dfhack/plugins/stockpiles.cpp

1033 lines
44 KiB
C++

2011-12-31 04:48:42 -07:00
#include "Core.h"
#include "Console.h"
#include "Export.h"
#include "PluginManager.h"
#include "MiscUtils.h"
#include "modules/Materials.h"
#include "modules/Items.h"
#include "DataDefs.h"
#include "df/world.h"
#include "df/world_data.h"
#include "df/inorganic_raw.h"
#include "df/organic_mat_category.h"
#include "df/furniture_type.h"
#include "df/item_quality.h"
#include "df/item_type.h"
#include "df/creature_raw.h"
#include "df/caste_raw.h"
#include "df/material.h"
#include "df/inorganic_raw.h"
#include "df/plant_raw.h"
#include "df/stockpile_group_set.h"
#include "df/ui.h"
#include "df/building_stockpilest.h"
#include "df/global_objects.h"
#include "df/viewscreen_dwarfmodest.h"
#include <df/itemdef_ammost.h>
#include "stockpiles.pb.h"
#include <google/protobuf/text_format.h>
#include <functional>
using std::vector;
using std::string;
using std::endl;
using namespace DFHack;
using namespace df::enums;
using namespace google::protobuf;
using namespace dfstockpiles;
using df::global::world;
using df::global::ui;
using df::global::selection_rect;
using df::building_stockpilest;
static command_result copystock ( color_ostream &out, vector <string> & parameters );
static bool copystock_guard ( df::viewscreen *top );
static command_result savestock ( color_ostream &out, vector <string> & parameters );
static bool savestock_guard ( df::viewscreen *top );
DFHACK_PLUGIN ( "stockpiles" );
DFhackCExport command_result plugin_init ( color_ostream &out, std::vector <PluginCommand> &commands )
{
if ( world && ui ) {
commands.push_back (
PluginCommand (
"copystock", "Copy stockpile under cursor.",
copystock, copystock_guard,
" - In 'q' or 't' mode: select a stockpile and invoke in order\n"
" to switch to the 'p' stockpile creation mode, and initialize\n"
" the custom settings from the selected stockpile.\n"
" - In 'p': invoke in order to switch back to 'q'.\n"
)
);
commands.push_back (
PluginCommand (
"savestock", "Export the stockpile under cursor.",
savestock, savestock_guard,
" - In 'q' or 't' mode: select a stockpile and invoke in order\n"
" to switch to the 'p' stockpile creation mode, and initialize\n"
" the custom settings from the selected stockpile.\n"
" - In 'p': invoke in order to switch back to 'q'.\n"
)
);
}
std::cerr << "world: " << sizeof ( df::world ) << " ui: " << sizeof ( df::ui )
<< " b_stock: " << sizeof ( building_stockpilest ) << endl;
return CR_OK;
}
DFhackCExport command_result plugin_shutdown ( color_ostream &out )
{
return CR_OK;
}
static bool copystock_guard ( df::viewscreen *top )
{
using namespace ui_sidebar_mode;
if ( !Gui::dwarfmode_hotkey ( top ) )
return false;
switch ( ui->main.mode ) {
case Stockpiles:
return true;
case BuildingItems:
case QueryBuilding:
return !!virtual_cast<building_stockpilest> ( world->selected_building );
default:
return false;
}
}
static command_result copystock ( color_ostream &out, vector <string> & parameters )
{
// HOTKEY COMMAND: CORE ALREADY SUSPENDED
// For convenience: when used in the stockpiles mode, switch to 'q'
if ( ui->main.mode == ui_sidebar_mode::Stockpiles ) {
world->selected_building = NULL; // just in case it contains some kind of garbage
ui->main.mode = ui_sidebar_mode::QueryBuilding;
selection_rect->start_x = -30000;
out << "Switched back to query building." << endl;
return CR_OK;
}
building_stockpilest *sp = virtual_cast<building_stockpilest> ( world->selected_building );
if ( !sp ) {
out.printerr ( "Selected building isn't a stockpile.\n" );
return CR_WRONG_USAGE;
}
ui->stockpile.custom_settings = sp->settings;
ui->main.mode = ui_sidebar_mode::Stockpiles;
world->selected_stockpile_type = stockpile_category::Custom;
out << "Stockpile options copied." << endl;
return CR_OK;
}
static bool savestock_guard ( df::viewscreen *top )
{
using namespace ui_sidebar_mode;
if ( !Gui::dwarfmode_hotkey ( top ) )
return false;
switch ( ui->main.mode ) {
case Stockpiles:
return true;
case BuildingItems:
case QueryBuilding:
return !!virtual_cast<building_stockpilest> ( world->selected_building );
default:
return false;
}
}
/**
* Retrieve creature raw from index
*/
static df::creature_raw* find_creature ( int32_t idx )
{
return world->raws.creatures.all[idx];
}
/**
* Retrieve creature index from id string
*/
static int16_t find_creature ( const std::string &creature_id )
