show-blocks - pub/scm/linux/kernel/git/mason/btrfs-progs - Git at Google

 #!/usr/bin/env python
 #
 # Copyright (C) 2007 Oracle.  All rights reserved.
 #
 # This program is free software; you can redistribute it and/or
 # modify it under the terms of the GNU General Public
 # License v2 as published by the Free Software Foundation.
 #
 # 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, write to the
 # Free Software Foundation, Inc., 59 Temple Place - Suite 330,
 # Boston, MA 021110-1307, USA.
 #
 import sys, os, signal, time, commands, tempfile, random

 # numpy seems to override random() with something else.  Instantiate our
 # own here
 randgen = random.Random()
 randgen.seed(50)

 from optparse import OptionParser
 from matplotlib import rcParams
 from matplotlib.font_manager import fontManager, FontProperties
 import numpy

 rcParams['numerix'] = 'numpy'
 rcParams['backend'] = 'Agg'
 rcParams['interactive'] = 'False'
 from pylab import *

 class AnnoteFinder:
   """
   callback for matplotlib to display an annotation when points are clicked on.  The
   point which is closest to the click and within xtol and ytol is identified.

   Register this function like this:

   scatter(xdata, ydata)
   af = AnnoteFinder(xdata, ydata, annotes)
   connect('button_press_event', af)
   """

   def __init__(self, axis=None):
     if axis is None:
       self.axis = gca()
     else:
       self.axis= axis
     self.drawnAnnotations = {}
     self.links = []

   def clear(self):
     for k in self.drawnAnnotations.keys():
         self.drawnAnnotations[k].set_visible(False)

   def __call__(self, event):
     if event.inaxes:
       if event.button != 1:
         self.clear()
         draw()
         return
       clickX = event.xdata
       clickY = event.ydata
       if (self.axis is None) or (self.axis==event.inaxes):
         self.drawAnnote(event.inaxes, clickX, clickY)

   def drawAnnote(self, axis, x, y):
     """
     Draw the annotation on the plot
     """
     if self.drawnAnnotations.has_key((x,y)):
       markers = self.drawnAnnotations[(x,y)]
       markers.set_visible(not markers.get_visible())
       draw()
     else:
       t = axis.text(x,y, "(%3.2f, %3.2f)"%(x,y), bbox=dict(facecolor='red',
                     alpha=0.8))
       self.drawnAnnotations[(x,y)] = t
       draw()

 def loaddata(fh,delimiter=None, converters=None):

     #14413824 8192 extent back ref root 5 gen 10 owner 282 num_refs 1
     def iter(fh, delimiter, converters):
         global total_data
         global total_metadata
         for i,line in enumerate(fh):
             line = line.split(' ')
             start = float(line[0])
             len = float(line[1])
             owner = float(line[10])
             root = float(line[6])
             if owner <= 255:
                 total_metadata += int(len)
             else:
                 total_data += int(len)
             if start < zoommin or (zoommax != 0 and start > zoommax):
                 continue
             yield start
             yield len
             yield owner
             yield root
     X = numpy.fromiter(iter(fh, delimiter, converters), dtype=float)
     return X

 def run_debug_tree(device):
     p = os.popen('btrfs-debug-tree -e ' + device)
     data = loaddata(p)
     return data

 def shapeit(X):
     lines = len(X) / 4
     X.shape = (lines, 4)

 def line_picker(line, mouseevent):
     if mouseevent.xdata is None: return False, dict()
     print "%d %d\n", mouseevent.xdata, mouseevent.ydata
     return False, dict()

 def xycalc(byte):
     byte = byte / bytes_per_cell
     yval = floor(byte / num_cells)
     xval = byte % num_cells
     return (xval, yval + 1)

 # record the color used for each root the first time we find it
 root_colors = {}
 # there are lots of good colormaps to choose from
 # http://www.scipy.org/Cookbook/Matplotlib/Show_colormaps
 #
 meta_cmap = get_cmap("gist_ncar")
 data_done = False

 def plotone(a, xvals, yvals, owner, root, lines, labels):
     global data_done
     add_label = False

     if owner:
         if options.meta_only:
             return
         color = "blue"
         label = "Data"
         if not data_done:
             add_label = True
             data_done = True
     else:
         if options.data_only:
             return
         if root not in root_colors:
             color = meta_cmap(randgen.random())
             label = "Meta %d" % int(root)
             root_colors[root] = (color, label)
             add_label = True
         else:
             color, label = root_colors[root]

     plotlines = a.plot(xvals, yvals, 's', color=color, mfc=color, mec=color,
            markersize=.23, label=label)
     if add_label:
         lines += plotlines
         labels.append(label)
         print "add label %s" % label

