• Stars
    star
    446
  • Rank 97,888 (Top 2 %)
  • Language
    Python
  • License
    MIT License
  • Created almost 7 years ago
  • Updated 9 months ago

Reviews

There are no reviews yet. Be the first to send feedback to the community and the maintainers!

Repository Details

Concurrently detect the minimum Python versions needed to run code

Test Status Analyze Status CodeQL Status Coverage PyPI version Commits since last Downloads CII best practices

Vermin

Concurrently detect the minimum Python versions needed to run code. Additionally, since the code is vanilla Python, and it doesn't have any external dependencies, it can be run with v3+ but still includes detection of v2.x functionality.

It functions by parsing Python code into an abstract syntax tree (AST), which it traverses and matches against internal dictionaries with 3676 rules, covering v2.0-2.7 and v3.0-3.11, divided into 178 modules, 2510 classes/functions/constants members of modules, 859 kwargs of functions, 4 strftime directives, 3 bytes format directives, 2 array typecodes, 3 codecs error handler names, 20 codecs encodings, 78 builtin generic annotation types, 9 builtin dict union (|) types, 8 builtin dict union merge (|=) types, and 2 user function decorators.

Backports of the standard library, like typing, can be enabled for better results. Get full list of backports via --help.

The project is fairly well-tested with 3881 unit and integration tests that are executed on Linux, macOS, and Windows.

It is recommended to use the most recent Python version to run Vermin on projects since Python's own language parser is used to detect language features, like f-strings since Python 3.6 etc.

Table of Contents

Usage

It is fairly straightforward to use Vermin.

Running it from the repository either directly or through specific interpreter:

% ./vermin.py /path/to/your/project        # (1) executing via `/usr/bin/env python`
% python3 vermin.py /path/to/your/project  # (2) specifically `python3`

Or if installed via PyPi:

% pip install vermin
% vermin /path/to/your/project

Homebrew (pkg):

% brew install vermin

Spack (pkg):

% git clone https://github.com/spack/spack.git
% . spack/share/spack/setup-env.sh  # depending on shell
% spack install py-vermin
% spack load py-vermin

Arch Linux (AUR):

% yay -S python-vermin

When using continuous integration (CI) tools, like Travis CI, Vermin can be used to check that the minimum required versions didn't change. The following is an excerpt:

install:
- ./setup_virtual_env.sh
- pip install vermin
script:
- vermin -t=2.7 -t=3 project_package otherfile.py

Vermin can also be used as a pre-commit hook:

repos:
  - repo: https://github.com/netromdk/vermin
    rev: GIT_SHA_OR_TAG  # ex: 'e88bda9' or 'v1.3.4'
    hooks:
      - id: vermin
        # specify your target version here, OR in a Vermin config file as usual:
        args: ['-t=3.8-', '--violations']
        # (if your target is specified in a Vermin config, you may omit the 'args' entry entirely)

When using the hook, a target version must be specified via a Vermin config file in your package, or via the args option in your .pre-commit-config.yaml config. If you're passing the target via args, it's recommended to also include --violations (shown above).

If you're using the vermin-all hook, you can specify any target as you usually would. However, if you're using the vermin hook, your target must be in the form of x.y- (as opposed to x.y), otherwise you will run into issues when your staged changes meet a minimum version that is lower than your target.

See the pre-commit docs for further general information on how to get hooks set up on your project.

Features

Features detected include v2/v3 print expr and print(expr), long, f-strings, coroutines (async and await), asynchronous generators (await and yield in same function), asynchronous comprehensions, await in comprehensions, asynchronous for-loops, boolean constants, named expressions, keyword-only parameters, positional-only parameters, nonlocal, yield from, exception context cause (raise .. from ..), except*, set literals, set comprehensions, dict comprehensions, infix matrix multiplication, "..".format(..), imports (import X, from X import Y, from X import *), function calls wrt. name and kwargs, strftime + strptime directives used, function and variable annotations (also Final and Literal), continue in finally block, modular inverse pow(), array typecodes, codecs error handler names, encodings, % formatting and directives for bytes and bytearray, with statement, asynchronous with statement, multiple context expressions in a with statement, multiple context expressions in a with statement grouped with parenthesis, unpacking assignment, generalized unpacking, ellipsis literal (...) out of slices, dictionary union ({..} | {..}), dictionary union merge (a = {..}; a |= {..}), builtin generic type annotations (list[str]), function decorators, class decorators, relaxed decorators, metaclass class keyword, pattern matching with match, and union types written as X | Y. It tries to detect and ignore user-defined functions, classes, arguments, and variables with names that clash with library-defined symbols.

Caveats

For frequently asked questions, check out the FAQ discussions.

Self-documenting fstrings detection has been disabled by default because the built-in AST cannot distinguish f'{a=}' from f'a={a}', for instance, since it optimizes some information away (#39). And this incorrectly marks some source code as using fstring self-doc when only using general fstring. To enable (unstable) fstring self-doc detection, use --feature fstring-self-doc.

