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Although C is "close" to the low-level manipulation of 8-bit, 16-bit, 32-bit, 64-bit data, there are a few mathematical operations not supported by C which can often be performed elegantly in certain assembly instruction sets:

  1. Fixed-point multiplication: The product of two 16-bit numbers is a 32-bit number. But the rules in C says that the product of two 16-bit numbers is a 16-bit number, and the product of two 32-bit numbers is a 32-bit number -- the bottom half in both cases. If you want the top half of a 16x16 multiply or a 32x32 multiply, you have to play games with the compiler. The general method is to cast to a larger-than-necessary bit width, multiply, shift down, and cast back:

    int16_t x, y;
// int16_t is a typedef for "short"
// set x and y to something
int16_t prod = (int16_t)(((int32_t)x*y)>>16);`

    In this case the compiler may be smart enough to know that you're really just trying to get the top half of a 16x16 multiply and do the right thing with the machine's native 16x16multiply. Or it may be stupid and require a library call to do the 32x32 multiply that's way overkill because you only need 16 bits of the product -- but the C standard doesn't give you any way to express yourself.

  2. Certain bitshifting operations (rotation/carries): 

    // 256-bit array shifted right in its entirety:
uint8_t x[32];
for (int i = 32; --i > 0; )
{
   x[i] = (x[i] >> 1) | (x[i-1] << 7);
}
x[0] >>= 1;

    This is not too inelegant in C, but again, unless the compiler is smart enough to realize what you are doing, it's going to do a lot of "unnecessary" work. Many assembly instruction sets allow you to rotate or shift left/right with the result in the carry register, so you could accomplish the above in 34 instructions: load a pointer to the beginning of the array, clear the carry, and perform 32 8-bit right-shifts, using auto-increment on the pointer.

    For another example, there are linear feedback shift registers (LFSR) that are elegantly performed in assembly: Take a chunk of N bits (8, 16, 32, 64, 128, etc), shift the whole thing right by 1 (see above algorithm), then if the resulting carry is 1 then you XOR in a bit pattern that represents the polynomial.

Having said that, I wouldn't resort to these techniques unless I had serious performance constraints. As others have said, assembly is much harder to document/debug/test/maintain than C code: the performance gain comes with some serious costs.

edit: 3. Overflow detection is possible in assembly (can't really do it in C), this makes some algorithms much easier.
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Although C is "close" to the low-level manipulation of 8-bit, 16-bit, 32-bit, 64-bit data, there are a few mathematical operations not supported by C which can often be performed elegantly in certain assembly instruction sets:

  1. Fixed-point multiplication: The product of two 16-bit numbers is a 32-bit number. But the rules in C says that the product of two 16-bit numbers is a 16-bit number, and the product of two 32-bit numbers is a 32-bit number -- the bottom half in both cases. If you want the top half of a 16x16 multiply or a 32x32 multiply, you have to play games with the compiler. The general method is to cast to a larger-than-necessary bit width, multiply, shift down, and cast back:

    int16_t x, y;
// int16_t is a typedef for "short"
// set x and y to something
int16_t prod = (int16_t)(((int32_t)x*y)>>16);`

    In this case the compiler may be smart enough to know that you're really just trying to get the top half of a 16x16 multiply and do the right thing with the machine's native 16x16multiply. Or it may be stupid and require a library call to do the 32x32 multiply that's way overkill because you only need 16 bits of the product -- but the C standard doesn't give you any way to express yourself.

  2. Certain bitshifting operations (rotation/carries): 

    // 256-bit array shifted right in its entirety:
uint8_t x[32];
for (int i = 32; --i > 0; )
{
   x[i] = (x[i] >> 1) | (x[i-1] << 7);
}
x[0] >>= 1;

    This is not too inelegant in C, but again, unless the compiler is smart enough to realize what you are doing, it's going to do a lot of "unnecessary" work. Many assembly instruction sets allow you to rotate or shift left/right with the result in the carry register, so you could accomplish the above in 34 instructions: load a pointer to the beginning of the array, clear the carry, and perform 32 8-bit right-shifts, using auto-increment on the pointer.

    For another example, there are linear feedback shift registers (LFSR) that are elegantly performed in assembly: Take a chunk of N bits (8, 16, 32, 64, 128, etc), shift the whole thing right by 1 (see above algorithm), then if the resulting carry is 1 then you XOR in a bit pattern that represents the polynomial.

Having said that, I wouldn't resort to these techniques unless I had serious performance constraints. As others have said, assembly is much harder to document/debug/test/maintain than C code: the performance gain comes with some serious costs.