#!/usr/bin/env python # # Copyright 2008-2009 Jose Fonseca # # This program 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 3 of the License, or # (at your option) any later version. # # 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 Lesser General Public License for more details. # # You should have received a copy of the GNU Lesser General Public License # along with this program. If not, see . # """Generate a dot graph from the output of several profilers.""" __author__ = "Jose Fonseca" __version__ = "1.0" import sys import math import os.path import re import textwrap import optparse import xml.parsers.expat try: # Debugging helper module import debug except ImportError: pass def times(x): return u"%u\xd7" % (x,) def percentage(p): return "%.02f%%" % (p*100.0,) def add(a, b): return a + b def equal(a, b): if a == b: return a else: return None def fail(a, b): assert False tol = 2 ** -23 def ratio(numerator, denominator): try: ratio = float(numerator)/float(denominator) except ZeroDivisionError: # 0/0 is undefined, but 1.0 yields more useful results return 1.0 if ratio < 0.0: if ratio < -tol: sys.stderr.write('warning: negative ratio (%s/%s)\n' % (numerator, denominator)) return 0.0 if ratio > 1.0: if ratio > 1.0 + tol: sys.stderr.write('warning: ratio greater than one (%s/%s)\n' % (numerator, denominator)) return 1.0 return ratio class UndefinedEvent(Exception): """Raised when attempting to get an event which is undefined.""" def __init__(self, event): Exception.__init__(self) self.event = event def __str__(self): return 'unspecified event %s' % self.event.name class Event(object): """Describe a kind of event, and its basic operations.""" def __init__(self, name, null, aggregator, formatter = str): self.name = name self._null = null self._aggregator = aggregator self._formatter = formatter def __eq__(self, other): return self is other def __hash__(self): return id(self) def null(self): return self._null def aggregate(self, val1, val2): """Aggregate two event values.""" assert val1 is not None assert val2 is not None return self._aggregator(val1, val2) def format(self, val): """Format an event value.""" assert val is not None return self._formatter(val) CALLS = Event("Calls", 0, add, times) SAMPLES = Event("Samples", 0, add) SAMPLES2 = Event("Samples", 0, add) TIME = Event("Time", 0.0, add, lambda x: '(' + str(x) + ')') TIME_RATIO = Event("Time ratio", 0.0, add, lambda x: '(' + percentage(x) + ')') TOTAL_TIME = Event("Total time", 0.0, fail) TOTAL_TIME_RATIO = Event("Total time ratio", 0.0, fail, percentage) class Object(object): """Base class for all objects in profile which can store events.""" def __init__(self, events=None): if events is None: self.events = {} else: self.events = events def __hash__(self): return id(self) def __eq__(self, other): return self is other def __contains__(self, event): return event in self.events def __getitem__(self, event): try: return self.events[event] except KeyError: raise UndefinedEvent(event) def __setitem__(self, event, value): if value is None: if event in self.events: del self.events[event] else: self.events[event] = value class Call(Object): """A call between functions. There should be at most one call object for every pair of functions. """ def __init__(self, callee_id): Object.__init__(self) self.callee_id = callee_id self.ratio = None self.weight = None class Function(Object): """A function.""" def __init__(self, id, name): Object.__init__(self) self.id = id self.name = name self.module = None self.process = None self.calls = {} self.called = None self.weight = None self.cycle = None def add_call(self, call): if call.callee_id in self.calls: sys.stderr.write('warning: overwriting call from function %s to %s\n' % (str(self.id), str(call.callee_id))) self.calls[call.callee_id] = call # TODO: write utility functions def __repr__(self): return self.name class Cycle(Object): """A cycle made from recursive function calls.""" def __init__(self): Object.__init__(self) # XXX: Do cycles need an id? self.functions = set() def add_function(self, function): assert function not in self.functions self.functions.add(function) # XXX: Aggregate events? if function.cycle is not None: for other in function.cycle.functions: if function not in self.functions: self.add_function(other) function.cycle = self class Profile(Object): """The whole profile.""" def __init__(self): Object.__init__(self) self.functions = {} self.cycles = [] def add_function(self, function): if function.id in self.functions: sys.stderr.write('warning: overwriting function %s (id %s)\n' % (function.name, str(function.id))) self.functions[function.id] = function def add_cycle(self, cycle): self.cycles.append(cycle) def validate(self): """Validate the edges.""" for function in self.functions.itervalues(): for callee_id in function.calls.keys(): assert function.calls[callee_id].callee_id == callee_id if callee_id not in self.functions: sys.stderr.write('warning: call to undefined function %s from function %s\n' % (str(callee_id), function.name)) del function.calls[callee_id] def find_cycles(self): """Find cycles using Tarjan's strongly connected components algorithm.""" # Apply the Tarjan's algorithm successively until all functions are visited visited = set() for function in self.functions.itervalues(): if function not in visited: self._tarjan(function, 0, [], {}, {}, visited) cycles = [] for function in self.functions.itervalues(): if function.cycle is not None and function.cycle not in cycles: cycles.append(function.cycle) self.cycles = cycles if 0: for cycle in cycles: sys.stderr.write("Cycle:\n") for member in cycle.functions: sys.stderr.write("\tFunction %s\n" % member.name) def _tarjan(self, function, order, stack, orders, lowlinks, visited): """Tarjan's strongly connected components algorithm. See also: - http://en.wikipedia.org/wiki/Tarjan's_strongly_connected_components_algorithm """ visited.add(function) orders[function] = order lowlinks[function] = order order += 1 pos = len(stack) stack.append(function) for call in function.calls.itervalues(): callee = self.functions[call.callee_id] # TODO: use a set to optimize lookup if callee not in orders: order = self._tarjan(callee, order, stack, orders, lowlinks, visited) lowlinks[function] = min(lowlinks[function], lowlinks[callee]) elif callee in stack: lowlinks[function] = min(lowlinks[function], orders[callee]) if lowlinks[function] == orders[function]: # Strongly connected component found members = stack[pos:] del stack[pos:] if len(members) > 1: cycle = Cycle() for member in members: cycle.add_function(member) return order def call_ratios(self, event): # Aggregate for incoming calls cycle_totals = {} for cycle in self.cycles: cycle_totals[cycle] = 0.0 function_totals = {} for function in self.functions.itervalues(): function_totals[function] = 0.0 for function in self.functions.itervalues(): for call in function.calls.itervalues(): if call.callee_id != function.id: callee = self.functions[call.callee_id] function_totals[callee] += call[event] if callee.cycle is not None and callee.cycle is not function.cycle: cycle_totals[callee.cycle] += call[event] # Compute the ratios for function in self.functions.itervalues(): for call in function.calls.itervalues(): assert call.ratio is None if call.callee_id != function.id: callee = self.functions[call.callee_id] if callee.cycle is not None and callee.cycle is not function.cycle: total = cycle_totals[callee.cycle] else: total = function_totals[callee] call.ratio = ratio(call[event], total) def integrate(self, outevent, inevent): """Propagate function time ratio allong the function calls. Must be called after finding the cycles. See also: - http://citeseer.ist.psu.edu/graham82gprof.html """ # Sanity checking assert outevent not in self for function in self.functions.itervalues(): assert outevent not in function assert inevent in function for call in function.calls.itervalues(): assert outevent not in call if call.callee_id != function.id: assert call.ratio is not None # Aggregate the input for each cycle for cycle in self.cycles: total = inevent.null() for function in self.functions.itervalues(): total = inevent.aggregate(total, function[inevent]) self[inevent] = total # Integrate along the edges total = inevent.null() for function in self.functions.itervalues(): total = inevent.aggregate(total, function[inevent]) self._integrate_function(function, outevent, inevent) self[outevent] = total def _integrate_function(self, function, outevent, inevent): if function.cycle is not None: return self._integrate_cycle(function.cycle, outevent, inevent) else: if outevent not in function: total = function[inevent] for call in function.calls.itervalues(): if call.callee_id != function.id: total += self._integrate_call(call, outevent, inevent) function[outevent] = total return function[outevent] def _integrate_call(self, call, outevent, inevent): assert outevent not in call assert call.ratio is not None callee = self.functions[call.callee_id] subtotal = call.ratio *self._integrate_function(callee, outevent, inevent) call[outevent] = subtotal return subtotal def _integrate_cycle(self, cycle, outevent, inevent): if outevent not in cycle: # Compute the outevent for the whole cycle total = inevent.null() for member in cycle.functions: subtotal = member[inevent] for call in member.calls.itervalues(): callee = self.functions[call.callee_id] if callee.cycle is not cycle: subtotal += self._integrate_call(call, outevent, inevent) total += subtotal cycle[outevent] = total # Compute the time propagated to callers of this cycle callees = {} for function in self.functions.itervalues(): if function.cycle is not cycle: for call in function.calls.itervalues(): callee = self.functions[call.callee_id] if callee.cycle is cycle: try: callees[callee] += call.ratio except KeyError: callees[callee] = call.ratio for member in cycle.functions: member[outevent] = outevent.null() for callee, call_ratio in callees.iteritems(): ranks = {} call_ratios = {} partials = {} self._rank_cycle_function(cycle, callee, 0, ranks) self._call_ratios_cycle(cycle, callee, ranks, call_ratios, set()) partial = self._integrate_cycle_function(cycle, callee, call_ratio, partials, ranks, call_ratios, outevent, inevent) assert partial == max(partials.values()) assert not total or abs(1.0 - partial/(call_ratio*total)) <= 0.001 return cycle[outevent] def _rank_cycle_function(self, cycle, function, rank, ranks): if function not in ranks or ranks[function] > rank: ranks[function] = rank for call in function.calls.itervalues(): if call.callee_id != function.id: callee = self.functions[call.callee_id] if callee.cycle is cycle: self._rank_cycle_function(cycle, callee, rank + 1, ranks) def _call_ratios_cycle(self, cycle, function, ranks, call_ratios, visited): if function not in visited: visited.add(function) for call in function.calls.itervalues(): if call.callee_id != function.id: callee = self.functions[call.callee_id] if callee.cycle is cycle: if ranks[callee] > ranks[function]: call_ratios[callee] = call_ratios.get(callee, 0.0) + call.ratio self._call_ratios_cycle(cycle, callee, ranks, call_ratios, visited) def _integrate_cycle_function(self, cycle, function, partial_ratio, partials, ranks, call_ratios, outevent, inevent): if function not in partials: partial = partial_ratio*function[inevent] for call in function.calls.itervalues(): if call.callee_id != function.id: callee = self.functions[call.callee_id] if callee.cycle is not cycle: assert outevent in call partial += partial_ratio*call[outevent] else: if ranks[callee] > ranks[function]: callee_partial = self._integrate_cycle_function(cycle, callee, partial_ratio, partials, ranks, call_ratios, outevent, inevent) call_ratio = ratio(call.ratio, call_ratios[callee]) call_partial = call_ratio*callee_partial try: call[outevent] += call_partial except UndefinedEvent: call[outevent] = call_partial partial += call_partial partials[function] = partial try: function[outevent] += partial except UndefinedEvent: function[outevent] = partial return partials[function] def aggregate(self, event): """Aggregate an event for the whole profile.""" total = event.null() for function in self.functions.itervalues(): try: total = event.aggregate(total, function[event]) except UndefinedEvent: return self[event] = total def ratio(self, outevent, inevent): assert outevent not in self assert inevent in self for function in self.functions.itervalues(): assert outevent not in function assert inevent in function function[outevent] = ratio(function[inevent], self[inevent]) for call in function.calls.itervalues(): assert outevent not in call if inevent in call: call[outevent] = ratio(call[inevent], self[inevent]) self[outevent] = 1.0 def prune(self, node_thres, edge_thres): """Prune the profile""" # compute the prune ratios for function in self.functions.itervalues(): try: function.weight = function[TOTAL_TIME_RATIO] except UndefinedEvent: pass for call in function.calls.itervalues(): callee = self.functions[call.callee_id] if TOTAL_TIME_RATIO in call: # handle exact cases first call.weight = call[TOTAL_TIME_RATIO] else: try: # make a safe estimate call.weight = min(function[TOTAL_TIME_RATIO], callee[TOTAL_TIME_RATIO]) except UndefinedEvent: pass # prune the nodes for function_id in self.functions.keys(): function = self.functions[function_id] if function.weight is not None: if function.weight < node_thres: del self.functions[function_id] # prune the egdes for function in self.functions.itervalues(): for callee_id in function.calls.keys(): call = function.calls[callee_id] if callee_id not in self.functions or call.weight is not None and call.weight < edge_thres: del function.calls[callee_id] def dump(self): for function in self.functions.itervalues(): sys.stderr.write('Function %s:\n' % (function.name,)) self._dump_events(function.events) for call in function.calls.itervalues(): callee = self.functions[call.callee_id] sys.stderr.write(' Call %s:\n' % (callee.name,)) self._dump_events(call.events) for cycle in self.cycles: sys.stderr.write('Cycle:\n') self._dump_events(cycle.events) for function in cycle.functions: sys.stderr.write(' Function %s\n' % (function.name,)) def _dump_events(self, events): for event, value in events.iteritems(): sys.stderr.write(' %s: %s\n' % (event.name, event.format(value))) class Struct: """Masquerade a dictionary with a structure-like behavior.""" def __init__(self, attrs = None): if attrs is None: attrs = {} self.__dict__['_attrs'] = attrs def __getattr__(self, name): try: return self._attrs[name] except KeyError: raise AttributeError(name) def __setattr__(self, name, value): self._attrs[name] = value def __str__(self): return str(self._attrs) def __repr__(self): return repr(self._attrs) class ParseError(Exception): """Raised when parsing to signal mismatches.""" def __init__(self, msg, line): self.msg = msg # TODO: store more source line information self.line = line def __str__(self): return '%s: %r' % (self.msg, self.line) class Parser: """Parser interface.""" def __init__(self): pass def parse(self): raise NotImplementedError class LineParser(Parser): """Base class for parsers that read line-based formats.""" def __init__(self, file): Parser.__init__(self) self._file = file self.__line = None self.__eof = False def readline(self): line = self._file.readline() if not line: self.__line = '' self.__eof = True self.