Detecting union types (X | Y PEP 604) can be tricky because Vermin doesn't know all underlying details of constants and types since it parses and traverses the AST. For this reason, heuristics are employed and this can sometimes yield incorrect results (#103). To enable (unstable) union types detection, use --feature union-types.

Function and variable annotations aren't evaluated at definition time when from __future__ import annotations is used (PEP 563). This is why --no-eval-annotations is on by default (since v1.1.1, #66). If annotations are being evaluated at runtime, like using typing.get_type_hints or evaluating __annotations__ of an object, --eval-annotations should be used for best results.

Configuration File

Vermin automatically tries to detect a config file, starting in the current working directory where it is run, following parent folders until either the root or project boundary files/folders are reached. However, if --config-file is specified, no config is auto-detected and loaded.

Config file names being looked for: vermin.ini, vermin.conf, .vermin, setup.cfg

Project boundary files/folders: .git, .svn, .hg, .bzr, _darcs, .fslckout, .p4root, .pijul

A sample config file can be found here.

Note that Vermin config can be in the same INI file as other configs, like the commonly used setup.cfg:

[vermin]
verbose = 1
processes = 4

[flake8]
ignore = E111,F821

Examples

% ./vermin.py vermin
Minimum required versions: 3.0
Incompatible versions:     2

% ./vermin.py -t=3.3 vermin
Minimum required versions: 3.0
Incompatible versions:     2
Target versions not met:   3.3
% echo $?
1

% ./vermin.py --versions vermin
Minimum required versions: 3.0
Incompatible versions:     2
Version range:             2.0, 2.6, 2.7, 3.0

% ./vermin.py -v examples
Detecting python files..
Analyzing 6 files using 8 processes..
             /path/to/examples/formatv2.py
2.7, 3.2     /path/to/examples/argparse.py
2.7, 3.0     /path/to/examples/formatv3.py
2.0, 3.0     /path/to/examples/printv3.py
!2, 3.4      /path/to/examples/abc.py
             /path/to/examples/unknown.py
Minimum required versions:   3.4
Incompatible versions:         2

% ./vermin.py -vv /path/to/examples/abc.py
Detecting python files..
Analyzing using 8 processes..
!2, 3.4      /path/to/examples/abc.py
  'abc' requires 2.6, 3.0
  'abc.ABC' requires !2, 3.4

Minimum required versions: 3.4
Incompatible versions:     2

% ./vermin.py -vvv /path/to/examples/abc.py
Detecting python files..
Analyzing using 8 processes..
!2, 3.4      /path/to/examples/abc.py
  L1 C7: 'abc' requires 2.6, 3.0
  L2: 'abc.ABC' requires !2, 3.4

Minimum required versions: 3.4
Incompatible versions:     2

% ./vermin.py -f parsable /path/to/examples/abc.py
/path/to/examples/abc.py:1:7:2.6:3.0:'abc' module
/path/to/examples/abc.py:2::!2:3.4:'abc.ABC' member
/path/to/examples/abc.py:::!2:3.4:
:::!2:3.4:

See Parsable Output for more information about parsable output format.

Linting: Showing only target versions violations

Vermin shows lots of useful minimum version results when run normally, but it can also be used as a linter to show only rules violating specified target versions by using --violations (or --lint) and one or two --target values. Verbosity level 2 is automatically set when showing only violations, but can be increased if necessary. The final versions verdict is still calculated and printed at the end and the program exit code signifies whether the specified targets were met (0) or violated (1). However, if no rules are triggered the exit code will be 0 due to inconclusivity.

% cat test.py
import argparse  # 2.7, 3.2
all()            # 2.5, 3.0
enumerate()      # 2.3, 3.0

% ./vermin.py -t=2.4- -t=3 --violations test.py ; echo $?
Detecting python files..
Analyzing using 8 processes..
2.7, 3.2     test.py
  'all' member requires 2.5, 3.0
  'argparse' module requires 2.7, 3.2

Minimum required versions: 2.7, 3.2
Target versions not met:   2.4-, 3.0
1

The two first lines violate the targets but the third line matches and is therefore not shown.

API (experimental)

Information such as minimum versions, used functionality constructs etc. can also be accessed programmatically via the vermin Python module, though it's an experimental feature. It is still recommended to use the command-line interface.

>>> import vermin as V
>>> V.version_strings(V.detect("a = long(1)"))
'2.0, !3'

>>> config = V.Config()
>>> config.add_exclusion("long")
>>> V.version_strings(V.detect("a = long(1)", config))
'~2, ~3'

>>> config.set_verbose(3)
>>> v = V.visit("""from argparse import ArgumentParser
... ap = ArgumentParser(allow_abbrev=True)
... """, config)
>>> print(v.output_text(), end="")
L1 C5: 'argparse' module requires 2.7, 3.2
L2: 'argparse.ArgumentParser(allow_abbrev)' requires !2, 3.5
>>> V.version_strings(v.minimum_versions())
'!2, 3.5'

Analysis Exclusions

Analysis exclusion can be necessary in certain cases. The argument --exclude <name> (multiple can be specified) can be used to exclude modules, members, kwargs, codecs error handler names, or codecs encodings by name from being analysed via . Consider the following code block that checks if PROTOCOL_TLS is an attribute of ssl:

import ssl
tls_version = ssl.PROTOCOL_TLSv1
if hasattr(ssl, "PROTOCOL_TLS"):
  tls_version = ssl.PROTOCOL_TLS

It will state that "'ssl.PROTOCOL_TLS' requires 2.7, 3.6" but to exclude that from the results, use --exclude 'ssl.PROTOCOL_TLS'. Afterwards, only "'ssl' requires 2.6, 3.0" will be shown and the final minimum required versions are v2.6 and v3.0 instead of v2.7 and v3.6.

