~zulcss/samba/server-dailies-3.4

/*
 *  Unix SMB/CIFS implementation.
 *  Virtual Windows Registry Layer
 *  Copyright (C) Gerald Carter                     2002-2005
 *
 *  This program 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 3 of the License, or
 *  (at your option) any later version.
 *
 *  This program 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 this program; if not, see <http://www.gnu.org/licenses/>.
 */

/* Implementation of registry frontend view functions. */

#include "includes.h"

#undef DBGC_CLASS
#define DBGC_CLASS DBGC_REGISTRY

struct regsubkey_ctr {
	uint32_t        num_subkeys;
	char            **subkeys;
	struct db_context *subkeys_hash;
	int seqnum;
};

/**********************************************************************

 Note that the struct regsubkey_ctr and REGVAL_CTR objects *must* be
 talloc()'d since the methods use the object pointer as the talloc
 context for internal private data.

 There is no longer a regval_ctr_intit() and regval_ctr_destroy()
 pair of functions.  Simply TALLOC_ZERO_P() and TALLOC_FREE() the
 object.

 **********************************************************************/

WERROR regsubkey_ctr_init(TALLOC_CTX *mem_ctx, struct regsubkey_ctr **ctr)
{
	if (ctr == NULL) {
		return WERR_INVALID_PARAM;
	}

	*ctr = talloc_zero(mem_ctx, struct regsubkey_ctr);
	if (*ctr == NULL) {
		return WERR_NOMEM;
	}

	(*ctr)->subkeys_hash = db_open_rbt(*ctr);
	if ((*ctr)->subkeys_hash == NULL) {
		talloc_free(*ctr);
		return WERR_NOMEM;
	}

	return WERR_OK;
}

WERROR regsubkey_ctr_set_seqnum(struct regsubkey_ctr *ctr, int seqnum)
{
	if (ctr == NULL) {
		return WERR_INVALID_PARAM;
	}

	ctr->seqnum = seqnum;

	return WERR_OK;
}

int regsubkey_ctr_get_seqnum(struct regsubkey_ctr *ctr)
{
	if (ctr == NULL) {
		return -1;
	}

	return ctr->seqnum;
}

static WERROR regsubkey_ctr_hash_keyname(struct regsubkey_ctr *ctr,
					 const char *keyname,
					 uint32 idx)
{
	WERROR werr;

	werr = ntstatus_to_werror(dbwrap_store_bystring(ctr->subkeys_hash,
						keyname,
						make_tdb_data((uint8 *)&idx,
							      sizeof(idx)),
						TDB_REPLACE));
	if (!W_ERROR_IS_OK(werr)) {
		DEBUG(1, ("error hashing new key '%s' in container: %s\n",
			  keyname, win_errstr(werr)));
	}

	return werr;
}

static WERROR regsubkey_ctr_unhash_keyname(struct regsubkey_ctr *ctr,
					   const char *keyname)
{
	WERROR werr;

	werr = ntstatus_to_werror(dbwrap_delete_bystring(ctr->subkeys_hash,
				  keyname));
	if (!W_ERROR_IS_OK(werr)) {
		DEBUG(1, ("error unhashing key '%s' in container: %s\n",
			  keyname, win_errstr(werr)));
	}

	return werr;
}

static WERROR regsubkey_ctr_index_for_keyname(struct regsubkey_ctr *ctr,
					      const char *keyname,
					      uint32 *idx)
{
	TDB_DATA data;

	if ((ctr == NULL) || (keyname == NULL)) {
		return WERR_INVALID_PARAM;
	}

	data = dbwrap_fetch_bystring(ctr->subkeys_hash, ctr, keyname);
	if (data.dptr == NULL) {
		return WERR_NOT_FOUND;
	}

	if (data.dsize != sizeof(*idx)) {
		talloc_free(data.dptr);
		return WERR_INVALID_DATATYPE;
	}

	if (idx != NULL) {
		*idx = *(uint32 *)data.dptr;
	}

	talloc_free(data.dptr);
	return WERR_OK;
}

/***********************************************************************
 Add a new key to the array
 **********************************************************************/

WERROR regsubkey_ctr_addkey( struct regsubkey_ctr *ctr, const char *keyname )
{
	char **newkeys;
	WERROR werr;

	if ( !keyname ) {
		return WERR_OK;
	}

	/* make sure the keyname is not already there */

	if ( regsubkey_ctr_key_exists( ctr, keyname ) ) {
		return WERR_OK;
	}

	if (!(newkeys = TALLOC_REALLOC_ARRAY(ctr, ctr->subkeys, char *,
					     ctr->num_subkeys+1))) {
		return WERR_NOMEM;
	}

	ctr->subkeys = newkeys;

	if (!(ctr->subkeys[ctr->num_subkeys] = talloc_strdup(ctr->subkeys,
							     keyname ))) {
		/*
		 * Don't shrink the new array again, this wastes a pointer
		 */
		return WERR_NOMEM;
	}

	werr = regsubkey_ctr_hash_keyname(ctr, keyname, ctr->num_subkeys);
	W_ERROR_NOT_OK_RETURN(werr);

	ctr->num_subkeys++;

	return WERR_OK;
}

 /***********************************************************************
 Delete a key from the array
 **********************************************************************/

