third_party/zlib/contrib/blast/blast.c - bazel - Git at Google

 /* blast.c
  * Copyright (C) 2003, 2012, 2013 Mark Adler
  * For conditions of distribution and use, see copyright notice in blast.h
  * version 1.3, 24 Aug 2013
  *
  * blast.c decompresses data compressed by the PKWare Compression Library.
  * This function provides functionality similar to the explode() function of
  * the PKWare library, hence the name "blast".
  *
  * This decompressor is based on the excellent format description provided by
  * Ben Rudiak-Gould in comp.compression on August 13, 2001.  Interestingly, the
  * example Ben provided in the post is incorrect.  The distance 110001 should
  * instead be 111000.  When corrected, the example byte stream becomes:
  *
  *    00 04 82 24 25 8f 80 7f
  *
  * which decompresses to "AIAIAIAIAIAIA" (without the quotes).
  */

 /*
  * Change history:
  *
  * 1.0  12 Feb 2003     - First version
  * 1.1  16 Feb 2003     - Fixed distance check for > 4 GB uncompressed data
  * 1.2  24 Oct 2012     - Add note about using binary mode in stdio
  *                      - Fix comparisons of differently signed integers
  * 1.3  24 Aug 2013     - Return unused input from blast()
  *                      - Fix test code to correctly report unused input
  *                      - Enable the provision of initial input to blast()
  */

 #include <stddef.h>             /* for NULL */
 #include <setjmp.h>             /* for setjmp(), longjmp(), and jmp_buf */
 #include "blast.h"              /* prototype for blast() */

 #define local static            /* for local function definitions */
 #define MAXBITS 13              /* maximum code length */
 #define MAXWIN 4096             /* maximum window size */

 /* input and output state */
 struct state {
     /* input state */
     blast_in infun;             /* input function provided by user */
     void *inhow;                /* opaque information passed to infun() */
     unsigned char *in;          /* next input location */
     unsigned left;              /* available input at in */
     int bitbuf;                 /* bit buffer */
     int bitcnt;                 /* number of bits in bit buffer */

     /* input limit error return state for bits() and decode() */
     jmp_buf env;

     /* output state */
     blast_out outfun;           /* output function provided by user */
     void *outhow;               /* opaque information passed to outfun() */
     unsigned next;              /* index of next write location in out[] */
     int first;                  /* true to check distances (for first 4K) */
     unsigned char out[MAXWIN];  /* output buffer and sliding window */
 };

 /*
  * Return need bits from the input stream.  This always leaves less than
  * eight bits in the buffer.  bits() works properly for need == 0.
  *
  * Format notes:
  *
  * - Bits are stored in bytes from the least significant bit to the most
  *   significant bit.  Therefore bits are dropped from the bottom of the bit
  *   buffer, using shift right, and new bytes are appended to the top of the
  *   bit buffer, using shift left.
  */
 local int bits(struct state *s, int need)
 {
     int val;            /* bit accumulator */

     /* load at least need bits into val */
     val = s->bitbuf;
     while (s->bitcnt < need) {
         if (s->left == 0) {
             s->left = s->infun(s->inhow, &(s->in));
             if (s->left == 0) longjmp(s->env, 1);       /* out of input */
         }
         val |= (int)(*(s->in)++) << s->bitcnt;          /* load eight bits */
         s->left--;
         s->bitcnt += 8;
     }

     /* drop need bits and update buffer, always zero to seven bits left */
     s->bitbuf = val >> need;
     s->bitcnt -= need;

     /* return need bits, zeroing the bits above that */
     return val & ((1 << need) - 1);
 }

 /*
  * Huffman code decoding tables.  count[1..MAXBITS] is the number of symbols of
  * each length, which for a canonical code are stepped through in order.
  * symbol[] are the symbol values in canonical order, where the number of
  * entries is the sum of the counts in count[].  The decoding process can be
  * seen in the function decode() below.
  */
 struct huffman {
     short *count;       /* number of symbols of each length */
     short *symbol;      /* canonically ordered symbols */
 };

