Maybe someone can help me out. I am about to use dynamic allocation in my CUDA kernel for the simple reason that each block will require a significant amount of global memory as a scratchpad and the number of blocks is in the order of 4000. Statically allocating the scratchpad would have my preference, but this is simply not possible due to memory size restrictions. I figured in this case dynamic allocation would be useful as the amount of memory is now only the number of active blocks, order 100-200. This all as a side note and to let you know it does not have my preference too, but it seems to me the only way forward.
Coming to the point, according to the cuda c programming guide section B.17;
The CUDA in-kernel malloc() function allocates at least size bytes from the device heap and returns a pointer to the allocated memory or NULL if insufficient memory exists to fulfill the request. The returned pointer is guaranteed to be aligned to a 16-byte boundary.
and according to F.4.2;
A cache line is 128 bytes and maps to a 128 byte aligned segment in device memory. Memory accesses that are cached in both L1 and L2 are serviced with 128-byte memory transactions whereas memory accesses that are cached in L2 only are serviced with 32-byte memory transactions. Caching in L2 only can therefore reduce over-fetch, for example, in the case of scattered memory accesses.
and from 5.3.2;
Any address of a variable residing in global memory or returned by one of the memory allocation routines from the driver or runtime API is always aligned to at least 256 bytes.
so does this mean that kernel allocations are not correctly aligned for a warp to parallel access coalesced consecutive floats with dynamic allocation as is possible with cudaMalloc() ?