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/* composite.c - Handles GS1 Composite Symbols */
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/*
libzint - the open source barcode library
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Copyright ( C ) 2008 - 2016 Robin Stuart < rstuart114 @ gmail . com >
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Redistribution and use in source and binary forms , with or without
modification , are permitted provided that the following conditions
are met :
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1. Redistributions of source code must retain the above copyright
notice , this list of conditions and the following disclaimer .
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2. Redistributions in binary form must reproduce the above copyright
notice , this list of conditions and the following disclaimer in the
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documentation and / or other materials provided with the distribution .
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3. Neither the name of the project nor the names of its contributors
may be used to endorse or promote products derived from this software
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without specific prior written permission .
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THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS " AS IS " AND
ANY EXPRESS OR IMPLIED WARRANTIES , INCLUDING , BUT NOT LIMITED TO , THE
IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
ARE DISCLAIMED . IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE
FOR ANY DIRECT , INDIRECT , INCIDENTAL , SPECIAL , EXEMPLARY , OR CONSEQUENTIAL
DAMAGES ( INCLUDING , BUT NOT LIMITED TO , PROCUREMENT OF SUBSTITUTE GOODS
OR SERVICES ; LOSS OF USE , DATA , OR PROFITS ; OR BUSINESS INTERRUPTION )
HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY , WHETHER IN CONTRACT , STRICT
LIABILITY , OR TORT ( INCLUDING NEGLIGENCE OR OTHERWISE ) ARISING IN ANY WAY
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OUT OF THE USE OF THIS SOFTWARE , EVEN IF ADVISED OF THE POSSIBILITY OF
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SUCH DAMAGE .
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*/
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/* The functions "getBit", "init928" and "encode928" are copyright BSI and are
released with permission under the following terms :
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" Copyright subsists in all BSI publications. BSI also holds the copyright, in the
UK , of the international standardisation bodies . Except as
permitted under the Copyright , Designs and Patents Act 1988 no extract may be
reproduced , stored in a retrieval system or transmitted in any form or by any
means - electronic , photocopying , recording or otherwise - without prior written
permission from BSI .
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" This does not preclude the free use, in the course of implementing the standard,
of necessary details such as symbols , and size , type or grade designations . If these
details are to be used for any other purpose than implementation then the prior
written permission of BSI must be obtained . "
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The date of publication for these functions is 31 May 2006
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*/
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# include <stdio.h>
# include <string.h>
# include <stdlib.h>
# include <math.h>
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# ifdef _MSC_VER
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# include <malloc.h>
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# endif
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# include "common.h"
# include "large.h"
# include "composite.h"
# include "pdf417.h"
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# include "gs1.h"
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# define UINT unsigned short
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extern int general_rules ( char field [ ] , char type [ ] ) ;
extern int eanx ( struct zint_symbol * symbol , unsigned char source [ ] , int length ) ;
extern int ean_128 ( struct zint_symbol * symbol , unsigned char source [ ] , int length ) ;
extern int rss14 ( struct zint_symbol * symbol , unsigned char source [ ] , int length ) ;
extern int rsslimited ( struct zint_symbol * symbol , unsigned char source [ ] , int length ) ;
extern int rssexpanded ( struct zint_symbol * symbol , unsigned char source [ ] , int length ) ;
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static UINT pwr928 [ 69 ] [ 7 ] ;
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int _min ( int first , int second ) {
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if ( first < = second )
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return first ;
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else
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return second ;
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}
/* gets bit in bitString at bitPos */
int getBit ( UINT * bitStr , int bitPos ) {
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return ! ! ( bitStr [ bitPos > > 4 ] & ( 0x8000 > > ( bitPos & 15 ) ) ) ;
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}
/* initialize pwr928 encoding table */
void init928 ( void ) {
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int i , j , v ;
int cw [ 7 ] ;
cw [ 6 ] = 1L ;
for ( i = 5 ; i > = 0 ; i - - )
cw [ i ] = 0 ;
for ( i = 0 ; i < 7 ; i + + )
pwr928 [ 0 ] [ i ] = cw [ i ] ;
for ( j = 1 ; j < 69 ; j + + ) {
for ( v = 0 , i = 6 ; i > = 1 ; i - - ) {
v = ( 2 * cw [ i ] ) + ( v / 928 ) ;
pwr928 [ j ] [ i ] = cw [ i ] = v % 928 ;
}
pwr928 [ j ] [ 0 ] = cw [ 0 ] = ( 2 * cw [ 0 ] ) + ( v / 928 ) ;
}
return ;
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}
/* converts bit string to base 928 values, codeWords[0] is highest order */
int encode928 ( UINT bitString [ ] , UINT codeWords [ ] , int bitLng ) {
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int i , j , b , bitCnt , cwNdx , cwCnt , cwLng ;
for ( cwNdx = cwLng = b = 0 ; b < bitLng ; b + = 69 , cwNdx + = 7 ) {
bitCnt = _min ( bitLng - b , 69 ) ;
cwLng + = cwCnt = bitCnt / 10 + 1 ;
for ( i = 0 ; i < cwCnt ; i + + )
codeWords [ cwNdx + i ] = 0 ; /* init 0 */
for ( i = 0 ; i < bitCnt ; i + + ) {
if ( getBit ( bitString , b + bitCnt - i - 1 ) ) {
for ( j = 0 ; j < cwCnt ; j + + )
codeWords [ cwNdx + j ] + = pwr928 [ i ] [ j + 7 - cwCnt ] ;
}
}
for ( i = cwCnt - 1 ; i > 0 ; i - - ) {
/* add "carries" */
codeWords [ cwNdx + i - 1 ] + = codeWords [ cwNdx + i ] / 928L ;
codeWords [ cwNdx + i ] % = 928L ;
}
}
return ( cwLng ) ;
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}
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/* CC-A 2D component */
int cc_a ( struct zint_symbol * symbol , char source [ ] , int cc_width ) {
int i , strpos , segment , bitlen , cwCnt , variant , rows ;
int k , offset , j , total , rsCodeWords [ 8 ] ;
int LeftRAPStart , RightRAPStart , CentreRAPStart , StartCluster ;
int LeftRAP , RightRAP , CentreRAP , Cluster , dummy [ 5 ] ;
int writer , flip , loop ;
UINT codeWords [ 28 ] ;
UINT bitStr [ 13 ] ;
char codebarre [ 100 ] , pattern [ 580 ] ;
char local_source [ 210 ] ; /* A copy of source but with padding zeroes to make 208 bits */
variant = 0 ;
for ( i = 0 ; i < 13 ; i + + ) {
bitStr [ i ] = 0 ;
}
for ( i = 0 ; i < 28 ; i + + ) {
codeWords [ i ] = 0 ;
}
bitlen = strlen ( source ) ;
for ( i = 0 ; i < 208 ; i + + ) {
