# Copyright 2023 Mattia Giambirtone & All Contributors # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. import ../util/matrix export matrix import std/strutils import std/strformat type # Useful type aliases Location = tuple[row, col: int] Pieces = tuple[king: Location, queens: seq[Location], rooks: seq[Location], bishops: seq[Location], knights: seq[Location], pawns: seq[Location]] PieceColor* = enum ## A piece color enumeration None = 0, White, Black PieceKind* = enum ## A chess piece enumeration Empty = '\0', # No piece Bishop = 'b', King = 'k' Knight = 'n', Pawn = 'p', Queen = 'q', Rook = 'r', Piece* = object ## A chess piece color*: PieceColor kind*: PieceKind MoveFlag* = enum ## An enumeration of move flags Default, # Move is a regular move XRay, # Move is an X-ray attack # Move is a pawn promotion PromoteToQueen, PromoteToRook, PromoteToBishop, PromoteToKnight Move* = object ## A chess move piece*: Piece startSquare*: Location targetSquare*: Location flag*: MoveFlag ChessBoard* = ref object ## A chess board object grid: Matrix[Piece] # Currently active color turn*: PieceColor # Number of half moves since # last piece capture or pawn movement. # Used for the 50-move rule halfMoveClock: int # Full move counter. Increments # every 2 ply fullMoveCount: int # Stores metadata for castling. castling: tuple[white, black: tuple[queen, king: bool]] # En passant target square (see https://en.wikipedia.org/wiki/En_passant) # If en passant is not possible, both the row and # column of the position will be set to -1 enPassantSquare*: Move # Locations of all pieces pieces: tuple[white: Pieces, black: Pieces] # Locations of all attacked squares and their # respective attackers attacked*: tuple[white: seq[tuple[attacker: Piece, loc: Location]], black: seq[tuple[attacker: Piece, loc: Location]]] # Initialized only once, copied every time var empty: seq[Piece] = @[] for _ in countup(0, 63): empty.add(Piece(kind: Empty, color: None)) func emptyPiece*: Piece {.inline.} = Piece(kind: Empty, color: None) func emptyLocation*: Location {.inline.} = (-1 , -1) func opposite*(c: PieceColor): PieceColor {.inline.} = (if c == White: Black else: White) proc algebraicToPosition*(s: string): Location {.inline.} proc getCapture*(self: ChessBoard, move: Move): Location func emptyMove*: Move {.inline.} = Move(startSquare: emptyLocation(), targetSquare: emptyLocation(), piece: emptyPiece()) func getStartRow(piece: Piece): int {.inline.} = ## Retrieves the starting row of ## the given piece inside our 8x8 ## grid case piece.color: of None: return -1 of White: case piece.kind: of Pawn: return 6 else: return 5 of Black: case piece.kind: of Pawn: return 1 else: return 0 func getLastRow(color: PieceColor): int {.inline.} = ## Retrieves the location of the last ## row relative to the given color proc newChessboard: ChessBoard = ## Returns a new, empty chessboard new(result) # Turns our flat sequence into an 8x8 grid result.grid = newMatrixFromSeq[Piece](empty, (8, 8)) result.attacked = (@[], @[]) result.enPassantSquare = emptyMove() result.turn = White proc newChessboardFromFEN*(state: string): ChessBoard = ## Initializes a chessboard with the ## state encoded by the given FEN string result = newChessboard() var # Current location in the grid row = 0 column = 0 # Current section in the FEN string section = 0 # Current index into the FEN string index = 0 # Temporary variable to store the piece piece: Piece # See https://en.wikipedia.org/wiki/Forsyth%E2%80%93Edwards_Notation while index <= state.high(): var c = state[index] if c == ' ': # Next section inc(section) inc(index) continue case section: of 0: # Piece placement data case c.toLowerAscii(): # Piece of 'r', 'n', 'b', 'q', 'k', 'p': # We know for a fact these values are in our # enumeration, so all is good {.push.} {.warning[HoleEnumConv]:off.} piece = Piece(kind: PieceKind(c.toLowerAscii()), color: if c.isUpperAscii(): White else: Black) {.pop.