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android / toolchain / prebuilts / ndk / r18 / refs/heads/android-games-sdk-games-performance-tuner-release / . / simpleperf / report_html.py
blob: 1a616fbcdc14633bc28eda22e6db08afbb30b514 [file] [log] [blame]
#!/usr/bin/env python
#
# Copyright (C) 2017 The Android Open Source Project
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
#
import argparse
import collections
import datetime
import json
import os
import sys
from simpleperf_report_lib import ReportLib
from utils import log_info, log_exit
from utils import Addr2Nearestline, get_script_dir, Objdump, open_report_in_browser
from utils import SourceFileSearcher
MAX_CALLSTACK_LENGTH = 750
class HtmlWriter(object):
def __init__(self, output_path):
self.fh = open(output_path, 'w')
self.tag_stack = []
def close(self):
self.fh.close()
def open_tag(self, tag, **attrs):
attr_str = ''
for key in attrs:
attr_str += ' %s="%s"' % (key, attrs[key])
self.fh.write('<%s%s>' % (tag, attr_str))
self.tag_stack.append(tag)
return self
def close_tag(self, tag=None):
if tag:
assert tag == self.tag_stack[-1]
self.fh.write('</%s>\n' % self.tag_stack.pop())
def add(self, text):
self.fh.write(text)
return self
def add_file(self, file_path):
file_path = os.path.join(get_script_dir(), file_path)
with open(file_path, 'r') as f:
self.add(f.read())
return self
def modify_text_for_html(text):
return text.replace('>', '&gt;').replace('<', '&lt;')
class EventScope(object):
def __init__(self, name):
self.name = name
self.processes = {} # map from pid to ProcessScope
self.sample_count = 0
self.event_count = 0
def get_process(self, pid):
process = self.processes.get(pid)
if not process:
process = self.processes[pid] = ProcessScope(pid)
return process
def get_sample_info(self, gen_addr_hit_map):
result = {}
result['eventName'] = self.name
result['eventCount'] = self.event_count
processes = sorted(self.processes.values(), key=lambda a: a.event_count, reverse=True)
result['processes'] = [process.get_sample_info(gen_addr_hit_map)
for process in processes]
return result
@property
def threads(self):
for process in self.processes.values():
for thread in process.threads.values():
yield thread
@property
def libraries(self):
for process in self.processes.values():
for thread in process.threads.values():
for lib in thread.libs.values():
yield lib
class ProcessScope(object):
def __init__(self, pid):
self.pid = pid
self.name = ''
self.event_count = 0
self.threads = {} # map from tid to ThreadScope
def get_thread(self, tid, thread_name):
thread = self.threads.get(tid)
if not thread:
thread = self.threads[tid] = ThreadScope(tid)
thread.name = thread_name
if self.pid == tid:
self.name = thread_name
return thread
def get_sample_info(self, gen_addr_hit_map):
result = {}
result['pid'] = self.pid
result['eventCount'] = self.event_count
threads = sorted(self.threads.values(), key=lambda a: a.event_count, reverse=True)
result['threads'] = [thread.get_sample_info(gen_addr_hit_map)
for thread in threads]
return result
class ThreadScope(object):
def __init__(self, tid):
self.tid = tid
self.name = ''
self.event_count = 0
self.sample_count = 0
self.libs = {} # map from lib_id to LibScope
self.call_graph = CallNode(-1)
self.reverse_call_graph = CallNode(-1)
def add_callstack(self, event_count, callstack, build_addr_hit_map):
""" callstack is a list of tuple (lib_id, func_id, addr).
