i have the following code:
def multiple_invoice_matches(payment_regex, invoice_regex):
multiple_invoice_payment_matches=[]
for p in payment_regex:
if p["match_count"]>1:
for k in p["matches"]:
for i in invoice_regex:
if i["rechnung_nr"] ==k:
multiple_invoice_payment_matches.append({"fuzzy_ratio":100, "type":2, "m_match":0, "invoice":i, "payment":p})
return multiple_invoice_payment_matches
The sizes of payment_regex and invoice_regex are really huge. Therefore, the code snippet give above takes too much time to return the result. How can I speed up running time of this code?
You could take a look at the numba library, if your data has the possibility of parallelization, rewrite your function using the numba library would definitely speed up your code.
Without the dimensions of size and how your data is structured it's kind of hard to give a general approach to optimize your function.
I could say partition your data into multiple ranges (either by payment_regex, or by invoice_regex, or both) and then add those partitions to a work queue that is processed by multiple threads. Wait for those threads to finish (i.e.: join them), and then construct your final list based on the partial results you got for each partition.
This will work well in other programming languages, but unfortunately, not in Python, because of GIL - the Python's Global Interpreter Lock.
If you don't know much about GIL here's a decent article, saying:
The Python Global Interpreter Lock or GIL, in simple words,
is a mutex (or a lock) that allows only one thread to hold
the control of the Python interpreter.
[...]
The impact of the GIL isn’t visible to developers who execute
single-threaded programs, but it can be a performance bottleneck
in CPU-bound and multi-threaded code.
To evade GIL you basically have two options:
(1) spawn multiple Python processes and use shared memory for backing up your data => concurrency will now rely on the OS for switching between processes (e.g.: use numpy and shared memory, see here)
(2) use a Python package that can manipulate your data and implements the multi-threading model in C, where GIL is not effective (e.g.: use numba)
You may ask yourself then why Python supports multi-threading in the first place?
Multi-threading in Python is mostly useful when the threads are blocked by IO operations (read/write of files, sockets, etc.) or by other system calls that put the thread in the sleep state. That's where Python releases the GIL lock and other threads can operate concurrently while some are at sleep.
Related
With standard CPython, it's not possible to truly parallelized program execution on multiple CPU cores using threading. This is due to the Global Interpreter Lock (GIL).
CPython implementation detail: In CPython, due to the Global Interpreter Lock, only one thread can execute Python code at once (even though certain performance-oriented libraries might overcome this limitation). If you want your application to make better use of the computational resources of multi-core machines, you are advised to use multiprocessing or concurrent.futures.ProcessPoolExecutor. However, threading is still an appropriate model if you want to run multiple I/O-bound tasks simultaneously.
Source: CPython documentation
Another solution is to use multiple interpreters in parallel with Pythons multiprocessing. This solution spawns multiple processes, each with it's own interpreter instance and thus its own independent GIL.
In my usecase I have multiple chained generators. Each generator is generating a linked list objects. This list is input to the next generator, which generates again a linked list of objects.
While this algorithm is quite fast, I'm asking myself, if could be parallelized with Pythons multiprocessing, so each generator runs on one CPU core. I think in between of two generators (producer / consumer), some kind of buffer/ FIFO would be needed to decouple the execution speeds.
My questions:
Is such an implementation possible?
How would a minimal example look like?
tokenStream = Token.GetGenerator(fileContent) # producer
blockStream = Block.TranslateTokenToBlocks(tokenStream) # consumer / producer
groupStream = Group.TranslateBlockToGroup(blockStream) # consumer / producer
CodeDOM = CodeDOM.FromGroupStream(groupStream) # consumer
I'm slightly confused about whether multithreading works in Python or not.
I know there has been a lot of questions about this and I've read many of them, but I'm still confused. I know from my own experience and have seen others post their own answers and examples here on StackOverflow that multithreading is indeed possible in Python. So why is it that everyone keep saying that Python is locked by the GIL and that only one thread can run at a time? It clearly does work. Or is there some distinction I'm not getting here?
Many posters/respondents also keep mentioning that threading is limited because it does not make use of multiple cores. But I would say they are still useful because they do work simultaneously and thus get the combined workload done faster. I mean why would there even be a Python thread module otherwise?
Update:
Thanks for all the answers so far. The way I understand it is that multithreading will only run in parallel for some IO tasks, but can only run one at a time for CPU-bound multiple core tasks.
