Have you ever wondered where your lengthy processing was at, and when would it finish? Do you usually hit RETURN
several times to make sure it didn't crash, or the SSH connection didn't freeze? Have you ever thought it'd be awesome to be able to pause some processing without hassle, return to the Python prompt to manually fix some items, then seamlessly resume it? I did...
I've started this new progress bar thinking about all that, behold the alive-progress! π
Introducing the newest concept in progress bars for Python! alive-progress
is in a class of its own, with an array of cool features that set it apart. Here are a few highlights:
- A mesmerizing live spinner that reacts to your actual processing speed, i.e., it dynamically gets faster or slower with your throughput, and clearly shows a lengthy task is in progress, i.e., did not crash even if taking too long (and your SSH connection did not freeze if remote).
- An efficient multithreaded bar that updates itself at a fraction of the actual processing speed to keep CPU usage low and avoid terminal spamming (1,000,000 iterations per second equates to roughly 60 updates per second), and you can also calibrate it to your liking.
- An accurate ETA (Expected Time of Arrival) with an intelligent Exponential Smoothing Algorithm that shows the time to completion, allowing you to plan your time and manage your workload more effectively.
- Automatic print and logging hooks that provide seamless and efortless integration with any code, even enriching these outputs with the current bar position when they occurred.
- It prints a nice final receipt when your processing ends, including the total items, the elapsed time, and the observed throughput.
- It detects under and overflows, enabling you to track hits, misses, or any desired counts, not necessarily the actually performed iterations.
- You can suspend it! That's right, you heard it here first! No other progress bar anywhere in any language has this feature! You can suspend your processing and get back to the Python prompt, adjust or fix some items, and then get back into the same processing as if it had never stopped!
- It is highly customizable, with a smorgasbord of ready-to-use spinner and bar styles, as well as several factories to easily create yours! There's even a super powerful
check()
tool that helps you design your own animations! You can see how the generated frames and animation cycles will look like, exploded on your screen, and even see it alive before installing inalive-progress
! It's the coolest tool in the world! Unleash your creativity!
This README is always evolving, so do take a more comprehensive look from time to time... You might find great new details in other sections! π
- alive-progress
A very cool update here! In addition to polishing things up and improving terminal support, now alive-progress
supports resuming computations!
When processing huge datasets or things that take a long time, you might either use batches or cache partial results. Then, in case it stops and is restarted, you end up skipping all those already done items very quickly, which makes the alive_bar
think you're processing thousands of items per second, which in turn completely ruins the ETA... But not anymore! Just tell bar()
that you've skipped items... π
You can use it in two ways:
1. If you do know where you've stopped:
with alive_bar(120000) as bar:
bar(60000, skipped=True)
for i in range(60000, 120000):
# process item
bar()
Yep, just call bar(N, skipped=True)
once, with the number of items.
2. If you do not know or the items are scattered:
with alive_bar(120000) as bar:
for i in range(120000):
if done(i):
bar(skipped=True)
continue
# process item
bar()
Yep, it's as simple as that! Just call bar(skipped=True)
when an item is already done, or bar()
as usual otherwise. You could also share a single bar(skipped=?)
call at the end, with a bool saying whether you did skip that item or not. Cool, huh?
Also in this version:
- new
max_cols
config setting, the number of columns to use if not possible to fetch it, like in jupyter and other platforms which doesn't support size - fix fetching the size of the terminal when using stderr
- officially supports Python 3.11
- included ruff linter before building
π NEW in 3.0 series
Yep, I could finally get this version out! These are the new goodies:
- Units support! You can now label the data you're processing, like
B
,bytes
, or evenΒ°C
! - Automatic scaling! With support for SI (base 1000), IEC (base 1024), and even an alternate SI with base 1024, you'll be well served!
- Configurable precision! When your numbers are scaled, you get to choose how many decimals they display!
- Automatic stats scaling for slow throughputs! If your processing takes minutes or more, now you'll see rates per minute, per hour, and even per day! (It works within the auto-scaling system!)
- Support for using
sys.stderr
and other files instead ofsys.stdout
! - Smoothed out the rate estimation with the same Exponential Smoothing Algorithm that powers the ETA, so the bar returns a more realistic ETA!
- Query the currently running widgets' data, like the monitor, rate, and ETA!
- New help system on configuration errors, which explains why a value was not accepted, and what were the expected ones!
Highly anticipated fixes:
- Support for reusing logging handlers! No more
TypeError: unhashable type: 'types.SimpleNamespace'
. - Support for logging when using
RotatingFileHandler
s! Yep, seek support is here. - Fix unknown mode always ending with a warning (!)
And last but not least, a more polished layout for you to enjoy your progress!
π NEW in 2.4 series
Now, alive_bar
supports Dual Line text mode!
If you ever wanted to include longer situational messages within the bar, you probably felt squeezed into one line. You had to shrink the beautifully animated bar or, even worse, remove widgets (!) to be able to see what you needed...
Not anymore!! You can now make the bar Dual Line, and put text below it!
Yes, there's a message below the whole bar, and any other print/logging messages scroll above it!
letters = [chr(ord('A') + x) for x in range(26)]
with alive_bar(26, dual_line=True, title='Alphabet') as bar:
for c in letters:
bar.text = f'-> Teaching the letter: {c}, please wait...'
if c in 'HKWZ':
print(f'fail "{c}", retry later')
time.sleep(0.3)
bar()
on 7: fail "H", retry later
on 10: fail "K", retry later
Alphabet |ββββββββββββββββββββββββββββ | ββ
β 18/26 [69%] in 6s (3.2/s, eta: 3s)
-> Teaching the letter: S, please wait...
There's also a new finalize
function parameter in alive_it
which enables you to set the title and/or text of the final receipt, and improved logging support which detects customized loggers.
π NEW in 2.3 series
This is all about customization; the core widgets can now be changed:
- send a string to the
monitor
,elapsed
, andstats
widgets to make them look anyway you want!
