command_result changelayer (color_ostream &out, std::vector <std::string> & parameters)
{
CoreSuspender suspend;
string material;
bool force = false;
bool all_biomes = false;
bool all_layers = false;
bool verbose = false;
warned = false;
for(size_t i = 0; i < parameters.size();i++)
{
if(parameters[i] == "help" || parameters[i] == "?")
{
out.print(changelayer_help.c_str());
return CR_OK;
}
if(parameters[i] == "trouble")
{
out.print(changelayer_trouble.c_str());
return CR_OK;
}
if(parameters[i] == "force")
force = true;
if(parameters[i] == "all_biomes")
all_biomes = true;
if(parameters[i] == "all_layers")
all_layers = true;
if(parameters[i] == "verbose")
verbose = true;
}
if (!Maps::IsValid())
{
out.printerr("Map is not available!\n");
return CR_FAILURE;
}
if (parameters.empty())
{
out.printerr("You need to specify a material!\n");
return CR_WRONG_USAGE;
}
material = parameters[0];
MaterialInfo mat_new;
if (!mat_new.findInorganic(material))
{
out.printerr("No such material!\n");
return CR_FAILURE;
}
// check if specified material is stone or gem or soil
if (mat_new.inorganic->material.flags.is_set(material_flags::IS_METAL) ||
mat_new.inorganic->material.flags.is_set(material_flags::NO_STONE_STOCKPILE))
{
out.printerr("Invalid material - you must select a type of stone or gem or soil.\n");
return CR_FAILURE;
}
MapExtras::MapCache mc;
int32_t regionX, regionY, regionZ;
Maps::getPosition(regionX,regionY,regionZ);
int32_t cursorX, cursorY, cursorZ;
Gui::getCursorCoords(cursorX,cursorY,cursorZ);
if(cursorX == -30000)
{
out.printerr("No cursor; place cursor over tile.\n");
return CR_FAILURE;
}
DFCoord cursor (cursorX,cursorY,cursorZ);
uint32_t blockX = cursorX / 16;
uint32_t tileX = cursorX % 16;
uint32_t blockY = cursorY / 16;
uint32_t tileY = cursorY % 16;
MapExtras::Block * b = mc.BlockAt(cursor/16);
if(!b || !b->is_valid())
{
out.printerr("No data.\n");
return CR_OK;
}
df::tile_designation des = b->DesignationAt(cursor%16);
// get biome and geolayer at cursor position
uint32_t biome = des.bits.biome;
uint32_t layer = des.bits.geolayer_index;
if(verbose)
{
out << "biome: " << biome << endl
<< "geolayer: " << layer << endl;
}
// there is no Maps::WriteGeology or whatever, and I didn't want to mess with the library and add it
// so I copied the stuff which reads the geology information and modified it to be able to change it
//
// a more elegant solution would probably look like this:
// 1) modify Maps::ReadGeology to accept and fill one more optional vector
// where the geolayer ids of the 9 biomes are stored
// 2) call ReadGeology here, modify the data in the vectors without having to do all that map stuff
// 3) write Maps::WriteGeology, pass the vectors, let it do it's work
// Step 1) is optional, but it would make implementing 3) easier.
// Otherwise that "check which geo_index is used by biome X" loop would need to be done again.
