⏰ Whenever

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Sensible and typesafe datetimes

Do you cross your fingers every time you work with datetimes, hoping that you didn’t mix naive and aware? or that you converted to UTC everywhere? or that you avoided the many pitfalls of the standard library? There’s no way to be sure…

✨ Until now! ✨

Whenever is a datetime library designed from the ground up to enforce correctness. Mistakes become red squiggles in your IDE, instead of bugs in production.

📖 Docs | 🐍 PyPI | 🐙 GitHub | 🚀 Changelog | ❓ FAQ | 🗺️ Roadmap | 💬 Issues & discussions

Benefits

Quickstart

>>> from whenever import (
...    # Explicit types for different use cases
...    UTCDateTime,     # -> Enforce UTC-normalization
...    OffsetDateTime,  # -> Simple localized times
...    ZonedDateTime,   # -> Full-featured timezones
...    NaiveDateTime,   # -> Without any timezone
... )

>>> py311_release = UTCDateTime(2022, 10, 24, hour=17)
UTCDateTime(2022-10-24 17:00:00Z)
>>> pycon23_start = OffsetDateTime(2023, 4, 21, hour=9, offset=-6)
OffsetDateTime(2023-04-21 09:00:00-06:00)

# Simple, explicit conversions
>>> py311_release.as_zoned("Europe/Paris")
ZonedDateTime(2022-10-24 19:00:00+02:00[Europe/Paris])
>>> pycon23_start.as_local()  # example: system timezone in NYC
LocalSystemDateTime(2023-04-21 11:00:00-04:00)

# Comparison and equality across aware types
>>> py311_release > pycon23_start
False
>>> py311_release == py311_release.as_zoned("America/Los_Angeles")
True

# Naive type that can't accidentally mix with aware types
>>> hackathon_invite = NaiveDateTime(2023, 10, 28, hour=12)
>>> # Naïve/aware mixups are caught by typechecker
>>> hackathon_invite - py311_release
>>> # Only explicit assumptions will make it aware
>>> hackathon_start = hackathon_invite.assume_zoned("Europe/Amsterdam")
ZonedDateTime(2023-10-28 12:00:00+02:00[Europe/Amsterdam])

# DST-aware operators
>>> hackathon_end = hackathon_start.add(hours=24)
ZonedDateTime(2022-10-29 11:00:00+01:00[Europe/Amsterdam])

# Lossless round-trip to/from text (useful for JSON/serialization)
>>> py311_release.canonical_format()
'2022-10-24T17:00:00Z'
>>> ZonedDateTime.from_canonical_format('2022-10-24T19:00:00+02:00[Europe/Paris]')
ZonedDateTime(2022-10-24 19:00:00+02:00[Europe/Paris])

# Conversion to/from common formats
>>> py311_release.rfc2822()  # also: from_rfc2822()
"Mon, 24 Oct 2022 17:00:00 GMT"
>>> pycon23_start.rfc3339()  # also: from_rfc3339()
"2023-04-21T09:00:00-06:00"

# Basic parsing
>>> OffsetDateTime.strptime("2022-10-24+02:00", "%Y-%m-%d%z")
OffsetDateTime(2022-10-24 00:00:00+02:00)

# If you must: you can access the underlying datetime object
>>> pycon23_start.py_datetime().ctime()
'Fri Apr 21 09:00:00 2023'

Read more in the feature overview or API reference.

Why not…?

The standard library

The standard library is full of quirks and pitfalls. To summarize the detailed blog post:

  1. Incompatible concepts of naive and aware are squeezed into one class

  2. Operators ignore Daylight Saving Time (DST)

  3. The meaning of “naive” is inconsistent (UTC, local, or unspecified?)

  4. Non-existent datetimes pass silently

  5. It guesses in the face of ambiguity

  6. False negatives on equality of ambiguous times between timezones

  7. False positives on equality of ambiguous times within the same timezone

  8. datetime inherits from date, but behaves inconsistently

  9. datetime.timezone isn’t enough for full-featured timezones.

  10. The local timezone is DST-unaware

Pendulum

Pendulum is full-featured datetime library, but it’s hamstrung by the decision to inherit from the standard library datetime. This means it inherits most of the pitfalls mentioned above, with the notable exception of DST-aware addition/subtraction.

Arrow

Arrow is probably the most historically popular datetime library. Pendulum did a good write-up of the issues with Arrow. It addresses fewer of datetime’s pitfalls than Pendulum.

DateType

DateType mostly fixes the issue of mixing naive and aware datetimes, and datetime/date inheritance during type-checking, but doesn’t address the other pitfalls. The type-checker-only approach also means that it doesn’t enforce correctness at runtime, and it requires developers to be knowledgeable about how the ‘type checking reality’ differs from the ‘runtime reality’.

python-dateutil

Dateutil attempts to solve some of the issues with the standard library. However, it only adds functionality to work around the issues, instead of removing the pitfalls themselves. This still puts the burden on the developer to know about the issues, and to use the correct functions to avoid them. Without removing the pitfalls, it’s still very likely to make mistakes.

Maya

It’s unmaintained, but does have an interesting approach. By enforcing UTC, it bypasses a lot of issues with the standard library. To do so, it sacrifices the ability to represent offset, zoned, and local datetimes. So in order to perform any timezone-aware operations, you need to convert to the standard library datetime first, which reintroduces the issues.

Heliclockter

This library is a lot more explicit about the different types of datetimes, addressing issue of naive/aware mixing with UTC, local, and zoned datetime subclasses. It doesn’t address the other datetime pitfalls though.

Roadmap

  • 🧪 0.x: get to feature-parity, process feedback, and tweak the API:

    • ✅ Datetime classes

    • ✅ Deltas

    • ✅ Date and time of day (separate from datetime)

    • 🚧 Interval

    • 🚧 Improved parsing and formatting

  • 🔒 1.0: - API stability and backwards compatibility - Implement Rust extension for performance

  • 🐍 future: Inspire a standard library improvement

Not planned:

  • Different calendar systems

Versioning and compatibility policy

Whenever follows semantic versioning. Until the 1.0 version, the API may change with minor releases. Breaking changes will be avoided as much as possible, and meticulously explained in the changelog. Since the API is fully typed, your typechecker and/or IDE will help you adjust to any API changes.

⚠️ Note: until 1.x, pickled objects may not be unpicklable across versions. After 1.0, backwards compatibility of pickles will be maintained as much as possible.

Acknowledgements

This project is inspired by the following projects. Check them out!

Contributing

Contributions are welcome! Please open an issue or a pull request.

⚠️ Note: big changes should be discussed in an issue first. This is to avoid wasted effort if the change isn’t a good fit for the project.

⚠️ Note: Some tests are skipped on Windows. These tests use unix-specific features to set the timezone for the current process. As a result, Windows isn’t able to run certain tests that rely on the system timezone. It appears that this functionality is not available on Windows.

Setting up a development environment

You’ll need poetry installed. An example of setting up things up:

poetry install

# To run the tests with the current Python version
pytest

# if you want to build the docs
pip install -r docs/requirements.txt

# Various checks
mypy src/ tests/
flake8 src/ tests/

# autoformatting
black src/ tests/
isort src/ tests/

# To run the tests with all supported Python versions
# Alternatively, let the github actions on the PR do it for you
pip install tox
tox -p auto

Contents

Indices and tables