{
return linear_index ( world->raws.creatures.all, &df::creature_raw::creature_id, creature_id );
}
typedef std::pair<int16_t, int32_t> FoodMatPair;
typedef std::map<FoodMatPair, size_t> FoodMatMap;
/**
* Helper class for performing organic_index/organic_types <---> material array index lookups
*/
class FoodLookup
{
public:
struct FoodMat {
MaterialInfo material;
df::creature_raw *creature;
df::caste_raw * caste;
FoodMat() : material ( -1 ), creature ( 0 ), caste ( 0 ) {}
};
static void food_mat_by_idx ( color_ostream &out, organic_mat_category::organic_mat_category mat_category, std::vector<int16_t>::size_type food_idx, FoodMat & food_mat ) {
out << "food_lookup: food_idx(" << food_idx << ") ";
df::world_raws &raws = world->raws;
df::special_mat_table table = raws.mat_table;
int32_t main_idx = table.organic_indexes[mat_category][food_idx];
int16_t type = table.organic_types[mat_category][food_idx];
if ( mat_category == organic_mat_category::Fish ||
mat_category == organic_mat_category::UnpreparedFish ||
mat_category == organic_mat_category::Eggs ) {
food_mat.creature = raws.creatures.all[type];
food_mat.caste = food_mat.creature->caste[main_idx];
out << " special creature type(" << type << ") caste("<< main_idx <<")" <<endl;
} else {
food_mat.material.decode ( type, main_idx );
out << " type(" << type << ") index("<< main_idx <<")" <<endl;
}
}
static std::string food_token_by_idx ( color_ostream &out, organic_mat_category::organic_mat_category mat_category, std::vector<int16_t>::size_type idx ) {
FoodMat food_mat;
food_mat_by_idx ( out, mat_category, idx, food_mat );
if ( food_mat.material.isValid() ) {
return food_mat.material.getToken();
} else if ( food_mat.creature ) {
return food_mat.creature->creature_id + ":" + food_mat.caste->caste_id;
}
return std::string();
}
static void food_build_map ( color_ostream &out ) {
if ( index_built )
return;
df::world_raws &raws = world->raws;
df::special_mat_table table = raws.mat_table;
using df::enums::organic_mat_category::organic_mat_category;
df::enum_traits<organic_mat_category> traits;
for ( int32_t mat_category = traits.first_item_value; mat_category <traits.last_item_value; ++mat_category ) {
for ( size_t i = 0; i < table.organic_indexes[mat_category].size(); ++i ) {
int16_t type = table.organic_types[mat_category].at ( i );
int32_t index = table.organic_indexes[mat_category].at ( i );
food_index[mat_category].insert ( std::make_pair ( std::make_pair ( type,index ), i ) ); // wtf.. only in c++
}
}
index_built = true;
}
static int food_idx_by_token ( color_ostream &out, organic_mat_category::organic_mat_category mat_category, const std::string & token ) {
int16_t food_idx = -1;
df::world_raws &raws = world->raws;
df::special_mat_table table = raws.mat_table;
out << "food_idx_by_token: ";
if ( mat_category == organic_mat_category::Fish ||
mat_category == organic_mat_category::UnpreparedFish ||
mat_category == organic_mat_category::Eggs ) {
std::vector<string> tokens;
split_string ( &tokens, token, ":" );
if ( tokens.size() != 2 ) {
out << "creature " << "invalid CREATURE:CASTE token: " << token << endl;
} else {
int16_t creature_idx = find_creature ( tokens[0] );
if ( creature_idx >= 0 ) {
food_idx = linear_index ( table.organic_types[mat_category], creature_idx );
out << "creature " << token << " creature_idx(" << creature_idx << ") food_idx("<< food_idx << ")" << endl;
} else out << " creature invalid token " << tokens[0];
}
} else {
if ( !index_built ) {
food_build_map ( out );
}
MaterialInfo mat_info = food_mat_by_token ( out, mat_category, token );
int16_t type = mat_info.type;
int32_t index = mat_info.index;
int16_t food_idx2 = -1;
auto it = food_index[mat_category].find ( std::make_pair ( type, index ) );
if ( it != food_index[mat_category].end() ) {
out << "matinfo: " << token << " type(" << mat_info.type << ") idx(" << mat_info.index << ") food_idx(" << it->second << ")" << endl;
} else {
out << "matinfo: " << token << " type(" << mat_info.type << ") idx(" << mat_info.index << ") food_idx not found :(";
}
}
return food_idx;
}
static MaterialInfo food_mat_by_token ( color_ostream &out, organic_mat_category::organic_mat_category mat_category, const std::string & token ) {
MaterialInfo mat_info;
mat_info.find ( token );
return mat_info;
}
static bool index_built;
static std::vector<FoodMatMap> food_index;