} case piece.color: of Black: case piece.kind: of Pawn: result.pieces.black.pawns.add((row, column)) of Bishop: result.pieces.black.bishops.add((row, column)) of Knight: result.pieces.black.knights.add((row, column)) of Rook: result.pieces.black.rooks.add((row, column)) of Queen: result.pieces.black.queens.add((row, column)) of King: result.pieces.black.king = (row, column) else: discard of White: case piece.kind: of Pawn: result.pieces.white.pawns.add((row, column)) of Bishop: result.pieces.white.bishops.add((row, column)) of Knight: result.pieces.white.knights.add((row, column)) of Rook: result.pieces.white.rooks.add((row, column)) of Queen: result.pieces.white.queens.add((row, column)) of King: result.pieces.white.king = (row, column) else: discard else: discard result.grid[row, column] = piece inc(column) of '/': # Next row inc(row) column = 0 of '0'..'9': # Skip x columns let x = int(uint8(c) - uint8('0')) - 1 if x > 7: raise newException(ValueError, "invalid skip value (> 8) in FEN string") column += x else: raise newException(ValueError, "invalid piece identifier in FEN string") of 1: # Active color case c: of 'w': result.turn = White of 'b': result.turn = Black else: raise newException(ValueError, "invalid active color identifier in FEN string") of 2: # Castling availability case c: of '-': # Neither side can castle anywhere: do nothing, # as the castling metadata is set to this state # by default discard of 'K': result.castling.white.king = true of 'Q': result.castling.white.queen = true of 'k': result.castling.black.king = true of 'q': result.castling.black.queen = true else: raise newException(ValueError, "invalid castling availability in FEN string") of 3: # En passant target square case c: of '-': # Field is already uninitialized to the correct state discard else: result.enPassantSquare.targetSquare = state[index..index+1].algebraicToPosition() # Just for cleanliness purposes, we fill in the other positional metadata as # well result.enPassantSquare.piece.color = if result.turn == Black: White else: Black result.enPassantSquare.piece.kind = Pawn # Square metadata is 2 bytes long inc(index) of 4: # Halfmove clock var s = "" while not state[index].isSpaceAscii(): s.add(state[index]) inc(index) # Backtrack so the space is seen by the # next iteration of the loop dec(index) result.halfMoveClock = parseInt(s) of 5: # Fullmove number var s = "" while index <= state.high(): s.add(state[index]) inc(index) result.fullMoveCount = parseInt(s) else: raise newException(ValueError, "too many fields in FEN string") inc(index) proc newDefaultChessboard*: ChessBoard = ## Initializes a chessboard with the ## starting position return newChessboardFromFEN("rnbqkbnr/pppppppp/8/8/8/8/PPPPPPPP/RNBQKBNR w KQkq - 0 1") proc countPieces*(self: ChessBoard, kind: PieceKind, color: PieceColor): int = ## Counts the number of pieces with ## the given color and type case color: of White: case kind: of Pawn: return self.pieces.white.pawns.len() of Bishop: return self.pieces.white.bishops.len() of Knight: return self.pieces.white.knights.len() of Rook: return self.pieces.white.rooks.len() of Queen: return self.pieces.white.queens.len() of King: # There shall be only one, forever return 1 else: discard of Black: case kind: of Pawn: return self.pieces.black.pawns.len() of Bishop: return self.pieces.black.bishops.len() of Knight: return self.pieces.black.knights.len() of Rook: return self.pieces.black.rooks.len() of Queen: return self.pieces.black.queens.len() of King: # In perpetuity return 1 else: discard of None: raise newException(ValueError, "invalid piece type") proc countPieces*(self: ChessBoard, piece: Piece): int = ## Returns the number of pieces on the board that ## are of the same type and color of the given piece return self.countPieces(piece.kind, piece.color) func rankToColumn(rank: int): int = ## Converts a chess rank (1-indexed) ## into a 0-indexed column value for our ## board. This converter is necessary because ## chess positions are indexed differently with ## respect to our internal representation const indeces = [7, 6, 5, 4, 3, 2, 1, 0] return indeces[rank - 1] proc algebraicToPosition*(s: string): Location {.inline.