generic-poky/scripts/lib/mic/3rdparty/pykickstart/urlgrabber/progress.py

#   This library is free software; you can redistribute it and/or
#   modify it under the terms of the GNU Lesser General Public
#   License as published by the Free Software Foundation; either
#   version 2.1 of the License, or (at your option) any later version.
#
#   This library 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
#   Lesser General Public License for more details.
#
#   You should have received a copy of the GNU Lesser General Public
#   License along with this library; if not, write to the 
#      Free Software Foundation, Inc., 
#      59 Temple Place, Suite 330, 
#      Boston, MA  02111-1307  USA

# This file is part of urlgrabber, a high-level cross-protocol url-grabber
# Copyright 2002-2004 Michael D. Stenner, Ryan Tomayko

# $Id: progress.py,v 1.7 2005/08/19 21:59:07 mstenner Exp $

import sys
import time
import math
import thread
    
class BaseMeter:
    def __init__(self):
        self.update_period = 0.3 # seconds

        self.filename   = None
        self.url        = None
        self.basename   = None
        self.text       = None
        self.size       = None
        self.start_time = None
        self.last_amount_read = 0
        self.last_update_time = None
        self.re = RateEstimator()
        
    def start(self, filename=None, url=None, basename=None,
              size=None, now=None, text=None):
        self.filename = filename
        self.url      = url
        self.basename = basename
        self.text     = text

        #size = None #########  TESTING
        self.size = size
        if not size is None: self.fsize = format_number(size) + 'B'

        if now is None: now = time.time()
        self.start_time = now
        self.re.start(size, now)
        self.last_amount_read = 0
        self.last_update_time = now
        self._do_start(now)
        
    def _do_start(self, now=None):
        pass

    def update(self, amount_read, now=None):
        # for a real gui, you probably want to override and put a call
        # to your mainloop iteration function here
        if now is None: now = time.time()
        if (now >= self.last_update_time + self.update_period) or \
               not self.last_update_time:
            self.re.update(amount_read, now)
            self.last_amount_read = amount_read
            self.last_update_time = now
            self._do_update(amount_read, now)

    def _do_update(self, amount_read, now=None):
        pass

    def end(self, amount_read, now=None):
        if now is None: now = time.time()
        self.re.update(amount_read, now)
        self.last_amount_read = amount_read
        self.last_update_time = now
        self._do_end(amount_read, now)

    def _do_end(self, amount_read, now=None):
        pass
        
class TextMeter(BaseMeter):
    def __init__(self, fo=sys.stderr):
        BaseMeter.__init__(self)
        self.fo = fo

    def _do_update(self, amount_read, now=None):
        etime = self.re.elapsed_time()
        fetime = format_time(etime)
        fread = format_number(amount_read)
        #self.size = None
        if self.text is not None:
            text = self.text
        else:
            text = self.basename
        if self.size is None:
            out = '\r%-60.60s    %5sB %s ' % \
                  (text, fread, fetime)
        else:
            rtime = self.re.remaining_time()
            frtime = format_time(rtime)
            frac = self.re.fraction_read()
            bar = '='*int(25 * frac)

            out = '\r%-25.25s %3i%% |%-25.25s| %5sB %8s ETA ' % \
                  (text, frac*100, bar, fread, frtime)

        self.fo.write(out)
        self.fo.flush()

    def _do_end(self, amount_read, now=None):
        total_time = format_time(self.re.elapsed_time())
        total_size = format_number(amount_read)
        if self.text is not None:
            text = self.text
        else:
            text = self.basename
        if self.size is None:
            out = '\r%-60.60s    %5sB %s ' % \
                  (text, total_size, total_time)
        else:
            bar = '='*25
            out = '\r%-25.25s %3i%% |%-25.25s| %5sB %8s     ' % \
                  (text, 100, bar, total_size, total_time)
        self.fo.write(out + '\n')
        self.fo.flush()

text_progress_meter = TextMeter

class MultiFileHelper(BaseMeter):
    def __init__(self, master):
        BaseMeter.__init__(self)
        self.master = master

    def _do_start(self, now):
        self.master.start_meter(self, now)

    def _do_update(self, amount_read, now):
        # elapsed time since last update
        self.master.update_meter(self, now)

    def _do_end(self, amount_read, now):
        self.ftotal_time = format_time(now - self.start_time)
        self.ftotal_size = format_number(self.last_amount_read)
        self.master.end_meter(self, now)

    def failure(self, message, now=None):
        self.master.failure_meter(self, message, now)