private:
FoodLookup() {}
};
bool FoodLookup::index_built = false;
std::vector<FoodMatMap> FoodLookup::food_index = std::vector<FoodMatMap> ( 37 );
class StockpileSerializer
{
public:
StockpileSerializer ( color_ostream &out, building_stockpilest const * stockpile )
: mOut ( &out )
, mPile ( stockpile ) {
furniture_setup_other_mats();
}
StockpileSettings write() {
// *mOut << "GROUP SET " << bitfield_to_string(mPile->settings.flags) << endl;
write_general();
if ( mPile->settings.flags.bits.animals )
write_animals();
if ( mPile->settings.flags.bits.food )
write_food();
if ( mPile->settings.flags.bits.furniture )
write_furniture();
if ( mPile->settings.flags.bits.refuse )
write_refuse();
if ( mPile->settings.flags.bits.stone )
write_stone();
if ( mPile->settings.flags.bits.ammo )
write_ammo();
std::string str;
TextFormat::PrintToString ( mBuffer, &str );
*mOut << "serialized: " << str << endl;
return mBuffer;
}
void read ( const StockpileSettings & settings ) {
*mOut << endl << "==READ==" << endl;
mBuffer = settings;
read_general();
read_animals();
read_food();
read_furniture();
read_refuse();
read_stone();
read_ammo();
}
~StockpileSerializer() {}
private:
color_ostream * mOut;
building_stockpilest const * mPile;
StockpileSettings mBuffer;
std::map<int, std::string> mOtherMats;;
/**
* Find an enum's value based off the string label.
* @param traits the enum's trait struct
* @param token the string value in key_table
* @return the enum's value
*/
template<typename E>
static typename df::enum_traits<E>::base_type linear_index ( color_ostream& out, df::enum_traits<E> traits, const std::string &token ) {
auto j = traits.first_item_value;
auto limit = traits.last_item_value;
// sometimes enums start at -1, which is bad news for array indexing
if ( j < 0 ) {
j += abs ( traits.first_item_value );
limit += abs ( traits.first_item_value );
}
for ( ; j <= limit; ++j ) {
// out << " linear_index("<< token <<") = table["<<j<<"/"<<limit<<"]: " <<traits.key_table[j] << endl;
if ( token.compare ( traits.key_table[j] ) == 0 )
return j;
}
return -1;
}
void write_general() {
mBuffer.set_max_bins ( mPile->max_barrels );
mBuffer.set_max_wheelbarrows ( mPile->max_wheelbarrows );
mBuffer.set_use_links_only ( mPile->use_links_only );
mBuffer.set_unknown1 ( mPile->settings.unk1 );
*mOut << "unknown is " << mPile->settings.unk1 << endl;
}
void read_general() {
int bins = mBuffer.max_bins();
*mOut << "Max bins: " << bins <<endl;
}
void write_animals() {
dfstockpiles::StockpileSettings::AnimalsSet animals;
animals.set_empty_cages ( mPile->settings.animals.empty_cages );
animals.set_empty_traps ( mPile->settings.animals.empty_traps );
for ( size_t i = 0; i < mPile->settings.animals.enabled.size(); ++i ) {
if ( mPile->settings.animals.enabled.at ( i ) == 1 ) {
df::creature_raw* r = find_creature ( i );
*mOut << "creature "<< r->creature_id << " " << i << endl;
mBuffer.mutable_animals()->add_enabled ( r->creature_id );
}
}
}
void read_animals() {
if ( mBuffer.has_animals() ) {
// mPile->settings.flags.bits.animals = true;
*mOut << "animals:" <<endl;
mBuffer.animals().empty_cages();
mBuffer.animals().empty_traps();
if ( mBuffer.animals().enabled_size() > 0 ) {
for ( auto i = 0; i < mBuffer.animals().enabled().size(); ++i ) {
std::string id = mBuffer.animals().enabled ( i );
int idx = find_creature ( id );
*mOut << id << " " << idx << endl;
}
}
}
}
typedef std::function<std::string ( const size_t& ) > FoodImportFunc;
typedef std::function<void ( const string & ) > FoodExportFunc;
struct food_pair {
// exporting
FoodExportFunc set_value;
vector<char> stockpile_values;
// importing
FoodImportFunc get_value;
size_t serialized_count;
food_pair ( FoodExportFunc s, const vector<char>& sp_v, FoodImportFunc g, size_t count )
: set_value ( s )
, stockpile_values ( sp_v )
, get_value ( g )
,serialized_count ( count )
{}
food_pair() {}
};
food_pair food_map ( organic_mat_category::organic_mat_category cat ) {
using df::enums::organic_mat_category::organic_mat_category;
using namespace std::placeholders;
switch ( cat ) {
case organic_mat_category::Meat: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_meat ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().meat ( idx ); };
return food_pair ( setter, mPile->settings.food.meat, getter, mBuffer.food().meat_size() );
}
