llvm/utils/llvm-locstats/llvm-locstats.py - llvm-project - Git at Google

 #!/usr/bin/env python
 #
 # This is a tool that works like debug location coverage calculator.
 # It parses the llvm-dwarfdump --statistics output by reporting it
 # in a more human readable way.
 #

 from __future__ import print_function
 import argparse
 import os
 import sys
 from json import loads
 from math import ceil
 from collections import OrderedDict
 from subprocess import Popen, PIPE

 # Initialize the plot.
 def init_plot(plt):
   plt.title('Debug Location Statistics', fontweight='bold')
   plt.xlabel('location buckets')
   plt.ylabel('number of variables in the location buckets')
   plt.xticks(rotation=45, fontsize='x-small')
   plt.yticks()

 # Finalize the plot.
 def finish_plot(plt):
   plt.legend()
   plt.grid(color='grey', which='major', axis='y', linestyle='-', linewidth=0.3)
   plt.savefig('locstats.png')
   print('The plot was saved within "locstats.png".')

 # Holds the debug location statistics.
 class LocationStats:
   def __init__(self, file_name, variables_total, variables_total_locstats,
     variables_with_loc, variables_scope_bytes_covered, variables_scope_bytes,
     variables_coverage_map):
     self.file_name = file_name
     self.variables_total = variables_total
     self.variables_total_locstats = variables_total_locstats
     self.variables_with_loc = variables_with_loc
     self.scope_bytes_covered = variables_scope_bytes_covered
     self.scope_bytes = variables_scope_bytes
     self.variables_coverage_map = variables_coverage_map

   # Get the PC ranges coverage.
   def get_pc_coverage(self):
     pc_ranges_covered = int(ceil(self.scope_bytes_covered * 100.0) \
                 / self.scope_bytes)
     return pc_ranges_covered

   # Pretty print the debug location buckets.
   def pretty_print(self):
     if self.scope_bytes == 0:
       print ('No scope bytes found.')
       return -1

     pc_ranges_covered = self.get_pc_coverage()
     variables_coverage_per_map = {}
     for cov_bucket in coverage_buckets():
       variables_coverage_per_map[cov_bucket] = \
         int(ceil(self.variables_coverage_map[cov_bucket] * 100.0) \
                  / self.variables_total_locstats)

     print (' =================================================')
     print ('            Debug Location Statistics       ')
     print (' =================================================')
     print ('     cov%           samples         percentage(~)  ')
     print (' -------------------------------------------------')
     for cov_bucket in coverage_buckets():
       print ('   {0:10}     {1:8d}              {2:3d}%'. \
         format(cov_bucket, self.variables_coverage_map[cov_bucket], \
                variables_coverage_per_map[cov_bucket]))
     print (' =================================================')
     print (' -the number of debug variables processed: ' \
       + str(self.variables_total_locstats))
     print (' -PC ranges covered: ' + str(pc_ranges_covered) + '%')

     # Only if we are processing all the variables output the total
     # availability.
     if self.variables_total and self.variables_with_loc:
       total_availability = int(ceil(self.variables_with_loc * 100.0) \
                                     / self.variables_total)
       print (' -------------------------------------------------')
       print (' -total availability: ' + str(total_availability) + '%')
     print (' =================================================')

     return 0

   # Draw a plot representing the location buckets.
   def draw_plot(self):
     from matplotlib import pyplot as plt

     buckets = range(len(self.variables_coverage_map))
     plt.figure(figsize=(12, 8))
     init_plot(plt)
     plt.bar(buckets, self.variables_coverage_map.values(), align='center',
             tick_label=self.variables_coverage_map.keys(),
             label='variables of {}'.format(self.file_name))

     # Place the text box with the coverage info.
     pc_ranges_covered = self.get_pc_coverage()
     props = dict(boxstyle='round', facecolor='wheat', alpha=0.5)
     plt.text(0.02, 0.90, 'PC ranges covered: {}%'.format(pc_ranges_covered),
              transform=plt.gca().transAxes, fontsize=12,
              verticalalignment='top', bbox=props)

     finish_plot(plt)