    def message(self, message):
        self.master.message_meter(self, message)

class MultiFileMeter:
    helperclass = MultiFileHelper
    def __init__(self):
        self.meters = []
        self.in_progress_meters = []
        self._lock = thread.allocate_lock()
        self.update_period = 0.3 # seconds
        
        self.numfiles         = None
        self.finished_files   = 0
        self.failed_files     = 0
        self.open_files       = 0
        self.total_size       = None
        self.failed_size      = 0
        self.start_time       = None
        self.finished_file_size = 0
        self.last_update_time = None
        self.re = RateEstimator()

    def start(self, numfiles=None, total_size=None, now=None):
        if now is None: now = time.time()
        self.numfiles         = numfiles
        self.finished_files   = 0
        self.failed_files     = 0
        self.open_files       = 0
        self.total_size       = total_size
        self.failed_size      = 0
        self.start_time       = now
        self.finished_file_size = 0
        self.last_update_time = now
        self.re.start(total_size, now)
        self._do_start(now)

    def _do_start(self, now):
        pass

    def end(self, now=None):
        if now is None: now = time.time()
        self._do_end(now)
        
    def _do_end(self, now):
        pass

    def lock(self): self._lock.acquire()
    def unlock(self): self._lock.release()

    ###########################################################
    # child meter creation and destruction
    def newMeter(self):
        newmeter = self.helperclass(self)
        self.meters.append(newmeter)
        return newmeter
    
    def removeMeter(self, meter):
        self.meters.remove(meter)
        
    ###########################################################
    # child functions - these should only be called by helpers
    def start_meter(self, meter, now):
        if not meter in self.meters:
            raise ValueError('attempt to use orphaned meter')
        self._lock.acquire()
        try:
            if not meter in self.in_progress_meters:
                self.in_progress_meters.append(meter)
                self.open_files += 1
        finally:
            self._lock.release()
        self._do_start_meter(meter, now)
        
    def _do_start_meter(self, meter, now):
        pass
        
    def update_meter(self, meter, now):
        if not meter in self.meters:
            raise ValueError('attempt to use orphaned meter')
        if (now >= self.last_update_time + self.update_period) or \
               not self.last_update_time:
            self.re.update(self._amount_read(), now)
            self.last_update_time = now
            self._do_update_meter(meter, now)

    def _do_update_meter(self, meter, now):
        pass

    def end_meter(self, meter, now):
        if not meter in self.meters:
            raise ValueError('attempt to use orphaned meter')
        self._lock.acquire()
        try:
            try: self.in_progress_meters.remove(meter)
            except ValueError: pass
            self.open_files     -= 1
            self.finished_files += 1
            self.finished_file_size += meter.last_amount_read
        finally:
            self._lock.release()
        self._do_end_meter(meter, now)

    def _do_end_meter(self, meter, now):
        pass

    def failure_meter(self, meter, message, now):
        if not meter in self.meters:
            raise ValueError('attempt to use orphaned meter')
        self._lock.acquire()
        try:
            try: self.in_progress_meters.remove(meter)
            except ValueError: pass
            self.open_files     -= 1
            self.failed_files   += 1
            if meter.size and self.failed_size is not None:
                self.failed_size += meter.size
            else:
                self.failed_size = None
        finally:
            self._lock.release()
        self._do_failure_meter(meter, message, now)

    def _do_failure_meter(self, meter, message, now):
        pass

    def message_meter(self, meter, message):
        pass

    ########################################################
    # internal functions
    def _amount_read(self):
        tot = self.finished_file_size
        for m in self.in_progress_meters:
            tot += m.last_amount_read
        return tot


class TextMultiFileMeter(MultiFileMeter):
    def __init__(self, fo=sys.stderr):
        self.fo = fo
        MultiFileMeter.__init__(self)

