If you have same points of entries (e.g. kernel names, launch parameters, arguments are same) then you can rely on precompiler (this is from grabCut CUDA SDK sample):
#if __CUDA_ARCH__ < 200
unsigned int gmm_flags_bvec = 0;
for (int i=0; i<32; ++i)
if (gmm_flags[i] > 0)
gmm_flags_bvec |= 1 << i;
tile_gmms[blockIdx.y * gridDim.x + blockIdx.x] = gmm_flags_bvec;
tile_gmms[blockIdx.y * gridDim.x + blockIdx.x] = __ballot(gmm_flags[threadIdx.x] > 0);
then you would have to pass several -gencode arguments to NVCC - and it will build different kernels and include them in your executable. Driver will automatically pick the proper kernel for your device when application is running.
Then, if your host code differs between different device architectures (e.g. you do less on the device if it is really old) you can create several CU for different compute capabilities - and have every CU file will export host function that would serve as an entry point. It will be your application responsibility to use proper entry point depending on available hardware.
E.g. you would have application_logic_sm3x.cu that contains kernels that use SM 3.x features and a regular C function called compute_sm3x(...). Application_logic_sm2x.cu will use SM 2.x features and a contain C function called compute_sm2x(...).
Your main.cpp function will use cudaGetDeviceProperties and then call either compute_sm3x or compute_sm2x depending on available hardware.
Update You can take a look at simplePrintf sample from CUDA Toolkit 5.0 - it has slightly different code paths for 1.x and 2.x and newer.