@@ -1072,87 +1072,87 @@ static bool MakeLake(TileIndex tile, voi
return false;
}
/**
* Widen a river by expanding into adjacent tiles via circular tile search.
* @param tile The tile to try expanding the river into.
* @param data The tile to try surrounding the river around.
* @return Always false, so it continues searching.
*/
static bool RiverMakeWider(TileIndex tile, void *data)
{
/* Don't expand into void tiles. */
if (!IsValidTile(tile)) return false;
/* If the tile is already sea or river, don't expand. */
if (IsWaterTile(tile)) return false;
/* If the tile is at height 0 after terraforming but the ocean hasn't flooded yet, don't build river. */
if (GetTileMaxZ(tile) == 0) return false;
TileIndex origin_tile = *(TileIndex *)data;;
TileIndex origin_tile = *(TileIndex *)data;
Slope cur_slope = GetTileSlope(tile);
Slope desired_slope = GetTileSlope(origin_tile); // Initialize matching the origin tile as a shortcut if no terraforming is needed.
/* Never flow uphill. */
if (GetTileMaxZ(tile) > GetTileMaxZ(origin_tile)) return false;
/* If the new tile can't hold a river tile, try terraforming. */
if (!IsTileFlat(tile) && !IsInclinedSlope(cur_slope)) {
/* Don't try to terraform steep slopes. */
if (IsSteepSlope(cur_slope)) return false;
bool flat_river_found = false;
bool sloped_river_found = false;
/* There are two common possibilities:
* 1. River flat, adjacent tile has one corner lowered.
* 2. River descending, adjacent tile has either one or three corners raised.
/* First, determine the desired slope based on adjacent river tiles. This doesn't necessarily match the origin tile for the CircularTileSearch. */
for (DiagDirection d = DIAGDIR_BEGIN; d < DIAGDIR_END; d++) {
TileIndex other_tile = TileAddByDiagDir(tile, d);
Slope other_slope = GetTileSlope(other_tile);
/* Only consider river tiles. */
if (IsWaterTile(other_tile) && IsRiver(other_tile)) {
/* If the adjacent river tile flows downhill, we need to check where we are relative to the slope. */
if (IsInclinedSlope(other_slope) && GetTileMaxZ(tile) == GetTileMaxZ(other_tile)) {
/* Check for a parallel slope. If we don't find one, we're above or below the slope instead. */
if (GetInclinedSlopeDirection(other_slope) == ChangeDiagDir(d, DIAGDIRDIFF_90RIGHT) ||
GetInclinedSlopeDirection(other_slope) == ChangeDiagDir(d, DIAGDIRDIFF_90LEFT)) {
desired_slope = other_slope;
sloped_river_found = true;
break;
/* If we find an adjacent river tile, remember it. We'll terraform to match it later if we don't find a slope. */
if (IsTileFlat(tile)) flat_river_found = true;
if (IsTileFlat(other_tile)) flat_river_found = true;
/* We didn't find either an inclined or flat river, so we're climbing the wrong slope. Bail out. */
if (!sloped_river_found && !flat_river_found) return false;
/* We didn't find an inclined river, but there is a flat river. */
if (!sloped_river_found && flat_river_found) desired_slope = SLOPE_FLAT;
/* Now that we know the desired slope, it's time to terraform! */
/* If the river is flat and the adjacent tile has one corner lowered, we want to raise it. */
if (desired_slope == SLOPE_FLAT && IsSlopeWithThreeCornersRaised(cur_slope)) {
/* Make sure we're not affecting an existing river slope tile. */
if (IsInclinedSlope(GetTileSlope(other_tile)) && IsWaterTile(other_tile)) return false;
Command<CMD_TERRAFORM_LAND>::Do(DC_EXEC | DC_AUTO, tile, ComplementSlope(cur_slope), true);
/* If the river is descending and the adjacent tile has either one or three corners raised, we want to make it match the slope. */
} else if (IsInclinedSlope(desired_slope)) {
/* Don't break existing flat river tiles by terraforming under them. */
DiagDirection river_direction = ReverseDiagDir(GetInclinedSlopeDirection(desired_slope));
@@ -1182,66 +1182,76 @@ static bool RiverMakeWider(TileIndex til
/* Update cur_slope after possibly terraforming. */
cur_slope = GetTileSlope(tile);
/* Sloped rivers need water both upstream and downstream. */
if (IsInclinedSlope(cur_slope)) {
DiagDirection slope_direction = GetInclinedSlopeDirection(cur_slope);
