EnglishEnglish中文中文اَلْعَرَبِيَّةُاَلْعَرَبِيَّةُDeutschDeutschEspañolEspañolΕλληνικάΕλληνικάFrançaisFrançaisעִבְרִיתעִבְרִיתहिन्दीहिन्दीHrvatskiHrvatskiItalianoItaliano日本語日本語한국어한국어MalayMalayNederlandsNederlandsPortuguêsPortuguêsрусскийрусскийภาษาไทยภาษาไทยTürkTürkTiếng ViệtTiếng Việt粵語粵語
Learn
FAQs
Frequently asked questions by various stakeholders
Why Classic?
Start here to get the lowdown on Ethereum Classic's reason for being and unique value proposition
Knowledge
Further reading on the foundations that underpin ETC
Videos
A collection of videos and podcasts to keep you informed on ETC concepts and happenings
Support ETC by helping to translate this website!
Ethereum Classic Blog

Ethereum Classic Recursive Length Prefix Encoding

Christian Seberino
Apps, Development, Education

QShEODs

Ethereum Classic (ETC) uses Recursive Length Prefix (RLP) encoding to store and send data structures. I will describe RLP and how it is used in ETC.

Introduction

1 y8SOO9LmGSUWnSGG1vidg

Serialization is the process of encoding data structures into byte sequences. It is also referred to as marshalling and pickling. Serialization is necessary when storing and sending data structures.

RLP is a serialization format created by Ethereum developers for all data structures such as accounts, transactions and blocks. RLP is simpler than the alternatives such as Extensible Markup Language (XML), JavaScript Object Notation (JSON), Binary JSON (BSON), Protocol Buffers and Bencode.

RLP is also consistent. Identical objects are always converted to identical byte sequences. This is not true of all serialization formats. For example, when encoding sets of key value pairs, some schemes do not specify an ordering for the keys.

Details

lZK7AV3

RLP operates on byte sequences and lists. Lists can contain byte sequences and other lists. The interpretation of all inputs is handled by other protocols. For byte sequences, small headers are added which depend on the length. For lists, the elements are encoded separately and concatenated. As with byte sequences, small headers are added which depend on the length. Lastly, all lengths are encoded in big endian format.

Code

NpkXLnm

Here are Python functions which implement RLP encoding and decoding:

#!/usr/bin/env python3

import math

N_BITS_PER_BYTE = 8

def n_bytes(integer):
        """
        Finds the numbers of bytes needed to represent integers.
        """

        return math.ceil(integer.bit_length() / N_BITS_PER_BYTE)

def get_len(input, extra):
        """
        Finds the lengths of the longest inputs using the given extra values.
        """

        n_bytes = input[0] - extra

        return 1 + n_bytes + int.from_bytes(input[2:2 + n_bytes], "big")

def rlp_encode(input):
        """
        Recursive Length Prefix encodes inputs.
        """

        if isinstance(input, bytes):
                body = input
                if   (len(body) == 1) and (body[0] < 128):
                        header = bytes([])
                elif len(body) < 56:
                        header = bytes([len(body) + 128])
                else:
                        len_   = len(body)
                        len_   = len_.to_bytes(n_bytes(len_), "big")
                        header = bytes([len(len_) + 183]) + len_
                result = header + body
        else:
                body = bytes([])
                for e in input:
                        body += rlp_encode(e)
                if len(body) < 56:
                        header = bytes([len(body) + 192])
                else:
                        len_   = len(body)
                        len_   = len_.to_bytes(n_bytes(len_), "big")
                        header = bytes([len(len_) + 247]) + len_
                result = header + body

        return result

def rlp_decode(input):
        """
        Recursive Length Prefix decodes inputs.
        """

