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61 changed files with 535 additions and 6555 deletions

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[run]
source = src/
branch = true
command_line = -m unittest discover
omit =
.venv/*
[report]
fail_under = 100
show_missing = True
skip_covered = False
exclude_lines =
if TYPE_CHECKING:
if __name__ == ['"]__main__['"]:
omit =
tests/*

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@ -1,88 +0,0 @@
name: CI
on:
push:
branches: [master]
jobs:
tests:
name: Python ${{ matrix.python-version }} Tests
runs-on: ubuntu-latest
strategy:
matrix:
python-version:
- '3.8'
- '3.9'
- '3.10'
steps:
- uses: actions/checkout@v3
- uses: actions/setup-python@v3
with:
python-version: ${{ matrix.python-version }}
cache: 'pip'
cache-dependency-path: 'requirements/dev.txt'
- name: Upgrade packaging tools
run: pip install -U pip
- name: Install dependencies
run: pip install -U -r requirements/dev.txt
- name: Install asyncio-taskpool
run: pip install -e .
- name: Run tests for Python ${{ matrix.python-version }}
if: ${{ matrix.python-version != '3.10' }}
run: python -m tests
- name: Run tests for Python 3.10 and save coverage
if: ${{ matrix.python-version == '3.10' }}
run: echo "coverage=$(./coverage.sh)" >> $GITHUB_ENV
outputs:
coverage: ${{ env.coverage }}
update_badges:
needs: tests
name: Update Badges
env:
meta_gist_id: 3f8240a976e8781a765d9c74a583dcda
runs-on: ubuntu-latest
steps:
- name: Checkout repository
uses: actions/checkout@v3
- name: Download `cloc`
run: sudo apt-get update -y && sudo apt-get install -y cloc
- name: Count lines of code/comments
run: |
echo "cloc_code=$(./cloc.sh -c src/)" >> $GITHUB_ENV
echo "cloc_comments=$(./cloc.sh -m src/)" >> $GITHUB_ENV
echo "cloc_commentpercent=$(./cloc.sh -p src/)" >> $GITHUB_ENV
- name: Create badge for lines of code
uses: Schneegans/dynamic-badges-action@v1.2.0
with:
auth: ${{ secrets.GIST_META_DATA }}
gistID: ${{ env.meta_gist_id }}
filename: cloc-code.json
label: Lines of Code
message: ${{ env.cloc_code }}
- name: Create badge for lines of comments
uses: Schneegans/dynamic-badges-action@v1.2.0
with:
auth: ${{ secrets.GIST_META_DATA }}
gistID: ${{ env.meta_gist_id }}
filename: cloc-comments.json
label: Comments
message: ${{ env.cloc_comments }} (${{ env.cloc_commentpercent }}%)
- name: Create badge for test coverage
uses: Schneegans/dynamic-badges-action@v1.2.0
with:
auth: ${{ secrets.GIST_META_DATA }}
gistID: ${{ env.meta_gist_id }}
filename: test-coverage.json
label: Coverage
message: ${{ needs.tests.outputs.coverage }}

5
.gitignore vendored
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@ -3,11 +3,8 @@
# IDE settings:
/.idea/
/.vscode/
# Distribution / build files:
# Distribution / packaging:
*.egg-info/
/dist/
/docs/build/
# Python cache:
__pycache__/
# Testing:
.coverage

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@ -1,11 +0,0 @@
version: 2
build:
os: 'ubuntu-20.04'
tools:
python: '3.8'
python:
install:
- method: pip
path: .
sphinx:
fail_on_warning: true

674
COPYING
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@ -1,674 +0,0 @@
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@ -1,165 +0,0 @@
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@ -1,101 +1,19 @@
[//]: # (This file is part of asyncio-taskpool.)
[//]: # (asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of)
[//]: # (version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.)
[//]: # (asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;)
[//]: # (without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.)
[//]: # (See the GNU Lesser General Public License for more details.)
[//]: # (You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.)
[//]: # (If not, see <https://www.gnu.org/licenses/>.)
# asyncio-taskpool
[![GitHub last commit][github-last-commit-img]][github-last-commit]
![Lines of code][gist-cloc-code-img]
![Lines of comments][gist-cloc-comments-img]
![Test coverage][gist-test-coverage-img]
[![License: LGPL v3.0][lgpl3-img]][lgpl3]
[![PyPI version][pypi-latest-version-img]][pypi-latest-version]
**Dynamically manage pools of asyncio tasks**
Full documentation available at [RtD](https://asyncio-taskpool.readthedocs.io/en/latest).
---
## Contents
- [Contents](#contents)
- [Summary](#summary)
- [Usage](#usage)
- [Installation](#installation)
- [Dependencies](#dependencies)
- [Testing](#testing)
- [License](#license)
## Summary
A **task pool** is an object with a simple interface for aggregating and dynamically managing asynchronous tasks.
With an interface that is intentionally similar to the [`multiprocessing.Pool`](https://docs.python.org/3/library/multiprocessing.html#module-multiprocessing.pool) class from the standard library, the `TaskPool` provides you such methods as `apply`, `map`, and `starmap` to execute coroutines concurrently as [`asyncio.Task`](https://docs.python.org/3/library/asyncio-task.html#task-object) objects. There is no limitation imposed on what kind of tasks can be run or in what combination, when new ones can be added, or when they can be cancelled.
For a more streamlined use-case, the `SimpleTaskPool` provides an even more intuitive and simple interface at the cost of flexibility.
If you need control over a task pool at runtime, you can launch an asynchronous `ControlServer` to be able to interface with the pool from an outside process or via a network, and stop/start tasks within the pool as you wish.
Dynamically manage pools of asyncio tasks
## Usage
Generally speaking, a task is added to a pool by providing it with a coroutine function reference as well as the arguments for that function. Here is what that could look like in the most simplified form:
```python
from asyncio_taskpool import SimpleTaskPool
...
async def work(_foo, _bar): ...
async def main():
pool = SimpleTaskPool(work, args=('xyz', 420))
pool.start(5)
...
pool.stop(3)
...
await pool.gather_and_close()
```
Since one of the main goals of `asyncio-taskpool` is to be able to start/stop tasks dynamically or "on-the-fly", _most_ of the associated methods are non-blocking _most_ of the time. A notable exception is the `gather_and_close` method for awaiting the return of all tasks in the pool. (It is essentially a glorified wrapper around the [`asyncio.gather`](https://docs.python.org/3/library/asyncio-task.html#asyncio.gather) function.)
For working and fully documented demo scripts see [USAGE.md](usage/USAGE.md).
See [USAGE.md](usage/USAGE.md)
## Installation
```shell
pip install asyncio-taskpool
```
`pip install asyncio-taskpool`
## Dependencies
Python Version 3.8+, tested on Linux
## Testing
## Building from source
Install [`coverage`](https://coverage.readthedocs.io/en/latest/) with `pip`, then execute the [`./coverage.sh`](coverage.sh) shell script to run all unit tests and save the coverage report.
## License
`asyncio-taskpool` is licensed under the **GNU LGPL version 3.0** specifically.
The full license texts for the [GNU GPLv3.0](COPYING) and the [GNU LGPLv3.0](COPYING.LESSER) are included in this repository. If not, see https://www.gnu.org/licenses/.
---
© 2022 Daniil Fajnberg
[github-last-commit]: https://github.com/daniil-berg/asyncio-taskpool/commits
[github-last-commit-img]: https://img.shields.io/github/last-commit/daniil-berg/asyncio-taskpool?label=Last%20commit&logo=git&
[gist-cloc-code-img]: https://img.shields.io/endpoint?logo=python&color=blue&url=https://gist.githubusercontent.com/daniil-berg/3f8240a976e8781a765d9c74a583dcda/raw/cloc-code.json
[gist-cloc-comments-img]: https://img.shields.io/endpoint?logo=sharp&color=lightgrey&url=https://gist.githubusercontent.com/daniil-berg/3f8240a976e8781a765d9c74a583dcda/raw/cloc-comments.json
[gist-test-coverage-img]: https://img.shields.io/endpoint?logo=pytest&color=blue&url=https://gist.githubusercontent.com/daniil-berg/3f8240a976e8781a765d9c74a583dcda/raw/test-coverage.json
[lgpl3]: https://www.gnu.org/licenses/lgpl-3.0
[lgpl3-img]: https://img.shields.io/badge/License-LGPL_v3.0-darkgreen.svg?logo=gnu
[pypi-latest-version-img]: https://img.shields.io/pypi/v/asyncio-taskpool?color=teal&logo=pypi
[pypi-latest-version]: https://pypi.org/project/asyncio-taskpool/
Run `python -m build`

46
cloc.sh
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@ -1,46 +0,0 @@
#!/usr/bin/env bash
# This file is part of asyncio-taskpool.
# asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
# version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
# asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
# without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
# See the GNU Lesser General Public License for more details.
# You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
# If not, see <https://www.gnu.org/licenses/>.
typeset option
if getopts 'bcmp' option; then
if [[ ${option} == [bcmp] ]]; then
shift
else
echo >&2 "Invalid option '$1' provided"
exit 1
fi
fi
typeset source=$1
if [[ -z ${source} ]]; then
echo >&2 Source file/directory missing
exit 1
fi
typeset blank code comment commentpercent
read blank comment code commentpercent < <( \
cloc --csv --quiet --hide-rate --include-lang Python ${source} |
awk -F, '$2 == "SUM" {printf ("%d %d %d %1.0f", $3, $4, $5, 100 * $4 / ($5 + $4)); exit}'
)
case ${option} in
b) echo ${blank} ;;
c) echo ${code} ;;
m) echo ${comment} ;;
p) echo ${commentpercent} ;;
*) echo Blank lines: ${blank}
echo Lines of comments: ${comment}
echo Lines of code: ${code}
echo Comment percentage: ${commentpercent} ;;
esac

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@ -1,25 +1,3 @@
#!/usr/bin/env bash
#!/usr/bin/env sh
# This file is part of asyncio-taskpool.
# asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
# version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
# asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
# without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
# See the GNU Lesser General Public License for more details.
# You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
# If not, see <https://www.gnu.org/licenses/>.
coverage erase
coverage run 2> /dev/null
typeset report=$(coverage report)
typeset total=$(echo "${report}" | awk '$1 == "TOTAL" {print $NF; exit}')
if [[ ${total} == 100% ]]; then
echo ${total}
else
echo "${report}"
fi
coverage erase && coverage run -m unittest discover && coverage report

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@ -1,20 +0,0 @@
# Minimal makefile for Sphinx documentation
#
# You can set these variables from the command line, and also
# from the environment for the first two.
SPHINXOPTS ?=
SPHINXBUILD ?= sphinx-build
SOURCEDIR = source
BUILDDIR = build
# Put it first so that "make" without argument is like "make help".
help:
@$(SPHINXBUILD) -M help "$(SOURCEDIR)" "$(BUILDDIR)" $(SPHINXOPTS) $(O)
.PHONY: help Makefile
# Catch-all target: route all unknown targets to Sphinx using the new
# "make mode" option. $(O) is meant as a shortcut for $(SPHINXOPTS).
%: Makefile
@$(SPHINXBUILD) -M $@ "$(SOURCEDIR)" "$(BUILDDIR)" $(SPHINXOPTS) $(O)

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@ -1,35 +0,0 @@
@ECHO OFF
pushd %~dp0
REM Command file for Sphinx documentation
if "%SPHINXBUILD%" == "" (
set SPHINXBUILD=sphinx-build
)
set SOURCEDIR=source
set BUILDDIR=build
if "%1" == "" goto help
%SPHINXBUILD% >NUL 2>NUL
if errorlevel 9009 (
echo.
echo.The 'sphinx-build' command was not found. Make sure you have Sphinx
echo.installed, then set the SPHINXBUILD environment variable to point
echo.to the full path of the 'sphinx-build' executable. Alternatively you
echo.may add the Sphinx directory to PATH.
echo.
echo.If you don't have Sphinx installed, grab it from
echo.https://www.sphinx-doc.org/
exit /b 1
)
%SPHINXBUILD% -M %1 %SOURCEDIR% %BUILDDIR% %SPHINXOPTS% %O%
goto end
:help
%SPHINXBUILD% -M help %SOURCEDIR% %BUILDDIR% %SPHINXOPTS% %O%
:end
popd

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@ -1,7 +0,0 @@
API
===
.. toctree::
:maxdepth: 4
asyncio_taskpool

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@ -1,7 +0,0 @@
asyncio\_taskpool.control.client module
=======================================
.. automodule:: asyncio_taskpool.control.client
:members:
:undoc-members:
:show-inheritance:

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@ -1,16 +0,0 @@
asyncio\_taskpool.control package
=================================
.. automodule:: asyncio_taskpool.control
:members:
:undoc-members:
:show-inheritance:
Submodules
----------
.. toctree::
:maxdepth: 4
asyncio_taskpool.control.client
asyncio_taskpool.control.server

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@ -1,7 +0,0 @@
asyncio\_taskpool.control.server module
=======================================
.. automodule:: asyncio_taskpool.control.server
:members:
:undoc-members:
:show-inheritance:

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@ -1,7 +0,0 @@
asyncio\_taskpool.exceptions module
===================================
.. automodule:: asyncio_taskpool.exceptions
:members:
:undoc-members:
:show-inheritance:

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@ -1,7 +0,0 @@
asyncio\_taskpool.pool module
=============================
.. automodule:: asyncio_taskpool.pool
:members:
:undoc-members:
:show-inheritance:

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@ -1,7 +0,0 @@
asyncio\_taskpool.queue\_context module
=======================================
.. automodule:: asyncio_taskpool.queue_context
:members:
:undoc-members:
:show-inheritance:

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@ -1,25 +0,0 @@
asyncio\_taskpool package
=========================
.. automodule:: asyncio_taskpool
:members:
:undoc-members:
:show-inheritance:
Subpackages
-----------
.. toctree::
:maxdepth: 4
asyncio_taskpool.control
Submodules
----------
.. toctree::
:maxdepth: 4
asyncio_taskpool.exceptions
asyncio_taskpool.pool
asyncio_taskpool.queue_context

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@ -1,60 +0,0 @@
# Configuration file for the Sphinx documentation builder.
#
# This file only contains a selection of the most common options. For a full
# list see the documentation:
# https://www.sphinx-doc.org/en/master/usage/configuration.html
# -- Path setup --------------------------------------------------------------
# If extensions (or modules to document with autodoc) are in another directory,
# add these directories to sys.path here. If the directory is relative to the
# documentation root, use os.path.abspath to make it absolute, like shown here.
#
# import os
# import sys
# sys.path.insert(0, os.path.abspath('.'))
# -- Project information -----------------------------------------------------
project = 'asyncio-taskpool'
copyright = '2022 Daniil Fajnberg'
author = 'Daniil Fajnberg'
# The full version, including alpha/beta/rc tags
release = '1.1.4'
# -- General configuration ---------------------------------------------------
# Add any Sphinx extension module names here, as strings. They can be
# extensions coming with Sphinx (named 'sphinx.ext.*') or your custom
# ones.
extensions = [
'sphinx.ext.duration',
'sphinx.ext.napoleon'
]
# Add any paths that contain templates here, relative to this directory.
templates_path = ['_templates']
# List of patterns, relative to source directory, that match files and
# directories to ignore when looking for source files.
# This pattern also affects html_static_path and html_extra_path.
exclude_patterns = []
# -- Options for HTML output -------------------------------------------------
# The theme to use for HTML and HTML Help pages. See the documentation for
# a list of builtin themes.
#
html_theme = 'sphinx_rtd_theme'
html_theme_options = {
'style_external_links': True,
}
# Add any paths that contain custom static files (such as style sheets) here,
# relative to this directory. They are copied after the builtin static files,
# so a file named "default.css" will overwrite the builtin "default.css".
html_static_path = ['_static']

View File

@ -1,58 +0,0 @@
.. This file is part of asyncio-taskpool.
.. asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
.. asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
.. You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>.
.. Copyright © 2022 Daniil Fajnberg
Welcome to the asyncio-taskpool documentation!
==============================================
:code:`asyncio-taskpool` is a Python library for dynamically and conveniently managing pools of `asyncio <https://docs.python.org/3/library/asyncio.html>`_ tasks.
Purpose
-------
A `task <https://docs.python.org/3/library/asyncio-task.html>`_ is a very powerful tool of concurrency in the Python world. Since concurrency always implies doing more than one thing a time, you rarely deal with just one :code:`Task` instance. However, managing multiple tasks can become a bit cumbersome quickly, as their number increases. Moreover, especially in long-running code, you may find it useful (or even necessary) to dynamically adjust the extent to which the work is distributed, i.e. increase or decrease the number of tasks.
With that in mind, this library aims to provide two things:
#. An additional layer of abstraction and convenience for managing multiple tasks.
#. A simple interface for dynamically adding and removing tasks when a program is already running.
The first is achieved through the concept of a :doc:`task pool <pages/pool>`. The second is achieved by adding a :doc:`control server <pages/control>` to the task pool.
Installation
------------
.. code-block:: bash
$ pip install asyncio-taskpool
Contents
--------
.. toctree::
:maxdepth: 2
pages/pool
pages/ids
pages/control
api/api
Indices and tables
------------------
* :ref:`genindex`
* :ref:`modindex`
* :ref:`search`

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@ -1,107 +0,0 @@
.. This file is part of asyncio-taskpool.
.. asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
.. asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
.. You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>.
.. Copyright © 2022 Daniil Fajnberg
Control interface
=================
When you are dealing with programs that run for a long period of time or even as daemons (i.e. indefinitely), having a way to adjust their behavior without needing to stop and restart them can be desirable.
Task pools offer a high degree of flexibility regarding the number and kind of tasks that run within them, by providing methods to easily start and stop tasks and task groups. But without additional tools, they only allow you to establish a control logic *a priori*, as demonstrated in :ref:`this code snippet <simple-control-logic>`.
What if you have a long-running program that executes certain tasks concurrently, but you don't know in advance how many of them you'll need? What if you want to be able to adjust the number of tasks manually **without stopping the task pool**?
The control server
------------------
The :code:`asyncio-taskpool` library comes with a simple control interface for managing task pools that are already running, at the heart of which is the :py:class:`ControlServer <asyncio_taskpool.control.server.ControlServer>`. Any task pool can be passed to a control server. Once the server is running, you can issue commands to it either via TCP or via UNIX socket. The commands map directly to the task pool methods.
To enable control over a :py:class:`SimpleTaskPool <asyncio_taskpool.pool.SimpleTaskPool>` via local TCP port :code:`8001`, all you need to do is this:
.. code-block:: python
:caption: main.py
:name: control-server-minimal
from asyncio_taskpool import SimpleTaskPool
from asyncio_taskpool.control import TCPControlServer
from .work import any_worker_func
async def main():
...
pool = SimpleTaskPool(any_worker_func, kwargs={'foo': 42, 'bar': some_object})
control = await TCPControlServer(pool, host='127.0.0.1', port=8001).serve_forever()
await control
Under the hood, the :py:class:`ControlServer <asyncio_taskpool.control.server.ControlServer>` simply uses :code:`asyncio.start_server` for instantiating a socket server. The resulting control task will run indefinitely. Cancelling the control task stops the server.
In reality, you would probably want some graceful handler for an interrupt signal that cancels any remaining tasks as well as the serving control task.
The control client
------------------
Technically, any process that can read from and write to the socket exposed by the control server, will be able to interact with it. The :code:`asyncio-taskpool` package has its own simple implementation in the form of the :py:class:`ControlClient <asyncio_taskpool.control.client.ControlClient>` that makes it easy to use out of the box.
To start a client, you can use the main script of the :py:mod:`asyncio_taskpool.control` sub-package like this:
.. code-block:: bash
$ python -m asyncio_taskpool.control tcp localhost 8001
This would establish a connection to the control server from the previous example. Calling
.. code-block:: bash
$ python -m asyncio_taskpool.control -h
will display the available client options.
The control session
-------------------
Assuming you connected successfully, you should be greeted by the server with a help message and dropped into a simple input prompt.
.. code-block:: none
Connected to SimpleTaskPool-0
Type '-h' to get help and usage instructions for all available commands.
>
The input sent to the server is handled by a typical argument parser, so the interface should be straight-forward. A command like
.. code-block:: none
> start 5
will call the :py:meth:`.start() <asyncio_taskpool.pool.SimpleTaskPool.start>` method with :code:`5` as an argument and thus start 5 new tasks in the pool, while the command
.. code-block:: none
> pool-size
will call the :py:meth:`.pool_size <asyncio_taskpool.pool.BaseTaskPool.pool_size>` property getter and return the maximum number of tasks you that can run in the pool.
When you are dealing with a regular :py:class:`TaskPool <asyncio_taskpool.pool.TaskPool>` instance, starting new tasks works just fine, as long as the coroutine functions you want to use can be imported into the namespace of the pool. If you have a function named :code:`worker` in the module :code:`mymodule` under the package :code:`mypackage` and want to use it in a :py:meth:`.map() <asyncio_taskpool.pool.TaskPool.map>` call with the arguments :code:`'x'`, :code:`'x'`, and :code:`'z'`, you would do it like this:
.. code-block:: none
> map mypackage.mymodule.worker ['x','y','z'] -n 3
The :code:`-n` is a shorthand for :code:`--num-concurrent` in this case. In general, all (public) pool methods will have a corresponding command in the control session.
.. note::
The :code:`ast.literal_eval` function from the `standard library <https://docs.python.org/3/library/ast.html#ast.literal_eval>`_ is used to safely evaluate the iterable of arguments to work on. For obvious reasons, being able to provide arbitrary python objects in such a control session is neither practical nor secure. The way this is implemented now is limited in that regard, since you can only use Python literals and containers as arguments for your coroutine functions.
To exit a control session, use the :code:`exit` command or simply press :code:`Ctrl + D`.

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@ -1,42 +0,0 @@
.. This file is part of asyncio-taskpool.
.. asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
.. asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
.. You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>.
.. Copyright © 2022 Daniil Fajnberg
IDs, groups & names
===================
Task IDs
--------
Every task spawned within a pool receives an ID, which is an integer greater or equal to 0 that is unique **within that task pool instance**. An internal counter is incremented whenever a new task is spawned. A task with ID :code:`n` was the :code:`(n+1)`-th task to be spawned in the pool. Task IDs can be used to cancel specific tasks using the :py:meth:`.cancel() <asyncio_taskpool.pool.BaseTaskPool.cancel>` method.
In practice, it should rarely be necessary to target *specific* tasks. When dealing with a regular :py:class:`TaskPool <asyncio_taskpool.pool.TaskPool>` instance, you would typically cancel entire task groups (see below) rather than individual tasks, whereas with :py:class:`SimpleTaskPool <asyncio_taskpool.pool.SimpleTaskPool>` instances you would indiscriminately cancel a number of tasks using the :py:meth:`.stop() <asyncio_taskpool.pool.SimpleTaskPool.stop>` method.
The ID of a pool task also appears in the task's name, which is set upon spawning it. (See `here <https://docs.python.org/3/library/asyncio-task.html#asyncio.Task.set_name>`_ for the associated method of the :code:`Task` class.)
Task groups
-----------
Every method of spawning new tasks in a task pool will add them to a **task group** and return the name of that group. With :py:class:`TaskPool <asyncio_taskpool.pool.TaskPool>` methods such as :py:meth:`.apply() <asyncio_taskpool.pool.TaskPool.apply>` and :py:meth:`.map() <asyncio_taskpool.pool.TaskPool.map>`, the group name can be set explicitly via the :code:`group_name` parameter. By default, the name will be a string containing some meta information depending on which method is used. Passing an existing task group name in any of those methods will result in a :py:class:`InvalidGroupName <asyncio_taskpool.exceptions.InvalidGroupName>` error.
You can cancel entire task groups using the :py:meth:`.cancel_group() <asyncio_taskpool.pool.BaseTaskPool.cancel_group>` method by passing it the group name. To check which tasks belong to a group, the :py:meth:`.get_group_ids() <asyncio_taskpool.pool.BaseTaskPool.get_group_ids>` method can be used, which takes group names and returns the IDs of the tasks belonging to them.
The :py:meth:`SimpleTaskPool.start() <asyncio_taskpool.pool.SimpleTaskPool.start>` method will create a new group as well, each time it is called, but it does not allow customizing the group name. Typically, it will not be necessary to keep track of groups in a :py:class:`SimpleTaskPool <asyncio_taskpool.pool.SimpleTaskPool>` instance.
Task groups do not impose limits on the number of tasks in them, although they can be indirectly constrained by pool size limits.
Pool names
----------
When initializing a task pool, you can provide a custom name for it, which will appear in its string representation, e.g. when using it in a :code:`print()`. A class attribute keeps track of initialized task pools and assigns each one an index (similar to IDs for pool tasks). If no name is specified when creating a new pool, its index is used in the string representation of it. Pool names can be helpful when using multiple pools and analyzing log messages.

