📄 minilzo.c
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lzo_full_align_t a;
lzo_full_align_t u;
for (i = 0; i < (int) sizeof(x); i++)
x[i] = LZO_BYTE(i);
wrkmem = LZO_PTR_ALIGN_UP((lzo_byte *)_wrkmem,sizeof(lzo_full_align_t));
#if 0
dict = (lzo_bytepp) wrkmem;
#else
u.a_lzo_bytep = wrkmem; dict = u.a_lzo_bytepp;
#endif
d = (long) ((const lzo_bytep) dict - (const lzo_bytep) _wrkmem);
r &= __lzo_assert(d >= 0);
r &= __lzo_assert(d < (long) sizeof(lzo_full_align_t));
memset(&a,0,sizeof(a));
r &= __lzo_assert(a.a_lzo_voidp == NULL);
memset(&a,0xff,sizeof(a));
r &= __lzo_assert(a.a_ushort == USHRT_MAX);
r &= __lzo_assert(a.a_uint == UINT_MAX);
r &= __lzo_assert(a.a_ulong == ULONG_MAX);
r &= __lzo_assert(a.a_lzo_uint == LZO_UINT_MAX);
r &= __lzo_assert(a.a_lzo_uint32 == LZO_UINT32_MAX);
if (r == 1)
{
for (i = 0; i < 8; i++)
r &= __lzo_assert((const lzo_voidp) (&dict[i]) == (const lzo_voidp) (&wrkmem[i * sizeof(lzo_byte *)]));
}
memset(&a,0,sizeof(a));
r &= __lzo_assert(a.a_char_p == NULL);
r &= __lzo_assert(a.a_lzo_bytep == NULL);
r &= __lzo_assert(NULL == (void *)0);
if (r == 1)
{
for (i = 0; i < 10; i++)
dict[i] = wrkmem;
BZERO8_PTR(dict+1,sizeof(dict[0]),8);
r &= __lzo_assert(dict[0] == wrkmem);
for (i = 1; i < 9; i++)
r &= __lzo_assert(dict[i] == NULL);
r &= __lzo_assert(dict[9] == wrkmem);
}
if (r == 1)
{
unsigned k = 1;
const unsigned n = (unsigned) sizeof(lzo_uint32);
lzo_byte *p0;
lzo_byte *p1;
k += __lzo_align_gap(&x[k],n);
p0 = (lzo_bytep) &x[k];
#if defined(PTR_LINEAR)
r &= __lzo_assert((PTR_LINEAR(p0) & (n-1)) == 0);
#else
r &= __lzo_assert(n == 4);
r &= __lzo_assert(PTR_ALIGNED_4(p0));
#endif
r &= __lzo_assert(k >= 1);
p1 = (lzo_bytep) &x[1];
r &= __lzo_assert(PTR_GE(p0,p1));
r &= __lzo_assert(k < 1+n);
p1 = (lzo_bytep) &x[1+n];
r &= __lzo_assert(PTR_LT(p0,p1));
if (r == 1)
{
lzo_uint32 v0, v1;
#if 0
v0 = * (lzo_uint32 *) &x[k];
v1 = * (lzo_uint32 *) &x[k+n];
#else
u.a_uchar_p = &x[k];
v0 = *u.a_lzo_uint32_p;
u.a_uchar_p = &x[k+n];
v1 = *u.a_lzo_uint32_p;
#endif
r &= __lzo_assert(v0 > 0);
r &= __lzo_assert(v1 > 0);
}
}
return r;
}
LZO_PUBLIC(int)
_lzo_config_check(void)
{
lzo_bool r = 1;
int i;
union {
lzo_uint32 a;
unsigned short b;
lzo_uint32 aa[4];
unsigned char x[4*sizeof(lzo_full_align_t)];
} u;
COMPILE_TIME_ASSERT( (int) ((unsigned char) ((signed char) -1)) == 255);
COMPILE_TIME_ASSERT( (((unsigned char)128) << (int)(8*sizeof(int)-8)) < 0);
#if 0
r &= __lzo_assert((const void *)&u == (const void *)&u.a);
r &= __lzo_assert((const void *)&u == (const void *)&u.b);
r &= __lzo_assert((const void *)&u == (const void *)&u.x[0]);
r &= __lzo_assert((const void *)&u == (const void *)&u.aa[0]);
#endif
r &= basic_integral_check();
r &= basic_ptr_check();
if (r != 1)
return LZO_E_ERROR;
u.a = 0; u.b = 0;
for (i = 0; i < (int) sizeof(u.x); i++)
u.x[i] = LZO_BYTE(i);
#if defined(LZO_BYTE_ORDER)
if (r == 1)
{
# if (LZO_BYTE_ORDER == LZO_LITTLE_ENDIAN)
lzo_uint32 a = (lzo_uint32) (u.a & LZO_0xffffffffL);
unsigned short b = (unsigned short) (u.b & 0xffff);
r &= __lzo_assert(a == 0x03020100L);
r &= __lzo_assert(b == 0x0100);
# elif (LZO_BYTE_ORDER == LZO_BIG_ENDIAN)
lzo_uint32 a = u.a >> (8 * sizeof(u.a) - 32);
unsigned short b = u.b >> (8 * sizeof(u.b) - 16);
r &= __lzo_assert(a == 0x00010203L);
r &= __lzo_assert(b == 0x0001);
# else
# error "invalid LZO_BYTE_ORDER"
# endif
}
#endif
#if defined(LZO_UNALIGNED_OK_2)
COMPILE_TIME_ASSERT(sizeof(short) == 2);
if (r == 1)
{
unsigned short b[4];
for (i = 0; i < 4; i++)
b[i] = * (const unsigned short *) &u.x[i];
# if (LZO_BYTE_ORDER == LZO_LITTLE_ENDIAN)
r &= __lzo_assert(b[0] == 0x0100);
r &= __lzo_assert(b[1] == 0x0201);
r &= __lzo_assert(b[2] == 0x0302);
r &= __lzo_assert(b[3] == 0x0403);
# elif (LZO_BYTE_ORDER == LZO_BIG_ENDIAN)
r &= __lzo_assert(b[0] == 0x0001);
r &= __lzo_assert(b[1] == 0x0102);
r &= __lzo_assert(b[2] == 0x0203);
r &= __lzo_assert(b[3] == 0x0304);
# endif
}
#endif
#if defined(LZO_UNALIGNED_OK_4)
COMPILE_TIME_ASSERT(sizeof(lzo_uint32) == 4);
if (r == 1)
{
lzo_uint32 a[4];
for (i = 0; i < 4; i++)
a[i] = * (const lzo_uint32 *) &u.x[i];
# if (LZO_BYTE_ORDER == LZO_LITTLE_ENDIAN)
r &= __lzo_assert(a[0] == 0x03020100L);
r &= __lzo_assert(a[1] == 0x04030201L);
r &= __lzo_assert(a[2] == 0x05040302L);
r &= __lzo_assert(a[3] == 0x06050403L);
# elif (LZO_BYTE_ORDER == LZO_BIG_ENDIAN)
r &= __lzo_assert(a[0] == 0x00010203L);
r &= __lzo_assert(a[1] == 0x01020304L);
r &= __lzo_assert(a[2] == 0x02030405L);
r &= __lzo_assert(a[3] == 0x03040506L);
# endif
}
#endif
#if defined(LZO_ALIGNED_OK_4)
COMPILE_TIME_ASSERT(sizeof(lzo_uint32) == 4);
#endif
COMPILE_TIME_ASSERT(lzo_sizeof_dict_t == sizeof(lzo_dict_t));
#if defined(__LZO_IN_MINLZO)
if (r == 1)
{
lzo_uint32 adler;
adler = lzo_adler32(0, NULL, 0);
adler = lzo_adler32(adler, lzo_copyright(), 200);
r &= __lzo_assert(adler == 0xc76f1751L);
}
#endif
if (r == 1)
{
r &= __lzo_assert(!schedule_insns_bug());
}
if (r == 1)
{
static int x[3];
static unsigned xn = 3;
register unsigned j;
for (j = 0; j < xn; j++)
x[j] = (int)j - 3;
