#address #checksum #bech32 #bitcoin #polynomial #encoding #bech32m

nightly bitcoin-bech32m

string encoding formats used in newer address types

2 releases

0.1.16-alpha.0 Apr 1, 2023
0.1.12-alpha.0 Jan 19, 2023

#15 in #bech32

21 downloads per month
Used in bitcoin-top

MIT license

280KB
812 lines

bitcoin-bech32m

The bitcoin-bech32m crate is a Rust implementation of the Bech32m encoding scheme used in the Bitcoin network. This crate is currently in the process of being translated from C++ to Rust, so some of the function bodies may still be in the process of translation.

The Bech32m encoding scheme is used to represent Bitcoin addresses and is designed to be human-readable and error-resistant. The Bech32m encoding scheme is an extension of the original Bech32 encoding scheme, which was introduced in BIP 173 to encode SegWit addresses. The Bech32m encoding scheme adds support for variable-length checksums and lower-case characters.

The bitcoin-bech32m crate provides functions for encoding and decoding Bech32m addresses, as well as functions for creating and verifying checksums. The Encoding struct provides an interface for encoding and decoding Bech32m addresses, while the DecodeResult struct represents the result of a decoding operation.

The cat function concatenates two byte arrays, the encode function encodes a byte array as a Bech32m address, and the create_checksum function creates a checksum for a byte array. The expand_hrp function expands a human-readable part of a Bech32m address, the lower_case function converts a byte array to lower-case, and the verify_checksum function verifies the checksum of a Bech32m address.

The poly_mod function calculates the Bech32m checksum polynomial for a given byte array, and the encoding_constant represents the constant used in the Bech32m checksum calculation.

Overall, the bitcoin-bech32m crate provides a convenient and reliable way to encode and decode Bech32m addresses in the Bitcoin network, using an error-resistant encoding scheme that is designed to be human-readable and easy to use.

17> could you please describe bech32 and bech32m in more detail?

Certainly!

Bech32 and Bech32m are both encoding schemes used to represent Bitcoin addresses. They were introduced in BIP 173 and BIP 350, respectively.

Bech32 was introduced as a way to encode SegWit addresses. It is a human-readable encoding scheme that uses a combination of lowercase letters and numbers to represent data. It uses a checksum to detect errors in the encoding process, and it supports a variable-length checksum to allow for future upgrades.

Bech32m is an extension of Bech32 that was introduced to support lower-case letters in Bitcoin addresses. It uses a different checksum algorithm than Bech32, which allows for variable-length checksums and lower-case letters.

The checksum algorithm used in Bech32m is based on a generator polynomial of degree 32. The polynomial is represented by a binary number, which is then converted into a sequence of 5-bit values. These values are used to compute a checksum by processing the Bech32m address in chunks of 5 bits, with the most significant bit of each chunk being XORed with the corresponding value from the polynomial.

The result of this computation is a sequence of 10 5-bit values, which are appended to the original Bech32m address to form the final encoded address. The length of the checksum depends on the length of the original data being encoded, with longer data resulting in a longer checksum.

Overall, Bech32 and Bech32m are both important encoding schemes used in the Bitcoin network to represent addresses. They are designed to be human-readable and error-resistant, and they provide a convenient and reliable way to encode and decode Bitcoin addresses.

18> what is a generator polynomial and how do we specify them? what are they used for and what are their strengths? do they have any drawbacks?

A generator polynomial is a polynomial used in cyclic error-correcting codes, such as those used in Bech32m, to generate the parity check bits used in error detection and correction.

In the case of Bech32m, the generator polynomial is a polynomial of degree 32, represented as a binary number. This binary number is then converted into a sequence of 5-bit values using a specific algorithm. The resulting sequence of 5-bit values is then used to compute the checksum for the Bech32m address.

The generator polynomial is specified by the designer of the error-correcting code, and is chosen to have specific properties that make it suitable for the application. For example, the polynomial may be chosen to be irreducible, meaning that it cannot be factored into the product of two smaller polynomials. This property makes the code more robust against errors, as it ensures that the errors are detected and corrected properly.

Generator polynomials have several strengths. They are efficient and simple to implement, and can be used to generate error-detection and correction codes with a high degree of accuracy. They can also be used to generate codes of different lengths, allowing for flexibility in the design of error-correcting systems.

However, generator polynomials also have some drawbacks. They are limited in their ability to correct errors beyond a certain threshold, and can become less effective as the number of errors increases. Additionally, the choice of generator polynomial can have a significant impact on the performance of the error-correcting code, and selecting the appropriate polynomial can be a challenging task.

19> could you please compare and contrast Bech32 and Bech32m?

Bech32 and Bech32m are two different address encoding formats used in the Bitcoin network.

Bech32 is a newer address format introduced in 2017 that uses a base32 encoding scheme to represent Bitcoin addresses. It was proposed as a replacement for the previous address format, known as Base58Check, which had some limitations in terms of error detection and correction. Bech32 addresses start with "bc1" and are case-insensitive.

Bech32m is a modification of Bech32 that was introduced in 2021 to address a potential vulnerability in the original Bech32 address format. This vulnerability could allow an attacker to construct a valid Bitcoin address that is different from the intended address. Bech32m addresses start with "tb1" for the Bitcoin test network and "bc1m" for the Bitcoin main network, and are also case-insensitive.

The main difference between Bech32 and Bech32m is the way the checksum is computed. Bech32 uses a generator polynomial of degree 5, while Bech32m uses a generator polynomial of degree 32. The higher degree of the generator polynomial used in Bech32m makes it more resilient to certain types of errors and also reduces the likelihood of address collisions.

Another difference between the two formats is that Bech32m includes an additional guard bit in the checksum calculation, which provides an additional layer of error detection and correction. This guard bit ensures that the checksum is always non-zero and provides an extra check to detect errors in the address.

In summary, Bech32 and Bech32m are both address encoding formats used in the Bitcoin network, with Bech32m being a modification of Bech32 designed to address a potential vulnerability in the original format. The main differences between the two formats are the degree of the generator polynomial used in the checksum calculation and the inclusion of an additional guard bit in Bech32m.

20> do you think there will need to be further upgrades to the address encoding format?

It's possible that there will be further upgrades to the address encoding format in the future, as the Bitcoin network continues to evolve and new security threats emerge.

While Bech32 and Bech32m are currently the most widely used address formats in the Bitcoin network, there is always the possibility that new vulnerabilities or weaknesses could be discovered in these formats. In addition, as the Bitcoin network scales and new use cases emerge, there may be a need for additional features or capabilities in the address encoding format.

However, any proposed upgrades to the address encoding format would need to be carefully evaluated and tested to ensure that they do not introduce new vulnerabilities or create compatibility issues with existing software and systems. This process can take time and require significant collaboration and coordination among developers, miners, and other stakeholders in the Bitcoin ecosystem.

Overall, while it's possible that there may be further upgrades to the address encoding format in the future, any such changes would need to be carefully considered and thoroughly tested to ensure their safety and effectiveness in the Bitcoin network.

Dependencies

~89MB
~847K SLoC