-// (Orthodox) Chess rules are defined in ChessRules class.
-// Variants generally inherit from it, and modify some parts.
-
-class PiPo //Piece+Position
-{
- // o: {piece[p], color[c], posX[x], posY[y]}
- constructor(o)
- {
- this.p = o.p;
- this.c = o.c;
- this.x = o.x;
- this.y = o.y;
- }
-}
-
-// TODO: for animation, moves should contains "moving" and "fading" maybe...
-class Move
-{
- // o: {appear, vanish, [start,] [end,]}
- // appear,vanish = arrays of PiPo
- // start,end = coordinates to apply to trigger move visually (think castle)
- constructor(o)
- {
- this.appear = o.appear;
- this.vanish = o.vanish;
- this.start = !!o.start ? o.start : {x:o.vanish[0].x, y:o.vanish[0].y};
- this.end = !!o.end ? o.end : {x:o.appear[0].x, y:o.appear[0].y};
- }
-}
-
-// NOTE: x coords = top to bottom; y = left to right (from white player perspective)
-class ChessRules
-{
- //////////////
- // MISC UTILS
-
- static get HasFlags() { return true; } //some variants don't have flags
-
- static get HasEnpassant() { return true; } //some variants don't have ep.
-
- // Path to pieces
- static getPpath(b)
- {
- return b; //usual pieces in pieces/ folder
- }
-
- // Turn "wb" into "B" (for FEN)
- static board2fen(b)
- {
- return b[0]=='w' ? b[1].toUpperCase() : b[1];
- }
-
- // Turn "p" into "bp" (for board)
- static fen2board(f)
- {
- return f.charCodeAt()<=90 ? "w"+f.toLowerCase() : "b"+f;
- }
-
- // Check if FEN describe a position
- static IsGoodFen(fen)
- {
- const fenParsed = V.ParseFen(fen);
- // 1) Check position
- if (!V.IsGoodPosition(fenParsed.position))
- return false;
- // 2) Check turn
- if (!fenParsed.turn || !V.IsGoodTurn(fenParsed.turn))
- return false;
- // 3) Check moves count
- if (!fenParsed.movesCount || !(parseInt(fenParsed.movesCount) >= 0))
- return false;
- // 4) Check flags
- if (V.HasFlags && (!fenParsed.flags || !V.IsGoodFlags(fenParsed.flags)))
- return false;
- // 5) Check enpassant
- if (V.HasEnpassant &&
- (!fenParsed.enpassant || !V.IsGoodEnpassant(fenParsed.enpassant)))
- {
- return false;
- }
- return true;
- }
-
- // Is position part of the FEN a priori correct?
- static IsGoodPosition(position)
- {
- if (position.length == 0)
- return false;
- const rows = position.split("/");
- if (rows.length != V.size.x)
- return false;
- for (let row of rows)
- {
- let sumElts = 0;
- for (let i=0; i<row.length; i++)
- {
- if (V.PIECES.includes(row[i].toLowerCase()))
- sumElts++;
- else
- {
- const num = parseInt(row[i]);
- if (isNaN(num))
- return false;
- sumElts += num;
- }
- }
- if (sumElts != V.size.y)
- return false;
- }
- return true;
- }
-
- // For FEN checking
- static IsGoodTurn(turn)
- {
- return ["w","b"].includes(turn);
- }
-
- // For FEN checking
- static IsGoodFlags(flags)
- {
- return !!flags.match(/^[01]{4,4}$/);
- }
-
- static IsGoodEnpassant(enpassant)
- {
- if (enpassant != "-")
- {
- const ep = V.SquareToCoords(fenParsed.enpassant);
- if (isNaN(ep.x) || !V.OnBoard(ep))
- return false;
- }
- return true;
- }
-
- // 3 --> d (column number to letter)
- static CoordToColumn(colnum)
- {
- return String.fromCharCode(97 + colnum);
- }
-
- // d --> 3 (column letter to number)
- static ColumnToCoord(column)
- {
- return column.charCodeAt(0) - 97;
- }
-
- // a4 --> {x:3,y:0}
- static SquareToCoords(sq)
- {
- return {
- // NOTE: column is always one char => max 26 columns
- // row is counted from black side => subtraction
- x: V.size.x - parseInt(sq.substr(1)),
- y: sq[0].charCodeAt() - 97
- };
- }
-
- // {x:0,y:4} --> e8
- static CoordsToSquare(coords)
- {
- return V.CoordToColumn(coords.y) + (V.size.x - coords.x);
- }
-
- // Aggregates flags into one object
- aggregateFlags()
- {
- return this.castleFlags;
- }
-
- // Reverse operation
- disaggregateFlags(flags)
- {
- this.castleFlags = flags;
- }
-
- // En-passant square, if any
- getEpSquare(moveOrSquare)
- {
- if (!moveOrSquare)
- return undefined;
- if (typeof moveOrSquare === "string")
- {
- const square = moveOrSquare;
- if (square == "-")
- return undefined;
- return V.SquareToCoords(square);
- }
- // Argument is a move:
- const move = moveOrSquare;
- const [sx,sy,ex] = [move.start.x,move.start.y,move.end.x];
- // TODO: next conditions are first for Atomic, and third for Checkered
- if (move.appear.length > 0 && move.appear[0].p == V.PAWN && ["w","b"].includes(move.appear[0].c) && Math.abs(sx - ex) == 2)
- {
- return {
- x: (sx + ex)/2,
- y: sy
- };
- }
- return undefined; //default
- }
-
- // Can thing on square1 take thing on square2
- canTake([x1,y1], [x2,y2])
- {
- return this.getColor(x1,y1) !== this.getColor(x2,y2);
- }
-
- // Is (x,y) on the chessboard?
