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1 /****************************************************************************
2  *
3  * ftzopen.h
4  *
5  *   FreeType support for .Z compressed files.
6  *
7  * This optional component relies on NetBSD's zopen().  It should mainly
8  * be used to parse compressed PCF fonts, as found with many X11 server
9  * distributions.
10  *
11  * Copyright 2005-2018 by
12  * David Turner.
13  *
14  * This file is part of the FreeType project, and may only be used,
15  * modified, and distributed under the terms of the FreeType project
16  * license, LICENSE.TXT.  By continuing to use, modify, or distribute
17  * this file you indicate that you have read the license and
18  * understand and accept it fully.
19  *
20  */
21 
22 #ifndef FTZOPEN_H_
23 #define FTZOPEN_H_
24 
25 #include <ft2build.h>
26 #include FT_FREETYPE_H
27 
28 
29   /*
30    * This is a complete re-implementation of the LZW file reader,
31    * since the old one was incredibly badly written, using
32    * 400 KByte of heap memory before decompressing anything.
33    *
34    */
35 
36 #define FT_LZW_IN_BUFF_SIZE        64
37 #define FT_LZW_DEFAULT_STACK_SIZE  64
38 
39 #define LZW_INIT_BITS     9
40 #define LZW_MAX_BITS      16
41 
42 #define LZW_CLEAR         256
43 #define LZW_FIRST         257
44 
45 #define LZW_BIT_MASK      0x1F
46 #define LZW_BLOCK_MASK    0x80
47 #define LZW_MASK( n )     ( ( 1U << (n) ) - 1U )
48 
49 
50   typedef enum  FT_LzwPhase_
51   {
52     FT_LZW_PHASE_START = 0,
53     FT_LZW_PHASE_CODE,
54     FT_LZW_PHASE_STACK,
55     FT_LZW_PHASE_EOF
56 
57   } FT_LzwPhase;
58 
59 
60   /*
61    * state of LZW decompressor
62    *
63    * small technical note
64    * --------------------
65    *
66    * We use a few tricks in this implementation that are explained here to
67    * ease debugging and maintenance.
68    *
69    * - First of all, the `prefix' and `suffix' arrays contain the suffix
70    *   and prefix for codes over 256; this means that
71    *
72    *     prefix_of(code) == state->prefix[code-256]
73    *     suffix_of(code) == state->suffix[code-256]
74    *
75    *   Each prefix is a 16-bit code, and each suffix an 8-bit byte.
76    *
77    *   Both arrays are stored in a single memory block, pointed to by
78    *   `state->prefix'.  This means that the following equality is always
79    *   true:
80    *
81    *     state->suffix == (FT_Byte*)(state->prefix + state->prefix_size)
82    *
83    *   Of course, state->prefix_size is the number of prefix/suffix slots
84    *   in the arrays, corresponding to codes 256..255+prefix_size.
85    *
86    * - `free_ent' is the index of the next free entry in the `prefix'
87    *   and `suffix' arrays.  This means that the corresponding `next free
88    *   code' is really `256+free_ent'.
89    *
90    *   Moreover, `max_free' is the maximum value that `free_ent' can reach.
91    *
92    *   `max_free' corresponds to `(1 << max_bits) - 256'.  Note that this
93    *   value is always <= 0xFF00, which means that both `free_ent' and
94    *   `max_free' can be stored in an FT_UInt variable, even on 16-bit
95    *   machines.
96    *
97    *   If `free_ent == max_free', you cannot add new codes to the
98    *   prefix/suffix table.
99    *
100    * - `num_bits' is the current number of code bits, starting at 9 and
101    *   growing each time `free_ent' reaches the value of `free_bits'.  The
102    *   latter is computed as follows
103    *
104    *     if num_bits < max_bits:
105    *        free_bits = (1 << num_bits)-256
106    *     else:
107    *        free_bits = max_free + 1
108    *
109    *   Since the value of `max_free + 1' can never be reached by
110    *   `free_ent', `num_bits' cannot grow larger than `max_bits'.
111    */
112 
113   typedef struct  FT_LzwStateRec_
114   {
115     FT_LzwPhase  phase;
116     FT_Int       in_eof;
117 
118     FT_Byte      buf_tab[16];
119     FT_UInt      buf_offset;
120     FT_UInt      buf_size;
121     FT_Bool      buf_clear;
122     FT_Offset    buf_total;
123 
124     FT_UInt      max_bits;    /* max code bits, from file header   */
125     FT_Int       block_mode;  /* block mode flag, from file header */
126     FT_UInt      max_free;    /* (1 << max_bits) - 256             */
127 
128     FT_UInt      num_bits;    /* current code bit number */
129     FT_UInt      free_ent;    /* index of next free entry */
130     FT_UInt      free_bits;   /* if reached by free_ent, increment num_bits */
131     FT_UInt      old_code;
132     FT_UInt      old_char;
133     FT_UInt      in_code;
134 
135     FT_UShort*   prefix;      /* always dynamically allocated / reallocated */
136     FT_Byte*     suffix;      /* suffix = (FT_Byte*)(prefix + prefix_size)  */
137     FT_UInt      prefix_size; /* number of slots in `prefix' or `suffix'    */
138 
139     FT_Byte*     stack;       /* character stack */
140     FT_UInt      stack_top;
141     FT_Offset    stack_size;
142     FT_Byte      stack_0[FT_LZW_DEFAULT_STACK_SIZE]; /* minimize heap alloc */
143 
144     FT_Stream    source;      /* source stream */
145     FT_Memory    memory;
146 
147   } FT_LzwStateRec, *FT_LzwState;
148 
149 
150   FT_LOCAL( void )
151   ft_lzwstate_init( FT_LzwState  state,
152                     FT_Stream    source );
153 
154   FT_LOCAL( void )
155   ft_lzwstate_done( FT_LzwState  state );
156 
157 
158   FT_LOCAL( void )
159   ft_lzwstate_reset( FT_LzwState  state );
160 
161 
162   FT_LOCAL( FT_ULong )
163   ft_lzwstate_io( FT_LzwState  state,
164                   FT_Byte*     buffer,
165                   FT_ULong     out_size );
166 
167 /* */
168 
169 #endif /* FTZOPEN_H_ */
170 
171 
172 /* END */
173