    # files: ###/### ###%  data: ######/###### ###%  time: ##:##:##/##:##:##
    def _do_update_meter(self, meter, now):
        self._lock.acquire()
        try:
            format = "files: %3i/%-3i %3i%%   data: %6.6s/%-6.6s %3i%%   " \
                     "time: %8.8s/%8.8s"
            df = self.finished_files
            tf = self.numfiles or 1
            pf = 100 * float(df)/tf + 0.49
            dd = self.re.last_amount_read
            td = self.total_size
            pd = 100 * (self.re.fraction_read() or 0) + 0.49
            dt = self.re.elapsed_time()
            rt = self.re.remaining_time()
            if rt is None: tt = None
            else: tt = dt + rt

            fdd = format_number(dd) + 'B'
            ftd = format_number(td) + 'B'
            fdt = format_time(dt, 1)
            ftt = format_time(tt, 1)
            
            out = '%-79.79s' % (format % (df, tf, pf, fdd, ftd, pd, fdt, ftt))
            self.fo.write('\r' + out)
            self.fo.flush()
        finally:
            self._lock.release()

    def _do_end_meter(self, meter, now):
        self._lock.acquire()
        try:
            format = "%-30.30s %6.6s    %8.8s    %9.9s"
            fn = meter.basename
            size = meter.last_amount_read
            fsize = format_number(size) + 'B'
            et = meter.re.elapsed_time()
            fet = format_time(et, 1)
            frate = format_number(size / et) + 'B/s'
            
            out = '%-79.79s' % (format % (fn, fsize, fet, frate))
            self.fo.write('\r' + out + '\n')
        finally:
            self._lock.release()
        self._do_update_meter(meter, now)

    def _do_failure_meter(self, meter, message, now):
        self._lock.acquire()
        try:
            format = "%-30.30s %6.6s %s"
            fn = meter.basename
            if type(message) in (type(''), type(u'')):
                message = message.splitlines()
            if not message: message = ['']
            out = '%-79s' % (format % (fn, 'FAILED', message[0] or ''))
            self.fo.write('\r' + out + '\n')
            for m in message[1:]: self.fo.write('  ' + m + '\n')
            self._lock.release()
        finally:
            self._do_update_meter(meter, now)

    def message_meter(self, meter, message):
        self._lock.acquire()
        try:
            pass
        finally:
            self._lock.release()

    def _do_end(self, now):
        self._do_update_meter(None, now)
        self._lock.acquire()
        try:
            self.fo.write('\n')
            self.fo.flush()
        finally:
            self._lock.release()
        
######################################################################
# support classes and functions

class RateEstimator:
    def __init__(self, timescale=5.0):
        self.timescale = timescale

    def start(self, total=None, now=None):
        if now is None: now = time.time()
        self.total = total
        self.start_time = now
        self.last_update_time = now
        self.last_amount_read = 0
        self.ave_rate = None
        
    def update(self, amount_read, now=None):
        if now is None: now = time.time()
        if amount_read == 0:
            # if we just started this file, all bets are off
            self.last_update_time = now
            self.last_amount_read = 0
            self.ave_rate = None
            return

        #print 'times', now, self.last_update_time
        time_diff = now         - self.last_update_time
        read_diff = amount_read - self.last_amount_read
        self.last_update_time = now
        self.last_amount_read = amount_read
        self.ave_rate = self._temporal_rolling_ave(\
            time_diff, read_diff, self.ave_rate, self.timescale)
        #print 'results', time_diff, read_diff, self.ave_rate
        
    #####################################################################
    # result methods
    def average_rate(self):
        "get the average transfer rate (in bytes/second)"
        return self.ave_rate

    def elapsed_time(self):
        "the time between the start of the transfer and the most recent update"
        return self.last_update_time - self.start_time

    def remaining_time(self):
        "estimated time remaining"
        if not self.ave_rate or not self.total: return None
        return (self.total - self.last_amount_read) / self.ave_rate

    def fraction_read(self):
        """the fraction of the data that has been read
        (can be None for unknown transfer size)"""
        if self.total is None: return None
        elif self.total == 0: return 1.0
        else: return float(self.last_amount_read)/self.total

    #########################################################################
    # support methods
    def _temporal_rolling_ave(self, time_diff, read_diff, last_ave, timescale):
        """a temporal rolling average performs smooth averaging even when
        updates come at irregular intervals.  This is performed by scaling
        the "epsilon" according to the time since the last update.
        Specifically, epsilon = time_diff / timescale

        As a general rule, the average will take on a completely new value
        after 'timescale' seconds."""
        epsilon = time_diff / timescale
        if epsilon > 1: epsilon = 1.0
        return self._rolling_ave(time_diff, read_diff, last_ave, epsilon)
    
    def _rolling_ave(self, time_diff, read_diff, last_ave, epsilon):
        """perform a "rolling average" iteration
        a rolling average "folds" new data into an existing average with
        some weight, epsilon.  epsilon must be between 0.0 and 1.0 (inclusive)
        a value of 0.0 means only the old value (initial value) counts,
        and a value of 1.0 means only the newest value is considered."""
        
