util/stats/barchart.py - public/gem5 - Git at Google

 # Copyright (c) 2005-2006 The Regents of The University of Michigan
 # All rights reserved.
 #
 # Redistribution and use in source and binary forms, with or without
 # modification, are permitted provided that the following conditions are
 # met: redistributions of source code must retain the above copyright
 # notice, this list of conditions and the following disclaimer;
 # redistributions in binary form must reproduce the above copyright
 # notice, this list of conditions and the following disclaimer in the
 # documentation and/or other materials provided with the distribution;
 # neither the name of the copyright holders nor the names of its
 # contributors may be used to endorse or promote products derived from
 # this software without specific prior written permission.
 #
 # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 # "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 # LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 # A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 # OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 # SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 # LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 # DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 # THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 # (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 # OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 import matplotlib, pylab
 from matplotlib.font_manager import FontProperties
 from matplotlib.numerix import array, arange, reshape, shape, transpose, zeros
 from matplotlib.numerix import Float
 from matplotlib.ticker import NullLocator
 from functools import reduce

 matplotlib.interactive(False)

 from .chart import ChartOptions

 class BarChart(ChartOptions):
     def __init__(self, default=None, **kwargs):
         super(BarChart, self).__init__(default, **kwargs)
         self.inputdata = None
         self.chartdata = None
         self.inputerr = None
         self.charterr = None

     def gen_colors(self, count):
         cmap = matplotlib.cm.get_cmap(self.colormap)
         if count == 1:
             return cmap([ 0.5 ])

         if count < 5:
             return cmap(arange(5) / float(4))[:count]

         return cmap(arange(count) / float(count - 1))

     # The input data format does not match the data format that the
     # graph function takes because it is intuitive.  The conversion
     # from input data format to chart data format depends on the
     # dimensionality of the input data.  Check here for the
     # dimensionality and correctness of the input data
     def set_data(self, data):
         if data is None:
             self.inputdata = None
             self.chartdata = None
             return

         data = array(data)
         dim = len(shape(data))
         if dim not in (1, 2, 3):
             raise AttributeError("Input data must be a 1, 2, or 3d matrix")
         self.inputdata = data

         # If the input data is a 1d matrix, then it describes a
         # standard bar chart.
         if dim == 1:
             self.chartdata = array([[data]])

         # If the input data is a 2d matrix, then it describes a bar
         # chart with groups. The matrix being an array of groups of
         # bars.
         if dim == 2:
             self.chartdata = transpose([data], axes=(2,0,1))

         # If the input data is a 3d matrix, then it describes an array
         # of groups of bars with each bar being an array of stacked
         # values.
         if dim == 3:
             self.chartdata = transpose(data, axes=(1,2,0))

     def get_data(self):
         return self.inputdata

     data = property(get_data, set_data)

     def set_err(self, err):
         if err is None:
             self.inputerr = None
             self.charterr = None
             return

         err = array(err)
         dim = len(shape(err))
         if dim not in (1, 2, 3):
             raise AttributeError("Input err must be a 1, 2, or 3d matrix")
         self.inputerr = err

         if dim == 1:
             self.charterr = array([[err]])

         if dim == 2:
             self.charterr = transpose([err], axes=(2,0,1))

         if dim == 3:
             self.charterr = transpose(err, axes=(1,2,0))

     def get_err(self):
         return self.inputerr

     err = property(get_err, set_err)

     # Graph the chart data.
     # Input is a 3d matrix that describes a plot that has multiple
     # groups, multiple bars in each group, and multiple values stacked
     # in each bar.  The underlying bar() function expects a sequence of
     # bars in the same stack location and same group location, so the
     # organization of the matrix is that the inner most sequence
     # represents one of these bar groups, then those are grouped
     # together to make one full stack of bars in each group, and then
     # the outer most layer describes the groups.  Here is an example
     # data set and how it gets plotted as a result.
     #
     # e.g. data = [[[10,11,12], [13,14,15],  [16,17,18], [19,20,21]],
     #              [[22,23,24], [25,26,27],  [28,29,30], [31,32,33]]]
     #
     # will plot like this:
     #
     #    19 31    20 32    21 33
     #    16 28    17 29    18 30
     #    13 25    14 26    15 27
     #    10 22    11 23    12 24
     #
     # Because this arrangement is rather conterintuitive, the rearrange
     # function takes various matricies and arranges them to fit this
     # profile.
     #
     # This code deals with one of the dimensions in the matrix being
     # one wide.
     #
     def graph(self):
         if self.chartdata is None:
             raise AttributeError("Data not set for bar chart!")

