Skip to main content

Host software for 3D printers

Project description

PRINTRUN

License GitHub - Downloads GitHub contributors PyPI - Version PyPI - Downloads

Printrun consists of a suite of hosts for 3D printers and other CNC machines (printcore, pronsole and pronterface) and a small collection of helpful scripts.

  • printcore.py is a library that makes writing RepRap hosts easy
  • pronsole.py is an interactive command-line host with tab-completion goodness
  • pronterface.py is a graphical host with the same functionality as pronsole

The contents of this document are organized in the following sections:

GETTING PRINTRUN

Installation of Printrun can be done in several ways, either installing a pre-compiled binary, via distribution-specific packages from official repositories or from PyPI. If you want the newest, shiniest features, you can run Printrun from source.

Distributed Binaries and Packages

Windows and macOS pre-compiled binaries

Everything bundled into one single package for easy installation. Downloads available at: https://github.com/kliment/Printrun/releases/latest

Note for OSX users: if OSX tells you "pronterface.app" cannot be opened because the developer cannot be verified., you don't need to re-download it. Instead, you need to allow OSX to run the unsigned app. To do this, right- or ctrl click the application in Finder and select Open. Then click Open in the popup window that appears. You only need to do this once.

Linux packages from official repositories

Ubuntu / Mint / Raspberry Pi OS / Debian

Install the full suite: sudo apt install printrun

Or only the apps you need: sudo apt install pronsole or pronterface or plater

Chrome OS

You can use Printrun via crouton. Assuming you want Ubuntu Trusty, you used probably sudo sh -e ~/Downloads/crouton -r trusty -t xfce to install Ubuntu. Fetch and install printrun with the line given above for Ubuntu/Debian.

By default you have no access to the serial port under Chrome OS crouton, so you cannot connect to your 3D printer. Add yourself to the serial group within the linux environment to fix this

sudo usermod -G serial -a <username>

where <username> should be your username. Log out and in to make this group change active and allow communication with your printer.

Fedora

Install the full suite: sudo dnf install printrun

Or only the apps you need: sudo dnf install pronsole or pronterface or plater

Adding --enablerepo updates-testing option to dnf might sometimes give you newer packages (but also not very tested).

Arch Linux

Packages are available in AUR. Just run

yaourt printrun

Printrun package from PyPI

If you have a working Python environment, regardless of your OS, you can install the latest release distributed through the PyPI repository using pip and, optionally (but highly recommended), a virtual environment.

Activate your virtual environment, and run (Linux / macOS):

python -m pip install Printrun

or (Windows):

py -m pip install Printrun

Running From Source

By running Printrun from source you get access to the latest features and in-development changes. Warning note: these might not be fully working or stable.

Linux / macOS

1. Install Python

Almost all Linux distributions come with Python already pre-installed. If not, install Python normally from your package manager. On macOS download and install the latest Python from python.org.

2. Download the latest Printrun source code

Obtain the latest source code by running the following in a terminal window:

$ git clone https://github.com/kliment/Printrun.git  # clone the repository
$ cd Printrun  # change to Printrun directory

3. Use a Python virtual environment

Easiest way to run Printrun from source is to create and use a Python virtual environment. This step is optional but highly recommended to avoid conflicts with other Python libraries already installed (or that will be installed in the future) in your system. Within the Printrun's root directory, create and activate a virtual environment by running:

$ python -m venv venv       # create a virtual environment
$ source venv/bin/activate  # activate the virtual environment

Note for Ubuntu/Debian: You might need to install python3-venv first.

Note for Ubuntu/Debian: If you get python: command not found use python3 -m venv venv instead.

4. Install Printrun

Once activated your virtual environment, install Printrun' source code with:

(venv) $ python -m pip install .

Note for Linux users: wxPython4 doesn't have Linux wheels available from the Python Package Index yet. Before running the command above, find a proper wheel for your distro at extras.wxpython.org and substitute the link in the below example. You might skip this wheel installation, but that results in compiling wxPython4 from source, which can be time and resource consuming and might fail.