__line = line.rstrip('\r\n') def lookahead(self): assert self.__line is not None return self.__line def consume(self): assert self.__line is not None line = self.__line self.readline() return line def eof(self): assert self.__line is not None return self.__eof XML_ELEMENT_START, XML_ELEMENT_END, XML_CHARACTER_DATA, XML_EOF = range(4) class XmlToken: def __init__(self, type, name_or_data, attrs = None, line = None, column = None): assert type in (XML_ELEMENT_START, XML_ELEMENT_END, XML_CHARACTER_DATA, XML_EOF) self.type = type self.name_or_data = name_or_data self.attrs = attrs self.line = line self.column = column def __str__(self): if self.type == XML_ELEMENT_START: return '<' + self.name_or_data + ' ...>' if self.type == XML_ELEMENT_END: return '' if self.type == XML_CHARACTER_DATA: return self.name_or_data if self.type == XML_EOF: return 'end of file' assert 0 class XmlTokenizer: """Expat based XML tokenizer.""" def __init__(self, fp, skip_ws = True): self.fp = fp self.tokens = [] self.index = 0 self.final = False self.skip_ws = skip_ws self.character_pos = 0, 0 self.character_data = '' self.parser = xml.parsers.expat.ParserCreate() self.parser.StartElementHandler = self.handle_element_start self.parser.EndElementHandler = self.handle_element_end self.parser.CharacterDataHandler = self.handle_character_data def handle_element_start(self, name, attributes): self.finish_character_data() line, column = self.pos() token = XmlToken(XML_ELEMENT_START, name, attributes, line, column) self.tokens.append(token) def handle_element_end(self, name): self.finish_character_data() line, column = self.pos() token = XmlToken(XML_ELEMENT_END, name, None, line, column) self.tokens.append(token) def handle_character_data(self, data): if not self.character_data: self.character_pos = self.pos() self.character_data += data def finish_character_data(self): if self.character_data: if not self.skip_ws or not self.character_data.isspace(): line, column = self.character_pos token = XmlToken(XML_CHARACTER_DATA, self.character_data, None, line, column) self.tokens.append(token) self.character_data = '' def next(self): size = 16*1024 while self.index >= len(self.tokens) and not self.final: self.tokens = [] self.index = 0 data = self.fp.read(size) self.final = len(data) < size try: self.parser.Parse(data, self.final) except xml.parsers.expat.ExpatError, e: #if e.code == xml.parsers.expat.errors.XML_ERROR_NO_ELEMENTS: if e.code == 3: pass else: raise e if self.index >= len(self.tokens): line, column = self.pos() token = XmlToken(XML_EOF, None, None, line, column) else: token = self.tokens[self.index] self.index += 1 return token def pos(self): return self.parser.CurrentLineNumber, self.parser.CurrentColumnNumber class XmlTokenMismatch(Exception): def __init__(self, expected, found): self.expected = expected self.found = found def __str__(self): return '%u:%u: %s expected, %s found' % (self.found.line, self.found.column, str(self.expected), str(self.found)) class XmlParser(Parser): """Base XML document parser.""" def __init__(self, fp): Parser.__init__(self) self.tokenizer = XmlTokenizer(fp) self.consume() def consume(self): self.token = self.tokenizer.next() def match_element_start(self, name): return self.token.type == XML_ELEMENT_START and self.token.name_or_data == name def match_element_end(self, name): return self.token.type == XML_ELEMENT_END and self.token.name_or_data == name def element_start(self, name): while self.token.type == XML_CHARACTER_DATA: self.consume() if self.token.type != XML_ELEMENT_START: raise XmlTokenMismatch(XmlToken(XML_ELEMENT_START, name), self.token) if self.token.name_or_data != name: raise XmlTokenMismatch(XmlToken(XML_ELEMENT_START, name), self.token) attrs = self.token.attrs self.consume() return attrs def element_end(self, name): while self.token.type == XML_CHARACTER_DATA: self.consume() if self.token.type != XML_ELEMENT_END: raise XmlTokenMismatch(XmlToken(XML_ELEMENT_END, name), self.token) if self.token.name_or_data != name: raise XmlTokenMismatch(XmlToken(XML_ELEMENT_END, name), self.token) self.consume() def character_data(self, strip = True): data = '' while self.token.type == XML_CHARACTER_DATA: data += self.token.name_or_data self.consume() if strip: data = data.strip() return data class GprofParser(Parser): """Parser for GNU gprof output. See also: - Chapter "Interpreting gprof's Output" from the GNU gprof manual http://sourceware.org/binutils/docs-2.18/gprof/Call-Graph.html#Call-Graph - File "cg_print.c" from the GNU gprof source code http://sourceware.org/cgi-bin/cvsweb.cgi/~checkout~/src/gprof/cg_print.c?rev=1.12&cvsroot=src """ def __init__(self, fp): Parser.__init__(self) self.fp = fp self.functions = {} self.cycles = {} def readline(self): line = self.fp.readline() if not line: sys.stderr.write('error: unexpected end of file\n') sys.exit(1) line = line.rstrip('\r\n') return line _int_re = re.compile(r'^\d+$') _float_re = re.compile(r'^\d+\.\d+$') def translate(self, mo): """Extract a structure from a match object, while translating the types in the process.""" attrs = {} groupdict = mo.groupdict() for name, value in groupdict.iteritems(): if value is None: value = None elif self._int_re.match(value): value = int(value) elif self._float_re.match(value): value = float(value) attrs[name] = (value) return Struct(attrs) _cg_header_re = re.compile( # original gprof header r'^\s+called/total\s+parents\s*$|' + r'^index\s+%time\s+self\s+descendents\s+called\+self\s+name\s+index\s*$|' + r'^\s+called/total\s+children\s*$|' + # GNU gprof header r'^index\s+%\s+time\s+self\s+children\s+called\s+name\s*$' ) _cg_ignore_re = re.compile( # spontaneous r'^\s+\s*$|' # internal calls (such as "mcount") r'^.*\((\d+)\)$' ) _cg_primary_re = re.compile( r'^\[(?P\d+)\]?' + r'\s+(?P\d+\.\d+)' + r'\s+(?P\d+\.\d+)' + r'\s+(?P\d+\.\d+)' + r'\s+(?:(?P\d+)(?:\+(?P\d+))?)?' + r'\s+(?P\S.*?)' + r'(?:\s+\d+)>)?' + r'\s\[(\d+)\]$' ) _cg_parent_re = re.compile( r'^\s+(?P\d+\.\d+)?' + r'\s+(?P\d+\.\d+)?' + r'\s+(?P\d+)(?:/(?P\d+))?' + r'\s+(?P\S.*?)' + r'(?:\s+\d+)>)?' + r'\s\[(?P\d+)\]$' ) _cg_child_re = _cg_parent_re _cg_cycle_header_re = re.compile( r'^\[(?P\d+)\]?' + r'\s+(?P\d+\.\d+)' + r'\s+(?P\d+\.\d+)' + r'\s+(?P\d+\.\d+)' + r'\s+(?:(?P\d+)(?:\+(?P\d+))?)?' + r'\s+\d+)\sas\sa\swhole>' + r'\s\[(\d+)\]$' ) _cg_cycle_member_re = re.compile( r'^\s+(?P\d+\.\d+)?' + r'\s+(?P\d+\.\d+)?' + r'\s+(?P\d+)(?:\+(?P\d+))?' + r'\s+(?P\S.*?)' + r'(?:\s+\d+)>)?' + r'\s\[(?P\d+)\]$' ) _cg_sep_re = re.compile(r'^--+$') def parse_function_entry(self, lines): parents = [] children = [] while True: if not lines: sys.stderr.write('warning: unexpected end of entry\n') line = lines.pop(0) if line.startswith('['): break # read function parent line mo = self._cg_parent_re.match(line) if not mo: if self._cg_ignore_re.match(line): continue sys.stderr.write('warning: unrecognized call graph entry: %r\n' % line) else: parent = self.translate(mo) parents.append(parent) # read primary line mo = self._cg_primary_re.match(line) if not mo: sys.stderr.write('warning: unrecognized call graph entry: %r\n' % line) return else: function = self.translate(mo) while lines: line = lines.pop(0) # read function subroutine line mo = self._cg_child_re.match(line) if not mo: if self._cg_ignore_re.match(line): continue sys.stderr.write('warning: unrecognized call graph entry: %r\n' % line) else: child = self.translate(mo) children.append(child) function.parents = parents function.children = children self.functions[function.index] = function def parse_cycle_entry(self, lines): # read cycle header line line = lines[0] mo = self._cg_cycle_header_re.match(line) if not mo: sys.stderr.write('warning: unrecognized call graph entry: %r\n' % line) return