#define DEBG(x)
#define DEBG1(x)
version c10p1, 10 January 1993 */
* Adapted for booting Linux by Hannu Savolainen 1993
* based on gzip-1.0.3
*
* Nicolas Pitre <nico@fluxnic.net>, 1999/04/14 :
* Little mods for all variable to reside either into rodata or bss segments
* by marking constant variables with 'const' and initializing all the others
* at run-time only. This allows for the kernel uncompressor to run
* directly from Flash or ROM memory on embedded systems.
*/
Inflate deflated (PKZIP's method 8 compressed) data. The compression
method searches for as much of the current string of bytes (up to a
length of 258) in the previous 32 K bytes. If it doesn't find any
matches (of at least length 3), it codes the next byte. Otherwise, it
codes the length of the matched string and its distance backwards from
the current position. There is a single Huffman code that codes both
single bytes (called "literals") and match lengths. A second Huffman
code codes the distance information, which follows a length code. Each
length or distance code actually represents a base value and a number
of "extra" (sometimes zero) bits to get to add to the base value. At
the end of each deflated block is a special end-of-block (EOB) literal/
length code. The decoding process is basically: get a literal/length
code; if EOB then done; if a literal, emit the decoded byte; if a
length then get the distance and emit the referred-to bytes from the
sliding window of previously emitted data.
There are (currently) three kinds of inflate blocks: stored, fixed, and
dynamic. The compressor deals with some chunk of data at a time, and
decides which method to use on a chunk-by-chunk basis. A chunk might
typically be 32 K or 64 K. If the chunk is incompressible, then the
"stored" method is used. In this case, the bytes are simply stored as
is, eight bits per byte, with none of the above coding. The bytes are
preceded by a count, since there is no longer an EOB code.
If the data is compressible, then either the fixed or dynamic methods
are used. In the dynamic method, the compressed data is preceded by
an encoding of the literal/length and distance Huffman codes that are
to be used to decode this block. The representation is itself Huffman
coded, and so is preceded by a description of that code. These code
descriptions take up a little space, and so for small blocks, there is
a predefined set of codes, called the fixed codes. The fixed method is
used if the block codes up smaller that way (usually for quite small
chunks), otherwise the dynamic method is used. In the latter case, the
codes are customized to the probabilities in the current block, and so
can code it much better than the pre-determined fixed codes.
The Huffman codes themselves are decoded using a multi-level table
lookup, in order to maximize the speed of decoding plus the speed of
building the decoding tables. See the comments below that precede the
lbits and dbits tuning parameters.
*/
Notes beyond the 1.93a appnote.txt:
1. Distance pointers never point before the beginning of the output
stream.
2. Distance pointers can point back across blocks, up to 32k away.
3. There is an implied maximum of 7 bits for the bit length table and
15 bits for the actual data.
4. If only one code exists, then it is encoded using one bit. (Zero
would be more efficient, but perhaps a little confusing.) If two
codes exist, they are coded using one bit each (0 and 1).
5. There is no way of sending zero distance codes--a dummy must be
sent if there are none. (History: a pre 2.0 version of PKZIP would
store blocks with no distance codes, but this was discovered to be
too harsh a criterion.) Valid only for 1.93a. 2.04c does allow
zero distance codes, which is sent as one code of zero bits in
length.
6. There are up to 286 literal/length codes. Code 256 represents the
end-of-block. Note however that the static length tree defines
288 codes just to fill out the Huffman codes. Codes 286 and 287
cannot be used though, since there is no length base or extra bits
defined for them. Similarly, there are up to 30 distance codes.
However, static trees define 32 codes (all 5 bits) to fill out the
Huffman codes, but the last two had better not show up in the data.
7. Unzip can check dynamic Huffman blocks for complete code sets.
The exception is that a single code would not be complete (see #4).
8. The five bits following the block type is really the number of
literal codes sent minus 257.
9. Length codes 8,16,16 are interpreted as 13 length codes of 8 bits
(1+6+6). Therefore, to output three times the length, you output
three codes (1+1+1), whereas to output four times the same length,
you only need two codes (1+3). Hmm.
10. In the tree reconstruction algorithm, Code = Code + Increment
only if BitLength(i) is not zero. (Pretty obvious.)