   # Compare the two LocationStats objects and draw a plot showing
   # the difference.
   def draw_location_diff(self, locstats_to_compare):
     from matplotlib import pyplot as plt

     pc_ranges_covered = self.get_pc_coverage()
     pc_ranges_covered_to_compare = locstats_to_compare.get_pc_coverage()

     buckets = range(len(self.variables_coverage_map))
     buckets_to_compare = range(len(locstats_to_compare.variables_coverage_map))

     fig = plt.figure(figsize=(12, 8))
     ax = fig.add_subplot(111)
     init_plot(plt)

     comparison_keys = list(coverage_buckets())
     ax.bar(buckets, self.variables_coverage_map.values(), align='edge',
            width=0.4,
            label='variables of {}'.format(self.file_name))
     ax.bar(buckets_to_compare,
            locstats_to_compare.variables_coverage_map.values(),
            color='r', align='edge', width=-0.4,
            label='variables of {}'.format(locstats_to_compare.file_name))
     ax.set_xticks(range(len(comparison_keys)))
     ax.set_xticklabels(comparison_keys)

     props = dict(boxstyle='round', facecolor='wheat', alpha=0.5)
     plt.text(0.02, 0.88,
              '{} PC ranges covered: {}%'. \
              format(self.file_name, pc_ranges_covered),
              transform=plt.gca().transAxes, fontsize=12,
              verticalalignment='top', bbox=props)
     plt.text(0.02, 0.83,
              '{} PC ranges covered: {}%'. \
              format(locstats_to_compare.file_name,
                     pc_ranges_covered_to_compare),
              transform=plt.gca().transAxes, fontsize=12,
              verticalalignment='top', bbox=props)

     finish_plot(plt)

 # Define the location buckets.
 def coverage_buckets():
   yield '0%'
   yield '(0%,10%)'
   for start in range(10, 91, 10):
     yield '[{0}%,{1}%)'.format(start, start + 10)
   yield '100%'

 # Parse the JSON representing the debug statistics, and create a
 # LocationStats object.
 def parse_locstats(opts, binary):
   # These will be different due to different options enabled.
   variables_total = None
   variables_total_locstats = None
   variables_with_loc = None
   variables_scope_bytes_covered = None
   variables_scope_bytes = None
   variables_scope_bytes_entry_values = None
   variables_coverage_map = OrderedDict()

   # Get the directory of the LLVM tools.
   llvm_dwarfdump_cmd = os.path.join(os.path.dirname(__file__), \
                                     "llvm-dwarfdump")
   # The statistics llvm-dwarfdump option.
   llvm_dwarfdump_stats_opt = "--statistics"

   # Generate the stats with the llvm-dwarfdump.
   subproc = Popen([llvm_dwarfdump_cmd, llvm_dwarfdump_stats_opt, binary], \
                   stdin=PIPE, stdout=PIPE, stderr=PIPE, \
                   universal_newlines = True)
   cmd_stdout, cmd_stderr = subproc.communicate()

   # Get the JSON and parse it.
   json_parsed = None

   try:
     json_parsed = loads(cmd_stdout)
   except:
     print ('error: No valid llvm-dwarfdump statistics found.')
     sys.exit(1)