         dim = len(shape(self.inputdata))
         cshape = shape(self.chartdata)
         if self.charterr is not None and shape(self.charterr) != cshape:
             raise AttributeError('Dimensions of error and data do not match')

         if dim == 1:
             colors = self.gen_colors(cshape[2])
             colors = [ [ colors ] * cshape[1] ] * cshape[0]

         if dim == 2:
             colors = self.gen_colors(cshape[0])
             colors = [ [ [ c ] * cshape[2] ] * cshape[1] for c in colors ]

         if dim == 3:
             colors = self.gen_colors(cshape[1])
             colors = [ [ [ c ] * cshape[2] for c in colors ] ] * cshape[0]

         colors = array(colors)

         self.figure = pylab.figure(figsize=self.chart_size)

         outer_axes = None
         inner_axes = None
         if self.xsubticks is not None:
             color = self.figure.get_facecolor()
             self.metaaxes = self.figure.add_axes(self.figure_size,
                                                  axisbg=color, frameon=False)
             for tick in self.metaaxes.xaxis.majorTicks:
                 tick.tick1On = False
                 tick.tick2On = False
             self.metaaxes.set_yticklabels([])
             self.metaaxes.set_yticks([])
             size = [0] * 4
             size[0] = self.figure_size[0]
             size[1] = self.figure_size[1] + .12
             size[2] = self.figure_size[2]
             size[3] = self.figure_size[3] - .12
             self.axes = self.figure.add_axes(size)
             outer_axes = self.metaaxes
             inner_axes = self.axes
         else:
             self.axes = self.figure.add_axes(self.figure_size)
             outer_axes = self.axes
             inner_axes = self.axes

         bars_in_group = len(self.chartdata)

         width = 1.0 / ( bars_in_group + 1)
         center = width / 2

         bars = []
         for i,stackdata in enumerate(self.chartdata):
             bottom = array([0.0] * len(stackdata[0]), Float)
             stack = []
             for j,bardata in enumerate(stackdata):
                 bardata = array(bardata)
                 ind = arange(len(bardata)) + i * width + center
                 yerr = None
                 if self.charterr is not None:
                     yerr = self.charterr[i][j]
                 bar = self.axes.bar(ind, bardata, width, bottom=bottom,
                                     color=colors[i][j], yerr=yerr)
                 if self.xsubticks is not None:
                     self.metaaxes.bar(ind, [0] * len(bardata), width)
                 stack.append(bar)
                 bottom += bardata
             bars.append(stack)

         if self.xlabel is not None:
             outer_axes.set_xlabel(self.xlabel)

         if self.ylabel is not None:
             inner_axes.set_ylabel(self.ylabel)

         if self.yticks is not None:
             ymin, ymax = self.axes.get_ylim()
             nticks = float(len(self.yticks))
             ticks = arange(nticks) / (nticks - 1) * (ymax - ymin)  + ymin
             inner_axes.set_yticks(ticks)
             inner_axes.set_yticklabels(self.yticks)
         elif self.ylim is not None:
             inner_axes.set_ylim(self.ylim)

         if self.xticks is not None:
             outer_axes.set_xticks(arange(cshape[2]) + .5)
             outer_axes.set_xticklabels(self.xticks)

         if self.xsubticks is not None:
             numticks = (cshape[0] + 1) * cshape[2]
             inner_axes.set_xticks(arange(numticks) * width + 2 * center)
             xsubticks = list(self.xsubticks) + [ '' ]
             inner_axes.set_xticklabels(xsubticks * cshape[2], fontsize=7,
                                        rotation=30)

         if self.legend is not None:
             if dim == 1:
                 lbars = bars[0][0]
             if dim == 2:
                 lbars = [ bars[i][0][0] for i in range(len(bars))]
             if dim == 3:
                 number = len(bars[0])
                 lbars = [ bars[0][number - j - 1][0] for j in range(number)]

             if self.fig_legend:
                 self.figure.legend(lbars, self.legend, self.legend_loc,
                                    prop=FontProperties(size=self.legend_size))
             else:
                 self.axes.legend(lbars, self.legend, self.legend_loc,
                                  prop=FontProperties(size=self.legend_size))

         if self.title is not None:
             self.axes.set_title(self.title)

     def savefig(self, name):
         self.figure.savefig(name)

     def savecsv(self, name):
         f = file(name, 'w')
         data = array(self.inputdata)
         dim = len(data.shape)

