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| author | Juan J. Martinez <jjm@usebox.net> | 2020-12-30 19:07:31 +0000 |
|---|---|---|
| committer | Juan J. Martinez <jjm@usebox.net> | 2020-12-30 19:23:41 +0000 |
| commit | 2682bc5d1d864341aaeb42a449db73c3ecd16d70 (patch) | |
| tree | 9116764364b4ee0ce7f6037305077807b57776de /tools/hex2bin-2.0/doc/srec.txt | |
| download | ubox-msx-lib-2682bc5d1d864341aaeb42a449db73c3ecd16d70.tar.gz ubox-msx-lib-2682bc5d1d864341aaeb42a449db73c3ecd16d70.zip | |
Initial import1.0
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| -rw-r--r-- | tools/hex2bin-2.0/doc/srec.txt | 447 |
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diff --git a/tools/hex2bin-2.0/doc/srec.txt b/tools/hex2bin-2.0/doc/srec.txt new file mode 100644 index 0000000..ea63d31 --- /dev/null +++ b/tools/hex2bin-2.0/doc/srec.txt @@ -0,0 +1,447 @@ +S-Records
+
+
+ -S-Record Format-
+
+ Chaplin@keinstr.uucp (Roger Chaplin) reposted an article written
+ by mcdchg!motmpl!ron (Ron Widell) that explained how Motorola
+ S-Records are formatted. This comes from a unix man page. No
+ mention of which version of Unix is specified. This section
+ of the FAQ is a bit long. An anonymous ftp archive is currently
+ being sought. When one is found, the section will be placed in
+ the archive.
+
+
+ SREC(4) UNIX 5.0 (03/21/84) SREC(4)
+
+
+ An S-record file consists of a sequence of specially formatted
+ ASCII character strings. An S-record will be less than or equal to
+ 78 bytes in length.
+
+ The order of S-records within a file is of no significance and no
+ particular order may be assumed.
+
+ The general format of an S-record follow:
+
+ +------------------//-------------------//-----------------------+
+ | type | count | address | data | checksum |
+ +------------------//-------------------//-----------------------+
+
+ type A char-2- field. These characters describe the
+ type of record (S0, S1, S2, S3, S5, S7, S8, or
+ S9).
+ count A char-2- field. These characters when paired and
+ interpreted as a hexadecimal value, display the
+ count of remaining character pairs in the record.
+
+ address A char-4,6, or 8- field. These characters grouped
+ and interpreted as a hexadecimal value, display
+ the address at which the data field is to be
+ loaded into memory. The length of the field
+ depends on the number of bytes necessary to hold
+ the address. A 2-byte address uses 4 characters,
+ a 3-byte address uses 6 characters, and a 4-byte
+ address uses 8 characters.
+ data A char -0-64- field. These characters when paired
+ and interpreted as hexadecimal values represent
+ the memory loadable data or descriptive
+ information.
+
+ checksum A char-2- field. These characters when paired and
+ interpreted as a hexadecimal value display the
+ least significant byte of the ones complement of
+ the sum of the byte values represented by the
+ pairs of characters making up the count, the
+ address, and the data fields.
+
+ Each record is terminated with a line feed. If any
+ additional or different record terminator(s) or delay
+ characters are needed during transmission to the target
+ system it is the responsibility of the transmitting program
+ to provide them.
+
+ S0 Record The type of record is 'S0' (0x5330). The address
+
+
+ field is unused and will be filled with zeros
+ (0x0000). The header information within the data
+ field is divided into the following subfields.
+
+ mname is char-20- and is the
+ module name.
+ ver is char-2- and is the
+ version number.
+
+ rev is char-2- and is the
+ revision number.
+ description is char-0-36- and is a
+ text comment.
+
+ Each of the subfields is composed of ASCII bytes
+ whose associated characters, when paired,
+ represent one byte hexadecimal values in the case
+ of the version and revision numbers, or represent
+ the hexadecimal values of the ASCII characters
+ comprising the module name and description.
+
+ S1 Record The type of record field is 'S1' (0x5331). The
+ address field is interpreted as a 2-byte address.
+ The data field is composed of memory loadable
+ data.
+ S2 Record The type of record field is 'S2' (0x5332). The
+ address field is interpreted as a 3-byte address.
+ The data field is composed of memory loadable
+ data.
