dfhack/plugins/dig-now.cpp

823 lines
30 KiB
C++

/*
* Simulates completion of dig designations.
*/
#include "DataFuncs.h"
#include "PluginManager.h"
#include "TileTypes.h"
#include "LuaTools.h"
#include "modules/Gui.h"
#include "modules/Maps.h"
#include "modules/MapCache.h"
#include "modules/Random.h"
#include "modules/Units.h"
#include "modules/World.h"
#include <df/historical_entity.h>
#include <df/map_block.h>
#include <df/reaction_product_itemst.h>
#include <df/tile_designation.h>
#include <df/tile_occupancy.h>
#include <df/ui.h>
#include <df/unit.h>
#include <df/vermin.h>
#include <df/world.h>
#include <df/world_site.h>
DFHACK_PLUGIN("dig-now");
REQUIRE_GLOBAL(ui);
REQUIRE_GLOBAL(world);
using namespace DFHack;
struct boulder_percent_options {
// percent chance ([0..100]) for creating a boulder for the given rock type
uint32_t layer;
uint32_t vein;
uint32_t small_cluster;
uint32_t deep;
// defaults from
// https://dwarffortresswiki.org/index.php/DF2014:Mining
boulder_percent_options() :
layer(25), vein(33), small_cluster(100), deep(100) { }
static struct_identity _identity;
};
static const struct_field_info boulder_percent_options_fields[] = {
{ struct_field_info::PRIMITIVE, "layer", offsetof(boulder_percent_options, layer), &df::identity_traits<uint32_t>::identity, 0, 0 },
{ struct_field_info::PRIMITIVE, "vein", offsetof(boulder_percent_options, vein), &df::identity_traits<uint32_t>::identity, 0, 0 },
{ struct_field_info::PRIMITIVE, "small_cluster", offsetof(boulder_percent_options, small_cluster), &df::identity_traits<uint32_t>::identity, 0, 0 },
{ struct_field_info::PRIMITIVE, "deep", offsetof(boulder_percent_options, deep), &df::identity_traits<uint32_t>::identity, 0, 0 },
{ struct_field_info::END }
};
struct_identity boulder_percent_options::_identity(sizeof(boulder_percent_options), &df::allocator_fn<boulder_percent_options>, NULL, "boulder_percents", NULL, boulder_percent_options_fields);
struct dig_now_options {
bool help; // whether to show the short help
DFCoord start; // upper-left coordinate, min z-level
DFCoord end; // lower-right coordinate, max z-level
boulder_percent_options boulder_percents;
// if set to the pos of a walkable tile (or somewhere above such a tile),
// will dump generated boulders at this position instead of at their dig
// locations
DFCoord dump_pos;
static DFCoord getMapSize() {
uint32_t endx, endy, endz;
Maps::getTileSize(endx, endy, endz);
return DFCoord(endx, endy, endz);
}
dig_now_options() : help(false), start(0, 0, 0), end(getMapSize()) { }
static struct_identity _identity;
};
static const struct_field_info dig_now_options_fields[] = {
{ struct_field_info::PRIMITIVE, "help", offsetof(dig_now_options, help), &df::identity_traits<bool>::identity, 0, 0 },
{ struct_field_info::SUBSTRUCT, "start", offsetof(dig_now_options, start), &df::coord::_identity, 0, 0 },
{ struct_field_info::SUBSTRUCT, "end", offsetof(dig_now_options, end), &df::coord::_identity, 0, 0 },
{ struct_field_info::SUBSTRUCT, "boulder_percents", offsetof(dig_now_options, boulder_percents), &boulder_percent_options::_identity, 0, 0 },
{ struct_field_info::SUBSTRUCT, "dump_pos", offsetof(dig_now_options, dump_pos), &df::coord::_identity, 0, 0 },
{ struct_field_info::END }
};
struct_identity dig_now_options::_identity(sizeof(dig_now_options), &df::allocator_fn<dig_now_options>, NULL, "dig_now_options", NULL, dig_now_options_fields);
// propagate light, outside, and subterranean flags to open tiles below this one
static void propagate_vertical_flags(MapExtras::MapCache &map,
const DFCoord &pos) {
df::tile_designation td = map.designationAt(pos);
if (!map.ensureBlockAt(DFCoord(pos.x, pos.y, pos.z+1))) {
// only the sky above