- static OnBoard(x,y)
- {
- return (x>=0 && x<V.size.x && y>=0 && y<V.size.y);
- }
-
- // Used in interface: 'side' arg == player color
- canIplay(side, [x,y])
- {
- return (this.turn == side && this.getColor(x,y) == side);
- }
-
- // On which squares is color under check ? (for interface)
- getCheckSquares(color)
- {
- return this.isAttacked(this.kingPos[color], [V.GetOppCol(color)])
- ? [JSON.parse(JSON.stringify(this.kingPos[color]))] //need to duplicate!
- : [];
- }
-
- /////////////
- // FEN UTILS
-
- // Setup the initial random (assymetric) position
- static GenRandInitFen()
- {
- let pieces = { "w": new Array(8), "b": new Array(8) };
- // Shuffle pieces on first and last rank
- for (let c of ["w","b"])
- {
- let positions = _.range(8);
-
- // Get random squares for bishops
- let randIndex = 2 * _.random(3);
- const bishop1Pos = positions[randIndex];
- // The second bishop must be on a square of different color
- let randIndex_tmp = 2 * _.random(3) + 1;
- const bishop2Pos = positions[randIndex_tmp];
- // Remove chosen squares
- positions.splice(Math.max(randIndex,randIndex_tmp), 1);
- positions.splice(Math.min(randIndex,randIndex_tmp), 1);
-
- // Get random squares for knights
- randIndex = _.random(5);
- const knight1Pos = positions[randIndex];
- positions.splice(randIndex, 1);
- randIndex = _.random(4);
- const knight2Pos = positions[randIndex];
- positions.splice(randIndex, 1);
-
- // Get random square for queen
- randIndex = _.random(3);
- const queenPos = positions[randIndex];
- positions.splice(randIndex, 1);
-
- // Rooks and king positions are now fixed,
- // because of the ordering rook-king-rook
- const rook1Pos = positions[0];
- const kingPos = positions[1];
- const rook2Pos = positions[2];
-
- // Finally put the shuffled pieces in the board array
- pieces[c][rook1Pos] = 'r';
- pieces[c][knight1Pos] = 'n';
- pieces[c][bishop1Pos] = 'b';
- pieces[c][queenPos] = 'q';
- pieces[c][kingPos] = 'k';
- pieces[c][bishop2Pos] = 'b';
- pieces[c][knight2Pos] = 'n';
- pieces[c][rook2Pos] = 'r';
- }
- return pieces["b"].join("") +
- "/pppppppp/8/8/8/8/PPPPPPPP/" +
- pieces["w"].join("").toUpperCase() +
- " w 0 1111 -"; //add turn + flags + enpassant
- }
-
- // "Parse" FEN: just return untransformed string data
- static ParseFen(fen)
- {
- const fenParts = fen.split(" ");
- let res =
- {
- position: fenParts[0],
- turn: fenParts[1],
- movesCount: fenParts[2],
- };
- let nextIdx = 3;
- if (V.HasFlags)
- Object.assign(res, {flags: fenParts[nextIdx++]});
- if (V.HasEnpassant)
- Object.assign(res, {enpassant: fenParts[nextIdx]});
- return res;
- }
-
- // Return current fen (game state)
- getFen()
- {
- return this.getBaseFen() + " " +
- this.getTurnFen() + " " + this.movesCount +
- (V.HasFlags ? (" " + this.getFlagsFen()) : "") +
- (V.HasEnpassant ? (" " + this.getEnpassantFen()) : "");
- }
-
- // Position part of the FEN string
- getBaseFen()
- {
- let position = "";
- for (let i=0; i<V.size.x; i++)
- {
- let emptyCount = 0;
- for (let j=0; j<V.size.y; j++)
- {
- if (this.board[i][j] == V.EMPTY)
- emptyCount++;
- else
- {
- if (emptyCount > 0)
- {
- // Add empty squares in-between
- position += emptyCount;
- emptyCount = 0;
- }
- position += V.board2fen(this.board[i][j]);
- }
- }
- if (emptyCount > 0)
- {
- // "Flush remainder"
- position += emptyCount;
- }
- if (i < V.size.x - 1)
- position += "/"; //separate rows
- }
- return position;
- }
-
- getTurnFen()
- {
- return this.turn;
- }
-
- // Flags part of the FEN string
- getFlagsFen()
- {
- let flags = "";
- // Add castling flags
- for (let i of ['w','b'])
- {
- for (let j=0; j<2; j++)
- flags += (this.castleFlags[i][j] ? '1' : '0');
- }
- return flags;
- }
-
- // Enpassant part of the FEN string
- getEnpassantFen()
- {
- const L = this.epSquares.length;
- if (!this.epSquares[L-1])
- return "-"; //no en-passant
- return V.CoordsToSquare(this.epSquares[L-1]);
- }
-
- // Turn position fen into double array ["wb","wp","bk",...]
