, COLOR_RED, COLOR_BLACK);
init_pair(COLOR_BLUE, COLOR_BLUE, COLOR_BLACK);
init_pair(COLOR_YELLOW, COLOR_YELLOW, COLOR_BLACK);
init_color(COLOR_CYAN, 700, 700, 700); // lt grey
init_color(COLOR_MAGENTA, 500, 500, 500); // dk grey
init_pair(COLOR_WHITE, COLOR_WHITE, COLOR_BLACK);
init_pair(COLOR_CYAN, COLOR_CYAN, COLOR_BLACK);
init_pair(COLOR_MAGENTA, COLOR_MAGENTA, COLOR_BLACK);
}
int x_max,y_max,z_max;
uint32_t x_max_a,y_max_a,z_max_a;
/*
uint16_t tiletypes[16][16];
DFHack::t_designation designations[16][16];
uint8_t regionoffsets[16];
*/
map <int16_t, uint32_t> materials;
materials.clear();
mapblock40d blocks[3][3];
vector<DFHack::t_effect_df40d> effects;
vector< vector <uint16_t> > layerassign;
vector<t_vein> veinVector;
vector<t_frozenliquidvein> IceVeinVector;
vector<t_spattervein> splatter;
vector<t_grassvein> grass;
vector<t_worldconstruction> wconstructs;
t_temperatures b_temp1;
t_temperatures b_temp2;
DFHack::Materials * Mats = 0;
DFHack::Maps * Maps = 0;
DFHack::ContextManager DFMgr("Memory.xml");
DFHack::Context* DF;
try
{
pDF = DF = DFMgr.getSingleContext();
DF->Attach();
Maps = DF->getMaps();
}
catch (exception& e)
{
cerr << e.what() << endl;
#ifndef LINUX_BUILD
cin.ignore();
#endif
finish(0);
}
bool hasmats = true;
try
{
Mats = DF->getMaterials();
}
catch (exception& e)
{
hasmats = false;
}
// init the map
if(!Maps->Start())
{
error = "Can't find a map to look at.";
finish(0);
}
Maps->getSize(x_max_a,y_max_a,z_max_a);
x_max = x_max_a;
y_max = y_max_a;
z_max = z_max_a;
bool hasInorgMats = false;
bool hasPlantMats = false;
bool hasCreatureMats = false;
if(hasmats)
{
// get stone matgloss mapping
if(Mats->ReadInorganicMaterials())
{
hasInorgMats = true;
}
if(Mats->ReadCreatureTypes())
{
hasCreatureMats = true;
}
if(Mats->ReadOrganicMaterials())
{
hasPlantMats = true;
}
}
/*
// get region geology
if(!DF.ReadGeology( layerassign ))
{
error = "Can't read local geology.";
pDF = 0;
finish(0);
}
*/
// FIXME: could fail on small forts
int cursorX = x_max/2 - 1;
int cursorY = y_max/2 - 1;
int cursorZ = z_max/2 - 1;
bool dig = false;
bool dump = false;
bool digbit = false;
bool dotwiddle;
unsigned char twiddle = 0;
int vein = 0;
int filenum = 0;
bool dirtybit = false;
uint32_t blockaddr = 0;
uint32_t blockaddr2 = 0;
t_blockflags bflags;
bflags.whole = 0;
enum e_tempmode
{
TEMP_NO,
TEMP_1,
TEMP_2,
WATER_SALT,
WATER_STAGNANT
};
e_tempmode temperature = TEMP_NO;
// resume so we don't block DF while we wait for input
DF->Resume();
for (;;)
{
dig = false;
dump = false;
dotwiddle = false;
digbit = false;
int c = getch(); /* refresh, accept single keystroke of input */
flushinp();
clrscr();
/* process the command keystroke */
switch(c)
{
case KEY_DOWN:
cursorY ++;
break;
case KEY_UP:
cursorY --;
break;
case KEY_LEFT:
cursorX --;
break;
case KEY_RIGHT:
cursorX ++;
break;
case KEY_NPAGE:
cursorZ --;
break;
case KEY_PPAGE:
cursorZ ++;
break;
case '+':
vein ++;
break;
case 'd':
dig = true;
break;
case 'o':
dump = true;
break;
case '-':
vein --;
break;
case 'z':
digbit = true;
break;
case '/':
if(twiddle != 0) twiddle--;
break;
case '*':
twiddle++;
break;
case 't':
dotwiddle = true;
break;
case 'b':
temperature = TEMP_NO;
break;
case 'n':
temperature = TEMP_1;
break;
case 'm':
temperature = TEMP_2;
break;
case 'c':
temperature = WATER_SALT;
break;
case 'v':
temperature = WATER_STAGNANT;
break;
case 27: // escape key