td.bits.light = true;
td.bits.outside = true;
td.bits.subterranean = false;
}
int32_t zlevel = pos.z;
df::tiletype_shape shape =
tileShape(map.tiletypeAt(DFCoord(pos.x, pos.y, zlevel)));
while ((shape == df::tiletype_shape::EMPTY
|| shape == df::tiletype_shape::RAMP_TOP)
&& map.ensureBlockAt(DFCoord(pos.x, pos.y, --zlevel))) {
DFCoord pos_below(pos.x, pos.y, zlevel);
df::tile_designation td_below = map.designationAt(pos_below);
if (td_below.bits.light == td.bits.light
&& td_below.bits.outside == td.bits.outside
&& td_below.bits.subterranean == td.bits.subterranean)
break;
td_below.bits.light = td.bits.light;
td_below.bits.outside = td.bits.outside;
td_below.bits.subterranean = td.bits.subterranean;
map.setDesignationAt(pos_below, td_below);
shape = tileShape(map.tiletypeAt(pos_below));
}
}
static bool can_dig_default(df::tiletype tt) {
df::tiletype_shape shape = tileShape(tt);
return shape == df::tiletype_shape::WALL ||
shape == df::tiletype_shape::FORTIFICATION ||
shape == df::tiletype_shape::RAMP ||
shape == df::tiletype_shape::STAIR_UP ||
shape == df::tiletype_shape::STAIR_UPDOWN;
}
static bool can_dig_channel(df::tiletype tt) {
df::tiletype_shape shape = tileShape(tt);
return shape != df::tiletype_shape::EMPTY &&
shape != df::tiletype_shape::ENDLESS_PIT &&
shape != df::tiletype_shape::NONE &&
shape != df::tiletype_shape::RAMP_TOP &&
shape != df::tiletype_shape::TRUNK_BRANCH;
}
static bool can_dig_up_stair(df::tiletype tt) {
df::tiletype_shape shape = tileShape(tt);
return shape == df::tiletype_shape::WALL ||
shape == df::tiletype_shape::FORTIFICATION;
}
static bool can_dig_down_stair(df::tiletype tt) {
df::tiletype_shape shape = tileShape(tt);
return shape == df::tiletype_shape::BOULDER ||
shape == df::tiletype_shape::BROOK_BED ||
shape == df::tiletype_shape::BROOK_TOP ||
shape == df::tiletype_shape::FLOOR ||
shape == df::tiletype_shape::FORTIFICATION ||
shape == df::tiletype_shape::PEBBLES ||
shape == df::tiletype_shape::RAMP ||
shape == df::tiletype_shape::SAPLING ||
shape == df::tiletype_shape::SHRUB ||
shape == df::tiletype_shape::TWIG ||
shape == df::tiletype_shape::WALL;
}
static bool can_dig_up_down_stair(df::tiletype tt) {
df::tiletype_shape shape = tileShape(tt);
return shape == df::tiletype_shape::WALL ||
shape == df::tiletype_shape::FORTIFICATION ||
shape == df::tiletype_shape::STAIR_UP;
}
static bool can_dig_ramp(df::tiletype tt) {
df::tiletype_shape shape = tileShape(tt);
return shape == df::tiletype_shape::WALL ||
shape == df::tiletype_shape::FORTIFICATION;
}
static void dig_type(MapExtras::MapCache &map, const DFCoord &pos,
df::tiletype tt) {
auto blk = map.BlockAtTile(pos);
if (!blk)
return;
// ensure we run this even if one of the later steps fails (e.g. OpenSpace)
map.setTiletypeAt(pos, tt);
// digging a tile reverts it to the layer soil/stone material
if (!blk->setStoneAt(pos, tt, map.layerMaterialAt(pos)) &&
!blk->setSoilAt(pos, tt, map.layerMaterialAt(pos)))
return;
// un-smooth dug tiles
tt = map.tiletypeAt(pos);
tt = findTileType(tileShape(tt), tileMaterial(tt), tileVariant(tt),
df::tiletype_special::NORMAL, tileDirection(tt));
map.setTiletypeAt(pos, tt);
}
static void dig_shape(MapExtras::MapCache &map, const DFCoord &pos,
df::tiletype tt, df::tiletype_shape shape) {
dig_type(map, pos, findSimilarTileType(tt, shape));
}
static void remove_ramp_top(MapExtras::MapCache &map, const DFCoord &pos) {
if (!map.ensureBlockAt(pos))
return;
if (tileShape(map.tiletypeAt(pos)) == df::tiletype_shape::RAMP_TOP)
dig_type(map, pos, df::tiletype::OpenSpace);
}
static bool is_wall(MapExtras::MapCache &map, const DFCoord &pos) {
if (!map.ensureBlockAt(pos))
return false;
