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/* Fax G3/G4 tables */
/*
<raph> the first 2^(initialbits) entries map bit patterns to decodes
<raph> let's say initial_bits is 8 for the sake of example
<raph> and that the code is 1001
<raph> that means that entries 0x90 .. 0x9f have the entry { val, 4 }
<raph> because those are all the bytes that start with the code
<raph> and the 4 is the length of the code
... if (n_bits > initial_bits) ...
<raph> anyway, in that case, it basically points to a mini table
<raph> the n_bits is the maximum length of all codes beginning with that byte
<raph> so 2^(n_bits - initial_bits) is the size of the mini-table
<raph> peter came up with this, and it makes sense
*/
typedef struct cfd_node_s cfd_node;
struct cfd_node_s
{
short val;
short nbits;
};
enum
{
cfd_white_initial_bits = 8,
cfd_black_initial_bits = 7,
cfd_2d_initial_bits = 7,
cfd_uncompressed_initial_bits = 6 /* must be 6 */
};
/* non-run codes in tables */
enum
{
ERROR = -1,
ZEROS = -2, /* EOL follows, possibly with more padding first */
UNCOMPRESSED = -3
};
/* semantic codes for cf_2d_decode */
enum
{
P = -4,
H = -5,
VR3 = 0,
VR2 = 1,
VR1 = 2,
V0 = 3,
VL1 = 4,
VL2 = 5,
VL3 = 6
};
/* Decoding tables */
extern const cfd_node cf_white_decode[];
extern const cfd_node cf_black_decode[];
extern const cfd_node cf_2d_decode[];
extern const cfd_node cf_uncompressed_decode[];
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