case organic_mat_category::Fish: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_fish ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().fish ( idx ); };
return food_pair ( setter, mPile->settings.food.fish, getter, mBuffer.food().fish_size() );
}
case organic_mat_category::UnpreparedFish: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_unprepared_fish ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().unprepared_fish ( idx ); };
return food_pair ( setter, mPile->settings.food.unprepared_fish, getter, mBuffer.food().unprepared_fish_size() );
}
case organic_mat_category::Eggs: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_egg ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().egg ( idx ); };
return food_pair ( setter, mPile->settings.food.egg, getter, mBuffer.food().egg_size() );
}
case organic_mat_category::Plants: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_plants ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().plants ( idx ); };
return food_pair ( setter, mPile->settings.food.plants, getter, mBuffer.food().plants_size() );
}
case organic_mat_category::PlantDrink: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_drink_plant ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().drink_plant ( idx ); };
return food_pair ( setter, mPile->settings.food.drink_plant, getter, mBuffer.food().drink_plant_size() );
}
case organic_mat_category::CreatureDrink: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_drink_animal ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().drink_animal ( idx ); };
return food_pair ( setter, mPile->settings.food.drink_animal, getter, mBuffer.food().drink_animal_size() );
}
case organic_mat_category::PlantCheese: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_cheese_plant ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().cheese_plant ( idx ); };
return food_pair ( setter, mPile->settings.food.cheese_plant, getter, mBuffer.food().cheese_plant_size() );
}
case organic_mat_category::CreatureCheese: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_cheese_animal ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().cheese_animal ( idx ); };
return food_pair ( setter, mPile->settings.food.cheese_animal, getter, mBuffer.food().cheese_animal_size() );
}
case organic_mat_category::Seed: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_seeds ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().seeds ( idx ); };
return food_pair ( setter, mPile->settings.food.seeds, getter, mBuffer.food().seeds_size() );
}
case organic_mat_category::Leaf: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_leaves ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().leaves ( idx ); };
return food_pair ( setter, mPile->settings.food.leaves, getter, mBuffer.food().leaves_size() );
}
case organic_mat_category::PlantPowder: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_powder_plant ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().powder_plant ( idx ); };
return food_pair ( setter, mPile->settings.food.powder_plant, getter, mBuffer.food().powder_plant_size() );
}
case organic_mat_category::CreaturePowder: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_powder_creature ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().powder_creature ( idx ); };
return food_pair ( setter, mPile->settings.food.powder_creature, getter, mBuffer.food().powder_creature_size() );
}
case organic_mat_category::Glob: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_glob ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().glob ( idx ); };
return food_pair ( setter, mPile->settings.food.glob, getter, mBuffer.food().glob_size() );
}
case organic_mat_category::PlantLiquid: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_liquid_plant ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().liquid_plant ( idx ); };
return food_pair ( setter, mPile->settings.food.liquid_plant, getter, mBuffer.food().liquid_plant_size() );
}
case organic_mat_category::CreatureLiquid: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_liquid_animal ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().liquid_animal ( idx ); };
return food_pair ( setter, mPile->settings.food.liquid_animal, getter, mBuffer.food().liquid_animal_size() );
}
case organic_mat_category::MiscLiquid: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_liquid_misc ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().liquid_misc ( idx ); };
