libc/rpc/rpcb_prot.c

1.1  fvdl /*	$NetBSD: rpcb_prot.c,v 1.1 2000/06/02 23:11:15 fvdl Exp $	*/
1.1  fvdl
1.1  fvdl /*
1.1  fvdl  * Sun RPC is a product of Sun Microsystems, Inc. and is provided for
1.1  fvdl  * unrestricted use provided that this legend is included on all tape
1.1  fvdl  * media and as a part of the software program in whole or part.  Users
1.1  fvdl  * may copy or modify Sun RPC without charge, but are not authorized
1.1  fvdl  * to license or distribute it to anyone else except as part of a product or
1.1  fvdl  * program developed by the user.
1.1  fvdl  *
1.1  fvdl  * SUN RPC IS PROVIDED AS IS WITH NO WARRANTIES OF ANY KIND INCLUDING THE
1.1  fvdl  * WARRANTIES OF DESIGN, MERCHANTIBILITY AND FITNESS FOR A PARTICULAR
1.1  fvdl  * PURPOSE, OR ARISING FROM A COURSE OF DEALING, USAGE OR TRADE PRACTICE.
1.1  fvdl  *
1.1  fvdl  * Sun RPC is provided with no support and without any obligation on the
1.1  fvdl  * part of Sun Microsystems, Inc. to assist in its use, correction,
1.1  fvdl  * modification or enhancement.
1.1  fvdl  *
1.1  fvdl  * SUN MICROSYSTEMS, INC. SHALL HAVE NO LIABILITY WITH RESPECT TO THE
1.1  fvdl  * INFRINGEMENT OF COPYRIGHTS, TRADE SECRETS OR ANY PATENTS BY SUN RPC
1.1  fvdl  * OR ANY PART THEREOF.
1.1  fvdl  *
1.1  fvdl  * In no event will Sun Microsystems, Inc. be liable for any lost revenue
1.1  fvdl  * or profits or other special, indirect and consequential damages, even if
1.1  fvdl  * Sun has been advised of the possibility of such damages.
1.1  fvdl  *
1.1  fvdl  * Sun Microsystems, Inc.
1.1  fvdl  * 2550 Garcia Avenue
1.1  fvdl  * Mountain View, California  94043
1.1  fvdl  */
1.1  fvdl /*
1.1  fvdl  * Copyright (c) 1986-1991 by Sun Microsystems Inc.
1.1  fvdl  */
1.1  fvdl
1.1  fvdl /* #ident	"@(#)rpcb_prot.c	1.13	94/04/24 SMI" */
1.1  fvdl
1.1  fvdl #if 0
1.1  fvdl #if !defined(lint) && defined(SCCSIDS)
1.1  fvdl static char sccsid[] = "@(#)rpcb_prot.c 1.9 89/04/21 Copyr 1984 Sun Micro";
1.1  fvdl #endif
1.1  fvdl #endif
1.1  fvdl
1.1  fvdl /*
1.1  fvdl  * rpcb_prot.c
1.1  fvdl  * XDR routines for the rpcbinder version 3.
1.1  fvdl  *
1.1  fvdl  * Copyright (C) 1984, 1988, Sun Microsystems, Inc.
