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.