} = ## Converts a square location from algebraic ## notation to its corresponding row and column ## in the chess grid (0 indexed) if len(s) != 2: raise newException(ValueError, "algebraic position must be of length 2") var s = s.toLowerAscii() if s[0] notin 'a'..'h': raise newException(ValueError, &"algebraic position has invalid first character ('{s[0]}')") if s[1] notin '1'..'8': raise newException(ValueError, &"algebraic position has invalid second character ('{s[1]}')") let file = int(uint8(s[0]) - uint8('a')) # Convert the rank character to a number let rank = rankToColumn(int(uint8(s[1]) - uint8('0'))) return (rank, file) proc getPiece*(self: ChessBoard, square: string): Piece = ## Gets the piece on the given square ## in algebraic notation let loc = square.algebraicToPosition() return self.grid[loc.row, loc.col] proc generatePawnMoves(self: ChessBoard, location: Location): seq[Move] = ## Generates the possible moves for the pawn in the given ## location var piece = self.grid[location.row, location.col] locations: seq[Location] = @[] doAssert piece.kind == Pawn, &"generatePawnMoves called on a {piece.kind}" case piece.color: of White: # Pawns can move forward one square. In our flipped # board configuration, that means moving up one row # while keeping the column the same if location.row in 1..6 and self.grid[location.row - 1, location.col].color == None: locations.add((location.row - 1, location.col)) if self.enPassantSquare.piece.color == piece.color.opposite: if abs(self.enPassantSquare.targetSquare.col - location.col) == 1 and abs(self.enPassantSquare.targetSquare.row - location.row) == 1: # Only viable if the piece is on the diagonal of the target locations.add(self.enPassantSquare.targetSquare) # They can also move on either diagonal one # square, but only to capture if location.col in 1..6 and location.row in 1..6: if self.grid[location.row + 1, location.col + 1].color == Black: # Top right diagonal (white side) locations.add((location.row + 1, location.col + 1)) if self.grid[location.row - 1, location.col - 1].color == Black: # Top left diagonal locations.add((location.row + 1, location.col + 1)) # Pawn is at the right side, can only capture # on the left one elif location.col == 0 and location.row < 7 and self.grid[location.row + 1, location.col + 1].color == Black: locations.add((location.row + 1, location.col + 1)) # Pawn is at the left side, can only capture # on the right one elif location.col == 7 and location.row < 7 and self.grid[location.row + 1, location.col - 1].color == Black: locations.add((location.row - 1, location.col - 1)) of Black: # Pawns can move forward one square. In our flipped # board configuration, that means moving down one row # while keeping the column the same if location.row in 1..6 and self.grid[location.row - 1, location.col].color == None: locations.add((1, 0)) if self.enPassantSquare.piece.color == piece.color.opposite: if abs(self.enPassantSquare.targetSquare.col - location.col) == 1 and abs(self.enPassantSquare.targetSquare.row - location.row) == 1: # Only viable if the piece is on the diagonal of the target locations.add(self.enPassantSquare.targetSquare) # They can also move on either diagonal one # square, but only to capture if location.col in 1..6 and location.row in 1..6: if self.grid[location.row - 1, location.col - 1].color == White: # Top right diagonal (black side) locations.add((1, 1)) if self.grid[location.row + 1, location.col + 1].color == White: # Top left diagonal locations.add((-1, -1)) # Pawn is at the right side, can only capture # on the left one elif location.col > 0 and location.row > 0 and self.grid[location.row - 1, location.col + 1].color == White: locations.add((-1, -1)) # Pawn