For each i > 0, callstack[i] calls callstack[i-1]."""
hit_func_ids = set()
for i, (lib_id, func_id, addr) in enumerate(callstack):
# When a callstack contains recursive function, only add for each function once.
if func_id in hit_func_ids:
continue
hit_func_ids.add(func_id)
lib = self.libs.get(lib_id)
if not lib:
lib = self.libs[lib_id] = LibScope(lib_id)
function = lib.get_function(func_id)
function.subtree_event_count += event_count
if i == 0:
lib.event_count += event_count
function.event_count += event_count
function.sample_count += 1
if build_addr_hit_map:
function.build_addr_hit_map(addr, event_count if i == 0 else 0, event_count)
# build call graph and reverse call graph
node = self.call_graph
for item in reversed(callstack):
node = node.get_child(item[1])
node.event_count += event_count
node = self.reverse_call_graph
for item in callstack:
node = node.get_child(item[1])
node.event_count += event_count
def update_subtree_event_count(self):
self.call_graph.update_subtree_event_count()
self.reverse_call_graph.update_subtree_event_count()
def limit_percents(self, min_func_limit, min_callchain_percent, hit_func_ids):
for lib in self.libs.values():
to_del_funcs = []
for function in lib.functions.values():
if function.subtree_event_count < min_func_limit:
to_del_funcs.append(function.func_id)
else:
hit_func_ids.add(function.func_id)
for func_id in to_del_funcs:
del lib.functions[func_id]
min_limit = min_callchain_percent * 0.01 * self.call_graph.subtree_event_count
self.call_graph.cut_edge(min_limit, hit_func_ids)
self.reverse_call_graph.cut_edge(min_limit, hit_func_ids)
def get_sample_info(self, gen_addr_hit_map):
result = {}
result['tid'] = self.tid
result['eventCount'] = self.event_count
result['sampleCount'] = self.sample_count
result['libs'] = [lib.gen_sample_info(gen_addr_hit_map)
for lib in self.libs.values()]
result['g'] = self.call_graph.gen_sample_info()
result['rg'] = self.reverse_call_graph.gen_sample_info()
return result
class LibScope(object):
def __init__(self, lib_id):
self.lib_id = lib_id
self.event_count = 0
self.functions = {} # map from func_id to FunctionScope.
def get_function(self, func_id):
function = self.functions.get(func_id)
if not function:
function = self.functions[func_id] = FunctionScope(func_id)
return function
def gen_sample_info(self, gen_addr_hit_map):
result = {}
result['libId'] = self.lib_id
result['eventCount'] = self.event_count
result['functions'] = [func.gen_sample_info(gen_addr_hit_map)
for func in self.functions.values()]
return result
class FunctionScope(object):
def __init__(self, func_id):
self.func_id = func_id
self.sample_count = 0
self.event_count = 0
self.subtree_event_count = 0
self.addr_hit_map = None # map from addr to [event_count, subtree_event_count].
# map from (source_file_id, line) to [event_count, subtree_event_count].
self.line_hit_map = None
def build_addr_hit_map(self, addr, event_count, subtree_event_count):
if self.addr_hit_map is None:
self.addr_hit_map = {}
count_info = self.addr_hit_map.get(addr)
if count_info is None:
self.addr_hit_map[addr] = [event_count, subtree_event_count]
else:
count_info[0] += event_count
count_info[1] += subtree_event_count
def build_line_hit_map(self, source_file_id, line, event_count, subtree_event_count):
if self.line_hit_map is None:
self.line_hit_map = {}
key = (source_file_id, line)
count_info = self.line_hit_map.get(key)
if count_info is None:
self.line_hit_map[key] = [event_count, subtree_event_count]
else:
count_info[0] += event_count
count_info[1] += subtree_event_count
def gen_sample_info(self, gen_addr_hit_map):
result = {}
result['f'] = self.func_id
result['c'] = [self.sample_count, self.event_count, self.subtree_event_count]
if self.line_hit_map:
items = []
for key in self.line_hit_map:
count_info = self.line_hit_map[key]
item = {'f': key[0], 'l': key[1], 'e': count_info[0], 's': count_info[1]}
items.append(item)
result['s'] = items
if gen_addr_hit_map and self.addr_hit_map:
items = []
for addr in sorted(self.addr_hit_map):
count_info = self.addr_hit_map[addr]
items.append({'a': addr, 'e': count_info[0], 's': count_info[1]})
result['a'] = items
return result
class CallNode(object):
def __init__(self, func_id):
self.event_count = 0
self.subtree_event_count = 0
self.func_id = func_id
self.children = collections.OrderedDict() # map from func_id to CallNode
