tableprinter: code cleanup

[libucw.git] / ucw / lizard.c

/*
 *      LiZaRd -- Fast compression method based on Lempel-Ziv 77
 *
 *      (c) 2004, Robert Spalek <robert@ucw.cz>
 *
 *      This software may be freely distributed and used according to the terms
 *      of the GNU Lesser General Public License.
 *
 *      The file format is based on LZO1X and
 *      the compression method is based on zlib.
 */

#include <ucw/lib.h>
#include <ucw/lizard.h>

#include <string.h>

typedef u16 hash_ptr_t;
struct hash_record {
  /* the position in the original text is implicit; it is computed by locate_string() */
  hash_ptr_t next;                      // 0=end
  hash_ptr_t prev;                      // high bit: 0=record in array, 1=head in hash-table (i.e. value of hashf)
};

#define HASH_SIZE       (1<<14)         // size of hash-table
#define HASH_RECORDS    (1<<15)         // maximum number of records in hash-table, 0 is unused ==> subtract 1
#define CHAIN_MAX_TESTS         8       // crop longer collision chains
#define CHAIN_GOOD_MATCH        32      // we already have a good match => end

static inline uint
hashf(const byte *string)
  /* 0..HASH_SIZE-1 */
{
    return string[0] ^ (string[1]<<3) ^ (string[2]<<6);
}

static inline byte *
locate_string(const byte *string, int record_id, int head)
  /* The strings are recorded into the hash-table regularly, hence there is no
   * need to store the pointer there.  */
{
  string += record_id - head;
  if (record_id >= head)
    string -= HASH_RECORDS-1;
  return (byte *)string;
}

static inline uint
find_match(uint record_id, struct hash_record *hash_rec, const byte *string, const byte *string_end, byte **best_ptr, uint head)
  /* hash_tab[hash] == record_id points to the head of the double-linked
   * link-list of strings with the same hash.  The records are statically
   * stored in circular array hash_rec (with the 1st entry unused), and the
   * pointers are just 16-bit indices.  The strings in every collision chain
   * are ordered by age.  */
{
  uint count = CHAIN_MAX_TESTS;
  uint best_len = 0;
  while (record_id && count-- > 0)
  {
    byte *record_string = locate_string(string, record_id, head);
    byte *cmp = record_string;
    if (cmp[0] == string[0] && cmp[2] == string[2])
    /* implies cmp[1] == string[1] */
    {
      if (cmp[3] == string[3])
      {
        cmp += 4;
        if (*cmp++ == string[4] && *cmp++ == string[5]
            && *cmp++ == string[6] && *cmp++ == string[7])
        {
          const byte *str = string + 8;
          while (str <= string_end && *cmp++ == *str++);
        }
      }
      else
        cmp += 4;
      uint len = cmp - record_string - 1;       /* cmp points 2 characters after the last match */
      if (len > best_len)
      {
        best_len = len;
        *best_ptr = record_string;
        if (best_len >= CHAIN_GOOD_MATCH)       /* optimization */
          break;
      }
    }
    record_id = hash_rec[record_id].next;
  }
  return best_len;
}

static uint
hash_string(hash_ptr_t *hash_tab, uint hash, struct hash_record *hash_rec, /*byte *string,*/ uint head, uint *to_delete)
  /* We reuse hash-records stored in a circular array.  First, delete the old
   * one and then add the new one in front of the link-list.  */
{
  struct hash_record *rec = hash_rec + head;
  if (*to_delete)                               /* unlink the original record */
  {
    uint prev_id = rec->prev & ((1<<15)-1);
    if (rec->prev & (1<<15))                    /* was a head */
      hash_tab[prev_id] = 0;
    else                                        /* thanks to the ordering, this was a tail */
      hash_rec[prev_id].next = 0;
  }
  rec->next = hash_tab[hash];
  rec->prev = (1<<15) | hash;
  hash_rec[rec->next].prev = head;
  hash_tab[hash] = head;                        /* add the new record before the link-list */

  if (++head >= HASH_RECORDS)                   /* circular buffer, reuse old records, 0 is unused */
  {
    head = 1;
    *to_delete = 1;
  }
  return head;
}

static inline byte *
dump_unary_value(byte *out, uint l)
{
  while (l > 255)
  {
    l -= 255;
    *out++ = 0;
  }
  *out++ = l;
  return out;
}

static byte *
flush_copy_command(uint bof, byte *out, const byte *start, uint len)
{
  if (bof && len <= 238)
    *out++ = len + 17;
  else if (len < 4)
  {
    /* cannot happen when !!bof */
    out[-2] |= len;                             /* invariant: lowest 2 bits 2 bytes back */
#ifdef  CPU_ALLOW_UNALIGNED
    * (u32*) out = * (u32*) start;
    return out + len;
#else
    while (len-- > 0)
      *out++ = *start++;
    return out;
#endif
  }
  else
  {
    /* leave 2 least significant bits of out[-2] set to 0 */
    if (len <= 18)
      *out++ = len - 3;
    else
    {
      *out++ = 0;
      out = dump_unary_value(out, len - 18);
    }
  }
  memcpy(out, start, len);
  return out + len;
}