        try:
            recent_rate = read_diff / time_diff
        except ZeroDivisionError:
            recent_rate = None
        if last_ave is None: return recent_rate
        elif recent_rate is None: return last_ave

        # at this point, both last_ave and recent_rate are numbers
        return epsilon * recent_rate  +  (1 - epsilon) * last_ave

    def _round_remaining_time(self, rt, start_time=15.0):
        """round the remaining time, depending on its size
        If rt is between n*start_time and (n+1)*start_time round downward
        to the nearest multiple of n (for any counting number n).
        If rt < start_time, round down to the nearest 1.
        For example (for start_time = 15.0):
         2.7  -> 2.0
         25.2 -> 25.0
         26.4 -> 26.0
         35.3 -> 34.0
         63.6 -> 60.0
        """

        if rt < 0: return 0.0
        shift = int(math.log(rt/start_time)/math.log(2))
        rt = int(rt)
        if shift <= 0: return rt
        return float(int(rt) >> shift << shift)
        

def format_time(seconds, use_hours=0):
    if seconds is None or seconds < 0:
        if use_hours: return '--:--:--'
        else:         return '--:--'
    else:
        seconds = int(seconds)
        minutes = seconds / 60
        seconds = seconds % 60
        if use_hours:
            hours = minutes / 60
            minutes = minutes % 60
            return '%02i:%02i:%02i' % (hours, minutes, seconds)
        else:
            return '%02i:%02i' % (minutes, seconds)
            
def format_number(number, SI=0, space=' '):
    """Turn numbers into human-readable metric-like numbers"""
    symbols = ['',  # (none)
               'k', # kilo
               'M', # mega
               'G', # giga
               'T', # tera
               'P', # peta
               'E', # exa
               'Z', # zetta
               'Y'] # yotta
    
    if SI: step = 1000.0
    else: step = 1024.0

    thresh = 999
    depth = 0
    max_depth = len(symbols) - 1
    
    # we want numbers between 0 and thresh, but don't exceed the length
    # of our list.  In that event, the formatting will be screwed up,
    # but it'll still show the right number.
    while number > thresh and depth < max_depth:
        depth  = depth + 1
        number = number / step

    if type(number) == type(1) or type(number) == type(1L):
        # it's an int or a long, which means it didn't get divided,
        # which means it's already short enough
        format = '%i%s%s'
    elif number < 9.95:
        # must use 9.95 for proper sizing.  For example, 9.99 will be
        # rounded to 10.0 with the .1f format string (which is too long)
        format = '%.1f%s%s'
    else:
        format = '%.0f%s%s'
        
    return(format % (float(number or 0), space, symbols[depth]))
wic: Add mic w/pykickstart This is the starting point for the implemention described in [YOCTO 3847] which came to the conclusion that it would make sense to use kickstart syntax to implement image creation in OpenEmbedded. I subsequently realized that there was an existing tool that already implemented image creation using kickstart syntax, the Tizen/Meego mic tool. As such, it made sense to use that as a starting point - this commit essentially just copies the relevant Python code from the MIC tool to the scripts/lib dir, where it can be accessed by the previously created wic tool. Most of this will be removed or renamed by later commits, since we're initially focusing on partitioning only. Care should be taken so that we can easily add back any additional functionality should we decide later to expand the tool, though (we may also want to contribute our local changes to the mic tool to the Tizen project if it makes sense, and therefore should avoid gratuitous changes to the original code if possible). Added the /mic subdir from Tizen mic repo as a starting point: git clone git://review.tizen.org/tools/mic.git For reference, the top commit: commit 20164175ddc234a17b8a12c33d04b012347b1530 Author: Gui Chen <gui.chen@intel.com> Date: Sun Jun 30 22:32:16 2013 -0400 bump up to 0.19.2 Also added the /plugins subdir, moved to under the /mic subdir (to match the default plugin_dir location in mic.conf.in, which was renamed to yocto-image.conf (moved and renamed by later patches) and put into /scripts. (From OE-Core rev: 31f0360f1fd4ebc9dfcaed42d1c50d2448b4632e) Signed-off-by: Tom Zanussi <tom.zanussi@linux.intel.com> Signed-off-by: Saul Wold <sgw@linux.intel.com> Signed-off-by: Richard Purdie <richard.purdie@linuxfoundation.org> 2013-08-24 15:31:34 +00:00			`# This library is free software; you can redistribute it and/or`
			`# modify it under the terms of the GNU Lesser General Public`
			`# License as published by the Free Software Foundation; either`
			`# version 2.1 of the License, or (at your option) any later version.`
			`#`
			`# This library 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`
			`# Lesser General Public License for more details.`
			`#`
			`# You should have received a copy of the GNU Lesser General Public`
			`# License along with this library; if not, write to the`
			`# Free Software Foundation, Inc.,`
			`# 59 Temple Place, Suite 330,`
			`# Boston, MA 02111-1307 USA`