It's incredible that these strings support all Python format features, so you can e.g.,
{percent:.1%}
π.
They can be further customized when on the final receipt!
- new
monitor_end
,elapsed_end
, andstats_end
, with dynamic formats inherited from the standard ones!
If you've hidden some widgets before, just so they wouldn't appear on the receipt, now you can see them in all their running glory, and hide just the receipt ones! Or the other way around π
Another addition, now alive-progress
beautifully renders its cool final receipt whenever it is stopped, even if you CTRL+C it prematurely! I don't know why I haven't thought about that before...
Download |βββββββββββββββββββ οΈ | (!) 45/100 [45%] in 4.8s (9.43/s)
And finally, you can choose to disable CTRL+C at all! The default is the safer ctrl_c=True
, which does make CTRL-C work as usual.
Disable it ctrl_c=False
, to make your interactive alive_bar
much smoother to use (there are no stack traces if you stop it), and/or if it is at the top-level of your program!
Beware: If it is e.g. inside a for-loop, it will just continue to the next iteration, which may or may not be what you want...
for i in range(10):
with alive_bar(100, ctrl_c=False, title=f'Download {i}') as bar:
for i in range(100):
time.sleep(0.02)
bar()
Download 0 |ββββββββββ οΈ | (!) 22/100 [22%] in 0.6s (36.40/s)
Download 1 |ββββββββββββββββββ οΈ | (!) 42/100 [42%] in 1.0s (41.43/s)
Download 2 |ββββββββ οΈ | (!) 16/100 [16%] in 0.4s (39.29/s)
Download 3 |βββββββ οΈ | (!) 14/100 [14%] in 0.4s (33.68/s)
Download 4 |βββββββββββββββ οΈ | (!) 33/100 [33%] in 0.8s (39.48/s)
Download 5 |βββββββββ οΈ | (!) 18/100 [18%] in 0.5s (37.69/s)
Download 6 |βββββββ οΈ | (!) 13/100 [13%] in 0.3s (37.28/s)
Download 7 |βββββββββββββ οΈ | (!) 30/100 [30%] in 0.8s (38.43/s)
Download 8 |βββββββ οΈ | (!) 15/100 [15%] in 0.4s (36.26/s)
...
π NEW in 2.2 series
Some major new features, often requested, have finally landed!
- bar title can be dynamically set, changed, or even removed after being displayed
- new custom fps system, which enables very slow refresh rates (to let it run on those k8s for long periods)
- the final receipt can be totally hidden (great for special effects, like using the cool spinners standalone)
- new support for
click.echo()
printing - terminal columns detection is safer for exotic environments
- requires Python 3.7+
π NEW in 2.1 series
YES! Now alive-progress
has support for Jupyter Notebooks and also includes a Disabled state! Both were highly sought after, and have finally landed!
And better, I've implemented an auto-detection mechanism for jupyter notebooks, so it just works, out of the box, without any changes in your code!!
See for yourself:
It seems to work very well, but at this moment, it should be considered experimental.
There were instances in which some visual glitches have appeared, like twoalive_bar
refreshes being concatenated together instead of over one another... And it's something I think I can't possibly work around: it seems Jupyter sometimes refresh the canvas at odd times, which makes it lose some data. Please let me know on the issues if something funnier arises.
π NEW in 2.0 series
This is a major breakthrough in alive-progress
!
I took 1 year developing it, and I'm very proud of what I've accomplished \o/
- now, there's complete support for Emojis π€© and exotic Unicode chars in general, which required MAJOR refactoring deep within the project, giving rise to what I called "Cell Architecture" => now, all internal components use and generate streams of cells instead of characters, and correctly interpret grapheme clusters β those so-called wide chars, which are encoded with a variable number of chars, but always take two cells on screen!! This has enabled us to render complex multi-chars symbols as if they were one, thus making them work on any spinners, bars, texts, borders and backgrounds, even when fractured!!! Pretty advanced stuff π€
- new super cool spinner compiler and runner, which generates complete animations ahead of time, and plays these ready-to-go animations seamlessly, with no overhead at all! π
- the spinner compiler also includes advanced extra commands to generate and modify animations, like reshape, replace, transpose, or randomize the animation cycles!
- new powerful and polished
.check()
tools that compile and beautifully render all frames from all animation cycles of spinners and bars! they can even include complete frame data, internal codepoints, and even their animations! π - bars engine revamp, with invisible fills, advanced support for multi-char tips (which gradually enter and leave the bar), borders, tips and errors of any length, and underflow errors that can leap into the border if they can't fit!
- spinners engine revamp, with standardized factory signatures, improved performance, new types, and new features: smoother bouncing spinners (with an additional frame at the edges), optimized scrolling of text messages (which go slower and pause for a moment at the edges), new alongside and sequential spinners, nicer effect in alongside spinners (which use weighted spreading over the available space), smoother animation in scrolling spinners (when the input is longer than the available space)
- new builtin spinners, bars, and themes, which make use of the new animation features
- new showtime that displays themes and is dynamic => it does not scroll the screen when it can't fit vertically or horizontally, and can even filter for patterns!
- improved support for logging into files, which gets enriched as the print hook is!
- several new configuration options for customizing appearance, including support for disabling any
alive-progress
widgets! - includes a new iterator adapter,
alive_it
, that accepts an iterable and callsbar()
for you! - requires Python 3.6+ (and officially supports Python 3.9 and 3.10)
Since this is a major version change, direct backward compatibility is not guaranteed. If something does not work at first, just check the new imports and functions' signatures, and you should be good to go. All previous features should still work here! π
Just install with pip:
β― pip install alive-progress
If you're wondering what styles are builtin, it's showtime
! ;)
from alive_progress.styles import showtime
showtime()
Note: Please disregard the path in the animated gif below, the correct one is above. These long gifs are very time-consuming to generate, so I can't make another on every single change. Thanks for your understanding.