r &= __lzo_assert(!strength_reduce_bug(x));
}
if (r == 1)
{
r &= ptr_check();
}
return r == 1 ? LZO_E_OK : LZO_E_ERROR;
}
static lzo_bool schedule_insns_bug(void)
{
#if defined(__LZO_CHECKER)
return 0;
#else
const int clone[] = {1, 2, 0};
const int *q;
q = clone;
return (*q) ? 0 : 1;
#endif
}
static lzo_bool strength_reduce_bug(int *x)
{
return x[0] != -3 || x[1] != -2 || x[2] != -1;
}
#undef COMPILE_TIME_ASSERT
int __lzo_init_done = 0;
LZO_PUBLIC(int)
__lzo_init2(unsigned v, int s1, int s2, int s3, int s4, int s5,
int s6, int s7, int s8, int s9)
{
int r;
__lzo_init_done = 1;
if (v == 0)
return LZO_E_ERROR;
r = (s1 == -1 || s1 == (int) sizeof(short)) &&
(s2 == -1 || s2 == (int) sizeof(int)) &&
(s3 == -1 || s3 == (int) sizeof(long)) &&
(s4 == -1 || s4 == (int) sizeof(lzo_uint32)) &&
(s5 == -1 || s5 == (int) sizeof(lzo_uint)) &&
(s6 == -1 || s6 == (int) lzo_sizeof_dict_t) &&
(s7 == -1 || s7 == (int) sizeof(char *)) &&
(s8 == -1 || s8 == (int) sizeof(lzo_voidp)) &&
(s9 == -1 || s9 == (int) sizeof(lzo_compress_t));
if (!r)
return LZO_E_ERROR;
r = _lzo_config_check();
if (r != LZO_E_OK)
return r;
return r;
}
#if !defined(__LZO_IN_MINILZO)
LZO_EXTERN(int)
__lzo_init(unsigned v,int s1,int s2,int s3,int s4,int s5,int s6,int s7);
LZO_PUBLIC(int)
__lzo_init(unsigned v,int s1,int s2,int s3,int s4,int s5,int s6,int s7)
{
if (v == 0 || v > 0x1010)
return LZO_E_ERROR;
return __lzo_init2(v,s1,s2,s3,s4,s5,-1,-1,s6,s7);
}
#endif
#define do_compress _lzo1x_1_do_compress
#define LZO_NEED_DICT_H
#define D_BITS 14
#define D_INDEX1(d,p) d = DM((0x21*DX3(p,5,5,6)) >> 5)
#define D_INDEX2(d,p) d = (d & (D_MASK & 0x7ff)) ^ (D_HIGH | 0x1f)
#ifndef __LZO_CONFIG1X_H
#define __LZO_CONFIG1X_H
#if !defined(LZO1X) && !defined(LZO1Y) && !defined(LZO1Z)
# define LZO1X
#endif
#if !defined(__LZO_IN_MINILZO)
#include <lzo1x.h>
#endif
#define LZO_EOF_CODE
#undef LZO_DETERMINISTIC
#define M1_MAX_OFFSET 0x0400
#ifndef M2_MAX_OFFSET
#define M2_MAX_OFFSET 0x0800
#endif
#define M3_MAX_OFFSET 0x4000
#define M4_MAX_OFFSET 0xbfff
#define MX_MAX_OFFSET (M1_MAX_OFFSET + M2_MAX_OFFSET)
#define M1_MIN_LEN 2
#define M1_MAX_LEN 2
#define M2_MIN_LEN 3
#ifndef M2_MAX_LEN
#define M2_MAX_LEN 8
#endif
#define M3_MIN_LEN 3
#define M3_MAX_LEN 33
#define M4_MIN_LEN 3
#define M4_MAX_LEN 9
#define M1_MARKER 0
#define M2_MARKER 64
#define M3_MARKER 32
#define M4_MARKER 16
#ifndef MIN_LOOKAHEAD
#define MIN_LOOKAHEAD (M2_MAX_LEN + 1)
#endif
#if defined(LZO_NEED_DICT_H)
#ifndef LZO_HASH
#define LZO_HASH LZO_HASH_LZO_INCREMENTAL_B