   # TODO: Parse the statistics Version from JSON.

   if opts.only_variables:
     # Read the JSON only for local variables.
     variables_total_locstats = \
       json_parsed['#local vars processed by location statistics']
     variables_scope_bytes_covered = \
       json_parsed['sum_all_local_vars(#bytes in parent scope covered' \
                   ' by DW_AT_location)']
     variables_scope_bytes = \
       json_parsed['sum_all_local_vars(#bytes in parent scope)']
     if not opts.ignore_debug_entry_values:
       for cov_bucket in coverage_buckets():
         cov_category = "#local vars with {} of parent scope covered " \
                        "by DW_AT_location".format(cov_bucket)
         variables_coverage_map[cov_bucket] = json_parsed[cov_category]
     else:
       variables_scope_bytes_entry_values = \
         json_parsed['sum_all_local_vars(#bytes in parent scope ' \
                     'covered by DW_OP_entry_value)']
       variables_scope_bytes_covered = variables_scope_bytes_covered \
          - variables_scope_bytes_entry_values
       for cov_bucket in coverage_buckets():
         cov_category = \
           "#local vars - entry values with {} of parent scope " \
           "covered by DW_AT_location".format(cov_bucket)
         variables_coverage_map[cov_bucket] = json_parsed[cov_category]
   elif opts.only_formal_parameters:
     # Read the JSON only for formal parameters.
     variables_total_locstats = \
       json_parsed['#params processed by location statistics']
     variables_scope_bytes_covered = \
       json_parsed['sum_all_params(#bytes in parent scope covered ' \
                   'by DW_AT_location)']
     variables_scope_bytes = \
       json_parsed['sum_all_params(#bytes in parent scope)']
     if not opts.ignore_debug_entry_values:
       for cov_bucket in coverage_buckets():
         cov_category = "#params with {} of parent scope covered " \
                        "by DW_AT_location".format(cov_bucket)
         variables_coverage_map[cov_bucket] = json_parsed[cov_category]
     else:
       variables_scope_bytes_entry_values = \
         json_parsed['sum_all_params(#bytes in parent scope covered ' \
                     'by DW_OP_entry_value)']
       variables_scope_bytes_covered = variables_scope_bytes_covered \
         - variables_scope_bytes_entry_values
       for cov_bucket in coverage_buckets():
         cov_category = \
           "#params - entry values with {} of parent scope covered" \
           " by DW_AT_location".format(cov_bucket)
         variables_coverage_map[cov_bucket] = json_parsed[cov_category]
   else:
     # Read the JSON for both local variables and formal parameters.
     variables_total = \
       json_parsed['#source variables']
     variables_with_loc = json_parsed['#source variables with location']
     variables_total_locstats = \
       json_parsed['#variables processed by location statistics']
     variables_scope_bytes_covered = \
       json_parsed['sum_all_variables(#bytes in parent scope covered ' \
                   'by DW_AT_location)']
     variables_scope_bytes = \
       json_parsed['sum_all_variables(#bytes in parent scope)']
     if not opts.ignore_debug_entry_values:
       for cov_bucket in coverage_buckets():
         cov_category = "#variables with {} of parent scope covered " \
                        "by DW_AT_location".format(cov_bucket)
         variables_coverage_map[cov_bucket] = json_parsed[cov_category]
     else:
       variables_scope_bytes_entry_values = \
         json_parsed['sum_all_variables(#bytes in parent scope covered ' \
                     'by DW_OP_entry_value)']
       variables_scope_bytes_covered = variables_scope_bytes_covered \
         - variables_scope_bytes_entry_values
       for cov_bucket in coverage_buckets():
         cov_category = \
           "#variables - entry values with {} of parent scope covered " \
           "by DW_AT_location".format(cov_bucket)
         variables_coverage_map[cov_bucket] = json_parsed[cov_category]

   return LocationStats(binary, variables_total, variables_total_locstats,
                        variables_with_loc, variables_scope_bytes_covered,
                        variables_scope_bytes, variables_coverage_map)