local_source [ i ] = ' 0 ' ;
}
for ( i = 0 ; i < bitlen ; i + + ) {
local_source [ i ] = source [ i ] ;
}
local_source [ 208 ] = ' \0 ' ;
for ( segment = 0 ; segment < 13 ; segment + + ) {
strpos = segment * 16 ;
for ( i = 0 ; i < 16 ; i + + ) {
if ( local_source [ strpos + i ] = = ' 1 ' ) {
bitStr [ segment ] + = ( 0x8000 > > i ) ;
}
}
}
init928 ( ) ;
/* encode codeWords from bitStr */
cwCnt = encode928 ( bitStr , codeWords , bitlen ) ;
switch ( cc_width ) {
case 2 :
switch ( cwCnt ) {
case 6 : variant = 0 ;
break ;
case 8 : variant = 1 ;
break ;
case 9 : variant = 2 ;
break ;
case 11 : variant = 3 ;
break ;
case 12 : variant = 4 ;
break ;
case 14 : variant = 5 ;
break ;
case 17 : variant = 6 ;
break ;
}
break ;
case 3 :
switch ( cwCnt ) {
case 8 : variant = 7 ;
break ;
case 10 : variant = 8 ;
break ;
case 12 : variant = 9 ;
break ;
case 14 : variant = 10 ;
break ;
case 17 : variant = 11 ;
break ;
}
break ;
case 4 :
switch ( cwCnt ) {
case 8 : variant = 12 ;
break ;
case 11 : variant = 13 ;
break ;
case 14 : variant = 14 ;
break ;
case 17 : variant = 15 ;
break ;
case 20 : variant = 16 ;
break ;
}
break ;
}
rows = ccaVariants [ variant ] ;
k = ccaVariants [ 17 + variant ] ;
offset = ccaVariants [ 34 + variant ] ;
/* Reed-Solomon error correction */
for ( i = 0 ; i < 8 ; i + + ) {
rsCodeWords [ i ] = 0 ;
}
total = 0 ;
for ( i = 0 ; i < cwCnt ; i + + ) {
total = ( codeWords [ i ] + rsCodeWords [ k - 1 ] ) % 929 ;
for ( j = k - 1 ; j > = 0 ; j - - ) {
if ( j = = 0 ) {
rsCodeWords [ j ] = ( 929 - ( total * ccaCoeffs [ offset + j ] ) % 929 ) % 929 ;
} else {
rsCodeWords [ j ] = ( rsCodeWords [ j - 1 ] + 929 - ( total * ccaCoeffs [ offset + j ] ) % 929 ) % 929 ;
}
}
}
for ( j = 0 ; j < k ; j + + ) {
if ( rsCodeWords [ j ] ! = 0 ) {
rsCodeWords [ j ] = 929 - rsCodeWords [ j ] ;
}
}
for ( i = k - 1 ; i > = 0 ; i - - ) {
codeWords [ cwCnt ] = rsCodeWords [ i ] ;
cwCnt + + ;
}
/* Place data into table */
LeftRAPStart = aRAPTable [ variant ] ;
CentreRAPStart = aRAPTable [ variant + 17 ] ;
RightRAPStart = aRAPTable [ variant + 34 ] ;
StartCluster = aRAPTable [ variant + 51 ] / 3 ;
LeftRAP = LeftRAPStart ;
CentreRAP = CentreRAPStart ;
RightRAP = RightRAPStart ;
Cluster = StartCluster ; /* Cluster can be 0, 1 or 2 for Cluster(0), Cluster(3) and Cluster(6) */
for ( i = 0 ; i < rows ; i + + ) {
strcpy ( codebarre , " " ) ;
offset = 929 * Cluster ;
for ( j = 0 ; j < 5 ; j + + ) {
dummy [ j ] = 0 ;
}
for ( j = 0 ; j < cc_width ; j + + ) {
dummy [ j + 1 ] = codeWords [ i * cc_width + j ] ;
}
/* Copy the data into codebarre */
concat ( codebarre , RAPLR [ LeftRAP ] ) ;
concat ( codebarre , " 1 " ) ;
concat ( codebarre , codagemc [ offset + dummy [ 1 ] ] ) ;
concat ( codebarre , " 1 " ) ;
if ( cc_width = = 3 ) {
concat ( codebarre , RAPC [ CentreRAP ] ) ;
}
if ( cc_width > = 2 ) {
concat ( codebarre , " 1 " ) ;
concat ( codebarre , codagemc [ offset + dummy [ 2 ] ] ) ;
concat ( codebarre , " 1 " ) ;
}
if ( cc_width = = 4 ) {
concat ( codebarre , RAPC [ CentreRAP ] ) ;
}
if ( cc_width > = 3 ) {
concat ( codebarre , " 1 " ) ;
concat ( codebarre , codagemc [ offset + dummy [ 3 ] ] ) ;
concat ( codebarre , " 1 " ) ;
}
if ( cc_width = = 4 ) {
concat ( codebarre , " 1 " ) ;
concat ( codebarre , codagemc [ offset + dummy [ 4 ] ] ) ;
concat ( codebarre , " 1 " ) ;
}
concat ( codebarre , RAPLR [ RightRAP ] ) ;
concat ( codebarre , " 1 " ) ; /* stop */
/* Now codebarre is a mixture of letters and numbers */
writer = 0 ;
flip = 1 ;
strcpy ( pattern , " " ) ;
for ( loop = 0 ; loop < strlen ( codebarre ) ; loop + + ) {
if ( ( codebarre [ loop ] > = ' 0 ' ) & & ( codebarre [ loop ] < = ' 9 ' ) ) {
for ( k = 0 ; k < ctoi ( codebarre [ loop ] ) ; k + + ) {
if ( flip = = 0 ) {
pattern [ writer ] = ' 0 ' ;
} else {
pattern [ writer ] = ' 1 ' ;
}
writer + + ;
}
pattern [ writer ] = ' \0 ' ;
if ( flip = = 0 ) {
flip = 1 ;
} else {
flip = 0 ;
}
} else {
lookup ( BRSET , PDFttf , codebarre [ loop ] , pattern ) ;
writer + = 5 ;
}
}
symbol - > width = writer ;
/* so now pattern[] holds the string of '1's and '0's. - copy this to the symbol */
for ( loop = 0 ; loop < strlen ( pattern ) ; loop + + ) {
if ( pattern [ loop ] = = ' 1 ' ) {
set_module ( symbol , i , loop ) ;
}
}
symbol - > row_height [ i ] = 2 ;
symbol - > rows + + ;
/* Set up RAPs and Cluster for next row */
LeftRAP + + ;
CentreRAP + + ;
RightRAP + + ;
Cluster + + ;
if ( LeftRAP = = 53 ) {
LeftRAP = 1 ;
}
if ( CentreRAP = = 53 ) {
CentreRAP = 1 ;
}
if ( RightRAP = = 53 ) {
RightRAP = 1 ;
}
if ( Cluster = = 3 ) {
Cluster = 0 ;
}
}
return 0 ;
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}
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/* CC-B 2D component */
int cc_b ( struct zint_symbol * symbol , char source [ ] , int cc_width ) {
int length , i , binloc ;
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# ifndef _MSC_VER
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unsigned char data_string [ ( strlen ( source ) / 8 ) + 3 ] ;
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# else
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unsigned char * data_string = ( unsigned char * ) _alloca ( ( strlen ( source ) / 8 ) + 3 ) ;
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# endif
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int chainemc [ 180 ] , mclength ;
int k , j , longueur , mccorrection [ 50 ] , offset ;
int total , dummy [ 5 ] ;
char codebarre [ 100 ] , pattern [ 580 ] ;
int variant , LeftRAPStart , CentreRAPStart , RightRAPStart , StartCluster ;
int LeftRAP , CentreRAP , RightRAP , Cluster , writer , flip , loop ;
length = strlen ( source ) / 8 ;
for ( i = 0 ; i < length ; i + + ) {
binloc = i * 8 ;
data_string [ i ] = 0 ;
for ( int p = 0 ; p < 8 ; p + + ) {
if ( source [ binloc + p ] = = ' 1 ' ) {
data_string [ i ] + = ( 0x80 > > p ) ;
}
}
}
mclength = 0 ;
/* "the CC-B component shall have codeword 920 in the first symbol character position" (section 9a) */
chainemc [ mclength ] = 920 ;
mclength + + ;
byteprocess ( chainemc , & mclength , data_string , 0 , length , 0 ) ;
/* Now figure out which variant of the symbol to use and load values accordingly */
variant = 0 ;
if ( cc_width = = 2 ) {
variant = 13 ;
if ( mclength < = 33 ) {
variant = 12 ;
}
if ( mclength < = 29 ) {
variant = 11 ;
}
if ( mclength < = 24 ) {
variant = 10 ;
}
if ( mclength < = 19 ) {
variant = 9 ;
}
if ( mclength < = 13 ) {
variant = 8 ;
}
if ( mclength < = 8 ) {
variant = 7 ;
}
}
if ( cc_width = = 3 ) {
variant = 23 ;
if ( mclength < = 70 ) {
variant = 22 ;
}
if ( mclength < = 58 ) {
variant = 21 ;
}
if ( mclength < = 46 ) {
variant = 20 ;
}
if ( mclength < = 34 ) {
variant = 19 ;
}
if ( mclength < = 24 ) {
variant = 18 ;
}
if ( mclength < = 18 ) {
variant = 17 ;
}
if ( mclength < = 14 ) {
variant = 16 ;
}
if ( mclength < = 10 ) {
variant = 15 ;
}
if ( mclength < = 6 ) {
variant = 14 ;
}
}
if ( cc_width = = 4 ) {
variant = 34 ;
if ( mclength < = 108 ) {
variant = 33 ;
}
if ( mclength < = 90 ) {
variant = 32 ;
}
if ( mclength < = 72 ) {
variant = 31 ;
}
if ( mclength < = 54 ) {
variant = 30 ;
}
if ( mclength < = 39 ) {
variant = 29 ;
}
if ( mclength < = 30 ) {
variant = 28 ;
}
if ( mclength < = 24 ) {
variant = 27 ;
}
if ( mclength < = 18 ) {
variant = 26 ;
}
if ( mclength < = 12 ) {
variant = 25 ;
}
if ( mclength < = 8 ) {
variant = 24 ;
}
}
/* Now we have the variant we can load the data - from here on the same as MicroPDF417 code */
variant - - ;
symbol - > option_2 = MicroVariants [ variant ] ; /* columns */
symbol - > rows = MicroVariants [ variant + 34 ] ; /* rows */
k = MicroVariants [ variant + 68 ] ; /* number of EC CWs */
longueur = ( symbol - > option_2 * symbol - > rows ) - k ; /* number of non-EC CWs */