I've made these styles just to try all the animation factories I've created, but I think some of them ended up very, very cool! Use them at will, and mix them to your heart's content!
Do you want to see actual alive-progress
bars gloriously running in your system before trying them yourself?
β― python -m alive_progress.tools.demo
Cool, huh?? Now enter an ipython
REPL and try this:
from alive_progress import alive_bar
import time
for x in 1000, 1500, 700, 0:
with alive_bar(x) as bar:
for i in range(1000):
time.sleep(.005)
bar()
You'll see something like this, with cool animations throughout the process π:
|ββββββββββββββββββββββββββββββββββββββββ| 1000/1000 [100%] in 5.8s (171.62/s)
|ββββββββββββββββββββββββββββ οΈ | (!) 1000/1500 [67%] in 5.8s (172.62/s)
|βββββββββββββββββββββββββββββββββββββββββοΈ (!) 1000/700 [143%] in 5.8s (172.06/s)
|ββββββββββββββββββββββββββββββββββββββββ| 1000 in 5.8s (172.45/s)
Nice, huh? Loved it? I knew you would, thank you π.
To actually use it, just wrap your normal loop in an alive_bar
context manager like this:
with alive_bar(total) as bar: # declare your expected total
for item in items: # <<-- your original loop
print(item) # process each item
bar() # call `bar()` at the end
And it's alive! π
So, in short: retrieve the items as always, enter the alive_bar
context manager with the number of items, and then iterate/process those items, calling bar()
at the end! It's that simple! :)
items
can be any iterable, like for example, a queryset;- the first argument of the
alive_bar
is the expected total, likeqs.count()
for querysets,len(items)
for iterables with length, or even a static number; - the call
bar()
is what makes the bar go forward β you usually call it in every iteration, just after finishing an item; - if you call
bar()
too much (or too few at the end), the bar will graphically render that deviation from the expectedtotal
, making it very easy to notice overflows and underflows; - to retrieve the current bar count or percentage, call
bar.current
.
You can get creative! Since the bar only goes forward when you call
bar()
, it is independent of the loop! So you can use it to monitor anything you want, like pending transactions, broken items, etc., or even call it more than once in the same iteration! So, in the end, you'll get to know how many of those "special" events there were, including their percentage relative to the total!
While inside an alive_bar
context, you can effortlessly display messages tightly integrated with the current progress bar being displayed! It won't break in any way and will even enrich your message!
- the cool
bar.text('message')
andbar.text = 'message'
set a situational message right within the bar, where you can display something about the current item or the phase the processing is in; - the (π new) dynamic title, which can be set right at the start, but also be changed anytime with
bar.title('Title')
andbar.title = 'Title'
β mix withtitle_length
to keep the bar from changing its length; - the usual Python
print()
statement, wherealive_bar
nicely cleans up the line, prints your message alongside the current bar position at the time, and continues the bar right below it; - the standard Python
logging
framework, including file outputs, is also enriched exactly like the previous one; - if you're using click CLI lib, you can even use
click.echo()
to print styled text.
Awesome right? And all of these work just the same in a terminal or in a Jupyter notebook!
You now have a quicker way to monitor anything! Here, the items are automatically tracked for you!
Behold the alive_it
=> the alive_bar
iterator adapter!
Simply wrap your items with it, and loop over them as usual!
The bar will just work; it's that simple!
from alive_progress import alive_it
for item in alive_it(items): # <<-- wrapped items
print(item) # process each item
HOW COOL IS THAT?! π
All alive_bar
parameters apply but total
, which is smarter (if not supplied, it will be auto-inferred from your data using len
or length_hint
), and manual
that does not make sense here.
Note there isn't any bar
handle at all in there. But what if you do want it, e.g. to set text messages or retrieve the current progress?
You can interact with the internal alive_bar
by just assigning alive_it
to a variable like this:
bar = alive_it(items) # <<-- bar with wrapped items
for item in bar: # <<-- iterate on bar
print(item) # process each item
bar.text(f'ok: {item}') # WOW, it works!
Note that this is a slightly special bar
, which does not support bar()
, since the iterator adapter tracks items automatically for you. Also, it supports finalize
, which enables you to set the title and/or text of the final receipt:
alive_it(items, finalize=lambda bar: bar.text('Success!'))
...
In a nutshell:
- full use is always
with alive_bar() as bar
, where you iterate and callbar()
whenever you want;- quick adapter use is
for item in alive_it(items)
, where items are automatically tracked;- full adapter use is
bar = alive_it(items)
, where in addition to items being automatically tracked, you get a special iterablebar
able to customize the inneralive_progress
however you want.
Actually, the total
argument is optional. If you do provide it, the bar enters in definite mode, the one used for well-bounded tasks. This mode has all the widgets alive-progress
has to offer: progress, count, throughput, and ETA.
If you don't, the bar enters in unknown mode, the one used for unbounded tasks. In this mode, the whole progress bar is animated, as it's not possible to determine the progress, and therefore the ETA. But you still get the count and throughput widgets as usual.
The cool spinner is still present here alongside the progress bar, both running their animations concurrently and independently of each other, rendering a unique show in your terminal! π
Both definite and unknown modes use internally a counter to maintain progress. This is the source value which all widgets are derived from.
On the other hand, the manual mode uses internally a percentage to maintain progress. This enables you to get complete control of the bar position! It's usually used to monitor processes that only feed you the percentage of completion, or to generate some kind of special effects.
To use it, just include a manual=True
argument into alive_bar
(or config_handler
), and you get to send any percentage to the bar()
handler! For example, to set it to 15%, just call bar(0.15)
β which is 15 / 100.
You can also use total
here! If you do provide it, alive-progress
will infer an internal counter by itself, and thus will be able to offer you the same count, throughput, and ETA widgets!