TileIndex upstream_tile = TileAddByDiagDir(tile, slope_direction);
TileIndex downstream_tile = TileAddByDiagDir(tile, ReverseDiagDir(slope_direction));
/* Don't look outside the map. */
if (!IsValidTile(upstream_tile) || !IsValidTile(downstream_tile)) return false;
/* Downstream might be new ocean created by our terraforming, and it hasn't flooded yet. */
bool downstream_is_ocean = GetTileZ(downstream_tile) == 0 && (GetTileSlope(downstream_tile) == SLOPE_FLAT || IsSlopeWithOneCornerRaised(GetTileSlope(downstream_tile)));
/* If downstream is dry, flat, and not ocean, try making it a river tile. */
if (!IsWaterTile(downstream_tile) && !downstream_is_ocean) {
/* If the tile upstream isn't flat, don't bother. */
if (GetTileSlope(downstream_tile) != SLOPE_FLAT) return false;
MakeRiver(downstream_tile, Random());
MarkTileDirtyByTile(downstream_tile);
/* Remove desert directly around the river tile. */
TileIndex cur_tile = downstream_tile;
CircularTileSearch(&cur_tile, RIVER_OFFSET_DESERT_DISTANCE, RiverModifyDesertZone, nullptr);
/* If upstream is dry and flat, try making it a river tile. */
if (!IsWaterTile(upstream_tile)) {
if (GetTileSlope(upstream_tile) != SLOPE_FLAT) return false;
MakeRiver(upstream_tile, Random());
MarkTileDirtyByTile(upstream_tile);
TileIndex cur_tile = upstream_tile;
/* If the tile slope matches the desired slope, add a river tile. */
if (cur_slope == desired_slope) {
MakeRiver(tile, Random());
MarkTileDirtyByTile(tile);
TileIndex cur_tile = tile;
MarkTileDirtyByTile(cur_tile);
/* Always return false to keep searching. */
* Check whether a river at begin could (logically) flow down to end.
* @param begin The origin of the flow.
* @param end The destination of the flow.
* @return True iff the water can be flowing down.
static bool FlowsDown(TileIndex begin, TileIndex end)
assert(DistanceManhattan(begin, end) == 1);
int heightBegin;
int heightEnd;
Slope slopeBegin = GetTileSlope(begin, &heightBegin);
Slope slopeEnd = GetTileSlope(end, &heightEnd);
return heightEnd <= heightBegin &&
/* Slope either is inclined or flat; rivers don't support other slopes. */
@@ -1473,48 +1483,51 @@ static void CreateRivers()
uint wells = ScaleByMapSize(4 << _settings_game.game_creation.amount_of_rivers);
const uint num_short_rivers = wells - std::max(1u, wells / 10);
SetGeneratingWorldProgress(GWP_RIVER, wells + 256 / 64); // Include the tile loop calls below.
/* Try to create long rivers. */
for (; wells > num_short_rivers; wells--) {
IncreaseGeneratingWorldProgress(GWP_RIVER);
for (int tries = 0; tries < 512; tries++) {
TileIndex t = RandomTile();
if (!CircularTileSearch(&t, 8, FindSpring, nullptr)) continue;
if (std::get<0>(FlowRiver(t, t, _settings_game.game_creation.min_river_length * 4))) break;
/* Try to create short rivers. */
for (; wells != 0; wells--) {
for (int tries = 0; tries < 128; tries++) {
if (std::get<0>(FlowRiver(t, t, _settings_game.game_creation.min_river_length))) break;
/* Widening rivers may have left some tiles requiring to be watered. */
ConvertGroundTilesIntoWaterTiles();
/* Run tile loop to update the ground density. */
for (uint i = 0; i != 256; i++) {
if (i % 64 == 0) IncreaseGeneratingWorldProgress(GWP_RIVER);
RunTileLoop();
* Calculate what height would be needed to cover N% of the landmass.
*
* The function allows both snow and desert/tropic line to be calculated. It
* tries to find the closests height which covers N% of the landmass; it can
* be below or above it.
* Tropic has a mechanism where water and tropic tiles in mountains grow
* inside the desert. To better approximate the requested coverage, this is
* taken into account via an edge histogram, which tells how many neighbouring
* tiles are lower than the tiles of that height. The multiplier indicates how
* severe this has to be taken into account.
* @param coverage A value between 0 and 100 indicating a percentage of landmass that should be covered.
* @param edge_multiplier How much effect neighbouring tiles that are of a lower height level have on the score.
* @return The estimated best height to use to cover N% of the landmass.
Status change: