/* lzo1x_9x.c -- implementation of the LZO1X-999 compression algorithm
This file is part of the LZO real-time data compression library.
Copyright (C) 1996-2014 Markus Franz Xaver Johannes Oberhumer
All Rights Reserved.
The LZO library is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License as
published by the Free Software Foundation; either version 2 of
the License, or (at your option) any later version.
The LZO library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with the LZO library; see the file COPYING.
If not, write to the Free Software Foundation, Inc.,
51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
Markus F.X.J. Oberhumer
<markus@oberhumer.com>
http://www.oberhumer.com/opensource/lzo/
*/
#if !defined(LZO1X) && !defined(LZO1Y) && !defined(LZO1Z)
# define LZO1X 1
#endif
#if defined(LZO1X)
# include "config1x.h"
#elif defined(LZO1Y)
# include "config1y.h"
#elif defined(LZO1Z)
# include "config1z.h"
#else
# error
#endif
/***********************************************************************
//
************************************************************************/
#define SWD_N M4_MAX_OFFSET /* size of ring buffer */
#define SWD_THRESHOLD 1 /* lower limit for match length */
#define SWD_F 2048 /* upper limit for match length */
#define SWD_BEST_OFF (LZO_MAX3( M2_MAX_LEN, M3_MAX_LEN, M4_MAX_LEN ) + 1)
#if defined(LZO1X)
# define LZO_COMPRESS_T lzo1x_999_t
# define lzo_swd_t lzo1x_999_swd_t
#elif defined(LZO1Y)
# define LZO_COMPRESS_T lzo1y_999_t
# define lzo_swd_t lzo1y_999_swd_t
# define lzo1x_999_compress_internal lzo1y_999_compress_internal
# define lzo1x_999_compress_dict lzo1y_999_compress_dict
# define lzo1x_999_compress_level lzo1y_999_compress_level
# define lzo1x_999_compress lzo1y_999_compress
#elif defined(LZO1Z)
# define LZO_COMPRESS_T lzo1z_999_t
# define lzo_swd_t lzo1z_999_swd_t
# define lzo1x_999_compress_internal lzo1z_999_compress_internal
# define lzo1x_999_compress_dict lzo1z_999_compress_dict
# define lzo1x_999_compress_level lzo1z_999_compress_level
# define lzo1x_999_compress lzo1z_999_compress
#else
# error
#endif
#if 0
# define HEAD3(b,p) \
((((((lzo_xint)b[p]<<3)^b[p+1])<<3)^b[p+2]) & (SWD_HSIZE-1))
#endif
#if 0 && (LZO_OPT_UNALIGNED32) && (LZO_ABI_LITTLE_ENDIAN)
# define HEAD3(b,p) \
(((* (lzo_uint32_tp) &b[p]) ^ ((* (lzo_uint32_tp) &b[p])>>10)) & (SWD_HSIZE-1))
#endif
#include "lzo_mchw.ch"
/* this is a public functions, but there is no prototype in a header file */
LZO_EXTERN(int)
lzo1x_999_compress_internal ( const lzo_bytep in , lzo_uint in_len,
lzo_bytep out, lzo_uintp out_len,
lzo_voidp wrkmem,
const lzo_bytep dict, lzo_uint dict_len,
lzo_callback_p cb,
int try_lazy_parm,
lzo_uint good_length,
lzo_uint max_lazy,
lzo_uint nice_length,
lzo_uint max_chain,
lzo_uint32_t flags );
/***********************************************************************
//
************************************************************************/
static lzo_bytep
code_match ( LZO_COMPRESS_T *c, lzo_bytep op, lzo_uint m_len, lzo_uint m_off )
{
lzo_uint x_len = m_len;
lzo_uint x_off = m_off;
c->match_bytes += (unsigned long) m_len;
#if 0
/*
static lzo_uint last_m_len = 0, last_m_off = 0;
static lzo_uint prev_m_off[4];
static unsigned prev_m_off_ptr = 0;
unsigned i;
//if (m_len >= 3 && m_len <= M2_MAX_LEN && m_off <= M2_MAX_OFFSET)
if (m_len >= 3 && m_len <= M2_MAX_LEN)
{
//if (m_len == last_m_len && m_off == last_m_off)
//printf("last_m_len + last_m_off\n");
//else
if (m_off == last_m_off)
printf("last_m_off\n");
else
{
for (i = 0; i < 4; i++)
if (m_off == prev_m_off[i])
printf("prev_m_off %u: %5ld\n",i,(long)m_off);
}
}
last_m_len = m_len;
last_m_off = prev_m_off[prev_m_off_ptr] = m_off;
prev_m_off_ptr = (prev_m_off_ptr + 1) & 3;
*/
#endif
assert(op > c->out);
if (m_len == 2)
{
assert(m_off <= M1_MAX_OFFSET);
assert(c->r1_lit > 0); assert(c->r1_lit < 4);
m_off -= 1;
#if defined(LZO1Z)
*op++ = LZO_BYTE(M1_MARKER | (m_off >> 6));
*op++ = LZO_BYTE(m_off << 2);
#else
*op++ = LZO_BYTE(M1_MARKER | ((m_off & 3) << 2));
*op++ = LZO_BYTE(m_off >> 2);
#endif
c->m1a_m++;
}
#if defined(LZO1Z)
else if (m_len <= M2_MAX_LEN && (m_off <= M2_MAX_OFFSET || m_off == c->last_m_off))
#else
else if (m_len <= M2_MAX_LEN && m_off <= M2_MAX_OFFSET)
#endif
{
assert(m_len >= 3);
#if defined(LZO1X)
m_off -= 1;
*op++ = LZO_BYTE(((m_len - 1) << 5) | ((m_off & 7) << 2));
*op++ = LZO_BYTE(m_off >> 3);
assert(op[-2] >= M2_MARKER);
#elif defined(LZO1Y)
m_off -= 1;
*op++ = LZO_BYTE(((m_len + 1) << 4) | ((m_off & 3) << 2));
*op++ = LZO_BYTE(m_off >> 2);
assert(op[-2] >= M2_MARKER);
#elif defined(LZO1Z)
if (m_off == c->last_m_off)
*op++ = LZO_BYTE(((m_len - 1) << 5) | (0x700 >> 6));
else
{
m_off -= 1;
*op++ = LZO_BYTE(((m_len - 1) << 5) | (m_off >> 6));
*op++ = LZO_BYTE(m_off << 2);
}
#endif
c->m2_m++;
}
else if (m_len == M2_MIN_LEN && m_off <= MX_MAX_OFFSET && c->r1_lit >= 4)
{
assert(m_len == 3);
assert(m_off > M2_MAX_OFFSET);
m_off -= 1 + M2_MAX_OFFSET;
#if defined(LZO1Z)
*op++ = LZO_BYTE(M1_MARKER | (m_off >> 6));
*op++ = LZO_BYTE(m_off << 2);
#else
*op++ = LZO_BYTE(M1_MARKER | ((m_off & 3) << 2));
*op++ = LZO_BYTE(m_off >> 2);
#endif
c->m1b_m++;
}
else if (m_off <= M3_MAX_OFFSET)
{
assert(m_len >= 3);
m_off -= 1;
if (m_len <= M3_MAX_LEN)
*op++ = LZO_BYTE(M3_MARKER | (m_len - 2));
else
{
m_len -= M3_MAX_LEN;
*op++ = M3_MARKER | 0;
while (m_len > 255)
{
m_len -= 255;
*op++ = 0;
}
assert(m_len > 0);
*op++ = LZO_BYTE(m_len);
}
#if defined(LZO1Z)
*op++ = LZO_BYTE(m_off >> 6);
*op++ = LZO_BYTE(m_off << 2);
#else
*op++ = LZO_BYTE(m_off << 2);
*op++ = LZO_BYTE(m_off >> 6);
#endif
c->m3_m++;
}
else
{
lzo_uint k;
assert(m_len >= 3);
assert(m_off > 0x4000); assert(m_off <= 0xbfff);
m_off -= 0x4000;
k = (m_off & 0x4000) >> 11;
if (m_len <= M4_MAX_LEN)
*op++ = LZO_BYTE(M4_MARKER | k | (m_len - 2));
else
{
m_len -= M4_MAX_LEN;
*op++ = LZO_BYTE(M4_MARKER | k | 0);
while (m_len > 255)
{
m_len -= 255;
*op++ = 0;
}
assert(m_len > 0);
*op++ = LZO_BYTE(m_len);
}
#if defined(LZO1Z)
*op++ = LZO_BYTE(m_off >> 6);
*op++ = LZO_BYTE(m_off << 2);
#else
*op++ = LZO_BYTE(m_off << 2);
*op++ = LZO_BYTE(m_off >> 6);
#endif
c->m4_m++;
}
c->last_m_len = x_len;
c->last_m_off = x_off;
return op;
}
static lzo_bytep
STORE_RUN ( LZO_COMPRESS_T *c, lzo_bytep op, const lzo_bytep ii, lzo_uint t )
{
c->lit_bytes += (unsigned long) t;
if (op == c->out && t <= 238)
{
*op++ = LZO_BYTE(17 + t);
}
else if (t <= 3)
{
#if defined(LZO1Z)
op[-1] = LZO_BYTE(op[-1] | t);
#else
op[-2] = LZO_BYTE(op[-2] | t);
#endif
c->lit1_r++;
}
else if (t <= 18)
{
*op++ = LZO_BYTE(t - 3);
c->lit2_r++;
}
else
{
lzo_uint tt = t - 18;
*op++ = 0;
while (tt > 255)
{
tt -= 255;
*op++ = 0;
}
assert(tt > 0);
*op++ = LZO_BYTE(tt);
c->lit3_r++;
}
do *op++ = *ii++; while (--t > 0);
return op;
}
static lzo_bytep
code_run ( LZO_COMPRESS_T *c, lzo_bytep op, const lzo_bytep ii,
lzo_uint lit, lzo_uint m_len )
{
if (lit > 0)
{
assert(m_len >= 2);
op = STORE_RUN(c,op,ii,lit);
c->r1_m_len = m_len;
c->r1_lit = lit;
}
else
{
assert(m_len >= 3);
c->r1_m_len = 0;
c->r1_lit = 0;
}
return op;
}
/***********************************************************************
//
************************************************************************/
static lzo_uint
len_of_coded_match ( lzo_uint m_len, lzo_uint m_off, lzo_uint lit )
{
lzo_uint n = 4;
if (m_len < 2)
return 0;
if (m_len == 2)
return (m_off <= M1_MAX_OFFSET && lit > 0 && lit < 4) ? 2 : 0;
if (m_len <= M2_MAX_LEN && m_off <= M2_MAX_OFFSET)
return 2;
if (m_len == M2_MIN_LEN && m_off <= MX_MAX_OFFSET && lit >= 4)
return 2;
if (m_off <= M3_MAX_OFFSET)
{
if (m_len <= M3_MAX_LEN)
return 3;
m_len -= M3_MAX_LEN;
while (m_len > 255)
{
m_len -= 255;
n++;
}
return n;
}
if (m_off <= M4_MAX_OFFSET)
{
if (m_len <= M4_MAX_LEN)
return 3;
m_len -= M4_MAX_LEN;
while (m_len > 255)
{
m_len -= 255;
n++;
}
return n;
}
return 0;
}
static lzo_uint
min_gain(lzo_uint ahead, lzo_uint lit1, lzo_uint lit2, lzo_uint l1, lzo_uint l2, lzo_uint l3)
{
lzo_uint lazy_match_min_gain;
assert (ahead >= 1);
lazy_match_min_gain = ahead;
#if 0
if (l3)
lit2 -= ahead;
#endif
if (lit1 <= 3)
lazy_match_min_gain += (lit2 <= 3) ? 0 : 2;
else if (lit1 <= 18)
lazy_match_min_gain += (lit2 <= 18) ? 0 : 1;
lazy_match_min_gain += (l2 - l1) * 2;
if (l3)
lazy_match_min_gain -= (ahead - l3) * 2;
if ((lzo_int) lazy_match_min_gain < 0)
lazy_match_min_gain = 0;
#if 0
if (l1 == 2)
if (lazy_match_min_gain == 0)
lazy_match_min_gain = 1;
#endif
return lazy_match_min_gain;
}
/***********************************************************************
//
************************************************************************/
#if !defined(NDEBUG)
static
void assert_match( const lzo_swd_p swd, lzo_uint m_len, lzo_uint m_off )
{
const LZO_COMPRESS_T *c = swd->c;
lzo_uint d_off;
assert(m_len >= 2);
if (m_off <= (lzo_uint) (c->bp - c->in))
{
assert(c->bp - m_off + m_len < c->ip);
assert(lzo_memcmp(c->bp, c->bp - m_off, m_len) == 0);
}
else
{
assert(swd->dict != NULL);
d_off = m_off - (lzo_uint) (c->bp - c->in);
assert(d_off <= swd->dict_len);
if (m_len > d_off)
{
assert(lzo_memcmp(c->bp, swd->dict_end - d_off, d_off) == 0);
assert(c->in + m_len - d_off < c->ip);
assert(lzo_memcmp(c->bp + d_off, c->in, m_len - d_off) == 0);
}
else
{
assert(lzo_memcmp(c->bp, swd->dict_end - d_off, m_len) == 0);
}
}
}
#else
# define assert_match(a,b,c) ((void)0)
#endif
#if defined(SWD_BEST_OFF)
static void
better_match ( const lzo_swd_p swd, lzo_uint *m_len, lzo_uint *m_off )
{
#if defined(LZO1Z)
const LZO_COMPRESS_T *c = swd->c;
#endif
if (*m_len <= M2_MIN_LEN)
return;
#if defined(LZO1Z)
if (*m_off == c->last_m_off && *m_len <= M2_MAX_LEN)
return;
#if 1
if (*m_len >= M2_MIN_LEN + 1 && *m_len <= M2_MAX_LEN + 1 &&
c->last_m_off && swd->best_off[*m_len-1] == c->last_m_off)
{
*m_len = *m_len - 1;
*m_off = swd->best_off[*m_len];
return;
}
#endif
#endif
if (*m_off <= M2_MAX_OFFSET)
return;
#if 1
/* M3/M4 -> M2 */
if (*m_off > M2_MAX_OFFSET &&
*m_len >= M2_MIN_LEN + 1 && *m_len <= M2_MAX_LEN + 1 &&
swd->best_off[*m_len-1] && swd->best_off[*m_len-1] <= M2_MAX_OFFSET)
{
*m_len = *m_len - 1;
*m_off = swd->best_off[*m_len];
return;
}
#endif
#if 1
/* M4 -> M2 */
if (*m_off > M3_MAX_OFFSET &&
*m_len >= M4_MAX_LEN + 1 && *m_len <= M2_MAX_LEN + 2 &&
swd->best_off[*m_len-2] && swd->best_off[*m_len-2] <= M2_MAX_OFFSET)
{
*m_len = *m_len - 2;
*m_off = swd->best_off[*m_len];
return;
}
#endif
#if 1
/* M4 -> M3 */
if (*m_off > M3_MAX_OFFSET &&
*m_len >= M4_MAX_LEN + 1 && *m_len <= M3_MAX_LEN + 1 &&
swd->best_off[*m_len-1] && swd->best_off[*m_len-1] <= M3_MAX_OFFSET)
{
*m_len = *m_len - 1;
*m_off = swd->best_off[*m_len];
}
#endif
}
#endif
/***********************************************************************
//
************************************************************************/
LZO_PUBLIC(int)
lzo1x_999_compress_internal ( const lzo_bytep in , lzo_uint in_len,
lzo_bytep out, lzo_uintp out_len,
lzo_voidp wrkmem,
const lzo_bytep dict, lzo_uint dict_len,
lzo_callback_p cb,
int try_lazy_parm,
lzo_uint good_length,
lzo_uint max_lazy,
lzo_uint nice_length,
lzo_uint max_chain,
lzo_uint32_t flags )
{
lzo_bytep op;
const lzo_bytep ii;
lzo_uint lit;
lzo_uint m_len, m_off;
LZO_COMPRESS_T cc;
LZO_COMPRESS_T * const c = &cc;
lzo_swd_p const swd = (lzo_swd_p) wrkmem;
lzo_uint try_lazy;
int r;
/* sanity check */
#if defined(LZO1X)
LZO_COMPILE_TIME_ASSERT(LZO1X_999_MEM_COMPRESS >= SIZEOF_LZO_SWD_T)
#elif defined(LZO1Y)
LZO_COMPILE_TIME_ASSERT(LZO1Y_999_MEM_COMPRESS >= SIZEOF_LZO_SWD_T)
#elif defined(LZO1Z)
LZO_COMPILE_TIME_ASSERT(LZO1Z_999_MEM_COMPRESS >= SIZEOF_LZO_SWD_T)
#else
# error
#endif
/* setup parameter defaults */
/* number of lazy match tries */
try_lazy = (lzo_uint) try_lazy_parm;
if (try_lazy_parm < 0)
try_lazy = 1;
/* reduce lazy match search if we already have a match with this length */
if (good_length == 0)
good_length = 32;
/* do not try a lazy match if we already have a match with this length */
if (max_lazy == 0)
max_lazy = 32;
/* stop searching for longer matches than this one */
if (nice_length == 0)
nice_length = 0;
/* don't search more positions than this */
if (max_chain == 0)
max_chain = SWD_MAX_CHAIN;
c->init = 0;
c->ip = c->in = in;
c->in_end = in + in_len;
c->out = out;
c->cb = cb;
c->m1a_m = c->m1b_m = c->m2_m = c->m3_m = c->m4_m = 0;
c->lit1_r = c->lit2_r = c->lit3_r = 0;
op = out;
ii = c->ip; /* point to start of literal run */
lit = 0;
c->r1_lit = c->r1_m_len = 0;
r = init_match(c,swd,dict,dict_len,flags);
if (r != 0)
return r;
if (max_chain > 0)
swd->max_chain = max_chain;
if (nice_length > 0)
swd->nice_length = nice_length;
r = find_match(c,swd,0,0);
if (r != 0)
return r;
while (c->look > 0)
{
lzo_uint ahead;
lzo_uint max_ahead;
lzo_uint l1, l2, l3;
c->codesize = pd(op, out);
m_len = c->m_len;
m_off = c->m_off;
assert(c->bp == c->ip - c->look);
assert(c->bp >= in);
if (lit == 0)
ii = c->bp;
assert(ii + lit == c->bp);
assert(swd->b_char == *(c->bp));
if ( m_len < 2 ||
(m_len == 2 && (m_off > M1_MAX_OFFSET || lit == 0 || lit >= 4)) ||
#if 1
/* Do not accept this match for compressed-data compatibility
* with LZO v1.01 and before
* [ might be a problem for decompress() and optimize() ]
*/
(m_len == 2 && op == out) ||
#endif
(op == out && lit == 0))
{
/* a literal */
m_len = 0;
}
else if (m_len == M2_MIN_LEN)
{
/* compression ratio improves if we code a literal in some cases */
if (m_off > MX_MAX_OFFSET && lit >= 4)
m_len = 0;
}
if (m_len == 0)
{
/* a literal */
lit++;
swd->max_chain = max_chain;
r = find_match(c,swd,1,0);
assert(r == 0); LZO_UNUSED(r);
continue;
}
/* a match */
#if defined(SWD_BEST_OFF)
if (swd->use_best_off)
better_match(swd,&m_len,&m_off);
#endif
assert_match(swd,m_len,m_off);
/* shall we try a lazy match ? */
ahead = 0;
if (try_lazy == 0 || m_len >= max_lazy)
{
/* no */
l1 = 0;
max_ahead = 0;
}
else
{
/* yes, try a lazy match */
l1 = len_of_coded_match(m_len,m_off,lit);
assert(l1 > 0);
#if 1
max_ahead = LZO_MIN(try_lazy, l1 - 1);
#else
max_ahead = LZO_MIN3(try_lazy, l1, m_len - 1);
#endif
}
while (ahead < max_ahead && c->look > m_len)
{
lzo_uint lazy_match_min_gain;
if (m_len >= good_length)
swd->max_chain = max_chain >> 2;
else
swd->max_chain = max_chain;
r = find_match(c,swd,1,0);
ahead++;
assert(r == 0); LZO_UNUSED(r);
assert(c->look > 0);
assert(ii + lit + ahead == c->bp);
#if defined(LZO1Z)
if (m_off == c->last_m_off && c->m_off != c->last_m_off)
if (m_len >= M2_MIN_LEN && m_len <= M2_MAX_LEN)
c->m_len = 0;
#endif
if (c->m_len < m_len)
continue;
#if 1
if (c->m_len == m_len && c->m_off >= m_off)
continue;
#endif
#if defined(SWD_BEST_OFF)
if (swd->use_best_off)
better_match(swd,&c->m_len,&c->m_off);
#endif
l2 = len_of_coded_match(c->m_len,c->m_off,lit+ahead);
if (l2 == 0)
continue;
#if 0
if (c->m_len == m_len && l2 >= l1)
continue;
#endif
#if 1
/* compressed-data compatibility [see above] */
l3 = (op == out) ? 0 : len_of_coded_match(ahead,m_off,lit);
#else
l3 = len_of_coded_match(ahead,m_off,lit);
#endif
lazy_match_min_gain = min_gain(ahead,lit,lit+ahead,l1,l2,l3);
if (c->m_len >= m_len + lazy_match_min_gain)
{
c->lazy++;
assert_match(swd,c->m_len,c->m_off);