 # Parse the program arguments.
 def parse_program_args(parser):
   parser.add_argument('--only-variables', action='store_true', default=False,
             help='calculate the location statistics only for local variables')
   parser.add_argument('--only-formal-parameters', action='store_true',
             default=False,
             help='calculate the location statistics only for formal parameters')
   parser.add_argument('--ignore-debug-entry-values', action='store_true',
             default=False,
             help='ignore the location statistics on locations with '
                  'entry values')
   parser.add_argument('--draw-plot', action='store_true', default=False,
             help='show histogram of location buckets generated (requires '
                  'matplotlib)')
   parser.add_argument('--compare', action='store_true', default=False,
             help='compare the debug location coverage on two files provided, '
                  'and draw a plot showing the difference  (requires '
                  'matplotlib)')
   parser.add_argument('file_names', nargs='+', type=str, help='file to process')

   return parser.parse_args()

 # Verify that the program inputs meet the requirements.
 def verify_program_inputs(opts):
   if len(sys.argv) < 2:
     print ('error: Too few arguments.')
     return False

   if opts.only_variables and opts.only_formal_parameters:
     print ('error: Please use just one --only* option.')
     return False

   if not opts.compare and len(opts.file_names) != 1:
     print ('error: Please specify only one file to process.')
     return False

   if opts.compare and len(opts.file_names) != 2:
     print ('error: Please specify two files to process.')
     return False

   if opts.draw_plot or opts.compare:
     try:
       import matplotlib
     except ImportError:
       print('error: matplotlib not found.')
       return False

   return True

 def Main():
   parser = argparse.ArgumentParser()
   opts = parse_program_args(parser)

   if not verify_program_inputs(opts):
     parser.print_help()
     sys.exit(1)

   binary_file = opts.file_names[0]
   locstats = parse_locstats(opts, binary_file)

   if not opts.compare:
     if opts.draw_plot:
       # Draw a histogram representing the location buckets.
       locstats.draw_plot()
     else:
       # Pretty print collected info on the standard output.
       if locstats.pretty_print() == -1:
         sys.exit(0)
   else:
     binary_file_to_compare = opts.file_names[1]
     locstats_to_compare = parse_locstats(opts, binary_file_to_compare)
     # Draw a plot showing the difference in debug location coverage between
     # two files.
     locstats.draw_location_diff(locstats_to_compare)

 if __name__ == '__main__':
   Main()
   sys.exit(0)
	#!/usr/bin/env python
	#
	# This is a tool that works like debug location coverage calculator.
	# It parses the llvm-dwarfdump --statistics output by reporting it
	# in a more human readable way.
	#

	from __future__ import print_function
	import argparse
	import os
	import sys
	from json import loads
	from math import ceil
	from collections import OrderedDict
	from subprocess import Popen, PIPE

	# Initialize the plot.
	def init_plot(plt):
	plt.title('Debug Location Statistics', fontweight='bold')
	plt.xlabel('location buckets')
	plt.ylabel('number of variables in the location buckets')
	plt.xticks(rotation=45, fontsize='x-small')
	plt.yticks()

	# Finalize the plot.
	def finish_plot(plt):
	plt.legend()
	plt.grid(color='grey', which='major', axis='y', linestyle='-', linewidth=0.3)
	plt.savefig('locstats.png')
	print('The plot was saved within "locstats.png".')

	# Holds the debug location statistics.
	class LocationStats:
	def __init__(self, file_name, variables_total, variables_total_locstats,
	variables_with_loc, variables_scope_bytes_covered, variables_scope_bytes,
	variables_coverage_map):
	self.file_name = file_name
	self.variables_total = variables_total
	self.variables_total_locstats = variables_total_locstats
	self.variables_with_loc = variables_with_loc
	self.scope_bytes_covered = variables_scope_bytes_covered
	self.scope_bytes = variables_scope_bytes
	self.variables_coverage_map = variables_coverage_map

	# Get the PC ranges coverage.
	def get_pc_coverage(self):
	pc_ranges_covered = int(ceil(self.scope_bytes_covered * 100.0) \
	/ self.scope_bytes)
	return pc_ranges_covered

