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gprof2dot.py
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gprof2dot.py
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#!/usr/bin/env python3
#
# Copyright 2008-2017 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 <http://www.gnu.org/licenses/>.
#
"""Generate a dot graph from the output of several profilers."""
__author__ = "Jose Fonseca et al"
import sys
import math
import os.path
import re
import textwrap
import optparse
import xml.parsers.expat
import collections
import locale
import json
import fnmatch
# Python 2.x/3.x compatibility
if sys.version_info[0] >= 3:
PYTHON_3 = True
def compat_iteritems(x): return x.items() # No iteritems() in Python 3
def compat_itervalues(x): return x.values() # No itervalues() in Python 3
def compat_keys(x): return list(x.keys()) # keys() is a generator in Python 3
basestring = str # No class basestring in Python 3
unichr = chr # No unichr in Python 3
xrange = range # No xrange in Python 3
else:
PYTHON_3 = False
def compat_iteritems(x): return x.iteritems()
def compat_itervalues(x): return x.itervalues()
def compat_keys(x): return x.keys()
########################################################################
# Model
MULTIPLICATION_SIGN = unichr(0xd7)
def times(x):
return "%u%s" % (x, MULTIPLICATION_SIGN)
def percentage(p):
return "%.02f%%" % (p*100.0,)
def add(a, b):
return a + b
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, times)
SAMPLES2 = Event("Samples", 0, add, times)
# Count of samples where a given function was either executing or on the stack.
# This is used to calculate the total time ratio according to the
# straightforward method described in Mike Dunlavey's answer to
# stackoverflow.com/questions/1777556/alternatives-to-gprof, item 4 (the myth
# "that recursion is a tricky confusing issue"), last edited 2012-08-30: it's
# just the ratio of TOTAL_SAMPLES over the number of samples in the profile.
#
# Used only when totalMethod == callstacks
TOTAL_SAMPLES = Event("Samples", 0, add, times)
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)
totalMethod = 'callratios'
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 __lt__(self, other):
return id(self) < id(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
self.filename = 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
def get_call(self, callee_id):
if not callee_id in self.calls:
call = Call(callee_id)
call[SAMPLES] = 0
call[SAMPLES2] = 0
call[CALLS] = 0
self.calls[callee_id] = call
return self.calls[callee_id]
_parenthesis_re = re.compile(r'\([^()]*\)')
_angles_re = re.compile(r'<[^<>]*>')
_const_re = re.compile(r'\s+const$')
def stripped_name(self):
"""Remove extraneous information from C++ demangled function names."""
name = self.name
# 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
# 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)
self.functions = set()
def add_function(self, function):
assert function not in self.functions
self.functions.add(function)
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 compat_itervalues(self.functions):
for callee_id in compat_keys(function.calls):
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
stack = []
data = {}
order = 0
for function in compat_itervalues(self.functions):
order = self._tarjan(function, order, stack, data)
cycles = []
for function in compat_itervalues(self.functions):
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 prune_root(self, roots, depth=-1):
visited = set()
frontier = set([(root_node, depth) for root_node in roots])
while len(frontier) > 0:
node, node_depth = frontier.pop()
visited.add(node)
if node_depth == 0:
continue
f = self.functions[node]
newNodes = set(f.calls.keys()) - visited
frontier = frontier.union({(new_node, node_depth - 1) for new_node in newNodes})
subtreeFunctions = {}
for n in visited:
f = self.functions[n]
newCalls = {}
for c in f.calls.keys():
if c in visited:
newCalls[c] = f.calls[c]
f.calls = newCalls
subtreeFunctions[n] = f
self.functions = subtreeFunctions
def prune_leaf(self, leafs, depth=-1):
edgesUp = collections.defaultdict(set)
for f in self.functions.keys():
for n in self.functions[f].calls.keys():
edgesUp[n].add(f)
# build the tree up
visited = set()
frontier = set([(leaf_node, depth) for leaf_node in leafs])
while len(frontier) > 0:
node, node_depth = frontier.pop()
visited.add(node)
if node_depth == 0:
continue
newNodes = edgesUp[node] - visited
frontier = frontier.union({(new_node, node_depth - 1) for new_node in newNodes})
downTree = set(self.functions.keys())
upTree = visited
path = downTree.intersection(upTree)
pathFunctions = {}
for n in path:
f = self.functions[n]
newCalls = {}
for c in f.calls.keys():
if c in path:
newCalls[c] = f.calls[c]
f.calls = newCalls
pathFunctions[n] = f
self.functions = pathFunctions
def getFunctionIds(self, funcName):
function_names = {v.name: k for (k, v) in self.functions.items()}
return [function_names[name] for name in fnmatch.filter(function_names.keys(), funcName)]
def getFunctionId(self, funcName):
for f in self.functions:
if self.functions[f].name == funcName:
return f
return False
class _TarjanData:
def __init__(self, order):
self.order = order
self.lowlink = order
self.onstack = False
def _tarjan(self, function, order, stack, data):
"""Tarjan's strongly connected components algorithm.