         if dim == 1:
             #if self.xlabel:
             #    f.write(', '.join(list(self.xlabel)) + '\n')
             f.write(', '.join([ '%f' % val for val in data]) + '\n')
         if dim == 2:
             #if self.xlabel:
             #    f.write(', '.join([''] + list(self.xlabel)) + '\n')
             for i,row in enumerate(data):
                 ylabel = []
                 #if self.ylabel:
                 #    ylabel = [ self.ylabel[i] ]
                 f.write(', '.join(ylabel + [ '%f' % v for v in row]) + '\n')
         if dim == 3:
             f.write("don't do 3D csv files\n")
             pass

         f.close()

 if __name__ == '__main__':
     from random import randrange
     import random, sys

     dim = 3
     number = 5

     args = sys.argv[1:]
     if len(args) > 3:
         sys.exit("invalid number of arguments")
     elif len(args) > 0:
         myshape = [ int(x) for x in args ]
     else:
         myshape = [ 3, 4, 8 ]

     # generate a data matrix of the given shape
     size = reduce(lambda x,y: x*y, myshape)
     #data = [ random.randrange(size - i) + 10 for i in xrange(size) ]
     data = [ float(i)/100.0 for i in range(size) ]
     data = reshape(data, myshape)

     # setup some test bar charts
     if True:
         chart1 = BarChart()
         chart1.data = data

         chart1.xlabel = 'Benchmark'
         chart1.ylabel = 'Bandwidth (GBps)'
         chart1.legend = [ 'x%d' % x for x in range(myshape[-1]) ]
         chart1.xticks = [ 'xtick%d' % x for x in range(myshape[0]) ]
         chart1.title = 'this is the title'
         if len(myshape) > 2:
             chart1.xsubticks = [ '%d' % x for x in range(myshape[1]) ]
         chart1.graph()
         chart1.savefig('/tmp/test1.png')
         chart1.savefig('/tmp/test1.ps')
         chart1.savefig('/tmp/test1.eps')
         chart1.savecsv('/tmp/test1.csv')

     if False:
         chart2 = BarChart()
         chart2.data = data
         chart2.colormap = 'gray'
         chart2.graph()
         chart2.savefig('/tmp/test2.png')
         chart2.savefig('/tmp/test2.ps')

 #    pylab.show()
	# Copyright (c) 2005-2006 The Regents of The University of Michigan
	# All rights reserved.
	#
	# Redistribution and use in source and binary forms, with or without
	# modification, are permitted provided that the following conditions are
	# met: redistributions of source code must retain the above copyright
	# notice, this list of conditions and the following disclaimer;
	# redistributions in binary form must reproduce the above copyright
	# notice, this list of conditions and the following disclaimer in the
	# documentation and/or other materials provided with the distribution;
	# neither the name of the copyright holders nor the names of its
	# contributors may be used to endorse or promote products derived from
	# this software without specific prior written permission.
	#
	# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	# "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	# LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	# A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	# OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	# SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	# LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	# DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	# THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	# (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	# OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	import matplotlib, pylab
	from matplotlib.font_manager import FontProperties
	from matplotlib.numerix import array, arange, reshape, shape, transpose, zeros
	from matplotlib.numerix import Float
	from matplotlib.ticker import NullLocator
	from functools import reduce

	matplotlib.interactive(False)

	from .chart import ChartOptions

	class BarChart(ChartOptions):
	def __init__(self, default=None, **kwargs):
	super(BarChart, self).__init__(default, **kwargs)
	self.inputdata = None
	self.chartdata = None
	self.inputerr = None
	self.charterr = None

	def gen_colors(self, count):
	cmap = matplotlib.cm.get_cmap(self.colormap)
	if count == 1:
	return cmap([ 0.5 ])

	if count < 5:
	return cmap(arange(5) / float(4))[:count]

	return cmap(arange(count) / float(count - 1))

	# The input data format does not match the data format that the
	# graph function takes because it is intuitive. The conversion
	# from input data format to chart data format depends on the
	# dimensionality of the input data. Check here for the
	# dimensionality and correctness of the input data
	def set_data(self, data):
	if data is None:
	self.inputdata = None
	self.chartdata = None
	return

	data = array(data)
	dim = len(shape(data))
	if dim not in (1, 2, 3):
	raise AttributeError("Input data must be a 1, 2, or 3d matrix")
	self.inputdata = data