(venv) $ python -m pip install https://extras.wxpython.org/wxPython4/extras/linux/gtk3/fedora-27/wxPython-4.0.1-cp36-cp36m-linux_x86_64.whl  # replace the link with yours

5. Run Printrun

With your virtual environment still active, invoke the app you need like:

(venv) $ pronterface.py  # or `pronsole.py` or `plater.py`

Windows

First download and install GIT for Windows, Python 3.10 and a C-compiler environment. For the next steps we need a CMD window or a PowerShell window. You can use Windows Terminal for this as well. Create and navigate to a directory of your choice where you want to download the source files of this repository and follow the next steps:

CMD

> git clone https://github.com/kliment/Printrun.git
> cd Printrun
> release_windows.bat

PowerShell:

> git clone https://github.com/kliment/Printrun.git
> cd Printrun
> ./release_windows.bat

The script above will clone this repository. The script release_windows.bat will install a virtual environment named v3, download all needed python libraries and compile the binaries for Pronterface.exe and Pronsole.exe. You will find the files in the new created directory dist. You will find further and more detailed information in the script release_windows.bat. Run Pronterface or Pronsole from the binary files or from source calling pronterface.py for the GUI version and pronsole.py for the commandline version.

Running Pronsole works best by running it in WindowsTerminal. You can create a desktop shortcut link to the file pronsole.exe. Then edit the target for your shortcut as shown in belows example: %LocalAppData%\Microsoft\WindowsApps\wt.exe --title Pronsole %USERPROFILE%\Downloads\pronterface-test\pronsole.exe You need to adjust the path to your location of pronsole.exe.

Run 'release_windows.bat' when ever you make changes or updates. With each new run it will compile the binaries and update all involved libraries in the virtual environment if needed. Delete the virtual environment if you have problems with it.

USING PRINTRUN

USING PRONTERFACE

When you're done setting up Printrun, you can start pronterface.py in the directory you unpacked it. Select the port name you are using from the first drop-down, select your baud rate, and hit connect. Load an STL (see the note on skeinforge below) or GCODE file, and you can upload it to SD or print it directly. The "monitor printer" function, when enabled, checks the printer state (temperatures, SD print progress) every 3 seconds. The command box recognizes all pronsole commands, but has no tabcompletion.

If you want to load stl files, you need to install a slicing program such as Slic3r or Skeinforge and add its path to the settings.

Slic3r integration

To invoke Slic3r directly from Pronterface your slicing command (Settings > Options > External Commands > Slice Command) should look something like slic3r $s -o $o. If Slic3r is properly installed "slic3r" will suffice, otherwise, replace it with the full path to Slic3r's executable.

If the Slic3r integration option (Settings > Options > User interface > Enable Slic3r integration) is checked a new menu will appear after application restart which will allow you to choose among your previously saved Slic3r Print/Filament/Printer settings.

USING PRONSOLE

To use pronsole, you need:

  • Python 3 (ideally 3.10),
  • pyserial (or python3-serial on ubuntu/debian) and
  • pyreadline (not needed on Linux)

Start pronsole and you will be greeted with a command prompt. Type help to view the available commands. All commands have internal help, which you can access by typing "help commandname", for example "help connect"

If you want to load stl files, you need to put a version of skeinforge (doesn't matter which one) in a folder called "skeinforge". The "skeinforge" folder must be in the same folder as pronsole.py

USING PRINTCORE

To use printcore you need Python 3 (ideally 3.10) and pyserial (or python3-serial on ubuntu/debian) See pronsole for an example of a full-featured host, the bottom of printcore.py for a simple command-line sender, or the following code example:

#to send a file of gcode to the printer
from printrun.printcore import printcore
from printrun import gcoder
import time
p=printcore('/dev/ttyUSB0', 115200) # or p.printcore('COM3',115200) on Windows
gcode=[i.strip() for i in open('filename.gcode')] # or pass in your own array of gcode lines instead of reading from a file
gcode = gcoder.LightGCode(gcode)

# startprint silently exits if not connected yet
while not p.online:
  time.sleep(0.1)

p.startprint(gcode) # this will start a print

#If you need to interact with the printer:
p.send_now("M105") # this will send M105 immediately, ahead of the rest of the print
p.pause() # use these to pause/resume the current print
p.resume()
p.disconnect() # this is how you disconnect from the printer once you are done. This will also stop running prints.

PLATERS

Printrun provides two platers: a STL plater (plater.py) and a G-Code plater (gcodeplater.py).

