r = p.map_async(main1, d.values()) does this:
d.values() - that's
main1(item) for each item in that list on a worker from the pool
3) Gather the results from those calls into a list -
[1, 1] - because that's what
4) Assign that list to
So it does exactly what the builtin function
map() does, but in a parallelized way.
This means, your dict
d never makes it into any of the worker processes, because it's not a reference to
d that's passed to
map_async, and therefore
And even if you would pass in a reference to
d - it wouldn't work for the reasons explained by @Roland Smith.
The point is: You shouldn't modify the dictionary in the first place. It's not even very good style in conventional programming for functions to modify their arguments, even if they can. For parallel programming it's absolutely crucial to follow a functional programming style, which in this context means:
Functions should do the computation on their input, and return a result that is further processed.
The functions map and reduce are very common in functional programming, and combined together they form a pattern that is suited very well for distributed computing. From the Wikipedia article on MapReduce:
"Map" step: The master node takes the input, divides it into smaller
sub-problems, and distributes them to worker nodes. A worker node may
do this again in turn, leading to a multi-level tree structure. The
worker node processes the smaller problem, and passes the answer back
to its master node.
"Reduce" step: The master node then collects the answers to all the
sub-problems and combines them in some way to form the output – the
answer to the problem it was originally trying to solve.
So in order to effectively parallelize your program it helps to try to think of your problem in terms of those functions.
For a very concrete example, see the Article The Trouble With Multicore in IEEE Spectrum. It describes a method of parallelizing the computation of PI that could easily be implemented with map/reduce.