 /*
  * Decode a code from the stream s using huffman table h.  Return the symbol or
  * a negative value if there is an error.  If all of the lengths are zero, i.e.
  * an empty code, or if the code is incomplete and an invalid code is received,
  * then -9 is returned after reading MAXBITS bits.
  *
  * Format notes:
  *
  * - The codes as stored in the compressed data are bit-reversed relative to
  *   a simple integer ordering of codes of the same lengths.  Hence below the
  *   bits are pulled from the compressed data one at a time and used to
  *   build the code value reversed from what is in the stream in order to
  *   permit simple integer comparisons for decoding.
  *
  * - The first code for the shortest length is all ones.  Subsequent codes of
  *   the same length are simply integer decrements of the previous code.  When
  *   moving up a length, a one bit is appended to the code.  For a complete
  *   code, the last code of the longest length will be all zeros.  To support
  *   this ordering, the bits pulled during decoding are inverted to apply the
  *   more "natural" ordering starting with all zeros and incrementing.
  */
 local int decode(struct state *s, struct huffman *h)
 {
     int len;            /* current number of bits in code */
     int code;           /* len bits being decoded */
     int first;          /* first code of length len */
     int count;          /* number of codes of length len */
     int index;          /* index of first code of length len in symbol table */
     int bitbuf;         /* bits from stream */
     int left;           /* bits left in next or left to process */
     short *next;        /* next number of codes */

     bitbuf = s->bitbuf;
     left = s->bitcnt;
     code = first = index = 0;
     len = 1;
     next = h->count + 1;
     while (1) {
         while (left--) {
             code |= (bitbuf & 1) ^ 1;   /* invert code */
             bitbuf >>= 1;
             count = *next++;
             if (code < first + count) { /* if length len, return symbol */
                 s->bitbuf = bitbuf;
                 s->bitcnt = (s->bitcnt - len) & 7;
                 return h->symbol[index + (code - first)];
             }
             index += count;             /* else update for next length */
             first += count;
             first <<= 1;
             code <<= 1;
             len++;
         }
         left = (MAXBITS+1) - len;
         if (left == 0) break;
         if (s->left == 0) {
             s->left = s->infun(s->inhow, &(s->in));
             if (s->left == 0) longjmp(s->env, 1);       /* out of input */
         }
         bitbuf = *(s->in)++;
         s->left--;
         if (left > 8) left = 8;
     }
     return -9;                          /* ran out of codes */
 }

 /*
  * Given a list of repeated code lengths rep[0..n-1], where each byte is a
  * count (high four bits + 1) and a code length (low four bits), generate the
  * list of code lengths.  This compaction reduces the size of the object code.
  * Then given the list of code lengths length[0..n-1] representing a canonical
  * Huffman code for n symbols, construct the tables required to decode those
  * codes.  Those tables are the number of codes of each length, and the symbols
  * sorted by length, retaining their original order within each length.  The
  * return value is zero for a complete code set, negative for an over-
  * subscribed code set, and positive for an incomplete code set.  The tables
  * can be used if the return value is zero or positive, but they cannot be used
  * if the return value is negative.  If the return value is zero, it is not
  * possible for decode() using that table to return an error--any stream of
  * enough bits will resolve to a symbol.  If the return value is positive, then
  * it is possible for decode() using that table to return an error for received
  * codes past the end of the incomplete lengths.
  */
 local int construct(struct huffman *h, const unsigned char *rep, int n)
 {
     int symbol;         /* current symbol when stepping through length[] */
     int len;            /* current length when stepping through h->count[] */
     int left;           /* number of possible codes left of current length */
     short offs[MAXBITS+1];      /* offsets in symbol table for each length */
     short length[256];  /* code lengths */

     /* convert compact repeat counts into symbol bit length list */
     symbol = 0;
     do {
         len = *rep++;
         left = (len >> 4) + 1;
         len &= 15;
         do {
             length[symbol++] = len;
         } while (--left);
     } while (--n);
     n = symbol;

     /* count number of codes of each length */
     for (len = 0; len <= MAXBITS; len++)
         h->count[len] = 0;
     for (symbol = 0; symbol < n; symbol++)
         (h->count[length[symbol]])++;   /* assumes lengths are within bounds */
     if (h->count[0] == n)               /* no codes! */
         return 0;                       /* complete, but decode() will fail */

     /* check for an over-subscribed or incomplete set of lengths */
     left = 1;                           /* one possible code of zero length */
     for (len = 1; len <= MAXBITS; len++) {
         left <<= 1;                     /* one more bit, double codes left */
         left -= h->count[len];          /* deduct count from possible codes */
         if (left < 0) return left;      /* over-subscribed--return negative */
     }                                   /* left > 0 means incomplete */