i = longueur - mclength ; /* amount of padding required */
offset = MicroVariants [ variant + 102 ] ; /* coefficient offset */
/* We add the padding */
while ( i > 0 ) {
chainemc [ mclength ] = 900 ;
mclength + + ;
i - - ;
}
/* Reed-Solomon error correction */
longueur = mclength ;
for ( loop = 0 ; loop < 50 ; loop + + ) {
mccorrection [ loop ] = 0 ;
}
total = 0 ;
for ( i = 0 ; i < longueur ; i + + ) {
total = ( chainemc [ i ] + mccorrection [ k - 1 ] ) % 929 ;
for ( j = k - 1 ; j > = 0 ; j - - ) {
if ( j = = 0 ) {
mccorrection [ j ] = ( 929 - ( total * Microcoeffs [ offset + j ] ) % 929 ) % 929 ;
} else {
mccorrection [ j ] = ( mccorrection [ j - 1 ] + 929 - ( total * Microcoeffs [ offset + j ] ) % 929 ) % 929 ;
}
}
}
for ( j = 0 ; j < k ; j + + ) {
if ( mccorrection [ j ] ! = 0 ) {
mccorrection [ j ] = 929 - mccorrection [ j ] ;
}
}
/* we add these codes to the string */
for ( i = k - 1 ; i > = 0 ; i - - ) {
chainemc [ mclength ] = mccorrection [ i ] ;
mclength + + ;
}
/* Now get the RAP (Row Address Pattern) start values */
LeftRAPStart = RAPTable [ variant ] ;
CentreRAPStart = RAPTable [ variant + 34 ] ;
RightRAPStart = RAPTable [ variant + 68 ] ;
StartCluster = RAPTable [ variant + 102 ] / 3 ;
/* That's all values loaded, get on with the encoding */
LeftRAP = LeftRAPStart ;
CentreRAP = CentreRAPStart ;
RightRAP = RightRAPStart ;
Cluster = StartCluster ;
/* Cluster can be 0, 1 or 2 for Cluster(0), Cluster(3) and Cluster(6) */
for ( i = 0 ; i < symbol - > rows ; i + + ) {
strcpy ( codebarre , " " ) ;
offset = 929 * Cluster ;
for ( j = 0 ; j < 5 ; j + + ) {
dummy [ j ] = 0 ;
}
for ( j = 0 ; j < symbol - > option_2 ; j + + ) {
dummy [ j + 1 ] = chainemc [ i * symbol - > option_2 + j ] ;
}
/* Copy the data into codebarre */
concat ( codebarre , RAPLR [ LeftRAP ] ) ;
concat ( codebarre , " 1 " ) ;
concat ( codebarre , codagemc [ offset + dummy [ 1 ] ] ) ;
concat ( codebarre , " 1 " ) ;
if ( cc_width = = 3 ) {
concat ( codebarre , RAPC [ CentreRAP ] ) ;
}
if ( cc_width > = 2 ) {
concat ( codebarre , " 1 " ) ;
concat ( codebarre , codagemc [ offset + dummy [ 2 ] ] ) ;
concat ( codebarre , " 1 " ) ;
}
if ( cc_width = = 4 ) {
concat ( codebarre , RAPC [ CentreRAP ] ) ;
}
if ( cc_width > = 3 ) {
concat ( codebarre , " 1 " ) ;
concat ( codebarre , codagemc [ offset + dummy [ 3 ] ] ) ;
concat ( codebarre , " 1 " ) ;
}
if ( cc_width = = 4 ) {
concat ( codebarre , " 1 " ) ;
concat ( codebarre , codagemc [ offset + dummy [ 4 ] ] ) ;
concat ( codebarre , " 1 " ) ;
}
concat ( codebarre , RAPLR [ RightRAP ] ) ;
concat ( codebarre , " 1 " ) ; /* stop */
/* Now codebarre is a mixture of letters and numbers */
writer = 0 ;
flip = 1 ;
strcpy ( pattern , " " ) ;
for ( loop = 0 ; loop < strlen ( codebarre ) ; loop + + ) {
if ( ( codebarre [ loop ] > = ' 0 ' ) & & ( codebarre [ loop ] < = ' 9 ' ) ) {
for ( k = 0 ; k < ctoi ( codebarre [ loop ] ) ; k + + ) {
if ( flip = = 0 ) {
pattern [ writer ] = ' 0 ' ;
} else {
pattern [ writer ] = ' 1 ' ;
}
writer + + ;
}
pattern [ writer ] = ' \0 ' ;
if ( flip = = 0 ) {
flip = 1 ;
} else {
flip = 0 ;
}
} else {
lookup ( BRSET , PDFttf , codebarre [ loop ] , pattern ) ;
writer + = 5 ;
}
}
symbol - > width = writer ;
/* so now pattern[] holds the string of '1's and '0's. - copy this to the symbol */
for ( loop = 0 ; loop < strlen ( pattern ) ; loop + + ) {
if ( pattern [ loop ] = = ' 1 ' ) {
set_module ( symbol , i , loop ) ;
}
}
symbol - > row_height [ i ] = 2 ;
/* Set up RAPs and Cluster for next row */
LeftRAP + + ;
CentreRAP + + ;
RightRAP + + ;
Cluster + + ;
if ( LeftRAP = = 53 ) {
LeftRAP = 1 ;
}
if ( CentreRAP = = 53 ) {
CentreRAP = 1 ;
}
if ( RightRAP = = 53 ) {
RightRAP = 1 ;
}
if ( Cluster = = 3 ) {
Cluster = 0 ;
}
}
return 0 ;
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}
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/* CC-C 2D component - byte compressed PDF417 */
int cc_c ( struct zint_symbol * symbol , char source [ ] , int cc_width , int ecc_level ) {
int length , i , binloc ;
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# ifndef _MSC_VER
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unsigned char data_string [ ( strlen ( source ) / 8 ) + 4 ] ;
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# else
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unsigned char * data_string = ( unsigned char * ) _alloca ( ( strlen ( source ) / 8 ) + 4 ) ;
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# endif
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int chainemc [ 1000 ] , mclength , k ;
int offset , longueur , loop , total , j , mccorrection [ 520 ] ;
int c1 , c2 , c3 , dummy [ 35 ] ;
char codebarre [ 100 ] , pattern [ 580 ] ;
length = strlen ( source ) / 8 ;
for ( i = 0 ; i < length ; i + + ) {
binloc = i * 8 ;
data_string [ i ] = 0 ;
for ( int p = 0 ; p < 8 ; p + + ) {
if ( source [ binloc + p ] = = ' 1 ' ) {
data_string [ i ] + = ( 0x80 > > p ) ;
}
}
}
mclength = 0 ;
chainemc [ mclength ] = 0 ; /* space for length descriptor */
mclength + + ;
chainemc [ mclength ] = 920 ; /* CC-C identifier */
mclength + + ;
byteprocess ( chainemc , & mclength , data_string , 0 , length , 0 ) ;
chainemc [ 0 ] = mclength ;
k = 1 ;
for ( i = 1 ; i < = ( ecc_level + 1 ) ; i + + ) {
k * = 2 ;
}
/* 796 - we now take care of the Reed Solomon codes */
switch ( ecc_level ) {
case 1 : offset = 2 ;
break ;
case 2 : offset = 6 ;
break ;
case 3 : offset = 14 ;
break ;
case 4 : offset = 30 ;
break ;
case 5 : offset = 62 ;
break ;
case 6 : offset = 126 ;
break ;
case 7 : offset = 254 ;
break ;
case 8 : offset = 510 ;
break ;
default : offset = 0 ;
break ;
}
longueur = mclength ;
for ( loop = 0 ; loop < 520 ; loop + + ) {
mccorrection [ loop ] = 0 ;
}
total = 0 ;
for ( i = 0 ; i < longueur ; i + + ) {
total = ( chainemc [ i ] + mccorrection [ k - 1 ] ) % 929 ;
for ( j = k - 1 ; j > = 0 ; j - - ) {
if ( j = = 0 ) {
mccorrection [ j ] = ( 929 - ( total * coefrs [ offset + j ] ) % 929 ) % 929 ;
} else {
mccorrection [ j ] = ( mccorrection [ j - 1 ] + 929 - ( total * coefrs [ offset + j ] ) % 929 ) % 929 ;
}
}
}
for ( j = 0 ; j < k ; j + + ) {
if ( mccorrection [ j ] ! = 0 ) {
mccorrection [ j ] = 929 - mccorrection [ j ] ;
}
}
/* we add these codes to the string */
for ( i = k - 1 ; i > = 0 ; i - - ) {
chainemc [ mclength ] = mccorrection [ i ] ;
mclength + + ;
}
/* 818 - The CW string is finished */
c1 = ( mclength / cc_width - 1 ) / 3 ;
c2 = ecc_level * 3 + ( mclength / cc_width - 1 ) % 3 ;
c3 = cc_width - 1 ;
/* we now encode each row */
for ( i = 0 ; i < = ( mclength / cc_width ) - 1 ; i + + ) {
for ( j = 0 ; j < cc_width ; j + + ) {
dummy [ j + 1 ] = chainemc [ i * cc_width + j ] ;
}
k = ( i / 3 ) * 30 ;
switch ( i % 3 ) {
case 0 :
dummy [ 0 ] = k + c1 ;
dummy [ cc_width + 1 ] = k + c3 ;
break ;
case 1 :
dummy [ 0 ] = k + c2 ;
dummy [ cc_width + 1 ] = k + c1 ;
break ;
case 2 :
dummy [ 0 ] = k + c3 ;
dummy [ cc_width + 1 ] = k + c2 ;
break ;
}
strcpy ( codebarre , " +* " ) ; /* Start with a start char and a separator */
for ( j = 0 ; j < = cc_width + 1 ; j + + ) {
switch ( i % 3 ) {
case 1 : offset = 929 ; /* cluster(3) */
break ;
case 2 : offset = 1858 ; /* cluster(6) */
break ;
default : offset = 0 ; /* cluster(0) */
break ;
}
concat ( codebarre , codagemc [ offset + dummy [ j ] ] ) ;
concat ( codebarre , " * " ) ;
}
concat ( codebarre , " - " ) ;
strcpy ( pattern , " " ) ;
for ( loop = 0 ; loop < strlen ( codebarre ) ; loop + + ) {
lookup ( BRSET , PDFttf , codebarre [ loop ] , pattern ) ;
}
for ( loop = 0 ; loop < strlen ( pattern ) ; loop + + ) {
if ( pattern [ loop ] = = ' 1 ' ) {
set_module ( symbol , i , loop ) ;
}
}
symbol - > row_height [ i ] = 3 ;