3D VIEWER CONTROLS

When the 3D viewer is enabled, the controls are the following:

  • Mousewheel: zoom (Control reduces the zoom change steps)
  • Shift+mousewheel: explore layers (in print gcode view ; Control key makes layer change by increments of 10 instead of 1) or rotate object (in platers)
  • Left-click dragging: rotate view
  • Right-click dragging: pan view
  • Shift + left-click dragging: move object (in platers)
  • Page up/down keys: zoom (Control reduces the zoom change steps)
  • Up/down keys: explore layers
  • R key: reset view
  • F key: fit view to display entire print
  • C key: toggle "display current layer only" mode (in print gcode view)

RPC SERVER

pronterface and pronsole start a RPC server, which runs by default on localhost port 7978, which provides print progress information. Here is a sample Python script querying the print status:

import xmlrpc.client

rpc = xmlrpc.client.ServerProxy('http://localhost:7978')
print(rpc.status())

CONFIGURATION

Build dimensions

Build dimensions can be specified using the build_dimensions option (which can be graphically edited in Pronterface settings). This option is formed of 9 parameters: 3 for the build volume dimensions, 3 for the build volume coordinate system offset minimum, 3 for the endstop positions.

The default value is 200x200x100+0+0+0+0+0+0, which corresponds to a 200x200mm (width x height) bed with 100mm travel in Z (there are the first three numbers) and no offset. The absolute coordinates system origin (0,0,0) is at the bottom left corner on the bed surface, and the top right corner on the bed surface is (200,200,0).

A common practice is to have the origin of the coordinate system (0,0,0) at the center of the bed surface. This is achieved by using the next three parameters, for instance with 200x200x100-100-100+0+0+0+0. In this case, the bottom left corner of the bed will be at (-100,-100,0) and the top right one at (100,100,0).

These two sets of settings should be sufficient for most people. However, for some specific complicated setups and GCodes and some features, we might also need the endstops positions for perfect display. These positions (which are usually 0,0,0, so if you don't know you probably have a standard setup) are specified in absolute coordinates, so if you have your bed starting at (-100,-100,0) and your endstops are 10mm away from the bed left and right and the Z endstop 5mm above the bed, you'll want to set the endstops positions to (-110,-110,5) for this option.

USING MACROS AND CUSTOM BUTTONS

Macros in pronsole and pronterface

To send simple G-code (or pronsole command) sequence is as simple as entering them one by one in macro definition. If you want to use parameters for your macros, substitute them with {0} {1} {2} ... etc.

All macros are saved automatically immediately after being entered.

Example 1, simple one-line alias:

PC> macro where M114

Instead of having to remember the code to query position, you can query the position:

PC> where
X:25.00Y:11.43Z:5.11E:0.00

Example 2 - macros to switch between different slicer programs, using "set" command to change options:

PC> macro use_slicer
Enter macro using indented lines, end with empty line
..> set sliceoptscommand Slic3r/slic3r.exe --load slic3r.ini
..> set slicecommand Slic3r/slic3r.exe $s --load slic3r.ini --output $o
Macro 'use_slicer' defined
PC> macro use_sfact
..> set sliceoptscommand python skeinforge/skeinforge_application/skeinforge.py
..> set slicecommand python skeinforge/skeinforge_application/skeinforge_utilities/skeinforge_craft.py $s
Macro 'use_sfact' defined

Example 3, simple parametric macro:

PC> macro move_down_by
Enter macro using indented lines, end with empty line
..> G91
..> G1 Z-{0}
..> G90
..>

Invoke the macro to move the printhead down by 5 millimeters:

PC> move_down_by 5

For more powerful macro programming, it is possible to use python code escaping using ! symbol in front of macro commands. Note that this python code invocation also works in interactive prompt:

PC> !print("Hello, printer!")
Hello printer!