WERROR regsubkey_ctr_delkey( struct regsubkey_ctr *ctr, const char *keyname )
{
	WERROR werr;
	uint32 idx, j;

	if (keyname == NULL) {
		return WERR_INVALID_PARAM;
	}

	/* make sure the keyname is actually already there */

	werr = regsubkey_ctr_index_for_keyname(ctr, keyname, &idx);
	W_ERROR_NOT_OK_RETURN(werr);

	werr = regsubkey_ctr_unhash_keyname(ctr, keyname);
	W_ERROR_NOT_OK_RETURN(werr);

	/* update if we have any keys left */
	ctr->num_subkeys--;
	if (idx < ctr->num_subkeys) {
		memmove(&ctr->subkeys[idx], &ctr->subkeys[idx+1],
			sizeof(char *) * (ctr->num_subkeys - idx));

		/* we have to re-hash rest of the array...  :-( */
		for (j = idx; j < ctr->num_subkeys; j++) {
			werr = regsubkey_ctr_hash_keyname(ctr, ctr->subkeys[j], j);
			W_ERROR_NOT_OK_RETURN(werr);
		}
	}

	return WERR_OK;
}

/***********************************************************************
 Check for the existance of a key
 **********************************************************************/

bool regsubkey_ctr_key_exists( struct regsubkey_ctr *ctr, const char *keyname )
{
	WERROR werr;

	if (!ctr->subkeys) {
		return False;
	}

	werr = regsubkey_ctr_index_for_keyname(ctr, keyname, NULL);
	if (!W_ERROR_IS_OK(werr)) {
		return false;
	}

	return true;
}

/***********************************************************************
 How many keys does the container hold ?
 **********************************************************************/

int regsubkey_ctr_numkeys( struct regsubkey_ctr *ctr )
{
	return ctr->num_subkeys;
}

/***********************************************************************
 Retreive a specific key string
 **********************************************************************/

char* regsubkey_ctr_specific_key( struct regsubkey_ctr *ctr, uint32_t key_index )
{
	if ( ! (key_index < ctr->num_subkeys) )
		return NULL;

	return ctr->subkeys[key_index];
}

/*
 * Utility functions for REGVAL_CTR
 */

/***********************************************************************
 How many keys does the container hold ?
 **********************************************************************/

int regval_ctr_numvals( REGVAL_CTR *ctr )
{
	return ctr->num_values;
}

/***********************************************************************
 allocate memory for and duplicate a REGISTRY_VALUE.
 This is malloc'd memory so the caller should free it when done
 **********************************************************************/

REGISTRY_VALUE* dup_registry_value( REGISTRY_VALUE *val )
{
	REGISTRY_VALUE 	*copy = NULL;

	if ( !val )
		return NULL;

	if ( !(copy = SMB_MALLOC_P( REGISTRY_VALUE)) ) {
		DEBUG(0,("dup_registry_value: malloc() failed!\n"));
		return NULL;
	}

	/* copy all the non-pointer initial data */

	memcpy( copy, val, sizeof(REGISTRY_VALUE) );

	copy->size = 0;
	copy->data_p = NULL;

	if ( val->data_p && val->size )
	{
		if ( !(copy->data_p = (uint8 *)memdup( val->data_p,
						       val->size )) ) {
			DEBUG(0,("dup_registry_value: memdup() failed for [%d] "
				 "bytes!\n", val->size));
			SAFE_FREE( copy );
			return NULL;
		}
		copy->size = val->size;
	}

	return copy;
}

/**********************************************************************
 free the memory allocated to a REGISTRY_VALUE
 *********************************************************************/

void free_registry_value( REGISTRY_VALUE *val )
{
	if ( !val )
		return;

	SAFE_FREE( val->data_p );
	SAFE_FREE( val );

	return;
}

/**********************************************************************
 *********************************************************************/

uint8* regval_data_p( REGISTRY_VALUE *val )
{
	return val->data_p;
}

/**********************************************************************
 *********************************************************************/

uint32 regval_size( REGISTRY_VALUE *val )
{
	return val->size;
}

/**********************************************************************
 *********************************************************************/

char* regval_name( REGISTRY_VALUE *val )
{
	return val->valuename;
}

/**********************************************************************
 *********************************************************************/

uint32 regval_type( REGISTRY_VALUE *val )
{
	return val->type;
}

/***********************************************************************
 Retreive a pointer to a specific value.  Caller shoud dup the structure
 since this memory will go away when the ctr is free()'d
 **********************************************************************/

