/*
* This file is part of OpenTTD.
* OpenTTD is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, version 2.
* OpenTTD is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
* See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with OpenTTD. If not, see <http://www.gnu.org/licenses/>.
*/
/** @file tree_cmd.cpp Handling of tree tiles. */
#include "stdafx.h"
#include "clear_map.h"
#include "landscape.h"
#include "tree_map.h"
#include "viewport_func.h"
#include "command_func.h"
#include "town.h"
#include "genworld.h"
#include "clear_func.h"
#include "company_func.h"
#include "sound_func.h"
#include "water.h"
#include "company_base.h"
#include "core/geometry_type.hpp"
#include "core/random_func.hpp"
#include "newgrf_generic.h"
#include "timer/timer_game_tick.h"
#include "tree_cmd.h"
#include "landscape_cmd.h"
#include "table/strings.h"
#include "table/tree_land.h"
#include "table/clear_land.h"
#include "safeguards.h"
/**
* List of tree placer algorithm.
*
* This enumeration defines all possible tree placer algorithm in the game.
*/
enum TreePlacer : uint8_t {
TP_NONE, ///< No tree placer algorithm
TP_ORIGINAL, ///< The original algorithm
TP_IMPROVED, ///< A 'improved' algorithm
};
/** Where to place trees while in-game? */
enum ExtraTreePlacement : uint8_t {
ETP_NO_SPREAD, ///< Grow trees on tiles that have them but don't spread to new ones
ETP_SPREAD_RAINFOREST, ///< Grow trees on tiles that have them, only spread to new ones in rainforests
ETP_SPREAD_ALL, ///< Grow trees and spread them without restrictions
ETP_NO_GROWTH_NO_SPREAD, ///< Don't grow trees and don't spread them at all
};
/** Determines when to consider building more trees. */
uint8_t _trees_tick_ctr;
static const uint16_t DEFAULT_TREE_STEPS = 1000; ///< Default number of attempts for placing trees.
static const uint16_t DEFAULT_RAINFOREST_TREE_STEPS = 15000; ///< Default number of attempts for placing extra trees at rainforest in tropic.
static const uint16_t EDITOR_TREE_DIV = 5; ///< Game editor tree generation divisor factor.
/**
* Tests if a tile can be converted to MP_TREES
* This is true for clear ground without farms or rocks.
*
* @param tile the tile of interest
* @param allow_desert Allow planting trees on CLEAR_DESERT?
* @return true if trees can be built.
*/
static bool CanPlantTreesOnTile(TileIndex tile, bool allow_desert)
{
switch (GetTileType(tile)) {
case MP_WATER:
return !IsBridgeAbove(tile) && IsCoast(tile) && !IsSlopeWithOneCornerRaised(GetTileSlope(tile));
case MP_CLEAR:
return !IsBridgeAbove(tile) && !IsClearGround(tile, CLEAR_FIELDS) && !IsClearGround(tile, CLEAR_ROCKS) &&
(allow_desert || !IsClearGround(tile, CLEAR_DESERT));
default: return false;
}
}
/**
* Creates a tree tile
* Ground type and density is preserved.
*
* @pre the tile must be suitable for trees.
*
* @param tile where to plant the trees.
* @param treetype The type of the tree
* @param count the number of trees (minus 1)
* @param growth the growth status
*/
static void PlantTreesOnTile(TileIndex tile, TreeType treetype, uint count, TreeGrowthStage growth)
{
assert(treetype != TREE_INVALID);
assert(CanPlantTreesOnTile(tile, true));
TreeGround ground;
uint density = 3;
switch (GetTileType(tile)) {
case MP_WATER:
ground = TREE_GROUND_SHORE;
ClearNeighbourNonFloodingStates(tile);
break;
case MP_CLEAR: {
ClearGround clearground = GetClearGround(tile);
if (IsSnowTile(tile)) {
ground = clearground == CLEAR_ROUGH ? TREE_GROUND_ROUGH_SNOW : TREE_GROUND_SNOW_DESERT;
} else {
switch (clearground) {
case CLEAR_GRASS: ground = TREE_GROUND_GRASS; break;
case CLEAR_ROUGH: ground = TREE_GROUND_ROUGH; break;
default: ground = TREE_GROUND_SNOW_DESERT; break;
}
}
if (clearground != CLEAR_ROUGH) density = GetClearDensity(tile);
break;
}
default: NOT_REACHED();
}
MakeTree(tile, treetype, count, growth, ground, density);
}
/**
* Get a random TreeType for the given tile based on a given seed
*
* This function returns a random TreeType which can be placed on the given tile.
* The seed for randomness must be less or equal 256, use #GB on the value of Random()
* to get such a value.