PC> macro debug_on !self.p.loud = 1
Macro 'debug_on' defined
PC> debug_on
PC> M114
SENT:  M114
X:0.00Y:0.00Z:0.00E:0.00 Count X:0.00Y:0.00Z:0.00
RECV:  X:0.00Y:0.00Z:0.00E:0.00 Count X:0.00Y:0.00Z:0.00
RECV:  ok

You can use macro command itself to create simple self-modify or toggle functionality:

Example: swapping two macros to implement toggle:

PC> macro toggle_debug_on
Enter macro using indented lines, end with empty line
..> !self.p.loud = 1
..> !print("Diagnostic information ON")
..> macro toggle_debug toggle_debug_off
..>
Macro 'toggle_debug_on' defined
PC> macro toggle_debug_off
Enter macro using indented lines, end with empty line
..> !self.p.loud = 0
..> !print("Diagnostic information OFF")
..> macro toggle_debug toggle_debug_on
..>
Macro 'toggle_debug_off' defined
PC> macro toggle_debug toggle_debug_on
Macro 'toggle_debug' defined

Now, each time we invoke "toggle_debug" macro, it toggles debug information on and off:

PC> toggle_debug
Diagnostic information ON

PC> toggle_debug
Diagnostic information OFF

When python code (using ! symbol) is used in macros, it is even possible to use blocks/conditionals/loops. It is okay to mix python code with pronsole commands, just keep the python indentation. For example, following macro toggles the diagnostic information similarily to the previous example:

!if self.p.loud:
  !self.p.loud = 0
  !print("Diagnostic information OFF")
!else:
  !self.p.loud = 1
  !print("Diagnostic information ON")

Macro parameters are available in '!'-escaped python code as locally defined list variable: arg[0] arg1 ... arg[N]

All python code is executed in the context of the pronsole (or PronterWindow) object, so it is possible to use all internal variables and methods, which provide great deal of functionality. However the internal variables and methods are not very well documented and may be subject of change, as the program is developed. Therefore it is best to use pronsole commands, which easily contain majority of the functionality that might be needed.

Some useful python-mode-only variables:

!self.settings - contains all settings, e.g.
  port (!self.settings.port), baudrate, xy_feedrate, e_feedrate, slicecommand, final_command, build_dimensions
  You can set them also via pronsole command "set", but you can query the values only via python code.
!self.p - printcore object (see USING PRINTCORE section for using printcore object)
!self.cur_button - if macro was invoked via custom button, the number of the custom button, e.g. for usage in "button" command
!self.gwindow - wx graphical interface object for pronterface (highly risky to use because the GUI implementation details may change a lot between versions)

Some useful methods:

!self.onecmd - invokes raw command, e.g.
    !self.onecmd("move x 10")
    !self.onecmd("!print self.p.loud")
    !self.onecmd("button "+self.cur_button+" fanOFF /C cyan M107")
!self.project - invoke Projector

USING HOST COMMANDS

Pronsole and the console interface in Pronterface accept a number of commands which you can either use directly or inside your G-Code. To run a host command from inside a G-Code, simply prefix it with ;@.

List of available commands:

  • pause: pauses the print until the user resumes it
  • run_script scriptname [arg1 ...]: runs a custom script or program on the host computer. This can for instance be used to produce a sound to warn the user (e.g. run_script beep -r 2 on machines were the beep util is available), or to send an email or text message at the end of a print. The $s token can be used in the arguments to get the current gcode file name
  • run_gcode_script scripname [arg1 ...]: same as run_script, except that all lines displayed by the script will be interpreted in turn (so that G-Code lines will be immediately sent to the printer)
  • shell pythoncommand: run a python command (can also be achieved by doing !pythoncommand)
  • set option value: sets the value of an option, e.g. set mainviz 3D
  • connect
  • block_until_online: wait for the printer to be online. For instance you can do python pronsole.py -e "connect" -e "block_until_online" -e "upload object.gcode" to start pronsole, connect for the printer, wait for it to be online to start uploading the object.gcode file.
  • disconnect
  • load gcodefile
  • upload gcodefile target.g: upload gcodefile to target.g on the SD card
  • slice stlfile: slice stlfile and load the produced G-Code
  • print: print the currently loaded file
  • sdprint target.g: start a SD print
  • ls: list files on SD card
  • eta: display remaining print time
  • gettemp: get current printer temperatures
  • settemp: set hotend target temperature
  • bedtemp: set bed target temperature
  • monitor: monitor printer progress during a print
  • tool K: switch to tool K
  • move xK: move along x axis (works with other axes too)
  • extrude length [speed]
  • reverse length [speed]
  • home [axis]
  • off: turns off fans, motors, extruder, heatbed, power supply
  • exit

TESTING

A small (work in progress) test suite is developed within folder tests using unittest which can be run with (requires Python 3.11+):

python -m unittest discover tests

Small utilities for testing/debugging communications or g-code reading/writing are also provided within folder testtools.