// no need to touch the same geology more than once
// though it wouldn't matter much since there is not much data to be processed
vector<uint16_t> v_geoprocessed;
v_geoprocessed.clear();
// iterate over 8 surrounding regions + local region
for (int i = eNorthWest; i < eBiomeCount; i++)
{
if(verbose)
out << "---Biome: " << i;
if(!all_biomes && i!=biome)
{
if(verbose)
out << "-skipping" << endl;
continue;
}
else
{
if(verbose)
out << "-checking" << endl;
}
// check against worldmap boundaries, fix if needed
// regionX is in embark squares
// regionX/16 is in 16x16 embark square regions
// i provides -1 .. +1 offset from the current region
int bioRX = world->map.region_x / 16 + ((i % 3) - 1);
if (bioRX < 0) bioRX = 0;
if (bioRX >= world->world_data->world_width) bioRX = world->world_data->world_width - 1;
int bioRY = world->map.region_y / 16 + ((i / 3) - 1);
if (bioRY < 0) bioRY = 0;
if (bioRY >= world->world_data->world_height) bioRY = world->world_data->world_height - 1;
// get index into geoblock vector
uint16_t geoindex = world->world_data->region_map[bioRX][bioRY].geo_index;
if(verbose)
out << "geoindex: " << geoindex << endl;
bool skip = false;
for(int g=0; g<v_geoprocessed.size(); g++)
{
if(v_geoprocessed.at(g)==geoindex)
{
if(verbose)
out << "already processed" << endl;
skip = true;
break;
}
}
if(skip)
continue;
v_geoprocessed.push_back(geoindex);
/// geology blocks have a vector of layer descriptors
// get the vector with pointer to layers
df::world_geo_biome *geo_biome = df::world_geo_biome::find(geoindex);
if (!geo_biome)
{
if(verbose)
out << "no geology found here." << endl;
continue;
}
vector <df::world_geo_layer*> &geolayers = geo_biome->layers;
// complain if layer is out of range
// geology has up to 16 layers currently, but can have less!
if(layer >= geolayers.size() || layer < 0)
{
if(verbose)
out << "layer out of range!";
continue;
}
// now let's actually write the new mat id to the layer(s)
if(all_layers)
{
for (size_t j = 0; j < geolayers.size(); j++)
{
MaterialInfo mat_old;
mat_old.decode(0, geolayers[j]->mat_index);
if(conversionAllowed(out, mat_new, mat_old, force))
{
if(verbose)
out << "changing geolayer " << j
<< " from " << mat_old.getToken()
<< " to " << mat_new.getToken()
<< endl;
geolayers[j]->mat_index = mat_new.index;
}
}
}
else
{
MaterialInfo mat_old;
mat_old.decode(0, geolayers[layer]->mat_index);
if(conversionAllowed(out, mat_new, mat_old, force))
{
if(verbose)
out << "changing geolayer " << layer
<< " from " << mat_old.getToken()
<< " to " << mat_new.getToken()
<< endl;
geolayers[layer]->mat_index = mat_new.index;
}
}
}
out.print("Done.\n");
// Give control back to DF.
return CR_OK;
}
command_result prospector (color_ostream &con, vector <string> & parameters)
{
bool showHidden = false;
bool showPlants = true;
bool showValue = false;
bool showHFS = false;
for(size_t i = 0; i < parameters.size();i++)
{
if (parameters[i] == "all")
{
showHidden = true;
}
else if (parameters[i] == "value")
{
showValue = true;
}
else if (parameters[i] == "hell")
{
showHidden = showHFS = true;
}
else
return CR_WRONG_USAGE;
}
CoreSuspender suspend;
// Embark screen active: estimate using world geology data
if (VIRTUAL_CAST_VAR(screen, df::viewscreen_choose_start_sitest, Core::getTopViewscreen()))
return embark_prospector(con, screen, showHidden, showValue);
if (!Maps::IsValid())
{
con.printerr("Map is not available!\n");
return CR_FAILURE;
}
uint32_t x_max = 0, y_max = 0, z_max = 0;
Maps::getSize(x_max, y_max, z_max);
MapExtras::MapCache map;
DFHack::Materials *mats = Core::getInstance().getMaterials();
DFHack::t_feature blockFeature;
bool hasAquifer = false;
MatMap baseMats;
MatMap layerMats;
MatMap veinMats;
MatMap plantMats;
MatMap treeMats;
matdata liquidWater;
matdata liquidMagma;
matdata aquiferTiles;
matdata hfsTiles;
uint32_t vegCount = 0;
for(uint32_t z = 0; z < z_max; z++)
{
for(uint32_t b_y = 0; b_y < y_max; b_y++)
{
for(uint32_t b_x = 0; b_x < x_max; b_x++)
