def get_enpassant_board():
__ = BlankPiece()
p1 = Pawn("black")
p2 = Pawn("black")
wp = Pawn("white")
wp.has_never_moved = False
# 0 1 2 3 4 5 6 7
board = [
[__, __, __, __, __, __, __, __], # 0
[__, __, __, __, __, p1, __, p2], # 1
[__, __, __, __, __, __, __, __], # 2
[__, __, __, __, __, __, wp, __], # 3
[__, __, __, __, __, __, __, __], # 4
[__, __, __, __, __, __, __, __], # 5
[__, __, __, __, __, __, __, __], # 6
[__, __, __, __, __, __, __, __] # 7
]
assert_length(board[3][6].get_attack_set(board, [3, 6], []), 0)
assert_contains(
board[3][6].get_move_set(board, [3, 6], []),
[
Move(MoveType.NORMAL, [3, 6], [2, 6])
]
)
return board
def test_pawn_enpassant():
# Advance pawn by two spaces
conducted_move_history = []
board = get_enpassant_board()
board, move_history_element = conduct_move(
board, Move(MoveType.NORMAL, [1, 5], [3, 5]), "black")
conducted_move_history.append(move_history_element)
# Assert white pawn can only do regular attack, one space advance AND enpassant
en_passant_move = Move.en_passant([3, 6], [2, 5])
assert_contains(
board[3][6].get_attack_set(board, [3, 6], conducted_move_history),
[en_passant_move])
# Actually execute en passant move
board, move_history_element = conduct_move(board, en_passant_move, "white")
conducted_move_history.append(move_history_element)
__ = BlankPiece()
p2 = Pawn("black")
wp = Pawn("white")
# 0 1 2 3 4 5 6 7
expected_board = [
[__, __, __, __, __, __, __, __], # 0
[__, __, __, __, __, __, __, p2], # 1
[__, __, __, __, __, wp, __, __], # 2
[__, __, __, __, __, __, __, __], # 3
[__, __, __, __, __, __, __, __], # 4
[__, __, __, __, __, __, __, __], # 5
[__, __, __, __, __, __, __, __], # 6
[__, __, __, __, __, __, __, __] # 7
]
assert_row_contain_same_type_elements(expected_board[1], board[1])
assert_row_contain_same_type_elements(expected_board[2], board[2])
assert_row_contain_same_type_elements(expected_board[3], board[3])
def test_white_pawn_movements():
__ = BlankPiece()
p1 = Pawn("white")
p2 = Pawn("white")
p3 = Pawn("white")
p3.has_never_moved = False
# Enemy rook
rr = Rook("black")
# 0 1 2 3 4 5 6 7
board = [
[__, __, __, __, __, __, __, __], # 0
[__, __, __, __, __, __, __, __], # 1
[__, __, __, __, __, __, __, __], # 2
[__, __, __, __, __, __, rr, rr], # 3
[__, __, __, __, __, __, __, p3], # 4
[__, __, __, __, rr, __, __, __], # 5
[p1, __, __, __, __, p2, __, __], # 6
[__, __, __, __, __, __, __, __] # 7
]
# Left-most pawn
assert_length(board[6][0].get_attack_set(board, [6, 0], []), 0)
assert_contains(board[6][0].get_move_set(board, [6, 0], []),
create_list_of_moves(MoveType.NORMAL, [6, 0], [[5, 0], [4, 0]]))
assert_contains(board[6][5].get_attack_set(board, [6, 5], []),
create_list_of_moves(MoveType.NORMAL, [6, 5], [[5, 4]]))
assert_contains(board[6][5].get_move_set(board, [6, 5], []),
create_list_of_moves(MoveType.NORMAL, [6, 5], [[5, 5], [4, 5]]))
assert_contains(board[4][7].get_attack_set(board, [4, 7], []), create_list_of_moves(MoveType.NORMAL, [4, 7], [[3, 6]]))
assert_length(board[4][7].get_move_set(board, [4, 7], []), 0)
def test_white_pawn_promotion():
__ = BlankPiece()
p1 = Pawn("white")
p2 = Pawn("white")
# Enemy rook
rr = Rook("black")
# 0 1 2 3 4 5 6 7
board = [
[__, __, __, __, __, rr, __, __], # 0
[__, __, p1, __, __, p2, __, __], # 1
[__, __, __, __, __, __, __, __], # 2
[__, __, __, __, __, __, __, __], # 3
[__, __, __, __, __, __, __, __], # 4
[__, __, __, __, __, __, __, __], # 5
[__, __, __, __, __, __, __, __], # 6
[__, __, __, __, __, __, __, __] # 7
]
# Left-most pawn
assert_length(board[1][2].get_attack_set(board, [1, 2], []), 0)
assert_contains(board[1][2].get_move_set(board, [1, 2], []), [
Move.pawn_promotion([1, 2], [0, 2], Queen("white")),
