Trying to understand the differences between virtual and real architecture of cuda, and how the different configurations will affect the performance of the program, e.g.
-gencode arch=compute_20,code=sm_20 -gencode arch=compute_20,code=sm_21 -gencode arch=compute_21,code=sm_21 ...
The following explanation was given in NVCC manual,
GPU compilation is performed via an intermediate representation, PTX ([...]), which can be considered as assembly for a virtual GPU architecture. Contrary to an actual graphics processor, such a virtual GPU is defined entirely by the set of capabilities, or features, that it provides to the application. In particular, a virtual GPU architecture provides a (largely) generic instruction set, and binary instruction encoding is a non-issue because PTX programs are always represented in text format. Hence, a nvcc compilation command always uses two architectures: a compute architecture to specify the virtual intermediate architecture, plus a real GPU architecture to specify the intended processor to execute on. For such an nvcc command to be valid, the real architecture must be an implementation (someway or another) of the virtual architecture. This is further explained below. The chosen virtual architecture is more of a statement on the GPU capabilities that the application requires: using a smallest virtual architecture still allows a widest range of actual architectures for the second nvcc stage. Conversely, specifying a virtual architecture that provides features unused by the application unnecessarily restricts the set of possible GPUs that can be specified in the second nvcc stage.
But still don't quite get how the performance will be affected by different configurations (or, maybe only affect the selection of the physical GPU devices?). In particular, this statement is most confusing to me:
In particular, a virtual GPU architecture provides a (largely) generic instruction set, and binary instruction encoding is a non-issue because PTX programs are always represented in text format.