if (l3)
{
/* code previous run */
op = code_run(c,op,ii,lit,ahead);
lit = 0;
/* code shortened match */
op = code_match(c,op,ahead,m_off);
}
else
{
lit += ahead;
assert(ii + lit == c->bp);
}
goto lazy_match_done;
}
}
assert(ii + lit + ahead == c->bp);
/* 1 - code run */
op = code_run(c,op,ii,lit,m_len);
lit = 0;
/* 2 - code match */
op = code_match(c,op,m_len,m_off);
swd->max_chain = max_chain;
r = find_match(c,swd,m_len,1+ahead);
assert(r == 0); LZO_UNUSED(r);
lazy_match_done: ;
}
/* store final run */
if (lit > 0)
op = STORE_RUN(c,op,ii,lit);
#if defined(LZO_EOF_CODE)
*op++ = M4_MARKER | 1;
*op++ = 0;
*op++ = 0;
#endif
c->codesize = pd(op, out);
assert(c->textsize == in_len);
*out_len = pd(op, out);
if (c->cb && c->cb->nprogress)
(*c->cb->nprogress)(c->cb, c->textsize, c->codesize, 0);
#if 0
printf("%ld %ld -> %ld %ld: %ld %ld %ld %ld %ld %ld: %ld %ld %ld %ld\n",
(long) c->textsize, (long) in_len, (long) c->codesize,
c->match_bytes, c->m1a_m, c->m1b_m, c->m2_m, c->m3_m, c->m4_m,
c->lit_bytes, c->lit1_r, c->lit2_r, c->lit3_r, c->lazy);
#endif
assert(c->lit_bytes + c->match_bytes == in_len);
return LZO_E_OK;
}
/***********************************************************************
//
************************************************************************/
LZO_PUBLIC(int)
lzo1x_999_compress_level ( const lzo_bytep in , lzo_uint in_len,
lzo_bytep out, lzo_uintp out_len,
lzo_voidp wrkmem,
const lzo_bytep dict, lzo_uint dict_len,
lzo_callback_p cb,
int compression_level )
{
static const struct
{
int try_lazy_parm;
lzo_uint good_length;
lzo_uint max_lazy;
lzo_uint nice_length;
lzo_uint max_chain;
lzo_uint32_t flags;
} c[9] = {
/* faster compression */
{ 0, 0, 0, 8, 4, 0 },
{ 0, 0, 0, 16, 8, 0 },
{ 0, 0, 0, 32, 16, 0 },
{ 1, 4, 4, 16, 16, 0 },
{ 1, 8, 16, 32, 32, 0 },
{ 1, 8, 16, 128, 128, 0 },
{ 2, 8, 32, 128, 256, 0 },
{ 2, 32, 128, SWD_F, 2048, 1 },
{ 2, SWD_F, SWD_F, SWD_F, 4096, 1 }
/* max. compression */
};
if (compression_level < 1 || compression_level > 9)
return LZO_E_ERROR;
compression_level -= 1;
return lzo1x_999_compress_internal(in, in_len, out, out_len, wrkmem,
dict, dict_len, cb,
c[compression_level].try_lazy_parm,
c[compression_level].good_length,
c[compression_level].max_lazy,
#if 0
c[compression_level].nice_length,
#else
0,
#endif
c[compression_level].max_chain,
c[compression_level].flags);
}
/***********************************************************************
//
************************************************************************/
LZO_PUBLIC(int)
lzo1x_999_compress_dict ( const lzo_bytep in , lzo_uint in_len,
lzo_bytep out, lzo_uintp out_len,
lzo_voidp wrkmem,
const lzo_bytep dict, lzo_uint dict_len )
{
return lzo1x_999_compress_level(in, in_len, out, out_len, wrkmem,
dict, dict_len, 0, 8);
}
LZO_PUBLIC(int)
lzo1x_999_compress ( const lzo_bytep in , lzo_uint in_len,
lzo_bytep out, lzo_uintp out_len,
lzo_voidp wrkmem )
{
return lzo1x_999_compress_level(in, in_len, out, out_len, wrkmem,
NULL, 0, (lzo_callback_p) 0, 8);
}
/*
vi:ts=4:et
*/