1.1  fvdl  */
1.1  fvdl
1.1  fvdl #include "namespace.h"
1.1  fvdl
1.1  fvdl #include <rpc/rpc.h>
1.1  fvdl #include <rpc/types.h>
1.1  fvdl #include <rpc/xdr.h>
1.1  fvdl #include <rpc/rpcb_prot.h>
1.1  fvdl
1.1  fvdl #ifdef __weak_alias
1.1  fvdl __weak_alias(xdr_rpcb,_xdr_rpcb)
1.1  fvdl __weak_alias(xdr_rpcblist_ptr,_xdr_rpcblist_ptr)
1.1  fvdl __weak_alias(xdr_rpcblist,_xdr_rpcblist)
1.1  fvdl __weak_alias(xdr_rpcb_entry,_xdr_rpcb_entry)
1.1  fvdl __weak_alias(xdr_rpcb_entry_list_ptr,_xdr_rpcb_entry_list_ptr)
1.1  fvdl __weak_alias(xdr_rpcb_rmtcallargs,_xdr_rpcb_rmtcallargs)
1.1  fvdl __weak_alias(xdr_rpcb_rmtcallres,_xdr_rpcb_rmtcallres)
1.1  fvdl __weak_alias(xdr_netbuf,_xdr_netbuf)
1.1  fvdl #endif
1.1  fvdl
1.1  fvdl
1.1  fvdl bool_t
1.1  fvdl xdr_rpcb(xdrs, objp)
1.1  fvdl 	XDR *xdrs;
1.1  fvdl 	RPCB *objp;
1.1  fvdl {
1.1  fvdl 	if (!xdr_u_int32_t(xdrs, &objp->r_prog)) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	if (!xdr_u_int32_t(xdrs, &objp->r_vers)) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	if (!xdr_string(xdrs, &objp->r_netid, ~0)) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	if (!xdr_string(xdrs, &objp->r_addr, ~0)) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	if (!xdr_string(xdrs, &objp->r_owner, ~0)) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	return (TRUE);
1.1  fvdl }
1.1  fvdl
1.1  fvdl /*
1.1  fvdl  * rpcblist_ptr implements a linked list.  The RPCL definition from
1.1  fvdl  * rpcb_prot.x is:
1.1  fvdl  *
1.1  fvdl  * struct rpcblist {
1.1  fvdl  * 	rpcb		rpcb_map;
1.1  fvdl  *	struct rpcblist *rpcb_next;
1.1  fvdl  * };
1.1  fvdl  * typedef rpcblist *rpcblist_ptr;
1.1  fvdl  *
1.1  fvdl  * Recall that "pointers" in XDR are encoded as a boolean, indicating whether
1.1  fvdl  * there's any data behind the pointer, followed by the data (if any exists).
1.1  fvdl  * The boolean can be interpreted as ``more data follows me''; if FALSE then
1.1  fvdl  * nothing follows the boolean; if TRUE then the boolean is followed by an
1.1  fvdl  * actual struct rpcb, and another rpcblist_ptr (declared in RPCL as "struct
1.1  fvdl  * rpcblist *").
1.1  fvdl  *
1.1  fvdl  * This could be implemented via the xdr_pointer type, though this would
1.1  fvdl  * result in one recursive call per element in the list.  Rather than do that
1.1  fvdl  * we can ``unwind'' the recursion into a while loop and use xdr_reference to
1.1  fvdl  * serialize the rpcb elements.
1.1  fvdl  */
1.1  fvdl
1.1  fvdl bool_t
1.1  fvdl xdr_rpcblist_ptr(xdrs, rp)
1.1  fvdl 	register XDR *xdrs;
1.1  fvdl 	register rpcblist_ptr *rp;
1.1  fvdl {
1.1  fvdl 	/*
1.1  fvdl 	 * more_elements is pre-computed in case the direction is
1.1  fvdl 	 * XDR_ENCODE or XDR_FREE.  more_elements is overwritten by
1.1  fvdl 	 * xdr_bool when the direction is XDR_DECODE.
1.1  fvdl 	 */
1.1  fvdl 	bool_t more_elements;
1.1  fvdl 	register int freeing = (xdrs->x_op == XDR_FREE);
1.1  fvdl 	rpcblist_ptr next;
1.1  fvdl 	rpcblist_ptr next_copy;
1.1  fvdl
1.1  fvdl 	while (TRUE) {
1.1  fvdl 		more_elements = (bool_t)(*rp != NULL);
1.1  fvdl 		if (! xdr_bool(xdrs, &more_elements)) {
1.1  fvdl 			return (FALSE);
1.1  fvdl 		}
1.1  fvdl 		if (! more_elements) {
1.1  fvdl 			return (TRUE);  /* we are done */
1.1  fvdl 		}
1.1  fvdl 		/*
1.1  fvdl 		 * the unfortunate side effect of non-recursion is that in
1.1  fvdl 		 * the case of freeing we must remember the next object
1.1  fvdl 		 * before we free the current object ...
1.1  fvdl 		 */
1.1  fvdl 		if (freeing)
1.1  fvdl 			next = (*rp)->rpcb_next;
1.1  fvdl 		if (! xdr_reference(xdrs, (caddr_t *)rp,
1.1  fvdl 		    (u_int)sizeof (rpcblist), (xdrproc_t)xdr_rpcb)) {
1.1  fvdl 			return (FALSE);
1.1  fvdl 		}
1.1  fvdl 		if (freeing) {
1.1  fvdl 			next_copy = next;
1.1  fvdl 			rp = &next_copy;
1.1  fvdl 			/*
1.1  fvdl 			 * Note that in the subsequent iteration, next_copy
1.1  fvdl 			 * gets nulled out by the xdr_reference
1.1  fvdl 			 * but next itself survives.
