---
type: article
identifier: python-regex-homoglyphs
title: Patching Python's regex AST for confusable homoglyphs
description: Exploiting the re module's parsing and compiling methods to check for "confusable homoglyphs" and create a better automoderator.
datestring: 2023-03-18
banner_image: /static/images/futaba-filter.jpg
links:
futaba: https://github.com/strinking/futaba
confusable-homoglyphs: https://pypi.org/project/confusable-homoglyphs/
Python re module: https://docs.python.org/3/library/re.html
Scunthorpe problem: https://en.wikipedia.org/wiki/Scunthorpe_problem
Abstract Syntax Tree (AST): https://en.wikipedia.org/wiki/Abstract_syntax_tree
---
A couple years ago I contributed to an open source Discord
[bot](https://github.com/strinking/futaba) designed by a public computer
programming community I’m part of. As with most popular Discord bots, it
incorporates its own filter to prohibit unwanted language. However, to ensure
coverage of messages like `as𝕕f` (notice non-ASCII `𝕕`) in case it’s told to
filter `asdf` (an ASCII-only string), the bot makes use of the
[confusable_homoglyphs](https://pypi.org/project/confusable-homoglyphs/) Python
package to automatically expand an inputted filter string to cover these
non-ASCII edge cases.
Originally, the bot used Python's native string manipulation to convert the
inputted filter string into a Python [regular
expression](https://docs.python.org/3/library/re.html) string that matches for
each original character as well as each character's confusable homoglyphs
(similar-looking non-ASCII characters). For example, the inputted filter string
`asdf` was converted by the bot into the following regular expression:
```bash
[a⍺a𝐚𝑎𝒂𝒶𝓪𝔞𝕒𝖆𝖺𝗮𝘢𝙖𝚊ɑα𝛂𝛼𝜶𝝰𝞪а][ss𝐬𝑠𝒔𝓈𝓼𝔰𝕤𝖘𝗌𝘀𝘴𝙨𝚜ꜱƽѕꮪ𑣁𐑈][dⅾⅆ𝐝𝑑𝒅𝒹𝓭𝔡𝕕𝖉𝖽𝗱𝘥𝙙𝚍ԁᏧᑯꓒ][f𝐟𝑓𝒇𝒻𝓯𝔣𝕗𝖋𝖿𝗳𝘧𝙛𝚏ꬵꞙſẝք]
```
This regular expression uses character sets to match one instance each of the
original character or its confusable homoglyphs. In other words, it has the
ability to catch any recognizable rendition of a word using uncommon non-ASCII
characters. This was really nice, because it meant the bot could catch most
edge cases automatically. Unfortunately, however...
## The problem
Using the method of regex generation described above precludes the use of
arbitrary regex patterns, which would help in looking at context to prevent
[false positives](https://en.wikipedia.org/wiki/Scunthorpe_problem). When
expanding filter strings, the bot could not differentiate between literal
characters and special regex tokens. So, instead of the valid regular
expression string `^asdf(.*)$` (which matches anything following "asdf", only
if "asdf" is at the beginning of the message) being converted into the
following, preserving special regex tokens as desired...
```bash
^[a⍺a𝐚𝑎𝒂𝒶𝓪𝔞𝕒𝖆𝖺𝗮𝘢𝙖𝚊ɑα𝛂𝛼𝜶𝝰𝞪а][ss𝐬𝑠𝒔𝓈𝓼𝔰𝕤𝖘𝗌𝘀𝘴𝙨𝚜ꜱƽѕꮪ𑣁𐑈][dⅾⅆ𝐝𝑑𝒅𝒹𝓭𝔡𝕕𝖉𝖽𝗱𝘥𝙙𝚍ԁᏧᑯꓒ][f𝐟𝑓𝒇𝒻𝓯𝔣𝕗𝖋𝖿𝗳𝘧𝙛𝚏ꬵꞙſẝք](.*)$
```
...it would convert into this, mangling the original intended regex string,
making it useless for arbitrary matching:
```bash
[\^˄ˆ][a⍺a𝐚𝑎𝒂𝒶𝓪𝔞𝕒𝖆𝖺𝗮𝘢𝙖𝚊ɑα𝛂𝛼𝜶𝝰𝞪а][ss𝐬𝑠𝒔𝓈𝓼𝔰𝕤𝖘𝗌𝘀𝘴𝙨𝚜ꜱƽѕꮪ𑣁𐑈][dⅾⅆ𝐝𝑑𝒅𝒹𝓭𝔡𝕕𝖉𝖽𝗱𝘥𝙙𝚍ԁᏧᑯꓒ][f𝐟𝑓𝒇𝒻𝓯𝔣𝕗𝖋𝖿𝗳𝘧𝙛𝚏ꬵꞙſẝք][\([❨❲〔﴾][\.𝅭․܁܂꘎𐩐٠۰ꓸ][\*⁎٭∗𐌟][\)]❩❳〕﴿]$
```
Interestingly, the confusable-homoglyphs package doesn't list any
special characters that look similar to $
.