is at the left side, can only capture # on the right one elif location.col == 7 and location.row > 0 and self.grid[location.row + 1, location.col + 1].color == White: locations.add((1, 1)) else: discard for target in locations: if target.row == piece.color.getLastRow(): # Generate all promotion moves for promotionType in [PromoteToKnight, PromoteToBishop, PromoteToRook, PromoteToQueen]: result.add(Move(startSquare: location, targetSquare: target, piece: self.grid[location.row, location.col], flag: promotionType)) else: result.add(Move(startSquare: location, targetSquare: target, piece: self.grid[location.row, location.col])) proc generateSlidingMoves(self: ChessBoard, location: Location): seq[Move] = ## Generates sliding moves for the sliding piece in the given location var piece = self.grid[location.row, location.col] doAssert piece.kind in [Bishop, Rook, Queen], &"generateSlidingMoves called on a {piece.kind}" proc generateMoves(self: ChessBoard, location: Location): seq[Move] = ## Returns the list of possible moves for the ## piece in the given location let piece = self.grid[location.row, location.col] case piece.kind: of Queen, Bishop, Rook: return self.generateSlidingMoves(location) of Pawn: return self.generatePawnMoves(location) else: return @[] proc getCapture*(self: ChessBoard, move: Move): Location = ## Returns the location that would be captured if this ## move were played on the board, taking en passant and ## other things into account. An empty location is returned ## if no piece is captured by the given move result = emptyLocation() let target = self.grid[move.targetSquare.row, move.targetSquare.col] if target.color == None: if move.targetSquare != self.enPassantSquare.targetSquare: return else: return ((if move.piece.color == White: move.targetSquare.row + 1 else: move.targetSquare.row - 1), move.targetSquare.col) if target.color == move.piece.color.opposite() and move in self.generateMoves(move.startSquare): return move.targetSquare proc isCapture*(self: ChessBoard, move: Move): bool {.inline.} = ## Returns whether the given move is a capture ## or not return self.getCapture(move) != emptyLocation() proc validatePawnMove(self: ChessBoard, move: Move): bool = ## Returns true if the given pawn move is allowed ## (internal helper to testMoveOffsets) if move.targetSquare.col != move.startSquare.col: # Pawn can only change column in case of capture or en passant if self.enPassantSquare == emptyMove(): # No en passant possible, only possibility # is a capture return self.isCapture(move) # En passant is possible, check if the destination is # its target square if self.enPassantSquare.targetSquare != move.targetSquare: # We still need to check for captures even if en passant # is possible return self.isCapture(move) # Number of rows traveled var rows: int # Due to our unique board layout, we need to do this nonsense if move.piece.color == White: rows = move.startSquare.row - move.targetSquare.row else: rows = move.targetSquare.row - move.startSquare.row if rows < 0 or rows > 2: # Pawns don't go backwards, I'm afraid. They also can't # go any further than 2 squares return false if rows == 2: # Check if double pawn pushing is possible (only the first # move for each pawn) if move.startSquare.row != move.piece.getStartRow(): # Pawn has already moved more than once, double push # is not allowed return false # En passant is now possible let targetSquare: Location = ((if move.piece.color == White: move.targetSquare.row + 1 else: move.targetSquare.row - 1), move.targetSquare.col) self.enPassantSquare = Move(piece: move.piece, startSquare: move.startSquare, targetSquare: targetSquare) # Captures are checked earlier, so we only need to make sure we aren't blocked by # a piece return self.grid[move.targetSquare.row, move.targetSquare.col].kind == Empty proc validateSlidingMove(self: ChessBoard, move: Move): bool = ## Returns true if the given pawn move is allowed ## (internal