Move.pawn_promotion([1, 2], [0, 2], Bishop("white")),
Move.pawn_promotion([1, 2], [0, 2], Knight("white")),
Move.pawn_promotion([1, 2], [0, 2], Rook("white"))
])
assert_length(board[1][5].get_attack_set(board, [1, 5], []), 0)
assert_length(board[1][5].get_move_set(board, [1, 5], []), 0)
def test_serialization():
__ = BlankPiece()
wp = Pawn("white")
bp = Pawn("black")
br = Rook("black")
bh = Knight("black")
bb = Bishop("black")
bq = Queen("black")
bk = King("black")
# 0 1 2 3 4 5 6 7
board = [
[br, bh, bb, bq, bk, __, __, __], # 0
[bp, __, __, __, __, __, __, __], # 1
[__, __, __, __, __, __, __, __], # 2
[__, __, __, __, __, __, __, __], # 3
[__, __, __, __, __, __, __, __], # 4
[__, __, __, __, __, __, __, __], # 5
[wp, __, __, __, __, __, __, __], # 6
[__, __, __, __, __, __, __, __] # 7
]
serializable_gameboard = convert_to_string_gameboard(board)
expected_gameboard = [
['br', 'bh', 'bb', 'bq', 'bk', '_', '_', '_'],
['bp', '_', '_', '_', '_', '_', '_', '_'],
['_', '_', '_', '_', '_', '_', '_', '_'],
['_', '_', '_', '_', '_', '_', '_', '_'],
['_', '_', '_', '_', '_', '_', '_', '_'],
['_', '_', '_', '_', '_', '_', '_', '_'],
['wp', '_', '_', '_', '_', '_', '_', '_'],
['_', '_', '_', '_', '_', '_', '_', '_']
]
assert_length(serializable_gameboard, 8)
assert_length(serializable_gameboard[3], 8)
if expected_gameboard != serializable_gameboard:
raise AssertionError("Expected gameboard" + str(expected_gameboard) + " but was " + str(serializable_gameboard))
new_board = convert_from_string_gameboard(expected_gameboard)
for i in range(0, len(board)):
for j in range(0, len(board[0])):
expected_piece = board[i][j]
actual_piece = new_board[i][j]
if expected_piece.type != actual_piece.type:
raise AssertionError("Expected piece type at " + str(i) + ", " + str(j) + " was " + expected_piece.type
+ ", but got " + actual_piece.type)
if expected_piece.col != actual_piece.col:
raise AssertionError("Expected piece col at " + str(i) + ", " + str(
j) + " was " + expected_piece.col + " but got " + actual_piece.col)
def test_damiano_mate():
""""""
game = Game([
[Empty() for _ in range(5)] +
[Tower('black'), King('black'), Empty()],
[Empty()
for _ in range(6)] + [Pawn('black'), Queen('white')],
[Empty() for _ in range(6)] + [Pawn('white'), Empty()],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(7)] + [King('white')],
])
assert game.is_check('black'), print(game)
assert game.is_checkmate('black'), print(game)
def test_back_rank_mate():
""""""
game = Game([
[Empty() for _ in range(3)] +
[Tower('white'),
Empty(), Empty(),
King('black'),
Empty()],
[Empty() for _ in range(5)] +
[Pawn('black'), Pawn('black'),
Pawn('black')],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
])
assert game.is_check('black'), print(game)
assert game.is_checkmate('black'), print(game)
def test_check():
# Opposite col test omitted as it requires an alternate implementation *and* player color doesn't effect this test.
_ = BlankPiece()
k = King("white")
k.has_never_moved = False
p = Pawn("black")
p.has_never_moved = False
# 0 1 2 3 4 5 6 7
board = [
[_, _, _, _, _, _, _, _], # 0
[_, _, _, _, _, _, _, _], # 1
[_, _, _, _, _, p, _, _], # 2
[_, _, _, _, k, _, _, _], # 3
[_, _, _, _, _, _, _, _], # 4
[_, _, _, _, _, _, _, _], # 5
[_, _, _, _, _, _, _, _], # 6
[_, _, _, _, _, _, _, _] # 7
]
assert_true("King should be checked", is_being_checked(board, "white"))
# Enemy rook
r = Rook("black")
q = Queen("black")
# 0 1 2 3 4 5 6 7
board = [
[_, _, _, _, _, _, _, _], # 0
[_, _, _, _, _, _, _, _], # 1
[_, _, _, _, _, _, _, _], # 2
[_, _, _, _, _, _, _, _], # 3
[_, _, _, _, _, _, _, _], # 4
[_, _, _, _, _, _, _, _], # 5
[_, _, _, _, _, _, r, _], # 6
[_, _, k, _, _, _, _, q] # 7
]
assert_false("Should be checkmate",