## The solution
To support expansion for confusables while preserving arbitrary regex, we need
to generate an **[abstract syntax
tree](https://en.wikipedia.org/wiki/Abstract_syntax_tree) (AST)** for the regular
expression and manipulate that somehow. For structured languages, an AST
represents the layout of meaningful tokens based on a predefined grammar, or
syntax. For example, regex parsers have to correctly interpret `[` and `]` as
special characters defining a set of characters within—unless they're escaped,
like `\[` and `\]`, in which case they'll be taken as "literal" bracket
characters.
After generating an AST for the regular expression, we then must modify it to
replace predefined character literals (e.g. `a`) with sets of their confusable
homoglyphs (e.g. `[a⍺a𝐚𝑎𝒂𝒶𝓪𝔞𝕒𝖆𝖺𝗮𝘢𝙖𝚊ɑα𝛂𝛼𝜶𝝰𝞪а]`) before compiling the AST into a
usable pattern-matching object. While this process appears similar to the
string manipulation method described previously, parsing first for an AST
provides a mutable structure that allows us to distinguish character literals
from special regex tokens/grammar. Fortunately, Python’s `re` module already
contains (and exposes!) the internal tools for parsing and compiling—we just
need to modify the process.
**The AST is generated from the inputted filter string, and the usable
pattern matching object is compiled from the AST. Since these steps are
separate in Python's `re` pipeline and since the AST is a mutable object, the
AST object can be separately modified before being compiled.**
# Manipulating Python’s regex AST
This required a bit of reverse engineering on my part as I couldn't find any
adequate documentation on the internals of Python’s `re` module. After some
brief digging in the CPython source repository, I found **two submodules of
`re` that handle regex string parsing and compilation: `re.sre_parse` and
`re.sre_compile`**, respectively.
## Reverse engineering
The `re.compile()` function uses the `sre_parse` and `sre_compile` submodules
by effectively doing the following to return a `re.Pattern` object:
```python
ast = re.sre_parse.parse( input_regex_string ) # -> re.sre_parse.SubPattern
pattern_object = re.sre_compile.compile( ast ) # -> re.Pattern
return pattern_object
```
Knowing this, we can experiment with the output of `sre_parse.parse()` function
to determine `re`'s AST structure and figure out how we need to modify it.
```python
>>> import re
>>> re.sre_parse.parse("asdf")
[(LITERAL, 97), (LITERAL, 115), (LITERAL, 100), (LITERAL, 102)]
>>> type(re.sre_parse.parse("asdf"))
sre_parse.SubPattern
>>> re.sre_parse.parse("[asdf]")
[(IN, [(LITERAL, 97), (LITERAL, 115), (LITERAL, 100), (LITERAL, 102)])]
>>> re.sre_parse.parse("[asd-f]") # Ranges?
[(IN, [(LITERAL, 97), (LITERAL, 115), (RANGE, (100, 102))])]
>>> re.sre_parse.parse("(asdf)") # To see how `re` handles nested tokens
[(SUBPATTERN, (1, 0, 0, [(LITERAL, 97), (LITERAL, 115), (LITERAL, 100), (LITERAL, 102)]))]
```
From this, we know the `sre_parse.parse()` function returns a `SubPattern`
list-like object containing *tuples of tokens in the format `(TOKEN_NAME,
TOKEN_VALUE)`.* Also, given the name `SubPattern`, it's likely this is nested
for other types of regex grammar (maybe for lookarounds or matching groups?).
## Modifying the AST (implementing the solution)
For our case, we’re looking to replace tokens identified as `LITERAL`s:
> `(LITERAL, ord)`, representing literal characters like `a`
with character match sets—`IN` tokens—wrapping more `LITERAL` tokens:
> `(IN, [ (LITERAL, ord) ... ])`, representing sets like `[a⍺a𝐚𝑎𝒂𝒶𝓪𝔞𝕒𝖆𝖺𝗮𝘢𝙖𝚊ɑα𝛂𝛼𝜶𝝰𝞪а]`
We also have this `RANGE` token that needs to be handled:
> `(RANGE, (LOWER_ORD, UPPER_ORD))`, representing set ranges like `a-z` in `[a-z]`
Because abstract syntax trees are, well, trees, this needs to be done
recursively to account for nested tokens, such as those within matching groups.
