| #!/usr/bin/python |
| # |
| # Copyright (c) 2016, Intel Corporation |
| # |
| # 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. |
| |
| # Based on a script by: |
| # Chereau, Fabien <fabien.chereau@intel.com> |
| |
| import os |
| import re |
| from optparse import OptionParser |
| import sys |
| import argparse |
| import subprocess |
| import json |
| import operator |
| |
| class bcolors: |
| HEADER = '\033[95m' |
| OKBLUE = '\033[94m' |
| OKGREEN = '\033[92m' |
| WARNING = '\033[93m' |
| FAIL = '\033[91m' |
| ENDC = '\033[0m' |
| BOLD = '\033[1m' |
| UNDERLINE = '\033[4m' |
| |
| |
| parser = OptionParser() |
| parser.add_option("-d", "--depth", dest="depth", type="int", |
| help="How deep should we go into the tree", metavar="DEPTH") |
| parser.add_option("-o", "--outdir", dest="outdir", |
| help="read files from directory OUT", metavar="OUT") |
| parser.add_option("-k", "--kernel-name", dest="binary", default="zephyr", |
| help="kernel binary name") |
| parser.add_option("-r", "--ram", |
| action="store_true", dest="ram", default=False, |
| help="print RAM statistics") |
| parser.add_option("-F", "--rom", |
| action="store_true", dest="rom", default=False, |
| help="print ROM statistics") |
| |
| (options, args) = parser.parse_args() |
| |
| # Return a dict containing symbol_name: path/to/file/where/it/originates |
| # for all symbols from the .elf file. Optionnaly strips the path according |
| # to the passed sub-path |
| def load_symbols_and_paths(elf_file, path_to_strip = None): |
| symbols_paths = {} |
| nm_out = subprocess.check_output(["nm", elf_file, "-S", "-l", "--size-sort", "--radix=d"]) |
| for line in nm_out.split('\n'): |
| fields = line.replace('\t', ' ').split(' ') |
| # Get rid of trailing empty field |
| if len(fields) == 1 and fields[0] == '': |
| continue |
| assert len(fields)>=4 |
| if len(fields)<5: |
| path = ":/" + fields[3] |
| else: |
| path = fields[4].split(':')[0] |
| if path_to_strip != None: |
| if path_to_strip in path: |
| path = path.replace(path_to_strip, "") + '/' + fields[3] |
| else: |
| path = ":/" + fields[3] |
| symbols_paths[fields[3]] = path |
| return symbols_paths |
| |
| def get_section_size(f, section_name): |
| decimal_size = 0 |
| re_res = re.search(r"(.*] "+section_name+".*)", f, re.MULTILINE) |
| if re_res != None : |
| # Replace multiple spaces with one space |
| # Skip first characters to avoid having 1 extra random space |
| res = ' '.join(re_res.group(1).split())[5:] |
| decimal_size = int(res.split()[4], 16) |
| return decimal_size |
| |
| def get_footprint_from_bin_and_statfile(bin_file, stat_file, total_flash, total_ram): |
| """Compute flash and RAM memory footprint from a .bin and.stat file""" |
| f = open(stat_file).read() |
| |
| # Get kctext + text + ctors + rodata + kcrodata segment size |
| total_used_flash = os.path.getsize(bin_file) |
| |
| #getting used ram on target |
| total_used_ram = (get_section_size(f, "noinit") + get_section_size(f, "bss") |
| + get_section_size(f, "initlevel") + get_section_size(f, "datas") + get_section_size(f, ".data") |
| + get_section_size(f, ".heap") + get_section_size(f, ".stack") + get_section_size(f, ".bss") |
| + get_section_size(f, ".panic_section")) |
| |
| total_percent_ram = 0 |
| total_percent_flash = 0 |
| if total_ram > 0: |
| total_percent_ram = float(total_used_ram) / total_ram * 100 |
| if total_flash >0: |
| total_percent_flash = float(total_used_flash) / total_flash * 100 |
| |
| res = { "total_flash": total_used_flash, |
| "percent_flash": total_percent_flash, |
| "total_ram": total_used_ram, |
| "percent_ram": total_percent_ram} |
| return res |
| |
| def generate_target_memory_section(out, kernel_name, source_dir, features_json): |
| features_path_data = None |
| try: |
| features_path_data = json.loads(open(features_json, 'r').read()) |