cycle = self.translate(mo) # read cycle member lines cycle.functions = [] for line in lines[1:]: mo = self._cg_cycle_member_re.match(line) if not mo: sys.stderr.write('warning: unrecognized call graph entry: %r\n' % line) continue call = self.translate(mo) cycle.functions.append(call) self.cycles[cycle.cycle] = cycle def parse_cg_entry(self, lines): if lines[0].startswith("["): self.parse_cycle_entry(lines) else: self.parse_function_entry(lines) def parse_cg(self): """Parse the call graph.""" # skip call graph header while not self._cg_header_re.match(self.readline()): pass line = self.readline() while self._cg_header_re.match(line): line = self.readline() # process call graph entries entry_lines = [] while line != '\014': # form feed if line and not line.isspace(): if self._cg_sep_re.match(line): self.parse_cg_entry(entry_lines) entry_lines = [] else: entry_lines.append(line) line = self.readline() def parse(self): self.parse_cg() self.fp.close() profile = Profile() profile[TIME] = 0.0 cycles = {} for index in self.cycles.iterkeys(): cycles[index] = Cycle() for entry in self.functions.itervalues(): # populate the function function = Function(entry.index, entry.name) function[TIME] = entry.self if entry.called is not None: function.called = entry.called if entry.called_self is not None: call = Call(entry.index) call[CALLS] = entry.called_self function.called += entry.called_self # populate the function calls for child in entry.children: call = Call(child.index) assert child.called is not None call[CALLS] = child.called if child.index not in self.functions: # NOTE: functions that were never called but were discovered by gprof's # static call graph analysis dont have a call graph entry so we need # to add them here missing = Function(child.index, child.name) function[TIME] = 0.0 function.called = 0 profile.add_function(missing) function.add_call(call) profile.add_function(function) if entry.cycle is not None: try: cycle = cycles[entry.cycle] except KeyError: sys.stderr.write('warning: entry missing\n' % entry.cycle) cycle = Cycle() cycles[entry.cycle] = cycle cycle.add_function(function) profile[TIME] = profile[TIME] + function[TIME] for cycle in cycles.itervalues(): profile.add_cycle(cycle) # Compute derived events profile.validate() profile.ratio(TIME_RATIO, TIME) profile.call_ratios(CALLS) profile.integrate(TOTAL_TIME, TIME) profile.ratio(TOTAL_TIME_RATIO, TOTAL_TIME) return profile class CallgrindParser(LineParser): """Parser for valgrind's callgrind tool. See also: - http://valgrind.org/docs/manual/cl-format.html """ _call_re = re.compile('^calls=\s*(\d+)\s+((\d+|\+\d+|-\d+|\*)\s+)+$') def __init__(self, infile): LineParser.__init__(self, infile) # Textual positions self.position_ids = {} self.positions = {} # Numeric positions self.num_positions = 1 self.cost_positions = ['line'] self.last_positions = [0] # Events self.num_events = 0 self.cost_events = [] self.profile = Profile() self.profile[SAMPLES] = 0 def parse(self): # read lookahead self.readline() self.parse_key('version') self.parse_key('creator') self.parse_part() # compute derived data self.profile.validate() self.profile.find_cycles() self.profile.ratio(TIME_RATIO, SAMPLES) self.profile.call_ratios(CALLS) self.profile.integrate(TOTAL_TIME_RATIO, TIME_RATIO) return self.profile def parse_part(self): while self.parse_header_line(): pass while self.parse_body_line(): pass return True def parse_header_line(self): return \ self.parse_empty() or \ self.parse_comment() or \ self.parse_part_detail() or \ self.parse_description() or \ self.parse_event_specification() or \ self.parse_cost_line_def() or \ self.parse_cost_summary() _detail_keys = set(('cmd', 'pid', 'thread', 'part')) def parse_part_detail(self): return self.parse_keys(self._detail_keys) def parse_description(self): return self.parse_key('desc') is not None def parse_event_specification(self): event = self.parse_key('event') if event is None: return False return True def parse_cost_line_def(self): pair = self.parse_keys(('events', 'positions')) if pair is None: return False key, value = pair items = value.split() if key == 'events': self.num_events = len(items) self.cost_events = items if key == 'positions': self.num_positions = len(items) self.cost_positions = items self.last_positions = [0]*self.num_positions return True def parse_cost_summary(self): pair = self.parse_keys(('summary', 'totals')) if pair is None: return False return True def parse_body_line(self): return \ self.parse_empty() or \ self.parse_comment() or \ self.parse_cost_line() or \ self.parse_position_spec() or \ self.parse_association_spec() _cost_re = re.compile(r'^(\d+|\+\d+|-\d+|\*)( \d+)+$') def parse_cost_line(self, calls=None): line = self.lookahead() mo = self._cost_re.match(line) if not mo: return False function = self.get_function() values = line.split(' ') assert len(values) == self.num_positions + self.num_events positions = values[0 : self.num_positions] events = values[self.num_positions : ] for i in range(self.num_positions): position = positions[i] if position == '*': position = self.last_positions[i] elif position[0] in '-+': position = self.last_positions[i] + int(position) else: position = int(position) self.last_positions[i] = position events = map(float, events) if calls is None: function[SAMPLES] += events[0] self.profile[SAMPLES] += events[0] else: callee = self.get_callee() callee.called += calls try: call = function.calls[callee.id] except KeyError: call = Call(callee.id) call[CALLS] = calls call[SAMPLES] = events[0] function.add_call(call) else: call[CALLS] += calls call[SAMPLES] += events[0] self.consume() return True def parse_association_spec(self): line = self.lookahead() if not line.startswith('calls='): return False _, values = line.split('=', 1) values = values.strip().split() calls = int(values[0]) call_position = values[1:] self.consume() self.parse_cost_line(calls) return True _position_re = re.compile('^(?Pc?(?:ob|fl|fi|fe|fn))=\s*(?:\((?P\d+)\))?(?:\s*(?P.+))?') _position_table_map = { 'ob': 'ob', 'fl': 'fl', 'fi': 'fl', 'fe': 'fl', 'fn': 'fn', 'cob': 'ob', 'cfl': 'fl', 'cfi': 'fl', 'cfe': 'fl', 'cfn': 'fn', } _position_map = { 'ob': 'ob', 'fl': 'fl', 'fi': 'fl', 'fe': 'fl', 'fn': 'fn', 'cob': 'cob', 'cfl': 'cfl', 'cfi': 'cfl', 'cfe': 'cfl', 'cfn': 'cfn', } def parse_position_spec(self): line = self.lookahead() mo = self._position_re.match(line) if not mo: return False position, id, name = mo.groups() if id: table = self._position_table_map[position] if name: self.position_ids[(table, id)] = name else: name = self.position_ids.get((table, id), '') self.positions[self._position_map[position]] = name self.consume() return True def parse_empty(self): line = self.lookahead() if line.strip(): return False self.consume() return True def parse_comment(self): line = self.lookahead() if not line.startswith('#'): return False self.consume() return True _key_re = re.compile(r'^(\w+):') def parse_key(self, key): pair = self.parse_keys((key,)) if not pair: return None key, value = pair return value line = self.lookahead() mo = self._key_re.match(line) if not mo: return None key, value = line.split(':', 1) if key not in keys: return None value = value.strip() self.consume() return key, value def parse_keys(self, keys): line = self.lookahead() mo = self._key_re.match(line) if not mo: return None key, value = line.split(':', 1) if key not in keys: return None value = value.strip() self.consume() return key, value def make_function(self, module, filename, name): # FIXME: module and filename are not being tracked reliably #id = '|'.join((module, filename, name)) id = name try: function = self.profile.functions[id] except KeyError: function = Function(id, name) function[SAMPLES] = 0 function.called = 0 self.profile.add_function(function) return function def get_function(self): module = self.positions.get('ob', '') filename = self.positions.get('fl', '') function = self.positions.get('fn', '') return self.make_function(module, filename, function) def get_callee(self): module = self.positions.get('cob', '') filename = self.positions.get('cfi', '') function = self.positions.get('cfn', '') return self.make_function(module, filename, function) class OprofileParser(LineParser): """Parser for oprofile callgraph output. See also: - http://oprofile.sourceforge.net/doc/opreport.html#opreport-callgraph """ _fields_re = { 'samples': r'(\d+)', '%': r'(\S+)', 'linenr info': r'(?P\(no location information\)|\S+:\d+)', 'image name': r'(?P\S+(?:\s\(tgid:[^)]*\))?)', 'app name': r'(?P\S+)', 'symbol name': r'(?P\(no symbols\)|.