helper to testMoveOffsets) var directions: seq[Location] proc testMoveOffsets(self: ChessBoard, move: Move): bool = ## Returns true if the piece in the given ## move is pseudo-legal: this does not take pins ## nor checks into account, but other rules like ## double pawn pushes and en passant are validated ## here. Note that this is an internal method called ## by checkMove and it does not validate whether the ## target square is occupied or not (it is assumed the ## check has been performed beforehand, like checkMove ## does) case move.piece.kind: of Pawn: return self.validatePawnMove(move) of Bishop: return self.validateSlidingMove(move) else: return false proc updateAttackedSquares(self: ChessBoard) = ## Updates internal metadata about which squares ## are attacked. Called internally by doMove # We refresh the attack metadata at every move. This is an # O(1) operation, because we're only updating the length # field without deallocating the memory, which will promptly # be reused by us again. Neat! self.attacked.white.setLen(0) self.attacked.black.setLen(0) # Go over each piece one by one and see which squares # it currently attacks # White pawns for loc in self.pieces.white.pawns: for move in self.generateMoves(loc): self.attacked.white.add((move.piece, move.targetSquare)) # Black pawns for loc in self.pieces.black.pawns: for move in self.generateMoves(loc): self.attacked.black.add((move.piece, move.targetSquare)) # White bishops for loc in self.pieces.white.bishops: for move in self.generateMoves(loc): self.attacked.white.add((move.piece, move.targetSquare)) # Black bishops for loc in self.pieces.black.bishops: for move in self.generateMoves(loc): self.attacked.black.add((move.piece, move.targetSquare)) proc getAttackers*(self: ChessBoard, square: string): seq[Piece] = ## Returns the attackers of the given square. ## If the square has no attackers, an empty ## seq is returned let loc = square.algebraicToPosition() case self.turn: of White: for (attacker, location) in self.attacked.black: if location == loc: result.add(attacker) of Black: for (attacker, location) in self.attacked.white: if location == loc: result.add(attacker) else: return @[] # We don't use getAttackers because this one only cares about whether # the square is attacked or not (and can therefore exit earlier than # getAttackers) proc isAttacked*(self: ChessBoard, square: string): bool = ## Returns whether the given square is attacked ## by one of the enemy pieces let loc = square.algebraicToPosition() case self.turn: of White: for (attacker, location) in self.attacked.black: if location == loc: return true return false of Black: for (attacker, location) in self.attacked.white: if location == loc: return true return false else: discard proc removePiece(self: ChessBoard, location: Location) = ## Removes a piece from the board, updating necessary ## metadata var piece = self.grid[location.row, location.col] self.grid[location.row, location.col] = emptyPiece() case piece.color: of White: case piece.kind: of Pawn: self.pieces.white.pawns.delete(self.pieces.white.pawns.find(location)) of Bishop: self.pieces.white.pawns.delete(self.pieces.white.bishops.find(location)) of Knight: self.pieces.white.pawns.delete(self.pieces.white.knights.find(location)) of Rook: self.pieces.white.rooks.delete(self.pieces.white.rooks.find(location)) of Queen: self.pieces.white.queens.delete(self.pieces.white.rooks.find(location)) of King: doAssert false, "removePiece: attempted to remove the white king" else: discard of Black: case piece.kind: of Pawn: self.pieces.black.pawns.delete(self.pieces.black.pawns.find(location)) of Bishop: self.pieces.black.pawns.delete(self.pieces.black.bishops.find(location)) of Knight: self.pieces.black.pawns.delete(self.pieces.black.knights.find(location)) of Rook: self.pieces.black.rooks.delete(self.pieces.black.rooks.find(location)) of Queen: self.pieces.black.queens.delete(self.pieces.black.rooks.find(location)) of