def get_child(self, func_id):
child = self.children.get(func_id)
if not child:
child = self.children[func_id] = CallNode(func_id)
return child
def update_subtree_event_count(self):
self.subtree_event_count = self.event_count
for child in self.children.values():
self.subtree_event_count += child.update_subtree_event_count()
return self.subtree_event_count
def cut_edge(self, min_limit, hit_func_ids):
hit_func_ids.add(self.func_id)
to_del_children = []
for key in self.children:
child = self.children[key]
if child.subtree_event_count < min_limit:
to_del_children.append(key)
else:
child.cut_edge(min_limit, hit_func_ids)
for key in to_del_children:
del self.children[key]
def gen_sample_info(self):
result = {}
result['e'] = self.event_count
result['s'] = self.subtree_event_count
result['f'] = self.func_id
result['c'] = [child.gen_sample_info() for child in self.children.values()]
return result
class LibSet(object):
""" Collection of shared libraries used in perf.data. """
def __init__(self):
self.lib_name_to_id = {}
self.lib_id_to_name = []
def get_lib_id(self, lib_name):
lib_id = self.lib_name_to_id.get(lib_name)
if lib_id is None:
lib_id = len(self.lib_id_to_name)
self.lib_name_to_id[lib_name] = lib_id
self.lib_id_to_name.append(lib_name)
return lib_id
def get_lib_name(self, lib_id):
return self.lib_id_to_name[lib_id]
class Function(object):
""" Represent a function in a shared library. """
def __init__(self, lib_id, func_name, func_id, start_addr, addr_len):
self.lib_id = lib_id
self.func_name = func_name
self.func_id = func_id
self.start_addr = start_addr
self.addr_len = addr_len
self.source_info = None
self.disassembly = None
class FunctionSet(object):
""" Collection of functions used in perf.data. """
def __init__(self):
self.name_to_func = {}
self.id_to_func = {}
def get_func_id(self, lib_id, symbol):
key = (lib_id, symbol.symbol_name)
function = self.name_to_func.get(key)
if function is None:
func_id = len(self.id_to_func)
function = Function(lib_id, symbol.symbol_name, func_id, symbol.symbol_addr,
symbol.symbol_len)
self.name_to_func[key] = function
self.id_to_func[func_id] = function
return function.func_id
def trim_functions(self, left_func_ids):
""" Remove functions excepts those in left_func_ids. """
for function in self.name_to_func.values():
if function.func_id not in left_func_ids:
del self.id_to_func[function.func_id]
# name_to_func will not be used.
self.name_to_func = None
class SourceFile(object):
""" A source file containing source code hit by samples. """
def __init__(self, file_id, abstract_path):
self.file_id = file_id
self.abstract_path = abstract_path # path reported by addr2line
self.real_path = None # file path in the file system
self.requested_lines = set()
self.line_to_code = {} # map from line to code in that line.
def request_lines(self, start_line, end_line):
self.requested_lines |= set(range(start_line, end_line + 1))
def add_source_code(self, real_path):
self.real_path = real_path
with open(real_path, 'r') as f:
source_code = f.readlines()
max_line = len(source_code)
for line in self.requested_lines:
if line > 0 and line <= max_line:
self.line_to_code[line] = source_code[line - 1]
# requested_lines is no longer used.
self.requested_lines = None
class SourceFileSet(object):
""" Collection of source files. """
def __init__(self):
self.path_to_source_files = {} # map from file path to SourceFile.
def get_source_file(self, file_path):
source_file = self.path_to_source_files.get(file_path)
if source_file is None:
source_file = SourceFile(len(self.path_to_source_files), file_path)
self.path_to_source_files[file_path] = source_file
return source_file
def load_source_code(self, source_dirs):
file_searcher = SourceFileSearcher(source_dirs)
for source_file in self.path_to_source_files.values():
real_path = file_searcher.get_real_path(source_file.abstract_path)
if real_path:
source_file.add_source_code(real_path)
class RecordData(object):
"""RecordData reads perf.data, and generates data used by report.js in json format.
All generated items are listed as below:
1. recordTime: string
2. machineType: string
3. androidVersion: string
4. recordCmdline: string
5. totalSamples: int
6. processNames: map from pid to processName.
7. threadNames: map from tid to threadName.
8. libList: an array of libNames, indexed by libId.