     /* generate offsets into symbol table for each length for sorting */
     offs[1] = 0;
     for (len = 1; len < MAXBITS; len++)
         offs[len + 1] = offs[len] + h->count[len];

     /*
      * put symbols in table sorted by length, by symbol order within each
      * length
      */
     for (symbol = 0; symbol < n; symbol++)
         if (length[symbol] != 0)
             h->symbol[offs[length[symbol]]++] = symbol;

     /* return zero for complete set, positive for incomplete set */
     return left;
 }

 /*
  * Decode PKWare Compression Library stream.
  *
  * Format notes:
  *
  * - First byte is 0 if literals are uncoded or 1 if they are coded.  Second
  *   byte is 4, 5, or 6 for the number of extra bits in the distance code.
  *   This is the base-2 logarithm of the dictionary size minus six.
  *
  * - Compressed data is a combination of literals and length/distance pairs
  *   terminated by an end code.  Literals are either Huffman coded or
  *   uncoded bytes.  A length/distance pair is a coded length followed by a
  *   coded distance to represent a string that occurs earlier in the
  *   uncompressed data that occurs again at the current location.
  *
  * - A bit preceding a literal or length/distance pair indicates which comes
  *   next, 0 for literals, 1 for length/distance.
  *
  * - If literals are uncoded, then the next eight bits are the literal, in the
  *   normal bit order in the stream, i.e. no bit-reversal is needed. Similarly,
  *   no bit reversal is needed for either the length extra bits or the distance
  *   extra bits.
  *
  * - Literal bytes are simply written to the output.  A length/distance pair is
  *   an instruction to copy previously uncompressed bytes to the output.  The
  *   copy is from distance bytes back in the output stream, copying for length
  *   bytes.
  *
  * - Distances pointing before the beginning of the output data are not
  *   permitted.
  *
  * - Overlapped copies, where the length is greater than the distance, are
  *   allowed and common.  For example, a distance of one and a length of 518
  *   simply copies the last byte 518 times.  A distance of four and a length of
  *   twelve copies the last four bytes three times.  A simple forward copy
  *   ignoring whether the length is greater than the distance or not implements
  *   this correctly.
  */
 local int decomp(struct state *s)
 {
     int lit;            /* true if literals are coded */
     int dict;           /* log2(dictionary size) - 6 */
     int symbol;         /* decoded symbol, extra bits for distance */
     int len;            /* length for copy */
     unsigned dist;      /* distance for copy */
     int copy;           /* copy counter */
     unsigned char *from, *to;   /* copy pointers */
     static int virgin = 1;                              /* build tables once */
     static short litcnt[MAXBITS+1], litsym[256];        /* litcode memory */
     static short lencnt[MAXBITS+1], lensym[16];         /* lencode memory */
     static short distcnt[MAXBITS+1], distsym[64];       /* distcode memory */
     static struct huffman litcode = {litcnt, litsym};   /* length code */
     static struct huffman lencode = {lencnt, lensym};   /* length code */
     static struct huffman distcode = {distcnt, distsym};/* distance code */
         /* bit lengths of literal codes */
     static const unsigned char litlen[] = {
         11, 124, 8, 7, 28, 7, 188, 13, 76, 4, 10, 8, 12, 10, 12, 10, 8, 23, 8,
         9, 7, 6, 7, 8, 7, 6, 55, 8, 23, 24, 12, 11, 7, 9, 11, 12, 6, 7, 22, 5,
         7, 24, 6, 11, 9, 6, 7, 22, 7, 11, 38, 7, 9, 8, 25, 11, 8, 11, 9, 12,
         8, 12, 5, 38, 5, 38, 5, 11, 7, 5, 6, 21, 6, 10, 53, 8, 7, 24, 10, 27,
         44, 253, 253, 253, 252, 252, 252, 13, 12, 45, 12, 45, 12, 61, 12, 45,
         44, 173};
         /* bit lengths of length codes 0..15 */
     static const unsigned char lenlen[] = {2, 35, 36, 53, 38, 23};
         /* bit lengths of distance codes 0..63 */
     static const unsigned char distlen[] = {2, 20, 53, 230, 247, 151, 248};
     static const short base[16] = {     /* base for length codes */
         3, 2, 4, 5, 6, 7, 8, 9, 10, 12, 16, 24, 40, 72, 136, 264};
     static const char extra[16] = {     /* extra bits for length codes */
         0, 0, 0, 0, 0, 0, 0, 0, 1, 2, 3, 4, 5, 6, 7, 8};