}
symbol - > rows = ( mclength / cc_width ) ;
symbol - > width = strlen ( pattern ) ;
return 0 ;
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}
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int cc_binary_string ( struct zint_symbol * symbol , const char source [ ] , char binary_string [ ] , int cc_mode , int * cc_width , int * ecc , int lin_width ) { /* Handles all data encodation from section 5 of ISO/IEC 24723 */
int encoding_method , read_posn , d1 , d2 , value , alpha_pad ;
int i , j , mask , ai_crop , fnc1_latch ;
long int group_val ;
int ai90_mode , latch , remainder , binary_length ;
char date_str [ 4 ] ;
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# ifndef _MSC_VER
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char general_field [ strlen ( source ) + 1 ] , general_field_type [ strlen ( source ) + 1 ] ;
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# else
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char * general_field = ( char * ) _alloca ( strlen ( source ) + 1 ) ;
char * general_field_type = ( char * ) _alloca ( strlen ( source ) + 1 ) ;
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# endif
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int target_bitsize ;
encoding_method = 1 ;
read_posn = 0 ;
ai_crop = 0 ;
fnc1_latch = 0 ;
alpha_pad = 0 ;
ai90_mode = 0 ;
* ecc = 0 ;
value = 0 ;
target_bitsize = 0 ;
if ( ( source [ 0 ] = = ' 1 ' ) & & ( ( source [ 1 ] = = ' 0 ' ) | | ( source [ 1 ] = = ' 1 ' ) | | ( source [ 1 ] = = ' 7 ' ) ) & & ( strlen ( source ) > 8 ) ) {
/* Source starts (10), (11) or (17) */
encoding_method = 2 ;
}
if ( ( source [ 0 ] = = ' 9 ' ) & & ( source [ 1 ] = = ' 0 ' ) ) {
/* Source starts (90) */
encoding_method = 3 ;
}
if ( encoding_method = = 1 ) {
concat ( binary_string , " 0 " ) ;
}
if ( encoding_method = = 2 ) {
/* Encoding Method field "10" - date and lot number */
concat ( binary_string , " 10 " ) ;
if ( source [ 1 ] = = ' 0 ' ) {
/* No date data */
concat ( binary_string , " 11 " ) ;
read_posn = 2 ;
} else {
/* Production Date (11) or Expiration Date (17) */
date_str [ 0 ] = source [ 2 ] ;
date_str [ 1 ] = source [ 3 ] ;
date_str [ 2 ] = ' \0 ' ;
group_val = atoi ( date_str ) * 384 ;
date_str [ 0 ] = source [ 4 ] ;
date_str [ 1 ] = source [ 5 ] ;
group_val + = ( atoi ( date_str ) - 1 ) * 32 ;
date_str [ 0 ] = source [ 6 ] ;
date_str [ 1 ] = source [ 7 ] ;
group_val + = atoi ( date_str ) ;
mask = 0x8000 ;
for ( j = 0 ; j < 16 ; j + + ) {
if ( ( group_val & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
if ( source [ 1 ] = = ' 1 ' ) {
/* Production Date AI 11 */
concat ( binary_string , " 0 " ) ;
} else {
/* Expiration Date AI 17 */
concat ( binary_string , " 1 " ) ;
}
read_posn = 8 ;
}
if ( ( source [ read_posn ] = = ' 1 ' ) & & ( source [ read_posn + 1 ] = = ' 0 ' ) ) {
/* Followed by AI 10 - strip this from general field */
read_posn + = 2 ;
} else {
/* An FNC1 character needs to be inserted in the general field */
fnc1_latch = 1 ;
}
}
if ( encoding_method = = 3 ) {
/* Encodation Method field of "11" - AI 90 */
# ifndef _MSC_VER
char ninety [ strlen ( source ) + 1 ] ;
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# else
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char * ninety = ( char * ) _alloca ( strlen ( source ) + 1 ) ;
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# endif
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char numeric_part [ 4 ] ;
int alpha , alphanum , numeric , test1 , test2 , test3 , next_ai_posn ;
int numeric_value , table3_letter , mask ;
/* "This encodation method may be used if an element string with an AI
90 occurs at the start of the data message , and if the data field
following the two - digit AI 90 starts with an alphanumeric string which
complies with a specific format . " (para 5.2.2) */
i = 0 ;
do {
ninety [ i ] = source [ i + 2 ] ;
i + + ;
} while ( ( strlen ( source ) > i + 2 ) & & ( ' [ ' ! = source [ i + 2 ] ) ) ;
ninety [ i ] = ' \0 ' ;
/* Find out if the AI 90 data is alphabetic or numeric or both */
alpha = 0 ;
alphanum = 0 ;
numeric = 0 ;
for ( i = 0 ; i < strlen ( ninety ) ; i + + ) {
if ( ( ninety [ i ] > = ' A ' ) & & ( ninety [ i ] < = ' Z ' ) ) {
/* Character is alphabetic */
alpha + = 1 ;
}
if ( ( ninety [ i ] > = ' 0 ' ) & & ( ninety [ i ] < = ' 9 ' ) ) {
/* Character is numeric */
numeric + = 1 ;
}
switch ( ninety [ i ] ) {
case ' * ' :
case ' , ' :
case ' - ' :
case ' . ' :
case ' / ' : alphanum + = 1 ;
break ;
}
if ( ! ( ( ( ninety [ i ] > = ' 0 ' ) & & ( ninety [ i ] < = ' 9 ' ) ) | | ( ( ninety [ i ] > = ' A ' ) & & ( ninety [ i ] < = ' Z ' ) ) ) ) {
if ( ( ninety [ i ] ! = ' * ' ) & & ( ninety [ i ] ! = ' , ' ) & & ( ninety [ i ] ! = ' - ' ) & & ( ninety [ i ] ! = ' . ' ) & & ( ninety [ i ] ! = ' / ' ) ) {
/* An Invalid AI 90 character */
strcpy ( symbol - > errtxt , " Invalid AI 90 data " ) ;
return ZINT_ERROR_INVALID_DATA ;
}
}
}
/* must start with 0, 1, 2 or 3 digits followed by an uppercase character */
test1 = - 1 ;
for ( i = 3 ; i > = 0 ; i - - ) {
if ( ( ninety [ i ] > = ' A ' ) & & ( ninety [ i ] < = ' Z ' ) ) {
test1 = i ;
}
}
test2 = 0 ;
for ( i = 0 ; i < test1 ; i + + ) {
if ( ! ( ( ninety [ i ] > = ' 0 ' ) & & ( ninety [ i ] < = ' 9 ' ) ) ) {
test2 = 1 ;
}
}
/* leading zeros are not permitted */
test3 = 0 ;
if ( ( test1 > = 1 ) & & ( ninety [ 0 ] = = ' 0 ' ) ) {
test3 = 1 ;
}
if ( ( test1 ! = - 1 ) & & ( test2 ! = 1 ) & & ( test3 = = 0 ) ) {
/* Encodation method "11" can be used */
concat ( binary_string , " 11 " ) ;
numeric - = test1 ;
alpha - - ;
/* Decide on numeric, alpha or alphanumeric mode */
/* Alpha mode is a special mode for AI 90 */
if ( alphanum > 0 ) {
/* Alphanumeric mode */
concat ( binary_string , " 0 " ) ;
ai90_mode = 1 ;
} else {
if ( alpha > numeric ) {
/* Alphabetic mode */
concat ( binary_string , " 11 " ) ;
ai90_mode = 2 ;
} else {
/* Numeric mode */
concat ( binary_string , " 10 " ) ;
ai90_mode = 3 ;
}
}
next_ai_posn = 2 + strlen ( ninety ) ;
if ( source [ next_ai_posn ] = = ' [ ' ) {
/* There are more AIs afterwords */
if ( ( source [ next_ai_posn + 1 ] = = ' 2 ' ) & & ( source [ next_ai_posn + 2 ] = = ' 1 ' ) ) {
/* AI 21 follows */
ai_crop = 1 ;
}
if ( ( source [ next_ai_posn + 1 ] = = ' 8 ' ) & & ( source [ next_ai_posn + 2 ] = = ' 0 ' ) & & ( source [ next_ai_posn + 3 ] = = ' 0 ' ) & & ( source [ next_ai_posn + 4 ] = = ' 4 ' ) ) {
/* AI 8004 follows */
ai_crop = 2 ;
}
}
switch ( ai_crop ) {
case 0 : concat ( binary_string , " 0 " ) ;
break ;
case 1 : concat ( binary_string , " 10 " ) ;
break ;
case 2 : concat ( binary_string , " 11 " ) ;
break ;
}
if ( test1 = = 0 ) {
strcpy ( numeric_part , " 0 " ) ;
} else {
for ( i = 0 ; i < test1 ; i + + ) {
numeric_part [ i ] = ninety [ i ] ;
}
numeric_part [ i ] = ' \0 ' ;
}
numeric_value = atoi ( numeric_part ) ;
table3_letter = - 1 ;
if ( numeric_value < 31 ) {
switch ( ninety [ test1 ] ) {
case ' B ' : table3_letter = 0 ;
break ;
case ' D ' : table3_letter = 1 ;
break ;
case ' H ' : table3_letter = 2 ;
break ;
case ' I ' : table3_letter = 3 ;
break ;
case ' J ' : table3_letter = 4 ;
break ;
case ' K ' : table3_letter = 5 ;
break ;
case ' L ' : table3_letter = 6 ;
break ;
case ' N ' : table3_letter = 7 ;
break ;
case ' P ' : table3_letter = 8 ;
break ;
case ' Q ' : table3_letter = 9 ;
break ;
case ' R ' : table3_letter = 10 ;
break ;
case ' S ' : table3_letter = 11 ;
break ;
case ' T ' : table3_letter = 12 ;
break ;
case ' V ' : table3_letter = 13 ;
break ;
case ' W ' : table3_letter = 14 ;
break ;
case ' Z ' : table3_letter = 15 ;
break ;
}
}
if ( table3_letter ! = - 1 ) {
/* Encoding can be done according to 5.2.2 c) 2) */
/* five bit binary string representing value before letter */