can_player_leave_check_state(board, "white", []))
def standard_configuration(cls):
board = cls()
padding = 2
main_rank = seq(Rook, Knight, Bishop, Queen, King, Bishop, Knight, Rook)
board[Rank.ONE][padding:-padding] = main_rank.map(lambda kls: kls(Color.WHITE)).list()
board[Rank.EIGHT][padding:-padding] = main_rank.map(lambda kls: kls(Color.BLACK)).list()
board[Rank.TWO][padding:-padding] = main_rank.map(lambda _: Pawn(Color.WHITE)).list()
board[Rank.SEVEN][padding:-padding] = main_rank.map(lambda _: Pawn(Color.BLACK)).list()
board.kings = {
Color.BLACK: Position(Rank.EIGHT, File.E),
Color.WHITE: Position(Rank.ONE, File.E),
}
board.player, board.enemy = Color.WHITE, Color.BLACK
board.castling_perms[Color.WHITE] = CastlingPerm.ALL
board.castling_perms[Color.BLACK] = CastlingPerm.ALL
return board
def test_pieces_can_capture_opponent_pieces():
board = Board(initial_pieces={
'a8': King('black'),
'e5': Pawn('black'),
'f3': Knight('white')
})
assert board.pieces_quantity() == 3
knight = board.get_piece('f3')
board.move('f3', 'e5')
assert board.get_piece('e5') is knight
assert board.pieces_quantity() == 2
def test_fail_castling_when_king_already_moved():
board = Board(initial_pieces={
'a8': King('black'),
'a7': Pawn('black'),
'e1': King('white'),
'h1': Rook('white')})
board.move('e1', 'f1') # king moves
board.move('a7', 'a6') # pawn moves
board.move('f1', 'e1') # king moves back
board.move('a6', 'a5') # pawn moves again
with pytest.raises(ImpossibleMove):
board.move('e1', 'g1')
def test_check():
# Opposite col test omitted as it requires an alternate implementation *and* player color doesn't effect this test.
_ = BlankPiece()
k = King("white")
k.has_never_moved = False
p = Pawn("black")
p.has_never_moved = False
# 0 1 2 3 4 5 6 7
board = [
[_, _, _, _, _, _, _, _], # 0
[_, _, _, _, _, _, _, _], # 1
[_, _, _, _, _, p, _, _], # 2
[_, _, _, _, k, _, _, _], # 3
[_, _, _, _, _, _, _, _], # 4
[_, _, _, _, _, _, _, _], # 5
[_, _, _, _, _, _, _, _], # 6
[_, _, _, _, _, _, _, _] # 7
]
assert_true("King should be checked", is_being_checked(board, "white"))
# Enemy rook
r = Rook("black")
q = Queen("black")
# 0 1 2 3 4 5 6 7
board = [
[_, _, _, _, _, _, _, _], # 0
[_, _, _, _, _, _, _, _], # 1
[_, _, _, _, _, _, _, _], # 2
[_, _, _, _, _, _, _, _], # 3
[_, _, _, _, _, _, _, _], # 4
[_, _, _, _, _, _, _, _], # 5
[_, _, _, _, _, _, r, _], # 6
[_, _, k, _, _, _, _, q] # 7
]
assert_false("Should be checkmate", can_player_leave_check_state(board, "white", []))
def test_fail_castling_when_king_already_moved(self):
board = Board(
initial_pieces={
'a8': King('black'),
'a7': Pawn('black'),
'e1': King('white'),
'h1': Rook('white')
})
board.move('e1', 'f1')
board.move('a7', 'a6') # pawn moves
board.move('f1', 'e1')
board.move('a6', 'a5') # pawn moves
self.assertRaises(ImpossibleMove, board.move, 'e1', 'g1')
def get_enpassant_board():
__ = BlankPiece()
p1 = Pawn("black")
p2 = Pawn("black")
wp = Pawn("white")
wp.has_never_moved = False
# 0 1 2 3 4 5 6 7
board = [
[__, __, __, __, __, __, __, __], # 0
[__, __, __, __, __, p1, __, p2], # 1
[__, __, __, __, __, __, __, __], # 2
[__, __, __, __, __, __, wp, __], # 3
[__, __, __, __, __, __, __, __], # 4
[__, __, __, __, __, __, __, __], # 5
[__, __, __, __, __, __, __, __], # 6
[__, __, __, __, __, __, __, __] # 7
]
assert_length(board[3][6].get_attack_set(board, [3, 6], []), 0)
assert_contains(board[3][6].get_move_set(board, [3, 6], []),
[Move(MoveType.NORMAL, [3, 6], [2, 6])])
return board
def test_castling_left_black(self):
board = Board(initial_pieces={
'a2': Pawn('white'),
'e8': King('black'),
'a8': Rook('black')
})
king = board.squares['e8']
rook = board.squares['a8']
board.move('a2', 'a3') # just because white have to move first