			`# This file is part of urlgrabber, a high-level cross-protocol url-grabber`
			`# Copyright 2002-2004 Michael D. Stenner, Ryan Tomayko`

			`# $Id: progress.py,v 1.7 2005/08/19 21:59:07 mstenner Exp $`

			`import sys`
			`import time`
			`import math`
			`import thread`

			`class BaseMeter:`
			`def __init__(self):`
			`self.update_period = 0.3 # seconds`

			`self.filename = None`
			`self.url = None`
			`self.basename = None`
			`self.text = None`
			`self.size = None`
			`self.start_time = None`
			`self.last_amount_read = 0`
			`self.last_update_time = None`
			`self.re = RateEstimator()`

			`def start(self, filename=None, url=None, basename=None,`
			`size=None, now=None, text=None):`
			`self.filename = filename`
			`self.url = url`
			`self.basename = basename`
			`self.text = text`

			`#size = None ######### TESTING`
			`self.size = size`
			`if not size is None: self.fsize = format_number(size) + 'B'`

			`if now is None: now = time.time()`
			`self.start_time = now`
			`self.re.start(size, now)`
			`self.last_amount_read = 0`
			`self.last_update_time = now`
			`self._do_start(now)`

			`def _do_start(self, now=None):`
			`pass`

			`def update(self, amount_read, now=None):`
			`# for a real gui, you probably want to override and put a call`
			`# to your mainloop iteration function here`
			`if now is None: now = time.time()`
			`if (now >= self.last_update_time + self.update_period) or \`
			`not self.last_update_time:`
			`self.re.update(amount_read, now)`
			`self.last_amount_read = amount_read`
			`self.last_update_time = now`
			`self._do_update(amount_read, now)`

			`def _do_update(self, amount_read, now=None):`
			`pass`

			`def end(self, amount_read, now=None):`
			`if now is None: now = time.time()`
			`self.re.update(amount_read, now)`
			`self.last_amount_read = amount_read`
			`self.last_update_time = now`
			`self._do_end(amount_read, now)`

			`def _do_end(self, amount_read, now=None):`
			`pass`

			`class TextMeter(BaseMeter):`
			`def __init__(self, fo=sys.stderr):`
			`BaseMeter.__init__(self)`
			`self.fo = fo`

			`def _do_update(self, amount_read, now=None):`
			`etime = self.re.elapsed_time()`
			`fetime = format_time(etime)`
			`fread = format_number(amount_read)`
			`#self.size = None`
			`if self.text is not None:`
			`text = self.text`
			`else:`
			`text = self.basename`
			`if self.size is None:`
			`out = '\r%-60.60s %5sB %s ' % \`
			`(text, fread, fetime)`
			`else:`
			`rtime = self.re.remaining_time()`
			`frtime = format_time(rtime)`
			`frac = self.re.fraction_read()`
			`bar = '='int(25 frac)`

			`out = '\r%-25.25s %3i%% \|%-25.25s\| %5sB %8s ETA ' % \`
			`(text, frac*100, bar, fread, frtime)`

			`self.fo.write(out)`
			`self.fo.flush()`

			`def _do_end(self, amount_read, now=None):`
			`total_time = format_time(self.re.elapsed_time())`
			`total_size = format_number(amount_read)`
			`if self.text is not None:`
			`text = self.text`
			`else:`
			`text = self.basename`
			`if self.size is None:`
			`out = '\r%-60.60s %5sB %s ' % \`
			`(text, total_size, total_time)`
			`else:`
			`bar = '='*25`
			`out = '\r%-25.25s %3i%% \|%-25.25s\| %5sB %8s ' % \`
			`(text, 100, bar, total_size, total_time)`
			`self.fo.write(out + '\n')`
			`self.fo.flush()`

			`text_progress_meter = TextMeter`

			`class MultiFileHelper(BaseMeter):`
			`def __init__(self, master):`
			`BaseMeter.__init__(self)`
			`self.master = master`

			`def _do_start(self, now):`
			`self.master.start_meter(self, now)`

			`def _do_update(self, amount_read, now):`
			`# elapsed time since last update`
			`self.master.update_meter(self, now)`

