Provided by: avr-libc_2.0.0+Atmel3.6.2-3_all bug

NAME

       util_crc - <util/crc16.h>: CRC Computations

SYNOPSIS

   Functions
       static __inline__ uint16_t _crc16_update (uint16_t __crc, uint8_t __data)
       static __inline__ uint16_t _crc_xmodem_update (uint16_t __crc, uint8_t __data)
       static __inline__ uint16_t _crc_ccitt_update (uint16_t __crc, uint8_t __data)
       static __inline__ uint8_t _crc_ibutton_update (uint8_t __crc, uint8_t __data)
       static __inline__ uint8_t _crc8_ccitt_update (uint8_t __crc, uint8_t __data)

Detailed Description

       #include <util/crc16.h>

       This header file provides a optimized inline functions for calculating cyclic redundancy
       checks (CRC) using common polynomials.

       References:

       See the Dallas Semiconductor app note 27 for 8051 assembler example and general CRC
       optimization suggestions. The table on the last page of the app note is the key to
       understanding these implementations.

       Jack Crenshaw's 'Implementing CRCs' article in the January 1992 isue of Embedded Systems
       Programming. This may be difficult to find, but it explains CRC's in very clear and
       concise terms. Well worth the effort to obtain a copy.

       A typical application would look like:

       // Dallas iButton test vector.
       uint8_t serno[] = { 0x02, 0x1c, 0xb8, 0x01, 0, 0, 0, 0xa2 };

       int
       checkcrc(void)
       {
       uint8_t crc = 0, i;

       for (i = 0; i < sizeof serno / sizeof serno[0]; i++)
           crc = _crc_ibutton_update(crc, serno[i]);

       return crc; // must be 0
       }

Function Documentation

   static __inline__ uint16_t _crc16_update (uint16_t __crc, uint8_t __data) [static]
       Optimized CRC-16 calculation.

       Polynomial: x^16 + x^15 + x^2 + 1 (0xa001)
        Initial value: 0xffff

       This CRC is normally used in disk-drive controllers.

       The following is the equivalent functionality written in C.

       uint16_t
       crc16_update(uint16_t crc, uint8_t a)
       {
       int i;

       crc ^= a;
       for (i = 0; i < 8; ++i)
       {
           if (crc & 1)
           crc = (crc >> 1) ^ 0xA001;
           else
           crc = (crc >> 1);
       }

       return crc;
       }

   static __inline__ uint8_t _crc8_ccitt_update (uint8_t __crc, uint8_t __data) [static]
       Optimized CRC-8-CCITT calculation.

       Polynomial: x^8 + x^2 + x + 1 (0xE0)

       For use with simple CRC-8
        Initial value: 0x0

       For use with CRC-8-ROHC
        Initial value: 0xff
        Reference: http://tools.ietf.org/html/rfc3095#section-5.9.1

       For use with CRC-8-ATM/ITU
        Initial value: 0xff
        Final XOR value: 0x55
        Reference: http://www.itu.int/rec/T-REC-I.432.1-199902-I/en

       The C equivalent has been originally written by Dave Hylands. Assembly code is based on
       _crc_ibutton_update optimization.

       The following is the equivalent functionality written in C.

       uint8_t
       _crc8_ccitt_update (uint8_t inCrc, uint8_t inData)
       {
           uint8_t   i;
           uint8_t   data;

           data = inCrc ^ inData;

           for ( i = 0; i < 8; i++ )
           {
               if (( data & 0x80 ) != 0 )
               {
                   data <<= 1;
                   data ^= 0x07;
               }
               else
               {
                   data <<= 1;
               }
           }
           return data;
       }

   static __inline__ uint16_t _crc_ccitt_update (uint16_t __crc, uint8_t __data) [static]
       Optimized CRC-CCITT calculation.

       Polynomial: x^16 + x^12 + x^5 + 1 (0x8408)
        Initial value: 0xffff

       This is the CRC used by PPP and IrDA.

       See RFC1171 (PPP protocol) and IrDA IrLAP 1.1

       Note
           Although the CCITT polynomial is the same as that used by the Xmodem protocol, they
           are quite different. The difference is in how the bits are shifted through the
           alorgithm. Xmodem shifts the MSB of the CRC and the input first, while CCITT shifts
           the LSB of the CRC and the input first.

       The following is the equivalent functionality written in C.

       uint16_t
       crc_ccitt_update (uint16_t crc, uint8_t data)
       {
           data ^= lo8 (crc);
           data ^= data << 4;

           return ((((uint16_t)data << 8) | hi8 (crc)) ^ (uint8_t)(data >> 4)
                   ^ ((uint16_t)data << 3));
       }

   static __inline__ uint8_t _crc_ibutton_update (uint8_t __crc, uint8_t __data) [static]
       Optimized Dallas (now Maxim) iButton 8-bit CRC calculation.

       Polynomial: x^8 + x^5 + x^4 + 1 (0x8C)
        Initial value: 0x0

       See http://www.maxim-ic.com/appnotes.cfm/appnote_number/27

       The following is the equivalent functionality written in C.

       uint8_t
       _crc_ibutton_update(uint8_t crc, uint8_t data)
       {
       uint8_t i;

       crc = crc ^ data;
       for (i = 0; i < 8; i++)
       {
           if (crc & 0x01)
               crc = (crc >> 1) ^ 0x8C;
           else
               crc >>= 1;
       }

       return crc;
       }

   static __inline__ uint16_t _crc_xmodem_update (uint16_t __crc, uint8_t __data) [static]
       Optimized CRC-XMODEM calculation.

       Polynomial: x^16 + x^12 + x^5 + 1 (0x1021)
        Initial value: 0x0

       This is the CRC used by the Xmodem-CRC protocol.

       The following is the equivalent functionality written in C.

       uint16_t
       crc_xmodem_update (uint16_t crc, uint8_t data)
       {
           int i;

           crc = crc ^ ((uint16_t)data << 8);
           for (i=0; i<8; i++)
           {
               if (crc & 0x8000)
                   crc = (crc << 1) ^ 0x1021;
               else
                   crc <<= 1;
           }

           return crc;
       }

Author

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