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@ -1,233 +0,0 @@
.. This file is part of asyncio-taskpool.
.. asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
.. asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
.. You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>.
.. Copyright © 2022 Daniil Fajnberg
Task pools
==========
What is a task pool?
--------------------
A task pool is an object with a simple interface for aggregating and dynamically managing asynchronous tasks.
To make use of task pools, your code obviously needs to contain coroutine functions (introduced with the :code:`async def` keywords). By adding such functions along with their arguments to a task pool, they are turned into tasks and executed asynchronously.
If you are familiar with the :code:`Pool` class of the `multiprocessing module <https://docs.python.org/3/library/multiprocessing.html#module-multiprocessing.pool>`_ from the standard library, then you should feel at home with the :py:class:`TaskPool <asyncio_taskpool.pool.TaskPool>` class. Obviously, there are major conceptual and functional differences between the two, but the methods provided by the :py:class:`TaskPool <asyncio_taskpool.pool.TaskPool>` follow a very similar logic. If you never worked with process or thread pools, don't worry. Task pools are much simpler.
The :code:`TaskPool` class
--------------------------
There are essentially two distinct use cases for a concurrency pool. You want to
#. execute a function *n* times with the same arguments concurrently or
#. execute a function *n* times with different arguments concurrently.
The first is accomplished with the :py:meth:`TaskPool.apply() <asyncio_taskpool.pool.TaskPool.apply>` method, while the second is accomplished with the :py:meth:`TaskPool.map() <asyncio_taskpool.pool.TaskPool.map>` method and its variations :py:meth:`.starmap() <asyncio_taskpool.pool.TaskPool.starmap>` and :py:meth:`.doublestarmap() <asyncio_taskpool.pool.TaskPool.doublestarmap>`.
Let's take a look at an example. Say you have a coroutine function that takes two queues as arguments: The first one being an input-queue (containing items to work on) and the second one being the output queue (for passing on the results to some other function). Your function may look something like this:
.. code-block:: python
:caption: work.py
:name: queue-worker-function
from asyncio.queues import Queue
async def queue_worker_function(in_queue: Queue, out_queue: Queue) -> None:
while True:
item = await in_queue.get()
... # Do some work on the item and arrive at a result.
await out_queue.put(result)
How would we go about concurrently executing this function, say 5 times? There are (as always) a number of ways to do this with :code:`asyncio`. If we want to use tasks and be clean about it, we can do it like this:
.. code-block:: python
:caption: main.py
from asyncio.tasks import create_task, gather
from .work import queue_worker_function
...
# We assume that the queues have been initialized already.
tasks = []
for _ in range(5):
new_task = create_task(queue_worker_function(q_in, q_out))
tasks.append(new_task)
# Run some other code and let the tasks do their thing.
...
# At some point, we want the tasks to stop waiting for new items and end.
for task in tasks:
task.cancel()
...
await gather(*tasks)
By contrast, here is how you would do it with a task pool:
.. code-block:: python
:caption: main.py
from asyncio_taskpool import TaskPool
from .work import queue_worker_function
...
pool = TaskPool()
group_name = pool.apply(queue_worker_function, args=(q_in, q_out), num=5)
...
pool.cancel_group(group_name)
...
await pool.flush()
Pretty much self-explanatory, no? (See :doc:`here <./ids>` for more information about groups/names).
Let's consider a slightly more involved example. Assume you have a coroutine function that takes just one argument (some data) as input, does some work with it (maybe connects to the internet in the process), and eventually writes its results to a database (which is globally defined). Here is how that might look:
.. code-block:: python
:caption: work.py
:name: another-worker-function
from .my_database_stuff import insert_into_results_table
async def another_worker_function(data: object) -> None:
if data.some_attribute > 1:
...
# Do the work, arrive at results.
await insert_into_results_table(results)
Say we have some *iterator* of data-items (of arbitrary length) that we want to be worked on, and say we want 5 coroutines concurrently working on that data. Here is a very naive task-based solution:
.. code-block:: python
:caption: main.py
from asyncio.tasks import create_task, gather
from .work import another_worker_function
async def main():
...
# We got our data_iterator from somewhere.
keep_going = True
while keep_going:
tasks = []
for _ in range(5):
try:
data = next(data_iterator)
except StopIteration:
keep_going = False
break
new_task = create_task(another_worker_function(data))
tasks.append(new_task)
await gather(*tasks)
Here we already run into problems with the task-based approach. The last line in our :code:`while`-loop blocks until **all 5 tasks** return (or raise an exception). This means that as soon as one of them returns, the number of working coroutines is already less than 5 (until all the others return). This can obviously be solved in different ways. We could, for instance, wrap the creation of new tasks itself in a coroutine, which immediately creates a new task, when one is finished, and then call that coroutine 5 times concurrently. Or we could use the queue-based approach from before, but then we would need to write some queue producing coroutine.
Or we could use a task pool:
.. code-block:: python
:caption: main.py
from asyncio_taskpool import TaskPool
from .work import another_worker_function
async def main():
...
pool = TaskPool()
pool.map(another_worker_function, data_iterator, num_concurrent=5)
...
await pool.gather_and_close()
Calling the :py:meth:`.map() <asyncio_taskpool.pool.TaskPool.map>` method this way ensures that there will **always** -- i.e. at any given moment in time -- be exactly 5 tasks working concurrently on our data (assuming no other pool interaction).
The :py:meth:`.gather_and_close() <asyncio_taskpool.pool.BaseTaskPool.gather_and_close>` line will block until **all the data** has been consumed. (see :ref:`blocking-pool-methods`)
.. note::
Neither :py:meth:`.apply() <asyncio_taskpool.pool.TaskPool.apply>` nor :py:meth:`.map() <asyncio_taskpool.pool.TaskPool.map>` return coroutines. When they are called, the task pool immediately begins scheduling new tasks to run. No :code:`await` needed.
It can't get any simpler than that, can it? So glad you asked...
The :code:`SimpleTaskPool` class
--------------------------------
Let's take the :ref:`queue worker example <queue-worker-function>` from before. If we know that the task pool will only ever work with that one function with the same queue objects, we can make use of the :py:class:`SimpleTaskPool <asyncio_taskpool.pool.SimpleTaskPool>` class:
.. code-block:: python
:caption: main.py
from asyncio_taskpool import SimpleTaskPool
from .work import queue_worker_function
async def main():
...
pool = SimpleTaskPool(queue_worker_function, args=(q_in, q_out))
pool.start(5)
...
pool.stop_all()
...
await pool.gather_and_close()
This may, at first glance, not seem like much of a difference, aside from different method names. However, assume that our main function runs a loop and needs to be able to periodically regulate the number of tasks being executed in the pool based on some additional variables it receives. With the :py:class:`SimpleTaskPool <asyncio_taskpool.pool.SimpleTaskPool>`, this could not be simpler:
.. code-block:: python
:caption: main.py
:name: simple-control-logic
from asyncio_taskpool import SimpleTaskPool
from .work import queue_worker_function
async def main():
...
pool = SimpleTaskPool(queue_worker_function, args=(q_in, q_out))
await pool.start(5)
while True:
...
if some_condition and pool.num_running > 10:
pool.stop(3)
elif some_other_condition and pool.num_running < 5:
pool.start(5)
else:
pool.start(1)
...
await pool.gather_and_close()
Notice how we only specify the function and its arguments during initialization of the pool. From that point on, all we need is the :py:meth:`.start() <asyncio_taskpool.pool.SimpleTaskPool.start>` add :py:meth:`.stop() <asyncio_taskpool.pool.SimpleTaskPool.stop>` methods to adjust the number of concurrently running tasks.
The trade-off here is that this simplified task pool class lacks the flexibility of the regular :py:class:`TaskPool <asyncio_taskpool.pool.TaskPool>` class. On an instance of the latter we can call :py:meth:`.map() <asyncio_taskpool.pool.TaskPool.map>` and :py:meth:`.apply() <asyncio_taskpool.pool.TaskPool.apply>` as often as we like with completely unrelated functions and arguments. With a :py:class:`SimpleTaskPool <asyncio_taskpool.pool.SimpleTaskPool>`, once you initialize it, it is pegged to one function and one set of arguments, and all you can do is control the number of tasks working with those.
This simplified interface becomes particularly useful in conjunction with the :doc:`control server <./control>`.
.. _blocking-pool-methods:
(Non-)Blocking pool methods
---------------------------
One of the main concerns when dealing with concurrent programs in general and with :code:`async` functions in particular is when and how a particular piece of code **blocks** during execution, i.e. delays the execution of the following code significantly.
.. note::
Every statement will block to *some* extent. Obviously, when a program does something, that takes time. This is why the proper question to ask is not *if* but *to what extent, under which circumstances* the execution of a particular line of code blocks.
It is fair to assume that anyone reading this is familiar enough with the concepts of asynchronous programming in Python to know that just slapping :code:`async` in front of a function definition will not magically make it suitable for concurrent execution (in any meaningful way). Therefore, we assume that you are dealing with coroutines that can actually unblock the `event loop <https://docs.python.org/3/library/asyncio-eventloop.html>`_ (e.g. doing a significant amount of I/O).
So how does the task pool behave in that regard?
The only method of a pool that one should **always** assume to be blocking is :py:meth:`.gather_and_close() <asyncio_taskpool.pool.BaseTaskPool.gather_and_close>`. This method awaits **all** tasks in the pool, meaning as long as one of them is still running, this coroutine will not return.
.. warning::
This includes awaiting any callbacks that were passed along with the tasks.
One method to be aware of is :py:meth:`.flush() <asyncio_taskpool.pool.BaseTaskPool.flush>`. Since it will await only those tasks that the pool considers **ended** or **cancelled**, the blocking can only come from any callbacks that were provided for either of those situations.
All methods that add tasks to a pool, i.e. :py:meth:`TaskPool.map() <asyncio_taskpool.pool.TaskPool.map>` (and its variants), :py:meth:`TaskPool.apply() <asyncio_taskpool.pool.TaskPool.apply>` and :py:meth:`SimpleTaskPool.start() <asyncio_taskpool.pool.SimpleTaskPool.start>`, are non-blocking by design. They all make use of "meta tasks" under the hood and return immediately. It is important however, to realize that just because they return, does not mean that any actual tasks have been spawned. For example, if a pool size limit was set and there was "no more room" in the pool when :py:meth:`.map() <asyncio_taskpool.pool.TaskPool.map>` was called, there is **no guarantee** that even a single task has started, when it returns.

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@ -1,4 +1,2 @@
-r common.txt
coverage
sphinx
sphinx-rtd-theme

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@ -1,25 +1,17 @@
[metadata]
name = asyncio-taskpool
version = 1.1.4
version = 0.0.1
author = Daniil Fajnberg
author_email = mail@daniil.fajnberg.de
description = Dynamically manage pools of asyncio tasks
long_description = file: README.md
long_description_content_type = text/markdown
keywords = asyncio, concurrency, tasks, coroutines, asynchronous, server
url = https://git.fajnberg.de/daniil/asyncio-taskpool
project_urls =
Bug Tracker = https://github.com/daniil-berg/asyncio-taskpool/issues
Bug Tracker = https://git.fajnberg.de/daniil/asyncio-taskpool/issues
classifiers =
Development Status :: 5 - Production/Stable
Programming Language :: Python :: 3
Operating System :: OS Independent
License :: OSI Approved :: GNU Lesser General Public License v3 (LGPLv3)
Intended Audience :: Developers
Intended Audience :: System Administrators
Framework :: AsyncIO
Topic :: Software Development :: Libraries
Topic :: Software Development :: Libraries :: Python Modules
[options]
package_dir =
@ -30,8 +22,6 @@ python_requires = >=3.8
[options.extras_require]
dev =
coverage
sphinx
sphinx-rtd-theme
[options.packages.find]
where = src

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@ -1,18 +1,2 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
from .pool import TaskPool, SimpleTaskPool
from .server import UnixControlServer

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@ -0,0 +1,46 @@
import sys
from argparse import ArgumentParser
from asyncio import run
from pathlib import Path
from typing import Dict, Any
from .client import ControlClient, UnixControlClient
from .constants import PACKAGE_NAME
from .pool import TaskPool
from .server import ControlServer
CONN_TYPE = 'conn_type'
UNIX, TCP = 'unix', 'tcp'
SOCKET_PATH = 'path'
def parse_cli() -> Dict[str, Any]:
parser = ArgumentParser(
prog=PACKAGE_NAME,
description=f"CLI based {ControlClient.__name__} for {PACKAGE_NAME}"
)
subparsers = parser.add_subparsers(title="Connection types", dest=CONN_TYPE)
unix_parser = subparsers.add_parser(UNIX, help="Connect via unix socket")
unix_parser.add_argument(
SOCKET_PATH,
type=Path,
help=f"Path to the unix socket on which the {ControlServer.__name__} for the {TaskPool.__name__} is listening."
)
return vars(parser.parse_args())
async def main():
kwargs = parse_cli()
if kwargs[CONN_TYPE] == UNIX:
client = UnixControlClient(path=kwargs[SOCKET_PATH])
elif kwargs[CONN_TYPE] == TCP:
# TODO: Implement the TCP client class
client = UnixControlClient(path=kwargs[SOCKET_PATH])
else:
print("Invalid connection type", file=sys.stderr)
sys.exit(2)
await client.start()
if __name__ == '__main__':
run(main())

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@ -0,0 +1,63 @@
import sys
from abc import ABC, abstractmethod
from asyncio.streams import StreamReader, StreamWriter, open_unix_connection
from pathlib import Path
from asyncio_taskpool import constants
from asyncio_taskpool.types import ClientConnT
class ControlClient(ABC):
@abstractmethod
async def open_connection(self, **kwargs) -> ClientConnT:
raise NotImplementedError
def __init__(self, **conn_kwargs) -> None:
self._conn_kwargs = conn_kwargs
self._connected: bool = False
async def _interact(self, reader: StreamReader, writer: StreamWriter) -> None:
try:
msg = input("> ").strip().lower()
except EOFError:
msg = constants.CLIENT_EXIT
except KeyboardInterrupt:
print()
return
if msg == constants.CLIENT_EXIT:
writer.close()
self._connected = False
return
try:
writer.write(msg.encode())
await writer.drain()
except ConnectionError as e:
self._connected = False
print(e, file=sys.stderr)
return
print((await reader.read(constants.MSG_BYTES)).decode())
async def start(self):
reader, writer = await self.open_connection(**self._conn_kwargs)
if reader is None:
print("Failed to connect.", file=sys.stderr)
return
self._connected = True
print("Connected to", (await reader.read(constants.MSG_BYTES)).decode())
while self._connected:
await self._interact(reader, writer)
print("Disconnected from control server.")
class UnixControlClient(ControlClient):
def __init__(self, **conn_kwargs) -> None:
self._socket_path = Path(conn_kwargs.pop('path'))
super().__init__(**conn_kwargs)
async def open_connection(self, **kwargs) -> ClientConnT:
try:
return await open_unix_connection(self._socket_path, **kwargs)
except FileNotFoundError:
print("No socket at", self._socket_path, file=sys.stderr)
return None, None

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@ -0,0 +1,8 @@
PACKAGE_NAME = 'asyncio_taskpool'
MSG_BYTES = 1024
CMD_START = 'start'
CMD_STOP = 'stop'
CMD_STOP_ALL = 'stop_all'
CMD_SIZE = 'size'
CMD_FUNC = 'func'
CLIENT_EXIT = 'exit'

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@ -1,2 +0,0 @@
from .server import TCPControlServer, UnixControlServer
from .client import TCPControlClient, UnixControlClient

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@ -1,80 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
CLI entry point script for a :class:`ControlClient`.
"""
from argparse import ArgumentParser
from asyncio import run
from pathlib import Path
from typing import Any, Dict, Sequence
from ..internals.constants import PACKAGE_NAME
from ..pool import TaskPool
from .client import TCPControlClient, UnixControlClient
from .server import TCPControlServer, UnixControlServer
__all__ = []
CLIENT_CLASS = 'client_class'
UNIX, TCP = 'unix', 'tcp'
SOCKET_PATH = 'socket_path'
HOST, PORT = 'host', 'port'
def parse_cli(args: Sequence[str] = None) -> Dict[str, Any]:
parser = ArgumentParser(
prog=f'{PACKAGE_NAME}.control',
description=f"Simple CLI based control client for {PACKAGE_NAME}"
)
subparsers = parser.add_subparsers(title="Connection types")
tcp_parser = subparsers.add_parser(TCP, help="Connect via TCP socket")
tcp_parser.add_argument(
HOST,
help=f"IP address or url that the {TCPControlServer.__name__} for the {TaskPool.__name__} is listening on."
)
tcp_parser.add_argument(
PORT,
type=int,
help=f"Port that the {TCPControlServer.__name__} for the {TaskPool.__name__} is listening on."
)
tcp_parser.set_defaults(**{CLIENT_CLASS: TCPControlClient})
unix_parser = subparsers.add_parser(UNIX, help="Connect via unix socket")
unix_parser.add_argument(
SOCKET_PATH,
type=Path,
help=f"Path to the unix socket on which the {UnixControlServer.__name__} for the {TaskPool.__name__} is "
f"listening."
)
unix_parser.set_defaults(**{CLIENT_CLASS: UnixControlClient})
return vars(parser.parse_args(args))
async def main():
kwargs = parse_cli()
client_cls = kwargs.pop(CLIENT_CLASS)
await client_cls(**kwargs).start()
if __name__ == '__main__':
run(main())

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@ -1,209 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Classes of control clients for a simply interface to a task pool control server.
"""
import json
import shutil
import sys
from abc import ABC, abstractmethod
from asyncio.streams import StreamReader, StreamWriter, open_connection
from pathlib import Path
from typing import Optional, Union
from ..internals.constants import CLIENT_INFO, SESSION_MSG_BYTES
from ..internals.types import ClientConnT, PathT
__all__ = [
'ControlClient',
'TCPControlClient',
'UnixControlClient',
'CLIENT_EXIT'
]
CLIENT_EXIT = 'exit'
class ControlClient(ABC):
"""
Abstract base class for a simple implementation of a pool control client.
Since the server's control interface is simply expecting commands to be sent, any process able to connect to the
TCP or UNIX socket and issue the relevant commands (and optionally read the responses) will work just as well.
This is a minimal working implementation.
"""
@staticmethod
def _client_info() -> dict:
"""Returns a dictionary of client information relevant for the handshake with the server."""
return {CLIENT_INFO.TERMINAL_WIDTH: shutil.get_terminal_size().columns}
@abstractmethod
async def _open_connection(self, **kwargs) -> ClientConnT:
"""
Tries to connect to a socket using the provided arguments and return the associated reader-writer-pair.
This method will be invoked by the public `start()` method with the pre-defined internal `_conn_kwargs`
(unpacked) as keyword-arguments.
This method should return either a tuple of `asyncio.StreamReader` and `asyncio.StreamWriter` or a tuple of
`None` and `None`, if it failed to establish the defined connection.
"""
raise NotImplementedError
def __init__(self, **conn_kwargs) -> None:
"""Simply stores the keyword-arguments for opening the connection."""
self._conn_kwargs = conn_kwargs
self._connected: bool = False
async def _server_handshake(self, reader: StreamReader, writer: StreamWriter) -> None:
"""
Performs the first interaction with the server providing it with the necessary client information.
Upon completion, the server's info is printed.
Args:
reader: The `asyncio.StreamReader` returned by the `_open_connection()` method
writer: The `asyncio.StreamWriter` returned by the `_open_connection()` method
"""
self._connected = True
writer.write(json.dumps(self._client_info()).encode())
writer.write(b'\n')
await writer.drain()
print("Connected to", (await reader.read(SESSION_MSG_BYTES)).decode())
print("Type '-h' to get help and usage instructions for all available commands.\n")
def _get_command(self, writer: StreamWriter) -> Optional[str]:
"""
Prompts the user for input and either returns it (after cleaning it up) or `None` in special cases.
Args:
writer: The `asyncio.StreamWriter` returned by the `_open_connection()` method
Returns:
`None`, if either `Ctrl+C` was hit, an empty or whitespace-only string was entered, or the user wants the
client to disconnect; otherwise, returns the user's input, stripped of leading and trailing spaces and
converted to lowercase.
"""
try:
cmd = input("> ").strip().lower()
except EOFError: # Ctrl+D shall be equivalent to the :const:`CLIENT_EXIT` command.
cmd = CLIENT_EXIT
except KeyboardInterrupt: # Ctrl+C shall simply reset to the input prompt.
print()
return
if cmd == CLIENT_EXIT:
writer.close()
self._connected = False
return
return cmd or None # will be None if `cmd` is an empty string
async def _interact(self, reader: StreamReader, writer: StreamWriter) -> None:
"""
Reacts to the user's command, potentially performing a back-and-forth interaction with the server.
If `_get_command` returns `None`, this may imply that the client disconnected, but may also just be `Ctrl+C`.
If an actual command is retrieved, it is written to the stream, a response is awaited and eventually printed.
Args:
reader: The `asyncio.StreamReader` returned by the `_open_connection()` method
writer: The `asyncio.StreamWriter` returned by the `_open_connection()` method
"""
cmd = self._get_command(writer)
if cmd is None:
return
try:
# Send the command to the server.
writer.write(cmd.encode())
writer.write(b'\n')
await writer.drain()
except ConnectionError as e:
self._connected = False
print(e, file=sys.stderr)
return
# Await the server's response, then print it.
print((await reader.read(SESSION_MSG_BYTES)).decode())
async def start(self) -> None:
"""
Opens connection, performs handshake, and enters interaction loop.
An input prompt is presented to the user and any input is sent (encoded) to the connected server.
One exception is the :const:`CLIENT_EXIT` command (equivalent to Ctrl+D), which merely closes the connection.
If the connection can not be established, an error message is printed to `stderr` and the method returns.
If either the exit command is issued or the connection to the server is lost during the interaction loop,
the method returns and prints out a disconnected-message.
"""
reader, writer = await self._open_connection(**self._conn_kwargs)
if reader is None:
print("Failed to connect.", file=sys.stderr)
return
await self._server_handshake(reader, writer)
while self._connected:
await self._interact(reader, writer)
print("Disconnected from control server.")
class TCPControlClient(ControlClient):
"""Task pool control client for connecting to a :class:`TCPControlServer`."""
def __init__(self, host: str, port: Union[int, str], **conn_kwargs) -> None:
"""`host` and `port` are expected as non-optional connection arguments."""
self._host = host
self._port = port
super().__init__(**conn_kwargs)
async def _open_connection(self, **kwargs) -> ClientConnT:
"""
Wrapper around the `asyncio.open_connection` function.
Returns a tuple of `None` and `None`, if the connection can not be established;
otherwise, the stream-reader and -writer tuple is returned.
"""
try:
return await open_connection(self._host, self._port, **kwargs)
except ConnectionError as e:
print(str(e), file=sys.stderr)
return None, None
class UnixControlClient(ControlClient):
"""Task pool control client for connecting to a :class:`UnixControlServer`."""
def __init__(self, socket_path: PathT, **conn_kwargs) -> None:
"""`socket_path` is expected as a non-optional connection argument."""
from asyncio.streams import open_unix_connection
self._open_unix_connection = open_unix_connection
self._socket_path = Path(socket_path)
super().__init__(**conn_kwargs)
async def _open_connection(self, **kwargs) -> ClientConnT:
"""
Wrapper around the `asyncio.open_unix_connection` function.
Returns a tuple of `None` and `None`, if the socket is not found at the pre-defined path;
otherwise, the stream-reader and -writer tuple is returned.
"""
try:
return await self._open_unix_connection(self._socket_path, **kwargs)
except FileNotFoundError:
print("No socket at", self._socket_path, file=sys.stderr)
return None, None

