public bool Equals(MapCoordinates other)
{
return(Row.Equals(other.Row) && Column.Equals(other.Column));
}
////////////////////////////////////////////////////////////////////////////////////////////////////
/// <summary> Computes the FOV. </summary>
///
/// <remarks> Darrell, 8/28/2016. </remarks>
///
/// <param name="octant"> The octant to be scanned. </param>
/// <param name="origin"> The spot from which the FOV is computed. </param>
/// <param name="rangeLimit"> The range limit. </param>
/// <param name="x"> The x coordinate. </param>
/// <param name="top"> The top slope. </param>
/// <param name="bottom"> The bottom slope. </param>
////////////////////////////////////////////////////////////////////////////////////////////////////
private void Compute(int octant, MapCoordinates origin, int rangeLimit, int x, Slope top, Slope bottom)
{
// throughout this function there are references to various parts of tiles. a tile's coordinates refer to its
// center, and the following diagram shows the parts of the tile and the vectors from the origin that pass through
// those parts. given a part of a tile with vector u, a vector v passes above it if v > u and below it if v < u
// g center: y / x
// a------b a top left: (y*2+1) / (x*2-1) i inner top left: (y*4+1) / (x*4-1)
// | /\ | b top right: (y*2+1) / (x*2+1) j inner top right: (y*4+1) / (x*4+1)
// |i/__\j| c bottom left: (y*2-1) / (x*2-1) k inner bottom left: (y*4-1) / (x*4-1)
//e|/| |\|f d bottom right: (y*2-1) / (x*2+1) m inner bottom right: (y*4-1) / (x*4+1)
// |\|__|/| e middle left: (y*2) / (x*2-1)
// |k\ /m| f middle right: (y*2) / (x*2+1) a-d are the corners of the tile
// | \/ | g top center: (y*2+1) / (x*2) e-h are the corners of the inner (wall) diamond
// c------d h bottom center: (y*2-1) / (x*2) i-m are the corners of the inner square (1/2 tile width)
// h
for (; x <= rangeLimit; x++)
{
// compute the Y coordinates of the top and bottom of the sector. we maintain that top > bottom
int topY;
// if top == ?/1 then it must be 1/1 because 0/1 < top <= 1/1. this is special-cased because top
// starts at 1/1 and remains 1/1 as long as it doesn't hit anything, so it's a common case
if (top.X == 1)
{
topY = x;
}
else // top < 1
{
// Get the tile that the top vector enters from the left. Since our coordinates refer to the center of the
// tile, this is (x-0.5)*top+0.5, which can be computed as (x-0.5)*top+0.5 = (2(x+0.5)*top+1)/2 =
// ((2x+1)*top+1)/2. Since top == a/b, this is ((2x+1)*a+b)/2b. If it enters a tile at one of the left
// corners, it will round up, so it'll enter from the bottom-left and never the top-left
//
// The Y coordinate of the tile entered from the left
// Now it's possible that the vector passes from the left side of the tile up into the tile above before
// exiting from the right side of this column so we may need to increment topY
topY = ((x * 2 - 1) * top.Y + top.X) / (top.X * 2);
// If the tile blocks light (i.e. is a wall)...
if (BlocksLight(x, topY, octant, origin))
{
// If the tile entered from the left blocks light, whether it passes into the tile above depends on the shape
// of the wall tile as well as the angle of the vector. If the tile has does not have a beveled top-left
// corner, then it is blocked. The corner is beveled if the tiles above and to the left are not walls. We can
// ignore the tile to the left because if it was a wall tile, the top vector must have entered this tile from
// the bottom-left corner, in which case it can't possibly enter the tile above.
//
// Otherwise, with a beveled top-left corner, the slope of the vector must be greater than or equal to the
// slope of the vector to the top center of the tile (x*2, topY*2+1) in order for it to miss the wall and
// pass into the tile above
if (top.GreaterOrEqual(topY * 2 + 1, x * 2) && !BlocksLight(x, topY + 1, octant, origin))
{
topY++;
}
}
else
{
// Since this tile doesn't block light, there's nothing to stop it from passing into the tile above, and it
// does so if the vector is greater than the vector for the bottom-right corner of the tile above. However,
// there is one additional consideration - later code in this method assumes that if a tile blocks light then
// it must be visible, so if the tile above blocks light we have to make sure the light actually impacts the
// wall shape. There are three cases:
//
// 1) the tile above is clear, in which case the vector must be above the bottom-right corner of the tile above
// 2) the tile above blocks light and does not have a beveled bottom-right corner, in which case the
// vector must be above the bottom-right corner
// 3) the tile above blocks light and does have a beveled bottom-right corner, in which case
// the vector must be above the bottom center of the tile above (i.e. the corner of the beveled edge).
//
// Now it's possible to merge 1 and 2 into a single check, and we get the following: if the tile above and to
// the right is a wall, then the vector must be above the bottom-right corner. Otherwise, the vector must be
// above the bottom center. this works because if the tile above and to the right is a wall, then there are
// two cases:
//
// 1) the tile above is also a wall, in which case we must check against the bottom-right corner,
// 2) the tile above is not a wall, in which case the vector passes into it if it's above the bottom-right corner.
//
// So either way we use the bottom-right corner in that case. Now, if the tile above and to the right
// is not a wall, then we again have two cases:
//
// 1) the tile above is a wall with a beveled edge, in which case we must check against the bottom center
// 2) the tile above is not a wall, in which case it will only be visible if light passes through the inner
// square, and the inner square is guaranteed to be no larger than a wall diamond, so if it wouldn't pass
// through a wall diamond then it can't be visible, so there's no point in incrementing topY even if light
// passes through the corner of the tile above. so we might as well use the bottom center for both cases.
// center
var ax = x * 2;
// use bottom-right if the tile above and right is a wall
if (BlocksLight(x + 1, topY + 1, octant, origin))
{
ax++;
}
if (top.Greater(topY * 2 + 1, ax))
{
topY++;
}
}
}
// if bottom == 0/?, then it's hitting the tile at Y=0 dead center. this is special-cased because
// bottom.Y starts at zero and remains zero as long as it doesn't hit anything, so it's common
int bottomY;
if (bottom.Y == 0)
{
bottomY = 0;
}
else
{
// The tile that the bottom vector enters from the left
// code below assumes that if a tile is a wall then it's visible, so if the tile contains a wall we have to
// ensure that the bottom vector actually hits the wall shape. It misses the wall shape if the top-left corner
// is beveled and bottom >= (bottomY*2+1)/(x*2). Finally, the top-left corner is beveled if the tiles to the
// left and above are clear. we can assume the tile to the left is clear because otherwise the bottom vector
// would be greater, so we only have to check above
bottomY = ((x * 2 - 1) * bottom.Y + bottom.X) / (bottom.X * 2);
if (bottom.GreaterOrEqual(bottomY * 2 + 1, x * 2) && BlocksLight(x, bottomY, octant, origin) &&
!BlocksLight(x, bottomY + 1, octant, origin))
{
bottomY++;
}
}
// Go through the tiles in the column now that we know which ones could possibly be visible
var wasOpaque = -1; // 0:false, 1:true, -1:not applicable
var rangeLimitSq = rangeLimit * rangeLimit;
for (var y = topY; y >= bottomY; y--) // use a signed comparison because y can wrap around when decremented
{
if (rangeLimit < 0 || GetDistanceSq(x, y) <= rangeLimitSq) // skip the tile if it's out of visual range
{
var isOpaque = BlocksLight(x, y, octant, origin);
// every tile where topY > y > bottomY is guaranteed to be visible. also, the code that initializes topY and
// bottomY guarantees that if the tile is opaque then it's visible. so we only have to do extra work for the
// case where the tile is clear and y == topY or y == bottomY. if y == topY then we have to make sure that
// the top vector is above the bottom-right corner of the inner square. if y == bottomY then we have to make
// sure that the bottom vector is below the top-left corner of the inner square
var isVisible =
isOpaque || ((y != topY || top.Greater(y * 4 - 1, x * 4 + 1)) && (y != bottomY || bottom.Less(y * 4 + 1, x * 4 - 1)));
// NOTE: if you want the algorithm to be either fully or mostly symmetrical, replace the line above with the
// following line (and uncomment the Slope.LessOrEqual method). the line ensures that a clear tile is visible
// only if there's an unobstructed line to its center. if you want it to be fully symmetrical, also remove
// the "isOpaque ||" part and see NOTE comments further down
// bool isVisible = isOpaque || ((y != topY || top.GreaterOrEqual(y, x)) && (y != bottomY || bottom.LessOrEqual(y, x)));
if (isVisible)
{
SetVisible(x, y, octant, origin);
}
// if we found a transition from clear to opaque or vice versa, adjust the top and bottom vectors
// but don't bother adjusting them if this is the last column anyway
if (x != rangeLimit)
{
if (isOpaque)
{
// If we found a transition from clear to opaque, this sector is done in this column,
// so adjust the bottom vector upward and continue processing it in the next column.
// If the opaque tile has a beveled top-left corner, move the bottom vector up to the top center.
// Otherwise, move it up to the top left. The corner is beveled if the tiles above and to the left are
// clear. we can assume the tile to the left is clear because otherwise the vector would be higher, so
// we only have to check the tile above.
if (wasOpaque == 0)
{
// top center by default
int nx = x * 2, ny = y * 2 + 1;
// NOTE: If you're using full symmetry and want more expansive walls (recommended), comment out the next if statement
if (BlocksLight(x, y + 1, octant, origin))
{
// top left if the corner is not beveled
nx--;
}
// We have to maintain the invariant that top > bottom, so the new sector
// created by adjusting the bottom is only valid if that's the case
// if we're at the bottom of the column, then just adjust the current sector rather than recursing
// since there's no chance that this sector can be split in two by a later transition back to clear
if (top.Greater(ny, nx))
{
// don't recurse unless necessary
if (y == bottomY)
{
bottom = new Slope(ny, nx);
break;
}
Compute(octant, origin, rangeLimit, x + 1, top, new Slope(ny, nx));
}
// the new bottom is greater than or equal to the top, so the new sector is empty and we'll ignore
// it. if we're at the bottom of the column, we'd normally adjust the current sector rather than
else
{
// recursing, so that invalidates the current sector and we're done
if (y == bottomY)
{
return;
}
}
}
wasOpaque = 1;
}
else
{
// If we found a transition from opaque to clear, adjust the top vector downwards
if (wasOpaque > 0)
{
// If the opaque tile has a beveled bottom-right corner, move the top vector down to the bottom center -
// otherwise, move it down to the bottom right. The corner is beveled if the tiles below and to the right
// are clear. We know the tile below is clear because that's the current tile, so just check to the right
// The bottom of the opaque tile (oy*2-1) equals the top of this tile (y*2+1)
int nx = x * 2, ny = y * 2 + 1;
// NOTE: if you're using full symmetry and want more expansive walls (recommended), comment out the next line
// Check the right of the opaque tile (y+1), not this one
if (BlocksLight(x + 1, y + 1, octant, origin))
{
nx++;
}
// We have to maintain the invariant that top > bottom. if not, the sector is empty and we're done
if (bottom.GreaterOrEqual(ny, nx))
{
return;
}
top = new Slope(ny, nx);
}
wasOpaque = 0;
}
}
}
}
// if the column didn't end in a clear tile, then there's no reason to continue processing the current sector
// because that means either 1) wasOpaque == -1, implying that the sector is empty or at its range limit, or 2)
// wasOpaque == 1, implying that we found a transition from clear to opaque and we recursed and we never found
// a transition back to clear, so there's nothing else for us to do that the recursive method hasn't already. (if
// we didn't recurse (because y == bottomY), it would have executed a break, leaving wasOpaque equal to 0.)
if (wasOpaque != 0)
{
break;
}
}
}
////////////////////////////////////////////////////////////////////////////////////////////////////
/// <summary> Constructor from a 2D character layout. </summary>
///
/// <remarks> Darrellp, 9/27/2011. </remarks>
///
/// <param name="layout"> The layout. </param>
/// <param name="location"> The location. </param>
/// <param name="exits"> The exits. </param>
////////////////////////////////////////////////////////////////////////////////////////////////////
internal GenericRoom(char[][] layout, MapCoordinates location, List <GenericRoom> exits)
{
Setup(layout, location, exits);
}
////////////////////////////////////////////////////////////////////////////////////////////////////
/// <summary> Return true if a location is part of this room's floor. </summary>
///
/// <remarks> Darrellp, 9/29/2011. </remarks>
///
/// <param name="location"> The location in global coordinates to be tested. </param>
///
/// <returns> true if location is part of our room, false if not. </returns>
////////////////////////////////////////////////////////////////////////////////////////////////////
public bool ContainsPosition(MapCoordinates location)
{
return(location.Column >= Left && location.Column <= Right &&
location.Row >= Top && location.Row <= Bottom &&
this[location] == '.');
}
////////////////////////////////////////////////////////////////////////////////////////////////////
/// <summary> Sets a room at a grid location. </summary>
///
/// <remarks> Darrellp, 9/23/2011. </remarks>
///
/// <param name="gridLocation"> The grid location. </param>
/// <param name="room"> The room to be placed there.. </param>
////////////////////////////////////////////////////////////////////////////////////////////////////
private void SetRoomAt(MapCoordinates gridLocation, RectangularRoom room)
{
_rooms[gridLocation.Column][gridLocation.Row] = room;
}
////////////////////////////////////////////////////////////////////////////////////////////////////
/// <summary> Retrieve the room at a grid location. </summary>
///
/// <remarks> Darrellp, 9/23/2011. </remarks>
///
/// <param name="gridLocation"> The grid location. </param>
///
/// <returns> The room occupying that grid location. </returns>
////////////////////////////////////////////////////////////////////////////////////////////////////
private RectangularRoom RoomAt(MapCoordinates gridLocation)
{
return(!WithinGrid(gridLocation) ? null : _rooms[gridLocation.Column][gridLocation.Row]);
}
////////////////////////////////////////////////////////////////////////////////////////////////////
/// <summary> Locates the rooms on the map. </summary>
///
/// <remarks> Darrellp, 9/19/2011. </remarks>
///
/// <param name="map"> The map to be excavated. </param>
////////////////////////////////////////////////////////////////////////////////////////////////////
private void LocateRooms(IRoomsMap map)
{
// Max number of cells we can fit with at least base cell size
int gridWidth = map.Width / _baseCellWidth;
int gridHeight = map.Height / _baseCellHeight;
// Size of cells we can manage total
int baseRoomWidth = map.Width / gridWidth;
int baseRoomHeight = map.Height / gridHeight;
// Remainders for Bresenham algorithm
int widthRemainder = map.Width % baseRoomWidth;
int heightRemainder = map.Height % baseRoomHeight;
// Tally for Bresenham
int widthTally = gridWidth / 2;
int heightTally = gridHeight / 2;
// First column is on the left
int mapColumn = 0;
// Array of rooms in the grid
_rooms = new RectangularRoom[gridWidth][];
// For each grid column
for (int gridColumn = 0; gridColumn < gridWidth; gridColumn++)
{
// Reset the map row to 0
int mapRow = 0;
// Determine the current map column
int currentWidth = baseRoomWidth;
widthTally += widthRemainder;
// Do we need to bump width ala Bresenham?
if (widthTally >= gridWidth)
{
// Bump width
currentWidth++;
widthTally -= gridWidth;
}
// Create the row of rooms for this column
_rooms[gridColumn] = new RectangularRoom[gridHeight];
// For each row of the grid
for (int gridRow = 0; gridRow < gridHeight; gridRow++)
{
// Determine the current map row
int currentHeight = baseRoomHeight;
heightTally += heightRemainder;
// Do we need to bump height ala Bresenham?
if (heightTally >= gridHeight)
{
// Bump height
currentHeight++;
heightTally -= gridHeight;
}
// Create a room in the grid cell
MapCoordinates gridLocation = new MapCoordinates(gridColumn, gridRow);
MapCoordinates cellLocation = new MapCoordinates(mapColumn, mapRow);
RectangularRoom room = CreateRoomInCell(gridLocation, cellLocation, currentWidth, currentHeight);
// Place it in the grid
_rooms[gridColumn][gridRow] = room;
// Advance the map row
mapRow += currentHeight;
}
// Advance the map column
mapColumn += currentWidth;
}
}
////////////////////////////////////////////////////////////////////////////////////////////////////
/// <summary> Merge two rooms. </summary>
///
/// <remarks> Named as though dir was vertical. Darrellp, 9/22/2011. </remarks>
///
/// <param name="topRoomsGridLocation"> The location of the top room in the grid. </param>
/// <param name="dir"> The direction of the merge. </param>
////////////////////////////////////////////////////////////////////////////////////////////////////
private void MergeTwoRooms(MapCoordinates topRoomsGridLocation, Dir dir)
{
// Get grid coordinates of the other room
MapCoordinates bottomRoomsGridLocation = topRoomsGridLocation.NextLarger(dir);
Dir otherDir = MapCoordinates.OtherDirection(dir);
// Retrieve both rooms
RectangularRoom topRoom = RoomAt(topRoomsGridLocation);
RectangularRoom bottomRoom = RoomAt(bottomRoomsGridLocation);
// Are the rooms unmergable?
if (!CheckMergeForOverlap(topRoom, bottomRoom, otherDir))
{
// Return and don't merge them - use normal corridors
return;
}
// Remove their generic counterparts
_mapRoomToGenericRooms.Remove(topRoom);
_mapRoomToGenericRooms.Remove(bottomRoom);
// Get their current coordinates, etc.
int topRoomsBottom = topRoom.LargeCoord(dir);
int topRoomsTop = topRoom.SmallCoord(dir);
int bottomRoomsTop = bottomRoom.SmallCoord(dir);
int bottomRoomsHeight = bottomRoom.Size(dir);
int topRoomsWidth = topRoom.Size(otherDir);
int bottomRoomsWidth = bottomRoom.Size(otherDir);
// Pick a random spot between the rooms to merge them
// This will be the new inside coord of the small coordinate room
int mergeRow = _rnd.Next(topRoomsBottom, bottomRoomsTop);
// Determine all the new coordinates
int topRoomsNewHeight = mergeRow - topRoomsTop + 1;
int bottomRoomsNewHeight = bottomRoomsTop - mergeRow + bottomRoomsHeight - 1;
MapCoordinates bottomRoomsLocation = bottomRoom.Location;
bottomRoomsLocation[dir] = mergeRow + 1;
// Create our new expanded rooms
RectangularRoom roomTopNew = RectangularRoom.CreateUndirectional(
topRoom.Location,
topRoomsNewHeight,
topRoomsWidth,
topRoomsGridLocation[dir],
topRoomsGridLocation[otherDir],
dir);
RectangularRoom roomBottomNew = RectangularRoom.CreateUndirectional(
bottomRoomsLocation,
bottomRoomsNewHeight,
bottomRoomsWidth,
bottomRoomsGridLocation[dir],
bottomRoomsGridLocation[otherDir],
dir);
// Install the new rooms
SetRoomAt(topRoomsGridLocation, roomTopNew);
SetRoomAt(bottomRoomsGridLocation, roomBottomNew);
// Create the new generic rooms
// We don't create the single merged generic room until we excavate because we don't know
// the layout until then.