mask = 0x10 ;
for ( j = 0 ; j < 5 ; j + + ) {
if ( ( numeric_value & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
/* followed by four bit representation of letter from Table 3 */
mask = 0x08 ;
for ( j = 0 ; j < 4 ; j + + ) {
if ( ( table3_letter & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
} else {
/* Encoding is done according to 5.2.2 c) 3) */
concat ( binary_string , " 11111 " ) ;
/* ten bit representation of number */
mask = 0x200 ;
for ( j = 0 ; j < 10 ; j + + ) {
if ( ( numeric_value & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
/* five bit representation of ASCII character */
mask = 0x10 ;
for ( j = 0 ; j < 5 ; j + + ) {
if ( ( ( ninety [ test1 ] - 65 ) & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
}
read_posn = test1 + 3 ;
} else {
/* Use general field encodation instead */
concat ( binary_string , " 0 " ) ;
read_posn = 0 ;
}
}
/* Now encode the rest of the AI 90 data field */
if ( ai90_mode = = 2 ) {
/* Alpha encodation (section 5.2.3) */
do {
if ( ( source [ read_posn ] > = ' 0 ' ) & & ( source [ read_posn ] < = ' 9 ' ) ) {
mask = 0x10 ;
for ( j = 0 ; j < 5 ; j + + ) {
if ( ( ( source [ read_posn ] + 4 ) & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
}
if ( ( source [ read_posn ] > = ' A ' ) & & ( source [ read_posn ] < = ' Z ' ) ) {
mask = 0x20 ;
for ( j = 0 ; j < 6 ; j + + ) {
if ( ( ( source [ read_posn ] - 65 ) & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
}
if ( source [ read_posn ] = = ' [ ' ) {
concat ( binary_string , " 11111 " ) ;
}
read_posn + + ;
} while ( ( source [ read_posn - 1 ] ! = ' [ ' ) & & ( source [ read_posn - 1 ] ! = ' \0 ' ) ) ;
alpha_pad = 1 ; /* This is overwritten if a general field is encoded */
}
if ( ai90_mode = = 1 ) {
/* Alphanumeric mode */
do {
if ( ( source [ read_posn ] > = ' 0 ' ) & & ( source [ read_posn ] < = ' 9 ' ) ) {
mask = 0x10 ;
for ( j = 0 ; j < 5 ; j + + ) {
if ( ( ( source [ read_posn ] - 43 ) & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
}
if ( ( source [ read_posn ] > = ' A ' ) & & ( source [ read_posn ] < = ' Z ' ) ) {
mask = 0x20 ;
for ( j = 0 ; j < 6 ; j + + ) {
if ( ( ( source [ read_posn ] - 33 ) & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
}
switch ( source [ read_posn ] ) {
case ' [ ' : concat ( binary_string , " 01111 " ) ;
break ;
case ' * ' : concat ( binary_string , " 111010 " ) ;
break ;
case ' , ' : concat ( binary_string , " 111011 " ) ;
break ;
case ' - ' : concat ( binary_string , " 111100 " ) ;
break ;
case ' . ' : concat ( binary_string , " 111101 " ) ;
break ;
case ' / ' : concat ( binary_string , " 111110 " ) ;
break ;
}
read_posn + + ;
} while ( ( source [ read_posn - 1 ] ! = ' [ ' ) & & ( source [ read_posn - 1 ] ! = ' \0 ' ) ) ;
}
read_posn + = ( 2 * ai_crop ) ;
/* The compressed data field has been processed if appropriate - the
rest of the data ( if any ) goes into a general - purpose data compaction field */
j = 0 ;
if ( fnc1_latch = = 1 ) {
/* Encodation method "10" has been used but it is not followed by
AI 10 , so a FNC1 character needs to be added */
general_field [ j ] = ' [ ' ;
j + + ;
}
for ( i = read_posn ; i < strlen ( source ) ; i + + ) {
general_field [ j ] = source [ i ] ;
j + + ;
}
general_field [ j ] = ' \0 ' ;
if ( strlen ( general_field ) ! = 0 ) {
alpha_pad = 0 ;
}
latch = 0 ;
for ( i = 0 ; i < strlen ( general_field ) ; i + + ) {
/* Table 13 - ISO/IEC 646 encodation */
if ( ( general_field [ i ] < ' ' ) | | ( general_field [ i ] > ' z ' ) ) {
general_field_type [ i ] = INVALID_CHAR ;
latch = 1 ;
} else {
general_field_type [ i ] = ISOIEC ;
}
if ( general_field [ i ] = = ' # ' ) {
general_field_type [ i ] = INVALID_CHAR ;
latch = 1 ;
}
if ( general_field [ i ] = = ' $ ' ) {
general_field_type [ i ] = INVALID_CHAR ;
latch = 1 ;
}
if ( general_field [ i ] = = ' @ ' ) {
general_field_type [ i ] = INVALID_CHAR ;
latch = 1 ;
}
if ( general_field [ i ] = = 92 ) {
general_field_type [ i ] = INVALID_CHAR ;
latch = 1 ;
}
if ( general_field [ i ] = = ' ^ ' ) {
general_field_type [ i ] = INVALID_CHAR ;
latch = 1 ;
}
if ( general_field [ i ] = = 96 ) {
general_field_type [ i ] = INVALID_CHAR ;
latch = 1 ;
}
/* Table 12 - Alphanumeric encodation */
if ( ( general_field [ i ] > = ' A ' ) & & ( general_field [ i ] < = ' Z ' ) ) {
general_field_type [ i ] = ALPHA_OR_ISO ;
}
if ( general_field [ i ] = = ' * ' ) {
general_field_type [ i ] = ALPHA_OR_ISO ;
}
if ( general_field [ i ] = = ' , ' ) {
general_field_type [ i ] = ALPHA_OR_ISO ;
}
if ( general_field [ i ] = = ' - ' ) {
general_field_type [ i ] = ALPHA_OR_ISO ;
}
if ( general_field [ i ] = = ' . ' ) {
general_field_type [ i ] = ALPHA_OR_ISO ;
}
if ( general_field [ i ] = = ' / ' ) {
general_field_type [ i ] = ALPHA_OR_ISO ;
}
/* Numeric encodation */
if ( ( general_field [ i ] > = ' 0 ' ) & & ( general_field [ i ] < = ' 9 ' ) ) {
general_field_type [ i ] = ANY_ENC ;
}
if ( general_field [ i ] = = ' [ ' ) {
/* FNC1 can be encoded in any system */
general_field_type [ i ] = ANY_ENC ;
}
}
general_field_type [ strlen ( general_field ) ] = ' \0 ' ;
if ( latch = = 1 ) {
/* Invalid characters in input data */
strcpy ( symbol - > errtxt , " Invalid characters in input data " ) ;
return ZINT_ERROR_INVALID_DATA ;
}
for ( i = 0 ; i < strlen ( general_field ) ; i + + ) {
if ( ( general_field_type [ i ] = = ISOIEC ) & & ( general_field [ i + 1 ] = = ' [ ' ) ) {
general_field_type [ i + 1 ] = ISOIEC ;
}
}
for ( i = 0 ; i < strlen ( general_field ) ; i + + ) {
if ( ( general_field_type [ i ] = = ALPHA_OR_ISO ) & & ( general_field [ i + 1 ] = = ' [ ' ) ) {
general_field_type [ i + 1 ] = ALPHA_OR_ISO ;
}
}
latch = general_rules ( general_field , general_field_type ) ;
i = 0 ;
do {
switch ( general_field_type [ i ] ) {
case NUMERIC :
if ( i ! = 0 ) {
if ( ( general_field_type [ i - 1 ] ! = NUMERIC ) & & ( general_field [ i - 1 ] ! = ' [ ' ) ) {
concat ( binary_string , " 000 " ) ; /* Numeric latch */
}
}
if ( general_field [ i ] ! = ' [ ' ) {
d1 = ctoi ( general_field [ i ] ) ;
} else {
d1 = 10 ;
}
if ( general_field [ i + 1 ] ! = ' [ ' ) {
d2 = ctoi ( general_field [ i + 1 ] ) ;
} else {
d2 = 10 ;
}
value = ( 11 * d1 ) + d2 + 8 ;
mask = 0x40 ;
for ( j = 0 ; j < 7 ; j + + ) {
if ( ( value & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
i + = 2 ;
break ;
case ALPHA :
if ( i ! = 0 ) {
if ( ( general_field_type [ i - 1 ] = = NUMERIC ) | | ( general_field [ i - 1 ] = = ' [ ' ) ) {
concat ( binary_string , " 0000 " ) ; /* Alphanumeric latch */
}
if ( general_field_type [ i - 1 ] = = ISOIEC ) {
concat ( binary_string , " 00100 " ) ; /* ISO/IEC 646 latch */
}
}
if ( ( general_field [ i ] > = ' 0 ' ) & & ( general_field [ i ] < = ' 9 ' ) ) {
value = general_field [ i ] - 43 ;
mask = 0x10 ;
for ( j = 0 ; j < 5 ; j + + ) {
if ( ( value & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
}
if ( ( general_field [ i ] > = ' A ' ) & & ( general_field [ i ] < = ' Z ' ) ) {
value = general_field [ i ] - 33 ;
mask = 0x20 ;
for ( j = 0 ; j < 6 ; j + + ) {
if ( ( value & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
}
if ( general_field [ i ] = = ' [ ' ) concat ( binary_string , " 01111 " ) ; /* FNC1/Numeric latch */
if ( general_field [ i ] = = ' * ' ) concat ( binary_string , " 111010 " ) ; /* asterisk */
if ( general_field [ i ] = = ' , ' ) concat ( binary_string , " 111011 " ) ; /* comma */
if ( general_field [ i ] = = ' - ' ) concat ( binary_string , " 111100 " ) ; /* minus or hyphen */
if ( general_field [ i ] = = ' . ' ) concat ( binary_string , " 111101 " ) ; /* period or full stop */
if ( general_field [ i ] = = ' / ' ) concat ( binary_string , " 111110 " ) ; /* slash or solidus */
i + + ;
break ;
