/* io.c - ber general i/o routines */
/* $OpenLDAP$ */
/* This work is part of OpenLDAP Software .
*
* Copyright 1998-2007 The OpenLDAP Foundation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted only as authorized by the OpenLDAP
* Public License.
*
* A copy of this license is available in the file LICENSE in the
* top-level directory of the distribution or, alternatively, at
* .
*/
/* Portions Copyright (c) 1990 Regents of the University of Michigan.
* All rights reserved.
*
* Redistribution and use in source and binary forms are permitted
* provided that this notice is preserved and that due credit is given
* to the University of Michigan at Ann Arbor. The name of the University
* may not be used to endorse or promote products derived from this
* software without specific prior written permission. This software
* is provided ``as is'' without express or implied warranty.
*/
/* ACKNOWLEDGEMENTS:
* This work was originally developed by the University of Michigan
* (as part of U-MICH LDAP).
*/
#include "portable.h"
#include
#include
#include
#include
#include
#include
#include
#ifdef HAVE_IO_H
#include
#endif
#include "lber-int.h"
#include "ldap_log.h"
ber_slen_t
ber_skip_data(
BerElement *ber,
ber_len_t len )
{
ber_len_t actuallen, nleft;
assert( ber != NULL );
assert( LBER_VALID( ber ) );
nleft = ber_pvt_ber_remaining( ber );
actuallen = nleft < len ? nleft : len;
ber->ber_ptr += actuallen;
ber->ber_tag = *(unsigned char *)ber->ber_ptr;
return( (ber_slen_t) actuallen );
}
ber_slen_t
ber_read(
BerElement *ber,
char *buf,
ber_len_t len )
{
ber_len_t actuallen, nleft;
assert( ber != NULL );
assert( buf != NULL );
assert( LBER_VALID( ber ) );
nleft = ber_pvt_ber_remaining( ber );
actuallen = nleft < len ? nleft : len;
AC_MEMCPY( buf, ber->ber_ptr, actuallen );
ber->ber_ptr += actuallen;
return( (ber_slen_t) actuallen );
}
ber_slen_t
ber_write(
BerElement *ber,
LDAP_CONST char *buf,
ber_len_t len,
int nosos )
{
assert( ber != NULL );
assert( buf != NULL );
assert( LBER_VALID( ber ) );
if ( nosos || ber->ber_sos == NULL ) {
if ( ber->ber_ptr + len > ber->ber_end ) {
if ( ber_realloc( ber, len ) != 0 ) return( -1 );
}
AC_MEMCPY( ber->ber_ptr, buf, (size_t)len );
ber->ber_ptr += len;
return( (ber_slen_t) len );
} else {
if ( ber->ber_sos->sos_ptr + len > ber->ber_end ) {
if ( ber_realloc( ber, len ) != 0 ) return( -1 );
}
AC_MEMCPY( ber->ber_sos->sos_ptr, buf, (size_t)len );
ber->ber_sos->sos_ptr += len;
ber->ber_sos->sos_clen += len;
return( (ber_slen_t) len );
}
}
int
ber_realloc( BerElement *ber, ber_len_t len )
{
ber_len_t total;
Seqorset *s;
long off;
char *oldbuf;
assert( ber != NULL );
assert( len > 0 );
assert( LBER_VALID( ber ) );
total = ber_pvt_ber_total( ber );
#define LBER_EXBUFSIZ 4060 /* a few words less than 2^N for binary buddy */
#if defined( LBER_EXBUFSIZ ) && LBER_EXBUFSIZ > 0
# ifndef notdef
/* don't realloc by small amounts */
total += len < LBER_EXBUFSIZ ? LBER_EXBUFSIZ : len;
# else
{ /* not sure what value this adds */
ber_len_t have = (total + (LBER_EXBUFSIZE - 1)) / LBER_EXBUFSIZ;
ber_len_t need = (len + (LBER_EXBUFSIZ - 1)) / LBER_EXBUFSIZ;
total = ( have + need ) * LBER_EXBUFSIZ;
}
# endif
#else
total += len; /* realloc just what's needed */
#endif
oldbuf = ber->ber_buf;
ber->ber_buf = (char *) ber_memrealloc_x( oldbuf, total, ber->ber_memctx );
if ( ber->ber_buf == NULL ) {
ber->ber_buf = oldbuf;
return( -1 );
}
ber->ber_end = ber->ber_buf + total;
/*
* If the stinking thing was moved, we need to go through and
* reset all the sos and ber pointers. Offsets would've been
* a better idea... oh well.