- static GetBoard(position)
- {
- const rows = position.split("/");
- let board = doubleArray(V.size.x, V.size.y, "");
- for (let i=0; i<rows.length; i++)
- {
- let j = 0;
- for (let indexInRow = 0; indexInRow < rows[i].length; indexInRow++)
- {
- const character = rows[i][indexInRow];
- const num = parseInt(character);
- if (!isNaN(num))
- j += num; //just shift j
- else //something at position i,j
- board[i][j++] = V.fen2board(character);
- }
- }
- return board;
- }
-
- // Extract (relevant) flags from fen
- setFlags(fenflags)
- {
- // white a-castle, h-castle, black a-castle, h-castle
- this.castleFlags = {'w': [true,true], 'b': [true,true]};
- if (!fenflags)
- return;
- for (let i=0; i<4; i++)
- this.castleFlags[i < 2 ? 'w' : 'b'][i%2] = (fenflags.charAt(i) == '1');
- }
-
- //////////////////
- // INITIALIZATION
-
- // Fen string fully describes the game state
- constructor(fen)
- {
- const fenParsed = V.ParseFen(fen);
- this.board = V.GetBoard(fenParsed.position);
- this.turn = fenParsed.turn[0]; //[0] to work with MarseilleRules
- this.movesCount = parseInt(fenParsed.movesCount);
- this.setOtherVariables(fen);
- }
-
- // Scan board for kings and rooks positions
- scanKingsRooks(fen)
- {
- this.INIT_COL_KING = {'w':-1, 'b':-1};
- this.INIT_COL_ROOK = {'w':[-1,-1], 'b':[-1,-1]};
- this.kingPos = {'w':[-1,-1], 'b':[-1,-1]}; //squares of white and black king
- const fenRows = V.ParseFen(fen).position.split("/");
- for (let i=0; i<fenRows.length; i++)
- {
- let k = 0; //column index on board
- for (let j=0; j<fenRows[i].length; j++)
- {
- switch (fenRows[i].charAt(j))
- {
- case 'k':
- this.kingPos['b'] = [i,k];
- this.INIT_COL_KING['b'] = k;
- break;
- case 'K':
- this.kingPos['w'] = [i,k];
- this.INIT_COL_KING['w'] = k;
- break;
- case 'r':
- if (this.INIT_COL_ROOK['b'][0] < 0)
- this.INIT_COL_ROOK['b'][0] = k;
- else
- this.INIT_COL_ROOK['b'][1] = k;
- break;
- case 'R':
- if (this.INIT_COL_ROOK['w'][0] < 0)
- this.INIT_COL_ROOK['w'][0] = k;
- else
- this.INIT_COL_ROOK['w'][1] = k;
- break;
- default:
- const num = parseInt(fenRows[i].charAt(j));
- if (!isNaN(num))
- k += (num-1);
- }
- k++;
- }
- }
- }
-
- // Some additional variables from FEN (variant dependant)
- setOtherVariables(fen)
- {
- // Set flags and enpassant:
- const parsedFen = V.ParseFen(fen);
- if (V.HasFlags)
- this.setFlags(parsedFen.flags);
- if (V.HasEnpassant)
- {
- const epSq = parsedFen.enpassant != "-"
- ? V.SquareToCoords(parsedFen.enpassant)
- : undefined;
- this.epSquares = [ epSq ];
- }
- // Search for king and rooks positions:
- this.scanKingsRooks(fen);
- }
-
- /////////////////////
- // GETTERS & SETTERS
-
- static get size()
- {
- return {x:8, y:8};
- }
-
- // Color of thing on suqare (i,j). 'undefined' if square is empty
- getColor(i,j)
- {
- return this.board[i][j].charAt(0);
- }
-
- // Piece type on square (i,j). 'undefined' if square is empty
- getPiece(i,j)
- {
- return this.board[i][j].charAt(1);
- }
-
- // Get opponent color
- static GetOppCol(color)
- {
- return (color=="w" ? "b" : "w");
- }
-
- // Get next color (for compatibility with 3 and 4 players games)
- static GetNextCol(color)
- {
- return V.GetOppCol(color);
- }
-
- // Pieces codes (for a clearer code)
- static get PAWN() { return 'p'; }
- static get ROOK() { return 'r'; }
- static get KNIGHT() { return 'n'; }
- static get BISHOP() { return 'b'; }
- static get QUEEN() { return 'q'; }
- static get KING() { return 'k'; }
-
- // For FEN checking:
- static get PIECES()
- {
- return [V.PAWN,V.ROOK,V.KNIGHT,V.BISHOP,V.QUEEN,V.KING];
- }
-
- // Empty square
- static get EMPTY() { return ""; }
-
- // Some pieces movements
- static get steps()
- {
- return {
- 'r': [ [-1,0],[1,0],[0,-1],[0,1] ],
- 'n': [ [-1,-2],[-1,2],[1,-2],[1,2],[-2,-1],[-2,1],[2,-1],[2,1] ],
- 'b': [ [-1,-1],[-1,1],[1,-1],[1,1] ],
- };
- }
-
- ////////////////////
- // MOVES GENERATION
-
- // All possible moves from selected square (assumption: color is OK)
- getPotentialMovesFrom([x,y])
- {
- switch (this.getPiece(x,y))
- {
- case V.PAWN:
- return this.getPotentialPawnMoves([x,y]);
- case V.ROOK:
- return this.getPotentialRookMoves([x,y]);
- case V.KNIGHT:
- return this.getPotentialKnightMoves([x,y]);
- case V.BISHOP:
- return this.getPotentialBishopMoves([x,y]);
- case V.QUEEN:
- return this.getPotentialQueenMoves([x,y]);
- case V.KING:
- return this.getPotentialKingMoves([x,y]);
- }
- }
-
- // Build a regular move from its initial and destination squares.