return food_pair ( setter, mPile->settings.food.liquid_misc, getter, mBuffer.food().liquid_misc_size() );
}
case organic_mat_category::Paste: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_glob_paste ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().glob_paste ( idx ); };
return food_pair ( setter, mPile->settings.food.glob_paste, getter, mBuffer.food().glob_paste_size() );
}
case organic_mat_category::Pressed: {
auto setter = [=] ( const std::string &id ) {
mBuffer.mutable_food()->add_glob_pressed ( id );
};
auto getter = [=] ( size_t idx ) -> std::string { return mBuffer.food().glob_pressed ( idx ); };
return food_pair ( setter, mPile->settings.food.glob_pressed, getter, mBuffer.food().glob_pressed_size() );
}
case organic_mat_category::Leather:
case organic_mat_category::Silk:
case organic_mat_category::PlantFiber:
case organic_mat_category::Bone:
case organic_mat_category::Shell:
case organic_mat_category::Wood:
case organic_mat_category::Horn:
case organic_mat_category::Pearl:
case organic_mat_category::Tooth:
case organic_mat_category::EdibleCheese:
case organic_mat_category::AnyDrink:
case organic_mat_category::EdiblePlant:
case organic_mat_category::CookableLiquid:
case organic_mat_category::CookablePowder:
case organic_mat_category::CookableSeed:
case organic_mat_category::CookableLeaf:
case organic_mat_category::Yarn:
case organic_mat_category::MetalThread:
// not used in stockpile food menu
break;
}
return food_pair();
}
void food_write_helper ( std::function<void ( const string & ) > add_value, const vector<char> & list, organic_mat_category::organic_mat_category cat ) {
for ( size_t i = 0; i < list.size(); ++i ) {
if ( list.at ( i ) ) {
std::string token = FoodLookup::food_token_by_idx ( *mOut, cat, i );
if ( !token.empty() ) {
add_value ( token );
} else {
*mOut << "food mat invalid :(" << endl;
}
}
}
}
void write_food() {
StockpileSettings::FoodSet *food = mBuffer.mutable_food();
food->set_prepared_meals ( mPile->settings.food.prepared_meals );
food_pair p = food_map ( organic_mat_category::Meat );
food_write_helper ( p.set_value, p.stockpile_values, organic_mat_category::Meat );
using df::enums::organic_mat_category::organic_mat_category;
df::enum_traits<organic_mat_category> traits;
for ( int32_t mat_category = traits.first_item_value; mat_category <traits.last_item_value; ++mat_category ) {
food_pair p = food_map ( ( organic_mat_category ) mat_category );
food_write_helper ( p.set_value, p.stockpile_values, ( organic_mat_category ) mat_category );
}
}
void food_read_helper ( std::function<std::string ( const size_t& ) > get_value, size_t list_size, organic_mat_category::organic_mat_category cat ) {
if ( list_size > 0 ) {
for ( size_t i = 0; i < list_size; ++i ) {
std::string token = get_value ( i );
int idx = FoodLookup::food_idx_by_token ( *mOut, cat, token );
//mPile->settings.food.meat.at(idx) = (char) 1;
}
}
}
void read_food() {
if ( mBuffer.has_food() ) {
const StockpileSettings::FoodSet food = mBuffer.food();
*mOut << "food:" <<endl;
using df::enums::organic_mat_category::organic_mat_category;
df::enum_traits<organic_mat_category> traits;
for ( int32_t mat_category = traits.first_item_value; mat_category <traits.last_item_value; ++mat_category ) {
food_pair p = food_map ( ( organic_mat_category ) mat_category );
food_read_helper ( p.get_value, p.serialized_count, ( organic_mat_category ) mat_category );
}
}
}
void furniture_setup_other_mats() {
mOtherMats.insert ( std::make_pair ( 0,"WOOD" ) );
mOtherMats.insert ( std::make_pair ( 1,"PLANT_CLOTH" ) );
mOtherMats.insert ( std::make_pair ( 2,"BONE" ) );
mOtherMats.insert ( std::make_pair ( 3,"TOOTH" ) );
mOtherMats.insert ( std::make_pair ( 4,"HORN" ) );
mOtherMats.insert ( std::make_pair ( 5,"PEARL" ) );
mOtherMats.insert ( std::make_pair ( 6,"SHELL" ) );
mOtherMats.insert ( std::make_pair ( 7,"LEATHER" ) );
mOtherMats.insert ( std::make_pair ( 8,"SILK" ) );
mOtherMats.insert ( std::make_pair ( 9,"AMBER" ) );
mOtherMats.insert ( std::make_pair ( 10,"CORAL" ) );
mOtherMats.insert ( std::make_pair ( 11,"GREEN_GLASS" ) );
mOtherMats.insert ( std::make_pair ( 12,"CLEAR_GLASS" ) );
mOtherMats.insert ( std::make_pair ( 13,"CRYSTAL_GLASS" ) );
mOtherMats.insert ( std::make_pair ( 14,"YARN" ) );
}