11. Correction: 4 Bits: # of Bit Length codes - 4 (4 - 19)
12. Note: length code 284 can represent 227-258, but length code 285
really is 258. The last length deserves its own, short code
since it gets used a lot in very redundant files. The length
258 is special since 258 - 3 (the min match length) is 255.
13. The literal/length and distance code bit lengths are read as a
single stream of lengths. It is possible (and advantageous) for
a repeat code (16, 17, or 18) to go across the boundary between
the two sets of lengths.
*/
#include <linux/compiler.h>
#ifdef NO_INFLATE_MALLOC
#include <linux/slab.h>
#endif
#ifdef RCSID
static char rcsid[] = "#Id: inflate.c,v 0.14 1993/06/10 13:27:04 jloup Exp #";
#endif
#ifndef STATIC
#if defined(STDC_HEADERS) || defined(HAVE_STDLIB_H)
# include <sys/types.h>
# include <stdlib.h>
#endif
#include "gzip.h"
#define STATIC
#endif
#ifndef INIT
#define INIT
#endif
#define slide window
that have 16-bit pointers (e.g. PC's in the small or medium model).
Valid extra bits are 0..13. e == 15 is EOB (end of block), e == 16
means that v is a literal, 16 < e < 32 means that v is a pointer to
the next table, which codes e - 16 bits, and lastly e == 99 indicates
an unused code. If a code with e == 99 is looked up, this implies an
error in the data. */
struct huft {
uch e;
uch b;
union {
ush n;
struct huft *t;
} v;
};
STATIC int INIT huft_build OF((unsigned *, unsigned, unsigned,
const ush *, const ush *, struct huft **, int *));
STATIC int INIT huft_free OF((struct huft *));
STATIC int INIT inflate_codes OF((struct huft *, struct huft *, int, int));
STATIC int INIT inflate_stored OF((void));
STATIC int INIT inflate_fixed OF((void));
STATIC int INIT inflate_dynamic OF((void));
STATIC int INIT inflate_block OF((int *));
STATIC int INIT inflate OF((void));
stream to find repeated byte strings. This is implemented here as a
circular buffer. The index is updated simply by incrementing and then
ANDing with 0x7fff (32K-1). */
to be usable as if it were declared "uch slide[32768];" or as just
"uch *slide;" and then malloc'ed in the latter case. The definition
must be in unzip.h, included above. */
#define wp outcnt
#define flush_output(w) (wp=(w),flush_window())
static const unsigned border[] = {
16, 17, 18, 0, 8, 7, 9, 6, 10, 5, 11, 4, 12, 3, 13, 2, 14, 1, 15};
static const ush cplens[] = {
3, 4, 5, 6, 7, 8, 9, 10, 11, 13, 15, 17, 19, 23, 27, 31,
35, 43, 51, 59, 67, 83, 99, 115, 131, 163, 195, 227, 258, 0, 0};
static const ush cplext[] = {
0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2,
3, 3, 3, 3, 4, 4, 4, 4, 5, 5, 5, 5, 0, 99, 99};
static const ush cpdist[] = {
1, 2, 3, 4, 5, 7, 9, 13, 17, 25, 33, 49, 65, 97, 129, 193,
257, 385, 513, 769, 1025, 1537, 2049, 3073, 4097, 6145,
8193, 12289, 16385, 24577};
static const ush cpdext[] = {
0, 0, 0, 0, 1, 1, 2, 2, 3, 3, 4, 4, 5, 5, 6, 6,
7, 7, 8, 8, 9, 9, 10, 10, 11, 11,
12, 12, 13, 13};
The usage is:
NEEDBITS(j)
x = b & mask_bits[j];
DUMPBITS(j)
where NEEDBITS makes sure that b has at least j bits in it, and
DUMPBITS removes the bits from b. The macros use the variable k
for the number of bits in b. Normally, b and k are register
variables for speed, and are initialized at the beginning of a
routine that uses these macros from a global bit buffer and count.
If we assume that EOB will be the longest code, then we will never
ask for bits with NEEDBITS that are beyond the end of the stream.
So, NEEDBITS should not read any more bytes than are needed to
meet the request. Then no bytes need to be "returned" to the buffer
at the end of the last block.
However, this assumption is not true for fixed blocks--the EOB code
is 7 bits, but the other literal/length codes can be 8 or 9 bits.