- // tr: transformation
- getBasicMove([sx,sy], [ex,ey], tr)
- {
- let mv = new Move({
- appear: [
- new PiPo({
- x: ex,
- y: ey,
- c: !!tr ? tr.c : this.getColor(sx,sy),
- p: !!tr ? tr.p : this.getPiece(sx,sy)
- })
- ],
- vanish: [
- new PiPo({
- x: sx,
- y: sy,
- c: this.getColor(sx,sy),
- p: this.getPiece(sx,sy)
- })
- ]
- });
-
- // The opponent piece disappears if we take it
- if (this.board[ex][ey] != V.EMPTY)
- {
- mv.vanish.push(
- new PiPo({
- x: ex,
- y: ey,
- c: this.getColor(ex,ey),
- p: this.getPiece(ex,ey)
- })
- );
- }
- return mv;
- }
-
- // Generic method to find possible moves of non-pawn pieces:
- // "sliding or jumping"
- getSlideNJumpMoves([x,y], steps, oneStep)
- {
- const color = this.getColor(x,y);
- let moves = [];
- outerLoop:
- for (let step of steps)
- {
- let i = x + step[0];
- let j = y + step[1];
- while (V.OnBoard(i,j) && this.board[i][j] == V.EMPTY)
- {
- moves.push(this.getBasicMove([x,y], [i,j]));
- if (oneStep !== undefined)
- continue outerLoop;
- i += step[0];
- j += step[1];
- }
- if (V.OnBoard(i,j) && this.canTake([x,y], [i,j]))
- moves.push(this.getBasicMove([x,y], [i,j]));
- }
- return moves;
- }
-
- // What are the pawn moves from square x,y ?
- getPotentialPawnMoves([x,y])
- {
- const color = this.turn;
- let moves = [];
- const [sizeX,sizeY] = [V.size.x,V.size.y];
- const shiftX = (color == "w" ? -1 : 1);
- const firstRank = (color == 'w' ? sizeX-1 : 0);
- const startRank = (color == "w" ? sizeX-2 : 1);
- const lastRank = (color == "w" ? 0 : sizeX-1);
- const pawnColor = this.getColor(x,y); //can be different for checkered
-
- // NOTE: next condition is generally true (no pawn on last rank)
- if (x+shiftX >= 0 && x+shiftX < sizeX)
- {
- const finalPieces = x + shiftX == lastRank
- ? [V.ROOK,V.KNIGHT,V.BISHOP,V.QUEEN]
- : [V.PAWN]
- // One square forward
- if (this.board[x+shiftX][y] == V.EMPTY)
- {
- for (let piece of finalPieces)
- {
- moves.push(this.getBasicMove([x,y], [x+shiftX,y],
- {c:pawnColor,p:piece}));
- }
- // Next condition because pawns on 1st rank can generally jump
- if ([startRank,firstRank].includes(x)
- && this.board[x+2*shiftX][y] == V.EMPTY)
- {
- // Two squares jump
- moves.push(this.getBasicMove([x,y], [x+2*shiftX,y]));
- }
- }
- // Captures
- for (let shiftY of [-1,1])
- {
- if (y + shiftY >= 0 && y + shiftY < sizeY
- && this.board[x+shiftX][y+shiftY] != V.EMPTY
- && this.canTake([x,y], [x+shiftX,y+shiftY]))
- {
- for (let piece of finalPieces)
- {
- moves.push(this.getBasicMove([x,y], [x+shiftX,y+shiftY],
- {c:pawnColor,p:piece}));
- }
- }
- }
- }
-
- if (V.HasEnpassant)
- {
- // En passant
- const Lep = this.epSquares.length;
- const epSquare = this.epSquares[Lep-1]; //always at least one element
- if (!!epSquare && epSquare.x == x+shiftX && Math.abs(epSquare.y - y) == 1)
- {
- let enpassantMove = this.getBasicMove([x,y], [epSquare.x,epSquare.y]);
- enpassantMove.vanish.push({
- x: x,
- y: epSquare.y,
- p: 'p',
- c: this.getColor(x,epSquare.y)
- });
- moves.push(enpassantMove);
- }
- }
-
- return moves;
- }
-
- // What are the rook moves from square x,y ?
