For my application I have to handle a bunch of objects (let's say `int`

s) that gets subsequently divided and sorted into smaller buckets. To this end, I store the elements in a single continuous array

```
arr = {0,1,2,3,4,5,6,7,8,9,10,11,12,13,14...}
```

and the information about the buckets (sublists) is given by offsets to the first element in the respective bucket and the lengths of the sublist.

So, for instance, given

```
offsets = {0,3,8,..}
sublist_lengths = {3,5,2,...}
```

would result in the following splits:

```
0 1 2 || 3 4 5 6 7 || 8 9 || ...
```

What I am looking for is a somewhat general and efficient way to run algorithms, like reductions, on the buckets only using either custom kernels or the `thrust`

library. Summing the buckets should give:

```
3 || 25 || 17 || ...
```

What I've come up with:

*option 1*: custom kernels require a quite a bit of tinkering, copies into shared memory, proper choice of block and grid sizes and an own implementation of the algorithms, like scan, reduce, etc. Also, every single operation would require an own custom kernel. In general it is clear to me how to do this, but after having used`thrust`

for the last couple of days I have the impression that there might be a smarter way*option 2*: generate an array of keys from the offsets (`{0,0,0,1,1,1,1,1,2,2,3,...}`

in the above example) and use`thrust::reduce_by_key`

. I don't like the extra list generation, though.*option 3*: Use`thrust::transform_iterator`

together with`thrust::counting_iterator`

to generate the above given key list on the fly. Unfortunately, I can't come up with an implementation that doesn't require increments of indices to the offset list on the device and defeats parallelism.

What would be the most sane way to implement this?