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# -*- python -*-
'''
xpybar – xmobar replacement written in python
Copyright © 2014, 2015, 2016, 2017, 2018, 2019  Mattias Andrée (m@maandreese)

This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.

This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
GNU General Public License for more details.

You should have received a copy of the GNU General Public License
along with this program.  If not, see <http://www.gnu.org/licenses/>.
'''

# A moderate xpybar configuration example that has a few monitors
# that are updates continuously, and rat support

import time
import threading

from util import *

from plugins.clock   import Clock
from plugins.cpu     import CPU
from plugins.mem     import Memory
from plugins.network import Network
from plugins.ping    import Ping
from plugins.alsa    import ALSA
from plugins.moc     import MOC

import Xlib.protocol.event



OUTPUT = 0
'''
:int  The index of the monitor that the panel is displayed on
'''

YPOS = 24
'''
:int  The panels position relative to the upper or lower edge
      of the monitor (which is determined by `TOP`)
'''

TOP = True
'''
:bool  True:  `YPOS` is relative to the upper edge
       False: `YPOS` is relative to the lower edge
'''



TICKS_PER_SECOND = 4
'''
:float  The number of times per second the panel is updated
'''


time_format = '%Y-(%m)%b-%d %T, %a w%V, %Z'
'''
:str  The format the clock is displayed in
'''

my_clock = Clock(format = time_format, utc = False,
                 sync_to = Clock.SECONDS / TICKS_PER_SECOND)
'''
:Clock  The clock monitor
'''

my_cpu = '...'
'''
:str  The output of the CPU monitor
'''

my_mem = '...'
'''
:str  The output of the RAM monitor
'''

my_swp = '...'
'''
:str  The output of the swap memory monitor
'''

my_shm = '...'
'''
:str  The output of the shared memory monitor
'''

my_net = 'Net: ...'
'''
:str  The output of the network monitor
'''

my_snd = '...'
'''
:str  The output of the audio monitor
'''

my_moc = '...'
'''
:str  The output of the music on console monitor
'''



limited = lambda v : min(max(int(v + 0.5), 0), 100)
'''
:(float)→int  Round an float to nearest integer and limit the range to [0, 100]
'''


len_ = len
len = lambda string : colour_aware_len(string, len_)



###############################################################################################################


###############################################################################################################
# CPU monitor


def cpu():
    '''
    Update CPU usage
    '''
    global my_cpu, last_cpus_idle, last_cpus_total, last_cpu_idle, last_cpu_total
    try:
        cpu_ = CPU()
        now_cpu_idle, now_cpus_idle = cpu_.cpu[CPU.idle], [cpu[CPU.idle] for cpu in cpu_.cpus]
        now_cpu_total, now_cpus_total = sum(cpu_.cpu), [sum(cpu) for cpu in cpu_.cpus]
        if len(now_cpus_idle) > len(last_cpus_idle):
            last_cpus_idle += now_cpus_idle[len(last_cpus_idle):]
            last_cpus_total += now_cpus_total[len(last_cpus_total):]
        cpus = zip(now_cpus_idle, now_cpus_total, last_cpus_idle, last_cpus_total)
        cpus = ' '.join([cpu_colourise(cpu_usage(*c)) for c in cpus])
        cpu_ = cpu_colourise(cpu_usage(now_cpu_idle, now_cpu_total, last_cpu_idle, last_cpu_total))
        cpu_ = '%s : %s' % (cpus, cpu_)
        last_cpus_idle, last_cpus_total = now_cpus_idle, now_cpus_total
        last_cpu_idle, last_cpu_total = now_cpu_idle, now_cpu_total
        my_cpu = cpu_
    except:
        my_cpu = '...'

def cpu_usage(now_idle, now_total, last_idle, last_total):
    '''
    Calculate the CPU usage
    