If you don't, you'll at least get rough versions of the throughput and ETA widgets. The throughput will use "%/s" (percent per second), and the ETA will be till 1.0 (100%). Both are very inaccurate but better than nothing.
You can call bar
in manual mode as frequently as you want! The refresh rate will still be asynchronously computed as usual, according to the current progress and the elapsed time, so you won't ever spam the terminal with more updates than it can handle.
When total
is provided all is cool:
mode | counter | percentage | throughput | ETA | over/underflow |
---|---|---|---|---|---|
definite | β (user tick) | β (inferred) | β | β | β |
manual | β (inferred) | β (user set) | β | β | β |
When it isn't, some compromises have to be made:
mode | counter | percentage | throughput | ETA | over/underflow |
---|---|---|---|---|---|
unknown | β (user tick) | β | β | β | β |
manual | β | β (user set) | β |
But actually it's quite simple, you do not need to think about which mode you should use:
Just always send the total
if you have it, and use manual
if you need it!
It will just work the best it can! π \o/
The bar()
handlers support either relative or absolute semantics, depending on the mode:
- definite and unknown modes use relative positioning, so you can just call
bar()
to increment the counter by one, or send any other positive increment likebar(5)
to increment by those at once; - manual modes use absolute positioning, so you can just call
bar(0.35)
to instantly put the bar in 35% position β this argument is mandatory here!
The manual modes enable you to get super creative! Since you can set the bar instantly to whatever position you want, you could:
- make it go backwards β perhaps to graphically display the timeout of something;
- create special effects β perhaps to act as a real-time gauge of some sort.
In any case, to retrieve the current count/percentage, just call: bar.current
:
- in definite and unknown modes, this provides an integer β the actual internal counter;
- in manual modes, this provides a float in the interval [0, 1] β the last percentage set.
Last but not least, the bar()
handler of the definite mode has a unique ability: skipping items for an accurate ETA! Just call bar(skipped=False)
or bar(skipped=True)
to use it. When skipped is True, that item(s) are ignored when computing the rate, and thus not ruining the ETA.
Maintaining an open source project is hard and time-consuming, and I've put much β€οΈ and effort into this.
If you've appreciated my work, you can back me up with a donation! Thank you π
The showtime
exhibit has an optional argument to choose which show to present, Show.SPINNERS
(default), Show.BARS
or Show.THEMES
, do take a look at them! ;)
from alive_progress.styles import showtime, Show
Note: Please disregard the path in the animated gif below, the correct one is above. These long gifs are very time-consuming to generate, so I can't make another on every single change. Thanks for your understanding.
And the themes one (π new in 2.0):
The showtime
exhibit also accepts some customization options:
- fps: the frames per second rate refresh rate, default is 15;
- length: the length of the bars, default is 40;
- pattern: a filter to choose which ones to display.
For example to get a marine show, you can showtime(pattern='boat|fish|crab')
:
You can also access these shows with the shorthands
show_bars()
,show_spinners()
, andshow_themes()
!
There's also a small utility called
print_chars()
, to help find that cool character to put in your customized spinners and bars, or to determine if your terminal does support Unicode characters.
There are several options to customize both appearance and behavior!
All of them can be set both directly in the alive_bar
or globally in the config_handler
!
These are the options - default values in brackets:
title
: an optional, always visible bar titlelength
: [40
] the number of cols to render the animated progress barmax_cols
: [80
] the maximum cols to use if not possible to fetch it, like in jupyterspinner
: the spinner style to be rendered next to the bar
β³ accepts a predefined spinner name, a custom spinner factory, or Nonebar
: the bar style to be rendered in known modes
β³ accepts a predefined bar name, a custom bar factory, or Noneunknown
: the bar style to be rendered in the unknown mode
β³ accepts a predefined spinner name, or a custom spinner factory (cannot be None)theme
: ['smooth'
] a set of matching spinner, bar, and unknown
β³ accepts a predefined theme nameforce_tty
: [None
] forces animations to be on, off, or according to the tty (more details here)
β³ None -> auto select, according to the terminal/Jupyter
β³ True -> unconditionally enables animations, but still auto-detects Jupyter Notebooks
β³ False -> unconditionally disables animations, keeping only the final receiptfile
: [sys.stdout
] the file object to use:sys.stdout
,sys.stderr
, or a similarTextIOWrapper
disable
: [False
] if True, completely disables all output, do not install hooksmanual
: [False
] set to manually control the bar positionenrich_print
: [True
] enriches print() and logging messages with the bar positionreceipt
: [True
] prints the nice final receipt, disables if Falsereceipt_text
: [False
] set to repeat the last text message in the final receiptmonitor
(bool|str): [True
] configures the monitor widget152/200 [76%]
β³ send a string with{count}
,{total}
and{percent}
to customize itelapsed
(bool|str): [True
] configures the elapsed time widgetin 12s
β³ send a string with{elapsed}
to customize itstats
(bool|str): [True
] configures the stats widget(123.4/s, eta: 12s)
β³ send a string with{rate}
and{eta}
to customize itmonitor_end
(bool|str): [True
] configures the monitor widget within final receipt
β³ same as monitor, the default format is dynamic, it inheritsmonitor
's oneelapsed_end
(bool|str): [True
] configures the elapsed time widget within final receipt
β³ same as elapsed, the default format is dynamic, it inheritselapsed
's onestats_end
(bool|str): [True
] configures the stats widget within final receipt
β³ send a string with{rate}
to customize it (no relation to stats)title_length
: [0
] fixes the length of titles, or 0 for unlimited
β³ title will be truncated if longer, and a cool ellipsis "β¦" will appear at the endspinner_length
: [0
] forces the spinner length, or0
for its natural onerefresh_secs
: [0
] forces the refresh period to this,0
is the reactive visual feedbackctrl_c
: [True
] if False, disables CTRL+C (captures it)dual_line
: [False
] if True, places the text below the barunit
: any text that labels your entitiesscale
: the scaling to apply to units:None
,SI
,IEC
, orSI2
β³ supports aliases:False
or''
->None
,True
->SI
,10
or'10'
->SI
,2
or'2'
->IEC
precision
: [1
] how many decimals do display when scaling
And there's also one that can only be set locally in an alive_bar
context:
calibrate
: maximum theoretical throughput to calibrate the animation speed (more details here)
To set them locally, just send them as keyword arguments to alive_bar
:
with alive_bar(total, title='Processing', length=20, bar='halloween') as bar:
...
