I have written an algorithm that takes geospatial data and performs a number of steps. The input data are a shapefile of polygons and covariate rasters for a large raster study area (~150 million pixels). The steps are as follows:
- Sample points from within polygons of the shapefile
- For each sampling point, extract values from the covariate rasters
- Build a predictive model on the sampling points
- Extract covariates for target grid points
- Apply predictive model to target grid
- Write predictions to a set of output grids
The whole process needs to be iterated a number of times (say 100) but each iteration currently takes more than an hour when processed in series. For each iteration, the most time-consuming parts are step 4 and 5. Because the target grid is so large, I’ve been processing it a block (say 1000 rows) at a time.
I have a 6-core CPU with 32 Gb RAM, so within each iteration, I had a go at using Python’s multiprocessing module with a Pool object to process a number of blocks simultaneously (steps 4 and 5) and then write the output (the predictions) to the common set of output grids using a callback function that calls a global output-writing function. This seems to work, but is no faster (actually, it’s probably slower) than processing each block in series.
So my question is, is there a more efficient way to do it? I’m interested in the multiprocessing module’s Queue class, but I’m not really sure how it works. For example, I’m wondering if it’s more efficient to have a queue that carries out steps 4 and 5 then passes the results to another queue that carries out step 6. Or is this even what Queue is for?
Any pointers would be appreciated.
The current state of Python’s multi-processing capabilities are not great for CPU bound processing. I fear to tell you that there is no way to make it run faster using the
multiprocessingmodule nor is it your use ofmultiprocessingthat is the problem.The real problem is that Python is still bound by the rules of the GlobalInterpreterLock(GIL) (I highly suggest the slides). There have been some exciting theoretical and experimental advances on working around the GIL. Python 3.2 event contains a new GIL which solves some of the issues, but introduces others.
For now, it is faster to execute many Python process with a single serial thread than to attempt to run many threads within one process. This will allow you avoid issues of acquiring the GIL between threads (by effectively having more GILs). This however is only beneficial if the IPC overhead between your Python processes doesn’t eclipse the benefits of the processing.
Eli Bendersky wrote a decent overview article on his experiences with attempting to make a CPU bound process run faster with multiprocessing.
It is worth noting that PEP 371 had the desire to ‘side-step’ the GIL with the introduction of the
multiprocessingmodule (previously a non-standard packaged namedpyProcessing). However the GIL still seems to play too large of a role in the Python interpreter to make it work well with CPU bound algorithms. Many different people have worked on removing/rewriting the GIL, but nothing has made enough traction to make it into a Python release.