#endif
#define DL_MIN_LEN M2_MIN_LEN
#ifndef __LZO_DICT_H
#define __LZO_DICT_H
#ifdef __cplusplus
extern "C" {
#endif
#if !defined(D_BITS) && defined(DBITS)
# define D_BITS DBITS
#endif
#if !defined(D_BITS)
# error "D_BITS is not defined"
#endif
#if (D_BITS < 16)
# define D_SIZE LZO_SIZE(D_BITS)
# define D_MASK LZO_MASK(D_BITS)
#else
# define D_SIZE LZO_USIZE(D_BITS)
# define D_MASK LZO_UMASK(D_BITS)
#endif
#define D_HIGH ((D_MASK >> 1) + 1)
#if !defined(DD_BITS)
# define DD_BITS 0
#endif
#define DD_SIZE LZO_SIZE(DD_BITS)
#define DD_MASK LZO_MASK(DD_BITS)
#if !defined(DL_BITS)
# define DL_BITS (D_BITS - DD_BITS)
#endif
#if (DL_BITS < 16)
# define DL_SIZE LZO_SIZE(DL_BITS)
# define DL_MASK LZO_MASK(DL_BITS)
#else
# define DL_SIZE LZO_USIZE(DL_BITS)
# define DL_MASK LZO_UMASK(DL_BITS)
#endif
#if (D_BITS != DL_BITS + DD_BITS)
# error "D_BITS does not match"
#endif
#if (D_BITS < 8 || D_BITS > 18)
# error "invalid D_BITS"
#endif
#if (DL_BITS < 8 || DL_BITS > 20)
# error "invalid DL_BITS"
#endif
#if (DD_BITS < 0 || DD_BITS > 6)
# error "invalid DD_BITS"
#endif
#if !defined(DL_MIN_LEN)
# define DL_MIN_LEN 3
#endif
#if !defined(DL_SHIFT)
# define DL_SHIFT ((DL_BITS + (DL_MIN_LEN - 1)) / DL_MIN_LEN)
#endif
#define LZO_HASH_GZIP 1
#define LZO_HASH_GZIP_INCREMENTAL 2
#define LZO_HASH_LZO_INCREMENTAL_A 3
#define LZO_HASH_LZO_INCREMENTAL_B 4
#if !defined(LZO_HASH)
# error "choose a hashing strategy"
#endif
#if (DL_MIN_LEN == 3)
# define _DV2_A(p,shift1,shift2) \
(((( (lzo_uint32)((p)[0]) << shift1) ^ (p)[1]) << shift2) ^ (p)[2])
# define _DV2_B(p,shift1,shift2) \
(((( (lzo_uint32)((p)[2]) << shift1) ^ (p)[1]) << shift2) ^ (p)[0])
# define _DV3_B(p,shift1,shift2,shift3) \
((_DV2_B((p)+1,shift1,shift2) << (shift3)) ^ (p)[0])
#elif (DL_MIN_LEN == 2)
# define _DV2_A(p,shift1,shift2) \
(( (lzo_uint32)(p[0]) << shift1) ^ p[1])
# define _DV2_B(p,shift1,shift2) \
(( (lzo_uint32)(p[1]) << shift1) ^ p[2])
#else
# error "invalid DL_MIN_LEN"
#endif
#define _DV_A(p,shift) _DV2_A(p,shift,shift)
#define _DV_B(p,shift) _DV2_B(p,shift,shift)
#define DA2(p,s1,s2) \
(((((lzo_uint32)((p)[2]) << (s2)) + (p)[1]) << (s1)) + (p)[0])
#define DS2(p,s1,s2) \
(((((lzo_uint32)((p)[2]) << (s2)) - (p)[1]) << (s1)) - (p)[0])
#define DX2(p,s1,s2) \
(((((lzo_uint32)((p)[2]) << (s2)) ^ (p)[1]) << (s1)) ^ (p)[0])
#define DA3(p,s1,s2,s3) ((DA2((p)+1,s2,s3) << (s1)) + (p)[0])
#define DS3(p,s1,s2,s3) ((DS2((p)+1,s2,s3) << (s1)) - (p)[0])
#define DX3(p,s1,s2,s3) ((DX2((p)+1,s2,s3) << (s1)) ^ (p)[0])