(The EOB code is shorter than other codes because fixed blocks are
generally short. So, while a block always has an EOB, many other
literal/length codes have a significantly lower probability of
showing up at all.) However, by making the first table have a
lookup of seven bits, the EOB code will be found in that first
lookup, and so will not require that too many bits be pulled from
the stream.
*/
STATIC ulg bb;
STATIC unsigned bk;
STATIC const ush mask_bits[] = {
0x0000,
0x0001, 0x0003, 0x0007, 0x000f, 0x001f, 0x003f, 0x007f, 0x00ff,
0x01ff, 0x03ff, 0x07ff, 0x0fff, 0x1fff, 0x3fff, 0x7fff, 0xffff
};
#define NEXTBYTE() ({ int v = get_byte(); if (v < 0) goto underrun; (uch)v; })
#define NEEDBITS(n) {while(k<(n)){b|=((ulg)NEXTBYTE())<<k;k+=8;}}
#define DUMPBITS(n) {b>>=(n);k-=(n);}
#ifndef NO_INFLATE_MALLOC
* malloc by Hannu Savolainen 1993 and Matthias Urlichs 1994
*/
static unsigned long malloc_ptr;
static int malloc_count;
static void *malloc(int size)
{
void *p;
if (size < 0)
error("Malloc error");
if (!malloc_ptr)
malloc_ptr = free_mem_ptr;
malloc_ptr = (malloc_ptr + 3) & ~3;
p = (void *)malloc_ptr;
malloc_ptr += size;
if (free_mem_end_ptr && malloc_ptr >= free_mem_end_ptr)
error("Out of memory");
malloc_count++;
return p;
}
static void free(void *where)
{
malloc_count--;
if (!malloc_count)
malloc_ptr = free_mem_ptr;
}
#else
#define malloc(a) kmalloc(a, GFP_KERNEL)
#define free(a) kfree(a)
#endif
Huffman code decoding is performed using a multi-level table lookup.
The fastest way to decode is to simply build a lookup table whose
size is determined by the longest code. However, the time it takes
to build this table can also be a factor if the data being decoded
is not very long. The most common codes are necessarily the
shortest codes, so those codes dominate the decoding time, and hence
the speed. The idea is you can have a shorter table that decodes the
shorter, more probable codes, and then point to subsidiary tables for
the longer codes. The time it costs to decode the longer codes is
then traded against the time it takes to make longer tables.
This results of this trade are in the variables lbits and dbits
below. lbits is the number of bits the first level table for literal/
length codes can decode in one step, and dbits is the same thing for
the distance codes. Subsequent tables are also less than or equal to
those sizes. These values may be adjusted either when all of the
codes are shorter than that, in which case the longest code length in
bits is used, or when the shortest code is *longer* than the requested
table size, in which case the length of the shortest code in bits is
used.
There are two different values for the two tables, since they code a
different number of possibilities each. The literal/length table
codes 286 possible values, or in a flat code, a little over eight
bits. The distance table codes 30 possible values, or a little less
than five bits, flat. The optimum values for speed end up being
about one bit more than those, so lbits is 8+1 and dbits is 5+1.
The optimum values may differ though from machine to machine, and
possibly even between compilers. Your mileage may vary.