    @param   now_idle:int    Time spent in the idle task, at the current measurement
    @param   now_total:int   Total time that has passed, at the current measurement
    @param   last_idle:int   Time spent in the idle task, at the last measurement
    @param   last_total:int  Total time that has passed, at the last measurement
    @return  :float?         The CPU usage, `None` if not time has passed
    '''
    total = now_total - last_total
    idle = now_idle - last_idle
    return None if total == 0 else (total - idle) * 100 / total

def cpu_colourise_(value):
    '''
    Colourise a CPU usage value
    
    @param   value:int  The CPU usage
    @return  :str       `value` coloured with an appropriate colour
    '''
    if value is None:
        return '--%'
    elif value >= 100:
        return '\033[31m100\033[0m'
    colour = '39'
    if value >= 5:   colour = '32'
    if value >= 50:  colour = '33'
    if value >= 90:  colour = '31'
    return '\033[%sm%2i\033[0m%%' % (colour, value)

cpu_none = cpu_colourise_(None)
'''
:str  Cache for the coloursation of the value `None`
'''

cpu_coloured = tuple(cpu_colourise_(i) for i in range(101))
'''
:tuple<str>  Cache of colourised CPU usage values
'''

cpu_colourise = lambda v : cpu_none if v is None else cpu_coloured[limited(v)]
'''
:(value:int)→str  Cached version of `cpu_colourise_`
'''

last_cpu_idle = 0
'''
:int  Time spent in the idle task, at the last measurement, on all CPU-threads
'''

last_cpu_total = 0
'''
:int  Total time that has passed, at the last measurement, on all CPU-threads
'''

last_cpus_idle = []
'''
:int  Time spent in the idle task, at the last measurement, for each CPU-thread
'''

last_cpus_total = []
'''
:int  Total time that has passed, at the last measurement, for each CPU-thread
'''



###############################################################################################################
# Memory usage monitor


def mem():
    '''
    Update memory usage
    '''
    global my_mem, my_swp, my_shm
    try:
        memory = Memory()
        if memory.mem_total == 0:
            my_mem = '---'
            my_shm = '---'
        else:
            my_mem = memory_coloured[limited(memory.mem_used * 100 / memory.mem_total)]
            my_shm = memory_coloured[limited(memory.shmem * 100 / memory.mem_total)]
        if memory.swap_total == 0:
            my_swp = 'off'
        else:
            my_swp = memory_coloured[limited(memory.swap_used * 100 / memory.swap_total)]
    except:
        my_mem = '...'
        my_swp = '...'
        my_shm = '...'

def memory_colourise(value):
    '''
    Colourise a memory usage value
    
    @param   value:int  The memory usage
    @return  :str       `value` coloured with an appropriate colour
    '''
    if value >= 100:
        return '\033[31m100\033[0m'
    colour = '39'
    if value > 30:  colour = '32'
    if value > 50:  colour = '33'
    if value > 80:  colour = '31'
    return '\033[%sm%i\033[0m%%' % (colour, value)

memory_coloured = tuple(memory_colourise(i) for i in range(101))
'''
:tuple<str>  Cache of colourised memory usage values
'''



###############################################################################################################
# Network monitor


def net():
    '''
    Update network usage and latency
    '''
    global my_net, net_time, net_last
    try:
        net_now = time.monotonic()
        net_tdiff, net_time = net_now - net_time, net_now
        devs = Network('lo').devices
        def kbps(device, direction):
            '''
            Get the number of kilobits transmitted or received per second since the last measurement
            
            @param   device:str     The network device
            @param   direction:str  'rx' for received data, 'tx' for transmitted data
            @return  :str           The number of kilobits transmitted or received per second, colourised
            '''
            direction += '_bytes'
            value = devs[device][direction]
            if device in net_last:
                value -= net_last[device][direction]
            else:
                value = 0
            value /= 128 * net_tdiff
            return network_colourise(value)
        def KBps(device, direction):
            '''
            Get the number of kilobytes transmitted or received per second since the last measurement
            
            @param   device:str     The network device
            @param   direction:str  'rx' for received data, 'tx' for transmitted data
            @return  :float         The number of kilobytes transmitted or received per second
            '''
            direction += '_bytes'
            value = devs[device][direction]
            if device in net_last:
                value -= net_last[device][direction]
            else:
                value = 0
            value /= 1024 * net_tdiff
            return value
        my_net = ' '.join('%s: %skbps(%.0fKB/s)↓ %skbps(%.0fKB/s)↑ %s' %
                          (dev, kbps(dev, 'rx'), KBps(dev, 'rx'), kbps(dev, 'tx'), KBps(dev, 'tx'), ping(dev))
                          for dev in devs)
        net_last = devs
    except:
        my_net = 'Net: ...'

