static char * getFullStateJSON(void)
{
char separator = '{';
size_t alloc = INITIAL_ALLOC;
char * state;
int i, s;
Pgn * pgn;
size_t remain = alloc;
size_t l;
time_t now = time(0);
state = malloc(alloc);
for (l = 0, i = 0; i < maxPgnList; i++)
{
pgn = *pgnList[i];
MAKE_SPACE(100 + strlen(pgn->p_description));
snprintf(state + l, remain, "%c\"%u\":\n {\"description\":\"%s\"\n"
, separator
, pgn->p_prn
, pgn->p_description
);
INC_L_REMAIN;
for (s = 0; s < pgn->p_maxSrc; s++)
{
Message * m = &pgn->p_message[s];
if (m->m_time >= now)
{
MAKE_SPACE(strlen(m->m_text) + 32);
snprintf(state + l, remain, " ,\"%u%s%s\":%s"
, m->m_src
, m->m_key2 ? "_" : ""
, m->m_key2 ? m->m_key2 : ""
, m->m_text
);
INC_L_REMAIN;
}
}
strcpy(state + l, " }\n");
INC_L_REMAIN;
separator = ',';
}
if (separator == ',')
{
strcpy(state + l, "}\n");
}
else
{
strcpy(state + l, "\n");
}
logDebug("state %d bytes\n", strlen(state));
return state;
}
char *
entry2str_wrap(
Entry *e,
int *len,
ber_len_t wrap )
{
Attribute *a;
struct berval *bv;
int i;
ber_len_t tmplen;
assert( e != NULL );
/*
* In string format, an entry looks like this:
* dn: <dn>\n
* [<attr>: <value>\n]*
*/
ecur = ebuf;
/* put the dn */
if ( e->e_dn != NULL ) {
/* put "dn: <dn>" */
tmplen = e->e_name.bv_len;
MAKE_SPACE( LDIF_SIZE_NEEDED( 2, tmplen ));
ldif_sput_wrap( &ecur, LDIF_PUT_VALUE, "dn", e->e_dn, tmplen, wrap );
}
/* put the attributes */
for ( a = e->e_attrs; a != NULL; a = a->a_next ) {
/* put "<type>:[:] <value>" line for each value */
for ( i = 0; a->a_vals[i].bv_val != NULL; i++ ) {
bv = &a->a_vals[i];
tmplen = a->a_desc->ad_cname.bv_len;
MAKE_SPACE( LDIF_SIZE_NEEDED( tmplen, bv->bv_len ));
ldif_sput_wrap( &ecur, LDIF_PUT_VALUE,
a->a_desc->ad_cname.bv_val,
bv->bv_val, bv->bv_len, wrap );
}
}
MAKE_SPACE( 1 );
*ecur = '\0';
*len = ecur - ebuf;
return( ebuf );
}
/****************
* Scan the provided buffer and return the S expression in our internal
* format. Returns a newly allocated expression. If erroff is not NULL and
* a parsing error has occurred, the offset into buffer will be returned.
* If ARGFLAG is true, the function supports some printf like
* expressions.
* These are:
* %m - MPI
* %s - string (no autoswitch to secure allocation)
* %d - integer stored as string (no autoswitch to secure allocation)
* %b - memory buffer; this takes _two_ arguments: an integer with the
* length of the buffer and a pointer to the buffer.
* %S - Copy an gcry_sexp_t here. The S-expression needs to be a
* regular one, starting with a parenthesis.
* (no autoswitch to secure allocation)
* all other format elements are currently not defined and return an error.
* this includes the "%%" sequence becauce the percent sign is not an
* allowed character.
* FIXME: We should find a way to store the secure-MPIs not in the string
* but as reference to somewhere - this can help us to save huge amounts
* of secure memory. The problem is, that if only one element is secure, all
* other elements are automagicaly copied to secure memory too, so the most
* common operation gcry_sexp_cdr_mpi() will always return a secure MPI
* regardless whether it is needed or not.