	# Pretty print the debug location buckets.
	def pretty_print(self):
	if self.scope_bytes == 0:
	print ('No scope bytes found.')
	return -1

	pc_ranges_covered = self.get_pc_coverage()
	variables_coverage_per_map = {}
	for cov_bucket in coverage_buckets():
	variables_coverage_per_map[cov_bucket] = \
	int(ceil(self.variables_coverage_map[cov_bucket] * 100.0) \
	/ self.variables_total_locstats)

	print (' =================================================')
	print (' Debug Location Statistics ')
	print (' =================================================')
	print (' cov% samples percentage(~) ')
	print (' -------------------------------------------------')
	for cov_bucket in coverage_buckets():
	print (' {0:10} {1:8d} {2:3d}%'. \
	format(cov_bucket, self.variables_coverage_map[cov_bucket], \
	variables_coverage_per_map[cov_bucket]))
	print (' =================================================')
	print (' -the number of debug variables processed: ' \
	+ str(self.variables_total_locstats))
	print (' -PC ranges covered: ' + str(pc_ranges_covered) + '%')

	# Only if we are processing all the variables output the total
	# availability.
	if self.variables_total and self.variables_with_loc:
	total_availability = int(ceil(self.variables_with_loc * 100.0) \
	/ self.variables_total)
	print (' -------------------------------------------------')
	print (' -total availability: ' + str(total_availability) + '%')
	print (' =================================================')

	return 0

	# Draw a plot representing the location buckets.
	def draw_plot(self):
	from matplotlib import pyplot as plt

	buckets = range(len(self.variables_coverage_map))
	plt.figure(figsize=(12, 8))
	init_plot(plt)
	plt.bar(buckets, self.variables_coverage_map.values(), align='center',
	tick_label=self.variables_coverage_map.keys(),
	label='variables of {}'.format(self.file_name))

	# Place the text box with the coverage info.
	pc_ranges_covered = self.get_pc_coverage()
	props = dict(boxstyle='round', facecolor='wheat', alpha=0.5)
	plt.text(0.02, 0.90, 'PC ranges covered: {}%'.format(pc_ranges_covered),
	transform=plt.gca().transAxes, fontsize=12,
	verticalalignment='top', bbox=props)

	finish_plot(plt)

	# Compare the two LocationStats objects and draw a plot showing
	# the difference.
	def draw_location_diff(self, locstats_to_compare):
	from matplotlib import pyplot as plt

	pc_ranges_covered = self.get_pc_coverage()
	pc_ranges_covered_to_compare = locstats_to_compare.get_pc_coverage()

	buckets = range(len(self.variables_coverage_map))
	buckets_to_compare = range(len(locstats_to_compare.variables_coverage_map))

	fig = plt.figure(figsize=(12, 8))
	ax = fig.add_subplot(111)
	init_plot(plt)

	comparison_keys = list(coverage_buckets())
	ax.bar(buckets, self.variables_coverage_map.values(), align='edge',
	width=0.4,
	label='variables of {}'.format(self.file_name))
	ax.bar(buckets_to_compare,
	locstats_to_compare.variables_coverage_map.values(),
	color='r', align='edge', width=-0.4,
	label='variables of {}'.format(locstats_to_compare.file_name))
	ax.set_xticks(range(len(comparison_keys)))
	ax.set_xticklabels(comparison_keys)

	props = dict(boxstyle='round', facecolor='wheat', alpha=0.5)
	plt.text(0.02, 0.88,
	'{} PC ranges covered: {}%'. \
	format(self.file_name, pc_ranges_covered),
	transform=plt.gca().transAxes, fontsize=12,
	verticalalignment='top', bbox=props)
	plt.text(0.02, 0.83,
	'{} PC ranges covered: {}%'. \
	format(locstats_to_compare.file_name,
	pc_ranges_covered_to_compare),
	transform=plt.gca().transAxes, fontsize=12,
	verticalalignment='top', bbox=props)

	finish_plot(plt)