int
lizard_compress(const byte *in, uint in_len, byte *out)
  /* Requires out being allocated for at least in_len * LIZARD_MAX_MULTIPLY +
   * LIZARD_MAX_ADD.  There must be at least LIZARD_NEEDS_CHARS characters
   * allocated after in.  Returns the actual compressed length. */
{
  hash_ptr_t hash_tab[HASH_SIZE];
  struct hash_record hash_rec[HASH_RECORDS];
  const byte *in_end = in + in_len;
  byte *out_start = out;
  const byte *copy_start = in;
  uint head = 1;                                        /* 0 in unused */
  uint to_delete = 0, bof = 1;
  bzero(hash_tab, sizeof(hash_tab));            /* init the hash-table */
  while (in < in_end)
  {
    uint hash = hashf(in);
    byte *best = NULL;
    uint len = find_match(hash_tab[hash], hash_rec, in, in_end, &best, head);
    if (len < 3)
#if 0                   // TODO: now, our routine does not detect matches of length 2
      if (len == 2 && (in - best->string - 1) < (1<<10))
      { /* pass-thru */ }
      else
#endif
      {
literal:
        head = hash_string(hash_tab, hash, hash_rec, head, &to_delete);
        in++;                                   /* add a literal */
        continue;
      }

    if (in + len > in_end)                      /* crop EOF */
    {
      len = in_end - in;
      if (len < 3)
        goto literal;
    }
    /* Record the match.  */
    uint copy_len = in - copy_start;
    uint is_in_copy_mode = bof || copy_len >= 4;
    uint shift = in - best - 1;
    /* Try to use a 2-byte sequence.  */
#if 0
    if (len == 2)
    {
      if (is_in_copy_mode || !copy_len)         /* cannot use with 0 copied characters, because this bit pattern is reserved for copy mode */
        goto literal;
      else
        goto dump_2sequence;
    } else
#endif
    /* now, len >= 3 */
    if (shift < (1<<11) && len <= 8)
    {
      shift |= (len-3 + 2)<<11;
dump_2sequence:
      if (copy_len)
        out = flush_copy_command(bof, out, copy_start, copy_len);
      *out++ = (shift>>6) & ~3;                 /* shift fits into 10 bits */
      *out++ = shift & 0xff;
    }
    else if (len == 3 && is_in_copy_mode)
    {
      if (shift < (1<<11) + (1<<10))            /* optimisation for length-3 matches after a copy command */
      {
        shift -= 1<<11;
        goto dump_2sequence;                    /* shift has 11 bits and contains also len */
      }
      else                                      /* avoid 3-sequence compressed to 3 sequence if it can simply be appended */
        goto literal;
    }
    /* We have to use a 3-byte sequence.  */
    else
    {
      if (copy_len)
        out = flush_copy_command(bof, out, copy_start, copy_len);
      if (shift < (1<<14))
      {
        if (len <= 33)
          *out++ = (1<<5) | (len-2);
        else
        {
          *out++ = 1<<5;
          out = dump_unary_value(out, len - 33);
        }
      }
      else /* shift < (1<<15)-1 becase of HASH_RECORDS */
      {
        shift++;                                /* because shift==0 is reserved for EOF */
        byte pos_bit = ((shift>>11) & (1<<3)) | (1<<4);
        if (len <= 9)
          *out++ = pos_bit | (len-2);
        else
        {
          *out++ = pos_bit;
          out = dump_unary_value(out, len - 9);
        }
      }
      *out++ = (shift>>6) & ~3;                 /* rest of shift fits into 14 bits */
      *out++ = shift & 0xff;
    }
    /* Update the hash-table.  */
    head = hash_string(hash_tab, hash, hash_rec, head, &to_delete);
    for (uint i=1; i<len; i++)
      head = hash_string(hash_tab, hashf(in+i), hash_rec, head, &to_delete);
    in += len;
    copy_start = in;
    bof = 0;
  }
  uint copy_len = in - copy_start;
  if (copy_len)
    out = flush_copy_command(bof, out, copy_start, copy_len);
  *out++ = 17;                                  /* add EOF */
  *out++ = 0;
  *out++ = 0;
  return out - out_start;
}

static inline byte *
read_unary_value(const byte *in, uint *val)
{
  uint l = 0;
  while (!*in++)
    l += 255;
  l += in[-1];
  *val = l;
  return (byte *)in;
}