1.1  fvdl 			 */
1.1  fvdl 		} else {
1.1  fvdl 			rp = &((*rp)->rpcb_next);
1.1  fvdl 		}
1.1  fvdl 	}
1.1  fvdl 	/*NOTREACHED*/
1.1  fvdl }
1.1  fvdl
1.1  fvdl /*
1.1  fvdl  * xdr_rpcblist() is specified to take a RPCBLIST **, but is identical in
1.1  fvdl  * functionality to xdr_rpcblist_ptr().
1.1  fvdl  */
1.1  fvdl bool_t
1.1  fvdl xdr_rpcblist(xdrs, rp)
1.1  fvdl 	register XDR *xdrs;
1.1  fvdl 	register RPCBLIST **rp;
1.1  fvdl {
1.1  fvdl 	bool_t	dummy;
1.1  fvdl
1.1  fvdl 	dummy = xdr_rpcblist_ptr(xdrs, (rpcblist_ptr *)rp);
1.1  fvdl 	return (dummy);
1.1  fvdl }
1.1  fvdl
1.1  fvdl
1.1  fvdl bool_t
1.1  fvdl xdr_rpcb_entry(xdrs, objp)
1.1  fvdl 	XDR *xdrs;
1.1  fvdl 	rpcb_entry *objp;
1.1  fvdl {
1.1  fvdl 	if (!xdr_string(xdrs, &objp->r_maddr, ~0)) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	if (!xdr_string(xdrs, &objp->r_nc_netid, ~0)) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	if (!xdr_u_int32_t(xdrs, &objp->r_nc_semantics)) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	if (!xdr_string(xdrs, &objp->r_nc_protofmly, ~0)) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	if (!xdr_string(xdrs, &objp->r_nc_proto, ~0)) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	return (TRUE);
1.1  fvdl }
1.1  fvdl
1.1  fvdl bool_t
1.1  fvdl xdr_rpcb_entry_list_ptr(xdrs, rp)
1.1  fvdl 	register XDR *xdrs;
1.1  fvdl 	register rpcb_entry_list_ptr *rp;
1.1  fvdl {
1.1  fvdl 	/*
1.1  fvdl 	 * more_elements is pre-computed in case the direction is
1.1  fvdl 	 * XDR_ENCODE or XDR_FREE.  more_elements is overwritten by
1.1  fvdl 	 * xdr_bool when the direction is XDR_DECODE.
1.1  fvdl 	 */
1.1  fvdl 	bool_t more_elements;
1.1  fvdl 	register int freeing = (xdrs->x_op == XDR_FREE);
1.1  fvdl 	rpcb_entry_list_ptr next;
1.1  fvdl 	rpcb_entry_list_ptr next_copy;
1.1  fvdl
1.1  fvdl 	while (TRUE) {
1.1  fvdl 		more_elements = (bool_t)(*rp != NULL);
1.1  fvdl 		if (! xdr_bool(xdrs, &more_elements)) {
1.1  fvdl 			return (FALSE);
1.1  fvdl 		}
1.1  fvdl 		if (! more_elements) {
1.1  fvdl 			return (TRUE);  /* we are done */
1.1  fvdl 		}
1.1  fvdl 		/*
1.1  fvdl 		 * the unfortunate side effect of non-recursion is that in
1.1  fvdl 		 * the case of freeing we must remember the next object
1.1  fvdl 		 * before we free the current object ...
1.1  fvdl 		 */
1.1  fvdl 		if (freeing)
1.1  fvdl 			next = (*rp)->rpcb_entry_next;
1.1  fvdl 		if (! xdr_reference(xdrs, (caddr_t *)rp,
1.1  fvdl 		    (u_int)sizeof (rpcb_entry_list),
1.1  fvdl 				    (xdrproc_t)xdr_rpcb_entry)) {
1.1  fvdl 			return (FALSE);
1.1  fvdl 		}
1.1  fvdl 		if (freeing) {
1.1  fvdl 			next_copy = next;
1.1  fvdl 			rp = &next_copy;
1.1  fvdl 			/*
1.1  fvdl 			 * Note that in the subsequent iteration, next_copy
1.1  fvdl 			 * gets nulled out by the xdr_reference
1.1  fvdl 			 * but next itself survives.