case ISOIEC :
if ( i ! = 0 ) {
if ( ( general_field_type [ i - 1 ] = = NUMERIC ) | | ( general_field [ i - 1 ] = = ' [ ' ) ) {
concat ( binary_string , " 0000 " ) ; /* Alphanumeric latch */
concat ( binary_string , " 00100 " ) ; /* ISO/IEC 646 latch */
}
if ( general_field_type [ i - 1 ] = = ALPHA ) {
concat ( binary_string , " 00100 " ) ; /* ISO/IEC 646 latch */
}
}
if ( ( general_field [ i ] > = ' 0 ' ) & & ( general_field [ i ] < = ' 9 ' ) ) {
value = general_field [ i ] - 43 ;
mask = 0x10 ;
for ( j = 0 ; j < 5 ; j + + ) {
if ( ( value & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
}
if ( ( general_field [ i ] > = ' A ' ) & & ( general_field [ i ] < = ' Z ' ) ) {
value = general_field [ i ] - 1 ;
mask = 0x40 ;
for ( j = 0 ; j < 7 ; j + + ) {
if ( ( value & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
}
if ( ( general_field [ i ] > = ' a ' ) & & ( general_field [ i ] < = ' z ' ) ) {
value = general_field [ i ] - 7 ;
mask = 0x40 ;
for ( j = 0 ; j < 7 ; j + + ) {
if ( ( value & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
}
if ( general_field [ i ] = = ' [ ' ) concat ( binary_string , " 01111 " ) ; /* FNC1/Numeric latch */
if ( general_field [ i ] = = ' ! ' ) concat ( binary_string , " 11101000 " ) ; /* exclamation mark */
if ( general_field [ i ] = = 34 ) concat ( binary_string , " 11101001 " ) ; /* quotation mark */
if ( general_field [ i ] = = 37 ) concat ( binary_string , " 11101010 " ) ; /* percent sign */
if ( general_field [ i ] = = ' & ' ) concat ( binary_string , " 11101011 " ) ; /* ampersand */
if ( general_field [ i ] = = 39 ) concat ( binary_string , " 11101100 " ) ; /* apostrophe */
if ( general_field [ i ] = = ' ( ' ) concat ( binary_string , " 11101101 " ) ; /* left parenthesis */
if ( general_field [ i ] = = ' ) ' ) concat ( binary_string , " 11101110 " ) ; /* right parenthesis */
if ( general_field [ i ] = = ' * ' ) concat ( binary_string , " 11101111 " ) ; /* asterisk */
if ( general_field [ i ] = = ' + ' ) concat ( binary_string , " 11110000 " ) ; /* plus sign */
if ( general_field [ i ] = = ' , ' ) concat ( binary_string , " 11110001 " ) ; /* comma */
if ( general_field [ i ] = = ' - ' ) concat ( binary_string , " 11110010 " ) ; /* minus or hyphen */
if ( general_field [ i ] = = ' . ' ) concat ( binary_string , " 11110011 " ) ; /* period or full stop */
if ( general_field [ i ] = = ' / ' ) concat ( binary_string , " 11110100 " ) ; /* slash or solidus */
if ( general_field [ i ] = = ' : ' ) concat ( binary_string , " 11110101 " ) ; /* colon */
if ( general_field [ i ] = = ' ; ' ) concat ( binary_string , " 11110110 " ) ; /* semicolon */
if ( general_field [ i ] = = ' < ' ) concat ( binary_string , " 11110111 " ) ; /* less-than sign */
if ( general_field [ i ] = = ' = ' ) concat ( binary_string , " 11111000 " ) ; /* equals sign */
if ( general_field [ i ] = = ' > ' ) concat ( binary_string , " 11111001 " ) ; /* greater-than sign */
if ( general_field [ i ] = = ' ? ' ) concat ( binary_string , " 11111010 " ) ; /* question mark */
if ( general_field [ i ] = = ' _ ' ) concat ( binary_string , " 11111011 " ) ; /* underline or low line */
if ( general_field [ i ] = = ' ' ) concat ( binary_string , " 11111100 " ) ; /* space */
i + + ;
break ;
}
} while ( i + latch < strlen ( general_field ) ) ;
binary_length = strlen ( binary_string ) ;
if ( cc_mode = = 1 ) {
/* CC-A 2D component - calculate remaining space */
switch ( * ( cc_width ) ) {
case 2 :
if ( binary_length > 167 ) {
return ZINT_ERROR_TOO_LONG ;
}
if ( binary_length < = 167 ) {
target_bitsize = 167 ;
}
if ( binary_length < = 138 ) {
target_bitsize = 138 ;
}
if ( binary_length < = 118 ) {
target_bitsize = 118 ;
}
if ( binary_length < = 108 ) {
target_bitsize = 108 ;
}
if ( binary_length < = 88 ) {
target_bitsize = 88 ;
}
if ( binary_length < = 78 ) {
target_bitsize = 78 ;
}
if ( binary_length < = 59 ) {
target_bitsize = 59 ;
}
break ;
case 3 :
if ( binary_length > 167 ) {
return ZINT_ERROR_TOO_LONG ;
}
if ( binary_length < = 167 ) {
target_bitsize = 167 ;
}
if ( binary_length < = 138 ) {
target_bitsize = 138 ;
}
if ( binary_length < = 118 ) {
target_bitsize = 118 ;
}
if ( binary_length < = 98 ) {
target_bitsize = 98 ;
}
if ( binary_length < = 78 ) {
target_bitsize = 78 ;
}
break ;
case 4 :
if ( binary_length > 197 ) {
return ZINT_ERROR_TOO_LONG ;
}
if ( binary_length < = 197 ) {
target_bitsize = 197 ;
}
if ( binary_length < = 167 ) {
target_bitsize = 167 ;
}
if ( binary_length < = 138 ) {
target_bitsize = 138 ;
}
if ( binary_length < = 108 ) {
target_bitsize = 108 ;
}
if ( binary_length < = 78 ) {
target_bitsize = 78 ;
}
break ;
}
}
if ( cc_mode = = 2 ) {
/* CC-B 2D component - calculated from ISO/IEC 24728 Table 1 */
switch ( * ( cc_width ) ) {
case 2 :
if ( binary_length > 336 ) {
return ZINT_ERROR_TOO_LONG ;
}
if ( binary_length < = 336 ) {
target_bitsize = 336 ;
}
if ( binary_length < = 296 ) {
target_bitsize = 296 ;
}
if ( binary_length < = 256 ) {
target_bitsize = 256 ;
}
if ( binary_length < = 208 ) {
target_bitsize = 208 ;
}
if ( binary_length < = 160 ) {
target_bitsize = 160 ;
}
if ( binary_length < = 104 ) {
target_bitsize = 104 ;
}
if ( binary_length < = 56 ) {
target_bitsize = 56 ;
}
break ;
case 3 :
if ( binary_length > 768 ) {
return ZINT_ERROR_TOO_LONG ;
}
if ( binary_length < = 768 ) {
target_bitsize = 768 ;
}
if ( binary_length < = 648 ) {
target_bitsize = 648 ;
}
if ( binary_length < = 536 ) {
target_bitsize = 536 ;
}
if ( binary_length < = 416 ) {
target_bitsize = 416 ;
}
if ( binary_length < = 304 ) {
target_bitsize = 304 ;
}
if ( binary_length < = 208 ) {
target_bitsize = 208 ;
}
if ( binary_length < = 152 ) {
target_bitsize = 152 ;
}
if ( binary_length < = 112 ) {
target_bitsize = 112 ;
}
if ( binary_length < = 72 ) {
target_bitsize = 72 ;
}
if ( binary_length < = 32 ) {
target_bitsize = 32 ;
}
break ;
case 4 :
if ( binary_length > 1184 ) {
return ZINT_ERROR_TOO_LONG ;
}
if ( binary_length < = 1184 ) {
target_bitsize = 1184 ;
}
if ( binary_length < = 1016 ) {
target_bitsize = 1016 ;
}
if ( binary_length < = 840 ) {
target_bitsize = 840 ;
}
if ( binary_length < = 672 ) {
target_bitsize = 672 ;
}
if ( binary_length < = 496 ) {
target_bitsize = 496 ;
}
if ( binary_length < = 352 ) {
target_bitsize = 352 ;
}
if ( binary_length < = 264 ) {
target_bitsize = 264 ;
}
if ( binary_length < = 208 ) {
target_bitsize = 208 ;
}
if ( binary_length < = 152 ) {
target_bitsize = 152 ;
}
if ( binary_length < = 96 ) {
target_bitsize = 96 ;
}
if ( binary_length < = 56 ) {
target_bitsize = 56 ;
}
break ;
}
}
if ( cc_mode = = 3 ) {
/* CC-C 2D Component is a bit more complex! */
int byte_length , codewords_used , ecc_level , ecc_codewords , rows ;
int codewords_total , target_codewords , target_bytesize ;
byte_length = binary_length / 8 ;
if ( binary_length % 8 ! = 0 ) {
byte_length + + ;
}
codewords_used = ( byte_length / 6 ) * 5 ;
codewords_used + = byte_length % 6 ;
ecc_level = 7 ;
if ( codewords_used < = 1280 ) {
ecc_level = 6 ;
}
if ( codewords_used < = 640 ) {
ecc_level = 5 ;
}
if ( codewords_used < = 320 ) {
ecc_level = 4 ;
}
if ( codewords_used < = 160 ) {
ecc_level = 3 ;
}
if ( codewords_used < = 40 ) {
ecc_level = 2 ;
}
* ( ecc ) = ecc_level ;
ecc_codewords = 1 ;
for ( i = 1 ; i < = ( ecc_level + 1 ) ; i + + ) {
ecc_codewords * = 2 ;
}
codewords_used + = ecc_codewords ;
codewords_used + = 3 ;
if ( codewords_used > symbol - > option_3 ) {
return ZINT_ERROR_TOO_LONG ;
}
* ( cc_width ) = ( lin_width - 62 ) / 17 ;
if ( ( codewords_used / * ( cc_width ) ) > 90 ) {
/* stop the symbol from becoming too high */
* ( cc_width ) = * ( cc_width ) + 1 ;
}
rows = codewords_used / * ( cc_width ) ;
if ( codewords_used % * ( cc_width ) ! = 0 ) {