*/
STATIC const int lbits = 9;
STATIC const int dbits = 6;
#define BMAX 16
#define N_MAX 288
STATIC unsigned hufts;
STATIC int INIT huft_build(
unsigned *b,
unsigned n,
unsigned s,
const ush *d,
const ush *e,
struct huft **t,
int *m
)
tables to decode that set of codes. Return zero on success, one if
the given code set is incomplete (the tables are still built in this
case), two if the input is invalid (all zero length codes or an
oversubscribed set of lengths), and three if not enough memory. */
{
unsigned a;
unsigned f;
int g;
int h;
register unsigned i;
register unsigned j;
register int k;
int l;
register unsigned *p;
register struct huft *q;
struct huft r;
register int w;
unsigned *xp;
int y;
unsigned z;
struct {
unsigned c[BMAX+1];
struct huft *u[BMAX];
unsigned v[N_MAX];
unsigned x[BMAX+1];
} *stk;
unsigned *c, *v, *x;
struct huft **u;
int ret;
DEBG("huft1 ");
stk = malloc(sizeof(*stk));
if (stk == NULL)
return 3;
c = stk->c;
v = stk->v;
x = stk->x;
u = stk->u;
memzero(stk->c, sizeof(stk->c));
p = b; i = n;
do {
Tracecv(*p, (stderr, (n-i >= ' ' && n-i <= '~' ? "%c %d\n" : "0x%x %d\n"),
n-i, *p));
c[*p]++;
p++;
} while (--i);
if (c[0] == n)
{
*t = (struct huft *)NULL;
*m = 0;
ret = 2;
goto out;
}
DEBG("huft2 ");
l = *m;
for (j = 1; j <= BMAX; j++)
if (c[j])
break;
k = j;
if ((unsigned)l < j)
l = j;
for (i = BMAX; i; i--)
if (c[i])
break;
g = i;
if ((unsigned)l > i)
l = i;
*m = l;
DEBG("huft3 ");
for (y = 1 << j; j < i; j++, y <<= 1)
if ((y -= c[j]) < 0) {
ret = 2;
goto out;
}
if ((y -= c[i]) < 0) {
ret = 2;
goto out;
}
c[i] += y;
DEBG("huft4 ");
x[1] = j = 0;
p = c + 1; xp = x + 2;
while (--i) {
*xp++ = (j += *p++);
}
DEBG("huft5 ");
p = b; i = 0;
do {
if ((j = *p++) != 0)
v[x[j]++] = i;
} while (++i < n);
n = x[g];
DEBG("h6 ");
x[0] = i = 0;
p = v;
h = -1;
w = -l;
u[0] = (struct huft *)NULL;
q = (struct huft *)NULL;
z = 0;
DEBG("h6a ");
for (; k <= g; k++)
{
DEBG("h6b ");
a = c[k];
while (a--)
{
DEBG("h6b1 ");
while (k > w + l)
{
DEBG1("1 ");
h++;
w += l;
z = (z = g - w) > (unsigned)l ? l : z;
if ((f = 1 << (j = k - w)) > a + 1)
{
DEBG1("2 ");
f -= a + 1;
xp = c + k;
if (j < z)
while (++j < z)
{
if ((f <<= 1) <= *++xp)
break;
f -= *xp;
}
}
DEBG1("3 ");
z = 1 << j;
if ((q = (struct huft *)malloc((z + 1)*sizeof(struct huft))) ==
(struct huft *)NULL)
{
if (h)
huft_free(u[0]);
ret = 3;
goto out;
}
DEBG1("4 ");
hufts += z + 1;
*t = q + 1;
*(t = &(q->v.t)) = (struct huft *)NULL;
u[h] = ++q;
DEBG1("5 ");
if (h)
{
x[h] = i;
r.b = (uch)l;
r.e = (uch)(16 + j);
r.v.t = q;
j = i >> (w - l);
u[h-1][j] = r;
}
DEBG1("6 ");
}
DEBG("h6c ");
r.b = (uch)(k - w);
if (p >= v + n)
r.e = 99;
else if (*p < s)
{
r.e = (uch)(*p < 256 ? 16 : 15);
r.v.n = (ush)(*p);
p++;
}
else
{
r.e = (uch)e[*p - s];
r.v.n = d[*p++ - s];
}
DEBG("h6d ");
f = 1 << (k - w);
for (j = i >> w; j < z; j += f)
q[j] = r;
for (j = 1 << (k - 1); i & j; j >>= 1)
i ^= j;
i ^= j;
while ((i & ((1 << w) - 1)) != x[h])
{
h--;
w -= l;
}
DEBG("h6e ");
}
DEBG("h6f ");
}
DEBG("huft7 ");
ret = y != 0 && g != 1;
out:
free(stk);
return ret;
}
STATIC int INIT huft_free(