See also:
- http://en.wikipedia.org/wiki/Tarjan's_strongly_connected_components_algorithm
"""
try:
func_data = data[function.id]
return order
except KeyError:
func_data = self._TarjanData(order)
data[function.id] = func_data
order += 1
pos = len(stack)
stack.append(function)
func_data.onstack = True
for call in compat_itervalues(function.calls):
try:
callee_data = data[call.callee_id]
if callee_data.onstack:
func_data.lowlink = min(func_data.lowlink, callee_data.order)
except KeyError:
callee = self.functions[call.callee_id]
order = self._tarjan(callee, order, stack, data)
callee_data = data[call.callee_id]
func_data.lowlink = min(func_data.lowlink, callee_data.lowlink)
if func_data.lowlink == func_data.order:
# Strongly connected component found
members = stack[pos:]
del stack[pos:]
if len(members) > 1:
cycle = Cycle()
for member in members:
cycle.add_function(member)
data[member.id].onstack = False
else:
for member in members:
data[member.id].onstack = False
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 compat_itervalues(self.functions):
function_totals[function] = 0.0
# Pass 1: function_total gets the sum of call[event] for all
# incoming arrows. Same for cycle_total for all arrows
# that are coming into the *cycle* but are not part of it.
for function in compat_itervalues(self.functions):
for call in compat_itervalues(function.calls):
if call.callee_id != function.id:
callee = self.functions[call.callee_id]
if event in call.events:
function_totals[callee] += call[event]
if callee.cycle is not None and callee.cycle is not function.cycle:
cycle_totals[callee.cycle] += call[event]
else:
sys.stderr.write("call_ratios: No data for " + function.name + " call to " + callee.name + "\n")
# Pass 2: Compute the ratios. Each call[event] is scaled by the
# function_total of the callee. Calls into cycles use the
# cycle_total, but not calls within cycles.
for function in compat_itervalues(self.functions):
for call in compat_itervalues(function.calls):
assert call.ratio is None
if call.callee_id != function.id:
callee = self.functions[call.callee_id]
if event in call.events:
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)
else:
# Warnings here would only repeat those issued above.
call.ratio = 0.0
def integrate(self, outevent, inevent):
"""Propagate function time ratio along 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 compat_itervalues(self.functions):
assert outevent not in function
assert inevent in function
for call in compat_itervalues(function.calls):
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 compat_itervalues(self.functions):
total = inevent.aggregate(total, function[inevent])
self[inevent] = total
# Integrate along the edges
total = inevent.null()
for function in compat_itervalues(self.functions):
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 compat_itervalues(function.calls):
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 compat_itervalues(member.calls):
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 compat_itervalues(self.functions):
if function.cycle is not cycle:
for call in compat_itervalues(function.calls):
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 compat_iteritems(callees):
ranks = {}
call_ratios = {}
partials = {}
self._rank_cycle_function(cycle, callee, 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)
# Ensure `partial == max(partials.values())`, but with round-off tolerance
max_partial = max(partials.values())
assert abs(partial - max_partial) <= 1e-7*max_partial
assert abs(call_ratio*total - partial) <= 0.001*call_ratio*total
return cycle[outevent]
def _rank_cycle_function(self, cycle, function, ranks):
"""Dijkstra's shortest paths algorithm.