*
* @param tile The tile to get a random TreeType from
* @param seed The seed for randomness, must be less or equal 256
* @return The random tree type
*/
static TreeType GetRandomTreeType(TileIndex tile, uint seed)
{
switch (_settings_game.game_creation.landscape) {
case LandscapeType::Temperate:
return static_cast<TreeType>(seed * TREE_COUNT_TEMPERATE / 256 + TREE_TEMPERATE);
case LandscapeType::Arctic:
return static_cast<TreeType>(seed * TREE_COUNT_SUB_ARCTIC / 256 + TREE_SUB_ARCTIC);
case LandscapeType::Tropic:
switch (GetTropicZone(tile)) {
case TROPICZONE_NORMAL: return static_cast<TreeType>(seed * TREE_COUNT_SUB_TROPICAL / 256 + TREE_SUB_TROPICAL);
case TROPICZONE_DESERT: return static_cast<TreeType>((seed > 12) ? TREE_INVALID : TREE_CACTUS);
default: return static_cast<TreeType>(seed * TREE_COUNT_RAINFOREST / 256 + TREE_RAINFOREST);
}
default:
return static_cast<TreeType>(seed * TREE_COUNT_TOYLAND / 256 + TREE_TOYLAND);
}
}
/**
* Make a random tree tile of the given tile
*
* Create a new tree-tile for the given tile. The second parameter is used for
* randomness like type and number of trees.
*
* @param tile The tile to make a tree-tile from
* @param r The randomness value from a Random() value
*/
static void PlaceTree(TileIndex tile, uint32_t r)
{
TreeType tree = GetRandomTreeType(tile, GB(r, 24, 8));
if (tree != TREE_INVALID) {
PlantTreesOnTile(tile, tree, GB(r, 22, 2), static_cast<TreeGrowthStage>(std::min<uint8_t>(GB(r, 16, 3), 6)));
MarkTileDirtyByTile(tile);
/* Rerandomize ground, if neither snow nor shore */
TreeGround ground = GetTreeGround(tile);
if (ground != TREE_GROUND_SNOW_DESERT && ground != TREE_GROUND_ROUGH_SNOW && ground != TREE_GROUND_SHORE) {
SetTreeGroundDensity(tile, (TreeGround)GB(r, 28, 1), 3);
}
}
}
struct BlobHarmonic {
int amplitude;
float phase;
int frequency;
};
/**
* Creates a star-shaped polygon originating from (0, 0) as defined by the given harmonics.
* The shape is placed into a pre-allocated span so the caller controls allocation.
* @param radius The maximum radius of the polygon. May be smaller, but will not be larger.
* @param harmonics Harmonics data for the polygon.
* @param[out] shape Shape to fill with points.
*/
static void CreateStarShapedPolygon(int radius, std::span<const BlobHarmonic> harmonics, std::span<Point> shape)
{
float theta = 0;
float step = (M_PI * 2) / std::size(shape);
/* Divide a circle into a number of equally spaced divisions. */
for (Point &vertex : shape) {
/* Add up the values of each harmonic at this segment.*/
float deviation = std::accumulate(std::begin(harmonics), std::end(harmonics), 0.f, [theta](float d, const BlobHarmonic &harmonic) -> float {
return d + sinf((theta + harmonic.phase) * harmonic.frequency) * harmonic.amplitude;
});
/* Smooth out changes. */
float adjusted_radius = (radius / 2.f) + (deviation / 2);
/* Add to the final polygon. */
vertex.x = cosf(theta) * adjusted_radius;
vertex.y = sinf(theta) * adjusted_radius;
/* Proceed to the next segment. */
theta += step;
}
}
/**
* Creates a random star-shaped polygon originating from (0, 0).
* The shape is placed into a pre-allocated span so the caller controls allocation.
* @param radius The maximum radius of the blob. May be smaller, but will not be larger.
* @param[out] shape Shape to fill with polygon points.
*/
static void CreateRandomStarShapedPolygon(int radius, std::span<Point> shape)
{
/* Valid values for the phase of blob harmonics are between 0 and Tau. we can get a value in the correct range
* from Random() by dividing the maximum possible value by the desired maximum, and then dividing the random
* value by the result. */
static constexpr float PHASE_DIVISOR = static_cast<float>(INT32_MAX / M_PI * 2);
/* These values are ones found in testing that result in suitable-looking polygons that did not self-intersect
* and fit within a square of radius * radius dimensions. */
std::initializer_list<BlobHarmonic> harmonics = {
{radius / 2, Random() / PHASE_DIVISOR, 1},
{radius / 4, Random() / PHASE_DIVISOR, 2},
{radius / 8, Random() / PHASE_DIVISOR, 3},
{radius / 16, Random() / PHASE_DIVISOR, 4},
};
CreateStarShapedPolygon(radius, harmonics, shape);
}
/**
* Returns true if the given coordinates lie within a triangle.
* @param x X coordinate relative to centre of shape.
* @param y Y coordinate relative to centre of shape.
* @param v1 First vertex of triangle.
* @param v2 Second vertex of triangle.
* @param v3 Third vertex of triangle.
* @returns true if the given coordinates lie within a triangle.
*/
static bool IsPointInTriangle(int x, int y, const Point &v1, const Point &v2, const Point &v3)
{
const int s = ((v1.x - v3.x) * (y - v3.y)) - ((v1.y - v3.y) * (x - v3.x));
const int t = ((v2.x - v1.x) * (y - v1.y)) - ((v2.y - v1.y) * (x - v1.x));
if ((s < 0) != (t < 0) && s != 0 && t != 0) return false;
const int d = (v3.x - v2.x) * (y - v2.y) - (v3.y - v2.y) * (x - v2.x);
return (d < 0) == (s + t <= 0);
}
/**
* Returns true if the given coordinates lie within a star shaped polygon.