struct huft *t
)
list of the tables it made, with the links in a dummy first entry of
each table. */
{
register struct huft *p, *q;
p = t;
while (p != (struct huft *)NULL)
{
q = (--p)->v.t;
free((char*)p);
p = q;
}
return 0;
}
STATIC int INIT inflate_codes(
struct huft *tl,
struct huft *td,
int bl,
int bd
)
Return an error code or zero if it all goes ok. */
{
register unsigned e;
unsigned n, d;
unsigned w;
struct huft *t;
unsigned ml, md;
register ulg b;
register unsigned k;
b = bb;
k = bk;
w = wp;
ml = mask_bits[bl];
md = mask_bits[bd];
for (;;)
{
NEEDBITS((unsigned)bl)
if ((e = (t = tl + ((unsigned)b & ml))->e) > 16)
do {
if (e == 99)
return 1;
DUMPBITS(t->b)
e -= 16;
NEEDBITS(e)
} while ((e = (t = t->v.t + ((unsigned)b & mask_bits[e]))->e) > 16);
DUMPBITS(t->b)
if (e == 16)
{
slide[w++] = (uch)t->v.n;
Tracevv((stderr, "%c", slide[w-1]));
if (w == WSIZE)
{
flush_output(w);
w = 0;
}
}
else
{
if (e == 15)
break;
NEEDBITS(e)
n = t->v.n + ((unsigned)b & mask_bits[e]);
DUMPBITS(e);
NEEDBITS((unsigned)bd)
if ((e = (t = td + ((unsigned)b & md))->e) > 16)
do {
if (e == 99)
return 1;
DUMPBITS(t->b)
e -= 16;
NEEDBITS(e)
} while ((e = (t = t->v.t + ((unsigned)b & mask_bits[e]))->e) > 16);
DUMPBITS(t->b)
NEEDBITS(e)
d = w - t->v.n - ((unsigned)b & mask_bits[e]);
DUMPBITS(e)
Tracevv((stderr,"\\[%d,%d]", w-d, n));
do {
n -= (e = (e = WSIZE - ((d &= WSIZE-1) > w ? d : w)) > n ? n : e);
#if !defined(NOMEMCPY) && !defined(DEBUG)
if (w - d >= e)
{
memcpy(slide + w, slide + d, e);
w += e;
d += e;
}
else
#endif
do {
slide[w++] = slide[d++];
Tracevv((stderr, "%c", slide[w-1]));
} while (--e);
if (w == WSIZE)
{
flush_output(w);
w = 0;
}
} while (n);
}
}
wp = w;
bb = b;
bk = k;
return 0;
underrun:
return 4;
}
STATIC int INIT inflate_stored(void)
{
unsigned n;
unsigned w;
register ulg b;
register unsigned k;
DEBG("<stor");
b = bb;
k = bk;
w = wp;
n = k & 7;
DUMPBITS(n);
NEEDBITS(16)
n = ((unsigned)b & 0xffff);
DUMPBITS(16)
NEEDBITS(16)
if (n != (unsigned)((~b) & 0xffff))
return 1;
DUMPBITS(16)
while (n--)
{
NEEDBITS(8)
slide[w++] = (uch)b;
if (w == WSIZE)
{
flush_output(w);
w = 0;
}
DUMPBITS(8)
}
wp = w;
bb = b;
bk = k;
DEBG(">");
return 0;
underrun:
return 4;
}
* We use `noinline' here to prevent gcc-3.5 from using too much stack space
*/
STATIC int noinline INIT inflate_fixed(void)
either replace this with a custom decoder, or at least precompute the
Huffman tables. */
{
int i;
struct huft *tl;
struct huft *td;
int bl;
int bd;
unsigned *l;
DEBG("<fix");
l = malloc(sizeof(*l) * 288);
if (l == NULL)
return 3;
for (i = 0; i < 144; i++)
l[i] = 8;
for (; i < 256; i++)
l[i] = 9;
for (; i < 280; i++)
l[i] = 7;
for (; i < 288; i++)
l[i] = 8;
bl = 7;
if ((i = huft_build(l, 288, 257, cplens, cplext, &tl, &bl)) != 0) {
free(l);
return i;
}
for (i = 0; i < 30; i++)
l[i] = 5;
bd = 5;
if ((i = huft_build(l, 30, 0, cpdist, cpdext, &td, &bd)) > 1)
{
huft_free(tl);
free(l);
DEBG(">");
return i;
}
if (inflate_codes(tl, td, bl, bd)) {
free(l);
return 1;
}
free(l);
huft_free(tl);
huft_free(td);
return 0;
}
