x64/Tools/scripts/analyze_dxp.py - platform/prebuilts/python/windows-x86 - Git at Google

 #!/usr/bin/env python
 """
 Some helper functions to analyze the output of sys.getdxp() (which is
 only available if Python was built with -DDYNAMIC_EXECUTION_PROFILE).
 These will tell you which opcodes have been executed most frequently
 in the current process, and, if Python was also built with -DDXPAIRS,
 will tell you which instruction _pairs_ were executed most frequently,
 which may help in choosing new instructions.

 If Python was built without -DDYNAMIC_EXECUTION_PROFILE, importing
 this module will raise a RuntimeError.

 If you're running a script you want to profile, a simple way to get
 the common pairs is:

 $ PYTHONPATH=$PYTHONPATH:<python_srcdir>/Tools/scripts \
 ./python -i -O the_script.py --args
 ...
 > from analyze_dxp import *
 > s = render_common_pairs()
 > open('/tmp/some_file', 'w').write(s)
 """

 import copy
 import opcode
 import operator
 import sys
 import threading

 if not hasattr(sys, "getdxp"):
     raise RuntimeError("Can't import analyze_dxp: Python built without"
                        " -DDYNAMIC_EXECUTION_PROFILE.")


 _profile_lock = threading.RLock()
 _cumulative_profile = sys.getdxp()

 # If Python was built with -DDXPAIRS, sys.getdxp() returns a list of
 # lists of ints.  Otherwise it returns just a list of ints.
 def has_pairs(profile):
     """Returns True if the Python that produced the argument profile
     was built with -DDXPAIRS."""

     return len(profile) > 0 and isinstance(profile[0], list)


 def reset_profile():
     """Forgets any execution profile that has been gathered so far."""
     with _profile_lock:
         sys.getdxp()  # Resets the internal profile
         global _cumulative_profile
         _cumulative_profile = sys.getdxp()  # 0s out our copy.


 def merge_profile():
     """Reads sys.getdxp() and merges it into this module's cached copy.

     We need this because sys.getdxp() 0s itself every time it's called."""

     with _profile_lock:
         new_profile = sys.getdxp()
         if has_pairs(new_profile):
             for first_inst in range(len(_cumulative_profile)):
                 for second_inst in range(len(_cumulative_profile[first_inst])):
                     _cumulative_profile[first_inst][second_inst] += (
                         new_profile[first_inst][second_inst])
         else:
             for inst in range(len(_cumulative_profile)):
                 _cumulative_profile[inst] += new_profile[inst]


 def snapshot_profile():
     """Returns the cumulative execution profile until this call."""
     with _profile_lock:
         merge_profile()
         return copy.deepcopy(_cumulative_profile)


 def common_instructions(profile):
     """Returns the most common opcodes in order of descending frequency.

     The result is a list of tuples of the form
       (opcode, opname, # of occurrences)

     """
     if has_pairs(profile) and profile:
         inst_list = profile[-1]
     else:
         inst_list = profile
     result = [(op, opcode.opname[op], count)
               for op, count in enumerate(inst_list)
               if count > 0]
     result.sort(key=operator.itemgetter(2), reverse=True)
     return result


 def common_pairs(profile):
     """Returns the most common opcode pairs in order of descending frequency.

     The result is a list of tuples of the form
       ((1st opcode, 2nd opcode),
        (1st opname, 2nd opname),
        # of occurrences of the pair)

     """
     if not has_pairs(profile):
         return []
     result = [((op1, op2), (opcode.opname[op1], opcode.opname[op2]), count)
               # Drop the row of single-op profiles with [:-1]
               for op1, op1profile in enumerate(profile[:-1])
               for op2, count in enumerate(op1profile)
               if count > 0]
     result.sort(key=operator.itemgetter(2), reverse=True)
     return result


 def render_common_pairs(profile=None):
     """Renders the most common opcode pairs to a string in order of
     descending frequency.