* Breaks the polygon into a series of triangles around the centre point (0, 0) and then tests the coordinates against each triangle until a match is found (or not).
* @param x X coordinate relative to centre of shape.
* @param y Y coordinate relative to centre of shape.
* @param shape The shape to check against.
* @returns true if the given coordinates lie within the star shaped polygon.
*/
static bool IsPointInStarShapedPolygon(int x, int y, std::span<Point> shape)
{
for (auto it = std::begin(shape); it != std::end(shape); /* nothing */) {
const Point &v1 = *it;
++it;
const Point &v2 = (it == std::end(shape)) ? shape.front() : *it;
if (IsPointInTriangle(x, y, v1, v2, {0, 0})) return true;
}
return false;
}
/**
* Creates a number of tree groups.
* The number of trees in each group depends on how many trees are actually placed around the given tile.
*
* @param num_groups Number of tree groups to place.
*/
static void PlaceTreeGroups(uint num_groups)
{
static constexpr uint GROVE_SEGMENTS = 16; ///< How many segments make up the tree group.
static constexpr uint GROVE_RADIUS = 16; ///< Maximum radius of tree groups.
/* Shape in which trees may be contained. Array is here to reduce allocations. */
std::array<Point, GROVE_SEGMENTS> grove;
do {
TileIndex center_tile = RandomTile();
CreateRandomStarShapedPolygon(GROVE_RADIUS, grove);
for (uint i = 0; i < DEFAULT_TREE_STEPS; i++) {
IncreaseGeneratingWorldProgress(GWP_TREE);
uint32_t r = Random();
int x = GB(r, 0, 5) - GROVE_RADIUS;
int y = GB(r, 8, 5) - GROVE_RADIUS;
TileIndex cur_tile = TileAddWrap(center_tile, x, y);
if (cur_tile == INVALID_TILE) continue;
if (!CanPlantTreesOnTile(cur_tile, true)) continue;
if (!IsPointInStarShapedPolygon(x, y, grove)) continue;
PlaceTree(cur_tile, r);
}
} while (--num_groups);
}
/**
* Place a tree at the same height as an existing tree.
*
* Add a new tree around the given tile which is at the same
* height or at some offset (2 units) of it.
*
* @param tile The base tile to add a new tree somewhere around
* @param height The height (like the one from the tile)
*/
static void PlaceTreeAtSameHeight(TileIndex tile, int height)
{
for (uint i = 0; i < DEFAULT_TREE_STEPS; i++) {
uint32_t r = Random();
int x = GB(r, 0, 5) - 16;
int y = GB(r, 8, 5) - 16;
TileIndex cur_tile = TileAddWrap(tile, x, y);
if (cur_tile == INVALID_TILE) continue;
/* Keep in range of the existing tree */
if (abs(x) + abs(y) > 16) continue;
/* Clear tile, no farm-tiles or rocks */
if (!CanPlantTreesOnTile(cur_tile, true)) continue;
/* Not too much height difference */
if (Delta(GetTileZ(cur_tile), height) > 2) continue;
/* Place one tree and quit */
PlaceTree(cur_tile, r);
break;
}
}
/**
* Place some trees randomly
*
* This function just place some trees randomly on the map.
*/
void PlaceTreesRandomly()
{
int i, j, ht;
uint8_t max_height = _settings_game.construction.map_height_limit;
i = Map::ScaleBySize(DEFAULT_TREE_STEPS);
if (_game_mode == GM_EDITOR) i /= EDITOR_TREE_DIV;
do {
uint32_t r = Random();
TileIndex tile = RandomTileSeed(r);
IncreaseGeneratingWorldProgress(GWP_TREE);
if (CanPlantTreesOnTile(tile, true)) {
PlaceTree(tile, r);
if (_settings_game.game_creation.tree_placer != TP_IMPROVED) continue;
/* Place a number of trees based on the tile height.
* This gives a cool effect of multiple trees close together.
* It is almost real life ;) */
ht = GetTileZ(tile);
/* The higher we get, the more trees we plant */
j = GetTileZ(tile) * 2;
/* Above snowline more trees! */
if (_settings_game.game_creation.landscape == LandscapeType::Arctic && ht > GetSnowLine()) j *= 3;
/* Scale generation by maximum map height. */
if (max_height > MAP_HEIGHT_LIMIT_ORIGINAL) j = j * MAP_HEIGHT_LIMIT_ORIGINAL / max_height;
while (j--) {
PlaceTreeAtSameHeight(tile, ht);
}
}
} while (--i);
/* place extra trees at rainforest area */
if (_settings_game.game_creation.landscape == LandscapeType::Tropic) {
i = Map::ScaleBySize(DEFAULT_RAINFOREST_TREE_STEPS);
if (_game_mode == GM_EDITOR) i /= EDITOR_TREE_DIV;
do {
uint32_t r = Random();
TileIndex tile = RandomTileSeed(r);
IncreaseGeneratingWorldProgress(GWP_TREE);
if (GetTropicZone(tile) == TROPICZONE_RAINFOREST && CanPlantTreesOnTile(tile, false)) {
PlaceTree(tile, r);
}
} while (--i);
}
}
/**
* Place some trees in a radius around a tile.