* We use `noinline' here to prevent gcc-3.5 from using too much stack space
*/
STATIC int noinline INIT inflate_dynamic(void)
{
int i;
unsigned j;
unsigned l;
unsigned m;
unsigned n;
struct huft *tl;
struct huft *td;
int bl;
int bd;
unsigned nb;
unsigned nl;
unsigned nd;
unsigned *ll;
register ulg b;
register unsigned k;
int ret;
DEBG("<dyn");
#ifdef PKZIP_BUG_WORKAROUND
ll = malloc(sizeof(*ll) * (288+32));
#else
ll = malloc(sizeof(*ll) * (286+30));
#endif
if (ll == NULL)
return 1;
b = bb;
k = bk;
NEEDBITS(5)
nl = 257 + ((unsigned)b & 0x1f);
DUMPBITS(5)
NEEDBITS(5)
nd = 1 + ((unsigned)b & 0x1f);
DUMPBITS(5)
NEEDBITS(4)
nb = 4 + ((unsigned)b & 0xf);
DUMPBITS(4)
#ifdef PKZIP_BUG_WORKAROUND
if (nl > 288 || nd > 32)
#else
if (nl > 286 || nd > 30)
#endif
{
ret = 1;
goto out;
}
DEBG("dyn1 ");
for (j = 0; j < nb; j++)
{
NEEDBITS(3)
ll[border[j]] = (unsigned)b & 7;
DUMPBITS(3)
}
for (; j < 19; j++)
ll[border[j]] = 0;
DEBG("dyn2 ");
bl = 7;
if ((i = huft_build(ll, 19, 19, NULL, NULL, &tl, &bl)) != 0)
{
if (i == 1)
huft_free(tl);
ret = i;
goto out;
}
DEBG("dyn3 ");
n = nl + nd;
m = mask_bits[bl];
i = l = 0;
while ((unsigned)i < n)
{
NEEDBITS((unsigned)bl)
j = (td = tl + ((unsigned)b & m))->b;
DUMPBITS(j)
j = td->v.n;
if (j < 16)
ll[i++] = l = j;
else if (j == 16)
{
NEEDBITS(2)
j = 3 + ((unsigned)b & 3);
DUMPBITS(2)
if ((unsigned)i + j > n) {
ret = 1;
goto out;
}
while (j--)
ll[i++] = l;
}
else if (j == 17)
{
NEEDBITS(3)
j = 3 + ((unsigned)b & 7);
DUMPBITS(3)
if ((unsigned)i + j > n) {
ret = 1;
goto out;
}
while (j--)
ll[i++] = 0;
l = 0;
}
else
{
NEEDBITS(7)
j = 11 + ((unsigned)b & 0x7f);
DUMPBITS(7)
if ((unsigned)i + j > n) {
ret = 1;
goto out;
}
while (j--)
ll[i++] = 0;
l = 0;
}
}
DEBG("dyn4 ");
huft_free(tl);
DEBG("dyn5 ");
bb = b;
bk = k;
DEBG("dyn5a ");
bl = lbits;
if ((i = huft_build(ll, nl, 257, cplens, cplext, &tl, &bl)) != 0)
{
DEBG("dyn5b ");
if (i == 1) {
error("incomplete literal tree");
huft_free(tl);
}
ret = i;
goto out;
}
DEBG("dyn5c ");
bd = dbits;
if ((i = huft_build(ll + nl, nd, 0, cpdist, cpdext, &td, &bd)) != 0)
{
DEBG("dyn5d ");
if (i == 1) {
error("incomplete distance tree");
#ifdef PKZIP_BUG_WORKAROUND
i = 0;
}
#else
huft_free(td);
}
huft_free(tl);
ret = i;
goto out;
#endif
}
DEBG("dyn6 ");
if (inflate_codes(tl, td, bl, bd)) {
ret = 1;
goto out;
}
DEBG("dyn7 ");
huft_free(tl);
huft_free(td);
DEBG(">");
ret = 0;
out:
free(ll);
return ret;
underrun:
ret = 4;
goto out;
}
STATIC int INIT inflate_block(
int *e
)
{
unsigned t;
register ulg b;
register unsigned k;
DEBG("<blk");
b = bb;
k = bk;
NEEDBITS(1)
*e = (int)b & 1;
DUMPBITS(1)
NEEDBITS(2)
t = (unsigned)b & 3;
DUMPBITS(2)
bb = b;
bk = k;
if (t == 2)
return inflate_dynamic();
if (t == 0)
return inflate_stored();
if (t == 1)
return inflate_fixed();
DEBG(">");
return 2;
underrun:
return 4;
}
STATIC int INIT inflate(void)
{
int e;
int r;
unsigned h;
wp = 0;
bk = 0;
bb = 0;
h = 0;
do {
hufts = 0;
#ifdef ARCH_HAS_DECOMP_WDOG
arch_decomp_wdog();
#endif
r = inflate_block(&e);
if (r)
return r;
if (hufts > h)
h = hufts;
} while (!e);
* can discard unused bits in the last meaningful byte.
