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A tooling for flashable parameter data container generation

Project description

Pargen - A Tool for Flashable Parameter Container Creation

Pargen is an embedded development tool for generating parameters values that can be stored in flash memory and maintained independently from the application. It allows to alter/update parameter values without recompilations.

License Python package

Concept and Features

Concept

  • Read input from a schema validated XML file
  • Generate C-Source stubs for embedding into the application source amd testing environments
  • Generate Intel Hex files for flashing with a programmer
  • Generate GNU linker include file for mapping the parameter to absolute addresses

Installation

The package is available on Pypi and can be installed using

pip install flashcontainer

A python 3.8 or higher version is required.

The parameter generator tool can then by called on cmdline using

$ pargen -h
usage: pargen [-h] [--ihex] [--csrc] [--gld] [--a2l] [--pyhexdump] [--destdir directory] [--filename basename] [--static] [--modify name=value] [--version] file

pargen 0.4.0: A tool for generating flashable parameter container.

positional arguments:
  file                  name of the XML parameter definition file

optional arguments:
  -h, --help            show this help message and exit
  --ihex                generate intelhex file
  --csrc                generate c/c++ header and source files
  --gld                 generate GNU linker include file for parameter symbol generation
  --a2l                 generate A2L parameter description file
  --pyhexdump           generate pyHexDump print configuration file
  --destdir directory, -o directory
                        specify output directory for generated files
  --filename basename, -f basename
                        set basename for generated files
  --static, -s          create static comment output without dynamic elements like date and time
  --modify name=value, -m name=value
                        modify parameter value using name=value notation
  --version             show program's version number and exit

Copyright (c) 2022-2023 Haju Schulz <haju.schulz@online.de>. Visit https://github.com/nhjschulz/flashcontainer for full documentation and examples.

The Pargen Developing page on Github explains how to use unreleased development builds or how to setup a development environment for Pargen.

XML Definitions File

The flash container configuration for Pargen is a XML definition file with the format explained below.

TL;DR

The examples folder shows how to configure Pargen for various use cases. Most of it is likely self explanatory. Read the examples.md files inside the examples folder to learn more about them. To understand Pargen's XML capabilities in depth, read on.

XML Configuration File Anatomy

The XML follows an XSD-schema defined in pargen_1.0.xsd. It is highly recommended to use an XML editor with schema validation support to avoid or detect validations already while editing. Visual Studio Code is a perfect choice, given the "XML Language Support" extension from Red Hat is installed. This extensions brings validation and "IntelliSense" to editing XML files.

The file defines the following data element hierarchy. The "..." lines mean that the preceding element may appear multiple times:

  <pd:Container>
    <pd:blocks>
      <pd:block>
        <pd:parameter> or <pd:crc>
        ...
      </pd:block>
      ...
    <pd:blocks>
    ...
  </pd:Container>

XML Root Element

The XML file uses XSD schema validation and a namespace. This requires the following (static) XML element to be used as the root XML element at the beginning of the file:

?xml version="1.0" encoding="utf-8"?>
<pd:pargen xmlns:pd="http://nhjschulz.github.io/1.0/pargen"
    xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
    xsi:schemaLocation="http://nhjschulz.github.io/1.0/pargen http://nhjschulz.github.io/xsd/pargen_1.0.xsd" >

Container Element

The top level configuration element is the container. A container maps its parameter blocks to absolute addresses by the at attribute. Address attributes inside block elements are offsets to the at attribute value.

Container Element Attributes

Attribute Description optional default
name The container name. No
at Absolute address of the container. No

Container Child Elements

Element Description Multiplicity
blocks Parent Element for blocks 1

Example Container Element

<pd:container name="UCBRange" at="0xAF400000">
  <pd:blocks>
  ....
  </pd:blocks>
</pd:container>

Block Element

A block element defines a contiguous memory area inside a container. Blocks contain an optional header and parameters at unique offsets inside the block memory range. Gaps between parameters are filled with the byte value specified using the 'fill' attribute. A container may have 1 to many block children inside a blocks element.

Block Attributes

Attribute Description optional default
name The block name. No
offset Memory start offset inside container. Value may be "." to use the next free offset inside the container. No
length Number of bytes covered by this block No
align block alignment to the next 1,2,4,8 bytes boundary Yes 1
fill byte value used to fill gaps. Yes 0x00
endianness LE or BE: Little or or big endian byte order Yes LE

Block Child Elements

Element Description Multiplicity
comment Optional comment text for this block 0..1
header Optional header with id, version and length information 0..1
data Parent element for block parameter 1

Block Header Element

Pargen blocks may contain a header at the beginning of the block memory area. This optional header contains block identification, version and length information. The header supports parameter validation to verify correctness and compatibility with the using application during runtime. The safety example in the examples folder shows how to use the header in combination with a CRC for this purpose.