What's important to note here is that regex does not allow nested character
sets. So, if the input string uses sets natively, and we want to expand the
characters in that set to cover confusable homoglyphs, we need to make sure we
aren't creating a new set within the original set. You can see how I
accomplished this below, among other things like handling ranges.
This is the solution I came up with:
```python
from collections.abc import Iterable
import re
from confusable_homoglyphs import confusables
def patched_regex(regex_string: str) -> re.Pattern:
"""
Generate a regex pattern object after replacing literals with sets of
confusable homoglyphs
"""
# Generate AST from base input string
ast_root = re.sre_parse.parse(regex_string)
# Generate list of confusable homoglyph LITERAL tokens based on input
# character, including token for input character
def generate_confusables(confusable: chr) -> list:
groups = confusables.is_confusable(confusable, greedy=True)
# Begin the homoglyph set with the original character
confusable_literals = [(re.sre_parse.LITERAL, ord(confusable))]
if not groups:
# Nothing to be confused with the original character
return confusable_literals
# Append confusable homoglyph tokens to list
# Check confusable_homoglyphs documentation to verify this usage
for homoglyph in groups[0]["homoglyphs"]:
confusable_literals += [
(re.sre_parse.LITERAL, ord(char))
for char in homoglyph["c"]
]
return confusable_literals
# Iterative function to patch AST
def modify(ast_local: Iterable):
# Step through this level of the AST
for index, item in enumerate(ast_local):
# Token represented by tuple
# (TOKEN_NAME, TOKEN_VALUE) is likely
if isinstance(item, tuple):
token_name, token_value, *_ = item
if token_name == re.sre_parse.IN:
# IN type found, (IN, [ (LITERAL, ord) ... ])
# Because you can't nest sets in regex, these need to be
# handled separately, with confusables inserted in place
# Generate confusables for every literal in charset
confusables = []
for set_token in token_value:
if set_token[0] == re.sre_parse.RANGE:
# If this is a RANGE, e.g. [a-z]
# ( RANGE, (LOWER_ORD, UPPER_ORD) )
lower_bound = set_token[1][0]
upper_bound = set_token[1][1]
# [lower_bound, upper_bound] loop, inclusive
# Appends confusables for all characters in range
for ord_value in range(lower_bound, upper_bound + 1):
confusables += generate_confusables(chr(ord_value))
else:
# Must be a LITERAL
# Append confusables for this character to list
confusables += generate_confusables(chr(set_token[1]))
# Append confusables to character set
token_value += confusables
elif token_name == re.sre_parse.LITERAL:
# LITERAL type found, (LITERAL, ord)
# *NOT* in a set, replace with set
# Generate list of confusable homoglyphs based on `ord`
confusables = generate_confusables(chr(token_value))
# Overwrite the original LITERAL token in the AST with a
# set of confusable homoglyphs
ast_local[index] = (re.sre_parse.IN, confusables)
else:
# Not LITERAL or IN; more possible tokens nested in this
# one. Convert to list, recurse, output back to tuple, then
# overwrite in AST
ast_local[index] = tuple(modify(list(item)))
# If not a tuple/token
elif isinstance(item, re.sre_parse.SubPattern):
# More possible tokens, recurse and overwrite in AST
ast_local[index] = modify(item)
return ast_local
# Patch generated native AST
ast_root = modify(ast_root)
# Compile AST to case-insensitive re.Pattern and return
return re.sre_compile.compile(ast_root, re.IGNORECASE)
```
Testing with some sample regular expressions, we can see it works as desired:
```python
>>> patched_regex("asdf").match("asdf")
>>> patched_regex("asdf").match("as𝕕f")
>>> patched_regex("as[d-f]").match("as𝕕")
>>> patched_regex("as[d-f]*").match("as𝕗𝕗𝕗𝕗")
>>> patched_regex("as[d-f]").match("as𝕗")
>>> patched_regex("[asd-f]").findall("asxℯ")
['a', 's', 'ℯ']
>>> patched_regex("[asd-f]").match("qwerty")
None # Looks weird, but native compile yields this too. `findall` and `search` work for this.
```
This works likewise with re.Pattern.search() and other re.Pattern
functions, and includes all native regex features. The only real limitation
here is generating confusables, since confusable-homoglyphs
doesn't seem to
account for accent characters, e.g. é
-> e
.
I submitted a pull request to the bot which would make any filter string
prefixed by `regex:` use a custom regex compilation process similar to the one
above. This allows the Discord bot to employ arbitrary regular expressions as
filter items, making use of supported regex features such as lookarounds, while
still preserving expansion for non-ASCII confusable homoglyphs.