     /* set up decoding tables (once--might not be thread-safe) */
     if (virgin) {
         construct(&litcode, litlen, sizeof(litlen));
         construct(&lencode, lenlen, sizeof(lenlen));
         construct(&distcode, distlen, sizeof(distlen));
         virgin = 0;
     }

     /* read header */
     lit = bits(s, 8);
     if (lit > 1) return -1;
     dict = bits(s, 8);
     if (dict < 4 || dict > 6) return -2;

     /* decode literals and length/distance pairs */
     do {
         if (bits(s, 1)) {
             /* get length */
             symbol = decode(s, &lencode);
             len = base[symbol] + bits(s, extra[symbol]);
             if (len == 519) break;              /* end code */

             /* get distance */
             symbol = len == 2 ? 2 : dict;
             dist = decode(s, &distcode) << symbol;
             dist += bits(s, symbol);
             dist++;
             if (s->first && dist > s->next)
                 return -3;              /* distance too far back */

             /* copy length bytes from distance bytes back */
             do {
                 to = s->out + s->next;
                 from = to - dist;
                 copy = MAXWIN;
                 if (s->next < dist) {
                     from += copy;
                     copy = dist;
                 }
                 copy -= s->next;
                 if (copy > len) copy = len;
                 len -= copy;
                 s->next += copy;
                 do {
                     *to++ = *from++;
                 } while (--copy);
                 if (s->next == MAXWIN) {
                     if (s->outfun(s->outhow, s->out, s->next)) return 1;
                     s->next = 0;
                     s->first = 0;
                 }
             } while (len != 0);
         }
         else {
             /* get literal and write it */
             symbol = lit ? decode(s, &litcode) : bits(s, 8);
             s->out[s->next++] = symbol;
             if (s->next == MAXWIN) {
                 if (s->outfun(s->outhow, s->out, s->next)) return 1;
                 s->next = 0;
                 s->first = 0;
             }
         }
     } while (1);
     return 0;
 }

 /* See comments in blast.h */
 int blast(blast_in infun, void *inhow, blast_out outfun, void *outhow,
           unsigned *left, unsigned char **in)
 {
     struct state s;             /* input/output state */
     int err;                    /* return value */

     /* initialize input state */
     s.infun = infun;
     s.inhow = inhow;
     if (left != NULL && *left) {
         s.left = *left;
         s.in = *in;
     }
     else
         s.left = 0;
     s.bitbuf = 0;
     s.bitcnt = 0;

     /* initialize output state */
     s.outfun = outfun;
     s.outhow = outhow;
     s.next = 0;
     s.first = 1;

     /* return if bits() or decode() tries to read past available input */
     if (setjmp(s.env) != 0)             /* if came back here via longjmp(), */
         err = 2;                        /*  then skip decomp(), return error */
     else
         err = decomp(&s);               /* decompress */

     /* return unused input */
     if (left != NULL)
         *left = s.left;
     if (in != NULL)
         *in = s.left ? s.in : NULL;

     /* write any leftover output and update the error code if needed */
     if (err != 1 && s.next && s.outfun(s.outhow, s.out, s.next) && err == 0)
         err = 1;
     return err;
 }

 #ifdef TEST
 /* Example of how to use blast() */
 #include <stdio.h>
 #include <stdlib.h>

 #define CHUNK 16384

 local unsigned inf(void *how, unsigned char **buf)
 {
     static unsigned char hold[CHUNK];

     *buf = hold;
     return fread(hold, 1, CHUNK, (FILE *)how);
 }

 local int outf(void *how, unsigned char *buf, unsigned len)
 {
     return fwrite(buf, 1, len, (FILE *)how) != len;
 }

 /* Decompress a PKWare Compression Library stream from stdin to stdout */
 int main(void)
 {
     int ret;
     unsigned left;

     /* decompress to stdout */
     left = 0;
     ret = blast(inf, stdin, outf, stdout, &left, NULL);
     if (ret != 0)
         fprintf(stderr, "blast error: %d\n", ret);