 def parse_zoom():
     def parse_num(s):
         mult = 1
         c = s.lower()[-1]
         if c == 't':
             mult = 1024 * 1024 * 1024 * 1024
         elif c == 'g':
             mult = 1024 * 1024 * 1024
         elif c == 'm':
             mult = 1024 * 1024
         elif c == 'k':
             mult = 1024
         else:
             c = None
         if c:
             num = int(s[:-1]) * mult
         else:
             num = int(s)
         return num

     if not options.zoom:
         return (0, 0)

     vals = options.zoom.split(':')
     if len(vals) != 2:
         sys.stderr.write("warning: unable to parse zoom %s\n" % options.zoom)
         return (0, 0)
     zoommin = parse_num(vals[0])
     zoommax = parse_num(vals[1])
     return (zoommin, zoommax)

 usage = "usage: %prog [options]"
 parser = OptionParser(usage=usage)
 parser.add_option("-d", "--device", help="Btrfs device", default="")
 parser.add_option("-i", "--input-file", help="debug-tree data", default="")
 parser.add_option("-o", "--output", help="Output file", default="blocks.png")
 parser.add_option("-z", "--zoom", help="Zoom", default=None)
 parser.add_option("", "--data-only", help="Only print data blocks",
                   default=False, action="store_true")
 parser.add_option("", "--meta-only", help="Only print metadata blocks",
                   default=False, action="store_true")

 (options,args) = parser.parse_args()

 if not options.device and not options.input_file:
     parser.print_help()
     sys.exit(1)

 zoommin, zoommax = parse_zoom()
 total_data = 0
 total_metadata = 0

 if options.device:
     data = run_debug_tree(options.device)
 elif options.input_file:
     data = loaddata(file(options.input_file))
 shapeit(data)

 # try to drop out the least common data points by creating
 # a historgram of the sectors seen.
 sectors = data[:,0]
 sizes = data[:,1]
 datalen = len(data)
 sectormax = numpy.max(sectors)
 sectormin = 0
 num_cells = 800
 total_cells = num_cells * num_cells
 byte_range = sectormax - sectormin
 bytes_per_cell = byte_range / total_cells

 f = figure(figsize=(8,6))

 # Throughput goes at the botoom
 a = subplot(1, 1, 1)
 subplots_adjust(right=0.7)
 datai = 0
 xvals = []
 yvals = []
 last_owner = 0
 last_root = 0
 lines = []
 labels = []
 while datai < datalen:
     row = data[datai]
     datai += 1
     byte = row[0]
     size = row[1]
     owner = row[2]
     root = row[3]

     if owner <= 255:
         owner = 0
     else:
         owner = 1

     if len(xvals) and (owner != last_owner or last_root != root):
         plotone(a, xvals, yvals, last_owner, last_root, lines, labels)
         xvals = []
         yvals = []
     cell = 0
     while cell < size:
         xy = xycalc(byte)
         byte += bytes_per_cell
         cell += bytes_per_cell
         if xy:
             xvals.append(xy[0])
             yvals.append(xy[1])
     last_owner = owner
     last_root = root

 if xvals:
     plotone(a, xvals, yvals, last_owner, last_root, lines, labels)

 # make sure the final second goes on the x axes
 ticks = []
 a.set_xticks(ticks)
 ticks = a.get_yticks()

 first_tick = ticks[1] * bytes_per_cell * num_cells
 if first_tick > 1024 * 1024 * 1024 * 1024:
     scale = 1024 * 1024 * 1024 * 1024;
     scalestr = "TB"
 elif first_tick > 1024 * 1024 * 1024:
     scale = 1024 * 1024 * 1024;
     scalestr = "GB"
 elif first_tick > 1024 * 1024:
     scale = 1024 * 1024;
     scalestr = "MB"
 elif first_tick > 1024:
     scale = 1024;
     scalestr = "KB"
 else:
     scalestr = "Bytes"
     scale = 1

 ylabels = [ str(int((x * bytes_per_cell * num_cells) / scale)) for x in ticks ]
 a.set_yticklabels(ylabels)
 a.set_ylabel('Disk offset (%s)' % scalestr)
 a.set_xlim(0, num_cells)
 a.set_title('Blocks')

 a.legend(lines, labels, loc=(1.05, 0.8), shadow=True, pad=0.1, numpoints=1,
               handletextsep = 0.005,
               labelsep = 0.01,
               markerscale=10,
               prop=FontProperties(size='x-small') )

 if total_data == 0:
     percent_meta = 100
 else:
     percent_meta = (float(total_metadata) / float(total_data)) * 100

 print "Total metadata bytes %d data %d ratio %.3f" % (total_metadata,
                                                     total_data, percent_meta)
 print "saving graph to %s" % options.output
 savefig(options.output, orientation='landscape')
 show()
	#!/usr/bin/env python
	#
	# Copyright (C) 2007 Oracle. All rights reserved.
	#
	# This program is free software; you can redistribute it and/or
	# modify it under the terms of the GNU General Public
	# License v2 as published by the Free Software Foundation.
	#
	# 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, write to the
	# Free Software Foundation, Inc., 59 Temple Place - Suite 330,
	# Boston, MA 021110-1307, USA.
	#
	import sys, os, signal, time, commands, tempfile, random