board.move('e8', 'c8')
self.assertIs(king, board.squares['c8'])
self.assertIs(rook, board.squares['d8'])
self.assertIsNone(board.squares['e8'])
self.assertIsNone(board.squares['a8'])
def test_white_pawn_movements():
__ = BlankPiece()
p1 = Pawn("white")
p2 = Pawn("white")
p3 = Pawn("white")
p3.has_never_moved = False
# Enemy rook
rr = Rook("black")
# 0 1 2 3 4 5 6 7
board = [
[__, __, __, __, __, __, __, __], # 0
[__, __, __, __, __, __, __, __], # 1
[__, __, __, __, __, __, __, __], # 2
[__, __, __, __, __, __, rr, rr], # 3
[__, __, __, __, __, __, __, p3], # 4
[__, __, __, __, rr, __, __, __], # 5
[p1, __, __, __, __, p2, __, __], # 6
[__, __, __, __, __, __, __, __] # 7
]
# Left-most pawn
assert_length(board[6][0].get_attack_set(board, [6, 0], []), 0)
assert_contains(
board[6][0].get_move_set(board, [6, 0], []),
create_list_of_moves(MoveType.NORMAL, [6, 0], [[5, 0], [4, 0]]))
assert_contains(board[6][5].get_attack_set(board, [6, 5], []),
create_list_of_moves(MoveType.NORMAL, [6, 5], [[5, 4]]))
assert_contains(
board[6][5].get_move_set(board, [6, 5], []),
create_list_of_moves(MoveType.NORMAL, [6, 5], [[5, 5], [4, 5]]))
assert_contains(board[4][7].get_attack_set(board, [4, 7], []),
create_list_of_moves(MoveType.NORMAL, [4, 7], [[3, 6]]))
assert_length(board[4][7].get_move_set(board, [4, 7], []), 0)
def test_corner_mate():
""""""
game = Game([
[Empty() for _ in range(7)] + [King('black')],
[Empty() for _ in range(5)] +
[Horse('white'), Empty(), Pawn('black')],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(6)] + [Tower('white'), Empty()],
])
assert game.is_check('black'), print(game)
assert game.is_checkmate('black'), print(game)
def test_black_pawn_movements():
__ = BlankPiece()
p1 = Pawn("black")
p2 = Pawn("black")
p3 = Pawn("black")
# Enemy rook
rr = Rook("white")
# 0 1 2 3 4 5 6 7
board = [
[__, __, __, __, __, __, __, __], # 0
[p1, __, __, __, __, p2, __, __], # 1
[__, __, __, __, rr, __, __, __], # 2
[__, __, __, __, __, __, __, p3], # 3
[__, __, __, __, __, __, rr, rr], # 4
[__, __, __, __, __, __, __, __], # 5
[__, __, __, __, __, __, __, __], # 6
[__, __, __, __, __, __, __, __] # 7
]
# Left-most pawn
assert_length(board[1][0].get_attack_set(board, [1, 0], []), 0)
assert_contains(
board[1][0].get_move_set(board, [1, 0], []),
create_list_of_moves(MoveType.NORMAL, [1, 0], [[2, 0], [3, 0]]))
assert_contains(board[1][5].get_attack_set(board, [1, 5], []),
create_list_of_moves(MoveType.NORMAL, [1, 5], [[2, 4]]))
assert_contains(
board[1][5].get_move_set(board, [1, 5], []),
create_list_of_moves(MoveType.NORMAL, [1, 5], [[2, 5], [3, 5]]))
assert_contains(board[3][7].get_attack_set(board, [3, 7], []),
create_list_of_moves(MoveType.NORMAL, [3, 7], [[4, 6]]))
assert_length(board[3][7].get_move_set(board, [3, 7], []), 0)
def test_anastasia_s_mate():
""""""
game = Game([
[Empty() for _ in range(8)],
[Empty() for _ in range(4)] +
[Horse('white'), Empty(),
Pawn('black'), King('black')],
[Empty() for _ in range(8)],
[Empty() for _ in range(7)] + [Tower('white')],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[King('white')] + [Empty() for _ in range(7)],
])
assert game.is_check('black'), print(game)
assert game.is_checkmate('black'), print(game)
def test_anderssen_s_mate():
""""""
game = Game([
[Empty()
for _ in range(6)] + [King('black'), Tower('white')],
[Empty() for _ in range(6)] + [Pawn('white'), Empty()],
[Empty() for _ in range(5)] +
[King('white'), Empty(), Empty()],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
])
assert game.is_check('black'), print(game)
assert game.is_checkmate('black'), print(game)
def test_bodens_mate():
""""""
game = Game([
[Empty(), Empty()] + [King('black'), Tower('black')] +
[Empty() for _ in range(4)],