CONTRIBUTING

Thinking of contributing to Printrun? Awesome! Thank you! ❤️

Printrun is an open source project and we love to receive contributions from anyone. There are many ways to contribute:

  • Improving the documentation. This README is our main source of documentation and it surely lacks some love here and there or requires being brought up to date.

  • Submitting bug reports and feature requests.

    • We use GitHub's issue tracker to keep track of them.
    • Please remember to state your OS and Printrun version on new issues.
  • Improving the test code base. Current code coverage is extremely low. See testing section for more information.

  • Fixing existing issues and/or implementing requested features. There is a fair amount of known issues and a great deal of requested features waiting to be implemented. We (the maintainers) don't have the time and resources to look at them all so every code contribution will be very welcome.

    • We use GitHub's pull requests to review and incorporate new code.
    • Issues labeled Regression would be the most urgent fixes needed, followed by issues/requests labeled 2.x and lastly those with 3.x.
    • Ideally every new contribution should comply with PEP 8 style guide as much as possible and should be thoroughly documented to ease reviewing and future understanding of the code.
    • Please note that breaking changes might need to wait to be incorporated until the next major release is due.

CONTRIBUTORS

An enormous number of people helped make Printrun. See the list here.

LICENSE

Copyright (C) 2011-2024 Kliment Yanev, Guillaume Seguin, and the other contributors listed in CONTRIBUTORS.md

Printrun is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.

Printrun 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 General Public License for more details.

You should have received a copy of the GNU General Public License
along with Printrun.  If not, see <http://www.gnu.org/licenses/>.

All scripts should contain this license note, if not, feel free to ask us. Please note that files where it is difficult to state this license note (such as images) are distributed under the same terms.

Project details


Download files

Download the file for your platform. If you're not sure which to choose, learn more about installing packages.

Source Distribution

printrun-2.2.0.tar.gz (535.0 kB view hashes)

Uploaded Source

Built Distributions

Printrun-2.2.0-cp313-cp313-win_amd64.whl (459.0 kB view hashes)

Uploaded CPython 3.13 Windows x86-64

Printrun-2.2.0-cp313-cp313-win32.whl (455.4 kB view hashes)

Uploaded CPython 3.13 Windows x86

Printrun-2.2.0-cp313-cp313-manylinux_2_17_aarch64.manylinux2014_aarch64.whl (593.3 kB view hashes)

Uploaded CPython 3.13 manylinux: glibc 2.17+ ARM64

Printrun-2.2.0-cp313-cp313-manylinux_2_5_x86_64.manylinux1_x86_64.manylinux_2_17_x86_64.manylinux2014_x86_64.whl (595.5 kB view hashes)

Uploaded CPython 3.13 manylinux: glibc 2.17+ x86-64 manylinux: glibc 2.5+ x86-64

Printrun-2.2.0-cp313-cp313-manylinux_2_5_i686.manylinux1_i686.manylinux_2_17_i686.manylinux2014_i686.whl (581.6 kB view hashes)

Uploaded CPython 3.13 manylinux: glibc 2.17+ i686 manylinux: glibc 2.5+ i686

Printrun-2.2.0-cp313-cp313-macosx_11_0_arm64.whl (459.6 kB view hashes)

Uploaded CPython 3.13 macOS 11.0+ ARM64

Printrun-2.2.0-cp313-cp313-macosx_10_13_x86_64.whl (459.7 kB view hashes)

Uploaded CPython 3.13 macOS 10.13+ x86-64

Printrun-2.2.0-cp313-cp313-macosx_10_13_universal2.whl (485.3 kB view hashes)

Uploaded CPython 3.13 macOS 10.13+ universal2 (ARM64, x86-64)

Printrun-2.2.0-cp312-cp312-win_amd64.whl (459.7 kB view hashes)

Uploaded CPython 3.12 Windows x86-64

Printrun-2.2.0-cp312-cp312-win32.whl (456.0 kB view hashes)

Uploaded CPython 3.12 Windows x86

Printrun-2.2.0-cp312-cp312-manylinux_2_17_aarch64.manylinux2014_aarch64.whl (600.2 kB view hashes)