	# Define the location buckets.
	def coverage_buckets():
	yield '0%'
	yield '(0%,10%)'
	for start in range(10, 91, 10):
	yield '[{0}%,{1}%)'.format(start, start + 10)
	yield '100%'

	# Parse the JSON representing the debug statistics, and create a
	# LocationStats object.
	def parse_locstats(opts, binary):
	# These will be different due to different options enabled.
	variables_total = None
	variables_total_locstats = None
	variables_with_loc = None
	variables_scope_bytes_covered = None
	variables_scope_bytes = None
	variables_scope_bytes_entry_values = None
	variables_coverage_map = OrderedDict()

	# Get the directory of the LLVM tools.
	llvm_dwarfdump_cmd = os.path.join(os.path.dirname(__file__), \
	"llvm-dwarfdump")
	# The statistics llvm-dwarfdump option.
	llvm_dwarfdump_stats_opt = "--statistics"

	# Generate the stats with the llvm-dwarfdump.
	subproc = Popen([llvm_dwarfdump_cmd, llvm_dwarfdump_stats_opt, binary], \
	stdin=PIPE, stdout=PIPE, stderr=PIPE, \
	universal_newlines = True)
	cmd_stdout, cmd_stderr = subproc.communicate()

	# Get the JSON and parse it.
	json_parsed = None

	try:
	json_parsed = loads(cmd_stdout)
	except:
	print ('error: No valid llvm-dwarfdump statistics found.')
	sys.exit(1)

	# TODO: Parse the statistics Version from JSON.

	if opts.only_variables:
	# Read the JSON only for local variables.
	variables_total_locstats = \
	json_parsed['#local vars processed by location statistics']
	variables_scope_bytes_covered = \
	json_parsed['sum_all_local_vars(#bytes in parent scope covered' \
	' by DW_AT_location)']
	variables_scope_bytes = \
	json_parsed['sum_all_local_vars(#bytes in parent scope)']
	if not opts.ignore_debug_entry_values:
	for cov_bucket in coverage_buckets():
	cov_category = "#local vars with {} of parent scope covered " \
	"by DW_AT_location".format(cov_bucket)
	variables_coverage_map[cov_bucket] = json_parsed[cov_category]
	else:
	variables_scope_bytes_entry_values = \
	json_parsed['sum_all_local_vars(#bytes in parent scope ' \
	'covered by DW_OP_entry_value)']
	variables_scope_bytes_covered = variables_scope_bytes_covered \
	- variables_scope_bytes_entry_values
	for cov_bucket in coverage_buckets():
	cov_category = \
	"#local vars - entry values with {} of parent scope " \
	"covered by DW_AT_location".format(cov_bucket)
	variables_coverage_map[cov_bucket] = json_parsed[cov_category]
	elif opts.only_formal_parameters:
	# Read the JSON only for formal parameters.
	variables_total_locstats = \
	json_parsed['#params processed by location statistics']
	variables_scope_bytes_covered = \
	json_parsed['sum_all_params(#bytes in parent scope covered ' \
	'by DW_AT_location)']
	variables_scope_bytes = \
	json_parsed['sum_all_params(#bytes in parent scope)']
	if not opts.ignore_debug_entry_values:
	for cov_bucket in coverage_buckets():
	cov_category = "#params with {} of parent scope covered " \
	"by DW_AT_location".format(cov_bucket)
	variables_coverage_map[cov_bucket] = json_parsed[cov_category]
	else:
	variables_scope_bytes_entry_values = \
	json_parsed['sum_all_params(#bytes in parent scope covered ' \
	'by DW_OP_entry_value)']
	variables_scope_bytes_covered = variables_scope_bytes_covered \
	- variables_scope_bytes_entry_values
	for cov_bucket in coverage_buckets():
	cov_category = \
	"#params - entry values with {} of parent scope covered" \
	" by DW_AT_location".format(cov_bucket)
	variables_coverage_map[cov_bucket] = json_parsed[cov_category]
	else:
	# Read the JSON for both local variables and formal parameters.
	variables_total = \
	json_parsed['#source variables']
	variables_with_loc = json_parsed['#source variables with location']
	variables_total_locstats = \
	json_parsed['#variables processed by location statistics']
	variables_scope_bytes_covered = \
	json_parsed['sum_all_variables(#bytes in parent scope covered ' \
	'by DW_AT_location)']
	variables_scope_bytes = \
	json_parsed['sum_all_variables(#bytes in parent scope)']
	if not opts.ignore_debug_entry_values:
	for cov_bucket in coverage_buckets():
	cov_category = "#variables with {} of parent scope covered " \
	"by DW_AT_location".format(cov_bucket)
	variables_coverage_map[cov_bucket] = json_parsed[cov_category]
	else:
	variables_scope_bytes_entry_values = \
	json_parsed['sum_all_variables(#bytes in parent scope covered ' \
	'by DW_OP_entry_value)']
	variables_scope_bytes_covered = variables_scope_bytes_covered \
	- variables_scope_bytes_entry_values
	for cov_bucket in coverage_buckets():
	cov_category = \
	"#variables - entry values with {} of parent scope covered " \
	"by DW_AT_location".format(cov_bucket)
	variables_coverage_map[cov_bucket] = json_parsed[cov_category]