Code can even be excluded on a more fine grained level using the # novermin or # novm comments at line level. The following yields the same behavior as the previous code block, but only for that particular if and its body:

import ssl
tls_version = ssl.PROTOCOL_TLSv1
if hasattr(ssl, "PROTOCOL_TLS"):  # novermin
  tls_version = ssl.PROTOCOL_TLS

In scenarios where multiple tools are employed that use comments for various features, exclusions can be defined by having # for each comment "segment":

if hasattr(ssl, "PROTOCOL_TLS"):  # noqa # novermin # pylint: disable=no-member
  tls_version = ssl.PROTOCOL_TLS

Note that if a code base does not have any occurrences of # novermin or # novm, speedups up to 30-40%+ can be achieved by using the --no-parse-comments argument or parse_comments = no config setting.

Parsable Output

For scenarios where the results of Vermin output is required, it is recommended to use the parsable output format (--format parsable) instead of the default output. With this format enabled, each line will be on the form:

<file>:<line>:<column>:<py2>:<py3>:<feature>

The <line> and <column> are only shown when the verbosity level is high enough, otherwise they are empty.

Each feature detected per processed file will have the <feature> defined on an individual line. The last line of the processed file will have a special line with the corresponding <file> and no <feature>, constituting the minimum versions of that file:

<file>:::<py2>:<py3>:

The very last line is the final minimum versions results of the entire scan and therefore has no <file> and <feature>:

:::<py2>:<py3>:

Inspection of example output

% ./vermin.py -f parsable /path/to/project
/path/to/project/abc.py:1:7:2.6:3.0:'abc' module
/path/to/project/abc.py:2::!2:3.4:'abc.ABC' member
/path/to/project/abc.py:::!2:3.4:
/path/to/project/except_star.py:::~2:~3:
/path/to/project/annotations.py:::2.0:3.0:print(expr)
/path/to/project/annotations.py:1::!2:3.0:annotations
/path/to/project/annotations.py:::!2:3.0:
:::!2:3.4:

abc.py requires !2 and 3.4 via:

/path/to/project/abc.py:::!2:3.4:

except_star.py requires ~2 and ~3 via:

/path/to/project/except_star.py:::~2:~3:

And annotations.py requires !2 and 3.0 via:

/path/to/project/annotations.py:::!2:3.0:

That means that the final result is !2 and 3.4, which is shown by the last line:

:::!2:3.4:

Contributing

Contributions are very welcome, especially adding and updating detection rules of modules, functions, classes etc. to cover as many Python versions as possible. See CONTRIBUTING.md for more information.

More Repositories

1

sigs

Simple thread-safe signal/slot C++17 include-only library.
C++
37
star
2

dispar

Dispar - Cross-platform Disassemling binary Parser
C++
20
star
3

.emacs.d

My personal Emacs v28+ configuration.
Emacs Lisp
14
star
4

slacker

Slacker - Easy access to the Slack API and admin of workspaces/teams.
Python
14
star
5

bmod

bmod parses binaries for modification/patching and disassembles machine code sections.
C++
12
star
6

describe-number

Describe arbitrarily large number at point in Emacs.
Emacs Lisp
6
star
7

tracepp

C++17 tracing library for debugging with ease.
C++
6
star
8

clyzer

C[ryptographic Ana]lyzer
C++
5
star
9

math

Math library written in C++
C
4
star
10

annotate-depth

Annotate buffer if indentation depth is beyond threshold in Emacs.
Emacs Lisp
3
star
11

carapace.rs

Shell written in Rust
Rust
3
star
12

mocam

Interaction with video capturing devices coupled with facial recognition.
C++
3
star
13

patching

Patching binaries
Python
3
star
14

faes

Fast AES
C++
2
star
15

doors

Doors of Open Run-time Systems (OS)
C++
2
star
16

tourney

Slack general match generator bot
Python
2
star
17

threadpool

Thread pool purely written in C++11.
C++
2
star
18

cods

Collection of Data Structures (vanilla C++14)
C++
1
star
19

annoycode

Annoy people by converting unicode characters to other characters that looks the same.
C++
1
star
20

blurator

Blurator
C++
1
star
21

sld

Strategic Layout Designer
C++
1
star
22

sublime-text-conf

Sublime Text 3 configurations and settings.
Python
1
star
23

tbgame

tbgame implements turn-based games for making board games easier to play without requiring a lot of paper and pencils.
Python
1
star