*/
while (bk >= 8) {
bk -= 8;
inptr--;
}
flush_output(wp);
#ifdef DEBUG
fprintf(stderr, "<%u> ", h);
#endif
return 0;
}
*
* The following are support routines for inflate.c
*
**********************************************************************/
static ulg crc_32_tab[256];
static ulg crc;
#define CRC_VALUE (crc ^ 0xffffffffUL)
* Code to compute the CRC-32 table. Borrowed from
* gzip-1.0.3/makecrc.c.
*/
static void INIT
makecrc(void)
{
unsigned long c;
unsigned long e;
int i;
int k;
static const int p[] = {0,1,2,4,5,7,8,10,11,12,16,22,23,26};
e = 0;
for (i = 0; i < sizeof(p)/sizeof(int); i++)
e |= 1L << (31 - p[i]);
crc_32_tab[0] = 0;
for (i = 1; i < 256; i++)
{
c = 0;
for (k = i | 256; k != 1; k >>= 1)
{
c = c & 1 ? (c >> 1) ^ e : c >> 1;
if (k & 1)
c ^= e;
}
crc_32_tab[i] = c;
}
crc = (ulg)0xffffffffUL;
}
#define ASCII_FLAG 0x01
#define CONTINUATION 0x02
#define EXTRA_FIELD 0x04
#define ORIG_NAME 0x08
#define COMMENT 0x10
#define ENCRYPTED 0x20
#define RESERVED 0xC0
* Do the uncompression!
*/
static int INIT gunzip(void)
{
uch flags;
unsigned char magic[2];
char method;
ulg orig_crc = 0;
ulg orig_len = 0;
int res;
magic[0] = NEXTBYTE();
magic[1] = NEXTBYTE();
method = NEXTBYTE();
if (magic[0] != 037 ||
((magic[1] != 0213) && (magic[1] != 0236))) {
error("bad gzip magic numbers");
return -1;
}
if (method != 8) {
error("internal error, invalid method");
return -1;
}
flags = (uch)get_byte();
if ((flags & ENCRYPTED) != 0) {
error("Input is encrypted");
return -1;
}
if ((flags & CONTINUATION) != 0) {
error("Multi part input");
return -1;
}
if ((flags & RESERVED) != 0) {
error("Input has invalid flags");
return -1;
}
NEXTBYTE();
NEXTBYTE();
NEXTBYTE();
NEXTBYTE();
(void)NEXTBYTE();
(void)NEXTBYTE();
if ((flags & EXTRA_FIELD) != 0) {
unsigned len = (unsigned)NEXTBYTE();
len |= ((unsigned)NEXTBYTE())<<8;
while (len--) (void)NEXTBYTE();
}
if ((flags & ORIG_NAME) != 0) {
while (NEXTBYTE() != 0) ;
}
if ((flags & COMMENT) != 0) {
while (NEXTBYTE() != 0) ;
}
if ((res = inflate())) {
switch (res) {
case 0:
break;
case 1:
error("invalid compressed format (err=1)");
break;
case 2:
error("invalid compressed format (err=2)");
break;
case 3:
error("out of memory");
break;
case 4:
error("out of input data");
break;
default:
error("invalid compressed format (other)");
}
return -1;
}
* uncompressed input size modulo 2^32
*/
orig_crc = (ulg) NEXTBYTE();
orig_crc |= (ulg) NEXTBYTE() << 8;
orig_crc |= (ulg) NEXTBYTE() << 16;
orig_crc |= (ulg) NEXTBYTE() << 24;
orig_len = (ulg) NEXTBYTE();
orig_len |= (ulg) NEXTBYTE() << 8;
orig_len |= (ulg) NEXTBYTE() << 16;
orig_len |= (ulg) NEXTBYTE() << 24;
if (orig_crc != CRC_VALUE) {
error("crc error");
return -1;
}
if (orig_len != bytes_out) {
error("length error");
return -1;
}
return 0;
underrun:
error("out of input data");
return -1;
}