def network_colourise(value):
    '''
    Colourise a network usage value
    
    @param   value:int  The network usage, in kilobits per second
    @return  :str       `value` coloured with an appropriate colour
    '''
    colour = '39'
    if value > 40:     colour = '32'
    if value > 8000:   colour = '33'
    if value > 60000:  colour = '31'
    return '\033[%sm%3.0f\033[0m' % (colour, value)

def ping(device):
    '''
    Get the latency for a network device
    
    @param   device:str  The device
    @return  :str        The latency, colourised
    '''
    try:
        monitor = my_ping[device][0]
        monitor.semaphore.acquire()
        try:
            latency = monitor.get_latency(True)[1]
            droptime = monitor.dropped_time(True)
            if droptime:
                return '\033[31m%4is\033[00m' % droptime
            elif latency is None:
                return '\033[31mdrop?\033[00m'
            colour = '31'
            if   latency <  5:  colour = '32'
            elif latency < 10:  colour = '00'
            elif latency < 20:  colour = '33'
            return '\033[%sm%5.2f\033[00m' % (colour, latency)
        finally:
            monitor.semaphore.release()
    except:
        return '...'

my_ping = Ping(targets = Ping.get_nics(), interval = 10).monitors
'''
:Ping  Latency monitor
'''

net_time = time.monotonic()
'''
:float  The time of the last reading
'''

net_last = {}
'''
:dict<str, dict<str, int>>  Readings from the update
'''



###############################################################################################################
# Audio monitor


def snd(add_missing_mixers = True):
    '''
    Update audio volume
    
    @param  add_missing_mixers:bool  Whether missing mixers should be added
    '''
    global my_snd, stops_alsa
    stops_ = []
    if add_missing_mixers:
        try:
            for i, mixer in my_alsa:
                if mixer is None:
                    my_alsa[i] = alsa(*(mixers[i]))
        except:
            pass
    try:
        offset = 0
        my_snd_ = []
        for mixer in my_alsa:
            if mixer is not None:
                text = snd_read_m(mixer)
                my_snd_.append(text)
                text_len = len(text)
                mixer_stops = [0, text_len]
                mixer_name_len, text = len(text.split(': ')[0]), ': '.join(text.split(': ')[1:])
                for i in range((len(text) + 1) // 4):
                    mixer_stops.append(mixer_name_len + 2 + 4 * i + 0)
                    mixer_stops.append(mixer_name_len + 2 + 4 * i + 3)
                stops_.append(tuple(offset + stop for stop in mixer_stops))
                offset += text_len + 3
            else:
                stops_.append((-1, -1))
        my_snd = ' │ '.join(my_snd_)
        stops_alsa = stops_
    except:
        my_snd = '...'
        stops_alsa = [(-1, -1)] * len(my_alsa)

def alsa(cardindex, mixername):
    '''
    The a volume controller for a mixer
    
    @param   cardindex:int  The index of the audio card
    @param   mixername:str  The name of the mixer
    @return  :Alsa?         Volume controller, `None` if the mixers is not available
    '''
    try:
        return ALSA(cardindex, mixername)
    except:
        return None

snd_text_v = lambda v : '--%' if v is None else ('%2i%%' % v)[:3]
'''
:(v:int?)→str  Convert a volume integer to a volume str, `None` as input means it is muted
'''

snd_read_m = lambda m : '%s: %s' % (m.mixername, ' '.join(snd_text_v(v) for v in m.get_volume()))
'''
:(m:ALSA)→str  Create a string representing the current volumes on a mixer
'''

mixers = ((0, 'Master'), (0, 'Headphone'), (0, 'Speaker'), (0, 'PCM'))
'''
:tuple<(cardindex:int, mixername:str)>  List of mixers that should be monitored
'''

my_alsa = [alsa(card, mixer) for card, mixer in mixers]
'''
:list<ALSA>  ALSA volume controllers
'''

stops_alsa = [(-1, -1)] * len(my_alsa)
'''
:itr<itr<int>>  Map from mixer index to location of substring in the monitor display.
                The first element is where the mixer starts, and the second element is
                where the mixer stops. Each mixer may have 2 additional elements for each
                channel, in that case that are starts and stops, alternating.
'''



###############################################################################################################
# Music on console monitor


my_moc = '> || [] |< >|'

moc_controller = MOC()
'''
:MOC  The MOC controller
'''