King: doAssert false, "removePiece: attempted to remove the black king" else: discard else: discard proc updatePositions(self: ChessBoard, move: Move) = ## Internal helper to update the position of ## the pieces on the board after a move let capture = self.getCapture(move) if capture != emptyLocation(): # Move has captured a piece: remove the destination square's piece as well. # We call a helper instead of doing it ourselves because there's a bunch # of metadata that needs to be updated to do this properly and I thought # it'd fit into its neat little function self.removePiece(capture) # Update the positional metadata of the moving piece case move.piece.color: of White: case move.piece.kind: of Pawn: # The way things are structured, we don't care about the order # of this list, so we can add and remove entries as we please self.pieces.white.pawns.delete(self.pieces.white.pawns.find(move.startSquare)) self.pieces.white.pawns.add(move.targetSquare) of Bishop: self.pieces.white.bishops.delete(self.pieces.white.bishops.find(move.startSquare)) self.pieces.white.bishops.add(move.targetSquare) of Knight: self.pieces.white.knights.delete(self.pieces.white.knights.find(move.startSquare)) self.pieces.white.knights.add(move.targetSquare) of Rook: self.pieces.white.rooks.delete(self.pieces.white.rooks.find(move.startSquare)) self.pieces.white.rooks.add(move.targetSquare) of Queen: self.pieces.white.queens.delete(self.pieces.white.queens.find(move.startSquare)) self.pieces.white.queens.add(move.targetSquare) of King: self.pieces.white.king = move.targetSquare else: discard of Black: case move.piece.kind: of Pawn: self.pieces.black.pawns.delete(self.pieces.black.pawns.find(move.startSquare)) self.pieces.black.pawns.add(move.targetSquare) of Bishop: self.pieces.black.bishops.delete(self.pieces.black.bishops.find(move.startSquare)) self.pieces.black.bishops.add(move.targetSquare) of Knight: self.pieces.black.knights.delete(self.pieces.black.knights.find(move.startSquare)) self.pieces.black.knights.add(move.targetSquare) of Rook: self.pieces.black.rooks.delete(self.pieces.black.rooks.find(move.startSquare)) self.pieces.black.rooks.add(move.targetSquare) of Queen: self.pieces.black.queens.delete(self.pieces.black.queens.find(move.startSquare)) self.pieces.white.queens.add(move.targetSquare) of King: self.pieces.black.king = move.targetSquare else: discard else: discard # Empty out the starting square self.grid[move.startSquare.row, move.startSquare.col] = emptyPiece() # Actually move the piece self.grid[move.targetSquare.row, move.targetSquare.col] = move.piece proc doMove(self: ChessBoard, move: Move) = ## Internal function called by makeMove after ## performing legality checks on the given move. Can ## be used in performance-critical paths where ## a move is already known to be legal self.updatePositions(move) self.updateAttackedSquares() # En passant is possible only immediately after the # pawn has moved if self.enPassantSquare != emptyMove() and self.enPassantSquare.piece.color == self.turn.opposite(): self.enPassantSquare = emptyMove() self.turn = self.turn.opposite() proc checkMove(self: ChessBoard, startSquare, targetSquare: string): Move = ## Internal function called by makeMove to check a move for legality var pieceToMove = self.getPiece(startSquare) # Start square doesn't contain a piece (and it isn't the en passant square) # or it is of the wrong color for which turn it is to move if pieceToMove.kind == Empty or pieceToMove.color != self.turn: return emptyMove() var destination = self.getPiece(targetSquare) # Destination square is occupied by a piece of the same color as the piece # being moved: illegal! if destination.kind != Empty and destination.color == self.turn: return emptyMove() var startLocation = startSquare.algebraicToPosition() targetLocation = targetSquare.algebraicToPosition() result = Move(startSquare: startLocation, targetSquare: targetLocation, piece: pieceToMove) if not self.testMoveOffsets(result): # Piece cannot arrive to destination (either # because it is blocked or because the moving # pattern is incorrect) return emptyMove() # TODO: Check for checks and pins (moves are currently pseudo-legal) proc makeMove*(self: ChessBoard, startSquare, targetSquare: string): Move {.discardable.