1.1  fvdl 			 */
1.1  fvdl 		} else {
1.1  fvdl 			rp = &((*rp)->rpcb_entry_next);
1.1  fvdl 		}
1.1  fvdl 	}
1.1  fvdl 	/*NOTREACHED*/
1.1  fvdl }
1.1  fvdl
1.1  fvdl /*
1.1  fvdl  * XDR remote call arguments
1.1  fvdl  * written for XDR_ENCODE direction only
1.1  fvdl  */
1.1  fvdl bool_t
1.1  fvdl xdr_rpcb_rmtcallargs(xdrs, p)
1.1  fvdl 	XDR *xdrs;
1.1  fvdl 	struct rpcb_rmtcallargs *p;
1.1  fvdl {
1.1  fvdl 	struct r_rpcb_rmtcallargs *objp = (struct r_rpcb_rmtcallargs *)p;
1.1  fvdl 	u_int lenposition, argposition, position;
1.1  fvdl 	int32_t *buf;
1.1  fvdl
1.1  fvdl 	buf = XDR_INLINE(xdrs, 3 * BYTES_PER_XDR_UNIT);
1.1  fvdl 	if (buf == NULL) {
1.1  fvdl 		if (!xdr_u_int32_t(xdrs, &objp->prog)) {
1.1  fvdl 			return (FALSE);
1.1  fvdl 		}
1.1  fvdl 		if (!xdr_u_int32_t(xdrs, &objp->vers)) {
1.1  fvdl 			return (FALSE);
1.1  fvdl 		}
1.1  fvdl 		if (!xdr_u_int32_t(xdrs, &objp->proc)) {
1.1  fvdl 			return (FALSE);
1.1  fvdl 		}
1.1  fvdl 	} else {
1.1  fvdl 		IXDR_PUT_U_LONG(buf, objp->prog);
1.1  fvdl 		IXDR_PUT_U_LONG(buf, objp->vers);
1.1  fvdl 		IXDR_PUT_U_LONG(buf, objp->proc);
1.1  fvdl 	}
1.1  fvdl
1.1  fvdl 	/*
1.1  fvdl 	 * All the jugglery for just getting the size of the arguments
1.1  fvdl 	 */
1.1  fvdl 	lenposition = XDR_GETPOS(xdrs);
1.1  fvdl 	if (! xdr_u_int(xdrs, &(objp->args.args_len))) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	argposition = XDR_GETPOS(xdrs);
1.1  fvdl 	if (! (*objp->xdr_args)(xdrs, objp->args.args_val)) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	position = XDR_GETPOS(xdrs);
1.1  fvdl 	objp->args.args_len = (u_long)position - (u_long)argposition;
1.1  fvdl 	XDR_SETPOS(xdrs, lenposition);
1.1  fvdl 	if (! xdr_u_int(xdrs, &(objp->args.args_len))) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	XDR_SETPOS(xdrs, position);
1.1  fvdl 	return (TRUE);
1.1  fvdl }
1.1  fvdl
1.1  fvdl /*
1.1  fvdl  * XDR remote call results
1.1  fvdl  * written for XDR_DECODE direction only
1.1  fvdl  */
1.1  fvdl bool_t
1.1  fvdl xdr_rpcb_rmtcallres(xdrs, p)
1.1  fvdl 	XDR *xdrs;
1.1  fvdl 	struct rpcb_rmtcallres *p;
1.1  fvdl {
1.1  fvdl 	bool_t dummy;
1.1  fvdl 	struct r_rpcb_rmtcallres *objp = (struct r_rpcb_rmtcallres *)p;
1.1  fvdl
1.1  fvdl 	if (!xdr_string(xdrs, &objp->addr, ~0)) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	if (!xdr_u_int(xdrs, &objp->results.results_len)) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	dummy = (*(objp->xdr_res))(xdrs, objp->results.results_val);
1.1  fvdl 	return (dummy);
1.1  fvdl }
1.1  fvdl
1.1  fvdl bool_t
1.1  fvdl xdr_netbuf(xdrs, objp)
1.1  fvdl 	XDR *xdrs;
1.1  fvdl 	struct netbuf *objp;
1.1  fvdl {
1.1  fvdl 	bool_t dummy;
1.1  fvdl
1.1  fvdl 	if (!xdr_u_int32_t(xdrs, (u_int32_t *) &objp->maxlen)) {
1.1  fvdl 		return (FALSE);
1.1  fvdl 	}
1.1  fvdl 	dummy = xdr_bytes(xdrs, (char **)&(objp->buf),
1.1  fvdl 			(u_int *)&(objp->len), objp->maxlen);
1.1  fvdl 	return (dummy);
1.1  fvdl }