return tileShape(map.tiletypeAt(pos)) == df::tiletype_shape::WALL;
}
static void clean_ramp(MapExtras::MapCache &map, const DFCoord &pos) {
if (!map.ensureBlockAt(pos))
return;
df::tiletype tt = map.tiletypeAt(pos);
if (tileShape(tt) != df::tiletype_shape::RAMP)
return;
if (is_wall(map, DFCoord(pos.x-1, pos.y, pos.z)) ||
is_wall(map, DFCoord(pos.x+1, pos.y, pos.z)) ||
is_wall(map, DFCoord(pos.x, pos.y-1, pos.z)) ||
is_wall(map, DFCoord(pos.x, pos.y+1, pos.z)))
return;
remove_ramp_top(map, DFCoord(pos.x, pos.y, pos.z+1));
dig_shape(map,pos, tt, df::tiletype_shape::FLOOR);
}
// removes self and/or orthogonally adjacent ramps that are no longer adjacent
// to a wall
static void clean_ramps(MapExtras::MapCache &map, const DFCoord &pos) {
clean_ramp(map, pos);
clean_ramp(map, DFCoord(pos.x-1, pos.y, pos.z));
clean_ramp(map, DFCoord(pos.x+1, pos.y, pos.z));
clean_ramp(map, DFCoord(pos.x, pos.y-1, pos.z));
clean_ramp(map, DFCoord(pos.x, pos.y+1, pos.z));
}
// destroys any colonies located at pos
static void destroy_colony(const DFCoord &pos) {
auto same_pos = [&](df::vermin *colony){ return colony->pos == pos; };
auto &colonies = world->vermin.colonies;
auto found_colony = std::find_if(begin(colonies), end(colonies), same_pos);
if (found_colony == end(colonies))
return;
colonies.erase(found_colony);
auto &all_vermin = world->vermin.all;
all_vermin.erase(
std::find_if(begin(all_vermin), end(all_vermin), same_pos));
}
struct dug_tile_info {
DFCoord pos;
df::tiletype_material tmat;
df::item_type itype;
int32_t imat; // mat idx of boulder/gem potentially generated at this pos
dug_tile_info(MapExtras::MapCache &map, const DFCoord &pos) {
this->pos = pos;
df::tiletype tt = map.tiletypeAt(pos);
tmat = tileMaterial(tt);
switch (map.BlockAtTile(pos)->veinTypeAt(pos)) {
case df::inclusion_type::CLUSTER_ONE:
case df::inclusion_type::CLUSTER_SMALL:
itype = df::item_type::ROUGH;
break;
default:
itype = df::item_type::BOULDER;
}
imat = -1;
if (tileShape(tt) == df::tiletype_shape::WALL
&& (tmat == df::tiletype_material::STONE
|| tmat == df::tiletype_material::MINERAL
|| tmat == df::tiletype_material::FEATURE))
imat = map.baseMaterialAt(pos).mat_index;
}
};
static bool is_diggable(MapExtras::MapCache &map, const DFCoord &pos,
df::tiletype tt) {
df::tiletype_material mat = tileMaterial(tt);
switch (mat) {
case df::tiletype_material::CONSTRUCTION:
case df::tiletype_material::POOL:
case df::tiletype_material::RIVER:
case df::tiletype_material::TREE:
case df::tiletype_material::ROOT:
case df::tiletype_material::LAVA_STONE:
case df::tiletype_material::MAGMA:
case df::tiletype_material::HFS:
case df::tiletype_material::UNDERWORLD_GATE:
return false;
default:
break;
}
if (mat == df::tiletype_material::FEATURE) {
// adamantine is the only is diggable feature
t_feature feature;
return map.BlockAtTile(pos)->GetLocalFeature(&feature)
&& feature.type == feature_type::deep_special_tube;
}
return true;
}
static bool dig_tile(color_ostream &out, MapExtras::MapCache &map,
const DFCoord &pos, df::tile_dig_designation designation,
std::vector<dug_tile_info> &dug_tiles) {
df::tiletype tt = map.tiletypeAt(pos);
if (!is_diggable(map, pos, tt))
return false;
df::tiletype target_type = df::tiletype::Void;
switch(designation) {
case df::tile_dig_designation::Default:
if (can_dig_default(tt)) {
df::tiletype_shape shape = tileShape(tt);
df::tiletype_shape target_shape = df::tiletype_shape::FLOOR;
if (shape == df::tiletype_shape::STAIR_UPDOWN)
target_shape = df::tiletype_shape::STAIR_DOWN;
else if (shape == df::tiletype_shape::RAMP)
remove_ramp_top(map, DFCoord(pos.x, pos.y, pos.z+1));
target_type = findSimilarTileType(tt, target_shape);
}
break;
case df::tile_dig_designation::Channel:
if (can_dig_channel(tt)) {
target_type = df::tiletype::OpenSpace;
DFCoord pos_above(pos.x, pos.y, pos.z+1);
if (map.ensureBlockAt(pos_above))
remove_ramp_top(map, pos_above);
DFCoord pos_below(pos.x, pos.y, pos.z-1);
if (map.ensureBlockAt(pos_below) &&
dig_tile(out, map, pos_below,
df::tile_dig_designation::Ramp, dug_tiles)) {
clean_ramps(map, pos_below);
// if we successfully dug out the ramp below, that took care
// of adding the ramp top here
return true;
}
break;
}
case df::tile_dig_designation::UpStair:
if (can_dig_up_stair(tt))
target_type =
findSimilarTileType(tt, df::tiletype_shape::STAIR_UP);
break;
case df::tile_dig_designation::DownStair:
if (can_dig_down_stair(tt)) {
target_type =
findSimilarTileType(tt, df::tiletype_shape::STAIR_DOWN);
}
break;
case df::tile_dig_designation::UpDownStair:
if (can_dig_up_down_stair(tt)) {
target_type =
findSimilarTileType(tt,
df::tiletype_shape::STAIR_UPDOWN);
}
break;
case df::tile_dig_designation::Ramp:
{
if (can_dig_ramp(tt)) {
target_type = findSimilarTileType(tt, df::tiletype_shape::RAMP);
DFCoord pos_above(pos.x, pos.y, pos.z+1);
if (target_type != tt && map.ensureBlockAt(pos_above)) {
// only capture the tile info of pos_above if we didn't get
// here via the Channel case above
if (dug_tiles.size() == 0)
dug_tiles.push_back(dug_tile_info(map, pos_above));
destroy_colony(pos_above);
// set tile type directly instead of calling dig_shape
// because we need to use *this* tile's material, not the
// material of the tile above
map.setTiletypeAt(pos_above,
findSimilarTileType(tt, df::tiletype_shape::RAMP_TOP));
remove_ramp_top(map, DFCoord(pos.x, pos.y, pos.z+2));
}
}
break;
}
case df::tile_dig_designation::No:
default:
out.printerr(
"unhandled dig designation for tile (%d, %d, %d): %d\n",
pos.x, pos.y, pos.z, designation);
}
// fail if unhandled or no change to tile
if (target_type == df::tiletype::Void || target_type == tt)
return false;
dug_tiles.push_back(dug_tile_info(map, pos));
dig_type(map, pos, target_type);
// let light filter down to newly exposed tiles
propagate_vertical_flags(map, pos);
return true;
}
static bool is_smooth_wall(MapExtras::MapCache &map, const DFCoord &pos) {
df::tiletype tt = map.tiletypeAt(pos);
return tileSpecial(tt) == df::tiletype_special::SMOOTH
&& tileShape(tt) == df::tiletype_shape::WALL;
}
// adds adjacent smooth walls to the given tdir
static TileDirection get_adjacent_smooth_walls(MapExtras::MapCache &map,
const DFCoord &pos,
TileDirection tdir) {
if (is_smooth_wall(map, DFCoord(pos.x, pos.y-1, pos.z)))
tdir.north = 1;
if (is_smooth_wall(map, DFCoord(pos.x, pos.y+1, pos.z)))
tdir.south = 1;
if (is_smooth_wall(map, DFCoord(pos.x-1, pos.y, pos.z)))
tdir.west = 1;
if (is_smooth_wall(map, DFCoord(pos.x+1, pos.y, pos.z)))
tdir.east = 1;
return tdir;
}
// ensure we have at least two directions enabled so we can find a matching
// tiletype
static TileDirection ensure_valid_tdir(TileDirection tdir) {
if (tdir.sum() < 2) {
if (tdir.north) tdir.south = 1;
else if (tdir.south) tdir.north = 1;
else if (tdir.east) tdir.west = 1;
else if (tdir.west) tdir.east = 1;
}
return tdir;
}
// connects adjacent smooth walls to our new smooth wall
static bool adjust_smooth_wall_dir(MapExtras::MapCache &map,
const DFCoord &pos,
TileDirection tdir) {
if (!is_smooth_wall(map, pos))
return false;
tdir = ensure_valid_tdir(get_adjacent_smooth_walls(map, pos, tdir));
df::tiletype tt = map.tiletypeAt(pos);
tt = findTileType(tileShape(tt), tileMaterial(tt), tileVariant(tt),
tileSpecial(tt), tdir);
if (tt == df::tiletype::Void)
return false;
map.setTiletypeAt(pos, tt);
return true;
}
// assumes that if the game let you designate a tile for smoothing, it must be
// valid to do so.