	# If the input data is a 1d matrix, then it describes a
	# standard bar chart.
	if dim == 1:
	self.chartdata = array([[data]])

	# If the input data is a 2d matrix, then it describes a bar
	# chart with groups. The matrix being an array of groups of
	# bars.
	if dim == 2:
	self.chartdata = transpose([data], axes=(2,0,1))

	# If the input data is a 3d matrix, then it describes an array
	# of groups of bars with each bar being an array of stacked
	# values.
	if dim == 3:
	self.chartdata = transpose(data, axes=(1,2,0))

	def get_data(self):
	return self.inputdata

	data = property(get_data, set_data)

	def set_err(self, err):
	if err is None:
	self.inputerr = None
	self.charterr = None
	return

	err = array(err)
	dim = len(shape(err))
	if dim not in (1, 2, 3):
	raise AttributeError("Input err must be a 1, 2, or 3d matrix")
	self.inputerr = err

	if dim == 1:
	self.charterr = array([[err]])

	if dim == 2:
	self.charterr = transpose([err], axes=(2,0,1))

	if dim == 3:
	self.charterr = transpose(err, axes=(1,2,0))

	def get_err(self):
	return self.inputerr

	err = property(get_err, set_err)

	# Graph the chart data.
	# Input is a 3d matrix that describes a plot that has multiple
	# groups, multiple bars in each group, and multiple values stacked
	# in each bar. The underlying bar() function expects a sequence of
	# bars in the same stack location and same group location, so the
	# organization of the matrix is that the inner most sequence
	# represents one of these bar groups, then those are grouped
	# together to make one full stack of bars in each group, and then
	# the outer most layer describes the groups. Here is an example
	# data set and how it gets plotted as a result.
	#
	# e.g. data = [[[10,11,12], [13,14,15], [16,17,18], [19,20,21]],
	# [[22,23,24], [25,26,27], [28,29,30], [31,32,33]]]
	#
	# will plot like this:
	#
	# 19 31 20 32 21 33
	# 16 28 17 29 18 30
	# 13 25 14 26 15 27
	# 10 22 11 23 12 24
	#
	# Because this arrangement is rather conterintuitive, the rearrange
	# function takes various matricies and arranges them to fit this
	# profile.
	#
	# This code deals with one of the dimensions in the matrix being
	# one wide.
	#
	def graph(self):
	if self.chartdata is None:
	raise AttributeError("Data not set for bar chart!")

	dim = len(shape(self.inputdata))
	cshape = shape(self.chartdata)
	if self.charterr is not None and shape(self.charterr) != cshape:
	raise AttributeError('Dimensions of error and data do not match')

	if dim == 1:
	colors = self.gen_colors(cshape[2])
	colors = [ [ colors ] * cshape[1] ] * cshape[0]

	if dim == 2:
	colors = self.gen_colors(cshape[0])
	colors = [ [ [ c ] * cshape[2] ] * cshape[1] for c in colors ]

	if dim == 3:
	colors = self.gen_colors(cshape[1])
	colors = [ [ [ c ] * cshape[2] for c in colors ] ] * cshape[0]

	colors = array(colors)

	self.figure = pylab.figure(figsize=self.chart_size)

	outer_axes = None
	inner_axes = None
	if self.xsubticks is not None:
	color = self.figure.get_facecolor()
	self.metaaxes = self.figure.add_axes(self.figure_size,
	axisbg=color, frameon=False)
	for tick in self.metaaxes.xaxis.majorTicks:
	tick.tick1On = False
	tick.tick2On = False
	self.metaaxes.set_yticklabels([])
	self.metaaxes.set_yticks([])
	size = [0] * 4
	size[0] = self.figure_size[0]
	size[1] = self.figure_size[1] + .12
	size[2] = self.figure_size[2]
	size[3] = self.figure_size[3] - .12
	self.axes = self.figure.add_axes(size)
	outer_axes = self.metaaxes
	inner_axes = self.axes
	else:
	self.axes = self.figure.add_axes(self.figure_size)
	outer_axes = self.axes
	inner_axes = self.axes

	bars_in_group = len(self.chartdata)

	width = 1.0 / ( bars_in_group + 1)
	center = width / 2

	bars = []
	for i,stackdata in enumerate(self.chartdata):
	bottom = array([0.0] * len(stackdata[0]), Float)
	stack = []
	for j,bardata in enumerate(stackdata):
	bardata = array(bardata)
	ind = arange(len(bardata)) + i * width + center
	yerr = None
	if self.charterr is not None:
	yerr = self.charterr[i][j]
	bar = self.axes.bar(ind, bardata, width, bottom=bottom,
	color=colors[i][j], yerr=yerr)
	if self.xsubticks is not None:
	self.metaaxes.bar(ind, [0] * len(bardata), width)
	stack.append(bar)
	bottom += bardata
	bars.append(stack)

