I'm trying to develop a spatial based SQL query of all unique points within one or more of a given set of polygons. I am using PostGIS on a cloud VPS with 6 vCPU's and 16 GB of RAM. The spatial test in question is ST_Contains on the WHERE clause. The polygon set is approximately 40,000 unique geometries that constrain the 3.7 million feature point dataset.
My problem is that when I create a query with more than 13,000 polygons (an therefore 13,000 SELECT statements) the PostGIS server responds with an
ERROR: stack depth limit exceeded"
HINT: Increase the configuration parameter "max_stack_depth".
I want to know why and if I have options to work around it.
This is part of an optimization exercise. I'm already retrieving the polygon geometries as a separate SELECT to form the required SQL query. I want to execute the query that tests the polygon set as a single SQL statement. So far I have been building a SELECT subquery for each polygon then UNION each together as a start point. When compiled, the query using only 13,000 polygons is ~28,000,000 characters which I believe is much less than the PostGIS SQL statement limit.
I have tried smaller sizes and found that there is normal performance right up to the approximate limit. I had hit this limit earlier but after taking the advice of the error message I increased the "max_stack_depth" to approximately the size of what "ulimit -s" returns. At my current understanding, this SQL statement is not a recursive function of any kind which is what I would expect to cause the stack depth to be exceeded.
Also from my reading around stack vs heap memory, I cannot understand why this query would overload the stack as most of the required stored data should end up in the heap. I also expect the query to execute sequentially while collecting the results but it seems like PostGIS might be running all the SELECT substatements first then tallying up the results.
I have chosen to not try to merge the individual polygon geometries into a single polygon as they cover a very geographically diverse area (i.e not clustered into a simple mass) which I believe would drastically decrease benefits from spatial indexing.
My current working SQL script follows the pattern (trimmed to fit on this post):
SELECT * FROM point_table WHERE ST_Contains("poly1_geom_str", pt_geom_col) UNION SELECT * FROM point_table WHERE ST_Contains("poly2_geom_str", pt_geom_col) UNION .... SELECT * FROM point_table WHERE ST_Contains("polyN_geom_str", pt_geom_col);
Is my strategy for constructing this SQL statement unlikely to be able to be resolved? Is there an alternative strategy I can try that would avoid the recursion problem?