_mapRoomToGenericRooms[roomTopNew] = roomTopNew.ToGeneric();
_mapRoomToGenericRooms[roomBottomNew] = roomBottomNew.ToGeneric();
// Mark this in our merges structure
_merges.Connect(topRoomsGridLocation, bottomRoomsGridLocation);
}
////////////////////////////////////////////////////////////////////////////////////////////////////
/// <summary> Excavate a merge between two rooms. </summary>
///
/// <remarks>
/// Names are named as though dir was vertical and dirOther horizontal. Darrellp, 9/22/2011.
/// </remarks>
///
/// <param name="map"> The map. </param>
/// <param name="topRoom"> The top room. </param>
/// <param name="bottomRoom"> The bottom room. </param>
/// <param name="dir"> The dir. </param>
////////////////////////////////////////////////////////////////////////////////////////////////////
private void ExcavateMerge(IRoomsMap map, RectangularRoom topRoom, RectangularRoom bottomRoom, Dir dir)
{
// Get the opposite direction
Dir dirOther = MapCoordinates.OtherDirection(dir);
// Are the rooms unmergable?
if (!CheckOverlap(topRoom, bottomRoom, dirOther))
{
// Should have caught this in MergeTwoRooms - throw exception
throw new RogueException("Non-overlapping rooms made it to ExcavateMerge");
}
// Get the appropriate coordinates
int topRoomsLeft = topRoom.Location[dirOther];
int topRoomsRight = topRoomsLeft + topRoom.Size(dirOther) - 1;
int bottomRoomsLeft = bottomRoom.Location[dirOther];
int bottomRoomsRight = bottomRoomsLeft + bottomRoom.Size(dirOther) - 1;
// Get the high and low points of the overlap
int overlapLeft = Math.Max(topRoomsLeft, bottomRoomsLeft) + 1;
int overlapRight = Math.Min(topRoomsRight, bottomRoomsRight) - 1;
// Create our new merged generic room
GenericRoom groomTop = _mapRoomToGenericRooms[topRoom];
GenericRoom groomBottom = _mapRoomToGenericRooms[bottomRoom];
groomTop.CombineWith(groomBottom);
// For each column in the grid
foreach (RectangularRoom[] roomColumn in _rooms)
{
// For each row in the grid
for (int iRow = 0; iRow < _rooms[0].Length; iRow++)
{
// Get the rect room at that spot
RectangularRoom room = roomColumn[iRow];
// Is it mapped to our defunct bottom room?
if (_mapRoomToGenericRooms[room] == groomBottom)
{
// Map it to our shiny new top room
_mapRoomToGenericRooms[room] = groomTop;
}
}
}
// Get the location we're going to start the clearing at
int topRoomsBottom = topRoom.Location[dir] + topRoom.Size(dir) - 1;
MapCoordinates currentLocation = MapCoordinates.CreateUndirectional(topRoomsBottom, overlapLeft, dir);
char floorChar = TerrainFactory.TerrainToChar(TerrainType.Floor);
// For each spot along the overlap
for (int iCol = overlapLeft; iCol <= overlapRight; iCol++)
{
// Clear out the two walls of the abutting rooms
currentLocation[dirOther] = iCol;
map[currentLocation].Terrain = TerrainType.Floor;
groomTop[currentLocation] = floorChar;
currentLocation[dir] = topRoomsBottom + 1;
map[currentLocation].Terrain = TerrainType.Floor;
groomTop[currentLocation] = floorChar;
currentLocation[dir] = topRoomsBottom;
}
Debug.Assert(groomBottom == groomTop || !_mapRoomToGenericRooms.ContainsValue(groomBottom));
}