{
// Get the map block
df::coord2d blockCoord(b_x, b_y);
MapExtras::Block *b = map.BlockAt(DFHack::DFCoord(b_x, b_y, z));
if (!b || !b->is_valid())
{
continue;
}
// Find features
b->GetFeature(&blockFeature);
int global_z = world->map.region_z + z;
// Iterate over all the tiles in the block
for(uint32_t y = 0; y < 16; y++)
{
for(uint32_t x = 0; x < 16; x++)
{
df::coord2d coord(x, y);
df::tile_designation des = b->DesignationAt(coord);
df::tile_occupancy occ = b->OccupancyAt(coord);
// Skip hidden tiles
if (!showHidden && des.bits.hidden)
{
continue;
}
// Check for aquifer
if (des.bits.water_table)
{
hasAquifer = true;
aquiferTiles.add(global_z);
}
// Check for liquid
if (des.bits.flow_size)
{
if (des.bits.liquid_type == tile_liquid::Magma)
liquidMagma.add(global_z);
else
liquidWater.add(global_z);
}
df::tiletype type = b->tiletypeAt(coord);
df::tiletype_shape tileshape = tileShape(type);
df::tiletype_material tilemat = tileMaterial(type);
// We only care about these types
switch (tileshape)
{
case tiletype_shape::WALL:
case tiletype_shape::FORTIFICATION:
break;
case tiletype_shape::EMPTY:
/* find the top of the HFS chamber */
if (tilemat == tiletype_material::AIR &&
des.bits.feature && des.bits.hidden &&
blockFeature.type == feature_type::glowing_pit)
{
hfsTiles.add(global_z);
}
default:
continue;
}
// Count the material type
baseMats[tilemat].add(global_z);
// Find the type of the tile
switch (tilemat)
{
case tiletype_material::SOIL:
case tiletype_material::STONE:
layerMats[b->layerMaterialAt(coord)].add(global_z);
break;
case tiletype_material::MINERAL:
veinMats[b->veinMaterialAt(coord)].add(global_z);
break;
case tiletype_material::LAVA_STONE:
// TODO ?
break;
default:
break;
}
}
}
// Check plants this way, as the other way wasn't getting them all
// and we can check visibility more easily here
if (showPlants)
{
auto block = Maps::getBlock(b_x,b_y,z);
stl::vector<df::plant *> *plants = block ? &block->plants : NULL;
if(plants)
{
for (auto it = plants->begin(); it != plants->end(); it++)
{
const df::plant & plant = *(*it);
df::coord2d loc(plant.pos.x, plant.pos.y);
loc = loc % 16;
if (showHidden || !b->DesignationAt(loc).bits.hidden)
{
if(plant.flags.bits.is_shrub)
plantMats[plant.plant_id].add(global_z);
else
treeMats[plant.wood_id].add(global_z);
}
}
}
}
// Block end
} // block x
// Clean uneeded memory
map.trash();
} // block y
} // z
MatMap::const_iterator it;
con << "Base materials:" << std::endl;
for (it = baseMats.begin(); it != baseMats.end(); ++it)
{
con << std::setw(25) << ENUM_KEY_STR(tiletype_material,(df::tiletype_material)it->first) << " : " << it->second.count << std::endl;
}
if (liquidWater.count || liquidMagma.count)
{
con << std::endl << "Liquids:" << std::endl;
if (liquidWater.count)
{
con << std::setw(25) << "WATER" << " : ";
printMatdata(con, liquidWater);
}
if (liquidWater.count)
{
con << std::setw(25) << "MAGMA" << " : ";
printMatdata(con, liquidMagma);
}
}
con << std::endl << "Layer materials:" << std::endl;
printMats<df::matgloss_stone, shallower>(con, layerMats, world->raws.matgloss.stone, showValue);
printVeins(con, veinMats, mats, showValue);
if (showPlants)
{
con << "Shrubs:" << std::endl;
printMats<df::matgloss_plant, std::greater>(con, plantMats, world->raws.matgloss.plant, showValue);
con << "Wood in trees:" << std::endl;
printMats<df::matgloss_wood, std::greater>(con, treeMats, world->raws.matgloss.wood, showValue);
}
if (hasAquifer)
{
con << "Has aquifer";
if (aquiferTiles.count)
{
con << " : ";
printMatdata(con, aquiferTiles);
}
else
con << std::endl;
}
if (showHFS && hfsTiles.count)
{
con << "Has HFS : ";
printMatdata(con, hfsTiles);
}
// Cleanup
mats->Finish();
con << std::endl;
return CR_OK;
}
command_result mapexport (color_ostream &out, std::vector <std::string> & parameters)
{
bool showHidden = false;
int filenameParameter = 1;
for(size_t i = 0; i < parameters.size();i++)
{
if(parameters[i] == "help" || parameters[i] == "?")
{
out.print("Exports the currently visible map to a file.\n"
"Usage: mapexport [options] <filename>\n"
"Example: mapexport all embark.dfmap\n"
"Options:\n"
" all - Export the entire map, not just what's revealed.\n"
);
return CR_OK;
}
if (parameters[i] == "all")
{
showHidden = true;
filenameParameter++;
}
}
CoreSuspender suspend;
uint32_t x_max=0, y_max=0, z_max=0;
if (!Maps::IsValid())
{
out.printerr("Map is not available!\n");
return CR_FAILURE;
}
if (parameters.size() < filenameParameter)
{
out.printerr("Please supply a filename.\n");
return CR_FAILURE;
}
std::string filename = parameters[filenameParameter-1];
if (filename.rfind(".dfmap") == std::string::npos) filename += ".dfmap";
out << "Writing to " << filename << "..." << std::endl;
std::ofstream output_file(filename, std::ios::out | std::ios::trunc | std::ios::binary);
if (!output_file.is_open())
{
out.printerr("Couldn't open the output file.\n");
return CR_FAILURE;
}
ZeroCopyOutputStream *raw_output = new OstreamOutputStream(&output_file);
GzipOutputStream *zip_output = new GzipOutputStream(raw_output);
CodedOutputStream *coded_output = new CodedOutputStream(zip_output);
coded_output->WriteLittleEndian32(0x50414DDF); //Write our file header
Maps::getSize(x_max, y_max, z_max);
MapExtras::MapCache map;
DFHack::Materials *mats = Core::getInstance().getMaterials();
out << "Writing map info..." << std::endl;
dfproto::Map protomap;
protomap.set_x_size(x_max);
protomap.set_y_size(y_max);
protomap.set_z_size(z_max);
out << "Writing material dictionary..." << std::endl;
for (size_t i = 0; i < world->raws.inorganics.size(); i++)
{
dfproto::Material *protomaterial = protomap.add_inorganic_material();
protomaterial->set_index(i);
protomaterial->set_name(world->raws.inorganics[i]->id);
}
for (size_t i = 0; i < world->raws.plants.all.size(); i++)
{
dfproto::Material *protomaterial = protomap.add_organic_material();
protomaterial->set_index(i);
protomaterial->set_name(world->raws.plants.all[i]->id);
}
std::map<df::coord,std::pair<uint32_t,uint16_t> > constructionMaterials;
if (Constructions::isValid())
{
for (uint32_t i = 0; i < Constructions::getCount(); i++)
{
df::construction *construction = Constructions::getConstruction(i);
constructionMaterials[construction->pos] = std::make_pair(construction->mat_index, construction->mat_type);
}
}
coded_output->WriteVarint32(protomap.ByteSize());
protomap.SerializeToCodedStream(coded_output);
DFHack::t_feature blockFeatureGlobal;
DFHack::t_feature blockFeatureLocal;
out.print("Writing map block information");
for(uint32_t z = 0; z < z_max; z++)
{
for(uint32_t b_y = 0; b_y < y_max; b_y++)
{
for(uint32_t b_x = 0; b_x < x_max; b_x++)
{
if (b_x == 0 && b_y == 0 && z % 10 == 0) out.print(".");
// Get the map block
df::coord2d blockCoord(b_x, b_y);
MapExtras::Block *b = map.BlockAt(DFHack::DFCoord(b_x, b_y, z));
if (!b || !b->valid)
{
continue;
}
dfproto::Block protoblock;
protoblock.set_x(b_x);
protoblock.set_y(b_y);
protoblock.set_z(z);
{ // Find features
uint32_t index = b->raw.global_feature;
if (index != -1)
Maps::GetGlobalFeature(blockFeatureGlobal, index);
index = b->raw.local_feature;
if (index != -1)
Maps::GetLocalFeature(blockFeatureLocal, blockCoord, index);
}
int global_z = df::global::world->map.region_z + z;
// Iterate over all the tiles in the block
for(uint32_t y = 0; y < 16; y++)
{
for(uint32_t x = 0; x < 16; x++)
{
df::coord2d coord(x, y);
df::tile_designation des = b->DesignationAt(coord);
df::tile_occupancy occ = b->OccupancyAt(coord);
// Skip hidden tiles
if (!showHidden && des.bits.hidden)
{
continue;
}
dfproto::Tile *prototile = protoblock.add_tile();
prototile->set_x(x);
prototile->set_y(y);
// Check for liquid
if (des.bits.flow_size)
{
prototile->set_liquid_type((dfproto::Tile::LiquidType)des.bits.liquid_type);
prototile->set_flow_size(des.bits.flow_size);
}
df::tiletype type = b->TileTypeAt(coord);
prototile->set_type((dfproto::Tile::TileType)tileShape(type));
prototile->set_tile_material((dfproto::Tile::TileMaterialType)tileMaterial(type));
df::coord map_pos = df::coord(b_x*16+x,b_y*16+y,z);
switch (tileMaterial(type))
{
case tiletype_material::SOIL:
case tiletype_material::STONE:
prototile->set_material_type(0);
prototile->set_material_index(b->baseMaterialAt(coord));
break;
case tiletype_material::MINERAL:
prototile->set_material_type(0);
prototile->set_material_index(b->veinMaterialAt(coord));
break;
case tiletype_material::FEATURE:
if (blockFeatureLocal.type != -1 && des.bits.feature_local)
{
if (blockFeatureLocal.type == feature_type::deep_special_tube
&& blockFeatureLocal.main_material == 0) // stone
{
prototile->set_material_type(0);
prototile->set_material_index(blockFeatureLocal.sub_material);
}
if (blockFeatureGlobal.type != -1 && des.bits.feature_global
&& blockFeatureGlobal.type == feature_type::feature_underworld_from_layer
&& blockFeatureGlobal.main_material == 0) // stone
{
prototile->set_material_type(0);
prototile->set_material_index(blockFeatureGlobal.sub_material);
}
}
break;
case tiletype_material::CONSTRUCTION:
if (constructionMaterials.find(map_pos) != constructionMaterials.end())
{
prototile->set_material_index(constructionMaterials[map_pos].first);
prototile->set_material_type(constructionMaterials[map_pos].second);
}
break;
default:
break;
}
}
}
PlantList *plants;
if (Maps::ReadVegetation(b_x, b_y, z, plants))
{
for (PlantList::const_iterator it = plants->begin(); it != plants->end(); it++)
{
const df::plant & plant = *(*it);
df::coord2d loc(plant.pos.x, plant.pos.y);
loc = loc % 16;
if (showHidden || !b->DesignationAt(loc).bits.hidden)
{
dfproto::Plant *protoplant = protoblock.add_plant();
protoplant->set_x(loc.x);
protoplant->set_y(loc.y);
protoplant->set_is_shrub(plant.flags.bits.is_shrub);
protoplant->set_material(plant.material);
}
}
}
coded_output->WriteVarint32(protoblock.ByteSize());
protoblock.SerializeToCodedStream(coded_output);
} // block x
// Clean uneeded memory
map.trash();
} // block y
} // z
delete coded_output;
delete zip_output;
delete raw_output;
mats->Finish();
out.print("\nMap succesfully exported!\n");
return CR_OK;
}
command_result prospector (color_ostream &con, vector <string> & parameters)
{
bool showHidden = false;
bool showPlants = true;
bool showSlade = true;
bool showTemple = true;
bool showValue = false;
bool showTube = false;
for(size_t i = 0; i < parameters.size();i++)
{
if (parameters[i] == "all")
{
showHidden = true;
}
else if (parameters[i] == "value")
{
showValue = true;
}
else if (parameters[i] == "hell")
{
showHidden = showTube = true;
}
else
return CR_WRONG_USAGE;
}
CoreSuspender suspend;
// Embark screen active: estimate using world geology data
if (VIRTUAL_CAST_VAR(screen, df::viewscreen_choose_start_sitest, Core::getTopViewscreen()))