        if   input[0] < 128:
                result = input
        elif input[0] < 184:
                result = input[1:]
        elif input[0] < 192:
                result = input[1 + (input[0] - 183):]
        else:
                result = []
                if input[0] < 248:
                        input = input[1:]
                else:
                        input = input[1 + (input[0] - 247):]
                while input:
                        if   input[0] < 128:
                                len_ = 1
                        elif input[0] < 184:
                                len_ = 1 + (input[0] - 128)
                        elif input[0] < 192:
                                len_ = get_len(input, 183)
                        elif input[0] < 248:
                                len_ = 1 + (input[0] - 192)
                        else:
                                len_ = get_len(input, 247)
                        result.append(rlp_decode(input[:len_]))
                        input = input[len_:]

        return result

Notice that the functions are recursive. Notice also that the functions work for inputs requiring up to about 18 million terabytes. Here are examples of their usage:
>>> rlp_encode(b"A")
b'A'

>>> rlp_encode(b"12345")
b'\x8512345'

>>> rlp_encode(20 * b"12345")
b'\xb8d1234512345123451234512345123451234512345123451234512345123451234512345123451234512345123451234512345'

>>> rlp_encode([b"12345"])
b'\xc6\x8512345'

>>> rlp_encode([b"abcde", 3 * [b"12345"], [b"fghij"], b"67890", 4 * [b"klmno"]])
b'\xf8\x85abcde\xd2\x8512345\x8512345\x8512345\xc6\x85fghij\x8567890\xd8\x85klmno\x85klmno\x85klmno\x85klmno'

>>> rlp_decode(b"\x8512345")
b'12345'

>>> rlp_decode(b"\xc6\x8512345")
[b'12345']

>>> rlp_decode(b"\xf8\x85abcde\xd2\x8512345\x8512345\x8512345\xc6\x85fghij\x8567890\xd8\x85klmno\x85klmno\x85klmno\x85klmno")
[b'abcde', [b'12345', b'12345', b'12345'], [b'fghij'], b'67890', [b'klmno', b'klmno', b'klmno', b'klmno']]

Conclusion

iI2jnWZ

RLP is an elegant and approachable serialization format used extensively by ETC. It can be quickly mastered thereby illuminating this important aspect of the system.

Feedback

You can contact me by clicking any of these icons:

0eoFC6QOWZ  bCngK

0i3CwTFEKUnKYHMf0

0HQj6HSHxE7pkIBjk

Acknowledgements

I would like to thank IOHK (Input Output Hong Kong) for funding this effort.

License

0hocpUZXBcjzNJeQ2

This work is licensed under the Creative Commons Attribution ShareAlike 4.0 International License.

This page exists thanks in part to the following contributors:


cseberino
cseberino
  • EnglishEnglish
  • 中文中文
  • اَلْعَرَبِيَّةُاَلْعَرَبِيَّةُ
  • DeutschDeutsch
  • EspañolEspañol
  • ΕλληνικάΕλληνικά
  • FrançaisFrançais
  • עִבְרִיתעִבְרִית
  • हिन्दीहिन्दी
  • HrvatskiHrvatski
  • ItalianoItaliano
  • 日本語日本語
  • 한국어한국어
  • MalayMalay
  • NederlandsNederlands
  • PortuguêsPortuguês
  • русскийрусский
  • ภาษาไทยภาษาไทย
  • TürkTürk
  • Tiếng ViệtTiếng Việt
  • 粵語粵語
Add ETC to MetaMask
The ETC community is active on Discord
Discord
Discord
ETC Coop Discord
ETC Coop Discord
eth_classic Twitter
eth_classic Twitter
ETC_Network Twitter
ETC_Network Twitter
Github
Github
ETC Labs Github
ETC Labs Github
Reddit
Reddit
This site is powered by Netlify

Learn

  • FAQs
  • Why Classic?
  • Knowledge
  • Videos

Made with <3 for the Original Ethereum Vision

The content on this website is user-generated and solely for informational purposes. Do not interpret any content as an endorsement of any product or service. There's "no official anything" in Ethereum Classic. Always do your own research, and remember: don't trust, verify!