To use them globally, send them to config_handler
, and any alive_bar
created after that will include those options! And you can mix and match them, local options always have precedence over global ones:
from alive_progress import config_handler
config_handler.set_global(length=20, spinner='wait')
with alive_bar(total, bar='blocks', spinner='twirls') as bar:
# the length is 20, the bar is 'blocks' and the spinner is 'twirls'.
...
Yes, you can assemble your own spinners! And it's easy!
I've created a plethora of special effects, so you can just mix and match them any way you want! There are frames, scrolling, bouncing, sequential, alongside, and delayed spinners! Get creative! π
The spinners' animations are engineered by very advanced generator expressions, deep within several layers of meta factories, factories and generators π€―!
- the meta factory (public interface) receives the styling parameters from you, the user, and processes/stores them inside a closure to create the actual factory => this is the object you'll send to both
alive_bar
andconfig_handler
; - internally it still receives other operating parameters (like for instance the rendition length), to assemble the actual generator expression of the animation cycles of some effect, within yet another closure;
- this, for each cycle, assembles another generator expression for the animation frames of the same effect;
- these generators together finally produce the streams of cycles and frames of the cool animations we see on the screen! Wow! ππ
These generators are capable of multiple different animation cycles according to the spinner behavior, e.g. a bouncing spinner can run one cycle to smoothly bring a subject into the scene, then repeatedly reposition it until the other side, then make it smoothly disappear off the scene => and this is all only one cycle! Then it can be followed by another cycle to make it all again but backwards! And bouncing spinners also accept different and alternating patterns in both the right and left directions, which makes them generate the cartesian product of all the combinations, possibly producing dozens of different cycles until they start repeating them!! π€―
And there's more, I think one of the most impressive achievements I got in this animation system (besides the spinner compiler itself)... They only yield more animation frames until the current cycle is not exhausted, then they halt themselves! Yep, the next cycle does not start just yet! This behavior creates natural breaks in exactly the correct spots, where the animations are not disrupted, so I can smoothly link with whatever other animation I want!!
This has all kinds of cool implications: the cycles can have different frame counts, different screen lengths, they do not need to be synchronized, they can create long different sequences by themselves, they can cooperate to play cycles in sequence or alongside, and I can amaze you displaying several totally distinct animations at the same time without any interferences whatsoever!
It's almost like they were... alive!! π
==> Yes, that's where this project's name came from! π
Now, these generators of cycles and frames are fully consumed ahead of time by the Spinner Compiler! This is a very cool new processor that I made inside the Cell Architecture effort, to make all these animations work even in the presence of wide chars or complex grapheme clusters! It was very hard to make these clusters gradually enter and exit frames, smoothly, while keeping them from breaking the Unicode encoding and especially maintain their original lengths in all frames! Yes, several chars in sequence can represent another completely different symbol, so they cannot ever be split! They have to enter and exit the frame always together, all at once, or the grapheme won't show up at all (an Emoji for instance)!! Enter the Spinner Compiler......
This has made possible some incredible things!! Since this Compiler generates the whole spinner frame data beforehand:
- the grapheme fixes can be applied only once;
- the animations do not need to be calculated again!
So, I can just collect all that ready to play animations and be done with it, no runtime overhead at all!! π
Also, with the complete frame data compiled and persisted, I could create several commands to refactor that data, like changing shapes, replacing chars, adding visual pauses (frame repetitions), generating bouncing effects on-demand over any content, and even transposing cycles with frames!!
But how can you see these effects? Does the effect you created look good? Or is it not working as you thought? YES, now you can see all generated cycles and frames analytically, in a very beautiful rendition!!
I love what I've achieved here π, it's probably THE most beautiful tool I've ever created... Behold the check
tool!!
It's awesome if I say so myself, isn't it? And a very complex piece of software I'm proud of, take a look at its code if you'd like.
And the check
tool is much more powerful! For instance, you can see the codepoints of the frames!!! And maybe have a glimpse of why this version was so, so very hard and complex to make...
In red, you see the grapheme clusters, that occupy one or two "logical positions", regardless of their actual sizes... These are the "Cells" of the new Cell Architecture...
Look how awesome an Emoji Flag is represented:
The flag seems to move so smoothly because it uses "half-characters"! Since it is a wide char, alive-progress
knows it will be rendered with "two visible chars", and the animations consider this, but compose with spaces, which occupy only one. When one uses mixed backgrounds, the situation is much more complex...
The types of factories I've created are:
frames
: draws any sequence of characters at will, that will be played frame by frame in sequence;scrolling
: generates a smooth flow from one side to the other, hiding behind or wrapping upon invisible borders β allows using subjects one at a time, generating several cycles of distinct characters;bouncing
: similar toscrolling
, but makes the animations bounce back to the start, hiding behind or immediately bouncing upon invisible borders;sequential
get a handful of factories and play them one after the other sequentially! allows to intermix them or not;alongside
get a handful of factories and play them alongside simultaneously, why choose when you can have them all?! allows to choose the pivot of the animation;delayed
: get any other factory and copy it multiple times, increasingly skipping some frames on each one! very cool effects are made here!
For more details please look at their docstrings, which are very complete.
Customizing bars is nowhere near that involved. Let's say they are "immediate", passive objects. They do not support animations, i.e. they will always generate the same rendition given the same parameters. Remember spinners are infinite generators, capable of generating long and complex sequences.