return embark_prospector(con, screen, showHidden, showValue);
if (!Maps::IsValid())
{
con.printerr("Map is not available!\n");
return CR_FAILURE;
}
uint32_t x_max = 0, y_max = 0, z_max = 0;
Maps::getSize(x_max, y_max, z_max);
MapExtras::MapCache map;
DFHack::Materials *mats = Core::getInstance().getMaterials();
DFHack::t_feature blockFeatureGlobal;
DFHack::t_feature blockFeatureLocal;
bool hasAquifer = false;
bool hasDemonTemple = false;
bool hasLair = false;
MatMap baseMats;
MatMap layerMats;
MatMap veinMats;
MatMap plantMats;
MatMap treeMats;
matdata liquidWater;
matdata liquidMagma;
matdata aquiferTiles;
matdata tubeTiles;
uint32_t vegCount = 0;
for(uint32_t z = 0; z < z_max; z++)
{
for(uint32_t b_y = 0; b_y < y_max; b_y++)
{
for(uint32_t b_x = 0; b_x < x_max; b_x++)
{
// Get the map block
df::coord2d blockCoord(b_x, b_y);
MapExtras::Block *b = map.BlockAt(DFHack::DFCoord(b_x, b_y, z));
if (!b || !b->is_valid())
{
continue;
}
// Find features
b->GetGlobalFeature(&blockFeatureGlobal);
b->GetLocalFeature(&blockFeatureLocal);
int global_z = world->map.region_z + z;
// Iterate over all the tiles in the block
for(uint32_t y = 0; y < 16; y++)
{
for(uint32_t x = 0; x < 16; x++)
{
df::coord2d coord(x, y);
df::tile_designation des = b->DesignationAt(coord);
df::tile_occupancy occ = b->OccupancyAt(coord);
// Skip hidden tiles
if (!showHidden && des.bits.hidden)
{
continue;
}
// Check for aquifer
if (des.bits.water_table)
{
hasAquifer = true;
aquiferTiles.add(global_z);
}
// Check for lairs
if (occ.bits.monster_lair)
{
hasLair = true;
}
// Check for liquid
if (des.bits.flow_size)
{
if (des.bits.liquid_type == tile_liquid::Magma)
liquidMagma.add(global_z);
else
liquidWater.add(global_z);
}
df::tiletype type = b->tiletypeAt(coord);
df::tiletype_shape tileshape = tileShape(type);
df::tiletype_material tilemat = tileMaterial(type);
// We only care about these types
switch (tileshape)
{
case tiletype_shape::WALL:
case tiletype_shape::FORTIFICATION:
break;
case tiletype_shape::EMPTY:
/* A heuristic: tubes inside adamantine have EMPTY:AIR tiles which
still have feature_local set. Also check the unrevealed status,
so as to exclude any holes mined by the player. */
if (tilemat == tiletype_material::AIR &&
des.bits.feature_local && des.bits.hidden &&
blockFeatureLocal.type == feature_type::deep_special_tube)
{
tubeTiles.add(global_z);
}
default:
continue;
}
// Count the material type
baseMats[tilemat].add(global_z);
// Find the type of the tile
switch (tilemat)
{
case tiletype_material::SOIL:
case tiletype_material::STONE:
layerMats[b->layerMaterialAt(coord)].add(global_z);
break;
case tiletype_material::MINERAL:
veinMats[b->veinMaterialAt(coord)].add(global_z);
break;
case tiletype_material::FEATURE:
if (blockFeatureLocal.type != -1 && des.bits.feature_local)
{
if (blockFeatureLocal.type == feature_type::deep_special_tube
&& blockFeatureLocal.main_material == 0) // stone
{
veinMats[blockFeatureLocal.sub_material].add(global_z);
}
else if (showTemple
&& blockFeatureLocal.type == feature_type::deep_surface_portal)
{
hasDemonTemple = true;
}
}
if (showSlade && blockFeatureGlobal.type != -1 && des.bits.feature_global
&& blockFeatureGlobal.type == feature_type::feature_underworld_from_layer
&& blockFeatureGlobal.main_material == 0) // stone
{
layerMats[blockFeatureGlobal.sub_material].add(global_z);
}
break;
case tiletype_material::LAVA_STONE:
// TODO ?