I'm not entirely sure what this means for me in practical terms, so I'll just give an example of the kind of task I'd like to multithread. For instance, let's say I want to loop through a very long list of strings and I want to do some basic string operations on each list item. If I split up the list, send each sublist to be processed by my loop/string code in a new thread, and send the results back in a queue, will these workloads run roughly at the same time? Most importantly will this theoretically speed up the time it takes to run the script?
Another example might be if I can render and save four different pictures using PIL in four different threads, and have this be faster than processing the pictures one by one after each other? I guess this speed-component is what I'm really wondering about rather than what the correct terminology is.
I also know about the multiprocessing module but my main interest right now is for small-to-medium task loads (10-30 secs) and so I think multithreading will be more appropriate because subprocesses can be slow to initiate.
The GIL does not prevent threading. All the GIL does is make sure only one thread is executing Python code at a time; control still switches between threads.
What the GIL prevents then, is making use of more than one CPU core or separate CPUs to run threads in parallel.
This only applies to Python code. C extensions can and do release the GIL to allow multiple threads of C code and one Python thread to run across multiple cores. This extends to I/O controlled by the kernel, such as select() calls for socket reads and writes, making Python handle network events reasonably efficiently in a multi-threaded multi-core setup.
What many server deployments then do, is run more than one Python process, to let the OS handle the scheduling between processes to utilize your CPU cores to the max. You can also use the multiprocessing library to handle parallel processing across multiple processes from one codebase and parent process, if that suits your use cases.
Note that the GIL is only applicable to the CPython implementation; Jython and IronPython use a different threading implementation (the native Java VM and .NET common runtime threads respectively).
To address your update directly: Any task that tries to get a speed boost from parallel execution, using pure Python code, will not see a speed-up as threaded Python code is locked to one thread executing at a time. If you mix in C extensions and I/O, however (such as PIL or numpy operations) and any C code can run in parallel with one active Python thread.
Python threading is great for creating a responsive GUI, or for handling multiple short web requests where I/O is the bottleneck more than the Python code. It is not suitable for parallelizing computationally intensive Python code, stick to the multiprocessing module for such tasks or delegate to a dedicated external library.
Yes. :)
You have the low level thread module and the higher level threading module. But it you simply want to use multicore machines, the multiprocessing module is the way to go.
Quote from the docs:
In CPython, due to the Global Interpreter Lock, only one thread can
execute Python code at once (even though certain performance-oriented
libraries might overcome this limitation). If you want your
application to make better use of the computational resources of
multi-core machines, you are advised to use multiprocessing. However,
threading is still an appropriate model if you want to run multiple
I/O-bound tasks simultaneously.
Threading is Allowed in Python, the only problem is that the GIL will make sure that just one thread is executed at a time (no parallelism).
So basically if you want to multi-thread the code to speed up calculation it won't speed it up as just one thread is executed at a time, but if you use it to interact with a database for example it will.
I feel for the poster because the answer is invariably "it depends what you want to do". However parallel speed up in python has always been terrible in my experience even for multiprocessing.
For example check this tutorial out (second to top result in google): https://www.machinelearningplus.com/python/parallel-processing-python/
I put timings around this code and increased the number of processes (2,4,8,16) for the pool map function and got the following bad timings:
serial 70.8921644706279
parallel 93.49704207479954 tasks 2
parallel 56.02441442012787 tasks 4
parallel 51.026168536394835 tasks 8
parallel 39.18044807203114 tasks 16
code:
# increase array size at the start
# my compute node has 40 CPUs so I've got plenty to spare here
arr = np.random.randint(0, 10, size=[2000000, 600])
.... more code ....
tasks = [2,4,8,16]
for task in tasks:
tic = time.perf_counter()
pool = mp.Pool(task)
results = pool.map(howmany_within_range_rowonly, [row for row in data])
pool.close()
toc = time.perf_counter()
time1 = toc - tic
print(f"parallel {time1} tasks {task}")
I'm slightly confused about whether multithreading works in Python or not.
I know there has been a lot of questions about this and I've read many of them, but I'm still confused. I know from my own experience and have seen others post their own answers and examples here on StackOverflow that multithreading is indeed possible in Python. So why is it that everyone keep saying that Python is locked by the GIL and that only one thread can run at a time? It clearly does work. Or is there some distinction I'm not getting here?
Many posters/respondents also keep mentioning that threading is limited because it does not make use of multiple cores. But I would say they are still useful because they do work simultaneously and thus get the combined workload done faster. I mean why would there even be a Python thread module otherwise?