	if self.xlabel is not None:
	outer_axes.set_xlabel(self.xlabel)

	if self.ylabel is not None:
	inner_axes.set_ylabel(self.ylabel)

	if self.yticks is not None:
	ymin, ymax = self.axes.get_ylim()
	nticks = float(len(self.yticks))
	ticks = arange(nticks) / (nticks - 1) * (ymax - ymin) + ymin
	inner_axes.set_yticks(ticks)
	inner_axes.set_yticklabels(self.yticks)
	elif self.ylim is not None:
	inner_axes.set_ylim(self.ylim)

	if self.xticks is not None:
	outer_axes.set_xticks(arange(cshape[2]) + .5)
	outer_axes.set_xticklabels(self.xticks)

	if self.xsubticks is not None:
	numticks = (cshape[0] + 1) * cshape[2]
	inner_axes.set_xticks(arange(numticks) * width + 2 * center)
	xsubticks = list(self.xsubticks) + [ '' ]
	inner_axes.set_xticklabels(xsubticks * cshape[2], fontsize=7,
	rotation=30)

	if self.legend is not None:
	if dim == 1:
	lbars = bars[0][0]
	if dim == 2:
	lbars = [ bars[i][0][0] for i in range(len(bars))]
	if dim == 3:
	number = len(bars[0])
	lbars = [ bars[0][number - j - 1][0] for j in range(number)]

	if self.fig_legend:
	self.figure.legend(lbars, self.legend, self.legend_loc,
	prop=FontProperties(size=self.legend_size))
	else:
	self.axes.legend(lbars, self.legend, self.legend_loc,
	prop=FontProperties(size=self.legend_size))

	if self.title is not None:
	self.axes.set_title(self.title)

	def savefig(self, name):
	self.figure.savefig(name)

	def savecsv(self, name):
	f = file(name, 'w')
	data = array(self.inputdata)
	dim = len(data.shape)

	if dim == 1:
	#if self.xlabel:
	# f.write(', '.join(list(self.xlabel)) + '\n')
	f.write(', '.join([ '%f' % val for val in data]) + '\n')
	if dim == 2:
	#if self.xlabel:
	# f.write(', '.join([''] + list(self.xlabel)) + '\n')
	for i,row in enumerate(data):
	ylabel = []
	#if self.ylabel:
	# ylabel = [ self.ylabel[i] ]
	f.write(', '.join(ylabel + [ '%f' % v for v in row]) + '\n')
	if dim == 3:
	f.write("don't do 3D csv files\n")
	pass

	f.close()

	if __name__ == '__main__':
	from random import randrange
	import random, sys

	dim = 3
	number = 5

	args = sys.argv[1:]
	if len(args) > 3:
	sys.exit("invalid number of arguments")
	elif len(args) > 0:
	myshape = [ int(x) for x in args ]
	else:
	myshape = [ 3, 4, 8 ]

	# generate a data matrix of the given shape
	size = reduce(lambda x,y: x*y, myshape)
	#data = [ random.randrange(size - i) + 10 for i in xrange(size) ]
	data = [ float(i)/100.0 for i in range(size) ]
	data = reshape(data, myshape)

	# setup some test bar charts
	if True:
	chart1 = BarChart()
	chart1.data = data

	chart1.xlabel = 'Benchmark'
	chart1.ylabel = 'Bandwidth (GBps)'
	chart1.legend = [ 'x%d' % x for x in range(myshape[-1]) ]
	chart1.xticks = [ 'xtick%d' % x for x in range(myshape[0]) ]
	chart1.title = 'this is the title'
	if len(myshape) > 2:
	chart1.xsubticks = [ '%d' % x for x in range(myshape[1]) ]
	chart1.graph()
	chart1.savefig('/tmp/test1.png')
	chart1.savefig('/tmp/test1.ps')
	chart1.savefig('/tmp/test1.eps')
	chart1.savecsv('/tmp/test1.csv')

	if False:
	chart2 = BarChart()
	chart2.data = data
	chart2.colormap = 'gray'
	chart2.graph()
	chart2.savefig('/tmp/test2.png')
	chart2.savefig('/tmp/test2.ps')

	# pylab.show()