REGISTRY_VALUE* regval_ctr_specific_value( REGVAL_CTR *ctr, uint32 idx )
{
	if ( !(idx < ctr->num_values) )
		return NULL;

	return ctr->values[idx];
}

/***********************************************************************
 Check for the existance of a value
 **********************************************************************/

bool regval_ctr_key_exists( REGVAL_CTR *ctr, const char *value )
{
	int 	i;

	for ( i=0; i<ctr->num_values; i++ ) {
		if ( strequal( ctr->values[i]->valuename, value) )
			return True;
	}

	return False;
}

/***********************************************************************
 * compose a REGISTRY_VALUE from input data
 **********************************************************************/

REGISTRY_VALUE *regval_compose(TALLOC_CTX *ctx, const char *name, uint16 type,
			       const char *data_p, size_t size)
{
	REGISTRY_VALUE *regval = TALLOC_P(ctx, REGISTRY_VALUE);

	if (regval == NULL) {
		return NULL;
	}

	fstrcpy(regval->valuename, name);
	regval->type = type;
	if (size) {
		regval->data_p = (uint8 *)TALLOC_MEMDUP(regval, data_p, size);
		if (!regval->data_p) {
			TALLOC_FREE(regval);
			return NULL;
		}
	} else {
		regval->data_p = NULL;
	}
	regval->size = size;

	return regval;
}

/***********************************************************************
 Add a new registry value to the array
 **********************************************************************/

int regval_ctr_addvalue( REGVAL_CTR *ctr, const char *name, uint16 type,
                         const char *data_p, size_t size )
{
	if ( !name )
		return ctr->num_values;

	/* Delete the current value (if it exists) and add the new one */

	regval_ctr_delvalue( ctr, name );

	/* allocate a slot in the array of pointers */

	if (  ctr->num_values == 0 ) {
		ctr->values = TALLOC_P( ctr, REGISTRY_VALUE *);
	} else {
		ctr->values = TALLOC_REALLOC_ARRAY(ctr, ctr->values,
						   REGISTRY_VALUE *,
						   ctr->num_values+1);
	}

	if (!ctr->values) {
		ctr->num_values = 0;
		return 0;
	}

	/* allocate a new value and store the pointer in the arrya */

	ctr->values[ctr->num_values] = regval_compose(ctr, name, type, data_p,
						      size);
	if (ctr->values[ctr->num_values] == NULL) {
		ctr->num_values = 0;
		return 0;
	}
	ctr->num_values++;

	return ctr->num_values;
}

/***********************************************************************
 Add a new registry value to the array
 **********************************************************************/

int regval_ctr_copyvalue( REGVAL_CTR *ctr, REGISTRY_VALUE *val )
{
	if ( val ) {
		regval_ctr_addvalue(ctr, val->valuename, val->type,
				    (char *)val->data_p, val->size);
	}

	return ctr->num_values;
}

/***********************************************************************
 Delete a single value from the registry container.
 No need to free memory since it is talloc'd.
 **********************************************************************/

int regval_ctr_delvalue( REGVAL_CTR *ctr, const char *name )
{
	int 	i;

	for ( i=0; i<ctr->num_values; i++ ) {
		if ( strequal( ctr->values[i]->valuename, name ) )
			break;
	}

	/* just return if we don't find it */

	if ( i == ctr->num_values )
		return ctr->num_values;

	/* If 'i' was not the last element, just shift everything down one */
	ctr->num_values--;
	if ( i < ctr->num_values )
		memmove(&ctr->values[i], &ctr->values[i+1],
			sizeof(REGISTRY_VALUE*)*(ctr->num_values-i));

	return ctr->num_values;
}

/***********************************************************************
 Retrieve single value from the registry container.
 No need to free memory since it is talloc'd.
 **********************************************************************/

REGISTRY_VALUE* regval_ctr_getvalue( REGVAL_CTR *ctr, const char *name )
{
	int 	i;

	/* search for the value */

	for ( i=0; i<ctr->num_values; i++ ) {
		if ( strequal( ctr->values[i]->valuename, name ) )
			return ctr->values[i];
	}

	return NULL;
}

/***********************************************************************
 return the data_p as a uint32
 **********************************************************************/

uint32 regval_dword( REGISTRY_VALUE *val )
{
	uint32 data;

	data = IVAL( regval_data_p(val), 0 );

	return data;
}

/***********************************************************************
 return the data_p as a character string
 **********************************************************************/

char *regval_sz(REGISTRY_VALUE *val)
{
	char *data = NULL;

	rpcstr_pull_talloc(talloc_tos(), &data,
			regval_data_p(val), regval_size(val),0);
	return data;
}