Update:
Thanks for all the answers so far. The way I understand it is that multithreading will only run in parallel for some IO tasks, but can only run one at a time for CPU-bound multiple core tasks.
I'm not entirely sure what this means for me in practical terms, so I'll just give an example of the kind of task I'd like to multithread. For instance, let's say I want to loop through a very long list of strings and I want to do some basic string operations on each list item. If I split up the list, send each sublist to be processed by my loop/string code in a new thread, and send the results back in a queue, will these workloads run roughly at the same time? Most importantly will this theoretically speed up the time it takes to run the script?
Another example might be if I can render and save four different pictures using PIL in four different threads, and have this be faster than processing the pictures one by one after each other? I guess this speed-component is what I'm really wondering about rather than what the correct terminology is.
I also know about the multiprocessing module but my main interest right now is for small-to-medium task loads (10-30 secs) and so I think multithreading will be more appropriate because subprocesses can be slow to initiate.
The GIL does not prevent threading. All the GIL does is make sure only one thread is executing Python code at a time; control still switches between threads.
What the GIL prevents then, is making use of more than one CPU core or separate CPUs to run threads in parallel.
This only applies to Python code. C extensions can and do release the GIL to allow multiple threads of C code and one Python thread to run across multiple cores. This extends to I/O controlled by the kernel, such as select() calls for socket reads and writes, making Python handle network events reasonably efficiently in a multi-threaded multi-core setup.
What many server deployments then do, is run more than one Python process, to let the OS handle the scheduling between processes to utilize your CPU cores to the max. You can also use the multiprocessing library to handle parallel processing across multiple processes from one codebase and parent process, if that suits your use cases.
Note that the GIL is only applicable to the CPython implementation; Jython and IronPython use a different threading implementation (the native Java VM and .NET common runtime threads respectively).
To address your update directly: Any task that tries to get a speed boost from parallel execution, using pure Python code, will not see a speed-up as threaded Python code is locked to one thread executing at a time. If you mix in C extensions and I/O, however (such as PIL or numpy operations) and any C code can run in parallel with one active Python thread.
Python threading is great for creating a responsive GUI, or for handling multiple short web requests where I/O is the bottleneck more than the Python code. It is not suitable for parallelizing computationally intensive Python code, stick to the multiprocessing module for such tasks or delegate to a dedicated external library.
Yes. :)
You have the low level thread module and the higher level threading module. But it you simply want to use multicore machines, the multiprocessing module is the way to go.
Quote from the docs:
In CPython, due to the Global Interpreter Lock, only one thread can
execute Python code at once (even though certain performance-oriented
libraries might overcome this limitation). If you want your
application to make better use of the computational resources of
multi-core machines, you are advised to use multiprocessing. However,
threading is still an appropriate model if you want to run multiple
I/O-bound tasks simultaneously.
Threading is Allowed in Python, the only problem is that the GIL will make sure that just one thread is executed at a time (no parallelism).
So basically if you want to multi-thread the code to speed up calculation it won't speed it up as just one thread is executed at a time, but if you use it to interact with a database for example it will.
I feel for the poster because the answer is invariably "it depends what you want to do". However parallel speed up in python has always been terrible in my experience even for multiprocessing.
For example check this tutorial out (second to top result in google): https://www.machinelearningplus.com/python/parallel-processing-python/
I put timings around this code and increased the number of processes (2,4,8,16) for the pool map function and got the following bad timings:
serial 70.8921644706279
parallel 93.49704207479954 tasks 2
parallel 56.02441442012787 tasks 4
parallel 51.026168536394835 tasks 8
parallel 39.18044807203114 tasks 16
code:
# increase array size at the start
# my compute node has 40 CPUs so I've got plenty to spare here
arr = np.random.randint(0, 10, size=[2000000, 600])
.... more code ....
tasks = [2,4,8,16]
for task in tasks:
tic = time.perf_counter()
pool = mp.Pool(task)
results = pool.map(howmany_within_range_rowonly, [row for row in data])
pool.close()
toc = time.perf_counter()
time1 = toc - tic
print(f"parallel {time1} tasks {task}")
I'm relatively new to threading and asynchronous programming in general, but I'm trying to understand the distinction between the two as it relates to the GIL in CPython.