     /* count any leftover bytes */
     while (getchar() != EOF)
         left++;
     if (left)
         fprintf(stderr, "blast warning: %u unused bytes of input\n", left);

     /* return blast() error code */
     return ret;
 }
 #endif
	/* blast.c
	* Copyright (C) 2003, 2012, 2013 Mark Adler
	* For conditions of distribution and use, see copyright notice in blast.h
	* version 1.3, 24 Aug 2013
	*
	* blast.c decompresses data compressed by the PKWare Compression Library.
	* This function provides functionality similar to the explode() function of
	* the PKWare library, hence the name "blast".
	*
	* This decompressor is based on the excellent format description provided by
	* Ben Rudiak-Gould in comp.compression on August 13, 2001. Interestingly, the
	* example Ben provided in the post is incorrect. The distance 110001 should
	* instead be 111000. When corrected, the example byte stream becomes:
	*
	* 00 04 82 24 25 8f 80 7f
	*
	* which decompresses to "AIAIAIAIAIAIA" (without the quotes).
	*/

	/*
	* Change history:
	*
	* 1.0 12 Feb 2003 - First version
	* 1.1 16 Feb 2003 - Fixed distance check for > 4 GB uncompressed data
	* 1.2 24 Oct 2012 - Add note about using binary mode in stdio
	* - Fix comparisons of differently signed integers
	* 1.3 24 Aug 2013 - Return unused input from blast()
	* - Fix test code to correctly report unused input
	* - Enable the provision of initial input to blast()
	*/

	#include <stddef.h> /* for NULL */
	#include <setjmp.h> /* for setjmp(), longjmp(), and jmp_buf */
	#include "blast.h" /* prototype for blast() */

	#define local static /* for local function definitions */
	#define MAXBITS 13 /* maximum code length */
	#define MAXWIN 4096 /* maximum window size */

	/* input and output state */
	struct state {
	/* input state */
	blast_in infun; /* input function provided by user */
	void inhow; / opaque information passed to infun() */
	unsigned char in; / next input location */
	unsigned left; /* available input at in */
	int bitbuf; /* bit buffer */
	int bitcnt; /* number of bits in bit buffer */

	/* input limit error return state for bits() and decode() */
	jmp_buf env;

	/* output state */
	blast_out outfun; /* output function provided by user */
	void outhow; / opaque information passed to outfun() */
	unsigned next; /* index of next write location in out[] */
	int first; /* true to check distances (for first 4K) */
	unsigned char out[MAXWIN]; /* output buffer and sliding window */
	};

	/*
	* Return need bits from the input stream. This always leaves less than
	* eight bits in the buffer. bits() works properly for need == 0.
	*
	* Format notes:
	*
	* - Bits are stored in bytes from the least significant bit to the most
	* significant bit. Therefore bits are dropped from the bottom of the bit
	* buffer, using shift right, and new bytes are appended to the top of the
	* bit buffer, using shift left.
	*/
	local int bits(struct state *s, int need)
	{
	int val; /* bit accumulator */

	/* load at least need bits into val */
	val = s->bitbuf;
	while (s->bitcnt < need) {
	if (s->left == 0) {
	s->left = s->infun(s->inhow, &(s->in));
	if (s->left == 0) longjmp(s->env, 1); /* out of input */
	}
	val \|= (int)((s->in)++) << s->bitcnt; / load eight bits */
	s->left--;
	s->bitcnt += 8;
	}

	/* drop need bits and update buffer, always zero to seven bits left */
	s->bitbuf = val >> need;
	s->bitcnt -= need;

	/* return need bits, zeroing the bits above that */
	return val & ((1 << need) - 1);
	}

	/*
	* Huffman code decoding tables. count[1..MAXBITS] is the number of symbols of
	* each length, which for a canonical code are stepped through in order.
	* symbol[] are the symbol values in canonical order, where the number of
	* entries is the sum of the counts in count[]. The decoding process can be
	* seen in the function decode() below.
	*/
	struct huffman {
	short count; / number of symbols of each length */
	short symbol; / canonically ordered symbols */
	};

