Hdaps ess
ess.py stands for Enhanced Smack Script.
It is an improved version of the smacks scripts you can find here.
Features:
- stabilization for both axis,
- you can disable an axis if needed,
- invert axis flag,
- almost everything tunable,
- different log levels for debug messages.
NEW: I made a video that you can download there: http://www.megaupload.com/fr/?d=SC4EYGDO
Or you can to watch it here: http://video.google.com/videoplay?docid=-8015556449081994308&hl=en
At best you should be able to map 8 commands, even if it is possible I was not able to do so.
Unfortunately it is not a copy and paste script, you have to tune some parameters and to add the commands you want to execute. Usually you only have to adjust the short term thresholds.
I am sure it is far to be exempt of any bug so do not hesitate to fix the wrong things.
The default thresholds should work on quiet environment.
I commented the dbus commands I used with KDE so you can activate them easily.
Good luck ;)
--Damajor 00:02, 18 September 2008 (CEST)
Code:
#!/usr/bin/env python import sys, re, time, math #import dbus import os # hdaps input file POS_FILE = '/sys/devices/platform/hdaps/position' # regex to gather hdaps values POS_RX = re.compile('^\((-?\d+),(-?\d+)\)$') # invert x and y axis (True or False) INVERT_AXIS = False # interval to pause between hdaps reads INTERVAL = 0.01 # length of the short term buffer (same value will be used for x and y buffers) ST_LENGTH = 20 # short term standard deviation threshold for x ST_X_STDDEV_THRESHOLD = 1 # short term standard deviation threshold for y ST_Y_STDDEV_THRESHOLD = 1 # short term threshold for x (0 to disable x axis knocks) ST_X_THRESHOLD = 2 # short term threshold for y (0 to disable y axis knocks) ST_Y_THRESHOLD = 2 # length of the long term buffer (same value will be used for x and y buffers) LT_LENGTH = 6 # long term standard deviation threshold for x LT_X_STDDEV_THRESHOLD = 2 # long term standard deviation threshold for y LT_Y_STDDEV_THRESHOLD = 2 # Debug (0 to 4) 0=no output DEBUG = 1 # END OF CONFIG SECTION # dbus init #bus = dbus.SessionBus() #kwin = bus.get_object('org.kde.kwin','/KWin') def switch_to_workspace_at_right(): os.system('/full/path/cdb.py wall next_key') # kwin.nextDesktop() def switch_to_workspace_at_left(): os.system('/full/path/cdb.py wall prev_key') # kwin.previousDesktop() def launch_x_left(): debug("X-Left",1) # switch_to_workspace_at_left() def launch_x_right(): debug("X-Right",1) # switch_to_workspace_at_right() def launch_y_front(): debug("Y-Front",1) def launch_y_back(): debug("Y-Back",1) def launch_x_left_y_front(): debug("X-Left Y-Front",1) # switch_to_workspace_at_left() def launch_x_left_y_back(): debug("X-Left Y-Back",1) # switch_to_workspace_at_left() def launch_x_right_y_front(): debug("X-Right Y-Front",1) # switch_to_workspace_at_right() def launch_x_right_y_back(): debug("X-Right Y-Back",1) # switch_to_workspace_at_right() def get_pos(): pos = open(POS_FILE).read() match = POS_RX.match(pos) return (int(match.group(1)), int(match.groups(2))) def loop(): st_x = [0] * ST_LENGTH st_y = [0] * ST_LENGTH st_x_idx = 0 st_y_idx = 0 lt_x = [0] * LT_LENGTH lt_y = [0] * LT_LENGTH lt_x_idx = 0 lt_y_idx = 0 lt_x_stable = False lt_y_stable = False while True: if INVERT_AXIS: y, x = get_pos() else: x, y = get_pos() st_x[st_x_idx] = x st_y[st_y_idx] = y if stddev(lt_x) < LT_X_STDDEV_THRESHOLD and stddev(lt_y) < LT_Y_STDDEV_THRESHOLD: if not lt_x_stable or not lt_y_stable: debug("Stable",1) lt_x_stable = True lt_y_stable = True # Split short term buffer into older and newer values old_x = [] old_y = [] new_x = [] new_y = [] for i in range(ST_LENGTH / 2): old_x.append(st_x[(st_x_idx + i + 1) % ST_LENGTH]) old_y.append(st_y[(st_y_idx + i + 1) % ST_LENGTH]) new_x.append(st_x[(st_x_idx + i + 1 + ST_LENGTH / 2) % ST_LENGTH]) new_y.append(st_y[(st_y_idx + i + 1 + ST_LENGTH / 2) % ST_LENGTH]) # Add some older stable data to new array, to make sure it's gone # back to the same stable state rather than a new one for i in range(ST_LENGTH / 2 + 1, ST_LENGTH): new_x.append(lt_x[(lt_x_idx + i) % LT_LENGTH]) new_y.append(lt_y[(lt_y_idx + i) % LT_LENGTH]) if (stddev(new_x) < ST_X_STDDEV_THRESHOLD) and (stddev(new_y) < ST_Y_STDDEV_THRESHOLD): st_x_mean = mean(st_x) st_y_mean = mean(st_y) debug("Max x: " + str(max(old_x)) + " > " + str(st_x_mean + ST_X_THRESHOLD) + \ " Min x: " + str(min(old_x)) + " < " + str(st_x_mean - ST_X_THRESHOLD) + \ " SD x: " + str(stddev(new_x)) + " < " + str(ST_X_STDDEV_THRESHOLD),4) debug("Max y: " + str(max(old_y)) + " < " + str(st_y_mean + ST_Y_THRESHOLD) + \ " Min y: " + str(min(old_y)) + " > " + str(st_y_mean - ST_Y_THRESHOLD) + \ " SD y: " + str(stddev(new_y)) + " < " + str(ST_Y_STDDEV_THRESHOLD),4) max_x_idx = -1 max_y_idx = -1 min_x_idx = -1 min_y_idx = -1 # Heartbeat for i in range(len(old_y)): if ST_X_THRESHOLD != 0: if old_x[i] > st_x_mean + ST_X_THRESHOLD: max_x_idx = i; if old_x[i] < st_x_mean - ST_X_THRESHOLD: min_x_idx = i; if ST_Y_THRESHOLD != 0: if old_y[i] > st_y_mean + ST_Y_THRESHOLD: max_y_idx = i; if old_y[i] < st_y_mean - ST_Y_THRESHOLD: min_y_idx = i; # Check knock directions and launch associated commands if max_x_idx != -1 and min_x_idx != -1 or max_y_idx != -1 and min_y_idx != -1: if max_x_idx == min_x_idx and max_y_idx >= min_y_idx: debug("Smack! X-Disabled or stable x=" + str(old_x[max_x_idx]) + "/" + str(old_x[min_x_idx]) + \ " Y-Front y=" + str(old_y[max_y_idx]) + "/" + str(old_y[min_y_idx]),2) launch_y_front() if max_x_idx == min_x_idx and max_y_idx <= min_y_idx: debug("Smack! X-Disabled or stable x=" + str(old_x[max_x_idx]) + "/" + str(old_x[min_x_idx]) + \ " Y-Back y=" + str(old_y[max_y_idx]) + "/" + str(old_y[min_y_idx]),2) launch_y_back() if max_x_idx >= min_x_idx and max_y_idx == min_y_idx: debug("Smack! X-Right x=" + str(old_x[max_x_idx]) + "/" + str(old_x[min_x_idx]) + \ " Y-Disabled or stable y=" + str(old_y[max_y_idx]) + "/" + str(old_y[min_y_idx]),2) launch_x_right() if max_x_idx < min_x_idx and max_y_idx == min_y_idx: debug("Smack! X-Left x=" + str(old_x[max_x_idx]) + "/" + str(old_x[min_x_idx]) + \ " Y-Disabled or stable y=" + str(old_y[max_y_idx]) + "/" + str(old_y[min_y_idx]),2) launch_x_left() if max_x_idx > min_x_idx and max_y_idx > min_y_idx: debug("Smack! X-Right x=" + str(old_x[max_x_idx]) + "/" + str(old_x[min_x_idx]) + \ " Y-Front y=" + str(old_y[max_y_idx]) + "/" + str(old_y[min_y_idx]),2) launch_x_right_y_front() if max_x_idx < min_x_idx and max_y_idx < min_y_idx: debug("Smack! X-Left x=" + str(old_x[max_x_idx]) + "/" + str(old_x[min_x_idx]) + \ " Y-Back y=" + str(old_y[max_y_idx]) + "/" + str(old_y[min_y_idx]),2) launch_x_left_y_back() if max_x_idx < min_x_idx and max_y_idx > min_y_idx: debug("Smack! X-Left x=" + str(old_x[max_x_idx]) + "/" + str(old_x[min_x_idx]) + \ " Y-Front y=" + str(old_y[max_y_idx]) + "/" + str(old_y[min_y_idx]),2) launch_x_left_y_front() if max_x_idx > min_x_idx and max_y_idx < min_y_idx: debug("Smack! X-Right x=" + str(old_x[max_x_idx]) + "/" + str(old_x[min_x_idx]) + \ " Y-Back y=" + str(old_y[max_y_idx]) + "/" + str(old_y[min_y_idx]),2) launch_x_right_y_back() # No further smacks for a while; bias long-term stddev #lt_x[(lt_x_idx + LT_LENGTH - 1) % LT_LENGTH] = 10000000; lt_y[(lt_y_idx + LT_LENGTH - 1) % LT_LENGTH] = 10000000; else: if lt_x_stable or lt_y_stable: debug("Unstable",1) lt_x_stable = False lt_y_stable = False st_x_idx += 1 st_x_idx %= ST_LENGTH st_y_idx += 1 st_y_idx %= ST_LENGTH if st_x_idx == 0: lt_x[lt_x_idx] = st_x[st_x_idx] lt_x_idx += 1 lt_x_idx %= LT_LENGTH debug("X Stability stddev: " + str(stddev(lt_x)),3) if st_y_idx == 0: lt_y[lt_y_idx] = st_y[st_y_idx] lt_y_idx += 1 lt_y_idx %= LT_LENGTH debug("Y Stability stddev: " + str(stddev(lt_y)),3) time.sleep(INTERVAL) def debug(param, level): # show the message depending on the DEBUG level if level <= DEBUG: print param def mean(values): # average of the values return sum(values) / float(len(values)) def stddev(values): # standard deviation of the values meanval = mean(values) return math.sqrt(sum((x - meanval)**2 for x in values) / (len(values)-1)) def main(): try: loop() except KeyboardInterrupt: pass if __name__ == '__main__': main()