As @MrSmith42 says, provided you don't need to keep the file length constant, a "collision" (the name given for two input messages that result in the same hash) can be easily calculated.

It's fiddly, with lots of bit twiddling, but very quick.

Suppose the original file is, in hex:

```
1122334455667788
```

Then its CRC-32 checksum would be `0x9118E1C2`

using the standard CRC32 polynomial. If the algorithm in use is not standard, it can be substituted. I'll stick with the standard for demonstration purposes.

First, make your file changes as necessary. Eg, I change a byte in the middle:

```
11223344FF667788
```

Step one to restore the CRC is to pad the file with 4 zero bytes:

```
11223344FF66778800000000
```

The CRC checksum is now `0x6BBE83C9`

.

Step two, XOR the two checksums:

```
0x9118E1C2 XOR 0x6BBE83C9 = 0xFAA6620B
```

Step three, bit reverse the result:

```
Bit reverse of 0xFAA6620B = 0xD046655F
```

Step four, and this is a bit funky so see below, perform an inverse CRC32 calculation:

```
0xD046655F * inverse(x32) mod crc_poly = 0xe4c7d232
```

Step five, bit reverse the result, byte-wise this time:

```
0xe4c7d232 bit reversed byte-wise = 0x27E34B4C
```

Step six, replace the padded bytes with the result

```
11223344FF66778827E34B4C
```

Voila, the CRC32 checksum value is now back to 0x9118E1C2.

Easiest way I know of to do the inverse CRC calc is with the BitVector package in Python:

```
>>> import BitVector as bv
>>> poly = bv.BitVector(intVal = 0x104C11DB7) # "standard" CRC32 polynomial
>>> inv = bv.BitVector(intVal = 0x100000000).gf_MI(poly, 32)
>>> k = 0xD046655F
>>> p = bv.BitVector(intVal = k).gf_multiply_modular(inv, poly, 32)
>>> print(p.getHexStringFromBitVector())
e4c7d232
```

This algorithm is by Redditor /u/supersaw7 published in this thread. I've not come across a better one, despite a simpler version being tantalisingly possible.