* The trees are placed in an quasi-normal distribution around the indicated tile, meaning that while
* the radius does define a square, the distribution inside the square will be roughly circular.
* @note This function the interactive RNG and must only be used in editor and map generation.
* @param tile Tile to place trees around.
* @param treetype Type of trees to place. Must be a valid tree type for the climate.
* @param radius Maximum distance (on each axis) from tile to place trees.
* @param count Maximum number of trees to place.
* @param set_zone Whether to create a rainforest zone when placing rainforest trees.
* @return Number of trees actually placed.
*/
uint PlaceTreeGroupAroundTile(TileIndex tile, TreeType treetype, uint radius, uint count, bool set_zone)
{
assert(_game_mode == GM_EDITOR); // Due to InteractiveRandom being used in this function
assert(treetype < TREE_TOYLAND + TREE_COUNT_TOYLAND);
const bool allow_desert = treetype == TREE_CACTUS;
uint planted = 0;
for (; count > 0; count--) {
/* Simple quasi-normal distribution with range [-radius; radius) */
auto mkcoord = [&]() -> int32_t {
const uint32_t rand = InteractiveRandom();
const int32_t dist = GB<int32_t>(rand, 0, 8) + GB<int32_t>(rand, 8, 8) + GB<int32_t>(rand, 16, 8) + GB<int32_t>(rand, 24, 8);
const int32_t scu = dist * radius / 512;
return scu - radius;
};
const int32_t xofs = mkcoord();
const int32_t yofs = mkcoord();
const TileIndex tile_to_plant = TileAddWrap(tile, xofs, yofs);
if (tile_to_plant != INVALID_TILE) {
if (IsTileType(tile_to_plant, MP_TREES) && GetTreeCount(tile_to_plant) < 4) {
AddTreeCount(tile_to_plant, 1);
SetTreeGrowth(tile_to_plant, TreeGrowthStage::Growing1);
MarkTileDirtyByTile(tile_to_plant, 0);
planted++;
} else if (CanPlantTreesOnTile(tile_to_plant, allow_desert)) {
PlantTreesOnTile(tile_to_plant, treetype, 0, TreeGrowthStage::Grown);
MarkTileDirtyByTile(tile_to_plant, 0);
planted++;
}
}
}
if (set_zone && IsInsideMM(treetype, TREE_RAINFOREST, TREE_CACTUS)) {
for (TileIndex t : TileArea(tile).Expand(radius)) {
if (GetTileType(t) != MP_VOID && DistanceSquare(tile, t) < radius * radius) SetTropicZone(t, TROPICZONE_RAINFOREST);
}
}
return planted;
}
/**
* Place new trees.
*
* This function takes care of the selected tree placer algorithm and
* place randomly the trees for a new game.
*/
void GenerateTrees()
{
uint i, total;
if (_settings_game.game_creation.tree_placer == TP_NONE) return;
switch (_settings_game.game_creation.tree_placer) {
case TP_ORIGINAL: i = _settings_game.game_creation.landscape == LandscapeType::Arctic ? 15 : 6; break;
case TP_IMPROVED: i = _settings_game.game_creation.landscape == LandscapeType::Arctic ? 4 : 2; break;
default: NOT_REACHED();
}
total = Map::ScaleBySize(DEFAULT_TREE_STEPS);
if (_settings_game.game_creation.landscape == LandscapeType::Tropic) total += Map::ScaleBySize(DEFAULT_RAINFOREST_TREE_STEPS);
total *= i;
uint num_groups = (_settings_game.game_creation.landscape != LandscapeType::Toyland) ? Map::ScaleBySize(GB(Random(), 0, 5) + 25) : 0;
total += num_groups * DEFAULT_TREE_STEPS;
SetGeneratingWorldProgress(GWP_TREE, total);
if (num_groups != 0) PlaceTreeGroups(num_groups);
for (; i != 0; i--) {
PlaceTreesRandomly();
}
}
/**
* Plant a tree.
* @param flags type of operation
* @param tile end tile of area-drag
* @param start_tile start tile of area-drag of tree plantation
* @param tree_to_plant tree type, TREE_INVALID means random.
* @param diagonal Whether to use the Orthogonal (false) or Diagonal (true) iterator.