break;
default:
break;
}
}
}
// Check plants this way, as the other way wasn't getting them all
// and we can check visibility more easily here
if (showPlants)
{
auto block = Maps::getBlockColumn(b_x,b_y);
vector<df::plant *> *plants = block ? &block->plants : NULL;
if(plants)
{
for (PlantList::const_iterator it = plants->begin(); it != plants->end(); it++)
{
const df::plant & plant = *(*it);
if (plant.pos.z != z)
continue;
df::coord2d loc(plant.pos.x, plant.pos.y);
loc = loc % 16;
if (showHidden || !b->DesignationAt(loc).bits.hidden)
{
if(plant.flags.bits.is_shrub)
plantMats[plant.material].add(global_z);
else
treeMats[plant.material].add(global_z);
}
}
}
}
// Block end
} // block x
// Clean uneeded memory
map.trash();
} // block y
} // z
MatMap::const_iterator it;
con << "Base materials:" << std::endl;
for (it = baseMats.begin(); it != baseMats.end(); ++it)
{
con << std::setw(25) << ENUM_KEY_STR(tiletype_material,(df::tiletype_material)it->first) << " : " << it->second.count << std::endl;
}
if (liquidWater.count || liquidMagma.count)
{
con << std::endl << "Liquids:" << std::endl;
if (liquidWater.count)
{
con << std::setw(25) << "WATER" << " : ";
printMatdata(con, liquidWater);
}
if (liquidWater.count)
{
con << std::setw(25) << "MAGMA" << " : ";
printMatdata(con, liquidMagma);
}
}
con << std::endl << "Layer materials:" << std::endl;
printMats<df::inorganic_raw, shallower>(con, layerMats, world->raws.inorganics, showValue);
printVeins(con, veinMats, mats, showValue);
if (showPlants)
{
con << "Shrubs:" << std::endl;
printMats<df::plant_raw, std::greater>(con, plantMats, world->raws.plants.all, showValue);
con << "Wood in trees:" << std::endl;
printMats<df::plant_raw, std::greater>(con, treeMats, world->raws.plants.all, showValue);
}
if (hasAquifer)
{
con << "Has aquifer";
if (aquiferTiles.count)
{
con << " : ";
printMatdata(con, aquiferTiles);
}
else
con << std::endl;
}
if (showTube && tubeTiles.count)
{
con << "Has HFS tubes : ";
printMatdata(con, tubeTiles);
}
if (hasDemonTemple)
{
con << "Has demon temple" << std::endl;
}
if (hasLair)
{
con << "Has lair" << std::endl;
}
// Cleanup
mats->Finish();
con << std::endl;
return CR_OK;
}
bool gather_embark_tile_layer(int EmbX, int EmbY, int EmbZ, EmbarkTileLayer * tile, MapExtras::MapCache * MP)
{
for(int i = tile->mat_type_table_size(); i < 2304; i++) { //This is needed so we have a full array to work with, otherwise the size isn't updated correctly.
