| name | raster-at-scale |
| description | Use when processing raster or imagery data that is large — multi-gigabyte GeoTIFFs, mosaics, satellite scenes, DEMs — where loading the whole array into memory would fail or thrash. Makes the agent work in windows/tiles, use overviews and cloud-optimized formats, and avoid out-of-memory full-array reads. |
Raster at Scale
A large raster will not fit in memory, and the naive read everything into a NumPy array is how raster jobs crash. Process big rasters the way they're built to be processed.
Don't load the whole thing
- Read in windows/blocks, not all at once (
rasterio windowed reads, GDAL block reads). Process tile by tile and write tile by tile.
- Read in the raster's native block size where you can — aligned reads are far faster than arbitrary windows.
Use the right format and pyramids
- Prefer Cloud-Optimized GeoTIFF (COG) for efficient partial/range reads.
- Build overviews (
gdaladdo) so display and downsampled analysis don't touch full resolution.
- For chunked array work, reach for
xarray/dask or rioxarray rather than a monolithic array.
Reproject and warp without loading
- Resample/reproject with
gdalwarp (use -multi -wo NUM_THREADS=ALL_CPUS), not by reading arrays into Python.
- Pick the resampling method by data type: nearest for categorical/classified rasters (preserves class values), bilinear/cubic for continuous (elevation, imagery). Using bilinear on a land-cover raster invents classes that don't exist.
Get the details right
- Honor the NoData value so it doesn't poison statistics or show up as real zeros.
- Confirm the CRS before warping or aligning to other layers (see
crs-discipline).
Why this matters
The failure modes at scale are distinct: out-of-memory crashes, hour-long full-resolution passes that should have used overviews, and silently wrong resampling that corrupts categorical data. Windowed reads, COGs/overviews, and method-appropriate resampling turn an unworkable raster job into a fast, correct one.