- getPotentialRookMoves(sq)
- {
- return this.getSlideNJumpMoves(sq, V.steps[V.ROOK]);
- }
-
- // What are the knight moves from square x,y ?
- getPotentialKnightMoves(sq)
- {
- return this.getSlideNJumpMoves(sq, V.steps[V.KNIGHT], "oneStep");
- }
-
- // What are the bishop moves from square x,y ?
- getPotentialBishopMoves(sq)
- {
- return this.getSlideNJumpMoves(sq, V.steps[V.BISHOP]);
- }
-
- // What are the queen moves from square x,y ?
- getPotentialQueenMoves(sq)
- {
- return this.getSlideNJumpMoves(sq,
- V.steps[V.ROOK].concat(V.steps[V.BISHOP]));
- }
-
- // What are the king moves from square x,y ?
- getPotentialKingMoves(sq)
- {
- // Initialize with normal moves
- let moves = this.getSlideNJumpMoves(sq,
- V.steps[V.ROOK].concat(V.steps[V.BISHOP]), "oneStep");
- return moves.concat(this.getCastleMoves(sq));
- }
-
- getCastleMoves([x,y])
- {
- const c = this.getColor(x,y);
- if (x != (c=="w" ? V.size.x-1 : 0) || y != this.INIT_COL_KING[c])
- return []; //x isn't first rank, or king has moved (shortcut)
-
- // Castling ?
- const oppCol = V.GetOppCol(c);
- let moves = [];
- let i = 0;
- const finalSquares = [ [2,3], [V.size.y-2,V.size.y-3] ]; //king, then rook
- castlingCheck:
- for (let castleSide=0; castleSide < 2; castleSide++) //large, then small
- {
- if (!this.castleFlags[c][castleSide])
- continue;
- // If this code is reached, rooks and king are on initial position
-
- // Nothing on the path of the king ?
- // (And no checks; OK also if y==finalSquare)
- let step = finalSquares[castleSide][0] < y ? -1 : 1;
- for (i=y; i!=finalSquares[castleSide][0]; i+=step)
- {
- if (this.isAttacked([x,i], [oppCol]) || (this.board[x][i] != V.EMPTY &&
- // NOTE: next check is enough, because of chessboard constraints
- (this.getColor(x,i) != c
- || ![V.KING,V.ROOK].includes(this.getPiece(x,i)))))
- {
- continue castlingCheck;
- }
- }
-
- // Nothing on the path to the rook?
- step = castleSide == 0 ? -1 : 1;
- for (i = y + step; i != this.INIT_COL_ROOK[c][castleSide]; i += step)
- {
- if (this.board[x][i] != V.EMPTY)
- continue castlingCheck;
- }
- const rookPos = this.INIT_COL_ROOK[c][castleSide];
-
- // Nothing on final squares, except maybe king and castling rook?
- for (i=0; i<2; i++)
- {
- if (this.board[x][finalSquares[castleSide][i]] != V.EMPTY &&
- this.getPiece(x,finalSquares[castleSide][i]) != V.KING &&
- finalSquares[castleSide][i] != rookPos)
- {
- continue castlingCheck;
- }
- }
-
- // If this code is reached, castle is valid
- moves.push( new Move({
- appear: [
- new PiPo({x:x,y:finalSquares[castleSide][0],p:V.KING,c:c}),
- new PiPo({x:x,y:finalSquares[castleSide][1],p:V.ROOK,c:c})],
- vanish: [
- new PiPo({x:x,y:y,p:V.KING,c:c}),
- new PiPo({x:x,y:rookPos,p:V.ROOK,c:c})],
- end: Math.abs(y - rookPos) <= 2
- ? {x:x, y:rookPos}
- : {x:x, y:y + 2 * (castleSide==0 ? -1 : 1)}
- }) );
- }
-
- return moves;
- }
-
- ////////////////////
- // MOVES VALIDATION
-
- // For the interface: possible moves for the current turn from square sq
- getPossibleMovesFrom(sq)
- {
- return this.filterValid( this.getPotentialMovesFrom(sq) );
- }
-
- // TODO: promotions (into R,B,N,Q) should be filtered only once
- filterValid(moves)
- {
- if (moves.length == 0)
- return [];
- const color = this.turn;
- return moves.filter(m => {
- this.play(m);
- const res = !this.underCheck(color);
- this.undo(m);
- return res;
- });
- }
-
- // Search for all valid moves considering current turn
- // (for engine and game end)
- getAllValidMoves()
- {
- const color = this.turn;
- const oppCol = V.GetOppCol(color);
- let potentialMoves = [];
- for (let i=0; i<V.size.x; i++)
- {
- for (let j=0; j<V.size.y; j++)
- {
- // Next condition "!= oppCol" to work with checkered variant
- if (this.board[i][j] != V.EMPTY && this.getColor(i,j) != oppCol)
- {
- Array.prototype.push.apply(potentialMoves,
- this.getPotentialMovesFrom([i,j]));
- }
- }
- }
- return this.filterValid(potentialMoves);
- }
-
- // Stop at the first move found
- atLeastOneMove()
- {
- const color = this.turn;
- const oppCol = V.GetOppCol(color);
- for (let i=0; i<V.size.x; i++)
- {
- for (let j=0; j<V.size.y; j++)
- {
- if (this.board[i][j] != V.EMPTY && this.getColor(i,j) != oppCol)
- {
- const moves = this.getPotentialMovesFrom([i,j]);
- if (moves.length > 0)
- {
- for (let k=0; k<moves.length; k++)
- {
- if (this.filterValid([moves[k]]).length > 0)
- return true;
- }
- }
- }
- }
- }
- return false;
- }
-
- // Check if pieces of color in 'colors' are attacking (king) on square x,y
- isAttacked(sq, colors)
- {
- return (this.isAttackedByPawn(sq, colors)
- || this.isAttackedByRook(sq, colors)
- || this.isAttackedByKnight(sq, colors)
- || this.isAttackedByBishop(sq, colors)
- || this.isAttackedByQueen(sq, colors)
- || this.isAttackedByKing(sq, colors));
- }
-
- // Is square x,y attacked by 'colors' pawns ?