+
+ S3 Record The type of record field is 'S3' (0x5333). The
+ address field is interpreted as a 4-byte address.
+ The data field is composed of memory loadable
+ data.
+ S5 Record The type of record field is 'S5' (0x5335). The
+ address field is interpreted as a 2-byte value
+ and contains the count of S1, S2, and S3 records
+ previously transmitted. There is no data field.
+
+ S7 Record The type of record field is 'S7' (0x5337). The
+ address field contains the starting execution
+ address and is interpreted as 4-byte address.
+ There is no data field.
+ S8 Record The type of record field is 'S8' (0x5338). The
+ address field contains the starting execution
+ address and is interpreted as 3-byte address.
+ There is no data field.
+
+ S9 Record The type of record field is 'S9' (0x5339). The
+ address field contains the starting execution
+ address and is interpreted as 2-byte address.
+ There is no data field.
+
+ EXAMPLE
+
+ Shown below is a typical S-record format file.
+
+ S00600004844521B
+ S1130000285F245F2212226A000424290008237C2A
+ S11300100002000800082629001853812341001813
+ S113002041E900084E42234300182342000824A952
+ S107003000144ED492
+ S5030004F8
+ S9030000FC
+
+ The file consists of one S0 record, four S1 records, one S5
+ record and an S9 record.
+
+ The S0 record is comprised as follows:
+
+ S0 S-record type S0, indicating it is a header
+ record.
+ 06 Hexadecimal 06 (decimal 6), indicating that six
+ character pairs (or ASCII bytes) follow.
+
+ 00 00 Four character 2-byte address field, zeroes in
+ this example.
+ 48 ASCII H, D, and R - "HDR".
+
+ 1B The checksum.
+
+ The first S1 record is comprised as follows:
+ S1 S-record type S1, indicating it is a data record
+ to be loaded at a 2-byte address.
+
+ 13 Hexadecimal 13 (decimal 19), indicating that
+ nineteen character pairs, representing a 2 byte
+ address, 16 bytes of binary data, and a 1 byte
+ checksum, follow.
+ 00 00 Four character 2-byte address field; hexadecimal
+ address 0x0000, where the data which follows is to
+ be loaded.
+
+ 28 5F 24 5F 22 12 22 6A 00 04 24 29 00 08 23 7C Sixteen
+ character pairs representing the actual binary
+ data.
+ 2A The checksum.
+
+ The second and third S1 records each contain 0x13 (19)
+ character pairs and are ended with checksums of 13 and 52,
+ respectively. The fourth S1 record contains 07 character
+ pairs and has a checksum of 92.
+
+ The S5 record is comprised as follows:
+
+ S5 S-record type S5, indicating it is a count record
+ indicating the number of S1 records.
+
+
+
+ 03 Hexadecimal 03 (decimal 3), indicating that three
+ character pairs follow.
+
+ 00 04 Hexadecimal 0004 (decimal 4), indicating that
+ there are four data records previous to this
+ record.
+ F8 The checksum.
+
+ The S9 record is comprised as follows:
+
+ S9 S-record type S9, indicating it is a termination
+ record.
+ 03 Hexadecimal 03 (decimal 3), indicating that three
+ character pairs follow.
+
+ 00 00 The address field, hexadecimal 0 (decimal 0)
+ indicating the starting execution address.
+ FC The checksum.
+
+
+ -Intel Hex ASCII Format-
+
+ Intel HEX-ASCII format takes the form:
+
+ +----------------------------------- Start Character
+ |
+ | +-------------------------------- Byte Count
+ | | (# of data bytes)
+ | |
+ | | +-------------------------- Address of first data.
+ | | |
+ | | | +-------------------- Record Type (00 data,
+ | | | | 01 end of record)
+ | | | |
+ | | | | +------------ Data Bytes
+ | | | | |
+ | | | | | +---- Checksum
+ | | | | | |
+ | / \ / \ / \ / \ / \
+ : B C A A A A T T H H ... H H C C
+
+ An examples:
+
+ :10000000DB00E60F5F1600211100197ED300C3004C
+ :1000100000000101030307070F0F1F1F3F3F7F7FF2
+ :01002000FFE0
+ :00000001FF
+
+ This information comes from _Microprocessors and Programmed
+ Logic_, Second Edition, Kenneth L. Short, 1987, Prentice-Hall,
+ ISBN 0-13-580606-2.