[Empty()
for _ in range(3)] + [Pawn('black')] + [Empty() for _ in range(4)],
[Bishop('white')] + [Empty() for _ in range(7)],
[Empty() for _ in range(8)],
[Empty() for _ in range(5)] +
[Bishop('white'), Empty(), Empty()],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
[Empty() for _ in range(8)],
])
assert game.is_check('black'), print(game)
assert game.is_checkmate('black'), print(game)
def test_knight_capture(self):
board = Board(initial_pieces={
'a8': King('black'),
'e5': Pawn('black'),
'f3': Knight('white')
})
pieces = [
piece for piece in board.squares.values() if piece is not None
]
self.assertEqual(3, len(pieces))
knight = board.squares['f3']
board.move('f3', 'e5')
self.assertIs(knight, board.squares['e5'])
pieces = [
piece for piece in board.squares.values() if piece is not None
]
self.assertEqual(2, len(pieces))
def get_fifty_move_rule_board():
"""
Helper function to run through the first 3 moves in a "four move rule" (use a smaller deque for sanity here -- 50
is a lot),
"""
#
conducted_move_history = deque([], 4)
__ = BlankPiece()
wk = King("white")
wp = Pawn("white")
br = Rook("black")
bk = King("black")
# 0 1 2 3 4 5 6 7
board = [
[__, __, __, bk, __, __, __, __], # 0
[__, __, __, __, __, __, __, __], # 1
[__, __, __, __, __, __, __, __], # 2
[__, br, __, __, __, __, __, __], # 3
[__, __, __, __, __, __, __, __], # 4
[__, __, __, __, __, __, __, __], # 5
[__, wp, __, __, __, __, __, __], # 6
[__, __, __, __, wk, __, __, __] # 7
]
msg = "Should NOT be 50-move rule draw"
board, move_history_element = conduct_move(
board, Move(MoveType.NORMAL, [7, 4], [7, 1]), "white")
conducted_move_history.append(move_history_element)
assert_false(msg, is_fifty_move_rule_draw(conducted_move_history))
board, move_history_element = conduct_move(
board, Move(MoveType.NORMAL, [7, 1], [7, 2]), "white")
conducted_move_history.append(move_history_element)
assert_false(msg, is_fifty_move_rule_draw(conducted_move_history))
board, move_history_element = conduct_move(
board, Move(MoveType.NORMAL, [7, 2], [7, 3]), "white")
conducted_move_history.append(move_history_element)
assert_false(msg, is_fifty_move_rule_draw(conducted_move_history))
return board, conducted_move_history
def get_castling_board():
# Home rank is just a constant in the castling implementation
# so it's asserted unit testing only white piece's castling is sufficient
__ = BlankPiece()
p = Pawn("white")
k = King("white")
r1 = Rook("white")
r2 = Rook("white")
# 0 1 2 3 4 5 6 7
return [
[__, __, __, __, __, __, __, __], # 0
[__, __, __, __, __, __, __, __], # 1
[__, __, __, __, __, __, __, __], # 2
[__, __, __, __, __, __, __, __], # 3
[__, __, __, __, __, __, __, __], # 4
[__, __, __, __, __, __, __, __], # 5
[__, __, __, p, p, p, __, __], # 6
[r1, __, __, __, k, __, __, r2] # 7
]
def print_board(player_color, board):
# Direction of board depends on player color
player_dir_increment = Pawn(player_color).forward_dir
row_number = 8
if player_color == "black":
board = board.copy()
list.reverse(board)
row_number = 1
print(' a b c d e f g h')
for row in board[:]:
print(row_number, end=' ')
for piece in row[:]:
if not piece.is_blank_piece:
print(piece.unicode_symbol.decode("utf-8", "ignore"), end=' ')
else:
# just for prettiness
print('_', end=' ')
row_number = row_number + player_dir_increment
print(end='\n') # next row
print(' a b c d e f g h')
def convert_from_string_gameboard(serializable_gameboard):
"""
Get gameboard from the serializable entity.
Note: This information is only useful for display purposes. (information such as whether castling is still a
valid move does not exist here).
:param game_board: list of lists containing "wp" or "bk" to represent white pawn or black knight.