rows + + ;
}
codewords_total = * ( cc_width ) * rows ;
target_codewords = codewords_total - ecc_codewords ;
target_codewords - = 3 ;
target_bytesize = 6 * ( target_codewords / 5 ) ;
target_bytesize + = target_codewords % 5 ;
target_bitsize = 8 * target_bytesize ;
}
remainder = binary_length - target_bitsize ;
if ( latch = = 1 ) {
i = 0 ;
/* There is still one more numeric digit to encode */
if ( ( remainder > = 4 ) & & ( remainder < = 6 ) ) {
d1 = ctoi ( general_field [ i ] ) ;
d1 + + ;
mask = 0x08 ;
for ( j = 0 ; j < 4 ; j + + ) {
if ( ( value & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
} else {
d1 = ctoi ( general_field [ i ] ) ;
d2 = 10 ;
value = ( 11 * d1 ) + d2 + 8 ;
mask = 0x40 ;
for ( j = 0 ; j < 7 ; j + + ) {
if ( ( value & mask ) = = 0x00 ) {
concat ( binary_string , " 0 " ) ;
} else {
concat ( binary_string , " 1 " ) ;
}
mask = mask > > 1 ;
}
/* This may push the symbol up to the next size */
}
}
if ( strlen ( binary_string ) > 11805 ) { /* (2361 * 5) */
strcpy ( symbol - > errtxt , " Input too long " ) ;
return ZINT_ERROR_TOO_LONG ;
}
/* all the code below is repeated from above - it needs to be calculated again because the
size of the symbol may have changed when adding data in the above sequence */
binary_length = strlen ( binary_string ) ;
if ( cc_mode = = 1 ) {
/* CC-A 2D component - calculate padding required */
switch ( * ( cc_width ) ) {
case 2 :
if ( binary_length > 167 ) {
return ZINT_ERROR_TOO_LONG ;
}
if ( binary_length < = 167 ) {
target_bitsize = 167 ;
}
if ( binary_length < = 138 ) {
target_bitsize = 138 ;
}
if ( binary_length < = 118 ) {
target_bitsize = 118 ;
}
if ( binary_length < = 108 ) {
target_bitsize = 108 ;
}
if ( binary_length < = 88 ) {
target_bitsize = 88 ;
}
if ( binary_length < = 78 ) {
target_bitsize = 78 ;
}
if ( binary_length < = 59 ) {
target_bitsize = 59 ;
}
break ;
case 3 :
if ( binary_length > 167 ) {
return ZINT_ERROR_TOO_LONG ;
}
if ( binary_length < = 167 ) {
target_bitsize = 167 ;
}
if ( binary_length < = 138 ) {
target_bitsize = 138 ;
}
if ( binary_length < = 118 ) {
target_bitsize = 118 ;
}
if ( binary_length < = 98 ) {
target_bitsize = 98 ;
}
if ( binary_length < = 78 ) {
target_bitsize = 78 ;
}
break ;
case 4 :
if ( binary_length > 197 ) {
return ZINT_ERROR_TOO_LONG ;
}
if ( binary_length < = 197 ) {
target_bitsize = 197 ;
}
if ( binary_length < = 167 ) {
target_bitsize = 167 ;
}
if ( binary_length < = 138 ) {
target_bitsize = 138 ;
}
if ( binary_length < = 108 ) {
target_bitsize = 108 ;
}
if ( binary_length < = 78 ) {
target_bitsize = 78 ;
}
break ;
}
}
if ( cc_mode = = 2 ) {
/* CC-B 2D component */
switch ( * ( cc_width ) ) {
case 2 :
if ( binary_length > 336 ) {
return ZINT_ERROR_TOO_LONG ;
}
if ( binary_length < = 336 ) {
target_bitsize = 336 ;
}
if ( binary_length < = 296 ) {
target_bitsize = 296 ;
}
if ( binary_length < = 256 ) {
target_bitsize = 256 ;
}
if ( binary_length < = 208 ) {
target_bitsize = 208 ;
}
if ( binary_length < = 160 ) {
target_bitsize = 160 ;
}
if ( binary_length < = 104 ) {
target_bitsize = 104 ;
}
if ( binary_length < = 56 ) {
target_bitsize = 56 ;
}
break ;
case 3 :
if ( binary_length > 768 ) {
return ZINT_ERROR_TOO_LONG ;
}
if ( binary_length < = 768 ) {
target_bitsize = 768 ;
}
if ( binary_length < = 648 ) {
target_bitsize = 648 ;
}
if ( binary_length < = 536 ) {
target_bitsize = 536 ;
}
if ( binary_length < = 416 ) {
target_bitsize = 416 ;
}
if ( binary_length < = 304 ) {
target_bitsize = 304 ;
}
if ( binary_length < = 208 ) {
target_bitsize = 208 ;
}
if ( binary_length < = 152 ) {
target_bitsize = 152 ;
}
if ( binary_length < = 112 ) {
target_bitsize = 112 ;
}
if ( binary_length < = 72 ) {
target_bitsize = 72 ;
}
if ( binary_length < = 32 ) {
target_bitsize = 32 ;
}
break ;
case 4 :
if ( binary_length > 1184 ) {
return ZINT_ERROR_TOO_LONG ;
}
if ( binary_length < = 1184 ) {
target_bitsize = 1184 ;
}
if ( binary_length < = 1016 ) {
target_bitsize = 1016 ;
}
if ( binary_length < = 840 ) {
target_bitsize = 840 ;
}
if ( binary_length < = 672 ) {
target_bitsize = 672 ;
}
if ( binary_length < = 496 ) {
target_bitsize = 496 ;
}
if ( binary_length < = 352 ) {
target_bitsize = 352 ;
}
if ( binary_length < = 264 ) {
target_bitsize = 264 ;
}
if ( binary_length < = 208 ) {
target_bitsize = 208 ;
}
if ( binary_length < = 152 ) {
target_bitsize = 152 ;
}
if ( binary_length < = 96 ) {
target_bitsize = 96 ;
}
if ( binary_length < = 56 ) {
target_bitsize = 56 ;
}
break ;
}
}
if ( cc_mode = = 3 ) {
/* CC-C 2D Component is a bit more complex! */
int byte_length , codewords_used , ecc_level , ecc_codewords , rows ;
int codewords_total , target_codewords , target_bytesize ;
byte_length = binary_length / 8 ;
if ( binary_length % 8 ! = 0 ) {
byte_length + + ;
}
codewords_used = ( byte_length / 6 ) * 5 ;
codewords_used + = byte_length % 6 ;
ecc_level = 7 ;
if ( codewords_used < = 1280 ) {
ecc_level = 6 ;
}
if ( codewords_used < = 640 ) {
ecc_level = 5 ;
}
if ( codewords_used < = 320 ) {
ecc_level = 4 ;
}
if ( codewords_used < = 160 ) {
ecc_level = 3 ;
}
if ( codewords_used < = 40 ) {
ecc_level = 2 ;
}
* ( ecc ) = ecc_level ;
ecc_codewords = 1 ;
for ( i = 1 ; i < = ( ecc_level + 1 ) ; i + + ) {
ecc_codewords * = 2 ;
}
codewords_used + = ecc_codewords ;
codewords_used + = 3 ;
if ( codewords_used > symbol - > option_3 ) {
return ZINT_ERROR_TOO_LONG ;
}
* ( cc_width ) = ( lin_width - 62 ) / 17 ;
if ( ( codewords_used / * ( cc_width ) ) > 90 ) {
/* stop the symbol from becoming too high */
* ( cc_width ) = * ( cc_width ) + 1 ;
}
rows = codewords_used / * ( cc_width ) ;
if ( codewords_used % * ( cc_width ) ! = 0 ) {
rows + + ;
}
codewords_total = * ( cc_width ) * rows ;
target_codewords = codewords_total - ecc_codewords ;
target_codewords - = 3 ;
target_bytesize = 6 * ( target_codewords / 5 ) ;
target_bytesize + = target_codewords % 5 ;
target_bitsize = 8 * target_bytesize ;
}
if ( binary_length < target_bitsize ) {
/* Now add padding to binary string */
if ( alpha_pad = = 1 ) {
concat ( binary_string , " 11111 " ) ;
alpha_pad = 0 ;
/* Extra FNC1 character required after Alpha encodation (section 5.2.3) */
}
if ( ( strlen ( general_field ) ! = 0 ) & & ( general_field_type [ strlen ( general_field ) - 1 ] = = NUMERIC ) ) {
concat ( binary_string , " 0000 " ) ;
}
while ( strlen ( binary_string ) < target_bitsize ) {
concat ( binary_string , " 00100 " ) ;
}
if ( strlen ( binary_string ) > target_bitsize ) {
binary_string [ target_bitsize ] = ' \0 ' ;
}
}
return 0 ;
2008-07-14 09:15:55 +12:00
}
2016-02-20 22:38:03 +13:00
void add_leading_zeroes ( struct zint_symbol * symbol ) {
int with_addon = 0 ;
int first_len = 0 , second_len = 0 , zfirst_len = 0 , zsecond_len = 0 , i , h , n = 0 ;
h = strlen ( symbol - > primary ) ;
for ( i = 0 ; i < h ; i + + ) {
if ( symbol - > primary [ i ] = = ' + ' ) {
with_addon = 1 ;
} else {
if ( with_addon = = 0 ) {
first_len + + ;
} else {
second_len + + ;
}
}
}
/* Calculate target lengths */
if ( first_len < = 12 ) {
zfirst_len = 12 ;
}
if ( first_len < = 7 ) {
zfirst_len = 7 ;
}
if ( second_len < = 5 ) {
zsecond_len = 5 ;
}
if ( second_len < = 2 ) {
zsecond_len = 2 ;
}
if ( second_len = = 0 ) {
zsecond_len = 0 ;
}
/* Add leading zeroes */
n = zfirst_len - first_len ;
if ( n > 0 ) {
memmove ( symbol - > primary + n , symbol - > primary , h ) ;
memset ( symbol - > primary , ' 0 ' , n ) ;
}
n + = first_len + 1 ;
if ( zsecond_len ) {
memmove ( symbol - > primary + n + zsecond_len , symbol - > primary + n , second_len ) ;
memset ( symbol - > primary + n , ' 0 ' , zsecond_len ) ;
n + = zsecond_len + second_len ;
}
symbol - > primary [ n ] = ' \0 ' ;
2009-07-08 09:47:57 +12:00
}
2016-02-20 22:38:03 +13:00