* @return the cost of this operation or an error
*/
CommandCost CmdPlantTree(DoCommandFlags flags, TileIndex tile, TileIndex start_tile, uint8_t tree_to_plant, bool diagonal)
{
StringID msg = INVALID_STRING_ID;
CommandCost cost(EXPENSES_OTHER);
if (start_tile >= Map::Size()) return CMD_ERROR;
/* Check the tree type within the current climate */
if (tree_to_plant != TREE_INVALID && !IsInsideBS(tree_to_plant, _tree_base_by_landscape[to_underlying(_settings_game.game_creation.landscape)], _tree_count_by_landscape[to_underlying(_settings_game.game_creation.landscape)])) return CMD_ERROR;
Company *c = (_game_mode != GM_EDITOR) ? Company::GetIfValid(_current_company) : nullptr;
int limit = (c == nullptr ? INT32_MAX : GB(c->tree_limit, 16, 16));
std::unique_ptr<TileIterator> iter = TileIterator::Create(tile, start_tile, diagonal);
for (; *iter != INVALID_TILE; ++(*iter)) {
TileIndex current_tile = *iter;
switch (GetTileType(current_tile)) {
case MP_TREES:
/* no more space for trees? */
if (GetTreeCount(current_tile) == 4) {
msg = STR_ERROR_TREE_ALREADY_HERE;
continue;
}
/* Test tree limit. */
if (--limit < 1) {
msg = STR_ERROR_TREE_PLANT_LIMIT_REACHED;
break;
}
if (flags.Test(DoCommandFlag::Execute)) {
AddTreeCount(current_tile, 1);
MarkTileDirtyByTile(current_tile);
if (c != nullptr) c->tree_limit -= 1 << 16;
}
/* 2x as expensive to add more trees to an existing tile */
cost.AddCost(_price[PR_BUILD_TREES] * 2);
break;
case MP_WATER:
if (!IsCoast(current_tile) || IsSlopeWithOneCornerRaised(GetTileSlope(current_tile))) {
msg = STR_ERROR_CAN_T_BUILD_ON_WATER;
continue;
}
[[fallthrough]];
case MP_CLEAR: {
if (IsBridgeAbove(current_tile)) {
msg = STR_ERROR_SITE_UNSUITABLE;
continue;
}
TreeType treetype = (TreeType)tree_to_plant;
/* Be a bit picky about which trees go where. */
if (_settings_game.game_creation.landscape == LandscapeType::Tropic && treetype != TREE_INVALID && (
/* No cacti outside the desert */
(treetype == TREE_CACTUS && GetTropicZone(current_tile) != TROPICZONE_DESERT) ||
/* No rainforest trees outside the rainforest, except in the editor mode where it makes those tiles rainforest tile */
(IsInsideMM(treetype, TREE_RAINFOREST, TREE_CACTUS) && GetTropicZone(current_tile) != TROPICZONE_RAINFOREST && _game_mode != GM_EDITOR) ||
/* And no subtropical trees in the desert/rainforest */
(IsInsideMM(treetype, TREE_SUB_TROPICAL, TREE_TOYLAND) && GetTropicZone(current_tile) != TROPICZONE_NORMAL))) {
msg = STR_ERROR_TREE_WRONG_TERRAIN_FOR_TREE_TYPE;
continue;
}
/* Test tree limit. */
if (--limit < 1) {
msg = STR_ERROR_TREE_PLANT_LIMIT_REACHED;
break;
}
if (IsTileType(current_tile, MP_CLEAR)) {
/* Remove fields or rocks. Note that the ground will get barrened */
switch (GetClearGround(current_tile)) {
case CLEAR_FIELDS:
case CLEAR_ROCKS: {
CommandCost ret = Command<CMD_LANDSCAPE_CLEAR>::Do(flags, current_tile);
if (ret.Failed()) return ret;
cost.AddCost(ret);
break;
}
default: break;
}
}
if (_game_mode != GM_EDITOR && Company::IsValidID(_current_company)) {
Town *t = ClosestTownFromTile(current_tile, _settings_game.economy.dist_local_authority);
if (t != nullptr) ChangeTownRating(t, RATING_TREE_UP_STEP, RATING_TREE_MAXIMUM, flags);
}
if (flags.Test(DoCommandFlag::Execute)) {
if (treetype == TREE_INVALID) {
treetype = GetRandomTreeType(current_tile, GB(Random(), 24, 8));
if (treetype == TREE_INVALID) treetype = TREE_CACTUS;
}
/* Plant full grown trees in scenario editor */
PlantTreesOnTile(current_tile, treetype, 0, _game_mode == GM_EDITOR ? TreeGrowthStage::Grown : TreeGrowthStage::Growing1);
MarkTileDirtyByTile(current_tile);
if (c != nullptr) c->tree_limit -= 1 << 16;
/* When planting rainforest-trees, set tropiczone to rainforest in editor. */
if (_game_mode == GM_EDITOR && IsInsideMM(treetype, TREE_RAINFOREST, TREE_CACTUS)) {
SetTropicZone(current_tile, TROPICZONE_RAINFOREST);
}
}
cost.AddCost(_price[PR_BUILD_TREES]);
break;
}
default:
msg = STR_ERROR_SITE_UNSUITABLE;
break;
}
/* Tree limit used up? No need to check more. */
if (limit < 0) break;
}
if (cost.GetCost() == 0) {
return CommandCost(msg);
} else {
return cost;
}
}
struct TreeListEnt : PalSpriteID {
uint8_t x, y;
};
static void DrawTile_Trees(TileInfo *ti)
{
switch (GetTreeGround(ti->tile)) {