:return: list of list containing instances of the Piece class
"""
gameboard = []
for row in serializable_gameboard:
gameboard_row = []
for piece in row:
piece_col = ""
if piece == "_":
gameboard_row.append(BlankPiece())
else:
if piece[0] == "w":
piece_col = "white"
elif piece[0] == "b":
piece_col = "black"
if piece[1] == "r":
gameboard_row.append(Rook(piece_col))
elif piece[1] == "h":
gameboard_row.append(Knight(piece_col))
elif piece[1] == "b":
gameboard_row.append(Bishop(piece_col))
elif piece[1] == "q":
gameboard_row.append(Queen(piece_col))
elif piece[1] == "k":
gameboard_row.append(King(piece_col))
elif piece[1] == "p":
gameboard_row.append(Pawn(piece_col))
gameboard.append(gameboard_row)
return gameboard
def test_pawn_cant_move_back():
board = Board(initial_pieces={'b4': Pawn('white')})
with pytest.raises(ImpossibleMove):
assert board.move('b4', 'b3')
def test_pawn_move(self):
pawn = Pawn('white')
self.assertTrue(pawn.can_move('b4', 'b5'))
self.assertTrue(pawn.can_move('e7', 'e8'))
def test_fail_pawn_move(self):
pawn = Pawn('white')
self.assertFalse(pawn.can_move('e2', 'e8'))
def test_fail_pawn_move_back(self):
pawn = Pawn('white')
self.assertFalse(pawn.can_move('b4', 'b3'))
def __init__(self, initial_pieces=None):
self.check = None
self.__turn = 'white'
self.__squares = {}
self.__initial_pieces = initial_pieces or {
'a1': Rook('white'),
'b1': Knight('white'),
'c1': Bishop('white'),
'd1': Queen('white'),
'e1': King('white'),
'f1': Bishop('white'),
'g1': Knight('white'),
'h1': Rook('white'),
'a2': Pawn('white'),
'b2': Pawn('white'),
'c2': Pawn('white'),
'd2': Pawn('white'),
'e2': Pawn('white'),
'f2': Pawn('white'),
'g2': Pawn('white'),
'h2': Pawn('white'),
'a8': Rook('black'),
'b8': Knight('black'),
'c8': Bishop('black'),
'd8': Queen('black'),
'e8': King('black'),
'f8': Bishop('black'),
'g8': Knight('black'),
'h8': Rook('black'),
'a7': Pawn('black'),
'b7': Pawn('black'),
'c7': Pawn('black'),
'd7': Pawn('black'),
'e7': Pawn('black'),
'f7': Pawn('black'),
'g7': Pawn('black'),
'h7': Pawn('black'),
}
for _x in x:
for _y in y:
self.__squares[_x + _y] = None
if _x + _y in self.__initial_pieces:
self.__squares[_x + _y] = self.__initial_pieces[_x + _y]
def pawn_row(self, color):
return [Pawn(color, self) for j in range(len(self))]
def test_teleporting_pieces(player_col, opponent_col):
_ = BlankPiece()
k = King(player_col)
k.has_never_moved = False
h = Knight(player_col)
# Enemy rook
e = Rook(opponent_col)
# Friendly Pawn
f = Pawn(player_col)
f.has_never_moved = False
# 0 1 2 3 4 5 6 7
board = [
[h, _, _, _, _, _, _, _], # 0
[_, _, _, _, _, _, _, _], # 1
[_, _, _, f, _, e, _, _], # 2
[_, _, _, _, _, _, _, _], # 3
[_, _, _, _, h, _, _, _], # 4
[_, _, _, _, _, _, _, _], # 5
[_, h, _, _, _, _, _, _], # 6
[_, _, _, _, _, _, _, k] # 7
]
# Top-left knight
assert_length(board[0][0].get_move_set(board, [0, 0], []), 0)
assert_contains(
board[0][0].get_attack_set(board, [0, 0], []),
create_list_of_moves(MoveType.NORMAL, [0, 0], [
[1, 2],
[2, 1],
]))
# Knight near bottom
assert_length(board[6][1].get_move_set(board, [6, 1], []), 0)
assert_contains(
board[6][1].get_attack_set(board, [6, 1], []),
create_list_of_moves(MoveType.NORMAL, [6, 1],
[[4, 0], [4, 2], [5, 3], [7, 3]]))
# Middle knight
assert_length(board[4][4].get_move_set(board, [4, 4], []), 0)
assert_contains(
board[4][4].get_attack_set(board, [4, 4], []),
create_list_of_moves(
MoveType.NORMAL, [4, 4],
[[2, 5], [6, 5], [6, 3], [3, 2], [5, 2], [3, 6], [5, 6]]))
# Bottom-right king
assert_length(board[7][7].get_move_set(board, [7, 7], []), 0)
assert_contains(
board[7][7].get_attack_set(board, [7, 7], []),
create_list_of_moves(
MoveType.NORMAL,
[7, 7],
[ # Up
[6, 7],
# Left
[7, 6],
# north-east
[6, 6]