	/*
	* Decode a code from the stream s using huffman table h. Return the symbol or
	* a negative value if there is an error. If all of the lengths are zero, i.e.
	* an empty code, or if the code is incomplete and an invalid code is received,
	* then -9 is returned after reading MAXBITS bits.
	*
	* Format notes:
	*
	* - The codes as stored in the compressed data are bit-reversed relative to
	* a simple integer ordering of codes of the same lengths. Hence below the
	* bits are pulled from the compressed data one at a time and used to
	* build the code value reversed from what is in the stream in order to
	* permit simple integer comparisons for decoding.
	*
	* - The first code for the shortest length is all ones. Subsequent codes of
	* the same length are simply integer decrements of the previous code. When
	* moving up a length, a one bit is appended to the code. For a complete
	* code, the last code of the longest length will be all zeros. To support
	* this ordering, the bits pulled during decoding are inverted to apply the
	* more "natural" ordering starting with all zeros and incrementing.
	*/
	local int decode(struct state s, struct huffman h)
	{
	int len; /* current number of bits in code */
	int code; /* len bits being decoded */
	int first; /* first code of length len */
	int count; /* number of codes of length len */
	int index; /* index of first code of length len in symbol table */
	int bitbuf; /* bits from stream */
	int left; /* bits left in next or left to process */
	short next; / next number of codes */

	bitbuf = s->bitbuf;
	left = s->bitcnt;
	code = first = index = 0;
	len = 1;
	next = h->count + 1;
	while (1) {
	while (left--) {
	code \|= (bitbuf & 1) ^ 1; /* invert code */
	bitbuf >>= 1;
	count = *next++;
	if (code < first + count) { /* if length len, return symbol */
	s->bitbuf = bitbuf;
	s->bitcnt = (s->bitcnt - len) & 7;
	return h->symbol[index + (code - first)];
	}
	index += count; /* else update for next length */
	first += count;
	first <<= 1;
	code <<= 1;
	len++;
	}
	left = (MAXBITS+1) - len;
	if (left == 0) break;
	if (s->left == 0) {
	s->left = s->infun(s->inhow, &(s->in));
	if (s->left == 0) longjmp(s->env, 1); /* out of input */
	}
	bitbuf = *(s->in)++;
	s->left--;
	if (left > 8) left = 8;
	}
	return -9; /* ran out of codes */
	}

	/*
	* Given a list of repeated code lengths rep[0..n-1], where each byte is a
	* count (high four bits + 1) and a code length (low four bits), generate the
	* list of code lengths. This compaction reduces the size of the object code.
	* Then given the list of code lengths length[0..n-1] representing a canonical
	* Huffman code for n symbols, construct the tables required to decode those
	* codes. Those tables are the number of codes of each length, and the symbols
	* sorted by length, retaining their original order within each length. The
	* return value is zero for a complete code set, negative for an over-
	* subscribed code set, and positive for an incomplete code set. The tables
	* can be used if the return value is zero or positive, but they cannot be used
	* if the return value is negative. If the return value is zero, it is not
	* possible for decode() using that table to return an error--any stream of
	* enough bits will resolve to a symbol. If the return value is positive, then
	* it is possible for decode() using that table to return an error for received
	* codes past the end of the incomplete lengths.
	*/
	local int construct(struct huffman h, const unsigned char rep, int n)
	{
	int symbol; /* current symbol when stepping through length[] */
	int len; /* current length when stepping through h->count[] */
	int left; /* number of possible codes left of current length */
	short offs[MAXBITS+1]; /* offsets in symbol table for each length */
	short length[256]; /* code lengths */

	/* convert compact repeat counts into symbol bit length list */
	symbol = 0;
	do {
	len = *rep++;
	left = (len >> 4) + 1;
	len &= 15;
	do {
	length[symbol++] = len;
	} while (--left);
	} while (--n);
	n = symbol;

	/* count number of codes of each length */
	for (len = 0; len <= MAXBITS; len++)
	h->count[len] = 0;
	for (symbol = 0; symbol < n; symbol++)
	(h->count[length[symbol]])++; /* assumes lengths are within bounds */
	if (h->count[0] == n) /* no codes! */
	return 0; /* complete, but decode() will fail */

	/* check for an over-subscribed or incomplete set of lengths */
	left = 1; /* one possible code of zero length */
	for (len = 1; len <= MAXBITS; len++) {
	left <<= 1; /* one more bit, double codes left */
	left -= h->count[len]; /* deduct count from possible codes */
	if (left < 0) return left; /* over-subscribed--return negative */
	} /* left > 0 means incomplete */