DF->Detach();
return 0;
break;
default:
break;
}
cursorX = max(cursorX, 0);
cursorY = max(cursorY, 0);
cursorZ = max(cursorZ, 0);
cursorX = min(cursorX, x_max - 1);
cursorY = min(cursorY, y_max - 1);
cursorZ = min(cursorZ, z_max - 1);
if(twiddle > 31)
twiddle = 31;
// clear data before we suspend
memset(blocks,0,sizeof(blocks));
veinVector.clear();
IceVeinVector.clear();
effects.clear();
splatter.clear();
grass.clear();
dirtybit = 0;
// Supend, read/write data
DF->Suspend();
// restart cleared modules
Maps->Start();
if(hasmats)
{
Mats->Start();
if(hasInorgMats)
{
Mats->ReadInorganicMaterials();
}
if(hasPlantMats)
{
Mats->ReadOrganicMaterials();
}
if(hasCreatureMats)
{
Mats->ReadCreatureTypes();
}
}
/*
if(DF.InitReadEffects(effectnum))
{
for(uint32_t i = 0; i < effectnum;i++)
{
t_effect_df40d effect;
DF.ReadEffect(i,effect);
effects.push_back(effect);
}
}
*/
for(int i = -1; i <= 1; i++) for(int j = -1; j <= 1; j++)
{
mapblock40d * Block = &blocks[i+1][j+1];
if(Maps->isValidBlock(cursorX+i,cursorY+j,cursorZ))
{
Maps->ReadBlock40d(cursorX+i,cursorY+j,cursorZ, Block);
// extra processing of the block in the middle
if(i == 0 && j == 0)
{
if(hasInorgMats)
do_features(DF, Block, cursorX, cursorY, 50,10, Mats->inorganic);
// read veins
Maps->ReadVeins(cursorX+i,cursorY+j,cursorZ,&veinVector,&IceVeinVector,&splatter,&grass, &wconstructs);
// get pointer to block
blockaddr = Maps->getBlockPtr(cursorX+i,cursorY+j,cursorZ);
blockaddr2 = Block->origin;
// dig all veins and trees
if(dig)
{
for(int x = 0; x < 16; x++) for(int y = 0; y < 16; y++)
{
int16_t tiletype = Block->tiletypes[x][y];
TileShape tc = tileShape(tiletype);
TileMaterial tm = tileMaterial(tiletype);
if( tc == WALL && tm == VEIN || tc == TREE_OK || tc == TREE_DEAD)
{
Block->designation[x][y].bits.dig = designation_default;
}
}
Maps->WriteDesignations(cursorX+i,cursorY+j,cursorZ, &(Block->designation));
}
// read temperature data
Maps->ReadTemperatures(cursorX+i,cursorY+j,cursorZ,&b_temp1, &b_temp2 );
if(dotwiddle)
{
bitset<32> bs = Block->designation[0][0].whole;
bs.flip(twiddle);
Block->designation[0][0].whole = bs.to_ulong();
Maps->WriteDesignations(cursorX+i,cursorY+j,cursorZ, &(Block->designation));
dotwiddle = false;
}
// do a dump of the block data
if(dump)
{
hexdump(DF,blockaddr,0x1E00,filenum);
filenum++;
}
// read/write dirty bit of the block
Maps->ReadDirtyBit(cursorX+i,cursorY+j,cursorZ,dirtybit);
Maps->ReadBlockFlags(cursorX+i,cursorY+j,cursorZ,bflags);
if(digbit)
{
dirtybit = !dirtybit;
Maps->WriteDirtyBit(cursorX+i,cursorY+j,cursorZ,dirtybit);
}
}
}
}
// Resume, print stuff to the terminal
DF->Resume();
for(int i = -1; i <= 1; i++) for(int j = -1; j <= 1; j++)
{
mapblock40d * Block = &blocks[i+1][j+1];
for(int x = 0; x < 16; x++) for(int y = 0; y < 16; y++)
{
int color = COLOR_BLACK;
color = pickColor(Block->tiletypes[x][y]);
/*
if(!Block->designation[x][y].bits.hidden)
{
puttile(x+(i+1)*16,y+(j+1)*16,Block->tiletypes[x][y], color);
}
else*/
{
attron(A_STANDOUT);
puttile(x+(i+1)*16,y+(j+1)*16,Block->tiletypes[x][y], color);
attroff(A_STANDOUT);
}
}
// print effects for the center tile
/*
if(i == 0 && j == 0)
{
for(uint zz = 0; zz < effects.size();zz++)
{
if(effects[zz].z == cursorZ && !effects[zz].isHidden)
{
// block coords to tile coords
uint16_t x = effects[zz].x - (cursorX * 16);
uint16_t y = effects[zz].y - (cursorY * 16);
if(x < 16 && y < 16)