std::string furn_other_mats ( int idx ) {
auto it = mOtherMats.find ( idx );
if ( it == mOtherMats.end() )
return std::string();
return it->second;
}
int furn_other_mats ( const std::string & token ) {
for ( auto it = mOtherMats.begin(); it != mOtherMats.end(); ++it ) {
if ( it->second == token )
return it->first;
}
return -1;
}
void write_furniture() {
StockpileSettings::FurnitureSet *furniture= mBuffer.mutable_furniture();
furniture->set_sand_bags ( mPile->settings.furniture.sand_bags );
// FURNITURE type
using df::enums::furniture_type::furniture_type;
df::enum_traits<furniture_type> type_traits;
for ( size_t i = 0; i < mPile->settings.furniture.type.size(); ++i ) {
if ( mPile->settings.furniture.type.at ( i ) ) {
std::string f_type ( type_traits.key_table[i] );
furniture->add_type ( f_type );
*mOut << "furniture_type " << i << " is " << f_type <<endl;
}
}
// metal, stone/clay materials
MaterialInfo mi;
for ( size_t i = 0; i < mPile->settings.furniture.mats.size(); ++i ) {
if ( mPile->settings.furniture.mats.at ( i ) ) {
mi.decode ( 0, i );
if ( !furniture_mat_is_allowed ( mi ) ) continue;
*mOut << "furniture mat: " << mi.getToken() << endl;
furniture->add_mats ( mi.getToken() );
}
}
// other mats
for ( size_t i = 0; i < mPile->settings.furniture.other_mats.size(); ++i ) {
if ( mPile->settings.furniture.other_mats.at ( i ) ) {
const std::string token = furn_other_mats ( i );
if ( token.empty() ) {
*mOut << " invalid other material with index " << i << endl;
continue;
}
furniture->add_other_mats ( token );
*mOut << " other mats " << i << " is " << token << endl;
}
}
// quality core
using df::enums::item_quality::item_quality;
df::enum_traits<item_quality> quality_traits;
size_t core_size = std::extent< decltype ( mPile->settings.furniture.quality_core ) >::value;
for ( size_t i = 0; i < core_size; ++i ) {
if ( mPile->settings.furniture.quality_core[i] ) {
const std::string f_type ( quality_traits.key_table[i] );
furniture->add_quality_core ( f_type );
*mOut << "quality_core " << i << " is " << f_type <<endl;
}
}
// quality total
size_t total_size = std::extent< decltype ( mPile->settings.furniture.quality_total ) >::value;
for ( size_t i = 0; i < total_size; ++i ) {
if ( mPile->settings.furniture.quality_total[i] ) {
const std::string f_type ( quality_traits.key_table[i] );
furniture->add_quality_total ( f_type );
*mOut << "quality_total " << i << " is " << f_type <<endl;
}
}
}
/* skip gems and non hard things
should be roughly (<range>:<step): 32-158:1,242-262:1,264-282:2,283-310:1
*/
bool furniture_mat_is_allowed ( const MaterialInfo &mi ) {
if ( !mi.isValid() ) return false;
return !mi.material->flags.is_set ( material_flags::IS_GEM ) && mi.material->flags.is_set ( material_flags::ITEMS_HARD );
}
void read_furniture() {
if ( mBuffer.has_furniture() ) {
const StockpileSettings::FurnitureSet furniture = mBuffer.furniture();
*mOut << "furniture:" <<endl;
// type
using df::enums::furniture_type::furniture_type;
df::enum_traits<furniture_type> type_traits;
for ( int i = 0; i < furniture.type_size(); ++i ) {
const std::string type = furniture.type ( i );
df::enum_traits<furniture_type>::base_type idx = linear_index ( *mOut, type_traits, type );
*mOut << " type " << idx << " is " << type << endl;
}
// metal, stone/clay materials
for ( int i = 0; i < furniture.mats_size(); ++i ) {
const std::string token = furniture.mats ( i );
MaterialInfo mi;
mi.find ( token );
if ( !furniture_mat_is_allowed ( mi ) ) continue;
*mOut << " mats " << mi.index << " is " << token << endl;
}
// other materials
for ( int i = 0; i < furniture.other_mats_size(); ++i ) {
const std::string token = furniture.other_mats ( i );
int16_t idx = furn_other_mats ( token );
if ( idx < 0 ) {
*mOut << "invalid other mat with token " << token;
continue;
}
*mOut << " other_mats" << idx << " is " << token << endl;
}
// core quality
using df::enums::item_quality::item_quality;
df::enum_traits<item_quality> quality_traits;
for ( int i = 0; i < furniture.quality_core_size(); ++i ) {
const std::string quality = furniture.quality_core ( i );
df::enum_traits<item_quality>::base_type idx = linear_index ( *mOut, quality_traits, quality );
if ( idx < 0 ) {
*mOut << " invalid quality core token " << quality << endl;
continue;
}
*mOut << " quality_core" << idx << " is " << quality << endl;
}
// total quality