*/
if ( ber->ber_buf != oldbuf ) {
ber->ber_ptr = ber->ber_buf + (ber->ber_ptr - oldbuf);
for ( s = ber->ber_sos; s != NULL; s = s->sos_next ) {
off = s->sos_first - oldbuf;
s->sos_first = ber->ber_buf + off;
off = s->sos_ptr - oldbuf;
s->sos_ptr = ber->ber_buf + off;
}
}
return( 0 );
}
void
ber_free_buf( BerElement *ber )
{
Seqorset *s, *next;
assert( LBER_VALID( ber ) );
if ( ber->ber_buf) ber_memfree_x( ber->ber_buf, ber->ber_memctx );
for( s = ber->ber_sos ; s != NULL ; s = next ) {
next = s->sos_next;
ber_memfree_x( s, ber->ber_memctx );
}
ber->ber_buf = NULL;
ber->ber_sos = NULL;
ber->ber_valid = LBER_UNINITIALIZED;
}
void
ber_free( BerElement *ber, int freebuf )
{
if( ber == NULL ) {
LDAP_MEMORY_DEBUG_ASSERT( ber != NULL );
return;
}
if( freebuf ) ber_free_buf( ber );
ber_memfree_x( (char *) ber, ber->ber_memctx );
}
int
ber_flush( Sockbuf *sb, BerElement *ber, int freeit )
{
return ber_flush2( sb, ber,
freeit ? LBER_FLUSH_FREE_ON_SUCCESS
: LBER_FLUSH_FREE_NEVER );
}
int
ber_flush2( Sockbuf *sb, BerElement *ber, int freeit )
{
ber_len_t towrite;
ber_slen_t rc;
assert( sb != NULL );
assert( ber != NULL );
assert( SOCKBUF_VALID( sb ) );
assert( LBER_VALID( ber ) );
if ( ber->ber_rwptr == NULL ) {
ber->ber_rwptr = ber->ber_buf;
}
towrite = ber->ber_ptr - ber->ber_rwptr;
if ( sb->sb_debug ) {
ber_log_printf( LDAP_DEBUG_TRACE, sb->sb_debug,
"ber_flush2: %ld bytes to sd %ld%s\n",
towrite, (long) sb->sb_fd,
ber->ber_rwptr != ber->ber_buf ? " (re-flush)" : "" );
ber_log_bprint( LDAP_DEBUG_PACKETS, sb->sb_debug,
ber->ber_rwptr, towrite );
}
while ( towrite > 0 ) {
#ifdef LBER_TRICKLE
sleep(1);
rc = ber_int_sb_write( sb, ber->ber_rwptr, 1 );
#else
rc = ber_int_sb_write( sb, ber->ber_rwptr, towrite );
#endif
if ( rc <= 0 ) {
if ( freeit & LBER_FLUSH_FREE_ON_ERROR ) ber_free( ber, 1 );
return -1;
}
towrite -= rc;
ber->ber_rwptr += rc;
}
if ( freeit & LBER_FLUSH_FREE_ON_SUCCESS ) ber_free( ber, 1 );
return 0;
}
BerElement *
ber_alloc_t( int options )
{
BerElement *ber;
ber = (BerElement *) LBER_CALLOC( 1, sizeof(BerElement) );
if ( ber == NULL ) {
return NULL;
}
ber->ber_valid = LBER_VALID_BERELEMENT;
ber->ber_tag = LBER_DEFAULT;
ber->ber_options = options;
ber->ber_debug = ber_int_debug;
assert( LBER_VALID( ber ) );
return ber;
}
BerElement *
ber_alloc( void ) /* deprecated */
{
return ber_alloc_t( 0 );
}
BerElement *
der_alloc( void ) /* deprecated */
{
return ber_alloc_t( LBER_USE_DER );
}
BerElement *
ber_dup( BerElement *ber )
{
BerElement *new;
assert( ber != NULL );
assert( LBER_VALID( ber ) );
if ( (new = ber_alloc_t( ber->ber_options )) == NULL ) {
return NULL;
}
*new = *ber;
assert( LBER_VALID( new ) );
return( new );
}
void
ber_init2( BerElement *ber, struct berval *bv, int options )
{