| except: |
| pass |
| |
| bin_file_abs = os.path.join(out, kernel_name+'.bin') |
| elf_file_abs = os.path.join(out, kernel_name+'.elf') |
| |
| # First deal with size on flash. These are the symbols flagged as LOAD in objdump output |
| size_out = subprocess.check_output(["objdump", "-hw", elf_file_abs]) |
| loaded_section_total = 0 |
| loaded_section_names = [] |
| loaded_section_names_sizes = {} |
| ram_section_total = 0 |
| ram_section_names = [] |
| ram_section_names_sizes = {} |
| for line in size_out.split('\n'): |
| if "LOAD" in line: |
| loaded_section_total = loaded_section_total + int(line.split()[2], 16) |
| loaded_section_names.append(line.split()[1]) |
| loaded_section_names_sizes[line.split()[1]] = int(line.split()[2], 16) |
| if "ALLOC" in line and "READONLY" not in line and "rodata" not in line and "CODE" not in line: |
| ram_section_total = ram_section_total + int(line.split()[2], 16) |
| ram_section_names.append(line.split()[1]) |
| ram_section_names_sizes[line.split()[1]] = int(line.split()[2], 16) |
| |
| # Actual .bin size, which doesn't not always match section sizes |
| bin_size = os.stat(bin_file_abs).st_size |
| |
| # Get the path associated to each symbol |
| symbols_paths = load_symbols_and_paths(elf_file_abs, source_dir) |
| |
| # A set of helper function for building a simple tree with a path-like |
| # hierarchy. |
| def _insert_one_elem(tree, path, size): |
| splitted_path = path.split('/') |
| cur = None |
| for p in splitted_path: |
| if cur == None: |
| cur = p |
| else: |
| cur = cur + '/' + p |
| if cur in tree: |
| tree[cur] += size |
| else: |
| tree[cur] = size |
| |
| def _parent_for_node(e): |
| parent = "root" if len(e.split('/')) == 1 else e.rsplit('/', 1)[0] |
| if e == "root": |
| parent = None |
| return parent |
| |
| def _childs_for_node(tree, node): |
| res = [] |
| for e in tree: |
| if _parent_for_node(e) == node: |
| res += [e] |
| return res |
| |
| def _siblings_for_node(tree, node): |
| return _childs_for_node(tree, _parent_for_node(node)) |
| |
| def _max_sibling_size(tree, node): |
| siblings = _siblings_for_node(tree, node) |
| return max([tree[e] for e in siblings]) |
| |
| |
| # Extract the list of symbols a second time but this time using the objdump tool |
| # which provides more info as nm |
| symbols_out = subprocess.check_output(["objdump", "-tw", elf_file_abs]) |
| flash_symbols_total = 0 |
| data_nodes = {} |
| data_nodes['root'] = 0 |
| |
| ram_symbols_total = 0 |
| ram_nodes = {} |
| ram_nodes['root'] = 0 |
| for l in symbols_out.split('\n'): |
| line = l[0:9] + "......." + l[16:] |
| fields = line.replace('\t', ' ').split(' ') |
| # Get rid of trailing empty field |
| if len(fields) != 5: |
| continue |
| size = int(fields[3], 16) |
| if fields[2] in loaded_section_names and size != 0: |
| flash_symbols_total += size |
| _insert_one_elem(data_nodes, symbols_paths[fields[4]], size) |
| if fields[2] in ram_section_names and size != 0: |
| ram_symbols_total += size |
| _insert_one_elem(ram_nodes, symbols_paths[fields[4]], size) |
| |
| def _init_features_list_results(features_list): |
| for feature in features_list: |
| _init_feature_results(feature) |
| |
| def _init_feature_results(feature): |
| feature["size"] = 0 |
| # recursive through children |
| for child in feature["children"]: |
| _init_feature_results(child) |
| |
| def _check_all_symbols(symbols_struct, features_list): |
| out = "" |
| sorted_nodes = sorted(symbols_struct.items(), key=operator.itemgetter(0)) |
| named_symbol_filter = re.compile('.*\.[a-zA-Z]+/.*') |
| out_symbols_filter = re.compile('^:/') |
| for symbpath in sorted_nodes: |
| matched = 0 |
| # The files and folders (not matching regex) are discarded |
| # like: folder folder/file.ext |
| is_symbol=named_symbol_filter.match(symbpath[0]) |
| is_generated=out_symbols_filter.match(symbpath[0]) |
