Finished full client to web stack, works fine
parent
e760498b3b
commit
581bcd71e9
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@ -12,7 +12,7 @@ local_port = 5001
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# UDP webserver port to bypass frameserver for testing
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# UDP webserver port to bypass frameserver for testing
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remote_port = 4422
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remote_port = 4422
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# port to frameserver
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# port to frameserver
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#remote_port = 4321
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remote_port = 4321
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# TODO: autodetect interface address for remote application
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# TODO: autodetect interface address for remote application
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outgoing_if = "127.0.0.1"
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outgoing_if = "127.0.0.1"
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@ -56,6 +56,9 @@ frequency = 1000 / sleeptime # frames per second
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# function resets map to zero
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# function resets map to zero
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def set_wdata(r, g, b):
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def set_wdata(r, g, b):
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global wdata
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wdata = []
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for x in xrange(width):
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for x in xrange(width):
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wdata.append([0] * height)
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wdata.append([0] * height)
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for y in xrange(height):
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for y in xrange(height):
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@ -80,6 +83,21 @@ def i2c(rgba):
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# ignore rgba[0] because it is the state
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# ignore rgba[0] because it is the state
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return chr(int(rgba[1])) + chr(int(rgba[2])) + chr(int(rgba[3])) + chr(int(rgba[4]))
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return chr(int(rgba[1])) + chr(int(rgba[2])) + chr(int(rgba[3])) + chr(int(rgba[4]))
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# determine if a cells neighbour is active (any will do)
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def has_active_neighb(x, y):
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# check the cell to the left
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if x > 0 and wdata[x - 1][y][0] > 0:
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return True
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# check the cell above
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if y > 0 and wdata[x][y - 1][0] > 0:
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return True
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# check the cell to the right
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if x < (width - 1) and wdata[x + 1][y][0] > 0:
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return True
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# check the cell below
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if y < (height - 1) and wdata[x][y + 1][0] > 0:
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return True
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# function sends wdata and sdata state to server
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# function sends wdata and sdata state to server
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def send_update():
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def send_update():
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#zero out the data buffer
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#zero out the data buffer
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@ -105,101 +123,75 @@ def send_update():
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# send the data packet to remote host
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# send the data packet to remote host
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UDPSock.sendto(data,(remote_host,remote_port))
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UDPSock.sendto(data,(remote_host,remote_port))
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# initialize map
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# main loop
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set_wdata(67,67,67)
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while True:
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set_sdata(0,0,255)
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# reset/initialize map
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set_wdata(67,67,67)
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set_sdata(255,255,255)
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# set start seed
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# set start seed
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# get random location
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# get random location
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rx = randint(0, width - 1)
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rx = randint(0, width - 1)
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ry = randint(0, height - 1)
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ry = randint(0, height - 1)
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wdata[rx][ry] = [1,1,0,0,1]
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wdata[rx][ry] = [1,1,0,0,1]
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print "origin(" + str(rx) + "," + str(ry) + ")"
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# print "origin(" + str(rx) + "," + str(ry) + ")"
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def has_active_neighb(x, y):
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# check the cell to the left
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if x > 0 and wdata[x - 1][y][0] > 0:
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return True
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# check the cell above
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if y > 0 and wdata[x][y - 1][0] > 0:
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return True
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# check the cell to the right
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if x < (width - 1) and wdata[x + 1][y][0] > 0:
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return True
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# check the cell below
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if y < (height - 1) and wdata[x][y + 1][0] > 0:
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return True
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# main logic loop
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for t in range(60):
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# push update to clients
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send_update()
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# create CA buffer
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data_buffer = deepcopy(wdata)
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for y in xrange(height):
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for x in xrange(width):
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# if cell is active, increase its rating/value
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if wdata[x][y][0] > 0:
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# change the state of the cell
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data_buffer[x][y][0] += 10
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# assign stat to red colour
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data_buffer[x][y][1] = data_buffer[x][y][0]
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# check we don't go too high
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if data_buffer[x][y][0] > 127:
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data_buffer[x][y][1] = 127
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# assign stat to green colour
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data_buffer[x][y][2] = data_buffer[x][y][0] - 127
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if data_buffer[x][y][0] > 255:
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data_buffer[x][y][2] = 127
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# assign stat to blue colour
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data_buffer[x][y][3] = data_buffer[x][y][0] - 255
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if data_buffer[x][y][0] > 383:
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data_buffer[x][y][3] = 127
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set_sdata(0,0,0)
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# E
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sdata[0][0] = [0,255,0,0,1]
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sdata[0][3] = [0,255,0,0,1]
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sdata[0][4] = [0,255,0,0,1]
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sdata[0][5] = [0,255,0,0,1]
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sdata[0][6] = [0,255,0,0,1]
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# N
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sdata[1][2] = [0,255,0,0,1]
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sdata[1][4] = [0,255,0,0,1]
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sdata[1][5] = [0,255,0,0,1]
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sdata[1][6] = [0,255,0,0,1]
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# D
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sdata[2][1] = [0,255,0,0,1]
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sdata[2][2] = [0,255,0,0,1]
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sdata[2][3] = [0,255,0,0,1]
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sdata[2][4] = [0,255,0,0,1]
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sdata[2][6] = [0,255,0,0,1]
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send_update()
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exit()
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# main logic loop
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for t in range(23):
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# push update to clients
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send_update()
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# if not active, check if adjacent cell is active
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# create CA buffer
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if wdata[x][y][0] == 0 and has_active_neighb(x, y):
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data_buffer = deepcopy(wdata)
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# activate and colour
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data_buffer[x][y][0] = 1
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for y in xrange(height):
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data_buffer[x][y][1] = 1
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for x in xrange(width):
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data_buffer[x][y][2] = 0
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# if cell is active, increase its rating/value
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data_buffer[x][y][3] = 0
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if wdata[x][y][0] > 0:
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# change the state of the cell
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data_buffer[x][y][0] += 16
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# assign stat to red colour
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data_buffer[x][y][1] = data_buffer[x][y][0]
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# check we don't go too high
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# if the state is over 127, reset red
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if data_buffer[x][y][0] > 127:
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# assign max stat to red colour
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data_buffer[x][y][1] = 0
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# assign stat to green colour
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data_buffer[x][y][2] = data_buffer[x][y][0] - 128
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# if the state is over 128*2, reset green
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if data_buffer[x][y][0] > 255:
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# assign max stat to green colour
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data_buffer[x][y][2] = 0
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# assign stat to blue colour
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data_buffer[x][y][3] = data_buffer[x][y][0] - 255
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# if the state is over 128*3, reset blue
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if data_buffer[x][y][0] > 383:
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data_buffer[x][y][3] = data_buffer[x][y][0]%128
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# if not active, check if adjacent cell is active
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if wdata[x][y][0] == 0 and has_active_neighb(x, y):
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# activate and colour
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data_buffer[x][y][0] = 1
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data_buffer[x][y][1] = 1
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data_buffer[x][y][2] = 0
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data_buffer[x][y][3] = 0
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# set wdata to new buffer
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# set wdata to new buffer
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wdata = data_buffer
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wdata = data_buffer
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# wait to paint process next frame
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# wait to paint process next frame
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time.sleep(sleeptime/1000.0)
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time.sleep(sleeptime/1000.0)
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# end of iteration, restart
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# end of main animation loop
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# close socket
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# close socket
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UDPSock.close()
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UDPSock.close()
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@ -27,8 +27,6 @@ UDPSock.bind((outgoing_if, local_port))
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# goes down or refuses connection
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# goes down or refuses connection
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#UDPSock.connect((remote_host, remote_port))
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#UDPSock.connect((remote_host, remote_port))
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segmentsfile = open('segments','r')
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hash = "s2l\n<8<18 " # 10 bytes
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hash = "s2l\n<8<18 " # 10 bytes
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alpha = chr(255)
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alpha = chr(255)
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@ -0,0 +1,99 @@
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# s2llib.py
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# Python utility functions for syndelights
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from socket import *
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import sys, time
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#from copy import deepcopy
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class syndelights_canvas:
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"""Holds the state of the canvas to be sent"""
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segments_in_window = 8
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def __init__(self, hpc, zb, w, h, seg_wins, hs, hsp, ts, tsp, deblvl):
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# get hash passcode and z-buffer depth
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self.hash_passcode = hpc
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self.zed_buffer = zb
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# main window dimensions
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self.width = w
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self.height = h
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# number of windows with segment displays
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self.segmented_windows_num = seg_wins
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# set servers and ports
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self.host_server = hs
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self.host_server_port = hsp
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self.target_server = ts
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self.target_server_port = tsp
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# debugging
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self.debug_level = deblvl
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# make data structures for windows and segments
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self.reset_windows(0,127,127,127, 255)