for ( int i = 0; i < furniture.quality_total_size(); ++i ) {
const std::string quality = furniture.quality_total ( i );
df::enum_traits<item_quality>::base_type idx = linear_index ( *mOut, quality_traits, quality );
if ( idx < 0 ) {
*mOut << " invalid quality total token " << quality << endl;
continue;
}
*mOut << " quality_total" << idx << " is " << quality << endl;
}
}
}
bool refuse_creature_is_allowed ( const df::creature_raw *raw ) {
if ( !raw ) return false;
// wagon and generated creatures not allowed, except angels
const bool is_wagon = raw->creature_id == "EQUIPMENT_WAGON";
const bool is_generated = raw->flags.is_set ( creature_raw_flags::GENERATED );
const bool is_angel = is_generated && raw->creature_id.find ( "DIVINE_" ) != std::string::npos;
return !is_wagon && ! ( is_generated && !is_angel );
}
void refuse_write_helper ( std::function<void ( const string & ) > add_value, const vector<char> & list ) {
for ( size_t i = 0; i < list.size(); ++i ) {
if ( list.at ( i ) == 1 ) {
df::creature_raw* r = find_creature ( i );
// skip forgotten beasts, titans, demons, and night creatures
if ( !refuse_creature_is_allowed ( r ) ) continue;
*mOut << "creature "<< r->creature_id << " " << i << endl;
add_value ( r->creature_id );
}
}
}
bool refuse_type_is_allowed ( item_type::item_type type ) {
if ( type == item_type::NONE
|| type == item_type::BAR
|| type == item_type::SMALLGEM
|| type == item_type::BLOCKS
|| type == item_type::ROUGH
|| type == item_type::BOULDER
|| type == item_type::CORPSE
|| type == item_type::CORPSEPIECE
|| type == item_type::ROCK
|| type == item_type::ORTHOPEDIC_CAST
) return false;
return true;
}
void write_refuse() {
StockpileSettings::RefuseSet *refuse = mBuffer.mutable_refuse();
refuse->set_fresh_raw_hide ( mPile->settings.refuse.fresh_raw_hide );
refuse->set_rotten_raw_hide ( mPile->settings.refuse.rotten_raw_hide );
// type
using df::enums::item_type::item_type;
df::enum_traits<item_type> type_traits;
*mOut << "refuse type size = " << mPile->settings.refuse.type.size() << " size limit = " << type_traits.last_item_value << " typecasted: " << ( size_t ) type_traits.last_item_value << endl;
for ( size_t i = 0; i <= ( size_t ) type_traits.last_item_value; ++i ) {
if ( mPile->settings.refuse.type.at ( i ) ) {
const item_type type = ( item_type ) ( ( df::enum_traits<item_type>::base_type ) i );
std::string r_type ( type_traits.key_table[i+1] );
if ( !refuse_type_is_allowed ( type ) ) continue;
refuse->add_type ( r_type );
*mOut << "refuse type key_table[" << i+1 << "] type[" << ( int16_t ) type << "] is " << r_type <<endl;
}
}
// corpses
refuse_write_helper ( [=] ( const std::string &id ) {
refuse->add_corpses ( id );
}, mPile->settings.refuse.corpses );
// body_parts
refuse_write_helper ( [=] ( const std::string &id ) {
refuse->add_body_parts ( id );
}, mPile->settings.refuse.body_parts );
// skulls
refuse_write_helper ( [=] ( const std::string &id ) {
refuse->add_skulls ( id );
}, mPile->settings.refuse.skulls );
// bones
refuse_write_helper ( [=] ( const std::string &id ) {
refuse->add_bones ( id );
}, mPile->settings.refuse.bones );
// hair
refuse_write_helper ( [=] ( const std::string &id ) {
refuse->add_hair ( id );
}, mPile->settings.refuse.hair );
// shells
refuse_write_helper ( [=] ( const std::string &id ) {
refuse->add_shells ( id );
}, mPile->settings.refuse.shells );
// teeth
refuse_write_helper ( [=] ( const std::string &id ) {
refuse->add_teeth ( id );
}, mPile->settings.refuse.teeth );
// horns
refuse_write_helper ( [=] ( const std::string &id ) {
refuse->add_horns ( id );
}, mPile->settings.refuse.horns );
}
void refuse_read_helper ( std::function<std::string ( const size_t& ) > get_value, size_t list_size ) {
if ( list_size > 0 ) {
for ( size_t i = 0; i < list_size; ++i ) {
const std::string creature_id = get_value ( i );
const int idx = find_creature ( creature_id );
const df::creature_raw* creature = find_creature ( idx );
if ( idx < 0 || !refuse_creature_is_allowed ( creature ) ) {
*mOut << "invalid refuse creature: " << creature_id << endl;
continue;
}
*mOut << " creature " << idx << " is " << creature_id << endl;
}
}
}
void read_refuse() {
if ( mBuffer.has_refuse() ) {
const StockpileSettings::RefuseSet refuse = mBuffer.refuse();
*mOut << "refuse: " <<endl;
*mOut << " fresh hide " << refuse.fresh_raw_hide() << endl;
*mOut << " rotten hide " << refuse.rotten_raw_hide() << endl;