9. functionMap: map from functionId to funcData.
funcData = {
l: libId
f: functionName
s: [sourceFileId, startLine, endLine] [optional]
d: [(disassembly, addr)] [optional]
}
10. sampleInfo = [eventInfo]
eventInfo = {
eventName
eventCount
processes: [processInfo]
}
processInfo = {
pid
eventCount
threads: [threadInfo]
}
threadInfo = {
tid
eventCount
sampleCount
libs: [libInfo],
g: callGraph,
rg: reverseCallgraph
}
libInfo = {
libId,
eventCount,
functions: [funcInfo]
}
funcInfo = {
f: functionId
c: [sampleCount, eventCount, subTreeEventCount]
s: [sourceCodeInfo] [optional]
a: [addrInfo] (sorted by addrInfo.addr) [optional]
}
callGraph and reverseCallGraph are both of type CallNode.
callGraph shows how a function calls other functions.
reverseCallGraph shows how a function is called by other functions.
CallNode {
e: selfEventCount
s: subTreeEventCount
f: functionId
c: [CallNode] # children
}
sourceCodeInfo {
f: sourceFileId
l: line
e: eventCount
s: subtreeEventCount
}
addrInfo {
a: addr
e: eventCount
s: subtreeEventCount
}
11. sourceFiles: an array of sourceFile, indexed by sourceFileId.
sourceFile {
path
code: # a map from line to code for that line.
}
"""
def __init__(self, binary_cache_path, ndk_path, build_addr_hit_map):
self.binary_cache_path = binary_cache_path
self.ndk_path = ndk_path
self.build_addr_hit_map = build_addr_hit_map
self.meta_info = None
self.cmdline = None
self.arch = None
self.events = {}
self.libs = LibSet()
self.functions = FunctionSet()
self.total_samples = 0
self.source_files = SourceFileSet()
self.gen_addr_hit_map_in_record_info = False
def load_record_file(self, record_file, show_art_frames):
lib = ReportLib()
lib.SetRecordFile(record_file)
# If not showing ip for unknown symbols, the percent of the unknown symbol may be
# accumulated to very big, and ranks first in the sample table.
lib.ShowIpForUnknownSymbol()
if show_art_frames:
lib.ShowArtFrames()
if self.binary_cache_path:
lib.SetSymfs(self.binary_cache_path)
self.meta_info = lib.MetaInfo()
self.cmdline = lib.GetRecordCmd()
self.arch = lib.GetArch()
while True:
raw_sample = lib.GetNextSample()
if not raw_sample:
lib.Close()
break
raw_event = lib.GetEventOfCurrentSample()
symbol = lib.GetSymbolOfCurrentSample()
callchain = lib.GetCallChainOfCurrentSample()
event = self._get_event(raw_event.name)
self.total_samples += 1
event.sample_count += 1
event.event_count += raw_sample.period
process = event.get_process(raw_sample.pid)
process.event_count += raw_sample.period
thread = process.get_thread(raw_sample.tid, raw_sample.thread_comm)
thread.event_count += raw_sample.period
thread.sample_count += 1
lib_id = self.libs.get_lib_id(symbol.dso_name)
func_id = self.functions.get_func_id(lib_id, symbol)
callstack = [(lib_id, func_id, symbol.vaddr_in_file)]
for i in range(callchain.nr):
symbol = callchain.entries[i].symbol
lib_id = self.libs.get_lib_id(symbol.dso_name)
func_id = self.functions.get_func_id(lib_id, symbol)
callstack.append((lib_id, func_id, symbol.vaddr_in_file))
if len(callstack) > MAX_CALLSTACK_LENGTH:
callstack = callstack[:MAX_CALLSTACK_LENGTH]
thread.add_callstack(raw_sample.period, callstack, self.build_addr_hit_map)
for event in self.events.values():
for thread in event.threads:
thread.update_subtree_event_count()
def limit_percents(self, min_func_percent, min_callchain_percent):
hit_func_ids = set()
for event in self.events.values():
min_limit = event.event_count * min_func_percent * 0.01
for process in event.processes.values():
to_del_threads = []
for thread in process.threads.values():
if thread.call_graph.subtree_event_count < min_limit:
to_del_threads.append(thread.tid)
else:
thread.limit_percents(min_limit, min_callchain_percent, hit_func_ids)
for thread in to_del_threads:
del process.threads[thread]
self.functions.trim_functions(hit_func_ids)
def _get_event(self, event_name):
if event_name not in self.events:
self.events[event_name] = EventScope(event_name)
return self.events[event_name]
def add_source_code(self, source_dirs, filter_lib):
""" Collect source code information:
1. Find line ranges for each function in FunctionSet.
2. Find line for each addr in FunctionScope.addr_hit_map.
3. Collect needed source code in SourceFileSet.
"""
addr2line = Addr2Nearestline(self.ndk_path, self.binary_cache_path, False)
# Request line range for each function.
for function in self.functions.id_to_func.values():
if function.func_name == 'unknown':
continue
lib_name = self.libs.get_lib_name(function.lib_id)
if filter_lib(lib_name):
addr2line.add_addr(lib_name, function.start_addr, function.start_addr)
addr2line.add_addr(lib_name, function.start_addr,
function.start_addr + function.addr_len - 1)
# Request line for each addr in FunctionScope.addr_hit_map.
for event in self.events.values():
for lib in event.libraries:
lib_name = self.libs.get_lib_name(lib.lib_id)
if filter_lib(lib_name):
for function in lib.functions.values():
func_addr = self.functions.id_to_func[function.func_id].start_addr
for addr in function.addr_hit_map:
addr2line.add_addr(lib_name, func_addr, addr)
addr2line.convert_addrs_to_lines()
# Set line range for each function.
for function in self.functions.id_to_func.values():
if function.func_name == 'unknown':
continue
dso = addr2line.get_dso(self.libs.get_lib_name(function.lib_id))
if not dso:
continue
start_source = addr2line.get_addr_source(dso, function.start_addr)
end_source = addr2line.get_addr_source(dso, function.start_addr + function.addr_len - 1)
if not start_source or not end_source:
continue
start_file_path, start_line = start_source[-1]
end_file_path, end_line = end_source[-1]
if start_file_path != end_file_path or start_line > end_line:
continue
source_file = self.source_files.get_source_file(start_file_path)
source_file.request_lines(start_line, end_line)
function.source_info = (source_file.file_id, start_line, end_line)
# Build FunctionScope.line_hit_map.
for event in self.events.values():
for lib in event.libraries:
dso = addr2line.get_dso(self.libs.get_lib_name(lib.lib_id))
if not dso:
continue
for function in lib.functions.values():
for addr in function.addr_hit_map:
source = addr2line.get_addr_source(dso, addr)
if not source:
continue
for file_path, line in source:
source_file = self.source_files.get_source_file(file_path)
# Show [line - 5, line + 5] of the line hit by a sample.
source_file.request_lines(line - 5, line + 5)
count_info = function.addr_hit_map[addr]
function.build_line_hit_map(source_file.file_id, line, count_info[0],
count_info[1])
# Collect needed source code in SourceFileSet.
self.source_files.load_source_code(source_dirs)
def add_disassembly(self, filter_lib):
""" Collect disassembly information:
1. Use objdump to collect disassembly for each function in FunctionSet.
2. Set flag to dump addr_hit_map when generating record info.
"""
objdump = Objdump(self.ndk_path, self.binary_cache_path)
cur_lib_name = None
dso_info = None
for function in sorted(self.functions.id_to_func.values(), key=lambda a: a.lib_id):
if function.func_name == 'unknown':
continue
lib_name = self.libs.get_lib_name(function.lib_id)
if lib_name != cur_lib_name:
cur_lib_name = lib_name
if filter_lib(lib_name):
dso_info = objdump.get_dso_info(lib_name)
else:
dso_info = None
if dso_info:
log_info('Disassemble %s' % dso_info[0])
if dso_info:
code = objdump.disassemble_code(dso_info, function.start_addr, function.addr_len)
function.disassembly = code
self.gen_addr_hit_map_in_record_info = True
def gen_record_info(self):
record_info = {}
timestamp = self.meta_info.get('timestamp')
if timestamp:
t = datetime.datetime.fromtimestamp(int(timestamp))
else:
t = datetime.datetime.now()
record_info['recordTime'] = t.strftime('%Y-%m-%d (%A) %H:%M:%S')
product_props = self.meta_info.get('product_props')
machine_type = self.arch
if product_props:
manufacturer, model, name = product_props.split(':')
machine_type = '%s (%s) by %s, arch %s' % (model, name, manufacturer, self.arch)
record_info['machineType'] = machine_type
record_info['androidVersion'] = self.meta_info.get('android_version', '')
record_info['recordCmdline'] = self.cmdline
record_info['totalSamples'] = self.total_samples
record_info['processNames'] = self._gen_process_names()
record_info['threadNames'] = self._gen_thread_names()
record_info['libList'] = self._gen_lib_list()
record_info['functionMap'] = self._gen_function_map()
record_info['sampleInfo'] = self._gen_sample_info()
record_info['sourceFiles'] = self._gen_source_files()
return record_info
def _gen_process_names(self):
process_names = {}
for event in self.events.values():
for process in event.processes.values():
process_names[process.pid] = process.name
return process_names
def _gen_thread_names(self):
thread_names = {}
for event in self.events.values():
for process in event.processes.values():
for thread in process.threads.values():
thread_names[thread.tid] = thread.name
return thread_names
def _gen_lib_list(self):
return [modify_text_for_html(x) for x in self.libs.lib_id_to_name]
def _gen_function_map(self):
func_map = {}
for func_id in sorted(self.functions.id_to_func):
function = self.functions.id_to_func[func_id]
func_data = {}
func_data['l'] = function.lib_id
func_data['f'] = modify_text_for_html(function.func_name)
if function.source_info:
func_data['s'] = function.source_info
if function.disassembly:
disassembly_list = []
for code, addr in function.disassembly:
disassembly_list.append([modify_text_for_html(code), addr])
func_data['d'] = disassembly_list
func_map[func_id] = func_data
return func_map
def _gen_sample_info(self):
return [event.get_sample_info(self.gen_addr_hit_map_in_record_info)
for event in self.events.values()]
def _gen_source_files(self):
source_files = sorted(self.source_files.path_to_source_files.values(),
key=lambda x: x.file_id)
file_list = []
for source_file in source_files:
file_data = {}
if not source_file.real_path:
file_data['path'] = ''
file_data['code'] = {}
else:
file_data['path'] = source_file.real_path
code_map = {}
for line in source_file.line_to_code:
code_map[line] = modify_text_for_html(source_file.line_to_code[line])
file_data['code'] = code_map
file_list.append(file_data)
return file_list
URLS = {
'jquery': 'https://ajax.googleapis.com/ajax/libs/jquery/3.3.1/jquery.min.js',
'bootstrap4-css': 'https://stackpath.bootstrapcdn.com/bootstrap/4.1.2/css/bootstrap.min.css',
'bootstrap4-popper':
'https://cdnjs.cloudflare.com/ajax/libs/popper.js/1.12.9/umd/popper.min.js',
'bootstrap4': 'https://stackpath.bootstrapcdn.com/bootstrap/4.1.2/js/bootstrap.min.js',
'dataTable': 'https://cdn.datatables.net/1.10.19/js/jquery.dataTables.min.js',
'dataTable-bootstrap4': 'https://cdn.datatables.net/1.10.19/js/dataTables.bootstrap4.min.js',
'dataTable-css': 'https://cdn.datatables.net/1.10.19/css/dataTables.bootstrap4.min.css',
'gstatic-charts': 'https://www.gstatic.com/charts/loader.js',
}
class ReportGenerator(object):
def __init__(self, html_path):
self.hw = HtmlWriter(html_path)
self.hw.open_tag('html')
self.hw.open_tag('head')
for css in ['bootstrap4-css', 'dataTable-css']:
self.hw.open_tag('link', rel='stylesheet', type='text/css', href=URLS[css]).close_tag()
for js in ['jquery', 'bootstrap4-popper', 'bootstrap4', 'dataTable', 'dataTable-bootstrap4',
'gstatic-charts']:
self.hw.open_tag('script', src=URLS[js]).close_tag()
self.hw.open_tag('script').add(
"google.charts.load('current', {'packages': ['corechart', 'table']});").close_tag()
self.hw.open_tag('style', type='text/css').add("""
.colForLine { width: 50px; }
.colForCount { width: 100px; }
.tableCell { font-size: 17px; }
.boldTableCell { font-weight: bold; font-size: 17px; }
""").close_tag()
self.hw.close_tag('head')
self.hw.open_tag('body')
self.record_info = {}
def write_content_div(self):
self.hw.open_tag('div', id='report_content').close_tag()
def write_record_data(self, record_data):
self.hw.open_tag('script', id='record_data', type='application/json')
self.hw.add(json.dumps(record_data))
self.hw.close_tag()
def write_script(self):
self.hw.open_tag('script').add_file('report_html.js').close_tag()
def finish(self):
self.hw.close_tag('body')
self.hw.close_tag('html')
self.hw.close()
def main():
sys.setrecursionlimit(MAX_CALLSTACK_LENGTH * 2 + 50)
parser = argparse.ArgumentParser(description='report profiling data')
parser.add_argument('-i', '--record_file', nargs='+', default=['perf.data'], help="""
Set profiling data file to report. Default is perf.data.""")