+
+ Provisions have been made for data spaces larger than 64 kBytes.
+ The above reference does not discuss them. I suspect there is
+ a start of segment type record, but I do not know how it is
+ implemented.
+
+----------------------------------------------------------------------------
+
+/* This file contains source code to read a Motorola S-record file into
+** a memory image. The size of the file cannot exceed BUFSIZE of data.
+** The image is then written to disk either as binary data starting at
+** address 0 with no data gaps, or as a C array of unsigned longs.
+** Input lines must be no longer than MAXLINE. No check is made!
+**
+** Author: Eric McRae, Electro-Logic Machines, Inc.
+** Date: Copyright 1994
+**
+** This source code is made available to the public "as is". No
+** warranty is given or implied for it's proper operation. This source
+** code may be used in whole or in part as long as this copyright is
+** included.
+*/
+#include <stdio.h>
+#include <stdlib.h>
+#include <string.h>
+
+/* Comment the following line for non PC applications */
+#define PCDOS
+
+/* Uncomment the following line if you want a binary output instead of
+** a structure
+*/
+/* #define BINARY */
+
+#ifdef PCDOS /* Intel x86 architecture */
+#define BUFSIZE 49152 /* 48K to avoid segment hopping */
+#else /* Any reasonable (non-segmented) arch... */
+#define BUFSIZE 65536 /* As big as you want */
+#endif
+
+#define MAXLINE 256 /* Length of longest input line + 1 */
+/* Globals */
+FILE *infilePH, *outfilePH; /* Handles for input and output files */
+unsigned char *bufAC, /* Allocated image buffer */
+ *highestPC = NULL; /* Highest buffer address written */
+
+/* Change this string to reflect the name of the output array */
+char headerAC[] = "unsigned long sRec[] =\n{\n";
+
+/* Predeclarations */
+int parsebufN( char * ); /* Does the actual parsing */
+
+void main(int argc, const char * argv[])
+{
+ int c, /* Temp char storage */
+ resN; /* result status */
+ char *lbufPC, lbufAC[MAXLINE];
+ int linectrN = 0; /* Used to correlate parse fail to input line */
+
+#ifndef BINARY
+ int i;
+ unsigned long *codePL;
+ unsigned char *codePC;
+#endif
+
+ /* Check the argument count */
+ if( argc != 3 ) /* If didn't specify input and output files */
+ {
+ printf("Usage: %s: infile outfile\n", argv[0] );
+ exit(1);
+ }
+
+ /* OK, let's open some files */
+ if( ( infilePH = fopen( argv[1], "r" ) )== NULL )
+ {
+ printf("%s: Couldn't open input file %s\n", argv[0], argv[1] );
+ exit(2);
+ }
+
+ if( ( outfilePH = fopen( argv[2], "w" ) ) == NULL )
+ {
+ printf("%s: Couldn't open output file %s\n", argv[0], argv[3] );
+ exit(3);
+ }
+
+ /* OK, get a buffer and clear it. */
+ if( (bufAC = calloc( (size_t)BUFSIZE, (size_t)1 )) == NULL )
+ {
+ printf("%s: Couldn't malloc memory for buffer\n", argv[0] );
+ exit(4);
+ }
+
+ lbufPC = lbufAC; /* Point at beginning of line buffer */
+ while( c = fgetc( infilePH ))
+ {
+ if( (c == '\n') || (c == EOF) ) /* If found end of line or file */
+ { /* Parse the Line */
+ if( ( c == EOF ) && ( ferror( infilePH ) ) )
+ {
+ printf("%s: Error reading input file\n", argv[0] );
+ exit(5);
+ }
+ else
+ { /* OK, have a complete line in buffer */
+ linectrN++; /* Increment line counter */
+ if( lbufPC == lbufAC )
+ break; /* ignore blank lines */
+ *lbufPC = 0; /* Terminate the line string */
+ if( resN = parsebufN( lbufAC ) ) /* Parse data record to mem */
+ {
+ printf("%s: Error reading input file at line %d, return code = %d\n",
+ argv[0], linectrN, resN );
+ exit( resN );
+ }
+ lbufPC = lbufAC; /* Repoint line buffer pointer */
+ } /* End of have a complete line */
+ }
+ else
+ *lbufPC++ = c; /* Place char into line buffer */
+ }
+
+ /* At this point, the input file has been emptied. Now dispose of the
+ ** output data according to compilation mode.