int
lizard_decompress(const byte *in, byte *out)
  /* Requires out being allocated for the decompressed length must be known
   * beforehand.  It is desirable to lock the following memory page for
   * read-only access to prevent buffer overflow.  Returns the actual
   * decompressed length or a negative number when an error has occurred.  */
{
  byte *out_start = out;
  uint expect_copy_command = 1;
  uint len;
  if (*in > 17)                                 /* short copy command at BOF */
  {
    len = *in++ - 17;
    goto perform_copy_command;
  }
  while (1)
  {
    uint c = *in++;
    uint pos;
    if (c < 0x10)
      if (expect_copy_command == 1)
      {
        if (!c)
        {
          in = read_unary_value(in, &len);
          len += 18;
        }
        else
          len = c + 3;
        goto perform_copy_command;
      }
      else
      {
        pos = ((c&0xc)<<6) | *in++;
        if (expect_copy_command == 2)
        {
          pos += 1<<11;
          len = 3;
        }
        else
          len = 2;
        pos++;
      }
    else if (c < 0x20)
    {
      pos = (c&0x8)<<11;
      len = c&0x7;
      if (!len)
      {
        in = read_unary_value(in, &len);
        len += 9;
      }
      else
        len += 2;
      pos |= (*in++ & 0xfc)<<6;
      pos |= *in++;
      if (!pos)                                 /* EOF */
        break;
      /* do NOT pos++ */
    }
    else if (c < 0x40)
    {
      len = c&0x1f;
      if (!len)
      {
        in = read_unary_value(in, &len);
        len += 33;
      }
      else
        len += 2;
      pos = (*in++ & 0xfc)<<6;
      pos |= *in++;
      pos++;
    }
    else /* high bits encode the length */
    {
      len = ((c&0xe0)>>5) -2 +3;
      pos = (c&0x1c)<<6;
      pos |= *in++;
      pos++;
    }
    /* take from the sliding window */
    if (len <= pos)
    {
      memcpy(out, out-pos, len);
      out += len;
    }
    else
    {                                           /* overlapping */
      for (; len-- > 0; out++)
        *out = *(out-pos);
      /* It's tempting to use out[-pos] above, but unfortunately it's not the same */
    }
    /* extract the copy-bits */
    len = in[-2] & 0x3;
    if (len)
    {
      expect_copy_command = 0;
#ifdef  CPU_ALLOW_UNALIGNED
      * (u32*) out = * (u32*) in;
      out += len;
      in += len;
#else
      while (len-- > 0)
        *out++ = *in++;
#endif
    }
    else
      expect_copy_command = 1;
    continue;

perform_copy_command:
    expect_copy_command = 2;
    memcpy(out, in, len);
    out += len;
    in += len;
  }

  return out - out_start;
}

/*

Description of the LZO1X format :
=================================

The meaning of the commands depends on the current mode. It can be either
the compressed mode or the copy mode. In some cases, the compressed mode
also distinguishes whether we just left the copy mode or not.

Beginning of file:
------------------

Start in copy mode. If the first byte is 00010001, it means probably EOF (empty file),
so switch to the compressed mode.  If it is bigger, subtract 17 and copy this number of
the following characters to the output and switch to the compressed mode.
If it is smaller, interpret it as a regular copy mode command.

Compressed mode:
----------------

Read the first byte of the sequence and determine the type of bit encoding by
looking at the most significant bits.  The sequence is always at least 2 bytes
long.  Decode sequences of these types until the EOF or END marker is read.

  length L = length of the text taken from the sliding window

    If L=0, then count the number Z of the following zero bytes and add Z*255
    to the value of the following non-zero byte.  This allows setting L
    arbitrarily high.

  position p = relative position of the beginning of the text

    Exception: 00010001 00000000 00000000 means EOF

  copying C = length 1..3 of copied characters or END=0

    C following characters will be copied from the compressed text to the
    output.  The number CC is always stored in the 2 least significant bits of
    the second last byte of the sequence.

    If END is read, the algorithm switches to the copy mode.

pattern                                 length          position

0000ppCC                 pppppppp       2               10 bits         [default interpretation]
0000ppCC                 pppppppp       3               10 bits + 2048  [just after return from copy mode]
0001pLLL L*     ppppppCC pppppppp       3..9 + extend   15 bits         [pos 0 interpreted as EOF]
001LLLLL L*     ppppppCC pppppppp       3..33 + extend  14 bits
LLLpppCC                 pppppppp       3..8            11 bits         [LLL >= 010]

Copy mode:
----------

Read the first byte and, if the most significant bits are 0000, perform the
following command, otherwise switch to the compressed mode (and evaluate the
command there).

pattern                                 length          position

0000LLLL L*                             4..18 + extend  N/A

  Copy L characters from the compressed text to the output.  The overhead for
  incompressible strings is only roughly 1/256 + epsilon.

*/