case TREE_GROUND_SHORE: DrawShoreTile(ti->tileh); break;
case TREE_GROUND_GRASS: DrawClearLandTile(ti, GetTreeDensity(ti->tile)); break;
case TREE_GROUND_ROUGH: DrawHillyLandTile(ti); break;
default: DrawGroundSprite(_clear_land_sprites_snow_desert[GetTreeDensity(ti->tile)] + SlopeToSpriteOffset(ti->tileh), PAL_NONE); break;
}
/* Do not draw trees when the invisible trees setting is set */
if (IsInvisibilitySet(TO_TREES)) return;
uint tmp = CountBits(ti->tile.base() + ti->x + ti->y);
uint index = GB(tmp, 0, 2) + (GetTreeType(ti->tile) << 2);
/* different tree styles above one of the grounds */
if ((GetTreeGround(ti->tile) == TREE_GROUND_SNOW_DESERT || GetTreeGround(ti->tile) == TREE_GROUND_ROUGH_SNOW) &&
GetTreeDensity(ti->tile) >= 2 &&
IsInsideMM(index, TREE_SUB_ARCTIC << 2, TREE_RAINFOREST << 2)) {
index += 164 - (TREE_SUB_ARCTIC << 2);
}
assert(index < lengthof(_tree_layout_sprite));
const PalSpriteID *s = _tree_layout_sprite[index];
const TreePos *d = _tree_layout_xy[GB(tmp, 2, 2)];
/* combine trees into one sprite object */
StartSpriteCombine();
TreeListEnt te[4];
/* put the trees to draw in a list */
uint trees = GetTreeCount(ti->tile);
for (uint i = 0; i < trees; i++) {
SpriteID sprite = s[0].sprite + (i == trees - 1 ? static_cast<uint>(GetTreeGrowth(ti->tile)) : 3);
PaletteID pal = s[0].pal;
te[i].sprite = sprite;
te[i].pal = pal;
te[i].x = d->x;
te[i].y = d->y;
s++;
d++;
}
/* draw them in a sorted way */
int z = ti->z + GetSlopeMaxPixelZ(ti->tileh) / 2;
for (; trees > 0; trees--) {
uint min = te[0].x + te[0].y;
uint mi = 0;
for (uint i = 1; i < trees; i++) {
if ((uint)(te[i].x + te[i].y) < min) {
min = te[i].x + te[i].y;
mi = i;
}
}
AddSortableSpriteToDraw(te[mi].sprite, te[mi].pal, ti->x + te[mi].x, ti->y + te[mi].y, 16 - te[mi].x, 16 - te[mi].y, 0x30, z, IsTransparencySet(TO_TREES), -te[mi].x, -te[mi].y);
/* replace the removed one with the last one */
te[mi] = te[trees - 1];
}
EndSpriteCombine();
}
static int GetSlopePixelZ_Trees(TileIndex tile, uint x, uint y, bool)
{
auto [tileh, z] = GetTilePixelSlope(tile);
return z + GetPartialPixelZ(x & 0xF, y & 0xF, tileh);
}
static Foundation GetFoundation_Trees(TileIndex, Slope)
{
return FOUNDATION_NONE;
}
static CommandCost ClearTile_Trees(TileIndex tile, DoCommandFlags flags)
{
uint num;
if (Company::IsValidID(_current_company)) {
Town *t = ClosestTownFromTile(tile, _settings_game.economy.dist_local_authority);
if (t != nullptr) ChangeTownRating(t, RATING_TREE_DOWN_STEP, RATING_TREE_MINIMUM, flags);
}
num = GetTreeCount(tile);
if (IsInsideMM(GetTreeType(tile), TREE_RAINFOREST, TREE_CACTUS)) num *= 4;
if (flags.Test(DoCommandFlag::Execute)) DoClearSquare(tile);
return CommandCost(EXPENSES_CONSTRUCTION, num * _price[PR_CLEAR_TREES]);
}
static void GetTileDesc_Trees(TileIndex tile, TileDesc &td)
{
TreeType tt = GetTreeType(tile);
if (IsInsideMM(tt, TREE_RAINFOREST, TREE_CACTUS)) {
td.str = STR_LAI_TREE_NAME_RAINFOREST;
} else {
td.str = tt == TREE_CACTUS ? STR_LAI_TREE_NAME_CACTUS_PLANTS : STR_LAI_TREE_NAME_TREES;
}
td.owner[0] = GetTileOwner(tile);
}
static void TileLoopTreesDesert(TileIndex tile)
{
switch (GetTropicZone(tile)) {
case TROPICZONE_DESERT:
if (GetTreeGround(tile) != TREE_GROUND_SNOW_DESERT) {
SetTreeGroundDensity(tile, TREE_GROUND_SNOW_DESERT, 3);
MarkTileDirtyByTile(tile);
}
break;
case TROPICZONE_RAINFOREST: {
static const SoundFx forest_sounds[] = {
SND_42_RAINFOREST_1,
SND_43_RAINFOREST_2,
SND_44_RAINFOREST_3,
SND_48_RAINFOREST_4
};
uint32_t r = Random();
if (Chance16I(1, 200, r) && _settings_client.sound.ambient) SndPlayTileFx(forest_sounds[GB(r, 16, 2)], tile);
break;
}
default: break;
}
}
static void TileLoopTreesAlps(TileIndex tile)
{
int k = GetTileZ(tile) - GetSnowLine() + 1;
if (k < 0) {
switch (GetTreeGround(tile)) {
case TREE_GROUND_SNOW_DESERT: SetTreeGroundDensity(tile, TREE_GROUND_GRASS, 3); break;
case TREE_GROUND_ROUGH_SNOW: SetTreeGroundDensity(tile, TREE_GROUND_ROUGH, 3); break;
default: return;
}
} else {
uint density = std::min<uint>(k, 3);
if (GetTreeGround(tile) != TREE_GROUND_SNOW_DESERT && GetTreeGround(tile) != TREE_GROUND_ROUGH_SNOW) {
TreeGround tg = GetTreeGround(tile) == TREE_GROUND_ROUGH ? TREE_GROUND_ROUGH_SNOW : TREE_GROUND_SNOW_DESERT;
SetTreeGroundDensity(tile, tg, density);