	/* generate offsets into symbol table for each length for sorting */
	offs[1] = 0;
	for (len = 1; len < MAXBITS; len++)
	offs[len + 1] = offs[len] + h->count[len];

	/*
	* put symbols in table sorted by length, by symbol order within each
	* length
	*/
	for (symbol = 0; symbol < n; symbol++)
	if (length[symbol] != 0)
	h->symbol[offs[length[symbol]]++] = symbol;

	/* return zero for complete set, positive for incomplete set */
	return left;
	}

	/*
	* Decode PKWare Compression Library stream.
	*
	* Format notes:
	*
	* - First byte is 0 if literals are uncoded or 1 if they are coded. Second
	* byte is 4, 5, or 6 for the number of extra bits in the distance code.
	* This is the base-2 logarithm of the dictionary size minus six.
	*
	* - Compressed data is a combination of literals and length/distance pairs
	* terminated by an end code. Literals are either Huffman coded or
	* uncoded bytes. A length/distance pair is a coded length followed by a
	* coded distance to represent a string that occurs earlier in the
	* uncompressed data that occurs again at the current location.
	*
	* - A bit preceding a literal or length/distance pair indicates which comes
	* next, 0 for literals, 1 for length/distance.
	*
	* - If literals are uncoded, then the next eight bits are the literal, in the
	* normal bit order in the stream, i.e. no bit-reversal is needed. Similarly,
	* no bit reversal is needed for either the length extra bits or the distance
	* extra bits.
	*
	* - Literal bytes are simply written to the output. A length/distance pair is
	* an instruction to copy previously uncompressed bytes to the output. The
	* copy is from distance bytes back in the output stream, copying for length
	* bytes.
	*
	* - Distances pointing before the beginning of the output data are not
	* permitted.
	*
	* - Overlapped copies, where the length is greater than the distance, are
	* allowed and common. For example, a distance of one and a length of 518
	* simply copies the last byte 518 times. A distance of four and a length of
	* twelve copies the last four bytes three times. A simple forward copy
	* ignoring whether the length is greater than the distance or not implements
	* this correctly.
	*/
	local int decomp(struct state *s)
	{
	int lit; /* true if literals are coded */
	int dict; /* log2(dictionary size) - 6 */
	int symbol; /* decoded symbol, extra bits for distance */
	int len; /* length for copy */
	unsigned dist; /* distance for copy */
	int copy; /* copy counter */
	unsigned char from, to; /* copy pointers */
	static int virgin = 1; /* build tables once */
	static short litcnt[MAXBITS+1], litsym[256]; /* litcode memory */
	static short lencnt[MAXBITS+1], lensym[16]; /* lencode memory */
	static short distcnt[MAXBITS+1], distsym[64]; /* distcode memory */
	static struct huffman litcode = {litcnt, litsym}; /* length code */
	static struct huffman lencode = {lencnt, lensym}; /* length code */
	static struct huffman distcode = {distcnt, distsym};/* distance code */
	/* bit lengths of literal codes */
	static const unsigned char litlen[] = {
	11, 124, 8, 7, 28, 7, 188, 13, 76, 4, 10, 8, 12, 10, 12, 10, 8, 23, 8,
	9, 7, 6, 7, 8, 7, 6, 55, 8, 23, 24, 12, 11, 7, 9, 11, 12, 6, 7, 22, 5,
	7, 24, 6, 11, 9, 6, 7, 22, 7, 11, 38, 7, 9, 8, 25, 11, 8, 11, 9, 12,
	8, 12, 5, 38, 5, 38, 5, 11, 7, 5, 6, 21, 6, 10, 53, 8, 7, 24, 10, 27,
	44, 253, 253, 253, 252, 252, 252, 13, 12, 45, 12, 45, 12, 61, 12, 45,
	44, 173};
	/* bit lengths of length codes 0..15 */
	static const unsigned char lenlen[] = {2, 35, 36, 53, 38, 23};
	/* bit lengths of distance codes 0..63 */
	static const unsigned char distlen[] = {2, 20, 53, 230, 247, 151, 248};
	static const short base[16] = { /* base for length codes */
	3, 2, 4, 5, 6, 7, 8, 9, 10, 12, 16, 24, 40, 72, 136, 264};
	static const char extra[16] = { /* extra bits for length codes */
	0, 0, 0, 0, 0, 0, 0, 0, 1, 2, 3, 4, 5, 6, 7, 8};