			`def _do_end(self, amount_read, now):`
			`self.ftotal_time = format_time(now - self.start_time)`
			`self.ftotal_size = format_number(self.last_amount_read)`
			`self.master.end_meter(self, now)`

			`def failure(self, message, now=None):`
			`self.master.failure_meter(self, message, now)`

			`def message(self, message):`
			`self.master.message_meter(self, message)`

			`class MultiFileMeter:`
			`helperclass = MultiFileHelper`
			`def __init__(self):`
			`self.meters = []`
			`self.in_progress_meters = []`
			`self._lock = thread.allocate_lock()`
			`self.update_period = 0.3 # seconds`

			`self.numfiles = None`
			`self.finished_files = 0`
			`self.failed_files = 0`
			`self.open_files = 0`
			`self.total_size = None`
			`self.failed_size = 0`
			`self.start_time = None`
			`self.finished_file_size = 0`
			`self.last_update_time = None`
			`self.re = RateEstimator()`

			`def start(self, numfiles=None, total_size=None, now=None):`
			`if now is None: now = time.time()`
			`self.numfiles = numfiles`
			`self.finished_files = 0`
			`self.failed_files = 0`
			`self.open_files = 0`
			`self.total_size = total_size`
			`self.failed_size = 0`
			`self.start_time = now`
			`self.finished_file_size = 0`
			`self.last_update_time = now`
			`self.re.start(total_size, now)`
			`self._do_start(now)`

			`def _do_start(self, now):`
			`pass`

			`def end(self, now=None):`
			`if now is None: now = time.time()`
			`self._do_end(now)`

			`def _do_end(self, now):`
			`pass`

			`def lock(self): self._lock.acquire()`
			`def unlock(self): self._lock.release()`

			`###########################################################`
			`# child meter creation and destruction`
			`def newMeter(self):`
			`newmeter = self.helperclass(self)`
			`self.meters.append(newmeter)`
			`return newmeter`

			`def removeMeter(self, meter):`
			`self.meters.remove(meter)`

			`###########################################################`
			`# child functions - these should only be called by helpers`
			`def start_meter(self, meter, now):`
			`if not meter in self.meters:`
			`raise ValueError('attempt to use orphaned meter')`
			`self._lock.acquire()`
			`try:`
			`if not meter in self.in_progress_meters:`
			`self.in_progress_meters.append(meter)`
			`self.open_files += 1`
			`finally:`
			`self._lock.release()`
			`self._do_start_meter(meter, now)`

			`def _do_start_meter(self, meter, now):`
			`pass`

			`def update_meter(self, meter, now):`
			`if not meter in self.meters:`
			`raise ValueError('attempt to use orphaned meter')`
			`if (now >= self.last_update_time + self.update_period) or \`
			`not self.last_update_time:`
			`self.re.update(self._amount_read(), now)`
			`self.last_update_time = now`
			`self._do_update_meter(meter, now)`

			`def _do_update_meter(self, meter, now):`
			`pass`

			`def end_meter(self, meter, now):`
			`if not meter in self.meters:`
			`raise ValueError('attempt to use orphaned meter')`
			`self._lock.acquire()`
			`try:`
			`try: self.in_progress_meters.remove(meter)`
			`except ValueError: pass`
			`self.open_files -= 1`
			`self.finished_files += 1`
			`self.finished_file_size += meter.last_amount_read`
			`finally:`
			`self._lock.release()`
			`self._do_end_meter(meter, now)`

			`def _do_end_meter(self, meter, now):`
			`pass`

			`def failure_meter(self, meter, message, now):`
			`if not meter in self.meters:`
			`raise ValueError('attempt to use orphaned meter')`
			`self._lock.acquire()`
			`try:`
			`try: self.in_progress_meters.remove(meter)`
			`except ValueError: pass`
			`self.open_files -= 1`
			`self.failed_files += 1`
			`if meter.size and self.failed_size is not None:`
			`self.failed_size += meter.size`
			`else:`
			`self.failed_size = None`
			`finally:`
			`self._lock.release()`
			`self._do_failure_meter(meter, message, now)`

			`def _do_failure_meter(self, meter, message, now):`
			`pass`

			`def message_meter(self, meter, message):`
			`pass`

			`########################################################`
			`# internal functions`
			`def _amount_read(self):`
			`tot = self.finished_file_size`
			`for m in self.in_progress_meters:`
			`tot += m.last_amount_read`
			`return tot`