From the reading that I've down, I understand that threads have their own stack and the two models are a different programming paradigm. But given that they cannot run concurrently because of the GIL, are python threads a type of asynchronous execution underneath? I'd really like to get a better understanding of how the python interpreter implements threading, specifically how it determines when one thread is blocking and another can be executed?
The GIL does only play a role when executing python code - calling Functions that are implemented in C, for example, GIL shouldn't interfere afaik. Also, downloading files or moving files from the disk can be made work concurrently with python Threads.
Quote from the Python Wiki:
Note that potentially blocking or long-running operations, such as I/O, image processing, and NumPy number crunching, happen outside the GIL. Therefore it is only in multithreaded programs that spend a lot of time inside the GIL, interpreting CPython bytecode, that the GIL becomes a bottleneck.
You might have a look on the multiprocessing module, which allows you to overcome the GIL and use multiple Cores on the machine. Also, there is work going on to make PyPy, an alternative Python Interpreter, become GIL-less in some day (just search for STM/AME).
I have a python application that grabs a collection of data and for each piece of data in that collection it performs a task. The task takes some time to complete as there is a delay involved. Because of this delay, I don't want each piece of data to perform the task subsequently, I want them to all happen in parallel. Should I be using multiprocess? or threading for this operation?
I attempted to use threading but had some trouble, often some of the tasks would never actually fire.
If you are truly compute bound, using the multiprocessing module is probably the lightest weight solution (in terms of both memory consumption and implementation difficulty.)
If you are I/O bound, using the threading module will usually give you good results. Make sure that you use thread safe storage (like the Queue) to hand data to your threads. Or else hand them a single piece of data that is unique to them when they are spawned.
PyPy is focused on performance. It has a number of features that can help with compute-bound processing. They also have support for Software Transactional Memory, although that is not yet production quality. The promise is that you can use simpler parallel or concurrent mechanisms than multiprocessing (which has some awkward requirements.)
Stackless Python is also a nice idea. Stackless has portability issues as indicated above. Unladen Swallow was promising, but is now defunct. Pyston is another (unfinished) Python implementation focusing on speed. It is taking an approach different to PyPy, which may yield better (or just different) speedups.
Tasks runs like sequentially but you have the illusion that are run in parallel. Tasks are good when you use for file or connection I/O and because are lightweights.
Multiprocess with Pool may be the right solution for you because processes runs in parallel so are very good with intensive computing because each process run in one CPU (or core).
Setup multiprocess may be very easy:
from multiprocessing import Pool
def worker(input_item):
output = do_some_work()
return output
pool = Pool() # it make one process for each CPU (or core) of your PC. Use "Pool(4)" to force to use 4 processes, for example.
list_of_results = pool.map(worker, input_list) # Launch all automatically
For small collections of data, simply create subprocesses with subprocess.Popen.
Each subprocess can simply get it's piece of data from stdin or from command-line arguments, do it's processing, and simply write the result to an output file.
When the subprocesses have all finished (or timed out), you simply merge the output files.
Very simple.
You might consider looking into Stackless Python. If you have control over the function that takes a long time, you can just throw some stackless.schedule()s in there (saying yield to the next coroutine), or else you can set Stackless to preemptive multitasking.
In Stackless, you don't have threads, but tasklets or greenlets which are essentially very lightweight threads. It works great in the sense that there's a pretty good framework with very little setup to get multitasking going.
However, Stackless hinders portability because you have to replace a few of the standard Python libraries -- Stackless removes reliance on the C stack. It's very portable if the next user also has Stackless installed, but that will rarely be the case.
Using CPython's threading model will not give you any performance improvement, because the threads are not actually executed in parallel, due to the way garbage collection is handled. Multiprocess would allow parallel execution. Obviously in this case you have to have multiple cores available to farm out your parallel jobs to.
There is much more information available in this related question.
If you can easily partition and separate the data you have, it sounds like you should just do that partitioning externally, and feed them to several processes of your program. (i.e. several processes instead of threads)
IronPython has real multithreading, unlike CPython and it's GIL. So depending on what you're doing it may be worth looking at. But it sounds like your use case is better suited to the multiprocessing module.
To the guy who recommends stackless python, I'm not an expert on it, but it seems to me that he's talking about software "multithreading", which is actually not parallel at all (still runs in one physical thread, so cannot scale to multiple cores.) It's merely an alternative way to structure asynchronous (but still single-threaded, non-parallel) application.
You may want to look at Twisted. It is designed for asynchronous network tasks.