int composite ( struct zint_symbol * symbol , unsigned char source [ ] , int length ) {
int error_number , cc_mode , cc_width , ecc_level ;
int j , i , k ;
unsigned int rs = length + 1 ;
unsigned int bs = 20 * rs ;
unsigned int pri_len ;
2009-06-03 08:23:38 +12:00
# ifndef _MSC_VER
2016-02-20 22:38:03 +13:00
char reduced [ rs ] ;
char binary_string [ bs ] ;
2009-06-03 08:23:38 +12:00
# else
2016-02-20 22:38:03 +13:00
char * reduced = ( char * ) _alloca ( rs ) ;
char * binary_string = ( char * ) _alloca ( bs ) ;
2009-06-03 08:23:38 +12:00
# endif
2016-02-20 22:38:03 +13:00
struct zint_symbol * linear ;
int top_shift , bottom_shift ;
error_number = 0 ;
pri_len = strlen ( symbol - > primary ) ;
if ( pri_len = = 0 ) {
strcpy ( symbol - > errtxt , " No primary (linear) message in 2D composite " ) ;
return ZINT_ERROR_INVALID_OPTION ;
}
if ( length > 2990 ) {
strcpy ( symbol - > errtxt , " 2D component input data too long " ) ;
return ZINT_ERROR_TOO_LONG ;
}
linear = ZBarcode_Create ( ) ; /* Symbol contains the 2D component and Linear contains the rest */
error_number = gs1_verify ( symbol , source , length , reduced ) ;
if ( error_number ! = 0 ) {
return error_number ;
}
cc_mode = symbol - > option_1 ;
if ( ( cc_mode = = 3 ) & & ( symbol - > symbology ! = BARCODE_EAN128_CC ) ) {
/* CC-C can only be used with a GS1-128 linear part */
strcpy ( symbol - > errtxt , " Invalid mode (CC-C only valid with GS1-128 linear component) " ) ;
return ZINT_ERROR_INVALID_OPTION ;
}
linear - > symbology = symbol - > symbology ;
if ( linear - > symbology ! = BARCODE_EAN128_CC ) {
/* Set the "component linkage" flag in the linear component */
linear - > option_1 = 2 ;
} else {
/* GS1-128 needs to know which type of 2D component is used */
linear - > option_1 = cc_mode ;
}
switch ( symbol - > symbology ) {
case BARCODE_EANX_CC : error_number = eanx ( linear , ( unsigned char * ) symbol - > primary , pri_len ) ;
break ;
case BARCODE_EAN128_CC : error_number = ean_128 ( linear , ( unsigned char * ) symbol - > primary , pri_len ) ;
break ;
case BARCODE_RSS14_CC : error_number = rss14 ( linear , ( unsigned char * ) symbol - > primary , pri_len ) ;
break ;
case BARCODE_RSS_LTD_CC : error_number = rsslimited ( linear , ( unsigned char * ) symbol - > primary , pri_len ) ;
break ;
case BARCODE_RSS_EXP_CC : error_number = rssexpanded ( linear , ( unsigned char * ) symbol - > primary , pri_len ) ;
break ;
case BARCODE_UPCA_CC : error_number = eanx ( linear , ( unsigned char * ) symbol - > primary , pri_len ) ;
break ;
case BARCODE_UPCE_CC : error_number = eanx ( linear , ( unsigned char * ) symbol - > primary , pri_len ) ;
break ;
case BARCODE_RSS14STACK_CC : error_number = rss14 ( linear , ( unsigned char * ) symbol - > primary , pri_len ) ;
break ;
case BARCODE_RSS14_OMNI_CC : error_number = rss14 ( linear , ( unsigned char * ) symbol - > primary , pri_len ) ;
break ;
case BARCODE_RSS_EXPSTACK_CC : error_number = rssexpanded ( linear , ( unsigned char * ) symbol - > primary , pri_len ) ;
break ;
}
if ( error_number ! = 0 ) {
strcpy ( symbol - > errtxt , linear - > errtxt ) ;
concat ( symbol - > errtxt , " in linear component " ) ;
return error_number ;
}
switch ( symbol - > symbology ) {
/* Determine width of 2D component according to ISO/IEC 24723 Table 1 */
case BARCODE_EANX_CC :
switch ( pri_len ) {
case 7 : /* EAN-8 */
case 10 : /* EAN-8 + 2 */
case 13 : /* EAN-8 + 5 */
cc_width = 3 ;
break ;
case 12 : /* EAN-13 */
case 15 : /* EAN-13 + 2 */
case 18 : /* EAN-13 + 5 */
cc_width = 4 ;
break ;
}
break ;
case BARCODE_EAN128_CC : cc_width = 4 ;
break ;
case BARCODE_RSS14_CC : cc_width = 4 ;
break ;
case BARCODE_RSS_LTD_CC : cc_width = 3 ;
break ;
case BARCODE_RSS_EXP_CC : cc_width = 4 ;
break ;
case BARCODE_UPCA_CC : cc_width = 4 ;
break ;
case BARCODE_UPCE_CC : cc_width = 2 ;
break ;
case BARCODE_RSS14STACK_CC : cc_width = 2 ;
break ;
case BARCODE_RSS14_OMNI_CC : cc_width = 2 ;
break ;
case BARCODE_RSS_EXPSTACK_CC : cc_width = 4 ;
break ;
}
memset ( binary_string , 0 , bs ) ;
if ( cc_mode < 1 | | cc_mode > 3 ) {
cc_mode = 1 ;
}
if ( cc_mode = = 1 ) {
i = cc_binary_string ( symbol , reduced , binary_string , cc_mode , & cc_width , & ecc_level , linear - > width ) ;
if ( i = = ZINT_ERROR_TOO_LONG ) {
cc_mode = 2 ;
}
}
if ( cc_mode = = 2 ) {
/* If the data didn't fit into CC-A it is recalculated for CC-B */
i = cc_binary_string ( symbol , reduced , binary_string , cc_mode , & cc_width , & ecc_level , linear - > width ) ;
if ( i = = ZINT_ERROR_TOO_LONG ) {
if ( symbol - > symbology ! = BARCODE_EAN128_CC ) {
return ZINT_ERROR_TOO_LONG ;
} else {
cc_mode = 3 ;
}
}
}
if ( cc_mode = = 3 ) {
/* If the data didn't fit in CC-B (and linear part is GS1-128) it is recalculated for CC-C */
i = cc_binary_string ( symbol , reduced , binary_string , cc_mode , & cc_width , & ecc_level , linear - > width ) ;
if ( i = = ZINT_ERROR_TOO_LONG ) {
return ZINT_ERROR_TOO_LONG ;
}
}
switch ( cc_mode ) {
/* Note that ecc_level is only relevant to CC-C */
case 1 : error_number = cc_a ( symbol , binary_string , cc_width ) ;
break ;
case 2 : error_number = cc_b ( symbol , binary_string , cc_width ) ;
break ;
case 3 : error_number = cc_c ( symbol , binary_string , cc_width , ecc_level ) ;
break ;
}
if ( error_number ! = 0 ) {
return ZINT_ERROR_ENCODING_PROBLEM ;
}
/* Merge the linear component with the 2D component */
top_shift = 0 ;
bottom_shift = 0 ;
switch ( symbol - > symbology ) {
/* Determine horizontal alignment (according to section 12.3) */
case BARCODE_EANX_CC :
switch ( pri_len ) {
case 7 : /* EAN-8 */
case 10 : /* EAN-8 + 2 */
case 13 : /* EAN-8 + 5 */
bottom_shift = 13 ;
break ;
case 12 : /* EAN-13 */
case 15 : /* EAN-13 + 2 */
case 18 : /* EAN-13 + 5 */
bottom_shift = 2 ;
break ;
}
break ;
case BARCODE_EAN128_CC : if ( cc_mode = = 3 ) {
bottom_shift = 7 ;
}
break ;
case BARCODE_RSS14_CC : bottom_shift = 4 ;
break ;
case BARCODE_RSS_LTD_CC : bottom_shift = 9 ;
break ;
case BARCODE_RSS_EXP_CC : k = 1 ;
while ( ( ! ( module_is_set ( linear , 1 , k - 1 ) ) ) & & module_is_set ( linear , 1 , k ) ) {
k + + ;
}
top_shift = k ;
break ;
case BARCODE_UPCA_CC : bottom_shift = 2 ;
break ;
case BARCODE_UPCE_CC : bottom_shift = 2 ;
break ;
case BARCODE_RSS14STACK_CC : top_shift = 1 ;
break ;
case BARCODE_RSS14_OMNI_CC : top_shift = 1 ;
break ;
case BARCODE_RSS_EXPSTACK_CC : k = 1 ;
while ( ( ! ( module_is_set ( linear , 1 , k - 1 ) ) ) & & module_is_set ( linear , 1 , k ) ) {
k + + ;
}
top_shift = k ;
break ;
}
if ( top_shift ! = 0 ) {
/* Move the 2d component of the symbol horizontally */
for ( i = 0 ; i < = symbol - > rows ; i + + ) {
for ( j = ( symbol - > width + top_shift ) ; j > = top_shift ; j - - ) {
if ( module_is_set ( symbol , i , j - top_shift ) ) {
set_module ( symbol , i , j ) ;
} else {
unset_module ( symbol , i , j ) ;
}
}
for ( j = 0 ; j < top_shift ; j + + ) {
unset_module ( symbol , i , j ) ;
}
}
}
/* Merge linear and 2D components into one structure */
for ( i = 0 ; i < = linear - > rows ; i + + ) {
symbol - > row_height [ symbol - > rows + i ] = linear - > row_height [ i ] ;
for ( j = 0 ; j < = linear - > width ; j + + ) {
if ( module_is_set ( linear , i , j ) ) {
set_module ( symbol , i + symbol - > rows , j + bottom_shift ) ;
} else {
unset_module ( symbol , i + symbol - > rows , j + bottom_shift ) ;
}
}
}
if ( ( linear - > width + bottom_shift ) > symbol - > width ) {
symbol - > width = linear - > width + bottom_shift ;
}
if ( ( symbol - > width + top_shift ) > symbol - > width ) {
symbol - > width + = top_shift ;
}
symbol - > rows + = linear - > rows ;
ustrcpy ( symbol - > text , ( unsigned char * ) linear - > text ) ;
ZBarcode_Delete ( linear ) ;
return error_number ;
2008-07-14 09:15:55 +12:00
}