srec_fpc(5)

NAME

srec_fpc - four packed code file format

SYNOPSIS

All  ASCII based file formats have one disadvantage in common: they all
need more than double the amount of characters as opposed to the number
of  bytes  to be sent.  Address fields and checksums will add even more
characters.  So the shorter the records, the more characters have to be
sent to get the file across.

The  FPC format helps to reduce the number of characters needed to send
a file in ASCII format, although it still needs  more  characters  than
the  actual  bytes  it  sends.  FPC stands for "Four Packed Code".  The
reduction is accomplished by squeezing 4 real bytes into 5 ASCII  char-
acters.   In  fact every ASCII character will be a digit in the base 85
number system.  There aren't enough  letters,  digits  and  punctuation
marks  available  to  get  85  different characters, but if we use both
upper case and lower case letters we will manage.   This  implies  that
the  FPC  is  case  sensitive, as opposed to all other ASCII based file
formats.

Base 85
The numbering system is in base 85, and is somewhat hard to  understand
for us humans who are usually only familiar with base 10 numbers.  Some
of us understand base 2 and base 16 as well, but base 85  is  for  most
people  something  new.  Luckily we don't have to do any math with this
number system.  We just convert a 32 bit number into a 5  digit  number
in  base  85.   A 32 bit number has a range of 4,294,967,296, while a 5
digit number in base 85 has a range of 4,437,053,125, which  is  enough
to do the trick.  One drawback is that we always have to send multiples
of 4 bytes, even if we actually want to send 1, 2 or 3  bytes.   Unused
bytes are padded with zeroes, and are discarded at the receiving end.

The digits of the base 85 numbering system start at %, which represents
the value of 0.  The highest value of a digit in base 85 is 84, and  is
represented  by  the  character  'z'.  If you want to check this with a
normal ASCII table you will notice that we have used one character  too
many!   Why?  I don't know, but for some reason we have to skip the '*'
character in the row.  This means that after the ')' character  follows
the '+' character.

We can use normal number conversion algorithms to generate the FPC dig-
its, with this tiny difference.  We have to check whether the digit  is
going  to  be equal or larger than the ASCII value for '*'.  If this is
the case we have to increment the digit once to stay clear of the  '*'.
In base 85 MSD digits go first, like in all number systems!

The  benefit  of this all is hopefully clear. For every 4 bytes we only
have to send 5 ASCII characters, as opposed to  8  characters  for  all
other formats.

Records
Now  we  take a look at the the formatting of the FPC records.  We look
at the record at byte level, not at the actual base 85  encoded  level.
Only  after  formatting the FPC record at byte level we convert 4 bytes
at a time to a 5 digit base 85 number.  If we don't have  enough  bytes
in the record to fill the last group of 5 digits we will add bytes with
the value of 0 behind the record.

              +--+----+----+------+----------+----------+
              |$ | ss | cc | ffff | aaaaaaaa | dddddddd |
The field are defined-as:--+------+----------+----------+

$       Every line starts with the character $,  all  other  characters
        are digits of base 85.

ss      The  checksum.  A one byte 2's-complement checksum of all bytes
        of the record.

cc      The byte-count.  A one byte value, counting all  the  bytes  in
        the record minus 4.

ffff    Format code, a two byte value, defining the record type.

aaaaaaaa
        The  address  field.   A  4  byte number representing the first
        address of this record.

dddddddd
        The actual data of this record.

Record Begin
Every record begins with the ASCII character "$".  No  spaces  or  tabs
are allowed in a record.  All other characters in the record are formed
by groups of 5 digits of base 85.

Checksum field
This field is a one byte 2's-complement checksum of the entire  record.
To  create  the checksum make a one byte sum from all of the bytes from
all of the fields of the record:

Then take the 2's-complement of this sum to create the final  checksum.
The 2's-complement is simply inverting all bits and then increment by 1
(or using  the  negative  operator).   Checking  the  checksum  at  the
receivers end is done by adding all bytes together including the check-
sum itself, discarding all carries, and the result must  be  $00.   The
padding  bytes at the end of the line, should they exist, should not be
included in checksum.  But it doesn't really matter if  they  are,  for
their influence will be 0 anyway.