assert( ber != NULL );
(void) memset( (char *)ber, '\0', sizeof( BerElement ));
ber->ber_valid = LBER_VALID_BERELEMENT;
ber->ber_tag = LBER_DEFAULT;
ber->ber_options = (char) options;
ber->ber_debug = ber_int_debug;
if ( bv != NULL ) {
ber->ber_buf = bv->bv_val;
ber->ber_ptr = ber->ber_buf;
ber->ber_end = ber->ber_buf + bv->bv_len;
}
assert( LBER_VALID( ber ) );
}
/* OLD U-Mich ber_init() */
void
ber_init_w_nullc( BerElement *ber, int options )
{
ber_init2( ber, NULL, options );
}
/* New C-API ber_init() */
/* This function constructs a BerElement containing a copy
** of the data in the bv argument.
*/
BerElement *
ber_init( struct berval *bv )
{
BerElement *ber;
assert( bv != NULL );
if ( bv == NULL ) {
return NULL;
}
ber = ber_alloc_t( 0 );
if( ber == NULL ) {
/* allocation failed */
return NULL;
}
/* copy the data */
if ( ((ber_len_t) ber_write ( ber, bv->bv_val, bv->bv_len, 0 ))
!= bv->bv_len )
{
/* write failed, so free and return NULL */
ber_free( ber, 1 );
return NULL;
}
ber_reset( ber, 1 ); /* reset the pointer to the start of the buffer */
return ber;
}
/* New C-API ber_flatten routine */
/* This routine allocates a struct berval whose contents are a BER
** encoding taken from the ber argument. The bvPtr pointer points to
** the returned berval.
**
** ber_flatten2 is the same, but uses a struct berval passed by
** the caller. If alloc is 0 the returned bv uses the ber buf directly.
*/
int ber_flatten2(
BerElement *ber,
struct berval *bv,
int alloc )
{
assert( bv != NULL );
if ( bv == NULL ) {
return -1;
}
if ( ber == NULL ) {
/* ber is null, create an empty berval */
bv->bv_val = NULL;
bv->bv_len = 0;
} else {
/* copy the berval */
ber_len_t len = ber_pvt_ber_write( ber );
if ( alloc ) {
bv->bv_val = (char *) ber_memalloc_x( len + 1, ber->ber_memctx );
if ( bv->bv_val == NULL ) {
return -1;
}
AC_MEMCPY( bv->bv_val, ber->ber_buf, len );
} else {
bv->bv_val = ber->ber_buf;
}
bv->bv_val[len] = '\0';
bv->bv_len = len;
}
return 0;
}
int ber_flatten(
BerElement *ber,
struct berval **bvPtr)
{
struct berval *bv;
int rc;
assert( bvPtr != NULL );
if(bvPtr == NULL) {
return -1;
}
bv = ber_memalloc_x( sizeof(struct berval), ber->ber_memctx );
if ( bv == NULL ) {
return -1;
}
rc = ber_flatten2(ber, bv, 1);
if (rc == -1) {
ber_memfree_x(bv, ber->ber_memctx);
} else {
*bvPtr = bv;
}
return rc;
}
void
ber_reset( BerElement *ber, int was_writing )
{
assert( ber != NULL );
assert( LBER_VALID( ber ) );
if ( was_writing ) {
ber->ber_end = ber->ber_ptr;
ber->ber_ptr = ber->ber_buf;
} else {
ber->ber_ptr = ber->ber_end;
}
ber->ber_rwptr = NULL;
}
/*
* A rewrite of ber_get_next that can safely be called multiple times
* for the same packet. It will simply continue where it stopped until
* a full packet is read.