See also:
- http://en.wikipedia.org/wiki/Dijkstra's_algorithm
"""
import heapq
Q = []
Qd = {}
p = {}
visited = set([function])
ranks[function] = 0
for call in compat_itervalues(function.calls):
if call.callee_id != function.id:
callee = self.functions[call.callee_id]
if callee.cycle is cycle:
ranks[callee] = 1
item = [ranks[callee], function, callee]
heapq.heappush(Q, item)
Qd[callee] = item
while Q:
cost, parent, member = heapq.heappop(Q)
if member not in visited:
p[member]= parent
visited.add(member)
for call in compat_itervalues(member.calls):
if call.callee_id != member.id:
callee = self.functions[call.callee_id]
if callee.cycle is cycle:
member_rank = ranks[member]
rank = ranks.get(callee)
if rank is not None:
if rank > 1 + member_rank:
rank = 1 + member_rank
ranks[callee] = rank
Qd_callee = Qd[callee]
Qd_callee[0] = rank
Qd_callee[1] = member
heapq._siftdown(Q, 0, Q.index(Qd_callee))
else:
rank = 1 + member_rank
ranks[callee] = rank
item = [rank, member, callee]
heapq.heappush(Q, item)
Qd[callee] = item
def _call_ratios_cycle(self, cycle, function, ranks, call_ratios, visited):
if function not in visited:
visited.add(function)
for call in compat_itervalues(function.calls):
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 compat_itervalues(function.calls):
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 compat_itervalues(self.functions):
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 compat_itervalues(self.functions):
assert outevent not in function
assert inevent in function
function[outevent] = ratio(function[inevent], self[inevent])
for call in compat_itervalues(function.calls):
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, paths, color_nodes_by_selftime):
"""Prune the profile"""
# compute the prune ratios
for function in compat_itervalues(self.functions):
try:
function.weight = function[TOTAL_TIME_RATIO]
except UndefinedEvent:
pass
for call in compat_itervalues(function.calls):
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 compat_keys(self.functions):
function = self.functions[function_id]
if function.weight is not None:
if function.weight < node_thres:
del self.functions[function_id]
# prune file paths
for function_id in compat_keys(self.functions):
function = self.functions[function_id]
if paths and not any(function.filename.startswith(path) for path in paths):
del self.functions[function_id]
# prune the egdes
for function in compat_itervalues(self.functions):
for callee_id in compat_keys(function.calls):
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]
if color_nodes_by_selftime:
weights = []
for function in compat_itervalues(self.functions):
try:
weights.append(function[TIME_RATIO])
except UndefinedEvent:
pass
max_ratio = max(weights or [1])
# apply rescaled weights for coloriung
for function in compat_itervalues(self.functions):
try:
function.weight = function[TIME_RATIO] / max_ratio
except (ZeroDivisionError, UndefinedEvent):
pass
def dump(self):
for function in compat_itervalues(self.functions):
sys.stderr.write('Function %s:\n' % (function.name,))
self._dump_events(function.events)
for call in compat_itervalues(function.calls):
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 compat_iteritems(events):
sys.stderr.write(' %s: %s\n' % (event.name, event.format(value)))
########################################################################
# Parsers
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):
Exception.__init__(self)
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."""
stdinInput = True
multipleInput = False
def __init__(self):
pass
def parse(self):
raise NotImplementedError
class JsonParser(Parser):
"""Parser for a custom JSON representation of profile data.
See schema.json for details.
"""
def __init__(self, stream):
Parser.__init__(self)
self.stream = stream
def parse(self):
obj = json.load(self.stream)
assert obj['version'] == 0
profile = Profile()
profile[SAMPLES] = 0
fns = obj['functions']
for functionIndex in range(len(fns)):
fn = fns[functionIndex]
function = Function(functionIndex, fn['name'])
try:
function.module = fn['module']
except KeyError:
pass
try:
function.process = fn['process']
except KeyError:
pass
function[SAMPLES] = 0
profile.add_function(function)
for event in obj['events']:
callchain = []
for functionIndex in event['callchain']:
function = profile.functions[functionIndex]
callchain.append(function)
cost = event['cost'][0]
callee = callchain[0]
callee[SAMPLES] += cost
profile[SAMPLES] += cost
for caller in callchain[1:]:
try:
call = caller.calls[callee.id]
except KeyError:
call = Call(callee.id)
call[SAMPLES2] = cost
caller.add_call(call)
else:
call[SAMPLES2] += cost
callee = caller
if False:
profile.dump()
# 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
class LineParser(Parser):
"""Base class for parsers that read line-based formats."""
def __init__(self, stream):
Parser.__init__(self)
self._stream = stream
self.__line = None
self.__eof = False
self.line_no = 0
def readline(self):
line = self._stream.readline()
if not line:
self.__line = ''
self.__eof = True
else:
self.line_no += 1
line = line.rstrip('\r\n')
if not PYTHON_3:
encoding = self._stream.encoding
if encoding is None:
encoding = locale.getpreferredencoding()
line = line.decode(encoding)
self.__line = line
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 '</' + self.name_or_data + '>'
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