+?)', } def __init__(self, infile): LineParser.__init__(self, infile) self.entries = {} self.entry_re = None def add_entry(self, callers, function, callees): try: entry = self.entries[function.id] except KeyError: self.entries[function.id] = (callers, function, callees) else: callers_total, function_total, callees_total = entry self.update_subentries_dict(callers_total, callers) function_total.samples += function.samples self.update_subentries_dict(callees_total, callees) def update_subentries_dict(self, totals, partials): for partial in partials.itervalues(): try: total = totals[partial.id] except KeyError: totals[partial.id] = partial else: total.samples += partial.samples def parse(self): # read lookahead self.readline() self.parse_header() while self.lookahead(): self.parse_entry() profile = Profile() reverse_call_samples = {} # populate the profile profile[SAMPLES] = 0 for _callers, _function, _callees in self.entries.itervalues(): function = Function(_function.id, _function.name) function[SAMPLES] = _function.samples profile.add_function(function) profile[SAMPLES] += _function.samples if _function.application: function.process = os.path.basename(_function.application) if _function.image: function.module = os.path.basename(_function.image) total_callee_samples = 0 for _callee in _callees.itervalues(): total_callee_samples += _callee.samples for _callee in _callees.itervalues(): if not _callee.self: call = Call(_callee.id) call[SAMPLES2] = _callee.samples function.add_call(call) # compute derived data profile.validate() profile.find_cycles() profile.ratio(TIME_RATIO, SAMPLES) profile.call_ratios(SAMPLES2) profile.integrate(TOTAL_TIME_RATIO, TIME_RATIO) return profile def parse_header(self): while not self.match_header(): self.consume() line = self.lookahead() fields = re.split(r'\s\s+', line) entry_re = r'^\s*' + r'\s+'.join([self._fields_re[field] for field in fields]) + r'(?P\s+\[self\])?$' self.entry_re = re.compile(entry_re) self.skip_separator() def parse_entry(self): callers = self.parse_subentries() if self.match_primary(): function = self.parse_subentry() if function is not None: callees = self.parse_subentries() self.add_entry(callers, function, callees) self.skip_separator() def parse_subentries(self): subentries = {} while self.match_secondary(): subentry = self.parse_subentry() subentries[subentry.id] = subentry return subentries def parse_subentry(self): entry = Struct() line = self.consume() mo = self.entry_re.match(line) if not mo: raise ParseError('failed to parse', line) fields = mo.groupdict() entry.samples = int(mo.group(1)) if 'source' in fields and fields['source'] != '(no location information)': source = fields['source'] filename, lineno = source.split(':') entry.filename = filename entry.lineno = int(lineno) else: source = '' entry.filename = None entry.lineno = None entry.image = fields.get('image', '') entry.application = fields.get('application', '') if 'symbol' in fields and fields['symbol'] != '(no symbols)': entry.symbol = fields['symbol'] else: entry.symbol = '' if entry.symbol.startswith('"') and entry.symbol.endswith('"'): entry.symbol = entry.symbol[1:-1] entry.id = ':'.join((entry.application, entry.image, source, entry.symbol)) entry.self = fields.get('self', None) != None if entry.self: entry.id += ':self' if entry.symbol: entry.name = entry.symbol else: entry.name = entry.image return entry def skip_separator(self): while not self.match_separator(): self.consume() self.consume() def match_header(self): line = self.lookahead() return line.startswith('samples') def match_separator(self): line = self.lookahead() return line == '-'*len(line) def match_primary(self): line = self.lookahead() return not line[:1].isspace() def match_secondary(self): line = self.lookahead() return line[:1].isspace() class SysprofParser(XmlParser): def __init__(self, stream): XmlParser.__init__(self, stream) def parse(self): objects = {} nodes = {} self.element_start('profile') while self.token.type == XML_ELEMENT_START: if self.token.name_or_data == 'objects': assert not objects objects = self.parse_items('objects') elif self.token.name_or_data == 'nodes': assert not nodes nodes = self.parse_items('nodes') else: self.parse_value(self.token.name_or_data) self.element_end('profile') return self.build_profile(objects, nodes) def parse_items(self, name): assert name[-1] == 's' items = {} self.element_start(name) while self.token.type == XML_ELEMENT_START: id, values = self.parse_item(name[:-1]) assert id not in items items[id] = values self.element_end(name) return items def parse_item(self, name): attrs = self.element_start(name) id = int(attrs['id']) values = self.parse_values() self.element_end(name) return id, values def parse_values(self): values = {} while self.token.type == XML_ELEMENT_START: name = self.token.name_or_data value = self.parse_value(name) assert name not in values values[name] = value return values def parse_value(self, tag): self.element_start(tag) value = self.character_data() self.element_end(tag) if value.isdigit(): return int(value) if value.startswith('"') and value.endswith('"'): return value[1:-1] return value def build_profile(self, objects, nodes): profile = Profile() profile[SAMPLES] = 0 for id, object in objects.iteritems(): # Ignore fake objects (process names, modules, "Everything", "kernel", etc.) if object['self'] == 0: continue function = Function(id, object['name']) function[SAMPLES] = object['self'] profile.add_function(function) profile[SAMPLES] += function[SAMPLES] for id, node in nodes.iteritems(): # Ignore fake calls if node['self'] == 0: continue # Find a non-ignored parent parent_id = node['parent'] while parent_id != 0: parent = nodes[parent_id] caller_id = parent['object'] if objects[caller_id]['self'] != 0: break parent_id = parent['parent'] if parent_id == 0: continue callee_id = node['object'] assert objects[caller_id]['self'] assert objects[callee_id]['self'] function = profile.functions[caller_id] samples = node['self'] try: call = function.calls[callee_id] except KeyError: call = Call(callee_id) call[SAMPLES2] = samples function.add_call(call) else: call[SAMPLES2] += samples # Compute derived events profile.validate() profile.find_cycles() profile.ratio(TIME_RATIO, SAMPLES) profile.call_ratios(SAMPLES2) profile.integrate(TOTAL_TIME_RATIO, TIME_RATIO) return profile class SharkParser(LineParser): """Parser for MacOSX Shark output. Author: tom@dbservice.com """ def __init__(self, infile): LineParser.__init__(self, infile) self.stack = [] self.entries = {} def add_entry(self, function): try: entry = self.entries[function.id] except KeyError: self.entries[function.id] = (function, { }) else: function_total, callees_total = entry function_total.samples += function.samples def add_callee(self, function, callee): func, callees = self.entries[function.id] try: entry = callees[callee.id] except KeyError: callees[callee.id] = callee else: entry.samples += callee.samples def parse(self): self.readline() self.readline() self.readline() self.readline() match = re.compile(r'(?P[|+ ]*)(?P\d+), (?P[^,]+), (?P.