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@ -1,342 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Definition of the :class:`ControlParser` used in a
:class:`ControlSession <asyncio_taskpool.control.session.ControlSession>`.
It should not be considered part of the public API.
"""
import logging
from argparse import Action, ArgumentParser, ArgumentDefaultsHelpFormatter, HelpFormatter, ArgumentTypeError, SUPPRESS
from ast import literal_eval
from inspect import Parameter, getmembers, isfunction, signature
from io import StringIO
from shutil import get_terminal_size
from typing import Any, Callable, Container, Dict, Iterable, Set, Type, TypeVar
from ..exceptions import HelpRequested, ParserError
from ..internals.constants import CLIENT_INFO, CMD
from ..internals.helpers import get_first_doc_line, resolve_dotted_path
from ..internals.types import ArgsT, CancelCB, CoroutineFunc, EndCB, KwArgsT
__all__ = ['ControlParser']
log = logging.getLogger(__name__)
FmtCls = TypeVar('FmtCls', bound=Type[HelpFormatter])
ParsersDict = Dict[str, 'ControlParser']
OMIT_PARAMS_DEFAULT = ('self', )
NAME, PROG, HELP, DESCRIPTION = 'name', 'prog', 'help', 'description'
class ControlParser(ArgumentParser):
"""
Subclass of the standard :code:`argparse.ArgumentParser` for pool control.
Such a parser is not supposed to ever print to stdout/stderr, but instead direct all messages to a file-like
`StringIO` instance passed to it during initialization.
Furthermore, it requires defining the width of the terminal, to adjust help formatting to the terminal size of a
connected client.
Finally, it offers some convenience methods and makes use of custom exceptions.
"""
@staticmethod
def help_formatter_factory(terminal_width: int, base_cls: FmtCls = None) -> FmtCls:
"""
Constructs and returns a subclass of :class:`argparse.HelpFormatter`
The formatter class will have the defined `terminal_width`.
Although a custom formatter class can be explicitly passed into the :class:`ArgumentParser` constructor,
this is not as convenient, when making use of sub-parsers.
Args:
terminal_width:
The number of columns of the terminal to which to adjust help formatting.
base_cls (optional):
Base class to use for inheritance. By default :class:`argparse.ArgumentDefaultsHelpFormatter` is used.
Returns:
The subclass of `base_cls` which fixes the constructor's `width` keyword-argument to `terminal_width`.
"""
if base_cls is None:
base_cls = ArgumentDefaultsHelpFormatter
class ClientHelpFormatter(base_cls):
def __init__(self, *args, **kwargs) -> None:
kwargs['width'] = terminal_width
super().__init__(*args, **kwargs)
return ClientHelpFormatter
def __init__(self, stream: StringIO, terminal_width: int = None, **kwargs) -> None:
"""
Sets some internal attributes in addition to the base class.
Args:
stream:
A file-like I/O object to use for message output.
terminal_width (optional):
The terminal width to use for all message formatting. By default the :code:`columns` attribute from
:func:`shutil.get_terminal_size` is taken.
**kwargs(optional):
Passed to the parent class constructor. The exception is the `formatter_class` parameter: Even if a
class is specified, it will always be subclassed in the :meth:`help_formatter_factory`.
"""
self._stream: StringIO = stream
self._terminal_width: int = terminal_width if terminal_width is not None else get_terminal_size().columns
kwargs['formatter_class'] = self.help_formatter_factory(self._terminal_width, kwargs.get('formatter_class'))
super().__init__(**kwargs)
self._flags: Set[str] = set()
self._commands = None
def add_function_command(self, function: Callable, omit_params: Container[str] = OMIT_PARAMS_DEFAULT,
**subparser_kwargs) -> 'ControlParser':
"""
Takes a function and adds a corresponding (sub-)command to the parser.
The :meth:`add_subparsers` method must have been called prior to this.
NOTE: Currently, only a limited spectrum of parameters can be accurately converted to parser arguments.
This method works correctly with any public method of the any task pool class.
Args:
function:
The reference to the function to be "converted" to a parser command.
omit_params (optional):
Names of function parameters not to add as parser arguments.
**subparser_kwargs (optional):
Passed directly to the :meth:`add_parser` method.
Returns:
The subparser instance created from the function.
"""
subparser_kwargs.setdefault(NAME, function.__name__.replace('_', '-'))
subparser_kwargs.setdefault(PROG, subparser_kwargs[NAME])
subparser_kwargs.setdefault(HELP, get_first_doc_line(function))
subparser_kwargs.setdefault(DESCRIPTION, subparser_kwargs[HELP])
subparser: ControlParser = self._commands.add_parser(**subparser_kwargs)
subparser.add_function_args(function, omit_params)
return subparser
def add_property_command(self, prop: property, cls_name: str = '', **subparser_kwargs) -> 'ControlParser':
"""
Same as the :meth:`add_function_command` method, but for properties.
Args:
prop:
The reference to the property to be "converted" to a parser command.
cls_name (optional):
Name of the class the property is defined on to appear in the command help text.
**subparser_kwargs (optional):
Passed directly to the :meth:`add_parser` method.
Returns:
The subparser instance created from the property.
"""
subparser_kwargs.setdefault(NAME, prop.fget.__name__.replace('_', '-'))
subparser_kwargs.setdefault(PROG, subparser_kwargs[NAME])
getter_help = get_first_doc_line(prop.fget)
if prop.fset is None:
subparser_kwargs.setdefault(HELP, getter_help)
else:
subparser_kwargs.setdefault(HELP, f"Get/set the `{cls_name}.{subparser_kwargs[NAME]}` property")
subparser_kwargs.setdefault(DESCRIPTION, subparser_kwargs[HELP])
subparser: ControlParser = self._commands.add_parser(**subparser_kwargs)
if prop.fset is not None:
_, param = signature(prop.fset).parameters.values()
setter_arg_help = f"If provided: {get_first_doc_line(prop.fset)} If omitted: {getter_help}"
subparser.add_function_arg(param, nargs='?', default=SUPPRESS, help=setter_arg_help)
return subparser
def add_class_commands(self, cls: Type, public_only: bool = True, omit_members: Container[str] = (),
member_arg_name: str = CMD) -> ParsersDict:
"""
Adds methods/properties of a class as (sub-)commands to the parser.
The :meth:`add_subparsers` method must have been called prior to this.
NOTE: Currently, only a limited spectrum of function parameters can be accurately converted to parser arguments.
This method works correctly with any task pool class.
Args:
cls:
The reference to the class whose methods/properties are to be "converted" to parser commands.
public_only (optional):
If `False`, protected and private members are considered as well. `True` by default.
omit_members (optional):
Names of functions/properties not to add as parser commands.
member_arg_name (optional):
After parsing the arguments, depending on which command was invoked by the user, the corresponding
method/property will be stored as an extra argument in the parsed namespace under this attribute name.
Returns:
Dictionary mapping class member names to the (sub-)parsers created from them.
"""
parsers: ParsersDict = {}
common_kwargs = {'stream': self._stream, CLIENT_INFO.TERMINAL_WIDTH: self._terminal_width}
for name, member in getmembers(cls):
if name in omit_members or (name.startswith('_') and public_only):
continue
if isfunction(member):
subparser = self.add_function_command(member, **common_kwargs)
elif isinstance(member, property):
subparser = self.add_property_command(member, cls.__name__, **common_kwargs)
else:
continue
subparser.set_defaults(**{member_arg_name: member})
parsers[name] = subparser
return parsers
def add_subparsers(self, *args, **kwargs):
"""Adds the subparsers action as an attribute before returning it."""
self._commands = super().add_subparsers(*args, **kwargs)
return self._commands
def _print_message(self, message: str, *args, **kwargs) -> None:
"""This is overridden to ensure that no messages are sent to stdout/stderr, but always to the stream buffer."""
if message:
self._stream.write(message)
def exit(self, status: int = 0, message: str = None) -> None:
"""This is overridden to prevent system exit to be invoked."""
if message:
self._print_message(message)
def error(self, message: str) -> None:
"""Raises the :exc:`ParserError <asyncio_taskpool.exceptions.ParserError>` exception at the end."""
super().error(message=message)
raise ParserError
def print_help(self, file=None) -> None:
"""Raises the :exc:`HelpRequested <asyncio_taskpool.exceptions.HelpRequested>` exception at the end."""
super().print_help(file)
raise HelpRequested
def add_function_arg(self, parameter: Parameter, **kwargs) -> Action:
"""
Takes an :class:`inspect.Parameter` and adds a corresponding parser argument.
NOTE: Currently, only a limited spectrum of parameters can be accurately converted to a parser argument.
This method works correctly with any parameter of any public method any task pool class.
Args:
parameter: The :class:`inspect.Parameter` object to be converted to a parser argument.
**kwargs: Passed to the :meth:`add_argument` method of the base class.
Returns:
The :class:`argparse.Action` returned by the :meth:`add_argument` method.
"""
if parameter.default is Parameter.empty:
# A non-optional function parameter should correspond to a positional argument.
name_or_flags = [parameter.name]
else:
flag = None
long = f'--{parameter.name.replace("_", "-")}'
# We try to generate a short version (flag) for the argument.
letter = parameter.name[0]
if letter not in self._flags:
flag = f'-{letter}'
self._flags.add(letter)
elif letter.upper() not in self._flags:
flag = f'-{letter.upper()}'
self._flags.add(letter.upper())
name_or_flags = [long] if flag is None else [flag, long]
if parameter.annotation is bool:
# If we are dealing with a boolean parameter, always use the 'store_true' action.
# Even if the parameter's default value is `True`, this will make the parser argument's default `False`.
kwargs.setdefault('action', 'store_true')
else:
# For now, any other type annotation will implicitly use the default action 'store'.
# In addition, we always set the default value.
kwargs.setdefault('default', parameter.default)
if parameter.kind == Parameter.VAR_POSITIONAL:
# This is to be able to later unpack an arbitrary number of positional arguments.
kwargs.setdefault('nargs', '*')
if not kwargs.get('action') == 'store_true':
# Set the type from the parameter annotation.
kwargs.setdefault('type', _get_type_from_annotation(parameter.annotation))
return self.add_argument(*name_or_flags, **kwargs)
def add_function_args(self, function: Callable, omit: Container[str] = OMIT_PARAMS_DEFAULT) -> None:
"""
Takes a function and adds its parameters as arguments to the parser.
NOTE: Currently, only a limited spectrum of parameters can be accurately converted to a parser argument.
This method works correctly with any public method of any task pool class.
Args:
function:
The function whose parameters are to be converted to parser arguments.
Its parameters must be properly annotated.
omit (optional):
Names of function parameters not to add as parser arguments.
"""
for param in signature(function).parameters.values():
if param.name not in omit:
# TODO: Look into parsing docstrings properly to try and extract argument help text.
# For now, the argument help just shows the type it will be converted to.
self.add_function_arg(param, help=repr(param.annotation))
def _get_arg_type_wrapper(cls: Type) -> Callable[[Any], Any]:
"""
Returns a wrapper for the constructor of `cls` to avoid a ValueError being raised on suppressed arguments.
See: https://bugs.python.org/issue36078
In addition, the type conversion wrapper catches exceptions not handled properly by the parser, logs them, and
turns them into `ArgumentTypeError` exceptions the parser can propagate to the client.
"""
def wrapper(arg: Any) -> Any:
if arg is SUPPRESS:
return arg
try:
return cls(arg)
except (ArgumentTypeError, TypeError, ValueError):
raise # handled properly by the parser and propagated to the client anyway
except Exception as e:
text = f"{e.__class__.__name__} occurred in parser trying to convert type: {cls.__name__}({repr(arg)})"
log.exception(text)
raise ArgumentTypeError(text) # propagate to the client
# Copy the name of the class to maintain useful help messages when incorrect arguments are passed.
wrapper.__name__ = cls.__name__
return wrapper
def _get_type_from_annotation(annotation: Type) -> Callable[[Any], Any]:
"""
Returns a type conversion function based on the `annotation` passed.
Required to properly convert parsed arguments to the type expected by certain pool methods.
Each conversion function is wrapped by `_get_arg_type_wrapper`.
`Callable`-type annotations give the `resolve_dotted_path` function.
`Iterable`- or args/kwargs-type annotations give the `ast.literal_eval` function.
Others pass unchanged (but still wrapped with `_get_arg_type_wrapper`).
"""
if any(annotation is t for t in {CoroutineFunc, EndCB, CancelCB}):
annotation = resolve_dotted_path
if any(annotation is t for t in {ArgsT, KwArgsT, Iterable[ArgsT], Iterable[KwArgsT]}):
annotation = literal_eval
return _get_arg_type_wrapper(annotation)

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@ -1,182 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Task pool control server class definitions.
"""
import logging
from abc import ABC, abstractmethod
from asyncio import AbstractServer
from asyncio.exceptions import CancelledError
from asyncio.streams import StreamReader, StreamWriter, start_server
from asyncio.tasks import Task, create_task
from pathlib import Path
from typing import Optional, Union
from .client import ControlClient, TCPControlClient, UnixControlClient
from .session import ControlSession
from ..pool import AnyTaskPoolT
from ..internals.helpers import classmethod
from ..internals.types import ConnectedCallbackT, PathT
__all__ = ['ControlServer', 'TCPControlServer', 'UnixControlServer']
log = logging.getLogger(__name__)
class ControlServer(ABC):
"""
Abstract base class for a task pool control server.
This class acts as a wrapper around an async server instance and initializes a
:class:`ControlSession <asyncio_taskpool.control.session.ControlSession>` once a client connects to it.
The interface is defined within the session class.
"""
_client_class = ControlClient
@classmethod
@property
def client_class_name(cls) -> str:
"""Returns the name of the matching control client class."""
return cls._client_class.__name__
def __init__(self, pool: AnyTaskPoolT, **server_kwargs) -> None:
"""
Merely sets internal attributes, but does not start the server yet.
The task pool must be passed here and can not be set/changed afterwards. This means a control server is always
tied to one specific task pool.
Args:
pool:
An instance of a `BaseTaskPool` subclass to tie the server to.
**server_kwargs (optional):
Keyword arguments that will be passed into the function that starts the server.
"""
self._pool: AnyTaskPoolT = pool
self._server_kwargs = server_kwargs
self._server: Optional[AbstractServer] = None
@property
def pool(self) -> AnyTaskPoolT:
"""The task pool instance controlled by the server."""
return self._pool
def is_serving(self) -> bool:
"""Wrapper around the `asyncio.Server.is_serving` method."""
return self._server.is_serving()
async def _client_connected_cb(self, reader: StreamReader, writer: StreamWriter) -> None:
"""
The universal client callback that will be passed into the `_get_server_instance` method.
Instantiates a control session, performs the client handshake, and enters the session's `listen` loop.
"""
session = ControlSession(self, reader, writer)
await session.client_handshake()
await session.listen()
@abstractmethod
async def _get_server_instance(self, client_connected_cb: ConnectedCallbackT, **kwargs) -> AbstractServer:
"""
Initializes, starts, and returns an async server instance (Unix or TCP type).
Args:
client_connected_cb:
The callback for when a client connects to the server (as per `asyncio.start_server` or
`asyncio.start_unix_server`); will always be the internal `_client_connected_cb` method.
**kwargs (optional):
Keyword arguments to pass into the function that starts the server.
Returns:
The running server object (a type of `asyncio.Server`).
"""
raise NotImplementedError
@abstractmethod
def _final_callback(self) -> None:
"""The method to run after the server's `serve_forever` methods ends for whatever reason."""
raise NotImplementedError
async def _serve_forever(self) -> None:
"""
To be run as an `asyncio.Task` by the following method.
Serves as a wrapper around the the `asyncio.Server.serve_forever` method that ensures that the `_final_callback`
method is called, when the former method ends for whatever reason.
"""
try:
async with self._server:
await self._server.serve_forever()
except CancelledError:
log.debug("%s stopped", self.__class__.__name__)
finally:
self._final_callback()
async def serve_forever(self) -> Task:
"""
Starts the server and begins listening to client connections.
It should never block because the serving will be performed in a separate task.
Returns:
The forever serving task. To stop the server, this task should be cancelled.
"""
log.debug("Starting %s...", self.__class__.__name__)
self._server = await self._get_server_instance(self._client_connected_cb, **self._server_kwargs)
return create_task(self._serve_forever())
class TCPControlServer(ControlServer):
"""Exposes a TCP socket for control clients to connect to."""
_client_class = TCPControlClient
def __init__(self, pool: AnyTaskPoolT, host: str, port: Union[int, str], **server_kwargs) -> None:
"""`host` and `port` are expected as non-optional server arguments."""
self._host = host
self._port = port
super().__init__(pool, **server_kwargs)
async def _get_server_instance(self, client_connected_cb: ConnectedCallbackT, **kwargs) -> AbstractServer:
server = await start_server(client_connected_cb, self._host, self._port, **kwargs)
log.debug("Opened socket at %s:%s", self._host, self._port)
return server
def _final_callback(self) -> None:
log.debug("Closed socket at %s:%s", self._host, self._port)
class UnixControlServer(ControlServer):
"""Exposes a unix socket for control clients to connect to."""
_client_class = UnixControlClient
def __init__(self, pool: AnyTaskPoolT, socket_path: PathT, **server_kwargs) -> None:
"""`socket_path` is expected as a non-optional server argument."""
from asyncio.streams import start_unix_server
self._start_unix_server = start_unix_server
self._socket_path = Path(socket_path)
super().__init__(pool, **server_kwargs)
async def _get_server_instance(self, client_connected_cb: ConnectedCallbackT, **kwargs) -> AbstractServer:
server = await self._start_unix_server(client_connected_cb, self._socket_path, **kwargs)
log.debug("Opened socket '%s'", str(self._socket_path))
return server
def _final_callback(self) -> None:
"""Removes the unix socket on which the server was listening."""
self._socket_path.unlink()
log.debug("Removed socket '%s'", str(self._socket_path))

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@ -1,200 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Definition of the :class:`ControlSession` used by a :class:`ControlServer`.
It should not be considered part of the public API.
"""
import logging
import json
from argparse import ArgumentError
from asyncio.streams import StreamReader, StreamWriter
from inspect import isfunction, signature
from io import StringIO
from typing import Callable, Optional, Union, TYPE_CHECKING
from .parser import ControlParser
from ..exceptions import CommandError, HelpRequested, ParserError
from ..pool import TaskPool, SimpleTaskPool
from ..internals.constants import CLIENT_INFO, CMD, CMD_OK
from ..internals.helpers import return_or_exception
if TYPE_CHECKING:
from .server import ControlServer
__all__ = ['ControlSession']
log = logging.getLogger(__name__)
class ControlSession:
"""
Manages a single control session between a server and a client.
The commands received from a connected client are translated into method calls on the task pool instance.
A subclass of the standard :class:`argparse.ArgumentParser` is used to handle the input read from the stream.
"""
def __init__(self, server: 'ControlServer', reader: StreamReader, writer: StreamWriter) -> None:
"""
Connection to the control server should already been established.
For more convenient/efficient access, some of the server's properties are saved in separate attributes.
The argument parser is _not_ instantiated in the constructor. It requires a bit of client information during
initialization, which is obtained in the `client_handshake` method; only there is the parser fully configured.
Args:
server:
The instance of a :class:`ControlServer` subclass starting the session.
reader:
The `asyncio.StreamReader` created when a client connected to the server.
writer:
The `asyncio.StreamWriter` created when a client connected to the server.
"""
self._control_server: 'ControlServer' = server
self._pool: Union[TaskPool, SimpleTaskPool] = server.pool
self._client_class_name = server.client_class_name
self._reader: StreamReader = reader
self._writer: StreamWriter = writer
self._parser: Optional[ControlParser] = None
self._response_buffer: StringIO = StringIO()
async def _exec_method_and_respond(self, method: Callable, **kwargs) -> None:
"""
Takes a pool method reference, executes it, and writes a response accordingly.
If the first parameter is named `self`, the method will be called with the `_pool` instance as its first
positional argument.
If it returns nothing, the response upon successful execution will be :const:`constants.CMD_OK`, otherwise the
response written to the stream will be its return value (as an encoded string).
Args:
prop:
The reference to the method defined on the `_pool` instance's class.
**kwargs (optional):
Must correspond to the arguments expected by the `method`.
Correctly unpacks arbitrary-length positional and keyword-arguments.
"""
log.debug("%s calls %s.%s", self._client_class_name, self._pool.__class__.__name__, method.__name__)
normal_pos, var_pos = [], []
for param in signature(method).parameters.values():
if param.name == 'self':
normal_pos.append(self._pool)
elif param.kind in (param.POSITIONAL_OR_KEYWORD, param.POSITIONAL_ONLY):
normal_pos.append(kwargs.pop(param.name))
elif param.kind == param.VAR_POSITIONAL:
var_pos = kwargs.pop(param.name)
output = await return_or_exception(method, *normal_pos, *var_pos, **kwargs)
self._response_buffer.write(CMD_OK.decode() if output is None else str(output))
async def _exec_property_and_respond(self, prop: property, **kwargs) -> None:
"""
Takes a pool property reference, executes its setter or getter, and writes a response accordingly.
The property set/get method will always be called with the `_pool` instance as its first positional argument.
Args:
prop:
The reference to the property defined on the `_pool` instance's class.
**kwargs (optional):
If not empty, the property setter is executed and the keyword arguments are passed along to it; the
response upon successful execution will be :const:`constants.CMD_OK`. Otherwise the property getter is
executed and the response written to the stream will be its return value (as an encoded string).
"""
if kwargs:
log.debug("%s sets %s.%s", self._client_class_name, self._pool.__class__.__name__, prop.fset.__name__)
await return_or_exception(prop.fset, self._pool, **kwargs)
self._response_buffer.write(CMD_OK.decode())
else:
log.debug("%s gets %s.%s", self._client_class_name, self._pool.__class__.__name__, prop.fget.__name__)
self._response_buffer.write(str(await return_or_exception(prop.fget, self._pool)))
async def client_handshake(self) -> None:
"""
Must be invoked before starting any other client interaction.
Client info is retrieved, server info is sent back, and the
:class:`ControlParser <asyncio_taskpool.control.parser.ControlParser>` is set up.
"""
msg = (await self._reader.readline()).decode().strip()
client_info = json.loads(msg)
log.debug("%s connected", self._client_class_name)
parser_kwargs = {
'stream': self._response_buffer,
CLIENT_INFO.TERMINAL_WIDTH: client_info[CLIENT_INFO.TERMINAL_WIDTH],
'prog': '',
'usage': f'[-h] [{CMD}] ...'
}
self._parser = ControlParser(**parser_kwargs)
self._parser.add_subparsers(title="Commands",
metavar="(A command followed by '-h' or '--help' will show command-specific help.)")
self._parser.add_class_commands(self._pool.__class__)
self._writer.write(str(self._pool).encode() + b'\n')
await self._writer.drain()
async def _parse_command(self, msg: str) -> None:
"""
Takes a message from the client and attempts to parse it.
If a parsing error occurs, it is returned to the client. If the :exc:`HelpRequested` exception was raised by the
:class:`ControlParser`, nothing else happens. Otherwise, the appropriate `_exec...` method is called with the
entire dictionary of keyword-arguments returned by the :class:`ControlParser` passed into it.
Args:
msg: The non-empty string read from the client stream.
"""
try:
kwargs = vars(self._parser.parse_args(msg.split(' ')))
except ArgumentError as e:
log.debug("%s got an ArgumentError", self._client_class_name)
self._response_buffer.write(str(e))
return
except (HelpRequested, ParserError):
log.debug("%s received usage help", self._client_class_name)
return
command = kwargs.pop(CMD)
if isfunction(command):
await self._exec_method_and_respond(command, **kwargs)
elif isinstance(command, property):
await self._exec_property_and_respond(command, **kwargs)
else:
self._response_buffer.write(str(CommandError(f"Unknown command object: {command}")))
async def listen(self) -> None:
"""
Enters the main control loop listening to client input.
This method only returns if either the server or the client disconnect.
Messages from the client are read, parsed, and turned into pool commands (if possible).
This method should be called, when the client connection was established and the handshake was successful.
It will obviously block indefinitely.
"""
while self._control_server.is_serving():
msg = (await self._reader.readline()).decode().strip()
if not msg:
log.debug("%s disconnected", self._client_class_name)
break
await self._parse_command(msg)
response = self._response_buffer.getvalue() + "\n"
self._response_buffer.seek(0)
self._response_buffer.truncate()
self._writer.write(response.encode())
await self._writer.drain()

View File

@ -1,24 +1,3 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Custom exception classes used in various modules.
"""
class PoolException(Exception):
pass
@ -27,10 +6,6 @@ class PoolIsClosed(PoolException):
pass
class PoolIsLocked(PoolException):
pass
class TaskEnded(PoolException):
pass
@ -39,7 +14,7 @@ class AlreadyCancelled(TaskEnded):
pass
class AlreadyEnded(TaskEnded):
class AlreadyFinished(TaskEnded):
pass
@ -47,25 +22,5 @@ class InvalidTaskID(PoolException):
pass
class InvalidGroupName(PoolException):
pass
class NotCoroutine(PoolException):
pass
class ServerException(Exception):
pass
class HelpRequested(ServerException):
pass
class ParserError(ServerException):
pass
class CommandError(ServerException):
class PoolStillOpen(PoolException):
pass

View File

@ -1,41 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Constants used by more than one module in the package.
This module should **not** be considered part of the public API.
"""
import sys
PACKAGE_NAME = 'asyncio_taskpool'
PYTHON_BEFORE_39 = sys.version_info[:2] < (3, 9)
DEFAULT_TASK_GROUP = 'default'
SESSION_MSG_BYTES = 1024 * 100
CMD = 'command'
CMD_OK = b"ok"
class CLIENT_INFO:
__slots__ = ()
TERMINAL_WIDTH = 'terminal_width'