*/
static gcry_error_t
vsexp_sscan (gcry_sexp_t *retsexp, size_t *erroff,
const char *buffer, size_t length, int argflag,
void **arg_list, va_list arg_ptr)
{
gcry_err_code_t err = 0;
static const char tokenchars[] =
"abcdefghijklmnopqrstuvwxyz"
"ABCDEFGHIJKLMNOPQRSTUVWXYZ"
"0123456789-./_:*+=";
const char *p;
size_t n;
const char *digptr = NULL;
const char *quoted = NULL;
const char *tokenp = NULL;
const char *hexfmt = NULL;
const char *base64 = NULL;
const char *disphint = NULL;
const char *percent = NULL;
int hexcount = 0;
int quoted_esc = 0;
int datalen = 0;
size_t dummy_erroff;
struct make_space_ctx c;
int arg_counter = 0;
int level = 0;
if (!erroff)
erroff = &dummy_erroff;
/* Depending on whether ARG_LIST is non-zero or not, this macro gives
us the next argument, either from the variable argument list as
specified by ARG_PTR or from the argument array ARG_LIST. */
#define ARG_NEXT(storage, type) \
do \
{ \
if (!arg_list) \
storage = va_arg (arg_ptr, type); \
else \
storage = *((type *) (arg_list[arg_counter++])); \
} \
while (0)
/* The MAKE_SPACE macro is used before each store operation to
ensure that the buffer is large enough. It requires a global
context named C and jumps out to the label LEAVE on error! It
also sets ERROFF using the variables BUFFER and P. */
#define MAKE_SPACE(n) do { \
gpg_err_code_t _ms_err = make_space (&c, (n)); \
if (_ms_err) \
{ \
err = _ms_err; \
*erroff = p - buffer; \
goto leave; \
} \
} while (0)
/* The STORE_LEN macro is used to store the length N at buffer P. */
#define STORE_LEN(p,n) do { \
DATALEN ashort = (n); \
memcpy ( (p), &ashort, sizeof(ashort) ); \
(p) += sizeof (ashort); \
} while (0)
/* We assume that the internal representation takes less memory than
the provided one. However, we add space for one extra datalen so
that the code which does the ST_CLOSE can use MAKE_SPACE */
c.allocated = length + sizeof(DATALEN);
if (buffer && length && gcry_is_secure (buffer))
c.sexp = gcry_malloc_secure (sizeof *c.sexp + c.allocated - 1);
else
c.sexp = gcry_malloc (sizeof *c.sexp + c.allocated - 1);
if (!c.sexp)
{
err = gpg_err_code_from_errno (errno);
*erroff = 0;
goto leave;
}
c.pos = c.sexp->d;
for (p = buffer, n = length; n; p++, n--)
{
if (tokenp && !hexfmt)
{
if (strchr (tokenchars, *p))
continue;
else
{
datalen = p - tokenp;
MAKE_SPACE (datalen);
*c.pos++ = ST_DATA;
STORE_LEN (c.pos, datalen);
memcpy (c.pos, tokenp, datalen);
c.pos += datalen;
tokenp = NULL;
}
}
if (quoted)
{
if (quoted_esc)
{
switch (*p)
{
case 'b': case 't': case 'v': case 'n': case 'f':
case 'r': case '"': case '\'': case '\\':
quoted_esc = 0;
break;
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7':
if (!((n > 2)
&& (p[1] >= '0') && (p[1] <= '7')