Byte Count
The  byte  count  cc  counts  the number of bytes in the current record
minus 4.  So only the number of address bytes and the  data  bytes  are
counted  and  not the first 4 bytes of the record (checksum, byte count
and format flags).  The byte count can have any value from 0 to 255.

Usually records have 32 data bytes.  It is not recommended to send  too
many data bytes in a record for that may increase the transmission time
in case of errors.  Also avoid  sending  only  a  few  data  bytes  per
record, because the address overhead will be too heavy in comparison to
the payload.

Format Flags
This is a 2 byte number, indicating what format is represented in  this
record.   Only a few formats are available, so we actually waste 1 byte
in each record for the sake of having multiples of 4 bytes.

Format code 0 means that the address field in  this  record  is  to  be
treated as the absolute address where the first data byte of the record
should be stored.

Format code 1 means that the address field in this record  is  missing.
Simply  the  last  known  address  of the previous record +1 is used to
store the first data byte.  As if the FPC  format  wasn't  fast  enough
already ;-)

Format  code  2  means  that  the address field in this record is to be
treated as a relative address.  Relative to what is not  really  clear.
The relative address will remain in effect until an absolute address is
received again.

Address Field
The first data byte of the record is stored in the address specified by
the  Address field aaaaaaaa.  After storing that data byte, the address
is incremented by 1 to point to the address for the next data  byte  of
the record.  And so on, until all data bytes are stored.

The  length  of  the  address  field  is  always 4 bytes, if present of
course.  So the address range for the FPC format is always 2**32.

If only the address field is given, without any data bytes, the address
will be set as starting address for records that have no address field.

Addresses between records are non sequential.  There may be gaps in the
addressing or the address pointer may even point to lower addresses  as
before  in  the  same  file.  But every time the sequence of addressing
must be changed, a format 0 record must be used.  Addressing within one
single record is sequential of course.

Data Field
This  field  contains  0 or more data bytes.  The actual number of data
bytes is indicated by the byte count in the  beginning  of  the  record
less the number of address bytes.  The first data byte is stored in the
location indicated by the address in the address field.  After that the
address  is  incremented  by 1 and the next data byte is stored in that
new location.  This continues until all bytes are stored.  If there are
not  enough data bytes to obtain a multiple of 4 we use 0x00 as padding
bytes at the end of the record.  These padding bytes are ignored on the
receiving side.

End of File
End  of  file  is  recognized if the first four bytes of the record all
contain 0x00.  In base 85 this will be  "$%%%%%".   This  is  the  only
decent way to terminate the file.

Size Multiplier
In general, binary data will expand in sized by approximately 1.7 times
when represented with this format.

Example

Now it's time for an example. In the first table you can see the byte representation of the file to be transferred. The 4th row of bytes is not a multiple of 4 bytes. But that does not matter, for we append $00 bytes at the end until we do have a multiple of 4 bytes. These padding bytes are not counted in the byte count however!

D81400000000B000576F77212044696420796F7520726561
431400000000B0106C6C7920676F207468726F7567682061
361400000000B0206C6C20746861742074726F75626C6520
591100000000B030746F207265616420746869733F000000
00000000

Only after converting the bytes to base 85 we get the records of the FPC type file format presented in the next table. Note that there is always a multiple of 5 characters to represent a multiple of 4 bytes in each record.

$kL&@h%%,:,B.\?00EPuX0K3rO0JI))
$;UPR'%%,:<Hn&FCG:at<GVF(;G9wIw
$7FD1p%%,:LHmy:>GTV%/KJ7@GE[kYz
$B[6\;%%,:\KIn?GFWY/qKI1G5:;-_e
$%%%%%

As you can see the length of the lines is clearly shorter than the original ASCII lines.

SEE ALSO

http://sbprojects.fol.nl/knowledge/fileformats/fpc.htm

AUTHOR

This man page was taken from the above Web page. It was written by San Bergmans <sanmail@bigfoot.com>

For extra points: Who invented this format? Where is it used?

Reference Manual SRecord srec_fpc(5)