View File

@ -1,77 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Definition of :class:`TaskGroupRegister`.
It should not be considered part of the public API.
"""
from asyncio.locks import Lock
from collections.abc import MutableSet
from typing import Iterator, Set
class TaskGroupRegister(MutableSet):
"""
Combines the interface of a regular `set` with that of the `asyncio.Lock`.
Serves simultaneously as a container of IDs of tasks that belong to the same group, and as a mechanism for
preventing race conditions within a task group. The lock should be acquired before cancelling the entire group of
tasks, as well as before starting a task within the group.
"""
def __init__(self, *task_ids: int) -> None:
self._ids: Set[int] = set(task_ids)
self._lock = Lock()
def __contains__(self, task_id: int) -> bool:
"""Abstract method for the `MutableSet` base class."""
return task_id in self._ids
def __iter__(self) -> Iterator[int]:
"""Abstract method for the `MutableSet` base class."""
return iter(self._ids)
def __len__(self) -> int:
"""Abstract method for the `MutableSet` base class."""
return len(self._ids)
def add(self, task_id: int) -> None:
"""Abstract method for the `MutableSet` base class."""
self._ids.add(task_id)
def discard(self, task_id: int) -> None:
"""Abstract method for the `MutableSet` base class."""
self._ids.discard(task_id)
async def acquire(self) -> bool:
"""Wrapper around the lock's `acquire()` method."""
return await self._lock.acquire()
def release(self) -> None:
"""Wrapper around the lock's `release()` method."""
self._lock.release()
async def __aenter__(self) -> None:
"""Provides the asynchronous context manager syntax `async with ... :` when using the lock."""
await self._lock.acquire()
return None
async def __aexit__(self, exc_type, exc, tb) -> None:
"""Provides the asynchronous context manager syntax `async with ... :` when using the lock."""
self._lock.release()

View File

@ -1,157 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Miscellaneous helper functions. None of these should be considered part of the public API.
"""
import builtins
from asyncio.coroutines import iscoroutinefunction
from importlib import import_module
from inspect import getdoc
from typing import Any, Callable, Optional, Type, Union
from .constants import PYTHON_BEFORE_39
from .types import T, AnyCallableT, ArgsT, KwArgsT
async def execute_optional(function: AnyCallableT, args: ArgsT = (), kwargs: KwArgsT = None) -> Optional[T]:
"""
Runs `function` with `args` and `kwargs` and returns its output.
Args:
function:
Any callable that accepts the provided positional and keyword-arguments.
If it is a coroutine function, it will be awaited.
If it is not a callable, nothing is returned.
*args (optional):
Positional arguments to pass to `function`.
**kwargs (optional):
Keyword-arguments to pass to `function`.
Returns:
Whatever `function` returns (possibly after being awaited) or `None` if `function` is not callable.
"""
if not callable(function):
return
if kwargs is None:
kwargs = {}
if iscoroutinefunction(function):
return await function(*args, **kwargs)
return function(*args, **kwargs)
def star_function(function: AnyCallableT, arg: Any, arg_stars: int = 0) -> T:
"""
Calls `function` passing `arg` to it, optionally unpacking it first.
Args:
function:
Any callable that accepts the provided argument(s).
arg:
The single positional argument that `function` expects; in this case `arg_stars` should be 0.
Or the iterable of positional arguments that `function` expects; in this case `arg_stars` should be 1.
Or the mapping of keyword-arguments that `function` expects; in this case `arg_stars` should be 2.
arg_stars (optional):
Determines if and how to unpack `arg`.
0 means no unpacking, i.e. `arg` is passed into `function` directly as `function(arg)`.
1 means unpacking to an arbitrary number of positional arguments, i.e. as `function(*arg)`.
2 means unpacking to an arbitrary number of keyword-arguments, i.e. as `function(**arg)`.
Returns:
Whatever `function` returns.
Raises:
`ValueError`: `arg_stars` is something other than 0, 1, or 2.
"""
if arg_stars == 0:
return function(arg)
if arg_stars == 1:
return function(*arg)
if arg_stars == 2:
return function(**arg)
raise ValueError(f"Invalid argument arg_stars={arg_stars}; must be 0, 1, or 2.")
def get_first_doc_line(obj: object) -> str:
"""Takes an object and returns the first (non-empty) line of its docstring."""
return getdoc(obj).strip().split("\n", 1)[0].strip()
async def return_or_exception(_function_to_execute: AnyCallableT, *args, **kwargs) -> Union[T, Exception]:
"""
Returns the output of a function or the exception thrown during its execution.
Args:
_function_to_execute:
Any callable that accepts the provided positional and keyword-arguments.
*args (optional):
Positional arguments to pass to `_function_to_execute`.
**kwargs (optional):
Keyword-arguments to pass to `_function_to_execute`.
Returns:
Whatever `_function_to_execute` returns or throws. (An exception is not raised, but returned!)
"""
try:
if iscoroutinefunction(_function_to_execute):
return await _function_to_execute(*args, **kwargs)
else:
return _function_to_execute(*args, **kwargs)
except Exception as e:
return e
def resolve_dotted_path(dotted_path: str) -> object:
"""
Resolves a dotted path to a global object and returns that object.
Algorithm shamelessly stolen from the `logging.config` module from the standard library.
"""
names = dotted_path.split('.')
module_name = names.pop(0)
found = import_module(module_name)
for name in names:
try:
found = getattr(found, name)
except AttributeError:
module_name += f'.{name}'
import_module(module_name)
found = getattr(found, name)
return found
class ClassMethodWorkaround:
"""Dirty workaround to make the `@classmethod` decorator work with properties."""
def __init__(self, method_or_property: Union[Callable, property]) -> None:
if isinstance(method_or_property, property):
self._getter = method_or_property.fget
else:
self._getter = method_or_property
def __get__(self, obj: Union[T, None], cls: Union[Type[T], None]) -> Any:
if obj is None:
return self._getter(cls)
return self._getter(obj)
# Starting with Python 3.9, this is thankfully no longer necessary.
if PYTHON_BEFORE_39:
classmethod = ClassMethodWorkaround
else:
classmethod = builtins.classmethod

View File

@ -1,43 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Custom type definitions used in various modules.
This module should **not** be considered part of the public API.
"""
from asyncio.streams import StreamReader, StreamWriter
from pathlib import Path
from typing import Any, Awaitable, Callable, Coroutine, Iterable, Mapping, Tuple, TypeVar, Union
T = TypeVar('T')
ArgsT = Iterable[Any]
KwArgsT = Mapping[str, Any]
AnyCallableT = Callable[..., Union[T, Awaitable[T]]]
CoroutineFunc = Callable[..., Coroutine]
EndCB = Callable
CancelCB = Callable
ConnectedCallbackT = Callable[[StreamReader, StreamWriter], Awaitable[None]]
ClientConnT = Union[Tuple[StreamReader, StreamWriter], Tuple[None, None]]
PathT = Union[Path, str]

File diff suppressed because it is too large Load Diff

View File

@ -1,66 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Definition of an :code:`asyncio.Queue` subclass with some small additions.
"""
from asyncio.queues import Queue as _Queue
from typing import Any
__all__ = ['Queue']
class Queue(_Queue):
"""
Adds a little syntactic sugar to the :code:`asyncio.Queue`.
Allows being used as an async context manager awaiting `get` upon entering the context and calling
:meth:`item_processed` upon exiting it.
"""
def item_processed(self) -> None:
"""
Does exactly the same as :meth:`asyncio.Queue.task_done`.
This method exists because `task_done` is an atrocious name for the method. It communicates the wrong thing,
invites confusion, and immensely reduces readability (in the context of this library). And readability counts.
"""
self.task_done()
async def __aenter__(self) -> Any:
"""
Implements an asynchronous context manager for the queue.
Upon entering :meth:`get` is awaited and subsequently whatever came out of the queue is returned.
It allows writing code this way:
>>> queue = Queue()
>>> ...
>>> async with queue as item:
>>> ...
"""
return await self.get()
async def __aexit__(self, exc_type, exc_val, exc_tb) -> None:
"""
Implements an asynchronous context manager for the queue.
Upon exiting :meth:`item_processed` is called. This is why this context manager may not always be what you want,
but in some situations it makes the code much cleaner.
"""
self.item_processed()

View File

@ -0,0 +1,130 @@
import logging
from abc import ABC, abstractmethod
from asyncio import AbstractServer
from asyncio.exceptions import CancelledError
from asyncio.streams import StreamReader, StreamWriter, start_unix_server
from asyncio.tasks import Task, create_task
from pathlib import Path
from typing import Tuple, Union, Optional
from . import constants
from .pool import SimpleTaskPool
from .client import ControlClient, UnixControlClient
log = logging.getLogger(__name__)
def tasks_str(num: int) -> str:
return "tasks" if num != 1 else "task"
def get_cmd_arg(msg: str) -> Union[Tuple[str, Optional[int]], Tuple[None, None]]:
cmd = msg.strip().split(' ', 1)
if len(cmd) > 1:
try:
return cmd[0], int(cmd[1])
except ValueError:
return None, None
return cmd[0], None
class ControlServer(ABC): # TODO: Implement interface for normal TaskPool instances, not just SimpleTaskPool
client_class = ControlClient
@abstractmethod
async def get_server_instance(self, client_connected_cb, **kwargs) -> AbstractServer:
raise NotImplementedError
@abstractmethod
def final_callback(self) -> None:
raise NotImplementedError
def __init__(self, pool: SimpleTaskPool, **server_kwargs) -> None:
self._pool: SimpleTaskPool = pool
self._server_kwargs = server_kwargs
self._server: Optional[AbstractServer] = None
async def _start_tasks(self, writer: StreamWriter, num: int = None) -> None:
if num is None:
num = 1
log.debug("%s requests starting %s %s", self.client_class.__name__, num, tasks_str(num))
writer.write(str(await self._pool.start(num)).encode())
def _stop_tasks(self, writer: StreamWriter, num: int = None) -> None:
if num is None:
num = 1
log.debug("%s requests stopping %s %s", self.client_class.__name__, num, tasks_str(num))
# the requested number may be greater than the total number of running tasks
writer.write(str(self._pool.stop(num)).encode())
def _stop_all_tasks(self, writer: StreamWriter) -> None:
log.debug("%s requests stopping all tasks", self.client_class.__name__)
writer.write(str(self._pool.stop_all()).encode())
def _pool_size(self, writer: StreamWriter) -> None:
log.debug("%s requests pool size", self.client_class.__name__)
writer.write(str(self._pool.size).encode())
def _pool_func(self, writer: StreamWriter) -> None:
log.debug("%s requests pool function", self.client_class.__name__)
writer.write(self._pool.func_name.encode())
async def _listen(self, reader: StreamReader, writer: StreamWriter) -> None:
while self._server.is_serving():
msg = (await reader.read(constants.MSG_BYTES)).decode().strip()
if not msg:
log.debug("%s disconnected", self.client_class.__name__)
break
cmd, arg = get_cmd_arg(msg)
if cmd == constants.CMD_START:
await self._start_tasks(writer, arg)
elif cmd == constants.CMD_STOP:
self._stop_tasks(writer, arg)
elif cmd == constants.CMD_STOP_ALL:
self._stop_all_tasks(writer)
elif cmd == constants.CMD_SIZE:
self._pool_size(writer)
elif cmd == constants.CMD_FUNC:
self._pool_func(writer)
else:
log.debug("%s sent invalid command: %s", self.client_class.__name__, msg)
writer.write(b"Invalid command!")
await writer.drain()
async def _client_connected_cb(self, reader: StreamReader, writer: StreamWriter) -> None:
log.debug("%s connected", self.client_class.__name__)
writer.write(str(self._pool).encode())
await writer.drain()
await self._listen(reader, writer)
async def _serve_forever(self) -> None:
try:
async with self._server:
await self._server.serve_forever()
except CancelledError:
log.debug("%s stopped", self.__class__.__name__)
finally:
self.final_callback()
async def serve_forever(self) -> Task:
log.debug("Starting %s...", self.__class__.__name__)
self._server = await self.get_server_instance(self._client_connected_cb, **self._server_kwargs)
return create_task(self._serve_forever())
class UnixControlServer(ControlServer):
client_class = UnixControlClient
def __init__(self, pool: SimpleTaskPool, **server_kwargs) -> None:
self._socket_path = Path(server_kwargs.pop('path'))
super().__init__(pool, **server_kwargs)
async def get_server_instance(self, client_connected_cb, **kwargs) -> AbstractServer:
srv = await start_unix_server(client_connected_cb, self._socket_path, **kwargs)
log.debug("Opened socket '%s'", str(self._socket_path))
return srv
def final_callback(self) -> None:
self._socket_path.unlink()
log.debug("Removed socket '%s'", str(self._socket_path))

View File

@ -0,0 +1,11 @@
from asyncio.streams import StreamReader, StreamWriter
from typing import Any, Awaitable, Callable, Iterable, Mapping, Tuple, Union
ArgsT = Iterable[Any]
KwArgsT = Mapping[str, Any]
CoroutineFunc = Callable[[...], Awaitable[Any]]
EndCallbackT = Callable
CancelCallbackT = Callable
ClientConnT = Union[Tuple[StreamReader, StreamWriter], Tuple[None, None]]

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@ -1,30 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Main entry point for all unit tests.
"""
import sys
import unittest
if __name__ == '__main__':
test_suite = unittest.defaultTestLoader.discover('.')
test_runner = unittest.TextTestRunner(resultclass=unittest.TextTestResult)
result = test_runner.run(test_suite)
sys.exit(not result.wasSuccessful())

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@ -1,45 +0,0 @@
from pathlib import Path
from unittest import IsolatedAsyncioTestCase
from unittest.mock import AsyncMock, MagicMock, patch
from asyncio_taskpool.control.client import TCPControlClient, UnixControlClient
from asyncio_taskpool.control import __main__ as module
class CLITestCase(IsolatedAsyncioTestCase):
def test_parse_cli(self):
socket_path = '/some/path/to.sock'
args = [module.UNIX, socket_path]
expected_kwargs = {
module.CLIENT_CLASS: UnixControlClient,
module.SOCKET_PATH: Path(socket_path)
}
parsed_kwargs = module.parse_cli(args)
self.assertDictEqual(expected_kwargs, parsed_kwargs)
host, port = '1.2.3.4', '1234'
args = [module.TCP, host, port]
expected_kwargs = {
module.CLIENT_CLASS: TCPControlClient,
module.HOST: host,
module.PORT: int(port)
}
parsed_kwargs = module.parse_cli(args)
self.assertDictEqual(expected_kwargs, parsed_kwargs)
with patch('sys.stderr'):
with self.assertRaises(SystemExit):
module.parse_cli(['invalid', 'foo', 'bar'])
@patch.object(module, 'parse_cli')
async def test_main(self, mock_parse_cli: MagicMock):
mock_client_start = AsyncMock()
mock_client = MagicMock(start=mock_client_start)
mock_client_cls = MagicMock(return_value=mock_client)
mock_client_kwargs = {'foo': 123, 'bar': 456, 'baz': 789}
mock_parse_cli.return_value = {module.CLIENT_CLASS: mock_client_cls, **mock_client_kwargs}
self.assertIsNone(await module.main())
mock_parse_cli.assert_called_once_with()
mock_client_cls.assert_called_once_with(**mock_client_kwargs)
mock_client_start.assert_awaited_once_with()

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@ -1,249 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Unittests for the `asyncio_taskpool.client` module.
"""
import json
import os
import shutil
import sys
from pathlib import Path
from unittest import IsolatedAsyncioTestCase, skipIf
from unittest.mock import AsyncMock, MagicMock, call, patch
from asyncio_taskpool.control import client
from asyncio_taskpool.internals.constants import CLIENT_INFO, SESSION_MSG_BYTES
FOO, BAR = 'foo', 'bar'
class ControlClientTestCase(IsolatedAsyncioTestCase):
def setUp(self) -> None:
self.abstract_patcher = patch('asyncio_taskpool.control.client.ControlClient.__abstractmethods__', set())
self.print_patcher = patch.object(client, 'print')
self.mock_abstract_methods = self.abstract_patcher.start()
self.mock_print = self.print_patcher.start()
self.kwargs = {FOO: 123, BAR: 456}
self.client = client.ControlClient(**self.kwargs)
self.mock_read = AsyncMock(return_value=FOO.encode())
self.mock_write, self.mock_drain = MagicMock(), AsyncMock()
self.mock_reader = MagicMock(read=self.mock_read)
self.mock_writer = MagicMock(write=self.mock_write, drain=self.mock_drain)
def tearDown(self) -> None:
self.abstract_patcher.stop()
self.print_patcher.stop()
def test_client_info(self):
self.assertEqual({CLIENT_INFO.TERMINAL_WIDTH: shutil.get_terminal_size().columns},
client.ControlClient._client_info())
async def test_abstract(self):
with self.assertRaises(NotImplementedError):
await self.client._open_connection(**self.kwargs)
def test_init(self):
self.assertEqual(self.kwargs, self.client._conn_kwargs)
self.assertFalse(self.client._connected)
@patch.object(client.ControlClient, '_client_info')
async def test__server_handshake(self, mock__client_info: MagicMock):
mock__client_info.return_value = mock_info = {FOO: 1, BAR: 9999}
self.assertIsNone(await self.client._server_handshake(self.mock_reader, self.mock_writer))
self.assertTrue(self.client._connected)
mock__client_info.assert_called_once_with()
self.mock_write.assert_has_calls([call(json.dumps(mock_info).encode()), call(b'\n')])
self.mock_drain.assert_awaited_once_with()
self.mock_read.assert_awaited_once_with(SESSION_MSG_BYTES)
self.mock_print.assert_has_calls([
call("Connected to", self.mock_read.return_value.decode()),
call("Type '-h' to get help and usage instructions for all available commands.\n")
])
@patch.object(client, 'input')
def test__get_command(self, mock_input: MagicMock):
self.client._connected = True
mock_input.return_value = ' ' + FOO.upper() + ' '
mock_close = MagicMock()
mock_writer = MagicMock(close=mock_close)
output = self.client._get_command(mock_writer)
self.assertEqual(FOO, output)
mock_input.assert_called_once()
mock_close.assert_not_called()
self.assertTrue(self.client._connected)
mock_input.reset_mock()
mock_input.side_effect = KeyboardInterrupt
self.assertIsNone(self.client._get_command(mock_writer))
mock_input.assert_called_once()
mock_close.assert_not_called()
self.assertTrue(self.client._connected)
mock_input.reset_mock()
mock_input.side_effect = EOFError
self.assertIsNone(self.client._get_command(mock_writer))
mock_input.assert_called_once()
mock_close.assert_called_once()
self.assertFalse(self.client._connected)
@patch.object(client.ControlClient, '_get_command')
async def test__interact(self, mock__get_command: MagicMock):
self.client._connected = True
mock__get_command.return_value = None
self.assertIsNone(await self.client._interact(self.mock_reader, self.mock_writer))
self.mock_write.assert_not_called()
self.mock_drain.assert_not_awaited()
self.mock_read.assert_not_awaited()
self.mock_print.assert_not_called()
self.assertTrue(self.client._connected)
mock__get_command.return_value = cmd = FOO + BAR + ' 123'
self.mock_drain.side_effect = err = ConnectionError()
self.assertIsNone(await self.client._interact(self.mock_reader, self.mock_writer))
self.mock_write.assert_has_calls([call(cmd.encode()), call(b'\n')])
self.mock_drain.assert_awaited_once_with()
self.mock_read.assert_not_awaited()
self.mock_print.assert_called_once_with(err, file=sys.stderr)
self.assertFalse(self.client._connected)
self.client._connected = True
self.mock_write.reset_mock()
self.mock_drain.reset_mock(side_effect=True)
self.mock_print.reset_mock()
self.assertIsNone(await self.client._interact(self.mock_reader, self.mock_writer))
self.mock_write.assert_has_calls([call(cmd.encode()), call(b'\n')])
self.mock_drain.assert_awaited_once_with()
self.mock_read.assert_awaited_once_with(SESSION_MSG_BYTES)
self.mock_print.assert_called_once_with(FOO)
self.assertTrue(self.client._connected)
@patch.object(client.ControlClient, '_interact')
@patch.object(client.ControlClient, '_server_handshake')
@patch.object(client.ControlClient, '_open_connection')
async def test_start(self, mock__open_connection: AsyncMock, mock__server_handshake: AsyncMock,
mock__interact: AsyncMock):
mock__open_connection.return_value = None, None
self.assertIsNone(await self.client.start())
mock__open_connection.assert_awaited_once_with(**self.kwargs)
mock__server_handshake.assert_not_awaited()
mock__interact.assert_not_awaited()
self.mock_print.assert_called_once_with("Failed to connect.", file=sys.stderr)
mock__open_connection.reset_mock()
self.mock_print.reset_mock()
mock__open_connection.return_value = self.mock_reader, self.mock_writer
self.assertIsNone(await self.client.start())
mock__open_connection.assert_awaited_once_with(**self.kwargs)
mock__server_handshake.assert_awaited_once_with(self.mock_reader, self.mock_writer)
mock__interact.assert_not_awaited()
self.mock_print.assert_called_once_with("Disconnected from control server.")
mock__open_connection.reset_mock()
mock__server_handshake.reset_mock()
self.mock_print.reset_mock()
self.client._connected = True
def disconnect(*_args, **_kwargs) -> None: self.client._connected = False
mock__interact.side_effect = disconnect
self.assertIsNone(await self.client.start())
mock__open_connection.assert_awaited_once_with(**self.kwargs)
mock__server_handshake.assert_awaited_once_with(self.mock_reader, self.mock_writer)
mock__interact.assert_awaited_once_with(self.mock_reader, self.mock_writer)
self.mock_print.assert_called_once_with("Disconnected from control server.")
class TCPControlClientTestCase(IsolatedAsyncioTestCase):
def setUp(self) -> None:
self.base_init_patcher = patch.object(client.ControlClient, '__init__')
self.mock_base_init = self.base_init_patcher.start()
self.host, self.port = 'localhost', 12345
self.kwargs = {FOO: 123, BAR: 456}
self.client = client.TCPControlClient(host=self.host, port=self.port, **self.kwargs)
def tearDown(self) -> None:
self.base_init_patcher.stop()
def test_init(self):
self.assertEqual(self.host, self.client._host)
self.assertEqual(self.port, self.client._port)
self.mock_base_init.assert_called_once_with(**self.kwargs)
@patch.object(client, 'print')
@patch.object(client, 'open_connection')
async def test__open_connection(self, mock_open_connection: AsyncMock, mock_print: MagicMock):
mock_open_connection.return_value = expected_output = 'something'
kwargs = {'a': 1, 'b': 2}
output = await self.client._open_connection(**kwargs)
self.assertEqual(expected_output, output)
mock_open_connection.assert_awaited_once_with(self.host, self.port, **kwargs)
mock_print.assert_not_called()
mock_open_connection.reset_mock()
mock_open_connection.side_effect = e = ConnectionError()
output1, output2 = await self.client._open_connection(**kwargs)
self.assertIsNone(output1)
self.assertIsNone(output2)
mock_open_connection.assert_awaited_once_with(self.host, self.port, **kwargs)
mock_print.assert_called_once_with(str(e), file=sys.stderr)
@skipIf(os.name == 'nt', "No Unix sockets on Windows :(")
class UnixControlClientTestCase(IsolatedAsyncioTestCase):
def setUp(self) -> None:
self.base_init_patcher = patch.object(client.ControlClient, '__init__')
self.mock_base_init = self.base_init_patcher.start()
self.path = '/tmp/asyncio_taskpool'
self.kwargs = {FOO: 123, BAR: 456}
self.client = client.UnixControlClient(socket_path=self.path, **self.kwargs)
def tearDown(self) -> None:
self.base_init_patcher.stop()
def test_init(self):
self.assertEqual(Path(self.path), self.client._socket_path)
self.mock_base_init.assert_called_once_with(**self.kwargs)
@patch.object(client, 'print')
async def test__open_connection(self, mock_print: MagicMock):
expected_output = 'something'
self.client._open_unix_connection = mock_open_unix_connection = AsyncMock(return_value=expected_output)
kwargs = {'a': 1, 'b': 2}
output = await self.client._open_connection(**kwargs)
self.assertEqual(expected_output, output)
mock_open_unix_connection.assert_awaited_once_with(Path(self.path), **kwargs)
mock_print.assert_not_called()
mock_open_unix_connection.reset_mock()
mock_open_unix_connection.side_effect = FileNotFoundError
output1, output2 = await self.client._open_connection(**kwargs)
self.assertIsNone(output1)
self.assertIsNone(output2)
mock_open_unix_connection.assert_awaited_once_with(Path(self.path), **kwargs)
mock_print.assert_called_once_with("No socket at", Path(self.path), file=sys.stderr)