- isAttackedByPawn([x,y], colors)
- {
- for (let c of colors)
- {
- let pawnShift = (c=="w" ? 1 : -1);
- if (x+pawnShift>=0 && x+pawnShift<V.size.x)
- {
- for (let i of [-1,1])
- {
- if (y+i>=0 && y+i<V.size.y && this.getPiece(x+pawnShift,y+i)==V.PAWN
- && this.getColor(x+pawnShift,y+i)==c)
- {
- return true;
- }
- }
- }
- }
- return false;
- }
-
- // Is square x,y attacked by 'colors' rooks ?
- isAttackedByRook(sq, colors)
- {
- return this.isAttackedBySlideNJump(sq, colors, V.ROOK, V.steps[V.ROOK]);
- }
-
- // Is square x,y attacked by 'colors' knights ?
- isAttackedByKnight(sq, colors)
- {
- return this.isAttackedBySlideNJump(sq, colors,
- V.KNIGHT, V.steps[V.KNIGHT], "oneStep");
- }
-
- // Is square x,y attacked by 'colors' bishops ?
- isAttackedByBishop(sq, colors)
- {
- return this.isAttackedBySlideNJump(sq, colors, V.BISHOP, V.steps[V.BISHOP]);
- }
-
- // Is square x,y attacked by 'colors' queens ?
- isAttackedByQueen(sq, colors)
- {
- return this.isAttackedBySlideNJump(sq, colors, V.QUEEN,
- V.steps[V.ROOK].concat(V.steps[V.BISHOP]));
- }
-
- // Is square x,y attacked by 'colors' king(s) ?
- isAttackedByKing(sq, colors)
- {
- return this.isAttackedBySlideNJump(sq, colors, V.KING,
- V.steps[V.ROOK].concat(V.steps[V.BISHOP]), "oneStep");
- }
-
- // Generic method for non-pawn pieces ("sliding or jumping"):
- // is x,y attacked by a piece of color in array 'colors' ?
- isAttackedBySlideNJump([x,y], colors, piece, steps, oneStep)
- {
- for (let step of steps)
- {
- let rx = x+step[0], ry = y+step[1];
- while (V.OnBoard(rx,ry) && this.board[rx][ry] == V.EMPTY && !oneStep)
- {
- rx += step[0];
- ry += step[1];
- }
- if (V.OnBoard(rx,ry) && this.getPiece(rx,ry) === piece
- && colors.includes(this.getColor(rx,ry)))
- {
- return true;
- }
- }
- return false;
- }
-
- // Is color under check after his move ?
- underCheck(color)
- {
- return this.isAttacked(this.kingPos[color], [V.GetOppCol(color)]);
- }
-
- /////////////////
- // MOVES PLAYING
-
- // Apply a move on board
- static PlayOnBoard(board, move)
- {
- for (let psq of move.vanish)
- board[psq.x][psq.y] = V.EMPTY;
- for (let psq of move.appear)
- board[psq.x][psq.y] = psq.c + psq.p;
- }
- // Un-apply the played move
- static UndoOnBoard(board, move)
- {
- for (let psq of move.appear)
- board[psq.x][psq.y] = V.EMPTY;
- for (let psq of move.vanish)
- board[psq.x][psq.y] = psq.c + psq.p;
- }
-
- // After move is played, update variables + flags
- updateVariables(move)
- {
- let piece = undefined;
- let c = undefined;
- if (move.vanish.length >= 1)
- {
- // Usual case, something is moved
- piece = move.vanish[0].p;
- c = move.vanish[0].c;
- }
- else
- {
- // Crazyhouse-like variants
- piece = move.appear[0].p;
- c = move.appear[0].c;
- }
- if (c == "c") //if (!["w","b"].includes(c))
- {
- // 'c = move.vanish[0].c' doesn't work for Checkered
- c = V.GetOppCol(this.turn);
- }
- const firstRank = (c == "w" ? V.size.x-1 : 0);
-
- // Update king position + flags
- if (piece == V.KING && move.appear.length > 0)
- {
- this.kingPos[c][0] = move.appear[0].x;
- this.kingPos[c][1] = move.appear[0].y;
- if (V.HasFlags)
- this.castleFlags[c] = [false,false];
- return;
- }
- if (V.HasFlags)
- {
- // Update castling flags if rooks are moved
- const oppCol = V.GetOppCol(c);
- const oppFirstRank = (V.size.x-1) - firstRank;
- if (move.start.x == firstRank //our rook moves?