#define DMS(v,s) ((lzo_uint) (((v) & (D_MASK >> (s))) << (s)))
#define DM(v) DMS(v,0)
#if (LZO_HASH == LZO_HASH_GZIP)
# define _DINDEX(dv,p) (_DV_A((p),DL_SHIFT))
#elif (LZO_HASH == LZO_HASH_GZIP_INCREMENTAL)
# define __LZO_HASH_INCREMENTAL
# define DVAL_FIRST(dv,p) dv = _DV_A((p),DL_SHIFT)
# define DVAL_NEXT(dv,p) dv = (((dv) << DL_SHIFT) ^ p[2])
# define _DINDEX(dv,p) (dv)
# define DVAL_LOOKAHEAD DL_MIN_LEN
#elif (LZO_HASH == LZO_HASH_LZO_INCREMENTAL_A)
# define __LZO_HASH_INCREMENTAL
# define DVAL_FIRST(dv,p) dv = _DV_A((p),5)
# define DVAL_NEXT(dv,p) \
dv ^= (lzo_uint32)(p[-1]) << (2*5); dv = (((dv) << 5) ^ p[2])
# define _DINDEX(dv,p) ((0x9f5f * (dv)) >> 5)
# define DVAL_LOOKAHEAD DL_MIN_LEN
#elif (LZO_HASH == LZO_HASH_LZO_INCREMENTAL_B)
# define __LZO_HASH_INCREMENTAL
# define DVAL_FIRST(dv,p) dv = _DV_B((p),5)
# define DVAL_NEXT(dv,p) \
dv ^= p[-1]; dv = (((dv) >> 5) ^ ((lzo_uint32)(p[2]) << (2*5)))
# define _DINDEX(dv,p) ((0x9f5f * (dv)) >> 5)
# define DVAL_LOOKAHEAD DL_MIN_LEN
#else
# error "choose a hashing strategy"
#endif
#ifndef DINDEX
#define DINDEX(dv,p) ((lzo_uint)((_DINDEX(dv,p)) & DL_MASK) << DD_BITS)
#endif
#if !defined(DINDEX1) && defined(D_INDEX1)
#define DINDEX1 D_INDEX1
#endif
#if !defined(DINDEX2) && defined(D_INDEX2)
#define DINDEX2 D_INDEX2
#endif
#if !defined(__LZO_HASH_INCREMENTAL)
# define DVAL_FIRST(dv,p) ((void) 0)
# define DVAL_NEXT(dv,p) ((void) 0)
# define DVAL_LOOKAHEAD 0
#endif
#if !defined(DVAL_ASSERT)
#if defined(__LZO_HASH_INCREMENTAL) && !defined(NDEBUG)
static void DVAL_ASSERT(lzo_uint32 dv, const lzo_byte *p)
{
lzo_uint32 df;
DVAL_FIRST(df,(p));
assert(DINDEX(dv,p) == DINDEX(df,p));
}
#else
# define DVAL_ASSERT(dv,p) ((void) 0)
#endif
#endif
#if defined(LZO_DICT_USE_PTR)
# define DENTRY(p,in) (p)
# define GINDEX(m_pos,m_off,dict,dindex,in) m_pos = dict[dindex]
#else
# define DENTRY(p,in) ((lzo_uint) ((p)-(in)))
# define GINDEX(m_pos,m_off,dict,dindex,in) m_off = dict[dindex]
#endif
#if (DD_BITS == 0)
# define UPDATE_D(dict,drun,dv,p,in) dict[ DINDEX(dv,p) ] = DENTRY(p,in)
# define UPDATE_I(dict,drun,index,p,in) dict[index] = DENTRY(p,in)
# define UPDATE_P(ptr,drun,p,in) (ptr)[0] = DENTRY(p,in)
#else
# define UPDATE_D(dict,drun,dv,p,in) \
dict[ DINDEX(dv,p) + drun++ ] = DENTRY(p,in); drun &= DD_MASK
# define UPDATE_I(dict,drun,index,p,in) \
dict[ (index) + drun++ ] = DENTRY(p,in); drun &= DD_MASK
# define UPDATE_P(ptr,drun,p,in) \
(ptr) [ drun++ ] = DENTRY(p,in); drun &= DD_MASK
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