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Do child processes spawned via multiprocessing share objects created earlier in the program?

I have the following setup:

    for line in file(filename):
        if line.split(',')[0] in big_lookup_object:
            # something here

if __name__ == '__main__':
    big_lookup_object = marshal.load('file.bin')
    pool = Pool(processes=4)
    print pool.map(do_some_processing, glob.glob('*.data'))

I'm loading some big object into memory, then creating a pool of workers that need to make use of that big object. The big object is accessed read-only, I don't need to pass modifications of it between processes.

My question is: is the big object loaded into shared memory, as it would be if I spawned a process in unix/c, or does each process load its own copy of the big object?

Update: to clarify further - big_lookup_object is a shared lookup object. I don't need to split that up and process it separately. I need to keep a single copy of it. The work that I need to split it is reading lots of other large files and looking up the items in those large files against the lookup object.

Further update: database is a fine solution, memcached might be a better solution, and file on disk (shelve or dbm) might be even better. In this question I was particularly interested in an in memory solution. For the final solution I'll be using hadoop, but I wanted to see if I can have a local in-memory version as well.

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your code as written will call marshal.load for parent and for each child (each process imports the module). – J.F. Sebastian Mar 19 '09 at 0:08
You're right, corrected. – Parand Mar 19 '09 at 0:33
For "local in-memory" and if you'd like to avoid copying the following might be useful docs.python.org/library/… – J.F. Sebastian Mar 19 '09 at 2:45

"Do child processes spawned via multiprocessing share objects created earlier in the program?"


Processes have independent memory space.

Solution 1

To make best use of a large structure with lots of workers, do this.

  1. Write each worker as a "filter" -- reads intermediate results from stdin, does work, writes intermediate results on stdout.

  2. Connect all the workers as a pipeline:

    process1 <source | process2 | process3 | ... | processn >result

Each process reads, does work and writes.

This is remarkably efficient since all processes are running concurrently. The writes and reads pass directly through shared buffers between the processes.

Solution 2

In some cases, you have a more complex structure -- often a "fan-out" structure. In this case you have a parent with multiple children.

  1. Parent opens source data. Parent forks a number of children.

  2. Parent reads source, farms parts of the source out to each concurrently running child.

  3. When parent reaches the end, close the pipe. Child gets end of file and finishes normally.

The child parts are pleasant to write because each child simply reads sys.sydin.

The parent has a little bit of fancy footwork in spawning all the children and retaining the pipes properly, but it's not too bad.

Fan-in is the opposite structure. A number of independently running processes need to interleave their inputs into a common process. The collector is not as easy to write, since it has to read from many sources.

Reading from many named pipes is often done using the select module to see which pipes have pending input.

Solution 3

Shared lookup is the definition of a database.

Solution 3A -- load a database. Let the workers process the data in the database.

Solution 3B -- create a very simple server using werkzeug (or similar) to provide WSGI applications that respond to HTTP GET so the workers can query the server.

Solution 4

Shared filesystem object. Unix OS offers shared memory objects. These are just files that are mapped to memory so that swapping I/O is done instead of more convention buffered reads.

You can do this from a Python context in several ways

  1. Write a startup program that (1) breaks your original gigantic object into smaller objects, and (2) starts workers, each with a smaller object. The smaller objects could be pickled Python objects to save a tiny bit of file reading time.

  2. Write a startup program that (1) reads your original gigantic object and writes a page-structured, byte-coded file using seek operations to assure that individual sections are easy to find with simple seeks. This is what a database engine does -- break the data into pages, make each page easy to locate via a seek.

    Spawn workers with access this this large page-structured file. Each worker can seek to the relevant parts and do their work there.

share|improve this answer
My processes aren't really fitlers; they're all the same, just processing different pieces of data. – Parand Mar 18 '09 at 20:20
They can often be structured as filters. They read their piece of data, do their work, and write their result for later processing. – S.Lott Mar 18 '09 at 20:33
I like your solution, but what happens with the blocking I/O? What if the parent blocks reading/writing from/to one of its children? Select does notify you that you can write, but it doesn't say how much. Same for reading. – Cristian Ciupitu Mar 18 '09 at 21:39
These are separate processes -- parents and children do not interfere with each other. Each byte produced at one end of a pipe is immediately available at the other end to be consumed -- a pipe is a shared buffer. Not sure what your question means in this context. – S.Lott Mar 18 '09 at 23:16
I can verify what S.Lott said. I needed the same operations done on a single file. So the first worker ran its function on every line with number % 2 == 0 and saved it to a file, and sent the other lines to the next piped process (which was the same script). Runtime went down by half. It's a little hacky, but the overhead is much lighter than map/poop in the multiprocessing module. – Vince Nov 30 '09 at 21:55

Do child processes spawned via multiprocessing share objects created earlier in the program?

It depends. For global read-only variables it can be often considered so (apart from the memory consumed) else it should not.

multiprocessing's documentation says:

Better to inherit than pickle/unpickle

On Windows many types from multiprocessing need to be picklable so that child processes can use them. However, one should generally avoid sending shared objects to other processes using pipes or queues. Instead you should arrange the program so that a process which need access to a shared resource created elsewhere can inherit it from an ancestor process.