Well, bars also have a meta factory, use closures to store the styling parameters, and receive additional operating parameters, but then the actual factory can't generate any content by itself. It still needs an extra parameter, a floating-point number between 0 and 1, which is the percentage to render itself.
alive_bar
calculates this percentage automatically based on the counter and total, but you can send it yourself when in themanual
mode!
Bars also do not have a Bar Compiler, but they do provide the check tool!! π
You can even mix and match wide chars and normal chars just like in spinners! (and everything keeps perfectly aligned π )
Use the check tools to your heart's content!! They have even more goodies awaiting you, even real-time animations!
Create the wildest and coolest animations you can and send them to me!
I'm thinking about creating some kind ofcontrib
package, with user-contributed spinners and bars!
Wow, if you've read everything till here, you should now have a sound knowledge about using alive-progress
! π
But brace yourself because there is even more, exciting stuff lies ahead!
Maintaining an open source project is hard and time-consuming, and I've put much β€οΈ and effort into this.
If you've appreciated my work, you can back me up with a donation! Thank you π
Oh, you want to pause it altogether, I hear? This is an amazing novel concept, not found anywhere AFAIK.
With this you get to act on some items manually, at will, right in the middle of an ongoing processing!!
YES, you can return to the prompt and fix, change, submit things, and the bar will just "remember" where it was...
Suppose you need to reconcile payment transactions (been there, done that). You need to iterate over thousands of them, detect somehow the faulty ones, and fix them. This fix is not simple nor deterministic, you need to study each one to understand what to do. They could be missing a recipient, or have the wrong amount, or not be synced with the server, etc., it's hard to even imagine all possibilities.
Typically, you would have to let the detection process run until completion, appending to a list each inconsistency it finds and waiting, potentially a long time, until you can finally start fixing them... You could of course mitigate that by processing in chunks, or printing them and acting via another shell, etc., but those have their own shortcomings... π
Now, there's a better way! Simply pause the actual detection process for a while! Then you just have to wait till the next fault is found, and act in near real-time!
To use the pause mechanism you just have to write a function, so the code can yield
the items you want to interact with. You most probably already use one in your code, but in the ipython
shell or another REPL you probably don't. So just wrap your debug code in a function, then enter within a bar.pause()
context!!
def reconcile_transactions():
qs = Transaction.objects.filter() # django example, or in sqlalchemy: session.query(Transaction).filter()
with alive_bar(qs.count()) as bar:
for transaction in qs:
if faulty(transaction):
with bar.pause():
yield transaction
bar()
That's it! It's that simple! \o/
Now run gen = reconcile_transactions()
to instantiate the generator, and whenever you want the next faulty transaction, just call next(gen, None)
! I love it...
The alive-progress
bar will start and run as usual, but as soon as any inconsistency is found, the bar will pause itself, turning off the refresh thread and remembering its exact state, and yield the transaction to you directly on the prompt! It's almost magic! π
In [11]: gen = reconcile_transactions()
In [12]: next(gen, None)
|βββββββββββββββββββββ | 105/200 [52%] in 5s (18.8/s, eta: 4s)
Out[12]: Transaction<#123>
You can then inspect the transaction with the usual _
shortcut of ipython
(or just directly assign it with t = next(gen, None)
), and you're all set to fix it!
When you're done, just reactivate the bar with the same next
call as before!! The bar reappears, turns everything back on, and continues like it had never stopped!! Ok, it is magic π
In [21]: next(gen, None)
|βββββββββββββββββββββ | βββ
106/200 [52%] in 5s (18.8/s, eta: 4s)
Rinse and repeat till the final receipt appears, and there'll be no faulty transactions anymore. π
So, you need to monitor a fixed operation, without any loops, right?
It'll work for sure! Here is a naive example (we'll do better in a moment):
with alive_bar(4) as bar:
corpus = read_file(file)
bar() # file was read, tokenizing
tokens = tokenize(corpus)
bar() # tokens generated, processing
data = process(tokens)
bar() # process finished, sending response
resp = send(data)
bar() # we're done! four bar calls with `total=4`
It's naive because it assumes all steps take the same amount of time, but actually, each one may take a very different time to complete. Think read_file
and tokenize
may be extremely fast, which makes the percentage skyrocket to 50%, then stopping for a long time in the process
step... You get the point, it can ruin the user experience and create a very misleading ETA.
To improve upon that you need to distribute the steps' percentages accordingly! Since you told alive_bar
there were four steps, when the first one was completed it understood 1/4 or 25% of the whole processing was complete... Thus, you need to measure how long your steps actually take and use the manual mode to increase the bar percentage by the right amount at each step!
You can use my other open source project about-time to easily measure these durations! Just try to simulate with some representative inputs, to get better results. Something like:
from about_time import about_time
with about_time() as t_total: # this about_time will measure the whole time of the block.
with about_time() as t1 # the other four will get the relative timings within the whole.
corpus = read_file(file) # `about_time` supports several calling conventions, including one-liners.
with about_time() as t2 # see its documentation for more details.
tokens = tokenize(corpus)
with about_time() as t3
data = process(tokens)
with about_time() as t4
resp = send(data)
print(f'percentage1 = {t1.duration / t_total.duration}')
print(f'percentage2 = {t2.duration / t_total.duration}')
print(f'percentage3 = {t3.duration / t_total.duration}')
print(f'percentage4 = {t4.duration / t_total.duration}')
There you go! Now you know the relative timings of all the steps, and can use them to improve your original code! Just get the cumulative timings and put them within a manual mode alive_bar
!
For example, if the timings you found were 10%, 30%, 20%, and 40%, you'd use 0.1, 0.4, 0.6, and 1.0 (the last one should always be 1.0):
with alive_bar(4, manual=True) as bar:
corpus = read_big_file()
bar(0.1) # 10%
tokens = tokenize(corpus)
bar(0.4) # 30% + 10% from previous steps
data = process(tokens)
bar(0.6) # 20% + 40% from previous steps
resp = send(data)
bar(1.) # always 1. in the last step
That's it! The user experience and ETA should be greatly improved now.