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@ -1,311 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Unittests for the `asyncio_taskpool.control.parser` module.
"""
from argparse import ArgumentParser, HelpFormatter, ArgumentDefaultsHelpFormatter, RawTextHelpFormatter, SUPPRESS
from ast import literal_eval
from inspect import signature
from unittest import TestCase
from unittest.mock import MagicMock, call, patch
from typing import Iterable
from asyncio_taskpool.control import parser
from asyncio_taskpool.exceptions import HelpRequested, ParserError
from asyncio_taskpool.internals.helpers import resolve_dotted_path
from asyncio_taskpool.internals.types import ArgsT, CancelCB, CoroutineFunc, EndCB, KwArgsT
FOO, BAR = 'foo', 'bar'
class ControlParserTestCase(TestCase):
def setUp(self) -> None:
self.help_formatter_factory_patcher = patch.object(parser.ControlParser, 'help_formatter_factory')
self.mock_help_formatter_factory = self.help_formatter_factory_patcher.start()
self.mock_help_formatter_factory.return_value = RawTextHelpFormatter
self.stream, self.terminal_width = MagicMock(), 420
self.kwargs = {
'stream': self.stream,
'terminal_width': self.terminal_width,
'formatter_class': FOO
}
self.parser = parser.ControlParser(**self.kwargs)
def tearDown(self) -> None:
self.help_formatter_factory_patcher.stop()
def test_help_formatter_factory(self):
self.help_formatter_factory_patcher.stop()
class MockBaseClass(HelpFormatter):
def __init__(self, *args, **kwargs):
super().__init__(*args, **kwargs)
terminal_width = 123456789
cls = parser.ControlParser.help_formatter_factory(terminal_width, MockBaseClass)
self.assertTrue(issubclass(cls, MockBaseClass))
instance = cls('prog')
self.assertEqual(terminal_width, getattr(instance, '_width'))
cls = parser.ControlParser.help_formatter_factory(terminal_width)
self.assertTrue(issubclass(cls, ArgumentDefaultsHelpFormatter))
instance = cls('prog')
self.assertEqual(terminal_width, getattr(instance, '_width'))
def test_init(self):
self.assertIsInstance(self.parser, ArgumentParser)
self.assertEqual(self.stream, self.parser._stream)
self.assertEqual(self.terminal_width, self.parser._terminal_width)
self.mock_help_formatter_factory.assert_called_once_with(self.terminal_width, FOO)
self.assertEqual(RawTextHelpFormatter, getattr(self.parser, 'formatter_class'))
self.assertSetEqual(set(), self.parser._flags)
self.assertIsNone(self.parser._commands)
@patch.object(parser, 'get_first_doc_line')
def test_add_function_command(self, mock_get_first_doc_line: MagicMock):
def foo_bar(): pass
mock_subparser = MagicMock()
mock_add_parser = MagicMock(return_value=mock_subparser)
self.parser._commands = MagicMock(add_parser=mock_add_parser)
mock_get_first_doc_line.return_value = mock_help = 'help 123'
kwargs = {FOO: 1, BAR: 2, parser.DESCRIPTION: FOO + BAR}
expected_name = 'foo-bar'
expected_kwargs = {parser.NAME: expected_name, parser.PROG: expected_name, parser.HELP: mock_help, **kwargs}
to_omit = ['abc', 'xyz']
output = self.parser.add_function_command(foo_bar, omit_params=to_omit, **kwargs)
self.assertEqual(mock_subparser, output)
mock_add_parser.assert_called_once_with(**expected_kwargs)
mock_subparser.add_function_args.assert_called_once_with(foo_bar, to_omit)
@patch.object(parser, 'get_first_doc_line')
def test_add_property_command(self, mock_get_first_doc_line: MagicMock):
def get_prop(_self): pass
def set_prop(_self, _value): pass
prop = property(get_prop)
mock_subparser = MagicMock()
mock_add_parser = MagicMock(return_value=mock_subparser)
self.parser._commands = MagicMock(add_parser=mock_add_parser)
mock_get_first_doc_line.return_value = mock_help = 'help 123'
kwargs = {FOO: 1, BAR: 2, parser.DESCRIPTION: FOO + BAR}
expected_name = 'get-prop'
expected_kwargs = {parser.NAME: expected_name, parser.PROG: expected_name, parser.HELP: mock_help, **kwargs}
output = self.parser.add_property_command(prop, **kwargs)
self.assertEqual(mock_subparser, output)
mock_get_first_doc_line.assert_called_once_with(get_prop)
mock_add_parser.assert_called_once_with(**expected_kwargs)
mock_subparser.add_function_arg.assert_not_called()
mock_get_first_doc_line.reset_mock()
mock_add_parser.reset_mock()
prop = property(get_prop, set_prop)
expected_help = f"Get/set the `.{expected_name}` property"
expected_kwargs = {parser.NAME: expected_name, parser.PROG: expected_name, parser.HELP: expected_help, **kwargs}
output = self.parser.add_property_command(prop, **kwargs)
self.assertEqual(mock_subparser, output)
mock_get_first_doc_line.assert_has_calls([call(get_prop), call(set_prop)])
mock_add_parser.assert_called_once_with(**expected_kwargs)
mock_subparser.add_function_arg.assert_called_once_with(
tuple(signature(set_prop).parameters.values())[1],
nargs='?',
default=SUPPRESS,
help=f"If provided: {mock_help} If omitted: {mock_help}"
)
@patch.object(parser.ControlParser, 'add_property_command')
@patch.object(parser.ControlParser, 'add_function_command')
def test_add_class_commands(self, mock_add_function_command: MagicMock, mock_add_property_command: MagicMock):
class FooBar:
some_attribute = None
def _protected(self, _): pass
def __private(self, _): pass
def to_omit(self, _): pass
def method(self, _): pass
@property
def prop(self): return None
mock_set_defaults = MagicMock()
mock_subparser = MagicMock(set_defaults=mock_set_defaults)
mock_add_function_command.return_value = mock_add_property_command.return_value = mock_subparser
x = 'x'
common_kwargs = {'stream': self.parser._stream, parser.CLIENT_INFO.TERMINAL_WIDTH: self.parser._terminal_width}
expected_output = {'method': mock_subparser, 'prop': mock_subparser}
output = self.parser.add_class_commands(FooBar, public_only=True, omit_members=['to_omit'], member_arg_name=x)
self.assertDictEqual(expected_output, output)
mock_add_function_command.assert_called_once_with(FooBar.method, **common_kwargs)
mock_add_property_command.assert_called_once_with(FooBar.prop, FooBar.__name__, **common_kwargs)
mock_set_defaults.assert_has_calls([call(**{x: FooBar.method}), call(**{x: FooBar.prop})])
@patch.object(parser.ArgumentParser, 'add_subparsers')
def test_add_subparsers(self, mock_base_add_subparsers: MagicMock):
args, kwargs = [1, 2, 42], {FOO: 123, BAR: 456}
mock_base_add_subparsers.return_value = mock_action = MagicMock()
output = self.parser.add_subparsers(*args, **kwargs)
self.assertEqual(mock_action, output)
mock_base_add_subparsers.assert_called_once_with(*args, **kwargs)
def test__print_message(self):
self.stream.write = MagicMock()
self.assertIsNone(self.parser._print_message(''))
self.stream.write.assert_not_called()
msg = 'foo bar baz'
self.assertIsNone(self.parser._print_message(msg))
self.stream.write.assert_called_once_with(msg)
@patch.object(parser.ControlParser, '_print_message')
def test_exit(self, mock__print_message: MagicMock):
self.assertIsNone(self.parser.exit(123, ''))
mock__print_message.assert_not_called()
msg = 'foo bar baz'
self.assertIsNone(self.parser.exit(123, msg))
mock__print_message.assert_called_once_with(msg)
@patch.object(parser.ArgumentParser, 'error')
def test_error(self, mock_supercls_error: MagicMock):
with self.assertRaises(ParserError):
self.parser.error(FOO + BAR)
mock_supercls_error.assert_called_once_with(message=FOO + BAR)
@patch.object(parser.ArgumentParser, 'print_help')
def test_print_help(self, mock_print_help: MagicMock):
arg = MagicMock()
with self.assertRaises(HelpRequested):
self.parser.print_help(arg)
mock_print_help.assert_called_once_with(arg)
@patch.object(parser, '_get_type_from_annotation')
@patch.object(parser.ArgumentParser, 'add_argument')
def test_add_function_arg(self, mock_add_argument: MagicMock, mock__get_type_from_annotation: MagicMock):
mock_add_argument.return_value = expected_output = 'action'
mock__get_type_from_annotation.return_value = mock_type = 'fake'
foo_type, args_type, bar_type, baz_type, boo_type = tuple, str, int, float, complex
bar_default, baz_default, boo_default = 1, 0.1, 1j
def func(foo: foo_type, *args: args_type, bar: bar_type = bar_default, baz: baz_type = baz_default,
boo: boo_type = boo_default, flag: bool = False):
return foo, args, bar, baz, boo, flag
param_foo, param_args, param_bar, param_baz, param_boo, param_flag = signature(func).parameters.values()
kwargs = {FOO + BAR: 'xyz'}
self.assertEqual(expected_output, self.parser.add_function_arg(param_foo, **kwargs))
mock_add_argument.assert_called_once_with('foo', type=mock_type, **kwargs)
mock__get_type_from_annotation.assert_called_once_with(foo_type)
mock_add_argument.reset_mock()
mock__get_type_from_annotation.reset_mock()
self.assertEqual(expected_output, self.parser.add_function_arg(param_args, **kwargs))
mock_add_argument.assert_called_once_with('args', nargs='*', type=mock_type, **kwargs)
mock__get_type_from_annotation.assert_called_once_with(args_type)
mock_add_argument.reset_mock()
mock__get_type_from_annotation.reset_mock()
self.assertEqual(expected_output, self.parser.add_function_arg(param_bar, **kwargs))
mock_add_argument.assert_called_once_with('-b', '--bar', default=bar_default, type=mock_type, **kwargs)
mock__get_type_from_annotation.assert_called_once_with(bar_type)
mock_add_argument.reset_mock()
mock__get_type_from_annotation.reset_mock()
self.assertEqual(expected_output, self.parser.add_function_arg(param_baz, **kwargs))
mock_add_argument.assert_called_once_with('-B', '--baz', default=baz_default, type=mock_type, **kwargs)
mock__get_type_from_annotation.assert_called_once_with(baz_type)
mock_add_argument.reset_mock()
mock__get_type_from_annotation.reset_mock()
self.assertEqual(expected_output, self.parser.add_function_arg(param_boo, **kwargs))
mock_add_argument.assert_called_once_with('--boo', default=boo_default, type=mock_type, **kwargs)
mock__get_type_from_annotation.assert_called_once_with(boo_type)
mock_add_argument.reset_mock()
mock__get_type_from_annotation.reset_mock()
self.assertEqual(expected_output, self.parser.add_function_arg(param_flag, **kwargs))
mock_add_argument.assert_called_once_with('-f', '--flag', action='store_true', **kwargs)
mock__get_type_from_annotation.assert_not_called()
@patch.object(parser.ControlParser, 'add_function_arg')
def test_add_function_args(self, mock_add_function_arg: MagicMock):
def func(foo: str, *args: int, bar: float = 0.1):
return foo, args, bar
_, param_args, param_bar = signature(func).parameters.values()
self.assertIsNone(self.parser.add_function_args(func, omit=['foo']))
mock_add_function_arg.assert_has_calls([
call(param_args, help=repr(param_args.annotation)),
call(param_bar, help=repr(param_bar.annotation)),
])
class RestTestCase(TestCase):
log_lvl: int
@classmethod
def setUpClass(cls) -> None:
cls.log_lvl = parser.log.level
parser.log.setLevel(999)
@classmethod
def tearDownClass(cls) -> None:
parser.log.setLevel(cls.log_lvl)
def test__get_arg_type_wrapper(self):
type_wrap = parser._get_arg_type_wrapper(int)
self.assertEqual('int', type_wrap.__name__)
self.assertEqual(SUPPRESS, type_wrap(SUPPRESS))
self.assertEqual(13, type_wrap('13'))
name = 'abcdef'
mock_type = MagicMock(side_effect=[parser.ArgumentTypeError, TypeError, ValueError, Exception], __name__=name)
type_wrap = parser._get_arg_type_wrapper(mock_type)
self.assertEqual(name, type_wrap.__name__)
with self.assertRaises(parser.ArgumentTypeError):
type_wrap(FOO)
with self.assertRaises(TypeError):
type_wrap(FOO)
with self.assertRaises(ValueError):
type_wrap(FOO)
with self.assertRaises(parser.ArgumentTypeError):
type_wrap(FOO)
@patch.object(parser, '_get_arg_type_wrapper')
def test__get_type_from_annotation(self, mock__get_arg_type_wrapper: MagicMock):
mock__get_arg_type_wrapper.return_value = expected_output = FOO + BAR
dotted_path_ann = [CoroutineFunc, EndCB, CancelCB]
literal_eval_ann = [ArgsT, KwArgsT, Iterable[ArgsT], Iterable[KwArgsT]]
any_other_ann = MagicMock()
for a in dotted_path_ann:
self.assertEqual(expected_output, parser._get_type_from_annotation(a))
mock__get_arg_type_wrapper.assert_has_calls(len(dotted_path_ann) * [call(resolve_dotted_path)])
mock__get_arg_type_wrapper.reset_mock()
for a in literal_eval_ann:
self.assertEqual(expected_output, parser._get_type_from_annotation(a))
mock__get_arg_type_wrapper.assert_has_calls(len(literal_eval_ann) * [call(literal_eval)])
mock__get_arg_type_wrapper.reset_mock()
self.assertEqual(expected_output, parser._get_type_from_annotation(any_other_ann))
mock__get_arg_type_wrapper.assert_called_once_with(any_other_ann)

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@ -1,210 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Unittests for the `asyncio_taskpool.server` module.
"""
import asyncio
import logging
import os
from pathlib import Path
from unittest import IsolatedAsyncioTestCase, skipIf
from unittest.mock import AsyncMock, MagicMock, patch
from asyncio_taskpool.control import server
from asyncio_taskpool.control.client import ControlClient, TCPControlClient, UnixControlClient
FOO, BAR = 'foo', 'bar'
class ControlServerTestCase(IsolatedAsyncioTestCase):
log_lvl: int
@classmethod
def setUpClass(cls) -> None:
cls.log_lvl = server.log.level
server.log.setLevel(999)
@classmethod
def tearDownClass(cls) -> None:
server.log.setLevel(cls.log_lvl)
def setUp(self) -> None:
self.abstract_patcher = patch('asyncio_taskpool.control.server.ControlServer.__abstractmethods__', set())
self.mock_abstract_methods = self.abstract_patcher.start()
self.mock_pool = MagicMock()
self.kwargs = {FOO: 123, BAR: 456}
self.server = server.ControlServer(pool=self.mock_pool, **self.kwargs)
def tearDown(self) -> None:
self.abstract_patcher.stop()
def test_client_class_name(self):
self.assertEqual(ControlClient.__name__, server.ControlServer.client_class_name)
async def test_abstract(self):
with self.assertRaises(NotImplementedError):
args = [AsyncMock()]
await self.server._get_server_instance(*args)
with self.assertRaises(NotImplementedError):
self.server._final_callback()
def test_init(self):
self.assertEqual(self.mock_pool, self.server._pool)
self.assertEqual(self.kwargs, self.server._server_kwargs)
self.assertIsNone(self.server._server)
def test_pool(self):
self.assertEqual(self.mock_pool, self.server.pool)
def test_is_serving(self):
self.server._server = MagicMock(is_serving=MagicMock(return_value=FOO + BAR))
self.assertEqual(FOO + BAR, self.server.is_serving())
@patch.object(server, 'ControlSession')
async def test__client_connected_cb(self, mock_client_session_cls: MagicMock):
mock_client_handshake, mock_listen = AsyncMock(), AsyncMock()
mock_client_session_cls.return_value = MagicMock(client_handshake=mock_client_handshake, listen=mock_listen)
mock_reader, mock_writer = MagicMock(), MagicMock()
self.assertIsNone(await self.server._client_connected_cb(mock_reader, mock_writer))
mock_client_session_cls.assert_called_once_with(self.server, mock_reader, mock_writer)
mock_client_handshake.assert_awaited_once_with()
mock_listen.assert_awaited_once_with()
@patch.object(server.ControlServer, '_final_callback')
async def test__serve_forever(self, mock__final_callback: MagicMock):
mock_aenter, mock_serve_forever = AsyncMock(), AsyncMock(side_effect=asyncio.CancelledError)
self.server._server = MagicMock(__aenter__=mock_aenter, serve_forever=mock_serve_forever)
with self.assertLogs(server.log, logging.DEBUG):
self.assertIsNone(await self.server._serve_forever())
mock_aenter.assert_awaited_once_with()
mock_serve_forever.assert_awaited_once_with()
mock__final_callback.assert_called_once_with()
mock_aenter.reset_mock()
mock_serve_forever.reset_mock(side_effect=True)
mock__final_callback.reset_mock()
self.assertIsNone(await self.server._serve_forever())
mock_aenter.assert_awaited_once_with()
mock_serve_forever.assert_awaited_once_with()
mock__final_callback.assert_called_once_with()
@patch.object(server, 'create_task')
@patch.object(server.ControlServer, '_serve_forever', new_callable=MagicMock())
@patch.object(server.ControlServer, '_get_server_instance')
async def test_serve_forever(self, mock__get_server_instance: AsyncMock, mock__serve_forever: MagicMock,
mock_create_task: MagicMock):
mock__serve_forever.return_value = mock_awaitable = 'some_coroutine'
mock_create_task.return_value = expected_output = 12345
output = await self.server.serve_forever()
self.assertEqual(expected_output, output)
mock__get_server_instance.assert_awaited_once_with(self.server._client_connected_cb, **self.kwargs)
mock__serve_forever.assert_called_once_with()
mock_create_task.assert_called_once_with(mock_awaitable)
class TCPControlServerTestCase(IsolatedAsyncioTestCase):
log_lvl: int
@classmethod
def setUpClass(cls) -> None:
cls.log_lvl = server.log.level
server.log.setLevel(999)
@classmethod
def tearDownClass(cls) -> None:
server.log.setLevel(cls.log_lvl)
def setUp(self) -> None:
self.base_init_patcher = patch.object(server.ControlServer, '__init__')
self.mock_base_init = self.base_init_patcher.start()
self.mock_pool = MagicMock()
self.host, self.port = 'localhost', 12345
self.kwargs = {FOO: 123, BAR: 456}
self.server = server.TCPControlServer(pool=self.mock_pool, host=self.host, port=self.port, **self.kwargs)
def tearDown(self) -> None:
self.base_init_patcher.stop()
def test__client_class(self):
self.assertEqual(TCPControlClient, self.server._client_class)
def test_init(self):
self.assertEqual(self.host, self.server._host)
self.assertEqual(self.port, self.server._port)
self.mock_base_init.assert_called_once_with(self.mock_pool, **self.kwargs)
@patch.object(server, 'start_server')
async def test__get_server_instance(self, mock_start_server: AsyncMock):
mock_start_server.return_value = expected_output = 'totally_a_server'
mock_callback, mock_kwargs = MagicMock(), {'a': 1, 'b': 2}
args = [mock_callback]
output = await self.server._get_server_instance(*args, **mock_kwargs)
self.assertEqual(expected_output, output)
mock_start_server.assert_called_once_with(mock_callback, self.host, self.port, **mock_kwargs)
def test__final_callback(self):
self.assertIsNone(self.server._final_callback())
@skipIf(os.name == 'nt', "No Unix sockets on Windows :(")
class UnixControlServerTestCase(IsolatedAsyncioTestCase):
log_lvl: int
@classmethod
def setUpClass(cls) -> None:
cls.log_lvl = server.log.level
server.log.setLevel(999)
@classmethod
def tearDownClass(cls) -> None:
server.log.setLevel(cls.log_lvl)
def setUp(self) -> None:
self.base_init_patcher = patch.object(server.ControlServer, '__init__')
self.mock_base_init = self.base_init_patcher.start()
self.mock_pool = MagicMock()
self.path = '/tmp/asyncio_taskpool'
self.kwargs = {FOO: 123, BAR: 456}
self.server = server.UnixControlServer(pool=self.mock_pool, socket_path=self.path, **self.kwargs)
def tearDown(self) -> None:
self.base_init_patcher.stop()
def test__client_class(self):
self.assertEqual(UnixControlClient, self.server._client_class)
def test_init(self):
self.assertEqual(Path(self.path), self.server._socket_path)
self.mock_base_init.assert_called_once_with(self.mock_pool, **self.kwargs)
async def test__get_server_instance(self):
expected_output = 'totally_a_server'
self.server._start_unix_server = mock_start_unix_server = AsyncMock(return_value=expected_output)
mock_callback, mock_kwargs = MagicMock(), {'a': 1, 'b': 2}
args = [mock_callback]
output = await self.server._get_server_instance(*args, **mock_kwargs)
self.assertEqual(expected_output, output)
mock_start_unix_server.assert_called_once_with(mock_callback, Path(self.path), **mock_kwargs)
def test__final_callback(self):
self.server._socket_path = MagicMock()
self.assertIsNone(self.server._final_callback())
self.server._socket_path.unlink.assert_called_once_with()