} else if (GetTreeDensity(tile) != density) {
SetTreeGroundDensity(tile, GetTreeGround(tile), density);
} else {
if (GetTreeDensity(tile) == 3) {
uint32_t r = Random();
if (Chance16I(1, 200, r) && _settings_client.sound.ambient) {
SndPlayTileFx((r & 0x80000000) ? SND_39_ARCTIC_SNOW_2 : SND_34_ARCTIC_SNOW_1, tile);
}
}
return;
}
}
MarkTileDirtyByTile(tile);
}
static bool CanPlantExtraTrees(TileIndex tile)
{
return ((_settings_game.game_creation.landscape == LandscapeType::Tropic && GetTropicZone(tile) == TROPICZONE_RAINFOREST) ?
(_settings_game.construction.extra_tree_placement == ETP_SPREAD_ALL || _settings_game.construction.extra_tree_placement == ETP_SPREAD_RAINFOREST) :
_settings_game.construction.extra_tree_placement == ETP_SPREAD_ALL);
}
static void TileLoop_Trees(TileIndex tile)
{
if (GetTreeGround(tile) == TREE_GROUND_SHORE) {
TileLoop_Water(tile);
} else {
switch (_settings_game.game_creation.landscape) {
case LandscapeType::Tropic: TileLoopTreesDesert(tile); break;
case LandscapeType::Arctic: TileLoopTreesAlps(tile); break;
default: break;
}
}
AmbientSoundEffect(tile);
/* TimerGameTick::counter is incremented by 256 between each call, so ignore lower 8 bits.
* Also, we use a simple hash to spread the updates evenly over the map.
* 11 and 9 are just some co-prime numbers for better spread.
*/
uint32_t cycle = 11 * TileX(tile) + 9 * TileY(tile) + (TimerGameTick::counter >> 8);
/* Handle growth of grass (under trees/on MP_TREES tiles) at every 8th processings, like it's done for grass on MP_CLEAR tiles. */
if ((cycle & 7) == 7 && GetTreeGround(tile) == TREE_GROUND_GRASS) {
uint density = GetTreeDensity(tile);
if (density < 3) {
SetTreeGroundDensity(tile, TREE_GROUND_GRASS, density + 1);
MarkTileDirtyByTile(tile);
}
}
if (_settings_game.construction.extra_tree_placement == ETP_NO_GROWTH_NO_SPREAD) return;
static const uint32_t TREE_UPDATE_FREQUENCY = 16; // How many tile updates happen for one tree update
if (cycle % TREE_UPDATE_FREQUENCY != TREE_UPDATE_FREQUENCY - 1) return;
switch (GetTreeGrowth(tile)) {
case TreeGrowthStage::Grown: // regular sized tree
if (_settings_game.game_creation.landscape == LandscapeType::Tropic &&
GetTreeType(tile) != TREE_CACTUS &&
GetTropicZone(tile) == TROPICZONE_DESERT) {
AddTreeGrowth(tile, 1);
} else {
switch (GB(Random(), 0, 3)) {
case 0: // start destructing
AddTreeGrowth(tile, 1);
break;
case 1: // add a tree
if (GetTreeCount(tile) < 4 && CanPlantExtraTrees(tile)) {
AddTreeCount(tile, 1);
SetTreeGrowth(tile, TreeGrowthStage::Growing1);
break;
}
[[fallthrough]];
case 2: { // add a neighbouring tree
if (!CanPlantExtraTrees(tile)) break;
TreeType treetype = GetTreeType(tile);
tile += TileOffsByDir(static_cast<Direction>(Random() % DIR_END));
/* Cacti don't spread */
if (!CanPlantTreesOnTile(tile, false)) return;
/* Don't plant trees, if ground was freshly cleared */
if (IsTileType(tile, MP_CLEAR) && GetClearGround(tile) == CLEAR_GRASS && GetClearDensity(tile) != 3) return;
PlantTreesOnTile(tile, treetype, 0, TreeGrowthStage::Growing1);
break;
}
default:
return;
}
}
break;
case TreeGrowthStage::Dead: // final stage of tree destruction
if (!CanPlantExtraTrees(tile)) {
/* if trees can't spread just plant a new one to prevent deforestation */
SetTreeGrowth(tile, TreeGrowthStage::Growing1);
} else if (GetTreeCount(tile) > 1) {
/* more than one tree, delete it */
AddTreeCount(tile, -1);
SetTreeGrowth(tile, TreeGrowthStage::Grown);
} else {
/* just one tree, change type into MP_CLEAR */
switch (GetTreeGround(tile)) {
case TREE_GROUND_SHORE: MakeShore(tile); break;
case TREE_GROUND_GRASS: MakeClear(tile, CLEAR_GRASS, GetTreeDensity(tile)); break;
case TREE_GROUND_ROUGH: MakeClear(tile, CLEAR_ROUGH, 3); break;
case TREE_GROUND_ROUGH_SNOW: {
uint density = GetTreeDensity(tile);
MakeClear(tile, CLEAR_ROUGH, 3);
MakeSnow(tile, density);
break;
}
default: // snow or desert
if (_settings_game.game_creation.landscape == LandscapeType::Tropic) {
MakeClear(tile, CLEAR_DESERT, GetTreeDensity(tile));
} else {
uint density = GetTreeDensity(tile);
MakeClear(tile, CLEAR_GRASS, 3);
MakeSnow(tile, density);
}
break;
}
}
break;
default:
AddTreeGrowth(tile, 1);
break;
}
MarkTileDirtyByTile(tile);
}
/**
* Decrement the tree tick counter.
