Marco Zecchini
/
Example_RTOS
Rtos API example
mbed-os/tools/flash_algo/flash_algo.py
- Committer:
- marcozecchini
- Date:
- 2019-02-23
- Revision:
- 0:9fca2b23d0ba
File content as of revision 0:9fca2b23d0ba:
#!/usr/bin/env python """ mbed Copyright (c) 2017-2017 ARM Limited 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. """ from __future__ import print_function import os import struct import binascii import argparse import logging import StringIO import jinja2 from collections import namedtuple from itertools import count from elftools.common.py3compat import bytes2str from elftools.elf.elffile import ELFFile from elftools.elf.sections import SymbolTableSection logger = logging.getLogger(__name__) logger.addHandler(logging.NullHandler()) def main(): parser = argparse.ArgumentParser(description="Algo Extracter") parser.add_argument("input", help="File to extract flash algo from") parser.add_argument("template", default="py_blob.tmpl", help="Template to use") parser.add_argument("output", help="Output file") args = parser.parse_args() with open(args.input, "rb") as file_handle: data = file_handle.read() algo = PackFlashAlgo(data) algo.process_template(args.template, args.output) class PackFlashAlgo(object): """ Class to wrap a flash algo This class is intended to provide easy access to the information provided by a flash algorithm, such as symbols and the flash algorithm itself. """ REQUIRED_SYMBOLS = set([ "Init", "UnInit", "EraseSector", "ProgramPage", ]) EXTRA_SYMBOLS = set([ "BlankCheck", "EraseChip", "Verify", ]) def __init__(self, data): """Construct a PackFlashAlgorithm from an ElfFileSimple""" self.elf = ElfFileSimple(data) self.flash_info = PackFlashInfo(self.elf) self.flash_start = self.flash_info.start self.flash_size = self.flash_info.size self.page_size = self.flash_info.page_size self.sector_sizes = self.flash_info.sector_info_list symbols = {} symbols.update(_extract_symbols(self.elf, self.REQUIRED_SYMBOLS)) symbols.update(_extract_symbols(self.elf, self.EXTRA_SYMBOLS, default=0xFFFFFFFF)) self.symbols = symbols sections_to_find = ( ("PrgCode", "SHT_PROGBITS"), ("PrgData", "SHT_PROGBITS"), ("PrgData", "SHT_NOBITS"), ) ro_rw_zi = _find_sections(self.elf, sections_to_find) ro_rw_zi = _algo_fill_zi_if_missing(ro_rw_zi) error_msg = _algo_check_for_section_problems(ro_rw_zi) if error_msg is not None: raise Exception(error_msg) sect_ro, sect_rw, sect_zi = ro_rw_zi self.ro_start = sect_ro["sh_addr"] self.ro_size = sect_ro["sh_size"] self.rw_start = sect_rw["sh_addr"] self.rw_size = sect_rw["sh_size"] self.zi_start = sect_zi["sh_addr"] self.zi_size = sect_zi["sh_size"] self.algo_data = _create_algo_bin(ro_rw_zi) def format_algo_data(self, spaces, group_size, fmt): """" Return a string representing algo_data suitable for use in a template The string is intended for use in a template. :param spaces: The number of leading spaces for each line :param group_size: number of elements per line (element type depends of format) :param fmt: - format to create - can be either "hex" or "c" """ padding = " " * spaces if fmt == "hex": blob = binascii.b2a_hex(self.algo_data) line_list = [] for i in xrange(0, len(blob), group_size): line_list.append('"' + blob[i:i + group_size] + '"') return ("\n" + padding).join(line_list) elif fmt == "c": blob = self.algo_data[:] pad_size = 0 if len(blob) % 4 == 0 else 4 - len(blob) % 4 blob = blob + "\x00" * pad_size integer_list = struct.unpack("<" + "L" * (len(blob) / 4), blob) line_list = [] for pos in range(0, len(integer_list), group_size): group = ["0x%08x" % value for value in integer_list[pos:pos + group_size]] line_list.append(", ".join(group)) return (",\n" + padding).join(line_list) else: raise Exception("Unsupported format %s" % fmt) def process_template(self, template_path, output_path, data_dict=None): """ Generate output from the supplied template All the public methods and fields of this class can be accessed from the template via "algo". :param template_path: Relative or absolute file path to the template :param output_path: Relative or absolute file path to create :param data_dict: Additional data to use when generating """ if data_dict is None: data_dict = {} else: assert isinstance(data_dict, dict) data_dict = dict(data_dict) assert "algo" not in data_dict, "algo already set by user data" data_dict["algo"] = self with open(template_path) as file_handle: template_text = file_handle.read() template = jinja2.Template(template_text) target_text = template.render(data_dict) with open(output_path, "wb") as file_handle: file_handle.write(target_text) def _extract_symbols(simple_elf, symbols, default=None): """Fill 'symbols' field with required flash algo symbols""" to_ret = {} for symbol in symbols: if symbol not in simple_elf.symbols: if default is not None: to_ret[symbol] = default continue raise Exception("Missing symbol %s" % symbol) to_ret[symbol] = simple_elf.symbols[symbol].value return to_ret def _find_sections(elf, name_type_pairs): """Return a list of sections the same length and order of the input list""" sections = [None] * len(name_type_pairs) for section in elf.iter_sections(): section_name = bytes2str(section.name) section_type = section["sh_type"] for i, name_and_type in enumerate(name_type_pairs): if name_and_type != (section_name, section_type): continue if sections[i] is not None: raise Exception("Elf contains duplicate section %s attr %s" % (section_name, section_type)) sections[i] = section return sections def _algo_fill_zi_if_missing(ro_rw_zi): """Create an empty zi section if it is missing""" s_ro, s_rw, s_zi = ro_rw_zi if s_rw is None: return ro_rw_zi if s_zi is not None: return ro_rw_zi s_zi = { "sh_addr": s_rw["sh_addr"] + s_rw["sh_size"], "sh_size": 0 } return s_ro, s_rw, s_zi def _algo_check_for_section_problems(ro_rw_zi): """Return a string describing any errors with the layout or None if good""" s_ro, s_rw, s_zi = ro_rw_zi if s_ro is None: return "RO section is missing" if s_rw is None: return "RW section is missing" if s_zi is None: return "ZI section is missing" if s_ro["sh_addr"] != 0: return "RO section does not start at address 0" if s_ro["sh_addr"] + s_ro["sh_size"] != s_rw["sh_addr"]: return "RW section does not follow RO section" if s_rw["sh_addr"] + s_rw["sh_size"] != s_zi["sh_addr"]: return "ZI section does not follow RW section" return None def _create_algo_bin(ro_rw_zi): """Create a binary blob of the flash algo which can execute from ram""" sect_ro, sect_rw, sect_zi = ro_rw_zi algo_size = sect_ro["sh_size"] + sect_rw["sh_size"] + sect_zi["sh_size"] algo_data = bytearray(algo_size) for section in (sect_ro, sect_rw): start = section["sh_addr"] size = section["sh_size"] data = section.data() assert len(data) == size algo_data[start:start + size] = data return algo_data class PackFlashInfo(object): """Wrapper class for the non-executable information in an FLM file""" FLASH_DEVICE_STRUCT = "<H128sHLLLLBxxxLL" FLASH_SECTORS_STRUCT = "<LL" FLASH_SECTORS_STRUCT_SIZE = struct.calcsize(FLASH_SECTORS_STRUCT) SECTOR_END = 0xFFFFFFFF def __init__(self, elf_simple): dev_info = elf_simple.symbols["FlashDevice"] info_start = dev_info.value info_size = struct.calcsize(self.FLASH_DEVICE_STRUCT) data = elf_simple.read(info_start, info_size) values = struct.unpack(self.FLASH_DEVICE_STRUCT, data) self.version = values[0] self.name = values[1].strip("\x00") self.type = values[2] self.start = values[3] self.size = values[4] self.page_size = values[5] self.value_empty = values[7] self.prog_timeout_ms = values[8] self.erase_timeout_ms = values[9] sector_gen = self._sector_and_sz_itr(elf_simple, info_start + info_size) self.sector_info_list = list(sector_gen) def __str__(self): desc = "" desc += "Flash Device:" + os.linesep desc += " name=%s" % self.name + os.linesep desc += " version=0x%x" % self.version + os.linesep desc += " type=%i" % self.type + os.linesep desc += " start=0x%x" % self.start + os.linesep desc += " size=0x%x" % self.size + os.linesep desc += " page_size=0x%x" % self.page_size + os.linesep desc += " value_empty=0x%x" % self.value_empty + os.linesep desc += " prog_timeout_ms=%i" % self.prog_timeout_ms + os.linesep desc += " erase_timeout_ms=%i" % self.erase_timeout_ms + os.linesep desc += " sectors:" + os.linesep for sector_start, sector_size in self.sector_info_list: desc += (" start=0x%x, size=0x%x" % (sector_start, sector_size) + os.linesep) return desc def _sector_and_sz_itr(self, elf_simple, data_start): """Iterator which returns starting address and sector size""" for entry_start in count(data_start, self.FLASH_SECTORS_STRUCT_SIZE): data = elf_simple.read(entry_start, self.FLASH_SECTORS_STRUCT_SIZE) size, start = struct.unpack(self.FLASH_SECTORS_STRUCT, data) start_and_size = start, size if start_and_size == (self.SECTOR_END, self.SECTOR_END): return yield start_and_size SymbolSimple = namedtuple("SymbolSimple", "name, value, size") class ElfFileSimple(ELFFile): """Wrapper for elf object which allows easy access to symbols and rom""" def __init__(self, data): """Construct a ElfFileSimple from bytes or a bytearray""" super(ElfFileSimple, self).__init__(StringIO.StringIO(data)) self.symbols = self._read_symbol_table() def _read_symbol_table(self): """Read the symbol table into the field "symbols" for easy use""" section = self.get_section_by_name(b".symtab") if not section: raise Exception("Missing symbol table") if not isinstance(section, SymbolTableSection): raise Exception("Invalid symbol table section") symbols = {} for symbol in section.iter_symbols(): name_str = bytes2str(symbol.name) if name_str in symbols: logging.debug("Duplicate symbol %s", name_str) symbols[name_str] = SymbolSimple(name_str, symbol["st_value"], symbol["st_size"]) return symbols def read(self, addr, size): """Read program data from the elf file :param addr: physical address (load address) to read from :param size: number of bytes to read :return: Requested data or None if address is unmapped """ for segment in self.iter_segments(): seg_addr = segment["p_paddr"] seg_size = min(segment["p_memsz"], segment["p_filesz"]) if addr >= seg_addr + seg_size: continue if addr + size <= seg_addr: continue # There is at least some overlap if addr >= seg_addr and addr + size <= seg_addr + seg_size: # Region is fully contained data = segment.data() start = addr - seg_addr return data[start:start + size] if __name__ == '__main__': main()