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@ -1,217 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Unittests for the `asyncio_taskpool.session` module.
"""
import json
from argparse import ArgumentError, Namespace
from io import StringIO
from unittest import IsolatedAsyncioTestCase
from unittest.mock import AsyncMock, MagicMock, patch, call
from asyncio_taskpool.control import session
from asyncio_taskpool.internals.constants import CLIENT_INFO, CMD
from asyncio_taskpool.exceptions import HelpRequested
from asyncio_taskpool.pool import SimpleTaskPool
FOO, BAR = 'foo', 'bar'
class ControlServerTestCase(IsolatedAsyncioTestCase):
log_lvl: int
@classmethod
def setUpClass(cls) -> None:
cls.log_lvl = session.log.level
session.log.setLevel(999)
@classmethod
def tearDownClass(cls) -> None:
session.log.setLevel(cls.log_lvl)
def setUp(self) -> None:
self.mock_pool = MagicMock(spec=SimpleTaskPool(AsyncMock()))
self.mock_client_class_name = FOO + BAR
self.mock_server = MagicMock(pool=self.mock_pool,
client_class_name=self.mock_client_class_name)
self.mock_reader = MagicMock()
self.mock_writer = MagicMock()
self.session = session.ControlSession(self.mock_server, self.mock_reader, self.mock_writer)
def test_init(self):
self.assertEqual(self.mock_server, self.session._control_server)
self.assertEqual(self.mock_pool, self.session._pool)
self.assertEqual(self.mock_client_class_name, self.session._client_class_name)
self.assertEqual(self.mock_reader, self.session._reader)
self.assertEqual(self.mock_writer, self.session._writer)
self.assertIsNone(self.session._parser)
self.assertIsInstance(self.session._response_buffer, StringIO)
@patch.object(session, 'return_or_exception')
async def test__exec_method_and_respond(self, mock_return_or_exception: AsyncMock):
def method(self, arg1, arg2, *var_args, **rest): pass
test_arg1, test_arg2, test_var_args, test_rest = 123, 'xyz', [0.1, 0.2, 0.3], {'aaa': 1, 'bbb': 11}
kwargs = {'arg1': test_arg1, 'arg2': test_arg2, 'var_args': test_var_args}
mock_return_or_exception.return_value = None
self.assertIsNone(await self.session._exec_method_and_respond(method, **kwargs, **test_rest))
mock_return_or_exception.assert_awaited_once_with(
method, self.mock_pool, test_arg1, test_arg2, *test_var_args, **test_rest
)
self.assertEqual(session.CMD_OK.decode(), self.session._response_buffer.getvalue())
@patch.object(session, 'return_or_exception')
async def test__exec_property_and_respond(self, mock_return_or_exception: AsyncMock):
def prop_get(_): pass
def prop_set(_): pass
prop = property(prop_get, prop_set)
kwargs = {'value': 'something'}
mock_return_or_exception.return_value = None
self.assertIsNone(await self.session._exec_property_and_respond(prop, **kwargs))
mock_return_or_exception.assert_awaited_once_with(prop_set, self.mock_pool, **kwargs)
self.assertEqual(session.CMD_OK.decode(), self.session._response_buffer.getvalue())
mock_return_or_exception.reset_mock()
self.session._response_buffer.seek(0)
self.session._response_buffer.truncate()
mock_return_or_exception.return_value = val = 420.69
self.assertIsNone(await self.session._exec_property_and_respond(prop))
mock_return_or_exception.assert_awaited_once_with(prop_get, self.mock_pool)
self.assertEqual(str(val), self.session._response_buffer.getvalue())
@patch.object(session, 'ControlParser')
async def test_client_handshake(self, mock_parser_cls: MagicMock):
mock_add_subparsers, mock_add_class_commands = MagicMock(), MagicMock()
mock_parser = MagicMock(add_subparsers=mock_add_subparsers, add_class_commands=mock_add_class_commands)
mock_parser_cls.return_value = mock_parser
width = 5678
msg = ' ' + json.dumps({CLIENT_INFO.TERMINAL_WIDTH: width, FOO: BAR}) + ' '
mock_readline = AsyncMock(return_value=msg.encode())
self.mock_reader.readline = mock_readline
self.mock_writer.drain = AsyncMock()
expected_parser_kwargs = {
'stream': self.session._response_buffer,
CLIENT_INFO.TERMINAL_WIDTH: width,
'prog': '',
'usage': f'[-h] [{CMD}] ...'
}
expected_subparsers_kwargs = {
'title': "Commands",
'metavar': "(A command followed by '-h' or '--help' will show command-specific help.)"
}
self.assertIsNone(await self.session.client_handshake())
self.assertEqual(mock_parser, self.session._parser)
mock_readline.assert_awaited_once_with()
mock_parser_cls.assert_called_once_with(**expected_parser_kwargs)
mock_add_subparsers.assert_called_once_with(**expected_subparsers_kwargs)
mock_add_class_commands.assert_called_once_with(self.mock_pool.__class__)
self.mock_writer.write.assert_called_once_with(str(self.mock_pool).encode() + b'\n')
self.mock_writer.drain.assert_awaited_once_with()
@patch.object(session.ControlSession, '_exec_property_and_respond')
@patch.object(session.ControlSession, '_exec_method_and_respond')
async def test__parse_command(self, mock__exec_method_and_respond: AsyncMock,
mock__exec_property_and_respond: AsyncMock):
def method(_): pass
prop = property(method)
msg = 'asdf asd as a'
kwargs = {FOO: BAR, 'hello': 'python'}
mock_parse_args = MagicMock(return_value=Namespace(**{CMD: method}, **kwargs))
self.session._parser = MagicMock(parse_args=mock_parse_args)
self.assertIsNone(await self.session._parse_command(msg))
mock_parse_args.assert_called_once_with(msg.split(' '))
self.assertEqual('', self.session._response_buffer.getvalue())
mock__exec_method_and_respond.assert_awaited_once_with(method, **kwargs)
mock__exec_property_and_respond.assert_not_called()
mock__exec_method_and_respond.reset_mock()
mock_parse_args.reset_mock()
mock_parse_args.return_value = Namespace(**{CMD: prop}, **kwargs)
self.assertIsNone(await self.session._parse_command(msg))
mock_parse_args.assert_called_once_with(msg.split(' '))
self.assertEqual('', self.session._response_buffer.getvalue())
mock__exec_method_and_respond.assert_not_called()
mock__exec_property_and_respond.assert_awaited_once_with(prop, **kwargs)
mock__exec_property_and_respond.reset_mock()
mock_parse_args.reset_mock()
bad_command = 'definitely not a function or property'
mock_parse_args.return_value = Namespace(**{CMD: bad_command}, **kwargs)
with patch.object(session, 'CommandError') as cmd_err_cls:
cmd_err_cls.return_value = exc = MagicMock()
self.assertIsNone(await self.session._parse_command(msg))
cmd_err_cls.assert_called_once_with(f"Unknown command object: {bad_command}")
mock_parse_args.assert_called_once_with(msg.split(' '))
mock__exec_method_and_respond.assert_not_called()
mock__exec_property_and_respond.assert_not_called()
self.assertEqual(str(exc), self.session._response_buffer.getvalue())
mock__exec_property_and_respond.reset_mock()
mock_parse_args.reset_mock()
self.session._response_buffer.seek(0)
self.session._response_buffer.truncate()
mock_parse_args.side_effect = exc = ArgumentError(MagicMock(), "oops")
self.assertIsNone(await self.session._parse_command(msg))
mock_parse_args.assert_called_once_with(msg.split(' '))
self.assertEqual(str(exc), self.session._response_buffer.getvalue())
mock__exec_method_and_respond.assert_not_awaited()
mock__exec_property_and_respond.assert_not_awaited()
mock_parse_args.reset_mock()
self.session._response_buffer.seek(0)
self.session._response_buffer.truncate()
mock_parse_args.side_effect = HelpRequested()
self.assertIsNone(await self.session._parse_command(msg))
mock_parse_args.assert_called_once_with(msg.split(' '))
self.assertEqual('', self.session._response_buffer.getvalue())
mock__exec_method_and_respond.assert_not_awaited()
mock__exec_property_and_respond.assert_not_awaited()
@patch.object(session.ControlSession, '_parse_command')
async def test_listen(self, mock__parse_command: AsyncMock):
def make_reader_return_empty():
self.mock_reader.readline.return_value = b''
self.mock_writer.drain = AsyncMock(side_effect=make_reader_return_empty)
msg = "fascinating"
self.mock_reader.readline = AsyncMock(return_value=f' {msg} '.encode())
response = FOO + BAR + FOO
self.session._response_buffer.write(response)
self.assertIsNone(await self.session.listen())
self.mock_reader.readline.assert_has_awaits([call(), call()])
mock__parse_command.assert_awaited_once_with(msg)
self.assertEqual('', self.session._response_buffer.getvalue())
self.mock_writer.write.assert_called_once_with(response.encode() + b'\n')
self.mock_writer.drain.assert_awaited_once_with()
self.mock_reader.readline.reset_mock()
mock__parse_command.reset_mock()
self.mock_writer.write.reset_mock()
self.mock_writer.drain.reset_mock()
self.mock_server.is_serving = MagicMock(return_value=False)
self.assertIsNone(await self.session.listen())
self.mock_reader.readline.assert_not_awaited()
mock__parse_command.assert_not_awaited()
self.mock_writer.write.assert_not_called()
self.mock_writer.drain.assert_not_awaited()

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@ -1,84 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Unittests for the `asyncio_taskpool.group_register` module.
"""
from asyncio.locks import Lock
from unittest import IsolatedAsyncioTestCase
from unittest.mock import MagicMock, patch
from asyncio_taskpool.internals import group_register
FOO, BAR = 'foo', 'bar'
class TaskGroupRegisterTestCase(IsolatedAsyncioTestCase):
def setUp(self) -> None:
self.reg = group_register.TaskGroupRegister()
def test_init(self):
ids = [FOO, BAR, 1, 2]
reg = group_register.TaskGroupRegister(*ids)
self.assertSetEqual(set(ids), reg._ids)
self.assertIsInstance(reg._lock, Lock)
def test___contains__(self):
self.reg._ids = {1, 2, 3}
for i in self.reg._ids:
self.assertTrue(i in self.reg)
self.assertFalse(4 in self.reg)
@patch.object(group_register, 'iter', return_value=FOO)
def test___iter__(self, mock_iter: MagicMock):
self.assertEqual(FOO, self.reg.__iter__())
mock_iter.assert_called_once_with(self.reg._ids)
def test___len__(self):
self.reg._ids = [1, 2, 3, 4]
self.assertEqual(4, len(self.reg))
def test_add(self):
self.assertSetEqual(set(), self.reg._ids)
self.assertIsNone(self.reg.add(123))
self.assertSetEqual({123}, self.reg._ids)
def test_discard(self):
self.reg._ids = {123}
self.assertIsNone(self.reg.discard(0))
self.assertIsNone(self.reg.discard(999))
self.assertIsNone(self.reg.discard(123))
self.assertSetEqual(set(), self.reg._ids)
async def test_acquire(self):
self.assertFalse(self.reg._lock.locked())
await self.reg.acquire()
self.assertTrue(self.reg._lock.locked())
def test_release(self):
self.reg._lock._locked = True
self.assertTrue(self.reg._lock.locked())
self.reg.release()
self.assertFalse(self.reg._lock.locked())
async def test_contextmanager(self):
self.assertFalse(self.reg._lock.locked())
async with self.reg as nothing:
self.assertIsNone(nothing)
self.assertTrue(self.reg._lock.locked())
self.assertFalse(self.reg._lock.locked())

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@ -1,167 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Unittests for the `asyncio_taskpool.helpers` module.
"""
import importlib
from unittest import IsolatedAsyncioTestCase, TestCase
from unittest.mock import MagicMock, AsyncMock, NonCallableMagicMock, call, patch
from asyncio_taskpool.internals import constants
from asyncio_taskpool.internals import helpers
class HelpersTestCase(IsolatedAsyncioTestCase):
async def test_execute_optional(self):
f, args, kwargs = NonCallableMagicMock(), [1, 2], None
a = [f, args, kwargs] # to avoid IDE nagging
self.assertIsNone(await helpers.execute_optional(*a))
expected_output = 'foo'
f = MagicMock(return_value=expected_output)
output = await helpers.execute_optional(f, args, kwargs)
self.assertEqual(expected_output, output)
f.assert_called_once_with(*args)
f.reset_mock()
kwargs = {'a': 100, 'b': 200}
output = await helpers.execute_optional(f, args, kwargs)
self.assertEqual(expected_output, output)
f.assert_called_once_with(*args, **kwargs)
f = AsyncMock(return_value=expected_output)
output = await helpers.execute_optional(f, args, kwargs)
self.assertEqual(expected_output, output)
f.assert_awaited_once_with(*args, **kwargs)
def test_star_function(self):
expected_output = 'bar'
f = MagicMock(return_value=expected_output)
a = (1, 2, 3)
stars = 0
output = helpers.star_function(f, a, stars)
self.assertEqual(expected_output, output)
f.assert_called_once_with(a)
f.reset_mock()
stars = 1
output = helpers.star_function(f, a, stars)
self.assertEqual(expected_output, output)
f.assert_called_once_with(*a)
f.reset_mock()
a = {'a': 1, 'b': 2}
stars = 2
output = helpers.star_function(f, a, stars)
self.assertEqual(expected_output, output)
f.assert_called_once_with(**a)
with self.assertRaises(ValueError):
helpers.star_function(f, a, 3)
with self.assertRaises(ValueError):
helpers.star_function(f, a, -1)
with self.assertRaises(ValueError):
helpers.star_function(f, a, 123456789)
def test_get_first_doc_line(self):
expected_output = 'foo bar baz'
mock_obj = MagicMock(__doc__=f"""{expected_output}
something else
even more
""")
output = helpers.get_first_doc_line(mock_obj)
self.assertEqual(expected_output, output)
async def test_return_or_exception(self):
expected_output = '420'
mock_func = AsyncMock(return_value=expected_output)
args = (1, 3, 5)
kwargs = {'a': 1, 'b': 2, 'c': 'foo'}
output = await helpers.return_or_exception(mock_func, *args, **kwargs)
self.assertEqual(expected_output, output)
mock_func.assert_awaited_once_with(*args, **kwargs)
mock_func = MagicMock(return_value=expected_output)
output = await helpers.return_or_exception(mock_func, *args, **kwargs)
self.assertEqual(expected_output, output)
mock_func.assert_called_once_with(*args, **kwargs)
class TestException(Exception):
pass
test_exception = TestException()
mock_func = MagicMock(side_effect=test_exception)
output = await helpers.return_or_exception(mock_func, *args, **kwargs)
self.assertEqual(test_exception, output)
mock_func.assert_called_once_with(*args, **kwargs)
def test_resolve_dotted_path(self):
from logging import WARNING
from urllib.request import urlopen
self.assertEqual(WARNING, helpers.resolve_dotted_path('logging.WARNING'))
self.assertEqual(urlopen, helpers.resolve_dotted_path('urllib.request.urlopen'))
with patch.object(helpers, 'import_module', return_value=object) as mock_import_module:
with self.assertRaises(AttributeError):
helpers.resolve_dotted_path('foo.bar.baz')
mock_import_module.assert_has_calls([call('foo'), call('foo.bar')])
class ClassMethodWorkaroundTestCase(TestCase):
def test_init(self):
def func(): return 'foo'
def getter(): return 'bar'
prop = property(getter)
instance = helpers.ClassMethodWorkaround(func)
self.assertIs(func, instance._getter)
instance = helpers.ClassMethodWorkaround(prop)
self.assertIs(getter, instance._getter)
@patch.object(helpers.ClassMethodWorkaround, '__init__', return_value=None)
def test_get(self, _mock_init: MagicMock):
def func(x: MagicMock): return x.__name__
instance = helpers.ClassMethodWorkaround(MagicMock())
instance._getter = func
obj, cls = None, MagicMock
expected_output = 'MagicMock'
output = instance.__get__(obj, cls)
self.assertEqual(expected_output, output)
obj = MagicMock(__name__='bar')
expected_output = 'bar'
output = instance.__get__(obj, cls)
self.assertEqual(expected_output, output)
cls = None
output = instance.__get__(obj, cls)
self.assertEqual(expected_output, output)
def test_correct_class(self):
is_older_python = constants.PYTHON_BEFORE_39
try:
constants.PYTHON_BEFORE_39 = True
importlib.reload(helpers)
self.assertIs(helpers.ClassMethodWorkaround, helpers.classmethod)
constants.PYTHON_BEFORE_39 = False
importlib.reload(helpers)
self.assertIs(classmethod, helpers.classmethod)
finally:
constants.PYTHON_BEFORE_39 = is_older_python