     The result is a series of lines of the form:
       # of occurrences: ('1st opname', '2nd opname')

     """
     if profile is None:
         profile = snapshot_profile()
     def seq():
         for _, ops, count in common_pairs(profile):
             yield "%s: %s\n" % (count, ops)
     return ''.join(seq())
	#!/usr/bin/env python
	"""
	Some helper functions to analyze the output of sys.getdxp() (which is
	only available if Python was built with -DDYNAMIC_EXECUTION_PROFILE).
	These will tell you which opcodes have been executed most frequently
	in the current process, and, if Python was also built with -DDXPAIRS,
	will tell you which instruction _pairs_ were executed most frequently,
	which may help in choosing new instructions.

	If Python was built without -DDYNAMIC_EXECUTION_PROFILE, importing
	this module will raise a RuntimeError.

	If you're running a script you want to profile, a simple way to get
	the common pairs is:

	$ PYTHONPATH=$PYTHONPATH:<python_srcdir>/Tools/scripts \
	./python -i -O the_script.py --args
	...
	> from analyze_dxp import *
	> s = render_common_pairs()
	> open('/tmp/some_file', 'w').write(s)
	"""

	import copy
	import opcode
	import operator
	import sys
	import threading

	if not hasattr(sys, "getdxp"):
	raise RuntimeError("Can't import analyze_dxp: Python built without"
	" -DDYNAMIC_EXECUTION_PROFILE.")


	_profile_lock = threading.RLock()
	_cumulative_profile = sys.getdxp()

	# If Python was built with -DDXPAIRS, sys.getdxp() returns a list of
	# lists of ints. Otherwise it returns just a list of ints.
	def has_pairs(profile):
	"""Returns True if the Python that produced the argument profile
	was built with -DDXPAIRS."""

	return len(profile) > 0 and isinstance(profile[0], list)


	def reset_profile():
	"""Forgets any execution profile that has been gathered so far."""
	with _profile_lock:
	sys.getdxp() # Resets the internal profile
	global _cumulative_profile
	_cumulative_profile = sys.getdxp() # 0s out our copy.


	def merge_profile():
	"""Reads sys.getdxp() and merges it into this module's cached copy.

	We need this because sys.getdxp() 0s itself every time it's called."""

	with _profile_lock:
	new_profile = sys.getdxp()
	if has_pairs(new_profile):
	for first_inst in range(len(_cumulative_profile)):
	for second_inst in range(len(_cumulative_profile[first_inst])):
	_cumulative_profile[first_inst][second_inst] += (
	new_profile[first_inst][second_inst])
	else:
	for inst in range(len(_cumulative_profile)):
	_cumulative_profile[inst] += new_profile[inst]


	def snapshot_profile():
	"""Returns the cumulative execution profile until this call."""
	with _profile_lock:
	merge_profile()
	return copy.deepcopy(_cumulative_profile)


	def common_instructions(profile):
	"""Returns the most common opcodes in order of descending frequency.

	The result is a list of tuples of the form
	(opcode, opname, # of occurrences)

	"""
	if has_pairs(profile) and profile:
	inst_list = profile[-1]
	else:
	inst_list = profile
	result = [(op, opcode.opname[op], count)
	for op, count in enumerate(inst_list)
	if count > 0]
	result.sort(key=operator.itemgetter(2), reverse=True)
	return result


	def common_pairs(profile):
	"""Returns the most common opcode pairs in order of descending frequency.

	The result is a list of tuples of the form
	((1st opcode, 2nd opcode),
	(1st opname, 2nd opname),
	# of occurrences of the pair)

	"""
	if not has_pairs(profile):
	return []
	result = [((op1, op2), (opcode.opname[op1], opcode.opname[op2]), count)
	# Drop the row of single-op profiles with [:-1]
	for op1, op1profile in enumerate(profile[:-1])
	for op2, count in enumerate(op1profile)
	if count > 0]
	result.sort(key=operator.itemgetter(2), reverse=True)
	return result


	def render_common_pairs(profile=None):
	"""Renders the most common opcode pairs to a string in order of
	descending frequency.

	The result is a series of lines of the form:
	# of occurrences: ('1st opname', '2nd opname')

	"""
	if profile is None:
	profile = snapshot_profile()
	def seq():
	for _, ops, count in common_pairs(profile):
	yield "%s: %s\n" % (count, ops)
	return ''.join(seq())