parser.add_argument('-o', '--report_path', default='report.html', help="""
Set output html file. Default is report.html.""")
parser.add_argument('--min_func_percent', default=0.01, type=float, help="""
Set min percentage of functions shown in the report.
For example, when set to 0.01, only functions taking >= 0.01%% of total
event count are collected in the report. Default is 0.01.""")
parser.add_argument('--min_callchain_percent', default=0.01, type=float, help="""
Set min percentage of callchains shown in the report.
It is used to limit nodes shown in the function flamegraph. For example,
when set to 0.01, only callchains taking >= 0.01%% of the event count of
the starting function are collected in the report. Default is 0.01.""")
parser.add_argument('--add_source_code', action='store_true', help='Add source code.')
parser.add_argument('--source_dirs', nargs='+', help='Source code directories.')
parser.add_argument('--add_disassembly', action='store_true', help='Add disassembled code.')
parser.add_argument('--binary_filter', nargs='+', help="""Annotate source code and disassembly
only for selected binaries.""")
parser.add_argument('--ndk_path', nargs=1, help='Find tools in the ndk path.')
parser.add_argument('--no_browser', action='store_true', help="Don't open report in browser.")
parser.add_argument('--show_art_frames', action='store_true',
help='Show frames of internal methods in the ART Java interpreter.')
args = parser.parse_args()
# 1. Process args.
binary_cache_path = 'binary_cache'
if not os.path.isdir(binary_cache_path):
if args.add_source_code or args.add_disassembly:
log_exit("""binary_cache/ doesn't exist. Can't add source code or disassembled code
without collected binaries. Please run binary_cache_builder.py to
collect binaries for current profiling data, or run app_profiler.py
without -nb option.""")
binary_cache_path = None
if args.add_source_code and not args.source_dirs:
log_exit('--source_dirs is needed to add source code.')
build_addr_hit_map = args.add_source_code or args.add_disassembly
ndk_path = None if not args.ndk_path else args.ndk_path[0]
# 2. Produce record data.
record_data = RecordData(binary_cache_path, ndk_path, build_addr_hit_map)
for record_file in args.record_file:
record_data.load_record_file(record_file, args.show_art_frames)
record_data.limit_percents(args.min_func_percent, args.min_callchain_percent)
def filter_lib(lib_name):
if not args.binary_filter:
return True
for binary in args.binary_filter:
if binary in lib_name:
return True
return False
if args.add_source_code:
record_data.add_source_code(args.source_dirs, filter_lib)
if args.add_disassembly:
record_data.add_disassembly(filter_lib)
# 3. Generate report html.
report_generator = ReportGenerator(args.report_path)
report_generator.write_script()
report_generator.write_content_div()
report_generator.write_record_data(record_data.gen_record_info())
report_generator.finish()
if not args.no_browser:
open_report_in_browser(args.report_path)
log_info("Report generated at '%s'." % args.report_path)
if __name__ == '__main__':
main()