| if is_symbol == None and is_generated == None: |
| continue |
| # The symbols inside a file are kept: folder/file.ext/symbol |
| # and unrecognized paths too (":/") |
| for feature in features_list: |
| matched = matched + _does_symbol_matches_feature(symbpath[0], symbpath[1], feature) |
| if matched is 0: |
| out += "UNCATEGORIZED: %s %d<br/>" % (symbpath[0], symbpath[1]) |
| return out |
| |
| def _does_symbol_matches_feature(symbol, size, feature): |
| matched = 0 |
| # check each include-filter in feature |
| for inc_path in feature["folders"]: |
| # filter out if the include-filter is not in the symbol string |
| if inc_path not in symbol: |
| continue |
| # if the symbol match the include-filter, check against exclude-filter |
| is_excluded = 0 |
| for exc_path in feature["excludes"]: |
| if exc_path in symbol: |
| is_excluded = 1 |
| break |
| if is_excluded == 0: |
| matched = 1 |
| feature["size"] = feature["size"] + size |
| # it can only be matched once per feature (add size once) |
| break |
| # check children independently of this feature's result |
| for child in feature["children"]: |
| child_matched = _does_symbol_matches_feature(symbol, size, child) |
| matched = matched + child_matched |
| return matched |
| |
| |
| |
| # Create a simplified tree keeping only the most important contributors |
| # This is used for the pie diagram summary |
| min_parent_size = bin_size/25 |
| min_sibling_size = bin_size/35 |
| tmp = {} |
| for e in data_nodes: |
| if _parent_for_node(e) == None: |
| continue |
| if data_nodes[_parent_for_node(e)] < min_parent_size: |
| continue |
| if _max_sibling_size(data_nodes, e) < min_sibling_size: |
| continue |
| tmp[e] = data_nodes[e] |
| |
| # Keep only final nodes |
| tmp2 = {} |
| for e in tmp: |
| if len(_childs_for_node(tmp, e)) == 0: |
| tmp2[e] = tmp[e] |
| |
| # Group nodes too small in an "other" section |
| filtered_data_nodes = {} |
| for e in tmp2: |
| if tmp[e] < min_sibling_size: |
| k = _parent_for_node(e) + "/(other)" |
| if k in filtered_data_nodes: |
| filtered_data_nodes[k] += tmp[e] |
| else: |
| filtered_data_nodes[k] = tmp[e] |
| else: |
| filtered_data_nodes[e] = tmp[e] |
| |
| |
| def _parent_level_3_at_most(node): |
| e = _parent_for_node(node) |
| while e.count('/')>2: |
| e = _parent_for_node(e) |
| return e |
| |
| return ram_nodes, data_nodes |
| |
| |
| def print_tree(data, total, depth): |
| base = os.environ['ZEPHYR_BASE'] |
| totp = 0 |
| print '{:92s} {:10s} {:8s}'.format(bcolors.FAIL + "Path", "Size", "%" + bcolors.ENDC) |
| print '='*110 |
| for i in sorted(data): |
| p = i.split("/") |
| if depth and len(p) > depth: |
| continue |
| |
| percent = 100 * float(data[i])/float(total) |
| percent_c = percent |
| if len(p) < 2: |
| totp += percent |
| |
| if len(p) > 1: |
| if not os.path.exists(os.path.join(base, i)): |
| s = bcolors.WARNING + p[-1] + bcolors.ENDC |
| else: |
| s = bcolors.OKBLUE + p[-1] + bcolors.ENDC |
| print '{:80s} {:20d} {:8.2f}%'.format(" "*(len(p)-1) + s, data[i], percent_c ) |
| else: |
| print '{:80s} {:20d} {:8.2f}%'.format(bcolors.OKBLUE + i + bcolors.ENDC, data[i], percent_c ) |
| |
| print '='*110 |
| print '{:92d}'.format(total) |
| return totp |
| |
| |
| binary = os.path.join(options.outdir, options.binary + ".elf") |
| |
| if options.outdir and os.path.exists(binary): |
| fp = get_footprint_from_bin_and_statfile("%s/%s.bin" %(options.outdir, options.binary), |
| "%s/%s.stat" %(options.outdir,options.binary), 0, 0 ) |
| base = os.environ['ZEPHYR_BASE'] |
| ram, data = generate_target_memory_section(options.outdir, options.binary, base + '/', None) |
| if options.rom: |
| print_tree(data, fp['total_flash'], options.depth) |
| if options.ram: |
| print_tree(ram, fp['total_ram'], options.depth) |
| |
| else: |
| print "%s does not exist." %(binary) |