As others have explained, the result depends on endianess. In addition to that, your code is unsafe and invokes undefined behavior. Because there is no guarantee that you can cast from a struct to an array of short.
This is because of data alignment. Many CPUs prefers or demands data bytes to be allocated on even addresses. For example, a 32-bit CPU with such an alignment requirement would want data to be stored at an address which is divisible by 4 (addresses correspond to bytes, 4 bytes = 32 bits).
If the data is not stored on such an even address, it is misaligned, which will lead to poor CPU performance on most mainstream 32/64-bit CPUs (86, PowerPC, ARM etc) or possibly that the code can't even execute (rare case, I think some MIPS CPU applies?).
Therefore, during optimization the compiler attempts to store all members of a struct on aligned addresses. This is allowed by the C standard: the compiler is free to add something called padding bytes, which is essentially just garbage space allocated between the struct members.
In your example, a compiler for a 32-bit big endian CPU could do something like this:
0x00000000 unsigned short a; MS byte
0x00000001 unsigned short b; LS byte
0x00000002 Padding byte
0x00000003 Padding byte
0x00000004 unsigned short b; MS byte
0x00000005 unsigned short b; LS byte
0x00000006 Padding byte
0x00000007 Padding byte
0x00000008 unsigned long c; MS byte
0x00000009 unsigned long c;
0x0000000A unsigned long c;
0x0000000B unsigned long c; LS byte
As you can see, trying to interpret this memory chunk as an array of
short would give you problems, since you would end up with padding bytes in the middle of the array.
So formally, casting between structs and arrays of data is undefined behavior and bad practice. But there are various non-standard extensions that will allow you to disable struct padding, the most common is
#pragma pack. If you invoke such a non-standard compiler setting, then your code would work in practice.