The polynomial for CRC32 is:

0x04C11DB7

x32 + x26 + x23 + x22 + x16 + x12 + x11 + x10 + x8 + x7 + x5 + x4 + x2 + x + 1

Which works out to be in binary:

100110000010001110110110111

Feel free to count the 1s and 0s, but you'll find they match up with the polynomial where 1 is bit 0 (or the first bit) and x is bit 1 (or the second bit).

Why this polynomial? Because there needs to be a standard given polynomial and the standard was set by IEEE 802.3. Also it is extremely difficult to find a polynomial that works effectively.

You can think of the CRC-32 as a series of "Binary Arithmetic with No Carries" or basically XOR and shift operations. This is technically called Polynomial Arithmetic.

-CRC primer, Chapter 5

To better understand, think of this situation:

```
(x^3 + x^2 + x^0)(x^3 + x^1 + x^0)
= (x^6 + x^4 + x^3
+ x^5 + x^3 + x^2
+ x^3 + x^1 + x^0) = x^6 + x^5 + x^4 + 3*x^3 + x^2 + x^1 + x^0
```

If we assume x is base 2 then we get:

```
x^7 + x^3 + x^2 + x^1 + x^0
```

-CRC primer Chp.5

Why? Because 3x^3 is 11x^11 (but we need only 1 or 0 pre digit) so we carry over:

```
=1x^110 + 1x^101 + 1x^100 + 11x^11 + 1x^10 + 1x^1 + x^0
=1x^110 + 1x^101 + 1x^100 + 1x^100 + 1x^11 + 1x^10 + 1x^1 + x^0
=1x^110 + 1x^101 + 1x^101 + 1x^11 + 1x^10 + 1x^1 + x^0
=1x^110 + 1x^110 + 1x^11 + 1x^10 + 1x^1 + x^0
=1x^111 + 1x^11 + 1x^10 + 1x^1 + x^0
```

But mathematicians changed the rules so that it is mod 2. So basically any binary polynomial mod 2 is just addition without carry or XORs. So our original equation looks like:

```
=( 1x^110 + 1x^101 + 1x^100 + 11x^11 + 1x^10 + 1x^1 + x^0 ) MOD 2
=( 1x^110 + 1x^101 + 1x^100 + 1x^11 + 1x^10 + 1x^1 + x^0 )
= x^6 + x^5 + x^4 + 3*x^3 + x^2 + x^1 + x^0 (or that original number we had)
```

I know this is a leap of faith but this is beyond my capability as a line-programmer. If you are a hard-core CS-student or engineer I challenge to break this down. Everyone will benefit from this analysis.

So to work out a full example:

```
Original message : 1101011011
Poly : 10011
Message after appending W zeros : 11010110110000
Now we simply divide the augmented message by the poly using CRC
arithmetic. This is the same division as before:
1100001010 = Quotient (nobody cares about the quotient)
_______________
10011 ) 11010110110000 = Augmented message (1101011011 + 0000)
=Poly 10011,,.,,....
-----,,.,,....
10011,.,,....
10011,.,,....
-----,.,,....
00001.,,....
00000.,,....
-----.,,....
00010,,....
00000,,....
-----,,....
00101,....
00000,....
-----,....
01011....
00000....
-----....
10110...
10011...
-----...
01010..
00000..
-----..
10100.
10011.
-----.
01110
00000
-----
1110 = Remainder = THE CHECKSUM!!!!
The division yields a quotient, which we throw away, and a remainder,
which is the calculated checksum. This ends the calculation.
Usually, the checksum is then appended to the message and the result
transmitted. In this case the transmission would be: 11010110111110.
```

-CRC primer, Chapter 7

Only use a 32-bit number as your divisor and use your entire stream as your dividend. Throw out the quotient and keep the remainder. Tack the remainder on the end of your message and you have a CRC32.

Average guy review:

```
QUOTIENT
----------
DIVISOR ) DIVIDEND
= REMAINDER
```

- Take the first 32 bits.
- Shift bits
- If 32 bits are less than DIVISOR, goto step 2.
- XOR 32 bits by DIVISOR. Goto step 2.

(Note that the stream has to be dividable by 32 bits or it should be paddded. For example, an 8-bit ANSI stream would have to be padded. Also at the end of the stream, the division is halted.)

reversed) CRC32 polynomial of`0xEDB88320`

can also be written msbit-first (normal) as`0x04C11DB7`

. Were the table values you found elsewhere generated using the same CRC polynomial? – jschmier Jan 27 '11 at 20:23