+ */
+
+#ifdef BINARY
+
+ /* Write the buffer back to disk as a binary image */
+ resN = fwrite( bufAC, 1, (size_t)((highestPC - bufAC) + 1), outfilePH );
+ if( resN != (int)( (highestPC - bufAC) + 1) )
+ {
+ printf("%s: Error writing output file\n", argv[0] );
+ exit( 6 );
+ }
+
+#else
+ /* Produce a file that can be included in a C program. Data is read
+ ** from buffer as bytes to avoid portability/endian problems with
+ ** this program.
+ */
+ /* Output header first, then 1 long per line */
+ fwrite( (void *)headerAC, 1, (size_t)(sizeof( headerAC )-1), outfilePH );
+
+ codePL = (unsigned long *)bufAC;
+ for( i = (highestPC - bufAC + 1) / 4; i; i-- ) /* for each long */
+ {
+ codePC = (unsigned char *)codePL++;
+ sprintf(lbufAC, "0x%02x%02x%02x%02x%s",
+ *codePC, *(codePC + 1), *(codePC + 2), *(codePC + 3),
+ i == 1 ? "\n" : ",\n" ); /* No comma after final long */
+ fwrite( lbufAC, 1, (size_t)(strlen( lbufAC )), outfilePH );
+ }
+ /* OK, data has been written out, close end of array */
+ fwrite( "};\n", 1, (size_t)3, outfilePH );
+#endif
+}
+
+/* Function: parsebufV
+** Parses an S-record in the buffer and writes it into the buffer
+** if it is has a valid checksum.
+**
+** Args: pointer to character buffer for null terminated line
+** Returns: int result code: 0 = success, else failure
+*/
+int parsebufN( char *lbufPC )
+{
+ unsigned long addrL;
+ unsigned char cksmB, /* checksum of addr, count, & data length */
+ *bufPC; /* Pointer into memory array */
+ int i, countN, /* Number of bytes represented in record */
+ oheadN, /* Number of overhead (addr + chksum) bytes */
+ tvalN; /* Temp for check checksum */
+
+ switch( *(lbufPC+1) ) /* examine 2nd character on the line */
+ {
+ case '1': /* 16 bit address field */
+ if( sscanf(lbufPC, "S1%2x%4lx", &countN, &addrL ) != 2 )
+ return( 10 ); /* Flag error in S1 record */
+ oheadN = 3; /* 2 address + 1 checksum */
+ break;
+
+ case '2': /* 24 bit address field */
+ if( sscanf(lbufPC, "S2%2x%6lx", &countN, &addrL ) != 2 )
+ return( 11 ); /* Flag error in S2 record */
+ oheadN = 4; /* 3 address + 1 checksum */
+ break;
+
+ case '3': /* 32 bit address field */
+ if( sscanf(lbufPC, "S3%2x%8lx", &countN, &addrL ) != 2 )
+ return( 12 ); /* Flag error in S3 record */
+ oheadN = 5; /* 4 address + 1 checksum */
+ break;
+
+ default: /* ignore all but S1,2,3 records. */
+ return( 0 );
+ }
+
+ if( addrL > BUFSIZE ) return( 13 ); /* if address exceeds buffer size */
+ bufPC = bufAC + addrL; /* otherwise, point to right spot in buffer */
+
+ /* OK now see if checksum is OK, while reading data to buffer */
+ cksmB = 0;
+ countN++; /* Bump counter to read final checksum too */
+ for( i = 1; i <= countN; i++ )
+ {
+ sscanf( lbufPC + i*2, "%2x", &tvalN ); /* Scan a 2 hex digit byte */
+ cksmB += (unsigned char)tvalN;
+ if( ( i > oheadN ) && ( i < countN ) ) /* If scanned a data byte */
+ *bufPC++ = (unsigned char) tvalN; /* write it to the buffer */
+ }
+ if( cksmB += 1 ) return( 14 ); /* flag checksum error */
+
+ if( (bufPC - 1) > highestPC )
+ highestPC = bufPC - 1; /* track highest address loaded */
+
+ return( 0 ); /* Successful return */
+}
+
+
+
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