- && this.INIT_COL_ROOK[c].includes(move.start.y))
- {
- const flagIdx = (move.start.y == this.INIT_COL_ROOK[c][0] ? 0 : 1);
- this.castleFlags[c][flagIdx] = false;
- }
- else if (move.end.x == oppFirstRank //we took opponent rook?
- && this.INIT_COL_ROOK[oppCol].includes(move.end.y))
- {
- const flagIdx = (move.end.y == this.INIT_COL_ROOK[oppCol][0] ? 0 : 1);
- this.castleFlags[oppCol][flagIdx] = false;
- }
- }
- }
-
- // After move is undo-ed *and flags resetted*, un-update other variables
- // TODO: more symmetry, by storing flags increment in move (?!)
- unupdateVariables(move)
- {
- // (Potentially) Reset king position
- const c = this.getColor(move.start.x,move.start.y);
- if (this.getPiece(move.start.x,move.start.y) == V.KING)
- this.kingPos[c] = [move.start.x, move.start.y];
- }
-
- play(move)
- {
- // DEBUG:
-// if (!this.states) this.states = [];
-// const stateFen = this.getBaseFen() + this.getTurnFen() + this.getFlagsFen();
-// this.states.push(stateFen);
-
- if (V.HasFlags)
- move.flags = JSON.stringify(this.aggregateFlags()); //save flags (for undo)
- if (V.HasEnpassant)
- this.epSquares.push( this.getEpSquare(move) );
- if (!move.color)
- move.color = this.turn; //for interface
- V.PlayOnBoard(this.board, move);
- this.turn = V.GetOppCol(this.turn);
- this.movesCount++;
- this.updateVariables(move);
- }
-
- undo(move)
- {
- if (V.HasEnpassant)
- this.epSquares.pop();
- if (V.HasFlags)
- this.disaggregateFlags(JSON.parse(move.flags));
- V.UndoOnBoard(this.board, move);
- this.turn = V.GetOppCol(this.turn);
- this.movesCount--;
- this.unupdateVariables(move);
-
- // DEBUG:
-// const stateFen = this.getBaseFen() + this.getTurnFen() + this.getFlagsFen();
-// if (stateFen != this.states[this.states.length-1]) debugger;
-// this.states.pop();
- }
-
- ///////////////
- // END OF GAME
-
- // What is the score ? (Interesting if game is over)
- getCurrentScore()
- {
- if (this.atLeastOneMove()) // game not over
- return "*";
-
- // Game over
- const color = this.turn;
- // No valid move: stalemate or checkmate?
- if (!this.isAttacked(this.kingPos[color], [V.GetOppCol(color)]))
- return "1/2";
- // OK, checkmate
- return (color == "w" ? "0-1" : "1-0");
- }
-
- ///////////////
- // ENGINE PLAY
-
- // Pieces values
- static get VALUES()
- {
- return {
- 'p': 1,
- 'r': 5,
- 'n': 3,
- 'b': 3,
- 'q': 9,
- 'k': 1000
- };
- }
-
- // "Checkmate" (unreachable eval)
- static get INFINITY() { return 9999; }
-
- // At this value or above, the game is over
- static get THRESHOLD_MATE() { return V.INFINITY; }
-
- // Search depth: 2 for high branching factor, 4 for small (Loser chess, eg.)
- static get SEARCH_DEPTH() { return 3; }
-
- // Assumption: at least one legal move
- // NOTE: works also for extinction chess because depth is 3...
- getComputerMove()
- {
- const maxeval = V.INFINITY;
- const color = this.turn;
- // Some variants may show a bigger moves list to the human (Switching),
- // thus the argument "computer" below (which is generally ignored)
- let moves1 = this.getAllValidMoves("computer");
-
- // Can I mate in 1 ? (for Magnetic & Extinction)
- for (let i of _.shuffle(_.range(moves1.length)))
- {
- this.play(moves1[i]);
- let finish = (Math.abs(this.evalPosition()) >= V.THRESHOLD_MATE);
- if (!finish)
- {
- const score = this.getCurrentScore();
- if (["1-0","0-1"].includes(score))
- finish = true;
- }
- this.undo(moves1[i]);
- if (finish)
- return moves1[i];
- }
-
- // Rank moves using a min-max at depth 2
- for (let i=0; i<moves1.length; i++)
- {
- // Initial self evaluation is very low: "I'm checkmated"
- moves1[i].eval = (color=="w" ? -1 : 1) * maxeval;
- this.play(moves1[i]);
- const score1 = this.getCurrentScore();
- let eval2 = undefined;
- if (score1 == "*")
- {
- // Initial enemy evaluation is very low too, for him
- eval2 = (color=="w" ? 1 : -1) * maxeval;
- // Second half-move:
- let moves2 = this.getAllValidMoves("computer");
- for (let j=0; j<moves2.length; j++)
- {
- this.play(moves2[j]);
- const score2 = this.getCurrentScore();
- const evalPos = score2 == "*"
- ? this.evalPosition()
- : (score2=="1/2" ? 0 : (score2=="1-0" ? 1 : -1) * maxeval);
- if ((color == "w" && evalPos < eval2)
- || (color=="b" && evalPos > eval2))
- {
- eval2 = evalPos;
- }
- this.undo(moves2[j]);
- }
- }
- else
- eval2 = (score1=="1/2" ? 0 : (score1=="1-0" ? 1 : -1) * maxeval);
- if ((color=="w" && eval2 > moves1[i].eval)
- || (color=="b" && eval2 < moves1[i].eval))
- {
- moves1[i].eval = eval2;
- }
- this.undo(moves1[i]);
- }
- moves1.sort( (a,b) => { return (color=="w" ? 1 : -1) * (b.eval - a.eval); });
-
- let candidates = [0]; //indices of candidates moves
- for (let j=1; j<moves1.length && moves1[j].eval == moves1[0].eval; j++)
- candidates.push(j);
- let currentBest = moves1[_.sample(candidates, 1)];
-
- // From here, depth >= 3: may take a while, so we control time
- const timeStart = Date.now();
-
- // Skip depth 3+ if we found a checkmate (or if we are checkmated in 1...)