*)') while self.lookahead(): line = self.consume() mo = match.match(line) if not mo: raise ParseError('failed to parse', line) fields = mo.groupdict() prefix = len(fields.get('prefix', 0)) / 2 - 1 symbol = str(fields.get('symbol', 0)) image = str(fields.get('image', 0)) entry = Struct() entry.id = ':'.join([symbol, image]) entry.samples = int(fields.get('samples', 0)) entry.name = symbol entry.image = image # adjust the callstack if prefix < len(self.stack): del self.stack[prefix:] if prefix == len(self.stack): self.stack.append(entry) # if the callstack has had an entry, it's this functions caller if prefix > 0: self.add_callee(self.stack[prefix - 1], entry) self.add_entry(entry) profile = Profile() profile[SAMPLES] = 0 for _function, _callees in self.entries.itervalues(): function = Function(_function.id, _function.name) function[SAMPLES] = _function.samples profile.add_function(function) profile[SAMPLES] += _function.samples if _function.image: function.module = os.path.basename(_function.image) for _callee in _callees.itervalues(): call = Call(_callee.id) call[SAMPLES] = _callee.samples function.add_call(call) # compute derived data profile.validate() profile.find_cycles() profile.ratio(TIME_RATIO, SAMPLES) profile.call_ratios(SAMPLES) profile.integrate(TOTAL_TIME_RATIO, TIME_RATIO) return profile class XPerfParser(Parser): """Parser for CSVs generted by XPerf, from Microsoft Windows Performance Tools. """ def __init__(self, stream): Parser.__init__(self) self.stream = stream self.profile = Profile() self.profile[SAMPLES] = 0 self.column = {} def parse(self): import csv reader = csv.reader( self.stream, delimiter = ',', quotechar = None, escapechar = None, doublequote = False, skipinitialspace = True, lineterminator = '\r\n', quoting = csv.QUOTE_NONE) it = iter(reader) row = reader.next() self.parse_header(row) for row in it: self.parse_row(row) # compute derived data self.profile.validate() self.profile.find_cycles() self.profile.ratio(TIME_RATIO, SAMPLES) self.profile.call_ratios(SAMPLES2) self.profile.integrate(TOTAL_TIME_RATIO, TIME_RATIO) return self.profile def parse_header(self, row): for column in range(len(row)): name = row[column] assert name not in self.column self.column[name] = column def parse_row(self, row): fields = {} for name, column in self.column.iteritems(): value = row[column] for factory in int, float: try: value = factory(value) except ValueError: pass else: break fields[name] = value process = fields['Process Name'] symbol = fields['Module'] + '!' + fields['Function'] weight = fields['Weight'] count = fields['Count'] function = self.get_function(process, symbol) function[SAMPLES] += weight * count self.profile[SAMPLES] += weight * count stack = fields['Stack'] if stack != '?': stack = stack.split('/') assert stack[0] == '[Root]' if stack[-1] != symbol: # XXX: some cases the sampled function does not appear in the stack stack.append(symbol) caller = None for symbol in stack[1:]: callee = self.get_function(process, symbol) if caller is not None: try: call = caller.calls[callee.id] except KeyError: call = Call(callee.id) call[SAMPLES2] = count caller.add_call(call) else: call[SAMPLES2] += count caller = callee def get_function(self, process, symbol): function_id = process + '!' + symbol try: function = self.profile.functions[function_id] except KeyError: module, name = symbol.split('!') function = Function(function_id, name) function.process = process function.module = module function[SAMPLES] = 0 self.profile.add_function(function) return function class SleepyParser(Parser): """Parser for GNU gprof output. See also: - http://www.codersnotes.com/sleepy/ - http://sleepygraph.sourceforge.net/ """ def __init__(self, filename): Parser.__init__(self) from zipfile import ZipFile self.database = ZipFile(filename) self.symbols = {} self.calls = {} self.profile = Profile() _symbol_re = re.compile( r'^(?P\w+)' + r'\s+"(?P[^"]*)"' + r'\s+"(?P[^"]*)"' + r'\s+"(?P[^"]*)"' + r'\s+(?P\d+)$' ) def parse_symbols(self): lines = self.database.read('symbols.txt').splitlines() for line in lines: mo = self._symbol_re.match(line) if mo: symbol_id, module, procname, sourcefile, sourceline = mo.groups() function_id = ':'.join([module, procname]) try: function = self.profile.functions[function_id] except KeyError: function = Function(function_id, procname) function.module = module function[SAMPLES] = 0 self.profile.add_function(function) self.symbols[symbol_id] = function def parse_callstacks(self): lines = self.database.read("callstacks.txt").splitlines() for line in lines: fields = line.split() samples = int(fields[0]) callstack = fields[1:] callstack = [self.symbols[symbol_id] for symbol_id in callstack] callee = callstack[0] callee[SAMPLES] += samples self.profile[SAMPLES] += samples for caller in callstack[1:]: try: call = caller.calls[callee.id] except KeyError: call = Call(callee.id) call[SAMPLES2] = samples caller.add_call(call) else: call[SAMPLES2] += samples callee = caller def parse(self): profile = self.profile profile[SAMPLES] = 0 self.parse_symbols() self.parse_callstacks() # Compute derived events profile.validate() profile.find_cycles() profile.ratio(TIME_RATIO, SAMPLES) profile.call_ratios(SAMPLES2) profile.integrate(TOTAL_TIME_RATIO, TIME_RATIO) return profile class AQtimeTable: def __init__(self, name, fields): self.name = name self.fields = fields self.field_column = {} for column in range(len(fields)): self.field_column[fields[column]] = column self.rows = [] def __len__(self): return len(self.rows) def __iter__(self): for values, children in self.rows: fields = {} for name, value in zip(self.fields, values): fields[name] = value children = dict([(child.name, child) for child in children]) yield fields, children raise StopIteration def add_row(self, values, children=()): self.rows.append((values, children)) class AQtimeParser(XmlParser): def __init__(self, stream): XmlParser.__init__(self, stream) self.tables = {} def parse(self): self.element_start('AQtime_Results') self.parse_headers() results = self.parse_results() self.element_end('AQtime_Results') return self.build_profile(results) def parse_headers(self): self.element_start('HEADERS') while self.token.type == XML_ELEMENT_START: self.parse_table_header() self.element_end('HEADERS') def parse_table_header(self): attrs = self.element_start('TABLE_HEADER') name = attrs['NAME'] id = int(attrs['ID']) field_types = [] field_names = [] while self.token.type == XML_ELEMENT_START: field_type, field_name = self.parse_table_field() field_types.append(field_type) field_names.append(field_name) self.element_end('TABLE_HEADER') self.tables[id] = name, field_types, field_names def parse_table_field(self): attrs = self.element_start('TABLE_FIELD') type = attrs['TYPE'] name = self.character_data() self.element_end('TABLE_FIELD') return type, name def parse_results(self): self.element_start('RESULTS') table = self.parse_data() self.element_end('RESULTS') return table def parse_data(self): rows = [] attrs = self.element_start('DATA') table_id = int(attrs['TABLE_ID']) table_name, field_types, field_names = self.tables[table_id] table = AQtimeTable(table_name, field_names) while self.token.type == XML_ELEMENT_START: row, children = self.parse_row(field_types) table.add_row(row, children) self.element_end('DATA') return table def parse_row(self, field_types): row = [None]*len(field_types) children = [] self.element_start('ROW') while self.token.type == XML_ELEMENT_START: if self.token.name_or_data == 'FIELD': field_id, field_value = self.parse_field(field_types) row[field_id] = field_value elif self.token.name_or_data == 'CHILDREN': children = self.parse_children() else: raise XmlTokenMismatch(" or ", self.token) self.element_end('ROW') return row, children def parse_field(self, field_types): attrs = self.element_start('FIELD') id = int(attrs['ID']) type = field_types[id] value = self.character_data() if type == 'Integer': value = int(value) elif type == 'Float': value = float(value) elif type == 'Address': value = int(value) elif type == 'String': pass else: assert False self.element_end('FIELD') return id, value def parse_children(self): children = [] self.element_start('CHILDREN') while self.token.type == XML_ELEMENT_START: table = self.parse_data() assert table.name not in children children.append(table) self.element_end('CHILDREN') return children def build_profile(self, results): assert results.name == 'Routines' profile = Profile() profile[TIME] = 0.0 for fields, tables in results: function = self.build_function(fields) children = tables['Children'] for fields, _ in children: call = self.build_call(fields) function.add_call(call) profile.add_function(function) profile[TIME] = profile[TIME] + function[TIME] profile[TOTAL_TIME] = profile[TIME] profile.ratio(TOTAL_TIME_RATIO, TOTAL_TIME) return profile def build_function(self, fields): function = Function(self.build_id(fields), self.build_name(fields)) function[TIME] = fields['Time'] function[TOTAL_TIME] = fields['Time with Children'] #function[TIME_RATIO] = fields['% Time']/100.0 #function[TOTAL_TIME_RATIO] = fields['% with Children']/100.0 return function def build_call(self, fields): call = Call(self.build_id(fields)) call[TIME] = fields['Time'] call[TOTAL_TIME] = fields['Time with Children'] #call[TIME_RATIO] = fields['% Time']/100.0 #call[TOTAL_TIME_RATIO] = fields['% with Children']/100.0 return call def build_id(self, fields): return ':'.join([fields['Module Name'], fields['Unit Name'], fields['Routine Name']]) def build_name(self, fields): # TODO: use more fields return fields['Routine Name'] class PstatsParser: """Parser python profiling statistics saved with te pstats module.""" def __init__(self, *filename): import pstats try: self.stats = pstats.Stats(*filename) except ValueError: import hotshot.stats self.stats = hotshot.stats.load(filename[0]) self.profile = Profile() self.function_ids = {} def get_function_name(self, (filename, line, name)): module = os.path.splitext(filename)[0] module = os.path.basename(module) return "%s:%d:%s" % (module, line, name) def get_function(self, key): try: id = self.function_ids[key] except KeyError: id = len(self.function_ids) name = self.get_function_name(key) function = Function(id, name) self.profile.functions[id] = function self.function_ids[key] = id else: function = self.profile.functions[id] return function def parse(self): self.profile[TIME] = 0.0 self.profile[TOTAL_TIME] = self.stats.total_tt for fn, (cc, nc, tt, ct, callers) in self.stats.stats.iteritems(): callee = self.get_function(fn) callee.called = nc callee[TOTAL_TIME] = ct callee[TIME] = tt self.profile[TIME] += tt self.profile[TOTAL_TIME] = max(self.profile[TOTAL_TIME], ct) for fn, value in callers.iteritems(): caller = self.get_function(fn) call = Call(callee.id) if isinstance(value, tuple): for i in xrange(0, len(value), 4): nc, cc, tt, ct = value[i:i+4] if CALLS in call: call[CALLS] += cc else: call[CALLS] = cc if TOTAL_TIME in call: call[TOTAL_TIME] += ct else: call[TOTAL_TIME] = ct else: call[CALLS] = value call[TOTAL_TIME] = ratio(value, nc)*ct caller.add_call(call) #self.stats.print_stats() #self.stats.print_callees() # Compute derived events self.profile.validate() self.profile.ratio(TIME_RATIO, TIME) self.profile.ratio(TOTAL_TIME_RATIO, TOTAL_TIME) return self.profile class Theme: def __init__(self, bgcolor = (0.0, 0.0, 1.0), mincolor = (0.0, 0.0, 0.0), maxcolor = (0.0, 0.0, 1.0), fontname = "Arial", minfontsize = 10.0, maxfontsize = 10.0, minpenwidth = 0.5, maxpenwidth = 4.0, gamma = 2.2, skew = 1.0): self.bgcolor = bgcolor self.mincolor = mincolor self.maxcolor = maxcolor self.fontname = fontname self.minfontsize = minfontsize self.maxfontsize = maxfontsize self.minpenwidth = minpenwidth self.maxpenwidth = maxpenwidth self.gamma = gamma self.skew = skew def graph_bgcolor(self): return self.hsl_to_rgb(*self.bgcolor) def graph_fontname(self): return self.fontname def graph_fontsize(self): return self.minfontsize def node_bgcolor(self, weight): return self.color(weight) def node_fgcolor(self, weight): return self.graph_bgcolor() def node_fontsize(self, weight): return self.fontsize(weight) def edge_color(self, weight): return self.color(weight) def edge_fontsize(self, weight): return self.fontsize(weight) def edge_penwidth(self, weight): return max(weight*self.maxpenwidth, self.minpenwidth) def edge_arrowsize(self, weight): return 0.5 * math.sqrt(self.edge_penwidth(weight)) def fontsize(self, weight): return max(weight**2 * self.maxfontsize, self.minfontsize) def color(self, weight): weight = min(max(weight, 0.0), 1.0) hmin, smin, lmin = self.mincolor hmax, smax, lmax = self.maxcolor if self.skew < 0: raise ValueError("Skew must be greater than 0") elif self.skew == 1.0: h = hmin + weight*(hmax - hmin) s = smin + weight*(smax - smin) l = lmin + weight*(lmax - lmin) else: base = self.skew h = hmin + ((hmax-hmin)*(-1.0 + (base ** weight)) / (base - 1.0)) s = smin + ((smax-smin)*(-1.0 + (base ** weight)) / (base - 1.0)) l = lmin + ((lmax-lmin)*(-1.0 + (base ** weight)) / (base - 1.0)) return self.hsl_to_rgb(h, s, l) def hsl_to_rgb(self, h, s, l): """Convert a color from HSL color-model to RGB. See also: - http://www.w3.org/TR/css3-color/#hsl-color """ h = h % 1.0 s = min(max(s, 0.0), 1.0) l = min(max(l, 0.0), 1.0) if l <= 0.5: m2 = l*(s + 1.0) else: m2 = l + s - l*s m1 = l*2.0 - m2 r = self._hue_to_rgb(m1, m2, h + 1.0/3.0) g = self._hue_to_rgb(m1, m2, h) b = self._hue_to_rgb(m1, m2, h - 1.0/3.0) # Apply gamma correction r **= self.gamma g **= self.gamma b **= self.gamma return (r, g, b) def _hue_to_rgb(self, m1, m2, h): if h < 0.0: h += 1.0 elif h > 1.0: h -= 1.0 if h*6 < 1.0: return m1 + (m2 - m1)*h*6.0 elif h*2 < 1.0: return m2 elif h*3 < 2.0: return m1 + (m2 - m1)*(2.0/3.0 - h)*6.0 else: return m1 TEMPERATURE_COLORMAP = Theme( mincolor = (2.0/3.0, 0.80, 0.25), # dark blue maxcolor = (0.0, 1.0, 0.5), # satured red gamma = 1.0 ) PINK_COLORMAP = Theme( mincolor = (0.0, 1.0, 0.90), # pink maxcolor = (0.0, 1.0, 0.5), # satured red ) GRAY_COLORMAP = Theme( mincolor = (0.0, 0.0, 0.85), # light gray maxcolor = (0.0, 0.0, 0.0), # black ) BW_COLORMAP = Theme( minfontsize = 8.0, maxfontsize = 24.0, mincolor = (0.0, 0.0, 0.0), # black maxcolor = (0.0, 0.0, 0.0), # black minpenwidth = 0.1, maxpenwidth = 8.0, ) class DotWriter: """Writer for the DOT language. See also: - "The DOT Language" specification http://www.graphviz.org/doc/info/lang.html """ def __init__(self, fp): self.fp = fp def graph(self, profile, theme): self.begin_graph() fontname = theme.graph_fontname() self.attr('graph', fontname=fontname, ranksep=0.25, nodesep=0.125) self.attr('node', fontname=fontname, shape="box", style="filled", fontcolor="white", width=0, height=0) self.attr('edge', fontname=fontname) for function in profile.functions.itervalues(): labels = [] if function.process is not None: labels.append(function.process) if function.module is not None: labels.append(function.module) labels.append(function.name) for event in TOTAL_TIME_RATIO, TIME_RATIO: if event in function.events: label = event.format(function[event]) labels.append(label) if function.called is not None: labels.append(u"%u\xd7" % (function.called,)) if function.weight is not None: weight = function.weight else: weight = 0.0 label = '\n'.join(labels) self.node(function.id, label = label, color = self.color(theme.node_bgcolor(weight)), fontcolor = self.color(theme.node_fgcolor(weight)), fontsize = "%.2f" % theme.node_fontsize(weight), ) for call in function.calls.itervalues(): callee = profile.functions[call.callee_id] labels = [] for event in TOTAL_TIME_RATIO, CALLS: if event in call.events: label = event.format(call[event]) labels.append(label) if call.weight is not None: weight = call.weight elif callee.weight is not None: weight = callee.weight else: weight = 0.0 label = '\n'.join(labels) self.edge(function.id, call.callee_id, label = label, color = self.color(theme.edge_color(weight)), fontcolor = self.color(theme.edge_color(weight)), fontsize = "%.2f" % theme.edge_fontsize(weight), penwidth = "%.2f" % theme.edge_penwidth(weight), labeldistance = "%.2f" % theme.edge_penwidth(weight), arrowsize = "%.2f" % theme.edge_arrowsize(weight), ) self.end_graph() def begin_graph(self): self.write('digraph {\n') def end_graph(self): self.write('}\n') def attr(self, what, **attrs): self.write("\t") self.write(what) self.attr_list(attrs) self.write(";\n") def node(self, node, **attrs): self.write("\t") self.id(node) self.attr_list(attrs) self.write(";\n") def edge(self, src, dst, **attrs): self.write("\t") self.id(src) self.write(" -> ") self.id(dst) self.attr_list(attrs) self.write(";\n") def attr_list(self, attrs): if not attrs: return self.write(' [') first = True for name, value in attrs.iteritems(): if first: first = False else: self.write(", ") self.id(name) self.write('=') self.id(value) self.write(']') def id(self, id): if isinstance(id, (int, float)): s = str(id) elif isinstance(id, basestring): if id.isalnum() and not id.startswith('0x'): s = id else: s = self.escape(id) else: raise TypeError self.write(s) def color(self, (r, g, b)): def float2int(f): if f <= 0.0: return 0 if f >= 1.0: return 255 return int(255.0*f + 0.5) return "#" + "".join(["%02x" % float2int(c) for c in (r, g, b)]) def escape(self, s): s = s.encode('utf-8') s = s.replace('\\', r'\\') s = s.replace('\n', r'\n') s = s.replace('\t', r'\t') s = s.replace('"', r'\"') return '"' + s + '"' def write(self, s): self.fp.write(s) class Main: """Main program.""" themes = { "color": TEMPERATURE_COLORMAP, "pink": PINK_COLORMAP, "gray": GRAY_COLORMAP, "bw": BW_COLORMAP, } def main(self): """Main program.""" parser = optparse.OptionParser( usage="\n\t%prog [options] [file] ...", version="%%prog %s" % __version__) parser.add_option( '-o', '--output', metavar='FILE', type="string", dest="output", help="output filename [stdout]") parser.add_option( '-n', '--node-thres', metavar='PERCENTAGE', type="float", dest="node_thres", default=0.5, help="eliminate nodes below this threshold [default: %default]") parser.add_option( '-e', '--edge-thres', metavar='PERCENTAGE', type="float", dest="edge_thres", default=0.1, help="eliminate edges below this threshold [default: %default]") parser.add_option( '-f', '--format', type="choice", choices=('prof', 'callgrind', 'oprofile', 'sysprof', 'pstats', 'shark', 'sleepy', 'aqtime', 'xperf'), dest="format", default="prof", help="profile format: prof, callgrind, oprofile, sysprof, shark, sleepy, aqtime, pstats, or xperf [default: %default]") parser.add_option( '-c', '--colormap', type="choice", choices=('color', 'pink', 'gray', 'bw'), dest="theme", default="color", help="color map: color, pink, gray, or bw [default: %default]") parser.add_option( '-s', '--strip', action="store_true", dest="strip", default=False, help="strip function parameters, template parameters, and const modifiers from demangled C++ function names") parser.add_option( '-w', '--wrap', action="store_true", dest="wrap", default=False, help="wrap function names") # add a new option to control skew of the colorization curve parser.add_option( '--skew', type="float", dest="theme_skew", default=1.0, help="skew the colorization curve. Values < 1.0 give more variety to lower percentages. Value > 1.0 give less variety to lower percentages") (self.options, self.args) = parser.parse_args(sys.argv[1:]) if len(self.args) > 1 and self.options.format != 'pstats': parser.error('incorrect number of arguments') try: self.theme = self.themes[self.options.theme] except KeyError: parser.error('invalid colormap \'%s\'' % self.options.theme) # set skew on the theme now that it has been picked. if self.options.theme_skew: self.theme.skew = self.options.theme_skew if self.options.format == 'prof': if not self.args: fp = sys.stdin else: fp = open(self.args[0], 'rt') parser = GprofParser(fp) elif self.options.format == 'callgrind': if not self.args: fp = sys.stdin else: fp = open(self.args[0], 'rt') parser = CallgrindParser(fp) elif self.options.format == 'oprofile': if not self.args: fp = sys.stdin else: fp = open(self.args[0], 'rt') parser = OprofileParser(fp) elif self.options.format == 'sysprof': if not self.args: fp = sys.stdin else: fp = open(self.args[0], 'rt') parser = SysprofParser(fp) elif self.options.format == 'pstats': if not self.args: parser.error('at least a file must be specified for pstats input') parser = PstatsParser(*self.args) elif self.options.format == 'xperf': if not self.args: fp = sys.stdin else: fp = open(self.args[0], 'rt') parser = XPerfParser(fp) elif self.options.format == 'shark': if not self.args: fp = sys.stdin else: fp = open(self.args[0], 'rt') parser = SharkParser(fp) elif self.options.format == 'sleepy': if len(self.args) != 1: parser.error('exactly one file must be specified for sleepy input') parser = SleepyParser(self.args[0]) elif self.options.format == 'aqtime': if not self.args: fp = sys.stdin else: fp = open(self.args[0], 'rt') parser = AQtimeParser(fp) else: parser.error('invalid format \'%s\'' % self.options.format) self.profile = parser.parse() if self.options.output is None: self.output = sys.stdout else: self.output = open(self.options.output, 'wt') self.write_graph() _parenthesis_re = re.compile(r'\([^()]*\)') _angles_re = re.compile(r'<[^<>]*>') _const_re = re.compile(r'\s+const$') def strip_function_name(self, name): """Remove extraneous information from C++ demangled function names.""" # Strip function parameters from name by recursively removing paired parenthesis while True: name, n = self._parenthesis_re.subn('', name) if not n: break # Strip const qualifier name = self._const_re.sub('', name) # Strip template parameters from name by recursively removing paired angles while True: name, n = self._angles_re.subn('', name) if not n: break return name def wrap_function_name(self, name): """Split the function name on multiple lines.""" if len(name) > 32: ratio = 2.0/3.0 height = max(int(len(name)/(1.0 - ratio) + 0.5), 1) width = max(len(name)/height, 32) # TODO: break lines in symbols name = textwrap.fill(name, width, break_long_words=False) # Take away spaces name = name.replace(", ", ",") name = name.replace("> >", ">>") name = name.replace("> >", ">>") # catch consecutive return name def compress_function_name(self, name): """Compress function name according to the user preferences.""" if self.options.strip: name = self.strip_function_name(name) if self.options.wrap: name = self.wrap_function_name(name) # TODO: merge functions with same resulting name return name def write_graph(self): dot = DotWriter(self.output) profile = self.profile profile.prune(self.options.node_thres/100.0, self.options.edge_thres/100.0) for function in profile.functions.itervalues(): function.name = self.compress_function_name(function.name) dot.graph(profile, self.theme) if __name__ == '__main__': Main().main()