&& (p[2] >= '0') && (p[2] <= '7')))
{
*erroff = p - buffer;
/* Invalid octal value. */
err = GPG_ERR_SEXP_BAD_QUOTATION;
goto leave;
}
p += 2;
n -= 2;
quoted_esc = 0;
break;
case 'x':
if (!((n > 2) && hexdigitp (p+1) && hexdigitp (p+2)))
{
*erroff = p - buffer;
/* Invalid hex value. */
err = GPG_ERR_SEXP_BAD_QUOTATION;
goto leave;
}
p += 2;
n -= 2;
quoted_esc = 0;
break;
case '\r':
/* ignore CR[,LF] */
if (n && (p[1] == '\n'))
{
p++;
n--;
}
quoted_esc = 0;
break;
case '\n':
/* ignore LF[,CR] */
if (n && (p[1] == '\r'))
{
p++;
n--;
}
quoted_esc = 0;
break;
default:
*erroff = p - buffer;
/* Invalid quoted string escape. */
err = GPG_ERR_SEXP_BAD_QUOTATION;
goto leave;
}
}
else if (*p == '\\')
quoted_esc = 1;
else if (*p == '\"')
{
/* Keep it easy - we know that the unquoted string will
never be larger. */
unsigned char *save;
size_t len;
quoted++; /* Skip leading quote. */
MAKE_SPACE (p - quoted);
*c.pos++ = ST_DATA;
save = c.pos;
STORE_LEN (c.pos, 0); /* Will be fixed up later. */
len = unquote_string (quoted, p - quoted, c.pos);
c.pos += len;
STORE_LEN (save, len);
quoted = NULL;
}
}
else if (hexfmt)
{
if (isxdigit (*p))
hexcount++;
else if (*p == '#')
{
if ((hexcount & 1))
{
*erroff = p - buffer;
err = GPG_ERR_SEXP_ODD_HEX_NUMBERS;
goto leave;
}
datalen = hexcount / 2;
MAKE_SPACE (datalen);
*c.pos++ = ST_DATA;
STORE_LEN (c.pos, datalen);
for (hexfmt++; hexfmt < p; hexfmt++)
{
int tmpc;
if (whitespacep (hexfmt))
continue;
tmpc = hextonibble (*(const unsigned char*)hexfmt);
for (hexfmt++; hexfmt < p && whitespacep (hexfmt); hexfmt++)
;
if (hexfmt < p)
{
tmpc *= 16;
tmpc += hextonibble (*(const unsigned char*)hexfmt);
}
*c.pos++ = tmpc;
}
hexfmt = NULL;
}
else if (!whitespacep (p))
{
*erroff = p - buffer;
err = GPG_ERR_SEXP_BAD_HEX_CHAR;
goto leave;
}
}
else if (base64)
{
if (*p == '|')
base64 = NULL;
}
else if (digptr)
{
if (digitp (p))
;
else if (*p == ':')
{
datalen = atoi (digptr); /* FIXME: check for overflow. */
digptr = NULL;
if (datalen > n - 1)
{
*erroff = p - buffer;
/* Buffer too short. */
err = GPG_ERR_SEXP_STRING_TOO_LONG;
goto leave;
}
/* Make a new list entry. */
MAKE_SPACE (datalen);
*c.pos++ = ST_DATA;
STORE_LEN (c.pos, datalen);
memcpy (c.pos, p + 1, datalen);
c.pos += datalen;
n -= datalen;
p += datalen;
}
else if (*p == '\"')
{
digptr = NULL; /* We ignore the optional length. */
quoted = p;
quoted_esc = 0;
}
else if (*p == '#')
{
digptr = NULL; /* We ignore the optional length. */
hexfmt = p;
hexcount = 0;
}
else if (*p == '|')
{
digptr = NULL; /* We ignore the optional length. */
base64 = p;
}
else
{
*erroff = p - buffer;
err = GPG_ERR_SEXP_INV_LEN_SPEC;
goto leave;
}
}
else if (percent)
{
if (*p == 'm' || *p == 'M')
{
/* Insert an MPI. */
