# C MSB to LSB explanation

Could someone explain to me how this algorithm converts MSB to LSB or LSB to MSB on a 32-bit system?

``````unsigned char b = x;
b = ((b * 0x0802LU & 0x22110LU) | (b * 0x8020LU & 0x88440LU)) * 0x10101LU >> 16;
``````

I've seen hex values end with LU or just U in code before, what do they mean?

Thanks!

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`u` = unsigned integer, `lu` = long unsigned integer... –  Mysticial Aug 21 '13 at 22:43
Not really an explanation but I think the best way to understand would be to work through some examples in binary, try x = 1000-0000-0000-0000 and x = 0000-0000-0000-00001 –  Mehul Rathod Aug 21 '13 at 22:52

Presumably, a `char` has eight bits, so `unsigned char b = x` takes the low eight bits of x.

The mask with 0x22110 extracts bits 4, 8, 13, and 17 (numbering from 0 for the least significant bit). So, in the multiplication by 0x0802, we only care about what it places at those bits. In 0x802, bits 1 and 11 are on, so this multiplication places a copy of the eight bits of `b` in bits 1 through 8 and another copy in bits 11 through 18. There is no overlap, so there are no effects from adding bits that overlap in more general multiplications.

From this product, we take these bits:

• Bit 4, which is bit 3 of `b`. (Bit 4 from the copy starting at bit 1, so bit 4–1 = 3 of `b`.)
• Bit 8, which is bit 7 of `b`. (8–1 = 7.)
• Bit 13, which is bit 2 of `b`. (13–11 = 2.)
• Bit 17, which is bit 6 of `b`. (17–11 = 6.)

Similarly, the mask by 0x88440 extracts bits 6, 10, 15, and 19. The multiplication by 0x8020 places a copy of `b` in bits 5 to 12 and another copy in bits 15 to 22. From this product, we take these bits:

• Bit 6, which is bit 1 of `b`.
• Bit 10, which is bit 5 of `b`.
• Bit 15, which is bit 0 of `b`.
• Bit 19, which is bit 4 of `b`.

Then we OR those together, producing:

• Bit 4, which is bit 3 of `b`.
• Bit 6, which is bit 1 of `b`.
• Bit 8, which is bit 7 of `b`.
• Bit 10, which is bit 5 of `b`.
• Bit 13, which is bit 2 of `b`.
• Bit 15, which is bit 0 of `b`.
• Bit 17, which is bit 6 of `b`.
• Bit 19, which is bit 4 of `b`.

Call this result `t`.

We are going to multiply that by 0x10101, shift right by 16, and assign to `b`. The assignment converts to `unsigned char`, so only the low eight bits are kept. The low eight bits after the shift are bits 24 to 31 before the shift. So we only care about bits 24 to 31 in the product.

The multiplier 0x10101 has bits 0, 8, and 16 set. Thus, bit 24 in the result is the sum of bits 24, 16, and 8 in `t`, plus any carry from elsewhere. However, there is no carry: Observe that none of the set bits in `t` are eight apart, as the bits in the multiplier are. Therefore, none of them can directly contribute to the same bit in the product. Each bit in the product is the result of at most one bit in `t`. We just need to figure out which bit that is.

Bit 24 must come from bit 8, 16, or 24 in `t`. Only bit 8 can be set, and it is bit 7 from `b`. Deducing all the bits this way:

• Bit 24 is bit 8 in `t`, which is bit 7 in `b`.
• Bit 25 is bit 17 in `t`, which is bit 6 in `b`.
• Bit 26 is bit 10 in `t`, which is bit 5 in `b`.
• Bit 27 is bit 19 in `t`, which is bit 4 in `b`.
• Bit 28 is bit 4 in `t`, which is bit 3 in `b`.
• Bit 29 is bit 13 in `t`, which is bit 2 in `b`.
• Bit 30 is bit 6 in `t`, which is bit 1 in `b`.
• Bit 31 is bit 15 in `t`, which is bit 0 in `b`.

Thus, bits 24 to 31 in the product are bits 7 to 0 in `b`, so the eight bits finally produced are bits 7 to 0 in `b`.

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+1 very nice thorough explanation –  R.. Aug 22 '13 at 0:35
Thanks for your explanation, very helpful. It took a couple rounds of looking at your explanation and going through an example but I think I get it now. –  txcotrader Aug 22 '13 at 15:47

View b as an 8 bit value `abcdefgh` where each of those letters is a single bit (0 or 1), with `a` the most significant bit and `h` the least significant. Then look at what each of the operations do to those bits:

``````b * 0x0802LU             = 00000abcdefgh00abcdefgh0
b * 0x0802LU & 0x22110LU = 000000b000f0000a000e0000
b * 0x8020LU             = 0abcdefgh00abcdefgh00000
b * 0x8020LU & 0x88440LU = 0000d000h0000c000g000000
((b * 0x0802LU & 0x22110LU) | (b * 0x8020LU & 0x88440LU))
= 0000d0b0h0f00c0a0g0e0000
``````

so at this point, it has shuffled the bits and spread them out.

``````(....) * 0x10101LU       =                 d0b0h0f00c0a0g0e0000
+         d0b0h0f00c0a0g0e000000000000
+ d0b0h0f00c0a0g0e00000000000000000000
= d0b0f0f0dcbahgfedcbahgfe0c0a0g0e0000
(...) * 0x10101LU >> 16  = d0b0f0f0dcbahgfedcba
b                        = hgfedcba
``````

the multiply is equivalent to shift/add/add (3 bits set in the constant), which lines up the bits where they should end up. Then the final shift and reduction to 8 bits gives you the final bit-reversed result.

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To answer your second question, `u` means to treat the hex constant as an unsigned (if there is need to expand it to a longer width), and `l` means to treat it as a `long`.

I'm working on your first question.

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It's difficult to visualize what this algorithm is doing when you look at it as multiplications and hex. It becomes more clear when you convert it to binary and replace the multiplications with an equivalent sum of shift operations. Essentially what it is doing is it is spreading out parts of the byte by shifting and masking it, and then implementing a parallel half-adder that reconstructs the parts in place, which happens to be the reverse of where they started.

For example,

``````b * 0x0802 = b << 11 | b << 1
``````

Plug in some values (in binary) for b and follow along.

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