So, you want to calibrate the engine?
The alive-progress
bars have cool visual feedback of the current throughput, so you can actually see how fast your processing is, as the spinner runs faster or slower with it.
For this to happen, I've put together and implemented a few fps curves to empirically find which one gave the best feel of speed:
(interactive version [here](https://www.desmos.com/calculator/ema05elsux))
The graph shows the logarithmic (red), parabolic (blue) and linear (green) curves, these are the ones I started with. It was not an easy task, I've made dozens of tests, and never found one that really inspired that feel of speed I was looking for. The best one seemed to be the logarithmic one, but it reacted poorly with small numbers. I know I could make it work with a few twists for those small numbers, so I experimented a lot and adjusted the logarithmic curve (dotted orange) until I finally found the behavior I expected! It is the one that seemed to provide the best all-around perceived speed changes throughout the whole spectrum from a few to billions... That is the curve I've settled with, and it's the one used in all modes and conditions. In the future and if someone would find it useful, that curve could be configurable.
Well, the default alive-progress
calibration is 1,000,000 in bounded modes, i.e., it takes 1 million iterations per second for the bar to refresh itself at 60 frames per second. In the manual unbounded mode, it is 1.0 (100%). Both enable a vast operating range and generally work quite well.
For example, take a look at the effect these very different calibrations have, running the very same code at the very same speed! Notice the feel the spinner passes to the user, is this processing going slow or going fast? And remember that isn't only the spinner refreshing but the whole line, complete with the bar rendition and all widgets, so everything gets smoother or sluggish:
So, if your processing hardly gets to 20 items per second, and you think
alive-progress
is rendering sluggish, you could increase that sense of speed by calibrating it to let's say40
, and it will be running waaaay faster... It is better to always leave some headroom and calibrate it to something between 50% and 100% more, and then tweak it from there to find the one you like the most! :)
Do these astonishing alive-progress
animations refuse to display?
PyCharm is awesome, I love it! But I'll never understand why they've disabled emulating a terminal by default... If you do use PyCharm's output console, please enable this on all your Run Configurations:
I even recommend you go into
File
>New Projects Setup
>Run Configuration Templates
, selectPython
, and also enable it there, so any new ones you create will already have this set.
In addition to that, some terminals report themselves as "non-interactive", like when running out of a real terminal (PyCharm and Jupyter for example), in shell pipelines (cat file.txt | python program.py
), or in background processes (not connected to a tty).
When alive-progress
finds itself in a non-interactive terminal, it automatically disables all kinds of animations, printing only the final receipt. This is made in order to avoid both messing up the pipeline output and spamming your log file with thousands of alive-progress
refreshes.
So, when you know it's safe, you can force them to see alive-progress
in all its glory! Here is the force_tty
argument:
with alive_bar(1000, force_tty=True) as bar:
for i in range(1000):
time.sleep(.01)
bar()
The values accepted are:
force_tty=True
-> always enables animations, and auto-detects Jupyter Notebooks!force_tty=False
-> always disables animations, keeping only the final receiptforce_tty=None
(default) -> auto detect, according to the terminal's tty state
You can also set it system-wide using config_handler
, so you don't need to pass it manually anymore.
Do note that PyCharm's console and Jupyter notebooks are heavily instrumented and thus have much more overhead, so the outcome may not be as fluid as you would expect. On top of that, Jupyter notebooks do not support ANSI Escape Codes, so I had to develop some workarounds to emulate functions like "clear the line" and "clear from cursor"... To see the fluid and smooth
alive_bar
animations as I intended, always prefer a full-fledged terminal.
- This whole project was implemented in functional style;
- It uses extensively (and very creatively) Python Closures and Generators, e.g. all spinners are made with cool Generator Expressions! Besides it, there are other cool examples like the exhibit module, and the core spinner player/spinner runner generators; π
- Until 2.0,
alive-progress
hadn't had any dependency. Now it has two: one is about-time (another very cool project of mine if I say so myself), to track the spinner compilation times and generate its human-friendly renditions. The other is grapheme, to detect grapheme cluster breaks (I've opened an issue there asking about the future and correctness of it, and the author guarantees he intends to update the project on every new Unicode version); - Also, until 2.0
alive-progress
hadn't had a single Python class! Now it has a few tiny ones for very specific reasons (change callables, iterator adapter, and some descriptors for the widgets).
Everything else is a function, which generates other functions internally with some state on the parent, i.e. Closures. I've used them to create spinner factories, bar factories, the global configuration, the system hooks, the spinner compiler (which is also a big Function Decorator), evenalive_bar
itself is a function! And in the latter mostly, I dynamically plug several other functions into the main one (Python functions have a__dict__
just like classes do). π
- enable multiple simultaneous bars for nested or multiple activities (the most requested, but very complex)
- reset a running bar context, i.e. run in unknown mode while "quantifying" then switch to definite mode
- dynamic bar width rendition, which notices terminal size changes and shrink or expand the bar as needed (currently
alive_bar
does notice terminal size changes, but just truncates the line accordingly) - improve test coverage, currently at
7789% branch coverage (but it's very hard since it's multithreaded, full of stateful closures, and includes system print hooks) - create a
contrib
system somehow, to allow a simple way to share cool spinners and bars from users - support colors in spinners and bars (it's very hard, since color codes alter string sizes, which makes it tricky to synchronize animations, besides correctly slicing, reversing, and iterating fragments of strings while also maintaining color codes is very, very complex)
- update here: this may be much simpler now with the new Cell Architecture!
- any other ideas are welcome!