###############################################################################################################


###############################################################################################################



functions = [ my_clock.read
            , lambda : my_cpu
            , lambda : my_mem
            , lambda : my_swp
            , lambda : my_shm
            
            , lambda : my_net
            , lambda : my_snd
            , lambda : my_moc
            ]
'''
:itr<()→str>  Functions that are evulated and replaces the %s:s in
              `pattern` every time to panel is redrawn
'''

pattern = [ [ '%n%s%n │ %nCpu: %s%n │ %nMem: %s%n │ %nSwp: %s%n │ %nShm: %s%n'
            , '%n%s%n │ %n%s%n │ %nMoc: %s%n'
            ]
          ]
'''
:itr<itr<str>>  The layout of the monitors on the panel
'''


async_fun = [ Sometimes(cpu, TICKS_PER_SECOND)
            , Sometimes(mem, TICKS_PER_SECOND)
            , Sometimes(net, TICKS_PER_SECOND)
            , Sometimes(snd, TICKS_PER_SECOND * 3)
            ]
'''
:itr<()→void>  Monitors that are be update asynchronously
'''

semaphore = threading.Semaphore()
'''
:Semaphore  Semaphore used to make sure functions do not step on each others' toes
'''


HEIGHT_PER_LINE = 12
'''
:int  The height of each line
'''


HEIGHT = len(pattern) * HEIGHT_PER_LINE
'''
:int  The height of the panel
'''


stops = [-1] * (2 * len(functions))
'''
:itr<int>  Locations of stops marked by `%n` in `pattern`
'''



pattern = '\n'.join('\0'.join(p) for p in pattern)



start_ = start
def start():
    '''
    Invoked when it is time to create panels and map them
    '''
    # Create panel, clear it, and synchronise
    start_()
    bar.clear()
    get_display().flush()
    
    def update_sys():
        '''
        Update data asynchronously, but do not redraw the panel
        '''
        [f() for f in async_fun]
    
    def update_clock():
        '''
        Update the clock, and redraw the panel
        '''
        if semaphore.acquire(blocking = False):
            try:
                for f in functions:
                    if isinstance(f, Clocked):
                        f(True)
            finally:
                semaphore.release()
            bar.invalidate()
    
    # Start monitoring
    xasync(lambda : watch(1 / TICKS_PER_SECOND, update_sys), name = 'sys')
    xasync(lambda : my_clock.continuous_sync(update_clock), name = 'clock')



def redraw():
    '''
    Invoked when redraw is needed
    '''
    global stops
    if semaphore.acquire(blocking = False):
        try:
            (values, stops) = sprintf(pattern, *(f() for f in functions))
            bar.partial_clear(0, bar.width, 10, 0, 2, values)
            bar.draw_coloured_splitted_text(0, bar.width, 10, 0, 2, values)
        finally:
            semaphore.release()



LEFT_BUTTON = 1
'''
:int  The index of the left button
'''

MIDDLE_BUTTON = 2
'''
:int  The index of the middle button
'''

RIGHT_BUTTON = 3
'''
:int  The index of the right button
'''

SCROLL_UP = 4
'''
:int  The index of the psuedo-button for scrolling upwards
'''

SCROLL_DOWN = 5
'''
:int  The index of the psuedo-button for scrolling downwards
'''

SCROLL_LEFT = 6
'''
:int  The index of the psuedo-button for scrolling left
'''

SCROLL_RIGHT = 7
'''
:int  The index of the psuedo-button for scrolling right
'''

FORWARD_BUTTON = 8 # X1
'''
:int  The index of the forward button, also known as X1
'''

BACKWARD_BUTTON = 9 # X2
'''
:int  The index of the backward button, also known as X2
'''


def unhandled_event(e):
    '''
    Invoked when an unrecognised even is polled,
    feel free to replace this completely
    
    @param  e  The event
    '''
    if isinstance(e, Xlib.protocol.event.ButtonPress):
        y = e.event_y // HEIGHT_PER_LINE
        lx = e.event_x // bar.font_width
        rx = (bar.width - e.event_x) // bar.font_width
        button = e.detail
        button_pressed(y, lx, rx, button)


def button_pressed(y, lx, rx, button):
    '''
    Called from `unhandled_event` when a button on a pointer device is pressed
    