			`class TextMultiFileMeter(MultiFileMeter):`
			`def __init__(self, fo=sys.stderr):`
			`self.fo = fo`
			`MultiFileMeter.__init__(self)`

			`# files: ###/### ###% data: ######/###### ###% time: ##:##:##/##:##:##`
			`def _do_update_meter(self, meter, now):`
			`self._lock.acquire()`
			`try:`
			`format = "files: %3i/%-3i %3i%% data: %6.6s/%-6.6s %3i%% " \`
			`"time: %8.8s/%8.8s"`
			`df = self.finished_files`
			`tf = self.numfiles or 1`
			`pf = 100 * float(df)/tf + 0.49`
			`dd = self.re.last_amount_read`
			`td = self.total_size`
			`pd = 100 * (self.re.fraction_read() or 0) + 0.49`
			`dt = self.re.elapsed_time()`
			`rt = self.re.remaining_time()`
			`if rt is None: tt = None`
			`else: tt = dt + rt`

			`fdd = format_number(dd) + 'B'`
			`ftd = format_number(td) + 'B'`
			`fdt = format_time(dt, 1)`
			`ftt = format_time(tt, 1)`

			`out = '%-79.79s' % (format % (df, tf, pf, fdd, ftd, pd, fdt, ftt))`
			`self.fo.write('\r' + out)`
			`self.fo.flush()`
			`finally:`
			`self._lock.release()`

			`def _do_end_meter(self, meter, now):`
			`self._lock.acquire()`
			`try:`
			`format = "%-30.30s %6.6s %8.8s %9.9s"`
			`fn = meter.basename`
			`size = meter.last_amount_read`
			`fsize = format_number(size) + 'B'`
			`et = meter.re.elapsed_time()`
			`fet = format_time(et, 1)`
			`frate = format_number(size / et) + 'B/s'`

			`out = '%-79.79s' % (format % (fn, fsize, fet, frate))`
			`self.fo.write('\r' + out + '\n')`
			`finally:`
			`self._lock.release()`
			`self._do_update_meter(meter, now)`

			`def _do_failure_meter(self, meter, message, now):`
			`self._lock.acquire()`
			`try:`
			`format = "%-30.30s %6.6s %s"`
			`fn = meter.basename`
			`if type(message) in (type(''), type(u'')):`
			`message = message.splitlines()`
			`if not message: message = ['']`
			`out = '%-79s' % (format % (fn, 'FAILED', message[0] or ''))`
			`self.fo.write('\r' + out + '\n')`
			`for m in message[1:]: self.fo.write(' ' + m + '\n')`
			`self._lock.release()`
			`finally:`
			`self._do_update_meter(meter, now)`

			`def message_meter(self, meter, message):`
			`self._lock.acquire()`
			`try:`
			`pass`
			`finally:`
			`self._lock.release()`

			`def _do_end(self, now):`
			`self._do_update_meter(None, now)`
			`self._lock.acquire()`
			`try:`
			`self.fo.write('\n')`
			`self.fo.flush()`
			`finally:`
			`self._lock.release()`

			`######################################################################`
			`# support classes and functions`

			`class RateEstimator:`
			`def __init__(self, timescale=5.0):`
			`self.timescale = timescale`

			`def start(self, total=None, now=None):`
			`if now is None: now = time.time()`
			`self.total = total`
			`self.start_time = now`
			`self.last_update_time = now`
			`self.last_amount_read = 0`
			`self.ave_rate = None`

			`def update(self, amount_read, now=None):`
			`if now is None: now = time.time()`
			`if amount_read == 0:`
			`# if we just started this file, all bets are off`
			`self.last_update_time = now`
			`self.last_amount_read = 0`
			`self.ave_rate = None`
			`return`

			`#print 'times', now, self.last_update_time`
			`time_diff = now - self.last_update_time`
			`read_diff = amount_read - self.last_amount_read`
			`self.last_update_time = now`
			`self.last_amount_read = amount_read`
			`self.ave_rate = self._temporal_rolling_ave(\`
			`time_diff, read_diff, self.ave_rate, self.timescale)`
			`#print 'results', time_diff, read_diff, self.ave_rate`

			`#####################################################################`
			`# result methods`
			`def average_rate(self):`
			`"get the average transfer rate (in bytes/second)"`
			`return self.ave_rate`

			`def elapsed_time(self):`
			`"the time between the start of the transfer and the most recent update"`
			`return self.last_update_time - self.start_time`