*/
#define LENSIZE 4
ber_tag_t
ber_get_next(
Sockbuf *sb,
ber_len_t *len,
BerElement *ber )
{
assert( sb != NULL );
assert( len != NULL );
assert( ber != NULL );
assert( SOCKBUF_VALID( sb ) );
assert( LBER_VALID( ber ) );
if ( ber->ber_debug & LDAP_DEBUG_TRACE ) {
ber_log_printf( LDAP_DEBUG_TRACE, ber->ber_debug,
"ber_get_next\n" );
}
/*
* Any ber element looks like this: tag length contents.
* Assuming everything's ok, we return the tag byte (we
* can assume a single byte), return the length in len,
* and the rest of the undecoded element in buf.
*
* Assumptions:
* 1) small tags (less than 128)
* 2) definite lengths
* 3) primitive encodings used whenever possible
*
* The code also handles multi-byte tags. The first few bytes
* of the message are read to check for multi-byte tags and
* lengths. These bytes are temporarily stored in the ber_tag,
* ber_len, and ber_usertag fields of the berelement until
* tag/len parsing is complete. After this parsing, any leftover
* bytes and the rest of the message are copied into the ber_buf.
*
* We expect tag and len to be at most 32 bits wide.
*/
if (ber->ber_rwptr == NULL) {
assert( ber->ber_buf == NULL );
ber->ber_rwptr = (char *) &ber->ber_len-1;
ber->ber_ptr = ber->ber_rwptr;
ber->ber_tag = 0;
}
while (ber->ber_rwptr > (char *)&ber->ber_tag && ber->ber_rwptr <
(char *)&ber->ber_len + LENSIZE*2 -1) {
ber_slen_t sblen;
char buf[sizeof(ber->ber_len)-1];
ber_len_t tlen = 0;
sock_errset(0);
sblen=ber_int_sb_read( sb, ber->ber_rwptr,
((char *)&ber->ber_len + LENSIZE*2 - 1)-ber->ber_rwptr);
if (sblen<=0) return LBER_DEFAULT;
ber->ber_rwptr += sblen;
/* We got at least one byte, try to parse the tag. */
if (ber->ber_ptr == (char *)&ber->ber_len-1) {
ber_tag_t tag;
unsigned char *p = (unsigned char *)ber->ber_ptr;
tag = *p++;
if ((tag & LBER_BIG_TAG_MASK) == LBER_BIG_TAG_MASK) {
ber_len_t i;
for (i=1; (char *)pber_rwptr; i++) {
tag <<= 8;
tag |= *p++;
if (!(tag & LBER_MORE_TAG_MASK))
break;
/* Is the tag too big? */
if (i == sizeof(ber_tag_t)-1) {
sock_errset(ERANGE);
return LBER_DEFAULT;
}
}
/* Did we run out of bytes? */
if ((char *)p == ber->ber_rwptr) {
#if defined( EWOULDBLOCK )
sock_errset(EWOULDBLOCK);
#elif defined( EAGAIN )
sock_errset(EAGAIN);
#endif
return LBER_DEFAULT;
}
}
ber->ber_tag = tag;
ber->ber_ptr = (char *)p;
}
if ( ber->ber_ptr == ber->ber_rwptr ) {
#if defined( EWOULDBLOCK )
sock_errset(EWOULDBLOCK);
#elif defined( EAGAIN )
sock_errset(EAGAIN);
#endif
return LBER_DEFAULT;
}
/* Now look for the length */
if (*ber->ber_ptr & 0x80) { /* multi-byte */
int i;
unsigned char *p = (unsigned char *)ber->ber_ptr;
int llen = *p++ & 0x7f;
if (llen > (int)sizeof(ber_len_t)) {
sock_errset(ERANGE);
return LBER_DEFAULT;
}
/* Not enough bytes? */
if (ber->ber_rwptr - (char *)p < llen) {