gcry_mpi_t m;
size_t nm = 0;
int mpifmt = *p == 'm'? GCRYMPI_FMT_STD: GCRYMPI_FMT_USG;
ARG_NEXT (m, gcry_mpi_t);
if (gcry_mpi_get_flag (m, GCRYMPI_FLAG_OPAQUE))
{
void *mp;
unsigned int nbits;
mp = gcry_mpi_get_opaque (m, &nbits);
nm = (nbits+7)/8;
if (mp && nm)
{
MAKE_SPACE (nm);
if (!gcry_is_secure (c.sexp->d)
&& gcry_mpi_get_flag (m, GCRYMPI_FLAG_SECURE))
{
/* We have to switch to secure allocation. */
gcry_sexp_t newsexp;
byte *newhead;
newsexp = gcry_malloc_secure (sizeof *newsexp
+ c.allocated - 1);
if (!newsexp)
{
err = gpg_err_code_from_errno (errno);
goto leave;
}
newhead = newsexp->d;
memcpy (newhead, c.sexp->d, (c.pos - c.sexp->d));
c.pos = newhead + (c.pos - c.sexp->d);
gcry_free (c.sexp);
c.sexp = newsexp;
}
*c.pos++ = ST_DATA;
STORE_LEN (c.pos, nm);
memcpy (c.pos, mp, nm);
c.pos += nm;
}
}
else
{
if (gcry_mpi_print (mpifmt, NULL, 0, &nm, m))
BUG ();
MAKE_SPACE (nm);
if (!gcry_is_secure (c.sexp->d)
&& gcry_mpi_get_flag ( m, GCRYMPI_FLAG_SECURE))
{
/* We have to switch to secure allocation. */
gcry_sexp_t newsexp;
byte *newhead;
newsexp = gcry_malloc_secure (sizeof *newsexp
+ c.allocated - 1);
if (!newsexp)
{
err = gpg_err_code_from_errno (errno);
goto leave;
}
newhead = newsexp->d;
memcpy (newhead, c.sexp->d, (c.pos - c.sexp->d));
c.pos = newhead + (c.pos - c.sexp->d);
gcry_free (c.sexp);
c.sexp = newsexp;
}
*c.pos++ = ST_DATA;
STORE_LEN (c.pos, nm);
if (gcry_mpi_print (mpifmt, c.pos, nm, &nm, m))
BUG ();
c.pos += nm;
}
}
else if (*p == 's')
{
/* Insert an string. */
const char *astr;
size_t alen;
ARG_NEXT (astr, const char *);
alen = strlen (astr);
MAKE_SPACE (alen);
*c.pos++ = ST_DATA;
STORE_LEN (c.pos, alen);
memcpy (c.pos, astr, alen);
c.pos += alen;
}
else if (*p == 'b')
{
/* Insert a memory buffer. */
const char *astr;
int alen;
ARG_NEXT (alen, int);
ARG_NEXT (astr, const char *);
MAKE_SPACE (alen);
if (alen
&& !gcry_is_secure (c.sexp->d)
&& gcry_is_secure (astr))
{
/* We have to switch to secure allocation. */
gcry_sexp_t newsexp;
byte *newhead;
newsexp = gcry_malloc_secure (sizeof *newsexp
+ c.allocated - 1);
if (!newsexp)
{
err = gpg_err_code_from_errno (errno);
goto leave;
}
newhead = newsexp->d;
memcpy (newhead, c.sexp->d, (c.pos - c.sexp->d));
c.pos = newhead + (c.pos - c.sexp->d);
gcry_free (c.sexp);
c.sexp = newsexp;
}
*c.pos++ = ST_DATA;
STORE_LEN (c.pos, alen);
memcpy (c.pos, astr, alen);
c.pos += alen;
}
else if (*p == 'd')
{
/* Insert an integer as string. */
int aint;
size_t alen;
char buf[35];
ARG_NEXT (aint, int);
sprintf (buf, "%d", aint);
alen = strlen (buf);
MAKE_SPACE (alen);
*c.pos++ = ST_DATA;
STORE_LEN (c.pos, alen);
memcpy (c.pos, buf, alen);
c.pos += alen;
}
else if (*p == 'u')
{
/* Insert an unsigned integer as string. */