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self.reset_segment_windows(0, 127, 127, 127, 255)
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def reset_windows(self, state, red, green, blue, alpha):
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self.window_data = []
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for y in xrange(self.height):
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self.window_data.append([0] * self.width)
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for x in xrange(self.width):
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self.window_data[y][x] = dict(s=state, r=red, g=green, b=blue, a=alpha)
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def reset_segment_windows(self, state, red, green, blue, alpha):
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self.segmented_windows = []
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for w in xrange(self.segmented_windows_num):
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self.segmented_windows.append([0] * self.segments_in_window)
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for s in xrange(self.segments_in_window):
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self.segmented_windows[w][s] = dict(s=state, r=red, g=green, b=blue, a=alpha)
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# convert [r, g, b, a] into a 4 character string
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def int2chr(self, rgba_dict):
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return chr(int(rgba_dict["r"])) + chr(int(rgba_dict["g"])) + chr(int(rgba_dict["b"])) + chr(int(rgba_dict["a"]))
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# draw the data object, send it to the target server
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def draw(self):
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# prep header with hash, z-buffer and new line (12 bytes)
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data = self.hash_passcode + chr(self.zed_buffer) + "\n"
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# package window data
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for y in xrange(self.height):
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for x in xrange(self.width):
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data = data + self.int2chr( self.window_data[y][x] )
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data = data + "\n"
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# package segment data
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for w in xrange(self.segmented_windows_num):
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for s in xrange(self.segments_in_window):
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data = data + self.int2chr( self.segmented_windows[w][s] )
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data = data + "\n"
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if self.debug_level > 2:
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print data
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# send the data through UDP to remote server
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self.UDPSock.sendto(data, (self.target_server, self.target_server_port))
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def setwin_xy_srgba_array(self, x, y, srgba):
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self.window_data[y][x] = dict(s=srgba[0], r=srgba[1], g=srgba[2], b=srgba[3], a=srgba[4])
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def setwin_xy_sval(self, x, y, col, val):
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if col == 's':
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self.window_data[y][x]['s'] = val
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if col == 'r':
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self.window_data[y][x]['r'] = val
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if col == 'g':
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self.window_data[y][x]['r'] = val
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if col == 'b':
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self.window_data[y][x]['r'] = val
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if col == 'a':
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self.window_data[y][x]['r'] = val
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def connect(self):
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self.UDPSock = socket(AF_INET, SOCK_DGRAM)
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self.UDPSock.bind((self.host_server, self.host_server_port))
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def disconnect(self):
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self.UDPSock.close()
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@ -0,0 +1,22 @@
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from s2llib import *
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import time
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width = 12
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height = 8
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test = syndelights_canvas("s2l\n<8<18 ", 1, width, height, width, "127.0.0.1", 5001, "127.0.0.1", 4422, 3)
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test = syndelights_canvas("s2l\n<8<18 ", 1, width, height, width, "127.0.0.1", 5001, "127.0.0.1", 4321, 3)
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test.connect()
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test.reset_windows(0, 0, 0, 0, 127)
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test.reset_segment_windows(0, 62, 62, 62, 63)
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for y in xrange(height):
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for x in xrange(width):
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test.setwin_xy_srgba_array(x, y, [0, 255, 0, 0, 127])
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test.draw()
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time.sleep(0.5)
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test.setwin_xy_srgba_array(x, y, [0, 0, 0, 0, 127])
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test.disconnect()
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@ -173,7 +173,7 @@ void Server::listen()
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void Server::send()
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void Server::send()
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{
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{
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const int length = 12 + HEIGHT*(WIDTH*CHANNELS+1) + SEGWIDTH*(SEGNUM*SEGCHANNELS+1);
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const int length = HEADEROFFSET + HEIGHT*(WIDTH*CHANNELS+1) + SEGWIDTH*(SEGNUM*SEGCHANNELS+1);
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static char data[length];
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static char data[length];
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while(1)
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while(1)
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@ -188,10 +188,10 @@ void Server::send()
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{
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{
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for(int k = 0; k < CHANNELS; k++)
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for(int k = 0; k < CHANNELS; k++)
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{
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{
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data[i*(WIDTH*CHANNELS+1) + j*CHANNELS + k] = frame.windows[i][j][k];
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data[HEADEROFFSET + i*(WIDTH*CHANNELS+1) + j*CHANNELS + k] = frame.windows[i][j][k];
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}
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}
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}
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}
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data[i*(WIDTH*CHANNELS+1) + (WIDTH*CHANNELS)] = '\n';
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data[HEADEROFFSET + i*(WIDTH*CHANNELS+1) + (WIDTH*CHANNELS)] = '\n';
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}
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}
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for(int i = 0; i < SEGWIDTH; i++)
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for(int i = 0; i < SEGWIDTH; i++)
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||||||
{
|
{
|
||||||
for(int k = 0; k < SEGCHANNELS; k++)
|
for(int k = 0; k < SEGCHANNELS; k++)
|
||||||
{
|
{
|
||||||
data[HEIGHT*(WIDTH*CHANNELS+1) +
|
data[HEADEROFFSET + HEIGHT*(WIDTH*CHANNELS+1) +
|
||||||
i*(SEGNUM*SEGCHANNELS+1) + j*SEGCHANNELS + k] = frame.segments[i][j][k];
|
i*(SEGNUM*SEGCHANNELS+1) + j*SEGCHANNELS + k] = frame.segments[i][j][k];
|
||||||
}
|
}
|
||||||
}
|
}
|
||||||
data[HEIGHT*(WIDTH*CHANNELS+1) +
|
data[HEADEROFFSET + HEIGHT*(WIDTH*CHANNELS+1) +
|
||||||
i*(SEGNUM*SEGCHANNELS+1) + (SEGNUM*SEGCHANNELS)] = '\n';
|
i*(SEGNUM*SEGCHANNELS+1) + (SEGNUM*SEGCHANNELS)] = '\n';
|
||||||
}
|
}
|
||||||
}
|
}
|
||||||
|
|
Loading…
Reference in New Issue