	# numpy seems to override random() with something else. Instantiate our
	# own here
	randgen = random.Random()
	randgen.seed(50)

	from optparse import OptionParser
	from matplotlib import rcParams
	from matplotlib.font_manager import fontManager, FontProperties
	import numpy

	rcParams['numerix'] = 'numpy'
	rcParams['backend'] = 'Agg'
	rcParams['interactive'] = 'False'
	from pylab import *

	class AnnoteFinder:
	"""
	callback for matplotlib to display an annotation when points are clicked on. The
	point which is closest to the click and within xtol and ytol is identified.

	Register this function like this:

	scatter(xdata, ydata)
	af = AnnoteFinder(xdata, ydata, annotes)
	connect('button_press_event', af)
	"""

	def __init__(self, axis=None):
	if axis is None:
	self.axis = gca()
	else:
	self.axis= axis
	self.drawnAnnotations = {}
	self.links = []

	def clear(self):
	for k in self.drawnAnnotations.keys():
	self.drawnAnnotations[k].set_visible(False)

	def __call__(self, event):
	if event.inaxes:
	if event.button != 1:
	self.clear()
	draw()
	return
	clickX = event.xdata
	clickY = event.ydata
	if (self.axis is None) or (self.axis==event.inaxes):
	self.drawAnnote(event.inaxes, clickX, clickY)

	def drawAnnote(self, axis, x, y):
	"""
	Draw the annotation on the plot
	"""
	if self.drawnAnnotations.has_key((x,y)):
	markers = self.drawnAnnotations[(x,y)]
	markers.set_visible(not markers.get_visible())
	draw()
	else:
	t = axis.text(x,y, "(%3.2f, %3.2f)"%(x,y), bbox=dict(facecolor='red',
	alpha=0.8))
	self.drawnAnnotations[(x,y)] = t
	draw()

	def loaddata(fh,delimiter=None, converters=None):

	#14413824 8192 extent back ref root 5 gen 10 owner 282 num_refs 1
	def iter(fh, delimiter, converters):
	global total_data
	global total_metadata
	for i,line in enumerate(fh):
	line = line.split(' ')
	start = float(line[0])
	len = float(line[1])
	owner = float(line[10])
	root = float(line[6])
	if owner <= 255:
	total_metadata += int(len)
	else:
	total_data += int(len)
	if start < zoommin or (zoommax != 0 and start > zoommax):
	continue
	yield start
	yield len
	yield owner
	yield root
	X = numpy.fromiter(iter(fh, delimiter, converters), dtype=float)
	return X

	def run_debug_tree(device):
	p = os.popen('btrfs-debug-tree -e ' + device)
	data = loaddata(p)
	return data

	def shapeit(X):
	lines = len(X) / 4
	X.shape = (lines, 4)

	def line_picker(line, mouseevent):
	if mouseevent.xdata is None: return False, dict()
	print "%d %d\n", mouseevent.xdata, mouseevent.ydata
	return False, dict()

	def xycalc(byte):
	byte = byte / bytes_per_cell
	yval = floor(byte / num_cells)
	xval = byte % num_cells
	return (xval, yval + 1)

	# record the color used for each root the first time we find it
	root_colors = {}
	# there are lots of good colormaps to choose from
	# http://www.scipy.org/Cookbook/Matplotlib/Show_colormaps
	#
	meta_cmap = get_cmap("gist_ncar")
	data_done = False

	def plotone(a, xvals, yvals, owner, root, lines, labels):
	global data_done
	add_label = False

	if owner:
	if options.meta_only:
	return
	color = "blue"
	label = "Data"
	if not data_done:
	add_label = True
	data_done = True
	else:
	if options.data_only:
	return
	if root not in root_colors:
	color = meta_cmap(randgen.random())
	label = "Meta %d" % int(root)
	root_colors[root] = (color, label)
	add_label = True
	else:
	color, label = root_colors[root]

	plotlines = a.plot(xvals, yvals, 's', color=color, mfc=color, mec=color,
	markersize=.23, label=label)
	if add_label:
	lines += plotlines
	labels.append(label)
	print "add label %s" % label

