2 of 5 edited title

Implement a movement function in my python 2.7 checkers game

I am working on a python checkers game for college. I have the board drawn, using tk, but I can't seem to implement a movement function for the pieces. If anyone see any errors in my code, or can offer help, I would appreciate. Here is the complete source. Thanks in advance.


from Tkinter import *
import thread
import random
import time

root = Tk()
size = 500
root.geometry("500x500")
root.title("Checkers")

padding = size / 10
#xSize = ySize = 0
board = []
#Normally 3 and 3, but could make bigger board
rows=0
cols=0
#records whether it's X or O's turn
turn=0
rPiece = 2
rKPiece = 4
bPiece = 1
bKPiece = 3
firstPass = 0
firstPositon = []
secondPass = 0
secondPosition = []
press = 0

canvas = Canvas(root,width=size, height=size, bg="White")

#Frame rate is how often canvas will be updated
# each second. For Tic Tac Toe, 10 should be plenty.
FRAME_RATE = 10


#Function responsible for starting the drawing thread
def startDrawing():
    thread.start_new(drawThread,())


#Function where the drawing thread picks up.
# It runs independently of the mainloop(), but
# it can still access global variables if needed.
def drawThread():

    #Width and height of each 'block' on the screen.
    #This number is in pixels.
    width = size / 10
    height = size / 10

    #declare canvas and root as global since
    # we want to be able to interact with them.
    global canvas, root, board
    print 'in draw thread'
    over = False

    #horizontal lines.  These lines won't be
    # deleted since they should always be there.
#Why are the beginning and end points what they are?
c = 1
while c < 10:
    canvas.create_line(width,height*c,width*9,height*c)
    c += 1
else:
    c = 1

#vertical lines.  These lines won't be
# deleted since they should always be there.
#Why are the beginning and end points what they are?
while c < 10:
    canvas.create_line(width*c,height,width*c,height*9)
    c += 1
else:
    c = 1


#Draw the black odd squares
d = 1
k = 2
l = 1
m = 2

while l < 9:
    while d < 8:
        canvas.create_rectangle(height*l,height*d,width*m,width*k,fill="DarkOliveGreen4")
        k += 2
        d += 2
    else:
        k = 2
        d = 1
    l += 2
    m += 2
else:
    l = 2
    m = 3
    d = 2
    k = 3


#Draw the black even squares
while l < 9:
    while d < 9:
        canvas.create_rectangle(height*l,height*d,width*m,width*k,fill="DarkOliveGreen4")
        d += 2
        k += 2
    else:
        k = 3
        d = 2
    l += 2
    m += 2
else:
    l = 1
    m = 2
    d = 1
    k = 2




#over becomes True when the game is over (win or draw)
while over == False:
    #List variable to store the text objects from
    #when we draw X and O in different cells of the board
    #Not used to delete yet, but program could be extended
    #to "start new game". To do this, the X's and O's that
    #have been draw would need to be deleted.
    lst2 = []

    #counter variable
    i=0

    #board variable is what stores the X/O/- values.
    # It's a 2D list. We iterate over it, looking to see
    # if there is a value that is X or O. If so, we draw
    # text to the screen in the appropriate spot (based on
    # i and j.
    while i < len(board):
        j=0
        while j < len(board[i]):

            if board[i][j] == 2:
                lst2.append(canvas.create_oval((i+1)*width + width/2 + 15,(j+1)*height + height/2 +15,(i+1)*width + width/2 - 15,(j+1)*width + width/2 - 15,fill="Red",outline='Black'))
            elif board[i][j] == 4:
                lst2.append(canvas.create_oval((i+1)*width + width/2 + 15,(j+1)*height + height/2 +15,(i+1)*width + width/2 - 15,(j+1)*width + width/2 - 15,fill="Red",outline='Black'))
            elif board[i][j] == 1:
                lst2.append(canvas.create_oval((i+1)*width + width/2 + 15,(j+1)*height + height/2 +15,(i+1)*width + width/2 - 15,(j+1)*width + width/2 - 15,fill="Black",outline='Black'))
            elif board[i][j] == 3:
                lst2.append(canvas.create_oval((i+1)*width + width/2 + 15,(j+1)*height + height/2 +15,(i+1)*width + width/2 - 15,(j+1)*width + width/2 - 15,fill="Black",outline='Black'))

            j+=1

        i+=1

    #like the bind() call, this updates the screen
    root.update_idletasks()

