/* $NetBSD: xdr.h,v 1.17 2000/06/02 22:57:57 fvdl Exp $ */ /* * Sun RPC is a product of Sun Microsystems, Inc. and is provided for * unrestricted use provided that this legend is included on all tape * media and as a part of the software program in whole or part. Users * may copy or modify Sun RPC without charge, but are not authorized * to license or distribute it to anyone else except as part of a product or * program developed by the user. * * SUN RPC IS PROVIDED AS IS WITH NO WARRANTIES OF ANY KIND INCLUDING THE * WARRANTIES OF DESIGN, MERCHANTIBILITY AND FITNESS FOR A PARTICULAR * PURPOSE, OR ARISING FROM A COURSE OF DEALING, USAGE OR TRADE PRACTICE. * * Sun RPC is provided with no support and without any obligation on the * part of Sun Microsystems, Inc. to assist in its use, correction, * modification or enhancement. * * SUN MICROSYSTEMS, INC. SHALL HAVE NO LIABILITY WITH RESPECT TO THE * INFRINGEMENT OF COPYRIGHTS, TRADE SECRETS OR ANY PATENTS BY SUN RPC * OR ANY PART THEREOF. * * In no event will Sun Microsystems, Inc. be liable for any lost revenue * or profits or other special, indirect and consequential damages, even if * Sun has been advised of the possibility of such damages. * * Sun Microsystems, Inc. * 2550 Garcia Avenue * Mountain View, California 94043 * * from: @(#)xdr.h 1.19 87/04/22 SMI * @(#)xdr.h 2.2 88/07/29 4.0 RPCSRC */ /* * xdr.h, External Data Representation Serialization Routines. * * Copyright (C) 1984, Sun Microsystems, Inc. */ #ifndef _RPC_XDR_H_ #define _RPC_XDR_H_ #include /* * XDR provides a conventional way for converting between C data * types and an external bit-string representation. Library supplied * routines provide for the conversion on built-in C data types. These * routines and utility routines defined here are used to help implement * a type encode/decode routine for each user-defined type. * * Each data type provides a single procedure which takes two arguments: * * bool_t * xdrproc(xdrs, argresp) * XDR *xdrs; * *argresp; * * xdrs is an instance of a XDR handle, to which or from which the data * type is to be converted. argresp is a pointer to the structure to be * converted. The XDR handle contains an operation field which indicates * which of the operations (ENCODE, DECODE * or FREE) is to be performed. * * XDR_DECODE may allocate space if the pointer argresp is null. This * data can be freed with the XDR_FREE operation. * * We write only one procedure per data type to make it easy * to keep the encode and decode procedures for a data type consistent. * In many cases the same code performs all operations on a user defined type, * because all the hard work is done in the component type routines. * decode as a series of calls on the nested data types. */ /* * Xdr operations. XDR_ENCODE causes the type to be encoded into the * stream. XDR_DECODE causes the type to be extracted from the stream. * XDR_FREE can be used to release the space allocated by an XDR_DECODE * request. */ enum xdr_op { XDR_ENCODE=0, XDR_DECODE=1, XDR_FREE=2 }; /* * This is the number of bytes per unit of external data. */ #define BYTES_PER_XDR_UNIT (4) #define RNDUP(x) ((((x) + BYTES_PER_XDR_UNIT - 1) / BYTES_PER_XDR_UNIT) \ * BYTES_PER_XDR_UNIT) /* * The XDR handle. * Contains operation which is being applied to the stream, * an operations vector for the paticular implementation (e.g. see xdr_mem.c), * and two private fields for the use of the particular impelementation. */ typedef struct __rpc_xdr { enum xdr_op x_op; /* operation; fast additional param */ const struct xdr_ops { /* get a long from underlying stream */ bool_t (*x_getlong) __P((struct __rpc_xdr *, long *)); /* put a long to " */ bool_t (*x_putlong) __P((struct __rpc_xdr *, const long *)); /* get some bytes from " */ bool_t (*x_getbytes) __P((struct __rpc_xdr *, char *, u_int)); /* put some bytes to " */ bool_t (*x_putbytes) __P((struct __rpc_xdr *, const char *, u_int)); /* returns bytes off from beginning */ u_int (*x_getpostn) __P((struct __rpc_xdr *)); /* lets you reposition the stream */ bool_t (*x_setpostn) __P((struct __rpc_xdr *, u_int)); /* buf quick ptr to buffered data */ int32_t *(*x_inline) __P((struct __rpc_xdr *, u_int)); /* free privates of this xdr_stream */ void (*x_destroy) __P((struct __rpc_xdr *)); bool_t (*x_control) __P((struct __rpc_xdr *, int, void *)); } *x_ops; char * x_public; /* users' data */ void * x_private; /* pointer to private data */ char * x_base; /* private used for position info */ int x_handy; /* extra private word */ } XDR; /* * A xdrproc_t exists for each data type which is to be encoded or decoded. * * The second argument to the xdrproc_t is a pointer to an opaque pointer. * The opaque pointer generally points to a structure of the data type * to be decoded. If this pointer is 0, then the type routines should * allocate dynamic storage of the appropriate size and return it. * * XXX can't actually prototype it, because some take three args!!! */ typedef bool_t (*xdrproc_t) __P((/* XDR *, void *, u_int */)); /* * Operations defined on a XDR handle * * XDR *xdrs; * long *longp; * char * addr; * u_int len; * u_int pos; */ #define XDR_GETLONG(xdrs, longp) \ (*(xdrs)->x_ops->x_getlong)(xdrs, longp) #define xdr_getlong(xdrs, longp) \ (*(xdrs)->x_ops->x_getlong)(xdrs, longp) #define XDR_PUTLONG(xdrs, longp) \ (*(xdrs)->x_ops->x_putlong)(xdrs, longp) #define xdr_putlong(xdrs, longp) \ (*(xdrs)->x_ops->x_putlong)(xdrs, longp) #define XDR_GETBYTES(xdrs, addr, len) \ (*(xdrs)->x_ops->x_getbytes)(xdrs, addr, len) #define xdr_getbytes(xdrs, addr, len) \ (*(xdrs)->x_ops->x_getbytes)(xdrs, addr, len) #define XDR_PUTBYTES(xdrs, addr, len) \ (*(xdrs)->x_ops->x_putbytes)(xdrs, addr, len) #define xdr_putbytes(xdrs, addr, len) \ (*(xdrs)->x_ops->x_putbytes)(xdrs, addr, len) #define XDR_GETPOS(xdrs) \ (*(xdrs)->x_ops->x_getpostn)(xdrs) #define xdr_getpos(xdrs) \ (*(xdrs)->x_ops->x_getpostn)(xdrs) #define XDR_SETPOS(xdrs, pos) \ (*(xdrs)->x_ops->x_setpostn)(xdrs, pos) #define xdr_setpos(xdrs, pos) \ (*(xdrs)->x_ops->x_setpostn)(xdrs, pos) #define XDR_INLINE(xdrs, len) \ (*(xdrs)->x_ops->x_inline)(xdrs, len) #define xdr_inline(xdrs, len) \ (*(xdrs)->x_ops->x_inline)(xdrs, len) #define XDR_DESTROY(xdrs) \ if ((xdrs)->x_ops->x_destroy) \ (*(xdrs)->x_ops->x_destroy)(xdrs) #define xdr_destroy(xdrs) \ if ((xdrs)->x_ops->x_destroy) \ (*(xdrs)->x_ops->x_destroy)(xdrs) #define XDR_CONTROL(xdrs, req, op) \ if ((xdrs)->x_ops->x_control) \ (*(xdrs)->x_ops->x_control)(xdrs, req, op) #define xdr_control(xdrs, req, op) XDR_CONTROL(xdrs, req, op) /* * Solaris strips the '_t' from these types -- not sure why. * But, let's be compatible. */ #define xdr_rpcvers(xdrs, versp) xdr_u_int32(xdrs, versp) #define xdr_rpcprog(xdrs, progp) xdr_u_int32(xdrs, progp) #define xdr_rpcproc(xdrs, procp) xdr_u_int32(xdrs, procp) #define xdr_rpcprot(xdrs, protp) xdr_u_int32(xdrs, protp) #define xdr_rpcport(xdrs, portp) xdr_u_int32(xdrs, portp) /* * Support struct for discriminated unions. * You create an array of xdrdiscrim structures, terminated with * a entry with a null procedure pointer. The xdr_union routine gets * the discriminant value and then searches the array of structures * for a matching value. If a match is found the associated xdr routine * is called to handle that part of the union. If there is * no match, then a default routine may be called. * If there is no match and no default routine it is an error. */ #define NULL_xdrproc_t ((xdrproc_t)0) struct xdr_discrim { int value; xdrproc_t proc; }; /* * In-line routines for fast encode/decode of primitive data types. * Caveat emptor: these use single memory cycles to get the * data from the underlying buffer, and will fail to operate * properly if the data is not aligned. The standard way to use these * is to say: * if ((buf = XDR_INLINE(xdrs, count)) == NULL) * return (FALSE); * <<< macro calls >>> * where ``count'' is the number of bytes of data occupied * by the primitive data types. * * N.B. and frozen for all time: each data type here uses 4 bytes * of external representation. */ #define IXDR_GET_LONG(buf) ((long)ntohl((u_int32_t)*(buf)++)) #define IXDR_PUT_LONG(buf, v) (*(buf)++ =(int32_t)htonl((u_int32_t)v)) #define IXDR_GET_BOOL(buf) ((bool_t)IXDR_GET_LONG(buf)) #define IXDR_GET_ENUM(buf, t) ((t)IXDR_GET_LONG(buf)) #define IXDR_GET_U_LONG(buf) ((u_long)IXDR_GET_LONG(buf)) #define IXDR_GET_SHORT(buf) ((short)IXDR_GET_LONG(buf)) #define IXDR_GET_U_SHORT(buf) ((u_short)IXDR_GET_LONG(buf)) #define IXDR_PUT_BOOL(buf, v) IXDR_PUT_LONG((buf), (v)) #define IXDR_PUT_ENUM(buf, v) IXDR_PUT_LONG((buf), (v)) #define IXDR_PUT_U_LONG(buf, v) IXDR_PUT_LONG((buf), (v)) #define IXDR_PUT_SHORT(buf, v) IXDR_PUT_LONG((buf), (v)) #define IXDR_PUT_U_SHORT(buf, v) IXDR_PUT_LONG((buf), (v)) /* * These are the "generic" xdr routines. */ __BEGIN_DECLS extern bool_t xdr_void __P((void)); extern bool_t xdr_int __P((XDR *, int *)); extern bool_t xdr_u_int __P((XDR *, u_int *)); extern bool_t xdr_long __P((XDR *, long *)); extern bool_t xdr_u_long __P((XDR *, u_long *)); extern bool_t xdr_short __P((XDR *, short *)); extern bool_t xdr_u_short __P((XDR *, u_short *)); extern bool_t xdr_int16_t __P((XDR *, int16_t *)); extern bool_t xdr_u_int16_t __P((XDR *, u_int16_t *)); extern bool_t xdr_int32_t __P((XDR *, int32_t *)); extern bool_t xdr_u_int32_t __P((XDR *, u_int32_t *)); extern bool_t xdr_int64_t __P((XDR *, int64_t *)); extern bool_t xdr_u_int64_t __P((XDR *, u_int64_t *)); extern bool_t xdr_bool __P((XDR *, bool_t *)); extern bool_t xdr_enum __P((XDR *, enum_t *)); extern bool_t xdr_array __P((XDR *, char **, u_int *, u_int, u_int, xdrproc_t)); extern bool_t xdr_bytes __P((XDR *, char **, u_int *, u_int)); extern bool_t xdr_opaque __P((XDR *, char *, u_int)); extern bool_t xdr_string __P((XDR *, char **, u_int)); extern bool_t xdr_union __P((XDR *, enum_t *, char *, const struct xdr_discrim *, xdrproc_t)); extern bool_t xdr_char __P((XDR *, char *)); extern bool_t xdr_u_char __P((XDR *, u_char *)); extern bool_t xdr_vector __P((XDR *, char *, u_int, u_int, xdrproc_t)); extern bool_t xdr_float __P((XDR *, float *)); extern bool_t xdr_double __P((XDR *, double *)); extern bool_t xdr_quadruple __P((XDR *, long double *)); extern bool_t xdr_reference __P((XDR *, char **, u_int, xdrproc_t)); extern bool_t xdr_pointer __P((XDR *, char **, u_int, xdrproc_t)); extern bool_t xdr_wrapstring __P((XDR *, char **)); extern void xdr_free __P((xdrproc_t, char *)); extern bool_t xdr_hyper __P((XDR *, longlong_t *)); extern bool_t xdr_u_hyper __P((XDR *, u_longlong_t *)); extern bool_t xdr_longlong_t __P((XDR *, longlong_t *)); extern bool_t xdr_u_longlong_t __P((XDR *, u_longlong_t *)); __END_DECLS /* * Common opaque bytes objects used by many rpc protocols; * declared here due to commonality. */ #define MAX_NETOBJ_SZ 1024 struct netobj { u_int n_len; char *n_bytes; }; typedef struct netobj netobj; extern bool_t xdr_netobj __P((XDR *, struct netobj *)); /* * These are the public routines for the various implementations of * xdr streams. */ __BEGIN_DECLS /* XDR using memory buffers */ extern void xdrmem_create __P((XDR *, char *, u_int, enum xdr_op)); /* XDR using stdio library */ #ifdef _STDIO_H_ extern void xdrstdio_create __P((XDR *, FILE *, enum xdr_op)); #endif /* XDR pseudo records for tcp */ extern void xdrrec_create __P((XDR *, u_int, u_int, char *, int (*) __P((char *, char *, int)), int (*) __P((char *, char *, int)))); /* make end of xdr record */ extern bool_t xdrrec_endofrecord __P((XDR *, int)); /* move to beginning of next record */ extern bool_t xdrrec_skiprecord __P((XDR *)); /* true if no more input */ extern bool_t xdrrec_eof __P((XDR *)); extern u_int xdrrec_readbytes __P((XDR *, caddr_t, u_int)); __END_DECLS #endif /* !_RPC_XDR_H_ */