{
putch(x + 16,y + 16,'@',COLOR_WHITE);
}
}
}
}
*/
}
gotoxy(50,0);
cprintf("arrow keys, PGUP, PGDN = navigate");
gotoxy(50,1);
cprintf("+,- = switch vein");
gotoxy(50,2);
uint32_t mineralsize = veinVector.size();
uint32_t icesize = IceVeinVector.size();
uint32_t splattersize = splatter.size();
uint32_t grasssize = grass.size();
uint32_t wconstrsize = wconstructs.size();
uint32_t totalVeinSize = mineralsize+ icesize + splattersize + grasssize + wconstrsize;
if(vein == totalVeinSize) vein = totalVeinSize - 1;
if(vein < -1) vein = -1;
cprintf("X %d/%d, Y %d/%d, Z %d/%d. Vein %d of %d",cursorX+1,x_max,cursorY+1,y_max,cursorZ,z_max,vein+1,totalVeinSize);
if(!veinVector.empty() || !IceVeinVector.empty() || !splatter.empty() || !grass.empty() || !wconstructs.empty())
{
if(vein != -1 && vein < totalVeinSize)
{
uint32_t realvein = 0;
if(vein < mineralsize)
{
realvein = vein;
//iterate through vein rows
for(uint32_t j = 0;j<16;j++)
{
//iterate through the bits
for (uint32_t k = 0; k< 16;k++)
{
// and the bit array with a one-bit mask, check if the bit is set
bool set = !!(((1 << k) & veinVector[realvein].assignment[j]) >> k);
if(set)
{
putch(k+16,j+16,'$',COLOR_RED);
}
}
}
if(hasInorgMats)
{
gotoxy(50,3);
cprintf("Mineral: %s",Mats->inorganic[veinVector[vein].type].id);
}
}
else if (vein < mineralsize + icesize)
{
realvein = vein - mineralsize;
t_frozenliquidvein &frozen = IceVeinVector[realvein];
for(uint32_t i = 0;i<16;i++)
{
for (uint32_t j = 0; j< 16;j++)
{
int color = COLOR_BLACK;
int tile = frozen.tiles[i][j];
color = pickColor(tile);
attron(A_STANDOUT);
puttile(i+16,j+16,tile, color);
attroff(A_STANDOUT);
}
}
gotoxy(50,3);
cprintf("ICE");
}
else if(vein < mineralsize + icesize + splattersize)
{
realvein = vein - mineralsize - icesize;
for(uint32_t yyy = 0; yyy < 16; yyy++)
{
for(uint32_t xxx = 0; xxx < 16; xxx++)
{
uint8_t intensity = splatter[realvein].intensity[xxx][yyy];
if(intensity)
{
attron(A_STANDOUT);
putch(xxx+16,yyy+16,'*', COLOR_RED);
attroff(A_STANDOUT);
}
}
}
if(hasCreatureMats)
{
gotoxy(50,3);
cprintf("Spatter: %s",PrintSplatterType(splatter[realvein].mat1,splatter[realvein].mat2,Mats->race).c_str());
}
}
else if(vein < mineralsize + icesize + splattersize + grasssize)
{
realvein = vein - mineralsize - icesize - splattersize;
t_grassvein & grassy =grass[realvein];
for(uint32_t yyy = 0; yyy < 16; yyy++)
{
for(uint32_t xxx = 0; xxx < 16; xxx++)
{
uint8_t intensity = grassy.intensity[xxx][yyy];
if(intensity)
{
attron(A_STANDOUT);
putch(xxx+16,yyy+16,'X', COLOR_RED);
attroff(A_STANDOUT);
}
}
}
if(hasPlantMats)
{
gotoxy(50,3);
cprintf("Grass: 0x%x, %s",grassy.address_of, Mats->organic[grassy.material].id);
}
}
else
{
realvein = vein - mineralsize - icesize - splattersize - grasssize;
t_worldconstruction & wconstr=wconstructs[realvein];
for(uint32_t j = 0; j < 16; j++)
{
for(uint32_t k = 0; k < 16; k++)
{
bool set = !!(((1 << k) & wconstr.assignment[j]) >> k);
if(set)
{
putch(k+16,j+16,'$',COLOR_RED);
}
}
}
if(hasInorgMats)
{
gotoxy(50,3);
cprintf("Road: 0x%x, %d - %s", wconstr.address_of, wconstr.material,Mats->inorganic[wconstr.material].id);
}
}
}
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;
}
int main (int numargs, char ** args)
{
DFHack::World * World;
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;
}
string check = "";
if(numargs == 2)
check = args[1];
Creatures = DF->getCreatures();