Uploaded CPython 3.12 manylinux: glibc 2.17+ ARM64

Printrun-2.2.0-cp312-cp312-manylinux_2_5_x86_64.manylinux1_x86_64.manylinux_2_17_x86_64.manylinux2014_x86_64.whl (602.3 kB view hashes)

Uploaded CPython 3.12 manylinux: glibc 2.17+ x86-64 manylinux: glibc 2.5+ x86-64

Printrun-2.2.0-cp312-cp312-manylinux_2_5_i686.manylinux1_i686.manylinux_2_17_i686.manylinux2014_i686.whl (588.0 kB view hashes)

Uploaded CPython 3.12 manylinux: glibc 2.17+ i686 manylinux: glibc 2.5+ i686

Printrun-2.2.0-cp312-cp312-macosx_11_0_arm64.whl (460.0 kB view hashes)

Uploaded CPython 3.12 macOS 11.0+ ARM64

Printrun-2.2.0-cp312-cp312-macosx_10_13_x86_64.whl (460.1 kB view hashes)

Uploaded CPython 3.12 macOS 10.13+ x86-64

Printrun-2.2.0-cp312-cp312-macosx_10_13_universal2.whl (486.3 kB view hashes)

Uploaded CPython 3.12 macOS 10.13+ universal2 (ARM64, x86-64)

Printrun-2.2.0-cp311-cp311-win_amd64.whl (459.6 kB view hashes)

Uploaded CPython 3.11 Windows x86-64

Printrun-2.2.0-cp311-cp311-win32.whl (455.7 kB view hashes)

Uploaded CPython 3.11 Windows x86

Printrun-2.2.0-cp311-cp311-manylinux_2_17_aarch64.manylinux2014_aarch64.whl (593.8 kB view hashes)

Uploaded CPython 3.11 manylinux: glibc 2.17+ ARM64

Printrun-2.2.0-cp311-cp311-manylinux_2_5_x86_64.manylinux1_x86_64.manylinux_2_17_x86_64.manylinux2014_x86_64.whl (595.2 kB view hashes)

Uploaded CPython 3.11 manylinux: glibc 2.17+ x86-64 manylinux: glibc 2.5+ x86-64

Printrun-2.2.0-cp311-cp311-manylinux_2_5_i686.manylinux1_i686.manylinux_2_17_i686.manylinux2014_i686.whl (582.8 kB view hashes)

Uploaded CPython 3.11 manylinux: glibc 2.17+ i686 manylinux: glibc 2.5+ i686

Printrun-2.2.0-cp311-cp311-macosx_11_0_arm64.whl (459.8 kB view hashes)

Uploaded CPython 3.11 macOS 11.0+ ARM64

Printrun-2.2.0-cp311-cp311-macosx_10_9_x86_64.whl (459.7 kB view hashes)

Uploaded CPython 3.11 macOS 10.9+ x86-64

Printrun-2.2.0-cp311-cp311-macosx_10_9_universal2.whl (485.5 kB view hashes)

Uploaded CPython 3.11 macOS 10.9+ universal2 (ARM64, x86-64)

Printrun-2.2.0-cp310-cp310-win_amd64.whl (459.5 kB view hashes)

Uploaded CPython 3.10 Windows x86-64

Printrun-2.2.0-cp310-cp310-win32.whl (455.9 kB view hashes)

Uploaded CPython 3.10 Windows x86

Printrun-2.2.0-cp310-cp310-manylinux_2_17_aarch64.manylinux2014_aarch64.whl (584.8 kB view hashes)

Uploaded CPython 3.10 manylinux: glibc 2.17+ ARM64

Printrun-2.2.0-cp310-cp310-manylinux_2_5_x86_64.manylinux1_x86_64.manylinux_2_17_x86_64.manylinux2014_x86_64.whl (586.0 kB view hashes)

Uploaded CPython 3.10 manylinux: glibc 2.17+ x86-64 manylinux: glibc 2.5+ x86-64

Printrun-2.2.0-cp310-cp310-manylinux_2_5_i686.manylinux1_i686.manylinux_2_17_i686.manylinux2014_i686.whl (576.2 kB view hashes)

Uploaded CPython 3.10 manylinux: glibc 2.17+ i686 manylinux: glibc 2.5+ i686

Printrun-2.2.0-cp310-cp310-macosx_11_0_arm64.whl (459.9 kB view hashes)

