The sequence to use for the CRC calculation in your protocol is the ASCII string

- starting from the first printing character (e.g. the 'R' from REQ)
- until and including the '1E' in the calculation.
It's a CRC with the following specs according to our CRC calculator

CRC:16,1021,0000,0000,No,No

which means:

```
CRC width: 16 bit (of course)
polynomial: 1021 HEX (truncated CRC polynomial)
init value: 0000
final Xor applied: 0000
reflectedInput: No
reflectedOutput: No`
```

(If 'init value' were FFFF, it would be a "16 bit width CRC as designated by CCITT").

See also the Docklight CRC glossary and the Boost CRC library on what the CRC terms mean plus sample code.

What I did is to write a small script that tries out the popular 16 bit CRCs on varying parts of the first simple "REQ=INI" command, and see if I end up with a sum of 4255. This failed, but instead of going a full brute force with trying all sorts of polynoms, I assumed that it was maybe just an oddball / flawed implementation of the known standards, and indeed succeeded with a variation of the CRC-CCITT.

Heres is some slow & easy C code (not table based!) to calculate all sorts of CRCs:

```
// Generic, not table-based CRC calculation
// Based on and credits to the following:
// CRC tester v1.3 written on 4th of February 2003 by Sven Reifegerste (zorc/reflex)
unsigned long reflect (unsigned long crc, int bitnum) {
// reflects the lower 'bitnum' bits of 'crc'
unsigned long i, j=1, crcout=0;
for (i=(unsigned long)1<<(bitnum-1); i; i>>=1) {
if (crc & i) crcout|=j;
j<<= 1;
}
return (crcout);
}
calcCRC(
const int width, const unsigned long polynominal, const unsigned long initialRemainder,
const unsigned long finalXOR, const int reflectedInput, const int reflectedOutput,
const unsigned char message[], const long startIndex, const long endIndex)
{
// Ensure the width is in range: 1-32 bits
assert(width >= 1 && width <= 32);
// some constant parameters used
const bool b_refInput = (reflectedInput > 0);
const bool b_refOutput = (reflectedOutput > 0);
const unsigned long crcmask = ((((unsigned long)1<<(width-1))-1)<<1)|1;
const unsigned long crchighbit = (unsigned long)1<<(width-1);
unsigned long j, c, bit;
unsigned long crc = initialRemainder;
for (long msgIndex = startIndex; msgIndex <= endIndex; ++msgIndex) {
c = (unsigned long)message[msgIndex];
if (b_refInput) c = reflect(c, 8);
for (j=0x80; j; j>>=1) {
bit = crc & crchighbit;
crc<<= 1;
if (c & j) bit^= crchighbit;
if (bit) crc^= polynominal;
}
}
if (b_refOutput) crc=reflect(crc, width);
crc^= finalXOR;
crc&= crcmask;
return(crc);
}
```

With this code and the CRCs specs listed above, I have been able to re-calculate the following three sample CRCs:

```
10.03.2014 22:20:57.109 [TX] - REQ=INI<CR><LF>
<RS>CRC=4255<CR><LF>
<GS>
10.03.2014 22:20:57.731 [TX] - ANS=INI<CR><LF>
STATUS=0<CR><LF>
<RS>CRC=57654<CR><LF>
<GS>
10.03.2014 22:20:59.323 [TX] - ANS=INI<CR><LF>
STATUS=0<CR><LF>
MID="CTL1"<CR><LF>
DEF="DTLREQ";1025<CR><LF>
INFO=0<CR><LF>
<RS>CRC=1683<CR><LF>
<GS>
```

I failed on the very complex one with the `DEF=`

parts - probably didn't understand the character sequence correctly.

The Docklight script I used to reverse engineer this:

```
Sub crcReverseEngineer()
Dim crctypes(7)
crctypes(0) = "CRC:16,1021,FFFF,0000" ' CCITT
crctypes(1) = "CRC:16,8005,0000,0000" ' CRC-16
crctypes(2) = "CRC:16,8005,FFFF,0000" ' CRC-MODBUS
' lets try also some nonstandard variations with different init and final Xor, but stick
' to the known two polynoms.
crctypes(3) = "CRC:16,1021,FFFF,FFFF"
crctypes(4) = "CRC:16,1021,0000,FFFF"
crctypes(5) = "CRC:16,1021,0000,0000"
crctypes(6) = "CRC:16,8005,FFFF,FFFF"
crctypes(7) = "CRC:16,8005,FFFF,0000"
crcString = "06 1C 52 45 51 3D 49 4E 49 0D 0A 1E 43 52 43 3D 30 30 30 30 0D 0A 1D"
For reflectedInOrOut = 0 To 3
For cType = 0 To 7
crcSpec = crctypes(cType) & "," & IIf(reflectedInOrOut Mod 2 = 1, "Yes", "No") & "," & IIf(reflectedInOrOut > 1, "Yes", "No")
For cStart = 1 To 3
For cEnd = 9 To (Len(crcString) + 1) / 3
subDataString = Mid(crcString, (cStart - 1) * 3 + 1, (cEnd - cStart + 1) * 3)
result = DL.CalcChecksum(crcSpec, subDataString, "H")
resultInt = CLng("&h" + Left(result, 2)) * 256 + CLng("&h" + Right(result, 2))
If resultInt = 4255 Then
DL.AddComment "Found it!"
DL.AddComment "sequence: " & subDataString
DL.AddComment "CRC spec: " & crcSpec
DL.AddComment "CRC result: " & result & " (Integer = " & resultInt & ")"
Exit Sub
End If
Next
Next
Next
Next
End Sub
Public Function IIf(blnExpression, vTrueResult, vFalseResult)
If blnExpression Then
IIf = vTrueResult
Else
IIf = vFalseResult
End If
End Function
```

Hope this helps and I'm happy to provide extra information or clarify details.

thinkis used as the src data for the crc calculation. You should also review the formatting of your data - its not exactly consistent or clear. What is`0D 0A`

for instance? Is it 5 ascii charcaters, or is it 2 characters, whose values are expressed in hexadecimal? Do be aware, that before you can even start to guess at the CRC algo used, and the seed value used, you'll have to work out what you're calculating the CRC of. I.e - is it the CRC of any binary data sent, is it the CRC of the whole line, etc, etc. Big task ahead of you!! – enhzflep Mar 6 '14 at 10:45`R "RC=23947" 0D 0A 1D`

- am I correct in thinking that the`"`

character is there for the reader. I.e this code sends the 8 ascii characters`RC=23497`

, followed immediately by the 3 hex bytes`0D 0A 1D`

. Your post is still really unclear. Think of the data as a map - a map that is still without a key and specified notation. – enhzflep Mar 6 '14 at 11:58