    @param  y:int       The line that the pointer is on, zero based
    @param  lx:int      The column the pointer is on, relative to the left edge, zero based
    @param  rx:int      The column the pointer is on, relative to the right edge, zero based
    @param  button:int  The button on the device that is pressed
    '''
    # Stops at the left side of line 0
    stops_l0 = stops[0 : 10]
    
    # Stops at the right side of line 0
    stops_r0 = [stops[15] - x for x in stops[10 : 16]]
    
    try:
        if y == 0:
            if stops_l0[0] <= lx < stops_l0[1]: # clock
                if button == LEFT_BUTTON:
                    Clock.__init__(my_clock, time_format, not my_clock.utc, my_clock.sync_to)
                    bar.invalidate()
            elif stops_l0[2] <= lx < stops_l0[3]: # cpu
                pass
            elif stops_l0[4] <= lx < stops_l0[5]: # mem
                pass
            elif stops_l0[6] <= lx < stops_l0[7]: # swp
                pass
            elif stops_l0[8] <= lx < stops_l0[9]: # shm
                pass
            elif stops_r0[0] > rx >= stops_r0[1]: # net
                pass
            elif stops_r0[2] > rx >= stops_r0[3]: # snd
                button_pressed_mixer(stops_r0[2] - rx - 1, button)
            elif stops_r0[4] > rx >= stops_r0[5]: # moc
                mx = stops_r0[4] - rx - 1 - 5
                if button == LEFT_BUTTON:
                    if    0 <= mx <  1:          xasync(lambda : moc_controller.play().wait())         # >
                    elif  2 <= mx <  4:          xasync(lambda : moc_controller.toggle_pause().wait()) # ||
                    elif  5 <= mx <  7:          xasync(lambda : moc_controller.stop().wait())         # []
                    elif  8 <= mx < 10:          xasync(lambda : moc_controller.previous().wait())     # |<
                    elif 11 <= mx < 13:          xasync(lambda : moc_controller.next().wait())         # >|
                elif button == FORWARD_BUTTON:   xasync(lambda : moc_controller.next().wait())
                elif button == BACKWARD_BUTTON:  xasync(lambda : moc_controller.previous().wait())
                elif button == SCROLL_UP:        xasync(lambda : moc_controller.seek(+5).wait())
                elif button == SCROLL_DOWN:      xasync(lambda : moc_controller.seek(-5).wait())
    except:
        pass


def button_pressed_mixer(mx, button):
    '''
    Called from `button_pressed` when the user is touched the audio mixer monitor
    
    @param  mx:int      The column the pointer is at right-relative to the left edge of the mixer display
    @param  button:int  The button on the device that is pressed
    '''
    for mixer_index, mixer_stops in enumerate(stops_alsa):
        if mixer_stops[0] <= mx < mixer_stops[1]:
            # Get channel
            channel = ALSA.ALL_CHANNELS
            if not button == RIGHT_BUTTON: # not (balance channels)
                mixer_stops = mixer_stops[2:]
                for channel_index in range(len(mixer_stops) // 2):
                    if mixer_stops[channel_index * 2 + 0] <= mx < mixer_stops[channel_index * 2 + 1]:
                        channel = channel_index
                        break
            # Get mixer
            mixer = my_alsa[mixer_index]
            # Get volumes and all selected channels
            volumes = mixer.get_volume()
            channels = list(range(len(volumes))) if channel == ALSA.ALL_CHANNELS else [channel]
            # Filter volumes to selected channels
            volumes = [volume for c, volume in enumerate(volumes) if c in channels]
            
            # Control the volume
            if button == LEFT_BUTTON: # toggle mute
                mute = not any(volume is None for volume in volumes)
                [mixer.set_mute(mute, c) for c in channels]
            elif button == RIGHT_BUTTON: # balance channels
                mixer.set_volume(sum(volumes) // len(volumes), ALSA.ALL_CHANNELS)
            elif button == SCROLL_UP: # turn up the volume
                [mixer.set_volume(limited(v + 5), c) for c, v in zip(channels, volumes)]
            elif button == SCROLL_DOWN: # turn down the volume
                [mixer.set_volume(limited(v - 5), c) for c, v in zip(channels, volumes)]
            
            # Update the panel
            snd(False)
            bar.invalidate()
            break