tile->add_mat_type_table(AIR);
tile->add_mat_subtype_table(0);
}
int num_valid_blocks = 0;
for(int yy = 0; yy < 3; yy++) {
for(int xx = 0; xx < 3; xx++) {
DFCoord current_coord, upper_coord;
current_coord.x = EmbX+xx;
current_coord.y = EmbY+yy;
current_coord.z = EmbZ;
upper_coord = current_coord;
upper_coord.z += 1;
MapExtras::Block * b = MP->BlockAt(current_coord);
MapExtras::Block * b_upper = MP->BlockAt(upper_coord);
if(b && b->getRaw()) {
for(int block_y=0; block_y<16; block_y++) {
for(int block_x=0; block_x<16; block_x++) {
df::coord2d block_coord;
block_coord.x = block_x;
block_coord.y = block_y;
df::tiletype tile_type = b->tiletypeAt(block_coord);
df::tiletype upper_tile = df::tiletype::Void;
if(b_upper && b_upper->getRaw()) {
upper_tile = b_upper->tiletypeAt(block_coord);
}
df::tile_designation designation = b->DesignationAt(block_coord);
DFHack::t_matpair actual_mat;
if(tileShapeBasic(tileShape(upper_tile)) == tiletype_shape_basic::Floor && (tileMaterial(tile_type) != tiletype_material::FROZEN_LIQUID) && (tileMaterial(tile_type) != tiletype_material::BROOK)) { //if the upper tile is a floor, use that material instead. Unless it's ice.
actual_mat = b_upper->staticMaterialAt(block_coord);
}
else {
actual_mat = b->staticMaterialAt(block_coord);
}
if(((tileMaterial(tile_type) == tiletype_material::FROZEN_LIQUID) || (tileMaterial(tile_type) == tiletype_material::BROOK)) && (tileShapeBasic(tileShape(tile_type)) == tiletype_shape_basic::Floor)) {
tile_type = tiletype::OpenSpace;
}
unsigned int array_index = coord_to_index_48(xx*16+block_x, yy*16+block_y);
//make a new fake material at the given index
if(tileMaterial(tile_type) == tiletype_material::FROZEN_LIQUID && !((tileShapeBasic(tileShape(upper_tile)) == tiletype_shape_basic::Floor) && (tileMaterial(upper_tile) != tiletype_material::FROZEN_LIQUID))) { //Ice.
tile->set_mat_type_table(array_index, BasicMaterial::LIQUID); //Ice is totally a liquid, shut up.
tile->set_mat_subtype_table(array_index, LiquidType::ICE);
num_valid_blocks++;
}
else if(designation.bits.flow_size && (tileShapeBasic(tileShape(upper_tile)) != tiletype_shape_basic::Floor)) { //Contains either water or lava.
tile->set_mat_type_table(array_index, BasicMaterial::LIQUID);
if(designation.bits.liquid_type) //Magma
tile->set_mat_subtype_table(array_index, LiquidType::MAGMA);
else //water
tile->set_mat_subtype_table(array_index, LiquidType::WATER);
num_valid_blocks++;
}
else if(((tileShapeBasic(tileShape(tile_type)) != tiletype_shape_basic::Open) ||
(tileShapeBasic(tileShape(upper_tile)) == tiletype_shape_basic::Floor)) &&
((tileShapeBasic(tileShape(tile_type)) != tiletype_shape_basic::Floor) ||
(tileShapeBasic(tileShape(upper_tile)) == tiletype_shape_basic::Floor))) { //if the upper tile is a floor, we don't skip, otherwise we do.
if(actual_mat.mat_type == builtin_mats::INORGANIC) { //inorganic
tile->set_mat_type_table(array_index, BasicMaterial::INORGANIC);
tile->set_mat_subtype_table(array_index, actual_mat.mat_index);
}
else if(actual_mat.mat_type == 419) { //Growing plants
tile->set_mat_type_table(array_index, BasicMaterial::PLANT);
tile->set_mat_subtype_table(array_index, actual_mat.mat_index);
}
else if(actual_mat.mat_type >= 420) { //Wooden constructions. Different from growing plants.
tile->set_mat_type_table(array_index, BasicMaterial::WOOD);
tile->set_mat_subtype_table(array_index, actual_mat.mat_index);
}
else { //Unknown and unsupported stuff. Will just be drawn as grey.
tile->set_mat_type_table(array_index, BasicMaterial::OTHER);
tile->set_mat_subtype_table(array_index, actual_mat.mat_type);
}
num_valid_blocks++;
}
else {
tile->set_mat_type_table(array_index, BasicMaterial::AIR);
}
}
}
}
}
}
return (num_valid_blocks >0);
}