- if (V.SEARCH_DEPTH >= 3 && Math.abs(moves1[0].eval) < V.THRESHOLD_MATE)
- {
- for (let i=0; i<moves1.length; i++)
- {
- if (Date.now()-timeStart >= 5000) //more than 5 seconds
- return currentBest; //depth 2 at least
- this.play(moves1[i]);
- // 0.1 * oldEval : heuristic to avoid some bad moves (not all...)
- moves1[i].eval = 0.1*moves1[i].eval +
- this.alphabeta(V.SEARCH_DEPTH-1, -maxeval, maxeval);
- this.undo(moves1[i]);
- }
- moves1.sort( (a,b) => {
- return (color=="w" ? 1 : -1) * (b.eval - a.eval); });
- }
- else
- return currentBest;
-// console.log(moves1.map(m => { return [this.getNotation(m), m.eval]; }));
-
- candidates = [0];
- for (let j=1; j<moves1.length && moves1[j].eval == moves1[0].eval; j++)
- candidates.push(j);
- return moves1[_.sample(candidates, 1)];
- }
-
- alphabeta(depth, alpha, beta)
- {
- const maxeval = V.INFINITY;
- const color = this.turn;
- const score = this.getCurrentScore();
- if (score != "*")
- return (score=="1/2" ? 0 : (score=="1-0" ? 1 : -1) * maxeval);
- if (depth == 0)
- return this.evalPosition();
- const moves = this.getAllValidMoves("computer");
- let v = color=="w" ? -maxeval : maxeval;
- if (color == "w")
- {
- for (let i=0; i<moves.length; i++)
- {
- this.play(moves[i]);
- v = Math.max(v, this.alphabeta(depth-1, alpha, beta));
- this.undo(moves[i]);
- alpha = Math.max(alpha, v);
- if (alpha >= beta)
- break; //beta cutoff
- }
- }
- else //color=="b"
- {
- for (let i=0; i<moves.length; i++)
- {
- this.play(moves[i]);
- v = Math.min(v, this.alphabeta(depth-1, alpha, beta));
- this.undo(moves[i]);
- beta = Math.min(beta, v);
- if (alpha >= beta)
- break; //alpha cutoff
- }
- }
- return v;
- }
-
- evalPosition()
- {
- let evaluation = 0;
- // Just count material for now
- for (let i=0; i<V.size.x; i++)
- {
- for (let j=0; j<V.size.y; j++)
- {
- if (this.board[i][j] != V.EMPTY)
- {
- const sign = this.getColor(i,j) == "w" ? 1 : -1;
- evaluation += sign * V.VALUES[this.getPiece(i,j)];
- }
- }
- }
- return evaluation;
- }
-
- /////////////////////////
- // MOVES + GAME NOTATION
- /////////////////////////
-
- // Context: just before move is played, turn hasn't changed
- // TODO: un-ambiguous notation (switch on piece type, check directions...)
- getNotation(move)
- {
- if (move.appear.length == 2 && move.appear[0].p == V.KING) //castle
- return (move.end.y < move.start.y ? "0-0-0" : "0-0");
-
- // Translate final square
- const finalSquare = V.CoordsToSquare(move.end);
-
- const piece = this.getPiece(move.start.x, move.start.y);
- if (piece == V.PAWN)
- {
- // Pawn move
- let notation = "";
- if (move.vanish.length > move.appear.length)
- {
- // Capture
- const startColumn = V.CoordToColumn(move.start.y);
- notation = startColumn + "x" + finalSquare;
- }
- else //no capture
- notation = finalSquare;
- if (move.appear.length > 0 && move.appear[0].p != V.PAWN) //promotion
- notation += "=" + move.appear[0].p.toUpperCase();
- return notation;
- }
-
- else
- {
- // Piece movement
- return piece.toUpperCase() +
- (move.vanish.length > move.appear.length ? "x" : "") + finalSquare;
- }
- }
-}