freebsd-nq/include/rpcsvc/key_prot.x

285 lines
6.2 KiB
Plaintext
Raw Normal View History

%/*
% * 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
% */
/*
* Key server protocol definition
* Copyright (C) 1990, 1991 Sun Microsystems, Inc.
*
* The keyserver is a public key storage/encryption/decryption service
* The encryption method used is based on the Diffie-Hellman exponential
* key exchange technology.
*
* The key server is local to each machine, akin to the portmapper.
* Under TI-RPC, communication with the keyserver is through the
* loopback transport.
*
* NOTE: This .x file generates the USER level headers for the keyserver.
* the KERNEL level headers are created by hand as they kernel has special
* requirements.
*/
%/* From: #pragma ident "@(#)key_prot.x 1.7 94/04/29 SMI" */
Bring in a hybrid of SunSoft's transport-independent RPC (TI-RPC) and associated changes that had to happen to make this possible as well as bugs fixed along the way. Bring in required TLI library routines to support this. Since we don't support TLI we've essentially copied what NetBSD has done, adding a thin layer to emulate direct the TLI calls into BSD socket calls. This is mostly from Sun's tirpc release that was made in 1994, however some fixes were backported from the 1999 release (supposedly only made available after this porting effort was underway). The submitter has agreed to continue on and bring us up to the 1999 release. Several key features are introduced with this update: Client calls are thread safe. (1999 code has server side thread safe) Updated, a more modern interface. Many userland updates were done to bring the code up to par with the recent RPC API. There is an update to the pthreads library, a function pthread_main_np() was added to emulate a function of Sun's threads library. While we're at it, bring in NetBSD's lockd, it's been far too long of a wait. New rpcbind(8) replaces portmap(8) (supporting communication over an authenticated Unix-domain socket, and by default only allowing set and unset requests over that channel). It's much more secure than the old portmapper. Umount(8), mountd(8), mount_nfs(8), nfsd(8) have also been upgraded to support TI-RPC and to support IPV6. Umount(8) is also fixed to unmount pathnames longer than 80 chars, which are currently truncated by the Kernel statfs structure. Submitted by: Martin Blapp <mb@imp.ch> Manpage review: ru Secure RPC implemented by: wpaul
2001-03-19 12:50:13 +00:00
%/* $FreeBSD$ */
%/* Copyright (c) 1990, 1991 Sun Microsystems, Inc. */
%
%/*
% * Compiled from key_prot.x using rpcgen.
% * DO NOT EDIT THIS FILE!
% * This is NOT source code!
% */
/*
* PROOT and MODULUS define the way the Diffie-Hellman key is generated.
*
* MODULUS should be chosen as a prime of the form: MODULUS == 2*p + 1,
* where p is also prime.
*
* PROOT satisfies the following two conditions:
* (1) (PROOT ** 2) % MODULUS != 1
* (2) (PROOT ** p) % MODULUS != 1
*
*/
const PROOT = 3;
const HEXMODULUS = "d4a0ba0250b6fd2ec626e7efd637df76c716e22d0944b88b";
const HEXKEYBYTES = 48; /* HEXKEYBYTES == strlen(HEXMODULUS) */
const KEYSIZE = 192; /* KEYSIZE == bit length of key */
const KEYBYTES = 24; /* byte length of key */
/*
* The first 16 hex digits of the encrypted secret key are used as
* a checksum in the database.
*/
const KEYCHECKSUMSIZE = 16;
/*
* status of operation
*/
enum keystatus {
KEY_SUCCESS, /* no problems */
KEY_NOSECRET, /* no secret key stored */
KEY_UNKNOWN, /* unknown netname */
KEY_SYSTEMERR /* system error (out of memory, encryption failure) */
};
typedef opaque keybuf[HEXKEYBYTES]; /* store key in hex */
typedef string netnamestr<MAXNETNAMELEN>;
/*
* Argument to ENCRYPT or DECRYPT
*/
struct cryptkeyarg {
netnamestr remotename;
des_block deskey;
};
/*
* Argument to ENCRYPT_PK or DECRYPT_PK
*/
struct cryptkeyarg2 {
netnamestr remotename;
netobj remotekey; /* Contains a length up to 1024 bytes */
des_block deskey;
};
/*
* Result of ENCRYPT, DECRYPT, ENCRYPT_PK, and DECRYPT_PK
*/
union cryptkeyres switch (keystatus status) {
case KEY_SUCCESS:
des_block deskey;
default:
void;
};
const MAXGIDS = 16; /* max number of gids in gid list */
/*
* Unix credential
*/
struct unixcred {
u_int uid;
u_int gid;
u_int gids<MAXGIDS>;
};
/*
* Result returned from GETCRED
*/
union getcredres switch (keystatus status) {
case KEY_SUCCESS:
unixcred cred;
default:
void;
};
/*
* key_netstarg;
*/
struct key_netstarg {
keybuf st_priv_key;
keybuf st_pub_key;
netnamestr st_netname;
};
union key_netstres switch (keystatus status){
case KEY_SUCCESS:
key_netstarg knet;
default:
void;
};
#ifdef RPC_HDR
%
%#ifndef opaque
%#define opaque char
%#endif
%
#endif
program KEY_PROG {
version KEY_VERS {
/*
* This is my secret key.
* Store it for me.
*/
keystatus
KEY_SET(keybuf) = 1;
/*
* I want to talk to X.
* Encrypt a conversation key for me.
*/
cryptkeyres
KEY_ENCRYPT(cryptkeyarg) = 2;
/*
* X just sent me a message.
* Decrypt the conversation key for me.
*/
cryptkeyres
KEY_DECRYPT(cryptkeyarg) = 3;
/*
* Generate a secure conversation key for me
*/
des_block
KEY_GEN(void) = 4;
/*
* Get me the uid, gid and group-access-list associated
* with this netname (for kernel which cannot use NIS)
*/
getcredres
KEY_GETCRED(netnamestr) = 5;
} = 1;
version KEY_VERS2 {
/*
* #######
* Procedures 1-5 are identical to version 1
* #######
*/
/*
* This is my secret key.
* Store it for me.
*/
keystatus
KEY_SET(keybuf) = 1;
/*
* I want to talk to X.
* Encrypt a conversation key for me.
*/
cryptkeyres
KEY_ENCRYPT(cryptkeyarg) = 2;
/*
* X just sent me a message.
* Decrypt the conversation key for me.
*/
cryptkeyres
KEY_DECRYPT(cryptkeyarg) = 3;
/*
* Generate a secure conversation key for me
*/
des_block
KEY_GEN(void) = 4;
/*
* Get me the uid, gid and group-access-list associated
* with this netname (for kernel which cannot use NIS)
*/
getcredres
KEY_GETCRED(netnamestr) = 5;
/*
* I want to talk to X. and I know X's public key
* Encrypt a conversation key for me.
*/
cryptkeyres
KEY_ENCRYPT_PK(cryptkeyarg2) = 6;
/*
* X just sent me a message. and I know X's public key
* Decrypt the conversation key for me.
*/
cryptkeyres
KEY_DECRYPT_PK(cryptkeyarg2) = 7;
/*
* Store my public key, netname and private key.
*/
keystatus
KEY_NET_PUT(key_netstarg) = 8;
/*
* Retrieve my public key, netname and private key.
*/
key_netstres
KEY_NET_GET(void) = 9;
/*
* Return me the conversation key that is constructed
* from my secret key and this publickey.
*/
cryptkeyres
KEY_GET_CONV(keybuf) = 10;
} = 2;
} = 100029;