Materials = DF->getMaterials();
World = DF->getWorld();
current_year = World->ReadCurrentYear();
current_tick = World->ReadCurrentTick();
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();
Materials->ReadInorganicMaterials();
Materials->ReadOrganicMaterials();
Materials->ReadWoodMaterials();
Materials->ReadPlantMaterials();
Materials->ReadCreatureTypes();
Materials->ReadCreatureTypesEx();
Materials->ReadDescriptorColors();
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++)
{
printf("%d/%d\n", i, numCreatures);
DFHack::t_creature temp;
Creatures->ReadCreature(i,temp);
if(check.empty() || string(Materials->raceEx[temp.race].rawname) == check)
{
cout << "index " << i << " ";
printCreature(DF,temp);
addrs.push_back(temp.origin);
}
printf("!\n");
}
if(addrs.size() <= 10)
{
interleave_hex(DF,addrs,200);
}
/*
uint32_t currentIdx;
DFHack::t_creature currentCreature;
DF.getCurrentCursorCreature(currentIdx);
cout << "current creature at index " << currentIdx << endl;
DF.ReadCreature(currentIdx, currentCreature);
printCreature(DF,currentCreature);
*/
Creatures->Finish();
DF->Detach();
#ifndef LINUX_BUILD
cout << "Done. Press any key to continue" << endl;
cin.ignore();
#endif
return 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;
}
int main (int argc, char *argv[])
{
bool print_refs = false;
bool print_hex = false;
bool print_acc = false;
for(int i = 1; i < argc; i++)
{
char *arg = argv[i];
if (arg[0] != '-')
continue;
for (; *arg; arg++) {
switch (arg[0]) {
case 'r':
print_refs = true;
break;
case 'x':
print_hex = true;
break;
case 'a':
print_acc = true;
break;
}
}
}
DFHack::Process * p;
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;
}
DFHack::Materials * Materials = DF->getMaterials();
Materials->ReadAllMaterials();
DFHack::Gui * Gui = DF->getGui();
DFHack::Items * Items = DF->getItems();
Items->Start();
DFHack::VersionInfo * mem = DF->getMemoryInfo();
p = DF->getProcess();
int32_t x,y,z;
Gui->getCursorCoords(x,y,z);
std::vector<uint32_t> p_items;
Items->readItemVector(p_items);
uint32_t size = p_items.size();
// FIXME: tools should never be exposed to DFHack internals!
DFHack::OffsetGroup* itemGroup = mem->getGroup("Items");
uint32_t ref_vector = itemGroup->getOffset("item_ref_vector");
for(size_t i = 0; i < size; i++)
{
DFHack::dfh_item itm;
memset(&itm, 0, sizeof(DFHack::dfh_item));
Items->readItem(p_items[i],itm);
if (x != -30000
&& !(itm.base.x == x && itm.base.y == y && itm.base.z == z
&& itm.base.flags.on_ground
&& !itm.base.flags.in_chest
&& !itm.base.flags.in_inventory
&& !itm.base.flags.in_building))
continue;
printf(
"%5d: %08x %6d %08x (%d,%d,%d) #%08x [%d] *%d %s - %s\n",
i, itm.origin, itm.id, itm.base.flags.whole,
itm.base.x, itm.base.y, itm.base.z,
itm.base.vtable,
itm.wear_level,
itm.quantity,
Items->getItemClass(itm).c_str(),
Items->getItemDescription(itm, Materials).c_str()
);
if (print_hex)
hexdump(DF,p_items[i],0x300);
if (print_acc)
cout << Items->dumpAccessors(itm) << endl;
if (print_refs) {
DFHack::DfVector<uint32_t> p_refs(p, itm.origin + ref_vector);
for (size_t j = 0; j < p_refs.size(); j++) {
uint32_t vptr = p->readDWord(p_refs[j]);
uint32_t val = p->readDWord(p_refs[j]+4);
printf("\t-> %d \t%s\n", int(val), p->readClassName(vptr).c_str());
}
}
}
#ifndef LINUX_BUILD
cout << "Done. Press any key to continue" << endl;
cin.ignore();
#endif
return 0;
}