			`def remaining_time(self):`
			`"estimated time remaining"`
			`if not self.ave_rate or not self.total: return None`
			`return (self.total - self.last_amount_read) / self.ave_rate`

			`def fraction_read(self):`
			`"""the fraction of the data that has been read`
			`(can be None for unknown transfer size)"""`
			`if self.total is None: return None`
			`elif self.total == 0: return 1.0`
			`else: return float(self.last_amount_read)/self.total`

			`#########################################################################`
			`# support methods`
			`def _temporal_rolling_ave(self, time_diff, read_diff, last_ave, timescale):`
			`"""a temporal rolling average performs smooth averaging even when`
			`updates come at irregular intervals. This is performed by scaling`
			`the "epsilon" according to the time since the last update.`
			`Specifically, epsilon = time_diff / timescale`

			`As a general rule, the average will take on a completely new value`
			`after 'timescale' seconds."""`
			`epsilon = time_diff / timescale`
			`if epsilon > 1: epsilon = 1.0`
			`return self._rolling_ave(time_diff, read_diff, last_ave, epsilon)`

			`def _rolling_ave(self, time_diff, read_diff, last_ave, epsilon):`
			`"""perform a "rolling average" iteration`
			`a rolling average "folds" new data into an existing average with`
			`some weight, epsilon. epsilon must be between 0.0 and 1.0 (inclusive)`
			`a value of 0.0 means only the old value (initial value) counts,`
			`and a value of 1.0 means only the newest value is considered."""`

			`try:`
			`recent_rate = read_diff / time_diff`
			`except ZeroDivisionError:`
			`recent_rate = None`
			`if last_ave is None: return recent_rate`
			`elif recent_rate is None: return last_ave`

			`# at this point, both last_ave and recent_rate are numbers`
			`return epsilon * recent_rate + (1 - epsilon) * last_ave`

			`def _round_remaining_time(self, rt, start_time=15.0):`
			`"""round the remaining time, depending on its size`
			`If rt is between nstart_time and (n+1)start_time round downward`
			`to the nearest multiple of n (for any counting number n).`
			`If rt < start_time, round down to the nearest 1.`
			`For example (for start_time = 15.0):`
			`2.7 -> 2.0`
			`25.2 -> 25.0`
			`26.4 -> 26.0`
			`35.3 -> 34.0`
			`63.6 -> 60.0`
			`"""`

			`if rt < 0: return 0.0`
			`shift = int(math.log(rt/start_time)/math.log(2))`
			`rt = int(rt)`
			`if shift <= 0: return rt`
			`return float(int(rt) >> shift << shift)`


			`def format_time(seconds, use_hours=0):`
			`if seconds is None or seconds < 0:`
			`if use_hours: return '--:--:--'`
			`else: return '--:--'`
			`else:`
			`seconds = int(seconds)`
			`minutes = seconds / 60`
			`seconds = seconds % 60`
			`if use_hours:`
			`hours = minutes / 60`
			`minutes = minutes % 60`
			`return '%02i:%02i:%02i' % (hours, minutes, seconds)`
			`else:`
			`return '%02i:%02i' % (minutes, seconds)`

			`def format_number(number, SI=0, space=' '):`
			`"""Turn numbers into human-readable metric-like numbers"""`
			`symbols = ['', # (none)`
			`'k', # kilo`
			`'M', # mega`
			`'G', # giga`
			`'T', # tera`
			`'P', # peta`
			`'E', # exa`
			`'Z', # zetta`
			`'Y'] # yotta`

			`if SI: step = 1000.0`
			`else: step = 1024.0`

			`thresh = 999`
			`depth = 0`
			`max_depth = len(symbols) - 1`

			`# we want numbers between 0 and thresh, but don't exceed the length`
			`# of our list. In that event, the formatting will be screwed up,`
			`# but it'll still show the right number.`
			`while number > thresh and depth < max_depth:`
			`depth = depth + 1`
			`number = number / step`

			`if type(number) == type(1) or type(number) == type(1L):`
			`# it's an int or a long, which means it didn't get divided,`
			`# which means it's already short enough`
			`format = '%i%s%s'`
			`elif number < 9.95:`
			`# must use 9.95 for proper sizing. For example, 9.99 will be`
			`# rounded to 10.0 with the .1f format string (which is too long)`
			`format = '%.1f%s%s'`
			`else:`
			`format = '%.0f%s%s'`

			`return(format % (float(number or 0), space, symbols[depth]))`