	return LocationStats(binary, variables_total, variables_total_locstats,
	variables_with_loc, variables_scope_bytes_covered,
	variables_scope_bytes, variables_coverage_map)

	# Parse the program arguments.
	def parse_program_args(parser):
	parser.add_argument('--only-variables', action='store_true', default=False,
	help='calculate the location statistics only for local variables')
	parser.add_argument('--only-formal-parameters', action='store_true',
	default=False,
	help='calculate the location statistics only for formal parameters')
	parser.add_argument('--ignore-debug-entry-values', action='store_true',
	default=False,
	help='ignore the location statistics on locations with '
	'entry values')
	parser.add_argument('--draw-plot', action='store_true', default=False,
	help='show histogram of location buckets generated (requires '
	'matplotlib)')
	parser.add_argument('--compare', action='store_true', default=False,
	help='compare the debug location coverage on two files provided, '
	'and draw a plot showing the difference (requires '
	'matplotlib)')
	parser.add_argument('file_names', nargs='+', type=str, help='file to process')

	return parser.parse_args()

	# Verify that the program inputs meet the requirements.
	def verify_program_inputs(opts):
	if len(sys.argv) < 2:
	print ('error: Too few arguments.')
	return False

	if opts.only_variables and opts.only_formal_parameters:
	print ('error: Please use just one --only* option.')
	return False

	if not opts.compare and len(opts.file_names) != 1:
	print ('error: Please specify only one file to process.')
	return False

	if opts.compare and len(opts.file_names) != 2:
	print ('error: Please specify two files to process.')
	return False

	if opts.draw_plot or opts.compare:
	try:
	import matplotlib
	except ImportError:
	print('error: matplotlib not found.')
	return False

	return True

	def Main():
	parser = argparse.ArgumentParser()
	opts = parse_program_args(parser)

	if not verify_program_inputs(opts):
	parser.print_help()
	sys.exit(1)

	binary_file = opts.file_names[0]
	locstats = parse_locstats(opts, binary_file)

	if not opts.compare:
	if opts.draw_plot:
	# Draw a histogram representing the location buckets.
	locstats.draw_plot()
	else:
	# Pretty print collected info on the standard output.
	if locstats.pretty_print() == -1:
	sys.exit(0)
	else:
	binary_file_to_compare = opts.file_names[1]
	locstats_to_compare = parse_locstats(opts, binary_file_to_compare)
	# Draw a plot showing the difference in debug location coverage between
	# two files.
	locstats.draw_location_diff(locstats_to_compare)

	if __name__ == '__main__':
	Main()
	sys.exit(0)