blokus/blokus.py

#!/usr/bin/env python
import numpy as np
import random

BOARD_SIZE = 14

def make_board():
    a = np.array([[0 for i in range(BOARD_SIZE)] for j in range(BOARD_SIZE)])
    a[4,4] = -1
    a[9,9] = -1
    return a

tiles = [
    np.array([[1]]),
    np.array([[1],[1]]),
    np.array([[1],[1],[1]]),
    np.array([[1,0],[1,1]]),
    np.array([[1],[1],[1],[1]]),
    np.array([[1,0],[1,0],[1,1]]),
    np.array([[1,0],[1,1],[1,0]]),
    np.array([[1,1],[1,1]]),
    np.array([[1,1,0],[0,1,1]]),
    np.array([[1],[1],[1],[1],[1]]),
    np.array([[1,0],[1,0],[1,0],[1,1]]),
    np.array([[1,0],[1,0],[1,1],[0,1]]),
    np.array([[1,0],[1,1],[1,1]]),
    np.array([[1,1],[1,0],[1,1]]),
    np.array([[1,0],[1,1],[1,0],[1,0]]),
    np.array([[0,1,0],[0,1,0],[1,1,1]]),
    np.array([[1,0,0],[1,0,0],[1,1,1]]),
    np.array([[1,1,0],[0,1,1],[0,0,1]]),
    np.array([[1,0,0],[1,1,1],[0,0,1]]),
    np.array([[1,0,0],[1,1,1],[0,1,0]]),
    np.array([[0,1,0],[1,1,1],[0,1,0]]),
]


def get_permutations(which_tiles: list[tuple[int,int]]):
    permutations = []
    for i,tile in enumerate(tiles):
        if i not in which_tiles:
            continue
        permutations.append((i,tile))
        permutations.append((i,np.rot90(tile)))
        permutations.append((i,np.rot90(np.rot90(tile))))
        permutations.append((i,np.rot90(np.rot90(np.rot90(tile)))))
        permutations.append((i,np.flip(tile)))
        permutations.append((i,np.flip(np.rot90(tile))))
        permutations.append((i,np.flip(np.rot90(np.rot90(tile)))))
        permutations.append((i,np.flip(np.rot90(np.rot90(np.rot90(tile))))))

    unique_arrays = []
    for arr in permutations:
        if not any(np.array_equal(arr, u) for u in unique_arrays):
            unique_arrays.append(arr)

    return unique_arrays

def can_place(board, tile, player):
    placements = []
    has_minus_one = False
    for x in range(BOARD_SIZE):
        for y in range(BOARD_SIZE):
            if board[x,y] == -1:
                has_minus_one = True
            with np.nditer(tile, flags=['multi_index']) as it:
                for v in it:
                    if v == 1:
                        (i,j) = it.multi_index
                        if x + i >= BOARD_SIZE:
                            break
                        if y + j >= BOARD_SIZE:
                            break
                        if board[x + i][y + j] > 0:
                            break
                        if x + i - 1 >= 0 and board[x + i - 1][y+j] == player:
                            break
                        if y + j - 1 >= 0 and board[x + i][y + j - 1] == player:
                            break
                        if x + i + 1 < BOARD_SIZE and board[x + i + 1][y+j] == player:
                            break
                        if y + j + 1 < BOARD_SIZE and board[x + i][y+j+1] == player:
                            break
                else:
                    placements.append((x,y))
    final = []
    if has_minus_one:
        for (x,y) in placements:
            with np.nditer(tile, flags=['multi_index']) as it:
                for v in it:
                    (i,j) = it.multi_index
                    if v == 1 and board[x+i,y+j] == -1:
                        final.append((x,y))
                        break
    else:
        for (x,y) in placements:
            with np.nditer(tile, flags=['multi_index']) as it:
                for v in it:
                    (i,j) = it.multi_index
                    if x+i+1 < BOARD_SIZE and y+j+1 < BOARD_SIZE and board[x+i+1][y+j+1] == player:
                        final.append((x,y))
                        break
                    if x+i+1 < BOARD_SIZE and y+j-1 >= 0 and board[x+i+1][y+j-1] == player:
                        final.append((x,y))
                        break
                    if x+i-1 >= 0 and y+j+1 < BOARD_SIZE and board[x+i-1][y+j+1] == player:
                        final.append((x,y))
                        break
                    if x+i-1 >= 0 and y+j-1 >= 0 and board[x+i-1][y+j-1] == player:
                        final.append((x,y))
                        break
    return final

def do_placement(tidx, tile, placement, game_state, player):
    (x,y) = placement
    with np.nditer(tile, flags=['multi_index']) as it:
        for v in it:
            (i,j) = it.multi_index
            if v == 1:
                game_state[0][x+i,y+j] = player
    game_state[player].remove(tidx)

def print_game_state(game_state):
    (board, p1tiles, p2tiles) = game_state

    for row in board:
        print("".join([" " if x == 0 else "X" if x == 1 else "O" if x == 2 else "S" for x in row]))

    print("")
    print(f"Player 1 tiles left: {p1tiles}")
    print(f"Player 2 tiles left: {p2tiles}")

game_state = (
    make_board(),
    [i for i in range(21)],
    [i for i in range(21)],
)


playing = True
player = 1
while playing:
    moves = []
    for (tidx, tile) in get_permutations(game_state[player]):
        for placement in can_place(game_state[0], tile, player):
            moves.append((tidx, tile, placement))

    print_game_state(game_state)
    print(f"player {player} has {len(moves)} options")

    if len(moves) == 0:
        print(f"No moves left, player {player} lost")
        playing = False
        continue

    (tidx, tile, placement) = random.choice(moves)
    do_placement(tidx, tile, placement, game_state, player)


    if player == 1:
        player = 2
    elif player == 2:
        player = 1