View File

@ -1,880 +1,105 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
import asyncio
from unittest import TestCase
from unittest.mock import PropertyMock, patch
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Unittests for the `asyncio_taskpool.pool` module.
"""
from asyncio.exceptions import CancelledError
from asyncio.locks import Event, Semaphore
from unittest import IsolatedAsyncioTestCase
from unittest.mock import PropertyMock, MagicMock, AsyncMock, patch, call
from typing import Type
from asyncio_taskpool import pool, exceptions
from asyncio_taskpool import pool
EMPTY_LIST, EMPTY_DICT, EMPTY_SET = [], {}, set()
FOO, BAR, BAZ = 'foo', 'bar', 'baz'
EMPTY_LIST, EMPTY_DICT = [], {}
class TestException(Exception):
pass
class CommonTestCase(IsolatedAsyncioTestCase):
TEST_CLASS: Type[pool.BaseTaskPool] = pool.BaseTaskPool
TEST_POOL_SIZE: int = 420
TEST_POOL_NAME: str = 'test123'
task_pool: pool.BaseTaskPool
log_lvl: int
def get_task_pool_init_params(self) -> dict:
return {'pool_size': self.TEST_POOL_SIZE, 'name': self.TEST_POOL_NAME}
class BaseTaskPoolTestCase(TestCase):
def setUp(self) -> None:
self.log_lvl = pool.log.level
pool.log.setLevel(999)
self._pools = self.TEST_CLASS._pools
# These three methods are called during initialization, so we mock them by default during setup:
self._add_pool_patcher = patch.object(self.TEST_CLASS, '_add_pool')
self.pool_size_patcher = patch.object(self.TEST_CLASS, 'pool_size', new_callable=PropertyMock)
self.dunder_str_patcher = patch.object(self.TEST_CLASS, '__str__')
self._pools = getattr(pool.BaseTaskPool, '_pools')
# These three methods are called during initialization, so we mock them by default during setup
self._add_pool_patcher = patch.object(pool.BaseTaskPool, '_add_pool')
self.pool_size_patcher = patch.object(pool.BaseTaskPool, 'pool_size', new_callable=PropertyMock)
self.__str___patcher = patch.object(pool.BaseTaskPool, '__str__')
self.mock__add_pool = self._add_pool_patcher.start()
self.mock_pool_size = self.pool_size_patcher.start()
self.mock___str__ = self.dunder_str_patcher.start()
self.mock___str__ = self.__str___patcher.start()
self.mock__add_pool.return_value = self.mock_idx = 123
self.mock___str__.return_value = self.mock_str = 'foobar'
self.task_pool = self.TEST_CLASS(**self.get_task_pool_init_params())
# Test pool parameters:
self.test_pool_size, self.test_pool_name = 420, 'test123'
self.task_pool = pool.BaseTaskPool(pool_size=self.test_pool_size, name=self.test_pool_name)
def tearDown(self) -> None:
self.TEST_CLASS._pools.clear()
setattr(pool.TaskPool, '_pools', self._pools)
self._add_pool_patcher.stop()
self.pool_size_patcher.stop()
self.dunder_str_patcher.stop()
pool.log.setLevel(self.log_lvl)
class BaseTaskPoolTestCase(CommonTestCase):
self.__str___patcher.stop()
def test__add_pool(self):
self.assertListEqual(EMPTY_LIST, self._pools)
self._add_pool_patcher.stop()
output = pool.BaseTaskPool._add_pool(self.task_pool)
output = pool.TaskPool._add_pool(self.task_pool)
self.assertEqual(0, output)
self.assertListEqual([self.task_pool], pool.BaseTaskPool._pools)
self.assertListEqual([self.task_pool], getattr(pool.TaskPool, '_pools'))
def test_init(self):
self.assertEqual(0, self.task_pool._num_started)
self.assertFalse(self.task_pool._locked)
self.assertIsInstance(self.task_pool._closed, Event)
self.assertFalse(self.task_pool._closed.is_set())
self.assertEqual(self.TEST_POOL_NAME, self.task_pool._name)
self.assertDictEqual(EMPTY_DICT, self.task_pool._tasks_running)
self.assertDictEqual(EMPTY_DICT, self.task_pool._tasks_cancelled)
self.assertDictEqual(EMPTY_DICT, self.task_pool._tasks_ended)
self.assertIsInstance(self.task_pool._enough_room, Semaphore)
self.assertDictEqual(EMPTY_DICT, self.task_pool._task_groups)
self.assertDictEqual(EMPTY_DICT, self.task_pool._group_meta_tasks_running)
self.assertSetEqual(EMPTY_SET, self.task_pool._meta_tasks_cancelled)
self.assertIsInstance(self.task_pool._enough_room, asyncio.locks.Semaphore)
self.assertTrue(self.task_pool._open)
self.assertEqual(0, self.task_pool._counter)
self.assertDictEqual(EMPTY_DICT, self.task_pool._running)
self.assertDictEqual(EMPTY_DICT, self.task_pool._cancelled)
self.assertDictEqual(EMPTY_DICT, self.task_pool._ended)
self.assertEqual(0, self.task_pool._num_cancelled)
self.assertEqual(0, self.task_pool._num_ended)
self.assertEqual(self.mock_idx, self.task_pool._idx)
self.assertEqual(self.test_pool_name, self.task_pool._name)
self.assertIsInstance(self.task_pool._all_tasks_known_flag, asyncio.locks.Event)
self.assertTrue(self.task_pool._all_tasks_known_flag.is_set())
self.mock__add_pool.assert_called_once_with(self.task_pool)
self.mock_pool_size.assert_called_once_with(self.TEST_POOL_SIZE)
self.mock_pool_size.assert_called_once_with(self.test_pool_size)
self.mock___str__.assert_called_once_with()
def test___str__(self):
self.dunder_str_patcher.stop()
expected_str = f'{pool.BaseTaskPool.__name__}-{self.TEST_POOL_NAME}'
self.__str___patcher.stop()
expected_str = f'{pool.BaseTaskPool.__name__}-{self.test_pool_name}'
self.assertEqual(expected_str, str(self.task_pool))
self.task_pool._name = None
setattr(self.task_pool, '_name', None)
expected_str = f'{pool.BaseTaskPool.__name__}-{self.task_pool._idx}'
self.assertEqual(expected_str, str(self.task_pool))
def test_pool_size(self):
self.pool_size_patcher.stop()
self.task_pool._enough_room._value = self.TEST_POOL_SIZE
self.assertEqual(self.TEST_POOL_SIZE, self.task_pool.pool_size)
self.task_pool._pool_size = self.test_pool_size
self.assertEqual(self.test_pool_size, self.task_pool.pool_size)
with self.assertRaises(ValueError):
self.task_pool.pool_size = -1
self.task_pool.pool_size = new_size = 69
self.assertEqual(new_size, self.task_pool._enough_room._value)
self.assertEqual(new_size, self.task_pool._pool_size)
def test_is_locked(self):
self.task_pool._locked = FOO
self.assertEqual(FOO, self.task_pool.is_locked)
def test_lock(self):
assert not self.task_pool._locked
self.task_pool.lock()
self.assertTrue(self.task_pool._locked)
self.task_pool.lock()
self.assertTrue(self.task_pool._locked)
def test_unlock(self):
self.task_pool._locked = True
self.task_pool.unlock()
self.assertFalse(self.task_pool._locked)
self.task_pool.unlock()
self.assertFalse(self.task_pool._locked)
def test_is_open(self):
self.task_pool._open = foo = 'foo'
self.assertEqual(foo, self.task_pool.is_open)
def test_num_running(self):
self.task_pool._tasks_running = {1: FOO, 2: BAR, 3: BAZ}
self.task_pool._running = ['foo', 'bar', 'baz']
self.assertEqual(3, self.task_pool.num_running)
def test_num_cancelled(self):
self.task_pool._tasks_cancelled = {1: FOO, 2: BAR, 3: BAZ}
self.task_pool._num_cancelled = 33
self.assertEqual(3, self.task_pool.num_cancelled)
def test_num_ended(self):
self.task_pool._tasks_ended = {1: FOO, 2: BAR, 3: BAZ}
self.task_pool._num_ended = 3
self.assertEqual(3, self.task_pool.num_ended)
def test_num_finished(self):
self.task_pool._num_cancelled = cancelled = 69
self.task_pool._num_ended = ended = 420
self.task_pool._cancelled = mock_cancelled_dict = {1: 'foo', 2: 'bar'}
self.assertEqual(ended - cancelled + len(mock_cancelled_dict), self.task_pool.num_finished)
def test_is_full(self):
self.assertEqual(self.task_pool._enough_room.locked(), self.task_pool.is_full)
def test_get_group_ids(self):
group_name, ids = 'abcdef', [1, 2, 3]
self.task_pool._task_groups[group_name] = MagicMock(__iter__=lambda _: iter(ids))
self.assertEqual(set(ids), self.task_pool.get_group_ids(group_name))
with self.assertRaises(exceptions.InvalidGroupName):
self.task_pool.get_group_ids(group_name, 'something else')
async def test__check_start(self):
self.task_pool._closed.set()
mock_coroutine, mock_coroutine_function = AsyncMock()(), AsyncMock()
try:
with self.assertRaises(AssertionError):
self.task_pool._check_start(awaitable=None, function=None)
with self.assertRaises(AssertionError):
self.task_pool._check_start(awaitable=mock_coroutine, function=mock_coroutine_function)
with self.assertRaises(exceptions.NotCoroutine):
self.task_pool._check_start(awaitable=mock_coroutine_function, function=None)
with self.assertRaises(exceptions.NotCoroutine):
self.task_pool._check_start(awaitable=None, function=mock_coroutine)
with self.assertRaises(exceptions.PoolIsClosed):
self.task_pool._check_start(awaitable=mock_coroutine, function=None)
self.task_pool._closed.clear()
self.task_pool._locked = True
with self.assertRaises(exceptions.PoolIsLocked):
self.task_pool._check_start(awaitable=mock_coroutine, function=None, ignore_lock=False)
self.assertIsNone(self.task_pool._check_start(awaitable=mock_coroutine, function=None, ignore_lock=True))
finally:
await mock_coroutine
def test__task_name(self):
i = 123
self.assertEqual(f'{self.mock_str}_Task-{i}', self.task_pool._task_name(i))
@patch.object(pool, 'execute_optional')
@patch.object(pool.BaseTaskPool, '_task_name', return_value=FOO)
async def test__task_cancellation(self, mock__task_name: MagicMock, mock_execute_optional: AsyncMock):
task_id, mock_task, mock_callback = 1, MagicMock(), MagicMock()
self.task_pool._tasks_running[task_id] = mock_task
self.assertIsNone(await self.task_pool._task_cancellation(task_id, mock_callback))
self.assertNotIn(task_id, self.task_pool._tasks_running)
self.assertEqual(mock_task, self.task_pool._tasks_cancelled[task_id])
mock__task_name.assert_called_with(task_id)
mock_execute_optional.assert_awaited_once_with(mock_callback, args=(task_id, ))
@patch.object(pool, 'execute_optional')
@patch.object(pool.BaseTaskPool, '_task_name', return_value=FOO)
async def test__task_ending(self, mock__task_name: MagicMock, mock_execute_optional: AsyncMock):
task_id, mock_task, mock_callback = 1, MagicMock(), MagicMock()
self.task_pool._enough_room._value = room = 123
# End running task:
self.task_pool._tasks_running[task_id] = mock_task
self.assertIsNone(await self.task_pool._task_ending(task_id, mock_callback))
self.assertNotIn(task_id, self.task_pool._tasks_running)
self.assertEqual(mock_task, self.task_pool._tasks_ended[task_id])
self.assertEqual(room + 1, self.task_pool._enough_room._value)
mock__task_name.assert_called_with(task_id)
mock_execute_optional.assert_awaited_once_with(mock_callback, args=(task_id, ))
mock__task_name.reset_mock()
mock_execute_optional.reset_mock()
# End cancelled task:
self.task_pool._tasks_cancelled[task_id] = self.task_pool._tasks_ended.pop(task_id)
self.assertIsNone(await self.task_pool._task_ending(task_id, mock_callback))
self.assertNotIn(task_id, self.task_pool._tasks_cancelled)
self.assertEqual(mock_task, self.task_pool._tasks_ended[task_id])
self.assertEqual(room + 2, self.task_pool._enough_room._value)
mock__task_name.assert_called_with(task_id)
mock_execute_optional.assert_awaited_once_with(mock_callback, args=(task_id, ))
@patch.object(pool.BaseTaskPool, '_task_ending')
@patch.object(pool.BaseTaskPool, '_task_cancellation')
@patch.object(pool.BaseTaskPool, '_task_name', return_value=FOO)
async def test__task_wrapper(self, mock__task_name: MagicMock,
mock__task_cancellation: AsyncMock, mock__task_ending: AsyncMock):
task_id = 42
mock_cancel_cb, mock_end_cb = MagicMock(), MagicMock()
mock_coroutine_func = AsyncMock(return_value=FOO, side_effect=CancelledError)
# Cancelled during execution:
mock_awaitable = mock_coroutine_func()
output = await self.task_pool._task_wrapper(mock_awaitable, task_id,
end_callback=mock_end_cb, cancel_callback=mock_cancel_cb)
self.assertIsNone(output)
mock_coroutine_func.assert_awaited_once()
mock__task_name.assert_called_with(task_id)
mock__task_cancellation.assert_awaited_once_with(task_id, custom_callback=mock_cancel_cb)
mock__task_ending.assert_awaited_once_with(task_id, custom_callback=mock_end_cb)
mock_coroutine_func.reset_mock(side_effect=True)
mock__task_name.reset_mock()
mock__task_cancellation.reset_mock()
mock__task_ending.reset_mock()
# Not cancelled:
mock_awaitable = mock_coroutine_func()
output = await self.task_pool._task_wrapper(mock_awaitable, task_id,
end_callback=mock_end_cb, cancel_callback=mock_cancel_cb)
self.assertEqual(FOO, output)
mock_coroutine_func.assert_awaited_once()
mock__task_name.assert_called_with(task_id)
mock__task_cancellation.assert_not_awaited()
mock__task_ending.assert_awaited_once_with(task_id, custom_callback=mock_end_cb)
@patch.object(pool, 'create_task')
@patch.object(pool.BaseTaskPool, '_task_wrapper', new_callable=MagicMock)
@patch.object(pool.BaseTaskPool, '_task_name', return_value=FOO)
@patch.object(pool, 'TaskGroupRegister')
@patch.object(pool.BaseTaskPool, '_check_start')
async def test__start_task(self, mock__check_start: MagicMock, mock_reg_cls: MagicMock, mock__task_name: MagicMock,
mock__task_wrapper: AsyncMock, mock_create_task: MagicMock):
mock_group_reg = set_up_mock_group_register(mock_reg_cls)
mock_create_task.return_value = mock_task = MagicMock()
mock__task_wrapper.return_value = mock_wrapped = MagicMock()
mock_coroutine, mock_cancel_cb, mock_end_cb = MagicMock(), MagicMock(), MagicMock()
self.task_pool._num_started = count = 123
self.task_pool._enough_room._value = room = 123
group_name, ignore_lock = 'testgroup', True
output = await self.task_pool._start_task(mock_coroutine, group_name=group_name, ignore_lock=ignore_lock,
end_callback=mock_end_cb, cancel_callback=mock_cancel_cb)
self.assertEqual(count, output)
mock__check_start.assert_called_once_with(awaitable=mock_coroutine, ignore_lock=ignore_lock)
self.assertEqual(room - 1, self.task_pool._enough_room._value)
self.assertEqual(mock_group_reg, self.task_pool._task_groups[group_name])
mock_reg_cls.assert_called_once_with()
mock_group_reg.__aenter__.assert_awaited_once_with()
mock_group_reg.add.assert_called_once_with(count)
mock__task_name.assert_called_once_with(count)
mock__task_wrapper.assert_called_once_with(mock_coroutine, count, mock_end_cb, mock_cancel_cb)
mock_create_task.assert_called_once_with(coro=mock_wrapped, name=FOO)
self.assertEqual(mock_task, self.task_pool._tasks_running[count])
mock_group_reg.__aexit__.assert_awaited_once()
@patch.object(pool.BaseTaskPool, '_task_name', return_value=FOO)
def test__get_running_task(self, mock__task_name: MagicMock):
task_id, mock_task = 555, MagicMock()
self.task_pool._tasks_running[task_id] = mock_task
output = self.task_pool._get_running_task(task_id)
self.assertEqual(mock_task, output)
self.task_pool._tasks_cancelled[task_id] = self.task_pool._tasks_running.pop(task_id)
with self.assertRaises(exceptions.AlreadyCancelled):
self.task_pool._get_running_task(task_id)
mock__task_name.assert_called_once_with(task_id)
mock__task_name.reset_mock()
self.task_pool._tasks_ended[task_id] = self.task_pool._tasks_cancelled.pop(task_id)
with self.assertRaises(exceptions.TaskEnded):
self.task_pool._get_running_task(task_id)
mock__task_name.assert_called_once_with(task_id)
mock__task_name.reset_mock()
del self.task_pool._tasks_ended[task_id]
with self.assertRaises(exceptions.InvalidTaskID):
self.task_pool._get_running_task(task_id)
mock__task_name.assert_not_called()
@patch('warnings.warn')
def test__get_cancel_kw(self, mock_warn: MagicMock):
msg = None
self.assertDictEqual(EMPTY_DICT, pool.BaseTaskPool._get_cancel_kw(msg))
mock_warn.assert_not_called()
msg = 'something'
with patch.object(pool, 'PYTHON_BEFORE_39', new=True):
self.assertDictEqual(EMPTY_DICT, pool.BaseTaskPool._get_cancel_kw(msg))
mock_warn.assert_called_once()
mock_warn.reset_mock()
with patch.object(pool, 'PYTHON_BEFORE_39', new=False):
self.assertDictEqual({'msg': msg}, pool.BaseTaskPool._get_cancel_kw(msg))
mock_warn.assert_not_called()
@patch.object(pool.BaseTaskPool, '_get_cancel_kw')
@patch.object(pool.BaseTaskPool, '_get_running_task')
def test_cancel(self, mock__get_running_task: MagicMock, mock__get_cancel_kw: MagicMock):
mock__get_cancel_kw.return_value = fake_cancel_kw = {'a': 10, 'b': 20}
task_id1, task_id2, task_id3 = 1, 4, 9
mock__get_running_task.return_value.cancel = mock_cancel = MagicMock()
self.assertIsNone(self.task_pool.cancel(task_id1, task_id2, task_id3, msg=FOO))
mock__get_running_task.assert_has_calls([call(task_id1), call(task_id2), call(task_id3)])
mock__get_cancel_kw.assert_called_once_with(FOO)
mock_cancel.assert_has_calls(3 * [call(**fake_cancel_kw)])
def test__cancel_group_meta_tasks(self):
mock_task1, mock_task2 = MagicMock(), MagicMock()
self.task_pool._group_meta_tasks_running[BAR] = {mock_task1, mock_task2}
self.assertIsNone(self.task_pool._cancel_group_meta_tasks(FOO))
self.assertDictEqual({BAR: {mock_task1, mock_task2}}, self.task_pool._group_meta_tasks_running)
self.assertSetEqual(EMPTY_SET, self.task_pool._meta_tasks_cancelled)
mock_task1.cancel.assert_not_called()
mock_task2.cancel.assert_not_called()
self.assertIsNone(self.task_pool._cancel_group_meta_tasks(BAR))
self.assertDictEqual(EMPTY_DICT, self.task_pool._group_meta_tasks_running)
self.assertSetEqual({mock_task1, mock_task2}, self.task_pool._meta_tasks_cancelled)
mock_task1.cancel.assert_called_once_with()
mock_task2.cancel.assert_called_once_with()
@patch.object(pool.BaseTaskPool, '_cancel_group_meta_tasks')
def test__cancel_and_remove_all_from_group(self, mock__cancel_group_meta_tasks: MagicMock):
kw = {BAR: 10, BAZ: 20}
task_id = 555
mock_cancel = MagicMock()
def add_mock_task_to_running(_):
self.task_pool._tasks_running[task_id] = MagicMock(cancel=mock_cancel)
# We add the fake task to the `_tasks_running` dictionary as a side effect of calling the mocked method,
# to verify that it is called first, before the cancellation loop starts.
mock__cancel_group_meta_tasks.side_effect = add_mock_task_to_running
class MockRegister(set, MagicMock):
pass
self.assertIsNone(self.task_pool._cancel_and_remove_all_from_group(' ', MockRegister({task_id, 'x'}), **kw))
mock_cancel.assert_called_once_with(**kw)
@patch.object(pool.BaseTaskPool, '_get_cancel_kw')
@patch.object(pool.BaseTaskPool, '_cancel_and_remove_all_from_group')
def test_cancel_group(self, mock__cancel_and_remove_all_from_group: MagicMock, mock__get_cancel_kw: MagicMock):
mock__get_cancel_kw.return_value = fake_cancel_kw = {'a': 10, 'b': 20}
self.task_pool._task_groups[FOO] = mock_group_reg = MagicMock()
with self.assertRaises(exceptions.InvalidGroupName):
self.task_pool.cancel_group(BAR)
mock__cancel_and_remove_all_from_group.assert_not_called()
self.assertIsNone(self.task_pool.cancel_group(FOO, msg=BAR))
self.assertDictEqual(EMPTY_DICT, self.task_pool._task_groups)
mock__get_cancel_kw.assert_called_once_with(BAR)
mock__cancel_and_remove_all_from_group.assert_called_once_with(FOO, mock_group_reg, **fake_cancel_kw)
@patch.object(pool.BaseTaskPool, '_get_cancel_kw')
@patch.object(pool.BaseTaskPool, '_cancel_and_remove_all_from_group')
def test_cancel_all(self, mock__cancel_and_remove_all_from_group: MagicMock, mock__get_cancel_kw: MagicMock):
mock__get_cancel_kw.return_value = fake_cancel_kw = {'a': 10, 'b': 20}
mock_group_reg = MagicMock()
self.task_pool._task_groups = {FOO: mock_group_reg, BAR: mock_group_reg}
self.assertIsNone(self.task_pool.cancel_all(BAZ))
mock__get_cancel_kw.assert_called_once_with(BAZ)
mock__cancel_and_remove_all_from_group.assert_has_calls([
call(BAR, mock_group_reg, **fake_cancel_kw),
call(FOO, mock_group_reg, **fake_cancel_kw)
])
def test__pop_ended_meta_tasks(self):
mock_task, mock_done_task1 = MagicMock(done=lambda: False), MagicMock(done=lambda: True)
self.task_pool._group_meta_tasks_running[FOO] = {mock_task, mock_done_task1}
mock_done_task2, mock_done_task3 = MagicMock(done=lambda: True), MagicMock(done=lambda: True)
self.task_pool._group_meta_tasks_running[BAR] = {mock_done_task2, mock_done_task3}
expected_output = {mock_done_task1, mock_done_task2, mock_done_task3}
output = self.task_pool._pop_ended_meta_tasks()
self.assertSetEqual(expected_output, output)
self.assertDictEqual({FOO: {mock_task}}, self.task_pool._group_meta_tasks_running)
@patch.object(pool.BaseTaskPool, '_pop_ended_meta_tasks')
async def test_flush(self, mock__pop_ended_meta_tasks: MagicMock):
# Meta tasks:
mock_ended_meta_task = AsyncMock()
mock__pop_ended_meta_tasks.return_value = {mock_ended_meta_task()}
mock_cancelled_meta_task = AsyncMock(side_effect=CancelledError)
self.task_pool._meta_tasks_cancelled = {mock_cancelled_meta_task()}
# Actual tasks:
mock_ended_func, mock_cancelled_func = AsyncMock(), AsyncMock(side_effect=Exception)
self.task_pool._tasks_ended = {123: mock_ended_func()}
self.task_pool._tasks_cancelled = {456: mock_cancelled_func()}
self.assertIsNone(await self.task_pool.flush(return_exceptions=True))
# Meta tasks:
mock__pop_ended_meta_tasks.assert_called_once_with()
mock_ended_meta_task.assert_awaited_once_with()
mock_cancelled_meta_task.assert_awaited_once_with()
self.assertSetEqual(EMPTY_SET, self.task_pool._meta_tasks_cancelled)
# Actual tasks:
mock_ended_func.assert_awaited_once_with()
mock_cancelled_func.assert_awaited_once_with()
self.assertDictEqual(EMPTY_DICT, self.task_pool._tasks_ended)
self.assertDictEqual(EMPTY_DICT, self.task_pool._tasks_cancelled)
@patch.object(pool.BaseTaskPool, 'lock')
async def test_gather_and_close(self, mock_lock: MagicMock):
# Meta tasks:
mock_meta_task1, mock_meta_task2 = AsyncMock(), AsyncMock()
self.task_pool._group_meta_tasks_running = {FOO: {mock_meta_task1()}, BAR: {mock_meta_task2()}}
mock_cancelled_meta_task = AsyncMock(side_effect=CancelledError)
self.task_pool._meta_tasks_cancelled = {mock_cancelled_meta_task()}
# Actual tasks:
mock_running_func = AsyncMock()
mock_ended_func, mock_cancelled_func = AsyncMock(), AsyncMock(side_effect=Exception)
self.task_pool._tasks_ended = {123: mock_ended_func()}
self.task_pool._tasks_cancelled = {456: mock_cancelled_func()}
self.task_pool._tasks_running = {789: mock_running_func()}
self.assertIsNone(await self.task_pool.gather_and_close(return_exceptions=True))
mock_lock.assert_called_once_with()
# Meta tasks:
mock_meta_task1.assert_awaited_once_with()
mock_meta_task2.assert_awaited_once_with()
mock_cancelled_meta_task.assert_awaited_once_with()
self.assertDictEqual(EMPTY_DICT, self.task_pool._group_meta_tasks_running)
self.assertSetEqual(EMPTY_SET, self.task_pool._meta_tasks_cancelled)
# Actual tasks:
mock_ended_func.assert_awaited_once_with()
mock_cancelled_func.assert_awaited_once_with()
mock_running_func.assert_awaited_once_with()
self.assertDictEqual(EMPTY_DICT, self.task_pool._tasks_ended)
self.assertDictEqual(EMPTY_DICT, self.task_pool._tasks_cancelled)
self.assertDictEqual(EMPTY_DICT, self.task_pool._tasks_running)
self.assertTrue(self.task_pool._closed.is_set())
async def test_until_closed(self):
self.task_pool._closed = MagicMock(wait=AsyncMock(return_value=FOO))
output = await self.task_pool.until_closed()
self.assertEqual(FOO, output)
self.task_pool._closed.wait.assert_awaited_once_with()
class TaskPoolTestCase(CommonTestCase):
TEST_CLASS = pool.TaskPool
task_pool: pool.TaskPool
def test__generate_group_name(self):
prefix, func = 'x y z', AsyncMock(__name__=BAR)
base_name = f'{prefix}-{BAR}-group'
self.task_pool._task_groups = {
f'{base_name}-0': MagicMock(),
f'{base_name}-1': MagicMock(),
f'{base_name}-100': MagicMock(),
}
expected_output = f'{base_name}-2'
output = self.task_pool._generate_group_name(prefix, func)
self.assertEqual(expected_output, output)
@patch.object(pool.TaskPool, '_start_task')
async def test__apply_spawner(self, mock__start_task: AsyncMock):
grp_name = FOO + BAR
mock_awaitable1, mock_awaitable2 = object(), object()
mock_func = MagicMock(side_effect=[mock_awaitable1, Exception(), mock_awaitable2], __name__='func')
args, kw, num = (FOO, BAR), {'a': 1, 'b': 2}, 3
end_cb, cancel_cb = MagicMock(), MagicMock()
self.assertIsNone(await self.task_pool._apply_spawner(grp_name, mock_func, args, kw, num, end_cb, cancel_cb))
mock_func.assert_has_calls(num * [call(*args, **kw)])
mock__start_task.assert_has_awaits([
call(mock_awaitable1, group_name=grp_name, end_callback=end_cb, cancel_callback=cancel_cb),
call(mock_awaitable2, group_name=grp_name, end_callback=end_cb, cancel_callback=cancel_cb),
])
mock_func.reset_mock(side_effect=True)
mock__start_task.reset_mock()
# Simulate cancellation while the second task is being started.
mock__start_task.side_effect = [None, CancelledError, None]
mock_coroutine_to_close = MagicMock()
mock_func.side_effect = [mock_awaitable1, mock_coroutine_to_close, 'never called']
self.assertIsNone(await self.task_pool._apply_spawner(grp_name, mock_func, args, None, num, end_cb, cancel_cb))
mock_func.assert_has_calls(2 * [call(*args)])
mock__start_task.assert_has_awaits([
call(mock_awaitable1, group_name=grp_name, end_callback=end_cb, cancel_callback=cancel_cb),
call(mock_coroutine_to_close, group_name=grp_name, end_callback=end_cb, cancel_callback=cancel_cb),
])
mock_coroutine_to_close.close.assert_called_once_with()
@patch.object(pool, 'create_task')
@patch.object(pool.TaskPool, '_apply_spawner', new_callable=MagicMock())
@patch.object(pool, 'TaskGroupRegister')
@patch.object(pool.TaskPool, '_generate_group_name')
@patch.object(pool.BaseTaskPool, '_check_start')
def test_apply(self, mock__check_start: MagicMock, mock__generate_group_name: MagicMock,
mock_reg_cls: MagicMock, mock__apply_spawner: MagicMock, mock_create_task: MagicMock):
mock__generate_group_name.return_value = generated_name = 'name 123'
mock_group_reg = set_up_mock_group_register(mock_reg_cls)
mock__apply_spawner.return_value = mock_apply_coroutine = object()
mock_create_task.return_value = fake_task = object()
mock_func, num, group_name = MagicMock(), 3, FOO + BAR
args, kwargs = (FOO, BAR), {'a': 1, 'b': 2}
end_cb, cancel_cb = MagicMock(), MagicMock()
self.task_pool._task_groups = {group_name: 'causes error'}
with self.assertRaises(exceptions.InvalidGroupName):
self.task_pool.apply(mock_func, args, kwargs, num, group_name, end_cb, cancel_cb)
mock__check_start.assert_called_once_with(function=mock_func)
mock__apply_spawner.assert_not_called()
mock_create_task.assert_not_called()
mock__check_start.reset_mock()
self.task_pool._task_groups = {}
def check_assertions(_group_name, _output):
self.assertEqual(_group_name, _output)
mock__check_start.assert_called_once_with(function=mock_func)
self.assertEqual(mock_group_reg, self.task_pool._task_groups[_group_name])
mock__apply_spawner.assert_called_once_with(_group_name, mock_func, args, kwargs, num,
end_callback=end_cb, cancel_callback=cancel_cb)
mock_create_task.assert_called_once_with(mock_apply_coroutine)
self.assertSetEqual({fake_task}, self.task_pool._group_meta_tasks_running[group_name])
output = self.task_pool.apply(mock_func, args, kwargs, num, group_name, end_cb, cancel_cb)
check_assertions(group_name, output)
mock__generate_group_name.assert_not_called()
mock__check_start.reset_mock()
self.task_pool._task_groups.clear()
mock__apply_spawner.reset_mock()
mock_create_task.reset_mock()
output = self.task_pool.apply(mock_func, args, kwargs, num, None, end_cb, cancel_cb)
check_assertions(generated_name, output)
mock__generate_group_name.assert_called_once_with('apply', mock_func)
@patch.object(pool, 'execute_optional')
async def test__get_map_end_callback(self, mock_execute_optional: AsyncMock):
semaphore, mock_end_cb = Semaphore(1), MagicMock()
wrapped = pool.TaskPool._get_map_end_callback(semaphore, mock_end_cb)
task_id = 1234
await wrapped(task_id)
self.assertEqual(2, semaphore._value)
mock_execute_optional.assert_awaited_once_with(mock_end_cb, args=(task_id,))
@patch.object(pool, 'star_function')
@patch.object(pool.TaskPool, '_start_task')
@patch.object(pool.TaskPool, '_get_map_end_callback')
@patch.object(pool, 'Semaphore')
async def test__queue_consumer(self, mock_semaphore_cls: MagicMock, mock__get_map_end_callback: MagicMock,
mock__start_task: AsyncMock, mock_star_function: MagicMock):
n = 2
mock_semaphore_cls.return_value = semaphore = Semaphore(n)
mock__get_map_end_callback.return_value = map_cb = MagicMock()
awaitable1, awaitable2 = 'totally an awaitable', object()
mock_star_function.side_effect = [awaitable1, Exception(), awaitable2]
arg1, arg2, bad = 123456789, 'function argument', None
args = [arg1, bad, arg2]
grp_name, mock_func, stars = 'whatever', MagicMock(__name__="mock"), 3
end_cb, cancel_cb = MagicMock(), MagicMock()
self.assertIsNone(await self.task_pool._arg_consumer(grp_name, n, mock_func, args, stars, end_cb, cancel_cb))
# We initialized the semaphore with a value of 2. It should have been acquired twice. We expect it be locked.
self.assertTrue(semaphore.locked())
mock_semaphore_cls.assert_called_once_with(n)
mock__get_map_end_callback.assert_called_once_with(semaphore, actual_end_callback=end_cb)
mock__start_task.assert_has_awaits([
call(awaitable1, group_name=grp_name, ignore_lock=True, end_callback=map_cb, cancel_callback=cancel_cb),
call(awaitable2, group_name=grp_name, ignore_lock=True, end_callback=map_cb, cancel_callback=cancel_cb),
])
mock_star_function.assert_has_calls([
call(mock_func, arg1, arg_stars=stars),
call(mock_func, bad, arg_stars=stars),
call(mock_func, arg2, arg_stars=stars)
])
mock_semaphore_cls.reset_mock()
mock__get_map_end_callback.reset_mock()
mock__start_task.reset_mock()
mock_star_function.reset_mock(side_effect=True)
# With a CancelledError thrown while acquiring the semaphore:
mock_acquire = AsyncMock(side_effect=[True, CancelledError])
mock_semaphore_cls.return_value = mock_semaphore = MagicMock(acquire=mock_acquire)
mock_star_function.return_value = mock_coroutine = MagicMock()
arg_it = iter(arg for arg in (arg1, arg2, FOO))
self.assertIsNone(await self.task_pool._arg_consumer(grp_name, n, mock_func, arg_it, stars, end_cb, cancel_cb))
mock_semaphore_cls.assert_called_once_with(n)
mock__get_map_end_callback.assert_called_once_with(mock_semaphore, actual_end_callback=end_cb)
mock_star_function.assert_has_calls([
call(mock_func, arg1, arg_stars=stars),
call(mock_func, arg2, arg_stars=stars)
])
mock_acquire.assert_has_awaits([call(), call()])
mock__start_task.assert_awaited_once_with(mock_coroutine, group_name=grp_name, ignore_lock=True,
end_callback=map_cb, cancel_callback=cancel_cb)
mock_coroutine.close.assert_called_once_with()
mock_semaphore.release.assert_not_called()
self.assertEqual(FOO, next(arg_it))
mock_acquire.reset_mock(side_effect=True)
mock_semaphore_cls.reset_mock()
mock__get_map_end_callback.reset_mock()
mock__start_task.reset_mock()
mock_star_function.reset_mock(side_effect=True)
# With a CancelledError thrown while starting the task:
mock__start_task.side_effect = [None, CancelledError]
arg_it = iter(arg for arg in (arg1, arg2, FOO))
self.assertIsNone(await self.task_pool._arg_consumer(grp_name, n, mock_func, arg_it, stars, end_cb, cancel_cb))
mock_semaphore_cls.assert_called_once_with(n)
mock__get_map_end_callback.assert_called_once_with(mock_semaphore, actual_end_callback=end_cb)
mock_star_function.assert_has_calls([
call(mock_func, arg1, arg_stars=stars),
call(mock_func, arg2, arg_stars=stars)
])
mock_acquire.assert_has_awaits([call(), call()])
mock__start_task.assert_has_awaits(2 * [
call(mock_coroutine, group_name=grp_name, ignore_lock=True, end_callback=map_cb, cancel_callback=cancel_cb)
])
mock_coroutine.close.assert_called_once_with()
mock_semaphore.release.assert_called_once_with()
self.assertEqual(FOO, next(arg_it))
@patch.object(pool, 'create_task')
@patch.object(pool.TaskPool, '_arg_consumer', new_callable=MagicMock)
@patch.object(pool, 'TaskGroupRegister')
@patch.object(pool.BaseTaskPool, '_check_start')
def test__map(self, mock__check_start: MagicMock, mock_reg_cls: MagicMock, mock__arg_consumer: MagicMock,
mock_create_task: MagicMock):
mock_group_reg = set_up_mock_group_register(mock_reg_cls)
mock__arg_consumer.return_value = fake_consumer = object()
mock_create_task.return_value = fake_task = object()
group_name, n = 'onetwothree', 0
func, arg_iter, stars = AsyncMock(), [55, 66, 77], 3
end_cb, cancel_cb = MagicMock(), MagicMock()
with self.assertRaises(ValueError):
self.task_pool._map(group_name, n, func, arg_iter, stars, end_cb, cancel_cb)
mock__check_start.assert_called_once_with(function=func)
mock__check_start.reset_mock()
n = 1234
self.task_pool._task_groups = {group_name: MagicMock()}
with self.assertRaises(exceptions.InvalidGroupName):
self.task_pool._map(group_name, n, func, arg_iter, stars, end_cb, cancel_cb)
mock__check_start.assert_called_once_with(function=func)
mock__check_start.reset_mock()
self.task_pool._task_groups.clear()
self.assertIsNone(self.task_pool._map(group_name, n, func, arg_iter, stars, end_cb, cancel_cb))
mock__check_start.assert_called_once_with(function=func)
mock_reg_cls.assert_called_once_with()
self.task_pool._task_groups[group_name] = mock_group_reg
mock__arg_consumer.assert_called_once_with(group_name, n, func, arg_iter, stars,
end_callback=end_cb, cancel_callback=cancel_cb)
mock_create_task.assert_called_once_with(fake_consumer)
self.assertSetEqual({fake_task}, self.task_pool._group_meta_tasks_running[group_name])
@patch.object(pool.TaskPool, '_map')
@patch.object(pool.TaskPool, '_generate_group_name')
def test_map(self, mock__generate_group_name: MagicMock, mock__map: MagicMock):
mock__generate_group_name.return_value = generated_name = 'name 1 2 3'
mock_func = MagicMock()
arg_iter, num_concurrent, group_name = (FOO, BAR, 1, 2, 3), 2, FOO + BAR
end_cb, cancel_cb = MagicMock(), MagicMock()
output = self.task_pool.map(mock_func, arg_iter, num_concurrent, group_name, end_cb, cancel_cb)
self.assertEqual(group_name, output)
mock__map.assert_called_once_with(group_name, num_concurrent, mock_func, arg_iter, 0,
end_callback=end_cb, cancel_callback=cancel_cb)
mock__generate_group_name.assert_not_called()
mock__map.reset_mock()
output = self.task_pool.map(mock_func, arg_iter, num_concurrent, None, end_cb, cancel_cb)
self.assertEqual(generated_name, output)
mock__map.assert_called_once_with(generated_name, num_concurrent, mock_func, arg_iter, 0,
end_callback=end_cb, cancel_callback=cancel_cb)
mock__generate_group_name.assert_called_once_with('map', mock_func)
@patch.object(pool.TaskPool, '_map')
@patch.object(pool.TaskPool, '_generate_group_name')
def test_starmap(self, mock__generate_group_name: MagicMock, mock__map: MagicMock):
mock__generate_group_name.return_value = generated_name = 'name 1 2 3'
mock_func = MagicMock()
args_iter, num_concurrent, group_name = ([FOO], [BAR]), 2, FOO + BAR
end_cb, cancel_cb = MagicMock(), MagicMock()
output = self.task_pool.starmap(mock_func, args_iter, num_concurrent, group_name, end_cb, cancel_cb)
self.assertEqual(group_name, output)
mock__map.assert_called_once_with(group_name, num_concurrent, mock_func, args_iter, 1,
end_callback=end_cb, cancel_callback=cancel_cb)
mock__generate_group_name.assert_not_called()
mock__map.reset_mock()
output = self.task_pool.starmap(mock_func, args_iter, num_concurrent, None, end_cb, cancel_cb)
self.assertEqual(generated_name, output)
mock__map.assert_called_once_with(generated_name, num_concurrent, mock_func, args_iter, 1,
end_callback=end_cb, cancel_callback=cancel_cb)
mock__generate_group_name.assert_called_once_with('starmap', mock_func)
@patch.object(pool.TaskPool, '_map')
@patch.object(pool.TaskPool, '_generate_group_name')
async def test_doublestarmap(self, mock__generate_group_name: MagicMock, mock__map: MagicMock):
mock__generate_group_name.return_value = generated_name = 'name 1 2 3'
mock_func = MagicMock()
kw_iter, num_concurrent, group_name = [{'a': FOO}, {'a': BAR}], 2, FOO + BAR
end_cb, cancel_cb = MagicMock(), MagicMock()
output = self.task_pool.doublestarmap(mock_func, kw_iter, num_concurrent, group_name, end_cb, cancel_cb)
self.assertEqual(group_name, output)
mock__map.assert_called_once_with(group_name, num_concurrent, mock_func, kw_iter, 2,
end_callback=end_cb, cancel_callback=cancel_cb)
mock__generate_group_name.assert_not_called()
mock__map.reset_mock()
output = self.task_pool.doublestarmap(mock_func, kw_iter, num_concurrent, None, end_cb, cancel_cb)
self.assertEqual(generated_name, output)
mock__map.assert_called_once_with(generated_name, num_concurrent, mock_func, kw_iter, 2,
end_callback=end_cb, cancel_callback=cancel_cb)
mock__generate_group_name.assert_called_once_with('doublestarmap', mock_func)
class SimpleTaskPoolTestCase(CommonTestCase):
TEST_CLASS = pool.SimpleTaskPool
task_pool: pool.SimpleTaskPool
TEST_POOL_FUNC = AsyncMock(__name__=FOO)
TEST_POOL_ARGS = (FOO, BAR)
TEST_POOL_KWARGS = {'a': 1, 'b': 2}
TEST_POOL_END_CB = MagicMock()
TEST_POOL_CANCEL_CB = MagicMock()
def get_task_pool_init_params(self) -> dict:
params = super().get_task_pool_init_params()
params.update({
'func': self.TEST_POOL_FUNC,
'args': self.TEST_POOL_ARGS,
'kwargs': self.TEST_POOL_KWARGS,
'end_callback': self.TEST_POOL_END_CB,
'cancel_callback': self.TEST_POOL_CANCEL_CB,
})
return params
def setUp(self) -> None:
self.base_class_init_patcher = patch.object(pool.BaseTaskPool, '__init__')
self.base_class_init = self.base_class_init_patcher.start()
super().setUp()
def tearDown(self) -> None:
self.base_class_init_patcher.stop()
super().tearDown()
def test_init(self):
self.assertEqual(self.TEST_POOL_FUNC, self.task_pool._func)
self.assertEqual(self.TEST_POOL_ARGS, self.task_pool._args)
self.assertEqual(self.TEST_POOL_KWARGS, self.task_pool._kwargs)
self.assertEqual(self.TEST_POOL_END_CB, self.task_pool._end_callback)
self.assertEqual(self.TEST_POOL_CANCEL_CB, self.task_pool._cancel_callback)
self.base_class_init.assert_called_once_with(pool_size=self.TEST_POOL_SIZE, name=self.TEST_POOL_NAME)
with self.assertRaises(exceptions.NotCoroutine):
pool.SimpleTaskPool(MagicMock())
def test_func_name(self):
self.assertEqual(self.TEST_POOL_FUNC.__name__, self.task_pool.func_name)
@patch.object(pool.SimpleTaskPool, '_start_task')
async def test__start_num(self, mock__start_task: AsyncMock):
group_name = FOO + BAR + 'abc'
mock_awaitable1, mock_awaitable2 = object(), object()
self.task_pool._func = MagicMock(side_effect=[mock_awaitable1, Exception(), mock_awaitable2], __name__='func')
num = 3
self.assertIsNone(await self.task_pool._start_num(num, group_name))
self.task_pool._func.assert_has_calls(num * [call(*self.task_pool._args, **self.task_pool._kwargs)])
call_kw = {
'group_name': group_name,
'end_callback': self.task_pool._end_callback,
'cancel_callback': self.task_pool._cancel_callback
}
mock__start_task.assert_has_awaits([call(mock_awaitable1, **call_kw), call(mock_awaitable2, **call_kw)])
self.task_pool._func.reset_mock(side_effect=True)
mock__start_task.reset_mock()
# Simulate cancellation while the second task is being started.
mock__start_task.side_effect = [None, CancelledError, None]
mock_coroutine_to_close = MagicMock()
self.task_pool._func.side_effect = [mock_awaitable1, mock_coroutine_to_close, 'never called']
self.assertIsNone(await self.task_pool._start_num(num, group_name))
self.task_pool._func.assert_has_calls(2 * [call(*self.task_pool._args, **self.task_pool._kwargs)])
mock__start_task.assert_has_awaits([call(mock_awaitable1, **call_kw), call(mock_coroutine_to_close, **call_kw)])
mock_coroutine_to_close.close.assert_called_once_with()
@patch.object(pool, 'create_task')
@patch.object(pool.SimpleTaskPool, '_start_num', new_callable=MagicMock())
@patch.object(pool, 'TaskGroupRegister')
@patch.object(pool.BaseTaskPool, '_check_start')
def test_start(self, mock__check_start: MagicMock, mock_reg_cls: MagicMock, mock__start_num: AsyncMock,
mock_create_task: MagicMock):
mock_group_reg = set_up_mock_group_register(mock_reg_cls)
mock__start_num.return_value = mock_start_num_coroutine = object()
mock_create_task.return_value = fake_task = object()
self.task_pool._task_groups = {}
self.task_pool._group_meta_tasks_running = {}
num = 5
self.task_pool._start_calls = 42
expected_group_name = 'start-group-42'
output = self.task_pool.start(num)
self.assertEqual(expected_group_name, output)
mock__check_start.assert_called_once_with(function=self.TEST_POOL_FUNC)
self.assertEqual(43, self.task_pool._start_calls)
self.assertEqual(mock_group_reg, self.task_pool._task_groups[expected_group_name])
mock__start_num.assert_called_once_with(num, expected_group_name)
mock_create_task.assert_called_once_with(mock_start_num_coroutine)
self.assertSetEqual({fake_task}, self.task_pool._group_meta_tasks_running[expected_group_name])
@patch.object(pool.SimpleTaskPool, 'cancel')
def test_stop(self, mock_cancel: MagicMock):
num = 2
id1, id2, id3 = 5, 6, 7
self.task_pool._tasks_running = {id1: FOO, id2: BAR, id3: FOO + BAR}
output = self.task_pool.stop(num)
expected_output = [id3, id2]
self.assertEqual(expected_output, output)
mock_cancel.assert_called_once_with(*expected_output)
mock_cancel.reset_mock()
num = 50
output = self.task_pool.stop(num)
expected_output = [id3, id2, id1]
self.assertEqual(expected_output, output)
mock_cancel.assert_called_once_with(*expected_output)
@patch.object(pool.SimpleTaskPool, 'num_running', new_callable=PropertyMock)
@patch.object(pool.SimpleTaskPool, 'stop')
def test_stop_all(self, mock_stop: MagicMock, mock_num_running: MagicMock):
mock_num_running.return_value = num = 9876
mock_stop.return_value = expected_output = 'something'
output = self.task_pool.stop_all()
self.assertEqual(expected_output, output)
mock_num_running.assert_called_once_with()
mock_stop.assert_called_once_with(num)
def set_up_mock_group_register(mock_reg_cls: MagicMock) -> MagicMock:
mock_grp_aenter, mock_grp_aexit, mock_grp_add = AsyncMock(), AsyncMock(), MagicMock()
mock_reg_cls.return_value = mock_group_reg = MagicMock(__aenter__=mock_grp_aenter, __aexit__=mock_grp_aexit,
add=mock_grp_add)
return mock_group_reg