	/* set up decoding tables (once--might not be thread-safe) */
	if (virgin) {
	construct(&litcode, litlen, sizeof(litlen));
	construct(&lencode, lenlen, sizeof(lenlen));
	construct(&distcode, distlen, sizeof(distlen));
	virgin = 0;
	}

	/* read header */
	lit = bits(s, 8);
	if (lit > 1) return -1;
	dict = bits(s, 8);
	if (dict < 4 \|\| dict > 6) return -2;

	/* decode literals and length/distance pairs */
	do {
	if (bits(s, 1)) {
	/* get length */
	symbol = decode(s, &lencode);
	len = base[symbol] + bits(s, extra[symbol]);
	if (len == 519) break; /* end code */

	/* get distance */
	symbol = len == 2 ? 2 : dict;
	dist = decode(s, &distcode) << symbol;
	dist += bits(s, symbol);
	dist++;
	if (s->first && dist > s->next)
	return -3; /* distance too far back */

	/* copy length bytes from distance bytes back */
	do {
	to = s->out + s->next;
	from = to - dist;
	copy = MAXWIN;
	if (s->next < dist) {
	from += copy;
	copy = dist;
	}
	copy -= s->next;
	if (copy > len) copy = len;
	len -= copy;
	s->next += copy;
	do {
	to++ = from++;
	} while (--copy);
	if (s->next == MAXWIN) {
	if (s->outfun(s->outhow, s->out, s->next)) return 1;
	s->next = 0;
	s->first = 0;
	}
	} while (len != 0);
	}
	else {
	/* get literal and write it */
	symbol = lit ? decode(s, &litcode) : bits(s, 8);
	s->out[s->next++] = symbol;
	if (s->next == MAXWIN) {
	if (s->outfun(s->outhow, s->out, s->next)) return 1;
	s->next = 0;
	s->first = 0;
	}
	}
	} while (1);
	return 0;
	}

	/* See comments in blast.h */
	int blast(blast_in infun, void inhow, blast_out outfun, void outhow,
	unsigned left, unsigned char *in)
	{
	struct state s; /* input/output state */
	int err; /* return value */

	/* initialize input state */
	s.infun = infun;
	s.inhow = inhow;
	if (left != NULL && *left) {
	s.left = *left;
	s.in = *in;
	}
	else
	s.left = 0;
	s.bitbuf = 0;
	s.bitcnt = 0;

	/* initialize output state */
	s.outfun = outfun;
	s.outhow = outhow;
	s.next = 0;
	s.first = 1;

	/* return if bits() or decode() tries to read past available input */
	if (setjmp(s.env) != 0) /* if came back here via longjmp(), */
	err = 2; /* then skip decomp(), return error */
	else
	err = decomp(&s); /* decompress */

	/* return unused input */
	if (left != NULL)
	*left = s.left;
	if (in != NULL)
	*in = s.left ? s.in : NULL;

	/* write any leftover output and update the error code if needed */
	if (err != 1 && s.next && s.outfun(s.outhow, s.out, s.next) && err == 0)
	err = 1;
	return err;
	}

	#ifdef TEST
	/* Example of how to use blast() */
	#include <stdio.h>
	#include <stdlib.h>

	#define CHUNK 16384

	local unsigned inf(void how, unsigned char *buf)
	{
	static unsigned char hold[CHUNK];

	*buf = hold;
	return fread(hold, 1, CHUNK, (FILE *)how);
	}

	local int outf(void how, unsigned char buf, unsigned len)
	{
	return fwrite(buf, 1, len, (FILE *)how) != len;
	}

	/* Decompress a PKWare Compression Library stream from stdin to stdout */
	int main(void)
	{
	int ret;
	unsigned left;

	/* decompress to stdout */
	left = 0;
	ret = blast(inf, stdin, outf, stdout, &left, NULL);
	if (ret != 0)
	fprintf(stderr, "blast error: %d\n", ret);

	/* count any leftover bytes */
	while (getchar() != EOF)
	left++;
	if (left)
	fprintf(stderr, "blast warning: %u unused bytes of input\n", left);

	/* return blast() error code */
	return ret;
	}
	#endif