    #puts the program to sleep for 100 ms
    #(since frame rate is 10)
    time.sleep(1.0 / FRAME_RATE)

    #call win method to check to see if someone wins
    winner = win()

    #if X wins, put appropriate message on screen
    if winner == 2:
        over=True
        canvas.create_text(size/2,size/2, text="RED WINS!",font=("helvetica","18"))
    #if O wins, put appropriate message on screen
    elif winner == 1:
        over=True
        canvas.create_text(size/2,size/2, text="BLACK WINS!", font=("helvetica","18"))
    #if draw, put appropriate message on screen
    if draw() == True:
        over=True
        canvas.create_text(size/2,size/2, text="DRAW!", font=("helvetica","18"))


#detect win condition in board
# win is three of the same vert/horiz/diag
# should return -1 for no win, 0 for x win, 1 for o win

def win():
    #Is the board cleared of all red or black pieces?
    rCount = 0
    bCount = 0
    for row in board:
        for cell in row:
            if  cell == rPiece or cell == rKPiece:
                rCount += 1
    for row in board:
        for cell in row:
            if  cell == bPiece or cell == bKPiece:
                bCount += 1


if rCount == 0:
    return 2
if bCount == 0:
    return 1
#Check for errors
if rCount > 12 or bCount > 12:
    return 

#Does a player have three in a row?
# if board[0][0] == board[0][1] and board[0][1] == board[0][2] and board[0][0] != -1:
    # return board[0][0]
# if board[1][0] == board[1][1] and board[1][1] == board[1][2] and board[1][0] != -1:
    # return board[1][0]
# if board[2][0] == board[2][1] and board[2][1] == board[2][2] and board[2][0] != -1:
    # return board[2][0]

#Does a player have three in a column?
# if board[0][0] == board[1][0] and board[1][0] == board[2][0] and board[0][0] != -1:
    # return board[0][0]
# if board[0][1] == board[1][1] and board[1][1] == board[2][1] and board[0][1] != -1:
    # return board[0][1]
# if board[0][2] == board[1][2] and board[1][2] == board[2][2] and board[0][2] != -1:
    # return board[0][2]

#Does a player of a diagonal?
# if board[0][0] == board[1][1] and board[1][1] == board[2][2] and board[0][0] != -1:
    # return board[0][0]
# if board[2][0] == board[1][1] and board[1][1] == board[0][2] and board[2][0] != -1:
    # return board[2][0]

return -1

#If there is no winner but all the spaces are taken,
#then there must be a tie.
def draw():
for row in board:
    for cell in row:
    #if a cell is not taken, can't be a draw
        if cell == -1:
            return False
#If there is a winner, then there can't be a draw
if win()>=0:
    return False
#Otherwise, there must be a draw
else:
    return True




#This function is called to set up the board. 8 and 8
#are usually passed as arguments
def grid(x,y):

global cols,rows,board
i=0
#set number of columns and rows
cols=x
rows=y

board.append([])
board[0].append(1)
board[0].append(-1)
board[0].append(1)
board[0].append(-1)
board[0].append(0)
board[0].append(-1)
board[0].append(2)
board[0].append(-1)

board.append([])
board[1].append(-1)
board[1].append(1)
board[1].append(-1)
board[1].append(0)
board[1].append(-1)
board[1].append(2)
board[1].append(-1)
board[1].append(2)

board.append([])
board[2].append(1)
board[2].append(-1)
board[2].append(1)
board[2].append(-1)
board[2].append(0)
board[2].append(-1)
board[2].append(2)
board[2].append(-1)

board.append([])
board[3].append(-1)
board[3].append(1)
board[3].append(-1)
board[3].append(0)
board[3].append(-1)
board[3].append(2)
board[3].append(-1)
board[3].append(2)