	def parse_zoom():
	def parse_num(s):
	mult = 1
	c = s.lower()[-1]
	if c == 't':
	mult = 1024 * 1024 * 1024 * 1024
	elif c == 'g':
	mult = 1024 * 1024 * 1024
	elif c == 'm':
	mult = 1024 * 1024
	elif c == 'k':
	mult = 1024
	else:
	c = None
	if c:
	num = int(s[:-1]) * mult
	else:
	num = int(s)
	return num

	if not options.zoom:
	return (0, 0)

	vals = options.zoom.split(':')
	if len(vals) != 2:
	sys.stderr.write("warning: unable to parse zoom %s\n" % options.zoom)
	return (0, 0)
	zoommin = parse_num(vals[0])
	zoommax = parse_num(vals[1])
	return (zoommin, zoommax)

	usage = "usage: %prog [options]"
	parser = OptionParser(usage=usage)
	parser.add_option("-d", "--device", help="Btrfs device", default="")
	parser.add_option("-i", "--input-file", help="debug-tree data", default="")
	parser.add_option("-o", "--output", help="Output file", default="blocks.png")
	parser.add_option("-z", "--zoom", help="Zoom", default=None)
	parser.add_option("", "--data-only", help="Only print data blocks",
	default=False, action="store_true")
	parser.add_option("", "--meta-only", help="Only print metadata blocks",
	default=False, action="store_true")

	(options,args) = parser.parse_args()

	if not options.device and not options.input_file:
	parser.print_help()
	sys.exit(1)

	zoommin, zoommax = parse_zoom()
	total_data = 0
	total_metadata = 0

	if options.device:
	data = run_debug_tree(options.device)
	elif options.input_file:
	data = loaddata(file(options.input_file))
	shapeit(data)

	# try to drop out the least common data points by creating
	# a historgram of the sectors seen.
	sectors = data[:,0]
	sizes = data[:,1]
	datalen = len(data)
	sectormax = numpy.max(sectors)
	sectormin = 0
	num_cells = 800
	total_cells = num_cells * num_cells
	byte_range = sectormax - sectormin
	bytes_per_cell = byte_range / total_cells

	f = figure(figsize=(8,6))

	# Throughput goes at the botoom
	a = subplot(1, 1, 1)
	subplots_adjust(right=0.7)
	datai = 0
	xvals = []
	yvals = []
	last_owner = 0
	last_root = 0
	lines = []
	labels = []
	while datai < datalen:
	row = data[datai]
	datai += 1
	byte = row[0]
	size = row[1]
	owner = row[2]
	root = row[3]

	if owner <= 255:
	owner = 0
	else:
	owner = 1

	if len(xvals) and (owner != last_owner or last_root != root):
	plotone(a, xvals, yvals, last_owner, last_root, lines, labels)
	xvals = []
	yvals = []
	cell = 0
	while cell < size:
	xy = xycalc(byte)
	byte += bytes_per_cell
	cell += bytes_per_cell
	if xy:
	xvals.append(xy[0])
	yvals.append(xy[1])
	last_owner = owner
	last_root = root

	if xvals:
	plotone(a, xvals, yvals, last_owner, last_root, lines, labels)

	# make sure the final second goes on the x axes
	ticks = []
	a.set_xticks(ticks)
	ticks = a.get_yticks()

	first_tick = ticks[1] * bytes_per_cell * num_cells
	if first_tick > 1024 * 1024 * 1024 * 1024:
	scale = 1024 * 1024 * 1024 * 1024;
	scalestr = "TB"
	elif first_tick > 1024 * 1024 * 1024:
	scale = 1024 * 1024 * 1024;
	scalestr = "GB"
	elif first_tick > 1024 * 1024:
	scale = 1024 * 1024;
	scalestr = "MB"
	elif first_tick > 1024:
	scale = 1024;
	scalestr = "KB"
	else:
	scalestr = "Bytes"
	scale = 1

	ylabels = [ str(int((x * bytes_per_cell * num_cells) / scale)) for x in ticks ]
	a.set_yticklabels(ylabels)
	a.set_ylabel('Disk offset (%s)' % scalestr)
	a.set_xlim(0, num_cells)
	a.set_title('Blocks')

	a.legend(lines, labels, loc=(1.05, 0.8), shadow=True, pad=0.1, numpoints=1,
	handletextsep = 0.005,
	labelsep = 0.01,
	markerscale=10,
	prop=FontProperties(size='x-small') )

	if total_data == 0:
	percent_meta = 100
	else:
	percent_meta = (float(total_metadata) / float(total_data)) * 100

	print "Total metadata bytes %d data %d ratio %.3f" % (total_metadata,
	total_data, percent_meta)
	print "saving graph to %s" % options.output
	savefig(options.output, orientation='landscape')
	show()