The header data is a 16 byte long data structure with the following layout:

struct sruct_pargen_header_type
{
    uint16_t id;        /* from id header attribute */
    uint16_t major;     /* from major header attribute */
    uint16_t minor;     /* from minor header attribute */
    uint16_t dataver;   /* from version header attribute */
    uint32_t reserved;  /* reserved = 0x00000000 */
    uint32_t length;    /* from length block attribute */
};

Application can freely decide how to use the id, major, minor and dataver header fields. The proposed usage is as follows:

  • id - A unique id to identify the blocks purpose. (Example: 1:CAN Bus settings, 2 :Motor parameters, ...)
  • Major.Minor - A version pair defining the layout of the block
  • dataver - The version or build number of the parameter set

The header data is internally handled as a parameter. Space for any further parameter starts at offset 16 (0x10) if the header is used.

Example Block Element

<pd:block offset="0x0000" name="UCB_BMHD0" length="0x1F4" fill="0x00" endianness="LE">
    <pd:header id="0x0A" major="1" minor="0" version="1"></pd:header>
    <pd:comment>Aurix Bootmode Headers</pd:comment>
    <pd:data>
      ....
    </pd:data>
</pd:block>

Parameter Element

A parameter element defines a single parameter inside a block. Blocks may have one to many parameter elements.

Parameter Element Attributes

Attribute Description optional default
offset Memory start offset inside block. Value may be "." to use the next free offset inside the block. No
name The parameter name. No
type Parameter type, one of [u]int{bits} with bits one of 8,16,32,64 or float32,float64 or utf8 No
align Parameter offset alignment to the next 1,2,4,8 bytes boundary Yes 1

Parameter Child Elements

Element Description Multiplicity
comment Optional comment text for this parameter 0..1
value The parameter value 1

Parameter Element Example

<pd:param offset="0x004" name="STAD" type="uint32">
  <pd:comment>Application entry point address</pd:comment>
  <pd:value>0x80028000</pd:value>

Parameter Value Element

The value element of a parameter holds the parameter value inside its text element using a JSON style syntax. The following subset of JSON definitions are supported:

Value type Examples
Integer values in decimal or hexadecimal 1, -2, 0xABCDEF
Floating point variables 3.141, 1E-005
Strings in double quotes "Hello world!"
One-dimensional arrays [1, 2, 3, 4, 5, 6]

Crc Element

The crc element defines an integer parameter. The difference to a normal integer parameter is the automatic value calculation using a crc algorithm. Instead of a parameter value child element, memory and config elements are used to define crc calculation parameters.

Crc Element Attributes

Attribute Description optional default
offset Memory start offset inside block. Value may be "." to use the next free offset inside the block No
name The crc parameter name. No
type Parameter type, one of uint{bits} with bits one of 8,16,32,64 No
align Parameter offset alignment to the next 1,2,4,8 bytes boundary Yes 1

Crc Child Elements

Element Description Multiplicity
comment Optional comment text for this parameter 0..1
memory The crc memory range and access method 1
config The optional crc computation parameter 0..1

Crc Memory Element

The memory element defines the memory range used to calculate the crc and the access method to this memory range if byte swapping is needed. The bytes at the range boundaries are included into the crc calculation.

Attribute Description optional default
from Start address for crc calculation No
to End address for crc calculation. The value may be "." to represent an address right before the crc offset. No
access Bit width in case of swapping (8,16,32,64) yes 8
swap Enable bytes swapping using access size Yes false

Crc Config Element

The config element defines the crc calculation parameters to enable arbitrary crc methods. The values for common used crc methods can be taken from this crc catalog page. The default values select the IEEE802.3 crc calculation also known as CRC-32. Note that the bit size of the crc is not part of these parameters, but derived from the type attribute of the crc element.

Attribute Description optional default
polynomial polynomial coefficients yes 0x04C11DB7
init Start value, usual 0 or -1 yes 0xFFFFFFFF
rev_in Process bytes MSB(false) or LSB(true) first. yes true
rev_out Enable reflection of final crc result Yes true
final_xor Perform final XOR of the crc yes true

Crc Element Example

<pd:crc offset="0x008" name="CRCBMHD" type="uint32">
  <pd:memory from="0x0000" to="0x0007" access="32" swap="true"/>
  <pd:config polynomial="0x04C11DB7" init="0xFFFFFFFF" rev_in="true" rev_out="true" final_xor="true" ></pd:config>
</pd:crc>

Issues, Ideas And Bugs

If you have further ideas or you found some bugs, great! Create an issue or if you are able and willing to fix it by yourself, clone the repository and create a pull request.

Used Non Standard Python Libraries

The project uses the following non standard python libraries:

Library Purpose License
lxml XML parsing and validation BSD-3-Clause
intelhex intel hex file generation BSD
json5 JSON read and write (with hexadecimal number support) Apache
toml Accessing toml file content MIT

License

The whole source code is published under the BSD 3-Clause License. Consider also the different licenses of used third party libraries too!

Contribution

We welcome contribution, but unless you explicitly state otherwise: Any contribution intentionally submitted for inclusion in the work by you, shall be licensed as above, without any additional terms or conditions.

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