Uploaded CPython 3.10 macOS 11.0+ ARM64

Printrun-2.2.0-cp310-cp310-macosx_10_9_x86_64.whl (459.7 kB view hashes)

Uploaded CPython 3.10 macOS 10.9+ x86-64

Printrun-2.2.0-cp310-cp310-macosx_10_9_universal2.whl (485.6 kB view hashes)

Uploaded CPython 3.10 macOS 10.9+ universal2 (ARM64, x86-64)

Printrun-2.2.0-cp39-cp39-win_amd64.whl (460.0 kB view hashes)

Uploaded CPython 3.9 Windows x86-64

Printrun-2.2.0-cp39-cp39-win32.whl (456.4 kB view hashes)

Uploaded CPython 3.9 Windows x86

Printrun-2.2.0-cp39-cp39-manylinux_2_17_aarch64.manylinux2014_aarch64.whl (588.7 kB view hashes)

Uploaded CPython 3.9 manylinux: glibc 2.17+ ARM64

Printrun-2.2.0-cp39-cp39-manylinux_2_5_x86_64.manylinux1_x86_64.manylinux_2_17_x86_64.manylinux2014_x86_64.whl (589.2 kB view hashes)

Uploaded CPython 3.9 manylinux: glibc 2.17+ x86-64 manylinux: glibc 2.5+ x86-64

Printrun-2.2.0-cp39-cp39-manylinux_2_5_i686.manylinux1_i686.manylinux_2_17_i686.manylinux2014_i686.whl (579.8 kB view hashes)

Uploaded CPython 3.9 manylinux: glibc 2.17+ i686 manylinux: glibc 2.5+ i686

Printrun-2.2.0-cp39-cp39-macosx_11_0_arm64.whl (460.6 kB view hashes)

Uploaded CPython 3.9 macOS 11.0+ ARM64

Printrun-2.2.0-cp39-cp39-macosx_10_9_x86_64.whl (460.4 kB view hashes)

Uploaded CPython 3.9 macOS 10.9+ x86-64

Printrun-2.2.0-cp39-cp39-macosx_10_9_universal2.whl (487.2 kB view hashes)

Uploaded CPython 3.9 macOS 10.9+ universal2 (ARM64, x86-64)

Printrun-2.2.0-cp38-cp38-win_amd64.whl (460.2 kB view hashes)

Uploaded CPython 3.8 Windows x86-64

Printrun-2.2.0-cp38-cp38-win32.whl (391.5 kB view hashes)

Uploaded CPython 3.8 Windows x86

Printrun-2.2.0-cp38-cp38-manylinux_2_17_aarch64.manylinux2014_aarch64.whl (523.0 kB view hashes)

Uploaded CPython 3.8 manylinux: glibc 2.17+ ARM64

Printrun-2.2.0-cp38-cp38-manylinux_2_5_x86_64.manylinux1_x86_64.manylinux_2_17_x86_64.manylinux2014_x86_64.whl (523.4 kB view hashes)

Uploaded CPython 3.8 manylinux: glibc 2.17+ x86-64 manylinux: glibc 2.5+ x86-64

Printrun-2.2.0-cp38-cp38-manylinux_2_5_i686.manylinux1_i686.manylinux_2_17_i686.manylinux2014_i686.whl (514.3 kB view hashes)

Uploaded CPython 3.8 manylinux: glibc 2.17+ i686 manylinux: glibc 2.5+ i686

Printrun-2.2.0-cp38-cp38-macosx_11_0_arm64.whl (460.9 kB view hashes)

Uploaded CPython 3.8 macOS 11.0+ ARM64

Printrun-2.2.0-cp38-cp38-macosx_10_9_x86_64.whl (395.7 kB view hashes)

Uploaded CPython 3.8 macOS 10.9+ x86-64

Printrun-2.2.0-cp38-cp38-macosx_10_9_universal2.whl (487.8 kB view hashes)

Uploaded CPython 3.8 macOS 10.9+ universal2 (ARM64, x86-64)

Supported by

AWS AWS Cloud computing and Security Sponsor Datadog Datadog Monitoring Fastly Fastly CDN Google Google Download Analytics Microsoft Microsoft PSF Sponsor Pingdom Pingdom Monitoring Sentry Sentry Error logging StatusPage StatusPage Status page