View File

@ -1,43 +0,0 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Unittests for the `asyncio_taskpool.queue_context` module.
"""
from unittest import IsolatedAsyncioTestCase
from unittest.mock import MagicMock, patch
from asyncio_taskpool.queue_context import Queue
class QueueTestCase(IsolatedAsyncioTestCase):
def test_item_processed(self):
queue = Queue()
queue._unfinished_tasks = 1000
queue.item_processed()
self.assertEqual(999, queue._unfinished_tasks)
@patch.object(Queue, 'item_processed')
async def test_contextmanager(self, mock_item_processed: MagicMock):
queue = Queue()
item = 'foo'
queue.put_nowait(item)
async with queue as item_from_queue:
self.assertEqual(item, item_from_queue)
mock_item_processed.assert_not_called()
mock_item_processed.assert_called_once_with()

View File

@ -1,24 +1,18 @@
# Using `asyncio-taskpool`
## Contents
- [Contents](#contents)
- [Minimal example for `SimpleTaskPool`](#minimal-example-for-simpletaskpool)
- [Advanced example for `TaskPool`](#advanced-example-for-taskpool)
- [Control server example](#control-server-example)
## Minimal example for `SimpleTaskPool`
With a `SimpleTaskPool` the function to execute as well as the arguments with which to execute it must be defined during its initialization (and they cannot be changed later). The only control you have after initialization is how many of such tasks are being run.
The minimum required setup is a "worker" coroutine function that can do something asynchronously, a main coroutine function that sets up the `SimpleTaskPool` and starts/stops the tasks as desired, eventually awaiting them all.
The minimum required setup is a "worker" coroutine function that can do something asynchronously, and a main coroutine function that sets up the `SimpleTaskPool`, starts/stops the tasks as desired, and eventually awaits them all.
The following demo script enables full log output first for additional clarity. It is complete and should work as is.
The following demo code enables full log output first for additional clarity. It is complete and should work as is.
### Code
```python
import logging
import asyncio
from asyncio_taskpool import SimpleTaskPool
from asyncio_taskpool.pool import SimpleTaskPool
logging.getLogger().setLevel(logging.NOTSET)
logging.getLogger('asyncio_taskpool').addHandler(logging.StreamHandler())
@ -29,238 +23,60 @@ async def work(n: int) -> None:
Pseudo-worker function.
Counts up to an integer with a second of sleep before each iteration.
In a real-world use case, a worker function should probably have access
to some synchronisation primitive (such as a queue) or shared resource
to distribute work between an arbitrary number of workers.
to some synchronisation primitive or shared resource to distribute work
between an arbitrary number of workers.
"""
for i in range(n):
await asyncio.sleep(1)
print("> did", i)
print("did", i)
async def main() -> None:
pool = SimpleTaskPool(work, args=(5,)) # initializes the pool; no work is being done yet
pool.start(3) # launches work tasks 0, 1, and 2
pool = SimpleTaskPool(work, (5,)) # initializes the pool; no work is being done yet
await pool.start(3) # launches work tasks 0, 1, and 2
await asyncio.sleep(1.5) # lets the tasks work for a bit
pool.start(1) # launches work task 3
await pool.start() # launches work task 3
await asyncio.sleep(1.5) # lets the tasks work for a bit
pool.stop(2) # cancels tasks 3 and 2 (LIFO order)
await pool.gather_and_close() # awaits all tasks, then flushes the pool
pool.stop(2) # cancels tasks 3 and 2
pool.close() # required for the last line
await pool.gather() # awaits all tasks, then flushes the pool
if __name__ == '__main__':
asyncio.run(main())
```
<details>
<summary>Output: (Click to expand)</summary>
### Output
```
SimpleTaskPool-0 initialized
Started SimpleTaskPool-0_Task-0
Started SimpleTaskPool-0_Task-1
Started SimpleTaskPool-0_Task-2
> did 0
> did 0
> did 0
did 0
did 0
did 0
Started SimpleTaskPool-0_Task-3
> did 1
> did 1
> did 1
> did 0
> did 2
> did 2
SimpleTaskPool-0 is locked!
Cancelling SimpleTaskPool-0_Task-2 ...
Cancelled SimpleTaskPool-0_Task-2
Ended SimpleTaskPool-0_Task-2
did 1
did 1
did 1
did 0
SimpleTaskPool-0 is closed!
Cancelling SimpleTaskPool-0_Task-3 ...
Cancelled SimpleTaskPool-0_Task-3
Ended SimpleTaskPool-0_Task-3
> did 3
> did 3
Cancelling SimpleTaskPool-0_Task-2 ...
Cancelled SimpleTaskPool-0_Task-2
Ended SimpleTaskPool-0_Task-2
did 2
did 2
did 3
did 3
Ended SimpleTaskPool-0_Task-0
Ended SimpleTaskPool-0_Task-1
> did 4
> did 4
```
</details>
## Advanced example for `TaskPool`
This time, we want to start tasks from _different_ coroutine functions **and** with _different_ arguments. For this we need an instance of the more generalized `TaskPool` class.
As with the simple example, we need "worker" coroutine functions that can do something asynchronously, as well as a main coroutine function that sets up the pool, starts the tasks, and eventually awaits them.
The following demo script enables full log output first for additional clarity. It is complete and should work as is.
```python
import logging
import asyncio
from asyncio_taskpool import TaskPool
logging.getLogger().setLevel(logging.NOTSET)
logging.getLogger('asyncio_taskpool').addHandler(logging.StreamHandler())
async def work(start: int, stop: int, step: int = 1) -> None:
"""Pseudo-worker function counting through a range with a second of sleep in between each iteration."""
for i in range(start, stop, step):
await asyncio.sleep(1)
print("> work with", i)
async def other_work(a: int, b: int) -> None:
"""Different pseudo-worker counting through a range with half a second of sleep in between each iteration."""
for i in range(a, b):
await asyncio.sleep(0.5)
print("> other_work with", i)
async def main() -> None:
# Initialize a new task pool instance and limit its size to 3 tasks.
pool = TaskPool(3)
# Queue up two tasks (IDs 0 and 1) to run concurrently (with the same keyword-arguments).
print("> Called `apply`")
pool.apply(work, kwargs={'start': 100, 'stop': 200, 'step': 10}, num=2)
# Let the tasks work for a bit.
await asyncio.sleep(1.5)
# Now, let us enqueue four more tasks (which will receive IDs 2, 3, 4, and 5), each created with different
# positional arguments by using `starmap`, but we want no more than two of those to run concurrently.
# Since we set our pool size to 3, and already have two tasks working within the pool,
# only the first one of these will start immediately (and receive ID 2).
# The second one will start (with ID 3), only once there is room in the pool,
# which -- in this example -- will be the case after ID 2 ends.
# Once there is room in the pool again, the third and fourth will each start (with IDs 4 and 5)
# only once there is room in the pool and no more than one other task of these new ones is running.
args_list = [(0, 10), (10, 20), (20, 30), (30, 40)]
pool.starmap(other_work, args_list, num_concurrent=2)
print("> Called `starmap`")
# We block, until all tasks have ended.
print("> Calling `gather_and_close`...")
await pool.gather_and_close()
print("> Done.")
if __name__ == '__main__':
asyncio.run(main())
did 4
did 4
```
<details>
<summary>Output: (Click to expand)</summary>
## Advanced example
```
TaskPool-0 initialized
Started TaskPool-0_Task-0
Started TaskPool-0_Task-1
> Called `apply`
> work with 100
> work with 100
> Called `starmap` <--- notice that this immediately returns, even before Task-2 is started
> Calling `gather_and_close`... <--- this blocks `main()` until all tasks have ended
TaskPool-0 is locked!
Started TaskPool-0_Task-2 <--- at this point the pool is full
> work with 110
> work with 110
> other_work with 0
> other_work with 1
> work with 120
> work with 120
> other_work with 2
> other_work with 3
> work with 130
> work with 130
> other_work with 4
> other_work with 5
> work with 140
> work with 140
> other_work with 6
> other_work with 7
> work with 150
> work with 150
> other_work with 8
Ended TaskPool-0_Task-2 <--- this frees up room for one more task from `starmap`
Started TaskPool-0_Task-3
> other_work with 9
> work with 160
> work with 160
> other_work with 10
> other_work with 11
> work with 170
> work with 170
> other_work with 12
> other_work with 13
> work with 180
> work with 180
> other_work with 14
> other_work with 15
Ended TaskPool-0_Task-0
Ended TaskPool-0_Task-1 <--- these two end and free up two more slots in the pool
Started TaskPool-0_Task-4 <--- since `num_concurrent` is set to 2, Task-5 will not start
> work with 190
> work with 190
> other_work with 16
> other_work with 17
> other_work with 20
> other_work with 18
> other_work with 21
Ended TaskPool-0_Task-3 <--- now that only Task-4 of the group remains, Task-5 starts
Started TaskPool-0_Task-5
> other_work with 19
> other_work with 22
> other_work with 23
> other_work with 30
> other_work with 24
> other_work with 31
> other_work with 25
> other_work with 32
> other_work with 26
> other_work with 33
> other_work with 27
> other_work with 34
> other_work with 28
> other_work with 35
> other_work with 29
> other_work with 36
Ended TaskPool-0_Task-4
> other_work with 37
> other_work with 38
> other_work with 39
Ended TaskPool-0_Task-5
> Done.
```
(Added comments with `<---` next to the output lines.)
Keep in mind that the logger and `print` asynchronously write to `stdout`, so the order of lines in your output may be slightly different.
</details>
## Control server example
One of the main features of `asyncio-taskpool` is the ability to control a task pool "from the outside" at runtime.
The [example_server.py](./example_server.py) script launches a couple of worker tasks within a `SimpleTaskPool` instance and then starts a `TCPControlServer` instance for that task pool. The server is configured to locally bind to port `9999` and is stopped automatically after the "work" is done.
To run the script:
```shell
python usage/example_server.py
```
You can then connect to the server via the command line interface:
```shell
python -m asyncio_taskpool.control tcp localhost 9999
```
The CLI starts a `TCPControlClient` that connects to our example server. Once the connection is established, it gives you an input prompt allowing you to issue commands to the task pool:
```
Connected to SimpleTaskPool-0
Type '-h' to get help and usage instructions for all available commands.
>
```
It may be useful to run the server script and the client interface in two separate terminal windows side by side. The server script is configured with a verbose logger and will react to any commands issued by the client with detailed log messages in the terminal.
---
© 2022 Daniil Fajnberg
...

View File

@ -1,31 +1,8 @@
__author__ = "Daniil Fajnberg"
__copyright__ = "Copyright © 2022 Daniil Fajnberg"
__license__ = """GNU LGPLv3.0
This file is part of asyncio-taskpool.
asyncio-taskpool is free software: you can redistribute it and/or modify it under the terms of
version 3.0 of the GNU Lesser General Public License as published by the Free Software Foundation.
asyncio-taskpool is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with asyncio-taskpool.
If not, see <https://www.gnu.org/licenses/>."""
__doc__ = """
Working example of a TCPControlServer in combination with the SimpleTaskPool.
Use the main CLI client to interface at the socket.
"""
import asyncio
import logging
from asyncio_taskpool import SimpleTaskPool
from asyncio_taskpool.control import TCPControlServer
from asyncio_taskpool.internals.constants import PACKAGE_NAME
from asyncio_taskpool import SimpleTaskPool, UnixControlServer
from asyncio_taskpool.constants import PACKAGE_NAME
logging.getLogger().setLevel(logging.NOTSET)
@ -35,11 +12,11 @@ logging.getLogger(PACKAGE_NAME).addHandler(logging.StreamHandler())
async def work(item: int) -> None:
"""The non-blocking sleep simulates something like an I/O operation that can be done asynchronously."""
await asyncio.sleep(1)
print("worked on", item, flush=True)
print("worked on", item)
async def worker(q: asyncio.Queue) -> None:
"""Simulates doing asynchronous work that takes a bit of time to finish."""
"""Simulates doing asynchronous work that takes a little bit of time to finish."""
# We only want the worker to stop, when its task is cancelled; therefore we start an infinite loop.
while True:
# We want to block here, until we can get the next item from the queue.
@ -66,20 +43,21 @@ async def main() -> None:
# We just put some integers into our queue, since all our workers actually do, is print an item and sleep for a bit.
for item in range(100):
q.put_nowait(item)
pool = SimpleTaskPool(worker, args=(q,)) # initializes the pool
pool.start(3) # launches three worker tasks
control_server_task = await TCPControlServer(pool, host='127.0.0.1', port=9999).serve_forever()
pool = SimpleTaskPool(worker, (q,)) # initializes the pool
await pool.start(3) # launches three worker tasks
control_server_task = await UnixControlServer(pool, path='/tmp/py_asyncio_taskpool.sock').serve_forever()
# We block until `.task_done()` has been called once by our workers for every item placed into the queue.
await q.join()
# Since we don't need any "work" done anymore, we can get rid of our control server by cancelling the task.
# Since we don't need any "work" done anymore, we can close our control server by cancelling the task.
control_server_task.cancel()
# Since our workers should now be stuck waiting for more items to pick from the queue, but no items are left,
# we can now safely cancel their tasks.
pool.stop_all()
# Finally, we allow for all tasks to do their cleanup (as if they need to do any) upon being cancelled.
pool.close()
# Finally we allow for all tasks to do do their cleanup, if they need to do any, upon being cancelled.
# We block until they all return or raise an exception, but since we are not interested in any of their exceptions,
# we just silently collect their exceptions along with their return values.
await pool.gather_and_close(return_exceptions=True)
await pool.gather(return_exceptions=True)
await control_server_task