} = ## Makes a move on the board from the chosen start square to ## the chosen target square, ensuring it is legal (turns are ## taken into account!). This function returns a Move object: if the move ## is legal and has been performed, the fields will be populated properly. ## For efficiency purposes, no exceptions are raised if the move is ## illegal, but the move's piece kind will be Empty (its color will be None ## too) and the locations will both be set to the tuple (-1, -1) result = self.checkMove(startSquare, targetSquare) if result == emptyMove(): return self.doMove(result) proc `$`*(self: ChessBoard): string = result &= "- - - - - - - -" for i, row in self.grid: result &= "\n" for piece in row: if piece.kind == Empty: result &= "x " continue if piece.color == White: result &= &"{char(piece.kind).toUpperAscii()} " else: result &= &"{char(piece.kind)} " result &= &"{rankToColumn(i + 1) + 1}" result &= "\n- - - - - - - -" result &= "\na b c d e f g h" proc pretty*(self: ChessBoard): string = ## Returns a colorized version of the ## board for easier visualization result &= "- - - - - - - -" for i, row in self.grid: result &= "\n" for j, piece in row: if piece.kind == Empty: result &= "\x1b[36;1mx" # Avoids the color overflowing # onto the numbers if j < 7: result &= " \x1b[0m" else: result &= "\x1b[0m " continue if piece.color == White: result &= &"\x1b[37;1m{char(piece.kind).toUpperAscii()}\x1b[0m " else: result &= &"\x1b[30;1m{char(piece.kind)} " result &= &"\x1b[33;1m{rankToColumn(i + 1) + 1}\x1b[0m" result &= "\n- - - - - - - -" result &= "\n\x1b[31;1ma b c d e f g h" result &= "\x1b[0m" when isMainModule: proc testPiece(piece: Piece, kind: PieceKind, color: PieceColor) = doAssert piece.kind == kind and piece.color == color, &"expected piece of kind {kind} and color {color}, got {piece.kind} / {piece.color} instead" proc testPieceCount(board: ChessBoard, kind: PieceKind, color: PieceColor, count: int) = let pieces = board.countPieces(kind, color) doAssert pieces == count, &"expected {count} pieces of kind {kind} and color {color}, got {pieces} instead" echo "Running tests" var b = newDefaultChessboard() # Ensure correct number of pieces testPieceCount(b, Pawn, White, 8) testPieceCount(b, Pawn, Black, 8) testPieceCount(b, Knight, White, 2) testPieceCount(b, Knight, Black, 2) testPieceCount(b, Bishop, White, 2) testPieceCount(b, Bishop, Black, 2) testPieceCount(b, Rook, White, 2) testPieceCount(b, Rook, Black, 2) testPieceCount(b, Queen, White, 1) testPieceCount(b, Queen, Black, 1) testPieceCount(b, King, White, 1) testPieceCount(b, King, Black, 1) # Ensure pieces are in the correct location # Pawns for loc in ["a2", "b2", "c2", "d2", "e2", "f2", "g2", "h2"]: testPiece(b.getPiece(loc), Pawn, White) for loc in ["a7", "b7", "c7", "d7", "e7", "f7", "g7", "h7"]: testPiece(b.getPiece(loc), Pawn, Black) # Rooks testPiece(b.getPiece("a1"), Rook, White) testPiece(b.getPiece("h1"), Rook, White) testPiece(b.getPiece("a8"), Rook, Black) testPiece(b.getPiece("h8"), Rook, Black) # Knights testPiece(b.getPiece("b1"), Knight, White) testPiece(b.getPiece("g1"), Knight, White) testPiece(b.getPiece("b8"), Knight, Black) testPiece(b.getPiece("g8"), Knight, Black) # Bishops testPiece(b.getPiece("c1"), Bishop, White) testPiece(b.getPiece("f1"), Bishop, White) testPiece(b.getPiece("c8"), Bishop, Black) testPiece(b.getPiece("f8"), Bishop, Black) # Kings testPiece(b.getPiece("e1"), King, White) testPiece(b.getPiece("e8"), King, Black) # Queens testPiece(b.getPiece("d1"), Queen, White) testPiece(b.getPiece("d8"), Queen, Black) echo "All tests were successful"