static bool smooth_tile(color_ostream &out, MapExtras::MapCache &map,
const DFCoord &pos) {
df::tiletype tt = map.tiletypeAt(pos);
TileDirection tdir;
if (tileShape(tt) == df::tiletype_shape::WALL) {
if (adjust_smooth_wall_dir(map, DFCoord(pos.x, pos.y-1, pos.z),
TileDirection(0, 1, 0, 0)))
tdir.north = 1;
if (adjust_smooth_wall_dir(map, DFCoord(pos.x, pos.y+1, pos.z),
TileDirection(1, 0, 0, 0)))
tdir.south = 1;
if (adjust_smooth_wall_dir(map, DFCoord(pos.x-1, pos.y, pos.z),
TileDirection(0, 0, 0, 1)))
tdir.west = 1;
if (adjust_smooth_wall_dir(map, DFCoord(pos.x+1, pos.y, pos.z),
TileDirection(0, 0, 1, 0)))
tdir.east = 1;
tdir = ensure_valid_tdir(tdir);
}
tt = findTileType(tileShape(tt), tileMaterial(tt), tileVariant(tt),
df::tiletype_special::SMOOTH, tdir);
if (tt == df::tiletype::Void)
return false;
map.setTiletypeAt(pos, tt);
return true;
}
// assumes that if the game let you designate a tile for track carving, it must
// be valid to do so.
static bool carve_tile(MapExtras::MapCache &map,
const DFCoord &pos, df::tile_occupancy &to) {
df::tiletype tt = map.tiletypeAt(pos);
TileDirection tdir = tileDirection(tt);
if (to.bits.carve_track_north)
tdir.north = 1;
if (to.bits.carve_track_east)
tdir.east = 1;
if (to.bits.carve_track_south)
tdir.south = 1;
if (to.bits.carve_track_west)
tdir.west = 1;
tt = findTileType(tileShape(tt), tileMaterial(tt), tileVariant(tt),
df::tiletype_special::TRACK, tdir);
if (tt == df::tiletype::Void)
return false;
map.setTiletypeAt(pos, tt);
return true;
}
static bool produces_item(const boulder_percent_options &options,
MapExtras::MapCache &map, Random::MersenneRNG &rng,
const dug_tile_info &info) {
uint32_t probability;
if (info.tmat == df::tiletype_material::FEATURE)
probability = options.deep;
else {
switch (map.BlockAtTile(info.pos)->veinTypeAt(info.pos)) {
case df::inclusion_type::CLUSTER:
case df::inclusion_type::VEIN:
probability = options.vein;
break;
case df::inclusion_type::CLUSTER_ONE:
case df::inclusion_type::CLUSTER_SMALL:
probability = options.small_cluster;
break;
default:
probability = options.layer;
break;
}
}
return rng.random(100) < probability;
}
typedef std::map<std::pair<df::item_type, int32_t>, std::vector<DFCoord>>
item_coords_t;
static void do_dig(color_ostream &out, std::vector<DFCoord> &dug_coords,
item_coords_t &item_coords, const dig_now_options &options) {
MapExtras::MapCache map;
Random::MersenneRNG rng;
rng.init();
// go down levels instead of up so stacked ramps behave as expected
for (int16_t z = options.end.z; z >= options.start.z; --z) {
for (int16_t y = options.start.y; y <= options.end.y; ++y) {
for (int16_t x = options.start.x; x <= options.end.x; ++x) {
// this will return NULL if the map block hasn't been allocated
// yet, but that means there aren't any designations anyway.