#if defined( EWOULDBLOCK )
sock_errset(EWOULDBLOCK);
#elif defined( EAGAIN )
sock_errset(EAGAIN);
#endif
return LBER_DEFAULT;
}
for (i=0; iber_ptr = (char *)p;
} else {
tlen = *(unsigned char *)ber->ber_ptr++;
}
/* Are there leftover data bytes inside ber->ber_len? */
if (ber->ber_ptr < (char *)&ber->ber_usertag) {
if (ber->ber_rwptr < (char *)&ber->ber_usertag) {
sblen = ber->ber_rwptr - ber->ber_ptr;
} else {
sblen = (char *)&ber->ber_usertag - ber->ber_ptr;
}
AC_MEMCPY(buf, ber->ber_ptr, sblen);
ber->ber_ptr += sblen;
} else {
sblen = 0;
}
ber->ber_len = tlen;
/* now fill the buffer. */
/* make sure length is reasonable */
if ( ber->ber_len == 0 ) {
sock_errset(ERANGE);
return LBER_DEFAULT;
}
if ( sb->sb_max_incoming && ber->ber_len > sb->sb_max_incoming ) {
ber_log_printf( LDAP_DEBUG_CONNS, ber->ber_debug,
"ber_get_next: sockbuf_max_incoming exceeded "
"(%ld > %ld)\n", ber->ber_len, sb->sb_max_incoming );
sock_errset(ERANGE);
return LBER_DEFAULT;
}
if (ber->ber_buf==NULL) {
ber_len_t l = ber->ber_rwptr - ber->ber_ptr;
/* ber->ber_ptr is always <= ber->ber->ber_rwptr.
* make sure ber->ber_len agrees with what we've
* already read.
*/
if ( ber->ber_len < sblen + l ) {
sock_errset(ERANGE);
return LBER_DEFAULT;
}
ber->ber_buf = (char *) ber_memalloc_x( ber->ber_len + 1, ber->ber_memctx );
if (ber->ber_buf==NULL) {
return LBER_DEFAULT;
}
ber->ber_end = ber->ber_buf + ber->ber_len;
if (sblen) {
AC_MEMCPY(ber->ber_buf, buf, sblen);
}
if (l > 0) {
AC_MEMCPY(ber->ber_buf + sblen, ber->ber_ptr, l);
sblen += l;
}
*ber->ber_end = '\0';
ber->ber_ptr = ber->ber_buf;
ber->ber_usertag = 0;
if ((ber_len_t)sblen == ber->ber_len) {
goto done;
}
ber->ber_rwptr = ber->ber_buf + sblen;
}
}
if ((ber->ber_rwptr>=ber->ber_buf) && (ber->ber_rwptrber_end)) {
ber_slen_t res;
ber_slen_t to_go;
to_go = ber->ber_end - ber->ber_rwptr;
assert( to_go > 0 );
sock_errset(0);
res = ber_int_sb_read( sb, ber->ber_rwptr, to_go );
if (res<=0) return LBER_DEFAULT;
ber->ber_rwptr+=res;
if (resber_rwptr = NULL;
*len = ber->ber_len;
if ( ber->ber_debug ) {
ber_log_printf( LDAP_DEBUG_TRACE, ber->ber_debug,
"ber_get_next: tag 0x%lx len %ld contents:\n",
ber->ber_tag, ber->ber_len );
ber_log_dump( LDAP_DEBUG_BER, ber->ber_debug, ber, 1 );
}
return (ber->ber_tag);
}
assert( 0 ); /* ber structure is messed up ?*/
return LBER_DEFAULT;
}
char *
ber_start( BerElement* ber )
{
return ber->ber_buf;
}
int
ber_len( BerElement* ber )
{
return ( ber->ber_end - ber->ber_buf );
}
int
ber_ptrlen( BerElement* ber )
{
return ( ber->ber_ptr - ber->ber_buf );
}
void
ber_rewind ( BerElement * ber )
{
ber->ber_rwptr = NULL;
ber->ber_sos = NULL;
ber->ber_end = ber->ber_ptr;
ber->ber_ptr = ber->ber_buf;
}
int
ber_remaining( BerElement * ber )
{
return ber_pvt_ber_remaining( ber );
}