Noteworthy features already done β
- resuming computations support with
skipped
items - help system on configuration errors
- readable widgets to extract information
- exponential smoothing algorithm for the rate
- support for using
stderr
and other files instead ofstdout
- units with automatic scaling
- dual-line mode
- customize final receipt widgets
- customize widgets rendition like
monitor
,elapsed
,stats
- bar title can be dynamically set, changed or removed
- exponential smoothing algorithm for the ETA
- jupyter notebook support, which works the same as in the terminal, animations and everything
- create an unknown mode for bars (without a known total and eta)
- implement a pausing mechanism
- change spinner styles
- change bar styles
- include a global configuration system
- create customizable generators for scrolling, bouncing, delayed, and compound spinners
- create an exhibition for spinners and bars, to see them all in motion
- include theme support in configuration
- soft wrapping support
- hiding cursor support
- Python logging support
- exponential smoothing of ETA time series
- create an exhibition for themes
Changelog highlights
Complete here.
- 3.1.4: support spaces at the start and end of titles and units
- 3.1.3: better error handling of invalid
alive_it
calls, detect nested uses of alive_progress and throw a clearer error message - 3.1.2: fix some exotic ANSI Escape Codes not being printed (OSC)
- 3.1.1: support for printing ANSI Escape Codes without extra newlines, typing annotations in
alive_it
- 3.1.0: new resuming computations support with
skipped
items, newmax_cols
config setting for jupyter, fix fetching the size of the terminal when using stderr, officially supports Python 3.11 - 3.0.1: fix for logging streams that extend StreamHandler but doesn't allow changing streams
- 3.0.0: units support with automatic and configurable scaling and precision, automatic stats scaling for slow throughputs, support for using
sys.stderr
and other files instead ofsys.stdout
, smoothed out the rate estimation, more queries into the currently running widgets' data, help system in configuration errors - 2.4.1: fix a crash when dual-line and disabled are set
- 2.4.0: support dual line text mode; finalize function parameter in alive_it; improve logging support, detecting customized ones
- 2.3.1: introduce ctrl_c config param; print the final receipt even when interrupted
- 2.3.0: customizable
monitor
,elapsed
, andstats
core widgets, newmonitor_end
,elapsed_end
, andstats_end
core widgets, better support for CTRL+C, which makesalive_bar
stop prematurely - 2.2.0: bar title can be dynamically set, changed or removed; customizable refresh rates; final receipt can be hidden;
click.echo()
support; faster performance; safer detection of terminal columns;bar.current
acts like a property; remove Python 3.6 - 2.1.0: Jupyter notebook support (experimental), Jupyter auto-detection, disable feature and configuration
- 2.0.0: new system-wide Cell Architecture with grapheme clusters support; super cool spinner compiler and runner;
.check()
tools in both spinners and bars; bars and spinners engines revamp; new animation modes in alongside and sequential spinners; new builtin spinners, bars, and themes; dynamic showtime with themes, scroll protection and filter patterns; improved logging for files; several new configuration options for customizing appearance; new iterator adapteralive_it
; usestime.perf_counter()
high-resolution clock; requires Python 3.6+ (and officially supports Python 3.9 and 3.10) - 1.6.2: new
bar.current()
method; newlines get printed on vanilla Python REPL; the bar is truncated to 80 chars on Windows - 1.6.1: fix logging support for Python 3.6 and lower; support logging for file; support for wide Unicode chars, which use 2 columns but have length 1
- 1.6.0: soft wrapping support; hiding cursor support; Python logging support; exponential smoothing of ETA time series; proper bar title, always visible; enhanced times representation; new
bar.text()
method, to set situational messages at any time, without incrementing position (deprecates 'text' parameter inbar()
); performance optimizations - 1.5.1: fix compatibility with Python 2.7 (should be the last one, version 2 is in the works, with Python 3 support only)
- 1.5.0: standard_bar accepts a
background
parameter instead ofblank
, which accepts arbitrarily sized strings and remains fixed in the background, simulating a bar going "over it" - 1.4.4: restructure internal packages; 100% branch coverage of all animations systems, i.e., bars and spinners
- 1.4.3: protect configuration system against other errors (length='a' for example); first automated tests, 100% branch coverage of configuration system
- 1.4.2: sanitize text input, keeping \n from entering and replicating bar on the screen
- 1.4.1: include license file in the source distribution
- 1.4.0: print() enrichment can now be disabled (locally and globally), exhibits now have a real-time fps indicator, new exhibit functions
show_spinners
andshow_bars
, new utilityprint_chars
,show_bars
gain some advanced demonstrations (try it again!) - 1.3.3: further improve stream compatibility with isatty
- 1.3.2: beautifully finalize bar in case of unexpected errors
- 1.3.1: fix a subtle race condition that could leave artifacts if ended very fast, flush print buffer when position changes or bar terminates, keep the total argument from unexpected types
- 1.3.0: new fps calibration system, support force_tty and manual options in global configuration, multiple increment support in bar handler
- 1.2.0: filled blanks bar styles, clean underflow representation of filled blanks
- 1.1.1: optional percentage in manual mode
- 1.1.0: new manual mode
- 1.0.1: pycharm console support with force_tty, improve compatibility with Python stdio streams
- 1.0.0: first public release, already very complete and mature
alive_progress
will always try to keep up with Python, so starting from version 2.0, I'll drop support for all Python versions which enter EoL. See their schedule here.
But don't worry if you can't migrate just yet: alive_progress
versions are perennial, so just keep using the one that works for you and you're good.
I just strongly recommend setting older alive_progress
packages in a requirements.txt file with the following formats. These will always fetch the latest build releases previous to a given version, so, if I ever release bug fixes, you'll get them too.
β― pip install -U "alive_progress<2"
β― pip install -U "alive_progress<2.2"
This software is licensed under the MIT License. See the LICENSE file in the top distribution directory for the full license text.
Maintaining an open source project is hard and time-consuming, and I've put much β€οΈ and effort into this.
If you've appreciated my work, you can back me up with a donation! Thank you π