if (!Maps::getTileBlock(x, y, z))
continue;
DFCoord pos(x, y, z);
df::tile_designation td = map.designationAt(pos);
df::tile_occupancy to = map.occupancyAt(pos);
if (td.bits.dig != df::tile_dig_designation::No) {
std::vector<dug_tile_info> dug_tiles;
if (dig_tile(out, map, pos, td.bits.dig, dug_tiles)) {
td = map.designationAt(pos);
td.bits.dig = df::tile_dig_designation::No;
map.setDesignationAt(pos, td);
for (auto info : dug_tiles) {
dug_coords.push_back(info.pos);
if (info.imat < 0)
continue;
if (produces_item(options.boulder_percents,
map, rng, info)) {
auto k = std::make_pair(info.itype, info.imat);
item_coords[k].push_back(info.pos);
}
}
}
} else if (td.bits.smooth == 1) {
if (smooth_tile(out, map, pos)) {
to = map.occupancyAt(pos);
td.bits.smooth = 0;
map.setDesignationAt(pos, td);
}
} else if (to.bits.carve_track_north == 1
|| to.bits.carve_track_east == 1
|| to.bits.carve_track_south == 1
|| to.bits.carve_track_west == 1) {
if (carve_tile(map, pos, to)) {
to = map.occupancyAt(pos);
to.bits.carve_track_north = 0;
to.bits.carve_track_east = 0;
to.bits.carve_track_south = 0;
to.bits.carve_track_west = 0;
map.setOccupancyAt(pos, to);
}
}
}
}
}
map.WriteAll();
}
// if pos is empty space, teleport to a floor somewhere below
// if we fall out of the world (e.g. empty space or walls all the way down),
// returned position will be invalid
static DFCoord simulate_fall(const DFCoord &pos) {
DFCoord resting_pos(pos);
while (Maps::ensureTileBlock(resting_pos)) {
df::tiletype tt = *Maps::getTileType(resting_pos);
df::tiletype_shape_basic basic_shape = tileShapeBasic(tileShape(tt));
if (isWalkable(tt) && basic_shape != df::tiletype_shape_basic::Open)
break;
--resting_pos.z;
}
return resting_pos;
}
static void create_boulders(color_ostream &out,
const item_coords_t &item_coords,
const dig_now_options &options) {
df::unit *unit = world->units.active[0];
df::historical_entity *civ = df::historical_entity::find(unit->civ_id);
df::world_site *site = World::isFortressMode() ?
df::world_site::find(ui->site_id) : NULL;
std::vector<df::reaction_reagent *> in_reag;
std::vector<df::item *> in_items;
DFCoord dump_pos;
if (Maps::isValidTilePos(options.dump_pos)) {
dump_pos = simulate_fall(options.dump_pos);
if (!Maps::ensureTileBlock(dump_pos))
out.printerr("Invalid dump tile coordinates! Ensure the --dump"
" option specifies an open, non-wall tile.");
}
for (auto entry : item_coords) {
df::reaction_product_itemst *prod =
df::allocate<df::reaction_product_itemst>();
const std::vector<DFCoord> &coords = entry.second;
prod->item_type = entry.first.first;
prod->item_subtype = -1;
prod->mat_type = 0;
prod->mat_index = entry.first.second;
prod->probability = 100;
prod->count = coords.size();
prod->product_dimension = 1;
std::vector<df::reaction_product*> out_products;
std::vector<df::item *> out_items;
prod->produce(unit, &out_products, &out_items, &in_reag, &in_items, 1,
job_skill::NONE, 0, civ, site, NULL);
size_t num_items = out_items.size();
if (num_items != coords.size()) {
out.printerr("unexpected number of boulders produced; "
"some boulders may be missing.\n");
num_items = min(num_items, entry.second.size());
}
for (size_t i = 0; i < num_items; ++i) {
DFCoord pos = Maps::isValidTilePos(dump_pos) ?