* The interval is scaled by map size to allow for the same density regardless of size.
* Adjustment for map sizes below the standard 256 * 256 are handled earlier.
* @return true if the counter was decremented past zero
*/
bool DecrementTreeCounter()
{
/* Ensure _trees_tick_ctr can be decremented past zero only once for the largest map size. */
static_assert(2 * (MAX_MAP_SIZE_BITS - MIN_MAP_SIZE_BITS) - 4 <= std::numeric_limits<uint8_t>::digits);
/* byte underflow */
uint8_t old_trees_tick_ctr = _trees_tick_ctr;
_trees_tick_ctr -= Map::ScaleBySize(1);
return old_trees_tick_ctr <= _trees_tick_ctr;
}
/**
* Place a random tree on a random tile.
* @param rainforest If set the random tile must be in a rainforest zone.
*/
static void PlantRandomTree(bool rainforest)
{
uint32_t r = Random();
TileIndex tile = RandomTileSeed(r);
if (rainforest && GetTropicZone(tile) != TROPICZONE_RAINFOREST) return;
if (!CanPlantTreesOnTile(tile, false)) return;
TreeType tree = GetRandomTreeType(tile, GB(r, 24, 8));
if (tree == TREE_INVALID) return;
PlantTreesOnTile(tile, tree, 0, TreeGrowthStage::Growing1);
}
void OnTick_Trees()
{
/* Don't spread trees if that's not allowed */
if (_settings_game.construction.extra_tree_placement == ETP_NO_SPREAD || _settings_game.construction.extra_tree_placement == ETP_NO_GROWTH_NO_SPREAD) return;
/* Skip some tree ticks for map sizes below 256 * 256. 64 * 64 is 16 times smaller, so
* this is the maximum number of ticks that are skipped. Number of ticks to skip is
* inversely proportional to map size, so that is handled to create a mask. */
int skip = Map::ScaleBySize(16);
if (skip < 16 && (TimerGameTick::counter & (16 / skip - 1)) != 0) return;
/* place a tree at a random rainforest spot */
if (_settings_game.game_creation.landscape == LandscapeType::Tropic) {
for (uint c = Map::ScaleBySize(1); c > 0; c--) {
PlantRandomTree(true);
}
}
if (!DecrementTreeCounter() || _settings_game.construction.extra_tree_placement == ETP_SPREAD_RAINFOREST) return;
/* place a tree at a random spot */
PlantRandomTree(false);
}
static TrackStatus GetTileTrackStatus_Trees(TileIndex, TransportType, uint, DiagDirection)
{
return 0;
}
static void ChangeTileOwner_Trees(TileIndex, Owner, Owner)
{
/* not used */
}
void InitializeTrees()
{
_trees_tick_ctr = 0;
}
static CommandCost TerraformTile_Trees(TileIndex tile, DoCommandFlags flags, int, Slope)
{
return Command<CMD_LANDSCAPE_CLEAR>::Do(flags, tile);
}
extern const TileTypeProcs _tile_type_trees_procs = {
DrawTile_Trees, // draw_tile_proc
GetSlopePixelZ_Trees, // get_slope_z_proc
ClearTile_Trees, // clear_tile_proc
nullptr, // add_accepted_cargo_proc
GetTileDesc_Trees, // get_tile_desc_proc
GetTileTrackStatus_Trees, // get_tile_track_status_proc
nullptr, // click_tile_proc
nullptr, // animate_tile_proc
TileLoop_Trees, // tile_loop_proc
ChangeTileOwner_Trees, // change_tile_owner_proc
nullptr, // add_produced_cargo_proc
nullptr, // vehicle_enter_tile_proc
GetFoundation_Trees, // get_foundation_proc
TerraformTile_Trees, // terraform_tile_proc
};