]))
def __init__(self):
self.classic = ([
Rook.Rook(0, "White", 0, 0),
Knight.Knight(1, "White", 1, 0),
Bishop.Bishop(2, "White", 2, 0),
Queen.Queen(3, "White", 3, 0),
King.King(4, "White", 4, 0),
Bishop.Bishop(5, "White", 5, 0),
Knight.Knight(6, "White", 6, 0),
Rook.Rook(7, "White", 7, 0),
Pawn.Pawn(8, "White", 0, 1),
Pawn.Pawn(9, "White", 1, 1),
Pawn.Pawn(10, "White", 2, 1),
Pawn.Pawn(11, "White", 3, 1),
Pawn.Pawn(12, "White", 4, 1),
Pawn.Pawn(13, "White", 5, 1),
Pawn.Pawn(14, "White", 6, 1),
Pawn.Pawn(15, "White", 7, 1)
], [
Pawn.Pawn(16, "Black", 0, 6),
Pawn.Pawn(17, "Black", 1, 6),
Pawn.Pawn(18, "Black", 2, 6),
Pawn.Pawn(19, "Black", 3, 6),
Pawn.Pawn(20, "Black", 4, 6),
Pawn.Pawn(21, "Black", 5, 6),
Pawn.Pawn(22, "Black", 6, 6),
Pawn.Pawn(23, "Black", 7, 6),
Rook.Rook(24, "Black", 0, 7),
Knight.Knight(25, "Black", 1, 7),
Bishop.Bishop(26, "Black", 2, 7),
King.King(27, "Black", 4, 7),
Queen.Queen(28, "Black", 3, 7),
Bishop.Bishop(29, "Black", 5, 7),
Knight.Knight(30, "Black", 6, 7),
Rook.Rook(31, "Black", 7, 7)
])
self.table = Table.Table(self.classic[0], self.classic[1])
self.shift = "White"
self.player1 = ("Player 1", "White")
self.player2 = ("Player 2", "Black")
self.winner = None
self.finish = False
def test_pawn():
piece = Pawn(Color.WHITE, Position(x=3, y=3))
assert piece.can_move_to(Position(x=3, y=4))
assert piece.can_move_to(Position(x=3, y=5))
piece.move_to(Position(x=3, y=4))
assert not piece.can_move_to(Position(x=3, y=6))
piece = Pawn(Color.BLACK, Position(x=3, y=3))
assert piece.can_move_to(Position(x=3, y=2))
assert piece.can_move_to(Position(x=3, y=1))
piece.move_to(Position(x=3, y=2))
assert not piece.can_move_to(Position(x=3, y=0))
# Knight
assert not piece.can_move_to(Position(x=4, y=5))
assert not piece.can_move_to(Position(x=2, y=5))
assert not piece.can_move_to(Position(x=4, y=1))
assert not piece.can_move_to(Position(x=2, y=1))
assert not piece.can_move_to(Position(x=1, y=2))
assert not piece.can_move_to(Position(x=1, y=4))
assert not piece.can_move_to(Position(x=5, y=2))
assert not piece.can_move_to(Position(x=5, y=4))
# Queen
assert not piece.can_move_to(Position(x=7, y=3))
assert not piece.can_move_to(Position(x=3, y=7))
assert not piece.can_move_to(Position(x=1, y=1))
assert not piece.can_move_to(Position(x=5, y=5))
assert not piece.can_move_to(Position(x=1, y=5))
def test_teleporting_pieces(player_col, opponent_col):
_ = BlankPiece()
k = King(player_col)
k.has_never_moved = False
h = Knight(player_col)
# Enemy rook
e = Rook(opponent_col)
# Friendly Pawn
f = Pawn(player_col)
f.has_never_moved = False
# 0 1 2 3 4 5 6 7
board = [
[h, _, _, _, _, _, _, _], # 0
[_, _, _, _, _, _, _, _], # 1
[_, _, _, f, _, e, _, _], # 2
[_, _, _, _, _, _, _, _], # 3
[_, _, _, _, h, _, _, _], # 4
[_, _, _, _, _, _, _, _], # 5
[_, h, _, _, _, _, _, _], # 6
[_, _, _, _, _, _, _, k] # 7
]
# Top-left knight
assert_length(board[0][0].get_move_set(board, [0, 0], []), 0)
assert_contains(board[0][0].get_attack_set(board, [0, 0], []),
create_list_of_moves(MoveType.NORMAL, [0, 0],
[
[1, 2],
[2, 1],
]))
# Knight near bottom
assert_length(board[6][1].get_move_set(board, [6, 1], []), 0)
assert_contains(board[6][1].get_attack_set(board, [6, 1], []),
create_list_of_moves(MoveType.NORMAL, [6, 1],
[
[4, 0],
[4, 2],
[5, 3],
[7, 3]
]))
# Middle knight
assert_length(board[4][4].get_move_set(board, [4, 4], []), 0)
assert_contains(board[4][4].get_attack_set(board, [4, 4], []),
create_list_of_moves(MoveType.NORMAL, [4, 4],
[
[2, 5],
[6, 5],
[6, 3],
[3, 2],
[5, 2],
[3, 6],
[5, 6]
]))
# Bottom-right king
assert_length(board[7][7].get_move_set(board, [7, 7], []), 0)
assert_contains(board[7][7].get_attack_set(board, [7, 7], []),