dump_pos : simulate_fall(coords[i]);
if (!Maps::ensureTileBlock(pos)) {
out.printerr(
"unable to place boulder generated at (%d, %d, %d)\n",
coords[i].x, coords[i].y, coords[i].z);
continue;
}
out_items[i]->moveToGround(pos.x, pos.y, pos.z);
}
delete(prod);
}
}
static void flood_unhide(color_ostream &out, const DFCoord &pos) {
auto L = Lua::Core::State;
Lua::StackUnwinder top(L);
if (!lua_checkstack(L, 2)
|| !Lua::PushModulePublic(out, L, "plugins.reveal", "unhideFlood"))
return;
Lua::Push(L, pos);
Lua::SafeCall(out, L, 1, 0);
}
static void post_process_dug_tiles(color_ostream &out,
const std::vector<DFCoord> &dug_coords) {
for (DFCoord pos : dug_coords) {
if (Maps::getTileDesignation(pos)->bits.hidden)
flood_unhide(out, pos);
df::tile_occupancy &to = *Maps::getTileOccupancy(pos);
if (to.bits.unit or to.bits.item) {
DFCoord resting_pos = simulate_fall(pos);
if (resting_pos == pos)
continue;
if (!Maps::ensureTileBlock(resting_pos)) {
out.printerr("No valid tile beneath (%d, %d, %d); can't move"
" units and items to floor",
pos.x, pos.y, pos.z);
continue;
}
if (to.bits.unit) {
std::vector<df::unit*> units;
Units::getUnitsInBox(units, pos.x, pos.y, pos.z,
pos.x, pos.y, pos.z);
for (auto unit : units)
Units::teleport(unit, resting_pos);
}
if (to.bits.item) {
for (auto item : world->items.other.IN_PLAY) {
if (item->pos == pos and item->flags.bits.on_ground)
item->moveToGround(
resting_pos.x, resting_pos.y, resting_pos.z);
}
}
}
// refresh block metadata and flows
Maps::enableBlockUpdates(Maps::getTileBlock(pos), true, true);
}
}
static bool get_options(color_ostream &out,
dig_now_options &opts,
const std::vector<std::string> &parameters) {
auto L = Lua::Core::State;
Lua::StackUnwinder top(L);
if (!lua_checkstack(L, parameters.size() + 2) ||
!Lua::PushModulePublic(
out, L, "plugins.dig-now", "parse_commandline")) {
out.printerr("Failed to load dig-now Lua code\n");
return false;
}
Lua::Push(L, &opts);
for (const std::string &param : parameters)
Lua::Push(L, param);
if (!Lua::SafeCall(out, L, parameters.size() + 1, 0))
return false;
return true;
}
static void print_help(color_ostream &out) {
auto L = Lua::Core::State;
Lua::StackUnwinder top(L);
if (!lua_checkstack(L, 1) ||
!Lua::PushModulePublic(out, L, "plugins.dig-now", "print_help") ||
!Lua::SafeCall(out, L, 0, 0)) {
out.printerr("Failed to load dig-now Lua code\n");
}
}
command_result dig_now(color_ostream &out, std::vector<std::string> &params) {
CoreSuspender suspend;
dig_now_options options;
if (!get_options(out, options, params) || options.help)
{
print_help(out);
return options.help ? CR_OK : CR_FAILURE;
}
if (!Maps::IsValid()) {
out.printerr("Map is not available!\n");
return CR_FAILURE;
}
// required for boulder generation
if (world->units.active.size() == 0) {
out.printerr("At least one unit must be alive!\n");
return CR_FAILURE;
}
// track which positions were modified and where to produce items
std::vector<DFCoord> dug_coords;
item_coords_t item_coords;
do_dig(out, dug_coords, item_coords, options);
create_boulders(out, item_coords, options);
post_process_dug_tiles (out, dug_coords);
// force the game to recompute its walkability cache
world->reindex_pathfinding = true;
return CR_OK;
}
DFhackCExport command_result plugin_init(color_ostream &,
std::vector<PluginCommand> &commands) {
commands.push_back(PluginCommand(
"dig-now", "Instantly complete dig designations", dig_now, false));
return CR_OK;
}
DFhackCExport command_result plugin_shutdown(color_ostream &) {
return CR_OK;
}