board.append([])
board[4].append(1)
board[4].append(-1)
board[4].append(1)
board[4].append(-1)
board[4].append(0)
board[4].append(-1)
board[4].append(2)
board[4].append(-1)

board.append([])
board[5].append(-1)
board[5].append(1)
board[5].append(-1)
board[5].append(0)
board[5].append(-1)
board[5].append(2)
board[5].append(-1)
board[5].append(2)

board.append([])
board[6].append(1)
board[6].append(-1)
board[6].append(1)
board[6].append(-1)
board[6].append(0)
board[6].append(-1)
board[6].append(2)
board[6].append(-1)

board.append([])
board[7].append(-1)
board[7].append(1)
board[7].append(-1)
board[7].append(0)
board[7].append(-1)
board[7].append(2)
board[7].append(-1)
board[7].append(2)

#initialize board with checker pieces
# while i<x:
    #remember, board is a 2D list
    # board.append([])
    # j=1
    # while j < y:
        # if j % 2 == 0:
        #   -1 means no move yet
            # board[i].append(-1)
            # j+=1
        # else:
            # board[i].append(1)
            # j+=1
    # i+=1

#Assuming the user has clicked cell i,j, this
#function checks to see if it's a valid move. If
#so, it moves the appropriate piece there.
def moveFrom(i,j):
global board, turn, firstPass
k = board[i][j]
#case 1 -- if i or j is off the board
if i < 0 or i >= len(board) or j < 0 or j >= len(board[i]):
    return
#case 2 -- check if selection is white (-1)
elif k == -1:
    return
#case 3 -- check if selected the corect color piece
elif turn != k%2:
    return
#stores the selected position
else:
    firstPass = k
    board[i][j] = 0


def moveTo(i,j):
global board, turn, secondPass, secondPosition
k = board[i][j]
#case 1 -- if i or j is off the board
if i < 0 or i >= len(board) or j < 0 or j >= len(board[i]):
    return
#case 2 -- check if selection is white (-1)
elif k == -1:
    return
#case 3 -- does the new position contain a piece, if not, return
elif k > 0 :
    return
# case 4 -- prevent the black pawn from moving backwards
elif firstPass == bPiece and j != firstPosition[1+1]:
    return
#case 5 -- prevent the red pawn from moving backwards
elif firstPass == rPiece and j != firstPosition[1-1]:
    return
#case 6 -- 
#case 7 -- is the new square a green square
else:
    secondPass = k


def processMove():
global board, turn
board[i][j] == secondPass
turn = (turn + 1) % 2



#case 1 -- if i or j is off the board
# if i < 0 or i >= len(board) or j < 0 or j >= len(board[i]):
    # return
#case 2 -- already been clicked
# elif board[i][j]>=0:
    # return
#case 3 -- if clicked cell is not already taken
# elif board[i][j] <0:
    # board[i][j] = turn
    # turn = (turn + 1) % 2




#Function that handles mouse clicks. From the x,y coordinate
# of the mouse click, it calculates the corresponding i,j
# of the board.

def buttonPressed(event):
#will want to change turn so declare global
global turn, press


#padding is 100 (for a 500x500 board). This is the
#size of each cell. Recall that / does integer math
#so that 323 / 100 is actually 3. If someone clicks at
#pixel 250,250, then i and j are both set to 2.

#debug print so we can see what i,j it calculates

if press == 0:
    i = event.x / padding 
    j = event.y / padding 
    print i, ' ' ,j
    moveFrom(i-1,j-1)
    press = (press + 1) % 2
    return
else:
    i = event.x / padding 
    j = event.y / padding 
    print i, ' ' ,j
    moveTo(i-1,j-1)
    press = (press + 1) % 2



#create tic tac toe board (not the graphics...just the
#logical board representation)
grid(8,8)

#Bind left mouse button clicks to the buttonPressed function
root.bind("<Button-1>",buttonPressed)

#make the canvas visible on the root window
canvas.pack()

#start the drawing thread
startDrawing()

#show the main window
root.mainloop()