Explicitly pass resources to child processes

On Unix a child process can make use of a shared resource created in a parent process using a global resource. However, it is better to pass the object as an argument to the constructor for the child process.

Apart from making the code (potentially) compatible with Windows this also ensures that as long as the child process is still alive the object will not be garbage collected in the parent process. This might be important if some resource is freed when the object is garbage collected in the parent process.

Global variables

Bear in mind that if code run in a child process tries to access a global variable, then the value it sees (if any) may not be the same as the value in the parent process at the time that Process.start() was called.


On Windows (single CPU):

#!/usr/bin/env python
import os, sys, time
from multiprocessing import Pool

x = 23000 # replace `23` due to small integers share representation
z = []    # integers are immutable, let's try mutable object

def printx(y):
    global x
    if y == 3:
       x = -x
    print os.getpid(), x, id(x), z, id(z) 
    print y
    if len(sys.argv) == 2 and sys.argv[1] == "sleep":
       time.sleep(.1) # should make more apparant the effect

if __name__ == '__main__':
    pool = Pool(processes=4)
    pool.map(printx, (1,2,3,4))

With sleep:

$ python26 test_share.py sleep
2504 23000 11639492 [1] 10774408
2564 23000 11639492 [2] 10774408
2504 -23000 11639384 [1, 3] 10774408
4084 23000 11639492 [4] 10774408

Without sleep:

$ python26 test_share.py
1148 23000 11639492 [1] 10774408
1148 23000 11639492 [1, 2] 10774408
1148 -23000 11639324 [1, 2, 3] 10774408
1148 -23000 11639324 [1, 2, 3, 4] 10774408
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Thank you really much! – fulmicoton Mar 19 '09 at 0:43
Huh? How is z getting shared across the processes?? – cbare Jul 14 '10 at 15:44
@cbare: Good question! z is in fact not shared, as the output with sleep shows. The output without sleep shows that a single process handles (PID = 1148) all the work; what we see in the last example is the value of z for this single process. – EOL Apr 20 '12 at 8:24

S.Lott is correct. Python's multiprocessing shortcuts effectively give you a separate, duplicated chunk of memory.

On most *nix systems, using a lower-level call to os.fork() will, in fact, give you copy-on-write memory, which might be what you're thinking. AFAIK, in theory, in the most simplistic of programs possible, you could read from that data without having it duplicated.

However, things aren't quite that simple in the Python interpreter. Object data and meta-data are stored in the same memory segment, so even if the object never changes, something like a reference counter for that object being incremented will cause a memory write, and therefore a copy. Almost any Python program that is doing more than "print 'hello'" will cause reference count increments, so you will likely never realize the benefit of copy-on-write.

Even if someone did manage to hack a shared-memory solution in Python, trying to coordinate garbage collection across processes would probably be pretty painful.

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If you're running under Unix, they may share the same object, due to how fork works (i.e., the child processes have separate memory but it's copy-on-write, so it may be shared as long as nobody modifies it). I tried the following:

import multiprocessing

x = 23

def printx(y):
    print x, id(x)
    print y

if __name__ == '__main__':
    pool = multiprocessing.Pool(processes=4)
    pool.map(printx, (1,2,3,4))

and got the following output:

$ ./mtest.py
23 22995656
23 22995656
23 22995656
23 22995656

Of course this doesn't prove that a copy hasn't been made, but you should be able to verify that in your situation by looking at the output of ps to see how much real memory each subprocess is using.

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What about the garbage collector? What happens when it runs? Doesn't the memory layout change? – Cristian Ciupitu Mar 18 '09 at 21:42
That's a valid concern. Whether it would affect Parand would depend on how he's using all of this and how reliable this code has to be. If it weren't working for him I'd recommend using the mmap module for more control (assuming he wants to stick with this basic approach). – Jacob Gabrielson Mar 18 '09 at 21:54
It works on Windows too. – J.F. Sebastian Mar 18 '09 at 22:37
I've posted an update to your example: stackoverflow.com/questions/659865/… – J.F. Sebastian Mar 19 '09 at 1:51
@JacobGabrielson: The copy is made. The original question is about whether the copy is made. – abhinavkulkarni Sep 19 '13 at 1:26

Different processes have different address space. Like running different instances of the interpreter. That's what IPC (interprocess communication) is for.

You can use either queues or pipes for this purpose. You can also use rpc over tcp if you want to distribute the processes over a network later.


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I don't think IPC would be appropriate for this; this is read-only data that everybody needs access to. No sense passing it around between processes; at worst each can read its own copy. I'm attempting to save memory by not having a separate copy in each process. – Parand Mar 18 '09 at 20:21
You can have a master process delegating pieces of data to work on to the other slave processes. Either the slaves can ask for data or it can push data. This way not every process will have a copy of the whole object. – Vasil Mar 18 '09 at 20:39
@Vasil: What if each process needs the whole data set, and is just running a different operation on it? – Will Jun 2 '13 at 22:55

Not directly related to multiprocessing per se, but from your example, it would seem you could just use the shelve module or something like that. Does the "big_lookup_object" really have to be completely in memory?

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Good point, I haven't directly compared performance of on-disk vs. in memory. I had assumed there would be a big difference, but I haven't actually tested. – Parand Mar 18 '09 at 23:57

For Linux/Unix/MacOS platform, forkmap is a quick-and-dirty solution.

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