// type
using df::enums::item_type::item_type;
df::enum_traits<item_type> type_traits;
for ( int i = 0; i < refuse.type_size(); ++i ) {
const std::string token = refuse.type ( i );
// subtract one because item_type starts at -1
const df::enum_traits<item_type>::base_type idx = linear_index ( *mOut, type_traits, token ) - 1;
const item_type type = (item_type) idx;
if ( !refuse_type_is_allowed(type) ) continue;
*mOut << " type " << idx << " is " << token << endl;
}
// corpses
*mOut << " corpses" << endl;
refuse_read_helper ( [=] ( const size_t & idx ) -> const std::string& {
return refuse.corpses ( idx );
}, refuse.corpses_size() );
// body_parts
*mOut << " body_parts" << endl;
refuse_read_helper ( [=] ( const size_t & idx ) -> const std::string& {
return refuse.body_parts ( idx );
}, refuse.body_parts_size() );
// skulls
*mOut << " skulls" << endl;
refuse_read_helper ( [=] ( const size_t & idx ) -> const std::string& {
return refuse.skulls ( idx );
}, refuse.skulls_size() );
// bones
*mOut << " bones" << endl;
refuse_read_helper ( [=] ( const size_t & idx ) -> const std::string& {
return refuse.bones ( idx );
}, refuse.bones_size() );
// hair
*mOut << " hair" << endl;
refuse_read_helper ( [=] ( const size_t & idx ) -> const std::string& {
return refuse.hair ( idx );
}, refuse.hair_size() );
// shells
*mOut << " shells" << endl;
refuse_read_helper ( [=] ( const size_t & idx ) -> const std::string& {
return refuse.shells ( idx );
}, refuse.shells_size() );
// teeth
*mOut << " teeth" << endl;
refuse_read_helper ( [=] ( const size_t & idx ) -> const std::string& {
return refuse.teeth ( idx );
}, refuse.teeth_size() );
// horns
*mOut << " horns" << endl;
refuse_read_helper ( [=] ( const size_t & idx ) -> const std::string& {
return refuse.horns ( idx );
}, refuse.horns_size() );
}
}
bool stone_is_allowed ( const MaterialInfo &mi ) {
if ( !mi.isValid() ) return false;
const bool is_allowed_soil = mi.inorganic->flags.is_set ( inorganic_flags::SOIL ) && !mi.inorganic->flags.is_set ( inorganic_flags::AQUIFER );
const bool is_allowed_stone = mi.material->flags.is_set ( material_flags::IS_STONE ) && !mi.material->flags.is_set ( material_flags::NO_STONE_STOCKPILE );
return is_allowed_soil || is_allowed_stone;
}
void write_stone() {
StockpileSettings::StoneSet *stone= mBuffer.mutable_stone();
MaterialInfo mi;
for ( size_t i = 0; i < mPile->settings.stone.mats.size(); ++i ) {
if ( mPile->settings.stone.mats.at ( i ) ) {
mi.decode ( 0, i );
if ( !stone_is_allowed ( mi ) ) continue;
*mOut << "stone mat: " << i << " is " << mi.getToken() << endl;
stone->add_mats ( mi.getToken() );
}
}
}
void read_stone() {
if ( mBuffer.has_stone() ) {
const StockpileSettings::StoneSet stone = mBuffer.stone();
*mOut << "stone: " <<endl;
for ( int i = 0; i < stone.mats_size(); ++i ) {
const std::string token = stone.mats ( i );
MaterialInfo mi;
mi.find ( token );
if ( !stone_is_allowed ( mi ) ) continue;
*mOut << " mats " << mi.index << " is " << token << endl;
}
}
}
void write_ammo() {
StockpileSettings::AmmoSet *ammo= mBuffer.mutable_ammo();
for ( size_t i = 0; i < mPile->settings.ammo.type.size(); ++i ) {
if ( mPile->settings.ammo.type.at ( i ) ) {
const df::itemdef_ammost *a = world->raws.itemdefs.ammo.at ( i );
// skip procedurally generated ammo
if ( a->base_flags.is_set ( 0 ) ) continue;
ItemTypeInfo ii;
// ii.decode(item_type::AMMO, a->subtype);
ii.decode ( item_type::AMMO, i );
if ( !ii.isValid() ) continue;
ammo->add_type ( ii.getToken() );
*mOut << " " << i << " is " << ii.getToken() << endl;
}
}
}
void read_ammo() {
if ( mBuffer.has_ammo() ) {
const StockpileSettings::AmmoSet ammo = mBuffer.ammo();
*mOut << "ammo: " <<endl;
for ( int i = 0; i < ammo.type_size(); ++i ) {
std::string token = ammo.type ( i );
ItemTypeInfo ii;
if ( !ii.find ( token ) ) continue;
*mOut << " " << token << endl;
}
}
}
};
static command_result savestock ( color_ostream &out, vector <string> & parameters )
{
// HOTKEY COMMAND: CORE ALREADY SUSPENDED
building_stockpilest *sp = virtual_cast<building_stockpilest> ( world->selected_building );
if ( !sp ) {
out.printerr ( "Selected building isn't a stockpile.\n" );
return CR_WRONG_USAGE;
}
// for testing
StockpileSerializer cereal ( out, sp );
StockpileSettings s = cereal.write();
StockpileSerializer cereal2 ( out, sp );
cereal2.read ( s );
return CR_OK;
}