create_list_of_moves(MoveType.NORMAL, [7, 7],
[ # Up
[6, 7],
# Left
[7, 6],
# north-east
[6, 6]
]))
def test_sliding_pieces(player_col, opponent_col):
_ = BlankPiece()
r = Rook(player_col)
b = Bishop(player_col)
q = Queen(player_col)
# Enemy rook
e = Rook(opponent_col)
# Friendly Pawn
f = Pawn(player_col)
f.has_never_moved = False
# 0 1 2 3 4 5 6 7
board = [
[r, _, _, e, _, _, _, _], # 0
[_, _, _, _, _, _, r, _], # 1
[_, _, q, _, _, _, f, _], # 2
[_, _, _, _, _, _, _, _], # 3
[_, _, _, _, _, _, _, _], # 4
[_, _, _, b, _, _, _, _], # 5
[_, _, _, _, _, _, _, _], # 6
[_, _, e, _, _, _, _, f] # 7
]
# Top-left rook
assert_length(board[0][0].get_move_set(board, [0, 0], []), 0)
assert_contains(
board[0][0].get_attack_set(board, [0, 0], []),
create_list_of_moves(
MoveType.NORMAL,
[0, 0],
[ # Down
[1, 0],
[2, 0],
[3, 0],
[4, 0],
[5, 0],
[6, 0],
[7, 0],
# Right
[0, 1],
[0, 2],
[0, 3]
]))
# Second rook
assert_length(board[1][6].get_move_set(board, [1, 6], []), 0)
assert_contains(
board[1][6].get_attack_set(board, [1, 6], []),
create_list_of_moves(
MoveType.NORMAL,
[1, 6],
[ # Up
[0, 6],
# Left
[1, 5],
[1, 4],
[1, 3],
[1, 2],
[1, 1],
[1, 0],
# Right
[1, 7]
]))
# Bishop
assert_length(board[5][3].get_move_set(board, [5, 3], []), 0)
assert_contains(
board[5][3].get_attack_set(board, [5, 3], []),
create_list_of_moves(
MoveType.NORMAL,
[5, 3],
[ # North-west
[4, 2],
[3, 1],
[2, 0],
# North-east
[4, 4],
[3, 5],
# South-west
[6, 2],
[7, 1],
# South-east
[6, 4],
[7, 5]
]))
# Queen
assert_length(board[2][2].get_move_set(board, [2, 2], []), 0)
assert_contains(
board[2][2].get_attack_set(board, [2, 2], []),
create_list_of_moves(
MoveType.NORMAL,
[2, 2],
[ # Down
[3, 2],
[4, 2],
[5, 2],
[6, 2],
[7, 2],
# Up
[1, 2],
[0, 2],
# Left
[2, 0],
[2, 1],
# Right
[2, 3],
[2, 4],
[2, 5],
# North-west
[1, 1],
# North-east
[1, 3],
[0, 4],
# South-west
[3, 1],
[4, 0],
# South-east
[3, 3],
[4, 4],
[5, 5],
[6, 6]
]))
def test_sliding_pieces(player_col, opponent_col):
_ = BlankPiece()
r = Rook(player_col)
b = Bishop(player_col)
q = Queen(player_col)
# Enemy rook
e = Rook(opponent_col)
# Friendly Pawn
f = Pawn(player_col)
f.has_never_moved = False
# 0 1 2 3 4 5 6 7
board = [
[r, _, _, e, _, _, _, _], # 0
[_, _, _, _, _, _, r, _], # 1
[_, _, q, _, _, _, f, _], # 2
[_, _, _, _, _, _, _, _], # 3
[_, _, _, _, _, _, _, _], # 4
[_, _, _, b, _, _, _, _], # 5
[_, _, _, _, _, _, _, _], # 6
[_, _, e, _, _, _, _, f] # 7
]
# Top-left rook
assert_length(board[0][0].get_move_set(board, [0, 0], []), 0)
assert_contains(board[0][0].get_attack_set(board, [0, 0], []),
create_list_of_moves(MoveType.NORMAL, [0, 0],
[ # Down
[1, 0], [2, 0], [3, 0], [4, 0], [5, 0], [6, 0], [7, 0],
# Right
[0, 1], [0, 2], [0, 3]
]))
# Second rook
assert_length(board[1][6].get_move_set(board, [1, 6], []), 0)
assert_contains(board[1][6].get_attack_set(board, [1, 6], []),
create_list_of_moves(MoveType.NORMAL, [1, 6],
[ # Up
[0, 6],
# Left
[1, 5], [1, 4], [1, 3], [1, 2], [1, 1], [1, 0],
# Right
[1, 7]
]))
# Bishop
assert_length(board[5][3].get_move_set(board, [5, 3], []), 0)
assert_contains(board[5][3].get_attack_set(board, [5, 3], []),
create_list_of_moves(MoveType.NORMAL, [5, 3],
[ # North-west
[4, 2], [3, 1], [2, 0],
# North-east
[4, 4], [3, 5],
# South-west
[6, 2], [7, 1],
# South-east
[6, 4], [7, 5]
]))
# Queen
assert_length(board[2][2].get_move_set(board, [2, 2], []), 0)
assert_contains(board[2][2].get_attack_set(board, [2, 2], []),
create_list_of_moves(MoveType.NORMAL, [2, 2],
[ # Down
[3, 2], [4, 2], [5, 2], [6, 2], [7, 2],
# Up
[1, 2], [0, 2],
# Left
[2, 0], [2, 1],
# Right
[2, 3], [2, 4], [2, 5],
# North-west
[1, 1],
# North-east
[1, 3], [0, 4],
# South-west
[3, 1], [4, 0],
# South-east
[3, 3], [4, 4], [5, 5], [6, 6]
]))