unsigned int aint;
size_t alen;
char buf[35];
ARG_NEXT (aint, unsigned int);
sprintf (buf, "%u", aint);
alen = strlen (buf);
MAKE_SPACE (alen);
*c.pos++ = ST_DATA;
STORE_LEN (c.pos, alen);
memcpy (c.pos, buf, alen);
c.pos += alen;
}
else if (*p == 'S')
{
/* Insert a gcry_sexp_t. */
gcry_sexp_t asexp;
size_t alen, aoff;
ARG_NEXT (asexp, gcry_sexp_t);
alen = get_internal_buffer (asexp, &aoff);
if (alen)
{
MAKE_SPACE (alen);
memcpy (c.pos, asexp->d + aoff, alen);
c.pos += alen;
}
}
else
{
*erroff = p - buffer;
/* Invalid format specifier. */
err = GPG_ERR_SEXP_INV_LEN_SPEC;
goto leave;
}
percent = NULL;
}
else if (*p == '(')
{
if (disphint)
{
*erroff = p - buffer;
/* Open display hint. */
err = GPG_ERR_SEXP_UNMATCHED_DH;
goto leave;
}
MAKE_SPACE (0);
*c.pos++ = ST_OPEN;
level++;
}
else if (*p == ')')
{
/* Walk up. */
if (disphint)
{
*erroff = p - buffer;
/* Open display hint. */
err = GPG_ERR_SEXP_UNMATCHED_DH;
goto leave;
}
MAKE_SPACE (0);
*c.pos++ = ST_CLOSE;
level--;
}
else if (*p == '\"')
{
quoted = p;
quoted_esc = 0;
}
else if (*p == '#')
{
hexfmt = p;
hexcount = 0;
}
else if (*p == '|')
base64 = p;
else if (*p == '[')
{
if (disphint)
{
*erroff = p - buffer;
/* Open display hint. */
err = GPG_ERR_SEXP_NESTED_DH;
goto leave;
}
disphint = p;
}
else if (*p == ']')
{
if (!disphint)
{
*erroff = p - buffer;
/* Open display hint. */
err = GPG_ERR_SEXP_UNMATCHED_DH;
goto leave;
}
disphint = NULL;
}
else if (digitp (p))
{
if (*p == '0')
{
/* A length may not begin with zero. */
*erroff = p - buffer;
err = GPG_ERR_SEXP_ZERO_PREFIX;
goto leave;
}
digptr = p;
}
else if (strchr (tokenchars, *p))
tokenp = p;
else if (whitespacep (p))
;
else if (*p == '{')
{
/* fixme: handle rescanning: we can do this by saving our
current state and start over at p+1 -- Hmmm. At this
point here we are in a well defined state, so we don't
need to save it. Great. */
*erroff = p - buffer;
err = GPG_ERR_SEXP_UNEXPECTED_PUNC;
goto leave;
}
else if (strchr ("&\\", *p))
{
/* Reserved punctuation. */
*erroff = p - buffer;
err = GPG_ERR_SEXP_UNEXPECTED_PUNC;
goto leave;
}
else if (argflag && (*p == '%'))
percent = p;
else
{
/* Bad or unavailable. */
*erroff = p - buffer;
err = GPG_ERR_SEXP_BAD_CHARACTER;
goto leave;
}
}
MAKE_SPACE (0);
*c.pos++ = ST_STOP;
if (level && !err)
err = GPG_ERR_SEXP_UNMATCHED_PAREN;
leave:
if (err)
{
/* Error -> deallocate. */
if (c.sexp)
{
/* Extra paranoid wipe on error. */
if (gcry_is_secure (c.sexp))
wipememory (c.sexp, sizeof (struct gcry_sexp) + c.allocated - 1);
gcry_free (c.sexp);
}
/* This might be expected by existing code... */
*retsexp = NULL;
}
else
*retsexp = normalize (c.sexp);
return gcry_error (err);
#undef MAKE_SPACE
#undef STORE_LEN
}
